std::rint, std::lrint, std::llrint
Defined in header <cmath>
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float rint( float arg ); |
(1) | (since C++11) |
double rint( double arg ); |
(2) | (since C++11) |
long double rint( long double arg ); |
(3) | (since C++11) |
double rint( Integral arg ); |
(4) | (since C++11) |
long lrint( float arg ); |
(5) | (since C++11) |
long lrint( double arg ); |
(6) | (since C++11) |
long lrint( long double arg ); |
(7) | (since C++11) |
long lrint( Integral arg ); |
(8) | (since C++11) |
long long llrint( float arg ); |
(9) | (since C++11) |
long long llrint( double arg ); |
(10) | (since C++11) |
long long llrint( long double arg ); |
(11) | (since C++11) |
long long llrint( Integral arg ); |
(12) | (since C++11) |
arg
to an integer value (in floating-point format), using the current rounding mode.arg
to an integer value, using the current rounding mode. Parameters
arg | - | floating point value |
Return value
If no errors occur, the nearest integer value to arg
, according to the current rounding mode, is returned.
Error handling
Errors are reported as specified in math_errhandling
If the result of std::lrint
or std::llrint
is outside the range representable by the return type, a domain error or a range error may occur.
If the implementation supports IEEE floating-point arithmetic (IEC 60559),
- For the
std::rint
function:
- If
arg
is ±∞, it is returned, unmodified - If
arg
is ±0, it is returned, unmodified - If
arg
is NaN, NaN is returned
- For
std::lrint
andstd::llrint
functions:
- If
arg
is ±∞, FE_INVALID is raised and an implementation-defined value is returned - If the result of the rounding is outside the range of the return type, FE_INVALID is raised and an implementation-defined value is returned
- If
arg
is NaN, FE_INVALID is raised and an implementation-defined value is returned
Notes
POSIX specifies that all cases where std::lrint
or std::llrint
raise FE_INEXACT are domain errors.
As specified in math_errhandling, FE_INEXACT may be (but isn't required to be on non-IEEE floating-point platforms) raised by std::rint
when rounding a non-integer finite value.
The only difference between std::rint
and std::nearbyint is that std::nearbyint never raises FE_INEXACT.
The largest representable floating-point values are exact integers in all standard floating-point formats, so std::rint
never overflows on its own; however the result may overflow any integer type (including std::intmax_t), when stored in an integer variable.
If the current rounding mode is...
- FE_DOWNWARD, then
std::rint
is equivalent to std::floor. - FE_UPWARD, then
std::rint
is equivalent to std::ceil. - FE_TOWARDZERO, then
std::rint
is equivalent to std::trunc - FE_TONEAREST, then
std::rint
differs from std::round in that halfway cases are rounded to even rather than away from zero.
Example
#include <iostream> #include <cmath> #include <cfenv> #include <climits> int main() { #pragma STDC FENV_ACCESS ON std::fesetround(FE_TONEAREST); std::cout << "rounding to nearest (halfway cases to even):\n" << "rint(+2.3) = " << std::rint(2.3) << " rint(+2.5) = " << std::rint(2.5) << " rint(+3.5) = " << std::rint(3.5) << '\n' << "rint(-2.3) = " << std::rint(-2.3) << " rint(-2.5) = " << std::rint(-2.5) << " rint(-3.5) = " << std::rint(-3.5) << '\n'; std::fesetround(FE_DOWNWARD); std::cout << "rounding down:\n" << "rint(+2.3) = " << std::rint(2.3) << " rint(+2.5) = " << std::rint(2.5) << " rint(+3.5) = " << std::rint(3.5) << '\n' << "rint(-2.3) = " << std::rint(-2.3) << " rint(-2.5) = " << std::rint(-2.5) << " rint(-3.5) = " << std::rint(-3.5) << '\n' << "rounding down with lrint\n" << "lrint(+2.3) = " << std::lrint(2.3) << " lrint(+2.5) = " << std::lrint(2.5) << " lrint(+3.5) = " << std::lrint(3.5) << '\n' << "lrint(-2.3) = " << std::lrint(-2.3) << " lrint(-2.5) = " << std::lrint(-2.5) << " lrint(-3.5) = " << std::lrint(-3.5) << '\n'; std::cout << "lrint(-0.0) = " << std::lrint(-0.0) << '\n' << "lrint(-Inf) = " << std::lrint(-INFINITY) << '\n'; // error handling std::feclearexcept(FE_ALL_EXCEPT); std::cout << "std::rint(0.1) = " << std::rint(.1) << '\n'; if(std::fetestexcept(FE_INEXACT)) std::cout << " FE_INEXACT was raised\n"; std::feclearexcept(FE_ALL_EXCEPT); std::cout << "std::lrint(LONG_MIN-2048.0) = " << std::lrint(LONG_MIN-2048.0) << '\n'; if(std::fetestexcept(FE_INVALID)) std::cout << " FE_INVALID was raised\n"; }
Possible output:
rounding to nearest (halfway cases to even): rint(+2.3) = 2 rint(+2.5) = 2 rint(+3.5) = 4 rint(-2.3) = -2 rint(-2.5) = -2 rint(-3.5) = -4 rounding down: rint(+2.3) = 2 rint(+2.5) = 2 rint(+3.5) = 3 rint(-2.3) = -3 rint(-2.5) = -3 rint(-3.5) = -4 rounding down with lrint lrint(+2.3) = 2 lrint(+2.5) = 2 lrint(+3.5) = 3 lrint(-2.3) = -3 lrint(-2.5) = -3 lrint(-3.5) = -4 lrint(-0.0) = 0 lrint(-Inf) = -9223372036854775808 std::rint(0.1) = 0 FE_INEXACT was raised std::lrint(LONG_MIN-2048.0) = -9223372036854775808 FE_INVALID was raised
See also
(C++11) |
nearest integer not greater in magnitude than the given value (function) |
(C++11) |
nearest integer using current rounding mode (function) |
(C++11)(C++11) |
gets or sets rounding direction (function) |
C documentation for rint
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