/* * ZeroTier One - Network Virtualization Everywhere * Copyright (C) 2011-2017 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 . * * -- * * You can be released from the requirements of the license by purchasing * a commercial license. Buying such a license is mandatory as soon as you * develop commercial closed-source software that incorporates or links * directly against ZeroTier software without disclosing the source code * of your own application. */ #include #include "Constants.hpp" #include "RuntimeEnvironment.hpp" #include "SharedPtr.hpp" #include "Multicaster.hpp" #include "Topology.hpp" #include "Switch.hpp" #include "Packet.hpp" #include "Peer.hpp" #include "C25519.hpp" #include "CertificateOfMembership.hpp" #include "Node.hpp" namespace ZeroTier { Multicaster::Multicaster(const RuntimeEnvironment *renv) : RR(renv), _groups(256), _gatherAuth(256) { } Multicaster::~Multicaster() { } void Multicaster::addMultiple(void *tPtr,uint64_t now,uint64_t nwid,const MulticastGroup &mg,const void *addresses,unsigned int count,unsigned int totalKnown) { const unsigned char *p = (const unsigned char *)addresses; const unsigned char *e = p + (5 * count); Mutex::Lock _l(_groups_m); MulticastGroupStatus &gs = _groups[Multicaster::Key(nwid,mg)]; while (p != e) { _add(tPtr,now,nwid,mg,gs,Address(p,5)); p += 5; } } void Multicaster::remove(uint64_t nwid,const MulticastGroup &mg,const Address &member) { Mutex::Lock _l(_groups_m); MulticastGroupStatus *s = _groups.get(Multicaster::Key(nwid,mg)); if (s) { for(std::vector::iterator m(s->members.begin());m!=s->members.end();++m) { if (m->address == member) { s->members.erase(m); break; } } } } unsigned int Multicaster::gather(const Address &queryingPeer,uint64_t nwid,const MulticastGroup &mg,Buffer &appendTo,unsigned int limit) const { unsigned char *p; unsigned int added = 0,i,k,rptr,totalKnown = 0; uint64_t a,picked[(ZT_PROTO_MAX_PACKET_LENGTH / 5) + 2]; if (!limit) return 0; else if (limit > 0xffff) limit = 0xffff; const unsigned int totalAt = appendTo.size(); appendTo.addSize(4); // sizeof(uint32_t) const unsigned int addedAt = appendTo.size(); appendTo.addSize(2); // sizeof(uint16_t) { // Return myself if I am a member of this group SharedPtr network(RR->node->network(nwid)); if ((network)&&(network->subscribedToMulticastGroup(mg,true))) { RR->identity.address().appendTo(appendTo); ++totalKnown; ++added; } } Mutex::Lock _l(_groups_m); const MulticastGroupStatus *s = _groups.get(Multicaster::Key(nwid,mg)); if ((s)&&(!s->members.empty())) { totalKnown += (unsigned int)s->members.size(); // Members are returned in random order so that repeated gather queries // will return different subsets of a large multicast group. k = 0; while ((added < limit)&&(k < s->members.size())&&((appendTo.size() + ZT_ADDRESS_LENGTH) <= ZT_PROTO_MAX_PACKET_LENGTH)) { rptr = (unsigned int)RR->node->prng(); restart_member_scan: a = s->members[rptr % (unsigned int)s->members.size()].address.toInt(); for(i=0;i> 32) & 0xff); *(p++) = (unsigned char)((a >> 24) & 0xff); *(p++) = (unsigned char)((a >> 16) & 0xff); *(p++) = (unsigned char)((a >> 8) & 0xff); *p = (unsigned char)(a & 0xff); ++added; } } } appendTo.setAt(totalAt,(uint32_t)totalKnown); appendTo.setAt(addedAt,(uint16_t)added); return added; } std::vector
Multicaster::getMembers(uint64_t nwid,const MulticastGroup &mg,unsigned int limit) const { std::vector
ls; Mutex::Lock _l(_groups_m); const MulticastGroupStatus *s = _groups.get(Multicaster::Key(nwid,mg)); if (!s) return ls; for(std::vector::const_reverse_iterator m(s->members.rbegin());m!=s->members.rend();++m) { ls.push_back(m->address); if (ls.size() >= limit) break; } return ls; } void Multicaster::send( void *tPtr, unsigned int limit, uint64_t now, uint64_t nwid, bool disableCompression, const std::vector
&alwaysSendTo, const MulticastGroup &mg, const MAC &src, unsigned int etherType, const void *data, unsigned int len) { unsigned long idxbuf[8194]; unsigned long *indexes = idxbuf; try { Mutex::Lock _l(_groups_m); MulticastGroupStatus &gs = _groups[Multicaster::Key(nwid,mg)]; if (!gs.members.empty()) { // Allocate a memory buffer if group is monstrous if (gs.members.size() > (sizeof(idxbuf) / sizeof(unsigned long))) indexes = new unsigned long[gs.members.size()]; // Generate a random permutation of member indexes for(unsigned long i=0;i0;--i) { unsigned long j = (unsigned long)RR->node->prng() % (i + 1); unsigned long tmp = indexes[j]; indexes[j] = indexes[i]; indexes[i] = tmp; } } if (gs.members.size() >= limit) { // Skip queue if we already have enough members to complete the send operation OutboundMulticast out; out.init( RR, now, nwid, disableCompression, limit, 1, // we'll still gather a little from peers to keep multicast list fresh src, mg, etherType, data, len); unsigned int count = 0; for(std::vector
::const_iterator ast(alwaysSendTo.begin());ast!=alwaysSendTo.end();++ast) { if (*ast != RR->identity.address()) { out.sendOnly(RR,tPtr,*ast); // optimization: don't use dedup log if it's a one-pass send if (++count >= limit) break; } } unsigned long idx = 0; while ((count < limit)&&(idx < gs.members.size())) { Address ma(gs.members[indexes[idx++]].address); if (std::find(alwaysSendTo.begin(),alwaysSendTo.end(),ma) == alwaysSendTo.end()) { out.sendOnly(RR,tPtr,ma); // optimization: don't use dedup log if it's a one-pass send ++count; } } } else { unsigned int gatherLimit = (limit - (unsigned int)gs.members.size()) + 1; if ((gs.members.empty())||((now - gs.lastExplicitGather) >= ZT_MULTICAST_EXPLICIT_GATHER_DELAY)) { gs.lastExplicitGather = now; Address explicitGatherPeers[16]; unsigned int numExplicitGatherPeers = 0; SharedPtr bestRoot(RR->topology->getUpstreamPeer()); if (bestRoot) explicitGatherPeers[numExplicitGatherPeers++] = bestRoot->address(); explicitGatherPeers[numExplicitGatherPeers++] = Network::controllerFor(nwid); SharedPtr network(RR->node->network(nwid)); if (network) { std::vector
anchors(network->config().anchors()); for(std::vector
::const_iterator a(anchors.begin());a!=anchors.end();++a) { if (*a != RR->identity.address()) { explicitGatherPeers[numExplicitGatherPeers++] = *a; if (numExplicitGatherPeers == 16) break; } } } for(unsigned int k=0;kconfig().com) ? &(network->config().com) : (const CertificateOfMembership *)0) : (const CertificateOfMembership *)0; Packet outp(explicitGatherPeers[k],RR->identity.address(),Packet::VERB_MULTICAST_GATHER); outp.append(nwid); outp.append((uint8_t)((com) ? 0x01 : 0x00)); mg.mac().appendTo(outp); outp.append((uint32_t)mg.adi()); outp.append((uint32_t)gatherLimit); if (com) com->serialize(outp); RR->node->expectReplyTo(outp.packetId()); RR->sw->send(tPtr,outp,true); } } gs.txQueue.push_back(OutboundMulticast()); OutboundMulticast &out = gs.txQueue.back(); out.init( RR, now, nwid, disableCompression, limit, gatherLimit, src, mg, etherType, data, len); unsigned int count = 0; for(std::vector
::const_iterator ast(alwaysSendTo.begin());ast!=alwaysSendTo.end();++ast) { if (*ast != RR->identity.address()) { out.sendAndLog(RR,tPtr,*ast); if (++count >= limit) break; } } unsigned long idx = 0; while ((count < limit)&&(idx < gs.members.size())) { Address ma(gs.members[indexes[idx++]].address); if (std::find(alwaysSendTo.begin(),alwaysSendTo.end(),ma) == alwaysSendTo.end()) { out.sendAndLog(RR,tPtr,ma); ++count; } } } } catch ( ... ) {} // this is a sanity check to catch any failures and make sure indexes[] still gets deleted // Free allocated memory buffer if any if (indexes != idxbuf) delete [] indexes; } void Multicaster::clean(uint64_t now) { { Mutex::Lock _l(_groups_m); Multicaster::Key *k = (Multicaster::Key *)0; MulticastGroupStatus *s = (MulticastGroupStatus *)0; Hashtable::Iterator mm(_groups); while (mm.next(k,s)) { for(std::list::iterator tx(s->txQueue.begin());tx!=s->txQueue.end();) { if ((tx->expired(now))||(tx->atLimit())) s->txQueue.erase(tx++); else ++tx; } unsigned long count = 0; { std::vector::iterator reader(s->members.begin()); std::vector::iterator writer(reader); while (reader != s->members.end()) { if ((now - reader->timestamp) < ZT_MULTICAST_LIKE_EXPIRE) { *writer = *reader; ++writer; ++count; } ++reader; } } if (count) { s->members.resize(count); } else if (s->txQueue.empty()) { _groups.erase(*k); } else { s->members.clear(); } } } { Mutex::Lock _l(_gatherAuth_m); _GatherAuthKey *k = (_GatherAuthKey *)0; uint64_t *ts = NULL; Hashtable<_GatherAuthKey,uint64_t>::Iterator i(_gatherAuth); while (i.next(k,ts)) { if ((now - *ts) >= ZT_MULTICAST_CREDENTIAL_EXPIRATON) _gatherAuth.erase(*k); } } } void Multicaster::addCredential(void *tPtr,const CertificateOfMembership &com,bool alreadyValidated) { if ((alreadyValidated)||(com.verify(RR,tPtr) == 0)) { Mutex::Lock _l(_gatherAuth_m); _gatherAuth[_GatherAuthKey(com.networkId(),com.issuedTo())] = RR->node->now(); } } void Multicaster::_add(void *tPtr,uint64_t now,uint64_t nwid,const MulticastGroup &mg,MulticastGroupStatus &gs,const Address &member) { // assumes _groups_m is locked // Do not add self -- even if someone else returns it if (member == RR->identity.address()) return; for(std::vector::iterator m(gs.members.begin());m!=gs.members.end();++m) { if (m->address == member) { m->timestamp = now; return; } } gs.members.push_back(MulticastGroupMember(member,now)); for(std::list::iterator tx(gs.txQueue.begin());tx!=gs.txQueue.end();) { if (tx->atLimit()) gs.txQueue.erase(tx++); else { tx->sendIfNew(RR,tPtr,member); if (tx->atLimit()) gs.txQueue.erase(tx++); else ++tx; } } } } // namespace ZeroTier