If the AP advertises FT-over-DS support it likely wants us to use
it. Additionally signal_low is probably going to be true since IWD
has started a roam attempt.
When netdev goes down so does station, but prior to netdev calling
the neighbor report callback. The way the logic was written station
is dereferenced prior to checking for any errors, causing a use
after free.
Since -ENODEV is used in this case check for that early before
accessing station.
This adds a utility to convert a chandef obtained from the kernel into a
3 byte OCI element format containing the operating class, primary
channel and secondary channel center frequency index.
This changes scan_bss from using separate members for each
OWE transition element data type (ssid, ssid_len, and bssid)
to a structure that holds them all.
This is being done because OWE transition has option operating
class and channel bytes which will soon be parsed. This would
end up needing 5 separate members in scan_bss which is a bit
much for a single IE that needs to be parsed.
This makes checking the presense of the IE more convenient
as well since it can be done with a simple NULL pointer check
rather than having to l_memeqzero the BSSID.
These members are currently stored in scan_bss but with the
addition of operating class/band info this will become 5
separate members. This is a bit excessive to store in scan_bss
separately so instead this structure can hold everything related
to the OWE transition IE.
Add a utility for setting the OCI obtained from the hardware (prior to
handshake starting) as well as a utility to validate the OCI obtained
from the peer.
This adds a utility that can convert an operating class + channel
combination to a frequency. Operating class is assumed to be a global
operating class from 802.11 Appendix E4.
This information can be found in Operating Channel Information (OCI) IEs,
as well as OWE Transition Mode IEs.
Calling handshake_state_setup_own_ciphers from within
handshate_state_set_authenticator_ie was misleading. In all cases the
supplicant chooses the AKM. This worked since our AP code only ever
advertises a single AKM, but would not work in the general case.
Similarly, the supplicant would choose which authentication type to use
by either sending the WPA1 or WPA2 IE (or OSEN). Thus the setting of
the related variables in handshake_state_set_authenticator_ie was also
incorrect. In iwd, the supplicant_ie would be set after the
authenticator_ie, so these settings would be overwritten in most cases.
Refactor these two setters so that the supplicant's chosen rsn_info
would be used to drive the handshake.
reallocarray has been added to glibc relatively recently (version 2.26,
from 2017) and apparently not all users run new enough glibc. Moreover,
reallocarray is not available with uclibc-ng. So use realloc if
reallocarray is not available to avoid the following build failure
raised since commit 891b78e9e8:
/home/giuliobenetti/autobuild/run/instance-3/output-1/host/lib/gcc/xtensa-buildroot-linux-uclibc/10.3.0/../../../../xtensa-buildroot-linux-uclibc/bin/ld: src/sae.o: in function `sae_rx_authenticate':
sae.c:(.text+0xd74): undefined reference to `reallocarray'
Fixes:
- http://autobuild.buildroot.org/results/c6d3f86282c44645b4f1c61882dc63ccfc8eb35a
There isn't much control station has with how BSS's are inserted to
a network object. The rank algorithm makes that decision. Because of
this we could end up in a situation where the Open BSS is preferred
over the OWE transition BSS.
In attempt to better handle this any Open BSS in this type of network
will not be chosen unless its the only candidate (e.g. no other BSSs,
inability to connect with OWE, or an improperly configured network).
OWE Transition is described in the WiFi Alliance OWE Specification
version 1.1. The idea behind it is to support both legacy devices
without any concept of OWE as well as modern ones which support the
OWE protocol.
OWE is a somewhat special type of network. Where it advertises an
RSN element but is still "open". This apparently confuses older
devices so the OWE transition procedure was created.
The idea is simple: have two BSS's, one open, and one as a hidden
OWE network. Each network advertises a vendor IE which points to the
other. A device sees the open network and can connect (legacy) or
parse the IE, scan for the hidden OWE network, and connect to that
instead.
Care was taken to handle connections to hidden networks directly.
The policy is being set that any hidden network with the WFA OWE IE
is not connectable via ConnectHiddenNetwork(). These networks are
special, and can only be connected to via the network object for
the paired open network.
When scan results come in from any source (DBus, quick, autoconnect)
each BSS is checked for the OWE Transition IE. A few paths can be
taken here when the IE is found:
1. The BSS is open. The BSSID in the IE is checked against the
current scan results (excluding hidden networks). If a match is
found we should already have the hidden OWE BSS and nothing
else needs to be done (3).
2. The BSS is open. The BSSID in the IE is not found in the
current scan results, and the open network also has no OWE BSS
in it. This will be processed after scan results.
3. The BSS is not open and contains the OWE IE. This BSS will
automatically get added to the network object and nothing else
needs to be done.
After the scan results each network is checked for any non-paired
open BSS's. If found a scan is started for these BSS's per-network.
Once these scan results come in the network is notified.
From here network.c can detect that this is an OWE transition
network and connect to the OWE BSS rather than the open one.
Specifically OWE networks with multiple open/hidden BSS's are troublesome
to scan for with the current APIs. The scan parameters are limited to a
single SSID and even if that was changed we have the potential of hitting
the max SSID's per scan limit. In all, it puts the burden onto the caller
to sort out the SSIDs/frequencies to scan for.
Rather than requiring station to handle this a new scan API was added,
scan_owe_hidden() which takes a list of open BSS's and will automatically
scan for the SSIDs in the OWE transition IE for each.
It is slightly optimized to first check if all the hidden SSID's are the
same. This is the most likely case (e.g. single pair or single network)
and a single scan command can be used. Otherwise individual scan commands
are queued for each SSID/frequency combo.
handshake_util_ap_ie_matches() is used to make sure that the RSN element
received from the Authenticator during handshake / association response
is the same as the one advertised in Beacon/Probe Response frames. This
utility tries to bitwise compare the element first, and only if that
fails, compares RSN members individually.
For FT, bitwise comparison will always fail since the PMKID has to be
included by the Authenticator in any RSN IEs included in Authenticate
& Association Response frames.
Perform the bitwise comparison as an optimization only during processing
of eapol message 3/4. Also keep the parsed rsn information for future
use and to possibly avoid re-parsing it during later checks.
DBus scan is performed in several subsets. In certain corner-case
circumstances it would be possible for autoconnect to run after each
subset scan. Instead, trigger autoconnect only after the dbus scan
completes.
This also works around a condition where ANQP results could trigger
autoconnect too early.
Several invocations of station_set_scan_results() base the
'add_to_autoconnect' parameter on station_is_autoconnecting(). Simplify
the code by having station_set_scan_results() invoke that itself.
'add_to_autoconnect' now becomes an 'intent' parameter, specifying
whether autoconnect path should be invoked as a result of these scan
results or not when station is in an appropriate state. Rename
'add_to_autoconnect' parameter to make this clearer.
If the frequency of the bss is not in the list of frequencies for the
current scan, then this is a cached bss. It was likely already
processed for ANQP before, so skip it.
IWD has restricted SSIDs to only utf8 so they can be displayed but
with the addition of OWE transition networks this is an unneeded
restriction (for these networks). The SSID of an OWE transition
network is never displayed to the user so limiting to utf8 isn't
required.
Allow non-utf8 SSIDs to be scanned for by including the length in
the scan parameters and not relying on strlen().
This is a parser for the WFA OWE Transition element. For now the
optional band/channel bytes will not be parsed as hostapd does not
yet support these and would also require the 802.11 appendix E-1
to be added to IWD. Because of this OWE Transition networks are
assumed to be on the same channel as their open counterpart.
in6_addr.__in6_u.__u6_addr8 is glibc-specific and named differently in
the headers shipped with musl libc for example. The POSIX compliant and
universal way of accessing it is in6_addr.s6_addr.
This was actually broken if triggered because __network_connect
checks if network->connect_after_owe_hidden is set and returns
already in progress. We want to keep this behavior though for
obvious reasons.
To fix this station_connect_network can be called directly which
bypasses the check. This is essentially how ANQP avoids this
problem as well.
Similar to ANQP a connect call could come in while station is
scanning for OWE hidden networks. This is supported in the same
manor by saving away the dbus message and resuming the connection
after the hidden OWE scan.
With the addition of OWE transition network needs to be notified
of the hidden OWE scan which is quite similar to how it is notified
of ANQP. The ANQP event watch can be made generic and reused to
allow other events besides ANQP.
This is being added to support OWE transition mode. For these
type of networks the OWE BSS may contain a different SSID than
that of the network, but the WFA spec requires this be hidden
from the user. This means we need to set the handshake SSID based
on the BSS rather than the network object.