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Make event triggering robust to (un)registration....

Make event triggering robust to (un)registration. Event callbacks can register or unregister new callbacks for the same event while executing, and the previous triggering implementation allowed for event callbacks to be inadvertently skipped. The fix is to make a copy of the list of callbacks before executing any of them. With this change, the resulting semantics are simple: any callbacks registered before triggering are executed, and any new callbacks registered are only visible at the next triggering of the event. Note that this could potentially break existing callers who expected newly-appended callbacks were immediately executed. Fixes . Originally based on a patch by @marksandler2.

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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 nose.tools as nt

      from IPython.lib import pretty

      from IPython.testing.decorators import skip_without, py2_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):

              output = 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):

              output = pretty.pretty(ReallyBadRepr())

      class SA(object):

          pass

      class SB(SA):

          pass

      def test_super_repr():

          output = pretty.pretty(super(SA))

          nt.assert_in("SA", output)

          sb = SB()

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

          nt.assert_in("SA", output)

      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)

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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 nose.tools as nt

				from IPython.lib import pretty
				from IPython.testing.decorators import skip_without, py2_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):
				output = 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):
				output = pretty.pretty(ReallyBadRepr())


				class SA(object):
				pass

				class SB(SA):
				pass

				def test_super_repr():
				output = pretty.pretty(super(SA))
				nt.assert_in("SA", output)

				sb = SB()
				output = pretty.pretty(super(SA, sb))
				nt.assert_in("SA", output)


				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)