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Primality Testing
Patrick Lee
12 July 2003
(updated on 13 July 2003)
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Finding a Prime Number
Finding a prime number is critical for public-key cryptosystems, such as RSA and Diffie-Hellman.
Naïve approach: Randomly pick a number n. Try if n is divided by
2, 3, 5, 7, …., p, where p is the largest prime number less than or equal to the square root of n.
Computationally expensive. You need to pre-obtain all small prime numbers.
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Introduction to Number Theory
Number theory: modular arithmetic on a finite set of integers
Most of the randomized algorithms starts by choosing a random number from some domain and then works deterministically from there on. We hope that with high probability the chosen number has some desirable properties.
Goal: Given a number n, the desired complexity is O(logn), i.e., polynomial in the length of n.
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Computing GCD
gcd(a, b): greatest common divisor of (a,b) a and b are co-prime iff gcd(a,b) = 1
Euclid’s algorithm: Finding gcd(a,b) for a>b, gcd(a,b) = gcd(b, a mod b)
Extended Euclid’s: Finding gcd d and numbers x and y such that
d=ax+by
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Groups
Additive Group: Zn = {0, 1, …, n-1} forms a group under addition
modulo n.
Multiplicative Group: Zn
* = {x | 1 <= x < n and gcd(x,n) = 1} forms a group under multiplication modulo n.
For prime p, Zp* includes all elements [1,p-1].
E.g., Z6* = {1, 5}
E.g., Z7* = {1, 2, 3, 4, 5, 6}
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Chinese Remainder Theorem (CRT)
Given n1, n2,…, nk are pairwise co-prime. There exists a unique r, r in [0, n = n1n2…nk), satisfying
r = ri mod ni for any sequence {r1,..,rk}, where ri in [0, ni).
E.g., r = 2 (mod 3)r = 3 (mod 5)r = 2 (mod 7)
We have r = 23, unique in [0,105).
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Euler phi Function: phi(.) phi(n) = |Zn
*| e.g., phi(p) = p–1 for prime p
Theorem: if n= p1e1p2
e2…pkek,
phi(n) = (p1-1)p1e1 - 1...(pk-1)pk
ek – 1
e.g., if n = pq, phi(n) = (p-1)(q-1) If we know phi(n), we can factorize n.
Euler’s Theorem: for all n and x in Zn*xphi(n) = 1 (mod n)
For any prime p, xp-1 = 1 (mod p) for all x in [1, p-1]. (Fermat’s Little Theorem).
If xn-1 <> 1, n is not prime (e.g., 45 mod 6 = 4).
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Order and Generator
ord(x): smallest t such that xt = 1 mod n E.g., in Z11*, ord(3) = 5, ord(2) = 10
Generator: an element whose order = group size. E.g., 3 is the generator of Z7
*
Subgroup: generated from an element of order t < phi(n) {1,3,32=9,33=5,34=4} = {1,3,4,5,9} is a subgroup of Z11
*
A group is cyclic if it has a generator.
For any prime p, the group Zp* is cyclic, i.e, every Zp
* has a generator, say g.
Zp* = {1, g, g2, g3, …, gp-2}
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Group Size
Subgroup size divides group size (for all n) Group size = phi(n) We use an element of order t < phi(n) as the generator
of the subgroup, (say 2 in Z7*). The subgroup spans t elements. For x in subgroup, we observe t has to divide phi(n) so
that xtk = xphi(n) = 1, for some integer k. You can prove it by contradiction by assuming t does not divide phi(n).
E.g., H = {1, 3, 4, 5, 9} is a subgroup of Z11*, |H| dividies |
Z11*|.
This proposition applies to all n (prime / composite).
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Quadratic Residue
y is a quadratic residue (mod n) if there exists x in Zn
* such that x2 = y (mod n) i.e., y has a square root in Zn*
Claim: For any prime p, every quadratic residue has exactly two square roots x, -x mod p. Proof: if x2 = u2 (mod p), then (x-u)(x+u) = 0
(mod p), so either p divides x-u (i.e., x=u), or p divides x+u (i.e., x=-u).
It implies if x2 = 1 (mod p), x = 1 or -1.
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Quadratic Residue (cont’d)
Theorem: For any prime p, and g is generator, gk is a quadratic residue iff k is even.
Given Zp* = {1, g, g2, g3, …, gp-2}
Even powers of g are quadratic residues Odd powers of g are not quadratic residues
Legendre symbol: [a/p] = 1 if a is a quadratic residue mod p, and -
1 if a is not a quadratic residue mod p.
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Quadratic Residue (cont’d)
Theorem: For prime p and a in Zp*, [a/p] = a(p-1)/2
(mod p). Zp
* is cyclic, a = gk for some k. If k is even, let k = 2m, a(p-1)/2 = g(p-1)m = 1. If k is odd, let k = 2m+1, a(p-1)/2 = g(p-1)/2 = -1. Reasons:
This is a square root of 1. g(p-1)/2 <> 1 since ord(g) <> (p-1)/2. But 1 has two square roots. Thus, the only solution is -1.
If n is prime, a(n-1)/2= 1 or -1. If we find a(n-1)/2 is not 1 and -1, n is composite.
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Ideas of Primality Testing
Idea 1: If xn-1 mod n <> 1, n is definitely composite. If xn-1 mod n = 1, n is probably prime.
Idea 2: If x(n-1)/2 mod n <> {1,-1}, n is definitely
composite. If x(n-1)/2 mod n = {1,-1}, n is probably prime.
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Simple Primality Testing Alg.
Repeat k times: Pick a in {2,...,n-1} at random. If gcd(a,n) != 1, then output COMPOSITE.
[this is actually unnecessary but conceptually helps] If a(n-1)/2 is not congruent to +1 or -1 (mod n), then output
COMPOSITE.
Now, if we ever got a "-1" above output "PROBABLY PRIME" else output "PROBABLY COMPOSITE".
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Error of the Simple Alg.
The alg is BPP with error probability 1/2k. If n is prime, half of them makes a(n-1)/2 = 1. Prob. error in
each iteration is ½. If n is composite, error occurs if n is claimed to be
“PROBABLY PRIME”. We use the key lemma.
Key Lemma: Let n be an odd composite, not a prime power, and let t=(n-1)/2. If there exists a in Zn
* such that at = -1 (mod n), then at most half of the x's in Zn
* have xt = {-1,+1} (mod n).
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Error of the Simple Alg. (cont’d)
Let S = {x in Zn* | xt = 1 or -1} (let t = (n-1)/2).
We’d like to show S is a proper subgroup of Zn*.
S is a subgroup of Zn* since it's closed under multiplication
(xt)(yt) = (xy)t.
Find b in Zn* but not in S.
Let n = qr, where q and r are co-prime.
Using the CRT notation, let b = (a,1), denoting b=a (mod q), b=1 (mod r). CRT assures the existence of b.
Thus, bt = (at, 1t) = (-1, 1), implying b <> 1 and -1, since 1 = (1, 1) and -1 = (-1,-1).
S is a proper subgroup. Since the subgroup size divides the group size, |S| <= ½ |Zn
*|.
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Case of Prime-Power Composites
Key Lemma doesn’t apply if n is a prime-power. However, it doesn’t matter since it cannot pass the test of step (3), i.e., we are sure that a(n-1)/2 <> 1,-1 mod n for all a.
Proof (assume all operations are mod n): Write n = pe, where p is prime. Consider an-1, which is equal to ape-1. Note that phi(n) = pe-1(p-1) = pe-pe-1, according to the theorem in
slide 7. ape-1 = aphi(n)+pe-1-1 = ape-1-1 (by Euler’s Theorem) Recursively, we get ape-1 = a-1. Since a<>1, a-1 <> 1. We have an-1 <> 1, and its square root is not 1
and -1. Thus, if n is prime-power, it does not pass the test case in step (3).
We can safely ignore the case of prime-powers in the Key Lemma.
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Miller-Rabin Algorithm
1) pick a in {2,...,n-1} at random.
2) If an-1 != 1 (mod n), then output COMPOSITE
3) Let n-1 = 2r * B, where B is odd.
4) Compute aB, a2B, ..., an-1 (mod n).
5) If we found a non {-1,+1} root of 1 in the above list, then
6) output COMPOSITE.
7) else output POSSIBLY PRIME.
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Error of MR Algorithm
It is RP.
For prime n, the algorithm always returns prime.
For non-Carmichael composite n, the algorithm returns prime with probability at most ½ in each iteration (i.e., step 2 detects compositeness with probability at least ½).
Carmichael number: a composite n such that for all a in Zn
*, an-1 = 1 mod n. (e.g., 561, 1729)
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Error of MR Algorithm (Proof)
Let Fn = {x in Zn* | xn-1 = 1 mod n}, the set of
elements that do not violate Fermat’s theorem.
Lemma: Let n be a composite non-Carmichael number. Then |Fn| <= ½ |Zn
*|. Clearly, Fn <> Zn
* . There exists a such that an-1 <> 1 mod n.
Fn forms a group. It is closed under multiplication (trivial proof!)
Fn is a proper subgroup of Zn*. |Fn| divides |Zn
*|, and |Fn| is strictly less than |Zn
*|.
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Detecting Carmichael Numbers
Computing aB, a2B, ..., a2rB (mod n), where B =(n-1)/2r, detects Carmichael numbers.
Idea: a(n-1)/2 = {1,-1}, how about a(n-1)/4? If a(n-1)/4 = {1,-1}, how about a(n-1)/8?
Prove by contradiction. Assume n is Carmichael, for all a, aB = 1 mod n. Property: Carmichael number is the product of distinct prime. Thus,
let n = p1p2..pk. Let g’ is a generator of Zp1
*. Let a = (g’, 1), i.e., a = g’ (mod p1), a = 1 (mod p2..pr), by CRT By assumption, aB = 1 (mod n). It implies g’B = 1 (mod p1) (why?). Since g’ is the generator, B = p-1, which contradicts B is odd.
Thus, for some a, aB <> 1. The probability is > ½.
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How to Find a Prime Number?
Algorithm: Randomly pick a number from [1,n-1]. Plug it into the primality testing algorithm. If fails, repeat the test with another number.
Are prime numbers rare? No.
Prime number theorem: No. of prime numbers less than n ~ n/ln(n).
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References
R. Motwani and P. Raghavan, “Randomized Algorithms”, Ch. 14.
CMU, “Randomized algorithms”, http://www-2.cs.cmu.edu/afs/cs/usr/avrim/www/Randalgs98/home.html
CLRS, “Introduction to Algorithms”, 2nd edition. Ch. 31.