User-defined literals (since C++11)
Allows integer, floating-point, character, and string literals to produce objects of user-defined type by defining a user-defined suffix.
Syntax
A user-defined literal is an expression of any of the following forms
decimal-literal ud-suffix | (1) | ||||||||
octal-literal ud-suffix | (2) | ||||||||
hex-literal ud-suffix | (3) | ||||||||
binary-literal ud-suffix | (4) | ||||||||
fractional-constant exponent-part(optional) ud-suffix | (5) | ||||||||
digit-sequence exponent-part ud-suffix | (6) | ||||||||
character-literal ud-suffix | (7) | ||||||||
string-literal ud-suffix | (8) | ||||||||
decimal-literal | - | same as in integer literal, a non-zero decimal digit followed by zero or more decimal digits |
octal-literal | - | same as in integer literal, a zero followed by zero or more octal digits |
hex-literal | - | same as in integer literal, 0x or 0X followed by one or more hexadecimal digits
|
binary-literal | - | same as in integer literal, 0b or 0B followed by one or more binary digits
|
digit-sequence | - | same as in floating literal, a sequence of decimal digits |
fractional-constant | - | same as in floating literal, either a digit-sequence followed by a dot (123.) or an optional digit-sequence followed by a dot and another digit-sequence (1.0 or .12) |
exponent-part | - | same as in floating literal, the letter e or the letter E followed by optional sign, followed by digit-sequence
|
character-literal | - | same as in character literal |
string-literal | - | same as in string literal, including raw string literals |
ud-suffix | - | an identifier, introduced by a literal operator or a literal operator template declaration (see below). All ud-suffixes introduced by a program must begin with the underscore character _ . The standard library ud-suffixes do not begin with underscores.
|
In the integer and floating-point digit sequences, optional separators ' are allowed between any two digits and are ignored |
(since C++14) |
If a token matches a user-defined literal syntax and a regular literal syntax, it is assumed to be a regular literal (that is, it's impossible to overload LL in 123LL)
When the compiler encounters a user-defined literal with ud-suffix X
, it performs unqualified name lookup, looking for a function with the name operator "" X
. If the lookup does not find a declaration, the program is ill-formed. Otherwise,
n
.f
is the literal without ud-suffixf
.str
be the literal without ud-suffix:
a) If the overload set includes a string literal operator template with a non-type template parameter for which str is a well-formed template argument, then the user-defined literal expression is treated as a function call operator "" X<str>(),
|
(since C++20) |
len
is the length of the string literal, excluding the terminating null characterch
is the literal without ud-suffixlong double operator "" _w(long double); std::string operator "" _w(const char16_t*, size_t); unsigned operator "" _w(const char*); int main() { 1.2_w; // calls operator "" _w(1.2L) u"one"_w; // calls operator "" _w(u"one", 3) 12_w; // calls operator "" _w("12") "two"_w; // error: no applicable literal operator }
When string literal concatenation takes place in translation phase 6, user-defined string literals are concatenated as well, and their ud-suffixes are ignored for the purpose of concatenation, except that only one suffix may appear on all concatenated literals:
int main() { L"A" "B" "C"_x; // OK: same as L"ABC"_x "P"_x "Q" "R"_y;// error: two different ud-suffixes (_x and _y) }
Literal operators
The function called by a user-defined literal is known as literal operator (or, if it's a template, literal operator template). It is declared just like any other function or function template at namespace scope (it may also be a friend function, an explicit instantiation or specialization of a function template, or introduced by a using-declaration), except for the following restrictions:
The name of this function can have one of the two forms:
operator "" identifier
|
|||||||||
operator user-defined-string-literal (since C++14)
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|||||||||
identifier | - | the identifier to use as the ud-suffix for the user-defined literals that will call this function. Must begin with the underscore _ : the suffixes that do not begin with the underscore are reserved for the literal operators provided by the standard library.
|
user-defined-string-literal | - | the character sequence "" followed, without a space, by the character sequence that becomes the ud-suffix. This special syntax makes it possible to use language keywords and reserved identifiers as ud-suffixes, and is used by the declaration of operator ""if from the header <complex>. Note that using this form does not change the rules that user-defined literal operators must begin with an underscore: declarations such as operator ""if may only appear as part of a standard library header. However, it allows the use of an underscore followed by a capital letter (which is otherwise a reserved identifier)
|
If the literal operator is a template, it must have an empty parameter list and can have only one template parameter, which must be a non-type template parameter pack with element type char (in which case it is known as a numeric literal operator template)
template <char...> double operator "" _x();
or a non-type template parameter of class type (in which case it is known as a string literal operator template) struct A { A(const char *); auto operator<=>(const A&) const = default; }; template<A a> A operator ""_a(); |
(since C++20) |
Only the following parameter lists are allowed on literal operators:
( const char * )
|
(1) | ||||||||
( unsigned long long int )
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(2) | ||||||||
( long double )
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(3) | ||||||||
( char )
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(4) | ||||||||
( wchar_t )
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(5) | ||||||||
( char16_t )
|
(6) | ||||||||
( char32_t )
|
(7) | ||||||||
( const char * , std::size_t )
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(8) | ||||||||
( const wchar_t * , std::size_t )
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(9) | ||||||||
( const char16_t * , std::size_t )
|
(10) | ||||||||
( const char32_t * , std::size_t )
|
(11) | ||||||||
Default arguments are not allowed.
C language linkage is not allowed.
Other than the restrictions above, literal operators and literal operator templates are normal functions (and function templates), they can be declared inline or constexpr, they may have internal or external linkage, they can be called explicitly, their addresses can be taken, etc.
void operator "" _km(long double); // OK, will be called for 1.0_km std::string operator "" _i18n(const char*, std::size_t); // OK template <char...> double operator "" _(); // OK float operator ""_e(const char*); // OK float operator ""Z(const char*); // error: suffix must begin with underscore double operator"" _Z(long double); // error: all names that begin with underscore // followed by uppercase letter are reserved double operator""_Z(long double); // OK: even though _Z is reserved ""_Z is allowed
Notes
Since the introduction of user-defined literals, the code that uses format macro constants for fixed-width integer types with no space after the preceding string literal became invalid: std::printf("%"PRId64"\n",INT64_MIN); has to be replaced by std::printf("%" PRId64"\n",INT64_MIN);
Due to maximal munch, user-defined integer and floating point literals ending in p
, P
, (since C++17) e
and E
, when followed by the operators +
or -
, must be separated from the operator with whitespace or parentheses in the source:
long double operator""_E(long double); long double operator""_a(long double); int operator""_p(unsigned long long); auto x = 1.0_E+2.0; // error auto y = 1.0_a+2.0; // OK auto z = 1.0_E +2.0; // OK auto q = (1.0_E)+2.0; // OK auto w = 1_p+2; // error auto u = 1_p +2; // OK
Same applies to dot operator following an integer or floating-point user-defined literal:
#include <chrono> using namespace std::literals; auto a = 4s.count(); // Error auto b = 4s .count(); // OK auto c = (4s).count(); // OK
Otherwise, a single invalid preprocessing number token (e.g., 1.0_E+2.0 or 4s.count) is formed, which causes compilation to fail.
Examples
#include <iostream> // used as conversion constexpr long double operator"" _deg ( long double deg ) { return deg*3.141592/180; } // used with custom type struct mytype { mytype ( unsigned long long m):m(m){} unsigned long long m; }; mytype operator"" _mytype ( unsigned long long n ) { return mytype(n); } // used for side-effects void operator"" _print ( const char* str ) { std::cout << str; } int main(){ double x = 90.0_deg; std::cout << std::fixed << x << '\n'; mytype y = 123_mytype; std::cout << y.m << '\n'; 0x123ABC_print; }
Output:
1.570796 123 0x123ABC
Standard library
The following literal operators are defined in the standard library
Defined in inline namespace
std::literals::complex_literals | |
A std::complex literal representing pure imaginary number (function) | |
Defined in inline namespace
std::literals::chrono_literals | |
(C++14) |
A std::chrono::duration literal representing hours (function) |
(C++14) |
A std::chrono::duration literal representing minutes (function) |
(C++14) |
A std::chrono::duration literal representing seconds (function) |
(C++14) |
A std::chrono::duration literal representing milliseconds (function) |
(C++14) |
A std::chrono::duration literal representing microseconds (function) |
(C++14) |
A std::chrono::duration literal representing nanoseconds (function) |
(C++20) |
A std::chrono::year literal representing a particular year (function) |
(C++20) |
A std::chrono::day literal representing a day of a month (function) |
Defined in inline namespace
std::literals::string_literals | |
(C++14) |
Converts a character array literal to basic_string (function) |
Defined in inline namespace
std::literals::string_view_literals | |
(C++17) |
Creates a string view of a character array literal (function) |