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|
//==--- Attr.td - attribute definitions -----------------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
// The documentation is organized by category. Attributes can have category-
// specific documentation that is collated within the larger document.
class DocumentationCategory<string name> {
string Name = name;
code Content = [{}];
}
def DocCatFunction : DocumentationCategory<"Function Attributes">;
def DocCatVariable : DocumentationCategory<"Variable Attributes">;
def DocCatField : DocumentationCategory<"Field Attributes">;
def DocCatType : DocumentationCategory<"Type Attributes">;
def DocCatStmt : DocumentationCategory<"Statement Attributes">;
def DocCatDecl : DocumentationCategory<"Declaration Attributes">;
// Attributes listed under the Undocumented category do not generate any public
// documentation. Ideally, this category should be used for internal-only
// attributes which contain no spellings.
def DocCatUndocumented : DocumentationCategory<"Undocumented">;
class DocDeprecated<string replacement = ""> {
// If the Replacement field is empty, no replacement will be listed with the
// documentation. Otherwise, the documentation will specify the attribute has
// been superseded by this replacement.
string Replacement = replacement;
}
// Specifies the documentation to be associated with the given category.
class Documentation {
DocumentationCategory Category;
code Content;
// If the heading is empty, one may be picked automatically. If the attribute
// only has one spelling, no heading is required as the attribute's sole
// spelling is sufficient. If all spellings are semantically common, the
// heading will be the semantic spelling. If the spellings are not
// semantically common and no heading is provided, an error will be emitted.
string Heading = "";
// When set, specifies that the attribute is deprecated and can optionally
// specify a replacement attribute.
DocDeprecated Deprecated;
}
// Specifies that the attribute is explicitly undocumented. This can be a
// helpful placeholder for the attribute while working on the implementation,
// but should not be used once feature work has been completed.
def Undocumented : Documentation {
let Category = DocCatUndocumented;
}
include "clang/Basic/AttrDocs.td"
// An attribute's subject is whatever it appertains to. In this file, it is
// more accurately a list of things that an attribute can appertain to. All
// Decls and Stmts are possibly AttrSubjects (even though the syntax may not
// allow attributes on a given Decl or Stmt).
class AttrSubject;
include "clang/Basic/DeclNodes.td"
include "clang/Basic/StmtNodes.td"
// A subset-subject is an AttrSubject constrained to operate only on some subset
// of that subject.
//
// The code fragment is a boolean expression that will confirm that the subject
// meets the requirements; the subject will have the name S, and will have the
// type specified by the base. It should be a simple boolean expression. The
// diagnostic string should be a comma-separated list of subject names.
class SubsetSubject<AttrSubject base, code check, string diag> : AttrSubject {
AttrSubject Base = base;
code CheckCode = check;
string DiagSpelling = diag;
}
def LocalVar : SubsetSubject<Var,
[{S->hasLocalStorage() && !isa<ParmVarDecl>(S)}],
"local variables">;
def NonParmVar : SubsetSubject<Var,
[{S->getKind() != Decl::ParmVar}],
"variables">;
def NonLocalVar : SubsetSubject<Var,
[{!S->hasLocalStorage()}],
"variables with non-local storage">;
def NonBitField : SubsetSubject<Field,
[{!S->isBitField()}],
"non-bit-field non-static data members">;
def NonStaticCXXMethod : SubsetSubject<CXXMethod,
[{!S->isStatic()}],
"non-static member functions">;
def NonStaticNonConstCXXMethod
: SubsetSubject<CXXMethod,
[{!S->isStatic() && !S->isConst()}],
"non-static non-const member functions">;
def ObjCInstanceMethod : SubsetSubject<ObjCMethod,
[{S->isInstanceMethod()}],
"Objective-C instance methods">;
def Struct : SubsetSubject<Record,
[{!S->isUnion()}], "structs">;
def TLSVar : SubsetSubject<Var,
[{S->getTLSKind() != 0}], "thread-local variables">;
def SharedVar : SubsetSubject<Var,
[{S->hasGlobalStorage() && !S->getTLSKind()}],
"global variables">;
def GlobalVar : SubsetSubject<Var,
[{S->hasGlobalStorage()}], "global variables">;
def InlineFunction : SubsetSubject<Function,
[{S->isInlineSpecified()}], "inline functions">;
// FIXME: this hack is needed because DeclNodes.td defines the base Decl node
// type to be a class, not a definition. This makes it impossible to create an
// attribute subject which accepts a Decl. Normally, this is not a problem,
// because the attribute can have no Subjects clause to accomplish this. But in
// the case of a SubsetSubject, there's no way to express it without this hack.
def DeclBase : AttrSubject;
def FunctionLike : SubsetSubject<DeclBase,
[{S->getFunctionType(false) != nullptr}],
"functions, function pointers">;
def OpenCLKernelFunction
: SubsetSubject<Function, [{S->hasAttr<OpenCLKernelAttr>()}],
"kernel functions">;
// HasFunctionProto is a more strict version of FunctionLike, so it should
// never be specified in a Subjects list along with FunctionLike (due to the
// inclusive nature of subject testing).
def HasFunctionProto : SubsetSubject<DeclBase,
[{(S->getFunctionType(true) != nullptr &&
isa<FunctionProtoType>(S->getFunctionType())) ||
isa<ObjCMethodDecl>(S) ||
isa<BlockDecl>(S)}],
"non-K&R-style functions">;
// A subject that matches the implicit object parameter of a non-static member
// function. Accepted as a function type attribute on the type of such a
// member function.
// FIXME: This does not actually ever match currently.
def ImplicitObjectParameter
: SubsetSubject<Function, [{static_cast<void>(S), false}],
"implicit object parameters">;
// A single argument to an attribute
class Argument<string name, bit optional, bit fake = 0> {
string Name = name;
bit Optional = optional;
/// A fake argument is used to store and serialize additional information
/// in an attribute without actually changing its parsing or pretty-printing.
bit Fake = fake;
}
class BoolArgument<string name, bit opt = 0, bit fake = 0> : Argument<name, opt,
fake>;
class IdentifierArgument<string name, bit opt = 0> : Argument<name, opt>;
class IntArgument<string name, bit opt = 0> : Argument<name, opt>;
class StringArgument<string name, bit opt = 0> : Argument<name, opt>;
class ExprArgument<string name, bit opt = 0> : Argument<name, opt>;
class FunctionArgument<string name, bit opt = 0, bit fake = 0> : Argument<name,
opt,
fake>;
class NamedArgument<string name, bit opt = 0, bit fake = 0> : Argument<name,
opt,
fake>;
class TypeArgument<string name, bit opt = 0> : Argument<name, opt>;
class UnsignedArgument<string name, bit opt = 0> : Argument<name, opt>;
class VariadicUnsignedArgument<string name> : Argument<name, 1>;
class VariadicExprArgument<string name> : Argument<name, 1>;
class VariadicStringArgument<string name> : Argument<name, 1>;
class VariadicIdentifierArgument<string name> : Argument<name, 1>;
// Like VariadicUnsignedArgument except values are ParamIdx.
class VariadicParamIdxArgument<string name> : Argument<name, 1>;
// A list of identifiers matching parameters or ParamIdx indices.
class VariadicParamOrParamIdxArgument<string name> : Argument<name, 1>;
// Like VariadicParamIdxArgument but for a single function parameter index.
class ParamIdxArgument<string name, bit opt = 0> : Argument<name, opt>;
// A version of the form major.minor[.subminor].
class VersionArgument<string name, bit opt = 0> : Argument<name, opt>;
// This one's a doozy, so it gets its own special type
// It can be an unsigned integer, or a type. Either can
// be dependent.
class AlignedArgument<string name, bit opt = 0> : Argument<name, opt>;
// A bool argument with a default value
class DefaultBoolArgument<string name, bit default, bit fake = 0>
: BoolArgument<name, 1, fake> {
bit Default = default;
}
// An integer argument with a default value
class DefaultIntArgument<string name, int default> : IntArgument<name, 1> {
int Default = default;
}
// This argument is more complex, it includes the enumerator type name,
// a list of strings to accept, and a list of enumerators to map them to.
class EnumArgument<string name, string type, list<string> values,
list<string> enums, bit opt = 0, bit fake = 0>
: Argument<name, opt, fake> {
string Type = type;
list<string> Values = values;
list<string> Enums = enums;
}
// FIXME: There should be a VariadicArgument type that takes any other type
// of argument and generates the appropriate type.
class VariadicEnumArgument<string name, string type, list<string> values,
list<string> enums> : Argument<name, 1> {
string Type = type;
list<string> Values = values;
list<string> Enums = enums;
}
// This handles one spelling of an attribute.
class Spelling<string name, string variety> {
string Name = name;
string Variety = variety;
bit KnownToGCC;
}
class GNU<string name> : Spelling<name, "GNU">;
class Declspec<string name> : Spelling<name, "Declspec">;
class Microsoft<string name> : Spelling<name, "Microsoft">;
class CXX11<string namespace, string name, int version = 1>
: Spelling<name, "CXX11"> {
string Namespace = namespace;
int Version = version;
}
class C2x<string namespace, string name> : Spelling<name, "C2x"> {
string Namespace = namespace;
}
class Keyword<string name> : Spelling<name, "Keyword">;
class Pragma<string namespace, string name> : Spelling<name, "Pragma"> {
string Namespace = namespace;
}
// The GCC spelling implies GNU<name> and CXX11<"gnu", name> and also sets
// KnownToGCC to 1. This spelling should be used for any GCC-compatible
// attributes.
class GCC<string name> : Spelling<name, "GCC"> {
let KnownToGCC = 1;
}
// The Clang spelling implies GNU<name>, CXX11<"clang", name>, and optionally,
// C2x<"clang", name>. This spelling should be used for any Clang-specific
// attributes.
class Clang<string name, bit allowInC = 1> : Spelling<name, "Clang"> {
bit AllowInC = allowInC;
}
class Accessor<string name, list<Spelling> spellings> {
string Name = name;
list<Spelling> Spellings = spellings;
}
class SubjectDiag<bit warn> {
bit Warn = warn;
}
def WarnDiag : SubjectDiag<1>;
def ErrorDiag : SubjectDiag<0>;
class SubjectList<list<AttrSubject> subjects, SubjectDiag diag = WarnDiag,
string customDiag = ""> {
list<AttrSubject> Subjects = subjects;
SubjectDiag Diag = diag;
string CustomDiag = customDiag;
}
class LangOpt<string name, code customCode = [{}]> {
string Name = name;
// A custom predicate, written as an expression evaluated in a context with
// "LangOpts" bound.
code CustomCode = customCode;
}
def MicrosoftExt : LangOpt<"MicrosoftExt">;
def Borland : LangOpt<"Borland">;
def CUDA : LangOpt<"CUDA">;
def HIP : LangOpt<"HIP">;
def COnly : LangOpt<"COnly", "!LangOpts.CPlusPlus">;
def CPlusPlus : LangOpt<"CPlusPlus">;
def OpenCL : LangOpt<"OpenCL">;
def RenderScript : LangOpt<"RenderScript">;
def ObjC : LangOpt<"ObjC">;
def BlocksSupported : LangOpt<"Blocks">;
def ObjCAutoRefCount : LangOpt<"ObjCAutoRefCount">;
def ObjCNonFragileRuntime : LangOpt<"ObjCNonFragileRuntime",
"LangOpts.ObjCRuntime.allowsClassStubs()">;
// Language option for CMSE extensions
def Cmse : LangOpt<"Cmse">;
// Defines targets for target-specific attributes. Empty lists are unchecked.
class TargetSpec {
// Specifies Architectures for which the target applies, based off the
// ArchType enumeration in Triple.h.
list<string> Arches = [];
// Specifies Operating Systems for which the target applies, based off the
// OSType enumeration in Triple.h
list<string> OSes;
// Specifies Object Formats for which the target applies, based off the
// ObjectFormatType enumeration in Triple.h
list<string> ObjectFormats;
// A custom predicate, written as an expression evaluated in a context
// with the following declarations in scope:
// const clang::TargetInfo &Target;
// const llvm::Triple &T = Target.getTriple();
code CustomCode = [{}];
}
class TargetArch<list<string> arches> : TargetSpec {
let Arches = arches;
}
def TargetARM : TargetArch<["arm", "thumb", "armeb", "thumbeb"]>;
def TargetAVR : TargetArch<["avr"]>;
def TargetMips32 : TargetArch<["mips", "mipsel"]>;
def TargetAnyMips : TargetArch<["mips", "mipsel", "mips64", "mips64el"]>;
def TargetMSP430 : TargetArch<["msp430"]>;
def TargetRISCV : TargetArch<["riscv32", "riscv64"]>;
def TargetX86 : TargetArch<["x86"]>;
def TargetAnyX86 : TargetArch<["x86", "x86_64"]>;
def TargetWebAssembly : TargetArch<["wasm32", "wasm64"]>;
def TargetWindows : TargetArch<["x86", "x86_64", "arm", "thumb", "aarch64"]> {
let OSes = ["Win32"];
}
def TargetItaniumCXXABI : TargetSpec {
let CustomCode = [{ Target.getCXXABI().isItaniumFamily() }];
}
def TargetMicrosoftCXXABI : TargetArch<["x86", "x86_64", "arm", "thumb", "aarch64"]> {
let CustomCode = [{ Target.getCXXABI().isMicrosoft() }];
}
def TargetELF : TargetSpec {
let ObjectFormats = ["ELF"];
}
// Attribute subject match rules that are used for #pragma clang attribute.
//
// A instance of AttrSubjectMatcherRule represents an individual match rule.
// An individual match rule can correspond to a number of different attribute
// subjects, e.g. "record" matching rule corresponds to the Record and
// CXXRecord attribute subjects.
//
// Match rules are used in the subject list of the #pragma clang attribute.
// Match rules can have sub-match rules that are instances of
// AttrSubjectMatcherSubRule. A sub-match rule can correspond to a number
// of different attribute subjects, and it can have a negated spelling as well.
// For example, "variable(unless(is_parameter))" matching rule corresponds to
// the NonParmVar attribute subject.
class AttrSubjectMatcherSubRule<string name, list<AttrSubject> subjects,
bit negated = 0> {
string Name = name;
list<AttrSubject> Subjects = subjects;
bit Negated = negated;
// Lists language options, one of which is required to be true for the
// attribute to be applicable. If empty, the language options are taken
// from the parent matcher rule.
list<LangOpt> LangOpts = [];
}
class AttrSubjectMatcherRule<string name, list<AttrSubject> subjects,
list<AttrSubjectMatcherSubRule> subrules = []> {
string Name = name;
list<AttrSubject> Subjects = subjects;
list<AttrSubjectMatcherSubRule> Constraints = subrules;
// Lists language options, one of which is required to be true for the
// attribute to be applicable. If empty, no language options are required.
list<LangOpt> LangOpts = [];
}
// function(is_member)
def SubRuleForCXXMethod : AttrSubjectMatcherSubRule<"is_member", [CXXMethod]> {
let LangOpts = [CPlusPlus];
}
def SubjectMatcherForFunction : AttrSubjectMatcherRule<"function", [Function], [
SubRuleForCXXMethod
]>;
// hasType is abstract, it should be used with one of the sub-rules.
def SubjectMatcherForType : AttrSubjectMatcherRule<"hasType", [], [
AttrSubjectMatcherSubRule<"functionType", [FunctionLike]>
// FIXME: There's a matcher ambiguity with objc methods and blocks since
// functionType excludes them but functionProtoType includes them.
// AttrSubjectMatcherSubRule<"functionProtoType", [HasFunctionProto]>
]>;
def SubjectMatcherForTypedef : AttrSubjectMatcherRule<"type_alias",
[TypedefName]>;
def SubjectMatcherForRecord : AttrSubjectMatcherRule<"record", [Record,
CXXRecord], [
// unless(is_union)
AttrSubjectMatcherSubRule<"is_union", [Struct], 1>
]>;
def SubjectMatcherForEnum : AttrSubjectMatcherRule<"enum", [Enum]>;
def SubjectMatcherForEnumConstant : AttrSubjectMatcherRule<"enum_constant",
[EnumConstant]>;
def SubjectMatcherForVar : AttrSubjectMatcherRule<"variable", [Var], [
AttrSubjectMatcherSubRule<"is_thread_local", [TLSVar]>,
AttrSubjectMatcherSubRule<"is_global", [GlobalVar]>,
AttrSubjectMatcherSubRule<"is_parameter", [ParmVar]>,
// unless(is_parameter)
AttrSubjectMatcherSubRule<"is_parameter", [NonParmVar], 1>
]>;
def SubjectMatcherForField : AttrSubjectMatcherRule<"field", [Field]>;
def SubjectMatcherForNamespace : AttrSubjectMatcherRule<"namespace",
[Namespace]> {
let LangOpts = [CPlusPlus];
}
def SubjectMatcherForObjCInterface : AttrSubjectMatcherRule<"objc_interface",
[ObjCInterface]> {
let LangOpts = [ObjC];
}
def SubjectMatcherForObjCProtocol : AttrSubjectMatcherRule<"objc_protocol",
[ObjCProtocol]> {
let LangOpts = [ObjC];
}
def SubjectMatcherForObjCCategory : AttrSubjectMatcherRule<"objc_category",
[ObjCCategory]> {
let LangOpts = [ObjC];
}
def SubjectMatcherForObjCImplementation :
AttrSubjectMatcherRule<"objc_implementation", [ObjCImpl]> {
let LangOpts = [ObjC];
}
def SubjectMatcherForObjCMethod : AttrSubjectMatcherRule<"objc_method",
[ObjCMethod], [
AttrSubjectMatcherSubRule<"is_instance", [ObjCInstanceMethod]>
]> {
let LangOpts = [ObjC];
}
def SubjectMatcherForObjCProperty : AttrSubjectMatcherRule<"objc_property",
[ObjCProperty]> {
let LangOpts = [ObjC];
}
def SubjectMatcherForBlock : AttrSubjectMatcherRule<"block", [Block]> {
let LangOpts = [BlocksSupported];
}
// Aggregate attribute subject match rules are abstract match rules that can't
// be used directly in #pragma clang attribute. Instead, users have to use
// subject match rules that correspond to attribute subjects that derive from
// the specified subject.
class AttrSubjectMatcherAggregateRule<AttrSubject subject> {
AttrSubject Subject = subject;
}
def SubjectMatcherForNamed : AttrSubjectMatcherAggregateRule<Named>;
class Attr {
// The various ways in which an attribute can be spelled in source
list<Spelling> Spellings;
// The things to which an attribute can appertain
SubjectList Subjects;
// The arguments allowed on an attribute
list<Argument> Args = [];
// Accessors which should be generated for the attribute.
list<Accessor> Accessors = [];
// Set to true for attributes with arguments which require delayed parsing.
bit LateParsed = 0;
// Set to false to prevent an attribute from being propagated from a template
// to the instantiation.
bit Clone = 1;
// Set to true for attributes which must be instantiated within templates
bit TemplateDependent = 0;
// Set to true for attributes that have a corresponding AST node.
bit ASTNode = 1;
// Set to true for attributes which have handler in Sema.
bit SemaHandler = 1;
// Set to true for attributes that are completely ignored.
bit Ignored = 0;
// Set to true if the attribute's parsing does not match its semantic
// content. Eg) It parses 3 args, but semantically takes 4 args. Opts out of
// common attribute error checking.
bit HasCustomParsing = 0;
// Set to true if all of the attribute's arguments should be parsed in an
// unevaluated context.
bit ParseArgumentsAsUnevaluated = 0;
// Set to true if this attribute meaningful when applied to or inherited
// in a class template definition.
bit MeaningfulToClassTemplateDefinition = 0;
// Set to true if this attribute can be used with '#pragma clang attribute'.
// By default, an attribute is supported by the '#pragma clang attribute'
// only when:
// - It has a subject list whose subjects can be represented using subject
// match rules.
// - It has GNU/CXX11 spelling and doesn't require delayed parsing.
bit PragmaAttributeSupport;
// Lists language options, one of which is required to be true for the
// attribute to be applicable. If empty, no language options are required.
list<LangOpt> LangOpts = [];
// Any additional text that should be included verbatim in the class.
// Note: Any additional data members will leak and should be constructed
// externally on the ASTContext.
code AdditionalMembers = [{}];
// Any documentation that should be associated with the attribute. Since an
// attribute may be documented under multiple categories, more than one
// Documentation entry may be listed.
list<Documentation> Documentation;
}
/// A type attribute is not processed on a declaration or a statement.
class TypeAttr : Attr;
/// A stmt attribute is not processed on a declaration or a type.
class StmtAttr : Attr;
/// An inheritable attribute is inherited by later redeclarations.
class InheritableAttr : Attr {
// Set to true if this attribute can be duplicated on a subject when inheriting
// attributes from prior declarations.
bit InheritEvenIfAlreadyPresent = 0;
}
/// Some attributes, like calling conventions, can appear in either the
/// declaration or the type position. These attributes are morally type
/// attributes, but have historically been written on declarations.
class DeclOrTypeAttr : InheritableAttr;
/// A target-specific attribute. This class is meant to be used as a mixin
/// with InheritableAttr or Attr depending on the attribute's needs.
class TargetSpecificAttr<TargetSpec target> {
TargetSpec Target = target;
// Attributes are generally required to have unique spellings for their names
// so that the parser can determine what kind of attribute it has parsed.
// However, target-specific attributes are special in that the attribute only
// "exists" for a given target. So two target-specific attributes can share
// the same name when they exist in different targets. To support this, a
// Kind can be explicitly specified for a target-specific attribute. This
// corresponds to the ParsedAttr::AT_* enum that is generated and it
// should contain a shared value between the attributes.
//
// Target-specific attributes which use this feature should ensure that the
// spellings match exactly between the attributes, and if the arguments or
// subjects differ, should specify HasCustomParsing = 1 and implement their
// own parsing and semantic handling requirements as-needed.
string ParseKind;
}
/// An inheritable parameter attribute is inherited by later
/// redeclarations, even when it's written on a parameter.
class InheritableParamAttr : InheritableAttr;
/// An attribute which changes the ABI rules for a specific parameter.
class ParameterABIAttr : InheritableParamAttr {
let Subjects = SubjectList<[ParmVar]>;
}
/// An ignored attribute, which we parse but discard with no checking.
class IgnoredAttr : Attr {
let Ignored = 1;
let ASTNode = 0;
let SemaHandler = 0;
let Documentation = [Undocumented];
}
//
// Attributes begin here
//
def AbiTag : Attr {
let Spellings = [GCC<"abi_tag">];
let Args = [VariadicStringArgument<"Tags">];
let Subjects = SubjectList<[Struct, Var, Function, Namespace], ErrorDiag>;
let MeaningfulToClassTemplateDefinition = 1;
let Documentation = [AbiTagsDocs];
}
def AddressSpace : TypeAttr {
let Spellings = [Clang<"address_space">];
let Args = [IntArgument<"AddressSpace">];
let Documentation = [Undocumented];
}
def Alias : Attr {
let Spellings = [GCC<"alias">];
let Args = [StringArgument<"Aliasee">];
let Subjects = SubjectList<[Function, GlobalVar], ErrorDiag>;
let Documentation = [Undocumented];
}
def Aligned : InheritableAttr {
let Spellings = [GCC<"aligned">, Declspec<"align">, Keyword<"alignas">,
Keyword<"_Alignas">];
let Args = [AlignedArgument<"Alignment", 1>];
let Accessors = [Accessor<"isGNU", [GCC<"aligned">]>,
Accessor<"isC11", [Keyword<"_Alignas">]>,
Accessor<"isAlignas", [Keyword<"alignas">,
Keyword<"_Alignas">]>,
Accessor<"isDeclspec",[Declspec<"align">]>];
let Documentation = [Undocumented];
}
def AlignValue : Attr {
let Spellings = [
// Unfortunately, this is semantically an assertion, not a directive
// (something else must ensure the alignment), so aligned_value is a
// probably a better name. We might want to add an aligned_value spelling in
// the future (and a corresponding C++ attribute), but this can be done
// later once we decide if we also want them to have slightly-different
// semantics than Intel's align_value.
//
// Does not get a [[]] spelling because the attribute is not exposed as such
// by Intel.
GNU<"align_value">
// Intel's compiler on Windows also supports:
// , Declspec<"align_value">
];
let Args = [ExprArgument<"Alignment">];
let Subjects = SubjectList<[Var, TypedefName]>;
let Documentation = [AlignValueDocs];
}
def AlignMac68k : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let SemaHandler = 0;
let Documentation = [Undocumented];
}
def AlwaysInline : InheritableAttr {
let Spellings = [GCC<"always_inline">, Keyword<"__forceinline">];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def Artificial : InheritableAttr {
let Spellings = [GCC<"artificial">];
let Subjects = SubjectList<[InlineFunction], WarnDiag>;
let Documentation = [ArtificialDocs];
}
def XRayInstrument : InheritableAttr {
let Spellings = [Clang<"xray_always_instrument">,
Clang<"xray_never_instrument">];
let Subjects = SubjectList<[Function, ObjCMethod]>;
let Accessors = [Accessor<"alwaysXRayInstrument",
[Clang<"xray_always_instrument">]>,
Accessor<"neverXRayInstrument",
[Clang<"xray_never_instrument">]>];
let Documentation = [XRayDocs];
}
def XRayLogArgs : InheritableAttr {
let Spellings = [Clang<"xray_log_args">];
let Subjects = SubjectList<[Function, ObjCMethod]>;
// This argument is a count not an index, so it has the same encoding (base
// 1 including C++ implicit this parameter) at the source and LLVM levels of
// representation, so ParamIdxArgument is inappropriate. It is never used
// at the AST level of representation, so it never needs to be adjusted not
// to include any C++ implicit this parameter. Thus, we just store it and
// use it as an unsigned that never needs adjustment.
let Args = [UnsignedArgument<"ArgumentCount">];
let Documentation = [XRayDocs];
}
def TLSModel : InheritableAttr {
let Spellings = [GCC<"tls_model">];
let Subjects = SubjectList<[TLSVar], ErrorDiag>;
let Args = [StringArgument<"Model">];
let Documentation = [TLSModelDocs];
}
def AnalyzerNoReturn : InheritableAttr {
// TODO: should this attribute be exposed with a [[]] spelling under the clang
// vendor namespace, or should it use a vendor namespace specific to the
// analyzer?
let Spellings = [GNU<"analyzer_noreturn">];
// TODO: Add subject list.
let Documentation = [Undocumented];
}
def Annotate : InheritableParamAttr {
let Spellings = [Clang<"annotate">];
let Args = [StringArgument<"Annotation">];
// Ensure that the annotate attribute can be used with
// '#pragma clang attribute' even though it has no subject list.
let PragmaAttributeSupport = 1;
let Documentation = [Undocumented];
}
def ARMInterrupt : InheritableAttr, TargetSpecificAttr<TargetARM> {
// NOTE: If you add any additional spellings, MSP430Interrupt's,
// MipsInterrupt's and AnyX86Interrupt's spellings must match.
let Spellings = [GCC<"interrupt">];
let Args = [EnumArgument<"Interrupt", "InterruptType",
["IRQ", "FIQ", "SWI", "ABORT", "UNDEF", ""],
["IRQ", "FIQ", "SWI", "ABORT", "UNDEF", "Generic"],
1>];
let ParseKind = "Interrupt";
let HasCustomParsing = 1;
let Documentation = [ARMInterruptDocs];
}
def AVRInterrupt : InheritableAttr, TargetSpecificAttr<TargetAVR> {
let Spellings = [GCC<"interrupt">];
let Subjects = SubjectList<[Function]>;
let ParseKind = "Interrupt";
let Documentation = [AVRInterruptDocs];
}
def AVRSignal : InheritableAttr, TargetSpecificAttr<TargetAVR> {
let Spellings = [GCC<"signal">];
let Subjects = SubjectList<[Function]>;
let Documentation = [AVRSignalDocs];
}
def AsmLabel : InheritableAttr {
let Spellings = [Keyword<"asm">, Keyword<"__asm__">];
let Args = [StringArgument<"Label">];
let SemaHandler = 0;
let Documentation = [Undocumented];
}
def Availability : InheritableAttr {
let Spellings = [Clang<"availability">];
let Args = [IdentifierArgument<"platform">, VersionArgument<"introduced">,
VersionArgument<"deprecated">, VersionArgument<"obsoleted">,
BoolArgument<"unavailable">, StringArgument<"message">,
BoolArgument<"strict">, StringArgument<"replacement">,
IntArgument<"priority">];
let AdditionalMembers =
[{static llvm::StringRef getPrettyPlatformName(llvm::StringRef Platform) {
return llvm::StringSwitch<llvm::StringRef>(Platform)
.Case("android", "Android")
.Case("ios", "iOS")
.Case("macos", "macOS")
.Case("tvos", "tvOS")
.Case("watchos", "watchOS")
.Case("ios_app_extension", "iOS (App Extension)")
.Case("macos_app_extension", "macOS (App Extension)")
.Case("tvos_app_extension", "tvOS (App Extension)")
.Case("watchos_app_extension", "watchOS (App Extension)")
.Case("swift", "Swift")
.Default(llvm::StringRef());
}
static llvm::StringRef getPlatformNameSourceSpelling(llvm::StringRef Platform) {
return llvm::StringSwitch<llvm::StringRef>(Platform)
.Case("ios", "iOS")
.Case("macos", "macOS")
.Case("tvos", "tvOS")
.Case("watchos", "watchOS")
.Case("ios_app_extension", "iOSApplicationExtension")
.Case("macos_app_extension", "macOSApplicationExtension")
.Case("tvos_app_extension", "tvOSApplicationExtension")
.Case("watchos_app_extension", "watchOSApplicationExtension")
.Default(Platform);
}
static llvm::StringRef canonicalizePlatformName(llvm::StringRef Platform) {
return llvm::StringSwitch<llvm::StringRef>(Platform)
.Case("iOS", "ios")
.Case("macOS", "macos")
.Case("tvOS", "tvos")
.Case("watchOS", "watchos")
.Case("iOSApplicationExtension", "ios_app_extension")
.Case("macOSApplicationExtension", "macos_app_extension")
.Case("tvOSApplicationExtension", "tvos_app_extension")
.Case("watchOSApplicationExtension", "watchos_app_extension")
.Default(Platform);
} }];
let HasCustomParsing = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Named]>;
let Documentation = [AvailabilityDocs];
}
def ExternalSourceSymbol : InheritableAttr {
let Spellings = [Clang<"external_source_symbol">];
let Args = [StringArgument<"language", 1>,
StringArgument<"definedIn", 1>,
BoolArgument<"generatedDeclaration", 1>];
let HasCustomParsing = 1;
let Subjects = SubjectList<[Named]>;
let Documentation = [ExternalSourceSymbolDocs];
}
def Blocks : InheritableAttr {
let Spellings = [Clang<"blocks">];
let Args = [EnumArgument<"Type", "BlockType", ["byref"], ["ByRef"]>];
let Documentation = [Undocumented];
}
def Bounded : IgnoredAttr {
// Does not have a [[]] spelling because the attribute is ignored.
let Spellings = [GNU<"bounded">];
}
def CarriesDependency : InheritableParamAttr {
let Spellings = [GNU<"carries_dependency">,
CXX11<"","carries_dependency", 200809>];
let Subjects = SubjectList<[ParmVar, ObjCMethod, Function], ErrorDiag>;
let Documentation = [CarriesDependencyDocs];
}
def CDecl : DeclOrTypeAttr {
let Spellings = [GCC<"cdecl">, Keyword<"__cdecl">, Keyword<"_cdecl">];
// let Subjects = [Function, ObjCMethod];
let Documentation = [Undocumented];
}
// cf_audited_transfer indicates that the given function has been
// audited and has been marked with the appropriate cf_consumed and
// cf_returns_retained attributes. It is generally applied by
// '#pragma clang arc_cf_code_audited' rather than explicitly.
def CFAuditedTransfer : InheritableAttr {
let Spellings = [Clang<"cf_audited_transfer">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [Undocumented];
}
// cf_unknown_transfer is an explicit opt-out of cf_audited_transfer.
// It indicates that the function has unknown or unautomatable
// transfer semantics.
def CFUnknownTransfer : InheritableAttr {
let Spellings = [Clang<"cf_unknown_transfer">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [Undocumented];
}
def CFReturnsRetained : InheritableAttr {
let Spellings = [Clang<"cf_returns_retained">];
// let Subjects = SubjectList<[ObjCMethod, ObjCProperty, Function]>;
let Documentation = [RetainBehaviorDocs];
}
def CFReturnsNotRetained : InheritableAttr {
let Spellings = [Clang<"cf_returns_not_retained">];
// let Subjects = SubjectList<[ObjCMethod, ObjCProperty, Function]>;
let Documentation = [RetainBehaviorDocs];
}
def CFConsumed : InheritableParamAttr {
let Spellings = [Clang<"cf_consumed">];
let Subjects = SubjectList<[ParmVar]>;
let Documentation = [RetainBehaviorDocs];
}
// OSObject-based attributes.
def OSConsumed : InheritableParamAttr {
let Spellings = [Clang<"os_consumed">];
let Subjects = SubjectList<[ParmVar]>;
let Documentation = [RetainBehaviorDocs];
}
def OSReturnsRetained : InheritableAttr {
let Spellings = [Clang<"os_returns_retained">];
let Subjects = SubjectList<[Function, ObjCMethod, ObjCProperty, ParmVar]>;
let Documentation = [RetainBehaviorDocs];
}
def OSReturnsNotRetained : InheritableAttr {
let Spellings = [Clang<"os_returns_not_retained">];
let Subjects = SubjectList<[Function, ObjCMethod, ObjCProperty, ParmVar]>;
let Documentation = [RetainBehaviorDocs];
}
def OSReturnsRetainedOnZero : InheritableAttr {
let Spellings = [Clang<"os_returns_retained_on_zero">];
let Subjects = SubjectList<[ParmVar]>;
let Documentation = [RetainBehaviorDocs];
}
def OSReturnsRetainedOnNonZero : InheritableAttr {
let Spellings = [Clang<"os_returns_retained_on_non_zero">];
let Subjects = SubjectList<[ParmVar]>;
let Documentation = [RetainBehaviorDocs];
}
def OSConsumesThis : InheritableAttr {
let Spellings = [Clang<"os_consumes_this">];
let Subjects = SubjectList<[NonStaticCXXMethod]>;
let Documentation = [RetainBehaviorDocs];
}
def Cleanup : InheritableAttr {
let Spellings = [GCC<"cleanup">];
let Args = [FunctionArgument<"FunctionDecl">];
let Subjects = SubjectList<[LocalVar]>;
let Documentation = [Undocumented];
}
def Cold : InheritableAttr {
let Spellings = [GCC<"cold">];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def Common : InheritableAttr {
let Spellings = [GCC<"common">];
let Subjects = SubjectList<[Var]>;
let Documentation = [Undocumented];
}
def Const : InheritableAttr {
let Spellings = [GCC<"const">, GCC<"__const">];
let Documentation = [Undocumented];
}
def Constructor : InheritableAttr {
let Spellings = [GCC<"constructor">];
let Args = [DefaultIntArgument<"Priority", 65535>];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def CPUSpecific : InheritableAttr {
let Spellings = [Clang<"cpu_specific">, Declspec<"cpu_specific">];
let Args = [VariadicIdentifierArgument<"Cpus">];
let Subjects = SubjectList<[Function]>;
let Documentation = [CPUSpecificCPUDispatchDocs];
let AdditionalMembers = [{
IdentifierInfo *getCPUName(unsigned Index) const {
return *(cpus_begin() + Index);
}
}];
}
def CPUDispatch : InheritableAttr {
let Spellings = [Clang<"cpu_dispatch">, Declspec<"cpu_dispatch">];
let Args = [VariadicIdentifierArgument<"Cpus">];
let Subjects = SubjectList<[Function]>;
let Documentation = [CPUSpecificCPUDispatchDocs];
}
// CUDA attributes are spelled __attribute__((attr)) or __declspec(__attr__),
// and they do not receive a [[]] spelling.
def CUDAConstant : InheritableAttr {
let Spellings = [GNU<"constant">, Declspec<"__constant__">];
let Subjects = SubjectList<[Var]>;
let LangOpts = [CUDA];
let Documentation = [Undocumented];
}
def CUDACudartBuiltin : IgnoredAttr {
let Spellings = [GNU<"cudart_builtin">, Declspec<"__cudart_builtin__">];
let LangOpts = [CUDA];
}
def CUDADevice : InheritableAttr {
let Spellings = [GNU<"device">, Declspec<"__device__">];
let Subjects = SubjectList<[Function, Var]>;
let LangOpts = [CUDA];
let Documentation = [Undocumented];
}
def HIPPinnedShadow : InheritableAttr {
let Spellings = [GNU<"hip_pinned_shadow">, Declspec<"__hip_pinned_shadow__">];
let Subjects = SubjectList<[Var]>;
let LangOpts = [HIP];
let Documentation = [HIPPinnedShadowDocs];
}
def CUDADeviceBuiltin : IgnoredAttr {
let Spellings = [GNU<"device_builtin">, Declspec<"__device_builtin__">];
let LangOpts = [CUDA];
}
def CUDADeviceBuiltinSurfaceType : IgnoredAttr {
let Spellings = [GNU<"device_builtin_surface_type">,
Declspec<"__device_builtin_surface_type__">];
let LangOpts = [CUDA];
}
def CUDADeviceBuiltinTextureType : IgnoredAttr {
let Spellings = [GNU<"device_builtin_texture_type">,
Declspec<"__device_builtin_texture_type__">];
let LangOpts = [CUDA];
}
def CUDAGlobal : InheritableAttr {
let Spellings = [GNU<"global">, Declspec<"__global__">];
let Subjects = SubjectList<[Function]>;
let LangOpts = [CUDA];
let Documentation = [Undocumented];
}
def CUDAHost : InheritableAttr {
let Spellings = [GNU<"host">, Declspec<"__host__">];
let Subjects = SubjectList<[Function]>;
let LangOpts = [CUDA];
let Documentation = [Undocumented];
}
def CUDAInvalidTarget : InheritableAttr {
let Spellings = [];
let Subjects = SubjectList<[Function]>;
let LangOpts = [CUDA];
let Documentation = [Undocumented];
}
def CUDALaunchBounds : InheritableAttr {
let Spellings = [GNU<"launch_bounds">, Declspec<"__launch_bounds__">];
let Args = [ExprArgument<"MaxThreads">, ExprArgument<"MinBlocks", 1>];
let LangOpts = [CUDA];
let Subjects = SubjectList<[ObjCMethod, FunctionLike]>;
// An AST node is created for this attribute, but is not used by other parts
// of the compiler. However, this node needs to exist in the AST because
// non-LLVM backends may be relying on the attribute's presence.
let Documentation = [Undocumented];
}
def CUDAShared : InheritableAttr {
let Spellings = [GNU<"shared">, Declspec<"__shared__">];
let Subjects = SubjectList<[Var]>;
let LangOpts = [CUDA];
let Documentation = [Undocumented];
}
def C11NoReturn : InheritableAttr {
let Spellings = [Keyword<"_Noreturn">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let SemaHandler = 0;
let Documentation = [C11NoReturnDocs];
}
def CXX11NoReturn : InheritableAttr {
let Spellings = [CXX11<"", "noreturn", 200809>];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [CXX11NoReturnDocs];
}
// Similar to CUDA, OpenCL attributes do not receive a [[]] spelling because
// the specification does not expose them with one currently.
def OpenCLKernel : InheritableAttr {
let Spellings = [Keyword<"__kernel">, Keyword<"kernel">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [Undocumented];
}
def OpenCLUnrollHint : InheritableAttr {
let Spellings = [GNU<"opencl_unroll_hint">];
let Args = [UnsignedArgument<"UnrollHint">];
let Documentation = [OpenCLUnrollHintDocs];
}
def OpenCLIntelReqdSubGroupSize: InheritableAttr {
let Spellings = [GNU<"intel_reqd_sub_group_size">];
let Args = [UnsignedArgument<"SubGroupSize">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [OpenCLIntelReqdSubGroupSizeDocs];
}
// This attribute is both a type attribute, and a declaration attribute (for
// parameter variables).
def OpenCLAccess : Attr {
let Spellings = [Keyword<"__read_only">, Keyword<"read_only">,
Keyword<"__write_only">, Keyword<"write_only">,
Keyword<"__read_write">, Keyword<"read_write">];
let Subjects = SubjectList<[ParmVar, TypedefName], ErrorDiag>;
let Accessors = [Accessor<"isReadOnly", [Keyword<"__read_only">,
Keyword<"read_only">]>,
Accessor<"isReadWrite", [Keyword<"__read_write">,
Keyword<"read_write">]>,
Accessor<"isWriteOnly", [Keyword<"__write_only">,
Keyword<"write_only">]>];
let Documentation = [OpenCLAccessDocs];
}
def OpenCLPrivateAddressSpace : TypeAttr {
let Spellings = [Keyword<"__private">, Keyword<"private">];
let Documentation = [OpenCLAddressSpacePrivateDocs];
}
def OpenCLGlobalAddressSpace : TypeAttr {
let Spellings = [Keyword<"__global">, Keyword<"global">];
let Documentation = [OpenCLAddressSpaceGlobalDocs];
}
def OpenCLLocalAddressSpace : TypeAttr {
let Spellings = [Keyword<"__local">, Keyword<"local">];
let Documentation = [OpenCLAddressSpaceLocalDocs];
}
def OpenCLConstantAddressSpace : TypeAttr {
let Spellings = [Keyword<"__constant">, Keyword<"constant">];
let Documentation = [OpenCLAddressSpaceConstantDocs];
}
def OpenCLGenericAddressSpace : TypeAttr {
let Spellings = [Keyword<"__generic">, Keyword<"generic">];
let Documentation = [OpenCLAddressSpaceGenericDocs];
}
def OpenCLNoSVM : Attr {
let Spellings = [GNU<"nosvm">];
let Subjects = SubjectList<[Var]>;
let Documentation = [OpenCLNoSVMDocs];
let LangOpts = [OpenCL];
let ASTNode = 0;
}
def RenderScriptKernel : Attr {
let Spellings = [GNU<"kernel">];
let Subjects = SubjectList<[Function]>;
let Documentation = [RenderScriptKernelAttributeDocs];
let LangOpts = [RenderScript];
}
def Deprecated : InheritableAttr {
let Spellings = [GCC<"deprecated">, Declspec<"deprecated">,
CXX11<"","deprecated", 201309>, C2x<"", "deprecated">];
let Args = [StringArgument<"Message", 1>,
// An optional string argument that enables us to provide a
// Fix-It.
StringArgument<"Replacement", 1>];
let MeaningfulToClassTemplateDefinition = 1;
let Documentation = [DeprecatedDocs];
}
def Destructor : InheritableAttr {
let Spellings = [GCC<"destructor">];
let Args = [DefaultIntArgument<"Priority", 65535>];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def EmptyBases : InheritableAttr, TargetSpecificAttr<TargetMicrosoftCXXABI> {
let Spellings = [Declspec<"empty_bases">];
let Subjects = SubjectList<[CXXRecord]>;
let Documentation = [EmptyBasesDocs];
}
def AllocSize : InheritableAttr {
let Spellings = [GCC<"alloc_size">];
let Subjects = SubjectList<[Function]>;
let Args = [ParamIdxArgument<"ElemSizeParam">,
ParamIdxArgument<"NumElemsParam", /*opt*/ 1>];
let TemplateDependent = 1;
let Documentation = [AllocSizeDocs];
}
def EnableIf : InheritableAttr {
// Does not have a [[]] spelling because this attribute requires the ability
// to parse function arguments but the attribute is not written in the type
// position.
let Spellings = [GNU<"enable_if">];
let Subjects = SubjectList<[Function]>;
let Args = [ExprArgument<"Cond">, StringArgument<"Message">];
let TemplateDependent = 1;
let Documentation = [EnableIfDocs];
}
def ExtVectorType : Attr {
// This is an OpenCL-related attribute and does not receive a [[]] spelling.
let Spellings = [GNU<"ext_vector_type">];
// FIXME: This subject list is wrong; this is a type attribute.
let Subjects = SubjectList<[TypedefName], ErrorDiag>;
let Args = [ExprArgument<"NumElements">];
let ASTNode = 0;
let Documentation = [Undocumented];
// This is a type attribute with an incorrect subject list, so should not be
// permitted by #pragma clang attribute.
let PragmaAttributeSupport = 0;
}
def FallThrough : StmtAttr {
let Spellings = [CXX11<"", "fallthrough", 201603>, C2x<"", "fallthrough">,
CXX11<"clang", "fallthrough">];
// let Subjects = [NullStmt];
let Documentation = [FallthroughDocs];
}
def FastCall : DeclOrTypeAttr {
let Spellings = [GCC<"fastcall">, Keyword<"__fastcall">,
Keyword<"_fastcall">];
// let Subjects = [Function, ObjCMethod];
let Documentation = [FastCallDocs];
}
def RegCall : DeclOrTypeAttr {
let Spellings = [GCC<"regcall">, Keyword<"__regcall">];
let Documentation = [RegCallDocs];
}
def Final : InheritableAttr {
let Spellings = [Keyword<"final">, Keyword<"sealed">];
let Accessors = [Accessor<"isSpelledAsSealed", [Keyword<"sealed">]>];
let SemaHandler = 0;
let Documentation = [Undocumented];
}
def MinSize : InheritableAttr {
let Spellings = [Clang<"minsize">];
let Subjects = SubjectList<[Function, ObjCMethod], ErrorDiag>;
let Documentation = [Undocumented];
}
def FlagEnum : InheritableAttr {
let Spellings = [Clang<"flag_enum">];
let Subjects = SubjectList<[Enum]>;
let Documentation = [FlagEnumDocs];
}
def EnumExtensibility : InheritableAttr {
let Spellings = [Clang<"enum_extensibility">];
let Subjects = SubjectList<[Enum]>;
let Args = [EnumArgument<"Extensibility", "Kind",
["closed", "open"], ["Closed", "Open"]>];
let Documentation = [EnumExtensibilityDocs];
}
def Flatten : InheritableAttr {
let Spellings = [GCC<"flatten">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [FlattenDocs];
}
def Format : InheritableAttr {
let Spellings = [GCC<"format">];
let Args = [IdentifierArgument<"Type">, IntArgument<"FormatIdx">,
IntArgument<"FirstArg">];
let Subjects = SubjectList<[ObjCMethod, Block, HasFunctionProto]>;
let Documentation = [FormatDocs];
}
def FormatArg : InheritableAttr {
let Spellings = [GCC<"format_arg">];
let Args = [ParamIdxArgument<"FormatIdx">];
let Subjects = SubjectList<[ObjCMethod, HasFunctionProto]>;
let Documentation = [Undocumented];
}
def Callback : InheritableAttr {
let Spellings = [Clang<"callback">];
let Args = [VariadicParamOrParamIdxArgument<"Encoding">];
let Subjects = SubjectList<[Function]>;
let Documentation = [CallbackDocs];
}
def GNUInline : InheritableAttr {
let Spellings = [GCC<"gnu_inline">];
let Subjects = SubjectList<[Function]>;
let Documentation = [GnuInlineDocs];
}
def Hot : InheritableAttr {
let Spellings = [GCC<"hot">];
let Subjects = SubjectList<[Function]>;
// An AST node is created for this attribute, but not actually used beyond
// semantic checking for mutual exclusion with the Cold attribute.
let Documentation = [Undocumented];
}
def IBAction : InheritableAttr {
let Spellings = [Clang<"ibaction">];
let Subjects = SubjectList<[ObjCInstanceMethod]>;
// An AST node is created for this attribute, but is not used by other parts
// of the compiler. However, this node needs to exist in the AST because
// external tools rely on it.
let Documentation = [Undocumented];
}
def IBOutlet : InheritableAttr {
let Spellings = [Clang<"iboutlet">];
// let Subjects = [ObjCIvar, ObjCProperty];
let Documentation = [Undocumented];
}
def IBOutletCollection : InheritableAttr {
let Spellings = [Clang<"iboutletcollection">];
let Args = [TypeArgument<"Interface", 1>];
// let Subjects = [ObjCIvar, ObjCProperty];
let Documentation = [Undocumented];
}
def IFunc : Attr, TargetSpecificAttr<TargetELF> {
let Spellings = [GCC<"ifunc">];
let Args = [StringArgument<"Resolver">];
let Subjects = SubjectList<[Function]>;
let Documentation = [IFuncDocs];
}
def Restrict : InheritableAttr {
let Spellings = [Declspec<"restrict">, GCC<"malloc">];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def LayoutVersion : InheritableAttr, TargetSpecificAttr<TargetMicrosoftCXXABI> {
let Spellings = [Declspec<"layout_version">];
let Args = [UnsignedArgument<"Version">];
let Subjects = SubjectList<[CXXRecord]>;
let Documentation = [LayoutVersionDocs];
}
def LifetimeBound : DeclOrTypeAttr {
let Spellings = [Clang<"lifetimebound", 0>];
let Subjects = SubjectList<[ParmVar, ImplicitObjectParameter], ErrorDiag>;
let Documentation = [LifetimeBoundDocs];
let LangOpts = [CPlusPlus];
}
def TrivialABI : InheritableAttr {
// This attribute does not have a C [[]] spelling because it requires the
// CPlusPlus language option.
let Spellings = [Clang<"trivial_abi", 0>];
let Subjects = SubjectList<[CXXRecord]>;
let Documentation = [TrivialABIDocs];
let LangOpts = [CPlusPlus];
}
def MaxFieldAlignment : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let Args = [UnsignedArgument<"Alignment">];
let SemaHandler = 0;
let Documentation = [Undocumented];
}
def MayAlias : InheritableAttr {
// FIXME: this is a type attribute in GCC, but a declaration attribute here.
let Spellings = [GCC<"may_alias">];
let Documentation = [Undocumented];
}
def MIGServerRoutine : InheritableAttr {
let Spellings = [Clang<"mig_server_routine">];
let Subjects = SubjectList<[Function, ObjCMethod, Block]>;
let Documentation = [MIGConventionDocs];
}
def MSABI : DeclOrTypeAttr {
let Spellings = [GCC<"ms_abi">];
// let Subjects = [Function, ObjCMethod];
let Documentation = [MSABIDocs];
}
def MSP430Interrupt : InheritableAttr, TargetSpecificAttr<TargetMSP430> {
// NOTE: If you add any additional spellings, ARMInterrupt's, MipsInterrupt's
// and AnyX86Interrupt's spellings must match.
let Spellings = [GCC<"interrupt">];
let Args = [UnsignedArgument<"Number">];
let ParseKind = "Interrupt";
let HasCustomParsing = 1;
let Documentation = [Undocumented];
}
def Mips16 : InheritableAttr, TargetSpecificAttr<TargetMips32> {
let Spellings = [GCC<"mips16">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [Undocumented];
}
def MipsInterrupt : InheritableAttr, TargetSpecificAttr<TargetMips32> {
// NOTE: If you add any additional spellings, ARMInterrupt's,
// MSP430Interrupt's and AnyX86Interrupt's spellings must match.
let Spellings = [GCC<"interrupt">];
let Subjects = SubjectList<[Function]>;
let Args = [EnumArgument<"Interrupt", "InterruptType",
["vector=sw0", "vector=sw1", "vector=hw0",
"vector=hw1", "vector=hw2", "vector=hw3",
"vector=hw4", "vector=hw5", "eic", ""],
["sw0", "sw1", "hw0", "hw1", "hw2", "hw3",
"hw4", "hw5", "eic", "eic"]
>];
let ParseKind = "Interrupt";
let Documentation = [MipsInterruptDocs];
}
def MicroMips : InheritableAttr, TargetSpecificAttr<TargetMips32> {
let Spellings = [GCC<"micromips">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [MicroMipsDocs];
}
def MipsLongCall : InheritableAttr, TargetSpecificAttr<TargetAnyMips> {
let Spellings = [GCC<"long_call">, GCC<"far">];
let Subjects = SubjectList<[Function]>;
let Documentation = [MipsLongCallStyleDocs];
}
def MipsShortCall : InheritableAttr, TargetSpecificAttr<TargetAnyMips> {
let Spellings = [GCC<"short_call">, GCC<"near">];
let Subjects = SubjectList<[Function]>;
let Documentation = [MipsShortCallStyleDocs];
}
def Mode : Attr {
let Spellings = [GCC<"mode">];
let Subjects = SubjectList<[Var, Enum, TypedefName, Field], ErrorDiag>;
let Args = [IdentifierArgument<"Mode">];
let Documentation = [Undocumented];
// This is notionally a type attribute, which #pragma clang attribute
// generally does not support.
let PragmaAttributeSupport = 0;
}
def Naked : InheritableAttr {
let Spellings = [GCC<"naked">, Declspec<"naked">];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def NeonPolyVectorType : TypeAttr {
let Spellings = [Clang<"neon_polyvector_type">];
let Args = [IntArgument<"NumElements">];
let Documentation = [Undocumented];
// Represented as VectorType instead.
let ASTNode = 0;
}
def NeonVectorType : TypeAttr {
let Spellings = [Clang<"neon_vector_type">];
let Args = [IntArgument<"NumElements">];
let Documentation = [Undocumented];
// Represented as VectorType instead.
let ASTNode = 0;
}
def NoUniqueAddress : InheritableAttr, TargetSpecificAttr<TargetItaniumCXXABI> {
let Spellings = [CXX11<"", "no_unique_address", 201803>];
let Subjects = SubjectList<[NonBitField], ErrorDiag>;
let Documentation = [NoUniqueAddressDocs];
}
def ReturnsTwice : InheritableAttr {
let Spellings = [GCC<"returns_twice">];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def DisableTailCalls : InheritableAttr {
let Spellings = [Clang<"disable_tail_calls">];
let Subjects = SubjectList<[Function, ObjCMethod]>;
let Documentation = [DisableTailCallsDocs];
}
def NoAlias : InheritableAttr {
let Spellings = [Declspec<"noalias">];
let Subjects = SubjectList<[Function]>;
let Documentation = [NoAliasDocs];
}
def NoCommon : InheritableAttr {
let Spellings = [GCC<"nocommon">];
let Subjects = SubjectList<[Var]>;
let Documentation = [Undocumented];
}
def NoDebug : InheritableAttr {
let Spellings = [GCC<"nodebug">];
let Subjects = SubjectList<[TypedefName, FunctionLike, ObjCMethod, NonParmVar]>;
let Documentation = [NoDebugDocs];
}
def NoDuplicate : InheritableAttr {
let Spellings = [Clang<"noduplicate">];
let Subjects = SubjectList<[Function]>;
let Documentation = [NoDuplicateDocs];
}
def Convergent : InheritableAttr {
let Spellings = [Clang<"convergent">];
let Subjects = SubjectList<[Function]>;
let Documentation = [ConvergentDocs];
}
def NoInline : InheritableAttr {
let Spellings = [GCC<"noinline">, Declspec<"noinline">];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def NoMips16 : InheritableAttr, TargetSpecificAttr<TargetMips32> {
let Spellings = [GCC<"nomips16">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [Undocumented];
}
def NoMicroMips : InheritableAttr, TargetSpecificAttr<TargetMips32> {
let Spellings = [GCC<"nomicromips">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [MicroMipsDocs];
}
def RISCVInterrupt : InheritableAttr, TargetSpecificAttr<TargetRISCV> {
let Spellings = [GCC<"interrupt">];
let Subjects = SubjectList<[Function]>;
let Args = [EnumArgument<"Interrupt", "InterruptType",
["user", "supervisor", "machine"],
["user", "supervisor", "machine"],
1>];
let ParseKind = "Interrupt";
let Documentation = [RISCVInterruptDocs];
}
// This is not a TargetSpecificAttr so that is silently accepted and
// ignored on other targets as encouraged by the OpenCL spec.
//
// See OpenCL 1.2 6.11.5: "It is our intention that a particular
// implementation of OpenCL be free to ignore all attributes and the
// resulting executable binary will produce the same result."
//
// However, only AMD GPU targets will emit the corresponding IR
// attribute.
//
// FIXME: This provides a sub-optimal error message if you attempt to
// use this in CUDA, since CUDA does not use the same terminology.
//
// FIXME: SubjectList should be for OpenCLKernelFunction, but is not to
// workaround needing to see kernel attribute before others to know if
// this should be rejected on non-kernels.
def AMDGPUFlatWorkGroupSize : InheritableAttr {
let Spellings = [Clang<"amdgpu_flat_work_group_size", 0>];
let Args = [ExprArgument<"Min">, ExprArgument<"Max">];
let Documentation = [AMDGPUFlatWorkGroupSizeDocs];
let Subjects = SubjectList<[Function], ErrorDiag, "kernel functions">;
}
def AMDGPUWavesPerEU : InheritableAttr {
let Spellings = [Clang<"amdgpu_waves_per_eu", 0>];
let Args = [ExprArgument<"Min">, ExprArgument<"Max", 1>];
let Documentation = [AMDGPUWavesPerEUDocs];
let Subjects = SubjectList<[Function], ErrorDiag, "kernel functions">;
}
def AMDGPUNumSGPR : InheritableAttr {
let Spellings = [Clang<"amdgpu_num_sgpr", 0>];
let Args = [UnsignedArgument<"NumSGPR">];
let Documentation = [AMDGPUNumSGPRNumVGPRDocs];
let Subjects = SubjectList<[Function], ErrorDiag, "kernel functions">;
}
def AMDGPUNumVGPR : InheritableAttr {
let Spellings = [Clang<"amdgpu_num_vgpr", 0>];
let Args = [UnsignedArgument<"NumVGPR">];
let Documentation = [AMDGPUNumSGPRNumVGPRDocs];
let Subjects = SubjectList<[Function], ErrorDiag, "kernel functions">;
}
def WebAssemblyImportModule : InheritableAttr,
TargetSpecificAttr<TargetWebAssembly> {
let Spellings = [Clang<"import_module">];
let Args = [StringArgument<"ImportModule">];
let Documentation = [WebAssemblyImportModuleDocs];
let Subjects = SubjectList<[Function], ErrorDiag>;
}
def WebAssemblyImportName : InheritableAttr,
TargetSpecificAttr<TargetWebAssembly> {
let Spellings = [Clang<"import_name">];
let Args = [StringArgument<"ImportName">];
let Documentation = [WebAssemblyImportNameDocs];
let Subjects = SubjectList<[Function], ErrorDiag>;
}
def NoSplitStack : InheritableAttr {
let Spellings = [GCC<"no_split_stack">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [NoSplitStackDocs];
}
def NonNull : InheritableParamAttr {
let Spellings = [GCC<"nonnull">];
let Subjects = SubjectList<[ObjCMethod, HasFunctionProto, ParmVar], WarnDiag,
"functions, methods, and parameters">;
let Args = [VariadicParamIdxArgument<"Args">];
let AdditionalMembers = [{
bool isNonNull(unsigned IdxAST) const {
if (!args_size())
return true;
return args_end() != std::find_if(
args_begin(), args_end(),
[=](const ParamIdx &Idx) { return Idx.getASTIndex() == IdxAST; });
}
}];
// FIXME: We should merge duplicates into a single nonnull attribute.
let InheritEvenIfAlreadyPresent = 1;
let Documentation = [NonNullDocs];
}
def ReturnsNonNull : InheritableAttr {
let Spellings = [GCC<"returns_nonnull">];
let Subjects = SubjectList<[ObjCMethod, Function]>;
let Documentation = [ReturnsNonNullDocs];
}
// pass_object_size(N) indicates that the parameter should have
// __builtin_object_size with Type=N evaluated on the parameter at the callsite.
def PassObjectSize : InheritableParamAttr {
let Spellings = [Clang<"pass_object_size">,
Clang<"pass_dynamic_object_size">];
let Accessors = [Accessor<"isDynamic", [Clang<"pass_dynamic_object_size">]>];
let Args = [IntArgument<"Type">];
let Subjects = SubjectList<[ParmVar]>;
let Documentation = [PassObjectSizeDocs];
}
// Nullability type attributes.
def TypeNonNull : TypeAttr {
let Spellings = [Keyword<"_Nonnull">];
let Documentation = [TypeNonNullDocs];
}
def TypeNullable : TypeAttr {
let Spellings = [Keyword<"_Nullable">];
let Documentation = [TypeNullableDocs];
}
def TypeNullUnspecified : TypeAttr {
let Spellings = [Keyword<"_Null_unspecified">];
let Documentation = [TypeNullUnspecifiedDocs];
}
// This is a marker used to indicate that an __unsafe_unretained qualifier was
// ignored because ARC is not enabled. The usual representation for this
// qualifier is as an ObjCOwnership attribute with Kind == "none".
def ObjCInertUnsafeUnretained : TypeAttr {
let Spellings = [Keyword<"__unsafe_unretained">];
let Documentation = [Undocumented];
}
def ObjCKindOf : TypeAttr {
let Spellings = [Keyword<"__kindof">];
let Documentation = [Undocumented];
}
def NoEscape : Attr {
let Spellings = [Clang<"noescape">];
let Subjects = SubjectList<[ParmVar]>;
let Documentation = [NoEscapeDocs];
}
def AssumeAligned : InheritableAttr {
let Spellings = [GCC<"assume_aligned">];
let Subjects = SubjectList<[ObjCMethod, Function]>;
let Args = [ExprArgument<"Alignment">, ExprArgument<"Offset", 1>];
let Documentation = [AssumeAlignedDocs];
}
def AllocAlign : InheritableAttr {
let Spellings = [GCC<"alloc_align">];
let Subjects = SubjectList<[HasFunctionProto]>;
let Args = [ParamIdxArgument<"ParamIndex">];
let Documentation = [AllocAlignDocs];
}
def NoReturn : InheritableAttr {
let Spellings = [GCC<"noreturn">, Declspec<"noreturn">];
// FIXME: Does GCC allow this on the function instead?
let Documentation = [Undocumented];
}
def NoInstrumentFunction : InheritableAttr {
let Spellings = [GCC<"no_instrument_function">];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def NotTailCalled : InheritableAttr {
let Spellings = [Clang<"not_tail_called">];
let Subjects = SubjectList<[Function]>;
let Documentation = [NotTailCalledDocs];
}
def NoStackProtector : InheritableAttr {
let Spellings = [Clang<"no_stack_protector">];
let Subjects = SubjectList<[Function]>;
let Documentation = [NoStackProtectorDocs];
}
def NoThrow : InheritableAttr {
let Spellings = [GCC<"nothrow">, Declspec<"nothrow">];
let Subjects = SubjectList<[FunctionLike]>;
let Documentation = [NoThrowDocs];
}
def NvWeak : IgnoredAttr {
// No Declspec spelling of this attribute; the CUDA headers use
// __attribute__((nv_weak)) unconditionally. Does not receive an [[]]
// spelling because it is a CUDA attribute.
let Spellings = [GNU<"nv_weak">];
let LangOpts = [CUDA];
}
def ObjCBridge : InheritableAttr {
let Spellings = [Clang<"objc_bridge">];
let Subjects = SubjectList<[Record, TypedefName], ErrorDiag>;
let Args = [IdentifierArgument<"BridgedType">];
let Documentation = [Undocumented];
}
def ObjCBridgeMutable : InheritableAttr {
let Spellings = [Clang<"objc_bridge_mutable">];
let Subjects = SubjectList<[Record], ErrorDiag>;
let Args = [IdentifierArgument<"BridgedType">];
let Documentation = [Undocumented];
}
def ObjCBridgeRelated : InheritableAttr {
let Spellings = [Clang<"objc_bridge_related">];
let Subjects = SubjectList<[Record], ErrorDiag>;
let Args = [IdentifierArgument<"RelatedClass">,
IdentifierArgument<"ClassMethod">,
IdentifierArgument<"InstanceMethod">];
let HasCustomParsing = 1;
let Documentation = [Undocumented];
}
def NSReturnsRetained : DeclOrTypeAttr {
let Spellings = [Clang<"ns_returns_retained">];
// let Subjects = SubjectList<[ObjCMethod, ObjCProperty, Function]>;
let Documentation = [RetainBehaviorDocs];
}
def NSReturnsNotRetained : InheritableAttr {
let Spellings = [Clang<"ns_returns_not_retained">];
// let Subjects = SubjectList<[ObjCMethod, ObjCProperty, Function]>;
let Documentation = [RetainBehaviorDocs];
}
def NSReturnsAutoreleased : InheritableAttr {
let Spellings = [Clang<"ns_returns_autoreleased">];
// let Subjects = SubjectList<[ObjCMethod, ObjCProperty, Function]>;
let Documentation = [RetainBehaviorDocs];
}
def NSConsumesSelf : InheritableAttr {
let Spellings = [Clang<"ns_consumes_self">];
let Subjects = SubjectList<[ObjCMethod]>;
let Documentation = [RetainBehaviorDocs];
}
def NSConsumed : InheritableParamAttr {
let Spellings = [Clang<"ns_consumed">];
let Subjects = SubjectList<[ParmVar]>;
let Documentation = [RetainBehaviorDocs];
}
def ObjCException : InheritableAttr {
let Spellings = [Clang<"objc_exception">];
let Subjects = SubjectList<[ObjCInterface], ErrorDiag>;
let Documentation = [Undocumented];
}
def ObjCMethodFamily : InheritableAttr {
let Spellings = [Clang<"objc_method_family">];
let Subjects = SubjectList<[ObjCMethod], ErrorDiag>;
let Args = [EnumArgument<"Family", "FamilyKind",
["none", "alloc", "copy", "init", "mutableCopy", "new"],
["OMF_None", "OMF_alloc", "OMF_copy", "OMF_init",
"OMF_mutableCopy", "OMF_new"]>];
let Documentation = [ObjCMethodFamilyDocs];
}
def ObjCNSObject : InheritableAttr {
let Spellings = [Clang<"NSObject">];
let Documentation = [Undocumented];
}
def ObjCIndependentClass : InheritableAttr {
let Spellings = [Clang<"objc_independent_class">];
let Documentation = [Undocumented];
}
def ObjCPreciseLifetime : InheritableAttr {
let Spellings = [Clang<"objc_precise_lifetime">];
let Subjects = SubjectList<[Var], ErrorDiag>;
let Documentation = [Undocumented];
}
def ObjCReturnsInnerPointer : InheritableAttr {
let Spellings = [Clang<"objc_returns_inner_pointer">];
let Subjects = SubjectList<[ObjCMethod, ObjCProperty], ErrorDiag>;
let Documentation = [Undocumented];
}
def ObjCRequiresSuper : InheritableAttr {
let Spellings = [Clang<"objc_requires_super">];
let Subjects = SubjectList<[ObjCMethod], ErrorDiag>;
let Documentation = [ObjCRequiresSuperDocs];
}
def ObjCRootClass : InheritableAttr {
let Spellings = [Clang<"objc_root_class">];
let Subjects = SubjectList<[ObjCInterface], ErrorDiag>;
let Documentation = [Undocumented];
}
def ObjCNonLazyClass : Attr {
let Spellings = [Clang<"objc_nonlazy_class">];
let Subjects = SubjectList<[ObjCInterface, ObjCImpl], ErrorDiag>;
let LangOpts = [ObjC];
let Documentation = [ObjCNonLazyClassDocs];
}
def ObjCSubclassingRestricted : InheritableAttr {
let Spellings = [Clang<"objc_subclassing_restricted">];
let Subjects = SubjectList<[ObjCInterface], ErrorDiag>;
let Documentation = [ObjCSubclassingRestrictedDocs];
}
def ObjCExplicitProtocolImpl : InheritableAttr {
let Spellings = [Clang<"objc_protocol_requires_explicit_implementation">];
let Subjects = SubjectList<[ObjCProtocol], ErrorDiag>;
let Documentation = [Undocumented];
}
def ObjCDesignatedInitializer : Attr {
let Spellings = [Clang<"objc_designated_initializer">];
let Subjects = SubjectList<[ObjCMethod], ErrorDiag>;
let Documentation = [Undocumented];
}
def ObjCRuntimeName : Attr {
let Spellings = [Clang<"objc_runtime_name">];
let Subjects = SubjectList<[ObjCInterface, ObjCProtocol], ErrorDiag>;
let Args = [StringArgument<"MetadataName">];
let Documentation = [ObjCRuntimeNameDocs];
}
def ObjCRuntimeVisible : Attr {
let Spellings = [Clang<"objc_runtime_visible">];
let Subjects = SubjectList<[ObjCInterface], ErrorDiag>;
let Documentation = [ObjCRuntimeVisibleDocs];
}
def ObjCClassStub : Attr {
let Spellings = [Clang<"objc_class_stub">];
let Subjects = SubjectList<[ObjCInterface], ErrorDiag>;
let Documentation = [ObjCClassStubDocs];
let LangOpts = [ObjCNonFragileRuntime];
}
def ObjCBoxable : Attr {
let Spellings = [Clang<"objc_boxable">];
let Subjects = SubjectList<[Record], ErrorDiag>;
let Documentation = [ObjCBoxableDocs];
}
def OptimizeNone : InheritableAttr {
let Spellings = [Clang<"optnone">];
let Subjects = SubjectList<[Function, ObjCMethod]>;
let Documentation = [OptnoneDocs];
}
def Overloadable : Attr {
let Spellings = [Clang<"overloadable">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [OverloadableDocs];
}
def Override : InheritableAttr {
let Spellings = [Keyword<"override">];
let SemaHandler = 0;
let Documentation = [Undocumented];
}
def Ownership : InheritableAttr {
let Spellings = [Clang<"ownership_holds">, Clang<"ownership_returns">,
Clang<"ownership_takes">];
let Accessors = [Accessor<"isHolds", [Clang<"ownership_holds">]>,
Accessor<"isReturns", [Clang<"ownership_returns">]>,
Accessor<"isTakes", [Clang<"ownership_takes">]>];
let AdditionalMembers = [{
enum OwnershipKind { Holds, Returns, Takes };
OwnershipKind getOwnKind() const {
return isHolds() ? Holds :
isTakes() ? Takes :
Returns;
}
}];
let Args = [IdentifierArgument<"Module">,
VariadicParamIdxArgument<"Args">];
let Subjects = SubjectList<[HasFunctionProto]>;
let Documentation = [Undocumented];
}
def Packed : InheritableAttr {
let Spellings = [GCC<"packed">];
// let Subjects = [Tag, Field];
let Documentation = [Undocumented];
}
def IntelOclBicc : DeclOrTypeAttr {
let Spellings = [Clang<"intel_ocl_bicc", 0>];
// let Subjects = [Function, ObjCMethod];
let Documentation = [Undocumented];
}
def Pcs : DeclOrTypeAttr {
let Spellings = [GCC<"pcs">];
let Args = [EnumArgument<"PCS", "PCSType",
["aapcs", "aapcs-vfp"],
["AAPCS", "AAPCS_VFP"]>];
// let Subjects = [Function, ObjCMethod];
let Documentation = [PcsDocs];
}
def AArch64VectorPcs: DeclOrTypeAttr {
let Spellings = [Clang<"aarch64_vector_pcs">];
let Documentation = [AArch64VectorPcsDocs];
}
def Pure : InheritableAttr {
let Spellings = [GCC<"pure">];
let Documentation = [Undocumented];
}
def Regparm : TypeAttr {
let Spellings = [GCC<"regparm">];
let Args = [UnsignedArgument<"NumParams">];
let Documentation = [RegparmDocs];
// Represented as part of the enclosing function type.
let ASTNode = 0;
}
def NoDeref : TypeAttr {
let Spellings = [Clang<"noderef">];
let Documentation = [NoDerefDocs];
}
def ReqdWorkGroupSize : InheritableAttr {
// Does not have a [[]] spelling because it is an OpenCL-related attribute.
let Spellings = [GNU<"reqd_work_group_size">];
let Args = [UnsignedArgument<"XDim">, UnsignedArgument<"YDim">,
UnsignedArgument<"ZDim">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [Undocumented];
}
def RequireConstantInit : InheritableAttr {
// This attribute does not have a C [[]] spelling because it requires the
// CPlusPlus language option.
let Spellings = [Clang<"require_constant_initialization", 0>];
let Subjects = SubjectList<[GlobalVar], ErrorDiag>;
let Documentation = [RequireConstantInitDocs];
let LangOpts = [CPlusPlus];
}
def WorkGroupSizeHint : InheritableAttr {
// Does not have a [[]] spelling because it is an OpenCL-related attribute.
let Spellings = [GNU<"work_group_size_hint">];
let Args = [UnsignedArgument<"XDim">,
UnsignedArgument<"YDim">,
UnsignedArgument<"ZDim">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [Undocumented];
}
def InitPriority : InheritableAttr {
let Spellings = [GCC<"init_priority">];
let Args = [UnsignedArgument<"Priority">];
let Subjects = SubjectList<[Var], ErrorDiag>;
let Documentation = [Undocumented];
}
def Section : InheritableAttr {
let Spellings = [GCC<"section">, Declspec<"allocate">];
let Args = [StringArgument<"Name">];
let Subjects =
SubjectList<[ Function, GlobalVar, ObjCMethod, ObjCProperty ], ErrorDiag>;
let Documentation = [SectionDocs];
}
// This is used for `__declspec(code_seg("segname"))`, but not for
// `#pragma code_seg("segname")`.
def CodeSeg : InheritableAttr {
let Spellings = [Declspec<"code_seg">];
let Args = [StringArgument<"Name">];
let Subjects = SubjectList<[Function, CXXRecord], ErrorDiag>;
let Documentation = [CodeSegDocs];
}
def PragmaClangBSSSection : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let Args = [StringArgument<"Name">];
let Subjects = SubjectList<[GlobalVar], ErrorDiag>;
let Documentation = [Undocumented];
}
def PragmaClangDataSection : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let Args = [StringArgument<"Name">];
let Subjects = SubjectList<[GlobalVar], ErrorDiag>;
let Documentation = [Undocumented];
}
def PragmaClangRodataSection : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let Args = [StringArgument<"Name">];
let Subjects = SubjectList<[GlobalVar], ErrorDiag>;
let Documentation = [Undocumented];
}
def PragmaClangTextSection : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let Args = [StringArgument<"Name">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [Undocumented];
}
def Sentinel : InheritableAttr {
let Spellings = [GCC<"sentinel">];
let Args = [DefaultIntArgument<"Sentinel", 0>,
DefaultIntArgument<"NullPos", 0>];
// let Subjects = SubjectList<[Function, ObjCMethod, Block, Var]>;
let Documentation = [Undocumented];
}
def StdCall : DeclOrTypeAttr {
let Spellings = [GCC<"stdcall">, Keyword<"__stdcall">, Keyword<"_stdcall">];
// let Subjects = [Function, ObjCMethod];
let Documentation = [StdCallDocs];
}
def SwiftCall : DeclOrTypeAttr {
let Spellings = [Clang<"swiftcall">];
// let Subjects = SubjectList<[Function]>;
let Documentation = [SwiftCallDocs];
}
def SwiftContext : ParameterABIAttr {
let Spellings = [Clang<"swift_context">];
let Documentation = [SwiftContextDocs];
}
def SwiftErrorResult : ParameterABIAttr {
let Spellings = [Clang<"swift_error_result">];
let Documentation = [SwiftErrorResultDocs];
}
def SwiftIndirectResult : ParameterABIAttr {
let Spellings = [Clang<"swift_indirect_result">];
let Documentation = [SwiftIndirectResultDocs];
}
def Suppress : StmtAttr {
let Spellings = [CXX11<"gsl", "suppress">];
let Args = [VariadicStringArgument<"DiagnosticIdentifiers">];
let Documentation = [SuppressDocs];
}
def SysVABI : DeclOrTypeAttr {
let Spellings = [GCC<"sysv_abi">];
// let Subjects = [Function, ObjCMethod];
let Documentation = [Undocumented];
}
def ThisCall : DeclOrTypeAttr {
let Spellings = [GCC<"thiscall">, Keyword<"__thiscall">,
Keyword<"_thiscall">];
// let Subjects = [Function, ObjCMethod];
let Documentation = [ThisCallDocs];
}
def VectorCall : DeclOrTypeAttr {
let Spellings = [Clang<"vectorcall">, Keyword<"__vectorcall">,
Keyword<"_vectorcall">];
// let Subjects = [Function, ObjCMethod];
let Documentation = [VectorCallDocs];
}
def Pascal : DeclOrTypeAttr {
let Spellings = [Clang<"pascal">, Keyword<"__pascal">, Keyword<"_pascal">];
// let Subjects = [Function, ObjCMethod];
let Documentation = [Undocumented];
}
def PreserveMost : DeclOrTypeAttr {
let Spellings = [Clang<"preserve_most">];
let Documentation = [PreserveMostDocs];
}
def PreserveAll : DeclOrTypeAttr {
let Spellings = [Clang<"preserve_all">];
let Documentation = [PreserveAllDocs];
}
def Target : InheritableAttr {
let Spellings = [GCC<"target">];
let Args = [StringArgument<"featuresStr">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [TargetDocs];
let AdditionalMembers = [{
struct ParsedTargetAttr {
std::vector<std::string> Features;
StringRef Architecture;
bool DuplicateArchitecture = false;
bool operator ==(const ParsedTargetAttr &Other) const {
return DuplicateArchitecture == Other.DuplicateArchitecture &&
Architecture == Other.Architecture && Features == Other.Features;
}
};
ParsedTargetAttr parse() const {
return parse(getFeaturesStr());
}
StringRef getArchitecture() const {
StringRef Features = getFeaturesStr();
if (Features == "default") return {};
SmallVector<StringRef, 1> AttrFeatures;
Features.split(AttrFeatures, ",");
for (auto &Feature : AttrFeatures) {
Feature = Feature.trim();
if (Feature.startswith("arch="))
return Feature.drop_front(sizeof("arch=") - 1);
}
return "";
}
// Gets the list of features as simple string-refs with no +/- or 'no-'.
// Only adds the items to 'Out' that are additions.
void getAddedFeatures(llvm::SmallVectorImpl<StringRef> &Out) const {
StringRef Features = getFeaturesStr();
if (Features == "default") return;
SmallVector<StringRef, 1> AttrFeatures;
Features.split(AttrFeatures, ",");
for (auto &Feature : AttrFeatures) {
Feature = Feature.trim();
if (!Feature.startswith("no-") && !Feature.startswith("arch=") &&
!Feature.startswith("fpmath=") && !Feature.startswith("tune="))
Out.push_back(Feature);
}
}
template<class Compare>
ParsedTargetAttr parse(Compare cmp) const {
ParsedTargetAttr Attrs = parse();
llvm::sort(std::begin(Attrs.Features), std::end(Attrs.Features), cmp);
return Attrs;
}
bool isDefaultVersion() const { return getFeaturesStr() == "default"; }
static ParsedTargetAttr parse(StringRef Features) {
ParsedTargetAttr Ret;
if (Features == "default") return Ret;
SmallVector<StringRef, 1> AttrFeatures;
Features.split(AttrFeatures, ",");
// Grab the various features and prepend a "+" to turn on the feature to
// the backend and add them to our existing set of features.
for (auto &Feature : AttrFeatures) {
// Go ahead and trim whitespace rather than either erroring or
// accepting it weirdly.
Feature = Feature.trim();
// We don't support cpu tuning this way currently.
// TODO: Support the fpmath option. It will require checking
// overall feature validity for the function with the rest of the
// attributes on the function.
if (Feature.startswith("fpmath=") || Feature.startswith("tune="))
continue;
// While we're here iterating check for a different target cpu.
if (Feature.startswith("arch=")) {
if (!Ret.Architecture.empty())
Ret.DuplicateArchitecture = true;
else
Ret.Architecture = Feature.split("=").second.trim();
} else if (Feature.startswith("no-"))
Ret.Features.push_back("-" + Feature.split("-").second.str());
else
Ret.Features.push_back("+" + Feature.str());
}
return Ret;
}
}];
}
def MinVectorWidth : InheritableAttr {
let Spellings = [Clang<"min_vector_width">];
let Args = [UnsignedArgument<"VectorWidth">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [MinVectorWidthDocs];
}
def TransparentUnion : InheritableAttr {
let Spellings = [GCC<"transparent_union">];
// let Subjects = SubjectList<[Record, TypedefName]>;
let Documentation = [TransparentUnionDocs];
let LangOpts = [COnly];
}
def Unavailable : InheritableAttr {
let Spellings = [Clang<"unavailable">];
let Args = [StringArgument<"Message", 1>,
EnumArgument<"ImplicitReason", "ImplicitReason",
["", "", "", ""],
["IR_None",
"IR_ARCForbiddenType",
"IR_ForbiddenWeak",
"IR_ARCForbiddenConversion",
"IR_ARCInitReturnsUnrelated",
"IR_ARCFieldWithOwnership"], 1, /*fake*/ 1>];
let Documentation = [Undocumented];
}
def DiagnoseIf : InheritableAttr {
// Does not have a [[]] spelling because this attribute requires the ability
// to parse function arguments but the attribute is not written in the type
// position.
let Spellings = [GNU<"diagnose_if">];
let Subjects = SubjectList<[Function, ObjCMethod, ObjCProperty]>;
let Args = [ExprArgument<"Cond">, StringArgument<"Message">,
EnumArgument<"DiagnosticType",
"DiagnosticType",
["error", "warning"],
["DT_Error", "DT_Warning"]>,
BoolArgument<"ArgDependent", 0, /*fake*/ 1>,
NamedArgument<"Parent", 0, /*fake*/ 1>];
let InheritEvenIfAlreadyPresent = 1;
let LateParsed = 1;
let AdditionalMembers = [{
bool isError() const { return diagnosticType == DT_Error; }
bool isWarning() const { return diagnosticType == DT_Warning; }
}];
let TemplateDependent = 1;
let Documentation = [DiagnoseIfDocs];
}
def ArcWeakrefUnavailable : InheritableAttr {
let Spellings = [Clang<"objc_arc_weak_reference_unavailable">];
let Subjects = SubjectList<[ObjCInterface], ErrorDiag>;
let Documentation = [Undocumented];
}
def ObjCGC : TypeAttr {
let Spellings = [Clang<"objc_gc">];
let Args = [IdentifierArgument<"Kind">];
let Documentation = [Undocumented];
}
def ObjCOwnership : DeclOrTypeAttr {
let Spellings = [Clang<"objc_ownership">];
let Args = [IdentifierArgument<"Kind">];
let Documentation = [Undocumented];
}
def ObjCRequiresPropertyDefs : InheritableAttr {
let Spellings = [Clang<"objc_requires_property_definitions">];
let Subjects = SubjectList<[ObjCInterface], ErrorDiag>;
let Documentation = [Undocumented];
}
def Unused : InheritableAttr {
let Spellings = [CXX11<"", "maybe_unused", 201603>, GCC<"unused">,
C2x<"", "maybe_unused">];
let Subjects = SubjectList<[Var, ObjCIvar, Type, Enum, EnumConstant, Label,
Field, ObjCMethod, FunctionLike]>;
let Documentation = [WarnMaybeUnusedDocs];
}
def Used : InheritableAttr {
let Spellings = [GCC<"used">];
let Subjects = SubjectList<[NonLocalVar, Function, ObjCMethod]>;
let Documentation = [Undocumented];
}
def Uuid : InheritableAttr {
let Spellings = [Declspec<"uuid">, Microsoft<"uuid">];
let Args = [StringArgument<"Guid">];
let Subjects = SubjectList<[Record, Enum]>;
// FIXME: Allow expressing logical AND for LangOpts. Our condition should be:
// CPlusPlus && (MicrosoftExt || Borland)
let LangOpts = [MicrosoftExt, Borland];
let Documentation = [Undocumented];
}
def VectorSize : TypeAttr {
let Spellings = [GCC<"vector_size">];
let Args = [ExprArgument<"NumBytes">];
let Documentation = [Undocumented];
// Represented as VectorType instead.
let ASTNode = 0;
}
def VecTypeHint : InheritableAttr {
// Does not have a [[]] spelling because it is an OpenCL-related attribute.
let Spellings = [GNU<"vec_type_hint">];
let Args = [TypeArgument<"TypeHint">];
let Subjects = SubjectList<[Function], ErrorDiag>;
let Documentation = [Undocumented];
}
def Visibility : InheritableAttr {
let Clone = 0;
let Spellings = [GCC<"visibility">];
let Args = [EnumArgument<"Visibility", "VisibilityType",
["default", "hidden", "internal", "protected"],
["Default", "Hidden", "Hidden", "Protected"]>];
let MeaningfulToClassTemplateDefinition = 1;
let Documentation = [Undocumented];
}
def TypeVisibility : InheritableAttr {
let Clone = 0;
let Spellings = [Clang<"type_visibility">];
let Args = [EnumArgument<"Visibility", "VisibilityType",
["default", "hidden", "internal", "protected"],
["Default", "Hidden", "Hidden", "Protected"]>];
// let Subjects = [Tag, ObjCInterface, Namespace];
let Documentation = [Undocumented];
}
def VecReturn : InheritableAttr {
// This attribute does not have a C [[]] spelling because it only appertains
// to C++ struct/class/union.
// FIXME: should this attribute have a CPlusPlus language option?
let Spellings = [Clang<"vecreturn", 0>];
let Subjects = SubjectList<[CXXRecord], ErrorDiag>;
let Documentation = [Undocumented];
}
def WarnUnused : InheritableAttr {
let Spellings = [GCC<"warn_unused">];
let Subjects = SubjectList<[Record]>;
let Documentation = [Undocumented];
}
def WarnUnusedResult : InheritableAttr {
let Spellings = [CXX11<"", "nodiscard", 201603>, C2x<"", "nodiscard">,
CXX11<"clang", "warn_unused_result">,
GCC<"warn_unused_result">];
let Subjects = SubjectList<[ObjCMethod, Enum, Record, FunctionLike]>;
let Documentation = [WarnUnusedResultsDocs];
}
def Weak : InheritableAttr {
let Spellings = [GCC<"weak">];
let Subjects = SubjectList<[Var, Function, CXXRecord]>;
let Documentation = [Undocumented];
}
def WeakImport : InheritableAttr {
let Spellings = [Clang<"weak_import">];
let Documentation = [Undocumented];
}
def WeakRef : InheritableAttr {
let Spellings = [GCC<"weakref">];
// A WeakRef that has an argument is treated as being an AliasAttr
let Args = [StringArgument<"Aliasee", 1>];
let Subjects = SubjectList<[Var, Function], ErrorDiag>;
let Documentation = [Undocumented];
}
def LTOVisibilityPublic : InheritableAttr {
let Spellings = [Clang<"lto_visibility_public">];
let Subjects = SubjectList<[Record]>;
let Documentation = [LTOVisibilityDocs];
}
def AnyX86Interrupt : InheritableAttr, TargetSpecificAttr<TargetAnyX86> {
// NOTE: If you add any additional spellings, ARMInterrupt's,
// MSP430Interrupt's and MipsInterrupt's spellings must match.
let Spellings = [GCC<"interrupt">];
let Subjects = SubjectList<[HasFunctionProto]>;
let ParseKind = "Interrupt";
let HasCustomParsing = 1;
let Documentation = [Undocumented];
}
def AnyX86NoCallerSavedRegisters : InheritableAttr,
TargetSpecificAttr<TargetAnyX86> {
let Spellings = [GCC<"no_caller_saved_registers">];
let Documentation = [AnyX86NoCallerSavedRegistersDocs];
}
def AnyX86NoCfCheck : DeclOrTypeAttr, TargetSpecificAttr<TargetAnyX86>{
let Spellings = [GCC<"nocf_check">];
let Subjects = SubjectList<[FunctionLike]>;
let Documentation = [AnyX86NoCfCheckDocs];
}
def X86ForceAlignArgPointer : InheritableAttr, TargetSpecificAttr<TargetAnyX86> {
let Spellings = [GCC<"force_align_arg_pointer">];
// Technically, this appertains to a FunctionDecl, but the target-specific
// code silently allows anything function-like (such as typedefs or function
// pointers), but does not apply the attribute to them.
let Documentation = [X86ForceAlignArgPointerDocs];
}
def NoSanitize : InheritableAttr {
let Spellings = [Clang<"no_sanitize">];
let Args = [VariadicStringArgument<"Sanitizers">];
let Subjects = SubjectList<[Function, ObjCMethod, GlobalVar], ErrorDiag>;
let Documentation = [NoSanitizeDocs];
let AdditionalMembers = [{
SanitizerMask getMask() const {
SanitizerMask Mask;
for (auto SanitizerName : sanitizers()) {
SanitizerMask ParsedMask =
parseSanitizerValue(SanitizerName, /*AllowGroups=*/true);
Mask |= expandSanitizerGroups(ParsedMask);
}
return Mask;
}
}];
}
// Attributes to disable a specific sanitizer. No new sanitizers should be added
// to this list; the no_sanitize attribute should be extended instead.
def NoSanitizeSpecific : InheritableAttr {
let Spellings = [GCC<"no_address_safety_analysis">,
GCC<"no_sanitize_address">,
GCC<"no_sanitize_thread">,
Clang<"no_sanitize_memory">];
let Subjects = SubjectList<[Function, GlobalVar], ErrorDiag>;
let Documentation = [NoSanitizeAddressDocs, NoSanitizeThreadDocs,
NoSanitizeMemoryDocs];
let ASTNode = 0;
}
// C/C++ Thread safety attributes (e.g. for deadlock, data race checking)
// Not all of these attributes will be given a [[]] spelling. The attributes
// which require access to function parameter names cannot use the [[]] spelling
// because they are not written in the type position. Some attributes are given
// an updated captability-based name and the older name will only be supported
// under the GNU-style spelling.
def GuardedVar : InheritableAttr {
let Spellings = [Clang<"guarded_var", 0>];
let Subjects = SubjectList<[Field, SharedVar]>;
let Documentation = [Undocumented];
}
def PtGuardedVar : InheritableAttr {
let Spellings = [Clang<"pt_guarded_var", 0>];
let Subjects = SubjectList<[Field, SharedVar]>;
let Documentation = [Undocumented];
}
def Lockable : InheritableAttr {
let Spellings = [GNU<"lockable">];
let Subjects = SubjectList<[Record]>;
let Documentation = [Undocumented];
let ASTNode = 0; // Replaced by Capability
}
def ScopedLockable : InheritableAttr {
let Spellings = [Clang<"scoped_lockable", 0>];
let Subjects = SubjectList<[Record]>;
let Documentation = [Undocumented];
}
def Capability : InheritableAttr {
let Spellings = [Clang<"capability", 0>, Clang<"shared_capability", 0>];
let Subjects = SubjectList<[Record, TypedefName], ErrorDiag>;
let Args = [StringArgument<"Name">];
let Accessors = [Accessor<"isShared",
[Clang<"shared_capability", 0>]>];
let Documentation = [Undocumented];
let AdditionalMembers = [{
bool isMutex() const { return getName().equals_lower("mutex"); }
bool isRole() const { return getName().equals_lower("role"); }
}];
}
def AssertCapability : InheritableAttr {
let Spellings = [Clang<"assert_capability", 0>,
Clang<"assert_shared_capability", 0>];
let Subjects = SubjectList<[Function]>;
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Args = [VariadicExprArgument<"Args">];
let Accessors = [Accessor<"isShared",
[Clang<"assert_shared_capability", 0>]>];
let Documentation = [AssertCapabilityDocs];
}
def AcquireCapability : InheritableAttr {
let Spellings = [Clang<"acquire_capability", 0>,
Clang<"acquire_shared_capability", 0>,
GNU<"exclusive_lock_function">,
GNU<"shared_lock_function">];
let Subjects = SubjectList<[Function]>;
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Args = [VariadicExprArgument<"Args">];
let Accessors = [Accessor<"isShared",
[Clang<"acquire_shared_capability", 0>,
GNU<"shared_lock_function">]>];
let Documentation = [AcquireCapabilityDocs];
}
def TryAcquireCapability : InheritableAttr {
let Spellings = [Clang<"try_acquire_capability", 0>,
Clang<"try_acquire_shared_capability", 0>];
let Subjects = SubjectList<[Function],
ErrorDiag>;
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Args = [ExprArgument<"SuccessValue">, VariadicExprArgument<"Args">];
let Accessors = [Accessor<"isShared",
[Clang<"try_acquire_shared_capability", 0>]>];
let Documentation = [TryAcquireCapabilityDocs];
}
def ReleaseCapability : InheritableAttr {
let Spellings = [Clang<"release_capability", 0>,
Clang<"release_shared_capability", 0>,
Clang<"release_generic_capability", 0>,
Clang<"unlock_function", 0>];
let Subjects = SubjectList<[Function]>;
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Args = [VariadicExprArgument<"Args">];
let Accessors = [Accessor<"isShared",
[Clang<"release_shared_capability", 0>]>,
Accessor<"isGeneric",
[Clang<"release_generic_capability", 0>,
Clang<"unlock_function", 0>]>];
let Documentation = [ReleaseCapabilityDocs];
}
def RequiresCapability : InheritableAttr {
let Spellings = [Clang<"requires_capability", 0>,
Clang<"exclusive_locks_required", 0>,
Clang<"requires_shared_capability", 0>,
Clang<"shared_locks_required", 0>];
let Args = [VariadicExprArgument<"Args">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Function]>;
let Accessors = [Accessor<"isShared", [Clang<"requires_shared_capability", 0>,
Clang<"shared_locks_required", 0>]>];
let Documentation = [Undocumented];
}
def NoThreadSafetyAnalysis : InheritableAttr {
let Spellings = [Clang<"no_thread_safety_analysis">];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def GuardedBy : InheritableAttr {
let Spellings = [GNU<"guarded_by">];
let Args = [ExprArgument<"Arg">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Field, SharedVar]>;
let Documentation = [Undocumented];
}
def PtGuardedBy : InheritableAttr {
let Spellings = [GNU<"pt_guarded_by">];
let Args = [ExprArgument<"Arg">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Field, SharedVar]>;
let Documentation = [Undocumented];
}
def AcquiredAfter : InheritableAttr {
let Spellings = [GNU<"acquired_after">];
let Args = [VariadicExprArgument<"Args">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Field, SharedVar]>;
let Documentation = [Undocumented];
}
def AcquiredBefore : InheritableAttr {
let Spellings = [GNU<"acquired_before">];
let Args = [VariadicExprArgument<"Args">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Field, SharedVar]>;
let Documentation = [Undocumented];
}
def AssertExclusiveLock : InheritableAttr {
let Spellings = [GNU<"assert_exclusive_lock">];
let Args = [VariadicExprArgument<"Args">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def AssertSharedLock : InheritableAttr {
let Spellings = [GNU<"assert_shared_lock">];
let Args = [VariadicExprArgument<"Args">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
// The first argument is an integer or boolean value specifying the return value
// of a successful lock acquisition.
def ExclusiveTrylockFunction : InheritableAttr {
let Spellings = [GNU<"exclusive_trylock_function">];
let Args = [ExprArgument<"SuccessValue">, VariadicExprArgument<"Args">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
// The first argument is an integer or boolean value specifying the return value
// of a successful lock acquisition.
def SharedTrylockFunction : InheritableAttr {
let Spellings = [GNU<"shared_trylock_function">];
let Args = [ExprArgument<"SuccessValue">, VariadicExprArgument<"Args">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def LockReturned : InheritableAttr {
let Spellings = [GNU<"lock_returned">];
let Args = [ExprArgument<"Arg">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def LocksExcluded : InheritableAttr {
let Spellings = [GNU<"locks_excluded">];
let Args = [VariadicExprArgument<"Args">];
let LateParsed = 1;
let TemplateDependent = 1;
let ParseArgumentsAsUnevaluated = 1;
let InheritEvenIfAlreadyPresent = 1;
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
// C/C++ consumed attributes.
def Consumable : InheritableAttr {
// This attribute does not have a C [[]] spelling because it only appertains
// to C++ struct/class/union.
// FIXME: should this attribute have a CPlusPlus language option?
let Spellings = [Clang<"consumable", 0>];
let Subjects = SubjectList<[CXXRecord]>;
let Args = [EnumArgument<"DefaultState", "ConsumedState",
["unknown", "consumed", "unconsumed"],
["Unknown", "Consumed", "Unconsumed"]>];
let Documentation = [ConsumableDocs];
}
def ConsumableAutoCast : InheritableAttr {
// This attribute does not have a C [[]] spelling because it only appertains
// to C++ struct/class/union.
// FIXME: should this attribute have a CPlusPlus language option?
let Spellings = [Clang<"consumable_auto_cast_state", 0>];
let Subjects = SubjectList<[CXXRecord]>;
let Documentation = [Undocumented];
}
def ConsumableSetOnRead : InheritableAttr {
// This attribute does not have a C [[]] spelling because it only appertains
// to C++ struct/class/union.
// FIXME: should this attribute have a CPlusPlus language option?
let Spellings = [Clang<"consumable_set_state_on_read", 0>];
let Subjects = SubjectList<[CXXRecord]>;
let Documentation = [Undocumented];
}
def CallableWhen : InheritableAttr {
// This attribute does not have a C [[]] spelling because it only appertains
// to C++ function (but doesn't require it to be a member function).
// FIXME: should this attribute have a CPlusPlus language option?
let Spellings = [Clang<"callable_when", 0>];
let Subjects = SubjectList<[CXXMethod]>;
let Args = [VariadicEnumArgument<"CallableStates", "ConsumedState",
["unknown", "consumed", "unconsumed"],
["Unknown", "Consumed", "Unconsumed"]>];
let Documentation = [CallableWhenDocs];
}
def ParamTypestate : InheritableAttr {
// This attribute does not have a C [[]] spelling because it only appertains
// to a parameter whose type is a consumable C++ class.
// FIXME: should this attribute have a CPlusPlus language option?
let Spellings = [Clang<"param_typestate", 0>];
let Subjects = SubjectList<[ParmVar]>;
let Args = [EnumArgument<"ParamState", "ConsumedState",
["unknown", "consumed", "unconsumed"],
["Unknown", "Consumed", "Unconsumed"]>];
let Documentation = [ParamTypestateDocs];
}
def ReturnTypestate : InheritableAttr {
// This attribute does not have a C [[]] spelling because it only appertains
// to a parameter or function return type that is a consumable C++ class.
// FIXME: should this attribute have a CPlusPlus language option?
let Spellings = [Clang<"return_typestate", 0>];
let Subjects = SubjectList<[Function, ParmVar]>;
let Args = [EnumArgument<"State", "ConsumedState",
["unknown", "consumed", "unconsumed"],
["Unknown", "Consumed", "Unconsumed"]>];
let Documentation = [ReturnTypestateDocs];
}
def SetTypestate : InheritableAttr {
// This attribute does not have a C [[]] spelling because it only appertains
// to C++ function (but doesn't require it to be a member function).
// FIXME: should this attribute have a CPlusPlus language option?
let Spellings = [Clang<"set_typestate", 0>];
let Subjects = SubjectList<[CXXMethod]>;
let Args = [EnumArgument<"NewState", "ConsumedState",
["unknown", "consumed", "unconsumed"],
["Unknown", "Consumed", "Unconsumed"]>];
let Documentation = [SetTypestateDocs];
}
def TestTypestate : InheritableAttr {
// This attribute does not have a C [[]] spelling because it only appertains
// to C++ function (but doesn't require it to be a member function).
// FIXME: should this attribute have a CPlusPlus language option?
let Spellings = [Clang<"test_typestate", 0>];
let Subjects = SubjectList<[CXXMethod]>;
let Args = [EnumArgument<"TestState", "ConsumedState",
["consumed", "unconsumed"],
["Consumed", "Unconsumed"]>];
let Documentation = [TestTypestateDocs];
}
// Type safety attributes for `void *' pointers and type tags.
def ArgumentWithTypeTag : InheritableAttr {
let Spellings = [Clang<"argument_with_type_tag">,
Clang<"pointer_with_type_tag">];
let Subjects = SubjectList<[HasFunctionProto], ErrorDiag>;
let Args = [IdentifierArgument<"ArgumentKind">,
ParamIdxArgument<"ArgumentIdx">,
ParamIdxArgument<"TypeTagIdx">,
BoolArgument<"IsPointer", /*opt*/0, /*fake*/1>];
let Documentation = [ArgumentWithTypeTagDocs, PointerWithTypeTagDocs];
}
def TypeTagForDatatype : InheritableAttr {
let Spellings = [Clang<"type_tag_for_datatype">];
let Args = [IdentifierArgument<"ArgumentKind">,
TypeArgument<"MatchingCType">,
BoolArgument<"LayoutCompatible">,
BoolArgument<"MustBeNull">];
// let Subjects = SubjectList<[Var], ErrorDiag>;
let HasCustomParsing = 1;
let Documentation = [TypeTagForDatatypeDocs];
}
// Microsoft-related attributes
def MSNoVTable : InheritableAttr, TargetSpecificAttr<TargetMicrosoftCXXABI> {
let Spellings = [Declspec<"novtable">];
let Subjects = SubjectList<[CXXRecord]>;
let Documentation = [MSNoVTableDocs];
}
def : IgnoredAttr {
let Spellings = [Declspec<"property">];
}
def MSAllocator : InheritableAttr {
let Spellings = [Declspec<"allocator">];
let Subjects = SubjectList<[Function]>;
let Documentation = [MSAllocatorDocs];
}
def MSStruct : InheritableAttr {
let Spellings = [GCC<"ms_struct">];
let Subjects = SubjectList<[Record]>;
let Documentation = [Undocumented];
}
def DLLExport : InheritableAttr, TargetSpecificAttr<TargetWindows> {
let Spellings = [Declspec<"dllexport">, GCC<"dllexport">];
let Subjects = SubjectList<[Function, Var, CXXRecord, ObjCInterface]>;
let Documentation = [DLLExportDocs];
}
def DLLExportStaticLocal : InheritableAttr, TargetSpecificAttr<TargetWindows> {
// This attribute is used internally only when -fno-dllexport-inlines is
// passed. This attribute is added to inline function of class having
// dllexport attribute. And if the function has static local variables, this
// attribute is used to whether the variables are exported or not. Also if
// function has local static variables, the function is dllexported too.
let Spellings = [];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def DLLImport : InheritableAttr, TargetSpecificAttr<TargetWindows> {
let Spellings = [Declspec<"dllimport">, GCC<"dllimport">];
let Subjects = SubjectList<[Function, Var, CXXRecord, ObjCInterface]>;
let Documentation = [DLLImportDocs];
let AdditionalMembers = [{
private:
bool PropagatedToBaseTemplate = false;
public:
void setPropagatedToBaseTemplate() { PropagatedToBaseTemplate = true; }
bool wasPropagatedToBaseTemplate() { return PropagatedToBaseTemplate; }
}];
}
def DLLImportStaticLocal : InheritableAttr, TargetSpecificAttr<TargetWindows> {
// This attribute is used internally only when -fno-dllexport-inlines is
// passed. This attribute is added to inline function of class having
// dllimport attribute. And if the function has static local variables, this
// attribute is used to whether the variables are imported or not.
let Spellings = [];
let Subjects = SubjectList<[Function]>;
let Documentation = [Undocumented];
}
def SelectAny : InheritableAttr {
let Spellings = [Declspec<"selectany">, GCC<"selectany">];
let Documentation = [SelectAnyDocs];
}
def Thread : Attr {
let Spellings = [Declspec<"thread">];
let LangOpts = [MicrosoftExt];
let Documentation = [ThreadDocs];
let Subjects = SubjectList<[Var]>;
}
def Win64 : IgnoredAttr {
let Spellings = [Keyword<"__w64">];
let LangOpts = [MicrosoftExt];
}
def Ptr32 : TypeAttr {
let Spellings = [Keyword<"__ptr32">];
let Documentation = [Undocumented];
}
def Ptr64 : TypeAttr {
let Spellings = [Keyword<"__ptr64">];
let Documentation = [Undocumented];
}
def SPtr : TypeAttr {
let Spellings = [Keyword<"__sptr">];
let Documentation = [Undocumented];
}
def UPtr : TypeAttr {
let Spellings = [Keyword<"__uptr">];
let Documentation = [Undocumented];
}
def MSInheritance : InheritableAttr {
let LangOpts = [MicrosoftExt];
let Args = [DefaultBoolArgument<"BestCase", /*default*/1, /*fake*/1>];
let Spellings = [Keyword<"__single_inheritance">,
Keyword<"__multiple_inheritance">,
Keyword<"__virtual_inheritance">,
Keyword<"__unspecified_inheritance">];
let AdditionalMembers = [{
static bool hasVBPtrOffsetField(Spelling Inheritance) {
return Inheritance == Keyword_unspecified_inheritance;
}
// Only member pointers to functions need a this adjustment, since it can be
// combined with the field offset for data pointers.
static bool hasNVOffsetField(bool IsMemberFunction, Spelling Inheritance) {
return IsMemberFunction && Inheritance >= Keyword_multiple_inheritance;
}
static bool hasVBTableOffsetField(Spelling Inheritance) {
return Inheritance >= Keyword_virtual_inheritance;
}
static bool hasOnlyOneField(bool IsMemberFunction,
Spelling Inheritance) {
if (IsMemberFunction)
return Inheritance <= Keyword_single_inheritance;
return Inheritance <= Keyword_multiple_inheritance;
}
}];
let Documentation = [MSInheritanceDocs];
}
def MSVtorDisp : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let Args = [UnsignedArgument<"vdm">];
let SemaHandler = 0;
let AdditionalMembers = [{
enum Mode {
Never,
ForVBaseOverride,
ForVFTable
};
Mode getVtorDispMode() const { return Mode(vdm); }
}];
let Documentation = [Undocumented];
}
def InitSeg : Attr {
let Spellings = [Pragma<"", "init_seg">];
let Args = [StringArgument<"Section">];
let SemaHandler = 0;
let Documentation = [InitSegDocs];
let AdditionalMembers = [{
void printPrettyPragma(raw_ostream &OS, const PrintingPolicy &Policy) const {
OS << " (" << getSection() << ')';
}
}];
}
def LoopHint : Attr {
/// #pragma clang loop <option> directive
/// vectorize: vectorizes loop operations if State == Enable.
/// vectorize_width: vectorize loop operations with width 'Value'.
/// interleave: interleave multiple loop iterations if State == Enable.
/// interleave_count: interleaves 'Value' loop iterations.
/// unroll: fully unroll loop if State == Enable.
/// unroll_count: unrolls loop 'Value' times.
/// unroll_and_jam: attempt to unroll and jam loop if State == Enable.
/// unroll_and_jam_count: unroll and jams loop 'Value' times.
/// distribute: attempt to distribute loop if State == Enable.
/// pipeline: disable pipelining loop if State == Disable.
/// pipeline_initiation_interval: create loop schedule with initiation interval equal to 'Value'.
/// #pragma unroll <argument> directive
/// <no arg>: fully unrolls loop.
/// boolean: fully unrolls loop if State == Enable.
/// expression: unrolls loop 'Value' times.
let Spellings = [Pragma<"clang", "loop">, Pragma<"", "unroll">,
Pragma<"", "nounroll">, Pragma<"", "unroll_and_jam">,
Pragma<"", "nounroll_and_jam">];
/// State of the loop optimization specified by the spelling.
let Args = [EnumArgument<"Option", "OptionType",
["vectorize", "vectorize_width", "interleave", "interleave_count",
"unroll", "unroll_count", "unroll_and_jam", "unroll_and_jam_count",
"pipeline", "pipeline_initiation_interval", "distribute"],
["Vectorize", "VectorizeWidth", "Interleave", "InterleaveCount",
"Unroll", "UnrollCount", "UnrollAndJam", "UnrollAndJamCount",
"PipelineDisabled", "PipelineInitiationInterval", "Distribute"]>,
EnumArgument<"State", "LoopHintState",
["enable", "disable", "numeric", "assume_safety", "full"],
["Enable", "Disable", "Numeric", "AssumeSafety", "Full"]>,
ExprArgument<"Value">];
let AdditionalMembers = [{
static const char *getOptionName(int Option) {
switch(Option) {
case Vectorize: return "vectorize";
case VectorizeWidth: return "vectorize_width";
case Interleave: return "interleave";
case InterleaveCount: return "interleave_count";
case Unroll: return "unroll";
case UnrollCount: return "unroll_count";
case UnrollAndJam: return "unroll_and_jam";
case UnrollAndJamCount: return "unroll_and_jam_count";
case PipelineDisabled: return "pipeline";
case PipelineInitiationInterval: return "pipeline_initiation_interval";
case Distribute: return "distribute";
}
llvm_unreachable("Unhandled LoopHint option.");
}
void printPrettyPragma(raw_ostream &OS, const PrintingPolicy &Policy) const {
unsigned SpellingIndex = getSpellingListIndex();
// For "#pragma unroll" and "#pragma nounroll" the string "unroll" or
// "nounroll" is already emitted as the pragma name.
if (SpellingIndex == Pragma_nounroll || SpellingIndex == Pragma_nounroll_and_jam)
return;
else if (SpellingIndex == Pragma_unroll || SpellingIndex == Pragma_unroll_and_jam) {
OS << ' ' << getValueString(Policy);
return;
}
assert(SpellingIndex == Pragma_clang_loop && "Unexpected spelling");
OS << ' ' << getOptionName(option) << getValueString(Policy);
}
// Return a string containing the loop hint argument including the
// enclosing parentheses.
std::string getValueString(const PrintingPolicy &Policy) const {
std::string ValueName;
llvm::raw_string_ostream OS(ValueName);
OS << "(";
if (state == Numeric)
value->printPretty(OS, nullptr, Policy);
else if (state == Enable)
OS << "enable";
else if (state == Full)
OS << "full";
else if (state == AssumeSafety)
OS << "assume_safety";
else
OS << "disable";
OS << ")";
return OS.str();
}
// Return a string suitable for identifying this attribute in diagnostics.
std::string getDiagnosticName(const PrintingPolicy &Policy) const {
unsigned SpellingIndex = getSpellingListIndex();
if (SpellingIndex == Pragma_nounroll)
return "#pragma nounroll";
else if (SpellingIndex == Pragma_unroll)
return "#pragma unroll" + (option == UnrollCount ? getValueString(Policy) : "");
else if (SpellingIndex == Pragma_nounroll_and_jam)
return "#pragma nounroll_and_jam";
else if (SpellingIndex == Pragma_unroll_and_jam)
return "#pragma unroll_and_jam" +
(option == UnrollAndJamCount ? getValueString(Policy) : "");
assert(SpellingIndex == Pragma_clang_loop && "Unexpected spelling");
return getOptionName(option) + getValueString(Policy);
}
}];
let Documentation = [LoopHintDocs, UnrollHintDocs];
}
def CapturedRecord : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let SemaHandler = 0;
let Documentation = [Undocumented];
}
def OMPThreadPrivateDecl : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let SemaHandler = 0;
let Documentation = [Undocumented];
}
def OMPCaptureNoInit : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let SemaHandler = 0;
let Documentation = [Undocumented];
}
def OMPCaptureKind : Attr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let SemaHandler = 0;
let Args = [UnsignedArgument<"CaptureKind">];
let Documentation = [Undocumented];
}
def OMPReferencedVar : Attr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let SemaHandler = 0;
let Args = [ExprArgument<"Ref">];
let Documentation = [Undocumented];
}
def OMPDeclareSimdDecl : Attr {
let Spellings = [Pragma<"omp", "declare simd">];
let Subjects = SubjectList<[Function]>;
let SemaHandler = 0;
let HasCustomParsing = 1;
let Documentation = [OMPDeclareSimdDocs];
let Args = [
EnumArgument<"BranchState", "BranchStateTy",
[ "", "inbranch", "notinbranch" ],
[ "BS_Undefined", "BS_Inbranch", "BS_Notinbranch" ]>,
ExprArgument<"Simdlen">, VariadicExprArgument<"Uniforms">,
VariadicExprArgument<"Aligneds">, VariadicExprArgument<"Alignments">,
VariadicExprArgument<"Linears">, VariadicUnsignedArgument<"Modifiers">,
VariadicExprArgument<"Steps">
];
let AdditionalMembers = [{
void printPrettyPragma(raw_ostream & OS, const PrintingPolicy &Policy)
const {
if (getBranchState() != BS_Undefined)
OS << ' ' << ConvertBranchStateTyToStr(getBranchState());
if (auto *E = getSimdlen()) {
OS << " simdlen(";
E->printPretty(OS, nullptr, Policy);
OS << ")";
}
if (uniforms_size() > 0) {
OS << " uniform";
StringRef Sep = "(";
for (auto *E : uniforms()) {
OS << Sep;
E->printPretty(OS, nullptr, Policy);
Sep = ", ";
}
OS << ")";
}
alignments_iterator NI = alignments_begin();
for (auto *E : aligneds()) {
OS << " aligned(";
E->printPretty(OS, nullptr, Policy);
if (*NI) {
OS << ": ";
(*NI)->printPretty(OS, nullptr, Policy);
}
OS << ")";
++NI;
}
steps_iterator I = steps_begin();
modifiers_iterator MI = modifiers_begin();
for (auto *E : linears()) {
OS << " linear(";
if (*MI != OMPC_LINEAR_unknown)
OS << getOpenMPSimpleClauseTypeName(OMPC_linear, *MI) << "(";
E->printPretty(OS, nullptr, Policy);
if (*MI != OMPC_LINEAR_unknown)
OS << ")";
if (*I) {
OS << ": ";
(*I)->printPretty(OS, nullptr, Policy);
}
OS << ")";
++I;
++MI;
}
}
}];
}
def OMPDeclareTargetDecl : InheritableAttr {
let Spellings = [Pragma<"omp", "declare target">];
let SemaHandler = 0;
let Subjects = SubjectList<[Function, SharedVar]>;
let Documentation = [OMPDeclareTargetDocs];
let Args = [
EnumArgument<"MapType", "MapTypeTy",
[ "to", "link" ],
[ "MT_To", "MT_Link" ]>
];
let AdditionalMembers = [{
void printPrettyPragma(raw_ostream &OS, const PrintingPolicy &Policy) const {
// Use fake syntax because it is for testing and debugging purpose only.
if (getMapType() != MT_To)
OS << ' ' << ConvertMapTypeTyToStr(getMapType());
}
static llvm::Optional<MapTypeTy>
isDeclareTargetDeclaration(const ValueDecl *VD) {
if (!VD->hasAttrs())
return llvm::None;
if (const auto *Attr = VD->getAttr<OMPDeclareTargetDeclAttr>())
return Attr->getMapType();
return llvm::None;
}
}];
}
def OMPAllocateDecl : InheritableAttr {
// This attribute has no spellings as it is only ever created implicitly.
let Spellings = [];
let SemaHandler = 0;
let Args = [
EnumArgument<"AllocatorType", "AllocatorTypeTy",
[
"omp_default_mem_alloc", "omp_large_cap_mem_alloc",
"omp_const_mem_alloc", "omp_high_bw_mem_alloc",
"omp_low_lat_mem_alloc", "omp_cgroup_mem_alloc",
"omp_pteam_mem_alloc", "omp_thread_mem_alloc", ""
],
[
"OMPDefaultMemAlloc", "OMPLargeCapMemAlloc",
"OMPConstMemAlloc", "OMPHighBWMemAlloc", "OMPLowLatMemAlloc",
"OMPCGroupMemAlloc", "OMPPTeamMemAlloc", "OMPThreadMemAlloc",
"OMPUserDefinedMemAlloc"
]>,
ExprArgument<"Allocator">
];
let Documentation = [Undocumented];
}
def InternalLinkage : InheritableAttr {
let Spellings = [Clang<"internal_linkage">];
let Subjects = SubjectList<[Var, Function, CXXRecord]>;
let Documentation = [InternalLinkageDocs];
}
def ExcludeFromExplicitInstantiation : InheritableAttr {
let Spellings = [Clang<"exclude_from_explicit_instantiation">];
let Subjects = SubjectList<[Var, Function, CXXRecord]>;
let Documentation = [ExcludeFromExplicitInstantiationDocs];
let MeaningfulToClassTemplateDefinition = 1;
}
def Reinitializes : InheritableAttr {
let Spellings = [Clang<"reinitializes", 0>];
let Subjects = SubjectList<[NonStaticNonConstCXXMethod], ErrorDiag>;
let Documentation = [ReinitializesDocs];
}
def NoDestroy : InheritableAttr {
let Spellings = [Clang<"no_destroy", 0>];
let Subjects = SubjectList<[Var]>;
let Documentation = [NoDestroyDocs];
}
def AlwaysDestroy : InheritableAttr {
let Spellings = [Clang<"always_destroy", 0>];
let Subjects = SubjectList<[Var]>;
let Documentation = [AlwaysDestroyDocs];
}
def SpeculativeLoadHardening : InheritableAttr {
let Spellings = [Clang<"speculative_load_hardening">];
let Subjects = SubjectList<[Function, ObjCMethod], ErrorDiag>;
let Documentation = [SpeculativeLoadHardeningDocs];
}
def NoSpeculativeLoadHardening : InheritableAttr {
let Spellings = [Clang<"no_speculative_load_hardening">];
let Subjects = SubjectList<[Function, ObjCMethod], ErrorDiag>;
let Documentation = [NoSpeculativeLoadHardeningDocs];
}
def Uninitialized : InheritableAttr {
let Spellings = [Clang<"uninitialized", 0>];
let Subjects = SubjectList<[LocalVar]>;
let Documentation = [UninitializedDocs];
}
def ObjCExternallyRetained : InheritableAttr {
let LangOpts = [ObjCAutoRefCount];
let Spellings = [Clang<"objc_externally_retained">];
let Subjects = SubjectList<[NonParmVar, Function, Block, ObjCMethod]>;
let Documentation = [ObjCExternallyRetainedDocs];
}
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