log1p, log1pf, log1pl

From cppreference.com

Types

div_t ldiv_t lldiv_t imaxdiv_t (C99) (C99)

float_t double_t (C99) (C99)
_Decimal32_t _Decimal64_t (C23) (C23)

Functions

Basic operations

abs labs llabs imaxabs (C99) (C99)
fabs
div ldiv lldiv imaxdiv (C99) (C99)

fmod
remainder (C99)
remquo (C99)
fma (C99)
fdim (C99)
nan nanf nanl nand N (C99) (C99) (C99) (C23)

Maximum/minimum operations

fmax (C99)
fmaximum (C23)
fmaximum_mag (C23)
fmaximum_num (C23)
fmaximum_mag_num (C23)

fmin (C99)
fminimum (C23)
fminimum_mag (C23)
fminimum_num (C23)
fminimum_mag_num (C23)

Exponential functions

exp
exp10 (C23)
exp2 (C99)
expm1 (C99)
exp10m1 (C23)
exp2m1 (C23)

log
log10
log2 (C99)
log1p logp1 (C99) (C23)
log10p1 (C23)
log2p1 (C23)

Power functions

sqrt
cbrt (C99)
rootn (C23)
rsqrt (C23)

hypot (C99)
compound (C23)
pow
pown (C23)
powr (C23)

Trigonometric and hyperbolic functions

sin
cos
tan
asin
acos
atan
atan2
sinpi (C23)
cospi (C23)
tanpi (C23)

asinpi (C23)
acospi (C23)
atanpi (C23)
atan2pi (C23)
sinh
cosh
tanh
asinh (C99)
acosh (C99)
atanh (C99)

Error and gamma functions

erf (C99)
erfc (C99)

lgamma (C99)
tgamma (C99)

Nearest integer floating-point operations

ceil
floor
round lround llround (C99) (C99) (C99)
roundeven (C23)
trunc (C99)

nearbyint (C99)
rint lrint llrint (C99) (C99) (C99)
fromfp fromfpx ufromfp ufromfpx (C23) (C23) (C23) (C23)

Floating-point manipulation functions

ldexp
frexp
scalbn scalbln (C99) (C99)
ilogb llogb (C99) (C23)
logb (C99)

modf
nextafter nexttoward (C99) (C99)
nextup nextdown (C23) (C23)
copysign (C99)
canonicalize (C23)

Narrowing operations

fadd (C23)
fsub (C23)
fmul (C23)

fdiv (C23)
ffma (C23)
fsqrt (C23)

Quantum and quantum exponent functions

quantized N (C23)
samequantumd N (C23)

quantumd N (C23)
llquantexpd N (C23)

Decimal re-encoding functions

encodedecd N (C23)
decodedecd N (C23)

encodebind N (C23)
decodebind N (C23)

Total order and payload functions

totalorder (C23)
getpayload (C23)

setpayload (C23)
setpayloadsig (C23)

Classification

fpclassify (C99)
iscanonical (C23)
isfinite (C99)
isinf (C99)
isnan (C99)
isnormal (C99)
signbit (C99)
issubnormal (C23)
iszero (C23)

isgreater (C99)
isgreaterequal (C99)
isless (C99)
islessequal (C99)
islessgreater (C99)
isunordered (C99)
issignaling (C23)
iseqsig (C23)

Macro constants

Special floating-point values

HUGE_VALF HUGE_VAL HUGE_VALL HUGE_VALD N

(C99) (C99) (C23)

INFINITY DEC_INFINITY (C99) (C23)
NAN DEC_NAN (C99) (C23)

Arguments and return values

FP_ILOGB0 FP_ILOGBNAN (C99) (C99)
FP_INT_UPWARD FP_INT_DOWNWARD FP_INT_TOWARDZERO FP_INT_TONEARESTFROMZERO FP_INT_TONEAREST (C23) (C23) (C23) (C23) (C23)

FP_LLOGB0 FP_LLOGBNAN (C23) (C23)
FP_NORMAL FP_SUBNORMAL FP_ZERO FP_INFINITE FP_NAN (C99) (C99) (C99) (C99) (C99)

Error handling

MATH_ERRNO MATH_ERRNOEXCEPT

(C99) (C99)

math_errhandling (C99)

Fast operation indicators

FP_FAST_FMAF FP_FAST_FMA (C99) (C99)
FP_FAST_FADD FP_FAST_FADDL FP_FAST_DADDL FP_FAST_D M ADDD N (C23) (C23) (C23) (C23)
FP_FAST_FMUL FP_FAST_FMULL FP_FAST_DMULL FP_FAST_D M MULD N (C23) (C23) (C23) (C23)
FP_FAST_FFMA FP_FAST_FFMAL FP_FAST_DFMAL FP_FAST_D M FMAD N (C23) (C23) (C23) (C23)

FP_FAST_FMAL FP_FAST_FMAD N (C99) (C23)
FP_FAST_FSUB FP_FAST_FSUBL FP_FAST_DSUBL FP_FAST_D M SUBD N (C23) (C23) (C23) (C23)
FP_FAST_FDIV FP_FAST_FDIVL FP_FAST_DDIVL FP_FAST_D M DIVD N (C23) (C23) (C23) (C23)
FP_FAST_FSQRT FP_FAST_FSQRTL FP_FAST_DSQRTL FP_FAST_D M SQRTD N (C23) (C23) (C23) (C23)

Defined in header `<math.h>`
float log1pf ( float arg ) ;	(1)	(since C99)
double log1p ( double arg ) ;	(2)	(since C99)
long double log1pl ( long double arg ) ;	(3)	(since C99)
Defined in header `<tgmath.h>`
#define log1p( arg )	(4)	(since C99)

1-3) Computes the natural (base e ) logarithm of 1 + arg . This function is more precise than the expression log ( 1 + arg ) if arg is close to zero.

4) Type-generic macro: If arg has type long double ,


        log1pl

is called. Otherwise, if arg has integer type or the type double ,


        log1p

is called. Otherwise,


        log1pf

is called.

Parameters

arg

floating-point value

Return value

If no errors occur $ln(1 + arg)$ is returned.

If a domain error occurs, an implementation-defined value is returned (NaN where supported).

If a pole error occurs, - HUGE_VAL , -HUGE_VALF , or -HUGE_VALL is returned.

If a range error occurs due to underflow, the correct result (after rounding) is returned.

Error handling

Errors are reported as specified in math_errhandling .

Domain error occurs if arg is less than $-1$ .

Pole error may occur if arg is $-1$ .

If the implementation supports IEEE floating-point arithmetic (IEC 60559),

If the argument is ±0, it is returned unmodified.
If the argument is -1, -∞ is returned and FE_DIVBYZERO is raised.
If the argument is less than -1, NaN is returned and FE_INVALID is raised.
If the argument is +∞, +∞ is returned.
If the argument is NaN, NaN is returned.

Notes

The functions expm1 and log1p are useful for financial calculations, for example, when calculating small daily interest rates: $(1+x) n -1$ can be expressed as expm1 ( n * log1p ( x ) ) . These functions also simplify writing accurate inverse hyperbolic functions.

Example

Run this code

#include <errno.h>
#include <fenv.h>
#include <float.h>
#include <math.h>
#include <stdio.h>
// #pragma STDC FENV_ACCESS ON
 
int main(void)
{
    printf("log1p(0) = %f\n", log1p(0));
    printf("Interest earned in 2 days on $100, compounded daily at 1%%\n"
           " on a 30/360 calendar = %f\n",
           100*expm1(2*log1p(0.01/360)));
    printf("log(1+1e-16) = %g, but log1p(1e-16) = %g\n",
           log(1+1e-16), log1p(1e-16));
 
    // special values
    printf("log1p(-0) = %f\n", log1p(-0.0));
    printf("log1p(+Inf) = %f\n", log1p(INFINITY));
 
    // error handling
    errno = 0; feclearexcept(FE_ALL_EXCEPT);
    printf("log1p(-1) = %f\n", log1p(-1));
    if (errno == ERANGE)
        perror("    errno == ERANGE");
    if (fetestexcept(FE_DIVBYZERO))
        puts("    FE_DIVBYZERO raised");
}

Possible output:

log1p(0) = 0.000000
Interest earned in 2 days on $100, compounded daily at 1%
 on a 30/360 calendar = 0.005556
log(1+1e-16) = 0, but log1p(1e-16) = 1e-16
log1p(-0) = -0.000000
log1p(+Inf) = Inf
log1p(-1) = -Inf
    errno == ERANGE: Result too large
    FE_DIVBYZERO raised

References

C23 standard (ISO/IEC 9899:2024):

7.12.6.9 The log1p functions (p: TBD)

7.25 Type-generic math <tgmath.h> (p: TBD)

F.10.3.9 The log1p functions (p: TBD)

C17 standard (ISO/IEC 9899:2018):

7.12.6.9 The log1p functions (p: TBD)

7.25 Type-generic math <tgmath.h> (p: TBD)

F.10.3.9 The log1p functions (p: TBD)

C11 standard (ISO/IEC 9899:2011):

7.12.6.9 The log1p functions (p: 245)

7.25 Type-generic math <tgmath.h> (p: 373-375)

F.10.3.9 The log1p functions (p: 522)

C99 standard (ISO/IEC 9899:1999):

7.12.6.9 The log1p functions (p: 226)

7.22 Type-generic math <tgmath.h> (p: 335-337)

F.9.3.9 The log1p functions (p: 459)

Compiler support
Language
Headers
Type support
Program utilities
Variadic function support
Error handling
Dynamic memory management
Strings library
Algorithms
Numerics
Date and time utilities
Input/output support
Localization support
Concurrency support (C11)
Technical Specifications
Symbol index

Common mathematical functions
Floating-point environment (C99)
Pseudo-random number generation
Complex number arithmetic (C99)
Type-generic math (C99)

log logf logl (C99) (C99)	computes natural (base- e ) logarithm ( $ln(x)$ ) (function)
log10 log10f log10l (C99) (C99)	computes common (base- 10 ) logarithm ( $log 10 (x)$ ) (function)
log2 log2f log2l (C99) (C99) (C99)	computes base-2 logarithm ( $log 2 (x)$ ) (function)
expm1 expm1f expm1l (C99) (C99) (C99)	computes e raised to the given power, minus one ( \({\small e^x-1}\) $e x -1$ ) (function)
C++ documentation for log1p

log1p, log1pf, log1pl

Parameters

Return value

Error handling

Notes

Example

References

See also

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