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- '''functions for 2D affine transformations'''
- __all__ = (
- 'nullTransform',
- 'translate',
- 'scale',
- 'rotate',
- 'skewX',
- 'skewY',
- 'mmult',
- 'inverse',
- 'zTransformPoint',
- 'transformPoint',
- 'transformPoints',
- 'zTransformPoints',
- )
- from math import pi, cos, sin, tan
- # constructors for matrices:
- def nullTransform():
- return (1, 0, 0, 1, 0, 0)
- def translate(dx, dy):
- return (1, 0, 0, 1, dx, dy)
- def scale(sx, sy):
- return (sx, 0, 0, sy, 0, 0)
- def rotate(angle):
- a = angle * pi/180
- return (cos(a), sin(a), -sin(a), cos(a), 0, 0)
- def skewX(angle):
- a = angle * pi/180
- return (1, 0, tan(a), 1, 0, 0)
- def skewY(angle):
- a = angle * pi/180
- return (1, tan(a), 0, 1, 0, 0)
- def mmult(A, B):
- "A postmultiplied by B"
- # I checked this RGB
- # [a0 a2 a4] [b0 b2 b4]
- # [a1 a3 a5] * [b1 b3 b5]
- # [ 1 ] [ 1 ]
- #
- return (A[0]*B[0] + A[2]*B[1],
- A[1]*B[0] + A[3]*B[1],
- A[0]*B[2] + A[2]*B[3],
- A[1]*B[2] + A[3]*B[3],
- A[0]*B[4] + A[2]*B[5] + A[4],
- A[1]*B[4] + A[3]*B[5] + A[5])
- def inverse(A):
- "For A affine 2D represented as 6vec return 6vec version of A**(-1)"
- # I checked this RGB
- det = float(A[0]*A[3] - A[2]*A[1])
- R = [A[3]/det, -A[1]/det, -A[2]/det, A[0]/det]
- return tuple(R+[-R[0]*A[4]-R[2]*A[5],-R[1]*A[4]-R[3]*A[5]])
- def zTransformPoint(A,v):
- "Apply the homogenous part of atransformation a to vector v --> A*v"
- return (A[0]*v[0]+A[2]*v[1],A[1]*v[0]+A[3]*v[1])
- def transformPoint(A,v):
- "Apply transformation a to vector v --> A*v"
- return (A[0]*v[0]+A[2]*v[1]+A[4],A[1]*v[0]+A[3]*v[1]+A[5])
- def transformPoints(matrix, V):
- r = [transformPoint(matrix,v) for v in V]
- if isinstance(V,tuple): r = tuple(r)
- return r
- def zTransformPoints(matrix, V):
- return list(map(lambda x,matrix=matrix: zTransformPoint(matrix,x), V))
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