Пример #1
0
int privkey::decrypt (const bvector & in, bvector & out, bvector & errors)
{
	if (in.size() != cipher_size() ) return 2;
	polynomial synd;
	uint i, j, tmp;

	/*
	 * compute the syndrome from alternant check matrix
	 * that is H_alt = Vdm(L) * Diag(g(L_i)^{-2})
	 */
	uint h_size = 1 << (T + 1); //= 2*block_size
	synd.clear();
	synd.resize (h_size, 0);
	for (i = 0; i < cipher_size(); ++i) if (in[i]) {
			tmp = fld.inv (g.eval (permuted_support[i], fld) );
			tmp = fld.mult (tmp, tmp); //g(Li)^{-2}
			synd[0] = fld.add (synd[0], tmp);
			for (j = 1; j < h_size; ++j) {
				tmp = fld.mult (tmp, permuted_support[i]);
				synd[j] = fld.add (synd[j], tmp);
			}
		}

	//decoding
	polynomial loc;
	compute_alternant_error_locator (synd, fld, 1 << T, loc);

	bvector ev;
	if (!evaluate_error_locator_trace (loc, ev, fld) )
		return 1; //couldn't decode
	//TODO evaluator should return error positions, not bvector. fix it everywhere!

	out = in;
	out.resize (plain_size() );
	errors.clear();
	errors.resize (cipher_size(), 0);
	//flip error positions of out.
	for (i = 0; i < ev.size(); ++i) if (ev[i]) {
			uint epos = support_pos[fld.inv (i)];
			if (epos == fld.n) {
				//found unexpected support, die.
				out.clear();
				return 1;
			}
			if (epos >= cipher_size() ) return 1;
			errors[epos] = 1;
			if (epos < plain_size() )
				out[epos] = !out[epos];
		}

	return 0;
}
Пример #2
0
bool evaluate_error_locator_trace (polynomial&sigma, bvector&ev, gf2m&fld)
{
	ev.clear();
	ev.resize (fld.n, 0);

	std::vector<polynomial> trace_aux, trace; //trace cache
	trace_aux.resize (fld.m);
	trace.resize (fld.m);

	trace_aux[0] = polynomial();
	trace_aux[0].resize (2, 0);
	trace_aux[0][1] = 1; //trace_aux[0] = x
	trace[0] = trace_aux[0]; //trace[0] = x

	for (uint i = 1; i < fld.m; ++i) {
		trace_aux[i] = trace_aux[i - 1];
		trace_aux[i].square (fld);
		trace_aux[i].mod (sigma, fld);
		trace[0].add (trace_aux[i], fld);
	}

	std::set<std::pair<uint, polynomial> > stk; //"stack"

	stk.insert (make_pair (0, sigma));

	bool failed = false;

	while (!stk.empty()) {

		uint i = stk.begin()->first;
		polynomial cur = stk.begin()->second;

		stk.erase (stk.begin());

		int deg = cur.degree();

		if (deg <= 0) continue;
		if (deg == 1) { //found a linear factor
			ev[fld.mult (cur[0], fld.inv (cur[1])) ] = 1;
			continue;
		}

		if (i >= fld.m) {
			failed = true;
			continue;
		}

		if (trace[i].zero()) {
			//compute the trace if it isn't cached
			uint a = fld.exp (i);
			for (uint j = 0; j < fld.m; ++j) {
				trace[i].add_mult (trace_aux[j], a, fld);
				a = fld.mult (a, a);
			}
		}

		polynomial t;
		t = cur.gcd (trace[i], fld);
		polynomial q, r;
		cur.divmod (t, q, r, fld);

		stk.insert (make_pair (i + 1, t));
		stk.insert (make_pair (i + 1, q));
	}

	return !failed;
}