Attribute specifier sequence(since C++11)
Introduces implementation-defined attributes for types, objects, code, etc.
Syntax
[[ attribute-list ]]
|
(since C++11) | ||||||||
[[ using attribute-namespace : attribute-list ]]
|
(since C++17) | ||||||||
where attribute-list is a comma-separated sequence of zero or more attributes (possibly ending with an ellipsis ...
indicating a pack expansion)
identifier | (1) | ||||||||
attribute-namespace :: identifier
|
(2) | ||||||||
identifier ( argument-list (optional) )
|
(3) | ||||||||
attribute-namespace :: identifier ( argument-list (optional) )
|
(4) | ||||||||
where attribute-namespace is an identifier and argument-list is a sequence of tokens where parentheses, brackets and braces are balanced (balanced-token-seq).
If [[using CC: opt(1), debug]] // same as [[CC::opt(1), CC::debug]] [[using CC: CC::opt(1)]] // error: cannot combine using and scoped attribute |
(since C++17) |
Explanation
Attributes provide the unified standard syntax for implementation-defined language extensions, such as the GNU and IBM language extensions __attribute__((...))
, Microsoft extension __declspec()
, etc.
An attribute can be used almost everywhere in the C++ program, and can be applied to almost everything: to types, to variables, to functions, to names, to code blocks, to entire translation units, although each particular attribute is only valid where it is permitted by the implementation: [[expect_true]]
could be an attribute that can only be used with an if, and not with a class declaration. [[omp::parallel()]]
could be an attribute that applies to a code block or to a for loop, but not to the type int
, etc (note these two attributes are fictional examples, see below for the standard and some non-standard attributes).
In declarations, attributes may appear both before the whole declaration and directly after the name of the entity that is declared, in which case they are combined. In most other situations, attributes apply to the directly preceding entity.
The alignas
specifier is a part of the attribute specifier sequence, although it has different syntax. It may appear where the [[...]]
attributes appear and may mix with them (provided it is used where alignas is permitted).
Two consecutive left square bracket tokens ([[
) may only appear when introducing an attribute-specifier or inside an attribute argument.
void f() { int y[3]; y[[] { return 0; }()] = 1; // error int i [[cats::meow([[]])]]; // OK }
Besides the standard attributes listed below, implementations may support arbitrary non-standard attributes with implementation-defined behavior. All attributes unknown to an implementation are ignored without causing an error. (since C++17)
An attribute without attribute-namespace and an attribute-namespace whose name is either |
(since C++20) |
Standard attributes
Only the following attributes are defined by the C++ standard.
[[noreturn]] (C++11)
|
indicates that the function does not return (attribute specifier) |
[[carries_dependency]] (C++11)
|
indicates that dependency chain in release-consume std::memory_order propagates in and out of the function (attribute specifier) |
[[deprecated]] (C++14)[[deprecated("reason")]] (C++14)
|
indicates that the use of the name or entity declared with this attribute is allowed, but discouraged for some reason (attribute specifier) |
[[fallthrough]] (C++17)
|
indicates that the fall through from the previous case label is intentional and should not be diagnosed by a compiler that warns on fall-through (attribute specifier) |
[[nodiscard]] (C++17)[[nodiscard("reason")]] (C++20)
|
encourages the compiler to issue a warning if the return value is discarded (attribute specifier) |
[[maybe_unused]] (C++17)
|
suppresses compiler warnings on unused entities, if any (attribute specifier) |
[[likely]] (C++20)[[unlikely]] (C++20)
|
indicates that the compiler should optimize for the case where a path of execution through a statement is more or less likely than any other path of execution (attribute specifier) |
[[no_unique_address]] (C++20)
|
indicates that a non-static data member need not have an address distinct from all other non-static data members of its class (attribute specifier) |
[[assume(expression)]] (C++23)
|
specifies that the expression will always evaluate to true at a given point (attribute specifier) |
[[optimize_for_synchronized]] (TM TS)
|
indicates that the function definition should be optimized for invocation from a synchronized statement (attribute specifier) |
Notes
The presence of each individual attribute on a given platform can be checked with __has_cpp_attribute
preprocessor macro.
Feature-test macro | Value | Std | Comment |
---|---|---|---|
__cpp_attributes |
200809L | (C++11) | Attributes |
__cpp_namespace_attributes |
201411L | (C++17) | Attributes for namespaces |
Example
[[gnu::always_inline]] [[gnu::hot]] [[gnu::const]] [[nodiscard]] inline int f(); // declare f with four attributes [[gnu::always_inline, gnu::const, gnu::hot, nodiscard]] int f(); // same as above, but uses a single attr specifier that contains four attributes // C++17: [[using gnu : const, always_inline, hot]] [[nodiscard]] int f[[gnu::always_inline]](); // an attribute may appear in multiple specifiers int f() { return 0; } int main() {}
Defect reports
The following behavior-changing defect reports were applied retroactively to previously published C++ standards.
DR | Applied to | Behavior as published | Correct behavior |
---|---|---|---|
CWG 2079 | C++11 | [[ could not appear inside an attribute argument
|
allowed |
P2156R1 | C++11 | every standard attribute was required to appear at most once in an attribute-list | not required |
See also
__has_cpp_attribute - checks for the presence of an attribute
|
External links
1. | Attributes in GCC. These attributes can be used as [[gnu::...]] , See SO.
|
2. | Attributes in Clang. |
3. | Attributes in MSVC. |