1 //===--- Overload.h - C++ Overloading ---------------------------*- C++ -*-===//
2 //
3 //                     The LLVM Compiler Infrastructure
4 //
5 // This file is distributed under the University of Illinois Open Source
6 // License. See LICENSE.TXT for details.
7 //
8 //===----------------------------------------------------------------------===//
9 //
10 // This file defines the data structures and types used in C++
11 // overload resolution.
12 //
13 //===----------------------------------------------------------------------===//
14 
15 #ifndef LLVM_CLANG_SEMA_OVERLOAD_H
16 #define LLVM_CLANG_SEMA_OVERLOAD_H
17 
18 #include "clang/AST/Decl.h"
19 #include "clang/AST/DeclTemplate.h"
20 #include "clang/AST/Expr.h"
21 #include "clang/AST/TemplateBase.h"
22 #include "clang/AST/Type.h"
23 #include "clang/AST/UnresolvedSet.h"
24 #include "clang/Sema/SemaFixItUtils.h"
25 #include "clang/Sema/TemplateDeduction.h"
26 #include "llvm/ADT/SmallPtrSet.h"
27 #include "llvm/ADT/SmallVector.h"
28 #include "llvm/Support/AlignOf.h"
29 #include "llvm/Support/Allocator.h"
30 
31 namespace clang {
32   class ASTContext;
33   class CXXConstructorDecl;
34   class CXXConversionDecl;
35   class FunctionDecl;
36   class Sema;
37 
38   /// OverloadingResult - Capture the result of performing overload
39   /// resolution.
40   enum OverloadingResult {
41     OR_Success,             ///< Overload resolution succeeded.
42     OR_No_Viable_Function,  ///< No viable function found.
43     OR_Ambiguous,           ///< Ambiguous candidates found.
44     OR_Deleted              ///< Succeeded, but refers to a deleted function.
45   };
46 
47   enum OverloadCandidateDisplayKind {
48     /// Requests that all candidates be shown.  Viable candidates will
49     /// be printed first.
50     OCD_AllCandidates,
51 
52     /// Requests that only viable candidates be shown.
53     OCD_ViableCandidates
54   };
55 
56   /// ImplicitConversionKind - The kind of implicit conversion used to
57   /// convert an argument to a parameter's type. The enumerator values
58   /// match with Table 9 of (C++ 13.3.3.1.1) and are listed such that
59   /// better conversion kinds have smaller values.
60   enum ImplicitConversionKind {
61     ICK_Identity = 0,          ///< Identity conversion (no conversion)
62     ICK_Lvalue_To_Rvalue,      ///< Lvalue-to-rvalue conversion (C++ 4.1)
63     ICK_Array_To_Pointer,      ///< Array-to-pointer conversion (C++ 4.2)
64     ICK_Function_To_Pointer,   ///< Function-to-pointer (C++ 4.3)
65     ICK_NoReturn_Adjustment,   ///< Removal of noreturn from a type (Clang)
66     ICK_Qualification,         ///< Qualification conversions (C++ 4.4)
67     ICK_Integral_Promotion,    ///< Integral promotions (C++ 4.5)
68     ICK_Floating_Promotion,    ///< Floating point promotions (C++ 4.6)
69     ICK_Complex_Promotion,     ///< Complex promotions (Clang extension)
70     ICK_Integral_Conversion,   ///< Integral conversions (C++ 4.7)
71     ICK_Floating_Conversion,   ///< Floating point conversions (C++ 4.8)
72     ICK_Complex_Conversion,    ///< Complex conversions (C99 6.3.1.6)
73     ICK_Floating_Integral,     ///< Floating-integral conversions (C++ 4.9)
74     ICK_Pointer_Conversion,    ///< Pointer conversions (C++ 4.10)
75     ICK_Pointer_Member,        ///< Pointer-to-member conversions (C++ 4.11)
76     ICK_Boolean_Conversion,    ///< Boolean conversions (C++ 4.12)
77     ICK_Compatible_Conversion, ///< Conversions between compatible types in C99
78     ICK_Derived_To_Base,       ///< Derived-to-base (C++ [over.best.ics])
79     ICK_Vector_Conversion,     ///< Vector conversions
80     ICK_Vector_Splat,          ///< A vector splat from an arithmetic type
81     ICK_Complex_Real,          ///< Complex-real conversions (C99 6.3.1.7)
82     ICK_Block_Pointer_Conversion,    ///< Block Pointer conversions
83     ICK_TransparentUnionConversion, ///< Transparent Union Conversions
84     ICK_Writeback_Conversion,  ///< Objective-C ARC writeback conversion
85     ICK_Zero_Event_Conversion, ///< Zero constant to event (OpenCL1.2 6.12.10)
86     ICK_Num_Conversion_Kinds   ///< The number of conversion kinds
87   };
88 
89   /// ImplicitConversionRank - The rank of an implicit conversion
90   /// kind. The enumerator values match with Table 9 of (C++
91   /// 13.3.3.1.1) and are listed such that better conversion ranks
92   /// have smaller values.
93   enum ImplicitConversionRank {
94     ICR_Exact_Match = 0,         ///< Exact Match
95     ICR_Promotion,               ///< Promotion
96     ICR_Conversion,              ///< Conversion
97     ICR_Complex_Real_Conversion, ///< Complex <-> Real conversion
98     ICR_Writeback_Conversion     ///< ObjC ARC writeback conversion
99   };
100 
101   ImplicitConversionRank GetConversionRank(ImplicitConversionKind Kind);
102 
103   /// NarrowingKind - The kind of narrowing conversion being performed by a
104   /// standard conversion sequence according to C++11 [dcl.init.list]p7.
105   enum NarrowingKind {
106     /// Not a narrowing conversion.
107     NK_Not_Narrowing,
108 
109     /// A narrowing conversion by virtue of the source and destination types.
110     NK_Type_Narrowing,
111 
112     /// A narrowing conversion, because a constant expression got narrowed.
113     NK_Constant_Narrowing,
114 
115     /// A narrowing conversion, because a non-constant-expression variable might
116     /// have got narrowed.
117     NK_Variable_Narrowing
118   };
119 
120   /// StandardConversionSequence - represents a standard conversion
121   /// sequence (C++ 13.3.3.1.1). A standard conversion sequence
122   /// contains between zero and three conversions. If a particular
123   /// conversion is not needed, it will be set to the identity conversion
124   /// (ICK_Identity). Note that the three conversions are
125   /// specified as separate members (rather than in an array) so that
126   /// we can keep the size of a standard conversion sequence to a
127   /// single word.
128   class StandardConversionSequence {
129   public:
130     /// First -- The first conversion can be an lvalue-to-rvalue
131     /// conversion, array-to-pointer conversion, or
132     /// function-to-pointer conversion.
133     ImplicitConversionKind First : 8;
134 
135     /// Second - The second conversion can be an integral promotion,
136     /// floating point promotion, integral conversion, floating point
137     /// conversion, floating-integral conversion, pointer conversion,
138     /// pointer-to-member conversion, or boolean conversion.
139     ImplicitConversionKind Second : 8;
140 
141     /// Third - The third conversion can be a qualification conversion.
142     ImplicitConversionKind Third : 8;
143 
144     /// \brief Whether this is the deprecated conversion of a
145     /// string literal to a pointer to non-const character data
146     /// (C++ 4.2p2).
147     unsigned DeprecatedStringLiteralToCharPtr : 1;
148 
149     /// \brief Whether the qualification conversion involves a change in the
150     /// Objective-C lifetime (for automatic reference counting).
151     unsigned QualificationIncludesObjCLifetime : 1;
152 
153     /// IncompatibleObjC - Whether this is an Objective-C conversion
154     /// that we should warn about (if we actually use it).
155     unsigned IncompatibleObjC : 1;
156 
157     /// ReferenceBinding - True when this is a reference binding
158     /// (C++ [over.ics.ref]).
159     unsigned ReferenceBinding : 1;
160 
161     /// DirectBinding - True when this is a reference binding that is a
162     /// direct binding (C++ [dcl.init.ref]).
163     unsigned DirectBinding : 1;
164 
165     /// \brief Whether this is an lvalue reference binding (otherwise, it's
166     /// an rvalue reference binding).
167     unsigned IsLvalueReference : 1;
168 
169     /// \brief Whether we're binding to a function lvalue.
170     unsigned BindsToFunctionLvalue : 1;
171 
172     /// \brief Whether we're binding to an rvalue.
173     unsigned BindsToRvalue : 1;
174 
175     /// \brief Whether this binds an implicit object argument to a
176     /// non-static member function without a ref-qualifier.
177     unsigned BindsImplicitObjectArgumentWithoutRefQualifier : 1;
178 
179     /// \brief Whether this binds a reference to an object with a different
180     /// Objective-C lifetime qualifier.
181     unsigned ObjCLifetimeConversionBinding : 1;
182 
183     /// FromType - The type that this conversion is converting
184     /// from. This is an opaque pointer that can be translated into a
185     /// QualType.
186     void *FromTypePtr;
187 
188     /// ToType - The types that this conversion is converting to in
189     /// each step. This is an opaque pointer that can be translated
190     /// into a QualType.
191     void *ToTypePtrs[3];
192 
193     /// CopyConstructor - The copy constructor that is used to perform
194     /// this conversion, when the conversion is actually just the
195     /// initialization of an object via copy constructor. Such
196     /// conversions are either identity conversions or derived-to-base
197     /// conversions.
198     CXXConstructorDecl *CopyConstructor;
199 
setFromType(QualType T)200     void setFromType(QualType T) { FromTypePtr = T.getAsOpaquePtr(); }
setToType(unsigned Idx,QualType T)201     void setToType(unsigned Idx, QualType T) {
202       assert(Idx < 3 && "To type index is out of range");
203       ToTypePtrs[Idx] = T.getAsOpaquePtr();
204     }
setAllToTypes(QualType T)205     void setAllToTypes(QualType T) {
206       ToTypePtrs[0] = T.getAsOpaquePtr();
207       ToTypePtrs[1] = ToTypePtrs[0];
208       ToTypePtrs[2] = ToTypePtrs[0];
209     }
210 
getFromType()211     QualType getFromType() const {
212       return QualType::getFromOpaquePtr(FromTypePtr);
213     }
getToType(unsigned Idx)214     QualType getToType(unsigned Idx) const {
215       assert(Idx < 3 && "To type index is out of range");
216       return QualType::getFromOpaquePtr(ToTypePtrs[Idx]);
217     }
218 
219     void setAsIdentityConversion();
220 
isIdentityConversion()221     bool isIdentityConversion() const {
222       return Second == ICK_Identity && Third == ICK_Identity;
223     }
224 
225     ImplicitConversionRank getRank() const;
226     NarrowingKind getNarrowingKind(ASTContext &Context, const Expr *Converted,
227                                    APValue &ConstantValue,
228                                    QualType &ConstantType) const;
229     bool isPointerConversionToBool() const;
230     bool isPointerConversionToVoidPointer(ASTContext& Context) const;
231     void dump() const;
232   };
233 
234   /// UserDefinedConversionSequence - Represents a user-defined
235   /// conversion sequence (C++ 13.3.3.1.2).
236   struct UserDefinedConversionSequence {
237     /// \brief Represents the standard conversion that occurs before
238     /// the actual user-defined conversion.
239     ///
240     /// C++11 13.3.3.1.2p1:
241     ///   If the user-defined conversion is specified by a constructor
242     ///   (12.3.1), the initial standard conversion sequence converts
243     ///   the source type to the type required by the argument of the
244     ///   constructor. If the user-defined conversion is specified by
245     ///   a conversion function (12.3.2), the initial standard
246     ///   conversion sequence converts the source type to the implicit
247     ///   object parameter of the conversion function.
248     StandardConversionSequence Before;
249 
250     /// EllipsisConversion - When this is true, it means user-defined
251     /// conversion sequence starts with a ... (ellipsis) conversion, instead of
252     /// a standard conversion. In this case, 'Before' field must be ignored.
253     // FIXME. I much rather put this as the first field. But there seems to be
254     // a gcc code gen. bug which causes a crash in a test. Putting it here seems
255     // to work around the crash.
256     bool EllipsisConversion : 1;
257 
258     /// HadMultipleCandidates - When this is true, it means that the
259     /// conversion function was resolved from an overloaded set having
260     /// size greater than 1.
261     bool HadMultipleCandidates : 1;
262 
263     /// After - Represents the standard conversion that occurs after
264     /// the actual user-defined conversion.
265     StandardConversionSequence After;
266 
267     /// ConversionFunction - The function that will perform the
268     /// user-defined conversion. Null if the conversion is an
269     /// aggregate initialization from an initializer list.
270     FunctionDecl* ConversionFunction;
271 
272     /// \brief The declaration that we found via name lookup, which might be
273     /// the same as \c ConversionFunction or it might be a using declaration
274     /// that refers to \c ConversionFunction.
275     DeclAccessPair FoundConversionFunction;
276 
277     void dump() const;
278   };
279 
280   /// Represents an ambiguous user-defined conversion sequence.
281   struct AmbiguousConversionSequence {
282     typedef SmallVector<FunctionDecl*, 4> ConversionSet;
283 
284     void *FromTypePtr;
285     void *ToTypePtr;
286     char Buffer[sizeof(ConversionSet)];
287 
getFromTypeAmbiguousConversionSequence288     QualType getFromType() const {
289       return QualType::getFromOpaquePtr(FromTypePtr);
290     }
getToTypeAmbiguousConversionSequence291     QualType getToType() const {
292       return QualType::getFromOpaquePtr(ToTypePtr);
293     }
setFromTypeAmbiguousConversionSequence294     void setFromType(QualType T) { FromTypePtr = T.getAsOpaquePtr(); }
setToTypeAmbiguousConversionSequence295     void setToType(QualType T) { ToTypePtr = T.getAsOpaquePtr(); }
296 
conversionsAmbiguousConversionSequence297     ConversionSet &conversions() {
298       return *reinterpret_cast<ConversionSet*>(Buffer);
299     }
300 
conversionsAmbiguousConversionSequence301     const ConversionSet &conversions() const {
302       return *reinterpret_cast<const ConversionSet*>(Buffer);
303     }
304 
addConversionAmbiguousConversionSequence305     void addConversion(FunctionDecl *D) {
306       conversions().push_back(D);
307     }
308 
309     typedef ConversionSet::iterator iterator;
beginAmbiguousConversionSequence310     iterator begin() { return conversions().begin(); }
endAmbiguousConversionSequence311     iterator end() { return conversions().end(); }
312 
313     typedef ConversionSet::const_iterator const_iterator;
beginAmbiguousConversionSequence314     const_iterator begin() const { return conversions().begin(); }
endAmbiguousConversionSequence315     const_iterator end() const { return conversions().end(); }
316 
317     void construct();
318     void destruct();
319     void copyFrom(const AmbiguousConversionSequence &);
320   };
321 
322   /// BadConversionSequence - Records information about an invalid
323   /// conversion sequence.
324   struct BadConversionSequence {
325     enum FailureKind {
326       no_conversion,
327       unrelated_class,
328       bad_qualifiers,
329       lvalue_ref_to_rvalue,
330       rvalue_ref_to_lvalue
331     };
332 
333     // This can be null, e.g. for implicit object arguments.
334     Expr *FromExpr;
335 
336     FailureKind Kind;
337 
338   private:
339     // The type we're converting from (an opaque QualType).
340     void *FromTy;
341 
342     // The type we're converting to (an opaque QualType).
343     void *ToTy;
344 
345   public:
initBadConversionSequence346     void init(FailureKind K, Expr *From, QualType To) {
347       init(K, From->getType(), To);
348       FromExpr = From;
349     }
initBadConversionSequence350     void init(FailureKind K, QualType From, QualType To) {
351       Kind = K;
352       FromExpr = nullptr;
353       setFromType(From);
354       setToType(To);
355     }
356 
getFromTypeBadConversionSequence357     QualType getFromType() const { return QualType::getFromOpaquePtr(FromTy); }
getToTypeBadConversionSequence358     QualType getToType() const { return QualType::getFromOpaquePtr(ToTy); }
359 
setFromExprBadConversionSequence360     void setFromExpr(Expr *E) {
361       FromExpr = E;
362       setFromType(E->getType());
363     }
setFromTypeBadConversionSequence364     void setFromType(QualType T) { FromTy = T.getAsOpaquePtr(); }
setToTypeBadConversionSequence365     void setToType(QualType T) { ToTy = T.getAsOpaquePtr(); }
366   };
367 
368   /// ImplicitConversionSequence - Represents an implicit conversion
369   /// sequence, which may be a standard conversion sequence
370   /// (C++ 13.3.3.1.1), user-defined conversion sequence (C++ 13.3.3.1.2),
371   /// or an ellipsis conversion sequence (C++ 13.3.3.1.3).
372   class ImplicitConversionSequence {
373   public:
374     /// Kind - The kind of implicit conversion sequence. BadConversion
375     /// specifies that there is no conversion from the source type to
376     /// the target type.  AmbiguousConversion represents the unique
377     /// ambiguous conversion (C++0x [over.best.ics]p10).
378     enum Kind {
379       StandardConversion = 0,
380       UserDefinedConversion,
381       AmbiguousConversion,
382       EllipsisConversion,
383       BadConversion
384     };
385 
386   private:
387     enum {
388       Uninitialized = BadConversion + 1
389     };
390 
391     /// ConversionKind - The kind of implicit conversion sequence.
392     unsigned ConversionKind : 30;
393 
394     /// \brief Whether the target is really a std::initializer_list, and the
395     /// sequence only represents the worst element conversion.
396     bool StdInitializerListElement : 1;
397 
setKind(Kind K)398     void setKind(Kind K) {
399       destruct();
400       ConversionKind = K;
401     }
402 
destruct()403     void destruct() {
404       if (ConversionKind == AmbiguousConversion) Ambiguous.destruct();
405     }
406 
407   public:
408     union {
409       /// When ConversionKind == StandardConversion, provides the
410       /// details of the standard conversion sequence.
411       StandardConversionSequence Standard;
412 
413       /// When ConversionKind == UserDefinedConversion, provides the
414       /// details of the user-defined conversion sequence.
415       UserDefinedConversionSequence UserDefined;
416 
417       /// When ConversionKind == AmbiguousConversion, provides the
418       /// details of the ambiguous conversion.
419       AmbiguousConversionSequence Ambiguous;
420 
421       /// When ConversionKind == BadConversion, provides the details
422       /// of the bad conversion.
423       BadConversionSequence Bad;
424     };
425 
ImplicitConversionSequence()426     ImplicitConversionSequence()
427       : ConversionKind(Uninitialized), StdInitializerListElement(false)
428     {}
~ImplicitConversionSequence()429     ~ImplicitConversionSequence() {
430       destruct();
431     }
ImplicitConversionSequence(const ImplicitConversionSequence & Other)432     ImplicitConversionSequence(const ImplicitConversionSequence &Other)
433       : ConversionKind(Other.ConversionKind),
434         StdInitializerListElement(Other.StdInitializerListElement)
435     {
436       switch (ConversionKind) {
437       case Uninitialized: break;
438       case StandardConversion: Standard = Other.Standard; break;
439       case UserDefinedConversion: UserDefined = Other.UserDefined; break;
440       case AmbiguousConversion: Ambiguous.copyFrom(Other.Ambiguous); break;
441       case EllipsisConversion: break;
442       case BadConversion: Bad = Other.Bad; break;
443       }
444     }
445 
446     ImplicitConversionSequence &
447         operator=(const ImplicitConversionSequence &Other) {
448       destruct();
449       new (this) ImplicitConversionSequence(Other);
450       return *this;
451     }
452 
getKind()453     Kind getKind() const {
454       assert(isInitialized() && "querying uninitialized conversion");
455       return Kind(ConversionKind);
456     }
457 
458     /// \brief Return a ranking of the implicit conversion sequence
459     /// kind, where smaller ranks represent better conversion
460     /// sequences.
461     ///
462     /// In particular, this routine gives user-defined conversion
463     /// sequences and ambiguous conversion sequences the same rank,
464     /// per C++ [over.best.ics]p10.
getKindRank()465     unsigned getKindRank() const {
466       switch (getKind()) {
467       case StandardConversion:
468         return 0;
469 
470       case UserDefinedConversion:
471       case AmbiguousConversion:
472         return 1;
473 
474       case EllipsisConversion:
475         return 2;
476 
477       case BadConversion:
478         return 3;
479       }
480 
481       llvm_unreachable("Invalid ImplicitConversionSequence::Kind!");
482     }
483 
isBad()484     bool isBad() const { return getKind() == BadConversion; }
isStandard()485     bool isStandard() const { return getKind() == StandardConversion; }
isEllipsis()486     bool isEllipsis() const { return getKind() == EllipsisConversion; }
isAmbiguous()487     bool isAmbiguous() const { return getKind() == AmbiguousConversion; }
isUserDefined()488     bool isUserDefined() const { return getKind() == UserDefinedConversion; }
isFailure()489     bool isFailure() const { return isBad() || isAmbiguous(); }
490 
491     /// Determines whether this conversion sequence has been
492     /// initialized.  Most operations should never need to query
493     /// uninitialized conversions and should assert as above.
isInitialized()494     bool isInitialized() const { return ConversionKind != Uninitialized; }
495 
496     /// Sets this sequence as a bad conversion for an explicit argument.
setBad(BadConversionSequence::FailureKind Failure,Expr * FromExpr,QualType ToType)497     void setBad(BadConversionSequence::FailureKind Failure,
498                 Expr *FromExpr, QualType ToType) {
499       setKind(BadConversion);
500       Bad.init(Failure, FromExpr, ToType);
501     }
502 
503     /// Sets this sequence as a bad conversion for an implicit argument.
setBad(BadConversionSequence::FailureKind Failure,QualType FromType,QualType ToType)504     void setBad(BadConversionSequence::FailureKind Failure,
505                 QualType FromType, QualType ToType) {
506       setKind(BadConversion);
507       Bad.init(Failure, FromType, ToType);
508     }
509 
setStandard()510     void setStandard() { setKind(StandardConversion); }
setEllipsis()511     void setEllipsis() { setKind(EllipsisConversion); }
setUserDefined()512     void setUserDefined() { setKind(UserDefinedConversion); }
setAmbiguous()513     void setAmbiguous() {
514       if (ConversionKind == AmbiguousConversion) return;
515       ConversionKind = AmbiguousConversion;
516       Ambiguous.construct();
517     }
518 
519     /// \brief Whether the target is really a std::initializer_list, and the
520     /// sequence only represents the worst element conversion.
isStdInitializerListElement()521     bool isStdInitializerListElement() const {
522       return StdInitializerListElement;
523     }
524 
525     void setStdInitializerListElement(bool V = true) {
526       StdInitializerListElement = V;
527     }
528 
529     // The result of a comparison between implicit conversion
530     // sequences. Use Sema::CompareImplicitConversionSequences to
531     // actually perform the comparison.
532     enum CompareKind {
533       Better = -1,
534       Indistinguishable = 0,
535       Worse = 1
536     };
537 
538     void DiagnoseAmbiguousConversion(Sema &S,
539                                      SourceLocation CaretLoc,
540                                      const PartialDiagnostic &PDiag) const;
541 
542     void dump() const;
543   };
544 
545   enum OverloadFailureKind {
546     ovl_fail_too_many_arguments,
547     ovl_fail_too_few_arguments,
548     ovl_fail_bad_conversion,
549     ovl_fail_bad_deduction,
550 
551     /// This conversion candidate was not considered because it
552     /// duplicates the work of a trivial or derived-to-base
553     /// conversion.
554     ovl_fail_trivial_conversion,
555 
556     /// This conversion candidate was not considered because it is
557     /// an illegal instantiation of a constructor temploid: it is
558     /// callable with one argument, we only have one argument, and
559     /// its first parameter type is exactly the type of the class.
560     ///
561     /// Defining such a constructor directly is illegal, and
562     /// template-argument deduction is supposed to ignore such
563     /// instantiations, but we can still get one with the right
564     /// kind of implicit instantiation.
565     ovl_fail_illegal_constructor,
566 
567     /// This conversion candidate is not viable because its result
568     /// type is not implicitly convertible to the desired type.
569     ovl_fail_bad_final_conversion,
570 
571     /// This conversion function template specialization candidate is not
572     /// viable because the final conversion was not an exact match.
573     ovl_fail_final_conversion_not_exact,
574 
575     /// (CUDA) This candidate was not viable because the callee
576     /// was not accessible from the caller's target (i.e. host->device,
577     /// global->host, device->host).
578     ovl_fail_bad_target,
579 
580     /// This candidate function was not viable because an enable_if
581     /// attribute disabled it.
582     ovl_fail_enable_if
583   };
584 
585   /// OverloadCandidate - A single candidate in an overload set (C++ 13.3).
586   struct OverloadCandidate {
587     /// Function - The actual function that this candidate
588     /// represents. When NULL, this is a built-in candidate
589     /// (C++ [over.oper]) or a surrogate for a conversion to a
590     /// function pointer or reference (C++ [over.call.object]).
591     FunctionDecl *Function;
592 
593     /// FoundDecl - The original declaration that was looked up /
594     /// invented / otherwise found, together with its access.
595     /// Might be a UsingShadowDecl or a FunctionTemplateDecl.
596     DeclAccessPair FoundDecl;
597 
598     // BuiltinTypes - Provides the return and parameter types of a
599     // built-in overload candidate. Only valid when Function is NULL.
600     struct {
601       QualType ResultTy;
602       QualType ParamTypes[3];
603     } BuiltinTypes;
604 
605     /// Surrogate - The conversion function for which this candidate
606     /// is a surrogate, but only if IsSurrogate is true.
607     CXXConversionDecl *Surrogate;
608 
609     /// Conversions - The conversion sequences used to convert the
610     /// function arguments to the function parameters, the pointer points to a
611     /// fixed size array with NumConversions elements. The memory is owned by
612     /// the OverloadCandidateSet.
613     ImplicitConversionSequence *Conversions;
614 
615     /// The FixIt hints which can be used to fix the Bad candidate.
616     ConversionFixItGenerator Fix;
617 
618     /// NumConversions - The number of elements in the Conversions array.
619     unsigned NumConversions;
620 
621     /// Viable - True to indicate that this overload candidate is viable.
622     bool Viable;
623 
624     /// IsSurrogate - True to indicate that this candidate is a
625     /// surrogate for a conversion to a function pointer or reference
626     /// (C++ [over.call.object]).
627     bool IsSurrogate;
628 
629     /// IgnoreObjectArgument - True to indicate that the first
630     /// argument's conversion, which for this function represents the
631     /// implicit object argument, should be ignored. This will be true
632     /// when the candidate is a static member function (where the
633     /// implicit object argument is just a placeholder) or a
634     /// non-static member function when the call doesn't have an
635     /// object argument.
636     bool IgnoreObjectArgument;
637 
638     /// FailureKind - The reason why this candidate is not viable.
639     /// Actually an OverloadFailureKind.
640     unsigned char FailureKind;
641 
642     /// \brief The number of call arguments that were explicitly provided,
643     /// to be used while performing partial ordering of function templates.
644     unsigned ExplicitCallArguments;
645 
646     union {
647       DeductionFailureInfo DeductionFailure;
648 
649       /// FinalConversion - For a conversion function (where Function is
650       /// a CXXConversionDecl), the standard conversion that occurs
651       /// after the call to the overload candidate to convert the result
652       /// of calling the conversion function to the required type.
653       StandardConversionSequence FinalConversion;
654     };
655 
656     /// hasAmbiguousConversion - Returns whether this overload
657     /// candidate requires an ambiguous conversion or not.
hasAmbiguousConversionOverloadCandidate658     bool hasAmbiguousConversion() const {
659       for (unsigned i = 0, e = NumConversions; i != e; ++i) {
660         if (!Conversions[i].isInitialized()) return false;
661         if (Conversions[i].isAmbiguous()) return true;
662       }
663       return false;
664     }
665 
TryToFixBadConversionOverloadCandidate666     bool TryToFixBadConversion(unsigned Idx, Sema &S) {
667       bool CanFix = Fix.tryToFixConversion(
668                       Conversions[Idx].Bad.FromExpr,
669                       Conversions[Idx].Bad.getFromType(),
670                       Conversions[Idx].Bad.getToType(), S);
671 
672       // If at least one conversion fails, the candidate cannot be fixed.
673       if (!CanFix)
674         Fix.clear();
675 
676       return CanFix;
677     }
678 
getNumParamsOverloadCandidate679     unsigned getNumParams() const {
680       if (IsSurrogate) {
681         auto STy = Surrogate->getConversionType();
682         while (STy->isPointerType() || STy->isReferenceType())
683           STy = STy->getPointeeType();
684         return STy->getAs<FunctionProtoType>()->getNumParams();
685       }
686       if (Function)
687         return Function->getNumParams();
688       return ExplicitCallArguments;
689     }
690   };
691 
692   /// OverloadCandidateSet - A set of overload candidates, used in C++
693   /// overload resolution (C++ 13.3).
694   class OverloadCandidateSet {
695   public:
696     enum CandidateSetKind {
697       /// Normal lookup.
698       CSK_Normal,
699       /// Lookup for candidates for a call using operator syntax. Candidates
700       /// that have no parameters of class type will be skipped unless there
701       /// is a parameter of (reference to) enum type and the corresponding
702       /// argument is of the same enum type.
703       CSK_Operator
704     };
705 
706   private:
707     SmallVector<OverloadCandidate, 16> Candidates;
708     llvm::SmallPtrSet<Decl *, 16> Functions;
709 
710     // Allocator for OverloadCandidate::Conversions. We store the first few
711     // elements inline to avoid allocation for small sets.
712     llvm::BumpPtrAllocator ConversionSequenceAllocator;
713 
714     SourceLocation Loc;
715     CandidateSetKind Kind;
716 
717     unsigned NumInlineSequences;
718     llvm::AlignedCharArray<llvm::AlignOf<ImplicitConversionSequence>::Alignment,
719                            16 * sizeof(ImplicitConversionSequence)> InlineSpace;
720 
721     OverloadCandidateSet(const OverloadCandidateSet &) = delete;
722     void operator=(const OverloadCandidateSet &) = delete;
723 
724     void destroyCandidates();
725 
726   public:
OverloadCandidateSet(SourceLocation Loc,CandidateSetKind CSK)727     OverloadCandidateSet(SourceLocation Loc, CandidateSetKind CSK)
728         : Loc(Loc), Kind(CSK), NumInlineSequences(0) {}
~OverloadCandidateSet()729     ~OverloadCandidateSet() { destroyCandidates(); }
730 
getLocation()731     SourceLocation getLocation() const { return Loc; }
getKind()732     CandidateSetKind getKind() const { return Kind; }
733 
734     /// \brief Determine when this overload candidate will be new to the
735     /// overload set.
isNewCandidate(Decl * F)736     bool isNewCandidate(Decl *F) {
737       return Functions.insert(F->getCanonicalDecl()).second;
738     }
739 
740     /// \brief Clear out all of the candidates.
741     void clear();
742 
743     typedef SmallVectorImpl<OverloadCandidate>::iterator iterator;
begin()744     iterator begin() { return Candidates.begin(); }
end()745     iterator end() { return Candidates.end(); }
746 
size()747     size_t size() const { return Candidates.size(); }
empty()748     bool empty() const { return Candidates.empty(); }
749 
750     /// \brief Add a new candidate with NumConversions conversion sequence slots
751     /// to the overload set.
752     OverloadCandidate &addCandidate(unsigned NumConversions = 0) {
753       Candidates.push_back(OverloadCandidate());
754       OverloadCandidate &C = Candidates.back();
755 
756       // Assign space from the inline array if there are enough free slots
757       // available.
758       if (NumConversions + NumInlineSequences <= 16) {
759         ImplicitConversionSequence *I =
760             (ImplicitConversionSequence *)InlineSpace.buffer;
761         C.Conversions = &I[NumInlineSequences];
762         NumInlineSequences += NumConversions;
763       } else {
764         // Otherwise get memory from the allocator.
765         C.Conversions = ConversionSequenceAllocator
766                           .Allocate<ImplicitConversionSequence>(NumConversions);
767       }
768 
769       // Construct the new objects.
770       for (unsigned i = 0; i != NumConversions; ++i)
771         new (&C.Conversions[i]) ImplicitConversionSequence();
772 
773       C.NumConversions = NumConversions;
774       return C;
775     }
776 
777     /// Find the best viable function on this overload set, if it exists.
778     OverloadingResult BestViableFunction(Sema &S, SourceLocation Loc,
779                                          OverloadCandidateSet::iterator& Best,
780                                          bool UserDefinedConversion = false);
781 
782     void NoteCandidates(Sema &S,
783                         OverloadCandidateDisplayKind OCD,
784                         ArrayRef<Expr *> Args,
785                         StringRef Opc = "",
786                         SourceLocation Loc = SourceLocation());
787   };
788 
789   bool isBetterOverloadCandidate(Sema &S,
790                                  const OverloadCandidate& Cand1,
791                                  const OverloadCandidate& Cand2,
792                                  SourceLocation Loc,
793                                  bool UserDefinedConversion = false);
794 } // end namespace clang
795 
796 #endif // LLVM_CLANG_SEMA_OVERLOAD_H
797