コード例 #1
0
        public static byte[] SignRaw(ECPrivateKey sk, IDigest rfc6979Hash,
                                     byte[] hash, int hashOff, int hashLen)
        {
            ECCurve curve = sk.Curve;

            byte[]  q  = curve.SubgroupOrder;
            RFC6979 rf = new RFC6979(rfc6979Hash, q, sk.X,
                                     hash, hashOff, hashLen, rfc6979Hash != null);
            ModInt mh = rf.GetHashMod();
            ModInt mx = mh.Dup();

            mx.Decode(sk.X);

            /*
             * Compute DSA signature. We use a loop to enumerate
             * candidates for k until a proper one is found (it
             * is VERY improbable that we may have to loop).
             */
            ModInt mr = mh.Dup();
            ModInt ms = mh.Dup();
            ModInt mk = mh.Dup();

            byte[] k = new byte[q.Length];
            for (;;)
            {
                rf.NextK(k);
                MutableECPoint G = curve.MakeGenerator();
                if (G.MulSpecCT(k) == 0)
                {
                    /*
                     * We may get an error here only if the
                     * curve is invalid (generator does not
                     * produce the expected subgroup).
                     */
                    throw new CryptoException(
                              "Invalid EC private key / curve");
                }
                mr.DecodeReduce(G.X);
                if (mr.IsZero)
                {
                    continue;
                }
                ms.Set(mx);
                ms.ToMonty();
                ms.MontyMul(mr);
                ms.Add(mh);
                mk.Decode(k);
                mk.Invert();
                ms.ToMonty();
                ms.MontyMul(mk);

                byte[] sig = new byte[q.Length << 1];
                mr.Encode(sig, 0, q.Length);
                ms.Encode(sig, q.Length, q.Length);
                return(sig);
            }
        }
コード例 #2
0
        public static bool VerifyRaw(ECPublicKey pk,
                                     byte[] hash, int hashOff, int hashLen,
                                     byte[] sig, int sigOff, int sigLen)
        {
            try {
                /*
                 * Get the curve.
                 */
                ECCurve curve = pk.Curve;

                /*
                 * Get r and s from signature. This also verifies
                 * that they do not exceed the subgroup order.
                 */
                if (sigLen == 0 || (sigLen & 1) != 0)
                {
                    return(false);
                }
                int    tlen = sigLen >> 1;
                ModInt oneQ = new ModInt(curve.SubgroupOrder);
                oneQ.Set(1);
                ModInt r = oneQ.Dup();
                ModInt s = oneQ.Dup();
                r.Decode(sig, sigOff, tlen);
                s.Decode(sig, sigOff + tlen, tlen);

                /*
                 * If either r or s was too large, it got set to
                 * zero. We also don't want real zeros.
                 */
                if (r.IsZero || s.IsZero)
                {
                    return(false);
                }

                /*
                 * Convert the hash value to an integer modulo q.
                 * As per FIPS 186-4, if the hash value is larger
                 * than q, then we keep the qlen leftmost bits of
                 * the hash value.
                 */
                int    qBitLength = oneQ.ModBitLength;
                int    hBitLength = hashLen << 3;
                byte[] hv;
                if (hBitLength <= qBitLength)
                {
                    hv = new byte[hashLen];
                    Array.Copy(hash, hashOff, hv, 0, hashLen);
                }
                else
                {
                    int qlen = (qBitLength + 7) >> 3;
                    hv = new byte[qlen];
                    Array.Copy(hash, hashOff, hv, 0, qlen);
                    int rs = (8 - (qBitLength & 7)) & 7;
                    BigInt.RShift(hv, rs);
                }
                ModInt z = oneQ.Dup();
                z.DecodeReduce(hv);

                /*
                 * Apply the verification algorithm:
                 *   w = 1/s mod q
                 *   u = z*w mod q
                 *   v = r*w mod q
                 *   T = u*G + v*Pub
                 *   test whether T.x mod q == r.
                 */
                /*
                 * w = 1/s mod q
                 */
                ModInt w = s.Dup();
                w.Invert();

                /*
                 * u = z*w mod q
                 */
                w.ToMonty();
                ModInt u = w.Dup();
                u.MontyMul(z);

                /*
                 * v = r*w mod q
                 */
                ModInt v = w.Dup();
                v.MontyMul(r);

                /*
                 * Compute u*G
                 */
                MutableECPoint T    = curve.MakeGenerator();
                uint           good = T.MulSpecCT(u.Encode());

                /*
                 * Compute v*iPub
                 */
                MutableECPoint M = pk.iPub.Dup();
                good &= M.MulSpecCT(v.Encode());

                /*
                 * Compute T = u*G+v*iPub
                 */
                uint nd = T.AddCT(M);
                M.DoubleCT();
                T.Set(M, ~nd);
                good &= ~T.IsInfinityCT;

                /*
                 * Get T.x, reduced modulo q.
                 * Signature is valid if and only if we get
                 * the same value as r (and we did not encounter
                 * an error previously).
                 */
                s.DecodeReduce(T.X);
                return((good & r.EqCT(s)) != 0);
            } catch (CryptoException) {
                /*
                 * Exceptions may occur if the key or signature
                 * have invalid values (non invertible, out of
                 * range...). Any such occurrence means that the
                 * signature is not valid.
                 */
                return(false);
            }
        }