// Copyright (C) 2006 Davis E. King (davis@dlib.net) // License: Boost Software License See LICENSE.txt for the full license. #undef DLIB_MATRIx_SUBEXP_ABSTRACT_ #ifdef DLIB_MATRIx_SUBEXP_ABSTRACT_ #include "matrix_abstract.h" #include "../geometry/rectangle.h" namespace dlib { // ---------------------------------------------------------------------------------------- template const matrix_exp range ( ); /*! requires - inc > 0 ensures - returns a matrix R such that: - R::type == long - R.nr() == 1 - R.nc() == abs(end - start)/inc + 1 - if (start <= end) then - R(i) == start + i*inc - else - R(i) == start - i*inc !*/ template const matrix_exp range ( ) { return range(); } const matrix_exp range ( long start, long inc, long end ); /*! requires - inc > 0 ensures - returns a matrix R such that: - R::type == long - R.nr() == 1 - R.nc() == abs(end - start)/inc + 1 - if (start <= end) then - R(i) == start + i*inc - else - R(i) == start - i*inc !*/ const matrix_exp range ( long start, long end ) { return range(start,1,end); } // ---------------------------------------------------------------------------------------- const matrix_exp subm ( const matrix_exp& m, const matrix_exp& rows, const matrix_exp& cols, ); /*! requires - rows and cols contain integral elements (e.g. int, long) - 0 <= min(rows) && max(rows) < m.nr() - 0 <= min(cols) && max(cols) < m.nc() - rows.nr() == 1 || rows.nc() == 1 - cols.nr() == 1 || cols.nc() == 1 (i.e. rows and cols must be vectors) ensures - returns a matrix R such that: - R::type == the same type that was in m - R.nr() == rows.size() - R.nc() == cols.size() - for all valid r and c: R(r,c) == m(rows(r),cols(c)) !*/ // ---------------------------------------------------------------------------------------- const matrix_exp subm ( const matrix_exp& m, long row, long col, long nr, long nc ); /*! requires - row >= 0 - col >= 0 - nr >= 0 - nc >= 0 - row + nr <= m.nr() - col + nc <= m.nc() ensures - returns a matrix R such that: - R.nr() == nr - R.nc() == nc - for all valid r and c: R(r, c) == m(r+row,c+col) !*/ // ---------------------------------------------------------------------------------------- const matrix_exp subm ( const matrix_exp& m, const rectangle& rect ); /*! requires - get_rect(m).contains(rect) == true (i.e. rect is a region inside the matrix m) ensures - returns a matrix R such that: - R.nr() == rect.height() - R.nc() == rect.width() - for all valid r and c: R(r, c) == m(r+rect.top(), c+rect.left()) !*/ // ---------------------------------------------------------------------------------------- const matrix_exp subm_clipped ( const matrix_exp& m, long row, long col, long nr, long nc ); /*! ensures - This function is just like subm() except that it will automatically clip the indicated sub matrix window so that it does not extend outside m. In particular: - Let box = rectangle(col,row,col+nc-1,row+nr-1) (i.e. the box that contains the indicated sub matrix) - Let box_clipped = box.intersect(get_rect(m)) - Then this function returns a matrix R such that: - R.nr() == box_clipped.height() - R.nc() == box_clipped.width() - for all valid r and c: R(r, c) == m(r+box_clipped.top(),c+box_clipped.left()) !*/ // ---------------------------------------------------------------------------------------- const matrix_exp subm_clipped ( const matrix_exp& m, const rectangle& rect ); /*! ensures - Let box_clipped == rect.intersect(get_rect(m)) - returns a matrix R such that: - R.nr() == box_clipped.height() - R.nc() == box_clipped.width() - for all valid r and c: R(r, c) == m(r+box_clipped.top(), c+box_clipped.left()) !*/ // ---------------------------------------------------------------------------------------- const matrix_exp rowm ( const matrix_exp& m, long row ); /*! requires - 0 <= row < m.nr() ensures - returns a matrix R such that: - R.nr() == 1 - R.nc() == m.nc() - for all valid i: R(i) == m(row,i) !*/ template struct rowm_exp { /*! WHAT THIS OBJECT REPRESENTS This struct allows you to determine the type of matrix expression object returned from the rowm(m,row) function. An example makes its use clear: template void do_something( const matrix_exp& mat) { // r is a matrix expression that aliases mat. typename rowm_exp::type r = rowm(mat,0); // Print the first row of mat. So we see that by using // rowm_exp we can save the object returned by rowm() in // a local variable. cout << r << endl; // Note that you can only save the return value of rowm() to // a local variable if the argument to rowm() has a lifetime // beyond the rowm() expression. The example shown above is // OK but the following would result in undefined behavior: typename rowm_exp::type bad = rowm(mat + mat,0); } !*/ typedef type_of_expression_returned_by_rowm type; }; // ---------------------------------------------------------------------------------------- const matrix_exp rowm ( const matrix_exp& m, long row, long length ); /*! requires - 0 <= row < m.nr() - 0 <= length <= m.nc() ensures - returns a matrix R such that: - R.nr() == 1 - R.nc() == length - for all valid i: R(i) == m(row,i) !*/ // ---------------------------------------------------------------------------------------- const matrix_exp rowm ( const matrix_exp& m, const matrix_exp& rows ); /*! requires - rows contains integral elements (e.g. int, long) - 0 <= min(rows) && max(rows) < m.nr() - rows.nr() == 1 || rows.nc() == 1 (i.e. rows must be a vector) ensures - returns a matrix R such that: - R::type == the same type that was in m - R.nr() == rows.size() - R.nc() == m.nc() - for all valid r and c: R(r,c) == m(rows(r),c) !*/ // ---------------------------------------------------------------------------------------- const matrix_exp colm ( const matrix_exp& m, long col ); /*! requires - 0 <= col < m.nc() ensures - returns a matrix R such that: - R.nr() == m.nr() - R.nc() == 1 - for all valid i: R(i) == m(i,col) !*/ template struct colm_exp { /*! WHAT THIS OBJECT REPRESENTS This struct allows you to determine the type of matrix expression object returned from the colm(m,col) function. An example makes its use clear: template void do_something( const matrix_exp& mat) { // c is a matrix expression that aliases mat. typename colm_exp::type c = colm(mat,0); // Print the first column of mat. So we see that by using // colm_exp we can save the object returned by colm() in // a local variable. cout << c << endl; // Note that you can only save the return value of colm() to // a local variable if the argument to colm() has a lifetime // beyond the colm() expression. The example shown above is // OK but the following would result in undefined behavior: typename colm_exp::type bad = colm(mat + mat,0); } !*/ typedef type_of_expression_returned_by_colm type; }; // ---------------------------------------------------------------------------------------- const matrix_exp colm ( const matrix_exp& m, long col, long length ); /*! requires - 0 <= col < m.nc() - 0 <= length <= m.nr() ensures - returns a matrix R such that: - R.nr() == length - R.nc() == 1 - for all valid i: R(i) == m(i,col) !*/ // ---------------------------------------------------------------------------------------- const matrix_exp colm ( const matrix_exp& m, const matrix_exp& cols ); /*! requires - cols contains integral elements (e.g. int, long) - 0 <= min(cols) && max(cols) < m.nc() - cols.nr() == 1 || cols.nc() == 1 (i.e. cols must be a vector) ensures - returns a matrix R such that: - R::type == the same type that was in m - R.nr() == m.nr() - R.nc() == cols.size() - for all valid r and c: R(r,c) == m(r,cols(c)) !*/ // ---------------------------------------------------------------------------------------- template assignable_matrix_expression set_ptrm ( T* ptr, long nr, long nc = 1 ); /*! requires - ptr == a pointer to nr*nc elements of type T - nr >= 0 - nc >= 0 ensures - statements of the following form: - set_ptrm(ptr,nr,nc) = some_matrix; result in it being the case that: - mat(ptr,nr,nc) == some_matrix. - statements of the following form: - set_ptrm(ptr,nr,nc) = scalar_value; result in it being the case that: - mat(ptr,nr,nc) == uniform_matrix(nr,nc,scalar_value). - In addition to the normal assignment statements using the = symbol, you may also use the usual += and -= versions of the assignment operator. In these cases, they have their usual effect. !*/ // ---------------------------------------------------------------------------------------- assignable_matrix_expression set_subm ( matrix& m, long row, long col, long nr, long nc ); /*! requires - row >= 0 - col >= 0 - nr >= 0 - nc >= 0 - row + nr <= m.nr() - col + nc <= m.nc() ensures - statements of the following form: - set_subm(m,row,col,nr,nc) = some_matrix; result in it being the case that: - subm(m,row,col,nr,nc) == some_matrix. - statements of the following form: - set_subm(m,row,col,nr,nc) = scalar_value; result in it being the case that: - subm(m,row,col,nr,nc) == uniform_matrix(nr,nc,scalar_value). - In addition to the normal assignment statements using the = symbol, you may also use the usual += and -= versions of the assignment operator. In these cases, they have their usual effect. !*/ // ---------------------------------------------------------------------------------------- assignable_matrix_expression set_subm ( matrix& m, const rectangle& rect ); /*! requires - get_rect(m).contains(rect) == true (i.e. rect is a region inside the matrix m) ensures - statements of the following form: - set_subm(m,rect) = some_matrix; result in it being the case that: - subm(m,rect) == some_matrix. - statements of the following form: - set_subm(m,rect) = scalar_value; result in it being the case that: - subm(m,rect) == uniform_matrix(nr,nc,scalar_value). - In addition to the normal assignment statements using the = symbol, you may also use the usual += and -= versions of the assignment operator. In these cases, they have their usual effect. !*/ // ---------------------------------------------------------------------------------------- assignable_matrix_expression set_subm ( matrix& m, const matrix_exp& rows, const matrix_exp& cols ); /*! requires - rows and cols contain integral elements (e.g. int, long) - 0 <= min(rows) && max(rows) < m.nr() - 0 <= min(cols) && max(cols) < m.nc() - rows.nr() == 1 || rows.nc() == 1 - cols.nr() == 1 || cols.nc() == 1 (i.e. rows and cols must be vectors) ensures - statements of the following form: - set_subm(m,rows,cols) = some_matrix; result in it being the case that: - subm(m,rows,cols) == some_matrix. - statements of the following form: - set_subm(m,rows,cols) = scalar_value; result in it being the case that: - subm(m,rows,cols) == uniform_matrix(nr,nc,scalar_value). - In addition to the normal assignment statements using the = symbol, you may also use the usual += and -= versions of the assignment operator. In these cases, they have their usual effect. !*/ // ---------------------------------------------------------------------------------------- assignable_matrix_expression set_rowm ( matrix& m, long row ); /*! requires - 0 <= row < m.nr() ensures - statements of the following form: - set_rowm(m,row) = some_matrix; result in it being the case that: - rowm(m,row) == some_matrix. - statements of the following form: - set_rowm(m,row) = scalar_value; result in it being the case that: - rowm(m,row) == uniform_matrix(1,nc,scalar_value). - In addition to the normal assignment statements using the = symbol, you may also use the usual += and -= versions of the assignment operator. In these cases, they have their usual effect. !*/ // ---------------------------------------------------------------------------------------- assignable_matrix_expression set_rowm ( matrix& m, const matrix_exp& rows ); /*! requires - rows contains integral elements (e.g. int, long) - 0 <= min(rows) && max(rows) < m.nr() - rows.nr() == 1 || rows.nc() == 1 (i.e. rows must be a vector) ensures - statements of the following form: - set_rowm(m,rows) = some_matrix; result in it being the case that: - rowm(m,rows) == some_matrix. - statements of the following form: - set_rowm(m,rows) = scalar_value; result in it being the case that: - rowm(m,rows) == uniform_matrix(nr,nc,scalar_value). - In addition to the normal assignment statements using the = symbol, you may also use the usual += and -= versions of the assignment operator. In these cases, they have their usual effect. !*/ // ---------------------------------------------------------------------------------------- assignable_matrix_expression set_colm ( matrix& m, long col ); /*! requires - 0 <= col < m.nr() ensures - statements of the following form: - set_colm(m,col) = some_matrix; result in it being the case that: - colm(m,col) == some_matrix. - statements of the following form: - set_colm(m,col) = scalar_value; result in it being the case that: - colm(m,col) == uniform_matrix(nr,1,scalar_value). - In addition to the normal assignment statements using the = symbol, you may also use the usual += and -= versions of the assignment operator. In these cases, they have their usual effect. !*/ // ---------------------------------------------------------------------------------------- assignable_matrix_expression set_colm ( matrix& m, const matrix_exp& cols ); /*! requires - cols contains integral elements (e.g. int, long) - 0 <= min(cols) && max(cols) < m.nc() - cols.nr() == 1 || cols.nc() == 1 (i.e. cols must be a vector) ensures - statements of the following form: - set_colm(m,cols) = some_matrix; result in it being the case that: - colm(m,cols) == some_matrix. - statements of the following form: - set_colm(m,cols) = scalar_value; result in it being the case that: - colm(m,cols) == uniform_matrix(nr,nc,scalar_value). - In addition to the normal assignment statements using the = symbol, you may also use the usual += and -= versions of the assignment operator. In these cases, they have their usual effect. !*/ // ---------------------------------------------------------------------------------------- } #endif // DLIB_MATRIx_SUBEXP_ABSTRACT_