ext/pybind11/tests/test_numpy_dtypes.py - public/gem5 - Git at Google

 # -*- coding: utf-8 -*-
 import re

 import pytest

 import env  # noqa: F401

 from pybind11_tests import numpy_dtypes as m

 np = pytest.importorskip("numpy")


 @pytest.fixture(scope="module")
 def simple_dtype():
     ld = np.dtype("longdouble")
     return np.dtype(
         {
             "names": ["bool_", "uint_", "float_", "ldbl_"],
             "formats": ["?", "u4", "f4", "f{}".format(ld.itemsize)],
             "offsets": [0, 4, 8, (16 if ld.alignment > 4 else 12)],
         }
     )


 @pytest.fixture(scope="module")
 def packed_dtype():
     return np.dtype([("bool_", "?"), ("uint_", "u4"), ("float_", "f4"), ("ldbl_", "g")])


 def dt_fmt():
     from sys import byteorder

     e = "<" if byteorder == "little" else ">"
     return (
         "{{'names':['bool_','uint_','float_','ldbl_'],"
         " 'formats':['?','" + e + "u4','" + e + "f4','" + e + "f{}'],"
         " 'offsets':[0,4,8,{}], 'itemsize':{}}}"
     )


 def simple_dtype_fmt():
     ld = np.dtype("longdouble")
     simple_ld_off = 12 + 4 * (ld.alignment > 4)
     return dt_fmt().format(ld.itemsize, simple_ld_off, simple_ld_off + ld.itemsize)


 def packed_dtype_fmt():
     from sys import byteorder

     return "[('bool_', '?'), ('uint_', '{e}u4'), ('float_', '{e}f4'), ('ldbl_', '{e}f{}')]".format(
         np.dtype("longdouble").itemsize, e="<" if byteorder == "little" else ">"
     )


 def partial_ld_offset():
     return (
         12
         + 4 * (np.dtype("uint64").alignment > 4)
         + 8
         + 8 * (np.dtype("longdouble").alignment > 8)
     )


 def partial_dtype_fmt():
     ld = np.dtype("longdouble")
     partial_ld_off = partial_ld_offset()
     return dt_fmt().format(ld.itemsize, partial_ld_off, partial_ld_off + ld.itemsize)


 def partial_nested_fmt():
     ld = np.dtype("longdouble")
     partial_nested_off = 8 + 8 * (ld.alignment > 8)
     partial_ld_off = partial_ld_offset()
     partial_nested_size = partial_nested_off * 2 + partial_ld_off + ld.itemsize
     return "{{'names':['a'], 'formats':[{}], 'offsets':[{}], 'itemsize':{}}}".format(
         partial_dtype_fmt(), partial_nested_off, partial_nested_size
     )


 def assert_equal(actual, expected_data, expected_dtype):
     np.testing.assert_equal(actual, np.array(expected_data, dtype=expected_dtype))


 def test_format_descriptors():
     with pytest.raises(RuntimeError) as excinfo:
         m.get_format_unbound()
     assert re.match(
         "^NumPy type info missing for .*UnboundStruct.*$", str(excinfo.value)
     )

     ld = np.dtype("longdouble")
     ldbl_fmt = ("4x" if ld.alignment > 4 else "") + ld.char
     ss_fmt = "^T{?:bool_:3xI:uint_:f:float_:" + ldbl_fmt + ":ldbl_:}"
     dbl = np.dtype("double")
     partial_fmt = (
         "^T{?:bool_:3xI:uint_:f:float_:"
         + str(4 * (dbl.alignment > 4) + dbl.itemsize + 8 * (ld.alignment > 8))
         + "xg:ldbl_:}"
     )
     nested_extra = str(max(8, ld.alignment))
     assert m.print_format_descriptors() == [
         ss_fmt,
         "^T{?:bool_:I:uint_:f:float_:g:ldbl_:}",
         "^T{" + ss_fmt + ":a:^T{?:bool_:I:uint_:f:float_:g:ldbl_:}:b:}",
         partial_fmt,
         "^T{" + nested_extra + "x" + partial_fmt + ":a:" + nested_extra + "x}",
         "^T{3s:a:3s:b:}",
         "^T{(3)4s:a:(2)i:b:(3)B:c:1x(4, 2)f:d:}",
         "^T{q:e1:B:e2:}",
         "^T{Zf:cflt:Zd:cdbl:}",
     ]


 def test_dtype(simple_dtype):
     from sys import byteorder

     e = "<" if byteorder == "little" else ">"

     assert m.print_dtypes() == [
         simple_dtype_fmt(),
         packed_dtype_fmt(),
         "[('a', {}), ('b', {})]".format(simple_dtype_fmt(), packed_dtype_fmt()),
         partial_dtype_fmt(),
         partial_nested_fmt(),
         "[('a', 'S3'), ('b', 'S3')]",
         (
             "{{'names':['a','b','c','d'], "
             + "'formats':[('S4', (3,)),('"
             + e
             + "i4', (2,)),('u1', (3,)),('"
             + e
             + "f4', (4, 2))], "
             + "'offsets':[0,12,20,24], 'itemsize':56}}"
         ).format(e=e),
         "[('e1', '" + e + "i8'), ('e2', 'u1')]",
         "[('x', 'i1'), ('y', '" + e + "u8')]",
         "[('cflt', '" + e + "c8'), ('cdbl', '" + e + "c16')]",
     ]

     d1 = np.dtype(
         {
             "names": ["a", "b"],
             "formats": ["int32", "float64"],
             "offsets": [1, 10],
             "itemsize": 20,
         }
     )
     d2 = np.dtype([("a", "i4"), ("b", "f4")])
     assert m.test_dtype_ctors() == [
         np.dtype("int32"),
         np.dtype("float64"),
         np.dtype("bool"),
         d1,
         d1,
         np.dtype("uint32"),
         d2,
     ]

     assert m.test_dtype_methods() == [
         np.dtype("int32"),
         simple_dtype,
         False,
         True,
         np.dtype("int32").itemsize,
         simple_dtype.itemsize,
     ]

     assert m.trailing_padding_dtype() == m.buffer_to_dtype(
         np.zeros(1, m.trailing_padding_dtype())
     )


 def test_recarray(simple_dtype, packed_dtype):
     elements = [(False, 0, 0.0, -0.0), (True, 1, 1.5, -2.5), (False, 2, 3.0, -5.0)]

     for func, dtype in [
         (m.create_rec_simple, simple_dtype),
         (m.create_rec_packed, packed_dtype),
     ]:
         arr = func(0)
         assert arr.dtype == dtype
         assert_equal(arr, [], simple_dtype)
         assert_equal(arr, [], packed_dtype)

         arr = func(3)
         assert arr.dtype == dtype
         assert_equal(arr, elements, simple_dtype)
         assert_equal(arr, elements, packed_dtype)

         # Show what recarray's look like in NumPy.
         assert type(arr[0]) == np.void
         assert type(arr[0].item()) == tuple

         if dtype == simple_dtype:
             assert m.print_rec_simple(arr) == [
                 "s:0,0,0,-0",
                 "s:1,1,1.5,-2.5",
                 "s:0,2,3,-5",
             ]
         else:
             assert m.print_rec_packed(arr) == [
                 "p:0,0,0,-0",
                 "p:1,1,1.5,-2.5",
                 "p:0,2,3,-5",
             ]

     nested_dtype = np.dtype([("a", simple_dtype), ("b", packed_dtype)])

     arr = m.create_rec_nested(0)
     assert arr.dtype == nested_dtype
     assert_equal(arr, [], nested_dtype)

     arr = m.create_rec_nested(3)
     assert arr.dtype == nested_dtype
     assert_equal(
         arr,
         [
             ((False, 0, 0.0, -0.0), (True, 1, 1.5, -2.5)),
             ((True, 1, 1.5, -2.5), (False, 2, 3.0, -5.0)),
             ((False, 2, 3.0, -5.0), (True, 3, 4.5, -7.5)),
         ],
         nested_dtype,
     )
     assert m.print_rec_nested(arr) == [
         "n:a=s:0,0,0,-0;b=p:1,1,1.5,-2.5",
         "n:a=s:1,1,1.5,-2.5;b=p:0,2,3,-5",
         "n:a=s:0,2,3,-5;b=p:1,3,4.5,-7.5",
     ]

     arr = m.create_rec_partial(3)
     assert str(arr.dtype) == partial_dtype_fmt()
     partial_dtype = arr.dtype
     assert "" not in arr.dtype.fields
     assert partial_dtype.itemsize > simple_dtype.itemsize
     assert_equal(arr, elements, simple_dtype)
     assert_equal(arr, elements, packed_dtype)

     arr = m.create_rec_partial_nested(3)
     assert str(arr.dtype) == partial_nested_fmt()
     assert "" not in arr.dtype.fields
     assert "" not in arr.dtype.fields["a"][0].fields
     assert arr.dtype.itemsize > partial_dtype.itemsize
     np.testing.assert_equal(arr["a"], m.create_rec_partial(3))


 def test_array_constructors():
     data = np.arange(1, 7, dtype="int32")
     for i in range(8):
         np.testing.assert_array_equal(m.test_array_ctors(10 + i), data.reshape((3, 2)))
         np.testing.assert_array_equal(m.test_array_ctors(20 + i), data.reshape((3, 2)))
     for i in range(5):
         np.testing.assert_array_equal(m.test_array_ctors(30 + i), data)
         np.testing.assert_array_equal(m.test_array_ctors(40 + i), data)


 def test_string_array():
     arr = m.create_string_array(True)
     assert str(arr.dtype) == "[('a', 'S3'), ('b', 'S3')]"
     assert m.print_string_array(arr) == [
         "a='',b=''",
         "a='a',b='a'",
         "a='ab',b='ab'",
         "a='abc',b='abc'",
     ]
     dtype = arr.dtype
     assert arr["a"].tolist() == [b"", b"a", b"ab", b"abc"]
     assert arr["b"].tolist() == [b"", b"a", b"ab", b"abc"]
     arr = m.create_string_array(False)
     assert dtype == arr.dtype


 def test_array_array():
     from sys import byteorder

     e = "<" if byteorder == "little" else ">"

     arr = m.create_array_array(3)
     assert str(arr.dtype) == (
         "{{'names':['a','b','c','d'], "
         + "'formats':[('S4', (3,)),('"
         + e
         + "i4', (2,)),('u1', (3,)),('{e}f4', (4, 2))], "
         + "'offsets':[0,12,20,24], 'itemsize':56}}"
     ).format(e=e)
     assert m.print_array_array(arr) == [
         "a={{A,B,C,D},{K,L,M,N},{U,V,W,X}},b={0,1},"
         + "c={0,1,2},d={{0,1},{10,11},{20,21},{30,31}}",
         "a={{W,X,Y,Z},{G,H,I,J},{Q,R,S,T}},b={1000,1001},"
         + "c={10,11,12},d={{100,101},{110,111},{120,121},{130,131}}",
         "a={{S,T,U,V},{C,D,E,F},{M,N,O,P}},b={2000,2001},"
         + "c={20,21,22},d={{200,201},{210,211},{220,221},{230,231}}",
     ]
     assert arr["a"].tolist() == [
         [b"ABCD", b"KLMN", b"UVWX"],
         [b"WXYZ", b"GHIJ", b"QRST"],
         [b"STUV", b"CDEF", b"MNOP"],
     ]
     assert arr["b"].tolist() == [[0, 1], [1000, 1001], [2000, 2001]]
     assert m.create_array_array(0).dtype == arr.dtype


 def test_enum_array():
     from sys import byteorder

     e = "<" if byteorder == "little" else ">"

     arr = m.create_enum_array(3)
     dtype = arr.dtype
     assert dtype == np.dtype([("e1", e + "i8"), ("e2", "u1")])
     assert m.print_enum_array(arr) == ["e1=A,e2=X", "e1=B,e2=Y", "e1=A,e2=X"]
     assert arr["e1"].tolist() == [-1, 1, -1]
     assert arr["e2"].tolist() == [1, 2, 1]
     assert m.create_enum_array(0).dtype == dtype


 def test_complex_array():
     from sys import byteorder

     e = "<" if byteorder == "little" else ">"

     arr = m.create_complex_array(3)
     dtype = arr.dtype
     assert dtype == np.dtype([("cflt", e + "c8"), ("cdbl", e + "c16")])
     assert m.print_complex_array(arr) == [
         "c:(0,0.25),(0.5,0.75)",
         "c:(1,1.25),(1.5,1.75)",
         "c:(2,2.25),(2.5,2.75)",
     ]
     assert arr["cflt"].tolist() == [0.0 + 0.25j, 1.0 + 1.25j, 2.0 + 2.25j]
     assert arr["cdbl"].tolist() == [0.5 + 0.75j, 1.5 + 1.75j, 2.5 + 2.75j]
     assert m.create_complex_array(0).dtype == dtype


 def test_signature(doc):
     assert (
         doc(m.create_rec_nested)
         == "create_rec_nested(arg0: int) -> numpy.ndarray[NestedStruct]"
     )


 def test_scalar_conversion():
     n = 3
     arrays = [
         m.create_rec_simple(n),
         m.create_rec_packed(n),
         m.create_rec_nested(n),
         m.create_enum_array(n),
     ]
     funcs = [m.f_simple, m.f_packed, m.f_nested]

     for i, func in enumerate(funcs):
         for j, arr in enumerate(arrays):
             if i == j and i < 2:
                 assert [func(arr[k]) for k in range(n)] == [k * 10 for k in range(n)]
             else:
                 with pytest.raises(TypeError) as excinfo:
                     func(arr[0])
                 assert "incompatible function arguments" in str(excinfo.value)


 def test_vectorize():
     n = 3
     array = m.create_rec_simple(n)
     values = m.f_simple_vectorized(array)
     np.testing.assert_array_equal(values, [0, 10, 20])
     array_2 = m.f_simple_pass_thru_vectorized(array)
     np.testing.assert_array_equal(array, array_2)


 def test_cls_and_dtype_conversion(simple_dtype):
     s = m.SimpleStruct()
     assert s.astuple() == (False, 0, 0.0, 0.0)
     assert m.SimpleStruct.fromtuple(s.astuple()).astuple() == s.astuple()

     s.uint_ = 2
     assert m.f_simple(s) == 20

     # Try as recarray of shape==(1,).
     s_recarray = np.array([(False, 2, 0.0, 0.0)], dtype=simple_dtype)
     # Show that this will work for vectorized case.
     np.testing.assert_array_equal(m.f_simple_vectorized(s_recarray), [20])

     # Show as a scalar that inherits from np.generic.
     s_scalar = s_recarray[0]
     assert isinstance(s_scalar, np.void)
     assert m.f_simple(s_scalar) == 20

     # Show that an *array* scalar (np.ndarray.shape == ()) does not convert.
     # More specifically, conversion to SimpleStruct is not implicit.
     s_recarray_scalar = s_recarray.reshape(())
     assert isinstance(s_recarray_scalar, np.ndarray)
     assert s_recarray_scalar.dtype == simple_dtype
     with pytest.raises(TypeError) as excinfo:
         m.f_simple(s_recarray_scalar)
     assert "incompatible function arguments" in str(excinfo.value)
     # Explicitly convert to m.SimpleStruct.
     assert m.f_simple(m.SimpleStruct.fromtuple(s_recarray_scalar.item())) == 20

     # Show that an array of dtype=object does *not* convert.
     s_array_object = np.array([s])
     assert s_array_object.dtype == object
     with pytest.raises(TypeError) as excinfo:
         m.f_simple_vectorized(s_array_object)
     assert "incompatible function arguments" in str(excinfo.value)
     # Explicitly convert to `np.array(..., dtype=simple_dtype)`
     s_array = np.array([s.astuple()], dtype=simple_dtype)
     np.testing.assert_array_equal(m.f_simple_vectorized(s_array), [20])


 def test_register_dtype():
     with pytest.raises(RuntimeError) as excinfo:
         m.register_dtype()
     assert "dtype is already registered" in str(excinfo.value)


 @pytest.mark.xfail("env.PYPY")
 def test_str_leak():
     from sys import getrefcount

     fmt = "f4"
     pytest.gc_collect()
     start = getrefcount(fmt)
     d = m.dtype_wrapper(fmt)
     assert d is np.dtype("f4")
     del d
     pytest.gc_collect()
     assert getrefcount(fmt) == start


 def test_compare_buffer_info():
     assert all(m.compare_buffer_info())
	# -- coding: utf-8 --
	import re

	import pytest

	import env # noqa: F401

	from pybind11_tests import numpy_dtypes as m

	np = pytest.importorskip("numpy")


	@pytest.fixture(scope="module")
	def simple_dtype():
	ld = np.dtype("longdouble")
	return np.dtype(
	{
	"names": ["bool_", "uint_", "float_", "ldbl_"],
	"formats": ["?", "u4", "f4", "f{}".format(ld.itemsize)],
	"offsets": [0, 4, 8, (16 if ld.alignment > 4 else 12)],
	}
	)


	@pytest.fixture(scope="module")
	def packed_dtype():
	return np.dtype([("bool_", "?"), ("uint_", "u4"), ("float_", "f4"), ("ldbl_", "g")])


	def dt_fmt():
	from sys import byteorder

	e = "<" if byteorder == "little" else ">"
	return (
	"{{'names':['bool_','uint_','float_','ldbl_'],"
	" 'formats':['?','" + e + "u4','" + e + "f4','" + e + "f{}'],"
	" 'offsets':[0,4,8,{}], 'itemsize':{}}}"
	)


	def simple_dtype_fmt():
	ld = np.dtype("longdouble")
	simple_ld_off = 12 + 4 * (ld.alignment > 4)
	return dt_fmt().format(ld.itemsize, simple_ld_off, simple_ld_off + ld.itemsize)


	def packed_dtype_fmt():
	from sys import byteorder

	return "[('bool_', '?'), ('uint_', '{e}u4'), ('float_', '{e}f4'), ('ldbl_', '{e}f{}')]".format(
	np.dtype("longdouble").itemsize, e="<" if byteorder == "little" else ">"
	)


	def partial_ld_offset():
	return (
	12
	+ 4 * (np.dtype("uint64").alignment > 4)
	+ 8
	+ 8 * (np.dtype("longdouble").alignment > 8)
	)


	def partial_dtype_fmt():
	ld = np.dtype("longdouble")
	partial_ld_off = partial_ld_offset()
	return dt_fmt().format(ld.itemsize, partial_ld_off, partial_ld_off + ld.itemsize)


	def partial_nested_fmt():
	ld = np.dtype("longdouble")
	partial_nested_off = 8 + 8 * (ld.alignment > 8)
	partial_ld_off = partial_ld_offset()
	partial_nested_size = partial_nested_off * 2 + partial_ld_off + ld.itemsize
	return "{{'names':['a'], 'formats':[{}], 'offsets':[{}], 'itemsize':{}}}".format(
	partial_dtype_fmt(), partial_nested_off, partial_nested_size
	)


	def assert_equal(actual, expected_data, expected_dtype):
	np.testing.assert_equal(actual, np.array(expected_data, dtype=expected_dtype))


	def test_format_descriptors():
	with pytest.raises(RuntimeError) as excinfo:
	m.get_format_unbound()
	assert re.match(
	"^NumPy type info missing for .UnboundStruct.$", str(excinfo.value)
	)

	ld = np.dtype("longdouble")
	ldbl_fmt = ("4x" if ld.alignment > 4 else "") + ld.char
	ss_fmt = "^T{?:bool_:3xI:uint_:f:float_:" + ldbl_fmt + ":ldbl_:}"
	dbl = np.dtype("double")
	partial_fmt = (
	"^T{?:bool_:3xI:uint_:f:float_:"
	+ str(4 * (dbl.alignment > 4) + dbl.itemsize + 8 * (ld.alignment > 8))
	+ "xg:ldbl_:}"
	)
	nested_extra = str(max(8, ld.alignment))
	assert m.print_format_descriptors() == [
	ss_fmt,
	"^T{?:bool_:I:uint_:f:float_:g:ldbl_:}",
	"^T{" + ss_fmt + ":a:^T{?:bool_:I:uint_:f:float_:g:ldbl_:}:b:}",
	partial_fmt,
	"^T{" + nested_extra + "x" + partial_fmt + ":a:" + nested_extra + "x}",
	"^T{3s:a:3s:b:}",
	"^T{(3)4s:a:(2)i:b:(3)B:c:1x(4, 2)f:d:}",
	"^T{q:e1:B:e2:}",
	"^T{Zf:cflt:Zd:cdbl:}",
	]


	def test_dtype(simple_dtype):
	from sys import byteorder

	e = "<" if byteorder == "little" else ">"

	assert m.print_dtypes() == [
	simple_dtype_fmt(),
	packed_dtype_fmt(),
	"[('a', {}), ('b', {})]".format(simple_dtype_fmt(), packed_dtype_fmt()),
	partial_dtype_fmt(),
	partial_nested_fmt(),
	"[('a', 'S3'), ('b', 'S3')]",
	(
	"{{'names':['a','b','c','d'], "
	+ "'formats':[('S4', (3,)),('"
	+ e
	+ "i4', (2,)),('u1', (3,)),('"
	+ e
	+ "f4', (4, 2))], "
	+ "'offsets':[0,12,20,24], 'itemsize':56}}"
	).format(e=e),
	"[('e1', '" + e + "i8'), ('e2', 'u1')]",
	"[('x', 'i1'), ('y', '" + e + "u8')]",
	"[('cflt', '" + e + "c8'), ('cdbl', '" + e + "c16')]",
	]

	d1 = np.dtype(
	{
	"names": ["a", "b"],
	"formats": ["int32", "float64"],
	"offsets": [1, 10],
	"itemsize": 20,
	}
	)
	d2 = np.dtype([("a", "i4"), ("b", "f4")])
	assert m.test_dtype_ctors() == [
	np.dtype("int32"),
	np.dtype("float64"),
	np.dtype("bool"),
	d1,
	d1,
	np.dtype("uint32"),
	d2,
	]

	assert m.test_dtype_methods() == [
	np.dtype("int32"),
	simple_dtype,
	False,
	True,
	np.dtype("int32").itemsize,
	simple_dtype.itemsize,
	]

	assert m.trailing_padding_dtype() == m.buffer_to_dtype(
	np.zeros(1, m.trailing_padding_dtype())
	)


	def test_recarray(simple_dtype, packed_dtype):
	elements = [(False, 0, 0.0, -0.0), (True, 1, 1.5, -2.5), (False, 2, 3.0, -5.0)]

	for func, dtype in [
	(m.create_rec_simple, simple_dtype),
	(m.create_rec_packed, packed_dtype),
	]:
	arr = func(0)
	assert arr.dtype == dtype
	assert_equal(arr, [], simple_dtype)
	assert_equal(arr, [], packed_dtype)

	arr = func(3)
	assert arr.dtype == dtype
	assert_equal(arr, elements, simple_dtype)
	assert_equal(arr, elements, packed_dtype)

	# Show what recarray's look like in NumPy.
	assert type(arr[0]) == np.void
	assert type(arr[0].item()) == tuple

	if dtype == simple_dtype:
	assert m.print_rec_simple(arr) == [
	"s:0,0,0,-0",
	"s:1,1,1.5,-2.5",
	"s:0,2,3,-5",
	]
	else:
	assert m.print_rec_packed(arr) == [
	"p:0,0,0,-0",
	"p:1,1,1.5,-2.5",
	"p:0,2,3,-5",
	]

	nested_dtype = np.dtype([("a", simple_dtype), ("b", packed_dtype)])

	arr = m.create_rec_nested(0)
	assert arr.dtype == nested_dtype
	assert_equal(arr, [], nested_dtype)

	arr = m.create_rec_nested(3)
	assert arr.dtype == nested_dtype
	assert_equal(
	arr,
	[
	((False, 0, 0.0, -0.0), (True, 1, 1.5, -2.5)),
	((True, 1, 1.5, -2.5), (False, 2, 3.0, -5.0)),
	((False, 2, 3.0, -5.0), (True, 3, 4.5, -7.5)),
	],
	nested_dtype,
	)
	assert m.print_rec_nested(arr) == [
	"n:a=s:0,0,0,-0;b=p:1,1,1.5,-2.5",
	"n:a=s:1,1,1.5,-2.5;b=p:0,2,3,-5",
	"n:a=s:0,2,3,-5;b=p:1,3,4.5,-7.5",
	]

	arr = m.create_rec_partial(3)
	assert str(arr.dtype) == partial_dtype_fmt()
	partial_dtype = arr.dtype
	assert "" not in arr.dtype.fields
	assert partial_dtype.itemsize > simple_dtype.itemsize
	assert_equal(arr, elements, simple_dtype)
	assert_equal(arr, elements, packed_dtype)

	arr = m.create_rec_partial_nested(3)
	assert str(arr.dtype) == partial_nested_fmt()
	assert "" not in arr.dtype.fields
	assert "" not in arr.dtype.fields["a"][0].fields
	assert arr.dtype.itemsize > partial_dtype.itemsize
	np.testing.assert_equal(arr["a"], m.create_rec_partial(3))


	def test_array_constructors():
	data = np.arange(1, 7, dtype="int32")
	for i in range(8):
	np.testing.assert_array_equal(m.test_array_ctors(10 + i), data.reshape((3, 2)))
	np.testing.assert_array_equal(m.test_array_ctors(20 + i), data.reshape((3, 2)))
	for i in range(5):
	np.testing.assert_array_equal(m.test_array_ctors(30 + i), data)
	np.testing.assert_array_equal(m.test_array_ctors(40 + i), data)


	def test_string_array():
	arr = m.create_string_array(True)
	assert str(arr.dtype) == "[('a', 'S3'), ('b', 'S3')]"
	assert m.print_string_array(arr) == [
	"a='',b=''",
	"a='a',b='a'",
	"a='ab',b='ab'",
	"a='abc',b='abc'",
	]
	dtype = arr.dtype
	assert arr["a"].tolist() == [b"", b"a", b"ab", b"abc"]
	assert arr["b"].tolist() == [b"", b"a", b"ab", b"abc"]
	arr = m.create_string_array(False)
	assert dtype == arr.dtype


	def test_array_array():
	from sys import byteorder

	e = "<" if byteorder == "little" else ">"

	arr = m.create_array_array(3)
	assert str(arr.dtype) == (
	"{{'names':['a','b','c','d'], "
	+ "'formats':[('S4', (3,)),('"
	+ e
	+ "i4', (2,)),('u1', (3,)),('{e}f4', (4, 2))], "
	+ "'offsets':[0,12,20,24], 'itemsize':56}}"
	).format(e=e)
	assert m.print_array_array(arr) == [
	"a={{A,B,C,D},{K,L,M,N},{U,V,W,X}},b={0,1},"
	+ "c={0,1,2},d={{0,1},{10,11},{20,21},{30,31}}",
	"a={{W,X,Y,Z},{G,H,I,J},{Q,R,S,T}},b={1000,1001},"
	+ "c={10,11,12},d={{100,101},{110,111},{120,121},{130,131}}",
	"a={{S,T,U,V},{C,D,E,F},{M,N,O,P}},b={2000,2001},"
	+ "c={20,21,22},d={{200,201},{210,211},{220,221},{230,231}}",
	]
	assert arr["a"].tolist() == [
	[b"ABCD", b"KLMN", b"UVWX"],
	[b"WXYZ", b"GHIJ", b"QRST"],
	[b"STUV", b"CDEF", b"MNOP"],
	]
	assert arr["b"].tolist() == [[0, 1], [1000, 1001], [2000, 2001]]
	assert m.create_array_array(0).dtype == arr.dtype


	def test_enum_array():
	from sys import byteorder

	e = "<" if byteorder == "little" else ">"

	arr = m.create_enum_array(3)
	dtype = arr.dtype
	assert dtype == np.dtype([("e1", e + "i8"), ("e2", "u1")])
	assert m.print_enum_array(arr) == ["e1=A,e2=X", "e1=B,e2=Y", "e1=A,e2=X"]
	assert arr["e1"].tolist() == [-1, 1, -1]
	assert arr["e2"].tolist() == [1, 2, 1]
	assert m.create_enum_array(0).dtype == dtype


	def test_complex_array():
	from sys import byteorder

	e = "<" if byteorder == "little" else ">"

	arr = m.create_complex_array(3)
	dtype = arr.dtype
	assert dtype == np.dtype([("cflt", e + "c8"), ("cdbl", e + "c16")])
	assert m.print_complex_array(arr) == [
	"c:(0,0.25),(0.5,0.75)",
	"c:(1,1.25),(1.5,1.75)",
	"c:(2,2.25),(2.5,2.75)",
	]
	assert arr["cflt"].tolist() == [0.0 + 0.25j, 1.0 + 1.25j, 2.0 + 2.25j]
	assert arr["cdbl"].tolist() == [0.5 + 0.75j, 1.5 + 1.75j, 2.5 + 2.75j]
	assert m.create_complex_array(0).dtype == dtype


	def test_signature(doc):
	assert (
	doc(m.create_rec_nested)
	== "create_rec_nested(arg0: int) -> numpy.ndarray[NestedStruct]"
	)


	def test_scalar_conversion():
	n = 3
	arrays = [
	m.create_rec_simple(n),
	m.create_rec_packed(n),
	m.create_rec_nested(n),
	m.create_enum_array(n),
	]
	funcs = [m.f_simple, m.f_packed, m.f_nested]

	for i, func in enumerate(funcs):
	for j, arr in enumerate(arrays):
	if i == j and i < 2:
	assert [func(arr[k]) for k in range(n)] == [k * 10 for k in range(n)]
	else:
	with pytest.raises(TypeError) as excinfo:
	func(arr[0])
	assert "incompatible function arguments" in str(excinfo.value)


	def test_vectorize():
	n = 3
	array = m.create_rec_simple(n)
	values = m.f_simple_vectorized(array)
	np.testing.assert_array_equal(values, [0, 10, 20])
	array_2 = m.f_simple_pass_thru_vectorized(array)
	np.testing.assert_array_equal(array, array_2)


	def test_cls_and_dtype_conversion(simple_dtype):
	s = m.SimpleStruct()
	assert s.astuple() == (False, 0, 0.0, 0.0)
	assert m.SimpleStruct.fromtuple(s.astuple()).astuple() == s.astuple()

	s.uint_ = 2
	assert m.f_simple(s) == 20

	# Try as recarray of shape==(1,).
	s_recarray = np.array([(False, 2, 0.0, 0.0)], dtype=simple_dtype)
	# Show that this will work for vectorized case.
	np.testing.assert_array_equal(m.f_simple_vectorized(s_recarray), [20])

	# Show as a scalar that inherits from np.generic.
	s_scalar = s_recarray[0]
	assert isinstance(s_scalar, np.void)
	assert m.f_simple(s_scalar) == 20

	# Show that an array scalar (np.ndarray.shape == ()) does not convert.
	# More specifically, conversion to SimpleStruct is not implicit.
	s_recarray_scalar = s_recarray.reshape(())
	assert isinstance(s_recarray_scalar, np.ndarray)
	assert s_recarray_scalar.dtype == simple_dtype
	with pytest.raises(TypeError) as excinfo:
	m.f_simple(s_recarray_scalar)
	assert "incompatible function arguments" in str(excinfo.value)
	# Explicitly convert to m.SimpleStruct.
	assert m.f_simple(m.SimpleStruct.fromtuple(s_recarray_scalar.item())) == 20

	# Show that an array of dtype=object does not convert.
	s_array_object = np.array([s])
	assert s_array_object.dtype == object
	with pytest.raises(TypeError) as excinfo:
	m.f_simple_vectorized(s_array_object)
	assert "incompatible function arguments" in str(excinfo.value)
	# Explicitly convert to `np.array(..., dtype=simple_dtype)`
	s_array = np.array([s.astuple()], dtype=simple_dtype)
	np.testing.assert_array_equal(m.f_simple_vectorized(s_array), [20])


	def test_register_dtype():
	with pytest.raises(RuntimeError) as excinfo:
	m.register_dtype()
	assert "dtype is already registered" in str(excinfo.value)


	@pytest.mark.xfail("env.PYPY")
	def test_str_leak():
	from sys import getrefcount

	fmt = "f4"
	pytest.gc_collect()
	start = getrefcount(fmt)
	d = m.dtype_wrapper(fmt)
	assert d is np.dtype("f4")
	del d
	pytest.gc_collect()
	assert getrefcount(fmt) == start


	def test_compare_buffer_info():
	assert all(m.compare_buffer_info())