# -*- coding: ISO-8859-1 -*- # # # Copyright (C) 2002-2006 Jörg Lehmann # Copyright (C) 2002-2004 André Wobst # # This file is part of PyX (http://pyx.sourceforge.net/). # # PyX is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation; either version 2 of the License, or # (at your option) any later version. # # PyX 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 General Public License for more details. # # You should have received a copy of the GNU General Public License # along with PyX; if not, write to the Free Software # Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA import math import attr, canvas, deformer, unit import bbox as bboxmodule # global epsilon (used to judge whether a matrix is singular) _epsilon = (1e-5)**2 def set(epsilon=None): global _epsilon if epsilon is not None: _epsilon = epsilon # some helper routines def _rmatrix(angle): phi = math.pi*angle/180.0 return ((math.cos(phi), -math.sin(phi)), (math.sin(phi), math.cos(phi))) def _rvector(angle, x, y): phi = math.pi*angle/180.0 return ((1-math.cos(phi))*x + math.sin(phi) *y, -math.sin(phi) *x + (1-math.cos(phi))*y) def _mmatrix(angle): phi = math.pi*angle/180.0 return ( (math.cos(phi)*math.cos(phi)-math.sin(phi)*math.sin(phi), -2*math.sin(phi)*math.cos(phi) ), (-2*math.sin(phi)*math.cos(phi), math.sin(phi)*math.sin(phi)-math.cos(phi)*math.cos(phi) ) ) class _marker: pass # Exception class TrafoException(Exception): pass # trafo: affine transformations class trafo_pt(canvas.canvasitem, deformer.deformer): """affine transformation (coordinates in constructor in pts) Note that though the coordinates in the constructor are in pts (which is useful for internal purposes), all other methods only accept units in the standard user notation. """ def __init__(self, matrix=((1, 0), (0, 1)), vector=(0, 0), epsilon=_marker): """Return trafo with given transformation matrix and vector. If epsilon is passed it is used instead of the global epsilon defined in the module to check whether the matrix is singular or not. Use epsilon=None to turn of this checking. """ if epsilon is _marker: epsilon = _epsilon self.epsilon = epsilon if epsilon is not None and abs(matrix[0][0]*matrix[1][1] - matrix[0][1]*matrix[1][0]) < epsilon: raise TrafoException("transformation matrix must not be singular") else: self.matrix = matrix self.vector = vector def __mul__(self, other): if isinstance(other, trafo_pt): if self.epsilon is None or other.epsilon is None: epsilon = None elif self.epsilon <= other.epsilon: epsilon = self.epsilon else: epsilon = other.epsilon matrix = ( ( self.matrix[0][0]*other.matrix[0][0] + self.matrix[0][1]*other.matrix[1][0], self.matrix[0][0]*other.matrix[0][1] + self.matrix[0][1]*other.matrix[1][1] ), ( self.matrix[1][0]*other.matrix[0][0] + self.matrix[1][1]*other.matrix[1][0], self.matrix[1][0]*other.matrix[0][1] + self.matrix[1][1]*other.matrix[1][1] ) ) vector = ( self.matrix[0][0]*other.vector[0] + self.matrix[0][1]*other.vector[1] + self.vector[0], self.matrix[1][0]*other.vector[0] + self.matrix[1][1]*other.vector[1] + self.vector[1] ) return trafo_pt(matrix=matrix, vector=vector, epsilon=epsilon) else: raise NotImplementedError("can only multiply two transformations") def __str__(self): return "[%f %f %f %f %f %f]" % \ ( self.matrix[0][0], self.matrix[1][0], self.matrix[0][1], self.matrix[1][1], self.vector[0], self.vector[1] ) def processPS(self, file, writer, context, registry, bbox): file.write("[%f %f %f %f %f %f] concat\n" % \ ( self.matrix[0][0], self.matrix[1][0], self.matrix[0][1], self.matrix[1][1], self.vector[0], self.vector[1] ) ) def processPDF(self, file, writer, context, registry, bbox): file.write("%f %f %f %f %f %f cm\n" % \ ( self.matrix[0][0], self.matrix[1][0], self.matrix[0][1], self.matrix[1][1], self.vector[0], self.vector[1] ) ) def bbox(self): return bboxmodule.empty() def apply_pt(self, x_pt, y_pt): """apply transformation to point (x_pt, y_pt) in pts""" return ( self.matrix[0][0]*x_pt + self.matrix[0][1]*y_pt + self.vector[0], self.matrix[1][0]*x_pt + self.matrix[1][1]*y_pt + self.vector[1] ) def apply(self, x, y): # for the transformation we have to convert to points tx, ty = self.apply_pt(unit.topt(x), unit.topt(y)) return tx * unit.t_pt, ty * unit.t_pt def deform(self, path): return path.transformed(self) def inverse(self): det = 1.0*(self.matrix[0][0]*self.matrix[1][1] - self.matrix[0][1]*self.matrix[1][0]) matrix = ( ( self.matrix[1][1]/det, -self.matrix[0][1]/det), (-self.matrix[1][0]/det, self.matrix[0][0]/det) ) return ( trafo_pt(matrix=matrix, epsilon=self.epsilon) * trafo_pt(vector=(-self.vector[0], -self.vector[1]), epsilon=self.epsilon) ) def mirrored(self, angle): return mirror(angle, epsilon=self.epsilon) * self def rotated_pt(self, angle, x=None, y=None): return rotate_pt(angle, x, y, epsilon=self.epsilon) * self def rotated(self, angle, x=None, y=None): return rotate(angle, x, y, epsilon=self.epsilon) * self def scaled_pt(self, sx, sy=None, x=None, y=None): return scale_pt(sx, sy, x, y, epsilon=self.epsilon) * self def scaled(self, sx, sy=None, x=None, y=None): return scale(sx, sy, x, y, epsilon=self.epsilon) * self def slanted_pt(self, a, angle=0, x=None, y=None): return slant_pt(a, angle, x, y, epsilon=self.epsilon) * self def slanted(self, a, angle=0, x=None, y=None): return slant(a, angle, x, y, epsilon=self.epsilon) * self def translated_pt(self, x, y): return translate_pt(x, y, epsilon=self.epsilon) * self def translated(self, x, y): return translate(x, y, epsilon=self.epsilon) * self class trafo(trafo_pt): """affine transformation""" def __init__(self, matrix=((1,0), (0,1)), vector=(0, 0), epsilon=_marker): trafo_pt.__init__(self, matrix, (unit.topt(vector[0]), unit.topt(vector[1])), epsilon=epsilon) # # some standard transformations # class mirror(trafo): def __init__(self, angle=0, epsilon=_marker): trafo.__init__(self, matrix=_mmatrix(angle), epsilon=epsilon) class rotate_pt(trafo_pt): def __init__(self, angle, x=None, y=None, epsilon=_marker): vector = 0, 0 if x is not None or y is not None: if x is None or y is None: raise TrafoException("either specify both x and y or none of them") vector=_rvector(angle, x, y) trafo_pt.__init__(self, matrix=_rmatrix(angle), vector=vector, epsilon=epsilon) class rotate(trafo_pt): def __init__(self, angle, x=None, y=None, epsilon=_marker): vector = 0, 0 if x is not None or y is not None: if x is None or y is None: raise TrafoException("either specify both x and y or none of them") vector=_rvector(angle, unit.topt(x), unit.topt(y)) trafo_pt.__init__(self, matrix=_rmatrix(angle), vector=vector, epsilon=epsilon) class scale_pt(trafo_pt): def __init__(self, sx, sy=None, x=None, y=None, epsilon=_marker): if sy is None: sy = sx vector = 0, 0 if x is not None or y is not None: if x is None or y is None: raise TrafoException("either specify both x and y or none of them") vector = (1-sx)*x, (1-sy)*y trafo_pt.__init__(self, matrix=((sx, 0), (0, sy)), vector=vector, epsilon=epsilon) class scale(trafo): def __init__(self, sx, sy=None, x=None, y=None, epsilon=_marker): if sy is None: sy = sx vector = 0, 0 if x is not None or y is not None: if x is None or y is None: raise TrafoException("either specify both x and y or none of them") vector = (1-sx)*x, (1-sy)*y trafo.__init__(self, matrix=((sx, 0), (0, sy)), vector=vector, epsilon=epsilon) class slant_pt(trafo_pt): def __init__(self, a, angle=0, x=None, y=None, epsilon=_marker): t = ( rotate_pt(-angle, x, y, epsilon=epsilon) * trafo(matrix=((1, a), (0, 1)), epsilon=epsilon) * rotate_pt(angle, x, y, epsilon=epsilon) ) trafo_pt.__init__(self, t.matrix, t.vector, epsilon=epsilon) class slant(trafo): def __init__(self, a, angle=0, x=None, y=None, epsilon=_marker): t = ( rotate(-angle, x, y, epsilon=epsilon) * trafo(matrix=((1, a), (0, 1)), epsilon=epsilon) * rotate(angle, x, y, epsilon=epsilon) ) trafo.__init__(self, t.matrix, t.vector, epsilon=epsilon) class translate_pt(trafo_pt): def __init__(self, x, y, epsilon=_marker): trafo_pt.__init__(self, vector=(x, y), epsilon=epsilon) class translate(trafo): def __init__(self, x, y, epsilon=_marker): trafo.__init__(self, vector=(x, y), epsilon=epsilon)