xref: /freebsd/contrib/llvm-project/clang/lib/AST/Interp/Compiler.cpp (revision 7fdf597e96a02165cfe22ff357b857d5fa15ed8a)
1 //===--- Compiler.cpp - Code generator for expressions ---*- C++ -*-===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 
9 #include "Compiler.h"
10 #include "ByteCodeEmitter.h"
11 #include "Context.h"
12 #include "Floating.h"
13 #include "Function.h"
14 #include "InterpShared.h"
15 #include "PrimType.h"
16 #include "Program.h"
17 #include "clang/AST/Attr.h"
18 
19 using namespace clang;
20 using namespace clang::interp;
21 
22 using APSInt = llvm::APSInt;
23 
24 namespace clang {
25 namespace interp {
26 
27 /// Scope used to handle temporaries in toplevel variable declarations.
28 template <class Emitter> class DeclScope final : public LocalScope<Emitter> {
29 public:
30   DeclScope(Compiler<Emitter> *Ctx, const ValueDecl *VD)
31       : LocalScope<Emitter>(Ctx, VD), Scope(Ctx->P, VD),
32         OldGlobalDecl(Ctx->GlobalDecl),
33         OldInitializingDecl(Ctx->InitializingDecl) {
34     Ctx->GlobalDecl = Context::shouldBeGloballyIndexed(VD);
35     Ctx->InitializingDecl = VD;
36     Ctx->InitStack.push_back(InitLink::Decl(VD));
37   }
38 
39   void addExtended(const Scope::Local &Local) override {
40     return this->addLocal(Local);
41   }
42 
43   ~DeclScope() {
44     this->Ctx->GlobalDecl = OldGlobalDecl;
45     this->Ctx->InitializingDecl = OldInitializingDecl;
46     this->Ctx->InitStack.pop_back();
47   }
48 
49 private:
50   Program::DeclScope Scope;
51   bool OldGlobalDecl;
52   const ValueDecl *OldInitializingDecl;
53 };
54 
55 /// Scope used to handle initialization methods.
56 template <class Emitter> class OptionScope final {
57 public:
58   /// Root constructor, compiling or discarding primitives.
59   OptionScope(Compiler<Emitter> *Ctx, bool NewDiscardResult,
60               bool NewInitializing)
61       : Ctx(Ctx), OldDiscardResult(Ctx->DiscardResult),
62         OldInitializing(Ctx->Initializing) {
63     Ctx->DiscardResult = NewDiscardResult;
64     Ctx->Initializing = NewInitializing;
65   }
66 
67   ~OptionScope() {
68     Ctx->DiscardResult = OldDiscardResult;
69     Ctx->Initializing = OldInitializing;
70   }
71 
72 private:
73   /// Parent context.
74   Compiler<Emitter> *Ctx;
75   /// Old discard flag to restore.
76   bool OldDiscardResult;
77   bool OldInitializing;
78 };
79 
80 template <class Emitter>
81 bool InitLink::emit(Compiler<Emitter> *Ctx, const Expr *E) const {
82   switch (Kind) {
83   case K_This:
84     return Ctx->emitThis(E);
85   case K_Field:
86     // We're assuming there's a base pointer on the stack already.
87     return Ctx->emitGetPtrFieldPop(Offset, E);
88   case K_Temp:
89     return Ctx->emitGetPtrLocal(Offset, E);
90   case K_Decl:
91     return Ctx->visitDeclRef(D, E);
92   default:
93     llvm_unreachable("Unhandled InitLink kind");
94   }
95   return true;
96 }
97 
98 /// Scope managing label targets.
99 template <class Emitter> class LabelScope {
100 public:
101   virtual ~LabelScope() {}
102 
103 protected:
104   LabelScope(Compiler<Emitter> *Ctx) : Ctx(Ctx) {}
105   /// Compiler instance.
106   Compiler<Emitter> *Ctx;
107 };
108 
109 /// Sets the context for break/continue statements.
110 template <class Emitter> class LoopScope final : public LabelScope<Emitter> {
111 public:
112   using LabelTy = typename Compiler<Emitter>::LabelTy;
113   using OptLabelTy = typename Compiler<Emitter>::OptLabelTy;
114 
115   LoopScope(Compiler<Emitter> *Ctx, LabelTy BreakLabel, LabelTy ContinueLabel)
116       : LabelScope<Emitter>(Ctx), OldBreakLabel(Ctx->BreakLabel),
117         OldContinueLabel(Ctx->ContinueLabel) {
118     this->Ctx->BreakLabel = BreakLabel;
119     this->Ctx->ContinueLabel = ContinueLabel;
120   }
121 
122   ~LoopScope() {
123     this->Ctx->BreakLabel = OldBreakLabel;
124     this->Ctx->ContinueLabel = OldContinueLabel;
125   }
126 
127 private:
128   OptLabelTy OldBreakLabel;
129   OptLabelTy OldContinueLabel;
130 };
131 
132 // Sets the context for a switch scope, mapping labels.
133 template <class Emitter> class SwitchScope final : public LabelScope<Emitter> {
134 public:
135   using LabelTy = typename Compiler<Emitter>::LabelTy;
136   using OptLabelTy = typename Compiler<Emitter>::OptLabelTy;
137   using CaseMap = typename Compiler<Emitter>::CaseMap;
138 
139   SwitchScope(Compiler<Emitter> *Ctx, CaseMap &&CaseLabels, LabelTy BreakLabel,
140               OptLabelTy DefaultLabel)
141       : LabelScope<Emitter>(Ctx), OldBreakLabel(Ctx->BreakLabel),
142         OldDefaultLabel(this->Ctx->DefaultLabel),
143         OldCaseLabels(std::move(this->Ctx->CaseLabels)) {
144     this->Ctx->BreakLabel = BreakLabel;
145     this->Ctx->DefaultLabel = DefaultLabel;
146     this->Ctx->CaseLabels = std::move(CaseLabels);
147   }
148 
149   ~SwitchScope() {
150     this->Ctx->BreakLabel = OldBreakLabel;
151     this->Ctx->DefaultLabel = OldDefaultLabel;
152     this->Ctx->CaseLabels = std::move(OldCaseLabels);
153   }
154 
155 private:
156   OptLabelTy OldBreakLabel;
157   OptLabelTy OldDefaultLabel;
158   CaseMap OldCaseLabels;
159 };
160 
161 template <class Emitter> class StmtExprScope final {
162 public:
163   StmtExprScope(Compiler<Emitter> *Ctx) : Ctx(Ctx), OldFlag(Ctx->InStmtExpr) {
164     Ctx->InStmtExpr = true;
165   }
166 
167   ~StmtExprScope() { Ctx->InStmtExpr = OldFlag; }
168 
169 private:
170   Compiler<Emitter> *Ctx;
171   bool OldFlag;
172 };
173 
174 } // namespace interp
175 } // namespace clang
176 
177 template <class Emitter>
178 bool Compiler<Emitter>::VisitCastExpr(const CastExpr *CE) {
179   const Expr *SubExpr = CE->getSubExpr();
180   switch (CE->getCastKind()) {
181 
182   case CK_LValueToRValue: {
183     if (DiscardResult)
184       return this->discard(SubExpr);
185 
186     std::optional<PrimType> SubExprT = classify(SubExpr->getType());
187     // Prepare storage for the result.
188     if (!Initializing && !SubExprT) {
189       std::optional<unsigned> LocalIndex = allocateLocal(SubExpr);
190       if (!LocalIndex)
191         return false;
192       if (!this->emitGetPtrLocal(*LocalIndex, CE))
193         return false;
194     }
195 
196     if (!this->visit(SubExpr))
197       return false;
198 
199     if (SubExprT)
200       return this->emitLoadPop(*SubExprT, CE);
201 
202     // If the subexpr type is not primitive, we need to perform a copy here.
203     // This happens for example in C when dereferencing a pointer of struct
204     // type.
205     return this->emitMemcpy(CE);
206   }
207 
208   case CK_DerivedToBaseMemberPointer: {
209     assert(classifyPrim(CE->getType()) == PT_MemberPtr);
210     assert(classifyPrim(SubExpr->getType()) == PT_MemberPtr);
211     const auto *FromMP = SubExpr->getType()->getAs<MemberPointerType>();
212     const auto *ToMP = CE->getType()->getAs<MemberPointerType>();
213 
214     unsigned DerivedOffset = collectBaseOffset(QualType(ToMP->getClass(), 0),
215                                                QualType(FromMP->getClass(), 0));
216 
217     if (!this->visit(SubExpr))
218       return false;
219 
220     return this->emitGetMemberPtrBasePop(DerivedOffset, CE);
221   }
222 
223   case CK_BaseToDerivedMemberPointer: {
224     assert(classifyPrim(CE) == PT_MemberPtr);
225     assert(classifyPrim(SubExpr) == PT_MemberPtr);
226     const auto *FromMP = SubExpr->getType()->getAs<MemberPointerType>();
227     const auto *ToMP = CE->getType()->getAs<MemberPointerType>();
228 
229     unsigned DerivedOffset = collectBaseOffset(QualType(FromMP->getClass(), 0),
230                                                QualType(ToMP->getClass(), 0));
231 
232     if (!this->visit(SubExpr))
233       return false;
234     return this->emitGetMemberPtrBasePop(-DerivedOffset, CE);
235   }
236 
237   case CK_UncheckedDerivedToBase:
238   case CK_DerivedToBase: {
239     if (!this->visit(SubExpr))
240       return false;
241 
242     const auto extractRecordDecl = [](QualType Ty) -> const CXXRecordDecl * {
243       if (const auto *PT = dyn_cast<PointerType>(Ty))
244         return PT->getPointeeType()->getAsCXXRecordDecl();
245       return Ty->getAsCXXRecordDecl();
246     };
247 
248     // FIXME: We can express a series of non-virtual casts as a single
249     // GetPtrBasePop op.
250     QualType CurType = SubExpr->getType();
251     for (const CXXBaseSpecifier *B : CE->path()) {
252       if (B->isVirtual()) {
253         if (!this->emitGetPtrVirtBasePop(extractRecordDecl(B->getType()), CE))
254           return false;
255         CurType = B->getType();
256       } else {
257         unsigned DerivedOffset = collectBaseOffset(B->getType(), CurType);
258         if (!this->emitGetPtrBasePop(DerivedOffset, CE))
259           return false;
260         CurType = B->getType();
261       }
262     }
263 
264     return true;
265   }
266 
267   case CK_BaseToDerived: {
268     if (!this->visit(SubExpr))
269       return false;
270 
271     unsigned DerivedOffset =
272         collectBaseOffset(SubExpr->getType(), CE->getType());
273 
274     return this->emitGetPtrDerivedPop(DerivedOffset, CE);
275   }
276 
277   case CK_FloatingCast: {
278     // HLSL uses CK_FloatingCast to cast between vectors.
279     if (!SubExpr->getType()->isFloatingType() ||
280         !CE->getType()->isFloatingType())
281       return false;
282     if (DiscardResult)
283       return this->discard(SubExpr);
284     if (!this->visit(SubExpr))
285       return false;
286     const auto *TargetSemantics = &Ctx.getFloatSemantics(CE->getType());
287     return this->emitCastFP(TargetSemantics, getRoundingMode(CE), CE);
288   }
289 
290   case CK_IntegralToFloating: {
291     if (DiscardResult)
292       return this->discard(SubExpr);
293     std::optional<PrimType> FromT = classify(SubExpr->getType());
294     if (!FromT)
295       return false;
296 
297     if (!this->visit(SubExpr))
298       return false;
299 
300     const auto *TargetSemantics = &Ctx.getFloatSemantics(CE->getType());
301     llvm::RoundingMode RM = getRoundingMode(CE);
302     return this->emitCastIntegralFloating(*FromT, TargetSemantics, RM, CE);
303   }
304 
305   case CK_FloatingToBoolean:
306   case CK_FloatingToIntegral: {
307     if (DiscardResult)
308       return this->discard(SubExpr);
309 
310     std::optional<PrimType> ToT = classify(CE->getType());
311 
312     if (!ToT)
313       return false;
314 
315     if (!this->visit(SubExpr))
316       return false;
317 
318     if (ToT == PT_IntAP)
319       return this->emitCastFloatingIntegralAP(Ctx.getBitWidth(CE->getType()),
320                                               CE);
321     if (ToT == PT_IntAPS)
322       return this->emitCastFloatingIntegralAPS(Ctx.getBitWidth(CE->getType()),
323                                                CE);
324 
325     return this->emitCastFloatingIntegral(*ToT, CE);
326   }
327 
328   case CK_NullToPointer:
329   case CK_NullToMemberPointer: {
330     if (DiscardResult)
331       return true;
332 
333     const Descriptor *Desc = nullptr;
334     const QualType PointeeType = CE->getType()->getPointeeType();
335     if (!PointeeType.isNull()) {
336       if (std::optional<PrimType> T = classify(PointeeType))
337         Desc = P.createDescriptor(SubExpr, *T);
338     }
339     return this->emitNull(classifyPrim(CE->getType()), Desc, CE);
340   }
341 
342   case CK_PointerToIntegral: {
343     if (DiscardResult)
344       return this->discard(SubExpr);
345 
346     if (!this->visit(SubExpr))
347       return false;
348 
349     // If SubExpr doesn't result in a pointer, make it one.
350     if (PrimType FromT = classifyPrim(SubExpr->getType()); FromT != PT_Ptr) {
351       assert(isPtrType(FromT));
352       if (!this->emitDecayPtr(FromT, PT_Ptr, CE))
353         return false;
354     }
355 
356     PrimType T = classifyPrim(CE->getType());
357     if (T == PT_IntAP)
358       return this->emitCastPointerIntegralAP(Ctx.getBitWidth(CE->getType()),
359                                              CE);
360     if (T == PT_IntAPS)
361       return this->emitCastPointerIntegralAPS(Ctx.getBitWidth(CE->getType()),
362                                               CE);
363     return this->emitCastPointerIntegral(T, CE);
364   }
365 
366   case CK_ArrayToPointerDecay: {
367     if (!this->visit(SubExpr))
368       return false;
369     if (!this->emitArrayDecay(CE))
370       return false;
371     if (DiscardResult)
372       return this->emitPopPtr(CE);
373     return true;
374   }
375 
376   case CK_IntegralToPointer: {
377     QualType IntType = SubExpr->getType();
378     assert(IntType->isIntegralOrEnumerationType());
379     if (!this->visit(SubExpr))
380       return false;
381     // FIXME: I think the discard is wrong since the int->ptr cast might cause a
382     // diagnostic.
383     PrimType T = classifyPrim(IntType);
384     if (DiscardResult)
385       return this->emitPop(T, CE);
386 
387     QualType PtrType = CE->getType();
388     assert(PtrType->isPointerType());
389 
390     const Descriptor *Desc;
391     if (std::optional<PrimType> T = classify(PtrType->getPointeeType()))
392       Desc = P.createDescriptor(SubExpr, *T);
393     else if (PtrType->getPointeeType()->isVoidType())
394       Desc = nullptr;
395     else
396       Desc = P.createDescriptor(CE, PtrType->getPointeeType().getTypePtr(),
397                                 Descriptor::InlineDescMD, true, false,
398                                 /*IsMutable=*/false, nullptr);
399 
400     if (!this->emitGetIntPtr(T, Desc, CE))
401       return false;
402 
403     PrimType DestPtrT = classifyPrim(PtrType);
404     if (DestPtrT == PT_Ptr)
405       return true;
406 
407     // In case we're converting the integer to a non-Pointer.
408     return this->emitDecayPtr(PT_Ptr, DestPtrT, CE);
409   }
410 
411   case CK_AtomicToNonAtomic:
412   case CK_ConstructorConversion:
413   case CK_FunctionToPointerDecay:
414   case CK_NonAtomicToAtomic:
415   case CK_NoOp:
416   case CK_UserDefinedConversion:
417   case CK_AddressSpaceConversion:
418     return this->delegate(SubExpr);
419 
420   case CK_BitCast: {
421     // Reject bitcasts to atomic types.
422     if (CE->getType()->isAtomicType()) {
423       if (!this->discard(SubExpr))
424         return false;
425       return this->emitInvalidCast(CastKind::Reinterpret, CE);
426     }
427 
428     if (DiscardResult)
429       return this->discard(SubExpr);
430 
431     QualType SubExprTy = SubExpr->getType();
432     std::optional<PrimType> FromT = classify(SubExprTy);
433     std::optional<PrimType> ToT = classify(CE->getType());
434     if (!FromT || !ToT)
435       return false;
436 
437     assert(isPtrType(*FromT));
438     assert(isPtrType(*ToT));
439     if (FromT == ToT) {
440       if (CE->getType()->isVoidPointerType())
441         return this->delegate(SubExpr);
442 
443       if (!this->visit(SubExpr))
444         return false;
445       if (FromT == PT_Ptr)
446         return this->emitPtrPtrCast(SubExprTy->isVoidPointerType(), CE);
447       return true;
448     }
449 
450     if (!this->visit(SubExpr))
451       return false;
452     return this->emitDecayPtr(*FromT, *ToT, CE);
453   }
454 
455   case CK_IntegralToBoolean:
456   case CK_BooleanToSignedIntegral:
457   case CK_IntegralCast: {
458     if (DiscardResult)
459       return this->discard(SubExpr);
460     std::optional<PrimType> FromT = classify(SubExpr->getType());
461     std::optional<PrimType> ToT = classify(CE->getType());
462 
463     if (!FromT || !ToT)
464       return false;
465 
466     if (!this->visit(SubExpr))
467       return false;
468 
469     // Possibly diagnose casts to enum types if the target type does not
470     // have a fixed size.
471     if (Ctx.getLangOpts().CPlusPlus && CE->getType()->isEnumeralType()) {
472       if (const auto *ET = CE->getType().getCanonicalType()->getAs<EnumType>();
473           ET && !ET->getDecl()->isFixed()) {
474         if (!this->emitCheckEnumValue(*FromT, ET->getDecl(), CE))
475           return false;
476       }
477     }
478 
479     if (ToT == PT_IntAP)
480       return this->emitCastAP(*FromT, Ctx.getBitWidth(CE->getType()), CE);
481     if (ToT == PT_IntAPS)
482       return this->emitCastAPS(*FromT, Ctx.getBitWidth(CE->getType()), CE);
483 
484     if (FromT == ToT)
485       return true;
486     if (!this->emitCast(*FromT, *ToT, CE))
487       return false;
488 
489     if (CE->getCastKind() == CK_BooleanToSignedIntegral)
490       return this->emitNeg(*ToT, CE);
491     return true;
492   }
493 
494   case CK_PointerToBoolean:
495   case CK_MemberPointerToBoolean: {
496     PrimType PtrT = classifyPrim(SubExpr->getType());
497 
498     // Just emit p != nullptr for this.
499     if (!this->visit(SubExpr))
500       return false;
501 
502     if (!this->emitNull(PtrT, nullptr, CE))
503       return false;
504 
505     return this->emitNE(PtrT, CE);
506   }
507 
508   case CK_IntegralComplexToBoolean:
509   case CK_FloatingComplexToBoolean: {
510     if (DiscardResult)
511       return this->discard(SubExpr);
512     if (!this->visit(SubExpr))
513       return false;
514     return this->emitComplexBoolCast(SubExpr);
515   }
516 
517   case CK_IntegralComplexToReal:
518   case CK_FloatingComplexToReal:
519     return this->emitComplexReal(SubExpr);
520 
521   case CK_IntegralRealToComplex:
522   case CK_FloatingRealToComplex: {
523     // We're creating a complex value here, so we need to
524     // allocate storage for it.
525     if (!Initializing) {
526       std::optional<unsigned> LocalIndex = allocateLocal(CE);
527       if (!LocalIndex)
528         return false;
529       if (!this->emitGetPtrLocal(*LocalIndex, CE))
530         return false;
531     }
532 
533     // Init the complex value to {SubExpr, 0}.
534     if (!this->visitArrayElemInit(0, SubExpr))
535       return false;
536     // Zero-init the second element.
537     PrimType T = classifyPrim(SubExpr->getType());
538     if (!this->visitZeroInitializer(T, SubExpr->getType(), SubExpr))
539       return false;
540     return this->emitInitElem(T, 1, SubExpr);
541   }
542 
543   case CK_IntegralComplexCast:
544   case CK_FloatingComplexCast:
545   case CK_IntegralComplexToFloatingComplex:
546   case CK_FloatingComplexToIntegralComplex: {
547     assert(CE->getType()->isAnyComplexType());
548     assert(SubExpr->getType()->isAnyComplexType());
549     if (DiscardResult)
550       return this->discard(SubExpr);
551 
552     if (!Initializing) {
553       std::optional<unsigned> LocalIndex = allocateLocal(CE);
554       if (!LocalIndex)
555         return false;
556       if (!this->emitGetPtrLocal(*LocalIndex, CE))
557         return false;
558     }
559 
560     // Location for the SubExpr.
561     // Since SubExpr is of complex type, visiting it results in a pointer
562     // anyway, so we just create a temporary pointer variable.
563     unsigned SubExprOffset = allocateLocalPrimitive(
564         SubExpr, PT_Ptr, /*IsConst=*/true, /*IsExtended=*/false);
565     if (!this->visit(SubExpr))
566       return false;
567     if (!this->emitSetLocal(PT_Ptr, SubExprOffset, CE))
568       return false;
569 
570     PrimType SourceElemT = classifyComplexElementType(SubExpr->getType());
571     QualType DestElemType =
572         CE->getType()->getAs<ComplexType>()->getElementType();
573     PrimType DestElemT = classifyPrim(DestElemType);
574     // Cast both elements individually.
575     for (unsigned I = 0; I != 2; ++I) {
576       if (!this->emitGetLocal(PT_Ptr, SubExprOffset, CE))
577         return false;
578       if (!this->emitArrayElemPop(SourceElemT, I, CE))
579         return false;
580 
581       // Do the cast.
582       if (!this->emitPrimCast(SourceElemT, DestElemT, DestElemType, CE))
583         return false;
584 
585       // Save the value.
586       if (!this->emitInitElem(DestElemT, I, CE))
587         return false;
588     }
589     return true;
590   }
591 
592   case CK_VectorSplat: {
593     assert(!classify(CE->getType()));
594     assert(classify(SubExpr->getType()));
595     assert(CE->getType()->isVectorType());
596 
597     if (DiscardResult)
598       return this->discard(SubExpr);
599 
600     if (!Initializing) {
601       std::optional<unsigned> LocalIndex = allocateLocal(CE);
602       if (!LocalIndex)
603         return false;
604       if (!this->emitGetPtrLocal(*LocalIndex, CE))
605         return false;
606     }
607 
608     const auto *VT = CE->getType()->getAs<VectorType>();
609     PrimType ElemT = classifyPrim(SubExpr->getType());
610     unsigned ElemOffset = allocateLocalPrimitive(
611         SubExpr, ElemT, /*IsConst=*/true, /*IsExtended=*/false);
612 
613     // Prepare a local variable for the scalar value.
614     if (!this->visit(SubExpr))
615       return false;
616     if (classifyPrim(SubExpr) == PT_Ptr && !this->emitLoadPop(ElemT, CE))
617       return false;
618 
619     if (!this->emitSetLocal(ElemT, ElemOffset, CE))
620       return false;
621 
622     for (unsigned I = 0; I != VT->getNumElements(); ++I) {
623       if (!this->emitGetLocal(ElemT, ElemOffset, CE))
624         return false;
625       if (!this->emitInitElem(ElemT, I, CE))
626         return false;
627     }
628 
629     return true;
630   }
631 
632   case CK_ToVoid:
633     return discard(SubExpr);
634 
635   default:
636     return this->emitInvalid(CE);
637   }
638   llvm_unreachable("Unhandled clang::CastKind enum");
639 }
640 
641 template <class Emitter>
642 bool Compiler<Emitter>::VisitIntegerLiteral(const IntegerLiteral *LE) {
643   if (DiscardResult)
644     return true;
645 
646   return this->emitConst(LE->getValue(), LE);
647 }
648 
649 template <class Emitter>
650 bool Compiler<Emitter>::VisitFloatingLiteral(const FloatingLiteral *E) {
651   if (DiscardResult)
652     return true;
653 
654   return this->emitConstFloat(E->getValue(), E);
655 }
656 
657 template <class Emitter>
658 bool Compiler<Emitter>::VisitImaginaryLiteral(const ImaginaryLiteral *E) {
659   assert(E->getType()->isAnyComplexType());
660   if (DiscardResult)
661     return true;
662 
663   if (!Initializing) {
664     std::optional<unsigned> LocalIndex = allocateLocal(E);
665     if (!LocalIndex)
666       return false;
667     if (!this->emitGetPtrLocal(*LocalIndex, E))
668       return false;
669   }
670 
671   const Expr *SubExpr = E->getSubExpr();
672   PrimType SubExprT = classifyPrim(SubExpr->getType());
673 
674   if (!this->visitZeroInitializer(SubExprT, SubExpr->getType(), SubExpr))
675     return false;
676   if (!this->emitInitElem(SubExprT, 0, SubExpr))
677     return false;
678   return this->visitArrayElemInit(1, SubExpr);
679 }
680 
681 template <class Emitter>
682 bool Compiler<Emitter>::VisitParenExpr(const ParenExpr *E) {
683   return this->delegate(E->getSubExpr());
684 }
685 
686 template <class Emitter>
687 bool Compiler<Emitter>::VisitBinaryOperator(const BinaryOperator *BO) {
688   // Need short-circuiting for these.
689   if (BO->isLogicalOp())
690     return this->VisitLogicalBinOp(BO);
691 
692   const Expr *LHS = BO->getLHS();
693   const Expr *RHS = BO->getRHS();
694 
695   // Handle comma operators. Just discard the LHS
696   // and delegate to RHS.
697   if (BO->isCommaOp()) {
698     if (!this->discard(LHS))
699       return false;
700     if (RHS->getType()->isVoidType())
701       return this->discard(RHS);
702 
703     return this->delegate(RHS);
704   }
705 
706   if (BO->getType()->isAnyComplexType())
707     return this->VisitComplexBinOp(BO);
708   if ((LHS->getType()->isAnyComplexType() ||
709        RHS->getType()->isAnyComplexType()) &&
710       BO->isComparisonOp())
711     return this->emitComplexComparison(LHS, RHS, BO);
712 
713   if (BO->isPtrMemOp()) {
714     if (!this->visit(LHS))
715       return false;
716 
717     if (!this->visit(RHS))
718       return false;
719 
720     if (!this->emitToMemberPtr(BO))
721       return false;
722 
723     if (classifyPrim(BO) == PT_MemberPtr)
724       return true;
725 
726     if (!this->emitCastMemberPtrPtr(BO))
727       return false;
728     return DiscardResult ? this->emitPopPtr(BO) : true;
729   }
730 
731   // Typecheck the args.
732   std::optional<PrimType> LT = classify(LHS->getType());
733   std::optional<PrimType> RT = classify(RHS->getType());
734   std::optional<PrimType> T = classify(BO->getType());
735 
736   // Special case for C++'s three-way/spaceship operator <=>, which
737   // returns a std::{strong,weak,partial}_ordering (which is a class, so doesn't
738   // have a PrimType).
739   if (!T && BO->getOpcode() == BO_Cmp) {
740     if (DiscardResult)
741       return true;
742     const ComparisonCategoryInfo *CmpInfo =
743         Ctx.getASTContext().CompCategories.lookupInfoForType(BO->getType());
744     assert(CmpInfo);
745 
746     // We need a temporary variable holding our return value.
747     if (!Initializing) {
748       std::optional<unsigned> ResultIndex = this->allocateLocal(BO);
749       if (!this->emitGetPtrLocal(*ResultIndex, BO))
750         return false;
751     }
752 
753     if (!visit(LHS) || !visit(RHS))
754       return false;
755 
756     return this->emitCMP3(*LT, CmpInfo, BO);
757   }
758 
759   if (!LT || !RT || !T)
760     return false;
761 
762   // Pointer arithmetic special case.
763   if (BO->getOpcode() == BO_Add || BO->getOpcode() == BO_Sub) {
764     if (isPtrType(*T) || (isPtrType(*LT) && isPtrType(*RT)))
765       return this->VisitPointerArithBinOp(BO);
766   }
767 
768   if (!visit(LHS) || !visit(RHS))
769     return false;
770 
771   // For languages such as C, cast the result of one
772   // of our comparision opcodes to T (which is usually int).
773   auto MaybeCastToBool = [this, T, BO](bool Result) {
774     if (!Result)
775       return false;
776     if (DiscardResult)
777       return this->emitPop(*T, BO);
778     if (T != PT_Bool)
779       return this->emitCast(PT_Bool, *T, BO);
780     return true;
781   };
782 
783   auto Discard = [this, T, BO](bool Result) {
784     if (!Result)
785       return false;
786     return DiscardResult ? this->emitPop(*T, BO) : true;
787   };
788 
789   switch (BO->getOpcode()) {
790   case BO_EQ:
791     return MaybeCastToBool(this->emitEQ(*LT, BO));
792   case BO_NE:
793     return MaybeCastToBool(this->emitNE(*LT, BO));
794   case BO_LT:
795     return MaybeCastToBool(this->emitLT(*LT, BO));
796   case BO_LE:
797     return MaybeCastToBool(this->emitLE(*LT, BO));
798   case BO_GT:
799     return MaybeCastToBool(this->emitGT(*LT, BO));
800   case BO_GE:
801     return MaybeCastToBool(this->emitGE(*LT, BO));
802   case BO_Sub:
803     if (BO->getType()->isFloatingType())
804       return Discard(this->emitSubf(getRoundingMode(BO), BO));
805     return Discard(this->emitSub(*T, BO));
806   case BO_Add:
807     if (BO->getType()->isFloatingType())
808       return Discard(this->emitAddf(getRoundingMode(BO), BO));
809     return Discard(this->emitAdd(*T, BO));
810   case BO_Mul:
811     if (BO->getType()->isFloatingType())
812       return Discard(this->emitMulf(getRoundingMode(BO), BO));
813     return Discard(this->emitMul(*T, BO));
814   case BO_Rem:
815     return Discard(this->emitRem(*T, BO));
816   case BO_Div:
817     if (BO->getType()->isFloatingType())
818       return Discard(this->emitDivf(getRoundingMode(BO), BO));
819     return Discard(this->emitDiv(*T, BO));
820   case BO_Assign:
821     if (DiscardResult)
822       return LHS->refersToBitField() ? this->emitStoreBitFieldPop(*T, BO)
823                                      : this->emitStorePop(*T, BO);
824     if (LHS->refersToBitField()) {
825       if (!this->emitStoreBitField(*T, BO))
826         return false;
827     } else {
828       if (!this->emitStore(*T, BO))
829         return false;
830     }
831     // Assignments aren't necessarily lvalues in C.
832     // Load from them in that case.
833     if (!BO->isLValue())
834       return this->emitLoadPop(*T, BO);
835     return true;
836   case BO_And:
837     return Discard(this->emitBitAnd(*T, BO));
838   case BO_Or:
839     return Discard(this->emitBitOr(*T, BO));
840   case BO_Shl:
841     return Discard(this->emitShl(*LT, *RT, BO));
842   case BO_Shr:
843     return Discard(this->emitShr(*LT, *RT, BO));
844   case BO_Xor:
845     return Discard(this->emitBitXor(*T, BO));
846   case BO_LOr:
847   case BO_LAnd:
848     llvm_unreachable("Already handled earlier");
849   default:
850     return false;
851   }
852 
853   llvm_unreachable("Unhandled binary op");
854 }
855 
856 /// Perform addition/subtraction of a pointer and an integer or
857 /// subtraction of two pointers.
858 template <class Emitter>
859 bool Compiler<Emitter>::VisitPointerArithBinOp(const BinaryOperator *E) {
860   BinaryOperatorKind Op = E->getOpcode();
861   const Expr *LHS = E->getLHS();
862   const Expr *RHS = E->getRHS();
863 
864   if ((Op != BO_Add && Op != BO_Sub) ||
865       (!LHS->getType()->isPointerType() && !RHS->getType()->isPointerType()))
866     return false;
867 
868   std::optional<PrimType> LT = classify(LHS);
869   std::optional<PrimType> RT = classify(RHS);
870 
871   if (!LT || !RT)
872     return false;
873 
874   if (LHS->getType()->isPointerType() && RHS->getType()->isPointerType()) {
875     if (Op != BO_Sub)
876       return false;
877 
878     assert(E->getType()->isIntegerType());
879     if (!visit(RHS) || !visit(LHS))
880       return false;
881 
882     return this->emitSubPtr(classifyPrim(E->getType()), E);
883   }
884 
885   PrimType OffsetType;
886   if (LHS->getType()->isIntegerType()) {
887     if (!visit(RHS) || !visit(LHS))
888       return false;
889     OffsetType = *LT;
890   } else if (RHS->getType()->isIntegerType()) {
891     if (!visit(LHS) || !visit(RHS))
892       return false;
893     OffsetType = *RT;
894   } else {
895     return false;
896   }
897 
898   if (Op == BO_Add)
899     return this->emitAddOffset(OffsetType, E);
900   else if (Op == BO_Sub)
901     return this->emitSubOffset(OffsetType, E);
902 
903   return false;
904 }
905 
906 template <class Emitter>
907 bool Compiler<Emitter>::VisitLogicalBinOp(const BinaryOperator *E) {
908   assert(E->isLogicalOp());
909   BinaryOperatorKind Op = E->getOpcode();
910   const Expr *LHS = E->getLHS();
911   const Expr *RHS = E->getRHS();
912   std::optional<PrimType> T = classify(E->getType());
913 
914   if (Op == BO_LOr) {
915     // Logical OR. Visit LHS and only evaluate RHS if LHS was FALSE.
916     LabelTy LabelTrue = this->getLabel();
917     LabelTy LabelEnd = this->getLabel();
918 
919     if (!this->visitBool(LHS))
920       return false;
921     if (!this->jumpTrue(LabelTrue))
922       return false;
923 
924     if (!this->visitBool(RHS))
925       return false;
926     if (!this->jump(LabelEnd))
927       return false;
928 
929     this->emitLabel(LabelTrue);
930     this->emitConstBool(true, E);
931     this->fallthrough(LabelEnd);
932     this->emitLabel(LabelEnd);
933 
934   } else {
935     assert(Op == BO_LAnd);
936     // Logical AND.
937     // Visit LHS. Only visit RHS if LHS was TRUE.
938     LabelTy LabelFalse = this->getLabel();
939     LabelTy LabelEnd = this->getLabel();
940 
941     if (!this->visitBool(LHS))
942       return false;
943     if (!this->jumpFalse(LabelFalse))
944       return false;
945 
946     if (!this->visitBool(RHS))
947       return false;
948     if (!this->jump(LabelEnd))
949       return false;
950 
951     this->emitLabel(LabelFalse);
952     this->emitConstBool(false, E);
953     this->fallthrough(LabelEnd);
954     this->emitLabel(LabelEnd);
955   }
956 
957   if (DiscardResult)
958     return this->emitPopBool(E);
959 
960   // For C, cast back to integer type.
961   assert(T);
962   if (T != PT_Bool)
963     return this->emitCast(PT_Bool, *T, E);
964   return true;
965 }
966 
967 template <class Emitter>
968 bool Compiler<Emitter>::VisitComplexBinOp(const BinaryOperator *E) {
969   // Prepare storage for result.
970   if (!Initializing) {
971     std::optional<unsigned> LocalIndex = allocateLocal(E);
972     if (!LocalIndex)
973       return false;
974     if (!this->emitGetPtrLocal(*LocalIndex, E))
975       return false;
976   }
977 
978   // Both LHS and RHS might _not_ be of complex type, but one of them
979   // needs to be.
980   const Expr *LHS = E->getLHS();
981   const Expr *RHS = E->getRHS();
982 
983   PrimType ResultElemT = this->classifyComplexElementType(E->getType());
984   unsigned ResultOffset = ~0u;
985   if (!DiscardResult)
986     ResultOffset = this->allocateLocalPrimitive(E, PT_Ptr, true, false);
987 
988   // Save result pointer in ResultOffset
989   if (!this->DiscardResult) {
990     if (!this->emitDupPtr(E))
991       return false;
992     if (!this->emitSetLocal(PT_Ptr, ResultOffset, E))
993       return false;
994   }
995   QualType LHSType = LHS->getType();
996   if (const auto *AT = LHSType->getAs<AtomicType>())
997     LHSType = AT->getValueType();
998   QualType RHSType = RHS->getType();
999   if (const auto *AT = RHSType->getAs<AtomicType>())
1000     RHSType = AT->getValueType();
1001 
1002   bool LHSIsComplex = LHSType->isAnyComplexType();
1003   unsigned LHSOffset;
1004   bool RHSIsComplex = RHSType->isAnyComplexType();
1005 
1006   // For ComplexComplex Mul, we have special ops to make their implementation
1007   // easier.
1008   BinaryOperatorKind Op = E->getOpcode();
1009   if (Op == BO_Mul && LHSIsComplex && RHSIsComplex) {
1010     assert(classifyPrim(LHSType->getAs<ComplexType>()->getElementType()) ==
1011            classifyPrim(RHSType->getAs<ComplexType>()->getElementType()));
1012     PrimType ElemT =
1013         classifyPrim(LHSType->getAs<ComplexType>()->getElementType());
1014     if (!this->visit(LHS))
1015       return false;
1016     if (!this->visit(RHS))
1017       return false;
1018     return this->emitMulc(ElemT, E);
1019   }
1020 
1021   if (Op == BO_Div && RHSIsComplex) {
1022     QualType ElemQT = RHSType->getAs<ComplexType>()->getElementType();
1023     PrimType ElemT = classifyPrim(ElemQT);
1024     // If the LHS is not complex, we still need to do the full complex
1025     // division, so just stub create a complex value and stub it out with
1026     // the LHS and a zero.
1027 
1028     if (!LHSIsComplex) {
1029       // This is using the RHS type for the fake-complex LHS.
1030       if (auto LHSO = allocateLocal(RHS))
1031         LHSOffset = *LHSO;
1032       else
1033         return false;
1034 
1035       if (!this->emitGetPtrLocal(LHSOffset, E))
1036         return false;
1037 
1038       if (!this->visit(LHS))
1039         return false;
1040       // real is LHS
1041       if (!this->emitInitElem(ElemT, 0, E))
1042         return false;
1043       // imag is zero
1044       if (!this->visitZeroInitializer(ElemT, ElemQT, E))
1045         return false;
1046       if (!this->emitInitElem(ElemT, 1, E))
1047         return false;
1048     } else {
1049       if (!this->visit(LHS))
1050         return false;
1051     }
1052 
1053     if (!this->visit(RHS))
1054       return false;
1055     return this->emitDivc(ElemT, E);
1056   }
1057 
1058   // Evaluate LHS and save value to LHSOffset.
1059   if (LHSType->isAnyComplexType()) {
1060     LHSOffset = this->allocateLocalPrimitive(LHS, PT_Ptr, true, false);
1061     if (!this->visit(LHS))
1062       return false;
1063     if (!this->emitSetLocal(PT_Ptr, LHSOffset, E))
1064       return false;
1065   } else {
1066     PrimType LHST = classifyPrim(LHSType);
1067     LHSOffset = this->allocateLocalPrimitive(LHS, LHST, true, false);
1068     if (!this->visit(LHS))
1069       return false;
1070     if (!this->emitSetLocal(LHST, LHSOffset, E))
1071       return false;
1072   }
1073 
1074   // Same with RHS.
1075   unsigned RHSOffset;
1076   if (RHSType->isAnyComplexType()) {
1077     RHSOffset = this->allocateLocalPrimitive(RHS, PT_Ptr, true, false);
1078     if (!this->visit(RHS))
1079       return false;
1080     if (!this->emitSetLocal(PT_Ptr, RHSOffset, E))
1081       return false;
1082   } else {
1083     PrimType RHST = classifyPrim(RHSType);
1084     RHSOffset = this->allocateLocalPrimitive(RHS, RHST, true, false);
1085     if (!this->visit(RHS))
1086       return false;
1087     if (!this->emitSetLocal(RHST, RHSOffset, E))
1088       return false;
1089   }
1090 
1091   // For both LHS and RHS, either load the value from the complex pointer, or
1092   // directly from the local variable. For index 1 (i.e. the imaginary part),
1093   // just load 0 and do the operation anyway.
1094   auto loadComplexValue = [this](bool IsComplex, bool LoadZero,
1095                                  unsigned ElemIndex, unsigned Offset,
1096                                  const Expr *E) -> bool {
1097     if (IsComplex) {
1098       if (!this->emitGetLocal(PT_Ptr, Offset, E))
1099         return false;
1100       return this->emitArrayElemPop(classifyComplexElementType(E->getType()),
1101                                     ElemIndex, E);
1102     }
1103     if (ElemIndex == 0 || !LoadZero)
1104       return this->emitGetLocal(classifyPrim(E->getType()), Offset, E);
1105     return this->visitZeroInitializer(classifyPrim(E->getType()), E->getType(),
1106                                       E);
1107   };
1108 
1109   // Now we can get pointers to the LHS and RHS from the offsets above.
1110   for (unsigned ElemIndex = 0; ElemIndex != 2; ++ElemIndex) {
1111     // Result pointer for the store later.
1112     if (!this->DiscardResult) {
1113       if (!this->emitGetLocal(PT_Ptr, ResultOffset, E))
1114         return false;
1115     }
1116 
1117     // The actual operation.
1118     switch (Op) {
1119     case BO_Add:
1120       if (!loadComplexValue(LHSIsComplex, true, ElemIndex, LHSOffset, LHS))
1121         return false;
1122 
1123       if (!loadComplexValue(RHSIsComplex, true, ElemIndex, RHSOffset, RHS))
1124         return false;
1125       if (ResultElemT == PT_Float) {
1126         if (!this->emitAddf(getRoundingMode(E), E))
1127           return false;
1128       } else {
1129         if (!this->emitAdd(ResultElemT, E))
1130           return false;
1131       }
1132       break;
1133     case BO_Sub:
1134       if (!loadComplexValue(LHSIsComplex, true, ElemIndex, LHSOffset, LHS))
1135         return false;
1136 
1137       if (!loadComplexValue(RHSIsComplex, true, ElemIndex, RHSOffset, RHS))
1138         return false;
1139       if (ResultElemT == PT_Float) {
1140         if (!this->emitSubf(getRoundingMode(E), E))
1141           return false;
1142       } else {
1143         if (!this->emitSub(ResultElemT, E))
1144           return false;
1145       }
1146       break;
1147     case BO_Mul:
1148       if (!loadComplexValue(LHSIsComplex, false, ElemIndex, LHSOffset, LHS))
1149         return false;
1150 
1151       if (!loadComplexValue(RHSIsComplex, false, ElemIndex, RHSOffset, RHS))
1152         return false;
1153 
1154       if (ResultElemT == PT_Float) {
1155         if (!this->emitMulf(getRoundingMode(E), E))
1156           return false;
1157       } else {
1158         if (!this->emitMul(ResultElemT, E))
1159           return false;
1160       }
1161       break;
1162     case BO_Div:
1163       assert(!RHSIsComplex);
1164       if (!loadComplexValue(LHSIsComplex, false, ElemIndex, LHSOffset, LHS))
1165         return false;
1166 
1167       if (!loadComplexValue(RHSIsComplex, false, ElemIndex, RHSOffset, RHS))
1168         return false;
1169 
1170       if (ResultElemT == PT_Float) {
1171         if (!this->emitDivf(getRoundingMode(E), E))
1172           return false;
1173       } else {
1174         if (!this->emitDiv(ResultElemT, E))
1175           return false;
1176       }
1177       break;
1178 
1179     default:
1180       return false;
1181     }
1182 
1183     if (!this->DiscardResult) {
1184       // Initialize array element with the value we just computed.
1185       if (!this->emitInitElemPop(ResultElemT, ElemIndex, E))
1186         return false;
1187     } else {
1188       if (!this->emitPop(ResultElemT, E))
1189         return false;
1190     }
1191   }
1192   return true;
1193 }
1194 
1195 template <class Emitter>
1196 bool Compiler<Emitter>::VisitImplicitValueInitExpr(
1197     const ImplicitValueInitExpr *E) {
1198   QualType QT = E->getType();
1199 
1200   if (std::optional<PrimType> T = classify(QT))
1201     return this->visitZeroInitializer(*T, QT, E);
1202 
1203   if (QT->isRecordType()) {
1204     const RecordDecl *RD = QT->getAsRecordDecl();
1205     assert(RD);
1206     if (RD->isInvalidDecl())
1207       return false;
1208     if (RD->isUnion()) {
1209       // C++11 [dcl.init]p5: If T is a (possibly cv-qualified) union type, the
1210       // object's first non-static named data member is zero-initialized
1211       // FIXME
1212       return false;
1213     }
1214 
1215     if (const auto *CXXRD = dyn_cast<CXXRecordDecl>(RD);
1216         CXXRD && CXXRD->getNumVBases() > 0) {
1217       // TODO: Diagnose.
1218       return false;
1219     }
1220 
1221     const Record *R = getRecord(QT);
1222     if (!R)
1223       return false;
1224 
1225     assert(Initializing);
1226     return this->visitZeroRecordInitializer(R, E);
1227   }
1228 
1229   if (QT->isIncompleteArrayType())
1230     return true;
1231 
1232   if (QT->isArrayType()) {
1233     const ArrayType *AT = QT->getAsArrayTypeUnsafe();
1234     assert(AT);
1235     const auto *CAT = cast<ConstantArrayType>(AT);
1236     size_t NumElems = CAT->getZExtSize();
1237     PrimType ElemT = classifyPrim(CAT->getElementType());
1238 
1239     for (size_t I = 0; I != NumElems; ++I) {
1240       if (!this->visitZeroInitializer(ElemT, CAT->getElementType(), E))
1241         return false;
1242       if (!this->emitInitElem(ElemT, I, E))
1243         return false;
1244     }
1245 
1246     return true;
1247   }
1248 
1249   if (const auto *ComplexTy = E->getType()->getAs<ComplexType>()) {
1250     assert(Initializing);
1251     QualType ElemQT = ComplexTy->getElementType();
1252     PrimType ElemT = classifyPrim(ElemQT);
1253     for (unsigned I = 0; I < 2; ++I) {
1254       if (!this->visitZeroInitializer(ElemT, ElemQT, E))
1255         return false;
1256       if (!this->emitInitElem(ElemT, I, E))
1257         return false;
1258     }
1259     return true;
1260   }
1261 
1262   if (const auto *VecT = E->getType()->getAs<VectorType>()) {
1263     unsigned NumVecElements = VecT->getNumElements();
1264     QualType ElemQT = VecT->getElementType();
1265     PrimType ElemT = classifyPrim(ElemQT);
1266 
1267     for (unsigned I = 0; I < NumVecElements; ++I) {
1268       if (!this->visitZeroInitializer(ElemT, ElemQT, E))
1269         return false;
1270       if (!this->emitInitElem(ElemT, I, E))
1271         return false;
1272     }
1273     return true;
1274   }
1275 
1276   return false;
1277 }
1278 
1279 template <class Emitter>
1280 bool Compiler<Emitter>::VisitArraySubscriptExpr(const ArraySubscriptExpr *E) {
1281   const Expr *Base = E->getBase();
1282   const Expr *Index = E->getIdx();
1283 
1284   if (DiscardResult)
1285     return this->discard(Base) && this->discard(Index);
1286 
1287   // Take pointer of LHS, add offset from RHS.
1288   // What's left on the stack after this is a pointer.
1289   if (!this->visit(Base))
1290     return false;
1291 
1292   if (!this->visit(Index))
1293     return false;
1294 
1295   PrimType IndexT = classifyPrim(Index->getType());
1296   return this->emitArrayElemPtrPop(IndexT, E);
1297 }
1298 
1299 template <class Emitter>
1300 bool Compiler<Emitter>::visitInitList(ArrayRef<const Expr *> Inits,
1301                                       const Expr *ArrayFiller, const Expr *E) {
1302 
1303   QualType QT = E->getType();
1304 
1305   if (const auto *AT = QT->getAs<AtomicType>())
1306     QT = AT->getValueType();
1307 
1308   if (QT->isVoidType())
1309     return this->emitInvalid(E);
1310 
1311   // Handle discarding first.
1312   if (DiscardResult) {
1313     for (const Expr *Init : Inits) {
1314       if (!this->discard(Init))
1315         return false;
1316     }
1317     return true;
1318   }
1319 
1320   // Primitive values.
1321   if (std::optional<PrimType> T = classify(QT)) {
1322     assert(!DiscardResult);
1323     if (Inits.size() == 0)
1324       return this->visitZeroInitializer(*T, QT, E);
1325     assert(Inits.size() == 1);
1326     return this->delegate(Inits[0]);
1327   }
1328 
1329   if (QT->isRecordType()) {
1330     const Record *R = getRecord(QT);
1331 
1332     if (Inits.size() == 1 && E->getType() == Inits[0]->getType())
1333       return this->delegate(Inits[0]);
1334 
1335     auto initPrimitiveField = [=](const Record::Field *FieldToInit,
1336                                   const Expr *Init, PrimType T) -> bool {
1337       InitStackScope<Emitter> ISS(this, isa<CXXDefaultInitExpr>(Init));
1338       if (!this->visit(Init))
1339         return false;
1340 
1341       if (FieldToInit->isBitField())
1342         return this->emitInitBitField(T, FieldToInit, E);
1343       return this->emitInitField(T, FieldToInit->Offset, E);
1344     };
1345 
1346     auto initCompositeField = [=](const Record::Field *FieldToInit,
1347                                   const Expr *Init) -> bool {
1348       InitStackScope<Emitter> ISS(this, isa<CXXDefaultInitExpr>(Init));
1349       InitLinkScope<Emitter> ILS(this, InitLink::Field(FieldToInit->Offset));
1350       // Non-primitive case. Get a pointer to the field-to-initialize
1351       // on the stack and recurse into visitInitializer().
1352       if (!this->emitGetPtrField(FieldToInit->Offset, Init))
1353         return false;
1354       if (!this->visitInitializer(Init))
1355         return false;
1356       return this->emitPopPtr(E);
1357     };
1358 
1359     if (R->isUnion()) {
1360       if (Inits.size() == 0) {
1361         // Zero-initialize the first union field.
1362         if (R->getNumFields() == 0)
1363           return this->emitFinishInit(E);
1364         const Record::Field *FieldToInit = R->getField(0u);
1365         QualType FieldType = FieldToInit->Desc->getType();
1366         if (std::optional<PrimType> T = classify(FieldType)) {
1367           if (!this->visitZeroInitializer(*T, FieldType, E))
1368             return false;
1369           if (!this->emitInitField(*T, FieldToInit->Offset, E))
1370             return false;
1371         }
1372         // FIXME: Non-primitive case?
1373       } else {
1374         const Expr *Init = Inits[0];
1375         const FieldDecl *FToInit = nullptr;
1376         if (const auto *ILE = dyn_cast<InitListExpr>(E))
1377           FToInit = ILE->getInitializedFieldInUnion();
1378         else
1379           FToInit = cast<CXXParenListInitExpr>(E)->getInitializedFieldInUnion();
1380 
1381         const Record::Field *FieldToInit = R->getField(FToInit);
1382         if (std::optional<PrimType> T = classify(Init)) {
1383           if (!initPrimitiveField(FieldToInit, Init, *T))
1384             return false;
1385         } else {
1386           if (!initCompositeField(FieldToInit, Init))
1387             return false;
1388         }
1389       }
1390       return this->emitFinishInit(E);
1391     }
1392 
1393     assert(!R->isUnion());
1394     unsigned InitIndex = 0;
1395     for (const Expr *Init : Inits) {
1396       // Skip unnamed bitfields.
1397       while (InitIndex < R->getNumFields() &&
1398              R->getField(InitIndex)->Decl->isUnnamedBitField())
1399         ++InitIndex;
1400 
1401       if (std::optional<PrimType> T = classify(Init)) {
1402         const Record::Field *FieldToInit = R->getField(InitIndex);
1403         if (!initPrimitiveField(FieldToInit, Init, *T))
1404           return false;
1405         ++InitIndex;
1406       } else {
1407         // Initializer for a direct base class.
1408         if (const Record::Base *B = R->getBase(Init->getType())) {
1409           if (!this->emitGetPtrBase(B->Offset, Init))
1410             return false;
1411 
1412           if (!this->visitInitializer(Init))
1413             return false;
1414 
1415           if (!this->emitFinishInitPop(E))
1416             return false;
1417           // Base initializers don't increase InitIndex, since they don't count
1418           // into the Record's fields.
1419         } else {
1420           const Record::Field *FieldToInit = R->getField(InitIndex);
1421           if (!initCompositeField(FieldToInit, Init))
1422             return false;
1423           ++InitIndex;
1424         }
1425       }
1426     }
1427     return this->emitFinishInit(E);
1428   }
1429 
1430   if (QT->isArrayType()) {
1431     if (Inits.size() == 1 && QT == Inits[0]->getType())
1432       return this->delegate(Inits[0]);
1433 
1434     unsigned ElementIndex = 0;
1435     for (const Expr *Init : Inits) {
1436       if (const auto *EmbedS =
1437               dyn_cast<EmbedExpr>(Init->IgnoreParenImpCasts())) {
1438         PrimType TargetT = classifyPrim(Init->getType());
1439 
1440         auto Eval = [&](const Expr *Init, unsigned ElemIndex) {
1441           PrimType InitT = classifyPrim(Init->getType());
1442           if (!this->visit(Init))
1443             return false;
1444           if (InitT != TargetT) {
1445             if (!this->emitCast(InitT, TargetT, E))
1446               return false;
1447           }
1448           return this->emitInitElem(TargetT, ElemIndex, Init);
1449         };
1450         if (!EmbedS->doForEachDataElement(Eval, ElementIndex))
1451           return false;
1452       } else {
1453         if (!this->visitArrayElemInit(ElementIndex, Init))
1454           return false;
1455         ++ElementIndex;
1456       }
1457     }
1458 
1459     // Expand the filler expression.
1460     // FIXME: This should go away.
1461     if (ArrayFiller) {
1462       const ConstantArrayType *CAT =
1463           Ctx.getASTContext().getAsConstantArrayType(QT);
1464       uint64_t NumElems = CAT->getZExtSize();
1465 
1466       for (; ElementIndex != NumElems; ++ElementIndex) {
1467         if (!this->visitArrayElemInit(ElementIndex, ArrayFiller))
1468           return false;
1469       }
1470     }
1471 
1472     return this->emitFinishInit(E);
1473   }
1474 
1475   if (const auto *ComplexTy = QT->getAs<ComplexType>()) {
1476     unsigned NumInits = Inits.size();
1477 
1478     if (NumInits == 1)
1479       return this->delegate(Inits[0]);
1480 
1481     QualType ElemQT = ComplexTy->getElementType();
1482     PrimType ElemT = classifyPrim(ElemQT);
1483     if (NumInits == 0) {
1484       // Zero-initialize both elements.
1485       for (unsigned I = 0; I < 2; ++I) {
1486         if (!this->visitZeroInitializer(ElemT, ElemQT, E))
1487           return false;
1488         if (!this->emitInitElem(ElemT, I, E))
1489           return false;
1490       }
1491     } else if (NumInits == 2) {
1492       unsigned InitIndex = 0;
1493       for (const Expr *Init : Inits) {
1494         if (!this->visit(Init))
1495           return false;
1496 
1497         if (!this->emitInitElem(ElemT, InitIndex, E))
1498           return false;
1499         ++InitIndex;
1500       }
1501     }
1502     return true;
1503   }
1504 
1505   if (const auto *VecT = QT->getAs<VectorType>()) {
1506     unsigned NumVecElements = VecT->getNumElements();
1507     assert(NumVecElements >= Inits.size());
1508 
1509     QualType ElemQT = VecT->getElementType();
1510     PrimType ElemT = classifyPrim(ElemQT);
1511 
1512     // All initializer elements.
1513     unsigned InitIndex = 0;
1514     for (const Expr *Init : Inits) {
1515       if (!this->visit(Init))
1516         return false;
1517 
1518       // If the initializer is of vector type itself, we have to deconstruct
1519       // that and initialize all the target fields from the initializer fields.
1520       if (const auto *InitVecT = Init->getType()->getAs<VectorType>()) {
1521         if (!this->emitCopyArray(ElemT, 0, InitIndex,
1522                                  InitVecT->getNumElements(), E))
1523           return false;
1524         InitIndex += InitVecT->getNumElements();
1525       } else {
1526         if (!this->emitInitElem(ElemT, InitIndex, E))
1527           return false;
1528         ++InitIndex;
1529       }
1530     }
1531 
1532     assert(InitIndex <= NumVecElements);
1533 
1534     // Fill the rest with zeroes.
1535     for (; InitIndex != NumVecElements; ++InitIndex) {
1536       if (!this->visitZeroInitializer(ElemT, ElemQT, E))
1537         return false;
1538       if (!this->emitInitElem(ElemT, InitIndex, E))
1539         return false;
1540     }
1541     return true;
1542   }
1543 
1544   return false;
1545 }
1546 
1547 /// Pointer to the array(not the element!) must be on the stack when calling
1548 /// this.
1549 template <class Emitter>
1550 bool Compiler<Emitter>::visitArrayElemInit(unsigned ElemIndex,
1551                                            const Expr *Init) {
1552   if (std::optional<PrimType> T = classify(Init->getType())) {
1553     // Visit the primitive element like normal.
1554     if (!this->visit(Init))
1555       return false;
1556     return this->emitInitElem(*T, ElemIndex, Init);
1557   }
1558 
1559   // Advance the pointer currently on the stack to the given
1560   // dimension.
1561   if (!this->emitConstUint32(ElemIndex, Init))
1562     return false;
1563   if (!this->emitArrayElemPtrUint32(Init))
1564     return false;
1565   if (!this->visitInitializer(Init))
1566     return false;
1567   return this->emitFinishInitPop(Init);
1568 }
1569 
1570 template <class Emitter>
1571 bool Compiler<Emitter>::VisitInitListExpr(const InitListExpr *E) {
1572   return this->visitInitList(E->inits(), E->getArrayFiller(), E);
1573 }
1574 
1575 template <class Emitter>
1576 bool Compiler<Emitter>::VisitCXXParenListInitExpr(
1577     const CXXParenListInitExpr *E) {
1578   return this->visitInitList(E->getInitExprs(), E->getArrayFiller(), E);
1579 }
1580 
1581 template <class Emitter>
1582 bool Compiler<Emitter>::VisitSubstNonTypeTemplateParmExpr(
1583     const SubstNonTypeTemplateParmExpr *E) {
1584   return this->delegate(E->getReplacement());
1585 }
1586 
1587 template <class Emitter>
1588 bool Compiler<Emitter>::VisitConstantExpr(const ConstantExpr *E) {
1589   std::optional<PrimType> T = classify(E->getType());
1590   if (T && E->hasAPValueResult()) {
1591     // Try to emit the APValue directly, without visiting the subexpr.
1592     // This will only fail if we can't emit the APValue, so won't emit any
1593     // diagnostics or any double values.
1594     if (DiscardResult)
1595       return true;
1596 
1597     if (this->visitAPValue(E->getAPValueResult(), *T, E))
1598       return true;
1599   }
1600   return this->delegate(E->getSubExpr());
1601 }
1602 
1603 template <class Emitter>
1604 bool Compiler<Emitter>::VisitEmbedExpr(const EmbedExpr *E) {
1605   auto It = E->begin();
1606   return this->visit(*It);
1607 }
1608 
1609 static CharUnits AlignOfType(QualType T, const ASTContext &ASTCtx,
1610                              UnaryExprOrTypeTrait Kind) {
1611   bool AlignOfReturnsPreferred =
1612       ASTCtx.getLangOpts().getClangABICompat() <= LangOptions::ClangABI::Ver7;
1613 
1614   // C++ [expr.alignof]p3:
1615   //     When alignof is applied to a reference type, the result is the
1616   //     alignment of the referenced type.
1617   if (const auto *Ref = T->getAs<ReferenceType>())
1618     T = Ref->getPointeeType();
1619 
1620   if (T.getQualifiers().hasUnaligned())
1621     return CharUnits::One();
1622 
1623   // __alignof is defined to return the preferred alignment.
1624   // Before 8, clang returned the preferred alignment for alignof and
1625   // _Alignof as well.
1626   if (Kind == UETT_PreferredAlignOf || AlignOfReturnsPreferred)
1627     return ASTCtx.toCharUnitsFromBits(ASTCtx.getPreferredTypeAlign(T));
1628 
1629   return ASTCtx.getTypeAlignInChars(T);
1630 }
1631 
1632 template <class Emitter>
1633 bool Compiler<Emitter>::VisitUnaryExprOrTypeTraitExpr(
1634     const UnaryExprOrTypeTraitExpr *E) {
1635   UnaryExprOrTypeTrait Kind = E->getKind();
1636   const ASTContext &ASTCtx = Ctx.getASTContext();
1637 
1638   if (Kind == UETT_SizeOf || Kind == UETT_DataSizeOf) {
1639     QualType ArgType = E->getTypeOfArgument();
1640 
1641     // C++ [expr.sizeof]p2: "When applied to a reference or a reference type,
1642     //   the result is the size of the referenced type."
1643     if (const auto *Ref = ArgType->getAs<ReferenceType>())
1644       ArgType = Ref->getPointeeType();
1645 
1646     CharUnits Size;
1647     if (ArgType->isVoidType() || ArgType->isFunctionType())
1648       Size = CharUnits::One();
1649     else {
1650       if (ArgType->isDependentType() || !ArgType->isConstantSizeType())
1651         return false;
1652 
1653       if (Kind == UETT_SizeOf)
1654         Size = ASTCtx.getTypeSizeInChars(ArgType);
1655       else
1656         Size = ASTCtx.getTypeInfoDataSizeInChars(ArgType).Width;
1657     }
1658 
1659     if (DiscardResult)
1660       return true;
1661 
1662     return this->emitConst(Size.getQuantity(), E);
1663   }
1664 
1665   if (Kind == UETT_AlignOf || Kind == UETT_PreferredAlignOf) {
1666     CharUnits Size;
1667 
1668     if (E->isArgumentType()) {
1669       QualType ArgType = E->getTypeOfArgument();
1670 
1671       Size = AlignOfType(ArgType, ASTCtx, Kind);
1672     } else {
1673       // Argument is an expression, not a type.
1674       const Expr *Arg = E->getArgumentExpr()->IgnoreParens();
1675 
1676       // The kinds of expressions that we have special-case logic here for
1677       // should be kept up to date with the special checks for those
1678       // expressions in Sema.
1679 
1680       // alignof decl is always accepted, even if it doesn't make sense: we
1681       // default to 1 in those cases.
1682       if (const auto *DRE = dyn_cast<DeclRefExpr>(Arg))
1683         Size = ASTCtx.getDeclAlign(DRE->getDecl(),
1684                                    /*RefAsPointee*/ true);
1685       else if (const auto *ME = dyn_cast<MemberExpr>(Arg))
1686         Size = ASTCtx.getDeclAlign(ME->getMemberDecl(),
1687                                    /*RefAsPointee*/ true);
1688       else
1689         Size = AlignOfType(Arg->getType(), ASTCtx, Kind);
1690     }
1691 
1692     if (DiscardResult)
1693       return true;
1694 
1695     return this->emitConst(Size.getQuantity(), E);
1696   }
1697 
1698   if (Kind == UETT_VectorElements) {
1699     if (const auto *VT = E->getTypeOfArgument()->getAs<VectorType>())
1700       return this->emitConst(VT->getNumElements(), E);
1701     assert(E->getTypeOfArgument()->isSizelessVectorType());
1702     return this->emitSizelessVectorElementSize(E);
1703   }
1704 
1705   if (Kind == UETT_VecStep) {
1706     if (const auto *VT = E->getTypeOfArgument()->getAs<VectorType>()) {
1707       unsigned N = VT->getNumElements();
1708 
1709       // The vec_step built-in functions that take a 3-component
1710       // vector return 4. (OpenCL 1.1 spec 6.11.12)
1711       if (N == 3)
1712         N = 4;
1713 
1714       return this->emitConst(N, E);
1715     }
1716     return this->emitConst(1, E);
1717   }
1718 
1719   return false;
1720 }
1721 
1722 template <class Emitter>
1723 bool Compiler<Emitter>::VisitMemberExpr(const MemberExpr *E) {
1724   // 'Base.Member'
1725   const Expr *Base = E->getBase();
1726   const ValueDecl *Member = E->getMemberDecl();
1727 
1728   if (DiscardResult)
1729     return this->discard(Base);
1730 
1731   // MemberExprs are almost always lvalues, in which case we don't need to
1732   // do the load. But sometimes they aren't.
1733   const auto maybeLoadValue = [&]() -> bool {
1734     if (E->isGLValue())
1735       return true;
1736     if (std::optional<PrimType> T = classify(E))
1737       return this->emitLoadPop(*T, E);
1738     return false;
1739   };
1740 
1741   if (const auto *VD = dyn_cast<VarDecl>(Member)) {
1742     // I am almost confident in saying that a var decl must be static
1743     // and therefore registered as a global variable. But this will probably
1744     // turn out to be wrong some time in the future, as always.
1745     if (auto GlobalIndex = P.getGlobal(VD))
1746       return this->emitGetPtrGlobal(*GlobalIndex, E) && maybeLoadValue();
1747     return false;
1748   }
1749 
1750   if (!isa<FieldDecl>(Member))
1751     return this->discard(Base) && this->visitDeclRef(Member, E);
1752 
1753   if (Initializing) {
1754     if (!this->delegate(Base))
1755       return false;
1756   } else {
1757     if (!this->visit(Base))
1758       return false;
1759   }
1760 
1761   // Base above gives us a pointer on the stack.
1762   const auto *FD = cast<FieldDecl>(Member);
1763   const RecordDecl *RD = FD->getParent();
1764   const Record *R = getRecord(RD);
1765   if (!R)
1766     return false;
1767   const Record::Field *F = R->getField(FD);
1768   // Leave a pointer to the field on the stack.
1769   if (F->Decl->getType()->isReferenceType())
1770     return this->emitGetFieldPop(PT_Ptr, F->Offset, E) && maybeLoadValue();
1771   return this->emitGetPtrFieldPop(F->Offset, E) && maybeLoadValue();
1772 }
1773 
1774 template <class Emitter>
1775 bool Compiler<Emitter>::VisitArrayInitIndexExpr(const ArrayInitIndexExpr *E) {
1776   // ArrayIndex might not be set if a ArrayInitIndexExpr is being evaluated
1777   // stand-alone, e.g. via EvaluateAsInt().
1778   if (!ArrayIndex)
1779     return false;
1780   return this->emitConst(*ArrayIndex, E);
1781 }
1782 
1783 template <class Emitter>
1784 bool Compiler<Emitter>::VisitArrayInitLoopExpr(const ArrayInitLoopExpr *E) {
1785   assert(Initializing);
1786   assert(!DiscardResult);
1787 
1788   // We visit the common opaque expression here once so we have its value
1789   // cached.
1790   if (!this->discard(E->getCommonExpr()))
1791     return false;
1792 
1793   // TODO: This compiles to quite a lot of bytecode if the array is larger.
1794   //   Investigate compiling this to a loop.
1795   const Expr *SubExpr = E->getSubExpr();
1796   size_t Size = E->getArraySize().getZExtValue();
1797 
1798   // So, every iteration, we execute an assignment here
1799   // where the LHS is on the stack (the target array)
1800   // and the RHS is our SubExpr.
1801   for (size_t I = 0; I != Size; ++I) {
1802     ArrayIndexScope<Emitter> IndexScope(this, I);
1803     BlockScope<Emitter> BS(this);
1804 
1805     if (!this->visitArrayElemInit(I, SubExpr))
1806       return false;
1807     if (!BS.destroyLocals())
1808       return false;
1809   }
1810   return true;
1811 }
1812 
1813 template <class Emitter>
1814 bool Compiler<Emitter>::VisitOpaqueValueExpr(const OpaqueValueExpr *E) {
1815   const Expr *SourceExpr = E->getSourceExpr();
1816   if (!SourceExpr)
1817     return false;
1818 
1819   if (Initializing)
1820     return this->visitInitializer(SourceExpr);
1821 
1822   PrimType SubExprT = classify(SourceExpr).value_or(PT_Ptr);
1823   if (auto It = OpaqueExprs.find(E); It != OpaqueExprs.end())
1824     return this->emitGetLocal(SubExprT, It->second, E);
1825 
1826   if (!this->visit(SourceExpr))
1827     return false;
1828 
1829   // At this point we either have the evaluated source expression or a pointer
1830   // to an object on the stack. We want to create a local variable that stores
1831   // this value.
1832   unsigned LocalIndex = allocateLocalPrimitive(E, SubExprT, /*IsConst=*/true);
1833   if (!this->emitSetLocal(SubExprT, LocalIndex, E))
1834     return false;
1835 
1836   // Here the local variable is created but the value is removed from the stack,
1837   // so we put it back if the caller needs it.
1838   if (!DiscardResult) {
1839     if (!this->emitGetLocal(SubExprT, LocalIndex, E))
1840       return false;
1841   }
1842 
1843   // This is cleaned up when the local variable is destroyed.
1844   OpaqueExprs.insert({E, LocalIndex});
1845 
1846   return true;
1847 }
1848 
1849 template <class Emitter>
1850 bool Compiler<Emitter>::VisitAbstractConditionalOperator(
1851     const AbstractConditionalOperator *E) {
1852   const Expr *Condition = E->getCond();
1853   const Expr *TrueExpr = E->getTrueExpr();
1854   const Expr *FalseExpr = E->getFalseExpr();
1855 
1856   LabelTy LabelEnd = this->getLabel();   // Label after the operator.
1857   LabelTy LabelFalse = this->getLabel(); // Label for the false expr.
1858 
1859   if (!this->visitBool(Condition))
1860     return false;
1861 
1862   if (!this->jumpFalse(LabelFalse))
1863     return false;
1864 
1865   if (!this->delegate(TrueExpr))
1866     return false;
1867   if (!this->jump(LabelEnd))
1868     return false;
1869 
1870   this->emitLabel(LabelFalse);
1871 
1872   if (!this->delegate(FalseExpr))
1873     return false;
1874 
1875   this->fallthrough(LabelEnd);
1876   this->emitLabel(LabelEnd);
1877 
1878   return true;
1879 }
1880 
1881 template <class Emitter>
1882 bool Compiler<Emitter>::VisitStringLiteral(const StringLiteral *E) {
1883   if (DiscardResult)
1884     return true;
1885 
1886   if (!Initializing) {
1887     unsigned StringIndex = P.createGlobalString(E);
1888     return this->emitGetPtrGlobal(StringIndex, E);
1889   }
1890 
1891   // We are initializing an array on the stack.
1892   const ConstantArrayType *CAT =
1893       Ctx.getASTContext().getAsConstantArrayType(E->getType());
1894   assert(CAT && "a string literal that's not a constant array?");
1895 
1896   // If the initializer string is too long, a diagnostic has already been
1897   // emitted. Read only the array length from the string literal.
1898   unsigned ArraySize = CAT->getZExtSize();
1899   unsigned N = std::min(ArraySize, E->getLength());
1900   size_t CharWidth = E->getCharByteWidth();
1901 
1902   for (unsigned I = 0; I != N; ++I) {
1903     uint32_t CodeUnit = E->getCodeUnit(I);
1904 
1905     if (CharWidth == 1) {
1906       this->emitConstSint8(CodeUnit, E);
1907       this->emitInitElemSint8(I, E);
1908     } else if (CharWidth == 2) {
1909       this->emitConstUint16(CodeUnit, E);
1910       this->emitInitElemUint16(I, E);
1911     } else if (CharWidth == 4) {
1912       this->emitConstUint32(CodeUnit, E);
1913       this->emitInitElemUint32(I, E);
1914     } else {
1915       llvm_unreachable("unsupported character width");
1916     }
1917   }
1918 
1919   // Fill up the rest of the char array with NUL bytes.
1920   for (unsigned I = N; I != ArraySize; ++I) {
1921     if (CharWidth == 1) {
1922       this->emitConstSint8(0, E);
1923       this->emitInitElemSint8(I, E);
1924     } else if (CharWidth == 2) {
1925       this->emitConstUint16(0, E);
1926       this->emitInitElemUint16(I, E);
1927     } else if (CharWidth == 4) {
1928       this->emitConstUint32(0, E);
1929       this->emitInitElemUint32(I, E);
1930     } else {
1931       llvm_unreachable("unsupported character width");
1932     }
1933   }
1934 
1935   return true;
1936 }
1937 
1938 template <class Emitter>
1939 bool Compiler<Emitter>::VisitObjCStringLiteral(const ObjCStringLiteral *E) {
1940   return this->delegate(E->getString());
1941 }
1942 
1943 template <class Emitter>
1944 bool Compiler<Emitter>::VisitObjCEncodeExpr(const ObjCEncodeExpr *E) {
1945   auto &A = Ctx.getASTContext();
1946   std::string Str;
1947   A.getObjCEncodingForType(E->getEncodedType(), Str);
1948   StringLiteral *SL =
1949       StringLiteral::Create(A, Str, StringLiteralKind::Ordinary,
1950                             /*Pascal=*/false, E->getType(), E->getAtLoc());
1951   return this->delegate(SL);
1952 }
1953 
1954 template <class Emitter>
1955 bool Compiler<Emitter>::VisitSYCLUniqueStableNameExpr(
1956     const SYCLUniqueStableNameExpr *E) {
1957   if (DiscardResult)
1958     return true;
1959 
1960   assert(!Initializing);
1961 
1962   auto &A = Ctx.getASTContext();
1963   std::string ResultStr = E->ComputeName(A);
1964 
1965   QualType CharTy = A.CharTy.withConst();
1966   APInt Size(A.getTypeSize(A.getSizeType()), ResultStr.size() + 1);
1967   QualType ArrayTy = A.getConstantArrayType(CharTy, Size, nullptr,
1968                                             ArraySizeModifier::Normal, 0);
1969 
1970   StringLiteral *SL =
1971       StringLiteral::Create(A, ResultStr, StringLiteralKind::Ordinary,
1972                             /*Pascal=*/false, ArrayTy, E->getLocation());
1973 
1974   unsigned StringIndex = P.createGlobalString(SL);
1975   return this->emitGetPtrGlobal(StringIndex, E);
1976 }
1977 
1978 template <class Emitter>
1979 bool Compiler<Emitter>::VisitCharacterLiteral(const CharacterLiteral *E) {
1980   if (DiscardResult)
1981     return true;
1982   return this->emitConst(E->getValue(), E);
1983 }
1984 
1985 template <class Emitter>
1986 bool Compiler<Emitter>::VisitFloatCompoundAssignOperator(
1987     const CompoundAssignOperator *E) {
1988 
1989   const Expr *LHS = E->getLHS();
1990   const Expr *RHS = E->getRHS();
1991   QualType LHSType = LHS->getType();
1992   QualType LHSComputationType = E->getComputationLHSType();
1993   QualType ResultType = E->getComputationResultType();
1994   std::optional<PrimType> LT = classify(LHSComputationType);
1995   std::optional<PrimType> RT = classify(ResultType);
1996 
1997   assert(ResultType->isFloatingType());
1998 
1999   if (!LT || !RT)
2000     return false;
2001 
2002   PrimType LHST = classifyPrim(LHSType);
2003 
2004   // C++17 onwards require that we evaluate the RHS first.
2005   // Compute RHS and save it in a temporary variable so we can
2006   // load it again later.
2007   if (!visit(RHS))
2008     return false;
2009 
2010   unsigned TempOffset = this->allocateLocalPrimitive(E, *RT, /*IsConst=*/true);
2011   if (!this->emitSetLocal(*RT, TempOffset, E))
2012     return false;
2013 
2014   // First, visit LHS.
2015   if (!visit(LHS))
2016     return false;
2017   if (!this->emitLoad(LHST, E))
2018     return false;
2019 
2020   // If necessary, convert LHS to its computation type.
2021   if (!this->emitPrimCast(LHST, classifyPrim(LHSComputationType),
2022                           LHSComputationType, E))
2023     return false;
2024 
2025   // Now load RHS.
2026   if (!this->emitGetLocal(*RT, TempOffset, E))
2027     return false;
2028 
2029   llvm::RoundingMode RM = getRoundingMode(E);
2030   switch (E->getOpcode()) {
2031   case BO_AddAssign:
2032     if (!this->emitAddf(RM, E))
2033       return false;
2034     break;
2035   case BO_SubAssign:
2036     if (!this->emitSubf(RM, E))
2037       return false;
2038     break;
2039   case BO_MulAssign:
2040     if (!this->emitMulf(RM, E))
2041       return false;
2042     break;
2043   case BO_DivAssign:
2044     if (!this->emitDivf(RM, E))
2045       return false;
2046     break;
2047   default:
2048     return false;
2049   }
2050 
2051   if (!this->emitPrimCast(classifyPrim(ResultType), LHST, LHS->getType(), E))
2052     return false;
2053 
2054   if (DiscardResult)
2055     return this->emitStorePop(LHST, E);
2056   return this->emitStore(LHST, E);
2057 }
2058 
2059 template <class Emitter>
2060 bool Compiler<Emitter>::VisitPointerCompoundAssignOperator(
2061     const CompoundAssignOperator *E) {
2062   BinaryOperatorKind Op = E->getOpcode();
2063   const Expr *LHS = E->getLHS();
2064   const Expr *RHS = E->getRHS();
2065   std::optional<PrimType> LT = classify(LHS->getType());
2066   std::optional<PrimType> RT = classify(RHS->getType());
2067 
2068   if (Op != BO_AddAssign && Op != BO_SubAssign)
2069     return false;
2070 
2071   if (!LT || !RT)
2072     return false;
2073 
2074   if (!visit(LHS))
2075     return false;
2076 
2077   if (!this->emitLoad(*LT, LHS))
2078     return false;
2079 
2080   if (!visit(RHS))
2081     return false;
2082 
2083   if (Op == BO_AddAssign) {
2084     if (!this->emitAddOffset(*RT, E))
2085       return false;
2086   } else {
2087     if (!this->emitSubOffset(*RT, E))
2088       return false;
2089   }
2090 
2091   if (DiscardResult)
2092     return this->emitStorePopPtr(E);
2093   return this->emitStorePtr(E);
2094 }
2095 
2096 template <class Emitter>
2097 bool Compiler<Emitter>::VisitCompoundAssignOperator(
2098     const CompoundAssignOperator *E) {
2099 
2100   const Expr *LHS = E->getLHS();
2101   const Expr *RHS = E->getRHS();
2102   std::optional<PrimType> LHSComputationT =
2103       classify(E->getComputationLHSType());
2104   std::optional<PrimType> LT = classify(LHS->getType());
2105   std::optional<PrimType> RT = classify(RHS->getType());
2106   std::optional<PrimType> ResultT = classify(E->getType());
2107 
2108   if (!Ctx.getLangOpts().CPlusPlus14)
2109     return this->visit(RHS) && this->visit(LHS) && this->emitError(E);
2110 
2111   if (!LT || !RT || !ResultT || !LHSComputationT)
2112     return false;
2113 
2114   // Handle floating point operations separately here, since they
2115   // require special care.
2116 
2117   if (ResultT == PT_Float || RT == PT_Float)
2118     return VisitFloatCompoundAssignOperator(E);
2119 
2120   if (E->getType()->isPointerType())
2121     return VisitPointerCompoundAssignOperator(E);
2122 
2123   assert(!E->getType()->isPointerType() && "Handled above");
2124   assert(!E->getType()->isFloatingType() && "Handled above");
2125 
2126   // C++17 onwards require that we evaluate the RHS first.
2127   // Compute RHS and save it in a temporary variable so we can
2128   // load it again later.
2129   // FIXME: Compound assignments are unsequenced in C, so we might
2130   //   have to figure out how to reject them.
2131   if (!visit(RHS))
2132     return false;
2133 
2134   unsigned TempOffset = this->allocateLocalPrimitive(E, *RT, /*IsConst=*/true);
2135 
2136   if (!this->emitSetLocal(*RT, TempOffset, E))
2137     return false;
2138 
2139   // Get LHS pointer, load its value and cast it to the
2140   // computation type if necessary.
2141   if (!visit(LHS))
2142     return false;
2143   if (!this->emitLoad(*LT, E))
2144     return false;
2145   if (LT != LHSComputationT) {
2146     if (!this->emitCast(*LT, *LHSComputationT, E))
2147       return false;
2148   }
2149 
2150   // Get the RHS value on the stack.
2151   if (!this->emitGetLocal(*RT, TempOffset, E))
2152     return false;
2153 
2154   // Perform operation.
2155   switch (E->getOpcode()) {
2156   case BO_AddAssign:
2157     if (!this->emitAdd(*LHSComputationT, E))
2158       return false;
2159     break;
2160   case BO_SubAssign:
2161     if (!this->emitSub(*LHSComputationT, E))
2162       return false;
2163     break;
2164   case BO_MulAssign:
2165     if (!this->emitMul(*LHSComputationT, E))
2166       return false;
2167     break;
2168   case BO_DivAssign:
2169     if (!this->emitDiv(*LHSComputationT, E))
2170       return false;
2171     break;
2172   case BO_RemAssign:
2173     if (!this->emitRem(*LHSComputationT, E))
2174       return false;
2175     break;
2176   case BO_ShlAssign:
2177     if (!this->emitShl(*LHSComputationT, *RT, E))
2178       return false;
2179     break;
2180   case BO_ShrAssign:
2181     if (!this->emitShr(*LHSComputationT, *RT, E))
2182       return false;
2183     break;
2184   case BO_AndAssign:
2185     if (!this->emitBitAnd(*LHSComputationT, E))
2186       return false;
2187     break;
2188   case BO_XorAssign:
2189     if (!this->emitBitXor(*LHSComputationT, E))
2190       return false;
2191     break;
2192   case BO_OrAssign:
2193     if (!this->emitBitOr(*LHSComputationT, E))
2194       return false;
2195     break;
2196   default:
2197     llvm_unreachable("Unimplemented compound assign operator");
2198   }
2199 
2200   // And now cast from LHSComputationT to ResultT.
2201   if (ResultT != LHSComputationT) {
2202     if (!this->emitCast(*LHSComputationT, *ResultT, E))
2203       return false;
2204   }
2205 
2206   // And store the result in LHS.
2207   if (DiscardResult) {
2208     if (LHS->refersToBitField())
2209       return this->emitStoreBitFieldPop(*ResultT, E);
2210     return this->emitStorePop(*ResultT, E);
2211   }
2212   if (LHS->refersToBitField())
2213     return this->emitStoreBitField(*ResultT, E);
2214   return this->emitStore(*ResultT, E);
2215 }
2216 
2217 template <class Emitter>
2218 bool Compiler<Emitter>::VisitExprWithCleanups(const ExprWithCleanups *E) {
2219   LocalScope<Emitter> ES(this);
2220   const Expr *SubExpr = E->getSubExpr();
2221 
2222   assert(E->getNumObjects() == 0 && "TODO: Implement cleanups");
2223 
2224   return this->delegate(SubExpr) && ES.destroyLocals();
2225 }
2226 
2227 template <class Emitter>
2228 bool Compiler<Emitter>::VisitMaterializeTemporaryExpr(
2229     const MaterializeTemporaryExpr *E) {
2230   const Expr *SubExpr = E->getSubExpr();
2231 
2232   if (Initializing) {
2233     // We already have a value, just initialize that.
2234     return this->delegate(SubExpr);
2235   }
2236   // If we don't end up using the materialized temporary anyway, don't
2237   // bother creating it.
2238   if (DiscardResult)
2239     return this->discard(SubExpr);
2240 
2241   // When we're initializing a global variable *or* the storage duration of
2242   // the temporary is explicitly static, create a global variable.
2243   std::optional<PrimType> SubExprT = classify(SubExpr);
2244   bool IsStatic = E->getStorageDuration() == SD_Static;
2245   if (GlobalDecl || IsStatic) {
2246     std::optional<unsigned> GlobalIndex = P.createGlobal(E);
2247     if (!GlobalIndex)
2248       return false;
2249 
2250     const LifetimeExtendedTemporaryDecl *TempDecl =
2251         E->getLifetimeExtendedTemporaryDecl();
2252     if (IsStatic)
2253       assert(TempDecl);
2254 
2255     if (SubExprT) {
2256       if (!this->visit(SubExpr))
2257         return false;
2258       if (IsStatic) {
2259         if (!this->emitInitGlobalTemp(*SubExprT, *GlobalIndex, TempDecl, E))
2260           return false;
2261       } else {
2262         if (!this->emitInitGlobal(*SubExprT, *GlobalIndex, E))
2263           return false;
2264       }
2265       return this->emitGetPtrGlobal(*GlobalIndex, E);
2266     }
2267 
2268     // Non-primitive values.
2269     if (!this->emitGetPtrGlobal(*GlobalIndex, E))
2270       return false;
2271     if (!this->visitInitializer(SubExpr))
2272       return false;
2273     if (IsStatic)
2274       return this->emitInitGlobalTempComp(TempDecl, E);
2275     return true;
2276   }
2277 
2278   // For everyhing else, use local variables.
2279   if (SubExprT) {
2280     unsigned LocalIndex = allocateLocalPrimitive(
2281         SubExpr, *SubExprT, /*IsConst=*/true, /*IsExtended=*/true);
2282     if (!this->visit(SubExpr))
2283       return false;
2284     if (!this->emitSetLocal(*SubExprT, LocalIndex, E))
2285       return false;
2286     return this->emitGetPtrLocal(LocalIndex, E);
2287   } else {
2288     const Expr *Inner = E->getSubExpr()->skipRValueSubobjectAdjustments();
2289     if (std::optional<unsigned> LocalIndex =
2290             allocateLocal(Inner, E->getExtendingDecl())) {
2291       InitLinkScope<Emitter> ILS(this, InitLink::Temp(*LocalIndex));
2292       if (!this->emitGetPtrLocal(*LocalIndex, E))
2293         return false;
2294       return this->visitInitializer(SubExpr);
2295     }
2296   }
2297   return false;
2298 }
2299 
2300 template <class Emitter>
2301 bool Compiler<Emitter>::VisitCXXBindTemporaryExpr(
2302     const CXXBindTemporaryExpr *E) {
2303   return this->delegate(E->getSubExpr());
2304 }
2305 
2306 template <class Emitter>
2307 bool Compiler<Emitter>::VisitCompoundLiteralExpr(const CompoundLiteralExpr *E) {
2308   const Expr *Init = E->getInitializer();
2309   if (Initializing) {
2310     // We already have a value, just initialize that.
2311     return this->visitInitializer(Init) && this->emitFinishInit(E);
2312   }
2313 
2314   std::optional<PrimType> T = classify(E->getType());
2315   if (E->isFileScope()) {
2316     // Avoid creating a variable if this is a primitive RValue anyway.
2317     if (T && !E->isLValue())
2318       return this->delegate(Init);
2319 
2320     if (std::optional<unsigned> GlobalIndex = P.createGlobal(E)) {
2321       if (!this->emitGetPtrGlobal(*GlobalIndex, E))
2322         return false;
2323 
2324       if (T) {
2325         if (!this->visit(Init))
2326           return false;
2327         return this->emitInitGlobal(*T, *GlobalIndex, E);
2328       }
2329 
2330       return this->visitInitializer(Init) && this->emitFinishInit(E);
2331     }
2332 
2333     return false;
2334   }
2335 
2336   // Otherwise, use a local variable.
2337   if (T && !E->isLValue()) {
2338     // For primitive types, we just visit the initializer.
2339     return this->delegate(Init);
2340   } else {
2341     unsigned LocalIndex;
2342 
2343     if (T)
2344       LocalIndex = this->allocateLocalPrimitive(Init, *T, false, false);
2345     else if (std::optional<unsigned> MaybeIndex = this->allocateLocal(Init))
2346       LocalIndex = *MaybeIndex;
2347     else
2348       return false;
2349 
2350     if (!this->emitGetPtrLocal(LocalIndex, E))
2351       return false;
2352 
2353     if (T) {
2354       if (!this->visit(Init)) {
2355         return false;
2356       }
2357       return this->emitInit(*T, E);
2358     } else {
2359       if (!this->visitInitializer(Init) || !this->emitFinishInit(E))
2360         return false;
2361     }
2362 
2363     if (DiscardResult)
2364       return this->emitPopPtr(E);
2365     return true;
2366   }
2367 
2368   return false;
2369 }
2370 
2371 template <class Emitter>
2372 bool Compiler<Emitter>::VisitTypeTraitExpr(const TypeTraitExpr *E) {
2373   if (DiscardResult)
2374     return true;
2375   if (E->getType()->isBooleanType())
2376     return this->emitConstBool(E->getValue(), E);
2377   return this->emitConst(E->getValue(), E);
2378 }
2379 
2380 template <class Emitter>
2381 bool Compiler<Emitter>::VisitArrayTypeTraitExpr(const ArrayTypeTraitExpr *E) {
2382   if (DiscardResult)
2383     return true;
2384   return this->emitConst(E->getValue(), E);
2385 }
2386 
2387 template <class Emitter>
2388 bool Compiler<Emitter>::VisitLambdaExpr(const LambdaExpr *E) {
2389   if (DiscardResult)
2390     return true;
2391 
2392   assert(Initializing);
2393   const Record *R = P.getOrCreateRecord(E->getLambdaClass());
2394 
2395   auto *CaptureInitIt = E->capture_init_begin();
2396   // Initialize all fields (which represent lambda captures) of the
2397   // record with their initializers.
2398   for (const Record::Field &F : R->fields()) {
2399     const Expr *Init = *CaptureInitIt;
2400     ++CaptureInitIt;
2401 
2402     if (!Init)
2403       continue;
2404 
2405     if (std::optional<PrimType> T = classify(Init)) {
2406       if (!this->visit(Init))
2407         return false;
2408 
2409       if (!this->emitInitField(*T, F.Offset, E))
2410         return false;
2411     } else {
2412       if (!this->emitGetPtrField(F.Offset, E))
2413         return false;
2414 
2415       if (!this->visitInitializer(Init))
2416         return false;
2417 
2418       if (!this->emitPopPtr(E))
2419         return false;
2420     }
2421   }
2422 
2423   return true;
2424 }
2425 
2426 template <class Emitter>
2427 bool Compiler<Emitter>::VisitPredefinedExpr(const PredefinedExpr *E) {
2428   if (DiscardResult)
2429     return true;
2430 
2431   return this->delegate(E->getFunctionName());
2432 }
2433 
2434 template <class Emitter>
2435 bool Compiler<Emitter>::VisitCXXThrowExpr(const CXXThrowExpr *E) {
2436   if (E->getSubExpr() && !this->discard(E->getSubExpr()))
2437     return false;
2438 
2439   return this->emitInvalid(E);
2440 }
2441 
2442 template <class Emitter>
2443 bool Compiler<Emitter>::VisitCXXReinterpretCastExpr(
2444     const CXXReinterpretCastExpr *E) {
2445   if (!this->discard(E->getSubExpr()))
2446     return false;
2447 
2448   return this->emitInvalidCast(CastKind::Reinterpret, E);
2449 }
2450 
2451 template <class Emitter>
2452 bool Compiler<Emitter>::VisitCXXNoexceptExpr(const CXXNoexceptExpr *E) {
2453   assert(E->getType()->isBooleanType());
2454 
2455   if (DiscardResult)
2456     return true;
2457   return this->emitConstBool(E->getValue(), E);
2458 }
2459 
2460 template <class Emitter>
2461 bool Compiler<Emitter>::VisitCXXConstructExpr(const CXXConstructExpr *E) {
2462   QualType T = E->getType();
2463   assert(!classify(T));
2464 
2465   if (T->isRecordType()) {
2466     const CXXConstructorDecl *Ctor = E->getConstructor();
2467 
2468     // Trivial copy/move constructor. Avoid copy.
2469     if (Ctor->isDefaulted() && Ctor->isCopyOrMoveConstructor() &&
2470         Ctor->isTrivial() &&
2471         E->getArg(0)->isTemporaryObject(Ctx.getASTContext(),
2472                                         T->getAsCXXRecordDecl()))
2473       return this->visitInitializer(E->getArg(0));
2474 
2475     // If we're discarding a construct expression, we still need
2476     // to allocate a variable and call the constructor and destructor.
2477     if (DiscardResult) {
2478       if (Ctor->isTrivial())
2479         return true;
2480       assert(!Initializing);
2481       std::optional<unsigned> LocalIndex = allocateLocal(E);
2482 
2483       if (!LocalIndex)
2484         return false;
2485 
2486       if (!this->emitGetPtrLocal(*LocalIndex, E))
2487         return false;
2488     }
2489 
2490     // Zero initialization.
2491     if (E->requiresZeroInitialization()) {
2492       const Record *R = getRecord(E->getType());
2493 
2494       if (!this->visitZeroRecordInitializer(R, E))
2495         return false;
2496 
2497       // If the constructor is trivial anyway, we're done.
2498       if (Ctor->isTrivial())
2499         return true;
2500     }
2501 
2502     const Function *Func = getFunction(Ctor);
2503 
2504     if (!Func)
2505       return false;
2506 
2507     assert(Func->hasThisPointer());
2508     assert(!Func->hasRVO());
2509 
2510     //  The This pointer is already on the stack because this is an initializer,
2511     //  but we need to dup() so the call() below has its own copy.
2512     if (!this->emitDupPtr(E))
2513       return false;
2514 
2515     // Constructor arguments.
2516     for (const auto *Arg : E->arguments()) {
2517       if (!this->visit(Arg))
2518         return false;
2519     }
2520 
2521     if (Func->isVariadic()) {
2522       uint32_t VarArgSize = 0;
2523       unsigned NumParams = Func->getNumWrittenParams();
2524       for (unsigned I = NumParams, N = E->getNumArgs(); I != N; ++I) {
2525         VarArgSize +=
2526             align(primSize(classify(E->getArg(I)->getType()).value_or(PT_Ptr)));
2527       }
2528       if (!this->emitCallVar(Func, VarArgSize, E))
2529         return false;
2530     } else {
2531       if (!this->emitCall(Func, 0, E))
2532         return false;
2533     }
2534 
2535     // Immediately call the destructor if we have to.
2536     if (DiscardResult) {
2537       if (!this->emitRecordDestruction(getRecord(E->getType())))
2538         return false;
2539       if (!this->emitPopPtr(E))
2540         return false;
2541     }
2542     return true;
2543   }
2544 
2545   if (T->isArrayType()) {
2546     const ConstantArrayType *CAT =
2547         Ctx.getASTContext().getAsConstantArrayType(E->getType());
2548     if (!CAT)
2549       return false;
2550 
2551     size_t NumElems = CAT->getZExtSize();
2552     const Function *Func = getFunction(E->getConstructor());
2553     if (!Func || !Func->isConstexpr())
2554       return false;
2555 
2556     // FIXME(perf): We're calling the constructor once per array element here,
2557     //   in the old intepreter we had a special-case for trivial constructors.
2558     for (size_t I = 0; I != NumElems; ++I) {
2559       if (!this->emitConstUint64(I, E))
2560         return false;
2561       if (!this->emitArrayElemPtrUint64(E))
2562         return false;
2563 
2564       // Constructor arguments.
2565       for (const auto *Arg : E->arguments()) {
2566         if (!this->visit(Arg))
2567           return false;
2568       }
2569 
2570       if (!this->emitCall(Func, 0, E))
2571         return false;
2572     }
2573     return true;
2574   }
2575 
2576   return false;
2577 }
2578 
2579 template <class Emitter>
2580 bool Compiler<Emitter>::VisitSourceLocExpr(const SourceLocExpr *E) {
2581   if (DiscardResult)
2582     return true;
2583 
2584   const APValue Val =
2585       E->EvaluateInContext(Ctx.getASTContext(), SourceLocDefaultExpr);
2586 
2587   // Things like __builtin_LINE().
2588   if (E->getType()->isIntegerType()) {
2589     assert(Val.isInt());
2590     const APSInt &I = Val.getInt();
2591     return this->emitConst(I, E);
2592   }
2593   // Otherwise, the APValue is an LValue, with only one element.
2594   // Theoretically, we don't need the APValue at all of course.
2595   assert(E->getType()->isPointerType());
2596   assert(Val.isLValue());
2597   const APValue::LValueBase &Base = Val.getLValueBase();
2598   if (const Expr *LValueExpr = Base.dyn_cast<const Expr *>())
2599     return this->visit(LValueExpr);
2600 
2601   // Otherwise, we have a decl (which is the case for
2602   // __builtin_source_location).
2603   assert(Base.is<const ValueDecl *>());
2604   assert(Val.getLValuePath().size() == 0);
2605   const auto *BaseDecl = Base.dyn_cast<const ValueDecl *>();
2606   assert(BaseDecl);
2607 
2608   auto *UGCD = cast<UnnamedGlobalConstantDecl>(BaseDecl);
2609 
2610   std::optional<unsigned> GlobalIndex = P.getOrCreateGlobal(UGCD);
2611   if (!GlobalIndex)
2612     return false;
2613 
2614   if (!this->emitGetPtrGlobal(*GlobalIndex, E))
2615     return false;
2616 
2617   const Record *R = getRecord(E->getType());
2618   const APValue &V = UGCD->getValue();
2619   for (unsigned I = 0, N = R->getNumFields(); I != N; ++I) {
2620     const Record::Field *F = R->getField(I);
2621     const APValue &FieldValue = V.getStructField(I);
2622 
2623     PrimType FieldT = classifyPrim(F->Decl->getType());
2624 
2625     if (!this->visitAPValue(FieldValue, FieldT, E))
2626       return false;
2627     if (!this->emitInitField(FieldT, F->Offset, E))
2628       return false;
2629   }
2630 
2631   // Leave the pointer to the global on the stack.
2632   return true;
2633 }
2634 
2635 template <class Emitter>
2636 bool Compiler<Emitter>::VisitOffsetOfExpr(const OffsetOfExpr *E) {
2637   unsigned N = E->getNumComponents();
2638   if (N == 0)
2639     return false;
2640 
2641   for (unsigned I = 0; I != N; ++I) {
2642     const OffsetOfNode &Node = E->getComponent(I);
2643     if (Node.getKind() == OffsetOfNode::Array) {
2644       const Expr *ArrayIndexExpr = E->getIndexExpr(Node.getArrayExprIndex());
2645       PrimType IndexT = classifyPrim(ArrayIndexExpr->getType());
2646 
2647       if (DiscardResult) {
2648         if (!this->discard(ArrayIndexExpr))
2649           return false;
2650         continue;
2651       }
2652 
2653       if (!this->visit(ArrayIndexExpr))
2654         return false;
2655       // Cast to Sint64.
2656       if (IndexT != PT_Sint64) {
2657         if (!this->emitCast(IndexT, PT_Sint64, E))
2658           return false;
2659       }
2660     }
2661   }
2662 
2663   if (DiscardResult)
2664     return true;
2665 
2666   PrimType T = classifyPrim(E->getType());
2667   return this->emitOffsetOf(T, E, E);
2668 }
2669 
2670 template <class Emitter>
2671 bool Compiler<Emitter>::VisitCXXScalarValueInitExpr(
2672     const CXXScalarValueInitExpr *E) {
2673   QualType Ty = E->getType();
2674 
2675   if (DiscardResult || Ty->isVoidType())
2676     return true;
2677 
2678   if (std::optional<PrimType> T = classify(Ty))
2679     return this->visitZeroInitializer(*T, Ty, E);
2680 
2681   if (const auto *CT = Ty->getAs<ComplexType>()) {
2682     if (!Initializing) {
2683       std::optional<unsigned> LocalIndex = allocateLocal(E);
2684       if (!LocalIndex)
2685         return false;
2686       if (!this->emitGetPtrLocal(*LocalIndex, E))
2687         return false;
2688     }
2689 
2690     // Initialize both fields to 0.
2691     QualType ElemQT = CT->getElementType();
2692     PrimType ElemT = classifyPrim(ElemQT);
2693 
2694     for (unsigned I = 0; I != 2; ++I) {
2695       if (!this->visitZeroInitializer(ElemT, ElemQT, E))
2696         return false;
2697       if (!this->emitInitElem(ElemT, I, E))
2698         return false;
2699     }
2700     return true;
2701   }
2702 
2703   if (const auto *VT = Ty->getAs<VectorType>()) {
2704     // FIXME: Code duplication with the _Complex case above.
2705     if (!Initializing) {
2706       std::optional<unsigned> LocalIndex = allocateLocal(E);
2707       if (!LocalIndex)
2708         return false;
2709       if (!this->emitGetPtrLocal(*LocalIndex, E))
2710         return false;
2711     }
2712 
2713     // Initialize all fields to 0.
2714     QualType ElemQT = VT->getElementType();
2715     PrimType ElemT = classifyPrim(ElemQT);
2716 
2717     for (unsigned I = 0, N = VT->getNumElements(); I != N; ++I) {
2718       if (!this->visitZeroInitializer(ElemT, ElemQT, E))
2719         return false;
2720       if (!this->emitInitElem(ElemT, I, E))
2721         return false;
2722     }
2723     return true;
2724   }
2725 
2726   return false;
2727 }
2728 
2729 template <class Emitter>
2730 bool Compiler<Emitter>::VisitSizeOfPackExpr(const SizeOfPackExpr *E) {
2731   return this->emitConst(E->getPackLength(), E);
2732 }
2733 
2734 template <class Emitter>
2735 bool Compiler<Emitter>::VisitGenericSelectionExpr(
2736     const GenericSelectionExpr *E) {
2737   return this->delegate(E->getResultExpr());
2738 }
2739 
2740 template <class Emitter>
2741 bool Compiler<Emitter>::VisitChooseExpr(const ChooseExpr *E) {
2742   return this->delegate(E->getChosenSubExpr());
2743 }
2744 
2745 template <class Emitter>
2746 bool Compiler<Emitter>::VisitObjCBoolLiteralExpr(const ObjCBoolLiteralExpr *E) {
2747   if (DiscardResult)
2748     return true;
2749 
2750   return this->emitConst(E->getValue(), E);
2751 }
2752 
2753 template <class Emitter>
2754 bool Compiler<Emitter>::VisitCXXInheritedCtorInitExpr(
2755     const CXXInheritedCtorInitExpr *E) {
2756   const CXXConstructorDecl *Ctor = E->getConstructor();
2757   assert(!Ctor->isTrivial() &&
2758          "Trivial CXXInheritedCtorInitExpr, implement. (possible?)");
2759   const Function *F = this->getFunction(Ctor);
2760   assert(F);
2761   assert(!F->hasRVO());
2762   assert(F->hasThisPointer());
2763 
2764   if (!this->emitDupPtr(SourceInfo{}))
2765     return false;
2766 
2767   // Forward all arguments of the current function (which should be a
2768   // constructor itself) to the inherited ctor.
2769   // This is necessary because the calling code has pushed the pointer
2770   // of the correct base for  us already, but the arguments need
2771   // to come after.
2772   unsigned Offset = align(primSize(PT_Ptr)); // instance pointer.
2773   for (const ParmVarDecl *PD : Ctor->parameters()) {
2774     PrimType PT = this->classify(PD->getType()).value_or(PT_Ptr);
2775 
2776     if (!this->emitGetParam(PT, Offset, E))
2777       return false;
2778     Offset += align(primSize(PT));
2779   }
2780 
2781   return this->emitCall(F, 0, E);
2782 }
2783 
2784 template <class Emitter>
2785 bool Compiler<Emitter>::VisitCXXNewExpr(const CXXNewExpr *E) {
2786   assert(classifyPrim(E->getType()) == PT_Ptr);
2787   const Expr *Init = E->getInitializer();
2788   QualType ElementType = E->getAllocatedType();
2789   std::optional<PrimType> ElemT = classify(ElementType);
2790   unsigned PlacementArgs = E->getNumPlacementArgs();
2791   bool IsNoThrow = false;
2792 
2793   // FIXME: Better diagnostic. diag::note_constexpr_new_placement
2794   if (PlacementArgs != 0) {
2795     // The only new-placement list we support is of the form (std::nothrow).
2796     //
2797     // FIXME: There is no restriction on this, but it's not clear that any
2798     // other form makes any sense. We get here for cases such as:
2799     //
2800     //   new (std::align_val_t{N}) X(int)
2801     //
2802     // (which should presumably be valid only if N is a multiple of
2803     // alignof(int), and in any case can't be deallocated unless N is
2804     // alignof(X) and X has new-extended alignment).
2805     if (PlacementArgs != 1 || !E->getPlacementArg(0)->getType()->isNothrowT())
2806       return this->emitInvalid(E);
2807 
2808     if (!this->discard(E->getPlacementArg(0)))
2809       return false;
2810     IsNoThrow = true;
2811   }
2812 
2813   const Descriptor *Desc;
2814   if (ElemT) {
2815     if (E->isArray())
2816       Desc = nullptr; // We're not going to use it in this case.
2817     else
2818       Desc = P.createDescriptor(E, *ElemT, Descriptor::InlineDescMD,
2819                                 /*IsConst=*/false, /*IsTemporary=*/false,
2820                                 /*IsMutable=*/false);
2821   } else {
2822     Desc = P.createDescriptor(
2823         E, ElementType.getTypePtr(),
2824         E->isArray() ? std::nullopt : Descriptor::InlineDescMD,
2825         /*IsConst=*/false, /*IsTemporary=*/false, /*IsMutable=*/false, Init);
2826   }
2827 
2828   if (E->isArray()) {
2829     std::optional<const Expr *> ArraySizeExpr = E->getArraySize();
2830     if (!ArraySizeExpr)
2831       return false;
2832 
2833     const Expr *Stripped = *ArraySizeExpr;
2834     for (; auto *ICE = dyn_cast<ImplicitCastExpr>(Stripped);
2835          Stripped = ICE->getSubExpr())
2836       if (ICE->getCastKind() != CK_NoOp &&
2837           ICE->getCastKind() != CK_IntegralCast)
2838         break;
2839 
2840     PrimType SizeT = classifyPrim(Stripped->getType());
2841 
2842     if (!this->visit(Stripped))
2843       return false;
2844 
2845     if (ElemT) {
2846       // N primitive elements.
2847       if (!this->emitAllocN(SizeT, *ElemT, E, IsNoThrow, E))
2848         return false;
2849     } else {
2850       // N Composite elements.
2851       if (!this->emitAllocCN(SizeT, Desc, IsNoThrow, E))
2852         return false;
2853     }
2854 
2855     if (Init && !this->visitInitializer(Init))
2856       return false;
2857 
2858   } else {
2859     // Allocate just one element.
2860     if (!this->emitAlloc(Desc, E))
2861       return false;
2862 
2863     if (Init) {
2864       if (ElemT) {
2865         if (!this->visit(Init))
2866           return false;
2867 
2868         if (!this->emitInit(*ElemT, E))
2869           return false;
2870       } else {
2871         // Composite.
2872         if (!this->visitInitializer(Init))
2873           return false;
2874       }
2875     }
2876   }
2877 
2878   if (DiscardResult)
2879     return this->emitPopPtr(E);
2880 
2881   return true;
2882 }
2883 
2884 template <class Emitter>
2885 bool Compiler<Emitter>::VisitCXXDeleteExpr(const CXXDeleteExpr *E) {
2886   const Expr *Arg = E->getArgument();
2887 
2888   // Arg must be an lvalue.
2889   if (!this->visit(Arg))
2890     return false;
2891 
2892   return this->emitFree(E->isArrayForm(), E);
2893 }
2894 
2895 template <class Emitter>
2896 bool Compiler<Emitter>::VisitExpressionTraitExpr(const ExpressionTraitExpr *E) {
2897   assert(Ctx.getLangOpts().CPlusPlus);
2898   return this->emitConstBool(E->getValue(), E);
2899 }
2900 
2901 template <class Emitter>
2902 bool Compiler<Emitter>::VisitCXXUuidofExpr(const CXXUuidofExpr *E) {
2903   if (DiscardResult)
2904     return true;
2905   assert(!Initializing);
2906 
2907   const MSGuidDecl *GuidDecl = E->getGuidDecl();
2908   const RecordDecl *RD = GuidDecl->getType()->getAsRecordDecl();
2909   assert(RD);
2910   // If the definiton of the result type is incomplete, just return a dummy.
2911   // If (and when) that is read from, we will fail, but not now.
2912   if (!RD->isCompleteDefinition()) {
2913     if (std::optional<unsigned> I = P.getOrCreateDummy(GuidDecl))
2914       return this->emitGetPtrGlobal(*I, E);
2915     return false;
2916   }
2917 
2918   std::optional<unsigned> GlobalIndex = P.getOrCreateGlobal(GuidDecl);
2919   if (!GlobalIndex)
2920     return false;
2921   if (!this->emitGetPtrGlobal(*GlobalIndex, E))
2922     return false;
2923 
2924   assert(this->getRecord(E->getType()));
2925 
2926   const APValue &V = GuidDecl->getAsAPValue();
2927   if (V.getKind() == APValue::None)
2928     return true;
2929 
2930   assert(V.isStruct());
2931   assert(V.getStructNumBases() == 0);
2932   if (!this->visitAPValueInitializer(V, E))
2933     return false;
2934 
2935   return this->emitFinishInit(E);
2936 }
2937 
2938 template <class Emitter>
2939 bool Compiler<Emitter>::VisitRequiresExpr(const RequiresExpr *E) {
2940   assert(classifyPrim(E->getType()) == PT_Bool);
2941   if (DiscardResult)
2942     return true;
2943   return this->emitConstBool(E->isSatisfied(), E);
2944 }
2945 
2946 template <class Emitter>
2947 bool Compiler<Emitter>::VisitConceptSpecializationExpr(
2948     const ConceptSpecializationExpr *E) {
2949   assert(classifyPrim(E->getType()) == PT_Bool);
2950   if (DiscardResult)
2951     return true;
2952   return this->emitConstBool(E->isSatisfied(), E);
2953 }
2954 
2955 template <class Emitter>
2956 bool Compiler<Emitter>::VisitCXXRewrittenBinaryOperator(
2957     const CXXRewrittenBinaryOperator *E) {
2958   return this->delegate(E->getSemanticForm());
2959 }
2960 
2961 template <class Emitter>
2962 bool Compiler<Emitter>::VisitPseudoObjectExpr(const PseudoObjectExpr *E) {
2963 
2964   for (const Expr *SemE : E->semantics()) {
2965     if (auto *OVE = dyn_cast<OpaqueValueExpr>(SemE)) {
2966       if (SemE == E->getResultExpr())
2967         return false;
2968 
2969       if (OVE->isUnique())
2970         continue;
2971 
2972       if (!this->discard(OVE))
2973         return false;
2974     } else if (SemE == E->getResultExpr()) {
2975       if (!this->delegate(SemE))
2976         return false;
2977     } else {
2978       if (!this->discard(SemE))
2979         return false;
2980     }
2981   }
2982   return true;
2983 }
2984 
2985 template <class Emitter>
2986 bool Compiler<Emitter>::VisitPackIndexingExpr(const PackIndexingExpr *E) {
2987   return this->delegate(E->getSelectedExpr());
2988 }
2989 
2990 template <class Emitter>
2991 bool Compiler<Emitter>::VisitRecoveryExpr(const RecoveryExpr *E) {
2992   return this->emitError(E);
2993 }
2994 
2995 template <class Emitter>
2996 bool Compiler<Emitter>::VisitAddrLabelExpr(const AddrLabelExpr *E) {
2997   assert(E->getType()->isVoidPointerType());
2998 
2999   unsigned Offset = allocateLocalPrimitive(
3000       E->getLabel(), PT_Ptr, /*IsConst=*/true, /*IsExtended=*/false);
3001 
3002   return this->emitGetLocal(PT_Ptr, Offset, E);
3003 }
3004 
3005 template <class Emitter>
3006 bool Compiler<Emitter>::VisitConvertVectorExpr(const ConvertVectorExpr *E) {
3007   assert(Initializing);
3008   const auto *VT = E->getType()->castAs<VectorType>();
3009   QualType ElemType = VT->getElementType();
3010   PrimType ElemT = classifyPrim(ElemType);
3011   const Expr *Src = E->getSrcExpr();
3012   PrimType SrcElemT =
3013       classifyPrim(Src->getType()->castAs<VectorType>()->getElementType());
3014 
3015   unsigned SrcOffset = this->allocateLocalPrimitive(Src, PT_Ptr, true, false);
3016   if (!this->visit(Src))
3017     return false;
3018   if (!this->emitSetLocal(PT_Ptr, SrcOffset, E))
3019     return false;
3020 
3021   for (unsigned I = 0; I != VT->getNumElements(); ++I) {
3022     if (!this->emitGetLocal(PT_Ptr, SrcOffset, E))
3023       return false;
3024     if (!this->emitArrayElemPop(SrcElemT, I, E))
3025       return false;
3026     if (SrcElemT != ElemT) {
3027       if (!this->emitPrimCast(SrcElemT, ElemT, ElemType, E))
3028         return false;
3029     }
3030     if (!this->emitInitElem(ElemT, I, E))
3031       return false;
3032   }
3033 
3034   return true;
3035 }
3036 
3037 template <class Emitter>
3038 bool Compiler<Emitter>::VisitShuffleVectorExpr(const ShuffleVectorExpr *E) {
3039   assert(Initializing);
3040   assert(E->getNumSubExprs() > 2);
3041 
3042   const Expr *Vecs[] = {E->getExpr(0), E->getExpr(1)};
3043   const VectorType *VT = Vecs[0]->getType()->castAs<VectorType>();
3044   PrimType ElemT = classifyPrim(VT->getElementType());
3045   unsigned NumInputElems = VT->getNumElements();
3046   unsigned NumOutputElems = E->getNumSubExprs() - 2;
3047   assert(NumOutputElems > 0);
3048 
3049   // Save both input vectors to a local variable.
3050   unsigned VectorOffsets[2];
3051   for (unsigned I = 0; I != 2; ++I) {
3052     VectorOffsets[I] = this->allocateLocalPrimitive(
3053         Vecs[I], PT_Ptr, /*IsConst=*/true, /*IsExtended=*/false);
3054     if (!this->visit(Vecs[I]))
3055       return false;
3056     if (!this->emitSetLocal(PT_Ptr, VectorOffsets[I], E))
3057       return false;
3058   }
3059   for (unsigned I = 0; I != NumOutputElems; ++I) {
3060     APSInt ShuffleIndex = E->getShuffleMaskIdx(Ctx.getASTContext(), I);
3061     if (ShuffleIndex == -1)
3062       return this->emitInvalid(E); // FIXME: Better diagnostic.
3063 
3064     assert(ShuffleIndex < (NumInputElems * 2));
3065     if (!this->emitGetLocal(PT_Ptr,
3066                             VectorOffsets[ShuffleIndex >= NumInputElems], E))
3067       return false;
3068     unsigned InputVectorIndex = ShuffleIndex.getZExtValue() % NumInputElems;
3069     if (!this->emitArrayElemPop(ElemT, InputVectorIndex, E))
3070       return false;
3071 
3072     if (!this->emitInitElem(ElemT, I, E))
3073       return false;
3074   }
3075 
3076   return true;
3077 }
3078 
3079 template <class Emitter>
3080 bool Compiler<Emitter>::VisitExtVectorElementExpr(
3081     const ExtVectorElementExpr *E) {
3082   const Expr *Base = E->getBase();
3083   assert(
3084       Base->getType()->isVectorType() ||
3085       Base->getType()->getAs<PointerType>()->getPointeeType()->isVectorType());
3086 
3087   SmallVector<uint32_t, 4> Indices;
3088   E->getEncodedElementAccess(Indices);
3089 
3090   if (Indices.size() == 1) {
3091     if (!this->visit(Base))
3092       return false;
3093 
3094     if (E->isGLValue()) {
3095       if (!this->emitConstUint32(Indices[0], E))
3096         return false;
3097       return this->emitArrayElemPtrPop(PT_Uint32, E);
3098     }
3099     // Else, also load the value.
3100     return this->emitArrayElemPop(classifyPrim(E->getType()), Indices[0], E);
3101   }
3102 
3103   // Create a local variable for the base.
3104   unsigned BaseOffset = allocateLocalPrimitive(Base, PT_Ptr, /*IsConst=*/true,
3105                                                /*IsExtended=*/false);
3106   if (!this->visit(Base))
3107     return false;
3108   if (!this->emitSetLocal(PT_Ptr, BaseOffset, E))
3109     return false;
3110 
3111   // Now the vector variable for the return value.
3112   if (!Initializing) {
3113     std::optional<unsigned> ResultIndex;
3114     ResultIndex = allocateLocal(E);
3115     if (!ResultIndex)
3116       return false;
3117     if (!this->emitGetPtrLocal(*ResultIndex, E))
3118       return false;
3119   }
3120 
3121   assert(Indices.size() == E->getType()->getAs<VectorType>()->getNumElements());
3122 
3123   PrimType ElemT =
3124       classifyPrim(E->getType()->getAs<VectorType>()->getElementType());
3125   uint32_t DstIndex = 0;
3126   for (uint32_t I : Indices) {
3127     if (!this->emitGetLocal(PT_Ptr, BaseOffset, E))
3128       return false;
3129     if (!this->emitArrayElemPop(ElemT, I, E))
3130       return false;
3131     if (!this->emitInitElem(ElemT, DstIndex, E))
3132       return false;
3133     ++DstIndex;
3134   }
3135 
3136   // Leave the result pointer on the stack.
3137   assert(!DiscardResult);
3138   return true;
3139 }
3140 
3141 template <class Emitter>
3142 bool Compiler<Emitter>::VisitObjCBoxedExpr(const ObjCBoxedExpr *E) {
3143   if (!E->isExpressibleAsConstantInitializer())
3144     return this->emitInvalid(E);
3145 
3146   return this->delegate(E->getSubExpr());
3147 }
3148 
3149 template <class Emitter>
3150 bool Compiler<Emitter>::VisitCXXStdInitializerListExpr(
3151     const CXXStdInitializerListExpr *E) {
3152   const Expr *SubExpr = E->getSubExpr();
3153   const ConstantArrayType *ArrayType =
3154       Ctx.getASTContext().getAsConstantArrayType(SubExpr->getType());
3155   const Record *R = getRecord(E->getType());
3156   assert(Initializing);
3157   assert(SubExpr->isGLValue());
3158 
3159   if (!this->visit(SubExpr))
3160     return false;
3161   if (!this->emitInitFieldPtr(R->getField(0u)->Offset, E))
3162     return false;
3163 
3164   PrimType SecondFieldT = classifyPrim(R->getField(1u)->Decl->getType());
3165   if (isIntegralType(SecondFieldT)) {
3166     if (!this->emitConst(static_cast<APSInt>(ArrayType->getSize()),
3167                          SecondFieldT, E))
3168       return false;
3169     return this->emitInitField(SecondFieldT, R->getField(1u)->Offset, E);
3170   }
3171   assert(SecondFieldT == PT_Ptr);
3172 
3173   if (!this->emitGetFieldPtr(R->getField(0u)->Offset, E))
3174     return false;
3175   if (!this->emitConst(static_cast<APSInt>(ArrayType->getSize()), PT_Uint64, E))
3176     return false;
3177   if (!this->emitArrayElemPtrPop(PT_Uint64, E))
3178     return false;
3179   return this->emitInitFieldPtr(R->getField(1u)->Offset, E);
3180 }
3181 
3182 template <class Emitter>
3183 bool Compiler<Emitter>::VisitStmtExpr(const StmtExpr *E) {
3184   BlockScope<Emitter> BS(this);
3185   StmtExprScope<Emitter> SS(this);
3186 
3187   const CompoundStmt *CS = E->getSubStmt();
3188   const Stmt *Result = CS->getStmtExprResult();
3189   for (const Stmt *S : CS->body()) {
3190     if (S != Result) {
3191       if (!this->visitStmt(S))
3192         return false;
3193       continue;
3194     }
3195 
3196     assert(S == Result);
3197     if (const Expr *ResultExpr = dyn_cast<Expr>(S)) {
3198       if (DiscardResult)
3199         return this->discard(ResultExpr);
3200       return this->delegate(ResultExpr);
3201     }
3202 
3203     return this->visitStmt(S);
3204   }
3205 
3206   return BS.destroyLocals();
3207 }
3208 
3209 template <class Emitter> bool Compiler<Emitter>::discard(const Expr *E) {
3210   OptionScope<Emitter> Scope(this, /*NewDiscardResult=*/true,
3211                              /*NewInitializing=*/false);
3212   return this->Visit(E);
3213 }
3214 
3215 template <class Emitter> bool Compiler<Emitter>::delegate(const Expr *E) {
3216   if (E->containsErrors())
3217     return this->emitError(E);
3218 
3219   // We're basically doing:
3220   // OptionScope<Emitter> Scope(this, DicardResult, Initializing);
3221   // but that's unnecessary of course.
3222   return this->Visit(E);
3223 }
3224 
3225 template <class Emitter> bool Compiler<Emitter>::visit(const Expr *E) {
3226   if (E->getType().isNull())
3227     return false;
3228 
3229   if (E->getType()->isVoidType())
3230     return this->discard(E);
3231 
3232   // Create local variable to hold the return value.
3233   if (!E->isGLValue() && !E->getType()->isAnyComplexType() &&
3234       !classify(E->getType())) {
3235     std::optional<unsigned> LocalIndex = allocateLocal(E);
3236     if (!LocalIndex)
3237       return false;
3238 
3239     if (!this->emitGetPtrLocal(*LocalIndex, E))
3240       return false;
3241     return this->visitInitializer(E);
3242   }
3243 
3244   //  Otherwise,we have a primitive return value, produce the value directly
3245   //  and push it on the stack.
3246   OptionScope<Emitter> Scope(this, /*NewDiscardResult=*/false,
3247                              /*NewInitializing=*/false);
3248   return this->Visit(E);
3249 }
3250 
3251 template <class Emitter>
3252 bool Compiler<Emitter>::visitInitializer(const Expr *E) {
3253   assert(!classify(E->getType()));
3254 
3255   if (E->containsErrors())
3256     return this->emitError(E);
3257 
3258   OptionScope<Emitter> Scope(this, /*NewDiscardResult=*/false,
3259                              /*NewInitializing=*/true);
3260   return this->Visit(E);
3261 }
3262 
3263 template <class Emitter> bool Compiler<Emitter>::visitBool(const Expr *E) {
3264   std::optional<PrimType> T = classify(E->getType());
3265   if (!T) {
3266     // Convert complex values to bool.
3267     if (E->getType()->isAnyComplexType()) {
3268       if (!this->visit(E))
3269         return false;
3270       return this->emitComplexBoolCast(E);
3271     }
3272     return false;
3273   }
3274 
3275   if (!this->visit(E))
3276     return false;
3277 
3278   if (T == PT_Bool)
3279     return true;
3280 
3281   // Convert pointers to bool.
3282   if (T == PT_Ptr || T == PT_FnPtr) {
3283     if (!this->emitNull(*T, nullptr, E))
3284       return false;
3285     return this->emitNE(*T, E);
3286   }
3287 
3288   // Or Floats.
3289   if (T == PT_Float)
3290     return this->emitCastFloatingIntegralBool(E);
3291 
3292   // Or anything else we can.
3293   return this->emitCast(*T, PT_Bool, E);
3294 }
3295 
3296 template <class Emitter>
3297 bool Compiler<Emitter>::visitZeroInitializer(PrimType T, QualType QT,
3298                                              const Expr *E) {
3299   switch (T) {
3300   case PT_Bool:
3301     return this->emitZeroBool(E);
3302   case PT_Sint8:
3303     return this->emitZeroSint8(E);
3304   case PT_Uint8:
3305     return this->emitZeroUint8(E);
3306   case PT_Sint16:
3307     return this->emitZeroSint16(E);
3308   case PT_Uint16:
3309     return this->emitZeroUint16(E);
3310   case PT_Sint32:
3311     return this->emitZeroSint32(E);
3312   case PT_Uint32:
3313     return this->emitZeroUint32(E);
3314   case PT_Sint64:
3315     return this->emitZeroSint64(E);
3316   case PT_Uint64:
3317     return this->emitZeroUint64(E);
3318   case PT_IntAP:
3319     return this->emitZeroIntAP(Ctx.getBitWidth(QT), E);
3320   case PT_IntAPS:
3321     return this->emitZeroIntAPS(Ctx.getBitWidth(QT), E);
3322   case PT_Ptr:
3323     return this->emitNullPtr(nullptr, E);
3324   case PT_FnPtr:
3325     return this->emitNullFnPtr(nullptr, E);
3326   case PT_MemberPtr:
3327     return this->emitNullMemberPtr(nullptr, E);
3328   case PT_Float: {
3329     return this->emitConstFloat(APFloat::getZero(Ctx.getFloatSemantics(QT)), E);
3330   }
3331   }
3332   llvm_unreachable("unknown primitive type");
3333 }
3334 
3335 template <class Emitter>
3336 bool Compiler<Emitter>::visitZeroRecordInitializer(const Record *R,
3337                                                    const Expr *E) {
3338   assert(E);
3339   assert(R);
3340   // Fields
3341   for (const Record::Field &Field : R->fields()) {
3342     const Descriptor *D = Field.Desc;
3343     if (D->isPrimitive()) {
3344       QualType QT = D->getType();
3345       PrimType T = classifyPrim(D->getType());
3346       if (!this->visitZeroInitializer(T, QT, E))
3347         return false;
3348       if (!this->emitInitField(T, Field.Offset, E))
3349         return false;
3350       continue;
3351     }
3352 
3353     if (!this->emitGetPtrField(Field.Offset, E))
3354       return false;
3355 
3356     if (D->isPrimitiveArray()) {
3357       QualType ET = D->getElemQualType();
3358       PrimType T = classifyPrim(ET);
3359       for (uint32_t I = 0, N = D->getNumElems(); I != N; ++I) {
3360         if (!this->visitZeroInitializer(T, ET, E))
3361           return false;
3362         if (!this->emitInitElem(T, I, E))
3363           return false;
3364       }
3365     } else if (D->isCompositeArray()) {
3366       const Record *ElemRecord = D->ElemDesc->ElemRecord;
3367       assert(D->ElemDesc->ElemRecord);
3368       for (uint32_t I = 0, N = D->getNumElems(); I != N; ++I) {
3369         if (!this->emitConstUint32(I, E))
3370           return false;
3371         if (!this->emitArrayElemPtr(PT_Uint32, E))
3372           return false;
3373         if (!this->visitZeroRecordInitializer(ElemRecord, E))
3374           return false;
3375         if (!this->emitPopPtr(E))
3376           return false;
3377       }
3378     } else if (D->isRecord()) {
3379       if (!this->visitZeroRecordInitializer(D->ElemRecord, E))
3380         return false;
3381     } else {
3382       assert(false);
3383     }
3384 
3385     if (!this->emitPopPtr(E))
3386       return false;
3387   }
3388 
3389   for (const Record::Base &B : R->bases()) {
3390     if (!this->emitGetPtrBase(B.Offset, E))
3391       return false;
3392     if (!this->visitZeroRecordInitializer(B.R, E))
3393       return false;
3394     if (!this->emitFinishInitPop(E))
3395       return false;
3396   }
3397 
3398   // FIXME: Virtual bases.
3399 
3400   return true;
3401 }
3402 
3403 template <class Emitter>
3404 template <typename T>
3405 bool Compiler<Emitter>::emitConst(T Value, PrimType Ty, const Expr *E) {
3406   switch (Ty) {
3407   case PT_Sint8:
3408     return this->emitConstSint8(Value, E);
3409   case PT_Uint8:
3410     return this->emitConstUint8(Value, E);
3411   case PT_Sint16:
3412     return this->emitConstSint16(Value, E);
3413   case PT_Uint16:
3414     return this->emitConstUint16(Value, E);
3415   case PT_Sint32:
3416     return this->emitConstSint32(Value, E);
3417   case PT_Uint32:
3418     return this->emitConstUint32(Value, E);
3419   case PT_Sint64:
3420     return this->emitConstSint64(Value, E);
3421   case PT_Uint64:
3422     return this->emitConstUint64(Value, E);
3423   case PT_Bool:
3424     return this->emitConstBool(Value, E);
3425   case PT_Ptr:
3426   case PT_FnPtr:
3427   case PT_MemberPtr:
3428   case PT_Float:
3429   case PT_IntAP:
3430   case PT_IntAPS:
3431     llvm_unreachable("Invalid integral type");
3432     break;
3433   }
3434   llvm_unreachable("unknown primitive type");
3435 }
3436 
3437 template <class Emitter>
3438 template <typename T>
3439 bool Compiler<Emitter>::emitConst(T Value, const Expr *E) {
3440   return this->emitConst(Value, classifyPrim(E->getType()), E);
3441 }
3442 
3443 template <class Emitter>
3444 bool Compiler<Emitter>::emitConst(const APSInt &Value, PrimType Ty,
3445                                   const Expr *E) {
3446   if (Ty == PT_IntAPS)
3447     return this->emitConstIntAPS(Value, E);
3448   if (Ty == PT_IntAP)
3449     return this->emitConstIntAP(Value, E);
3450 
3451   if (Value.isSigned())
3452     return this->emitConst(Value.getSExtValue(), Ty, E);
3453   return this->emitConst(Value.getZExtValue(), Ty, E);
3454 }
3455 
3456 template <class Emitter>
3457 bool Compiler<Emitter>::emitConst(const APSInt &Value, const Expr *E) {
3458   return this->emitConst(Value, classifyPrim(E->getType()), E);
3459 }
3460 
3461 template <class Emitter>
3462 unsigned Compiler<Emitter>::allocateLocalPrimitive(DeclTy &&Src, PrimType Ty,
3463                                                    bool IsConst,
3464                                                    bool IsExtended) {
3465   // Make sure we don't accidentally register the same decl twice.
3466   if (const auto *VD =
3467           dyn_cast_if_present<ValueDecl>(Src.dyn_cast<const Decl *>())) {
3468     assert(!P.getGlobal(VD));
3469     assert(!Locals.contains(VD));
3470     (void)VD;
3471   }
3472 
3473   // FIXME: There are cases where Src.is<Expr*>() is wrong, e.g.
3474   //   (int){12} in C. Consider using Expr::isTemporaryObject() instead
3475   //   or isa<MaterializeTemporaryExpr>().
3476   Descriptor *D = P.createDescriptor(Src, Ty, Descriptor::InlineDescMD, IsConst,
3477                                      Src.is<const Expr *>());
3478   Scope::Local Local = this->createLocal(D);
3479   if (auto *VD = dyn_cast_if_present<ValueDecl>(Src.dyn_cast<const Decl *>()))
3480     Locals.insert({VD, Local});
3481   VarScope->add(Local, IsExtended);
3482   return Local.Offset;
3483 }
3484 
3485 template <class Emitter>
3486 std::optional<unsigned>
3487 Compiler<Emitter>::allocateLocal(DeclTy &&Src, const ValueDecl *ExtendingDecl) {
3488   // Make sure we don't accidentally register the same decl twice.
3489   if ([[maybe_unused]] const auto *VD =
3490           dyn_cast_if_present<ValueDecl>(Src.dyn_cast<const Decl *>())) {
3491     assert(!P.getGlobal(VD));
3492     assert(!Locals.contains(VD));
3493   }
3494 
3495   QualType Ty;
3496   const ValueDecl *Key = nullptr;
3497   const Expr *Init = nullptr;
3498   bool IsTemporary = false;
3499   if (auto *VD = dyn_cast_if_present<ValueDecl>(Src.dyn_cast<const Decl *>())) {
3500     Key = VD;
3501     Ty = VD->getType();
3502 
3503     if (const auto *VarD = dyn_cast<VarDecl>(VD))
3504       Init = VarD->getInit();
3505   }
3506   if (auto *E = Src.dyn_cast<const Expr *>()) {
3507     IsTemporary = true;
3508     Ty = E->getType();
3509   }
3510 
3511   Descriptor *D = P.createDescriptor(
3512       Src, Ty.getTypePtr(), Descriptor::InlineDescMD, Ty.isConstQualified(),
3513       IsTemporary, /*IsMutable=*/false, Init);
3514   if (!D)
3515     return std::nullopt;
3516 
3517   Scope::Local Local = this->createLocal(D);
3518   if (Key)
3519     Locals.insert({Key, Local});
3520   if (ExtendingDecl)
3521     VarScope->addExtended(Local, ExtendingDecl);
3522   else
3523     VarScope->add(Local, false);
3524   return Local.Offset;
3525 }
3526 
3527 template <class Emitter>
3528 const RecordType *Compiler<Emitter>::getRecordTy(QualType Ty) {
3529   if (const PointerType *PT = dyn_cast<PointerType>(Ty))
3530     return PT->getPointeeType()->getAs<RecordType>();
3531   return Ty->getAs<RecordType>();
3532 }
3533 
3534 template <class Emitter> Record *Compiler<Emitter>::getRecord(QualType Ty) {
3535   if (const auto *RecordTy = getRecordTy(Ty))
3536     return getRecord(RecordTy->getDecl());
3537   return nullptr;
3538 }
3539 
3540 template <class Emitter>
3541 Record *Compiler<Emitter>::getRecord(const RecordDecl *RD) {
3542   return P.getOrCreateRecord(RD);
3543 }
3544 
3545 template <class Emitter>
3546 const Function *Compiler<Emitter>::getFunction(const FunctionDecl *FD) {
3547   return Ctx.getOrCreateFunction(FD);
3548 }
3549 
3550 template <class Emitter> bool Compiler<Emitter>::visitExpr(const Expr *E) {
3551   LocalScope<Emitter> RootScope(this);
3552   // Void expressions.
3553   if (E->getType()->isVoidType()) {
3554     if (!visit(E))
3555       return false;
3556     return this->emitRetVoid(E) && RootScope.destroyLocals();
3557   }
3558 
3559   // Expressions with a primitive return type.
3560   if (std::optional<PrimType> T = classify(E)) {
3561     if (!visit(E))
3562       return false;
3563     return this->emitRet(*T, E) && RootScope.destroyLocals();
3564   }
3565 
3566   // Expressions with a composite return type.
3567   // For us, that means everything we don't
3568   // have a PrimType for.
3569   if (std::optional<unsigned> LocalOffset = this->allocateLocal(E)) {
3570     if (!this->emitGetPtrLocal(*LocalOffset, E))
3571       return false;
3572 
3573     if (!visitInitializer(E))
3574       return false;
3575 
3576     if (!this->emitFinishInit(E))
3577       return false;
3578     // We are destroying the locals AFTER the Ret op.
3579     // The Ret op needs to copy the (alive) values, but the
3580     // destructors may still turn the entire expression invalid.
3581     return this->emitRetValue(E) && RootScope.destroyLocals();
3582   }
3583 
3584   RootScope.destroyLocals();
3585   return false;
3586 }
3587 
3588 template <class Emitter>
3589 VarCreationState Compiler<Emitter>::visitDecl(const VarDecl *VD) {
3590 
3591   auto R = this->visitVarDecl(VD, /*Toplevel=*/true);
3592 
3593   if (R.notCreated())
3594     return R;
3595 
3596   if (R)
3597     return true;
3598 
3599   if (!R && Context::shouldBeGloballyIndexed(VD)) {
3600     if (auto GlobalIndex = P.getGlobal(VD)) {
3601       Block *GlobalBlock = P.getGlobal(*GlobalIndex);
3602       GlobalInlineDescriptor &GD =
3603           *reinterpret_cast<GlobalInlineDescriptor *>(GlobalBlock->rawData());
3604 
3605       GD.InitState = GlobalInitState::InitializerFailed;
3606       GlobalBlock->invokeDtor();
3607     }
3608   }
3609 
3610   return R;
3611 }
3612 
3613 /// Toplevel visitDeclAndReturn().
3614 /// We get here from evaluateAsInitializer().
3615 /// We need to evaluate the initializer and return its value.
3616 template <class Emitter>
3617 bool Compiler<Emitter>::visitDeclAndReturn(const VarDecl *VD,
3618                                            bool ConstantContext) {
3619   std::optional<PrimType> VarT = classify(VD->getType());
3620 
3621   // We only create variables if we're evaluating in a constant context.
3622   // Otherwise, just evaluate the initializer and return it.
3623   if (!ConstantContext) {
3624     DeclScope<Emitter> LS(this, VD);
3625     if (!this->visit(VD->getAnyInitializer()))
3626       return false;
3627     return this->emitRet(VarT.value_or(PT_Ptr), VD) && LS.destroyLocals();
3628   }
3629 
3630   LocalScope<Emitter> VDScope(this, VD);
3631   if (!this->visitVarDecl(VD, /*Toplevel=*/true))
3632     return false;
3633 
3634   if (Context::shouldBeGloballyIndexed(VD)) {
3635     auto GlobalIndex = P.getGlobal(VD);
3636     assert(GlobalIndex); // visitVarDecl() didn't return false.
3637     if (VarT) {
3638       if (!this->emitGetGlobalUnchecked(*VarT, *GlobalIndex, VD))
3639         return false;
3640     } else {
3641       if (!this->emitGetPtrGlobal(*GlobalIndex, VD))
3642         return false;
3643     }
3644   } else {
3645     auto Local = Locals.find(VD);
3646     assert(Local != Locals.end()); // Same here.
3647     if (VarT) {
3648       if (!this->emitGetLocal(*VarT, Local->second.Offset, VD))
3649         return false;
3650     } else {
3651       if (!this->emitGetPtrLocal(Local->second.Offset, VD))
3652         return false;
3653     }
3654   }
3655 
3656   // Return the value.
3657   if (!this->emitRet(VarT.value_or(PT_Ptr), VD)) {
3658     // If the Ret above failed and this is a global variable, mark it as
3659     // uninitialized, even everything else succeeded.
3660     if (Context::shouldBeGloballyIndexed(VD)) {
3661       auto GlobalIndex = P.getGlobal(VD);
3662       assert(GlobalIndex);
3663       Block *GlobalBlock = P.getGlobal(*GlobalIndex);
3664       GlobalInlineDescriptor &GD =
3665           *reinterpret_cast<GlobalInlineDescriptor *>(GlobalBlock->rawData());
3666 
3667       GD.InitState = GlobalInitState::InitializerFailed;
3668       GlobalBlock->invokeDtor();
3669     }
3670     return false;
3671   }
3672 
3673   return VDScope.destroyLocals();
3674 }
3675 
3676 template <class Emitter>
3677 VarCreationState Compiler<Emitter>::visitVarDecl(const VarDecl *VD, bool Toplevel) {
3678   // We don't know what to do with these, so just return false.
3679   if (VD->getType().isNull())
3680     return false;
3681 
3682   // This case is EvalEmitter-only. If we won't create any instructions for the
3683   // initializer anyway, don't bother creating the variable in the first place.
3684   if (!this->isActive())
3685     return VarCreationState::NotCreated();
3686 
3687   const Expr *Init = VD->getInit();
3688   std::optional<PrimType> VarT = classify(VD->getType());
3689 
3690   if (Context::shouldBeGloballyIndexed(VD)) {
3691     auto checkDecl = [&]() -> bool {
3692       bool NeedsOp = !Toplevel && VD->isLocalVarDecl() && VD->isStaticLocal();
3693       return !NeedsOp || this->emitCheckDecl(VD, VD);
3694     };
3695 
3696     auto initGlobal = [&](unsigned GlobalIndex) -> bool {
3697       assert(Init);
3698       DeclScope<Emitter> LocalScope(this, VD);
3699 
3700       if (VarT) {
3701         if (!this->visit(Init))
3702           return checkDecl() && false;
3703 
3704         return checkDecl() && this->emitInitGlobal(*VarT, GlobalIndex, VD);
3705       }
3706 
3707       if (!checkDecl())
3708         return false;
3709 
3710       if (!this->emitGetPtrGlobal(GlobalIndex, Init))
3711         return false;
3712 
3713       if (!visitInitializer(Init))
3714         return false;
3715 
3716       if (!this->emitFinishInit(Init))
3717         return false;
3718 
3719       return this->emitPopPtr(Init);
3720     };
3721 
3722     // We've already seen and initialized this global.
3723     if (std::optional<unsigned> GlobalIndex = P.getGlobal(VD)) {
3724       if (P.getPtrGlobal(*GlobalIndex).isInitialized())
3725         return checkDecl();
3726 
3727       // The previous attempt at initialization might've been unsuccessful,
3728       // so let's try this one.
3729       return Init && checkDecl() && initGlobal(*GlobalIndex);
3730     }
3731 
3732     std::optional<unsigned> GlobalIndex = P.createGlobal(VD, Init);
3733 
3734     if (!GlobalIndex)
3735       return false;
3736 
3737     return !Init || (checkDecl() && initGlobal(*GlobalIndex));
3738   } else {
3739     InitLinkScope<Emitter> ILS(this, InitLink::Decl(VD));
3740 
3741     if (VarT) {
3742       unsigned Offset = this->allocateLocalPrimitive(
3743           VD, *VarT, VD->getType().isConstQualified());
3744       if (Init) {
3745         // If this is a toplevel declaration, create a scope for the
3746         // initializer.
3747         if (Toplevel) {
3748           LocalScope<Emitter> Scope(this);
3749           if (!this->visit(Init))
3750             return false;
3751           return this->emitSetLocal(*VarT, Offset, VD) && Scope.destroyLocals();
3752         } else {
3753           if (!this->visit(Init))
3754             return false;
3755           return this->emitSetLocal(*VarT, Offset, VD);
3756         }
3757       }
3758     } else {
3759       if (std::optional<unsigned> Offset = this->allocateLocal(VD)) {
3760         if (!Init)
3761           return true;
3762 
3763         if (!this->emitGetPtrLocal(*Offset, Init))
3764           return false;
3765 
3766         if (!visitInitializer(Init))
3767           return false;
3768 
3769         if (!this->emitFinishInit(Init))
3770           return false;
3771 
3772         return this->emitPopPtr(Init);
3773       }
3774       return false;
3775     }
3776     return true;
3777   }
3778 
3779   return false;
3780 }
3781 
3782 template <class Emitter>
3783 bool Compiler<Emitter>::visitAPValue(const APValue &Val, PrimType ValType,
3784                                      const Expr *E) {
3785   assert(!DiscardResult);
3786   if (Val.isInt())
3787     return this->emitConst(Val.getInt(), ValType, E);
3788   else if (Val.isFloat())
3789     return this->emitConstFloat(Val.getFloat(), E);
3790 
3791   if (Val.isLValue()) {
3792     if (Val.isNullPointer())
3793       return this->emitNull(ValType, nullptr, E);
3794     APValue::LValueBase Base = Val.getLValueBase();
3795     if (const Expr *BaseExpr = Base.dyn_cast<const Expr *>())
3796       return this->visit(BaseExpr);
3797     else if (const auto *VD = Base.dyn_cast<const ValueDecl *>()) {
3798       return this->visitDeclRef(VD, E);
3799     }
3800   } else if (Val.isMemberPointer()) {
3801     if (const ValueDecl *MemberDecl = Val.getMemberPointerDecl())
3802       return this->emitGetMemberPtr(MemberDecl, E);
3803     return this->emitNullMemberPtr(nullptr, E);
3804   }
3805 
3806   return false;
3807 }
3808 
3809 template <class Emitter>
3810 bool Compiler<Emitter>::visitAPValueInitializer(const APValue &Val,
3811                                                 const Expr *E) {
3812 
3813   if (Val.isStruct()) {
3814     const Record *R = this->getRecord(E->getType());
3815     assert(R);
3816     for (unsigned I = 0, N = Val.getStructNumFields(); I != N; ++I) {
3817       const APValue &F = Val.getStructField(I);
3818       const Record::Field *RF = R->getField(I);
3819 
3820       if (F.isInt() || F.isFloat() || F.isLValue() || F.isMemberPointer()) {
3821         PrimType T = classifyPrim(RF->Decl->getType());
3822         if (!this->visitAPValue(F, T, E))
3823           return false;
3824         if (!this->emitInitField(T, RF->Offset, E))
3825           return false;
3826       } else if (F.isArray()) {
3827         assert(RF->Desc->isPrimitiveArray());
3828         const auto *ArrType = RF->Decl->getType()->getAsArrayTypeUnsafe();
3829         PrimType ElemT = classifyPrim(ArrType->getElementType());
3830         assert(ArrType);
3831 
3832         if (!this->emitGetPtrField(RF->Offset, E))
3833           return false;
3834 
3835         for (unsigned A = 0, AN = F.getArraySize(); A != AN; ++A) {
3836           if (!this->visitAPValue(F.getArrayInitializedElt(A), ElemT, E))
3837             return false;
3838           if (!this->emitInitElem(ElemT, A, E))
3839             return false;
3840         }
3841 
3842         if (!this->emitPopPtr(E))
3843           return false;
3844       } else if (F.isStruct() || F.isUnion()) {
3845         if (!this->emitGetPtrField(RF->Offset, E))
3846           return false;
3847         if (!this->visitAPValueInitializer(F, E))
3848           return false;
3849         if (!this->emitPopPtr(E))
3850           return false;
3851       } else {
3852         assert(false && "I don't think this should be possible");
3853       }
3854     }
3855     return true;
3856   } else if (Val.isUnion()) {
3857     const FieldDecl *UnionField = Val.getUnionField();
3858     const Record *R = this->getRecord(UnionField->getParent());
3859     assert(R);
3860     const APValue &F = Val.getUnionValue();
3861     const Record::Field *RF = R->getField(UnionField);
3862     PrimType T = classifyPrim(RF->Decl->getType());
3863     if (!this->visitAPValue(F, T, E))
3864       return false;
3865     return this->emitInitField(T, RF->Offset, E);
3866   }
3867   // TODO: Other types.
3868 
3869   return false;
3870 }
3871 
3872 template <class Emitter>
3873 bool Compiler<Emitter>::VisitBuiltinCallExpr(const CallExpr *E) {
3874   const Function *Func = getFunction(E->getDirectCallee());
3875   if (!Func)
3876     return false;
3877 
3878   // For these, we're expected to ultimately return an APValue pointing
3879   // to the CallExpr. This is needed to get the correct codegen.
3880   unsigned Builtin = E->getBuiltinCallee();
3881   if (Builtin == Builtin::BI__builtin___CFStringMakeConstantString ||
3882       Builtin == Builtin::BI__builtin___NSStringMakeConstantString ||
3883       Builtin == Builtin::BI__builtin_ptrauth_sign_constant ||
3884       Builtin == Builtin::BI__builtin_function_start) {
3885     if (std::optional<unsigned> GlobalOffset = P.createGlobal(E)) {
3886       if (!this->emitGetPtrGlobal(*GlobalOffset, E))
3887         return false;
3888 
3889       if (PrimType PT = classifyPrim(E); PT != PT_Ptr && isPtrType(PT))
3890         return this->emitDecayPtr(PT_Ptr, PT, E);
3891       return true;
3892     }
3893     return false;
3894   }
3895 
3896   QualType ReturnType = E->getType();
3897   std::optional<PrimType> ReturnT = classify(E);
3898 
3899   // Non-primitive return type. Prepare storage.
3900   if (!Initializing && !ReturnT && !ReturnType->isVoidType()) {
3901     std::optional<unsigned> LocalIndex = allocateLocal(E);
3902     if (!LocalIndex)
3903       return false;
3904     if (!this->emitGetPtrLocal(*LocalIndex, E))
3905       return false;
3906   }
3907 
3908   if (!Func->isUnevaluatedBuiltin()) {
3909     // Put arguments on the stack.
3910     for (const auto *Arg : E->arguments()) {
3911       if (!this->visit(Arg))
3912         return false;
3913     }
3914   }
3915 
3916   if (!this->emitCallBI(Func, E, E))
3917     return false;
3918 
3919   if (DiscardResult && !ReturnType->isVoidType()) {
3920     assert(ReturnT);
3921     return this->emitPop(*ReturnT, E);
3922   }
3923 
3924   return true;
3925 }
3926 
3927 template <class Emitter>
3928 bool Compiler<Emitter>::VisitCallExpr(const CallExpr *E) {
3929   if (E->getBuiltinCallee())
3930     return VisitBuiltinCallExpr(E);
3931 
3932   QualType ReturnType = E->getCallReturnType(Ctx.getASTContext());
3933   std::optional<PrimType> T = classify(ReturnType);
3934   bool HasRVO = !ReturnType->isVoidType() && !T;
3935   const FunctionDecl *FuncDecl = E->getDirectCallee();
3936 
3937   if (HasRVO) {
3938     if (DiscardResult) {
3939       // If we need to discard the return value but the function returns its
3940       // value via an RVO pointer, we need to create one such pointer just
3941       // for this call.
3942       if (std::optional<unsigned> LocalIndex = allocateLocal(E)) {
3943         if (!this->emitGetPtrLocal(*LocalIndex, E))
3944           return false;
3945       }
3946     } else {
3947       // We need the result. Prepare a pointer to return or
3948       // dup the current one.
3949       if (!Initializing) {
3950         if (std::optional<unsigned> LocalIndex = allocateLocal(E)) {
3951           if (!this->emitGetPtrLocal(*LocalIndex, E))
3952             return false;
3953         }
3954       }
3955       if (!this->emitDupPtr(E))
3956         return false;
3957     }
3958   }
3959 
3960   auto Args = llvm::ArrayRef(E->getArgs(), E->getNumArgs());
3961   // Calling a static operator will still
3962   // pass the instance, but we don't need it.
3963   // Discard it here.
3964   if (isa<CXXOperatorCallExpr>(E)) {
3965     if (const auto *MD = dyn_cast_if_present<CXXMethodDecl>(FuncDecl);
3966         MD && MD->isStatic()) {
3967       if (!this->discard(E->getArg(0)))
3968         return false;
3969       Args = Args.drop_front();
3970     }
3971   }
3972 
3973   std::optional<unsigned> CalleeOffset;
3974   // Add the (optional, implicit) This pointer.
3975   if (const auto *MC = dyn_cast<CXXMemberCallExpr>(E)) {
3976     if (!FuncDecl && classifyPrim(E->getCallee()) == PT_MemberPtr) {
3977       // If we end up creating a CallPtr op for this, we need the base of the
3978       // member pointer as the instance pointer, and later extract the function
3979       // decl as the function pointer.
3980       const Expr *Callee = E->getCallee();
3981       CalleeOffset =
3982           this->allocateLocalPrimitive(Callee, PT_MemberPtr, true, false);
3983       if (!this->visit(Callee))
3984         return false;
3985       if (!this->emitSetLocal(PT_MemberPtr, *CalleeOffset, E))
3986         return false;
3987       if (!this->emitGetLocal(PT_MemberPtr, *CalleeOffset, E))
3988         return false;
3989       if (!this->emitGetMemberPtrBase(E))
3990         return false;
3991     } else if (!this->visit(MC->getImplicitObjectArgument())) {
3992       return false;
3993     }
3994   }
3995 
3996   llvm::BitVector NonNullArgs = collectNonNullArgs(FuncDecl, Args);
3997   // Put arguments on the stack.
3998   unsigned ArgIndex = 0;
3999   for (const auto *Arg : Args) {
4000     if (!this->visit(Arg))
4001       return false;
4002 
4003     // If we know the callee already, check the known parametrs for nullability.
4004     if (FuncDecl && NonNullArgs[ArgIndex]) {
4005       PrimType ArgT = classify(Arg).value_or(PT_Ptr);
4006       if (ArgT == PT_Ptr || ArgT == PT_FnPtr) {
4007         if (!this->emitCheckNonNullArg(ArgT, Arg))
4008           return false;
4009       }
4010     }
4011     ++ArgIndex;
4012   }
4013 
4014   if (FuncDecl) {
4015     const Function *Func = getFunction(FuncDecl);
4016     if (!Func)
4017       return false;
4018     assert(HasRVO == Func->hasRVO());
4019 
4020     bool HasQualifier = false;
4021     if (const auto *ME = dyn_cast<MemberExpr>(E->getCallee()))
4022       HasQualifier = ME->hasQualifier();
4023 
4024     bool IsVirtual = false;
4025     if (const auto *MD = dyn_cast<CXXMethodDecl>(FuncDecl))
4026       IsVirtual = MD->isVirtual();
4027 
4028     // In any case call the function. The return value will end up on the stack
4029     // and if the function has RVO, we already have the pointer on the stack to
4030     // write the result into.
4031     if (IsVirtual && !HasQualifier) {
4032       uint32_t VarArgSize = 0;
4033       unsigned NumParams =
4034           Func->getNumWrittenParams() + isa<CXXOperatorCallExpr>(E);
4035       for (unsigned I = NumParams, N = E->getNumArgs(); I != N; ++I)
4036         VarArgSize += align(primSize(classify(E->getArg(I)).value_or(PT_Ptr)));
4037 
4038       if (!this->emitCallVirt(Func, VarArgSize, E))
4039         return false;
4040     } else if (Func->isVariadic()) {
4041       uint32_t VarArgSize = 0;
4042       unsigned NumParams =
4043           Func->getNumWrittenParams() + isa<CXXOperatorCallExpr>(E);
4044       for (unsigned I = NumParams, N = E->getNumArgs(); I != N; ++I)
4045         VarArgSize += align(primSize(classify(E->getArg(I)).value_or(PT_Ptr)));
4046       if (!this->emitCallVar(Func, VarArgSize, E))
4047         return false;
4048     } else {
4049       if (!this->emitCall(Func, 0, E))
4050         return false;
4051     }
4052   } else {
4053     // Indirect call. Visit the callee, which will leave a FunctionPointer on
4054     // the stack. Cleanup of the returned value if necessary will be done after
4055     // the function call completed.
4056 
4057     // Sum the size of all args from the call expr.
4058     uint32_t ArgSize = 0;
4059     for (unsigned I = 0, N = E->getNumArgs(); I != N; ++I)
4060       ArgSize += align(primSize(classify(E->getArg(I)).value_or(PT_Ptr)));
4061 
4062     // Get the callee, either from a member pointer saved in CalleeOffset,
4063     // or by just visiting the Callee expr.
4064     if (CalleeOffset) {
4065       if (!this->emitGetLocal(PT_MemberPtr, *CalleeOffset, E))
4066         return false;
4067       if (!this->emitGetMemberPtrDecl(E))
4068         return false;
4069       if (!this->emitCallPtr(ArgSize, E, E))
4070         return false;
4071     } else {
4072       if (!this->visit(E->getCallee()))
4073         return false;
4074 
4075       if (!this->emitCallPtr(ArgSize, E, E))
4076         return false;
4077     }
4078   }
4079 
4080   // Cleanup for discarded return values.
4081   if (DiscardResult && !ReturnType->isVoidType() && T)
4082     return this->emitPop(*T, E);
4083 
4084   return true;
4085 }
4086 
4087 template <class Emitter>
4088 bool Compiler<Emitter>::VisitCXXDefaultInitExpr(const CXXDefaultInitExpr *E) {
4089   SourceLocScope<Emitter> SLS(this, E);
4090 
4091   return this->delegate(E->getExpr());
4092 }
4093 
4094 template <class Emitter>
4095 bool Compiler<Emitter>::VisitCXXDefaultArgExpr(const CXXDefaultArgExpr *E) {
4096   SourceLocScope<Emitter> SLS(this, E);
4097 
4098   const Expr *SubExpr = E->getExpr();
4099   if (std::optional<PrimType> T = classify(E->getExpr()))
4100     return this->visit(SubExpr);
4101 
4102   assert(Initializing);
4103   return this->visitInitializer(SubExpr);
4104 }
4105 
4106 template <class Emitter>
4107 bool Compiler<Emitter>::VisitCXXBoolLiteralExpr(const CXXBoolLiteralExpr *E) {
4108   if (DiscardResult)
4109     return true;
4110 
4111   return this->emitConstBool(E->getValue(), E);
4112 }
4113 
4114 template <class Emitter>
4115 bool Compiler<Emitter>::VisitCXXNullPtrLiteralExpr(
4116     const CXXNullPtrLiteralExpr *E) {
4117   if (DiscardResult)
4118     return true;
4119 
4120   return this->emitNullPtr(nullptr, E);
4121 }
4122 
4123 template <class Emitter>
4124 bool Compiler<Emitter>::VisitGNUNullExpr(const GNUNullExpr *E) {
4125   if (DiscardResult)
4126     return true;
4127 
4128   assert(E->getType()->isIntegerType());
4129 
4130   PrimType T = classifyPrim(E->getType());
4131   return this->emitZero(T, E);
4132 }
4133 
4134 template <class Emitter>
4135 bool Compiler<Emitter>::VisitCXXThisExpr(const CXXThisExpr *E) {
4136   if (DiscardResult)
4137     return true;
4138 
4139   if (this->LambdaThisCapture.Offset > 0) {
4140     if (this->LambdaThisCapture.IsPtr)
4141       return this->emitGetThisFieldPtr(this->LambdaThisCapture.Offset, E);
4142     return this->emitGetPtrThisField(this->LambdaThisCapture.Offset, E);
4143   }
4144 
4145   // In some circumstances, the 'this' pointer does not actually refer to the
4146   // instance pointer of the current function frame, but e.g. to the declaration
4147   // currently being initialized. Here we emit the necessary instruction(s) for
4148   // this scenario.
4149   if (!InitStackActive || !E->isImplicit())
4150     return this->emitThis(E);
4151 
4152   if (InitStackActive && !InitStack.empty()) {
4153     unsigned StartIndex = 0;
4154     for (StartIndex = InitStack.size() - 1; StartIndex > 0; --StartIndex) {
4155       if (InitStack[StartIndex].Kind != InitLink::K_Field)
4156         break;
4157     }
4158 
4159     for (unsigned I = StartIndex, N = InitStack.size(); I != N; ++I) {
4160       if (!InitStack[I].template emit<Emitter>(this, E))
4161         return false;
4162     }
4163     return true;
4164   }
4165   return this->emitThis(E);
4166 }
4167 
4168 template <class Emitter> bool Compiler<Emitter>::visitStmt(const Stmt *S) {
4169   switch (S->getStmtClass()) {
4170   case Stmt::CompoundStmtClass:
4171     return visitCompoundStmt(cast<CompoundStmt>(S));
4172   case Stmt::DeclStmtClass:
4173     return visitDeclStmt(cast<DeclStmt>(S));
4174   case Stmt::ReturnStmtClass:
4175     return visitReturnStmt(cast<ReturnStmt>(S));
4176   case Stmt::IfStmtClass:
4177     return visitIfStmt(cast<IfStmt>(S));
4178   case Stmt::WhileStmtClass:
4179     return visitWhileStmt(cast<WhileStmt>(S));
4180   case Stmt::DoStmtClass:
4181     return visitDoStmt(cast<DoStmt>(S));
4182   case Stmt::ForStmtClass:
4183     return visitForStmt(cast<ForStmt>(S));
4184   case Stmt::CXXForRangeStmtClass:
4185     return visitCXXForRangeStmt(cast<CXXForRangeStmt>(S));
4186   case Stmt::BreakStmtClass:
4187     return visitBreakStmt(cast<BreakStmt>(S));
4188   case Stmt::ContinueStmtClass:
4189     return visitContinueStmt(cast<ContinueStmt>(S));
4190   case Stmt::SwitchStmtClass:
4191     return visitSwitchStmt(cast<SwitchStmt>(S));
4192   case Stmt::CaseStmtClass:
4193     return visitCaseStmt(cast<CaseStmt>(S));
4194   case Stmt::DefaultStmtClass:
4195     return visitDefaultStmt(cast<DefaultStmt>(S));
4196   case Stmt::AttributedStmtClass:
4197     return visitAttributedStmt(cast<AttributedStmt>(S));
4198   case Stmt::CXXTryStmtClass:
4199     return visitCXXTryStmt(cast<CXXTryStmt>(S));
4200   case Stmt::NullStmtClass:
4201     return true;
4202   // Always invalid statements.
4203   case Stmt::GCCAsmStmtClass:
4204   case Stmt::MSAsmStmtClass:
4205   case Stmt::GotoStmtClass:
4206     return this->emitInvalid(S);
4207   case Stmt::LabelStmtClass:
4208     return this->visitStmt(cast<LabelStmt>(S)->getSubStmt());
4209   default: {
4210     if (const auto *E = dyn_cast<Expr>(S))
4211       return this->discard(E);
4212     return false;
4213   }
4214   }
4215 }
4216 
4217 /// Visits the given statment without creating a variable
4218 /// scope for it in case it is a compound statement.
4219 template <class Emitter> bool Compiler<Emitter>::visitLoopBody(const Stmt *S) {
4220   if (isa<NullStmt>(S))
4221     return true;
4222 
4223   if (const auto *CS = dyn_cast<CompoundStmt>(S)) {
4224     for (const auto *InnerStmt : CS->body())
4225       if (!visitStmt(InnerStmt))
4226         return false;
4227     return true;
4228   }
4229 
4230   return this->visitStmt(S);
4231 }
4232 
4233 template <class Emitter>
4234 bool Compiler<Emitter>::visitCompoundStmt(const CompoundStmt *S) {
4235   BlockScope<Emitter> Scope(this);
4236   for (const auto *InnerStmt : S->body())
4237     if (!visitStmt(InnerStmt))
4238       return false;
4239   return Scope.destroyLocals();
4240 }
4241 
4242 template <class Emitter>
4243 bool Compiler<Emitter>::visitDeclStmt(const DeclStmt *DS) {
4244   for (const auto *D : DS->decls()) {
4245     if (isa<StaticAssertDecl, TagDecl, TypedefNameDecl, UsingEnumDecl,
4246             FunctionDecl>(D))
4247       continue;
4248 
4249     const auto *VD = dyn_cast<VarDecl>(D);
4250     if (!VD)
4251       return false;
4252     if (!this->visitVarDecl(VD))
4253       return false;
4254   }
4255 
4256   return true;
4257 }
4258 
4259 template <class Emitter>
4260 bool Compiler<Emitter>::visitReturnStmt(const ReturnStmt *RS) {
4261   if (this->InStmtExpr)
4262     return this->emitUnsupported(RS);
4263 
4264   if (const Expr *RE = RS->getRetValue()) {
4265     LocalScope<Emitter> RetScope(this);
4266     if (ReturnType) {
4267       // Primitive types are simply returned.
4268       if (!this->visit(RE))
4269         return false;
4270       this->emitCleanup();
4271       return this->emitRet(*ReturnType, RS);
4272     } else if (RE->getType()->isVoidType()) {
4273       if (!this->visit(RE))
4274         return false;
4275     } else {
4276       // RVO - construct the value in the return location.
4277       if (!this->emitRVOPtr(RE))
4278         return false;
4279       if (!this->visitInitializer(RE))
4280         return false;
4281       if (!this->emitPopPtr(RE))
4282         return false;
4283 
4284       this->emitCleanup();
4285       return this->emitRetVoid(RS);
4286     }
4287   }
4288 
4289   // Void return.
4290   this->emitCleanup();
4291   return this->emitRetVoid(RS);
4292 }
4293 
4294 template <class Emitter> bool Compiler<Emitter>::visitIfStmt(const IfStmt *IS) {
4295   BlockScope<Emitter> IfScope(this);
4296 
4297   if (IS->isNonNegatedConsteval())
4298     return visitStmt(IS->getThen());
4299   if (IS->isNegatedConsteval())
4300     return IS->getElse() ? visitStmt(IS->getElse()) : true;
4301 
4302   if (auto *CondInit = IS->getInit())
4303     if (!visitStmt(CondInit))
4304       return false;
4305 
4306   if (const DeclStmt *CondDecl = IS->getConditionVariableDeclStmt())
4307     if (!visitDeclStmt(CondDecl))
4308       return false;
4309 
4310   if (!this->visitBool(IS->getCond()))
4311     return false;
4312 
4313   if (const Stmt *Else = IS->getElse()) {
4314     LabelTy LabelElse = this->getLabel();
4315     LabelTy LabelEnd = this->getLabel();
4316     if (!this->jumpFalse(LabelElse))
4317       return false;
4318     if (!visitStmt(IS->getThen()))
4319       return false;
4320     if (!this->jump(LabelEnd))
4321       return false;
4322     this->emitLabel(LabelElse);
4323     if (!visitStmt(Else))
4324       return false;
4325     this->emitLabel(LabelEnd);
4326   } else {
4327     LabelTy LabelEnd = this->getLabel();
4328     if (!this->jumpFalse(LabelEnd))
4329       return false;
4330     if (!visitStmt(IS->getThen()))
4331       return false;
4332     this->emitLabel(LabelEnd);
4333   }
4334 
4335   return IfScope.destroyLocals();
4336 }
4337 
4338 template <class Emitter>
4339 bool Compiler<Emitter>::visitWhileStmt(const WhileStmt *S) {
4340   const Expr *Cond = S->getCond();
4341   const Stmt *Body = S->getBody();
4342 
4343   LabelTy CondLabel = this->getLabel(); // Label before the condition.
4344   LabelTy EndLabel = this->getLabel();  // Label after the loop.
4345   LoopScope<Emitter> LS(this, EndLabel, CondLabel);
4346 
4347   this->fallthrough(CondLabel);
4348   this->emitLabel(CondLabel);
4349 
4350   if (const DeclStmt *CondDecl = S->getConditionVariableDeclStmt())
4351     if (!visitDeclStmt(CondDecl))
4352       return false;
4353 
4354   if (!this->visitBool(Cond))
4355     return false;
4356   if (!this->jumpFalse(EndLabel))
4357     return false;
4358 
4359   LocalScope<Emitter> Scope(this);
4360   {
4361     DestructorScope<Emitter> DS(Scope);
4362     if (!this->visitLoopBody(Body))
4363       return false;
4364   }
4365 
4366   if (!this->jump(CondLabel))
4367     return false;
4368   this->emitLabel(EndLabel);
4369 
4370   return true;
4371 }
4372 
4373 template <class Emitter> bool Compiler<Emitter>::visitDoStmt(const DoStmt *S) {
4374   const Expr *Cond = S->getCond();
4375   const Stmt *Body = S->getBody();
4376 
4377   LabelTy StartLabel = this->getLabel();
4378   LabelTy EndLabel = this->getLabel();
4379   LabelTy CondLabel = this->getLabel();
4380   LoopScope<Emitter> LS(this, EndLabel, CondLabel);
4381   LocalScope<Emitter> Scope(this);
4382 
4383   this->fallthrough(StartLabel);
4384   this->emitLabel(StartLabel);
4385   {
4386     DestructorScope<Emitter> DS(Scope);
4387 
4388     if (!this->visitLoopBody(Body))
4389       return false;
4390     this->fallthrough(CondLabel);
4391     this->emitLabel(CondLabel);
4392     if (!this->visitBool(Cond))
4393       return false;
4394   }
4395   if (!this->jumpTrue(StartLabel))
4396     return false;
4397 
4398   this->fallthrough(EndLabel);
4399   this->emitLabel(EndLabel);
4400   return true;
4401 }
4402 
4403 template <class Emitter>
4404 bool Compiler<Emitter>::visitForStmt(const ForStmt *S) {
4405   // for (Init; Cond; Inc) { Body }
4406   const Stmt *Init = S->getInit();
4407   const Expr *Cond = S->getCond();
4408   const Expr *Inc = S->getInc();
4409   const Stmt *Body = S->getBody();
4410 
4411   LabelTy EndLabel = this->getLabel();
4412   LabelTy CondLabel = this->getLabel();
4413   LabelTy IncLabel = this->getLabel();
4414   LoopScope<Emitter> LS(this, EndLabel, IncLabel);
4415   LocalScope<Emitter> Scope(this);
4416 
4417   if (Init && !this->visitStmt(Init))
4418     return false;
4419   this->fallthrough(CondLabel);
4420   this->emitLabel(CondLabel);
4421 
4422   if (const DeclStmt *CondDecl = S->getConditionVariableDeclStmt())
4423     if (!visitDeclStmt(CondDecl))
4424       return false;
4425 
4426   if (Cond) {
4427     if (!this->visitBool(Cond))
4428       return false;
4429     if (!this->jumpFalse(EndLabel))
4430       return false;
4431   }
4432 
4433   {
4434     DestructorScope<Emitter> DS(Scope);
4435 
4436     if (Body && !this->visitLoopBody(Body))
4437       return false;
4438     this->fallthrough(IncLabel);
4439     this->emitLabel(IncLabel);
4440     if (Inc && !this->discard(Inc))
4441       return false;
4442   }
4443 
4444   if (!this->jump(CondLabel))
4445     return false;
4446   this->fallthrough(EndLabel);
4447   this->emitLabel(EndLabel);
4448   return true;
4449 }
4450 
4451 template <class Emitter>
4452 bool Compiler<Emitter>::visitCXXForRangeStmt(const CXXForRangeStmt *S) {
4453   const Stmt *Init = S->getInit();
4454   const Expr *Cond = S->getCond();
4455   const Expr *Inc = S->getInc();
4456   const Stmt *Body = S->getBody();
4457   const Stmt *BeginStmt = S->getBeginStmt();
4458   const Stmt *RangeStmt = S->getRangeStmt();
4459   const Stmt *EndStmt = S->getEndStmt();
4460   const VarDecl *LoopVar = S->getLoopVariable();
4461 
4462   LabelTy EndLabel = this->getLabel();
4463   LabelTy CondLabel = this->getLabel();
4464   LabelTy IncLabel = this->getLabel();
4465   LoopScope<Emitter> LS(this, EndLabel, IncLabel);
4466 
4467   // Emit declarations needed in the loop.
4468   if (Init && !this->visitStmt(Init))
4469     return false;
4470   if (!this->visitStmt(RangeStmt))
4471     return false;
4472   if (!this->visitStmt(BeginStmt))
4473     return false;
4474   if (!this->visitStmt(EndStmt))
4475     return false;
4476 
4477   // Now the condition as well as the loop variable assignment.
4478   this->fallthrough(CondLabel);
4479   this->emitLabel(CondLabel);
4480   if (!this->visitBool(Cond))
4481     return false;
4482   if (!this->jumpFalse(EndLabel))
4483     return false;
4484 
4485   if (!this->visitVarDecl(LoopVar))
4486     return false;
4487 
4488   // Body.
4489   LocalScope<Emitter> Scope(this);
4490   {
4491     DestructorScope<Emitter> DS(Scope);
4492 
4493     if (!this->visitLoopBody(Body))
4494       return false;
4495   this->fallthrough(IncLabel);
4496     this->emitLabel(IncLabel);
4497     if (!this->discard(Inc))
4498       return false;
4499   }
4500 
4501   if (!this->jump(CondLabel))
4502     return false;
4503 
4504   this->fallthrough(EndLabel);
4505   this->emitLabel(EndLabel);
4506   return true;
4507 }
4508 
4509 template <class Emitter>
4510 bool Compiler<Emitter>::visitBreakStmt(const BreakStmt *S) {
4511   if (!BreakLabel)
4512     return false;
4513 
4514   this->VarScope->emitDestructors();
4515   return this->jump(*BreakLabel);
4516 }
4517 
4518 template <class Emitter>
4519 bool Compiler<Emitter>::visitContinueStmt(const ContinueStmt *S) {
4520   if (!ContinueLabel)
4521     return false;
4522 
4523   this->VarScope->emitDestructors();
4524   return this->jump(*ContinueLabel);
4525 }
4526 
4527 template <class Emitter>
4528 bool Compiler<Emitter>::visitSwitchStmt(const SwitchStmt *S) {
4529   const Expr *Cond = S->getCond();
4530   PrimType CondT = this->classifyPrim(Cond->getType());
4531 
4532   LabelTy EndLabel = this->getLabel();
4533   OptLabelTy DefaultLabel = std::nullopt;
4534   unsigned CondVar = this->allocateLocalPrimitive(Cond, CondT, true, false);
4535 
4536   if (const auto *CondInit = S->getInit())
4537     if (!visitStmt(CondInit))
4538       return false;
4539 
4540   if (const DeclStmt *CondDecl = S->getConditionVariableDeclStmt())
4541     if (!visitDeclStmt(CondDecl))
4542       return false;
4543 
4544   // Initialize condition variable.
4545   if (!this->visit(Cond))
4546     return false;
4547   if (!this->emitSetLocal(CondT, CondVar, S))
4548     return false;
4549 
4550   CaseMap CaseLabels;
4551   // Create labels and comparison ops for all case statements.
4552   for (const SwitchCase *SC = S->getSwitchCaseList(); SC;
4553        SC = SC->getNextSwitchCase()) {
4554     if (const auto *CS = dyn_cast<CaseStmt>(SC)) {
4555       // FIXME: Implement ranges.
4556       if (CS->caseStmtIsGNURange())
4557         return false;
4558       CaseLabels[SC] = this->getLabel();
4559 
4560       const Expr *Value = CS->getLHS();
4561       PrimType ValueT = this->classifyPrim(Value->getType());
4562 
4563       // Compare the case statement's value to the switch condition.
4564       if (!this->emitGetLocal(CondT, CondVar, CS))
4565         return false;
4566       if (!this->visit(Value))
4567         return false;
4568 
4569       // Compare and jump to the case label.
4570       if (!this->emitEQ(ValueT, S))
4571         return false;
4572       if (!this->jumpTrue(CaseLabels[CS]))
4573         return false;
4574     } else {
4575       assert(!DefaultLabel);
4576       DefaultLabel = this->getLabel();
4577     }
4578   }
4579 
4580   // If none of the conditions above were true, fall through to the default
4581   // statement or jump after the switch statement.
4582   if (DefaultLabel) {
4583     if (!this->jump(*DefaultLabel))
4584       return false;
4585   } else {
4586     if (!this->jump(EndLabel))
4587       return false;
4588   }
4589 
4590   SwitchScope<Emitter> SS(this, std::move(CaseLabels), EndLabel, DefaultLabel);
4591   if (!this->visitStmt(S->getBody()))
4592     return false;
4593   this->emitLabel(EndLabel);
4594   return true;
4595 }
4596 
4597 template <class Emitter>
4598 bool Compiler<Emitter>::visitCaseStmt(const CaseStmt *S) {
4599   this->emitLabel(CaseLabels[S]);
4600   return this->visitStmt(S->getSubStmt());
4601 }
4602 
4603 template <class Emitter>
4604 bool Compiler<Emitter>::visitDefaultStmt(const DefaultStmt *S) {
4605   this->emitLabel(*DefaultLabel);
4606   return this->visitStmt(S->getSubStmt());
4607 }
4608 
4609 template <class Emitter>
4610 bool Compiler<Emitter>::visitAttributedStmt(const AttributedStmt *S) {
4611   if (this->Ctx.getLangOpts().CXXAssumptions &&
4612       !this->Ctx.getLangOpts().MSVCCompat) {
4613     for (const Attr *A : S->getAttrs()) {
4614       auto *AA = dyn_cast<CXXAssumeAttr>(A);
4615       if (!AA)
4616         continue;
4617 
4618       assert(isa<NullStmt>(S->getSubStmt()));
4619 
4620       const Expr *Assumption = AA->getAssumption();
4621       if (Assumption->isValueDependent())
4622         return false;
4623 
4624       if (Assumption->HasSideEffects(this->Ctx.getASTContext()))
4625         continue;
4626 
4627       // Evaluate assumption.
4628       if (!this->visitBool(Assumption))
4629         return false;
4630 
4631       if (!this->emitAssume(Assumption))
4632         return false;
4633     }
4634   }
4635 
4636   // Ignore other attributes.
4637   return this->visitStmt(S->getSubStmt());
4638 }
4639 
4640 template <class Emitter>
4641 bool Compiler<Emitter>::visitCXXTryStmt(const CXXTryStmt *S) {
4642   // Ignore all handlers.
4643   return this->visitStmt(S->getTryBlock());
4644 }
4645 
4646 template <class Emitter>
4647 bool Compiler<Emitter>::emitLambdaStaticInvokerBody(const CXXMethodDecl *MD) {
4648   assert(MD->isLambdaStaticInvoker());
4649   assert(MD->hasBody());
4650   assert(cast<CompoundStmt>(MD->getBody())->body_empty());
4651 
4652   const CXXRecordDecl *ClosureClass = MD->getParent();
4653   const CXXMethodDecl *LambdaCallOp = ClosureClass->getLambdaCallOperator();
4654   assert(ClosureClass->captures_begin() == ClosureClass->captures_end());
4655   const Function *Func = this->getFunction(LambdaCallOp);
4656   if (!Func)
4657     return false;
4658   assert(Func->hasThisPointer());
4659   assert(Func->getNumParams() == (MD->getNumParams() + 1 + Func->hasRVO()));
4660 
4661   if (Func->hasRVO()) {
4662     if (!this->emitRVOPtr(MD))
4663       return false;
4664   }
4665 
4666   // The lambda call operator needs an instance pointer, but we don't have
4667   // one here, and we don't need one either because the lambda cannot have
4668   // any captures, as verified above. Emit a null pointer. This is then
4669   // special-cased when interpreting to not emit any misleading diagnostics.
4670   if (!this->emitNullPtr(nullptr, MD))
4671     return false;
4672 
4673   // Forward all arguments from the static invoker to the lambda call operator.
4674   for (const ParmVarDecl *PVD : MD->parameters()) {
4675     auto It = this->Params.find(PVD);
4676     assert(It != this->Params.end());
4677 
4678     // We do the lvalue-to-rvalue conversion manually here, so no need
4679     // to care about references.
4680     PrimType ParamType = this->classify(PVD->getType()).value_or(PT_Ptr);
4681     if (!this->emitGetParam(ParamType, It->second.Offset, MD))
4682       return false;
4683   }
4684 
4685   if (!this->emitCall(Func, 0, LambdaCallOp))
4686     return false;
4687 
4688   this->emitCleanup();
4689   if (ReturnType)
4690     return this->emitRet(*ReturnType, MD);
4691 
4692   // Nothing to do, since we emitted the RVO pointer above.
4693   return this->emitRetVoid(MD);
4694 }
4695 
4696 template <class Emitter>
4697 bool Compiler<Emitter>::visitFunc(const FunctionDecl *F) {
4698   // Classify the return type.
4699   ReturnType = this->classify(F->getReturnType());
4700 
4701   auto emitFieldInitializer = [&](const Record::Field *F, unsigned FieldOffset,
4702                                   const Expr *InitExpr) -> bool {
4703     // We don't know what to do with these, so just return false.
4704     if (InitExpr->getType().isNull())
4705       return false;
4706 
4707     if (std::optional<PrimType> T = this->classify(InitExpr)) {
4708       if (!this->visit(InitExpr))
4709         return false;
4710 
4711       if (F->isBitField())
4712         return this->emitInitThisBitField(*T, F, FieldOffset, InitExpr);
4713       return this->emitInitThisField(*T, FieldOffset, InitExpr);
4714     }
4715     // Non-primitive case. Get a pointer to the field-to-initialize
4716     // on the stack and call visitInitialzer() for it.
4717     InitLinkScope<Emitter> FieldScope(this, InitLink::Field(F->Offset));
4718     if (!this->emitGetPtrThisField(FieldOffset, InitExpr))
4719       return false;
4720 
4721     if (!this->visitInitializer(InitExpr))
4722       return false;
4723 
4724     return this->emitPopPtr(InitExpr);
4725   };
4726 
4727   // Emit custom code if this is a lambda static invoker.
4728   if (const auto *MD = dyn_cast<CXXMethodDecl>(F);
4729       MD && MD->isLambdaStaticInvoker())
4730     return this->emitLambdaStaticInvokerBody(MD);
4731 
4732   // Constructor. Set up field initializers.
4733   if (const auto *Ctor = dyn_cast<CXXConstructorDecl>(F)) {
4734     const RecordDecl *RD = Ctor->getParent();
4735     const Record *R = this->getRecord(RD);
4736     if (!R)
4737       return false;
4738 
4739     InitLinkScope<Emitter> InitScope(this, InitLink::This());
4740     for (const auto *Init : Ctor->inits()) {
4741       // Scope needed for the initializers.
4742       BlockScope<Emitter> Scope(this);
4743 
4744       const Expr *InitExpr = Init->getInit();
4745       if (const FieldDecl *Member = Init->getMember()) {
4746         const Record::Field *F = R->getField(Member);
4747 
4748         if (!emitFieldInitializer(F, F->Offset, InitExpr))
4749           return false;
4750       } else if (const Type *Base = Init->getBaseClass()) {
4751         const auto *BaseDecl = Base->getAsCXXRecordDecl();
4752         assert(BaseDecl);
4753 
4754         if (Init->isBaseVirtual()) {
4755           assert(R->getVirtualBase(BaseDecl));
4756           if (!this->emitGetPtrThisVirtBase(BaseDecl, InitExpr))
4757             return false;
4758 
4759         } else {
4760           // Base class initializer.
4761           // Get This Base and call initializer on it.
4762           const Record::Base *B = R->getBase(BaseDecl);
4763           assert(B);
4764           if (!this->emitGetPtrThisBase(B->Offset, InitExpr))
4765             return false;
4766         }
4767 
4768         if (!this->visitInitializer(InitExpr))
4769           return false;
4770         if (!this->emitFinishInitPop(InitExpr))
4771           return false;
4772       } else if (const IndirectFieldDecl *IFD = Init->getIndirectMember()) {
4773         assert(IFD->getChainingSize() >= 2);
4774 
4775         unsigned NestedFieldOffset = 0;
4776         const Record::Field *NestedField = nullptr;
4777         for (const NamedDecl *ND : IFD->chain()) {
4778           const auto *FD = cast<FieldDecl>(ND);
4779           const Record *FieldRecord =
4780               this->P.getOrCreateRecord(FD->getParent());
4781           assert(FieldRecord);
4782 
4783           NestedField = FieldRecord->getField(FD);
4784           assert(NestedField);
4785 
4786           NestedFieldOffset += NestedField->Offset;
4787         }
4788         assert(NestedField);
4789 
4790         if (!emitFieldInitializer(NestedField, NestedFieldOffset, InitExpr))
4791           return false;
4792       } else {
4793         assert(Init->isDelegatingInitializer());
4794         if (!this->emitThis(InitExpr))
4795           return false;
4796         if (!this->visitInitializer(Init->getInit()))
4797           return false;
4798         if (!this->emitPopPtr(InitExpr))
4799           return false;
4800       }
4801 
4802       if (!Scope.destroyLocals())
4803         return false;
4804     }
4805   }
4806 
4807   if (const auto *Body = F->getBody())
4808     if (!visitStmt(Body))
4809       return false;
4810 
4811   // Emit a guard return to protect against a code path missing one.
4812   if (F->getReturnType()->isVoidType())
4813     return this->emitRetVoid(SourceInfo{});
4814   return this->emitNoRet(SourceInfo{});
4815 }
4816 
4817 template <class Emitter>
4818 bool Compiler<Emitter>::VisitUnaryOperator(const UnaryOperator *E) {
4819   const Expr *SubExpr = E->getSubExpr();
4820   if (SubExpr->getType()->isAnyComplexType())
4821     return this->VisitComplexUnaryOperator(E);
4822   std::optional<PrimType> T = classify(SubExpr->getType());
4823 
4824   switch (E->getOpcode()) {
4825   case UO_PostInc: { // x++
4826     if (!Ctx.getLangOpts().CPlusPlus14)
4827       return this->emitInvalid(E);
4828     if (!T)
4829       return this->emitError(E);
4830 
4831     if (!this->visit(SubExpr))
4832       return false;
4833 
4834     if (T == PT_Ptr || T == PT_FnPtr) {
4835       if (!this->emitIncPtr(E))
4836         return false;
4837 
4838       return DiscardResult ? this->emitPopPtr(E) : true;
4839     }
4840 
4841     if (T == PT_Float) {
4842       return DiscardResult ? this->emitIncfPop(getRoundingMode(E), E)
4843                            : this->emitIncf(getRoundingMode(E), E);
4844     }
4845 
4846     return DiscardResult ? this->emitIncPop(*T, E) : this->emitInc(*T, E);
4847   }
4848   case UO_PostDec: { // x--
4849     if (!Ctx.getLangOpts().CPlusPlus14)
4850       return this->emitInvalid(E);
4851     if (!T)
4852       return this->emitError(E);
4853 
4854     if (!this->visit(SubExpr))
4855       return false;
4856 
4857     if (T == PT_Ptr || T == PT_FnPtr) {
4858       if (!this->emitDecPtr(E))
4859         return false;
4860 
4861       return DiscardResult ? this->emitPopPtr(E) : true;
4862     }
4863 
4864     if (T == PT_Float) {
4865       return DiscardResult ? this->emitDecfPop(getRoundingMode(E), E)
4866                            : this->emitDecf(getRoundingMode(E), E);
4867     }
4868 
4869     return DiscardResult ? this->emitDecPop(*T, E) : this->emitDec(*T, E);
4870   }
4871   case UO_PreInc: { // ++x
4872     if (!Ctx.getLangOpts().CPlusPlus14)
4873       return this->emitInvalid(E);
4874     if (!T)
4875       return this->emitError(E);
4876 
4877     if (!this->visit(SubExpr))
4878       return false;
4879 
4880     if (T == PT_Ptr || T == PT_FnPtr) {
4881       if (!this->emitLoadPtr(E))
4882         return false;
4883       if (!this->emitConstUint8(1, E))
4884         return false;
4885       if (!this->emitAddOffsetUint8(E))
4886         return false;
4887       return DiscardResult ? this->emitStorePopPtr(E) : this->emitStorePtr(E);
4888     }
4889 
4890     // Post-inc and pre-inc are the same if the value is to be discarded.
4891     if (DiscardResult) {
4892       if (T == PT_Float)
4893         return this->emitIncfPop(getRoundingMode(E), E);
4894       return this->emitIncPop(*T, E);
4895     }
4896 
4897     if (T == PT_Float) {
4898       const auto &TargetSemantics = Ctx.getFloatSemantics(E->getType());
4899       if (!this->emitLoadFloat(E))
4900         return false;
4901       if (!this->emitConstFloat(llvm::APFloat(TargetSemantics, 1), E))
4902         return false;
4903       if (!this->emitAddf(getRoundingMode(E), E))
4904         return false;
4905       if (!this->emitStoreFloat(E))
4906         return false;
4907     } else {
4908       assert(isIntegralType(*T));
4909       if (!this->emitLoad(*T, E))
4910         return false;
4911       if (!this->emitConst(1, E))
4912         return false;
4913       if (!this->emitAdd(*T, E))
4914         return false;
4915       if (!this->emitStore(*T, E))
4916         return false;
4917     }
4918     return E->isGLValue() || this->emitLoadPop(*T, E);
4919   }
4920   case UO_PreDec: { // --x
4921     if (!Ctx.getLangOpts().CPlusPlus14)
4922       return this->emitInvalid(E);
4923     if (!T)
4924       return this->emitError(E);
4925 
4926     if (!this->visit(SubExpr))
4927       return false;
4928 
4929     if (T == PT_Ptr || T == PT_FnPtr) {
4930       if (!this->emitLoadPtr(E))
4931         return false;
4932       if (!this->emitConstUint8(1, E))
4933         return false;
4934       if (!this->emitSubOffsetUint8(E))
4935         return false;
4936       return DiscardResult ? this->emitStorePopPtr(E) : this->emitStorePtr(E);
4937     }
4938 
4939     // Post-dec and pre-dec are the same if the value is to be discarded.
4940     if (DiscardResult) {
4941       if (T == PT_Float)
4942         return this->emitDecfPop(getRoundingMode(E), E);
4943       return this->emitDecPop(*T, E);
4944     }
4945 
4946     if (T == PT_Float) {
4947       const auto &TargetSemantics = Ctx.getFloatSemantics(E->getType());
4948       if (!this->emitLoadFloat(E))
4949         return false;
4950       if (!this->emitConstFloat(llvm::APFloat(TargetSemantics, 1), E))
4951         return false;
4952       if (!this->emitSubf(getRoundingMode(E), E))
4953         return false;
4954       if (!this->emitStoreFloat(E))
4955         return false;
4956     } else {
4957       assert(isIntegralType(*T));
4958       if (!this->emitLoad(*T, E))
4959         return false;
4960       if (!this->emitConst(1, E))
4961         return false;
4962       if (!this->emitSub(*T, E))
4963         return false;
4964       if (!this->emitStore(*T, E))
4965         return false;
4966     }
4967     return E->isGLValue() || this->emitLoadPop(*T, E);
4968   }
4969   case UO_LNot: // !x
4970     if (!T)
4971       return this->emitError(E);
4972 
4973     if (DiscardResult)
4974       return this->discard(SubExpr);
4975 
4976     if (!this->visitBool(SubExpr))
4977       return false;
4978 
4979     if (!this->emitInvBool(E))
4980       return false;
4981 
4982     if (PrimType ET = classifyPrim(E->getType()); ET != PT_Bool)
4983       return this->emitCast(PT_Bool, ET, E);
4984     return true;
4985   case UO_Minus: // -x
4986     if (!T)
4987       return this->emitError(E);
4988 
4989     if (!this->visit(SubExpr))
4990       return false;
4991     return DiscardResult ? this->emitPop(*T, E) : this->emitNeg(*T, E);
4992   case UO_Plus:                // +x
4993     if (!T)
4994       return this->emitError(E);
4995 
4996     if (!this->visit(SubExpr)) // noop
4997       return false;
4998     return DiscardResult ? this->emitPop(*T, E) : true;
4999   case UO_AddrOf: // &x
5000     if (E->getType()->isMemberPointerType()) {
5001       // C++11 [expr.unary.op]p3 has very strict rules on how the address of a
5002       // member can be formed.
5003       return this->emitGetMemberPtr(cast<DeclRefExpr>(SubExpr)->getDecl(), E);
5004     }
5005     // We should already have a pointer when we get here.
5006     return this->delegate(SubExpr);
5007   case UO_Deref: // *x
5008     if (DiscardResult)
5009       return this->discard(SubExpr);
5010     return this->visit(SubExpr);
5011   case UO_Not: // ~x
5012     if (!T)
5013       return this->emitError(E);
5014 
5015     if (!this->visit(SubExpr))
5016       return false;
5017     return DiscardResult ? this->emitPop(*T, E) : this->emitComp(*T, E);
5018   case UO_Real: // __real x
5019     assert(T);
5020     return this->delegate(SubExpr);
5021   case UO_Imag: { // __imag x
5022     assert(T);
5023     if (!this->discard(SubExpr))
5024       return false;
5025     return this->visitZeroInitializer(*T, SubExpr->getType(), SubExpr);
5026   }
5027   case UO_Extension:
5028     return this->delegate(SubExpr);
5029   case UO_Coawait:
5030     assert(false && "Unhandled opcode");
5031   }
5032 
5033   return false;
5034 }
5035 
5036 template <class Emitter>
5037 bool Compiler<Emitter>::VisitComplexUnaryOperator(const UnaryOperator *E) {
5038   const Expr *SubExpr = E->getSubExpr();
5039   assert(SubExpr->getType()->isAnyComplexType());
5040 
5041   if (DiscardResult)
5042     return this->discard(SubExpr);
5043 
5044   std::optional<PrimType> ResT = classify(E);
5045   auto prepareResult = [=]() -> bool {
5046     if (!ResT && !Initializing) {
5047       std::optional<unsigned> LocalIndex = allocateLocal(SubExpr);
5048       if (!LocalIndex)
5049         return false;
5050       return this->emitGetPtrLocal(*LocalIndex, E);
5051     }
5052 
5053     return true;
5054   };
5055 
5056   // The offset of the temporary, if we created one.
5057   unsigned SubExprOffset = ~0u;
5058   auto createTemp = [=, &SubExprOffset]() -> bool {
5059     SubExprOffset = this->allocateLocalPrimitive(SubExpr, PT_Ptr, true, false);
5060     if (!this->visit(SubExpr))
5061       return false;
5062     return this->emitSetLocal(PT_Ptr, SubExprOffset, E);
5063   };
5064 
5065   PrimType ElemT = classifyComplexElementType(SubExpr->getType());
5066   auto getElem = [=](unsigned Offset, unsigned Index) -> bool {
5067     if (!this->emitGetLocal(PT_Ptr, Offset, E))
5068       return false;
5069     return this->emitArrayElemPop(ElemT, Index, E);
5070   };
5071 
5072   switch (E->getOpcode()) {
5073   case UO_Minus:
5074     if (!prepareResult())
5075       return false;
5076     if (!createTemp())
5077       return false;
5078     for (unsigned I = 0; I != 2; ++I) {
5079       if (!getElem(SubExprOffset, I))
5080         return false;
5081       if (!this->emitNeg(ElemT, E))
5082         return false;
5083       if (!this->emitInitElem(ElemT, I, E))
5084         return false;
5085     }
5086     break;
5087 
5088   case UO_Plus:   // +x
5089   case UO_AddrOf: // &x
5090   case UO_Deref:  // *x
5091     return this->delegate(SubExpr);
5092 
5093   case UO_LNot:
5094     if (!this->visit(SubExpr))
5095       return false;
5096     if (!this->emitComplexBoolCast(SubExpr))
5097       return false;
5098     if (!this->emitInvBool(E))
5099       return false;
5100     if (PrimType ET = classifyPrim(E->getType()); ET != PT_Bool)
5101       return this->emitCast(PT_Bool, ET, E);
5102     return true;
5103 
5104   case UO_Real:
5105     return this->emitComplexReal(SubExpr);
5106 
5107   case UO_Imag:
5108     if (!this->visit(SubExpr))
5109       return false;
5110 
5111     if (SubExpr->isLValue()) {
5112       if (!this->emitConstUint8(1, E))
5113         return false;
5114       return this->emitArrayElemPtrPopUint8(E);
5115     }
5116 
5117     // Since our _Complex implementation does not map to a primitive type,
5118     // we sometimes have to do the lvalue-to-rvalue conversion here manually.
5119     return this->emitArrayElemPop(classifyPrim(E->getType()), 1, E);
5120 
5121   case UO_Not: // ~x
5122     if (!this->visit(SubExpr))
5123       return false;
5124     // Negate the imaginary component.
5125     if (!this->emitArrayElem(ElemT, 1, E))
5126       return false;
5127     if (!this->emitNeg(ElemT, E))
5128       return false;
5129     if (!this->emitInitElem(ElemT, 1, E))
5130       return false;
5131     return DiscardResult ? this->emitPopPtr(E) : true;
5132 
5133   case UO_Extension:
5134     return this->delegate(SubExpr);
5135 
5136   default:
5137     return this->emitInvalid(E);
5138   }
5139 
5140   return true;
5141 }
5142 
5143 template <class Emitter>
5144 bool Compiler<Emitter>::visitDeclRef(const ValueDecl *D, const Expr *E) {
5145   if (DiscardResult)
5146     return true;
5147 
5148   if (const auto *ECD = dyn_cast<EnumConstantDecl>(D)) {
5149     return this->emitConst(ECD->getInitVal(), E);
5150   } else if (const auto *BD = dyn_cast<BindingDecl>(D)) {
5151     return this->visit(BD->getBinding());
5152   } else if (const auto *FuncDecl = dyn_cast<FunctionDecl>(D)) {
5153     const Function *F = getFunction(FuncDecl);
5154     return F && this->emitGetFnPtr(F, E);
5155   } else if (const auto *TPOD = dyn_cast<TemplateParamObjectDecl>(D)) {
5156     if (std::optional<unsigned> Index = P.getOrCreateGlobal(D)) {
5157       if (!this->emitGetPtrGlobal(*Index, E))
5158         return false;
5159       if (std::optional<PrimType> T = classify(E->getType())) {
5160         if (!this->visitAPValue(TPOD->getValue(), *T, E))
5161           return false;
5162         return this->emitInitGlobal(*T, *Index, E);
5163       }
5164       return this->visitAPValueInitializer(TPOD->getValue(), E);
5165     }
5166     return false;
5167   }
5168 
5169   // References are implemented via pointers, so when we see a DeclRefExpr
5170   // pointing to a reference, we need to get its value directly (i.e. the
5171   // pointer to the actual value) instead of a pointer to the pointer to the
5172   // value.
5173   bool IsReference = D->getType()->isReferenceType();
5174 
5175   // Check for local/global variables and parameters.
5176   if (auto It = Locals.find(D); It != Locals.end()) {
5177     const unsigned Offset = It->second.Offset;
5178     if (IsReference)
5179       return this->emitGetLocal(PT_Ptr, Offset, E);
5180     return this->emitGetPtrLocal(Offset, E);
5181   } else if (auto GlobalIndex = P.getGlobal(D)) {
5182     if (IsReference) {
5183       if (!Ctx.getLangOpts().CPlusPlus11)
5184         return this->emitGetGlobal(classifyPrim(E), *GlobalIndex, E);
5185       return this->emitGetGlobalUnchecked(classifyPrim(E), *GlobalIndex, E);
5186     }
5187 
5188     return this->emitGetPtrGlobal(*GlobalIndex, E);
5189   } else if (const auto *PVD = dyn_cast<ParmVarDecl>(D)) {
5190     if (auto It = this->Params.find(PVD); It != this->Params.end()) {
5191       if (IsReference || !It->second.IsPtr)
5192         return this->emitGetParam(classifyPrim(E), It->second.Offset, E);
5193 
5194       return this->emitGetPtrParam(It->second.Offset, E);
5195     }
5196   }
5197 
5198   // In case we need to re-visit a declaration.
5199   auto revisit = [&](const VarDecl *VD) -> bool {
5200     auto VarState = this->visitDecl(VD);
5201 
5202     if (VarState.notCreated())
5203       return true;
5204     if (!VarState)
5205       return false;
5206     // Retry.
5207     return this->visitDeclRef(D, E);
5208   };
5209 
5210   // Handle lambda captures.
5211   if (auto It = this->LambdaCaptures.find(D);
5212       It != this->LambdaCaptures.end()) {
5213     auto [Offset, IsPtr] = It->second;
5214 
5215     if (IsPtr)
5216       return this->emitGetThisFieldPtr(Offset, E);
5217     return this->emitGetPtrThisField(Offset, E);
5218   } else if (const auto *DRE = dyn_cast<DeclRefExpr>(E);
5219              DRE && DRE->refersToEnclosingVariableOrCapture()) {
5220     if (const auto *VD = dyn_cast<VarDecl>(D); VD && VD->isInitCapture())
5221       return revisit(VD);
5222   }
5223 
5224   if (D != InitializingDecl) {
5225     // Try to lazily visit (or emit dummy pointers for) declarations
5226     // we haven't seen yet.
5227     if (Ctx.getLangOpts().CPlusPlus) {
5228       if (const auto *VD = dyn_cast<VarDecl>(D)) {
5229         const auto typeShouldBeVisited = [&](QualType T) -> bool {
5230           if (T.isConstant(Ctx.getASTContext()))
5231             return true;
5232           if (const auto *RT = T->getAs<ReferenceType>())
5233             return RT->getPointeeType().isConstQualified();
5234           return false;
5235         };
5236 
5237         // Visit local const variables like normal.
5238         if ((VD->hasGlobalStorage() || VD->isLocalVarDecl() ||
5239              VD->isStaticDataMember()) &&
5240             typeShouldBeVisited(VD->getType()))
5241           return revisit(VD);
5242       }
5243     } else {
5244       if (const auto *VD = dyn_cast<VarDecl>(D);
5245           VD && VD->getAnyInitializer() &&
5246           VD->getType().isConstant(Ctx.getASTContext()) && !VD->isWeak())
5247         return revisit(VD);
5248     }
5249   }
5250 
5251   if (std::optional<unsigned> I = P.getOrCreateDummy(D)) {
5252     if (!this->emitGetPtrGlobal(*I, E))
5253       return false;
5254     if (E->getType()->isVoidType())
5255       return true;
5256     // Convert the dummy pointer to another pointer type if we have to.
5257     if (PrimType PT = classifyPrim(E); PT != PT_Ptr) {
5258       if (isPtrType(PT))
5259         return this->emitDecayPtr(PT_Ptr, PT, E);
5260       return false;
5261     }
5262     return true;
5263   }
5264 
5265   if (const auto *DRE = dyn_cast<DeclRefExpr>(E))
5266     return this->emitInvalidDeclRef(DRE, E);
5267   return false;
5268 }
5269 
5270 template <class Emitter>
5271 bool Compiler<Emitter>::VisitDeclRefExpr(const DeclRefExpr *E) {
5272   const auto *D = E->getDecl();
5273   return this->visitDeclRef(D, E);
5274 }
5275 
5276 template <class Emitter> void Compiler<Emitter>::emitCleanup() {
5277   for (VariableScope<Emitter> *C = VarScope; C; C = C->getParent())
5278     C->emitDestruction();
5279 }
5280 
5281 template <class Emitter>
5282 unsigned Compiler<Emitter>::collectBaseOffset(const QualType BaseType,
5283                                               const QualType DerivedType) {
5284   const auto extractRecordDecl = [](QualType Ty) -> const CXXRecordDecl * {
5285     if (const auto *PT = dyn_cast<PointerType>(Ty))
5286       return PT->getPointeeType()->getAsCXXRecordDecl();
5287     return Ty->getAsCXXRecordDecl();
5288   };
5289   const CXXRecordDecl *BaseDecl = extractRecordDecl(BaseType);
5290   const CXXRecordDecl *DerivedDecl = extractRecordDecl(DerivedType);
5291 
5292   return Ctx.collectBaseOffset(BaseDecl, DerivedDecl);
5293 }
5294 
5295 /// Emit casts from a PrimType to another PrimType.
5296 template <class Emitter>
5297 bool Compiler<Emitter>::emitPrimCast(PrimType FromT, PrimType ToT,
5298                                      QualType ToQT, const Expr *E) {
5299 
5300   if (FromT == PT_Float) {
5301     // Floating to floating.
5302     if (ToT == PT_Float) {
5303       const llvm::fltSemantics *ToSem = &Ctx.getFloatSemantics(ToQT);
5304       return this->emitCastFP(ToSem, getRoundingMode(E), E);
5305     }
5306 
5307     if (ToT == PT_IntAP)
5308       return this->emitCastFloatingIntegralAP(Ctx.getBitWidth(ToQT), E);
5309     if (ToT == PT_IntAPS)
5310       return this->emitCastFloatingIntegralAPS(Ctx.getBitWidth(ToQT), E);
5311 
5312     // Float to integral.
5313     if (isIntegralType(ToT) || ToT == PT_Bool)
5314       return this->emitCastFloatingIntegral(ToT, E);
5315   }
5316 
5317   if (isIntegralType(FromT) || FromT == PT_Bool) {
5318     if (ToT == PT_IntAP)
5319       return this->emitCastAP(FromT, Ctx.getBitWidth(ToQT), E);
5320     if (ToT == PT_IntAPS)
5321       return this->emitCastAPS(FromT, Ctx.getBitWidth(ToQT), E);
5322 
5323     // Integral to integral.
5324     if (isIntegralType(ToT) || ToT == PT_Bool)
5325       return FromT != ToT ? this->emitCast(FromT, ToT, E) : true;
5326 
5327     if (ToT == PT_Float) {
5328       // Integral to floating.
5329       const llvm::fltSemantics *ToSem = &Ctx.getFloatSemantics(ToQT);
5330       return this->emitCastIntegralFloating(FromT, ToSem, getRoundingMode(E),
5331                                             E);
5332     }
5333   }
5334 
5335   return false;
5336 }
5337 
5338 /// Emits __real(SubExpr)
5339 template <class Emitter>
5340 bool Compiler<Emitter>::emitComplexReal(const Expr *SubExpr) {
5341   assert(SubExpr->getType()->isAnyComplexType());
5342 
5343   if (DiscardResult)
5344     return this->discard(SubExpr);
5345 
5346   if (!this->visit(SubExpr))
5347     return false;
5348   if (SubExpr->isLValue()) {
5349     if (!this->emitConstUint8(0, SubExpr))
5350       return false;
5351     return this->emitArrayElemPtrPopUint8(SubExpr);
5352   }
5353 
5354   // Rvalue, load the actual element.
5355   return this->emitArrayElemPop(classifyComplexElementType(SubExpr->getType()),
5356                                 0, SubExpr);
5357 }
5358 
5359 template <class Emitter>
5360 bool Compiler<Emitter>::emitComplexBoolCast(const Expr *E) {
5361   assert(!DiscardResult);
5362   PrimType ElemT = classifyComplexElementType(E->getType());
5363   // We emit the expression (__real(E) != 0 || __imag(E) != 0)
5364   // for us, that means (bool)E[0] || (bool)E[1]
5365   if (!this->emitArrayElem(ElemT, 0, E))
5366     return false;
5367   if (ElemT == PT_Float) {
5368     if (!this->emitCastFloatingIntegral(PT_Bool, E))
5369       return false;
5370   } else {
5371     if (!this->emitCast(ElemT, PT_Bool, E))
5372       return false;
5373   }
5374 
5375   // We now have the bool value of E[0] on the stack.
5376   LabelTy LabelTrue = this->getLabel();
5377   if (!this->jumpTrue(LabelTrue))
5378     return false;
5379 
5380   if (!this->emitArrayElemPop(ElemT, 1, E))
5381     return false;
5382   if (ElemT == PT_Float) {
5383     if (!this->emitCastFloatingIntegral(PT_Bool, E))
5384       return false;
5385   } else {
5386     if (!this->emitCast(ElemT, PT_Bool, E))
5387       return false;
5388   }
5389   // Leave the boolean value of E[1] on the stack.
5390   LabelTy EndLabel = this->getLabel();
5391   this->jump(EndLabel);
5392 
5393   this->emitLabel(LabelTrue);
5394   if (!this->emitPopPtr(E))
5395     return false;
5396   if (!this->emitConstBool(true, E))
5397     return false;
5398 
5399   this->fallthrough(EndLabel);
5400   this->emitLabel(EndLabel);
5401 
5402   return true;
5403 }
5404 
5405 template <class Emitter>
5406 bool Compiler<Emitter>::emitComplexComparison(const Expr *LHS, const Expr *RHS,
5407                                               const BinaryOperator *E) {
5408   assert(E->isComparisonOp());
5409   assert(!Initializing);
5410   assert(!DiscardResult);
5411 
5412   PrimType ElemT;
5413   bool LHSIsComplex;
5414   unsigned LHSOffset;
5415   if (LHS->getType()->isAnyComplexType()) {
5416     LHSIsComplex = true;
5417     ElemT = classifyComplexElementType(LHS->getType());
5418     LHSOffset = allocateLocalPrimitive(LHS, PT_Ptr, /*IsConst=*/true,
5419                                        /*IsExtended=*/false);
5420     if (!this->visit(LHS))
5421       return false;
5422     if (!this->emitSetLocal(PT_Ptr, LHSOffset, E))
5423       return false;
5424   } else {
5425     LHSIsComplex = false;
5426     PrimType LHST = classifyPrim(LHS->getType());
5427     LHSOffset = this->allocateLocalPrimitive(LHS, LHST, true, false);
5428     if (!this->visit(LHS))
5429       return false;
5430     if (!this->emitSetLocal(LHST, LHSOffset, E))
5431       return false;
5432   }
5433 
5434   bool RHSIsComplex;
5435   unsigned RHSOffset;
5436   if (RHS->getType()->isAnyComplexType()) {
5437     RHSIsComplex = true;
5438     ElemT = classifyComplexElementType(RHS->getType());
5439     RHSOffset = allocateLocalPrimitive(RHS, PT_Ptr, /*IsConst=*/true,
5440                                        /*IsExtended=*/false);
5441     if (!this->visit(RHS))
5442       return false;
5443     if (!this->emitSetLocal(PT_Ptr, RHSOffset, E))
5444       return false;
5445   } else {
5446     RHSIsComplex = false;
5447     PrimType RHST = classifyPrim(RHS->getType());
5448     RHSOffset = this->allocateLocalPrimitive(RHS, RHST, true, false);
5449     if (!this->visit(RHS))
5450       return false;
5451     if (!this->emitSetLocal(RHST, RHSOffset, E))
5452       return false;
5453   }
5454 
5455   auto getElem = [&](unsigned LocalOffset, unsigned Index,
5456                      bool IsComplex) -> bool {
5457     if (IsComplex) {
5458       if (!this->emitGetLocal(PT_Ptr, LocalOffset, E))
5459         return false;
5460       return this->emitArrayElemPop(ElemT, Index, E);
5461     }
5462     return this->emitGetLocal(ElemT, LocalOffset, E);
5463   };
5464 
5465   for (unsigned I = 0; I != 2; ++I) {
5466     // Get both values.
5467     if (!getElem(LHSOffset, I, LHSIsComplex))
5468       return false;
5469     if (!getElem(RHSOffset, I, RHSIsComplex))
5470       return false;
5471     // And compare them.
5472     if (!this->emitEQ(ElemT, E))
5473       return false;
5474 
5475     if (!this->emitCastBoolUint8(E))
5476       return false;
5477   }
5478 
5479   // We now have two bool values on the stack. Compare those.
5480   if (!this->emitAddUint8(E))
5481     return false;
5482   if (!this->emitConstUint8(2, E))
5483     return false;
5484 
5485   if (E->getOpcode() == BO_EQ) {
5486     if (!this->emitEQUint8(E))
5487       return false;
5488   } else if (E->getOpcode() == BO_NE) {
5489     if (!this->emitNEUint8(E))
5490       return false;
5491   } else
5492     return false;
5493 
5494   // In C, this returns an int.
5495   if (PrimType ResT = classifyPrim(E->getType()); ResT != PT_Bool)
5496     return this->emitCast(PT_Bool, ResT, E);
5497   return true;
5498 }
5499 
5500 /// When calling this, we have a pointer of the local-to-destroy
5501 /// on the stack.
5502 /// Emit destruction of record types (or arrays of record types).
5503 template <class Emitter>
5504 bool Compiler<Emitter>::emitRecordDestruction(const Record *R) {
5505   assert(R);
5506   // First, destroy all fields.
5507   for (const Record::Field &Field : llvm::reverse(R->fields())) {
5508     const Descriptor *D = Field.Desc;
5509     if (!D->isPrimitive() && !D->isPrimitiveArray()) {
5510       if (!this->emitGetPtrField(Field.Offset, SourceInfo{}))
5511         return false;
5512       if (!this->emitDestruction(D))
5513         return false;
5514       if (!this->emitPopPtr(SourceInfo{}))
5515         return false;
5516     }
5517   }
5518 
5519   // FIXME: Unions need to be handled differently here. We don't want to
5520   //   call the destructor of its members.
5521 
5522   // Now emit the destructor and recurse into base classes.
5523   if (const CXXDestructorDecl *Dtor = R->getDestructor();
5524       Dtor && !Dtor->isTrivial()) {
5525     const Function *DtorFunc = getFunction(Dtor);
5526     if (!DtorFunc)
5527       return false;
5528     assert(DtorFunc->hasThisPointer());
5529     assert(DtorFunc->getNumParams() == 1);
5530     if (!this->emitDupPtr(SourceInfo{}))
5531       return false;
5532     if (!this->emitCall(DtorFunc, 0, SourceInfo{}))
5533       return false;
5534   }
5535 
5536   for (const Record::Base &Base : llvm::reverse(R->bases())) {
5537     if (!this->emitGetPtrBase(Base.Offset, SourceInfo{}))
5538       return false;
5539     if (!this->emitRecordDestruction(Base.R))
5540       return false;
5541     if (!this->emitPopPtr(SourceInfo{}))
5542       return false;
5543   }
5544 
5545   // FIXME: Virtual bases.
5546   return true;
5547 }
5548 /// When calling this, we have a pointer of the local-to-destroy
5549 /// on the stack.
5550 /// Emit destruction of record types (or arrays of record types).
5551 template <class Emitter>
5552 bool Compiler<Emitter>::emitDestruction(const Descriptor *Desc) {
5553   assert(Desc);
5554   assert(!Desc->isPrimitive());
5555   assert(!Desc->isPrimitiveArray());
5556 
5557   // Arrays.
5558   if (Desc->isArray()) {
5559     const Descriptor *ElemDesc = Desc->ElemDesc;
5560     assert(ElemDesc);
5561 
5562     // Don't need to do anything for these.
5563     if (ElemDesc->isPrimitiveArray())
5564       return true;
5565 
5566     // If this is an array of record types, check if we need
5567     // to call the element destructors at all. If not, try
5568     // to save the work.
5569     if (const Record *ElemRecord = ElemDesc->ElemRecord) {
5570       if (const CXXDestructorDecl *Dtor = ElemRecord->getDestructor();
5571           !Dtor || Dtor->isTrivial())
5572         return true;
5573     }
5574 
5575     for (ssize_t I = Desc->getNumElems() - 1; I >= 0; --I) {
5576       if (!this->emitConstUint64(I, SourceInfo{}))
5577         return false;
5578       if (!this->emitArrayElemPtrUint64(SourceInfo{}))
5579         return false;
5580       if (!this->emitDestruction(ElemDesc))
5581         return false;
5582       if (!this->emitPopPtr(SourceInfo{}))
5583         return false;
5584     }
5585     return true;
5586   }
5587 
5588   assert(Desc->ElemRecord);
5589   return this->emitRecordDestruction(Desc->ElemRecord);
5590 }
5591 
5592 namespace clang {
5593 namespace interp {
5594 
5595 template class Compiler<ByteCodeEmitter>;
5596 template class Compiler<EvalEmitter>;
5597 
5598 } // namespace interp
5599 } // namespace clang
5600