Lib/fontTools/misc/transform.py - third_party/fonttools - Git at Google

 """Affine 2D transformation matrix class.

 The Transform class implements various transformation matrix operations,
 both on the matrix itself, as well as on 2D coordinates.

 Transform instances are effectively immutable: all methods that operate on the
 transformation itself always return a new instance. This has as the
 interesting side effect that Transform instances are hashable, ie. they can be
 used as dictionary keys.

 This module exports the following symbols:

 	Transform -- this is the main class
 	Identity  -- Transform instance set to the identity transformation
 	Offset    -- Convenience function that returns a translating transformation
 	Scale     -- Convenience function that returns a scaling transformation

 Examples:

 	>>> t = Transform(2, 0, 0, 3, 0, 0)
 	>>> t.transformPoint((100, 100))
 	(200, 300)
 	>>> t = Scale(2, 3)
 	>>> t.transformPoint((100, 100))
 	(200, 300)
 	>>> t.transformPoint((0, 0))
 	(0, 0)
 	>>> t = Offset(2, 3)
 	>>> t.transformPoint((100, 100))
 	(102, 103)
 	>>> t.transformPoint((0, 0))
 	(2, 3)
 	>>> t2 = t.scale(0.5)
 	>>> t2.transformPoint((100, 100))
 	(52.0, 53.0)
 	>>> import math
 	>>> t3 = t2.rotate(math.pi / 2)
 	>>> t3.transformPoint((0, 0))
 	(2.0, 3.0)
 	>>> t3.transformPoint((100, 100))
 	(-48.0, 53.0)
 	>>> t = Identity.scale(0.5).translate(100, 200).skew(0.1, 0.2)
 	>>> t.transformPoints([(0, 0), (1, 1), (100, 100)])
 	[(50.0, 100.0), (50.550167336042726, 100.60135501775433), (105.01673360427253, 160.13550177543362)]
 	>>>
 """

 from __future__ import print_function, division, absolute_import
 from fontTools.misc.py23 import *

 __all__ = ["Transform", "Identity", "Offset", "Scale"]


 _EPSILON = 1e-15
 _ONE_EPSILON = 1 - _EPSILON
 _MINUS_ONE_EPSILON = -1 + _EPSILON


 def _normSinCos(v):
 	if abs(v) < _EPSILON:
 		v = 0
 	elif v > _ONE_EPSILON:
 		v = 1
 	elif v < _MINUS_ONE_EPSILON:
 		v = -1
 	return v


 class Transform(object):

 	"""2x2 transformation matrix plus offset, a.k.a. Affine transform.
 	Transform instances are immutable: all transforming methods, eg.
 	rotate(), return a new Transform instance.

 	Examples:
 		>>> t = Transform()
 		>>> t
 		<Transform [1 0 0 1 0 0]>
 		>>> t.scale(2)
 		<Transform [2 0 0 2 0 0]>
 		>>> t.scale(2.5, 5.5)
 		<Transform [2.5 0 0 5.5 0 0]>
 		>>>
 		>>> t.scale(2, 3).transformPoint((100, 100))
 		(200, 300)
 	"""

 	def __init__(self, xx=1, xy=0, yx=0, yy=1, dx=0, dy=0):
 		"""Transform's constructor takes six arguments, all of which are
 		optional, and can be used as keyword arguments:
 			>>> Transform(12)
 			<Transform [12 0 0 1 0 0]>
 			>>> Transform(dx=12)
 			<Transform [1 0 0 1 12 0]>
 			>>> Transform(yx=12)
 			<Transform [1 0 12 1 0 0]>
 			>>>
 		"""
 		self.__affine = xx, xy, yx, yy, dx, dy

 	def transformPoint(self, p):
 		"""Transform a point.

 		Example:
 			>>> t = Transform()
 			>>> t = t.scale(2.5, 5.5)
 			>>> t.transformPoint((100, 100))
 			(250.0, 550.0)
 		"""
 		(x, y) = p
 		xx, xy, yx, yy, dx, dy = self.__affine
 		return (xx*x + yx*y + dx, xy*x + yy*y + dy)

 	def transformPoints(self, points):
 		"""Transform a list of points.

 		Example:
 			>>> t = Scale(2, 3)
 			>>> t.transformPoints([(0, 0), (0, 100), (100, 100), (100, 0)])
 			[(0, 0), (0, 300), (200, 300), (200, 0)]
 			>>>
 		"""
 		xx, xy, yx, yy, dx, dy = self.__affine
 		return [(xx*x + yx*y + dx, xy*x + yy*y + dy) for x, y in points]

 	def translate(self, x=0, y=0):
 		"""Return a new transformation, translated (offset) by x, y.

 		Example:
 			>>> t = Transform()
 			>>> t.translate(20, 30)
 			<Transform [1 0 0 1 20 30]>
 			>>>
 		"""
 		return self.transform((1, 0, 0, 1, x, y))

 	def scale(self, x=1, y=None):
 		"""Return a new transformation, scaled by x, y. The 'y' argument
 		may be None, which implies to use the x value for y as well.

 		Example:
 			>>> t = Transform()
 			>>> t.scale(5)
 			<Transform [5 0 0 5 0 0]>
 			>>> t.scale(5, 6)
 			<Transform [5 0 0 6 0 0]>
 			>>>
 		"""
 		if y is None:
 			y = x
 		return self.transform((x, 0, 0, y, 0, 0))

 	def rotate(self, angle):
 		"""Return a new transformation, rotated by 'angle' (radians).

 		Example:
 			>>> import math
 			>>> t = Transform()
 			>>> t.rotate(math.pi / 2)
 			<Transform [0 1 -1 0 0 0]>
 			>>>
 		"""
 		import math
 		c = _normSinCos(math.cos(angle))
 		s = _normSinCos(math.sin(angle))
 		return self.transform((c, s, -s, c, 0, 0))

 	def skew(self, x=0, y=0):
 		"""Return a new transformation, skewed by x and y.

 		Example:
 			>>> import math
 			>>> t = Transform()
 			>>> t.skew(math.pi / 4)
 			<Transform [1 0 1 1 0 0]>
 			>>>
 		"""
 		import math
 		return self.transform((1, math.tan(y), math.tan(x), 1, 0, 0))

 	def transform(self, other):
 		"""Return a new transformation, transformed by another
 		transformation.

 		Example:
 			>>> t = Transform(2, 0, 0, 3, 1, 6)
 			>>> t.transform((4, 3, 2, 1, 5, 6))
 			<Transform [8 9 4 3 11 24]>
 			>>>
 		"""
 		xx1, xy1, yx1, yy1, dx1, dy1 = other
 		xx2, xy2, yx2, yy2, dx2, dy2 = self.__affine
 		return self.__class__(
 				xx1*xx2 + xy1*yx2,
 				xx1*xy2 + xy1*yy2,
 				yx1*xx2 + yy1*yx2,
 				yx1*xy2 + yy1*yy2,
 				xx2*dx1 + yx2*dy1 + dx2,
 				xy2*dx1 + yy2*dy1 + dy2)

 	def reverseTransform(self, other):
 		"""Return a new transformation, which is the other transformation
 		transformed by self. self.reverseTransform(other) is equivalent to
 		other.transform(self).

 		Example:
 			>>> t = Transform(2, 0, 0, 3, 1, 6)
 			>>> t.reverseTransform((4, 3, 2, 1, 5, 6))
 			<Transform [8 6 6 3 21 15]>
 			>>> Transform(4, 3, 2, 1, 5, 6).transform((2, 0, 0, 3, 1, 6))
 			<Transform [8 6 6 3 21 15]>
 			>>>
 		"""
 		xx1, xy1, yx1, yy1, dx1, dy1 = self.__affine
 		xx2, xy2, yx2, yy2, dx2, dy2 = other
 		return self.__class__(
 				xx1*xx2 + xy1*yx2,
 				xx1*xy2 + xy1*yy2,
 				yx1*xx2 + yy1*yx2,
 				yx1*xy2 + yy1*yy2,
 				xx2*dx1 + yx2*dy1 + dx2,
 				xy2*dx1 + yy2*dy1 + dy2)

 	def inverse(self):
 		"""Return the inverse transformation.

 		Example:
 			>>> t = Identity.translate(2, 3).scale(4, 5)
 			>>> t.transformPoint((10, 20))
 			(42, 103)
 			>>> it = t.inverse()
 			>>> it.transformPoint((42, 103))
 			(10.0, 20.0)
 			>>>
 		"""
 		if self.__affine == (1, 0, 0, 1, 0, 0):
 			return self
 		xx, xy, yx, yy, dx, dy = self.__affine
 		det = xx*yy - yx*xy
 		xx, xy, yx, yy = yy/det, -xy/det, -yx/det, xx/det
 		dx, dy = -xx*dx - yx*dy, -xy*dx - yy*dy
 		return self.__class__(xx, xy, yx, yy, dx, dy)

 	def toPS(self):
 		"""Return a PostScript representation:
 			>>> t = Identity.scale(2, 3).translate(4, 5)
 			>>> t.toPS()
 			'[2 0 0 3 8 15]'
 			>>>
 		"""
 		return "[%s %s %s %s %s %s]" % self.__affine

 	def __len__(self):
 		"""Transform instances also behave like sequences of length 6:
 			>>> len(Identity)
 			6
 			>>>
 		"""
 		return 6

 	def __getitem__(self, index):
 		"""Transform instances also behave like sequences of length 6:
 			>>> list(Identity)
 			[1, 0, 0, 1, 0, 0]
 			>>> tuple(Identity)
 			(1, 0, 0, 1, 0, 0)
 			>>>
 		"""
 		return self.__affine[index]

 	def __ne__(self, other):
 		return not self.__eq__(other)
 	def __eq__(self, other):
 		"""Transform instances are comparable:
 			>>> t1 = Identity.scale(2, 3).translate(4, 6)
 			>>> t2 = Identity.translate(8, 18).scale(2, 3)
 			>>> t1 == t2
 			1
 			>>>

 		But beware of floating point rounding errors:
 			>>> t1 = Identity.scale(0.2, 0.3).translate(0.4, 0.6)
 			>>> t2 = Identity.translate(0.08, 0.18).scale(0.2, 0.3)
 			>>> t1
 			<Transform [0.2 0 0 0.3 0.08 0.18]>
 			>>> t2
 			<Transform [0.2 0 0 0.3 0.08 0.18]>
 			>>> t1 == t2
 			0
 			>>>
 		"""
 		xx1, xy1, yx1, yy1, dx1, dy1 = self.__affine
 		xx2, xy2, yx2, yy2, dx2, dy2 = other
 		return (xx1, xy1, yx1, yy1, dx1, dy1) == \
 				(xx2, xy2, yx2, yy2, dx2, dy2)

 	def __hash__(self):
 		"""Transform instances are hashable, meaning you can use them as
 		keys in dictionaries:
 			>>> d = {Scale(12, 13): None}
 			>>> d
 			{<Transform [12 0 0 13 0 0]>: None}
 			>>>

 		But again, beware of floating point rounding errors:
 			>>> t1 = Identity.scale(0.2, 0.3).translate(0.4, 0.6)
 			>>> t2 = Identity.translate(0.08, 0.18).scale(0.2, 0.3)
 			>>> t1
 			<Transform [0.2 0 0 0.3 0.08 0.18]>
 			>>> t2
 			<Transform [0.2 0 0 0.3 0.08 0.18]>
 			>>> d = {t1: None}
 			>>> d
 			{<Transform [0.2 0 0 0.3 0.08 0.18]>: None}
 			>>> d[t2]
 			Traceback (most recent call last):
 			  File "<stdin>", line 1, in ?
 			KeyError: <Transform [0.2 0 0 0.3 0.08 0.18]>
 			>>>
 		"""
 		return hash(self.__affine)

 	def __bool__(self):
 		"""Returns True if transform is not identity, False otherwise.
 			>>> bool(Identity)
 			False
 			>>> bool(Transform())
 			False
 			>>> bool(Scale(1.))
 			False
 			>>> bool(Scale(2))
 			True
 			>>> bool(Offset())
 			False
 			>>> bool(Offset(0))
 			False
 			>>> bool(Offset(2))
 			True
 		"""
 		return self.__affine != Identity.__affine

 	__nonzero__ = __bool__

 	def __repr__(self):
 		return "<%s [%g %g %g %g %g %g]>" % ((self.__class__.__name__,) \
 				+ self.__affine)


 Identity = Transform()

 def Offset(x=0, y=0):
 	"""Return the identity transformation offset by x, y.

 	Example:
 		>>> Offset(2, 3)
 		<Transform [1 0 0 1 2 3]>
 		>>>
 	"""
 	return Transform(1, 0, 0, 1, x, y)

 def Scale(x, y=None):
 	"""Return the identity transformation scaled by x, y. The 'y' argument
 	may be None, which implies to use the x value for y as well.

 	Example:
 		>>> Scale(2, 3)
 		<Transform [2 0 0 3 0 0]>
 		>>>
 	"""
 	if y is None:
 		y = x
 	return Transform(x, 0, 0, y, 0, 0)


 if __name__ == "__main__":
 	import sys
 	import doctest
 	sys.exit(doctest.testmod().failed)
	"""Affine 2D transformation matrix class.

	The Transform class implements various transformation matrix operations,
	both on the matrix itself, as well as on 2D coordinates.

	Transform instances are effectively immutable: all methods that operate on the
	transformation itself always return a new instance. This has as the
	interesting side effect that Transform instances are hashable, ie. they can be
	used as dictionary keys.

	This module exports the following symbols:

	Transform -- this is the main class
	Identity -- Transform instance set to the identity transformation
	Offset -- Convenience function that returns a translating transformation
	Scale -- Convenience function that returns a scaling transformation

	Examples:

	>>> t = Transform(2, 0, 0, 3, 0, 0)
	>>> t.transformPoint((100, 100))
	(200, 300)
	>>> t = Scale(2, 3)
	>>> t.transformPoint((100, 100))
	(200, 300)
	>>> t.transformPoint((0, 0))
	(0, 0)
	>>> t = Offset(2, 3)
	>>> t.transformPoint((100, 100))
	(102, 103)
	>>> t.transformPoint((0, 0))
	(2, 3)
	>>> t2 = t.scale(0.5)
	>>> t2.transformPoint((100, 100))
	(52.0, 53.0)
	>>> import math
	>>> t3 = t2.rotate(math.pi / 2)
	>>> t3.transformPoint((0, 0))
	(2.0, 3.0)
	>>> t3.transformPoint((100, 100))
	(-48.0, 53.0)
	>>> t = Identity.scale(0.5).translate(100, 200).skew(0.1, 0.2)
	>>> t.transformPoints([(0, 0), (1, 1), (100, 100)])
	[(50.0, 100.0), (50.550167336042726, 100.60135501775433), (105.01673360427253, 160.13550177543362)]
	>>>
	"""

	from __future__ import print_function, division, absolute_import
	from fontTools.misc.py23 import *

	__all__ = ["Transform", "Identity", "Offset", "Scale"]


	_EPSILON = 1e-15
	_ONE_EPSILON = 1 - _EPSILON
	_MINUS_ONE_EPSILON = -1 + _EPSILON


	def _normSinCos(v):
	if abs(v) < _EPSILON:
	v = 0
	elif v > _ONE_EPSILON:
	v = 1
	elif v < _MINUS_ONE_EPSILON:
	v = -1
	return v


	class Transform(object):

	"""2x2 transformation matrix plus offset, a.k.a. Affine transform.
	Transform instances are immutable: all transforming methods, eg.
	rotate(), return a new Transform instance.

	Examples:
	>>> t = Transform()
	>>> t
	<Transform [1 0 0 1 0 0]>
	>>> t.scale(2)
	<Transform [2 0 0 2 0 0]>
	>>> t.scale(2.5, 5.5)
	<Transform [2.5 0 0 5.5 0 0]>
	>>>
	>>> t.scale(2, 3).transformPoint((100, 100))
	(200, 300)
	"""

	def __init__(self, xx=1, xy=0, yx=0, yy=1, dx=0, dy=0):
	"""Transform's constructor takes six arguments, all of which are
	optional, and can be used as keyword arguments:
	>>> Transform(12)
	<Transform [12 0 0 1 0 0]>
	>>> Transform(dx=12)
	<Transform [1 0 0 1 12 0]>
	>>> Transform(yx=12)
	<Transform [1 0 12 1 0 0]>
	>>>
	"""
	self.__affine = xx, xy, yx, yy, dx, dy

	def transformPoint(self, p):
	"""Transform a point.

	Example:
	>>> t = Transform()
	>>> t = t.scale(2.5, 5.5)
	>>> t.transformPoint((100, 100))
	(250.0, 550.0)
	"""
	(x, y) = p
	xx, xy, yx, yy, dx, dy = self.__affine
	return (xxx + yxy + dx, xyx + yyy + dy)

	def transformPoints(self, points):
	"""Transform a list of points.

	Example:
	>>> t = Scale(2, 3)
	>>> t.transformPoints([(0, 0), (0, 100), (100, 100), (100, 0)])
	[(0, 0), (0, 300), (200, 300), (200, 0)]
	>>>
	"""
	xx, xy, yx, yy, dx, dy = self.__affine
	return [(xxx + yxy + dx, xyx + yyy + dy) for x, y in points]

	def translate(self, x=0, y=0):
	"""Return a new transformation, translated (offset) by x, y.

	Example:
	>>> t = Transform()
	>>> t.translate(20, 30)
	<Transform [1 0 0 1 20 30]>
	>>>
	"""
	return self.transform((1, 0, 0, 1, x, y))

	def scale(self, x=1, y=None):
	"""Return a new transformation, scaled by x, y. The 'y' argument
	may be None, which implies to use the x value for y as well.

	Example:
	>>> t = Transform()
	>>> t.scale(5)
	<Transform [5 0 0 5 0 0]>
	>>> t.scale(5, 6)
	<Transform [5 0 0 6 0 0]>
	>>>
	"""
	if y is None:
	y = x
	return self.transform((x, 0, 0, y, 0, 0))

	def rotate(self, angle):
	"""Return a new transformation, rotated by 'angle' (radians).

	Example:
	>>> import math
	>>> t = Transform()
	>>> t.rotate(math.pi / 2)
	<Transform [0 1 -1 0 0 0]>
	>>>
	"""
	import math
	c = _normSinCos(math.cos(angle))
	s = _normSinCos(math.sin(angle))
	return self.transform((c, s, -s, c, 0, 0))

	def skew(self, x=0, y=0):
	"""Return a new transformation, skewed by x and y.

	Example:
	>>> import math
	>>> t = Transform()
	>>> t.skew(math.pi / 4)
	<Transform [1 0 1 1 0 0]>
	>>>
	"""
	import math
	return self.transform((1, math.tan(y), math.tan(x), 1, 0, 0))

	def transform(self, other):
	"""Return a new transformation, transformed by another
	transformation.

	Example:
	>>> t = Transform(2, 0, 0, 3, 1, 6)
	>>> t.transform((4, 3, 2, 1, 5, 6))
	<Transform [8 9 4 3 11 24]>
	>>>
	"""
	xx1, xy1, yx1, yy1, dx1, dy1 = other
	xx2, xy2, yx2, yy2, dx2, dy2 = self.__affine
	return self.__class__(
	xx1xx2 + xy1yx2,
	xx1xy2 + xy1yy2,
	yx1xx2 + yy1yx2,
	yx1xy2 + yy1yy2,
	xx2dx1 + yx2dy1 + dx2,
	xy2dx1 + yy2dy1 + dy2)

	def reverseTransform(self, other):
	"""Return a new transformation, which is the other transformation
	transformed by self. self.reverseTransform(other) is equivalent to
	other.transform(self).

	Example:
	>>> t = Transform(2, 0, 0, 3, 1, 6)
	>>> t.reverseTransform((4, 3, 2, 1, 5, 6))
	<Transform [8 6 6 3 21 15]>
	>>> Transform(4, 3, 2, 1, 5, 6).transform((2, 0, 0, 3, 1, 6))
	<Transform [8 6 6 3 21 15]>
	>>>
	"""
	xx1, xy1, yx1, yy1, dx1, dy1 = self.__affine
	xx2, xy2, yx2, yy2, dx2, dy2 = other
	return self.__class__(
	xx1xx2 + xy1yx2,
	xx1xy2 + xy1yy2,
	yx1xx2 + yy1yx2,
	yx1xy2 + yy1yy2,
	xx2dx1 + yx2dy1 + dx2,
	xy2dx1 + yy2dy1 + dy2)

	def inverse(self):
	"""Return the inverse transformation.

	Example:
	>>> t = Identity.translate(2, 3).scale(4, 5)
	>>> t.transformPoint((10, 20))
	(42, 103)
	>>> it = t.inverse()
	>>> it.transformPoint((42, 103))
	(10.0, 20.0)
	>>>
	"""
	if self.__affine == (1, 0, 0, 1, 0, 0):
	return self
	xx, xy, yx, yy, dx, dy = self.__affine
	det = xxyy - yxxy
	xx, xy, yx, yy = yy/det, -xy/det, -yx/det, xx/det
	dx, dy = -xxdx - yxdy, -xydx - yydy
	return self.__class__(xx, xy, yx, yy, dx, dy)

	def toPS(self):
	"""Return a PostScript representation:
	>>> t = Identity.scale(2, 3).translate(4, 5)
	>>> t.toPS()
	'[2 0 0 3 8 15]'
	>>>
	"""
	return "[%s %s %s %s %s %s]" % self.__affine

	def __len__(self):
	"""Transform instances also behave like sequences of length 6:
	>>> len(Identity)
	6
	>>>
	"""
	return 6

	def __getitem__(self, index):
	"""Transform instances also behave like sequences of length 6:
	>>> list(Identity)
	[1, 0, 0, 1, 0, 0]
	>>> tuple(Identity)
	(1, 0, 0, 1, 0, 0)
	>>>
	"""
	return self.__affine[index]

	def __ne__(self, other):
	return not self.__eq__(other)
	def __eq__(self, other):
	"""Transform instances are comparable:
	>>> t1 = Identity.scale(2, 3).translate(4, 6)
	>>> t2 = Identity.translate(8, 18).scale(2, 3)
	>>> t1 == t2
	1
	>>>

	But beware of floating point rounding errors:
	>>> t1 = Identity.scale(0.2, 0.3).translate(0.4, 0.6)
	>>> t2 = Identity.translate(0.08, 0.18).scale(0.2, 0.3)
	>>> t1
	<Transform [0.2 0 0 0.3 0.08 0.18]>
	>>> t2
	<Transform [0.2 0 0 0.3 0.08 0.18]>
	>>> t1 == t2
	0
	>>>
	"""
	xx1, xy1, yx1, yy1, dx1, dy1 = self.__affine
	xx2, xy2, yx2, yy2, dx2, dy2 = other
	return (xx1, xy1, yx1, yy1, dx1, dy1) == \
	(xx2, xy2, yx2, yy2, dx2, dy2)

	def __hash__(self):
	"""Transform instances are hashable, meaning you can use them as
	keys in dictionaries:
	>>> d = {Scale(12, 13): None}
	>>> d
	{<Transform [12 0 0 13 0 0]>: None}
	>>>

	But again, beware of floating point rounding errors:
	>>> t1 = Identity.scale(0.2, 0.3).translate(0.4, 0.6)
	>>> t2 = Identity.translate(0.08, 0.18).scale(0.2, 0.3)
	>>> t1
	<Transform [0.2 0 0 0.3 0.08 0.18]>
	>>> t2
	<Transform [0.2 0 0 0.3 0.08 0.18]>
	>>> d = {t1: None}
	>>> d
	{<Transform [0.2 0 0 0.3 0.08 0.18]>: None}
	>>> d[t2]
	Traceback (most recent call last):
	File "<stdin>", line 1, in ?
	KeyError: <Transform [0.2 0 0 0.3 0.08 0.18]>
	>>>
	"""
	return hash(self.__affine)

	def __bool__(self):
	"""Returns True if transform is not identity, False otherwise.
	>>> bool(Identity)
	False
	>>> bool(Transform())
	False
	>>> bool(Scale(1.))
	False
	>>> bool(Scale(2))
	True
	>>> bool(Offset())
	False
	>>> bool(Offset(0))
	False
	>>> bool(Offset(2))
	True
	"""
	return self.__affine != Identity.__affine

	__nonzero__ = __bool__

	def __repr__(self):
	return "<%s [%g %g %g %g %g %g]>" % ((self.__class__.__name__,) \
	+ self.__affine)


	Identity = Transform()

	def Offset(x=0, y=0):
	"""Return the identity transformation offset by x, y.

	Example:
	>>> Offset(2, 3)
	<Transform [1 0 0 1 2 3]>
	>>>
	"""
	return Transform(1, 0, 0, 1, x, y)

	def Scale(x, y=None):
	"""Return the identity transformation scaled by x, y. The 'y' argument
	may be None, which implies to use the x value for y as well.

	Example:
	>>> Scale(2, 3)
	<Transform [2 0 0 3 0 0]>
	>>>
	"""
	if y is None:
	y = x
	return Transform(x, 0, 0, y, 0, 0)


	if __name__ == "__main__":
	import sys
	import doctest
	sys.exit(doctest.testmod().failed)