/usr/include/cairomm-1.0/cairomm/matrix.h is in libcairomm-1.0-dev 1.12.2-3.
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*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Library General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
* 02110-1301, USA.
*/
#ifndef __CAIROMM_MATRIX_H
#define __CAIROMM_MATRIX_H
#include <cairo.h>
namespace Cairo
{
/** @class cairo_matrix_t
* See the <a
* href="http://www.cairographics.org/manual/cairo-matrix.html">cairo_matrix_t
* reference</a> in the cairo manual for more information
*/
/** A Transformation matrix.
*
* Cairo::Matrix is used throughout cairomm to convert between different
* coordinate spaces. A Matrix holds an affine transformation, such as
* a scale, rotation, shear, or a combination of these. The transformation of
* a point (x,y) is given by:
*
* @code
* x_new = xx * x + xy * y + x0;
* y_new = yx * x + yy * y + y0;
* @endcode
*
* The current transformation matrix of a Context, represented as a
* Matrix, defines the transformation from user-space coordinates to
* device-space coordinates.
* @sa Context::get_matrix()
* @sa Context::set_matrix()
*/
class Matrix : public cairo_matrix_t
{
public:
/** Creates an uninitialized matrix. If you want a matrix initialized to a
* certain value, either specify the values explicitly with the other
* constructor or use one of the free functions for initializing matrices with
* specific scales, rotations, etc.
*
* @sa identity_matrix()
* @sa rotation_matrix()
* @sa translation_matrix()
* @sa scaling_matrix()
*/
Matrix();
/** Creates a matrix Sets to be the affine transformation given by xx, yx, xy,
* yy, x0, y0. The transformation is given by:
*
* @code
* x_new = xx * x + xy * y + x0;
* y_new = yx * x + yy * y + y0;
* @endcode
*
* @param xx xx component of the affine transformation
* @param yx yx component of the affine transformation
* @param xy xy component of the affine transformation
* @param yy yy component of the affine transformation
* @param x0 X translation component of the affine transformation
* @param y0 Y translation component of the affine transformation
*/
Matrix(double xx, double yx, double xy, double yy, double x0, double y0);
/** Applies a translation by tx, ty to the transformation in matrix. The
* effect of the new transformation is to first translate the coordinates by
* tx and ty, then apply the original transformation to the coordinates.
*
* @param tx amount to translate in the X direction
* @param ty amount to translate in the Y direction
*/
void translate(double tx, double ty);
/** Applies scaling by sx, sy to the transformation in matrix. The effect of
* the new transformation is to first scale the coordinates by sx and sy, then
* apply the original transformation to the coordinates.
*
* @param sx scale factor in the X direction
* @param sy scale factor in the Y direction
*/
void scale(double sx, double sy);
/** Applies rotation by radians to the transformation in matrix. The effect of
* the new transformation is to first rotate the coordinates by radians, then
* apply the original transformation to the coordinates.
*
* @param radians angle of rotation, in radians. The direction of rotation is
* defined such that positive angles rotate in the direction from the positive
* X axis toward the positive Y axis. With the default axis orientation of
* cairo, positive angles rotate in a clockwise direction.
*/
void rotate(double radians);
/** Changes matrix to be the inverse of it's original value. Not all
* transformation matrices have inverses; if the matrix collapses points
* together (it is degenerate), then it has no inverse and this function will
* throw an exception.
*
* @exception
*/
void invert();
/** Multiplies the affine transformations in a and b together and stores the
* result in this matrix. The effect of the resulting transformation is to first
* apply the transformation in a to the coordinates and then apply the
* transformation in b to the coordinates.
*
* It is allowable for result to be identical to either a or b.
*
* @param a a Matrix
* @param b a Matrix
*
* @sa operator*()
*/
void multiply(Matrix& a, Matrix& b);
/** Transforms the distance vector (dx,dy) by matrix. This is similar to
* transform_point() except that the translation components of the
* transformation are ignored. The calculation of the returned vector is as
* follows:
*
* @code
* dx2 = dx1 * a + dy1 * c;
* dy2 = dx1 * b + dy1 * d;
* @endcode
*
* Affine transformations are position invariant, so the same vector always
* transforms to the same vector. If (x1,y1) transforms to (x2,y2) then
* (x1+dx1,y1+dy1) will transform to (x1+dx2,y1+dy2) for all values of x1 and
* x2.
*
* @param dx X component of a distance vector. An in/out parameter
* @param dy Y component of a distance vector. An in/out parameter
*/
void transform_distance(double& dx, double& dy) const;
/** Transforms the point (x, y) by this matrix.
*
* @param x X position. An in/out parameter
* @param y Y position. An in/out parameter
*/
void transform_point(double& x, double& y) const;
};
/** Returns a Matrix initialized to the identity matrix
*
* @relates Matrix
*/
Matrix identity_matrix();
/** Returns a Matrix initialized to a transformation that translates by tx and
* ty in the X and Y dimensions, respectively.
*
* @param tx amount to translate in the X direction
* @param ty amount to translate in the Y direction
*
* @relates Matrix
*/
Matrix translation_matrix(double tx, double ty);
/** Returns a Matrix initialized to a transformation that scales by sx and sy in
* the X and Y dimensions, respectively.
*
* @param sx scale factor in the X direction
* @param sy scale factor in the Y direction
*
* @relates Matrix
*/
Matrix scaling_matrix(double sx, double sy);
/** Returns a Matrix initialized to a transformation that rotates by radians.
*
* @param radians angle of rotation, in radians. The direction of rotation is
* defined such that positive angles rotate in the direction from the positive X
* axis toward the positive Y axis. With the default axis orientation of cairo,
* positive angles rotate in a clockwise direction.
*
* @relates Matrix
*/
Matrix rotation_matrix(double radians);
/** Multiplies the affine transformations in a and b together and returns the
* result. The effect of the resulting transformation is to first
* apply the transformation in a to the coordinates and then apply the
* transformation in b to the coordinates.
*
* It is allowable for result to be identical to either a or b.
*
* @param a a Matrix
* @param b a Matrix
*
* @relates Matrix
*/
Matrix operator*(const Matrix& a, const Matrix& b);
} // namespace Cairo
#endif // __CAIROMM_MATRIX_H
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