Intel® Integrated Performance Primitives Developer Guide and Reference

ID 790148
Date 11/07/2023
Public

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Document Table of Contents

Pow

Raises each element of the first vector to the power of corresponding element of the second vector.

Syntax

IppStatus ippsPow_32f_A11 (const Ipp32f* pSrc1, const Ipp32f* pSrc2, Ipp32f* pDst, Ipp32s len);

IppStatus ippsPow_32f_A21 (const Ipp32f* pSrc1, const Ipp32f* pSrc2, Ipp32f* pDst, Ipp32s len);

IppStatus ippsPow_32f_A24 (const Ipp32f* pSrc1, const Ipp32f* pSrc2, Ipp32f* pDst, Ipp32s len);

IppStatus ippsPow_64f_A26 (const Ipp64f* pSrc1, const Ipp64f* pSrc2, Ipp64f* pDst, Ipp32s len);

IppStatus ippsPow_64f_A50 (const Ipp64f* pSrc1, const Ipp64f* pSrc2, Ipp64f* pDst, Ipp32s len);

IppStatus ippsPow_64f_A53 (const Ipp64f* pSrc1, const Ipp64f* pSrc2, Ipp64f* pDst, Ipp32s len);

IppStatus ippsPow_32fc_A11 (const Ipp32fc* pSrc1, const Ipp32fc* pSrc2, Ipp32fc* pDst, Ipp32s len);

IppStatus ippsPow_32fc_A21 (const Ipp32fc* pSrc1, const Ipp32fc* pSrc2, Ipp32fc* pDst, Ipp32s len);

IppStatus ippsPow_32fc_A24 (const Ipp32fc* pSrc1, const Ipp32fc* pSrc2, Ipp32fc* pDst, Ipp32s len);

IppStatus ippsPow_64fc_A26 (const Ipp64fc* pSrc1, const Ipp64fc* pSrc2, Ipp64fc* pDst, Ipp32s len);

IppStatus ippsPow_64fc_A50 (const Ipp64fc* pSrc1, const Ipp64fc* pSrc2, Ipp64fc* pDst, Ipp32s len);

IppStatus ippsPow_64fc_A53 (const Ipp64fc* pSrc1, const Ipp64fc* pSrc2, Ipp64fc* pDst, Ipp32s len);

Include Files

ippvm.h

Domain Dependencies

Headers: ippcore.h

Libraries: ippcore.lib

Parameters

pSrc1

Pointer to the first source vector.

pSrc2

Pointer to the second source vector.

pDst

Pointer to the destination vector.

len

Number of elements in the vectors.

Description

This function raises each element of vector pSrc1 to the power of the corresponding element of the vector pSrc2 and stores the result in the corresponding element of pDst.

For single precision data:

function flavors ippsPow_32f_A11and ippsPow_32cf_A11 guarantee 11 correctly rounded bits of significand, or at least 3 exact decimal digits;

function flavors ippsPow_32f_A21 and ippsPow_32fc_A21 guarantee 21 correctly rounded bits of significand, or 4 ulps, or about 6 exact decimal digits;

function flavors ippsPow_32f_A24 and ippsPow_32fc_A24 guarantee 24 correctly rounded bits of significand, including the implied bit, with the maximum guaranteed error within 1 ulp.

For double precision data:

function flavors ippsPow_64f_A26 and ippsPow_64fc_A26 guarantee 26 correctly rounded bits of significand, or 6.7E+7 ulps, or approximately 8 exact decimal digits;

function flavors ippsPow_64f_A50 and ippsPow_64fc_A50 guarantee 50 correctly rounded bits of significand, or 4 ulps, or approximately 15 exact decimal digits;

function flavors ippsPow_64f_A53 and ippsPow_64fc_A53 guarantee 53 correctly rounded bits of significand, including the implied bit, with the maximum guaranteed error within 1 ulp.

Note that for ippsPow complex functions there may be argument ranges where the accuracy specification does not hold.

The computation is performed as follows:

pDst[n] = (pSrc1[n])pSrc2[n] , 0 ≤ n < len.

Return Values

ippStsNoErr

Indicates no error.

ippStsNullPtrErr

Indicates an error when pSrc1 or pSrc2 or pDst pointer is NULL.

ippStsSizeErr

Indicates an error when len is less than or equal to 0.

IppStsDomain

In real functions, indicates a warning that the argument is out of the function domain, that is, at least one pair of the source elements meets the following condition: element of pSrc1 is finite, less than 0, and element of pSrc2 is finite, non-integer.

IppStsSingularity

In real functions, indicates a warning that the argument is the singularity point, that is, at least one pair of the elements is as follows: element of pSrc1 is equal to 0, and element of pSrc2 is integer and less than 0.

Example

The example below shows how to use the function ippsPow.

IppStatus ippsPow_32f_A21_sample(void) {
	const Ipp32f x1[4] = {0.483, 0.565, 0.776, 0.252};
	const Ipp32f x2[4] = {0.823, 0.991, 0.411, 0.692};
	Ipp32f y[4];
	IppStatus st = ippsPow_32f_A21( x1, x2, y, 4 );
	
	printf(" ippsPow_32f_A21:\n");
	printf(" x1 = %.3f %.3f %.3f %.3f \n", x1[0], x1[1], x1[2], x1[3]);
	printf(" x2 = %.3f %.3f %.3f %.3f \n", x2[0], x2[1], x2[2], x2[3]);
	printf(" y  = %.3f %.3f %.3f %.3f \n", y[0],  y[1],  y[2],  y[3]);
	return st;
}

Output:

 
ippsPow_32f_A21:
x1 = 0.483 0.565 0.776 0.252
x2 = 0.823 0.991 0.411 0.692
y  = 0.549 0.568 0.901 0.386