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Direktori : /proc/self/root/opt/alt/python37/lib64/python3.7/site-packages/numpy/core/tests/ |
Current File : //proc/self/root/opt/alt/python37/lib64/python3.7/site-packages/numpy/core/tests/test_unicode.py |
from __future__ import division, absolute_import, print_function import sys import numpy as np from numpy.compat import unicode from numpy.testing import ( TestCase, run_module_suite, assert_, assert_equal, assert_array_equal) # Guess the UCS length for this python interpreter if sys.version_info[:2] >= (3, 3): # Python 3.3 uses a flexible string representation ucs4 = False def buffer_length(arr): if isinstance(arr, unicode): arr = str(arr) if not arr: charmax = 0 else: charmax = max([ord(c) for c in arr]) if charmax < 256: size = 1 elif charmax < 65536: size = 2 else: size = 4 return size * len(arr) v = memoryview(arr) if v.shape is None: return len(v) * v.itemsize else: return np.prod(v.shape) * v.itemsize else: if len(buffer(u'u')) == 4: ucs4 = True else: ucs4 = False def buffer_length(arr): if isinstance(arr, np.ndarray): return len(arr.data) return len(buffer(arr)) # In both cases below we need to make sure that the byte swapped value (as # UCS4) is still a valid unicode: # Value that can be represented in UCS2 interpreters ucs2_value = u'\u0900' # Value that cannot be represented in UCS2 interpreters (but can in UCS4) ucs4_value = u'\U00100900' def test_string_cast(): str_arr = np.array(["1234", "1234\0\0"], dtype='S') uni_arr1 = str_arr.astype('>U') uni_arr2 = str_arr.astype('<U') if sys.version_info[0] < 3: assert_array_equal(str_arr, uni_arr1) assert_array_equal(str_arr, uni_arr2) else: assert_(str_arr != uni_arr1) assert_(str_arr != uni_arr2) assert_array_equal(uni_arr1, uni_arr2) ############################################################ # Creation tests ############################################################ class create_zeros(object): """Check the creation of zero-valued arrays""" def content_check(self, ua, ua_scalar, nbytes): # Check the length of the unicode base type self.assertTrue(int(ua.dtype.str[2:]) == self.ulen) # Check the length of the data buffer self.assertTrue(buffer_length(ua) == nbytes) # Small check that data in array element is ok self.assertTrue(ua_scalar == u'') # Encode to ascii and double check self.assertTrue(ua_scalar.encode('ascii') == b'') # Check buffer lengths for scalars if ucs4: self.assertTrue(buffer_length(ua_scalar) == 0) else: self.assertTrue(buffer_length(ua_scalar) == 0) def test_zeros0D(self): # Check creation of 0-dimensional objects ua = np.zeros((), dtype='U%s' % self.ulen) self.content_check(ua, ua[()], 4*self.ulen) def test_zerosSD(self): # Check creation of single-dimensional objects ua = np.zeros((2,), dtype='U%s' % self.ulen) self.content_check(ua, ua[0], 4*self.ulen*2) self.content_check(ua, ua[1], 4*self.ulen*2) def test_zerosMD(self): # Check creation of multi-dimensional objects ua = np.zeros((2, 3, 4), dtype='U%s' % self.ulen) self.content_check(ua, ua[0, 0, 0], 4*self.ulen*2*3*4) self.content_check(ua, ua[-1, -1, -1], 4*self.ulen*2*3*4) class test_create_zeros_1(create_zeros, TestCase): """Check the creation of zero-valued arrays (size 1)""" ulen = 1 class test_create_zeros_2(create_zeros, TestCase): """Check the creation of zero-valued arrays (size 2)""" ulen = 2 class test_create_zeros_1009(create_zeros, TestCase): """Check the creation of zero-valued arrays (size 1009)""" ulen = 1009 class create_values(object): """Check the creation of unicode arrays with values""" def content_check(self, ua, ua_scalar, nbytes): # Check the length of the unicode base type self.assertTrue(int(ua.dtype.str[2:]) == self.ulen) # Check the length of the data buffer self.assertTrue(buffer_length(ua) == nbytes) # Small check that data in array element is ok self.assertTrue(ua_scalar == self.ucs_value*self.ulen) # Encode to UTF-8 and double check self.assertTrue(ua_scalar.encode('utf-8') == (self.ucs_value*self.ulen).encode('utf-8')) # Check buffer lengths for scalars if ucs4: self.assertTrue(buffer_length(ua_scalar) == 4*self.ulen) else: if self.ucs_value == ucs4_value: # In UCS2, the \U0010FFFF will be represented using a # surrogate *pair* self.assertTrue(buffer_length(ua_scalar) == 2*2*self.ulen) else: # In UCS2, the \uFFFF will be represented using a # regular 2-byte word self.assertTrue(buffer_length(ua_scalar) == 2*self.ulen) def test_values0D(self): # Check creation of 0-dimensional objects with values ua = np.array(self.ucs_value*self.ulen, dtype='U%s' % self.ulen) self.content_check(ua, ua[()], 4*self.ulen) def test_valuesSD(self): # Check creation of single-dimensional objects with values ua = np.array([self.ucs_value*self.ulen]*2, dtype='U%s' % self.ulen) self.content_check(ua, ua[0], 4*self.ulen*2) self.content_check(ua, ua[1], 4*self.ulen*2) def test_valuesMD(self): # Check creation of multi-dimensional objects with values ua = np.array([[[self.ucs_value*self.ulen]*2]*3]*4, dtype='U%s' % self.ulen) self.content_check(ua, ua[0, 0, 0], 4*self.ulen*2*3*4) self.content_check(ua, ua[-1, -1, -1], 4*self.ulen*2*3*4) class test_create_values_1_ucs2(create_values, TestCase): """Check the creation of valued arrays (size 1, UCS2 values)""" ulen = 1 ucs_value = ucs2_value class test_create_values_1_ucs4(create_values, TestCase): """Check the creation of valued arrays (size 1, UCS4 values)""" ulen = 1 ucs_value = ucs4_value class test_create_values_2_ucs2(create_values, TestCase): """Check the creation of valued arrays (size 2, UCS2 values)""" ulen = 2 ucs_value = ucs2_value class test_create_values_2_ucs4(create_values, TestCase): """Check the creation of valued arrays (size 2, UCS4 values)""" ulen = 2 ucs_value = ucs4_value class test_create_values_1009_ucs2(create_values, TestCase): """Check the creation of valued arrays (size 1009, UCS2 values)""" ulen = 1009 ucs_value = ucs2_value class test_create_values_1009_ucs4(create_values, TestCase): """Check the creation of valued arrays (size 1009, UCS4 values)""" ulen = 1009 ucs_value = ucs4_value ############################################################ # Assignment tests ############################################################ class assign_values(object): """Check the assignment of unicode arrays with values""" def content_check(self, ua, ua_scalar, nbytes): # Check the length of the unicode base type self.assertTrue(int(ua.dtype.str[2:]) == self.ulen) # Check the length of the data buffer self.assertTrue(buffer_length(ua) == nbytes) # Small check that data in array element is ok self.assertTrue(ua_scalar == self.ucs_value*self.ulen) # Encode to UTF-8 and double check self.assertTrue(ua_scalar.encode('utf-8') == (self.ucs_value*self.ulen).encode('utf-8')) # Check buffer lengths for scalars if ucs4: self.assertTrue(buffer_length(ua_scalar) == 4*self.ulen) else: if self.ucs_value == ucs4_value: # In UCS2, the \U0010FFFF will be represented using a # surrogate *pair* self.assertTrue(buffer_length(ua_scalar) == 2*2*self.ulen) else: # In UCS2, the \uFFFF will be represented using a # regular 2-byte word self.assertTrue(buffer_length(ua_scalar) == 2*self.ulen) def test_values0D(self): # Check assignment of 0-dimensional objects with values ua = np.zeros((), dtype='U%s' % self.ulen) ua[()] = self.ucs_value*self.ulen self.content_check(ua, ua[()], 4*self.ulen) def test_valuesSD(self): # Check assignment of single-dimensional objects with values ua = np.zeros((2,), dtype='U%s' % self.ulen) ua[0] = self.ucs_value*self.ulen self.content_check(ua, ua[0], 4*self.ulen*2) ua[1] = self.ucs_value*self.ulen self.content_check(ua, ua[1], 4*self.ulen*2) def test_valuesMD(self): # Check assignment of multi-dimensional objects with values ua = np.zeros((2, 3, 4), dtype='U%s' % self.ulen) ua[0, 0, 0] = self.ucs_value*self.ulen self.content_check(ua, ua[0, 0, 0], 4*self.ulen*2*3*4) ua[-1, -1, -1] = self.ucs_value*self.ulen self.content_check(ua, ua[-1, -1, -1], 4*self.ulen*2*3*4) class test_assign_values_1_ucs2(assign_values, TestCase): """Check the assignment of valued arrays (size 1, UCS2 values)""" ulen = 1 ucs_value = ucs2_value class test_assign_values_1_ucs4(assign_values, TestCase): """Check the assignment of valued arrays (size 1, UCS4 values)""" ulen = 1 ucs_value = ucs4_value class test_assign_values_2_ucs2(assign_values, TestCase): """Check the assignment of valued arrays (size 2, UCS2 values)""" ulen = 2 ucs_value = ucs2_value class test_assign_values_2_ucs4(assign_values, TestCase): """Check the assignment of valued arrays (size 2, UCS4 values)""" ulen = 2 ucs_value = ucs4_value class test_assign_values_1009_ucs2(assign_values, TestCase): """Check the assignment of valued arrays (size 1009, UCS2 values)""" ulen = 1009 ucs_value = ucs2_value class test_assign_values_1009_ucs4(assign_values, TestCase): """Check the assignment of valued arrays (size 1009, UCS4 values)""" ulen = 1009 ucs_value = ucs4_value ############################################################ # Byteorder tests ############################################################ class byteorder_values: """Check the byteorder of unicode arrays in round-trip conversions""" def test_values0D(self): # Check byteorder of 0-dimensional objects ua = np.array(self.ucs_value*self.ulen, dtype='U%s' % self.ulen) ua2 = ua.newbyteorder() # This changes the interpretation of the data region (but not the # actual data), therefore the returned scalars are not # the same (they are byte-swapped versions of each other). self.assertTrue(ua[()] != ua2[()]) ua3 = ua2.newbyteorder() # Arrays must be equal after the round-trip assert_equal(ua, ua3) def test_valuesSD(self): # Check byteorder of single-dimensional objects ua = np.array([self.ucs_value*self.ulen]*2, dtype='U%s' % self.ulen) ua2 = ua.newbyteorder() self.assertTrue((ua != ua2).all()) self.assertTrue(ua[-1] != ua2[-1]) ua3 = ua2.newbyteorder() # Arrays must be equal after the round-trip assert_equal(ua, ua3) def test_valuesMD(self): # Check byteorder of multi-dimensional objects ua = np.array([[[self.ucs_value*self.ulen]*2]*3]*4, dtype='U%s' % self.ulen) ua2 = ua.newbyteorder() self.assertTrue((ua != ua2).all()) self.assertTrue(ua[-1, -1, -1] != ua2[-1, -1, -1]) ua3 = ua2.newbyteorder() # Arrays must be equal after the round-trip assert_equal(ua, ua3) def test_values_cast(self): # Check byteorder of when casting the array for a strided and # contiguous array: test1 = np.array([self.ucs_value*self.ulen]*2, dtype='U%s' % self.ulen) test2 = np.repeat(test1, 2)[::2] for ua in (test1, test2): ua2 = ua.astype(dtype=ua.dtype.newbyteorder()) self.assertTrue((ua == ua2).all()) self.assertTrue(ua[-1] == ua2[-1]) ua3 = ua2.astype(dtype=ua.dtype) # Arrays must be equal after the round-trip assert_equal(ua, ua3) def test_values_updowncast(self): # Check byteorder of when casting the array to a longer and shorter # string length for strided and contiguous arrays test1 = np.array([self.ucs_value*self.ulen]*2, dtype='U%s' % self.ulen) test2 = np.repeat(test1, 2)[::2] for ua in (test1, test2): # Cast to a longer type with zero padding longer_type = np.dtype('U%s' % (self.ulen+1)).newbyteorder() ua2 = ua.astype(dtype=longer_type) self.assertTrue((ua == ua2).all()) self.assertTrue(ua[-1] == ua2[-1]) # Cast back again with truncating: ua3 = ua2.astype(dtype=ua.dtype) # Arrays must be equal after the round-trip assert_equal(ua, ua3) class test_byteorder_1_ucs2(byteorder_values, TestCase): """Check the byteorder in unicode (size 1, UCS2 values)""" ulen = 1 ucs_value = ucs2_value class test_byteorder_1_ucs4(byteorder_values, TestCase): """Check the byteorder in unicode (size 1, UCS4 values)""" ulen = 1 ucs_value = ucs4_value class test_byteorder_2_ucs2(byteorder_values, TestCase): """Check the byteorder in unicode (size 2, UCS2 values)""" ulen = 2 ucs_value = ucs2_value class test_byteorder_2_ucs4(byteorder_values, TestCase): """Check the byteorder in unicode (size 2, UCS4 values)""" ulen = 2 ucs_value = ucs4_value class test_byteorder_1009_ucs2(byteorder_values, TestCase): """Check the byteorder in unicode (size 1009, UCS2 values)""" ulen = 1009 ucs_value = ucs2_value class test_byteorder_1009_ucs4(byteorder_values, TestCase): """Check the byteorder in unicode (size 1009, UCS4 values)""" ulen = 1009 ucs_value = ucs4_value if __name__ == "__main__": run_module_suite()