from collections import namedtuple from copy import deepcopy import re import textwrap import warnings import jinja2 from numpydoc.numpydoc import update_config from numpydoc.xref import DEFAULT_LINKS from numpydoc.docscrape import NumpyDocString, FunctionDoc, ClassDoc, ParseError from numpydoc.docscrape_sphinx import ( SphinxDocString, SphinxClassDoc, SphinxFunctionDoc, get_doc_object, ) import pytest from pytest import raises as assert_raises from pytest import warns as assert_warns doc_txt = """\ numpy.multivariate_normal(mean, cov, shape=None, spam=None) Draw values from a multivariate normal distribution with specified mean and covariance. The multivariate normal or Gaussian distribution is a generalisation of the one-dimensional normal distribution to higher dimensions. Parameters ---------- mean : (N,) ndarray Mean of the N-dimensional distribution. .. math:: (1+2+3)/3 cov : (N, N) ndarray Covariance matrix of the distribution. shape : tuple of ints Given a shape of, for example, (m,n,k), m*n*k samples are generated, and packed in an m-by-n-by-k arrangement. Because each sample is N-dimensional, the output shape is (m,n,k,N). dtype : data type object, optional (default : float) The type and size of the data to be returned. Returns ------- out : ndarray The drawn samples, arranged according to `shape`. If the shape given is (m,n,...), then the shape of `out` is (m,n,...,N). In other words, each entry ``out[i,j,...,:]`` is an N-dimensional value drawn from the distribution. list of str This is not a real return value. It exists to test anonymous return values. no_description Other Parameters ---------------- spam : parrot A parrot off its mortal coil. Raises ------ RuntimeError Some error Warns ----- RuntimeWarning Some warning Warnings -------- Certain warnings apply. Notes ----- Instead of specifying the full covariance matrix, popular approximations include: - Spherical covariance (`cov` is a multiple of the identity matrix) - Diagonal covariance (`cov` has non-negative elements only on the diagonal) This geometrical property can be seen in two dimensions by plotting generated data-points: >>> mean = [0,0] >>> cov = [[1,0],[0,100]] # diagonal covariance, points lie on x or y-axis >>> x,y = multivariate_normal(mean,cov,5000).T >>> plt.plot(x,y,'x'); plt.axis('equal'); plt.show() Note that the covariance matrix must be symmetric and non-negative definite. References ---------- .. [1] A. Papoulis, "Probability, Random Variables, and Stochastic Processes," 3rd ed., McGraw-Hill Companies, 1991 .. [2] R.O. Duda, P.E. Hart, and D.G. Stork, "Pattern Classification," 2nd ed., Wiley, 2001. See Also -------- some, other, funcs otherfunc : relationship :py:meth:`spyder.widgets.mixins.GetHelpMixin.show_object_info` Examples -------- >>> mean = (1,2) >>> cov = [[1,0],[1,0]] >>> x = multivariate_normal(mean,cov,(3,3)) >>> print(x.shape) (3, 3, 2) The following is probably true, given that 0.6 is roughly twice the standard deviation: >>> print(list((x[0, 0, :] - mean) < 0.6)) [True, True] .. index:: random :refguide: random;distributions, random;gauss """ @pytest.fixture(params=["", "\n "], ids=["flush", "newline_indented"]) def doc(request): return NumpyDocString(request.param + doc_txt) doc_yields_txt = """ Test generator Yields ------ a : int The number of apples. b : int The number of bananas. int The number of unknowns. """ doc_yields = NumpyDocString(doc_yields_txt) doc_sent_txt = """ Test generator Yields ------ a : int The number of apples. Receives -------- b : int The number of bananas. c : int The number of oranges. """ doc_sent = NumpyDocString(doc_sent_txt) def test_signature(doc): assert doc["Signature"].startswith("numpy.multivariate_normal(") assert doc["Signature"].endswith("spam=None)") def test_summary(doc): assert doc["Summary"][0].startswith("Draw values") assert doc["Summary"][-1].endswith("covariance.") def test_extended_summary(doc): assert doc["Extended Summary"][0].startswith("The multivariate normal") def test_parameters(doc): assert len(doc["Parameters"]) == 4 names = [n for n, _, _ in doc["Parameters"]] assert all(a == b for a, b in zip(names, ["mean", "cov", "shape"])) arg, arg_type, desc = doc["Parameters"][1] assert arg_type == "(N, N) ndarray" assert desc[0].startswith("Covariance matrix") assert doc["Parameters"][0][-1][-1] == " (1+2+3)/3" arg, arg_type, desc = doc["Parameters"][2] assert arg == "shape" assert arg_type == "tuple of ints" assert desc[0].startswith("Given") assert doc["Parameters"][0][-1][-1] == " (1+2+3)/3" arg, arg_type, desc = doc["Parameters"][3] assert arg == "dtype" assert arg_type == "data type object, optional (default : float)" assert desc[0].startswith("The type and size") def test_other_parameters(doc): assert len(doc["Other Parameters"]) == 1 assert [n for n, _, _ in doc["Other Parameters"]] == ["spam"] arg, arg_type, desc = doc["Other Parameters"][0] assert arg_type == "parrot" assert desc[0].startswith("A parrot off its mortal coil") def test_returns(doc): assert len(doc["Returns"]) == 3 arg, arg_type, desc = doc["Returns"][0] assert arg == "out" assert arg_type == "ndarray" assert desc[0].startswith("The drawn samples") assert desc[-1].endswith("distribution.") arg, arg_type, desc = doc["Returns"][1] assert arg == "" assert arg_type == "list of str" assert desc[0].startswith("This is not a real") assert desc[-1].endswith("anonymous return values.") arg, arg_type, desc = doc["Returns"][2] assert arg == "" assert arg_type == "no_description" assert not "".join(desc).strip() def test_yields(): section = doc_yields["Yields"] assert len(section) == 3 truth = [ ("a", "int", "apples."), ("b", "int", "bananas."), ("", "int", "unknowns."), ] for (arg, arg_type, desc), (arg_, arg_type_, end) in zip(section, truth): assert arg == arg_ assert arg_type == arg_type_ assert desc[0].startswith("The number of") assert desc[0].endswith(end) def test_sent(): section = doc_sent["Receives"] assert len(section) == 2 truth = [("b", "int", "bananas."), ("c", "int", "oranges.")] for (arg, arg_type, desc), (arg_, arg_type_, end) in zip(section, truth): assert arg == arg_ assert arg_type == arg_type_ assert desc[0].startswith("The number of") assert desc[0].endswith(end) def test_returnyield(): doc_text = """ Test having returns and yields. Returns ------- int The number of apples. Yields ------ a : int The number of apples. b : int The number of bananas. """ assert_raises(ValueError, NumpyDocString, doc_text) def test_section_twice(): doc_text = """ Test having a section Notes twice Notes ----- See the next note for more information Notes ----- That should break... """ with pytest.raises(ValueError, match="The section Notes appears twice"): NumpyDocString(doc_text) # if we have a numpydoc object, we know where the error came from class Dummy: """ Dummy class. Notes ----- First note. Notes ----- Second note. """ def spam(self, a, b): """Spam\n\nSpam spam.""" pass def ham(self, c, d): """Cheese\n\nNo cheese.""" pass def dummy_func(arg): """ Dummy function. Notes ----- First note. Notes ----- Second note. """ with pytest.raises(ValueError, match="Dummy class"): SphinxClassDoc(Dummy) with pytest.raises(ValueError, match="dummy_func"): SphinxFunctionDoc(dummy_func) def test_notes(doc): assert doc["Notes"][0].startswith("Instead") assert doc["Notes"][-1].endswith("definite.") assert len(doc["Notes"]) == 17 def test_references(doc): assert doc["References"][0].startswith("..") assert doc["References"][-1].endswith("2001.") def test_examples(doc): assert doc["Examples"][0].startswith(">>>") assert doc["Examples"][-1].endswith("True]") def test_index(doc): assert doc["index"]["default"] == "random" assert len(doc["index"]) == 2 assert len(doc["index"]["refguide"]) == 2 def _strip_blank_lines(s): "Remove leading, trailing and multiple blank lines" s = re.sub(r"^\s*\n", "", s) s = re.sub(r"\n\s*$", "", s) s = re.sub(r"\n\s*\n", r"\n\n", s) return s def line_by_line_compare(a, b, n_lines=None): a = textwrap.dedent(a) b = textwrap.dedent(b) a = [l.rstrip() for l in _strip_blank_lines(a).split("\n")][:n_lines] b = [l.rstrip() for l in _strip_blank_lines(b).split("\n")][:n_lines] assert len(a) == len(b) for ii, (aa, bb) in enumerate(zip(a, b)): assert aa == bb def test_str(doc): # doc_txt has the order of Notes and See Also sections flipped. # This should be handled automatically, and so, one thing this test does # is to make sure that See Also precedes Notes in the output. line_by_line_compare( str(doc), """numpy.multivariate_normal(mean, cov, shape=None, spam=None) Draw values from a multivariate normal distribution with specified mean and covariance. The multivariate normal or Gaussian distribution is a generalisation of the one-dimensional normal distribution to higher dimensions. Parameters ---------- mean : (N,) ndarray Mean of the N-dimensional distribution. .. math:: (1+2+3)/3 cov : (N, N) ndarray Covariance matrix of the distribution. shape : tuple of ints Given a shape of, for example, (m,n,k), m*n*k samples are generated, and packed in an m-by-n-by-k arrangement. Because each sample is N-dimensional, the output shape is (m,n,k,N). dtype : data type object, optional (default : float) The type and size of the data to be returned. Returns ------- out : ndarray The drawn samples, arranged according to `shape`. If the shape given is (m,n,...), then the shape of `out` is (m,n,...,N). In other words, each entry ``out[i,j,...,:]`` is an N-dimensional value drawn from the distribution. list of str This is not a real return value. It exists to test anonymous return values. no_description Other Parameters ---------------- spam : parrot A parrot off its mortal coil. Raises ------ RuntimeError Some error Warns ----- RuntimeWarning Some warning Warnings -------- Certain warnings apply. See Also -------- `some`_, `other`_, `funcs`_ .. `otherfunc`_ relationship :py:meth:`spyder.widgets.mixins.GetHelpMixin.show_object_info` .. Notes ----- Instead of specifying the full covariance matrix, popular approximations include: - Spherical covariance (`cov` is a multiple of the identity matrix) - Diagonal covariance (`cov` has non-negative elements only on the diagonal) This geometrical property can be seen in two dimensions by plotting generated data-points: >>> mean = [0,0] >>> cov = [[1,0],[0,100]] # diagonal covariance, points lie on x or y-axis >>> x,y = multivariate_normal(mean,cov,5000).T >>> plt.plot(x,y,'x'); plt.axis('equal'); plt.show() Note that the covariance matrix must be symmetric and non-negative definite. References ---------- .. [1] A. Papoulis, "Probability, Random Variables, and Stochastic Processes," 3rd ed., McGraw-Hill Companies, 1991 .. [2] R.O. Duda, P.E. Hart, and D.G. Stork, "Pattern Classification," 2nd ed., Wiley, 2001. Examples -------- >>> mean = (1,2) >>> cov = [[1,0],[1,0]] >>> x = multivariate_normal(mean,cov,(3,3)) >>> print(x.shape) (3, 3, 2) The following is probably true, given that 0.6 is roughly twice the standard deviation: >>> print(list((x[0, 0, :] - mean) < 0.6)) [True, True] .. index:: random :refguide: random;distributions, random;gauss""", ) def test_yield_str(): line_by_line_compare( str(doc_yields), """Test generator Yields ------ a : int The number of apples. b : int The number of bananas. int The number of unknowns. """, ) def test_receives_str(): line_by_line_compare( str(doc_sent), """Test generator Yields ------ a : int The number of apples. Receives -------- b : int The number of bananas. c : int The number of oranges. """, ) def test_no_index_in_str(): assert "index" not in str( NumpyDocString( """Test idx """ ) ) assert "index" in str( NumpyDocString( """Test idx .. index :: random """ ) ) assert "index" in str( NumpyDocString( """Test idx .. index :: foo """ ) ) def test_sphinx_str(): sphinx_doc = SphinxDocString(doc_txt) line_by_line_compare( str(sphinx_doc), """ .. index:: random single: random;distributions, random;gauss Draw values from a multivariate normal distribution with specified mean and covariance. The multivariate normal or Gaussian distribution is a generalisation of the one-dimensional normal distribution to higher dimensions. :Parameters: **mean** : (N,) ndarray Mean of the N-dimensional distribution. .. math:: (1+2+3)/3 **cov** : (N, N) ndarray Covariance matrix of the distribution. **shape** : tuple of ints Given a shape of, for example, (m,n,k), m*n*k samples are generated, and packed in an m-by-n-by-k arrangement. Because each sample is N-dimensional, the output shape is (m,n,k,N). **dtype** : data type object, optional (default : float) The type and size of the data to be returned. :Returns: **out** : ndarray The drawn samples, arranged according to `shape`. If the shape given is (m,n,...), then the shape of `out` is (m,n,...,N). In other words, each entry ``out[i,j,...,:]`` is an N-dimensional value drawn from the distribution. list of str This is not a real return value. It exists to test anonymous return values. no_description .. :Other Parameters: **spam** : parrot A parrot off its mortal coil. :Raises: RuntimeError Some error :Warns: RuntimeWarning Some warning .. warning:: Certain warnings apply. .. seealso:: :obj:`some`, :obj:`other`, :obj:`funcs` .. :obj:`otherfunc` relationship :py:meth:`spyder.widgets.mixins.GetHelpMixin.show_object_info` .. .. rubric:: Notes Instead of specifying the full covariance matrix, popular approximations include: - Spherical covariance (`cov` is a multiple of the identity matrix) - Diagonal covariance (`cov` has non-negative elements only on the diagonal) This geometrical property can be seen in two dimensions by plotting generated data-points: >>> mean = [0,0] >>> cov = [[1,0],[0,100]] # diagonal covariance, points lie on x or y-axis >>> x,y = multivariate_normal(mean,cov,5000).T >>> plt.plot(x,y,'x'); plt.axis('equal'); plt.show() Note that the covariance matrix must be symmetric and non-negative definite. .. rubric:: References .. [1] A. Papoulis, "Probability, Random Variables, and Stochastic Processes," 3rd ed., McGraw-Hill Companies, 1991 .. [2] R.O. Duda, P.E. Hart, and D.G. Stork, "Pattern Classification," 2nd ed., Wiley, 2001. .. only:: latex [1]_, [2]_ .. rubric:: Examples >>> mean = (1,2) >>> cov = [[1,0],[1,0]] >>> x = multivariate_normal(mean,cov,(3,3)) >>> print(x.shape) (3, 3, 2) The following is probably true, given that 0.6 is roughly twice the standard deviation: >>> print(list((x[0, 0, :] - mean) < 0.6)) [True, True] """, ) def test_sphinx_yields_str(): sphinx_doc = SphinxDocString(doc_yields_txt) line_by_line_compare( str(sphinx_doc), """Test generator :Yields: **a** : int The number of apples. **b** : int The number of bananas. int The number of unknowns. """, ) doc2 = NumpyDocString( """ Returns array of indices of the maximum values of along the given axis. Parameters ---------- a : {array_like} Array to look in. axis : {None, integer} If None, the index is into the flattened array, otherwise along the specified axis""" ) def test_parameters_without_extended_description(): assert len(doc2["Parameters"]) == 2 doc3 = NumpyDocString( """ my_signature(*params, **kwds) Return this and that. """ ) def test_escape_stars(): signature = str(doc3).split("\n")[0] assert signature == r"my_signature(\*params, \*\*kwds)" def my_func(a, b, **kwargs): pass fdoc = FunctionDoc(func=my_func) assert fdoc["Signature"] == "" doc4 = NumpyDocString( """a.conj() Return an array with all complex-valued elements conjugated.""" ) def test_empty_extended_summary(): assert doc4["Extended Summary"] == [] doc5 = NumpyDocString( """ a.something() Raises ------ LinAlgException If array is singular. Warns ----- SomeWarning If needed """ ) def test_raises(): assert len(doc5["Raises"]) == 1 param = doc5["Raises"][0] assert param.name == "" assert param.type == "LinAlgException" assert param.desc == ["If array is singular."] def test_warns(): assert len(doc5["Warns"]) == 1 param = doc5["Warns"][0] assert param.name == "" assert param.type == "SomeWarning" assert param.desc == ["If needed"] # see numpydoc/numpydoc #281 # we want to correctly parse "See Also" both in docstrings both like # """foo # and # """ # foo @pytest.mark.parametrize("prefix", ["", "\n "]) def test_see_also(prefix): doc6 = NumpyDocString( prefix + """z(x,theta) See Also -------- func_a, func_b, func_c func_d : some equivalent func foo.func_e : some other func over multiple lines func_f, func_g, :meth:`func_h`, func_j, func_k func_f1, func_g1, :meth:`func_h1`, func_j1 func_f2, func_g2, :meth:`func_h2`, func_j2 : description of multiple :obj:`baz.obj_q` :obj:`~baz.obj_r` :class:`class_j`: fubar foobar """ ) assert len(doc6["See Also"]) == 10 for funcs, desc in doc6["See Also"]: for func, role in funcs: if func in ( "func_a", "func_b", "func_c", "func_f", "func_g", "func_h", "func_j", "func_k", "baz.obj_q", "func_f1", "func_g1", "func_h1", "func_j1", "~baz.obj_r", ): assert not desc, str([func, desc]) elif func in ("func_f2", "func_g2", "func_h2", "func_j2"): assert desc, str([func, desc]) else: assert desc, str([func, desc]) if func == "func_h": assert role == "meth" elif func == "baz.obj_q" or func == "~baz.obj_r": assert role == "obj" elif func == "class_j": assert role == "class" elif func in ["func_h1", "func_h2"]: assert role == "meth" else: assert role is None, str([func, role]) if func == "func_d": assert desc == ["some equivalent func"] elif func == "foo.func_e": assert desc == ["some other func over", "multiple lines"] elif func == "class_j": assert desc == ["fubar", "foobar"] elif func in ["func_f2", "func_g2", "func_h2", "func_j2"]: assert desc == ["description of multiple"], str( [desc, ["description of multiple"]] ) def test_see_also_parse_error(): text = """ z(x,theta) See Also -------- :func:`~foo` """ with pytest.raises(ValueError, match="See Also entry ':func:`~foo`'"): NumpyDocString(text) def test_see_also_print(): class Dummy: """ See Also -------- func_a, func_b func_c : some relationship goes here func_d """ pass s = str(FunctionDoc(Dummy, role="func")) assert ":func:`func_a`, :func:`func_b`" in s assert " some relationship" in s assert ":func:`func_d`" in s def test_see_also_trailing_comma_warning(): warnings.filterwarnings("error") with assert_warns( Warning, match="Unexpected comma or period after function list at index 43 of line .*", ): NumpyDocString( """ z(x,theta) See Also -------- func_f2, func_g2, :meth:`func_h2`, func_j2, : description of multiple :class:`class_j`: fubar foobar """ ) def test_unknown_section(): doc_text = """ Test having an unknown section Mope ---- This should be ignored and warned about """ class BadSection: """Class with bad section. Nope ---- This class has a nope section. """ pass with pytest.warns(UserWarning, match="Unknown section Mope") as record: NumpyDocString(doc_text) assert len(record) == 1 # SphinxClassDoc has _obj.__name__ == "BadSection". Test that this is # included in the message msg_match = "Unknown section Nope in the docstring of BadSection" with pytest.warns(UserWarning, match=msg_match) as record: SphinxClassDoc(BadSection) assert len(record) == 1 doc7 = NumpyDocString( """ Doc starts on second line. """ ) def test_empty_first_line(): assert doc7["Summary"][0].startswith("Doc starts") doc8 = NumpyDocString( """ Parameters with colon and no types: Parameters ---------- data : some stuff, technically invalid """ ) def test_trailing_colon(): assert doc8["Parameters"][0].name == "data" def test_no_summary(): str( SphinxDocString( """ Parameters ----------""" ) ) def test_unicode(): doc = SphinxDocString( """ öäöäöäöäöåååå öäöäöäööäååå Parameters ---------- ååå : äää ööö Returns ------- ååå : ööö äää """ ) assert isinstance(doc["Summary"][0], str) assert doc["Summary"][0] == "öäöäöäöäöåååå" def test_plot_examples(): cfg = dict(use_plots=True) doc = SphinxDocString( """ Examples -------- >>> import matplotlib.pyplot as plt >>> plt.plot([1,2,3],[4,5,6]) >>> plt.show() """, config=cfg, ) assert "plot::" in str(doc), str(doc) doc = SphinxDocString( """ Examples -------- >>> from matplotlib import pyplot as plt >>> plt.plot([1,2,3],[4,5,6]) >>> plt.show() """, config=cfg, ) assert "plot::" in str(doc), str(doc) doc = SphinxDocString( """ Examples -------- .. plot:: import matplotlib.pyplot as plt plt.plot([1,2,3],[4,5,6]) plt.show() """, config=cfg, ) assert str(doc).count("plot::") == 1, str(doc) def test_use_blockquotes(): cfg = dict(use_blockquotes=True) doc = SphinxDocString( """ Parameters ---------- abc : def ghi jkl mno Returns ------- ABC : DEF GHI JKL MNO """, config=cfg, ) line_by_line_compare( str(doc), """ :Parameters: **abc** : def ghi **jkl** mno :Returns: **ABC** : DEF GHI JKL MNO """, ) def test_class_members(): class Dummy: """ Dummy class. """ def spam(self, a, b): """Spam\n\nSpam spam.""" pass def ham(self, c, d): """Cheese\n\nNo cheese.""" pass @property def spammity(self): """Spammity index""" return 0.95 class Ignorable: """local class, to be ignored""" pass for cls in (ClassDoc, SphinxClassDoc): doc = cls(Dummy, config=dict(show_class_members=False)) assert "Methods" not in str(doc), (cls, str(doc)) assert "spam" not in str(doc), (cls, str(doc)) assert "ham" not in str(doc), (cls, str(doc)) assert "spammity" not in str(doc), (cls, str(doc)) assert "Spammity index" not in str(doc), (cls, str(doc)) doc = cls(Dummy, config=dict(show_class_members=True)) assert "Methods" in str(doc), (cls, str(doc)) assert "spam" in str(doc), (cls, str(doc)) assert "ham" in str(doc), (cls, str(doc)) assert "spammity" in str(doc), (cls, str(doc)) if cls is SphinxClassDoc: assert ".. autosummary::" in str(doc), str(doc) else: assert "Spammity index" in str(doc), str(doc) class SubDummy(Dummy): """ Subclass of Dummy class. """ def ham(self, c, d): """Cheese\n\nNo cheese.\nOverloaded Dummy.ham""" pass def bar(self, a, b): """Bar\n\nNo bar""" pass for cls in (ClassDoc, SphinxClassDoc): doc = cls( SubDummy, config=dict(show_class_members=True, show_inherited_class_members=False), ) assert "Methods" in str(doc), (cls, str(doc)) assert "spam" not in str(doc), (cls, str(doc)) assert "ham" in str(doc), (cls, str(doc)) assert "bar" in str(doc), (cls, str(doc)) assert "spammity" not in str(doc), (cls, str(doc)) if cls is SphinxClassDoc: assert ".. autosummary::" in str(doc), str(doc) else: assert "Spammity index" not in str(doc), str(doc) doc = cls( SubDummy, config=dict(show_class_members=True, show_inherited_class_members=True), ) assert "Methods" in str(doc), (cls, str(doc)) assert "spam" in str(doc), (cls, str(doc)) assert "ham" in str(doc), (cls, str(doc)) assert "bar" in str(doc), (cls, str(doc)) assert "spammity" in str(doc), (cls, str(doc)) if cls is SphinxClassDoc: assert ".. autosummary::" in str(doc), str(doc) else: assert "Spammity index" in str(doc), str(doc) def test_duplicate_signature(): # Duplicate function signatures occur e.g. in ufuncs, when the # automatic mechanism adds one, and a more detailed comes from the # docstring itself. doc = NumpyDocString( """ z(x1, x2) z(a, theta) """ ) assert doc["Signature"].strip() == "z(a, theta)" class_doc_txt = """ Foo Parameters ---------- f : callable ``f(t, y, *f_args)`` Aaa. jac : callable ``jac(t, y, *jac_args)`` Bbb. Attributes ---------- t : float Current time. y : ndarray Current variable values. * hello * world an_attribute : float The docstring is printed instead no_docstring : str But a description no_docstring2 : str multiline_sentence midword_period no_period Methods ------- a b c Examples -------- For usage examples, see `ode`. """ def test_class_members_doc(): doc = ClassDoc(None, class_doc_txt) line_by_line_compare( str(doc), """ Foo Parameters ---------- f : callable ``f(t, y, *f_args)`` Aaa. jac : callable ``jac(t, y, *jac_args)`` Bbb. Examples -------- For usage examples, see `ode`. Attributes ---------- t : float Current time. y : ndarray Current variable values. * hello * world an_attribute : float The docstring is printed instead no_docstring : str But a description no_docstring2 : str multiline_sentence midword_period no_period Methods ------- a b c """, ) def test_class_members_doc_sphinx(): class Foo: @property def an_attribute(self): """Test attribute""" return None @property def no_docstring(self): return None @property def no_docstring2(self): return None @property def multiline_sentence(self): """This is a sentence. It spans multiple lines.""" return None @property def midword_period(self): """The sentence for numpy.org.""" return None @property def no_period(self): """This does not have a period so we truncate its summary to the first linebreak Apparently. """ return None doc = SphinxClassDoc(Foo, class_doc_txt) line_by_line_compare( str(doc), """ Foo :Parameters: **f** : callable ``f(t, y, *f_args)`` Aaa. **jac** : callable ``jac(t, y, *jac_args)`` Bbb. .. rubric:: Examples For usage examples, see `ode`. :Attributes: **t** : float Current time. **y** : ndarray Current variable values. * hello * world :obj:`an_attribute ` : float Test attribute **no_docstring** : str But a description **no_docstring2** : str .. :obj:`multiline_sentence ` This is a sentence. :obj:`midword_period ` The sentence for numpy.org. :obj:`no_period ` This does not have a period .. rubric:: Methods ===== ========== **a** **b** **c** ===== ========== """, ) def test_class_attributes_as_member_list(): class Foo: """ Class docstring. Attributes ---------- an_attribute Another description that is not used. """ @property def an_attribute(self): """Test attribute""" return None attr_doc = """:Attributes: :obj:`an_attribute ` Test attribute""" assert attr_doc in str(SphinxClassDoc(Foo)) assert "Another description" not in str(SphinxClassDoc(Foo)) attr_doc2 = """.. rubric:: Attributes .. autosummary:: :toctree: an_attribute""" cfg = dict(attributes_as_param_list=False) assert attr_doc2 in str(SphinxClassDoc(Foo, config=cfg)) assert "Another description" not in str(SphinxClassDoc(Foo, config=cfg)) def test_templated_sections(): doc = SphinxClassDoc( None, class_doc_txt, config={"template": jinja2.Template("{{examples}}\n{{parameters}}")}, ) line_by_line_compare( str(doc), """ .. rubric:: Examples For usage examples, see `ode`. :Parameters: **f** : callable ``f(t, y, *f_args)`` Aaa. **jac** : callable ``jac(t, y, *jac_args)`` Bbb. """, ) def test_nonstandard_property(): # test discovery of a property that does not satisfy isinstace(.., property) class SpecialProperty: def __init__(self, axis=0, doc=""): self.axis = axis self.__doc__ = doc def __get__(self, obj, type): if obj is None: # Only instances have actual _data, not classes return self else: return obj._data.axes[self.axis] def __set__(self, obj, value): obj._set_axis(self.axis, value) class Dummy: attr = SpecialProperty(doc="test attribute") doc = get_doc_object(Dummy) assert "test attribute" in str(doc) def test_args_and_kwargs(): cfg = dict() doc = SphinxDocString( """ Parameters ---------- param1 : int First parameter *args : tuple Arguments **kwargs : dict Keyword arguments """, config=cfg, ) line_by_line_compare( str(doc), r""" :Parameters: **param1** : int First parameter **\*args** : tuple Arguments **\*\*kwargs** : dict Keyword arguments """, ) def test_autoclass(): cfg = dict(show_class_members=True, show_inherited_class_members=True) doc = SphinxClassDoc( str, """ A top section before .. autoclass:: str """, config=cfg, ) line_by_line_compare( str(doc), r""" A top section before .. autoclass:: str .. rubric:: Methods """, 5, ) xref_doc_txt = """ Test xref in Parameters, Other Parameters and Returns Parameters ---------- p1 : int Integer value p2 : float, optional Integer value Other Parameters ---------------- p3 : list[int] List of integers p4 : :class:`pandas.DataFrame` A dataframe p5 : sequence of `int` A sequence Returns ------- out : array Numerical return value """ xref_doc_txt_expected = r""" Test xref in Parameters, Other Parameters and Returns :Parameters: **p1** : :class:`python:int` Integer value **p2** : :class:`python:float`, optional Integer value :Returns: **out** : :obj:`array ` Numerical return value :Other Parameters: **p3** : :class:`python:list`\[:class:`python:int`] List of integers **p4** : :class:`pandas.DataFrame` A dataframe **p5** : :obj:`python:sequence` of `int` A sequence """ def test_xref(): xref_aliases = { "sequence": ":obj:`python:sequence`", } class Config: def __init__(self, a, b): self.numpydoc_xref_aliases = a self.numpydoc_xref_aliases_complete = b # numpydoc.update_config fails if this config option not present self.numpydoc_validation_checks = set() self.numpydoc_validation_exclude = set() xref_aliases_complete = deepcopy(DEFAULT_LINKS) for key in xref_aliases: xref_aliases_complete[key] = xref_aliases[key] config = Config(xref_aliases, xref_aliases_complete) app = namedtuple("config", "config")(config) update_config(app) xref_ignore = {"of", "default", "optional"} doc = SphinxDocString( xref_doc_txt, config=dict( xref_param_type=True, xref_aliases=xref_aliases_complete, xref_ignore=xref_ignore, ), ) line_by_line_compare(str(doc), xref_doc_txt_expected) def test__error_location_no_name_attr(): """ Ensure that NumpyDocString._error_location doesn't fail when self._obj does not have a __name__ attr. See gh-362 """ from collections.abc import Callable # Create a Callable that doesn't have a __name__ attribute class Foo: def __call__(self): pass foo = Foo() # foo is a Callable, but no a function instance assert isinstance(foo, Callable) # Create an NumpyDocString instance to call the _error_location method nds = get_doc_object(foo) msg = "Potentially wrong underline length.*Foo.*" with pytest.raises(ValueError, match=msg): nds._error_location(msg=msg) if __name__ == "__main__": import pytest pytest.main()