blob: e651cb14e8b522c8936429e760db4f31d3808a64 [file] [log] [blame]
#!/usr/bin/python
"""Tests for connection_manager.py."""
import logging
import os
import shutil
import tempfile
import connection_manager
import interface_test
import iw
import status
from wvtest import wvtest
logging.basicConfig(level=logging.DEBUG)
FAKE_MOCA_NODE1_FILE = """{
"NodeId": 1,
"RxNBAS": 25
}
"""
FAKE_MOCA_NODE1_FILE_DISCONNECTED = """{
"NodeId": 1,
"RxNBAS": 0
}
"""
WIFI_SHOW_OUTPUT_MARVELL8897 = """Band: 2.4
RegDomain: US
Interface: wlan0 # 2.4 GHz ap
Channel: 149
BSSID: f4:f5:e8:81:1b:a0
AutoChannel: True
AutoType: NONDFS
Station List for band: 2.4
Client Interface: wcli0 # 2.4 GHz client
Client BSSID: f4:f5:e8:81:1b:a1
Band: 5
RegDomain: US
Interface: wlan0 # 5 GHz ap
Channel: 149
BSSID: f4:f5:e8:81:1b:a0
AutoChannel: True
AutoType: NONDFS
Station List for band: 5
Client Interface: wcli0 # 5 GHz client
Client BSSID: f4:f5:e8:81:1b:a1
"""
WIFI_SHOW_OUTPUT_ATH9K_ATH10K = """Band: 2.4
RegDomain: US
Interface: wlan0 # 2.4 GHz ap
Channel: 149
BSSID: f4:f5:e8:81:1b:a0
AutoChannel: True
AutoType: NONDFS
Station List for band: 2.4
Client Interface: wcli0 # 2.4 GHz client
Client BSSID: f4:f5:e8:81:1b:a1
Band: 5
RegDomain: US
Interface: wlan1 # 5 GHz ap
Channel: 149
BSSID: f4:f5:e8:81:1b:a0
AutoChannel: True
AutoType: NONDFS
Station List for band: 5
Client Interface: wcli1 # 5 GHz client
Client BSSID: f4:f5:e8:81:1b:a1
"""
# See b/27328894.
WIFI_SHOW_OUTPUT_MARVELL8897_NO_5GHZ = """Band: 2.4
RegDomain: 00
Interface: wlan0 # 2.4 GHz ap
BSSID: 00:50:43:02:fe:01
AutoChannel: False
Station List for band: 2.4
Client Interface: wcli0 # 2.4 GHz client
Client BSSID: 00:50:43:02:fe:02
Band: 5
RegDomain: 00
"""
WIFI_SHOW_OUTPUT_ATH9K_FRENZY = """Band: 2.4
RegDomain: US
Interface: wlan0 # 2.4 GHz ap
Channel: 149
BSSID: f4:f5:e8:81:1b:a0
AutoChannel: True
AutoType: NONDFS
Station List for band: 2.4
Client Interface: wcli0 # 2.4 GHz client
Client BSSID: f4:f5:e8:81:1b:a1
Band: 5
RegDomain: 00
"""
WIFI_SHOW_OUTPUT_FRENZY = """Band: 2.4
RegDomain: 00
Band: 5
RegDomain: 00
"""
IW_SCAN_DEFAULT_OUTPUT = """BSS 00:11:22:33:44:55(on wcli0)
SSID: s1
BSS 66:77:88:99:aa:bb(on wcli0)
SSID: s1
BSS 01:23:45:67:89:ab(on wcli0)
SSID: s2
"""
IW_SCAN_HIDDEN_OUTPUT = """BSS ff:ee:dd:cc:bb:aa(on wcli0)
Vendor specific: OUI f4:f5:e8, data: 01
Vendor specific: OUI f4:f5:e8, data: 03 73 33
"""
@wvtest.wvtest
def get_client_interfaces_test():
"""Test get_client_interfaces."""
wifi_show = None
quantenna_interfaces = None
# pylint: disable=protected-access
old_wifi_show = connection_manager._wifi_show
old_get_quantenna_interfaces = connection_manager._get_quantenna_interfaces
connection_manager._wifi_show = lambda: wifi_show
connection_manager._get_quantenna_interfaces = lambda: quantenna_interfaces
wifi_show = WIFI_SHOW_OUTPUT_MARVELL8897
quantenna_interfaces = []
wvtest.WVPASSEQ(connection_manager.get_client_interfaces(),
{'wcli0': {'bands': set(['2.4', '5'])}})
wifi_show = WIFI_SHOW_OUTPUT_ATH9K_ATH10K
quantenna_interfaces = []
wvtest.WVPASSEQ(connection_manager.get_client_interfaces(), {
'wcli0': {'bands': set(['2.4'])},
'wcli1': {'bands': set(['5'])}
})
# Test Quantenna devices.
# 2.4 GHz cfg80211 radio + 5 GHz Frenzy (Optimus Prime).
wifi_show = WIFI_SHOW_OUTPUT_ATH9K_FRENZY
quantenna_interfaces = ['wlan1', 'wlan1_portal', 'wcli1']
wvtest.WVPASSEQ(connection_manager.get_client_interfaces(), {
'wcli0': {'bands': set(['2.4'])},
'wcli1': {'frenzy': True, 'bands': set(['5'])}
})
# Only Frenzy (e.g. Lockdown).
wifi_show = WIFI_SHOW_OUTPUT_FRENZY
quantenna_interfaces = ['wlan0', 'wlan0_portal', 'wcli0']
wvtest.WVPASSEQ(connection_manager.get_client_interfaces(),
{'wcli0': {'frenzy': True, 'bands': set(['5'])}})
connection_manager._wifi_show = old_wifi_show
connection_manager._get_quantenna_interfaces = old_get_quantenna_interfaces
class WLANConfiguration(connection_manager.WLANConfiguration):
"""WLANConfiguration subclass for testing."""
WIFI_STOPAP = ['echo', 'stopap']
WIFI_SETCLIENT = ['echo', 'setclient']
WIFI_STOPCLIENT = ['echo', 'stopclient']
def start_client(self):
client_was_up = self.client_up
was_attached = self.wifi.attached()
# Do this before calling the super method so that the attach call at the end
# succeeds.
if not client_was_up and not was_attached:
self.wifi._initial_ssid_testonly = self.ssid
self.wifi.start_wpa_supplicant_testonly(self._wpa_control_interface)
super(WLANConfiguration, self).start_client()
if not client_was_up:
self.wifi.set_connection_check_result('succeed')
if was_attached:
self.wifi._wpa_control.ssid_testonly = self.ssid
self.wifi.add_connected_event()
# Normally, wpa_supplicant would bring up the client interface, which
# would trigger ifplugd, which would run ifplugd.action, which would do
# two things:
#
# 1) Write an interface status file.
# 2) Call run-dhclient, which would call dhclient-script, which would
# write a gateway file.
#
# Fake both of these things instead.
self.write_interface_status_file('1')
self.write_gateway_file()
def stop_client(self):
client_was_up = self.client_up
super(WLANConfiguration, self).stop_client()
if client_was_up:
self.wifi.add_terminating_event()
self.wifi.set_connection_check_result('fail')
# See comments in start_client.
self.write_interface_status_file('0')
def write_gateway_file(self):
gateway_file = os.path.join(self.tmp_dir,
self.gateway_file_prefix + self.wifi.name)
with open(gateway_file, 'w') as f:
# This value doesn't matter to conman, so it's fine to hard code it here.
f.write('192.168.1.1')
def write_interface_status_file(self, value):
status_file = os.path.join(self.interface_status_dir, self.wifi.name)
with open(status_file, 'w') as f:
# This value doesn't matter to conman, so it's fine to hard code it here.
f.write(value)
class Wifi(interface_test.Wifi):
def __init__(self, *args, **kwargs):
super(Wifi, self).__init__(*args, **kwargs)
self.wifi_scan_counter = 0
class FrenzyWifi(interface_test.FrenzyWifi):
def __init__(self, *args, **kwargs):
super(FrenzyWifi, self).__init__(*args, **kwargs)
self.wifi_scan_counter = 0
class ConnectionManager(connection_manager.ConnectionManager):
"""ConnectionManager subclass for testing."""
# pylint: disable=invalid-name
Bridge = interface_test.Bridge
Wifi = Wifi
FrenzyWifi = FrenzyWifi
WLANConfiguration = WLANConfiguration
WIFI_SETCLIENT = ['echo', 'setclient']
IFUP = ['echo', 'ifup']
IFPLUGD_ACTION = ['echo', 'ifplugd.action']
BINWIFI = ['echo', 'wifi']
def __init__(self, *args, **kwargs):
self._binwifi_commands = []
self.interfaces_already_up = kwargs.pop('__test_interfaces_already_up',
['eth0'])
self.wifi_interfaces_already_up = [ifc for ifc in self.interfaces_already_up
if ifc.startswith('w')]
for wifi in self.wifi_interfaces_already_up:
# wcli1 is always 5 GHz. wcli0 always *includes* 2.4. wlan* client
# interfaces are Frenzy interfaces and therefore 5 GHz-only.
band = '5' if wifi in ('wlan0', 'wlan1', 'wcli1') else '2.4'
# This will happen in the super function, but in order for
# write_wlan_config to work we have to do it now. This has to happen
# before the super function so that the files exist before the inotify
# registration.
self._config_dir = kwargs['config_dir']
self.write_wlan_config(band, 'my ssid', 'passphrase')
# Also create the wpa_supplicant socket to which to attach.
open(os.path.join(kwargs['wpa_control_interface'], wifi), 'w')
super(ConnectionManager, self).__init__(*args, **kwargs)
self.interface_with_scan_results = None
self.scan_results_include_hidden = False
# Should we be able to connect to open network s2?
self.can_connect_to_s2 = True
self.can_connect_to_s3 = True
# Will s2 fail rather than providing ACS access?
self.s2_fail = False
def create_wifi_interfaces(self):
super(ConnectionManager, self).create_wifi_interfaces()
for wifi in self.wifi_interfaces_already_up:
# pylint: disable=protected-access
self.interface_by_name(wifi)._initial_ssid_testonly = 'my ssid'
@property
def IP_LINK(self):
return ['echo'] + ['%s LOWER_UP' % ifc
for ifc in self.interfaces_already_up]
def _update_access_point(self, wlan_configuration):
client_was_up = wlan_configuration.client_up
super(ConnectionManager, self)._update_access_point(wlan_configuration)
if wlan_configuration.access_point_up:
if client_was_up:
wifi = self.wifi_for_band(wlan_configuration.band)
wifi.add_terminating_event()
def _try_bssid(self, wifi, bss_info):
self.last_provisioning_attempt = bss_info
super(ConnectionManager, self)._try_bssid(wifi, bss_info)
def connect(connection_check_result):
# pylint: disable=protected-access
if wifi.attached():
wifi._wpa_control._ssid_testonly = bss_info.ssid
wifi.add_connected_event()
else:
wifi._initial_ssid_testonly = bss_info.ssid
wifi.start_wpa_supplicant_testonly(self._wpa_control_interface)
wifi.set_connection_check_result(connection_check_result)
self.ifplugd_action(wifi.name, True)
if bss_info and bss_info.ssid == 's1':
connect('fail')
return True
if bss_info and bss_info.ssid == 's2' and self.can_connect_to_s2:
connect('fail' if self.s2_fail else 'succeed')
return True
if bss_info and bss_info.ssid == 's3' and self.can_connect_to_s3:
connect('restricted')
return True
return False
# pylint: disable=unused-argument,protected-access
def _find_bssids(self, band):
scan_output = ''
if (self.interface_with_scan_results and
band in self.interface_by_name(self.interface_with_scan_results).bands):
scan_output = IW_SCAN_DEFAULT_OUTPUT
if self.scan_results_include_hidden:
scan_output += IW_SCAN_HIDDEN_OUTPUT
iw._scan = lambda interface: scan_output
return super(ConnectionManager, self)._find_bssids(band)
def _update_wlan_configuration(self, wlan_configuration):
wlan_configuration.command.insert(0, 'echo')
wlan_configuration._wpa_control_interface = self._wpa_control_interface
wlan_configuration.tmp_dir = self._tmp_dir
wlan_configuration.interface_status_dir = self._interface_status_dir
wlan_configuration.gateway_file_prefix = self.GATEWAY_FILE_PREFIX
super(ConnectionManager, self)._update_wlan_configuration(
wlan_configuration)
# Just looking for last_wifi_scan_time to change doesn't work because the
# tests run too fast.
def _wifi_scan(self, wifi):
super(ConnectionManager, self)._wifi_scan(wifi)
wifi.wifi_scan_counter += 1
def ifplugd_action(self, interface_name, up):
# Typically, when moca comes up, conman calls ifplugd.action, which writes
# this file. Also, when conman starts, it calls ifplugd.action for eth0.
self.write_interface_status_file(interface_name, '1' if up else '0')
# ifplugd calls run-dhclient, which results in a gateway file if the link is
# up (and working).
if up:
self.write_gateway_file('br0' if interface_name in ('eth0', 'moca0')
else interface_name)
def _binwifi(self, *command):
super(ConnectionManager, self)._binwifi(*command)
self._binwifi_commands.append(command)
# Non-overrides
def access_point_up(self, band):
if band not in self._wlan_configuration:
return False
return self._wlan_configuration[band].access_point_up
def client_up(self, band):
if band not in self._wlan_configuration:
return False
return self._wlan_configuration[band].client_up
# Test methods
def delete_wlan_config(self, band):
delete_wlan_config(self._config_dir, band)
def write_wlan_config(self, *args, **kwargs):
write_wlan_config(self._config_dir, *args, **kwargs)
def enable_access_point(self, band):
enable_access_point(self._config_dir, band)
def disable_access_point(self, band):
disable_access_point(self._config_dir, band)
def write_gateway_file(self, interface_name):
gateway_file = os.path.join(self._tmp_dir,
self.GATEWAY_FILE_PREFIX + interface_name)
with open(gateway_file, 'w') as f:
# This value doesn't matter to conman, so it's fine to hard code it here.
f.write('192.168.1.1')
def write_interface_status_file(self, interface_name, value):
status_file = os.path.join(self._interface_status_dir, interface_name)
with open(status_file, 'w') as f:
# This value doesn't matter to conman, so it's fine to hard code it here.
f.write(value)
def set_ethernet(self, up):
self.ifplugd_action('eth0', up)
def set_moca(self, up):
moca_node1_file = os.path.join(self._moca_tmp_dir,
self.MOCA_NODE_FILE_PREFIX + '1')
with open(moca_node1_file, 'w') as f:
f.write(FAKE_MOCA_NODE1_FILE if up else
FAKE_MOCA_NODE1_FILE_DISCONNECTED)
def run_until_interface_update(self):
while self._interface_update_counter == 0:
self.run_once()
while self._interface_update_counter != 0:
self.run_once()
def run_until_scan(self, band):
wifi = self.wifi_for_band(band)
wifi_scan_counter = wifi.wifi_scan_counter
while wifi_scan_counter == wifi.wifi_scan_counter:
self.run_once()
def run_until_interface_update_and_scan(self, band):
wifi = self.wifi_for_band(band)
wifi_scan_counter = wifi.wifi_scan_counter
self.run_until_interface_update()
while wifi_scan_counter == wifi.wifi_scan_counter:
self.run_once()
def has_status_files(self, files):
return not set(files) - set(os.listdir(self._status_dir))
def wlan_config_filename(path, band):
return os.path.join(path, 'command.%s' % band)
def access_point_filename(path, band):
return os.path.join(path, 'access_point.%s' % band)
def write_wlan_config(path, band, ssid, psk, atomic=False):
final_filename = wlan_config_filename(path, band)
filename = final_filename + ('.tmp' if atomic else '')
with open(filename, 'w') as f:
f.write('\n'.join(['env', 'WIFI_PSK=%s' % psk,
'wifi', 'set', '-b', band, '--ssid', ssid]))
if atomic:
os.rename(filename, final_filename)
def delete_wlan_config(path, band):
os.unlink(wlan_config_filename(path, band))
def enable_access_point(path, band):
open(access_point_filename(path, band), 'w')
def disable_access_point(path, band):
ap_filename = access_point_filename(path, band)
if os.path.isfile(ap_filename):
os.unlink(ap_filename)
def connection_manager_test(radio_config, wlan_configs=None,
quantenna_interfaces=None, **cm_kwargs):
"""Returns a decorator that does ConnectionManager test boilerplate."""
if wlan_configs is None:
wlan_configs = {}
def inner(f):
"""The actual decorator."""
def actual_test():
"""The actual test function."""
run_duration_s = .01
interface_update_period = 5
wifi_scan_period = 15
wifi_scan_period_s = run_duration_s * wifi_scan_period
# pylint: disable=protected-access
old_wifi_show = connection_manager._wifi_show
connection_manager._wifi_show = lambda: radio_config
old_gqi = connection_manager._get_quantenna_interfaces
connection_manager._get_quantenna_interfaces = (
lambda: quantenna_interfaces or [])
try:
# No initial state.
tmp_dir = tempfile.mkdtemp()
config_dir = tempfile.mkdtemp()
os.mkdir(os.path.join(tmp_dir, 'interfaces'))
moca_tmp_dir = tempfile.mkdtemp()
wpa_control_interface = tempfile.mkdtemp()
for band, access_point in wlan_configs.iteritems():
write_wlan_config(config_dir, band, 'initial ssid', 'initial psk')
if access_point:
open(os.path.join(config_dir, 'access_point.%s' % band), 'w')
# Test that missing directories are created by ConnectionManager.
shutil.rmtree(tmp_dir)
c = ConnectionManager(tmp_dir=tmp_dir,
config_dir=config_dir,
moca_tmp_dir=moca_tmp_dir,
wpa_control_interface=wpa_control_interface,
run_duration_s=run_duration_s,
interface_update_period=interface_update_period,
wifi_scan_period_s=wifi_scan_period_s,
**cm_kwargs)
c.test_interface_update_period = interface_update_period
c.test_wifi_scan_period = wifi_scan_period
f(c)
finally:
shutil.rmtree(tmp_dir)
shutil.rmtree(config_dir)
shutil.rmtree(moca_tmp_dir)
shutil.rmtree(wpa_control_interface)
# pylint: disable=protected-access
connection_manager._wifi_show = old_wifi_show
connection_manager._get_quantenna_interfaces = old_gqi
actual_test.func_name = f.func_name
return actual_test
return inner
def connection_manager_test_generic(c, band):
"""Test ConnectionManager for things independent of radio configuration.
To verify that these things are both independent, this function is called once
below with each radio configuration.
Args:
c: The ConnectionManager set up by @connection_manager_test.
band: The band to test.
"""
# This test only checks that this file gets created and deleted once each.
# ConnectionManager cares that the file is created *where* expected, but it is
# Bridge's responsbility to make sure its creation and deletion are generally
# correct; more thorough tests are in bridge_test in interface_test.py.
acs_autoprov_filepath = os.path.join(c._tmp_dir, 'acs_autoprovisioning')
# Initially, there is ethernet access (via explicit check of ethernet status,
# rather than the interface status file).
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
wvtest.WVPASS(c.has_status_files([status.P.CAN_REACH_ACS,
status.P.CAN_REACH_INTERNET]))
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
wvtest.WVPASS(c.bridge.current_route())
wvtest.WVPASS(os.path.exists(acs_autoprov_filepath))
for wifi in c.wifi:
wvtest.WVFAIL(wifi.current_route())
wvtest.WVFAIL(c.has_status_files([status.P.CONNECTED_TO_WLAN,
status.P.HAVE_CONFIG]))
# Take down ethernet, no access.
c.set_ethernet(False)
c.run_once()
wvtest.WVFAIL(c.acs())
wvtest.WVFAIL(c.internet())
wvtest.WVFAIL(c.bridge.current_route())
wvtest.WVFAIL(os.path.exists(acs_autoprov_filepath))
wvtest.WVFAIL(c.has_status_files([status.P.CAN_REACH_ACS,
status.P.CAN_REACH_INTERNET]))
# Bring up moca, access.
c.set_moca(True)
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
wvtest.WVPASS(c.bridge.current_route())
# Bring up ethernet, access via both moca and ethernet.
c.set_ethernet(True)
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
wvtest.WVPASS(c.bridge.current_route())
# Bring down moca, still have access via ethernet.
c.set_moca(False)
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
wvtest.WVPASS(c.bridge.current_route())
# The bridge interfaces are up, but they can't reach anything.
c.bridge.set_connection_check_result('fail')
c.run_until_interface_update()
wvtest.WVFAIL(c.acs())
wvtest.WVFAIL(c.internet())
wvtest.WVFAIL(c.bridge.current_route())
# Now c connects to a restricted network.
c.bridge.set_connection_check_result('restricted')
c.run_until_interface_update()
wvtest.WVPASS(c.acs())
wvtest.WVFAIL(c.internet())
wvtest.WVPASS(c.bridge.current_route())
# Now the wired connection goes away.
c.set_ethernet(False)
c.set_moca(False)
c.run_once()
wvtest.WVFAIL(c.acs())
wvtest.WVFAIL(c.internet())
wvtest.WVFAIL(c.bridge.current_route())
# Now there are some scan results.
c.interface_with_scan_results = c.wifi_for_band(band).name
# Wait for a scan, plus 3 cycles, so that s2 will have been tried.
c.run_until_scan(band)
for _ in range(3):
c.run_once()
wvtest.WVPASS(c.has_status_files([status.P.CONNECTED_TO_OPEN]))
last_bss_info = c.wifi_for_band(band).last_attempted_bss_info
wvtest.WVPASSEQ(last_bss_info.ssid, 's2')
wvtest.WVPASSEQ(last_bss_info.bssid, '01:23:45:67:89:ab')
# Wait for the connection to be processed.
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
wvtest.WVFAIL(c.client_up(band))
wvtest.WVPASS(c.wifi_for_band(band).current_route())
# Disable scan results again.
c.interface_with_scan_results = None
# Now, create a WLAN configuration which should be connected to.
ssid = 'wlan'
psk = 'password'
c.write_wlan_config(band, ssid, psk)
c.disable_access_point(band)
c.run_once()
wvtest.WVPASS(c.client_up(band))
wvtest.WVPASS(c.wifi_for_band(band).current_route())
wvtest.WVPASS(c.has_status_files([status.P.CONNECTED_TO_WLAN]))
# Kill wpa_supplicant. conman should restart it.
wvtest.WVPASS(c.client_up(band))
wvtest.WVPASS(c._connected_to_wlan(c.wifi_for_band(band)))
c.wifi_for_band(band).kill_wpa_supplicant_testonly(c._wpa_control_interface)
wvtest.WVFAIL(c.client_up(band))
wvtest.WVFAIL(c._connected_to_wlan(c.wifi_for_band(band)))
c.run_once()
wvtest.WVPASS(c.has_status_files([status.P.CONNECTED_TO_WLAN]))
wvtest.WVPASS(c.client_up(band))
wvtest.WVPASS(c._connected_to_wlan(c.wifi_for_band(band)))
# Now, remove the WLAN configuration and make sure we are disconnected. Then
# disable the previously used ACS connection via s2, re-enable scan results,
# add the user's WLAN to the scan results, and scan again. This time, the
# first SSID tried should be 's3', which is now present in the scan results
# (with its SSID hidden, but included via vendor IE).
c.delete_wlan_config(band)
c.can_connect_to_s2 = False
c.interface_with_scan_results = c.wifi_for_band(band).name
c.scan_results_include_hidden = True
c.run_until_interface_update_and_scan(band)
wvtest.WVFAIL(c.has_status_files([status.P.CONNECTED_TO_WLAN]))
c.run_until_interface_update()
wvtest.WVPASS(c.has_status_files([status.P.CONNECTED_TO_OPEN]))
wvtest.WVPASSEQ(c.last_provisioning_attempt.ssid, 's3')
wvtest.WVPASSEQ(c.last_provisioning_attempt.bssid, 'ff:ee:dd:cc:bb:aa')
# Now, recreate the same WLAN configuration, which should be connected to.
# Also, test that atomic writes/renames work.
ssid = 'wlan'
psk = 'password'
c.write_wlan_config(band, ssid, psk, atomic=True)
c.disable_access_point(band)
c.run_once()
wvtest.WVPASS(c.client_up(band))
wvtest.WVPASS(c.wifi_for_band(band).current_route())
wvtest.WVPASS(c.has_status_files([status.P.CONNECTED_TO_WLAN]))
# Now enable the AP. Since we have no wired connection, this should have no
# effect.
c.enable_access_point(band)
c.run_once()
wvtest.WVPASS(c.client_up(band))
wvtest.WVPASS(c.wifi_for_band(band).current_route())
wvtest.WVFAIL(c.bridge.current_route())
# Now bring up the bridge. We should remove the wifi connection and start
# an AP.
c.set_ethernet(True)
c.bridge.set_connection_check_result('succeed')
c.run_until_interface_update()
wvtest.WVPASS(c.access_point_up(band))
wvtest.WVFAIL(c.client_up(band))
wvtest.WVFAIL(c.wifi_for_band(band).current_route())
wvtest.WVPASS(c.bridge.current_route())
# Now move (rather than delete) the configuration file. The AP should go
# away, and we should not be able to join the WLAN. Routes should not be
# affected.
filename = wlan_config_filename(c._config_dir, band)
other_filename = filename + '.bak'
os.rename(filename, other_filename)
c.run_once()
wvtest.WVFAIL(c.access_point_up(band))
wvtest.WVFAIL(c.client_up(band))
wvtest.WVFAIL(c.wifi_for_band(band).current_route())
wvtest.WVPASS(c.bridge.current_route())
wvtest.WVFAIL(c.has_status_files([status.P.HAVE_CONFIG]))
# Now move it back, and the AP should come back.
os.rename(other_filename, filename)
c.run_once()
wvtest.WVPASS(c.access_point_up(band))
wvtest.WVFAIL(c.client_up(band))
wvtest.WVFAIL(c.wifi_for_band(band).current_route())
wvtest.WVPASS(c.bridge.current_route())
# Now delete the config and bring down the bridge and make sure we reprovision
# via the last working BSS.
c.delete_wlan_config(band)
c.bridge.set_connection_check_result('fail')
scan_count_for_band = c.wifi_for_band(band).wifi_scan_counter
c.run_until_interface_update()
wvtest.WVFAIL(c.acs())
wvtest.WVFAIL(c.internet())
# s3 is not what the cycler would suggest trying next.
wvtest.WVPASSNE('s3', c.wifi_for_band(band).cycler.peek())
# Run only once, so that only one BSS can be tried. It should be the s3 one,
# since that worked previously.
c.run_once()
wvtest.WVPASS(c.acs())
# Make sure we didn't scan on `band`.
wvtest.WVPASSEQ(scan_count_for_band, c.wifi_for_band(band).wifi_scan_counter)
# Now re-create the WLAN config, connect to the WLAN, and make sure that s3 is
# unset as last_successful_bss_info, since it is no longer available.
c.write_wlan_config(band, ssid, psk)
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
c.can_connect_to_s3 = False
c.scan_results_include_hidden = False
c.delete_wlan_config(band)
c.run_once()
wvtest.WVPASSEQ(c.wifi_for_band(band).last_successful_bss_info, None)
# Now do the same, except this time s2 is connected to but doesn't provide ACS
# access. This requires first re-establishing s2 as successful, so there are
# four steps:
#
# 1) Connect to WLAN.
# 2) Disconnect, reprovision via s2 (establishing it as successful).
# 3) Reconnect to WLAN so that we can trigger re-provisioning by
# disconnecting.
# 4) Connect to s2 but get no ACS access; see that last_successful_bss_info is
# unset.
c.write_wlan_config(band, ssid, psk)
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
c.delete_wlan_config(band)
c.run_once()
wvtest.WVFAIL(c.wifi_for_band(band).acs())
c.can_connect_to_s2 = True
# Give it time to try all BSSIDs.
for _ in range(3):
c.run_once()
s2_bss = iw.BssInfo('01:23:45:67:89:ab', 's2')
wvtest.WVPASSEQ(c.wifi_for_band(band).last_successful_bss_info, s2_bss)
c.s2_fail = True
c.write_wlan_config(band, ssid, psk)
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
wvtest.WVPASSEQ(c.wifi_for_band(band).last_successful_bss_info, s2_bss)
c.delete_wlan_config(band)
# Run once so that c will reconnect to s2.
c.run_once()
# Now run until it sees the lack of ACS access.
c.run_until_interface_update()
wvtest.WVPASSEQ(c.wifi_for_band(band).last_successful_bss_info, None)
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_MARVELL8897)
def connection_manager_test_generic_marvell8897_2g(c):
connection_manager_test_generic(c, '2.4')
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_MARVELL8897)
def connection_manager_test_generic_marvell8897_5g(c):
connection_manager_test_generic(c, '5')
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_ATH9K_ATH10K)
def connection_manager_test_generic_ath9k_ath10k_2g(c):
connection_manager_test_generic(c, '2.4')
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_ATH9K_ATH10K)
def connection_manager_test_generic_ath9k_ath10k_5g(c):
connection_manager_test_generic(c, '5')
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_ATH9K_FRENZY,
quantenna_interfaces=['wlan1', 'wlan1_portal', 'wcli1']
)
def connection_manager_test_generic_ath9k_frenzy_2g(c):
connection_manager_test_generic(c, '2.4')
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_ATH9K_FRENZY,
quantenna_interfaces=['wlan1', 'wlan1_portal', 'wcli1']
)
def connection_manager_test_generic_ath9k_frenzy_5g(c):
connection_manager_test_generic(c, '5')
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_FRENZY,
quantenna_interfaces=['wlan0', 'wlan0_portal', 'wcli0']
)
def connection_manager_test_generic_frenzy_5g(c):
connection_manager_test_generic(c, '5')
def connection_manager_test_dual_band_two_radios(c):
"""Test ConnectionManager for devices with two radios.
This test should be kept roughly parallel to the one-radio test.
Args:
c: The ConnectionManager set up by @connection_manager_test.
"""
wvtest.WVPASSEQ(len(c._binwifi_commands), 2)
for band in ['2.4', '5']:
wvtest.WVPASS(('stop', '--band', band, '--persist') in c._binwifi_commands)
# Bring up ethernet, access.
c.set_ethernet(True)
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
ssid = 'my ssid'
psk = 'passphrase'
# Bring up both access points.
c.write_wlan_config('2.4', ssid, psk)
c.enable_access_point('2.4')
c.write_wlan_config('5', ssid, psk)
c.enable_access_point('5')
c.run_once()
wvtest.WVPASS(c.access_point_up('2.4'))
wvtest.WVPASS(c.access_point_up('5'))
wvtest.WVPASS(c.bridge.current_route())
wvtest.WVFAIL(c.client_up('2.4'))
wvtest.WVFAIL(c.client_up('5'))
wvtest.WVFAIL(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
# Disable the 2.4 GHz AP, make sure the 5 GHz AP stays up. 2.4 GHz should
# join the WLAN.
c.disable_access_point('2.4')
c.run_until_interface_update()
wvtest.WVFAIL(c.access_point_up('2.4'))
wvtest.WVPASS(c.access_point_up('5'))
wvtest.WVPASS(c.client_up('2.4'))
wvtest.WVPASS(c.bridge.current_route())
wvtest.WVPASS(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
# Delete the 2.4 GHz WLAN configuration; it should leave the WLAN but nothing
# else should change.
c.delete_wlan_config('2.4')
c.run_until_interface_update()
wvtest.WVFAIL(c.access_point_up('2.4'))
wvtest.WVPASS(c.access_point_up('5'))
wvtest.WVFAIL(c.client_up('2.4'))
wvtest.WVPASS(c.bridge.current_route())
wvtest.WVFAIL(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
# Disable the wired connection and remove the WLAN configurations. Both
# radios should scan. Wait for 5 GHz to scan, then enable scan results for
# 2.4. This should lead to ACS access.
c.delete_wlan_config('5')
c.set_ethernet(False)
c.run_once()
wvtest.WVFAIL(c.acs())
wvtest.WVFAIL(c.bridge.current_route())
wvtest.WVFAIL(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
# The 5 GHz scan has no results.
c.run_until_scan('5')
c.run_once()
c.run_until_interface_update()
wvtest.WVFAIL(c.acs())
wvtest.WVFAIL(c.bridge.current_route())
wvtest.WVFAIL(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
# The next 2.4 GHz scan will have results.
c.interface_with_scan_results = c.wifi_for_band('2.4').name
c.run_until_scan('2.4')
# Now run 3 cycles, so that s2 will have been tried.
for _ in range(3):
c.run_once()
c.run_until_interface_update()
wvtest.WVPASS(c.acs())
wvtest.WVFAIL(c.bridge.current_route())
wvtest.WVPASS(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_ATH9K_ATH10K)
def connection_manager_test_dual_band_two_radios_ath9k_ath10k(c):
connection_manager_test_dual_band_two_radios(c)
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_ATH9K_FRENZY,
quantenna_interfaces=['wlan1', 'wlan1_portal', 'wcli1']
)
def connection_manager_test_dual_band_two_radios_ath9k_frenzy(c):
connection_manager_test_dual_band_two_radios(c)
def connection_manager_test_dual_band_one_radio(c):
"""Test ConnectionManager for devices with one dual-band radio.
This test should be kept roughly parallel to
connection_manager_test_dual_band_two_radios.
Args:
c: The ConnectionManager set up by @connection_manager_test.
"""
wvtest.WVPASSEQ(len(c._binwifi_commands), 1)
wvtest.WVPASSEQ(('stop', '--band', '5', '--persist'), c._binwifi_commands[0])
# Bring up ethernet, access.
c.set_ethernet(True)
c.run_once()
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
ssid = 'my ssid'
psk = 'passphrase'
# Enable both access points. Only 5 should be up.
c.write_wlan_config('2.4', ssid, psk)
c.enable_access_point('2.4')
c.write_wlan_config('5', ssid, psk)
c.enable_access_point('5')
c.run_once()
wvtest.WVFAIL(c.access_point_up('2.4'))
wvtest.WVPASS(c.access_point_up('5'))
wvtest.WVPASS(c.bridge.current_route())
wvtest.WVFAIL(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
# Disable the 2.4 GHz AP; nothing should change. The 2.4 GHz client should
# not be up because the same radio is being used to run a 5 GHz AP.
c.disable_access_point('2.4')
c.run_until_interface_update()
wvtest.WVFAIL(c.access_point_up('2.4'))
wvtest.WVPASS(c.access_point_up('5'))
wvtest.WVFAIL(c.client_up('2.4'))
wvtest.WVPASS(c.bridge.current_route())
wvtest.WVFAIL(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
# Delete the 2.4 GHz WLAN configuration; nothing should change.
c.delete_wlan_config('2.4')
c.run_once()
wvtest.WVFAIL(c.access_point_up('2.4'))
wvtest.WVPASS(c.access_point_up('5'))
wvtest.WVFAIL(c.client_up('2.4'))
wvtest.WVPASS(c.bridge.current_route())
wvtest.WVFAIL(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
# Disable the wired connection and remove the WLAN configurations. There
# should be a single scan that leads to ACS access. (It doesn't matter which
# band we specify in run_until_scan, since both bands point to the same
# interface.)
c.delete_wlan_config('5')
c.set_ethernet(False)
c.run_once()
wvtest.WVFAIL(c.acs())
wvtest.WVFAIL(c.bridge.current_route())
wvtest.WVFAIL(c.wifi_for_band('2.4').current_route())
wvtest.WVFAIL(c.wifi_for_band('5').current_route())
# The 2.4 GHz scan will have results that will lead to ACS access.
c.interface_with_scan_results = c.wifi_for_band('2.4').name
c.run_until_scan('5')
for _ in range(3):
c.run_once()
c.run_until_interface_update()
wvtest.WVPASS(c.acs())
wvtest.WVFAIL(c.bridge.current_route())
wvtest.WVPASS(c.wifi_for_band('2.4').current_route())
wvtest.WVPASS(c.wifi_for_band('5').current_route())
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_MARVELL8897)
def connection_manager_test_dual_band_one_radio_marvell8897(c):
connection_manager_test_dual_band_one_radio(c)
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_MARVELL8897_NO_5GHZ)
def connection_manager_test_marvell8897_no_5ghz(c):
"""Test ConnectionManager for the case documented in b/27328894.
conman should be able to handle the lack of 5 GHz without actually
crashing. Wired connections should not be affected.
Args:
c: The ConnectionManager set up by @connection_manager_test.
"""
# Make sure we've correctly set up the test; that there is no 5 GHz wifi
# interface.
wvtest.WVPASSEQ(c.wifi_for_band('5'), None)
c.set_ethernet(True)
wvtest.WVPASS(c.acs())
wvtest.WVPASS(c.internet())
# Make sure this doesn't crash.
c.write_wlan_config('5', 'my ssid', 'my psk')
c.run_once()
c.enable_access_point('5')
c.run_once()
c.disable_access_point('5')
c.run_once()
c.delete_wlan_config('5')
c.run_once()
# Make sure 2.4 still works.
c.write_wlan_config('2.4', 'my ssid', 'my psk')
c.run_once()
wvtest.WVPASS(c.wifi_for_band('2.4').acs())
wvtest.WVPASS(c.wifi_for_band('2.4').internet())
wvtest.WVPASS(c.wifi_for_band('2.4').current_route())
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_MARVELL8897,
__test_interfaces_already_up=['eth0', 'wcli0'])
def connection_manager_test_wifi_already_up(c):
"""Test ConnectionManager when wifi is already up.
Args:
c: The ConnectionManager set up by @connection_manager_test.
"""
wvtest.WVPASS(c._connected_to_wlan(c.wifi_for_band('2.4')))
wvtest.WVPASS(c.wifi_for_band('2.4').current_route)
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_MARVELL8897, wlan_configs={'5': True})
def connection_manager_one_radio_marvell8897_existing_config_5g_ap(c):
wvtest.WVPASSEQ(len(c._binwifi_commands), 1)
wvtest.WVPASSEQ(('stopclient', '--band', '5', '--persist'),
c._binwifi_commands[0])
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_MARVELL8897,
wlan_configs={'5': False})
def connection_manager_one_radio_marvell8897_existing_config_5g_no_ap(c):
wvtest.WVPASSEQ(len(c._binwifi_commands), 1)
wvtest.WVPASSEQ(('stopap', '--band', '5', '--persist'),
c._binwifi_commands[0])
@wvtest.wvtest
@connection_manager_test(WIFI_SHOW_OUTPUT_ATH9K_ATH10K,
wlan_configs={'5': True})
def connection_manager_two_radios_ath9k_ath10k_existing_config_5g_ap(c):
wvtest.WVPASSEQ(len(c._binwifi_commands), 2)
wvtest.WVPASS(('stop', '--band', '2.4', '--persist') in c._binwifi_commands)
wvtest.WVPASS(('stopclient', '--band', '5', '--persist')
in c._binwifi_commands)
if __name__ == '__main__':
wvtest.wvtest_main()