# As a test suite for the os module, this is woefully inadequate, but this # does add tests for a few functions which have been determined to be more # portable than they had been thought to be. import os import errno import unittest import warnings import sys import signal import subprocess import time import shutil from test import support import contextlib # Detect whether we're on a Linux system that uses the (now outdated # and unmaintained) linuxthreads threading library. There's an issue # when combining linuxthreads with a failed execv call: see # http://bugs.python.org/issue4970. if (hasattr(os, "confstr_names") and "CS_GNU_LIBPTHREAD_VERSION" in os.confstr_names): libpthread = os.confstr("CS_GNU_LIBPTHREAD_VERSION") USING_LINUXTHREADS= libpthread.startswith("linuxthreads") else: USING_LINUXTHREADS= False # Tests creating TESTFN class FileTests(unittest.TestCase): def setUp(self): if os.path.exists(support.TESTFN): os.unlink(support.TESTFN) tearDown = setUp def test_access(self): f = os.open(support.TESTFN, os.O_CREAT|os.O_RDWR) os.close(f) self.assertTrue(os.access(support.TESTFN, os.W_OK)) def test_closerange(self): first = os.open(support.TESTFN, os.O_CREAT|os.O_RDWR) # We must allocate two consecutive file descriptors, otherwise # it will mess up other file descriptors (perhaps even the three # standard ones). second = os.dup(first) try: retries = 0 while second != first + 1: os.close(first) retries += 1 if retries > 10: # XXX test skipped self.skipTest("couldn't allocate two consecutive fds") first, second = second, os.dup(second) finally: os.close(second) # close a fd that is open, and one that isn't os.closerange(first, first + 2) self.assertRaises(OSError, os.write, first, b"a") @support.cpython_only def test_rename(self): path = support.TESTFN old = sys.getrefcount(path) self.assertRaises(TypeError, os.rename, path, 0) new = sys.getrefcount(path) self.assertEqual(old, new) def test_read(self): with open(support.TESTFN, "w+b") as fobj: fobj.write(b"spam") fobj.flush() fd = fobj.fileno() os.lseek(fd, 0, 0) s = os.read(fd, 4) self.assertEqual(type(s), bytes) self.assertEqual(s, b"spam") def test_write(self): # os.write() accepts bytes- and buffer-like objects but not strings fd = os.open(support.TESTFN, os.O_CREAT | os.O_WRONLY) self.assertRaises(TypeError, os.write, fd, "beans") os.write(fd, b"bacon\n") os.write(fd, bytearray(b"eggs\n")) os.write(fd, memoryview(b"spam\n")) os.close(fd) with open(support.TESTFN, "rb") as fobj: self.assertEqual(fobj.read().splitlines(), [b"bacon", b"eggs", b"spam"]) class TemporaryFileTests(unittest.TestCase): def setUp(self): self.files = [] os.mkdir(support.TESTFN) def tearDown(self): for name in self.files: os.unlink(name) os.rmdir(support.TESTFN) def check_tempfile(self, name): # make sure it doesn't already exist: self.assertFalse(os.path.exists(name), "file already exists for temporary file") # make sure we can create the file open(name, "w") self.files.append(name) def test_tempnam(self): if not hasattr(os, "tempnam"): return warnings.filterwarnings("ignore", "tempnam", RuntimeWarning, r"test_os$") self.check_tempfile(os.tempnam()) name = os.tempnam(support.TESTFN) self.check_tempfile(name) name = os.tempnam(support.TESTFN, "pfx") self.assertTrue(os.path.basename(name)[:3] == "pfx") self.check_tempfile(name) def test_tmpfile(self): if not hasattr(os, "tmpfile"): return # As with test_tmpnam() below, the Windows implementation of tmpfile() # attempts to create a file in the root directory of the current drive. # On Vista and Server 2008, this test will always fail for normal users # as writing to the root directory requires elevated privileges. With # XP and below, the semantics of tmpfile() are the same, but the user # running the test is more likely to have administrative privileges on # their account already. If that's the case, then os.tmpfile() should # work. In order to make this test as useful as possible, rather than # trying to detect Windows versions or whether or not the user has the # right permissions, just try and create a file in the root directory # and see if it raises a 'Permission denied' OSError. If it does, then # test that a subsequent call to os.tmpfile() raises the same error. If # it doesn't, assume we're on XP or below and the user running the test # has administrative privileges, and proceed with the test as normal. if sys.platform == 'win32': name = '\\python_test_os_test_tmpfile.txt' if os.path.exists(name): os.remove(name) try: fp = open(name, 'w') except IOError as first: # open() failed, assert tmpfile() fails in the same way. # Although open() raises an IOError and os.tmpfile() raises an # OSError(), 'args' will be (13, 'Permission denied') in both # cases. try: fp = os.tmpfile() except OSError as second: self.assertEqual(first.args, second.args) else: self.fail("expected os.tmpfile() to raise OSError") return else: # open() worked, therefore, tmpfile() should work. Close our # dummy file and proceed with the test as normal. fp.close() os.remove(name) fp = os.tmpfile() fp.write("foobar") fp.seek(0,0) s = fp.read() fp.close() self.assertTrue(s == "foobar") def test_tmpnam(self): if not hasattr(os, "tmpnam"): return warnings.filterwarnings("ignore", "tmpnam", RuntimeWarning, r"test_os$") name = os.tmpnam() if sys.platform in ("win32",): # The Windows tmpnam() seems useless. From the MS docs: # # The character string that tmpnam creates consists of # the path prefix, defined by the entry P_tmpdir in the # file STDIO.H, followed by a sequence consisting of the # digit characters '0' through '9'; the numerical value # of this string is in the range 1 - 65,535. Changing the # definitions of L_tmpnam or P_tmpdir in STDIO.H does not # change the operation of tmpnam. # # The really bizarre part is that, at least under MSVC6, # P_tmpdir is "\\". That is, the path returned refers to # the root of the current drive. That's a terrible place to # put temp files, and, depending on privileges, the user # may not even be able to open a file in the root directory. self.assertFalse(os.path.exists(name), "file already exists for temporary file") else: self.check_tempfile(name) def fdopen_helper(self, *args): fd = os.open(support.TESTFN, os.O_RDONLY) fp2 = os.fdopen(fd, *args) fp2.close() def test_fdopen(self): self.fdopen_helper() self.fdopen_helper('r') self.fdopen_helper('r', 100) # Test attributes on return values from os.*stat* family. class StatAttributeTests(unittest.TestCase): def setUp(self): os.mkdir(support.TESTFN) self.fname = os.path.join(support.TESTFN, "f1") f = open(self.fname, 'wb') f.write(b"ABC") f.close() def tearDown(self): os.unlink(self.fname) os.rmdir(support.TESTFN) def test_stat_attributes(self): if not hasattr(os, "stat"): return import stat result = os.stat(self.fname) # Make sure direct access works self.assertEquals(result[stat.ST_SIZE], 3) self.assertEquals(result.st_size, 3) # Make sure all the attributes are there members = dir(result) for name in dir(stat): if name[:3] == 'ST_': attr = name.lower() if name.endswith("TIME"): def trunc(x): return int(x) else: def trunc(x): return x self.assertEquals(trunc(getattr(result, attr)), result[getattr(stat, name)]) self.assertIn(attr, members) try: result[200] self.fail("No exception thrown") except IndexError: pass # Make sure that assignment fails try: result.st_mode = 1 self.fail("No exception thrown") except AttributeError: pass try: result.st_rdev = 1 self.fail("No exception thrown") except (AttributeError, TypeError): pass try: result.parrot = 1 self.fail("No exception thrown") except AttributeError: pass # Use the stat_result constructor with a too-short tuple. try: result2 = os.stat_result((10,)) self.fail("No exception thrown") except TypeError: pass # Use the constructr with a too-long tuple. try: result2 = os.stat_result((0,1,2,3,4,5,6,7,8,9,10,11,12,13,14)) except TypeError: pass def test_statvfs_attributes(self): if not hasattr(os, "statvfs"): return try: result = os.statvfs(self.fname) except OSError as e: # On AtheOS, glibc always returns ENOSYS if e.errno == errno.ENOSYS: return # Make sure direct access works self.assertEquals(result.f_bfree, result[3]) # Make sure all the attributes are there. members = ('bsize', 'frsize', 'blocks', 'bfree', 'bavail', 'files', 'ffree', 'favail', 'flag', 'namemax') for value, member in enumerate(members): self.assertEquals(getattr(result, 'f_' + member), result[value]) # Make sure that assignment really fails try: result.f_bfree = 1 self.fail("No exception thrown") except AttributeError: pass try: result.parrot = 1 self.fail("No exception thrown") except AttributeError: pass # Use the constructor with a too-short tuple. try: result2 = os.statvfs_result((10,)) self.fail("No exception thrown") except TypeError: pass # Use the constructr with a too-long tuple. try: result2 = os.statvfs_result((0,1,2,3,4,5,6,7,8,9,10,11,12,13,14)) except TypeError: pass def test_utime_dir(self): delta = 1000000 st = os.stat(support.TESTFN) # round to int, because some systems may support sub-second # time stamps in stat, but not in utime. os.utime(support.TESTFN, (st.st_atime, int(st.st_mtime-delta))) st2 = os.stat(support.TESTFN) self.assertEquals(st2.st_mtime, int(st.st_mtime-delta)) # Restrict test to Win32, since there is no guarantee other # systems support centiseconds if sys.platform == 'win32': def get_file_system(path): root = os.path.splitdrive(os.path.abspath(path))[0] + '\\' import ctypes kernel32 = ctypes.windll.kernel32 buf = ctypes.create_unicode_buffer("", 100) if kernel32.GetVolumeInformationW(root, None, 0, None, None, None, buf, len(buf)): return buf.value if get_file_system(support.TESTFN) == "NTFS": def test_1565150(self): t1 = 1159195039.25 os.utime(self.fname, (t1, t1)) self.assertEquals(os.stat(self.fname).st_mtime, t1) def test_1686475(self): # Verify that an open file can be stat'ed try: os.stat(r"c:\pagefile.sys") except WindowsError as e: if e.errno == 2: # file does not exist; cannot run test return self.fail("Could not stat pagefile.sys") from test import mapping_tests class EnvironTests(mapping_tests.BasicTestMappingProtocol): """check that os.environ object conform to mapping protocol""" type2test = None def setUp(self): self.__save = dict(os.environ) if os.supports_bytes_environ: self.__saveb = dict(os.environb) for key, value in self._reference().items(): os.environ[key] = value def tearDown(self): os.environ.clear() os.environ.update(self.__save) if os.supports_bytes_environ: os.environb.clear() os.environb.update(self.__saveb) def _reference(self): return {"KEY1":"VALUE1", "KEY2":"VALUE2", "KEY3":"VALUE3"} def _empty_mapping(self): os.environ.clear() return os.environ # Bug 1110478 def test_update2(self): os.environ.clear() if os.path.exists("/bin/sh"): os.environ.update(HELLO="World") value = os.popen("/bin/sh -c 'echo $HELLO'").read().strip() self.assertEquals(value, "World") def test_os_popen_iter(self): if os.path.exists("/bin/sh"): popen = os.popen("/bin/sh -c 'echo \"line1\nline2\nline3\"'") it = iter(popen) self.assertEquals(next(it), "line1\n") self.assertEquals(next(it), "line2\n") self.assertEquals(next(it), "line3\n") self.assertRaises(StopIteration, next, it) # Verify environ keys and values from the OS are of the # correct str type. def test_keyvalue_types(self): for key, val in os.environ.items(): self.assertEquals(type(key), str) self.assertEquals(type(val), str) def test_items(self): for key, value in self._reference().items(): self.assertEqual(os.environ.get(key), value) # Issue 7310 def test___repr__(self): """Check that the repr() of os.environ looks like environ({...}).""" env = os.environ self.assertTrue(isinstance(env.data, dict)) self.assertEqual(repr(env), 'environ({{{}}})'.format(', '.join( '{!r}: {!r}'.format(key, value) for key, value in env.items()))) def test_get_exec_path(self): defpath_list = os.defpath.split(os.pathsep) test_path = ['/monty', '/python', '', '/flying/circus'] test_env = {'PATH': os.pathsep.join(test_path)} saved_environ = os.environ try: os.environ = dict(test_env) # Test that defaulting to os.environ works. self.assertSequenceEqual(test_path, os.get_exec_path()) self.assertSequenceEqual(test_path, os.get_exec_path(env=None)) finally: os.environ = saved_environ # No PATH environment variable self.assertSequenceEqual(defpath_list, os.get_exec_path({})) # Empty PATH environment variable self.assertSequenceEqual(('',), os.get_exec_path({'PATH':''})) # Supplied PATH environment variable self.assertSequenceEqual(test_path, os.get_exec_path(test_env)) if os.supports_bytes_environ: # env cannot contain 'PATH' and b'PATH' keys try: mixed_env = {'PATH': '1', b'PATH': b'2'} except BytesWarning: pass else: self.assertRaises(ValueError, os.get_exec_path, mixed_env) # bytes key and/or value self.assertSequenceEqual(os.get_exec_path({b'PATH': b'abc'}), ['abc']) self.assertSequenceEqual(os.get_exec_path({b'PATH': 'abc'}), ['abc']) self.assertSequenceEqual(os.get_exec_path({'PATH': b'abc'}), ['abc']) @unittest.skipUnless(os.supports_bytes_environ, "os.environb required for this test.") def test_environb(self): # os.environ -> os.environb value = 'euro\u20ac' try: value_bytes = value.encode(sys.getfilesystemencoding(), 'surrogateescape') except UnicodeEncodeError: msg = "U+20AC character is not encodable to %s" % ( sys.getfilesystemencoding(),) self.skipTest(msg) os.environ['unicode'] = value self.assertEquals(os.environ['unicode'], value) self.assertEquals(os.environb[b'unicode'], value_bytes) # os.environb -> os.environ value = b'\xff' os.environb[b'bytes'] = value self.assertEquals(os.environb[b'bytes'], value) value_str = value.decode(sys.getfilesystemencoding(), 'surrogateescape') self.assertEquals(os.environ['bytes'], value_str) class WalkTests(unittest.TestCase): """Tests for os.walk().""" def test_traversal(self): import os from os.path import join # Build: # TESTFN/ # TEST1/ a file kid and two directory kids # tmp1 # SUB1/ a file kid and a directory kid # tmp2 # SUB11/ no kids # SUB2/ a file kid and a dirsymlink kid # tmp3 # link/ a symlink to TESTFN.2 # TEST2/ # tmp4 a lone file walk_path = join(support.TESTFN, "TEST1") sub1_path = join(walk_path, "SUB1") sub11_path = join(sub1_path, "SUB11") sub2_path = join(walk_path, "SUB2") tmp1_path = join(walk_path, "tmp1") tmp2_path = join(sub1_path, "tmp2") tmp3_path = join(sub2_path, "tmp3") link_path = join(sub2_path, "link") t2_path = join(support.TESTFN, "TEST2") tmp4_path = join(support.TESTFN, "TEST2", "tmp4") # Create stuff. os.makedirs(sub11_path) os.makedirs(sub2_path) os.makedirs(t2_path) for path in tmp1_path, tmp2_path, tmp3_path, tmp4_path: f = open(path, "w") f.write("I'm " + path + " and proud of it. Blame test_os.\n") f.close() if support.can_symlink(): os.symlink(os.path.abspath(t2_path), link_path) sub2_tree = (sub2_path, ["link"], ["tmp3"]) else: sub2_tree = (sub2_path, [], ["tmp3"]) # Walk top-down. all = list(os.walk(walk_path)) self.assertEqual(len(all), 4) # We can't know which order SUB1 and SUB2 will appear in. # Not flipped: TESTFN, SUB1, SUB11, SUB2 # flipped: TESTFN, SUB2, SUB1, SUB11 flipped = all[0][1][0] != "SUB1" all[0][1].sort() self.assertEqual(all[0], (walk_path, ["SUB1", "SUB2"], ["tmp1"])) self.assertEqual(all[1 + flipped], (sub1_path, ["SUB11"], ["tmp2"])) self.assertEqual(all[2 + flipped], (sub11_path, [], [])) self.assertEqual(all[3 - 2 * flipped], sub2_tree) # Prune the search. all = [] for root, dirs, files in os.walk(walk_path): all.append((root, dirs, files)) # Don't descend into SUB1. if 'SUB1' in dirs: # Note that this also mutates the dirs we appended to all! dirs.remove('SUB1') self.assertEqual(len(all), 2) self.assertEqual(all[0], (walk_path, ["SUB2"], ["tmp1"])) self.assertEqual(all[1], sub2_tree) # Walk bottom-up. all = list(os.walk(walk_path, topdown=False)) self.assertEqual(len(all), 4) # We can't know which order SUB1 and SUB2 will appear in. # Not flipped: SUB11, SUB1, SUB2, TESTFN # flipped: SUB2, SUB11, SUB1, TESTFN flipped = all[3][1][0] != "SUB1" all[3][1].sort() self.assertEqual(all[3], (walk_path, ["SUB1", "SUB2"], ["tmp1"])) self.assertEqual(all[flipped], (sub11_path, [], [])) self.assertEqual(all[flipped + 1], (sub1_path, ["SUB11"], ["tmp2"])) self.assertEqual(all[2 - 2 * flipped], sub2_tree) if support.can_symlink(): # Walk, following symlinks. for root, dirs, files in os.walk(walk_path, followlinks=True): if root == link_path: self.assertEqual(dirs, []) self.assertEqual(files, ["tmp4"]) break else: self.fail("Didn't follow symlink with followlinks=True") def tearDown(self): # Tear everything down. This is a decent use for bottom-up on # Windows, which doesn't have a recursive delete command. The # (not so) subtlety is that rmdir will fail unless the dir's # kids are removed first, so bottom up is essential. for root, dirs, files in os.walk(support.TESTFN, topdown=False): for name in files: os.remove(os.path.join(root, name)) for name in dirs: dirname = os.path.join(root, name) if not os.path.islink(dirname): os.rmdir(dirname) else: os.remove(dirname) os.rmdir(support.TESTFN) class MakedirTests(unittest.TestCase): def setUp(self): os.mkdir(support.TESTFN) def test_makedir(self): base = support.TESTFN path = os.path.join(base, 'dir1', 'dir2', 'dir3') os.makedirs(path) # Should work path = os.path.join(base, 'dir1', 'dir2', 'dir3', 'dir4') os.makedirs(path) # Try paths with a '.' in them self.assertRaises(OSError, os.makedirs, os.curdir) path = os.path.join(base, 'dir1', 'dir2', 'dir3', 'dir4', 'dir5', os.curdir) os.makedirs(path) path = os.path.join(base, 'dir1', os.curdir, 'dir2', 'dir3', 'dir4', 'dir5', 'dir6') os.makedirs(path) def tearDown(self): path = os.path.join(support.TESTFN, 'dir1', 'dir2', 'dir3', 'dir4', 'dir5', 'dir6') # If the tests failed, the bottom-most directory ('../dir6') # may not have been created, so we look for the outermost directory # that exists. while not os.path.exists(path) and path != support.TESTFN: path = os.path.dirname(path) os.removedirs(path) class DevNullTests(unittest.TestCase): def test_devnull(self): f = open(os.devnull, 'w') f.write('hello') f.close() f = open(os.devnull, 'r') self.assertEqual(f.read(), '') f.close() class URandomTests(unittest.TestCase): def test_urandom(self): try: self.assertEqual(len(os.urandom(1)), 1) self.assertEqual(len(os.urandom(10)), 10) self.assertEqual(len(os.urandom(100)), 100) self.assertEqual(len(os.urandom(1000)), 1000) except NotImplementedError: pass @contextlib.contextmanager def _execvpe_mockup(defpath=None): """ Stubs out execv and execve functions when used as context manager. Records exec calls. The mock execv and execve functions always raise an exception as they would normally never return. """ # A list of tuples containing (function name, first arg, args) # of calls to execv or execve that have been made. calls = [] def mock_execv(name, *args): calls.append(('execv', name, args)) raise RuntimeError("execv called") def mock_execve(name, *args): calls.append(('execve', name, args)) raise OSError(errno.ENOTDIR, "execve called") try: orig_execv = os.execv orig_execve = os.execve orig_defpath = os.defpath os.execv = mock_execv os.execve = mock_execve if defpath is not None: os.defpath = defpath yield calls finally: os.execv = orig_execv os.execve = orig_execve os.defpath = orig_defpath class ExecTests(unittest.TestCase): @unittest.skipIf(USING_LINUXTHREADS, "avoid triggering a linuxthreads bug: see issue #4970") def test_execvpe_with_bad_program(self): self.assertRaises(OSError, os.execvpe, 'no such app-', ['no such app-'], None) def test_execvpe_with_bad_arglist(self): self.assertRaises(ValueError, os.execvpe, 'notepad', [], None) @unittest.skipUnless(hasattr(os, '_execvpe'), "No internal os._execvpe function to test.") def _test_internal_execvpe(self, test_type): program_path = os.sep + 'absolutepath' if test_type is bytes: program = b'executable' fullpath = os.path.join(os.fsencode(program_path), program) native_fullpath = fullpath arguments = [b'progname', 'arg1', 'arg2'] else: program = 'executable' arguments = ['progname', 'arg1', 'arg2'] fullpath = os.path.join(program_path, program) if os.name != "nt": native_fullpath = os.fsencode(fullpath) else: native_fullpath = fullpath env = {'spam': 'beans'} # test os._execvpe() with an absolute path with _execvpe_mockup() as calls: self.assertRaises(RuntimeError, os._execvpe, fullpath, arguments) self.assertEqual(len(calls), 1) self.assertEqual(calls[0], ('execv', fullpath, (arguments,))) # test os._execvpe() with a relative path: # os.get_exec_path() returns defpath with _execvpe_mockup(defpath=program_path) as calls: self.assertRaises(OSError, os._execvpe, program, arguments, env=env) self.assertEqual(len(calls), 1) self.assertSequenceEqual(calls[0], ('execve', native_fullpath, (arguments, env))) # test os._execvpe() with a relative path: # os.get_exec_path() reads the 'PATH' variable with _execvpe_mockup() as calls: env_path = env.copy() if test_type is bytes: env_path[b'PATH'] = program_path else: env_path['PATH'] = program_path self.assertRaises(OSError, os._execvpe, program, arguments, env=env_path) self.assertEqual(len(calls), 1) self.assertSequenceEqual(calls[0], ('execve', native_fullpath, (arguments, env_path))) def test_internal_execvpe_str(self): self._test_internal_execvpe(str) if os.name != "nt": self._test_internal_execvpe(bytes) class Win32ErrorTests(unittest.TestCase): def test_rename(self): self.assertRaises(WindowsError, os.rename, support.TESTFN, support.TESTFN+".bak") def test_remove(self): self.assertRaises(WindowsError, os.remove, support.TESTFN) def test_chdir(self): self.assertRaises(WindowsError, os.chdir, support.TESTFN) def test_mkdir(self): f = open(support.TESTFN, "w") try: self.assertRaises(WindowsError, os.mkdir, support.TESTFN) finally: f.close() os.unlink(support.TESTFN) def test_utime(self): self.assertRaises(WindowsError, os.utime, support.TESTFN, None) def test_chmod(self): self.assertRaises(WindowsError, os.chmod, support.TESTFN, 0) class TestInvalidFD(unittest.TestCase): singles = ["fchdir", "dup", "fdopen", "fdatasync", "fstat", "fstatvfs", "fsync", "tcgetpgrp", "ttyname"] #singles.append("close") #We omit close because it doesn'r raise an exception on some platforms def get_single(f): def helper(self): if hasattr(os, f): self.check(getattr(os, f)) return helper for f in singles: locals()["test_"+f] = get_single(f) def check(self, f, *args): try: f(support.make_bad_fd(), *args) except OSError as e: self.assertEqual(e.errno, errno.EBADF) else: self.fail("%r didn't raise a OSError with a bad file descriptor" % f) def test_isatty(self): if hasattr(os, "isatty"): self.assertEqual(os.isatty(support.make_bad_fd()), False) def test_closerange(self): if hasattr(os, "closerange"): fd = support.make_bad_fd() # Make sure none of the descriptors we are about to close are # currently valid (issue 6542). for i in range(10): try: os.fstat(fd+i) except OSError: pass else: break if i < 2: raise unittest.SkipTest( "Unable to acquire a range of invalid file descriptors") self.assertEqual(os.closerange(fd, fd + i-1), None) def test_dup2(self): if hasattr(os, "dup2"): self.check(os.dup2, 20) def test_fchmod(self): if hasattr(os, "fchmod"): self.check(os.fchmod, 0) def test_fchown(self): if hasattr(os, "fchown"): self.check(os.fchown, -1, -1) def test_fpathconf(self): if hasattr(os, "fpathconf"): self.check(os.fpathconf, "PC_NAME_MAX") def test_ftruncate(self): if hasattr(os, "ftruncate"): self.check(os.ftruncate, 0) def test_lseek(self): if hasattr(os, "lseek"): self.check(os.lseek, 0, 0) def test_read(self): if hasattr(os, "read"): self.check(os.read, 1) def test_tcsetpgrpt(self): if hasattr(os, "tcsetpgrp"): self.check(os.tcsetpgrp, 0) def test_write(self): if hasattr(os, "write"): self.check(os.write, b" ") if sys.platform != 'win32': class Win32ErrorTests(unittest.TestCase): pass class PosixUidGidTests(unittest.TestCase): if hasattr(os, 'setuid'): def test_setuid(self): if os.getuid() != 0: self.assertRaises(os.error, os.setuid, 0) self.assertRaises(OverflowError, os.setuid, 1<<32) if hasattr(os, 'setgid'): def test_setgid(self): if os.getuid() != 0: self.assertRaises(os.error, os.setgid, 0) self.assertRaises(OverflowError, os.setgid, 1<<32) if hasattr(os, 'seteuid'): def test_seteuid(self): if os.getuid() != 0: self.assertRaises(os.error, os.seteuid, 0) self.assertRaises(OverflowError, os.seteuid, 1<<32) if hasattr(os, 'setegid'): def test_setegid(self): if os.getuid() != 0: self.assertRaises(os.error, os.setegid, 0) self.assertRaises(OverflowError, os.setegid, 1<<32) if hasattr(os, 'setreuid'): def test_setreuid(self): if os.getuid() != 0: self.assertRaises(os.error, os.setreuid, 0, 0) self.assertRaises(OverflowError, os.setreuid, 1<<32, 0) self.assertRaises(OverflowError, os.setreuid, 0, 1<<32) def test_setreuid_neg1(self): # Needs to accept -1. We run this in a subprocess to avoid # altering the test runner's process state (issue8045). subprocess.check_call([ sys.executable, '-c', 'import os,sys;os.setreuid(-1,-1);sys.exit(0)']) if hasattr(os, 'setregid'): def test_setregid(self): if os.getuid() != 0: self.assertRaises(os.error, os.setregid, 0, 0) self.assertRaises(OverflowError, os.setregid, 1<<32, 0) self.assertRaises(OverflowError, os.setregid, 0, 1<<32) def test_setregid_neg1(self): # Needs to accept -1. We run this in a subprocess to avoid # altering the test runner's process state (issue8045). subprocess.check_call([ sys.executable, '-c', 'import os,sys;os.setregid(-1,-1);sys.exit(0)']) class Pep383Tests(unittest.TestCase): def setUp(self): if support.TESTFN_UNENCODABLE: self.dir = support.TESTFN_UNENCODABLE else: self.dir = support.TESTFN self.bdir = os.fsencode(self.dir) bytesfn = [] def add_filename(fn): try: fn = os.fsencode(fn) except UnicodeEncodeError: return bytesfn.append(fn) add_filename(support.TESTFN_UNICODE) if support.TESTFN_UNENCODABLE: add_filename(support.TESTFN_UNENCODABLE) if not bytesfn: self.skipTest("couldn't create any non-ascii filename") self.unicodefn = set() os.mkdir(self.dir) try: for fn in bytesfn: f = open(os.path.join(self.bdir, fn), "w") f.close() fn = os.fsdecode(fn) if fn in self.unicodefn: raise ValueError("duplicate filename") self.unicodefn.add(fn) except: shutil.rmtree(self.dir) raise def tearDown(self): shutil.rmtree(self.dir) def test_listdir(self): expected = self.unicodefn found = set(os.listdir(self.dir)) self.assertEquals(found, expected) def test_open(self): for fn in self.unicodefn: f = open(os.path.join(self.dir, fn)) f.close() def test_stat(self): for fn in self.unicodefn: os.stat(os.path.join(self.dir, fn)) else: class PosixUidGidTests(unittest.TestCase): pass class Pep383Tests(unittest.TestCase): pass @unittest.skipUnless(sys.platform == "win32", "Win32 specific tests") class Win32KillTests(unittest.TestCase): def _kill(self, sig): # Start sys.executable as a subprocess and communicate from the # subprocess to the parent that the interpreter is ready. When it # becomes ready, send *sig* via os.kill to the subprocess and check # that the return code is equal to *sig*. import ctypes from ctypes import wintypes import msvcrt # Since we can't access the contents of the process' stdout until the # process has exited, use PeekNamedPipe to see what's inside stdout # without waiting. This is done so we can tell that the interpreter # is started and running at a point where it could handle a signal. PeekNamedPipe = ctypes.windll.kernel32.PeekNamedPipe PeekNamedPipe.restype = wintypes.BOOL PeekNamedPipe.argtypes = (wintypes.HANDLE, # Pipe handle ctypes.POINTER(ctypes.c_char), # stdout buf wintypes.DWORD, # Buffer size ctypes.POINTER(wintypes.DWORD), # bytes read ctypes.POINTER(wintypes.DWORD), # bytes avail ctypes.POINTER(wintypes.DWORD)) # bytes left msg = "running" proc = subprocess.Popen([sys.executable, "-c", "import sys;" "sys.stdout.write('{}');" "sys.stdout.flush();" "input()".format(msg)], stdout=subprocess.PIPE, stderr=subprocess.PIPE, stdin=subprocess.PIPE) count, max = 0, 100 while count < max and proc.poll() is None: # Create a string buffer to store the result of stdout from the pipe buf = ctypes.create_string_buffer(len(msg)) # Obtain the text currently in proc.stdout # Bytes read/avail/left are left as NULL and unused rslt = PeekNamedPipe(msvcrt.get_osfhandle(proc.stdout.fileno()), buf, ctypes.sizeof(buf), None, None, None) self.assertNotEqual(rslt, 0, "PeekNamedPipe failed") if buf.value: self.assertEqual(msg, buf.value.decode()) break time.sleep(0.1) count += 1 else: self.fail("Did not receive communication from the subprocess") os.kill(proc.pid, sig) self.assertEqual(proc.wait(), sig) def test_kill_sigterm(self): # SIGTERM doesn't mean anything special, but make sure it works self._kill(signal.SIGTERM) def test_kill_int(self): # os.kill on Windows can take an int which gets set as the exit code self._kill(100) def _kill_with_event(self, event, name): # Run a script which has console control handling enabled. proc = subprocess.Popen([sys.executable, os.path.join(os.path.dirname(__file__), "win_console_handler.py")], creationflags=subprocess.CREATE_NEW_PROCESS_GROUP) # Let the interpreter startup before we send signals. See #3137. time.sleep(0.5) os.kill(proc.pid, event) # proc.send_signal(event) could also be done here. # Allow time for the signal to be passed and the process to exit. time.sleep(0.5) if not proc.poll(): # Forcefully kill the process if we weren't able to signal it. os.kill(proc.pid, signal.SIGINT) self.fail("subprocess did not stop on {}".format(name)) @unittest.skip("subprocesses aren't inheriting CTRL+C property") def test_CTRL_C_EVENT(self): from ctypes import wintypes import ctypes # Make a NULL value by creating a pointer with no argument. NULL = ctypes.POINTER(ctypes.c_int)() SetConsoleCtrlHandler = ctypes.windll.kernel32.SetConsoleCtrlHandler SetConsoleCtrlHandler.argtypes = (ctypes.POINTER(ctypes.c_int), wintypes.BOOL) SetConsoleCtrlHandler.restype = wintypes.BOOL # Calling this with NULL and FALSE causes the calling process to # handle CTRL+C, rather than ignore it. This property is inherited # by subprocesses. SetConsoleCtrlHandler(NULL, 0) self._kill_with_event(signal.CTRL_C_EVENT, "CTRL_C_EVENT") def test_CTRL_BREAK_EVENT(self): self._kill_with_event(signal.CTRL_BREAK_EVENT, "CTRL_BREAK_EVENT") def skipUnlessWindows6(test): if (hasattr(sys, 'getwindowsversion') and sys.getwindowsversion().major >= 6): return test return unittest.skip("Requires Windows Vista or later")(test) @unittest.skipUnless(sys.platform == "win32", "Win32 specific tests") @support.skip_unless_symlink class Win32SymlinkTests(unittest.TestCase): filelink = 'filelinktest' filelink_target = os.path.abspath(__file__) dirlink = 'dirlinktest' dirlink_target = os.path.dirname(filelink_target) missing_link = 'missing link' def setUp(self): assert os.path.exists(self.dirlink_target) assert os.path.exists(self.filelink_target) assert not os.path.exists(self.dirlink) assert not os.path.exists(self.filelink) assert not os.path.exists(self.missing_link) def tearDown(self): if os.path.exists(self.filelink): os.remove(self.filelink) if os.path.exists(self.dirlink): os.rmdir(self.dirlink) if os.path.lexists(self.missing_link): os.remove(self.missing_link) def test_directory_link(self): os.symlink(self.dirlink_target, self.dirlink) self.assertTrue(os.path.exists(self.dirlink)) self.assertTrue(os.path.isdir(self.dirlink)) self.assertTrue(os.path.islink(self.dirlink)) self.check_stat(self.dirlink, self.dirlink_target) def test_file_link(self): os.symlink(self.filelink_target, self.filelink) self.assertTrue(os.path.exists(self.filelink)) self.assertTrue(os.path.isfile(self.filelink)) self.assertTrue(os.path.islink(self.filelink)) self.check_stat(self.filelink, self.filelink_target) def _create_missing_dir_link(self): 'Create a "directory" link to a non-existent target' linkname = self.missing_link if os.path.lexists(linkname): os.remove(linkname) target = r'c:\\target does not exist.29r3c740' assert not os.path.exists(target) target_is_dir = True os.symlink(target, linkname, target_is_dir) def test_remove_directory_link_to_missing_target(self): self._create_missing_dir_link() # For compatibility with Unix, os.remove will check the # directory status and call RemoveDirectory if the symlink # was created with target_is_dir==True. os.remove(self.missing_link) @unittest.skip("currently fails; consider for improvement") def test_isdir_on_directory_link_to_missing_target(self): self._create_missing_dir_link() # consider having isdir return true for directory links self.assertTrue(os.path.isdir(self.missing_link)) @unittest.skip("currently fails; consider for improvement") def test_rmdir_on_directory_link_to_missing_target(self): self._create_missing_dir_link() # consider allowing rmdir to remove directory links os.rmdir(self.missing_link) def check_stat(self, link, target): self.assertEqual(os.stat(link), os.stat(target)) self.assertNotEqual(os.lstat(link), os.stat(link)) class FSEncodingTests(unittest.TestCase): def test_nop(self): self.assertEquals(os.fsencode(b'abc\xff'), b'abc\xff') self.assertEquals(os.fsdecode('abc\u0141'), 'abc\u0141') def test_identity(self): # assert fsdecode(fsencode(x)) == x for fn in ('unicode\u0141', 'latin\xe9', 'ascii'): try: bytesfn = os.fsencode(fn) except UnicodeEncodeError: continue self.assertEquals(os.fsdecode(bytesfn), fn) def get_output(self, fs_encoding, func): env = os.environ.copy() env['PYTHONIOENCODING'] = 'utf-8' env['PYTHONFSENCODING'] = fs_encoding code = 'import os; print(%s, end="")' % func process = subprocess.Popen( [sys.executable, "-c", code], stdout=subprocess.PIPE, env=env) stdout, stderr = process.communicate() self.assertEqual(process.returncode, 0) return stdout.decode('utf-8') @unittest.skipIf(sys.platform in ('win32', 'darwin'), 'PYTHONFSENCODING is ignored on Windows and Mac OS X') def test_encodings(self): def check(encoding, bytesfn, unicodefn): encoded = self.get_output(encoding, 'repr(os.fsencode(%a))' % unicodefn) self.assertEqual(encoded, repr(bytesfn)) decoded = self.get_output(encoding, 'repr(os.fsdecode(%a))' % bytesfn) self.assertEqual(decoded, repr(unicodefn)) check('utf-8', b'\xc3\xa9\x80', '\xe9\udc80') # Raise SkipTest() if sys.executable is not encodable to ascii support.workaroundIssue8611() check('ascii', b'abc\xff', 'abc\udcff') check('iso-8859-15', b'\xef\xa4', '\xef\u20ac') def test_main(): support.run_unittest( FileTests, StatAttributeTests, EnvironTests, WalkTests, MakedirTests, DevNullTests, URandomTests, ExecTests, Win32ErrorTests, TestInvalidFD, PosixUidGidTests, Pep383Tests, Win32KillTests, Win32SymlinkTests, FSEncodingTests, ) if __name__ == "__main__": test_main()