/*M/////////////////////////////////////////////////////////////////////////////////////// // // IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. // // By downloading, copying, installing or using the software you agree to this license. // If you do not agree to this license, do not download, install, // copy or use the software. // // // License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2010-2012, Institute Of Software Chinese Academy Of Science, all rights reserved. // Copyright (C) 2010-2012, Advanced Micro Devices, Inc., all rights reserved. // Copyright (C) 2013, OpenCV Foundation, all rights reserved. // Third party copyrights are property of their respective owners. // // @Authors // Jia Haipeng, jiahaipeng95@gmail.com // // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // // * Redistribution's of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // * Redistribution's in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // // * The name of the copyright holders may not be used to endorse or promote products // derived from this software without specific prior written permission. // // This software is provided by the copyright holders and contributors as is and // any express or implied warranties, including, but not limited to, the implied // warranties of merchantability and fitness for a particular purpose are disclaimed. // In no event shall the copyright holders or contributors be liable for any direct, // indirect, incidental, special, exemplary, or consequential damages // (including, but not limited to, procurement of substitute goods or services; // loss of use, data, or profits; or business interruption) however caused // and on any theory of liability, whether in contract, strict liability, // or tort (including negligence or otherwise) arising in any way out of // the use of this software, even if advised of the possibility of such damage. // //M*/ /* Usage: after compiling this program user gets a single kernel called KF. the following flags should be passed: 1) one of "-D BINARY_OP", "-D UNARY_OP", "-D MASK_BINARY_OP" or "-D MASK_UNARY_OP" 2) the actual operation performed, one of "-D OP_...", see below the list of operations. 2a) "-D dstDepth= [-D cn= -D srcDepth2= -D dstDepth= -D workDepth= [-D cn=]" - for mixed-type operations */ #ifdef DOUBLE_SUPPORT #ifdef cl_amd_fp64 #pragma OPENCL EXTENSION cl_amd_fp64:enable #elif defined cl_khr_fp64 #pragma OPENCL EXTENSION cl_khr_fp64:enable #endif #endif #if depth <= 5 #define CV_PI M_PI_F #else #define CV_PI M_PI #endif #ifndef cn #define cn 1 #endif #if cn == 1 #undef srcT1_C1 #undef srcT2_C1 #undef dstT_C1 #define srcT1_C1 srcT1 #define srcT2_C1 srcT2 #define dstT_C1 dstT #endif #if cn != 3 #define storedst(val) *(__global dstT *)(dstptr + dst_index) = val #define storedst2(val) *(__global dstT *)(dstptr2 + dst_index2) = val #else #define storedst(val) vstore3(val, 0, (__global dstT_C1 *)(dstptr + dst_index)) #define storedst2(val) vstore3(val, 0, (__global dstT_C1 *)(dstptr2 + dst_index2)) #endif #define noconvert #ifndef workT #ifndef srcT1 #define srcT1 dstT #endif #ifndef srcT1_C1 #define srcT1_C1 dstT_C1 #endif #ifndef srcT2 #define srcT2 dstT #endif #ifndef srcT2_C1 #define srcT2_C1 dstT_C1 #endif #define workT dstT #if cn != 3 #define srcelem1 *(__global srcT1 *)(srcptr1 + src1_index) #define srcelem2 *(__global srcT2 *)(srcptr2 + src2_index) #else #define srcelem1 vload3(0, (__global srcT1_C1 *)(srcptr1 + src1_index)) #define srcelem2 vload3(0, (__global srcT2_C1 *)(srcptr2 + src2_index)) #endif #ifndef convertToDT #define convertToDT noconvert #endif #else #ifndef convertToWT2 #define convertToWT2 convertToWT1 #endif #if cn != 3 #define srcelem1 convertToWT1(*(__global srcT1 *)(srcptr1 + src1_index)) #define srcelem2 convertToWT2(*(__global srcT2 *)(srcptr2 + src2_index)) #else #define srcelem1 convertToWT1(vload3(0, (__global srcT1_C1 *)(srcptr1 + src1_index))) #define srcelem2 convertToWT2(vload3(0, (__global srcT2_C1 *)(srcptr2 + src2_index))) #endif #endif #ifndef workST #define workST workT #endif #define EXTRA_PARAMS #define EXTRA_INDEX #if defined OP_ADD #define PROCESS_ELEM storedst(convertToDT(srcelem1 + srcelem2)) #elif defined OP_SUB #define PROCESS_ELEM storedst(convertToDT(srcelem1 - srcelem2)) #elif defined OP_RSUB #define PROCESS_ELEM storedst(convertToDT(srcelem2 - srcelem1)) #elif defined OP_ABSDIFF #define PROCESS_ELEM \ workT v = srcelem1 - srcelem2; \ storedst(convertToDT(v >= (workT)(0) ? v : -v)) #elif defined OP_AND #define PROCESS_ELEM storedst(srcelem1 & srcelem2) #elif defined OP_OR #define PROCESS_ELEM storedst(srcelem1 | srcelem2) #elif defined OP_XOR #define PROCESS_ELEM storedst(srcelem1 ^ srcelem2) #elif defined OP_NOT #define PROCESS_ELEM storedst(~srcelem1) #elif defined OP_MIN #define PROCESS_ELEM storedst(min(srcelem1, srcelem2)) #elif defined OP_MAX #define PROCESS_ELEM storedst(max(srcelem1, srcelem2)) #elif defined OP_MUL #define PROCESS_ELEM storedst(convertToDT(srcelem1 * srcelem2)) #elif defined OP_MUL_SCALE #undef EXTRA_PARAMS #ifdef UNARY_OP #define EXTRA_PARAMS , workST srcelem2_, scaleT scale #undef srcelem2 #define srcelem2 srcelem2_ #else #define EXTRA_PARAMS , scaleT scale #endif #define PROCESS_ELEM storedst(convertToDT(srcelem1 * scale * srcelem2)) #elif defined OP_DIV #define PROCESS_ELEM \ workT e2 = srcelem2, zero = (workT)(0); \ storedst(convertToDT(e2 != zero ? srcelem1 / e2 : zero)) #elif defined OP_DIV_SCALE #undef EXTRA_PARAMS #ifdef UNARY_OP #define EXTRA_PARAMS , workST srcelem2_, scaleT scale #undef srcelem2 #define srcelem2 srcelem2_ #else #define EXTRA_PARAMS , scaleT scale #endif #define PROCESS_ELEM \ workT e2 = srcelem2, zero = (workT)(0); \ storedst(convertToDT(e2 == zero ? zero : (srcelem1 * (workT)(scale) / e2))) #elif defined OP_RDIV_SCALE #undef EXTRA_PARAMS #ifdef UNARY_OP #define EXTRA_PARAMS , workST srcelem2_, scaleT scale #undef srcelem2 #define srcelem2 srcelem2_ #else #define EXTRA_PARAMS , scaleT scale #endif #define PROCESS_ELEM \ workT e1 = srcelem1, zero = (workT)(0); \ storedst(convertToDT(e1 == zero ? zero : (srcelem2 * (workT)(scale) / e1))) #elif defined OP_RECIP_SCALE #undef EXTRA_PARAMS #define EXTRA_PARAMS , scaleT scale #define PROCESS_ELEM \ workT e1 = srcelem1, zero = (workT)(0); \ storedst(convertToDT(e1 != zero ? scale / e1 : zero)) #elif defined OP_ADDW #undef EXTRA_PARAMS #define EXTRA_PARAMS , scaleT alpha, scaleT beta, scaleT gamma #if wdepth <= 4 #define PROCESS_ELEM storedst(convertToDT(mad24(srcelem1, alpha, mad24(srcelem2, beta, gamma)))) #else #define PROCESS_ELEM storedst(convertToDT(mad(srcelem1, alpha, mad(srcelem2, beta, gamma)))) #endif #elif defined OP_MAG #define PROCESS_ELEM storedst(hypot(srcelem1, srcelem2)) #elif defined OP_ABS_NOSAT #define PROCESS_ELEM \ dstT v = convertToDT(srcelem1); \ storedst(v >= 0 ? v : -v) #elif defined OP_PHASE_RADIANS #define PROCESS_ELEM \ workT tmp = atan2(srcelem2, srcelem1); \ if(tmp < 0) tmp += 6.283185307179586232f; \ storedst(tmp) #elif defined OP_PHASE_DEGREES #define PROCESS_ELEM \ workT tmp = atan2(srcelem2, srcelem1)*57.29577951308232286465f; \ if(tmp < 0) tmp += 360; \ storedst(tmp) #elif defined OP_EXP #define PROCESS_ELEM storedst(exp(srcelem1)) #elif defined OP_POW #define PROCESS_ELEM storedst(pow(srcelem1, srcelem2)) #elif defined OP_POWN #undef workT #define workT int #define PROCESS_ELEM storedst(pown(srcelem1, srcelem2)) #elif defined OP_SQRT #define PROCESS_ELEM storedst(sqrt(srcelem1)) #elif defined OP_LOG #define PROCESS_ELEM \ dstT v = (dstT)(srcelem1);\ storedst(v > (dstT)(0) ? log(v) : log(-v)) #elif defined OP_CMP #define srcT2 srcT1 #ifndef convertToWT1 #define convertToWT1 #endif #define PROCESS_ELEM \ workT __s1 = srcelem1; \ workT __s2 = srcelem2; \ storedst(((__s1 CMP_OPERATOR __s2) ? (dstT)(255) : (dstT)(0))) #elif defined OP_CONVERT_SCALE_ABS #undef EXTRA_PARAMS #define EXTRA_PARAMS , workT1 alpha, workT1 beta #if wdepth <= 4 #define PROCESS_ELEM \ workT value = mad24(srcelem1, (workT)(alpha), (workT)(beta)); \ storedst(convertToDT(value >= 0 ? value : -value)) #else #define PROCESS_ELEM \ workT value = mad(srcelem1, (workT)(alpha), (workT)(beta)); \ storedst(convertToDT(value >= 0 ? value : -value)) #endif #elif defined OP_SCALE_ADD #undef EXTRA_PARAMS #define EXTRA_PARAMS , workT1 alpha #if wdepth <= 4 #define PROCESS_ELEM storedst(convertToDT(mad24(srcelem1, (workT)(alpha), srcelem2))) #else #define PROCESS_ELEM storedst(convertToDT(mad(srcelem1, (workT)(alpha), srcelem2))) #endif #elif defined OP_CTP_AD || defined OP_CTP_AR #if depth <= 5 #define CV_EPSILON FLT_EPSILON #else #define CV_EPSILON DBL_EPSILON #endif #ifdef OP_CTP_AD #define TO_DEGREE cartToPolar *= (180 / CV_PI); #elif defined OP_CTP_AR #define TO_DEGREE #endif #define PROCESS_ELEM \ dstT x = srcelem1, y = srcelem2; \ dstT x2 = x * x, y2 = y * y; \ dstT magnitude = sqrt(x2 + y2); \ dstT tmp = y >= 0 ? 0 : CV_PI * 2; \ tmp = x < 0 ? CV_PI : tmp; \ dstT tmp1 = y >= 0 ? CV_PI * 0.5f : CV_PI * 1.5f; \ dstT cartToPolar = y2 <= x2 ? x * y / mad((dstT)(0.28f), y2, x2 + CV_EPSILON) + tmp : (tmp1 - x * y / mad((dstT)(0.28f), x2, y2 + CV_EPSILON)); \ TO_DEGREE \ storedst(magnitude); \ storedst2(cartToPolar) #elif defined OP_PTC_AD || defined OP_PTC_AR #ifdef OP_PTC_AD #define FROM_DEGREE \ dstT ascale = CV_PI/180.0f; \ dstT alpha = y * ascale #else #define FROM_DEGREE \ dstT alpha = y #endif #define PROCESS_ELEM \ dstT x = srcelem1, y = srcelem2; \ FROM_DEGREE; \ storedst(cos(alpha) * x); \ storedst2(sin(alpha) * x) #elif defined OP_PATCH_NANS #undef EXTRA_PARAMS #define EXTRA_PARAMS , int val #define PROCESS_ELEM \ if (( srcelem1 & 0x7fffffff) > 0x7f800000 ) \ storedst(val) #else #error "unknown op type" #endif #if defined OP_CTP_AD || defined OP_CTP_AR || defined OP_PTC_AD || defined OP_PTC_AR #undef EXTRA_PARAMS #define EXTRA_PARAMS , __global uchar* dstptr2, int dststep2, int dstoffset2 #undef EXTRA_INDEX #define EXTRA_INDEX int dst_index2 = mad24(y, dststep2, mad24(x, (int)sizeof(dstT_C1) * cn, dstoffset2)) #endif #if defined UNARY_OP || defined MASK_UNARY_OP #if defined OP_AND || defined OP_OR || defined OP_XOR || defined OP_ADD || defined OP_SAT_ADD || \ defined OP_SUB || defined OP_SAT_SUB || defined OP_RSUB || defined OP_SAT_RSUB || \ defined OP_ABSDIFF || defined OP_CMP || defined OP_MIN || defined OP_MAX || defined OP_POW || \ defined OP_MUL || defined OP_DIV || defined OP_POWN #undef EXTRA_PARAMS #define EXTRA_PARAMS , workST srcelem2_ #undef srcelem2 #define srcelem2 srcelem2_ #endif #if cn == 3 #undef srcelem2 #define srcelem2 (workT)(srcelem2_.x, srcelem2_.y, srcelem2_.z) #endif #endif #if defined BINARY_OP __kernel void KF(__global const uchar * srcptr1, int srcstep1, int srcoffset1, __global const uchar * srcptr2, int srcstep2, int srcoffset2, __global uchar * dstptr, int dststep, int dstoffset, int rows, int cols EXTRA_PARAMS ) { int x = get_global_id(0); int y = get_global_id(1); if (x < cols && y < rows) { int src1_index = mad24(y, srcstep1, mad24(x, (int)sizeof(srcT1_C1) * cn, srcoffset1)); #if !(defined(OP_RECIP_SCALE) || defined(OP_NOT)) int src2_index = mad24(y, srcstep2, mad24(x, (int)sizeof(srcT2_C1) * cn, srcoffset2)); #endif int dst_index = mad24(y, dststep, mad24(x, (int)sizeof(dstT_C1) * cn, dstoffset)); EXTRA_INDEX; PROCESS_ELEM; } } #elif defined MASK_BINARY_OP __kernel void KF(__global const uchar * srcptr1, int srcstep1, int srcoffset1, __global const uchar * srcptr2, int srcstep2, int srcoffset2, __global const uchar * mask, int maskstep, int maskoffset, __global uchar * dstptr, int dststep, int dstoffset, int rows, int cols EXTRA_PARAMS ) { int x = get_global_id(0); int y = get_global_id(1); if (x < cols && y < rows) { int mask_index = mad24(y, maskstep, x + maskoffset); if( mask[mask_index] ) { int src1_index = mad24(y, srcstep1, mad24(x, (int)sizeof(srcT1_C1) * cn, srcoffset1)); int src2_index = mad24(y, srcstep2, mad24(x, (int)sizeof(srcT2_C1) * cn, srcoffset2)); int dst_index = mad24(y, dststep, mad24(x, (int)sizeof(dstT_C1) * cn, dstoffset)); PROCESS_ELEM; } } } #elif defined UNARY_OP __kernel void KF(__global const uchar * srcptr1, int srcstep1, int srcoffset1, __global uchar * dstptr, int dststep, int dstoffset, int rows, int cols EXTRA_PARAMS ) { int x = get_global_id(0); int y = get_global_id(1); if (x < cols && y < rows) { int src1_index = mad24(y, srcstep1, mad24(x, (int)sizeof(srcT1_C1) * cn, srcoffset1)); int dst_index = mad24(y, dststep, mad24(x, (int)sizeof(dstT_C1) * cn, dstoffset)); PROCESS_ELEM; } } #elif defined MASK_UNARY_OP __kernel void KF(__global const uchar * srcptr1, int srcstep1, int srcoffset1, __global const uchar * mask, int maskstep, int maskoffset, __global uchar * dstptr, int dststep, int dstoffset, int rows, int cols EXTRA_PARAMS ) { int x = get_global_id(0); int y = get_global_id(1); if (x < cols && y < rows) { int mask_index = mad24(y, maskstep, x + maskoffset); if( mask[mask_index] ) { int src1_index = mad24(y, srcstep1, mad24(x, (int)sizeof(srcT1_C1) * cn, srcoffset1)); int dst_index = mad24(y, dststep, mad24(x, (int)sizeof(dstT_C1) * cn, dstoffset)); PROCESS_ELEM; } } } #else #error "Unknown operation type" #endif