Example #1
0
	void	connection::write(const net::buffer& data)
	{
		if(m_service.check_this_loop()){
			write_in_loop(data.data(),data.size());
		}else{
			m_service.run_task(  boost::bind(&connection::write_in_loop,this,data.data(),data.size()) );
		}
	}
Example #2
0
bool message_udp::recv::pong::expect(const net::buffer & recv_buf)
{
	if(recv_buf.size() != protocol_udp::pong_size){
		return false;
	}
	if(recv_buf[0] != protocol_udp::pong){
		return false;
	}
	return std::memcmp(recv_buf.data()+1, random.data(), 4) == 0;
}
Example #3
0
bool message_udp::recv::store_node::recv(const net::buffer & recv_buf,
	const net::endpoint & endpoint)
{
	if(!expect(recv_buf)){
		return false;
	}
	net::buffer random(recv_buf.data()+1, 4);
	std::string remote_ID(convert::bin_to_hex(std::string(
		reinterpret_cast<const char *>(recv_buf.data())+5, 20)));
	func(endpoint, random, remote_ID);
	return true;
}
Example #4
0
bool message_udp::recv::node_list::expect(const net::buffer & recv_buf)
{
	if(recv_buf.size() < protocol_udp::node_list_size){
		return false;
	}
	if(recv_buf[0] != protocol_udp::node_list){
		return false;
	}
	if((recv_buf.size() - protocol_udp::node_list_size) % 20 != 0){
		return false;
	}
	return std::memcmp(recv_buf.data()+1, random.data(), 4) == 0;
}
Example #5
0
void encryption::recv_rB(const net::buffer & buf)
{
	assert(enable_recv_rB);
	set_enable_false();
	enable_crypt = true;

	assert(buf.size() == protocol_tcp::DH_key_size);
	remote_result = mpa::mpint(buf.data(), protocol_tcp::DH_key_size);
	shared_key = mpa::exptmod(remote_result, s, p);

	std::string bin = shared_key.bin(protocol_tcp::DH_key_size);
	PRNG_send.seed(reinterpret_cast<const unsigned char *>(bin.data()), bin.size());
	PRNG_recv.seed(reinterpret_cast<const unsigned char *>(bin.data()), bin.size());
}
Example #6
0
void encryption::crypt_send(net::buffer & send_buff, const int index)
{
	assert(enable_crypt);
	for(int x=index; x<send_buff.size(); ++x){
		send_buff[x] ^= PRNG_send.byte();
	}
}
Example #7
0
void encryption::crypt_recv(net::buffer & recv_buff, const int index)
{
	assert(enable_crypt);
	for(int x=index; x<recv_buff.size(); ++x){
		recv_buff[x] ^= PRNG_recv.byte();
	}
}
Example #8
0
//BEGIN send::host_list
message_udp::send::host_list::host_list(const net::buffer & random,
	const std::string & local_ID,
	const std::list<net::endpoint> & hosts)
{
	assert(random.size() == 4);
	assert(hosts.size() <= protocol_udp::host_list_elements);
	bit_field BF(16);
	unsigned cnt = 0;
	for(std::list<net::endpoint>::const_iterator it_cur = hosts.begin(),
		it_end = hosts.end(); it_cur != it_end; ++it_cur)
	{
		if(it_cur->version() == net::IPv4){
			BF[cnt] = 0;
		}else{
			BF[cnt] = 1;
		}
		++cnt;
	}
	buf.append(protocol_udp::host_list)
		.append(random)
		.append(convert::hex_to_bin(local_ID))
		.append(BF.get_buf());
	//append addresses
	for(std::list<net::endpoint>::const_iterator it_cur = hosts.begin(),
		it_end = hosts.end(); it_cur != it_end; ++it_cur)
	{
		buf.append(it_cur->IP_bin())
			.append(it_cur->port_bin());
	}
}
Example #9
0
bool message_udp::recv::host_list::recv(const net::buffer & recv_buf,
	const net::endpoint & endpoint)
{
	if(!expect(recv_buf)){
		return false;
	}
	std::string remote_ID(convert::bin_to_hex(std::string(
		reinterpret_cast<const char *>(recv_buf.data())+5, 20)));
	bit_field BF(recv_buf.data()+25, 2, 16);
	std::list<net::endpoint> hosts;
	unsigned offset = protocol_udp::host_list_size;
	for(unsigned x=0; x<16 && offset != recv_buf.size(); ++x){
		if(BF[x] == 0){
			//IPv4
			boost::optional<net::endpoint> ep = net::bin_to_endpoint(
				recv_buf.str(offset, 4), recv_buf.str(offset + 4, 2));
			if(ep){
				hosts.push_back(*ep);
			}
			offset += 6;
		}else{
			//IPv6
			boost::optional<net::endpoint> ep = net::bin_to_endpoint(
				recv_buf.str(offset, 16), recv_buf.str(offset + 16, 2));
			if(ep){
				hosts.push_back(*ep);
			}
			offset += 18;
		}
	}
	func(endpoint, remote_ID, hosts);
	return true;
}
Example #10
0
//BEGIN send::store_node
message_udp::send::store_node::store_node(const net::buffer & random,
	const std::string & local_ID)
{
	assert(random.size() == 4);
	assert(local_ID.size() == SHA1::hex_size);
	buf.append(protocol_udp::store_node)
		.append(random)
		.append(convert::hex_to_bin(local_ID));
}
Example #11
0
bool message_udp::recv::find_node::expect(const net::buffer & recv_buf)
{
	if(recv_buf.size() != protocol_udp::find_node_size){
		return false;
	}
	if(recv_buf[0] != protocol_udp::find_node){
		return false;
	}
	return true;
}
Example #12
0
bool message_udp::recv::node_list::recv(const net::buffer & recv_buf,
	const net::endpoint & endpoint)
{
	if(!expect(recv_buf)){
		return false;
	}
	net::buffer random(recv_buf.data()+1, 4);
	std::string remote_ID(convert::bin_to_hex(std::string(
		reinterpret_cast<const char *>(recv_buf.data())+5, 20)));
	std::list<std::string> nodes;
	unsigned offset = protocol_udp::node_list_size;
	for(unsigned x=0; x<16 && offset != recv_buf.size(); ++x){
		nodes.push_back(convert::bin_to_hex(std::string(
			reinterpret_cast<const char *>(recv_buf.data())+offset, 20)));
		offset += 20;
	}
	func(endpoint, random, remote_ID, nodes);
	return true;
}
Example #13
0
//BEGIN send::query_file
message_udp::send::query_file::query_file(const net::buffer & random,
	const std::string & local_ID, const std::string & hash)
{
	assert(random.size() == 4);
	assert(local_ID.size() == SHA1::hex_size);
	assert(hash.size() == SHA1::hex_size);
	buf.append(protocol_udp::query_file)
		.append(random)
		.append(convert::hex_to_bin(local_ID))
		.append(convert::hex_to_bin(hash));
}
Example #14
0
bool encryption::recv_p_rA(const net::buffer & buf)
{
	assert(enable_recv_p_rA);
	set_enable_false();
	enable_send_rB = true;

	assert(buf.size() == protocol_tcp::DH_key_size * 2);
	p = mpa::mpint(buf.data(), protocol_tcp::DH_key_size);
	if(!mpa::is_prime(p)){
		return false;
	}
	remote_result = mpa::mpint(buf.data() + protocol_tcp::DH_key_size, protocol_tcp::DH_key_size);
	local_result = mpa::exptmod(g, s, p);
	shared_key = mpa::exptmod(remote_result, s, p);

	std::string bin = shared_key.bin(protocol_tcp::DH_key_size);
	PRNG_send.seed(reinterpret_cast<const unsigned char *>(bin.data()), bin.size());
	PRNG_recv.seed(reinterpret_cast<const unsigned char *>(bin.data()), bin.size());
	return true;
}
Example #15
0
//BEGIN send::node_list
message_udp::send::node_list::node_list(const net::buffer & random,
	const std::string & local_ID, const std::list<std::string> & nodes)
{
	assert(random.size() == 4);
	assert(local_ID.size() == SHA1::hex_size);
	assert(nodes.size() <= protocol_udp::node_list_elements);
	buf.append(protocol_udp::node_list)
		.append(random)
		.append(convert::hex_to_bin(local_ID));
	for(std::list<std::string>::const_iterator it_cur = nodes.begin(),
		it_end = nodes.end(); it_cur != it_end; ++it_cur)
	{
		assert(it_cur->size() == SHA1::hex_size);
		buf.append(convert::hex_to_bin(*it_cur));
	}
}
Example #16
0
bool message_udp::recv::host_list::expect(const net::buffer & recv_buf)
{
	//check minimum size
	if(recv_buf.size() < protocol_udp::host_list_size || recv_buf.size() > 508){
		return false;
	}
	//check command
	if(recv_buf[0] != protocol_udp::host_list){
		return false;
	}
	//check random
	if(std::memcmp(recv_buf.data()+1, random.data(), 4) != 0){
		return false;
	}
	//verify address list makes sense
	bit_field BF(recv_buf.data()+25, 2, 16);
	unsigned offset = protocol_udp::host_list_size;
	for(unsigned x=0; x<16 && offset != recv_buf.size(); ++x){
		if(BF[x] == 0){
			//IPv4
			if(recv_buf.size() < offset + 6){
				return false;
			}
			offset += 6;
		}else{
			//IPv6
			if(recv_buf.size() < offset + 18){
				return false;
			}
			offset += 18;
		}
	}
	//check if longer than expected
	if(offset != recv_buf.size()){
		return false;
	}
	return true;
}
Example #17
0
bool message_udp::recv::ping::expect(const net::buffer & recv_buf)
{
	return recv_buf.size() == protocol_udp::ping_size
		&& recv_buf[0] == protocol_udp::ping;
}