cv (const and volatile) type qualifiers
Appear in any type specifier, including decl-specifier-seq of declaration grammar, to specify constness or volatility of the object being declared or of the type being named.
-
const
- defines that the type is constant. -
volatile
- defines that the type is volatile.
Explanation
For any type T
(including incomplete types), other than function type or reference type, there are three more distinct types in the C++ type system: const-qualified T
, volatile-qualified T
, and const-volatile-qualified T
. Note: array types are considered to have the same cv-qualification as their element types.
When an object is first created, the cv-qualifiers used (which could be part of decl-specifier-seq or part of a declarator in a declaration, or part of type-id in a new-expression) determine the constness or volatility of the object, as follows:
- const object - an object whose type is const-qualified, or a non-mutable subobject of a const object. Such object cannot be modified: attempt to do so directly is a compile-time error, and attempt to do so indirectly (e.g., by modifying the const object through a reference or pointer to non-const type) results in undefined behavior.
-
volatile object - an object whose type is volatile-qualified, or a subobject of a volatile object, or a mutable subobject of a const-volatile object. Every access (read or write operation, member function call, etc.) made through a glvalue expression of volatile-qualified type is treated as a visible side-effect for the purposes of optimization (that is, within a single thread of execution, volatile accesses cannot be optimized out or reordered with another visible side effect that is sequenced-before or sequenced-after the volatile access. This makes volatile objects suitable for communication with a signal handler, but not with another thread of execution, see
std::memory_order
). Any attempt to refer to a volatile object through a non-volatile glvalue (e.g. through a reference or pointer to non-volatile type) results in undefined behavior. - const volatile object - an object whose type is const-volatile-qualified, a non-mutable subobject of a const volatile object, a const subobject of a volatile object, or a non-mutable volatile subobject of a const object. Behaves as both a const object and as a volatile object.
mutable
specifier
-
mutable
- permits modification of the class member declared mutable even if the containing object is declared const.
May appear in the declaration of a non-static class members of non-reference non-const type:
class X { mutable const int* p; // OK mutable int* const q; // ill-formed };
Mutable is used to specify that the member does not affect the externally visible state of the class (as often used for mutexes, memo caches, lazy evaluation, and access instrumentation).
class ThreadsafeCounter { mutable std::mutex m; // The "M&M rule": mutable and mutex go together int data = 0; public: int get() const { std::lock_guard<std::mutex> lk(m); return data; } void inc() { std::lock_guard<std::mutex> lk(m); ++data; } };
Conversions
There is partial ordering of cv-qualifiers by the order of increasing restrictions. The type can be said more or less cv-qualified then:
- unqualified <
const
- unqualified <
volatile
- unqualified <
const volatile
-
const
<const volatile
-
volatile
<const volatile
References and pointers to cv-qualified types may be implicitly converted to references and pointers to more cv-qualified types. In particular, the following conversions are allowed:
- reference/pointer to unqualified type can be converted to reference/pointer to
const
- reference/pointer to unqualified type can be converted to reference/pointer to
volatile
- reference/pointer to unqualified type can be converted to reference/pointer to
const volatile
- reference/pointer to
const
type can be converted to reference/pointer toconst volatile
- reference/pointer to
volatile
type can be converted to reference/pointer toconst volatile
To convert a reference or a pointer to a cv-qualified type to a reference or pointer to a less cv-qualified type, const_cast must be used.
Keywords
Notes
The const
qualifier used on a declaration of a non-local non-volatile non-template (since C++14)non-inline (since C++17) variable that is not declared extern
gives it internal linkage. This is different from C where const file scope variables have external linkage.
The C++ language grammar treats mutable
as a storage-class-specifier, rather than a type qualifier, but it does not affect storage class or linkage.
Example
int main() { int n1 = 0; // non-const object const int n2 = 0; // const object int const n3 = 0; // const object (same as n2) volatile int n4 = 0; // volatile object const struct { int n1; mutable int n2; } x = {0, 0}; // const object with mutable member n1 = 1; // ok, modifiable object // n2 = 2; // error: non-modifiable object n4 = 3; // ok, treated as a side-effect // x.n1 = 4; // error: member of a const object is const x.n2 = 4; // ok, mutable member of a const object isn't const const int& r1 = n1; // reference to const bound to non-const object // r1 = 2; // error: attempt to modify through reference to const const_cast<int&>(r1) = 2; // ok, modifies non-const object n1 const int& r2 = n2; // reference to const bound to const object // r2 = 2; // error: attempt to modify through reference to const // const_cast<int&>(r2) = 2; // undefined behavior: attempt to modify const object n2 }
Output:
# typical machine code produced on an x86_64 platform # (only the code that contributes to observable side-effects is emitted) main: movl $0, -4(%rsp) # volatile int n4 = 0; movl $3, -4(%rsp) # n4 = 3; xorl %eax, %eax # return 0 (implicit) ret
See also
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