performance evaluation of public key cryptosystems advisor: dr.jens peter kaps

Performance Evaluation of Public Key Cryptosystems

Advisor: Dr.Jens Peter Kaps

Project Team:Rakesh Malireddy

Rohan Malewar

Vasunandan Peddi

Vijay Koneru

Introduction to NTRU

Introduced in 1998 by Jeffrey Hoffstein, Jill Pipher and Joseph Silverman

First public-key algorithm not based on either integer factorization or the discrete logarithm problem

It promises efficient performance combined with robust security

NTRU’s creators claim that it is resistant to parallel processing attacks and that this fact, combined with its disposable key technology, considerably reduces the risk of power attacks, timing attacks and security breaches due to lost or intercepted keys

What is NTRU?

NTRU is nth degree truncation. A public key algorithm where a key pair(public and private

key) is generated using complicated mathematical functions.

The concept of NTRU lies in the ring of truncated polynomials of degree N-1 with integer coefficients. So, instead of using prime numbers we use a polynomial rings such as

a = a0 + a1 X + a2 X2 + … + aN-2 XN-2 + aN-1 XN-1

NTRU Key Generation

Compute a random polynomial ‘f’ that has ‘p1’ co-effecients equal to 1 and ‘m1’ co-effecients equal to –1 (p1 and m1 are inputs from the user)

Compute the inverse of ‘f’ with mod p (fp) such that f * fp = 1 (mod p) If fp does not exist then perform the above step again. Compute the inverse of ‘f’ with mod q (fq) such that: f * fq = 1 (mod q) If fq does not exist then return to step 2. Compute the value of h such that: h = pfq * g (mod q) The NTRU private key is (f, fp) and the public key is h. where, N - Polynomials in ring R have degree equal to N-1 p - The small modulus q - The large modulus

NTRU Encryption & Decryption

Encryption:

The message to be sent must first be expressed in the form of a polynomial whose co-effecients are chosen modulo p.The message can then be encrypted as follows: Generate a random polynomial ‘r’ that has ‘dr’ co-effecients equal to 1 and ‘dr-1’

coeffecients equal to -1 Compute polynomial E such that

E=r*h + M(mod q) E is the encrypted message

Decryption:

The original message can be recovered by : Compute a such that a=f*E(mod q) Compute b such that b= a mod p Compute M such that M=fp*b (mod p)

Calculating Inverse of a Polynomial To compute the inverse of a (mod m): Let d = a, u = 1, v1 = 0, v3 = XN – 1

While v3 ≠ 0, iterate the following: Compute q and t3 such that d = v3 * q + t3 (mod p) and the degree of t3 is less

than the degree of v3. (This is polynomial long division, a complex algorithm in itself.)

t1 = u – q * v1 u = v1 d = v3 v1 = t1 v3 = t3 If the degree of d is greater than 0, the inversion has failed (i.e. a is not invertible

(mod p) or (mod m)) EXIT Let c = d0

-1u (mod p) (where d0 is the constant term in the polynomial d). If r > 1: Let q = p. While q < m, iterate the following: x = c * c (mod m) x = a * x (mod m) c = 2c – x (mod m) q = q2 Return c (mod m).

Implementation The code to implement NTRU is written using the C language.Different functions

were written to implement the different functionalities.

Polynomial multiplication When calculating the cipher text, E=r*h+M(mod q), we pass the polynomials that we have

to multiply as arguments to the function and the result is the product of the two polynomials Polynomial division This function is used to calculate q and t3 when a and b are known in the equation a=b*q+t3 (mod p)

Polynomial Inverse This function determines whether or not the inverse of the polynomial can be computed or

not

Key Creation

Key Encryption

Key Decryption

How NTRU works?

a = f*e (mod q) = f*(r*h + m) (mod q) [since e = r*h + m (mod q)] = f*(r*pfq*g + m) (mod q) [since h = pfq*g (mod q)] = pr*g + f*m (mod q) [since f*fq= 1(mod q)]p , r , g , f , m are already in the (–q/2,q/2) range. So 'a' reducing again to 'q' would not effect anything

b = f*m (mod p) So Bob's final step is to multiply b by fp and use the fact that

fp*f = 1 (mod p) to computed = fp* b = fp* f*m = m (mod p)

This allows him to recover Alice's message ‘m’

XTR

XTR can be used in any cryptosystem that relies on discrete logarithm problem

XTR public key Data is ( P,Q,Tr(g))

Selection of ‘q’

int generate_q( bigint &q, bigint &r, const int q_bit_length, const int n_prime_tests){

int cnt;

bigint r_max;

cnt=0;

power(r_max,2,q_bit_length/2+1);

do{

r.randomize(r_max);

q=r*r-r+1;

cnt++;

}while(q.bit_length()!=q_bit_length ||! is_prime(q,n_prime_tests));

return cnt

Selection of ‘p’

int generate_p( bigint &p, const bigint &q, const bigint &r, const int n_prime_tests)

{ int k

k=0;p=r;do{

k++p+=q;

}while(remainder(p,3)!=2 || ! is_prime(p,n_prime_tests));return k;

}

Computation of Trace Group

Tr(h) = h+hp2+hp4

Trace belongs to GF(p2)

The trace group is represented by Sn

Computation of Trace Group

Sn(c) = (cn−1, cn, cn+1) belongs to GF(p2)3

Sn(Tr(g)) = (Tr(gn−1), Tr(gn), Tr(gn+1))

LiDIA Library

Mathematical library used in XTR programbigintbigmod

Results

Level of Security NTRU XTR Standard 167 bits 85 bits High 263 bits 170 bits Highest 503 bits 340 bits

Observations

Key Generation: XTR outperforms NTRU marginally at

Standard security level At High security level XTR outperforms NTRU

approximately by a factor of 1.5

Observations

Encryption: NTRU outperforms XTR by a large factor due

to exponentiation function in the XTR On going for higher security levels, the above

factor reduces marginally

Observations

Decryption: NTRU outperforms XTR XTR has same encryption as NTRU on a high

level security and on a platform with limited resources like PC

Problems Faced

NTRU: Performing long division method while

calculating inverse Performing mod function when p=3

XTR: Implementation of Library routine Implementation of encryption function

QUERIES ???