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David Evans http://www.cs.virginia.edu/evans

Lecture 2: Perfect Ciphers (in Theory, not Practice). Shannon was the person who saw that the binary digit was the fundamental element in all of communication. That was really his discovery, and from it the whole communications revolution has sprung. R G Gallager

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David Evans http://www.cs.virginia.edu/evans

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  1. Lecture 2: Perfect Ciphers (in Theory, not Practice) Shannon was the person who saw that the binary digit was the fundamental element in all of communication. That was really his discovery, and from it the whole communications revolution has sprung. R G Gallager I just wondered how things were put together. Claude Shannon David Evans http://www.cs.virginia.edu/evans Claude Shannon, 1916-2001 CS588: Cryptology University of Virginia Computer Science

  2. Menu • Survey Results • Perfect Ciphers • Entropy and Unicity University of Virginia CS 588

  3. Survey Responses • Majors: Cognitive Science, Computer Science (13), Computer Engineering (2), Economics, Math • Year: Third year: 6, Fourth Year: 10, Grad: 1, 2005: 1 • Midterm: March 3: 12, March 15: 3, March 17: 2, March 22: 1 • Broken in?: No: 13, Yes: 5 Full answers are on the course web site University of Virginia CS 588

  4. What was the coolest thing you learned last semester? “i've been sitting here for like five minutes trying to think of something. perhaps that aristotle (or perhaps plato) hates bands that sell out.” “hmm.... I learned there was a huge molasses explosion at the Boston harbor in the early 20th century.... not really all that cool i guess because a lot of people died but still pretty interesting.” University of Virginia CS 588

  5. Break In Story In high-school the administrators installed a fairly restrictive rights-control program called "FoolProof". It was so restrictive, however, that my AP Comp. Sci class was unable to compile and run programs on the main HD forcing us to use a floppy disk for our source and intermediate files, which was painfully slow as projects increased in size. Having unsuccessfully lobbied to have restrictions lifted so we could compile and run programs on a temporary directory. I tried to convince them that there were more eloquent and flexible security programs out there. So, I did a little research on the version of FoolProof being used. It turns out that this version of FoolProof had two major security flaws: University of Virginia CS 588

  6. Break In Story 1) A "backdoor" password used by tech support that is hardcoded into the executable and 2) The password information is stored in plaintext within main memory some number of bytes into one of its main data structures which was marked by an ascii string which was some sort of constant containing the version information. So, I acquired a utility which would allow me to browse and search the contents of physical memory determined what this ascii string would be for the given version of FoolProof and searched memory. Sure enough I came up with a match and about 8 bytes later a plaintext ascii string: "WhatAFool" University of Virginia CS 588

  7. Polling Protocol University of Virginia CS 588

  8. Last Time • Big keyspace is not necessarily a strong cipher • Claim: One-Time Pad is perfect cipher • In theory: depends on perfectly random key, secure key distribution, no reuse • In practice: usually ineffective (VENONA, Lorenz Machine) • Today: what does is mean to be a perfect cipher? University of Virginia CS 588

  9. Ways to Convince • “I tried really hard to break my cipher, but couldn’t. I’m a genius, so I’m sure no one else can break it either.” • “Lots of really smart people tried to break it, and couldn’t.” • Mathematical arguments – key size (dangerous!), statistical properties of ciphertext, depends on some provably (or believed) hard problem • Invulnerability to known cryptanalysis techniques (but what about undiscovered techniques?) • Show that ciphertext could match multiple reasonable plaintexts without knowing key • Simple monoalphabetic secure for about 10 letters of English: XBCF CF FWPHGW • This is secure • Spat at troner University of Virginia CS 588

  10. Claude Shannon • Master’s Thesis [1938] – boolean algebra in electronic circuits • “Mathematical Theory of Communication” [1948] – established information theory • “Communication Theory of Secrecy Systems” [1945/1949] (linked from notes) • Invented rocket-powered Frisbee, could juggle four balls while riding unicycle University of Virginia CS 588

  11. Entropy Amount of information in a message: H(M) =  Prob [Mi] log ([1 / Prob [Mi]) over all possible messagesMi n i=1 University of Virginia CS 588

  12. Entropy n If there are n equally probable messages, H(M)=1/n log n =n * (1/n log n)) = log n Base of log is alphabet size, so for binary: H(M) = log2n where n is the number of possible meanings i=1 University of Virginia CS 588

  13. Entropy Example M = months of the year H(M) • = log2 12  3.6 • (need 4 bits to encode a year) University of Virginia CS 588

  14. Rate • Absolute rate: how much information can be encoded R = log2 Z(Z=size of alphabet) REnglish = • Actual rate of a language: r = H(M) / N Mis a source of N-letter messages rof months spelled out using 8-bit ASCII: log2 26  4.7 bits / letter = log2 12 / (8 letters * 8 bits/letter)  0.06 University of Virginia CS 588

  15. Rate of English • r(English) is about .28 letters/letter (1.3 bits/letter) [Book uses 1.5] • How can one estimate this? • How many meaningful 20-letter messages in English? r = H(M) / N .28 = H(M)/20 H(M) = 5.6 = log26n n = 265.6 ~ 83 million (of 2*1028 possible) Probability that 20-letters are sensible English is About 1 in 2 * 1020 University of Virginia CS 588

  16. Redundancy • Redundancy (D) is defined: D = R – r • Redundancy in English: D = 1 - .28 = .72 letters/letter D = 4.7 – 1.3 = 3.4 bits/letter Each letter is 1.3 bits of content, and 3.4 bits of redundancy. (~72%) • 7-bit ASCII (as in PS1, problem 5) D = 7 – 1.3 = 5.7 81% redundancy, 19% information University of Virginia CS 588

  17. Unicity Distance • Entropy of cryptosystem: (K = number of possible keys) H(K) = logAlphabet SizeK if all keys equally likely H(64-bit key) = log2 264 = 64 • Unicity distance is defined as: U = H(K)/D Expected minimum amount of ciphertext needed for brute-force attack to succeed. University of Virginia CS 588

  18. Unicity Examples • Monoalphabetic Substitution H(K) = log2 26!87 D = 3.4 (redundancy in English) U = H(K)/D 25.5 Intuition: if you have 25 letters, probably only matches one possible plaintext. D = 0 (random bit stream) U = H(K)/D = infinite University of Virginia CS 588

  19. Unicity Distance • Probabilistic measure of how much ciphertext is needed to determine a unique plaintext • Does not indicate how much ciphertext is needed for cryptanalysis • If you have less than unicity distance ciphertext, can’t tell if guess is right. • As redundancy approaches 0, hard to cryptanalyze even simple cipher. University of Virginia CS 588

  20. Shannon’s Theory [1945] Message space: { M1, M2,..., Mn } Assume finite number of messages Each message has probability p(M1) + p(M2) + ... + p(Mn) = 1 Key space: { K1, K2,..., Kl } (Based on Eli Biham’s notes) University of Virginia CS 588

  21. Perfect Cipher: Definition Ka A perfect cipher: there is some key that maps any message to any ciphertext with equal probability. For any i, j: p (Mi|Cj) = p (Mi) C1 M1 Kb C2 M2 ... ... Mn Cn University of Virginia CS 588

  22. Conditional Probability Prob [B | A] = The probability of B, given that A occurs Prob [ coin flip is tails ] = ½ Prob [ coin flip is tails | last coin flip was heads ] = ½ Prob [ today is Monday | yesterday was Sunday] = 1 Prob [ today is a weekend day | yesterday was a workday] = 1/5 University of Virginia CS 588

  23. Calculating Conditional Probability P [B | A ] = Prob [ A B ] Prob [ A ] Prob [ coin flip is tails | last coin flip was heads ] = Prob [ coin flip is tails and last coin flip was heads ] Prob [ last coin flip was heads ] = (½ * ½) / ½ = ½ University of Virginia CS 588

  24. Wrong! P(A B) = P(A) * P(B) only if A and B are independent events P (today is a weekend day | yesterday was a workday) = P (today is a weekend day and yesterday was a workday) / P (yesterday was a workday) = P (today is a weekend day) * P(yesterday was a workday) / P (yesterday was a workday) = 2/7 * 5/7 / 5/7 = 2/7 University of Virginia CS 588

  25. Perfect Cipher Definition:  i, j: P (Mi|Cj) = P (Mi) A cipher is perfect iff:  M, CP (C | M) = P (C) Or, equivalently:  M, CP (M | C) = P (M) University of Virginia CS 588

  26. Perfect Cipher  M, CP (C | M) = P (C)  M, CP (C) =  P(K) such thatEK(M) = C Or:  C P(K) is independent of Msuch thatEK(M) = C K K Without knowing anything about the key, any ciphertext is equally likely to match any plaintext. University of Virginia CS 588

  27. Example: Monoalphabetic • Random monoalphabetic substitution for one letter message:  C,M: P (C) = P (C | M) = 1/26. University of Virginia CS 588

  28. Example: One-Time Pad For each bit: P(Ci = 0) = P(Ci = 0 | Mi = 0) = P (Ci = 0 | Mi = 1) = ½ since Ci = Ki Mi P (Ki Mi = 0) = P (Ki = 1) * P (Mi = 1) + P (Ki = 0) * P (Mi = 0) Truly randomKmeansP (Ki = 1) = P (Ki = 0) = ½ = ½ * P (Mi = 1) + ½ * P (Mi = 0) = ½ * (P (Mi = 1) + P (Mi = 0)) = ½ All key bits are independent, so: P(C) = P(C | M) QED. University of Virginia CS 588

  29. Perfect Cipher Keyspace Theorem Theorem: If a cipher is perfect, there must be at least as many keys (l) are there are possible messages (n). University of Virginia CS 588

  30. Proof by Contradiction Suppose there is a perfect cipher with l < n. (More messages than keys.) Let C0 be some ciphertext with P(C0) > 0. There exist mmessages M such that M = DK(C0 ) n - mmessagesM0 such that M0 DK(C0 ) We know 1  m  l< n so n - m > 0 and there is at least one message M0. University of Virginia CS 588

  31. Proof, cont. Consider the message M0 where M0 DK(C0 ) for any K. So, P (C0 |M0) = 0. In a perfect cipher, P (C0 |M0) = P (C0) > 0. Contradiction! It isn’t a perfect cipher. Hence, all perfect ciphers must have l  n. University of Virginia CS 588

  32. Example: Monoalphabetic Random monoalphabetic substitution is not a perfect cipher for messages of up to 20 letters: l = 26!n = 2620 l < n its not a perfect cipher. In previous proof, could choose C0 = “AB” and M0 = “ee” and P (C0 |M0) = 0. University of Virginia CS 588

  33. Example: Monoalphabetic Is random monoalphabetic substitution a perfect cipher for messages of up to 2 letters? l = 26!n = 262 l  n. No! Showing l  n does not prove its perfect. University of Virginia CS 588

  34. Summary • Cipher is perfect:  i, j: p (Mi|Cj) = p (Mi) Given any ciphertext, the probability that it matches any particular message is the same. • Equivalently,  i, j: p (Ci|Mj) = p (Ci) Given any plaintext, the probability that it matches any particular ciphertext is the same. University of Virginia CS 588

  35. Imperfect Cipher • To prove a cipher is imperfect either: • Find a ciphertext that is more likely to be one message than another • Show that there are more messages than keys • Implies there is some ciphertext more likely to be one message than another even if you can’t find it. University of Virginia CS 588

  36. Charge • Problem Set 1: due Feb 3 • All other questions covered (as much as we will cover them in class) already • Next time: • Classical ciphers (Nate Paul) University of Virginia CS 588

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