man pages section 3: Multimedia Library Functions

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Updated: July 2014
 
 

mlib_VectorScale_S8_S8_Sat (3MLIB)

Name

mlib_VectorScale_U8_U8_Mod, mlib_VectorScale_U8_U8_Sat, mlib_VectorScale_U8C_U8C_Mod, mlib_VectorScale_U8C_U8C_Sat, mlib_VectorScale_S8_S8_Mod, mlib_VectorScale_S8_S8_Sat, mlib_VectorScale_S8C_S8C_Mod, mlib_VectorScale_S8C_S8C_Sat, mlib_VectorScale_S16_U8_Mod, mlib_VectorScale_S16_U8_Sat, mlib_VectorScale_S16_S8_Mod, mlib_VectorScale_S16_S8_Sat, mlib_VectorScale_S16_S16_Mod, mlib_VectorScale_S16_S16_Sat, mlib_VectorScale_S16C_U8C_Mod, mlib_VectorScale_S16C_U8C_Sat, mlib_VectorScale_S16C_S8C_Mod, mlib_VectorScale_S16C_S8C_Sat, mlib_VectorScale_S16C_S16C_Mod, mlib_VectorScale_S16C_S16C_Sat, mlib_VectorScale_S32_S16_Mod, mlib_VectorScale_S32_S16_Sat, mlib_VectorScale_S32_S32_Mod, mlib_VectorScale_S32_S32_Sat, mlib_VectorScale_S32C_S16C_Mod, mlib_VectorScale_S32C_S16C_Sat, mlib_VectorScale_S32C_S32C_Mod, mlib_VectorScale_S32C_S32C_Sat - vector linear scaling

Synopsis

cc [ flag... ] file... –lmlib [ library... ]
#include <mlib.h>

mlib_status mlib_VectorScale_U8_U8_Mod(mlib_u8 *z, const mlib_u8 *x,
     const mlib_u8 *a, const mlib_u8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_U8_U8_Sat(mlib_u8 *z, const mlib_u8 *x,
     const mlib_u8 *a, const mlib_u8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_U8C_U8C_Mod(mlib_u8 *z, const mlib_u8 *x,
     const mlib_u8 *a, const mlib_u8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_U8C_U8C_Sat(mlib_u8 *z, const mlib_u8 *x,
     const mlib_u8 *a, const mlib_u8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S8_S8_Mod(mlib_s8 *z, const mlib_s8 *x,
     const mlib_s8 *a, const mlib_s8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S8_S8_Sat(mlib_s8 *z, const mlib_s8 *x,
     const mlib_s8 *a, const mlib_s8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S8C_S8C_Mod(mlib_s8 *z, const mlib_s8 *x,
     const mlib_s8 *a, const mlib_s8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S8C_S8C_Sat(mlib_s8 *z, const mlib_s8 *x,
     const mlib_s8 *a, const mlib_s8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16_U8_Mod(mlib_s16 *z, const mlib_u8 *x,
     const mlib_u8 *a, const mlib_u8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16_U8_Sat(mlib_s16 *z, const mlib_u8 *x,
     const mlib_u8 *a, const mlib_u8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16_S8_Mod(mlib_s16 *z, const mlib_s8 *x,
     const mlib_s8 *a, const mlib_s8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16_S8_Sat(mlib_s16 *z, const mlib_s8 *x,
     const mlib_s8 *a, const mlib_s8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16_S16_Mod(mlib_s16 *z, const mlib_s16 *x,
     const mlib_s16 *a, const mlib_s16 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16_S16_Sat(mlib_s16 *z, const mlib_s16 *x,
     const mlib_s16 *a, const mlib_s16 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16C_U8C_Mod(mlib_s16 *z, const mlib_u8 *x,
     const mlib_u8 *a, const mlib_u8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16C_U8C_Sat(mlib_s16 *z, const mlib_u8 *x,
     const mlib_u8 *a, const mlib_u8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16C_S8C_Mod(mlib_s16 *z, const mlib_s8 *x,
     const mlib_s8 *a, const mlib_s8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16C_S8C_Sat(mlib_s16 *z, const mlib_s8 *x,
     const mlib_s8 *a, const mlib_s8 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16C_S16C_Mod(mlib_s16 *z, const mlib_s16 *x,
     const mlib_s16 *a, const mlib_s16 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S16C_S16C_Sat(mlib_s16 *z, const mlib_s16 *x,
     const mlib_s16 *a, const mlib_s16 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S32_S16_Mod(mlib_s32 *z, const mlib_s16 *x,
     const mlib_s16 *a, const mlib_s16 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S32_S16_Sat(mlib_s32 *z, const mlib_s16 *x,
     const mlib_s16 *a, const mlib_s16 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S32_S32_Mod(mlib_s32 *z, const mlib_s32 *x,
     const mlib_s32 *a, const mlib_s32 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S32_S32_Sat(mlib_s32 *z, const mlib_s32 *x,
     const mlib_s32 *a, const mlib_s32 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S32C_S16C_Mod(mlib_s32 *z, const mlib_s16 *x,
     const mlib_s16 *a, const mlib_s16 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S32C_S16C_Sat(mlib_s32 *z, const mlib_s16 *x,
     const mlib_s16 *a, const mlib_s16 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S32C_S32C_Mod(mlib_s32 *z, const mlib_s32 *x,
     const mlib_s32 *a, const mlib_s32 *b, mlib_s32 n);
mlib_status mlib_VectorScale_S32C_S32C_Sat(mlib_s32 *z, const mlib_s32 *x,
     const mlib_s32 *a, const mlib_s32 *b, mlib_s32 n);

Description

Each of these functions scales a vector by multiplying by a scalar and adding an offset.

For real data, the following equation is used:

z[i] = a[0]*x[i] + b[0]

where i = 0, 1, ..., (n - 1).

For complex data, the following equation is used:

z[2*i]     = a[0]*x[2*i] - a[1]*x[2*i + 1] + b[0]
z[2*i + 1] = a[1]*x[2*i] + a[0]*x[2*i + 1] + b[1]

where i = 0, 1, ..., (n - 1).

Parameters

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 source vector.

a

Pointer to the source scaling factor. When the function is used with complex data types, a[0] contains the real part of the scaling factor, and a[1] contains the imaginary part of the scaling factor.

b

Pointer to the source offset. When the function is used with complex data types, b[0] contains the real part of the offset, and b[1] contains the imaginary part of the offset.

n

Number of elements in the vectors.

Return Values

Each of the functions returns MLIB_SUCCESS if successful. Otherwise it returns MLIB_FAILURE.

Attributes

See attributes(5) for descriptions of the following attributes:

ATTRIBUTE TYPE
ATTRIBUTE VALUE
Interface Stability
Committed
MT-Level
MT-Safe

See also

mlib_VectorScale_U8_Mod(3MLIB), attributes(5)