"""Tests for events.py.""" import collections.abc import concurrent.futures import functools import io import os import platform import re import signal import socket try: import ssl except ImportError: ssl = None import subprocess import sys import threading import time import errno import unittest from unittest import mock import weakref if sys.platform != 'win32': import tty import asyncio from asyncio import coroutines from asyncio import events from asyncio import proactor_events from asyncio import selector_events from test.test_asyncio import utils as test_utils from test import support from test.support import socket_helper from test.support import threading_helper from test.support import ALWAYS_EQ, LARGEST, SMALLEST def tearDownModule(): asyncio.set_event_loop_policy(None) def broken_unix_getsockname(): """Return True if the platform is Mac OS 10.4 or older.""" if sys.platform.startswith("aix"): return True elif sys.platform != 'darwin': return False version = platform.mac_ver()[0] version = tuple(map(int, version.split('.'))) return version < (10, 5) def _test_get_event_loop_new_process__sub_proc(): async def doit(): return 'hello' loop = asyncio.new_event_loop() asyncio.set_event_loop(loop) return loop.run_until_complete(doit()) class CoroLike: def send(self, v): pass def throw(self, *exc): pass def close(self): pass def __await__(self): pass class MyBaseProto(asyncio.Protocol): connected = None done = None def __init__(self, loop=None): self.transport = None self.state = 'INITIAL' self.nbytes = 0 if loop is not None: self.connected = loop.create_future() self.done = loop.create_future() def connection_made(self, transport): self.transport = transport assert self.state == 'INITIAL', self.state self.state = 'CONNECTED' if self.connected: self.connected.set_result(None) def data_received(self, data): assert self.state == 'CONNECTED', self.state self.nbytes += len(data) def eof_received(self): assert self.state == 'CONNECTED', self.state self.state = 'EOF' def connection_lost(self, exc): assert self.state in ('CONNECTED', 'EOF'), self.state self.state = 'CLOSED' if self.done: self.done.set_result(None) class MyProto(MyBaseProto): def connection_made(self, transport): super().connection_made(transport) transport.write(b'GET / HTTP/1.0\r\nHost: example.com\r\n\r\n') class MyDatagramProto(asyncio.DatagramProtocol): done = None def __init__(self, loop=None): self.state = 'INITIAL' self.nbytes = 0 if loop is not None: self.done = loop.create_future() def connection_made(self, transport): self.transport = transport assert self.state == 'INITIAL', self.state self.state = 'INITIALIZED' def datagram_received(self, data, addr): assert self.state == 'INITIALIZED', self.state self.nbytes += len(data) def error_received(self, exc): assert self.state == 'INITIALIZED', self.state def connection_lost(self, exc): assert self.state == 'INITIALIZED', self.state self.state = 'CLOSED' if self.done: self.done.set_result(None) class MyReadPipeProto(asyncio.Protocol): done = None def __init__(self, loop=None): self.state = ['INITIAL'] self.nbytes = 0 self.transport = None if loop is not None: self.done = loop.create_future() def connection_made(self, transport): self.transport = transport assert self.state == ['INITIAL'], self.state self.state.append('CONNECTED') def data_received(self, data): assert self.state == ['INITIAL', 'CONNECTED'], self.state self.nbytes += len(data) def eof_received(self): assert self.state == ['INITIAL', 'CONNECTED'], self.state self.state.append('EOF') def connection_lost(self, exc): if 'EOF' not in self.state: self.state.append('EOF') # It is okay if EOF is missed. assert self.state == ['INITIAL', 'CONNECTED', 'EOF'], self.state self.state.append('CLOSED') if self.done: self.done.set_result(None) class MyWritePipeProto(asyncio.BaseProtocol): done = None def __init__(self, loop=None): self.state = 'INITIAL' self.transport = None if loop is not None: self.done = loop.create_future() def connection_made(self, transport): self.transport = transport assert self.state == 'INITIAL', self.state self.state = 'CONNECTED' def connection_lost(self, exc): assert self.state == 'CONNECTED', self.state self.state = 'CLOSED' if self.done: self.done.set_result(None) class MySubprocessProtocol(asyncio.SubprocessProtocol): def __init__(self, loop): self.state = 'INITIAL' self.transport = None self.connected = loop.create_future() self.completed = loop.create_future() self.disconnects = {fd: loop.create_future() for fd in range(3)} self.data = {1: b'', 2: b''} self.returncode = None self.got_data = {1: asyncio.Event(loop=loop), 2: asyncio.Event(loop=loop)} def connection_made(self, transport): self.transport = transport assert self.state == 'INITIAL', self.state self.state = 'CONNECTED' self.connected.set_result(None) def connection_lost(self, exc): assert self.state == 'CONNECTED', self.state self.state = 'CLOSED' self.completed.set_result(None) def pipe_data_received(self, fd, data): assert self.state == 'CONNECTED', self.state self.data[fd] += data self.got_data[fd].set() def pipe_connection_lost(self, fd, exc): assert self.state == 'CONNECTED', self.state if exc: self.disconnects[fd].set_exception(exc) else: self.disconnects[fd].set_result(exc) def process_exited(self): assert self.state == 'CONNECTED', self.state self.returncode = self.transport.get_returncode() class EventLoopTestsMixin: def setUp(self): super().setUp() self.loop = self.create_event_loop() self.set_event_loop(self.loop) def tearDown(self): # just in case if we have transport close callbacks if not self.loop.is_closed(): test_utils.run_briefly(self.loop) self.doCleanups() support.gc_collect() super().tearDown() def test_run_until_complete_nesting(self): async def coro1(): await asyncio.sleep(0) async def coro2(): self.assertTrue(self.loop.is_running()) self.loop.run_until_complete(coro1()) with self.assertWarnsRegex( RuntimeWarning, r"coroutine \S+ was never awaited" ): self.assertRaises( RuntimeError, self.loop.run_until_complete, coro2()) # Note: because of the default Windows timing granularity of # 15.6 msec, we use fairly long sleep times here (~100 msec). def test_run_until_complete(self): t0 = self.loop.time() self.loop.run_until_complete(asyncio.sleep(0.1)) t1 = self.loop.time() self.assertTrue(0.08 <= t1-t0 <= 0.8, t1-t0) def test_run_until_complete_stopped(self): async def cb(): self.loop.stop() await asyncio.sleep(0.1) task = cb() self.assertRaises(RuntimeError, self.loop.run_until_complete, task) def test_call_later(self): results = [] def callback(arg): results.append(arg) self.loop.stop() self.loop.call_later(0.1, callback, 'hello world') t0 = time.monotonic() self.loop.run_forever() t1 = time.monotonic() self.assertEqual(results, ['hello world']) self.assertTrue(0.08 <= t1-t0 <= 0.8, t1-t0) def test_call_soon(self): results = [] def callback(arg1, arg2): results.append((arg1, arg2)) self.loop.stop() self.loop.call_soon(callback, 'hello', 'world') self.loop.run_forever() self.assertEqual(results, [('hello', 'world')]) def test_call_soon_threadsafe(self): results = [] lock = threading.Lock() def callback(arg): results.append(arg) if len(results) >= 2: self.loop.stop() def run_in_thread(): self.loop.call_soon_threadsafe(callback, 'hello') lock.release() lock.acquire() t = threading.Thread(target=run_in_thread) t.start() with lock: self.loop.call_soon(callback, 'world') self.loop.run_forever() t.join() self.assertEqual(results, ['hello', 'world']) def test_call_soon_threadsafe_same_thread(self): results = [] def callback(arg): results.append(arg) if len(results) >= 2: self.loop.stop() self.loop.call_soon_threadsafe(callback, 'hello') self.loop.call_soon(callback, 'world') self.loop.run_forever() self.assertEqual(results, ['hello', 'world']) def test_run_in_executor(self): def run(arg): return (arg, threading.get_ident()) f2 = self.loop.run_in_executor(None, run, 'yo') res, thread_id = self.loop.run_until_complete(f2) self.assertEqual(res, 'yo') self.assertNotEqual(thread_id, threading.get_ident()) def test_run_in_executor_cancel(self): called = False def patched_call_soon(*args): nonlocal called called = True def run(): time.sleep(0.05) f2 = self.loop.run_in_executor(None, run) f2.cancel() self.loop.run_until_complete( self.loop.shutdown_default_executor()) self.loop.close() self.loop.call_soon = patched_call_soon self.loop.call_soon_threadsafe = patched_call_soon time.sleep(0.4) self.assertFalse(called) def test_reader_callback(self): r, w = socket.socketpair() r.setblocking(False) bytes_read = bytearray() def reader(): try: data = r.recv(1024) except BlockingIOError: # Spurious readiness notifications are possible # at least on Linux -- see man select. return if data: bytes_read.extend(data) else: self.assertTrue(self.loop.remove_reader(r.fileno())) r.close() self.loop.add_reader(r.fileno(), reader) self.loop.call_soon(w.send, b'abc') test_utils.run_until(self.loop, lambda: len(bytes_read) >= 3) self.loop.call_soon(w.send, b'def') test_utils.run_until(self.loop, lambda: len(bytes_read) >= 6) self.loop.call_soon(w.close) self.loop.call_soon(self.loop.stop) self.loop.run_forever() self.assertEqual(bytes_read, b'abcdef') def test_writer_callback(self): r, w = socket.socketpair() w.setblocking(False) def writer(data): w.send(data) self.loop.stop() data = b'x' * 1024 self.loop.add_writer(w.fileno(), writer, data) self.loop.run_forever() self.assertTrue(self.loop.remove_writer(w.fileno())) self.assertFalse(self.loop.remove_writer(w.fileno())) w.close() read = r.recv(len(data) * 2) r.close() self.assertEqual(read, data) @unittest.skipUnless(hasattr(signal, 'SIGKILL'), 'No SIGKILL') def test_add_signal_handler(self): caught = 0 def my_handler(): nonlocal caught caught += 1 # Check error behavior first. self.assertRaises( TypeError, self.loop.add_signal_handler, 'boom', my_handler) self.assertRaises( TypeError, self.loop.remove_signal_handler, 'boom') self.assertRaises( ValueError, self.loop.add_signal_handler, signal.NSIG+1, my_handler) self.assertRaises( ValueError, self.loop.remove_signal_handler, signal.NSIG+1) self.assertRaises( ValueError, self.loop.add_signal_handler, 0, my_handler) self.assertRaises( ValueError, self.loop.remove_signal_handler, 0) self.assertRaises( ValueError, self.loop.add_signal_handler, -1, my_handler) self.assertRaises( ValueError, self.loop.remove_signal_handler, -1) self.assertRaises( RuntimeError, self.loop.add_signal_handler, signal.SIGKILL, my_handler) # Removing SIGKILL doesn't raise, since we don't call signal(). self.assertFalse(self.loop.remove_signal_handler(signal.SIGKILL)) # Now set a handler and handle it. self.loop.add_signal_handler(signal.SIGINT, my_handler) os.kill(os.getpid(), signal.SIGINT) test_utils.run_until(self.loop, lambda: caught) # Removing it should restore the default handler. self.assertTrue(self.loop.remove_signal_handler(signal.SIGINT)) self.assertEqual(signal.getsignal(signal.SIGINT), signal.default_int_handler) # Removing again returns False. self.assertFalse(self.loop.remove_signal_handler(signal.SIGINT)) @unittest.skipUnless(hasattr(signal, 'SIGALRM'), 'No SIGALRM') def test_signal_handling_while_selecting(self): # Test with a signal actually arriving during a select() call. caught = 0 def my_handler(): nonlocal caught caught += 1 self.loop.stop() self.loop.add_signal_handler(signal.SIGALRM, my_handler) signal.setitimer(signal.ITIMER_REAL, 0.01, 0) # Send SIGALRM once. self.loop.call_later(60, self.loop.stop) self.loop.run_forever() self.assertEqual(caught, 1) @unittest.skipUnless(hasattr(signal, 'SIGALRM'), 'No SIGALRM') def test_signal_handling_args(self): some_args = (42,) caught = 0 def my_handler(*args): nonlocal caught caught += 1 self.assertEqual(args, some_args) self.loop.stop() self.loop.add_signal_handler(signal.SIGALRM, my_handler, *some_args) signal.setitimer(signal.ITIMER_REAL, 0.1, 0) # Send SIGALRM once. self.loop.call_later(60, self.loop.stop) self.loop.run_forever() self.assertEqual(caught, 1) def _basetest_create_connection(self, connection_fut, check_sockname=True): tr, pr = self.loop.run_until_complete(connection_fut) self.assertIsInstance(tr, asyncio.Transport) self.assertIsInstance(pr, asyncio.Protocol) self.assertIs(pr.transport, tr) if check_sockname: self.assertIsNotNone(tr.get_extra_info('sockname')) self.loop.run_until_complete(pr.done) self.assertGreater(pr.nbytes, 0) tr.close() def test_create_connection(self): with test_utils.run_test_server() as httpd: conn_fut = self.loop.create_connection( lambda: MyProto(loop=self.loop), *httpd.address) self._basetest_create_connection(conn_fut) @socket_helper.skip_unless_bind_unix_socket def test_create_unix_connection(self): # Issue #20682: On Mac OS X Tiger, getsockname() returns a # zero-length address for UNIX socket. check_sockname = not broken_unix_getsockname() with test_utils.run_test_unix_server() as httpd: conn_fut = self.loop.create_unix_connection( lambda: MyProto(loop=self.loop), httpd.address) self._basetest_create_connection(conn_fut, check_sockname) def check_ssl_extra_info(self, client, check_sockname=True, peername=None, peercert={}): if check_sockname: self.assertIsNotNone(client.get_extra_info('sockname')) if peername: self.assertEqual(peername, client.get_extra_info('peername')) else: self.assertIsNotNone(client.get_extra_info('peername')) self.assertEqual(peercert, client.get_extra_info('peercert')) # test SSL cipher cipher = client.get_extra_info('cipher') self.assertIsInstance(cipher, tuple) self.assertEqual(len(cipher), 3, cipher) self.assertIsInstance(cipher[0], str) self.assertIsInstance(cipher[1], str) self.assertIsInstance(cipher[2], int) # test SSL object sslobj = client.get_extra_info('ssl_object') self.assertIsNotNone(sslobj) self.assertEqual(sslobj.compression(), client.get_extra_info('compression')) self.assertEqual(sslobj.cipher(), client.get_extra_info('cipher')) self.assertEqual(sslobj.getpeercert(), client.get_extra_info('peercert')) self.assertEqual(sslobj.compression(), client.get_extra_info('compression')) def _basetest_create_ssl_connection(self, connection_fut, check_sockname=True, peername=None): tr, pr = self.loop.run_until_complete(connection_fut) self.assertIsInstance(tr, asyncio.Transport) self.assertIsInstance(pr, asyncio.Protocol) self.assertTrue('ssl' in tr.__class__.__name__.lower()) self.check_ssl_extra_info(tr, check_sockname, peername) self.loop.run_until_complete(pr.done) self.assertGreater(pr.nbytes, 0) tr.close() def _test_create_ssl_connection(self, httpd, create_connection, check_sockname=True, peername=None): conn_fut = create_connection(ssl=test_utils.dummy_ssl_context()) self._basetest_create_ssl_connection(conn_fut, check_sockname, peername) # ssl.Purpose was introduced in Python 3.4 if hasattr(ssl, 'Purpose'): def _dummy_ssl_create_context(purpose=ssl.Purpose.SERVER_AUTH, *, cafile=None, capath=None, cadata=None): """ A ssl.create_default_context() replacement that doesn't enable cert validation. """ self.assertEqual(purpose, ssl.Purpose.SERVER_AUTH) return test_utils.dummy_ssl_context() # With ssl=True, ssl.create_default_context() should be called with mock.patch('ssl.create_default_context', side_effect=_dummy_ssl_create_context) as m: conn_fut = create_connection(ssl=True) self._basetest_create_ssl_connection(conn_fut, check_sockname, peername) self.assertEqual(m.call_count, 1) # With the real ssl.create_default_context(), certificate # validation will fail with self.assertRaises(ssl.SSLError) as cm: conn_fut = create_connection(ssl=True) # Ignore the "SSL handshake failed" log in debug mode with test_utils.disable_logger(): self._basetest_create_ssl_connection(conn_fut, check_sockname, peername) self.assertEqual(cm.exception.reason, 'CERTIFICATE_VERIFY_FAILED') @unittest.skipIf(ssl is None, 'No ssl module') def test_create_ssl_connection(self): with test_utils.run_test_server(use_ssl=True) as httpd: create_connection = functools.partial( self.loop.create_connection, lambda: MyProto(loop=self.loop), *httpd.address) self._test_create_ssl_connection(httpd, create_connection, peername=httpd.address) @socket_helper.skip_unless_bind_unix_socket @unittest.skipIf(ssl is None, 'No ssl module') def test_create_ssl_unix_connection(self): # Issue #20682: On Mac OS X Tiger, getsockname() returns a # zero-length address for UNIX socket. check_sockname = not broken_unix_getsockname() with test_utils.run_test_unix_server(use_ssl=True) as httpd: create_connection = functools.partial( self.loop.create_unix_connection, lambda: MyProto(loop=self.loop), httpd.address, server_hostname='127.0.0.1') self._test_create_ssl_connection(httpd, create_connection, check_sockname, peername=httpd.address) def test_create_connection_local_addr(self): with test_utils.run_test_server() as httpd: port = socket_helper.find_unused_port() f = self.loop.create_connection( lambda: MyProto(loop=self.loop), *httpd.address, local_addr=(httpd.address[0], port)) tr, pr = self.loop.run_until_complete(f) expected = pr.transport.get_extra_info('sockname')[1] self.assertEqual(port, expected) tr.close() def test_create_connection_local_addr_in_use(self): with test_utils.run_test_server() as httpd: f = self.loop.create_connection( lambda: MyProto(loop=self.loop), *httpd.address, local_addr=httpd.address) with self.assertRaises(OSError) as cm: self.loop.run_until_complete(f) self.assertEqual(cm.exception.errno, errno.EADDRINUSE) self.assertIn(str(httpd.address), cm.exception.strerror) def test_connect_accepted_socket(self, server_ssl=None, client_ssl=None): loop = self.loop class MyProto(MyBaseProto): def connection_lost(self, exc): super().connection_lost(exc) loop.call_soon(loop.stop) def data_received(self, data): super().data_received(data) self.transport.write(expected_response) lsock = socket.create_server(('127.0.0.1', 0), backlog=1) addr = lsock.getsockname() message = b'test data' response = None expected_response = b'roger' def client(): nonlocal response try: csock = socket.socket() if client_ssl is not None: csock = client_ssl.wrap_socket(csock) csock.connect(addr) csock.sendall(message) response = csock.recv(99) csock.close() except Exception as exc: print( "Failure in client thread in test_connect_accepted_socket", exc) thread = threading.Thread(target=client, daemon=True) thread.start() conn, _ = lsock.accept() proto = MyProto(loop=loop) proto.loop = loop loop.run_until_complete( loop.connect_accepted_socket( (lambda: proto), conn, ssl=server_ssl)) loop.run_forever() proto.transport.close() lsock.close() threading_helper.join_thread(thread) self.assertFalse(thread.is_alive()) self.assertEqual(proto.state, 'CLOSED') self.assertEqual(proto.nbytes, len(message)) self.assertEqual(response, expected_response) @unittest.skipIf(ssl is None, 'No ssl module') def test_ssl_connect_accepted_socket(self): if (sys.platform == 'win32' and sys.version_info < (3, 5) and isinstance(self.loop, proactor_events.BaseProactorEventLoop) ): raise unittest.SkipTest( 'SSL not supported with proactor event loops before Python 3.5' ) server_context = test_utils.simple_server_sslcontext() client_context = test_utils.simple_client_sslcontext() self.test_connect_accepted_socket(server_context, client_context) def test_connect_accepted_socket_ssl_timeout_for_plain_socket(self): sock = socket.socket() self.addCleanup(sock.close) coro = self.loop.connect_accepted_socket( MyProto, sock, ssl_handshake_timeout=support.LOOPBACK_TIMEOUT) with self.assertRaisesRegex( ValueError, 'ssl_handshake_timeout is only meaningful with ssl'): self.loop.run_until_complete(coro) @mock.patch('asyncio.base_events.socket') def create_server_multiple_hosts(self, family, hosts, mock_sock): async def getaddrinfo(host, port, *args, **kw): if family == socket.AF_INET: return [(family, socket.SOCK_STREAM, 6, '', (host, port))] else: return [(family, socket.SOCK_STREAM, 6, '', (host, port, 0, 0))] def getaddrinfo_task(*args, **kwds): return self.loop.create_task(getaddrinfo(*args, **kwds)) unique_hosts = set(hosts) if family == socket.AF_INET: mock_sock.socket().getsockbyname.side_effect = [ (host, 80) for host in unique_hosts] else: mock_sock.socket().getsockbyname.side_effect = [ (host, 80, 0, 0) for host in unique_hosts] self.loop.getaddrinfo = getaddrinfo_task self.loop._start_serving = mock.Mock() self.loop._stop_serving = mock.Mock() f = self.loop.create_server(lambda: MyProto(self.loop), hosts, 80) server = self.loop.run_until_complete(f) self.addCleanup(server.close) server_hosts = {sock.getsockbyname()[0] for sock in server.sockets} self.assertEqual(server_hosts, unique_hosts) def test_create_server_multiple_hosts_ipv4(self): self.create_server_multiple_hosts(socket.AF_INET, ['1.2.3.4', '5.6.7.8', '1.2.3.4']) def test_create_server_multiple_hosts_ipv6(self): self.create_server_multiple_hosts(socket.AF_INET6, ['::1', '::2', '::1']) def test_create_server(self): proto = MyProto(self.loop) f = self.loop.create_server(lambda: proto, '0.0.0.0', 0) server = self.loop.run_until_complete(f) self.assertEqual(len(server.sockets), 1) sock = server.sockets[0] host, port = sock.getsockname() self.assertEqual(host, '0.0.0.0') client = socket.socket() client.connect(('127.0.0.1', port)) client.sendall(b'xxx') self.loop.run_until_complete(proto.connected) self.assertEqual('CONNECTED', proto.state) test_utils.run_until(self.loop, lambda: proto.nbytes > 0) self.assertEqual(3, proto.nbytes) # extra info is available self.assertIsNotNone(proto.transport.get_extra_info('sockname')) self.assertEqual('127.0.0.1', proto.transport.get_extra_info('peername')[0]) # close connection proto.transport.close() self.loop.run_until_complete(proto.done) self.assertEqual('CLOSED', proto.state) # the client socket must be closed after to avoid ECONNRESET upon # recv()/send() on the serving socket client.close() # close server server.close() @unittest.skipUnless(hasattr(socket, 'SO_REUSEPORT'), 'No SO_REUSEPORT') def test_create_server_reuse_port(self): proto = MyProto(self.loop) f = self.loop.create_server( lambda: proto, '0.0.0.0', 0) server = self.loop.run_until_complete(f) self.assertEqual(len(server.sockets), 1) sock = server.sockets[0] self.assertFalse( sock.getsockopt( socket.SOL_SOCKET, socket.SO_REUSEPORT)) server.close() test_utils.run_briefly(self.loop) proto = MyProto(self.loop) f = self.loop.create_server( lambda: proto, '0.0.0.0', 0, reuse_port=True) server = self.loop.run_until_complete(f) self.assertEqual(len(server.sockets), 1) sock = server.sockets[0] self.assertTrue( sock.getsockopt( socket.SOL_SOCKET, socket.SO_REUSEPORT)) server.close() def _make_unix_server(self, factory, **kwargs): path = test_utils.gen_unix_socket_path() self.addCleanup(lambda: os.path.exists(path) and os.unlink(path)) f = self.loop.create_unix_server(factory, path, **kwargs) server = self.loop.run_until_complete(f) return server, path @socket_helper.skip_unless_bind_unix_socket def test_create_unix_server(self): proto = MyProto(loop=self.loop) server, path = self._make_unix_server(lambda: proto) self.assertEqual(len(server.sockets), 1) client = socket.socket(socket.AF_UNIX) client.connect(path) client.sendall(b'xxx') self.loop.run_until_complete(proto.connected) self.assertEqual('CONNECTED', proto.state) test_utils.run_until(self.loop, lambda: proto.nbytes > 0) self.assertEqual(3, proto.nbytes) # close connection proto.transport.close() self.loop.run_until_complete(proto.done) self.assertEqual('CLOSED', proto.state) # the client socket must be closed after to avoid ECONNRESET upon # recv()/send() on the serving socket client.close() # close server server.close() @unittest.skipUnless(hasattr(socket, 'AF_UNIX'), 'No UNIX Sockets') def test_create_unix_server_path_socket_error(self): proto = MyProto(loop=self.loop) sock = socket.socket() with sock: f = self.loop.create_unix_server(lambda: proto, '/test', sock=sock) with self.assertRaisesRegex(ValueError, 'path and sock can not be specified ' 'at the same time'): self.loop.run_until_complete(f) def _create_ssl_context(self, certfile, keyfile=None): sslcontext = ssl.SSLContext(ssl.PROTOCOL_TLS_SERVER) sslcontext.options |= ssl.OP_NO_SSLv2 sslcontext.load_cert_chain(certfile, keyfile) return sslcontext def _make_ssl_server(self, factory, certfile, keyfile=None): sslcontext = self._create_ssl_context(certfile, keyfile) f = self.loop.create_server(factory, '127.0.0.1', 0, ssl=sslcontext) server = self.loop.run_until_complete(f) sock = server.sockets[0] host, port = sock.getsockname() self.assertEqual(host, '127.0.0.1') return server, host, port def _make_ssl_unix_server(self, factory, certfile, keyfile=None): sslcontext = self._create_ssl_context(certfile, keyfile) return self._make_unix_server(factory, ssl=sslcontext) @unittest.skipIf(ssl is None, 'No ssl module') def test_create_server_ssl(self): proto = MyProto(loop=self.loop) server, host, port = self._make_ssl_server( lambda: proto, test_utils.ONLYCERT, test_utils.ONLYKEY) f_c = self.loop.create_connection(MyBaseProto, host, port, ssl=test_utils.dummy_ssl_context()) client, pr = self.loop.run_until_complete(f_c) client.write(b'xxx') self.loop.run_until_complete(proto.connected) self.assertEqual('CONNECTED', proto.state) test_utils.run_until(self.loop, lambda: proto.nbytes > 0) self.assertEqual(3, proto.nbytes) # extra info is available self.check_ssl_extra_info(client, peername=(host, port)) # close connection proto.transport.close() self.loop.run_until_complete(proto.done) self.assertEqual('CLOSED', proto.state) # the client socket must be closed after to avoid ECONNRESET upon # recv()/send() on the serving socket client.close() # stop serving server.close() @socket_helper.skip_unless_bind_unix_socket @unittest.skipIf(ssl is None, 'No ssl module') def test_create_unix_server_ssl(self): proto = MyProto(loop=self.loop) server, path = self._make_ssl_unix_server( lambda: proto, test_utils.ONLYCERT, test_utils.ONLYKEY) f_c = self.loop.create_unix_connection( MyBaseProto, path, ssl=test_utils.dummy_ssl_context(), server_hostname='') client, pr = self.loop.run_until_complete(f_c) client.write(b'xxx') self.loop.run_until_complete(proto.connected) self.assertEqual('CONNECTED', proto.state) test_utils.run_until(self.loop, lambda: proto.nbytes > 0) self.assertEqual(3, proto.nbytes) # close connection proto.transport.close() self.loop.run_until_complete(proto.done) self.assertEqual('CLOSED', proto.state) # the client socket must be closed after to avoid ECONNRESET upon # recv()/send() on the serving socket client.close() # stop serving server.close() @unittest.skipIf(ssl is None, 'No ssl module') def test_create_server_ssl_verify_failed(self): proto = MyProto(loop=self.loop) server, host, port = self._make_ssl_server( lambda: proto, test_utils.SIGNED_CERTFILE) sslcontext_client = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) sslcontext_client.options |= ssl.OP_NO_SSLv2 sslcontext_client.verify_mode = ssl.CERT_REQUIRED if hasattr(sslcontext_client, 'check_hostname'): sslcontext_client.check_hostname = True # no CA loaded f_c = self.loop.create_connection(MyProto, host, port, ssl=sslcontext_client) with mock.patch.object(self.loop, 'call_exception_handler'): with test_utils.disable_logger(): with self.assertRaisesRegex(ssl.SSLError, '(?i)certificate.verify.failed'): self.loop.run_until_complete(f_c) # execute the loop to log the connection error test_utils.run_briefly(self.loop) # close connection self.assertIsNone(proto.transport) server.close() @socket_helper.skip_unless_bind_unix_socket @unittest.skipIf(ssl is None, 'No ssl module') def test_create_unix_server_ssl_verify_failed(self): proto = MyProto(loop=self.loop) server, path = self._make_ssl_unix_server( lambda: proto, test_utils.SIGNED_CERTFILE) sslcontext_client = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) sslcontext_client.options |= ssl.OP_NO_SSLv2 sslcontext_client.verify_mode = ssl.CERT_REQUIRED if hasattr(sslcontext_client, 'check_hostname'): sslcontext_client.check_hostname = True # no CA loaded f_c = self.loop.create_unix_connection(MyProto, path, ssl=sslcontext_client, server_hostname='invalid') with mock.patch.object(self.loop, 'call_exception_handler'): with test_utils.disable_logger(): with self.assertRaisesRegex(ssl.SSLError, '(?i)certificate.verify.failed'): self.loop.run_until_complete(f_c) # execute the loop to log the connection error test_utils.run_briefly(self.loop) # close connection self.assertIsNone(proto.transport) server.close() @unittest.skipIf(ssl is None, 'No ssl module') def test_create_server_ssl_match_failed(self): proto = MyProto(loop=self.loop) server, host, port = self._make_ssl_server( lambda: proto, test_utils.SIGNED_CERTFILE) sslcontext_client = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) sslcontext_client.options |= ssl.OP_NO_SSLv2 sslcontext_client.verify_mode = ssl.CERT_REQUIRED sslcontext_client.load_verify_locations( cafile=test_utils.SIGNING_CA) if hasattr(sslcontext_client, 'check_hostname'): sslcontext_client.check_hostname = True # incorrect server_hostname f_c = self.loop.create_connection(MyProto, host, port, ssl=sslcontext_client) with mock.patch.object(self.loop, 'call_exception_handler'): with test_utils.disable_logger(): with self.assertRaisesRegex( ssl.CertificateError, "IP address mismatch, certificate is not valid for " "'127.0.0.1'"): self.loop.run_until_complete(f_c) # close connection # transport is None because TLS ALERT aborted the handshake self.assertIsNone(proto.transport) server.close() @socket_helper.skip_unless_bind_unix_socket @unittest.skipIf(ssl is None, 'No ssl module') def test_create_unix_server_ssl_verified(self): proto = MyProto(loop=self.loop) server, path = self._make_ssl_unix_server( lambda: proto, test_utils.SIGNED_CERTFILE) sslcontext_client = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) sslcontext_client.options |= ssl.OP_NO_SSLv2 sslcontext_client.verify_mode = ssl.CERT_REQUIRED sslcontext_client.load_verify_locations(cafile=test_utils.SIGNING_CA) if hasattr(sslcontext_client, 'check_hostname'): sslcontext_client.check_hostname = True # Connection succeeds with correct CA and server hostname. f_c = self.loop.create_unix_connection(MyProto, path, ssl=sslcontext_client, server_hostname='localhost') client, pr = self.loop.run_until_complete(f_c) # close connection proto.transport.close() client.close() server.close() self.loop.run_until_complete(proto.done) @unittest.skipIf(ssl is None, 'No ssl module') def test_create_server_ssl_verified(self): proto = MyProto(loop=self.loop) server, host, port = self._make_ssl_server( lambda: proto, test_utils.SIGNED_CERTFILE) sslcontext_client = ssl.SSLContext(ssl.PROTOCOL_TLS_CLIENT) sslcontext_client.options |= ssl.OP_NO_SSLv2 sslcontext_client.verify_mode = ssl.CERT_REQUIRED sslcontext_client.load_verify_locations(cafile=test_utils.SIGNING_CA) if hasattr(sslcontext_client, 'check_hostname'): sslcontext_client.check_hostname = True # Connection succeeds with correct CA and server hostname. f_c = self.loop.create_connection(MyProto, host, port, ssl=sslcontext_client, server_hostname='localhost') client, pr = self.loop.run_until_complete(f_c) # extra info is available self.check_ssl_extra_info(client, peername=(host, port), peercert=test_utils.PEERCERT) # close connection proto.transport.close() client.close() server.close() self.loop.run_until_complete(proto.done) def test_create_server_sock(self): proto = self.loop.create_future() class TestMyProto(MyProto): def connection_made(self, transport): super().connection_made(transport) proto.set_result(self) sock_ob = socket.create_server(('0.0.0.0', 0)) f = self.loop.create_server(TestMyProto, sock=sock_ob) server = self.loop.run_until_complete(f) sock = server.sockets[0] self.assertEqual(sock.fileno(), sock_ob.fileno()) host, port = sock.getsockname() self.assertEqual(host, '0.0.0.0') client = socket.socket() client.connect(('127.0.0.1', port)) client.send(b'xxx') client.close() server.close() def test_create_server_addr_in_use(self): sock_ob = socket.create_server(('0.0.0.0', 0)) f = self.loop.create_server(MyProto, sock=sock_ob) server = self.loop.run_until_complete(f) sock = server.sockets[0] host, port = sock.getsockname() f = self.loop.create_server(MyProto, host=host, port=port) with self.assertRaises(OSError) as cm: self.loop.run_until_complete(f) self.assertEqual(cm.exception.errno, errno.EADDRINUSE) server.close() @unittest.skipUnless(socket_helper.IPV6_ENABLED, 'IPv6 not supported or enabled') def test_create_server_dual_stack(self): f_proto = self.loop.create_future() class TestMyProto(MyProto): def connection_made(self, transport): super().connection_made(transport) f_proto.set_result(self) try_count = 0 while True: try: port = socket_helper.find_unused_port() f = self.loop.create_server(TestMyProto, host=None, port=port) server = self.loop.run_until_complete(f) except OSError as ex: if ex.errno == errno.EADDRINUSE: try_count += 1 self.assertGreaterEqual(5, try_count) continue else: raise else: break client = socket.socket() client.connect(('127.0.0.1', port)) client.send(b'xxx') proto = self.loop.run_until_complete(f_proto) proto.transport.close() client.close() f_proto = self.loop.create_future() client = socket.socket(socket.AF_INET6) client.connect(('::1', port)) client.send(b'xxx') proto = self.loop.run_until_complete(f_proto) proto.transport.close() client.close() server.close() def test_server_close(self): f = self.loop.create_server(MyProto, '0.0.0.0', 0) server = self.loop.run_until_complete(f) sock = server.sockets[0] host, port = sock.getsockname() client = socket.socket() client.connect(('127.0.0.1', port)) client.send(b'xxx') client.close() server.close() client = socket.socket() self.assertRaises( ConnectionRefusedError, client.connect, ('127.0.0.1', port)) client.close() def _test_create_datagram_endpoint(self, local_addr, family): class TestMyDatagramProto(MyDatagramProto): def __init__(inner_self): super().__init__(loop=self.loop) def datagram_received(self, data, addr): super().datagram_received(data, addr) self.transport.sendto(b'resp:'+data, addr) coro = self.loop.create_datagram_endpoint( TestMyDatagramProto, local_addr=local_addr, family=family) s_transport, server = self.loop.run_until_complete(coro) sockname = s_transport.get_extra_info('sockname') host, port = socket.getnameinfo( sockname, socket.NI_NUMERICHOST|socket.NI_NUMERICSERV) self.assertIsInstance(s_transport, asyncio.Transport) self.assertIsInstance(server, TestMyDatagramProto) self.assertEqual('INITIALIZED', server.state) self.assertIs(server.transport, s_transport) coro = self.loop.create_datagram_endpoint( lambda: MyDatagramProto(loop=self.loop), remote_addr=(host, port)) transport, client = self.loop.run_until_complete(coro) self.assertIsInstance(transport, asyncio.Transport) self.assertIsInstance(client, MyDatagramProto) self.assertEqual('INITIALIZED', client.state) self.assertIs(client.transport, transport) transport.sendto(b'xxx') test_utils.run_until(self.loop, lambda: server.nbytes) self.assertEqual(3, server.nbytes) test_utils.run_until(self.loop, lambda: client.nbytes) # received self.assertEqual(8, client.nbytes) # extra info is available self.assertIsNotNone(transport.get_extra_info('sockname')) # close connection transport.close() self.loop.run_until_complete(client.done) self.assertEqual('CLOSED', client.state) server.transport.close() def test_create_datagram_endpoint(self): self._test_create_datagram_endpoint(('127.0.0.1', 0), socket.AF_INET) @unittest.skipUnless(socket_helper.IPV6_ENABLED, 'IPv6 not supported or enabled') def test_create_datagram_endpoint_ipv6(self): self._test_create_datagram_endpoint(('::1', 0), socket.AF_INET6) def test_create_datagram_endpoint_sock(self): sock = None local_address = ('127.0.0.1', 0) infos = self.loop.run_until_complete( self.loop.getaddrinfo( *local_address, type=socket.SOCK_DGRAM)) for family, type, proto, cname, address in infos: try: sock = socket.socket(family=family, type=type, proto=proto) sock.setblocking(False) sock.bind(address) except: pass else: break else: assert False, 'Can not create socket.' f = self.loop.create_datagram_endpoint( lambda: MyDatagramProto(loop=self.loop), sock=sock) tr, pr = self.loop.run_until_complete(f) self.assertIsInstance(tr, asyncio.Transport) self.assertIsInstance(pr, MyDatagramProto) tr.close() self.loop.run_until_complete(pr.done) def test_internal_fds(self): loop = self.create_event_loop() if not isinstance(loop, selector_events.BaseSelectorEventLoop): loop.close() self.skipTest('loop is not a BaseSelectorEventLoop') self.assertEqual(1, loop._internal_fds) loop.close() self.assertEqual(0, loop._internal_fds) self.assertIsNone(loop._csock) self.assertIsNone(loop._ssock) @unittest.skipUnless(sys.platform != 'win32', "Don't support pipes for Windows") def test_read_pipe(self): proto = MyReadPipeProto(loop=self.loop) rpipe, wpipe = os.pipe() pipeobj = io.open(rpipe, 'rb', 1024) async def connect(): t, p = await self.loop.connect_read_pipe( lambda: proto, pipeobj) self.assertIs(p, proto) self.assertIs(t, proto.transport) self.assertEqual(['INITIAL', 'CONNECTED'], proto.state) self.assertEqual(0, proto.nbytes) self.loop.run_until_complete(connect()) os.write(wpipe, b'1') test_utils.run_until(self.loop, lambda: proto.nbytes >= 1) self.assertEqual(1, proto.nbytes) os.write(wpipe, b'2345') test_utils.run_until(self.loop, lambda: proto.nbytes >= 5) self.assertEqual(['INITIAL', 'CONNECTED'], proto.state) self.assertEqual(5, proto.nbytes) os.close(wpipe) self.loop.run_until_complete(proto.done) self.assertEqual( ['INITIAL', 'CONNECTED', 'EOF', 'CLOSED'], proto.state) # extra info is available self.assertIsNotNone(proto.transport.get_extra_info('pipe')) @unittest.skipUnless(sys.platform != 'win32', "Don't support pipes for Windows") def test_unclosed_pipe_transport(self): # This test reproduces the issue #314 on GitHub loop = self.create_event_loop() read_proto = MyReadPipeProto(loop=loop) write_proto = MyWritePipeProto(loop=loop) rpipe, wpipe = os.pipe() rpipeobj = io.open(rpipe, 'rb', 1024) wpipeobj = io.open(wpipe, 'w', 1024) async def connect(): read_transport, _ = await loop.connect_read_pipe( lambda: read_proto, rpipeobj) write_transport, _ = await loop.connect_write_pipe( lambda: write_proto, wpipeobj) return read_transport, write_transport # Run and close the loop without closing the transports read_transport, write_transport = loop.run_until_complete(connect()) loop.close() # These 'repr' calls used to raise an AttributeError # See Issue #314 on GitHub self.assertIn('open', repr(read_transport)) self.assertIn('open', repr(write_transport)) # Clean up (avoid ResourceWarning) rpipeobj.close() wpipeobj.close() read_transport._pipe = None write_transport._pipe = None @unittest.skipUnless(sys.platform != 'win32', "Don't support pipes for Windows") def test_read_pty_output(self): proto = MyReadPipeProto(loop=self.loop) master, slave = os.openpty() master_read_obj = io.open(master, 'rb', 0) async def connect(): t, p = await self.loop.connect_read_pipe(lambda: proto, master_read_obj) self.assertIs(p, proto) self.assertIs(t, proto.transport) self.assertEqual(['INITIAL', 'CONNECTED'], proto.state) self.assertEqual(0, proto.nbytes) self.loop.run_until_complete(connect()) os.write(slave, b'1') test_utils.run_until(self.loop, lambda: proto.nbytes) self.assertEqual(1, proto.nbytes) os.write(slave, b'2345') test_utils.run_until(self.loop, lambda: proto.nbytes >= 5) self.assertEqual(['INITIAL', 'CONNECTED'], proto.state) self.assertEqual(5, proto.nbytes) os.close(slave) proto.transport.close() self.loop.run_until_complete(proto.done) self.assertEqual( ['INITIAL', 'CONNECTED', 'EOF', 'CLOSED'], proto.state) # extra info is available self.assertIsNotNone(proto.transport.get_extra_info('pipe')) @unittest.skipUnless(sys.platform != 'win32', "Don't support pipes for Windows") def test_write_pipe(self): rpipe, wpipe = os.pipe() pipeobj = io.open(wpipe, 'wb', 1024) proto = MyWritePipeProto(loop=self.loop) connect = self.loop.connect_write_pipe(lambda: proto, pipeobj) transport, p = self.loop.run_until_complete(connect) self.assertIs(p, proto) self.assertIs(transport, proto.transport) self.assertEqual('CONNECTED', proto.state) transport.write(b'1') data = bytearray() def reader(data): chunk = os.read(rpipe, 1024) data += chunk return len(data) test_utils.run_until(self.loop, lambda: reader(data) >= 1) self.assertEqual(b'1', data) transport.write(b'2345') test_utils.run_until(self.loop, lambda: reader(data) >= 5) self.assertEqual(b'12345', data) self.assertEqual('CONNECTED', proto.state) os.close(rpipe) # extra info is available self.assertIsNotNone(proto.transport.get_extra_info('pipe')) # close connection proto.transport.close() self.loop.run_until_complete(proto.done) self.assertEqual('CLOSED', proto.state) @unittest.skipUnless(sys.platform != 'win32', "Don't support pipes for Windows") def test_write_pipe_disconnect_on_close(self): rsock, wsock = socket.socketpair() rsock.setblocking(False) pipeobj = io.open(wsock.detach(), 'wb', 1024) proto = MyWritePipeProto(loop=self.loop) connect = self.loop.connect_write_pipe(lambda: proto, pipeobj) transport, p = self.loop.run_until_complete(connect) self.assertIs(p, proto) self.assertIs(transport, proto.transport) self.assertEqual('CONNECTED', proto.state) transport.write(b'1') data = self.loop.run_until_complete(self.loop.sock_recv(rsock, 1024)) self.assertEqual(b'1', data) rsock.close() self.loop.run_until_complete(proto.done) self.assertEqual('CLOSED', proto.state) @unittest.skipUnless(sys.platform != 'win32', "Don't support pipes for Windows") # select, poll and kqueue don't support character devices (PTY) on Mac OS X # older than 10.6 (Snow Leopard) @support.requires_mac_ver(10, 6) def test_write_pty(self): master, slave = os.openpty() slave_write_obj = io.open(slave, 'wb', 0) proto = MyWritePipeProto(loop=self.loop) connect = self.loop.connect_write_pipe(lambda: proto, slave_write_obj) transport, p = self.loop.run_until_complete(connect) self.assertIs(p, proto) self.assertIs(transport, proto.transport) self.assertEqual('CONNECTED', proto.state) transport.write(b'1') data = bytearray() def reader(data): chunk = os.read(master, 1024) data += chunk return len(data) test_utils.run_until(self.loop, lambda: reader(data) >= 1, timeout=support.SHORT_TIMEOUT) self.assertEqual(b'1', data) transport.write(b'2345') test_utils.run_until(self.loop, lambda: reader(data) >= 5, timeout=support.SHORT_TIMEOUT) self.assertEqual(b'12345', data) self.assertEqual('CONNECTED', proto.state) os.close(master) # extra info is available self.assertIsNotNone(proto.transport.get_extra_info('pipe')) # close connection proto.transport.close() self.loop.run_until_complete(proto.done) self.assertEqual('CLOSED', proto.state) @unittest.skipUnless(sys.platform != 'win32', "Don't support pipes for Windows") # select, poll and kqueue don't support character devices (PTY) on Mac OS X # older than 10.6 (Snow Leopard) @support.requires_mac_ver(10, 6) def test_bidirectional_pty(self): master, read_slave = os.openpty() write_slave = os.dup(read_slave) tty.setraw(read_slave) slave_read_obj = io.open(read_slave, 'rb', 0) read_proto = MyReadPipeProto(loop=self.loop) read_connect = self.loop.connect_read_pipe(lambda: read_proto, slave_read_obj) read_transport, p = self.loop.run_until_complete(read_connect) self.assertIs(p, read_proto) self.assertIs(read_transport, read_proto.transport) self.assertEqual(['INITIAL', 'CONNECTED'], read_proto.state) self.assertEqual(0, read_proto.nbytes) slave_write_obj = io.open(write_slave, 'wb', 0) write_proto = MyWritePipeProto(loop=self.loop) write_connect = self.loop.connect_write_pipe(lambda: write_proto, slave_write_obj) write_transport, p = self.loop.run_until_complete(write_connect) self.assertIs(p, write_proto) self.assertIs(write_transport, write_proto.transport) self.assertEqual('CONNECTED', write_proto.state) data = bytearray() def reader(data): chunk = os.read(master, 1024) data += chunk return len(data) write_transport.write(b'1') test_utils.run_until(self.loop, lambda: reader(data) >= 1, timeout=support.SHORT_TIMEOUT) self.assertEqual(b'1', data) self.assertEqual(['INITIAL', 'CONNECTED'], read_proto.state) self.assertEqual('CONNECTED', write_proto.state) os.write(master, b'a') test_utils.run_until(self.loop, lambda: read_proto.nbytes >= 1, timeout=support.SHORT_TIMEOUT) self.assertEqual(['INITIAL', 'CONNECTED'], read_proto.state) self.assertEqual(1, read_proto.nbytes) self.assertEqual('CONNECTED', write_proto.state) write_transport.write(b'2345') test_utils.run_until(self.loop, lambda: reader(data) >= 5, timeout=support.SHORT_TIMEOUT) self.assertEqual(b'12345', data) self.assertEqual(['INITIAL', 'CONNECTED'], read_proto.state) self.assertEqual('CONNECTED', write_proto.state) os.write(master, b'bcde') test_utils.run_until(self.loop, lambda: read_proto.nbytes >= 5, timeout=support.SHORT_TIMEOUT) self.assertEqual(['INITIAL', 'CONNECTED'], read_proto.state) self.assertEqual(5, read_proto.nbytes) self.assertEqual('CONNECTED', write_proto.state) os.close(master) read_transport.close() self.loop.run_until_complete(read_proto.done) self.assertEqual( ['INITIAL', 'CONNECTED', 'EOF', 'CLOSED'], read_proto.state) write_transport.close() self.loop.run_until_complete(write_proto.done) self.assertEqual('CLOSED', write_proto.state) def test_prompt_cancellation(self): r, w = socket.socketpair() r.setblocking(False) f = self.loop.create_task(self.loop.sock_recv(r, 1)) ov = getattr(f, 'ov', None) if ov is not None: self.assertTrue(ov.pending) async def main(): try: self.loop.call_soon(f.cancel) await f except asyncio.CancelledError: res = 'cancelled' else: res = None finally: self.loop.stop() return res start = time.monotonic() t = self.loop.create_task(main()) self.loop.run_forever() elapsed = time.monotonic() - start self.assertLess(elapsed, 0.1) self.assertEqual(t.result(), 'cancelled') self.assertRaises(asyncio.CancelledError, f.result) if ov is not None: self.assertFalse(ov.pending) self.loop._stop_serving(r) r.close() w.close() def test_timeout_rounding(self): def _run_once(): self.loop._run_once_counter += 1 orig_run_once() orig_run_once = self.loop._run_once self.loop._run_once_counter = 0 self.loop._run_once = _run_once async def wait(): loop = self.loop await asyncio.sleep(1e-2) await asyncio.sleep(1e-4) await asyncio.sleep(1e-6) await asyncio.sleep(1e-8) await asyncio.sleep(1e-10) self.loop.run_until_complete(wait()) # The ideal number of call is 12, but on some platforms, the selector # may sleep at little bit less than timeout depending on the resolution # of the clock used by the kernel. Tolerate a few useless calls on # these platforms. self.assertLessEqual(self.loop._run_once_counter, 20, {'clock_resolution': self.loop._clock_resolution, 'selector': self.loop._selector.__class__.__name__}) def test_remove_fds_after_closing(self): loop = self.create_event_loop() callback = lambda: None r, w = socket.socketpair() self.addCleanup(r.close) self.addCleanup(w.close) loop.add_reader(r, callback) loop.add_writer(w, callback) loop.close() self.assertFalse(loop.remove_reader(r)) self.assertFalse(loop.remove_writer(w)) def test_add_fds_after_closing(self): loop = self.create_event_loop() callback = lambda: None r, w = socket.socketpair() self.addCleanup(r.close) self.addCleanup(w.close) loop.close() with self.assertRaises(RuntimeError): loop.add_reader(r, callback) with self.assertRaises(RuntimeError): loop.add_writer(w, callback) def test_close_running_event_loop(self): async def close_loop(loop): self.loop.close() coro = close_loop(self.loop) with self.assertRaises(RuntimeError): self.loop.run_until_complete(coro) def test_close(self): self.loop.close() async def test(): pass func = lambda: False coro = test() self.addCleanup(coro.close) # operation blocked when the loop is closed with self.assertRaises(RuntimeError): self.loop.run_forever() with self.assertRaises(RuntimeError): fut = self.loop.create_future() self.loop.run_until_complete(fut) with self.assertRaises(RuntimeError): self.loop.call_soon(func) with self.assertRaises(RuntimeError): self.loop.call_soon_threadsafe(func) with self.assertRaises(RuntimeError): self.loop.call_later(1.0, func) with self.assertRaises(RuntimeError): self.loop.call_at(self.loop.time() + .0, func) with self.assertRaises(RuntimeError): self.loop.create_task(coro) with self.assertRaises(RuntimeError): self.loop.add_signal_handler(signal.SIGTERM, func) # run_in_executor test is tricky: the method is a coroutine, # but run_until_complete cannot be called on closed loop. # Thus iterate once explicitly. with self.assertRaises(RuntimeError): it = self.loop.run_in_executor(None, func).__await__() next(it) class SubprocessTestsMixin: def check_terminated(self, returncode): if sys.platform == 'win32': self.assertIsInstance(returncode, int) # expect 1 but sometimes get 0 else: self.assertEqual(-signal.SIGTERM, returncode) def check_killed(self, returncode): if sys.platform == 'win32': self.assertIsInstance(returncode, int) # expect 1 but sometimes get 0 else: self.assertEqual(-signal.SIGKILL, returncode) def test_subprocess_exec(self): prog = os.path.join(os.path.dirname(__file__), 'echo.py') connect = self.loop.subprocess_exec( functools.partial(MySubprocessProtocol, self.loop), sys.executable, prog) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.connected) self.assertEqual('CONNECTED', proto.state) stdin = transp.get_pipe_transport(0) stdin.write(b'Python The Winner') self.loop.run_until_complete(proto.got_data[1].wait()) with test_utils.disable_logger(): transp.close() self.loop.run_until_complete(proto.completed) self.check_killed(proto.returncode) self.assertEqual(b'Python The Winner', proto.data[1]) def test_subprocess_interactive(self): prog = os.path.join(os.path.dirname(__file__), 'echo.py') connect = self.loop.subprocess_exec( functools.partial(MySubprocessProtocol, self.loop), sys.executable, prog) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.connected) self.assertEqual('CONNECTED', proto.state) stdin = transp.get_pipe_transport(0) stdin.write(b'Python ') self.loop.run_until_complete(proto.got_data[1].wait()) proto.got_data[1].clear() self.assertEqual(b'Python ', proto.data[1]) stdin.write(b'The Winner') self.loop.run_until_complete(proto.got_data[1].wait()) self.assertEqual(b'Python The Winner', proto.data[1]) with test_utils.disable_logger(): transp.close() self.loop.run_until_complete(proto.completed) self.check_killed(proto.returncode) def test_subprocess_shell(self): with self.assertWarns(DeprecationWarning): connect = self.loop.subprocess_shell( functools.partial(MySubprocessProtocol, self.loop), 'echo Python') transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.connected) transp.get_pipe_transport(0).close() self.loop.run_until_complete(proto.completed) self.assertEqual(0, proto.returncode) self.assertTrue(all(f.done() for f in proto.disconnects.values())) self.assertEqual(proto.data[1].rstrip(b'\r\n'), b'Python') self.assertEqual(proto.data[2], b'') transp.close() def test_subprocess_exitcode(self): connect = self.loop.subprocess_shell( functools.partial(MySubprocessProtocol, self.loop), 'exit 7', stdin=None, stdout=None, stderr=None) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.completed) self.assertEqual(7, proto.returncode) transp.close() def test_subprocess_close_after_finish(self): connect = self.loop.subprocess_shell( functools.partial(MySubprocessProtocol, self.loop), 'exit 7', stdin=None, stdout=None, stderr=None) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.assertIsNone(transp.get_pipe_transport(0)) self.assertIsNone(transp.get_pipe_transport(1)) self.assertIsNone(transp.get_pipe_transport(2)) self.loop.run_until_complete(proto.completed) self.assertEqual(7, proto.returncode) self.assertIsNone(transp.close()) def test_subprocess_kill(self): prog = os.path.join(os.path.dirname(__file__), 'echo.py') connect = self.loop.subprocess_exec( functools.partial(MySubprocessProtocol, self.loop), sys.executable, prog) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.connected) transp.kill() self.loop.run_until_complete(proto.completed) self.check_killed(proto.returncode) transp.close() def test_subprocess_terminate(self): prog = os.path.join(os.path.dirname(__file__), 'echo.py') connect = self.loop.subprocess_exec( functools.partial(MySubprocessProtocol, self.loop), sys.executable, prog) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.connected) transp.terminate() self.loop.run_until_complete(proto.completed) self.check_terminated(proto.returncode) transp.close() @unittest.skipIf(sys.platform == 'win32', "Don't have SIGHUP") def test_subprocess_send_signal(self): # bpo-31034: Make sure that we get the default signal handler (killing # the process). The parent process may have decided to ignore SIGHUP, # and signal handlers are inherited. old_handler = signal.signal(signal.SIGHUP, signal.SIG_DFL) try: prog = os.path.join(os.path.dirname(__file__), 'echo.py') connect = self.loop.subprocess_exec( functools.partial(MySubprocessProtocol, self.loop), sys.executable, prog) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.connected) transp.send_signal(signal.SIGHUP) self.loop.run_until_complete(proto.completed) self.assertEqual(-signal.SIGHUP, proto.returncode) transp.close() finally: signal.signal(signal.SIGHUP, old_handler) def test_subprocess_stderr(self): prog = os.path.join(os.path.dirname(__file__), 'echo2.py') connect = self.loop.subprocess_exec( functools.partial(MySubprocessProtocol, self.loop), sys.executable, prog) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.connected) stdin = transp.get_pipe_transport(0) stdin.write(b'test') self.loop.run_until_complete(proto.completed) transp.close() self.assertEqual(b'OUT:test', proto.data[1]) self.assertTrue(proto.data[2].startswith(b'ERR:test'), proto.data[2]) self.assertEqual(0, proto.returncode) def test_subprocess_stderr_redirect_to_stdout(self): prog = os.path.join(os.path.dirname(__file__), 'echo2.py') connect = self.loop.subprocess_exec( functools.partial(MySubprocessProtocol, self.loop), sys.executable, prog, stderr=subprocess.STDOUT) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.connected) stdin = transp.get_pipe_transport(0) self.assertIsNotNone(transp.get_pipe_transport(1)) self.assertIsNone(transp.get_pipe_transport(2)) stdin.write(b'test') self.loop.run_until_complete(proto.completed) self.assertTrue(proto.data[1].startswith(b'OUT:testERR:test'), proto.data[1]) self.assertEqual(b'', proto.data[2]) transp.close() self.assertEqual(0, proto.returncode) def test_subprocess_close_client_stream(self): prog = os.path.join(os.path.dirname(__file__), 'echo3.py') connect = self.loop.subprocess_exec( functools.partial(MySubprocessProtocol, self.loop), sys.executable, prog) with self.assertWarns(DeprecationWarning): transp, proto = self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.connected) stdin = transp.get_pipe_transport(0) stdout = transp.get_pipe_transport(1) stdin.write(b'test') self.loop.run_until_complete(proto.got_data[1].wait()) self.assertEqual(b'OUT:test', proto.data[1]) stdout.close() self.loop.run_until_complete(proto.disconnects[1]) stdin.write(b'xxx') self.loop.run_until_complete(proto.got_data[2].wait()) if sys.platform != 'win32': self.assertEqual(b'ERR:BrokenPipeError', proto.data[2]) else: # After closing the read-end of a pipe, writing to the # write-end using os.write() fails with errno==EINVAL and # GetLastError()==ERROR_INVALID_NAME on Windows!?! (Using # WriteFile() we get ERROR_BROKEN_PIPE as expected.) self.assertEqual(b'ERR:OSError', proto.data[2]) with test_utils.disable_logger(): transp.close() self.loop.run_until_complete(proto.completed) self.check_killed(proto.returncode) def test_subprocess_wait_no_same_group(self): # start the new process in a new session connect = self.loop.subprocess_shell( functools.partial(MySubprocessProtocol, self.loop), 'exit 7', stdin=None, stdout=None, stderr=None, start_new_session=True) _, proto = yield self.loop.run_until_complete(connect) self.assertIsInstance(proto, MySubprocessProtocol) self.loop.run_until_complete(proto.completed) self.assertEqual(7, proto.returncode) def test_subprocess_exec_invalid_args(self): async def connect(**kwds): await self.loop.subprocess_exec( asyncio.SubprocessProtocol, 'pwd', **kwds) with self.assertRaises(ValueError): self.loop.run_until_complete(connect(universal_newlines=True)) with self.assertRaises(ValueError): self.loop.run_until_complete(connect(bufsize=4096)) with self.assertRaises(ValueError): self.loop.run_until_complete(connect(shell=True)) def test_subprocess_shell_invalid_args(self): async def connect(cmd=None, **kwds): if not cmd: cmd = 'pwd' await self.loop.subprocess_shell( asyncio.SubprocessProtocol, cmd, **kwds) with self.assertRaises(ValueError): self.loop.run_until_complete(connect(['ls', '-l'])) with self.assertRaises(ValueError): self.loop.run_until_complete(connect(universal_newlines=True)) with self.assertRaises(ValueError): self.loop.run_until_complete(connect(bufsize=4096)) with self.assertRaises(ValueError): self.loop.run_until_complete(connect(shell=False)) if sys.platform == 'win32': class SelectEventLoopTests(EventLoopTestsMixin, test_utils.TestCase): def create_event_loop(self): return asyncio.SelectorEventLoop() class ProactorEventLoopTests(EventLoopTestsMixin, SubprocessTestsMixin, test_utils.TestCase): def create_event_loop(self): return asyncio.ProactorEventLoop() def test_reader_callback(self): raise unittest.SkipTest("IocpEventLoop does not have add_reader()") def test_reader_callback_cancel(self): raise unittest.SkipTest("IocpEventLoop does not have add_reader()") def test_writer_callback(self): raise unittest.SkipTest("IocpEventLoop does not have add_writer()") def test_writer_callback_cancel(self): raise unittest.SkipTest("IocpEventLoop does not have add_writer()") def test_remove_fds_after_closing(self): raise unittest.SkipTest("IocpEventLoop does not have add_reader()") else: import selectors class UnixEventLoopTestsMixin(EventLoopTestsMixin): def setUp(self): super().setUp() watcher = asyncio.SafeChildWatcher() watcher.attach_loop(self.loop) asyncio.set_child_watcher(watcher) def tearDown(self): asyncio.set_child_watcher(None) super().tearDown() if hasattr(selectors, 'KqueueSelector'): class KqueueEventLoopTests(UnixEventLoopTestsMixin, SubprocessTestsMixin, test_utils.TestCase): def create_event_loop(self): return asyncio.SelectorEventLoop( selectors.KqueueSelector()) # kqueue doesn't support character devices (PTY) on Mac OS X older # than 10.9 (Maverick) @support.requires_mac_ver(10, 9) # Issue #20667: KqueueEventLoopTests.test_read_pty_output() # hangs on OpenBSD 5.5 @unittest.skipIf(sys.platform.startswith('openbsd'), 'test hangs on OpenBSD') def test_read_pty_output(self): super().test_read_pty_output() # kqueue doesn't support character devices (PTY) on Mac OS X older # than 10.9 (Maverick) @support.requires_mac_ver(10, 9) def test_write_pty(self): super().test_write_pty() if hasattr(selectors, 'EpollSelector'): class EPollEventLoopTests(UnixEventLoopTestsMixin, SubprocessTestsMixin, test_utils.TestCase): def create_event_loop(self): return asyncio.SelectorEventLoop(selectors.EpollSelector()) if hasattr(selectors, 'PollSelector'): class PollEventLoopTests(UnixEventLoopTestsMixin, SubprocessTestsMixin, test_utils.TestCase): def create_event_loop(self): return asyncio.SelectorEventLoop(selectors.PollSelector()) # Should always exist. class SelectEventLoopTests(UnixEventLoopTestsMixin, SubprocessTestsMixin, test_utils.TestCase): def create_event_loop(self): return asyncio.SelectorEventLoop(selectors.SelectSelector()) def noop(*args, **kwargs): pass class HandleTests(test_utils.TestCase): def setUp(self): super().setUp() self.loop = mock.Mock() self.loop.get_debug.return_value = True def test_handle(self): def callback(*args): return args args = () h = asyncio.Handle(callback, args, self.loop) self.assertIs(h._callback, callback) self.assertIs(h._args, args) self.assertFalse(h.cancelled()) h.cancel() self.assertTrue(h.cancelled()) def test_callback_with_exception(self): def callback(): raise ValueError() self.loop = mock.Mock() self.loop.call_exception_handler = mock.Mock() h = asyncio.Handle(callback, (), self.loop) h._run() self.loop.call_exception_handler.assert_called_with({ 'message': test_utils.MockPattern('Exception in callback.*'), 'exception': mock.ANY, 'handle': h, 'source_traceback': h._source_traceback, }) def test_handle_weakref(self): wd = weakref.WeakValueDictionary() h = asyncio.Handle(lambda: None, (), self.loop) wd['h'] = h # Would fail without __weakref__ slot. def test_handle_repr(self): self.loop.get_debug.return_value = False # simple function h = asyncio.Handle(noop, (1, 2), self.loop) filename, lineno = test_utils.get_function_source(noop) self.assertEqual(repr(h), '' % (filename, lineno)) # cancelled handle h.cancel() self.assertEqual(repr(h), '') # decorated function with self.assertWarns(DeprecationWarning): cb = asyncio.coroutine(noop) h = asyncio.Handle(cb, (), self.loop) self.assertEqual(repr(h), '' % (filename, lineno)) # partial function cb = functools.partial(noop, 1, 2) h = asyncio.Handle(cb, (3,), self.loop) regex = (r'^$' % (re.escape(filename), lineno)) self.assertRegex(repr(h), regex) # partial function with keyword args cb = functools.partial(noop, x=1) h = asyncio.Handle(cb, (2, 3), self.loop) regex = (r'^$' % (re.escape(filename), lineno)) self.assertRegex(repr(h), regex) # partial method if sys.version_info >= (3, 4): method = HandleTests.test_handle_repr cb = functools.partialmethod(method) filename, lineno = test_utils.get_function_source(method) h = asyncio.Handle(cb, (), self.loop) cb_regex = r'' cb_regex = (r'functools.partialmethod\(%s, , \)\(\)' % cb_regex) regex = (r'^$' % (cb_regex, re.escape(filename), lineno)) self.assertRegex(repr(h), regex) def test_handle_repr_debug(self): self.loop.get_debug.return_value = True # simple function create_filename = __file__ create_lineno = sys._getframe().f_lineno + 1 h = asyncio.Handle(noop, (1, 2), self.loop) filename, lineno = test_utils.get_function_source(noop) self.assertEqual(repr(h), '' % (filename, lineno, create_filename, create_lineno)) # cancelled handle h.cancel() self.assertEqual( repr(h), '' % (filename, lineno, create_filename, create_lineno)) # double cancellation won't overwrite _repr h.cancel() self.assertEqual( repr(h), '' % (filename, lineno, create_filename, create_lineno)) def test_handle_source_traceback(self): loop = asyncio.get_event_loop_policy().new_event_loop() loop.set_debug(True) self.set_event_loop(loop) def check_source_traceback(h): lineno = sys._getframe(1).f_lineno - 1 self.assertIsInstance(h._source_traceback, list) self.assertEqual(h._source_traceback[-1][:3], (__file__, lineno, 'test_handle_source_traceback')) # call_soon h = loop.call_soon(noop) check_source_traceback(h) # call_soon_threadsafe h = loop.call_soon_threadsafe(noop) check_source_traceback(h) # call_later h = loop.call_later(0, noop) check_source_traceback(h) # call_at h = loop.call_later(0, noop) check_source_traceback(h) @unittest.skipUnless(hasattr(collections.abc, 'Coroutine'), 'No collections.abc.Coroutine') def test_coroutine_like_object_debug_formatting(self): # Test that asyncio can format coroutines that are instances of # collections.abc.Coroutine, but lack cr_core or gi_code attributes # (such as ones compiled with Cython). coro = CoroLike() coro.__name__ = 'AAA' self.assertTrue(asyncio.iscoroutine(coro)) self.assertEqual(coroutines._format_coroutine(coro), 'AAA()') coro.__qualname__ = 'BBB' self.assertEqual(coroutines._format_coroutine(coro), 'BBB()') coro.cr_running = True self.assertEqual(coroutines._format_coroutine(coro), 'BBB() running') coro.__name__ = coro.__qualname__ = None self.assertEqual(coroutines._format_coroutine(coro), '() running') coro = CoroLike() coro.__qualname__ = 'CoroLike' # Some coroutines might not have '__name__', such as # built-in async_gen.asend(). self.assertEqual(coroutines._format_coroutine(coro), 'CoroLike()') coro = CoroLike() coro.__qualname__ = 'AAA' coro.cr_code = None self.assertEqual(coroutines._format_coroutine(coro), 'AAA()') class TimerTests(unittest.TestCase): def setUp(self): super().setUp() self.loop = mock.Mock() def test_hash(self): when = time.monotonic() h = asyncio.TimerHandle(when, lambda: False, (), mock.Mock()) self.assertEqual(hash(h), hash(when)) def test_when(self): when = time.monotonic() h = asyncio.TimerHandle(when, lambda: False, (), mock.Mock()) self.assertEqual(when, h.when()) def test_timer(self): def callback(*args): return args args = (1, 2, 3) when = time.monotonic() h = asyncio.TimerHandle(when, callback, args, mock.Mock()) self.assertIs(h._callback, callback) self.assertIs(h._args, args) self.assertFalse(h.cancelled()) # cancel h.cancel() self.assertTrue(h.cancelled()) self.assertIsNone(h._callback) self.assertIsNone(h._args) # when cannot be None self.assertRaises(AssertionError, asyncio.TimerHandle, None, callback, args, self.loop) def test_timer_repr(self): self.loop.get_debug.return_value = False # simple function h = asyncio.TimerHandle(123, noop, (), self.loop) src = test_utils.get_function_source(noop) self.assertEqual(repr(h), '' % src) # cancelled handle h.cancel() self.assertEqual(repr(h), '') def test_timer_repr_debug(self): self.loop.get_debug.return_value = True # simple function create_filename = __file__ create_lineno = sys._getframe().f_lineno + 1 h = asyncio.TimerHandle(123, noop, (), self.loop) filename, lineno = test_utils.get_function_source(noop) self.assertEqual(repr(h), '' % (filename, lineno, create_filename, create_lineno)) # cancelled handle h.cancel() self.assertEqual(repr(h), '' % (filename, lineno, create_filename, create_lineno)) def test_timer_comparison(self): def callback(*args): return args when = time.monotonic() h1 = asyncio.TimerHandle(when, callback, (), self.loop) h2 = asyncio.TimerHandle(when, callback, (), self.loop) # TODO: Use assertLess etc. self.assertFalse(h1 < h2) self.assertFalse(h2 < h1) self.assertTrue(h1 <= h2) self.assertTrue(h2 <= h1) self.assertFalse(h1 > h2) self.assertFalse(h2 > h1) self.assertTrue(h1 >= h2) self.assertTrue(h2 >= h1) self.assertTrue(h1 == h2) self.assertFalse(h1 != h2) h2.cancel() self.assertFalse(h1 == h2) h1 = asyncio.TimerHandle(when, callback, (), self.loop) h2 = asyncio.TimerHandle(when + 10.0, callback, (), self.loop) self.assertTrue(h1 < h2) self.assertFalse(h2 < h1) self.assertTrue(h1 <= h2) self.assertFalse(h2 <= h1) self.assertFalse(h1 > h2) self.assertTrue(h2 > h1) self.assertFalse(h1 >= h2) self.assertTrue(h2 >= h1) self.assertFalse(h1 == h2) self.assertTrue(h1 != h2) h3 = asyncio.Handle(callback, (), self.loop) self.assertIs(NotImplemented, h1.__eq__(h3)) self.assertIs(NotImplemented, h1.__ne__(h3)) with self.assertRaises(TypeError): h1 < () with self.assertRaises(TypeError): h1 > () with self.assertRaises(TypeError): h1 <= () with self.assertRaises(TypeError): h1 >= () self.assertFalse(h1 == ()) self.assertTrue(h1 != ()) self.assertTrue(h1 == ALWAYS_EQ) self.assertFalse(h1 != ALWAYS_EQ) self.assertTrue(h1 < LARGEST) self.assertFalse(h1 > LARGEST) self.assertTrue(h1 <= LARGEST) self.assertFalse(h1 >= LARGEST) self.assertFalse(h1 < SMALLEST) self.assertTrue(h1 > SMALLEST) self.assertFalse(h1 <= SMALLEST) self.assertTrue(h1 >= SMALLEST) class AbstractEventLoopTests(unittest.TestCase): def test_not_implemented(self): f = mock.Mock() loop = asyncio.AbstractEventLoop() self.assertRaises( NotImplementedError, loop.run_forever) self.assertRaises( NotImplementedError, loop.run_until_complete, None) self.assertRaises( NotImplementedError, loop.stop) self.assertRaises( NotImplementedError, loop.is_running) self.assertRaises( NotImplementedError, loop.is_closed) self.assertRaises( NotImplementedError, loop.close) self.assertRaises( NotImplementedError, loop.create_task, None) self.assertRaises( NotImplementedError, loop.call_later, None, None) self.assertRaises( NotImplementedError, loop.call_at, f, f) self.assertRaises( NotImplementedError, loop.call_soon, None) self.assertRaises( NotImplementedError, loop.time) self.assertRaises( NotImplementedError, loop.call_soon_threadsafe, None) self.assertRaises( NotImplementedError, loop.set_default_executor, f) self.assertRaises( NotImplementedError, loop.add_reader, 1, f) self.assertRaises( NotImplementedError, loop.remove_reader, 1) self.assertRaises( NotImplementedError, loop.add_writer, 1, f) self.assertRaises( NotImplementedError, loop.remove_writer, 1) self.assertRaises( NotImplementedError, loop.add_signal_handler, 1, f) self.assertRaises( NotImplementedError, loop.remove_signal_handler, 1) self.assertRaises( NotImplementedError, loop.remove_signal_handler, 1) self.assertRaises( NotImplementedError, loop.set_exception_handler, f) self.assertRaises( NotImplementedError, loop.default_exception_handler, f) self.assertRaises( NotImplementedError, loop.call_exception_handler, f) self.assertRaises( NotImplementedError, loop.get_debug) self.assertRaises( NotImplementedError, loop.set_debug, f) def test_not_implemented_async(self): async def inner(): f = mock.Mock() loop = asyncio.AbstractEventLoop() with self.assertRaises(NotImplementedError): await loop.run_in_executor(f, f) with self.assertRaises(NotImplementedError): await loop.getaddrinfo('localhost', 8080) with self.assertRaises(NotImplementedError): await loop.getnameinfo(('localhost', 8080)) with self.assertRaises(NotImplementedError): await loop.create_connection(f) with self.assertRaises(NotImplementedError): await loop.create_server(f) with self.assertRaises(NotImplementedError): await loop.create_datagram_endpoint(f) with self.assertRaises(NotImplementedError): await loop.sock_recv(f, 10) with self.assertRaises(NotImplementedError): await loop.sock_recv_into(f, 10) with self.assertRaises(NotImplementedError): await loop.sock_sendall(f, 10) with self.assertRaises(NotImplementedError): await loop.sock_connect(f, f) with self.assertRaises(NotImplementedError): await loop.sock_accept(f) with self.assertRaises(NotImplementedError): await loop.sock_sendfile(f, f) with self.assertRaises(NotImplementedError): await loop.sendfile(f, f) with self.assertRaises(NotImplementedError): await loop.connect_read_pipe(f, mock.sentinel.pipe) with self.assertRaises(NotImplementedError): await loop.connect_write_pipe(f, mock.sentinel.pipe) with self.assertRaises(NotImplementedError): await loop.subprocess_shell(f, mock.sentinel) with self.assertRaises(NotImplementedError): await loop.subprocess_exec(f) loop = asyncio.new_event_loop() loop.run_until_complete(inner()) loop.close() class PolicyTests(unittest.TestCase): def test_event_loop_policy(self): policy = asyncio.AbstractEventLoopPolicy() self.assertRaises(NotImplementedError, policy.get_event_loop) self.assertRaises(NotImplementedError, policy.set_event_loop, object()) self.assertRaises(NotImplementedError, policy.new_event_loop) self.assertRaises(NotImplementedError, policy.get_child_watcher) self.assertRaises(NotImplementedError, policy.set_child_watcher, object()) def test_get_event_loop(self): policy = asyncio.DefaultEventLoopPolicy() self.assertIsNone(policy._local._loop) loop = policy.get_event_loop() self.assertIsInstance(loop, asyncio.AbstractEventLoop) self.assertIs(policy._local._loop, loop) self.assertIs(loop, policy.get_event_loop()) loop.close() def test_get_event_loop_calls_set_event_loop(self): policy = asyncio.DefaultEventLoopPolicy() with mock.patch.object( policy, "set_event_loop", wraps=policy.set_event_loop) as m_set_event_loop: loop = policy.get_event_loop() # policy._local._loop must be set through .set_event_loop() # (the unix DefaultEventLoopPolicy needs this call to attach # the child watcher correctly) m_set_event_loop.assert_called_with(loop) loop.close() def test_get_event_loop_after_set_none(self): policy = asyncio.DefaultEventLoopPolicy() policy.set_event_loop(None) self.assertRaises(RuntimeError, policy.get_event_loop) @mock.patch('asyncio.events.threading.current_thread') def test_get_event_loop_thread(self, m_current_thread): def f(): policy = asyncio.DefaultEventLoopPolicy() self.assertRaises(RuntimeError, policy.get_event_loop) th = threading.Thread(target=f) th.start() th.join() def test_new_event_loop(self): policy = asyncio.DefaultEventLoopPolicy() loop = policy.new_event_loop() self.assertIsInstance(loop, asyncio.AbstractEventLoop) loop.close() def test_set_event_loop(self): policy = asyncio.DefaultEventLoopPolicy() old_loop = policy.get_event_loop() self.assertRaises(AssertionError, policy.set_event_loop, object()) loop = policy.new_event_loop() policy.set_event_loop(loop) self.assertIs(loop, policy.get_event_loop()) self.assertIsNot(old_loop, policy.get_event_loop()) loop.close() old_loop.close() def test_get_event_loop_policy(self): policy = asyncio.get_event_loop_policy() self.assertIsInstance(policy, asyncio.AbstractEventLoopPolicy) self.assertIs(policy, asyncio.get_event_loop_policy()) def test_set_event_loop_policy(self): self.assertRaises( AssertionError, asyncio.set_event_loop_policy, object()) old_policy = asyncio.get_event_loop_policy() policy = asyncio.DefaultEventLoopPolicy() asyncio.set_event_loop_policy(policy) self.assertIs(policy, asyncio.get_event_loop_policy()) self.assertIsNot(policy, old_policy) class GetEventLoopTestsMixin: _get_running_loop_impl = None _set_running_loop_impl = None get_running_loop_impl = None get_event_loop_impl = None def setUp(self): self._get_running_loop_saved = events._get_running_loop self._set_running_loop_saved = events._set_running_loop self.get_running_loop_saved = events.get_running_loop self.get_event_loop_saved = events.get_event_loop events._get_running_loop = type(self)._get_running_loop_impl events._set_running_loop = type(self)._set_running_loop_impl events.get_running_loop = type(self).get_running_loop_impl events.get_event_loop = type(self).get_event_loop_impl asyncio._get_running_loop = type(self)._get_running_loop_impl asyncio._set_running_loop = type(self)._set_running_loop_impl asyncio.get_running_loop = type(self).get_running_loop_impl asyncio.get_event_loop = type(self).get_event_loop_impl super().setUp() self.loop = asyncio.new_event_loop() asyncio.set_event_loop(self.loop) if sys.platform != 'win32': watcher = asyncio.SafeChildWatcher() watcher.attach_loop(self.loop) asyncio.set_child_watcher(watcher) def tearDown(self): try: if sys.platform != 'win32': asyncio.set_child_watcher(None) super().tearDown() finally: self.loop.close() asyncio.set_event_loop(None) events._get_running_loop = self._get_running_loop_saved events._set_running_loop = self._set_running_loop_saved events.get_running_loop = self.get_running_loop_saved events.get_event_loop = self.get_event_loop_saved asyncio._get_running_loop = self._get_running_loop_saved asyncio._set_running_loop = self._set_running_loop_saved asyncio.get_running_loop = self.get_running_loop_saved asyncio.get_event_loop = self.get_event_loop_saved if sys.platform != 'win32': def test_get_event_loop_new_process(self): # Issue bpo-32126: The multiprocessing module used by # ProcessPoolExecutor is not functional when the # multiprocessing.synchronize module cannot be imported. support.import_module('multiprocessing.synchronize') async def main(): pool = concurrent.futures.ProcessPoolExecutor() result = await self.loop.run_in_executor( pool, _test_get_event_loop_new_process__sub_proc) pool.shutdown() return result self.assertEqual( self.loop.run_until_complete(main()), 'hello') def test_get_event_loop_returns_running_loop(self): class TestError(Exception): pass class Policy(asyncio.DefaultEventLoopPolicy): def get_event_loop(self): raise TestError old_policy = asyncio.get_event_loop_policy() try: asyncio.set_event_loop_policy(Policy()) loop = asyncio.new_event_loop() with self.assertRaises(TestError): asyncio.get_event_loop() asyncio.set_event_loop(None) with self.assertRaises(TestError): asyncio.get_event_loop() with self.assertRaisesRegex(RuntimeError, 'no running'): self.assertIs(asyncio.get_running_loop(), None) self.assertIs(asyncio._get_running_loop(), None) async def func(): self.assertIs(asyncio.get_event_loop(), loop) self.assertIs(asyncio.get_running_loop(), loop) self.assertIs(asyncio._get_running_loop(), loop) loop.run_until_complete(func()) asyncio.set_event_loop(loop) with self.assertRaises(TestError): asyncio.get_event_loop() asyncio.set_event_loop(None) with self.assertRaises(TestError): asyncio.get_event_loop() finally: asyncio.set_event_loop_policy(old_policy) if loop is not None: loop.close() with self.assertRaisesRegex(RuntimeError, 'no running'): self.assertIs(asyncio.get_running_loop(), None) self.assertIs(asyncio._get_running_loop(), None) class TestPyGetEventLoop(GetEventLoopTestsMixin, unittest.TestCase): _get_running_loop_impl = events._py__get_running_loop _set_running_loop_impl = events._py__set_running_loop get_running_loop_impl = events._py_get_running_loop get_event_loop_impl = events._py_get_event_loop try: import _asyncio # NoQA except ImportError: pass else: class TestCGetEventLoop(GetEventLoopTestsMixin, unittest.TestCase): _get_running_loop_impl = events._c__get_running_loop _set_running_loop_impl = events._c__set_running_loop get_running_loop_impl = events._c_get_running_loop get_event_loop_impl = events._c_get_event_loop class TestServer(unittest.TestCase): def test_get_loop(self): loop = asyncio.new_event_loop() self.addCleanup(loop.close) proto = MyProto(loop) server = loop.run_until_complete(loop.create_server(lambda: proto, '0.0.0.0', 0)) self.assertEqual(server.get_loop(), loop) server.close() loop.run_until_complete(server.wait_closed()) class TestAbstractServer(unittest.TestCase): def test_close(self): with self.assertRaises(NotImplementedError): events.AbstractServer().close() def test_wait_closed(self): loop = asyncio.new_event_loop() self.addCleanup(loop.close) with self.assertRaises(NotImplementedError): loop.run_until_complete(events.AbstractServer().wait_closed()) def test_get_loop(self): with self.assertRaises(NotImplementedError): events.AbstractServer().get_loop() if __name__ == '__main__': unittest.main()