C++ endpoint::port方法代码示例

ManagementClient::ManagementClient(ManagementInformationBase& mib, const udp::endpoint& clientEndpoint, u_int8_t wirelessStateUpdateInterval, u_int8_t locationUpdateInterval, Logger& logger)
	: mib(mib), clientEndpoint(clientEndpoint), logger(logger) {
	/**
	 * Check that source port is not an ephemeral port which would
	 * change every time a client sendto()s to MGMT
	 */
	if (clientEndpoint.port() >= 32768 && clientEndpoint.port() <= 61000)
		logger.error("Client uses an ephemeral port that will change every time it sends data and this will confuse my state management!");

	/**
	 * Initialise state strings map
	 */
	clientStateStringMap.insert(std::make_pair(ManagementClient::OFFLINE, "OFFLINE"));
	clientStateStringMap.insert(std::make_pair(ManagementClient::ONLINE, "ONLINE"));
	/**
	 * Initialise type strings map
	 */
	clientTypeStringMap.insert(std::make_pair(ManagementClient::UNKNOWN, "Unknown"));
	clientTypeStringMap.insert(std::make_pair(ManagementClient::GN, "GeoNetworking"));
	clientTypeStringMap.insert(std::make_pair(ManagementClient::FAC, "Facilities"));
	clientTypeStringMap.insert(std::make_pair(ManagementClient::LTE, "Long Term Evolution"));
	/**
	 * Initialise this client's state and type
	 */
	state = ManagementClient::OFFLINE;
	type = ManagementClient::UNKNOWN;
	/**
	 * We are not waiting a reply from this client now
	 */
	repliedToTheLastPacket = true;
}

void udp_socket::wrap(udp::endpoint const& ep, char const* p, int len, error_code& ec)
{
	CHECK_MAGIC;
	using namespace libtorrent::detail;

	char header[20];
	char* h = header;

	write_uint16(0, h); // reserved
	write_uint8(0, h); // fragment
	write_uint8(ep.address().is_v4()?1:4, h); // atyp
	write_address(ep.address(), h);
	write_uint16(ep.port(), h);

	boost::array<asio::const_buffer, 2> iovec;
	iovec[0] = asio::const_buffer(header, h - header);
	iovec[1] = asio::const_buffer(p, len);

#if TORRENT_USE_IPV6
	if (m_proxy_addr.address().is_v4() && m_ipv4_sock.is_open())
#endif
		m_ipv4_sock.send_to(iovec, m_proxy_addr, 0, ec);
#if TORRENT_USE_IPV6
	else
		m_ipv6_sock.send_to(iovec, m_proxy_addr, 0, ec);
#endif
}

string EndpointToString(const udp::endpoint &endpoint)
{	
	string strIp = endpoint.address().to_string();
	unsigned int dwPort = endpoint.port();
	char szIpPort[32] = {0};
	sprintf(szIpPort, "%s:%d", strIp.c_str(), dwPort);
	return szIpPort;
}

	node_entry(node_id const& id_, udp::endpoint ep, int roundtriptime = 0xffff, bool pinged = false)
		: addr(ep.address())
		, port(ep.port())
		, timeout_count(pinged ? 0 : 0xffff)
		, rtt(roundtriptime)
		, id(id_)
	{
#ifdef TORRENT_DHT_VERBOSE_LOGGING
		first_seen = time_now();
#endif
	}

void rpc_manager::invoke(int message_id, udp::endpoint target_addr
	, observer_ptr o)
{
	INVARIANT_CHECK;

	if (m_destructing)
	{
		o->abort();
		return;
	}

	msg m;
	m.message_id = message_id;
	m.reply = false;
	m.id = m_our_id;
	m.addr = target_addr;
	TORRENT_ASSERT(!m_transactions[m_next_transaction_id]);
#ifdef TORRENT_DEBUG
	int potential_new_id = m_next_transaction_id;
#endif
#ifndef BOOST_NO_EXCEPTIONS
	try
	{
#endif
		m.transaction_id.clear();
		std::back_insert_iterator<std::string> out(m.transaction_id);
		io::write_uint16(m_next_transaction_id, out);
		
		o->send(m);

		o->sent = time_now();
#if TORRENT_USE_IPV6
		o->target_addr = target_addr.address();
#else
		o->target_addr = target_addr.address().to_v4();
#endif
		o->port = target_addr.port();

#ifdef TORRENT_DHT_VERBOSE_LOGGING
		TORRENT_LOG(rpc) << "Invoking " << messages::ids[message_id] 
			<< " -> " << target_addr;
#endif	
		m_send(m);
		new_transaction_id(o);
#ifndef BOOST_NO_EXCEPTIONS
	}
	catch (std::exception& e)
	{
		// m_send may fail with "no route to host"
		TORRENT_ASSERT(potential_new_id == m_next_transaction_id);
		o->abort();
	}
#endif
}

bool CUDPSocket::SendData(udp::endpoint&  ep, char* msg, int size, string& errInfo, unsigned long iProxyIp /*= 0*/, unsigned short iProxyPort /*= 0*/)
{
	if(ep.address().to_v4().to_string().empty())
		return false;

	if(ep.address().to_v4().to_string()=="255.255.255.255")
		return false;

	if(ep.port() <=0 || ep.port() >65535)
		return false;


	if(msg == NULL)
		return true;

    try
    {
        int ret = this->m_mySocket.send_to(boost::asio::buffer((const void*)msg, size), ep);
        if (ret < size)
        {
            return false;
        }
    }
    catch (const boost::system::error_code& err)
    {
        ostringstream oss;
        oss << "严重错误 CUDPSocket error_code2 " << err.value();
        make_log_func_(oss.str());
        return false;
    }
    catch (...)
    {
        ostringstream oss;
        oss << "严重错误...";
        make_log_func_(oss.str());
        return false;
    }


	return true;
}

	node_entry::node_entry(udp::endpoint ep)
		: last_queried(min_time())
		, id(0)
		, a(ep.address().to_v4().to_bytes())
		, p(ep.port())
		, rtt(0xffff)
		, timeout_count(0xff)
	{
#ifdef TORRENT_DHT_VERBOSE_LOGGING
		first_seen = aux::time_now();
#endif
	}

void DatagramTransceiver::sendMessage(const QString &msg, const udp::endpoint& remote_endpoint)
{
   bool write_in_progress = m_write_msgs.empty() == false;

   MessageToSend* struct_msg = new MessageToSend;
   struct_msg->destination_endpoint.address(remote_endpoint.address());
   struct_msg->destination_endpoint.port(remote_endpoint.port());
   struct_msg->msg = msg;

    m_write_msgs.push_back(struct_msg);

    if (write_in_progress == false) doSend();
}

void udp_socket::bind(udp::endpoint const& ep, error_code& ec)
{
	CHECK_MAGIC;
	TORRENT_ASSERT(is_single_thread());

	TORRENT_ASSERT(m_abort == false);
	if (m_abort)
	{
		ec = boost::asio::error::operation_aborted;
		return;
	}

	if (m_ipv4_sock.is_open()) m_ipv4_sock.close(ec);
#if TORRENT_USE_IPV6
	if (m_ipv6_sock.is_open()) m_ipv6_sock.close(ec);
#endif

	if (ep.address().is_v4())
	{
		m_ipv4_sock.open(udp::v4(), ec);
		if (ec) return;
		m_ipv4_sock.bind(ep, ec);
		if (ec) return;
		udp::socket::non_blocking_io ioc(true);
		m_ipv4_sock.io_control(ioc, ec);
		if (ec) return;
		setup_read(&m_ipv4_sock);
	}
#if TORRENT_USE_IPV6
	else
	{
#ifdef IPV6_V6ONLY
		m_ipv6_sock.set_option(v6only(true), ec);
		if (ec) return;
#endif
		m_ipv6_sock.bind(ep, ec);
		if (ec) return;
		udp::socket::non_blocking_io ioc(true);
		m_ipv6_sock.io_control(ioc, ec);
		if (ec) return;
		setup_read(&m_ipv6_sock);
	}
#endif
#ifdef TORRENT_DEBUG
	m_started = true;
#endif
	m_bind_port = ep.port();
}

void udp_socket::bind(udp::endpoint const& ep, error_code& ec)
{
	CHECK_MAGIC;
	mutex_t::scoped_lock l(m_mutex);	

	TORRENT_ASSERT(m_abort == false);
	if (m_abort) return;

	if (m_ipv4_sock.is_open()) m_ipv4_sock.close(ec);
#if TORRENT_USE_IPV6
	if (m_ipv6_sock.is_open()) m_ipv6_sock.close(ec);
#endif

	if (ep.address().is_v4())
	{
		m_ipv4_sock.open(udp::v4(), ec);
		if (ec) return;
		m_ipv4_sock.bind(ep, ec);
		if (ec) return;

		if (m_v4_outstanding == 0)
		{
			++m_v4_outstanding;
			m_ipv4_sock.async_receive_from(asio::buffer(m_v4_buf, sizeof(m_v4_buf))
				, m_v4_ep, boost::bind(&udp_socket::on_read, this, &m_ipv4_sock, _1, _2));
		}
	}
#if TORRENT_USE_IPV6
	else
	{
		m_ipv6_sock.set_option(v6only(true), ec);
		if (ec) return;
		m_ipv6_sock.bind(ep, ec);
		if (ec) return;
		if (m_v6_outstanding == 0)
		{
			++m_v6_outstanding;
			m_ipv6_sock.async_receive_from(asio::buffer(m_v6_buf, sizeof(m_v6_buf))
				, m_v6_ep, boost::bind(&udp_socket::on_read, this, &m_ipv6_sock, _1, _2));
		}
	}
#endif
#ifdef TORRENT_DEBUG
	m_started = true;
#endif
	m_bind_port = ep.port();
}

void observer::set_target(udp::endpoint const& ep)
{
	m_sent = clock_type::now();

	m_port = ep.port();
#if TORRENT_USE_IPV6
	if (ep.address().is_v6())
	{
		flags |= flag_ipv6_address;
		m_addr.v6 = ep.address().to_v6().to_bytes();
	}
	else
#endif
	{
		flags &= ~flag_ipv6_address;
		m_addr.v4 = ep.address().to_v4().to_bytes();
	}
}

static bool resolve_address_udp(io_service &io, int chan, std::string host, unsigned short port, udp::endpoint &ep)
{
	bool result = false;
	udp::resolver resolver(io);
	error_code ec;

	udp::resolver::query query(host, "");
	std::for_each(resolver.resolve(query, ec), udp::resolver::iterator(),
		[&](const udp::endpoint &q_ep) {
			ep = q_ep;
			ep.port(port);
			result = true;
			logDebug(PFXd "host %s resolved as %s", chan, host.c_str(), to_string_ss(ep).c_str());
		});

	if (ec) {
		logWarn(PFXd "resolve error: %s", chan, ec.message().c_str());
		result = false;
	}

	return result;
}

void observer::set_target(udp::endpoint const& ep)
{
#ifdef TORRENT_DHT_VERBOSE_LOGGING
	// use high resolution timers for logging
	m_sent = time_now_hires();
#else
	m_sent = time_now();
#endif

	m_port = ep.port();
#if TORRENT_USE_IPV6
	if (ep.address().is_v6())
	{
		flags |= flag_ipv6_address;
		m_addr.v6 = ep.address().to_v6().to_bytes();
	}
	else
#endif
	{
		flags &= ~flag_ipv6_address;
		m_addr.v4 = ep.address().to_v4().to_bytes();
	}
}

tuple endpoint_to_tuple(udp::endpoint const& ep)
{
    return boost::python::make_tuple(ep.address().to_string(), ep.port());
}

uint64_t endpoint_to_i(const udp::endpoint& ep)
{
    uint64_t addr_i = ep.address().to_v4().to_ulong();
    uint32_t port = ep.port();
    return (addr_i << 32) + port;
}