arithm_add_scalar.cl

/*M///////////////////////////////////////////////////////////////////////////////////////
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//
//                           License Agreement
//                For Open Source Computer Vision Library
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// Copyright (C) 2010-2012, Institute Of Software Chinese Academy Of Science, all rights reserved.
// Copyright (C) 2010-2012, Advanced Micro Devices, Inc., all rights reserved.
// Third party copyrights are property of their respective owners.
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// @Authors
//    Jia Haipeng, jiahaipeng95@gmail.com
//
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// are permitted provided that the following conditions are met:
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#if defined (DOUBLE_SUPPORT)
#ifdef cl_khr_fp64
#pragma OPENCL EXTENSION cl_khr_fp64:enable
#elif defined (cl_amd_fp64)
#pragma OPENCL EXTENSION cl_amd_fp64:enable
#endif
#endif

#ifdef ARITHM_ADD
  #define ARITHM_OP(A,B) ((A)+(B))
#elif defined ARITHM_SUB
  #define ARITHM_OP(A,B) ((A)-(B))
#endif
/**************************************add with scalar without mask**************************************/
__kernel void arithm_s_add_C1_D0 (__global   uchar *src1, int src1_step, int src1_offset,
                                  __global   uchar *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{
    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        x = x << 2;
        
#ifdef dst_align
#undef dst_align
#endif
#define dst_align (dst_offset & 3)
        int src1_index = mad24(y, src1_step, x + src1_offset - dst_align);

        int dst_start  = mad24(y, dst_step, dst_offset);
        int dst_end    = mad24(y, dst_step, dst_offset + dst_step1);
        int dst_index  = mad24(y, dst_step, dst_offset + x & (int)0xfffffffc);
        int src1_index_fix = src1_index < 0 ? 0 : src1_index;
        uchar4 src1_data = vload4(0, src1 + src1_index_fix);
        int4 src2_data = (int4)(src2.x, src2.x, src2.x, src2.x);
        if(src1_index < 0)
        {
            uchar4 tmp;
            tmp.xyzw = (src1_index == -2) ? src1_data.zwxy:src1_data.yzwx;
            src1_data.xyzw = (src1_index == -1) ? src1_data.wxyz:tmp.xyzw;
        }

        uchar4 data = *((__global uchar4 *)(dst + dst_index));
        int4 tmp = ARITHM_OP(convert_int4_sat(src1_data), src2_data);
        uchar4 tmp_data = convert_uchar4_sat(tmp);

        data.x = ((dst_index + 0 >= dst_start) && (dst_index + 0 < dst_end)) ? tmp_data.x : data.x;
        data.y = ((dst_index + 1 >= dst_start) && (dst_index + 1 < dst_end)) ? tmp_data.y : data.y;
        data.z = ((dst_index + 2 >= dst_start) && (dst_index + 2 < dst_end)) ? tmp_data.z : data.z;
        data.w = ((dst_index + 3 >= dst_start) && (dst_index + 3 < dst_end)) ? tmp_data.w : data.w;

        *((__global uchar4 *)(dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C1_D2 (__global   ushort *src1, int src1_step, int src1_offset,
                                  __global   ushort *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        x = x << 1;
        
#ifdef dst_align
#undef dst_align
#endif
#define dst_align ((dst_offset >> 1) & 1)
        int src1_index = mad24(y, src1_step, (x << 1) + src1_offset - (dst_align << 1));

        int dst_start  = mad24(y, dst_step, dst_offset);
        int dst_end    = mad24(y, dst_step, dst_offset + dst_step1);
        int dst_index  = mad24(y, dst_step, dst_offset + (x << 1) & (int)0xfffffffc);

        ushort2 src1_data = vload2(0, (__global ushort *)((__global char *)src1 + src1_index));
        int2 src2_data = (int2)(src2.x, src2.x);

        ushort2 data = *((__global ushort2 *)((__global uchar *)dst + dst_index));
        int2    tmp = ARITHM_OP(convert_int2_sat(src1_data), src2_data);
        ushort2 tmp_data = convert_ushort2_sat(tmp);

        data.x = (dst_index + 0 >= dst_start) ? tmp_data.x : data.x;
        data.y = (dst_index + 2 <  dst_end  ) ? tmp_data.y : data.y;

        *((__global ushort2 *)((__global uchar *)dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C1_D3 (__global   short *src1, int src1_step, int src1_offset,
                                  __global   short *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        x = x << 1;
        
#ifdef dst_align
#undef dst_align
#endif
#define dst_align ((dst_offset >> 1) & 1)
        int src1_index = mad24(y, src1_step, (x << 1) + src1_offset - (dst_align << 1));

        int dst_start  = mad24(y, dst_step, dst_offset);
        int dst_end    = mad24(y, dst_step, dst_offset + dst_step1);
        int dst_index  = mad24(y, dst_step, dst_offset + (x << 1) & (int)0xfffffffc);

        short2 src1_data = vload2(0, (__global short *)((__global char *)src1 + src1_index));
        int2 src2_data = (int2)(src2.x, src2.x);
        short2 data = *((__global short2 *)((__global uchar *)dst + dst_index));

        int2    tmp = ARITHM_OP(convert_int2_sat(src1_data), src2_data);
        short2 tmp_data = convert_short2_sat(tmp);

        data.x = (dst_index + 0 >= dst_start) ? tmp_data.x : data.x;
        data.y = (dst_index + 2 <  dst_end  ) ? tmp_data.y : data.y;

        *((__global short2 *)((__global uchar *)dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C1_D4 (__global   int *src1, int src1_step, int src1_offset,
                                  __global   int *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 2) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 2) + dst_offset);

        int src_data1 = *((__global int *)((__global char *)src1 + src1_index));
        int src_data2 = src2.x;
        int dst_data  = *((__global int *)((__global char *)dst  + dst_index));

        int data = convert_int_sat(ARITHM_OP((long)src_data1, (long)src_data2));

        *((__global int *)((__global char *)dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C1_D5 (__global   float *src1, int src1_step, int src1_offset,
                                  __global   float *dst,  int dst_step,  int dst_offset,
                                  float4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 2) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 2) + dst_offset);

        float src_data1 = *((__global float *)((__global char *)src1 + src1_index));
        float src_data2 = src2.x;
        float dst_data  = *((__global float *)((__global char *)dst  + dst_index));

        float data = ARITHM_OP(src_data1, src_data2);

        *((__global float *)((__global char *)dst + dst_index)) = data;
    }
}

#if defined (DOUBLE_SUPPORT)
__kernel void arithm_s_add_C1_D6 (__global   double *src1, int src1_step, int src1_offset,
                                  __global   double *dst,  int dst_step,  int dst_offset,
                                  double4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 3) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 3) + dst_offset);

        double src_data1 = *((__global double *)((__global char *)src1 + src1_index));
        double src2_data = src2.x;
        double dst_data  = *((__global double *)((__global char *)dst  + dst_index));

        double data = ARITHM_OP(src_data1, src2_data);

        *((__global double *)((__global char *)dst + dst_index)) = data;
    }
}
#endif

__kernel void arithm_s_add_C2_D0 (__global   uchar *src1, int src1_step, int src1_offset,
                                  __global   uchar *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        x = x << 1;
        
#ifdef dst_align
#undef dst_align
#endif
#define dst_align ((dst_offset >> 1) & 1)
        int src1_index = mad24(y, src1_step, (x << 1) + src1_offset - (dst_align << 1));

        int dst_start  = mad24(y, dst_step, dst_offset);
        int dst_end    = mad24(y, dst_step, dst_offset + dst_step1);
        int dst_index  = mad24(y, dst_step, dst_offset + (x << 1) & (int)0xfffffffc);

        uchar4 src1_data = vload4(0, src1 + src1_index);
        int4 src2_data = (int4)(src2.x, src2.y, src2.x, src2.y);

        uchar4 data = *((__global uchar4 *)(dst + dst_index));
        int4 tmp = ARITHM_OP(convert_int4_sat(src1_data), src2_data);
        uchar4 tmp_data = convert_uchar4_sat(tmp);

        data.xy = (dst_index + 0 >= dst_start) ? tmp_data.xy : data.xy;
        data.zw = (dst_index + 2 <  dst_end  ) ? tmp_data.zw : data.zw;

        *((__global uchar4 *)(dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C2_D2 (__global   ushort *src1, int src1_step, int src1_offset,
                                  __global   ushort *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 2) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 2) + dst_offset);

        ushort2 src_data1 = *((__global ushort2 *)((__global char *)src1 + src1_index));
        int2 src_data2 = (int2)(src2.x, src2.y);
        ushort2 dst_data  = *((__global ushort2 *)((__global char *)dst  + dst_index));

        int2    tmp = ARITHM_OP(convert_int2_sat(src_data1), src_data2);
        ushort2 data = convert_ushort2_sat(tmp);

        *((__global ushort2 *)((__global char *)dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C2_D3 (__global   short *src1, int src1_step, int src1_offset,
                                  __global   short *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 2) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 2) + dst_offset);

        short2 src_data1 = *((__global short2 *)((__global char *)src1 + src1_index));
        int2 src_data2 = (int2)(src2.x, src2.y);
        short2 dst_data  = *((__global short2 *)((__global char *)dst  + dst_index));

        int2    tmp = ARITHM_OP(convert_int2_sat(src_data1), src_data2);
        short2 data = convert_short2_sat(tmp);

        *((__global short2 *)((__global char *)dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C2_D4 (__global   int *src1, int src1_step, int src1_offset,
                                  __global   int *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 3) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 3) + dst_offset);

        int2 src_data1 = *((__global int2 *)((__global char *)src1 + src1_index));
        int2 src_data2 = (int2)(src2.x, src2.y);
        int2 dst_data  = *((__global int2 *)((__global char *)dst  + dst_index));

        int2 data = convert_int2_sat(ARITHM_OP(convert_long2_sat(src_data1), convert_long2_sat(src_data2)));
        *((__global int2 *)((__global char *)dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C2_D5 (__global   float *src1, int src1_step, int src1_offset,
                                  __global   float *dst,  int dst_step,  int dst_offset,
                                  float4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 3) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 3) + dst_offset);

        float2 src_data1 = *((__global float2 *)((__global char *)src1 + src1_index));
        float2 src_data2 = (float2)(src2.x, src2.y);
        float2 dst_data  = *((__global float2 *)((__global char *)dst  + dst_index));

        float2 data = ARITHM_OP(src_data1, src_data2);
        *((__global float2 *)((__global char *)dst + dst_index)) = data;
    }
}

#if defined (DOUBLE_SUPPORT)
__kernel void arithm_s_add_C2_D6 (__global   double *src1, int src1_step, int src1_offset,
                                  __global   double *dst,  int dst_step,  int dst_offset,
                                  double4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 4) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 4) + dst_offset);

        double2 src_data1 = *((__global double2 *)((__global char *)src1 + src1_index));
        double2 src_data2 = (double2)(src2.x, src2.y);
        double2 dst_data  = *((__global double2 *)((__global char *)dst  + dst_index));

        double2 data = ARITHM_OP(src_data1, src_data2);

        *((__global double2 *)((__global char *)dst + dst_index)) = data;
    }
}
#endif

__kernel void arithm_s_add_C4_D0 (__global   uchar *src1, int src1_step, int src1_offset,
                                  __global   uchar *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 2) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 2) + dst_offset);

        uchar4 src_data1 = *((__global uchar4 *)(src1 + src1_index));

        uchar4 data = convert_uchar4_sat(ARITHM_OP(convert_int4_sat(src_data1), src2));

        *((__global uchar4 *)(dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C4_D2 (__global   ushort *src1, int src1_step, int src1_offset,
                                  __global   ushort *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 3) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 3) + dst_offset);

        ushort4 src_data1 = *((__global ushort4 *)((__global char *)src1 + src1_index));

        ushort4 data = convert_ushort4_sat(ARITHM_OP(convert_int4_sat(src_data1), src2));

        *((__global ushort4 *)((__global char *)dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C4_D3 (__global   short *src1, int src1_step, int src1_offset,
                                  __global   short *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 3) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 3) + dst_offset);

        short4 src_data1 = *((__global short4 *)((__global char *)src1 + src1_index));

        short4 data = convert_short4_sat(ARITHM_OP(convert_int4_sat(src_data1), src2));

        *((__global short4 *)((__global char *)dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C4_D4 (__global   int *src1, int src1_step, int src1_offset,
                                  __global   int *dst,  int dst_step,  int dst_offset,
                                  int4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 4) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 4) + dst_offset);

        int4 src_data1 = *((__global int4 *)((__global char *)src1 + src1_index));

        int4 data = convert_int4_sat(ARITHM_OP(convert_long4_sat(src_data1), convert_long4_sat(src2)));

        *((__global int4 *)((__global char *)dst + dst_index)) = data;
    }
}
__kernel void arithm_s_add_C4_D5 (__global   float *src1, int src1_step, int src1_offset,
                                  __global   float *dst,  int dst_step,  int dst_offset,
                                  float4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 4) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 4) + dst_offset);

        float4 src_data1 = *((__global float4 *)((__global char *)src1 + src1_index));

        float4 data = ARITHM_OP(src_data1, src2);

        *((__global float4 *)((__global char *)dst + dst_index)) = data;
    }
}

#if defined (DOUBLE_SUPPORT)
__kernel void arithm_s_add_C4_D6 (__global   double *src1, int src1_step, int src1_offset,
                                  __global   double *dst,  int dst_step,  int dst_offset,
                                  double4 src2, int rows, int cols, int dst_step1)
{

    int x = get_global_id(0);
    int y = get_global_id(1);

    if (x < cols && y < rows)
    {
        int src1_index = mad24(y, src1_step, (x << 5) + src1_offset);
        int dst_index  = mad24(y, dst_step,  (x << 5) + dst_offset);

        double4 src_data1 = *((__global double4 *)((__global char *)src1 + src1_index));

        double4 data = ARITHM_OP(src_data1, src2);

        *((__global double4 *)((__global char *)dst + dst_index)) = data;
    }
}
#endif