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Introduction to Security

Introduction to Security. Attacks. Interception Interruption Modification Fabrication. Interception (eavesdropping). Unauthorized party gains access to service or data Example: Wiretapping to capture data into a network and coping of files. Interruption (denial of service).

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Introduction to Security

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  1. Introduction to Security

  2. Attacks Interception Interruption Modification Fabrication

  3. Interception (eavesdropping) Unauthorized party gains access to service or data Example: Wiretapping to capture data into a network and coping of files

  4. Interruption (denial of service) Services or data become unavailable Examples: Destruction of a piece of hardware, cutting of cable and disabling of a file management system

  5. Modification Unauthorized party changes the data or tampers with the service Examples: Changing values in a file, altering a program so that it performs differently and changing the contents of messages that are sent over the network

  6. Fabrication Unauthorized party generates additional data or activity Examples Hacker gaining access to a person’s email and sending messages, and adding records to a file

  7. Cryptography

  8. Given credit where it is due Most slides are from B. A. Miller at Mount Allison University Some slides are from Scott Shenker and Ion Stoica at University of California, Berkeley I modified and added some slides

  9. What is cryptography? • kryptos – “hidden” • grafo – “write” • Keeping messages secret • Usually by making the message unintelligible to anyone that intercepts it

  10. The Problem Private Message Bob Alice Eavesdropping Eve

  11. The Solution Private Message Private Message Encryption Decryption Scrambled Message Bob Alice Eavesdropping Eve

  12. What do we need? • Bob and Alice want to be able to encrypt/decrypt easily • But no one else should be able to decrypt • How do we do this? • Keys!

  13. Using Keys Nonsense Encryption Decryption Ciphertext Plaintext Plaintext

  14. The Shift Cipher • We “shift” each letter over by a certain amount Plaintext five red balloons f + 3 = I i + 3 = L v + 3 = Y … Key = 3 Encryption Ciphertext ILYH UHG EDOORRQV

  15. The Shift Cipher cont. • To decrypt, we just subtract the key Ciphertext ILYH UHG EDOORRQV I - 3 = f L - 3 = i Y - 3 = v … Key = 3 Decryption five red balloons Plaintext

  16. What’s wrong with the shift cipher? • Not enough keys! • If we shift a letter 26 times, we get the same letter back • A shift of 27 is the same as a shift of 1, etc. • So we only have 25 keys (1 to 25) • Eve just tries every key until she finds the right one

  17. The Substitution Cipher Plaintext Ciphertext • Rather than having a fixed shift, change every plaintext letter to an arbitrary ciphertext letter

  18. The Substitution Cipher cont. Plaintext five red balloons Key = f = A i = L v = R … Encryption ALRD HDS XGOOYYBW Ciphertext

  19. The Substitution Cipher cont. • To decrypt we just look up the ciphertext letter in the table and then write down the matching plaintext letter • How many keys do we have now? • A key is just a permutation of the letters of the alphabet • There are 26! permutations • 403291461126605635584000000 • What’s wrong with this substitution Cipher?

  20. Frequency Analysis • In English (or any language) certain letters are used more often than others • If we look at a ciphertext, certain ciphertext letters are going to appear more often than others • It would be a good guess that the letters that occur most often in the ciphertext are actually the most common English letters

  21. Letter Frequency • This is the letter frequency for English • The most common letter is ‘e’ by a large margin, followed by ‘t’, ‘a’, and ‘o’ • ‘J’, ‘q’, ‘x’, and ‘z’ hardly occur at all

  22. Frequency Analysis in Practice • Suppose this is our ciphertext • dq lqwurgxfwlrq wr frpsxwlqj surylglqj d eurdg vxuyhb ri wkh glvflsolqh dqg dq lqwurgxfwlrq wr surjudpplqj. vxuyhb wrslfv zloo eh fkrvhq iurp: ruljlqv ri frpsxwhuv, gdwd uhsuhvhqwdwlrq dqg vwrudjh, errohdq dojheud, gljlwdo orjlf jdwhv, frpsxwhu dufklwhfwxuh, dvvhpeohuv dqg frpslohuv, rshudwlqj vbvwhpv, qhwzrunv dqg wkh lqwhuqhw, wkhrulhv ri frpsxwdwlrq, dqg duwlilfldo lqwhooljhqfh.

  23. Ciphertext distribution English distribution In our ciphertext we have one letter that occurs more often than any other (h), and 6 that occur a good deal more than any others (d, l, q, r, u, and w) There is a good chance that h corresponds to e, and d, l, q, r, u, and w correspond to the 6 next most common English letters

  24. Frequency Analysis cont. • If we replace ‘e’ with ‘h’ and the 6 next most common letters with their matches, the ciphertext becomes • an intro???tion to ?o?p?tin? pro?i?in? a ?roa? ??r?e? o? t?e ?i??ip?ine an? an intro???tion to pro?ra??in?. ??r?e? topi?? ?i?? ?e ??o?en ?ro?: ori?in? o? ?o?p?ter?, ?ata repre?entation an? ?tora?e, ?oo?ean a??e?ra, ?i?ita? ?o?i? ?ate?, ?o?p?ter ar??ite?t?re, a??e???er? an? ?o?pi?er?, operatin? ???te??, net?or?? an? t?e internet, t?eorie? o? ?o?p?tation, an? arti?i?ia? inte??i?en?e.

  25. Classical to Modern Cryptography • Classical cryptography • Encryption/decryption done by hand • Modern cryptography • Computers to encrypt and decrypt • Same principles, but automation allows ciphers to become much more complex

  26. The Enigma Machine • German encryption and decryption machine used in WWII • Essentially a complex, automated substitution cipher

  27. How did Enigma work? • Rotors have different wiring connecting input to output • Rotors move after each keypress • The key is the initial position of the three rotors

  28. Breaking the Enigma • Britain set up its cryptanalysis team in Bletchley Park • They consistently broke German codes throughout the war • Important location in the history of computing • Alan Turing: British Cryptanalyst • COLOSSUS: used by British codebreakers for Cryptanalysis

  29. Cryptography in the Computer Age • Working with binary instead of letters • We can do things many, many times • Think of an Enigma machine that has 2128 pairs of symbols on each rotor, and 20 rotors • Other than that, the basic principles are the same as classical cryptography

  30. Modern Ciphers • We design one relatively simple scrambling method (called a round) and repeat it many times • Think of each round as a rotor on the Enigma • One round may be easy to break, but when you put them all together it becomes very hard • Almost all ciphers follow one of two structures • SPN (Substitution Permutation Network) • Feistel Network (basis for DES) • These describe the basic structure of a round

  31. Modern Ciphers in Practice • Follow SPN/Feistel structure in general, but with added twists for security • There are two important ciphers in the history of modern cryptography • DES (Data Encryption Standard) • AES (Advanced Encryption Standard)

  32. DES • U.S. Government recognized the need to have a standardized cipher for secret documents • DES was developed by IBM in 1976 • Analysis of DES was the beginning of modern cryptographic research

  33. Breaking DES • The key length of DES was too short • If a key is 56 bits long, that means there are 256 possible keys • “DES Cracker” machines were designed to simply try all possible keys • Increase key length to 128 bit • Triple DES

  34. Breaking DES cont. • DES was further weakened by the discovery of differential cryptanalysis • Biham and Shamir in 1990; The most significant advance in cryptanalysis since frequency analysis • Ideally a ciphertext should be completely random, there should be no connection to its matching plaintext • Differential analysis exploits the fact that this is never actually the case; Uses patterns between plaintext and ciphertext to discover the key

  35. Developing the AES • With DES effectively broken, a new standard was needed • In 2001, the Rijndael cipher was selected to become the Advanced Encryption Standard

  36. The Problem of Symmetric Key Cryptography • Up until now we’ve been talking about symmetric key cryptography • Alice and Bob are using the same key to encrypt/decrypt • Problem: How does Bob get the key to Alice when Eve is eavesdropping? • Up until 1976 the only solution was to physically give Alice the key in a secure environment

  37. Public Key Cryptography • Diffie and Hellman published a paper in 1976 providing a solution • We use one key for encryption (the public key) and a different key for decryption (the private key) • Everyone knows Alice’s public key, so they can encrypt messages and send them to her • But only Alice has the key to decrypt those messages • No one can figure out Alice’s private key even if they know her public key

  38. Using Public Keys Nonsense Encryption Decryption Ciphertext Plaintext Plaintext

  39. Public Key Cryptography in Practice • The problem is that public key algorithms are too slow to encrypt large messages • Instead Bob uses a public key algorithm to send Alice the symmetric key, and then uses a symmetric key algorithm to send the message • The best of both worlds! • Security of public key cryptography • Speed of symmetric key cryptography

  40. Sending a Message What’s your public key? Bob picks a symmetric key and encrypts it using Alice’s public key Alice decrypts the symmetric key using her private key Then sends the key to Alice Bob encrypts his message using the symmetric key Alice decrypts the message using the symmetric key hi Then sends the message to Alice

  41. The RSA Public Key Cipher • The most popular public key cipher is RSA, developed in 1977 • Named after its creators: Rivest, Shamir, and Adleman • Uses the idea that it is really hard to factor large numbers • Create public and private keys using two large prime numbers • Then forget about the prime numbers and just tell people their product • Anyone can encrypt using the product, but they can’t decrypt unless they know the factors • If Eve could factor the large number efficiently she could get the private key, but there is no known way to do this

  42. Public-Key Cryptography: RSA (Rivest, Shamir, and Adleman) • Sender uses a public key • Advertised to everyone • Receiver uses a private key Plaintext Plaintext Internet Encrypt with public key Decrypt with private key Ciphertext

  43. Generating Public and Private Keys • Choose two large prime numbers p and q (~ 256 bit long) and multiply them: n = p*q • Chose encryption key e such that e and (p-1)*(q-1) are relatively prime • Compute decryption key d, where d = e-1mod ((p-1)*(q-1)) (equivalent to d*e = 1 mod ((p-1)*(q-1))) • Public key consists of pair (n, e) • Private key consists of pair (n, d)

  44. RSA Encryption and Decryption • Encryption of message block m: • c = memod n • Decryption of ciphertext c: • m = cd mod n

  45. Example (1/2) • Choose p = 7 and q = 11  n = p*q = 77 • Compute encryption key e: (p-1)*(q-1) = 6*10 = 60  chose e = 13 (13 and 60 are relatively prime numbers) • Compute decryption key d such that 13*d = 1 mod 60  d = 37 (37*13 = 481)

  46. Example (2/2) • n = 77; e = 13; d = 37 • Send message block m = 7 • Encryption: c = me mod n = 713 mod 77 = 35 • Decryption: m = cd mod n = 3537 mod 77 = 7

  47. Properties • Confidentiality • A receiver B computes n, e, d, and sends out (n, e) • Everyone who wants to send a message to B uses (n, e) to encrypt it • How difficult is to recover d ? (Someone that can do this can decrypt any message sent to B!) • Recall that d = e-1mod ((p-1)*(q-1)) • So to find d, you need to find primes factors p and q • This is provable very difficult

  48. RSA Factoring Challenge • In mathematics, the RSA numbers are a set of large semiprimes (numbers with exactly two prime factors) that are part of the RSA Factoring Challenge. • RSA-768 has 232 decimal digits and was factored on December 12, 2009. It’s the largest factored RSA number to date. • RSA-2048 may not be factorizable for many years to come, unless considerable advances are made in integer factorization or computational power in the near future.

  49. RSA Factoring Challenge • Suppose, for example, that in the year 2020 a factorization of RSA-1024 is announced that requires 6 months of effort on 100,000 workstations. In this hypothetical situation, would all 1024-bit RSA keys need to be replaced? • The answer is no. If the data being protected needs security for significantly less than six months, and its value is considerably less than the cost of running 100,000 workstations for that period, then 1024-bit keys may continue to be used.

  50. Are we all secure now? • Unfortunately not, there are still many problems that need to be dealt with • How does Bob know that he’s really talking to Alice? • How does Alice know that the message she receives hasn’t been tampered with? • How does Alice know the message was sent by Bob?

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