ECE497 Project WireShark

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Revision as of 13:59, 11 November 2013 by Parasby (talk | contribs) (Updated Work Breakdown)
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thumb‎ Embedded Linux Class by Mark A. Yoder


Team members: Ben Paras, Manuel Stephan

Grading Template

I'm using the following template to grade. Each slot is 10 points. 0 = Missing, 5=OK, 10=Wow!

00 Executive Summary
00 Installation Instructions 
00 User Instructions
00 Highlights
00 Theory of Operation
00 Work Breakdown
00 Future Work
00 Conclusions
00 Demo
00 Late
Comments: I'm looking forward to seeing this.

Score:  10/100

(Inline Comment)

Executive Summary

We want to try to port WireShark and see what we could get working on the BeagleBone.

As it was a problem to get wireshark compiled on the beaglebone after some skype sessions with Patrick Vogelaar, Graduate student in Advanced Communications at Napier in Edinburgh we thought of the problem in a different way. Instead of porting ressource consuming wireshark to the beaglebone we use tcpdump on the bone to just monitor the traffic. The traffic is tehn piped through ssh to the host computer and then analyzed by wireshark. So we get use the full capability of wireshark on a host computer and use lean tcpdump on the beaglebone.


Installation Instructions

Prerequisites

Hardware requirements:

  • Beagle Bone Black
  • Linux host computer running Ubuntu 12.04 LTS or later
  • USB cable
  • Ethernet Cable

Software requirements:

  • Wireshark
  • The g++ compiler
  • Make

If you do not have these, you can get them with these commands:

sudo apt-get install wireshark
sudo apt-get install g++
sudo apt-get install make

Getting the sources:

Do a git clone on our repository to get all the sources you need and do an ls to see them:

git clone git@github.com:manuelstephan/eLinuxProject.git 
ls
confused.pcap  Makefile   ooP.cpp        README.md  wireparser.cpp
main.cpp       Makefile~  original.pcap  run.sh     wireparser.hpp

You should have a matching directory from above, if not, do a git pull

To build the binary of the wireparser you just have to type make. No additional configuration is required.

make
g++ -c wireparser.cpp
g++ -c main.cpp
g++ -o wireparser wireparser.o main.o

Confiugration and Setup:

Now you need tcpdump so ssh to your beaglebone and check if tcpdump is installed:

ssh root@192.168.7.2
which tcpdump 
/usr/sbin/tcpdump

Make sure tcpdump exists and is configured to the path: /usr/sbin/tcpdump

If it isn't installed, install it:

opkg install tcpdump

It should automatically configured to the path: /usr/sbin/tcpdump

Now you need an ssh-id on the beaglebone so you can log onto it without typing a password. The script that sets up and runs program needs it to work. Otherwise the process of typing in a password interferes with it.

First do a ssh-keygen:

ssh-keygen
Generating public/private rsa key pair.
Enter file in which to save the key (/home/bp/.ssh/id_rsa): wire      
Enter passphrase (empty for no passphrase): 
Enter same passphrase again: 
Your identification has been saved in wire.
Your public key has been saved in wire.pub.
The key fingerprint is:
99:e4:9d:14:af:ec:e7:e7:39:9a:4d:e2:3c:31:16:ba bp@bp-HP-EliteBook-8530w
The key's randomart image is:
+--[ RSA 2048]----+
|          .      |
|           o     |
|        . . .    |
|       o * o.    |
|        S =. .   |
|         .. +    |
|          .ooo.  |
|          E=.=o. |
|            *=+. |
+-----------------+

You should get something similar to above. Now copy the key to the beaglebone:

ssh-copy-id root@192.168.7.2
Now try logging into the machine, with "ssh 'root@192.168.7.2'", and check in:
 ~/.ssh/authorized_keys
to make sure we haven't added extra keys that you weren't expecting.

From here just type exit

Now everything is prepared for the actual operation. See User Instructions in the next section to learn how to do a live capture on the beaglebone via the host and wireshark.

Here is a link to the github page from where the git clone operation above is running on: https://github.com/manuelstephan/eLinuxProject

User Instructions

Before you start, make sure the beaglebone is connected via USB to your host computer. After that, follow this one step to get everything running.

1) Run capture.sh (eth0 or usb0)

If you haven't already previously, make sure you run make in the eLinuxProject git directory

make
g++ -c wireparser.cpp
g++ -c main.cpp
g++ -o wireparser wireparser.o main.o

Now run the capture.sh script:

./capture.sh eth0 or ./capture.sh usb0 
Capturing from eth0
wireshark is installed on your system.
mkfifo /tmp/myfifo0 was created .. 
mkfifo /tmp/myfifo1 was created .. 
Starting tcpdump ...
Tcpdump running ...
Starting wireshark ... 
Wireshark running ... 
Starting wireparser ... 
tcpdump: WARNING: eth0: no IPv4 address assigned
tcpdump: listening on eth0, link-type EN10MB (Ethernet), capture size 65535 bytes

capture.sh takes in an interface parameter (eth0 or usb0) according to what part of the beagle bone you are watching

This runs the script that sets up and runs everything. After this script is ran, wireshark should open up:

Wireshark upon opening.

Now connect to the beaglebone's ethernet port and wait for the packets to arrive. It should take a few seconds. Once they arrive, you should see something like this:

Wireshark once it sees packets.

Now you can connect anything to either the usb0 or eth0 port of the beaglebone and monitor the traffic.

For more information check out this youtube video tutorial on Wireshark: http://www.youtube.com/watch?v=UFAA_7lpkTE

or visit http://www.wireshark.org/docs for more tutorials on Wireshark.

Highlights

Things we can do:

  • Monitor traffic on the beagle though the USB cable to the host using Wireshark

Here is where you brag about what your project can do.

Include a YouTube demo.

Theory of Operation

Components:

  • Named pipes - These are basically FIFOs. Many processes can share data through the named pipe.


  • tcpdump - A powerful commandline packet analyzer. It is very efficient to use on embedded systems due to its efficiency. The beaglebone also comes with this already installed. It is possible to forward tcpdump traffic over ssh.


  • wireshark - A packet analysis tool that comes with a GUI. This is very resource-consuming so it is not ideal to use this on an embedded system. The captures from wireshark also take up a lot of space so its a good idea to be running wireshark on a more powerful system such as your host computer.


  • .pcap - These are packet capture files. The following is the file format of .pcacp files (courtesy of wiki.wireshark.org):
.pcacp file format.

This format is supported by both wireshark and tcpdump. The Global Header has a magic number that you need to look for in order to parse the traffic.

typedef struct pcap_hdr_s {
       guint32 magic_number;   /* magic number */
       guint16 version_major;  /* major version number */
       guint16 version_minor;  /* minor version number */
       gint32  thiszone;       /* GMT to local correction */
       guint32 sigfigs;        /* accuracy of timestamps */
       guint32 snaplen;        /* max length of captured packets, in octets */
       guint32 network;        /* data link type */
} pcap_hdr_t;

The magic number ( 0xa1b2c3d4 (identical) or 0xd4c3b2a1 (swapped) ) is always located at the beginning at the global header.


  • wireparser - This is a c++ program that looks for the magic number and throws away everything before the magic number. After if finds the magic number, the rest of the data is passed through.


Operation workflow:

1) Check for existing FIFOs and delete them if they do exist - existing FIFOs may have junk information

2) Create 2 FIFOs in /tmp - myfifo0 and myfifo1

3) Start tcpdump in the background on the beaglebone with the parameters to use pcap format, listen to a specified interface (usb0 or eht0), and then pipe it to /tmp/myfifo0

4) Start wireshark in the background on the host with the parameters to start the capture immediately, capture the interface (/tmp/myfifo1)

5) Start the wireparser which will read from /tmp/myfifo0 , filter it, and write it to /tmp/myfifo1 from which wireshark will read from

6) Any data through tcpdump should appear in the wireshark graphical interface

7) Once finished with capture, CTRL+C to stop everything (wireshark , wireparser, and tcpdump)

All these steps are done in the capture.sh script that was made. See the graphic below for a visualization of the how the programs interact:

Overview of the System.

The graphic above represents what occurs in the whole process and is explained as follows:

1) The packets captured by tcpdump on the beaglebone from the specified interfaced interface are forwarded over ssh to the 1st FIFO on the host computer

2) The wireparser reads from the 1st FIFO and looks for the magic number 0xa1b2c3d4

3) Everything before the magic number is filtered out and the rest of the data (including the magic number) is passed to the 2nd FIFO

4) The 2nd FIFO now contains only data in the .pcacp format from which wireshark will read from

5) Now wireshark has all the traffic data from the beaglebone and can now be analyzed using the GUI provided

Work Breakdown

Major Tasks:

  • Try to compile wireshark on the beaglebone - Manuel Stephan
  • Try to crosscompi wireshark via the host - Ben Paras
  • Consulted Patrick Vogelaar for wireshark usability - Manuel Stephan and Ben Paras
  • Formulate new method to monitor traffic on the beaglebone - Manuel Stephan and Ben Paras
  • Evaluate new method and determine what needs to be done for it to work - Manuel Stephan and Ben Paras
  • Figure out how to interface tcpdump and wireshark using named pipes - Ben Paras
  • Learn about .pcap format and how to parse it - Manuel Stephan
  • Write the wireparser to filter out the captures - Manuel Stephan
  • Test out the wiresparser by using gHex and whether or not it parsed correct and incorret .pcap formats. -Ben Paras
  • Clean up and separate wiresparser into components and create a Makefile for it - Ben Paras
  • Write capture.sh - Manuel Stephan
  • Test capture.sh - Ben Paras
  • Documentation 1 (Executive Summary, Theory of Operation, Future Work) - Manuel Stephan
  • Documentation 2 (Installation Instructions, User Instructions, Work Breakdown) - Ben Paras
  • Take a youtube demo video and upload - Manuel Stephan and Ben Paras
  • Documentation 3 (Highlights and Conclusions) - Manuel Stephan and Ben Paras

The timeline below shows the tasks and major milestones and when they were accomplished:

Timeline showing tasks and major milestones of the project.

Future Work

Suggest addition things that could be done with this project.

Conclusions

Give some concluding thoughts about the project. Suggest some future additions that could make it even more interesting.


Special Thanks to:

B.Eng Patrick Vogelaar, Graduate Student in Advanced Communications at Napier University in Edinburgh for giving us the idea to use named pipes and our current setup to solve this problem.



thumb‎ Embedded Linux Class by Mark A. Yoder