#cython: cdivision=True #cython: boundscheck=False #cython: nonecheck=False #cython: wraparound=False import numpy as np from libc.math cimport sin, cos from .._shared.interpolation cimport round from .._shared.fused_numerics cimport np_floats from ._orb_descriptor_positions import POS, POS0, POS1 def _orb_loop(np_floats[:, ::1] image, Py_ssize_t[:, ::1] keypoints, np_floats[:] orientations): cdef Py_ssize_t i, d, kr, kc, pr0, pr1, pc0, pc1, spr0, spc0, spr1, spc1 cdef np_floats angle, sin_a, cos_a cdef unsigned char[:, ::1] descriptors = np.zeros( (keypoints.shape[0], POS.shape[0]), dtype=np.uint8) cdef signed char[:, ::1] cpos0 = POS0 cdef signed char[:, ::1] cpos1 = POS1 with nogil: for i in range(descriptors.shape[0]): angle = orientations[i] sin_a = sin(angle) cos_a = cos(angle) kr = keypoints[i, 0] kc = keypoints[i, 1] for j in range(descriptors.shape[1]): pr0 = cpos0[j, 0] pc0 = cpos0[j, 1] pr1 = cpos1[j, 0] pc1 = cpos1[j, 1] spr0 = round(sin_a * pr0 + cos_a * pc0) spc0 = round(cos_a * pr0 - sin_a * pc0) spr1 = round(sin_a * pr1 + cos_a * pc1) spc1 = round(cos_a * pr1 - sin_a * pc1) if image[kr + spr0, kc + spc0] < image[kr + spr1, kc + spc1]: descriptors[i, j] = True return np.asarray(descriptors)