# Algorithm for computing the inverse of a polynomial

I'm looking for an algorithm (or code) to help me compute the inverse a polynomial, I need it for implementing NTRUEncrypt. An algorithm that is easily understandable is what I prefer, there are pseudo-codes for doing this, but they are confusing and difficult to implement, furthermore I can not really understand the procedure from pseudo-code alone.

Any algorithms for computing the inverse of a polynomial with respect to a ring of truncated polynomials?

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Which inverse? Do you want the inverse function, to solve (i.e. factorise) polynomials, or do you want to find their multiplicative inverses in the field formed as the quotient of the polynomials over some base field, and an irreducible polynomial? NTRU stands for "Number Theorists R Us", IIRC, so it's difficult to intuit just what mathematics is required. en.wikipedia.org/wiki/NTRUEncrypt says "both encryption and decryption use only simple polynomial multiplication", so that article didn't tell me what you mean either. Whatever is needed, this could be a MathOverflow question. –  Steve Jessop Mar 10 '10 at 23:42
In that case go for carefully copying the pseudo-code, operation by operation. When they say things like, `f(X):=a(X)`, they mean that f is a variable in your routine, a is an input to the function, and the type of both those things is "polynomial". `f(X)/X` means for instance `x^2 + x + 0` -> `x + 1`. The other tricky part is when you finally get your answer, you have to reduce it mod `X^N-1`. –  Steve Jessop Mar 11 '10 at 0:02
Oh, and write a unit test for your function. You should be able to multiply the output by the input, reduce the coefficients modulo 2, reduce the resulting polynomial modulo X^N-1, and get the polynomial 1 (that is, all coefficients 0 except the last). –  Steve Jessop Mar 11 '10 at 0:24
Thanks a lot steve, I'm trying to implement the pseudo-code line by line very carefully, there is an extended pseudo-code that's written more clearly here: wpi.edu/Pubs/ETD/Available/etd-0430102-111906/unrestricted/… on page 27, I'm coding that carefully and i'm testing it with some sample answers given by NTRU, I think i'm also getting held back in understanding the pseudo-code, in my code I gave a fixed length and set of values to the polynomial f, and the infinite loop on 8-31 never ended, thanks for pointing out that f is a variable. Any more tricks to watch out for? –  Mohammad Sepahvand Mar 11 '10 at 0:25
Nothing springs to mind. Everything listed in "Step 1: Initialization" is a variable, and is modified somewhere. You should see f and g get smaller and smaller (in terms of their highest non-zero coefficient), while b, c and k in effect record what you did to f and g. Once f is as small as it can get (`1`) in step 5, the stuff you've "built up" in b and k gives you the inverse, you just have to put that information together. As an implementation detail, if you're storing a polynomial as an array of coefficients, then multiplying or dividing by x just means shift everything along one place. –  Steve Jessop Mar 11 '10 at 0:38

I work for Security Innovation, which owns NTRU, so I'm glad to see this interest.

The IEEE standard 1363.1-2008 specifies how to implement NTRUEncrypt with the most current parameter sets. It gives the following specifications to invert polynomials:

Division:

Inputs are a and b, two polynomials, where b is of degree N-1 and b_N is the leading coefficient of b. Outputs are q and r such that a = q*b + r and deg(r) < deg(b). r_d denotes the coefficient of r of degree d, i.e. the leading coefficient of r.

``````a)  Set r := a and q := 0
b)  Set u := (b_N)^–1 mod p
c)  While deg r >= N do
1)    Set d := deg r(X)
2)    Set v := u × r_d × X^(d–N)
3)    Set r := r – v × b
4)    Set q := q + v
d)  Return q, r
``````

Here, r_d is the coefficient of r of degree d.

Extended Euclidean Algorithm:

``````a)  If b = 0 then return (1, 0, a)
b)  Set u := 1
c)  Set d := a
d)  Set v1 := 0
e)  Set v3 := b
f)  While v3 ≠ 0 do
1)    Use the division algorithm (6.3.3.1) to write d = v3 × q + t3 with deg t3 < deg v3
2)    Set t1 := u – q × v1
3)    Set u := v1
4)    Set d := v3
5)    Set v1 := t1
6)    Set v3 := t3
g)  Set v := (d – a × u)/b  [This division is exact, i.e., the remainder is 0]
h)  Return (u, v, d)
``````

Inverse in Z_p, p a prime:

``````a)  Run the Extended Euclidean Algorithm with input a and (X^N – 1).  Let (u, v, d) be the output, such that a × u + (X^N – 1) × v = d = GCD(a, (X^N – 1)).
b)  If deg d = 0, return b = d^–1 (mod p) × u
c)  Else return FALSE
``````

Inverse in Z_p^e / (M(X), p a prime, M(X) a suitable polynomial such as X^N-1

``````a)  Use the Inversion Algorithmto compute a polynomial b(X) ε R[X] that gives an inverse of a(X) in (R/pR)[X]/(M(X)). Return FALSE if the inverse does not exist. [The Inversion Algorithm may be applied here because R/pR is a field, and so (R/pR)[X] is a Euclidean ring.]
b)  Set n = p
c)  While n <= e do
1)    b(X) = p × b(X) – a(X) × b(X)^2   (mod M(X)), with coefficients computed modulo p^n
2)    Set n = p × n
d)  Return b(X) mod M(X) with coefficients computed modulo p^e.
``````

If you're doing a full implementation of NTRU you should see if you can get your institution to buy 1363.1, as raw NTRU encryption isn't secure against an active attacker and 1363.1 describes message processing techniques to fix that.

(Update 2013-04-18: Thanks to Sonel Sharam for spotting some errors in the previous version)

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