# -*- coding: latin-1 -*- ''' Nose test generators Need function load / save / roundtrip tests ''' import os from collections import OrderedDict from os.path import join as pjoin, dirname from glob import glob from io import BytesIO from tempfile import mkdtemp import warnings import shutil import gzip from numpy.testing import (assert_array_equal, assert_array_almost_equal, assert_equal, assert_) from pytest import raises as assert_raises import numpy as np from numpy import array import scipy.sparse as SP import scipy.io.matlab.byteordercodes as boc from scipy.io.matlab.miobase import matdims, MatWriteError, MatReadError from scipy.io.matlab.mio import (mat_reader_factory, loadmat, savemat, whosmat) from scipy.io.matlab.mio5 import (MatlabObject, MatFile5Writer, MatFile5Reader, MatlabFunction, varmats_from_mat, to_writeable, EmptyStructMarker) from scipy.io.matlab import mio5_params as mio5p test_data_path = pjoin(dirname(__file__), 'data') def mlarr(*args, **kwargs): """Convenience function to return matlab-compatible 2-D array.""" arr = np.array(*args, **kwargs) arr.shape = matdims(arr) return arr # Define cases to test theta = np.pi/4*np.arange(9,dtype=float).reshape(1,9) case_table4 = [ {'name': 'double', 'classes': {'testdouble': 'double'}, 'expected': {'testdouble': theta} }] case_table4.append( {'name': 'string', 'classes': {'teststring': 'char'}, 'expected': {'teststring': array(['"Do nine men interpret?" "Nine men," I nod.'])} }) case_table4.append( {'name': 'complex', 'classes': {'testcomplex': 'double'}, 'expected': {'testcomplex': np.cos(theta) + 1j*np.sin(theta)} }) A = np.zeros((3,5)) A[0] = list(range(1,6)) A[:,0] = list(range(1,4)) case_table4.append( {'name': 'matrix', 'classes': {'testmatrix': 'double'}, 'expected': {'testmatrix': A}, }) case_table4.append( {'name': 'sparse', 'classes': {'testsparse': 'sparse'}, 'expected': {'testsparse': SP.coo_matrix(A)}, }) B = A.astype(complex) B[0,0] += 1j case_table4.append( {'name': 'sparsecomplex', 'classes': {'testsparsecomplex': 'sparse'}, 'expected': {'testsparsecomplex': SP.coo_matrix(B)}, }) case_table4.append( {'name': 'multi', 'classes': {'theta': 'double', 'a': 'double'}, 'expected': {'theta': theta, 'a': A}, }) case_table4.append( {'name': 'minus', 'classes': {'testminus': 'double'}, 'expected': {'testminus': mlarr(-1)}, }) case_table4.append( {'name': 'onechar', 'classes': {'testonechar': 'char'}, 'expected': {'testonechar': array(['r'])}, }) # Cell arrays stored as object arrays CA = mlarr(( # tuple for object array creation [], mlarr([1]), mlarr([[1,2]]), mlarr([[1,2,3]])), dtype=object).reshape(1,-1) CA[0,0] = array( ['This cell contains this string and 3 arrays of increasing length']) case_table5 = [ {'name': 'cell', 'classes': {'testcell': 'cell'}, 'expected': {'testcell': CA}}] CAE = mlarr(( # tuple for object array creation mlarr(1), mlarr(2), mlarr([]), mlarr([]), mlarr(3)), dtype=object).reshape(1,-1) objarr = np.empty((1,1),dtype=object) objarr[0,0] = mlarr(1) case_table5.append( {'name': 'scalarcell', 'classes': {'testscalarcell': 'cell'}, 'expected': {'testscalarcell': objarr} }) case_table5.append( {'name': 'emptycell', 'classes': {'testemptycell': 'cell'}, 'expected': {'testemptycell': CAE}}) case_table5.append( {'name': 'stringarray', 'classes': {'teststringarray': 'char'}, 'expected': {'teststringarray': array( ['one ', 'two ', 'three'])}, }) case_table5.append( {'name': '3dmatrix', 'classes': {'test3dmatrix': 'double'}, 'expected': { 'test3dmatrix': np.transpose(np.reshape(list(range(1,25)), (4,3,2)))} }) st_sub_arr = array([np.sqrt(2),np.exp(1),np.pi]).reshape(1,3) dtype = [(n, object) for n in ['stringfield', 'doublefield', 'complexfield']] st1 = np.zeros((1,1), dtype) st1['stringfield'][0,0] = array(['Rats live on no evil star.']) st1['doublefield'][0,0] = st_sub_arr st1['complexfield'][0,0] = st_sub_arr * (1 + 1j) case_table5.append( {'name': 'struct', 'classes': {'teststruct': 'struct'}, 'expected': {'teststruct': st1} }) CN = np.zeros((1,2), dtype=object) CN[0,0] = mlarr(1) CN[0,1] = np.zeros((1,3), dtype=object) CN[0,1][0,0] = mlarr(2, dtype=np.uint8) CN[0,1][0,1] = mlarr([[3]], dtype=np.uint8) CN[0,1][0,2] = np.zeros((1,2), dtype=object) CN[0,1][0,2][0,0] = mlarr(4, dtype=np.uint8) CN[0,1][0,2][0,1] = mlarr(5, dtype=np.uint8) case_table5.append( {'name': 'cellnest', 'classes': {'testcellnest': 'cell'}, 'expected': {'testcellnest': CN}, }) st2 = np.empty((1,1), dtype=[(n, object) for n in ['one', 'two']]) st2[0,0]['one'] = mlarr(1) st2[0,0]['two'] = np.empty((1,1), dtype=[('three', object)]) st2[0,0]['two'][0,0]['three'] = array(['number 3']) case_table5.append( {'name': 'structnest', 'classes': {'teststructnest': 'struct'}, 'expected': {'teststructnest': st2} }) a = np.empty((1,2), dtype=[(n, object) for n in ['one', 'two']]) a[0,0]['one'] = mlarr(1) a[0,0]['two'] = mlarr(2) a[0,1]['one'] = array(['number 1']) a[0,1]['two'] = array(['number 2']) case_table5.append( {'name': 'structarr', 'classes': {'teststructarr': 'struct'}, 'expected': {'teststructarr': a} }) ODT = np.dtype([(n, object) for n in ['expr', 'inputExpr', 'args', 'isEmpty', 'numArgs', 'version']]) MO = MatlabObject(np.zeros((1,1), dtype=ODT), 'inline') m0 = MO[0,0] m0['expr'] = array(['x']) m0['inputExpr'] = array([' x = INLINE_INPUTS_{1};']) m0['args'] = array(['x']) m0['isEmpty'] = mlarr(0) m0['numArgs'] = mlarr(1) m0['version'] = mlarr(1) case_table5.append( {'name': 'object', 'classes': {'testobject': 'object'}, 'expected': {'testobject': MO} }) fp_u_str = open(pjoin(test_data_path, 'japanese_utf8.txt'), 'rb') u_str = fp_u_str.read().decode('utf-8') fp_u_str.close() case_table5.append( {'name': 'unicode', 'classes': {'testunicode': 'char'}, 'expected': {'testunicode': array([u_str])} }) case_table5.append( {'name': 'sparse', 'classes': {'testsparse': 'sparse'}, 'expected': {'testsparse': SP.coo_matrix(A)}, }) case_table5.append( {'name': 'sparsecomplex', 'classes': {'testsparsecomplex': 'sparse'}, 'expected': {'testsparsecomplex': SP.coo_matrix(B)}, }) case_table5.append( {'name': 'bool', 'classes': {'testbools': 'logical'}, 'expected': {'testbools': array([[True], [False]])}, }) case_table5_rt = case_table5[:] # Inline functions can't be concatenated in matlab, so RT only case_table5_rt.append( {'name': 'objectarray', 'classes': {'testobjectarray': 'object'}, 'expected': {'testobjectarray': np.repeat(MO, 2).reshape(1,2)}}) def types_compatible(var1, var2): """Check if types are same or compatible. 0-D numpy scalars are compatible with bare python scalars. """ type1 = type(var1) type2 = type(var2) if type1 is type2: return True if type1 is np.ndarray and var1.shape == (): return type(var1.item()) is type2 if type2 is np.ndarray and var2.shape == (): return type(var2.item()) is type1 return False def _check_level(label, expected, actual): """ Check one level of a potentially nested array """ if SP.issparse(expected): # allow different types of sparse matrices assert_(SP.issparse(actual)) assert_array_almost_equal(actual.todense(), expected.todense(), err_msg=label, decimal=5) return # Check types are as expected assert_(types_compatible(expected, actual), "Expected type %s, got %s at %s" % (type(expected), type(actual), label)) # A field in a record array may not be an ndarray # A scalar from a record array will be type np.void if not isinstance(expected, (np.void, np.ndarray, MatlabObject)): assert_equal(expected, actual) return # This is an ndarray-like thing assert_(expected.shape == actual.shape, msg='Expected shape %s, got %s at %s' % (expected.shape, actual.shape, label)) ex_dtype = expected.dtype if ex_dtype.hasobject: # array of objects if isinstance(expected, MatlabObject): assert_equal(expected.classname, actual.classname) for i, ev in enumerate(expected): level_label = "%s, [%d], " % (label, i) _check_level(level_label, ev, actual[i]) return if ex_dtype.fields: # probably recarray for fn in ex_dtype.fields: level_label = "%s, field %s, " % (label, fn) _check_level(level_label, expected[fn], actual[fn]) return if ex_dtype.type in (str, # string or bool np.unicode_, np.bool_): assert_equal(actual, expected, err_msg=label) return # Something numeric assert_array_almost_equal(actual, expected, err_msg=label, decimal=5) def _load_check_case(name, files, case): for file_name in files: matdict = loadmat(file_name, struct_as_record=True) label = "test %s; file %s" % (name, file_name) for k, expected in case.items(): k_label = "%s, variable %s" % (label, k) assert_(k in matdict, "Missing key at %s" % k_label) _check_level(k_label, expected, matdict[k]) def _whos_check_case(name, files, case, classes): for file_name in files: label = "test %s; file %s" % (name, file_name) whos = whosmat(file_name) expected_whos = [ (k, expected.shape, classes[k]) for k, expected in case.items()] whos.sort() expected_whos.sort() assert_equal(whos, expected_whos, "%s: %r != %r" % (label, whos, expected_whos) ) # Round trip tests def _rt_check_case(name, expected, format): mat_stream = BytesIO() savemat(mat_stream, expected, format=format) mat_stream.seek(0) _load_check_case(name, [mat_stream], expected) # generator for load tests def test_load(): for case in case_table4 + case_table5: name = case['name'] expected = case['expected'] filt = pjoin(test_data_path, 'test%s_*.mat' % name) files = glob(filt) assert_(len(files) > 0, "No files for test %s using filter %s" % (name, filt)) _load_check_case(name, files, expected) # generator for whos tests def test_whos(): for case in case_table4 + case_table5: name = case['name'] expected = case['expected'] classes = case['classes'] filt = pjoin(test_data_path, 'test%s_*.mat' % name) files = glob(filt) assert_(len(files) > 0, "No files for test %s using filter %s" % (name, filt)) _whos_check_case(name, files, expected, classes) # generator for round trip tests def test_round_trip(): for case in case_table4 + case_table5_rt: case_table4_names = [case['name'] for case in case_table4] name = case['name'] + '_round_trip' expected = case['expected'] for format in (['4', '5'] if case['name'] in case_table4_names else ['5']): _rt_check_case(name, expected, format) def test_gzip_simple(): xdense = np.zeros((20,20)) xdense[2,3] = 2.3 xdense[4,5] = 4.5 x = SP.csc_matrix(xdense) name = 'gzip_test' expected = {'x':x} format = '4' tmpdir = mkdtemp() try: fname = pjoin(tmpdir,name) mat_stream = gzip.open(fname, mode='wb') savemat(mat_stream, expected, format=format) mat_stream.close() mat_stream = gzip.open(fname, mode='rb') actual = loadmat(mat_stream, struct_as_record=True) mat_stream.close() finally: shutil.rmtree(tmpdir) assert_array_almost_equal(actual['x'].todense(), expected['x'].todense(), err_msg=repr(actual)) def test_multiple_open(): # Ticket #1039, on Windows: check that files are not left open tmpdir = mkdtemp() try: x = dict(x=np.zeros((2, 2))) fname = pjoin(tmpdir, "a.mat") # Check that file is not left open savemat(fname, x) os.unlink(fname) savemat(fname, x) loadmat(fname) os.unlink(fname) # Check that stream is left open f = open(fname, 'wb') savemat(f, x) f.seek(0) f.close() f = open(fname, 'rb') loadmat(f) f.seek(0) f.close() finally: shutil.rmtree(tmpdir) def test_mat73(): # Check any hdf5 files raise an error filenames = glob( pjoin(test_data_path, 'testhdf5*.mat')) assert_(len(filenames) > 0) for filename in filenames: fp = open(filename, 'rb') assert_raises(NotImplementedError, loadmat, fp, struct_as_record=True) fp.close() def test_warnings(): # This test is an echo of the previous behavior, which was to raise a # warning if the user triggered a search for mat files on the Python system # path. We can remove the test in the next version after upcoming (0.13). fname = pjoin(test_data_path, 'testdouble_7.1_GLNX86.mat') with warnings.catch_warnings(): warnings.simplefilter('error') # This should not generate a warning loadmat(fname, struct_as_record=True) # This neither loadmat(fname, struct_as_record=False) def test_regression_653(): # Saving a dictionary with only invalid keys used to raise an error. Now we # save this as an empty struct in matlab space. sio = BytesIO() savemat(sio, {'d':{1:2}}, format='5') back = loadmat(sio)['d'] # Check we got an empty struct equivalent assert_equal(back.shape, (1,1)) assert_equal(back.dtype, np.dtype(object)) assert_(back[0,0] is None) def test_structname_len(): # Test limit for length of field names in structs lim = 31 fldname = 'a' * lim st1 = np.zeros((1,1), dtype=[(fldname, object)]) savemat(BytesIO(), {'longstruct': st1}, format='5') fldname = 'a' * (lim+1) st1 = np.zeros((1,1), dtype=[(fldname, object)]) assert_raises(ValueError, savemat, BytesIO(), {'longstruct': st1}, format='5') def test_4_and_long_field_names_incompatible(): # Long field names option not supported in 4 my_struct = np.zeros((1,1),dtype=[('my_fieldname',object)]) assert_raises(ValueError, savemat, BytesIO(), {'my_struct':my_struct}, format='4', long_field_names=True) def test_long_field_names(): # Test limit for length of field names in structs lim = 63 fldname = 'a' * lim st1 = np.zeros((1,1), dtype=[(fldname, object)]) savemat(BytesIO(), {'longstruct': st1}, format='5',long_field_names=True) fldname = 'a' * (lim+1) st1 = np.zeros((1,1), dtype=[(fldname, object)]) assert_raises(ValueError, savemat, BytesIO(), {'longstruct': st1}, format='5',long_field_names=True) def test_long_field_names_in_struct(): # Regression test - long_field_names was erased if you passed a struct # within a struct lim = 63 fldname = 'a' * lim cell = np.ndarray((1,2),dtype=object) st1 = np.zeros((1,1), dtype=[(fldname, object)]) cell[0,0] = st1 cell[0,1] = st1 savemat(BytesIO(), {'longstruct': cell}, format='5',long_field_names=True) # # Check to make sure it fails with long field names off # assert_raises(ValueError, savemat, BytesIO(), {'longstruct': cell}, format='5', long_field_names=False) def test_cell_with_one_thing_in_it(): # Regression test - make a cell array that's 1 x 2 and put two # strings in it. It works. Make a cell array that's 1 x 1 and put # a string in it. It should work but, in the old days, it didn't. cells = np.ndarray((1,2),dtype=object) cells[0,0] = 'Hello' cells[0,1] = 'World' savemat(BytesIO(), {'x': cells}, format='5') cells = np.ndarray((1,1),dtype=object) cells[0,0] = 'Hello, world' savemat(BytesIO(), {'x': cells}, format='5') def test_writer_properties(): # Tests getting, setting of properties of matrix writer mfw = MatFile5Writer(BytesIO()) assert_equal(mfw.global_vars, []) mfw.global_vars = ['avar'] assert_equal(mfw.global_vars, ['avar']) assert_equal(mfw.unicode_strings, False) mfw.unicode_strings = True assert_equal(mfw.unicode_strings, True) assert_equal(mfw.long_field_names, False) mfw.long_field_names = True assert_equal(mfw.long_field_names, True) def test_use_small_element(): # Test whether we're using small data element or not sio = BytesIO() wtr = MatFile5Writer(sio) # First check size for no sde for name arr = np.zeros(10) wtr.put_variables({'aaaaa': arr}) w_sz = len(sio.getvalue()) # Check small name results in largish difference in size sio.truncate(0) sio.seek(0) wtr.put_variables({'aaaa': arr}) assert_(w_sz - len(sio.getvalue()) > 4) # Whereas increasing name size makes less difference sio.truncate(0) sio.seek(0) wtr.put_variables({'aaaaaa': arr}) assert_(len(sio.getvalue()) - w_sz < 4) def test_save_dict(): # Test that dict can be saved (as recarray), loaded as matstruct dict_types = ((dict, False), (OrderedDict, True),) ab_exp = np.array([[(1, 2)]], dtype=[('a', object), ('b', object)]) ba_exp = np.array([[(2, 1)]], dtype=[('b', object), ('a', object)]) for dict_type, is_ordered in dict_types: # Initialize with tuples to keep order for OrderedDict d = dict_type([('a', 1), ('b', 2)]) stream = BytesIO() savemat(stream, {'dict': d}) stream.seek(0) vals = loadmat(stream)['dict'] assert_equal(set(vals.dtype.names), set(['a', 'b'])) if is_ordered: # Input was ordered, output in ab order assert_array_equal(vals, ab_exp) else: # Not ordered input, either order output if vals.dtype.names[0] == 'a': assert_array_equal(vals, ab_exp) else: assert_array_equal(vals, ba_exp) def test_1d_shape(): # New 5 behavior is 1D -> row vector arr = np.arange(5) for format in ('4', '5'): # Column is the default stream = BytesIO() savemat(stream, {'oned': arr}, format=format) vals = loadmat(stream) assert_equal(vals['oned'].shape, (1, 5)) # can be explicitly 'column' for oned_as stream = BytesIO() savemat(stream, {'oned':arr}, format=format, oned_as='column') vals = loadmat(stream) assert_equal(vals['oned'].shape, (5,1)) # but different from 'row' stream = BytesIO() savemat(stream, {'oned':arr}, format=format, oned_as='row') vals = loadmat(stream) assert_equal(vals['oned'].shape, (1,5)) def test_compression(): arr = np.zeros(100).reshape((5,20)) arr[2,10] = 1 stream = BytesIO() savemat(stream, {'arr':arr}) raw_len = len(stream.getvalue()) vals = loadmat(stream) assert_array_equal(vals['arr'], arr) stream = BytesIO() savemat(stream, {'arr':arr}, do_compression=True) compressed_len = len(stream.getvalue()) vals = loadmat(stream) assert_array_equal(vals['arr'], arr) assert_(raw_len > compressed_len) # Concatenate, test later arr2 = arr.copy() arr2[0,0] = 1 stream = BytesIO() savemat(stream, {'arr':arr, 'arr2':arr2}, do_compression=False) vals = loadmat(stream) assert_array_equal(vals['arr2'], arr2) stream = BytesIO() savemat(stream, {'arr':arr, 'arr2':arr2}, do_compression=True) vals = loadmat(stream) assert_array_equal(vals['arr2'], arr2) def test_single_object(): stream = BytesIO() savemat(stream, {'A':np.array(1, dtype=object)}) def test_skip_variable(): # Test skipping over the first of two variables in a MAT file # using mat_reader_factory and put_variables to read them in. # # This is a regression test of a problem that's caused by # using the compressed file reader seek instead of the raw file # I/O seek when skipping over a compressed chunk. # # The problem arises when the chunk is large: this file has # a 256x256 array of random (uncompressible) doubles. # filename = pjoin(test_data_path,'test_skip_variable.mat') # # Prove that it loads with loadmat # d = loadmat(filename, struct_as_record=True) assert_('first' in d) assert_('second' in d) # # Make the factory # factory, file_opened = mat_reader_factory(filename, struct_as_record=True) # # This is where the factory breaks with an error in MatMatrixGetter.to_next # d = factory.get_variables('second') assert_('second' in d) factory.mat_stream.close() def test_empty_struct(): # ticket 885 filename = pjoin(test_data_path,'test_empty_struct.mat') # before ticket fix, this would crash with ValueError, empty data # type d = loadmat(filename, struct_as_record=True) a = d['a'] assert_equal(a.shape, (1,1)) assert_equal(a.dtype, np.dtype(object)) assert_(a[0,0] is None) stream = BytesIO() arr = np.array((), dtype='U') # before ticket fix, this used to give data type not understood savemat(stream, {'arr':arr}) d = loadmat(stream) a2 = d['arr'] assert_array_equal(a2, arr) def test_save_empty_dict(): # saving empty dict also gives empty struct stream = BytesIO() savemat(stream, {'arr': {}}) d = loadmat(stream) a = d['arr'] assert_equal(a.shape, (1,1)) assert_equal(a.dtype, np.dtype(object)) assert_(a[0,0] is None) def assert_any_equal(output, alternatives): """ Assert `output` is equal to at least one element in `alternatives` """ one_equal = False for expected in alternatives: if np.all(output == expected): one_equal = True break assert_(one_equal) def test_to_writeable(): # Test to_writeable function res = to_writeable(np.array([1])) # pass through ndarrays assert_equal(res.shape, (1,)) assert_array_equal(res, 1) # Dict fields can be written in any order expected1 = np.array([(1, 2)], dtype=[('a', '|O8'), ('b', '|O8')]) expected2 = np.array([(2, 1)], dtype=[('b', '|O8'), ('a', '|O8')]) alternatives = (expected1, expected2) assert_any_equal(to_writeable({'a':1,'b':2}), alternatives) # Fields with underscores discarded assert_any_equal(to_writeable({'a':1,'b':2, '_c':3}), alternatives) # Not-string fields discarded assert_any_equal(to_writeable({'a':1,'b':2, 100:3}), alternatives) # String fields that are valid Python identifiers discarded assert_any_equal(to_writeable({'a':1,'b':2, '99':3}), alternatives) # Object with field names is equivalent class klass(object): pass c = klass c.a = 1 c.b = 2 assert_any_equal(to_writeable(c), alternatives) # empty list and tuple go to empty array res = to_writeable([]) assert_equal(res.shape, (0,)) assert_equal(res.dtype.type, np.float64) res = to_writeable(()) assert_equal(res.shape, (0,)) assert_equal(res.dtype.type, np.float64) # None -> None assert_(to_writeable(None) is None) # String to strings assert_equal(to_writeable('a string').dtype.type, np.str_) # Scalars to numpy to NumPy scalars res = to_writeable(1) assert_equal(res.shape, ()) assert_equal(res.dtype.type, np.array(1).dtype.type) assert_array_equal(res, 1) # Empty dict returns EmptyStructMarker assert_(to_writeable({}) is EmptyStructMarker) # Object does not have (even empty) __dict__ assert_(to_writeable(object()) is None) # Custom object does have empty __dict__, returns EmptyStructMarker class C(object): pass assert_(to_writeable(c()) is EmptyStructMarker) # dict keys with legal characters are convertible res = to_writeable({'a': 1})['a'] assert_equal(res.shape, (1,)) assert_equal(res.dtype.type, np.object_) # Only fields with illegal characters, falls back to EmptyStruct assert_(to_writeable({'1':1}) is EmptyStructMarker) assert_(to_writeable({'_a':1}) is EmptyStructMarker) # Unless there are valid fields, in which case structured array assert_equal(to_writeable({'1':1, 'f': 2}), np.array([(2,)], dtype=[('f', '|O8')])) def test_recarray(): # check roundtrip of structured array dt = [('f1', 'f8'), ('f2', 'S10')] arr = np.zeros((2,), dtype=dt) arr[0]['f1'] = 0.5 arr[0]['f2'] = 'python' arr[1]['f1'] = 99 arr[1]['f2'] = 'not perl' stream = BytesIO() savemat(stream, {'arr': arr}) d = loadmat(stream, struct_as_record=False) a20 = d['arr'][0,0] assert_equal(a20.f1, 0.5) assert_equal(a20.f2, 'python') d = loadmat(stream, struct_as_record=True) a20 = d['arr'][0,0] assert_equal(a20['f1'], 0.5) assert_equal(a20['f2'], 'python') # structs always come back as object types assert_equal(a20.dtype, np.dtype([('f1', 'O'), ('f2', 'O')])) a21 = d['arr'].flat[1] assert_equal(a21['f1'], 99) assert_equal(a21['f2'], 'not perl') def test_save_object(): class C(object): pass c = C() c.field1 = 1 c.field2 = 'a string' stream = BytesIO() savemat(stream, {'c': c}) d = loadmat(stream, struct_as_record=False) c2 = d['c'][0,0] assert_equal(c2.field1, 1) assert_equal(c2.field2, 'a string') d = loadmat(stream, struct_as_record=True) c2 = d['c'][0,0] assert_equal(c2['field1'], 1) assert_equal(c2['field2'], 'a string') def test_read_opts(): # tests if read is seeing option sets, at initialization and after # initialization arr = np.arange(6).reshape(1,6) stream = BytesIO() savemat(stream, {'a': arr}) rdr = MatFile5Reader(stream) back_dict = rdr.get_variables() rarr = back_dict['a'] assert_array_equal(rarr, arr) rdr = MatFile5Reader(stream, squeeze_me=True) assert_array_equal(rdr.get_variables()['a'], arr.reshape((6,))) rdr.squeeze_me = False assert_array_equal(rarr, arr) rdr = MatFile5Reader(stream, byte_order=boc.native_code) assert_array_equal(rdr.get_variables()['a'], arr) # inverted byte code leads to error on read because of swapped # header etc. rdr = MatFile5Reader(stream, byte_order=boc.swapped_code) assert_raises(Exception, rdr.get_variables) rdr.byte_order = boc.native_code assert_array_equal(rdr.get_variables()['a'], arr) arr = np.array(['a string']) stream.truncate(0) stream.seek(0) savemat(stream, {'a': arr}) rdr = MatFile5Reader(stream) assert_array_equal(rdr.get_variables()['a'], arr) rdr = MatFile5Reader(stream, chars_as_strings=False) carr = np.atleast_2d(np.array(list(arr.item()), dtype='U1')) assert_array_equal(rdr.get_variables()['a'], carr) rdr.chars_as_strings = True assert_array_equal(rdr.get_variables()['a'], arr) def test_empty_string(): # make sure reading empty string does not raise error estring_fname = pjoin(test_data_path, 'single_empty_string.mat') fp = open(estring_fname, 'rb') rdr = MatFile5Reader(fp) d = rdr.get_variables() fp.close() assert_array_equal(d['a'], np.array([], dtype='U1')) # Empty string round trip. Matlab cannot distinguish # between a string array that is empty, and a string array # containing a single empty string, because it stores strings as # arrays of char. There is no way of having an array of char that # is not empty, but contains an empty string. stream = BytesIO() savemat(stream, {'a': np.array([''])}) rdr = MatFile5Reader(stream) d = rdr.get_variables() assert_array_equal(d['a'], np.array([], dtype='U1')) stream.truncate(0) stream.seek(0) savemat(stream, {'a': np.array([], dtype='U1')}) rdr = MatFile5Reader(stream) d = rdr.get_variables() assert_array_equal(d['a'], np.array([], dtype='U1')) stream.close() def test_corrupted_data(): import zlib for exc, fname in [(ValueError, 'corrupted_zlib_data.mat'), (zlib.error, 'corrupted_zlib_checksum.mat')]: with open(pjoin(test_data_path, fname), 'rb') as fp: rdr = MatFile5Reader(fp) assert_raises(exc, rdr.get_variables) def test_corrupted_data_check_can_be_disabled(): with open(pjoin(test_data_path, 'corrupted_zlib_data.mat'), 'rb') as fp: rdr = MatFile5Reader(fp, verify_compressed_data_integrity=False) rdr.get_variables() def test_read_both_endian(): # make sure big- and little- endian data is read correctly for fname in ('big_endian.mat', 'little_endian.mat'): fp = open(pjoin(test_data_path, fname), 'rb') rdr = MatFile5Reader(fp) d = rdr.get_variables() fp.close() assert_array_equal(d['strings'], np.array([['hello'], ['world']], dtype=object)) assert_array_equal(d['floats'], np.array([[2., 3.], [3., 4.]], dtype=np.float32)) def test_write_opposite_endian(): # We don't support writing opposite endian .mat files, but we need to behave # correctly if the user supplies an other-endian NumPy array to write out. float_arr = np.array([[2., 3.], [3., 4.]]) int_arr = np.arange(6).reshape((2, 3)) uni_arr = np.array(['hello', 'world'], dtype='U') stream = BytesIO() savemat(stream, {'floats': float_arr.byteswap().newbyteorder(), 'ints': int_arr.byteswap().newbyteorder(), 'uni_arr': uni_arr.byteswap().newbyteorder()}) rdr = MatFile5Reader(stream) d = rdr.get_variables() assert_array_equal(d['floats'], float_arr) assert_array_equal(d['ints'], int_arr) assert_array_equal(d['uni_arr'], uni_arr) stream.close() def test_logical_array(): # The roundtrip test doesn't verify that we load the data up with the # correct (bool) dtype with open(pjoin(test_data_path, 'testbool_8_WIN64.mat'), 'rb') as fobj: rdr = MatFile5Reader(fobj, mat_dtype=True) d = rdr.get_variables() x = np.array([[True], [False]], dtype=np.bool_) assert_array_equal(d['testbools'], x) assert_equal(d['testbools'].dtype, x.dtype) def test_logical_out_type(): # Confirm that bool type written as uint8, uint8 class # See gh-4022 stream = BytesIO() barr = np.array([False, True, False]) savemat(stream, {'barray': barr}) stream.seek(0) reader = MatFile5Reader(stream) reader.initialize_read() reader.read_file_header() hdr, _ = reader.read_var_header() assert_equal(hdr.mclass, mio5p.mxUINT8_CLASS) assert_equal(hdr.is_logical, True) var = reader.read_var_array(hdr, False) assert_equal(var.dtype.type, np.uint8) def test_mat4_3d(): # test behavior when writing 3-D arrays to matlab 4 files stream = BytesIO() arr = np.arange(24).reshape((2,3,4)) assert_raises(ValueError, savemat, stream, {'a': arr}, True, '4') def test_func_read(): func_eg = pjoin(test_data_path, 'testfunc_7.4_GLNX86.mat') fp = open(func_eg, 'rb') rdr = MatFile5Reader(fp) d = rdr.get_variables() fp.close() assert_(isinstance(d['testfunc'], MatlabFunction)) stream = BytesIO() wtr = MatFile5Writer(stream) assert_raises(MatWriteError, wtr.put_variables, d) def test_mat_dtype(): double_eg = pjoin(test_data_path, 'testmatrix_6.1_SOL2.mat') fp = open(double_eg, 'rb') rdr = MatFile5Reader(fp, mat_dtype=False) d = rdr.get_variables() fp.close() assert_equal(d['testmatrix'].dtype.kind, 'u') fp = open(double_eg, 'rb') rdr = MatFile5Reader(fp, mat_dtype=True) d = rdr.get_variables() fp.close() assert_equal(d['testmatrix'].dtype.kind, 'f') def test_sparse_in_struct(): # reproduces bug found by DC where Cython code was insisting on # ndarray return type, but getting sparse matrix st = {'sparsefield': SP.coo_matrix(np.eye(4))} stream = BytesIO() savemat(stream, {'a':st}) d = loadmat(stream, struct_as_record=True) assert_array_equal(d['a'][0,0]['sparsefield'].todense(), np.eye(4)) def test_mat_struct_squeeze(): stream = BytesIO() in_d = {'st':{'one':1, 'two':2}} savemat(stream, in_d) # no error without squeeze loadmat(stream, struct_as_record=False) # previous error was with squeeze, with mat_struct loadmat(stream, struct_as_record=False, squeeze_me=True) def test_scalar_squeeze(): stream = BytesIO() in_d = {'scalar': [[0.1]], 'string': 'my name', 'st':{'one':1, 'two':2}} savemat(stream, in_d) out_d = loadmat(stream, squeeze_me=True) assert_(isinstance(out_d['scalar'], float)) assert_(isinstance(out_d['string'], str)) assert_(isinstance(out_d['st'], np.ndarray)) def test_str_round(): # from report by Angus McMorland on mailing list 3 May 2010 stream = BytesIO() in_arr = np.array(['Hello', 'Foob']) out_arr = np.array(['Hello', 'Foob ']) savemat(stream, dict(a=in_arr)) res = loadmat(stream) # resulted in ['HloolFoa', 'elWrdobr'] assert_array_equal(res['a'], out_arr) stream.truncate(0) stream.seek(0) # Make Fortran ordered version of string in_str = in_arr.tobytes(order='F') in_from_str = np.ndarray(shape=a.shape, dtype=in_arr.dtype, order='F', buffer=in_str) savemat(stream, dict(a=in_from_str)) assert_array_equal(res['a'], out_arr) # unicode save did lead to buffer too small error stream.truncate(0) stream.seek(0) in_arr_u = in_arr.astype('U') out_arr_u = out_arr.astype('U') savemat(stream, {'a': in_arr_u}) res = loadmat(stream) assert_array_equal(res['a'], out_arr_u) def test_fieldnames(): # Check that field names are as expected stream = BytesIO() savemat(stream, {'a': {'a':1, 'b':2}}) res = loadmat(stream) field_names = res['a'].dtype.names assert_equal(set(field_names), set(('a', 'b'))) def test_loadmat_varnames(): # Test that we can get just one variable from a mat file using loadmat mat5_sys_names = ['__globals__', '__header__', '__version__'] for eg_file, sys_v_names in ( (pjoin(test_data_path, 'testmulti_4.2c_SOL2.mat'), []), (pjoin( test_data_path, 'testmulti_7.4_GLNX86.mat'), mat5_sys_names)): vars = loadmat(eg_file) assert_equal(set(vars.keys()), set(['a', 'theta'] + sys_v_names)) vars = loadmat(eg_file, variable_names='a') assert_equal(set(vars.keys()), set(['a'] + sys_v_names)) vars = loadmat(eg_file, variable_names=['a']) assert_equal(set(vars.keys()), set(['a'] + sys_v_names)) vars = loadmat(eg_file, variable_names=['theta']) assert_equal(set(vars.keys()), set(['theta'] + sys_v_names)) vars = loadmat(eg_file, variable_names=('theta',)) assert_equal(set(vars.keys()), set(['theta'] + sys_v_names)) vars = loadmat(eg_file, variable_names=[]) assert_equal(set(vars.keys()), set(sys_v_names)) vnames = ['theta'] vars = loadmat(eg_file, variable_names=vnames) assert_equal(vnames, ['theta']) def test_round_types(): # Check that saving, loading preserves dtype in most cases arr = np.arange(10) stream = BytesIO() for dts in ('f8','f4','i8','i4','i2','i1', 'u8','u4','u2','u1','c16','c8'): stream.truncate(0) stream.seek(0) # needed for BytesIO in Python 3 savemat(stream, {'arr': arr.astype(dts)}) vars = loadmat(stream) assert_equal(np.dtype(dts), vars['arr'].dtype) def test_varmats_from_mat(): # Make a mat file with several variables, write it, read it back names_vars = (('arr', mlarr(np.arange(10))), ('mystr', mlarr('a string')), ('mynum', mlarr(10))) # Dict like thing to give variables in defined order class C(object): def items(self): return names_vars stream = BytesIO() savemat(stream, C()) varmats = varmats_from_mat(stream) assert_equal(len(varmats), 3) for i in range(3): name, var_stream = varmats[i] exp_name, exp_res = names_vars[i] assert_equal(name, exp_name) res = loadmat(var_stream) assert_array_equal(res[name], exp_res) def test_one_by_zero(): # Test 1x0 chars get read correctly func_eg = pjoin(test_data_path, 'one_by_zero_char.mat') fp = open(func_eg, 'rb') rdr = MatFile5Reader(fp) d = rdr.get_variables() fp.close() assert_equal(d['var'].shape, (0,)) def test_load_mat4_le(): # We were getting byte order wrong when reading little-endian floa64 dense # matrices on big-endian platforms mat4_fname = pjoin(test_data_path, 'test_mat4_le_floats.mat') vars = loadmat(mat4_fname) assert_array_equal(vars['a'], [[0.1, 1.2]]) def test_unicode_mat4(): # Mat4 should save unicode as latin1 bio = BytesIO() var = {'second_cat': 'Schrödinger'} savemat(bio, var, format='4') var_back = loadmat(bio) assert_equal(var_back['second_cat'], var['second_cat']) def test_logical_sparse(): # Test we can read logical sparse stored in mat file as bytes. # See https://github.com/scipy/scipy/issues/3539. # In some files saved by MATLAB, the sparse data elements (Real Part # Subelement in MATLAB speak) are stored with apparent type double # (miDOUBLE) but are in fact single bytes. filename = pjoin(test_data_path,'logical_sparse.mat') # Before fix, this would crash with: # ValueError: indices and data should have the same size d = loadmat(filename, struct_as_record=True) log_sp = d['sp_log_5_4'] assert_(isinstance(log_sp, SP.csc_matrix)) assert_equal(log_sp.dtype.type, np.bool_) assert_array_equal(log_sp.toarray(), [[True, True, True, False], [False, False, True, False], [False, False, True, False], [False, False, False, False], [False, False, False, False]]) def test_empty_sparse(): # Can we read empty sparse matrices? sio = BytesIO() import scipy.sparse empty_sparse = scipy.sparse.csr_matrix([[0,0],[0,0]]) savemat(sio, dict(x=empty_sparse)) sio.seek(0) res = loadmat(sio) assert_array_equal(res['x'].shape, empty_sparse.shape) assert_array_equal(res['x'].todense(), 0) # Do empty sparse matrices get written with max nnz 1? # See https://github.com/scipy/scipy/issues/4208 sio.seek(0) reader = MatFile5Reader(sio) reader.initialize_read() reader.read_file_header() hdr, _ = reader.read_var_header() assert_equal(hdr.nzmax, 1) def test_empty_mat_error(): # Test we get a specific warning for an empty mat file sio = BytesIO() assert_raises(MatReadError, loadmat, sio) def test_miuint32_compromise(): # Reader should accept miUINT32 for miINT32, but check signs # mat file with miUINT32 for miINT32, but OK values filename = pjoin(test_data_path, 'miuint32_for_miint32.mat') res = loadmat(filename) assert_equal(res['an_array'], np.arange(10)[None, :]) # mat file with miUINT32 for miINT32, with negative value filename = pjoin(test_data_path, 'bad_miuint32.mat') with assert_raises(ValueError): loadmat(filename) def test_miutf8_for_miint8_compromise(): # Check reader accepts ascii as miUTF8 for array names filename = pjoin(test_data_path, 'miutf8_array_name.mat') res = loadmat(filename) assert_equal(res['array_name'], [[1]]) # mat file with non-ascii utf8 name raises error filename = pjoin(test_data_path, 'bad_miutf8_array_name.mat') with assert_raises(ValueError): loadmat(filename) def test_bad_utf8(): # Check that reader reads bad UTF with 'replace' option filename = pjoin(test_data_path,'broken_utf8.mat') res = loadmat(filename) assert_equal(res['bad_string'], b'\x80 am broken'.decode('utf8', 'replace')) def test_save_unicode_field(tmpdir): filename = os.path.join(str(tmpdir), 'test.mat') test_dict = {u'a':{u'b':1,u'c':'test_str'}} savemat(filename, test_dict) def test_filenotfound(): # Check the correct error is thrown assert_raises(IOError, loadmat, "NotExistentFile00.mat") assert_raises(IOError, loadmat, "NotExistentFile00") def test_simplify_cells(): # Test output when simplify_cells=True filename = pjoin(test_data_path, 'testsimplecell.mat') res1 = loadmat(filename, simplify_cells=True) res2 = loadmat(filename, simplify_cells=False) assert_(isinstance(res1["s"], dict)) assert_(isinstance(res2["s"], np.ndarray)) assert_array_equal(res1["s"]["mycell"], np.array(["a", "b", "c"]))