EEC 688/788 Secure and Dependable Computing

1. EEC 688/788Secure and Dependable Computing Lecture 2 Wenbing Zhao Department of Electrical and Computer Engineering Cleveland State University wenbing@ieee.org

2. Outline Introduction to cryptography Terminology Basic encryption methods One time pad Symmetric-key algorithms DES, AES, etc Cipher modes EEC688: Secure & Dependable Computing

3. Cryptography Terminology Encryption is the process of encoding a message so that its meaning is not obvious Equivalent terms: encode, encipher Decryption is the reverse process, transforming an encrypted message back into its normal, original form Equivalent terms: decode, decipher Plaintext: message to be encrypted Ciphertext: encrypted message EEC688: Secure & Dependable Computing

4. Cryptography Terminology The cryptosystem involves a set of rules for how to encrypt the plaintext and how to decrypt the ciphertext Why encryption? It addresses the need for confidentiality of data, also helps to ensure integrity It forms the basis of protocols that enableus to provide security while accomplishing system or network tasks EEC688: Secure & Dependable Computing

5. Cryptography Terminology The encryption and decryption rules are called encryption and decryptionalgorithms Encryption/decryptions algorithms often use a device called a key, denoted by K, so that the resulting ciphertext depends on the original plaintext message, the algorithm, and the key value An encryption scheme that does not require the use of a key is called a keyless cipher EEC688: Secure & Dependable Computing

6. Symmetric Encryption The encryption and decryption keys are the same, so P = D(K, E(K,P)) D and E are closely related. They are mirror-image processes The symmetric systems provide a two-way channel to their users The symmetry of this situation is a major advantage of this type of encryption, but it also leads to a problem: key distribution EEC688: Secure & Dependable Computing

7. Symmetric Encryption DK(EK(P)) = P EEC688: Secure & Dependable Computing

8. Asymmetric Encryption Encryption and decryption keys come in pairs. The decryption key, KD, inverts the encryption of key KE, so that P = D(KD, E(KE,P)) Asymmetric encryption systems excel at key management EEC688: Secure & Dependable Computing

9. Cryptology Cryptologyis the research into and study of encryption and decryption; it includes both cryptography and cryptanalysis Cryptography– art of devising ciphers Comes from Greek words for“secret writing”. It refers to the practice of using encryption to conceal text Cryptanalysis– art of breaking ciphers Study of encryption and encrypted messages, hoping to find the hidden meanings EEC688: Secure & Dependable Computing

10. Cryptanalysis Attempt to break a single message Attempt to recognize patterns in encrypted messages, to be able to break subsequent ones Attempt to deduce the key, in order to break subsequent messages easily Attempt to find weaknesses in the implementation or environment of use of encryption Attempt to find general weaknesses in an encryption algorithm EEC688: Secure & Dependable Computing

11. Cryptanalysis Traffic analysis: attempt to infer some meaning without even breaking the encryption, e.g., Noticing an unusual frequency of communication Determining something by whether the communication was short or long EEC688: Secure & Dependable Computing

12. Cryptanalysis –Breaking Encryption Schemes Ciphertext-only: cryptanalyst has a quantity of ciphertext and no plaintext Known plaintext: cryptanalyst has some matched ciphertext and plaintext Chosen plaintext: cryptanalyst has the ability to encrypt pieces of plaintext of his own choosing 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

13. Basic Encryption Methods Substitution ciphers: one letter is exchanged for another Transposition ciphers: order of letters is rearranged EEC688: Secure & Dependable Computing

14. Substitution Ciphers Idea: each letter or group of letters is replaced by another letter or group of letters Caesar cipher – circularly shift by 3 letters a -> D, b -> E, … z -> C More generally, shift by k letters, k is the key Monoalphabetic cipher – map each letter to some other letter A b c d e f … w x y z Q W E R T Y … V B N M <= the key EEC688: Secure & Dependable Computing

15. Cryptanalysis of Substitution Ciphers Brute force cryptanalysis would have to try 26! permutations of a particular ciphertext message Smarter way: use frequencies of letters, pairs of letter etc., or by guessing a probable word or phrase. Most frequently occurred Letters: e, t, o, a, n, … Digrams: th, in, er, re, an, … Trigrams: the, ing, and, ion, ent Words: the, of, and, to, a, in, that, … When messages are long enough, the frequency distribution analysis quickly betrays many of the letters of the plaintext EEC688: Secure & Dependable Computing

16. Transposition Ciphers Substitution cipher – preserves order of plaintext symbols but disguises them Transposition cipher – reorders (rearrange) symbols but does not disguise them. It is also called permutation With transposition, the cryptography aims for Widely spreading the information from the message or the key across the ciphertext Transpositions try to break established patterns EEC688: Secure & Dependable Computing

17. Columnar Transposition Plaintext written in rows, number of columns = key length Key is used to number the columns Ciphertext read out by columns, starting with column whose key letter is lowest EEC688: Secure & Dependable Computing

18. Columnar Transposition A transposition cipher example EEC688: Secure & Dependable Computing

19. One-Time Pads One-time pad: construct an unbreakable cipher Choose a random bit string as the key Convert the plaintext into a bit string Compute the XOR of these two strings, bit by bit The resulting ciphertext cannot be broken, because in a sufficiently large sample of ciphertext, each letter will occur equally often, as will every digram, every trigram, and so on => There is simply no information in the message because all possible plaintexts of the given length are equally likely 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

20. One-Time Pads Disadvantages The key cannot be memorized, both sender and receiver must carry a written copy with them Total amount of data can be transmitted is limited by the amount of key available Sensitive to lost or inserted characters 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

21. Symmetric-Key Algorithms DES – The Data Encryption Standard AES – The Advanced Encryption Standard Other Ciphers Cipher Modes 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

22. Data Encryption Standard Developed by IBM. US standard for unclassified info(1977) Same key for encryption as for decryption Encrypts in 64-bit blocks Uses 56-bit key Has 19 stages, 16 parameterized by different functions of the key 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

23. Triple DES Triple DES – effectively increases the key length. It uses two keys and three stages In first stage, the plaintext is encrypted using DES in the usual way with K1 In second stage, DES is run in decryption mode, using K2 as the key In third stage, another DES encryption is done with K1 Triple DES encryption Triple DES decryption 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

24. AES – The Advanced Encryption Standard AES is a result of a cryptographic contest Organized by NIST in 1997 Rules for AES proposals The algorithm must be a symmetric block cipher The full design must be public Key lengths of 128, 192, and 256 bits supported Both software and hardware implementations required The algorithm must be public or licensed on nondiscriminatory terms Winner: Rijndael (from two Belgian cryptographers: Joan Daemen and Vincent Rijmen) 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

25. Other Symmetric-Key Ciphers 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

26. Stream Ciphers Stream ciphers: convert one symbol of plaintext immediately into a symbol of ciphertext The transformation depends only on the symbol, the key, and the control information of the encryption algorithm 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

27. Block Ciphers Block cipher: encrypts a group of plaintext symbols as one block It works on blocks of plaintext and produce blocks of ciphertext The columnar transposition is an example of block ciphers 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

28. Cipher Modes A block cipher (e.g., AES & DES) is basically a monoalphabetic substitution cipher using big characters Whenever the same plaintext block goes in the front end, the same ciphertext block comes out the back end If you encrypt the plaintext abcdefgh 100 times with same DES key, you get the same ciphertext 100 times An intruder can exploit this property to help subvert the cipher 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

29. Electronic Code Book Mode In ECB mode, each plaintext block is encrypted independently with the block cipher ECB allows easy parallelization to yield higher performance. However, no processing is possible before a block is seen 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

30. Electronic Code Book Mode - Problems In ECB, plaintext patterns are not concealed Each identical block of plaintext gives an identical block of ciphertext. The plaintext can be easily manipulated by removing, repeating, or interchanging blocks Example 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

31. Cipher Block Chaining Mode To avoid the ECB mode problem: replacing a block will cause the plaintext decrypted starting at the replaced to become garbage Exclusive OR the encrypted text with the next block of plaintext before encryption: Need an initialization vector (IV) to boostrap C0 = E(P0 XOR IV), C1 = E(P1 XOR C0), etc. Drawback: must wait until full 64-bit (128-bit) block to arrive to decrypt 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

32. Cipher Block Chaining Mode Exclusive OR the encrypted text with the next block of plaintext before encryption: C0 = E(P0 XOR IV), C1 = E(P1 XOR C0), etc. Initialization Vector Decryption Encryption 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

33. Cipher Feedback Mode Basic operation (Pi and Ci are blocks): Ci = E(Ci-1) XOR Pi, Pi = E(Ci-1) XOR Ci, C0 = IV Issue: Losing a single bit or byte will ruin all data after that 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

34. Cipher Feedback Mode To enable byte-by-byte encryption When plaintext byte n (Pn) arrives, DES algorithm operates a 64-bit register to generate a 64-bit ciphertext Leftmost byte of that ciphertext is extracted and XORed with Pn That byte is transmitted on the transmission line The shift register is shifted left 8 bits, causing Cn-8 to fall off the left end, and Cn is inserted in the position just vacated at the right end by C9 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

35. Cipher Feedback Mode Encryption Decryption 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

36. Stream Cipher Mode To be insensitive to transmission error, an arbitrarily large sequence of output blocks, called the keystream, is treated like a one-time pad and XORed with the plaintext to get the ciphertext It works by encrypting an IV, using a key to get an output block The output block is then encrypted, using the key to get a second output block This block is then encrypted to get a third block, and so on The keystream is independent of the data, so (1) It can be computed in advance (2) It is completely insensitive to transmission errors 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

37. Stream Cipher Mode Encryption Decryption 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

38. Stream Cipher Mode It is essential never to use the same (key, IV) pair twice with a stream cipher because doing so will generate the same keystream each time Using the same keystream twice exposes the ciphertext to a keystream reuse attack Stream cipher mode is also called output feedback mode 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

39. Keystream Reuse Attack Plaintext block, P0, is encrypted with the keystream to get P0 XOR K0 Later, a second plaintext block, Q0, is encrypted with the same keystream to get Q0 XOR K0 An intruder who captures both ciphertext blocks can simply XOR them together to get P0 XOR Q0, which eliminates the key The intruder now has the XOR of the two plaintext blocks If one of them is known or can be guessed, the other can also be found In any event, the XOR of two plaintext streams can be attacked by using statistical properties of the message 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

40. Counter Mode To allow random access to encrypted data The IV plus a constant is encrypted, and the resulting ciphertext XORed with the plaintext By stepping the IV by 1 for each new block, it is easy to decrypt a block anywhere in the file without first having to decrypt all of its predecessors 1/2/2020 EEC688: Secure & Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

41. Exercise Q1. Assuming that the DES block cipher is used in the Electronic Code Book mode. If one bit in a block of ciphertext is inverted during transmission, how many bits will likely be damaged after decryption at the receiver? 1/2/2020 EEC693: Secure and Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

42. Exercise Q2. Assuming that the DES block cipher is used in the Cipher Block Chaining mode. If one bit of ciphertext is inverted during transmission, how many bits will likely be damaged after decryption at the receiver? 1/2/2020 EEC693: Secure and Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

43. Exercise Q3. Assuming that the DES block cipher is used in the Cipher Feedback mode. If one bit of ciphertext is inverted during transmission, how many bits will likely be damaged after decryption at the receiver (for both variations)? 1/2/2020 EEC693: Secure and Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao

44. Exercise Q4. Assuming that the DES block cipher is used in the Stream Cipher mode (it is also called output feedback mode). If one bit of ciphertext is inverted during transmission, how many bits will likely be damaged after decryption at the receiver? 1/2/2020 EEC693: Secure and Dependable Computing EEC688: Secure & Dependable Computing Wenbing Zhao