devilutionX-ZeroTierOne/node/SelfAwareness.cpp

/*
 * ZeroTier One - Network Virtualization Everywhere
 * Copyright (C) 2011-2016  ZeroTier, Inc.  https://www.zerotier.com/
 *
 * This program 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.
 *
 * This program 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 this program.  If not, see <http://www.gnu.org/licenses/>.
 */

#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#include <set>
#include <vector>

#include "Constants.hpp"
#include "SelfAwareness.hpp"
#include "RuntimeEnvironment.hpp"
#include "Node.hpp"
#include "Topology.hpp"
#include "Packet.hpp"
#include "Peer.hpp"
#include "Switch.hpp"

// Entry timeout -- make it fairly long since this is just to prevent stale buildup
#define ZT_SELFAWARENESS_ENTRY_TIMEOUT 3600000

namespace ZeroTier {

class _ResetWithinScope
{
public:
	_ResetWithinScope(uint64_t now,InetAddress::IpScope scope) :
		_now(now),
		_scope(scope) {}

	inline void operator()(Topology &t,const SharedPtr<Peer> &p)
	{
		if (p->resetWithinScope(_scope,_now))
			peersReset.push_back(p);
	}

	std::vector< SharedPtr<Peer> > peersReset;

private:
	uint64_t _now;
	InetAddress::IpScope _scope;
};

SelfAwareness::SelfAwareness(const RuntimeEnvironment *renv) :
	RR(renv),
	_phy(32)
{
}

SelfAwareness::~SelfAwareness()
{
}

void SelfAwareness::iam(const Address &reporter,const InetAddress &receivedOnLocalAddress,const InetAddress &reporterPhysicalAddress,const InetAddress &myPhysicalAddress,bool trusted,uint64_t now)
{
	const InetAddress::IpScope scope = myPhysicalAddress.ipScope();

	if ((scope != reporterPhysicalAddress.ipScope())||(scope == InetAddress::IP_SCOPE_NONE)||(scope == InetAddress::IP_SCOPE_LOOPBACK)||(scope == InetAddress::IP_SCOPE_MULTICAST))
		return;

	Mutex::Lock _l(_phy_m);
	PhySurfaceEntry &entry = _phy[PhySurfaceKey(reporter,receivedOnLocalAddress,reporterPhysicalAddress,scope)];

	if ( (trusted) && ((now - entry.ts) < ZT_SELFAWARENESS_ENTRY_TIMEOUT) && (!entry.mySurface.ipsEqual(myPhysicalAddress)) ) {
		// Changes to external surface reported by trusted peers causes path reset in this scope
		TRACE("physical address %s for scope %u as seen from %s(%s) differs from %s, resetting paths in scope",myPhysicalAddress.toString().c_str(),(unsigned int)scope,reporter.toString().c_str(),reporterPhysicalAddress.toString().c_str(),entry.mySurface.toString().c_str());
		entry.mySurface = myPhysicalAddress;
		entry.ts = now;
		entry.trusted = trusted;

		// Erase all entries in this scope that were not reported from this remote address to prevent 'thrashing'
		// due to multiple reports of endpoint change.
		// Don't use 'entry' after this since hash table gets modified.
		{
			Hashtable< PhySurfaceKey,PhySurfaceEntry >::Iterator i(_phy);
			PhySurfaceKey *k = (PhySurfaceKey *)0;
			PhySurfaceEntry *e = (PhySurfaceEntry *)0;
			while (i.next(k,e)) {
				if ((k->reporterPhysicalAddress != reporterPhysicalAddress)&&(k->scope == scope))
					_phy.erase(*k);
			}
		}

		// Reset all paths within this scope
		_ResetWithinScope rset(now,(InetAddress::IpScope)scope);
		RR->topology->eachPeer<_ResetWithinScope &>(rset);

		// Send a NOP to all peers for whom we forgot a path. This will cause direct
		// links to be re-established if possible, possibly using a root server or some
		// other relay.
		for(std::vector< SharedPtr<Peer> >::const_iterator p(rset.peersReset.begin());p!=rset.peersReset.end();++p) {
			if ((*p)->activelyTransferringFrames(now)) {
				Packet outp((*p)->address(),RR->identity.address(),Packet::VERB_NOP);
				RR->sw->send(outp,true);
			}
		}
	} else {
		// Otherwise just update DB to use to determine external surface info
		entry.mySurface = myPhysicalAddress;
		entry.ts = now;
		entry.trusted = trusted;
	}
}

void SelfAwareness::clean(uint64_t now)
{
	Mutex::Lock _l(_phy_m);
	Hashtable< PhySurfaceKey,PhySurfaceEntry >::Iterator i(_phy);
	PhySurfaceKey *k = (PhySurfaceKey *)0;
	PhySurfaceEntry *e = (PhySurfaceEntry *)0;
	while (i.next(k,e)) {
		if ((now - e->ts) >= ZT_SELFAWARENESS_ENTRY_TIMEOUT)
			_phy.erase(*k);
	}
}

std::vector<InetAddress> SelfAwareness::getSymmetricNatPredictions()
{
	/* This is based on ideas and strategies found here:
	 * https://tools.ietf.org/html/draft-takeda-symmetric-nat-traversal-00
	 *
	 * In short: a great many symmetric NATs allocate ports sequentially.
	 * This is common on enterprise and carrier grade NATs as well as consumer
	 * devices. This code generates a list of "you might try this" addresses by
	 * extrapolating likely port assignments from currently known external
	 * global IPv4 surfaces. These can then be included in a PUSH_DIRECT_PATHS
	 * message to another peer, causing it to possibly try these addresses and
	 * bust our local symmetric NAT. It works often enough to be worth the
	 * extra bit of code and does no harm in cases where it fails. */

	// Gather unique surfaces indexed by local received-on address and flag
	// us as behind a symmetric NAT if there is more than one.
	std::map< InetAddress,std::set<InetAddress> > surfaces;
	bool symmetric = false;
	{
		Mutex::Lock _l(_phy_m);

		Hashtable< PhySurfaceKey,PhySurfaceEntry >::Iterator i(_phy);
		PhySurfaceKey *k = (PhySurfaceKey *)0;
		PhySurfaceEntry *e = (PhySurfaceEntry *)0;
		InetAddress lastTrustedSurface;
		while (i.next(k,e)) {
			if ((e->mySurface.ss_family == AF_INET)&&(e->mySurface.ipScope() == InetAddress::IP_SCOPE_GLOBAL)) {
				std::set<InetAddress> &s = surfaces[k->receivedOnLocalAddress];

				/* MINOR SECURITY FIX:
				 *
				 * If the surface was not reported by a trusted (upstream) peer, we do
				 * not use its report of our surface IP for symmetric NAT prediction.
				 * Otherwise a peer could poison our external surface cache and then
				 * use this to coax us into suggesting their IP as an endpoint. This
				 * in turn could allow them to relay traffic for us. They could not
				 * decrypt or otherwise mess with it, but they could DOS us or record
				 * meta-data without anything appearing amiss.
				 *
				 * So for surfaces reported by untrusted peers we use the IP reported
				 * by a trusted peer and then just use the port.
				 *
				 * As far as we know this has never been exploited. We discovered it
				 * because certain weird configurations, such as load balancers and
				 * gateways that do not preserve IP information, can coax a node into
				 * reporting back false surface information. */
				if (e->trusted) {
					s.insert(e->mySurface);
					lastTrustedSurface = e->mySurface;
				} else if (lastTrustedSurface) {
					InetAddress tmp(lastTrustedSurface);
					tmp.setPort(e->mySurface.port());
					s.insert(tmp);
				}

				symmetric = symmetric||(s.size() > 1);
			}
		}
	}

	/* If we appear to be symmetrically NATed, generate and return extrapolations
	 * of those surfaces. Since PUSH_DIRECT_PATHS is sent multiple times, we
	 * probabilistically generate extrapolations of anywhere from +1 to +5 to
	 * increase the odds that it will work "eventually". */
	if (symmetric) {
		std::vector<InetAddress> r;
		for(std::map< InetAddress,std::set<InetAddress> >::iterator si(surfaces.begin());si!=surfaces.end();++si) {
			for(std::set<InetAddress>::iterator i(si->second.begin());i!=si->second.end();++i) {
				InetAddress ipp(*i);
				unsigned int p = ipp.port() + 1 + ((unsigned int)RR->node->prng() & 3);
				if (p >= 65535)
					p -= 64510; // NATs seldom use ports <=1024 so wrap to 1025
				ipp.setPort(p);
				if ((si->second.count(ipp) == 0)&&(std::find(r.begin(),r.end(),ipp) == r.end())) {
					r.push_back(ipp);
				}
			}
		}
		return r;
	}

	return std::vector<InetAddress>();
}

} // namespace ZeroTier