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KillerBee

KillerBee is a Framework and Tools for Testing & Auditing ZigBee and IEEE 802.15.4 Networks

MAINTAINERS/LICENSE

Distributed under a BSD license, see LICENSE.txt for details. All Rights Reserved.

The main toolkit was/is authored by:

We appreciate the many contributers to the framework, including the following who have contributed capabilities:

  • Anonymous Contributors
  • Spencer McIntyre (scapy extension)
  • Bryan Halfpap Bryanhalf@gmail.com (additional tools)
  • Travis Goodspeed
  • Mike Kershaw (dragorn)
  • Chris Wang (aikiba)
  • Nick DePetrillo
  • Ed Skoudis
  • Matt Carpenter
  • Sergey Bratus (research support at Dartmouth)
  • Jeff Spielberg
  • Scytmo (bug fixes and CC2530/1 EMK board support)
  • Adam Laurie/rfidiot (APS crypto implementation, firmware, DFU & BOOTLOADER, SubGHZ, SiLabs NodeTest)
  • Steve Martin

REQUIREMENTS

KillerBee is developed and tested on Linux systems. MacOS usage is possible but not supported.

We have striven to use a minimum number of software dependencies, however, it is necessary to install the following Python modules before installation. The install will detect and prompt you for what is needed.

On Ubuntu systems, you can install the needed dependencies with the following commands:

# apt-get install python-gtk2 python-cairo python-usb python-crypto python-serial python-dev libgcrypt-dev
# git clone https://github.com/secdev/scapy
# cd scapy
# python setup.py install

The python-dev and libgcrypt are required for the Scapy Extension Patch.

Also note that this is a fairly advanced and un-friendly attack platform. This is not Cain & Abel. It is intended for developers and advanced analysts who are attacking ZigBee and IEEE 802.15.4 networks. I recommend you gain some understanding of the ZigBee protocol (the book ZigBee Wireless Networks and Transceivers by Shahin Farahani is reasonable, though still not great) and familiarity with the Python language before digging into this framework.

INSTALLATION

KillerBee uses the standard Python 'setup.py' installation file. Install KillerBee with the following command:

# python setup.py install

DIRECTORIES

The directory structure for the KillerBee code is described as follows:

  • doc - HTML documentation on the KillerBee library, courtesy of epydoc.
  • firmware - Firmware for supported KillerBee hardware devices.
  • killerbee - Python library source.
  • sample - Sample packet captures, referenced below.
  • scripts - Shell scripts used in development.
  • tools - ZigBee and IEEE 802.15.4 attack tools developed using this framework.

REQUIRED HARDWARE

The KillerBee framework is being expanded to support multiple devices. Currently there is support for the River Loop ApiMote, Atmel RZ RAVEN USB Stick, MoteIV Tmote Sky, TelosB mote, Sewino Sniffer, and various hardware running Silicon Labs Node Test firmware.

Support for Freaklab's Freakduino with added hardware & the Dartmouth arduino sketch and Zigduino boards are available but are not listed below as they are not maintained. You must enable these to be searched for in killerbee/config.py and then reinstall KillerBee.

ApiMote v4beta (and v3):

The devices typically come preloaded and do not need to be reflashed for basic use.

The hardware is open-source at https://github.com/riverloopsec/apimote. It is available assembled by contacting team at riverloopsecurity dot com.

This is currently supported for beta, and supports sniffing, injection, and jamming.

Texas Instruments CC2530/1 EMK:

This USB dongle is produced by Texas Instruments and is sold as an evaluation kit for their CC2530 or CC2531 integrated circuit.

It can be purchased from electronics distributors, or directly from them here.

This is currently supported for beta, and supports sniffing only.

MoteIV Tmote Sky or TelosB mode:

This device can be loaded with firmware via USB. Attach the device, and then within killerbee/firmware, run:

$ ./flash_telosb.sh

These boards can be obtained via multiple distributors, however this vendor has stated that their "clone" of the original hardware is compatible. We have not tested nor do we endorse any specific "clone".

Atmel RZ RAVEN USB Stick:

See http://www.atmel.com/tools/RZUSBSTICK.aspx. This hardware is convenient as the base firmware is open source with a freely-available IDE. The KillerBee firmware for the RZ RAVEN included in the firmware/ directory is a modified version of the stock firmware distributed by Atmel to include attack functionality.

The RZ RAVEN USB Stick is available from common electronics resellers for approximately $40/USD:

The stock firmware shipped with this hardware allows you to leverage the passive functionality included in the KillerBee tools and framework (such as receiving frames), but does not allow you to do packet injection, or to impersonate devices on the network.

In order to get the full functionality included in KillerBee, the RZ RAVEN USB Stick must be flashed with the custom firmware included in the firmware/ directory. See firmware/README.md for details.

Silicon Labs Node Test 2.4GHz & SubGHz:

See SiLabs AN1019.

This is a firmware image for a huge variety of hardware platforms, supporting EM250, EM375, EFR32, etc., and provides for (with appropriate radio part) the following frequencies:

  • 2.4 GHz (ch 11-26)
  • 863-917 MHz (pages 28-31, ch 0-26)

You must enable these to be searched for in killerbee/config.py and then reinstall KillerBee. See firmware/README.md for installation details.

NOTE: This is a SNIFFER only implementation which will only read packets with a good FCS, and although the firmware has injection capability, it adds a 2 byte counter to the end of every packet, rendering it useless for all practical purposes. If you are interested in an INJECTION and BAD FCS capable device, contact the author, Adam Laurie - adam at algroup.co.uk

TOOLS

KillerBee includes several tools designed to attack ZigBee and IEEE 802.15.4 networks, built using the KillerBee framework. Each tool has its own usage instructions documented by running the tool with the "-h" argument, and summarized below.

  • zbid - Identifies available interfaces that can be used by KillerBee and associated tools.

  • zbwireshark - Similar to zbdump but exposes a named pipe for real-time capture and viewing in Wireshark.

  • zbdump - A tcpdump-like took to capture IEEE 802.15.4 frames to a libpcap or Daintree SNA packet capture file. Does not display real-time stats like tcpdump when not writing to a file.

  • zbreplay - Implements a replay attack, reading from a specified Daintree DCF or libpcap packet capture file, retransmitting the frames. ACK frames are not retransmitted.

  • zbstumbler - Active ZigBee and IEEE 802.15.4 network discovery tool. Zbstumbler sends beacon request frames out while channel hopping, recording and displaying summarized information about discovered devices. Can also log results to a CSV file.

  • zbpanidconflictflood - Requires two killerbee interfaces one killerbee interface listens for packets and marks their PAN ID. The other interface constantly sends out beacon packets with found PAN ID's. The beacon packets with the same PAN ID cause the PAN coordinator to believe that there is a PAN ID conflict, and the coordinator begins the process of realigning the network on a new PAN ID. The process repeats ad nauseum. Typically, network devices can't keep up with the rapid change and after several seconds the network falls apart.

              _NO TARGETING BUILT IN_ This may *destroy* all zigbee networks
              within range on the channel you are performing the attack on. Use
              with caution.
    
  • zborphannotify - Spoofs an orphan notification packet from the target device to a PAN Coordinator to test Coordinator behavior.

  • zbrealign - Spoofs an 802.15.4 PAN Realignment frame from the coordinator to a target device. May be able to reset the device's PAN ID or Channel

  • zbfakebeacon - Spoofs beacon frames, either spamming them or on response to seeing a beacon request come through.

  • zbopenear - Assists in data capture where devices are operating on multiple channels or fast-frequency-hopping. It assigns multiple interfaces sequentially across all channels.

  • zbassocflood - Repeatedly associate to the target PANID in an effort to cause the device to crash from too many connected stations.

  • zbconvert - Convert a packet capture from Libpcap to Daintree SNA format, or vice-versa.

  • zbdsniff - Captures ZigBee traffic, looking for NWK frames and over-the-air key provisioning. When a key is found, zbdsniff prints the key to stdout. The sample packet capture sample/zigbee-network-key-ota.dcf can be used to demonstrate this functionality.

  • zbfind - A GTK GUI application for tracking the location of an IEEE 802.15.4 transmitter by measuring RSSI. zbfind can be passive in discovery (only listen for packets) or it can be active by sending Beacon Request frames and recording the responses from ZigBee routers and coordinators. If you get a bunch of errors after starting this tool, make sure your DISPLAY variable is set properly.

  • zbgoodfind - Implements a key search function using an encrypted packet capture and memory dump from a legitimate ZigBee or IEEE 802.15.4 device. This tool accompanies Travis Goodspeed's GoodFET hardware attack tool, or other binary data that could contain encryption key information such as bus sniffing with legacy chips (such as the CC2420). Zbgoodfind's search file must be in binary format (obj hexfile's are not supported). To convert from the hexfile format to a binary file, use the objcopy tool: objcopy -I ihex -O binary mem.hex mem.bin

  • zbwardrive - Discovers available interfaces and uses one to inject beacon requests and listen for respones across channels. Once a network is found on a channel, it assigns another device to continuously capture traffic on that channel to a PCAP file. Scapy must be installed to run this.

  • zbscapy - Provides an interactive Scapy shell for interacting via a KillerBee interface. Scapy must be installed to run this.

  • kbbootloader - Switches device into DFU/BOOTLOADER mode (if device is capable)

Additional tools, that are for special cases or are not stable, are stored in the Api-Do project repository: http://code.google.com/p/zigbee-security/ and at https://github.com/riverloopsec/beekeeperwids.

FRAMEWORK

KillerBee is designed to simplify the process of sniffing packets from the air interface or a supported packet capture file (libpcap or Daintree SNA), and for injecting arbitrary packets. Helper functions including IEEE 802.15.4, ZigBee NWK and ZigBee APS packet decoders are available as well.

The KillerBee API is documented in epydoc format, with HTML documentation in the doc/ directory of this distribution. If you have epydoc installed, you can also generate a convenient PDF for printing, if desired, as shown:

$ cd killerbee
$ mkdir pdf
$ epydoc --pdf -o pdf killerbee/

The pdf/ directory will have a file called "api.pdf" which includes the framework documentation.

To get started using the KillerBee framework, take a look at the included tools (zbdump and zbreplay are good examples to get started).

Since KillerBee is a Python library, it integrates well with other Python software as well. For example, the Sulley library is a fuzzing framework written in Python by Pedram Amini. Using the Sulley mutation features and KillerBee's packet injection features, it is staightforward to build a mechanism for generating and transmitting malformed ZigBee data to a target.

QUESTIONS/COMMENTS/CONCERNS

Please use the ticketing system at https://github.com/riverloopsec/killerbee/issues.

The original version was written by: jwright@willhackforsushi.com. The current version, fixes, etc are handled by: ryan@riverloopsecurity.com. (See the list above for all contributors/credits.)

For contributors/developers, see DEVELOPMENT.md for details and guidance.

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IEEE 802.15.4/ZigBee Security Research Toolkit

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