Description
1 Introduction
The nefarious Dr. Evil has planted a slew of “binary bombs” on our class machines. A binary bomb is a
program that consists of a sequence of phases. Each phase expects you to type a particular string on stdin.
If you type the correct string, then the phase is defused and the bomb proceeds to the next phase. Otherwise,
the bomb explodes by printing “BOOM!!!” and then terminating. The bomb is defused when every phase
has been defused.
There are too many bombs for us to deal with, so we are giving each student a bomb to defuse. Your
mission, which you have no choice but to accept, is to defuse your bomb before the due date. Good luck,
and welcome to the bomb squad!
Step 1: Get Your Bomb
You can obtain your bomb by visiting the bomb request web site.
For sections 01–04: https://wax.cs.rutgers.edu:15211/
For sections 09–11: https://plastic.cs.rutgers.edu:15211/
This will display a binary bomb request form for you to fill in. Enter your NetID and email address and
hit the Submit button. The server will build your bomb and return it to your browser in a tar file called
bombk.tar, where k is the unique number of your bomb.
Save the bombk.tar file to a (protected) directory in which you plan to do your work. Then give the
command: tar -xvf bombk.tar. This will create a directory called ./bombk with the following
files:
• README: Identifies the bomb and its owners.
• bomb: The executable binary bomb.
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• bomb.c: Source file with the bomb’s main routine and a friendly greeting from Dr. Evil.
If for some reason you request multiple bombs, this is not a problem. Choose one bomb to work on and
delete the rest.
Step 2: Defuse Your Bomb
Your job for this lab is to defuse your bomb.
You must do the assignment on one of the class machines. In fact, there is a rumor that Dr. Evil really is
evil, and the bomb will always blow up if run elsewhere. There are several other tamper-proofing devices
built into the bomb as well, or so we hear.
You can use many tools to help you defuse your bomb. Please look at the hints section for some tips and
ideas. The best way is to use your favorite debugger to step through the disassembled binary.
Each time your bomb explodes it notifies the bomblab server, and you lose half a point (up to a max of 20
points) in the final score for the lab. So there are consequences to exploding the bomb. You must be careful!
The first seven phases are worth 10 points each. Phases 8 and 9 are a little more difficult, so they are worth
15 points each. So the maximum score you can get is 100 points.
Although phases get progressively harder to defuse, the expertise you gain as you move from phase to phase
should offset this difficulty. However, the last phase will challenge even the best students, so please don’t
wait until the last minute to start.
The bomb ignores blank input lines. If you run your bomb with a command line argument, for example,
linux> ./bomb psol.txt
then it will read the input lines from psol.txt until it reaches EOF (end of file), and then switch over
to stdin. In a moment of weakness, Dr. Evil added this feature so you don’t have to keep retyping the
solutions to phases you have already defused.
To avoid accidentally detonating the bomb, you will need to learn how to single-step through the assembly
code and how to set breakpoints. You will also need to learn how to inspect both the registers and the
memory states. One of the nice side-effects of doing the lab is that you will get very good at using a
debugger. This is a crucial skill that will pay big dividends the rest of your career.
Logistics
This is an individual project. All handins are electronic. Clarifications and corrections will be posted on the
course message board.
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Handin
There is no explicit handin. The bomb will notify your instructor automatically about your progress as you
work on it. You can keep track of how you are doing by looking at the class scoreboard at:
https://cray1.cs.rutgers.edu:15211/scoreboard
This web page is updated continuously to show the progress for each bomb.
Hints (Please read this!)
There are many ways of defusing your bomb. You can examine it in great detail without ever running the
program, and figure out exactly what it does. This is a useful technique, but it not always easy to do. You
can also run it under a debugger, watch what it does step by step, and use this information to defuse it. This
is probably the fastest way of defusing it.
We do make one request, please do not use brute force! You could write a program that will try every
possible key to find the right one. But this is no good for several reasons:
• You lose half of a point (up to a max of 20 points) every time you guess incorrectly and the bomb
explodes.
• Every time you guess wrong, a message is sent to the bomblab server. You could very quickly saturate
the network with these messages, and cause the system administrators to revoke your computer access.
• We haven’t told you how long the strings are, nor have we told you what characters are in them. Even
if you made the (incorrect) assumptions that they all are less than 80 characters long and only contain
letters, then you will have 2680 guesses for each phase. This will take a very long time to run, and
you will not get the answer before the assignment is due.
There are many tools which are designed to help you figure out both how programs work, and what is wrong
when they don’t work. Here is a list of some of the tools you may find useful in analyzing your bomb, and
hints on how to use them.
• gdb
The GNU debugger, this is a command line debugger tool available on virtually every platform. You
can trace through a program line by line, examine memory and registers, look at both the source code
and assembly code (we are not giving you the source code for most of your bomb), set breakpoints,
set memory watch points, and write scripts.
The CS:APP web site
https://csapp.cs.cmu.edu/public/students.html
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has a very handy single-page gdb summary that you can print out and use as a reference. Here are
some other tips for using gdb.
– To keep the bomb from blowing up every time you type in a wrong input, you’ll want to learn
how to set breakpoints.
– For online documentation, type “help” at the gdb command prompt, or type “man gdb”,
or “info gdb” at a Unix prompt. Some people also like to run gdb under gdb-mode in
emacs.
• objdump -t
This will print out the bomb’s symbol table. The symbol table includes the names of all functions and
global variables in the bomb, the names of all the functions the bomb calls, and their addresses. You
may learn something by looking at the function names!
• objdump -d
Use this to disassemble all of the code in the bomb. You can also just look at individual functions.
Reading the assembler code can tell you how the bomb works.
Although objdump -d gives you a lot of information, it doesn’t tell you the whole story. Calls to
system-level functions are displayed in a cryptic form. For example, a call to sscanf might appear
as:
8048c36: e8 99 fc ff ff call 80488d4 <_init+0x1a0>
To determine that the call was to sscanf, you would need to disassemble within gdb.
• strings
This utility will display the printable strings in your bomb.
Looking for a particular tool? How about documentation? Don’t forget, the commands apropos, man,
and info are your friends. In particular, man ascii might come in useful. info as will give you more
than you ever wanted to know about the GNU Assembler. Also, the web may also be a treasure trove of
information. If you get stumped, feel free to ask your instructor for help.
Acceptable Machines
As mentioned earlier, you must use one of the approved iLab machines for testing, either in person or by
logging in remotely. The approved machines are:
cd.cs.rutgers.edu
cp.cs.rutgers.edu
grep.cs.rutgers.edu
kill.cs.rutgers.edu
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less.cs.rutgers.edu
ls.cs.rutgers.edu
man.cs.rutgers.edu
pwd.cs.rutgers.edu
rm.cs.rutgers.edu
top.cs.rutgers.edu
vi.cs.rutgers.edu
assembly.cs.rutgers.edu
basic.cs.rutgers.edu
batch.cs.rutgers.edu
cpp.cs.rutgers.edu
java.cs.rutgers.edu
lisp.cs.rutgers.edu
pascal.cs.rutgers.edu
perl.cs.rutgers.edu
prolog.cs.rutgers.edu
python.cs.rutgers.edu
ice.cs.rutgers.edu
snow.cs.rutgers.edu
butter.cs.rutgers.edu
cheese.cs.rutgers.edu
candle.cs.rutgers.edu
frost.cs.rutgers.edu
popsicle.cs.rutgers.edu
plastic.cs.rutgers.edu
crayon.cs.rutgers.edu
wax.cs.rutgers.edu
Use no other machines. In particular, do not use ilab.cs.rutgers.edu.
You may wish to check https://report.cs.rutgers.edu/nagiosnotes/iLab-machines.
html for current status of the iLab machines. If any machine is under high load, you may prefer to use
another. Your progress is kept on the project web server, so you are free to switch machines as needed.
(Since we are hosting the servers on wax and plastic, please avoid those as much as possible.)
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