# How to factor RSA modulus given the public and private exponent?

I have a RSA private key with modulus `m`, public exponent `e` and private exponent `d`, but the program I am using needs the modulus's prime factors `p` and `q`.

Is it possible to use `e` and `d` to get `p` and `q`?

• is there any code in openssl to perform this task – Abhishek Garg Nov 1 '19 at 8:04

Yes -- once you know the modulus N, and public/private exponents d and e, it is not too difficult to obtain p and q such that N=pq.

This paper by Dan Boneh describes an algorithm for doing so. It relies on the fact that, by definition,

de = 1 mod phi(N).

For any randomly chosen "witness" in (2,N), there is about a 50% chance of being able to use it to find a nontrivial square root of 1 mod N (call it x). Then gcd(x-1,N) gives one of the factors.

• Just nitpicking: all RSA needs is that de = 1 mod p-1 and mod q-1, so that's de = 1 mod lcm(p-1,q-1) which is a strict divisor of phi(N) (using phi(N) is just the way RSA was first described). However, the method described by Boneh works in the general case as well. – Thomas Pornin Apr 22 '11 at 15:40

You can use the open source tool I have developed in 2009 that converts RSA keys between the SFM format (n,e,d) and CRT format (p,q,dp,dq,u), and the other way around. It is on SourceForge : http://rsaconverter.sourceforge.net/

The algorithm I implemented is based on ideas presented by Dan Boneh, as described by the previous answer.

I hope this will be useful.

Mounir IDRASSI - IDRIX

• actually i need a code in openssl to perform this task , can u provide if available – Abhishek Garg Nov 1 '19 at 8:05
• You can look at the file librsaconverter.c from my project RsaConverter on SourceForge: sourceforge.net/p/rsaconverter/code/HEAD/tree/Trunk/src/…. There you will find the implementation of the function SfmToCrt that calculate RSA primes from public modulus and private exponent. – Mounir IDRASSI Nov 2 '19 at 12:26
• Thanks bro , it really solved my problem – Abhishek Garg Nov 4 '19 at 6:42

I posted a response on the crypto stack exchange answering the same question here. It uses the same approach as outlined in Boneh's paper, but does a lot more explanation as to how it actually works. I also try to assume a minimal amount of prior knowledge.

Hope this helps!