Hacked By AnonymousFox
from guppy.heapy.test import support
import inspect
import unittest
class TestCase(support.TestCase):
def setUp(self):
support.TestCase.setUp(self)
self.Path = self.heapy.Path
def chkrel(self, src, dst, relstr=None, clas=None):
rel = self.relation(src, dst)
if clas is not None:
self.assertTrue(isinstance(rel, clas))
if relstr is None:
print(rel)
else:
sr = str(rel)
if sr.startswith('<') and not relstr.startswith('<'):
self.assertTrue(sr.endswith('>'))
sr = sr[1:-1].split(',')
self.assertTrue(relstr in sr)
else:
self.aseq(sr, relstr)
def chkrelattr(self, src, *attrs):
for attr in attrs:
self.chkrel(src, getattr(src, attr), '%s.'+attr)
def chkpath(self, src, dst, expect=None):
rel = self.shpaths(dst, src)
if expect is None:
print(rel)
else:
li = rel.aslist()
if len(li) == 1:
li = li[0]
self.aseq(str(li), str(expect), -1)
def relation(self, src, dst):
return self.Path.relation(src, dst)
def shpaths(self, dst, src=None, *args, **kwds):
# return self.Path.shpaths(dst, src, *args, **kwds)
dst = self.iso(dst)
if src is not None:
src = self.iso(src)
return dst.get_shpaths(src, *args, **kwds)
class RelationTestCase(TestCase):
# Test relations from standard types and some simple paths
def test_cell_relation(self):
cellvalue = []
def f():
return cellvalue
self.chkrel(f.__closure__[0], cellvalue, '%s.cell_contents')
def test_code_relation(self):
def f():
a = 3
return self, a
co = f.__code__
# xxx brittle test but catches a bug
self.chkpath(co, 3, '%s.co_consts[1]')
# commented in notes Sep 27 2004
relAttr = ('co_code', 'co_consts', 'co_names',
'co_filename', 'co_name')
if self.version_info < (3, 11):
relAttr += ('co_varnames', 'co_freevars', 'co_cellvars')
else:
relAttr += ('co_exceptiontable', 'co_qualname')
if self.version_info >= (3, 10):
relAttr += ('co_linetable',)
else:
relAttr += ('co_lnotab',)
self.chkrelattr(co, *relAttr)
def test_dict_relation(self):
k1 = 'k1'
k2 = 'k2'
v1 = 'v1'
v2 = 'v2'
k3 = tuple(range(100))
v3 = tuple(range(100, 200))
x = {k1: v1, k2: v2, k3: v3}
self.chkrel(x, v1, "%s['k1']")
self.chkrel(x, v2, "%s['k2']")
self.chkrel(x, v3, "%s[(0, 1, 2, 3, 4, 5, ...)]")
ks = [str(self.relation(x, k1)),
str(self.relation(x, k2)),
str(self.relation(x, k3))]
ks.sort()
self.aseq(ks, ['%s.keys()[0]', '%s.keys()[1]', '%s.keys()[2]'])
def test_dictproxy_relation(self):
v1 = 'v1'
class T(object):
k1 = v1
x = T.__dict__
self.chkpath(x, v1, "%s->mapping['k1']")
self.chkrel(x, v1, "%s['k1']")
def test_frame_relation(self):
f = inspect.currentframe()
f.f_trace = lambda: None
self.chkrelattr(f, 'f_back', 'f_builtins', 'f_code', 'f_globals',
'f_locals', 'f_trace')
a = []
# The representation of local variables is how they may be accessed
# - not how they are really stored.
# xxx this may be confusing/lack information?
# The information is available in the relation object class,
# it is just not represented with str()...
self.chkrel(f, a, "%s.f_locals['a']", clas=self.Path.R_LOCAL_VAR)
x = []
z = []
def func(x, y=3):
frame = inspect.currentframe()
return self, frame, z
_, frame, __ = func(0)
del _, __
self.chkrel(frame, self, "%s.f_locals ['self']", clas=self.Path.R_CELL)
self.chkrel(f, x, "%s.f_locals['x']", clas=self.Path.R_LOCAL_VAR)
self.chkrel(f, z, "%s.f_locals ['z']", clas=self.Path.R_CELL)
# self becomes both a local var and a cell var, since it is an argument.
# FIXME: But not in py3... it seems
# self.chkrel(f, self, "<%s.f_locals['self'],%s.f_locals ['self']>")
# Stack variables doesn't work (Because ceval.c doesn't update
# the f_stacktop index.) so the corresponding part of frame_relate is not tested.
def test_function_relation(self):
def f(x, y=3):
return self
f.a = []
self.chkrelattr(f, '__code__', '__globals__', '__defaults__',
'__closure__', '__doc__', '__name__', '__dict__',
'a')
def test_instancemethod_relation(self):
class T:
def f(x):
pass
t = T()
self.chkrelattr(t.f, '__func__', '__self__')
def test_list_relation(self):
v1 = 'v1'
v2 = 'v2'
v3 = list(range(100, 200))
x = [v1, v2, v3]
self.chkrel(x, v1, '%s[0]')
self.chkrel(x, v2, '%s[1]')
self.chkrel(x, v3, '%s[2]')
def test_meth_relation(self):
x = []
self.chkrel(x.append, x, '%s.__self__')
def test_module_relation(self):
self.chkrelattr(unittest, '__dict__', 'TestCase')
def test_nodegraph_relation(self):
a = 0
b = 1
rl = [a, b]
rg = self.heapy.heapyc.NodeGraph([(a, rl), (b, rl)])
self.chkrel(rg, a, '%s->edges[0].src')
self.chkrel(rg, b, '%s->edges[1].src')
self.chkrel(rg, rl, '<%s->edges[0].tgt,%s->edges[1].tgt>')
self.chkpath(rg, a, '%s->edges[0].src')
self.chkpath(rg, rl, ['%s->edges[0].tgt', '%s->edges[1].tgt'])
def test_nodeset_relation(self):
from guppy.sets import immnodeset, mutnodeset
x = ['a']
for s in (immnodeset(x), mutnodeset(x)):
for i in range(len(x)):
self.chkrel(s, x[i], 'list(%%s)[%s]' % i)
def test_object_relation(self):
class T(object):
__slots__ = 'a', 'b'
t = T()
a = []
t.a = a
b = []
t.b = b
# self.chkrel(t, T, 'type(%s)')
self.chkrel(t, T, '%s->ob_type')
self.chkrelattr(t, 'a', 'b')
# We shouldn't have a __dict__ here - just make sure this is the case
self.assertRaises(AttributeError, lambda: t.__dict__)
class U(T):
pass
u = U()
u.a = a
self.chkpath(u, T, "%s->ob_type.__base__")
self.chkrel(u, a, '%s.a')
c = []
u.c = c
self.chkrel(u, c, '%s.c')
self.chkrel(u, u.__dict__, '%s.__dict__')
class V(U):
pass
v = V()
v.c = c
self.chkrelattr(v, '__dict__')
class W(V):
__slots__ = 'c', 'd', 'b'
pass
w = W()
w.a = a
w.b = b
w.c = c
w.d = []
w.e = []
self.chkrelattr(w, '__dict__', 'a', 'b', 'c', 'd', 'e')
self.chkpath(w, w.a, '%s.a')
self.chkpath(w, w.b, '%s.b')
self.chkpath(w, w.c, '%s.c')
self.chkpath(w, w.d, '%s.d')
self.chkpath(w, w.e, "%s.__dict__['e']")
class R(object):
rvar = []
class S(R, T):
svar = []
s = S()
s.a = a
s.b = b
s.c = c
self.chkrelattr(s, '__dict__', 'a', 'b', 'c')
self.chkpath(s, s.a, '%s.a')
self.chkpath(s, s.b, '%s.b')
self.chkpath(s, s.c, "%s.__dict__['c']")
# Class variables are not directly related- should they be that?
# Possibly, but the compression could as well be done in Python.
# We just check that we can get the path.
self.chkpath(s, s.svar, "%s->ob_type.__dict__['svar']")
self.chkpath(s, s.rvar, ["%s->ob_type.__bases__[0].__dict__['rvar']",
"%s->ob_type.__mro__[1].__dict__['rvar']"])
self.chkpath(s, s.__slots__,
"%s->ob_type.__base__.__dict__['__slots__']")
def test_traceback_relation(self):
import sys
try:
def g():
1/0
g()
except ZeroDivisionError:
type, value, traceback = sys.exc_info()
self.chkrelattr(traceback, 'tb_next', 'tb_frame')
def test_tuple_relation(self):
v1 = 'v1'
v2 = 'v2'
v3 = list(range(100, 200))
x = (v1, v2, v3)
self.chkrel(x, v1, '%s[0]')
self.chkrel(x, v2, '%s[1]')
self.chkrel(x, v3, '%s[2]')
def test_type_relation(self):
name = 'T'
base = object
bases = (base,)
dict = {'__slots__': ('a', 'b')}
T = type(name, bases, dict)
# tp_dict can't be directly tested since .__dict__ returns a proxy
# and the dict passed is not used directly.
# We test it indirectly by getting a path through it.
self.chkpath(T, T.a, "%s.__dict__['a']")
# The C-struct __slots__ field can't be tested directly
# This just tests the ordinary attribute
self.chkpath(T, T.__slots__, "%s.__dict__['__slots__']")
self.chkrelattr(T, '__mro__', '__base__', '__bases__')
# tp_cache and tp_subclasses can also not be tested directly
# Inheritance is tested via test_object_relation()
class RootTestCase(TestCase):
def test_1(self):
import sys
import builtins
root = self.View.root
# Interpreter attributes
rel = str(self.relation(root, sys.modules))
self.assertTrue(eval(rel % 'root') is sys.modules)
self.aseq(rel, '%s.i0_modules')
rel = str(self.relation(root, sys.__dict__))
self.assertTrue(eval(rel % 'root') is sys.__dict__)
self.aseq(rel, '%s.i0_sysdict')
rel = str(self.relation(root, builtins.__dict__))
self.assertTrue(eval(rel % 'root') is builtins.__dict__)
self.aseq(rel, '%s.i0_builtins')
for name in "codec_search_path", "codec_search_cache", "codec_error_registry":
attr = "i0_%s" % name
rel = str(self.relation(root, getattr(root, attr)))
self.aseq(rel, '%%s.%s' % attr)
# Thread attributes
try:
1/0
except ZeroDivisionError:
exc_type, exc_value, exc_traceback = sys.exc_info()
if sys.version_info >= (3, 11):
rel = str(self.relation(root, exc_value))
self.asis(eval(rel % 'root'), exc_value)
else:
for name in 'exc_type', 'exc_value', 'exc_traceback':
rel = str(self.relation(root, eval(name)))
self.asis(eval(rel % 'root'), eval(name))
# There are more, untested, attributes, but the code is farily regular...
# More complication is to do with frames which I concentrate on for now.
# We need to find out what level we are at - count to lowest frame
level = 0
frame = exc_traceback.tb_frame
while frame.f_back:
frame = frame.f_back
level += 1
rel = str(self.relation(root, frame))
self.assertTrue(rel.endswith('_f0'))
rel = str(self.relation(root, exc_traceback.tb_frame))
self.asis(eval(rel % 'root'), exc_traceback.tb_frame)
self.assertTrue(rel.endswith('_f%d' % level))
def test_thread(self):
try:
import _thread
except ImportError:
print('threading not enabled - skipping test')
return
root = self.View.root
def task(self):
import sys
try:
1/0
except ZeroDivisionError:
exc_type, exc_value, exc_traceback = sys.exc_info()
self.exc_value = exc_value
self.sync = 1
while self.sync:
pass
self.sync = 1
self.sync = 0
_thread.start_new_thread(task, (self,))
while not self.sync:
pass
exc_value = self.exc_value
rel = str(self.relation(root, exc_value))
self.asis(eval(rel % 'root'), exc_value)
self.sync = 0
while not self.sync:
pass
def task(self):
self.test_1()
self.sync = 1
self.sync = 0
_thread.start_new_thread(task, (self,))
while not self.sync:
pass
def test_secondary_interpreter(self):
import sys
if sys.version_info >= (3, 9):
print('multi-interpreter not supported past Python 3.9')
return
try:
import _thread
except ImportError:
print('threading not enabled - skipping test')
return
import_remote = """\
import sys
import _thread
import time
def task():
time.sleep(1)
self.sysdict = sys.__dict__
self.sync = 1
while self.sync:
pass
_thread.start_new_thread(task, ())
"""
self.sync = 0
thid = self.heapy.heapyc.interpreter(import_remote, {'self': self})
root = self.View.root
import sys
sysdict = sys.__dict__
rel = str(self.relation(root, sysdict))
self.aseq(rel, '%s.i0_sysdict')
while not self.sync:
pass
rel = str(self.relation(root, self.sysdict))
self.aseq(rel, '%s.i1_sysdict')
self.sync = 0
class PathTestCase(TestCase):
def makegraph(self, width, length):
# Generate a structure which will yield a high number
# of shortest paths.
# Returns a pair src, dst which are connected via a noncyclic graph
# with many edges.
# The length of each path (all shortest), number of edges will be length
# The number of nodes will be 2 + width * (length - 1)
# The number of paths will be
# width ** length, if width >= 1 and length >= 1
dst = []
ls = []
for i in range(width):
ls.append([dst])
ls = [dst] * width
for i in range(length-1):
xs = []
for j in range(width):
ys = []
xs.append(ys)
for k in range(width):
ys.append(ls[k])
ls = xs
src = ls
return src, dst
def chkgraph(self, width, length, expect=None):
src, dst = self.makegraph(width, length)
self.chkpath(src, dst, expect)
def test_path(self):
dst = 'dst'
self.chkpath([dst], dst, '%s[0]')
self.chkpath([[], dst], dst, '%s[1]')
self.chkpath([dst, dst], dst, "['%s[0]', '%s[1]']")
self.chkpath([[dst, 0], dst, [dst, 2]], dst, "%s[1]")
self.chkpath([[dst, 0], [dst, 2]], dst, "['%s[0][0]', '%s[1][0]']")
src, dst = self.makegraph(1, 1)
self.chkgraph(1, 1, '%s[0]')
self.chkgraph(1, 2, '%s[0][0]')
self.chkgraph(2, 1, ['%s[0]', '%s[1]'])
self.chkgraph(3, 2, ['%s[0][0]', '%s[0][1]', '%s[0][2]',
'%s[1][0]', '%s[1][1]', '%s[1][2]',
'%s[2][0]', '%s[2][1]', '%s[2][2]'])
def test_numpaths(self):
for (width, length) in [(2, 1), (7, 3), (3, 7), (10, 20)]:
src, dst = self.makegraph(width, length)
p = self.shpaths(dst, src)
self.aseq(p.numpaths, width**length)
def test_iter(self):
src, dst = self.makegraph(2, 2)
p = self.shpaths(dst, src)
it = iter(p)
ss = []
for i in it:
ss.append(str(i))
ss.sort()
self.aseq(ss, ['%s[0][0]', '%s[0][1]', '%s[1][0]', '%s[1][1]'])
# Check that we can get some of the first values from the iterator
# of a graph with an astronomical number of paths.
width = 11
length = 13
numpaths = 20
src, dst = self.makegraph(width, length)
p = self.shpaths(dst, src)
it = iter(p)
for i in range(numpaths):
path = next(it)
sp = str(path)
div, mod = divmod(i, width)
self.aseq(sp, '%s'+'[0]'*(length-2)+'[%d][%d]' % (div, mod))
# Check that the iterator works even if the graph initially
# would yield astronomical numbers of dead ends.
# (The initial algorithm took astronomically long time.)
osrc = src
src, dst = self.makegraph(width, length)
src[0] = osrc
p = self.shpaths(dst, src)
it = iter(p)
for i in range(numpaths):
path = next(it)
sp = str(path)
div, mod = divmod(i, width)
self.aseq(sp, '%s[1]'+'[0]'*(length-3)+'[%d][%d]' % (div, mod))
# Test iterating with a negative start and a large positive start
numfromend = width / 2
for it in [p.iter(-numfromend), p.iter(p.numpaths-numfromend)]:
for i, path in enumerate(it):
sp = str(path)
self.aseq(sp, '%s'+('[%d]' % (width-1)) *
(length-1)+'[%d]' % (width-numfromend+i))
# Test iterating with start and stop
start = 5
stop = 25
i = start
for path in p.iter(start, stop):
sp = str(path)
div, mod = divmod(i, width)
self.aseq(sp, '%s[1]'+'[0]'*(length-3)+'[%d][%d]' % (div, mod))
self.aseq(path.index, i)
i += 1
self.aseq(i, stop)
def test_str(self):
# Make sure large number of paths will yield reasonable representations
width = 11
length = 4
src, dst = self.makegraph(width, length)
p = self.shpaths(dst, src)
p.maxpaths = 1
self.aseq(str(p), " 0: Src[0][0][0][0]\n<... 14640 more paths ...>")
p.maxpaths = 2
self.aseq(
str(p), " 0: Src[0][0][0][0]\n 1: Src[0][0][0][1]\n<... 14639 more paths ...>")
def test_printing(self):
# Test the pretty-printing and moreing methods
from io import StringIO
output = StringIO()
self.Path.output = output
width = 11
length = 4
src, dst = self.makegraph(width, length)
p = self.shpaths(dst, src)
p.maxpaths = 2
self.aseq(str(p), """\
0: Src[0][0][0][0]
1: Src[0][0][0][1]
<... 14639 more paths ...>""")
self.aseq(str(p.more), """\
2: Src[0][0][0][2]
3: Src[0][0][0][3]
<... 14637 more paths ...>""")
def test_subscript(self):
# Test subscripting
width = 3
length = 40
src, dst = self.makegraph(width, length)
p = self.shpaths(dst, src)
np = width**length
self.aseq(np, p.numpaths)
# p[0].pp(p.output)
self.aseq(str(p[0]), '%s'+'[0]'*length)
self.aseq(str(p[-np]), '%s'+'[0]'*length)
self.aseq(str(p[width-1]), '%s'+'[0]'*(length-1) + '[%d]' % (width-1))
self.aseq(str(p[width]), '%s'+'[0]'*(length-2) + '[1][0]')
self.aseq(str(p[width+1]), '%s'+'[0]'*(length-2) + '[1][1]')
self.aseq(str(p[np-1]), '%s'+('[%d]' % (width-1))*length)
self.aseq(str(p[-1]), '%s'+('[%d]' % (width-1))*length)
self.assertRaises(IndexError, lambda: p[np])
self.assertRaises(IndexError, lambda: p[-np-1])
class MultiTestCase(TestCase):
def test_pp(self):
# Test printing of multi relations
iso = self.iso
dst = [[], []]
src = iso(dst[:]*2)
dst = [iso(x) for x in dst]
p = self.Path.shpgraph(dst, src)
self.aseq(str(p), """\
--- Dst[0] ---
0: Src[0]
1: Src[2]
--- Dst[1] ---
0: Src[1]
1: Src[3]""")
p = self.Path.shpgraph(dst, src, srcname='A', dstname='B')
self.aseq(str(p), """\
--- B[0] ---
0: A[0]
1: A[2]
--- B[1] ---
0: A[1]
1: A[3]""")
class AvoidTestCase(TestCase):
def test_1(self):
# Test that we can find new paths by avoiding edges
# selected from previously found paths.
# First we generate a graph with paths of various lengths...
src = ['src']
a = src
for i in range(3):
b = ['b%d' % i]
c = ['c%d' % i, b]
a.append(b)
a.append(c)
a = b
dst = a
p = self.shpaths(dst, src)
for avoid, result in [
([], '%s[1][1][1]'),
([0], '%s[2][1][1][1]'),
([1], '%s[1][2][1][1]'),
([2], '%s[1][1][2][1]'),
([0, 1], '%s[2][1][2][1][1]'),
([1, 2], '%s[1][2][1][2][1]'),
# ([1, -1], '%s[1][2][1][2][1]'),
([0, 2], '%s[2][1][1][2][1]'),
([0, 1, 2], '%s[2][1][2][1][2][1]'),
([2, 1, 0], '%s[2][1][2][1][2][1]'),
]:
result = result % ' 0: Src'
# Find new path by avoiding edges from the original path
q = self.shpaths(dst, src, avoid_edges=p.edges_at(*avoid))
self.aseq(str(q), result)
# Find the same path but via a direct method
q = p.copy_but_avoid_edges_at_levels(*avoid)
self.aseq(str(q), result)
# The same, but via a shorter method name
q = p.avoided(*avoid)
self.aseq(str(q), result)
# Test that the avoided set is carried on to copies
q = p.avoided(0).avoided(2)
self.aseq(str(q), ' 0: Src[2][1][2][1][1]')
class NewTestCase(TestCase):
def test_1(self):
import sys
o = self.python.io.StringIO()
iso = self.iso
x = iso(sys.__dict__)
print(x.shpaths, file=o)
# This used to include a path via parameter avoid_edges
# which was confusing
print(x.shpaths.avoided(0), file=o)
# repr() used to be quite useless. I have it now defined as .pp(),
# but without trailin newline.
print(repr(x.shpaths), file=o)
print(repr(x.shpaths), file=o)
# The shpaths object could sometimes disturb a shpath calculation
# because dst was free in it.
x = []
y = [[[x]]]
sp = iso(x).get_shpaths(iso(y))
print(sp, file=o)
y.append(sp)
print(iso(x).get_shpaths(iso(y)), file=o)
# Test that the shortest paths to a set of objects, is the shortest
# paths to those that can be reached by the shortest paths, only
x = []
y = [x]
z = [y]
print(iso(x, y).get_shpaths(iso(z)), file=o)
# Test that we can relate objects that inherits from a class and object
# (Used to segfault)
class C:
pass
class O(C, object):
__slots__ = 'x',
ob = O()
ob.x = x
print(iso(x).get_shpaths(iso(ob)), file=o)
# Test that generalization to a set of sources makes some sense
# The shortest paths are from the closest sources
# Hack to make a constant address rendering, for test comparison.
# This doesn't change anything permanently.
# XXX come up with an official way to do this.
summary_str = self.heapy.UniSet.summary_str
def str_address(x): return '<address>'
str_address._idpart_header = getattr(
summary_str.str_address, '_idpart_header', None)
str_address._idpart_sortrender = getattr(
summary_str.str_address, '_idpart_sortrender', None)
summary_str.str_address = str_address
S = iso()
shp = iso(x).get_shpaths(iso(y, z))
print(shp, file=o)
print(repr(shp), file=o)
for p in shp:
S = S ^ p.src
self.aseq(S, iso(y))
shp = iso(x).get_shpaths(iso(ob, y, z))
print(str(shp), file=o)
print(repr(shp), file=o)
S = iso()
for i, p in enumerate(shp):
S = S ^ p.src
self.aseq(p.src, shp[i].src)
self.aseq(S, iso(ob, y))
# Test that the iter can be restarted
# even after multiple sources handling was added
it = iter(shp)
a = list(it)
it.isatend = 0
b = list(it)
self.aseq(str(a), str(b))
# The sort order is based on the source set's byid partition (see
# Path.PathsIter.reset), which sorts based on the size, then render
# (see Part.IdentityPartition.__init__)
if sys.getsizeof(y) > sys.getsizeof(ob):
self.aseq(o.getvalue(), """\
0: hpy().Root.i0_sysdict
0: Src.i0_modules['sys'].__dict__
0: hpy().Root.i0_sysdict
0: hpy().Root.i0_sysdict
0: Src[0][0][0]
0: Src[0][0][0]
0: Src[0]
0: Src.x
0: <1 list: <address>*1>[0]
0: <1 list: <address>*1>[0]
0: <1 list: <address>*1>[0]
1: <1 __main__.O: <address>>.x
0: <1 list: <address>*1>[0]
1: <1 __main__.O: <address>>.x
""".replace('__main__', self.__module__))
else:
self.aseq(o.getvalue(), """\
0: hpy().Root.i0_sysdict
0: Src.i0_modules['sys'].__dict__
0: hpy().Root.i0_sysdict
0: hpy().Root.i0_sysdict
0: Src[0][0][0]
0: Src[0][0][0]
0: Src[0]
0: Src.x
0: <1 list: <address>*1>[0]
0: <1 list: <address>*1>[0]
0: <1 __main__.O: <address>>.x
1: <1 list: <address>*1>[0]
0: <1 __main__.O: <address>>.x
1: <1 list: <address>*1>[0]
""".replace('__main__', self.__module__))
def test_2(self):
# To assist interactivity,
# the more attribute is defined to return an object which
# the repr() of gives more lines; and has a similar more attribute.
# Testing this functionality here.
o = self.python.io.StringIO()
iso = self.iso
dst = []
src = [dst]*20
print(repr(iso(dst).get_shpaths(iso(src))), file=o)
print(repr(iso(dst).get_shpaths(iso(src)).more), file=o)
p = iso(dst).get_shpaths(iso(src))
print(repr(p.more), file=o)
self.aseq(o.getvalue(), """\
0: Src[0]
1: Src[1]
2: Src[2]
3: Src[3]
4: Src[4]
5: Src[5]
6: Src[6]
7: Src[7]
8: Src[8]
9: Src[9]
<... 10 more paths ...>
10: Src[10]
11: Src[11]
12: Src[12]
13: Src[13]
14: Src[14]
15: Src[15]
16: Src[16]
17: Src[17]
18: Src[18]
19: Src[19]
10: Src[10]
11: Src[11]
12: Src[12]
13: Src[13]
14: Src[14]
15: Src[15]
16: Src[16]
17: Src[17]
18: Src[18]
19: Src[19]
""")
def test_empty(self):
# Test empty paths
iso = self.iso
dst = []
self.assertTrue(len(list(iso(dst).get_shpaths(iso()))) == 0)
def test_3(self):
# Test that Edges is not included in the shortest path
iso = self.iso
dst = []
shp = iso(dst).shpaths
del dst
self.assertTrue('Edges' not in str(shp.avoided(0)))
dst = []
src = [dst]
shp = iso(dst).get_shpaths(iso(src))
src[0] = shp
dst = iso(dst)
src = iso(src)
self.assertTrue(dst.get_shpaths(src).numpaths == 0)
# Test the sets attribute
dst = []
src = [dst]
dst = iso(dst)
src = iso(src)
self.aseq(dst.get_shpaths(src).sets, (src, dst))
# Test that srs doesn't disturb the path calculation
class C:
pass
c = C()
cd = iso(c.__dict__)
p = cd.shpaths
repr(p)
del c
q = cd.shpaths
self.aseq(repr(q).strip(), "")
del p, q
# Test that internals of ShortestPath are hidden in general
# (via hiding_tag), to consistent result when used interactively,
# as commented on in notes.txt per Nov 30 2004.
dst = []
src = [[[[dst]]]]
d = iso(dst)
s = iso(src)
p = d.get_shpaths(s)
self.aseq(str(p), " 0: Src[0][0][0][0]")
src.append(p)
p._XX_ = dst # A shorter path, but it should be hidden
self.aseq(str(d.get_shpaths(s)), " 0: Src[0][0][0][0]")
# Test what .more prints finally
self.aseq(str(p.more), '<No more paths>')
# Test that .top is idempotent
self.asis(p.more.top.top, p)
def test_4(self):
# Test that if one extra path will be printed if there are
# exactly 11 paths
iso = self.iso
o = self.python.io.StringIO()
dst = []
src = [dst] * 11
shp = iso(dst).get_shpaths(iso(src))
print(str(shp), file=o)
self.aseq(o.getvalue(), """\
0: Src[0]
1: Src[1]
2: Src[2]
3: Src[3]
4: Src[4]
5: Src[5]
6: Src[6]
7: Src[7]
8: Src[8]
9: Src[9]
10: Src[10]
""")
def test_comparison(self):
# Test that non-compariable keys won't crash
# output order may be arbitrary not the output is not tested
iso = self.iso
dst = []
shp = iso(dst).get_shpaths(iso({0: dst, '': dst}))
str(shp)
shp = iso(dst).get_shpaths(iso({object(): dst, object(): dst}))
str(shp)
def run_test(case, debug=0):
support.run_unittest(case, debug)
def test_main(debug=0):
run_test(NewTestCase, debug)
run_test(RelationTestCase, debug)
run_test(RootTestCase, debug)
run_test(PathTestCase, debug)
run_test(MultiTestCase, debug)
run_test(AvoidTestCase, debug)
if __name__ == "__main__":
test_main()
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