//===--- Specifiers.h - Declaration and Type Specifiers ---------*- 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
//
//===----------------------------------------------------------------------===//
///
/// \file
/// Defines various enumerations that describe declaration and
/// type specifiers.
///
//===----------------------------------------------------------------------===//
#ifndef LLVM_CLANG_BASIC_SPECIFIERS_H
#define LLVM_CLANG_BASIC_SPECIFIERS_H
#include "llvm/ADT/StringRef.h"
#include "llvm/Support/DataTypes.h"
#include "llvm/Support/ErrorHandling.h"
namespace clang {
/// Define the meaning of possible values of the kind in ExplicitSpecifier.
enum class ExplicitSpecKind : unsigned {
ResolvedFalse,
ResolvedTrue,
Unresolved,
};
/// Define the kind of constexpr specifier.
enum class ConstexprSpecKind { Unspecified, Constexpr, Consteval, Constinit };
/// In an if statement, this denotes whether the the statement is
/// a constexpr or consteval if statement.
enum class IfStatementKind : unsigned {
Ordinary,
Constexpr,
ConstevalNonNegated,
ConstevalNegated
};
/// Specifies the width of a type, e.g., short, long, or long long.
enum class TypeSpecifierWidth { Unspecified, Short, Long, LongLong };
/// Specifies the signedness of a type, e.g., signed or unsigned.
enum class TypeSpecifierSign { Unspecified, Signed, Unsigned };
enum class TypeSpecifiersPipe { Unspecified, Pipe };
/// Specifies the kind of type.
enum TypeSpecifierType {
TST_unspecified,
TST_void,
TST_char,
TST_wchar, // C++ wchar_t
TST_char8, // C++20 char8_t (proposed)
TST_char16, // C++11 char16_t
TST_char32, // C++11 char32_t
TST_int,
TST_int128,
TST_bitint, // Bit-precise integer types.
TST_half, // OpenCL half, ARM NEON __fp16
TST_Float16, // C11 extension ISO/IEC TS 18661-3
TST_Accum, // ISO/IEC JTC1 SC22 WG14 N1169 Extension
TST_Fract,
TST_BFloat16,
TST_float,
TST_double,
TST_float128,
TST_ibm128,
TST_bool, // _Bool
TST_decimal32, // _Decimal32
TST_decimal64, // _Decimal64
TST_decimal128, // _Decimal128
TST_enum,
TST_union,
TST_struct,
TST_class, // C++ class type
TST_interface, // C++ (Microsoft-specific) __interface type
TST_typename, // Typedef, C++ class-name or enum name, etc.
TST_typeofType,
TST_typeofExpr,
TST_decltype, // C++11 decltype
TST_underlyingType, // __underlying_type for C++11
TST_auto, // C++11 auto
TST_decltype_auto, // C++1y decltype(auto)
TST_auto_type, // __auto_type extension
TST_unknown_anytype, // __unknown_anytype extension
TST_atomic, // C11 _Atomic
#define GENERIC_IMAGE_TYPE(ImgType, Id) TST_##ImgType##_t, // OpenCL image types
#include "clang/Basic/OpenCLImageTypes.def"
TST_error // erroneous type
};
/// Structure that packs information about the type specifiers that
/// were written in a particular type specifier sequence.
struct WrittenBuiltinSpecs {
static_assert(TST_error < 1 << 6, "Type bitfield not wide enough for TST");
/*DeclSpec::TST*/ unsigned Type : 6;
/*DeclSpec::TSS*/ unsigned Sign : 2;
/*TypeSpecifierWidth*/ unsigned Width : 2;
unsigned ModeAttr : 1;
};
/// A C++ access specifier (public, private, protected), plus the
/// special value "none" which means different things in different contexts.
enum AccessSpecifier {
AS_public,
AS_protected,
AS_private,
AS_none
};
/// The categorization of expression values, currently following the
/// C++11 scheme.
enum ExprValueKind {
/// A pr-value expression (in the C++11 taxonomy)
/// produces a temporary value.
VK_PRValue,
/// An l-value expression is a reference to an object with
/// independent storage.
VK_LValue,
/// An x-value expression is a reference to an object with
/// independent storage but which can be "moved", i.e.
/// efficiently cannibalized for its resources.
VK_XValue
};
/// A further classification of the kind of object referenced by an
/// l-value or x-value.
enum ExprObjectKind {
/// An ordinary object is located at an address in memory.
OK_Ordinary,
/// A bitfield object is a bitfield on a C or C++ record.
OK_BitField,
/// A vector component is an element or range of elements on a vector.
OK_VectorComponent,
/// An Objective-C property is a logical field of an Objective-C
/// object which is read and written via Objective-C method calls.
OK_ObjCProperty,
/// An Objective-C array/dictionary subscripting which reads an
/// object or writes at the subscripted array/dictionary element via
/// Objective-C method calls.
OK_ObjCSubscript,
/// A matrix component is a single element of a matrix.
OK_MatrixComponent
};
/// The reason why a DeclRefExpr does not constitute an odr-use.
enum NonOdrUseReason {
/// This is an odr-use.
NOUR_None = 0,
/// This name appears in an unevaluated operand.
NOUR_Unevaluated,
/// This name appears as a potential result of an lvalue-to-rvalue
/// conversion that is a constant expression.
NOUR_Constant,
/// This name appears as a potential result of a discarded value
/// expression.
NOUR_Discarded,
};
/// Describes the kind of template specialization that a
/// particular template specialization declaration represents.
enum TemplateSpecializationKind {
/// This template specialization was formed from a template-id but
/// has not yet been declared, defined, or instantiated.
TSK_Undeclared = 0,
/// This template specialization was implicitly instantiated from a
/// template. (C++ [temp.inst]).
TSK_ImplicitInstantiation,
/// This template specialization was declared or defined by an
/// explicit specialization (C++ [temp.expl.spec]) or partial
/// specialization (C++ [temp.class.spec]).
TSK_ExplicitSpecialization,
/// This template specialization was instantiated from a template
/// due to an explicit instantiation declaration request
/// (C++11 [temp.explicit]).
TSK_ExplicitInstantiationDeclaration,
/// This template specialization was instantiated from a template
/// due to an explicit instantiation definition request
/// (C++ [temp.explicit]).
TSK_ExplicitInstantiationDefinition
};
/// Determine whether this template specialization kind refers
/// to an instantiation of an entity (as opposed to a non-template or
/// an explicit specialization).
inline bool isTemplateInstantiation(TemplateSpecializationKind Kind) {
return Kind != TSK_Undeclared && Kind != TSK_ExplicitSpecialization;
}
/// True if this template specialization kind is an explicit
/// specialization, explicit instantiation declaration, or explicit
/// instantiation definition.
inline bool isTemplateExplicitInstantiationOrSpecialization(
TemplateSpecializationKind Kind) {
switch (Kind) {
case TSK_ExplicitSpecialization:
case TSK_ExplicitInstantiationDeclaration:
case TSK_ExplicitInstantiationDefinition:
return true;
case TSK_Undeclared:
case TSK_ImplicitInstantiation:
return false;
}
llvm_unreachable("bad template specialization kind");
}
/// Thread storage-class-specifier.
enum ThreadStorageClassSpecifier {
TSCS_unspecified,
/// GNU __thread.
TSCS___thread,
/// C++11 thread_local. Implies 'static' at block scope, but not at
/// class scope.
TSCS_thread_local,
/// C11 _Thread_local. Must be combined with either 'static' or 'extern'
/// if used at block scope.
TSCS__Thread_local
};
/// Storage classes.
enum StorageClass {
// These are legal on both functions and variables.
SC_None,
SC_Extern,
SC_Static,
SC_PrivateExtern,
// These are only legal on variables.
SC_Auto,
SC_Register
};
/// Checks whether the given storage class is legal for functions.
inline bool isLegalForFunction(StorageClass SC) {
return SC <= SC_PrivateExtern;
}
/// Checks whether the given storage class is legal for variables.
inline bool isLegalForVariable(StorageClass SC) {
return true;
}
/// In-class initialization styles for non-static data members.
enum InClassInitStyle {
ICIS_NoInit, ///< No in-class initializer.
ICIS_CopyInit, ///< Copy initialization.
ICIS_ListInit ///< Direct list-initialization.
};
/// CallingConv - Specifies the calling convention that a function uses.
enum CallingConv {
CC_C, // __attribute__((cdecl))
CC_X86StdCall, // __attribute__((stdcall))
CC_X86FastCall, // __attribute__((fastcall))
CC_X86ThisCall, // __attribute__((thiscall))
CC_X86VectorCall, // __attribute__((vectorcall))
CC_X86Pascal, // __attribute__((pascal))
CC_Win64, // __attribute__((ms_abi))
CC_X86_64SysV, // __attribute__((sysv_abi))
CC_X86RegCall, // __attribute__((regcall))
CC_AAPCS, // __attribute__((pcs("aapcs")))
CC_AAPCS_VFP, // __attribute__((pcs("aapcs-vfp")))
CC_IntelOclBicc, // __attribute__((intel_ocl_bicc))
CC_SpirFunction, // default for OpenCL functions on SPIR target
CC_OpenCLKernel, // inferred for OpenCL kernels
CC_Swift, // __attribute__((swiftcall))
CC_SwiftAsync, // __attribute__((swiftasynccall))
CC_PreserveMost, // __attribute__((preserve_most))
CC_PreserveAll, // __attribute__((preserve_all))
CC_AArch64VectorCall, // __attribute__((aarch64_vector_pcs))
CC_AArch64SVEPCS, // __attribute__((aarch64_sve_pcs))
CC_AMDGPUKernelCall, // __attribute__((amdgpu_kernel))
};
/// Checks whether the given calling convention supports variadic
/// calls. Unprototyped calls also use the variadic call rules.
inline bool supportsVariadicCall(CallingConv CC) {
switch (CC) {
case CC_X86StdCall:
case CC_X86FastCall:
case CC_X86ThisCall:
case CC_X86RegCall:
case CC_X86Pascal:
case CC_X86VectorCall:
case CC_SpirFunction:
case CC_OpenCLKernel:
case CC_Swift:
case CC_SwiftAsync:
return false;
default:
return true;
}
}
/// The storage duration for an object (per C++ [basic.stc]).
enum StorageDuration {
SD_FullExpression, ///< Full-expression storage duration (for temporaries).
SD_Automatic, ///< Automatic storage duration (most local variables).
SD_Thread, ///< Thread storage duration.
SD_Static, ///< Static storage duration.
SD_Dynamic ///< Dynamic storage duration.
};
/// Describes the nullability of a particular type.
enum class NullabilityKind : uint8_t {
/// Values of this type can never be null.
NonNull = 0,
/// Values of this type can be null.
Nullable,
/// Whether values of this type can be null is (explicitly)
/// unspecified. This captures a (fairly rare) case where we
/// can't conclude anything about the nullability of the type even
/// though it has been considered.
Unspecified,
// Generally behaves like Nullable, except when used in a block parameter
// that was imported into a swift async method. There, swift will assume
// that the parameter can get null even if no error occurred. _Nullable
// parameters are assumed to only get null on error.
NullableResult,
};
/// Return true if \p L has a weaker nullability annotation than \p R. The
/// ordering is: Unspecified < Nullable < NonNull.
inline bool hasWeakerNullability(NullabilityKind L, NullabilityKind R) {
return uint8_t(L) > uint8_t(R);
}
/// Retrieve the spelling of the given nullability kind.
llvm::StringRef getNullabilitySpelling(NullabilityKind kind,
bool isContextSensitive = false);
/// Kinds of parameter ABI.
enum class ParameterABI {
/// This parameter uses ordinary ABI rules for its type.
Ordinary,
/// This parameter (which must have pointer type) is a Swift
/// indirect result parameter.
SwiftIndirectResult,
/// This parameter (which must have pointer-to-pointer type) uses
/// the special Swift error-result ABI treatment. There can be at
/// most one parameter on a given function that uses this treatment.
SwiftErrorResult,
/// This parameter (which must have pointer type) uses the special
/// Swift context-pointer ABI treatment. There can be at
/// most one parameter on a given function that uses this treatment.
SwiftContext,
/// This parameter (which must have pointer type) uses the special
/// Swift asynchronous context-pointer ABI treatment. There can be at
/// most one parameter on a given function that uses this treatment.
SwiftAsyncContext,
};
/// Assigned inheritance model for a class in the MS C++ ABI. Must match order
/// of spellings in MSInheritanceAttr.
enum class MSInheritanceModel {
Single = 0,
Multiple = 1,
Virtual = 2,
Unspecified = 3,
};
llvm::StringRef getParameterABISpelling(ParameterABI kind);
inline llvm::StringRef getAccessSpelling(AccessSpecifier AS) {
switch (AS) {
case AccessSpecifier::AS_public:
return "public";
case AccessSpecifier::AS_protected:
return "protected";
case AccessSpecifier::AS_private:
return "private";
case AccessSpecifier::AS_none:
return {};
}
llvm_unreachable("Unknown AccessSpecifier");
}
} // end namespace clang
#endif // LLVM_CLANG_BASIC_SPECIFIERS_H