RSA and its Mathematics Behind July 2011
Topics Modular Arithmetic Greatest Common Divisor Euler’s Identity RSA algorithm Security in RSA
Modular Arithmetic A system of arithmetic for integers, where numbers wrap around after they reach a certain value—the modulus Modular or "clock" arithmetic is arithmetic on a circle instead of a number line In modulo N , we use only the twelve whole numbers from 0 through N-1 The 12-hour clock : modulo 12 If the time is 9:00 now, then 4 hours later it will be 1:00 9+4 =13 13 % 12= 1
Modular Clock Arithmetic 1:00 and and 13:00 hours are the same 1:00 and and 25:00 hours are the same 1 13 (mod 12) a b (mod n) n is the modulus a is congruent to b modulo n a-b is an integer multiple of (divisible by) n a % n = b % n
Example 38 14 (mod 12) 38-14 = 24 ; multiple of 12 38 2 (mod 12) 38-2 = 36 ; multiple of 12 The same rule for negative number -8 7 (mod 5) 2 -3 (mod 5) -3 -8 (mod 5)
Congruence Class Example 5 10 1 6 11 -- 2 7 12 3 8 13 -- 14 9 4 -- 1 6 11 (mod 5) Congruence Classes of the integers modulo 5
Replace of congruence item Let 11 +16 3 (mod 12) and 16 4 (mod 12), therefore 11 +16 11 + 4 (mod 12) Let 9835 7 (mod 12) and 1177 1 (mod 12), therefore 9835*1177 7 * 1 7 (mod 12)
Modular Arithmetic Notation Modulus operator Congruence relation a = b mod n a b (mod n) Inputs a number a and a base b, outputs a mod b as the remiander of ab (value between 0 and b –1) Relates two numbers a, b to each other relative some base = means that integer a is the reminder of the division of integer b by integer n indicates that the integers a and b fall into the same congruence class modulo n (same remainder when diving by b) 2 = 14 mod 3 14 2 (mod 3)
Exercise (I) A: Compute 113 mod 24: -29 mod 7
Exercise (I), cont A: Compute 113 mod 24: -29 mod 7
Exercise (I), cont A: Compute 113 mod 24: -29 mod 7
Exercise (I), cont A: Compute 113 mod 24: -29 mod 7
Exercise (II) Q: Which of the following are true? 3 3 (mod 17)
Exercise (II), cont A: 3 3 (mod 17) 3 -3 (mod 17) True. any number is congruent to itself (3-3 = 0, divisible by all) 3 -3 (mod 17) False. (3-(-3)) = 6 isn’t divisible by 17. 172 177 (mod 5) True. 172-177 = -5 is a multiple of 5 -13 13 (mod 26) True: -13-13 = -26 divisible by 26.
Topics Modular Arithmetic Greatest Common Divisor Euler’s Identity RSA algorithm Security in RSA
Greatest Common Divisor Def: Let a,b be integers, not both zero. The greatest common divisor of a and b (or gcd(a,b) ) is the biggest number d which divides both a and b without a remainder gcd (8,12) =4 Find gcd (54, 24) 54x1 = 27x2 = 18x3 = 9x6; {1, 2 ,3, 6, 9, 18, 27, 54} 24x1 = 12x2 = 8x3 = 4x6; {1, 2 ,3, 4, 6, 8, 12, 54} Share number : {1, 2, 3, 6} gcd (54, 24) = 6
Finding GCD gcd(a,0) = a, and gcd(a,b) = gcd(b, a mod b) Find gcd(132, 28) : r = 132 mod 28 = 20 => gcd(28, 20) r = 28 mod 20 = 8 => gcd(20,8) r = 20 mod 8 = 4 => gcd(8,4) r = 8 mod 4 = 0 => gcd(4,0) gcd(132, 28) = 4 1 2 3 4 5 a 132 28 20 8 b
GCD and Relatively Prime Def: two integers a and b are said to be relatively prime (also called co-prime) if gcd(a,b) = 1 so no prime common divisors. Find gcd(28, 15) : r = 28 mod 15 = 13 => gcd(15, 13) r = 15 mod 13 = 2 => gcd(13, 2) r = 13 mod 2 = 1 => gcd(2,1) r = 2 mod 1 = 0 => gcd(1,0) gcd(28,15) = 1 15 and 28 are relative prime Since a prime number has no factors besides itself, clearly a prime number is relatively prime to every other number (except for multiples of itself)
Test Relative Prime Q: Find the following gcd’s: gcd(77,11) gcd(77,33)
Test Relative Prime A: gcd(77,11) = 11 gcd(77,33) = 11 gcd(23,7) = 1. Therefore 23 and 7 are relatively prime.
Topics Modular Arithmetic Greatest Common Divisor Euler’s Identity RSA algorithm Security in RSA
Euler's Totient Function (N) = the numbers between 1 and N - 1 which are relatively prime to N Thus: (4) = 2 (1 and 3 are relatively prime to 4) (5) = 4 (1, 2, 3, and 4 are relatively prime to 5) (6) = 2 (1 and 5 are relatively prime to 6) (7) = 6 (1, 2, 3, 4, 5, and 6 are relatively prime to 7) (8) = 4 (1, 3, 5, and 7 are relatively prime to 8) (9) = 6 (1, 2, 4, 5, 7, and 8 are relatively prime to 9) Compute (N) in C code: phi = 1; for (i = 2 ; i < N ; ++i) if (gcd(i, N) == 1) ++phi;
Euler's Totient Function, cont Note that (N) = N-1 when N is prime Somewhat obvious fact that (N) is also easy to calculate when N has exactly two different prime factors: (p*q) = (p-1)*(q-1) Example: Find (15) (15) = (3*5) = (3-1) * (5-1) = 4*2 =8 {1, 2, 4, 7, 8, 11, 13, and 14}
Euler’s Totient Theorem One of the important keys to the RSA algorithm If gcd(m, n) = 1 and m < n, then m(n) 1 (mod n) m(n) 1 (mod n) where (n) = (p1-1)*(q-1) relatively prime m (p-1)(q-1) mod n = 1 Example: m (p-1)(q-1) mod n = 1 3840 mod 55 = 1 M=38 replace (p-1)(q-1) with (11-1)(5-1) n=55 Interpretation : If m and n are relatively prime, with m being the smaller number, then when we multiply m with itself (n) times and divide the result by n, the remainder will always be 1
More in Euler’s Theorem Multiply both sides of equation by m m (p-1)(q-1) mod n = 1 m (p-1)(q-1) *m mod n = 1*m m (p-1)(q-1)+1 mod n = m m (n)+1 mod n = m
The Road to crypto If we can find two numbers, call them e and d, such that e*d = [(p-1)(q-1)]+1 n = p*q Use e as the private key and d as the public key; Encrypts: c me (mod n) Decrypts: m cd (mod n) cd = (me (mod n))d = med (mod n) = m(p-1)(q-1)+1 (mod n) = m(n)+1 (mod n) = m m (n)+1 mod n = m Recall Euler’s theorem
A trapdoor one-way function Public key c = f(m) = me mod n Message m Ciphertext c m = f-1(c) = cd mod n Private key (trapdoor information) n = p*q (p & q: primes) e*d = 1 mod (p-1)(q-1)
Topics Modular Arithmetic Greatest Common Divisor Euler’s Identity RSA algorithm Security in RSA
RSA Public key cryptosystem Shamir Rivest Adleman Public key cryptosystem Proposed in 1977 by Ron L. Rivest, Adi Shamir and Leonard Adleman at MIT Best known & widely used public- key scheme Based on exponentiation in a finite (Galois) field over integers modulo a prime Main patent expired in 2000 RSA is the best known, and by far the most widely used general public key encryption algorithm, and was first published by Rivest, Shamir & Adleman of MIT in 1978 [RIVE78]. Since that time RSA has reigned supreme as the most widely accepted and implemented general-purpose approach to public-key encryption. It is based on exponentiation in a finite (Galois) field over integers modulo a prime, using large integers (eg. 1024 bits). Its security is due to the cost of factoring large numbers. Rivest Shamir Adleman
RSA Algorithm Uses two keys : e and d for encryption and decryption A message m is encrypted to the cipher text by c = me mod n The ciphertext is recover by m = cd mod n Because of symmetric in modular arithmetic m = cd mod n = (me)d mod n = (md)e mod n One can use one key to encrypt a message and another key to decrypt it
RSA Key Setup Selecting two large primes at random : p, q Typically 512 to 2048 bits Computing their system modulus n=p*q note ø(n)=(p-1)(q-1) Selecting at random the encryption key e where 1<e<ø(n), gcd(e,ø(n))=1 Meaning: there must be no numbers that divide neatly into e and into (p-1)(q-1), except for 1. Solve following equation to find decryption key d e*d=1 mod ø(n) and 0≤d≤n In other words, d is the unique number less than n that when multiplied by e gives you 1 modulo ø(n) Publish public encryption key: PU={e,n} Keep secret private decryption key: PR={d,n} RSA key setup is done once (rarely) when a user establishes (or replaces) their public key, using the steps as shown. The exponent e is usually fairly small, just must be relatively prime to ø(n). Need to compute its inverse mod ø(n) to find d. It is critically important that the factors p & q of the modulus n are kept secret, since if they become known, the system can be broken. Note that different users will have different moduli n.
Example: Key Generation Step by Step Selecting two large primes at random : p, q (use small numbers for demonstration) p = 7; q = 19 Computing their system modulus n=p.q ø(n) = (p-1)(q-1) n = 7*19 = 133 ø(n) = (7-1)*(19-1) = 6*18 = 108 Selecting at random the encryption key e and gcd(e, 108) = 1 e = 5 find decryption key d such that e*d = 1 mod ø(n) and 0≤d≤n d*5 mod 108 = 1; d = 65 Check : 65*5 = 325; 325 mod 108 = 1 Public encryption key: PU={e,n} PU = {5,133} Secret private decryption key: PR = {d,n} PR = {65,133} Encryption and Decryption for m = 6 c = me mod n = 65 % 133 = 62 m = cd mod n = 6265 % 133 = 6