The AP mode device APIs were hacked together and only able to start
stop an AP. Now that the AP interface has more functionality its
best to use the DBus class template to access the full AP interface
capabilities.
The disabled cipher list contained a '.' instead of ',' which prevented
the subsequent ciphers from being disabled. This was only group management
ciphers so it didn't have any effect on the test.
The __str__ function assumed station mode which throws an exception
if the device is in AP mode. Fix this as well as print out the mode
the device is in.
This API optimizes scanning to run tests quickly by only scanning
the frequencies which hostapd is using. But if a test doesn't use
hostapd this API raises an uncaught exception.
Check if hostapd is being used, and if not just do a full scan.
This test was taking about 5 minutes to run, specifically
the requested scan test. One slight optimization is to
remove the duplicate hidden network, since there is no
need for two. In addition the requested scan test was
changed so it does not periodic scan and only issues a dbus
scan.
The CI was sometimes taking ~10-15 minutes to run just this
test. This is likely due to the test having 7 radios and
which is a lot of beacons/probes to process.
Disabling the unused hostapd instances drops the runtime down
to about 1 minute.
This tests the new behavior where the roam request does not
indicate disassociation is imminent. In this case if no
candidates are found IWD should not roam.
Instead of requiring the initial condition be met when calling
wait_for_object_change, wait for it.
This is how every caller of this function uses it, specifically
with roaming where we first wait for DeviceState.roaming, then
call wait_for_object_change. This can be simplified for the caller
so the initial condition is first waited for.
The hostapd events for RRM come regardless of success
so they need to be checked as such. In addition one more
RRM request was added to scan on a frequency which is
disabled (operating class 82, channel 14).
Previously we had an ACD failure scenario where a new client forces its
IP to create an IP conflict and an already-connected client detects the
conflict and reacts. Now first test a scenario where a newly connecting
IWD client runs ACD before setting its statically configured IP, detects
a conflict and refuses to continue, then run the second scenario where
the newly connecting DHCP-configured client ignores the conflict and
starts ACD in defend-indefinitely mode and the older client in
defent-once mode gives up its IP.
Due to those variables being global (IWD class variables) calling either
unregister_psk_agent or del on one IWD class instance would unregister
all agents on all instances. Move .psk_agents and two other class
variables to the object. They were already referenced using "self."
as if they were object variables throughout the class.
Part of static_test.py starts a second IWD instance and tries to make
it connect to the AP with the same IP address as the first IWD instance
which is already connected, to produce an IP conflict. For this, the
second instance uses DHCP and the test expects the DHCP server to offer
the address 192.168.1.10 to it. However in the current setup the DHCP
server manages to detect that 192.168.1.10 is in use and offers .11
instead. Break the DHCP server's conflict detection by disabling ICMP
ping replies in order to fix the test.
Previously this has worked because the AP's and the DHCP server's
network interface is in the same network namespace as the first IWD
instance's network interface meaning that pings between the two
interfaces shouldn't work (a known Linux kernel routing quirk...).
I am not sure why those pings currently do work but take no chances and
disable ICMP pings.
This adds a few utilities for setting up an FT environment. All the
roaming tests basically copy/paste the same code for setting up the
hostapd instances and this can cause problems if not done correctly.
set_address() sets the MAC address on the device, and restarts hostapd
group_neighbors() takes a list of HostapdCLI objects and makes each a
neighbor to the others.
The neighbor report element requires the operating class which isn't
advertised by hostapd. For this we assume operating class 81 but this
can be set explicitly if it differs. Currently no roaming tests use
5/6GHz frequencies, and just in case an exception will be thrown if
the channel is greater than 14 and the op_class didn't change.
The packet loss test had a few problems. First being that the RSSI for
the original BSS was not low enough to change the rank. This meant any
roam was just lucky that the intended BSS was first in the results.
The second problem is timing related, and only happens on UML. Disabling
the rules after the roaming condition sometimes allows IWD to fully
roam and connect before the next state change checks.
A new test which blocks all data frames once connected, then tries
to send 100 packets. This should result in the kernel sending a
packet loss event to userspace, which IWD should react to and roam.
Test that the DHCPv4 lease got renewed after the T1 timer runs out.
Then also simulate the DHCPREQUEST during renew being lost and
retransmitted and the lease eventually getting renewed T1 + 60s later.
The main downside is that this test will inevitably take a while if
running in Qemu without the time travel ability.
Update the test and some utility code to run hostapd in an isolated net
namespace for connection_test.py. We now need a second hostapd
instance though because in static_test.py we test ACD and we need to
produce an IP conflict. Moving the hostapd instance unexpectedly fixes
dhcpd's internal mechanism to avoid IP conflicts and it would no longer
assign 192.168.1.10 to the second client, it'd notice that address was
already in use and assign the next free address, or fail if there was
none. So add a second hostapd instance that runs in the main namespace
together with the statically-configured client, it turns out the test
relies on the kernel being unable to deliver IP traffic to interfaces on
the same system.
testAgent had a few tests which weren't reliable, and one was not
actually testing anything, or at least not what the name implied it
should be testing.
The first issue was using iwctl in the first place. There is not a
reliable way to know when iwctl has registered its agent so relying on
that with a sleep, or waiting for the service to become available isn't
100% fool proof. To fix this use the updated PSKAgent which allows
multiple to be registered. This ensures the agent is ready for requests.
This test was also renamed to be consistent with what its actually
testing: that IWD uses the first agent registered.
This removes test_connection_with_other_agent as well because this test
case is covered by the client test itself. There is no need to re-test
iwctl's agent functionality here.
By creating a new bus connection for each agent we can register multiple
with IWD. This did mean the agent interface needs to be unique for each
agent (removing _agent_manager_if) as well as tracking multiple agents
in a list.
The test here is verifying that a DBus Connect() call will still
work with 'other' agents registered. In this case it uses iwctl to
set a password, then call Connect() manually.
The problem here is that we have no way of knowing when iwctl fully
starts and registers its agent. There was a sleep in there but that
is unreliable and we occationally were still getting past that without
iwctl having started fully.
To fix this properly we need to wait for iwctl's agent service to appear
on the bus. Since the bus name is unknown we must first find all names,
then cross reference their PID's against the iwctl PID. This is done
using ListNames, and GetConnectionUnixProcessID APIs.
The rekey/reauth logic was broken in a few different ways.
For rekeys the event list was not being reset so any past 4-way
handshake would allow the call to pass. This actually removes
the need for the sleep in the extended key ID test because the
actual handshake event is waited for correctly.
For both rekeys and reauths, just waiting for the EAP/handshake
events was not enough. Without checking if the client got
disconnected we essentially allow a full disconnect and reconnect,
meaning the rekey/reauth failed.
Now a 'disallow' array can be passed to wait_for_event which will
throw an exception if any events in that array are encountered
while waiting for the target event.
Yet another weird UML quirk. The intent of this tests was to ensure
the profile gets encrypted, and to check this both the mtime and
contents of the profile were checked.
But under UML the profile is copied, IWD started, and the profile
is encrypted all without any time passing. The (same) mtime was
then updated without any changes which fails the mtime check.
This puts a sleep after copying the profile to ensure the system
time differs once IWD encrypts the profile.
In UML if any process dies while test-runner is waiting for the DBus
service or some socket to be available it will block forever. This
is due to the way the non_block_wait works.
Its not optimal but it essentially polls over some input function
until the conditions are met. And, depending on the input function,
this can cause UML to hang since it never has a chance to go idle
and advance the time clock.
This can be fixed, at least for services/sockets, by sleeping in
the input function allowing time to pass. This will then allow
test-runner to bail out with an exception.
This patch adds a new wait_for_service function which handles this
automatically, and wait_for_socket was refactored to behave
similarly.
test_decryption_failure is quite simple and only verifies that a known
network exists after starting. This causes the test to end before IWD can
fully start up leaving the DBus utilities in limbo having not fully
initialized.
Then, on the next test, stale InterfaceAdded signals arrive (for Station
and P2P) which throw exceptions when trying to get the bus (since IWD is
long gone). In addition the next IWD instance has started so any paths
included in the InterfaceAdded signals are bogus and cause additional
exceptions.
At the end of this test we can call list_devices() which will wait for
the InterfaceAdded signal, and cleanly exit afterwards.