Storage class specifiers
The storage class specifiers are a part of the decl-specifier-seq of a name's declaration syntax. Together with the scope of the name, they control two independent properties of the name: its storage duration and its linkage.
|
(until C++11) |
|
(until C++17) |
static
- static or thread storage duration and internal linkage.extern
- static or thread storage duration and external linkage.
|
(since C++11) |
mutable
- does not affect storage duration or linkage. See const/volatile for the explanation.
Only one storage class specifier may appear in a declaration except that thread_local
may be combined with static
or with extern
(since C++11).
Explanation
1) The auto specifier was only allowed for objects declared at block scope or in function parameter lists. It indicated automatic storage duration, which is the default for these kinds of declarations. The meaning of this keyword was changed in C++11.
|
(until C++11) |
2) The register specifier is only allowed for objects declared at block scope and in function parameter lists. It indicates automatic storage duration, which is the default for these kinds of declarations. Additionally, the presence of this keyword may be used as a hint for the optimizer to store the value of this variable in a CPU register. This keyword was deprecated in C++11.
|
(until C++17) |
static
specifier is only allowed in the declarations of objects (except in function parameter lists), declarations of functions (except at block scope), and declarations of anonymous unions. When used in a declaration of a class member, it declares a static member. When used in a declaration of an object, it specifies static storage duration (except if accompanied by thread_local
). When used in a declaration at namespace scope, it specifies internal linkage.extern
specifier is only allowed in the declarations of variables and functions (except class members or function parameters). It specifies external linkage, and does not technically affect storage duration, but it cannot be used in a definition of an automatic storage duration object, so all extern
objects have static or thread durations. In addition, a variable declaration that uses extern
and has no initializer is not a definition.
5) The
thread_local keyword is only allowed for objects declared at namespace scope, objects declared at block scope, and static data members. It indicates that the object has thread storage duration. It can be combined with static or extern to specify internal or external linkage (except for static data members which always have external linkage), respectively, but that additional static doesn't affect the storage duration. |
(since C++11) |
Storage duration
All objects in a program have one of the following storage durations:
- automatic storage duration. The storage for the object is allocated at the beginning of the enclosing code block and deallocated at the end. All local objects have this storage duration, except those declared
static
,extern
orthread_local
.
- automatic storage duration. The storage for the object is allocated at the beginning of the enclosing code block and deallocated at the end. All local objects have this storage duration, except those declared
- static storage duration. The storage for the object is allocated when the program begins and deallocated when the program ends. Only one instance of the object exists. All objects declared at namespace scope (including global namespace) have this storage duration, plus those declared with
static
orextern
. See Non-local variables and Static local variables for details on initialization of objects with this storage duration.
- static storage duration. The storage for the object is allocated when the program begins and deallocated when the program ends. Only one instance of the object exists. All objects declared at namespace scope (including global namespace) have this storage duration, plus those declared with
|
(since C++11) |
- dynamic storage duration. The storage for the object is allocated and deallocated per request by using dynamic memory allocation functions. See new-expression for details on initialization of objects with this storage duration.
Linkage
A name that denotes object, reference, function, type, template, namespace, or value, may have linkage. If a name has linkage, it refers to the same entity as the same name introduced by a declaration in another scope. If a variable, function, or another entity with the same name is declared in several scopes, but does not have sufficient linkage, then several instances of the entity are generated.
The following linkages are recognized:
- no linkage. The name can be referred to only from the scope it is in.
- Any of the following names declared at block scope have no linkage:
- variables that aren't explicitly declared
extern
(regardless of thestatic
modifier); - local classes and their member functions;
- other names declared at block scope such as typedefs, enumerations, and enumerators.
- variables that aren't explicitly declared
- internal linkage. The name can be referred to from all scopes in the current translation unit.
- Any of the following names declared at namespace scope have internal linkage:
- variables, variable templates (since C++14), functions, or function templates declared
static
; - non-volatile non-template (since C++14)non-inline (since C++17) const-qualified variables (including constexpr) that aren't declared
extern
and aren't previously declared to have external linkage; - data members of anonymous unions.
- variables, variable templates (since C++14), functions, or function templates declared
|
(since C++11) |
- external linkage. The name can be referred to from the scopes in the other translation units. Variables and functions with external linkage also have language linkage, which makes it possible to link translation units written in different programming languages.
- Any of the following names declared at namespace scope have external linkage unless the namespace is unnamed or is contained within an unnamed namespace (since C++11):
- variables and functions not listed above (that is, functions not declared
static
, namespace-scope non-const variables not declaredstatic
, and any variables declaredextern
); - enumerations;
- names of classes, their member functions, static data members (const or not), nested classes and enumerations, and functions first introduced with friend declarations inside class bodies;
- names of all templates not listed above (that is, not function templates declared
static
).
- variables and functions not listed above (that is, functions not declared
- Any of the following names first declared at block scope have external linkage:
- names of variables declared
extern
; - names of functions.
- names of variables declared
Static local variables
Variables declared at block scope with the specifier static
have static storage duration but are initialized the first time control passes through their declaration (unless their initialization is zero- or constant-initialization, which can be performed before the block is first entered). On all further calls, the declaration is skipped.
If the initialization throws an exception, the variable is not considered to be initialized, and initialization will be attempted again the next time control passes through the declaration.
If the initialization recursively enters the block in which the variable is being initialized, the behavior is undefined.
If multiple threads attempt to initialize the same static local variable concurrently, the initialization occurs exactly once (similar behavior can be obtained for arbitrary functions with std::call_once). Note: usual implementations of this feature use variants of the double-checked locking pattern, which reduces runtime overhead for already-initialized local statics to a single non-atomic boolean comparison. |
(since C++11) |
The destructor for a block-scope static variable is called at program exit, but only if the initialization took place successfully.
Function-local static objects in all definitions of the same inline function (which may be implicitly inline) all refer to the same object defined in one translation unit.
Notes
Names at the top-level namespace scope (file scope in C) that are const
and not extern
have external linkage in C, but internal linkage in C++.
Since C++11, auto
is no longer a storage class specifier; it is used to indicate type deduction.
In C, the address of a |
(until C++17) |
In C++, unlike C, variables cannot be declared |
(since C++17) |
Names of thread_local
variables with internal or external linkage referred from different scopes may refer to the same or to different instances depending on whether the code is executing in the same or in different threads.
The extern
keyword can also be used to specify language linkage and explicit template instantiation declarations, but it's not a storage class specifier in those cases (except when a declaration is directly contained in a language linkage specification, in which case the declaration is treated as if it contains the extern
specifier).
The keyword mutable
is a storage class specifier in the C++ language grammar, although it doesn't affect storage duration or linkage.
This section is incomplete Reason: the rules about re-declaring names in the same TU |
Storage class specifiers, except for thread_local
, are not allowed on explicit specializations and explicit instantiations:
template <class T> struct S { thread_local static int tlm; }; template <> thread_local int S<float>::tlm = 0; // "static" does not appear here
Keywords
auto, register, static, extern, thread_local, mutable
Example
#include <iostream> #include <string> #include <thread> #include <mutex> thread_local unsigned int rage = 1; std::mutex cout_mutex; void increase_rage(const std::string& thread_name) { ++rage; // modifying outside a lock is okay; this is a thread-local variable std::lock_guard<std::mutex> lock(cout_mutex); std::cout << "Rage counter for " << thread_name << ": " << rage << '\n'; } int main() { std::thread a(increase_rage, "a"), b(increase_rage, "b"); { std::lock_guard<std::mutex> lock(cout_mutex); std::cout << "Rage counter for main: " << rage << '\n'; } a.join(); b.join(); }
Possible output:
Rage counter for a: 2 Rage counter for main: 1 Rage counter for b: 2
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 2387 | C++14 | unclear whether const-qualified variable template have internal linkage by default |
const qualifier does not affect the linkage of variable templates or their instances |