import _thread as thread import contextlib import errno import functools import gc from io import BytesIO import os import re import select import socket import struct import sys import threading import time import unittest import warnings from waitress import compat, wasyncore as asyncore TIMEOUT = 3 HAS_UNIX_SOCKETS = hasattr(socket, "AF_UNIX") HOST = "localhost" HOSTv4 = "127.0.0.1" HOSTv6 = "::1" # Filename used for testing if os.name == "java": # pragma: no cover # Jython disallows @ in module names TESTFN = "$test" else: TESTFN = "@test" TESTFN = "{}_{}_tmp".format(TESTFN, os.getpid()) class DummyLogger: # pragma: no cover def __init__(self): self.messages = [] def log(self, severity, message): self.messages.append((severity, message)) class WarningsRecorder: # pragma: no cover """Convenience wrapper for the warnings list returned on entry to the warnings.catch_warnings() context manager. """ def __init__(self, warnings_list): self._warnings = warnings_list self._last = 0 @property def warnings(self): return self._warnings[self._last :] def reset(self): self._last = len(self._warnings) def _filterwarnings(filters, quiet=False): # pragma: no cover """Catch the warnings, then check if all the expected warnings have been raised and re-raise unexpected warnings. If 'quiet' is True, only re-raise the unexpected warnings. """ # Clear the warning registry of the calling module # in order to re-raise the warnings. frame = sys._getframe(2) registry = frame.f_globals.get("__warningregistry__") if registry: registry.clear() with warnings.catch_warnings(record=True) as w: # Set filter "always" to record all warnings. Because # test_warnings swap the module, we need to look up in # the sys.modules dictionary. sys.modules["warnings"].simplefilter("always") yield WarningsRecorder(w) # Filter the recorded warnings reraise = list(w) missing = [] for msg, cat in filters: seen = False for w in reraise[:]: warning = w.message # Filter out the matching messages if re.match(msg, str(warning), re.I) and issubclass(warning.__class__, cat): seen = True reraise.remove(w) if not seen and not quiet: # This filter caught nothing missing.append((msg, cat.__name__)) if reraise: raise AssertionError("unhandled warning %s" % reraise[0]) if missing: raise AssertionError("filter (%r, %s) did not catch any warning" % missing[0]) @contextlib.contextmanager def check_warnings(*filters, **kwargs): # pragma: no cover """Context manager to silence warnings. Accept 2-tuples as positional arguments: ("message regexp", WarningCategory) Optional argument: - if 'quiet' is True, it does not fail if a filter catches nothing (default True without argument, default False if some filters are defined) Without argument, it defaults to: check_warnings(("", Warning), quiet=True) """ quiet = kwargs.get("quiet") if not filters: filters = (("", Warning),) # Preserve backward compatibility if quiet is None: quiet = True return _filterwarnings(filters, quiet) def gc_collect(): # pragma: no cover """Force as many objects as possible to be collected. In non-CPython implementations of Python, this is needed because timely deallocation is not guaranteed by the garbage collector. (Even in CPython this can be the case in case of reference cycles.) This means that __del__ methods may be called later than expected and weakrefs may remain alive for longer than expected. This function tries its best to force all garbage objects to disappear. """ gc.collect() if sys.platform.startswith("java"): time.sleep(0.1) gc.collect() gc.collect() def threading_setup(): # pragma: no cover return (thread._count(), None) def threading_cleanup(*original_values): # pragma: no cover global environment_altered _MAX_COUNT = 100 for count in range(_MAX_COUNT): values = (thread._count(), None) if values == original_values: break if not count: # Display a warning at the first iteration environment_altered = True sys.stderr.write( "Warning -- threading_cleanup() failed to cleanup " "%s threads" % (values[0] - original_values[0]) ) sys.stderr.flush() values = None time.sleep(0.01) gc_collect() def reap_threads(func): # pragma: no cover """Use this function when threads are being used. This will ensure that the threads are cleaned up even when the test fails. """ @functools.wraps(func) def decorator(*args): key = threading_setup() try: return func(*args) finally: threading_cleanup(*key) return decorator def join_thread(thread, timeout=30.0): # pragma: no cover """Join a thread. Raise an AssertionError if the thread is still alive after timeout seconds. """ thread.join(timeout) if thread.is_alive(): msg = "failed to join the thread in %.1f seconds" % timeout raise AssertionError(msg) def bind_port(sock, host=HOST): # pragma: no cover """Bind the socket to a free port and return the port number. Relies on ephemeral ports in order to ensure we are using an unbound port. This is important as many tests may be running simultaneously, especially in a buildbot environment. This method raises an exception if the sock.family is AF_INET and sock.type is SOCK_STREAM, *and* the socket has SO_REUSEADDR or SO_REUSEPORT set on it. Tests should *never* set these socket options for TCP/IP sockets. The only case for setting these options is testing multicasting via multiple UDP sockets. Additionally, if the SO_EXCLUSIVEADDRUSE socket option is available (i.e. on Windows), it will be set on the socket. This will prevent anyone else from bind()'ing to our host/port for the duration of the test. """ if sock.family == socket.AF_INET and sock.type == socket.SOCK_STREAM: if hasattr(socket, "SO_REUSEADDR"): if sock.getsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR) == 1: raise RuntimeError( "tests should never set the SO_REUSEADDR " "socket option on TCP/IP sockets!" ) if hasattr(socket, "SO_REUSEPORT"): try: if sock.getsockopt(socket.SOL_SOCKET, socket.SO_REUSEPORT) == 1: raise RuntimeError( "tests should never set the SO_REUSEPORT " "socket option on TCP/IP sockets!" ) except OSError: # Python's socket module was compiled using modern headers # thus defining SO_REUSEPORT but this process is running # under an older kernel that does not support SO_REUSEPORT. pass if hasattr(socket, "SO_EXCLUSIVEADDRUSE"): sock.setsockopt(socket.SOL_SOCKET, socket.SO_EXCLUSIVEADDRUSE, 1) sock.bind((host, 0)) port = sock.getsockname()[1] return port @contextlib.contextmanager def closewrapper(sock): # pragma: no cover try: yield sock finally: sock.close() class dummysocket: # pragma: no cover def __init__(self): self.closed = False def close(self): self.closed = True def fileno(self): return 42 def setblocking(self, yesno): self.isblocking = yesno def getpeername(self): return "peername" class dummychannel: # pragma: no cover def __init__(self): self.socket = dummysocket() def close(self): self.socket.close() class exitingdummy: # pragma: no cover def __init__(self): pass def handle_read_event(self): raise asyncore.ExitNow() handle_write_event = handle_read_event handle_close = handle_read_event handle_expt_event = handle_read_event class crashingdummy: def __init__(self): self.error_handled = False def handle_read_event(self): raise Exception() handle_write_event = handle_read_event handle_close = handle_read_event handle_expt_event = handle_read_event def handle_error(self): self.error_handled = True # used when testing senders; just collects what it gets until newline is sent def capture_server(evt, buf, serv): # pragma no cover try: serv.listen(0) conn, addr = serv.accept() except socket.timeout: pass else: n = 200 start = time.time() while n > 0 and time.time() - start < 3.0: r, w, e = select.select([conn], [], [], 0.1) if r: n -= 1 data = conn.recv(10) # keep everything except for the newline terminator buf.write(data.replace(b"\n", b"")) if b"\n" in data: break time.sleep(0.01) conn.close() finally: serv.close() evt.set() def bind_unix_socket(sock, addr): # pragma: no cover """Bind a unix socket, raising SkipTest if PermissionError is raised.""" assert sock.family == socket.AF_UNIX try: sock.bind(addr) except PermissionError: sock.close() raise unittest.SkipTest("cannot bind AF_UNIX sockets") def bind_af_aware(sock, addr): """Helper function to bind a socket according to its family.""" if HAS_UNIX_SOCKETS and sock.family == socket.AF_UNIX: # Make sure the path doesn't exist. unlink(addr) bind_unix_socket(sock, addr) else: sock.bind(addr) if sys.platform.startswith("win"): # pragma: no cover def _waitfor(func, pathname, waitall=False): # Perform the operation func(pathname) # Now setup the wait loop if waitall: dirname = pathname else: dirname, name = os.path.split(pathname) dirname = dirname or "." # Check for `pathname` to be removed from the filesystem. # The exponential backoff of the timeout amounts to a total # of ~1 second after which the deletion is probably an error # anyway. # Testing on an i7@4.3GHz shows that usually only 1 iteration is # required when contention occurs. timeout = 0.001 while timeout < 1.0: # Note we are only testing for the existence of the file(s) in # the contents of the directory regardless of any security or # access rights. If we have made it this far, we have sufficient # permissions to do that much using Python's equivalent of the # Windows API FindFirstFile. # Other Windows APIs can fail or give incorrect results when # dealing with files that are pending deletion. L = os.listdir(dirname) if not (L if waitall else name in L): return # Increase the timeout and try again time.sleep(timeout) timeout *= 2 warnings.warn( "tests may fail, delete still pending for " + pathname, RuntimeWarning, stacklevel=4, ) def _unlink(filename): _waitfor(os.unlink, filename) else: _unlink = os.unlink def unlink(filename): try: _unlink(filename) except OSError: pass def _is_ipv6_enabled(): # pragma: no cover """Check whether IPv6 is enabled on this host.""" if compat.HAS_IPV6: sock = None try: sock = socket.socket(socket.AF_INET6, socket.SOCK_STREAM) sock.bind(("::1", 0)) return True except OSError: pass finally: if sock: sock.close() return False IPV6_ENABLED = _is_ipv6_enabled() class HelperFunctionTests(unittest.TestCase): def test_readwriteexc(self): # Check exception handling behavior of read, write and _exception # check that ExitNow exceptions in the object handler method # bubbles all the way up through asyncore read/write/_exception calls tr1 = exitingdummy() self.assertRaises(asyncore.ExitNow, asyncore.read, tr1) self.assertRaises(asyncore.ExitNow, asyncore.write, tr1) self.assertRaises(asyncore.ExitNow, asyncore._exception, tr1) # check that an exception other than ExitNow in the object handler # method causes the handle_error method to get called tr2 = crashingdummy() asyncore.read(tr2) self.assertEqual(tr2.error_handled, True) tr2 = crashingdummy() asyncore.write(tr2) self.assertEqual(tr2.error_handled, True) tr2 = crashingdummy() asyncore._exception(tr2) self.assertEqual(tr2.error_handled, True) # asyncore.readwrite uses constants in the select module that # are not present in Windows systems (see this thread: # http://mail.python.org/pipermail/python-list/2001-October/109973.html) # These constants should be present as long as poll is available @unittest.skipUnless(hasattr(select, "poll"), "select.poll required") def test_readwrite(self): # Check that correct methods are called by readwrite() attributes = ("read", "expt", "write", "closed", "error_handled") expected = ( (select.POLLIN, "read"), (select.POLLPRI, "expt"), (select.POLLOUT, "write"), (select.POLLERR, "closed"), (select.POLLHUP, "closed"), (select.POLLNVAL, "closed"), ) class testobj: def __init__(self): self.read = False self.write = False self.closed = False self.expt = False self.error_handled = False def handle_read_event(self): self.read = True def handle_write_event(self): self.write = True def handle_close(self): self.closed = True def handle_expt_event(self): self.expt = True # def handle_error(self): # self.error_handled = True for flag, expectedattr in expected: tobj = testobj() self.assertEqual(getattr(tobj, expectedattr), False) asyncore.readwrite(tobj, flag) # Only the attribute modified by the routine we expect to be # called should be True. for attr in attributes: self.assertEqual(getattr(tobj, attr), attr == expectedattr) # check that ExitNow exceptions in the object handler method # bubbles all the way up through asyncore readwrite call tr1 = exitingdummy() self.assertRaises(asyncore.ExitNow, asyncore.readwrite, tr1, flag) # check that an exception other than ExitNow in the object handler # method causes the handle_error method to get called tr2 = crashingdummy() self.assertEqual(tr2.error_handled, False) asyncore.readwrite(tr2, flag) self.assertEqual(tr2.error_handled, True) def test_closeall(self): self.closeall_check(False) def test_closeall_default(self): self.closeall_check(True) def closeall_check(self, usedefault): # Check that close_all() closes everything in a given map l = [] testmap = {} for i in range(10): c = dummychannel() l.append(c) self.assertEqual(c.socket.closed, False) testmap[i] = c if usedefault: socketmap = asyncore.socket_map try: asyncore.socket_map = testmap asyncore.close_all() finally: testmap, asyncore.socket_map = asyncore.socket_map, socketmap else: asyncore.close_all(testmap) self.assertEqual(len(testmap), 0) for c in l: self.assertEqual(c.socket.closed, True) def test_compact_traceback(self): try: raise Exception("I don't like spam!") except: real_t, real_v, real_tb = sys.exc_info() r = asyncore.compact_traceback() (f, function, line), t, v, info = r self.assertEqual(os.path.split(f)[-1], "test_wasyncore.py") self.assertEqual(function, "test_compact_traceback") self.assertEqual(t, real_t) self.assertEqual(v, real_v) self.assertEqual(info, "[%s|%s|%s]" % (f, function, line)) class DispatcherTests(unittest.TestCase): def setUp(self): pass def tearDown(self): asyncore.close_all() def test_basic(self): d = asyncore.dispatcher() self.assertEqual(d.readable(), True) self.assertEqual(d.writable(), True) def test_repr(self): d = asyncore.dispatcher() self.assertEqual(repr(d), "" % id(d)) def test_log_info(self): import logging inst = asyncore.dispatcher(map={}) logger = DummyLogger() inst.logger = logger inst.log_info("message", "warning") self.assertEqual(logger.messages, [(logging.WARN, "message")]) def test_log(self): import logging inst = asyncore.dispatcher() logger = DummyLogger() inst.logger = logger inst.log("message") self.assertEqual(logger.messages, [(logging.DEBUG, "message")]) def test_unhandled(self): import logging inst = asyncore.dispatcher() logger = DummyLogger() inst.logger = logger inst.handle_expt() inst.handle_read() inst.handle_write() inst.handle_connect() expected = [ (logging.WARN, "unhandled incoming priority event"), (logging.WARN, "unhandled read event"), (logging.WARN, "unhandled write event"), (logging.WARN, "unhandled connect event"), ] self.assertEqual(logger.messages, expected) def test_strerror(self): # refers to bug #8573 err = asyncore._strerror(errno.EPERM) if hasattr(os, "strerror"): self.assertEqual(err, os.strerror(errno.EPERM)) err = asyncore._strerror(-1) self.assertTrue(err != "") class dispatcherwithsend_noread(asyncore.dispatcher_with_send): # pragma: no cover def readable(self): return False def handle_connect(self): pass class DispatcherWithSendTests(unittest.TestCase): def setUp(self): pass def tearDown(self): asyncore.close_all() @reap_threads def test_send(self): evt = threading.Event() sock = socket.socket() sock.settimeout(3) port = bind_port(sock) cap = BytesIO() args = (evt, cap, sock) t = threading.Thread(target=capture_server, args=args) t.start() try: # wait a little longer for the server to initialize (it sometimes # refuses connections on slow machines without this wait) time.sleep(0.2) data = b"Suppose there isn't a 16-ton weight?" d = dispatcherwithsend_noread() d.create_socket() d.connect((HOST, port)) # give time for socket to connect time.sleep(0.1) d.send(data) d.send(data) d.send(b"\n") n = 1000 while d.out_buffer and n > 0: # pragma: no cover asyncore.poll() n -= 1 evt.wait() self.assertEqual(cap.getvalue(), data * 2) finally: join_thread(t, timeout=TIMEOUT) @unittest.skipUnless( hasattr(asyncore, "file_wrapper"), "asyncore.file_wrapper required" ) class FileWrapperTest(unittest.TestCase): def setUp(self): self.d = b"It's not dead, it's sleeping!" with open(TESTFN, "wb") as file: file.write(self.d) def tearDown(self): unlink(TESTFN) def test_recv(self): fd = os.open(TESTFN, os.O_RDONLY) w = asyncore.file_wrapper(fd) os.close(fd) self.assertNotEqual(w.fd, fd) self.assertNotEqual(w.fileno(), fd) self.assertEqual(w.recv(13), b"It's not dead") self.assertEqual(w.read(6), b", it's") w.close() self.assertRaises(OSError, w.read, 1) def test_send(self): d1 = b"Come again?" d2 = b"I want to buy some cheese." fd = os.open(TESTFN, os.O_WRONLY | os.O_APPEND) w = asyncore.file_wrapper(fd) os.close(fd) w.write(d1) w.send(d2) w.close() with open(TESTFN, "rb") as file: self.assertEqual(file.read(), self.d + d1 + d2) @unittest.skipUnless( hasattr(asyncore, "file_dispatcher"), "asyncore.file_dispatcher required" ) def test_dispatcher(self): fd = os.open(TESTFN, os.O_RDONLY) data = [] class FileDispatcher(asyncore.file_dispatcher): def handle_read(self): data.append(self.recv(29)) FileDispatcher(fd) os.close(fd) asyncore.loop(timeout=0.01, use_poll=True, count=2) self.assertEqual(b"".join(data), self.d) def test_resource_warning(self): # Issue #11453 got_warning = False while got_warning is False: # we try until we get the outcome we want because this # test is not deterministic (gc_collect() may not fd = os.open(TESTFN, os.O_RDONLY) f = asyncore.file_wrapper(fd) os.close(fd) try: with check_warnings(("", ResourceWarning)): f = None gc_collect() except AssertionError: # pragma: no cover pass else: got_warning = True def test_close_twice(self): fd = os.open(TESTFN, os.O_RDONLY) f = asyncore.file_wrapper(fd) os.close(fd) os.close(f.fd) # file_wrapper dupped fd with self.assertRaises(OSError): f.close() self.assertEqual(f.fd, -1) # calling close twice should not fail f.close() class BaseTestHandler(asyncore.dispatcher): # pragma: no cover def __init__(self, sock=None): asyncore.dispatcher.__init__(self, sock) self.flag = False def handle_accept(self): raise Exception("handle_accept not supposed to be called") def handle_accepted(self): raise Exception("handle_accepted not supposed to be called") def handle_connect(self): raise Exception("handle_connect not supposed to be called") def handle_expt(self): raise Exception("handle_expt not supposed to be called") def handle_close(self): raise Exception("handle_close not supposed to be called") def handle_error(self): raise class BaseServer(asyncore.dispatcher): """A server which listens on an address and dispatches the connection to a handler. """ def __init__(self, family, addr, handler=BaseTestHandler): asyncore.dispatcher.__init__(self) self.create_socket(family) self.set_reuse_addr() bind_af_aware(self.socket, addr) self.listen(5) self.handler = handler @property def address(self): return self.socket.getsockname() def handle_accepted(self, sock, addr): self.handler(sock) def handle_error(self): # pragma: no cover raise class BaseClient(BaseTestHandler): def __init__(self, family, address): BaseTestHandler.__init__(self) self.create_socket(family) self.connect(address) def handle_connect(self): pass class BaseTestAPI: def tearDown(self): asyncore.close_all(ignore_all=True) def loop_waiting_for_flag(self, instance, timeout=5): # pragma: no cover timeout = float(timeout) / 100 count = 100 while asyncore.socket_map and count > 0: asyncore.loop(timeout=0.01, count=1, use_poll=self.use_poll) if instance.flag: return count -= 1 time.sleep(timeout) self.fail("flag not set") def test_handle_connect(self): # make sure handle_connect is called on connect() class TestClient(BaseClient): def handle_connect(self): self.flag = True server = BaseServer(self.family, self.addr) client = TestClient(self.family, server.address) self.loop_waiting_for_flag(client) def test_handle_accept(self): # make sure handle_accept() is called when a client connects class TestListener(BaseTestHandler): def __init__(self, family, addr): BaseTestHandler.__init__(self) self.create_socket(family) bind_af_aware(self.socket, addr) self.listen(5) self.address = self.socket.getsockname() def handle_accept(self): self.flag = True server = TestListener(self.family, self.addr) client = BaseClient(self.family, server.address) self.loop_waiting_for_flag(server) def test_handle_accepted(self): # make sure handle_accepted() is called when a client connects class TestListener(BaseTestHandler): def __init__(self, family, addr): BaseTestHandler.__init__(self) self.create_socket(family) bind_af_aware(self.socket, addr) self.listen(5) self.address = self.socket.getsockname() def handle_accept(self): asyncore.dispatcher.handle_accept(self) def handle_accepted(self, sock, addr): sock.close() self.flag = True server = TestListener(self.family, self.addr) client = BaseClient(self.family, server.address) self.loop_waiting_for_flag(server) def test_handle_read(self): # make sure handle_read is called on data received class TestClient(BaseClient): def handle_read(self): self.flag = True class TestHandler(BaseTestHandler): def __init__(self, conn): BaseTestHandler.__init__(self, conn) self.send(b"x" * 1024) server = BaseServer(self.family, self.addr, TestHandler) client = TestClient(self.family, server.address) self.loop_waiting_for_flag(client) def test_handle_write(self): # make sure handle_write is called class TestClient(BaseClient): def handle_write(self): self.flag = True server = BaseServer(self.family, self.addr) client = TestClient(self.family, server.address) self.loop_waiting_for_flag(client) def test_handle_close(self): # make sure handle_close is called when the other end closes # the connection class TestClient(BaseClient): def handle_read(self): # in order to make handle_close be called we are supposed # to make at least one recv() call self.recv(1024) def handle_close(self): self.flag = True self.close() class TestHandler(BaseTestHandler): def __init__(self, conn): BaseTestHandler.__init__(self, conn) self.close() server = BaseServer(self.family, self.addr, TestHandler) client = TestClient(self.family, server.address) self.loop_waiting_for_flag(client) def test_handle_close_after_conn_broken(self): # Check that ECONNRESET/EPIPE is correctly handled (issues #5661 and # #11265). data = b"\0" * 128 class TestClient(BaseClient): def handle_write(self): self.send(data) def handle_close(self): self.flag = True self.close() def handle_expt(self): # pragma: no cover # needs to exist for MacOS testing self.flag = True self.close() class TestHandler(BaseTestHandler): def handle_read(self): self.recv(len(data)) self.close() def writable(self): return False server = BaseServer(self.family, self.addr, TestHandler) client = TestClient(self.family, server.address) self.loop_waiting_for_flag(client) @unittest.skipIf( sys.platform.startswith("sunos"), "OOB support is broken on Solaris" ) def test_handle_expt(self): # Make sure handle_expt is called on OOB data received. # Note: this might fail on some platforms as OOB data is # tenuously supported and rarely used. if HAS_UNIX_SOCKETS and self.family == socket.AF_UNIX: self.skipTest("Not applicable to AF_UNIX sockets.") if sys.platform == "darwin" and self.use_poll: # pragma: no cover self.skipTest("poll may fail on macOS; see issue #28087") class TestClient(BaseClient): def handle_expt(self): self.socket.recv(1024, socket.MSG_OOB) self.flag = True class TestHandler(BaseTestHandler): def __init__(self, conn): BaseTestHandler.__init__(self, conn) self.socket.send(chr(244).encode("latin-1"), socket.MSG_OOB) server = BaseServer(self.family, self.addr, TestHandler) client = TestClient(self.family, server.address) self.loop_waiting_for_flag(client) def test_handle_error(self): class TestClient(BaseClient): def handle_write(self): 1.0 / 0 def handle_error(self): self.flag = True try: raise except ZeroDivisionError: pass else: # pragma: no cover raise Exception("exception not raised") server = BaseServer(self.family, self.addr) client = TestClient(self.family, server.address) self.loop_waiting_for_flag(client) def test_connection_attributes(self): server = BaseServer(self.family, self.addr) client = BaseClient(self.family, server.address) # we start disconnected self.assertFalse(server.connected) self.assertTrue(server.accepting) # this can't be taken for granted across all platforms # self.assertFalse(client.connected) self.assertFalse(client.accepting) # execute some loops so that client connects to server asyncore.loop(timeout=0.01, use_poll=self.use_poll, count=100) self.assertFalse(server.connected) self.assertTrue(server.accepting) self.assertTrue(client.connected) self.assertFalse(client.accepting) # disconnect the client client.close() self.assertFalse(server.connected) self.assertTrue(server.accepting) self.assertFalse(client.connected) self.assertFalse(client.accepting) # stop serving server.close() self.assertFalse(server.connected) self.assertFalse(server.accepting) def test_create_socket(self): s = asyncore.dispatcher() s.create_socket(self.family) # self.assertEqual(s.socket.type, socket.SOCK_STREAM) self.assertEqual(s.socket.family, self.family) self.assertEqual(s.socket.gettimeout(), 0) # self.assertFalse(s.socket.get_inheritable()) def test_bind(self): if HAS_UNIX_SOCKETS and self.family == socket.AF_UNIX: self.skipTest("Not applicable to AF_UNIX sockets.") s1 = asyncore.dispatcher() s1.create_socket(self.family) s1.bind(self.addr) s1.listen(5) port = s1.socket.getsockname()[1] s2 = asyncore.dispatcher() s2.create_socket(self.family) # EADDRINUSE indicates the socket was correctly bound self.assertRaises(socket.error, s2.bind, (self.addr[0], port)) def test_set_reuse_addr(self): # pragma: no cover if HAS_UNIX_SOCKETS and self.family == socket.AF_UNIX: self.skipTest("Not applicable to AF_UNIX sockets.") with closewrapper(socket.socket(self.family)) as sock: try: sock.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) except OSError: unittest.skip("SO_REUSEADDR not supported on this platform") else: # if SO_REUSEADDR succeeded for sock we expect asyncore # to do the same s = asyncore.dispatcher(socket.socket(self.family)) self.assertFalse( s.socket.getsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR) ) s.socket.close() s.create_socket(self.family) s.set_reuse_addr() self.assertTrue( s.socket.getsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR) ) @reap_threads def test_quick_connect(self): # pragma: no cover # see: http://bugs.python.org/issue10340 if self.family not in (socket.AF_INET, getattr(socket, "AF_INET6", object())): self.skipTest("test specific to AF_INET and AF_INET6") server = BaseServer(self.family, self.addr) # run the thread 500 ms: the socket should be connected in 200 ms t = threading.Thread(target=lambda: asyncore.loop(timeout=0.1, count=5)) t.start() try: sock = socket.socket(self.family, socket.SOCK_STREAM) with closewrapper(sock) as s: s.settimeout(0.2) s.setsockopt( socket.SOL_SOCKET, socket.SO_LINGER, struct.pack("ii", 1, 0) ) try: s.connect(server.address) except OSError: pass finally: join_thread(t, timeout=TIMEOUT) class TestAPI_UseIPv4Sockets(BaseTestAPI): family = socket.AF_INET addr = (HOST, 0) @unittest.skipUnless(IPV6_ENABLED, "IPv6 support required") class TestAPI_UseIPv6Sockets(BaseTestAPI): family = socket.AF_INET6 addr = (HOSTv6, 0) @unittest.skipUnless(HAS_UNIX_SOCKETS, "Unix sockets required") class TestAPI_UseUnixSockets(BaseTestAPI): if HAS_UNIX_SOCKETS: family = socket.AF_UNIX addr = TESTFN def tearDown(self): unlink(self.addr) BaseTestAPI.tearDown(self) class TestAPI_UseIPv4Select(TestAPI_UseIPv4Sockets, unittest.TestCase): use_poll = False @unittest.skipUnless(hasattr(select, "poll"), "select.poll required") class TestAPI_UseIPv4Poll(TestAPI_UseIPv4Sockets, unittest.TestCase): use_poll = True class TestAPI_UseIPv6Select(TestAPI_UseIPv6Sockets, unittest.TestCase): use_poll = False @unittest.skipUnless(hasattr(select, "poll"), "select.poll required") class TestAPI_UseIPv6Poll(TestAPI_UseIPv6Sockets, unittest.TestCase): use_poll = True class TestAPI_UseUnixSocketsSelect(TestAPI_UseUnixSockets, unittest.TestCase): use_poll = False @unittest.skipUnless(hasattr(select, "poll"), "select.poll required") class TestAPI_UseUnixSocketsPoll(TestAPI_UseUnixSockets, unittest.TestCase): use_poll = True class Test__strerror(unittest.TestCase): def _callFUT(self, err): from waitress.wasyncore import _strerror return _strerror(err) def test_gardenpath(self): self.assertEqual(self._callFUT(1), "Operation not permitted") def test_unknown(self): self.assertEqual(self._callFUT("wut"), "Unknown error wut") class Test_read(unittest.TestCase): def _callFUT(self, dispatcher): from waitress.wasyncore import read return read(dispatcher) def test_gardenpath(self): inst = DummyDispatcher() self._callFUT(inst) self.assertTrue(inst.read_event_handled) self.assertFalse(inst.error_handled) def test_reraised(self): from waitress.wasyncore import ExitNow inst = DummyDispatcher(ExitNow) self.assertRaises(ExitNow, self._callFUT, inst) self.assertTrue(inst.read_event_handled) self.assertFalse(inst.error_handled) def test_non_reraised(self): inst = DummyDispatcher(OSError) self._callFUT(inst) self.assertTrue(inst.read_event_handled) self.assertTrue(inst.error_handled) class Test_write(unittest.TestCase): def _callFUT(self, dispatcher): from waitress.wasyncore import write return write(dispatcher) def test_gardenpath(self): inst = DummyDispatcher() self._callFUT(inst) self.assertTrue(inst.write_event_handled) self.assertFalse(inst.error_handled) def test_reraised(self): from waitress.wasyncore import ExitNow inst = DummyDispatcher(ExitNow) self.assertRaises(ExitNow, self._callFUT, inst) self.assertTrue(inst.write_event_handled) self.assertFalse(inst.error_handled) def test_non_reraised(self): inst = DummyDispatcher(OSError) self._callFUT(inst) self.assertTrue(inst.write_event_handled) self.assertTrue(inst.error_handled) class Test__exception(unittest.TestCase): def _callFUT(self, dispatcher): from waitress.wasyncore import _exception return _exception(dispatcher) def test_gardenpath(self): inst = DummyDispatcher() self._callFUT(inst) self.assertTrue(inst.expt_event_handled) self.assertFalse(inst.error_handled) def test_reraised(self): from waitress.wasyncore import ExitNow inst = DummyDispatcher(ExitNow) self.assertRaises(ExitNow, self._callFUT, inst) self.assertTrue(inst.expt_event_handled) self.assertFalse(inst.error_handled) def test_non_reraised(self): inst = DummyDispatcher(OSError) self._callFUT(inst) self.assertTrue(inst.expt_event_handled) self.assertTrue(inst.error_handled) @unittest.skipUnless(hasattr(select, "poll"), "select.poll required") class Test_readwrite(unittest.TestCase): def _callFUT(self, obj, flags): from waitress.wasyncore import readwrite return readwrite(obj, flags) def test_handle_read_event(self): flags = 0 flags |= select.POLLIN inst = DummyDispatcher() self._callFUT(inst, flags) self.assertTrue(inst.read_event_handled) def test_handle_write_event(self): flags = 0 flags |= select.POLLOUT inst = DummyDispatcher() self._callFUT(inst, flags) self.assertTrue(inst.write_event_handled) def test_handle_expt_event(self): flags = 0 flags |= select.POLLPRI inst = DummyDispatcher() self._callFUT(inst, flags) self.assertTrue(inst.expt_event_handled) def test_handle_close(self): flags = 0 flags |= select.POLLHUP inst = DummyDispatcher() self._callFUT(inst, flags) self.assertTrue(inst.close_handled) def test_socketerror_not_in_disconnected(self): flags = 0 flags |= select.POLLIN inst = DummyDispatcher(socket.error(errno.EALREADY, "EALREADY")) self._callFUT(inst, flags) self.assertTrue(inst.read_event_handled) self.assertTrue(inst.error_handled) def test_socketerror_in_disconnected(self): flags = 0 flags |= select.POLLIN inst = DummyDispatcher(socket.error(errno.ECONNRESET, "ECONNRESET")) self._callFUT(inst, flags) self.assertTrue(inst.read_event_handled) self.assertTrue(inst.close_handled) def test_exception_in_reraised(self): from waitress import wasyncore flags = 0 flags |= select.POLLIN inst = DummyDispatcher(wasyncore.ExitNow) self.assertRaises(wasyncore.ExitNow, self._callFUT, inst, flags) self.assertTrue(inst.read_event_handled) def test_exception_not_in_reraised(self): flags = 0 flags |= select.POLLIN inst = DummyDispatcher(ValueError) self._callFUT(inst, flags) self.assertTrue(inst.error_handled) class Test_poll(unittest.TestCase): def _callFUT(self, timeout=0.0, map=None): from waitress.wasyncore import poll return poll(timeout, map) def test_nothing_writable_nothing_readable_but_map_not_empty(self): # i read the mock.patch docs. nerp. dummy_time = DummyTime() map = {0: DummyDispatcher()} try: from waitress import wasyncore old_time = wasyncore.time wasyncore.time = dummy_time result = self._callFUT(map=map) finally: wasyncore.time = old_time self.assertEqual(result, None) self.assertEqual(dummy_time.sleepvals, [0.0]) def test_select_raises_EINTR(self): # i read the mock.patch docs. nerp. dummy_select = DummySelect(select.error(errno.EINTR)) disp = DummyDispatcher() disp.readable = lambda: True map = {0: disp} try: from waitress import wasyncore old_select = wasyncore.select wasyncore.select = dummy_select result = self._callFUT(map=map) finally: wasyncore.select = old_select self.assertEqual(result, None) self.assertEqual(dummy_select.selected, [([0], [], [0], 0.0)]) def test_select_raises_non_EINTR(self): # i read the mock.patch docs. nerp. dummy_select = DummySelect(select.error(errno.EBADF)) disp = DummyDispatcher() disp.readable = lambda: True map = {0: disp} try: from waitress import wasyncore old_select = wasyncore.select wasyncore.select = dummy_select self.assertRaises(select.error, self._callFUT, map=map) finally: wasyncore.select = old_select self.assertEqual(dummy_select.selected, [([0], [], [0], 0.0)]) class Test_poll2(unittest.TestCase): def _callFUT(self, timeout=0.0, map=None): from waitress.wasyncore import poll2 return poll2(timeout, map) def test_select_raises_EINTR(self): # i read the mock.patch docs. nerp. pollster = DummyPollster(exc=select.error(errno.EINTR)) dummy_select = DummySelect(pollster=pollster) disp = DummyDispatcher() map = {0: disp} try: from waitress import wasyncore old_select = wasyncore.select wasyncore.select = dummy_select self._callFUT(map=map) finally: wasyncore.select = old_select self.assertEqual(pollster.polled, [0.0]) def test_select_raises_non_EINTR(self): # i read the mock.patch docs. nerp. pollster = DummyPollster(exc=select.error(errno.EBADF)) dummy_select = DummySelect(pollster=pollster) disp = DummyDispatcher() map = {0: disp} try: from waitress import wasyncore old_select = wasyncore.select wasyncore.select = dummy_select self.assertRaises(select.error, self._callFUT, map=map) finally: wasyncore.select = old_select self.assertEqual(pollster.polled, [0.0]) class Test_dispatcher(unittest.TestCase): def _makeOne(self, sock=None, map=None): from waitress.wasyncore import dispatcher return dispatcher(sock=sock, map=map) def test_unexpected_getpeername_exc(self): sock = dummysocket() def getpeername(): raise OSError(errno.EBADF) map = {} sock.getpeername = getpeername self.assertRaises(socket.error, self._makeOne, sock=sock, map=map) self.assertEqual(map, {}) def test___repr__accepting(self): sock = dummysocket() map = {} inst = self._makeOne(sock=sock, map=map) inst.accepting = True inst.addr = ("localhost", 8080) result = repr(inst) expected = "