# Java - Public-private key encryption - how to calculate private key in RSA - UNSOLVED

I know there are lots of threads on this topic, but I could not find one that actually answers my question cohesively.

I worked on a code for an RSA algorithm and it returns the incorrect number, which happens to be huge. I am sure i coded everything right except for one line i was not sure about. I did not know how to solve for the private key in the RSA, and just winged it (i saw someone code

d = e.modInverse(m);

where d is the private key, e is the public key, and m is (p-1)*(q-1). I dont understand how the modInverse method works though. long story short, how do you actually solve for the 'd' without having 2 unknowns in the same equation (i saw some equations given that said:

d = 1/(e % m);

I refrained from posting results just because the number returned is about as big as the encrypted message.

``````package encryptionalgorithms;

import java.math.BigInteger;
import java.util.*;

/**
*
* @author YAZAN Sources:
* http://introcs.cs.princeton.edu/java/78crypto/RSA.java.html
* http://www.math.rutgers.edu/~greenfie/gs2004/euclid.html
*/
public class EncryptionAlgorithms {

private static BigInteger p, q, n, m, e, r, a, b, d, encrypt, decrypt, message, userN, userE, userD;
private static BigInteger one = new BigInteger("1");
private static BigInteger badData = new BigInteger("-1");
private static BigInteger zero = new BigInteger("0");

public static void main(String[] args) {
PKE();
}

public static void PKE() { //Private Key Encryption
Scanner input = new Scanner(System.in);
Random rand1 = new Random(System.nanoTime());
Random rand2 = new Random(System.nanoTime() * 16); //to create a second obscure random number

p = BigInteger.probablePrime(1024, rand1);
q = BigInteger.probablePrime(1024, rand2);

n = p.multiply(q); // n = p * q
m = (p.subtract(one)).multiply(q.subtract(one)); // m = (p-1) * (q-1)

e = new BigInteger("65537"); //must be a prime. GCD(e,m)=1  //65537 = 2^16 + 1  // will have to make an algorith for this later
d = e.modInverse(m); //weakest link <============

//        System.out.println("Public Keys:");
//        System.out.println("e = " + e + " and n = " + n);
//        System.out.println("Private Keys:");
//        System.out.println("d = " + d + " and n = " + n);

System.out.println("please enther the message to be encrypted");
BigInteger mes = new BigInteger(input.next());
BigInteger ans = encrypt(mes, n, e);
decrypt(ans, n, d);
}

public static BigInteger encrypt(BigInteger num, BigInteger n, BigInteger e) {
encrypt = num.modPow(e, n);
System.out.println("encrypted: " + encrypt);
return encrypt;
}

public static BigInteger decrypt(BigInteger enc, BigInteger n, BigInteger d) {
decrypt = enc.modPow(d, n);
System.out.println("decrypted: " + decrypt);
return decrypt;
}
}
``````

and as a variant to the line in question, i tried:

d = one.divide(e.mod(m));

and i still got incorrect results.

thanks for any help provided

-

haha, you are going to kick yourself. You did everything correct, except for this teeny-weeny bug:

``````    decrypt(ans, n, e);
``````

should be

``````    decrypt(ans, n, d);
``````

In general, you could probably do a better job with variable names and class concepts such as instance variables. Kudos to you for posting a complete working example.

-
lol thanks. but now it will always return 1 as the decrypted message no matter what you input as the original message –  yazan May 18 '13 at 15:40
@yazan: It works for me. –  GregS May 18 '13 at 20:16