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413 lines
21 KiB
C++
413 lines
21 KiB
C++
/*M///////////////////////////////////////////////////////////////////////////////////////
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//
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// IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING.
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//
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// By downloading, copying, installing or using the software you agree to this license.
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// If you do not agree to this license, do not download, install,
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// copy or use the software.
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//
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//
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// License Agreement
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// For Open Source Computer Vision Library
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//
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// Copyright (C) 2000-2008, Intel Corporation, all rights reserved.
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// Copyright (C) 2009-2011, Willow Garage Inc., all rights reserved.
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// Copyright (C) 2014-2015, Itseez Inc., all rights reserved.
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// Third party copyrights are property of their respective owners.
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//
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// Redistribution and use in source and binary forms, with or without modification,
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// are permitted provided that the following conditions are met:
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//
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// * Redistribution's of source code must retain the above copyright notice,
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// this list of conditions and the following disclaimer.
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//
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// * Redistribution's in binary form must reproduce the above copyright notice,
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// this list of conditions and the following disclaimer in the documentation
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// and/or other materials provided with the distribution.
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//
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// * The name of the copyright holders may not be used to endorse or promote products
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// derived from this software without specific prior written permission.
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//
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// This software is provided by the copyright holders and contributors "as is" and
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// any express or implied warranties, including, but not limited to, the implied
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// warranties of merchantability and fitness for a particular purpose are disclaimed.
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// In no event shall the Intel Corporation or contributors be liable for any direct,
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// indirect, incidental, special, exemplary, or consequential damages
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// (including, but not limited to, procurement of substitute goods or services;
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// loss of use, data, or profits; or business interruption) however caused
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// and on any theory of liability, whether in contract, strict liability,
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// or tort (including negligence or otherwise) arising in any way out of
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// the use of this software, even if advised of the possibility of such damage.
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//
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//M*/
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#include "precomp.hpp"
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namespace cv { namespace hal {
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#if CV_NEON
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template<typename T> struct VMerge2;
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template<typename T> struct VMerge3;
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template<typename T> struct VMerge4;
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#define MERGE2_KERNEL_TEMPLATE(name, data_type, reg_type, load_func, store_func) \
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template<> \
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struct name<data_type>{ \
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void operator()(const data_type* src0, const data_type* src1, \
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data_type* dst){ \
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reg_type r; \
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r.val[0] = load_func(src0); \
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r.val[1] = load_func(src1); \
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store_func(dst, r); \
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} \
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}
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#define MERGE3_KERNEL_TEMPLATE(name, data_type, reg_type, load_func, store_func) \
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template<> \
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struct name<data_type>{ \
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void operator()(const data_type* src0, const data_type* src1, \
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const data_type* src2, data_type* dst){ \
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reg_type r; \
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r.val[0] = load_func(src0); \
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r.val[1] = load_func(src1); \
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r.val[2] = load_func(src2); \
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store_func(dst, r); \
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} \
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}
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#define MERGE4_KERNEL_TEMPLATE(name, data_type, reg_type, load_func, store_func) \
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template<> \
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struct name<data_type>{ \
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void operator()(const data_type* src0, const data_type* src1, \
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const data_type* src2, const data_type* src3, \
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data_type* dst){ \
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reg_type r; \
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r.val[0] = load_func(src0); \
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r.val[1] = load_func(src1); \
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r.val[2] = load_func(src2); \
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r.val[3] = load_func(src3); \
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store_func(dst, r); \
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} \
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}
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MERGE2_KERNEL_TEMPLATE(VMerge2, uchar , uint8x16x2_t, vld1q_u8 , vst2q_u8 );
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MERGE2_KERNEL_TEMPLATE(VMerge2, ushort, uint16x8x2_t, vld1q_u16, vst2q_u16);
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MERGE2_KERNEL_TEMPLATE(VMerge2, int , int32x4x2_t, vld1q_s32, vst2q_s32);
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MERGE2_KERNEL_TEMPLATE(VMerge2, int64 , int64x1x2_t, vld1_s64 , vst2_s64 );
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MERGE3_KERNEL_TEMPLATE(VMerge3, uchar , uint8x16x3_t, vld1q_u8 , vst3q_u8 );
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MERGE3_KERNEL_TEMPLATE(VMerge3, ushort, uint16x8x3_t, vld1q_u16, vst3q_u16);
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MERGE3_KERNEL_TEMPLATE(VMerge3, int , int32x4x3_t, vld1q_s32, vst3q_s32);
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MERGE3_KERNEL_TEMPLATE(VMerge3, int64 , int64x1x3_t, vld1_s64 , vst3_s64 );
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MERGE4_KERNEL_TEMPLATE(VMerge4, uchar , uint8x16x4_t, vld1q_u8 , vst4q_u8 );
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MERGE4_KERNEL_TEMPLATE(VMerge4, ushort, uint16x8x4_t, vld1q_u16, vst4q_u16);
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MERGE4_KERNEL_TEMPLATE(VMerge4, int , int32x4x4_t, vld1q_s32, vst4q_s32);
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MERGE4_KERNEL_TEMPLATE(VMerge4, int64 , int64x1x4_t, vld1_s64 , vst4_s64 );
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#elif CV_SSE2
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template <typename T>
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struct VMerge2
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{
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VMerge2() : support(false) { }
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void operator()(const T *, const T *, T *) const { }
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bool support;
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};
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template <typename T>
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struct VMerge3
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{
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VMerge3() : support(false) { }
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void operator()(const T *, const T *, const T *, T *) const { }
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bool support;
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};
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template <typename T>
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struct VMerge4
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{
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VMerge4() : support(false) { }
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void operator()(const T *, const T *, const T *, const T *, T *) const { }
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bool support;
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};
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#define MERGE2_KERNEL_TEMPLATE(data_type, reg_type, cast_type, _mm_interleave, flavor, se) \
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template <> \
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struct VMerge2<data_type> \
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{ \
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enum \
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{ \
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ELEMS_IN_VEC = 16 / sizeof(data_type) \
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}; \
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\
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VMerge2() \
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{ \
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support = checkHardwareSupport(se); \
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} \
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\
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void operator()(const data_type * src0, const data_type * src1, \
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data_type * dst) const \
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{ \
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reg_type v_src0 = _mm_loadu_##flavor((const cast_type *)(src0)); \
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reg_type v_src1 = _mm_loadu_##flavor((const cast_type *)(src0 + ELEMS_IN_VEC)); \
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reg_type v_src2 = _mm_loadu_##flavor((const cast_type *)(src1)); \
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reg_type v_src3 = _mm_loadu_##flavor((const cast_type *)(src1 + ELEMS_IN_VEC)); \
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\
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_mm_interleave(v_src0, v_src1, v_src2, v_src3); \
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\
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_mm_storeu_##flavor((cast_type *)(dst), v_src0); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC), v_src1); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 2), v_src2); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 3), v_src3); \
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} \
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\
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bool support; \
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}
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#define MERGE3_KERNEL_TEMPLATE(data_type, reg_type, cast_type, _mm_interleave, flavor, se) \
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template <> \
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struct VMerge3<data_type> \
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{ \
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enum \
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{ \
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ELEMS_IN_VEC = 16 / sizeof(data_type) \
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}; \
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\
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VMerge3() \
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{ \
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support = checkHardwareSupport(se); \
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} \
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\
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void operator()(const data_type * src0, const data_type * src1, const data_type * src2,\
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data_type * dst) const \
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{ \
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reg_type v_src0 = _mm_loadu_##flavor((const cast_type *)(src0)); \
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reg_type v_src1 = _mm_loadu_##flavor((const cast_type *)(src0 + ELEMS_IN_VEC)); \
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reg_type v_src2 = _mm_loadu_##flavor((const cast_type *)(src1)); \
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reg_type v_src3 = _mm_loadu_##flavor((const cast_type *)(src1 + ELEMS_IN_VEC)); \
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reg_type v_src4 = _mm_loadu_##flavor((const cast_type *)(src2)); \
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reg_type v_src5 = _mm_loadu_##flavor((const cast_type *)(src2 + ELEMS_IN_VEC)); \
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\
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_mm_interleave(v_src0, v_src1, v_src2, \
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v_src3, v_src4, v_src5); \
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\
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_mm_storeu_##flavor((cast_type *)(dst), v_src0); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC), v_src1); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 2), v_src2); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 3), v_src3); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 4), v_src4); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 5), v_src5); \
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} \
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\
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bool support; \
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}
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#define MERGE4_KERNEL_TEMPLATE(data_type, reg_type, cast_type, _mm_interleave, flavor, se) \
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template <> \
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struct VMerge4<data_type> \
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{ \
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enum \
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{ \
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ELEMS_IN_VEC = 16 / sizeof(data_type) \
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}; \
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\
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VMerge4() \
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{ \
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support = checkHardwareSupport(se); \
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} \
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\
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void operator()(const data_type * src0, const data_type * src1, \
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const data_type * src2, const data_type * src3, \
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data_type * dst) const \
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{ \
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reg_type v_src0 = _mm_loadu_##flavor((const cast_type *)(src0)); \
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reg_type v_src1 = _mm_loadu_##flavor((const cast_type *)(src0 + ELEMS_IN_VEC)); \
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reg_type v_src2 = _mm_loadu_##flavor((const cast_type *)(src1)); \
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reg_type v_src3 = _mm_loadu_##flavor((const cast_type *)(src1 + ELEMS_IN_VEC)); \
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reg_type v_src4 = _mm_loadu_##flavor((const cast_type *)(src2)); \
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reg_type v_src5 = _mm_loadu_##flavor((const cast_type *)(src2 + ELEMS_IN_VEC)); \
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reg_type v_src6 = _mm_loadu_##flavor((const cast_type *)(src3)); \
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reg_type v_src7 = _mm_loadu_##flavor((const cast_type *)(src3 + ELEMS_IN_VEC)); \
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\
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_mm_interleave(v_src0, v_src1, v_src2, v_src3, \
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v_src4, v_src5, v_src6, v_src7); \
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\
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_mm_storeu_##flavor((cast_type *)(dst), v_src0); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC), v_src1); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 2), v_src2); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 3), v_src3); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 4), v_src4); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 5), v_src5); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 6), v_src6); \
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_mm_storeu_##flavor((cast_type *)(dst + ELEMS_IN_VEC * 7), v_src7); \
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} \
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\
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bool support; \
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}
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MERGE2_KERNEL_TEMPLATE( uchar, __m128i, __m128i, _mm_interleave_epi8, si128, CV_CPU_SSE2);
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MERGE3_KERNEL_TEMPLATE( uchar, __m128i, __m128i, _mm_interleave_epi8, si128, CV_CPU_SSE2);
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MERGE4_KERNEL_TEMPLATE( uchar, __m128i, __m128i, _mm_interleave_epi8, si128, CV_CPU_SSE2);
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#if CV_SSE4_1
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MERGE2_KERNEL_TEMPLATE(ushort, __m128i, __m128i, _mm_interleave_epi16, si128, CV_CPU_SSE4_1);
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MERGE3_KERNEL_TEMPLATE(ushort, __m128i, __m128i, _mm_interleave_epi16, si128, CV_CPU_SSE4_1);
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MERGE4_KERNEL_TEMPLATE(ushort, __m128i, __m128i, _mm_interleave_epi16, si128, CV_CPU_SSE4_1);
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#endif
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MERGE2_KERNEL_TEMPLATE( int, __m128, float, _mm_interleave_ps, ps, CV_CPU_SSE2);
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MERGE3_KERNEL_TEMPLATE( int, __m128, float, _mm_interleave_ps, ps, CV_CPU_SSE2);
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MERGE4_KERNEL_TEMPLATE( int, __m128, float, _mm_interleave_ps, ps, CV_CPU_SSE2);
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#endif
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template<typename T> static void
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merge_( const T** src, T* dst, int len, int cn )
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{
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int k = cn % 4 ? cn % 4 : 4;
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int i, j;
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if( k == 1 )
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{
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const T* src0 = src[0];
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for( i = j = 0; i < len; i++, j += cn )
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dst[j] = src0[i];
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}
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else if( k == 2 )
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{
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const T *src0 = src[0], *src1 = src[1];
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i = j = 0;
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#if CV_NEON
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if(cn == 2)
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{
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int inc_i = (sizeof(T) == 8)? 1: 16/sizeof(T);
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int inc_j = 2 * inc_i;
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VMerge2<T> vmerge;
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for( ; i < len - inc_i; i += inc_i, j += inc_j)
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vmerge(src0 + i, src1 + i, dst + j);
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}
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#elif CV_SSE2
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if(cn == 2)
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{
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int inc_i = 32/sizeof(T);
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int inc_j = 2 * inc_i;
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VMerge2<T> vmerge;
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if (vmerge.support)
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for( ; i < len - inc_i; i += inc_i, j += inc_j)
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vmerge(src0 + i, src1 + i, dst + j);
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}
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#endif
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for( ; i < len; i++, j += cn )
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{
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dst[j] = src0[i];
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dst[j+1] = src1[i];
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}
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}
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else if( k == 3 )
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{
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const T *src0 = src[0], *src1 = src[1], *src2 = src[2];
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i = j = 0;
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#if CV_NEON
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if(cn == 3)
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{
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int inc_i = (sizeof(T) == 8)? 1: 16/sizeof(T);
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int inc_j = 3 * inc_i;
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VMerge3<T> vmerge;
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for( ; i < len - inc_i; i += inc_i, j += inc_j)
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vmerge(src0 + i, src1 + i, src2 + i, dst + j);
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}
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#elif CV_SSE2
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if(cn == 3)
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{
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int inc_i = 32/sizeof(T);
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int inc_j = 3 * inc_i;
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VMerge3<T> vmerge;
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if (vmerge.support)
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for( ; i < len - inc_i; i += inc_i, j += inc_j)
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vmerge(src0 + i, src1 + i, src2 + i, dst + j);
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}
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#endif
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for( ; i < len; i++, j += cn )
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{
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dst[j] = src0[i];
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dst[j+1] = src1[i];
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dst[j+2] = src2[i];
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}
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}
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else
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{
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const T *src0 = src[0], *src1 = src[1], *src2 = src[2], *src3 = src[3];
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i = j = 0;
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#if CV_NEON
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if(cn == 4)
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{
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int inc_i = (sizeof(T) == 8)? 1: 16/sizeof(T);
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int inc_j = 4 * inc_i;
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VMerge4<T> vmerge;
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for( ; i < len - inc_i; i += inc_i, j += inc_j)
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vmerge(src0 + i, src1 + i, src2 + i, src3 + i, dst + j);
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}
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#elif CV_SSE2
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if(cn == 4)
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{
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int inc_i = 32/sizeof(T);
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int inc_j = 4 * inc_i;
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VMerge4<T> vmerge;
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if (vmerge.support)
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for( ; i < len - inc_i; i += inc_i, j += inc_j)
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vmerge(src0 + i, src1 + i, src2 + i, src3 + i, dst + j);
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}
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#endif
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for( ; i < len; i++, j += cn )
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{
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dst[j] = src0[i]; dst[j+1] = src1[i];
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dst[j+2] = src2[i]; dst[j+3] = src3[i];
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}
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}
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for( ; k < cn; k += 4 )
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{
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const T *src0 = src[k], *src1 = src[k+1], *src2 = src[k+2], *src3 = src[k+3];
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for( i = 0, j = k; i < len; i++, j += cn )
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{
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dst[j] = src0[i]; dst[j+1] = src1[i];
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dst[j+2] = src2[i]; dst[j+3] = src3[i];
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}
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}
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}
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void merge8u(const uchar** src, uchar* dst, int len, int cn )
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{
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CALL_HAL(merge8u, cv_hal_merge8u, src, dst, len, cn)
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merge_(src, dst, len, cn);
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}
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void merge16u(const ushort** src, ushort* dst, int len, int cn )
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{
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CALL_HAL(merge16u, cv_hal_merge16u, src, dst, len, cn)
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merge_(src, dst, len, cn);
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}
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void merge32s(const int** src, int* dst, int len, int cn )
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{
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CALL_HAL(merge32s, cv_hal_merge32s, src, dst, len, cn)
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merge_(src, dst, len, cn);
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}
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void merge64s(const int64** src, int64* dst, int len, int cn )
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{
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CALL_HAL(merge64s, cv_hal_merge64s, src, dst, len, cn)
|
|
merge_(src, dst, len, cn);
|
|
}
|
|
|
|
}}
|