5

I tryed to implement Shamir's Secret Sharing in Java but I have some problem.

When I put K>10 the secret is no more reconstructed. Who can help me? This is what i've done. What's the problem?

Initially I choose N and K, next I have the generation of coefficients, the creation of shares and finally the reconstruction.

import java.math.BigInteger;
import java.util.Random;


public class Main {
    public static void main(String[] args){

        //INIT
        int N = 55;
        int K = 11;

        BigInteger secret = new BigInteger("123");
        modLength = secret.bitLength() + 1;
        BigInteger primeNum = genPrime();
        BigInteger[] coeff = new BigInteger[K-1];
        BigInteger[] partecipants = new BigInteger[K];
        for (int i=0;i<K;i++)
            partecipants[i] = new BigInteger(Integer.toString(i+1));
        System.out.println("Prime Number: "+primeNum);
        for (int i=0;i<K-1;i++){
            coeff[i] = randomZp(primeNum);
            System.out.println("a"+(i+1)+": "+coeff[i]);
        }

        //SHARES
        BigInteger[] shares = new BigInteger[N];
        for(int i=0;i<N;i++){
            BigInteger toAdd= secret;
            for(int j=0;j<K-1;j++){
                BigInteger power = new BigInteger(Integer.toString((int)(Math.pow((i+1),(j+1)))));
                toAdd=toAdd.add(coeff[j].multiply(power));  
            }
            shares[i] = toAdd.mod(primeNum);
            System.out.println("Share n."+(i+1)+": "+shares[i]);
        }
        //INTERPOLAZIONE
        BigInteger secret2= new BigInteger("0");
        double term;
        for (int i=0;i<K;i++){
            term = 1;
            BigInteger sharePartecipanteNow = shares[(partecipants[i].intValue())-1];
            for (int j=0;j<K;j++){
                if (partecipants[i].intValue()!=partecipants[j].intValue()){

                    BigInteger num = new BigInteger(Integer.toString(partecipants[j].intValue()*(-1)));
                    BigInteger den = new BigInteger(Integer.toString(partecipants[i].intValue()-partecipants[j].intValue()));
                    term = term*(num.doubleValue())/(den.doubleValue());
                }

            }
            term = term*sharePartecipanteNow.intValue();
            secret2 = secret2.add(new BigInteger(Integer.toString((int)term)));
        }
        while(secret2.intValue()<0)
            secret2 = secret2.add(primeNum);
        System.out.println("The secret is: "+secret2.mod(primeNum));
    }

    private static BigInteger genPrime() { 
        BigInteger p=null; 
        boolean ok=false; 
        do{
            p=BigInteger.probablePrime(modLength, new Random()); 
            if(p.isProbablePrime(CERTAINTY)) 
                ok=true; 
        }while(ok==false); 
        return p; 
    }

    private static BigInteger randomZp(BigInteger p) { 
        BigInteger r; 
        do{
            r = new BigInteger(modLength, new Random()); 
        } while (r.compareTo(BigInteger.ZERO) < 0 || r.compareTo(p) >= 0); 
         return r; 
    }

    private static final int CERTAINTY = 50; 
    private static int modLength; 
}
3

Looks like your implementation suffers from numerical errors in secret reconstruction part (using double causes rounding errors).

However there is also a problem in shares generation part, however I'm not able to point it out.

I have rewritten your code using Java example from Shamir's Secret Sharing. This is quick and dirty but correct (I hope).

import java.math.BigInteger;
import java.util.Random;

public final class Shamir {

    public final class SecretShare {
        public SecretShare(final int num, final BigInteger share) {
            this.num = num;
            this.share = share;
        }

        public int getNum() {
            return num;
        }

        public BigInteger getShare() {
            return share;
        }

        @Override
        public String toString() {
            return "SecretShare [num=" + num + ", share=" + share + "]";
        }

        private final int num;
        private final BigInteger share;
    }

    public Shamir(final int k, final int n) {
        this.k = k;
        this.n = n;

        random = new Random();
    }

    public SecretShare[] split(final BigInteger secret) {
        final int modLength = secret.bitLength() + 1;

        prime = new BigInteger(modLength, CERTAINTY, random);
        final BigInteger[] coeff = new BigInteger[k - 1];

        System.out.println("Prime Number: " + prime);

        for (int i = 0; i < k - 1; i++) {
            coeff[i] = randomZp(prime);
            System.out.println("a" + (i + 1) + ": " + coeff[i]);
        }

        final SecretShare[] shares = new SecretShare[n];
        for (int i = 1; i <= n; i++) {
            BigInteger accum = secret;

            for (int j = 1; j < k; j++) {
                final BigInteger t1 = BigInteger.valueOf(i).modPow(BigInteger.valueOf(j), prime);
                final BigInteger t2 = coeff[j - 1].multiply(t1).mod(prime);

                accum = accum.add(t2).mod(prime);
            }
            shares[i - 1] = new SecretShare(i - 1, accum);
            System.out.println("Share " + shares[i - 1]);
        }

        return shares;
    }

    public BigInteger getPrime() {
        return prime;
    }

    public BigInteger combine(final SecretShare[] shares, final BigInteger primeNum) {
        BigInteger accum = BigInteger.ZERO;
        for (int i = 0; i < k; i++) {
            BigInteger num = BigInteger.ONE;
            BigInteger den = BigInteger.ONE;

            for (int j = 0; j < k; j++) {
                if (i != j) {
                    num = num.multiply(BigInteger.valueOf(-j - 1)).mod(primeNum);
                    den = den.multiply(BigInteger.valueOf(i - j)).mod(primeNum);
                }
            }

            System.out.println("den: " + den + ", num: " + den + ", inv: " + den.modInverse(primeNum));
            final BigInteger value = shares[i].getShare();

            final BigInteger tmp = value.multiply(num).multiply(den.modInverse(primeNum)).mod(primeNum);
            accum = accum.add(primeNum).add(tmp).mod(primeNum);

            System.out.println("value: " + value + ", tmp: " + tmp + ", accum: " + accum);
        }

        System.out.println("The secret is: " + accum);

        return accum;
    }

    private BigInteger randomZp(final BigInteger p) {
        while (true) {
            final BigInteger r = new BigInteger(p.bitLength(), random);
            if (r.compareTo(BigInteger.ZERO) > 0 && r.compareTo(p) < 0) {
                return r;
            }
        }
    }

    private BigInteger prime;

    private final int k;
    private final int n;
    private final Random random;

    private static final int CERTAINTY = 50;

    public static void main(final String[] args) {
        final Shamir shamir = new Shamir(11, 20);

        final BigInteger secret = new BigInteger("1234567890123456789012345678901234567890");
        final SecretShare[] shares = shamir.split(secret);
        final BigInteger prime = shamir.getPrime();

        final Shamir shamir2 = new Shamir(11, 20);
        final BigInteger result = shamir2.combine(shares, prime);

    }
}
  • 1
    It only works, if you pass to 'combine' at least X number of shares IN ORDER OF IT'S GENERATION. With example configuration 'Shamir(11,20)', 'combine' should work with any combination of 11 shares, but it works only, if you pass array with 11 or more shares in order of generation (shares 0-10)! – JerzySkalski Dec 19 '15 at 0:22
  • It's unfortunate that this is another example of a non working (real & simple) SSS implementation. The one on wikipedia only works for odd numbered keys required too. Hard to find a simple implementation that actually works. – Alan Wolfe Apr 30 '16 at 21:53
5

karbi79's Shamir's Secret Sharing implementation is not valid. It could look like fine answer [basic test works fine], but it's not!

Proper implementation of Shamir Secret Sharing made my friend. It's his code:

import java.math.BigInteger;
import java.security.SecureRandom;
import java.util.Random;

public final class Shamir
{
    public static SecretShare[] split(final BigInteger secret, int needed, int available, BigInteger prime, Random random)
    {
        System.out.println("Prime Number: " + prime);

        final BigInteger[] coeff = new BigInteger[needed];
        coeff[0] = secret;
        for (int i = 1; i < needed; i++)
        {
            BigInteger r;
            while (true)
            {
                r = new BigInteger(prime.bitLength(), random);
                if (r.compareTo(BigInteger.ZERO) > 0 && r.compareTo(prime) < 0)
                {
                    break;
                }
            }
            coeff[i] = r;
        }

        final SecretShare[] shares = new SecretShare[available];
        for (int x = 1; x <= available; x++)
        {
            BigInteger accum = secret;

            for (int exp = 1; exp < needed; exp++)
            {
                accum = accum.add(coeff[exp].multiply(BigInteger.valueOf(x).pow(exp).mod(prime))).mod(prime);
            }
            shares[x - 1] = new SecretShare(x, accum);
            System.out.println("Share " + shares[x - 1]);
        }

        return shares;
    }

    public static BigInteger combine(final SecretShare[] shares, final BigInteger prime)
    {
        BigInteger accum = BigInteger.ZERO;

        for(int formula = 0; formula < shares.length; formula++)
        {
            BigInteger numerator = BigInteger.ONE;
            BigInteger denominator = BigInteger.ONE;

            for(int count = 0; count < shares.length; count++)
            {
                if(formula == count)
                    continue; // If not the same value

                int startposition = shares[formula].getNumber();
                int nextposition = shares[count].getNumber();

                numerator = numerator.multiply(BigInteger.valueOf(nextposition).negate()).mod(prime); // (numerator * -nextposition) % prime;
                denominator = denominator.multiply(BigInteger.valueOf(startposition - nextposition)).mod(prime); // (denominator * (startposition - nextposition)) % prime;
            }
            BigInteger value = shares[formula].getShare();
            BigInteger tmp = value.multiply(numerator) . multiply(modInverse(denominator, prime));
            accum = prime.add(accum).add(tmp) . mod(prime); //  (prime + accum + (value * numerator * modInverse(denominator))) % prime;
        }

        System.out.println("The secret is: " + accum + "\n");

        return accum;
    }

    private static BigInteger[] gcdD(BigInteger a, BigInteger b)
    { 
        if (b.compareTo(BigInteger.ZERO) == 0)
            return new BigInteger[] {a, BigInteger.ONE, BigInteger.ZERO}; 
        else
        { 
            BigInteger n = a.divide(b);
            BigInteger c = a.mod(b);
            BigInteger[] r = gcdD(b, c); 
            return new BigInteger[] {r[0], r[2], r[1].subtract(r[2].multiply(n))};
        }
    }

    private static BigInteger modInverse(BigInteger k, BigInteger prime)
    { 
        k = k.mod(prime);
        BigInteger r = (k.compareTo(BigInteger.ZERO) == -1) ? (gcdD(prime, k.negate())[2]).negate() : gcdD(prime,k)[2];
        return prime.add(r).mod(prime);
    }

    public static void main(final String[] args)
    {
        final int CERTAINTY = 256;
        final SecureRandom random = new SecureRandom();

        final BigInteger secret = new BigInteger("123");

        // prime number must be longer then secret number
        final BigInteger prime = new BigInteger(secret.bitLength() + 1, CERTAINTY, random);

        // 2 - at least 2 secret parts are needed to view secret
        // 5 - there are 5 persons that get secret parts
        final SecretShare[] shares = Shamir.split(secret, 2, 5, prime, random);


        // we can use any combination of 2 or more parts of secret
        SecretShare[] sharesToViewSecret = new SecretShare[] {shares[0],shares[1]}; // 0 & 1
        BigInteger result = Shamir.combine(sharesToViewSecret, prime);

        sharesToViewSecret = new SecretShare[] {shares[1],shares[4]}; // 1 & 4
        result = Shamir.combine(sharesToViewSecret, prime);

        sharesToViewSecret = new SecretShare[] {shares[0],shares[1],shares[3]}; // 0 & 1 & 3
        result = Shamir.combine(sharesToViewSecret, prime);
    }
}

SecretShare.java:

import java.math.BigInteger;

public class SecretShare
{
    public SecretShare(final int number, final BigInteger share)
    {
        this.number = number;
        this.share = share;
    }

    public int getNumber()
    {
        return number;
    }

    public BigInteger getShare()
    {
        return share;
    }

    @Override
    public String toString()
    {
        return "SecretShare [num=" + number + ", share=" + share + "]";
    }

    private final int number;
    private final BigInteger share;
}
2

https://github.com/codahale/jsecretsharing

// build 10 shares, of which 2 are required to recover the secret

ShareBuilder builder = new ShareBuilder("I am Batman. Seriously.".getBytes(), 2, 512); List shares = builder.build(10);

// takes 2 shares, recovers secret List someShares = new ArrayList(); someShares.add(shares.get(2)); someShares.add(shares.get(7)); ShareCombiner combiner = new ShareCombiner(someShares); System.err.println(new String(combiner.combine()));

// omg I'm batman

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