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848 lines
36 KiB
848 lines
36 KiB
/*M/////////////////////////////////////////////////////////////////////////////////////// |
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// |
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// IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. |
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// By downloading, copying, installing or using the software you agree to this license. |
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// If you do not agree to this license, do not download, install, |
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// copy or use the software. |
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// |
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// License Agreement |
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// For Open Source Computer Vision Library |
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// Copyright (C) 2000-2008, Intel Corporation, all rights reserved. |
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// Copyright (C) 2009, Willow Garage Inc., all rights reserved. |
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// Third party copyrights are property of their respective owners. |
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// Redistribution and use in source and binary forms, with or without modification, |
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// * Redistribution's of source code must retain the above copyright notice, |
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// * Redistribution's in binary form must reproduce the above copyright notice, |
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// * The name of the copyright holders may not be used to endorse or promote products |
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// derived from this software without specific prior written permission. |
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// This software is provided by the copyright holders and contributors "as is" and |
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//M*/ |
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#ifndef __OPENCV_CUDAARITHM_HPP__ |
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#define __OPENCV_CUDAARITHM_HPP__ |
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#ifndef __cplusplus |
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# error cudaarithm.hpp header must be compiled as C++ |
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#endif |
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#include "opencv2/core/cuda.hpp" |
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/** |
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@addtogroup cuda |
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@{ |
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@defgroup cudaarithm Operations on Matrices |
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@{ |
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@defgroup cudaarithm_core Core Operations on Matrices |
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@defgroup cudaarithm_elem Per-element Operations |
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@defgroup cudaarithm_reduce Matrix Reductions |
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@defgroup cudaarithm_arithm Arithm Operations on Matrices |
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@} |
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@} |
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*/ |
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namespace cv { namespace cuda { |
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//! @addtogroup cudaarithm |
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//! @{ |
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//! @addtogroup cudaarithm_elem |
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//! @{ |
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/** @brief Computes a matrix-matrix or matrix-scalar sum. |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. Matrix should have the same size and type as src1 . |
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@param dst Destination matrix that has the same size and number of channels as the input array(s). |
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The depth is defined by dtype or src1 depth. |
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@param mask Optional operation mask, 8-bit single channel array, that specifies elements of the |
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destination array to be changed. The mask can be used only with single channel images. |
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@param dtype Optional depth of the output array. |
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@param stream Stream for the asynchronous version. |
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@sa add |
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*/ |
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CV_EXPORTS void add(InputArray src1, InputArray src2, OutputArray dst, InputArray mask = noArray(), int dtype = -1, Stream& stream = Stream::Null()); |
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/** @brief Computes a matrix-matrix or matrix-scalar difference. |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. Matrix should have the same size and type as src1 . |
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@param dst Destination matrix that has the same size and number of channels as the input array(s). |
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The depth is defined by dtype or src1 depth. |
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@param mask Optional operation mask, 8-bit single channel array, that specifies elements of the |
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destination array to be changed. The mask can be used only with single channel images. |
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@param dtype Optional depth of the output array. |
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@param stream Stream for the asynchronous version. |
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@sa subtract |
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*/ |
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CV_EXPORTS void subtract(InputArray src1, InputArray src2, OutputArray dst, InputArray mask = noArray(), int dtype = -1, Stream& stream = Stream::Null()); |
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/** @brief Computes a matrix-matrix or matrix-scalar per-element product. |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. |
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@param dst Destination matrix that has the same size and number of channels as the input array(s). |
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The depth is defined by dtype or src1 depth. |
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@param scale Optional scale factor. |
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@param dtype Optional depth of the output array. |
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@param stream Stream for the asynchronous version. |
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@sa multiply |
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*/ |
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CV_EXPORTS void multiply(InputArray src1, InputArray src2, OutputArray dst, double scale = 1, int dtype = -1, Stream& stream = Stream::Null()); |
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/** @brief Computes a matrix-matrix or matrix-scalar division. |
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@param src1 First source matrix or a scalar. |
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@param src2 Second source matrix or scalar. |
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@param dst Destination matrix that has the same size and number of channels as the input array(s). |
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The depth is defined by dtype or src1 depth. |
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@param scale Optional scale factor. |
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@param dtype Optional depth of the output array. |
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@param stream Stream for the asynchronous version. |
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This function, in contrast to divide, uses a round-down rounding mode. |
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@sa divide |
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*/ |
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CV_EXPORTS void divide(InputArray src1, InputArray src2, OutputArray dst, double scale = 1, int dtype = -1, Stream& stream = Stream::Null()); |
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/** @brief Computes per-element absolute difference of two matrices (or of a matrix and scalar). |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. |
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@param dst Destination matrix that has the same size and type as the input array(s). |
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@param stream Stream for the asynchronous version. |
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@sa absdiff |
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*/ |
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CV_EXPORTS void absdiff(InputArray src1, InputArray src2, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Computes an absolute value of each matrix element. |
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@param src Source matrix. |
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@param dst Destination matrix with the same size and type as src . |
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@param stream Stream for the asynchronous version. |
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@sa abs |
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*/ |
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CV_EXPORTS void abs(InputArray src, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Computes a square value of each matrix element. |
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@param src Source matrix. |
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@param dst Destination matrix with the same size and type as src . |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void sqr(InputArray src, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Computes a square root of each matrix element. |
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@param src Source matrix. |
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@param dst Destination matrix with the same size and type as src . |
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@param stream Stream for the asynchronous version. |
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@sa sqrt |
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*/ |
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CV_EXPORTS void sqrt(InputArray src, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Computes an exponent of each matrix element. |
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@param src Source matrix. |
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@param dst Destination matrix with the same size and type as src . |
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@param stream Stream for the asynchronous version. |
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@sa exp |
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*/ |
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CV_EXPORTS void exp(InputArray src, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Computes a natural logarithm of absolute value of each matrix element. |
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@param src Source matrix. |
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@param dst Destination matrix with the same size and type as src . |
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@param stream Stream for the asynchronous version. |
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@sa log |
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*/ |
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CV_EXPORTS void log(InputArray src, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Raises every matrix element to a power. |
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@param src Source matrix. |
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@param power Exponent of power. |
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@param dst Destination matrix with the same size and type as src . |
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@param stream Stream for the asynchronous version. |
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The function pow raises every element of the input matrix to power : |
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\f[\texttt{dst} (I) = \fork{\texttt{src}(I)^power}{if \texttt{power} is integer}{|\texttt{src}(I)|^power}{otherwise}\f] |
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@sa pow |
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*/ |
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CV_EXPORTS void pow(InputArray src, double power, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Compares elements of two matrices (or of a matrix and scalar). |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. |
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@param dst Destination matrix that has the same size and type as the input array(s). |
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@param cmpop Flag specifying the relation between the elements to be checked: |
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- **CMP_EQ:** a(.) == b(.) |
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- **CMP_GT:** a(.) \> b(.) |
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- **CMP_GE:** a(.) \>= b(.) |
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- **CMP_LT:** a(.) \< b(.) |
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- **CMP_LE:** a(.) \<= b(.) |
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- **CMP_NE:** a(.) != b(.) |
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@param stream Stream for the asynchronous version. |
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@sa compare |
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*/ |
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CV_EXPORTS void compare(InputArray src1, InputArray src2, OutputArray dst, int cmpop, Stream& stream = Stream::Null()); |
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/** @brief Performs a per-element bitwise inversion. |
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@param src Source matrix. |
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@param dst Destination matrix with the same size and type as src . |
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@param mask Optional operation mask, 8-bit single channel array, that specifies elements of the |
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destination array to be changed. The mask can be used only with single channel images. |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void bitwise_not(InputArray src, OutputArray dst, InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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/** @brief Performs a per-element bitwise disjunction of two matrices (or of matrix and scalar). |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. |
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@param dst Destination matrix that has the same size and type as the input array(s). |
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@param mask Optional operation mask, 8-bit single channel array, that specifies elements of the |
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destination array to be changed. The mask can be used only with single channel images. |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void bitwise_or(InputArray src1, InputArray src2, OutputArray dst, InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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/** @brief Performs a per-element bitwise conjunction of two matrices (or of matrix and scalar). |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. |
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@param dst Destination matrix that has the same size and type as the input array(s). |
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@param mask Optional operation mask, 8-bit single channel array, that specifies elements of the |
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destination array to be changed. The mask can be used only with single channel images. |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void bitwise_and(InputArray src1, InputArray src2, OutputArray dst, InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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/** @brief Performs a per-element bitwise exclusive or operation of two matrices (or of matrix and scalar). |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. |
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@param dst Destination matrix that has the same size and type as the input array(s). |
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@param mask Optional operation mask, 8-bit single channel array, that specifies elements of the |
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destination array to be changed. The mask can be used only with single channel images. |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void bitwise_xor(InputArray src1, InputArray src2, OutputArray dst, InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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/** @brief Performs pixel by pixel right shift of an image by a constant value. |
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@param src Source matrix. Supports 1, 3 and 4 channels images with integers elements. |
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@param val Constant values, one per channel. |
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@param dst Destination matrix with the same size and type as src . |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void rshift(InputArray src, Scalar_<int> val, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Performs pixel by pixel right left of an image by a constant value. |
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@param src Source matrix. Supports 1, 3 and 4 channels images with CV_8U , CV_16U or CV_32S |
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depth. |
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@param val Constant values, one per channel. |
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@param dst Destination matrix with the same size and type as src . |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void lshift(InputArray src, Scalar_<int> val, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Computes the per-element minimum of two matrices (or a matrix and a scalar). |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. |
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@param dst Destination matrix that has the same size and type as the input array(s). |
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@param stream Stream for the asynchronous version. |
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@sa min |
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*/ |
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CV_EXPORTS void min(InputArray src1, InputArray src2, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Computes the per-element maximum of two matrices (or a matrix and a scalar). |
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@param src1 First source matrix or scalar. |
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@param src2 Second source matrix or scalar. |
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@param dst Destination matrix that has the same size and type as the input array(s). |
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@param stream Stream for the asynchronous version. |
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@sa max |
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*/ |
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CV_EXPORTS void max(InputArray src1, InputArray src2, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Computes the weighted sum of two arrays. |
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@param src1 First source array. |
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@param alpha Weight for the first array elements. |
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@param src2 Second source array of the same size and channel number as src1 . |
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@param beta Weight for the second array elements. |
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@param dst Destination array that has the same size and number of channels as the input arrays. |
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@param gamma Scalar added to each sum. |
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@param dtype Optional depth of the destination array. When both input arrays have the same depth, |
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dtype can be set to -1, which will be equivalent to src1.depth(). |
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@param stream Stream for the asynchronous version. |
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The function addWeighted calculates the weighted sum of two arrays as follows: |
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\f[\texttt{dst} (I)= \texttt{saturate} ( \texttt{src1} (I)* \texttt{alpha} + \texttt{src2} (I)* \texttt{beta} + \texttt{gamma} )\f] |
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where I is a multi-dimensional index of array elements. In case of multi-channel arrays, each |
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channel is processed independently. |
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@sa addWeighted |
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*/ |
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CV_EXPORTS void addWeighted(InputArray src1, double alpha, InputArray src2, double beta, double gamma, OutputArray dst, |
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int dtype = -1, Stream& stream = Stream::Null()); |
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//! adds scaled array to another one (dst = alpha*src1 + src2) |
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static inline void scaleAdd(InputArray src1, double alpha, InputArray src2, OutputArray dst, Stream& stream = Stream::Null()) |
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{ |
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addWeighted(src1, alpha, src2, 1.0, 0.0, dst, -1, stream); |
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} |
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/** @brief Applies a fixed-level threshold to each array element. |
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@param src Source array (single-channel). |
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@param dst Destination array with the same size and type as src . |
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@param thresh Threshold value. |
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@param maxval Maximum value to use with THRESH_BINARY and THRESH_BINARY_INV threshold types. |
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@param type Threshold type. For details, see threshold . The THRESH_OTSU and THRESH_TRIANGLE |
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threshold types are not supported. |
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@param stream Stream for the asynchronous version. |
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@sa threshold |
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*/ |
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CV_EXPORTS double threshold(InputArray src, OutputArray dst, double thresh, double maxval, int type, Stream& stream = Stream::Null()); |
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/** @brief Computes magnitudes of complex matrix elements. |
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@param xy Source complex matrix in the interleaved format ( CV_32FC2 ). |
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@param magnitude Destination matrix of float magnitudes ( CV_32FC1 ). |
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@param stream Stream for the asynchronous version. |
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@sa magnitude |
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*/ |
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CV_EXPORTS void magnitude(InputArray xy, OutputArray magnitude, Stream& stream = Stream::Null()); |
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/** @brief Computes squared magnitudes of complex matrix elements. |
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@param xy Source complex matrix in the interleaved format ( CV_32FC2 ). |
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@param magnitude Destination matrix of float magnitude squares ( CV_32FC1 ). |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void magnitudeSqr(InputArray xy, OutputArray magnitude, Stream& stream = Stream::Null()); |
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/** @overload |
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computes magnitude of each (x(i), y(i)) vector |
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supports only floating-point source |
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@param x Source matrix containing real components ( CV_32FC1 ). |
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@param y Source matrix containing imaginary components ( CV_32FC1 ). |
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@param magnitude Destination matrix of float magnitudes ( CV_32FC1 ). |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void magnitude(InputArray x, InputArray y, OutputArray magnitude, Stream& stream = Stream::Null()); |
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/** @overload |
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computes squared magnitude of each (x(i), y(i)) vector |
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supports only floating-point source |
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@param x Source matrix containing real components ( CV_32FC1 ). |
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@param y Source matrix containing imaginary components ( CV_32FC1 ). |
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@param magnitude Destination matrix of float magnitude squares ( CV_32FC1 ). |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void magnitudeSqr(InputArray x, InputArray y, OutputArray magnitude, Stream& stream = Stream::Null()); |
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/** @brief Computes polar angles of complex matrix elements. |
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@param x Source matrix containing real components ( CV_32FC1 ). |
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@param y Source matrix containing imaginary components ( CV_32FC1 ). |
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@param angle Destination matrix of angles ( CV_32FC1 ). |
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@param angleInDegrees Flag for angles that must be evaluated in degrees. |
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@param stream Stream for the asynchronous version. |
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@sa phase |
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*/ |
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CV_EXPORTS void phase(InputArray x, InputArray y, OutputArray angle, bool angleInDegrees = false, Stream& stream = Stream::Null()); |
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/** @brief Converts Cartesian coordinates into polar. |
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@param x Source matrix containing real components ( CV_32FC1 ). |
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@param y Source matrix containing imaginary components ( CV_32FC1 ). |
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@param magnitude Destination matrix of float magnitudes ( CV_32FC1 ). |
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@param angle Destination matrix of angles ( CV_32FC1 ). |
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@param angleInDegrees Flag for angles that must be evaluated in degrees. |
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@param stream Stream for the asynchronous version. |
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@sa cartToPolar |
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*/ |
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CV_EXPORTS void cartToPolar(InputArray x, InputArray y, OutputArray magnitude, OutputArray angle, bool angleInDegrees = false, Stream& stream = Stream::Null()); |
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/** @brief Converts polar coordinates into Cartesian. |
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@param magnitude Source matrix containing magnitudes ( CV_32FC1 ). |
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@param angle Source matrix containing angles ( CV_32FC1 ). |
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@param x Destination matrix of real components ( CV_32FC1 ). |
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@param y Destination matrix of imaginary components ( CV_32FC1 ). |
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@param angleInDegrees Flag that indicates angles in degrees. |
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@param stream Stream for the asynchronous version. |
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*/ |
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CV_EXPORTS void polarToCart(InputArray magnitude, InputArray angle, OutputArray x, OutputArray y, bool angleInDegrees = false, Stream& stream = Stream::Null()); |
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//! @} cudaarithm_elem |
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//! @addtogroup cudaarithm_core |
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//! @{ |
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/** @brief Makes a multi-channel matrix out of several single-channel matrices. |
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@param src Array/vector of source matrices. |
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@param n Number of source matrices. |
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@param dst Destination matrix. |
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@param stream Stream for the asynchronous version. |
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@sa merge |
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*/ |
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CV_EXPORTS void merge(const GpuMat* src, size_t n, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @overload */ |
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CV_EXPORTS void merge(const std::vector<GpuMat>& src, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Copies each plane of a multi-channel matrix into an array. |
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@param src Source matrix. |
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@param dst Destination array/vector of single-channel matrices. |
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@param stream Stream for the asynchronous version. |
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@sa split |
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*/ |
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CV_EXPORTS void split(InputArray src, GpuMat* dst, Stream& stream = Stream::Null()); |
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/** @overload */ |
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CV_EXPORTS void split(InputArray src, std::vector<GpuMat>& dst, Stream& stream = Stream::Null()); |
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/** @brief Transposes a matrix. |
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@param src1 Source matrix. 1-, 4-, 8-byte element sizes are supported for now. |
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@param dst Destination matrix. |
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@param stream Stream for the asynchronous version. |
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@sa transpose |
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*/ |
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CV_EXPORTS void transpose(InputArray src1, OutputArray dst, Stream& stream = Stream::Null()); |
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/** @brief Flips a 2D matrix around vertical, horizontal, or both axes. |
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@param src Source matrix. Supports 1, 3 and 4 channels images with CV_8U, CV_16U, CV_32S or |
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CV_32F depth. |
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@param dst Destination matrix. |
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@param flipCode Flip mode for the source: |
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- 0 Flips around x-axis. |
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- \> 0 Flips around y-axis. |
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- \< 0 Flips around both axes. |
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@param stream Stream for the asynchronous version. |
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@sa flip |
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*/ |
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CV_EXPORTS void flip(InputArray src, OutputArray dst, int flipCode, Stream& stream = Stream::Null()); |
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/** @brief Base class for transform using lookup table. |
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*/ |
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class CV_EXPORTS LookUpTable : public Algorithm |
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{ |
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public: |
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/** @brief Transforms the source matrix into the destination matrix using the given look-up table: |
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dst(I) = lut(src(I)) . |
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@param src Source matrix. CV_8UC1 and CV_8UC3 matrices are supported for now. |
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@param dst Destination matrix. |
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@param stream Stream for the asynchronous version. |
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*/ |
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virtual void transform(InputArray src, OutputArray dst, Stream& stream = Stream::Null()) = 0; |
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}; |
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/** @brief Creates implementation for cuda::LookUpTable . |
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@param lut Look-up table of 256 elements. It is a continuous CV_8U matrix. |
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*/ |
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CV_EXPORTS Ptr<LookUpTable> createLookUpTable(InputArray lut); |
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/** @brief Forms a border around an image. |
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@param src Source image. CV_8UC1 , CV_8UC4 , CV_32SC1 , and CV_32FC1 types are supported. |
|
@param dst Destination image with the same type as src. The size is |
|
Size(src.cols+left+right, src.rows+top+bottom) . |
|
@param top |
|
@param bottom |
|
@param left |
|
@param right Number of pixels in each direction from the source image rectangle to extrapolate. |
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For example: top=1, bottom=1, left=1, right=1 mean that 1 pixel-wide border needs to be built. |
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@param borderType Border type. See borderInterpolate for details. BORDER_REFLECT101 , |
|
BORDER_REPLICATE , BORDER_CONSTANT , BORDER_REFLECT and BORDER_WRAP are supported for now. |
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@param value Border value. |
|
@param stream Stream for the asynchronous version. |
|
*/ |
|
CV_EXPORTS void copyMakeBorder(InputArray src, OutputArray dst, int top, int bottom, int left, int right, int borderType, |
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Scalar value = Scalar(), Stream& stream = Stream::Null()); |
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|
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//! @} cudaarithm_core |
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|
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//! @addtogroup cudaarithm_reduce |
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//! @{ |
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|
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/** @brief Returns the norm of a matrix (or difference of two matrices). |
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|
|
@param src1 Source matrix. Any matrices except 64F are supported. |
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@param normType Norm type. NORM_L1 , NORM_L2 , and NORM_INF are supported for now. |
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@param mask optional operation mask; it must have the same size as src1 and CV_8UC1 type. |
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|
|
@sa norm |
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*/ |
|
CV_EXPORTS double norm(InputArray src1, int normType, InputArray mask = noArray()); |
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/** @overload */ |
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CV_EXPORTS void calcNorm(InputArray src, OutputArray dst, int normType, InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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|
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/** @brief Returns the difference of two matrices. |
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|
|
@param src1 Source matrix. Any matrices except 64F are supported. |
|
@param src2 Second source matrix (if any) with the same size and type as src1. |
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@param normType Norm type. NORM_L1 , NORM_L2 , and NORM_INF are supported for now. |
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|
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@sa norm |
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*/ |
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CV_EXPORTS double norm(InputArray src1, InputArray src2, int normType=NORM_L2); |
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/** @overload */ |
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CV_EXPORTS void calcNormDiff(InputArray src1, InputArray src2, OutputArray dst, int normType=NORM_L2, Stream& stream = Stream::Null()); |
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|
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/** @brief Returns the sum of matrix elements. |
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|
|
@param src Source image of any depth except for CV_64F . |
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@param mask optional operation mask; it must have the same size as src1 and CV_8UC1 type. |
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|
|
@sa sum |
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*/ |
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CV_EXPORTS Scalar sum(InputArray src, InputArray mask = noArray()); |
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/** @overload */ |
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CV_EXPORTS void calcSum(InputArray src, OutputArray dst, InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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|
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/** @brief Returns the sum of absolute values for matrix elements. |
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|
|
@param src Source image of any depth except for CV_64F . |
|
@param mask optional operation mask; it must have the same size as src1 and CV_8UC1 type. |
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*/ |
|
CV_EXPORTS Scalar absSum(InputArray src, InputArray mask = noArray()); |
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/** @overload */ |
|
CV_EXPORTS void calcAbsSum(InputArray src, OutputArray dst, InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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|
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/** @brief Returns the squared sum of matrix elements. |
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|
|
@param src Source image of any depth except for CV_64F . |
|
@param mask optional operation mask; it must have the same size as src1 and CV_8UC1 type. |
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*/ |
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CV_EXPORTS Scalar sqrSum(InputArray src, InputArray mask = noArray()); |
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/** @overload */ |
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CV_EXPORTS void calcSqrSum(InputArray src, OutputArray dst, InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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|
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/** @brief Finds global minimum and maximum matrix elements and returns their values. |
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|
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@param src Single-channel source image. |
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@param minVal Pointer to the returned minimum value. Use NULL if not required. |
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@param maxVal Pointer to the returned maximum value. Use NULL if not required. |
|
@param mask Optional mask to select a sub-matrix. |
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|
|
The function does not work with CV_64F images on GPUs with the compute capability \< 1.3. |
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|
|
@sa minMaxLoc |
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*/ |
|
CV_EXPORTS void minMax(InputArray src, double* minVal, double* maxVal, InputArray mask = noArray()); |
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/** @overload */ |
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CV_EXPORTS void findMinMax(InputArray src, OutputArray dst, InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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|
|
/** @brief Finds global minimum and maximum matrix elements and returns their values with locations. |
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|
|
@param src Single-channel source image. |
|
@param minVal Pointer to the returned minimum value. Use NULL if not required. |
|
@param maxVal Pointer to the returned maximum value. Use NULL if not required. |
|
@param minLoc Pointer to the returned minimum location. Use NULL if not required. |
|
@param maxLoc Pointer to the returned maximum location. Use NULL if not required. |
|
@param mask Optional mask to select a sub-matrix. |
|
|
|
The function does not work with CV_64F images on GPU with the compute capability \< 1.3. |
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|
|
@sa minMaxLoc |
|
*/ |
|
CV_EXPORTS void minMaxLoc(InputArray src, double* minVal, double* maxVal, Point* minLoc, Point* maxLoc, |
|
InputArray mask = noArray()); |
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/** @overload */ |
|
CV_EXPORTS void findMinMaxLoc(InputArray src, OutputArray minMaxVals, OutputArray loc, |
|
InputArray mask = noArray(), Stream& stream = Stream::Null()); |
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|
|
/** @brief Counts non-zero matrix elements. |
|
|
|
@param src Single-channel source image. |
|
|
|
The function does not work with CV_64F images on GPUs with the compute capability \< 1.3. |
|
|
|
@sa countNonZero |
|
*/ |
|
CV_EXPORTS int countNonZero(InputArray src); |
|
/** @overload */ |
|
CV_EXPORTS void countNonZero(InputArray src, OutputArray dst, Stream& stream = Stream::Null()); |
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|
|
/** @brief Reduces a matrix to a vector. |
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|
|
@param mtx Source 2D matrix. |
|
@param vec Destination vector. Its size and type is defined by dim and dtype parameters. |
|
@param dim Dimension index along which the matrix is reduced. 0 means that the matrix is reduced |
|
to a single row. 1 means that the matrix is reduced to a single column. |
|
@param reduceOp Reduction operation that could be one of the following: |
|
- **CV_REDUCE_SUM** The output is the sum of all rows/columns of the matrix. |
|
- **CV_REDUCE_AVG** The output is the mean vector of all rows/columns of the matrix. |
|
- **CV_REDUCE_MAX** The output is the maximum (column/row-wise) of all rows/columns of the |
|
matrix. |
|
- **CV_REDUCE_MIN** The output is the minimum (column/row-wise) of all rows/columns of the |
|
matrix. |
|
@param dtype When it is negative, the destination vector will have the same type as the source |
|
matrix. Otherwise, its type will be CV_MAKE_TYPE(CV_MAT_DEPTH(dtype), mtx.channels()) . |
|
@param stream Stream for the asynchronous version. |
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|
|
The function reduce reduces the matrix to a vector by treating the matrix rows/columns as a set of |
|
1D vectors and performing the specified operation on the vectors until a single row/column is |
|
obtained. For example, the function can be used to compute horizontal and vertical projections of a |
|
raster image. In case of CV_REDUCE_SUM and CV_REDUCE_AVG , the output may have a larger element |
|
bit-depth to preserve accuracy. And multi-channel arrays are also supported in these two reduction |
|
modes. |
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|
|
@sa reduce |
|
*/ |
|
CV_EXPORTS void reduce(InputArray mtx, OutputArray vec, int dim, int reduceOp, int dtype = -1, Stream& stream = Stream::Null()); |
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|
|
/** @brief Computes a mean value and a standard deviation of matrix elements. |
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|
|
@param mtx Source matrix. CV_8UC1 matrices are supported for now. |
|
@param mean Mean value. |
|
@param stddev Standard deviation value. |
|
|
|
@sa meanStdDev |
|
*/ |
|
CV_EXPORTS void meanStdDev(InputArray mtx, Scalar& mean, Scalar& stddev); |
|
/** @overload */ |
|
CV_EXPORTS void meanStdDev(InputArray mtx, OutputArray dst, Stream& stream = Stream::Null()); |
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|
|
/** @brief Computes a standard deviation of integral images. |
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|
|
@param src Source image. Only the CV_32SC1 type is supported. |
|
@param sqr Squared source image. Only the CV_32FC1 type is supported. |
|
@param dst Destination image with the same type and size as src . |
|
@param rect Rectangular window. |
|
@param stream Stream for the asynchronous version. |
|
*/ |
|
CV_EXPORTS void rectStdDev(InputArray src, InputArray sqr, OutputArray dst, Rect rect, Stream& stream = Stream::Null()); |
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|
|
/** @brief Normalizes the norm or value range of an array. |
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|
|
@param src Input array. |
|
@param dst Output array of the same size as src . |
|
@param alpha Norm value to normalize to or the lower range boundary in case of the range |
|
normalization. |
|
@param beta Upper range boundary in case of the range normalization; it is not used for the norm |
|
normalization. |
|
@param norm_type Normalization type ( NORM_MINMAX , NORM_L2 , NORM_L1 or NORM_INF ). |
|
@param dtype When negative, the output array has the same type as src; otherwise, it has the same |
|
number of channels as src and the depth =CV_MAT_DEPTH(dtype). |
|
@param mask Optional operation mask. |
|
@param stream Stream for the asynchronous version. |
|
|
|
@sa normalize |
|
*/ |
|
CV_EXPORTS void normalize(InputArray src, OutputArray dst, double alpha, double beta, |
|
int norm_type, int dtype, InputArray mask = noArray(), |
|
Stream& stream = Stream::Null()); |
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|
|
/** @brief Computes an integral image. |
|
|
|
@param src Source image. Only CV_8UC1 images are supported for now. |
|
@param sum Integral image containing 32-bit unsigned integer values packed into CV_32SC1 . |
|
@param stream Stream for the asynchronous version. |
|
|
|
@sa integral |
|
*/ |
|
CV_EXPORTS void integral(InputArray src, OutputArray sum, Stream& stream = Stream::Null()); |
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|
|
/** @brief Computes a squared integral image. |
|
|
|
@param src Source image. Only CV_8UC1 images are supported for now. |
|
@param sqsum Squared integral image containing 64-bit unsigned integer values packed into |
|
CV_64FC1 . |
|
@param stream Stream for the asynchronous version. |
|
*/ |
|
CV_EXPORTS void sqrIntegral(InputArray src, OutputArray sqsum, Stream& stream = Stream::Null()); |
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|
|
//! @} cudaarithm_reduce |
|
|
|
//! @addtogroup cudaarithm_arithm |
|
//! @{ |
|
|
|
/** @brief Performs generalized matrix multiplication. |
|
|
|
@param src1 First multiplied input matrix that should have CV_32FC1 , CV_64FC1 , CV_32FC2 , or |
|
CV_64FC2 type. |
|
@param src2 Second multiplied input matrix of the same type as src1 . |
|
@param alpha Weight of the matrix product. |
|
@param src3 Third optional delta matrix added to the matrix product. It should have the same type |
|
as src1 and src2 . |
|
@param beta Weight of src3 . |
|
@param dst Destination matrix. It has the proper size and the same type as input matrices. |
|
@param flags Operation flags: |
|
- **GEMM_1_T** transpose src1 |
|
- **GEMM_2_T** transpose src2 |
|
- **GEMM_3_T** transpose src3 |
|
@param stream Stream for the asynchronous version. |
|
|
|
The function performs generalized matrix multiplication similar to the gemm functions in BLAS level |
|
3. For example, gemm(src1, src2, alpha, src3, beta, dst, GEMM_1_T + GEMM_3_T) corresponds to |
|
|
|
\f[\texttt{dst} = \texttt{alpha} \cdot \texttt{src1} ^T \cdot \texttt{src2} + \texttt{beta} \cdot \texttt{src3} ^T\f] |
|
|
|
@note Transposition operation doesn't support CV_64FC2 input type. |
|
|
|
@sa gemm |
|
*/ |
|
CV_EXPORTS void gemm(InputArray src1, InputArray src2, double alpha, |
|
InputArray src3, double beta, OutputArray dst, int flags = 0, Stream& stream = Stream::Null()); |
|
|
|
/** @brief Performs a per-element multiplication of two Fourier spectrums. |
|
|
|
@param src1 First spectrum. |
|
@param src2 Second spectrum with the same size and type as a . |
|
@param dst Destination spectrum. |
|
@param flags Mock parameter used for CPU/CUDA interfaces similarity. |
|
@param conjB Optional flag to specify if the second spectrum needs to be conjugated before the |
|
multiplication. |
|
@param stream Stream for the asynchronous version. |
|
|
|
Only full (not packed) CV_32FC2 complex spectrums in the interleaved format are supported for now. |
|
|
|
@sa mulSpectrums |
|
*/ |
|
CV_EXPORTS void mulSpectrums(InputArray src1, InputArray src2, OutputArray dst, int flags, bool conjB=false, Stream& stream = Stream::Null()); |
|
|
|
/** @brief Performs a per-element multiplication of two Fourier spectrums and scales the result. |
|
|
|
@param src1 First spectrum. |
|
@param src2 Second spectrum with the same size and type as a . |
|
@param dst Destination spectrum. |
|
@param flags Mock parameter used for CPU/CUDA interfaces similarity, simply add a `0` value. |
|
@param scale Scale constant. |
|
@param conjB Optional flag to specify if the second spectrum needs to be conjugated before the |
|
multiplication. |
|
@param stream Stream for the asynchronous version. |
|
|
|
Only full (not packed) CV_32FC2 complex spectrums in the interleaved format are supported for now. |
|
|
|
@sa mulSpectrums |
|
*/ |
|
CV_EXPORTS void mulAndScaleSpectrums(InputArray src1, InputArray src2, OutputArray dst, int flags, float scale, bool conjB=false, Stream& stream = Stream::Null()); |
|
|
|
/** @brief Performs a forward or inverse discrete Fourier transform (1D or 2D) of the floating point matrix. |
|
|
|
@param src Source matrix (real or complex). |
|
@param dst Destination matrix (real or complex). |
|
@param dft_size Size of a discrete Fourier transform. |
|
@param flags Optional flags: |
|
- **DFT_ROWS** transforms each individual row of the source matrix. |
|
- **DFT_SCALE** scales the result: divide it by the number of elements in the transform |
|
(obtained from dft_size ). |
|
- **DFT_INVERSE** inverts DFT. Use for complex-complex cases (real-complex and complex-real |
|
cases are always forward and inverse, respectively). |
|
- **DFT_REAL_OUTPUT** specifies the output as real. The source matrix is the result of |
|
real-complex transform, so the destination matrix must be real. |
|
@param stream Stream for the asynchronous version. |
|
|
|
Use to handle real matrices ( CV32FC1 ) and complex matrices in the interleaved format ( CV32FC2 ). |
|
|
|
The source matrix should be continuous, otherwise reallocation and data copying is performed. The |
|
function chooses an operation mode depending on the flags, size, and channel count of the source |
|
matrix: |
|
|
|
- If the source matrix is complex and the output is not specified as real, the destination |
|
matrix is complex and has the dft_size size and CV_32FC2 type. The destination matrix |
|
contains a full result of the DFT (forward or inverse). |
|
- If the source matrix is complex and the output is specified as real, the function assumes that |
|
its input is the result of the forward transform (see the next item). The destination matrix |
|
has the dft_size size and CV_32FC1 type. It contains the result of the inverse DFT. |
|
- If the source matrix is real (its type is CV_32FC1 ), forward DFT is performed. The result of |
|
the DFT is packed into complex ( CV_32FC2 ) matrix. So, the width of the destination matrix |
|
is dft_size.width / 2 + 1 . But if the source is a single column, the height is reduced |
|
instead of the width. |
|
|
|
@sa dft |
|
*/ |
|
CV_EXPORTS void dft(InputArray src, OutputArray dst, Size dft_size, int flags=0, Stream& stream = Stream::Null()); |
|
|
|
/** @brief Base class for convolution (or cross-correlation) operator. : |
|
*/ |
|
class CV_EXPORTS Convolution : public Algorithm |
|
{ |
|
public: |
|
/** @brief Computes a convolution (or cross-correlation) of two images. |
|
|
|
@param image Source image. Only CV_32FC1 images are supported for now. |
|
@param templ Template image. The size is not greater than the image size. The type is the same as |
|
image . |
|
@param result Result image. If image is *W x H* and templ is *w x h*, then result must be *W-w+1 x |
|
H-h+1*. |
|
@param ccorr Flags to evaluate cross-correlation instead of convolution. |
|
@param stream Stream for the asynchronous version. |
|
*/ |
|
virtual void convolve(InputArray image, InputArray templ, OutputArray result, bool ccorr = false, Stream& stream = Stream::Null()) = 0; |
|
}; |
|
|
|
/** @brief Creates implementation for cuda::Convolution . |
|
|
|
@param user_block_size Block size. If you leave default value Size(0,0) then automatic |
|
estimation of block size will be used (which is optimized for speed). By varying user_block_size |
|
you can reduce memory requirements at the cost of speed. |
|
*/ |
|
CV_EXPORTS Ptr<Convolution> createConvolution(Size user_block_size = Size()); |
|
|
|
//! @} cudaarithm_arithm |
|
|
|
//! @} cudaarithm |
|
|
|
}} // namespace cv { namespace cuda { |
|
|
|
#endif /* __OPENCV_CUDAARITHM_HPP__ */
|
|
|