opencv/modules/core/src/arithm.cpp

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/*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) 2000-2008, Intel Corporation, all rights reserved.
// Copyright (C) 2009-2011, Willow Garage Inc., all rights reserved.
// Third party copyrights are property of their respective owners.
//
// 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 Intel Corporation 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*/
/* ////////////////////////////////////////////////////////////////////
//
// Arithmetic and logical operations: +, -, *, /, &, |, ^, ~, abs ...
//
// */
#include "precomp.hpp"
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#include "opencl_kernels_core.hpp"
namespace cv
{
struct NOP {};
#if CV_SSE2 || CV_NEON
#define FUNCTOR_TEMPLATE(name) \
template<typename T> struct name {}
FUNCTOR_TEMPLATE(VLoadStore128);
#if CV_SSE2
FUNCTOR_TEMPLATE(VLoadStore64);
FUNCTOR_TEMPLATE(VLoadStore128Aligned);
#endif
#endif
template<typename T, class Op, class VOp>
void vBinOp(const T* src1, size_t step1, const T* src2, size_t step2, T* dst, size_t step, Size sz)
{
#if CV_SSE2 || CV_NEON
VOp vop;
#endif
Op op;
for( ; sz.height--; src1 += step1/sizeof(src1[0]),
src2 += step2/sizeof(src2[0]),
dst += step/sizeof(dst[0]) )
{
int x = 0;
#if CV_NEON || CV_SSE2
#if CV_SSE2
if( USE_SSE2 )
{
#endif
for( ; x <= sz.width - 32/(int)sizeof(T); x += 32/sizeof(T) )
{
typename VLoadStore128<T>::reg_type r0 = VLoadStore128<T>::load(src1 + x );
typename VLoadStore128<T>::reg_type r1 = VLoadStore128<T>::load(src1 + x + 16/sizeof(T));
r0 = vop(r0, VLoadStore128<T>::load(src2 + x ));
r1 = vop(r1, VLoadStore128<T>::load(src2 + x + 16/sizeof(T)));
VLoadStore128<T>::store(dst + x , r0);
VLoadStore128<T>::store(dst + x + 16/sizeof(T), r1);
}
#if CV_SSE2
}
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#endif
#endif
#if CV_SSE2
if( USE_SSE2 )
{
for( ; x <= sz.width - 8/(int)sizeof(T); x += 8/sizeof(T) )
{
typename VLoadStore64<T>::reg_type r = VLoadStore64<T>::load(src1 + x);
r = vop(r, VLoadStore64<T>::load(src2 + x));
VLoadStore64<T>::store(dst + x, r);
}
}
#endif
#if CV_ENABLE_UNROLLED
for( ; x <= sz.width - 4; x += 4 )
{
T v0 = op(src1[x], src2[x]);
T v1 = op(src1[x+1], src2[x+1]);
dst[x] = v0; dst[x+1] = v1;
v0 = op(src1[x+2], src2[x+2]);
v1 = op(src1[x+3], src2[x+3]);
dst[x+2] = v0; dst[x+3] = v1;
}
#endif
for( ; x < sz.width; x++ )
dst[x] = op(src1[x], src2[x]);
}
}
template<typename T, class Op, class Op32>
void vBinOp32(const T* src1, size_t step1, const T* src2, size_t step2,
T* dst, size_t step, Size sz)
{
#if CV_SSE2 || CV_NEON
Op32 op32;
#endif
Op op;
for( ; sz.height--; src1 += step1/sizeof(src1[0]),
src2 += step2/sizeof(src2[0]),
dst += step/sizeof(dst[0]) )
{
int x = 0;
#if CV_SSE2
if( USE_SSE2 )
{
if( (((size_t)src1|(size_t)src2|(size_t)dst)&15) == 0 )
{
for( ; x <= sz.width - 8; x += 8 )
{
typename VLoadStore128Aligned<T>::reg_type r0 = VLoadStore128Aligned<T>::load(src1 + x );
typename VLoadStore128Aligned<T>::reg_type r1 = VLoadStore128Aligned<T>::load(src1 + x + 4);
r0 = op32(r0, VLoadStore128Aligned<T>::load(src2 + x ));
r1 = op32(r1, VLoadStore128Aligned<T>::load(src2 + x + 4));
VLoadStore128Aligned<T>::store(dst + x , r0);
VLoadStore128Aligned<T>::store(dst + x + 4, r1);
}
}
}
#endif
#if CV_NEON || CV_SSE2
#if CV_SSE2
if( USE_SSE2 )
{
#endif
for( ; x <= sz.width - 8; x += 8 )
{
typename VLoadStore128<T>::reg_type r0 = VLoadStore128<T>::load(src1 + x );
typename VLoadStore128<T>::reg_type r1 = VLoadStore128<T>::load(src1 + x + 4);
r0 = op32(r0, VLoadStore128<T>::load(src2 + x ));
r1 = op32(r1, VLoadStore128<T>::load(src2 + x + 4));
VLoadStore128<T>::store(dst + x , r0);
VLoadStore128<T>::store(dst + x + 4, r1);
}
#if CV_SSE2
}
#endif
#endif
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#if CV_ENABLE_UNROLLED
for( ; x <= sz.width - 4; x += 4 )
{
T v0 = op(src1[x], src2[x]);
T v1 = op(src1[x+1], src2[x+1]);
dst[x] = v0; dst[x+1] = v1;
v0 = op(src1[x+2], src2[x+2]);
v1 = op(src1[x+3], src2[x+3]);
dst[x+2] = v0; dst[x+3] = v1;
}
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#endif
for( ; x < sz.width; x++ )
dst[x] = op(src1[x], src2[x]);
}
}
template<typename T, class Op, class Op64>
void vBinOp64(const T* src1, size_t step1, const T* src2, size_t step2,
T* dst, size_t step, Size sz)
{
#if CV_SSE2
Op64 op64;
#endif
Op op;
for( ; sz.height--; src1 += step1/sizeof(src1[0]),
src2 += step2/sizeof(src2[0]),
dst += step/sizeof(dst[0]) )
{
int x = 0;
#if CV_SSE2
if( USE_SSE2 )
{
if( (((size_t)src1|(size_t)src2|(size_t)dst)&15) == 0 )
{
for( ; x <= sz.width - 4; x += 4 )
{
typename VLoadStore128Aligned<T>::reg_type r0 = VLoadStore128Aligned<T>::load(src1 + x );
typename VLoadStore128Aligned<T>::reg_type r1 = VLoadStore128Aligned<T>::load(src1 + x + 2);
r0 = op64(r0, VLoadStore128Aligned<T>::load(src2 + x ));
r1 = op64(r1, VLoadStore128Aligned<T>::load(src2 + x + 2));
VLoadStore128Aligned<T>::store(dst + x , r0);
VLoadStore128Aligned<T>::store(dst + x + 2, r1);
}
}
}
#endif
for( ; x <= sz.width - 4; x += 4 )
{
T v0 = op(src1[x], src2[x]);
T v1 = op(src1[x+1], src2[x+1]);
dst[x] = v0; dst[x+1] = v1;
v0 = op(src1[x+2], src2[x+2]);
v1 = op(src1[x+3], src2[x+3]);
dst[x+2] = v0; dst[x+3] = v1;
}
for( ; x < sz.width; x++ )
dst[x] = op(src1[x], src2[x]);
}
}
#if CV_SSE2
#define FUNCTOR_LOADSTORE_CAST(name, template_arg, register_type, load_body, store_body)\
template <> \
struct name<template_arg>{ \
typedef register_type reg_type; \
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static reg_type load(const template_arg * p) { return load_body ((const reg_type *)p); } \
static void store(template_arg * p, reg_type v) { store_body ((reg_type *)p, v); } \
}
#define FUNCTOR_LOADSTORE(name, template_arg, register_type, load_body, store_body)\
template <> \
struct name<template_arg>{ \
typedef register_type reg_type; \
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static reg_type load(const template_arg * p) { return load_body (p); } \
static void store(template_arg * p, reg_type v) { store_body (p, v); } \
}
#define FUNCTOR_CLOSURE_2arg(name, template_arg, body)\
template<> \
struct name<template_arg> \
{ \
VLoadStore128<template_arg>::reg_type operator()( \
const VLoadStore128<template_arg>::reg_type & a, \
const VLoadStore128<template_arg>::reg_type & b) const \
{ \
body; \
} \
}
#define FUNCTOR_CLOSURE_1arg(name, template_arg, body)\
template<> \
struct name<template_arg> \
{ \
VLoadStore128<template_arg>::reg_type operator()( \
const VLoadStore128<template_arg>::reg_type & a, \
const VLoadStore128<template_arg>::reg_type & ) const \
{ \
body; \
} \
}
FUNCTOR_LOADSTORE_CAST(VLoadStore128, uchar, __m128i, _mm_loadu_si128, _mm_storeu_si128);
FUNCTOR_LOADSTORE_CAST(VLoadStore128, schar, __m128i, _mm_loadu_si128, _mm_storeu_si128);
FUNCTOR_LOADSTORE_CAST(VLoadStore128, ushort, __m128i, _mm_loadu_si128, _mm_storeu_si128);
FUNCTOR_LOADSTORE_CAST(VLoadStore128, short, __m128i, _mm_loadu_si128, _mm_storeu_si128);
FUNCTOR_LOADSTORE_CAST(VLoadStore128, int, __m128i, _mm_loadu_si128, _mm_storeu_si128);
FUNCTOR_LOADSTORE( VLoadStore128, float, __m128 , _mm_loadu_ps , _mm_storeu_ps );
FUNCTOR_LOADSTORE( VLoadStore128, double, __m128d, _mm_loadu_pd , _mm_storeu_pd );
FUNCTOR_LOADSTORE_CAST(VLoadStore64, uchar, __m128i, _mm_loadl_epi64, _mm_storel_epi64);
FUNCTOR_LOADSTORE_CAST(VLoadStore64, schar, __m128i, _mm_loadl_epi64, _mm_storel_epi64);
FUNCTOR_LOADSTORE_CAST(VLoadStore64, ushort, __m128i, _mm_loadl_epi64, _mm_storel_epi64);
FUNCTOR_LOADSTORE_CAST(VLoadStore64, short, __m128i, _mm_loadl_epi64, _mm_storel_epi64);
FUNCTOR_LOADSTORE_CAST(VLoadStore128Aligned, int, __m128i, _mm_load_si128, _mm_store_si128);
FUNCTOR_LOADSTORE( VLoadStore128Aligned, float, __m128 , _mm_load_ps , _mm_store_ps );
FUNCTOR_LOADSTORE( VLoadStore128Aligned, double, __m128d, _mm_load_pd , _mm_store_pd );
FUNCTOR_TEMPLATE(VAdd);
FUNCTOR_CLOSURE_2arg(VAdd, uchar, return _mm_adds_epu8 (a, b));
FUNCTOR_CLOSURE_2arg(VAdd, schar, return _mm_adds_epi8 (a, b));
FUNCTOR_CLOSURE_2arg(VAdd, ushort, return _mm_adds_epu16(a, b));
FUNCTOR_CLOSURE_2arg(VAdd, short, return _mm_adds_epi16(a, b));
FUNCTOR_CLOSURE_2arg(VAdd, int, return _mm_add_epi32 (a, b));
FUNCTOR_CLOSURE_2arg(VAdd, float, return _mm_add_ps (a, b));
FUNCTOR_CLOSURE_2arg(VAdd, double, return _mm_add_pd (a, b));
FUNCTOR_TEMPLATE(VSub);
FUNCTOR_CLOSURE_2arg(VSub, uchar, return _mm_subs_epu8 (a, b));
FUNCTOR_CLOSURE_2arg(VSub, schar, return _mm_subs_epi8 (a, b));
FUNCTOR_CLOSURE_2arg(VSub, ushort, return _mm_subs_epu16(a, b));
FUNCTOR_CLOSURE_2arg(VSub, short, return _mm_subs_epi16(a, b));
FUNCTOR_CLOSURE_2arg(VSub, int, return _mm_sub_epi32 (a, b));
FUNCTOR_CLOSURE_2arg(VSub, float, return _mm_sub_ps (a, b));
FUNCTOR_CLOSURE_2arg(VSub, double, return _mm_sub_pd (a, b));
FUNCTOR_TEMPLATE(VMin);
FUNCTOR_CLOSURE_2arg(VMin, uchar, return _mm_min_epu8(a, b));
FUNCTOR_CLOSURE_2arg(VMin, schar,
__m128i m = _mm_cmpgt_epi8(a, b);
return _mm_xor_si128(a, _mm_and_si128(_mm_xor_si128(a, b), m));
);
FUNCTOR_CLOSURE_2arg(VMin, ushort, return _mm_subs_epu16(a, _mm_subs_epu16(a, b)));
FUNCTOR_CLOSURE_2arg(VMin, short, return _mm_min_epi16(a, b));
FUNCTOR_CLOSURE_2arg(VMin, int,
__m128i m = _mm_cmpgt_epi32(a, b);
return _mm_xor_si128(a, _mm_and_si128(_mm_xor_si128(a, b), m));
);
FUNCTOR_CLOSURE_2arg(VMin, float, return _mm_min_ps(a, b));
FUNCTOR_CLOSURE_2arg(VMin, double, return _mm_min_pd(a, b));
FUNCTOR_TEMPLATE(VMax);
FUNCTOR_CLOSURE_2arg(VMax, uchar, return _mm_max_epu8(a, b));
FUNCTOR_CLOSURE_2arg(VMax, schar,
__m128i m = _mm_cmpgt_epi8(b, a);
return _mm_xor_si128(a, _mm_and_si128(_mm_xor_si128(a, b), m));
);
FUNCTOR_CLOSURE_2arg(VMax, ushort, return _mm_adds_epu16(_mm_subs_epu16(a, b), b));
FUNCTOR_CLOSURE_2arg(VMax, short, return _mm_max_epi16(a, b));
FUNCTOR_CLOSURE_2arg(VMax, int,
__m128i m = _mm_cmpgt_epi32(b, a);
return _mm_xor_si128(a, _mm_and_si128(_mm_xor_si128(a, b), m));
);
FUNCTOR_CLOSURE_2arg(VMax, float, return _mm_max_ps(a, b));
FUNCTOR_CLOSURE_2arg(VMax, double, return _mm_max_pd(a, b));
static unsigned int CV_DECL_ALIGNED(16) v32f_absmask[] = { 0x7fffffff, 0x7fffffff, 0x7fffffff, 0x7fffffff };
static unsigned int CV_DECL_ALIGNED(16) v64f_absmask[] = { 0xffffffff, 0x7fffffff, 0xffffffff, 0x7fffffff };
FUNCTOR_TEMPLATE(VAbsDiff);
FUNCTOR_CLOSURE_2arg(VAbsDiff, uchar,
return _mm_add_epi8(_mm_subs_epu8(a, b), _mm_subs_epu8(b, a));
);
FUNCTOR_CLOSURE_2arg(VAbsDiff, schar,
__m128i d = _mm_subs_epi8(a, b);
__m128i m = _mm_cmpgt_epi8(b, a);
return _mm_subs_epi8(_mm_xor_si128(d, m), m);
);
FUNCTOR_CLOSURE_2arg(VAbsDiff, ushort,
return _mm_add_epi16(_mm_subs_epu16(a, b), _mm_subs_epu16(b, a));
);
FUNCTOR_CLOSURE_2arg(VAbsDiff, short,
__m128i M = _mm_max_epi16(a, b);
__m128i m = _mm_min_epi16(a, b);
return _mm_subs_epi16(M, m);
);
FUNCTOR_CLOSURE_2arg(VAbsDiff, int,
__m128i d = _mm_sub_epi32(a, b);
__m128i m = _mm_cmpgt_epi32(b, a);
return _mm_sub_epi32(_mm_xor_si128(d, m), m);
);
FUNCTOR_CLOSURE_2arg(VAbsDiff, float,
return _mm_and_ps(_mm_sub_ps(a,b), *(const __m128*)v32f_absmask);
);
FUNCTOR_CLOSURE_2arg(VAbsDiff, double,
return _mm_and_pd(_mm_sub_pd(a,b), *(const __m128d*)v64f_absmask);
);
FUNCTOR_TEMPLATE(VAnd);
FUNCTOR_CLOSURE_2arg(VAnd, uchar, return _mm_and_si128(a, b));
FUNCTOR_TEMPLATE(VOr);
FUNCTOR_CLOSURE_2arg(VOr , uchar, return _mm_or_si128 (a, b));
FUNCTOR_TEMPLATE(VXor);
FUNCTOR_CLOSURE_2arg(VXor, uchar, return _mm_xor_si128(a, b));
FUNCTOR_TEMPLATE(VNot);
FUNCTOR_CLOSURE_1arg(VNot, uchar, return _mm_xor_si128(_mm_set1_epi32(-1), a));
#endif
#if CV_NEON
#define FUNCTOR_LOADSTORE(name, template_arg, register_type, load_body, store_body)\
template <> \
struct name<template_arg>{ \
typedef register_type reg_type; \
static reg_type load(const template_arg * p) { return load_body (p);}; \
static void store(template_arg * p, reg_type v) { store_body (p, v);}; \
}
#define FUNCTOR_CLOSURE_2arg(name, template_arg, body)\
template<> \
struct name<template_arg> \
{ \
VLoadStore128<template_arg>::reg_type operator()( \
VLoadStore128<template_arg>::reg_type a, \
VLoadStore128<template_arg>::reg_type b) const \
{ \
return body; \
}; \
}
#define FUNCTOR_CLOSURE_1arg(name, template_arg, body)\
template<> \
struct name<template_arg> \
{ \
VLoadStore128<template_arg>::reg_type operator()( \
VLoadStore128<template_arg>::reg_type a, \
VLoadStore128<template_arg>::reg_type ) const \
{ \
return body; \
}; \
}
FUNCTOR_LOADSTORE(VLoadStore128, uchar, uint8x16_t, vld1q_u8 , vst1q_u8 );
FUNCTOR_LOADSTORE(VLoadStore128, schar, int8x16_t, vld1q_s8 , vst1q_s8 );
FUNCTOR_LOADSTORE(VLoadStore128, ushort, uint16x8_t, vld1q_u16, vst1q_u16);
FUNCTOR_LOADSTORE(VLoadStore128, short, int16x8_t, vld1q_s16, vst1q_s16);
FUNCTOR_LOADSTORE(VLoadStore128, int, int32x4_t, vld1q_s32, vst1q_s32);
FUNCTOR_LOADSTORE(VLoadStore128, float, float32x4_t, vld1q_f32, vst1q_f32);
FUNCTOR_TEMPLATE(VAdd);
FUNCTOR_CLOSURE_2arg(VAdd, uchar, vqaddq_u8 (a, b));
FUNCTOR_CLOSURE_2arg(VAdd, schar, vqaddq_s8 (a, b));
FUNCTOR_CLOSURE_2arg(VAdd, ushort, vqaddq_u16(a, b));
FUNCTOR_CLOSURE_2arg(VAdd, short, vqaddq_s16(a, b));
FUNCTOR_CLOSURE_2arg(VAdd, int, vaddq_s32 (a, b));
FUNCTOR_CLOSURE_2arg(VAdd, float, vaddq_f32 (a, b));
FUNCTOR_TEMPLATE(VSub);
FUNCTOR_CLOSURE_2arg(VSub, uchar, vqsubq_u8 (a, b));
FUNCTOR_CLOSURE_2arg(VSub, schar, vqsubq_s8 (a, b));
FUNCTOR_CLOSURE_2arg(VSub, ushort, vqsubq_u16(a, b));
FUNCTOR_CLOSURE_2arg(VSub, short, vqsubq_s16(a, b));
FUNCTOR_CLOSURE_2arg(VSub, int, vsubq_s32 (a, b));
FUNCTOR_CLOSURE_2arg(VSub, float, vsubq_f32 (a, b));
FUNCTOR_TEMPLATE(VMin);
FUNCTOR_CLOSURE_2arg(VMin, uchar, vminq_u8 (a, b));
FUNCTOR_CLOSURE_2arg(VMin, schar, vminq_s8 (a, b));
FUNCTOR_CLOSURE_2arg(VMin, ushort, vminq_u16(a, b));
FUNCTOR_CLOSURE_2arg(VMin, short, vminq_s16(a, b));
FUNCTOR_CLOSURE_2arg(VMin, int, vminq_s32(a, b));
FUNCTOR_CLOSURE_2arg(VMin, float, vminq_f32(a, b));
FUNCTOR_TEMPLATE(VMax);
FUNCTOR_CLOSURE_2arg(VMax, uchar, vmaxq_u8 (a, b));
FUNCTOR_CLOSURE_2arg(VMax, schar, vmaxq_s8 (a, b));
FUNCTOR_CLOSURE_2arg(VMax, ushort, vmaxq_u16(a, b));
FUNCTOR_CLOSURE_2arg(VMax, short, vmaxq_s16(a, b));
FUNCTOR_CLOSURE_2arg(VMax, int, vmaxq_s32(a, b));
FUNCTOR_CLOSURE_2arg(VMax, float, vmaxq_f32(a, b));
FUNCTOR_TEMPLATE(VAbsDiff);
FUNCTOR_CLOSURE_2arg(VAbsDiff, uchar, vabdq_u8 (a, b));
FUNCTOR_CLOSURE_2arg(VAbsDiff, schar, vqabsq_s8 (vqsubq_s8(a, b)));
FUNCTOR_CLOSURE_2arg(VAbsDiff, ushort, vabdq_u16 (a, b));
FUNCTOR_CLOSURE_2arg(VAbsDiff, short, vqabsq_s16(vqsubq_s16(a, b)));
FUNCTOR_CLOSURE_2arg(VAbsDiff, int, vabdq_s32 (a, b));
FUNCTOR_CLOSURE_2arg(VAbsDiff, float, vabdq_f32 (a, b));
FUNCTOR_TEMPLATE(VAnd);
FUNCTOR_CLOSURE_2arg(VAnd, uchar, vandq_u8(a, b));
FUNCTOR_TEMPLATE(VOr);
FUNCTOR_CLOSURE_2arg(VOr , uchar, vorrq_u8(a, b));
FUNCTOR_TEMPLATE(VXor);
FUNCTOR_CLOSURE_2arg(VXor, uchar, veorq_u8(a, b));
FUNCTOR_TEMPLATE(VNot);
FUNCTOR_CLOSURE_1arg(VNot, uchar, vmvnq_u8(a ));
#endif
#if CV_SSE2 || CV_NEON
#define IF_SIMD(op) op
#else
#define IF_SIMD(op) NOP
#endif
template<> inline uchar OpAdd<uchar>::operator ()(uchar a, uchar b) const
{ return CV_FAST_CAST_8U(a + b); }
template<> inline uchar OpSub<uchar>::operator ()(uchar a, uchar b) const
{ return CV_FAST_CAST_8U(a - b); }
template<typename T> struct OpAbsDiff
{
typedef T type1;
typedef T type2;
typedef T rtype;
T operator()(T a, T b) const { return (T)std::abs(a - b); }
};
template<> inline short OpAbsDiff<short>::operator ()(short a, short b) const
{ return saturate_cast<short>(std::abs(a - b)); }
template<> inline schar OpAbsDiff<schar>::operator ()(schar a, schar b) const
{ return saturate_cast<schar>(std::abs(a - b)); }
template<typename T, typename WT=T> struct OpAbsDiffS
{
typedef T type1;
typedef WT type2;
typedef T rtype;
T operator()(T a, WT b) const { return saturate_cast<T>(std::abs(a - b)); }
};
template<typename T> struct OpAnd
{
typedef T type1;
typedef T type2;
typedef T rtype;
T operator()( T a, T b ) const { return a & b; }
};
template<typename T> struct OpOr
{
typedef T type1;
typedef T type2;
typedef T rtype;
T operator()( T a, T b ) const { return a | b; }
};
template<typename T> struct OpXor
{
typedef T type1;
typedef T type2;
typedef T rtype;
T operator()( T a, T b ) const { return a ^ b; }
};
template<typename T> struct OpNot
{
typedef T type1;
typedef T type2;
typedef T rtype;
T operator()( T a, T ) const { return ~a; }
};
#if (ARITHM_USE_IPP == 1)
static inline void fixSteps(Size sz, size_t elemSize, size_t& step1, size_t& step2, size_t& step)
{
if( sz.height == 1 )
step1 = step2 = step = sz.width*elemSize;
}
#endif
static void add8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiAdd_8u_C1RSfs(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz), 0))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<uchar, OpAdd<uchar>, IF_SIMD(VAdd<uchar>)>(src1, step1, src2, step2, dst, step, sz));
}
static void add8s( const schar* src1, size_t step1,
const schar* src2, size_t step2,
schar* dst, size_t step, Size sz, void* )
{
vBinOp<schar, OpAdd<schar>, IF_SIMD(VAdd<schar>)>(src1, step1, src2, step2, dst, step, sz);
}
static void add16u( const ushort* src1, size_t step1,
const ushort* src2, size_t step2,
ushort* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiAdd_16u_C1RSfs(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz), 0))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<ushort, OpAdd<ushort>, IF_SIMD(VAdd<ushort>)>(src1, step1, src2, step2, dst, step, sz));
}
static void add16s( const short* src1, size_t step1,
const short* src2, size_t step2,
short* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiAdd_16s_C1RSfs(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz), 0))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<short, OpAdd<short>, IF_SIMD(VAdd<short>)>(src1, step1, src2, step2, dst, step, sz));
}
static void add32s( const int* src1, size_t step1,
const int* src2, size_t step2,
int* dst, size_t step, Size sz, void* )
{
vBinOp32<int, OpAdd<int>, IF_SIMD(VAdd<int>)>(src1, step1, src2, step2, dst, step, sz);
}
static void add32f( const float* src1, size_t step1,
const float* src2, size_t step2,
float* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiAdd_32f_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz)))
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return;
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setIppErrorStatus();
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#endif
(vBinOp32<float, OpAdd<float>, IF_SIMD(VAdd<float>)>(src1, step1, src2, step2, dst, step, sz));
}
static void add64f( const double* src1, size_t step1,
const double* src2, size_t step2,
double* dst, size_t step, Size sz, void* )
{
vBinOp64<double, OpAdd<double>, IF_SIMD(VAdd<double>)>(src1, step1, src2, step2, dst, step, sz);
}
static void sub8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiSub_8u_C1RSfs(src2, (int)step2, src1, (int)step1, dst, (int)step, ippiSize(sz), 0))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<uchar, OpSub<uchar>, IF_SIMD(VSub<uchar>)>(src1, step1, src2, step2, dst, step, sz));
}
static void sub8s( const schar* src1, size_t step1,
const schar* src2, size_t step2,
schar* dst, size_t step, Size sz, void* )
{
vBinOp<schar, OpSub<schar>, IF_SIMD(VSub<schar>)>(src1, step1, src2, step2, dst, step, sz);
}
static void sub16u( const ushort* src1, size_t step1,
const ushort* src2, size_t step2,
ushort* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiSub_16u_C1RSfs(src2, (int)step2, src1, (int)step1, dst, (int)step, ippiSize(sz), 0))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<ushort, OpSub<ushort>, IF_SIMD(VSub<ushort>)>(src1, step1, src2, step2, dst, step, sz));
}
static void sub16s( const short* src1, size_t step1,
const short* src2, size_t step2,
short* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiSub_16s_C1RSfs(src2, (int)step2, src1, (int)step1, dst, (int)step, ippiSize(sz), 0))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<short, OpSub<short>, IF_SIMD(VSub<short>)>(src1, step1, src2, step2, dst, step, sz));
}
static void sub32s( const int* src1, size_t step1,
const int* src2, size_t step2,
int* dst, size_t step, Size sz, void* )
{
vBinOp32<int, OpSub<int>, IF_SIMD(VSub<int>)>(src1, step1, src2, step2, dst, step, sz);
}
static void sub32f( const float* src1, size_t step1,
const float* src2, size_t step2,
float* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiSub_32f_C1R(src2, (int)step2, src1, (int)step1, dst, (int)step, ippiSize(sz)))
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return;
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setIppErrorStatus();
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#endif
(vBinOp32<float, OpSub<float>, IF_SIMD(VSub<float>)>(src1, step1, src2, step2, dst, step, sz));
}
static void sub64f( const double* src1, size_t step1,
const double* src2, size_t step2,
double* dst, size_t step, Size sz, void* )
{
vBinOp64<double, OpSub<double>, IF_SIMD(VSub<double>)>(src1, step1, src2, step2, dst, step, sz);
}
template<> inline uchar OpMin<uchar>::operator ()(uchar a, uchar b) const { return CV_MIN_8U(a, b); }
template<> inline uchar OpMax<uchar>::operator ()(uchar a, uchar b) const { return CV_MAX_8U(a, b); }
static void max8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* )
{
#if (ARITHM_USE_IPP == 1)
uchar* s1 = (uchar*)src1;
uchar* s2 = (uchar*)src2;
uchar* d = dst;
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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int i = 0;
for(; i < sz.height; i++)
{
if (0 > ippsMaxEvery_8u(s1, s2, d, sz.width))
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break;
s1 += step1;
s2 += step2;
d += step;
}
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if (i == sz.height)
return;
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setIppErrorStatus();
#endif
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vBinOp<uchar, OpMax<uchar>, IF_SIMD(VMax<uchar>)>(src1, step1, src2, step2, dst, step, sz);
}
static void max8s( const schar* src1, size_t step1,
const schar* src2, size_t step2,
schar* dst, size_t step, Size sz, void* )
{
vBinOp<schar, OpMax<schar>, IF_SIMD(VMax<schar>)>(src1, step1, src2, step2, dst, step, sz);
}
static void max16u( const ushort* src1, size_t step1,
const ushort* src2, size_t step2,
ushort* dst, size_t step, Size sz, void* )
{
#if (ARITHM_USE_IPP == 1)
ushort* s1 = (ushort*)src1;
ushort* s2 = (ushort*)src2;
ushort* d = dst;
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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int i = 0;
for(; i < sz.height; i++)
{
if (0 > ippsMaxEvery_16u(s1, s2, d, sz.width))
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break;
s1 = (ushort*)((uchar*)s1 + step1);
s2 = (ushort*)((uchar*)s2 + step2);
d = (ushort*)((uchar*)d + step);
}
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if (i == sz.height)
return;
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setIppErrorStatus();
#endif
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vBinOp<ushort, OpMax<ushort>, IF_SIMD(VMax<ushort>)>(src1, step1, src2, step2, dst, step, sz);
}
static void max16s( const short* src1, size_t step1,
const short* src2, size_t step2,
short* dst, size_t step, Size sz, void* )
{
vBinOp<short, OpMax<short>, IF_SIMD(VMax<short>)>(src1, step1, src2, step2, dst, step, sz);
}
static void max32s( const int* src1, size_t step1,
const int* src2, size_t step2,
int* dst, size_t step, Size sz, void* )
{
vBinOp32<int, OpMax<int>, IF_SIMD(VMax<int>)>(src1, step1, src2, step2, dst, step, sz);
}
static void max32f( const float* src1, size_t step1,
const float* src2, size_t step2,
float* dst, size_t step, Size sz, void* )
{
#if (ARITHM_USE_IPP == 1)
float* s1 = (float*)src1;
float* s2 = (float*)src2;
float* d = dst;
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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int i = 0;
for(; i < sz.height; i++)
{
if (0 > ippsMaxEvery_32f(s1, s2, d, sz.width))
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break;
s1 = (float*)((uchar*)s1 + step1);
s2 = (float*)((uchar*)s2 + step2);
d = (float*)((uchar*)d + step);
}
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if (i == sz.height)
return;
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setIppErrorStatus();
#endif
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vBinOp32<float, OpMax<float>, IF_SIMD(VMax<float>)>(src1, step1, src2, step2, dst, step, sz);
}
static void max64f( const double* src1, size_t step1,
const double* src2, size_t step2,
double* dst, size_t step, Size sz, void* )
{
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#if ARITHM_USE_IPP == 1
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double* s1 = (double*)src1;
double* s2 = (double*)src2;
double* d = dst;
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
int i = 0;
for(; i < sz.height; i++)
{
if (0 > ippsMaxEvery_64f(s1, s2, d, sz.width))
break;
s1 = (double*)((uchar*)s1 + step1);
s2 = (double*)((uchar*)s2 + step2);
d = (double*)((uchar*)d + step);
}
if (i == sz.height)
return;
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setIppErrorStatus();
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#endif
vBinOp64<double, OpMax<double>, IF_SIMD(VMax<double>)>(src1, step1, src2, step2, dst, step, sz);
}
static void min8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* )
{
#if (ARITHM_USE_IPP == 1)
uchar* s1 = (uchar*)src1;
uchar* s2 = (uchar*)src2;
uchar* d = dst;
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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int i = 0;
for(; i < sz.height; i++)
{
if (0 > ippsMinEvery_8u(s1, s2, d, sz.width))
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break;
s1 += step1;
s2 += step2;
d += step;
}
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if (i == sz.height)
return;
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setIppErrorStatus();
#endif
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vBinOp<uchar, OpMin<uchar>, IF_SIMD(VMin<uchar>)>(src1, step1, src2, step2, dst, step, sz);
}
static void min8s( const schar* src1, size_t step1,
const schar* src2, size_t step2,
schar* dst, size_t step, Size sz, void* )
{
vBinOp<schar, OpMin<schar>, IF_SIMD(VMin<schar>)>(src1, step1, src2, step2, dst, step, sz);
}
static void min16u( const ushort* src1, size_t step1,
const ushort* src2, size_t step2,
ushort* dst, size_t step, Size sz, void* )
{
#if (ARITHM_USE_IPP == 1)
ushort* s1 = (ushort*)src1;
ushort* s2 = (ushort*)src2;
ushort* d = dst;
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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int i = 0;
for(; i < sz.height; i++)
{
if (0 > ippsMinEvery_16u(s1, s2, d, sz.width))
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break;
s1 = (ushort*)((uchar*)s1 + step1);
s2 = (ushort*)((uchar*)s2 + step2);
d = (ushort*)((uchar*)d + step);
}
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if (i == sz.height)
return;
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setIppErrorStatus();
#endif
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vBinOp<ushort, OpMin<ushort>, IF_SIMD(VMin<ushort>)>(src1, step1, src2, step2, dst, step, sz);
}
static void min16s( const short* src1, size_t step1,
const short* src2, size_t step2,
short* dst, size_t step, Size sz, void* )
{
vBinOp<short, OpMin<short>, IF_SIMD(VMin<short>)>(src1, step1, src2, step2, dst, step, sz);
}
static void min32s( const int* src1, size_t step1,
const int* src2, size_t step2,
int* dst, size_t step, Size sz, void* )
{
vBinOp32<int, OpMin<int>, IF_SIMD(VMin<int>)>(src1, step1, src2, step2, dst, step, sz);
}
static void min32f( const float* src1, size_t step1,
const float* src2, size_t step2,
float* dst, size_t step, Size sz, void* )
{
#if (ARITHM_USE_IPP == 1)
float* s1 = (float*)src1;
float* s2 = (float*)src2;
float* d = dst;
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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int i = 0;
for(; i < sz.height; i++)
{
if (0 > ippsMinEvery_32f(s1, s2, d, sz.width))
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break;
s1 = (float*)((uchar*)s1 + step1);
s2 = (float*)((uchar*)s2 + step2);
d = (float*)((uchar*)d + step);
}
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if (i == sz.height)
return;
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setIppErrorStatus();
#endif
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vBinOp32<float, OpMin<float>, IF_SIMD(VMin<float>)>(src1, step1, src2, step2, dst, step, sz);
}
static void min64f( const double* src1, size_t step1,
const double* src2, size_t step2,
double* dst, size_t step, Size sz, void* )
{
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#if ARITHM_USE_IPP == 1
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double* s1 = (double*)src1;
double* s2 = (double*)src2;
double* d = dst;
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
int i = 0;
for(; i < sz.height; i++)
{
if (0 > ippsMinEvery_64f(s1, s2, d, sz.width))
break;
s1 = (double*)((uchar*)s1 + step1);
s2 = (double*)((uchar*)s2 + step2);
d = (double*)((uchar*)d + step);
}
if (i == sz.height)
return;
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setIppErrorStatus();
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#endif
vBinOp64<double, OpMin<double>, IF_SIMD(VMin<double>)>(src1, step1, src2, step2, dst, step, sz);
}
static void absdiff8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiAbsDiff_8u_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz)))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<uchar, OpAbsDiff<uchar>, IF_SIMD(VAbsDiff<uchar>)>(src1, step1, src2, step2, dst, step, sz));
}
static void absdiff8s( const schar* src1, size_t step1,
const schar* src2, size_t step2,
schar* dst, size_t step, Size sz, void* )
{
vBinOp<schar, OpAbsDiff<schar>, IF_SIMD(VAbsDiff<schar>)>(src1, step1, src2, step2, dst, step, sz);
}
static void absdiff16u( const ushort* src1, size_t step1,
const ushort* src2, size_t step2,
ushort* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiAbsDiff_16u_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz)))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<ushort, OpAbsDiff<ushort>, IF_SIMD(VAbsDiff<ushort>)>(src1, step1, src2, step2, dst, step, sz));
}
static void absdiff16s( const short* src1, size_t step1,
const short* src2, size_t step2,
short* dst, size_t step, Size sz, void* )
{
vBinOp<short, OpAbsDiff<short>, IF_SIMD(VAbsDiff<short>)>(src1, step1, src2, step2, dst, step, sz);
}
static void absdiff32s( const int* src1, size_t step1,
const int* src2, size_t step2,
int* dst, size_t step, Size sz, void* )
{
vBinOp32<int, OpAbsDiff<int>, IF_SIMD(VAbsDiff<int>)>(src1, step1, src2, step2, dst, step, sz);
}
static void absdiff32f( const float* src1, size_t step1,
const float* src2, size_t step2,
float* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiAbsDiff_32f_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz)))
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return;
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setIppErrorStatus();
2014-03-21 19:27:56 +08:00
#endif
(vBinOp32<float, OpAbsDiff<float>, IF_SIMD(VAbsDiff<float>)>(src1, step1, src2, step2, dst, step, sz));
}
static void absdiff64f( const double* src1, size_t step1,
const double* src2, size_t step2,
double* dst, size_t step, Size sz, void* )
{
vBinOp64<double, OpAbsDiff<double>, IF_SIMD(VAbsDiff<double>)>(src1, step1, src2, step2, dst, step, sz);
}
static void and8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiAnd_8u_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz)))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<uchar, OpAnd<uchar>, IF_SIMD(VAnd<uchar>)>(src1, step1, src2, step2, dst, step, sz));
}
static void or8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiOr_8u_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz)))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<uchar, OpOr<uchar>, IF_SIMD(VOr<uchar>)>(src1, step1, src2, step2, dst, step, sz));
}
static void xor8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
fixSteps(sz, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiXor_8u_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz)))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<uchar, OpXor<uchar>, IF_SIMD(VXor<uchar>)>(src1, step1, src2, step2, dst, step, sz));
}
static void not8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* )
{
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#if (ARITHM_USE_IPP == 1)
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fixSteps(sz, sizeof(dst[0]), step1, step2, step); (void)src2;
if (0 <= ippiNot_8u_C1R(src1, (int)step1, dst, (int)step, ippiSize(sz)))
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return;
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setIppErrorStatus();
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#endif
(vBinOp<uchar, OpNot<uchar>, IF_SIMD(VNot<uchar>)>(src1, step1, src2, step2, dst, step, sz));
}
/****************************************************************************************\
* logical operations *
\****************************************************************************************/
void convertAndUnrollScalar( const Mat& sc, int buftype, uchar* scbuf, size_t blocksize )
{
int scn = (int)sc.total(), cn = CV_MAT_CN(buftype);
size_t esz = CV_ELEM_SIZE(buftype);
getConvertFunc(sc.depth(), buftype)(sc.ptr(), 1, 0, 1, scbuf, 1, Size(std::min(cn, scn), 1), 0);
// unroll the scalar
if( scn < cn )
{
CV_Assert( scn == 1 );
size_t esz1 = CV_ELEM_SIZE1(buftype);
for( size_t i = esz1; i < esz; i++ )
scbuf[i] = scbuf[i - esz1];
}
for( size_t i = esz; i < blocksize*esz; i++ )
scbuf[i] = scbuf[i - esz];
}
enum { OCL_OP_ADD=0, OCL_OP_SUB=1, OCL_OP_RSUB=2, OCL_OP_ABSDIFF=3, OCL_OP_MUL=4,
OCL_OP_MUL_SCALE=5, OCL_OP_DIV_SCALE=6, OCL_OP_RECIP_SCALE=7, OCL_OP_ADDW=8,
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OCL_OP_AND=9, OCL_OP_OR=10, OCL_OP_XOR=11, OCL_OP_NOT=12, OCL_OP_MIN=13, OCL_OP_MAX=14,
OCL_OP_RDIV_SCALE=15 };
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#ifdef HAVE_OPENCL
static const char* oclop2str[] = { "OP_ADD", "OP_SUB", "OP_RSUB", "OP_ABSDIFF",
"OP_MUL", "OP_MUL_SCALE", "OP_DIV_SCALE", "OP_RECIP_SCALE",
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"OP_ADDW", "OP_AND", "OP_OR", "OP_XOR", "OP_NOT", "OP_MIN", "OP_MAX", "OP_RDIV_SCALE", 0 };
static bool ocl_binary_op(InputArray _src1, InputArray _src2, OutputArray _dst,
InputArray _mask, bool bitwise, int oclop, bool haveScalar )
{
bool haveMask = !_mask.empty();
int srctype = _src1.type();
int srcdepth = CV_MAT_DEPTH(srctype);
int cn = CV_MAT_CN(srctype);
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const ocl::Device d = ocl::Device::getDefault();
bool doubleSupport = d.doubleFPConfig() > 0;
if( oclop < 0 || ((haveMask || haveScalar) && cn > 4) ||
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(!doubleSupport && srcdepth == CV_64F && !bitwise))
return false;
char opts[1024];
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int kercn = haveMask || haveScalar ? cn : ocl::predictOptimalVectorWidth(_src1, _src2, _dst);
int scalarcn = kercn == 3 ? 4 : kercn;
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int rowsPerWI = d.isIntel() ? 4 : 1;
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sprintf(opts, "-D %s%s -D %s -D dstT=%s%s -D dstT_C1=%s -D workST=%s -D cn=%d -D rowsPerWI=%d",
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haveMask ? "MASK_" : "", haveScalar ? "UNARY_OP" : "BINARY_OP", oclop2str[oclop],
bitwise ? ocl::memopTypeToStr(CV_MAKETYPE(srcdepth, kercn)) :
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ocl::typeToStr(CV_MAKETYPE(srcdepth, kercn)), doubleSupport ? " -D DOUBLE_SUPPORT" : "",
bitwise ? ocl::memopTypeToStr(CV_MAKETYPE(srcdepth, 1)) :
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ocl::typeToStr(CV_MAKETYPE(srcdepth, 1)),
bitwise ? ocl::memopTypeToStr(CV_MAKETYPE(srcdepth, scalarcn)) :
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ocl::typeToStr(CV_MAKETYPE(srcdepth, scalarcn)),
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kercn, rowsPerWI);
ocl::Kernel k("KF", ocl::core::arithm_oclsrc, opts);
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if (k.empty())
return false;
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UMat src1 = _src1.getUMat(), src2;
UMat dst = _dst.getUMat(), mask = _mask.getUMat();
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ocl::KernelArg src1arg = ocl::KernelArg::ReadOnlyNoSize(src1, cn, kercn);
ocl::KernelArg dstarg = haveMask ? ocl::KernelArg::ReadWrite(dst, cn, kercn) :
ocl::KernelArg::WriteOnly(dst, cn, kercn);
ocl::KernelArg maskarg = ocl::KernelArg::ReadOnlyNoSize(mask, 1);
if( haveScalar )
{
size_t esz = CV_ELEM_SIZE1(srctype)*scalarcn;
double buf[4] = {0,0,0,0};
if( oclop != OCL_OP_NOT )
{
Mat src2sc = _src2.getMat();
convertAndUnrollScalar(src2sc, srctype, (uchar*)buf, 1);
}
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ocl::KernelArg scalararg = ocl::KernelArg(0, 0, 0, 0, buf, esz);
if( !haveMask )
k.args(src1arg, dstarg, scalararg);
else
k.args(src1arg, maskarg, dstarg, scalararg);
}
else
{
src2 = _src2.getUMat();
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ocl::KernelArg src2arg = ocl::KernelArg::ReadOnlyNoSize(src2, cn, kercn);
if( !haveMask )
k.args(src1arg, src2arg, dstarg);
else
k.args(src1arg, src2arg, maskarg, dstarg);
}
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size_t globalsize[] = { src1.cols * cn / kercn, (src1.rows + rowsPerWI - 1) / rowsPerWI };
return k.run(2, globalsize, 0, false);
}
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#endif
static void binary_op( InputArray _src1, InputArray _src2, OutputArray _dst,
InputArray _mask, const BinaryFunc* tab,
bool bitwise, int oclop )
{
const _InputArray *psrc1 = &_src1, *psrc2 = &_src2;
int kind1 = psrc1->kind(), kind2 = psrc2->kind();
int type1 = psrc1->type(), depth1 = CV_MAT_DEPTH(type1), cn = CV_MAT_CN(type1);
int type2 = psrc2->type(), depth2 = CV_MAT_DEPTH(type2), cn2 = CV_MAT_CN(type2);
int dims1 = psrc1->dims(), dims2 = psrc2->dims();
Size sz1 = dims1 <= 2 ? psrc1->size() : Size();
Size sz2 = dims2 <= 2 ? psrc2->size() : Size();
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#ifdef HAVE_OPENCL
bool use_opencl = (kind1 == _InputArray::UMAT || kind2 == _InputArray::UMAT) &&
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dims1 <= 2 && dims2 <= 2;
#endif
bool haveMask = !_mask.empty(), haveScalar = false;
BinaryFunc func;
if( dims1 <= 2 && dims2 <= 2 && kind1 == kind2 && sz1 == sz2 && type1 == type2 && !haveMask )
{
_dst.create(sz1, type1);
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CV_OCL_RUN(use_opencl,
ocl_binary_op(*psrc1, *psrc2, _dst, _mask, bitwise, oclop, false))
if( bitwise )
{
func = *tab;
cn = (int)CV_ELEM_SIZE(type1);
}
else
func = tab[depth1];
Mat src1 = psrc1->getMat(), src2 = psrc2->getMat(), dst = _dst.getMat();
Size sz = getContinuousSize(src1, src2, dst);
size_t len = sz.width*(size_t)cn;
if( len == (size_t)(int)len )
{
sz.width = (int)len;
func(src1.ptr(), src1.step, src2.ptr(), src2.step, dst.ptr(), dst.step, sz, 0);
return;
}
}
if( oclop == OCL_OP_NOT )
haveScalar = true;
else if( (kind1 == _InputArray::MATX) + (kind2 == _InputArray::MATX) == 1 ||
!psrc1->sameSize(*psrc2) || type1 != type2 )
{
if( checkScalar(*psrc1, type2, kind1, kind2) )
{
// src1 is a scalar; swap it with src2
swap(psrc1, psrc2);
swap(type1, type2);
swap(depth1, depth2);
swap(cn, cn2);
swap(sz1, sz2);
}
else if( !checkScalar(*psrc2, type1, kind2, kind1) )
CV_Error( CV_StsUnmatchedSizes,
"The operation is neither 'array op array' (where arrays have the same size and type), "
"nor 'array op scalar', nor 'scalar op array'" );
haveScalar = true;
}
else
{
CV_Assert( psrc1->sameSize(*psrc2) && type1 == type2 );
}
size_t esz = CV_ELEM_SIZE(type1);
size_t blocksize0 = (BLOCK_SIZE + esz-1)/esz;
BinaryFunc copymask = 0;
bool reallocate = false;
if( haveMask )
{
int mtype = _mask.type();
CV_Assert( (mtype == CV_8U || mtype == CV_8S) && _mask.sameSize(*psrc1));
copymask = getCopyMaskFunc(esz);
reallocate = !_dst.sameSize(*psrc1) || _dst.type() != type1;
}
AutoBuffer<uchar> _buf;
uchar *scbuf = 0, *maskbuf = 0;
_dst.createSameSize(*psrc1, type1);
// if this is mask operation and dst has been reallocated,
// we have to clear the destination
if( haveMask && reallocate )
_dst.setTo(0.);
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CV_OCL_RUN(use_opencl,
ocl_binary_op(*psrc1, *psrc2, _dst, _mask, bitwise, oclop, haveScalar))
Mat src1 = psrc1->getMat(), src2 = psrc2->getMat();
Mat dst = _dst.getMat(), mask = _mask.getMat();
if( bitwise )
{
func = *tab;
cn = (int)esz;
}
else
func = tab[depth1];
if( !haveScalar )
{
const Mat* arrays[] = { &src1, &src2, &dst, &mask, 0 };
uchar* ptrs[4];
NAryMatIterator it(arrays, ptrs);
size_t total = it.size, blocksize = total;
if( blocksize*cn > INT_MAX )
blocksize = INT_MAX/cn;
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if( haveMask )
{
blocksize = std::min(blocksize, blocksize0);
_buf.allocate(blocksize*esz);
maskbuf = _buf;
}
for( size_t i = 0; i < it.nplanes; i++, ++it )
{
for( size_t j = 0; j < total; j += blocksize )
{
int bsz = (int)MIN(total - j, blocksize);
func( ptrs[0], 0, ptrs[1], 0, haveMask ? maskbuf : ptrs[2], 0, Size(bsz*cn, 1), 0 );
if( haveMask )
{
copymask( maskbuf, 0, ptrs[3], 0, ptrs[2], 0, Size(bsz, 1), &esz );
ptrs[3] += bsz;
}
bsz *= (int)esz;
ptrs[0] += bsz; ptrs[1] += bsz; ptrs[2] += bsz;
}
}
}
else
{
const Mat* arrays[] = { &src1, &dst, &mask, 0 };
uchar* ptrs[3];
NAryMatIterator it(arrays, ptrs);
size_t total = it.size, blocksize = std::min(total, blocksize0);
_buf.allocate(blocksize*(haveMask ? 2 : 1)*esz + 32);
scbuf = _buf;
maskbuf = alignPtr(scbuf + blocksize*esz, 16);
convertAndUnrollScalar( src2, src1.type(), scbuf, blocksize);
for( size_t i = 0; i < it.nplanes; i++, ++it )
{
for( size_t j = 0; j < total; j += blocksize )
{
int bsz = (int)MIN(total - j, blocksize);
func( ptrs[0], 0, scbuf, 0, haveMask ? maskbuf : ptrs[1], 0, Size(bsz*cn, 1), 0 );
if( haveMask )
{
copymask( maskbuf, 0, ptrs[2], 0, ptrs[1], 0, Size(bsz, 1), &esz );
ptrs[2] += bsz;
}
bsz *= (int)esz;
ptrs[0] += bsz; ptrs[1] += bsz;
}
}
}
}
static BinaryFunc* getMaxTab()
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{
static BinaryFunc maxTab[] =
{
(BinaryFunc)GET_OPTIMIZED(max8u), (BinaryFunc)GET_OPTIMIZED(max8s),
(BinaryFunc)GET_OPTIMIZED(max16u), (BinaryFunc)GET_OPTIMIZED(max16s),
(BinaryFunc)GET_OPTIMIZED(max32s),
(BinaryFunc)GET_OPTIMIZED(max32f), (BinaryFunc)max64f,
0
};
return maxTab;
}
static BinaryFunc* getMinTab()
{
static BinaryFunc minTab[] =
{
(BinaryFunc)GET_OPTIMIZED(min8u), (BinaryFunc)GET_OPTIMIZED(min8s),
(BinaryFunc)GET_OPTIMIZED(min16u), (BinaryFunc)GET_OPTIMIZED(min16s),
(BinaryFunc)GET_OPTIMIZED(min32s),
(BinaryFunc)GET_OPTIMIZED(min32f), (BinaryFunc)min64f,
0
};
return minTab;
}
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}
void cv::bitwise_and(InputArray a, InputArray b, OutputArray c, InputArray mask)
{
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BinaryFunc f = (BinaryFunc)GET_OPTIMIZED(and8u);
binary_op(a, b, c, mask, &f, true, OCL_OP_AND);
}
void cv::bitwise_or(InputArray a, InputArray b, OutputArray c, InputArray mask)
{
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BinaryFunc f = (BinaryFunc)GET_OPTIMIZED(or8u);
binary_op(a, b, c, mask, &f, true, OCL_OP_OR);
}
void cv::bitwise_xor(InputArray a, InputArray b, OutputArray c, InputArray mask)
{
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BinaryFunc f = (BinaryFunc)GET_OPTIMIZED(xor8u);
binary_op(a, b, c, mask, &f, true, OCL_OP_XOR);
}
void cv::bitwise_not(InputArray a, OutputArray c, InputArray mask)
{
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BinaryFunc f = (BinaryFunc)GET_OPTIMIZED(not8u);
binary_op(a, a, c, mask, &f, true, OCL_OP_NOT);
}
void cv::max( InputArray src1, InputArray src2, OutputArray dst )
{
binary_op(src1, src2, dst, noArray(), getMaxTab(), false, OCL_OP_MAX );
}
void cv::min( InputArray src1, InputArray src2, OutputArray dst )
{
binary_op(src1, src2, dst, noArray(), getMinTab(), false, OCL_OP_MIN );
}
void cv::max(const Mat& src1, const Mat& src2, Mat& dst)
{
OutputArray _dst(dst);
binary_op(src1, src2, _dst, noArray(), getMaxTab(), false, OCL_OP_MAX );
}
void cv::min(const Mat& src1, const Mat& src2, Mat& dst)
{
OutputArray _dst(dst);
binary_op(src1, src2, _dst, noArray(), getMinTab(), false, OCL_OP_MIN );
}
void cv::max(const UMat& src1, const UMat& src2, UMat& dst)
{
OutputArray _dst(dst);
binary_op(src1, src2, _dst, noArray(), getMaxTab(), false, OCL_OP_MAX );
}
void cv::min(const UMat& src1, const UMat& src2, UMat& dst)
{
OutputArray _dst(dst);
binary_op(src1, src2, _dst, noArray(), getMinTab(), false, OCL_OP_MIN );
}
/****************************************************************************************\
* add/subtract *
\****************************************************************************************/
namespace cv
{
static int actualScalarDepth(const double* data, int len)
{
int i = 0, minval = INT_MAX, maxval = INT_MIN;
for(; i < len; ++i)
{
int ival = cvRound(data[i]);
if( ival != data[i] )
break;
minval = MIN(minval, ival);
maxval = MAX(maxval, ival);
}
return i < len ? CV_64F :
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minval >= 0 && maxval <= (int)UCHAR_MAX ? CV_8U :
minval >= (int)SCHAR_MIN && maxval <= (int)SCHAR_MAX ? CV_8S :
minval >= 0 && maxval <= (int)USHRT_MAX ? CV_16U :
minval >= (int)SHRT_MIN && maxval <= (int)SHRT_MAX ? CV_16S :
CV_32S;
}
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#ifdef HAVE_OPENCL
static bool ocl_arithm_op(InputArray _src1, InputArray _src2, OutputArray _dst,
InputArray _mask, int wtype,
void* usrdata, int oclop,
bool haveScalar )
{
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const ocl::Device d = ocl::Device::getDefault();
bool doubleSupport = d.doubleFPConfig() > 0;
int type1 = _src1.type(), depth1 = CV_MAT_DEPTH(type1), cn = CV_MAT_CN(type1);
bool haveMask = !_mask.empty();
if ( (haveMask || haveScalar) && cn > 4 )
return false;
int dtype = _dst.type(), ddepth = CV_MAT_DEPTH(dtype), wdepth = std::max(CV_32S, CV_MAT_DEPTH(wtype));
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if (!doubleSupport)
wdepth = std::min(wdepth, CV_32F);
wtype = CV_MAKETYPE(wdepth, cn);
int type2 = haveScalar ? wtype : _src2.type(), depth2 = CV_MAT_DEPTH(type2);
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if (!doubleSupport && (depth2 == CV_64F || depth1 == CV_64F))
return false;
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int kercn = haveMask || haveScalar ? cn : ocl::predictOptimalVectorWidth(_src1, _src2, _dst);
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int scalarcn = kercn == 3 ? 4 : kercn, rowsPerWI = d.isIntel() ? 4 : 1;
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char cvtstr[4][32], opts[1024];
sprintf(opts, "-D %s%s -D %s -D srcT1=%s -D srcT1_C1=%s -D srcT2=%s -D srcT2_C1=%s "
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"-D dstT=%s -D dstT_C1=%s -D workT=%s -D workST=%s -D scaleT=%s -D wdepth=%d -D convertToWT1=%s "
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"-D convertToWT2=%s -D convertToDT=%s%s -D cn=%d -D rowsPerWI=%d -D convertFromU=%s",
(haveMask ? "MASK_" : ""), (haveScalar ? "UNARY_OP" : "BINARY_OP"),
oclop2str[oclop], ocl::typeToStr(CV_MAKETYPE(depth1, kercn)),
ocl::typeToStr(depth1), ocl::typeToStr(CV_MAKETYPE(depth2, kercn)),
ocl::typeToStr(depth2), ocl::typeToStr(CV_MAKETYPE(ddepth, kercn)),
ocl::typeToStr(ddepth), ocl::typeToStr(CV_MAKETYPE(wdepth, kercn)),
ocl::typeToStr(CV_MAKETYPE(wdepth, scalarcn)),
ocl::typeToStr(wdepth), wdepth,
ocl::convertTypeStr(depth1, wdepth, kercn, cvtstr[0]),
ocl::convertTypeStr(depth2, wdepth, kercn, cvtstr[1]),
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ocl::convertTypeStr(wdepth, ddepth, kercn, cvtstr[2]),
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doubleSupport ? " -D DOUBLE_SUPPORT" : "", kercn, rowsPerWI,
oclop == OCL_OP_ABSDIFF && wdepth == CV_32S && ddepth == wdepth ?
ocl::convertTypeStr(CV_8U, ddepth, kercn, cvtstr[3]) : "noconvert");
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size_t usrdata_esz = CV_ELEM_SIZE(wdepth);
const uchar* usrdata_p = (const uchar*)usrdata;
const double* usrdata_d = (const double*)usrdata;
float usrdata_f[3];
int i, n = oclop == OCL_OP_MUL_SCALE || oclop == OCL_OP_DIV_SCALE ||
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oclop == OCL_OP_RDIV_SCALE || oclop == OCL_OP_RECIP_SCALE ? 1 : oclop == OCL_OP_ADDW ? 3 : 0;
if( n > 0 && wdepth == CV_32F )
{
for( i = 0; i < n; i++ )
usrdata_f[i] = (float)usrdata_d[i];
usrdata_p = (const uchar*)usrdata_f;
}
ocl::Kernel k("KF", ocl::core::arithm_oclsrc, opts);
if (k.empty())
return false;
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UMat src1 = _src1.getUMat(), src2;
UMat dst = _dst.getUMat(), mask = _mask.getUMat();
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ocl::KernelArg src1arg = ocl::KernelArg::ReadOnlyNoSize(src1, cn, kercn);
ocl::KernelArg dstarg = haveMask ? ocl::KernelArg::ReadWrite(dst, cn, kercn) :
ocl::KernelArg::WriteOnly(dst, cn, kercn);
ocl::KernelArg maskarg = ocl::KernelArg::ReadOnlyNoSize(mask, 1);
if( haveScalar )
{
size_t esz = CV_ELEM_SIZE1(wtype)*scalarcn;
double buf[4]={0,0,0,0};
Mat src2sc = _src2.getMat();
if( !src2sc.empty() )
convertAndUnrollScalar(src2sc, wtype, (uchar*)buf, 1);
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ocl::KernelArg scalararg = ocl::KernelArg(0, 0, 0, 0, buf, esz);
if( !haveMask )
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{
if(n == 0)
k.args(src1arg, dstarg, scalararg);
else if(n == 1)
k.args(src1arg, dstarg, scalararg,
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ocl::KernelArg(0, 0, 0, 0, usrdata_p, usrdata_esz));
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else
CV_Error(Error::StsNotImplemented, "unsupported number of extra parameters");
}
else
k.args(src1arg, maskarg, dstarg, scalararg);
}
else
{
src2 = _src2.getUMat();
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ocl::KernelArg src2arg = ocl::KernelArg::ReadOnlyNoSize(src2, cn, kercn);
if( !haveMask )
{
if (n == 0)
k.args(src1arg, src2arg, dstarg);
else if (n == 1)
k.args(src1arg, src2arg, dstarg,
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ocl::KernelArg(0, 0, 0, 0, usrdata_p, usrdata_esz));
else if (n == 3)
k.args(src1arg, src2arg, dstarg,
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ocl::KernelArg(0, 0, 0, 0, usrdata_p, usrdata_esz),
ocl::KernelArg(0, 0, 0, 0, usrdata_p + usrdata_esz, usrdata_esz),
ocl::KernelArg(0, 0, 0, 0, usrdata_p + usrdata_esz*2, usrdata_esz));
else
CV_Error(Error::StsNotImplemented, "unsupported number of extra parameters");
}
else
k.args(src1arg, src2arg, maskarg, dstarg);
}
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size_t globalsize[] = { src1.cols * cn / kercn, (src1.rows + rowsPerWI - 1) / rowsPerWI };
return k.run(2, globalsize, NULL, false);
}
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#endif
static void arithm_op(InputArray _src1, InputArray _src2, OutputArray _dst,
InputArray _mask, int dtype, BinaryFunc* tab, bool muldiv=false,
void* usrdata=0, int oclop=-1 )
{
const _InputArray *psrc1 = &_src1, *psrc2 = &_src2;
int kind1 = psrc1->kind(), kind2 = psrc2->kind();
bool haveMask = !_mask.empty();
bool reallocate = false;
int type1 = psrc1->type(), depth1 = CV_MAT_DEPTH(type1), cn = CV_MAT_CN(type1);
int type2 = psrc2->type(), depth2 = CV_MAT_DEPTH(type2), cn2 = CV_MAT_CN(type2);
int wtype, dims1 = psrc1->dims(), dims2 = psrc2->dims();
Size sz1 = dims1 <= 2 ? psrc1->size() : Size();
Size sz2 = dims2 <= 2 ? psrc2->size() : Size();
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#ifdef HAVE_OPENCL
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bool use_opencl = OCL_PERFORMANCE_CHECK(_dst.isUMat()) && dims1 <= 2 && dims2 <= 2;
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#endif
bool src1Scalar = checkScalar(*psrc1, type2, kind1, kind2);
bool src2Scalar = checkScalar(*psrc2, type1, kind2, kind1);
if( (kind1 == kind2 || cn == 1) && sz1 == sz2 && dims1 <= 2 && dims2 <= 2 && type1 == type2 &&
!haveMask && ((!_dst.fixedType() && (dtype < 0 || CV_MAT_DEPTH(dtype) == depth1)) ||
(_dst.fixedType() && _dst.type() == type1)) &&
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((src1Scalar && src2Scalar) || (!src1Scalar && !src2Scalar)) )
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{
_dst.createSameSize(*psrc1, type1);
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CV_OCL_RUN(use_opencl,
ocl_arithm_op(*psrc1, *psrc2, _dst, _mask,
(!usrdata ? type1 : std::max(depth1, CV_32F)),
usrdata, oclop, false))
Mat src1 = psrc1->getMat(), src2 = psrc2->getMat(), dst = _dst.getMat();
Size sz = getContinuousSize(src1, src2, dst, src1.channels());
tab[depth1](src1.ptr(), src1.step, src2.ptr(), src2.step, dst.ptr(), dst.step, sz, usrdata);
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return;
}
bool haveScalar = false, swapped12 = false;
if( dims1 != dims2 || sz1 != sz2 || cn != cn2 ||
(kind1 == _InputArray::MATX && (sz1 == Size(1,4) || sz1 == Size(1,1))) ||
(kind2 == _InputArray::MATX && (sz2 == Size(1,4) || sz2 == Size(1,1))) )
{
if( checkScalar(*psrc1, type2, kind1, kind2) )
{
// src1 is a scalar; swap it with src2
swap(psrc1, psrc2);
swap(sz1, sz2);
swap(type1, type2);
swap(depth1, depth2);
swap(cn, cn2);
swap(dims1, dims2);
swapped12 = true;
if( oclop == OCL_OP_SUB )
oclop = OCL_OP_RSUB;
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if ( oclop == OCL_OP_DIV_SCALE )
oclop = OCL_OP_RDIV_SCALE;
}
else if( !checkScalar(*psrc2, type1, kind2, kind1) )
CV_Error( CV_StsUnmatchedSizes,
"The operation is neither 'array op array' "
"(where arrays have the same size and the same number of channels), "
"nor 'array op scalar', nor 'scalar op array'" );
haveScalar = true;
CV_Assert(type2 == CV_64F && (sz2.height == 1 || sz2.height == 4));
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if (!muldiv)
{
Mat sc = psrc2->getMat();
depth2 = actualScalarDepth(sc.ptr<double>(), cn);
if( depth2 == CV_64F && (depth1 < CV_32S || depth1 == CV_32F) )
depth2 = CV_32F;
}
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else
depth2 = CV_64F;
}
if( dtype < 0 )
{
if( _dst.fixedType() )
dtype = _dst.type();
else
{
if( !haveScalar && type1 != type2 )
CV_Error(CV_StsBadArg,
"When the input arrays in add/subtract/multiply/divide functions have different types, "
"the output array type must be explicitly specified");
dtype = type1;
}
}
dtype = CV_MAT_DEPTH(dtype);
if( depth1 == depth2 && dtype == depth1 )
wtype = dtype;
else if( !muldiv )
{
wtype = depth1 <= CV_8S && depth2 <= CV_8S ? CV_16S :
depth1 <= CV_32S && depth2 <= CV_32S ? CV_32S : std::max(depth1, depth2);
wtype = std::max(wtype, dtype);
// when the result of addition should be converted to an integer type,
// and just one of the input arrays is floating-point, it makes sense to convert that input to integer type before the operation,
// instead of converting the other input to floating-point and then converting the operation result back to integers.
if( dtype < CV_32F && (depth1 < CV_32F || depth2 < CV_32F) )
wtype = CV_32S;
}
else
{
wtype = std::max(depth1, std::max(depth2, CV_32F));
wtype = std::max(wtype, dtype);
}
dtype = CV_MAKETYPE(dtype, cn);
wtype = CV_MAKETYPE(wtype, cn);
if( haveMask )
{
int mtype = _mask.type();
CV_Assert( (mtype == CV_8UC1 || mtype == CV_8SC1) && _mask.sameSize(*psrc1) );
reallocate = !_dst.sameSize(*psrc1) || _dst.type() != dtype;
}
_dst.createSameSize(*psrc1, dtype);
if( reallocate )
_dst.setTo(0.);
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CV_OCL_RUN(use_opencl,
ocl_arithm_op(*psrc1, *psrc2, _dst, _mask, wtype,
usrdata, oclop, haveScalar))
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BinaryFunc cvtsrc1 = type1 == wtype ? 0 : getConvertFunc(type1, wtype);
BinaryFunc cvtsrc2 = type2 == type1 ? cvtsrc1 : type2 == wtype ? 0 : getConvertFunc(type2, wtype);
BinaryFunc cvtdst = dtype == wtype ? 0 : getConvertFunc(wtype, dtype);
size_t esz1 = CV_ELEM_SIZE(type1), esz2 = CV_ELEM_SIZE(type2);
size_t dsz = CV_ELEM_SIZE(dtype), wsz = CV_ELEM_SIZE(wtype);
size_t blocksize0 = (size_t)(BLOCK_SIZE + wsz-1)/wsz;
BinaryFunc copymask = getCopyMaskFunc(dsz);
Mat src1 = psrc1->getMat(), src2 = psrc2->getMat(), dst = _dst.getMat(), mask = _mask.getMat();
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AutoBuffer<uchar> _buf;
uchar *buf, *maskbuf = 0, *buf1 = 0, *buf2 = 0, *wbuf = 0;
size_t bufesz = (cvtsrc1 ? wsz : 0) +
(cvtsrc2 || haveScalar ? wsz : 0) +
(cvtdst ? wsz : 0) +
(haveMask ? dsz : 0);
BinaryFunc func = tab[CV_MAT_DEPTH(wtype)];
if( !haveScalar )
{
const Mat* arrays[] = { &src1, &src2, &dst, &mask, 0 };
uchar* ptrs[4];
NAryMatIterator it(arrays, ptrs);
size_t total = it.size, blocksize = total;
if( haveMask || cvtsrc1 || cvtsrc2 || cvtdst )
blocksize = std::min(blocksize, blocksize0);
_buf.allocate(bufesz*blocksize + 64);
buf = _buf;
if( cvtsrc1 )
buf1 = buf, buf = alignPtr(buf + blocksize*wsz, 16);
if( cvtsrc2 )
buf2 = buf, buf = alignPtr(buf + blocksize*wsz, 16);
wbuf = maskbuf = buf;
if( cvtdst )
buf = alignPtr(buf + blocksize*wsz, 16);
if( haveMask )
maskbuf = buf;
for( size_t i = 0; i < it.nplanes; i++, ++it )
{
for( size_t j = 0; j < total; j += blocksize )
{
int bsz = (int)MIN(total - j, blocksize);
Size bszn(bsz*cn, 1);
const uchar *sptr1 = ptrs[0], *sptr2 = ptrs[1];
uchar* dptr = ptrs[2];
if( cvtsrc1 )
{
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cvtsrc1( sptr1, 1, 0, 1, buf1, 1, bszn, 0 );
sptr1 = buf1;
}
if( ptrs[0] == ptrs[1] )
sptr2 = sptr1;
else if( cvtsrc2 )
{
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cvtsrc2( sptr2, 1, 0, 1, buf2, 1, bszn, 0 );
sptr2 = buf2;
}
if( !haveMask && !cvtdst )
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func( sptr1, 1, sptr2, 1, dptr, 1, bszn, usrdata );
else
{
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func( sptr1, 1, sptr2, 1, wbuf, 0, bszn, usrdata );
if( !haveMask )
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cvtdst( wbuf, 1, 0, 1, dptr, 1, bszn, 0 );
else if( !cvtdst )
{
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copymask( wbuf, 1, ptrs[3], 1, dptr, 1, Size(bsz, 1), &dsz );
ptrs[3] += bsz;
}
else
{
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cvtdst( wbuf, 1, 0, 1, maskbuf, 1, bszn, 0 );
copymask( maskbuf, 1, ptrs[3], 1, dptr, 1, Size(bsz, 1), &dsz );
ptrs[3] += bsz;
}
}
ptrs[0] += bsz*esz1; ptrs[1] += bsz*esz2; ptrs[2] += bsz*dsz;
}
}
}
else
{
const Mat* arrays[] = { &src1, &dst, &mask, 0 };
uchar* ptrs[3];
NAryMatIterator it(arrays, ptrs);
size_t total = it.size, blocksize = std::min(total, blocksize0);
_buf.allocate(bufesz*blocksize + 64);
buf = _buf;
if( cvtsrc1 )
buf1 = buf, buf = alignPtr(buf + blocksize*wsz, 16);
buf2 = buf; buf = alignPtr(buf + blocksize*wsz, 16);
wbuf = maskbuf = buf;
if( cvtdst )
buf = alignPtr(buf + blocksize*wsz, 16);
if( haveMask )
maskbuf = buf;
convertAndUnrollScalar( src2, wtype, buf2, blocksize);
for( size_t i = 0; i < it.nplanes; i++, ++it )
{
for( size_t j = 0; j < total; j += blocksize )
{
int bsz = (int)MIN(total - j, blocksize);
Size bszn(bsz*cn, 1);
const uchar *sptr1 = ptrs[0];
const uchar* sptr2 = buf2;
uchar* dptr = ptrs[1];
if( cvtsrc1 )
{
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cvtsrc1( sptr1, 1, 0, 1, buf1, 1, bszn, 0 );
sptr1 = buf1;
}
if( swapped12 )
std::swap(sptr1, sptr2);
if( !haveMask && !cvtdst )
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func( sptr1, 1, sptr2, 1, dptr, 1, bszn, usrdata );
else
{
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func( sptr1, 1, sptr2, 1, wbuf, 1, bszn, usrdata );
if( !haveMask )
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cvtdst( wbuf, 1, 0, 1, dptr, 1, bszn, 0 );
else if( !cvtdst )
{
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copymask( wbuf, 1, ptrs[2], 1, dptr, 1, Size(bsz, 1), &dsz );
ptrs[2] += bsz;
}
else
{
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cvtdst( wbuf, 1, 0, 1, maskbuf, 1, bszn, 0 );
copymask( maskbuf, 1, ptrs[2], 1, dptr, 1, Size(bsz, 1), &dsz );
ptrs[2] += bsz;
}
}
ptrs[0] += bsz*esz1; ptrs[1] += bsz*dsz;
}
}
}
}
static BinaryFunc* getAddTab()
{
static BinaryFunc addTab[] =
{
(BinaryFunc)GET_OPTIMIZED(add8u), (BinaryFunc)GET_OPTIMIZED(add8s),
(BinaryFunc)GET_OPTIMIZED(add16u), (BinaryFunc)GET_OPTIMIZED(add16s),
(BinaryFunc)GET_OPTIMIZED(add32s),
(BinaryFunc)GET_OPTIMIZED(add32f), (BinaryFunc)add64f,
0
};
return addTab;
}
static BinaryFunc* getSubTab()
{
static BinaryFunc subTab[] =
{
(BinaryFunc)GET_OPTIMIZED(sub8u), (BinaryFunc)GET_OPTIMIZED(sub8s),
(BinaryFunc)GET_OPTIMIZED(sub16u), (BinaryFunc)GET_OPTIMIZED(sub16s),
(BinaryFunc)GET_OPTIMIZED(sub32s),
(BinaryFunc)GET_OPTIMIZED(sub32f), (BinaryFunc)sub64f,
0
};
return subTab;
}
static BinaryFunc* getAbsDiffTab()
{
static BinaryFunc absDiffTab[] =
{
(BinaryFunc)GET_OPTIMIZED(absdiff8u), (BinaryFunc)GET_OPTIMIZED(absdiff8s),
(BinaryFunc)GET_OPTIMIZED(absdiff16u), (BinaryFunc)GET_OPTIMIZED(absdiff16s),
(BinaryFunc)GET_OPTIMIZED(absdiff32s),
(BinaryFunc)GET_OPTIMIZED(absdiff32f), (BinaryFunc)absdiff64f,
0
};
return absDiffTab;
}
}
void cv::add( InputArray src1, InputArray src2, OutputArray dst,
InputArray mask, int dtype )
{
arithm_op(src1, src2, dst, mask, dtype, getAddTab(), false, 0, OCL_OP_ADD );
}
void cv::subtract( InputArray _src1, InputArray _src2, OutputArray _dst,
InputArray mask, int dtype )
{
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#ifdef HAVE_TEGRA_OPTIMIZATION
int kind1 = _src1.kind(), kind2 = _src2.kind();
Mat src1 = _src1.getMat(), src2 = _src2.getMat();
bool src1Scalar = checkScalar(src1, _src2.type(), kind1, kind2);
bool src2Scalar = checkScalar(src2, _src1.type(), kind2, kind1);
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if (!src1Scalar && !src2Scalar &&
src1.depth() == CV_8U && src2.type() == src1.type() &&
src1.dims == 2 && src2.size() == src1.size() &&
mask.empty())
{
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if (dtype < 0)
{
if (_dst.fixedType())
{
dtype = _dst.depth();
}
else
{
dtype = src1.depth();
}
}
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dtype = CV_MAT_DEPTH(dtype);
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if (!_dst.fixedType() || dtype == _dst.depth())
{
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_dst.create(src1.size(), CV_MAKE_TYPE(dtype, src1.channels()));
if (dtype == CV_16S)
{
Mat dst = _dst.getMat();
if(tegra::subtract_8u8u16s(src1, src2, dst))
return;
}
else if (dtype == CV_32F)
{
Mat dst = _dst.getMat();
if(tegra::subtract_8u8u32f(src1, src2, dst))
return;
}
else if (dtype == CV_8S)
{
Mat dst = _dst.getMat();
if(tegra::subtract_8u8u8s(src1, src2, dst))
return;
}
}
}
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#endif
arithm_op(_src1, _src2, _dst, mask, dtype, getSubTab(), false, 0, OCL_OP_SUB );
}
void cv::absdiff( InputArray src1, InputArray src2, OutputArray dst )
{
arithm_op(src1, src2, dst, noArray(), -1, getAbsDiffTab(), false, 0, OCL_OP_ABSDIFF);
}
/****************************************************************************************\
* multiply/divide *
\****************************************************************************************/
namespace cv
{
template<typename T, typename WT> static void
mul_( const T* src1, size_t step1, const T* src2, size_t step2,
T* dst, size_t step, Size size, WT scale )
{
step1 /= sizeof(src1[0]);
step2 /= sizeof(src2[0]);
step /= sizeof(dst[0]);
if( scale == (WT)1. )
{
for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
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int i=0;
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#if CV_ENABLE_UNROLLED
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for(; i <= size.width - 4; i += 4 )
{
T t0;
T t1;
t0 = saturate_cast<T>(src1[i ] * src2[i ]);
t1 = saturate_cast<T>(src1[i+1] * src2[i+1]);
dst[i ] = t0;
dst[i+1] = t1;
t0 = saturate_cast<T>(src1[i+2] * src2[i+2]);
t1 = saturate_cast<T>(src1[i+3] * src2[i+3]);
dst[i+2] = t0;
dst[i+3] = t1;
}
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#endif
for( ; i < size.width; i++ )
dst[i] = saturate_cast<T>(src1[i] * src2[i]);
}
}
else
{
for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
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int i = 0;
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#if CV_ENABLE_UNROLLED
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for(; i <= size.width - 4; i += 4 )
{
T t0 = saturate_cast<T>(scale*(WT)src1[i]*src2[i]);
T t1 = saturate_cast<T>(scale*(WT)src1[i+1]*src2[i+1]);
dst[i] = t0; dst[i+1] = t1;
t0 = saturate_cast<T>(scale*(WT)src1[i+2]*src2[i+2]);
t1 = saturate_cast<T>(scale*(WT)src1[i+3]*src2[i+3]);
dst[i+2] = t0; dst[i+3] = t1;
}
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#endif
for( ; i < size.width; i++ )
dst[i] = saturate_cast<T>(scale*(WT)src1[i]*src2[i]);
}
}
}
template<typename T> static void
div_( const T* src1, size_t step1, const T* src2, size_t step2,
T* dst, size_t step, Size size, double scale )
{
step1 /= sizeof(src1[0]);
step2 /= sizeof(src2[0]);
step /= sizeof(dst[0]);
for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
int i = 0;
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#if CV_ENABLE_UNROLLED
for( ; i <= size.width - 4; i += 4 )
{
if( src2[i] != 0 && src2[i+1] != 0 && src2[i+2] != 0 && src2[i+3] != 0 )
{
double a = (double)src2[i] * src2[i+1];
double b = (double)src2[i+2] * src2[i+3];
double d = scale/(a * b);
b *= d;
a *= d;
T z0 = saturate_cast<T>(src2[i+1] * ((double)src1[i] * b));
T z1 = saturate_cast<T>(src2[i] * ((double)src1[i+1] * b));
T z2 = saturate_cast<T>(src2[i+3] * ((double)src1[i+2] * a));
T z3 = saturate_cast<T>(src2[i+2] * ((double)src1[i+3] * a));
dst[i] = z0; dst[i+1] = z1;
dst[i+2] = z2; dst[i+3] = z3;
}
else
{
T z0 = src2[i] != 0 ? saturate_cast<T>(src1[i]*scale/src2[i]) : 0;
T z1 = src2[i+1] != 0 ? saturate_cast<T>(src1[i+1]*scale/src2[i+1]) : 0;
T z2 = src2[i+2] != 0 ? saturate_cast<T>(src1[i+2]*scale/src2[i+2]) : 0;
T z3 = src2[i+3] != 0 ? saturate_cast<T>(src1[i+3]*scale/src2[i+3]) : 0;
dst[i] = z0; dst[i+1] = z1;
dst[i+2] = z2; dst[i+3] = z3;
}
}
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#endif
for( ; i < size.width; i++ )
dst[i] = src2[i] != 0 ? saturate_cast<T>(src1[i]*scale/src2[i]) : 0;
}
}
template<typename T> static void
recip_( const T*, size_t, const T* src2, size_t step2,
T* dst, size_t step, Size size, double scale )
{
step2 /= sizeof(src2[0]);
step /= sizeof(dst[0]);
for( ; size.height--; src2 += step2, dst += step )
{
int i = 0;
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#if CV_ENABLE_UNROLLED
for( ; i <= size.width - 4; i += 4 )
{
if( src2[i] != 0 && src2[i+1] != 0 && src2[i+2] != 0 && src2[i+3] != 0 )
{
double a = (double)src2[i] * src2[i+1];
double b = (double)src2[i+2] * src2[i+3];
double d = scale/(a * b);
b *= d;
a *= d;
T z0 = saturate_cast<T>(src2[i+1] * b);
T z1 = saturate_cast<T>(src2[i] * b);
T z2 = saturate_cast<T>(src2[i+3] * a);
T z3 = saturate_cast<T>(src2[i+2] * a);
dst[i] = z0; dst[i+1] = z1;
dst[i+2] = z2; dst[i+3] = z3;
}
else
{
T z0 = src2[i] != 0 ? saturate_cast<T>(scale/src2[i]) : 0;
T z1 = src2[i+1] != 0 ? saturate_cast<T>(scale/src2[i+1]) : 0;
T z2 = src2[i+2] != 0 ? saturate_cast<T>(scale/src2[i+2]) : 0;
T z3 = src2[i+3] != 0 ? saturate_cast<T>(scale/src2[i+3]) : 0;
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dst[i] = z0; dst[i+1] = z1;
dst[i+2] = z2; dst[i+3] = z3;
}
}
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#endif
for( ; i < size.width; i++ )
dst[i] = src2[i] != 0 ? saturate_cast<T>(scale/src2[i]) : 0;
}
}
static void mul8u( const uchar* src1, size_t step1, const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* scale)
{
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float fscale = (float)*(const double*)scale;
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#if defined HAVE_IPP
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if (std::fabs(fscale - 1) <= FLT_EPSILON)
{
if (ippiMul_8u_C1RSfs(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz), 0) >= 0)
return;
setIppErrorStatus();
}
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#endif
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mul_(src1, step1, src2, step2, dst, step, sz, fscale);
}
static void mul8s( const schar* src1, size_t step1, const schar* src2, size_t step2,
schar* dst, size_t step, Size sz, void* scale)
{
mul_(src1, step1, src2, step2, dst, step, sz, (float)*(const double*)scale);
}
static void mul16u( const ushort* src1, size_t step1, const ushort* src2, size_t step2,
ushort* dst, size_t step, Size sz, void* scale)
{
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float fscale = (float)*(const double*)scale;
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#if defined HAVE_IPP
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if (std::fabs(fscale - 1) <= FLT_EPSILON)
{
if (ippiMul_16u_C1RSfs(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz), 0) >= 0)
return;
setIppErrorStatus();
}
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#endif
mul_(src1, step1, src2, step2, dst, step, sz, fscale);
}
static void mul16s( const short* src1, size_t step1, const short* src2, size_t step2,
short* dst, size_t step, Size sz, void* scale)
{
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float fscale = (float)*(const double*)scale;
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#if defined HAVE_IPP
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if (std::fabs(fscale - 1) <= FLT_EPSILON)
{
if (ippiMul_16s_C1RSfs(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz), 0) >= 0)
return;
setIppErrorStatus();
}
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#endif
mul_(src1, step1, src2, step2, dst, step, sz, fscale);
}
static void mul32s( const int* src1, size_t step1, const int* src2, size_t step2,
int* dst, size_t step, Size sz, void* scale)
{
mul_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void mul32f( const float* src1, size_t step1, const float* src2, size_t step2,
float* dst, size_t step, Size sz, void* scale)
{
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float fscale = (float)*(const double*)scale;
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#if defined HAVE_IPP
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if (std::fabs(fscale - 1) <= FLT_EPSILON)
{
if (ippiMul_32f_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(sz)) >= 0)
return;
setIppErrorStatus();
}
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#endif
mul_(src1, step1, src2, step2, dst, step, sz, fscale);
}
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static void mul64f( const double* src1, size_t step1, const double* src2, size_t step2,
double* dst, size_t step, Size sz, void* scale)
{
mul_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void div8u( const uchar* src1, size_t step1, const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* scale)
{
if( src1 )
div_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
else
recip_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void div8s( const schar* src1, size_t step1, const schar* src2, size_t step2,
schar* dst, size_t step, Size sz, void* scale)
{
div_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void div16u( const ushort* src1, size_t step1, const ushort* src2, size_t step2,
ushort* dst, size_t step, Size sz, void* scale)
{
div_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void div16s( const short* src1, size_t step1, const short* src2, size_t step2,
short* dst, size_t step, Size sz, void* scale)
{
div_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void div32s( const int* src1, size_t step1, const int* src2, size_t step2,
int* dst, size_t step, Size sz, void* scale)
{
div_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void div32f( const float* src1, size_t step1, const float* src2, size_t step2,
float* dst, size_t step, Size sz, void* scale)
{
div_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void div64f( const double* src1, size_t step1, const double* src2, size_t step2,
double* dst, size_t step, Size sz, void* scale)
{
div_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void recip8u( const uchar* src1, size_t step1, const uchar* src2, size_t step2,
uchar* dst, size_t step, Size sz, void* scale)
{
recip_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void recip8s( const schar* src1, size_t step1, const schar* src2, size_t step2,
schar* dst, size_t step, Size sz, void* scale)
{
recip_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void recip16u( const ushort* src1, size_t step1, const ushort* src2, size_t step2,
ushort* dst, size_t step, Size sz, void* scale)
{
recip_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void recip16s( const short* src1, size_t step1, const short* src2, size_t step2,
short* dst, size_t step, Size sz, void* scale)
{
recip_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void recip32s( const int* src1, size_t step1, const int* src2, size_t step2,
int* dst, size_t step, Size sz, void* scale)
{
recip_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void recip32f( const float* src1, size_t step1, const float* src2, size_t step2,
float* dst, size_t step, Size sz, void* scale)
{
recip_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static void recip64f( const double* src1, size_t step1, const double* src2, size_t step2,
double* dst, size_t step, Size sz, void* scale)
{
recip_(src1, step1, src2, step2, dst, step, sz, *(const double*)scale);
}
static BinaryFunc* getMulTab()
{
static BinaryFunc mulTab[] =
{
(BinaryFunc)mul8u, (BinaryFunc)mul8s, (BinaryFunc)mul16u,
(BinaryFunc)mul16s, (BinaryFunc)mul32s, (BinaryFunc)mul32f,
(BinaryFunc)mul64f, 0
};
return mulTab;
}
static BinaryFunc* getDivTab()
{
static BinaryFunc divTab[] =
{
(BinaryFunc)div8u, (BinaryFunc)div8s, (BinaryFunc)div16u,
(BinaryFunc)div16s, (BinaryFunc)div32s, (BinaryFunc)div32f,
(BinaryFunc)div64f, 0
};
return divTab;
}
static BinaryFunc* getRecipTab()
{
static BinaryFunc recipTab[] =
{
(BinaryFunc)recip8u, (BinaryFunc)recip8s, (BinaryFunc)recip16u,
(BinaryFunc)recip16s, (BinaryFunc)recip32s, (BinaryFunc)recip32f,
(BinaryFunc)recip64f, 0
};
return recipTab;
}
}
void cv::multiply(InputArray src1, InputArray src2,
OutputArray dst, double scale, int dtype)
{
arithm_op(src1, src2, dst, noArray(), dtype, getMulTab(),
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true, &scale, std::abs(scale - 1.0) < DBL_EPSILON ? OCL_OP_MUL : OCL_OP_MUL_SCALE);
}
void cv::divide(InputArray src1, InputArray src2,
OutputArray dst, double scale, int dtype)
{
arithm_op(src1, src2, dst, noArray(), dtype, getDivTab(), true, &scale, OCL_OP_DIV_SCALE);
}
void cv::divide(double scale, InputArray src2,
OutputArray dst, int dtype)
{
arithm_op(src2, src2, dst, noArray(), dtype, getRecipTab(), true, &scale, OCL_OP_RECIP_SCALE);
}
/****************************************************************************************\
* addWeighted *
\****************************************************************************************/
namespace cv
{
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template <typename T, typename WT>
struct AddWeighted_SIMD
{
int operator() (const T *, const T *, T *, int, WT, WT, WT) const
{
return 0;
}
};
#if CV_NEON
template <>
struct AddWeighted_SIMD<schar, float>
{
int operator() (const schar * src1, const schar * src2, schar * dst, int width, float alpha, float beta, float gamma) const
{
int x = 0;
float32x4_t g = vdupq_n_f32 (gamma);
for( ; x <= width - 8; x += 8 )
{
int8x8_t in1 = vld1_s8(src1 + x);
int16x8_t in1_16 = vmovl_s8(in1);
float32x4_t in1_f_l = vcvtq_f32_s32(vmovl_s16(vget_low_s16(in1_16)));
float32x4_t in1_f_h = vcvtq_f32_s32(vmovl_s16(vget_high_s16(in1_16)));
int8x8_t in2 = vld1_s8(src2+x);
int16x8_t in2_16 = vmovl_s8(in2);
float32x4_t in2_f_l = vcvtq_f32_s32(vmovl_s16(vget_low_s16(in2_16)));
float32x4_t in2_f_h = vcvtq_f32_s32(vmovl_s16(vget_high_s16(in2_16)));
float32x4_t out_f_l = vaddq_f32(vmulq_n_f32(in1_f_l, alpha), vmulq_n_f32(in2_f_l, beta));
float32x4_t out_f_h = vaddq_f32(vmulq_n_f32(in1_f_h, alpha), vmulq_n_f32(in2_f_h, beta));
out_f_l = vaddq_f32(out_f_l, g);
out_f_h = vaddq_f32(out_f_h, g);
int16x4_t out_16_l = vqmovn_s32(vcvtq_s32_f32(out_f_l));
int16x4_t out_16_h = vqmovn_s32(vcvtq_s32_f32(out_f_h));
int16x8_t out_16 = vcombine_s16(out_16_l, out_16_h);
int8x8_t out = vqmovn_s16(out_16);
vst1_s8(dst + x, out);
}
return x;
}
};
template <>
struct AddWeighted_SIMD<ushort, float>
{
int operator() (const ushort * src1, const ushort * src2, ushort * dst, int width, float alpha, float beta, float gamma) const
{
int x = 0;
float32x4_t g = vdupq_n_f32(gamma);
for( ; x <= width - 8; x += 8 )
{
uint16x8_t v_src1 = vld1q_u16(src1 + x), v_src2 = vld1q_u16(src2 + x);
float32x4_t v_s1 = vmulq_n_f32(vcvtq_f32_u32(vmovl_u16(vget_low_u16(v_src1))), alpha);
float32x4_t v_s2 = vmulq_n_f32(vcvtq_f32_u32(vmovl_u16(vget_low_u16(v_src2))), beta);
uint16x4_t v_dst1 = vqmovn_u32(vcvtq_u32_f32(vaddq_f32(vaddq_f32(v_s1, v_s2), g)));
v_s1 = vmulq_n_f32(vcvtq_f32_u32(vmovl_u16(vget_high_u16(v_src1))), alpha);
v_s2 = vmulq_n_f32(vcvtq_f32_u32(vmovl_u16(vget_high_u16(v_src2))), beta);
uint16x4_t v_dst2 = vqmovn_u32(vcvtq_u32_f32(vaddq_f32(vaddq_f32(v_s1, v_s2), g)));
vst1q_u16(dst + x, vcombine_u16(v_dst1, v_dst2));
}
return x;
}
};
template <>
struct AddWeighted_SIMD<short, float>
{
int operator() (const short * src1, const short * src2, short * dst, int width, float alpha, float beta, float gamma) const
{
int x = 0;
float32x4_t g = vdupq_n_f32(gamma);
for( ; x <= width - 8; x += 8 )
{
int16x8_t v_src1 = vld1q_s16(src1 + x), v_src2 = vld1q_s16(src2 + x);
float32x4_t v_s1 = vmulq_n_f32(vcvtq_f32_s32(vmovl_s16(vget_low_s16(v_src1))), alpha);
float32x4_t v_s2 = vmulq_n_f32(vcvtq_f32_s32(vmovl_s16(vget_low_s16(v_src2))), beta);
int16x4_t v_dst1 = vqmovn_s32(vcvtq_s32_f32(vaddq_f32(vaddq_f32(v_s1, v_s2), g)));
v_s1 = vmulq_n_f32(vcvtq_f32_s32(vmovl_s16(vget_high_s16(v_src1))), alpha);
v_s2 = vmulq_n_f32(vcvtq_f32_s32(vmovl_s16(vget_high_s16(v_src2))), beta);
int16x4_t v_dst2 = vqmovn_s32(vcvtq_s32_f32(vaddq_f32(vaddq_f32(v_s1, v_s2), g)));
vst1q_s16(dst + x, vcombine_s16(v_dst1, v_dst2));
}
return x;
}
};
#endif
template<typename T, typename WT> static void
addWeighted_( const T* src1, size_t step1, const T* src2, size_t step2,
T* dst, size_t step, Size size, void* _scalars )
{
const double* scalars = (const double*)_scalars;
WT alpha = (WT)scalars[0], beta = (WT)scalars[1], gamma = (WT)scalars[2];
step1 /= sizeof(src1[0]);
step2 /= sizeof(src2[0]);
step /= sizeof(dst[0]);
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AddWeighted_SIMD<T, WT> vop;
for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
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int x = vop(src1, src2, dst, size.width, alpha, beta, gamma);
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#if CV_ENABLE_UNROLLED
for( ; x <= size.width - 4; x += 4 )
{
T t0 = saturate_cast<T>(src1[x]*alpha + src2[x]*beta + gamma);
T t1 = saturate_cast<T>(src1[x+1]*alpha + src2[x+1]*beta + gamma);
dst[x] = t0; dst[x+1] = t1;
t0 = saturate_cast<T>(src1[x+2]*alpha + src2[x+2]*beta + gamma);
t1 = saturate_cast<T>(src1[x+3]*alpha + src2[x+3]*beta + gamma);
dst[x+2] = t0; dst[x+3] = t1;
}
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#endif
for( ; x < size.width; x++ )
dst[x] = saturate_cast<T>(src1[x]*alpha + src2[x]*beta + gamma);
}
}
static void
addWeighted8u( const uchar* src1, size_t step1,
const uchar* src2, size_t step2,
uchar* dst, size_t step, Size size,
void* _scalars )
{
const double* scalars = (const double*)_scalars;
float alpha = (float)scalars[0], beta = (float)scalars[1], gamma = (float)scalars[2];
for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
int x = 0;
#if CV_SSE2
if( USE_SSE2 )
{
__m128 a4 = _mm_set1_ps(alpha), b4 = _mm_set1_ps(beta), g4 = _mm_set1_ps(gamma);
__m128i z = _mm_setzero_si128();
for( ; x <= size.width - 8; x += 8 )
{
__m128i u = _mm_unpacklo_epi8(_mm_loadl_epi64((const __m128i*)(src1 + x)), z);
__m128i v = _mm_unpacklo_epi8(_mm_loadl_epi64((const __m128i*)(src2 + x)), z);
__m128 u0 = _mm_cvtepi32_ps(_mm_unpacklo_epi16(u, z));
__m128 u1 = _mm_cvtepi32_ps(_mm_unpackhi_epi16(u, z));
__m128 v0 = _mm_cvtepi32_ps(_mm_unpacklo_epi16(v, z));
__m128 v1 = _mm_cvtepi32_ps(_mm_unpackhi_epi16(v, z));
u0 = _mm_add_ps(_mm_mul_ps(u0, a4), _mm_mul_ps(v0, b4));
u1 = _mm_add_ps(_mm_mul_ps(u1, a4), _mm_mul_ps(v1, b4));
u0 = _mm_add_ps(u0, g4); u1 = _mm_add_ps(u1, g4);
u = _mm_packs_epi32(_mm_cvtps_epi32(u0), _mm_cvtps_epi32(u1));
u = _mm_packus_epi16(u, u);
_mm_storel_epi64((__m128i*)(dst + x), u);
}
}
#elif CV_NEON
float32x4_t g = vdupq_n_f32 (gamma);
for( ; x <= size.width - 8; x += 8 )
{
uint8x8_t in1 = vld1_u8(src1+x);
uint16x8_t in1_16 = vmovl_u8(in1);
float32x4_t in1_f_l = vcvtq_f32_u32(vmovl_u16(vget_low_u16(in1_16)));
float32x4_t in1_f_h = vcvtq_f32_u32(vmovl_u16(vget_high_u16(in1_16)));
uint8x8_t in2 = vld1_u8(src2+x);
uint16x8_t in2_16 = vmovl_u8(in2);
float32x4_t in2_f_l = vcvtq_f32_u32(vmovl_u16(vget_low_u16(in2_16)));
float32x4_t in2_f_h = vcvtq_f32_u32(vmovl_u16(vget_high_u16(in2_16)));
float32x4_t out_f_l = vaddq_f32(vmulq_n_f32(in1_f_l, alpha), vmulq_n_f32(in2_f_l, beta));
float32x4_t out_f_h = vaddq_f32(vmulq_n_f32(in1_f_h, alpha), vmulq_n_f32(in2_f_h, beta));
out_f_l = vaddq_f32(out_f_l, g);
out_f_h = vaddq_f32(out_f_h, g);
uint16x4_t out_16_l = vqmovun_s32(vcvtq_s32_f32(out_f_l));
uint16x4_t out_16_h = vqmovun_s32(vcvtq_s32_f32(out_f_h));
uint16x8_t out_16 = vcombine_u16(out_16_l, out_16_h);
uint8x8_t out = vqmovn_u16(out_16);
vst1_u8(dst+x, out);
}
#endif
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#if CV_ENABLE_UNROLLED
for( ; x <= size.width - 4; x += 4 )
{
float t0, t1;
t0 = CV_8TO32F(src1[x])*alpha + CV_8TO32F(src2[x])*beta + gamma;
t1 = CV_8TO32F(src1[x+1])*alpha + CV_8TO32F(src2[x+1])*beta + gamma;
dst[x] = saturate_cast<uchar>(t0);
dst[x+1] = saturate_cast<uchar>(t1);
t0 = CV_8TO32F(src1[x+2])*alpha + CV_8TO32F(src2[x+2])*beta + gamma;
t1 = CV_8TO32F(src1[x+3])*alpha + CV_8TO32F(src2[x+3])*beta + gamma;
dst[x+2] = saturate_cast<uchar>(t0);
dst[x+3] = saturate_cast<uchar>(t1);
}
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#endif
for( ; x < size.width; x++ )
{
float t0 = CV_8TO32F(src1[x])*alpha + CV_8TO32F(src2[x])*beta + gamma;
dst[x] = saturate_cast<uchar>(t0);
}
}
}
static void addWeighted8s( const schar* src1, size_t step1, const schar* src2, size_t step2,
schar* dst, size_t step, Size sz, void* scalars )
{
addWeighted_<schar, float>(src1, step1, src2, step2, dst, step, sz, scalars);
}
static void addWeighted16u( const ushort* src1, size_t step1, const ushort* src2, size_t step2,
ushort* dst, size_t step, Size sz, void* scalars )
{
addWeighted_<ushort, float>(src1, step1, src2, step2, dst, step, sz, scalars);
}
static void addWeighted16s( const short* src1, size_t step1, const short* src2, size_t step2,
short* dst, size_t step, Size sz, void* scalars )
{
addWeighted_<short, float>(src1, step1, src2, step2, dst, step, sz, scalars);
}
static void addWeighted32s( const int* src1, size_t step1, const int* src2, size_t step2,
int* dst, size_t step, Size sz, void* scalars )
{
addWeighted_<int, double>(src1, step1, src2, step2, dst, step, sz, scalars);
}
static void addWeighted32f( const float* src1, size_t step1, const float* src2, size_t step2,
float* dst, size_t step, Size sz, void* scalars )
{
addWeighted_<float, double>(src1, step1, src2, step2, dst, step, sz, scalars);
}
static void addWeighted64f( const double* src1, size_t step1, const double* src2, size_t step2,
double* dst, size_t step, Size sz, void* scalars )
{
addWeighted_<double, double>(src1, step1, src2, step2, dst, step, sz, scalars);
}
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static BinaryFunc* getAddWeightedTab()
{
static BinaryFunc addWeightedTab[] =
{
(BinaryFunc)GET_OPTIMIZED(addWeighted8u), (BinaryFunc)GET_OPTIMIZED(addWeighted8s), (BinaryFunc)GET_OPTIMIZED(addWeighted16u),
(BinaryFunc)GET_OPTIMIZED(addWeighted16s), (BinaryFunc)GET_OPTIMIZED(addWeighted32s), (BinaryFunc)addWeighted32f,
(BinaryFunc)addWeighted64f, 0
};
return addWeightedTab;
}
}
void cv::addWeighted( InputArray src1, double alpha, InputArray src2,
double beta, double gamma, OutputArray dst, int dtype )
{
double scalars[] = {alpha, beta, gamma};
arithm_op(src1, src2, dst, noArray(), dtype, getAddWeightedTab(), true, scalars, OCL_OP_ADDW);
}
/****************************************************************************************\
* compare *
\****************************************************************************************/
namespace cv
{
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template <typename T>
struct Cmp_SIMD
{
explicit Cmp_SIMD(int)
{
}
int operator () (const T *, const T *, uchar *, int) const
{
return 0;
}
};
#if CV_NEON
template <>
struct Cmp_SIMD<schar>
{
explicit Cmp_SIMD(int code_) :
code(code_)
{
CV_Assert(code == CMP_GT || code == CMP_LE ||
code == CMP_EQ || code == CMP_NE);
v_mask = vdupq_n_u8(255);
}
int operator () (const schar * src1, const schar * src2, uchar * dst, int width) const
{
int x = 0;
if (code == CMP_GT)
for ( ; x <= width - 16; x += 16)
vst1q_u8(dst + x, vcgtq_s8(vld1q_s8(src1 + x), vld1q_s8(src2 + x)));
else if (code == CMP_LE)
for ( ; x <= width - 16; x += 16)
vst1q_u8(dst + x, vcleq_s8(vld1q_s8(src1 + x), vld1q_s8(src2 + x)));
else if (code == CMP_EQ)
for ( ; x <= width - 16; x += 16)
vst1q_u8(dst + x, vceqq_s8(vld1q_s8(src1 + x), vld1q_s8(src2 + x)));
else if (code == CMP_NE)
for ( ; x <= width - 16; x += 16)
vst1q_u8(dst + x, veorq_u8(vceqq_s8(vld1q_s8(src1 + x), vld1q_s8(src2 + x)), v_mask));
return x;
}
int code;
uint8x16_t v_mask;
};
template <>
struct Cmp_SIMD<ushort>
{
explicit Cmp_SIMD(int code_) :
code(code_)
{
CV_Assert(code == CMP_GT || code == CMP_LE ||
code == CMP_EQ || code == CMP_NE);
v_mask = vdup_n_u8(255);
}
int operator () (const ushort * src1, const ushort * src2, uchar * dst, int width) const
{
int x = 0;
if (code == CMP_GT)
for ( ; x <= width - 8; x += 8)
{
uint16x8_t v_dst = vcgtq_u16(vld1q_u16(src1 + x), vld1q_u16(src2 + x));
vst1_u8(dst + x, vmovn_u16(v_dst));
}
else if (code == CMP_LE)
for ( ; x <= width - 8; x += 8)
{
uint16x8_t v_dst = vcleq_u16(vld1q_u16(src1 + x), vld1q_u16(src2 + x));
vst1_u8(dst + x, vmovn_u16(v_dst));
}
else if (code == CMP_EQ)
for ( ; x <= width - 8; x += 8)
{
uint16x8_t v_dst = vceqq_u16(vld1q_u16(src1 + x), vld1q_u16(src2 + x));
vst1_u8(dst + x, vmovn_u16(v_dst));
}
else if (code == CMP_NE)
for ( ; x <= width - 8; x += 8)
{
uint16x8_t v_dst = vceqq_u16(vld1q_u16(src1 + x), vld1q_u16(src2 + x));
vst1_u8(dst + x, veor_u8(vmovn_u16(v_dst), v_mask));
}
return x;
}
int code;
uint8x8_t v_mask;
};
template <>
struct Cmp_SIMD<int>
{
explicit Cmp_SIMD(int code_) :
code(code_)
{
CV_Assert(code == CMP_GT || code == CMP_LE ||
code == CMP_EQ || code == CMP_NE);
v_mask = vdup_n_u8(255);
}
int operator () (const int * src1, const int * src2, uchar * dst, int width) const
{
int x = 0;
if (code == CMP_GT)
for ( ; x <= width - 8; x += 8)
{
uint32x4_t v_dst1 = vcgtq_s32(vld1q_s32(src1 + x), vld1q_s32(src2 + x));
uint32x4_t v_dst2 = vcgtq_s32(vld1q_s32(src1 + x + 4), vld1q_s32(src2 + x + 4));
vst1_u8(dst + x, vmovn_u16(vcombine_u16(vmovn_u32(v_dst1), vmovn_u32(v_dst2))));
}
else if (code == CMP_LE)
for ( ; x <= width - 8; x += 8)
{
uint32x4_t v_dst1 = vcleq_s32(vld1q_s32(src1 + x), vld1q_s32(src2 + x));
uint32x4_t v_dst2 = vcleq_s32(vld1q_s32(src1 + x + 4), vld1q_s32(src2 + x + 4));
vst1_u8(dst + x, vmovn_u16(vcombine_u16(vmovn_u32(v_dst1), vmovn_u32(v_dst2))));
}
else if (code == CMP_EQ)
for ( ; x <= width - 8; x += 8)
{
uint32x4_t v_dst1 = vceqq_s32(vld1q_s32(src1 + x), vld1q_s32(src2 + x));
uint32x4_t v_dst2 = vceqq_s32(vld1q_s32(src1 + x + 4), vld1q_s32(src2 + x + 4));
vst1_u8(dst + x, vmovn_u16(vcombine_u16(vmovn_u32(v_dst1), vmovn_u32(v_dst2))));
}
else if (code == CMP_NE)
for ( ; x <= width - 8; x += 8)
{
uint32x4_t v_dst1 = vceqq_s32(vld1q_s32(src1 + x), vld1q_s32(src2 + x));
uint32x4_t v_dst2 = vceqq_s32(vld1q_s32(src1 + x + 4), vld1q_s32(src2 + x + 4));
uint8x8_t v_dst = vmovn_u16(vcombine_u16(vmovn_u32(v_dst1), vmovn_u32(v_dst2)));
vst1_u8(dst + x, veor_u8(v_dst, v_mask));
}
return x;
}
int code;
uint8x8_t v_mask;
};
template <>
struct Cmp_SIMD<float>
{
explicit Cmp_SIMD(int code_) :
code(code_)
{
CV_Assert(code == CMP_GT || code == CMP_LE ||
code == CMP_EQ || code == CMP_NE);
v_mask = vdup_n_u8(255);
}
int operator () (const float * src1, const float * src2, uchar * dst, int width) const
{
int x = 0;
if (code == CMP_GT)
for ( ; x <= width - 8; x += 8)
{
uint32x4_t v_dst1 = vcgtq_f32(vld1q_f32(src1 + x), vld1q_f32(src2 + x));
uint32x4_t v_dst2 = vcgtq_f32(vld1q_f32(src1 + x + 4), vld1q_f32(src2 + x + 4));
vst1_u8(dst + x, vmovn_u16(vcombine_u16(vmovn_u32(v_dst1), vmovn_u32(v_dst2))));
}
else if (code == CMP_LE)
for ( ; x <= width - 8; x += 8)
{
uint32x4_t v_dst1 = vcleq_f32(vld1q_f32(src1 + x), vld1q_f32(src2 + x));
uint32x4_t v_dst2 = vcleq_f32(vld1q_f32(src1 + x + 4), vld1q_f32(src2 + x + 4));
vst1_u8(dst + x, vmovn_u16(vcombine_u16(vmovn_u32(v_dst1), vmovn_u32(v_dst2))));
}
else if (code == CMP_EQ)
for ( ; x <= width - 8; x += 8)
{
uint32x4_t v_dst1 = vceqq_f32(vld1q_f32(src1 + x), vld1q_f32(src2 + x));
uint32x4_t v_dst2 = vceqq_f32(vld1q_f32(src1 + x + 4), vld1q_f32(src2 + x + 4));
vst1_u8(dst + x, vmovn_u16(vcombine_u16(vmovn_u32(v_dst1), vmovn_u32(v_dst2))));
}
else if (code == CMP_NE)
for ( ; x <= width - 8; x += 8)
{
uint32x4_t v_dst1 = vceqq_f32(vld1q_f32(src1 + x), vld1q_f32(src2 + x));
uint32x4_t v_dst2 = vceqq_f32(vld1q_f32(src1 + x + 4), vld1q_f32(src2 + x + 4));
uint8x8_t v_dst = vmovn_u16(vcombine_u16(vmovn_u32(v_dst1), vmovn_u32(v_dst2)));
vst1_u8(dst + x, veor_u8(v_dst, v_mask));
}
return x;
}
int code;
uint8x8_t v_mask;
};
#endif
template<typename T> static void
cmp_(const T* src1, size_t step1, const T* src2, size_t step2,
uchar* dst, size_t step, Size size, int code)
{
step1 /= sizeof(src1[0]);
step2 /= sizeof(src2[0]);
if( code == CMP_GE || code == CMP_LT )
{
std::swap(src1, src2);
std::swap(step1, step2);
code = code == CMP_GE ? CMP_LE : CMP_GT;
}
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Cmp_SIMD<T> vop(code);
if( code == CMP_GT || code == CMP_LE )
{
int m = code == CMP_GT ? 0 : 255;
for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
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int x = vop(src1, src2, dst, size.width);
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#if CV_ENABLE_UNROLLED
for( ; x <= size.width - 4; x += 4 )
{
int t0, t1;
t0 = -(src1[x] > src2[x]) ^ m;
t1 = -(src1[x+1] > src2[x+1]) ^ m;
dst[x] = (uchar)t0; dst[x+1] = (uchar)t1;
t0 = -(src1[x+2] > src2[x+2]) ^ m;
t1 = -(src1[x+3] > src2[x+3]) ^ m;
dst[x+2] = (uchar)t0; dst[x+3] = (uchar)t1;
}
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#endif
for( ; x < size.width; x++ )
dst[x] = (uchar)(-(src1[x] > src2[x]) ^ m);
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}
}
else if( code == CMP_EQ || code == CMP_NE )
{
int m = code == CMP_EQ ? 0 : 255;
for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
int x = 0;
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#if CV_ENABLE_UNROLLED
for( ; x <= size.width - 4; x += 4 )
{
int t0, t1;
t0 = -(src1[x] == src2[x]) ^ m;
t1 = -(src1[x+1] == src2[x+1]) ^ m;
dst[x] = (uchar)t0; dst[x+1] = (uchar)t1;
t0 = -(src1[x+2] == src2[x+2]) ^ m;
t1 = -(src1[x+3] == src2[x+3]) ^ m;
dst[x+2] = (uchar)t0; dst[x+3] = (uchar)t1;
}
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#endif
for( ; x < size.width; x++ )
dst[x] = (uchar)(-(src1[x] == src2[x]) ^ m);
}
}
}
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#if ARITHM_USE_IPP
inline static IppCmpOp convert_cmp(int _cmpop)
{
return _cmpop == CMP_EQ ? ippCmpEq :
_cmpop == CMP_GT ? ippCmpGreater :
_cmpop == CMP_GE ? ippCmpGreaterEq :
_cmpop == CMP_LT ? ippCmpLess :
_cmpop == CMP_LE ? ippCmpLessEq :
(IppCmpOp)-1;
}
#endif
static void cmp8u(const uchar* src1, size_t step1, const uchar* src2, size_t step2,
uchar* dst, size_t step, Size size, void* _cmpop)
{
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#if ARITHM_USE_IPP
IppCmpOp op = convert_cmp(*(int *)_cmpop);
if( op >= 0 )
{
fixSteps(size, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiCompare_8u_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(size), op))
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return;
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setIppErrorStatus();
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}
#endif
//vz optimized cmp_(src1, step1, src2, step2, dst, step, size, *(int*)_cmpop);
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int code = *(int*)_cmpop;
step1 /= sizeof(src1[0]);
step2 /= sizeof(src2[0]);
if( code == CMP_GE || code == CMP_LT )
{
std::swap(src1, src2);
std::swap(step1, step2);
code = code == CMP_GE ? CMP_LE : CMP_GT;
}
if( code == CMP_GT || code == CMP_LE )
{
int m = code == CMP_GT ? 0 : 255;
for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
int x =0;
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#if CV_SSE2
if( USE_SSE2 ){
__m128i m128 = code == CMP_GT ? _mm_setzero_si128() : _mm_set1_epi8 (-1);
__m128i c128 = _mm_set1_epi8 (-128);
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for( ; x <= size.width - 16; x += 16 )
{
__m128i r00 = _mm_loadu_si128((const __m128i*)(src1 + x));
__m128i r10 = _mm_loadu_si128((const __m128i*)(src2 + x));
// no simd for 8u comparison, that's why we need the trick
r00 = _mm_sub_epi8(r00,c128);
r10 = _mm_sub_epi8(r10,c128);
r00 =_mm_xor_si128(_mm_cmpgt_epi8(r00, r10), m128);
_mm_storeu_si128((__m128i*)(dst + x),r00);
}
}
#elif CV_NEON
uint8x16_t mask = code == CMP_GT ? vdupq_n_u8(0) : vdupq_n_u8(255);
for( ; x <= size.width - 16; x += 16 )
{
vst1q_u8(dst+x, veorq_u8(vcgtq_u8(vld1q_u8(src1+x), vld1q_u8(src2+x)), mask));
}
#endif
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for( ; x < size.width; x++ ){
dst[x] = (uchar)(-(src1[x] > src2[x]) ^ m);
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}
}
}
else if( code == CMP_EQ || code == CMP_NE )
{
int m = code == CMP_EQ ? 0 : 255;
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for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
int x = 0;
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#if CV_SSE2
if( USE_SSE2 ){
__m128i m128 = code == CMP_EQ ? _mm_setzero_si128() : _mm_set1_epi8 (-1);
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for( ; x <= size.width - 16; x += 16 )
{
__m128i r00 = _mm_loadu_si128((const __m128i*)(src1 + x));
__m128i r10 = _mm_loadu_si128((const __m128i*)(src2 + x));
r00 = _mm_xor_si128 ( _mm_cmpeq_epi8 (r00, r10), m128);
_mm_storeu_si128((__m128i*)(dst + x), r00);
}
}
#elif CV_NEON
uint8x16_t mask = code == CMP_EQ ? vdupq_n_u8(0) : vdupq_n_u8(255);
for( ; x <= size.width - 16; x += 16 )
{
vst1q_u8(dst+x, veorq_u8(vceqq_u8(vld1q_u8(src1+x), vld1q_u8(src2+x)), mask));
}
#endif
for( ; x < size.width; x++ )
dst[x] = (uchar)(-(src1[x] == src2[x]) ^ m);
}
}
}
static void cmp8s(const schar* src1, size_t step1, const schar* src2, size_t step2,
uchar* dst, size_t step, Size size, void* _cmpop)
{
cmp_(src1, step1, src2, step2, dst, step, size, *(int*)_cmpop);
}
static void cmp16u(const ushort* src1, size_t step1, const ushort* src2, size_t step2,
uchar* dst, size_t step, Size size, void* _cmpop)
{
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#if ARITHM_USE_IPP
IppCmpOp op = convert_cmp(*(int *)_cmpop);
if( op >= 0 )
{
fixSteps(size, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiCompare_16u_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(size), op))
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return;
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setIppErrorStatus();
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}
#endif
cmp_(src1, step1, src2, step2, dst, step, size, *(int*)_cmpop);
}
static void cmp16s(const short* src1, size_t step1, const short* src2, size_t step2,
uchar* dst, size_t step, Size size, void* _cmpop)
{
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#if ARITHM_USE_IPP
IppCmpOp op = convert_cmp(*(int *)_cmpop);
if( op > 0 )
{
fixSteps(size, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiCompare_16s_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(size), op))
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return;
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setIppErrorStatus();
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}
#endif
//vz optimized cmp_(src1, step1, src2, step2, dst, step, size, *(int*)_cmpop);
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int code = *(int*)_cmpop;
step1 /= sizeof(src1[0]);
step2 /= sizeof(src2[0]);
if( code == CMP_GE || code == CMP_LT )
{
std::swap(src1, src2);
std::swap(step1, step2);
code = code == CMP_GE ? CMP_LE : CMP_GT;
}
if( code == CMP_GT || code == CMP_LE )
{
int m = code == CMP_GT ? 0 : 255;
for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
int x =0;
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#if CV_SSE2
if( USE_SSE2){//
__m128i m128 = code == CMP_GT ? _mm_setzero_si128() : _mm_set1_epi16 (-1);
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for( ; x <= size.width - 16; x += 16 )
{
__m128i r00 = _mm_loadu_si128((const __m128i*)(src1 + x));
__m128i r10 = _mm_loadu_si128((const __m128i*)(src2 + x));
r00 = _mm_xor_si128 ( _mm_cmpgt_epi16 (r00, r10), m128);
__m128i r01 = _mm_loadu_si128((const __m128i*)(src1 + x + 8));
__m128i r11 = _mm_loadu_si128((const __m128i*)(src2 + x + 8));
r01 = _mm_xor_si128 ( _mm_cmpgt_epi16 (r01, r11), m128);
r11 = _mm_packs_epi16(r00, r01);
_mm_storeu_si128((__m128i*)(dst + x), r11);
}
if( x <= size.width-8)
{
__m128i r00 = _mm_loadu_si128((const __m128i*)(src1 + x));
__m128i r10 = _mm_loadu_si128((const __m128i*)(src2 + x));
r00 = _mm_xor_si128 ( _mm_cmpgt_epi16 (r00, r10), m128);
r10 = _mm_packs_epi16(r00, r00);
_mm_storel_epi64((__m128i*)(dst + x), r10);
x += 8;
}
}
#elif CV_NEON
uint8x16_t mask = code == CMP_GT ? vdupq_n_u8(0) : vdupq_n_u8(255);
for( ; x <= size.width - 16; x += 16 )
{
int16x8_t in1 = vld1q_s16(src1 + x);
int16x8_t in2 = vld1q_s16(src2 + x);
uint8x8_t t1 = vmovn_u16(vcgtq_s16(in1, in2));
in1 = vld1q_s16(src1 + x + 8);
in2 = vld1q_s16(src2 + x + 8);
uint8x8_t t2 = vmovn_u16(vcgtq_s16(in1, in2));
vst1q_u8(dst+x, veorq_u8(vcombine_u8(t1, t2), mask));
}
#endif
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for( ; x < size.width; x++ ){
dst[x] = (uchar)(-(src1[x] > src2[x]) ^ m);
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}
}
}
else if( code == CMP_EQ || code == CMP_NE )
{
int m = code == CMP_EQ ? 0 : 255;
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for( ; size.height--; src1 += step1, src2 += step2, dst += step )
{
int x = 0;
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#if CV_SSE2
if( USE_SSE2 ){
__m128i m128 = code == CMP_EQ ? _mm_setzero_si128() : _mm_set1_epi16 (-1);
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for( ; x <= size.width - 16; x += 16 )
{
__m128i r00 = _mm_loadu_si128((const __m128i*)(src1 + x));
__m128i r10 = _mm_loadu_si128((const __m128i*)(src2 + x));
r00 = _mm_xor_si128 ( _mm_cmpeq_epi16 (r00, r10), m128);
__m128i r01 = _mm_loadu_si128((const __m128i*)(src1 + x + 8));
__m128i r11 = _mm_loadu_si128((const __m128i*)(src2 + x + 8));
r01 = _mm_xor_si128 ( _mm_cmpeq_epi16 (r01, r11), m128);
r11 = _mm_packs_epi16(r00, r01);
_mm_storeu_si128((__m128i*)(dst + x), r11);
}
if( x <= size.width - 8)
{
__m128i r00 = _mm_loadu_si128((const __m128i*)(src1 + x));
__m128i r10 = _mm_loadu_si128((const __m128i*)(src2 + x));
r00 = _mm_xor_si128 ( _mm_cmpeq_epi16 (r00, r10), m128);
r10 = _mm_packs_epi16(r00, r00);
_mm_storel_epi64((__m128i*)(dst + x), r10);
x += 8;
}
}
#elif CV_NEON
uint8x16_t mask = code == CMP_EQ ? vdupq_n_u8(0) : vdupq_n_u8(255);
for( ; x <= size.width - 16; x += 16 )
{
int16x8_t in1 = vld1q_s16(src1 + x);
int16x8_t in2 = vld1q_s16(src2 + x);
uint8x8_t t1 = vmovn_u16(vceqq_s16(in1, in2));
in1 = vld1q_s16(src1 + x + 8);
in2 = vld1q_s16(src2 + x + 8);
uint8x8_t t2 = vmovn_u16(vceqq_s16(in1, in2));
vst1q_u8(dst+x, veorq_u8(vcombine_u8(t1, t2), mask));
}
#endif
for( ; x < size.width; x++ )
dst[x] = (uchar)(-(src1[x] == src2[x]) ^ m);
}
}
}
static void cmp32s(const int* src1, size_t step1, const int* src2, size_t step2,
uchar* dst, size_t step, Size size, void* _cmpop)
{
cmp_(src1, step1, src2, step2, dst, step, size, *(int*)_cmpop);
}
static void cmp32f(const float* src1, size_t step1, const float* src2, size_t step2,
uchar* dst, size_t step, Size size, void* _cmpop)
{
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#if ARITHM_USE_IPP
IppCmpOp op = convert_cmp(*(int *)_cmpop);
if( op >= 0 )
{
fixSteps(size, sizeof(dst[0]), step1, step2, step);
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if (0 <= ippiCompare_32f_C1R(src1, (int)step1, src2, (int)step2, dst, (int)step, ippiSize(size), op))
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return;
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setIppErrorStatus();
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}
#endif
cmp_(src1, step1, src2, step2, dst, step, size, *(int*)_cmpop);
}
static void cmp64f(const double* src1, size_t step1, const double* src2, size_t step2,
uchar* dst, size_t step, Size size, void* _cmpop)
{
cmp_(src1, step1, src2, step2, dst, step, size, *(int*)_cmpop);
}
static BinaryFunc getCmpFunc(int depth)
{
static BinaryFunc cmpTab[] =
{
(BinaryFunc)GET_OPTIMIZED(cmp8u), (BinaryFunc)GET_OPTIMIZED(cmp8s),
(BinaryFunc)GET_OPTIMIZED(cmp16u), (BinaryFunc)GET_OPTIMIZED(cmp16s),
(BinaryFunc)GET_OPTIMIZED(cmp32s),
(BinaryFunc)GET_OPTIMIZED(cmp32f), (BinaryFunc)cmp64f,
0
};
return cmpTab[depth];
}
static double getMinVal(int depth)
{
static const double tab[] = {0, -128, 0, -32768, INT_MIN, -FLT_MAX, -DBL_MAX, 0};
return tab[depth];
}
static double getMaxVal(int depth)
{
static const double tab[] = {255, 127, 65535, 32767, INT_MAX, FLT_MAX, DBL_MAX, 0};
return tab[depth];
}
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#ifdef HAVE_OPENCL
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static bool ocl_compare(InputArray _src1, InputArray _src2, OutputArray _dst, int op, bool haveScalar)
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{
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const ocl::Device& dev = ocl::Device::getDefault();
bool doubleSupport = dev.doubleFPConfig() > 0;
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int type1 = _src1.type(), depth1 = CV_MAT_DEPTH(type1), cn = CV_MAT_CN(type1),
type2 = _src2.type(), depth2 = CV_MAT_DEPTH(type2);
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if (!doubleSupport && depth1 == CV_64F)
return false;
if (!haveScalar && (!_src1.sameSize(_src2) || type1 != type2))
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return false;
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int kercn = haveScalar ? cn : ocl::predictOptimalVectorWidth(_src1, _src2, _dst), rowsPerWI = dev.isIntel() ? 4 : 1;
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// Workaround for bug with "?:" operator in AMD OpenCL compiler
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if (depth1 >= CV_16U)
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kercn = 1;
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int scalarcn = kercn == 3 ? 4 : kercn;
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const char * const operationMap[] = { "==", ">", ">=", "<", "<=", "!=" };
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char cvt[40];
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String opts = format("-D %s -D srcT1=%s -D dstT=%s -D workT=srcT1 -D cn=%d"
" -D convertToDT=%s -D OP_CMP -D CMP_OPERATOR=%s -D srcT1_C1=%s"
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" -D srcT2_C1=%s -D dstT_C1=%s -D workST=%s -D rowsPerWI=%d%s",
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haveScalar ? "UNARY_OP" : "BINARY_OP",
ocl::typeToStr(CV_MAKE_TYPE(depth1, kercn)),
ocl::typeToStr(CV_8UC(kercn)), kercn,
ocl::convertTypeStr(depth1, CV_8U, kercn, cvt),
operationMap[op], ocl::typeToStr(depth1),
ocl::typeToStr(depth1), ocl::typeToStr(CV_8U),
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ocl::typeToStr(CV_MAKE_TYPE(depth1, scalarcn)), rowsPerWI,
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doubleSupport ? " -D DOUBLE_SUPPORT" : "");
ocl::Kernel k("KF", ocl::core::arithm_oclsrc, opts);
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if (k.empty())
return false;
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UMat src1 = _src1.getUMat();
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Size size = src1.size();
_dst.create(size, CV_8UC(cn));
UMat dst = _dst.getUMat();
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if (haveScalar)
{
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size_t esz = CV_ELEM_SIZE1(type1) * scalarcn;
double buf[4] = { 0, 0, 0, 0 };
Mat src2 = _src2.getMat();
if( depth1 > CV_32S )
convertAndUnrollScalar( src2, depth1, (uchar *)buf, kercn );
else
{
double fval = 0;
getConvertFunc(depth2, CV_64F)(src2.ptr(), 1, 0, 1, (uchar *)&fval, 1, Size(1, 1), 0);
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if( fval < getMinVal(depth1) )
return dst.setTo(Scalar::all(op == CMP_GT || op == CMP_GE || op == CMP_NE ? 255 : 0)), true;
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if( fval > getMaxVal(depth1) )
return dst.setTo(Scalar::all(op == CMP_LT || op == CMP_LE || op == CMP_NE ? 255 : 0)), true;
int ival = cvRound(fval);
if( fval != ival )
{
if( op == CMP_LT || op == CMP_GE )
ival = cvCeil(fval);
else if( op == CMP_LE || op == CMP_GT )
ival = cvFloor(fval);
else
return dst.setTo(Scalar::all(op == CMP_NE ? 255 : 0)), true;
}
convertAndUnrollScalar(Mat(1, 1, CV_32S, &ival), depth1, (uchar *)buf, kercn);
}
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ocl::KernelArg scalararg = ocl::KernelArg(0, 0, 0, 0, buf, esz);
k.args(ocl::KernelArg::ReadOnlyNoSize(src1, cn, kercn),
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ocl::KernelArg::WriteOnly(dst, cn, kercn), scalararg);
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}
else
{
UMat src2 = _src2.getUMat();
k.args(ocl::KernelArg::ReadOnlyNoSize(src1),
ocl::KernelArg::ReadOnlyNoSize(src2),
ocl::KernelArg::WriteOnly(dst, cn, kercn));
}
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size_t globalsize[2] = { dst.cols * cn / kercn, (dst.rows + rowsPerWI - 1) / rowsPerWI };
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return k.run(2, globalsize, NULL, false);
}
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#endif
}
void cv::compare(InputArray _src1, InputArray _src2, OutputArray _dst, int op)
{
CV_Assert( op == CMP_LT || op == CMP_LE || op == CMP_EQ ||
op == CMP_NE || op == CMP_GE || op == CMP_GT );
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bool haveScalar = false;
if ((_src1.isMatx() + _src2.isMatx()) == 1
|| !_src1.sameSize(_src2)
|| _src1.type() != _src2.type())
{
if (checkScalar(_src1, _src2.type(), _src1.kind(), _src2.kind()))
{
op = op == CMP_LT ? CMP_GT : op == CMP_LE ? CMP_GE :
op == CMP_GE ? CMP_LE : op == CMP_GT ? CMP_LT : op;
// src1 is a scalar; swap it with src2
compare(_src2, _src1, _dst, op);
return;
}
else if( !checkScalar(_src2, _src1.type(), _src2.kind(), _src1.kind()) )
CV_Error( CV_StsUnmatchedSizes,
"The operation is neither 'array op array' (where arrays have the same size and the same type), "
"nor 'array op scalar', nor 'scalar op array'" );
haveScalar = true;
}
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CV_OCL_RUN(_src1.dims() <= 2 && _src2.dims() <= 2 && OCL_PERFORMANCE_CHECK(_dst.isUMat()),
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ocl_compare(_src1, _src2, _dst, op, haveScalar))
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int kind1 = _src1.kind(), kind2 = _src2.kind();
Mat src1 = _src1.getMat(), src2 = _src2.getMat();
if( kind1 == kind2 && src1.dims <= 2 && src2.dims <= 2 && src1.size() == src2.size() && src1.type() == src2.type() )
{
int cn = src1.channels();
_dst.create(src1.size(), CV_8UC(cn));
Mat dst = _dst.getMat();
Size sz = getContinuousSize(src1, src2, dst, src1.channels());
getCmpFunc(src1.depth())(src1.ptr(), src1.step, src2.ptr(), src2.step, dst.ptr(), dst.step, sz, &op);
return;
}
int cn = src1.channels(), depth1 = src1.depth(), depth2 = src2.depth();
_dst.create(src1.dims, src1.size, CV_8UC(cn));
src1 = src1.reshape(1); src2 = src2.reshape(1);
Mat dst = _dst.getMat().reshape(1);
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size_t esz = src1.elemSize();
size_t blocksize0 = (size_t)(BLOCK_SIZE + esz-1)/esz;
BinaryFunc func = getCmpFunc(depth1);
if( !haveScalar )
{
const Mat* arrays[] = { &src1, &src2, &dst, 0 };
uchar* ptrs[3];
NAryMatIterator it(arrays, ptrs);
size_t total = it.size;
for( size_t i = 0; i < it.nplanes; i++, ++it )
func( ptrs[0], 0, ptrs[1], 0, ptrs[2], 0, Size((int)total, 1), &op );
}
else
{
const Mat* arrays[] = { &src1, &dst, 0 };
uchar* ptrs[2];
NAryMatIterator it(arrays, ptrs);
size_t total = it.size, blocksize = std::min(total, blocksize0);
AutoBuffer<uchar> _buf(blocksize*esz);
uchar *buf = _buf;
if( depth1 > CV_32S )
convertAndUnrollScalar( src2, depth1, buf, blocksize );
else
{
double fval=0;
getConvertFunc(depth2, CV_64F)(src2.ptr(), 1, 0, 1, (uchar*)&fval, 1, Size(1,1), 0);
if( fval < getMinVal(depth1) )
{
dst = Scalar::all(op == CMP_GT || op == CMP_GE || op == CMP_NE ? 255 : 0);
return;
}
if( fval > getMaxVal(depth1) )
{
dst = Scalar::all(op == CMP_LT || op == CMP_LE || op == CMP_NE ? 255 : 0);
return;
}
int ival = cvRound(fval);
if( fval != ival )
{
if( op == CMP_LT || op == CMP_GE )
ival = cvCeil(fval);
else if( op == CMP_LE || op == CMP_GT )
ival = cvFloor(fval);
else
{
dst = Scalar::all(op == CMP_NE ? 255 : 0);
return;
}
}
convertAndUnrollScalar(Mat(1, 1, CV_32S, &ival), depth1, buf, blocksize);
}
for( size_t i = 0; i < it.nplanes; i++, ++it )
{
for( size_t j = 0; j < total; j += blocksize )
{
int bsz = (int)MIN(total - j, blocksize);
func( ptrs[0], 0, buf, 0, ptrs[1], 0, Size(bsz, 1), &op);
ptrs[0] += bsz*esz;
ptrs[1] += bsz;
}
}
}
}
/****************************************************************************************\
* inRange *
\****************************************************************************************/
namespace cv
{
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template <typename T>
struct InRange_SIMD
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{
int operator () (const T *, const T *, const T *, uchar *, int) const
{
return 0;
}
};
#if CV_SSE2
template <>
struct InRange_SIMD<uchar>
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{
int operator () (const uchar * src1, const uchar * src2, const uchar * src3,
uchar * dst, int len) const
{
int x = 0;
if (USE_SSE2)
{
__m128i v_full = _mm_set1_epi8(-1), v_128 = _mm_set1_epi8(-128);
for ( ; x <= len - 16; x += 16 )
{
__m128i v_src = _mm_add_epi8(_mm_loadu_si128((const __m128i *)(src1 + x)), v_128);
__m128i v_mask1 = _mm_cmpgt_epi8(_mm_add_epi8(_mm_loadu_si128((const __m128i *)(src2 + x)), v_128), v_src);
__m128i v_mask2 = _mm_cmpgt_epi8(v_src, _mm_add_epi8(_mm_loadu_si128((const __m128i *)(src3 + x)), v_128));
_mm_storeu_si128((__m128i *)(dst + x), _mm_andnot_si128(_mm_or_si128(v_mask1, v_mask2), v_full));
}
}
return x;
}
};
template <>
struct InRange_SIMD<schar>
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{
int operator () (const schar * src1, const schar * src2, const schar * src3,
uchar * dst, int len) const
{
int x = 0;
if (USE_SSE2)
{
__m128i v_full = _mm_set1_epi8(-1);
for ( ; x <= len - 16; x += 16 )
{
__m128i v_src = _mm_loadu_si128((const __m128i *)(src1 + x));
__m128i v_mask1 = _mm_cmpgt_epi8(_mm_loadu_si128((const __m128i *)(src2 + x)), v_src);
__m128i v_mask2 = _mm_cmpgt_epi8(v_src, _mm_loadu_si128((const __m128i *)(src3 + x)));
_mm_storeu_si128((__m128i *)(dst + x), _mm_andnot_si128(_mm_or_si128(v_mask1, v_mask2), v_full));
}
}
return x;
}
};
template <>
struct InRange_SIMD<ushort>
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{
int operator () (const ushort * src1, const ushort * src2, const ushort * src3,
uchar * dst, int len) const
{
int x = 0;
if (USE_SSE2)
{
__m128i v_zero = _mm_setzero_si128(), v_full = _mm_set1_epi16(-1), v_32768 = _mm_set1_epi16(-32768);
for ( ; x <= len - 8; x += 8 )
{
__m128i v_src = _mm_add_epi16(_mm_loadu_si128((const __m128i *)(src1 + x)), v_32768);
__m128i v_mask1 = _mm_cmpgt_epi16(_mm_add_epi16(_mm_loadu_si128((const __m128i *)(src2 + x)), v_32768), v_src);
__m128i v_mask2 = _mm_cmpgt_epi16(v_src, _mm_add_epi16(_mm_loadu_si128((const __m128i *)(src3 + x)), v_32768));
__m128i v_res = _mm_andnot_si128(_mm_or_si128(v_mask1, v_mask2), v_full);
_mm_storel_epi64((__m128i *)(dst + x), _mm_packus_epi16(_mm_srli_epi16(v_res, 8), v_zero));
}
}
return x;
}
};
template <>
struct InRange_SIMD<short>
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{
int operator () (const short * src1, const short * src2, const short * src3,
uchar * dst, int len) const
{
int x = 0;
if (USE_SSE2)
{
__m128i v_zero = _mm_setzero_si128(), v_full = _mm_set1_epi16(-1);
for ( ; x <= len - 8; x += 8 )
{
__m128i v_src = _mm_loadu_si128((const __m128i *)(src1 + x));
__m128i v_mask1 = _mm_cmpgt_epi16(_mm_loadu_si128((const __m128i *)(src2 + x)), v_src);
__m128i v_mask2 = _mm_cmpgt_epi16(v_src, _mm_loadu_si128((const __m128i *)(src3 + x)));
__m128i v_res = _mm_andnot_si128(_mm_or_si128(v_mask1, v_mask2), v_full);
_mm_storel_epi64((__m128i *)(dst + x), _mm_packus_epi16(_mm_srli_epi16(v_res, 8), v_zero));
}
}
return x;
}
};
template <>
struct InRange_SIMD<int>
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{
int operator () (const int * src1, const int * src2, const int * src3,
uchar * dst, int len) const
{
int x = 0;
if (USE_SSE2)
{
__m128i v_zero = _mm_setzero_si128(), v_full = _mm_set1_epi32(-1);
for ( ; x <= len - 8; x += 8 )
{
__m128i v_src = _mm_loadu_si128((const __m128i *)(src1 + x));
__m128i v_res1 = _mm_or_si128(_mm_cmpgt_epi32(_mm_loadu_si128((const __m128i *)(src2 + x)), v_src),
_mm_cmpgt_epi32(v_src, _mm_loadu_si128((const __m128i *)(src3 + x))));
v_src = _mm_loadu_si128((const __m128i *)(src1 + x + 4));
__m128i v_res2 = _mm_or_si128(_mm_cmpgt_epi32(_mm_loadu_si128((const __m128i *)(src2 + x + 4)), v_src),
_mm_cmpgt_epi32(v_src, _mm_loadu_si128((const __m128i *)(src3 + x + 4))));
__m128i v_res = _mm_packs_epi32(_mm_srli_epi32(_mm_andnot_si128(v_res1, v_full), 16),
_mm_srli_epi32(_mm_andnot_si128(v_res2, v_full), 16));
_mm_storel_epi64((__m128i *)(dst + x), _mm_packus_epi16(v_res, v_zero));
}
}
return x;
}
};
template <>
struct InRange_SIMD<float>
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{
int operator () (const float * src1, const float * src2, const float * src3,
uchar * dst, int len) const
{
int x = 0;
if (USE_SSE2)
{
__m128i v_zero = _mm_setzero_si128();
for ( ; x <= len - 8; x += 8 )
{
__m128 v_src = _mm_loadu_ps(src1 + x);
__m128 v_res1 = _mm_and_ps(_mm_cmple_ps(_mm_loadu_ps(src2 + x), v_src),
_mm_cmple_ps(v_src, _mm_loadu_ps(src3 + x)));
v_src = _mm_loadu_ps(src1 + x + 4);
__m128 v_res2 = _mm_and_ps(_mm_cmple_ps(_mm_loadu_ps(src2 + x + 4), v_src),
_mm_cmple_ps(v_src, _mm_loadu_ps(src3 + x + 4)));
__m128i v_res1i = _mm_cvtps_epi32(v_res1), v_res2i = _mm_cvtps_epi32(v_res2);
__m128i v_res = _mm_packs_epi32(_mm_srli_epi32(v_res1i, 16), _mm_srli_epi32(v_res2i, 16));
_mm_storel_epi64((__m128i *)(dst + x), _mm_packus_epi16(v_res, v_zero));
}
}
return x;
}
};
#elif CV_NEON
template <>
struct InRange_SIMD<uchar>
{
int operator () (const uchar * src1, const uchar * src2, const uchar * src3,
uchar * dst, int len) const
{
int x = 0;
for ( ; x <= len - 16; x += 16 )
{
uint8x16_t values = vld1q_u8(src1 + x);
uint8x16_t low = vld1q_u8(src2 + x);
uint8x16_t high = vld1q_u8(src3 + x);
vst1q_u8(dst + x, vandq_u8(vcgeq_u8(values, low), vcgeq_u8(high, values)));
}
return x;
}
};
template <>
struct InRange_SIMD<schar>
{
int operator () (const schar * src1, const schar * src2, const schar * src3,
uchar * dst, int len) const
{
int x = 0;
for ( ; x <= len - 16; x += 16 )
{
int8x16_t values = vld1q_s8(src1 + x);
int8x16_t low = vld1q_s8(src2 + x);
int8x16_t high = vld1q_s8(src3 + x);
vst1q_u8(dst + x, vandq_u8(vcgeq_s8(values, low), vcgeq_s8(high, values)));
}
return x;
}
};
template <>
struct InRange_SIMD<ushort>
{
int operator () (const ushort * src1, const ushort * src2, const ushort * src3,
uchar * dst, int len) const
{
int x = 0;
for ( ; x <= len - 16; x += 16 )
{
uint16x8_t values = vld1q_u16((const uint16_t*)(src1 + x));
uint16x8_t low = vld1q_u16((const uint16_t*)(src2 + x));
uint16x8_t high = vld1q_u16((const uint16_t*)(src3 + x));
uint8x8_t r1 = vmovn_u16(vandq_u16(vcgeq_u16(values, low), vcgeq_u16(high, values)));
values = vld1q_u16((const uint16_t*)(src1 + x + 8));
low = vld1q_u16((const uint16_t*)(src2 + x + 8));
high = vld1q_u16((const uint16_t*)(src3 + x + 8));
uint8x8_t r2 = vmovn_u16(vandq_u16(vcgeq_u16(values, low), vcgeq_u16(high, values)));
vst1q_u8(dst + x, vcombine_u8(r1, r2));
}
return x;
}
};
template <>
struct InRange_SIMD<short>
{
int operator () (const short * src1, const short * src2, const short * src3,
uchar * dst, int len) const
{
int x = 0;
for ( ; x <= len - 16; x += 16 )
{
int16x8_t values = vld1q_s16((const int16_t*)(src1 + x));
int16x8_t low = vld1q_s16((const int16_t*)(src2 + x));
int16x8_t high = vld1q_s16((const int16_t*)(src3 + x));
uint8x8_t r1 = vmovn_u16(vandq_u16(vcgeq_s16(values, low), vcgeq_s16(high, values)));
values = vld1q_s16((const int16_t*)(src1 + x + 8));
low = vld1q_s16((const int16_t*)(src2 + x + 8));
high = vld1q_s16((const int16_t*)(src3 + x + 8));
uint8x8_t r2 = vmovn_u16(vandq_u16(vcgeq_s16(values, low), vcgeq_s16(high, values)));
vst1q_u8(dst + x, vcombine_u8(r1, r2));
}
return x;
}
};
template <>
struct InRange_SIMD<int>
{
int operator () (const int * src1, const int * src2, const int * src3,
uchar * dst, int len) const
{
int x = 0;
for ( ; x <= len - 8; x += 8 )
{
int32x4_t values = vld1q_s32((const int32_t*)(src1 + x));
int32x4_t low = vld1q_s32((const int32_t*)(src2 + x));
int32x4_t high = vld1q_s32((const int32_t*)(src3 + x));
uint16x4_t r1 = vmovn_u32(vandq_u32(vcgeq_s32(values, low), vcgeq_s32(high, values)));
values = vld1q_s32((const int32_t*)(src1 + x + 4));
low = vld1q_s32((const int32_t*)(src2 + x + 4));
high = vld1q_s32((const int32_t*)(src3 + x + 4));
uint16x4_t r2 = vmovn_u32(vandq_u32(vcgeq_s32(values, low), vcgeq_s32(high, values)));
uint16x8_t res_16 = vcombine_u16(r1, r2);
vst1_u8(dst + x, vmovn_u16(res_16));
}
return x;
}
};
template <>
struct InRange_SIMD<float>
{
int operator () (const float * src1, const float * src2, const float * src3,
uchar * dst, int len) const
{
int x = 0;
for ( ; x <= len - 8; x += 8 )
{
float32x4_t values = vld1q_f32((const float32_t*)(src1 + x));
float32x4_t low = vld1q_f32((const float32_t*)(src2 + x));
float32x4_t high = vld1q_f32((const float32_t*)(src3 + x));
uint16x4_t r1 = vmovn_u32(vandq_u32(vcgeq_f32(values, low), vcgeq_f32(high, values)));
values = vld1q_f32((const float32_t*)(src1 + x + 4));
low = vld1q_f32((const float32_t*)(src2 + x + 4));
high = vld1q_f32((const float32_t*)(src3 + x + 4));
uint16x4_t r2 = vmovn_u32(vandq_u32(vcgeq_f32(values, low), vcgeq_f32(high, values)));
uint16x8_t res_16 = vcombine_u16(r1, r2);
vst1_u8(dst + x, vmovn_u16(res_16));
}
return x;
}
};
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#endif
template <typename T>
static void inRange_(const T* src1, size_t step1, const T* src2, size_t step2,
const T* src3, size_t step3, uchar* dst, size_t step,
Size size)
{
step1 /= sizeof(src1[0]);
step2 /= sizeof(src2[0]);
step3 /= sizeof(src3[0]);
InRange_SIMD<T> vop;
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for( ; size.height--; src1 += step1, src2 += step2, src3 += step3, dst += step )
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{
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int x = vop(src1, src2, src3, dst, size.width);
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#if CV_ENABLE_UNROLLED
for( ; x <= size.width - 4; x += 4 )
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{
int t0, t1;
t0 = src2[x] <= src1[x] && src1[x] <= src3[x];
t1 = src2[x+1] <= src1[x+1] && src1[x+1] <= src3[x+1];
dst[x] = (uchar)-t0; dst[x+1] = (uchar)-t1;
t0 = src2[x+2] <= src1[x+2] && src1[x+2] <= src3[x+2];
t1 = src2[x+3] <= src1[x+3] && src1[x+3] <= src3[x+3];
dst[x+2] = (uchar)-t0; dst[x+3] = (uchar)-t1;
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}
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#endif
for( ; x < size.width; x++ )
dst[x] = (uchar)-(src2[x] <= src1[x] && src1[x] <= src3[x]);
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}
}
static void inRange8u(const uchar* src1, size_t step1, const uchar* src2, size_t step2,
const uchar* src3, size_t step3, uchar* dst, size_t step, Size size)
{
inRange_(src1, step1, src2, step2, src3, step3, dst, step, size);
}
static void inRange8s(const schar* src1, size_t step1, const schar* src2, size_t step2,
const schar* src3, size_t step3, uchar* dst, size_t step, Size size)
{
inRange_(src1, step1, src2, step2, src3, step3, dst, step, size);
}
static void inRange16u(const ushort* src1, size_t step1, const ushort* src2, size_t step2,
const ushort* src3, size_t step3, uchar* dst, size_t step, Size size)
{
inRange_(src1, step1, src2, step2, src3, step3, dst, step, size);
}
static void inRange16s(const short* src1, size_t step1, const short* src2, size_t step2,
const short* src3, size_t step3, uchar* dst, size_t step, Size size)
{
inRange_(src1, step1, src2, step2, src3, step3, dst, step, size);
}
static void inRange32s(const int* src1, size_t step1, const int* src2, size_t step2,
const int* src3, size_t step3, uchar* dst, size_t step, Size size)
{
inRange_(src1, step1, src2, step2, src3, step3, dst, step, size);
}
static void inRange32f(const float* src1, size_t step1, const float* src2, size_t step2,
const float* src3, size_t step3, uchar* dst, size_t step, Size size)
{
inRange_(src1, step1, src2, step2, src3, step3, dst, step, size);
}
static void inRange64f(const double* src1, size_t step1, const double* src2, size_t step2,
const double* src3, size_t step3, uchar* dst, size_t step, Size size)
{
inRange_(src1, step1, src2, step2, src3, step3, dst, step, size);
}
static void inRangeReduce(const uchar* src, uchar* dst, size_t len, int cn)
{
int k = cn % 4 ? cn % 4 : 4;
size_t i, j;
if( k == 1 )
for( i = j = 0; i < len; i++, j += cn )
dst[i] = src[j];
else if( k == 2 )
for( i = j = 0; i < len; i++, j += cn )
dst[i] = src[j] & src[j+1];
else if( k == 3 )
for( i = j = 0; i < len; i++, j += cn )
dst[i] = src[j] & src[j+1] & src[j+2];
else
for( i = j = 0; i < len; i++, j += cn )
dst[i] = src[j] & src[j+1] & src[j+2] & src[j+3];
for( ; k < cn; k += 4 )
{
for( i = 0, j = k; i < len; i++, j += cn )
dst[i] &= src[j] & src[j+1] & src[j+2] & src[j+3];
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}
}
typedef void (*InRangeFunc)( const uchar* src1, size_t step1, const uchar* src2, size_t step2,
const uchar* src3, size_t step3, uchar* dst, size_t step, Size sz );
static InRangeFunc getInRangeFunc(int depth)
{
static InRangeFunc inRangeTab[] =
{
(InRangeFunc)GET_OPTIMIZED(inRange8u), (InRangeFunc)GET_OPTIMIZED(inRange8s), (InRangeFunc)GET_OPTIMIZED(inRange16u),
(InRangeFunc)GET_OPTIMIZED(inRange16s), (InRangeFunc)GET_OPTIMIZED(inRange32s), (InRangeFunc)GET_OPTIMIZED(inRange32f),
(InRangeFunc)inRange64f, 0
};
return inRangeTab[depth];
}
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#ifdef HAVE_OPENCL
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static bool ocl_inRange( InputArray _src, InputArray _lowerb,
InputArray _upperb, OutputArray _dst )
{
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const ocl::Device & d = ocl::Device::getDefault();
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int skind = _src.kind(), lkind = _lowerb.kind(), ukind = _upperb.kind();
Size ssize = _src.size(), lsize = _lowerb.size(), usize = _upperb.size();
int stype = _src.type(), ltype = _lowerb.type(), utype = _upperb.type();
int sdepth = CV_MAT_DEPTH(stype), ldepth = CV_MAT_DEPTH(ltype), udepth = CV_MAT_DEPTH(utype);
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int cn = CV_MAT_CN(stype), rowsPerWI = d.isIntel() ? 4 : 1;
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bool lbScalar = false, ubScalar = false;
if( (lkind == _InputArray::MATX && skind != _InputArray::MATX) ||
ssize != lsize || stype != ltype )
{
if( !checkScalar(_lowerb, stype, lkind, skind) )
CV_Error( CV_StsUnmatchedSizes,
"The lower bounary is neither an array of the same size and same type as src, nor a scalar");
lbScalar = true;
}
if( (ukind == _InputArray::MATX && skind != _InputArray::MATX) ||
ssize != usize || stype != utype )
{
if( !checkScalar(_upperb, stype, ukind, skind) )
CV_Error( CV_StsUnmatchedSizes,
"The upper bounary is neither an array of the same size and same type as src, nor a scalar");
ubScalar = true;
}
if (lbScalar != ubScalar)
return false;
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bool doubleSupport = d.doubleFPConfig() > 0,
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haveScalar = lbScalar && ubScalar;
if ( (!doubleSupport && sdepth == CV_64F) ||
(!haveScalar && (sdepth != ldepth || sdepth != udepth)) )
return false;
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int kercn = haveScalar ? cn : std::max(std::min(ocl::predictOptimalVectorWidth(_src, _lowerb, _upperb, _dst), 4), cn);
if (kercn % cn != 0)
kercn = cn;
int colsPerWI = kercn / cn;
String opts = format("%s-D cn=%d -D srcT=%s -D srcT1=%s -D dstT=%s -D kercn=%d -D depth=%d%s -D colsPerWI=%d",
haveScalar ? "-D HAVE_SCALAR " : "", cn, ocl::typeToStr(CV_MAKE_TYPE(sdepth, kercn)),
ocl::typeToStr(sdepth), ocl::typeToStr(CV_8UC(colsPerWI)), kercn, sdepth,
doubleSupport ? " -D DOUBLE_SUPPORT" : "", colsPerWI);
ocl::Kernel ker("inrange", ocl::core::inrange_oclsrc, opts);
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if (ker.empty())
return false;
_dst.create(ssize, CV_8UC1);
UMat src = _src.getUMat(), dst = _dst.getUMat(), lscalaru, uscalaru;
Mat lscalar, uscalar;
if (lbScalar && ubScalar)
{
lscalar = _lowerb.getMat();
uscalar = _upperb.getMat();
size_t esz = src.elemSize();
size_t blocksize = 36;
AutoBuffer<uchar> _buf(blocksize*(((int)lbScalar + (int)ubScalar)*esz + cn) + 2*cn*sizeof(int) + 128);
uchar *buf = alignPtr(_buf + blocksize*cn, 16);
if( ldepth != sdepth && sdepth < CV_32S )
{
int* ilbuf = (int*)alignPtr(buf + blocksize*esz, 16);
int* iubuf = ilbuf + cn;
BinaryFunc sccvtfunc = getConvertFunc(ldepth, CV_32S);
sccvtfunc(lscalar.ptr(), 1, 0, 1, (uchar*)ilbuf, 1, Size(cn, 1), 0);
sccvtfunc(uscalar.ptr(), 1, 0, 1, (uchar*)iubuf, 1, Size(cn, 1), 0);
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int minval = cvRound(getMinVal(sdepth)), maxval = cvRound(getMaxVal(sdepth));
for( int k = 0; k < cn; k++ )
{
if( ilbuf[k] > iubuf[k] || ilbuf[k] > maxval || iubuf[k] < minval )
ilbuf[k] = minval+1, iubuf[k] = minval;
}
lscalar = Mat(cn, 1, CV_32S, ilbuf);
uscalar = Mat(cn, 1, CV_32S, iubuf);
}
lscalar.convertTo(lscalar, stype);
uscalar.convertTo(uscalar, stype);
}
else
{
lscalaru = _lowerb.getUMat();
uscalaru = _upperb.getUMat();
}
ocl::KernelArg srcarg = ocl::KernelArg::ReadOnlyNoSize(src),
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dstarg = ocl::KernelArg::WriteOnly(dst, 1, colsPerWI);
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if (haveScalar)
{
lscalar.copyTo(lscalaru);
uscalar.copyTo(uscalaru);
ker.args(srcarg, dstarg, ocl::KernelArg::PtrReadOnly(lscalaru),
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ocl::KernelArg::PtrReadOnly(uscalaru), rowsPerWI);
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}
else
ker.args(srcarg, dstarg, ocl::KernelArg::ReadOnlyNoSize(lscalaru),
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ocl::KernelArg::ReadOnlyNoSize(uscalaru), rowsPerWI);
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size_t globalsize[2] = { ssize.width / colsPerWI, (ssize.height + rowsPerWI - 1) / rowsPerWI };
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return ker.run(2, globalsize, NULL, false);
}
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#endif
}
void cv::inRange(InputArray _src, InputArray _lowerb,
InputArray _upperb, OutputArray _dst)
{
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CV_OCL_RUN(_src.dims() <= 2 && _lowerb.dims() <= 2 &&
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_upperb.dims() <= 2 && OCL_PERFORMANCE_CHECK(_dst.isUMat()),
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ocl_inRange(_src, _lowerb, _upperb, _dst))
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int skind = _src.kind(), lkind = _lowerb.kind(), ukind = _upperb.kind();
Mat src = _src.getMat(), lb = _lowerb.getMat(), ub = _upperb.getMat();
bool lbScalar = false, ubScalar = false;
if( (lkind == _InputArray::MATX && skind != _InputArray::MATX) ||
src.size != lb.size || src.type() != lb.type() )
{
if( !checkScalar(lb, src.type(), lkind, skind) )
CV_Error( CV_StsUnmatchedSizes,
"The lower bounary is neither an array of the same size and same type as src, nor a scalar");
lbScalar = true;
}
if( (ukind == _InputArray::MATX && skind != _InputArray::MATX) ||
src.size != ub.size || src.type() != ub.type() )
{
if( !checkScalar(ub, src.type(), ukind, skind) )
CV_Error( CV_StsUnmatchedSizes,
"The upper bounary is neither an array of the same size and same type as src, nor a scalar");
ubScalar = true;
}
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CV_Assert(lbScalar == ubScalar);
int cn = src.channels(), depth = src.depth();
size_t esz = src.elemSize();
size_t blocksize0 = (size_t)(BLOCK_SIZE + esz-1)/esz;
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_dst.create(src.dims, src.size, CV_8UC1);
Mat dst = _dst.getMat();
InRangeFunc func = getInRangeFunc(depth);
const Mat* arrays_sc[] = { &src, &dst, 0 };
const Mat* arrays_nosc[] = { &src, &dst, &lb, &ub, 0 };
uchar* ptrs[4];
NAryMatIterator it(lbScalar && ubScalar ? arrays_sc : arrays_nosc, ptrs);
size_t total = it.size, blocksize = std::min(total, blocksize0);
AutoBuffer<uchar> _buf(blocksize*(((int)lbScalar + (int)ubScalar)*esz + cn) + 2*cn*sizeof(int) + 128);
uchar *buf = _buf, *mbuf = buf, *lbuf = 0, *ubuf = 0;
buf = alignPtr(buf + blocksize*cn, 16);
if( lbScalar && ubScalar )
{
lbuf = buf;
ubuf = buf = alignPtr(buf + blocksize*esz, 16);
CV_Assert( lb.type() == ub.type() );
int scdepth = lb.depth();
if( scdepth != depth && depth < CV_32S )
{
int* ilbuf = (int*)alignPtr(buf + blocksize*esz, 16);
int* iubuf = ilbuf + cn;
BinaryFunc sccvtfunc = getConvertFunc(scdepth, CV_32S);
sccvtfunc(lb.ptr(), 1, 0, 1, (uchar*)ilbuf, 1, Size(cn, 1), 0);
sccvtfunc(ub.ptr(), 1, 0, 1, (uchar*)iubuf, 1, Size(cn, 1), 0);
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int minval = cvRound(getMinVal(depth)), maxval = cvRound(getMaxVal(depth));
for( int k = 0; k < cn; k++ )
{
if( ilbuf[k] > iubuf[k] || ilbuf[k] > maxval || iubuf[k] < minval )
ilbuf[k] = minval+1, iubuf[k] = minval;
}
lb = Mat(cn, 1, CV_32S, ilbuf);
ub = Mat(cn, 1, CV_32S, iubuf);
}
convertAndUnrollScalar( lb, src.type(), lbuf, blocksize );
convertAndUnrollScalar( ub, src.type(), ubuf, blocksize );
}
for( size_t i = 0; i < it.nplanes; i++, ++it )
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{
for( size_t j = 0; j < total; j += blocksize )
{
int bsz = (int)MIN(total - j, blocksize);
size_t delta = bsz*esz;
uchar *lptr = lbuf, *uptr = ubuf;
if( !lbScalar )
{
lptr = ptrs[2];
ptrs[2] += delta;
}
if( !ubScalar )
{
int idx = !lbScalar ? 3 : 2;
uptr = ptrs[idx];
ptrs[idx] += delta;
}
func( ptrs[0], 0, lptr, 0, uptr, 0, cn == 1 ? ptrs[1] : mbuf, 0, Size(bsz*cn, 1));
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if( cn > 1 )
inRangeReduce(mbuf, ptrs[1], bsz, cn);
ptrs[0] += delta;
ptrs[1] += bsz;
}
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}
}
/****************************************************************************************\
* Earlier API: cvAdd etc. *
\****************************************************************************************/
CV_IMPL void
cvNot( const CvArr* srcarr, CvArr* dstarr )
{
cv::Mat src = cv::cvarrToMat(srcarr), dst = cv::cvarrToMat(dstarr);
CV_Assert( src.size == dst.size && src.type() == dst.type() );
cv::bitwise_not( src, dst );
}
CV_IMPL void
cvAnd( const CvArr* srcarr1, const CvArr* srcarr2, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), src2 = cv::cvarrToMat(srcarr2),
dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src1.size == dst.size && src1.type() == dst.type() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::bitwise_and( src1, src2, dst, mask );
}
CV_IMPL void
cvOr( const CvArr* srcarr1, const CvArr* srcarr2, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), src2 = cv::cvarrToMat(srcarr2),
dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src1.size == dst.size && src1.type() == dst.type() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::bitwise_or( src1, src2, dst, mask );
}
CV_IMPL void
cvXor( const CvArr* srcarr1, const CvArr* srcarr2, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), src2 = cv::cvarrToMat(srcarr2),
dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src1.size == dst.size && src1.type() == dst.type() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::bitwise_xor( src1, src2, dst, mask );
}
CV_IMPL void
cvAndS( const CvArr* srcarr, CvScalar s, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src = cv::cvarrToMat(srcarr), dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src.size == dst.size && src.type() == dst.type() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::bitwise_and( src, (const cv::Scalar&)s, dst, mask );
}
CV_IMPL void
cvOrS( const CvArr* srcarr, CvScalar s, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src = cv::cvarrToMat(srcarr), dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src.size == dst.size && src.type() == dst.type() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::bitwise_or( src, (const cv::Scalar&)s, dst, mask );
}
CV_IMPL void
cvXorS( const CvArr* srcarr, CvScalar s, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src = cv::cvarrToMat(srcarr), dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src.size == dst.size && src.type() == dst.type() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::bitwise_xor( src, (const cv::Scalar&)s, dst, mask );
}
CV_IMPL void cvAdd( const CvArr* srcarr1, const CvArr* srcarr2, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), src2 = cv::cvarrToMat(srcarr2),
dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src1.size == dst.size && src1.channels() == dst.channels() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::add( src1, src2, dst, mask, dst.type() );
}
CV_IMPL void cvSub( const CvArr* srcarr1, const CvArr* srcarr2, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), src2 = cv::cvarrToMat(srcarr2),
dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src1.size == dst.size && src1.channels() == dst.channels() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::subtract( src1, src2, dst, mask, dst.type() );
}
CV_IMPL void cvAddS( const CvArr* srcarr1, CvScalar value, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1),
dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src1.size == dst.size && src1.channels() == dst.channels() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::add( src1, (const cv::Scalar&)value, dst, mask, dst.type() );
}
CV_IMPL void cvSubRS( const CvArr* srcarr1, CvScalar value, CvArr* dstarr, const CvArr* maskarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1),
dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src1.size == dst.size && src1.channels() == dst.channels() );
if( maskarr )
mask = cv::cvarrToMat(maskarr);
cv::subtract( (const cv::Scalar&)value, src1, dst, mask, dst.type() );
}
CV_IMPL void cvMul( const CvArr* srcarr1, const CvArr* srcarr2,
CvArr* dstarr, double scale )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), src2 = cv::cvarrToMat(srcarr2),
dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && src1.channels() == dst.channels() );
cv::multiply( src1, src2, dst, scale, dst.type() );
}
CV_IMPL void cvDiv( const CvArr* srcarr1, const CvArr* srcarr2,
CvArr* dstarr, double scale )
{
cv::Mat src2 = cv::cvarrToMat(srcarr2),
dst = cv::cvarrToMat(dstarr), mask;
CV_Assert( src2.size == dst.size && src2.channels() == dst.channels() );
if( srcarr1 )
cv::divide( cv::cvarrToMat(srcarr1), src2, dst, scale, dst.type() );
else
cv::divide( scale, src2, dst, dst.type() );
}
CV_IMPL void
cvAddWeighted( const CvArr* srcarr1, double alpha,
const CvArr* srcarr2, double beta,
double gamma, CvArr* dstarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), src2 = cv::cvarrToMat(srcarr2),
dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && src1.channels() == dst.channels() );
cv::addWeighted( src1, alpha, src2, beta, gamma, dst, dst.type() );
}
CV_IMPL void
cvAbsDiff( const CvArr* srcarr1, const CvArr* srcarr2, CvArr* dstarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && src1.type() == dst.type() );
cv::absdiff( src1, cv::cvarrToMat(srcarr2), dst );
}
CV_IMPL void
cvAbsDiffS( const CvArr* srcarr1, CvArr* dstarr, CvScalar scalar )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && src1.type() == dst.type() );
cv::absdiff( src1, (const cv::Scalar&)scalar, dst );
}
CV_IMPL void
cvInRange( const void* srcarr1, const void* srcarr2,
const void* srcarr3, void* dstarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && dst.type() == CV_8U );
cv::inRange( src1, cv::cvarrToMat(srcarr2), cv::cvarrToMat(srcarr3), dst );
}
CV_IMPL void
cvInRangeS( const void* srcarr1, CvScalar lowerb, CvScalar upperb, void* dstarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && dst.type() == CV_8U );
cv::inRange( src1, (const cv::Scalar&)lowerb, (const cv::Scalar&)upperb, dst );
}
CV_IMPL void
cvCmp( const void* srcarr1, const void* srcarr2, void* dstarr, int cmp_op )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && dst.type() == CV_8U );
cv::compare( src1, cv::cvarrToMat(srcarr2), dst, cmp_op );
}
CV_IMPL void
cvCmpS( const void* srcarr1, double value, void* dstarr, int cmp_op )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && dst.type() == CV_8U );
cv::compare( src1, value, dst, cmp_op );
}
CV_IMPL void
cvMin( const void* srcarr1, const void* srcarr2, void* dstarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && src1.type() == dst.type() );
cv::min( src1, cv::cvarrToMat(srcarr2), dst );
}
CV_IMPL void
cvMax( const void* srcarr1, const void* srcarr2, void* dstarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && src1.type() == dst.type() );
cv::max( src1, cv::cvarrToMat(srcarr2), dst );
}
CV_IMPL void
cvMinS( const void* srcarr1, double value, void* dstarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && src1.type() == dst.type() );
cv::min( src1, value, dst );
}
CV_IMPL void
cvMaxS( const void* srcarr1, double value, void* dstarr )
{
cv::Mat src1 = cv::cvarrToMat(srcarr1), dst = cv::cvarrToMat(dstarr);
CV_Assert( src1.size == dst.size && src1.type() == dst.type() );
cv::max( src1, value, dst );
}
/* End of file. */