This adds a builder which sets the country IE in probes/beacons.
The IE will use the 'single subband triplet sequence' meaning
dot11OperatingClassesRequired is false. This is much easier to
build and doesn't require knowing an operating class.
The IE itself is variable in length and potentially could grow
large if the hardware has a weird configuration (many different
power levels or segmentation in supported channels) so the
overall builder was changed to take the length of the buffer and
warnings will be printed if any space issues are encountered.
IWD's channel/frequency conversions use simple math to convert and
have very minimal checks to ensure the input is valid. This can
lead to some channels/frequencies being calculated which are not
in IWD's E-4 table, specifically in the 5GHz band.
This is especially noticable using mac80211_hwsim which includes
some obscure high 5ghz frequencies which are not part of the 802.11
spec.
To fix this calculate the frequency or channel then iterate E-4
operating classes to check that the value actually matches a class.
The 6GHz test was not incrementing the frequencies properly which
was resulting in invalid frequencies, but since the conversion
API was never linked to E-4 the test was still passing.
The country IE can sometimes have a zero pad byte at the end for
alignment. This was not being checked for which caused the loop
to go past the end of the IE and print an entry for channel 0
(the pad byte) plus some garbage data.
Fix this by checking for the pad byte explicitly which skips the
print and terminates the loop.
If supported this will include the HT capabilities and HT
operations elements in beacons/probes. Some shortcuts were taken
here since not all the information is currently parsed from the
hardware. Namely the HT operation element does not include the
basic MCS set. Still, this will at least show stations that the
AP is capable of more than just basic rates.
The builders themselves are structured similar to the basic rates
builder where they build only the contents and return the length.
The caller must set the type/length manually. This is to support
the two use cases of using with an IE builder vs direct pointer.
To include HT support a chandef needs to be created for whatever
frequency is being used. This allows IWD to provide a secondary
channel to the kernel in the case of 40MHz operation. Now the AP
will generate a chandef when starting based on the channel set
in the user profile (or default).
If HT is not supported the chandef width is set to 20MHz no-HT,
otherwise band_freq_to_ht_chandef is used.
The WMM parameter IE is expected by the linux kernel for any AP
supporting HT/VHT etc. IWD won't actually use WMM and its not
clear exactly why the kernel uses this restriction, but regardless
it must be included to support HT.
For AP mode its convenient for IWD to choose an appropriate
channel definition rather than require the user provide very
low level parameters such as channel width, center1 frequency
etc. For now only HT is supported as VHT/HE etc. require
additional secondary channel frequencies.
The HT API tries to find an operating class using 40Mhz which
complies with any hardware restrictions. If an operating class is
found that is supported/not restricted it is marked as 'best' until
a better one is found. In this case 'better' is a larger channel
width. Since this is HT only 20mhz and 40mhz widths are checked.
This adds some additional parsing to obtain the AMPDU parameter
byte as well as wiphy_get_ht_capabilities() which returns the
complete IE (combining the 3 separate kernel attributes).
The supported rates IE was being built in two places. This makes that
code common. Unfortunately it needs to support both an ie builder
and using a pointer directly which is why it only builds the contents
of the IE and the caller must set the type/length.
Move the l_netconfig_set_route_priority() and
l_netconfig_set_optimistic_dad_enabled() calls from netconfig_new, which
is called once for the l_netconfig object's lifetime, to
netconfig_load_settings, which is called before every connection attempt.
This is needed because we clean up the l_netconfig configuration by calling
l_netconfig_reset_config() at different points in connection setup and
teardown so we'd reset the route priority that we've set in netconfig_new,
back to 0 and never reload it.
The disabled_freqs list is being removed and replaced with a new
list in the band object. This completely removes the need for
the pending_freqs list as well since any regdom related dumps
can just overwrite the existing frequency list.
This adds two new APIs:
wiphy_get_frequency_info(): Used to get information about a given
frequency such as disabled/no-IR. This can also be used to check
if the frequency is supported (NULL return is unsupported).
wiphy_band_is_disabled(): Checks if a band is disabled. Note that
an unsupported band will also return true. Checking support should
be done with wiphy_get_supported_bands()
As additional frequency info is needed it doesn't make sense to
store a full list of frequencies for every attribute (i.e.
supported, disabled, no-IR, etc).
This changes nl80211_parse_supported_frequencies to take a list
of frequency attributes where each index corresponds to a channel,
and each value can be filled with flag bits to signal any
limitations on that frequency.
wiphy.c then had to be updated to use this rather than the existing
scan_freq_set lists. This, as-is, will break anything using
wiphy_get_disabled_freqs().
Currently the wiphy object keeps track of supported and disabled
frequencies as two separate scan_freq_set's. This is very expensive
and limiting since we have to add more sets in order to track
additional frequency flags (no-IR, no-HT, no-HE etc).
Instead we can refactor how frequencies are stored. They will now
be part of the band object and stored as a list of flag structures
where each index corresponds to a channel
IWD was optimizing FT-over-DS by authenticating to multiple BSS's
at the time of connecting which then made future roams slightly
faster since they could jump right into association. So far this
hasn't posed a problem but it was reported that some AP's actually
enforce a reassociation timeout (included in 4-way handshake).
Hostapd itself does no such enforcement but anything external to
hostapd could monitor FT events and clear the cache if any exceeded
this timeout.
For now remove the early action frames and treat FT-over-DS the
same as FT-over-Air. In the future we could parse the reassociation
timeout, batch out FT-Action frames and track responses but for the
time being this just fix the issue at a small performance cost.
Queue the FT action just like we do with FT Authenticate which makes
it able to be used the same way, i.e. call ft_action() then queue
the ft_associate work right away.
A timer was added to end the work item in case the target never
responds.
If the regdom updates during a periodic scan the results will be
delayed until after the update in order to, potentially, add 6GHz
frequencies since they may become available. The delayed results
happen regardless of 6GHz support but scan_wiphy_watch() was
returning early if 6GHz was not supported causing the scan request
to never complete.
The blamed commit argues that the periodic scan callback doesn't do
anything useful in the event of an aborted scan, but this is not
entirely true. In particular, the callback is responsible for re-arming
the periodic scan timer. Make sure to call scan_finished() so that iwd's
periodic scanning logic continues unabated even when a periodic scan is
aborted.
Also remove the periodic boolean member of struct scan_request, as it
serves no purpose anymore.
Fixes: 6051a14952 ("scan: Don't callback on SCAN_ABORTED")
This enables IWD to use 5GHz frequencies in AP mode. Currently
6GHz is not supported so we can assume a [General].Channel value
36 or above indicates the 5GHz band.
It should be noted that the system will probably need a regulatory
domain set in order for 5GHz to be allowed in AP mode. This is due
to world roaming (00) restricting any/all 5GHz frequencies. This
can be accomplished by setting main.conf [General].Country=CC to
the country this AP will operate in.
wiphy_get_supported_rates expected an enum defined in the nl80211
header but the argument type was an unsigned int, not exactly
intuitive to anyone using the API. Since the nl80211 enum value
was only used in a switch statement it could just as well be IWD's
internal enum band_freq.
This also allows modules which do not reference nl80211.h to use
wiphy_get_supported_rates().
Before this change, I noticed that some non-interactive commands
don't work,
$ iwctl version
$ iwctl help
while other ones do.
$ iwctl station wlan0 show
This seems to be a typo bug in the if clause checking for additional
arguments.
This file is a compilation command database used by clangd and ccls,
and can be generated by tools like https://github.com/rizsotto/Bear.
$ bear -- make clean all
If a CMD_TRIGGER_SCAN request fails with -EBUSY, iwd currently assumes
that a scan is ongoing on the underlying wdev and will retry the same
command when that scan is complete. It gets notified of that completion
via the scan_notify() function, and kicks the scan logic to try again.
However, if there is another wdev on the same wiphy and that wdev has a
scan request in flight, the kernel will also return -EBUSY. In other
words, only one scan request per wiphy is permitted.
As an example, the brcmfmac driver can create an AP interface on the
same wiphy as the default station interface, and scans can be triggered
on that AP interface.
If -EBUSY is returned because another wdev is scanning, then iwd won't
know when it can retry the original trigger request because the relevant
netlink event will arrive on a different wdev. Indeed, if no scan
context exists for that other wdev, then scan_notify will return early
and the scan logic will stall indefinitely.
Instead, and in the event that no scan context matches, use it as a cue
to retry a pending scan request that happens to be destined for the same
wiphy.
The previous commit added an invocation of known_networks_watch_add, but
never updated the module dependency graph.
Fixes: a793a41662 ("station, eapol: Set up eap-tls-common for session caching")
Use eap_set_peer_id() to set a string identifying the TLS server,
currently the hex-encoded SSID of the network, to be used as group name
and primary key in the session cache l_settings object. Provide pointers
to storage_eap_tls_cache_{load,sync} to eap-tls-common.c using
eap_tls_set_session_cache_ops(). Listen to Known Network removed
signals and call eap_tls_forget_peer() to have any session related to
the network also dropped from the cache.