opencl_kernels_imgproc.cpp 341 KB

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// This file is auto-generated. Do not edit!
#include "opencv2/core.hpp"
#include "cvconfig.h"
#include "opencl_kernels_imgproc.hpp"
#ifdef HAVE_OPENCL
namespace cv
{
namespace ocl
{
namespace imgproc
{

static const char* const moduleName = "imgproc";

struct cv::ocl::internal::ProgramEntry accumulate_oclsrc={moduleName, "accumulate",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#define SRC_TSIZE cn * (int)sizeof(srcT1)\n"
"#define DST_TSIZE cn * (int)sizeof(dstT1)\n"
"#define noconvert\n"
"__kernel void accumulate(__global const uchar * srcptr, int src_step, int src_offset,\n"
"#ifdef ACCUMULATE_PRODUCT\n"
"__global const uchar * src2ptr, int src2_step, int src2_offset,\n"
"#endif\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols\n"
"#ifdef ACCUMULATE_WEIGHTED\n"
", dstT1 alpha\n"
"#endif\n"
"#ifdef HAVE_MASK\n"
", __global const uchar * mask, int mask_step, int mask_offset\n"
"#endif\n"
")\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * rowsPerWI;\n"
"if (x < dst_cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, SRC_TSIZE, src_offset));\n"
"#ifdef HAVE_MASK\n"
"int mask_index = mad24(y, mask_step, mask_offset + x);\n"
"mask += mask_index;\n"
"#endif\n"
"#ifdef ACCUMULATE_PRODUCT\n"
"int src2_index = mad24(y, src2_step, mad24(x, SRC_TSIZE, src2_offset));\n"
"#endif\n"
"int dst_index = mad24(y, dst_step, mad24(x, DST_TSIZE, dst_offset));\n"
"#pragma unroll\n"
"for (int i = 0; i < rowsPerWI; ++i)\n"
"if (y < dst_rows)\n"
"{\n"
"__global const srcT1 * src = (__global const srcT1 *)(srcptr + src_index);\n"
"#ifdef ACCUMULATE_PRODUCT\n"
"__global const srcT1 * src2 = (__global const srcT1 *)(src2ptr + src2_index);\n"
"#endif\n"
"__global dstT1 * dst = (__global dstT1 *)(dstptr + dst_index);\n"
"#ifdef HAVE_MASK\n"
"if (mask[0])\n"
"#endif\n"
"#pragma unroll\n"
"for (int c = 0; c < cn; ++c)\n"
"{\n"
"#ifdef ACCUMULATE\n"
"dst[c] += convertToDT(src[c]);\n"
"#elif defined ACCUMULATE_SQUARE\n"
"dstT1 val = convertToDT(src[c]);\n"
"dst[c] = fma(val, val, dst[c]);\n"
"#elif defined ACCUMULATE_PRODUCT\n"
"dst[c] = fma(convertToDT(src[c]), convertToDT(src2[c]), dst[c]);\n"
"#elif defined ACCUMULATE_WEIGHTED\n"
"dst[c] = fma(1 - alpha, dst[c], src[c] * alpha);\n"
"#else\n"
"#error \"Unknown accumulation type\"\n"
"#endif\n"
"}\n"
"src_index += src_step;\n"
"#ifdef ACCUMULATE_PRODUCT\n"
"src2_index += src2_step;\n"
"#endif\n"
"#ifdef HAVE_MASK\n"
"mask += mask_step;\n"
"#endif\n"
"dst_index += dst_step;\n"
"++y;\n"
"}\n"
"}\n"
"}\n"
, "5f2c2d40f721d738ad2b8ef755376c6f", NULL};
struct cv::ocl::internal::ProgramEntry bilateral_oclsrc={moduleName, "bilateral",
"#if cn != 3\n"
"#define loadpix(addr) *(__global const uchar_t *)(addr)\n"
"#define storepix(val, addr)  *(__global uchar_t *)(addr) = val\n"
"#define TSIZE cn\n"
"#else\n"
"#define loadpix(addr) vload3(0, (__global const uchar *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global uchar *)(addr))\n"
"#define TSIZE 3\n"
"#endif\n"
"#if cn == 1\n"
"#define SUM(a) a\n"
"#elif cn == 2\n"
"#define SUM(a) a.x + a.y\n"
"#elif cn == 3\n"
"#define SUM(a) a.x + a.y + a.z\n"
"#elif cn == 4\n"
"#define SUM(a) a.x + a.y + a.z + a.w\n"
"#else\n"
"#error \"cn should be <= 4\"\n"
"#endif\n"
"__kernel void bilateral(__global const uchar * src, int src_step, int src_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant float * space_weight, __constant int * space_ofs)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (y < dst_rows && x < dst_cols)\n"
"{\n"
"int src_index = mad24(y + radius, src_step, mad24(x + radius, TSIZE, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, TSIZE, dst_offset));\n"
"float_t sum = (float_t)(0.0f);\n"
"float wsum = 0.0f;\n"
"#ifdef INTEL_DEVICE\n"
"float_t val0 = convert_float_t(loadpix(src + src_index));\n"
"#else\n"
"int_t val0 = convert_int_t(loadpix(src + src_index));\n"
"#endif\n"
"#pragma unroll\n"
"for (int k = 0; k < maxk; k++ )\n"
"{\n"
"#ifdef INTEL_DEVICE\n"
"float_t val = convert_float_t(loadpix(src + src_index + space_ofs[k]));\n"
"float diff = SUM(fabs(val - val0));\n"
"#else\n"
"int_t val = convert_int_t(loadpix(src + src_index + space_ofs[k]));\n"
"int diff = SUM(abs(val - val0));\n"
"#endif\n"
"float w = space_weight[k] * native_exp((float)(diff * diff * gauss_color_coeff));\n"
"sum += convert_float_t(val) * (float_t)(w);\n"
"wsum += w;\n"
"}\n"
"storepix(convert_uchar_t(sum / (float_t)(wsum)), dst + dst_index);\n"
"}\n"
"}\n"
"#ifdef INTEL_DEVICE\n"
"#if cn == 1\n"
"__kernel void bilateral_float4(__global const uchar * src, int src_step, int src_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant float * space_weight, __constant int * space_ofs)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (y < dst_rows && x < dst_cols / 4 )\n"
"{\n"
"int src_index = ((y + radius) * src_step) + x * 4  + (radius + src_offset);\n"
"int dst_index = (y  * dst_step) +  x * 4 + dst_offset ;\n"
"float4 sum = 0.f, wsum = 0.f;\n"
"float4 val0 = convert_float4(vload4(0, src + src_index));\n"
"#pragma unroll\n"
"for (int k = 0; k < maxk; k++ )\n"
"{\n"
"float4 val = convert_float4(vload4(0, src + src_index + space_ofs[k]));\n"
"float4 w = space_weight[k] * native_exp((val - val0) * (val - val0) * gauss_color_coeff);\n"
"sum += val * w;\n"
"wsum += w;\n"
"}\n"
"sum = sum / wsum + .5f;\n"
"vstore4(convert_uchar4_rtz(sum), 0, dst + dst_index);\n"
"}\n"
"}\n"
"#endif\n"
"#endif\n"
, "1cc12569fdb93cbfa05bb215d3d42e64", NULL};
struct cv::ocl::internal::ProgramEntry blend_linear_oclsrc={moduleName, "blend_linear",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#define noconvert\n"
"__kernel void blendLinear(__global const uchar * src1ptr, int src1_step, int src1_offset,\n"
"__global const uchar * src2ptr, int src2_step, int src2_offset,\n"
"__global const uchar * weight1, int weight1_step, int weight1_offset,\n"
"__global const uchar * weight2, int weight2_step, int weight2_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"int src1_index = mad24(y, src1_step, src1_offset + x * cn * (int)sizeof(T));\n"
"int src2_index = mad24(y, src2_step, src2_offset + x * cn * (int)sizeof(T));\n"
"int weight1_index = mad24(y, weight1_step, weight1_offset + x * (int)sizeof(float));\n"
"int weight2_index = mad24(y, weight2_step, weight2_offset + x * (int)sizeof(float));\n"
"int dst_index = mad24(y, dst_step, dst_offset + x * cn * (int)sizeof(T));\n"
"float w1 = *(__global const float *)(weight1 + weight1_index),\n"
"w2 = *(__global const float *)(weight2 + weight2_index);\n"
"float den = w1 + w2 + 1e-5f;\n"
"__global const T * src1 = (__global const T *)(src1ptr + src1_index);\n"
"__global const T * src2 = (__global const T *)(src2ptr + src2_index);\n"
"__global T * dst = (__global T *)(dstptr + dst_index);\n"
"#pragma unroll\n"
"for (int i = 0; i < cn; ++i)\n"
"{\n"
"float num = w1 * convert_float(src1[i]) + w2 * convert_float(src2[i]);\n"
"dst[i] = convertToT(num / den);\n"
"}\n"
"}\n"
"}\n"
, "76072b51c3ede4951ee0200aa33297dc", NULL};
struct cv::ocl::internal::ProgramEntry boxFilter_oclsrc={moduleName, "boxFilter",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#if cn != 3\n"
"#define loadpix(addr) *(__global const ST *)(addr)\n"
"#define storepix(val, addr)  *(__global DT *)(addr) = val\n"
"#define SRCSIZE (int)sizeof(ST)\n"
"#define DSTSIZE (int)sizeof(DT)\n"
"#else\n"
"#define loadpix(addr) vload3(0, (__global const ST1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global DT1 *)(addr))\n"
"#define SRCSIZE (int)sizeof(ST1)*cn\n"
"#define DSTSIZE (int)sizeof(DT1)*cn\n"
"#endif\n"
"#ifdef BORDER_CONSTANT\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) \\\n"
"{ \\\n"
"x = max(min(x, maxX - 1), minX); \\\n"
"y = max(min(y, maxY - 1), minY); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) \\\n"
"{ \\\n"
"if (x < minX) \\\n"
"x -= ((x - maxX + 1) / maxX) * maxX; \\\n"
"if (x >= maxX) \\\n"
"x %= maxX; \\\n"
"if (y < minY) \\\n"
"y -= ((y - maxY + 1) / maxY) * maxY; \\\n"
"if (y >= maxY) \\\n"
"y %= maxY; \\\n"
"}\n"
"#elif defined(BORDER_REFLECT) || defined(BORDER_REFLECT_101)\n"
"#define EXTRAPOLATE_(x, y, minX, minY, maxX, maxY, delta) \\\n"
"{ \\\n"
"if (maxX - minX == 1) \\\n"
"x = minX; \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if (x < minX) \\\n"
"x = minX - (x - minX) - 1 + delta; \\\n"
"else \\\n"
"x = maxX - 1 - (x - maxX) - delta; \\\n"
"} \\\n"
"while (x >= maxX || x < minX); \\\n"
"\\\n"
"if (maxY - minY == 1) \\\n"
"y = minY; \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if (y < minY) \\\n"
"y = minY - (y - minY) - 1 + delta; \\\n"
"else \\\n"
"y = maxY - 1 - (y - maxY) - delta; \\\n"
"} \\\n"
"while (y >= maxY || y < minY); \\\n"
"}\n"
"#ifdef BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) EXTRAPOLATE_(x, y, minX, minY, maxX, maxY, 0)\n"
"#elif defined(BORDER_REFLECT_101)\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) EXTRAPOLATE_(x, y, minX, minY, maxX, maxY, 1)\n"
"#endif\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#define noconvert\n"
"#ifdef SQR\n"
"#define PROCESS_ELEM(value) (value * value)\n"
"#else\n"
"#define PROCESS_ELEM(value) value\n"
"#endif\n"
"struct RectCoords\n"
"{\n"
"int x1, y1, x2, y2;\n"
"};\n"
"inline WT readSrcPixel(int2 pos, __global const uchar * srcptr, int src_step, const struct RectCoords srcCoords)\n"
"{\n"
"#ifdef BORDER_ISOLATED\n"
"if (pos.x >= srcCoords.x1 && pos.y >= srcCoords.y1 && pos.x < srcCoords.x2 && pos.y < srcCoords.y2)\n"
"#else\n"
"if (pos.x >= 0 && pos.y >= 0 && pos.x < srcCoords.x2 && pos.y < srcCoords.y2)\n"
"#endif\n"
"{\n"
"int src_index = mad24(pos.y, src_step, pos.x * SRCSIZE);\n"
"WT value = convertToWT(loadpix(srcptr + src_index));\n"
"return PROCESS_ELEM(value);\n"
"}\n"
"else\n"
"{\n"
"#ifdef BORDER_CONSTANT\n"
"return (WT)(0);\n"
"#else\n"
"int selected_col = pos.x, selected_row = pos.y;\n"
"EXTRAPOLATE(selected_col, selected_row,\n"
"#ifdef BORDER_ISOLATED\n"
"srcCoords.x1, srcCoords.y1,\n"
"#else\n"
"0, 0,\n"
"#endif\n"
"srcCoords.x2, srcCoords.y2);\n"
"int src_index = mad24(selected_row, src_step, selected_col * SRCSIZE);\n"
"WT value = convertToWT(loadpix(srcptr + src_index));\n"
"return PROCESS_ELEM(value);\n"
"#endif\n"
"}\n"
"}\n"
"__kernel void boxFilter(__global const uchar * srcptr, int src_step, int srcOffsetX, int srcOffsetY, int srcEndX, int srcEndY,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int rows, int cols\n"
"#ifdef NORMALIZE\n"
", float alpha\n"
"#endif\n"
")\n"
"{\n"
"const struct RectCoords srcCoords = { srcOffsetX, srcOffsetY, srcEndX, srcEndY };\n"
"int x = get_local_id(0) + (LOCAL_SIZE_X - (KERNEL_SIZE_X - 1)) * get_group_id(0) - ANCHOR_X;\n"
"int y = get_global_id(1) * BLOCK_SIZE_Y;\n"
"int local_id = get_local_id(0);\n"
"WT data[KERNEL_SIZE_Y];\n"
"__local WT sumOfCols[LOCAL_SIZE_X];\n"
"int2 srcPos = (int2)(srcCoords.x1 + x, srcCoords.y1 + y - ANCHOR_Y);\n"
"#pragma unroll\n"
"for (int sy = 0; sy < KERNEL_SIZE_Y; sy++, srcPos.y++)\n"
"data[sy] = readSrcPixel(srcPos, srcptr, src_step, srcCoords);\n"
"WT tmp_sum = (WT)(0);\n"
"#pragma unroll\n"
"for (int sy = 0; sy < KERNEL_SIZE_Y; sy++)\n"
"tmp_sum += data[sy];\n"
"sumOfCols[local_id] = tmp_sum;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"int dst_index = mad24(y, dst_step, mad24(x, DSTSIZE, dst_offset));\n"
"__global DT * dst = (__global DT *)(dstptr + dst_index);\n"
"int sy_index = 0;\n"
"for (int i = 0, stepY = min(rows - y, BLOCK_SIZE_Y); i < stepY; ++i)\n"
"{\n"
"if (local_id >= ANCHOR_X && local_id < LOCAL_SIZE_X - (KERNEL_SIZE_X - 1 - ANCHOR_X) &&\n"
"x >= 0 && x < cols)\n"
"{\n"
"WT total_sum = (WT)(0);\n"
"#pragma unroll\n"
"for (int sx = 0; sx < KERNEL_SIZE_X; sx++)\n"
"total_sum += sumOfCols[local_id + sx - ANCHOR_X];\n"
"#ifdef NORMALIZE\n"
"DT dstval = convertToDT((WT)(alpha) * total_sum);\n"
"#else\n"
"DT dstval = convertToDT(total_sum);\n"
"#endif\n"
"storepix(dstval, dst);\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"tmp_sum = sumOfCols[local_id];\n"
"tmp_sum -= data[sy_index];\n"
"data[sy_index] = readSrcPixel(srcPos, srcptr, src_step, srcCoords);\n"
"srcPos.y++;\n"
"tmp_sum += data[sy_index];\n"
"sumOfCols[local_id] = tmp_sum;\n"
"sy_index = sy_index + 1 < KERNEL_SIZE_Y ? sy_index + 1 : 0;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"dst = (__global DT *)((__global uchar *)dst + dst_step);\n"
"}\n"
"}\n"
, "d3e542270fa2ea1fc3744043dad50cb4", NULL};
struct cv::ocl::internal::ProgramEntry boxFilter3x3_oclsrc={moduleName, "boxFilter3x3",
"__kernel void boxFilter3x3_8UC1_cols16_rows2(__global const uint* src, int src_step,\n"
"__global uint* dst, int dst_step, int rows, int cols\n"
"#ifdef NORMALIZE\n"
", float alpha\n"
"#endif\n"
")\n"
"{\n"
"int block_x = get_global_id(0);\n"
"int y = get_global_id(1) * 2;\n"
"int ssx, dsx;\n"
"if ((block_x * 16) >= cols || y >= rows) return;\n"
"uint4 line[4];\n"
"uint4 line_out[2];\n"
"ushort a; ushort16 b; ushort c;\n"
"ushort d; ushort16 e; ushort f;\n"
"ushort g; ushort16 h; ushort i;\n"
"ushort j; ushort16 k; ushort l;\n"
"ssx = dsx = 1;\n"
"int src_index = block_x * 4 * ssx + (y - 1) * (src_step / 4);\n"
"line[1] = vload4(0, src + src_index + (src_step / 4));\n"
"line[2] = vload4(0, src + src_index + 2 * (src_step / 4));\n"
"#ifdef BORDER_CONSTANT\n"
"line[0] = (y == 0) ? (uint4)0 : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? (uint4)0 : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#elif defined BORDER_REFLECT_101\n"
"line[0] = (y == 0) ? line[2] : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? line[1] : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#elif defined (BORDER_REPLICATE) || defined(BORDER_REFLECT)\n"
"line[0] = (y == 0) ? line[1] : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? line[2] : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#endif\n"
"ushort16 sum, mid;\n"
"__global uchar *src_p = (__global uchar *)src;\n"
"src_index = block_x * 16 * ssx + (y - 1) * src_step;\n"
"bool line_end = ((block_x + 1) * 16 == cols);\n"
"b = convert_ushort16(as_uchar16(line[0]));\n"
"e = convert_ushort16(as_uchar16(line[1]));\n"
"h = convert_ushort16(as_uchar16(line[2]));\n"
"k = convert_ushort16(as_uchar16(line[3]));\n"
"#ifdef BORDER_CONSTANT\n"
"a = (block_x == 0 || y == 0) ? 0 : convert_ushort(src_p[src_index - 1]);\n"
"c = (line_end || y == 0) ? 0 : convert_ushort(src_p[src_index + 16]);\n"
"d = (block_x == 0) ? 0 : convert_ushort(src_p[src_index + src_step - 1]);\n"
"f = line_end ? 0 : convert_ushort(src_p[src_index + src_step + 16]);\n"
"g = (block_x == 0) ? 0 : convert_ushort(src_p[src_index + 2 * src_step - 1]);\n"
"i = line_end ? 0 : convert_ushort(src_p[src_index + 2 * src_step + 16]);\n"
"j = (block_x == 0 || y == (rows - 2)) ? 0 : convert_ushort(src_p[src_index + 3 * src_step - 1]);\n"
"l = (line_end || y == (rows - 2))? 0 : convert_ushort(src_p[src_index + 3 * src_step + 16]);\n"
"#elif defined BORDER_REFLECT_101\n"
"int offset;\n"
"offset = (y == 0) ? (2 * src_step) : 0;\n"
"a = (block_x == 0) ? convert_ushort(src_p[src_index + offset + 1]) : convert_ushort(src_p[src_index + offset - 1]);\n"
"c = line_end ? convert_ushort(src_p[src_index + offset + 14]) : convert_ushort(src_p[src_index + offset + 16]);\n"
"d = (block_x == 0) ? convert_ushort(src_p[src_index + src_step + 1]) : convert_ushort(src_p[src_index + src_step - 1]);\n"
"f = line_end ? convert_ushort(src_p[src_index + src_step + 14]) : convert_ushort(src_p[src_index + src_step + 16]);\n"
"g = (block_x == 0) ? convert_ushort(src_p[src_index + 2 * src_step + 1]) : convert_ushort(src_p[src_index + 2 * src_step - 1]);\n"
"i = line_end ? convert_ushort(src_p[src_index + 2 * src_step + 14]) : convert_ushort(src_p[src_index + 2 * src_step + 16]);\n"
"offset = (y == (rows - 2)) ? (1 * src_step) : (3 * src_step);\n"
"j = (block_x == 0) ? convert_ushort(src_p[src_index + offset + 1]) : convert_ushort(src_p[src_index + offset - 1]);\n"
"l = line_end ? convert_ushort(src_p[src_index + offset + 14]) : convert_ushort(src_p[src_index + offset + 16]);\n"
"#elif defined (BORDER_REPLICATE) || defined(BORDER_REFLECT)\n"
"int offset;\n"
"offset = (y == 0) ? (1 * src_step) : 0;\n"
"a = (block_x == 0) ? convert_ushort(src_p[src_index + offset]) : convert_ushort(src_p[src_index + offset - 1]);\n"
"c = line_end ? convert_ushort(src_p[src_index + offset + 15]) : convert_ushort(src_p[src_index + offset + 16]);\n"
"d = (block_x == 0) ? convert_ushort(src_p[src_index + src_step]) : convert_ushort(src_p[src_index + src_step - 1]);\n"
"f = line_end ? convert_ushort(src_p[src_index + src_step + 15]) : convert_ushort(src_p[src_index + src_step + 16]);\n"
"g = (block_x == 0) ? convert_ushort(src_p[src_index + 2 * src_step]) : convert_ushort(src_p[src_index + 2 * src_step - 1]);\n"
"i = line_end ? convert_ushort(src_p[src_index + 2 * src_step + 15]) : convert_ushort(src_p[src_index + 2 * src_step + 16]);\n"
"offset = (y == (rows - 2)) ? (2 * src_step) : (3 * src_step);\n"
"j = (block_x == 0) ? convert_ushort(src_p[src_index + offset]) : convert_ushort(src_p[src_index + offset - 1]);\n"
"l = line_end ? convert_ushort(src_p[src_index + offset + 15]) : convert_ushort(src_p[src_index + offset + 16]);\n"
"#endif\n"
"mid = (ushort16)(d, e.s0123, e.s456789ab, e.scde) + e + (ushort16)(e.s123, e.s4567, e.s89abcdef, f) +\n"
"(ushort16)(g, h.s0123, h.s456789ab, h.scde) + h + (ushort16)(h.s123, h.s4567, h.s89abcdef, i);\n"
"sum = (ushort16)(a, b.s0123, b.s456789ab, b.scde) + b + (ushort16)(b.s123, b.s4567, b.s89abcdef, c) +\n"
"mid;\n"
"#ifdef NORMALIZE\n"
"line_out[0] = as_uint4(convert_uchar16_sat_rte((convert_float16(sum) * alpha)));\n"
"#else\n"
"line_out[0] = as_uint4(convert_uchar16_sat_rte(sum));\n"
"#endif\n"
"sum = mid +\n"
"(ushort16)(j, k.s0123, k.s456789ab, k.scde) + k + (ushort16)(k.s123, k.s4567, k.s89abcdef, l);\n"
"#ifdef NORMALIZE\n"
"line_out[1] = as_uint4(convert_uchar16_sat_rte((convert_float16(sum) * alpha)));\n"
"#else\n"
"line_out[1] = as_uint4(convert_uchar16_sat_rte(sum));\n"
"#endif\n"
"int dst_index = block_x * 4 * dsx + y * (dst_step / 4);\n"
"vstore4(line_out[0], 0, dst + dst_index);\n"
"vstore4(line_out[1], 0, dst + dst_index + (dst_step / 4));\n"
"}\n"
, "72a31e7e412911731db2747210c1b3d4", NULL};
struct cv::ocl::internal::ProgramEntry calc_back_project_oclsrc={moduleName, "calc_back_project",
"#define OUT_OF_RANGE -1\n"
"#define ROUNDING_EPS 0.000001f\n"
"#if histdims == 1\n"
"__kernel void calcLUT(__global const uchar * histptr, int hist_step, int hist_offset, int hist_bins,\n"
"__global int * lut, float scale, __constant float * ranges)\n"
"{\n"
"int x = get_global_id(0);\n"
"float value = convert_float(x);\n"
"if (value > ranges[1] || value < ranges[0])\n"
"lut[x] = OUT_OF_RANGE;\n"
"else\n"
"{\n"
"float lb = ranges[0], ub = ranges[1], gap = (ub - lb) / hist_bins;\n"
"value -= lb;\n"
"int bin = convert_int_sat_rtn(value / gap + ROUNDING_EPS);\n"
"if (bin >= hist_bins)\n"
"lut[x] = OUT_OF_RANGE;\n"
"else\n"
"{\n"
"int hist_index = mad24(hist_step, bin, hist_offset);\n"
"__global const float * hist = (__global const float *)(histptr + hist_index);\n"
"lut[x] = (int)convert_uchar_sat_rte(hist[0] * scale);\n"
"}\n"
"}\n"
"}\n"
"__kernel void LUT(__global const uchar * src, int src_step, int src_offset,\n"
"__constant int * lut,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"int src_index = mad24(y, src_step, src_offset + x * scn);\n"
"int dst_index = mad24(y, dst_step, dst_offset + x);\n"
"int value = lut[src[src_index]];\n"
"dst[dst_index] = value == OUT_OF_RANGE ? 0 : convert_uchar(value);\n"
"}\n"
"}\n"
"#elif histdims == 2\n"
"__kernel void calcLUT(int hist_bins, __global int * lut, int lut_offset,\n"
"__constant float * ranges, int roffset)\n"
"{\n"
"int x = get_global_id(0);\n"
"float value = convert_float(x);\n"
"ranges += roffset;\n"
"lut += lut_offset;\n"
"if (value > ranges[1] || value < ranges[0])\n"
"lut[x] = OUT_OF_RANGE;\n"
"else\n"
"{\n"
"float lb = ranges[0], ub = ranges[1], gap = (ub - lb) / hist_bins;\n"
"value -= lb;\n"
"int bin = convert_int_sat_rtn(value / gap + ROUNDING_EPS);\n"
"lut[x] = bin >= hist_bins ? OUT_OF_RANGE : bin;\n"
"}\n"
"}\n"
"__kernel void LUT(__global const uchar * src1, int src1_step, int src1_offset,\n"
"__global const uchar * src2, int src2_step, int src2_offset,\n"
"__global const uchar * histptr, int hist_step, int hist_offset,\n"
"__constant int * lut, float scale,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"int src1_index = mad24(y, src1_step, src1_offset + x * scn1);\n"
"int src2_index = mad24(y, src2_step, src2_offset + x * scn2);\n"
"int dst_index = mad24(y, dst_step, dst_offset + x);\n"
"int bin1 = lut[src1[src1_index]];\n"
"int bin2 = lut[src2[src2_index] + 256];\n"
"dst[dst_index] = bin1 == OUT_OF_RANGE || bin2 == OUT_OF_RANGE ? 0 :\n"
"convert_uchar_sat_rte(*(__global const float *)(histptr +\n"
"mad24(hist_step, bin1, hist_offset + bin2 * (int)sizeof(float))) * scale);\n"
"}\n"
"}\n"
"#else\n"
"#error \"(nimages <= 2) should be true\"\n"
"#endif\n"
, "6bab391f796ff5b2ba3d38f23929307e", NULL};
struct cv::ocl::internal::ProgramEntry canny_oclsrc={moduleName, "canny",
"#define TG22 0.4142135623730950488016887242097f\n"
"#define TG67 2.4142135623730950488016887242097f\n"
"#ifdef WITH_SOBEL\n"
"#if cn == 1\n"
"#define loadpix(addr) convert_floatN(*(__global const TYPE *)(addr))\n"
"#else\n"
"#define loadpix(addr) convert_floatN(vload3(0, (__global const TYPE *)(addr)))\n"
"#endif\n"
"#define storepix(value, addr) *(__global int *)(addr) = (int)(value)\n"
"__constant int prev[4][2] = {\n"
"{ 0, -1 },\n"
"{ -1, 1 },\n"
"{ -1, 0 },\n"
"{ -1, -1 }\n"
"};\n"
"__constant int next[4][2] = {\n"
"{ 0, 1 },\n"
"{ 1, -1 },\n"
"{ 1, 0 },\n"
"{ 1, 1 }\n"
"};\n"
"inline float3 sobel(int idx, __local const floatN *smem)\n"
"{\n"
"float3 res;\n"
"floatN dx = fma((floatN)2, smem[idx + GRP_SIZEX + 6] - smem[idx + GRP_SIZEX + 4],\n"
"smem[idx + 2] - smem[idx] + smem[idx + 2 * GRP_SIZEX + 10] - smem[idx + 2 * GRP_SIZEX + 8]);\n"
"floatN dy = fma((floatN)2, smem[idx + 1] - smem[idx + 2 * GRP_SIZEX + 9],\n"
"smem[idx + 2] - smem[idx + 2 * GRP_SIZEX + 10] + smem[idx] - smem[idx + 2 * GRP_SIZEX + 8]);\n"
"#ifdef L2GRAD\n"
"floatN magN = fma(dx, dx, dy * dy);\n"
"#else\n"
"floatN magN = fabs(dx) + fabs(dy);\n"
"#endif\n"
"#if cn == 1\n"
"res.z = magN;\n"
"res.x = dx;\n"
"res.y = dy;\n"
"#else\n"
"res.z = max(magN.x, max(magN.y, magN.z));\n"
"if (res.z == magN.y)\n"
"{\n"
"dx.x = dx.y;\n"
"dy.x = dy.y;\n"
"}\n"
"else if (res.z == magN.z)\n"
"{\n"
"dx.x = dx.z;\n"
"dy.x = dy.z;\n"
"}\n"
"res.x = dx.x;\n"
"res.y = dy.x;\n"
"#endif\n"
"return res;\n"
"}\n"
"__kernel void stage1_with_sobel(__global const uchar *src, int src_step, int src_offset, int rows, int cols,\n"
"__global uchar *map, int map_step, int map_offset,\n"
"float low_thr, float high_thr)\n"
"{\n"
"__local floatN smem[(GRP_SIZEX + 4) * (GRP_SIZEY + 4)];\n"
"int lidx = get_local_id(0);\n"
"int lidy = get_local_id(1);\n"
"int start_x = GRP_SIZEX * get_group_id(0);\n"
"int start_y = GRP_SIZEY * get_group_id(1);\n"
"int i = lidx + lidy * GRP_SIZEX;\n"
"for (int j = i;  j < (GRP_SIZEX + 4) * (GRP_SIZEY + 4); j += GRP_SIZEX * GRP_SIZEY)\n"
"{\n"
"int x = clamp(start_x - 2 + (j % (GRP_SIZEX + 4)), 0, cols - 1);\n"
"int y = clamp(start_y - 2 + (j / (GRP_SIZEX + 4)), 0, rows - 1);\n"
"smem[j] = loadpix(src + mad24(y, src_step, mad24(x, cn * (int)sizeof(TYPE), src_offset)));\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"__local float mag[(GRP_SIZEX + 2) * (GRP_SIZEY + 2)];\n"
"lidx++;\n"
"lidy++;\n"
"if (i < GRP_SIZEX + 2)\n"
"{\n"
"int grp_sizey = min(GRP_SIZEY + 1, rows - start_y);\n"
"mag[i] = (sobel(i, smem)).z;\n"
"mag[i + grp_sizey * (GRP_SIZEX + 2)] = (sobel(i + grp_sizey * (GRP_SIZEX + 4), smem)).z;\n"
"}\n"
"if (i < GRP_SIZEY + 2)\n"
"{\n"
"int grp_sizex = min(GRP_SIZEX + 1, cols - start_x);\n"
"mag[i * (GRP_SIZEX + 2)] = (sobel(i * (GRP_SIZEX + 4), smem)).z;\n"
"mag[i * (GRP_SIZEX + 2) + grp_sizex] = (sobel(i * (GRP_SIZEX + 4) + grp_sizex, smem)).z;\n"
"}\n"
"int idx = lidx + lidy * (GRP_SIZEX + 4);\n"
"i = lidx + lidy * (GRP_SIZEX + 2);\n"
"float3 res = sobel(idx, smem);\n"
"mag[i] = res.z;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"int x = (int) res.x;\n"
"int y = (int) res.y;\n"
"int gidx = get_global_id(0);\n"
"int gidy = get_global_id(1);\n"
"if (gidx >= cols || gidy >= rows)\n"
"return;\n"
"float mag0 = mag[i];\n"
"int value = 1;\n"
"if (mag0 > low_thr)\n"
"{\n"
"float x_ = abs(x);\n"
"float y_ = abs(y);\n"
"int a = (y_ * TG22 >= x_) ? 2 : 1;\n"
"int b = (y_ * TG67 >= x_) ? 1 : 0;\n"
"int dir3 = (a * b) & (((x ^ y) & 0x80000000) >> 31);\n"
"int dir = a * b + 2 * dir3;\n"
"float prev_mag = mag[(lidy + prev[dir][0]) * (GRP_SIZEX + 2) + lidx + prev[dir][1]];\n"
"float next_mag = mag[(lidy + next[dir][0]) * (GRP_SIZEX + 2) + lidx + next[dir][1]] + (dir & 1);\n"
"if (mag0 > prev_mag && mag0 >= next_mag)\n"
"{\n"
"value = (mag0 > high_thr) ? 2 : 0;\n"
"}\n"
"}\n"
"storepix(value, map + mad24(gidy, map_step, mad24(gidx, (int)sizeof(int), map_offset)));\n"
"}\n"
"#elif defined WITHOUT_SOBEL\n"
"#define loadpix(addr) (__global short *)(addr)\n"
"#define storepix(val, addr) *(__global int *)(addr) = (int)(val)\n"
"#ifdef L2GRAD\n"
"#define dist(x, y) ((int)(x) * (x) + (int)(y) * (y))\n"
"#else\n"
"#define dist(x, y) (abs((int)(x)) + abs((int)(y)))\n"
"#endif\n"
"__constant int prev[4][2] = {\n"
"{ 0, -1 },\n"
"{ -1, -1 },\n"
"{ -1, 0 },\n"
"{ -1, 1 }\n"
"};\n"
"__constant int next[4][2] = {\n"
"{ 0, 1 },\n"
"{ 1, 1 },\n"
"{ 1, 0 },\n"
"{ 1, -1 }\n"
"};\n"
"__kernel void stage1_without_sobel(__global const uchar *dxptr, int dx_step, int dx_offset,\n"
"__global const uchar *dyptr, int dy_step, int dy_offset,\n"
"__global uchar *map, int map_step, int map_offset, int rows, int cols,\n"
"int low_thr, int high_thr)\n"
"{\n"
"int start_x = get_group_id(0) * GRP_SIZEX;\n"
"int start_y = get_group_id(1) * GRP_SIZEY;\n"
"int lidx = get_local_id(0);\n"
"int lidy = get_local_id(1);\n"
"__local int mag[(GRP_SIZEX + 2) * (GRP_SIZEY + 2)];\n"
"__local short2 sigma[(GRP_SIZEX + 2) * (GRP_SIZEY + 2)];\n"
"#pragma unroll\n"
"for (int i = lidx + lidy * GRP_SIZEX; i < (GRP_SIZEX + 2) * (GRP_SIZEY + 2); i += GRP_SIZEX * GRP_SIZEY)\n"
"{\n"
"int x = clamp(start_x - 1 + i % (GRP_SIZEX + 2), 0, cols - 1);\n"
"int y = clamp(start_y - 1 + i / (GRP_SIZEX + 2), 0, rows - 1);\n"
"int dx_index = mad24(y, dx_step, mad24(x, cn * (int)sizeof(short), dx_offset));\n"
"int dy_index = mad24(y, dy_step, mad24(x, cn * (int)sizeof(short), dy_offset));\n"
"__global short *dx = loadpix(dxptr + dx_index);\n"
"__global short *dy = loadpix(dyptr + dy_index);\n"
"int mag0 = dist(dx[0], dy[0]);\n"
"#if cn > 1\n"
"short cdx = dx[0], cdy = dy[0];\n"
"#pragma unroll\n"
"for (int j = 1; j < cn; ++j)\n"
"{\n"
"int mag1 = dist(dx[j], dy[j]);\n"
"if (mag1 > mag0)\n"
"{\n"
"mag0 = mag1;\n"
"cdx = dx[j];\n"
"cdy = dy[j];\n"
"}\n"
"}\n"
"dx[0] = cdx;\n"
"dy[0] = cdy;\n"
"#endif\n"
"mag[i] = mag0;\n"
"sigma[i] = (short2)(dx[0], dy[0]);\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"int gidx = get_global_id(0);\n"
"int gidy = get_global_id(1);\n"
"if (gidx >= cols || gidy >= rows)\n"
"return;\n"
"lidx++;\n"
"lidy++;\n"
"int mag0 = mag[lidx + lidy * (GRP_SIZEX + 2)];\n"
"short x = (sigma[lidx + lidy * (GRP_SIZEX + 2)]).x;\n"
"short y = (sigma[lidx + lidy * (GRP_SIZEX + 2)]).y;\n"
"int value = 1;\n"
"if (mag0 > low_thr)\n"
"{\n"
"float x_ = abs(x);\n"
"float y_ = abs(y);\n"
"int a = (y_ * TG22 >= x_) ? 2 : 1;\n"
"int b = (y_ * TG67 >= x_) ? 1 : 0;\n"
"int dir3 = (a * b) & (((x ^ y) & 0x80000000) >> 31);\n"
"int dir = a * b + 2 * dir3;\n"
"int prev_mag = mag[(lidy + prev[dir][0]) * (GRP_SIZEX + 2) + lidx + prev[dir][1]];\n"
"int next_mag = mag[(lidy + next[dir][0]) * (GRP_SIZEX + 2) + lidx + next[dir][1]] + (dir & 1);\n"
"if (mag0 > prev_mag && mag0 >= next_mag)\n"
"{\n"
"value = (mag0 > high_thr) ? 2 : 0;\n"
"}\n"
"}\n"
"storepix(value, map + mad24(gidy, map_step, mad24(gidx, (int)sizeof(int), map_offset)));\n"
"}\n"
"#undef TG22\n"
"#undef CANNY_SHIFT\n"
"#elif defined STAGE2\n"
"#define loadpix(addr) *(__global int *)(addr)\n"
"#define storepix(val, addr) *(__global int *)(addr) = (int)(val)\n"
"#define LOCAL_TOTAL (LOCAL_X*LOCAL_Y)\n"
"#define l_stack_size (4*LOCAL_TOTAL)\n"
"#define p_stack_size 8\n"
"__constant short move_dir[2][8] = {\n"
"{ -1, -1, -1, 0, 0, 1, 1, 1 },\n"
"{ -1, 0, 1, -1, 1, -1, 0, 1 }\n"
"};\n"
"__kernel void stage2_hysteresis(__global uchar *map_ptr, int map_step, int map_offset, int rows, int cols)\n"
"{\n"
"map_ptr += map_offset;\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI;\n"
"int lid = get_local_id(0) + get_local_id(1) * LOCAL_X;\n"
"__local ushort2 l_stack[l_stack_size];\n"
"__local int l_counter;\n"
"if (lid == 0)\n"
"l_counter = 0;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (x < cols)\n"
"{\n"
"__global uchar* map = map_ptr + mad24(y, map_step, x * (int)sizeof(int));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"int type = loadpix(map);\n"
"if (type == 2)\n"
"{\n"
"l_stack[atomic_inc(&l_counter)] = (ushort2)(x, y);\n"
"}\n"
"y++;\n"
"map += map_step;\n"
"}\n"
"}\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"ushort2 p_stack[p_stack_size];\n"
"int p_counter = 0;\n"
"while(l_counter != 0)\n"
"{\n"
"int mod = l_counter % LOCAL_TOTAL;\n"
"int pix_per_thr = l_counter / LOCAL_TOTAL + ((lid < mod) ? 1 : 0);\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"for (int i = 0; i < pix_per_thr; ++i)\n"
"{\n"
"int index = atomic_dec(&l_counter) - 1;\n"
"if (index < 0)\n"
"continue;\n"
"ushort2 pos = l_stack[ index ];\n"
"#pragma unroll\n"
"for (int j = 0; j < 8; ++j)\n"
"{\n"
"ushort posx = pos.x + move_dir[0][j];\n"
"ushort posy = pos.y + move_dir[1][j];\n"
"if (posx < 0 || posy < 0 || posx >= cols || posy >= rows)\n"
"continue;\n"
"__global uchar *addr = map_ptr + mad24(posy, map_step, posx * (int)sizeof(int));\n"
"int type = loadpix(addr);\n"
"if (type == 0)\n"
"{\n"
"p_stack[p_counter++] = (ushort2)(posx, posy);\n"
"storepix(2, addr);\n"
"}\n"
"}\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (l_counter < 0)\n"
"l_counter = 0;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"while (p_counter > 0)\n"
"{\n"
"l_stack[ atomic_inc(&l_counter) ] = p_stack[--p_counter];\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"}\n"
"}\n"
"#elif defined GET_EDGES\n"
"__kernel void getEdges(__global const uchar *mapptr, int map_step, int map_offset, int rows, int cols,\n"
"__global uchar *dst, int dst_step, int dst_offset)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI;\n"
"if (x < cols)\n"
"{\n"
"int map_index = mad24(map_step, y, mad24(x, (int)sizeof(int), map_offset));\n"
"int dst_index = mad24(dst_step, y, x + dst_offset);\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const int * map = (__global const int *)(mapptr + map_index);\n"
"dst[dst_index] = (uchar)(-(map[0] >> 1));\n"
"y++;\n"
"map_index += map_step;\n"
"dst_index += dst_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
, "2e3c93ad703f4bcee1efbbcc0107fc8d", NULL};
struct cv::ocl::internal::ProgramEntry clahe_oclsrc={moduleName, "clahe",
"inline int calc_lut(__local int* smem, int val, int tid)\n"
"{\n"
"smem[tid] = val;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (tid == 0)\n"
"for (int i = 1; i < 256; ++i)\n"
"smem[i] += smem[i - 1];\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"return smem[tid];\n"
"}\n"
"inline int reduce(__local volatile int* smem, int val, int tid)\n"
"{\n"
"smem[tid] = val;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (tid < 128)\n"
"smem[tid] = val += smem[tid + 128];\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (tid < 64)\n"
"smem[tid] = val += smem[tid + 64];\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (tid < 32)\n"
"{\n"
"smem[tid] += smem[tid + 32];\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (tid < 16)\n"
"{\n"
"smem[tid] += smem[tid + 16];\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (tid < 8)\n"
"{\n"
"smem[tid] += smem[tid + 8];\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (tid < 4)\n"
"{\n"
"smem[tid] += smem[tid + 4];\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (tid == 0)\n"
"{\n"
"smem[0] = (smem[0] + smem[1]) + (smem[2] + smem[3]);\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"val = smem[0];\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"return val;\n"
"}\n"
"__kernel void calcLut(__global __const uchar * src, const int srcStep,\n"
"const int src_offset, __global uchar * lut,\n"
"const int dstStep, const int dst_offset,\n"
"const int2 tileSize, const int tilesX,\n"
"const int clipLimit, const float lutScale)\n"
"{\n"
"__local int smem[512];\n"
"int tx = get_group_id(0);\n"
"int ty = get_group_id(1);\n"
"int tid = get_local_id(1) * get_local_size(0)\n"
"+ get_local_id(0);\n"
"smem[tid] = 0;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"for (int i = get_local_id(1); i < tileSize.y; i += get_local_size(1))\n"
"{\n"
"__global const uchar* srcPtr = src + mad24(ty * tileSize.y + i, srcStep, tx * tileSize.x + src_offset);\n"
"for (int j = get_local_id(0); j < tileSize.x; j += get_local_size(0))\n"
"{\n"
"const int data = srcPtr[j];\n"
"atomic_inc(&smem[data]);\n"
"}\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"int tHistVal = smem[tid];\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (clipLimit > 0)\n"
"{\n"
"int clipped = 0;\n"
"if (tHistVal > clipLimit)\n"
"{\n"
"clipped = tHistVal - clipLimit;\n"
"tHistVal = clipLimit;\n"
"}\n"
"clipped = reduce(smem, clipped, tid);\n"
"int redistBatch = clipped / 256;\n"
"tHistVal += redistBatch;\n"
"int residual = clipped - redistBatch * 256;\n"
"int rStep = 256 / residual;\n"
"if (rStep < 1)\n"
"rStep = 1;\n"
"if (tid%rStep == 0 && (tid/rStep)<residual)\n"
"++tHistVal;\n"
"}\n"
"const int lutVal = calc_lut(smem, tHistVal, tid);\n"
"uint ires = (uint)convert_int_rte(lutScale * lutVal);\n"
"lut[(ty * tilesX + tx) * dstStep + tid + dst_offset] =\n"
"convert_uchar(clamp(ires, (uint)0, (uint)255));\n"
"}\n"
"__kernel void transform(__global __const uchar * src, const int srcStep, const int src_offset,\n"
"__global uchar * dst, const int dstStep, const int dst_offset,\n"
"__global uchar * lut, const int lutStep, int lut_offset,\n"
"const int cols, const int rows,\n"
"const int2 tileSize,\n"
"const int tilesX, const int tilesY)\n"
"{\n"
"const int x = get_global_id(0);\n"
"const int y = get_global_id(1);\n"
"if (x >= cols || y >= rows)\n"
"return;\n"
"const float tyf = (convert_float(y) / tileSize.y) - 0.5f;\n"
"int ty1 = convert_int_rtn(tyf);\n"
"int ty2 = ty1 + 1;\n"
"const float ya = tyf - ty1;\n"
"ty1 = max(ty1, 0);\n"
"ty2 = min(ty2, tilesY - 1);\n"
"const float txf = (convert_float(x) / tileSize.x) - 0.5f;\n"
"int tx1 = convert_int_rtn(txf);\n"
"int tx2 = tx1 + 1;\n"
"const float xa = txf - tx1;\n"
"tx1 = max(tx1, 0);\n"
"tx2 = min(tx2, tilesX - 1);\n"
"const int srcVal = src[mad24(y, srcStep, x + src_offset)];\n"
"float res = 0;\n"
"res += lut[mad24(ty1 * tilesX + tx1, lutStep, srcVal + lut_offset)] * ((1.0f - xa) * (1.0f - ya));\n"
"res += lut[mad24(ty1 * tilesX + tx2, lutStep, srcVal + lut_offset)] * ((xa) * (1.0f - ya));\n"
"res += lut[mad24(ty2 * tilesX + tx1, lutStep, srcVal + lut_offset)] * ((1.0f - xa) * (ya));\n"
"res += lut[mad24(ty2 * tilesX + tx2, lutStep, srcVal + lut_offset)] * ((xa) * (ya));\n"
"uint ires = (uint)convert_int_rte(res);\n"
"dst[mad24(y, dstStep, x + dst_offset)] = convert_uchar(clamp(ires, (uint)0, (uint)255));\n"
"}\n"
, "7399905b8fbf557bd2d5336b25327a7c", NULL};
struct cv::ocl::internal::ProgramEntry color_hsv_oclsrc={moduleName, "color_hsv",
"#if depth == 0\n"
"#define DATA_TYPE uchar\n"
"#define MAX_NUM  255\n"
"#define HALF_MAX_NUM 128\n"
"#define COEFF_TYPE int\n"
"#define SAT_CAST(num) convert_uchar_sat(num)\n"
"#define DEPTH_0\n"
"#elif depth == 2\n"
"#define DATA_TYPE ushort\n"
"#define MAX_NUM  65535\n"
"#define HALF_MAX_NUM 32768\n"
"#define COEFF_TYPE int\n"
"#define SAT_CAST(num) convert_ushort_sat(num)\n"
"#define DEPTH_2\n"
"#elif depth == 5\n"
"#define DATA_TYPE float\n"
"#define MAX_NUM  1.0f\n"
"#define HALF_MAX_NUM 0.5f\n"
"#define COEFF_TYPE float\n"
"#define SAT_CAST(num) (num)\n"
"#define DEPTH_5\n"
"#else\n"
"#error \"invalid depth: should be 0 (CV_8U), 2 (CV_16U) or 5 (CV_32F)\"\n"
"#endif\n"
"#define CV_DESCALE(x,n) (((x) + (1 << ((n)-1))) >> (n))\n"
"enum\n"
"{\n"
"hsv_shift  = 12\n"
"};\n"
"#define scnbytes ((int)sizeof(DATA_TYPE)*scn)\n"
"#define dcnbytes ((int)sizeof(DATA_TYPE)*dcn)\n"
"#ifndef hscale\n"
"#define hscale 0\n"
"#endif\n"
"#ifndef hrange\n"
"#define hrange 0\n"
"#endif\n"
"#if bidx == 0\n"
"#define R_COMP z\n"
"#define G_COMP y\n"
"#define B_COMP x\n"
"#else\n"
"#define R_COMP x\n"
"#define G_COMP y\n"
"#define B_COMP z\n"
"#endif\n"
"__constant int sector_data[][3] = { { 1, 3, 0 },\n"
"{ 1, 0, 2 },\n"
"{ 3, 0, 1 },\n"
"{ 0, 2, 1 },\n"
"{ 0, 1, 3 },\n"
"{ 2, 1, 0 } };\n"
"#ifdef DEPTH_0\n"
"__kernel void RGB2HSV(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols,\n"
"__constant int * sdiv_table, __constant int * hdiv_table)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"uchar4 src_pix = vload4(0, src + src_index);\n"
"int b = src_pix.B_COMP, g = src_pix.G_COMP, r = src_pix.R_COMP;\n"
"int h, s, v = b;\n"
"int vmin = b, diff;\n"
"int vr, vg;\n"
"v = max(v, g);\n"
"v = max(v, r);\n"
"vmin = min(vmin, g);\n"
"vmin = min(vmin, r);\n"
"diff = v - vmin;\n"
"vr = v == r ? -1 : 0;\n"
"vg = v == g ? -1 : 0;\n"
"s = mad24(diff, sdiv_table[v], (1 << (hsv_shift-1))) >> hsv_shift;\n"
"h = (vr & (g - b)) +\n"
"(~vr & ((vg & mad24(diff, 2, b - r)) + ((~vg) & mad24(4, diff, r - g))));\n"
"h = mad24(h, hdiv_table[diff], (1 << (hsv_shift-1))) >> hsv_shift;\n"
"h += h < 0 ? hrange : 0;\n"
"dst[dst_index] = convert_uchar_sat_rte(h);\n"
"dst[dst_index + 1] = (uchar)s;\n"
"dst[dst_index + 2] = (uchar)v;\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void HSV2RGB(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"uchar4 src_pix = vload4(0, src + src_index);\n"
"float h = src_pix.x, s = src_pix.y*(1/255.f), v = src_pix.z*(1/255.f);\n"
"float b, g, r;\n"
"if (s != 0)\n"
"{\n"
"float tab[4];\n"
"int sector;\n"
"h *= hscale;\n"
"if( h < 0 )\n"
"do h += 6; while( h < 0 );\n"
"else if( h >= 6 )\n"
"do h -= 6; while( h >= 6 );\n"
"sector = convert_int_sat_rtn(h);\n"
"h -= sector;\n"
"if( (unsigned)sector >= 6u )\n"
"{\n"
"sector = 0;\n"
"h = 0.f;\n"
"}\n"
"tab[0] = v;\n"
"tab[1] = v*(1.f - s);\n"
"tab[2] = v*(1.f - s*h);\n"
"tab[3] = v*(1.f - s*(1.f - h));\n"
"b = tab[sector_data[sector][0]];\n"
"g = tab[sector_data[sector][1]];\n"
"r = tab[sector_data[sector][2]];\n"
"}\n"
"else\n"
"b = g = r = v;\n"
"dst[dst_index + bidx] = convert_uchar_sat_rte(b*255.f);\n"
"dst[dst_index + 1] = convert_uchar_sat_rte(g*255.f);\n"
"dst[dst_index + (bidx^2)] = convert_uchar_sat_rte(r*255.f);\n"
"#if dcn == 4\n"
"dst[dst_index + 3] = MAX_NUM;\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#elif defined DEPTH_5\n"
"__kernel void RGB2HSV(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const float * src = (__global const float *)(srcptr + src_index);\n"
"__global float * dst = (__global float *)(dstptr + dst_index);\n"
"float4 src_pix = vload4(0, src);\n"
"float b = src_pix.B_COMP, g = src_pix.G_COMP, r = src_pix.R_COMP;\n"
"float h, s, v;\n"
"float vmin, diff;\n"
"v = vmin = r;\n"
"if( v < g ) v = g;\n"
"if( v < b ) v = b;\n"
"if( vmin > g ) vmin = g;\n"
"if( vmin > b ) vmin = b;\n"
"diff = v - vmin;\n"
"s = diff/(float)(fabs(v) + FLT_EPSILON);\n"
"diff = (float)(60.f/(diff + FLT_EPSILON));\n"
"if( v == r )\n"
"h = (g - b)*diff;\n"
"else if( v == g )\n"
"h = fma(b - r, diff, 120.f);\n"
"else\n"
"h = fma(r - g, diff, 240.f);\n"
"if( h < 0 )\n"
"h += 360.f;\n"
"dst[0] = h*hscale;\n"
"dst[1] = s;\n"
"dst[2] = v;\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void HSV2RGB(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const float * src = (__global const float *)(srcptr + src_index);\n"
"__global float * dst = (__global float *)(dstptr + dst_index);\n"
"float4 src_pix = vload4(0, src);\n"
"float h = src_pix.x, s = src_pix.y, v = src_pix.z;\n"
"float b, g, r;\n"
"if (s != 0)\n"
"{\n"
"float tab[4];\n"
"int sector;\n"
"h *= hscale;\n"
"if(h < 0)\n"
"do h += 6; while (h < 0);\n"
"else if (h >= 6)\n"
"do h -= 6; while (h >= 6);\n"
"sector = convert_int_sat_rtn(h);\n"
"h -= sector;\n"
"if ((unsigned)sector >= 6u)\n"
"{\n"
"sector = 0;\n"
"h = 0.f;\n"
"}\n"
"tab[0] = v;\n"
"tab[1] = v*(1.f - s);\n"
"tab[2] = v*(1.f - s*h);\n"
"tab[3] = v*(1.f - s*(1.f - h));\n"
"b = tab[sector_data[sector][0]];\n"
"g = tab[sector_data[sector][1]];\n"
"r = tab[sector_data[sector][2]];\n"
"}\n"
"else\n"
"b = g = r = v;\n"
"dst[bidx] = b;\n"
"dst[1] = g;\n"
"dst[bidx^2] = r;\n"
"#if dcn == 4\n"
"dst[3] = MAX_NUM;\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
"#ifdef DEPTH_0\n"
"__kernel void RGB2HLS(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"uchar4 src_pix = vload4(0, src + src_index);\n"
"float b = src_pix.B_COMP*(1/255.f), g = src_pix.G_COMP*(1/255.f), r = src_pix.R_COMP*(1/255.f);\n"
"float h = 0.f, s = 0.f, l;\n"
"float vmin, vmax, diff;\n"
"vmax = vmin = r;\n"
"if (vmax < g) vmax = g;\n"
"if (vmax < b) vmax = b;\n"
"if (vmin > g) vmin = g;\n"
"if (vmin > b) vmin = b;\n"
"diff = vmax - vmin;\n"
"l = (vmax + vmin)*0.5f;\n"
"if (diff > FLT_EPSILON)\n"
"{\n"
"s = l < 0.5f ? diff/(vmax + vmin) : diff/(2 - vmax - vmin);\n"
"diff = 60.f/diff;\n"
"if( vmax == r )\n"
"h = (g - b)*diff;\n"
"else if( vmax == g )\n"
"h = fma(b - r, diff, 120.f);\n"
"else\n"
"h = fma(r - g, diff, 240.f);\n"
"if( h < 0.f )\n"
"h += 360.f;\n"
"}\n"
"dst[dst_index] = convert_uchar_sat_rte(h*hscale);\n"
"dst[dst_index + 1] = convert_uchar_sat_rte(l*255.f);\n"
"dst[dst_index + 2] = convert_uchar_sat_rte(s*255.f);\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void HLS2RGB(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"uchar4 src_pix = vload4(0, src + src_index);\n"
"float h = src_pix.x, l = src_pix.y*(1.f/255.f), s = src_pix.z*(1.f/255.f);\n"
"float b, g, r;\n"
"if (s != 0)\n"
"{\n"
"float tab[4];\n"
"float p2 = l <= 0.5f ? l*(1 + s) : l + s - l*s;\n"
"float p1 = 2*l - p2;\n"
"h *= hscale;\n"
"if( h < 0 )\n"
"do h += 6; while( h < 0 );\n"
"else if( h >= 6 )\n"
"do h -= 6; while( h >= 6 );\n"
"int sector = convert_int_sat_rtn(h);\n"
"h -= sector;\n"
"tab[0] = p2;\n"
"tab[1] = p1;\n"
"tab[2] = fma(p2 - p1, 1-h, p1);\n"
"tab[3] = fma(p2 - p1, h, p1);\n"
"b = tab[sector_data[sector][0]];\n"
"g = tab[sector_data[sector][1]];\n"
"r = tab[sector_data[sector][2]];\n"
"}\n"
"else\n"
"b = g = r = l;\n"
"dst[dst_index + bidx] = convert_uchar_sat_rte(b*255.f);\n"
"dst[dst_index + 1] = convert_uchar_sat_rte(g*255.f);\n"
"dst[dst_index + (bidx^2)] = convert_uchar_sat_rte(r*255.f);\n"
"#if dcn == 4\n"
"dst[dst_index + 3] = MAX_NUM;\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#elif defined DEPTH_5\n"
"__kernel void RGB2HLS(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const float * src = (__global const float *)(srcptr + src_index);\n"
"__global float * dst = (__global float *)(dstptr + dst_index);\n"
"float4 src_pix = vload4(0, src);\n"
"float b = src_pix.B_COMP, g = src_pix.G_COMP, r = src_pix.R_COMP;\n"
"float h = 0.f, s = 0.f, l;\n"
"float vmin, vmax, diff;\n"
"vmax = vmin = r;\n"
"if (vmax < g) vmax = g;\n"
"if (vmax < b) vmax = b;\n"
"if (vmin > g) vmin = g;\n"
"if (vmin > b) vmin = b;\n"
"diff = vmax - vmin;\n"
"l = (vmax + vmin)*0.5f;\n"
"if (diff > FLT_EPSILON)\n"
"{\n"
"s = l < 0.5f ? diff/(vmax + vmin) : diff/(2 - vmax - vmin);\n"
"diff = 60.f/diff;\n"
"if( vmax == r )\n"
"h = (g - b)*diff;\n"
"else if( vmax == g )\n"
"h = fma(b - r, diff, 120.f);\n"
"else\n"
"h = fma(r - g, diff, 240.f);\n"
"if( h < 0.f ) h += 360.f;\n"
"}\n"
"dst[0] = h*hscale;\n"
"dst[1] = l;\n"
"dst[2] = s;\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void HLS2RGB(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const float * src = (__global const float *)(srcptr + src_index);\n"
"__global float * dst = (__global float *)(dstptr + dst_index);\n"
"float4 src_pix = vload4(0, src);\n"
"float h = src_pix.x, l = src_pix.y, s = src_pix.z;\n"
"float b, g, r;\n"
"if (s != 0)\n"
"{\n"
"float tab[4];\n"
"int sector;\n"
"float p2 = l <= 0.5f ? l*(1 + s) : l + s - l*s;\n"
"float p1 = 2*l - p2;\n"
"h *= hscale;\n"
"if( h < 0 )\n"
"do h += 6; while( h < 0 );\n"
"else if( h >= 6 )\n"
"do h -= 6; while( h >= 6 );\n"
"sector = convert_int_sat_rtn(h);\n"
"h -= sector;\n"
"tab[0] = p2;\n"
"tab[1] = p1;\n"
"tab[2] = fma(p2 - p1, 1-h, p1);\n"
"tab[3] = fma(p2 - p1, h, p1);\n"
"b = tab[sector_data[sector][0]];\n"
"g = tab[sector_data[sector][1]];\n"
"r = tab[sector_data[sector][2]];\n"
"}\n"
"else\n"
"b = g = r = l;\n"
"dst[bidx] = b;\n"
"dst[1] = g;\n"
"dst[bidx^2] = r;\n"
"#if dcn == 4\n"
"dst[3] = MAX_NUM;\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
, "7a58346cde62814d89c0233200848842", NULL};
struct cv::ocl::internal::ProgramEntry color_lab_oclsrc={moduleName, "color_lab",
"#if depth == 0\n"
"#define DATA_TYPE uchar\n"
"#define MAX_NUM  255\n"
"#define HALF_MAX_NUM 128\n"
"#define COEFF_TYPE int\n"
"#define SAT_CAST(num) convert_uchar_sat(num)\n"
"#define DEPTH_0\n"
"#elif depth == 2\n"
"#define DATA_TYPE ushort\n"
"#define MAX_NUM  65535\n"
"#define HALF_MAX_NUM 32768\n"
"#define COEFF_TYPE int\n"
"#define SAT_CAST(num) convert_ushort_sat(num)\n"
"#define DEPTH_2\n"
"#elif depth == 5\n"
"#define DATA_TYPE float\n"
"#define MAX_NUM  1.0f\n"
"#define HALF_MAX_NUM 0.5f\n"
"#define COEFF_TYPE float\n"
"#define SAT_CAST(num) (num)\n"
"#define DEPTH_5\n"
"#else\n"
"#error \"invalid depth: should be 0 (CV_8U), 2 (CV_16U) or 5 (CV_32F)\"\n"
"#endif\n"
"#define CV_DESCALE(x,n) (((x) + (1 << ((n)-1))) >> (n))\n"
"enum\n"
"{\n"
"xyz_shift  = 12,\n"
"};\n"
"#define scnbytes ((int)sizeof(DATA_TYPE)*scn)\n"
"#define dcnbytes ((int)sizeof(DATA_TYPE)*dcn)\n"
"#define __CAT(x, y) x##y\n"
"#define CAT(x, y) __CAT(x, y)\n"
"#define DATA_TYPE_4 CAT(DATA_TYPE, 4)\n"
"#define DATA_TYPE_3 CAT(DATA_TYPE, 3)\n"
"__kernel void RGB2XYZ(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols, __constant COEFF_TYPE * coeffs)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (dx < cols)\n"
"{\n"
"int src_index = mad24(dy, src_step, mad24(dx, scnbytes, src_offset));\n"
"int dst_index = mad24(dy, dst_step, mad24(dx, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (dy < rows)\n"
"{\n"
"__global const DATA_TYPE * src = (__global const DATA_TYPE *)(srcptr + src_index);\n"
"__global DATA_TYPE * dst = (__global DATA_TYPE *)(dstptr + dst_index);\n"
"DATA_TYPE_4 src_pix = vload4(0, src);\n"
"DATA_TYPE r = src_pix.x, g = src_pix.y, b = src_pix.z;\n"
"#ifdef DEPTH_5\n"
"float x = fma(r, coeffs[0], fma(g, coeffs[1], b * coeffs[2]));\n"
"float y = fma(r, coeffs[3], fma(g, coeffs[4], b * coeffs[5]));\n"
"float z = fma(r, coeffs[6], fma(g, coeffs[7], b * coeffs[8]));\n"
"#else\n"
"int x = CV_DESCALE(mad24(r, coeffs[0], mad24(g, coeffs[1], b * coeffs[2])), xyz_shift);\n"
"int y = CV_DESCALE(mad24(r, coeffs[3], mad24(g, coeffs[4], b * coeffs[5])), xyz_shift);\n"
"int z = CV_DESCALE(mad24(r, coeffs[6], mad24(g, coeffs[7], b * coeffs[8])), xyz_shift);\n"
"#endif\n"
"dst[0] = SAT_CAST(x);\n"
"dst[1] = SAT_CAST(y);\n"
"dst[2] = SAT_CAST(z);\n"
"++dy;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void XYZ2RGB(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols, __constant COEFF_TYPE * coeffs)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (dx < cols)\n"
"{\n"
"int src_index = mad24(dy, src_step, mad24(dx, scnbytes, src_offset));\n"
"int dst_index = mad24(dy, dst_step, mad24(dx, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (dy < rows)\n"
"{\n"
"__global const DATA_TYPE * src = (__global const DATA_TYPE *)(srcptr + src_index);\n"
"__global DATA_TYPE * dst = (__global DATA_TYPE *)(dstptr + dst_index);\n"
"DATA_TYPE_4 src_pix = vload4(0, src);\n"
"DATA_TYPE x = src_pix.x, y = src_pix.y, z = src_pix.z;\n"
"#ifdef DEPTH_5\n"
"float b = fma(x, coeffs[0], fma(y, coeffs[1], z * coeffs[2]));\n"
"float g = fma(x, coeffs[3], fma(y, coeffs[4], z * coeffs[5]));\n"
"float r = fma(x, coeffs[6], fma(y, coeffs[7], z * coeffs[8]));\n"
"#else\n"
"int b = CV_DESCALE(mad24(x, coeffs[0], mad24(y, coeffs[1], z * coeffs[2])), xyz_shift);\n"
"int g = CV_DESCALE(mad24(x, coeffs[3], mad24(y, coeffs[4], z * coeffs[5])), xyz_shift);\n"
"int r = CV_DESCALE(mad24(x, coeffs[6], mad24(y, coeffs[7], z * coeffs[8])), xyz_shift);\n"
"#endif\n"
"DATA_TYPE dst0 = SAT_CAST(b);\n"
"DATA_TYPE dst1 = SAT_CAST(g);\n"
"DATA_TYPE dst2 = SAT_CAST(r);\n"
"#if dcn == 3 || defined DEPTH_5\n"
"dst[0] = dst0;\n"
"dst[1] = dst1;\n"
"dst[2] = dst2;\n"
"#if dcn == 4\n"
"dst[3] = MAX_NUM;\n"
"#endif\n"
"#else\n"
"*(__global DATA_TYPE_4 *)dst = (DATA_TYPE_4)(dst0, dst1, dst2, MAX_NUM);\n"
"#endif\n"
"++dy;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#define lab_shift xyz_shift\n"
"#define gamma_shift 3\n"
"#define lab_shift2 (lab_shift + gamma_shift)\n"
"#define GAMMA_TAB_SIZE 1024\n"
"#define GammaTabScale (float)GAMMA_TAB_SIZE\n"
"inline float splineInterpolate(float x, __global const float * tab, int n)\n"
"{\n"
"int ix = clamp(convert_int_sat_rtn(x), 0, n-1);\n"
"x -= ix;\n"
"tab += ix << 2;\n"
"return fma(fma(fma(tab[3], x, tab[2]), x, tab[1]), x, tab[0]);\n"
"}\n"
"#ifdef DEPTH_0\n"
"__kernel void BGR2Lab(__global const uchar * src, int src_step, int src_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int rows, int cols,\n"
"__global const ushort * gammaTab, __global ushort * LabCbrtTab_b,\n"
"__constant int * coeffs, int Lscale, int Lshift)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const uchar* src_ptr = src + src_index;\n"
"__global uchar* dst_ptr = dst + dst_index;\n"
"uchar4 src_pix = vload4(0, src_ptr);\n"
"int C0 = coeffs[0], C1 = coeffs[1], C2 = coeffs[2],\n"
"C3 = coeffs[3], C4 = coeffs[4], C5 = coeffs[5],\n"
"C6 = coeffs[6], C7 = coeffs[7], C8 = coeffs[8];\n"
"int R = gammaTab[src_pix.x], G = gammaTab[src_pix.y], B = gammaTab[src_pix.z];\n"
"int fX = LabCbrtTab_b[CV_DESCALE(mad24(R, C0, mad24(G, C1, B*C2)), lab_shift)];\n"
"int fY = LabCbrtTab_b[CV_DESCALE(mad24(R, C3, mad24(G, C4, B*C5)), lab_shift)];\n"
"int fZ = LabCbrtTab_b[CV_DESCALE(mad24(R, C6, mad24(G, C7, B*C8)), lab_shift)];\n"
"int L = CV_DESCALE( Lscale*fY + Lshift, lab_shift2 );\n"
"int a = CV_DESCALE( mad24(500, fX - fY, 128*(1 << lab_shift2)), lab_shift2 );\n"
"int b = CV_DESCALE( mad24(200, fY - fZ, 128*(1 << lab_shift2)), lab_shift2 );\n"
"dst_ptr[0] = SAT_CAST(L);\n"
"dst_ptr[1] = SAT_CAST(a);\n"
"dst_ptr[2] = SAT_CAST(b);\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#elif defined DEPTH_5\n"
"__kernel void BGR2Lab(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int rows, int cols,\n"
"#ifdef SRGB\n"
"__global const float * gammaTab,\n"
"#endif\n"
"__constant float * coeffs, float _1_3, float _a)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const float * src = (__global const float *)(srcptr + src_index);\n"
"__global float * dst = (__global float *)(dstptr + dst_index);\n"
"float4 src_pix = vload4(0, src);\n"
"float C0 = coeffs[0], C1 = coeffs[1], C2 = coeffs[2],\n"
"C3 = coeffs[3], C4 = coeffs[4], C5 = coeffs[5],\n"
"C6 = coeffs[6], C7 = coeffs[7], C8 = coeffs[8];\n"
"float R = clamp(src_pix.x, 0.0f, 1.0f);\n"
"float G = clamp(src_pix.y, 0.0f, 1.0f);\n"
"float B = clamp(src_pix.z, 0.0f, 1.0f);\n"
"#ifdef SRGB\n"
"R = splineInterpolate(R * GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"G = splineInterpolate(G * GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"B = splineInterpolate(B * GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"#endif\n"
"float X = fma(R, C0, fma(G, C1, B*C2));\n"
"float Y = fma(R, C3, fma(G, C4, B*C5));\n"
"float Z = fma(R, C6, fma(G, C7, B*C8));\n"
"float FX = X > 0.008856f ? rootn(X, 3) : fma(7.787f, X, _a);\n"
"float FY = Y > 0.008856f ? rootn(Y, 3) : fma(7.787f, Y, _a);\n"
"float FZ = Z > 0.008856f ? rootn(Z, 3) : fma(7.787f, Z, _a);\n"
"float L = Y > 0.008856f ? fma(116.f, FY, -16.f) : (903.3f * Y);\n"
"float a = 500.f * (FX - FY);\n"
"float b = 200.f * (FY - FZ);\n"
"dst[0] = L;\n"
"dst[1] = a;\n"
"dst[2] = b;\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
"inline void Lab2BGR_f(const float * srcbuf, float * dstbuf,\n"
"#ifdef SRGB\n"
"__global const float * gammaTab,\n"
"#endif\n"
"__constant float * coeffs, float lThresh, float fThresh)\n"
"{\n"
"float li = srcbuf[0], ai = srcbuf[1], bi = srcbuf[2];\n"
"float C0 = coeffs[0], C1 = coeffs[1], C2 = coeffs[2],\n"
"C3 = coeffs[3], C4 = coeffs[4], C5 = coeffs[5],\n"
"C6 = coeffs[6], C7 = coeffs[7], C8 = coeffs[8];\n"
"float y, fy;\n"
"if (li <= lThresh)\n"
"{\n"
"y = li / 903.3f;\n"
"fy = fma(7.787f, y, 16.0f / 116.0f);\n"
"}\n"
"else\n"
"{\n"
"fy = (li + 16.0f) / 116.0f;\n"
"y = fy * fy * fy;\n"
"}\n"
"float fxz[] = { ai / 500.0f + fy, fy - bi / 200.0f };\n"
"#pragma unroll\n"
"for (int j = 0; j < 2; j++)\n"
"if (fxz[j] <= fThresh)\n"
"fxz[j] = (fxz[j] - 16.0f / 116.0f) / 7.787f;\n"
"else\n"
"fxz[j] = fxz[j] * fxz[j] * fxz[j];\n"
"float x = fxz[0], z = fxz[1];\n"
"float ro = clamp(fma(C0, x, fma(C1, y, C2 * z)), 0.0f, 1.0f);\n"
"float go = clamp(fma(C3, x, fma(C4, y, C5 * z)), 0.0f, 1.0f);\n"
"float bo = clamp(fma(C6, x, fma(C7, y, C8 * z)), 0.0f, 1.0f);\n"
"#ifdef SRGB\n"
"ro = splineInterpolate(ro * GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"go = splineInterpolate(go * GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"bo = splineInterpolate(bo * GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"#endif\n"
"dstbuf[0] = ro, dstbuf[1] = go, dstbuf[2] = bo;\n"
"}\n"
"#ifdef DEPTH_0\n"
"__kernel void Lab2BGR(__global const uchar * src, int src_step, int src_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int rows, int cols,\n"
"#ifdef SRGB\n"
"__global const float * gammaTab,\n"
"#endif\n"
"__constant float * coeffs, float lThresh, float fThresh)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const uchar* src_ptr = src + src_index;\n"
"__global uchar * dst_ptr = dst + dst_index;\n"
"uchar4 src_pix = vload4(0, src_ptr);\n"
"float srcbuf[3], dstbuf[3];\n"
"srcbuf[0] = src_pix.x*(100.f/255.f);\n"
"srcbuf[1] = convert_float(src_pix.y - 128);\n"
"srcbuf[2] = convert_float(src_pix.z - 128);\n"
"Lab2BGR_f(&srcbuf[0], &dstbuf[0],\n"
"#ifdef SRGB\n"
"gammaTab,\n"
"#endif\n"
"coeffs, lThresh, fThresh);\n"
"#if dcn == 3\n"
"dst_ptr[0] = SAT_CAST(dstbuf[0] * 255.0f);\n"
"dst_ptr[1] = SAT_CAST(dstbuf[1] * 255.0f);\n"
"dst_ptr[2] = SAT_CAST(dstbuf[2] * 255.0f);\n"
"#else\n"
"*(__global uchar4 *)dst_ptr = (uchar4)(SAT_CAST(dstbuf[0] * 255.0f),\n"
"SAT_CAST(dstbuf[1] * 255.0f), SAT_CAST(dstbuf[2] * 255.0f), MAX_NUM);\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#elif defined DEPTH_5\n"
"__kernel void Lab2BGR(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int rows, int cols,\n"
"#ifdef SRGB\n"
"__global const float * gammaTab,\n"
"#endif\n"
"__constant float * coeffs, float lThresh, float fThresh)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const float * src = (__global const float *)(srcptr + src_index);\n"
"__global float * dst = (__global float *)(dstptr + dst_index);\n"
"float4 src_pix = vload4(0, src);\n"
"float srcbuf[3], dstbuf[3];\n"
"srcbuf[0] = src_pix.x, srcbuf[1] = src_pix.y, srcbuf[2] = src_pix.z;\n"
"Lab2BGR_f(&srcbuf[0], &dstbuf[0],\n"
"#ifdef SRGB\n"
"gammaTab,\n"
"#endif\n"
"coeffs, lThresh, fThresh);\n"
"dst[0] = dstbuf[0], dst[1] = dstbuf[1], dst[2] = dstbuf[2];\n"
"#if dcn == 4\n"
"dst[3] = MAX_NUM;\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
"#define LAB_CBRT_TAB_SIZE 1024\n"
"#define LAB_CBRT_TAB_SIZE_B (256*3/2*(1<<gamma_shift))\n"
"__constant float LabCbrtTabScale = LAB_CBRT_TAB_SIZE/1.5f;\n"
"#ifdef DEPTH_5\n"
"__kernel void BGR2Luv(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int rows, int cols,\n"
"#ifdef SRGB\n"
"__global const float * gammaTab,\n"
"#endif\n"
"__global const float * LabCbrtTab, __constant float * coeffs, float _un, float _vn)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"if (y < rows)\n"
"{\n"
"__global const float * src = (__global const float *)(srcptr + src_index);\n"
"__global float * dst = (__global float *)(dstptr + dst_index);\n"
"float R = src[0], G = src[1], B = src[2];\n"
"R = clamp(R, 0.f, 1.f);\n"
"G = clamp(G, 0.f, 1.f);\n"
"B = clamp(B, 0.f, 1.f);\n"
"#ifdef SRGB\n"
"R = splineInterpolate(R*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"G = splineInterpolate(G*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"B = splineInterpolate(B*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"#endif\n"
"float X = fma(R, coeffs[0], fma(G, coeffs[1], B*coeffs[2]));\n"
"float Y = fma(R, coeffs[3], fma(G, coeffs[4], B*coeffs[5]));\n"
"float Z = fma(R, coeffs[6], fma(G, coeffs[7], B*coeffs[8]));\n"
"float L = splineInterpolate(Y*LabCbrtTabScale, LabCbrtTab, LAB_CBRT_TAB_SIZE);\n"
"L = fma(116.f, L, -16.f);\n"
"float d = 52.0f / fmax(fma(15.0f, Y, fma(3.0f, Z, X)), FLT_EPSILON);\n"
"float u = L*fma(X, d, -_un);\n"
"float v = L*fma(2.25f, Y*d, -_vn);\n"
"dst[0] = L;\n"
"dst[1] = u;\n"
"dst[2] = v;\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"#elif defined DEPTH_0\n"
"__kernel void BGR2Luv(__global const uchar * src, int src_step, int src_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int rows, int cols,\n"
"#ifdef SRGB\n"
"__global const float * gammaTab,\n"
"#endif\n"
"__global const float * LabCbrtTab, __constant float * coeffs, float _un, float _vn)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"src += mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"dst += mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"if (y < rows)\n"
"{\n"
"float scale = 1.0f / 255.0f;\n"
"float R = src[0]*scale, G = src[1]*scale, B = src[2]*scale;\n"
"#ifdef SRGB\n"
"R = splineInterpolate(R*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"G = splineInterpolate(G*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"B = splineInterpolate(B*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"#endif\n"
"float X = fma(R, coeffs[0], fma(G, coeffs[1], B*coeffs[2]));\n"
"float Y = fma(R, coeffs[3], fma(G, coeffs[4], B*coeffs[5]));\n"
"float Z = fma(R, coeffs[6], fma(G, coeffs[7], B*coeffs[8]));\n"
"float L = splineInterpolate(Y*LabCbrtTabScale, LabCbrtTab, LAB_CBRT_TAB_SIZE);\n"
"L = 116.f*L - 16.f;\n"
"float d = (4*13) / fmax(fma(15.0f, Y, fma(3.0f, Z, X)), FLT_EPSILON);\n"
"float u = L*(X*d - _un);\n"
"float v = L*fma(2.25f, Y*d, -_vn);\n"
"dst[0] = SAT_CAST(L * 2.55f);\n"
"dst[1] = SAT_CAST(fma(u, 0.72033898305084743f, 96.525423728813564f));\n"
"dst[2] = SAT_CAST(fma(v, 0.9732824427480916f, 136.259541984732824f));\n"
"++y;\n"
"dst += dst_step;\n"
"src += src_step;\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
"#ifdef DEPTH_5\n"
"__kernel void Luv2BGR(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int rows, int cols,\n"
"#ifdef SRGB\n"
"__global const float * gammaTab,\n"
"#endif\n"
"__constant float * coeffs, float _un, float _vn)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"if (y < rows)\n"
"{\n"
"__global const float * src = (__global const float *)(srcptr + src_index);\n"
"__global float * dst = (__global float *)(dstptr + dst_index);\n"
"float L = src[0], u = src[1], v = src[2], X, Y, Z;\n"
"if(L >= 8)\n"
"{\n"
"Y = fma(L, 1.f/116.f, 16.f/116.f);\n"
"Y = Y*Y*Y;\n"
"}\n"
"else\n"
"{\n"
"Y = L * (1.0f/903.3f);\n"
"}\n"
"float up = 3.f*fma(L, _un, u);\n"
"float vp = 0.25f/fma(L, _vn, v);\n"
"vp = clamp(vp, -0.25f, 0.25f);\n"
"X = 3.f*Y*up*vp;\n"
"Z = Y*fma(fma(12.f*13.f, L, -up), vp, -5.f);\n"
"float R = fma(X, coeffs[0], fma(Y, coeffs[1], Z * coeffs[2]));\n"
"float G = fma(X, coeffs[3], fma(Y, coeffs[4], Z * coeffs[5]));\n"
"float B = fma(X, coeffs[6], fma(Y, coeffs[7], Z * coeffs[8]));\n"
"R = clamp(R, 0.f, 1.f);\n"
"G = clamp(G, 0.f, 1.f);\n"
"B = clamp(B, 0.f, 1.f);\n"
"#ifdef SRGB\n"
"R = splineInterpolate(R*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"G = splineInterpolate(G*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"B = splineInterpolate(B*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"#endif\n"
"dst[0] = R;\n"
"dst[1] = G;\n"
"dst[2] = B;\n"
"#if dcn == 4\n"
"dst[3] = MAX_NUM;\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"#elif defined DEPTH_0\n"
"__kernel void Luv2BGR(__global const uchar * src, int src_step, int src_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int rows, int cols,\n"
"#ifdef SRGB\n"
"__global const float * gammaTab,\n"
"#endif\n"
"__constant float * coeffs, float _un, float _vn)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"src += mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"dst += mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"if (y < rows)\n"
"{\n"
"float d, X, Y, Z;\n"
"float L = src[0]*(100.f/255.f);\n"
"float u = fma(convert_float(src[1]), 1.388235294117647f, -134.f);\n"
"float v = fma(convert_float(src[2]), 1.027450980392157f, - 140.f);\n"
"if(L >= 8)\n"
"{\n"
"Y = fma(L, 1.f/116.f, 16.f/116.f);\n"
"Y = Y*Y*Y;\n"
"}\n"
"else\n"
"{\n"
"Y = L * (1.0f/903.3f);\n"
"}\n"
"float up = 3.f*fma(L, _un, u);\n"
"float vp = 0.25f/fma(L, _vn, v);\n"
"vp = clamp(vp, -0.25f, 0.25f);\n"
"X = 3.f*Y*up*vp;\n"
"Z = Y*fma(fma(12.f*13.f, L, -up), vp, -5.f);\n"
"X = clamp(X, 0.f, 2.f); Z = clamp(Z, 0.f, 2.f);\n"
"float R = fma(X, coeffs[0], fma(Y, coeffs[1], Z * coeffs[2]));\n"
"float G = fma(X, coeffs[3], fma(Y, coeffs[4], Z * coeffs[5]));\n"
"float B = fma(X, coeffs[6], fma(Y, coeffs[7], Z * coeffs[8]));\n"
"R = clamp(R, 0.f, 1.f);\n"
"G = clamp(G, 0.f, 1.f);\n"
"B = clamp(B, 0.f, 1.f);\n"
"#ifdef SRGB\n"
"R = splineInterpolate(R*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"G = splineInterpolate(G*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"B = splineInterpolate(B*GammaTabScale, gammaTab, GAMMA_TAB_SIZE);\n"
"#endif\n"
"uchar dst0 = SAT_CAST(R * 255.0f);\n"
"uchar dst1 = SAT_CAST(G * 255.0f);\n"
"uchar dst2 = SAT_CAST(B * 255.0f);\n"
"#if dcn == 4\n"
"*(__global uchar4 *)dst = (uchar4)(dst0, dst1, dst2, MAX_NUM);\n"
"#else\n"
"dst[0] = dst0;\n"
"dst[1] = dst1;\n"
"dst[2] = dst2;\n"
"#endif\n"
"++y;\n"
"dst += dst_step;\n"
"src += src_step;\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
, "5321f879afd5057810f4e7d4db9b2e78", NULL};
struct cv::ocl::internal::ProgramEntry color_rgb_oclsrc={moduleName, "color_rgb",
"#if depth == 0\n"
"#define DATA_TYPE uchar\n"
"#define MAX_NUM  255\n"
"#define HALF_MAX_NUM 128\n"
"#define COEFF_TYPE int\n"
"#define SAT_CAST(num) convert_uchar_sat(num)\n"
"#define DEPTH_0\n"
"#elif depth == 2\n"
"#define DATA_TYPE ushort\n"
"#define MAX_NUM  65535\n"
"#define HALF_MAX_NUM 32768\n"
"#define COEFF_TYPE int\n"
"#define SAT_CAST(num) convert_ushort_sat(num)\n"
"#define DEPTH_2\n"
"#elif depth == 5\n"
"#define DATA_TYPE float\n"
"#define MAX_NUM  1.0f\n"
"#define HALF_MAX_NUM 0.5f\n"
"#define COEFF_TYPE float\n"
"#define SAT_CAST(num) (num)\n"
"#define DEPTH_5\n"
"#else\n"
"#error \"invalid depth: should be 0 (CV_8U), 2 (CV_16U) or 5 (CV_32F)\"\n"
"#endif\n"
"#define CV_DESCALE(x,n) (((x) + (1 << ((n)-1))) >> (n))\n"
"enum\n"
"{\n"
"gray_shift = 15,\n"
"RY15 = 9798,\n"
"GY15 = 19235,\n"
"BY15 = 3735\n"
"};\n"
"#define B2YF 0.114f\n"
"#define G2YF 0.587f\n"
"#define R2YF 0.299f\n"
"#define scnbytes ((int)sizeof(DATA_TYPE)*scn)\n"
"#define dcnbytes ((int)sizeof(DATA_TYPE)*dcn)\n"
"#if bidx == 0\n"
"#define R_COMP z\n"
"#define G_COMP y\n"
"#define B_COMP x\n"
"#else\n"
"#define R_COMP x\n"
"#define G_COMP y\n"
"#define B_COMP z\n"
"#endif\n"
"#define __CAT(x, y) x##y\n"
"#define CAT(x, y) __CAT(x, y)\n"
"#define DATA_TYPE_4 CAT(DATA_TYPE, 4)\n"
"#define DATA_TYPE_3 CAT(DATA_TYPE, 3)\n"
"__kernel void RGB2Gray(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const DATA_TYPE* src = (__global const DATA_TYPE*)(srcptr + src_index);\n"
"__global DATA_TYPE* dst = (__global DATA_TYPE*)(dstptr + dst_index);\n"
"DATA_TYPE_3 src_pix = vload3(0, src);\n"
"#ifdef DEPTH_5\n"
"dst[0] = fma(src_pix.B_COMP, B2YF, fma(src_pix.G_COMP, G2YF, src_pix.R_COMP * R2YF));\n"
"#else\n"
"dst[0] = (DATA_TYPE)CV_DESCALE(mad24(src_pix.B_COMP, BY15, mad24(src_pix.G_COMP, GY15, mul24(src_pix.R_COMP, RY15))), gray_shift);\n"
"#endif\n"
"++y;\n"
"src_index += src_step;\n"
"dst_index += dst_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void Gray2RGB(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const DATA_TYPE* src = (__global const DATA_TYPE*)(srcptr + src_index);\n"
"__global DATA_TYPE* dst = (__global DATA_TYPE*)(dstptr + dst_index);\n"
"DATA_TYPE val = src[0];\n"
"#if dcn == 3 || defined DEPTH_5\n"
"dst[0] = dst[1] = dst[2] = val;\n"
"#if dcn == 4\n"
"dst[3] = MAX_NUM;\n"
"#endif\n"
"#else\n"
"*(__global DATA_TYPE_4 *)dst = (DATA_TYPE_4)(val, val, val, MAX_NUM);\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void RGB(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const DATA_TYPE * src = (__global const DATA_TYPE *)(srcptr + src_index);\n"
"__global DATA_TYPE * dst = (__global DATA_TYPE *)(dstptr + dst_index);\n"
"#if scn == 3\n"
"DATA_TYPE_3 src_pix = vload3(0, src);\n"
"#else\n"
"DATA_TYPE_4 src_pix = vload4(0, src);\n"
"#endif\n"
"#ifdef REVERSE\n"
"dst[0] = src_pix.z;\n"
"dst[1] = src_pix.y;\n"
"dst[2] = src_pix.x;\n"
"#else\n"
"dst[0] = src_pix.x;\n"
"dst[1] = src_pix.y;\n"
"dst[2] = src_pix.z;\n"
"#endif\n"
"#if dcn == 4\n"
"#if scn == 3\n"
"dst[3] = MAX_NUM;\n"
"#else\n"
"dst[3] = src[3];\n"
"#endif\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void RGB5x52RGB(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"ushort t = *((__global const ushort*)(src + src_index));\n"
"#if greenbits == 6\n"
"dst[dst_index + bidx] = (uchar)(t << 3);\n"
"dst[dst_index + 1] = (uchar)((t >> 3) & ~3);\n"
"dst[dst_index + (bidx^2)] = (uchar)((t >> 8) & ~7);\n"
"#else\n"
"dst[dst_index + bidx] = (uchar)(t << 3);\n"
"dst[dst_index + 1] = (uchar)((t >> 2) & ~7);\n"
"dst[dst_index + (bidx^2)] = (uchar)((t >> 7) & ~7);\n"
"#endif\n"
"#if dcn == 4\n"
"#if greenbits == 6\n"
"dst[dst_index + 3] = 255;\n"
"#else\n"
"dst[dst_index + 3] = t & 0x8000 ? 255 : 0;\n"
"#endif\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void RGB2RGB5x5(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"uchar4 src_pix = vload4(0, src + src_index);\n"
"#if greenbits == 6\n"
"*((__global ushort*)(dst + dst_index)) = (ushort)((src_pix.B_COMP >> 3)|((src_pix.G_COMP&~3) << 3)|((src_pix.R_COMP&~7) << 8));\n"
"#elif scn == 3\n"
"*((__global ushort*)(dst + dst_index)) = (ushort)((src_pix.B_COMP >> 3)|((src_pix.G_COMP&~7) << 2)|((src_pix.R_COMP&~7) << 7));\n"
"#else\n"
"*((__global ushort*)(dst + dst_index)) = (ushort)((src_pix.B_COMP >> 3)|((src_pix.G_COMP&~7) << 2)|\n"
"((src_pix.R_COMP&~7) << 7)|(src_pix.w ? 0x8000 : 0));\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void BGR5x52Gray(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, dst_offset + x);\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"int t = *((__global const ushort*)(src + src_index));\n"
"#if greenbits == 6\n"
"dst[dst_index] = (uchar)CV_DESCALE(mad24((t << 3) & 0xf8, BY15, mad24((t >> 3) & 0xfc, GY15, ((t >> 8) & 0xf8) * RY15)), gray_shift);\n"
"#else\n"
"dst[dst_index] = (uchar)CV_DESCALE(mad24((t << 3) & 0xf8, BY15, mad24((t >> 2) & 0xf8, GY15, ((t >> 7) & 0xf8) * RY15)), gray_shift);\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void Gray2BGR5x5(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, src_offset + x);\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"int t = src[src_index];\n"
"#if greenbits == 6\n"
"*((__global ushort*)(dst + dst_index)) = (ushort)((t >> 3) | ((t & ~3) << 3) | ((t & ~7) << 8));\n"
"#else\n"
"t >>= 3;\n"
"*((__global ushort*)(dst + dst_index)) = (ushort)(t|(t << 5)|(t << 10));\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#ifdef DEPTH_0\n"
"__kernel void RGBA2mRGBA(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, src_offset + (x << 2));\n"
"int dst_index = mad24(y, dst_step, dst_offset + (x << 2));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"uchar4 src_pix = *(__global const uchar4 *)(src + src_index);\n"
"*(__global uchar4 *)(dst + dst_index) =\n"
"(uchar4)(mad24(src_pix.x, src_pix.w, HALF_MAX_NUM) / MAX_NUM,\n"
"mad24(src_pix.y, src_pix.w, HALF_MAX_NUM) / MAX_NUM,\n"
"mad24(src_pix.z, src_pix.w, HALF_MAX_NUM) / MAX_NUM, src_pix.w);\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void mRGBA2RGBA(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, 4, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, 4, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"uchar4 src_pix = *(__global const uchar4 *)(src + src_index);\n"
"uchar v3 = src_pix.w, v3_half = v3 / 2;\n"
"if (v3 == 0)\n"
"*(__global uchar4 *)(dst + dst_index) = (uchar4)(0, 0, 0, 0);\n"
"else\n"
"*(__global uchar4 *)(dst + dst_index) =\n"
"(uchar4)(SAT_CAST(mad24(src_pix.x, MAX_NUM, v3_half) / v3),\n"
"SAT_CAST(mad24(src_pix.y, MAX_NUM, v3_half) / v3),\n"
"SAT_CAST(mad24(src_pix.z, MAX_NUM, v3_half) / v3),\n"
"SAT_CAST(v3));\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
, "7c7f5a9dd8757ef67722074f65469f9a", NULL};
struct cv::ocl::internal::ProgramEntry color_yuv_oclsrc={moduleName, "color_yuv",
"#if depth == 0\n"
"#define DATA_TYPE uchar\n"
"#define MAX_NUM  255\n"
"#define HALF_MAX_NUM 128\n"
"#define COEFF_TYPE int\n"
"#define SAT_CAST(num) convert_uchar_sat(num)\n"
"#define DEPTH_0\n"
"#elif depth == 2\n"
"#define DATA_TYPE ushort\n"
"#define MAX_NUM  65535\n"
"#define HALF_MAX_NUM 32768\n"
"#define COEFF_TYPE int\n"
"#define SAT_CAST(num) convert_ushort_sat(num)\n"
"#define DEPTH_2\n"
"#elif depth == 5\n"
"#define DATA_TYPE float\n"
"#define MAX_NUM  1.0f\n"
"#define HALF_MAX_NUM 0.5f\n"
"#define COEFF_TYPE float\n"
"#define SAT_CAST(num) (num)\n"
"#define DEPTH_5\n"
"#else\n"
"#error \"invalid depth: should be 0 (CV_8U), 2 (CV_16U) or 5 (CV_32F)\"\n"
"#endif\n"
"#define CV_DESCALE(x,n) (((x) + (1 << ((n)-1))) >> (n))\n"
"enum\n"
"{\n"
"yuv_shift  = 14,\n"
"R2Y        = 4899,\n"
"G2Y        = 9617,\n"
"B2Y        = 1868,\n"
"};\n"
"#define B2YF 0.114f\n"
"#define G2YF 0.587f\n"
"#define R2YF 0.299f\n"
"#define YCBF 0.564f\n"
"#define YCRF 0.713f\n"
"#define YCBI 9241\n"
"#define YCRI 11682\n"
"#define B2UF 0.492f\n"
"#define R2VF 0.877f\n"
"#define B2UI 8061\n"
"#define R2VI 14369\n"
"#define U2BF 2.032f\n"
"#define U2GF -0.395f\n"
"#define V2GF -0.581f\n"
"#define V2RF 1.140f\n"
"#define U2BI 33292\n"
"#define U2GI -6472\n"
"#define V2GI -9519\n"
"#define V2RI 18678\n"
"#define CR2RF 1.403f\n"
"#define CB2GF -0.344f\n"
"#define CR2GF -0.714f\n"
"#define CB2BF 1.773f\n"
"#define CR2RI 22987\n"
"#define CB2GI -5636\n"
"#define CR2GI -11698\n"
"#define CB2BI 29049\n"
"#define scnbytes ((int)sizeof(DATA_TYPE)*scn)\n"
"#define dcnbytes ((int)sizeof(DATA_TYPE)*dcn)\n"
"#if bidx == 0\n"
"#define R_COMP z\n"
"#define G_COMP y\n"
"#define B_COMP x\n"
"#else\n"
"#define R_COMP x\n"
"#define G_COMP y\n"
"#define B_COMP z\n"
"#endif\n"
"#ifndef uidx\n"
"#define uidx 0\n"
"#endif\n"
"#ifndef yidx\n"
"#define yidx 0\n"
"#endif\n"
"#ifndef PIX_PER_WI_X\n"
"#define PIX_PER_WI_X 1\n"
"#endif\n"
"#define __CAT(x, y) x##y\n"
"#define CAT(x, y) __CAT(x, y)\n"
"#define DATA_TYPE_4 CAT(DATA_TYPE, 4)\n"
"#define DATA_TYPE_3 CAT(DATA_TYPE, 3)\n"
"__constant float c_RGB2YUVCoeffs_f[5]  = { B2YF, G2YF, R2YF, B2UF, R2VF };\n"
"__constant int   c_RGB2YUVCoeffs_i[5]  = { B2Y, G2Y, R2Y, B2UI, R2VI };\n"
"__kernel void RGB2YUV(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dt_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dt_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const DATA_TYPE* src = (__global const DATA_TYPE*)(srcptr + src_index);\n"
"__global DATA_TYPE* dst = (__global DATA_TYPE*)(dstptr + dst_index);\n"
"DATA_TYPE_3 src_pix = vload3(0, src);\n"
"DATA_TYPE b = src_pix.B_COMP, g = src_pix.G_COMP, r = src_pix.R_COMP;\n"
"#ifdef DEPTH_5\n"
"__constant float * coeffs = c_RGB2YUVCoeffs_f;\n"
"const DATA_TYPE Y = fma(b, coeffs[0], fma(g, coeffs[1], r * coeffs[2]));\n"
"const DATA_TYPE U = fma(b - Y, coeffs[3], HALF_MAX_NUM);\n"
"const DATA_TYPE V = fma(r - Y, coeffs[4], HALF_MAX_NUM);\n"
"#else\n"
"__constant int * coeffs = c_RGB2YUVCoeffs_i;\n"
"const int delta = HALF_MAX_NUM * (1 << yuv_shift);\n"
"const int Y = CV_DESCALE(mad24(b, coeffs[0], mad24(g, coeffs[1], mul24(r, coeffs[2]))), yuv_shift);\n"
"const int U = CV_DESCALE(mad24(b - Y, coeffs[3], delta), yuv_shift);\n"
"const int V = CV_DESCALE(mad24(r - Y, coeffs[4], delta), yuv_shift);\n"
"#endif\n"
"dst[0] = SAT_CAST( Y );\n"
"dst[1] = SAT_CAST( U );\n"
"dst[2] = SAT_CAST( V );\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__constant float c_YUV2RGBCoeffs_f[4] = { U2BF, U2GF, V2GF, V2RF };\n"
"__constant int   c_YUV2RGBCoeffs_i[4] = { U2BI, U2GI, V2GI, V2RI };\n"
"__kernel void YUV2RGB(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dt_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dt_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const DATA_TYPE* src = (__global const DATA_TYPE*)(srcptr + src_index);\n"
"__global DATA_TYPE* dst = (__global DATA_TYPE*)(dstptr + dst_index);\n"
"DATA_TYPE_4 src_pix = vload4(0, src);\n"
"DATA_TYPE Y = src_pix.x, U = src_pix.y, V = src_pix.z;\n"
"#ifdef DEPTH_5\n"
"__constant float * coeffs = c_YUV2RGBCoeffs_f;\n"
"float r = fma(V - HALF_MAX_NUM, coeffs[3], Y);\n"
"float g = fma(V - HALF_MAX_NUM, coeffs[2], fma(U - HALF_MAX_NUM, coeffs[1], Y));\n"
"float b = fma(U - HALF_MAX_NUM, coeffs[0], Y);\n"
"#else\n"
"__constant int * coeffs = c_YUV2RGBCoeffs_i;\n"
"const int r = Y + CV_DESCALE(mul24(V - HALF_MAX_NUM, coeffs[3]), yuv_shift);\n"
"const int g = Y + CV_DESCALE(mad24(V - HALF_MAX_NUM, coeffs[2], mul24(U - HALF_MAX_NUM, coeffs[1])), yuv_shift);\n"
"const int b = Y + CV_DESCALE(mul24(U - HALF_MAX_NUM, coeffs[0]), yuv_shift);\n"
"#endif\n"
"dst[bidx] = SAT_CAST( b );\n"
"dst[1] = SAT_CAST( g );\n"
"dst[bidx^2] = SAT_CAST( r );\n"
"#if dcn == 4\n"
"dst[3] = MAX_NUM;\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__constant float c_YUV2RGBCoeffs_420[5] = { 1.163999557f, 2.017999649f, -0.390999794f,\n"
"-0.812999725f, 1.5959997177f };\n"
"__kernel void YUV2RGB_NVx(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dt_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols / 2)\n"
"{\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows / 2 )\n"
"{\n"
"__global const uchar* ysrc = srcptr + mad24(y << 1, src_step, (x << 1) + src_offset);\n"
"__global const uchar* usrc = srcptr + mad24(rows + y, src_step, (x << 1) + src_offset);\n"
"__global uchar*       dst1 = dstptr + mad24(y << 1, dst_step, mad24(x, dcn<<1, dt_offset));\n"
"__global uchar*       dst2 = dst1 + dst_step;\n"
"float Y1 = ysrc[0];\n"
"float Y2 = ysrc[1];\n"
"float Y3 = ysrc[src_step];\n"
"float Y4 = ysrc[src_step + 1];\n"
"float U  = ((float)usrc[uidx]) - HALF_MAX_NUM;\n"
"float V  = ((float)usrc[1-uidx]) - HALF_MAX_NUM;\n"
"__constant float* coeffs = c_YUV2RGBCoeffs_420;\n"
"float ruv = fma(coeffs[4], V, 0.5f);\n"
"float guv = fma(coeffs[3], V, fma(coeffs[2], U, 0.5f));\n"
"float buv = fma(coeffs[1], U, 0.5f);\n"
"Y1 = max(0.f, Y1 - 16.f) * coeffs[0];\n"
"dst1[2 - bidx] = convert_uchar_sat(Y1 + ruv);\n"
"dst1[1]        = convert_uchar_sat(Y1 + guv);\n"
"dst1[bidx]     = convert_uchar_sat(Y1 + buv);\n"
"#if dcn == 4\n"
"dst1[3]        = 255;\n"
"#endif\n"
"Y2 = max(0.f, Y2 - 16.f) * coeffs[0];\n"
"dst1[dcn + 2 - bidx] = convert_uchar_sat(Y2 + ruv);\n"
"dst1[dcn + 1]        = convert_uchar_sat(Y2 + guv);\n"
"dst1[dcn + bidx]     = convert_uchar_sat(Y2 + buv);\n"
"#if dcn == 4\n"
"dst1[7]        = 255;\n"
"#endif\n"
"Y3 = max(0.f, Y3 - 16.f) * coeffs[0];\n"
"dst2[2 - bidx] = convert_uchar_sat(Y3 + ruv);\n"
"dst2[1]        = convert_uchar_sat(Y3 + guv);\n"
"dst2[bidx]     = convert_uchar_sat(Y3 + buv);\n"
"#if dcn == 4\n"
"dst2[3]        = 255;\n"
"#endif\n"
"Y4 = max(0.f, Y4 - 16.f) * coeffs[0];\n"
"dst2[dcn + 2 - bidx] = convert_uchar_sat(Y4 + ruv);\n"
"dst2[dcn + 1]        = convert_uchar_sat(Y4 + guv);\n"
"dst2[dcn + bidx]     = convert_uchar_sat(Y4 + buv);\n"
"#if dcn == 4\n"
"dst2[7]        = 255;\n"
"#endif\n"
"}\n"
"++y;\n"
"}\n"
"}\n"
"}\n"
"#if uidx < 2\n"
"__kernel void YUV2RGB_YV12_IYUV(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dt_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols / 2)\n"
"{\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows / 2 )\n"
"{\n"
"__global const uchar* ysrc = srcptr + mad24(y << 1, src_step, (x << 1) + src_offset);\n"
"__global uchar*       dst1 = dstptr + mad24(y << 1, dst_step, x * (dcn<<1) + dt_offset);\n"
"__global uchar*       dst2 = dst1 + dst_step;\n"
"float Y1 = ysrc[0];\n"
"float Y2 = ysrc[1];\n"
"float Y3 = ysrc[src_step];\n"
"float Y4 = ysrc[src_step + 1];\n"
"#ifdef SRC_CONT\n"
"__global const uchar* uvsrc = srcptr + mad24(rows, src_step, src_offset);\n"
"int u_ind = mad24(y, cols >> 1, x);\n"
"float uv[2] = { ((float)uvsrc[u_ind]) - HALF_MAX_NUM, ((float)uvsrc[u_ind + ((rows * cols) >> 2)]) - HALF_MAX_NUM };\n"
"#else\n"
"int vsteps[2] = { cols >> 1, src_step - (cols >> 1)};\n"
"__global const uchar* usrc = srcptr + mad24(rows + (y>>1), src_step, src_offset + (y%2)*(cols >> 1) + x);\n"
"__global const uchar* vsrc = usrc + mad24(rows >> 2, src_step, rows % 4 ? vsteps[y%2] : 0);\n"
"float uv[2] = { ((float)usrc[0]) - HALF_MAX_NUM, ((float)vsrc[0]) - HALF_MAX_NUM };\n"
"#endif\n"
"float U = uv[uidx];\n"
"float V = uv[1-uidx];\n"
"__constant float* coeffs = c_YUV2RGBCoeffs_420;\n"
"float ruv = fma(coeffs[4], V, 0.5f);\n"
"float guv = fma(coeffs[3], V, fma(coeffs[2], U, 0.5f));\n"
"float buv = fma(coeffs[1], U, 0.5f);\n"
"Y1 = max(0.f, Y1 - 16.f) * coeffs[0];\n"
"dst1[2 - bidx] = convert_uchar_sat(Y1 + ruv);\n"
"dst1[1]        = convert_uchar_sat(Y1 + guv);\n"
"dst1[bidx]     = convert_uchar_sat(Y1 + buv);\n"
"#if dcn == 4\n"
"dst1[3]        = 255;\n"
"#endif\n"
"Y2 = max(0.f, Y2 - 16.f) * coeffs[0];\n"
"dst1[dcn + 2 - bidx] = convert_uchar_sat(Y2 + ruv);\n"
"dst1[dcn + 1]        = convert_uchar_sat(Y2 + guv);\n"
"dst1[dcn + bidx]     = convert_uchar_sat(Y2 + buv);\n"
"#if dcn == 4\n"
"dst1[7]        = 255;\n"
"#endif\n"
"Y3 = max(0.f, Y3 - 16.f) * coeffs[0];\n"
"dst2[2 - bidx] = convert_uchar_sat(Y3 + ruv);\n"
"dst2[1]        = convert_uchar_sat(Y3 + guv);\n"
"dst2[bidx]     = convert_uchar_sat(Y3 + buv);\n"
"#if dcn == 4\n"
"dst2[3]        = 255;\n"
"#endif\n"
"Y4 = max(0.f, Y4 - 16.f) * coeffs[0];\n"
"dst2[dcn + 2 - bidx] = convert_uchar_sat(Y4 + ruv);\n"
"dst2[dcn + 1]        = convert_uchar_sat(Y4 + guv);\n"
"dst2[dcn + bidx]     = convert_uchar_sat(Y4 + buv);\n"
"#if dcn == 4\n"
"dst2[7]        = 255;\n"
"#endif\n"
"}\n"
"++y;\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
"#if uidx < 2\n"
"__constant float c_RGB2YUVCoeffs_420[8] = { 0.256999969f, 0.50399971f, 0.09799957f, -0.1479988098f, -0.2909994125f,\n"
"0.438999176f, -0.3679990768f, -0.0709991455f };\n"
"__kernel void RGB2YUV_YV12_IYUV(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0) * PIX_PER_WI_X;\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols/2)\n"
"{\n"
"int src_index  = mad24(y << 1, src_step, mad24(x << 1, scn, src_offset));\n"
"int ydst_index = mad24(y << 1, dst_step, (x << 1) + dst_offset);\n"
"int y_rows = rows / 3 * 2;\n"
"int vsteps[2] = { cols >> 1, dst_step - (cols >> 1)};\n"
"__constant float* coeffs = c_RGB2YUVCoeffs_420;\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows / 3)\n"
"{\n"
"__global const uchar* src1 = srcptr + src_index;\n"
"__global const uchar* src2 = src1 + src_step;\n"
"__global uchar* ydst1 = dstptr + ydst_index;\n"
"__global uchar* ydst2 = ydst1 + dst_step;\n"
"__global uchar* udst = dstptr + mad24(y_rows + (y>>1), dst_step, dst_offset + (y%2)*(cols >> 1) + x);\n"
"__global uchar* vdst = udst + mad24(y_rows >> 2, dst_step, y_rows % 4 ? vsteps[y%2] : 0);\n"
"#if PIX_PER_WI_X == 2\n"
"int s11 = *((__global const int*) src1);\n"
"int s12 = *((__global const int*) src1 + 1);\n"
"int s13 = *((__global const int*) src1 + 2);\n"
"#if scn == 4\n"
"int s14 = *((__global const int*) src1 + 3);\n"
"#endif\n"
"int s21 = *((__global const int*) src2);\n"
"int s22 = *((__global const int*) src2 + 1);\n"
"int s23 = *((__global const int*) src2 + 2);\n"
"#if scn == 4\n"
"int s24 = *((__global const int*) src2 + 3);\n"
"#endif\n"
"float src_pix1[scn * 4], src_pix2[scn * 4];\n"
"*((float4*) src_pix1)     = convert_float4(as_uchar4(s11));\n"
"*((float4*) src_pix1 + 1) = convert_float4(as_uchar4(s12));\n"
"*((float4*) src_pix1 + 2) = convert_float4(as_uchar4(s13));\n"
"#if scn == 4\n"
"*((float4*) src_pix1 + 3) = convert_float4(as_uchar4(s14));\n"
"#endif\n"
"*((float4*) src_pix2)     = convert_float4(as_uchar4(s21));\n"
"*((float4*) src_pix2 + 1) = convert_float4(as_uchar4(s22));\n"
"*((float4*) src_pix2 + 2) = convert_float4(as_uchar4(s23));\n"
"#if scn == 4\n"
"*((float4*) src_pix2 + 3) = convert_float4(as_uchar4(s24));\n"
"#endif\n"
"uchar4 y1, y2;\n"
"y1.x = convert_uchar_sat(fma(coeffs[0], src_pix1[      2-bidx], fma(coeffs[1], src_pix1[      1], fma(coeffs[2], src_pix1[      bidx], 16.5f))));\n"
"y1.y = convert_uchar_sat(fma(coeffs[0], src_pix1[  scn+2-bidx], fma(coeffs[1], src_pix1[  scn+1], fma(coeffs[2], src_pix1[  scn+bidx], 16.5f))));\n"
"y1.z = convert_uchar_sat(fma(coeffs[0], src_pix1[2*scn+2-bidx], fma(coeffs[1], src_pix1[2*scn+1], fma(coeffs[2], src_pix1[2*scn+bidx], 16.5f))));\n"
"y1.w = convert_uchar_sat(fma(coeffs[0], src_pix1[3*scn+2-bidx], fma(coeffs[1], src_pix1[3*scn+1], fma(coeffs[2], src_pix1[3*scn+bidx], 16.5f))));\n"
"y2.x = convert_uchar_sat(fma(coeffs[0], src_pix2[      2-bidx], fma(coeffs[1], src_pix2[      1], fma(coeffs[2], src_pix2[      bidx], 16.5f))));\n"
"y2.y = convert_uchar_sat(fma(coeffs[0], src_pix2[  scn+2-bidx], fma(coeffs[1], src_pix2[  scn+1], fma(coeffs[2], src_pix2[  scn+bidx], 16.5f))));\n"
"y2.z = convert_uchar_sat(fma(coeffs[0], src_pix2[2*scn+2-bidx], fma(coeffs[1], src_pix2[2*scn+1], fma(coeffs[2], src_pix2[2*scn+bidx], 16.5f))));\n"
"y2.w = convert_uchar_sat(fma(coeffs[0], src_pix2[3*scn+2-bidx], fma(coeffs[1], src_pix2[3*scn+1], fma(coeffs[2], src_pix2[3*scn+bidx], 16.5f))));\n"
"*((__global int*) ydst1) = as_int(y1);\n"
"*((__global int*) ydst2) = as_int(y2);\n"
"float uv[4] = { fma(coeffs[3], src_pix1[      2-bidx], fma(coeffs[4], src_pix1[      1], fma(coeffs[5], src_pix1[      bidx], 128.5f))),\n"
"fma(coeffs[5], src_pix1[      2-bidx], fma(coeffs[6], src_pix1[      1], fma(coeffs[7], src_pix1[      bidx], 128.5f))),\n"
"fma(coeffs[3], src_pix1[2*scn+2-bidx], fma(coeffs[4], src_pix1[2*scn+1], fma(coeffs[5], src_pix1[2*scn+bidx], 128.5f))),\n"
"fma(coeffs[5], src_pix1[2*scn+2-bidx], fma(coeffs[6], src_pix1[2*scn+1], fma(coeffs[7], src_pix1[2*scn+bidx], 128.5f))) };\n"
"udst[0] = convert_uchar_sat(uv[uidx]    );\n"
"vdst[0] = convert_uchar_sat(uv[1 - uidx]);\n"
"udst[1] = convert_uchar_sat(uv[2 + uidx]);\n"
"vdst[1] = convert_uchar_sat(uv[3 - uidx]);\n"
"#else\n"
"float4 src_pix1 = convert_float4(vload4(0, src1));\n"
"float4 src_pix2 = convert_float4(vload4(0, src1+scn));\n"
"float4 src_pix3 = convert_float4(vload4(0, src2));\n"
"float4 src_pix4 = convert_float4(vload4(0, src2+scn));\n"
"ydst1[0] = convert_uchar_sat(fma(coeffs[0], src_pix1.R_COMP, fma(coeffs[1], src_pix1.G_COMP, fma(coeffs[2], src_pix1.B_COMP, 16.5f))));\n"
"ydst1[1] = convert_uchar_sat(fma(coeffs[0], src_pix2.R_COMP, fma(coeffs[1], src_pix2.G_COMP, fma(coeffs[2], src_pix2.B_COMP, 16.5f))));\n"
"ydst2[0] = convert_uchar_sat(fma(coeffs[0], src_pix3.R_COMP, fma(coeffs[1], src_pix3.G_COMP, fma(coeffs[2], src_pix3.B_COMP, 16.5f))));\n"
"ydst2[1] = convert_uchar_sat(fma(coeffs[0], src_pix4.R_COMP, fma(coeffs[1], src_pix4.G_COMP, fma(coeffs[2], src_pix4.B_COMP, 16.5f))));\n"
"float uv[2] = { fma(coeffs[3], src_pix1.R_COMP, fma(coeffs[4], src_pix1.G_COMP, fma(coeffs[5], src_pix1.B_COMP, 128.5f))),\n"
"fma(coeffs[5], src_pix1.R_COMP, fma(coeffs[6], src_pix1.G_COMP, fma(coeffs[7], src_pix1.B_COMP, 128.5f))) };\n"
"udst[0] = convert_uchar_sat(uv[uidx]  );\n"
"vdst[0] = convert_uchar_sat(uv[1-uidx]);\n"
"#endif\n"
"++y;\n"
"src_index += 2*src_step;\n"
"ydst_index += 2*dst_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
"__kernel void YUV2RGB_422(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols / 2)\n"
"{\n"
"__global const uchar* src = srcptr + mad24(y, src_step, (x << 2) + src_offset);\n"
"__global uchar*       dst = dstptr + mad24(y, dst_step, mad24(x << 1, dcn, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows )\n"
"{\n"
"__constant float* coeffs = c_YUV2RGBCoeffs_420;\n"
"#ifndef USE_OPTIMIZED_LOAD\n"
"float U = ((float) src[uidx]) - HALF_MAX_NUM;\n"
"float V = ((float) src[(2 + uidx) % 4]) - HALF_MAX_NUM;\n"
"float y00 = max(0.f, ((float) src[yidx]) - 16.f) * coeffs[0];\n"
"float y01 = max(0.f, ((float) src[yidx + 2]) - 16.f) * coeffs[0];\n"
"#else\n"
"int load_src = *((__global int*) src);\n"
"float vec_src[4] = { load_src & 0xff, (load_src >> 8) & 0xff, (load_src >> 16) & 0xff, (load_src >> 24) & 0xff};\n"
"float U = vec_src[uidx] - HALF_MAX_NUM;\n"
"float V = vec_src[(2 + uidx) % 4] - HALF_MAX_NUM;\n"
"float y00 = max(0.f, vec_src[yidx] - 16.f) * coeffs[0];\n"
"float y01 = max(0.f, vec_src[yidx + 2] - 16.f) * coeffs[0];\n"
"#endif\n"
"float ruv = fma(coeffs[4], V, 0.5f);\n"
"float guv = fma(coeffs[3], V, fma(coeffs[2], U, 0.5f));\n"
"float buv = fma(coeffs[1], U, 0.5f);\n"
"dst[2 - bidx] = convert_uchar_sat(y00 + ruv);\n"
"dst[1]        = convert_uchar_sat(y00 + guv);\n"
"dst[bidx]     = convert_uchar_sat(y00 + buv);\n"
"#if dcn == 4\n"
"dst[3]        = 255;\n"
"#endif\n"
"dst[dcn + 2 - bidx] = convert_uchar_sat(y01 + ruv);\n"
"dst[dcn + 1]        = convert_uchar_sat(y01 + guv);\n"
"dst[dcn + bidx]     = convert_uchar_sat(y01 + buv);\n"
"#if dcn == 4\n"
"dst[7]        = 255;\n"
"#endif\n"
"}\n"
"++y;\n"
"src += src_step;\n"
"dst += dst_step;\n"
"}\n"
"}\n"
"}\n"
"__constant float c_RGB2YCrCbCoeffs_f[5] = {R2YF, G2YF, B2YF, YCRF, YCBF};\n"
"__constant int   c_RGB2YCrCbCoeffs_i[5] = {R2Y, G2Y, B2Y, YCRI, YCBI};\n"
"__kernel void RGB2YCrCb(__global const uchar* srcptr, int src_step, int src_offset,\n"
"__global uchar* dstptr, int dst_step, int dt_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dt_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const DATA_TYPE* src = (__global const DATA_TYPE*)(srcptr + src_index);\n"
"__global DATA_TYPE* dst = (__global DATA_TYPE*)(dstptr + dst_index);\n"
"DATA_TYPE_4 src_pix = vload4(0, src);\n"
"DATA_TYPE b = src_pix.B_COMP, g = src_pix.G_COMP, r = src_pix.R_COMP;\n"
"#ifdef DEPTH_5\n"
"__constant float * coeffs = c_RGB2YCrCbCoeffs_f;\n"
"DATA_TYPE Y = fma(b, coeffs[2], fma(g, coeffs[1], r * coeffs[0]));\n"
"DATA_TYPE Cr = fma(r - Y, coeffs[3], HALF_MAX_NUM);\n"
"DATA_TYPE Cb = fma(b - Y, coeffs[4], HALF_MAX_NUM);\n"
"#else\n"
"__constant int * coeffs = c_RGB2YCrCbCoeffs_i;\n"
"int delta = HALF_MAX_NUM * (1 << yuv_shift);\n"
"int Y =  CV_DESCALE(mad24(b, coeffs[2], mad24(g, coeffs[1], mul24(r, coeffs[0]))), yuv_shift);\n"
"int Cr = CV_DESCALE(mad24(r - Y, coeffs[3], delta), yuv_shift);\n"
"int Cb = CV_DESCALE(mad24(b - Y, coeffs[4], delta), yuv_shift);\n"
"#endif\n"
"dst[0] = SAT_CAST( Y );\n"
"dst[1] = SAT_CAST( Cr );\n"
"dst[2] = SAT_CAST( Cb );\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__constant float c_YCrCb2RGBCoeffs_f[4] = { CR2RF, CR2GF, CB2GF, CB2BF };\n"
"__constant int   c_YCrCb2RGBCoeffs_i[4] = { CR2RI, CR2GI, CB2GI, CB2BI };\n"
"__kernel void YCrCb2RGB(__global const uchar* src, int src_step, int src_offset,\n"
"__global uchar* dst, int dst_step, int dst_offset,\n"
"int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * PIX_PER_WI_Y;\n"
"if (x < cols)\n"
"{\n"
"int src_index = mad24(y, src_step, mad24(x, scnbytes, src_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, dcnbytes, dst_offset));\n"
"#pragma unroll\n"
"for (int cy = 0; cy < PIX_PER_WI_Y; ++cy)\n"
"{\n"
"if (y < rows)\n"
"{\n"
"__global const DATA_TYPE * srcptr = (__global const DATA_TYPE*)(src + src_index);\n"
"__global DATA_TYPE * dstptr = (__global DATA_TYPE*)(dst + dst_index);\n"
"DATA_TYPE_4 src_pix = vload4(0, srcptr);\n"
"DATA_TYPE yp = src_pix.x, cr = src_pix.y, cb = src_pix.z;\n"
"#ifdef DEPTH_5\n"
"__constant float * coeff = c_YCrCb2RGBCoeffs_f;\n"
"float r = fma(coeff[0], cr - HALF_MAX_NUM, yp);\n"
"float g = fma(coeff[1], cr - HALF_MAX_NUM, fma(coeff[2], cb - HALF_MAX_NUM, yp));\n"
"float b = fma(coeff[3], cb - HALF_MAX_NUM, yp);\n"
"#else\n"
"__constant int * coeff = c_YCrCb2RGBCoeffs_i;\n"
"int r = yp + CV_DESCALE(coeff[0] * (cr - HALF_MAX_NUM), yuv_shift);\n"
"int g = yp + CV_DESCALE(mad24(coeff[1], cr - HALF_MAX_NUM, coeff[2] * (cb - HALF_MAX_NUM)), yuv_shift);\n"
"int b = yp + CV_DESCALE(coeff[3] * (cb - HALF_MAX_NUM), yuv_shift);\n"
"#endif\n"
"dstptr[(bidx^2)] = SAT_CAST(r);\n"
"dstptr[1] = SAT_CAST(g);\n"
"dstptr[bidx] = SAT_CAST(b);\n"
"#if dcn == 4\n"
"dstptr[3] = MAX_NUM;\n"
"#endif\n"
"++y;\n"
"dst_index += dst_step;\n"
"src_index += src_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
, "5c9da97816c27d6319efa89b2fd7c1ea", NULL};
struct cv::ocl::internal::ProgramEntry corner_oclsrc={moduleName, "corner",
"#ifdef BORDER_CONSTANT\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"x = max(min(x, maxV - 1), 0); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"if (x < 0) \\\n"
"x -= ((x - maxV + 1) / maxV) * maxV; \\\n"
"if (x >= maxV) \\\n"
"x %= maxV; \\\n"
"}\n"
"#elif defined(BORDER_REFLECT) || defined(BORDER_REFLECT101)\n"
"#define EXTRAPOLATE_(x, maxV, delta) \\\n"
"{ \\\n"
"if (maxV == 1) \\\n"
"x = 0; \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if ( x < 0 ) \\\n"
"x = -x - 1 + delta; \\\n"
"else \\\n"
"x = maxV - 1 - (x - maxV) - delta; \\\n"
"} \\\n"
"while (x >= maxV || x < 0); \\\n"
"}\n"
"#ifdef BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, maxV) EXTRAPOLATE_(x, maxV, 0)\n"
"#else\n"
"#define EXTRAPOLATE(x, maxV) EXTRAPOLATE_(x, maxV, 1)\n"
"#endif\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#define THREADS 256\n"
"__kernel void corner(__global const float * Dx, int dx_step, int dx_offset, int dx_whole_rows, int dx_whole_cols,\n"
"__global const float * Dy, int dy_step, int dy_offset, int dy_whole_rows, int dy_whole_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols, float k)\n"
"{\n"
"int col = get_local_id(0);\n"
"int gX = get_group_id(0);\n"
"int gY = get_group_id(1);\n"
"int gly = get_global_id(1);\n"
"int dx_x_off = (dx_offset % dx_step) >> 2;\n"
"int dx_y_off = dx_offset / dx_step;\n"
"int dy_x_off = (dy_offset % dy_step) >> 2;\n"
"int dy_y_off = dy_offset / dy_step;\n"
"int dst_x_off = (dst_offset % dst_step) >> 2;\n"
"int dst_y_off = dst_offset / dst_step;\n"
"int dx_startX = gX * (THREADS-ksX+1) - anX + dx_x_off;\n"
"int dx_startY = (gY << 1) - anY + dx_y_off;\n"
"int dy_startX = gX * (THREADS-ksX+1) - anX + dy_x_off;\n"
"int dy_startY = (gY << 1) - anY + dy_y_off;\n"
"int dst_startX = gX * (THREADS-ksX+1) + dst_x_off;\n"
"int dst_startY = (gY << 1) + dst_y_off;\n"
"float data[3][ksY+1];\n"
"__local float temp[6][THREADS];\n"
"#ifdef BORDER_CONSTANT\n"
"for (int i=0; i < ksY+1; i++)\n"
"{\n"
"bool dx_con = dx_startX+col >= 0 && dx_startX+col < dx_whole_cols && dx_startY+i >= 0 && dx_startY+i < dx_whole_rows;\n"
"int indexDx = mad24(dx_startY+i, dx_step>>2, dx_startX+col);\n"
"float dx_s = dx_con ? Dx[indexDx] : 0.0f;\n"
"bool dy_con = dy_startX+col >= 0 && dy_startX+col < dy_whole_cols && dy_startY+i >= 0 && dy_startY+i < dy_whole_rows;\n"
"int indexDy = mad24(dy_startY+i, dy_step>>2, dy_startX+col);\n"
"float dy_s = dy_con ? Dy[indexDy] : 0.0f;\n"
"data[0][i] = dx_s * dx_s;\n"
"data[1][i] = dx_s * dy_s;\n"
"data[2][i] = dy_s * dy_s;\n"
"}\n"
"#else\n"
"int clamped_col = min(2*dst_cols, col);\n"
"for (int i=0; i < ksY+1; i++)\n"
"{\n"
"int dx_selected_row = dx_startY+i, dx_selected_col = dx_startX+clamped_col;\n"
"EXTRAPOLATE(dx_selected_row, dx_whole_rows)\n"
"EXTRAPOLATE(dx_selected_col, dx_whole_cols)\n"
"float dx_s = Dx[mad24(dx_selected_row, dx_step>>2, dx_selected_col)];\n"
"int dy_selected_row = dy_startY+i, dy_selected_col = dy_startX+clamped_col;\n"
"EXTRAPOLATE(dy_selected_row, dy_whole_rows)\n"
"EXTRAPOLATE(dy_selected_col, dy_whole_cols)\n"
"float dy_s = Dy[mad24(dy_selected_row, dy_step>>2, dy_selected_col)];\n"
"data[0][i] = dx_s * dx_s;\n"
"data[1][i] = dx_s * dy_s;\n"
"data[2][i] = dy_s * dy_s;\n"
"}\n"
"#endif\n"
"float sum0 = 0.0f, sum1 = 0.0f, sum2 = 0.0f;\n"
"for (int i=1; i < ksY; i++)\n"
"{\n"
"sum0 += data[0][i];\n"
"sum1 += data[1][i];\n"
"sum2 += data[2][i];\n"
"}\n"
"float sum01 = sum0 + data[0][0];\n"
"float sum02 = sum0 + data[0][ksY];\n"
"temp[0][col] = sum01;\n"
"temp[1][col] = sum02;\n"
"float sum11 = sum1 + data[1][0];\n"
"float sum12 = sum1 + data[1][ksY];\n"
"temp[2][col] = sum11;\n"
"temp[3][col] = sum12;\n"
"float sum21 = sum2 + data[2][0];\n"
"float sum22 = sum2 + data[2][ksY];\n"
"temp[4][col] = sum21;\n"
"temp[5][col] = sum22;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (col < (THREADS - (ksX - 1)))\n"
"{\n"
"col += anX;\n"
"int posX = dst_startX - dst_x_off + col - anX;\n"
"int posY = (gly << 1);\n"
"int till = (ksX + 1) & 1;\n"
"float tmp_sum[6] = { 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f };\n"
"for (int k=0; k<6; k++)\n"
"{\n"
"float temp_sum = 0;\n"
"for (int i=-anX; i<=anX - till; i++)\n"
"temp_sum += temp[k][col+i];\n"
"tmp_sum[k] = temp_sum;\n"
"}\n"
"#ifdef CORNER_HARRIS\n"
"if (posX < dst_cols && (posY) < dst_rows)\n"
"{\n"
"int dst_index = mad24(dst_step, dst_startY, (int)sizeof(float) * (dst_startX + col - anX));\n"
"*(__global float *)(dst + dst_index) =\n"
"tmp_sum[0] * tmp_sum[4] - tmp_sum[2] * tmp_sum[2] - k * (tmp_sum[0] + tmp_sum[4]) * (tmp_sum[0] + tmp_sum[4]);\n"
"}\n"
"if (posX < dst_cols && (posY + 1) < dst_rows)\n"
"{\n"
"int dst_index = mad24(dst_step, dst_startY + 1, (int)sizeof(float) * (dst_startX + col - anX));\n"
"*(__global float *)(dst + dst_index) =\n"
"tmp_sum[1] * tmp_sum[5] - tmp_sum[3] * tmp_sum[3] - k * (tmp_sum[1] + tmp_sum[5]) * (tmp_sum[1] + tmp_sum[5]);\n"
"}\n"
"#elif defined CORNER_MINEIGENVAL\n"
"if (posX < dst_cols && (posY) < dst_rows)\n"
"{\n"
"int dst_index = mad24(dst_step, dst_startY, (int)sizeof(float) * (dst_startX + col - anX));\n"
"float a = tmp_sum[0] * 0.5f;\n"
"float b = tmp_sum[2];\n"
"float c = tmp_sum[4] * 0.5f;\n"
"*(__global float *)(dst + dst_index) = (float)((a+c) - native_sqrt((a-c)*(a-c) + b*b));\n"
"}\n"
"if (posX < dst_cols && (posY + 1) < dst_rows)\n"
"{\n"
"int dst_index = mad24(dst_step, dst_startY + 1, (int)sizeof(float) * (dst_startX + col - anX));\n"
"float a = tmp_sum[1] * 0.5f;\n"
"float b = tmp_sum[3];\n"
"float c = tmp_sum[5] * 0.5f;\n"
"*(__global float *)(dst + dst_index) = (float)((a+c) - native_sqrt((a-c)*(a-c) + b*b));\n"
"}\n"
"#else\n"
"#error \"No such corners type\"\n"
"#endif\n"
"}\n"
"}\n"
, "0b0ba9ee4305009cb2433737f7ed5bcd", NULL};
struct cv::ocl::internal::ProgramEntry covardata_oclsrc={moduleName, "covardata",
"#ifdef BORDER_CONSTANT\n"
"#define EXTRAPOLATE(x, maxV)\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = clamp((x), 0, (maxV)-1); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = ( (x) + (maxV) ) % (maxV); \\\n"
"}\n"
"#elif defined BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = min( mad24((maxV)-1,2,-(x))+1 , max((x),-(x)-1) ); \\\n"
"}\n"
"#elif defined BORDER_REFLECT_101 || defined BORDER_REFLECT101\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = min( mad24((maxV)-1,2,-(x)), max((x),-(x)) ); \\\n"
"}\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#define SRC(_x,_y) convert_float(((global SRCTYPE*)(Src+(_y)*src_step))[_x])\n"
"#ifdef BORDER_CONSTANT\n"
"#define ELEM(_x,_y,r_edge,t_edge,const_v) (_x)<0 | (_x) >= (r_edge) | (_y)<0 | (_y) >= (t_edge) ? (const_v) : SRC((_x),(_y))\n"
"#else\n"
"#define ELEM(_x,_y,r_edge,t_edge,const_v) SRC((_x),(_y))\n"
"#endif\n"
"#define DSTX(_x,_y) (((global float*)(DstX+DstXOffset+(_y)*DstXPitch))[_x])\n"
"#define DSTY(_x,_y) (((global float*)(DstY+DstYOffset+(_y)*DstYPitch))[_x])\n"
"#define INIT_AND_READ_LOCAL_SOURCE(width, height, fill_const, kernel_border) \\\n"
"int srcX = x + srcOffsetX - (kernel_border); \\\n"
"int srcY = y + srcOffsetY - (kernel_border); \\\n"
"int xb = srcX; \\\n"
"int yb = srcY; \\\n"
"\\\n"
"EXTRAPOLATE(xb, (width)); \\\n"
"EXTRAPOLATE(yb, (height)); \\\n"
"lsmem[liy][lix] = ELEM(xb, yb, (width), (height), (fill_const) ); \\\n"
"\\\n"
"if(lix < ((kernel_border)*2)) \\\n"
"{ \\\n"
"int xb = srcX+BLK_X; \\\n"
"EXTRAPOLATE(xb,(width)); \\\n"
"lsmem[liy][lix+BLK_X] = ELEM(xb, yb, (width), (height), (fill_const) ); \\\n"
"} \\\n"
"if(liy< ((kernel_border)*2)) \\\n"
"{ \\\n"
"int yb = srcY+BLK_Y; \\\n"
"EXTRAPOLATE(yb, (height)); \\\n"
"lsmem[liy+BLK_Y][lix] = ELEM(xb, yb, (width), (height), (fill_const) ); \\\n"
"} \\\n"
"if(lix<((kernel_border)*2) && liy<((kernel_border)*2)) \\\n"
"{ \\\n"
"int xb = srcX+BLK_X; \\\n"
"int yb = srcY+BLK_Y; \\\n"
"EXTRAPOLATE(xb,(width)); \\\n"
"EXTRAPOLATE(yb,(height)); \\\n"
"lsmem[liy+BLK_Y][lix+BLK_X] = ELEM(xb, yb, (width), (height), (fill_const) ); \\\n"
"}\n"
"__kernel void sobel3(__global const uchar * Src, int src_step, int srcOffsetX, int srcOffsetY,\n"
"__global uchar * DstX, int DstXPitch, int DstXOffset,\n"
"__global uchar * DstY, int DstYPitch, int DstYOffset, int dstHeight, int dstWidth,\n"
"int height, int width, float scale)\n"
"{\n"
"__local float lsmem[BLK_Y+2][BLK_X+2];\n"
"int lix = get_local_id(0);\n"
"int liy = get_local_id(1);\n"
"int x = (int)get_global_id(0);\n"
"int y = (int)get_global_id(1);\n"
"INIT_AND_READ_LOCAL_SOURCE(width, height, 0, 1)\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if( x >= dstWidth || y >=dstHeight )  return;\n"
"float u1 = lsmem[liy][lix];\n"
"float u2 = lsmem[liy][lix+1];\n"
"float u3 = lsmem[liy][lix+2];\n"
"float m1 = lsmem[liy+1][lix];\n"
"float m3 = lsmem[liy+1][lix+2];\n"
"float b1 = lsmem[liy+2][lix];\n"
"float b2 = lsmem[liy+2][lix+1];\n"
"float b3 = lsmem[liy+2][lix+2];\n"
"#ifdef SCHARR\n"
"DSTX(x,y) = mad(10.0f, m3 - m1, 3.0f * (u3 - u1 + b3 - b1)) * scale;\n"
"DSTY(x,y) = mad(10.0f, b2 - u2, 3.0f * (b1 - u1 + b3 - u3)) * scale;\n"
"#else\n"
"DSTX(x,y) = mad(2.0f, m3 - m1, u3 - u1 + b3 - b1) * scale;\n"
"DSTY(x,y) = mad(2.0f, b2 - u2, b1 - u1 + b3 - u3) * scale;\n"
"#endif\n"
"}\n"
"__kernel void sobel5(__global const uchar * Src, int src_step, int srcOffsetX, int srcOffsetY,\n"
"__global uchar * DstX, int DstXPitch, int DstXOffset,\n"
"__global uchar * DstY, int DstYPitch, int DstYOffset, int dstHeight, int dstWidth,\n"
"int height, int width, float scale)\n"
"{\n"
"__local float lsmem[BLK_Y+4][BLK_X+4];\n"
"int lix = get_local_id(0);\n"
"int liy = get_local_id(1);\n"
"int x = (int)get_global_id(0);\n"
"int y = (int)get_global_id(1);\n"
"INIT_AND_READ_LOCAL_SOURCE(width, height, 0, 2)\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if( x >= dstWidth || y >=dstHeight )  return;\n"
"float t1 = lsmem[liy][lix];\n"
"float t2 = lsmem[liy][lix+1];\n"
"float t3 = lsmem[liy][lix+2];\n"
"float t4 = lsmem[liy][lix+3];\n"
"float t5 = lsmem[liy][lix+4];\n"
"float u1 = lsmem[liy+1][lix];\n"
"float u2 = lsmem[liy+1][lix+1];\n"
"float u3 = lsmem[liy+1][lix+2];\n"
"float u4 = lsmem[liy+1][lix+3];\n"
"float u5 = lsmem[liy+1][lix+4];\n"
"float m1 = lsmem[liy+2][lix];\n"
"float m2 = lsmem[liy+2][lix+1];\n"
"float m4 = lsmem[liy+2][lix+3];\n"
"float m5 = lsmem[liy+2][lix+4];\n"
"float l1 = lsmem[liy+3][lix];\n"
"float l2 = lsmem[liy+3][lix+1];\n"
"float l3 = lsmem[liy+3][lix+2];\n"
"float l4 = lsmem[liy+3][lix+3];\n"
"float l5 = lsmem[liy+3][lix+4];\n"
"float b1 = lsmem[liy+4][lix];\n"
"float b2 = lsmem[liy+4][lix+1];\n"
"float b3 = lsmem[liy+4][lix+2];\n"
"float b4 = lsmem[liy+4][lix+3];\n"
"float b5 = lsmem[liy+4][lix+4];\n"
"DSTX(x,y) = scale *\n"
"mad(12.0f, m4 - m2,\n"
"mad(6.0f, m5 - m1,\n"
"mad(8.0f, u4 - u2 + l4 - l2,\n"
"mad(4.0f, u5 - u1 + l5 - l1,\n"
"mad(2.0f, t4 - t2 + b4 - b2, t5 - t1 + b5 - b1 )\n"
")\n"
")\n"
")\n"
");\n"
"DSTY(x,y) = scale *\n"
"mad(12.0f, l3 - u3,\n"
"mad(6.0f, b3 - t3,\n"
"mad(8.0f, l2 - u2 + l4 - u4,\n"
"mad(4.0f, b2 - t2 + b4 - t4,\n"
"mad(2.0f, l1 - u1 + l5 - u5, b1 - t1 + b5 - t5 )\n"
")\n"
")\n"
")\n"
");\n"
"}\n"
"__kernel void sobel7(__global const uchar * Src, int src_step, int srcOffsetX, int srcOffsetY,\n"
"__global uchar * DstX, int DstXPitch, int DstXOffset,\n"
"__global uchar * DstY, int DstYPitch, int DstYOffset, int dstHeight, int dstWidth,\n"
"int height, int width, float scale)\n"
"{\n"
"__local float lsmem[BLK_Y+6][BLK_X+6];\n"
"int lix = get_local_id(0);\n"
"int liy = get_local_id(1);\n"
"int x = (int)get_global_id(0);\n"
"int y = (int)get_global_id(1);\n"
"INIT_AND_READ_LOCAL_SOURCE(width, height, 0, 3)\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if( x >= dstWidth || y >=dstHeight )  return;\n"
"float tt1 = lsmem[liy][lix];\n"
"float tt2 = lsmem[liy][lix+1];\n"
"float tt3 = lsmem[liy][lix+2];\n"
"float tt4 = lsmem[liy][lix+3];\n"
"float tt5 = lsmem[liy][lix+4];\n"
"float tt6 = lsmem[liy][lix+5];\n"
"float tt7 = lsmem[liy][lix+6];\n"
"float t1 = lsmem[liy+1][lix];\n"
"float t2 = lsmem[liy+1][lix+1];\n"
"float t3 = lsmem[liy+1][lix+2];\n"
"float t4 = lsmem[liy+1][lix+3];\n"
"float t5 = lsmem[liy+1][lix+4];\n"
"float t6 = lsmem[liy+1][lix+5];\n"
"float t7 = lsmem[liy+1][lix+6];\n"
"float u1 = lsmem[liy+2][lix];\n"
"float u2 = lsmem[liy+2][lix+1];\n"
"float u3 = lsmem[liy+2][lix+2];\n"
"float u4 = lsmem[liy+2][lix+3];\n"
"float u5 = lsmem[liy+2][lix+4];\n"
"float u6 = lsmem[liy+2][lix+5];\n"
"float u7 = lsmem[liy+2][lix+6];\n"
"float m1 = lsmem[liy+3][lix];\n"
"float m2 = lsmem[liy+3][lix+1];\n"
"float m3 = lsmem[liy+3][lix+2];\n"
"float m5 = lsmem[liy+3][lix+4];\n"
"float m6 = lsmem[liy+3][lix+5];\n"
"float m7 = lsmem[liy+3][lix+6];\n"
"float l1 = lsmem[liy+4][lix];\n"
"float l2 = lsmem[liy+4][lix+1];\n"
"float l3 = lsmem[liy+4][lix+2];\n"
"float l4 = lsmem[liy+4][lix+3];\n"
"float l5 = lsmem[liy+4][lix+4];\n"
"float l6 = lsmem[liy+4][lix+5];\n"
"float l7 = lsmem[liy+4][lix+6];\n"
"float b1 = lsmem[liy+5][lix];\n"
"float b2 = lsmem[liy+5][lix+1];\n"
"float b3 = lsmem[liy+5][lix+2];\n"
"float b4 = lsmem[liy+5][lix+3];\n"
"float b5 = lsmem[liy+5][lix+4];\n"
"float b6 = lsmem[liy+5][lix+5];\n"
"float b7 = lsmem[liy+5][lix+6];\n"
"float bb1 = lsmem[liy+6][lix];\n"
"float bb2 = lsmem[liy+6][lix+1];\n"
"float bb3 = lsmem[liy+6][lix+2];\n"
"float bb4 = lsmem[liy+6][lix+3];\n"
"float bb5 = lsmem[liy+6][lix+4];\n"
"float bb6 = lsmem[liy+6][lix+5];\n"
"float bb7 = lsmem[liy+6][lix+6];\n"
"DSTX(x,y) = scale *\n"
"mad(100.0f, m5 - m3,\n"
"mad(80.0f, m6 - m2,\n"
"mad(20.0f, m7 - m1,\n"
"mad(75.0f, u5 - u3 + l5 - l3,\n"
"mad(60.0f, u6 - u2 + l6 - l2,\n"
"mad(15.0f, u7 - u1 + l7 - l1,\n"
"mad(30.0f, t5 - t3 + b5 - b3,\n"
"mad(24.0f, t6 - t2 + b6 - b2,\n"
"mad(6.0f, t7 - t1 + b7 - b1,\n"
"mad(5.0f, tt5 - tt3 + bb5 - bb3,\n"
"mad(4.0f, tt6 - tt2 + bb6 - bb2, tt7 - tt1 + bb7 - bb1 )\n"
")\n"
")\n"
")\n"
")\n"
")\n"
")\n"
")\n"
")\n"
")\n"
");\n"
"DSTY(x,y) = scale *\n"
"mad(100.0f, l4 - u4,\n"
"mad(80.0f, b4 - t4,\n"
"mad(20.0f, bb4 - tt4,\n"
"mad(75.0f, l5 - u5 + l3 - u3,\n"
"mad(60.0f, b5 - t5 + b3 - t3,\n"
"mad(15.0f, bb5 - tt5 + bb3 - tt3,\n"
"mad(30.0f, l6 - u6 + l2 - u2,\n"
"mad(24.0f, b6 - t6 + b2 - t2,\n"
"mad(6.0f, bb6 - tt6 + bb2 - tt2,\n"
"mad(5.0f, l7 - u7 + l1 - u1,\n"
"mad(4.0f, b7 - t7 + b1 - t1, bb7 - tt7 + bb1 - tt1 )\n"
")\n"
")\n"
")\n"
")\n"
")\n"
")\n"
")\n"
")\n"
")\n"
");\n"
"}\n"
, "97cb1ffd4e7c1bc93caba596bf9c6e55", NULL};
struct cv::ocl::internal::ProgramEntry filter2D_oclsrc={moduleName, "filter2D",
"#ifdef EXTRA_EXTRAPOLATION\n"
"#ifdef BORDER_CONSTANT\n"
"#define EXTRAPOLATE(x, minV, maxV)\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, minV, maxV) \\\n"
"{ \\\n"
"(x) = clamp((x), (minV), (maxV)-1); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, minV, maxV) \\\n"
"{ \\\n"
"if ((x) < (minV)) \\\n"
"(x) += ((maxV) - (minV)); \\\n"
"if ((x) >= (maxV)) \\\n"
"(x) -= ((maxV) - (minV)); \\\n"
"}\n"
"#elif defined BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, minV, maxV) \\\n"
"{ \\\n"
"if ((maxV) - (minV) == 1) \\\n"
"(x) = (minV); \\\n"
"else \\\n"
"while ((x) >= (maxV) || (x) < (minV)) \\\n"
"{ \\\n"
"if ((x) < (minV)) \\\n"
"(x) = (minV) - ((x) - (minV)) - 1; \\\n"
"else \\\n"
"(x) = (maxV) - 1 - ((x) - (maxV)); \\\n"
"} \\\n"
"}\n"
"#elif defined BORDER_REFLECT_101 || defined BORDER_REFLECT101\n"
"#define EXTRAPOLATE(x, minV, maxV) \\\n"
"{ \\\n"
"if ((maxV) - (minV) == 1) \\\n"
"(x) = (minV); \\\n"
"else \\\n"
"while ((x) >= (maxV) || (x) < (minV)) \\\n"
"{ \\\n"
"if ((x) < (minV)) \\\n"
"(x) = (minV) - ((x) - (minV)); \\\n"
"else \\\n"
"(x) = (maxV) - 1 - ((x) - (maxV)) - 1; \\\n"
"} \\\n"
"}\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#else\n"
"#ifdef BORDER_CONSTANT\n"
"#define EXTRAPOLATE(x, minV, maxV)\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, minV, maxV) \\\n"
"{ \\\n"
"(x) = clamp((x), (minV), (maxV)-1); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, minV, maxV) \\\n"
"{ \\\n"
"if ((x) < (minV)) \\\n"
"(x) += (((minV) - (x)) / ((maxV) - (minV)) + 1) * ((maxV) - (minV)); \\\n"
"if ((x) >= (maxV)) \\\n"
"(x) = ((x) - (minV)) % ((maxV) - (minV)) + (minV); \\\n"
"}\n"
"#elif defined BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, minV, maxV) \\\n"
"{ \\\n"
"(x) = clamp((x), 2 * (minV) - (x) - 1, 2 * (maxV) - (x) - 1); \\\n"
"}\n"
"#elif defined BORDER_REFLECT_101 || defined BORDER_REFLECT101\n"
"#define EXTRAPOLATE(x, minV, maxV) \\\n"
"{ \\\n"
"(x) = clamp((x), 2 * (minV) - (x), 2 * (maxV) - (x) - 2); \\\n"
"}\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#endif\n"
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#if cn != 3\n"
"#define loadpix(addr) *(__global const srcT *)(addr)\n"
"#define storepix(val, addr)  *(__global dstT *)(addr) = val\n"
"#define SRCSIZE (int)sizeof(srcT)\n"
"#define DSTSIZE (int)sizeof(dstT)\n"
"#else\n"
"#define loadpix(addr) vload3(0, (__global const srcT1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global dstT1 *)(addr))\n"
"#define SRCSIZE (int)sizeof(srcT1) * cn\n"
"#define DSTSIZE (int)sizeof(dstT1) * cn\n"
"#endif\n"
"#define UPDATE_COLUMN_SUM(col) \\\n"
"__constant WT1 * k = &kernelData[KERNEL_SIZE_Y2_ALIGNED * col]; \\\n"
"WT tmp_sum = 0;                                                 \\\n"
"for (int sy = 0; sy < KERNEL_SIZE_Y; sy++)                      \\\n"
"tmp_sum += data[sy] * k[sy];                                \\\n"
"sumOfCols[local_id] = tmp_sum;                                  \\\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"#define UPDATE_TOTAL_SUM(col) \\\n"
"int id = local_id + col - ANCHOR_X; \\\n"
"if (id >= 0 && id < LOCAL_SIZE)     \\\n"
"total_sum += sumOfCols[id];     \\\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"#define noconvert\n"
"#define DIG(a) a,\n"
"__constant WT1 kernelData[] = { COEFF };\n"
"__kernel void filter2D(__global const uchar * srcptr, int src_step, int srcOffsetX, int srcOffsetY, int srcEndX, int srcEndY,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int rows, int cols, float delta)\n"
"{\n"
"int local_id = get_local_id(0);\n"
"int x = local_id + (LOCAL_SIZE - (KERNEL_SIZE_X - 1)) * get_group_id(0) - ANCHOR_X;\n"
"int y = get_global_id(1);\n"
"WT data[KERNEL_SIZE_Y];\n"
"__local WT sumOfCols[LOCAL_SIZE];\n"
"#ifdef BORDER_ISOLATED\n"
"int srcBeginX = srcOffsetX;\n"
"int srcBeginY = srcOffsetY;\n"
"#else\n"
"int srcBeginX = 0;\n"
"int srcBeginY = 0;\n"
"#endif\n"
"int srcX = srcOffsetX + x;\n"
"int srcY = srcOffsetY + y - ANCHOR_Y;\n"
"__global dstT *dst = (__global dstT *)(dstptr + mad24(y, dst_step, mad24(x, DSTSIZE, dst_offset)));\n"
"#ifdef BORDER_CONSTANT\n"
"if (srcX >= srcBeginX && srcX < srcEndX)\n"
"{\n"
"for (int sy = 0, sy_index = 0; sy < KERNEL_SIZE_Y; sy++, srcY++)\n"
"{\n"
"if (srcY >= srcBeginY && srcY < srcEndY)\n"
"data[sy + sy_index] = convertToWT(loadpix(srcptr + mad24(srcY, src_step, srcX * SRCSIZE)));\n"
"else\n"
"data[sy + sy_index] = (WT)(0);\n"
"}\n"
"}\n"
"else\n"
"{\n"
"for (int sy = 0, sy_index = 0; sy < KERNEL_SIZE_Y; sy++, srcY++)\n"
"{\n"
"data[sy + sy_index] = (WT)(0);\n"
"}\n"
"}\n"
"#else\n"
"EXTRAPOLATE(srcX, srcBeginX, srcEndX);\n"
"for (int sy = 0, sy_index = 0; sy < KERNEL_SIZE_Y; sy++, srcY++)\n"
"{\n"
"int tempY = srcY;\n"
"EXTRAPOLATE(tempY, srcBeginY, srcEndY);\n"
"data[sy + sy_index] = convertToWT(loadpix(srcptr + mad24(tempY, src_step, srcX * SRCSIZE)));\n"
"}\n"
"#endif\n"
"WT total_sum = 0;\n"
"for (int sx = 0; sx < ANCHOR_X; sx++)\n"
"{\n"
"UPDATE_COLUMN_SUM(sx);\n"
"UPDATE_TOTAL_SUM(sx);\n"
"}\n"
"__constant WT1 * k = &kernelData[KERNEL_SIZE_Y2_ALIGNED * ANCHOR_X];\n"
"for (int sy = 0; sy < KERNEL_SIZE_Y; sy++)\n"
"total_sum += data[sy] * k[sy];\n"
"for (int sx = ANCHOR_X + 1; sx < KERNEL_SIZE_X; sx++)\n"
"{\n"
"UPDATE_COLUMN_SUM(sx);\n"
"UPDATE_TOTAL_SUM(sx);\n"
"}\n"
"if (local_id >= ANCHOR_X && local_id < LOCAL_SIZE - (KERNEL_SIZE_X - 1 - ANCHOR_X) && x >= 0 && x < cols)\n"
"storepix(convertToDstT(total_sum + (WT)(delta)), dst);\n"
"}\n"
, "77e935928055f243ff9082b1879a0b2c", NULL};
struct cv::ocl::internal::ProgramEntry filter2DSmall_oclsrc={moduleName, "filter2DSmall",
"#ifdef BORDER_REPLICATE\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? (l_edge)   : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? (r_edge)-1 : (addr))\n"
"#define ADDR_H(i, t_edge, b_edge)  ((i) <  (t_edge) ? (t_edge)   :(i))\n"
"#define ADDR_B(i, b_edge, addr)    ((i) >= (b_edge) ? (b_edge)-1 :(addr))\n"
"#endif\n"
"#ifdef BORDER_REFLECT\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? -(i)-1               : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? -(i)-1+((r_edge)<<1) : (addr))\n"
"#define ADDR_H(i, t_edge, b_edge)  ((i) <  (t_edge) ? -(i)-1 : (i))\n"
"#define ADDR_B(i, b_edge, addr)    ((i) >= (b_edge) ? -(i)-1+((b_edge)<<1) : (addr))\n"
"#endif\n"
"#ifdef BORDER_REFLECT_101\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? -(i)                 : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? -(i)-2+((r_edge)<<1) : (addr))\n"
"#define ADDR_H(i, t_edge, b_edge)  ((i) <  (t_edge) ? -(i)                 : (i))\n"
"#define ADDR_B(i, b_edge, addr)    ((i) >= (b_edge) ? -(i)-2+((b_edge)<<1) : (addr))\n"
"#endif\n"
"#ifdef BORDER_WRAP\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? (i)+(r_edge) : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? (i)-(r_edge) : (addr))\n"
"#define ADDR_H(i, t_edge, b_edge)  ((i) <  (t_edge) ? (i)+(b_edge) : (i))\n"
"#define ADDR_B(i, b_edge, addr)    ((i) >= (b_edge) ? (i)-(b_edge) : (addr))\n"
"#endif\n"
"#ifdef BORDER_ISOLATED\n"
"#define ISOLATED_MIN(VAL) (VAL)\n"
"#else\n"
"#define ISOLATED_MIN(VAL) 0\n"
"#endif\n"
"#ifdef EXTRA_EXTRAPOLATION\n"
"#ifdef BORDER_CONSTANT\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) \\\n"
"{ \\\n"
"x = max(min(x, maxX - 1), minX); \\\n"
"y = max(min(y, maxY - 1), minY); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) \\\n"
"{ \\\n"
"if (x < minX) \\\n"
"x -= ((x - maxX + 1) / maxX) * maxX; \\\n"
"if (x >= maxX) \\\n"
"x %= maxX; \\\n"
"if (y < minY) \\\n"
"y -= ((y - maxY + 1) / maxY) * maxY; \\\n"
"if (y >= maxY) \\\n"
"y %= maxY; \\\n"
"}\n"
"#elif defined(BORDER_REFLECT) || defined(BORDER_REFLECT_101)\n"
"#define EXTRAPOLATE_(x, y, minX, minY, maxX, maxY, delta) \\\n"
"{ \\\n"
"if (maxX - minX == 1) \\\n"
"x = minX; \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if (x < minX) \\\n"
"x = minX - (x - minX) - 1 + delta; \\\n"
"else \\\n"
"x = maxX - 1 - (x - maxX) - delta; \\\n"
"} \\\n"
"while (x >= maxX || x < minX); \\\n"
"\\\n"
"if (maxY - minY == 1) \\\n"
"y = minY; \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if (y < minY) \\\n"
"y = minY - (y - minY) - 1 + delta; \\\n"
"else \\\n"
"y = maxY - 1 - (y - maxY) - delta; \\\n"
"} \\\n"
"while (y >= maxY || y < minY); \\\n"
"}\n"
"#ifdef BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) EXTRAPOLATE_(x, y, minX, minY, maxX, maxY, 0)\n"
"#elif defined(BORDER_REFLECT_101) || defined(BORDER_REFLECT101)\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) EXTRAPOLATE_(x, y, minX, minY, maxX, maxY, 1)\n"
"#endif\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#else\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) \\\n"
"{ \\\n"
"int _row = y - ISOLATED_MIN(minY), _col = x - ISOLATED_MIN(minX); \\\n"
"_row = ADDR_H(_row, 0, maxY - ISOLATED_MIN(minY)); \\\n"
"_row = ADDR_B(_row, maxY - ISOLATED_MIN(minY), _row); \\\n"
"y = _row + ISOLATED_MIN(minY); \\\n"
"\\\n"
"_col = ADDR_L(_col, 0, maxX - ISOLATED_MIN(minX)); \\\n"
"_col = ADDR_R(_col, maxX - ISOLATED_MIN(minX), _col); \\\n"
"x = _col + ISOLATED_MIN(minX); \\\n"
"}\n"
"#endif\n"
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#if cn != 3\n"
"#define loadpix(addr) *(__global const srcT *)(addr)\n"
"#define storepix(val, addr)  *(__global dstT *)(addr) = val\n"
"#define SRCSIZE (int)sizeof(srcT)\n"
"#define DSTSIZE (int)sizeof(dstT)\n"
"#else\n"
"#define loadpix(addr) vload3(0, (__global const srcT1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global dstT1 *)(addr))\n"
"#define SRCSIZE (int)sizeof(srcT1) * cn\n"
"#define DSTSIZE (int)sizeof(dstT1) * cn\n"
"#endif\n"
"#define noconvert\n"
"struct RectCoords\n"
"{\n"
"int x1, y1, x2, y2;\n"
"};\n"
"#ifdef BORDER_ISOLATED\n"
"inline bool isBorder(const struct RectCoords bounds, int2 coord, int numPixels)\n"
"{\n"
"return (coord.x < bounds.x1 || coord.y < bounds.y1 || coord.x + numPixels > bounds.x2 || coord.y >= bounds.y2);\n"
"}\n"
"#else\n"
"inline bool isBorder(const struct RectCoords bounds, int2 coord, int numPixels)\n"
"{\n"
"return (coord.x < 0 || coord.y < 0 || coord.x + numPixels > bounds.x2 || coord.y >= bounds.y2);\n"
"}\n"
"#endif\n"
"inline WT getBorderPixel(const struct RectCoords bounds, int2 coord,\n"
"__global const uchar* srcptr, int srcstep)\n"
"{\n"
"#ifdef BORDER_CONSTANT\n"
"return (WT)(0);\n"
"#else\n"
"int selected_col = coord.x;\n"
"int selected_row = coord.y;\n"
"EXTRAPOLATE(selected_col, selected_row,\n"
"bounds.x1, bounds.y1,\n"
"bounds.x2, bounds.y2\n"
");\n"
"coord = (int2)(selected_col, selected_row);\n"
"__global const uchar* ptr = srcptr + mul24(coord.y, srcstep) +\n"
"coord.x * SRCSIZE;\n"
"return convertToWT(loadpix(ptr));\n"
"#endif\n"
"}\n"
"inline WT readSrcPixelSingle(int2 pos, __global const uchar* srcptr,\n"
"int srcstep, const struct RectCoords srcCoords)\n"
"{\n"
"if (!isBorder(srcCoords, pos, 1))\n"
"{\n"
"__global const uchar* ptr = srcptr + mul24(pos.y, srcstep) +\n"
"pos.x * SRCSIZE;\n"
"return convertToWT(loadpix(ptr));\n"
"}\n"
"else\n"
"{\n"
"return getBorderPixel(srcCoords, pos, srcptr, srcstep);\n"
"}\n"
"}\n"
"#define __CAT(x, y) x##y\n"
"#define CAT(x, y) __CAT(x, y)\n"
"#define vload1(OFFSET, PTR) (*(PTR + OFFSET))\n"
"#define PX_LOAD_VEC_TYPE CAT(srcT1, PX_LOAD_VEC_SIZE)\n"
"#define PX_LOAD_FLOAT_VEC_TYPE CAT(WT1, PX_LOAD_VEC_SIZE)\n"
"#if PX_LOAD_VEC_SIZE == 1\n"
"#define PX_LOAD_FLOAT_VEC_CONV (float)\n"
"#elif PX_LOAD_VEC_SIZE == 2\n"
"#define PX_LOAD_FLOAT_VEC_CONV convert_float2\n"
"#elif PX_LOAD_VEC_SIZE == 3\n"
"#define PX_LOAD_FLOAT_VEC_CONV convert_float3\n"
"#elif PX_LOAD_VEC_SIZE == 4\n"
"#define PX_LOAD_FLOAT_VEC_CONV convert_float4\n"
"#endif\n"
"#define PX_LOAD CAT(vload, PX_LOAD_VEC_SIZE)\n"
"#define float1 float\n"
"inline PX_LOAD_FLOAT_VEC_TYPE readSrcPixelGroup(int2 pos, __global const uchar* srcptr,\n"
"int srcstep, const struct RectCoords srcCoords)\n"
"{\n"
"__global const srcT1* ptr = (__global const srcT1*)\n"
"(srcptr + mul24(pos.y, srcstep) +\n"
"pos.x * SRCSIZE);\n"
"return PX_LOAD_FLOAT_VEC_CONV(PX_LOAD(0, ptr));\n"
"}\n"
"#define LOOP1(VAR, STMT) (STMT); (VAR)++;\n"
"#define LOOP2(VAR, STMT) LOOP1(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP3(VAR, STMT) LOOP2(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP4(VAR, STMT) LOOP3(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP5(VAR, STMT) LOOP4(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP6(VAR, STMT) LOOP5(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP7(VAR, STMT) LOOP6(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP8(VAR, STMT) LOOP7(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP9(VAR, STMT) LOOP8(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP10(VAR, STMT) LOOP9(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP11(VAR, STMT) LOOP10(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP12(VAR, STMT) LOOP11(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP13(VAR, STMT) LOOP12(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP(N, VAR, STMT) CAT(LOOP, N)((VAR), (STMT))\n"
"#define DIG(a) a,\n"
"__constant WT1 kernelData[] = { COEFF };\n"
"__kernel void filter2DSmall(__global const uchar * srcptr, int src_step, int srcOffsetX, int srcOffsetY, int srcEndX, int srcEndY,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int rows, int cols, float delta)\n"
"{\n"
"const struct RectCoords srcCoords = { srcOffsetX, srcOffsetY, srcEndX, srcEndY };\n"
"const int startX = get_global_id(0) * PX_PER_WI_X;\n"
"const int startY = get_global_id(1) * PX_PER_WI_Y;\n"
"if ((startX >= cols) || (startY >= rows))\n"
"{\n"
"return;\n"
"}\n"
"WT privateData[PX_PER_WI_Y + KERNEL_SIZE_Y - 1][PRIV_DATA_WIDTH];\n"
"int py = 0;\n"
"LOOP(PX_LOAD_Y_ITERATIONS, py,\n"
"{\n"
"int y = startY + py;\n"
"int px = 0;\n"
"LOOP(PX_LOAD_X_ITERATIONS, px,\n"
"{\n"
"int x = startX + (px * PX_LOAD_NUM_PX);\n"
"int2 srcPos = (int2)(srcCoords.x1 + x - ANCHOR_X, srcCoords.y1 + y - ANCHOR_Y);\n"
"if (!isBorder(srcCoords, srcPos, PX_LOAD_NUM_PX))\n"
"{\n"
"PX_LOAD_FLOAT_VEC_TYPE p = readSrcPixelGroup(srcPos, srcptr, src_step, srcCoords);\n"
"*((PX_LOAD_FLOAT_VEC_TYPE*)&privateData[py][px * PX_LOAD_NUM_PX]) = p;\n"
"}\n"
"else\n"
"{\n"
"int lx = 0;\n"
"LOOP(PX_LOAD_NUM_PX, lx,\n"
"{\n"
"WT p = readSrcPixelSingle(srcPos, srcptr, src_step, srcCoords);\n"
"*((WT*)&privateData[py][px * PX_LOAD_NUM_PX + lx]) = p;\n"
"srcPos.x++;\n"
"});\n"
"}\n"
"});\n"
"});\n"
"py = 0;\n"
"LOOP(PX_PER_WI_Y, py,\n"
"{\n"
"int y = startY + py;\n"
"int px = 0;\n"
"LOOP(PX_PER_WI_X, px,\n"
"{\n"
"int x = startX + px;\n"
"WT total_sum = 0;\n"
"int sy = 0;\n"
"int kernelIndex = 0;\n"
"LOOP(KERNEL_SIZE_Y, sy,\n"
"{\n"
"int sx = 0;\n"
"LOOP(KERNEL_SIZE_X, sx,\n"
"{\n"
"total_sum = mad(kernelData[kernelIndex++], privateData[py + sy][px + sx], total_sum);\n"
"});\n"
"});\n"
"__global dstT* dstPtr = (__global dstT*)(dstptr + y * dst_step + dst_offset + x * DSTSIZE);\n"
"storepix(convertToDstT(total_sum + (WT)(delta)), dstPtr);\n"
"});\n"
"});\n"
"}\n"
, "030d23b1d64d51e6485f8941af1e3fc3", NULL};
struct cv::ocl::internal::ProgramEntry filterSepCol_oclsrc={moduleName, "filterSepCol",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#define READ_TIMES_COL ((2*(RADIUSY+LSIZE1)-1)/LSIZE1)\n"
"#define RADIUS 1\n"
"#define noconvert\n"
"#if CN != 3\n"
"#define loadpix(addr) *(__global const srcT *)(addr)\n"
"#define storepix(val, addr)  *(__global dstT *)(addr) = val\n"
"#define SRCSIZE (int)sizeof(srcT)\n"
"#define DSTSIZE (int)sizeof(dstT)\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const srcT1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global dstT1 *)(addr))\n"
"#define SRCSIZE (int)sizeof(srcT1)*3\n"
"#define DSTSIZE (int)sizeof(dstT1)*3\n"
"#endif\n"
"#define DIG(a) a,\n"
"#if defined(INTEGER_ARITHMETIC)\n"
"__constant int mat_kernel[] = { COEFF };\n"
"#else\n"
"__constant srcT1 mat_kernel[] = { COEFF };\n"
"#endif\n"
"__kernel void col_filter(__global const uchar * src, int src_step, int src_offset, int src_whole_rows, int src_whole_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols, float delta)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"int l_x = get_local_id(0);\n"
"int l_y = get_local_id(1);\n"
"int start_addr = mad24(y, src_step, x * SRCSIZE);\n"
"int end_addr = mad24(src_whole_rows - 1, src_step, src_whole_cols * SRCSIZE);\n"
"srcT sum, temp[READ_TIMES_COL];\n"
"__local srcT LDS_DAT[LSIZE1 * READ_TIMES_COL][LSIZE0 + 1];\n"
"for (int i = 0; i < READ_TIMES_COL; ++i)\n"
"{\n"
"int current_addr = mad24(i, LSIZE1 * src_step, start_addr);\n"
"current_addr = current_addr < end_addr ? current_addr : 0;\n"
"temp[i] = loadpix(src + current_addr);\n"
"}\n"
"for (int i = 0; i < READ_TIMES_COL; ++i)\n"
"LDS_DAT[mad24(i, LSIZE1, l_y)][l_x] = temp[i];\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"sum = LDS_DAT[l_y + RADIUSY][l_x] * mat_kernel[RADIUSY] + (srcT)delta;\n"
"for (int i = 1; i <= RADIUSY; ++i)\n"
"{\n"
"temp[0] = LDS_DAT[l_y + RADIUSY - i][l_x];\n"
"temp[1] = LDS_DAT[l_y + RADIUSY + i][l_x];\n"
"#if defined(INTEGER_ARITHMETIC)\n"
"sum += mad24(temp[0],mat_kernel[RADIUSY - i], temp[1] * mat_kernel[RADIUSY + i]);\n"
"#else\n"
"sum += mad(temp[0], mat_kernel[RADIUSY - i], temp[1] * mat_kernel[RADIUSY + i]);\n"
"#endif\n"
"}\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"#if defined(SHIFT_BITS) && SHIFT_BITS > 0\n"
"dstT result = convertToDstT(convertToFloatT(sum) * (floatT)(1.0f / (1 << SHIFT_BITS)));\n"
"#else\n"
"dstT result = convertToDstT(sum);\n"
"#endif\n"
"start_addr = mad24(y, dst_step, mad24(DSTSIZE, x, dst_offset));\n"
"storepix(result, dst + start_addr);\n"
"}\n"
"}\n"
, "ab9607013c121ef09706d5eddedeebe9", NULL};
struct cv::ocl::internal::ProgramEntry filterSepRow_oclsrc={moduleName, "filterSepRow",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#define READ_TIMES_ROW ((2*(RADIUSX+LSIZE0)-1)/LSIZE0)\n"
"#define RADIUS 1\n"
"#ifdef BORDER_REPLICATE\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? (l_edge)   : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? (r_edge)-1 : (addr))\n"
"#endif\n"
"#ifdef BORDER_REFLECT\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? -(i)-1               : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? -(i)-1+((r_edge)<<1) : (addr))\n"
"#endif\n"
"#ifdef BORDER_REFLECT_101\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? -(i)                 : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? -(i)-2+((r_edge)<<1) : (addr))\n"
"#endif\n"
"#ifdef BORDER_WRAP\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? (i)+(r_edge) : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? (i)-(r_edge) : (addr))\n"
"#endif\n"
"#ifdef EXTRA_EXTRAPOLATION\n"
"#ifdef BORDER_CONSTANT\n"
"#define ELEM(i,l_edge,r_edge,elem1,elem2) (i)<(l_edge) | (i) >= (r_edge) ? (elem1) : (elem2)\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(t, minT, maxT) \\\n"
"{ \\\n"
"t = max(min(t, (maxT) - 1), (minT)); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, minT, maxT) \\\n"
"{ \\\n"
"if (t < (minT)) \\\n"
"t -= ((t - (maxT) + 1) / (maxT)) * (maxT); \\\n"
"if (t >= (maxT)) \\\n"
"t %= (maxT); \\\n"
"}\n"
"#elif defined(BORDER_REFLECT) || defined(BORDER_REFLECT_101)\n"
"#define EXTRAPOLATE_(t, minT, maxT, delta) \\\n"
"{ \\\n"
"if ((maxT) - (minT) == 1) \\\n"
"t = (minT); \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if (t < (minT)) \\\n"
"t = (minT) - (t - (minT)) - 1 + delta; \\\n"
"else \\\n"
"t = (maxT) - 1 - (t - (maxT)) - delta; \\\n"
"} \\\n"
"while (t >= (maxT) || t < (minT)); \\\n"
"\\\n"
"}\n"
"#ifdef BORDER_REFLECT\n"
"#define EXTRAPOLATE(t, minT, maxT) EXTRAPOLATE_(t, minT, maxT, 0)\n"
"#elif defined(BORDER_REFLECT_101)\n"
"#define EXTRAPOLATE(t, minT, maxT) EXTRAPOLATE_(t, minT, maxT, 1)\n"
"#endif\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#else\n"
"#ifdef BORDER_CONSTANT\n"
"#define ELEM(i,l_edge,r_edge,elem1,elem2) (i)<(l_edge) | (i) >= (r_edge) ? (elem1) : (elem2)\n"
"#else\n"
"#define EXTRAPOLATE(t, minT, maxT) \\\n"
"{ \\\n"
"int _delta = t - (minT); \\\n"
"_delta = ADDR_L(_delta, 0, (maxT) - (minT)); \\\n"
"_delta = ADDR_R(_delta, (maxT) - (minT), _delta); \\\n"
"t = _delta + (minT); \\\n"
"}\n"
"#endif\n"
"#endif\n"
"#define noconvert\n"
"#if CN != 3\n"
"#define loadpix(addr) *(__global const srcT *)(addr)\n"
"#define storepix(val, addr)  *(__global dstT *)(addr) = val\n"
"#define SRCSIZE (int)sizeof(srcT)\n"
"#define DSTSIZE (int)sizeof(dstT)\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const srcT1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global dstT1 *)(addr))\n"
"#define SRCSIZE (int)sizeof(srcT1)*3\n"
"#define DSTSIZE (int)sizeof(dstT1)*3\n"
"#endif\n"
"#define DIG(a) a,\n"
"#if defined(INTEGER_ARITHMETIC)\n"
"__constant int mat_kernel[] = { COEFF };\n"
"#else\n"
"__constant dstT1 mat_kernel[] = { COEFF };\n"
"#endif\n"
"#if defined(INTEGER_ARITHMETIC)\n"
"#define dstT4 int4\n"
"#define convertDstVec convert_int4\n"
"#else\n"
"#define dstT4 float4\n"
"#define convertDstVec convert_float4\n"
"#endif\n"
"__kernel void row_filter_C1_D0(__global const uchar * src, int src_step_in_pixel, int src_offset_x, int src_offset_y,\n"
"int src_cols, int src_rows, int src_whole_cols, int src_whole_rows,\n"
"__global float * dst, int dst_step_in_pixel, int dst_cols, int dst_rows,\n"
"int radiusy)\n"
"{\n"
"int x = get_global_id(0)<<2;\n"
"int y = get_global_id(1);\n"
"int l_x = get_local_id(0);\n"
"int l_y = get_local_id(1);\n"
"int start_x = x + src_offset_x - RADIUSX & 0xfffffffc;\n"
"int offset = src_offset_x - RADIUSX & 3;\n"
"int start_y = y + src_offset_y - radiusy;\n"
"int start_addr = mad24(start_y, src_step_in_pixel, start_x);\n"
"dstT4 sum;\n"
"uchar4 temp[READ_TIMES_ROW];\n"
"__local uchar4 LDS_DAT[LSIZE1][READ_TIMES_ROW * LSIZE0 + 1];\n"
"#ifdef BORDER_CONSTANT\n"
"int end_addr = mad24(src_whole_rows - 1, src_step_in_pixel, src_whole_cols);\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"{\n"
"int current_addr = mad24(i, LSIZE0 << 2, start_addr);\n"
"current_addr = current_addr < end_addr && current_addr > 0 ? current_addr : 0;\n"
"temp[i] = *(__global const uchar4 *)&src[current_addr];\n"
"}\n"
"#ifdef BORDER_ISOLATED\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"{\n"
"temp[i].x = ELEM(start_x+i*LSIZE0*4,   src_offset_x, src_offset_x + src_cols, 0,         temp[i].x);\n"
"temp[i].y = ELEM(start_x+i*LSIZE0*4+1, src_offset_x, src_offset_x + src_cols, 0,         temp[i].y);\n"
"temp[i].z = ELEM(start_x+i*LSIZE0*4+2, src_offset_x, src_offset_x + src_cols, 0,         temp[i].z);\n"
"temp[i].w = ELEM(start_x+i*LSIZE0*4+3, src_offset_x, src_offset_x + src_cols, 0,         temp[i].w);\n"
"temp[i]   = ELEM(start_y,              src_offset_y, src_offset_y + src_rows, (uchar4)0, temp[i]);\n"
"}\n"
"#else\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"{\n"
"temp[i].x = ELEM(start_x+i*LSIZE0*4,   0, src_whole_cols, 0,         temp[i].x);\n"
"temp[i].y = ELEM(start_x+i*LSIZE0*4+1, 0, src_whole_cols, 0,         temp[i].y);\n"
"temp[i].z = ELEM(start_x+i*LSIZE0*4+2, 0, src_whole_cols, 0,         temp[i].z);\n"
"temp[i].w = ELEM(start_x+i*LSIZE0*4+3, 0, src_whole_cols, 0,         temp[i].w);\n"
"temp[i]   = ELEM(start_y,              0, src_whole_rows, (uchar4)0, temp[i]);\n"
"}\n"
"#endif\n"
"#else\n"
"#ifdef BORDER_ISOLATED\n"
"int not_all_in_range = (start_x<src_offset_x) | (start_x + READ_TIMES_ROW*LSIZE0*4+4>src_offset_x + src_cols)| (start_y<src_offset_y) | (start_y >= src_offset_y + src_rows);\n"
"#else\n"
"int not_all_in_range = (start_x<0) | (start_x + READ_TIMES_ROW*LSIZE0*4+4>src_whole_cols)| (start_y<0) | (start_y >= src_whole_rows);\n"
"#endif\n"
"int4 index[READ_TIMES_ROW], addr;\n"
"int s_y;\n"
"if (not_all_in_range)\n"
"{\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"{\n"
"index[i] = (int4)(mad24(i, LSIZE0 << 2, start_x)) + (int4)(0, 1, 2, 3);\n"
"#ifdef BORDER_ISOLATED\n"
"EXTRAPOLATE(index[i].x, src_offset_x, src_offset_x + src_cols);\n"
"EXTRAPOLATE(index[i].y, src_offset_x, src_offset_x + src_cols);\n"
"EXTRAPOLATE(index[i].z, src_offset_x, src_offset_x + src_cols);\n"
"EXTRAPOLATE(index[i].w, src_offset_x, src_offset_x + src_cols);\n"
"#else\n"
"EXTRAPOLATE(index[i].x, 0, src_whole_cols);\n"
"EXTRAPOLATE(index[i].y, 0, src_whole_cols);\n"
"EXTRAPOLATE(index[i].z, 0, src_whole_cols);\n"
"EXTRAPOLATE(index[i].w, 0, src_whole_cols);\n"
"#endif\n"
"}\n"
"s_y = start_y;\n"
"#ifdef BORDER_ISOLATED\n"
"EXTRAPOLATE(s_y, src_offset_y, src_offset_y + src_rows);\n"
"#else\n"
"EXTRAPOLATE(s_y, 0, src_whole_rows);\n"
"#endif\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"{\n"
"addr = mad24((int4)s_y, (int4)src_step_in_pixel, index[i]);\n"
"temp[i].x = src[addr.x];\n"
"temp[i].y = src[addr.y];\n"
"temp[i].z = src[addr.z];\n"
"temp[i].w = src[addr.w];\n"
"}\n"
"}\n"
"else\n"
"{\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"temp[i] = *(__global uchar4*)&src[mad24(i, LSIZE0 << 2, start_addr)];\n"
"}\n"
"#endif\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"LDS_DAT[l_y][mad24(i, LSIZE0, l_x)] = temp[i];\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"sum = convertDstVec(vload4(0,(__local uchar *)&LDS_DAT[l_y][l_x]+RADIUSX+offset)) * mat_kernel[RADIUSX];\n"
"for (int i = 1; i <= RADIUSX; ++i)\n"
"{\n"
"temp[0] = vload4(0, (__local uchar*)&LDS_DAT[l_y][l_x] + RADIUSX + offset - i);\n"
"temp[1] = vload4(0, (__local uchar*)&LDS_DAT[l_y][l_x] + RADIUSX + offset + i);\n"
"#if defined(INTEGER_ARITHMETIC)\n"
"sum += mad24(convertDstVec(temp[0]), mat_kernel[RADIUSX-i], convertDstVec(temp[1]) * mat_kernel[RADIUSX + i]);\n"
"#else\n"
"sum += mad(convertDstVec(temp[0]), mat_kernel[RADIUSX-i], convertDstVec(temp[1]) * mat_kernel[RADIUSX + i]);\n"
"#endif\n"
"}\n"
"start_addr = mad24(y, dst_step_in_pixel, x);\n"
"if ((x+3<dst_cols) & (y<dst_rows))\n"
"*(__global dstT4*)&dst[start_addr] = sum;\n"
"else if ((x+2<dst_cols) && (y<dst_rows))\n"
"{\n"
"dst[start_addr] = sum.x;\n"
"dst[start_addr+1] = sum.y;\n"
"dst[start_addr+2] = sum.z;\n"
"}\n"
"else if ((x+1<dst_cols) && (y<dst_rows))\n"
"{\n"
"dst[start_addr] = sum.x;\n"
"dst[start_addr+1] = sum.y;\n"
"}\n"
"else if (x<dst_cols && y<dst_rows)\n"
"dst[start_addr] = sum.x;\n"
"}\n"
"__kernel void row_filter(__global const uchar * src, int src_step, int src_offset_x, int src_offset_y,\n"
"int src_cols, int src_rows, int src_whole_cols, int src_whole_rows,\n"
"__global uchar * dst, int dst_step, int dst_cols, int dst_rows,\n"
"int radiusy)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"int l_x = get_local_id(0);\n"
"int l_y = get_local_id(1);\n"
"int start_x = x + src_offset_x - RADIUSX;\n"
"int start_y = y + src_offset_y - radiusy;\n"
"int start_addr = mad24(start_y, src_step, start_x * SRCSIZE);\n"
"dstT sum;\n"
"srcT temp[READ_TIMES_ROW];\n"
"__local srcT LDS_DAT[LSIZE1][READ_TIMES_ROW * LSIZE0 + 1];\n"
"#ifdef BORDER_CONSTANT\n"
"int end_addr = mad24(src_whole_rows - 1, src_step, src_whole_cols * SRCSIZE);\n"
"for (int i = 0; i < READ_TIMES_ROW; i++)\n"
"{\n"
"int current_addr = mad24(i, LSIZE0 * SRCSIZE, start_addr);\n"
"current_addr = current_addr < end_addr && current_addr >= 0 ? current_addr : 0;\n"
"temp[i] = loadpix(src + current_addr);\n"
"}\n"
"#ifdef BORDER_ISOLATED\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"{\n"
"temp[i] = ELEM(mad24(i, LSIZE0, start_x), src_offset_x, src_offset_x + src_cols, (srcT)(0), temp[i]);\n"
"temp[i] = ELEM(start_y,                   src_offset_y, src_offset_y + src_rows, (srcT)(0), temp[i]);\n"
"}\n"
"#else\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"{\n"
"temp[i] = ELEM(mad24(i, LSIZE0, start_x), 0, src_whole_cols, (srcT)(0), temp[i]);\n"
"temp[i] = ELEM(start_y,                   0, src_whole_rows, (srcT)(0), temp[i]);\n"
"}\n"
"#endif\n"
"#else\n"
"int index[READ_TIMES_ROW], s_x, s_y;\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"{\n"
"s_x = mad24(i, LSIZE0, start_x);\n"
"s_y = start_y;\n"
"#ifdef BORDER_ISOLATED\n"
"EXTRAPOLATE(s_x, src_offset_x, src_offset_x + src_cols);\n"
"EXTRAPOLATE(s_y, src_offset_y, src_offset_y + src_rows);\n"
"#else\n"
"EXTRAPOLATE(s_x, 0, src_whole_cols);\n"
"EXTRAPOLATE(s_y, 0, src_whole_rows);\n"
"#endif\n"
"index[i] = mad24(s_y, src_step, s_x * SRCSIZE);\n"
"}\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"temp[i] = loadpix(src + index[i]);\n"
"#endif\n"
"for (int i = 0; i < READ_TIMES_ROW; ++i)\n"
"LDS_DAT[l_y][mad24(i, LSIZE0, l_x)] = temp[i];\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"sum = convertToDstT(LDS_DAT[l_y][l_x + RADIUSX]) * mat_kernel[RADIUSX];\n"
"for (int i = 1; i <= RADIUSX; ++i)\n"
"{\n"
"temp[0] = LDS_DAT[l_y][l_x + RADIUSX - i];\n"
"temp[1] = LDS_DAT[l_y][l_x + RADIUSX + i];\n"
"#if defined(INTEGER_ARITHMETIC)\n"
"sum += mad24(convertToDstT(temp[0]), mat_kernel[RADIUSX - i], convertToDstT(temp[1]) * mat_kernel[RADIUSX + i]);\n"
"#else\n"
"sum += mad(convertToDstT(temp[0]), mat_kernel[RADIUSX - i], convertToDstT(temp[1]) * mat_kernel[RADIUSX + i]);\n"
"#endif\n"
"}\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"start_addr = mad24(y, dst_step, x * DSTSIZE);\n"
"storepix(sum, dst + start_addr);\n"
"}\n"
"}\n"
, "048b140c890d74acfb2bc8b5d43a4cbf", NULL};
struct cv::ocl::internal::ProgramEntry filterSep_singlePass_oclsrc={moduleName, "filterSep_singlePass",
"#ifdef BORDER_CONSTANT\n"
"#define EXTRAPOLATE(x, maxV)\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = clamp((x), 0, (maxV)-1); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = ( (x) + (maxV) ) % (maxV); \\\n"
"}\n"
"#elif defined BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = min(((maxV)-1)*2-(x)+1, max((x),-(x)-1) ); \\\n"
"}\n"
"#elif defined BORDER_REFLECT_101 || defined BORDER_REFLECT101\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = min(((maxV)-1)*2-(x), max((x),-(x)) ); \\\n"
"}\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#if CN != 3\n"
"#define loadpix(addr) *(__global const srcT *)(addr)\n"
"#define storepix(val, addr)  *(__global dstT *)(addr) = val\n"
"#define SRCSIZE (int)sizeof(srcT)\n"
"#define DSTSIZE (int)sizeof(dstT)\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const srcT1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global dstT1 *)(addr))\n"
"#define SRCSIZE (int)sizeof(srcT1)*3\n"
"#define DSTSIZE (int)sizeof(dstT1)*3\n"
"#endif\n"
"#define SRC(_x,_y) convertToWT(loadpix(Src + mad24(_y, src_step, SRCSIZE * _x)))\n"
"#ifdef BORDER_CONSTANT\n"
"#define ELEM(_x,_y,r_edge,t_edge,const_v) (_x)<0 | (_x) >= (r_edge) | (_y)<0 | (_y) >= (t_edge) ? (const_v) : SRC((_x),(_y))\n"
"#else\n"
"#define ELEM(_x,_y,r_edge,t_edge,const_v) SRC((_x),(_y))\n"
"#endif\n"
"#define noconvert\n"
"#define DIG(a) a,\n"
"__constant WT1 mat_kernelX[] = { KERNEL_MATRIX_X };\n"
"__constant WT1 mat_kernelY[] = { KERNEL_MATRIX_Y };\n"
"__kernel void sep_filter(__global uchar* Src, int src_step, int srcOffsetX, int srcOffsetY, int height, int width,\n"
"__global uchar* Dst, int dst_step, int dst_offset, int dst_rows, int dst_cols, float delta)\n"
"{\n"
"__local WT lsmem[BLK_Y + 2 * RADIUSY][BLK_X + 2 * RADIUSX];\n"
"__local WT lsmemDy[BLK_Y][BLK_X + 2 * RADIUSX];\n"
"int lix = get_local_id(0);\n"
"int liy = get_local_id(1);\n"
"int x = get_global_id(0);\n"
"int srcX = x + srcOffsetX - RADIUSX;\n"
"int clocY = liy;\n"
"do\n"
"{\n"
"int yb = clocY + srcOffsetY - RADIUSY;\n"
"EXTRAPOLATE(yb, (height));\n"
"int clocX = lix;\n"
"int cSrcX = srcX;\n"
"do\n"
"{\n"
"int xb = cSrcX;\n"
"EXTRAPOLATE(xb,(width));\n"
"lsmem[clocY][clocX] = ELEM(xb, yb, (width), (height), 0 );\n"
"clocX += BLK_X;\n"
"cSrcX += BLK_X;\n"
"}\n"
"while(clocX < BLK_X+(RADIUSX*2));\n"
"clocY += BLK_Y;\n"
"}\n"
"while (clocY < BLK_Y+(RADIUSY*2));\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"for (int y = 0; y < dst_rows; y+=BLK_Y)\n"
"{\n"
"int i, clocX = lix;\n"
"WT sum = (WT) 0;\n"
"do\n"
"{\n"
"sum = (WT) 0;\n"
"for (i=0; i<=2*RADIUSY; i++)\n"
"#if defined(INTEGER_ARITHMETIC)\n"
"sum = mad24(lsmem[liy + i][clocX], mat_kernelY[i], sum);\n"
"#else\n"
"sum = mad(lsmem[liy + i][clocX], mat_kernelY[i], sum);\n"
"#endif\n"
"lsmemDy[liy][clocX] = sum;\n"
"clocX += BLK_X;\n"
"}\n"
"while(clocX < BLK_X+(RADIUSX*2));\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if ((x < dst_cols) && (y + liy < dst_rows))\n"
"{\n"
"sum = (WT)(delta);\n"
"for (i=0; i<=2*RADIUSX; i++)\n"
"#if defined(INTEGER_ARITHMETIC)\n"
"sum = mad24(lsmemDy[liy][lix+i], mat_kernelX[i], sum);\n"
"#else\n"
"sum = mad(lsmemDy[liy][lix+i], mat_kernelX[i], sum);\n"
"#endif\n"
"#if defined(SHIFT_BITS) && SHIFT_BITS > 0\n"
"#if !defined(INTEGER_ARITHMETIC)\n"
"sum = sum * (1.0f / (1 << SHIFT_BITS));\n"
"#else\n"
"sum = (sum + (1 << (SHIFT_BITS-1))) >> SHIFT_BITS;\n"
"#endif\n"
"#endif\n"
"storepix(convertToDstT(sum), Dst + mad24(y + liy, dst_step, mad24(x, DSTSIZE, dst_offset)));\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"for (int i = liy * BLK_X + lix; i < (RADIUSY*2) * (BLK_X+(RADIUSX*2)); i += BLK_X * BLK_Y)\n"
"{\n"
"int clocX = i % (BLK_X+(RADIUSX*2));\n"
"int clocY = i / (BLK_X+(RADIUSX*2));\n"
"lsmem[clocY][clocX] = lsmem[clocY + BLK_Y][clocX];\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"int yb = y + liy + BLK_Y + srcOffsetY + RADIUSY;\n"
"EXTRAPOLATE(yb, (height));\n"
"clocX = lix;\n"
"int cSrcX = x + srcOffsetX - RADIUSX;\n"
"do\n"
"{\n"
"int xb = cSrcX;\n"
"EXTRAPOLATE(xb,(width));\n"
"lsmem[liy + 2*RADIUSY][clocX] = ELEM(xb, yb, (width), (height), 0 );\n"
"clocX += BLK_X;\n"
"cSrcX += BLK_X;\n"
"}\n"
"while(clocX < BLK_X+(RADIUSX*2));\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"}\n"
"}\n"
, "478db57624f9e361da43e649f0a44c8f", NULL};
struct cv::ocl::internal::ProgramEntry filterSmall_oclsrc={moduleName, "filterSmall",
"#ifdef BORDER_REPLICATE\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? (l_edge)   : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? (r_edge)-1 : (addr))\n"
"#define ADDR_H(i, t_edge, b_edge)  ((i) <  (t_edge) ? (t_edge)   :(i))\n"
"#define ADDR_B(i, b_edge, addr)    ((i) >= (b_edge) ? (b_edge)-1 :(addr))\n"
"#endif\n"
"#ifdef BORDER_REFLECT\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? -(i)-1               : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? -(i)-1+((r_edge)<<1) : (addr))\n"
"#define ADDR_H(i, t_edge, b_edge)  ((i) <  (t_edge) ? -(i)-1 : (i))\n"
"#define ADDR_B(i, b_edge, addr)    ((i) >= (b_edge) ? -(i)-1+((b_edge)<<1) : (addr))\n"
"#endif\n"
"#ifdef BORDER_REFLECT_101\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? -(i)                 : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? -(i)-2+((r_edge)<<1) : (addr))\n"
"#define ADDR_H(i, t_edge, b_edge)  ((i) <  (t_edge) ? -(i)                 : (i))\n"
"#define ADDR_B(i, b_edge, addr)    ((i) >= (b_edge) ? -(i)-2+((b_edge)<<1) : (addr))\n"
"#endif\n"
"#ifdef BORDER_WRAP\n"
"#define ADDR_L(i, l_edge, r_edge)  ((i) <  (l_edge) ? (i)+(r_edge) : (i))\n"
"#define ADDR_R(i, r_edge, addr)    ((i) >= (r_edge) ? (i)-(r_edge) : (addr))\n"
"#define ADDR_H(i, t_edge, b_edge)  ((i) <  (t_edge) ? (i)+(b_edge) : (i))\n"
"#define ADDR_B(i, b_edge, addr)    ((i) >= (b_edge) ? (i)-(b_edge) : (addr))\n"
"#endif\n"
"#ifdef BORDER_ISOLATED\n"
"#define ISOLATED_MIN(VAL) (VAL)\n"
"#else\n"
"#define ISOLATED_MIN(VAL) 0\n"
"#endif\n"
"#ifdef EXTRA_EXTRAPOLATION\n"
"#ifdef BORDER_CONSTANT\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) \\\n"
"{ \\\n"
"x = max(min(x, maxX - 1), minX); \\\n"
"y = max(min(y, maxY - 1), minY); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) \\\n"
"{ \\\n"
"if (x < minX) \\\n"
"x -= ((x - maxX + 1) / maxX) * maxX; \\\n"
"if (x >= maxX) \\\n"
"x %= maxX; \\\n"
"if (y < minY) \\\n"
"y -= ((y - maxY + 1) / maxY) * maxY; \\\n"
"if (y >= maxY) \\\n"
"y %= maxY; \\\n"
"}\n"
"#elif defined(BORDER_REFLECT) || defined(BORDER_REFLECT_101)\n"
"#define EXTRAPOLATE_(x, y, minX, minY, maxX, maxY, delta) \\\n"
"{ \\\n"
"if (maxX - minX == 1) \\\n"
"x = minX; \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if (x < minX) \\\n"
"x = minX - (x - minX) - 1 + delta; \\\n"
"else \\\n"
"x = maxX - 1 - (x - maxX) - delta; \\\n"
"} \\\n"
"while (x >= maxX || x < minX); \\\n"
"\\\n"
"if (maxY - minY == 1) \\\n"
"y = minY; \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if (y < minY) \\\n"
"y = minY - (y - minY) - 1 + delta; \\\n"
"else \\\n"
"y = maxY - 1 - (y - maxY) - delta; \\\n"
"} \\\n"
"while (y >= maxY || y < minY); \\\n"
"}\n"
"#ifdef BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) EXTRAPOLATE_(x, y, minX, minY, maxX, maxY, 0)\n"
"#elif defined(BORDER_REFLECT_101) || defined(BORDER_REFLECT101)\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) EXTRAPOLATE_(x, y, minX, minY, maxX, maxY, 1)\n"
"#endif\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#else\n"
"#define EXTRAPOLATE(x, y, minX, minY, maxX, maxY) \\\n"
"{ \\\n"
"int _row = y - ISOLATED_MIN(minY), _col = x - ISOLATED_MIN(minX); \\\n"
"_row = ADDR_H(_row, 0, maxY - ISOLATED_MIN(minY)); \\\n"
"_row = ADDR_B(_row, maxY - ISOLATED_MIN(minY), _row); \\\n"
"y = _row + ISOLATED_MIN(minY); \\\n"
"\\\n"
"_col = ADDR_L(_col, 0, maxX - ISOLATED_MIN(minX)); \\\n"
"_col = ADDR_R(_col, maxX - ISOLATED_MIN(minX), _col); \\\n"
"x = _col + ISOLATED_MIN(minX); \\\n"
"}\n"
"#endif\n"
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#if cn != 3\n"
"#define loadpix(addr) *(__global const srcT *)(addr)\n"
"#define storepix(val, addr)  *(__global dstT *)(addr) = val\n"
"#define SRCSIZE (int)sizeof(srcT)\n"
"#define DSTSIZE (int)sizeof(dstT)\n"
"#else\n"
"#define loadpix(addr) vload3(0, (__global const srcT1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global dstT1 *)(addr))\n"
"#define SRCSIZE (int)sizeof(srcT1) * cn\n"
"#define DSTSIZE (int)sizeof(dstT1) * cn\n"
"#endif\n"
"#define noconvert\n"
"struct RectCoords\n"
"{\n"
"int x1, y1, x2, y2;\n"
"};\n"
"#ifdef BORDER_ISOLATED\n"
"inline bool isBorder(const struct RectCoords bounds, int2 coord, int numPixels)\n"
"{\n"
"return coord.x < bounds.x1 || coord.y < bounds.y1 || coord.x + numPixels > bounds.x2 || coord.y >= bounds.y2;\n"
"}\n"
"#else\n"
"inline bool isBorder(const struct RectCoords bounds, int2 coord, int numPixels)\n"
"{\n"
"return coord.x < 0 || coord.y < 0 || coord.x + numPixels > bounds.x2 || coord.y >= bounds.y2;\n"
"}\n"
"#endif\n"
"#define float1 float\n"
"#define double1 double\n"
"#define uchar1 uchar\n"
"#define int1 int\n"
"#define uint1 unit\n"
"#define __CAT(x, y) x##y\n"
"#define CAT(x, y) __CAT(x, y)\n"
"#define vload1(OFFSET, PTR) (*(PTR + OFFSET))\n"
"#define PX_LOAD_VEC_TYPE CAT(srcT1, PX_LOAD_VEC_SIZE)\n"
"#define PX_LOAD_FLOAT_VEC_TYPE CAT(WT1, PX_LOAD_VEC_SIZE)\n"
"#define PX_LOAD CAT(vload, PX_LOAD_VEC_SIZE)\n"
"inline PX_LOAD_FLOAT_VEC_TYPE readSrcPixelGroup(int2 pos, __global const uchar * srcptr,\n"
"int srcstep, const struct RectCoords srcCoords)\n"
"{\n"
"__global const srcT1 * ptr = (__global const srcT1 *)\n"
"(srcptr + mad24(pos.y, srcstep, pos.x * SRCSIZE));\n"
"return PX_LOAD_FLOAT_VEC_CONV(PX_LOAD(0, ptr));\n"
"}\n"
"#define LOOP1(VAR, STMT) (STMT); (VAR)++;\n"
"#define LOOP2(VAR, STMT) LOOP1(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP3(VAR, STMT) LOOP2(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP4(VAR, STMT) LOOP3(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP5(VAR, STMT) LOOP4(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP6(VAR, STMT) LOOP5(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP7(VAR, STMT) LOOP6(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP8(VAR, STMT) LOOP7(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP9(VAR, STMT) LOOP8(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP10(VAR, STMT) LOOP9(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP11(VAR, STMT) LOOP10(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP12(VAR, STMT) LOOP11(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP13(VAR, STMT) LOOP12(VAR, STMT); (STMT); (VAR)++;\n"
"#define LOOP(N, VAR, STMT) CAT(LOOP, N)((VAR), (STMT))\n"
"#ifdef OP_BOX_FILTER\n"
"#define PROCESS_ELEM \\\n"
"WT total_sum = (WT)(0); \\\n"
"int sy = 0; \\\n"
"LOOP(KERNEL_SIZE_Y, sy, \\\n"
"{ \\\n"
"int sx = 0; \\\n"
"LOOP(KERNEL_SIZE_X, sx, \\\n"
"{ \\\n"
"total_sum += privateData[py + sy][px + sx]; \\\n"
"}); \\\n"
"})\n"
"#elif defined OP_FILTER2D\n"
"#define DIG(a) a,\n"
"__constant WT1 kernelData[] = { COEFF };\n"
"#define PROCESS_ELEM \\\n"
"WT total_sum = 0; \\\n"
"int sy = 0; \\\n"
"int kernelIndex = 0; \\\n"
"LOOP(KERNEL_SIZE_Y, sy, \\\n"
"{ \\\n"
"int sx = 0; \\\n"
"LOOP(KERNEL_SIZE_X, sx, \\\n"
"{ \\\n"
"total_sum = fma(kernelData[kernelIndex++], privateData[py + sy][px + sx], total_sum); \\\n"
"}); \\\n"
"})\n"
"#elif defined OP_ERODE || defined OP_DILATE\n"
"#ifdef DEPTH_0\n"
"#define MIN_VAL 0\n"
"#define MAX_VAL UCHAR_MAX\n"
"#elif defined DEPTH_1\n"
"#define MIN_VAL SCHAR_MIN\n"
"#define MAX_VAL SCHAR_MAX\n"
"#elif defined DEPTH_2\n"
"#define MIN_VAL 0\n"
"#define MAX_VAL USHRT_MAX\n"
"#elif defined DEPTH_3\n"
"#define MIN_VAL SHRT_MIN\n"
"#define MAX_VAL SHRT_MAX\n"
"#elif defined DEPTH_4\n"
"#define MIN_VAL INT_MIN\n"
"#define MAX_VAL INT_MAX\n"
"#elif defined DEPTH_5\n"
"#define MIN_VAL (-FLT_MAX)\n"
"#define MAX_VAL FLT_MAX\n"
"#elif defined DEPTH_6\n"
"#define MIN_VAL (-DBL_MAX)\n"
"#define MAX_VAL DBL_MAX\n"
"#endif\n"
"#ifdef OP_ERODE\n"
"#define VAL (WT)MAX_VAL\n"
"#elif defined OP_DILATE\n"
"#define VAL (WT)MIN_VAL\n"
"#else\n"
"#error \"Unknown operation\"\n"
"#endif\n"
"#define convert_float1 convert_float\n"
"#define convert_uchar1 convert_uchar\n"
"#define convert_int1 convert_int\n"
"#define convert_uint1 convert_uint\n"
"#ifdef OP_ERODE\n"
"#if defined INTEL_DEVICE && defined DEPTH_0\n"
"#define WA_CONVERT_1 CAT(convert_uint, cn)\n"
"#define WA_CONVERT_2 CAT(convert_, srcT)\n"
"#define MORPH_OP(A, B) ((A) < (B) ? (A) : (B))\n"
"#else\n"
"#define MORPH_OP(A, B) min((A), (B))\n"
"#endif\n"
"#endif\n"
"#ifdef OP_DILATE\n"
"#define MORPH_OP(A, B) max((A), (B))\n"
"#endif\n"
"#define PROCESS(_y, _x) \\\n"
"total_sum = convertToWT(MORPH_OP(convertToWT(total_sum), convertToWT(privateData[py + _y][px + _x])));\n"
"#define PROCESS_ELEM \\\n"
"WT total_sum = convertToWT(VAL); \\\n"
"PROCESS_ELEM_\n"
"#else\n"
"#error \"No processing is specified\"\n"
"#endif\n"
"#if defined OP_GRADIENT || defined OP_TOPHAT || defined OP_BLACKHAT\n"
"#define EXTRA_PARAMS , __global const uchar * matptr, int mat_step, int mat_offset\n"
"#else\n"
"#define EXTRA_PARAMS\n"
"#endif\n"
"inline WT getBorderPixel(const struct RectCoords bounds, int2 coord,\n"
"__global const uchar * srcptr, int srcstep)\n"
"{\n"
"#ifdef BORDER_CONSTANT\n"
"#ifdef OP_ERODE\n"
"return (WT)(MAX_VAL);\n"
"#elif defined OP_DILATE\n"
"return (WT)(MIN_VAL);\n"
"#else\n"
"return (WT)(0);\n"
"#endif\n"
"#else\n"
"int selected_col = coord.x;\n"
"int selected_row = coord.y;\n"
"EXTRAPOLATE(selected_col, selected_row,\n"
"bounds.x1, bounds.y1,\n"
"bounds.x2, bounds.y2);\n"
"__global const uchar* ptr = srcptr + mad24(selected_row, srcstep, selected_col * SRCSIZE);\n"
"return convertToWT(loadpix(ptr));\n"
"#endif\n"
"}\n"
"inline WT readSrcPixelSingle(int2 pos, __global const uchar * srcptr,\n"
"int srcstep, const struct RectCoords srcCoords)\n"
"{\n"
"if (!isBorder(srcCoords, pos, 1))\n"
"{\n"
"__global const uchar * ptr = srcptr + mad24(pos.y, srcstep, pos.x * SRCSIZE);\n"
"return convertToWT(loadpix(ptr));\n"
"}\n"
"else\n"
"return getBorderPixel(srcCoords, pos, srcptr, srcstep);\n"
"}\n"
"__kernel void filterSmall(__global const uchar * srcptr, int src_step, int srcOffsetX, int srcOffsetY, int srcEndX, int srcEndY,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int rows, int cols\n"
"#ifdef NORMALIZE\n"
", float alpha\n"
"#endif\n"
"EXTRA_PARAMS )\n"
"{\n"
"const struct RectCoords srcCoords = { srcOffsetX, srcOffsetY, srcEndX, srcEndY };\n"
"const int startX = get_global_id(0) * PX_PER_WI_X;\n"
"const int startY = get_global_id(1) * PX_PER_WI_Y;\n"
"if (startX >= cols || startY >= rows)\n"
"return;\n"
"WT privateData[PX_PER_WI_Y + KERNEL_SIZE_Y - 1][PRIV_DATA_WIDTH];\n"
"int py = 0;\n"
"LOOP(PX_LOAD_Y_ITERATIONS, py,\n"
"{\n"
"int y = startY + py;\n"
"int px = 0;\n"
"LOOP(PX_LOAD_X_ITERATIONS, px,\n"
"{\n"
"int x = startX + (px * PX_LOAD_NUM_PX);\n"
"int2 srcPos = (int2)(srcCoords.x1 + x - ANCHOR_X, srcCoords.y1 + y - ANCHOR_Y);\n"
"if (!isBorder(srcCoords, srcPos, PX_LOAD_NUM_PX))\n"
"{\n"
"PX_LOAD_FLOAT_VEC_TYPE p = readSrcPixelGroup(srcPos, srcptr, src_step, srcCoords);\n"
"#ifdef SQR\n"
"*((PX_LOAD_FLOAT_VEC_TYPE *)&privateData[py][px * PX_LOAD_NUM_PX]) = p * p;\n"
"#else\n"
"*((PX_LOAD_FLOAT_VEC_TYPE *)&privateData[py][px * PX_LOAD_NUM_PX]) = p;\n"
"#endif\n"
"}\n"
"else\n"
"{\n"
"int lx = 0;\n"
"LOOP(PX_LOAD_NUM_PX, lx,\n"
"{\n"
"WT p = readSrcPixelSingle(srcPos, srcptr, src_step, srcCoords);\n"
"#ifdef SQR\n"
"*((WT*)&privateData[py][px * PX_LOAD_NUM_PX + lx]) = p * p;\n"
"#else\n"
"*((WT*)&privateData[py][px * PX_LOAD_NUM_PX + lx]) = p;\n"
"#endif\n"
"srcPos.x++;\n"
"});\n"
"}\n"
"});\n"
"});\n"
"py = 0;\n"
"LOOP(PX_PER_WI_Y, py,\n"
"{\n"
"int y = startY + py;\n"
"int px = 0;\n"
"LOOP(PX_PER_WI_X, px,\n"
"{\n"
"int x = startX + px;\n"
"PROCESS_ELEM;\n"
"int dst_index = mad24(y, dst_step, mad24(x, DSTSIZE, dst_offset));\n"
"__global dstT * dstPtr = (__global dstT *)(dstptr + dst_index);\n"
"#ifdef NORMALIZE\n"
"total_sum *= (WT)(alpha);\n"
"#endif\n"
"#if defined OP_GRADIENT || defined OP_TOPHAT || defined OP_BLACKHAT\n"
"int mat_index = mad24(y, mat_step, mad24(x, SRCSIZE, mat_offset));\n"
"WT value = convertToWT(loadpix(matptr + mat_index));\n"
"#ifdef OP_GRADIENT\n"
"storepix(convertToDstT(convertToWT(total_sum) - convertToWT(value)), dstPtr );\n"
"#elif defined OP_TOPHAT\n"
"storepix(convertToDstT(convertToWT(value) - convertToWT(total_sum)), dstPtr );\n"
"#elif defined OP_BLACKHAT\n"
"storepix(convertToDstT(convertToWT(total_sum) - convertToWT(value)), dstPtr );\n"
"#endif\n"
"#else\n"
"storepix(convertToDstT(total_sum), dstPtr);\n"
"#endif\n"
"});\n"
"});\n"
"}\n"
, "791281c9ee1a2ff7234c85b09b6af6bf", NULL};
struct cv::ocl::internal::ProgramEntry gaussianBlur3x3_oclsrc={moduleName, "gaussianBlur3x3",
"#define DIG(a) a,\n"
"__constant float kx[] = { KERNEL_MATRIX_X };\n"
"__constant float ky[] = { KERNEL_MATRIX_Y };\n"
"#define OP(delta, y, x) (convert_float16(arr[(y + delta) * 3 + x]) * ky[y] * kx[x])\n"
"__kernel void gaussianBlur3x3_8UC1_cols16_rows2(__global const uint* src, int src_step,\n"
"__global uint* dst, int dst_step, int rows, int cols)\n"
"{\n"
"int block_x = get_global_id(0);\n"
"int y = get_global_id(1) * 2;\n"
"int ssx, dsx;\n"
"if ((block_x * 16) >= cols || y >= rows) return;\n"
"uint4 line[4];\n"
"uint4 line_out[2];\n"
"uchar a; uchar16 b; uchar c;\n"
"uchar d; uchar16 e; uchar f;\n"
"uchar g; uchar16 h; uchar i;\n"
"uchar j; uchar16 k; uchar l;\n"
"ssx = dsx = 1;\n"
"int src_index = block_x * 4 * ssx + (y - 1) * (src_step / 4);\n"
"line[1] = vload4(0, src + src_index + (src_step / 4));\n"
"line[2] = vload4(0, src + src_index + 2 * (src_step / 4));\n"
"#ifdef BORDER_CONSTANT\n"
"line[0] = (y == 0) ? (uint4)0 : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? (uint4)0 : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#elif defined BORDER_REFLECT_101\n"
"line[0] = (y == 0) ? line[2] : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? line[1] : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#elif defined (BORDER_REPLICATE) || defined(BORDER_REFLECT)\n"
"line[0] = (y == 0) ? line[1] : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? line[2] : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#endif\n"
"__global uchar *src_p = (__global uchar *)src;\n"
"src_index = block_x * 16 * ssx + (y - 1) * src_step;\n"
"bool line_end = ((block_x + 1) * 16 == cols);\n"
"b = as_uchar16(line[0]);\n"
"e = as_uchar16(line[1]);\n"
"h = as_uchar16(line[2]);\n"
"k = as_uchar16(line[3]);\n"
"#ifdef BORDER_CONSTANT\n"
"a = (block_x == 0 || y == 0) ? 0 : src_p[src_index - 1];\n"
"c = (line_end || y == 0) ? 0 : src_p[src_index + 16];\n"
"d = (block_x == 0) ? 0 : src_p[src_index + src_step - 1];\n"
"f = line_end ? 0 : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? 0 : src_p[src_index + 2 * src_step - 1];\n"
"i = line_end ? 0 : src_p[src_index + 2 * src_step + 16];\n"
"j = (block_x == 0 || y == (rows - 2)) ? 0 : src_p[src_index + 3 * src_step - 1];\n"
"l = (line_end || y == (rows - 2))? 0 : src_p[src_index + 3 * src_step + 16];\n"
"#elif defined BORDER_REFLECT_101\n"
"int offset;\n"
"offset = (y == 0) ? (2 * src_step) : 0;\n"
"a = (block_x == 0) ? src_p[src_index + offset + 1] : src_p[src_index + offset - 1];\n"
"c = line_end ? src_p[src_index + offset + 14] : src_p[src_index + offset + 16];\n"
"d = (block_x == 0) ? src_p[src_index + src_step + 1] : src_p[src_index + src_step - 1];\n"
"f = line_end ? src_p[src_index + src_step + 14] : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? src_p[src_index + 2 * src_step + 1] : src_p[src_index + 2 * src_step - 1];\n"
"i = line_end ? src_p[src_index + 2 * src_step + 14] : src_p[src_index + 2 * src_step + 16];\n"
"offset = (y == (rows - 2)) ? (1 * src_step) : (3 * src_step);\n"
"j = (block_x == 0) ? src_p[src_index + offset + 1] : src_p[src_index + offset - 1];\n"
"l = line_end ? src_p[src_index + offset + 14] : src_p[src_index + offset + 16];\n"
"#elif defined (BORDER_REPLICATE) || defined(BORDER_REFLECT)\n"
"int offset;\n"
"offset = (y == 0) ? (1 * src_step) : 0;\n"
"a = (block_x == 0) ? src_p[src_index + offset] : src_p[src_index + offset - 1];\n"
"c = line_end ? src_p[src_index + offset + 15] : src_p[src_index + offset + 16];\n"
"d = (block_x == 0) ? src_p[src_index + src_step] : src_p[src_index + src_step - 1];\n"
"f = line_end ? src_p[src_index + src_step + 15] : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? src_p[src_index + 2 * src_step] : src_p[src_index + 2 * src_step - 1];\n"
"i = line_end ? src_p[src_index + 2 * src_step + 15] : src_p[src_index + 2 * src_step + 16];\n"
"offset = (y == (rows - 2)) ? (2 * src_step) : (3 * src_step);\n"
"j = (block_x == 0) ? src_p[src_index + offset] : src_p[src_index + offset - 1];\n"
"l = line_end ? src_p[src_index + offset + 15] : src_p[src_index + offset + 16];\n"
"#endif\n"
"uchar16 arr[12];\n"
"float16 sum[2];\n"
"arr[0] = (uchar16)(a, b.s0123, b.s456789ab, b.scde);\n"
"arr[1] = b;\n"
"arr[2] = (uchar16)(b.s123, b.s4567, b.s89abcdef, c);\n"
"arr[3] = (uchar16)(d, e.s0123, e.s456789ab, e.scde);\n"
"arr[4] = e;\n"
"arr[5] = (uchar16)(e.s123, e.s4567, e.s89abcdef, f);\n"
"arr[6] = (uchar16)(g, h.s0123, h.s456789ab, h.scde);\n"
"arr[7] = h;\n"
"arr[8] = (uchar16)(h.s123, h.s4567, h.s89abcdef, i);\n"
"arr[9] = (uchar16)(j, k.s0123, k.s456789ab, k.scde);\n"
"arr[10] = k;\n"
"arr[11] = (uchar16)(k.s123, k.s4567, k.s89abcdef, l);\n"
"sum[0] = OP(0, 0, 0) + OP(0, 0, 1) + OP(0, 0, 2) +\n"
"OP(0, 1, 0) + OP(0, 1, 1) + OP(0, 1, 2) +\n"
"OP(0, 2, 0) + OP(0, 2, 1) + OP(0, 2, 2);\n"
"sum[1] = OP(1, 0, 0) + OP(1, 0, 1) + OP(1, 0, 2) +\n"
"OP(1, 1, 0) + OP(1, 1, 1) + OP(1, 1, 2) +\n"
"OP(1, 2, 0) + OP(1, 2, 1) + OP(1, 2, 2);\n"
"line_out[0] = as_uint4(convert_uchar16_sat_rte(sum[0]));\n"
"line_out[1] = as_uint4(convert_uchar16_sat_rte(sum[1]));\n"
"int dst_index = block_x * 4 * dsx + y * (dst_step / 4);\n"
"vstore4(line_out[0], 0, dst + dst_index);\n"
"vstore4(line_out[1], 0, dst + dst_index + (dst_step / 4));\n"
"}\n"
, "dbbc069449fa882036a00c7734ead4c1", NULL};
struct cv::ocl::internal::ProgramEntry gaussianBlur5x5_oclsrc={moduleName, "gaussianBlur5x5",
"#define DIG(a) a,\n"
"__constant float kx[] = { KERNEL_MATRIX_X };\n"
"__constant float ky[] = { KERNEL_MATRIX_Y };\n"
"#define OP(y, x) (convert_float4(arr[y * 5 + x]) * ky[y] * kx[x])\n"
"#define FILL_ARR(s1, s2, n, e1, e2)                                                   \\\n"
"arr[5 * n + 0] = row_s ? (uchar4)(s1, s2, line[n].s23) : (uchar4)(line[n].s0123); \\\n"
"arr[5 * n + 1] = row_s ? (uchar4)(s2, line[n].s234) : (uchar4)(line[n].s1234);    \\\n"
"arr[5 * n + 2] = (uchar4)(line[n].s2345);                                         \\\n"
"arr[5 * n + 3] = row_e ? (uchar4)(line[n].s345, e1) : (uchar4)(line[n].s3456);    \\\n"
"arr[5 * n + 4] = row_e ? (uchar4)(line[n].s45, e1, e2) : (uchar4)(line[n].s4567);\n"
"__kernel void gaussianBlur5x5_8UC1_cols4(__global const uchar* src, int src_step,\n"
"__global uint* dst, int dst_step, int rows, int cols)\n"
"{\n"
"int x = get_global_id(0) * 4;\n"
"int y = get_global_id(1);\n"
"if (x >= cols || y >= rows) return;\n"
"uchar8 line[5];\n"
"int offset, src_index;\n"
"src_index = x + (y - 2) * src_step - 2;\n"
"offset = max(0, src_index + 2 * src_step);\n"
"line[2] = vload8(0, src + offset);\n"
"if (offset == 0) line[2] = (uchar8)(0, 0, line[2].s0123, line[2].s45);\n"
"#if defined BORDER_CONSTANT || defined BORDER_REPLICATE\n"
"uchar8 tmp;\n"
"#ifdef BORDER_CONSTANT\n"
"tmp = (uchar8)0;\n"
"#elif defined BORDER_REPLICATE\n"
"tmp = line[2];\n"
"#endif\n"
"line[0] = line[1] = tmp;\n"
"if (y > 1)\n"
"{\n"
"offset = max(0, src_index);\n"
"line[0] = vload8(0, src + offset);\n"
"if (offset == 0) line[0] = (uchar8)(0, 0, line[0].s0123, line[0].s45);\n"
"}\n"
"if (y > 0)\n"
"{\n"
"offset = max(0, src_index + src_step);\n"
"line[1] = vload8(0, src + offset);\n"
"if (offset == 0) line[1] = (uchar8)(0, 0, line[1].s0123, line[1].s45);\n"
"}\n"
"line[3] = (y == (rows - 1)) ? tmp : vload8(0, src + src_index + 3 * src_step);\n"
"line[4] = (y >= (rows - 2)) ? tmp : vload8(0, src + src_index + 4 * src_step);\n"
"#elif BORDER_REFLECT\n"
"int t;\n"
"t = (y <= 1) ? (abs(y - 1) - y + 2) : 0;\n"
"offset = max(0, src_index + t * src_step);\n"
"line[0] = vload8(0, src + offset);\n"
"if (offset == 0) line[0] = (uchar8)(0, 0, line[0].s0123, line[0].s45);\n"
"if (y == 0)\n"
"line[1] = line[2];\n"
"else\n"
"{\n"
"offset = max(0, src_index + 1 * src_step);\n"
"line[1] = vload8(0, src + offset);\n"
"if (offset == 0) line[1] = (uchar8)(0, 0, line[1].s0123, line[0].s45);\n"
"}\n"
"line[3] = (y == (rows - 1)) ? line[2] : vload8(0, src + src_index + 3 * src_step);\n"
"t = (y >= (rows - 2)) ? (abs(y - (rows - 1)) - (y - (rows - 2)) + 2) : 4;\n"
"line[4] = vload8(0, src + src_index + t * src_step);\n"
"#elif BORDER_REFLECT_101\n"
"if (y == 1)\n"
"line[0] = line[2];\n"
"else\n"
"{\n"
"offset = (y == 0) ? (src_index + 4 * src_step) : max(0, src_index);\n"
"line[0] = vload8(0, src + offset);\n"
"if (offset == 0) line[0] = (uchar8)(0, 0, line[0].s0123, line[0].s45);\n"
"}\n"
"offset = (y == 0) ? (src_index + 3 * src_step) : max(0, src_index + 1 * src_step);\n"
"line[1] = vload8(0, src + offset);\n"
"if (offset == 0) line[1] = (uchar8)(0, 0, line[1].s0123, line[1].s45);\n"
"line[3] = vload8(0, src + src_index + ((y == (rows - 1)) ? 1 : 3) * src_step);\n"
"if (y == (rows - 2))\n"
"line[4] = line[2];\n"
"else\n"
"{\n"
"line[4] = vload8(0, src + src_index + ((y == (rows - 1)) ? 1 : 4) * src_step);\n"
"}\n"
"#endif\n"
"bool row_s = (x == 0);\n"
"bool row_e = ((x + 4) == cols);\n"
"uchar4 arr[25];\n"
"uchar s, e;\n"
"#ifdef BORDER_CONSTANT\n"
"s = e = 0;\n"
"FILL_ARR(s, s, 0, e, e);\n"
"FILL_ARR(s, s, 1, e, e);\n"
"FILL_ARR(s, s, 2, e, e);\n"
"FILL_ARR(s, s, 3, e, e);\n"
"FILL_ARR(s, s, 4, e, e);\n"
"#elif defined BORDER_REPLICATE\n"
"s = line[0].s2;\n"
"e = line[0].s5;\n"
"FILL_ARR(s, s, 0, e, e);\n"
"s = line[1].s2;\n"
"e = line[1].s5;\n"
"FILL_ARR(s, s, 1, e, e);\n"
"s = line[2].s2;\n"
"e = line[2].s5;\n"
"FILL_ARR(s, s, 2, e, e);\n"
"s = line[3].s2;\n"
"e = line[3].s5;\n"
"FILL_ARR(s, s, 3, e, e);\n"
"s = line[4].s2;\n"
"e = line[4].s5;\n"
"FILL_ARR(s, s, 4, e, e);\n"
"#elif BORDER_REFLECT\n"
"uchar s1, s2;\n"
"uchar e1, e2;\n"
"s1 = line[0].s3;\n"
"s2 = line[0].s2;\n"
"e1 = line[0].s5;\n"
"e2 = line[0].s4;\n"
"FILL_ARR(s1, s2, 0, e1, e2);\n"
"s1 = line[1].s3;\n"
"s2 = line[1].s2;\n"
"e1 = line[1].s5;\n"
"e2 = line[1].s4;\n"
"FILL_ARR(s1, s2, 1, e1, e2);\n"
"s1 = line[2].s3;\n"
"s2 = line[2].s2;\n"
"e1 = line[2].s5;\n"
"e2 = line[2].s4;\n"
"FILL_ARR(s1, s2, 2, e1, e2);\n"
"s1 = line[3].s3;\n"
"s2 = line[3].s2;\n"
"e1 = line[3].s5;\n"
"e2 = line[3].s4;\n"
"FILL_ARR(s1, s2, 3, e1, e2);\n"
"s1 = line[4].s3;\n"
"s2 = line[4].s2;\n"
"e1 = line[4].s5;\n"
"e2 = line[4].s4;\n"
"FILL_ARR(s1, s2, 4, e1, e2);\n"
"#elif BORDER_REFLECT_101\n"
"s = line[0].s4;\n"
"e = line[0].s3;\n"
"FILL_ARR(s, e, 0, s, e);\n"
"s = line[1].s4;\n"
"e = line[1].s3;\n"
"FILL_ARR(s, e, 1, s, e);\n"
"s = line[2].s4;\n"
"e = line[2].s3;\n"
"FILL_ARR(s, e, 2, s, e);\n"
"s = line[3].s4;\n"
"e = line[3].s3;\n"
"FILL_ARR(s, e, 3, s, e);\n"
"s = line[4].s4;\n"
"e = line[4].s3;\n"
"FILL_ARR(s, e, 4, s, e);\n"
"#endif\n"
"float4 sum;\n"
"sum = OP(0, 0) + OP(0, 1) + OP(0, 2) + OP(0, 3) + OP(0, 4) +\n"
"OP(1, 0) + OP(1, 1) + OP(1, 2) + OP(1, 3) + OP(1, 4) +\n"
"OP(2, 0) + OP(2, 1) + OP(2, 2) + OP(2, 3) + OP(2, 4) +\n"
"OP(3, 0) + OP(3, 1) + OP(3, 2) + OP(3, 3) + OP(3, 4) +\n"
"OP(4, 0) + OP(4, 1) + OP(4, 2) + OP(4, 3) + OP(4, 4);\n"
"int dst_index = (x / 4) + y * (dst_step / 4);\n"
"dst[dst_index] = as_uint(convert_uchar4_sat_rte(sum));\n"
"}\n"
, "ece5030c9920436f23ce25e35dc12303", NULL};
struct cv::ocl::internal::ProgramEntry gftt_oclsrc={moduleName, "gftt",
"#ifdef OP_MAX_EIGEN_VAL\n"
"__kernel void maxEigenVal(__global const uchar * srcptr, int src_step, int src_offset, int cols,\n"
"int total, __global uchar * dstptr\n"
"#ifdef HAVE_MASK\n"
", __global const uchar * maskptr, int mask_step, int mask_offset\n"
"#endif\n"
")\n"
"{\n"
"int lid = get_local_id(0);\n"
"int gid = get_group_id(0);\n"
"int  id = get_global_id(0);\n"
"__local float localmem_max[WGS2_ALIGNED];\n"
"float maxval = -FLT_MAX;\n"
"for (int grain = groupnum * WGS; id < total; id += grain)\n"
"{\n"
"int src_index = mad24(id / cols, src_step, mad24((id % cols), (int)sizeof(float), src_offset));\n"
"#ifdef HAVE_MASK\n"
"int mask_index = mad24(id / cols, mask_step, id % cols + mask_offset);\n"
"if (maskptr[mask_index])\n"
"#endif\n"
"maxval = max(maxval, *(__global const float *)(srcptr + src_index));\n"
"}\n"
"if (lid < WGS2_ALIGNED)\n"
"localmem_max[lid] = maxval;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (lid >= WGS2_ALIGNED && total >= WGS2_ALIGNED)\n"
"localmem_max[lid - WGS2_ALIGNED] = max(maxval, localmem_max[lid - WGS2_ALIGNED]);\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"for (int lsize = WGS2_ALIGNED >> 1; lsize > 0; lsize >>= 1)\n"
"{\n"
"if (lid < lsize)\n"
"{\n"
"int lid2 = lsize + lid;\n"
"localmem_max[lid] = max(localmem_max[lid], localmem_max[lid2]);\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"}\n"
"if (lid == 0)\n"
"*(__global float *)(dstptr + (int)sizeof(float) * gid) = localmem_max[0];\n"
"}\n"
"__kernel void maxEigenValTask(__global float * dst, float qualityLevel,\n"
"__global int * cornersptr)\n"
"{\n"
"float maxval = -FLT_MAX;\n"
"#pragma unroll\n"
"for (int x = 0; x < groupnum; ++x)\n"
"maxval = max(maxval, dst[x]);\n"
"dst[0] = maxval * qualityLevel;\n"
"cornersptr[0] = 0;\n"
"}\n"
"#elif OP_FIND_CORNERS\n"
"#define GET_SRC_32F(_y, _x) *(__global const float *)(eigptr + (_y) * eig_step + (_x) * (int)sizeof(float) )\n"
"__kernel void findCorners(__global const uchar * eigptr, int eig_step, int eig_offset,\n"
"#ifdef HAVE_MASK\n"
"__global const uchar * mask, int mask_step, int mask_offset,\n"
"#endif\n"
"__global uchar * cornersptr, int rows, int cols,\n"
"__constant float * threshold, int max_corners)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"__global int* counter = (__global int*) cornersptr;\n"
"__global float2 * corners = (__global float2 *)(cornersptr + (int)sizeof(float2));\n"
"if (y < rows && x < cols\n"
"#ifdef HAVE_MASK\n"
"&& mask[mad24(y, mask_step, x + mask_offset)]\n"
"#endif\n"
")\n"
"{\n"
"++x, ++y;\n"
"float val = GET_SRC_32F(y, x);\n"
"if (val > threshold[0])\n"
"{\n"
"float maxVal = val;\n"
"maxVal = max(GET_SRC_32F(y - 1, x - 1), maxVal);\n"
"maxVal = max(GET_SRC_32F(y - 1, x    ), maxVal);\n"
"maxVal = max(GET_SRC_32F(y - 1, x + 1), maxVal);\n"
"maxVal = max(GET_SRC_32F(y    , x - 1), maxVal);\n"
"maxVal = max(GET_SRC_32F(y    , x + 1), maxVal);\n"
"maxVal = max(GET_SRC_32F(y + 1, x - 1), maxVal);\n"
"maxVal = max(GET_SRC_32F(y + 1, x    ), maxVal);\n"
"maxVal = max(GET_SRC_32F(y + 1, x + 1), maxVal);\n"
"if (val == maxVal)\n"
"{\n"
"int ind = atomic_inc(counter);\n"
"if (ind < max_corners)\n"
"{\n"
"corners[ind].x = val;\n"
"corners[ind].y = as_float(y | (x << 16));\n"
"}\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
, "cb2cfd26f04e14ae047e2f5eb28c8e11", NULL};
struct cv::ocl::internal::ProgramEntry histogram_oclsrc={moduleName, "histogram",
"#ifndef kercn\n"
"#define kercn 1\n"
"#endif\n"
"#ifndef T\n"
"#define T uchar\n"
"#endif\n"
"#define noconvert\n"
"__kernel void calculate_histogram(__global const uchar * src_ptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * histptr, int total)\n"
"{\n"
"int lid = get_local_id(0);\n"
"int id = get_global_id(0) * kercn;\n"
"int gid = get_group_id(0);\n"
"__local int localhist[BINS];\n"
"#pragma unroll\n"
"for (int i = lid; i < BINS; i += WGS)\n"
"localhist[i] = 0;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"__global const uchar * src = src_ptr + src_offset;\n"
"int src_index;\n"
"for (int grain = HISTS_COUNT * WGS * kercn; id < total; id += grain)\n"
"{\n"
"#ifdef HAVE_SRC_CONT\n"
"src_index = id;\n"
"#else\n"
"src_index = mad24(id / src_cols, src_step, id % src_cols);\n"
"#endif\n"
"#if kercn == 1\n"
"atomic_inc(localhist + convert_int(src[src_index]));\n"
"#elif kercn == 4\n"
"int value = *(__global const int *)(src + src_index);\n"
"atomic_inc(localhist + (value & 0xff));\n"
"atomic_inc(localhist + ((value >> 8) & 0xff));\n"
"atomic_inc(localhist + ((value >> 16) & 0xff));\n"
"atomic_inc(localhist + ((value >> 24) & 0xff));\n"
"#elif kercn >= 2\n"
"T value = *(__global const T *)(src + src_index);\n"
"atomic_inc(localhist + value.s0);\n"
"atomic_inc(localhist + value.s1);\n"
"#if kercn >= 4\n"
"atomic_inc(localhist + value.s2);\n"
"atomic_inc(localhist + value.s3);\n"
"#if kercn >= 8\n"
"atomic_inc(localhist + value.s4);\n"
"atomic_inc(localhist + value.s5);\n"
"atomic_inc(localhist + value.s6);\n"
"atomic_inc(localhist + value.s7);\n"
"#if kercn == 16\n"
"atomic_inc(localhist + value.s8);\n"
"atomic_inc(localhist + value.s9);\n"
"atomic_inc(localhist + value.sA);\n"
"atomic_inc(localhist + value.sB);\n"
"atomic_inc(localhist + value.sC);\n"
"atomic_inc(localhist + value.sD);\n"
"atomic_inc(localhist + value.sE);\n"
"atomic_inc(localhist + value.sF);\n"
"#endif\n"
"#endif\n"
"#endif\n"
"#endif\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"__global int * hist = (__global int *)(histptr + gid * BINS * (int)sizeof(int));\n"
"#pragma unroll\n"
"for (int i = lid; i < BINS; i += WGS)\n"
"hist[i] = localhist[i];\n"
"}\n"
"#ifndef HT\n"
"#define HT int\n"
"#endif\n"
"#ifndef convertToHT\n"
"#define convertToHT noconvert\n"
"#endif\n"
"__kernel void merge_histogram(__global const int * ghist, __global uchar * histptr, int hist_step, int hist_offset)\n"
"{\n"
"int lid = get_local_id(0);\n"
"__global HT * hist = (__global HT *)(histptr + hist_offset);\n"
"#if WGS >= BINS\n"
"HT res = (HT)(0);\n"
"#else\n"
"#pragma unroll\n"
"for (int i = lid; i < BINS; i += WGS)\n"
"hist[i] = (HT)(0);\n"
"#endif\n"
"#pragma unroll\n"
"for (int i = 0; i < HISTS_COUNT; ++i)\n"
"{\n"
"#pragma unroll\n"
"for (int j = lid; j < BINS; j += WGS)\n"
"#if WGS >= BINS\n"
"res += convertToHT(ghist[j]);\n"
"#else\n"
"hist[j] += convertToHT(ghist[j]);\n"
"#endif\n"
"ghist += BINS;\n"
"}\n"
"#if WGS >= BINS\n"
"if (lid < BINS)\n"
"*(__global HT *)(histptr + mad24(lid, hist_step, hist_offset)) = res;\n"
"#endif\n"
"}\n"
"__kernel void calcLUT(__global uchar * dst, __global const int * ghist, int total)\n"
"{\n"
"int lid = get_local_id(0);\n"
"__local int sumhist[BINS];\n"
"__local float scale;\n"
"#if WGS >= BINS\n"
"int res = 0;\n"
"#else\n"
"#pragma unroll\n"
"for (int i = lid; i < BINS; i += WGS)\n"
"sumhist[i] = 0;\n"
"#endif\n"
"#pragma unroll\n"
"for (int i = 0; i < HISTS_COUNT; ++i)\n"
"{\n"
"#pragma unroll\n"
"for (int j = lid; j < BINS; j += WGS)\n"
"#if WGS >= BINS\n"
"res += ghist[j];\n"
"#else\n"
"sumhist[j] += ghist[j];\n"
"#endif\n"
"ghist += BINS;\n"
"}\n"
"#if WGS >= BINS\n"
"if (lid < BINS)\n"
"sumhist[lid] = res;\n"
"#endif\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (lid == 0)\n"
"{\n"
"int sum = 0, i = 0;\n"
"while (!sumhist[i])\n"
"++i;\n"
"if (total == sumhist[i])\n"
"{\n"
"scale = 1;\n"
"for (int j = 0; j < BINS; ++j)\n"
"sumhist[i] = i;\n"
"}\n"
"else\n"
"{\n"
"scale = 255.f / (total - sumhist[i]);\n"
"for (sumhist[i++] = 0; i < BINS; i++)\n"
"{\n"
"sum += sumhist[i];\n"
"sumhist[i] = sum;\n"
"}\n"
"}\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"#pragma unroll\n"
"for (int i = lid; i < BINS; i += WGS)\n"
"dst[i]= convert_uchar_sat_rte(convert_float(sumhist[i]) * scale);\n"
"}\n"
, "3bfd6703e639c8a36eb7cdd5f3eefda6", NULL};
struct cv::ocl::internal::ProgramEntry hough_lines_oclsrc={moduleName, "hough_lines",
"#define ACCUM(ptr) *((__global int*)(ptr))\n"
"#ifdef MAKE_POINTS_LIST\n"
"__kernel void make_point_list(__global const uchar * src_ptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * list_ptr, int list_step, int list_offset, __global int* global_offset)\n"
"{\n"
"int x = get_local_id(0);\n"
"int y = get_group_id(1);\n"
"__local int l_index, l_offset;\n"
"__local int l_points[LOCAL_SIZE];\n"
"__global const uchar * src = src_ptr + mad24(y, src_step, src_offset);\n"
"__global int * list = (__global int*)(list_ptr + list_offset);\n"
"if (x == 0)\n"
"l_index = 0;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (y < src_rows)\n"
"{\n"
"y <<= 16;\n"
"for (int i=x; i < src_cols; i+=GROUP_SIZE)\n"
"{\n"
"if (src[i])\n"
"{\n"
"int val = y | i;\n"
"int index = atomic_inc(&l_index);\n"
"l_points[index] = val;\n"
"}\n"
"}\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (x == 0)\n"
"l_offset = atomic_add(global_offset, l_index);\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"list += l_offset;\n"
"for (int i=x; i < l_index; i+=GROUP_SIZE)\n"
"{\n"
"list[i] = l_points[i];\n"
"}\n"
"}\n"
"#elif defined FILL_ACCUM_GLOBAL\n"
"__kernel void fill_accum_global(__global const uchar * list_ptr, int list_step, int list_offset,\n"
"__global uchar * accum_ptr, int accum_step, int accum_offset,\n"
"int total_points, float irho, float theta, int numrho, int numangle)\n"
"{\n"
"int theta_idx = get_global_id(1);\n"
"int count_idx = get_global_id(0);\n"
"int glob_size = get_global_size(0);\n"
"float cosVal;\n"
"float sinVal = sincos(theta * ((float)theta_idx), &cosVal);\n"
"sinVal *= irho;\n"
"cosVal *= irho;\n"
"__global const int * list = (__global const int*)(list_ptr + list_offset);\n"
"__global int* accum = (__global int*)(accum_ptr + mad24(theta_idx + 1, accum_step, accum_offset));\n"
"const int shift = (numrho - 1) / 2;\n"
"if (theta_idx < numangle)\n"
"{\n"
"for (int i = count_idx; i < total_points; i += glob_size)\n"
"{\n"
"const int val = list[i];\n"
"const int x = (val & 0xFFFF);\n"
"const int y = (val >> 16) & 0xFFFF;\n"
"int r = convert_int_rte(mad((float)x, cosVal, y * sinVal)) + shift;\n"
"atomic_inc(accum + r + 1);\n"
"}\n"
"}\n"
"}\n"
"#elif defined FILL_ACCUM_LOCAL\n"
"__kernel void fill_accum_local(__global const uchar * list_ptr, int list_step, int list_offset,\n"
"__global uchar * accum_ptr, int accum_step, int accum_offset,\n"
"int total_points, float irho, float theta, int numrho, int numangle)\n"
"{\n"
"int theta_idx = get_group_id(1);\n"
"int count_idx = get_local_id(0);\n"
"__local int l_accum[BUFFER_SIZE];\n"
"if (theta_idx > 0 && theta_idx < numangle + 1)\n"
"{\n"
"float cosVal;\n"
"float sinVal = sincos(theta * (float) (theta_idx-1), &cosVal);\n"
"sinVal *= irho;\n"
"cosVal *= irho;\n"
"for (int i=count_idx; i<BUFFER_SIZE; i+=LOCAL_SIZE)\n"
"l_accum[i] = 0;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"__global const int * list = (__global const int*)(list_ptr + list_offset);\n"
"const int shift = (numrho - 1) / 2;\n"
"for (int i = count_idx; i < total_points; i += LOCAL_SIZE)\n"
"{\n"
"const int point = list[i];\n"
"const int x = (point & 0xFFFF);\n"
"const int y = point >> 16;\n"
"int r = convert_int_rte(mad((float)x, cosVal, y * sinVal)) + shift;\n"
"atomic_inc(l_accum + r + 1);\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"__global int* accum = (__global int*)(accum_ptr + mad24(theta_idx, accum_step, accum_offset));\n"
"for (int i=count_idx; i<BUFFER_SIZE; i+=LOCAL_SIZE)\n"
"accum[i] = l_accum[i];\n"
"}\n"
"else if (theta_idx < numangle + 2)\n"
"{\n"
"__global int* accum = (__global int*)(accum_ptr + mad24(theta_idx, accum_step, accum_offset));\n"
"for (int i=count_idx; i<BUFFER_SIZE; i+=LOCAL_SIZE)\n"
"accum[i] = 0;\n"
"}\n"
"}\n"
"#elif defined GET_LINES\n"
"__kernel void get_lines(__global uchar * accum_ptr, int accum_step, int accum_offset, int accum_rows, int accum_cols,\n"
"__global uchar * lines_ptr, int lines_step, int lines_offset, __global int* lines_index_ptr,\n"
"int linesMax, int threshold, float rho, float theta)\n"
"{\n"
"int x0 = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"int glob_size = get_global_size(0);\n"
"if (y < accum_rows-2)\n"
"{\n"
"__global uchar* accum = accum_ptr + mad24(y+1, accum_step, mad24(x0+1, (int) sizeof(int), accum_offset));\n"
"__global float2* lines = (__global float2*)(lines_ptr + lines_offset);\n"
"__global int* lines_index = lines_index_ptr + 1;\n"
"for (int x=x0; x<accum_cols-2; x+=glob_size)\n"
"{\n"
"int curVote = ACCUM(accum);\n"
"if (curVote > threshold && curVote > ACCUM(accum - sizeof(int)) && curVote >= ACCUM(accum + sizeof(int)) &&\n"
"curVote > ACCUM(accum - accum_step) && curVote >= ACCUM(accum + accum_step))\n"
"{\n"
"int index = atomic_inc(lines_index);\n"
"if (index < linesMax)\n"
"{\n"
"float radius = (x - (accum_cols - 3) * 0.5f) * rho;\n"
"float angle = y * theta;\n"
"lines[index] = (float2)(radius, angle);\n"
"}\n"
"}\n"
"accum += glob_size * (int) sizeof(int);\n"
"}\n"
"}\n"
"}\n"
"#elif GET_LINES_PROBABOLISTIC\n"
"__kernel void get_lines(__global const uchar * accum_ptr, int accum_step, int accum_offset, int accum_rows, int accum_cols,\n"
"__global const uchar * src_ptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * lines_ptr, int lines_step, int lines_offset, __global int* lines_index_ptr,\n"
"int linesMax, int threshold, int lineLength, int lineGap, float rho, float theta)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (y < accum_rows-2)\n"
"{\n"
"__global const uchar* accum = accum_ptr + mad24(y+1, accum_step, mad24(x+1, (int) sizeof(int), accum_offset));\n"
"__global int4* lines = (__global int4*)(lines_ptr + lines_offset);\n"
"__global int* lines_index = lines_index_ptr + 1;\n"
"int curVote = ACCUM(accum);\n"
"if (curVote >= threshold &&\n"
"curVote > ACCUM(accum - accum_step - sizeof(int)) &&\n"
"curVote > ACCUM(accum - accum_step) &&\n"
"curVote > ACCUM(accum - accum_step + sizeof(int)) &&\n"
"curVote > ACCUM(accum - sizeof(int)) &&\n"
"curVote > ACCUM(accum + sizeof(int)) &&\n"
"curVote > ACCUM(accum + accum_step - sizeof(int)) &&\n"
"curVote > ACCUM(accum + accum_step) &&\n"
"curVote > ACCUM(accum + accum_step + sizeof(int)))\n"
"{\n"
"const float radius = (x - (accum_cols - 2 - 1) * 0.5f) * rho;\n"
"const float angle = y * theta;\n"
"float cosa;\n"
"float sina = sincos(angle, &cosa);\n"
"float2 p0 = (float2)(cosa * radius, sina * radius);\n"
"float2 dir = (float2)(-sina, cosa);\n"
"float2 pb[4] = { (float2)(-1, -1), (float2)(-1, -1), (float2)(-1, -1), (float2)(-1, -1) };\n"
"float a;\n"
"if (dir.x != 0)\n"
"{\n"
"a = -p0.x / dir.x;\n"
"pb[0].x = 0;\n"
"pb[0].y = p0.y + a * dir.y;\n"
"a = (src_cols - 1 - p0.x) / dir.x;\n"
"pb[1].x = src_cols - 1;\n"
"pb[1].y = p0.y + a * dir.y;\n"
"}\n"
"if (dir.y != 0)\n"
"{\n"
"a = -p0.y / dir.y;\n"
"pb[2].x = p0.x + a * dir.x;\n"
"pb[2].y = 0;\n"
"a = (src_rows - 1 - p0.y) / dir.y;\n"
"pb[3].x = p0.x + a * dir.x;\n"
"pb[3].y = src_rows - 1;\n"
"}\n"
"if (pb[0].x == 0 && (pb[0].y >= 0 && pb[0].y < src_rows))\n"
"{\n"
"p0 = pb[0];\n"
"if (dir.x < 0)\n"
"dir = -dir;\n"
"}\n"
"else if (pb[1].x == src_cols - 1 && (pb[1].y >= 0 && pb[1].y < src_rows))\n"
"{\n"
"p0 = pb[1];\n"
"if (dir.x > 0)\n"
"dir = -dir;\n"
"}\n"
"else if (pb[2].y == 0 && (pb[2].x >= 0 && pb[2].x < src_cols))\n"
"{\n"
"p0 = pb[2];\n"
"if (dir.y < 0)\n"
"dir = -dir;\n"
"}\n"
"else if (pb[3].y == src_rows - 1 && (pb[3].x >= 0 && pb[3].x < src_cols))\n"
"{\n"
"p0 = pb[3];\n"
"if (dir.y > 0)\n"
"dir = -dir;\n"
"}\n"
"dir /= max(fabs(dir.x), fabs(dir.y));\n"
"float2 line_end[2];\n"
"int gap;\n"
"bool inLine = false;\n"
"if (p0.x < 0 || p0.x >= src_cols || p0.y < 0 || p0.y >= src_rows)\n"
"return;\n"
"for (;;)\n"
"{\n"
"if (*(src_ptr + mad24(p0.y, src_step, p0.x + src_offset)))\n"
"{\n"
"gap = 0;\n"
"if (!inLine)\n"
"{\n"
"line_end[0] = p0;\n"
"line_end[1] = p0;\n"
"inLine = true;\n"
"}\n"
"else\n"
"{\n"
"line_end[1] = p0;\n"
"}\n"
"}\n"
"else if (inLine)\n"
"{\n"
"if (++gap > lineGap)\n"
"{\n"
"bool good_line = fabs(line_end[1].x - line_end[0].x) >= lineLength ||\n"
"fabs(line_end[1].y - line_end[0].y) >= lineLength;\n"
"if (good_line)\n"
"{\n"
"int index = atomic_inc(lines_index);\n"
"if (index < linesMax)\n"
"lines[index] = (int4)(line_end[0].x, line_end[0].y, line_end[1].x, line_end[1].y);\n"
"}\n"
"gap = 0;\n"
"inLine = false;\n"
"}\n"
"}\n"
"p0 = p0 + dir;\n"
"if (p0.x < 0 || p0.x >= src_cols || p0.y < 0 || p0.y >= src_rows)\n"
"{\n"
"if (inLine)\n"
"{\n"
"bool good_line = fabs(line_end[1].x - line_end[0].x) >= lineLength ||\n"
"fabs(line_end[1].y - line_end[0].y) >= lineLength;\n"
"if (good_line)\n"
"{\n"
"int index = atomic_inc(lines_index);\n"
"if (index < linesMax)\n"
"lines[index] = (int4)(line_end[0].x, line_end[0].y, line_end[1].x, line_end[1].y);\n"
"}\n"
"}\n"
"break;\n"
"}\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
, "e6ccdb4eda8b85085da0ea6fa9ce4569", NULL};
struct cv::ocl::internal::ProgramEntry integral_sum_oclsrc={moduleName, "integral_sum",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#ifndef LOCAL_SUM_SIZE\n"
"#define LOCAL_SUM_SIZE      16\n"
"#endif\n"
"#define LOCAL_SUM_STRIDE    (LOCAL_SUM_SIZE + 1)\n"
"kernel void integral_sum_cols(__global const uchar *src_ptr, int src_step, int src_offset, int rows, int cols,\n"
"__global uchar *buf_ptr, int buf_step, int buf_offset\n"
"#ifdef SUM_SQUARE\n"
",__global uchar *buf_sq_ptr, int buf_sq_step, int buf_sq_offset\n"
"#endif\n"
")\n"
"{\n"
"__local sumT lm_sum[LOCAL_SUM_STRIDE * LOCAL_SUM_SIZE];\n"
"#ifdef SUM_SQUARE\n"
"__local sumSQT lm_sum_sq[LOCAL_SUM_STRIDE * LOCAL_SUM_SIZE];\n"
"#endif\n"
"int lid = get_local_id(0);\n"
"int gid = get_group_id(0);\n"
"int x = get_global_id(0);\n"
"int src_index = x + src_offset;\n"
"sumT accum = 0;\n"
"#ifdef SUM_SQUARE\n"
"sumSQT accum_sq = 0;\n"
"#endif\n"
"for (int y = 0; y < rows; y += LOCAL_SUM_SIZE)\n"
"{\n"
"int lsum_index = lid;\n"
"#pragma unroll\n"
"for (int yin = 0; yin < LOCAL_SUM_SIZE; yin++, src_index+=src_step, lsum_index += LOCAL_SUM_STRIDE)\n"
"{\n"
"if ((x < cols) && (y + yin < rows))\n"
"{\n"
"__global const uchar *src = src_ptr + src_index;\n"
"accum += src[0];\n"
"#ifdef SUM_SQUARE\n"
"sumSQT temp = src[0] * src[0];\n"
"accum_sq += temp;\n"
"#endif\n"
"}\n"
"lm_sum[lsum_index] = accum;\n"
"#ifdef SUM_SQUARE\n"
"lm_sum_sq[lsum_index] = accum_sq;\n"
"#endif\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"int buf_index = mad24(buf_step, LOCAL_SUM_SIZE * gid, mad24((int)sizeof(sumT), y + lid, buf_offset));\n"
"#ifdef SUM_SQUARE\n"
"int buf_sq_index = mad24(buf_sq_step, LOCAL_SUM_SIZE * gid, mad24((int)sizeof(sumSQT), y + lid, buf_sq_offset));\n"
"#endif\n"
"lsum_index = LOCAL_SUM_STRIDE * lid;\n"
"#pragma unroll\n"
"for (int yin = 0; yin < LOCAL_SUM_SIZE; yin++, lsum_index ++)\n"
"{\n"
"__global sumT *buf = (__global sumT *)(buf_ptr + buf_index);\n"
"buf[0] = lm_sum[lsum_index];\n"
"buf_index += buf_step;\n"
"#ifdef SUM_SQUARE\n"
"__global sumSQT *bufsq = (__global sumSQT *)(buf_sq_ptr + buf_sq_index);\n"
"bufsq[0] = lm_sum_sq[lsum_index];\n"
"buf_sq_index += buf_sq_step;\n"
"#endif\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"}\n"
"}\n"
"kernel void integral_sum_rows(__global const uchar *buf_ptr, int buf_step, int buf_offset,\n"
"#ifdef SUM_SQUARE\n"
"__global uchar *buf_sq_ptr, int buf_sq_step, int buf_sq_offset,\n"
"#endif\n"
"__global uchar *dst_ptr, int dst_step, int dst_offset, int rows, int cols\n"
"#ifdef SUM_SQUARE\n"
",__global uchar *dst_sq_ptr, int dst_sq_step, int dst_sq_offset\n"
"#endif\n"
")\n"
"{\n"
"__local sumT lm_sum[LOCAL_SUM_STRIDE * LOCAL_SUM_SIZE];\n"
"#ifdef SUM_SQUARE\n"
"__local sumSQT lm_sum_sq[LOCAL_SUM_STRIDE * LOCAL_SUM_SIZE];\n"
"#endif\n"
"int lid = get_local_id(0);\n"
"int gid = get_group_id(0);\n"
"int gs = get_global_size(0);\n"
"int x = get_global_id(0);\n"
"__global sumT *dst = (__global sumT *)(dst_ptr + dst_offset);\n"
"for (int xin = x; xin < cols; xin += gs)\n"
"{\n"
"dst[xin] = 0;\n"
"}\n"
"dst_offset += dst_step;\n"
"if (x < rows - 1)\n"
"{\n"
"dst = (__global sumT *)(dst_ptr + mad24(x, dst_step, dst_offset));\n"
"dst[0] = 0;\n"
"}\n"
"int buf_index = mad24((int)sizeof(sumT), x, buf_offset);\n"
"sumT accum = 0;\n"
"#ifdef SUM_SQUARE\n"
"__global sumSQT *dst_sq = (__global sumSQT *)(dst_sq_ptr + dst_sq_offset);\n"
"for (int xin = x; xin < cols; xin += gs)\n"
"{\n"
"dst_sq[xin] = 0;\n"
"}\n"
"dst_sq_offset += dst_sq_step;\n"
"if (x < rows - 1)\n"
"{\n"
"dst_sq = (__global sumSQT *)(dst_sq_ptr + mad24(x, dst_sq_step, dst_sq_offset));\n"
"dst_sq[0] = 0;\n"
"}\n"
"int buf_sq_index = mad24((int)sizeof(sumSQT), x, buf_sq_offset);\n"
"sumSQT accum_sq = 0;\n"
"#endif\n"
"for (int y = 1; y < cols; y += LOCAL_SUM_SIZE)\n"
"{\n"
"int lsum_index = lid;\n"
"#pragma unroll\n"
"for (int yin = 0; yin < LOCAL_SUM_SIZE; yin++, lsum_index += LOCAL_SUM_STRIDE)\n"
"{\n"
"__global const sumT *buf = (__global const sumT *)(buf_ptr + buf_index);\n"
"accum += buf[0];\n"
"lm_sum[lsum_index] = accum;\n"
"buf_index += buf_step;\n"
"#ifdef SUM_SQUARE\n"
"__global const sumSQT *buf_sq = (__global const sumSQT *)(buf_sq_ptr + buf_sq_index);\n"
"accum_sq += buf_sq[0];\n"
"lm_sum_sq[lsum_index] = accum_sq;\n"
"buf_sq_index += buf_sq_step;\n"
"#endif\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (y + lid < cols)\n"
"{\n"
"int dst_index = mad24(dst_step, LOCAL_SUM_SIZE * gid, mad24((int)sizeof(sumT), y + lid, dst_offset));\n"
"#ifdef SUM_SQUARE\n"
"int dst_sq_index = mad24(dst_sq_step, LOCAL_SUM_SIZE * gid, mad24((int)sizeof(sumSQT), y + lid, dst_sq_offset));\n"
"#endif\n"
"lsum_index = LOCAL_SUM_STRIDE * lid;\n"
"int yin_max = min(rows - 1 -  LOCAL_SUM_SIZE * gid, LOCAL_SUM_SIZE);\n"
"#pragma unroll\n"
"for (int yin = 0; yin < yin_max; yin++, lsum_index++)\n"
"{\n"
"dst = (__global sumT *)(dst_ptr + dst_index);\n"
"dst[0] = lm_sum[lsum_index];\n"
"dst_index += dst_step;\n"
"#ifdef SUM_SQUARE\n"
"dst_sq = (__global sumSQT *)(dst_sq_ptr + dst_sq_index);\n"
"dst_sq[0] = lm_sum_sq[lsum_index];\n"
"dst_sq_index += dst_sq_step;\n"
"#endif\n"
"}\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"}\n"
"}\n"
, "ed75bf92c46b18f3cbb1b0b85ed3d46d", NULL};
struct cv::ocl::internal::ProgramEntry laplacian3_oclsrc={moduleName, "laplacian3",
"#define DIG(a) a,\n"
"__constant float kx[] = { KERNEL_MATRIX };\n"
"#define OP(delta, x) (convert_float16(arr[delta + x]) * kx[x])\n"
"__kernel void laplacian3_8UC1_cols16_rows2(__global const uint* src, int src_step,\n"
"__global uint* dst, int dst_step,\n"
"int rows, int cols, float delta)\n"
"{\n"
"int block_x = get_global_id(0);\n"
"int y = get_global_id(1) * 2;\n"
"int ssx, dsx;\n"
"if ((block_x * 16) >= cols || y >= rows) return;\n"
"uint4 line[4];\n"
"uint4 line_out[2];\n"
"uchar a; uchar16 b; uchar c;\n"
"uchar d; uchar16 e; uchar f;\n"
"uchar g; uchar16 h; uchar i;\n"
"uchar j; uchar16 k; uchar l;\n"
"ssx = dsx = 1;\n"
"int src_index = block_x * 4 * ssx + (y - 1) * (src_step / 4);\n"
"line[1] = vload4(0, src + src_index + (src_step / 4));\n"
"line[2] = vload4(0, src + src_index + 2 * (src_step / 4));\n"
"#ifdef BORDER_CONSTANT\n"
"line[0] = (y == 0) ? (uint4)0 : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? (uint4)0 : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#elif defined BORDER_REFLECT_101\n"
"line[0] = (y == 0) ? line[2] : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? line[1] : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#elif defined (BORDER_REPLICATE) || defined(BORDER_REFLECT)\n"
"line[0] = (y == 0) ? line[1] : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? line[2] : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#endif\n"
"__global uchar *src_p = (__global uchar *)src;\n"
"src_index = block_x * 16 * ssx + (y - 1) * src_step;\n"
"bool line_end = ((block_x + 1) * 16 == cols);\n"
"b = as_uchar16(line[0]);\n"
"e = as_uchar16(line[1]);\n"
"h = as_uchar16(line[2]);\n"
"k = as_uchar16(line[3]);\n"
"#ifdef BORDER_CONSTANT\n"
"a = (block_x == 0 || y == 0) ? 0 : src_p[src_index - 1];\n"
"c = (line_end || y == 0) ? 0 : src_p[src_index + 16];\n"
"d = (block_x == 0) ? 0 : src_p[src_index + src_step - 1];\n"
"f = line_end ? 0 : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? 0 : src_p[src_index + 2 * src_step - 1];\n"
"i = line_end ? 0 : src_p[src_index + 2 * src_step + 16];\n"
"j = (block_x == 0 || y == (rows - 2)) ? 0 : src_p[src_index + 3 * src_step - 1];\n"
"l = (line_end || y == (rows - 2))? 0 : src_p[src_index + 3 * src_step + 16];\n"
"#elif defined BORDER_REFLECT_101\n"
"int offset;\n"
"offset = (y == 0) ? (2 * src_step) : 0;\n"
"a = (block_x == 0) ? src_p[src_index + offset + 1] : src_p[src_index + offset - 1];\n"
"c = line_end ? src_p[src_index + offset + 14] : src_p[src_index + offset + 16];\n"
"d = (block_x == 0) ? src_p[src_index + src_step + 1] : src_p[src_index + src_step - 1];\n"
"f = line_end ? src_p[src_index + src_step + 14] : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? src_p[src_index + 2 * src_step + 1] : src_p[src_index + 2 * src_step - 1];\n"
"i = line_end ? src_p[src_index + 2 * src_step + 14] : src_p[src_index + 2 * src_step + 16];\n"
"offset = (y == (rows - 2)) ? (1 * src_step) : (3 * src_step);\n"
"j = (block_x == 0) ? src_p[src_index + offset + 1] : src_p[src_index + offset - 1];\n"
"l = line_end ? src_p[src_index + offset + 14] : src_p[src_index + offset + 16];\n"
"#elif defined (BORDER_REPLICATE) || defined(BORDER_REFLECT)\n"
"int offset;\n"
"offset = (y == 0) ? (1 * src_step) : 0;\n"
"a = (block_x == 0) ? src_p[src_index + offset] : src_p[src_index + offset - 1];\n"
"c = line_end ? src_p[src_index + offset + 15] : src_p[src_index + offset + 16];\n"
"d = (block_x == 0) ? src_p[src_index + src_step] : src_p[src_index + src_step - 1];\n"
"f = line_end ? src_p[src_index + src_step + 15] : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? src_p[src_index + 2 * src_step] : src_p[src_index + 2 * src_step - 1];\n"
"i = line_end ? src_p[src_index + 2 * src_step + 15] : src_p[src_index + 2 * src_step + 16];\n"
"offset = (y == (rows - 2)) ? (2 * src_step) : (3 * src_step);\n"
"j = (block_x == 0) ? src_p[src_index + offset] : src_p[src_index + offset - 1];\n"
"l = line_end ? src_p[src_index + offset + 15] : src_p[src_index + offset + 16];\n"
"#endif\n"
"uchar16 arr[12];\n"
"float16 sum[2];\n"
"arr[0] = (uchar16)(a, b.s0123, b.s456789ab, b.scde);\n"
"arr[1] = b;\n"
"arr[2] = (uchar16)(b.s123, b.s4567, b.s89abcdef, c);\n"
"arr[3] = (uchar16)(d, e.s0123, e.s456789ab, e.scde);\n"
"arr[4] = e;\n"
"arr[5] = (uchar16)(e.s123, e.s4567, e.s89abcdef, f);\n"
"arr[6] = (uchar16)(g, h.s0123, h.s456789ab, h.scde);\n"
"arr[7] = h;\n"
"arr[8] = (uchar16)(h.s123, h.s4567, h.s89abcdef, i);\n"
"arr[9] = (uchar16)(j, k.s0123, k.s456789ab, k.scde);\n"
"arr[10] = k;\n"
"arr[11] = (uchar16)(k.s123, k.s4567, k.s89abcdef, l);\n"
"sum[0] = OP(0, 0) + OP(0, 1) + OP(0, 2) +\n"
"OP(0, 3) + OP(0, 4) + OP(0, 5) +\n"
"OP(0, 6) + OP(0, 7) + OP(0, 8);\n"
"sum[1] = OP(3, 0) + OP(3, 1) + OP(3, 2) +\n"
"OP(3, 3) + OP(3, 4) + OP(3, 5) +\n"
"OP(3, 6) + OP(3, 7) + OP(3, 8);\n"
"line_out[0] = as_uint4(convert_uchar16_sat_rte(sum[0] + delta));\n"
"line_out[1] = as_uint4(convert_uchar16_sat_rte(sum[1] + delta));\n"
"int dst_index = block_x * 4 * dsx + y * (dst_step / 4);\n"
"vstore4(line_out[0], 0, dst + dst_index);\n"
"vstore4(line_out[1], 0, dst + dst_index + (dst_step / 4));\n"
"}\n"
, "c7b7eb4f034bd214e42f2dccc9ffd970", NULL};
struct cv::ocl::internal::ProgramEntry laplacian5_oclsrc={moduleName, "laplacian5",
"#define noconvert\n"
"#ifdef ONLY_SUM_CONVERT\n"
"__kernel void sumConvert(__global const uchar * src1ptr, int src1_step, int src1_offset,\n"
"__global const uchar * src2ptr, int src2_step, int src2_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"coeffT scale, coeffT delta)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (y < dst_rows && x < dst_cols)\n"
"{\n"
"int src1_index = mad24(y, src1_step, mad24(x, (int)sizeof(srcT), src1_offset));\n"
"int src2_index = mad24(y, src2_step, mad24(x, (int)sizeof(srcT), src2_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, (int)sizeof(dstT), dst_offset));\n"
"__global const srcT * src1 = (__global const srcT *)(src1ptr + src1_index);\n"
"__global const srcT * src2 = (__global const srcT *)(src2ptr + src2_index);\n"
"__global dstT * dst = (__global dstT *)(dstptr + dst_index);\n"
"#if wdepth <= 4\n"
"dst[0] = convertToDT( mad24((WT)(scale), convertToWT(src1[0]) + convertToWT(src2[0]), (WT)(delta)) );\n"
"#else\n"
"dst[0] = convertToDT( mad((WT)(scale), convertToWT(src1[0]) + convertToWT(src2[0]), (WT)(delta)) );\n"
"#endif\n"
"}\n"
"}\n"
"#else\n"
"#ifdef BORDER_CONSTANT\n"
"#define EXTRAPOLATE(x, maxV)\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = clamp((x), 0, (maxV)-1); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = ( (x) + (maxV) ) % (maxV); \\\n"
"}\n"
"#elif defined BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = min(((maxV)-1)*2-(x)+1, max((x),-(x)-1) ); \\\n"
"}\n"
"#elif defined BORDER_REFLECT_101\n"
"#define EXTRAPOLATE(x, maxV) \\\n"
"{ \\\n"
"(x) = min(((maxV)-1)*2-(x), max((x),-(x)) ); \\\n"
"}\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#if CN != 3\n"
"#define loadpix(addr) *(__global const srcT *)(addr)\n"
"#define storepix(val, addr)  *(__global dstT *)(addr) = val\n"
"#define SRCSIZE (int)sizeof(srcT)\n"
"#define DSTSIZE (int)sizeof(dstT)\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const srcT1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global dstT1 *)(addr))\n"
"#define SRCSIZE (int)sizeof(srcT1)*3\n"
"#define DSTSIZE (int)sizeof(dstT1)*3\n"
"#endif\n"
"#define SRC(_x,_y) convertToWT(loadpix(Src + mad24(_y, src_step, SRCSIZE * _x)))\n"
"#ifdef BORDER_CONSTANT\n"
"#define ELEM(_x,_y,r_edge,t_edge,const_v) (_x)<0 | (_x) >= (r_edge) | (_y)<0 | (_y) >= (t_edge) ? (const_v) : SRC((_x),(_y))\n"
"#else\n"
"#define ELEM(_x,_y,r_edge,t_edge,const_v) SRC((_x),(_y))\n"
"#endif\n"
"#define DIG(a) a,\n"
"__constant WT1 mat_kernelX[] = { KERNEL_MATRIX_X };\n"
"__constant WT1 mat_kernelY[] = { KERNEL_MATRIX_Y };\n"
"__kernel void laplacian(__global uchar* Src, int src_step, int srcOffsetX, int srcOffsetY, int height, int width,\n"
"__global uchar* Dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"WT1 scale, WT1 delta)\n"
"{\n"
"__local WT lsmem[BLK_Y + 2 * RADIUS][BLK_X + 2 * RADIUS];\n"
"__local WT lsmemDy1[BLK_Y][BLK_X + 2 * RADIUS];\n"
"__local WT lsmemDy2[BLK_Y][BLK_X + 2 * RADIUS];\n"
"int lix = get_local_id(0);\n"
"int liy = get_local_id(1);\n"
"int x = get_global_id(0);\n"
"int srcX = x + srcOffsetX - RADIUS;\n"
"int clocY = liy;\n"
"do\n"
"{\n"
"int yb = clocY + srcOffsetY - RADIUS;\n"
"EXTRAPOLATE(yb, (height));\n"
"int clocX = lix;\n"
"int cSrcX = srcX;\n"
"do\n"
"{\n"
"int xb = cSrcX;\n"
"EXTRAPOLATE(xb,(width));\n"
"lsmem[clocY][clocX] = ELEM(xb, yb, (width), (height), 0 );\n"
"clocX += BLK_X;\n"
"cSrcX += BLK_X;\n"
"}\n"
"while(clocX < BLK_X+(RADIUS*2));\n"
"clocY += BLK_Y;\n"
"}\n"
"while (clocY < BLK_Y+(RADIUS*2));\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"WT scale_v = (WT)scale;\n"
"WT delta_v = (WT)delta;\n"
"for (int y = 0; y < dst_rows; y+=BLK_Y)\n"
"{\n"
"int i, clocX = lix;\n"
"WT sum1 = (WT) 0;\n"
"WT sum2 = (WT) 0;\n"
"do\n"
"{\n"
"sum1 = (WT) 0;\n"
"sum2 = (WT) 0;\n"
"for (i=0; i<=2*RADIUS; i++)\n"
"{\n"
"sum1 = mad(lsmem[liy + i][clocX], mat_kernelY[i], sum1);\n"
"sum2 = mad(lsmem[liy + i][clocX], mat_kernelX[i], sum2);\n"
"}\n"
"lsmemDy1[liy][clocX] = sum1;\n"
"lsmemDy2[liy][clocX] = sum2;\n"
"clocX += BLK_X;\n"
"}\n"
"while(clocX < BLK_X+(RADIUS*2));\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if ((x < dst_cols) && (y + liy < dst_rows))\n"
"{\n"
"sum1 = (WT) 0;\n"
"sum2 = (WT) 0;\n"
"for (i=0; i<=2*RADIUS; i++)\n"
"{\n"
"sum1 = mad(lsmemDy1[liy][lix+i], mat_kernelX[i], sum1);\n"
"sum2 = mad(lsmemDy2[liy][lix+i], mat_kernelY[i], sum2);\n"
"}\n"
"WT sum = mad(scale_v, (sum1 + sum2), delta_v);\n"
"storepix(convertToDT(sum), Dst + mad24(y + liy, dst_step, mad24(x, DSTSIZE, dst_offset)));\n"
"}\n"
"for (int i = liy * BLK_X + lix; i < (RADIUS*2) * (BLK_X+(RADIUS*2)); i += BLK_X * BLK_Y)\n"
"{\n"
"int clocX = i % (BLK_X+(RADIUS*2));\n"
"int clocY = i / (BLK_X+(RADIUS*2));\n"
"lsmem[clocY][clocX] = lsmem[clocY + BLK_Y][clocX];\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"int yb = y + liy + BLK_Y + srcOffsetY + RADIUS;\n"
"EXTRAPOLATE(yb, (height));\n"
"clocX = lix;\n"
"int cSrcX = x + srcOffsetX - RADIUS;\n"
"do\n"
"{\n"
"int xb = cSrcX;\n"
"EXTRAPOLATE(xb,(width));\n"
"lsmem[liy + 2*RADIUS][clocX] = ELEM(xb, yb, (width), (height), 0 );\n"
"clocX += BLK_X;\n"
"cSrcX += BLK_X;\n"
"}\n"
"while(clocX < BLK_X+(RADIUS*2));\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"}\n"
"}\n"
"#endif\n"
, "3ce3fc1a1c2e6be3a8fd0d2f51afeaf1", NULL};
struct cv::ocl::internal::ProgramEntry linearPolar_oclsrc={moduleName, "linearPolar",
"#define CV_2PI 6.283185307179586476925286766559\n"
"#ifdef ForwardMap\n"
"__kernel void computeAngleRadius(__global float2* cp_sp, __global float* r, float maxRadius_width,  float PI2_height,  unsigned width, unsigned height)\n"
"{\n"
"unsigned gid = get_global_id(0);\n"
"if (gid < height)\n"
"{\n"
"float angle = gid * PI2_height;\n"
"float2 angle_tri=(float2)(cos(angle), sin(angle));\n"
"cp_sp[gid] = angle_tri;\n"
"}\n"
"if (gid < width)\n"
"{\n"
"r[gid] = maxRadius_width*gid;\n"
"}\n"
"}\n"
"__kernel void linearPolar(__global float* mx, __global float* my, __global float2* cp_sp,  __global float* r, float cx, float cy, unsigned width, unsigned height)\n"
"{\n"
"__local float l_r[MEM_SIZE];\n"
"__local float2 l_double[MEM_SIZE];\n"
"unsigned rho = get_global_id(0);\n"
"unsigned phi = get_global_id(1);\n"
"unsigned local_0 = get_local_id(0);\n"
"unsigned local_1 = get_local_id(1);\n"
"if (local_1 == 0)\n"
"{\n"
"unsigned temp_phi=phi + local_0;\n"
"if (temp_phi < height)\n"
"{\n"
"l_double[local_0] = cp_sp[temp_phi];\n"
"}\n"
"}\n"
"if (local_1 == 1 )\n"
"{\n"
"if (rho < width)\n"
"{\n"
"l_r[local_0 ] = r[rho];\n"
"}\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (rho<width && phi<height)\n"
"{\n"
"unsigned g_id = rho + phi*width;\n"
"float radius = l_r[local_0];\n"
"float2 tri= l_double[local_1];\n"
"mx[g_id] = fma(radius, tri.x , cx);\n"
"my[g_id] = fma(radius, tri.y , cy);\n"
"}\n"
"}\n"
"#elif defined (InverseMap)\n"
"__kernel void linearPolar(__global float* mx, __global float* my, float ascale, float pscale, float cx, float cy, int angle_border, unsigned width, unsigned height)\n"
"{\n"
"const int x = get_global_id(0);\n"
"const int y = get_global_id(1);\n"
"if (x < width && y < height)\n"
"{\n"
"unsigned g_id = x + y*width;\n"
"float dx = (float)x - cx;\n"
"float dy = (float)y - cy;\n"
"float mag = sqrt(dx*dx + dy*dy);\n"
"float angle = atan2(dy, dx);\n"
"if (angle < 0)\n"
"angle = angle + CV_2PI;\n"
"mx[g_id] = mag*pscale;\n"
"my[g_id] = (angle*ascale) + angle_border;\n"
"}\n"
"}\n"
"#endif\n"
, "89f1e77eeee5eac065b1acecfa13ca5a", NULL};
struct cv::ocl::internal::ProgramEntry logPolar_oclsrc={moduleName, "logPolar",
"#define CV_2PI 6.283185307179586476925286766559\n"
"#ifdef ForwardMap\n"
"__kernel void computeAngleRadius(__global float2* cp_sp, __global float* r, float m, float PI2_height, unsigned width, unsigned height)\n"
"{\n"
"unsigned gid = get_global_id(0);\n"
"if (gid < height)\n"
"{\n"
"float angle = gid * PI2_height;\n"
"float2 angle_tri = (float2)(cos(angle), sin(angle));\n"
"cp_sp[gid] = angle_tri;\n"
"}\n"
"if (gid < width)\n"
"{\n"
"r[gid] = exp(gid/m)-1.0f;\n"
"}\n"
"}\n"
"__kernel void logPolar(__global float* mx, __global float* my, __global float2* cp_sp, __global float* r, float cx, float cy, unsigned width, unsigned height)\n"
"{\n"
"__local float l_r[MEM_SIZE];\n"
"__local float2 l_double[MEM_SIZE];\n"
"unsigned rho = get_global_id(0);\n"
"unsigned phi = get_global_id(1);\n"
"unsigned local_0 = get_local_id(0);\n"
"unsigned local_1 = get_local_id(1);\n"
"if (local_1 == 0)\n"
"{\n"
"unsigned temp_phi = phi + local_0;\n"
"if (temp_phi < height)\n"
"{\n"
"l_double[local_0] = cp_sp[temp_phi];\n"
"}\n"
"}\n"
"if (local_1 == 1)\n"
"{\n"
"if (rho < width)\n"
"{\n"
"l_r[local_0] = r[rho];\n"
"}\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (rho<width && phi<height)\n"
"{\n"
"unsigned g_id = rho + phi*width;\n"
"float radius = l_r[local_0];\n"
"float2 tri = l_double[local_1];\n"
"mx[g_id] = fma(radius, tri.x , cx);\n"
"my[g_id] = fma(radius, tri.y, cy);\n"
"}\n"
"}\n"
"#elif defined (InverseMap)\n"
"__kernel void logPolar(__global float* mx, __global float* my, float ascale, float m, float cx, float cy, int angle_border, unsigned width, unsigned height)\n"
"{\n"
"const int x = get_global_id(0);\n"
"const int y = get_global_id(1);\n"
"if (x < width && y < height)\n"
"{\n"
"unsigned g_id = x + y*width;\n"
"float dx = (float)x - cx;\n"
"float dy = (float)y - cy;\n"
"float mag = log(sqrt(dx*dx + dy*dy)+1.0f);\n"
"float angle = atan2(dy, dx);\n"
"if (angle < 0)\n"
"angle = angle + CV_2PI;\n"
"mx[g_id] = mag*m;\n"
"my[g_id] = (angle*ascale) + angle_border;\n"
"}\n"
"}\n"
"#endif\n"
, "d8138a1bd58e27bf2f6c1cecc6e1ad6b", NULL};
struct cv::ocl::internal::ProgramEntry match_template_oclsrc={moduleName, "match_template",
"#if cn != 3\n"
"#define loadpix(addr) *(__global const T *)(addr)\n"
"#define TSIZE (int)sizeof(T)\n"
"#else\n"
"#define loadpix(addr) vload3(0, (__global const T1 *)(addr))\n"
"#define TSIZE ((int)sizeof(T1)*3)\n"
"#endif\n"
"#define SQSUMS_PTR(ox, oy) mad24(y + oy, src_sqsums_step, mad24(x + ox, cn, src_sqsums_offset))\n"
"#define SUMS_PTR(ox, oy) mad24(y + oy, src_sums_step, mad24(x + ox, cn, src_sums_offset))\n"
"#define SUMS(ox, oy)    mad24(y+oy, src_sums_step, mad24(x+ox, (int)sizeof(T1)*cn, src_sums_offset))\n"
"#define SQ_SUMS(ox, oy) mad24(y+oy, src_sqsums_step, mad24(x+ox, (int)sizeof(T1)*cn, src_sqsums_offset))\n"
"inline float normAcc(float num, float denum)\n"
"{\n"
"if (fabs(num) < denum)\n"
"return num / denum;\n"
"if (fabs(num) < denum * 1.125f)\n"
"return num > 0 ? 1 : -1;\n"
"return 0;\n"
"}\n"
"inline float normAcc_SQDIFF(float num, float denum)\n"
"{\n"
"if (fabs(num) < denum)\n"
"return num / denum;\n"
"if (fabs(num) < denum * 1.125f)\n"
"return num > 0 ? 1 : -1;\n"
"return 1;\n"
"}\n"
"#define noconvert\n"
"#if cn == 1\n"
"#define convertToDT(value) (float)(value)\n"
"#elif cn == 2\n"
"#define convertToDT(value) (float)(value.x + value.y)\n"
"#elif cn == 3\n"
"#define convertToDT(value) (float)(value.x + value.y + value.z)\n"
"#elif cn == 4\n"
"#define convertToDT(value) (float)(value.x + value.y + value.z + value.w)\n"
"#else\n"
"#error \"cn should be 1-4\"\n"
"#endif\n"
"#ifdef CALC_SUM\n"
"__kernel void calcSum(__global const uchar * srcptr, int src_step, int src_offset,\n"
"int cols, int total, __global float * dst)\n"
"{\n"
"int lid = get_local_id(0), id = get_global_id(0);\n"
"__local WT localmem[WGS2_ALIGNED];\n"
"WT accumulator = (WT)(0), tmp;\n"
"for ( ; id < total; id += WGS)\n"
"{\n"
"int src_index = mad24(id / cols, src_step, mad24(id % cols, TSIZE, src_offset));\n"
"T src = loadpix(srcptr + src_index);\n"
"tmp = convertToWT(src);\n"
"accumulator = mad(tmp, tmp, accumulator);\n"
"}\n"
"if (lid < WGS2_ALIGNED)\n"
"localmem[lid] = accumulator;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (lid >= WGS2_ALIGNED && total >= WGS2_ALIGNED)\n"
"localmem[lid - WGS2_ALIGNED] += accumulator;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"for (int lsize = WGS2_ALIGNED >> 1; lsize > 0; lsize >>= 1)\n"
"{\n"
"if (lid < lsize)\n"
"{\n"
"int lid2 = lsize + lid;\n"
"localmem[lid] += localmem[lid2];\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"}\n"
"if (lid == 0)\n"
"dst[0] = convertToDT(localmem[0]);\n"
"}\n"
"#elif defined FIRST_CHANNEL\n"
"__kernel void extractFirstChannel( const __global uchar* img, int img_step, int img_offset,\n"
"__global uchar* res, int res_step, int res_offset, int rows, int cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1)*PIX_PER_WI_Y;\n"
"if(x < cols )\n"
"{\n"
"#pragma unroll\n"
"for (int cy=0; cy < PIX_PER_WI_Y && y < rows; ++cy, ++y)\n"
"{\n"
"T1 image = *(__global const T1*)(img + mad24(y, img_step, mad24(x, (int)sizeof(T1)*cn, img_offset)));;\n"
"int res_idx = mad24(y, res_step, mad24(x, (int)sizeof(float), res_offset));\n"
"*(__global float *)(res + res_idx) = image;\n"
"}\n"
"}\n"
"}\n"
"#elif defined CCORR\n"
"#if cn==1 && PIX_PER_WI_X==4\n"
"__kernel void matchTemplate_Naive_CCORR(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global const uchar * templateptr, int template_step, int template_offset, int template_rows, int template_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"int x0 = get_global_id(0)*PIX_PER_WI_X;\n"
"int y = get_global_id(1);\n"
"if (y < dst_rows)\n"
"{\n"
"if (x0 + PIX_PER_WI_X <= dst_cols)\n"
"{\n"
"WT sum = (WT)(0);\n"
"int ind = mad24(y, src_step, mad24(x0, (int)sizeof(T1), src_offset));\n"
"__global const T1 * template = (__global const T1*)(templateptr + template_offset);\n"
"for (int i = 0; i < template_rows; ++i)\n"
"{\n"
"for (int j = 0; j < template_cols; ++j)\n"
"{\n"
"T temp = (T)(template[j]);\n"
"T src = vload4(0, (__global const T1*)(srcptr + ind + j*(int)sizeof(T1)));\n"
"sum = mad(convertToWT(src), convertToWT(temp), sum);\n"
"}\n"
"ind += src_step;\n"
"template = (__global const T1 *)((__global const uchar *)template + template_step);\n"
"}\n"
"T temp = (T)(template[0]);\n"
"int dst_idx = mad24(y, dst_step, mad24(x0, (int)sizeof(float), dst_offset));\n"
"*(__global float4 *)(dst + dst_idx) = convert_float4(sum);\n"
"}\n"
"else\n"
"{\n"
"WT1 sum [PIX_PER_WI_X];\n"
"#pragma unroll\n"
"for (int i=0; i < PIX_PER_WI_X; i++) sum[i] = 0;\n"
"__global const T1 * src = (__global const T1 *)(srcptr + mad24(y, src_step, mad24(x0, (int)sizeof(T1), src_offset)));\n"
"__global const T1 * template = (__global const T1 *)(templateptr + template_offset);\n"
"for (int i = 0; i < template_rows; ++i)\n"
"{\n"
"for (int j = 0; j < template_cols; ++j)\n"
"{\n"
"#pragma unroll\n"
"for (int cx=0, x = x0; cx < PIX_PER_WI_X && x < dst_cols; ++cx, ++x)\n"
"{\n"
"sum[cx] = mad(convertToWT1(src[j+cx]), convertToWT1(template[j]), sum[cx]);\n"
"}\n"
"}\n"
"src = (__global const T1 *)((__global const uchar *)src + src_step);\n"
"template = (__global const T1 *)((__global const uchar *)template + template_step);\n"
"}\n"
"#pragma unroll\n"
"for (int cx=0; cx < PIX_PER_WI_X && x0 < dst_cols; ++cx, ++x0)\n"
"{\n"
"int dst_idx = mad24(y, dst_step, mad24(x0, (int)sizeof(float), dst_offset));\n"
"*(__global float *)(dst + dst_idx) = convertToDT(sum[cx]);\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#else\n"
"__kernel void matchTemplate_Naive_CCORR(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global const uchar * templateptr, int template_step, int template_offset, int template_rows, int template_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"WT sum = (WT)(0);\n"
"for (int i = 0; i < template_rows; ++i)\n"
"{\n"
"for (int j = 0; j < template_cols; ++j)\n"
"{\n"
"T src      = loadpix(srcptr      + mad24(y+i, src_step,    mad24(x+j, TSIZE, src_offset)));\n"
"T template = loadpix(templateptr + mad24(i, template_step, mad24(j, TSIZE, template_offset)));\n"
"sum = mad(convertToWT(src), convertToWT(template), sum);\n"
"}\n"
"}\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"*(__global float *)(dst + dst_idx) = convertToDT(sum);\n"
"}\n"
"}\n"
"#endif\n"
"#elif defined CCORR_NORMED\n"
"__kernel void matchTemplate_CCORR_NORMED(__global const uchar * src_sqsums, int src_sqsums_step, int src_sqsums_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"int template_rows, int template_cols, __global const float * template_sqsum)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"__global const float * sqsum = (__global const float *)(src_sqsums);\n"
"src_sqsums_step /= sizeof(float);\n"
"src_sqsums_offset /= sizeof(float);\n"
"float image_sqsum_ = (float)(sqsum[SQSUMS_PTR(template_cols, template_rows)] - sqsum[SQSUMS_PTR(template_cols, 0)] -\n"
"sqsum[SQSUMS_PTR(0, template_rows)] + sqsum[SQSUMS_PTR(0, 0)]);\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"__global float * dstult = (__global float *)(dst + dst_idx);\n"
"*dstult = normAcc(*dstult, sqrt(image_sqsum_ * template_sqsum[0]));\n"
"}\n"
"}\n"
"#elif defined SQDIFF\n"
"__kernel void matchTemplate_Naive_SQDIFF(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global const uchar * templateptr, int template_step, int template_offset, int template_rows, int template_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"WT sum = (WT)(0), value;\n"
"for (int i = 0; i < template_rows; ++i)\n"
"{\n"
"for (int j = 0; j < template_cols; ++j)\n"
"{\n"
"T src      = loadpix(srcptr      + mad24(y+i, src_step,    mad24(x+j, TSIZE, src_offset)));\n"
"T template = loadpix(templateptr + mad24(i, template_step, mad24(j, TSIZE, template_offset)));\n"
"value = convertToWT(src) - convertToWT(template);\n"
"sum = mad(value, value, sum);\n"
"}\n"
"}\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"*(__global float *)(dst + dst_idx) = convertToDT(sum);\n"
"}\n"
"}\n"
"#elif defined SQDIFF_PREPARED\n"
"__kernel void matchTemplate_Prepared_SQDIFF(__global const uchar * src_sqsums, int src_sqsums_step, int src_sqsums_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"int template_rows, int template_cols, __global const float * template_sqsum)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"src_sqsums_step /= sizeof(float);\n"
"src_sqsums_offset /= sizeof(float);\n"
"__global const float * sqsum = (__global const float *)(src_sqsums);\n"
"float image_sqsum_ = (float)(\n"
"(sqsum[SQSUMS_PTR(template_cols, template_rows)] - sqsum[SQSUMS_PTR(template_cols, 0)]) -\n"
"(sqsum[SQSUMS_PTR(0, template_rows)] - sqsum[SQSUMS_PTR(0, 0)]));\n"
"float template_sqsum_value = template_sqsum[0];\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"__global float * dstult = (__global float *)(dst + dst_idx);\n"
"*dstult = image_sqsum_ - 2.0f * dstult[0] + template_sqsum_value;\n"
"}\n"
"}\n"
"#elif defined SQDIFF_NORMED\n"
"__kernel void matchTemplate_SQDIFF_NORMED(__global const uchar * src_sqsums, int src_sqsums_step, int src_sqsums_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"int template_rows, int template_cols, __global const float * template_sqsum)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"src_sqsums_step /= sizeof(float);\n"
"src_sqsums_offset /= sizeof(float);\n"
"__global const float * sqsum = (__global const float *)(src_sqsums);\n"
"float image_sqsum_ = (float)(\n"
"(sqsum[SQSUMS_PTR(template_cols, template_rows)] - sqsum[SQSUMS_PTR(template_cols, 0)]) -\n"
"(sqsum[SQSUMS_PTR(0, template_rows)] - sqsum[SQSUMS_PTR(0, 0)]));\n"
"float template_sqsum_value = template_sqsum[0];\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"__global float * dstult = (__global float *)(dst + dst_idx);\n"
"*dstult = normAcc_SQDIFF(image_sqsum_ - 2.0f * dstult[0] + template_sqsum_value, sqrt(image_sqsum_ * template_sqsum_value));\n"
"}\n"
"}\n"
"#elif defined CCOEFF\n"
"#if cn == 1\n"
"__kernel void matchTemplate_Prepared_CCOEFF(__global const uchar * src_sums, int src_sums_step, int src_sums_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"int template_rows, int template_cols, float template_sum)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"__global const T* sum = (__global const T*)(src_sums + mad24(y, src_sums_step, mad24(x, (int)sizeof(T), src_sums_offset)));\n"
"int step = src_sums_step/(int)sizeof(T);\n"
"T image_sum = (T)(0), value;\n"
"value = (T)(sum[mad24(template_rows, step, template_cols)] - sum[mad24(template_rows, step, 0)] - sum[template_cols] + sum[0]);\n"
"image_sum = mad(value, template_sum , image_sum);\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"*(__global float *)(dst + dst_idx) -= convertToDT(image_sum);\n"
"}\n"
"}\n"
"#elif cn==3\n"
"__kernel void matchTemplate_Prepared_CCOEFF(__global const uchar * src_sums, int src_sums_step, int src_sums_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"int template_rows, int template_cols, float4 template_sum)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"T image_sum = (T)(0), value, temp_sum;\n"
"temp_sum.x = template_sum.x;\n"
"temp_sum.y = template_sum.y;\n"
"temp_sum.z = template_sum.z;\n"
"value  = vload3(0, (__global const T1 *)(src_sums + SUMS(template_cols, template_rows)));\n"
"value -= vload3(0, (__global const T1 *)(src_sums + SUMS(0, template_rows)));\n"
"value -= vload3(0, (__global const T1 *)(src_sums + SUMS(template_cols, 0)));\n"
"value += vload3(0, (__global const T1 *)(src_sums + SUMS(0, 0)));\n"
"image_sum = mad(value, temp_sum , 0);\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"*(__global float *)(dst + dst_idx) -= convertToDT(image_sum);\n"
"}\n"
"}\n"
"#elif (cn==2 || cn==4)\n"
"__kernel void matchTemplate_Prepared_CCOEFF(__global const uchar * src_sums, int src_sums_step, int src_sums_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"int template_rows, int template_cols, float4 template_sum)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"__global const T* sum = (__global const T*)(src_sums + mad24(y, src_sums_step, mad24(x, (int)sizeof(T), src_sums_offset)));\n"
"int step = src_sums_step/(int)sizeof(T);\n"
"T image_sum = (T)(0), value, temp_sum;\n"
"#if cn==2\n"
"temp_sum.x = template_sum.x;\n"
"temp_sum.y = template_sum.y;\n"
"#else\n"
"temp_sum = template_sum;\n"
"#endif\n"
"value = (sum[mad24(template_rows, step, template_cols)] - sum[mad24(template_rows, step, 0)] - sum[template_cols] + sum[0]);\n"
"image_sum = mad(value, temp_sum , image_sum);\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"*(__global float *)(dst + dst_idx) -= convertToDT(image_sum);\n"
"}\n"
"}\n"
"#else\n"
"#error \"cn should be 1-4\"\n"
"#endif\n"
"#elif defined CCOEFF_NORMED\n"
"#if cn == 1\n"
"__kernel void matchTemplate_CCOEFF_NORMED(__global const uchar * src_sums, int src_sums_step, int src_sums_offset,\n"
"__global const uchar * src_sqsums, int src_sqsums_step, int src_sqsums_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"int t_rows, int t_cols, float weight, float template_sum, float template_sqsum)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"float sum_[2];\n"
"float sqsum_[2];\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"int step = src_sums_step/(int)sizeof(T);\n"
"__global const T* sum   = (__global const T*)(src_sums + mad24(y, src_sums_step,     mad24(x, (int)sizeof(T), src_sums_offset)));\n"
"__global const T* sqsum = (__global const T*)(src_sqsums + mad24(y, src_sqsums_step, mad24(x, (int)sizeof(T), src_sqsums_offset)));\n"
"T value_sum   = sum[mad24(t_rows, step, t_cols)] - sum[mad24(t_rows, step, 0)] - sum[t_cols] + sum[0];\n"
"T value_sqsum = sqsum[mad24(t_rows, step, t_cols)] - sqsum[mad24(t_rows, step, 0)] - sqsum[t_cols] + sqsum[0];\n"
"float num = convertToDT(mad(value_sum, template_sum, (float)0));\n"
"value_sqsum -= weight * value_sum * value_sum;\n"
"float denum = sqrt(mad(template_sqsum, convertToDT(value_sqsum), (float)0));\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"__global float * dstult = (__global float *)(dst+dst_idx);\n"
"*dstult = normAcc((*dstult) - num, denum);\n"
"}\n"
"}\n"
"#elif cn==3\n"
"__kernel void matchTemplate_CCOEFF_NORMED(__global const uchar * src_sums, int src_sums_step, int src_sums_offset,\n"
"__global const uchar * src_sqsums, int src_sqsums_step, int src_sqsums_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"int t_rows, int t_cols, float weight, float4 template_sum, float template_sqsum)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"int step = src_sums_step/(int)sizeof(T);\n"
"T temp_sum, value_sum, value_sqsum;\n"
"temp_sum.x = template_sum.x;\n"
"temp_sum.y = template_sum.y;\n"
"temp_sum.z = template_sum.z;\n"
"value_sum  = vload3(0, (__global const T1 *)(src_sums + SUMS(t_cols, t_rows)));\n"
"value_sum -= vload3(0, (__global const T1 *)(src_sums + SUMS(0, t_rows)));\n"
"value_sum -= vload3(0, (__global const T1 *)(src_sums + SUMS(t_cols, 0)));\n"
"value_sum += vload3(0, (__global const T1 *)(src_sums + SUMS(0, 0)));\n"
"value_sqsum  = vload3(0, (__global const T1 *)(src_sqsums + SQ_SUMS(t_cols, t_rows)));\n"
"value_sqsum -= vload3(0, (__global const T1 *)(src_sqsums + SQ_SUMS(0, t_rows)));\n"
"value_sqsum -= vload3(0, (__global const T1 *)(src_sqsums + SQ_SUMS(t_cols, 0)));\n"
"value_sqsum += vload3(0, (__global const T1 *)(src_sqsums + SQ_SUMS(0, 0)));\n"
"float num = convertToDT(mad(value_sum, temp_sum, 0));\n"
"value_sqsum -= weight * value_sum * value_sum;\n"
"float denum = sqrt(mad(template_sqsum, convertToDT(value_sqsum), (float)0));\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"__global float * dstult = (__global float *)(dst+dst_idx);\n"
"*dstult = normAcc((*dstult) - num, denum);\n"
"}\n"
"}\n"
"#elif (cn==2 || cn==4)\n"
"__kernel void matchTemplate_CCOEFF_NORMED(__global const uchar * src_sums, int src_sums_step, int src_sums_offset,\n"
"__global const uchar * src_sqsums, int src_sqsums_step, int src_sqsums_offset,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"int t_rows, int t_cols, float weight, float4 template_sum, float template_sqsum)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"int step = src_sums_step/(int)sizeof(T);\n"
"T temp_sum;\n"
"__global const T* sum   = (__global const T*)(src_sums + mad24(y, src_sums_step,     mad24(x, (int)sizeof(T), src_sums_offset)));\n"
"__global const T* sqsum = (__global const T*)(src_sqsums + mad24(y, src_sqsums_step, mad24(x, (int)sizeof(T), src_sqsums_offset)));\n"
"T value_sum   = sum[mad24(t_rows, step, t_cols)] - sum[mad24(t_rows, step, 0)] - sum[t_cols] + sum[0];\n"
"T value_sqsum = sqsum[mad24(t_rows, step, t_cols)] - sqsum[mad24(t_rows, step, 0)] - sqsum[t_cols] + sqsum[0];\n"
"#if cn==2\n"
"temp_sum.x = template_sum.x;\n"
"temp_sum.y = template_sum.y;\n"
"#else\n"
"temp_sum = template_sum;\n"
"#endif\n"
"float num = convertToDT(mad(value_sum, temp_sum, 0));\n"
"value_sqsum -= weight * value_sum * value_sum;\n"
"float denum = sqrt(mad(template_sqsum, convertToDT(value_sqsum), (float)0));\n"
"int dst_idx = mad24(y, dst_step, mad24(x, (int)sizeof(float), dst_offset));\n"
"__global float * dstult = (__global float *)(dst+dst_idx);\n"
"*dstult = normAcc((*dstult) - num, denum);\n"
"}\n"
"}\n"
"#else\n"
"#error \"cn should be 1-4\"\n"
"#endif\n"
"#endif\n"
, "b1f65f1ba4717552e461b432297031d6", NULL};
struct cv::ocl::internal::ProgramEntry medianFilter_oclsrc={moduleName, "medianFilter",
"#if cn != 3\n"
"#define loadpix(addr) *(__global const T *)(addr)\n"
"#define storepix(val, addr)  *(__global T *)(addr) = val\n"
"#define TSIZE (int)sizeof(T)\n"
"#else\n"
"#define loadpix(addr) vload3(0, (__global const T1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global T1 *)(addr))\n"
"#define TSIZE (int)sizeof(T1) * cn\n"
"#endif\n"
"#define OP(a,b) {    mid=a; a=min(a,b); b=max(mid,b);}\n"
"#ifdef USE_4OPT\n"
"#if cn == 1\n"
"#define LOAD4(val, offs) (val) = vload4(0, (__global T1 *)(srcptr + src_index + (offs)))\n"
"#define STORE4(val, offs) vstore4((val), 0, (__global T1 *)(dstptr + (offs)))\n"
"#define SHUFFLE4_3(src0, src1, src2, dst0, dst1, dst2) { dst1 = src1; \\\n"
"dst0 = (T4)(src0, dst1.xyz); \\\n"
"dst2 = (T4)(dst1.yzw, src2); }\n"
"#define SHUFFLE4_5(src0, src1, src2, src3, src4, dst0, dst1, dst2, dst3, dst4) { dst2 = src2; \\\n"
"dst0 = (T4)(src0, src1, dst2.xy); \\\n"
"dst1 = (T4)(src1, dst2.xyz); \\\n"
"dst3 = (T4)(dst2.yzw, src3); \\\n"
"dst4 = (T4)(dst2.zw, src3, src4); }\n"
"#elif cn == 2\n"
"#define LOAD4(val, offs) (val) = vload8(0, (__global T1 *)(srcptr + src_index + (offs)))\n"
"#define STORE4(val, offs) vstore8((val), 0, (__global T1 *)(dstptr + (offs)))\n"
"#define SHUFFLE4_3(src0, src1, src2, dst0, dst1, dst2) { dst1 = src1; \\\n"
"dst0 = (T4)(src0, dst1.s012345); \\\n"
"dst2 = (T4)(dst1.s234567, src2); }\n"
"#define SHUFFLE4_5(src0, src1, src2, src3, src4, dst0, dst1, dst2, dst3, dst4) { dst2 = src2; \\\n"
"dst0 = (T4)(src0, src1, dst2.s0123); \\\n"
"dst1 = (T4)(src1, dst2.s012345); \\\n"
"dst3 = (T4)(dst2.s234567, src3); \\\n"
"dst4 = (T4)(dst2.s4567, src3, src4); }\n"
"#elif cn == 4\n"
"#define LOAD4(val, offs) (val) = vload16(0, (__global T1 *)(srcptr + src_index + (offs)))\n"
"#define STORE4(val, offs) vstore16((val), 0, (__global T1 *)(dstptr + (offs)))\n"
"#define SHUFFLE4_3(src0, src1, src2, dst0, dst1, dst2) { dst1 = src1; \\\n"
"dst0 = (T4)(src0, dst1.s0123456789ab ); \\\n"
"dst2 = (T4)(dst1.s456789abcdef, src2); }\n"
"#define SHUFFLE4_5(src0, src1, src2, src3, src4, dst0, dst1, dst2, dst3, dst4) { dst2 = src2; \\\n"
"dst0 = (T4)(src0, src1, dst2.s01234567); \\\n"
"dst1 = (T4)(src1, dst2.s0123456789ab); \\\n"
"dst3 = (T4)(dst2.s456789abcdef, src3); \\\n"
"dst4 = (T4)(dst2.s89abcdef, src3, src4); }\n"
"#endif\n"
"__kernel void medianFilter3_u(__global const uchar* srcptr, int srcStep, int srcOffset,\n"
"__global uchar*       dstptr, int dstStep, int dstOffset,\n"
"int rows, int cols)\n"
"{\n"
"int gx= get_global_id(0) << 2;\n"
"int gy= get_global_id(1) << 2;\n"
"if( gy >= rows || gx >= cols)\n"
"return;\n"
"T c0; T4 c1; T c2;\n"
"T c3; T4 c4; T c5;\n"
"T c6; T4 c7; T c8;\n"
"int x_left     = mad24(max(gx-1, 0), TSIZE, srcOffset);\n"
"int x_central  = mad24(gx, TSIZE, srcOffset);\n"
"int x_right    = mad24(min(gx+4, cols-1), TSIZE, srcOffset);\n"
"int xdst = mad24(gx, TSIZE, dstOffset);\n"
"int src_index = max(gy-1, 0)*srcStep;\n"
"c0 = *(__global T *)(srcptr + src_index + x_left);\n"
"LOAD4(c1, x_central);\n"
"c2 = *(__global T *)(srcptr + src_index + x_right);\n"
"src_index = gy*srcStep;\n"
"c3 = *(__global T *)(srcptr + src_index + x_left);\n"
"LOAD4(c4, x_central);\n"
"c5 = *(__global T *)(srcptr + src_index + x_right);\n"
"#define ITER3(k) { \\\n"
"src_index = min(gy+k+1, rows-1)*srcStep; \\\n"
"c6 = *(__global T *)(srcptr + src_index + x_left); \\\n"
"LOAD4(c7, x_central); \\\n"
"c8 = *(__global T *)(srcptr + src_index + x_right); \\\n"
"T4 p0, p1, p2, p3, p4, p5, p6, p7, p8; \\\n"
"SHUFFLE4_3(c0, c1, c2, p0, p1, p2); \\\n"
"SHUFFLE4_3(c3, c4, c5, p3, p4, p5); \\\n"
"SHUFFLE4_3(c6, c7, c8, p6, p7, p8); \\\n"
"T4 mid; \\\n"
"OP(p1, p2); OP(p4, p5); OP(p7, p8); OP(p0, p1); \\\n"
"OP(p3, p4); OP(p6, p7); OP(p1, p2); OP(p4, p5); \\\n"
"OP(p7, p8); OP(p0, p3); OP(p5, p8); OP(p4, p7); \\\n"
"OP(p3, p6); OP(p1, p4); OP(p2, p5); OP(p4, p7); \\\n"
"OP(p4, p2); OP(p6, p4); OP(p4, p2); \\\n"
"int dst_index = mad24( gy+k, dstStep, xdst); \\\n"
"STORE4(p4, dst_index); \\\n"
"c0 = c3; c1 = c4; c2 = c5; \\\n"
"c3 = c6; c4 = c7; c5 = c8; \\\n"
"}\n"
"ITER3(0);\n"
"ITER3(1);\n"
"ITER3(2);\n"
"ITER3(3);\n"
"}\n"
"__kernel void medianFilter5_u(__global const uchar* srcptr, int srcStep, int srcOffset,\n"
"__global uchar*       dstptr, int dstStep, int dstOffset,\n"
"int rows, int cols)\n"
"{\n"
"int gx= get_global_id(0) << 2;\n"
"int gy= get_global_id(1) << 2;\n"
"if( gy >= rows || gx >= cols)\n"
"return;\n"
"T  c0; T  c1; T4  c2; T  c3; T  c4;\n"
"T  c5; T  c6; T4  c7; T  c8; T  c9;\n"
"T c10; T c11; T4 c12; T c13; T c14;\n"
"T c15; T c16; T4 c17; T c18; T c19;\n"
"T c20; T c21; T4 c22; T c23; T c24;\n"
"int x_leftmost = mad24(max(gx-2, 0), TSIZE, srcOffset);\n"
"int x_left     = mad24(max(gx-1, 0), TSIZE, srcOffset);\n"
"int x_central  = mad24(gx, TSIZE, srcOffset);\n"
"int x_right    = mad24(min(gx+4, cols-1), TSIZE, srcOffset);\n"
"int x_rightmost= mad24(min(gx+5, cols-1), TSIZE, srcOffset);\n"
"int xdst = mad24(gx, TSIZE, dstOffset);\n"
"int src_index = max(gy-2, 0)*srcStep;\n"
"c0 = *(__global T *)(srcptr + src_index + x_leftmost);\n"
"c1 = *(__global T *)(srcptr + src_index + x_left);\n"
"LOAD4(c2, x_central);\n"
"c3 = *(__global T *)(srcptr + src_index + x_right);\n"
"c4 = *(__global T *)(srcptr + src_index + x_rightmost);\n"
"src_index = max(gy-1, 0)*srcStep;\n"
"c5 = *(__global T *)(srcptr + src_index + x_leftmost);\n"
"c6 = *(__global T *)(srcptr + src_index + x_left);\n"
"LOAD4(c7, x_central);\n"
"c8 = *(__global T *)(srcptr + src_index + x_right);\n"
"c9 = *(__global T *)(srcptr + src_index + x_rightmost);\n"
"src_index = gy*srcStep;\n"
"c10 = *(__global T *)(srcptr + src_index + x_leftmost);\n"
"c11 = *(__global T *)(srcptr + src_index + x_left);\n"
"LOAD4(c12, x_central);\n"
"c13 = *(__global T *)(srcptr + src_index + x_right);\n"
"c14 = *(__global T *)(srcptr + src_index + x_rightmost);\n"
"src_index = (gy+1)*srcStep;\n"
"c15 = *(__global T *)(srcptr + src_index + x_leftmost);\n"
"c16 = *(__global T *)(srcptr + src_index + x_left);\n"
"LOAD4(c17, x_central);\n"
"c18 = *(__global T *)(srcptr + src_index + x_right);\n"
"c19 = *(__global T *)(srcptr + src_index + x_rightmost);\n"
"for(int k = 0; k < 4; k++)\n"
"{\n"
"src_index = min(gy+k+2, rows-1) * srcStep;\n"
"c20 = *(__global T *)(srcptr + src_index + x_leftmost);\n"
"c21 = *(__global T *)(srcptr + src_index + x_left);\n"
"LOAD4(c22, x_central);\n"
"c23 = *(__global T *)(srcptr + src_index + x_right);\n"
"c24 = *(__global T *)(srcptr + src_index + x_rightmost);\n"
"T4 p0,  p1,  p2,  p3,  p4,\n"
"p5,  p6,  p7,  p8,  p9,\n"
"p10, p11, p12, p13, p14,\n"
"p15, p16, p17, p18, p19,\n"
"p20, p21, p22, p23, p24;\n"
"SHUFFLE4_5(c0, c1, c2, c3, c4, p0, p1, p2, p3, p4);\n"
"SHUFFLE4_5(c5, c6, c7, c8, c9, p5, p6, p7, p8, p9);\n"
"SHUFFLE4_5(c10, c11, c12, c13, c14, p10, p11, p12, p13, p14);\n"
"SHUFFLE4_5(c15, c16, c17, c18, c19, p15, p16, p17, p18, p19);\n"
"SHUFFLE4_5(c20, c21, c22, c23, c24, p20, p21, p22, p23, p24);\n"
"T4 mid;\n"
"OP(p1, p2); OP(p0, p1); OP(p1, p2); OP(p4, p5); OP(p3, p4);\n"
"OP(p4, p5); OP(p0, p3); OP(p2, p5); OP(p2, p3); OP(p1, p4);\n"
"OP(p1, p2); OP(p3, p4); OP(p7, p8); OP(p6, p7); OP(p7, p8);\n"
"OP(p10, p11); OP(p9, p10); OP(p10, p11); OP(p6, p9); OP(p8, p11);\n"
"OP(p8, p9); OP(p7, p10); OP(p7, p8); OP(p9, p10); OP(p0, p6);\n"
"OP(p4, p10); OP(p4, p6); OP(p2, p8); OP(p2, p4); OP(p6, p8);\n"
"OP(p1, p7); OP(p5, p11); OP(p5, p7); OP(p3, p9); OP(p3, p5);\n"
"OP(p7, p9); OP(p1, p2); OP(p3, p4); OP(p5, p6); OP(p7, p8);\n"
"OP(p9, p10); OP(p13, p14); OP(p12, p13); OP(p13, p14); OP(p16, p17);\n"
"OP(p15, p16); OP(p16, p17); OP(p12, p15); OP(p14, p17); OP(p14, p15);\n"
"OP(p13, p16); OP(p13, p14); OP(p15, p16); OP(p19, p20); OP(p18, p19);\n"
"OP(p19, p20); OP(p21, p22); OP(p23, p24); OP(p21, p23); OP(p22, p24);\n"
"OP(p22, p23); OP(p18, p21); OP(p20, p23); OP(p20, p21); OP(p19, p22);\n"
"OP(p22, p24); OP(p19, p20); OP(p21, p22); OP(p23, p24); OP(p12, p18);\n"
"OP(p16, p22); OP(p16, p18); OP(p14, p20); OP(p20, p24); OP(p14, p16);\n"
"OP(p18, p20); OP(p22, p24); OP(p13, p19); OP(p17, p23); OP(p17, p19);\n"
"OP(p15, p21); OP(p15, p17); OP(p19, p21); OP(p13, p14); OP(p15, p16);\n"
"OP(p17, p18); OP(p19, p20); OP(p21, p22); OP(p23, p24); OP(p0, p12);\n"
"OP(p8, p20);  OP(p8, p12); OP(p4, p16); OP(p16, p24); OP(p12, p16);\n"
"OP(p2, p14);  OP(p10, p22); OP(p10, p14); OP(p6, p18); OP(p6, p10);\n"
"OP(p10, p12); OP(p1, p13); OP(p9, p21); OP(p9, p13); OP(p5, p17);\n"
"OP(p13, p17); OP(p3, p15); OP(p11, p23); OP(p11, p15); OP(p7, p19);\n"
"OP(p7, p11);  OP(p11, p13); OP(p11, p12);\n"
"int dst_index = mad24( gy+k, dstStep, xdst);\n"
"STORE4(p12, dst_index);\n"
"c0=c5;   c1=c6;   c2=c7;   c3=c8;   c4=c9;\n"
"c5=c10;  c6=c11;  c7=c12;  c8=c13;  c9=c14;\n"
"c10=c15; c11=c16; c12=c17; c13=c18; c14=c19;\n"
"c15=c20; c16=c21; c17=c22; c18=c23; c19=c24;\n"
"}\n"
"}\n"
"#endif\n"
"__kernel void medianFilter3(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"__local T data[18][18];\n"
"int x = get_local_id(0);\n"
"int y = get_local_id(1);\n"
"int gx = get_global_id(0);\n"
"int gy = get_global_id(1);\n"
"int dx = gx - x - 1;\n"
"int dy = gy - y - 1;\n"
"int id = min(mad24(x, 16, y), 9*18-1);\n"
"int dr = id / 18;\n"
"int dc = id % 18;\n"
"int c = clamp(dx + dc, 0, dst_cols - 1);\n"
"int r = clamp(dy + dr, 0, dst_rows - 1);\n"
"int index1 = mad24(r, src_step, mad24(c, TSIZE, src_offset));\n"
"r = clamp(dy + dr + 9, 0, dst_rows - 1);\n"
"int index9 = mad24(r, src_step, mad24(c, TSIZE, src_offset));\n"
"data[dr][dc] = loadpix(srcptr + index1);\n"
"data[dr+9][dc] = loadpix(srcptr + index9);\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"T p0 = data[y][x], p1 = data[y][(x+1)], p2 = data[y][(x+2)];\n"
"T p3 = data[y+1][x], p4 = data[y+1][(x+1)], p5 = data[y+1][(x+2)];\n"
"T p6 = data[y+2][x], p7 = data[y+2][(x+1)], p8 = data[y+2][(x+2)];\n"
"T mid;\n"
"OP(p1, p2); OP(p4, p5); OP(p7, p8); OP(p0, p1);\n"
"OP(p3, p4); OP(p6, p7); OP(p1, p2); OP(p4, p5);\n"
"OP(p7, p8); OP(p0, p3); OP(p5, p8); OP(p4, p7);\n"
"OP(p3, p6); OP(p1, p4); OP(p2, p5); OP(p4, p7);\n"
"OP(p4, p2); OP(p6, p4); OP(p4, p2);\n"
"int dst_index = mad24( gy, dst_step, mad24(gx, TSIZE, dst_offset));\n"
"if (gy < dst_rows && gx < dst_cols)\n"
"storepix(p4, dstptr + dst_index);\n"
"}\n"
"__kernel void medianFilter5(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"__local T data[20][20];\n"
"int x = get_local_id(0);\n"
"int y = get_local_id(1);\n"
"int gx = get_global_id(0);\n"
"int gy = get_global_id(1);\n"
"int dx = gx - x - 2;\n"
"int dy = gy - y - 2;\n"
"int id = min(mad24(x, 16, y), 10*20-1);\n"
"int dr = id / 20;\n"
"int dc = id % 20;\n"
"int c = clamp(dx + dc, 0, dst_cols - 1);\n"
"int r = clamp(dy + dr, 0, dst_rows - 1);\n"
"int index1 = mad24(r, src_step, mad24(c, TSIZE, src_offset));\n"
"r = clamp(dy + dr + 10, 0, dst_rows - 1);\n"
"int index10 = mad24(r, src_step, mad24(c, TSIZE, src_offset));\n"
"data[dr][dc] = loadpix(srcptr + index1);\n"
"data[dr+10][dc] = loadpix(srcptr + index10);\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"T p0 = data[y][x], p1 = data[y][x+1], p2 = data[y][x+2], p3 = data[y][x+3], p4 = data[y][x+4];\n"
"T p5 = data[y+1][x], p6 = data[y+1][x+1], p7 = data[y+1][x+2], p8 = data[y+1][x+3], p9 = data[y+1][x+4];\n"
"T p10 = data[y+2][x], p11 = data[y+2][x+1], p12 = data[y+2][x+2], p13 = data[y+2][x+3], p14 = data[y+2][x+4];\n"
"T p15 = data[y+3][x], p16 = data[y+3][x+1], p17 = data[y+3][x+2], p18 = data[y+3][x+3], p19 = data[y+3][x+4];\n"
"T p20 = data[y+4][x], p21 = data[y+4][x+1], p22 = data[y+4][x+2], p23 = data[y+4][x+3], p24 = data[y+4][x+4];\n"
"T mid;\n"
"OP(p1, p2); OP(p0, p1); OP(p1, p2); OP(p4, p5); OP(p3, p4);\n"
"OP(p4, p5); OP(p0, p3); OP(p2, p5); OP(p2, p3); OP(p1, p4);\n"
"OP(p1, p2); OP(p3, p4); OP(p7, p8); OP(p6, p7); OP(p7, p8);\n"
"OP(p10, p11); OP(p9, p10); OP(p10, p11); OP(p6, p9); OP(p8, p11);\n"
"OP(p8, p9); OP(p7, p10); OP(p7, p8); OP(p9, p10); OP(p0, p6);\n"
"OP(p4, p10); OP(p4, p6); OP(p2, p8); OP(p2, p4); OP(p6, p8);\n"
"OP(p1, p7); OP(p5, p11); OP(p5, p7); OP(p3, p9); OP(p3, p5);\n"
"OP(p7, p9); OP(p1, p2); OP(p3, p4); OP(p5, p6); OP(p7, p8);\n"
"OP(p9, p10); OP(p13, p14); OP(p12, p13); OP(p13, p14); OP(p16, p17);\n"
"OP(p15, p16); OP(p16, p17); OP(p12, p15); OP(p14, p17); OP(p14, p15);\n"
"OP(p13, p16); OP(p13, p14); OP(p15, p16); OP(p19, p20); OP(p18, p19);\n"
"OP(p19, p20); OP(p21, p22); OP(p23, p24); OP(p21, p23); OP(p22, p24);\n"
"OP(p22, p23); OP(p18, p21); OP(p20, p23); OP(p20, p21); OP(p19, p22);\n"
"OP(p22, p24); OP(p19, p20); OP(p21, p22); OP(p23, p24); OP(p12, p18);\n"
"OP(p16, p22); OP(p16, p18); OP(p14, p20); OP(p20, p24); OP(p14, p16);\n"
"OP(p18, p20); OP(p22, p24); OP(p13, p19); OP(p17, p23); OP(p17, p19);\n"
"OP(p15, p21); OP(p15, p17); OP(p19, p21); OP(p13, p14); OP(p15, p16);\n"
"OP(p17, p18); OP(p19, p20); OP(p21, p22); OP(p23, p24); OP(p0, p12);\n"
"OP(p8, p20); OP(p8, p12); OP(p4, p16); OP(p16, p24); OP(p12, p16);\n"
"OP(p2, p14); OP(p10, p22); OP(p10, p14); OP(p6, p18); OP(p6, p10);\n"
"OP(p10, p12); OP(p1, p13); OP(p9, p21); OP(p9, p13); OP(p5, p17);\n"
"OP(p13, p17); OP(p3, p15); OP(p11, p23); OP(p11, p15); OP(p7, p19);\n"
"OP(p7, p11); OP(p11, p13); OP(p11, p12);\n"
"int dst_index = mad24(gy, dst_step, mad24(gx, TSIZE, dst_offset));\n"
"if (gy < dst_rows && gx < dst_cols)\n"
"storepix(p12, dstptr + dst_index);\n"
"}\n"
, "f082457348bfbcb2e2de3014f46093a8", NULL};
struct cv::ocl::internal::ProgramEntry moments_oclsrc={moduleName, "moments",
"#if TILE_SIZE != 32\n"
"#error \"TILE SIZE should be 32\"\n"
"#endif\n"
"__kernel void moments(__global const uchar* src, int src_step, int src_offset,\n"
"int src_rows, int src_cols, __global int* mom0, int xtiles)\n"
"{\n"
"int x0 = get_global_id(0);\n"
"int y0 = get_group_id(1);\n"
"int x, y = get_local_id(1);\n"
"int x_min = x0*TILE_SIZE;\n"
"int ypix = y0*TILE_SIZE + y;\n"
"__local int mom[TILE_SIZE][10];\n"
"if (x_min < src_cols && y0*TILE_SIZE < src_rows)\n"
"{\n"
"if (ypix < src_rows)\n"
"{\n"
"int x_max = min(src_cols - x_min, TILE_SIZE);\n"
"__global const uchar* ptr = src + src_offset + ypix*src_step + x_min;\n"
"int4 S = (int4)(0, 0, 0, 0), p;\n"
"#define SUM_ELEM(elem, ofs) \\\n"
"(int4)(1, (ofs), (ofs)*(ofs), (ofs)*(ofs)*(ofs))*elem\n"
"x = x_max & -4;\n"
"if (x_max >= 4)\n"
"{\n"
"p = convert_int4(vload4(0, ptr));\n"
"#ifdef OP_MOMENTS_BINARY\n"
"p = min(p, 1);\n"
"#endif\n"
"S += (int4)(p.s0, 0, 0, 0) + (int4)(p.s1, p.s1, p.s1, p.s1) +\n"
"(int4)(p.s2, p.s2 * 2, p.s2 * 4, p.s2 * 8) + (int4)(p.s3, p.s3 * 3, p.s3 * 9, p.s3 * 27);\n"
"if (x_max >= 8)\n"
"{\n"
"p = convert_int4(vload4(0, ptr + 4));\n"
"#ifdef OP_MOMENTS_BINARY\n"
"p = min(p, 1);\n"
"#endif\n"
"S += (int4)(p.s0, p.s0 * 4, p.s0 * 16, p.s0 * 64) + (int4)(p.s1, p.s1 * 5, p.s1 * 25, p.s1 * 125) +\n"
"(int4)(p.s2, p.s2 * 6, p.s2 * 36, p.s2 * 216) + (int4)(p.s3, p.s3 * 7, p.s3 * 49, p.s3 * 343);\n"
"if (x_max >= 12)\n"
"{\n"
"p = convert_int4(vload4(0, ptr + 8));\n"
"#ifdef OP_MOMENTS_BINARY\n"
"p = min(p, 1);\n"
"#endif\n"
"S += (int4)(p.s0, p.s0 * 8, p.s0 * 64, p.s0 * 512) + (int4)(p.s1, p.s1 * 9, p.s1 * 81, p.s1 * 729) +\n"
"(int4)(p.s2, p.s2 * 10, p.s2 * 100, p.s2 * 1000) + (int4)(p.s3, p.s3 * 11, p.s3 * 121, p.s3 * 1331);\n"
"if (x_max >= 16)\n"
"{\n"
"p = convert_int4(vload4(0, ptr + 12));\n"
"#ifdef OP_MOMENTS_BINARY\n"
"p = min(p, 1);\n"
"#endif\n"
"S += (int4)(p.s0, p.s0 * 12, p.s0 * 144, p.s0 * 1728) + (int4)(p.s1, p.s1 * 13, p.s1 * 169, p.s1 * 2197) +\n"
"(int4)(p.s2, p.s2 * 14, p.s2 * 196, p.s2 * 2744) + (int4)(p.s3, p.s3 * 15, p.s3 * 225, p.s3 * 3375);\n"
"}\n"
"}\n"
"}\n"
"}\n"
"if (x_max >= 20)\n"
"{\n"
"p = convert_int4(vload4(0, ptr + 16));\n"
"#ifdef OP_MOMENTS_BINARY\n"
"p = min(p, 1);\n"
"#endif\n"
"S += (int4)(p.s0, p.s0 * 16, p.s0 * 256, p.s0 * 4096) + (int4)(p.s1, p.s1 * 17, p.s1 * 289, p.s1 * 4913) +\n"
"(int4)(p.s2, p.s2 * 18, p.s2 * 324, p.s2 * 5832) + (int4)(p.s3, p.s3 * 19, p.s3 * 361, p.s3 * 6859);\n"
"if (x_max >= 24)\n"
"{\n"
"p = convert_int4(vload4(0, ptr + 20));\n"
"#ifdef OP_MOMENTS_BINARY\n"
"p = min(p, 1);\n"
"#endif\n"
"S += (int4)(p.s0, p.s0 * 20, p.s0 * 400, p.s0 * 8000) + (int4)(p.s1, p.s1 * 21, p.s1 * 441, p.s1 * 9261) +\n"
"(int4)(p.s2, p.s2 * 22, p.s2 * 484, p.s2 * 10648) + (int4)(p.s3, p.s3 * 23, p.s3 * 529, p.s3 * 12167);\n"
"if (x_max >= 28)\n"
"{\n"
"p = convert_int4(vload4(0, ptr + 24));\n"
"#ifdef OP_MOMENTS_BINARY\n"
"p = min(p, 1);\n"
"#endif\n"
"S += (int4)(p.s0, p.s0 * 24, p.s0 * 576, p.s0 * 13824) + (int4)(p.s1, p.s1 * 25, p.s1 * 625, p.s1 * 15625) +\n"
"(int4)(p.s2, p.s2 * 26, p.s2 * 676, p.s2 * 17576) + (int4)(p.s3, p.s3 * 27, p.s3 * 729, p.s3 * 19683);\n"
"if (x_max >= 32)\n"
"{\n"
"p = convert_int4(vload4(0, ptr + 28));\n"
"#ifdef OP_MOMENTS_BINARY\n"
"p = min(p, 1);\n"
"#endif\n"
"S += (int4)(p.s0, p.s0 * 28, p.s0 * 784, p.s0 * 21952) + (int4)(p.s1, p.s1 * 29, p.s1 * 841, p.s1 * 24389) +\n"
"(int4)(p.s2, p.s2 * 30, p.s2 * 900, p.s2 * 27000) + (int4)(p.s3, p.s3 * 31, p.s3 * 961, p.s3 * 29791);\n"
"}\n"
"}\n"
"}\n"
"}\n"
"if (x < x_max)\n"
"{\n"
"int ps = ptr[x];\n"
"#ifdef OP_MOMENTS_BINARY\n"
"ps = min(ps, 1);\n"
"#endif\n"
"S += SUM_ELEM(ps, x);\n"
"if (x + 1 < x_max)\n"
"{\n"
"ps = ptr[x + 1];\n"
"#ifdef OP_MOMENTS_BINARY\n"
"ps = min(ps, 1);\n"
"#endif\n"
"S += SUM_ELEM(ps, x + 1);\n"
"if (x + 2 < x_max)\n"
"{\n"
"ps = ptr[x + 2];\n"
"#ifdef OP_MOMENTS_BINARY\n"
"ps = min(ps, 1);\n"
"#endif\n"
"S += SUM_ELEM(ps, x + 2);\n"
"}\n"
"}\n"
"}\n"
"int sy = y*y;\n"
"mom[y][0] = S.s0;\n"
"mom[y][1] = S.s1;\n"
"mom[y][2] = y*S.s0;\n"
"mom[y][3] = S.s2;\n"
"mom[y][4] = y*S.s1;\n"
"mom[y][5] = sy*S.s0;\n"
"mom[y][6] = S.s3;\n"
"mom[y][7] = y*S.s2;\n"
"mom[y][8] = sy*S.s1;\n"
"mom[y][9] = y*sy*S.s0;\n"
"}\n"
"else\n"
"mom[y][0] = mom[y][1] = mom[y][2] = mom[y][3] = mom[y][4] =\n"
"mom[y][5] = mom[y][6] = mom[y][7] = mom[y][8] = mom[y][9] = 0;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"#define REDUCE(d) \\\n"
"if (y < d) \\\n"
"{ \\\n"
"mom[y][0] += mom[y + d][0]; \\\n"
"mom[y][1] += mom[y + d][1]; \\\n"
"mom[y][2] += mom[y + d][2]; \\\n"
"mom[y][3] += mom[y + d][3]; \\\n"
"mom[y][4] += mom[y + d][4]; \\\n"
"mom[y][5] += mom[y + d][5]; \\\n"
"mom[y][6] += mom[y + d][6]; \\\n"
"mom[y][7] += mom[y + d][7]; \\\n"
"mom[y][8] += mom[y + d][8]; \\\n"
"mom[y][9] += mom[y + d][9]; \\\n"
"} \\\n"
"barrier(CLK_LOCAL_MEM_FENCE)\n"
"REDUCE(16);\n"
"REDUCE(8);\n"
"REDUCE(4);\n"
"REDUCE(2);\n"
"if (y < 10)\n"
"{\n"
"__global int* momout = mom0 + (y0*xtiles + x0) * 10;\n"
"momout[y] = mom[0][y] + mom[1][y];\n"
"}\n"
"}\n"
"}\n"
, "1d0545282b5860ed7eeeb6860fa9edc3", NULL};
struct cv::ocl::internal::ProgramEntry morph_oclsrc={moduleName, "morph",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#define noconvert\n"
"#if cn != 3\n"
"#define loadpix(addr) *(__global const T *)(addr)\n"
"#define storepix(val, addr)  *(__global T *)(addr) = val\n"
"#define TSIZE (int)sizeof(T)\n"
"#else\n"
"#define loadpix(addr) vload3(0, (__global const T1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global T1 *)(addr))\n"
"#define TSIZE ((int)sizeof(T1)*3)\n"
"#endif\n"
"#ifdef DEPTH_0\n"
"#define MIN_VAL 0\n"
"#define MAX_VAL UCHAR_MAX\n"
"#elif defined DEPTH_1\n"
"#define MIN_VAL SCHAR_MIN\n"
"#define MAX_VAL SCHAR_MAX\n"
"#elif defined DEPTH_2\n"
"#define MIN_VAL 0\n"
"#define MAX_VAL USHRT_MAX\n"
"#elif defined DEPTH_3\n"
"#define MIN_VAL SHRT_MIN\n"
"#define MAX_VAL SHRT_MAX\n"
"#elif defined DEPTH_4\n"
"#define MIN_VAL INT_MIN\n"
"#define MAX_VAL INT_MAX\n"
"#elif defined DEPTH_5\n"
"#define MIN_VAL (-FLT_MAX)\n"
"#define MAX_VAL FLT_MAX\n"
"#elif defined DEPTH_6\n"
"#define MIN_VAL (-DBL_MAX)\n"
"#define MAX_VAL DBL_MAX\n"
"#endif\n"
"#ifdef OP_ERODE\n"
"#define VAL MAX_VAL\n"
"#elif defined OP_DILATE\n"
"#define VAL MIN_VAL\n"
"#else\n"
"#error \"Unknown operation\"\n"
"#endif\n"
"#ifdef OP_ERODE\n"
"#if defined INTEL_DEVICE && defined DEPTH_0\n"
"#define MORPH_OP(A, B) ((A) < (B) ? (A) : (B))\n"
"#else\n"
"#define MORPH_OP(A, B) min((A), (B))\n"
"#endif\n"
"#endif\n"
"#ifdef OP_DILATE\n"
"#define MORPH_OP(A, B) max((A), (B))\n"
"#endif\n"
"#define PROCESS(y, x) \\\n"
"temp = LDS_DAT[mad24(l_y + y, width, l_x + x)]; \\\n"
"res = MORPH_OP(res, temp);\n"
"#define ELEM(i, l_edge, r_edge, elem1, elem2) (i) < (l_edge) | (i) >= (r_edge) ? (elem1) : (elem2)\n"
"#if defined OP_GRADIENT || defined OP_TOPHAT || defined OP_BLACKHAT\n"
"#define EXTRA_PARAMS , __global const uchar * matptr, int mat_step, int mat_offset\n"
"#else\n"
"#define EXTRA_PARAMS\n"
"#endif\n"
"__kernel void morph(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset,\n"
"int src_offset_x, int src_offset_y, int cols, int rows,\n"
"int src_whole_cols, int src_whole_rows EXTRA_PARAMS)\n"
"{\n"
"int gidx = get_global_id(0), gidy = get_global_id(1);\n"
"int l_x = get_local_id(0), l_y = get_local_id(1);\n"
"int x = get_group_id(0) * LSIZE0, y = get_group_id(1) * LSIZE1;\n"
"int start_x = x + src_offset_x - RADIUSX;\n"
"int width = mad24(RADIUSX, 2, LSIZE0 + 1);\n"
"int start_y = y + src_offset_y - RADIUSY;\n"
"int point1 = mad24(l_y, LSIZE0, l_x);\n"
"int point2 = point1 + LSIZE0 * LSIZE1;\n"
"int tl_x = point1 % width, tl_y = point1 / width;\n"
"int tl_x2 = point2 % width, tl_y2 = point2 / width;\n"
"int cur_x = start_x + tl_x, cur_y = start_y + tl_y;\n"
"int cur_x2 = start_x + tl_x2, cur_y2 = start_y + tl_y2;\n"
"int start_addr = mad24(cur_y, src_step, cur_x * TSIZE);\n"
"int start_addr2 = mad24(cur_y2, src_step, cur_x2 * TSIZE);\n"
"__local T LDS_DAT[2 * LSIZE1 * LSIZE0];\n"
"int end_addr = mad24(src_whole_rows - 1, src_step, src_whole_cols * TSIZE);\n"
"start_addr = start_addr < end_addr && start_addr > 0 ? start_addr : 0;\n"
"start_addr2 = start_addr2 < end_addr && start_addr2 > 0 ? start_addr2 : 0;\n"
"T temp0 = loadpix(srcptr + start_addr);\n"
"T temp1 = loadpix(srcptr + start_addr2);\n"
"temp0 = ELEM(cur_x, 0, src_whole_cols, (T)(VAL), temp0);\n"
"temp0 = ELEM(cur_y, 0, src_whole_rows, (T)(VAL), temp0);\n"
"temp1 = ELEM(cur_x2, 0, src_whole_cols, (T)(VAL), temp1);\n"
"temp1 = ELEM(cur_y2, 0, src_whole_rows, (T)(VAL), temp1);\n"
"LDS_DAT[point1] = temp0;\n"
"LDS_DAT[point2] = temp1;\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"if (gidx < cols && gidy < rows)\n"
"{\n"
"T res = (T)(VAL), temp;\n"
"PROCESS_ELEMS;\n"
"int dst_index = mad24(gidy, dst_step, mad24(gidx, TSIZE, dst_offset));\n"
"#if defined OP_GRADIENT || defined OP_TOPHAT || defined OP_BLACKHAT\n"
"int mat_index =  mad24(gidy, mat_step, mad24(gidx, TSIZE, mat_offset));\n"
"T value = loadpix(matptr + mat_index);\n"
"#ifdef OP_GRADIENT\n"
"storepix(convertToT(convertToWT(res) - convertToWT(value)), dstptr + dst_index);\n"
"#elif defined OP_TOPHAT\n"
"storepix(convertToT(convertToWT(value) - convertToWT(res)), dstptr + dst_index);\n"
"#elif defined OP_BLACKHAT\n"
"storepix(convertToT(convertToWT(res) - convertToWT(value)), dstptr + dst_index);\n"
"#endif\n"
"#else\n"
"storepix(res, dstptr + dst_index);\n"
"#endif\n"
"}\n"
"}\n"
, "232e712bff362e53c55027da6e1e1584", NULL};
struct cv::ocl::internal::ProgramEntry morph3x3_oclsrc={moduleName, "morph3x3",
"#ifdef OP_ERODE\n"
"#define OP(m1, m2) min(m1, m2)\n"
"#define VAL UCHAR_MAX\n"
"#endif\n"
"#ifdef OP_DILATE\n"
"#define OP(m1, m2) max(m1, m2)\n"
"#define VAL 0\n"
"#endif\n"
"#if defined OP_GRADIENT || defined OP_TOPHAT || defined OP_BLACKHAT\n"
"#define EXTRA_PARAMS , __global const uchar * matptr, int mat_step, int mat_offset\n"
"#else\n"
"#define EXTRA_PARAMS\n"
"#endif\n"
"#define PROCESS(_y, _x) \\\n"
"line_out[0] = OP(line_out[0], arr[_x + 3 * _y]); \\\n"
"line_out[1] = OP(line_out[1], arr[_x + 3 * (_y + 1)]);\n"
"#define PROCESS_ELEM \\\n"
"line_out[0] = (uchar16)VAL; \\\n"
"line_out[1] = (uchar16)VAL; \\\n"
"PROCESS_ELEM_\n"
"__kernel void morph3x3_8UC1_cols16_rows2(__global const uint* src, int src_step,\n"
"__global uint* dst, int dst_step,\n"
"int rows, int cols\n"
"EXTRA_PARAMS)\n"
"{\n"
"int block_x = get_global_id(0);\n"
"int y = get_global_id(1) * 2;\n"
"int ssx = 1, dsx = 1;\n"
"if ((block_x * 16) >= cols || y >= rows) return;\n"
"uchar a; uchar16 b; uchar c;\n"
"uchar d; uchar16 e; uchar f;\n"
"uchar g; uchar16 h; uchar i;\n"
"uchar j; uchar16 k; uchar l;\n"
"uchar16 line[4];\n"
"uchar16 line_out[2];\n"
"int src_index = block_x * 4 * ssx + (y - 1) * (src_step / 4);\n"
"line[0] = (y == 0) ? (uchar16)VAL: as_uchar16(vload4(0, src + src_index));\n"
"line[1] = as_uchar16(vload4(0, src + src_index + (src_step / 4)));\n"
"line[2] = as_uchar16(vload4(0, src + src_index + 2 * (src_step / 4)));\n"
"line[3] = (y == (rows - 2)) ? (uchar16)VAL: as_uchar16(vload4(0, src + src_index + 3 * (src_step / 4)));\n"
"__global uchar *src_p = (__global uchar *)src;\n"
"bool line_end = ((block_x + 1) * 16 == cols);\n"
"src_index = block_x * 16 * ssx + (y - 1) * src_step;\n"
"a = (block_x == 0 || y == 0) ? VAL : src_p[src_index - 1];\n"
"b = line[0];\n"
"c = (line_end || y == 0) ? VAL : src_p[src_index + 16];\n"
"d = (block_x == 0) ? VAL : src_p[src_index + src_step - 1];\n"
"e = line[1];\n"
"f = line_end ? VAL : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? VAL : src_p[src_index + 2 * src_step - 1];\n"
"h = line[2];\n"
"i = line_end ? VAL : src_p[src_index + 2 * src_step + 16];\n"
"j = (block_x == 0 || y == (rows - 2)) ? VAL : src_p[src_index + 3 * src_step - 1];\n"
"k = line[3];\n"
"l = (line_end || y == (rows - 2)) ? VAL : src_p[src_index + 3 * src_step + 16];\n"
"uchar16 arr[12];\n"
"arr[0] = (uchar16)(a, b.s01234567, b.s89ab, b.scde);\n"
"arr[1] = b;\n"
"arr[2] = (uchar16)(b.s12345678, b.s9abc, b.sdef, c);\n"
"arr[3] = (uchar16)(d, e.s01234567, e.s89ab, e.scde);\n"
"arr[4] = e;\n"
"arr[5] = (uchar16)(e.s12345678, e.s9abc, e.sdef, f);\n"
"arr[6] = (uchar16)(g, h.s01234567, h.s89ab, h.scde);\n"
"arr[7] = h;\n"
"arr[8] = (uchar16)(h.s12345678, h.s9abc, h.sdef, i);\n"
"arr[9] = (uchar16)(j, k.s01234567, k.s89ab, k.scde);\n"
"arr[10] = k;\n"
"arr[11] = (uchar16)(k.s12345678, k.s9abc, k.sdef, l);\n"
"PROCESS_ELEM;\n"
"int dst_index = block_x * 4 * dsx + y * (dst_step / 4);\n"
"#if defined OP_GRADIENT || defined OP_TOPHAT || defined OP_BLACKHAT\n"
"int mat_index = y * mat_step + block_x * 16 * ssx + mat_offset;\n"
"uchar16 val0 = vload16(0, matptr + mat_index);\n"
"uchar16 val1 = vload16(0, matptr + mat_index + mat_step);\n"
"#ifdef OP_GRADIENT\n"
"line_out[0] = convert_uchar16_sat(convert_int16(line_out[0]) - convert_int16(val0));\n"
"line_out[1] = convert_uchar16_sat(convert_int16(line_out[1]) - convert_int16(val1));\n"
"vstore4(as_uint4(line_out[0]), 0, dst + dst_index);\n"
"vstore4(as_uint4(line_out[1]), 0, dst + dst_index + (dst_step / 4));\n"
"#elif defined OP_TOPHAT\n"
"line_out[0] = convert_uchar16_sat(convert_int16(val0) - convert_int16(line_out[0]));\n"
"line_out[1] = convert_uchar16_sat(convert_int16(val1) - convert_int16(line_out[1]));\n"
"vstore4(as_uint4(line_out[0]), 0, dst + dst_index);\n"
"vstore4(as_uint4(line_out[1]), 0, dst + dst_index + (dst_step / 4));\n"
"#elif defined OP_BLACKHAT\n"
"line_out[0] = convert_uchar16_sat(convert_int16(line_out[0]) - convert_int16(val0));\n"
"line_out[1] = convert_uchar16_sat(convert_int16(line_out[1]) - convert_int16(val1));\n"
"vstore4(as_uint4(line_out[0]), 0, dst + dst_index);\n"
"vstore4(as_uint4(line_out[1]), 0, dst + dst_index + (dst_step / 4));\n"
"#endif\n"
"#else\n"
"vstore4(as_uint4(line_out[0]), 0, dst + dst_index);\n"
"vstore4(as_uint4(line_out[1]), 0, dst + dst_index + (dst_step / 4));\n"
"#endif\n"
"}\n"
, "69fd431a8819a531ceca227a115c0a07", NULL};
struct cv::ocl::internal::ProgramEntry precornerdetect_oclsrc={moduleName, "precornerdetect",
"__kernel void preCornerDetect(__global const uchar * Dxptr, int dx_step, int dx_offset,\n"
"__global const uchar * Dyptr, int dy_step, int dy_offset,\n"
"__global const uchar * D2xptr, int d2x_step, int d2x_offset,\n"
"__global const uchar * D2yptr, int d2y_step, int d2y_offset,\n"
"__global const uchar * Dxyptr, int dxy_step, int dxy_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset,\n"
"int dst_rows, int dst_cols, float factor)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1);\n"
"if (x < dst_cols && y < dst_rows)\n"
"{\n"
"int dx_index = mad24(dx_step, y, (int)sizeof(float) * x + dx_offset);\n"
"int dy_index = mad24(dy_step, y, (int)sizeof(float) * x + dy_offset);\n"
"int d2x_index = mad24(d2x_step, y, (int)sizeof(float) * x + d2x_offset);\n"
"int d2y_index = mad24(d2y_step, y, (int)sizeof(float) * x + d2y_offset);\n"
"int dxy_index = mad24(dxy_step, y, (int)sizeof(float) * x + dxy_offset);\n"
"int dst_index = mad24(dst_step, y, (int)sizeof(float) * x + dst_offset);\n"
"float dx = *(__global const float *)(Dxptr + dx_index);\n"
"float dy = *(__global const float *)(Dyptr + dy_index);\n"
"float d2x = *(__global const float *)(D2xptr + d2x_index);\n"
"float d2y = *(__global const float *)(D2yptr + d2y_index);\n"
"float dxy = *(__global const float *)(Dxyptr + dxy_index);\n"
"__global float * dst = (__global float *)(dstptr + dst_index);\n"
"dst[0] = factor * (dx*dx*d2y + dy*dy*d2x - 2*dx*dy*dxy);\n"
"}\n"
"}\n"
, "14a94db70b88aa76ff8840f03f3ad556", NULL};
struct cv::ocl::internal::ProgramEntry pyr_down_oclsrc={moduleName, "pyr_down",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#if defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(x, maxV) clamp((x), 0, (maxV)-1)\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(x, maxV) ( (x) + (maxV) ) % (maxV)\n"
"#elif defined BORDER_REFLECT\n"
"#define EXTRAPOLATE(x, maxV) clamp(min(((maxV)-1)*2-(x)+1, max((x),-(x)-1) ), 0, (maxV)-1)\n"
"#elif defined BORDER_REFLECT_101 || defined BORDER_REFLECT101\n"
"#define EXTRAPOLATE(x, maxV) clamp(min(((maxV)-1)*2-(x), max((x),-(x)) ), 0, (maxV)-1)\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#if cn != 3\n"
"#define loadpix(addr)  *(__global const T*)(addr)\n"
"#define storepix(val, addr)  *(__global T*)(addr) = (val)\n"
"#define PIXSIZE ((int)sizeof(T))\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const T1*)(addr))\n"
"#define storepix(val, addr) vstore3((val), 0, (__global T1*)(addr))\n"
"#define PIXSIZE ((int)sizeof(T1)*3)\n"
"#endif\n"
"#define SRC(_x,_y) convertToFT(loadpix(srcData + mad24(_y, src_step, PIXSIZE * _x)))\n"
"#if kercn == 4\n"
"#define SRC4(_x,_y) convert_float4(vload4(0, srcData + mad24(_y, src_step, PIXSIZE * _x)))\n"
"#endif\n"
"#ifdef INTEL_DEVICE\n"
"#define MAD(x,y,z) fma((x),(y),(z))\n"
"#else\n"
"#define MAD(x,y,z) mad((x),(y),(z))\n"
"#endif\n"
"#define LOAD_LOCAL(col_gl, col_lcl) \\\n"
"sum0 =     co3* SRC(col_gl, EXTRAPOLATE_(src_y - 2, src_rows));         \\\n"
"sum0 = MAD(co2, SRC(col_gl, EXTRAPOLATE_(src_y - 1, src_rows)), sum0);  \\\n"
"temp = SRC(col_gl, EXTRAPOLATE_(src_y, src_rows));                      \\\n"
"sum0 = MAD(co1, temp, sum0);                                            \\\n"
"sum1 = co3 * temp;                                                      \\\n"
"temp = SRC(col_gl, EXTRAPOLATE_(src_y + 1, src_rows));                  \\\n"
"sum0 = MAD(co2, temp, sum0);                                            \\\n"
"sum1 = MAD(co2, temp, sum1);                                            \\\n"
"temp = SRC(col_gl, EXTRAPOLATE_(src_y + 2, src_rows));                  \\\n"
"sum0 = MAD(co3, temp, sum0);                                            \\\n"
"sum1 = MAD(co1, temp, sum1);                                            \\\n"
"smem[0][col_lcl] = sum0;                                                \\\n"
"sum1 = MAD(co2, SRC(col_gl, EXTRAPOLATE_(src_y + 3, src_rows)), sum1);  \\\n"
"sum1 = MAD(co3, SRC(col_gl, EXTRAPOLATE_(src_y + 4, src_rows)), sum1);  \\\n"
"smem[1][col_lcl] = sum1;\n"
"#if kercn == 4\n"
"#define LOAD_LOCAL4(col_gl, col_lcl) \\\n"
"sum40 =     co3* SRC4(col_gl, EXTRAPOLATE_(src_y - 2, src_rows));           \\\n"
"sum40 = MAD(co2, SRC4(col_gl, EXTRAPOLATE_(src_y - 1, src_rows)), sum40);   \\\n"
"temp4 = SRC4(col_gl,  EXTRAPOLATE_(src_y, src_rows));                       \\\n"
"sum40 = MAD(co1, temp4, sum40);                                             \\\n"
"sum41 = co3 * temp4;                                                        \\\n"
"temp4 = SRC4(col_gl,  EXTRAPOLATE_(src_y + 1, src_rows));                   \\\n"
"sum40 = MAD(co2, temp4, sum40);                                             \\\n"
"sum41 = MAD(co2, temp4, sum41);                                             \\\n"
"temp4 = SRC4(col_gl,  EXTRAPOLATE_(src_y + 2, src_rows));                   \\\n"
"sum40 = MAD(co3, temp4, sum40);                                             \\\n"
"sum41 = MAD(co1, temp4, sum41);                                             \\\n"
"vstore4(sum40, col_lcl, (__local float*) &smem[0][2]);                      \\\n"
"sum41 = MAD(co2, SRC4(col_gl,  EXTRAPOLATE_(src_y + 3, src_rows)), sum41);  \\\n"
"sum41 = MAD(co3, SRC4(col_gl,  EXTRAPOLATE_(src_y + 4, src_rows)), sum41);  \\\n"
"vstore4(sum41, col_lcl, (__local float*) &smem[1][2]);\n"
"#endif\n"
"#define noconvert\n"
"__kernel void pyrDown(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"const int x = get_global_id(0)*kercn;\n"
"const int y = 2*get_global_id(1);\n"
"__local FT smem[2][LOCAL_SIZE + 4];\n"
"__global uchar * dstData = dst + dst_offset;\n"
"__global const uchar * srcData = src + src_offset;\n"
"FT sum0, sum1, temp;\n"
"FT co1 = 0.375f;\n"
"FT co2 = 0.25f;\n"
"FT co3 = 0.0625f;\n"
"const int src_y = 2*y;\n"
"int col;\n"
"if (src_y >= 2 && src_y < src_rows - 4)\n"
"{\n"
"#undef EXTRAPOLATE_\n"
"#define EXTRAPOLATE_(val, maxVal)   val\n"
"#if kercn == 1\n"
"col = EXTRAPOLATE(x, src_cols);\n"
"LOAD_LOCAL(col, 2 + get_local_id(0))\n"
"#else\n"
"if (x < src_cols-4)\n"
"{\n"
"float4 sum40, sum41, temp4;\n"
"LOAD_LOCAL4(x, get_local_id(0))\n"
"}\n"
"else\n"
"{\n"
"for (int i=0; i<4; i++)\n"
"{\n"
"col = EXTRAPOLATE(x+i, src_cols);\n"
"LOAD_LOCAL(col, 2 + 4 * get_local_id(0) + i)\n"
"}\n"
"}\n"
"#endif\n"
"if (get_local_id(0) < 2)\n"
"{\n"
"col = EXTRAPOLATE((int)(get_group_id(0)*LOCAL_SIZE + get_local_id(0) - 2), src_cols);\n"
"LOAD_LOCAL(col, get_local_id(0))\n"
"}\n"
"else if (get_local_id(0) < 4)\n"
"{\n"
"col = EXTRAPOLATE((int)((get_group_id(0)+1)*LOCAL_SIZE + get_local_id(0) - 2), src_cols);\n"
"LOAD_LOCAL(col, LOCAL_SIZE + get_local_id(0))\n"
"}\n"
"}\n"
"else\n"
"{\n"
"#undef EXTRAPOLATE_\n"
"#define EXTRAPOLATE_(val, maxVal)   EXTRAPOLATE(val, maxVal)\n"
"#if kercn == 1\n"
"col = EXTRAPOLATE(x, src_cols);\n"
"LOAD_LOCAL(col, 2 + get_local_id(0))\n"
"#else\n"
"if (x < src_cols-4)\n"
"{\n"
"float4 sum40, sum41, temp4;\n"
"LOAD_LOCAL4(x, get_local_id(0))\n"
"}\n"
"else\n"
"{\n"
"for (int i=0; i<4; i++)\n"
"{\n"
"col = EXTRAPOLATE(x+i, src_cols);\n"
"LOAD_LOCAL(col, 2 + 4*get_local_id(0) + i)\n"
"}\n"
"}\n"
"#endif\n"
"if (get_local_id(0) < 2)\n"
"{\n"
"col = EXTRAPOLATE((int)(get_group_id(0)*LOCAL_SIZE + get_local_id(0) - 2), src_cols);\n"
"LOAD_LOCAL(col, get_local_id(0))\n"
"}\n"
"else if (get_local_id(0) < 4)\n"
"{\n"
"col = EXTRAPOLATE((int)((get_group_id(0)+1)*LOCAL_SIZE + get_local_id(0) - 2), src_cols);\n"
"LOAD_LOCAL(col, LOCAL_SIZE + get_local_id(0))\n"
"}\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"#if kercn == 1\n"
"if (get_local_id(0) < LOCAL_SIZE / 2)\n"
"{\n"
"const int tid2 = get_local_id(0) * 2;\n"
"const int dst_x = (get_group_id(0) * get_local_size(0) + tid2) / 2;\n"
"if (dst_x < dst_cols)\n"
"{\n"
"for (int yin = y, y1 = min(dst_rows, y + 2); yin < y1; yin++)\n"
"{\n"
"#if cn == 1\n"
"#if fdepth <= 5\n"
"FT sum = dot(vload4(0, (__local float*) (&smem) + tid2 + (yin - y) * (LOCAL_SIZE + 4)), (float4)(co3, co2, co1, co2));\n"
"#else\n"
"FT sum = dot(vload4(0, (__local double*) (&smem) + tid2 + (yin - y) * (LOCAL_SIZE + 4)), (double4)(co3, co2, co1, co2));\n"
"#endif\n"
"#else\n"
"FT sum = co3 * smem[yin - y][2 + tid2 - 2];\n"
"sum = MAD(co2, smem[yin - y][2 + tid2 - 1], sum);\n"
"sum = MAD(co1, smem[yin - y][2 + tid2    ], sum);\n"
"sum = MAD(co2, smem[yin - y][2 + tid2 + 1], sum);\n"
"#endif\n"
"sum = MAD(co3, smem[yin - y][2 + tid2 + 2], sum);\n"
"storepix(convertToT(sum), dstData + yin * dst_step + dst_x * PIXSIZE);\n"
"}\n"
"}\n"
"}\n"
"#else\n"
"int tid4 = get_local_id(0) * 4;\n"
"int dst_x = (get_group_id(0) * LOCAL_SIZE + tid4) / 2;\n"
"if (dst_x < dst_cols - 1)\n"
"{\n"
"for (int yin = y, y1 = min(dst_rows, y + 2); yin < y1; yin++)\n"
"{\n"
"FT sum =  co3* smem[yin - y][2 + tid4 + 2];\n"
"sum = MAD(co3, smem[yin - y][2 + tid4 - 2], sum);\n"
"sum = MAD(co2, smem[yin - y][2 + tid4 - 1], sum);\n"
"sum = MAD(co1, smem[yin - y][2 + tid4    ], sum);\n"
"sum = MAD(co2, smem[yin - y][2 + tid4 + 1], sum);\n"
"storepix(convertToT(sum), dstData + mad24(yin, dst_step, dst_x * PIXSIZE));\n"
"dst_x ++;\n"
"sum =     co3* smem[yin - y][2 + tid4 + 4];\n"
"sum = MAD(co3, smem[yin - y][2 + tid4    ], sum);\n"
"sum = MAD(co2, smem[yin - y][2 + tid4 + 1], sum);\n"
"sum = MAD(co1, smem[yin - y][2 + tid4 + 2], sum);\n"
"sum = MAD(co2, smem[yin - y][2 + tid4 + 3], sum);\n"
"storepix(convertToT(sum), dstData + mad24(yin, dst_step, dst_x * PIXSIZE));\n"
"dst_x --;\n"
"}\n"
"}\n"
"else if (dst_x < dst_cols)\n"
"{\n"
"for (int yin = y, y1 = min(dst_rows, y + 2); yin < y1; yin++)\n"
"{\n"
"FT sum =  co3* smem[yin - y][2 + tid4 + 2];\n"
"sum = MAD(co3, smem[yin - y][2 + tid4 - 2], sum);\n"
"sum = MAD(co2, smem[yin - y][2 + tid4 - 1], sum);\n"
"sum = MAD(co1, smem[yin - y][2 + tid4    ], sum);\n"
"sum = MAD(co2, smem[yin - y][2 + tid4 + 1], sum);\n"
"storepix(convertToT(sum), dstData + mad24(yin, dst_step, dst_x * PIXSIZE));\n"
"}\n"
"}\n"
"#endif\n"
"}\n"
, "a5f2dccf982eb988b2ed0e11453d00b9", NULL};
struct cv::ocl::internal::ProgramEntry pyr_up_oclsrc={moduleName, "pyr_up",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#if cn != 3\n"
"#define loadpix(addr)  *(__global const T*)(addr)\n"
"#define storepix(val, addr)  *(__global T*)(addr) = (val)\n"
"#define PIXSIZE ((int)sizeof(T))\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const T1*)(addr))\n"
"#define storepix(val, addr) vstore3((val), 0, (__global T1*)(addr))\n"
"#define PIXSIZE ((int)sizeof(T1)*3)\n"
"#endif\n"
"#define EXTRAPOLATE(x, maxV) min(maxV - 1, (int) abs(x))\n"
"#define noconvert\n"
"__kernel void pyrUp(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"const int x = get_global_id(0);\n"
"const int y = get_global_id(1);\n"
"const int tidx = get_local_id(0);\n"
"const int tidy = get_local_id(1);\n"
"__local FT s_srcPatch[LOCAL_SIZE/2 + 2][LOCAL_SIZE/2 + 2];\n"
"__local FT s_dstPatch[LOCAL_SIZE/2 + 2][LOCAL_SIZE];\n"
"__global uchar * dstData = dst + dst_offset;\n"
"__global const uchar * srcData = src + src_offset;\n"
"if( tidx < (LOCAL_SIZE/2 + 2) && tidy < LOCAL_SIZE/2 + 2 )\n"
"{\n"
"int srcx = EXTRAPOLATE(mad24((int)get_group_id(0), LOCAL_SIZE/2, tidx) - 1, src_cols);\n"
"int srcy = EXTRAPOLATE(mad24((int)get_group_id(1), LOCAL_SIZE/2, tidy) - 1, src_rows);\n"
"s_srcPatch[tidy][tidx] = convertToFT(loadpix(srcData + srcy * src_step + srcx * PIXSIZE));\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"FT sum = 0.f;\n"
"const FT co1 = 0.75f;\n"
"const FT co2 = 0.5f;\n"
"const FT co3 = 0.125f;\n"
"const FT coef1 = (tidx & 1) == 0 ? co1 : (FT) 0;\n"
"const FT coef2 = (tidx & 1) == 0 ? co3 : co2;\n"
"const FT coefy1 = (tidy & 1) == 0 ? co1 : (FT) 0;\n"
"const FT coefy2 = (tidy & 1) == 0 ? co3 : co2;\n"
"if(tidy < LOCAL_SIZE/2 + 2)\n"
"{\n"
"sum =     coef2* s_srcPatch[tidy][1 + ((tidx - 1) >> 1)];\n"
"sum = mad(coef1, s_srcPatch[tidy][1 + ((tidx    ) >> 1)], sum);\n"
"sum = mad(coef2, s_srcPatch[tidy][1 + ((tidx + 2) >> 1)], sum);\n"
"s_dstPatch[tidy][tidx] = sum;\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"sum =     coefy2* s_dstPatch[1 + ((tidy - 1) >> 1)][tidx];\n"
"sum = mad(coefy1, s_dstPatch[1 + ((tidy    ) >> 1)][tidx], sum);\n"
"sum = mad(coefy2, s_dstPatch[1 + ((tidy + 2) >> 1)][tidx], sum);\n"
"if ((x < dst_cols) && (y < dst_rows))\n"
"storepix(convertToT(sum), dstData + y * dst_step + x * PIXSIZE);\n"
"}\n"
"__kernel void pyrUp_unrolled(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"const int lx = 2*get_local_id(0);\n"
"const int ly = 2*get_local_id(1);\n"
"__local FT s_srcPatch[LOCAL_SIZE+2][LOCAL_SIZE+2];\n"
"__local FT s_dstPatch[LOCAL_SIZE+2][2*LOCAL_SIZE];\n"
"__global uchar * dstData = dst + dst_offset;\n"
"__global const uchar * srcData = src + src_offset;\n"
"if( lx < (LOCAL_SIZE+2) && ly < (LOCAL_SIZE+2) )\n"
"{\n"
"int srcx = mad24((int)get_group_id(0), LOCAL_SIZE, lx) - 1;\n"
"int srcy = mad24((int)get_group_id(1), LOCAL_SIZE, ly) - 1;\n"
"int srcx1 = EXTRAPOLATE(srcx, src_cols);\n"
"int srcx2 = EXTRAPOLATE(srcx+1, src_cols);\n"
"int srcy1 = EXTRAPOLATE(srcy, src_rows);\n"
"int srcy2 = EXTRAPOLATE(srcy+1, src_rows);\n"
"s_srcPatch[ly][lx] = convertToFT(loadpix(srcData + srcy1 * src_step + srcx1 * PIXSIZE));\n"
"s_srcPatch[ly+1][lx] = convertToFT(loadpix(srcData + srcy2 * src_step + srcx1 * PIXSIZE));\n"
"s_srcPatch[ly][lx+1] = convertToFT(loadpix(srcData + srcy1 * src_step + srcx2 * PIXSIZE));\n"
"s_srcPatch[ly+1][lx+1] = convertToFT(loadpix(srcData + srcy2 * src_step + srcx2 * PIXSIZE));\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"FT sum;\n"
"const FT co1 = 0.75f;\n"
"const FT co2 = 0.5f;\n"
"const FT co3 = 0.125f;\n"
"sum =       co3 * s_srcPatch[1 + (ly >> 1)][1 + ((lx - 2) >> 1)];\n"
"sum = mad(co1, s_srcPatch[1 + (ly >> 1)][1 + ((lx    ) >> 1)], sum);\n"
"sum = mad(co3, s_srcPatch[1 + (ly >> 1)][1 + ((lx + 2) >> 1)], sum);\n"
"s_dstPatch[1 + get_local_id(1)][lx] = sum;\n"
"sum =       co2 * s_srcPatch[1 + (ly >> 1)][1 + ((lx + 1 - 1) >> 1)];\n"
"sum = mad(co2, s_srcPatch[1 + (ly >> 1)][1 + ((lx + 1 + 1) >> 1)], sum);\n"
"s_dstPatch[1 + get_local_id(1)][lx+1] = sum;\n"
"if (ly < 1)\n"
"{\n"
"sum =       co3 * s_srcPatch[0][1 + ((lx - 2) >> 1)];\n"
"sum = mad(co1, s_srcPatch[0][1 + ((lx    ) >> 1)], sum);\n"
"sum = mad(co3, s_srcPatch[0][1 + ((lx + 2) >> 1)], sum);\n"
"s_dstPatch[0][lx] = sum;\n"
"sum =       co2 * s_srcPatch[0][1 + ((lx + 1 - 1) >> 1)];\n"
"sum = mad(co2, s_srcPatch[0][1 + ((lx + 1 + 1) >> 1)], sum);\n"
"s_dstPatch[0][lx+1] = sum;\n"
"}\n"
"if (ly > 2*LOCAL_SIZE-3)\n"
"{\n"
"sum =       co3 * s_srcPatch[LOCAL_SIZE+1][1 + ((lx - 2) >> 1)];\n"
"sum = mad(co1, s_srcPatch[LOCAL_SIZE+1][1 + ((lx    ) >> 1)], sum);\n"
"sum = mad(co3, s_srcPatch[LOCAL_SIZE+1][1 + ((lx + 2) >> 1)], sum);\n"
"s_dstPatch[LOCAL_SIZE+1][lx] = sum;\n"
"sum =       co2 * s_srcPatch[LOCAL_SIZE+1][1 + ((lx + 1 - 1) >> 1)];\n"
"sum = mad(co2, s_srcPatch[LOCAL_SIZE+1][1 + ((lx + 1 + 1) >> 1)], sum);\n"
"s_dstPatch[LOCAL_SIZE+1][lx+1] = sum;\n"
"}\n"
"barrier(CLK_LOCAL_MEM_FENCE);\n"
"int dst_x = 2*get_global_id(0);\n"
"int dst_y = 2*get_global_id(1);\n"
"if ((dst_x < dst_cols) && (dst_y < dst_rows))\n"
"{\n"
"sum =       co3 * s_dstPatch[1 + get_local_id(1) - 1][lx];\n"
"sum = mad(co1, s_dstPatch[1 + get_local_id(1)    ][lx], sum);\n"
"sum = mad(co3, s_dstPatch[1 + get_local_id(1) + 1][lx], sum);\n"
"storepix(convertToT(sum), dstData + dst_y * dst_step + dst_x * PIXSIZE);\n"
"sum =       co3 * s_dstPatch[1 + get_local_id(1) - 1][lx+1];\n"
"sum = mad(co1, s_dstPatch[1 + get_local_id(1)    ][lx+1], sum);\n"
"sum = mad(co3, s_dstPatch[1 + get_local_id(1) + 1][lx+1], sum);\n"
"storepix(convertToT(sum), dstData + dst_y * dst_step + (dst_x+1) * PIXSIZE);\n"
"sum =       co2 * s_dstPatch[1 + get_local_id(1)    ][lx];\n"
"sum = mad(co2, s_dstPatch[1 + get_local_id(1) + 1][lx], sum);\n"
"storepix(convertToT(sum), dstData + (dst_y+1) * dst_step + dst_x * PIXSIZE);\n"
"sum =       co2 * s_dstPatch[1 + get_local_id(1)    ][lx+1];\n"
"sum = mad(co2, s_dstPatch[1 + get_local_id(1) + 1][lx+1], sum);\n"
"storepix(convertToT(sum), dstData + (dst_y+1) * dst_step + (dst_x+1) * PIXSIZE);\n"
"}\n"
"}\n"
, "e48abb0036bd5e090ad06600b018eec9", NULL};
struct cv::ocl::internal::ProgramEntry pyramid_up_oclsrc={moduleName, "pyramid_up",
"__constant float kx[] = { 0.125, 0.5, 0.75, 0.5, 0.125 };\n"
"__constant float ky[] = { 0.125, 0.5, 0.75, 0.5, 0.125 };\n"
"#define OP(delta, y, x) (convert_float4(arr[(y + delta) * 5 + x]) * ky[y] * kx[x])\n"
"__kernel void pyrUp_cols2(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"int block_x = get_global_id(0);\n"
"int y = get_global_id(1) * 2;\n"
"if ((block_x * 4) >= dst_cols || y >= dst_rows) return;\n"
"uchar8 line[6];\n"
"uchar4 line_out;\n"
"int offset, src_index;\n"
"src_index = block_x * 2 + (y / 2 - 1) * src_step - 1 + src_offset;\n"
"uchar4 tmp;\n"
"line[0] = line[2] = line[4] = (uchar8)0;\n"
"line[1] = line[3] = line[5] = (uchar8)0;\n"
"offset = max(0, src_index + 1 * src_step);\n"
"tmp = vload4(0, src + offset);\n"
"if (offset == 0) tmp = (uchar4)(0, tmp.s012);\n"
"line[2].even = tmp;\n"
"offset = max(0, src_index + ((y == 0) ? 2 : 0) * src_step);\n"
"tmp = vload4(0, src + offset);\n"
"if (offset == 0) tmp = (uchar4)(0, tmp.s012);\n"
"line[0].even = tmp;\n"
"if (y == (dst_rows - 2))\n"
"line[4] = line[2];\n"
"else\n"
"line[4].even = vload4(0, src + src_index + 2 * src_step);\n"
"bool row_s = (block_x == 0);\n"
"bool row_e = ((block_x + 1) * 4 == dst_cols);\n"
"uchar4 arr[30];\n"
"uchar s, e;\n"
"s = line[0].s4;\n"
"e = line[0].s3;\n"
"arr[0] = row_s ? (uchar4)(s, e, line[0].s23) : (uchar4)(line[0].s0123);\n"
"arr[1] = row_s ? (uchar4)(e, line[0].s234) : (uchar4)(line[0].s1234);\n"
"arr[2] = (uchar4)(line[0].s2345);\n"
"arr[3] = row_e ? (uchar4)(line[0].s345, s) : (uchar4)(line[0].s3456);\n"
"arr[4] = row_e ? (uchar4)(line[0].s45, s, e) : (uchar4)(line[0].s4567);\n"
"s = line[1].s4;\n"
"e = line[1].s3;\n"
"arr[5] = row_s ? (uchar4)(s, e, line[1].s23) : (uchar4)(line[1].s0123);\n"
"arr[6] = row_s ? (uchar4)(e, line[1].s234) : (uchar4)(line[1].s1234);\n"
"arr[7] = (uchar4)(line[1].s2345);\n"
"arr[8] = row_e ? (uchar4)(line[1].s345, s) : (uchar4)(line[1].s3456);\n"
"arr[9] = row_e ? (uchar4)(line[1].s45, s, e) : (uchar4)(line[1].s4567);\n"
"s = line[2].s4;\n"
"e = line[2].s3;\n"
"arr[10] = row_s ? (uchar4)(s, e, line[2].s23) : (uchar4)(line[2].s0123);\n"
"arr[11] = row_s ? (uchar4)(e, line[2].s234) : (uchar4)(line[2].s1234);\n"
"arr[12] = (uchar4)(line[2].s2345);\n"
"arr[13] = row_e ? (uchar4)(line[2].s345, s) : (uchar4)(line[2].s3456);\n"
"arr[14] = row_e ? (uchar4)(line[2].s45, s, e) : (uchar4)(line[2].s4567);\n"
"s = line[3].s4;\n"
"e = line[3].s3;\n"
"arr[15] = row_s ? (uchar4)(s, e, line[3].s23) : (uchar4)(line[3].s0123);\n"
"arr[16] = row_s ? (uchar4)(e, line[3].s234) : (uchar4)(line[3].s1234);\n"
"arr[17] = (uchar4)(line[3].s2345);\n"
"arr[18] = row_e ? (uchar4)(line[3].s345, s) : (uchar4)(line[3].s3456);\n"
"arr[19] = row_e ? (uchar4)(line[3].s45, s, e) : (uchar4)(line[3].s4567);\n"
"s = line[4].s4;\n"
"e = line[4].s3;\n"
"arr[20] = row_s ? (uchar4)(s, e, line[4].s23) : (uchar4)(line[4].s0123);\n"
"arr[21] = row_s ? (uchar4)(e, line[4].s234) : (uchar4)(line[4].s1234);\n"
"arr[22] = (uchar4)(line[4].s2345);\n"
"arr[23] = row_e ? (uchar4)(line[4].s345, s) : (uchar4)(line[4].s3456);\n"
"arr[24] = row_e ? (uchar4)(line[4].s45, s, e) : (uchar4)(line[4].s4567);\n"
"s = line[5].s4;\n"
"e = line[5].s3;\n"
"arr[25] = row_s ? (uchar4)(s, e, line[5].s23) : (uchar4)(line[5].s0123);\n"
"arr[26] = row_s ? (uchar4)(e, line[5].s234) : (uchar4)(line[5].s1234);\n"
"arr[27] = (uchar4)(line[5].s2345);\n"
"arr[28] = row_e ? (uchar4)(line[5].s345, s) : (uchar4)(line[5].s3456);\n"
"arr[29] = row_e ? (uchar4)(line[5].s45, s, e) : (uchar4)(line[5].s4567);\n"
"float4 sum[2];\n"
"sum[0] = OP(0, 0, 0) + OP(0, 0, 1) + OP(0, 0, 2) + OP(0, 0, 3) + OP(0, 0, 4) +\n"
"OP(0, 1, 0) + OP(0, 1, 1) + OP(0, 1, 2) + OP(0, 1, 3) + OP(0, 1, 4) +\n"
"OP(0, 2, 0) + OP(0, 2, 1) + OP(0, 2, 2) + OP(0, 2, 3) + OP(0, 2, 4) +\n"
"OP(0, 3, 0) + OP(0, 3, 1) + OP(0, 3, 2) + OP(0, 3, 3) + OP(0, 3, 4) +\n"
"OP(0, 4, 0) + OP(0, 4, 1) + OP(0, 4, 2) + OP(0, 4, 3) + OP(0, 4, 4);\n"
"sum[1] = OP(1, 0, 0) + OP(1, 0, 1) + OP(1, 0, 2) + OP(1, 0, 3) + OP(1, 0, 4) +\n"
"OP(1, 1, 0) + OP(1, 1, 1) + OP(1, 1, 2) + OP(1, 1, 3) + OP(1, 1, 4) +\n"
"OP(1, 2, 0) + OP(1, 2, 1) + OP(1, 2, 2) + OP(1, 2, 3) + OP(1, 2, 4) +\n"
"OP(1, 3, 0) + OP(1, 3, 1) + OP(1, 3, 2) + OP(1, 3, 3) + OP(1, 3, 4) +\n"
"OP(1, 4, 0) + OP(1, 4, 1) + OP(1, 4, 2) + OP(1, 4, 3) + OP(1, 4, 4);\n"
"int dst_index = block_x * 4 + y * dst_step + dst_offset;\n"
"vstore4(convert_uchar4_sat_rte(sum[0]), 0, dst + dst_index);\n"
"vstore4(convert_uchar4_sat_rte(sum[1]), 0, dst + dst_index + dst_step);\n"
"}\n"
, "46bae9fe0213f767045e3c63f9ffc6a0", NULL};
struct cv::ocl::internal::ProgramEntry remap_oclsrc={moduleName, "remap",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#define noconvert\n"
"#if cn != 3\n"
"#define loadpix(addr)  *(__global const T*)(addr)\n"
"#define storepix(val, addr)  *(__global T*)(addr) = val\n"
"#define TSIZE ((int)sizeof(T))\n"
"#define convertScalar(a) (a)\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const T1*)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global T1*)(addr))\n"
"#define TSIZE ((int)sizeof(T1)*3)\n"
"#define convertScalar(a) (T)(a.x, a.y, a.z)\n"
"#endif\n"
"enum\n"
"{\n"
"INTER_BITS = 5,\n"
"INTER_TAB_SIZE = 1 << INTER_BITS,\n"
"INTER_TAB_SIZE2 = INTER_TAB_SIZE * INTER_TAB_SIZE\n"
"};\n"
"#ifdef INTER_NEAREST\n"
"#define convertToWT\n"
"#endif\n"
"#ifdef BORDER_CONSTANT\n"
"#define EXTRAPOLATE(v2, v) v = scalar;\n"
"#elif defined BORDER_REPLICATE\n"
"#define EXTRAPOLATE(v2, v) \\\n"
"{ \\\n"
"v2 = max(min(v2, (int2)(src_cols - 1, src_rows - 1)), (int2)(0)); \\\n"
"v = convertToWT(loadpix((__global const T*)(srcptr + mad24(v2.y, src_step, v2.x * TSIZE + src_offset)))); \\\n"
"}\n"
"#elif defined BORDER_WRAP\n"
"#define EXTRAPOLATE(v2, v) \\\n"
"{ \\\n"
"if (v2.x < 0) \\\n"
"v2.x -= ((v2.x - src_cols + 1) / src_cols) * src_cols; \\\n"
"if (v2.x >= src_cols) \\\n"
"v2.x %= src_cols; \\\n"
"\\\n"
"if (v2.y < 0) \\\n"
"v2.y -= ((v2.y - src_rows + 1) / src_rows) * src_rows; \\\n"
"if( v2.y >= src_rows ) \\\n"
"v2.y %= src_rows; \\\n"
"v = convertToWT(loadpix((__global const T*)(srcptr + mad24(v2.y, src_step, v2.x * TSIZE + src_offset)))); \\\n"
"}\n"
"#elif defined(BORDER_REFLECT) || defined(BORDER_REFLECT_101)\n"
"#ifdef BORDER_REFLECT\n"
"#define DELTA int delta = 0\n"
"#else\n"
"#define DELTA int delta = 1\n"
"#endif\n"
"#define EXTRAPOLATE(v2, v) \\\n"
"{ \\\n"
"DELTA; \\\n"
"if (src_cols == 1) \\\n"
"v2.x = 0; \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if( v2.x < 0 ) \\\n"
"v2.x = -v2.x - 1 + delta; \\\n"
"else \\\n"
"v2.x = src_cols - 1 - (v2.x - src_cols) - delta; \\\n"
"} \\\n"
"while (v2.x >= src_cols || v2.x < 0); \\\n"
"\\\n"
"if (src_rows == 1) \\\n"
"v2.y = 0; \\\n"
"else \\\n"
"do \\\n"
"{ \\\n"
"if( v2.y < 0 ) \\\n"
"v2.y = -v2.y - 1 + delta; \\\n"
"else \\\n"
"v2.y = src_rows - 1 - (v2.y - src_rows) - delta; \\\n"
"} \\\n"
"while (v2.y >= src_rows || v2.y < 0); \\\n"
"v = convertToWT(loadpix((__global const T*)(srcptr + mad24(v2.y, src_step, v2.x * TSIZE + src_offset)))); \\\n"
"}\n"
"#else\n"
"#error No extrapolation method\n"
"#endif\n"
"#define NEED_EXTRAPOLATION(gx, gy) (gx >= src_cols || gy >= src_rows || gx < 0 || gy < 0)\n"
"#ifdef INTER_NEAREST\n"
"__kernel void remap_2_32FC1(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__global const uchar * map1ptr, int map1_step, int map1_offset,\n"
"__global const uchar * map2ptr, int map2_step, int map2_offset,\n"
"ST nVal)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * rowsPerWI;\n"
"if (x < dst_cols)\n"
"{\n"
"T scalar = convertScalar(nVal);\n"
"int map1_index = mad24(y, map1_step, mad24(x, (int)sizeof(float), map1_offset));\n"
"int map2_index = mad24(y, map2_step, mad24(x, (int)sizeof(float), map2_offset));\n"
"int dst_index = mad24(y, dst_step, mad24(x, TSIZE, dst_offset));\n"
"#pragma unroll\n"
"for (int i = 0; i < rowsPerWI; ++i, ++y,\n"
"map1_index += map1_step, map2_index += map2_step, dst_index += dst_step)\n"
"if (y < dst_rows)\n"
"{\n"
"__global const float * map1 = (__global const float *)(map1ptr + map1_index);\n"
"__global const float * map2 = (__global const float *)(map2ptr + map2_index);\n"
"__global T * dst = (__global T *)(dstptr + dst_index);\n"
"int gx = convert_int_sat_rte(map1[0]);\n"
"int gy = convert_int_sat_rte(map2[0]);\n"
"if (NEED_EXTRAPOLATION(gx, gy))\n"
"{\n"
"#ifndef BORDER_CONSTANT\n"
"int2 gxy = (int2)(gx, gy);\n"
"#endif\n"
"T v;\n"
"EXTRAPOLATE(gxy, v)\n"
"storepix(v, dst);\n"
"}\n"
"else\n"
"{\n"
"int src_index = mad24(gy, src_step, mad24(gx, TSIZE, src_offset));\n"
"storepix(loadpix((__global const T*)(srcptr + src_index)), dst);\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void remap_32FC2(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__global const uchar * mapptr, int map_step, int map_offset,\n"
"ST nVal)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * rowsPerWI;\n"
"if (x < dst_cols)\n"
"{\n"
"T scalar = convertScalar(nVal);\n"
"int dst_index = mad24(y, dst_step, mad24(x, TSIZE, dst_offset));\n"
"int map_index = mad24(y, map_step, mad24(x, (int)sizeof(float2), map_offset));\n"
"#pragma unroll\n"
"for (int i = 0; i < rowsPerWI; ++i, ++y,\n"
"map_index += map_step, dst_index += dst_step)\n"
"if (y < dst_rows)\n"
"{\n"
"__global const float2 * map = (__global const float2 *)(mapptr + map_index);\n"
"__global T * dst = (__global T *)(dstptr + dst_index);\n"
"int2 gxy = convert_int2_sat_rte(map[0]);\n"
"int gx = gxy.x, gy = gxy.y;\n"
"if (NEED_EXTRAPOLATION(gx, gy))\n"
"{\n"
"T v;\n"
"EXTRAPOLATE(gxy, v)\n"
"storepix(v, dst);\n"
"}\n"
"else\n"
"{\n"
"int src_index = mad24(gy, src_step, mad24(gx, TSIZE, src_offset));\n"
"storepix(loadpix((__global const T *)(srcptr + src_index)), dst);\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void remap_16SC2(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__global const uchar * mapptr, int map_step, int map_offset,\n"
"ST nVal)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * rowsPerWI;\n"
"if (x < dst_cols)\n"
"{\n"
"T scalar = convertScalar(nVal);\n"
"int dst_index = mad24(y, dst_step, mad24(x, TSIZE, dst_offset));\n"
"int map_index = mad24(y, map_step, mad24(x, (int)sizeof(short2), map_offset));\n"
"#pragma unroll\n"
"for (int i = 0; i < rowsPerWI; ++i, ++y,\n"
"map_index += map_step, dst_index += dst_step)\n"
"if (y < dst_rows)\n"
"{\n"
"__global const short2 * map = (__global const short2 *)(mapptr + map_index);\n"
"__global T * dst = (__global T *)(dstptr + dst_index);\n"
"int2 gxy = convert_int2(map[0]);\n"
"int gx = gxy.x, gy = gxy.y;\n"
"if (NEED_EXTRAPOLATION(gx, gy))\n"
"{\n"
"T v;\n"
"EXTRAPOLATE(gxy, v)\n"
"storepix(v, dst);\n"
"}\n"
"else\n"
"{\n"
"int src_index = mad24(gy, src_step, mad24(gx, TSIZE, src_offset));\n"
"storepix(loadpix((__global const T *)(srcptr + src_index)), dst);\n"
"}\n"
"}\n"
"}\n"
"}\n"
"__kernel void remap_16SC2_16UC1(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__global const uchar * map1ptr, int map1_step, int map1_offset,\n"
"__global const uchar * map2ptr, int map2_step, int map2_offset,\n"
"ST nVal)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * rowsPerWI;\n"
"if (x < dst_cols)\n"
"{\n"
"T scalar = convertScalar(nVal);\n"
"int dst_index = mad24(y, dst_step, mad24(x, TSIZE, dst_offset));\n"
"int map1_index = mad24(y, map1_step, mad24(x, (int)sizeof(short2), map1_offset));\n"
"int map2_index = mad24(y, map2_step, mad24(x, (int)sizeof(ushort), map2_offset));\n"
"#pragma unroll\n"
"for (int i = 0; i < rowsPerWI; ++i, ++y,\n"
"map1_index += map1_step, map2_index += map2_step, dst_index += dst_step)\n"
"if (y < dst_rows)\n"
"{\n"
"__global const short2 * map1 = (__global const short2 *)(map1ptr + map1_index);\n"
"__global const ushort * map2 = (__global const ushort *)(map2ptr + map2_index);\n"
"__global T * dst = (__global T *)(dstptr + dst_index);\n"
"int map2Value = convert_int(map2[0]) & (INTER_TAB_SIZE2 - 1);\n"
"int dx = (map2Value & (INTER_TAB_SIZE - 1)) < (INTER_TAB_SIZE >> 1) ? 1 : 0;\n"
"int dy = (map2Value >> INTER_BITS) < (INTER_TAB_SIZE >> 1) ? 1 : 0;\n"
"int2 gxy = convert_int2(map1[0]) + (int2)(dx, dy);\n"
"int gx = gxy.x, gy = gxy.y;\n"
"if (NEED_EXTRAPOLATION(gx, gy))\n"
"{\n"
"T v;\n"
"EXTRAPOLATE(gxy, v)\n"
"storepix(v, dst);\n"
"}\n"
"else\n"
"{\n"
"int src_index = mad24(gy, src_step, mad24(gx, TSIZE, src_offset));\n"
"storepix(loadpix((__global const T *)(srcptr + src_index)), dst);\n"
"}\n"
"}\n"
"}\n"
"}\n"
"#elif defined INTER_LINEAR\n"
"__constant float coeffs[64] =\n"
"{ 1.000000f, 0.000000f, 0.968750f, 0.031250f, 0.937500f, 0.062500f, 0.906250f, 0.093750f, 0.875000f, 0.125000f, 0.843750f, 0.156250f,\n"
"0.812500f, 0.187500f, 0.781250f, 0.218750f, 0.750000f, 0.250000f, 0.718750f, 0.281250f, 0.687500f, 0.312500f, 0.656250f, 0.343750f,\n"
"0.625000f, 0.375000f, 0.593750f, 0.406250f, 0.562500f, 0.437500f, 0.531250f, 0.468750f, 0.500000f, 0.500000f, 0.468750f, 0.531250f,\n"
"0.437500f, 0.562500f, 0.406250f, 0.593750f, 0.375000f, 0.625000f, 0.343750f, 0.656250f, 0.312500f, 0.687500f, 0.281250f, 0.718750f,\n"
"0.250000f, 0.750000f, 0.218750f, 0.781250f, 0.187500f, 0.812500f, 0.156250f, 0.843750f, 0.125000f, 0.875000f, 0.093750f, 0.906250f,\n"
"0.062500f, 0.937500f, 0.031250f, 0.968750f };\n"
"__kernel void remap_16SC2_16UC1(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__global const uchar * map1ptr, int map1_step, int map1_offset,\n"
"__global const uchar * map2ptr, int map2_step, int map2_offset,\n"
"ST nVal)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * rowsPerWI;\n"
"if (x < dst_cols)\n"
"{\n"
"WT scalar = convertToWT(convertScalar(nVal));\n"
"int dst_index = mad24(y, dst_step, mad24(x, TSIZE, dst_offset));\n"
"int map1_index = mad24(y, map1_step, mad24(x, (int)sizeof(short2), map1_offset));\n"
"int map2_index = mad24(y, map2_step, mad24(x, (int)sizeof(ushort), map2_offset));\n"
"#pragma unroll\n"
"for (int i = 0; i < rowsPerWI; ++i, ++y,\n"
"map1_index += map1_step, map2_index += map2_step, dst_index += dst_step)\n"
"if (y < dst_rows)\n"
"{\n"
"__global const short2 * map1 = (__global const short2 *)(map1ptr + map1_index);\n"
"__global const ushort * map2 = (__global const ushort *)(map2ptr + map2_index);\n"
"__global T * dst = (__global T *)(dstptr + dst_index);\n"
"int2 map_dataA = convert_int2(map1[0]);\n"
"int2 map_dataB = (int2)(map_dataA.x + 1, map_dataA.y);\n"
"int2 map_dataC = (int2)(map_dataA.x, map_dataA.y + 1);\n"
"int2 map_dataD = (int2)(map_dataA.x + 1, map_dataA.y + 1);\n"
"ushort map2Value = (ushort)(map2[0] & (INTER_TAB_SIZE2 - 1));\n"
"WT2 u = (WT2)(map2Value & (INTER_TAB_SIZE - 1), map2Value >> INTER_BITS) / (WT2)(INTER_TAB_SIZE);\n"
"WT a = scalar, b = scalar, c = scalar, d = scalar;\n"
"if (!NEED_EXTRAPOLATION(map_dataA.x, map_dataA.y))\n"
"a = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataA.y, src_step, map_dataA.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataA, a);\n"
"if (!NEED_EXTRAPOLATION(map_dataB.x, map_dataB.y))\n"
"b = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataB.y, src_step, map_dataB.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataB, b);\n"
"if (!NEED_EXTRAPOLATION(map_dataC.x, map_dataC.y))\n"
"c = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataC.y, src_step, map_dataC.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataC, c);\n"
"if (!NEED_EXTRAPOLATION(map_dataD.x, map_dataD.y))\n"
"d = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataD.y, src_step, map_dataD.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataD, d);\n"
"WT dst_data = a * (1 - u.x) * (1 - u.y) +\n"
"b * (u.x)     * (1 - u.y) +\n"
"c * (1 - u.x) * (u.y) +\n"
"d * (u.x)     * (u.y);\n"
"storepix(convertToT(dst_data), dst);\n"
"}\n"
"}\n"
"}\n"
"__kernel void remap_2_32FC1(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__global const uchar * map1ptr, int map1_step, int map1_offset,\n"
"__global const uchar * map2ptr, int map2_step, int map2_offset,\n"
"ST nVal)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * rowsPerWI;\n"
"if (x < dst_cols)\n"
"{\n"
"WT scalar = convertToWT(convertScalar(nVal));\n"
"int dst_index = mad24(y, dst_step, mad24(x, TSIZE, dst_offset));\n"
"int map1_index = mad24(y, map1_step, mad24(x, (int)sizeof(float), map1_offset));\n"
"int map2_index = mad24(y, map2_step, mad24(x, (int)sizeof(float), map2_offset));\n"
"#pragma unroll\n"
"for (int i = 0; i < rowsPerWI; ++i, ++y,\n"
"map1_index += map1_step, map2_index += map2_step, dst_index += dst_step)\n"
"if (y < dst_rows)\n"
"{\n"
"__global const float * map1 = (__global const float *)(map1ptr + map1_index);\n"
"__global const float * map2 = (__global const float *)(map2ptr + map2_index);\n"
"__global T * dst = (__global T *)(dstptr + dst_index);\n"
"#if defined BORDER_CONSTANT\n"
"float xf = map1[0], yf = map2[0];\n"
"int sx = convert_int_sat_rtz(mad(xf, (float)INTER_TAB_SIZE, 0.5f)) >> INTER_BITS;\n"
"int sy = convert_int_sat_rtz(mad(yf, (float)INTER_TAB_SIZE, 0.5f)) >> INTER_BITS;\n"
"__constant float * coeffs_x = coeffs + ((convert_int_rte(xf * INTER_TAB_SIZE) & (INTER_TAB_SIZE - 1)) << 1);\n"
"__constant float * coeffs_y = coeffs + ((convert_int_rte(yf * INTER_TAB_SIZE) & (INTER_TAB_SIZE - 1)) << 1);\n"
"WT sum = (WT)(0), xsum;\n"
"int src_index = mad24(sy, src_step, mad24(sx, TSIZE, src_offset));\n"
"#pragma unroll\n"
"for (int yp = 0; yp < 2; ++yp, src_index += src_step)\n"
"{\n"
"if (sy + yp >= 0 && sy + yp < src_rows)\n"
"{\n"
"xsum = (WT)(0);\n"
"if (sx >= 0 && sx + 2 < src_cols)\n"
"{\n"
"#if depth == 0 && cn == 1\n"
"uchar2 value = vload2(0, srcptr + src_index);\n"
"xsum = dot(convert_float2(value), (float2)(coeffs_x[0], coeffs_x[1]));\n"
"#else\n"
"#pragma unroll\n"
"for (int xp = 0; xp < 2; ++xp)\n"
"xsum = fma(convertToWT(loadpix(srcptr + mad24(xp, TSIZE, src_index))), coeffs_x[xp], xsum);\n"
"#endif\n"
"}\n"
"else\n"
"{\n"
"#pragma unroll\n"
"for (int xp = 0; xp < 2; ++xp)\n"
"xsum = fma(sx + xp >= 0 && sx + xp < src_cols ?\n"
"convertToWT(loadpix(srcptr + mad24(xp, TSIZE, src_index))) : scalar, coeffs_x[xp], xsum);\n"
"}\n"
"sum = fma(xsum, coeffs_y[yp], sum);\n"
"}\n"
"else\n"
"sum = fma(scalar, coeffs_y[yp], sum);\n"
"}\n"
"storepix(convertToT(sum), dst);\n"
"#else\n"
"float2 map_data = (float2)(map1[0], map2[0]);\n"
"int2 map_dataA = convert_int2_sat_rtn(map_data);\n"
"int2 map_dataB = (int2)(map_dataA.x + 1, map_dataA.y);\n"
"int2 map_dataC = (int2)(map_dataA.x, map_dataA.y + 1);\n"
"int2 map_dataD = (int2)(map_dataA.x + 1, map_dataA.y + 1);\n"
"float2 _u = map_data - convert_float2(map_dataA);\n"
"WT2 u = convertToWT2(convert_int2_rte(convertToWT2(_u) * (WT2)INTER_TAB_SIZE)) / (WT2)INTER_TAB_SIZE;\n"
"WT scalar = convertToWT(convertScalar(nVal));\n"
"WT a = scalar, b = scalar, c = scalar, d = scalar;\n"
"if (!NEED_EXTRAPOLATION(map_dataA.x, map_dataA.y))\n"
"a = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataA.y, src_step, map_dataA.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataA, a);\n"
"if (!NEED_EXTRAPOLATION(map_dataB.x, map_dataB.y))\n"
"b = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataB.y, src_step, map_dataB.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataB, b);\n"
"if (!NEED_EXTRAPOLATION(map_dataC.x, map_dataC.y))\n"
"c = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataC.y, src_step, map_dataC.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataC, c);\n"
"if (!NEED_EXTRAPOLATION(map_dataD.x, map_dataD.y))\n"
"d = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataD.y, src_step, map_dataD.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataD, d);\n"
"WT dst_data = a * (1 - u.x) * (1 - u.y) +\n"
"b * (u.x)     * (1 - u.y) +\n"
"c * (1 - u.x) * (u.y) +\n"
"d * (u.x)     * (u.y);\n"
"storepix(convertToT(dst_data), dst);\n"
"#endif\n"
"}\n"
"}\n"
"}\n"
"__kernel void remap_32FC2(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__global const uchar * mapptr, int map_step, int map_offset,\n"
"ST nVal)\n"
"{\n"
"int x = get_global_id(0);\n"
"int y = get_global_id(1) * rowsPerWI;\n"
"if (x < dst_cols)\n"
"{\n"
"WT scalar = convertToWT(convertScalar(nVal));\n"
"int dst_index = mad24(y, dst_step, mad24(x, TSIZE, dst_offset));\n"
"int map_index = mad24(y, map_step, mad24(x, (int)sizeof(float2), map_offset));\n"
"#pragma unroll\n"
"for (int i = 0; i < rowsPerWI; ++i, ++y,\n"
"map_index += map_step, dst_index += dst_step)\n"
"if (y < dst_rows)\n"
"{\n"
"__global const float2 * map = (__global const float2 *)(mapptr + map_index);\n"
"__global T * dst = (__global T *)(dstptr + dst_index);\n"
"float2 map_data = map[0];\n"
"int2 map_dataA = convert_int2_sat_rtn(map_data);\n"
"int2 map_dataB = (int2)(map_dataA.x + 1, map_dataA.y);\n"
"int2 map_dataC = (int2)(map_dataA.x, map_dataA.y + 1);\n"
"int2 map_dataD = (int2)(map_dataA.x + 1, map_dataA.y + 1);\n"
"float2 _u = map_data - convert_float2(map_dataA);\n"
"WT2 u = convertToWT2(convert_int2_rte(convertToWT2(_u) * (WT2)INTER_TAB_SIZE)) / (WT2)INTER_TAB_SIZE;\n"
"WT a = scalar, b = scalar, c = scalar, d = scalar;\n"
"if (!NEED_EXTRAPOLATION(map_dataA.x, map_dataA.y))\n"
"a = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataA.y, src_step, map_dataA.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataA, a);\n"
"if (!NEED_EXTRAPOLATION(map_dataB.x, map_dataB.y))\n"
"b = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataB.y, src_step, map_dataB.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataB, b);\n"
"if (!NEED_EXTRAPOLATION(map_dataC.x, map_dataC.y))\n"
"c = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataC.y, src_step, map_dataC.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataC, c);\n"
"if (!NEED_EXTRAPOLATION(map_dataD.x, map_dataD.y))\n"
"d = convertToWT(loadpix((__global const T *)(srcptr + mad24(map_dataD.y, src_step, map_dataD.x * TSIZE + src_offset))));\n"
"else\n"
"EXTRAPOLATE(map_dataD, d);\n"
"WT dst_data = a * (1 - u.x) * (1 - u.y) +\n"
"b * (u.x)     * (1 - u.y) +\n"
"c * (1 - u.x) * (u.y) +\n"
"d * (u.x)     * (u.y);\n"
"storepix(convertToT(dst_data), dst);\n"
"}\n"
"}\n"
"}\n"
"#endif\n"
, "d71b990c30eb48e9063ba2446a0278c6", NULL};
struct cv::ocl::internal::ProgramEntry resize_oclsrc={moduleName, "resize",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#define INTER_RESIZE_COEF_SCALE (1 << INTER_RESIZE_COEF_BITS)\n"
"#define CAST_BITS (INTER_RESIZE_COEF_BITS << 1)\n"
"#define INC(x,l) min(x+1,l-1)\n"
"#define noconvert\n"
"#if cn != 3\n"
"#define loadpix(addr)  *(__global const T *)(addr)\n"
"#define storepix(val, addr)  *(__global T *)(addr) = val\n"
"#define TSIZE (int)sizeof(T)\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const T1 *)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global T1 *)(addr))\n"
"#define TSIZE (int)sizeof(T1)*cn\n"
"#endif\n"
"#if defined USE_SAMPLER\n"
"#if cn == 1\n"
"#define READ_IMAGE(X,Y,Z)  read_imagef(X,Y,Z).x\n"
"#define INTERMEDIATE_TYPE  float\n"
"#elif cn == 2\n"
"#define READ_IMAGE(X,Y,Z)  read_imagef(X,Y,Z).xy\n"
"#define INTERMEDIATE_TYPE  float2\n"
"#elif cn == 3\n"
"#define READ_IMAGE(X,Y,Z)  read_imagef(X,Y,Z).xyz\n"
"#define INTERMEDIATE_TYPE  float3\n"
"#elif cn == 4\n"
"#define READ_IMAGE(X,Y,Z)  read_imagef(X,Y,Z)\n"
"#define INTERMEDIATE_TYPE  float4\n"
"#endif\n"
"#define __CAT(x, y) x##y\n"
"#define CAT(x, y) __CAT(x, y)\n"
"#define float1 float\n"
"#if depth == 0\n"
"#define RESULT_SCALE    255.0f\n"
"#elif depth == 1\n"
"#define RESULT_SCALE    127.0f\n"
"#elif depth == 2\n"
"#define RESULT_SCALE    65535.0f\n"
"#elif depth == 3\n"
"#define RESULT_SCALE    32767.0f\n"
"#else\n"
"#define RESULT_SCALE    1.0f\n"
"#endif\n"
"__kernel void resizeSampler(__read_only image2d_t srcImage,\n"
"__global uchar* dstptr, int dststep, int dstoffset,\n"
"int dstrows, int dstcols,\n"
"float ifx, float ify)\n"
"{\n"
"const sampler_t sampler = CLK_NORMALIZED_COORDS_FALSE |\n"
"CLK_ADDRESS_CLAMP_TO_EDGE |\n"
"CLK_FILTER_LINEAR;\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"float sx = ((dx+0.5f) * ifx), sy = ((dy+0.5f) * ify);\n"
"INTERMEDIATE_TYPE intermediate = READ_IMAGE(srcImage, sampler, (float2)(sx, sy));\n"
"#if depth <= 4\n"
"T uval = convertToDT(round(intermediate * RESULT_SCALE));\n"
"#else\n"
"T uval = convertToDT(intermediate * RESULT_SCALE);\n"
"#endif\n"
"if(dx < dstcols && dy < dstrows)\n"
"{\n"
"storepix(uval, dstptr + mad24(dy, dststep, dstoffset + dx*TSIZE));\n"
"}\n"
"}\n"
"#elif defined INTER_LINEAR_INTEGER\n"
"__kernel void resizeLN(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__global const uchar * buffer)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"if (dx < dst_cols && dy < dst_rows)\n"
"{\n"
"__global const int * xofs = (__global const int *)(buffer), * yofs = xofs + dst_cols;\n"
"__global const short * ialpha = (__global const short *)(yofs + dst_rows);\n"
"__global const short * ibeta = ialpha + ((dst_cols + dy) << 1);\n"
"ialpha += dx << 1;\n"
"int sx0 = xofs[dx], sy0 = clamp(yofs[dy], 0, src_rows - 1),\n"
"sy1 = clamp(yofs[dy] + 1, 0, src_rows - 1);\n"
"short a0 = ialpha[0], a1 = ialpha[1];\n"
"short b0 = ibeta[0], b1 = ibeta[1];\n"
"int src_index0 = mad24(sy0, src_step, mad24(sx0, TSIZE, src_offset)),\n"
"src_index1 = mad24(sy1, src_step, mad24(sx0, TSIZE, src_offset));\n"
"WT data0 = convertToWT(loadpix(srcptr + src_index0));\n"
"WT data1 = convertToWT(loadpix(srcptr + src_index0 + TSIZE));\n"
"WT data2 = convertToWT(loadpix(srcptr + src_index1));\n"
"WT data3 = convertToWT(loadpix(srcptr + src_index1 + TSIZE));\n"
"WT val = ( (((data0 * a0 + data1 * a1) >> 4) * b0) >> 16) +\n"
"( (((data2 * a0 + data3 * a1) >> 4) * b1) >> 16);\n"
"storepix(convertToDT((val + 2) >> 2),\n"
"dstptr + mad24(dy, dst_step, mad24(dx, TSIZE, dst_offset)));\n"
"}\n"
"}\n"
"#elif defined INTER_LINEAR\n"
"__kernel void resizeLN(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"float ifx, float ify)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"if (dx < dst_cols && dy < dst_rows)\n"
"{\n"
"float sx = ((dx+0.5f) * ifx - 0.5f), sy = ((dy+0.5f) * ify - 0.5f);\n"
"int x = floor(sx), y = floor(sy);\n"
"float u = sx - x, v = sy - y;\n"
"if ( x<0 ) x=0,u=0;\n"
"if ( x>=src_cols ) x=src_cols-1,u=0;\n"
"if ( y<0 ) y=0,v=0;\n"
"if ( y>=src_rows ) y=src_rows-1,v=0;\n"
"int y_ = INC(y, src_rows);\n"
"int x_ = INC(x, src_cols);\n"
"#if depth <= 4\n"
"u = u * INTER_RESIZE_COEF_SCALE;\n"
"v = v * INTER_RESIZE_COEF_SCALE;\n"
"int U = rint(u);\n"
"int V = rint(v);\n"
"int U1 = rint(INTER_RESIZE_COEF_SCALE - u);\n"
"int V1 = rint(INTER_RESIZE_COEF_SCALE - v);\n"
"WT data0 = convertToWT(loadpix(srcptr + mad24(y, src_step, mad24(x, TSIZE, src_offset))));\n"
"WT data1 = convertToWT(loadpix(srcptr + mad24(y, src_step, mad24(x_, TSIZE, src_offset))));\n"
"WT data2 = convertToWT(loadpix(srcptr + mad24(y_, src_step, mad24(x, TSIZE, src_offset))));\n"
"WT data3 = convertToWT(loadpix(srcptr + mad24(y_, src_step, mad24(x_, TSIZE, src_offset))));\n"
"WT val = mul24((WT)mul24(U1, V1), data0) + mul24((WT)mul24(U, V1), data1) +\n"
"mul24((WT)mul24(U1, V), data2) + mul24((WT)mul24(U, V), data3);\n"
"T uval = convertToDT((val + (1<<(CAST_BITS-1)))>>CAST_BITS);\n"
"#else\n"
"float u1 = 1.f - u;\n"
"float v1 = 1.f - v;\n"
"WT data0 = convertToWT(loadpix(srcptr + mad24(y, src_step, mad24(x, TSIZE, src_offset))));\n"
"WT data1 = convertToWT(loadpix(srcptr + mad24(y, src_step, mad24(x_, TSIZE, src_offset))));\n"
"WT data2 = convertToWT(loadpix(srcptr + mad24(y_, src_step, mad24(x, TSIZE, src_offset))));\n"
"WT data3 = convertToWT(loadpix(srcptr + mad24(y_, src_step, mad24(x_, TSIZE, src_offset))));\n"
"T uval = u1 * v1 * data0 + u * v1 * data1 + u1 * v *data2 + u * v *data3;\n"
"#endif\n"
"storepix(uval, dstptr + mad24(dy, dst_step, mad24(dx, TSIZE, dst_offset)));\n"
"}\n"
"}\n"
"#elif defined INTER_NEAREST\n"
"__kernel void resizeNN(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"float ifx, float ify)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"if (dx < dst_cols && dy < dst_rows)\n"
"{\n"
"float s1 = dx * ifx;\n"
"float s2 = dy * ify;\n"
"int sx = min(convert_int_rtz(s1), src_cols - 1);\n"
"int sy = min(convert_int_rtz(s2), src_rows - 1);\n"
"storepix(loadpix(srcptr + mad24(sy, src_step, mad24(sx, TSIZE, src_offset))),\n"
"dstptr + mad24(dy, dst_step, mad24(dx, TSIZE, dst_offset)));\n"
"}\n"
"}\n"
"#elif defined INTER_AREA\n"
"#ifdef INTER_AREA_FAST\n"
"__kernel void resizeAREA_FAST(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"if (dx < dst_cols && dy < dst_rows)\n"
"{\n"
"int dst_index = mad24(dy, dst_step, dst_offset);\n"
"int sx = XSCALE * dx;\n"
"int sy = YSCALE * dy;\n"
"WTV sum = (WTV)(0);\n"
"#pragma unroll\n"
"for (int py = 0; py < YSCALE; ++py)\n"
"{\n"
"int y = min(sy + py, src_rows - 1);\n"
"int src_index = mad24(y, src_step, src_offset);\n"
"#pragma unroll\n"
"for (int px = 0; px < XSCALE; ++px)\n"
"{\n"
"int x = min(sx + px, src_cols - 1);\n"
"sum += convertToWTV(loadpix(src + src_index + x*TSIZE));\n"
"}\n"
"}\n"
"storepix(convertToT(convertToWT2V(sum) * (WT2V)(SCALE)), dst + mad24(dx, TSIZE, dst_index));\n"
"}\n"
"}\n"
"#else\n"
"__kernel void resizeAREA(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"float ifx, float ify, __global const int * ofs_tab,\n"
"__global const int * map_tab, __global const float * alpha_tab)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"if (dx < dst_cols && dy < dst_rows)\n"
"{\n"
"int dst_index = mad24(dy, dst_step, dst_offset);\n"
"__global const int * xmap_tab = map_tab;\n"
"__global const int * ymap_tab = (__global const int *)(map_tab + (src_cols << 1));\n"
"__global const float * xalpha_tab = alpha_tab;\n"
"__global const float * yalpha_tab = (__global const float *)(alpha_tab + (src_cols << 1));\n"
"__global const int * xofs_tab = ofs_tab;\n"
"__global const int * yofs_tab = (__global const int *)(ofs_tab + dst_cols + 1);\n"
"int xk0 = xofs_tab[dx], xk1 = xofs_tab[dx + 1];\n"
"int yk0 = yofs_tab[dy], yk1 = yofs_tab[dy + 1];\n"
"int sy0 = ymap_tab[yk0], sy1 = ymap_tab[yk1 - 1];\n"
"int sx0 = xmap_tab[xk0], sx1 = xmap_tab[xk1 - 1];\n"
"WTV sum = (WTV)(0), buf;\n"
"int src_index = mad24(sy0, src_step, src_offset);\n"
"for (int sy = sy0, yk = yk0; sy <= sy1; ++sy, src_index += src_step, ++yk)\n"
"{\n"
"WTV beta = (WTV)(yalpha_tab[yk]);\n"
"buf = (WTV)(0);\n"
"for (int sx = sx0, xk = xk0; sx <= sx1; ++sx, ++xk)\n"
"{\n"
"WTV alpha = (WTV)(xalpha_tab[xk]);\n"
"buf += convertToWTV(loadpix(src + mad24(sx, TSIZE, src_index))) * alpha;\n"
"}\n"
"sum += buf * beta;\n"
"}\n"
"storepix(convertToT(sum), dst + mad24(dx, TSIZE, dst_index));\n"
"}\n"
"}\n"
"#endif\n"
"#endif\n"
, "3e1ea3c21fc70a7a9166d5cc66b7ff80", NULL};
struct cv::ocl::internal::ProgramEntry sepFilter3x3_oclsrc={moduleName, "sepFilter3x3",
"#define DIG(a) a,\n"
"__constant float kx[] = { KERNEL_MATRIX_X };\n"
"__constant float ky[] = { KERNEL_MATRIX_Y };\n"
"#define OP(delta, y, x) (convert_float16(arr[(y + delta) * 3 + x]) * ky[y] * kx[x])\n"
"__kernel void sepFilter3x3_8UC1_cols16_rows2(__global const uint* src, int src_step,\n"
"__global uint* dst, int dst_step,\n"
"int rows, int cols, float delta)\n"
"{\n"
"int block_x = get_global_id(0);\n"
"int y = get_global_id(1) * 2;\n"
"int ssx, dsx;\n"
"if ((block_x * 16) >= cols || y >= rows) return;\n"
"uint4 line[4];\n"
"uint4 line_out[2];\n"
"uchar a; uchar16 b; uchar c;\n"
"uchar d; uchar16 e; uchar f;\n"
"uchar g; uchar16 h; uchar i;\n"
"uchar j; uchar16 k; uchar l;\n"
"ssx = dsx = 1;\n"
"int src_index = block_x * 4 * ssx + (y - 1) * (src_step / 4);\n"
"line[1] = vload4(0, src + src_index + (src_step / 4));\n"
"line[2] = vload4(0, src + src_index + 2 * (src_step / 4));\n"
"#ifdef BORDER_CONSTANT\n"
"line[0] = (y == 0) ? (uint4)0 : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? (uint4)0 : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#elif defined BORDER_REFLECT_101\n"
"line[0] = (y == 0) ? line[2] : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? line[1] : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#elif defined (BORDER_REPLICATE) || defined(BORDER_REFLECT)\n"
"line[0] = (y == 0) ? line[1] : vload4(0, src + src_index);\n"
"line[3] = (y == (rows - 2)) ? line[2] : vload4(0, src + src_index + 3 * (src_step / 4));\n"
"#endif\n"
"__global uchar *src_p = (__global uchar *)src;\n"
"src_index = block_x * 16 * ssx + (y - 1) * src_step;\n"
"bool line_end = ((block_x + 1) * 16 == cols);\n"
"b = as_uchar16(line[0]);\n"
"e = as_uchar16(line[1]);\n"
"h = as_uchar16(line[2]);\n"
"k = as_uchar16(line[3]);\n"
"#ifdef BORDER_CONSTANT\n"
"a = (block_x == 0 || y == 0) ? 0 : src_p[src_index - 1];\n"
"c = (line_end || y == 0) ? 0 : src_p[src_index + 16];\n"
"d = (block_x == 0) ? 0 : src_p[src_index + src_step - 1];\n"
"f = line_end ? 0 : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? 0 : src_p[src_index + 2 * src_step - 1];\n"
"i = line_end ? 0 : src_p[src_index + 2 * src_step + 16];\n"
"j = (block_x == 0 || y == (rows - 2)) ? 0 : src_p[src_index + 3 * src_step - 1];\n"
"l = (line_end || y == (rows - 2))? 0 : src_p[src_index + 3 * src_step + 16];\n"
"#elif defined BORDER_REFLECT_101\n"
"int offset;\n"
"offset = (y == 0) ? (2 * src_step) : 0;\n"
"a = (block_x == 0) ? src_p[src_index + offset + 1] : src_p[src_index + offset - 1];\n"
"c = line_end ? src_p[src_index + offset + 14] : src_p[src_index + offset + 16];\n"
"d = (block_x == 0) ? src_p[src_index + src_step + 1] : src_p[src_index + src_step - 1];\n"
"f = line_end ? src_p[src_index + src_step + 14] : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? src_p[src_index + 2 * src_step + 1] : src_p[src_index + 2 * src_step - 1];\n"
"i = line_end ? src_p[src_index + 2 * src_step + 14] : src_p[src_index + 2 * src_step + 16];\n"
"offset = (y == (rows - 2)) ? (1 * src_step) : (3 * src_step);\n"
"j = (block_x == 0) ? src_p[src_index + offset + 1] : src_p[src_index + offset - 1];\n"
"l = line_end ? src_p[src_index + offset + 14] : src_p[src_index + offset + 16];\n"
"#elif defined (BORDER_REPLICATE) || defined(BORDER_REFLECT)\n"
"int offset;\n"
"offset = (y == 0) ? (1 * src_step) : 0;\n"
"a = (block_x == 0) ? src_p[src_index + offset] : src_p[src_index + offset - 1];\n"
"c = line_end ? src_p[src_index + offset + 15] : src_p[src_index + offset + 16];\n"
"d = (block_x == 0) ? src_p[src_index + src_step] : src_p[src_index + src_step - 1];\n"
"f = line_end ? src_p[src_index + src_step + 15] : src_p[src_index + src_step + 16];\n"
"g = (block_x == 0) ? src_p[src_index + 2 * src_step] : src_p[src_index + 2 * src_step - 1];\n"
"i = line_end ? src_p[src_index + 2 * src_step + 15] : src_p[src_index + 2 * src_step + 16];\n"
"offset = (y == (rows - 2)) ? (2 * src_step) : (3 * src_step);\n"
"j = (block_x == 0) ? src_p[src_index + offset] : src_p[src_index + offset - 1];\n"
"l = line_end ? src_p[src_index + offset + 15] : src_p[src_index + offset + 16];\n"
"#endif\n"
"uchar16 arr[12];\n"
"float16 sum[2];\n"
"arr[0] = (uchar16)(a, b.s0123, b.s456789ab, b.scde);\n"
"arr[1] = b;\n"
"arr[2] = (uchar16)(b.s123, b.s4567, b.s89abcdef, c);\n"
"arr[3] = (uchar16)(d, e.s0123, e.s456789ab, e.scde);\n"
"arr[4] = e;\n"
"arr[5] = (uchar16)(e.s123, e.s4567, e.s89abcdef, f);\n"
"arr[6] = (uchar16)(g, h.s0123, h.s456789ab, h.scde);\n"
"arr[7] = h;\n"
"arr[8] = (uchar16)(h.s123, h.s4567, h.s89abcdef, i);\n"
"arr[9] = (uchar16)(j, k.s0123, k.s456789ab, k.scde);\n"
"arr[10] = k;\n"
"arr[11] = (uchar16)(k.s123, k.s4567, k.s89abcdef, l);\n"
"sum[0] = OP(0, 0, 0) + OP(0, 0, 1) + OP(0, 0, 2) +\n"
"OP(0, 1, 0) + OP(0, 1, 1) + OP(0, 1, 2) +\n"
"OP(0, 2, 0) + OP(0, 2, 1) + OP(0, 2, 2);\n"
"sum[1] = OP(1, 0, 0) + OP(1, 0, 1) + OP(1, 0, 2) +\n"
"OP(1, 1, 0) + OP(1, 1, 1) + OP(1, 1, 2) +\n"
"OP(1, 2, 0) + OP(1, 2, 1) + OP(1, 2, 2);\n"
"line_out[0] = as_uint4(convert_uchar16_sat_rte(sum[0] + delta));\n"
"line_out[1] = as_uint4(convert_uchar16_sat_rte(sum[1] + delta));\n"
"int dst_index = block_x * 4 * dsx + y * (dst_step / 4);\n"
"vstore4(line_out[0], 0, dst + dst_index);\n"
"vstore4(line_out[1], 0, dst + dst_index + (dst_step / 4));\n"
"}\n"
, "a8fb0c872c2ccd041ab86148ae012c62", NULL};
struct cv::ocl::internal::ProgramEntry threshold_oclsrc={moduleName, "threshold",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"__kernel void threshold(__global const uchar * srcptr, int src_step, int src_offset,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int rows, int cols,\n"
"T1 thresh, T1 max_val, T1 min_val)\n"
"{\n"
"int gx = get_global_id(0);\n"
"int gy = get_global_id(1) * STRIDE_SIZE;\n"
"if (gx < cols)\n"
"{\n"
"int src_index = mad24(gy, src_step, mad24(gx, (int)sizeof(T), src_offset));\n"
"int dst_index = mad24(gy, dst_step, mad24(gx, (int)sizeof(T), dst_offset));\n"
"#pragma unroll\n"
"for (int i = 0; i < STRIDE_SIZE; i++)\n"
"{\n"
"if (gy < rows)\n"
"{\n"
"T sdata = *(__global const T *)(srcptr + src_index);\n"
"__global T * dst = (__global T *)(dstptr + dst_index);\n"
"#ifdef THRESH_BINARY\n"
"dst[0] = sdata > (thresh) ? (T)(max_val) : (T)(0);\n"
"#elif defined THRESH_BINARY_INV\n"
"dst[0] = sdata > (thresh) ? (T)(0) : (T)(max_val);\n"
"#elif defined THRESH_TRUNC\n"
"dst[0] = clamp(sdata, (T)min_val, (T)(thresh));\n"
"#elif defined THRESH_TOZERO\n"
"dst[0] = sdata > (thresh) ? sdata : (T)(0);\n"
"#elif defined THRESH_TOZERO_INV\n"
"dst[0] = sdata > (thresh) ? (T)(0) : sdata;\n"
"#endif\n"
"gy++;\n"
"src_index += src_step;\n"
"dst_index += dst_step;\n"
"}\n"
"}\n"
"}\n"
"}\n"
, "f464151682565a20de380a62e09ae458", NULL};
struct cv::ocl::internal::ProgramEntry warp_affine_oclsrc={moduleName, "warp_affine",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#define INTER_BITS 5\n"
"#define INTER_TAB_SIZE (1 << INTER_BITS)\n"
"#define INTER_SCALE 1.f/INTER_TAB_SIZE\n"
"#define AB_BITS max(10, (int)INTER_BITS)\n"
"#define AB_SCALE (1 << AB_BITS)\n"
"#define INTER_REMAP_COEF_BITS 15\n"
"#define INTER_REMAP_COEF_SCALE (1 << INTER_REMAP_COEF_BITS)\n"
"#define ROUND_DELTA (1 << (AB_BITS - INTER_BITS - 1))\n"
"#define noconvert\n"
"#ifndef ST\n"
"#define ST T\n"
"#endif\n"
"#if cn != 3\n"
"#define loadpix(addr)  *(__global const T*)(addr)\n"
"#define storepix(val, addr)  *(__global T*)(addr) = val\n"
"#define scalar scalar_\n"
"#define pixsize (int)sizeof(T)\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const T1*)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global T1*)(addr))\n"
"#ifdef INTER_NEAREST\n"
"#define scalar (T)(scalar_.x, scalar_.y, scalar_.z)\n"
"#else\n"
"#define scalar (WT)(scalar_.x, scalar_.y, scalar_.z)\n"
"#endif\n"
"#define pixsize ((int)sizeof(T1)*3)\n"
"#endif\n"
"#ifdef INTER_NEAREST\n"
"__kernel void warpAffine(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant CT * M, ST scalar_)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy0 = get_global_id(1) * rowsPerWI;\n"
"if (dx < dst_cols)\n"
"{\n"
"int round_delta = (AB_SCALE >> 1);\n"
"int X0_ = rint(M[0] * dx * AB_SCALE);\n"
"int Y0_ = rint(M[3] * dx * AB_SCALE);\n"
"int dst_index = mad24(dy0, dst_step, mad24(dx, pixsize, dst_offset));\n"
"for (int dy = dy0, dy1 = min(dst_rows, dy0 + rowsPerWI); dy < dy1; ++dy, dst_index += dst_step)\n"
"{\n"
"int X0 = X0_ + rint(fma(M[1], (CT)dy, M[2]) * AB_SCALE) + round_delta;\n"
"int Y0 = Y0_ + rint(fma(M[4], (CT)dy, M[5]) * AB_SCALE) + round_delta;\n"
"short sx = convert_short_sat(X0 >> AB_BITS);\n"
"short sy = convert_short_sat(Y0 >> AB_BITS);\n"
"if (sx >= 0 && sx < src_cols && sy >= 0 && sy < src_rows)\n"
"{\n"
"int src_index = mad24(sy, src_step, mad24(sx, pixsize, src_offset));\n"
"storepix(loadpix(srcptr + src_index), dstptr + dst_index);\n"
"}\n"
"else\n"
"storepix(scalar, dstptr + dst_index);\n"
"}\n"
"}\n"
"}\n"
"#elif defined INTER_LINEAR\n"
"__constant float coeffs[64] =\n"
"{ 1.000000f, 0.000000f, 0.968750f, 0.031250f, 0.937500f, 0.062500f, 0.906250f, 0.093750f, 0.875000f, 0.125000f, 0.843750f, 0.156250f,\n"
"0.812500f, 0.187500f, 0.781250f, 0.218750f, 0.750000f, 0.250000f, 0.718750f, 0.281250f, 0.687500f, 0.312500f, 0.656250f, 0.343750f,\n"
"0.625000f, 0.375000f, 0.593750f, 0.406250f, 0.562500f, 0.437500f, 0.531250f, 0.468750f, 0.500000f, 0.500000f, 0.468750f, 0.531250f,\n"
"0.437500f, 0.562500f, 0.406250f, 0.593750f, 0.375000f, 0.625000f, 0.343750f, 0.656250f, 0.312500f, 0.687500f, 0.281250f, 0.718750f,\n"
"0.250000f, 0.750000f, 0.218750f, 0.781250f, 0.187500f, 0.812500f, 0.156250f, 0.843750f, 0.125000f, 0.875000f, 0.093750f, 0.906250f,\n"
"0.062500f, 0.937500f, 0.031250f, 0.968750f };\n"
"__kernel void warpAffine(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant CT * M, ST scalar_)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy0 = get_global_id(1) * rowsPerWI;\n"
"if (dx < dst_cols)\n"
"{\n"
"int tmp = dx << AB_BITS;\n"
"int X0_ = rint(M[0] * tmp);\n"
"int Y0_ = rint(M[3] * tmp);\n"
"for (int dy = dy0, dy1 = min(dst_rows, dy0 + rowsPerWI); dy < dy1; ++dy)\n"
"{\n"
"int X0 = X0_ + rint(fma(M[1], (CT)dy, M[2]) * AB_SCALE) + ROUND_DELTA;\n"
"int Y0 = Y0_ + rint(fma(M[4], (CT)dy, M[5]) * AB_SCALE) + ROUND_DELTA;\n"
"X0 = X0 >> (AB_BITS - INTER_BITS);\n"
"Y0 = Y0 >> (AB_BITS - INTER_BITS);\n"
"short sx = convert_short_sat(X0 >> INTER_BITS), sy = convert_short_sat(Y0 >> INTER_BITS);\n"
"short ax = convert_short(X0 & (INTER_TAB_SIZE-1)), ay = convert_short(Y0 & (INTER_TAB_SIZE-1));\n"
"#if defined AMD_DEVICE || depth > 4\n"
"WT v0 = scalar, v1 = scalar, v2 = scalar, v3 = scalar;\n"
"if (sx >= 0 && sx < src_cols)\n"
"{\n"
"if (sy >= 0 && sy < src_rows)\n"
"v0 = convertToWT(loadpix(srcptr + mad24(sy, src_step, mad24(sx, pixsize, src_offset))));\n"
"if (sy+1 >= 0 && sy+1 < src_rows)\n"
"v2 = convertToWT(loadpix(srcptr + mad24(sy+1, src_step, mad24(sx, pixsize, src_offset))));\n"
"}\n"
"if (sx+1 >= 0 && sx+1 < src_cols)\n"
"{\n"
"if (sy >= 0 && sy < src_rows)\n"
"v1 = convertToWT(loadpix(srcptr + mad24(sy, src_step, mad24(sx+1, pixsize, src_offset))));\n"
"if (sy+1 >= 0 && sy+1 < src_rows)\n"
"v3 = convertToWT(loadpix(srcptr + mad24(sy+1, src_step, mad24(sx+1, pixsize, src_offset))));\n"
"}\n"
"float taby = 1.f/INTER_TAB_SIZE*ay;\n"
"float tabx = 1.f/INTER_TAB_SIZE*ax;\n"
"int dst_index = mad24(dy, dst_step, mad24(dx, pixsize, dst_offset));\n"
"#if depth <= 4\n"
"int itab0 = convert_short_sat_rte( (1.0f-taby)*(1.0f-tabx) * INTER_REMAP_COEF_SCALE );\n"
"int itab1 = convert_short_sat_rte( (1.0f-taby)*tabx * INTER_REMAP_COEF_SCALE );\n"
"int itab2 = convert_short_sat_rte( taby*(1.0f-tabx) * INTER_REMAP_COEF_SCALE );\n"
"int itab3 = convert_short_sat_rte( taby*tabx * INTER_REMAP_COEF_SCALE );\n"
"WT val = mad24(v0, itab0, mad24(v1, itab1, mad24(v2, itab2, v3 * itab3)));\n"
"storepix(convertToT((val + (1 << (INTER_REMAP_COEF_BITS-1))) >> INTER_REMAP_COEF_BITS), dstptr + dst_index);\n"
"#else\n"
"float tabx2 = 1.0f - tabx, taby2 = 1.0f - taby;\n"
"WT val = fma(tabx2, fma(v0, taby2, v2 * taby), tabx * fma(v1, taby2, v3 * taby));\n"
"storepix(convertToT(val), dstptr + dst_index);\n"
"#endif\n"
"#else\n"
"__constant float * coeffs_y = coeffs + (ay << 1), * coeffs_x = coeffs + (ax << 1);\n"
"int src_index0 = mad24(sy, src_step, mad24(sx, pixsize, src_offset)), src_index;\n"
"int dst_index = mad24(dy, dst_step, mad24(dx, pixsize, dst_offset));\n"
"WT sum = (WT)(0), xsum;\n"
"#pragma unroll\n"
"for (int y = 0; y < 2; y++)\n"
"{\n"
"src_index = mad24(y, src_step, src_index0);\n"
"if (sy + y >= 0 && sy + y < src_rows)\n"
"{\n"
"xsum = (WT)(0);\n"
"if (sx >= 0 && sx + 2 < src_cols)\n"
"{\n"
"#if depth == 0 && cn == 1\n"
"uchar2 value = vload2(0, srcptr + src_index);\n"
"xsum = dot(convert_float2(value), (float2)(coeffs_x[0], coeffs_x[1]));\n"
"#else\n"
"#pragma unroll\n"
"for (int x = 0; x < 2; x++)\n"
"xsum = fma(convertToWT(loadpix(srcptr + mad24(x, pixsize, src_index))), coeffs_x[x], xsum);\n"
"#endif\n"
"}\n"
"else\n"
"{\n"
"#pragma unroll\n"
"for (int x = 0; x < 2; x++)\n"
"xsum = fma(sx + x >= 0 && sx + x < src_cols ?\n"
"convertToWT(loadpix(srcptr + mad24(x, pixsize, src_index))) : scalar, coeffs_x[x], xsum);\n"
"}\n"
"sum = fma(xsum, coeffs_y[y], sum);\n"
"}\n"
"else\n"
"sum = fma(scalar, coeffs_y[y], sum);\n"
"}\n"
"storepix(convertToT(sum), dstptr + dst_index);\n"
"#endif\n"
"}\n"
"}\n"
"}\n"
"#elif defined INTER_CUBIC\n"
"#ifdef AMD_DEVICE\n"
"inline void interpolateCubic( float x, float* coeffs )\n"
"{\n"
"const float A = -0.75f;\n"
"coeffs[0] = fma(fma(fma(A, (x + 1.f), - 5.0f*A), (x + 1.f), 8.0f*A), x + 1.f, - 4.0f*A);\n"
"coeffs[1] = fma(fma(A + 2.f, x, - (A + 3.f)), x*x, 1.f);\n"
"coeffs[2] = fma(fma(A + 2.f, 1.f - x, - (A + 3.f)), (1.f - x)*(1.f - x), 1.f);\n"
"coeffs[3] = 1.f - coeffs[0] - coeffs[1] - coeffs[2];\n"
"}\n"
"#else\n"
"__constant float coeffs[128] =\n"
"{ 0.000000f, 1.000000f, 0.000000f, 0.000000f, -0.021996f, 0.997841f, 0.024864f, -0.000710f, -0.041199f, 0.991516f, 0.052429f, -0.002747f,\n"
"-0.057747f, 0.981255f, 0.082466f, -0.005974f, -0.071777f, 0.967285f, 0.114746f, -0.010254f, -0.083427f, 0.949837f, 0.149040f, -0.015450f,\n"
"-0.092834f, 0.929138f, 0.185120f, -0.021423f, -0.100136f, 0.905418f, 0.222755f, -0.028038f, -0.105469f, 0.878906f, 0.261719f, -0.035156f,\n"
"-0.108971f, 0.849831f, 0.301781f, -0.042641f, -0.110779f, 0.818420f, 0.342712f, -0.050354f, -0.111031f, 0.784904f, 0.384285f, -0.058159f,\n"
"-0.109863f, 0.749512f, 0.426270f, -0.065918f, -0.107414f, 0.712471f, 0.468437f, -0.073494f, -0.103821f, 0.674011f, 0.510559f, -0.080750f,\n"
"-0.099220f, 0.634361f, 0.552406f, -0.087547f, -0.093750f, 0.593750f, 0.593750f, -0.093750f, -0.087547f, 0.552406f, 0.634361f, -0.099220f,\n"
"-0.080750f, 0.510559f, 0.674011f, -0.103821f, -0.073494f, 0.468437f, 0.712471f, -0.107414f, -0.065918f, 0.426270f, 0.749512f, -0.109863f,\n"
"-0.058159f, 0.384285f, 0.784904f, -0.111031f, -0.050354f, 0.342712f, 0.818420f, -0.110779f, -0.042641f, 0.301781f, 0.849831f, -0.108971f,\n"
"-0.035156f, 0.261719f, 0.878906f, -0.105469f, -0.028038f, 0.222755f, 0.905418f, -0.100136f, -0.021423f, 0.185120f, 0.929138f, -0.092834f,\n"
"-0.015450f, 0.149040f, 0.949837f, -0.083427f, -0.010254f, 0.114746f, 0.967285f, -0.071777f, -0.005974f, 0.082466f, 0.981255f, -0.057747f,\n"
"-0.002747f, 0.052429f, 0.991516f, -0.041199f, -0.000710f, 0.024864f, 0.997841f, -0.021996f };\n"
"#endif\n"
"__kernel void warpAffine(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant CT * M, ST scalar_)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"if (dx < dst_cols && dy < dst_rows)\n"
"{\n"
"int tmp = (dx << AB_BITS);\n"
"int X0 = rint(M[0] * tmp) + rint(fma(M[1], (CT)dy, M[2]) * AB_SCALE) + ROUND_DELTA;\n"
"int Y0 = rint(M[3] * tmp) + rint(fma(M[4], (CT)dy, M[5]) * AB_SCALE) + ROUND_DELTA;\n"
"X0 = X0 >> (AB_BITS - INTER_BITS);\n"
"Y0 = Y0 >> (AB_BITS - INTER_BITS);\n"
"int sx = (short)(X0 >> INTER_BITS) - 1, sy = (short)(Y0 >> INTER_BITS) - 1;\n"
"int ay = (short)(Y0 & (INTER_TAB_SIZE - 1)), ax = (short)(X0 & (INTER_TAB_SIZE - 1));\n"
"#ifdef AMD_DEVICE\n"
"WT v[16];\n"
"#pragma unroll\n"
"for (int y = 0; y < 4; y++)\n"
"{\n"
"if (sy+y >= 0 && sy+y < src_rows)\n"
"{\n"
"#pragma unroll\n"
"for (int x = 0; x < 4; x++)\n"
"v[mad24(y, 4, x)] = sx+x >= 0 && sx+x < src_cols ?\n"
"convertToWT(loadpix(srcptr + mad24(sy+y, src_step, mad24(sx+x, pixsize, src_offset)))) : scalar;\n"
"}\n"
"else\n"
"{\n"
"#pragma unroll\n"
"for (int x = 0; x < 4; x++)\n"
"v[mad24(y, 4, x)] = scalar;\n"
"}\n"
"}\n"
"float tab1y[4], tab1x[4];\n"
"float ayy = INTER_SCALE * ay;\n"
"float axx = INTER_SCALE * ax;\n"
"interpolateCubic(ayy, tab1y);\n"
"interpolateCubic(axx, tab1x);\n"
"int dst_index = mad24(dy, dst_step, mad24(dx, pixsize, dst_offset));\n"
"WT sum = (WT)(0);\n"
"#if depth <= 4\n"
"int itab[16];\n"
"#pragma unroll\n"
"for (int i = 0; i < 16; i++)\n"
"itab[i] = rint(tab1y[(i>>2)] * tab1x[(i&3)] * INTER_REMAP_COEF_SCALE);\n"
"#pragma unroll\n"
"for (int i = 0; i < 16; i++)\n"
"sum = mad24(v[i], itab[i], sum);\n"
"storepix(convertToT( (sum + (1 << (INTER_REMAP_COEF_BITS-1))) >> INTER_REMAP_COEF_BITS ), dstptr + dst_index);\n"
"#else\n"
"#pragma unroll\n"
"for (int i = 0; i < 16; i++)\n"
"sum = fma(v[i], tab1y[(i>>2)] * tab1x[(i&3)], sum);\n"
"storepix(convertToT( sum ), dstptr + dst_index);\n"
"#endif\n"
"#else\n"
"__constant float * coeffs_y = coeffs + (ay << 2), * coeffs_x = coeffs + (ax << 2);\n"
"int src_index0 = mad24(sy, src_step, mad24(sx, pixsize, src_offset)), src_index;\n"
"int dst_index = mad24(dy, dst_step, mad24(dx, pixsize, dst_offset));\n"
"WT sum = (WT)(0), xsum;\n"
"#pragma unroll\n"
"for (int y = 0; y < 4; y++)\n"
"{\n"
"src_index = mad24(y, src_step, src_index0);\n"
"if (sy + y >= 0 && sy + y < src_rows)\n"
"{\n"
"xsum = (WT)(0);\n"
"if (sx >= 0 && sx + 4 < src_cols)\n"
"{\n"
"#if depth == 0 && cn == 1\n"
"uchar4 value = vload4(0, srcptr + src_index);\n"
"xsum = dot(convert_float4(value), (float4)(coeffs_x[0], coeffs_x[1], coeffs_x[2], coeffs_x[3]));\n"
"#else\n"
"#pragma unroll\n"
"for (int x = 0; x < 4; x++)\n"
"xsum = fma(convertToWT(loadpix(srcptr + mad24(x, pixsize, src_index))), coeffs_x[x], xsum);\n"
"#endif\n"
"}\n"
"else\n"
"{\n"
"#pragma unroll\n"
"for (int x = 0; x < 4; x++)\n"
"xsum = fma(sx + x >= 0 && sx + x < src_cols ?\n"
"convertToWT(loadpix(srcptr + mad24(x, pixsize, src_index))) : scalar, coeffs_x[x], xsum);\n"
"}\n"
"sum = fma(xsum, coeffs_y[y], sum);\n"
"}\n"
"else\n"
"sum = fma(scalar, coeffs_y[y], sum);\n"
"}\n"
"storepix(convertToT(sum), dstptr + dst_index);\n"
"#endif\n"
"}\n"
"}\n"
"#endif\n"
, "ad75e82949ec363a8853f25adb4b808e", NULL};
struct cv::ocl::internal::ProgramEntry warp_perspective_oclsrc={moduleName, "warp_perspective",
"#ifdef DOUBLE_SUPPORT\n"
"#ifdef cl_amd_fp64\n"
"#pragma OPENCL EXTENSION cl_amd_fp64:enable\n"
"#elif defined (cl_khr_fp64)\n"
"#pragma OPENCL EXTENSION cl_khr_fp64:enable\n"
"#endif\n"
"#endif\n"
"#define INTER_BITS 5\n"
"#define INTER_TAB_SIZE (1 << INTER_BITS)\n"
"#define INTER_SCALE 1.f / INTER_TAB_SIZE\n"
"#define AB_BITS max(10, (int)INTER_BITS)\n"
"#define AB_SCALE (1 << AB_BITS)\n"
"#define INTER_REMAP_COEF_BITS 15\n"
"#define INTER_REMAP_COEF_SCALE (1 << INTER_REMAP_COEF_BITS)\n"
"#define noconvert\n"
"#ifndef ST\n"
"#define ST T\n"
"#endif\n"
"#if cn != 3\n"
"#define loadpix(addr)  *(__global const T*)(addr)\n"
"#define storepix(val, addr)  *(__global T*)(addr) = val\n"
"#define scalar scalar_\n"
"#define pixsize (int)sizeof(T)\n"
"#else\n"
"#define loadpix(addr)  vload3(0, (__global const T1*)(addr))\n"
"#define storepix(val, addr) vstore3(val, 0, (__global T1*)(addr))\n"
"#ifdef INTER_NEAREST\n"
"#define scalar (T)(scalar_.x, scalar_.y, scalar_.z)\n"
"#else\n"
"#define scalar (WT)(scalar_.x, scalar_.y, scalar_.z)\n"
"#endif\n"
"#define pixsize ((int)sizeof(T1)*3)\n"
"#endif\n"
"#ifdef INTER_NEAREST\n"
"__kernel void warpPerspective(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant CT * M, ST scalar_)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"if (dx < dst_cols && dy < dst_rows)\n"
"{\n"
"CT X0 = M[0] * dx + M[1] * dy + M[2];\n"
"CT Y0 = M[3] * dx + M[4] * dy + M[5];\n"
"CT W = M[6] * dx + M[7] * dy + M[8];\n"
"W = W != 0.0f ? 1.f / W : 0.0f;\n"
"short sx = convert_short_sat_rte(X0*W);\n"
"short sy = convert_short_sat_rte(Y0*W);\n"
"int dst_index = mad24(dy, dst_step, dx * pixsize + dst_offset);\n"
"if (sx >= 0 && sx < src_cols && sy >= 0 && sy < src_rows)\n"
"{\n"
"int src_index = mad24(sy, src_step, sx * pixsize + src_offset);\n"
"storepix(loadpix(srcptr + src_index), dstptr + dst_index);\n"
"}\n"
"else\n"
"storepix(scalar, dstptr + dst_index);\n"
"}\n"
"}\n"
"#elif defined INTER_LINEAR\n"
"__kernel void warpPerspective(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant CT * M, ST scalar_)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"if (dx < dst_cols && dy < dst_rows)\n"
"{\n"
"CT X0 = M[0] * dx + M[1] * dy + M[2];\n"
"CT Y0 = M[3] * dx + M[4] * dy + M[5];\n"
"CT W = M[6] * dx + M[7] * dy + M[8];\n"
"W = W != 0.0f ? INTER_TAB_SIZE / W : 0.0f;\n"
"int X = rint(X0 * W), Y = rint(Y0 * W);\n"
"short sx = convert_short_sat(X >> INTER_BITS);\n"
"short sy = convert_short_sat(Y >> INTER_BITS);\n"
"short ay = (short)(Y & (INTER_TAB_SIZE - 1));\n"
"short ax = (short)(X & (INTER_TAB_SIZE - 1));\n"
"WT v0 = (sx >= 0 && sx < src_cols && sy >= 0 && sy < src_rows) ?\n"
"convertToWT(loadpix(srcptr + mad24(sy, src_step, src_offset + sx * pixsize))) : scalar;\n"
"WT v1 = (sx+1 >= 0 && sx+1 < src_cols && sy >= 0 && sy < src_rows) ?\n"
"convertToWT(loadpix(srcptr + mad24(sy, src_step, src_offset + (sx+1) * pixsize))) : scalar;\n"
"WT v2 = (sx >= 0 && sx < src_cols && sy+1 >= 0 && sy+1 < src_rows) ?\n"
"convertToWT(loadpix(srcptr + mad24(sy+1, src_step, src_offset + sx * pixsize))) : scalar;\n"
"WT v3 = (sx+1 >= 0 && sx+1 < src_cols && sy+1 >= 0 && sy+1 < src_rows) ?\n"
"convertToWT(loadpix(srcptr + mad24(sy+1, src_step, src_offset + (sx+1) * pixsize))) : scalar;\n"
"float taby = 1.f/INTER_TAB_SIZE*ay;\n"
"float tabx = 1.f/INTER_TAB_SIZE*ax;\n"
"int dst_index = mad24(dy, dst_step, dst_offset + dx * pixsize);\n"
"#if depth <= 4\n"
"int itab0 = convert_short_sat_rte( (1.0f-taby)*(1.0f-tabx) * INTER_REMAP_COEF_SCALE );\n"
"int itab1 = convert_short_sat_rte( (1.0f-taby)*tabx * INTER_REMAP_COEF_SCALE );\n"
"int itab2 = convert_short_sat_rte( taby*(1.0f-tabx) * INTER_REMAP_COEF_SCALE );\n"
"int itab3 = convert_short_sat_rte( taby*tabx * INTER_REMAP_COEF_SCALE );\n"
"WT val = v0 * itab0 +  v1 * itab1 + v2 * itab2 + v3 * itab3;\n"
"storepix(convertToT((val + (1 << (INTER_REMAP_COEF_BITS-1))) >> INTER_REMAP_COEF_BITS), dstptr + dst_index);\n"
"#else\n"
"float tabx2 = 1.0f - tabx, taby2 = 1.0f - taby;\n"
"WT val = v0 * tabx2 * taby2 +  v1 * tabx * taby2 + v2 * tabx2 * taby + v3 * tabx * taby;\n"
"storepix(convertToT(val), dstptr + dst_index);\n"
"#endif\n"
"}\n"
"}\n"
"#elif defined INTER_CUBIC\n"
"inline void interpolateCubic( float x, float* coeffs )\n"
"{\n"
"const float A = -0.75f;\n"
"coeffs[0] = ((A*(x + 1.f) - 5.0f*A)*(x + 1.f) + 8.0f*A)*(x + 1.f) - 4.0f*A;\n"
"coeffs[1] = ((A + 2.f)*x - (A + 3.f))*x*x + 1.f;\n"
"coeffs[2] = ((A + 2.f)*(1.f - x) - (A + 3.f))*(1.f - x)*(1.f - x) + 1.f;\n"
"coeffs[3] = 1.f - coeffs[0] - coeffs[1] - coeffs[2];\n"
"}\n"
"__kernel void warpPerspective(__global const uchar * srcptr, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dstptr, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant CT * M, ST scalar_)\n"
"{\n"
"int dx = get_global_id(0);\n"
"int dy = get_global_id(1);\n"
"if (dx < dst_cols && dy < dst_rows)\n"
"{\n"
"CT X0 = M[0] * dx + M[1] * dy + M[2];\n"
"CT Y0 = M[3] * dx + M[4] * dy + M[5];\n"
"CT W = M[6] * dx + M[7] * dy + M[8];\n"
"W = W != 0.0f ? INTER_TAB_SIZE / W : 0.0f;\n"
"int X = rint(X0 * W), Y = rint(Y0 * W);\n"
"short sx = convert_short_sat(X >> INTER_BITS) - 1;\n"
"short sy = convert_short_sat(Y >> INTER_BITS) - 1;\n"
"short ay = (short)(Y & (INTER_TAB_SIZE-1));\n"
"short ax = (short)(X & (INTER_TAB_SIZE-1));\n"
"WT v[16];\n"
"#pragma unroll\n"
"for (int y = 0; y < 4; y++)\n"
"#pragma unroll\n"
"for (int x = 0; x < 4; x++)\n"
"v[mad24(y, 4, x)] = (sx+x >= 0 && sx+x < src_cols && sy+y >= 0 && sy+y < src_rows) ?\n"
"convertToWT(loadpix(srcptr + mad24(sy+y, src_step, src_offset + (sx+x) * pixsize))) : scalar;\n"
"float tab1y[4], tab1x[4];\n"
"float ayy = INTER_SCALE * ay;\n"
"float axx = INTER_SCALE * ax;\n"
"interpolateCubic(ayy, tab1y);\n"
"interpolateCubic(axx, tab1x);\n"
"int dst_index = mad24(dy, dst_step, dst_offset + dx * pixsize);\n"
"WT sum = (WT)(0);\n"
"#if depth <= 4\n"
"int itab[16];\n"
"#pragma unroll\n"
"for (int i = 0; i < 16; i++)\n"
"itab[i] = rint(tab1y[(i>>2)] * tab1x[(i&3)] * INTER_REMAP_COEF_SCALE);\n"
"#pragma unroll\n"
"for (int i = 0; i < 16; i++)\n"
"sum += v[i] * itab[i];\n"
"storepix(convertToT( (sum + (1 << (INTER_REMAP_COEF_BITS-1))) >> INTER_REMAP_COEF_BITS ), dstptr + dst_index);\n"
"#else\n"
"#pragma unroll\n"
"for (int i = 0; i < 16; i++)\n"
"sum += v[i] * tab1y[(i>>2)] * tab1x[(i&3)];\n"
"storepix(convertToT( sum ), dstptr + dst_index);\n"
"#endif\n"
"}\n"
"}\n"
"#endif\n"
, "a369fbc4026cb59e20aead1fb3f896f0", NULL};
struct cv::ocl::internal::ProgramEntry warp_transform_oclsrc={moduleName, "warp_transform",
"__constant short4 vec_offset = (short4)(0, 1, 2, 3);\n"
"#define GET_VAL(x, y) ((x) < 0 || (x) >= src_cols || (y) < 0 || (y) >= src_rows) ? scalar : src[src_offset + y * src_step + x]\n"
"__kernel void warpAffine_nearest_8u(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant float * M, ST scalar_)\n"
"{\n"
"int x = get_global_id(0) * 4;\n"
"int y = get_global_id(1);\n"
"uchar scalar = convert_uchar_sat_rte(scalar_);\n"
"if (x >= dst_cols || y >= dst_rows) return;\n"
"short4 new_x, new_y;\n"
"new_x = convert_short4_sat_rte(M[0] * convert_float4(vec_offset + (short4)(x)) +\n"
"M[1] * convert_float4((short4)y) + M[2]);\n"
"new_y = convert_short4_sat_rte(M[3] * convert_float4(vec_offset + (short4)(x)) +\n"
"M[4] * convert_float4((short4)y) + M[5]);\n"
"uchar4 pix = (uchar4)scalar;\n"
"pix.s0 = GET_VAL(new_x.s0, new_y.s0);\n"
"pix.s1 = GET_VAL(new_x.s1, new_y.s1);\n"
"pix.s2 = GET_VAL(new_x.s2, new_y.s2);\n"
"pix.s3 = GET_VAL(new_x.s3, new_y.s3);\n"
"int dst_index = x + y * dst_step + dst_offset;\n"
"vstore4(pix, 0,  dst + dst_index);\n"
"}\n"
"uchar4 read_pixels(__global const uchar * src, short tx, short ty,\n"
"int src_offset, int src_step, int src_cols, int\n"
"src_rows, uchar scalar)\n"
"{\n"
"uchar2 pt, pb;\n"
"short bx, by;\n"
"bx = tx + 1;\n"
"by = ty + 1;\n"
"if (tx >= 0 && (tx + 1) < src_cols && ty >= 0 && ty < src_rows)\n"
"{\n"
"pt = vload2(0, src + src_offset + ty * src_step + tx);\n"
"}\n"
"else\n"
"{\n"
"pt.s0 = GET_VAL(tx, ty);\n"
"pt.s1 = GET_VAL(bx, ty);\n"
"}\n"
"if (tx >= 0 && (tx + 1) < src_cols && by >= 0 && by < src_rows)\n"
"{\n"
"pb = vload2(0, src + src_offset + by * src_step + tx);\n"
"}\n"
"else\n"
"{\n"
"pb.s0 = GET_VAL(tx, by);\n"
"pb.s1 = GET_VAL(bx, by);\n"
"}\n"
"return (uchar4)(pt, pb);\n"
"}\n"
"__kernel void warpAffine_linear_8u(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant float * M, ST scalar_)\n"
"{\n"
"int x = get_global_id(0) * 4;\n"
"int y = get_global_id(1);\n"
"uchar scalar = convert_uchar_sat_rte(scalar_);\n"
"if (x >= dst_cols || y >= dst_rows) return;\n"
"float4 nx, ny;\n"
"nx = M[0] * convert_float4((vec_offset + (short4)x)) + M[1] * convert_float4((short4)y) + M[2];\n"
"ny = M[3] * convert_float4((vec_offset + (short4)x)) + M[4] * convert_float4((short4)y) + M[5];\n"
"float4 s, t;\n"
"s = round((nx - floor(nx)) * 32.0f) / 32.0f;\n"
"t = round((ny - floor(ny)) * 32.0f) / 32.0f;\n"
"short4 tx, ty;\n"
"tx = convert_short4_sat_rtn(nx);\n"
"ty = convert_short4_sat_rtn(ny);\n"
"uchar4 pix[4];\n"
"pix[0] = read_pixels(src, tx.s0, ty.s0, src_offset, src_step, src_cols, src_rows, scalar);\n"
"pix[1] = read_pixels(src, tx.s1, ty.s1, src_offset, src_step, src_cols, src_rows, scalar);\n"
"pix[2] = read_pixels(src, tx.s2, ty.s2, src_offset, src_step, src_cols, src_rows, scalar);\n"
"pix[3] = read_pixels(src, tx.s3, ty.s3, src_offset, src_step, src_cols, src_rows, scalar);\n"
"float4 tl, tr, bl, br;\n"
"tl = convert_float4((uchar4)(pix[0].s0, pix[1].s0, pix[2].s0, pix[3].s0));\n"
"tr = convert_float4((uchar4)(pix[0].s1, pix[1].s1, pix[2].s1, pix[3].s1));\n"
"bl = convert_float4((uchar4)(pix[0].s2, pix[1].s2, pix[2].s2, pix[3].s2));\n"
"br = convert_float4((uchar4)(pix[0].s3, pix[1].s3, pix[2].s3, pix[3].s3));\n"
"float4 pixel;\n"
"pixel = tl * (1 - s) * (1 - t) + tr * s * (1 - t) + bl * (1 - s) * t + br * s * t;\n"
"int dst_index = x + y * dst_step + dst_offset;\n"
"vstore4(convert_uchar4_sat_rte(pixel), 0, dst + dst_index);\n"
"}\n"
"__constant float coeffs[128] =\n"
"{ 0.000000f, 1.000000f, 0.000000f, 0.000000f, -0.021996f, 0.997841f, 0.024864f, -0.000710f, -0.041199f, 0.991516f, 0.052429f, -0.002747f,\n"
"-0.057747f, 0.981255f, 0.082466f, -0.005974f, -0.071777f, 0.967285f, 0.114746f, -0.010254f, -0.083427f, 0.949837f, 0.149040f, -0.015450f,\n"
"-0.092834f, 0.929138f, 0.185120f, -0.021423f, -0.100136f, 0.905418f, 0.222755f, -0.028038f, -0.105469f, 0.878906f, 0.261719f, -0.035156f,\n"
"-0.108971f, 0.849831f, 0.301781f, -0.042641f, -0.110779f, 0.818420f, 0.342712f, -0.050354f, -0.111031f, 0.784904f, 0.384285f, -0.058159f,\n"
"-0.109863f, 0.749512f, 0.426270f, -0.065918f, -0.107414f, 0.712471f, 0.468437f, -0.073494f, -0.103821f, 0.674011f, 0.510559f, -0.080750f,\n"
"-0.099220f, 0.634361f, 0.552406f, -0.087547f, -0.093750f, 0.593750f, 0.593750f, -0.093750f, -0.087547f, 0.552406f, 0.634361f, -0.099220f,\n"
"-0.080750f, 0.510559f, 0.674011f, -0.103821f, -0.073494f, 0.468437f, 0.712471f, -0.107414f, -0.065918f, 0.426270f, 0.749512f, -0.109863f,\n"
"-0.058159f, 0.384285f, 0.784904f, -0.111031f, -0.050354f, 0.342712f, 0.818420f, -0.110779f, -0.042641f, 0.301781f, 0.849831f, -0.108971f,\n"
"-0.035156f, 0.261719f, 0.878906f, -0.105469f, -0.028038f, 0.222755f, 0.905418f, -0.100136f, -0.021423f, 0.185120f, 0.929138f, -0.092834f,\n"
"-0.015450f, 0.149040f, 0.949837f, -0.083427f, -0.010254f, 0.114746f, 0.967285f, -0.071777f, -0.005974f, 0.082466f, 0.981255f, -0.057747f,\n"
"-0.002747f, 0.052429f, 0.991516f, -0.041199f, -0.000710f, 0.024864f, 0.997841f, -0.021996f };\n"
"uchar4 read_pixels_cubic(__global const uchar * src, int tx, int ty,\n"
"int src_offset, int src_step, int src_cols, int src_rows, uchar scalar)\n"
"{\n"
"uchar4 pix;\n"
"if (tx >= 0 && (tx + 3) < src_cols && ty >= 0 && ty < src_rows)\n"
"{\n"
"pix = vload4(0, src + src_offset + ty * src_step + tx);\n"
"}\n"
"else\n"
"{\n"
"pix.s0 = GET_VAL((tx + 0), ty);\n"
"pix.s1 = GET_VAL((tx + 1), ty);\n"
"pix.s2 = GET_VAL((tx + 2), ty);\n"
"pix.s3 = GET_VAL((tx + 3), ty);\n"
"}\n"
"return pix;\n"
"}\n"
"__kernel void warpAffine_cubic_8u(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant float * M, ST scalar_)\n"
"{\n"
"int x = get_global_id(0) * 4;\n"
"int y = get_global_id(1);\n"
"uchar scalar = convert_uchar_sat_rte(scalar_);\n"
"if (x >= dst_cols || y >= dst_rows) return;\n"
"float4 nx, ny;\n"
"nx = M[0] * convert_float4((vec_offset + (short4)x)) + M[1] * convert_float4((short4)y) + M[2];\n"
"ny = M[3] * convert_float4((vec_offset + (short4)x)) + M[4] * convert_float4((short4)y) + M[5];\n"
"int4 ax, ay;\n"
"ax = convert_int4_sat_rte((nx - floor(nx)) * 32.0f) & 31;\n"
"ay = convert_int4_sat_rte((ny - floor(ny)) * 32.0f) & 31;\n"
"int4 tx, ty;\n"
"int4 delta_x, delta_y;\n"
"delta_x = select((int4)1, (int4)0, ((nx - floor(nx))) * 64 > 63);\n"
"delta_y = select((int4)1, (int4)0, ((ny - floor(ny))) * 64 > 63);\n"
"tx = convert_int4_sat_rtn(nx) - delta_x;\n"
"ty = convert_int4_sat_rtn(ny) - delta_y;\n"
"__constant float * coeffs_x, * coeffs_y;\n"
"float4 sum = (float4)0.0f;\n"
"uchar4 pix;\n"
"float xsum;\n"
"coeffs_x = coeffs + (ax.s0 << 2);\n"
"coeffs_y = coeffs + (ay.s0 << 2);\n"
"for (int i = 0; i < 4; i++)\n"
"{\n"
"pix = read_pixels_cubic(src, tx.s0, ty.s0 + i, src_offset, src_step, src_cols, src_rows, scalar);\n"
"xsum = dot(convert_float4(pix), (float4)(coeffs_x[0], coeffs_x[1], coeffs_x[2], coeffs_x[3]));\n"
"sum.s0 = fma(xsum, coeffs_y[i], sum.s0);\n"
"}\n"
"coeffs_x = coeffs + (ax.s1 << 2);\n"
"coeffs_y = coeffs + (ay.s1 << 2);\n"
"for (int i = 0; i < 4; i++)\n"
"{\n"
"pix = read_pixels_cubic(src, tx.s1, ty.s1 + i, src_offset, src_step, src_cols, src_rows, scalar);\n"
"xsum = dot(convert_float4(pix), (float4)(coeffs_x[0], coeffs_x[1], coeffs_x[2], coeffs_x[3]));\n"
"sum.s1 = fma(xsum, coeffs_y[i], sum.s1);\n"
"}\n"
"coeffs_x = coeffs + (ax.s2 << 2);\n"
"coeffs_y = coeffs + (ay.s2 << 2);\n"
"for (int i = 0; i < 4; i++)\n"
"{\n"
"pix = read_pixels_cubic(src, tx.s2, ty.s2 + i, src_offset, src_step, src_cols, src_rows, scalar);\n"
"xsum = dot(convert_float4(pix), (float4)(coeffs_x[0], coeffs_x[1], coeffs_x[2], coeffs_x[3]));\n"
"sum.s2 = fma(xsum, coeffs_y[i], sum.s2);\n"
"}\n"
"coeffs_x = coeffs + (ax.s3 << 2);\n"
"coeffs_y = coeffs + (ay.s3 << 2);\n"
"for (int i = 0; i < 4; i++)\n"
"{\n"
"pix = read_pixels_cubic(src, tx.s3, ty.s3 + i, src_offset, src_step, src_cols, src_rows, scalar);\n"
"xsum = dot(convert_float4(pix), (float4)(coeffs_x[0], coeffs_x[1], coeffs_x[2], coeffs_x[3]));\n"
"sum.s3 = fma(xsum, coeffs_y[i], sum.s3);\n"
"}\n"
"int dst_index = x + y * dst_step + dst_offset;\n"
"vstore4(convert_uchar4_sat_rte(sum), 0, dst + dst_index);\n"
"}\n"
"__kernel void warpPerspective_nearest_8u(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant float * M, ST scalar_)\n"
"{\n"
"int x = get_global_id(0) * 4;\n"
"int y = get_global_id(1);\n"
"uchar scalar = convert_uchar_sat_rte(scalar_);\n"
"if (x >= dst_cols || y >= dst_rows) return;\n"
"float4 nx, ny, nz;\n"
"nx = M[0] * convert_float4(vec_offset + (short4)(x)) +\n"
"M[1] * convert_float4((short4)y) + M[2];\n"
"ny = M[3] * convert_float4(vec_offset + (short4)(x)) +\n"
"M[4] * convert_float4((short4)y) + M[5];\n"
"nz = M[6] * convert_float4(vec_offset + (short4)(x)) +\n"
"M[7] * convert_float4((short4)y) + M[8];\n"
"short4 new_x, new_y;\n"
"float4 fz = select((float4)(0.0f), (float4)(1.0f / nz), nz != 0.0f);\n"
"new_x = convert_short4_sat_rte(nx * fz);\n"
"new_y = convert_short4_sat_rte(ny * fz);\n"
"uchar4 pix = (uchar4)scalar;\n"
"pix.s0 = GET_VAL(new_x.s0, new_y.s0);\n"
"pix.s1 = GET_VAL(new_x.s1, new_y.s1);\n"
"pix.s2 = GET_VAL(new_x.s2, new_y.s2);\n"
"pix.s3 = GET_VAL(new_x.s3, new_y.s3);\n"
"int dst_index = x + y * dst_step + dst_offset;\n"
"vstore4(pix, 0,  dst + dst_index);\n"
"}\n"
"__kernel void warpPerspective_linear_8u(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant float * M, ST scalar_)\n"
"{\n"
"int x = get_global_id(0) * 4;\n"
"int y = get_global_id(1);\n"
"uchar scalar = convert_uchar_sat_rte(scalar_);\n"
"if (x >= dst_cols || y >= dst_rows) return;\n"
"float4 nx, ny, nz;\n"
"nx = M[0] * convert_float4(vec_offset + (short4)(x)) + M[1] * convert_float4((short4)y) + M[2];\n"
"ny = M[3] * convert_float4(vec_offset + (short4)(x)) + M[4] * convert_float4((short4)y) + M[5];\n"
"nz = M[6] * convert_float4(vec_offset + (short4)(x)) + M[7] * convert_float4((short4)y) + M[8];\n"
"float4 fz = select((float4)(0.0f), (float4)(1.0f / nz), nz != 0.0f);\n"
"nx = nx * fz;\n"
"ny = ny * fz;\n"
"float4 s, t;\n"
"s = round((nx - floor(nx)) * 32.0f) / (float4)32.0f;\n"
"t = round((ny - floor(ny)) * 32.0f) / (float4)32.0f;\n"
"short4 tx, ty;\n"
"tx = convert_short4_sat_rtn(nx);\n"
"ty = convert_short4_sat_rtn(ny);\n"
"uchar4 pix[4];\n"
"pix[0] = read_pixels(src, tx.s0, ty.s0, src_offset, src_step, src_cols, src_rows, scalar);\n"
"pix[1] = read_pixels(src, tx.s1, ty.s1, src_offset, src_step, src_cols, src_rows, scalar);\n"
"pix[2] = read_pixels(src, tx.s2, ty.s2, src_offset, src_step, src_cols, src_rows, scalar);\n"
"pix[3] = read_pixels(src, tx.s3, ty.s3, src_offset, src_step, src_cols, src_rows, scalar);\n"
"float4 tl, tr, bl, br;\n"
"tl = convert_float4((uchar4)(pix[0].s0, pix[1].s0, pix[2].s0, pix[3].s0));\n"
"tr = convert_float4((uchar4)(pix[0].s1, pix[1].s1, pix[2].s1, pix[3].s1));\n"
"bl = convert_float4((uchar4)(pix[0].s2, pix[1].s2, pix[2].s2, pix[3].s2));\n"
"br = convert_float4((uchar4)(pix[0].s3, pix[1].s3, pix[2].s3, pix[3].s3));\n"
"float4 pixel;\n"
"pixel = tl * (1 - s) * (1 - t) + tr * s * (1 - t) + bl * (1 - s) * t + br * s * t;\n"
"int dst_index = x + y * dst_step + dst_offset;\n"
"vstore4(convert_uchar4_sat_rte(pixel), 0,  dst + dst_index);\n"
"}\n"
"__kernel void warpPerspective_cubic_8u(__global const uchar * src, int src_step, int src_offset, int src_rows, int src_cols,\n"
"__global uchar * dst, int dst_step, int dst_offset, int dst_rows, int dst_cols,\n"
"__constant float * M, ST scalar_)\n"
"{\n"
"int x = get_global_id(0) * 4;\n"
"int y = get_global_id(1);\n"
"uchar scalar = convert_uchar_sat_rte(scalar_);\n"
"if (x >= dst_cols || y >= dst_rows) return;\n"
"float4 nx, ny, nz;\n"
"nx = M[0] * convert_float4(vec_offset + (short4)(x)) + M[1] * convert_float4((short4)y) + M[2];\n"
"ny = M[3] * convert_float4(vec_offset + (short4)(x)) + M[4] * convert_float4((short4)y) + M[5];\n"
"nz = M[6] * convert_float4(vec_offset + (short4)(x)) + M[7] * convert_float4((short4)y) + M[8];\n"
"float4 fz = select((float4)(0.0f), (float4)(1.0f / nz), nz != 0.0f);\n"
"nx = nx * fz;\n"
"ny = ny * fz;\n"
"int4 ax, ay;\n"
"ax = convert_int4_sat_rte((nx - floor(nx)) * 32.0f) & 31;\n"
"ay = convert_int4_sat_rte((ny - floor(ny)) * 32.0f) & 31;\n"
"int4 tx, ty;\n"
"int4 delta_x, delta_y;\n"
"delta_x = select((int4)1, (int4)0, ((nx - floor(nx))) * 64 > 63);\n"
"delta_y = select((int4)1, (int4)0, ((ny - floor(ny))) * 64 > 63);\n"
"tx = convert_int4_sat_rtn(nx) - delta_x;\n"
"ty = convert_int4_sat_rtn(ny) - delta_y;\n"
"__constant float * coeffs_x, * coeffs_y;\n"
"float4 sum = (float4)0.0f;\n"
"uchar4 pix;\n"
"float xsum;\n"
"coeffs_x = coeffs + (ax.s0 << 2);\n"
"coeffs_y = coeffs + (ay.s0 << 2);\n"
"for (int i = 0; i < 4; i++)\n"
"{\n"
"pix = read_pixels_cubic(src, tx.s0, ty.s0 + i, src_offset, src_step, src_cols, src_rows, scalar);\n"
"xsum = dot(convert_float4(pix), (float4)(coeffs_x[0], coeffs_x[1], coeffs_x[2], coeffs_x[3]));\n"
"sum.s0 = fma(xsum, coeffs_y[i], sum.s0);\n"
"}\n"
"coeffs_x = coeffs + (ax.s1 << 2);\n"
"coeffs_y = coeffs + (ay.s1 << 2);\n"
"for (int i = 0; i < 4; i++)\n"
"{\n"
"pix = read_pixels_cubic(src, tx.s1, ty.s1 + i, src_offset, src_step, src_cols, src_rows, scalar);\n"
"xsum = dot(convert_float4(pix), (float4)(coeffs_x[0], coeffs_x[1], coeffs_x[2], coeffs_x[3]));\n"
"sum.s1 = fma(xsum, coeffs_y[i], sum.s1);\n"
"}\n"
"coeffs_x = coeffs + (ax.s2 << 2);\n"
"coeffs_y = coeffs + (ay.s2 << 2);\n"
"for (int i = 0; i < 4; i++)\n"
"{\n"
"pix = read_pixels_cubic(src, tx.s2, ty.s2 + i, src_offset, src_step, src_cols, src_rows, scalar);\n"
"xsum = dot(convert_float4(pix), (float4)(coeffs_x[0], coeffs_x[1], coeffs_x[2], coeffs_x[3]));\n"
"sum.s2 = fma(xsum, coeffs_y[i], sum.s2);\n"
"}\n"
"coeffs_x = coeffs + (ax.s3 << 2);\n"
"coeffs_y = coeffs + (ay.s3 << 2);\n"
"for (int i = 0; i < 4; i++)\n"
"{\n"
"pix = read_pixels_cubic(src, tx.s3, ty.s3 + i, src_offset, src_step, src_cols, src_rows, scalar);\n"
"xsum = dot(convert_float4(pix), (float4)(coeffs_x[0], coeffs_x[1], coeffs_x[2], coeffs_x[3]));\n"
"sum.s3 = fma(xsum, coeffs_y[i], sum.s3);\n"
"}\n"
"int dst_index = x + y * dst_step + dst_offset;\n"
"vstore4(convert_uchar4_sat_rte(sum), 0, dst + dst_index);\n"
"}\n"
, "14b9aef8e98f5e09295cf556e35dbf81", NULL};

}}}
#endif