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SEED Labs – Secret-Key Encryption Lab 1

Secret-Key Encryption Lab

Copyright © 2018 Wenliang Du, All rights reserved.
Free to use for non-commercial educational purposes. Commercial uses of the materials are prohibited.
The SEED project was funded by multiple grants from the US National Science Foundation.

1 Overview

The learning objective of this lab is for students to get familiar with the concepts in the secret-key encryption
and some common attacks on encryption. From this lab, students will gain a first-hand experience on
encryption algorithms, encryption modes, paddings, and initial vector (IV). Moreover, students will be able
to use tools and write programs to encrypt/decrypt messages.

Many common mistakes have been made by developers in using the encryption algorithms and modes.
These mistakes weaken the strength of the encryption, and eventually lead to vulnerabilities. This lab
exposes students to some of these mistakes, and ask students to launch attacks to exploit those vulnerabilities.
This lab covers the following topics:

• Secret-key encryption
• Substitution cipher and frequency analysis
• Encryption modes, IV, and paddings
• Common mistakes in using encryption algorithms
• Programming using the crypto library

Readings. Detailed coverage of the secret-key encryption can be found in the following:

• Chapter 21 of the SEED Book, Computer & Internet Security: A Hands-on Approach, 2nd Edition,
by Wenliang Du. See details at

Lab Environment. This lab has been tested on our pre-built Ubuntu 16.04 VM, which can be downloaded
from the SEED website.

2 Task 1: Frequency Analysis

It is well-known that monoalphabetic substitution cipher (also known as monoalphabetic cipher) is not
secure, because it can be subjected to frequency analysis. In this lab, you are given a cipher-text that is
encrypted using a monoalphabetic cipher; namely, each letter in the original text is replaced by another
letter, where the replacement does not vary (i.e., a letter is always replaced by the same letter during the
encryption). Your job is to find out the original text using frequency analysis. It is known that the original
text is an English article.

In the following, we describe how we encrypt the original article, and what simplification we have made.
Instructors can use the same method to encrypt an article of their choices, instead of asking students to use
the ciphertext made by us.

• Step 1: let us do some simplification to the original article. We convert all upper cases to lower cases,
and then removed all the punctuations and numbers. We do keep the spaces between words, so you can
still see the boundaries of the words in the ciphertext. In real encryption using monoalphabetic cipher,

SEED Labs – Secret-Key Encryption Lab 2

spaces will be removed. We keep the spaces to simplify the task. We did this using the following

$ tr [:upper:] [:lower:] < article.txt > lowercase.txt
$ tr -cd ’[a-z][\n][:space:]’ < lowercase.txt > plaintext.txt

• Step 2: let us generate the encryption key, i.e., the substitution table. We will permute the alphabet
from a to z using Python, and use the permuted alphabet as the key. See the following program.

$ python
>>> import random
>>> s = “abcdefghijklmnopqrstuvwxyz”
>>> list = random.sample(s, len(s))
>>> ’’.join(list)

• Step 3: we use the tr command to do the encryption. We only encrypt letters, while leaving the space
and return characters alone.

$ tr ’abcdefghijklmnopqrstuvwxyz’ ’sxtrwinqbedpvgkfmalhyuojzc’ \
< plaintext.txt > ciphertext.txt

We have created a ciphertext using a different encryption key (not the one described above). You can
download it from the lab’s website. Your job is to use the frequency analysis to figure out the encryption
key and the original plaintext.

Guidelines. Using the frequency analysis, you can find out the plaintext for some of the characters quite
easily. For those characters, you may want to change them back to its plaintext, as you may be able to get
more clues. It is better to use capital letters for plaintext, so for the same letter, we know which is plaintext
and which is ciphertext. You can use the tr command to do this. For example, in the following, we replace
letters a, e, and t in in.txt with letters X, G, E, respectively; the results are saved in out.txt.

$ tr ’aet’ ’XGE’ < in.txt > out.txt

There are many online resources that you can use. We list four useful links in the following:

• : This website can produce the statis-
tics fro a ciphertext, including the single-letter frequencies, bigram frequencies (2-letter sequence),
and trigram frequencies (3-letter sequence), etc.

• This Wikipedia page pro-
vides frequencies for a typical English plaintext.

• Bigram frequency.

• Trigram frequency.

SEED Labs – Secret-Key Encryption Lab 3

3 Task 2: Encryption using Different Ciphers and Modes

In this task, we will play with various encryption algorithms and modes. You can use the following
openssl enc command to encrypt/decrypt a file. To see the manuals, you can type man openssl
and man enc.

$ openssl enc -ciphertype -e -in plain.txt -out cipher.bin \
-K 00112233445566778889aabbccddeeff \
-iv 0102030405060708

Please replace the ciphertype with a specific cipher type, such as -aes-128-cbc, -bf-cbc,
-aes-128-cfb, etc. In this task, you should try at least 3 different ciphers. You can find the meaning
of the command-line options and all the supported cipher types by typing “man enc”. We include some
common options for the openssl enc command in the following:

-in <file> input file
-out <file> output file
-e encrypt
-d decrypt
-K/-iv key/iv in hex is the next argument
-[pP] print the iv/key (then exit if -P)

4 Task 3: Encryption Mode – ECB vs. CBC

The file pic original.bmp can be downloaded from this lab’s website, and it contains a simple picture.
We would like to encrypt this picture, so people without the encryption keys cannot know what is in the
picture. Please encrypt the file using the ECB (Electronic Code Book) and CBC (Cipher Block Chaining)
modes, and then do the following:

1. Let us treat the encrypted picture as a picture, and use a picture viewing software to display it. How-
ever, For the .bmp file, the first 54 bytes contain the header information about the picture, we have
to set it correctly, so the encrypted file can be treated as a legitimate .bmp file. We will replace the
header of the encrypted picture with that of the original picture. We can use the bless hex editor
tool (already installed on our VM) to directly modify binary files. We can also use the following
commands to get the header from p1.bmp, the data from p2.bmp (from offset 55 to the end of the
file), and then combine the header and data together into a new file.

$ head -c 54 p1.bmp > header
$ tail -c +55 p2.bmp > body
$ cat header body > new.bmp

2. Display the encrypted picture using a picture viewing program (we have installed an image viewer
program called eog on our VM). Can you derive any useful information about the original picture
from the encrypted picture? Please explain your observations.

Select a picture of your choice, repeat the experiment above, and report your observations.

SEED Labs – Secret-Key Encryption Lab 4

5 Task 4: Padding

For block ciphers, when the size of a plaintext is not a multiple of the block size, padding may be required.
All the block ciphers normally use PKCS#5 padding, which is known as standard block padding (see Chapter
21.4 of the SEED book for details). We will conduct the following experiments to understand how this type
of padding works:

1. Use ECB, CBC, CFB, and OFB modes to encrypt a file (you can pick any cipher). Please report which
modes have paddings and which ones do not. For those that do not need paddings, please explain why.

2. Let us create three files, which contain 5 bytes, 10 bytes, and 16 bytes, respectively. We can use the
following “echo -n” command to create such files. The following example creates a file f1.txt
with length 5 (without the -n option, the length will be 6, because a newline character will be added
by echo):

$ echo -n “12345” > f1.txt

We then use “openssl enc -aes-128-cbc -e” to encrypt these three files using 128-bit AES
with CBC mode. Please describe the size of the encrypted files.

We would like to see what is added to the padding during the encryption. To achieve this goal, we
will decrypt these files using “openssl enc -aes-128-cbc -d”. Unfortunately, decryption
by default will automatically remove the padding, making it impossible for us to see the padding.
However, the command does have an option called “-nopad”, which disables the padding, i.e.,
during the decryption, the command will not remove the padded data. Therefore, by looking at the
decrypted data, we can see what data are used in the padding. Please use this technique to figure out
what paddings are added to the three files.

It should be noted that padding data may not be printable, so you need to use a hex tool to display the
content. The following example shows how to display a file in the hex format:

$ hexdump -C p1.txt
00000000 31 32 33 34 35 36 37 38 39 49 4a 4b 4c 0a |123456789IJKL.|
$ xxd p1.txt
00000000: 3132 3334 3536 3738 3949 4a4b 4c0a 123456789IJKL.

6 Task 5: Error Propagation – Corrupted Cipher Text

To understand the error propagation property of various encryption modes, we would like to do the following

1. Create a text file that is at least 1000 bytes long.

2. Encrypt the file using the AES-128 cipher.

3. Unfortunately, a single bit of the 55th byte in the encrypted file got corrupted. You can achieve this
corruption using the bless hex editor.

4. Decrypt the corrupted ciphertext file using the correct key and IV.

SEED Labs – Secret-Key Encryption Lab 5

Please answer the following question: How much information can you recover by decrypting the cor-
rupted file, if the encryption mode is ECB, CBC, CFB, or OFB, respectively? Please answer this question
before you conduct this task, and then find out whether your answer is correct or wrong after you finish this
task. Please provide justification.

7 Task 6: Initial Vector (IV) and Common Mistakes

Most of the encryption modes require an initial vector (IV). Properties of an IV depend on the cryptographic
scheme used. If we are not careful in selecting IVs, the data encrypted by us may not be secure at all, even
though we are using a secure encryption algorithm and mode. The objective of this task is to help students
understand the problems if an IV is not selected properly. The detailed guidelines for this task is provided
in Chapter 21.5 of the SEED book.

7.1 Task 6.1

A basic requirement for IV is uniqueness, which means that no IV may be reused under the same key. To
understand why, please encrypt the same plaintext using (1) two different IVs, and (2) the same IV. Please
describe your observation, based on which, explain why IV needs to be unique.

7.2 Task 6.2. Common Mistake: Use the Same IV

One may argue that if the plaintext does not repeat, using the same IV is safe. Let us look at the Output
Feedback (OFB) mode. Assume that the attacker gets hold of a plaintext (P1) and a ciphertext (C1) ,
can he/she decrypt other encrypted messages if the IV is always the same? You are given the following
information, please try to figure out the actual content of P2 based on C2, P1, and C1.

Plaintext (P1): This is a known message!
Ciphertext (C1): a469b1c502c1cab966965e50425438e1bb1b5f9037a4c159

Plaintext (P2): (unknown to you)
Ciphertext (C2): bf73bcd3509299d566c35b5d450337e1bb175f903fafc159

If we replace OFB in this experiment with CFB (Cipher Feedback), how much of P2 can be revealed?
You only need to answer the question; there is no need to demonstrate that.

The attack used in this experiment is called the known-plaintext attack, which is an attack model for
cryptanalysis where the attacker has access to both the plaintext and its encrypted version (ciphertext). If
this can lead to the revealing of further secret information, the encryption scheme is not considered as secure.

7.3 Task 6.3. Common Mistake: Use a Predictable IV

From the previous tasks, we now know that IVs cannot repeat. Another important requirement on IV is that
IVs need to be unpredictable for many schemes, i.e., IVs need to be randomly generated. In this task, we
will see what is going to happen if IVs are predictable.

Assume that Bob just sent out an encrypted message, and Eve knows that its content is either Yes or
No; Eve can see the ciphertext and the IV used to encrypt the message, but since the encryption algorithm
AES is quite strong, Eve has no idea what the actual content is. However, since Bob uses predictable IVs,
Eve knows exactly what IV Bob is going to use next. The following summarizes what Bob and Eve know:

Encryption method: 128-bit AES with CBC mode.

SEED Labs – Secret-Key Encryption Lab 6

Key (in hex): 00112233445566778899aabbccddeeff (known only to Bob)
Ciphertext (C1): bef65565572ccee2a9f9553154ed9498 (known to both)
IV used on P1 (known to both)

(in ascii): 1234567890123456
(in hex) : 31323334353637383930313233343536

Next IV (known to both)
(in ascii): 1234567890123457
(in hex) : 31323334353637383930313233343537

A good cipher should not only tolerate the known-plaintext attack described previously, it should also
tolerate the chosen-plaintext attack, which is an attack model for cryptanalysis where the attacker can obtain
the ciphertext for an arbitrary plaintext. Since AES is a strong cipher that can tolerate the chosen-plaintext
attack, Bob does not mind encrypting any plaintext given by Eve; he does use a different IV for each
plaintext, but unfortunately, the IVs he generates are not random, and they can always be predictable.

Your job is to construct a message P2 and ask Bob to encrypt it and give you the ciphertext. Your
objective is to use this opportunity to figure out whether the actual content of P1 is Yes or No.

7.4 Additional Readings

There are more advanced cryptanalysis on IV that is beyond the scope of this lab. Students can read the
article posted in this URL: Because the requirements on IV
really depend on cryptographic schemes, it is hard to remember what properties should be maintained when
we select an IV. However, we will be safe if we always use a new IV for each encryption, and the new IV
needs to be generated using a good pseudo random number generator, so it is unpredictable by adversaries.
See another SEED lab (Random Number Generation Lab) for details on how to generate cryptographically
strong pseudo random numbers.

8 Task 7: Programming using the Crypto Library

This task is mainly designed for students in Computer Science/Engineering or related fields, where pro-
gramming is required. Students should check with their professors to see whether this task is required for
their courses or not.

In this task, you are given a plaintext and a ciphertext, and your job is to find the key that is used for the
encryption. You do know the following facts:

• The aes-128-cbc cipher is used for the encryption.

• The key used to encrypt this plaintext is an English word shorter than 16 characters; the word can be
found from a typical English dictionary. Since the word has less than 16 characters (i.e. 128 bits),
pound signs (#: hexadecimal value is 0x23) are appended to the end of the word to form a key of
128 bits.

Your goal is to write a program to find out the encryption key. You can download a English word list
from the Internet. We have also linked one on the web page of this lab. The plaintext, ciphertext, and IV are
listed in the following:

Plaintext (total 21 characters): This is a top secret.
Ciphertext (in hex format): 764aa26b55a4da654df6b19e4bce00f4


SEED Labs – Secret-Key Encryption Lab 7

IV (in hex format): aabbccddeeff00998877665544332211

You need to pay attention to the following issues:

• If you choose to store the plaintext message in a file, and feed the file to your program, you need to
check whether the file length is 21. If you type the message in a text editor, you need to be aware that
some editors may add a special character to the end of the file. The easiest way to store the message
in a file is to use the following command (the -n flag tells echo not to add a trailing newline):

$ echo -n “This is a top secret.” > file

• In this task, you are supposed to write your own program to invoke the crypto library. No credit will
be given if you simply use the openssl commands to do this task. Sample code can be found from
the following URL:

• When you compile your code using gcc, do not forget to include the -lcrypto flag, because your
code needs the crypto library. See the following example:

$ gcc -o myenc myenc.c -lcrypto

Note to instructors. We encourage instructors to generate their own plaintext and ciphertext using a dif-
ferent key; this way students will not be able to get the answer from another place or from previous courses.
Instructors can use the following commands to achieve this goal (please replace the word example with
another secret word, and add the correct number of # signs to make the length of the string to be 16):

$ echo -n “This is a top secret.” > plaintext.txt
$ echo -n “example#########” > key
$ xxd -p key
$ openssl enc -aes-128-cbc -e -in plaintext.txt -out ciphertext.bin \

-K 6578616d706c65232323232323232323 \
-iv 010203040506070809000a0b0c0d0e0f \

$ xxd -p ciphertext.bin

9 Submission

You need to submit a detailed lab report, with screenshots, to describe what you have done and what you
have observed. You also need to provide explanation to the observations that are interesting or surprising.
Please also list the important code snippets followed by explanation. Simply attaching code without any
explanation will not receive credits.

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