std::numeric_limits::digits10
From cppreference.com
< cpp | types | numeric limits
| static const int digits10
|
(until C++11) | |
| static constexpr int digits10
|
(since C++11) | |
The value of std::numeric_limits<T>::digits10 is the number of base-10 digits that can be represented by the type T without change, that is, any number with this many decimal digits can be converted to a value of type T and back to decimal form, without change due to rounding or overflow. For base-radix types, it is the value of digits (digits-1 for floating-point types) multiplied by log
10(radix) and rounded down.
[edit] Standard specializations
| T | value of std::numeric_limits<T>::digits10 |
| /* non-specialized */ | 0 |
| bool | 0 |
| char | std::numeric_limits<char>::digits * std::log10(2) |
| signed char | std::numeric_limits<signed char>::digits * std::log10(2) |
| unsigned char | std::numeric_limits<unsigned char>::digits * std::log10(2) |
| wchar_t | std::numeric_limits<wchar_t>::digits * std::log10(2) |
| char16_t | std::numeric_limits<char16_t>::digits * std::log10(2) |
| char32_t | std::numeric_limits<char32_t>::digits * std::log10(2) |
| short | std::numeric_limits<short>::digits * std::log10(2) |
| unsigned short | std::numeric_limits<signed short>::digits * std::log10(2) |
| int | std::numeric_limits<int>::digits * std::log10(2) |
| unsigned int | std::numeric_limits<signed int>::digits * std::log10(2) |
| long | std::numeric_limits<long>::digits * std::log10(2) |
| unsigned long | std::numeric_limits<unsigned long>::digits * std::log10(2) |
| long long | std::numeric_limits<long long>::digits * std::log10(2) |
| unsigned long long | std::numeric_limits<unsigned long long>::digits * std::log10(2) |
| float | FLT_DIG |
| double | DBL_DIG |
| long double | LDBL_DIG |
[edit] Example
An 8-bit binary type can represent any two-digit decimal number exactly, but 3-digit decimal numbers 256..999 cannot be represented. The value of digits10 for an 8-bit type is 2 (8 * std::log10(2) is 2.41)
The standard 32-bit IEEE 754 floating-point type has a 24 bit fractional part (23 bits written, one implied), which may suggest that it can represent 7 digit decimals (24 * std::log10(2) is 7.22), but relative rounding errors are non-uniform and some floating-point values with 7 decimal digits do not survive conversion to 32-bit float and back. These rounding errors cannot exceed one bit in the representation, and digits10 is calculated as (24-1)*std::log10(2), which is 6.92. Rounding down results in the value 6.| This section is incomplete Reason: example of 7-digit decimal fraction that fails the roundtrip to float |
[edit] See also
| [static]
|
the radix or integer base used by the representation of the given type (public static member constant) |
| [static]
|
number of radix digits that can be represented without change (public static member constant) |
| [static]
|
one more than the smallest negative power of the radix that is a valid normalized floating-point value (public static member constant) |
| [static]
|
one more than the largest integer power of the radix that is a valid finite floating-point value (public static member constant) |