Numeric, boolean and pointer literals

A literal is a program element that directly represents a value. This article covers literals of type integer, floating-point, boolean and pointer. For information about string and character literals, see String and Character Literals (C++). You can also define your own literals based on any of these categories; for more information see User-Defined Literals (C++)

. You can use literals in many contexts, but most commonly to initialize named variables and to pass arguments to functions:

const int answer = 42; // integer literal
double d = sin(108.87);     //floating point literal passed to sin function
bool b = true;              // boolean literal
MyClass* mc = nullptr;      // pointer literal

Sometimes it's important to tell the compiler how to interpret a literal, or what specific type to give to it. You do this by appending prefixes or suffixes to the literal. For example, the prefix 0x tells the compiler to interpret the number that follows it as a hexadecimal value, for example 0x35. The ULL suffix tells the compiler to treat the value as an unsigned long long type, as in 5894345ULL. See the following sections for the complete list of prefixes and suffixes for each literal type.

Integer literals

Integer literals begin with a digit and have no fractional parts or exponents. You can specify integer literals in decimal, octal, or hexadecimal form. They can specify signed or unsigned types and long or short types.

When no prefix or suffix is present, the compiler will give an integral literal value type int (32 bits), if the value will fit, otherwise it will give it type long long (64 bits).

To specify a decimal integral literal, begin the specification with a nonzero digit. For example:

int i = 157;   // Decimal literal
int j = 0198;       // Not a decimal number; erroneous octal literal
int k = 0365;       // Leading zero specifies octal literal, not decimal
int m = 36'000'000  // digit separators make large values more readable
int

To specify an octal integral literal, begin the specification with 0, followed by a sequence of digits in the range 0 through 7. The digits 8 and 9 are errors in specifying an octal literal. For example:

int i = 0377;   // Octal literal
int j = 0397;        // Error: 9 is not an octal digit

To specify a hexadecimal integral literal, begin the specification with 0x or 0X (the case of the "x" does not matter), followed by a sequence of digits in the range 0 through 9 and a (or A) through f (or F). Hexadecimal digits a (or A) through f (or F) represent values in the range 10 through 15. For example:

int i = 0x3fff;   // Hexadecimal literal
int j = 0X3FFF;        // Equal to i

To specify an unsigned type, use either the u or U suffix. To specify a long type, use either the l or L suffix. To specify a 64-bit integral type, use the LL, or ll suffix. The i64 suffix is still supported but should be avoided because it is specific to Microsoft and is not portable. For example:

unsigned val_1 = 328u;             // Unsigned value
long val_2 = 0x7FFFFFL;                 // Long value specified
                                        //  as hex literal
unsigned long val_3 = 0776745ul;        // Unsigned long value
auto val_4 = 108LL;                           // signed long long
auto val_4 = 0x8000000000000000ULL << 16;     // unsigned long long

Digit separators: You can use the single-quote character (apostrophe) to separate place values in larger numbers to make them easier for humans to read. Separators have no effect on compilation.

long long i = 24'847'458'121

Floating point literals

Floating-point literals specify values that must have a fractional part. These values contain decimal points (.) and can contain exponents.

Floating-point literals have a "mantissa," which specifies the value of the number, an "exponent," which specifies the magnitude of the number, and an optional suffix that specifies the literal's type. The mantissa is specified as a sequence of digits followed by a period, followed by an optional sequence of digits representing the fractional part of the number. For example:

18.46
38.

The exponent, if present, specifies the magnitude of the number as a power of 10, as shown in the following example:

18.46e0      // 18.46
18.46e1           // 184.6

The exponent may be specified using e or E, which have the same meaning, followed by an optional sign (+ or -) and a sequence of digits. If an exponent is present, the trailing decimal point is unnecessary in whole numbers such as 18E0.

Floating-point literals default to type double. By using the suffixes f or l (or F or L — the suffix is not case sensitive), the literal can be specified as float or long double, respectively.

Although long double and double have the same representation, they are not the same type. For example, you can have overloaded functions like

void func( double );

and

void func( long double );

Boolean literals

The boolean literals are true and false.

Pointer literal (C++11)

C++ introduces the nullptr literal to specify a zero-initialized pointer. In portable code, nullptr should be used instead of integral-type zero or macros such as NULL.

Binary literals (C++14)

A binary literal can be specified by the use of the 0B or 0b prefix, followed by a sequence of 1's and 0's:

auto x = 0B001101 ; // int
auto y = 0b000001 ; // int

Avoid using literals as "magic constants"

You can use literals directly in expressions and statements although it's not always good programming practice:

if (num < 100)
    return "Success";

In the previous example, it might be better to use a named constant that conveys a clear meaning, for example "MAXIMUM_ERROR_THRESHOLD". And if the return value "Success" is seen by end users, then it might be better to use a named string constant that can be stored in a single location in a file from where it can be localized into other languages. Using named constants helps others as well as yourself to understand the intent of the code.

See also

Lexical Conventions
C++ String Literals
C++ User-Defined Literals