/* * Copyright (c)2019 ZeroTier, Inc. * * Use of this software is governed by the Business Source License included * in the LICENSE.TXT file in the project's root directory. * * Change Date: 2025-01-01 * * On the date above, in accordance with the Business Source License, use * of this software will be governed by version 2.0 of the Apache License. */ /****/ #ifndef ZT_TOPOLOGY_HPP #define ZT_TOPOLOGY_HPP #include #include #include #include #include #include #include "Constants.hpp" #include "../include/ZeroTierOne.h" #include "Address.hpp" #include "Identity.hpp" #include "Peer.hpp" #include "Path.hpp" #include "Mutex.hpp" #include "InetAddress.hpp" #include "Hashtable.hpp" #include "World.hpp" namespace ZeroTier { class RuntimeEnvironment; /** * Database of network topology */ class Topology { public: Topology(const RuntimeEnvironment *renv,void *tPtr); ~Topology(); /** * Add a peer to database * * This will not replace existing peers. In that case the existing peer * record is returned. * * @param tPtr Thread pointer to be handed through to any callbacks called as a result of this call * @param peer Peer to add * @return New or existing peer (should replace 'peer') */ SharedPtr addPeer(void *tPtr,const SharedPtr &peer); /** * Get a peer from its address * * @param tPtr Thread pointer to be handed through to any callbacks called as a result of this call * @param zta ZeroTier address of peer * @return Peer or NULL if not found */ SharedPtr getPeer(void *tPtr,const Address &zta); /** * @param tPtr Thread pointer to be handed through to any callbacks called as a result of this call * @param zta ZeroTier address of peer * @return Identity or NULL identity if not found */ Identity getIdentity(void *tPtr,const Address &zta); /** * Get a peer only if it is presently in memory (no disk cache) * * This also does not update the lastUsed() time for peers, which means * that it won't prevent them from falling out of RAM. This is currently * used in the Cluster code to update peer info without forcing all peers * across the entire cluster to remain in memory cache. * * @param zta ZeroTier address */ inline SharedPtr getPeerNoCache(const Address &zta) { Mutex::Lock _l(_peers_m); const SharedPtr *const ap = _peers.get(zta); if (ap) { return *ap; } return SharedPtr(); } /** * Get a Path object for a given local and remote physical address, creating if needed * * @param l Local socket * @param r Remote address * @return Pointer to canonicalized Path object */ inline SharedPtr getPath(const int64_t l,const InetAddress &r) { Mutex::Lock _l(_paths_m); SharedPtr &p = _paths[Path::HashKey(l,r)]; if (!p) { p.set(new Path(l,r)); } return p; } /** * Get the current best upstream peer * * @return Upstream or NULL if none available */ SharedPtr getUpstreamPeer(); /** * @param id Identity to check * @return True if this is a root server or a network preferred relay from one of our networks */ bool isUpstream(const Identity &id) const; /** * @param addr Address to check * @return True if we should accept a world update from this address */ bool shouldAcceptWorldUpdateFrom(const Address &addr) const; /** * @param ztaddr ZeroTier address * @return Peer role for this device */ ZT_PeerRole role(const Address &ztaddr) const; /** * Check for prohibited endpoints * * Right now this returns true if the designated ZT address is a root and if * the IP (IP only, not port) does not equal any of the IPs defined in the * current World. This is an extra little security feature in case root keys * get appropriated or something. * * Otherwise it returns false. * * @param ztaddr ZeroTier address * @param ipaddr IP address * @return True if this ZT/IP pair should not be allowed to be used */ bool isProhibitedEndpoint(const Address &ztaddr,const InetAddress &ipaddr) const; /** * Gets upstreams to contact and their stable endpoints (if known) * * @param eps Hash table to fill with addresses and their stable endpoints */ inline void getUpstreamsToContact(Hashtable< Address,std::vector > &eps) const { Mutex::Lock _l(_upstreams_m); for(std::vector::const_iterator i(_planet.roots().begin());i!=_planet.roots().end();++i) { if (i->identity != RR->identity) { std::vector &ips = eps[i->identity.address()]; for(std::vector::const_iterator j(i->stableEndpoints.begin());j!=i->stableEndpoints.end();++j) { if (std::find(ips.begin(),ips.end(),*j) == ips.end()) { ips.push_back(*j); } } } } for(std::vector::const_iterator m(_moons.begin());m!=_moons.end();++m) { for(std::vector::const_iterator i(m->roots().begin());i!=m->roots().end();++i) { if (i->identity != RR->identity) { std::vector &ips = eps[i->identity.address()]; for(std::vector::const_iterator j(i->stableEndpoints.begin());j!=i->stableEndpoints.end();++j) { if (std::find(ips.begin(),ips.end(),*j) == ips.end()) { ips.push_back(*j); } } } } } for(std::vector< std::pair >::const_iterator m(_moonSeeds.begin());m!=_moonSeeds.end();++m) { eps[m->second]; } } /** * @return Vector of active upstream addresses (including roots) */ inline std::vector
upstreamAddresses() const { Mutex::Lock _l(_upstreams_m); return _upstreamAddresses; } /** * @return Current moons */ inline std::vector moons() const { Mutex::Lock _l(_upstreams_m); return _moons; } /** * @return Moon IDs we are waiting for from seeds */ inline std::vector moonsWanted() const { Mutex::Lock _l(_upstreams_m); std::vector mw; for(std::vector< std::pair >::const_iterator s(_moonSeeds.begin());s!=_moonSeeds.end();++s) { if (std::find(mw.begin(),mw.end(),s->first) == mw.end()) { mw.push_back(s->first); } } return mw; } /** * @return Current planet */ inline World planet() const { Mutex::Lock _l(_upstreams_m); return _planet; } /** * @return Current planet's world ID */ inline uint64_t planetWorldId() const { return _planet.id(); // safe to read without lock, and used from within eachPeer() so don't lock } /** * @return Current planet's world timestamp */ inline uint64_t planetWorldTimestamp() const { return _planet.timestamp(); // safe to read without lock, and used from within eachPeer() so don't lock } /** * Validate new world and update if newer and signature is okay * * @param tPtr Thread pointer to be handed through to any callbacks called as a result of this call * @param newWorld A new or updated planet or moon to learn * @param alwaysAcceptNew If true, always accept new moons even if we're not waiting for one * @return True if it was valid and newer than current (or totally new for moons) */ bool addWorld(void *tPtr,const World &newWorld,bool alwaysAcceptNew); /** * Add a moon * * This loads it from moons.d if present, and if not adds it to * a list of moons that we want to contact. * * @param id Moon ID * @param seed If non-NULL, an address of any member of the moon to contact */ void addMoon(void *tPtr,const uint64_t id,const Address &seed); /** * Remove a moon * * @param tPtr Thread pointer to be handed through to any callbacks called as a result of this call * @param id Moon's world ID */ void removeMoon(void *tPtr,const uint64_t id); /** * Clean and flush database */ void doPeriodicTasks(void *tPtr,int64_t now); /** * @param now Current time * @return Number of peers with active direct paths */ inline unsigned long countActive(int64_t now) const { unsigned long cnt = 0; Mutex::Lock _l(_peers_m); Hashtable< Address,SharedPtr >::Iterator i(const_cast(this)->_peers); Address *a = (Address *)0; SharedPtr *p = (SharedPtr *)0; while (i.next(a,p)) { const SharedPtr pp((*p)->getAppropriatePath(now,false)); if (pp) { ++cnt; } } return cnt; } /** * Apply a function or function object to all peers * * @param f Function to apply * @tparam F Function or function object type */ template inline void eachPeer(F f) { Mutex::Lock _l(_peers_m); Hashtable< Address,SharedPtr >::Iterator i(_peers); Address *a = (Address *)0; SharedPtr *p = (SharedPtr *)0; while (i.next(a,p)) { f(*this,*((const SharedPtr *)p)); } } /** * @return All currently active peers by address (unsorted) */ inline std::vector< std::pair< Address,SharedPtr > > allPeers() const { Mutex::Lock _l(_peers_m); return _peers.entries(); } /** * @return True if I am a root server in a planet or moon */ inline bool amUpstream() const { return _amUpstream; } /** * Get info about a path * * The supplied result variables are not modified if no special config info is found. * * @param physicalAddress Physical endpoint address * @param mtu Variable set to MTU * @param trustedPathId Variable set to trusted path ID */ inline void getOutboundPathInfo(const InetAddress &physicalAddress,unsigned int &mtu,uint64_t &trustedPathId) { for(unsigned int i=0,j=_numConfiguredPhysicalPaths;i cpaths; for(unsigned int i=0,j=_numConfiguredPhysicalPaths;i ZT_MAX_PHYSMTU) { pc.mtu = ZT_MAX_PHYSMTU; } cpaths[*(reinterpret_cast(pathNetwork))] = pc; } else { cpaths.erase(*(reinterpret_cast(pathNetwork))); } unsigned int cnt = 0; for(std::map::const_iterator i(cpaths.begin());((i!=cpaths.end())&&(cntfirst; _physicalPathConfig[cnt].second = i->second; ++cnt; } _numConfiguredPhysicalPaths = cnt; } } private: Identity _getIdentity(void *tPtr,const Address &zta); void _memoizeUpstreams(void *tPtr); void _savePeer(void *tPtr,const SharedPtr &peer); const RuntimeEnvironment *const RR; std::pair _physicalPathConfig[ZT_MAX_CONFIGURABLE_PATHS]; volatile unsigned int _numConfiguredPhysicalPaths; Hashtable< Address,SharedPtr > _peers; Mutex _peers_m; Hashtable< Path::HashKey,SharedPtr > _paths; Mutex _paths_m; World _planet; std::vector _moons; std::vector< std::pair > _moonSeeds; std::vector
_upstreamAddresses; bool _amUpstream; Mutex _upstreams_m; // locks worlds, upstream info, moon info, etc. }; } // namespace ZeroTier #endif