HackPi is a combination of Samy Kamkar's Poisontap and Responder (original idea by Mubix) on a Raspberry Pi Zero.
It exploits locked/password protected computers over USB, drops persistent WebSocket-based backdoor, exposes internal router, siphons cookies and snag NTLM hashed credentials.
It works automatically on Windows, Linux and MacOs without any user interaction (e.g. no manual driver installation).
git clone https://github.com/wismna/HackPi
sudo chmod +x install.sh
./install.sh
For troubleshooting network issues on Linux or MacOs (not Windows at this time, unfortunately), you should be able to connect to your Raspberry Pi via the serial interface and investigate the problems:
sudo screen /dev/ttyACM0 115200
The really simple way create a gadget on the Pi is to follow this guide and use g_ether
kernel module. However, g_ether
is a legacy module that definitely does not work on Windows. During all my tests, the gadget was systematically recognized as a COM3 device. I couldn't even force newer versions of Windows (10) to use an Ethernet driver. Also, it's impossible to emulate more than one device at the same time.
I then found with this great guide, which uses the libcomposite
kernel module. This is far more advanced as it allows precise configuration of the gadget, as well as giving the ability to emulate more than one device at the same time.
I created an Ethernet gadget adapter as well as the serial adapter in a single configuration. The serial adapter is very very useful, especially while testing the Ethernet configuration, as if you make a breaking change and can't ssh back to your Raspberry Pi Zero, you still can use the console:
sudo screen /dev/ttyACM0 115200
To make the Ethernet gadget work on Windows, I used a little trick. When Windows is communicating with the adapter, it will look in its .inf files for a matching driver based on idVendor and idProduct (as well as bcdDevice for revision). Knowing this, I used
echo 0x04b3 > idVendor
echo 0x4010 > idProduct
so that Windows would load its generic RNDIS driver netimm.inf. However, this still wouldn't work for me, even though it appeared to be working for other people. Windows would load the driver but fail to start the adapter with a code 10 error.
Browsing a bit (a lot...) I determined that Windows would only reliably work with a RNDIS configuration. So I added a new configuration designed to emulate the RNDIS function. This configuration had to be defined first for Windows to work. Linux and Mac (supposedly) are smart enough to ignore it and load the second one, the CDC ECM configuration. And lo and behold, it worked! Windows correctly loaded the driver and the adapter, with no manual intervention. Unfortunately it didn't work on Linux anymore... great.
I realized (thanks to the serial console) that each configfs configuration creates a new network interface (usb0, usb1 and so on). However, all the servers were listening exclusively on usb0, which was assigned to the RNDIS configuration. Linux ignored this configuration to load the CDC ECM one, where no servers (especially ISC-DHCP) were listening and no routes nor iptables rules were added.
The easy solution would have been to duplicate everything, but I decided instead to create a bridge interface, br0
, which would be the master of all usbX
interfaces. Then, I would make the servers listen on that interface, as well as add the routes and iptable rules.
After a bit of fiddling around, it worked!
My gadget was now automatically recognized by Windows and Linux, without having to change anything to the configuration files. Unfortunately (bis...) the gadget stopped working on MacOs, and this is because since version 10.11, it's no longer smart enough to load the CDC ECM configuration if it isn't the first one! I now needed a way to make the gadget recognize the host it was connected to via USB fingerprinting, so that I could better configure libcomposite
.
This is where the fun began. I had two big issues to overcome:
The first thing to do was to find a way to dump incoming USB traffic. The obvious answer was to use the usbmon
kernel module which allows tracing of USB data. Unfortunately, this doesn't work at all (no data is captured) when the USB controller is in device mode. But to create a USB gadget of any kind, the controller has to be set in device (or peripheral) mode. So no usbmon
, and by way of consequence, no tcpdump, wireshark or whatever else uses usbmon
traces.
For device mode to work on the Raspberry Pi Zero, we have to load a kernel module, dwc2
, which enables USB OTG (dynamic switching between host and device modes). I tried setting the module to act as a host to enable usbmon
on it, but then no gadget would work, and there would be no trace.
After a lot of going around in circles, I decided to read the source of this module to understand how it worked. I found a function which handles the reception of USB Setup Requests, which is exactly what I was interested in. So I simply added a printk()
function in there to output these requests in the kernel messages, which could then be seen by calling dmesg
.
Clearly, this is not the most elegant way to do it, but I:
So, I made my change, recompiled the module, replaced the standard one with this one, and finally! I could see the USB Setup Requests in dmesg
.
I now had to tackle on the next issue: the messages would only be shown when the gadget was initialized. But I wanted to see those messages before initializing the gadget so that it could be set properly!
So I got the idea: what if I loaded a "dummy" gadget at boot, let it generate USB trace data, then disable it and activate the "real" gadget?
I tried at first creating another libcomposite
gadget, but it wouldn't work properly. I then decided to load one of the legacy modules which was replaced by libcomposite
, g_ether
. Even though it was a legacy module, it would still work, and as added bonuses, it required no configuration at all and was loaded very early during boot.
I tested that, and it worked: the g_ether
gadget was generating USB traffic in dmesg
, which I would interpret to determine which OS the Raspberry Pi was connected to.
Granted, at the time being, it is quite simple as it only allows recognizing MacOs among other OSs (which however is exactly what I needed), but it should be relatively easy to use this data to perform more precise USB fingerprinting.
So, finally, after all this, I now have a Ethernet Gadget that is recognized and loaded, without any user interaction (no manual driver installation etc.) on all major OSs: Linux, MacOS and Windows!