Integer literal
Allows values of integer type to be used in expressions directly.
Contents |
[edit]Syntax
An integer literal has the form
| decimal-literalinteger-suffix (optional) | (1) | ||||||||
| octal-literalinteger-suffix (optional) | (2) | ||||||||
| hex-literalinteger-suffix (optional) | (3) | ||||||||
| binary-literalinteger-suffix (optional) | (4) | (since C++14) | |||||||
where
- decimal-literal is a non-zero decimal digit (
1,2,3,4,5,6,7,8,9), followed by zero or more decimal digits (0,1,2,3,4,5,6,7,8,9) - octal-literal is the digit zero (
0) followed by zero or more octal digits (0,1,2,3,4,5,6,7) - hex-literal is the character sequence
0xor the character sequence0Xfollowed by one or more hexadecimal digits (0,1,2,3,4,5,6,7,8,9,a,A,b,B,c,C,d,D,e,E,f,F) - binary-literal is the character sequence
0bor the character sequence0Bfollowed by one or more binary digits (0,1) - integer-suffix, if provided, may contain one or both of the following (if both are provided, they may appear in any order:
- unsigned-suffix (the character
uor the characterU) - one of
- long-suffix (the character
lor the characterL)
- long-suffix (the character
- unsigned-suffix (the character
| (since C++11) |
| (since C++23) |
Optional single quotes (') may be inserted between the digits as a separator; they are ignored when determining the value of the literal. | (since C++14) |
An integer literal (as any literal) is a primary expression.
[edit]Explanation
The first digit of an integer literal is the most significant.
Example. The following variables are initialized to the same value:
int d =42;int o =052;int x =0x2a;int X =0X2A;int b =0b101010;// C++14
Example. The following variables are also initialized to the same value:
unsignedlonglong l1 = 18446744073709550592ull;// C++11unsignedlonglong l2 =18'446'744'073'709'550'592llu;// C++14unsignedlonglong l3 =1844'6744'0737'0955'0592uLL;// C++14unsignedlonglong l4 =184467'440737'0'95505'92LLU;// C++14
[edit]The type of the literal
The type of the integer literal is the first type in which the value can fit, from the list of types which depends on which numeric base and which integer-suffix was used:
| Suffix | Decimal bases | Binary, octal, or hexadecimal bases |
|---|---|---|
| (no suffix) |
|
|
u or U |
|
|
l or L |
|
|
both l/Land u/U |
|
|
ll or LL |
|
|
both ll/LLand u/U |
|
|
z or Z |
|
|
both z/Zand u/U |
|
|
If the value of the integer literal that does not have size-suffix(since C++23) is too big to fit in any of the types allowed by suffix/base combination and the compiler supports an extended integer type (such as __int128) which can represent the value of the literal, the literal may be given that extended integer type — otherwise the program is ill-formed.
[edit]Notes
Letters in the integer literals are case-insensitive: 0xDeAdBeEfU and 0XdeadBEEFu represent the same number (one exception is the long-long-suffix, which is either ll or LL, never lL or Ll)(since C++11).
There are no negative integer literals. Expressions such as -1 apply the unary minus operator to the value represented by the literal, which may involve implicit type conversions.
In C prior to C99 (but not in C++), unsuffixed decimal values that do not fit in longint are allowed to have the type unsignedlongint.
When used in a controlling expression of #if or #elif, all signed integer constants act as if they have type std::intmax_t and all unsigned integer constants act as if they have type std::uintmax_t. | (since C++11) |
Due to maximal munch, hexadecimal integer literals ending in e and E, when followed by the operators + or -, must be separated from the operator with whitespace or parentheses in the source:
auto x =0xE+2.0;// errorauto y =0xa+2.0;// OKauto z =0xE+2.0;// OKauto q =(0xE)+2.0;// OK
Otherwise, a single invalid preprocessing number token is formed, which causes further analysis to fail.
| Feature-test macro | Value | Std | Feature |
|---|---|---|---|
__cpp_binary_literals | 201304L | (C++14) | Binary literals |
__cpp_size_t_suffix | 202011L | (C++23) | Literal suffixes for std::size_t and its signed version |
[edit]Example
#include <cstddef>#include <iostream>#include <type_traits> int main(){std::cout<<123<<'\n'<<0123<<'\n'<<0x123<<'\n'<<0b10<<'\n'<< 12345678901234567890ull <<'\n'<< 12345678901234567890u <<'\n';// the type is unsigned long long// even without a long long suffix // std::cout << -9223372036854775808 << '\n'; // error: the value// 9223372036854775808 cannot fit in signed long long, which is the// biggest type allowed for unsuffixed decimal integer literalstd::cout<<-9223372036854775808u <<'\n';// unary minus applied to unsigned// value subtracts it from 2^64, this gives 9223372036854775808std::cout<<-9223372036854775807-1<<'\n';// correct way to calculate// the value -9223372036854775808 #if __cpp_size_t_suffix >= 202011L // C++23 static_assert(std::is_same_v<decltype(0UZ), std::size_t>); static_assert(std::is_same_v<decltype(0Z), std::make_signed_t<std::size_t>>);#endif}
Output:
123 83 291 2 12345678901234567890 12345678901234567890 9223372036854775808 -9223372036854775808
[edit]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 2698 | C++23 | an integer literal with size-suffix could have an extended integer type | ill-formed if too large |
[edit]References
- C++23 standard (ISO/IEC 14882:2024):
- 5.13.2 Integer literals [lex.icon]
- C++20 standard (ISO/IEC 14882:2020):
- 5.13.2 Integer literals [lex.icon]
- C++17 standard (ISO/IEC 14882:2017):
- 5.13.2 Integer literals [lex.icon]
- C++14 standard (ISO/IEC 14882:2014):
- 2.14.2 Integer literals [lex.icon]
- C++11 standard (ISO/IEC 14882:2011):
- 2.14.2 Integer literals [lex.icon]
- C++98 standard (ISO/IEC 14882:1998):
- 2.13.1 Integer literals [lex.icon]
[edit]See also
| user-defined literals(C++11) | literals with user-defined suffix |
C documentation for integer constant | |
