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IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE .\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL .\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS .\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) .\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT .\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY .\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF .\" SUCH DAMAGE. .\" .\" from: @(#)exp.3 6.12 (Berkeley) 7/31/91 .\" .Dd $Mdocdate: March 12 2016 $ .Dt EXP 3 .Os .Sh NAME .Nm exp , .Nm expf , .Nm expl , .Nm exp2 , .Nm exp2f , .Nm exp2l , .Nm expm1 , .Nm expm1f , .Nm expm1l , .Nm log , .Nm logf , .Nm logl , .Nm log2 , .Nm log2f , .Nm log2l , .Nm log10 , .Nm log10f , .Nm log10l , .Nm log1p , .Nm log1pf , .Nm log1pl , .Nm pow , .Nm powf , .Nm powl .Nd exponential, logarithm, power functions .Sh SYNOPSIS .In math.h .Ft double .Fn exp "double x" .Ft float .Fn expf "float x" .Ft long double .Fn expl "long double x" .Ft double .Fn exp2 "double x" .Ft float .Fn exp2f "float x" .Ft long double .Fn exp2l "long double x" .Ft double .Fn expm1 "double x" .Ft float .Fn expm1f "float x" .Ft long double .Fn expm1l "long double x" .Ft double .Fn log "double x" .Ft float .Fn logf "float x" .Ft long double .Fn logl "long double x" .Ft double .Fn log2 "double x" .Ft float .Fn log2f "float x" .Ft long double .Fn log2l "long double x" .Ft double .Fn log10 "double x" .Ft float .Fn log10f "float x" .Ft long double .Fn log10l "long double x" .Ft double .Fn log1p "double x" .Ft float .Fn log1pf "float x" .Ft long double .Fn log1pl "long double x" .Ft double .Fn pow "double x" "double y" .Ft float .Fn powf "float x" "float y" .Ft long double .Fn powl "long double x" "long double y" .Sh DESCRIPTION The .Fn exp function computes the base .Ms e exponential value of the given argument .Fa x . The .Fn expf function is a single precision version of .Fn exp . The .Fn expl function is an extended precision version of .Fn exp . .Pp The .Fn exp2 function computes the base 2 exponential of the given argument .Fa x . The .Fn exp2f function is a single precision version of .Fn exp2 . The .Fn exp2l function is an extended precision version of .Fn exp2 . .Pp The .Fn expm1 function computes the value exp(x)\-1 accurately even for tiny argument .Fa x . The .Fn expm1f function is a single precision version of .Fn expm1 . The .Fn expm1l function is an extended precision version of .Fn expm1 . .Pp The .Fn log function computes the value of the natural logarithm of argument .Fa x . The .Fn logf function is a single precision version of .Fn log . The .Fn logl function is an extended precision version of .Fn log . .Pp The .Fn log2 function computes the value of the logarithm of argument .Fa x to base 2. The .Fn log2f function is a single precision version of .Fn log2 . The .Fn log2l function is an extended precision version of .Fn log2 . .Pp The .Fn log10 function computes the value of the logarithm of argument .Fa x to base 10. The .Fn log10f function is a single precision version of .Fn log10 . The .Fn log10l function is an extended precision version of .Fn log10 . .Pp The .Fn log1p function computes the value of log(1+x) accurately even for tiny argument .Fa x . The .Fn log1pf function is a single precision version of .Fn log1p . The .Fn log1pl function is an extended precision version of .Fn log1p . .Pp The .Fn pow function computes the value of .Ar x to the exponent .Ar y . The .Fn powf function is a single precision version of .Fn pow . The .Fn powl function is an extended precision version of .Fn pow . .Sh RETURN VALUES These functions will return the appropriate computation unless an error occurs or an argument is out of range. The functions .Fn exp , .Fn expm1 and .Fn pow detect if the computed value will overflow and set the global variable .Va errno to .Er ERANGE . The function .Fn pow x y checks to see if .Fa x < 0 and .Fa y is not an integer, in the event this is true, the global variable .Va errno is set to .Er EDOM . .Sh ERRORS (due to Roundoff etc.) exp(x), log(x), expm1(x) and log1p(x) are accurate to within an .Em ulp , and log10(x) to within about 2 .Em ulps ; an .Em ulp is one .Em Unit in the .Em Last .Em Place . The error in .Fn pow x y is below about 2 .Em ulps when its magnitude is moderate, but increases as .Fn pow x y approaches the over/underflow thresholds until almost as many bits could be lost as are occupied by the floating\-point format's exponent field; that is 11 bits for IEEE 754 Double. No such drastic loss has been exposed by testing; the worst errors observed have been below 300 .Em ulps for IEEE 754 Double. Moderate values of .Fn pow are accurate enough that .Fn pow integer integer is exact until it is bigger than 2**53 for IEEE 754. .Sh NOTES The functions exp(x)\-1 and log(1+x) are called expm1 and logp1 in BASIC on the Hewlett\-Packard HP-71B and APPLE Macintosh, EXP1 and LN1 in Pascal, exp1 and log1 in C on APPLE Macintoshes, where they have been provided to make sure financial calculations of ((1+x)**n\-1)/x, namely expm1(n\(**log1p(x))/x, will be accurate when x is tiny. They also provide accurate inverse hyperbolic functions. .Pp The function .Fn pow x 0 returns x**0 = 1 for all x including x = 0 and .if n \ \*(If. .if t \ \(if. Previous implementations of .Fn pow may have defined x**0 to be undefined in some or all of these cases. Here are reasons for returning x**0 = 1 always: .Bl -enum -width indent .It Any program that already tests whether x is zero (or infinite or \*(Na) before computing x**0 cannot care whether 0**0 = 1 or not. Any program that depends upon 0**0 to be invalid is dubious anyway since that expression's meaning and, if invalid, its consequences vary from one computer system to another. .It Some Algebra texts (e.g., Sigler's) define x**0 = 1 for all x, including x = 0. This is compatible with the convention that accepts a[0] as the value of polynomial .Bd -literal -offset indent p(x) = a[0]\(**x**0 + a[1]\(**x**1 + a[2]\(**x**2 +...+ a[n]\(**x**n .Ed .Pp at x = 0 rather than reject a[0]\(**0**0 as invalid. .It Analysts will accept 0**0 = 1 despite that x**y can approach anything or nothing as x and y approach 0 independently. The reason for setting 0**0 = 1 anyway is this: .Bd -filled -offset indent If x(z) and y(z) are .Em any functions analytic (expandable in power series) in z around z = 0, and if there x(0) = y(0) = 0, then x(z)**y(z) \(-> 1 as z \(-> 0. .Ed .It If 0**0 = 1, then .if n \ \*(If**0 = 1/0**0 = 1 too; and .if t \ \(if**0 = 1/0**0 = 1 too; and then \*(Na**0 = 1 too because x**0 = 1 for all finite and infinite x, i.e., independently of x. .El .Sh SEE ALSO .Xr ilogb 3 .Sh HISTORY The .Fn exp and .Fn log functions first appeared in .At v1 ; .Fn pow in .At v3 ; .Fn log10 in .At v7 ; .Fn log1p and .Fn expm1 in .Bx 4.3 .