Initialization.h source code [clang/include/clang/Sema/Initialization.h]

1	//===- Initialization.h - Semantic Analysis for Initializers ----- 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	// This file provides supporting data types for initialization of objects.
10	//
11	//===----------------------------------------------------------------------===//
12
13	#ifndef LLVM_CLANG_SEMA_INITIALIZATION_H
14	#define LLVM_CLANG_SEMA_INITIALIZATION_H
15
16	#include "clang/AST/ASTContext.h"
17	#include "clang/AST/Attr.h"
18	#include "clang/AST/Decl.h"
19	#include "clang/AST/DeclAccessPair.h"
20	#include "clang/AST/DeclarationName.h"
21	#include "clang/AST/Expr.h"
22	#include "clang/AST/Type.h"
23	#include "clang/Basic/IdentifierTable.h"
24	#include "clang/Basic/LLVM.h"
25	#include "clang/Basic/LangOptions.h"
26	#include "clang/Basic/SourceLocation.h"
27	#include "clang/Basic/Specifiers.h"
28	#include "clang/Sema/Overload.h"
29	#include "clang/Sema/Ownership.h"
30	#include "llvm/ADT/ArrayRef.h"
31	#include "llvm/ADT/SmallVector.h"
32	#include "llvm/ADT/StringRef.h"
33	#include "llvm/ADT/iterator_range.h"
34	#include "llvm/Support/Casting.h"
35	#include <cassert>
36	#include <cstdint>
37	#include <string>
38
39	namespace clang {
40
41	class CXXBaseSpecifier;
42	class CXXConstructorDecl;
43	class ObjCMethodDecl;
44	class Sema;
45
46	/// Describes an entity that is being initialized.
47	class alignas(`8`) InitializedEntity {
48	public:
49	/// Specifies the kind of entity being initialized.
50	enum EntityKind {
51	/// The entity being initialized is a variable.
52	EK_Variable,
53
54	/// The entity being initialized is a function parameter.
55	EK_Parameter,
56
57	/// The entity being initialized is a non-type template parameter.
58	EK_TemplateParameter,
59
60	/// The entity being initialized is the result of a function call.
61	EK_Result,
62
63	/// The entity being initialized is the result of a statement expression.
64	EK_StmtExprResult,
65
66	/// The entity being initialized is an exception object that
67	/// is being thrown.
68	EK_Exception,
69
70	/// The entity being initialized is a non-static data member
71	/// subobject.
72	EK_Member,
73
74	/// The entity being initialized is an element of an array.
75	EK_ArrayElement,
76
77	/// The entity being initialized is an object (or array of
78	/// objects) allocated via new.
79	EK_New,
80
81	/// The entity being initialized is a temporary object.
82	EK_Temporary,
83
84	/// The entity being initialized is a base member subobject.
85	EK_Base,
86
87	/// The initialization is being done by a delegating constructor.
88	EK_Delegating,
89
90	/// The entity being initialized is an element of a vector.
91	/// or vector.
92	EK_VectorElement,
93
94	/// The entity being initialized is a field of block descriptor for
95	/// the copied-in c++ object.
96	EK_BlockElement,
97
98	/// The entity being initialized is a field of block descriptor for the
99	/// copied-in lambda object that's used in the lambda to block conversion.
100	EK_LambdaToBlockConversionBlockElement,
101
102	/// The entity being initialized is the real or imaginary part of a
103	/// complex number.
104	EK_ComplexElement,
105
106	/// The entity being initialized is the field that captures a
107	/// variable in a lambda.
108	EK_LambdaCapture,
109
110	/// The entity being initialized is the initializer for a compound
111	/// literal.
112	EK_CompoundLiteralInit,
113
114	/// The entity being implicitly initialized back to the formal
115	/// result type.
116	EK_RelatedResult,
117
118	/// The entity being initialized is a function parameter; function
119	/// is member of group of audited CF APIs.
120	EK_Parameter_CF_Audited,
121
122	/// The entity being initialized is a structured binding of a
123	/// decomposition declaration.
124	EK_Binding,
125
126	/// The entity being initialized is a non-static data member subobject of an
127	/// object initialized via parenthesized aggregate initialization.
128	EK_ParenAggInitMember,
129
130	// Note: err_init_conversion_failed in DiagnosticSemaKinds.td uses this
131	// enum as an index for its first %select. When modifying this list,
132	// that diagnostic text needs to be updated as well.
133	};
134
135	private:
136	/// The kind of entity being initialized.
137	EntityKind Kind;
138
139	/// If non-NULL, the parent entity in which this
140	/// initialization occurs.
141	const InitializedEntity Parent = nullptr*;
142
143	/// The type of the object or reference being initialized.
144	QualType Type;
145
146	/// The mangling number for the next reference temporary to be created.
147	mutable unsigned ManglingNumber = `0`;
148
149	struct LN {
150	/// When Kind == EK_Result, EK_Exception, EK_New, the
151	/// location of the 'return', 'throw', or 'new' keyword,
152	/// respectively. When Kind == EK_Temporary, the location where
153	/// the temporary is being created.
154	SourceLocation Location;
155
156	/// Whether the entity being initialized may end up using the
157	/// named return value optimization (NRVO).
158	bool NRVO;
159	};
160
161	struct VD {
162	/// The VarDecl, FieldDecl, or BindingDecl being initialized.
163	ValueDecl *VariableOrMember;
164
165	/// When Kind == EK_Member, whether this is an implicit member
166	/// initialization in a copy or move constructor. These can perform array
167	/// copies.
168	bool IsImplicitFieldInit;
169
170	/// When Kind == EK_Member, whether this is the initial initialization
171	/// check for a default member initializer.
172	bool IsDefaultMemberInit;
173	};
174
175	struct C {
176	/// The name of the variable being captured by an EK_LambdaCapture.
177	IdentifierInfo *VarID;
178
179	/// The source location at which the capture occurs.
180	SourceLocation Location;
181	};
182
183	union {
184	/// When Kind == EK_Variable, EK_Member, EK_Binding, or
185	/// EK_TemplateParameter, the variable, binding, or template parameter.
186	VD Variable;
187
188	/// When Kind == EK_RelatedResult, the ObjectiveC method where
189	/// result type was implicitly changed to accommodate ARC semantics.
190	ObjCMethodDecl *MethodDecl;
191
192	/// When Kind == EK_Parameter, the ParmVarDecl, with the
193	/// integer indicating whether the parameter is "consumed".
194	llvm::PointerIntPair<ParmVarDecl *, `1`> Parameter;
195
196	/// When Kind == EK_Temporary or EK_CompoundLiteralInit, the type
197	/// source information for the temporary.
198	TypeSourceInfo *TypeInfo;
199
200	struct LN LocAndNRVO;
201
202	/// When Kind == EK_Base, the base specifier that provides the
203	/// base class. The integer specifies whether the base is an inherited
204	/// virtual base.
205	llvm::PointerIntPair<const CXXBaseSpecifier *, `1`> Base;
206
207	/// When Kind == EK_ArrayElement, EK_VectorElement, or
208	/// EK_ComplexElement, the index of the array or vector element being
209	/// initialized.
210	unsigned Index;
211
212	struct C Capture;
213	};
214
215	InitializedEntity() {};
216
217	/// Create the initialization entity for a variable.
218	InitializedEntity(VarDecl *Var, EntityKind EK = EK_Variable)
219	: Kind(EK), Type(Var->getType()), Variable{Var, .IsImplicitFieldInit: false, .IsDefaultMemberInit: false} {}
220
221	/// Create the initialization entity for the result of a
222	/// function, throwing an object, performing an explicit cast, or
223	/// initializing a parameter for which there is no declaration.
224	InitializedEntity(EntityKind Kind, SourceLocation Loc, QualType Type,
225	bool NRVO = false)
226	: Kind(Kind), Type(Type) {
227	new (&LocAndNRVO) LN;
228	LocAndNRVO.Location = Loc;
229	LocAndNRVO.NRVO = NRVO;
230	}
231
232	/// Create the initialization entity for a member subobject.
233	InitializedEntity(FieldDecl Member, const* InitializedEntity *Parent,
234	bool Implicit, bool DefaultMemberInit,
235	bool IsParenAggInit = false)
236	: Kind(IsParenAggInit ? EK_ParenAggInitMember : EK_Member),
237	Parent(Parent), Type(Member->getType()),
238	Variable{Member, .IsImplicitFieldInit: Implicit, .IsDefaultMemberInit: DefaultMemberInit} {}
239
240	/// Create the initialization entity for an array element.
241	InitializedEntity(ASTContext &Context, unsigned Index,
242	const InitializedEntity &Parent);
243
244	/// Create the initialization entity for a lambda capture.
245	InitializedEntity(IdentifierInfo *VarID, QualType FieldType, SourceLocation Loc)
246	: Kind(EK_LambdaCapture), Type(FieldType) {
247	new (&Capture) C;
248	Capture.VarID = VarID;
249	Capture.Location = Loc;
250	}
251
252	public:
253	/// Create the initialization entity for a variable.
254	static InitializedEntity InitializeVariable(VarDecl *Var) {
255	return InitializedEntity (Var);
256	}
257
258	/// Create the initialization entity for a parameter.
259	static InitializedEntity InitializeParameter(ASTContext &Context,
260	ParmVarDecl *Parm) {
261	return InitializeParameter(Context, Parm, Parm->getType());
262	}
263
264	/// Create the initialization entity for a parameter, but use
265	/// another type.
266	static InitializedEntity
267	InitializeParameter(ASTContext &Context, ParmVarDecl *Parm, QualType Type) {
268	bool Consumed = (Context.getLangOpts().ObjCAutoRefCount &&
269	Parm->hasAttr<NSConsumedAttr>());
270
271	InitializedEntity Entity;
272	Entity.Kind = EK_Parameter;
273	Entity.Type =
274	Context.getVariableArrayDecayedType(Ty: Type.getUnqualifiedType());
275	Entity.Parent = nullptr;
276	Entity.Parameter = {Parm, Consumed};
277	return Entity;
278	}
279
280	/// Create the initialization entity for a parameter that is
281	/// only known by its type.
282	static InitializedEntity InitializeParameter(ASTContext &Context,
283	QualType Type,
284	bool Consumed) {
285	InitializedEntity Entity;
286	Entity.Kind = EK_Parameter;
287	Entity.Type = Context.getVariableArrayDecayedType(Ty: Type);
288	Entity.Parent = nullptr;
289	Entity.Parameter = {nullptr, Consumed};
290	return Entity;
291	}
292
293	/// Create the initialization entity for a template parameter.
294	static InitializedEntity
295	InitializeTemplateParameter(QualType T, NonTypeTemplateParmDecl *Param) {
296	InitializedEntity Entity;
297	Entity.Kind = EK_TemplateParameter;
298	Entity.Type = T;
299	Entity.Parent = nullptr;
300	Entity.Variable = {Param, false, false};
301	return Entity;
302	}
303
304	/// Create the initialization entity for the result of a function.
305	static InitializedEntity InitializeResult(SourceLocation ReturnLoc,
306	QualType Type) {
307	return InitializedEntity (EK_Result, ReturnLoc, Type);
308	}
309
310	static InitializedEntity InitializeStmtExprResult(SourceLocation ReturnLoc,
311	QualType Type) {
312	return InitializedEntity (EK_StmtExprResult, ReturnLoc, Type);
313	}
314
315	static InitializedEntity InitializeBlock(SourceLocation BlockVarLoc,
316	QualType Type) {
317	return InitializedEntity (EK_BlockElement, BlockVarLoc, Type);
318	}
319
320	static InitializedEntity InitializeLambdaToBlock(SourceLocation BlockVarLoc,
321	QualType Type) {
322	return InitializedEntity (EK_LambdaToBlockConversionBlockElement,
323	BlockVarLoc, Type);
324	}
325
326	/// Create the initialization entity for an exception object.
327	static InitializedEntity InitializeException(SourceLocation ThrowLoc,
328	QualType Type) {
329	return InitializedEntity (EK_Exception, ThrowLoc, Type);
330	}
331
332	/// Create the initialization entity for an object allocated via new.
333	static InitializedEntity InitializeNew(SourceLocation NewLoc, QualType Type) {
334	return InitializedEntity (EK_New, NewLoc, Type);
335	}
336
337	/// Create the initialization entity for a temporary.
338	static InitializedEntity InitializeTemporary(QualType Type) {
339	return InitializeTemporary(TypeInfo: nullptr, Type);
340	}
341
342	/// Create the initialization entity for a temporary.
343	static InitializedEntity InitializeTemporary(ASTContext &Context,
344	TypeSourceInfo *TypeInfo) {
345	QualType Type = TypeInfo->getType();
346	if (Context.getLangOpts().OpenCLCPlusPlus) {
347	assert(!Type.hasAddressSpace() && "Temporary already has address space!");
348	Type = Context.getAddrSpaceQualType(T: Type, AddressSpace: LangAS::opencl_private);
349	}
350
351	return InitializeTemporary(TypeInfo, Type);
352	}
353
354	/// Create the initialization entity for a temporary.
355	static InitializedEntity InitializeTemporary(TypeSourceInfo *TypeInfo,
356	QualType Type) {
357	InitializedEntity Result(EK_Temporary, SourceLocation (), Type);
358	Result.TypeInfo = TypeInfo;
359	return Result;
360	}
361
362	/// Create the initialization entity for a related result.
363	static InitializedEntity InitializeRelatedResult(ObjCMethodDecl *MD,
364	QualType Type) {
365	InitializedEntity Result(EK_RelatedResult, SourceLocation (), Type);
366	Result.MethodDecl = MD;
367	return Result;
368	}
369
370	/// Create the initialization entity for a base class subobject.
371	static InitializedEntity
372	InitializeBase(ASTContext &Context, const CXXBaseSpecifier *Base,
373	bool IsInheritedVirtualBase,
374	const InitializedEntity Parent = nullptr*);
375
376	/// Create the initialization entity for a delegated constructor.
377	static InitializedEntity InitializeDelegation(QualType Type) {
378	return InitializedEntity (EK_Delegating, SourceLocation (), Type);
379	}
380
381	/// Create the initialization entity for a member subobject.
382	static InitializedEntity
383	InitializeMember(FieldDecl *Member,
384	const InitializedEntity Parent = nullptr*,
385	bool Implicit = false) {
386	return InitializedEntity (Member, Parent, Implicit, false);
387	}
388
389	/// Create the initialization entity for a member subobject.
390	static InitializedEntity
391	InitializeMember(IndirectFieldDecl *Member,
392	const InitializedEntity Parent = nullptr*,
393	bool Implicit = false) {
394	return InitializedEntity (Member->getAnonField(), Parent, Implicit, false);
395	}
396
397	/// Create the initialization entity for a member subobject initialized via
398	/// parenthesized aggregate init.
399	static InitializedEntity InitializeMemberFromParenAggInit(FieldDecl *Member) {
400	return InitializedEntity (Member, /Parent=/nullptr, /Implicit=/false,
401	/DefaultMemberInit=/false,
402	/IsParenAggInit=/true);
403	}
404
405	/// Create the initialization entity for a default member initializer.
406	static InitializedEntity
407	InitializeMemberFromDefaultMemberInitializer(FieldDecl *Member) {
408	return InitializedEntity (Member, nullptr, false, true);
409	}
410
411	/// Create the initialization entity for an array element.
412	static InitializedEntity InitializeElement(ASTContext &Context,
413	unsigned Index,
414	const InitializedEntity &Parent) {
415	return InitializedEntity (Context, Index, Parent);
416	}
417
418	/// Create the initialization entity for a structured binding.
419	static InitializedEntity InitializeBinding(VarDecl *Binding) {
420	return InitializedEntity (Binding, EK_Binding);
421	}
422
423	/// Create the initialization entity for a lambda capture.
424	///
425	/// \p VarID The name of the entity being captured, or nullptr for 'this'.
426	static InitializedEntity InitializeLambdaCapture(IdentifierInfo *VarID,
427	QualType FieldType,
428	SourceLocation Loc) {
429	return InitializedEntity (VarID, FieldType, Loc);
430	}
431
432	/// Create the entity for a compound literal initializer.
433	static InitializedEntity InitializeCompoundLiteralInit(TypeSourceInfo *TSI) {
434	InitializedEntity Result(EK_CompoundLiteralInit, SourceLocation (),
435	TSI->getType());
436	Result.TypeInfo = TSI;
437	return Result;
438	}
439
440	/// Determine the kind of initialization.
441	EntityKind getKind() const { return Kind; }
442
443	/// Retrieve the parent of the entity being initialized, when
444	/// the initialization itself is occurring within the context of a
445	/// larger initialization.
446	const InitializedEntity getParent() const* { return Parent; }
447
448	/// Retrieve type being initialized.
449	QualType getType() const { return Type; }
450
451	/// Retrieve complete type-source information for the object being
452	/// constructed, if known.
453	TypeSourceInfo getTypeSourceInfo() const* {
454	if (Kind == EK_Temporary \|\| Kind == EK_CompoundLiteralInit)
455	return TypeInfo;
456
457	return nullptr;
458	}
459
460	/// Retrieve the name of the entity being initialized.
461	DeclarationName getName() const;
462
463	/// Retrieve the variable, parameter, or field being
464	/// initialized.
465	ValueDecl getDecl() const*;
466
467	/// Retrieve the ObjectiveC method being initialized.
468	ObjCMethodDecl getMethodDecl() const* { return MethodDecl; }
469
470	/// Determine whether this initialization allows the named return
471	/// value optimization, which also applies to thrown objects.
472	bool allowsNRVO() const;
473
474	bool isParameterKind() const {
475	return (getKind() == EK_Parameter \|\|
476	getKind() == EK_Parameter_CF_Audited);
477	}
478
479	bool isParamOrTemplateParamKind() const {
480	return isParameterKind() \|\| getKind() == EK_TemplateParameter;
481	}
482
483	/// Determine whether this initialization consumes the
484	/// parameter.
485	bool isParameterConsumed() const {
486	assert(isParameterKind() && "Not a parameter");
487	return Parameter.getInt();
488	}
489
490	/// Retrieve the base specifier.
491	const CXXBaseSpecifier getBaseSpecifier() const* {
492	assert(getKind() == EK_Base && "Not a base specifier");
493	return Base.getPointer();
494	}
495
496	/// Return whether the base is an inherited virtual base.
497	bool isInheritedVirtualBase() const {
498	assert(getKind() == EK_Base && "Not a base specifier");
499	return Base.getInt();
500	}
501
502	/// Determine whether this is an array new with an unknown bound.
503	bool isVariableLengthArrayNew() const {
504	return getKind() == EK_New && isa_and_nonnull<IncompleteArrayType>(
505	getType()->getAsArrayTypeUnsafe());
506	}
507
508	/// Is this the implicit initialization of a member of a class from
509	/// a defaulted constructor?
510	bool isImplicitMemberInitializer() const {
511	return getKind() == EK_Member && Variable.IsImplicitFieldInit;
512	}
513
514	/// Is this the default member initializer of a member (specified inside
515	/// the class definition)?
516	bool isDefaultMemberInitializer() const {
517	return getKind() == EK_Member && Variable.IsDefaultMemberInit;
518	}
519
520	/// Determine the location of the 'return' keyword when initializing
521	/// the result of a function call.
522	SourceLocation getReturnLoc() const {
523	assert(getKind() == EK_Result && "No 'return' location!");
524	return LocAndNRVO.Location;
525	}
526
527	/// Determine the location of the 'throw' keyword when initializing
528	/// an exception object.
529	SourceLocation getThrowLoc() const {
530	assert(getKind() == EK_Exception && "No 'throw' location!");
531	return LocAndNRVO.Location;
532	}
533
534	/// If this is an array, vector, or complex number element, get the
535	/// element's index.
536	unsigned getElementIndex() const {
537	assert(getKind() == EK_ArrayElement \|\| getKind() == EK_VectorElement \|\|
538	getKind() == EK_ComplexElement);
539	return Index;
540	}
541
542	/// If this is already the initializer for an array or vector
543	/// element, sets the element index.
544	void setElementIndex(unsigned Index) {
545	assert(getKind() == EK_ArrayElement \|\| getKind() == EK_VectorElement \|\|
546	getKind() == EK_ComplexElement);
547	this->Index = Index;
548	}
549
550	/// For a lambda capture, return the capture's name.
551	StringRef getCapturedVarName() const {
552	assert(getKind() == EK_LambdaCapture && "Not a lambda capture!");
553	return Capture.VarID ? Capture.VarID->getName() : "this";
554	}
555
556	/// Determine the location of the capture when initializing
557	/// field from a captured variable in a lambda.
558	SourceLocation getCaptureLoc() const {
559	assert(getKind() == EK_LambdaCapture && "Not a lambda capture!");
560	return Capture.Location;
561	}
562
563	void setParameterCFAudited() {
564	Kind = EK_Parameter_CF_Audited;
565	}
566
567	unsigned allocateManglingNumber() const { return ++ManglingNumber; }
568
569	/// Dump a representation of the initialized entity to standard error,
570	/// for debugging purposes.
571	void dump() const;
572
573	private:
574	unsigned dumpImpl(raw_ostream &OS) const;
575	};
576
577	/// Describes the kind of initialization being performed, along with
578	/// location information for tokens related to the initialization (equal sign,
579	/// parentheses).
580	class InitializationKind {
581	public:
582	/// The kind of initialization being performed.
583	enum InitKind {
584	/// Direct initialization
585	IK_Direct,
586
587	/// Direct list-initialization
588	IK_DirectList,
589
590	/// Copy initialization
591	IK_Copy,
592
593	/// Default initialization
594	IK_Default,
595
596	/// Value initialization
597	IK_Value
598	};
599
600	private:
601	/// The context of the initialization.
602	enum InitContext {
603	/// Normal context
604	IC_Normal,
605
606	/// Normal context, but allows explicit conversion functionss
607	IC_ExplicitConvs,
608
609	/// Implicit context (value initialization)
610	IC_Implicit,
611
612	/// Static cast context
613	IC_StaticCast,
614
615	/// C-style cast context
616	IC_CStyleCast,
617
618	/// Functional cast context
619	IC_FunctionalCast
620	};
621
622	/// The kind of initialization being performed.
623	InitKind Kind : `8`;
624
625	/// The context of the initialization.
626	InitContext Context : `8`;
627
628	/// The source locations involved in the initialization.
629	SourceLocation Locations[`3`];
630
631	InitializationKind(InitKind Kind, InitContext Context, SourceLocation Loc1,
632	SourceLocation Loc2, SourceLocation Loc3)
633	: Kind(Kind), Context(Context) {
634	Locations[`0`] = Loc1;
635	Locations[`1`] = Loc2;
636	Locations[`2`] = Loc3;
637	}
638
639	public:
640	/// Create a direct initialization.
641	static InitializationKind CreateDirect(SourceLocation InitLoc,
642	SourceLocation LParenLoc,
643	SourceLocation RParenLoc) {
644	return InitializationKind (IK_Direct, IC_Normal,
645	InitLoc, LParenLoc, RParenLoc);
646	}
647
648	static InitializationKind CreateDirectList(SourceLocation InitLoc) {
649	return InitializationKind (IK_DirectList, IC_Normal, InitLoc, InitLoc,
650	InitLoc);
651	}
652
653	static InitializationKind CreateDirectList(SourceLocation InitLoc,
654	SourceLocation LBraceLoc,
655	SourceLocation RBraceLoc) {
656	return InitializationKind (IK_DirectList, IC_Normal, InitLoc, LBraceLoc,
657	RBraceLoc);
658	}
659
660	/// Create a direct initialization due to a cast that isn't a C-style
661	/// or functional cast.
662	static InitializationKind CreateCast(SourceRange TypeRange) {
663	return InitializationKind (IK_Direct, IC_StaticCast, TypeRange.getBegin(),
664	TypeRange.getBegin(), TypeRange.getEnd());
665	}
666
667	/// Create a direct initialization for a C-style cast.
668	static InitializationKind CreateCStyleCast(SourceLocation StartLoc,
669	SourceRange TypeRange,
670	bool InitList) {
671	// C++ cast syntax doesn't permit init lists, but C compound literals are
672	// exactly that.
673	return InitializationKind (InitList ? IK_DirectList : IK_Direct,
674	IC_CStyleCast, StartLoc, TypeRange.getBegin(),
675	TypeRange.getEnd());
676	}
677
678	/// Create a direct initialization for a functional cast.
679	static InitializationKind CreateFunctionalCast(SourceRange TypeRange,
680	bool InitList) {
681	return InitializationKind (InitList ? IK_DirectList : IK_Direct,
682	IC_FunctionalCast, TypeRange.getBegin(),
683	TypeRange.getBegin(), TypeRange.getEnd());
684	}
685
686	/// Create a copy initialization.
687	static InitializationKind CreateCopy(SourceLocation InitLoc,
688	SourceLocation EqualLoc,
689	bool AllowExplicitConvs = false) {
690	return InitializationKind (IK_Copy,
691	AllowExplicitConvs? IC_ExplicitConvs : IC_Normal,
692	InitLoc, EqualLoc, EqualLoc);
693	}
694
695	/// Create a default initialization.
696	static InitializationKind CreateDefault(SourceLocation InitLoc) {
697	return InitializationKind (IK_Default, IC_Normal, InitLoc, InitLoc, InitLoc);
698	}
699
700	/// Create a value initialization.
701	static InitializationKind CreateValue(SourceLocation InitLoc,
702	SourceLocation LParenLoc,
703	SourceLocation RParenLoc,
704	bool isImplicit = false) {
705	return InitializationKind (IK_Value, isImplicit ? IC_Implicit : IC_Normal,
706	InitLoc, LParenLoc, RParenLoc);
707	}
708
709	/// Create an initialization from an initializer (which, for direct
710	/// initialization from a parenthesized list, will be a ParenListExpr).
711	static InitializationKind CreateForInit(SourceLocation Loc, bool DirectInit,
712	Expr *Init) {
713	if (!Init) return CreateDefault(InitLoc: Loc);
714	if (!DirectInit)
715	return CreateCopy(InitLoc: Loc, EqualLoc: Init->getBeginLoc());
716	if (isa<InitListExpr>(Val: Init))
717	return CreateDirectList(Loc, Init->getBeginLoc(), Init->getEndLoc());
718	return CreateDirect(InitLoc: Loc, LParenLoc: Init->getBeginLoc(), RParenLoc: Init->getEndLoc());
719	}
720
721	/// Determine the initialization kind.
722	InitKind getKind() const {
723	return Kind;
724	}
725
726	/// Determine whether this initialization is an explicit cast.
727	bool isExplicitCast() const {
728	return Context >= IC_StaticCast;
729	}
730
731	/// Determine whether this initialization is a static cast.
732	bool isStaticCast() const { return Context == IC_StaticCast; }
733
734	/// Determine whether this initialization is a C-style cast.
735	bool isCStyleOrFunctionalCast() const {
736	return Context >= IC_CStyleCast;
737	}
738
739	/// Determine whether this is a C-style cast.
740	bool isCStyleCast() const {
741	return Context == IC_CStyleCast;
742	}
743
744	/// Determine whether this is a functional-style cast.
745	bool isFunctionalCast() const {
746	return Context == IC_FunctionalCast;
747	}
748
749	/// Determine whether this initialization is an implicit
750	/// value-initialization, e.g., as occurs during aggregate
751	/// initialization.
752	bool isImplicitValueInit() const { return Context == IC_Implicit; }
753
754	/// Retrieve the location at which initialization is occurring.
755	SourceLocation getLocation() const { return Locations[`0`]; }
756
757	/// Retrieve the source range that covers the initialization.
758	SourceRange getRange() const {
759	return SourceRange (Locations[`0`], Locations[`2`]);
760	}
761
762	/// Retrieve the location of the equal sign for copy initialization
763	/// (if present).
764	SourceLocation getEqualLoc() const {
765	assert(Kind == IK_Copy && "Only copy initialization has an '='");
766	return Locations[`1`];
767	}
768
769	bool isCopyInit() const { return Kind == IK_Copy; }
770
771	/// Retrieve whether this initialization allows the use of explicit
772	/// constructors.
773	bool AllowExplicit() const { return !isCopyInit(); }
774
775	/// Retrieve whether this initialization allows the use of explicit
776	/// conversion functions when binding a reference. If the reference is the
777	/// first parameter in a copy or move constructor, such conversions are
778	/// permitted even though we are performing copy-initialization.
779	bool allowExplicitConversionFunctionsInRefBinding() const {
780	return !isCopyInit() \|\| Context == IC_ExplicitConvs;
781	}
782
783	/// Determine whether this initialization has a source range containing the
784	/// locations of open and closing parentheses or braces.
785	bool hasParenOrBraceRange() const {
786	return Kind == IK_Direct \|\| Kind == IK_Value \|\| Kind == IK_DirectList;
787	}
788
789	/// Retrieve the source range containing the locations of the open
790	/// and closing parentheses or braces for value, direct, and direct list
791	/// initializations.
792	SourceRange getParenOrBraceRange() const {
793	assert(hasParenOrBraceRange() && "Only direct, value, and direct-list "
794	"initialization have parentheses or "
795	"braces");
796	return SourceRange (Locations[`1`], Locations[`2`]);
797	}
798	};
799
800	/// Describes the sequence of initializations required to initialize
801	/// a given object or reference with a set of arguments.
802	class InitializationSequence {
803	public:
804	/// Describes the kind of initialization sequence computed.
805	enum SequenceKind {
806	/// A failed initialization sequence. The failure kind tells what
807	/// happened.
808	FailedSequence = `0`,
809
810	/// A dependent initialization, which could not be
811	/// type-checked due to the presence of dependent types or
812	/// dependently-typed expressions.
813	DependentSequence,
814
815	/// A normal sequence.
816	NormalSequence
817	};
818
819	/// Describes the kind of a particular step in an initialization
820	/// sequence.
821	enum StepKind {
822	/// Resolve the address of an overloaded function to a specific
823	/// function declaration.
824	SK_ResolveAddressOfOverloadedFunction,
825
826	/// Perform a derived-to-base cast, producing an rvalue.
827	SK_CastDerivedToBasePRValue,
828
829	/// Perform a derived-to-base cast, producing an xvalue.
830	SK_CastDerivedToBaseXValue,
831
832	/// Perform a derived-to-base cast, producing an lvalue.
833	SK_CastDerivedToBaseLValue,
834
835	/// Reference binding to an lvalue.
836	SK_BindReference,
837
838	/// Reference binding to a temporary.
839	SK_BindReferenceToTemporary,
840
841	/// An optional copy of a temporary object to another
842	/// temporary object, which is permitted (but not required) by
843	/// C++98/03 but not C++0x.
844	SK_ExtraneousCopyToTemporary,
845
846	/// Direct-initialization from a reference-related object in the
847	/// final stage of class copy-initialization.
848	SK_FinalCopy,
849
850	/// Perform a user-defined conversion, either via a conversion
851	/// function or via a constructor.
852	SK_UserConversion,
853
854	/// Perform a qualification conversion, producing a prvalue.
855	SK_QualificationConversionPRValue,
856
857	/// Perform a qualification conversion, producing an xvalue.
858	SK_QualificationConversionXValue,
859
860	/// Perform a qualification conversion, producing an lvalue.
861	SK_QualificationConversionLValue,
862
863	/// Perform a function reference conversion, see [dcl.init.ref]p4.
864	SK_FunctionReferenceConversion,
865
866	/// Perform a conversion adding _Atomic to a type.
867	SK_AtomicConversion,
868
869	/// Perform an implicit conversion sequence.
870	SK_ConversionSequence,
871
872	/// Perform an implicit conversion sequence without narrowing.
873	SK_ConversionSequenceNoNarrowing,
874
875	/// Perform list-initialization without a constructor.
876	SK_ListInitialization,
877
878	/// Unwrap the single-element initializer list for a reference.
879	SK_UnwrapInitList,
880
881	/// Rewrap the single-element initializer list for a reference.
882	SK_RewrapInitList,
883
884	/// Perform initialization via a constructor.
885	SK_ConstructorInitialization,
886
887	/// Perform initialization via a constructor, taking arguments from
888	/// a single InitListExpr.
889	SK_ConstructorInitializationFromList,
890
891	/// Zero-initialize the object
892	SK_ZeroInitialization,
893
894	/// C assignment
895	SK_CAssignment,
896
897	/// Initialization by string
898	SK_StringInit,
899
900	/// An initialization that "converts" an Objective-C object
901	/// (not a point to an object) to another Objective-C object type.
902	SK_ObjCObjectConversion,
903
904	/// Array indexing for initialization by elementwise copy.
905	SK_ArrayLoopIndex,
906
907	/// Array initialization by elementwise copy.
908	SK_ArrayLoopInit,
909
910	/// Array initialization (from an array rvalue).
911	SK_ArrayInit,
912
913	/// Array initialization (from an array rvalue) as a GNU extension.
914	SK_GNUArrayInit,
915
916	/// Array initialization from a parenthesized initializer list.
917	/// This is a GNU C++ extension.
918	SK_ParenthesizedArrayInit,
919
920	/// Pass an object by indirect copy-and-restore.
921	SK_PassByIndirectCopyRestore,
922
923	/// Pass an object by indirect restore.
924	SK_PassByIndirectRestore,
925
926	/// Produce an Objective-C object pointer.
927	SK_ProduceObjCObject,
928
929	/// Construct a std::initializer_list from an initializer list.
930	SK_StdInitializerList,
931
932	/// Perform initialization via a constructor taking a single
933	/// std::initializer_list argument.
934	SK_StdInitializerListConstructorCall,
935
936	/// Initialize an OpenCL sampler from an integer.
937	SK_OCLSamplerInit,
938
939	/// Initialize an opaque OpenCL type (event_t, queue_t, etc.) with zero
940	SK_OCLZeroOpaqueType,
941
942	/// Initialize an aggreagate with parenthesized list of values.
943	/// This is a C++20 feature.
944	SK_ParenthesizedListInit
945	};
946
947	/// A single step in the initialization sequence.
948	class Step {
949	public:
950	/// The kind of conversion or initialization step we are taking.
951	StepKind Kind;
952
953	// The type that results from this initialization.
954	QualType Type;
955
956	struct F {
957	bool HadMultipleCandidates;
958	FunctionDecl *Function;
959	DeclAccessPair FoundDecl;
960	};
961
962	union {
963	/// When Kind == SK_ResolvedOverloadedFunction or Kind ==
964	/// SK_UserConversion, the function that the expression should be
965	/// resolved to or the conversion function to call, respectively.
966	/// When Kind == SK_ConstructorInitialization or SK_ListConstruction,
967	/// the constructor to be called.
968	///
969	/// Always a FunctionDecl, plus a Boolean flag telling if it was
970	/// selected from an overloaded set having size greater than 1.
971	/// For conversion decls, the naming class is the source type.
972	/// For construct decls, the naming class is the target type.
973	struct F Function;
974
975	/// When Kind = SK_ConversionSequence, the implicit conversion
976	/// sequence.
977	ImplicitConversionSequence *ICS;
978
979	/// When Kind = SK_RewrapInitList, the syntactic form of the
980	/// wrapping list.
981	InitListExpr *WrappingSyntacticList;
982	};
983
984	void Destroy();
985	};
986
987	private:
988	/// The kind of initialization sequence computed.
989	enum SequenceKind SequenceKind;
990
991	/// Steps taken by this initialization.
992	SmallVector<Step, `4`> Steps;
993
994	public:
995	/// Describes why initialization failed.
996	enum FailureKind {
997	/// Too many initializers provided for a reference.
998	FK_TooManyInitsForReference,
999
1000	/// Reference initialized from a parenthesized initializer list.
1001	FK_ParenthesizedListInitForReference,
1002
1003	/// Array must be initialized with an initializer list.
1004	FK_ArrayNeedsInitList,
1005
1006	/// Array must be initialized with an initializer list or a
1007	/// string literal.
1008	FK_ArrayNeedsInitListOrStringLiteral,
1009
1010	/// Array must be initialized with an initializer list or a
1011	/// wide string literal.
1012	FK_ArrayNeedsInitListOrWideStringLiteral,
1013
1014	/// Initializing a wide char array with narrow string literal.
1015	FK_NarrowStringIntoWideCharArray,
1016
1017	/// Initializing char array with wide string literal.
1018	FK_WideStringIntoCharArray,
1019
1020	/// Initializing wide char array with incompatible wide string
1021	/// literal.
1022	FK_IncompatWideStringIntoWideChar,
1023
1024	/// Initializing char8_t array with plain string literal.
1025	FK_PlainStringIntoUTF8Char,
1026
1027	/// Initializing char array with UTF-8 string literal.
1028	FK_UTF8StringIntoPlainChar,
1029
1030	/// Array type mismatch.
1031	FK_ArrayTypeMismatch,
1032
1033	/// Non-constant array initializer
1034	FK_NonConstantArrayInit,
1035
1036	/// Cannot resolve the address of an overloaded function.
1037	FK_AddressOfOverloadFailed,
1038
1039	/// Overloading due to reference initialization failed.
1040	FK_ReferenceInitOverloadFailed,
1041
1042	/// Non-const lvalue reference binding to a temporary.
1043	FK_NonConstLValueReferenceBindingToTemporary,
1044
1045	/// Non-const lvalue reference binding to a bit-field.
1046	FK_NonConstLValueReferenceBindingToBitfield,
1047
1048	/// Non-const lvalue reference binding to a vector element.
1049	FK_NonConstLValueReferenceBindingToVectorElement,
1050
1051	/// Non-const lvalue reference binding to a matrix element.
1052	FK_NonConstLValueReferenceBindingToMatrixElement,
1053
1054	/// Non-const lvalue reference binding to an lvalue of unrelated
1055	/// type.
1056	FK_NonConstLValueReferenceBindingToUnrelated,
1057
1058	/// Rvalue reference binding to an lvalue.
1059	FK_RValueReferenceBindingToLValue,
1060
1061	/// Reference binding drops qualifiers.
1062	FK_ReferenceInitDropsQualifiers,
1063
1064	/// Reference with mismatching address space binding to temporary.
1065	FK_ReferenceAddrspaceMismatchTemporary,
1066
1067	/// Reference binding failed.
1068	FK_ReferenceInitFailed,
1069
1070	/// Implicit conversion failed.
1071	FK_ConversionFailed,
1072
1073	/// Implicit conversion failed.
1074	FK_ConversionFromPropertyFailed,
1075
1076	/// Too many initializers for scalar
1077	FK_TooManyInitsForScalar,
1078
1079	/// Scalar initialized from a parenthesized initializer list.
1080	FK_ParenthesizedListInitForScalar,
1081
1082	/// Reference initialization from an initializer list
1083	FK_ReferenceBindingToInitList,
1084
1085	/// Initialization of some unused destination type with an
1086	/// initializer list.
1087	FK_InitListBadDestinationType,
1088
1089	/// Overloading for a user-defined conversion failed.
1090	FK_UserConversionOverloadFailed,
1091
1092	/// Overloading for initialization by constructor failed.
1093	FK_ConstructorOverloadFailed,
1094
1095	/// Overloading for list-initialization by constructor failed.
1096	FK_ListConstructorOverloadFailed,
1097
1098	/// Default-initialization of a 'const' object.
1099	FK_DefaultInitOfConst,
1100
1101	/// Initialization of an incomplete type.
1102	FK_Incomplete,
1103
1104	/// Variable-length array must not have an initializer.
1105	FK_VariableLengthArrayHasInitializer,
1106
1107	/// List initialization failed at some point.
1108	FK_ListInitializationFailed,
1109
1110	/// Initializer has a placeholder type which cannot be
1111	/// resolved by initialization.
1112	FK_PlaceholderType,
1113
1114	/// Trying to take the address of a function that doesn't support
1115	/// having its address taken.
1116	FK_AddressOfUnaddressableFunction,
1117
1118	/// List-copy-initialization chose an explicit constructor.
1119	FK_ExplicitConstructor,
1120
1121	/// Parenthesized list initialization failed at some point.
1122	/// This is a C++20 feature.
1123	FK_ParenthesizedListInitFailed,
1124
1125	// A designated initializer was provided for a non-aggregate type.
1126	FK_DesignatedInitForNonAggregate,
1127	};
1128
1129	private:
1130	/// The reason why initialization failed.
1131	FailureKind Failure;
1132
1133	/// The failed result of overload resolution.
1134	OverloadingResult FailedOverloadResult;
1135
1136	/// The candidate set created when initialization failed.
1137	OverloadCandidateSet FailedCandidateSet;
1138
1139	/// The incomplete type that caused a failure.
1140	QualType FailedIncompleteType;
1141
1142	/// The fixit that needs to be applied to make this initialization
1143	/// succeed.
1144	std::string ZeroInitializationFixit;
1145	SourceLocation ZeroInitializationFixitLoc;
1146
1147	public:
1148	/// Call for initializations are invalid but that would be valid
1149	/// zero initialzations if Fixit was applied.
1150	void SetZeroInitializationFixit(const std::string& Fixit, SourceLocation L) {
1151	ZeroInitializationFixit = Fixit;
1152	ZeroInitializationFixitLoc = L;
1153	}
1154
1155	private:
1156	/// Prints a follow-up note that highlights the location of
1157	/// the initialized entity, if it's remote.
1158	void PrintInitLocationNote(Sema &S, const InitializedEntity &Entity);
1159
1160	public:
1161	/// Try to perform initialization of the given entity, creating a
1162	/// record of the steps required to perform the initialization.
1163	///
1164	/// The generated initialization sequence will either contain enough
1165	/// information to diagnose
1166	///
1167	/// \param S the semantic analysis object.
1168	///
1169	/// \param Entity the entity being initialized.
1170	///
1171	/// \param Kind the kind of initialization being performed.
1172	///
1173	/// \param Args the argument(s) provided for initialization.
1174	///
1175	/// \param TopLevelOfInitList true if we are initializing from an expression
1176	/// at the top level inside an initializer list. This disallows
1177	/// narrowing conversions in C++11 onwards.
1178	/// \param TreatUnavailableAsInvalid true if we want to treat unavailable
1179	/// as invalid.
1180	InitializationSequence(Sema &S,
1181	const InitializedEntity &Entity,
1182	const InitializationKind &Kind,
1183	MultiExprArg Args,
1184	bool TopLevelOfInitList = false,
1185	bool TreatUnavailableAsInvalid = true);
1186	void InitializeFrom(Sema &S, const InitializedEntity &Entity,
1187	const InitializationKind &Kind, MultiExprArg Args,
1188	bool TopLevelOfInitList, bool TreatUnavailableAsInvalid);
1189
1190	~InitializationSequence();
1191
1192	/// Perform the actual initialization of the given entity based on
1193	/// the computed initialization sequence.
1194	///
1195	/// \param S the semantic analysis object.
1196	///
1197	/// \param Entity the entity being initialized.
1198	///
1199	/// \param Kind the kind of initialization being performed.
1200	///
1201	/// \param Args the argument(s) provided for initialization, ownership of
1202	/// which is transferred into the routine.
1203	///
1204	/// \param ResultType if non-NULL, will be set to the type of the
1205	/// initialized object, which is the type of the declaration in most
1206	/// cases. However, when the initialized object is a variable of
1207	/// incomplete array type and the initializer is an initializer
1208	/// list, this type will be set to the completed array type.
1209	///
1210	/// \returns an expression that performs the actual object initialization, if
1211	/// the initialization is well-formed. Otherwise, emits diagnostics
1212	/// and returns an invalid expression.
1213	ExprResult Perform(Sema &S,
1214	const InitializedEntity &Entity,
1215	const InitializationKind &Kind,
1216	MultiExprArg Args,
1217	QualType ResultType = nullptr*);
1218
1219	/// Diagnose an potentially-invalid initialization sequence.
1220	///
1221	/// \returns true if the initialization sequence was ill-formed,
1222	/// false otherwise.
1223	bool Diagnose(Sema &S,
1224	const InitializedEntity &Entity,
1225	const InitializationKind &Kind,
1226	ArrayRef<Expr *> Args);
1227
1228	/// Determine the kind of initialization sequence computed.
1229	enum SequenceKind getKind() const { return SequenceKind; }
1230
1231	/// Set the kind of sequence computed.
1232	void setSequenceKind(enum SequenceKind SK) { SequenceKind = SK; }
1233
1234	/// Determine whether the initialization sequence is valid.
1235	explicit operator bool() const { return !Failed(); }
1236
1237	/// Determine whether the initialization sequence is invalid.
1238	bool Failed() const { return SequenceKind == FailedSequence; }
1239
1240	using step_iterator = SmallVectorImpl<Step>::const_iterator;
1241
1242	step_iterator step_begin() const { return Steps.begin(); }
1243	step_iterator step_end() const { return Steps.end(); }
1244
1245	using step_range = llvm::iterator_range<step_iterator>;
1246
1247	step_range steps() const { return {step_begin(), step_end()}; }
1248
1249	/// Determine whether this initialization is a direct reference
1250	/// binding (C++ [dcl.init.ref]).
1251	bool isDirectReferenceBinding() const;
1252
1253	/// Determine whether this initialization failed due to an ambiguity.
1254	bool isAmbiguous() const;
1255
1256	/// Determine whether this initialization is direct call to a
1257	/// constructor.
1258	bool isConstructorInitialization() const;
1259
1260	/// Add a new step in the initialization that resolves the address
1261	/// of an overloaded function to a specific function declaration.
1262	///
1263	/// \param Function the function to which the overloaded function reference
1264	/// resolves.
1265	void AddAddressOverloadResolutionStep(FunctionDecl *Function,
1266	DeclAccessPair Found,
1267	bool HadMultipleCandidates);
1268
1269	/// Add a new step in the initialization that performs a derived-to-
1270	/// base cast.
1271	///
1272	/// \param BaseType the base type to which we will be casting.
1273	///
1274	/// \param Category Indicates whether the result will be treated as an
1275	/// rvalue, an xvalue, or an lvalue.
1276	void AddDerivedToBaseCastStep(QualType BaseType,
1277	ExprValueKind Category);
1278
1279	/// Add a new step binding a reference to an object.
1280	///
1281	/// \param BindingTemporary True if we are binding a reference to a temporary
1282	/// object (thereby extending its lifetime); false if we are binding to an
1283	/// lvalue or an lvalue treated as an rvalue.
1284	void AddReferenceBindingStep(QualType T, bool BindingTemporary);
1285
1286	/// Add a new step that makes an extraneous copy of the input
1287	/// to a temporary of the same class type.
1288	///
1289	/// This extraneous copy only occurs during reference binding in
1290	/// C++98/03, where we are permitted (but not required) to introduce
1291	/// an extra copy. At a bare minimum, we must check that we could
1292	/// call the copy constructor, and produce a diagnostic if the copy
1293	/// constructor is inaccessible or no copy constructor matches.
1294	//
1295	/// \param T The type of the temporary being created.
1296	void AddExtraneousCopyToTemporary(QualType T);
1297
1298	/// Add a new step that makes a copy of the input to an object of
1299	/// the given type, as the final step in class copy-initialization.
1300	void AddFinalCopy(QualType T);
1301
1302	/// Add a new step invoking a conversion function, which is either
1303	/// a constructor or a conversion function.
1304	void AddUserConversionStep(FunctionDecl *Function,
1305	DeclAccessPair FoundDecl,
1306	QualType T,
1307	bool HadMultipleCandidates);
1308
1309	/// Add a new step that performs a qualification conversion to the
1310	/// given type.
1311	void AddQualificationConversionStep(QualType Ty,
1312	ExprValueKind Category);
1313
1314	/// Add a new step that performs a function reference conversion to the
1315	/// given type.
1316	void AddFunctionReferenceConversionStep(QualType Ty);
1317
1318	/// Add a new step that performs conversion from non-atomic to atomic
1319	/// type.
1320	void AddAtomicConversionStep(QualType Ty);
1321
1322	/// Add a new step that applies an implicit conversion sequence.
1323	void AddConversionSequenceStep(const ImplicitConversionSequence &ICS,
1324	QualType T, bool TopLevelOfInitList = false);
1325
1326	/// Add a list-initialization step.
1327	void AddListInitializationStep(QualType T);
1328
1329	/// Add a constructor-initialization step.
1330	///
1331	/// \param FromInitList The constructor call is syntactically an initializer
1332	/// list.
1333	/// \param AsInitList The constructor is called as an init list constructor.
1334	void AddConstructorInitializationStep(DeclAccessPair FoundDecl,
1335	CXXConstructorDecl *Constructor,
1336	QualType T,
1337	bool HadMultipleCandidates,
1338	bool FromInitList, bool AsInitList);
1339
1340	/// Add a zero-initialization step.
1341	void AddZeroInitializationStep(QualType T);
1342
1343	/// Add a C assignment step.
1344	//
1345	// FIXME: It isn't clear whether this should ever be needed;
1346	// ideally, we would handle everything needed in C in the common
1347	// path. However, that isn't the case yet.
1348	void AddCAssignmentStep(QualType T);
1349
1350	/// Add a string init step.
1351	void AddStringInitStep(QualType T);
1352
1353	/// Add an Objective-C object conversion step, which is
1354	/// always a no-op.
1355	void AddObjCObjectConversionStep(QualType T);
1356
1357	/// Add an array initialization loop step.
1358	void AddArrayInitLoopStep(QualType T, QualType EltTy);
1359
1360	/// Add an array initialization step.
1361	void AddArrayInitStep(QualType T, bool IsGNUExtension);
1362
1363	/// Add a parenthesized array initialization step.
1364	void AddParenthesizedArrayInitStep(QualType T);
1365
1366	/// Add a step to pass an object by indirect copy-restore.
1367	void AddPassByIndirectCopyRestoreStep(QualType T, bool shouldCopy);
1368
1369	/// Add a step to "produce" an Objective-C object (by
1370	/// retaining it).
1371	void AddProduceObjCObjectStep(QualType T);
1372
1373	/// Add a step to construct a std::initializer_list object from an
1374	/// initializer list.
1375	void AddStdInitializerListConstructionStep(QualType T);
1376
1377	/// Add a step to initialize an OpenCL sampler from an integer
1378	/// constant.
1379	void AddOCLSamplerInitStep(QualType T);
1380
1381	/// Add a step to initialzie an OpenCL opaque type (event_t, queue_t, etc.)
1382	/// from a zero constant.
1383	void AddOCLZeroOpaqueTypeStep(QualType T);
1384
1385	void AddParenthesizedListInitStep(QualType T);
1386
1387	/// Add steps to unwrap a initializer list for a reference around a
1388	/// single element and rewrap it at the end.
1389	void RewrapReferenceInitList(QualType T, InitListExpr *Syntactic);
1390
1391	/// Note that this initialization sequence failed.
1392	void SetFailed(FailureKind Failure) {
1393	SequenceKind = FailedSequence;
1394	this->Failure = Failure;
1395	assert((Failure != FK_Incomplete \|\| !FailedIncompleteType.isNull()) &&
1396	"Incomplete type failure requires a type!");
1397	}
1398
1399	/// Note that this initialization sequence failed due to failed
1400	/// overload resolution.
1401	void SetOverloadFailure(FailureKind Failure, OverloadingResult Result);
1402
1403	/// Retrieve a reference to the candidate set when overload
1404	/// resolution fails.
1405	OverloadCandidateSet &getFailedCandidateSet() {
1406	return FailedCandidateSet;
1407	}
1408
1409	/// Get the overloading result, for when the initialization
1410	/// sequence failed due to a bad overload.
1411	OverloadingResult getFailedOverloadResult() const {
1412	return FailedOverloadResult;
1413	}
1414
1415	/// Note that this initialization sequence failed due to an
1416	/// incomplete type.
1417	void setIncompleteTypeFailure(QualType IncompleteType) {
1418	FailedIncompleteType = IncompleteType;
1419	SetFailed(FK_Incomplete);
1420	}
1421
1422	/// Determine why initialization failed.
1423	FailureKind getFailureKind() const {
1424	assert(Failed() && "Not an initialization failure!");
1425	return Failure;
1426	}
1427
1428	/// Dump a representation of this initialization sequence to
1429	/// the given stream, for debugging purposes.
1430	void dump(raw_ostream &OS) const;
1431
1432	/// Dump a representation of this initialization sequence to
1433	/// standard error, for debugging purposes.
1434	void dump() const;
1435	};
1436
1437	} // namespace clang
1438
1439	#endif // LLVM_CLANG_SEMA_INITIALIZATION_H
1440

source code of clang/include/clang/Sema/Initialization.h