NodeTable into own files.

10 years ago · 6131bd62d6
2 changed files with 577 additions and 0 deletions
--- a/libp2p/NodeTable.cpp
+++ b/libp2p/NodeTable.cpp
@ -0,0 +1,351 @@
 /*
 This file is part of cpp-ethereum.
 cpp-ethereum is free software: you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation, either version 3 of the License, or
 (at your option) any later version.
 cpp-ethereum is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License
 along with cpp-ethereum.  If not, see <http://www.gnu.org/licenses/>.
 */
 /** @file NodeTable.cpp
 * @author Alex Leverington <nessence@gmail.com>
 * @date 2014
 */
 #include "NodeTable.h"
 using namespace std;
 using namespace dev;
 using namespace dev::p2p;
 NodeTable::NodeTable(ba::io_service& _io):
 		m_node(NodeEntry(Address(), Public(), bi::udp::endpoint())),
 		m_socket(new nodeSocket(_io, *this, 30300)),
 		m_socketPtr(m_socket.get()),
 		m_io(_io),
 		m_bucketRefreshTimer(m_io),
 		m_evictionCheckTimer(m_io)
 	{
 		for (unsigned i = 0; i < s_bins; i++)
 			m_state[i].distance = i, m_state[i].modified = chrono::steady_clock::now() - chrono::seconds(1);
 		doRefreshBuckets(boost::system::error_code());
 	}
 NodeTable::~NodeTable()
 {
 	m_evictionCheckTimer.cancel();
 	m_bucketRefreshTimer.cancel();
 	m_socketPtr->disconnect();
 }
 	void NodeTable::join()
 {
 	doFindNode(m_node.id);
 }
 std::list<Address> NodeTable::nodes() const
 {
 	std::list<Address> nodes;
 	Guard l(x_nodes);
 	for (auto& i: m_nodes)
 		nodes.push_back(i.second->id);
 	return std::move(nodes);
 }
 NodeTable::NodeEntry NodeTable::operator[](Address _id)
 {
 	Guard l(x_nodes);
 	return *m_nodes[_id];
 }
 void NodeTable::requestNeighbors(NodeEntry const& _node, Address _target) const
 {
 	FindNeighbors p;
 	p.target = _target;
 	p.to = _node.endpoint.udp;
 	p.seal(m_secret);
 	m_socketPtr->send(p);
 }
 void NodeTable::doFindNode(Address _node, unsigned _round, std::shared_ptr<std::set<std::shared_ptr<NodeEntry>>> _tried)
 {
 	if (!m_socketPtr->isOpen() || _round == 7)
 		return;
 	auto nearest = findNearest(_node);
 	std::list<std::shared_ptr<NodeEntry>> tried;
 	for (unsigned i = 0; i < nearest.size() && tried.size() < s_alpha; i++)
 		if (!_tried->count(nearest[i]))
 		{
 			tried.push_back(nearest[i]);
 			requestNeighbors(*nearest[i], _node);
 		}
 		else
 			continue;
 	while (auto n = tried.front())
 	{
 		_tried->insert(n);
 		tried.pop_front();
 	}
 	auto self(shared_from_this());
 	m_evictionCheckTimer.expires_from_now(boost::posix_time::milliseconds(s_findTimout));
 	m_evictionCheckTimer.async_wait([this, self, _node, _round, _tried](boost::system::error_code const& _ec)
 	{
 		if (_ec)
 			return;
 		doFindNode(_node, _round + 1, _tried);
 	});
 }
 std::vector<std::shared_ptr<NodeTable::NodeEntry>> NodeTable::findNearest(Address _target)
 {
 	// send s_alpha FindNeighbors packets to nodes we know, closest to target
 	unsigned head = dist(m_node.id, _target);
 	unsigned tail = (head - 1) % (s_bits - 1);
 	// todo: optimize with tree
 	std::map<unsigned, std::list<std::shared_ptr<NodeEntry>>> found;
 	unsigned count = 0;
 	// if d is 0, then we roll look forward, if last, we reverse, else, spread from d
 	if (head != 0 && tail != s_bits)
 		while (head != tail && count < s_bucketSize)
 		{
 			Guard l(x_state);
 			for (auto& n: m_state[head].nodes)
 				if (auto p = n.lock())
 				{
 					if (count < s_bucketSize)
 						found[dist(_target, p->id)].push_back(p);
 					else
 						break;
 				}
 			if (count < s_bucketSize && head)
 				for (auto& n: m_state[tail].nodes)
 					if (auto p = n.lock())
 					{
 						if (count < s_bucketSize)
 							found[dist(_target, p->id)].push_back(p);
 						else
 							break;
 					}
 			head++;
 			tail = (tail - 1) % (s_bits - 1);
 		}
 	else if (head == 0)
 		while (head < s_bucketSize && count < s_bucketSize)
 		{
 			Guard l(x_state);
 			for (auto& n: m_state[head].nodes)
 				if (auto p = n.lock())
 				{
 					if (count < s_bucketSize)
 						found[dist(_target, p->id)].push_back(p);
 					else
 						break;
 				}
 			head--;
 		}
 	else if (tail == s_bits - 1)
 		while (tail > 0 && count < s_bucketSize)
 		{
 			Guard l(x_state);
 			for (auto& n: m_state[tail].nodes)
 				if (auto p = n.lock())
 				{
 					if (count < s_bucketSize)
 						found[dist(_target, p->id)].push_back(p);
 					else
 						break;
 				}
 			tail--;
 		}
 	std::vector<std::shared_ptr<NodeEntry>> ret;
 	for (auto& nodes: found)
 		for (auto& n: nodes.second)
 			ret.push_back(n);
 	return std::move(ret);
 }
 void NodeTable::ping(bi::address _address, unsigned _port) const
 {
 	PingNode p;
 	string ip = m_node.endpoint.udp.address().to_string();
 	p.ipAddress = asBytes(ip);
 	p.port = m_node.endpoint.udp.port();
 //		p.expiration;
 	p.seal(m_secret);
 	m_socketPtr->send(p);
 }
 void NodeTable::ping(NodeEntry* _n) const
 {
 	if (_n && _n->endpoint.udp.address().is_v4())
 		ping(_n->endpoint.udp.address(), _n->endpoint.udp.port());
 }
 void NodeTable::evict(std::shared_ptr<NodeEntry> _leastSeen, std::shared_ptr<NodeEntry> _new)
 {
 	if (!m_socketPtr->isOpen())
 		return;
 	Guard l(x_evictions);
 	m_evictions.push_back(EvictionTimeout(make_pair(_leastSeen->id,chrono::steady_clock::now()), _new->id));
 	if (m_evictions.size() == 1)
 		doCheckEvictions(boost::system::error_code());
 	m_evictions.push_back(EvictionTimeout(make_pair(_leastSeen->id,chrono::steady_clock::now()), _new->id));
 	ping(_leastSeen.get());
 }
 void NodeTable::noteNode(Public _pubk, bi::udp::endpoint _endpoint)
 {
 	Address id = right160(sha3(_pubk));
 	std::shared_ptr<NodeEntry> node;
 	{
 		Guard l(x_nodes);
 		auto n = m_nodes.find(id);
 		if (n == m_nodes.end())
 		{
 			m_nodes[id] = std::shared_ptr<NodeEntry>(new NodeEntry(m_node, id, _pubk, _endpoint));
 			node = m_nodes[id];
 		}
 		else
 			node = n->second;
 	}
 	noteNode(node);
 }
 void NodeTable::noteNode(std::shared_ptr<NodeEntry> _n)
 {
 	std::shared_ptr<NodeEntry> contested;
 	{
 		NodeBucket s = bucket(_n.get());
 		Guard l(x_state);
 		s.nodes.remove_if([&_n](std::weak_ptr<NodeEntry> n)
 		{
 			auto p = n.lock();
 			if (!p || p == _n)
 				return true;
 			return false;
 		});
 		if (s.nodes.size() >= s_bucketSize)
 		{
 			contested = s.nodes.front().lock();
 			if (!contested)
 			{
 				s.nodes.pop_front();
 				s.nodes.push_back(_n);
 			}
 		}
 		else
 			s.nodes.push_back(_n);
 	}
 	if (contested)
 		evict(contested, _n);
 }
 void NodeTable::dropNode(std::shared_ptr<NodeEntry> _n)
 {
 	NodeBucket s = bucket(_n.get());
 	{
 		Guard l(x_state);
 		s.nodes.remove_if([&_n](std::weak_ptr<NodeEntry> n) { return n.lock() == _n; });
 	}
 	Guard l(x_nodes);
 	m_nodes.erase(_n->id);
 }
 NodeTable::NodeBucket const& NodeTable::bucket(NodeEntry* _n) const
 {
 	return m_state[_n->distance];
 }
 void NodeTable::onReceived(UDPSocketFace*, bi::udp::endpoint const& _from, bytesConstRef _packet)
 {
 	RLP rlp(_packet);
 	// whenever a pong is received, first check if it's in m_evictions, if so, remove it
 	Guard l(x_evictions);
 }
 void NodeTable::doCheckEvictions(boost::system::error_code const& _ec)
 {
 	if (_ec || !m_socketPtr->isOpen())
 		return;
 	m_evictionCheckTimer.expires_from_now(boost::posix_time::milliseconds(s_evictionCheckInterval));
 	auto self(shared_from_this());
 	m_evictionCheckTimer.async_wait([this, self](boost::system::error_code const& _ec)
 	{
 		if (_ec)
 			return;
 		bool evictionsRemain = false;
 		std::list<shared_ptr<NodeEntry>> drop;
 		{
 			Guard l(x_evictions);
 			for (auto& e: m_evictions)
 				if (chrono::steady_clock::now() - e.first.second > chrono::milliseconds(s_pingTimeout))
 				{
 					Guard l(x_nodes);
 					drop.push_back(m_nodes[e.second]);
 				}
 			evictionsRemain = m_evictions.size() - drop.size() > 0;
 		}
 		for (auto& n: drop)
 			dropNode(n);
 		if (evictionsRemain)
 			doCheckEvictions(boost::system::error_code());
 	});
 }
 void NodeTable::doRefreshBuckets(boost::system::error_code const& _ec)
 {
 	cout << "refreshing buckets" << endl;
 	if (_ec)
 		return;
 	bool connected = m_socketPtr->isOpen();
 	bool refreshed = false;
 	if (connected)
 	{
 		Guard l(x_state);
 		for (auto& d: m_state)
 			if (chrono::steady_clock::now() - d.modified > chrono::seconds(s_bucketRefresh))
 				while (!d.nodes.empty())
 				{
 					auto n = d.nodes.front();
 					if (auto p = n.lock())
 					{
 						refreshed = true;
 						ping(p.get());
 						break;
 					}
 					d.nodes.pop_front();
 				}
 	}
 	unsigned nextRefresh = connected ? (refreshed ? 200 : s_bucketRefresh*1000) : 10000;
 	auto runcb = [this](boost::system::error_code const& error) -> void { doRefreshBuckets(error); };
 	m_bucketRefreshTimer.expires_from_now(boost::posix_time::milliseconds(nextRefresh));
 	m_bucketRefreshTimer.async_wait(runcb);
 }
--- a/libp2p/NodeTable.h
+++ b/libp2p/NodeTable.h
@ -0,0 +1,226 @@
 /*
 This file is part of cpp-ethereum.
 cpp-ethereum is free software: you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation, either version 3 of the License, or
 (at your option) any later version.
 cpp-ethereum is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License
 along with cpp-ethereum.  If not, see <http://www.gnu.org/licenses/>.
 */
 /** @file NodeTable.h
 * @author Alex Leverington <nessence@gmail.com>
 * @date 2014
 */
 #pragma once
 #include <libdevcrypto/Common.h>
 #include <libp2p/UDP.h>
 namespace dev
 {
 namespace p2p
 {
 /**
 * Ping packet: Check if node is alive.
 * PingNode is cached and regenerated after expiration - t, where t is timeout.
 *
 * signature: Signature of message.
 * ipAddress: Our IP address.
 * port: Our port.
 * expiration: Triggers regeneration of packet. May also provide control over synchronization.
 *
 * Ping is used to implement evict. When a new node is seen for
 * a given bucket which is full, the least-responsive node is pinged.
 * If the pinged node doesn't respond then it is removed and the new
 * node is inserted.
 */
 struct PingNode: RLPDatagram
 {
 	bytes ipAddress;
 	uint16_t port;
 	uint64_t expiration;
 	Signature signature;
 	void streamRLP(RLPStream& _s) const { _s.appendList(3); _s << ipAddress << port << expiration; }
 };
 struct Pong: RLPDatagram
 {
 	// todo: weak-signed pong
 	Address from;
 	uint64_t replyTo;	/// expiration from PingNode
 	void streamRLP(RLPStream& _s) const { _s.appendList(2); _s << from << replyTo; }
 };
 /**
 * FindNeighbors Packet: Request k-nodes, closest to the target.
 * FindNeighbors is cached and regenerated after expiration - t, where t is timeout.
 *
 * signature: Signature of message.
 * target: Address of NodeId. The responding node will send back nodes closest to the target.
 * expiration: Triggers regeneration of packet. May also provide control over synchronization.
 *
 */
 struct FindNeighbors: RLPDatagram
 {
 	h160 target;
 	uint64_t expiration;
 	Signature signature;
 	void streamRLP(RLPStream& _s) const { _s.appendList(2); _s << target << expiration; }
 };
 /**
 * Node Packet: Multiple node packets are sent in response to FindNeighbors.
 */
 struct Neighbors: RLPDatagram
 {
 	struct Node
 	{
 		bytes ipAddress;
 		uint16_t port;
 		NodeId node;
 		void streamRLP(RLPStream& _s) const { _s.appendList(3); _s << ipAddress << port << node; }
 	};
 	std::set<Node> nodes;
 	h256 nonce;
 	Signature signature;
 	void streamRLP(RLPStream& _s) const { _s.appendList(2); _s.appendList(nodes.size()); for (auto& n: nodes) n.streamRLP(_s); _s << nonce; }
 };
 /**
 * NodeTable using S/Kademlia system for node discovery and preference.
 * untouched buckets are refreshed if they have not been touched within an hour
 *
 * Thread-safety is ensured by modifying NodeEntry details via 
 * shared_ptr replacement instead of mutating values.
 *
 * @todo don't try to evict node if node isRequired. (support for makeRequired)
 * @todo optimize (use tree for state (or set w/custom compare for cache))
 * @todo constructor support for m_node, m_secret
 * @todo use s_bitsPerStep for find and refresh/ping
 * @todo exclude bucket from refresh if we have node as peer
 * @todo restore nodes
 */
 class NodeTable: UDPSocketEvents, public std::enable_shared_from_this<NodeTable>
 {
 	using nodeSocket = UDPSocket<NodeTable, 1024>;
 	using timePoint = std::chrono::steady_clock::time_point;
 	static unsigned const s_bucketSize = 16;			// Denoted by k in [Kademlia]. Number of nodes stored in each bucket.
 //	const unsigned s_bitsPerStep = 5;					// @todo Denoted by b in [Kademlia]. Bits by which address space will be divided for find responses.
 	static unsigned const s_alpha = 3;				// Denoted by \alpha in [Kademlia]. Number of concurrent FindNeighbors requests.
 	const unsigned s_findTimout = 300;				// How long to wait between find queries.
 //	const unsigned s_siblings = 5;					// @todo Denoted by s in [S/Kademlia]. User-defined by sub-protocols.
 	const unsigned s_bucketRefresh = 3600;				// Refresh interval prevents bucket from becoming stale. [Kademlia]
 	static unsigned const s_bits = 8 * Address::size;	// Denoted by n.
 	static unsigned const s_bins = s_bits - 1;			//
 	const unsigned s_evictionCheckInterval = 75;		// Interval by which eviction timeouts are checked.
 	const unsigned s_pingTimeout = 500;
 public:
 	static unsigned dist(Address const& _a, Address const& _b) { u160 d = _a ^ _b; unsigned ret; for (ret = 0; d >>= 1; ++ret) {}; return ret; }
 	struct NodeDefaultEndpoint
 	{
 		NodeDefaultEndpoint(bi::udp::endpoint _udp): udp(_udp) {}
 		bi::udp::endpoint udp;
 	};
 	struct NodeEntry
 	{
 		NodeEntry(Address _id, Public _pubk, bi::udp::endpoint _udp): id(_id), pubk(_pubk), endpoint(NodeDefaultEndpoint(_udp)), distance(0) {}
 		NodeEntry(NodeEntry _src, Address _id, Public _pubk, bi::udp::endpoint _udp): id(_id), pubk(_pubk), endpoint(NodeDefaultEndpoint(_udp)), distance(dist(_src.id,_id)) {}
 		NodeEntry(NodeEntry _src, Address _id, Public _pubk, NodeDefaultEndpoint _gw): id(_id), pubk(_pubk), endpoint(_gw), distance(dist(_src.id,_id)) {}
 		Address id;
 		Public pubk;
 		NodeDefaultEndpoint endpoint;		///< How we've previously connected to this node. (must match node's reported endpoint)
 		const unsigned distance;
 		timePoint activePing;
 	};
 	struct NodeBucket
 	{
 		unsigned distance;
 		timePoint modified;
 		std::list<std::weak_ptr<NodeEntry>> nodes;
 	};
 	using EvictionTimeout = std::pair<std::pair<Address,timePoint>,Address>;
 	NodeTable(ba::io_service& _io);
 	~NodeTable();
 	void join();
 	std::list<Address> nodes() const;
 	NodeEntry operator[](Address _id);
 protected:
 	void requestNeighbors(NodeEntry const& _node, Address _target) const;
 	/// Sends requests to other nodes requesting nodes "near" to us in order to populate node table such that connected nodes form centrality.
 	void doFindNode(Address _node, unsigned _round = 0, std::shared_ptr<std::set<std::shared_ptr<NodeEntry>>> _tried = std::shared_ptr<std::set<std::shared_ptr<NodeEntry>>>());
 	std::vector<std::shared_ptr<NodeEntry>> findNearest(Address _target);
 	void ping(bi::address _address, unsigned _port) const;
 	void ping(NodeEntry* _n) const;
 	void evict(std::shared_ptr<NodeEntry> _leastSeen, std::shared_ptr<NodeEntry> _new);
 	void noteNode(Public _pubk, bi::udp::endpoint _endpoint);
 	void noteNode(std::shared_ptr<NodeEntry> _n);
 	void dropNode(std::shared_ptr<NodeEntry> _n);
 	NodeBucket const& bucket(NodeEntry* _n) const;
 	void onReceived(UDPSocketFace*, bi::udp::endpoint const& _from, bytesConstRef _packet);
 	void onDisconnected(UDPSocketFace*) {};
 	void doCheckEvictions(boost::system::error_code const& _ec);
 	void doRefreshBuckets(boost::system::error_code const& _ec);
 private:
 	NodeEntry m_node;										///< This node.
 	Secret m_secret;											///< This nodes secret key.
 	mutable Mutex x_nodes;									///< Mutable for thread-safe copy in nodes() const.
 	std::map<Address, std::shared_ptr<NodeEntry>> m_nodes;		///< Address -> Node table (most common lookup path)
 	Mutex x_state;
 	std::array<NodeBucket, s_bins> m_state;					///< State table of binned nodes.
 	Mutex x_evictions;
 	std::deque<EvictionTimeout> m_evictions;					///< Eviction timeouts.
 	std::shared_ptr<nodeSocket> m_socket;							///< Shared pointer for our UDPSocket; ASIO requires shared_ptr.
 	nodeSocket* m_socketPtr;									///< Set to m_socket.get().
 	ba::io_service& m_io;										///< Used by bucket refresh timer.
 	boost::asio::deadline_timer m_bucketRefreshTimer;			///< Timer which schedules and enacts bucket refresh.
 	boost::asio::deadline_timer m_evictionCheckTimer;			///< Timer for handling node evictions.
 };
 }
 }