Lib.test.test_pprint.py Maven / Gradle / Ivy
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Jython is an implementation of the high-level, dynamic, object-oriented
language Python written in 100% Pure Java, and seamlessly integrated with
the Java platform. It thus allows you to run Python on any Java platform.
import pprint
import test.test_support
import unittest
import test.test_set
try:
uni = unicode
except NameError:
def uni(x):
return x
# 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 tuple2(tuple):
pass
class tuple3(tuple):
def __repr__(self):
return tuple.__repr__(self)
class dict2(dict):
pass
class dict3(dict):
def __repr__(self):
return dict.__repr__(self)
class QueryTestCase(unittest.TestCase):
def setUp(self):
self.a = range(100)
self.b = range(200)
self.a[-12] = self.b
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}, uni("yaddayadda"),
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_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 overwrite __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, 0L, 0+0j, 0.0, "", uni(""),
(), tuple2(), tuple3(),
[], list2(), list3(),
{}, dict2(), dict3(),
self.assertTrue, pprint,
-6, -6L, -6-6j, -1.5, "x", uni("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)),
dict2({5: 6}), dict3({5: 6}),
range(10, -11, -1)
):
native = repr(simple)
for function in "pformat", "saferepr":
f = getattr(pprint, function)
got = f(simple)
self.assertEqual(native, got,
"expected %s got %s from pprint.%s" %
(native, got, function))
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)
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_subclassing(self):
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}"""
self.assertEqual(DottedPrettyPrinter().pformat(o), exp)
@unittest.skipIf(test.test_support.is_jython,
"XXX: depends on set repr order")
def test_set_reprs(self):
self.assertEqual(pprint.pformat(set()), 'set()')
self.assertEqual(pprint.pformat(set(range(3))), 'set([0, 1, 2])')
self.assertEqual(pprint.pformat(frozenset()), 'frozenset()')
self.assertEqual(pprint.pformat(frozenset(range(3))), 'frozenset([0, 1, 2])')
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)
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)
def test_main():
test.test_support.run_unittest(QueryTestCase)
if __name__ == "__main__":
test_main()