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import numpy as np
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import cv2
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import os
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image_extensions = ['.bmp', '.jpg', '.jpeg', '.png', '.tif', '.tiff', '.pbm', '.pgm', '.ppm']
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def splitfn(fn):
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path, fn = os.path.split(fn)
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name, ext = os.path.splitext(fn)
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return path, name, ext
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def anorm2(a):
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return (a*a).sum(-1)
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def anorm(a):
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return np.sqrt( anorm2(a) )
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def homotrans(H, x, y):
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xs = H[0, 0]*x + H[0, 1]*y + H[0, 2]
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ys = H[1, 0]*x + H[1, 1]*y + H[1, 2]
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s = H[2, 0]*x + H[2, 1]*y + H[2, 2]
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return xs/s, ys/s
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def to_rect(a):
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a = np.ravel(a)
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if len(a) == 2:
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a = (0, 0, a[0], a[1])
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return np.array(a, np.float64).reshape(2, 2)
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def rect2rect_mtx(src, dst):
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src, dst = to_rect(src), to_rect(dst)
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cx, cy = (dst[1] - dst[0]) / (src[1] - src[0])
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tx, ty = dst[0] - src[0] * (cx, cy)
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M = np.float64([[ cx, 0, tx],
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[ 0, cy, ty],
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[ 0, 0, 1]])
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return M
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def lookat(eye, target, up = (0, 0, 1)):
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fwd = np.asarray(target, np.float64) - eye
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fwd /= anorm(fwd)
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right = np.cross(fwd, up)
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right /= anorm(right)
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down = np.cross(fwd, right)
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R = np.float64([right, down, fwd])
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tvec = -np.dot(R, eye)
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return R, tvec
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def mtx2rvec(R):
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w, u, vt = cv2.SVDecomp(R - np.eye(3))
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p = vt[0] + u[:,0]*w[0] # same as np.dot(R, vt[0])
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c = np.dot(vt[0], p)
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s = np.dot(vt[1], p)
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axis = np.cross(vt[0], vt[1])
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return axis * np.arctan2(s, c)
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