Information Security and Management
4. Finite Fields8. Introduction to Number Theory
Chih-Hung WangFall 2011
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• A set of elements or “numbers”• obeys:
▫ (A1) Closure: If a and b belong to G, then ab is also in G.
▫ (A2) Associative: (ab) c = a(b c) ▫ (A3) Identity element: There is an element e in G
such that a e = e a = a▫ (A4) Inverses element: For each a in G there is an
element a’ in G such that a a’ = a’ a = e▫ If commutative (A5) a b = b a for all a, b in
G then forms an abelian group
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Group
• Define exponentiation as repeated application of operator▫ example: a3 = a a a
• Define identity: e=a0
• a-n=(a’)n
• A group is cyclic if every element is a power of some fixed element▫ ie b = ak for some a and every b in group G
• a is said to generate the group G or to be a generator of G.
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Cyclic Group
• A set of “numbers” with two operations (addition + and multiplication ) which are:
• An abelian group with addition operation (A1-A5) • Multiplication:
▫ (M1) Closure▫ (M2) Associative: a(bc)=(ab)c▫ (M3) Distributive law: a(b+c) = ab + ac
• If multiplication operation is commutative, it forms a commutative ring▫ (M4) Commutativity of multiplication: ab=ba
• If multiplication operation has identity and no zero divisors, it forms an integral domain▫ (M5) Multiplicative identity: There is an element 1 in R
such that a1=1a =a▫ (M6) No zero divisors: If a,b in R and ab=0, then either
a=0 or b=0.
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Ring
•A set of numbers with two operations:▫ Abelian group for addition (A1-A5) ▫ Abelian group for multiplication (ignoring
0) (M1-M6) ▫ (M7) Multiplicative inverse: For each a in
F, except 0, there is an element a-1 in F such that aa-1=(a-1)a =1.
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Field
• Define modulo operator a mod n to be remainder when a is divided by n
• Use the term congruence for: a ≡ b mod n ▫ when divided by n, a & b have the same remainder ▫ eg. 73 ≡ 4 mod 23
• r is called the residue of a mod n▫ since with integers can always write: a = qn + r
• Usually have 0 <= b <= n-1 ▫ -12 mod 7 ≡ -5 mod 7 ≡ 2 mod 7 ≡ 9 mod 7
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Modular Arithmetic
... -21 -20 -19 -18 -17 -16 -15 -14 -13 -12 -11 -10 -9 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 ...
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Modulo 7 Example
•Say a non-zero number b divides a if for some m have a=mb (a,b,m are all integers)
•That is b divides into a with no remainder •Denote this b|a •Also say that b is a divisor of a •eg. all of 1,2,3,4,6,8,12,24 divide 24
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Divisors
•is 'clock arithmetic'•uses a finite number of values, and loops
back from either end•modular arithmetic is when do addition &
multiplication and modulo reduce answer•can do reduction at any point, ie
▫ a+b mod n = [(a mod n) + (b mod n)] mod n ▫ a-b mod n = [(a mod n) – (b mod n)] mod n▫ ab mod n = [(a mod n) (b mod n)] mod n
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Modular Arithmetic Operations
•Can do modular arithmetic with any group of integers: Zn = {0, 1, … , n-1}
•form a commutative ring for addition•with a multiplicative identity•note some peculiarities
▫ if (a+b)≡(a+c) mod n then b≡c mod n▫ but (ab)≡(ac) mod n then b≡c mod n only
if a is relatively prime to n
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Modular Arithmetic
Relatively Prime• Relative prime: their only common positive integer
factor is 1.• An integer has a multiplicative inverse in Zn if that
integer is relatively prime to n.
• Example:▫ 63=18 ≡ 2 mod 8▫ 67=42 ≡ 2 mod 8▫ 3 ≡ 7 mod 8
ncb
nacaaba
mod
mod ))(())(( 11
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6 and 8 are not relatively prime
Residue Class
• The residue classes modulo n as▫ [0], [1], [2], …, [n-1] where ▫ [r] = {a: a is an integer, a ≡ r mod n}
Z8 0 1 2 3 4 5 6 7
6 0 6 12 18 24 30 36 42
Residues 0 6 4 2 0 6 4 2
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• If p is a prime number, then all the elements of Zp are relatively prime to p▫ Multiplicative inverse (w-1)
For each there exists a z such that w z 1 mod p
For each and gcd(w,n)=1, there exists a z such that w z 1 mod n
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Multiplicative Inverse
Z8 0 1 2 3 4 5 6 7
5 0 5 10 15 20 25 30 35
Residues 0 5 2 7 4 1 6 3
pZw
nZw
•A common problem in number theory•GCD (a,b) of a and b is the largest number
that divides evenly into both a and b ▫ eg GCD(60,24) = 12
•Often want no common factors (except 1) and hence numbers are relatively prime▫ eg GCD(8,15) = 1▫ hence 8 & 15 are relatively prime
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Greatest Common Divisor (GCD)
•An efficient way to find the GCD(a,b)•uses theorem that:
▫ GCD(a,b) = GCD(b, a mod b)▫ gcd(55,22)=gcd(22,55 mod
22)=gcd(22,11)=11 •Euclid's Algorithm to compute
GCD(a,b):
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Euclid's GCD Algorithm
EUCLID(a,b)1. A a; B b2. If B=0 return A=gcd(a,b)3. R = A mod B4. A B5. B R6. goto 2
1970 = 1 x 1066 + 904 gcd(1066, 904)1066 = 1 x 904 + 162 gcd(904, 162)904 = 5 x 162 + 94 gcd(162, 94)162 = 1 x 94 + 68 gcd(94, 68)94 = 1 x 68 + 26 gcd(68, 26)68 = 2 x 26 + 16 gcd(26, 16)26 = 1 x 16 + 10 gcd(16, 10)16 = 1 x 10 + 6 gcd(10, 6)10 = 1 x 6 + 4 gcd(6, 4)6 = 1 x 4 + 2 gcd(4, 2)4 = 2 x 2 + 0 gcd(2, 0)
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Example GCD(1970,1066)
•Finite fields play a key role in cryptography
•Can show number of elements in a finite field must be a power of a prime pn
•Known as Galois fields•Denoted GF(pn)•In particular often use the fields:
▫ GF(p)▫ GF(2n)
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Galois Fields
•GF(p) is the set of integers {0,1, … , p-1} with arithmetic operations modulo prime p
•These form a finite field▫ since have multiplicative inverses
•Hence arithmetic is “well-behaved” and can do addition, subtraction, multiplication, and division without leaving the field GF(p)
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Galois Fields GF(p)
• Can extend Euclid’s algorithm:EXTENDED EUCLID(m, b)1. (A1, A2, A3)=(1, 0, m); (B1, B2, B3)=(0, 1, b)2. if B3 = 0
return A3 = gcd(m, b); no inverse3. if B3 = 1
return B3 = gcd(m, b); B2 = b–1 mod m4. Q = A3 / B35. (T1, T2, T3)=(A1 – Q B1, A2 – Q B2, A3 – Q B3)6. (A1, A2, A3)=(B1, B2, B3)7. (B1, B2, B3)=(T1, T2, T3)8. goto 2
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Finding Inverses (1)
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Inverse of 550 in GF(1759)
17591650
550545
3
109
5
5
109=1*1759 – 3*550
5= -5 * 109 + 550 = -5*(1*1759 – 3*550) + 550 =-5 * 1759 + 16 * 550
B3 B1 B2
Polynomial Arithmetic
• Ordinary polynomial arithmetic▫ A polynomial with degree n
n
i
ii
nn
nn xaaxaxaxaxf
001
11 ...)(
011110
0
0 1
00
...
where,)()(
)()()(
,)( ,)(
babababac
xcxgxf
xaxbaxgxf
mnxbxgxaxf
kkkkk
mn
i
ii
m
i
n
mi
ii
iii
m
i
ii
n
i
ii
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Irreducible
• A polynomial f(x) over a field F is called irreducible if and only if f(x) cannot be expressed as a product of two polynomials.
• The polynomial over GF(2) is reducible because
1)( 4 xxf
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)1)(1(1 234 xxxxx
13 xx is irreducible
Finite Fields of the Form GF(2n)• To work with integers that fit exactly into a
given number of bits, with no wasted bit patterns. (for implementation efficiency)
• Arithmetic in GF(23)▫ Addition
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Modular Polynomial Arithmetic• Consider the set S of all polynomials of
degree n-1 or less over the field Zp. Thus, each polynomial has the form
where each ai takes on a value in the set {0,1,…,p-1}. There are a total of pn different polynomials in S.
1
1
)(n
i
iixaxf
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Arithmetic Operations Arithmetic follows the ordinary rules of polynomial
arithmetic using the basic rules of algebra, with the following refinements.
Arithmetic on the coefficients is performed modulo p. That is, we use the rules of arithmetic for the finite field Zp.
If multiplication results in a polynomial of degree greater than n-1, than the polynomial is reduced modulo some irreducible polynomial m(x) of degree n. That is, we divide by m(x) and keep the remainder. For a polynomial f(x), the remainder is expressed as
r(x)=f(x) mod m(x).
•ap-1 mod p = 1 ▫ where p is prime and gcd(a,p)=1
•also known as Fermat’s Little Theorem•useful in public key and primality testing
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Fermat's Theorem
• When doing arithmetic modulo n • Complete set of residues is: 0..n-1 • Reduced set of residues is those numbers
(residues) which are relatively prime to n ▫ e.g. for n=10, ▫ complete set of residues is {0,1,2,3,4,5,6,7,8,9} ▫ reduced set of residues is {1,3,7,9}
• Number of elements in reduced set of residues is called the Euler Totient Function ø(n)
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Euler Totient Function ø(n)
• To compute ø(n) need to count number of elements to be excluded
• In general need prime factorization, but▫ for p (p prime) ø(p) = p-1 ▫ for pq (p,q prime)ø(pq) = (p-1)(q-1)
• e.g.▫ ø(37) = 36▫ ø(21) = (3–1)×(7–1) = 2×6 = 12
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Euler Totient Function ø(n)
•A generalisation of Fermat's Theorem •aø(n) mod n = 1
▫ where gcd(a,n)=1•e.g.
▫ a=3;n=10; ø(10)=4; ▫ hence 34 = 81 = 1 mod 10▫ a=2;n=11; ø(11)=10;▫ hence 210 = 1024 = 1 mod 11
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Euler's Theorem
• Often need to find large prime numbers • Traditionally sieve using trial division
▫ ie. divide by all numbers (primes) in turn less than the square root of the number
▫ only works for small numbers• alternatively can use statistical primality
tests based on properties of primes ▫ for which all primes numbers satisfy property ▫ but some composite numbers, called pseudo-
primes, also satisfy the property
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Primality Testing
•The natural way of measuring the density of primes is to count the number of primes up to a bound x, where x is a real number. For a real number x ¸ 0, the function (x) is defined to be the number of primes up to x. Thus, (1) = 0, (2) = 1, (7:5) = 4, and so on.
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The distribution of primes
• a test based on Fermat’s Theorem• algorithm is:
TEST (n) is:1. Find integers k, q, k > 0, q odd, so that (n–1)=2kq2. Select a random integer a, 1<a<n–13. if aq mod n = 1 then return (“maybe prime");4. for j = 0 to k – 1 do
5. if (a2jq mod n = n-1) then return(" maybe prime ")
6. return ("composite")
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Miller Rabin Algorithm
• If Miller-Rabin returns “composite” the number is definitely not prime
• Otherwise is a prime or a pseudo-prime• chance it detects a pseudo-prime is < ¼• hence if repeat test with different random a
then chance n is prime after t tests is:▫ Pr(n prime after t tests) = 1-4-t
▫ eg. for t=10 this probability is > 0.99999
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Probabilistic Considerations
• Prime number theorem states that primes occur roughly every (ln n) integers
• Since can immediately ignore evens and multiples of 5, in practice only need test 0.4 ln(n) numbers of size n before locate a prime▫ note this is only the “average” sometimes primes
are close together, at other times are quite far apart
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Prime Distribution
• From Euler’s theorem have aø(n) mod n=1 • consider am mod n=1, GCD(a,n)=1
▫ must exist for m= ø(n) but may be smaller▫ once powers reach m, cycle will repeat
• If smallest is m= ø(n) than a is called a primitive root .▫ a, a2, …, aø(n) are distinct (mod n): order = ø(n)
• If p is prime, then successive powers of a "generate" the group mod p (a is called the “generator of Zp*”)▫ a, a2,…, ap-1 are distinct (mod p): order = ø(p)=p-1 ▫ All orders divides p-1 (in Zp*)
• These are useful but relatively hard to find.
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Primitive Roots
• The inverse problem to exponentiation is to find the discrete logarithm of a number modulo p
• That is to find x where y=gx mod p • Written as x=logg y mod p• If g is a primitive root then always exists,
otherwise may not▫ x = log5 12 mod 19 (x s.t. 5x = 12 mod 19) has no
answer ▫ x = log3 5 mod 19 = 4 by trying successive powers
• Computing exponentiation is relatively easy, finding discrete logarithms is generally a hard problem
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Discrete Logarithms