mirror of
https://github.com/zerotier/ZeroTierOne.git
synced 2024-12-22 06:17:48 +00:00
671 lines
24 KiB
C++
671 lines
24 KiB
C++
/*
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* ZeroTier One - Global Peer to Peer Ethernet
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* Copyright (C) 2012-2013 ZeroTier Networks LLC
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*
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*
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* --
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*
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* ZeroTier may be used and distributed under the terms of the GPLv3, which
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* are available at: http://www.gnu.org/licenses/gpl-3.0.html
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*
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* If you would like to embed ZeroTier into a commercial application or
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* redistribute it in a modified binary form, please contact ZeroTier Networks
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* LLC. Start here: http://www.zerotier.com/
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*/
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#include <stdio.h>
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#include <stdlib.h>
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#include <algorithm>
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#include <utility>
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#include <stdexcept>
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#include "Switch.hpp"
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#include "Node.hpp"
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#include "EthernetTap.hpp"
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#include "InetAddress.hpp"
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#include "Topology.hpp"
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#include "RuntimeEnvironment.hpp"
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#include "Peer.hpp"
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#include "NodeConfig.hpp"
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#include "Demarc.hpp"
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#include "Filter.hpp"
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#include "../version.h"
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namespace ZeroTier {
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Switch::Switch(const RuntimeEnvironment *renv) :
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_r(renv)
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{
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}
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Switch::~Switch()
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{
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}
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void Switch::onRemotePacket(Demarc::Port localPort,const InetAddress &fromAddr,const Buffer<4096> &data)
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{
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try {
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if (data.size() > ZT_PROTO_MIN_FRAGMENT_LENGTH) {
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if (data[ZT_PACKET_FRAGMENT_IDX_FRAGMENT_INDICATOR] == ZT_PACKET_FRAGMENT_INDICATOR)
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_handleRemotePacketFragment(localPort,fromAddr,data);
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else if (data.size() > ZT_PROTO_MIN_PACKET_LENGTH)
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_handleRemotePacketHead(localPort,fromAddr,data);
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}
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} catch (std::exception &ex) {
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TRACE("dropped packet from %s: unexpected exception: %s",fromAddr.toString().c_str(),ex.what());
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} catch ( ... ) {
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TRACE("dropped packet from %s: unexpected exception: (unknown)",fromAddr.toString().c_str());
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}
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}
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void Switch::onLocalEthernet(const SharedPtr<Network> &network,const MAC &from,const MAC &to,unsigned int etherType,const Buffer<4096> &data)
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{
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if (from != network->tap().mac()) {
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LOG("ignored tap: %s -> %s %s (bridging is not (yet?) supported)",from.toString().c_str(),to.toString().c_str(),Filter::etherTypeName(etherType));
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return;
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}
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if (to == network->tap().mac()) {
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LOG("%s: frame received from self, ignoring (bridge loop?)",network->tap().deviceName().c_str());
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return;
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}
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if ((etherType != ZT_ETHERTYPE_ARP)&&(etherType != ZT_ETHERTYPE_IPV4)&&(etherType != ZT_ETHERTYPE_IPV6)) {
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LOG("ignored tap: %s -> %s %s (not a supported etherType)",from.toString().c_str(),to.toString().c_str(),Filter::etherTypeName(etherType));
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return;
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}
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if (to.isMulticast()) {
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MulticastGroup mg(to,0);
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if (to.isBroadcast()) {
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// Handle broadcast special cases
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// Cram IPv4 IP into ADI field to make IPv4 ARP broadcast channel specific and scalable
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if ((etherType == ZT_ETHERTYPE_ARP)&&(data.size() == 28)&&(data[2] == 0x08)&&(data[3] == 0x00)&&(data[4] == 6)&&(data[5] == 4)&&(data[7] == 0x01))
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mg = MulticastGroup::deriveMulticastGroupForAddressResolution(InetAddress(data.field(24,4),4,0));
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}
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Multicaster::MulticastBloomFilter bloom;
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SharedPtr<Peer> propPeers[ZT_MULTICAST_PROPAGATION_BREADTH];
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unsigned int np = _r->multicaster->pickNextPropagationPeers(
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*(_r->prng),
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*(_r->topology),
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network->id(),
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mg,
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_r->identity.address(),
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Address(),
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bloom,
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ZT_MULTICAST_PROPAGATION_BREADTH,
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propPeers,
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Utils::now());
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if (!np)
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return;
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std::string signature(Multicaster::signMulticastPacket(_r->identity,network->id(),from,mg,etherType,data.data(),data.size()));
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if (!signature.length()) {
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TRACE("failure signing multicast message!");
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return;
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}
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Packet outpTmpl(propPeers[0]->address(),_r->identity.address(),Packet::VERB_MULTICAST_FRAME);
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outpTmpl.append((uint8_t)0);
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outpTmpl.append((uint64_t)network->id());
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_r->identity.address().appendTo(outpTmpl);
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outpTmpl.append(from.data,6);
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outpTmpl.append(mg.mac().data,6);
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outpTmpl.append((uint32_t)mg.adi());
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outpTmpl.append(bloom.data(),ZT_PROTO_VERB_MULTICAST_FRAME_BLOOM_FILTER_SIZE_BYTES);
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outpTmpl.append((uint8_t)0); // 0 hops
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outpTmpl.append((uint16_t)etherType);
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outpTmpl.append((uint16_t)data.size());
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outpTmpl.append((uint16_t)signature.length());
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outpTmpl.append(data.data(),data.size());
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outpTmpl.append(signature.data(),signature.length());
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outpTmpl.compress();
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send(outpTmpl,true);
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for(unsigned int i=1;i<np;++i) {
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outpTmpl.newInitializationVector();
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outpTmpl.setDestination(propPeers[i]->address());
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send(outpTmpl,true);
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}
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} else if (to.isZeroTier()) {
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// Simple unicast frame from us to another node
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Address toZT(to.data + 1,ZT_ADDRESS_LENGTH);
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if (network->isAllowed(toZT)) {
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Packet outp(toZT,_r->identity.address(),Packet::VERB_FRAME);
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outp.append(network->id());
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outp.append((uint16_t)etherType);
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outp.append(data);
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outp.compress();
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send(outp,true);
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} else {
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TRACE("UNICAST: %s -> %s %s (dropped, destination not a member of closed network %llu)",from.toString().c_str(),to.toString().c_str(),Filter::etherTypeName(etherType),network->id());
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}
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} else {
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TRACE("UNICAST: %s -> %s %s (dropped, destination MAC not ZeroTier)",from.toString().c_str(),to.toString().c_str(),Filter::etherTypeName(etherType));
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}
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}
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void Switch::send(const Packet &packet,bool encrypt)
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{
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if (packet.destination() == _r->identity.address()) {
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TRACE("BUG: caught attempt to send() to self, ignored");
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return;
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}
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//TRACE(">> %.16llx %s -> %s (size: %u) (enc: %s)",(unsigned long long)packet.packetId(),packet.source().toString().c_str(),packet.destination().toString().c_str(),packet.size(),(encrypt ? "yes" : "no"));
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if (!_trySend(packet,encrypt)) {
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Mutex::Lock _l(_txQueue_m);
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_txQueue.insert(std::pair< Address,TXQueueEntry >(packet.destination(),TXQueueEntry(Utils::now(),packet,encrypt)));
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}
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}
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void Switch::sendHELLO(const Address &dest)
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{
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Packet outp(dest,_r->identity.address(),Packet::VERB_HELLO);
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outp.append((unsigned char)ZT_PROTO_VERSION);
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outp.append((unsigned char)ZEROTIER_ONE_VERSION_MAJOR);
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outp.append((unsigned char)ZEROTIER_ONE_VERSION_MINOR);
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outp.append((uint16_t)ZEROTIER_ONE_VERSION_REVISION);
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outp.append(Utils::now());
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_r->identity.serialize(outp,false);
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send(outp,false);
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}
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bool Switch::sendHELLO(const SharedPtr<Peer> &dest,Demarc::Port localPort,const InetAddress &remoteAddr)
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{
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uint64_t now = Utils::now();
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Packet outp(dest->address(),_r->identity.address(),Packet::VERB_HELLO);
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outp.append((unsigned char)ZT_PROTO_VERSION);
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outp.append((unsigned char)ZEROTIER_ONE_VERSION_MAJOR);
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outp.append((unsigned char)ZEROTIER_ONE_VERSION_MINOR);
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outp.append((uint16_t)ZEROTIER_ONE_VERSION_REVISION);
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outp.append(now);
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_r->identity.serialize(outp,false);
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outp.hmacSet(dest->macKey());
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if (_r->demarc->send(localPort,remoteAddr,outp.data(),outp.size(),-1)) {
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dest->onSent(_r,false,Packet::VERB_HELLO,now);
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return true;
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}
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return false;
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}
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bool Switch::unite(const Address &p1,const Address &p2,bool force)
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{
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if ((p1 == _r->identity.address())||(p2 == _r->identity.address()))
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return false;
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SharedPtr<Peer> p1p = _r->topology->getPeer(p1);
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if (!p1p)
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return false;
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SharedPtr<Peer> p2p = _r->topology->getPeer(p2);
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if (!p2p)
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return false;
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uint64_t now = Utils::now();
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std::pair<InetAddress,InetAddress> cg(Peer::findCommonGround(*p1p,*p2p,now));
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if (!(cg.first))
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return false;
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// Addresses are sorted in key for last unite attempt map for order
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// invariant lookup: (p1,p2) == (p2,p1)
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Array<Address,2> uniteKey;
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if (p1 >= p2) {
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uniteKey[0] = p2;
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uniteKey[1] = p1;
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} else {
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uniteKey[0] = p1;
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uniteKey[1] = p2;
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}
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{
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Mutex::Lock _l(_lastUniteAttempt_m);
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std::map< Array< Address,2 >,uint64_t >::const_iterator e(_lastUniteAttempt.find(uniteKey));
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if ((!force)&&(e != _lastUniteAttempt.end())&&((now - e->second) < ZT_MIN_UNITE_INTERVAL))
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return false;
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else _lastUniteAttempt[uniteKey] = now;
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}
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TRACE("unite: %s(%s) <> %s(%s)",p1.toString().c_str(),cg.second.toString().c_str(),p2.toString().c_str(),cg.first.toString().c_str());
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{ // tell p1 where to find p2
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Packet outp(p1,_r->identity.address(),Packet::VERB_RENDEZVOUS);
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p2.appendTo(outp);
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outp.append((uint16_t)cg.first.port());
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if (cg.first.isV6()) {
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outp.append((unsigned char)16);
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outp.append(cg.first.rawIpData(),16);
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} else {
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outp.append((unsigned char)4);
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outp.append(cg.first.rawIpData(),4);
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}
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outp.encrypt(p1p->cryptKey());
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outp.hmacSet(p1p->macKey());
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if (p1p->send(_r,outp.data(),outp.size(),now))
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p1p->onSent(_r,false,Packet::VERB_RENDEZVOUS,now);
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}
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{ // tell p2 where to find p1
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Packet outp(p2,_r->identity.address(),Packet::VERB_RENDEZVOUS);
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p1.appendTo(outp);
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outp.append((uint16_t)cg.second.port());
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if (cg.second.isV6()) {
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outp.append((unsigned char)16);
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outp.append(cg.second.rawIpData(),16);
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} else {
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outp.append((unsigned char)4);
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outp.append(cg.second.rawIpData(),4);
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}
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outp.encrypt(p2p->cryptKey());
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outp.hmacSet(p2p->macKey());
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if (p2p->send(_r,outp.data(),outp.size(),now))
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p2p->onSent(_r,false,Packet::VERB_RENDEZVOUS,now);
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}
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return true;
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}
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void Switch::contact(const SharedPtr<Peer> &peer,const InetAddress &atAddr)
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{
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Demarc::Port fromPort = _r->demarc->pick(atAddr);
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_r->demarc->send(fromPort,atAddr,"\0",1,ZT_FIREWALL_OPENER_HOPS);
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{
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Mutex::Lock _l(_contactQueue_m);
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_contactQueue.push_back(ContactQueueEntry(peer,Utils::now() + ZT_RENDEZVOUS_NAT_T_DELAY,fromPort,atAddr));
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}
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// Kick main loop out of wait so that it can pick up this
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// change to our scheduled timer tasks.
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_r->mainLoopWaitCondition.signal();
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}
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unsigned long Switch::doTimerTasks()
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{
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unsigned long nextDelay = ~((unsigned long)0); // big number, caller will cap return value
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uint64_t now = Utils::now();
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{
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Mutex::Lock _l(_contactQueue_m);
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for(std::list<ContactQueueEntry>::iterator qi(_contactQueue.begin());qi!=_contactQueue.end();) {
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if (now >= qi->fireAtTime) {
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TRACE("sending NAT-T HELLO to %s(%s)",qi->peer->address().toString().c_str(),qi->inaddr.toString().c_str());
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sendHELLO(qi->peer,qi->localPort,qi->inaddr);
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_contactQueue.erase(qi++);
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} else {
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nextDelay = std::min(nextDelay,(unsigned long)(qi->fireAtTime - now));
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++qi;
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}
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}
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}
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{
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Mutex::Lock _l(_outstandingWhoisRequests_m);
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for(std::map< Address,WhoisRequest >::iterator i(_outstandingWhoisRequests.begin());i!=_outstandingWhoisRequests.end();) {
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unsigned long since = (unsigned long)(now - i->second.lastSent);
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if (since >= ZT_WHOIS_RETRY_DELAY) {
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if (i->second.retries >= ZT_MAX_WHOIS_RETRIES) {
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TRACE("WHOIS %s timed out",i->first.toString().c_str());
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_outstandingWhoisRequests.erase(i++);
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continue;
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} else {
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i->second.lastSent = now;
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i->second.peersConsulted[i->second.retries] = _sendWhoisRequest(i->first,i->second.peersConsulted,i->second.retries);
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++i->second.retries;
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TRACE("WHOIS %s (retry %u)",i->first.toString().c_str(),i->second.retries);
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nextDelay = std::min(nextDelay,(unsigned long)ZT_WHOIS_RETRY_DELAY);
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}
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} else nextDelay = std::min(nextDelay,ZT_WHOIS_RETRY_DELAY - since);
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++i;
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}
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}
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{
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Mutex::Lock _l(_txQueue_m);
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for(std::multimap< Address,TXQueueEntry >::iterator i(_txQueue.begin());i!=_txQueue.end();) {
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if (_trySend(i->second.packet,i->second.encrypt))
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_txQueue.erase(i++);
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else if ((now - i->second.creationTime) > ZT_TRANSMIT_QUEUE_TIMEOUT) {
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TRACE("TX %s -> %s timed out",i->second.packet.source().toString().c_str(),i->second.packet.destination().toString().c_str());
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_txQueue.erase(i++);
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} else ++i;
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}
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}
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{
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Mutex::Lock _l(_rxQueue_m);
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for(std::list< SharedPtr<PacketDecoder> >::iterator i(_rxQueue.begin());i!=_rxQueue.end();) {
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if ((now - (*i)->receiveTime()) > ZT_RECEIVE_QUEUE_TIMEOUT) {
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TRACE("RX %s -> %s timed out",(*i)->source().toString().c_str(),(*i)->destination().toString().c_str());
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_rxQueue.erase(i++);
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} else ++i;
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}
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}
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{
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Mutex::Lock _l(_defragQueue_m);
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for(std::map< uint64_t,DefragQueueEntry >::iterator i(_defragQueue.begin());i!=_defragQueue.end();) {
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if ((now - i->second.creationTime) > ZT_FRAGMENTED_PACKET_RECEIVE_TIMEOUT) {
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TRACE("incomplete fragmented packet %.16llx timed out, fragments discarded",i->first);
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_defragQueue.erase(i++);
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} else ++i;
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}
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}
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return std::max(nextDelay,(unsigned long)10); // minimum delay
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}
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void Switch::announceMulticastGroups(const std::map< SharedPtr<Network>,std::set<MulticastGroup> > &allMemberships)
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{
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std::vector< SharedPtr<Peer> > directPeers;
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_r->topology->eachPeer(Topology::CollectPeersWithActiveDirectPath(directPeers));
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#ifdef ZT_TRACE
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unsigned int totalMulticastGroups = 0;
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for(std::map< SharedPtr<Network>,std::set<MulticastGroup> >::const_iterator i(allMemberships.begin());i!=allMemberships.end();++i)
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totalMulticastGroups += (unsigned int)i->second.size();
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TRACE("announcing %u multicast groups for %u networks to %u peers",totalMulticastGroups,(unsigned int)allMemberships.size(),(unsigned int)directPeers.size());
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#endif
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for(std::vector< SharedPtr<Peer> >::iterator p(directPeers.begin());p!=directPeers.end();++p) {
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Packet outp((*p)->address(),_r->identity.address(),Packet::VERB_MULTICAST_LIKE);
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for(std::map< SharedPtr<Network>,std::set<MulticastGroup> >::const_iterator nwmgs(allMemberships.begin());nwmgs!=allMemberships.end();++nwmgs) {
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if ((_r->topology->isSupernode((*p)->address()))||(nwmgs->first->isAllowed((*p)->address()))) {
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for(std::set<MulticastGroup>::iterator mg(nwmgs->second.begin());mg!=nwmgs->second.end();++mg) {
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if ((outp.size() + 18) > ZT_UDP_DEFAULT_PAYLOAD_MTU) {
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send(outp,true);
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outp.reset((*p)->address(),_r->identity.address(),Packet::VERB_MULTICAST_LIKE);
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}
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outp.append((uint64_t)nwmgs->first->id());
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outp.append(mg->mac().data,6);
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outp.append((uint32_t)mg->adi());
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}
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}
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}
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if (outp.size() > ZT_PROTO_MIN_PACKET_LENGTH)
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send(outp,true);
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}
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}
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void Switch::requestWhois(const Address &addr)
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{
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TRACE("requesting WHOIS for %s",addr.toString().c_str());
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{
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Mutex::Lock _l(_outstandingWhoisRequests_m);
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std::pair< std::map< Address,WhoisRequest >::iterator,bool > entry(_outstandingWhoisRequests.insert(std::pair<Address,WhoisRequest>(addr,WhoisRequest())));
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entry.first->second.lastSent = Utils::now();
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entry.first->second.retries = 0; // reset retry count if entry already existed
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}
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_sendWhoisRequest(addr,(const Address *)0,0);
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}
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void Switch::doAnythingWaitingForPeer(const SharedPtr<Peer> &peer)
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{
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{
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Mutex::Lock _l(_outstandingWhoisRequests_m);
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_outstandingWhoisRequests.erase(peer->address());
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}
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{
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Mutex::Lock _l(_rxQueue_m);
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for(std::list< SharedPtr<PacketDecoder> >::iterator rxi(_rxQueue.begin());rxi!=_rxQueue.end();) {
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if ((*rxi)->tryDecode(_r))
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_rxQueue.erase(rxi++);
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else ++rxi;
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}
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}
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{
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Mutex::Lock _l(_txQueue_m);
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std::pair< std::multimap< Address,TXQueueEntry >::iterator,std::multimap< Address,TXQueueEntry >::iterator > waitingTxQueueItems(_txQueue.equal_range(peer->address()));
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for(std::multimap< Address,TXQueueEntry >::iterator txi(waitingTxQueueItems.first);txi!=waitingTxQueueItems.second;) {
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if (_trySend(txi->second.packet,txi->second.encrypt))
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_txQueue.erase(txi++);
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else ++txi;
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}
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}
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}
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void Switch::_handleRemotePacketFragment(Demarc::Port localPort,const InetAddress &fromAddr,const Buffer<4096> &data)
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{
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Packet::Fragment fragment(data);
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Address destination(fragment.destination());
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if (destination != _r->identity.address()) {
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// Fragment is not for us, so try to relay it
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if (fragment.hops() < ZT_RELAY_MAX_HOPS) {
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fragment.incrementHops();
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SharedPtr<Peer> relayTo = _r->topology->getPeer(destination);
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if ((!relayTo)||(!relayTo->send(_r,fragment.data(),fragment.size(),Utils::now()))) {
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relayTo = _r->topology->getBestSupernode();
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if (relayTo)
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relayTo->send(_r,fragment.data(),fragment.size(),Utils::now());
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}
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} else {
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TRACE("dropped relay [fragment](%s) -> %s, max hops exceeded",fromAddr.toString().c_str(),destination.toString().c_str());
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}
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} else {
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// Fragment looks like ours
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uint64_t pid = fragment.packetId();
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unsigned int fno = fragment.fragmentNumber();
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unsigned int tf = fragment.totalFragments();
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if ((tf <= ZT_MAX_PACKET_FRAGMENTS)&&(fno < ZT_MAX_PACKET_FRAGMENTS)&&(fno > 0)&&(tf > 1)) {
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// Fragment appears basically sane. Its fragment number must be
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// 1 or more, since a Packet with fragmented bit set is fragment 0.
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// Total fragments must be more than 1, otherwise why are we
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// seeing a Packet::Fragment?
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Mutex::Lock _l(_defragQueue_m);
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std::map< uint64_t,DefragQueueEntry >::iterator dqe(_defragQueue.find(pid));
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if (dqe == _defragQueue.end()) {
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// We received a Packet::Fragment without its head, so queue it and wait
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DefragQueueEntry &dq = _defragQueue[pid];
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dq.creationTime = Utils::now();
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dq.frags[fno - 1] = fragment;
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dq.totalFragments = tf; // total fragment count is known
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dq.haveFragments = 1 << fno; // we have only this fragment
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//TRACE("fragment (%u/%u) of %.16llx from %s",fno + 1,tf,pid,fromAddr.toString().c_str());
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} else if (!(dqe->second.haveFragments & (1 << fno))) {
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// We have other fragments and maybe the head, so add this one and check
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dqe->second.frags[fno - 1] = fragment;
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dqe->second.totalFragments = tf;
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//TRACE("fragment (%u/%u) of %.16llx from %s",fno + 1,tf,pid,fromAddr.toString().c_str());
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if (Utils::countBits(dqe->second.haveFragments |= (1 << fno)) == tf) {
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// We have all fragments -- assemble and process full Packet
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//TRACE("packet %.16llx is complete, assembling and processing...",pid);
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SharedPtr<PacketDecoder> packet(dqe->second.frag0);
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for(unsigned int f=1;f<tf;++f)
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packet->append(dqe->second.frags[f - 1].payload(),dqe->second.frags[f - 1].payloadLength());
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_defragQueue.erase(dqe);
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if (!packet->tryDecode(_r)) {
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Mutex::Lock _l(_rxQueue_m);
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_rxQueue.push_back(packet);
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}
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}
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} // else this is a duplicate fragment, ignore
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}
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}
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}
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void Switch::_handleRemotePacketHead(Demarc::Port localPort,const InetAddress &fromAddr,const Buffer<4096> &data)
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{
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SharedPtr<PacketDecoder> packet(new PacketDecoder(data,localPort,fromAddr));
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Address source(packet->source());
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Address destination(packet->destination());
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//TRACE("<< %.16llx %s -> %s (size: %u)",(unsigned long long)packet->packetId(),source.toString().c_str(),destination.toString().c_str(),packet->size());
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if (destination != _r->identity.address()) {
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// Packet is not for us, so try to relay it
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if (packet->hops() < ZT_RELAY_MAX_HOPS) {
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packet->incrementHops();
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SharedPtr<Peer> relayTo = _r->topology->getPeer(destination);
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if ((relayTo)&&(relayTo->send(_r,packet->data(),packet->size(),Utils::now()))) {
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// If we've relayed, this periodically tries to get them to
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// talk directly to save our bandwidth.
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unite(source,destination,false);
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} else {
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// If we've received a packet not for us and we don't have
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// a direct path to its recipient, pass it to (another)
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// supernode. This can happen due to Internet weather -- the
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// most direct supernode may not be reachable, yet another
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// further away may be.
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relayTo = _r->topology->getBestSupernode(&source,1,true);
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if (relayTo)
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relayTo->send(_r,packet->data(),packet->size(),Utils::now());
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}
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} else {
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TRACE("dropped relay %s(%s) -> %s, max hops exceeded",packet->source().toString().c_str(),fromAddr.toString().c_str(),destination.toString().c_str());
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}
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} else if (packet->fragmented()) {
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// Packet is the head of a fragmented packet series
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uint64_t pid = packet->packetId();
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Mutex::Lock _l(_defragQueue_m);
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std::map< uint64_t,DefragQueueEntry >::iterator dqe(_defragQueue.find(pid));
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if (dqe == _defragQueue.end()) {
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// If we have no other fragments yet, create an entry and save the head
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DefragQueueEntry &dq = _defragQueue[pid];
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dq.creationTime = Utils::now();
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dq.frag0 = packet;
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dq.totalFragments = 0; // 0 == unknown, waiting for Packet::Fragment
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dq.haveFragments = 1; // head is first bit (left to right)
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//TRACE("fragment (0/?) of %.16llx from %s",pid,fromAddr.toString().c_str());
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} else if (!(dqe->second.haveFragments & 1)) {
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// If we have other fragments but no head, see if we are complete with the head
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if ((dqe->second.totalFragments)&&(Utils::countBits(dqe->second.haveFragments |= 1) == dqe->second.totalFragments)) {
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// We have all fragments -- assemble and process full Packet
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//TRACE("packet %.16llx is complete, assembling and processing...",pid);
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// packet already contains head, so append fragments
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for(unsigned int f=1;f<dqe->second.totalFragments;++f)
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packet->append(dqe->second.frags[f - 1].payload(),dqe->second.frags[f - 1].payloadLength());
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_defragQueue.erase(dqe);
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if (!packet->tryDecode(_r)) {
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Mutex::Lock _l(_rxQueue_m);
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_rxQueue.push_back(packet);
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}
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} else {
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// Still waiting on more fragments, so queue the head
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dqe->second.frag0 = packet;
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}
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} // else this is a duplicate head, ignore
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} else {
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// Packet is unfragmented, so just process it
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if (!packet->tryDecode(_r)) {
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Mutex::Lock _l(_rxQueue_m);
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_rxQueue.push_back(packet);
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}
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}
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}
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Address Switch::_sendWhoisRequest(const Address &addr,const Address *peersAlreadyConsulted,unsigned int numPeersAlreadyConsulted)
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{
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SharedPtr<Peer> supernode(_r->topology->getBestSupernode(peersAlreadyConsulted,numPeersAlreadyConsulted,false));
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if (supernode) {
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Packet outp(supernode->address(),_r->identity.address(),Packet::VERB_WHOIS);
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addr.appendTo(outp);
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outp.encrypt(supernode->cryptKey());
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outp.hmacSet(supernode->macKey());
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uint64_t now = Utils::now();
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if (supernode->send(_r,outp.data(),outp.size(),now)) {
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supernode->onSent(_r,false,Packet::VERB_WHOIS,now);
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return supernode->address();
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}
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}
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return Address();
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}
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bool Switch::_trySend(const Packet &packet,bool encrypt)
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{
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SharedPtr<Peer> peer(_r->topology->getPeer(packet.destination()));
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if (peer) {
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uint64_t now = Utils::now();
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bool isRelay;
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SharedPtr<Peer> via;
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if ((_r->topology->isSupernode(peer->address()))||(peer->hasActiveDirectPath(now))) {
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isRelay = false;
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via = peer;
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} else {
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isRelay = true;
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via = _r->topology->getBestSupernode();
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if (!via)
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return false;
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}
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Packet tmp(packet);
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unsigned int chunkSize = std::min(tmp.size(),(unsigned int)ZT_UDP_DEFAULT_PAYLOAD_MTU);
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tmp.setFragmented(chunkSize < tmp.size());
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if (encrypt)
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tmp.encrypt(peer->cryptKey());
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tmp.hmacSet(peer->macKey());
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if (via->send(_r,tmp.data(),chunkSize,now)) {
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if (chunkSize < tmp.size()) {
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// Too big for one bite, fragment the rest
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unsigned int fragStart = chunkSize;
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unsigned int remaining = tmp.size() - chunkSize;
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unsigned int fragsRemaining = (remaining / (ZT_UDP_DEFAULT_PAYLOAD_MTU - ZT_PROTO_MIN_FRAGMENT_LENGTH));
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if ((fragsRemaining * (ZT_UDP_DEFAULT_PAYLOAD_MTU - ZT_PROTO_MIN_FRAGMENT_LENGTH)) < remaining)
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++fragsRemaining;
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unsigned int totalFragments = fragsRemaining + 1;
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for(unsigned int f=0;f<fragsRemaining;++f) {
|
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chunkSize = std::min(remaining,(unsigned int)(ZT_UDP_DEFAULT_PAYLOAD_MTU - ZT_PROTO_MIN_FRAGMENT_LENGTH));
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Packet::Fragment frag(tmp,fragStart,chunkSize,f + 1,totalFragments);
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if (!via->send(_r,frag.data(),frag.size(),now)) {
|
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TRACE("WARNING: packet send to %s failed on later fragment #%u (check IP layer buffer sizes?)",via->address().toString().c_str(),f + 1);
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}
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fragStart += chunkSize;
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remaining -= chunkSize;
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}
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}
|
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via->onSent(_r,isRelay,packet.verb(),now);
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return true;
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}
|
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return false;
|
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}
|
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|
|
requestWhois(packet.destination());
|
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return false;
|
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}
|
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} // namespace ZeroTier
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