When using mutual authentication an additional value needs to
be hashed when deriving i/r_auth values. A NULL value indicates
no mutual authentication (zero length iovec is passed to hash).
DPP configurators are running the majority of the protocol on the
current operating channel, meaning no ROC work. The retry logic
was bailing out if !dpp->roc_started with the assumption that DPP
was in between requesting offchannel work and it actually starting.
For configurators, this may not be the case. The offchannel ID also
needs to be checked, and if no work is scheduled we can send the
frame.
The prf_plus API was a bit restrictive because it only took a
string label which isn't compatible with some specs (e.g. DPP
inputs to HKDF-Expand). In addition it took additional label
aruments which were appended to the HMAC call (and the
non-intuitive '\0' if there were extra arguments).
Instead the label argument has been removed and callers can pass
it in through va_args. This also lets the caller decided the length
and can include the '\0' or not, dependent on the spec the caller
is following.
Adds a handler for the HE capabilities element and reworks the way
the MCS/NSS support bits are printed.
Now if the MCS support is 3 (unsupported) it won't be printed. This
makes the logs a bit shorter to read.
Matched the printed function name with the actual function name.
The simple-agent test prints the function name to allow easier debugging.
One name was not set currectly (most likely through copy pasting).
SAE was also relying on the ELL bug which was incorrectly performing
a subtraction on the Y coordinate based on the compressed point type.
Correct this and make the point type more clear (rather than
something like "is_odd + 2").
EAP-PWD was incorrectly computing the PWE but due to the also
incorrect logic in ELL the point converted correctly. This is
being fixed, so both places need the reverse logic.
Also added a big comment explaining why this is, and how
l_ecc_point_from_data behaves since its somewhat confusing since
EAP-PWD expects the pwd-seed to be compared to the actual Y
coordinate (which is handled automatically by ELL).
Add a test to show the incorrect ASN1 conversion to and from points.
This was due to the check if Y is odd/even being inverted which
incorrectly prefixes the X coordinate with the wrong byte.
The test itself was not fully correct because it was using compliant
points rather than full points, and the spec contains the entire
Y coordinate so the full point should be used.
This patch also adds ASN1 conversions to validate that
dpp_point_from_asn1 and dpp_point_to_asn1 work properly.
The previous attempt at working around this warning seems to no longer
work with gcc 13
In function ‘eap_handle_response’,
inlined from ‘eap_rx_packet’ at src/eap.c:570:3:
src/eap.c:421:49: error: ‘vendor_id’ may be used uninitialized [-Werror=maybe-uninitialized]
421 | (type == EAP_TYPE_EXPANDED && vendor_id == (id) && vendor_type == (t))
| ~~~~~~~~~~^~~~~~~
src/eap.c:533:20: note: in expansion of macro ‘IS_EXPANDED_RESPONSE’
533 | } else if (IS_EXPANDED_RESPONSE(our_vendor_id, our_vendor_type))
| ^~~~~~~~~~~~~~~~~~~~
src/eap.c: In function ‘eap_rx_packet’:
src/eap.c:431:18: note: ‘vendor_id’ was declared here
431 | uint32_t vendor_id;
| ^~~~~~~~~
width must be initialized since it depends on best not being NULL. If
best passes the non-NULL check above, then width must be initialized
since both width and best are set at the same time.
For IWD to work correctly either 2.4GHz or 5GHz bands must be enabled
(even for 6GHz to work). Check this and don't allow IWD to initialize
if both 2.4 and 5GHz is disabled.
wiphy_get_allowed_freqs was only being used to see if 6GHz was disabled
or not. This is expensive and requires several allocations when there
already exists wiphy_is_band_disabled(). The prior patch modified
wiphy_is_band_disabled() to return -ENOTSUP which allows scan.c to
completely remove the need for wiphy_get_allowed_freqs.
scan_wiphy_watch was also slightly re-ordered to avoid allocating
freqs_6ghz if the scan request was being completed.
The function wiphy_band_is_disabled() return was a bit misleading
because if the band was not supported it would return true which
could be misunderstood as the band is supported, but disabled.
There was only one call site and because of this behavior
wiphy_band_is_disabled needed to be paired with checking if the
band was supported.
To be more descriptive to the caller, wiphy_band_is_disabled() now
returns an int and if the band isn't supported -ENOTSUP will be
returned, otherwise 1 is returned if the band is disabled and 0
otherwise.
This adds support to allow users to disable entire bands, preventing
scanning and connecting on those frequencies. If the
[Rank].BandModifier* options are set to 0.0 it will imply those
bands should not be used for scanning, connecting or roaming. This
now applies to autoconnect, quick, hidden, roam, and dbus scans.
This is a station only feature meaning other modules like RRM, DPP,
WSC or P2P may still utilize those bands. Trying to limit bands in
those modules may sometimes conflict with the spec which is why it
was not added there. In addition modules like DPP/WSC are only used
in limited capacity for connecting so there is little benefit gained
to disallowing those bands.
To support user-disabled bands periodic scans need to specify a
frequency list filtered by any bands that are disabled. This was
needed in scan.c since periodic scans don't provide a frequency
list in the scan request.
If no bands are disabled the allowed freqs API should still
result in the same scan behavior as if a frequency list is left
out i.e. IWD just filters the frequencies as opposed to the kernel.
Currently the only way a scan can be split is if the request does
not specify any frequencies, implying the request should scan the
entire spectrum. This allows the scan logic to issue an extra
request if 6GHz becomes available during the 2.4 or 5GHz scans.
This restriction was somewhat arbitrary and done to let periodic
scans pick up 6GHz APs through a single scan request.
But now with the addition of allowing user-disabled bands
periodic scans will need to specify a frequency list in case a
given band has been disabled. This will break the scan splitting
code which is why this prep work is being done.
The main difference now is the original scan frequencies are
tracked with the scan request. The reason for this is so if a
request comes in with a limited set of 6GHz frequences IWD won't
end up scanning the full 6GHz spectrum later on.
This is more or less copied from scan_get_allowed_freqs but is
going to be needed by station (basically just saves the need for
station to do the same clone/constrain sequence itself).
One slight alteration is now a band mask can be passed in which
provides more flexibility for additional filtering.
This exposes the [Rank].BandModifier* settings so other modules
can use then. Doing this will allow user-disabling of certain
bands by setting these modifier values to 0.0.
The loop iterating the frequency attributes list was not including
the entire channel set since it was stopping at i < band->freqs_len.
The freq_attrs array is allocated to include the last channel:
band->freq_attrs = l_new(struct band_freq_attrs, num_channels + 1);
band->freqs_len = num_channels;
So instead the for loop should use i <= band->freqs_len. (I also
changed this to start the loop at 1 since channel zero is invalid).
The auth/action status is now tracked in ft.c. If an AP rejects the
FT attempt with "Invalid PMKID" we can now assume this AP is either
mis-configured for FT or is lagging behind getting the proper keys
from neighboring APs (e.g. was just rebooted).
If we see this condition IWD can now fall back to reassociation in
an attempt to still roam to the best candidate. The fallback decision
is still rank based: if a BSS fails FT it is marked as such, its
ranking is reset removing the FT factor and it is inserted back
into the queue.
The motivation behind this isn't necessarily to always force a roam,
but instead to handle two cases where IWD can either make a bad roam
decision or get 'stuck' and never roam:
1. If there is one good roam candidate and other bad ones. For
example say BSS A is experiencing this FT key pull issue:
Current BSS: -85dbm
BSS A: -55dbm
BSS B: -80dbm
The current logic would fail A, and roam to B. In this case
reassociation would have likely succeeded so it makes more sense
to reassociate to A as a fallback.
2. If there is only one candidate, but its failing FT. IWD will
never try anything other than FT and repeatedly fail.
Both of the above have been seen on real network deployments and
result in either poor performance (1) or eventually lead to a full
disconnect due to never roaming (2).
Certain return codes, though failures, can indicate that the AP is
just confused or booting up and treating it as a full failure may
not be the best route.
For example in some production deployments if an AP is rebooted it
may take some time for neighboring APs to exchange keys for
current associations. If a client roams during that time it will
reject saying the PMKID is invalid.
Use the ft_associate call return to communicate the status (if any)
that was in the auth/action response. If there was a parsing error
or no response -ENOENT is still returned.
In many tests the hostapd configuration does not include all the
values that a test uses. Its expected that each individual test
will add the values required. In many cases its required each test
slightly alter the configuration for each change every other test
has to set the value back to either a default or its own setting.
This results in a ton of duplicated code mainly setting things
back to defaults.
To help with this problem the hostapd configuration is read in
initially and stored as the default. Tests can then simply call
.default() to set everything back. This significantly reduces or
completely removes a ton of set_value() calls.
This does require that each hostapd configuration file includes all
values any of the subtests will set, which is a small price for the
convenience.
Removed several debug prints which are very verbose and provide
little to no important information.
The get_scan_{done,callback} prints are pointless since all the
parsed scan results are printed by station anyways.
Printing the BSS load is also not that useful since it doesn't
include the BSSID. If anything the BSS load should be included
when station prints out each individual BSS (along with frequency,
rank, etc).
The advertisement protocol print was just just left in there by
accident when debugging, and also provides basically no useful
information.
Some APs don't include the RSNE in the associate reply during
the OWE exchange. This causes IWD to be incompatible since it has
a hard requirement on the AKM being included.
This relaxes the requirement for the AKM and instead warns if it
is not included.
Below is an example of an association reply without the RSN element
IEEE 802.11 Association Response, Flags: ........
Type/Subtype: Association Response (0x0001)
Frame Control Field: 0x1000
.000 0000 0011 1100 = Duration: 60 microseconds
Receiver address: 64:c4:03:88:ff:26
Destination address: 64:c4:03:88:ff:26
Transmitter address: fc:34:97:2b:1b:48
Source address: fc:34:97:2b:1b:48
BSS Id: fc:34:97:2b:1b:48
.... .... .... 0000 = Fragment number: 0
0001 1100 1000 .... = Sequence number: 456
IEEE 802.11 wireless LAN
Fixed parameters (6 bytes)
Tagged parameters (196 bytes)
Tag: Supported Rates 6(B), 9, 12(B), 18, 24(B), 36, 48, 54, [Mbit/sec]
Tag: RM Enabled Capabilities (5 octets)
Tag: Extended Capabilities (11 octets)
Ext Tag: HE Capabilities (IEEE Std 802.11ax/D3.0)
Ext Tag: HE Operation (IEEE Std 802.11ax/D3.0)
Ext Tag: MU EDCA Parameter Set
Ext Tag: HE 6GHz Band Capabilities
Ext Tag: OWE Diffie-Hellman Parameter
Tag Number: Element ID Extension (255)
Ext Tag length: 51
Ext Tag Number: OWE Diffie-Hellman Parameter (32)
Group: 384-bit random ECP group (20)
Public Key: 14ba9d8abeb2ecd5d95e6c12491b16489d1bcc303e7a7fbd…
Tag: Vendor Specific: Broadcom
Tag: Vendor Specific: Microsoft Corp.: WMM/WME: Parameter Element
Reported-By: Wen Gong <quic_wgong@quicinc.com>
Tested-By: Wen Gong <quic_wgong@quicinc.com>
Handling these events notifies hwsim of address changes for interface
creation/removal outside the initial namespace as well as address
changes due to scanning address randomization.
Interfaces that hwsim already knows about are still handled via
nl80211. But any interfaces not known when ADD/DEL_MAC_ADDR events
come will be treated specially.
For ADD, a dummy interface object will be created and added to the
queue. This lets the frame processing match the destination address
correctly. This can happen both for scan randomization and interface
creation outside of the initial namespace.
For the DEL event we handle similarly and don't touch any interfaces
found via nl80211 (i.e. have a 'name') but need to also be careful
with the dummy interfaces that were created outside the initial
namespace. We want to keep these around but scanning MAC changes can
also delete them. This is why a reference count was added so scanning
doesn't cause a removal.
For example, the following sequence:
ADD_MAC_ADDR (interface creation)
ADD_MAC_ADDR (scanning started)
DEL_MAC_ADDR (scanning done)