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//===- DeclarationName.h - Representation of declaration names --*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file declares the DeclarationName and DeclarationNameTable classes.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_CLANG_AST_DECLARATIONNAME_H
#define LLVM_CLANG_AST_DECLARATIONNAME_H
#include "clang/AST/Type.h"
#include "clang/Basic/Diagnostic.h"
#include "clang/Basic/IdentifierTable.h"
#include "clang/Basic/OperatorKinds.h"
#include "clang/Basic/PartialDiagnostic.h"
#include "clang/Basic/SourceLocation.h"
#include "llvm/ADT/DenseMapInfo.h"
#include "llvm/ADT/FoldingSet.h"
#include "llvm/Support/Compiler.h"
#include "llvm/Support/type_traits.h"
#include <cassert>
#include <cstdint>
#include <cstring>
#include <string>
namespace clang {
class ASTContext;
template <typename> class CanQual;
class DeclarationName;
class DeclarationNameTable;
class MultiKeywordSelector;
struct PrintingPolicy;
class TemplateDecl;
class TypeSourceInfo;
class UsingDirectiveDecl;
using CanQualType = CanQual<Type>;
namespace detail {
/// CXXSpecialNameExtra records the type associated with one of the "special"
/// kinds of declaration names in C++, e.g., constructors, destructors, and
/// conversion functions. Note that CXXSpecialName is used for C++ constructor,
/// destructor and conversion functions, but the actual kind is not stored in
/// CXXSpecialName. Instead we use three different FoldingSet<CXXSpecialName>
/// in DeclarationNameTable.
class alignas(IdentifierInfoAlignment) CXXSpecialNameExtra
: public llvm::FoldingSetNode {
friend class clang::DeclarationName;
friend class clang::DeclarationNameTable;
/// The type associated with this declaration name.
QualType Type;
/// Extra information associated with this declaration name that
/// can be used by the front end. All bits are really needed
/// so it is not possible to stash something in the low order bits.
void *FETokenInfo;
CXXSpecialNameExtra(QualType QT) : Type(QT), FETokenInfo(nullptr) {}
public:
void Profile(llvm::FoldingSetNodeID &ID) {
ID.AddPointer(Type.getAsOpaquePtr());
}
};
/// Contains extra information for the name of a C++ deduction guide.
class alignas(IdentifierInfoAlignment) CXXDeductionGuideNameExtra
: public detail::DeclarationNameExtra,
public llvm::FoldingSetNode {
friend class clang::DeclarationName;
friend class clang::DeclarationNameTable;
/// The template named by the deduction guide.
TemplateDecl *Template;
/// Extra information associated with this operator name that
/// can be used by the front end. All bits are really needed
/// so it is not possible to stash something in the low order bits.
void *FETokenInfo;
CXXDeductionGuideNameExtra(TemplateDecl *TD)
: DeclarationNameExtra(CXXDeductionGuideName), Template(TD),
FETokenInfo(nullptr) {}
public:
void Profile(llvm::FoldingSetNodeID &ID) { ID.AddPointer(Template); }
};
/// Contains extra information for the name of an overloaded operator
/// in C++, such as "operator+. This do not includes literal or conversion
/// operators. For literal operators see CXXLiteralOperatorIdName and for
/// conversion operators see CXXSpecialNameExtra.
class alignas(IdentifierInfoAlignment) CXXOperatorIdName {
friend class clang::DeclarationName;
friend class clang::DeclarationNameTable;
/// The kind of this operator.
OverloadedOperatorKind Kind = OO_None;
/// Extra information associated with this operator name that
/// can be used by the front end. All bits are really needed
/// so it is not possible to stash something in the low order bits.
void *FETokenInfo = nullptr;
};
/// Contains the actual identifier that makes up the
/// name of a C++ literal operator.
class alignas(IdentifierInfoAlignment) CXXLiteralOperatorIdName
: public detail::DeclarationNameExtra,
public llvm::FoldingSetNode {
friend class clang::DeclarationName;
friend class clang::DeclarationNameTable;
IdentifierInfo *ID;
/// Extra information associated with this operator name that
/// can be used by the front end. All bits are really needed
/// so it is not possible to stash something in the low order bits.
void *FETokenInfo;
CXXLiteralOperatorIdName(IdentifierInfo *II)
: DeclarationNameExtra(CXXLiteralOperatorName), ID(II),
FETokenInfo(nullptr) {}
public:
void Profile(llvm::FoldingSetNodeID &FSID) { FSID.AddPointer(ID); }
};
} // namespace detail
/// The name of a declaration. In the common case, this just stores
/// an IdentifierInfo pointer to a normal name. However, it also provides
/// encodings for Objective-C selectors (optimizing zero- and one-argument
/// selectors, which make up 78% percent of all selectors in Cocoa.h),
/// special C++ names for constructors, destructors, and conversion functions,
/// and C++ overloaded operators.
class DeclarationName {
friend class DeclarationNameTable;
friend class NamedDecl;
/// StoredNameKind represent the kind of name that is actually stored in the
/// upper bits of the Ptr field. This is only used internally.
///
/// NameKind, StoredNameKind, and DeclarationNameExtra::ExtraKind
/// must satisfy the following properties. These properties enable
/// efficient conversion between the various kinds.
///
/// * The first seven enumerators of StoredNameKind must have the same
/// numerical value as the first seven enumerators of NameKind.
/// This enable efficient conversion between the two enumerations
/// in the usual case.
///
/// * The enumerations values of DeclarationNameExtra::ExtraKind must start
/// at zero, and correspond to the numerical value of the first non-inline
/// enumeration values of NameKind minus an offset. This makes conversion
/// between DeclarationNameExtra::ExtraKind and NameKind possible with
/// a single addition/substraction.
///
/// * The enumeration values of Selector::IdentifierInfoFlag must correspond
/// to the relevant enumeration values of StoredNameKind.
/// More specifically:
/// * ZeroArg == StoredObjCZeroArgSelector,
/// * OneArg == StoredObjCOneArgSelector,
/// * MultiArg == StoredDeclarationNameExtra
///
/// * PtrMask must mask the low 3 bits of Ptr.
enum StoredNameKind {
StoredIdentifier = 0,
StoredObjCZeroArgSelector = Selector::ZeroArg,
StoredObjCOneArgSelector = Selector::OneArg,
StoredCXXConstructorName = 3,
StoredCXXDestructorName = 4,
StoredCXXConversionFunctionName = 5,
StoredCXXOperatorName = 6,
StoredDeclarationNameExtra = Selector::MultiArg,
PtrMask = 7,
UncommonNameKindOffset = 8
};
static_assert(alignof(IdentifierInfo) >= 8 &&
alignof(detail::DeclarationNameExtra) >= 8 &&
alignof(detail::CXXSpecialNameExtra) >= 8 &&
alignof(detail::CXXOperatorIdName) >= 8 &&
alignof(detail::CXXDeductionGuideNameExtra) >= 8 &&
alignof(detail::CXXLiteralOperatorIdName) >= 8,
"The various classes that DeclarationName::Ptr can point to"
" must be at least aligned to 8 bytes!");
public:
/// The kind of the name stored in this DeclarationName.
/// The first 7 enumeration values are stored inline and correspond
/// to frequently used kinds. The rest is stored in DeclarationNameExtra
/// and correspond to infrequently used kinds.
enum NameKind {
Identifier = StoredIdentifier,
ObjCZeroArgSelector = StoredObjCZeroArgSelector,
ObjCOneArgSelector = StoredObjCOneArgSelector,
CXXConstructorName = StoredCXXConstructorName,
CXXDestructorName = StoredCXXDestructorName,
CXXConversionFunctionName = StoredCXXConversionFunctionName,
CXXOperatorName = StoredCXXOperatorName,
CXXDeductionGuideName = UncommonNameKindOffset +
detail::DeclarationNameExtra::CXXDeductionGuideName,
CXXLiteralOperatorName =
UncommonNameKindOffset +
detail::DeclarationNameExtra::CXXLiteralOperatorName,
CXXUsingDirective = UncommonNameKindOffset +
detail::DeclarationNameExtra::CXXUsingDirective,
ObjCMultiArgSelector = UncommonNameKindOffset +
detail::DeclarationNameExtra::ObjCMultiArgSelector
};
private:
/// The lowest three bits of Ptr are used to express what kind of name
/// we're actually storing, using the values of StoredNameKind. Depending
/// on the kind of name this is, the upper bits of Ptr may have one
/// of several different meanings:
///
/// StoredIdentifier - The name is a normal identifier, and Ptr is
/// a normal IdentifierInfo pointer.
///
/// StoredObjCZeroArgSelector - The name is an Objective-C
/// selector with zero arguments, and Ptr is an IdentifierInfo
/// pointer pointing to the selector name.
///
/// StoredObjCOneArgSelector - The name is an Objective-C selector
/// with one argument, and Ptr is an IdentifierInfo pointer
/// pointing to the selector name.
///
/// StoredCXXConstructorName - The name of a C++ constructor,
/// Ptr points to a CXXSpecialNameExtra.
///
/// StoredCXXDestructorName - The name of a C++ destructor,
/// Ptr points to a CXXSpecialNameExtra.
///
/// StoredCXXConversionFunctionName - The name of a C++ conversion function,
/// Ptr points to a CXXSpecialNameExtra.
///
/// StoredCXXOperatorName - The name of an overloaded C++ operator,
/// Ptr points to a CXXOperatorIdName.
///
/// StoredDeclarationNameExtra - Ptr is actually a pointer to a
/// DeclarationNameExtra structure, whose first value will tell us
/// whether this is an Objective-C selector, C++ deduction guide,
/// C++ literal operator, or C++ using directive.
uintptr_t Ptr = 0;
StoredNameKind getStoredNameKind() const {
return static_cast<StoredNameKind>(Ptr & PtrMask);
}
void *getPtr() const { return reinterpret_cast<void *>(Ptr & ~PtrMask); }
void setPtrAndKind(const void *P, StoredNameKind Kind) {
uintptr_t PAsInteger = reinterpret_cast<uintptr_t>(P);
assert((Kind & ~PtrMask) == 0 &&
"Invalid StoredNameKind in setPtrAndKind!");
assert((PAsInteger & PtrMask) == 0 &&
"Improperly aligned pointer in setPtrAndKind!");
Ptr = PAsInteger | Kind;
}
/// Construct a declaration name from a DeclarationNameExtra.
DeclarationName(detail::DeclarationNameExtra *Name) {
setPtrAndKind(Name, StoredDeclarationNameExtra);
}
/// Construct a declaration name from a CXXSpecialNameExtra.
DeclarationName(detail::CXXSpecialNameExtra *Name,
StoredNameKind StoredKind) {
assert((StoredKind == StoredCXXConstructorName ||
StoredKind == StoredCXXDestructorName ||
StoredKind == StoredCXXConversionFunctionName) &&
"Invalid StoredNameKind when constructing a DeclarationName"
" from a CXXSpecialNameExtra!");
setPtrAndKind(Name, StoredKind);
}
/// Construct a DeclarationName from a CXXOperatorIdName.
DeclarationName(detail::CXXOperatorIdName *Name) {
setPtrAndKind(Name, StoredCXXOperatorName);
}
/// Assert that the stored pointer points to an IdentifierInfo and return it.
IdentifierInfo *castAsIdentifierInfo() const {
assert((getStoredNameKind() == StoredIdentifier) &&
"DeclarationName does not store an IdentifierInfo!");
return static_cast<IdentifierInfo *>(getPtr());
}
/// Assert that the stored pointer points to a DeclarationNameExtra
/// and return it.
detail::DeclarationNameExtra *castAsExtra() const {
assert((getStoredNameKind() == StoredDeclarationNameExtra) &&
"DeclarationName does not store an Extra structure!");
return static_cast<detail::DeclarationNameExtra *>(getPtr());
}
/// Assert that the stored pointer points to a CXXSpecialNameExtra
/// and return it.
detail::CXXSpecialNameExtra *castAsCXXSpecialNameExtra() const {
assert((getStoredNameKind() == StoredCXXConstructorName ||
getStoredNameKind() == StoredCXXDestructorName ||
getStoredNameKind() == StoredCXXConversionFunctionName) &&
"DeclarationName does not store a CXXSpecialNameExtra!");
return static_cast<detail::CXXSpecialNameExtra *>(getPtr());
}
/// Assert that the stored pointer points to a CXXOperatorIdName
/// and return it.
detail::CXXOperatorIdName *castAsCXXOperatorIdName() const {
assert((getStoredNameKind() == StoredCXXOperatorName) &&
"DeclarationName does not store a CXXOperatorIdName!");
return static_cast<detail::CXXOperatorIdName *>(getPtr());
}
/// Assert that the stored pointer points to a CXXDeductionGuideNameExtra
/// and return it.
detail::CXXDeductionGuideNameExtra *castAsCXXDeductionGuideNameExtra() const {
assert(getNameKind() == CXXDeductionGuideName &&
"DeclarationName does not store a CXXDeductionGuideNameExtra!");
return static_cast<detail::CXXDeductionGuideNameExtra *>(getPtr());
}
/// Assert that the stored pointer points to a CXXLiteralOperatorIdName
/// and return it.
detail::CXXLiteralOperatorIdName *castAsCXXLiteralOperatorIdName() const {
assert(getNameKind() == CXXLiteralOperatorName &&
"DeclarationName does not store a CXXLiteralOperatorIdName!");
return static_cast<detail::CXXLiteralOperatorIdName *>(getPtr());
}
/// Get and set the FETokenInfo in the less common cases where the
/// declaration name do not point to an identifier.
void *getFETokenInfoSlow() const;
void setFETokenInfoSlow(void *T);
public:
/// Construct an empty declaration name.
DeclarationName() { setPtrAndKind(nullptr, StoredIdentifier); }
/// Construct a declaration name from an IdentifierInfo *.
DeclarationName(const IdentifierInfo *II) {
setPtrAndKind(II, StoredIdentifier);
}
/// Construct a declaration name from an Objective-C selector.
DeclarationName(Selector Sel) : Ptr(Sel.InfoPtr) {}
/// Returns the name for all C++ using-directives.
static DeclarationName getUsingDirectiveName() {
// Single instance of DeclarationNameExtra for using-directive
static detail::DeclarationNameExtra UDirExtra(
detail::DeclarationNameExtra::CXXUsingDirective);
return DeclarationName(&UDirExtra);
}
/// Evaluates true when this declaration name is non-empty.
explicit operator bool() const {
return getPtr() || (getStoredNameKind() != StoredIdentifier);
}
/// Evaluates true when this declaration name is empty.
bool isEmpty() const { return !*this; }
/// Predicate functions for querying what type of name this is.
bool isIdentifier() const { return getStoredNameKind() == StoredIdentifier; }
bool isObjCZeroArgSelector() const {
return getStoredNameKind() == StoredObjCZeroArgSelector;
}
bool isObjCOneArgSelector() const {
return getStoredNameKind() == StoredObjCOneArgSelector;
}
/// Determine what kind of name this is.
NameKind getNameKind() const {
// We rely on the fact that the first 7 NameKind and StoredNameKind
// have the same numerical value. This makes the usual case efficient.
StoredNameKind StoredKind = getStoredNameKind();
if (StoredKind != StoredDeclarationNameExtra)
return static_cast<NameKind>(StoredKind);
// We have to consult DeclarationNameExtra. We rely on the fact that the
// enumeration values of ExtraKind correspond to the enumeration values of
// NameKind minus an offset of UncommonNameKindOffset.
unsigned ExtraKind = castAsExtra()->getKind();
return static_cast<NameKind>(UncommonNameKindOffset + ExtraKind);
}
/// Determines whether the name itself is dependent, e.g., because it
/// involves a C++ type that is itself dependent.
///
/// Note that this does not capture all of the notions of "dependent name",
/// because an identifier can be a dependent name if it is used as the
/// callee in a call expression with dependent arguments.
bool isDependentName() const;
/// Retrieve the human-readable string for this name.
std::string getAsString() const;
/// Retrieve the IdentifierInfo * stored in this declaration name,
/// or null if this declaration name isn't a simple identifier.
IdentifierInfo *getAsIdentifierInfo() const {
if (isIdentifier())
return castAsIdentifierInfo();
return nullptr;
}
/// Get the representation of this declaration name as an opaque integer.
uintptr_t getAsOpaqueInteger() const { return Ptr; }
/// Get the representation of this declaration name as an opaque pointer.
void *getAsOpaquePtr() const { return reinterpret_cast<void *>(Ptr); }
/// Get a declaration name from an opaque pointer returned by getAsOpaquePtr.
static DeclarationName getFromOpaquePtr(void *P) {
DeclarationName N;
N.Ptr = reinterpret_cast<uintptr_t>(P);
return N;
}
/// Get a declaration name from an opaque integer
/// returned by getAsOpaqueInteger.
static DeclarationName getFromOpaqueInteger(uintptr_t P) {
DeclarationName N;
N.Ptr = P;
return N;
}
/// If this name is one of the C++ names (of a constructor, destructor,
/// or conversion function), return the type associated with that name.
QualType getCXXNameType() const {
if (getStoredNameKind() == StoredCXXConstructorName ||
getStoredNameKind() == StoredCXXDestructorName ||
getStoredNameKind() == StoredCXXConversionFunctionName) {
assert(getPtr() && "getCXXNameType on a null DeclarationName!");
return castAsCXXSpecialNameExtra()->Type;
}
return QualType();
}
/// If this name is the name of a C++ deduction guide, return the
/// template associated with that name.
TemplateDecl *getCXXDeductionGuideTemplate() const {
if (getNameKind() == CXXDeductionGuideName) {
assert(getPtr() &&
"getCXXDeductionGuideTemplate on a null DeclarationName!");
return castAsCXXDeductionGuideNameExtra()->Template;
}
return nullptr;
}
/// If this name is the name of an overloadable operator in C++
/// (e.g., @c operator+), retrieve the kind of overloaded operator.
OverloadedOperatorKind getCXXOverloadedOperator() const {
if (getStoredNameKind() == StoredCXXOperatorName) {
assert(getPtr() && "getCXXOverloadedOperator on a null DeclarationName!");
return castAsCXXOperatorIdName()->Kind;
}
return OO_None;
}
/// If this name is the name of a literal operator,
/// retrieve the identifier associated with it.
IdentifierInfo *getCXXLiteralIdentifier() const {
if (getNameKind() == CXXLiteralOperatorName) {
assert(getPtr() && "getCXXLiteralIdentifier on a null DeclarationName!");
return castAsCXXLiteralOperatorIdName()->ID;
}
return nullptr;
}
/// Get the Objective-C selector stored in this declaration name.
Selector getObjCSelector() const {
assert((getNameKind() == ObjCZeroArgSelector ||
getNameKind() == ObjCOneArgSelector ||
getNameKind() == ObjCMultiArgSelector || !getPtr()) &&
"Not a selector!");
return Selector(Ptr);
}
/// Get and set FETokenInfo. The language front-end is allowed to associate
/// arbitrary metadata with some kinds of declaration names, including normal
/// identifiers and C++ constructors, destructors, and conversion functions.
void *getFETokenInfo() const {
assert(getPtr() && "getFETokenInfo on an empty DeclarationName!");
if (getStoredNameKind() == StoredIdentifier)
return castAsIdentifierInfo()->getFETokenInfo();
return getFETokenInfoSlow();
}
void setFETokenInfo(void *T) {
assert(getPtr() && "setFETokenInfo on an empty DeclarationName!");
if (getStoredNameKind() == StoredIdentifier)
castAsIdentifierInfo()->setFETokenInfo(T);
else
setFETokenInfoSlow(T);
}
/// Determine whether the specified names are identical.
friend bool operator==(DeclarationName LHS, DeclarationName RHS) {
return LHS.Ptr == RHS.Ptr;
}
/// Determine whether the specified names are different.
friend bool operator!=(DeclarationName LHS, DeclarationName RHS) {
return LHS.Ptr != RHS.Ptr;
}
static DeclarationName getEmptyMarker() {
DeclarationName Name;
Name.Ptr = uintptr_t(-1);
return Name;
}
static DeclarationName getTombstoneMarker() {
DeclarationName Name;
Name.Ptr = uintptr_t(-2);
return Name;
}
static int compare(DeclarationName LHS, DeclarationName RHS);
void print(raw_ostream &OS, const PrintingPolicy &Policy);
void dump() const;
};
raw_ostream &operator<<(raw_ostream &OS, DeclarationName N);
/// Ordering on two declaration names. If both names are identifiers,
/// this provides a lexicographical ordering.
inline bool operator<(DeclarationName LHS, DeclarationName RHS) {
return DeclarationName::compare(LHS, RHS) < 0;
}
/// Ordering on two declaration names. If both names are identifiers,
/// this provides a lexicographical ordering.
inline bool operator>(DeclarationName LHS, DeclarationName RHS) {
return DeclarationName::compare(LHS, RHS) > 0;
}
/// Ordering on two declaration names. If both names are identifiers,
/// this provides a lexicographical ordering.
inline bool operator<=(DeclarationName LHS, DeclarationName RHS) {
return DeclarationName::compare(LHS, RHS) <= 0;
}
/// Ordering on two declaration names. If both names are identifiers,
/// this provides a lexicographical ordering.
inline bool operator>=(DeclarationName LHS, DeclarationName RHS) {
return DeclarationName::compare(LHS, RHS) >= 0;
}
/// DeclarationNameTable is used to store and retrieve DeclarationName
/// instances for the various kinds of declaration names, e.g., normal
/// identifiers, C++ constructor names, etc. This class contains
/// uniqued versions of each of the C++ special names, which can be
/// retrieved using its member functions (e.g., getCXXConstructorName).
class DeclarationNameTable {
/// Used to allocate elements in the FoldingSets below.
const ASTContext &Ctx;
/// Manage the uniqued CXXSpecialNameExtra representing C++ constructors.
/// getCXXConstructorName and getCXXSpecialName can be used to obtain
/// a DeclarationName from the corresponding type of the constructor.
llvm::FoldingSet<detail::CXXSpecialNameExtra> CXXConstructorNames;
/// Manage the uniqued CXXSpecialNameExtra representing C++ destructors.
/// getCXXDestructorName and getCXXSpecialName can be used to obtain
/// a DeclarationName from the corresponding type of the destructor.
llvm::FoldingSet<detail::CXXSpecialNameExtra> CXXDestructorNames;
/// Manage the uniqued CXXSpecialNameExtra representing C++ conversion
/// functions. getCXXConversionFunctionName and getCXXSpecialName can be
/// used to obtain a DeclarationName from the corresponding type of the
/// conversion function.
llvm::FoldingSet<detail::CXXSpecialNameExtra> CXXConversionFunctionNames;
/// Manage the uniqued CXXOperatorIdName, which contain extra information
/// for the name of overloaded C++ operators. getCXXOperatorName
/// can be used to obtain a DeclarationName from the operator kind.
detail::CXXOperatorIdName CXXOperatorNames[NUM_OVERLOADED_OPERATORS];
/// Manage the uniqued CXXLiteralOperatorIdName, which contain extra
/// information for the name of C++ literal operators.
/// getCXXLiteralOperatorName can be used to obtain a DeclarationName
/// from the corresponding IdentifierInfo.
llvm::FoldingSet<detail::CXXLiteralOperatorIdName> CXXLiteralOperatorNames;
/// Manage the uniqued CXXDeductionGuideNameExtra, which contain
/// extra information for the name of a C++ deduction guide.
/// getCXXDeductionGuideName can be used to obtain a DeclarationName
/// from the corresponding template declaration.
llvm::FoldingSet<detail::CXXDeductionGuideNameExtra> CXXDeductionGuideNames;
public:
DeclarationNameTable(const ASTContext &C);
DeclarationNameTable(const DeclarationNameTable &) = delete;
DeclarationNameTable &operator=(const DeclarationNameTable &) = delete;
DeclarationNameTable(DeclarationNameTable &&) = delete;
DeclarationNameTable &operator=(DeclarationNameTable &&) = delete;
~DeclarationNameTable() = default;
/// Create a declaration name that is a simple identifier.
DeclarationName getIdentifier(const IdentifierInfo *ID) {
return DeclarationName(ID);
}
/// Returns the name of a C++ constructor for the given Type.
DeclarationName getCXXConstructorName(CanQualType Ty);
/// Returns the name of a C++ destructor for the given Type.
DeclarationName getCXXDestructorName(CanQualType Ty);
/// Returns the name of a C++ deduction guide for the given template.
DeclarationName getCXXDeductionGuideName(TemplateDecl *TD);
/// Returns the name of a C++ conversion function for the given Type.
DeclarationName getCXXConversionFunctionName(CanQualType Ty);
/// Returns a declaration name for special kind of C++ name,
/// e.g., for a constructor, destructor, or conversion function.
/// Kind must be one of:
/// * DeclarationName::CXXConstructorName,
/// * DeclarationName::CXXDestructorName or
/// * DeclarationName::CXXConversionFunctionName
DeclarationName getCXXSpecialName(DeclarationName::NameKind Kind,
CanQualType Ty);
/// Get the name of the overloadable C++ operator corresponding to Op.
DeclarationName getCXXOperatorName(OverloadedOperatorKind Op) {
return DeclarationName(&CXXOperatorNames[Op]);
}
/// Get the name of the literal operator function with II as the identifier.
DeclarationName getCXXLiteralOperatorName(IdentifierInfo *II);
};
/// DeclarationNameLoc - Additional source/type location info
/// for a declaration name. Needs a DeclarationName in order
/// to be interpreted correctly.
struct DeclarationNameLoc {
// The source location for identifier stored elsewhere.
// struct {} Identifier;
// Type info for constructors, destructors and conversion functions.
// Locations (if any) for the tilde (destructor) or operator keyword
// (conversion) are stored elsewhere.
struct NT {
TypeSourceInfo *TInfo;
};
// The location (if any) of the operator keyword is stored elsewhere.
struct CXXOpName {
unsigned BeginOpNameLoc;
unsigned EndOpNameLoc;
};
// The location (if any) of the operator keyword is stored elsewhere.
struct CXXLitOpName {
unsigned OpNameLoc;
};
// struct {} CXXUsingDirective;
// struct {} ObjCZeroArgSelector;
// struct {} ObjCOneArgSelector;
// struct {} ObjCMultiArgSelector;
union {
struct NT NamedType;
struct CXXOpName CXXOperatorName;
struct CXXLitOpName CXXLiteralOperatorName;
};
DeclarationNameLoc(DeclarationName Name);
// FIXME: this should go away once all DNLocs are properly initialized.
DeclarationNameLoc() { memset((void*) this, 0, sizeof(*this)); }
};
/// DeclarationNameInfo - A collector data type for bundling together
/// a DeclarationName and the correspnding source/type location info.
struct DeclarationNameInfo {
private:
/// Name - The declaration name, also encoding name kind.
DeclarationName Name;
/// Loc - The main source location for the declaration name.
SourceLocation NameLoc;
/// Info - Further source/type location info for special kinds of names.
DeclarationNameLoc LocInfo;
public:
// FIXME: remove it.
DeclarationNameInfo() = default;
DeclarationNameInfo(DeclarationName Name, SourceLocation NameLoc)
: Name(Name), NameLoc(NameLoc), LocInfo(Name) {}
DeclarationNameInfo(DeclarationName Name, SourceLocation NameLoc,
DeclarationNameLoc LocInfo)
: Name(Name), NameLoc(NameLoc), LocInfo(LocInfo) {}
/// getName - Returns the embedded declaration name.
DeclarationName getName() const { return Name; }
/// setName - Sets the embedded declaration name.
void setName(DeclarationName N) { Name = N; }
/// getLoc - Returns the main location of the declaration name.
SourceLocation getLoc() const { return NameLoc; }
/// setLoc - Sets the main location of the declaration name.
void setLoc(SourceLocation L) { NameLoc = L; }
const DeclarationNameLoc &getInfo() const { return LocInfo; }
DeclarationNameLoc &getInfo() { return LocInfo; }
void setInfo(const DeclarationNameLoc &Info) { LocInfo = Info; }
/// getNamedTypeInfo - Returns the source type info associated to
/// the name. Assumes it is a constructor, destructor or conversion.
TypeSourceInfo *getNamedTypeInfo() const {
if (Name.getNameKind() != DeclarationName::CXXConstructorName &&
Name.getNameKind() != DeclarationName::CXXDestructorName &&
Name.getNameKind() != DeclarationName::CXXConversionFunctionName)
return nullptr;
return LocInfo.NamedType.TInfo;
}
/// setNamedTypeInfo - Sets the source type info associated to
/// the name. Assumes it is a constructor, destructor or conversion.
void setNamedTypeInfo(TypeSourceInfo *TInfo) {
assert(Name.getNameKind() == DeclarationName::CXXConstructorName ||
Name.getNameKind() == DeclarationName::CXXDestructorName ||
Name.getNameKind() == DeclarationName::CXXConversionFunctionName);
LocInfo.NamedType.TInfo = TInfo;
}
/// getCXXOperatorNameRange - Gets the range of the operator name
/// (without the operator keyword). Assumes it is a (non-literal) operator.
SourceRange getCXXOperatorNameRange() const {
if (Name.getNameKind() != DeclarationName::CXXOperatorName)
return SourceRange();
return SourceRange(
SourceLocation::getFromRawEncoding(LocInfo.CXXOperatorName.BeginOpNameLoc),
SourceLocation::getFromRawEncoding(LocInfo.CXXOperatorName.EndOpNameLoc)
);
}
/// setCXXOperatorNameRange - Sets the range of the operator name
/// (without the operator keyword). Assumes it is a C++ operator.
void setCXXOperatorNameRange(SourceRange R) {
assert(Name.getNameKind() == DeclarationName::CXXOperatorName);
LocInfo.CXXOperatorName.BeginOpNameLoc = R.getBegin().getRawEncoding();
LocInfo.CXXOperatorName.EndOpNameLoc = R.getEnd().getRawEncoding();
}
/// getCXXLiteralOperatorNameLoc - Returns the location of the literal
/// operator name (not the operator keyword).
/// Assumes it is a literal operator.
SourceLocation getCXXLiteralOperatorNameLoc() const {
if (Name.getNameKind() != DeclarationName::CXXLiteralOperatorName)
return SourceLocation();
return SourceLocation::
getFromRawEncoding(LocInfo.CXXLiteralOperatorName.OpNameLoc);
}
/// setCXXLiteralOperatorNameLoc - Sets the location of the literal
/// operator name (not the operator keyword).
/// Assumes it is a literal operator.
void setCXXLiteralOperatorNameLoc(SourceLocation Loc) {
assert(Name.getNameKind() == DeclarationName::CXXLiteralOperatorName);
LocInfo.CXXLiteralOperatorName.OpNameLoc = Loc.getRawEncoding();
}
/// Determine whether this name involves a template parameter.
bool isInstantiationDependent() const;
/// Determine whether this name contains an unexpanded
/// parameter pack.
bool containsUnexpandedParameterPack() const;
/// getAsString - Retrieve the human-readable string for this name.
std::string getAsString() const;
/// printName - Print the human-readable name to a stream.
void printName(raw_ostream &OS) const;
/// getBeginLoc - Retrieve the location of the first token.
SourceLocation getBeginLoc() const { return NameLoc; }
/// getSourceRange - The range of the declaration name.
SourceRange getSourceRange() const LLVM_READONLY {
return SourceRange(getBeginLoc(), getEndLoc());
}
SourceLocation getEndLoc() const LLVM_READONLY {
SourceLocation EndLoc = getEndLocPrivate();
return EndLoc.isValid() ? EndLoc : getBeginLoc();
}
private:
SourceLocation getEndLocPrivate() const;
};
/// Insertion operator for diagnostics. This allows sending DeclarationName's
/// into a diagnostic with <<.
inline const DiagnosticBuilder &operator<<(const DiagnosticBuilder &DB,
DeclarationName N) {
DB.AddTaggedVal(N.getAsOpaqueInteger(),
DiagnosticsEngine::ak_declarationname);
return DB;
}
/// Insertion operator for partial diagnostics. This allows binding
/// DeclarationName's into a partial diagnostic with <<.
inline const PartialDiagnostic &operator<<(const PartialDiagnostic &PD,
DeclarationName N) {
PD.AddTaggedVal(N.getAsOpaqueInteger(),
DiagnosticsEngine::ak_declarationname);
return PD;
}
inline raw_ostream &operator<<(raw_ostream &OS,
DeclarationNameInfo DNInfo) {
DNInfo.printName(OS);
return OS;
}
} // namespace clang
namespace llvm {
/// Define DenseMapInfo so that DeclarationNames can be used as keys
/// in DenseMap and DenseSets.
template<>
struct DenseMapInfo<clang::DeclarationName> {
static inline clang::DeclarationName getEmptyKey() {
return clang::DeclarationName::getEmptyMarker();
}
static inline clang::DeclarationName getTombstoneKey() {
return clang::DeclarationName::getTombstoneMarker();
}
static unsigned getHashValue(clang::DeclarationName Name) {
return DenseMapInfo<void*>::getHashValue(Name.getAsOpaquePtr());
}
static inline bool
isEqual(clang::DeclarationName LHS, clang::DeclarationName RHS) {
return LHS == RHS;
}
};
} // namespace llvm
// The definition of AssumedTemplateStorage is factored out of TemplateName to
// resolve a cyclic dependency between it and DeclarationName (via Type).
namespace clang {
/// A structure for storing the information associated with a name that has
/// been assumed to be a template name (despite finding no TemplateDecls).
class AssumedTemplateStorage : public UncommonTemplateNameStorage {
friend class ASTContext;
AssumedTemplateStorage(DeclarationName Name)
: UncommonTemplateNameStorage(Assumed, 0), Name(Name) {}
DeclarationName Name;
public:
/// Get the name of the template.
DeclarationName getDeclName() const { return Name; }
};
} // namespace clang
#endif // LLVM_CLANG_AST_DECLARATIONNAME_H