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Remove matplotlib requirement for building docs See gh-10003 We weren't actually using most of these extensions, and the one we were using can be replaced by a standard Sphinx directive.

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      # coding: utf-8

      """Tests for IPython.lib.pretty."""

      # Copyright (c) IPython Development Team.

      # Distributed under the terms of the Modified BSD License.

      from __future__ import print_function

      from collections import Counter, defaultdict, deque, OrderedDict

      import types, string

      import nose.tools as nt

      from IPython.lib import pretty

      from IPython.testing.decorators import (skip_without, py2_only, py3_only)

      from IPython.utils.py3compat import PY3, unicode_to_str

      if PY3:

          from io import StringIO

      else:

          from StringIO import StringIO

      class MyList(object):

          def __init__(self, content):

              self.content = content

          def _repr_pretty_(self, p, cycle):

              if cycle:

                  p.text("MyList(...)")

              else:

                  with p.group(3, "MyList(", ")"):

                      for (i, child) in enumerate(self.content):

                          if i:

                              p.text(",")

                              p.breakable()

                          else:

                              p.breakable("")

                          p.pretty(child)

      class MyDict(dict):

          def _repr_pretty_(self, p, cycle):

              p.text("MyDict(...)")

      class MyObj(object):

          def somemethod(self):

              pass

      class Dummy1(object):

          def _repr_pretty_(self, p, cycle):

              p.text("Dummy1(...)")

      class Dummy2(Dummy1):

          _repr_pretty_ = None

      class NoModule(object):

          pass

      NoModule.__module__ = None

      class Breaking(object):

          def _repr_pretty_(self, p, cycle):

              with p.group(4,"TG: ",":"):

                  p.text("Breaking(")

                  p.break_()

                  p.text(")")

      class BreakingRepr(object):

          def __repr__(self):

              return "Breaking(\n)"

      class BreakingReprParent(object):

          def _repr_pretty_(self, p, cycle):

              with p.group(4,"TG: ",":"):

                  p.pretty(BreakingRepr())

      class BadRepr(object):

          def __repr__(self):

              return 1/0

      def test_indentation():

          """Test correct indentation in groups"""

          count = 40

          gotoutput = pretty.pretty(MyList(range(count)))

          expectedoutput = "MyList(\n" + ",\n".join("   %d" % i for i in range(count)) + ")"

          nt.assert_equal(gotoutput, expectedoutput)

      def test_dispatch():

          """

          Test correct dispatching: The _repr_pretty_ method for MyDict

          must be found before the registered printer for dict.

          """

          gotoutput = pretty.pretty(MyDict())

          expectedoutput = "MyDict(...)"

          nt.assert_equal(gotoutput, expectedoutput)

      def test_callability_checking():

          """

          Test that the _repr_pretty_ method is tested for callability and skipped if

          not.

          """

          gotoutput = pretty.pretty(Dummy2())

          expectedoutput = "Dummy1(...)"

          nt.assert_equal(gotoutput, expectedoutput)

      def test_sets():

          """

          Test that set and frozenset use Python 3 formatting.

          """

          objects = [set(), frozenset(), set([1]), frozenset([1]), set([1, 2]),

              frozenset([1, 2]), set([-1, -2, -3])]

          expected = ['set()', 'frozenset()', '{1}', 'frozenset({1})', '{1, 2}',

              'frozenset({1, 2})', '{-3, -2, -1}']

          for obj, expected_output in zip(objects, expected):

              got_output = pretty.pretty(obj)

              yield nt.assert_equal, got_output, expected_output

      @skip_without('xxlimited')

      def test_pprint_heap_allocated_type():

          """

          Test that pprint works for heap allocated types.

          """

          import xxlimited

          output = pretty.pretty(xxlimited.Null)

          nt.assert_equal(output, 'xxlimited.Null')

      def test_pprint_nomod():

          """

          Test that pprint works for classes with no __module__.

          """

          output = pretty.pretty(NoModule)

          nt.assert_equal(output, 'NoModule')

      def test_pprint_break():

          """

          Test that p.break_ produces expected output

          """

          output = pretty.pretty(Breaking())

          expected = "TG: Breaking(\n    ):"

          nt.assert_equal(output, expected)

      def test_pprint_break_repr():

          """

          Test that p.break_ is used in repr

          """

          output = pretty.pretty(BreakingReprParent())

          expected = "TG: Breaking(\n    ):"

          nt.assert_equal(output, expected)

      def test_bad_repr():

          """Don't catch bad repr errors"""

          with nt.assert_raises(ZeroDivisionError):

              pretty.pretty(BadRepr())

      class BadException(Exception):

          def __str__(self):

              return -1

      class ReallyBadRepr(object):

          __module__ = 1

          @property

          def __class__(self):

              raise ValueError("I am horrible")

          def __repr__(self):

              raise BadException()

      def test_really_bad_repr():

          with nt.assert_raises(BadException):

              pretty.pretty(ReallyBadRepr())

      class SA(object):

          pass

      class SB(SA):

          pass

      def test_super_repr():

          # "<super: module_name.SA, None>"

          output = pretty.pretty(super(SA))

          nt.assert_regexp_matches(output, r"<super: \S+.SA, None>")

          # "<super: module_name.SA, <module_name.SB at 0x...>>"

          sb = SB()

          output = pretty.pretty(super(SA, sb))

          nt.assert_regexp_matches(output, r"<super: \S+.SA,\s+<\S+.SB at 0x\S+>>")

      def test_long_list():

          lis = list(range(10000))

          p = pretty.pretty(lis)

          last2 = p.rsplit('\n', 2)[-2:]

          nt.assert_equal(last2, [' 999,', ' ...]'])

      def test_long_set():

          s = set(range(10000))

          p = pretty.pretty(s)

          last2 = p.rsplit('\n', 2)[-2:]

          nt.assert_equal(last2, [' 999,', ' ...}'])

      def test_long_tuple():

          tup = tuple(range(10000))

          p = pretty.pretty(tup)

          last2 = p.rsplit('\n', 2)[-2:]

          nt.assert_equal(last2, [' 999,', ' ...)'])

      def test_long_dict():

          d = { n:n for n in range(10000) }

          p = pretty.pretty(d)

          last2 = p.rsplit('\n', 2)[-2:]

          nt.assert_equal(last2, [' 999: 999,', ' ...}'])

      def test_unbound_method():

          output = pretty.pretty(MyObj.somemethod)

          nt.assert_in('MyObj.somemethod', output)

      class MetaClass(type):

          def __new__(cls, name):

              return type.__new__(cls, name, (object,), {'name': name})

          def __repr__(self):

              return "[CUSTOM REPR FOR CLASS %s]" % self.name

      ClassWithMeta = MetaClass('ClassWithMeta')

      def test_metaclass_repr():

          output = pretty.pretty(ClassWithMeta)

          nt.assert_equal(output, "[CUSTOM REPR FOR CLASS ClassWithMeta]")

      def test_unicode_repr():

          u = u"üniçodé"

          ustr = unicode_to_str(u)

          class C(object):

              def __repr__(self):

                  return ustr

          c = C()

          p = pretty.pretty(c)

          nt.assert_equal(p, u)

          p = pretty.pretty([c])

          nt.assert_equal(p, u'[%s]' % u)

      def test_basic_class():

          def type_pprint_wrapper(obj, p, cycle):

              if obj is MyObj:

                  type_pprint_wrapper.called = True

              return pretty._type_pprint(obj, p, cycle)

          type_pprint_wrapper.called = False

          stream = StringIO()

          printer = pretty.RepresentationPrinter(stream)

          printer.type_pprinters[type] = type_pprint_wrapper

          printer.pretty(MyObj)

          printer.flush()

          output = stream.getvalue()

          nt.assert_equal(output, '%s.MyObj' % __name__)

          nt.assert_true(type_pprint_wrapper.called)

      # This is only run on Python 2 because in Python 3 the language prevents you

      # from setting a non-unicode value for __qualname__ on a metaclass, and it

      # doesn't respect the descriptor protocol if you subclass unicode and implement

      # __get__.

      @py2_only

      def test_fallback_to__name__on_type():

          # Test that we correctly repr types that have non-string values for

          # __qualname__ by falling back to __name__

          class Type(object):

              __qualname__ = 5

          # Test repring of the type.

          stream = StringIO()

          printer = pretty.RepresentationPrinter(stream)

          printer.pretty(Type)

          printer.flush()

          output = stream.getvalue()

          # If __qualname__ is malformed, we should fall back to __name__.

          expected = '.'.join([__name__, Type.__name__])

          nt.assert_equal(output, expected)

          # Clear stream buffer.

          stream.buf = ''

          # Test repring of an instance of the type.

          instance = Type()

          printer.pretty(instance)

          printer.flush()

          output = stream.getvalue()

          # Should look like:

          # <IPython.lib.tests.test_pretty.Type at 0x7f7658ae07d0>

          prefix = '<' + '.'.join([__name__, Type.__name__]) + ' at 0x'

          nt.assert_true(output.startswith(prefix))

      @py2_only

      def test_fail_gracefully_on_bogus__qualname__and__name__():

          # Test that we correctly repr types that have non-string values for both

          # __qualname__ and __name__

          class Meta(type):

              __name__ = 5

          class Type(object):

              __metaclass__ = Meta

              __qualname__ = 5

          stream = StringIO()

          printer = pretty.RepresentationPrinter(stream)

          printer.pretty(Type)

          printer.flush()

          output = stream.getvalue()

          # If we can't find __name__ or __qualname__ just use a sentinel string.

          expected = '.'.join([__name__, '<unknown type>'])

          nt.assert_equal(output, expected)

          # Clear stream buffer.

          stream.buf = ''

          # Test repring of an instance of the type.

          instance = Type()

          printer.pretty(instance)

          printer.flush()

          output = stream.getvalue()

          # Should look like:

          # <IPython.lib.tests.test_pretty.<unknown type> at 0x7f7658ae07d0>

          prefix = '<' + '.'.join([__name__, '<unknown type>']) + ' at 0x'

          nt.assert_true(output.startswith(prefix))

      def test_collections_defaultdict():

          # Create defaultdicts with cycles

          a = defaultdict()

          a.default_factory = a

          b = defaultdict(list)

          b['key'] = b

          # Dictionary order cannot be relied on, test against single keys.

          cases = [

              (defaultdict(list), 'defaultdict(list, {})'),

              (defaultdict(list, {'key': '-' * 50}),

               "defaultdict(list,\n"

               "            {'key': '--------------------------------------------------'})"),

              (a, 'defaultdict(defaultdict(...), {})'),

              (b, "defaultdict(list, {'key': defaultdict(...)})"),

          ]

          for obj, expected in cases:

              nt.assert_equal(pretty.pretty(obj), expected)

      def test_collections_ordereddict():

          # Create OrderedDict with cycle

          a = OrderedDict()

          a['key'] = a

          cases = [

              (OrderedDict(), 'OrderedDict()'),

              (OrderedDict((i, i) for i in range(1000, 1010)),

               'OrderedDict([(1000, 1000),\n'

               '             (1001, 1001),\n'

               '             (1002, 1002),\n'

               '             (1003, 1003),\n'

               '             (1004, 1004),\n'

               '             (1005, 1005),\n'

               '             (1006, 1006),\n'

               '             (1007, 1007),\n'

               '             (1008, 1008),\n'

               '             (1009, 1009)])'),

              (a, "OrderedDict([('key', OrderedDict(...))])"),

          ]

          for obj, expected in cases:

              nt.assert_equal(pretty.pretty(obj), expected)

      def test_collections_deque():

          # Create deque with cycle

          a = deque()

          a.append(a)

          cases = [

              (deque(), 'deque([])'),

              (deque(i for i in range(1000, 1020)),

               'deque([1000,\n'

               '       1001,\n'

               '       1002,\n'

               '       1003,\n'

               '       1004,\n'

               '       1005,\n'

               '       1006,\n'

               '       1007,\n'

               '       1008,\n'

               '       1009,\n'

               '       1010,\n'

               '       1011,\n'

               '       1012,\n'

               '       1013,\n'

               '       1014,\n'

               '       1015,\n'

               '       1016,\n'

               '       1017,\n'

               '       1018,\n'

               '       1019])'),

              (a, 'deque([deque(...)])'),

          ]

          for obj, expected in cases:

              nt.assert_equal(pretty.pretty(obj), expected)

      def test_collections_counter():

          class MyCounter(Counter):

              pass

          cases = [

              (Counter(), 'Counter()'),

              (Counter(a=1), "Counter({'a': 1})"),

              (MyCounter(a=1), "MyCounter({'a': 1})"),

          ]

          for obj, expected in cases:

              nt.assert_equal(pretty.pretty(obj), expected)

      @py3_only

      def test_mappingproxy():

          MP = types.MappingProxyType

          underlying_dict = {}

          mp_recursive = MP(underlying_dict)

          underlying_dict[2] = mp_recursive

          underlying_dict[3] = underlying_dict

          cases = [

              (MP({}), "mappingproxy({})"),

              (MP({None: MP({})}), "mappingproxy({None: mappingproxy({})})"),

              (MP({k: k.upper() for k in string.ascii_lowercase}),

               "mappingproxy({'a': 'A',\n"

               "              'b': 'B',\n"

               "              'c': 'C',\n"

               "              'd': 'D',\n"

               "              'e': 'E',\n"

               "              'f': 'F',\n"

               "              'g': 'G',\n"

               "              'h': 'H',\n"

               "              'i': 'I',\n"

               "              'j': 'J',\n"

               "              'k': 'K',\n"

               "              'l': 'L',\n"

               "              'm': 'M',\n"

               "              'n': 'N',\n"

               "              'o': 'O',\n"

               "              'p': 'P',\n"

               "              'q': 'Q',\n"

               "              'r': 'R',\n"

               "              's': 'S',\n"

               "              't': 'T',\n"

               "              'u': 'U',\n"

               "              'v': 'V',\n"

               "              'w': 'W',\n"

               "              'x': 'X',\n"

               "              'y': 'Y',\n"

               "              'z': 'Z'})"),

              (mp_recursive, "mappingproxy({2: {...}, 3: {2: {...}, 3: {...}}})"),

              (underlying_dict,

               "{2: mappingproxy({2: {...}, 3: {...}}), 3: {...}}"),

          ]

          for obj, expected in cases:

              nt.assert_equal(pretty.pretty(obj), expected)

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				# coding: utf-8
				"""Tests for IPython.lib.pretty."""

				# Copyright (c) IPython Development Team.
				# Distributed under the terms of the Modified BSD License.

				from __future__ import print_function

				from collections import Counter, defaultdict, deque, OrderedDict
				import types, string

				import nose.tools as nt

				from IPython.lib import pretty
				from IPython.testing.decorators import (skip_without, py2_only, py3_only)

				from IPython.utils.py3compat import PY3, unicode_to_str

				if PY3:
				from io import StringIO
				else:
				from StringIO import StringIO


				class MyList(object):
				def __init__(self, content):
				self.content = content
				def _repr_pretty_(self, p, cycle):
				if cycle:
				p.text("MyList(...)")
				else:
				with p.group(3, "MyList(", ")"):
				for (i, child) in enumerate(self.content):
				if i:
				p.text(",")
				p.breakable()
				else:
				p.breakable("")
				p.pretty(child)


				class MyDict(dict):
				def _repr_pretty_(self, p, cycle):
				p.text("MyDict(...)")

				class MyObj(object):
				def somemethod(self):
				pass


				class Dummy1(object):
				def _repr_pretty_(self, p, cycle):
				p.text("Dummy1(...)")

				class Dummy2(Dummy1):
				_repr_pretty_ = None

				class NoModule(object):
				pass

				NoModule.__module__ = None

				class Breaking(object):
				def _repr_pretty_(self, p, cycle):
				with p.group(4,"TG: ",":"):
				p.text("Breaking(")
				p.break_()
				p.text(")")

				class BreakingRepr(object):
				def __repr__(self):
				return "Breaking(\n)"

				class BreakingReprParent(object):
				def _repr_pretty_(self, p, cycle):
				with p.group(4,"TG: ",":"):
				p.pretty(BreakingRepr())

				class BadRepr(object):

				def __repr__(self):
				return 1/0


				def test_indentation():
				"""Test correct indentation in groups"""
				count = 40
				gotoutput = pretty.pretty(MyList(range(count)))
				expectedoutput = "MyList(\n" + ",\n".join(" %d" % i for i in range(count)) + ")"

				nt.assert_equal(gotoutput, expectedoutput)


				def test_dispatch():
				"""
				Test correct dispatching: The _repr_pretty_ method for MyDict
				must be found before the registered printer for dict.
				"""
				gotoutput = pretty.pretty(MyDict())
				expectedoutput = "MyDict(...)"

				nt.assert_equal(gotoutput, expectedoutput)


				def test_callability_checking():
				"""
				Test that the _repr_pretty_ method is tested for callability and skipped if
				not.
				"""
				gotoutput = pretty.pretty(Dummy2())
				expectedoutput = "Dummy1(...)"

				nt.assert_equal(gotoutput, expectedoutput)


				def test_sets():
				"""
				Test that set and frozenset use Python 3 formatting.
				"""
				objects = [set(), frozenset(), set([1]), frozenset([1]), set([1, 2]),
				frozenset([1, 2]), set([-1, -2, -3])]
				expected = ['set()', 'frozenset()', '{1}', 'frozenset({1})', '{1, 2}',
				'frozenset({1, 2})', '{-3, -2, -1}']
				for obj, expected_output in zip(objects, expected):
				got_output = pretty.pretty(obj)
				yield nt.assert_equal, got_output, expected_output


				@skip_without('xxlimited')
				def test_pprint_heap_allocated_type():
				"""
				Test that pprint works for heap allocated types.
				"""
				import xxlimited
				output = pretty.pretty(xxlimited.Null)
				nt.assert_equal(output, 'xxlimited.Null')

				def test_pprint_nomod():
				"""
				Test that pprint works for classes with no __module__.
				"""
				output = pretty.pretty(NoModule)
				nt.assert_equal(output, 'NoModule')

				def test_pprint_break():
				"""
				Test that p.break_ produces expected output
				"""
				output = pretty.pretty(Breaking())
				expected = "TG: Breaking(\n ):"
				nt.assert_equal(output, expected)

				def test_pprint_break_repr():
				"""
				Test that p.break_ is used in repr
				"""
				output = pretty.pretty(BreakingReprParent())
				expected = "TG: Breaking(\n ):"
				nt.assert_equal(output, expected)

				def test_bad_repr():
				"""Don't catch bad repr errors"""
				with nt.assert_raises(ZeroDivisionError):
				pretty.pretty(BadRepr())

				class BadException(Exception):
				def __str__(self):
				return -1

				class ReallyBadRepr(object):
				__module__ = 1
				@property
				def __class__(self):
				raise ValueError("I am horrible")

				def __repr__(self):
				raise BadException()

				def test_really_bad_repr():
				with nt.assert_raises(BadException):
				pretty.pretty(ReallyBadRepr())


				class SA(object):
				pass

				class SB(SA):
				pass

				def test_super_repr():
				# "<super: module_name.SA, None>"
				output = pretty.pretty(super(SA))
				nt.assert_regexp_matches(output, r"<super: \S+.SA, None>")

				# "<super: module_name.SA, <module_name.SB at 0x...>>"
				sb = SB()
				output = pretty.pretty(super(SA, sb))
				nt.assert_regexp_matches(output, r"<super: \S+.SA,\s+<\S+.SB at 0x\S+>>")


				def test_long_list():
				lis = list(range(10000))
				p = pretty.pretty(lis)
				last2 = p.rsplit('\n', 2)[-2:]
				nt.assert_equal(last2, [' 999,', ' ...]'])

				def test_long_set():
				s = set(range(10000))
				p = pretty.pretty(s)
				last2 = p.rsplit('\n', 2)[-2:]
				nt.assert_equal(last2, [' 999,', ' ...}'])

				def test_long_tuple():
				tup = tuple(range(10000))
				p = pretty.pretty(tup)
				last2 = p.rsplit('\n', 2)[-2:]
				nt.assert_equal(last2, [' 999,', ' ...)'])

				def test_long_dict():
				d = { n:n for n in range(10000) }
				p = pretty.pretty(d)
				last2 = p.rsplit('\n', 2)[-2:]
				nt.assert_equal(last2, [' 999: 999,', ' ...}'])

				def test_unbound_method():
				output = pretty.pretty(MyObj.somemethod)
				nt.assert_in('MyObj.somemethod', output)


				class MetaClass(type):
				def __new__(cls, name):
				return type.__new__(cls, name, (object,), {'name': name})

				def __repr__(self):
				return "[CUSTOM REPR FOR CLASS %s]" % self.name


				ClassWithMeta = MetaClass('ClassWithMeta')


				def test_metaclass_repr():
				output = pretty.pretty(ClassWithMeta)
				nt.assert_equal(output, "[CUSTOM REPR FOR CLASS ClassWithMeta]")


				def test_unicode_repr():
				u = u"üniçodé"
				ustr = unicode_to_str(u)

				class C(object):
				def __repr__(self):
				return ustr

				c = C()
				p = pretty.pretty(c)
				nt.assert_equal(p, u)
				p = pretty.pretty([c])
				nt.assert_equal(p, u'[%s]' % u)


				def test_basic_class():
				def type_pprint_wrapper(obj, p, cycle):
				if obj is MyObj:
				type_pprint_wrapper.called = True
				return pretty._type_pprint(obj, p, cycle)
				type_pprint_wrapper.called = False

				stream = StringIO()
				printer = pretty.RepresentationPrinter(stream)
				printer.type_pprinters[type] = type_pprint_wrapper
				printer.pretty(MyObj)
				printer.flush()
				output = stream.getvalue()

				nt.assert_equal(output, '%s.MyObj' % __name__)
				nt.assert_true(type_pprint_wrapper.called)


				# This is only run on Python 2 because in Python 3 the language prevents you
				# from setting a non-unicode value for __qualname__ on a metaclass, and it
				# doesn't respect the descriptor protocol if you subclass unicode and implement
				# __get__.
				@py2_only
				def test_fallback_to__name__on_type():
				# Test that we correctly repr types that have non-string values for
				# __qualname__ by falling back to __name__

				class Type(object):
				__qualname__ = 5

				# Test repring of the type.
				stream = StringIO()
				printer = pretty.RepresentationPrinter(stream)

				printer.pretty(Type)
				printer.flush()
				output = stream.getvalue()

				# If __qualname__ is malformed, we should fall back to __name__.
				expected = '.'.join([__name__, Type.__name__])
				nt.assert_equal(output, expected)

				# Clear stream buffer.
				stream.buf = ''

				# Test repring of an instance of the type.
				instance = Type()
				printer.pretty(instance)
				printer.flush()
				output = stream.getvalue()

				# Should look like:
				# <IPython.lib.tests.test_pretty.Type at 0x7f7658ae07d0>
				prefix = '<' + '.'.join([__name__, Type.__name__]) + ' at 0x'
				nt.assert_true(output.startswith(prefix))


				@py2_only
				def test_fail_gracefully_on_bogus__qualname__and__name__():
				# Test that we correctly repr types that have non-string values for both
				# __qualname__ and __name__

				class Meta(type):
				__name__ = 5

				class Type(object):
				__metaclass__ = Meta
				__qualname__ = 5

				stream = StringIO()
				printer = pretty.RepresentationPrinter(stream)

				printer.pretty(Type)
				printer.flush()
				output = stream.getvalue()

				# If we can't find __name__ or __qualname__ just use a sentinel string.
				expected = '.'.join([__name__, '<unknown type>'])
				nt.assert_equal(output, expected)

				# Clear stream buffer.
				stream.buf = ''

				# Test repring of an instance of the type.
				instance = Type()
				printer.pretty(instance)
				printer.flush()
				output = stream.getvalue()

				# Should look like:
				# <IPython.lib.tests.test_pretty.<unknown type> at 0x7f7658ae07d0>
				prefix = '<' + '.'.join([__name__, '<unknown type>']) + ' at 0x'
				nt.assert_true(output.startswith(prefix))


				def test_collections_defaultdict():
				# Create defaultdicts with cycles
				a = defaultdict()
				a.default_factory = a
				b = defaultdict(list)
				b['key'] = b

				# Dictionary order cannot be relied on, test against single keys.
				cases = [
				(defaultdict(list), 'defaultdict(list, {})'),
				(defaultdict(list, {'key': '-' * 50}),
				"defaultdict(list,\n"
				" {'key': '--------------------------------------------------'})"),
				(a, 'defaultdict(defaultdict(...), {})'),
				(b, "defaultdict(list, {'key': defaultdict(...)})"),
				]
				for obj, expected in cases:
				nt.assert_equal(pretty.pretty(obj), expected)


				def test_collections_ordereddict():
				# Create OrderedDict with cycle
				a = OrderedDict()
				a['key'] = a

				cases = [
				(OrderedDict(), 'OrderedDict()'),
				(OrderedDict((i, i) for i in range(1000, 1010)),
				'OrderedDict([(1000, 1000),\n'
				' (1001, 1001),\n'
				' (1002, 1002),\n'
				' (1003, 1003),\n'
				' (1004, 1004),\n'
				' (1005, 1005),\n'
				' (1006, 1006),\n'
				' (1007, 1007),\n'
				' (1008, 1008),\n'
				' (1009, 1009)])'),
				(a, "OrderedDict([('key', OrderedDict(...))])"),
				]
				for obj, expected in cases:
				nt.assert_equal(pretty.pretty(obj), expected)


				def test_collections_deque():
				# Create deque with cycle
				a = deque()
				a.append(a)

				cases = [
				(deque(), 'deque([])'),
				(deque(i for i in range(1000, 1020)),
				'deque([1000,\n'
				' 1001,\n'
				' 1002,\n'
				' 1003,\n'
				' 1004,\n'
				' 1005,\n'
				' 1006,\n'
				' 1007,\n'
				' 1008,\n'
				' 1009,\n'
				' 1010,\n'
				' 1011,\n'
				' 1012,\n'
				' 1013,\n'
				' 1014,\n'
				' 1015,\n'
				' 1016,\n'
				' 1017,\n'
				' 1018,\n'
				' 1019])'),
				(a, 'deque([deque(...)])'),
				]
				for obj, expected in cases:
				nt.assert_equal(pretty.pretty(obj), expected)

				def test_collections_counter():
				class MyCounter(Counter):
				pass
				cases = [
				(Counter(), 'Counter()'),
				(Counter(a=1), "Counter({'a': 1})"),
				(MyCounter(a=1), "MyCounter({'a': 1})"),
				]
				for obj, expected in cases:
				nt.assert_equal(pretty.pretty(obj), expected)

				@py3_only
				def test_mappingproxy():
				MP = types.MappingProxyType
				underlying_dict = {}
				mp_recursive = MP(underlying_dict)
				underlying_dict[2] = mp_recursive
				underlying_dict[3] = underlying_dict

				cases = [
				(MP({}), "mappingproxy({})"),
				(MP({None: MP({})}), "mappingproxy({None: mappingproxy({})})"),
				(MP({k: k.upper() for k in string.ascii_lowercase}),
				"mappingproxy({'a': 'A',\n"
				" 'b': 'B',\n"
				" 'c': 'C',\n"
				" 'd': 'D',\n"
				" 'e': 'E',\n"
				" 'f': 'F',\n"
				" 'g': 'G',\n"
				" 'h': 'H',\n"
				" 'i': 'I',\n"
				" 'j': 'J',\n"
				" 'k': 'K',\n"
				" 'l': 'L',\n"
				" 'm': 'M',\n"
				" 'n': 'N',\n"
				" 'o': 'O',\n"
				" 'p': 'P',\n"
				" 'q': 'Q',\n"
				" 'r': 'R',\n"
				" 's': 'S',\n"
				" 't': 'T',\n"
				" 'u': 'U',\n"
				" 'v': 'V',\n"
				" 'w': 'W',\n"
				" 'x': 'X',\n"
				" 'y': 'Y',\n"
				" 'z': 'Z'})"),
				(mp_recursive, "mappingproxy({2: {...}, 3: {2: {...}, 3: {...}}})"),
				(underlying_dict,
				"{2: mappingproxy({2: {...}, 3: {...}}), 3: {...}}"),
				]
				for obj, expected in cases:
				nt.assert_equal(pretty.pretty(obj), expected)