Declares a class data member with explicit size, in bits. Adjacent bit-field members may (or may not) be packed to share and straddle the individual bytes.
A bit-field declaration is a class data member declaration which uses the following declarator:
identifier (optional) attr (optional): size (1) identifier (optional) attr (optional) : size brace-or-equal-initializer (2) (since C++20)
The type of the bit-field is introduced by the decl-specifier-seq of the declaration syntax.
attr - (since C++11) sequence of any number of attributes identifier - the name of the bit-field that is being declared. The name is optional: unnamed bit-fields introduce the specified number of padding bits. size - an integral constant expression with a value greater or equal to zero. When greater than zero, this is the number of bits that this bit-field will occupy. The value zero is only allowed for nameless bit-fields and has special meaning. brace-or-equal-initializer - default member initializer to be used with this bit-field [edit] ExplanationThe type of a bit-field can only be integral (including bool) or (possibly cv-qualified) enumeration type, an unnamed bit-field cannot be declared with a cv-qualified type.
A bit-field cannot be a static data member.
There are no bit-field prvalues: lvalue-to-rvalue conversion always produces an object of the underlying type of the bit-field.
The number of bits in a bit-field sets the limit to the range of values it can hold:
#include <iostream>
struct S
{
// three-bit unsigned field, allowed values are 0...7
unsigned int b : 3;
};
int main()
{
S s = {6};
++s.b; // store the value 7 in the bit-field
std::cout << s.b << '\n';
++s.b; // the value 8 does not fit in this bit-field
std::cout << s.b << '\n'; // formally implementation-defined, typically 0
}
Possible output:
Multiple adjacent bit-fields are usually packed together (although this behavior is implementation-defined):
#include <bit>
#include <cstdint>
#include <iostream>
struct S
{
// will usually occupy 2 bytes:
unsigned char b1 : 3; // 1st 3 bits (in 1st byte) are b1
unsigned char : 2; // next 2 bits (in 1st byte) are blocked out as unused
unsigned char b2 : 6; // 6 bits for b2 - doesn't fit into the 1st byte => starts a 2nd
unsigned char b3 : 2; // 2 bits for b3 - next (and final) bits in the 2nd byte
};
int main()
{
std::cout << sizeof(S) << '\n'; // usually prints 2
S s;
// set distinguishable field values
s.b1 = 0b111;
s.b2 = 0b101111;
s.b3 = 0b11;
// show layout of fields in S
auto i = std::bit_cast<std::uint16_t>(s);
// usually prints 1110000011110111
// breakdown is: ââ¬âââââ¬ââââ¬âââââ¤
// b1 u a b2 b3
// where âuâ marks the unused :2 specified in the struct, and
// âaâ marks compiler-added padding to byte-align the next field.
// Byte-alignment is happening because b2's type is declared unsigned char;
// if b2 were declared uint16_t there would be no âaâ, b2 would abut âuâ.
for (auto b = i; b; b >>= 1) // print LSB-first
std::cout << (b & 1);
std::cout << '\n';
}
Possible output:
The special unnamed bit-field of size zero can be forced to break up padding. It specifies that the next bit-field begins at the beginning of its allocation unit:
#include <iostream>
struct S
{
// will usually occupy 2 bytes:
// 3 bits: value of b1
// 5 bits: unused
// 2 bits: value of b2
// 6 bits: unused
unsigned char b1 : 3;
unsigned char :0; // start a new byte
unsigned char b2 : 2;
};
int main()
{
std::cout << sizeof(S) << '\n'; // usually prints 2
// would usually print 1 if not for
// the padding break in line 11
}
Possible output:
If the specified size of the bit-field is greater than the size of its type, the value is limited by the type: a std::uint8_t b : 1000; would still hold values in the range [â0â, 255]. The extra bits are padding bits.
Because bit-fields do not necessarily begin at the beginning of a byte, address of a bit-field cannot be taken. Pointers and non-const references to bit-fields are not possible. When initializing a const reference from a bit-field, a temporary is created (its type is the type of the bit-field), copy initialized with the value of the bit-field, and the reference is bound to that temporary.
There are no default member initializers for bit-fields: int b : 1 = 0; and int b : 1 {0} are ill-formed.
(until C++20)In case of ambiguity between the size of the bit-field and the default member initializer, the longest sequence of tokens that forms a valid size is chosen:
int a;
const int b = 0;
struct S
{
// simple cases
int x1 : 8 = 42; // OK; "= 42" is brace-or-equal-initializer
int x2 : 8 {42}; // OK; "{42}" is brace-or-equal-initializer
// ambiguities
int y1 : true ? 8 : a = 42; // OK; brace-or-equal-initializer is absent
int y2 : true ? 8 : b = 42; // error: cannot assign to const int
int y3 : (true ? 8 : b) = 42; // OK; "= 42" is brace-or-equal-initializer
int z : 1 || new int{0}; // OK; brace-or-equal-initializer is absent
};(since C++20) [edit] Notes
The following properties of bit-fields are implementation-defined:
In the C programming language, the width of a bit-field cannot exceed the width of the underlying type, and whether int bit-fields that are not explicitly signed or unsigned are signed or unsigned is implementation-defined. For example, int b : 3; may have the range of values [â0â, 7] or [-4, 3] in C, but only the latter choice is allowed in C++.
The following behavior-changing defect reports were applied retroactively to previously published C++ standards.
DR Applied to Behavior as published Correct behavior CWG 324 C++98 it was unspecified whether the return valueRetroSearch is an open source project built by @garambo | Open a GitHub Issue
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