mirror of
https://github.com/opencv/opencv.git
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31289d2f32
Fix implicit conversion from array to scalar in python bindings * Fix wrong conversion behavior for primitive types - Introduce ArgTypeInfo namedtuple instead of plain tuple. If strict conversion parameter for type is set to true, it is handled like object argument in PyArg_ParseTupleAndKeywords and converted to concrete type with the appropriate pyopencv_to function call. - Remove deadcode and unused variables. - Fix implicit conversion from numpy array with 1 element to scalar - Fix narrowing conversion to size_t type. * Fix wrong conversion behavior for primitive types - Introduce ArgTypeInfo namedtuple instead of plain tuple. If strict conversion parameter for type is set to true, it is handled like object argument in PyArg_ParseTupleAndKeywords and converted to concrete type with the appropriate pyopencv_to function call. - Remove deadcode and unused variables. - Fix implicit conversion from numpy array with 1 element to scalar - Fix narrowing conversion to size_t type.· - Enable tests with wrong conversion behavior - Restrict passing None as value - Restrict bool to integer/floating types conversion * Add PyIntType support for Python 2 * Remove possible narrowing conversion of size_t * Bindings conversion update - Remove unused macro - Add better conversion for types to numpy types descriptors - Add argument name to fail messages - NoneType treated as a valid argument. Better handling will be added as a standalone patch * Add descriptor specialization for size_t * Add check for signed to unsigned integer conversion safety - If signed integer is positive it can be safely converted to unsigned - Add check for plain python 2 objects - Add check for numpy scalars - Add simple type_traits implementation for better code style * Resolve type "overflow" false negative in safe casting check - Move type_traits to separate header * Add copyright message to type_traits.hpp * Limit conversion scope for integral numpy types - Made canBeSafelyCasted specialized only for size_t, so type_traits header became unused and was removed. - Added clarification about descriptor pointer
174 lines
5.6 KiB
Python
174 lines
5.6 KiB
Python
#!/usr/bin/env python
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from itertools import product
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from functools import reduce
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import numpy as np
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import cv2 as cv
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from tests_common import NewOpenCVTests
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def norm_inf(x, y=None):
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def norm(vec):
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return np.linalg.norm(vec.flatten(), np.inf)
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x = x.astype(np.float64)
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return norm(x) if y is None else norm(x - y.astype(np.float64))
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def norm_l1(x, y=None):
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def norm(vec):
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return np.linalg.norm(vec.flatten(), 1)
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x = x.astype(np.float64)
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return norm(x) if y is None else norm(x - y.astype(np.float64))
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def norm_l2(x, y=None):
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def norm(vec):
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return np.linalg.norm(vec.flatten())
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x = x.astype(np.float64)
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return norm(x) if y is None else norm(x - y.astype(np.float64))
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def norm_l2sqr(x, y=None):
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def norm(vec):
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return np.square(vec).sum()
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x = x.astype(np.float64)
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return norm(x) if y is None else norm(x - y.astype(np.float64))
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def norm_hamming(x, y=None):
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def norm(vec):
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return sum(bin(i).count('1') for i in vec.flatten())
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return norm(x) if y is None else norm(np.bitwise_xor(x, y))
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def norm_hamming2(x, y=None):
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def norm(vec):
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def element_norm(element):
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binary_str = bin(element).split('b')[-1]
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if len(binary_str) % 2 == 1:
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binary_str = '0' + binary_str
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gen = filter(lambda p: p != '00',
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(binary_str[i:i+2]
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for i in range(0, len(binary_str), 2)))
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return sum(1 for _ in gen)
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return sum(element_norm(element) for element in vec.flatten())
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return norm(x) if y is None else norm(np.bitwise_xor(x, y))
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norm_type_under_test = {
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cv.NORM_INF: norm_inf,
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cv.NORM_L1: norm_l1,
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cv.NORM_L2: norm_l2,
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cv.NORM_L2SQR: norm_l2sqr,
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cv.NORM_HAMMING: norm_hamming,
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cv.NORM_HAMMING2: norm_hamming2
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}
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norm_name = {
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cv.NORM_INF: 'inf',
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cv.NORM_L1: 'L1',
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cv.NORM_L2: 'L2',
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cv.NORM_L2SQR: 'L2SQR',
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cv.NORM_HAMMING: 'Hamming',
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cv.NORM_HAMMING2: 'Hamming2'
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}
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def get_element_types(norm_type):
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if norm_type in (cv.NORM_HAMMING, cv.NORM_HAMMING2):
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return (np.uint8,)
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else:
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return (np.uint8, np.int8, np.uint16, np.int16, np.int32, np.float32,
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np.float64)
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def generate_vector(shape, dtype):
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if np.issubdtype(dtype, np.integer):
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return np.random.randint(0, 100, shape).astype(dtype)
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else:
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return np.random.normal(10., 12.5, shape).astype(dtype)
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shapes = (1, 2, 3, 5, 7, 16, (1, 1), (2, 2), (3, 5), (1, 7))
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class norm_test(NewOpenCVTests):
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def test_norm_for_one_array(self):
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np.random.seed(123)
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for norm_type, norm in norm_type_under_test.items():
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element_types = get_element_types(norm_type)
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for shape, element_type in product(shapes, element_types):
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array = generate_vector(shape, element_type)
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expected = norm(array)
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actual = cv.norm(array, norm_type)
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self.assertAlmostEqual(
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expected, actual, places=2,
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msg='Array {0} of {1} and norm {2}'.format(
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array, element_type.__name__, norm_name[norm_type]
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)
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)
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def test_norm_for_two_arrays(self):
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np.random.seed(456)
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for norm_type, norm in norm_type_under_test.items():
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element_types = get_element_types(norm_type)
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for shape, element_type in product(shapes, element_types):
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first = generate_vector(shape, element_type)
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second = generate_vector(shape, element_type)
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expected = norm(first, second)
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actual = cv.norm(first, second, norm_type)
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self.assertAlmostEqual(
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expected, actual, places=2,
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msg='Arrays {0} {1} of type {2} and norm {3}'.format(
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first, second, element_type.__name__,
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norm_name[norm_type]
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)
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)
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def test_norm_fails_for_wrong_type(self):
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for norm_type in (cv.NORM_HAMMING, cv.NORM_HAMMING2):
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with self.assertRaises(Exception,
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msg='Type is not checked {0}'.format(
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norm_name[norm_type]
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)):
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cv.norm(np.array([1, 2], dtype=np.int32), norm_type)
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def test_norm_fails_for_array_and_scalar(self):
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for norm_type in norm_type_under_test:
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with self.assertRaises(Exception,
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msg='Exception is not thrown for {0}'.format(
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norm_name[norm_type]
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)):
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cv.norm(np.array([1, 2], dtype=np.uint8), 123, norm_type)
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def test_norm_fails_for_scalar_and_array(self):
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for norm_type in norm_type_under_test:
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with self.assertRaises(Exception,
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msg='Exception is not thrown for {0}'.format(
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norm_name[norm_type]
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)):
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cv.norm(4, np.array([1, 2], dtype=np.uint8), norm_type)
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def test_norm_fails_for_array_and_norm_type_as_scalar(self):
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for norm_type in norm_type_under_test:
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with self.assertRaises(Exception,
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msg='Exception is not thrown for {0}'.format(
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norm_name[norm_type]
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)):
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cv.norm(np.array([3, 4, 5], dtype=np.uint8),
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norm_type, normType=norm_type)
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if __name__ == '__main__':
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NewOpenCVTests.bootstrap()
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