/*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) 2009-2010, 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*/ /* //////////////////////////////////////////////////////////////////// // // Mat basic operations: Copy, Set // // */ #include "precomp.hpp" namespace cv { class MatOp_Identity : public MatOp { public: MatOp_Identity() {} virtual ~MatOp_Identity() {} bool elementWise(const MatExpr& /*expr*/) const { return true; } void assign(const MatExpr& expr, Mat& m, int type=-1) const; static void makeExpr(MatExpr& res, const Mat& m); }; static MatOp_Identity g_MatOp_Identity; class MatOp_AddEx : public MatOp { public: MatOp_AddEx() {} virtual ~MatOp_AddEx() {} bool elementWise(const MatExpr& /*expr*/) const { return true; } void assign(const MatExpr& expr, Mat& m, int type=-1) const; void add(const MatExpr& e1, const Scalar& s, MatExpr& res) const; void subtract(const Scalar& s, const MatExpr& expr, MatExpr& res) const; void multiply(const MatExpr& e1, double s, MatExpr& res) const; void divide(double s, const MatExpr& e, MatExpr& res) const; void transpose(const MatExpr& e1, MatExpr& res) const; void abs(const MatExpr& expr, MatExpr& res) const; static void makeExpr(MatExpr& res, const Mat& a, const Mat& b, double alpha, double beta, const Scalar& s=Scalar()); }; static MatOp_AddEx g_MatOp_AddEx; class MatOp_Bin : public MatOp { public: MatOp_Bin() {} virtual ~MatOp_Bin() {} bool elementWise(const MatExpr& /*expr*/) const { return true; } void assign(const MatExpr& expr, Mat& m, int type=-1) const; void multiply(const MatExpr& e1, double s, MatExpr& res) const; void divide(double s, const MatExpr& e, MatExpr& res) const; static void makeExpr(MatExpr& res, char op, const Mat& a, const Mat& b, double scale=1); static void makeExpr(MatExpr& res, char op, const Mat& a, const Scalar& s); }; static MatOp_Bin g_MatOp_Bin; class MatOp_Cmp : public MatOp { public: MatOp_Cmp() {} virtual ~MatOp_Cmp() {} bool elementWise(const MatExpr& /*expr*/) const { return true; } void assign(const MatExpr& expr, Mat& m, int type=-1) const; static void makeExpr(MatExpr& res, int cmpop, const Mat& a, const Mat& b); static void makeExpr(MatExpr& res, int cmpop, const Mat& a, double alpha); }; static MatOp_Cmp g_MatOp_Cmp; class MatOp_GEMM : public MatOp { public: MatOp_GEMM() {} virtual ~MatOp_GEMM() {} bool elementWise(const MatExpr& /*expr*/) const { return false; } void assign(const MatExpr& expr, Mat& m, int type=-1) const; void add(const MatExpr& e1, const MatExpr& e2, MatExpr& res) const; void subtract(const MatExpr& e1, const MatExpr& e2, MatExpr& res) const; void multiply(const MatExpr& e, double s, MatExpr& res) const; void transpose(const MatExpr& expr, MatExpr& res) const; static void makeExpr(MatExpr& res, int flags, const Mat& a, const Mat& b, double alpha=1, const Mat& c=Mat(), double beta=1); }; static MatOp_GEMM g_MatOp_GEMM; class MatOp_Invert : public MatOp { public: MatOp_Invert() {} virtual ~MatOp_Invert() {} bool elementWise(const MatExpr& /*expr*/) const { return false; } void assign(const MatExpr& expr, Mat& m, int type=-1) const; void matmul(const MatExpr& expr1, const MatExpr& expr2, MatExpr& res) const; static void makeExpr(MatExpr& res, int method, const Mat& m); }; static MatOp_Invert g_MatOp_Invert; class MatOp_T : public MatOp { public: MatOp_T() {} virtual ~MatOp_T() {} bool elementWise(const MatExpr& /*expr*/) const { return false; } void assign(const MatExpr& expr, Mat& m, int type=-1) const; void multiply(const MatExpr& e1, double s, MatExpr& res) const; void transpose(const MatExpr& expr, MatExpr& res) const; static void makeExpr(MatExpr& res, const Mat& a, double alpha=1); }; static MatOp_T g_MatOp_T; class MatOp_Solve : public MatOp { public: MatOp_Solve() {} virtual ~MatOp_Solve() {} bool elementWise(const MatExpr& /*expr*/) const { return false; } void assign(const MatExpr& expr, Mat& m, int type=-1) const; static void makeExpr(MatExpr& res, int method, const Mat& a, const Mat& b); }; static MatOp_Solve g_MatOp_Solve; class MatOp_Initializer : public MatOp { public: MatOp_Initializer() {} virtual ~MatOp_Initializer() {} bool elementWise(const MatExpr& /*expr*/) const { return false; } void assign(const MatExpr& expr, Mat& m, int type=-1) const; void multiply(const MatExpr& e, double s, MatExpr& res) const; static void makeExpr(MatExpr& res, int method, Size sz, int type, double alpha=1); static void makeExpr(MatExpr& res, int method, int ndims, const int* sizes, int type, double alpha=1); }; static MatOp_Initializer* getGlobalMatOpInitializer() { static MatOp_Initializer initializer; return &initializer; } static inline bool isIdentity(const MatExpr& e) { return e.op == &g_MatOp_Identity; } static inline bool isAddEx(const MatExpr& e) { return e.op == &g_MatOp_AddEx; } static inline bool isScaled(const MatExpr& e) { return isAddEx(e) && (!e.b.data || e.beta == 0) && e.s == Scalar(); } static inline bool isBin(const MatExpr& e, char c) { return e.op == &g_MatOp_Bin && e.flags == c; } static inline bool isCmp(const MatExpr& e) { return e.op == &g_MatOp_Cmp; } static inline bool isReciprocal(const MatExpr& e) { return isBin(e,'/') && (!e.b.data || e.beta == 0); } static inline bool isT(const MatExpr& e) { return e.op == &g_MatOp_T; } static inline bool isInv(const MatExpr& e) { return e.op == &g_MatOp_Invert; } static inline bool isSolve(const MatExpr& e) { return e.op == &g_MatOp_Solve; } static inline bool isGEMM(const MatExpr& e) { return e.op == &g_MatOp_GEMM; } static inline bool isMatProd(const MatExpr& e) { return e.op == &g_MatOp_GEMM && (!e.c.data || e.beta == 0); } static inline bool isInitializer(const MatExpr& e) { return e.op == getGlobalMatOpInitializer(); } ///////////////////////////////////////////////////////////////////////////////////////////////////// MatOp::MatOp() {} MatOp::~MatOp() {} bool MatOp::elementWise(const MatExpr& /*expr*/) const { return false; } void MatOp::roi(const MatExpr& expr, const Range& rowRange, const Range& colRange, MatExpr& e) const { if( elementWise(expr) ) { e = MatExpr(expr.op, expr.flags, Mat(), Mat(), Mat(), expr.alpha, expr.beta, expr.s); if(expr.a.data) e.a = expr.a(rowRange, colRange); if(expr.b.data) e.b = expr.b(rowRange, colRange); if(expr.c.data) e.c = expr.c(rowRange, colRange); } else { Mat m; expr.op->assign(expr, m); e = MatExpr(&g_MatOp_Identity, 0, m(rowRange, colRange), Mat(), Mat()); } } void MatOp::diag(const MatExpr& expr, int d, MatExpr& e) const { if( elementWise(expr) ) { e = MatExpr(expr.op, expr.flags, Mat(), Mat(), Mat(), expr.alpha, expr.beta, expr.s); if(expr.a.data) e.a = expr.a.diag(d); if(expr.b.data) e.b = expr.b.diag(d); if(expr.c.data) e.c = expr.c.diag(d); } else { Mat m; expr.op->assign(expr, m); e = MatExpr(&g_MatOp_Identity, 0, m.diag(d), Mat(), Mat()); } } void MatOp::augAssignAdd(const MatExpr& expr, Mat& m) const { Mat temp; expr.op->assign(expr, temp); m += temp; } void MatOp::augAssignSubtract(const MatExpr& expr, Mat& m) const { Mat temp; expr.op->assign(expr, temp); m -= temp; } void MatOp::augAssignMultiply(const MatExpr& expr, Mat& m) const { Mat temp; expr.op->assign(expr, temp); m *= temp; } void MatOp::augAssignDivide(const MatExpr& expr, Mat& m) const { Mat temp; expr.op->assign(expr, temp); m /= temp; } void MatOp::augAssignAnd(const MatExpr& expr, Mat& m) const { Mat temp; expr.op->assign(expr, temp); m &= temp; } void MatOp::augAssignOr(const MatExpr& expr, Mat& m) const { Mat temp; expr.op->assign(expr, temp); m |= temp; } void MatOp::augAssignXor(const MatExpr& expr, Mat& m) const { Mat temp; expr.op->assign(expr, temp); m ^= temp; } void MatOp::add(const MatExpr& e1, const MatExpr& e2, MatExpr& res) const { if( this == e2.op ) { double alpha = 1, beta = 1; Scalar s; Mat m1, m2; if( isAddEx(e1) && (!e1.b.data || e1.beta == 0) ) { m1 = e1.a; alpha = e1.alpha; s = e1.s; } else e1.op->assign(e1, m1); if( isAddEx(e2) && (!e2.b.data || e2.beta == 0) ) { m2 = e2.a; beta = e2.alpha; s += e2.s; } else e2.op->assign(e2, m2); MatOp_AddEx::makeExpr(res, m1, m2, alpha, beta, s); } else e2.op->add(e1, e2, res); } void MatOp::add(const MatExpr& expr1, const Scalar& s, MatExpr& res) const { Mat m1; expr1.op->assign(expr1, m1); MatOp_AddEx::makeExpr(res, m1, Mat(), 1, 0, s); } void MatOp::subtract(const MatExpr& e1, const MatExpr& e2, MatExpr& res) const { if( this == e2.op ) { double alpha = 1, beta = -1; Scalar s; Mat m1, m2; if( isAddEx(e1) && (!e1.b.data || e1.beta == 0) ) { m1 = e1.a; alpha = e1.alpha; s = e1.s; } else e1.op->assign(e1, m1); if( isAddEx(e2) && (!e2.b.data || e2.beta == 0) ) { m2 = e2.a; beta = -e2.alpha; s -= e2.s; } else e2.op->assign(e2, m2); MatOp_AddEx::makeExpr(res, m1, m2, alpha, beta, s); } else e2.op->subtract(e1, e2, res); } void MatOp::subtract(const Scalar& s, const MatExpr& expr, MatExpr& res) const { Mat m; expr.op->assign(expr, m); MatOp_AddEx::makeExpr(res, m, Mat(), -1, 0, s); } void MatOp::multiply(const MatExpr& e1, const MatExpr& e2, MatExpr& res, double scale) const { if( this == e2.op ) { Mat m1, m2; if( isReciprocal(e1) ) { if( isScaled(e2) ) { scale *= e2.alpha; m2 = e2.a; } else e2.op->assign(e2, m2); MatOp_Bin::makeExpr(res, '/', m2, e1.a, scale/e1.alpha); } else { char op = '*'; if( isScaled(e1) ) { m1 = e1.a; scale *= e1.alpha; } else e1.op->assign(e1, m1); if( isScaled(e2) ) { m2 = e2.a; scale *= e2.alpha; } else if( isReciprocal(e2) ) { op = '/'; m2 = e2.a; scale /= e2.alpha; } else e2.op->assign(e2, m2); MatOp_Bin::makeExpr(res, op, m1, m2, scale); } } else e2.op->multiply(e1, e2, res, scale); } void MatOp::multiply(const MatExpr& expr, double s, MatExpr& res) const { Mat m; expr.op->assign(expr, m); MatOp_AddEx::makeExpr(res, m, Mat(), s, 0); } void MatOp::divide(const MatExpr& e1, const MatExpr& e2, MatExpr& res, double scale) const { if( this == e2.op ) { if( isReciprocal(e1) && isReciprocal(e2) ) MatOp_Bin::makeExpr(res, '/', e2.a, e1.a, e1.alpha/e2.alpha); else { Mat m1, m2; char op = '/'; if( isScaled(e1) ) { m1 = e1.a; scale *= e1.alpha; } else e1.op->assign(e1, m1); if( isScaled(e2) ) { m2 = e2.a; scale /= e2.alpha; } else if( isReciprocal(e2) ) { m2 = e2.a; scale /= e2.alpha; op = '*'; } else e2.op->assign(e2, m2); MatOp_Bin::makeExpr(res, op, m1, m2, scale); } } else e2.op->divide(e1, e2, res, scale); } void MatOp::divide(double s, const MatExpr& expr, MatExpr& res) const { Mat m; expr.op->assign(expr, m); MatOp_Bin::makeExpr(res, '/', m, Mat(), s); } void MatOp::abs(const MatExpr& expr, MatExpr& res) const { Mat m; expr.op->assign(expr, m); MatOp_Bin::makeExpr(res, 'a', m, Mat()); } void MatOp::transpose(const MatExpr& expr, MatExpr& res) const { Mat m; expr.op->assign(expr, m); MatOp_T::makeExpr(res, m, 1); } void MatOp::matmul(const MatExpr& e1, const MatExpr& e2, MatExpr& res) const { if( this == e2.op ) { double scale = 1; int flags = 0; Mat m1, m2; if( isT(e1) ) { flags = CV_GEMM_A_T; scale = e1.alpha; m1 = e1.a; } else if( isScaled(e1) ) { scale = e1.alpha; m1 = e1.a; } else e1.op->assign(e1, m1); if( isT(e2) ) { flags |= CV_GEMM_B_T; scale *= e2.alpha; m2 = e2.a; } else if( isScaled(e2) ) { scale *= e2.alpha; m2 = e2.a; } else e2.op->assign(e2, m2); MatOp_GEMM::makeExpr(res, flags, m1, m2, scale); } else e2.op->matmul(e1, e2, res); } void MatOp::invert(const MatExpr& expr, int method, MatExpr& res) const { Mat m; expr.op->assign(expr, m); MatOp_Invert::makeExpr(res, method, m); } Size MatOp::size(const MatExpr& expr) const { return !expr.a.empty() ? expr.a.size() : expr.b.empty() ? expr.b.size() : expr.c.size(); } int MatOp::type(const MatExpr& expr) const { return !expr.a.empty() ? expr.a.type() : expr.b.empty() ? expr.b.type() : expr.c.type(); } ////////////////////////////////////////////////////////////////////////////////////////////////// MatExpr::MatExpr(const Mat& m) : op(&g_MatOp_Identity), flags(0), a(m), b(Mat()), c(Mat()), alpha(1), beta(0), s(Scalar()) { } MatExpr MatExpr::row(int y) const { MatExpr e; op->roi(*this, Range(y, y+1), Range::all(), e); return e; } MatExpr MatExpr::col(int x) const { MatExpr e; op->roi(*this, Range::all(), Range(x, x+1), e); return e; } MatExpr MatExpr::diag(int d) const { MatExpr e; op->diag(*this, d, e); return e; } MatExpr MatExpr::operator()( const Range& rowRange, const Range& colRange ) const { MatExpr e; op->roi(*this, rowRange, colRange, e); return e; } MatExpr MatExpr::operator()( const Rect& roi ) const { MatExpr e; op->roi(*this, Range(roi.y, roi.y + roi.height), Range(roi.x, roi.x + roi.width), e); return e; } Mat MatExpr::cross(const Mat& m) const { return ((Mat)*this).cross(m); } double MatExpr::dot(const Mat& m) const { return ((Mat)*this).dot(m); } MatExpr MatExpr::t() const { MatExpr e; op->transpose(*this, e); return e; } MatExpr MatExpr::inv(int method) const { MatExpr e; op->invert(*this, method, e); return e; } MatExpr MatExpr::mul(const MatExpr& e, double scale) const { MatExpr en; op->multiply(*this, e, en, scale); return en; } MatExpr MatExpr::mul(const Mat& m, double scale) const { MatExpr e; op->multiply(*this, MatExpr(m), e, scale); return e; } MatExpr operator + (const Mat& a, const Mat& b) { MatExpr e; MatOp_AddEx::makeExpr(e, a, b, 1, 1); return e; } MatExpr operator + (const Mat& a, const Scalar& s) { MatExpr e; MatOp_AddEx::makeExpr(e, a, Mat(), 1, 0, s); return e; } MatExpr operator + (const Scalar& s, const Mat& a) { MatExpr e; MatOp_AddEx::makeExpr(e, a, Mat(), 1, 0, s); return e; } MatExpr operator + (const MatExpr& e, const Mat& m) { MatExpr en; e.op->add(e, MatExpr(m), en); return en; } MatExpr operator + (const Mat& m, const MatExpr& e) { MatExpr en; e.op->add(e, MatExpr(m), en); return en; } MatExpr operator + (const MatExpr& e, const Scalar& s) { MatExpr en; e.op->add(e, s, en); return en; } MatExpr operator + (const Scalar& s, const MatExpr& e) { MatExpr en; e.op->add(e, s, en); return en; } MatExpr operator + (const MatExpr& e1, const MatExpr& e2) { MatExpr en; e1.op->add(e1, e2, en); return en; } MatExpr operator - (const Mat& a, const Mat& b) { MatExpr e; MatOp_AddEx::makeExpr(e, a, b, 1, -1); return e; } MatExpr operator - (const Mat& a, const Scalar& s) { MatExpr e; MatOp_AddEx::makeExpr(e, a, Mat(), 1, 0, -s); return e; } MatExpr operator - (const Scalar& s, const Mat& a) { MatExpr e; MatOp_AddEx::makeExpr(e, a, Mat(), -1, 0, s); return e; } MatExpr operator - (const MatExpr& e, const Mat& m) { MatExpr en; e.op->subtract(e, MatExpr(m), en); return en; } MatExpr operator - (const Mat& m, const MatExpr& e) { MatExpr en; e.op->subtract(MatExpr(m), e, en); return en; } MatExpr operator - (const MatExpr& e, const Scalar& s) { MatExpr en; e.op->add(e, -s, en); return en; } MatExpr operator - (const Scalar& s, const MatExpr& e) { MatExpr en; e.op->subtract(s, e, en); return en; } MatExpr operator - (const MatExpr& e1, const MatExpr& e2) { MatExpr en; e1.op->subtract(e1, e2, en); return en; } MatExpr operator - (const Mat& m) { MatExpr e; MatOp_AddEx::makeExpr(e, m, Mat(), -1, 0); return e; } MatExpr operator - (const MatExpr& e) { MatExpr en; e.op->subtract(Scalar(0), e, en); return en; } MatExpr operator * (const Mat& a, const Mat& b) { MatExpr e; MatOp_GEMM::makeExpr(e, 0, a, b); return e; } MatExpr operator * (const Mat& a, double s) { MatExpr e; MatOp_AddEx::makeExpr(e, a, Mat(), s, 0); return e; } MatExpr operator * (double s, const Mat& a) { MatExpr e; MatOp_AddEx::makeExpr(e, a, Mat(), s, 0); return e; } MatExpr operator * (const MatExpr& e, const Mat& m) { MatExpr en; e.op->matmul(e, MatExpr(m), en); return en; } MatExpr operator * (const Mat& m, const MatExpr& e) { MatExpr en; e.op->matmul(MatExpr(m), e, en); return en; } MatExpr operator * (const MatExpr& e, double s) { MatExpr en; e.op->multiply(e, s, en); return en; } MatExpr operator * (double s, const MatExpr& e) { MatExpr en; e.op->multiply(e, s, en); return en; } MatExpr operator * (const MatExpr& e1, const MatExpr& e2) { MatExpr en; e1.op->matmul(e1, e2, en); return en; } MatExpr operator / (const Mat& a, const Mat& b) { MatExpr e; MatOp_Bin::makeExpr(e, '/', a, b); return e; } MatExpr operator / (const Mat& a, double s) { MatExpr e; MatOp_AddEx::makeExpr(e, a, Mat(), 1./s, 0); return e; } MatExpr operator / (double s, const Mat& a) { MatExpr e; MatOp_Bin::makeExpr(e, '/', a, Mat(), s); return e; } MatExpr operator / (const MatExpr& e, const Mat& m) { MatExpr en; e.op->divide(e, MatExpr(m), en); return en; } MatExpr operator / (const Mat& m, const MatExpr& e) { MatExpr en; e.op->divide(MatExpr(m), e, en); return en; } MatExpr operator / (const MatExpr& e, double s) { MatExpr en; e.op->multiply(e, 1./s, en); return en; } MatExpr operator / (double s, const MatExpr& e) { MatExpr en; e.op->divide(s, e, en); return en; } MatExpr operator / (const MatExpr& e1, const MatExpr& e2) { MatExpr en; e1.op->divide(e1, e2, en); return en; } MatExpr operator < (const Mat& a, const Mat& b) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_LT, a, b); return e; } MatExpr operator < (const Mat& a, double s) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_LT, a, s); return e; } MatExpr operator < (double s, const Mat& a) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_GT, a, s); return e; } MatExpr operator <= (const Mat& a, const Mat& b) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_LE, a, b); return e; } MatExpr operator <= (const Mat& a, double s) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_LE, a, s); return e; } MatExpr operator <= (double s, const Mat& a) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_GE, a, s); return e; } MatExpr operator == (const Mat& a, const Mat& b) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_EQ, a, b); return e; } MatExpr operator == (const Mat& a, double s) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_EQ, a, s); return e; } MatExpr operator == (double s, const Mat& a) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_EQ, a, s); return e; } MatExpr operator != (const Mat& a, const Mat& b) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_NE, a, b); return e; } MatExpr operator != (const Mat& a, double s) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_NE, a, s); return e; } MatExpr operator != (double s, const Mat& a) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_NE, a, s); return e; } MatExpr operator >= (const Mat& a, const Mat& b) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_GE, a, b); return e; } MatExpr operator >= (const Mat& a, double s) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_GE, a, s); return e; } MatExpr operator >= (double s, const Mat& a) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_LE, a, s); return e; } MatExpr operator > (const Mat& a, const Mat& b) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_GT, a, b); return e; } MatExpr operator > (const Mat& a, double s) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_GT, a, s); return e; } MatExpr operator > (double s, const Mat& a) { MatExpr e; MatOp_Cmp::makeExpr(e, CV_CMP_LT, a, s); return e; } MatExpr min(const Mat& a, const Mat& b) { MatExpr e; MatOp_Bin::makeExpr(e, 'm', a, b); return e; } MatExpr min(const Mat& a, double s) { MatExpr e; MatOp_Bin::makeExpr(e, 'n', a, s); return e; } MatExpr min(double s, const Mat& a) { MatExpr e; MatOp_Bin::makeExpr(e, 'n', a, s); return e; } MatExpr max(const Mat& a, const Mat& b) { MatExpr e; MatOp_Bin::makeExpr(e, 'M', a, b); return e; } MatExpr max(const Mat& a, double s) { MatExpr e; MatOp_Bin::makeExpr(e, 'N', a, s); return e; } MatExpr max(double s, const Mat& a) { MatExpr e; MatOp_Bin::makeExpr(e, 'N', a, s); return e; } MatExpr operator & (const Mat& a, const Mat& b) { MatExpr e; MatOp_Bin::makeExpr(e, '&', a, b); return e; } MatExpr operator & (const Mat& a, const Scalar& s) { MatExpr e; MatOp_Bin::makeExpr(e, '&', a, s); return e; } MatExpr operator & (const Scalar& s, const Mat& a) { MatExpr e; MatOp_Bin::makeExpr(e, '&', a, s); return e; } MatExpr operator | (const Mat& a, const Mat& b) { MatExpr e; MatOp_Bin::makeExpr(e, '|', a, b); return e; } MatExpr operator | (const Mat& a, const Scalar& s) { MatExpr e; MatOp_Bin::makeExpr(e, '|', a, s); return e; } MatExpr operator | (const Scalar& s, const Mat& a) { MatExpr e; MatOp_Bin::makeExpr(e, '|', a, s); return e; } MatExpr operator ^ (const Mat& a, const Mat& b) { MatExpr e; MatOp_Bin::makeExpr(e, '^', a, b); return e; } MatExpr operator ^ (const Mat& a, const Scalar& s) { MatExpr e; MatOp_Bin::makeExpr(e, '^', a, s); return e; } MatExpr operator ^ (const Scalar& s, const Mat& a) { MatExpr e; MatOp_Bin::makeExpr(e, '^', a, s); return e; } MatExpr operator ~(const Mat& a) { MatExpr e; MatOp_Bin::makeExpr(e, '~', a, Scalar()); return e; } MatExpr abs(const Mat& a) { MatExpr e; MatOp_Bin::makeExpr(e, 'a', a, Scalar()); return e; } MatExpr abs(const MatExpr& e) { MatExpr en; e.op->abs(e, en); return en; } Size MatExpr::size() const { if( isT(*this) || isInv(*this) ) return Size(a.rows, a.cols); if( isGEMM(*this) ) return Size(b.cols, a.rows); if( isSolve(*this) ) return Size(b.cols, a.cols); if( isInitializer(*this) ) return a.size(); return op ? op->size(*this) : Size(); } int MatExpr::type() const { if( isInitializer(*this) ) return a.type(); if( isCmp(*this) ) return CV_8U; return op ? op->type(*this) : -1; } ///////////////////////////////////////////////////////////////////////////////////////////////////// void MatOp_Identity::assign(const MatExpr& e, Mat& m, int _type) const { if( _type == -1 || _type == e.a.type() ) m = e.a; else { CV_Assert( CV_MAT_CN(_type) == e.a.channels() ); e.a.convertTo(m, _type); } } inline void MatOp_Identity::makeExpr(MatExpr& res, const Mat& m) { res = MatExpr(&g_MatOp_Identity, 0, m, Mat(), Mat(), 1, 0); } ///////////////////////////////////////////////////////////////////////////////////////////////////// void MatOp_AddEx::assign(const MatExpr& e, Mat& m, int _type) const { Mat temp, &dst = _type == -1 || e.a.type() == _type ? m : temp; if( e.b.data ) { if( e.s == Scalar() || !e.s.isReal() ) { if( e.alpha == 1 ) { if( e.beta == 1 ) cv::add(e.a, e.b, dst); else if( e.beta == -1 ) cv::subtract(e.a, e.b, dst); else cv::scaleAdd(e.b, e.beta, e.a, dst); } else if( e.beta == 1 ) { if( e.alpha == -1 ) cv::subtract(e.b, e.a, dst); else cv::scaleAdd(e.a, e.alpha, e.b, dst); } else cv::addWeighted(e.a, e.alpha, e.b, e.beta, 0, dst); if( !e.s.isReal() ) cv::add(dst, e.s, dst); } else cv::addWeighted(e.a, e.alpha, e.b, e.beta, e.s[0], dst); } else if( e.s.isReal() && (dst.data != m.data || fabs(e.alpha) != 1)) { e.a.convertTo(m, _type, e.alpha, e.s[0]); return; } else if( e.alpha == 1 ) cv::add(e.a, e.s, dst); else if( e.alpha == -1 ) cv::subtract(e.s, e.a, dst); else { e.a.convertTo(dst, e.a.type(), e.alpha); cv::add(dst, e.s, dst); } if( dst.data != m.data ) dst.convertTo(m, m.type()); } void MatOp_AddEx::add(const MatExpr& e, const Scalar& s, MatExpr& res) const { res = e; res.s += s; } void MatOp_AddEx::subtract(const Scalar& s, const MatExpr& e, MatExpr& res) const { res = e; res.alpha = -res.alpha; res.beta = -res.beta; res.s = s - res.s; } void MatOp_AddEx::multiply(const MatExpr& e, double s, MatExpr& res) const { res = e; res.alpha *= s; res.beta *= s; res.s *= s; } void MatOp_AddEx::divide(double s, const MatExpr& e, MatExpr& res) const { if( isScaled(e) ) MatOp_Bin::makeExpr(res, '/', e.a, Mat(), s/e.alpha); else MatOp::divide(s, e, res); } void MatOp_AddEx::transpose(const MatExpr& e, MatExpr& res) const { if( isScaled(e) ) MatOp_T::makeExpr(res, e.a, e.alpha); else MatOp::transpose(e, res); } void MatOp_AddEx::abs(const MatExpr& e, MatExpr& res) const { if( (!e.b.data || e.beta == 0) && fabs(e.alpha) == 1 ) MatOp_Bin::makeExpr(res, 'a', e.a, -e.s*e.alpha); else if( e.b.data && e.alpha + e.beta == 0 && e.alpha*e.beta == -1 ) MatOp_Bin::makeExpr(res, 'a', e.a, e.b); else MatOp::abs(e, res); } inline void MatOp_AddEx::makeExpr(MatExpr& res, const Mat& a, const Mat& b, double alpha, double beta, const Scalar& s) { res = MatExpr(&g_MatOp_AddEx, 0, a, b, Mat(), alpha, beta, s); } ////////////////////////////////////////////////////////////////////////////////////////////////////////////////// void MatOp_Bin::assign(const MatExpr& e, Mat& m, int _type) const { Mat temp, &dst = _type == -1 || e.a.type() == _type ? m : temp; if( e.flags == '*' ) cv::multiply(e.a, e.b, dst, e.alpha); else if( e.flags == '/' && e.b.data ) cv::divide(e.a, e.b, dst, e.alpha); else if( e.flags == '/' && !e.b.data ) cv::divide(e.alpha, e.a, dst ); else if( e.flags == '&' && e.b.data ) bitwise_and(e.a, e.b, dst); else if( e.flags == '&' && !e.b.data ) bitwise_and(e.a, e.s, dst); else if( e.flags == '|' && e.b.data ) bitwise_or(e.a, e.b, dst); else if( e.flags == '|' && !e.b.data ) bitwise_or(e.a, e.s, dst); else if( e.flags == '^' && e.b.data ) bitwise_xor(e.a, e.b, dst); else if( e.flags == '^' && !e.b.data ) bitwise_xor(e.a, e.s, dst); else if( e.flags == '~' && !e.b.data ) bitwise_not(e.a, dst); else if( e.flags == 'm' ) cv::min(e.a, e.b, dst); else if( e.flags == 'n' ) cv::min(e.a, e.s[0], dst); else if( e.flags == 'M' ) cv::max(e.a, e.b, dst); else if( e.flags == 'N' ) cv::max(e.a, e.s[0], dst); else if( e.flags == 'a' && e.b.data ) cv::absdiff(e.a, e.b, dst); else if( e.flags == 'a' && !e.b.data ) cv::absdiff(e.a, e.s, dst); else CV_Error(CV_StsError, "Unknown operation"); if( dst.data != m.data ) dst.convertTo(m, _type); } void MatOp_Bin::multiply(const MatExpr& e, double s, MatExpr& res) const { if( e.flags == '*' || e.flags == '/' ) { res = e; res.alpha *= s; } else MatOp::multiply(e, s, res); } void MatOp_Bin::divide(double s, const MatExpr& e, MatExpr& res) const { if( e.flags == '/' && (!e.b.data || e.beta == 0) ) MatOp_AddEx::makeExpr(res, e.a, Mat(), s/e.alpha, 0); else MatOp::divide(s, e, res); } inline void MatOp_Bin::makeExpr(MatExpr& res, char op, const Mat& a, const Mat& b, double scale) { res = MatExpr(&g_MatOp_Bin, op, a, b, Mat(), scale, b.data ? 1 : 0); } inline void MatOp_Bin::makeExpr(MatExpr& res, char op, const Mat& a, const Scalar& s) { res = MatExpr(&g_MatOp_Bin, op, a, Mat(), Mat(), 1, 0, s); } /////////////////////////////////////////////////////////////////////////////////////////////////////// void MatOp_Cmp::assign(const MatExpr& e, Mat& m, int _type) const { Mat temp, &dst = _type == -1 || _type == CV_8U ? m : temp; if( e.b.data ) cv::compare(e.a, e.b, dst, e.flags); else cv::compare(e.a, e.alpha, dst, e.flags); if( dst.data != m.data ) dst.convertTo(m, _type); } inline void MatOp_Cmp::makeExpr(MatExpr& res, int cmpop, const Mat& a, const Mat& b) { res = MatExpr(&g_MatOp_Cmp, cmpop, a, b, Mat(), 1, 1); } inline void MatOp_Cmp::makeExpr(MatExpr& res, int cmpop, const Mat& a, double alpha) { res = MatExpr(&g_MatOp_Cmp, cmpop, a, Mat(), Mat(), alpha, 1); } ///////////////////////////////////////////////////////////////////////////////////////////////////////// void MatOp_T::assign(const MatExpr& e, Mat& m, int _type) const { Mat temp, &dst = _type == -1 || _type == e.a.type() ? m : temp; cv::transpose(e.a, dst); if( dst.data != m.data || e.alpha != 1 ) dst.convertTo(m, _type, e.alpha); } void MatOp_T::multiply(const MatExpr& e, double s, MatExpr& res) const { res = e; res.alpha *= s; } void MatOp_T::transpose(const MatExpr& e, MatExpr& res) const { if( e.alpha == 1 ) MatOp_Identity::makeExpr(res, e.a); else MatOp_AddEx::makeExpr(res, e.a, Mat(), e.alpha, 0); } inline void MatOp_T::makeExpr(MatExpr& res, const Mat& a, double alpha) { res = MatExpr(&g_MatOp_T, 0, a, Mat(), Mat(), alpha, 0); } ///////////////////////////////////////////////////////////////////////////////////////////////////////// void MatOp_GEMM::assign(const MatExpr& e, Mat& m, int _type) const { Mat temp, &dst = _type == -1 || _type == e.a.type() ? m : temp; cv::gemm(e.a, e.b, e.alpha, e.c, e.beta, dst, e.flags); if( dst.data != m.data ) dst.convertTo(m, _type); } void MatOp_GEMM::add(const MatExpr& e1, const MatExpr& e2, MatExpr& res) const { bool i1 = isIdentity(e1), i2 = isIdentity(e2); double alpha1 = i1 ? 1 : e1.alpha, alpha2 = i2 ? 1 : e2.alpha; if( isMatProd(e1) && (i2 || isScaled(e2) || isT(e2)) ) MatOp_GEMM::makeExpr(res, (e1.flags & ~CV_GEMM_C_T)|(isT(e2) ? CV_GEMM_C_T : 0), e1.a, e1.b, alpha1, e2.a, alpha2); else if( isMatProd(e2) && (i1 || isScaled(e1) || isT(e1)) ) MatOp_GEMM::makeExpr(res, (e2.flags & ~CV_GEMM_C_T)|(isT(e1) ? CV_GEMM_C_T : 0), e2.a, e2.b, alpha2, e1.a, alpha1); else if( this == e2.op ) MatOp::add(e1, e2, res); else e2.op->add(e1, e2, res); } void MatOp_GEMM::subtract(const MatExpr& e1, const MatExpr& e2, MatExpr& res) const { bool i1 = isIdentity(e1), i2 = isIdentity(e2); double alpha1 = i1 ? 1 : e1.alpha, alpha2 = i2 ? 1 : e2.alpha; if( isMatProd(e1) && (i2 || isScaled(e2) || isT(e2)) ) MatOp_GEMM::makeExpr(res, (e1.flags & ~CV_GEMM_C_T)|(isT(e2) ? CV_GEMM_C_T : 0), e1.a, e1.b, alpha1, e2.a, -alpha2); else if( isMatProd(e2) && (i1 || isScaled(e1) || isT(e1)) ) MatOp_GEMM::makeExpr(res, (e2.flags & ~CV_GEMM_C_T)|(isT(e1) ? CV_GEMM_C_T : 0), e2.a, e2.b, -alpha2, e1.a, alpha1); else if( this == e2.op ) MatOp::subtract(e1, e2, res); else e2.op->subtract(e1, e2, res); } void MatOp_GEMM::multiply(const MatExpr& e, double s, MatExpr& res) const { res = e; res.alpha *= s; res.beta *= s; } void MatOp_GEMM::transpose(const MatExpr& e, MatExpr& res) const { res = e; res.flags = (!(e.flags & CV_GEMM_A_T) ? CV_GEMM_B_T : 0) | (!(e.flags & CV_GEMM_B_T) ? CV_GEMM_A_T : 0) | (!(e.flags & CV_GEMM_C_T) ? CV_GEMM_C_T : 0); swap(res.a, res.b); } inline void MatOp_GEMM::makeExpr(MatExpr& res, int flags, const Mat& a, const Mat& b, double alpha, const Mat& c, double beta) { res = MatExpr(&g_MatOp_GEMM, flags, a, b, c, alpha, beta); } /////////////////////////////////////////////////////////////////////////////////////////////////////// void MatOp_Invert::assign(const MatExpr& e, Mat& m, int _type) const { Mat temp, &dst = _type == -1 || _type == e.a.type() ? m : temp; cv::invert(e.a, dst, e.flags); if( dst.data != m.data ) dst.convertTo(m, _type); } void MatOp_Invert::matmul(const MatExpr& e1, const MatExpr& e2, MatExpr& res) const { if( isInv(e1) && isIdentity(e2) ) MatOp_Solve::makeExpr(res, e1.flags, e1.a, e2.a); else if( this == e2.op ) MatOp::matmul(e1, e2, res); else e2.op->matmul(e1, e2, res); } inline void MatOp_Invert::makeExpr(MatExpr& res, int method, const Mat& m) { res = MatExpr(&g_MatOp_Invert, method, m, Mat(), Mat(), 1, 0); } ///////////////////////////////////////////////////////////////////////////////////////////////////////// void MatOp_Solve::assign(const MatExpr& e, Mat& m, int _type) const { Mat temp, &dst = _type == -1 || _type == e.a.type() ? m : temp; cv::solve(e.a, e.b, dst, e.flags); if( dst.data != m.data ) dst.convertTo(m, _type); } inline void MatOp_Solve::makeExpr(MatExpr& res, int method, const Mat& a, const Mat& b) { res = MatExpr(&g_MatOp_Solve, method, a, b, Mat(), 1, 1); } ////////////////////////////////////////////////////////////////////////////////////////////////////////// void MatOp_Initializer::assign(const MatExpr& e, Mat& m, int _type) const { if( _type == -1 ) _type = e.a.type(); if( e.a.dims <= 2 ) m.create(e.a.size(), _type); else m.create(e.a.dims, e.a.size, _type); if( e.flags == 'I' && e.a.dims <= 2 ) setIdentity(m, Scalar(e.alpha)); else if( e.flags == '0' ) m = Scalar(); else if( e.flags == '1' ) m = Scalar(e.alpha); else CV_Error(CV_StsError, "Invalid matrix initializer type"); } void MatOp_Initializer::multiply(const MatExpr& e, double s, MatExpr& res) const { res = e; res.alpha *= s; } inline void MatOp_Initializer::makeExpr(MatExpr& res, int method, Size sz, int type, double alpha) { res = MatExpr(getGlobalMatOpInitializer(), method, Mat(sz, type, (void*)0), Mat(), Mat(), alpha, 0); } inline void MatOp_Initializer::makeExpr(MatExpr& res, int method, int ndims, const int* sizes, int type, double alpha) { res = MatExpr(getGlobalMatOpInitializer(), method, Mat(ndims, sizes, type, (void*)0), Mat(), Mat(), alpha, 0); } /////////////////////////////////////////////////////////////////////////////////////////////////////////// MatExpr Mat::t() const { MatExpr e; MatOp_T::makeExpr(e, *this); return e; } MatExpr Mat::inv(int method) const { MatExpr e; MatOp_Invert::makeExpr(e, method, *this); return e; } MatExpr Mat::mul(InputArray m, double scale) const { MatExpr e; if(m.kind() == _InputArray::EXPR) { const MatExpr& me = *(const MatExpr*)m.getObj(); me.op->multiply(MatExpr(*this), me, e, scale); } else MatOp_Bin::makeExpr(e, '*', *this, m.getMat(), scale); return e; } MatExpr Mat::zeros(int rows, int cols, int type) { MatExpr e; MatOp_Initializer::makeExpr(e, '0', Size(cols, rows), type); return e; } MatExpr Mat::zeros(Size size, int type) { MatExpr e; MatOp_Initializer::makeExpr(e, '0', size, type); return e; } MatExpr Mat::zeros(int ndims, const int* sizes, int type) { MatExpr e; MatOp_Initializer::makeExpr(e, '0', ndims, sizes, type); return e; } MatExpr Mat::ones(int rows, int cols, int type) { MatExpr e; MatOp_Initializer::makeExpr(e, '1', Size(cols, rows), type); return e; } MatExpr Mat::ones(Size size, int type) { MatExpr e; MatOp_Initializer::makeExpr(e, '1', size, type); return e; } MatExpr Mat::ones(int ndims, const int* sizes, int type) { MatExpr e; MatOp_Initializer::makeExpr(e, '1', ndims, sizes, type); return e; } MatExpr Mat::eye(int rows, int cols, int type) { MatExpr e; MatOp_Initializer::makeExpr(e, 'I', Size(cols, rows), type); return e; } MatExpr Mat::eye(Size size, int type) { MatExpr e; MatOp_Initializer::makeExpr(e, 'I', size, type); return e; } } /* End of file. */