# -*- coding: utf-8 -*- import collections import contextlib import dataclasses import io import itertools import pprint import random import test.support import test.test_set import types import unittest # list, tuple and dict subclasses that do or don't overwrite __repr__ class list2(list): pass class list3(list): def __repr__(self): return list.__repr__(self) class list_custom_repr(list): def __repr__(self): return '*'*len(list.__repr__(self)) class tuple2(tuple): pass class tuple3(tuple): def __repr__(self): return tuple.__repr__(self) class tuple_custom_repr(tuple): def __repr__(self): return '*'*len(tuple.__repr__(self)) class set2(set): pass class set3(set): def __repr__(self): return set.__repr__(self) class set_custom_repr(set): def __repr__(self): return '*'*len(set.__repr__(self)) class frozenset2(frozenset): pass class frozenset3(frozenset): def __repr__(self): return frozenset.__repr__(self) class frozenset_custom_repr(frozenset): def __repr__(self): return '*'*len(frozenset.__repr__(self)) class dict2(dict): pass class dict3(dict): def __repr__(self): return dict.__repr__(self) class dict_custom_repr(dict): def __repr__(self): return '*'*len(dict.__repr__(self)) @dataclasses.dataclass class dataclass1: field1: str field2: int field3: bool = False field4: int = dataclasses.field(default=1, repr=False) @dataclasses.dataclass class dataclass2: a: int = 1 def __repr__(self): return "custom repr that doesn't fit within pprint width" @dataclasses.dataclass(repr=False) class dataclass3: a: int = 1 @dataclasses.dataclass class dataclass4: a: "dataclass4" b: int = 1 @dataclasses.dataclass class dataclass5: a: "dataclass6" b: int = 1 @dataclasses.dataclass class dataclass6: c: "dataclass5" d: int = 1 class Unorderable: def __repr__(self): return str(id(self)) # Class Orderable is orderable with any type class Orderable: def __init__(self, hash): self._hash = hash def __lt__(self, other): return False def __gt__(self, other): return self != other def __le__(self, other): return self == other def __ge__(self, other): return True def __eq__(self, other): return self is other def __ne__(self, other): return self is not other def __hash__(self): return self._hash class QueryTestCase(unittest.TestCase): def setUp(self): self.a = list(range(100)) self.b = list(range(200)) self.a[-12] = self.b def test_init(self): pp = pprint.PrettyPrinter() pp = pprint.PrettyPrinter(indent=4, width=40, depth=5, stream=io.StringIO(), compact=True) pp = pprint.PrettyPrinter(4, 40, 5, io.StringIO()) pp = pprint.PrettyPrinter(sort_dicts=False) with self.assertRaises(TypeError): pp = pprint.PrettyPrinter(4, 40, 5, io.StringIO(), True) self.assertRaises(ValueError, pprint.PrettyPrinter, indent=-1) self.assertRaises(ValueError, pprint.PrettyPrinter, depth=0) self.assertRaises(ValueError, pprint.PrettyPrinter, depth=-1) self.assertRaises(ValueError, pprint.PrettyPrinter, width=0) def test_basic(self): # Verify .isrecursive() and .isreadable() w/o recursion pp = pprint.PrettyPrinter() for safe in (2, 2.0, 2j, "abc", [3], (2,2), {3: 3}, b"def", bytearray(b"ghi"), True, False, None, ..., self.a, self.b): # module-level convenience functions self.assertFalse(pprint.isrecursive(safe), "expected not isrecursive for %r" % (safe,)) self.assertTrue(pprint.isreadable(safe), "expected isreadable for %r" % (safe,)) # PrettyPrinter methods self.assertFalse(pp.isrecursive(safe), "expected not isrecursive for %r" % (safe,)) self.assertTrue(pp.isreadable(safe), "expected isreadable for %r" % (safe,)) def test_stdout_is_None(self): with contextlib.redirect_stdout(None): # smoke test - there is no output to check value = 'this should not fail' pprint.pprint(value) pprint.PrettyPrinter().pprint(value) def test_knotted(self): # Verify .isrecursive() and .isreadable() w/ recursion # Tie a knot. self.b[67] = self.a # Messy dict. self.d = {} self.d[0] = self.d[1] = self.d[2] = self.d pp = pprint.PrettyPrinter() for icky in self.a, self.b, self.d, (self.d, self.d): self.assertTrue(pprint.isrecursive(icky), "expected isrecursive") self.assertFalse(pprint.isreadable(icky), "expected not isreadable") self.assertTrue(pp.isrecursive(icky), "expected isrecursive") self.assertFalse(pp.isreadable(icky), "expected not isreadable") # Break the cycles. self.d.clear() del self.a[:] del self.b[:] for safe in self.a, self.b, self.d, (self.d, self.d): # module-level convenience functions self.assertFalse(pprint.isrecursive(safe), "expected not isrecursive for %r" % (safe,)) self.assertTrue(pprint.isreadable(safe), "expected isreadable for %r" % (safe,)) # PrettyPrinter methods self.assertFalse(pp.isrecursive(safe), "expected not isrecursive for %r" % (safe,)) self.assertTrue(pp.isreadable(safe), "expected isreadable for %r" % (safe,)) def test_unreadable(self): # Not recursive but not readable anyway pp = pprint.PrettyPrinter() for unreadable in type(3), pprint, pprint.isrecursive: # module-level convenience functions self.assertFalse(pprint.isrecursive(unreadable), "expected not isrecursive for %r" % (unreadable,)) self.assertFalse(pprint.isreadable(unreadable), "expected not isreadable for %r" % (unreadable,)) # PrettyPrinter methods self.assertFalse(pp.isrecursive(unreadable), "expected not isrecursive for %r" % (unreadable,)) self.assertFalse(pp.isreadable(unreadable), "expected not isreadable for %r" % (unreadable,)) def test_same_as_repr(self): # Simple objects, small containers and classes that override __repr__ # to directly call super's __repr__. # For those the result should be the same as repr(). # Ahem. The docs don't say anything about that -- this appears to # be testing an implementation quirk. Starting in Python 2.5, it's # not true for dicts: pprint always sorts dicts by key now; before, # it sorted a dict display if and only if the display required # multiple lines. For that reason, dicts with more than one element # aren't tested here. for simple in (0, 0, 0+0j, 0.0, "", b"", bytearray(), (), tuple2(), tuple3(), [], list2(), list3(), set(), set2(), set3(), frozenset(), frozenset2(), frozenset3(), {}, dict2(), dict3(), self.assertTrue, pprint, -6, -6, -6-6j, -1.5, "x", b"x", bytearray(b"x"), (3,), [3], {3: 6}, (1,2), [3,4], {5: 6}, tuple2((1,2)), tuple3((1,2)), tuple3(range(100)), [3,4], list2([3,4]), list3([3,4]), list3(range(100)), set({7}), set2({7}), set3({7}), frozenset({8}), frozenset2({8}), frozenset3({8}), dict2({5: 6}), dict3({5: 6}), range(10, -11, -1), True, False, None, ..., ): native = repr(simple) self.assertEqual(pprint.pformat(simple), native) self.assertEqual(pprint.pformat(simple, width=1, indent=0) .replace('\n', ' '), native) self.assertEqual(pprint.pformat(simple, underscore_numbers=True), native) self.assertEqual(pprint.saferepr(simple), native) def test_container_repr_override_called(self): N = 1000 # Ensure that __repr__ override is called for subclasses of containers for cont in (list_custom_repr(), list_custom_repr([1,2,3]), list_custom_repr(range(N)), tuple_custom_repr(), tuple_custom_repr([1,2,3]), tuple_custom_repr(range(N)), set_custom_repr(), set_custom_repr([1,2,3]), set_custom_repr(range(N)), frozenset_custom_repr(), frozenset_custom_repr([1,2,3]), frozenset_custom_repr(range(N)), dict_custom_repr(), dict_custom_repr({5: 6}), dict_custom_repr(zip(range(N),range(N))), ): native = repr(cont) expected = '*' * len(native) self.assertEqual(pprint.pformat(cont), expected) self.assertEqual(pprint.pformat(cont, width=1, indent=0), expected) self.assertEqual(pprint.saferepr(cont), expected) def test_basic_line_wrap(self): # verify basic line-wrapping operation o = {'RPM_cal': 0, 'RPM_cal2': 48059, 'Speed_cal': 0, 'controldesk_runtime_us': 0, 'main_code_runtime_us': 0, 'read_io_runtime_us': 0, 'write_io_runtime_us': 43690} exp = """\ {'RPM_cal': 0, 'RPM_cal2': 48059, 'Speed_cal': 0, 'controldesk_runtime_us': 0, 'main_code_runtime_us': 0, 'read_io_runtime_us': 0, 'write_io_runtime_us': 43690}""" for type in [dict, dict2]: self.assertEqual(pprint.pformat(type(o)), exp) o = range(100) exp = '[%s]' % ',\n '.join(map(str, o)) for type in [list, list2]: self.assertEqual(pprint.pformat(type(o)), exp) o = tuple(range(100)) exp = '(%s)' % ',\n '.join(map(str, o)) for type in [tuple, tuple2]: self.assertEqual(pprint.pformat(type(o)), exp) # indent parameter o = range(100) exp = '[ %s]' % ',\n '.join(map(str, o)) for type in [list, list2]: self.assertEqual(pprint.pformat(type(o), indent=4), exp) def test_nested_indentations(self): o1 = list(range(10)) o2 = dict(first=1, second=2, third=3) o = [o1, o2] expected = """\ [ [0, 1, 2, 3, 4, 5, 6, 7, 8, 9], {'first': 1, 'second': 2, 'third': 3}]""" self.assertEqual(pprint.pformat(o, indent=4, width=42), expected) expected = """\ [ [0, 1, 2, 3, 4, 5, 6, 7, 8, 9], { 'first': 1, 'second': 2, 'third': 3}]""" self.assertEqual(pprint.pformat(o, indent=4, width=41), expected) def test_width(self): expected = """\ [[[[[[1, 2, 3], '1 2']]]], {1: [1, 2, 3], 2: [12, 34]}, 'abc def ghi', ('ab cd ef',), set2({1, 23}), [[[[[1, 2, 3], '1 2']]]]]""" o = eval(expected) self.assertEqual(pprint.pformat(o, width=15), expected) self.assertEqual(pprint.pformat(o, width=16), expected) self.assertEqual(pprint.pformat(o, width=25), expected) self.assertEqual(pprint.pformat(o, width=14), """\ [[[[[[1, 2, 3], '1 ' '2']]]], {1: [1, 2, 3], 2: [12, 34]}, 'abc def ' 'ghi', ('ab cd ' 'ef',), set2({1, 23}), [[[[[1, 2, 3], '1 ' '2']]]]]""") def test_integer(self): self.assertEqual(pprint.pformat(1234567), '1234567') self.assertEqual(pprint.pformat(1234567, underscore_numbers=True), '1_234_567') class Temperature(int): def __new__(cls, celsius_degrees): return super().__new__(Temperature, celsius_degrees) def __repr__(self): kelvin_degrees = self + 273.15 return f"{kelvin_degrees}°K" self.assertEqual(pprint.pformat(Temperature(1000)), '1273.15°K') def test_sorted_dict(self): # Starting in Python 2.5, pprint sorts dict displays by key regardless # of how small the dictionary may be. # Before the change, on 32-bit Windows pformat() gave order # 'a', 'c', 'b' here, so this test failed. d = {'a': 1, 'b': 1, 'c': 1} self.assertEqual(pprint.pformat(d), "{'a': 1, 'b': 1, 'c': 1}") self.assertEqual(pprint.pformat([d, d]), "[{'a': 1, 'b': 1, 'c': 1}, {'a': 1, 'b': 1, 'c': 1}]") # The next one is kind of goofy. The sorted order depends on the # alphabetic order of type names: "int" < "str" < "tuple". Before # Python 2.5, this was in the test_same_as_repr() test. It's worth # keeping around for now because it's one of few tests of pprint # against a crazy mix of types. self.assertEqual(pprint.pformat({"xy\tab\n": (3,), 5: [[]], (): {}}), r"{5: [[]], 'xy\tab\n': (3,), (): {}}") def test_sort_dict(self): d = dict.fromkeys('cba') self.assertEqual(pprint.pformat(d, sort_dicts=False), "{'c': None, 'b': None, 'a': None}") self.assertEqual(pprint.pformat([d, d], sort_dicts=False), "[{'c': None, 'b': None, 'a': None}, {'c': None, 'b': None, 'a': None}]") def test_ordered_dict(self): d = collections.OrderedDict() self.assertEqual(pprint.pformat(d, width=1), 'OrderedDict()') d = collections.OrderedDict([]) self.assertEqual(pprint.pformat(d, width=1), 'OrderedDict()') words = 'the quick brown fox jumped over a lazy dog'.split() d = collections.OrderedDict(zip(words, itertools.count())) self.assertEqual(pprint.pformat(d), """\ OrderedDict([('the', 0), ('quick', 1), ('brown', 2), ('fox', 3), ('jumped', 4), ('over', 5), ('a', 6), ('lazy', 7), ('dog', 8)])""") def test_mapping_proxy(self): words = 'the quick brown fox jumped over a lazy dog'.split() d = dict(zip(words, itertools.count())) m = types.MappingProxyType(d) self.assertEqual(pprint.pformat(m), """\ mappingproxy({'a': 6, 'brown': 2, 'dog': 8, 'fox': 3, 'jumped': 4, 'lazy': 7, 'over': 5, 'quick': 1, 'the': 0})""") d = collections.OrderedDict(zip(words, itertools.count())) m = types.MappingProxyType(d) self.assertEqual(pprint.pformat(m), """\ mappingproxy(OrderedDict([('the', 0), ('quick', 1), ('brown', 2), ('fox', 3), ('jumped', 4), ('over', 5), ('a', 6), ('lazy', 7), ('dog', 8)]))""") def test_empty_simple_namespace(self): ns = types.SimpleNamespace() formatted = pprint.pformat(ns) self.assertEqual(formatted, "namespace()") def test_small_simple_namespace(self): ns = types.SimpleNamespace(a=1, b=2) formatted = pprint.pformat(ns) self.assertEqual(formatted, "namespace(a=1, b=2)") def test_simple_namespace(self): ns = types.SimpleNamespace( the=0, quick=1, brown=2, fox=3, jumped=4, over=5, a=6, lazy=7, dog=8, ) formatted = pprint.pformat(ns, width=60, indent=4) self.assertEqual(formatted, """\ namespace(the=0, quick=1, brown=2, fox=3, jumped=4, over=5, a=6, lazy=7, dog=8)""") def test_simple_namespace_subclass(self): class AdvancedNamespace(types.SimpleNamespace): pass ns = AdvancedNamespace( the=0, quick=1, brown=2, fox=3, jumped=4, over=5, a=6, lazy=7, dog=8, ) formatted = pprint.pformat(ns, width=60) self.assertEqual(formatted, """\ AdvancedNamespace(the=0, quick=1, brown=2, fox=3, jumped=4, over=5, a=6, lazy=7, dog=8)""") def test_empty_dataclass(self): dc = dataclasses.make_dataclass("MyDataclass", ())() formatted = pprint.pformat(dc) self.assertEqual(formatted, "MyDataclass()") def test_small_dataclass(self): dc = dataclass1("text", 123) formatted = pprint.pformat(dc) self.assertEqual(formatted, "dataclass1(field1='text', field2=123, field3=False)") def test_larger_dataclass(self): dc = dataclass1("some fairly long text", int(1e10), True) formatted = pprint.pformat([dc, dc], width=60, indent=4) self.assertEqual(formatted, """\ [ dataclass1(field1='some fairly long text', field2=10000000000, field3=True), dataclass1(field1='some fairly long text', field2=10000000000, field3=True)]""") def test_dataclass_with_repr(self): dc = dataclass2() formatted = pprint.pformat(dc, width=20) self.assertEqual(formatted, "custom repr that doesn't fit within pprint width") def test_dataclass_no_repr(self): dc = dataclass3() formatted = pprint.pformat(dc, width=10) self.assertRegex(formatted, r"<test.test_pprint.dataclass3 object at \w+>") def test_recursive_dataclass(self): dc = dataclass4(None) dc.a = dc formatted = pprint.pformat(dc, width=10) self.assertEqual(formatted, """\ dataclass4(a=..., b=1)""") def test_cyclic_dataclass(self): dc5 = dataclass5(None) dc6 = dataclass6(None) dc5.a = dc6 dc6.c = dc5 formatted = pprint.pformat(dc5, width=10) self.assertEqual(formatted, """\ dataclass5(a=dataclass6(c=..., d=1), b=1)""") def test_subclassing(self): # length(repr(obj)) > width o = {'names with spaces': 'should be presented using repr()', 'others.should.not.be': 'like.this'} exp = """\ {'names with spaces': 'should be presented using repr()', others.should.not.be: like.this}""" dotted_printer = DottedPrettyPrinter() self.assertEqual(dotted_printer.pformat(o), exp) # length(repr(obj)) < width o1 = ['with space'] exp1 = "['with space']" self.assertEqual(dotted_printer.pformat(o1), exp1) o2 = ['without.space'] exp2 = "[without.space]" self.assertEqual(dotted_printer.pformat(o2), exp2) def test_set_reprs(self): self.assertEqual(pprint.pformat(set()), 'set()') self.assertEqual(pprint.pformat(set(range(3))), '{0, 1, 2}') self.assertEqual(pprint.pformat(set(range(7)), width=20), '''\ {0, 1, 2, 3, 4, 5, 6}''') self.assertEqual(pprint.pformat(set2(range(7)), width=20), '''\ set2({0, 1, 2, 3, 4, 5, 6})''') self.assertEqual(pprint.pformat(set3(range(7)), width=20), 'set3({0, 1, 2, 3, 4, 5, 6})') self.assertEqual(pprint.pformat(frozenset()), 'frozenset()') self.assertEqual(pprint.pformat(frozenset(range(3))), 'frozenset({0, 1, 2})') self.assertEqual(pprint.pformat(frozenset(range(7)), width=20), '''\ frozenset({0, 1, 2, 3, 4, 5, 6})''') self.assertEqual(pprint.pformat(frozenset2(range(7)), width=20), '''\ frozenset2({0, 1, 2, 3, 4, 5, 6})''') self.assertEqual(pprint.pformat(frozenset3(range(7)), width=20), 'frozenset3({0, 1, 2, 3, 4, 5, 6})') @unittest.expectedFailure #See http://bugs.python.org/issue13907 @test.support.cpython_only def test_set_of_sets_reprs(self): # This test creates a complex arrangement of frozensets and # compares the pretty-printed repr against a string hard-coded in # the test. The hard-coded repr depends on the sort order of # frozensets. # # However, as the docs point out: "Since sets only define # partial ordering (subset relationships), the output of the # list.sort() method is undefined for lists of sets." # # In a nutshell, the test assumes frozenset({0}) will always # sort before frozenset({1}), but: # # >>> frozenset({0}) < frozenset({1}) # False # >>> frozenset({1}) < frozenset({0}) # False # # Consequently, this test is fragile and # implementation-dependent. Small changes to Python's sort # algorithm cause the test to fail when it should pass. # XXX Or changes to the dictionary implementation... cube_repr_tgt = """\ {frozenset(): frozenset({frozenset({2}), frozenset({0}), frozenset({1})}), frozenset({0}): frozenset({frozenset(), frozenset({0, 2}), frozenset({0, 1})}), frozenset({1}): frozenset({frozenset(), frozenset({1, 2}), frozenset({0, 1})}), frozenset({2}): frozenset({frozenset(), frozenset({1, 2}), frozenset({0, 2})}), frozenset({1, 2}): frozenset({frozenset({2}), frozenset({1}), frozenset({0, 1, 2})}), frozenset({0, 2}): frozenset({frozenset({2}), frozenset({0}), frozenset({0, 1, 2})}), frozenset({0, 1}): frozenset({frozenset({0}), frozenset({1}), frozenset({0, 1, 2})}), frozenset({0, 1, 2}): frozenset({frozenset({1, 2}), frozenset({0, 2}), frozenset({0, 1})})}""" cube = test.test_set.cube(3) self.assertEqual(pprint.pformat(cube), cube_repr_tgt) cubo_repr_tgt = """\ {frozenset({frozenset({0, 2}), frozenset({0})}): frozenset({frozenset({frozenset({0, 2}), frozenset({0, 1, 2})}), frozenset({frozenset({0}), frozenset({0, 1})}), frozenset({frozenset(), frozenset({0})}), frozenset({frozenset({2}), frozenset({0, 2})})}), frozenset({frozenset({0, 1}), frozenset({1})}): frozenset({frozenset({frozenset({0, 1}), frozenset({0, 1, 2})}), frozenset({frozenset({0}), frozenset({0, 1})}), frozenset({frozenset({1}), frozenset({1, 2})}), frozenset({frozenset(), frozenset({1})})}), frozenset({frozenset({1, 2}), frozenset({1})}): frozenset({frozenset({frozenset({1, 2}), frozenset({0, 1, 2})}), frozenset({frozenset({2}), frozenset({1, 2})}), frozenset({frozenset(), frozenset({1})}), frozenset({frozenset({1}), frozenset({0, 1})})}), frozenset({frozenset({1, 2}), frozenset({2})}): frozenset({frozenset({frozenset({1, 2}), frozenset({0, 1, 2})}), frozenset({frozenset({1}), frozenset({1, 2})}), frozenset({frozenset({2}), frozenset({0, 2})}), frozenset({frozenset(), frozenset({2})})}), frozenset({frozenset(), frozenset({0})}): frozenset({frozenset({frozenset({0}), frozenset({0, 1})}), frozenset({frozenset({0}), frozenset({0, 2})}), frozenset({frozenset(), frozenset({1})}), frozenset({frozenset(), frozenset({2})})}), frozenset({frozenset(), frozenset({1})}): frozenset({frozenset({frozenset(), frozenset({0})}), frozenset({frozenset({1}), frozenset({1, 2})}), frozenset({frozenset(), frozenset({2})}), frozenset({frozenset({1}), frozenset({0, 1})})}), frozenset({frozenset({2}), frozenset()}): frozenset({frozenset({frozenset({2}), frozenset({1, 2})}), frozenset({frozenset(), frozenset({0})}), frozenset({frozenset(), frozenset({1})}), frozenset({frozenset({2}), frozenset({0, 2})})}), frozenset({frozenset({0, 1, 2}), frozenset({0, 1})}): frozenset({frozenset({frozenset({1, 2}), frozenset({0, 1, 2})}), frozenset({frozenset({0, 2}), frozenset({0, 1, 2})}), frozenset({frozenset({0}), frozenset({0, 1})}), frozenset({frozenset({1}), frozenset({0, 1})})}), frozenset({frozenset({0}), frozenset({0, 1})}): frozenset({frozenset({frozenset(), frozenset({0})}), frozenset({frozenset({0, 1}), frozenset({0, 1, 2})}), frozenset({frozenset({0}), frozenset({0, 2})}), frozenset({frozenset({1}), frozenset({0, 1})})}), frozenset({frozenset({2}), frozenset({0, 2})}): frozenset({frozenset({frozenset({0, 2}), frozenset({0, 1, 2})}), frozenset({frozenset({2}), frozenset({1, 2})}), frozenset({frozenset({0}), frozenset({0, 2})}), frozenset({frozenset(), frozenset({2})})}), frozenset({frozenset({0, 1, 2}), frozenset({0, 2})}): frozenset({frozenset({frozenset({1, 2}), frozenset({0, 1, 2})}), frozenset({frozenset({0, 1}), frozenset({0, 1, 2})}), frozenset({frozenset({0}), frozenset({0, 2})}), frozenset({frozenset({2}), frozenset({0, 2})})}), frozenset({frozenset({1, 2}), frozenset({0, 1, 2})}): frozenset({frozenset({frozenset({0, 2}), frozenset({0, 1, 2})}), frozenset({frozenset({0, 1}), frozenset({0, 1, 2})}), frozenset({frozenset({2}), frozenset({1, 2})}), frozenset({frozenset({1}), frozenset({1, 2})})})}""" cubo = test.test_set.linegraph(cube) self.assertEqual(pprint.pformat(cubo), cubo_repr_tgt) def test_depth(self): nested_tuple = (1, (2, (3, (4, (5, 6))))) nested_dict = {1: {2: {3: {4: {5: {6: 6}}}}}} nested_list = [1, [2, [3, [4, [5, [6, []]]]]]] self.assertEqual(pprint.pformat(nested_tuple), repr(nested_tuple)) self.assertEqual(pprint.pformat(nested_dict), repr(nested_dict)) self.assertEqual(pprint.pformat(nested_list), repr(nested_list)) lv1_tuple = '(1, (...))' lv1_dict = '{1: {...}}' lv1_list = '[1, [...]]' self.assertEqual(pprint.pformat(nested_tuple, depth=1), lv1_tuple) self.assertEqual(pprint.pformat(nested_dict, depth=1), lv1_dict) self.assertEqual(pprint.pformat(nested_list, depth=1), lv1_list) def test_sort_unorderable_values(self): # Issue 3976: sorted pprints fail for unorderable values. n = 20 keys = [Unorderable() for i in range(n)] random.shuffle(keys) skeys = sorted(keys, key=id) clean = lambda s: s.replace(' ', '').replace('\n','') self.assertEqual(clean(pprint.pformat(set(keys))), '{' + ','.join(map(repr, skeys)) + '}') self.assertEqual(clean(pprint.pformat(frozenset(keys))), 'frozenset({' + ','.join(map(repr, skeys)) + '})') self.assertEqual(clean(pprint.pformat(dict.fromkeys(keys))), '{' + ','.join('%r:None' % k for k in skeys) + '}') # Issue 10017: TypeError on user-defined types as dict keys. self.assertEqual(pprint.pformat({Unorderable: 0, 1: 0}), '{1: 0, ' + repr(Unorderable) +': 0}') # Issue 14998: TypeError on tuples with NoneTypes as dict keys. keys = [(1,), (None,)] self.assertEqual(pprint.pformat(dict.fromkeys(keys, 0)), '{%r: 0, %r: 0}' % tuple(sorted(keys, key=id))) def test_sort_orderable_and_unorderable_values(self): # Issue 22721: sorted pprints is not stable a = Unorderable() b = Orderable(hash(a)) # should have the same hash value # self-test self.assertLess(a, b) self.assertLess(str(type(b)), str(type(a))) self.assertEqual(sorted([b, a]), [a, b]) self.assertEqual(sorted([a, b]), [a, b]) # set self.assertEqual(pprint.pformat(set([b, a]), width=1), '{%r,\n %r}' % (a, b)) self.assertEqual(pprint.pformat(set([a, b]), width=1), '{%r,\n %r}' % (a, b)) # dict self.assertEqual(pprint.pformat(dict.fromkeys([b, a]), width=1), '{%r: None,\n %r: None}' % (a, b)) self.assertEqual(pprint.pformat(dict.fromkeys([a, b]), width=1), '{%r: None,\n %r: None}' % (a, b)) def test_str_wrap(self): # pprint tries to wrap strings intelligently fox = 'the quick brown fox jumped over a lazy dog' self.assertEqual(pprint.pformat(fox, width=19), """\ ('the quick brown ' 'fox jumped over ' 'a lazy dog')""") self.assertEqual(pprint.pformat({'a': 1, 'b': fox, 'c': 2}, width=25), """\ {'a': 1, 'b': 'the quick brown ' 'fox jumped over ' 'a lazy dog', 'c': 2}""") # With some special characters # - \n always triggers a new line in the pprint # - \t and \n are escaped # - non-ASCII is allowed # - an apostrophe doesn't disrupt the pprint special = "Portons dix bons \"whiskys\"\nà l'avocat goujat\t qui fumait au zoo" self.assertEqual(pprint.pformat(special, width=68), repr(special)) self.assertEqual(pprint.pformat(special, width=31), """\ ('Portons dix bons "whiskys"\\n' "à l'avocat goujat\\t qui " 'fumait au zoo')""") self.assertEqual(pprint.pformat(special, width=20), """\ ('Portons dix bons ' '"whiskys"\\n' "à l'avocat " 'goujat\\t qui ' 'fumait au zoo')""") self.assertEqual(pprint.pformat([[[[[special]]]]], width=35), """\ [[[[['Portons dix bons "whiskys"\\n' "à l'avocat goujat\\t qui " 'fumait au zoo']]]]]""") self.assertEqual(pprint.pformat([[[[[special]]]]], width=25), """\ [[[[['Portons dix bons ' '"whiskys"\\n' "à l'avocat " 'goujat\\t qui ' 'fumait au zoo']]]]]""") self.assertEqual(pprint.pformat([[[[[special]]]]], width=23), """\ [[[[['Portons dix ' 'bons "whiskys"\\n' "à l'avocat " 'goujat\\t qui ' 'fumait au ' 'zoo']]]]]""") # An unwrappable string is formatted as its repr unwrappable = "x" * 100 self.assertEqual(pprint.pformat(unwrappable, width=80), repr(unwrappable)) self.assertEqual(pprint.pformat(''), "''") # Check that the pprint is a usable repr special *= 10 for width in range(3, 40): formatted = pprint.pformat(special, width=width) self.assertEqual(eval(formatted), special) formatted = pprint.pformat([special] * 2, width=width) self.assertEqual(eval(formatted), [special] * 2) def test_compact(self): o = ([list(range(i * i)) for i in range(5)] + [list(range(i)) for i in range(6)]) expected = """\ [[], [0], [0, 1, 2, 3], [0, 1, 2, 3, 4, 5, 6, 7, 8], [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15], [], [0], [0, 1], [0, 1, 2], [0, 1, 2, 3], [0, 1, 2, 3, 4]]""" self.assertEqual(pprint.pformat(o, width=47, compact=True), expected) def test_compact_width(self): levels = 20 number = 10 o = [0] * number for i in range(levels - 1): o = [o] for w in range(levels * 2 + 1, levels + 3 * number - 1): lines = pprint.pformat(o, width=w, compact=True).splitlines() maxwidth = max(map(len, lines)) self.assertLessEqual(maxwidth, w) self.assertGreater(maxwidth, w - 3) def test_bytes_wrap(self): self.assertEqual(pprint.pformat(b'', width=1), "b''") self.assertEqual(pprint.pformat(b'abcd', width=1), "b'abcd'") letters = b'abcdefghijklmnopqrstuvwxyz' self.assertEqual(pprint.pformat(letters, width=29), repr(letters)) self.assertEqual(pprint.pformat(letters, width=19), """\ (b'abcdefghijkl' b'mnopqrstuvwxyz')""") self.assertEqual(pprint.pformat(letters, width=18), """\ (b'abcdefghijkl' b'mnopqrstuvwx' b'yz')""") self.assertEqual(pprint.pformat(letters, width=16), """\ (b'abcdefghijkl' b'mnopqrstuvwx' b'yz')""") special = bytes(range(16)) self.assertEqual(pprint.pformat(special, width=61), repr(special)) self.assertEqual(pprint.pformat(special, width=48), """\ (b'\\x00\\x01\\x02\\x03\\x04\\x05\\x06\\x07\\x08\\t\\n\\x0b' b'\\x0c\\r\\x0e\\x0f')""") self.assertEqual(pprint.pformat(special, width=32), """\ (b'\\x00\\x01\\x02\\x03' b'\\x04\\x05\\x06\\x07\\x08\\t\\n\\x0b' b'\\x0c\\r\\x0e\\x0f')""") self.assertEqual(pprint.pformat(special, width=1), """\ (b'\\x00\\x01\\x02\\x03' b'\\x04\\x05\\x06\\x07' b'\\x08\\t\\n\\x0b' b'\\x0c\\r\\x0e\\x0f')""") self.assertEqual(pprint.pformat({'a': 1, 'b': letters, 'c': 2}, width=21), """\ {'a': 1, 'b': b'abcdefghijkl' b'mnopqrstuvwx' b'yz', 'c': 2}""") self.assertEqual(pprint.pformat({'a': 1, 'b': letters, 'c': 2}, width=20), """\ {'a': 1, 'b': b'abcdefgh' b'ijklmnop' b'qrstuvwxyz', 'c': 2}""") self.assertEqual(pprint.pformat([[[[[[letters]]]]]], width=25), """\ [[[[[[b'abcdefghijklmnop' b'qrstuvwxyz']]]]]]""") self.assertEqual(pprint.pformat([[[[[[special]]]]]], width=41), """\ [[[[[[b'\\x00\\x01\\x02\\x03\\x04\\x05\\x06\\x07' b'\\x08\\t\\n\\x0b\\x0c\\r\\x0e\\x0f']]]]]]""") # Check that the pprint is a usable repr for width in range(1, 64): formatted = pprint.pformat(special, width=width) self.assertEqual(eval(formatted), special) formatted = pprint.pformat([special] * 2, width=width) self.assertEqual(eval(formatted), [special] * 2) def test_bytearray_wrap(self): self.assertEqual(pprint.pformat(bytearray(), width=1), "bytearray(b'')") letters = bytearray(b'abcdefghijklmnopqrstuvwxyz') self.assertEqual(pprint.pformat(letters, width=40), repr(letters)) self.assertEqual(pprint.pformat(letters, width=28), """\ bytearray(b'abcdefghijkl' b'mnopqrstuvwxyz')""") self.assertEqual(pprint.pformat(letters, width=27), """\ bytearray(b'abcdefghijkl' b'mnopqrstuvwx' b'yz')""") self.assertEqual(pprint.pformat(letters, width=25), """\ bytearray(b'abcdefghijkl' b'mnopqrstuvwx' b'yz')""") special = bytearray(range(16)) self.assertEqual(pprint.pformat(special, width=72), repr(special)) self.assertEqual(pprint.pformat(special, width=57), """\ bytearray(b'\\x00\\x01\\x02\\x03\\x04\\x05\\x06\\x07\\x08\\t\\n\\x0b' b'\\x0c\\r\\x0e\\x0f')""") self.assertEqual(pprint.pformat(special, width=41), """\ bytearray(b'\\x00\\x01\\x02\\x03' b'\\x04\\x05\\x06\\x07\\x08\\t\\n\\x0b' b'\\x0c\\r\\x0e\\x0f')""") self.assertEqual(pprint.pformat(special, width=1), """\ bytearray(b'\\x00\\x01\\x02\\x03' b'\\x04\\x05\\x06\\x07' b'\\x08\\t\\n\\x0b' b'\\x0c\\r\\x0e\\x0f')""") self.assertEqual(pprint.pformat({'a': 1, 'b': letters, 'c': 2}, width=31), """\ {'a': 1, 'b': bytearray(b'abcdefghijkl' b'mnopqrstuvwx' b'yz'), 'c': 2}""") self.assertEqual(pprint.pformat([[[[[letters]]]]], width=37), """\ [[[[[bytearray(b'abcdefghijklmnop' b'qrstuvwxyz')]]]]]""") self.assertEqual(pprint.pformat([[[[[special]]]]], width=50), """\ [[[[[bytearray(b'\\x00\\x01\\x02\\x03\\x04\\x05\\x06\\x07' b'\\x08\\t\\n\\x0b\\x0c\\r\\x0e\\x0f')]]]]]""") def test_default_dict(self): d = collections.defaultdict(int) self.assertEqual(pprint.pformat(d, width=1), "defaultdict(<class 'int'>, {})") words = 'the quick brown fox jumped over a lazy dog'.split() d = collections.defaultdict(int, zip(words, itertools.count())) self.assertEqual(pprint.pformat(d), """\ defaultdict(<class 'int'>, {'a': 6, 'brown': 2, 'dog': 8, 'fox': 3, 'jumped': 4, 'lazy': 7, 'over': 5, 'quick': 1, 'the': 0})""") def test_counter(self): d = collections.Counter() self.assertEqual(pprint.pformat(d, width=1), "Counter()") d = collections.Counter('senselessness') self.assertEqual(pprint.pformat(d, width=40), """\ Counter({'s': 6, 'e': 4, 'n': 2, 'l': 1})""") def test_chainmap(self): d = collections.ChainMap() self.assertEqual(pprint.pformat(d, width=1), "ChainMap({})") words = 'the quick brown fox jumped over a lazy dog'.split() items = list(zip(words, itertools.count())) d = collections.ChainMap(dict(items)) self.assertEqual(pprint.pformat(d), """\ ChainMap({'a': 6, 'brown': 2, 'dog': 8, 'fox': 3, 'jumped': 4, 'lazy': 7, 'over': 5, 'quick': 1, 'the': 0})""") d = collections.ChainMap(dict(items), collections.OrderedDict(items)) self.assertEqual(pprint.pformat(d), """\ ChainMap({'a': 6, 'brown': 2, 'dog': 8, 'fox': 3, 'jumped': 4, 'lazy': 7, 'over': 5, 'quick': 1, 'the': 0}, OrderedDict([('the', 0), ('quick', 1), ('brown', 2), ('fox', 3), ('jumped', 4), ('over', 5), ('a', 6), ('lazy', 7), ('dog', 8)]))""") def test_deque(self): d = collections.deque() self.assertEqual(pprint.pformat(d, width=1), "deque([])") d = collections.deque(maxlen=7) self.assertEqual(pprint.pformat(d, width=1), "deque([], maxlen=7)") words = 'the quick brown fox jumped over a lazy dog'.split() d = collections.deque(zip(words, itertools.count())) self.assertEqual(pprint.pformat(d), """\ deque([('the', 0), ('quick', 1), ('brown', 2), ('fox', 3), ('jumped', 4), ('over', 5), ('a', 6), ('lazy', 7), ('dog', 8)])""") d = collections.deque(zip(words, itertools.count()), maxlen=7) self.assertEqual(pprint.pformat(d), """\ deque([('brown', 2), ('fox', 3), ('jumped', 4), ('over', 5), ('a', 6), ('lazy', 7), ('dog', 8)], maxlen=7)""") def test_user_dict(self): d = collections.UserDict() self.assertEqual(pprint.pformat(d, width=1), "{}") words = 'the quick brown fox jumped over a lazy dog'.split() d = collections.UserDict(zip(words, itertools.count())) self.assertEqual(pprint.pformat(d), """\ {'a': 6, 'brown': 2, 'dog': 8, 'fox': 3, 'jumped': 4, 'lazy': 7, 'over': 5, 'quick': 1, 'the': 0}""") def test_user_list(self): d = collections.UserList() self.assertEqual(pprint.pformat(d, width=1), "[]") words = 'the quick brown fox jumped over a lazy dog'.split() d = collections.UserList(zip(words, itertools.count())) self.assertEqual(pprint.pformat(d), """\ [('the', 0), ('quick', 1), ('brown', 2), ('fox', 3), ('jumped', 4), ('over', 5), ('a', 6), ('lazy', 7), ('dog', 8)]""") def test_user_string(self): d = collections.UserString('') self.assertEqual(pprint.pformat(d, width=1), "''") d = collections.UserString('the quick brown fox jumped over a lazy dog') self.assertEqual(pprint.pformat(d, width=20), """\ ('the quick brown ' 'fox jumped over ' 'a lazy dog')""") self.assertEqual(pprint.pformat({1: d}, width=20), """\ {1: 'the quick ' 'brown fox ' 'jumped over a ' 'lazy dog'}""") class DottedPrettyPrinter(pprint.PrettyPrinter): def format(self, object, context, maxlevels, level): if isinstance(object, str): if ' ' in object: return repr(object), 1, 0 else: return object, 0, 0 else: return pprint.PrettyPrinter.format( self, object, context, maxlevels, level) if __name__ == "__main__": unittest.main() SIMPAN PERUBAHAN