This repository is part of the P4wnP1 project and holds pre-compiled Nexmon binaries. The binaries are build for Raspbian Stretch with Kernel 4.9.51+
.
Nexmon by @seemoo-lab (NexMon Team) is licensed under GNU General Public License v3.0. The sources used to compile could be found here:
~ https://github.com/seemoo-lab/nexmon/tree/934c7066819913687742aba217a1d75b98c1d883 ~
https://github.com/mame82/nexmon/tree/bcm43430a1_KARMA
Custom source is used, till merged into nexmon main RePo. This adds in KARMA attack + AP support while having a monitor interface up.
By default the firmware / driver runs with monitor interface disable. To bring it up use:
iw phyN interface add mon0 type monitor; ifconfig mon0 up
where phyN
has to be replaced by the name of the physical interface, which for example is shown by the following command:
iw list
Under normal circumstances it should be phy0
Having the monitor + injection capable interface up, means tools like airodump-ng or aireplay-ng could be used.
P4wnP1 is licensed GNU General Public License v3.0, source code is here: https://github.com/mame82/P4wnP1
In current firmware version the ioctls have been changed. This means instead of nexutil, it is recommend
to use the code of karmatool.py
to change the KARMA settings. The advantage is: every firmware option could
be changed, while a hostapd Access Point is running (and only if hostapd is running).
This allows adding custom SSIDs, enable KARMA beaconing a.k.a MANA_LOUD or disable everything ON-DEMAND !
The docs get updated on this, as soon as the firmware mod is done.
To allow AP mode with hostapd, the monitor interface has to be brought up (steps described above) before hostapd is started.
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Under normal circumstances the driver/firmware of a WiFi interface only communicates data frames to the userland. This excludes management and control frames. But to deal with stations trying to connect to an access point, hostapd needs to receive and send these management and control frames. This is because AP beacons, probe requests, authentication requests, association requests and others are transmitted as management frames. To solve this problem hostapd uses a monitor interface which is able to send and receive raw 802.11 (a.k.a frame injection + monitor capability, to be more precise - radiotap headers are needed, too). This again means, a WiFi interface working with hostapd has to provide a monitor/injection interface along with a second interface which supports AP mode.
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For the other operation mode, hostapd doesn't need a dedicate monitor/ injection interface in addition to the needed AP interface (note: we are talking about multiple virtual interfaces on a single physical interface). Instead the interface firmware/driver handles the station management and communicates relevant events via callbacks to hostapd.
I "mode 1" hostapd receives an association request as management frame from the virtual monitor interface. If the station is allowed to associate, a management frame with an asociation response is sent back via the same virtual interface (injection). Hostapd is now able to handle the associated station in its internal data structures and communication is done via the second virtual interface, which works in AP mode instead of monitor mode.
In "mode 2" the association frame is handled in the firmware of the WiFi interface and hostapd is informed about the association via an event.
When hostapd is started, the following thing happen:
Step 1: Check if WiFi interface supports Full Station Management in hardware ("mode 2"). If yes, bring up the AP in this mode else continue with next step!
Step 2: Try to bring up a monitor interface. If it works, bring up the AP in "mode 1", else continue with next step.
Step 3: If neither one worked, fail over to "mode 2", bring up the AP and try to let the hardware handle the station management, although the interface reported that it doesn't support this mode of operation.
Now, the legacy firmware for the BCM43430a1 handles Station Management in hardware, but doesn't report this capability. This again means, that hostapd runs through all 3 steps described above and ends up in the failover for "mode 2".
The important part is, that the legacy driver reports "Erro Operation not supported", when hostapd tries to bring up the monitor interface in step 2. This again leads to the failover and everything works as intended.
With the "monitor enabled" patched nexmon firmware, this of course changes. Now hostapd is able to bring up the monitor interface and tries to work in "mode 1". This works for communication of probe request/response and authentication frames, but when it comes to association (which hostapd tries to handle internally and inform the driver about its doings) it fails, because the firmware isn't aware of the station which tries to associate (because the firmware hasn't handle probing and authentication itself). This ultimately results in a disassociation, send by the firmware. This again means, no station could connect to the spawned AP.
To overcome this issue, the brcmfmac driver has been modified in a manner to report "error operation not supported" if the userland part tries to add a monitor interface, but there's already a monitor interface up. This exactly mimics the behavior of the umodified driver/firmware and leads to the failover step 3 described above. So the only thing which has to be done in order to make hostapd work, is to bring up a monitor interface before starting hostapd. The nice thing about this, is that the monitor interface could be used, while the AP is up and running. There's one logical restriction with that: The channel of course couldn't be changed, hwen the AP is up.
To make KARMA work the following steps have to be done:
- Install the provided firmware
brcmfmac43430-sdio.bin
and driverbrcmfmac.ko
- Bring up a monitor interface and afterwards a hostapd based OPEN access point (steps describe above)
- Run
karmatool.py
to change the firmware configuration (including KARMA, custom SSIDs etc) as needed while the AP is running
To simply enable KARMA use karmatool.py -k 1
Usage: python karmatool.py [Arguments]
Arguments:
-h Print this help screen
-i Interactive mode
-d Load default configuration (KARMA on, KARMA beaconing off,
beaconing for 13 common SSIDs on, custom SSIDs never expire)
-c Print current KARMA firmware configuration
-p 0/1 Disable/Enable KARMA probe responses
-a 0/1 Disable/Enable KARMA association responses
-k 0/1 Disable/Enable KARMA association responses and probe responses
(overrides -p and -a)
-b 0/1 Disable/Enable KARMA beaconing (broadcasts up to 20 SSIDs
spotted in probe requests as beacon)
-s 0/1 Disable/Enable custom SSID beaconing (broadcasts up to 20 SSIDs
which have been added by the user with '--addssid=' when enabled)
--addssid="test" Add SSID "test" to custom SSID list (max 20 SSIDs)
--remssid="test" Remove SSID "test" from custom SSID list
--clearssids Clear list of custom SSIDs
--clearkarma Clear list of karma SSIDs (only influences beaconing, not probes)
--autoremkarma=600 Auto remove KARMA SSIDs from beaconing list after sending 600 beacons
without receiving an association (about 60 seconds, 0 = beacon forever)
--autoremcustom=3000 Auto remove custom SSIDs from beaconing list after sending 3000
beacons without receiving an association (about 5 minutes, 0 = beacon
forever)
Example:
python karmatool.py -k 1 -b 0 Enables KARMA (probe and association responses)
But sends no beacons for SSIDs from received probes
python karmatool.py -k 1 -b 0 Enables KARMA (probe and association responses)
and sends beacons for SSIDs from received probes
(max 20 SSIDs, if autoremove isn't enabled)
python karmatool.py --addssid="test 1" --addssid="test 2" -s 1
Add SSID "test 1" and "test 2" and enable beaconing for
custom SSIDs
If everything works, every probe request for a former unknwon network should be respond properbly and the client is magically allowed to connect to the AP (which effectively doesn't exist).
Of course the AP hasn't got to use "Open Authentication System", but this attacks doesn't make to much sense with an AP forcing authentication.
The initial idea was to use hostapd-mana by Sensepost (greetings to Dominic, who would have allowed to use a precompiled version). Unfortunately this didn't work out. The reason is partially deascribe above: hostapd couldn't work in the operation mode, where it uses a dedicated monitor interface for station handling. But, the KARMA patches of hostapd use exactly this monitor interface (with injection capabilities) to carry out the attack, which couldn't be made available to hostapd with the bcm43430a1 firmware.
There have been two options to overcome this:
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Modify the complete driver/firmware stack of BCM43430a1 to emulate the behavior of a WiFi interface which handles Station Management in software ("emulation" is the wrong word, as in fact one needs to implement station management in software).
-
Reverse the Firmware, use nexmon framework to modify it and let the hardware do the job.
To make a long story short (and avoid more TL;TR), option 2 was chosen. You find the result in this repo as precompiled firmware + driver. Everything is highly experimental, not widely tested and undergoing changes (especially when it comes to debug output to the chips internal console).
~ ~There are some ToDo's, like allow beaconing for seen probes (the mana_loud
option in hostapd-mana).
For now only probe responses for seen requests are transmitted (and of course association is handled correctly). As this is a firmware patch, everything runs in hardware and thus - let's say - a bit faster than with hostapd-mana: Probe requests are responded immediately (at least when I get rid of the throttling debug prints to the internal console).
The main ToDo is to integrate everything into P4wnP1.~ ~
Current version allows sending beacons for seen probes (KARMA LOUD). Additionally custom SSIDs could be added for beaconing and both, karma and custom SSIDs, could automatically be removed if no association request is received (user defined timeout).
Custom and KARMA SSIDs for beaoning are limited to 20, each. Probe and association responses are send back without such a limit.
In case somebody is working on a similar project, I'd be happy to see a mod where the chip could be used to run in station mode and KARMA-enabled AP mode at the same time. Why ? Because this would allow to use a single chip for an upstream WiFi internet connection, while a KARMA Access Point is running ... and hey, maybe it could be ported to Mobile Phones ;-)