mlib_vectorave_s8c_s8c(3mlib) [sunos man page]
mlib_VectorAve_U8_U8(3MLIB) mlib_VectorAve_U8_U8(3MLIB) NAME
mlib_VectorAve_U8_U8, mlib_VectorAve_U8C_U8C, mlib_VectorAve_S8_S8, mlib_VectorAve_S8C_S8C, mlib_VectorAve_S16_U8, mlib_VectorAve_S16_S8, mlib_VectorAve_S16_S16, mlib_VectorAve_S16C_U8C, mlib_VectorAve_S16C_S8C, mlib_VectorAve_S16C_S16C, mlib_VectorAve_S32_S16, mlib_Vec- torAve_S32_S32, mlib_VectorAve_S32C_S16C, mlib_VectorAve_S32C_S32C - vector average SYNOPSIS
cc [ flag... ] file... -lmlib [ library... ] #include <mlib.h> mlib_status mlib_VectorAve_U8_U8(mlib_u8 *z, const mlib_u8 *x, const mlib_u8 *y, mlib_s32 n); mlib_status mlib_VectorAve_U8C_U8C(mlib_u8 *z, const mlib_u8 *x, const mlib_u8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S8_S8(mlib_s8 *z, const mlib_s8 *x, const mlib_s8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S8C_S8C(mlib_s8 *z, const mlib_s8 *x, const mlib_s8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16_U8(mlib_s16 *z, const mlib_u8 *x, const mlib_u8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16_S8(mlib_s16 *z, const mlib_s8 *x, const mlib_s8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16_S16(mlib_s16 *z, const mlib_s16 *x, const mlib_s16 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16C_U8C(mlib_s16 *z, const mlib_u8 *x, const mlib_u8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16C_S8C(mlib_s16 *z, const mlib_s8 *x, const mlib_s8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16C_S16C(mlib_s16 *z, const mlib_s16 *x, const mlib_s16 *y, mlib_s32 n); mlib_status mlib_VectorAve_S32_S16(mlib_s32 *z, const mlib_s16 *x, const mlib_s16 *y, mlib_s32 n); mlib_status mlib_VectorAve_S32_S32(mlib_s32 *z, const mlib_s32 *x, const mlib_s32 *y, mlib_s32 n); mlib_status mlib_VectorAve_S32C_S16C(mlib_s32 *z, const mlib_s16 *x, const mlib_s16 *y, mlib_s32 n); mlib_status mlib_VectorAve_S32C_S32C(mlib_s32 *z, const mlib_s32 *x, const mlib_s32 *y, mlib_s32 n); Each of these functions computes the average of two vectors. It uses the following equation: z[i] = (x[i] + y[i]) / 2 where i = 0, 1, ..., (n - 1) for real data; i = 0, 1, ..., (2*n - 1) for complex data. Each of the functions takes the following arguments: z Pointer to the first element of the destination vector. x Pointer to the first element of the first source vector. y Pointer to the first element of the second source vector. n Number of elements in the vectors. Each of the functions returns MLIB_SUCCESS if successful. Otherwise it returns MLIB_FAILURE. See attributes(5) for descriptions of the following attributes: +-----------------------------+-----------------------------+ | ATTRIBUTE TYPE | ATTRIBUTE VALUE | +-----------------------------+-----------------------------+ |Interface Stability |Evolving | +-----------------------------+-----------------------------+ |MT-Level |MT-Safe | +-----------------------------+-----------------------------+ mlib_VectorAve_U8(3MLIB), attributes(5) 25 Feb 2005 mlib_VectorAve_U8_U8(3MLIB)
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mlib_VectorAve_U8_U8(3MLIB) mlib_VectorAve_U8_U8(3MLIB) NAME
mlib_VectorAve_U8_U8, mlib_VectorAve_U8C_U8C, mlib_VectorAve_S8_S8, mlib_VectorAve_S8C_S8C, mlib_VectorAve_S16_U8, mlib_VectorAve_S16_S8, mlib_VectorAve_S16_S16, mlib_VectorAve_S16C_U8C, mlib_VectorAve_S16C_S8C, mlib_VectorAve_S16C_S16C, mlib_VectorAve_S32_S16, mlib_Vec- torAve_S32_S32, mlib_VectorAve_S32C_S16C, mlib_VectorAve_S32C_S32C - vector average SYNOPSIS
cc [ flag... ] file... -lmlib [ library... ] #include <mlib.h> mlib_status mlib_VectorAve_U8_U8(mlib_u8 *z, const mlib_u8 *x, const mlib_u8 *y, mlib_s32 n); mlib_status mlib_VectorAve_U8C_U8C(mlib_u8 *z, const mlib_u8 *x, const mlib_u8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S8_S8(mlib_s8 *z, const mlib_s8 *x, const mlib_s8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S8C_S8C(mlib_s8 *z, const mlib_s8 *x, const mlib_s8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16_U8(mlib_s16 *z, const mlib_u8 *x, const mlib_u8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16_S8(mlib_s16 *z, const mlib_s8 *x, const mlib_s8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16_S16(mlib_s16 *z, const mlib_s16 *x, const mlib_s16 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16C_U8C(mlib_s16 *z, const mlib_u8 *x, const mlib_u8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16C_S8C(mlib_s16 *z, const mlib_s8 *x, const mlib_s8 *y, mlib_s32 n); mlib_status mlib_VectorAve_S16C_S16C(mlib_s16 *z, const mlib_s16 *x, const mlib_s16 *y, mlib_s32 n); mlib_status mlib_VectorAve_S32_S16(mlib_s32 *z, const mlib_s16 *x, const mlib_s16 *y, mlib_s32 n); mlib_status mlib_VectorAve_S32_S32(mlib_s32 *z, const mlib_s32 *x, const mlib_s32 *y, mlib_s32 n); mlib_status mlib_VectorAve_S32C_S16C(mlib_s32 *z, const mlib_s16 *x, const mlib_s16 *y, mlib_s32 n); mlib_status mlib_VectorAve_S32C_S32C(mlib_s32 *z, const mlib_s32 *x, const mlib_s32 *y, mlib_s32 n); Each of these functions computes the average of two vectors. It uses the following equation: z[i] = (x[i] + y[i]) / 2 where i = 0, 1, ..., (n - 1) for real data; i = 0, 1, ..., (2*n - 1) for complex data. Each of the functions takes the following arguments: z Pointer to the first element of the destination vector. x Pointer to the first element of the first source vector. y Pointer to the first element of the second source vector. n Number of elements in the vectors. Each of the functions returns MLIB_SUCCESS if successful. Otherwise it returns MLIB_FAILURE. See attributes(5) for descriptions of the following attributes: +-----------------------------+-----------------------------+ | ATTRIBUTE TYPE | ATTRIBUTE VALUE | +-----------------------------+-----------------------------+ |Interface Stability |Evolving | +-----------------------------+-----------------------------+ |MT-Level |MT-Safe | +-----------------------------+-----------------------------+ mlib_VectorAve_U8(3MLIB), attributes(5) 25 Feb 2005 mlib_VectorAve_U8_U8(3MLIB)