/*
* ZeroTier One - Network Virtualization Everywhere
* Copyright (C) 2011-2019 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/>.
*
* --
*
* 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 "../node/Constants.hpp"
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <string.h>
#include <fcntl.h>
#include <signal.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <sys/select.h>
#include <sys/time.h>
#include <sys/un.h>
#include <sys/ioctl.h>
#include <arpa/inet.h>
#include <netinet/in.h>
#include <netinet/ip.h>
#include <netinet/ip6.h>
#include <netinet/tcp.h>
#include "../node/Packet.hpp"
#include "../node/Utils.hpp"
#include "../node/Address.hpp"
#include "../node/Identity.hpp"
#include "../node/InetAddress.hpp"
#include "../node/Mutex.hpp"
#include "../node/SharedPtr.hpp"
#include "../node/MulticastGroup.hpp"
#include "../osdep/OSUtils.hpp"
#include <string>
#include <thread>
#include <map>
#include <set>
#include <vector>
#include <iostream>
#include <unordered_map>
#include <unordered_set>
#include <vector>
#include <atomic>
#include <mutex>
using namespace ZeroTier;
struct IdentityHasher { ZT_ALWAYS_INLINE std::size_t operator()(const Identity &id) const { return (std::size_t)id.hashCode(); } };
struct AddressHasher { ZT_ALWAYS_INLINE std::size_t operator()(const Address &a) const { return (std::size_t)a.toInt(); } };
struct InetAddressHasher { ZT_ALWAYS_INLINE std::size_t operator()(const InetAddress &ip) const { return (std::size_t)ip.hashCode(); } };
struct MulticastGroupHasher { ZT_ALWAYS_INLINE std::size_t operator()(const MulticastGroup &mg) const { return (std::size_t)mg.hashCode(); } };
struct RendezvousKey
{
RendezvousKey(const Address aa,const Address bb)
{
if (aa > bb) {
a = aa;
b = bb;
} else {
a = bb;
b = aa;
}
}
Address a,b;
ZT_ALWAYS_INLINE bool operator==(const RendezvousKey &k) const { return ((a == k.a)&&(b == k.b)); }
ZT_ALWAYS_INLINE bool operator!=(const RendezvousKey &k) const { return ((a != k.a)||(b != k.b)); }
struct Hasher { ZT_ALWAYS_INLINE std::size_t operator()(const RendezvousKey &k) const { return (std::size_t)(k.a.toInt() ^ k.b.toInt()); } };
};
struct RootPeer
{
Identity id;
uint8_t key[32];
InetAddress ip4,ip6;
int64_t lastReceive;
int64_t lastSync;
AtomicCounter __refCount;
ZT_ALWAYS_INLINE ~RootPeer() { Utils::burn(key,sizeof(key)); }
};
static Identity self;
static std::atomic_bool run;
static std::unordered_map< uint64_t,std::unordered_map< MulticastGroup,std::unordered_map< Address,int64_t,AddressHasher >,MulticastGroupHasher > > multicastSubscriptions;
static std::unordered_map< Identity,SharedPtr<RootPeer>,IdentityHasher > peersByIdentity;
static std::unordered_map< Address,std::set< SharedPtr<RootPeer> >,AddressHasher > peersByVirtAddr;
static std::unordered_map< InetAddress,std::set< SharedPtr<RootPeer> >,InetAddressHasher > peersByPhysAddr;
static std::unordered_map< RendezvousKey,int64_t,RendezvousKey::Hasher > lastRendezvous;
static std::mutex multicastSubscriptions_l;
static std::mutex peersByIdentity_l;
static std::mutex peersByVirtAddr_l;
static std::mutex peersByPhysAddr_l;
static std::mutex lastRendezvous_l;
static void handlePacket(const int sock,const InetAddress *const ip,Packet &pkt)
{
char ipstr[128],ipstr2[128],astr[32],astr2[32],tmpstr[256];
const bool fragment = pkt[ZT_PACKET_FRAGMENT_IDX_FRAGMENT_INDICATOR] == ZT_PACKET_FRAGMENT_INDICATOR;
const Address source(pkt.source());
const Address dest(pkt.destination());
const int64_t now = OSUtils::now();
// See if this is destined for us and isn't a fragment / fragmented. (No packets
// understood by the root are fragments/fragmented.)
if ((!fragment)&&(!pkt.fragmented())&&(dest == self.address())) {
SharedPtr<RootPeer> peer;
// If this is an un-encrypted HELLO, either learn a new peer or verify
// that this is a peer we already know.
if ((pkt.cipher() == ZT_PROTO_CIPHER_SUITE__POLY1305_NONE)&&(pkt.verb() == Packet::VERB_HELLO)) {
Identity id;
if (id.deserialize(pkt,ZT_PROTO_VERB_HELLO_IDX_IDENTITY)) {
{
std::lock_guard<std::mutex> pbi_l(peersByIdentity_l);
auto pById = peersByIdentity.find(id);
if (pById != peersByIdentity.end()) {
peer = pById->second;
//printf("%s has %s (known (1))" ZT_EOL_S,ip->toString(ipstr),source().toString(astr));
}
}
if (peer) {
if (!pkt.dearmor(peer->key)) {
printf("%s HELLO rejected: packet authentication failed" ZT_EOL_S,ip->toString(ipstr));
return;
}
} else {
peer.set(new RootPeer);
if (self.agree(id,peer->key)) {
if (pkt.dearmor(peer->key)) {
peer->id = id;
peer->lastSync = 0;
{
std::lock_guard<std::mutex> pbi_l(peersByIdentity_l);
peersByIdentity.emplace(id,peer);
}
{
std::lock_guard<std::mutex> pbv_l(peersByVirtAddr_l);
peersByVirtAddr[id.address()].emplace(peer);
}
} else {
printf("%s HELLO rejected: packet authentication failed" ZT_EOL_S,ip->toString(ipstr));
return;
}
} else {
printf("%s HELLO rejected: key agreement failed" ZT_EOL_S,ip->toString(ipstr));
return;
}
}
}
}
// If it wasn't a HELLO, check to see if any known identities for the sender's
// short ZT address successfully decrypt the packet.
if (!peer) {
std::lock_guard<std::mutex> pbv_l(peersByVirtAddr_l);
auto peers = peersByVirtAddr.find(source);
if (peers != peersByVirtAddr.end()) {
for(auto p=peers->second.begin();p!=peers->second.end();++p) {
if (pkt.dearmor((*p)->key)) {
peer = (*p);
//printf("%s has %s (known (2))" ZT_EOL_S,ip->toString(ipstr),source().toString(astr));
break;
}
}
}
}
// If we found the peer, update IP and/or time.
if (peer) {
InetAddress *const peerIp = (ip->ss_family == AF_INET) ? &(peer->ip4) : &(peer->ip6);
if (*peerIp != ip) {
std::lock_guard<std::mutex> pbp_l(peersByPhysAddr_l);
if (*peerIp) {
auto prev = peersByPhysAddr.find(*peerIp);
if (prev != peersByPhysAddr.end()) {
prev->second.erase(peer);
if (prev->second.empty())
peersByPhysAddr.erase(prev);
}
}
*peerIp = ip;
peersByPhysAddr[ip].emplace(peer);
}
const int64_t now = OSUtils::now();
peer->lastReceive = now;
switch(pkt.verb()) {
case Packet::VERB_HELLO:
try {
const uint64_t origId = pkt.packetId();
const uint64_t ts = pkt.template at<uint64_t>(ZT_PROTO_VERB_HELLO_IDX_TIMESTAMP);
pkt.reset(source,self.address(),Packet::VERB_OK);
pkt.append((uint8_t)Packet::VERB_HELLO);
pkt.append(origId);
pkt.append(ts);
pkt.append((uint8_t)ZT_PROTO_VERSION);
pkt.append((uint8_t)0);
pkt.append((uint8_t)0);
pkt.append((uint16_t)0);
ip->serialize(pkt);
pkt.armor(peer->key,true);
sendto(sock,pkt.data(),pkt.size(),0,(const struct sockaddr *)ip,(socklen_t)((ip->ss_family == AF_INET) ? sizeof(struct sockaddr_in) : sizeof(struct sockaddr_in6)));
//printf("%s <- OK(HELLO)" ZT_EOL_S,ip->toString(ipstr));
} catch ( ... ) {
printf("* unexpected exception handling HELLO from %s" ZT_EOL_S,ip->toString(ipstr));
}
break;
case Packet::VERB_MULTICAST_LIKE:
try {
std::lock_guard<std::mutex> l(multicastSubscriptions_l);
for(unsigned int ptr=ZT_PACKET_IDX_PAYLOAD;(ptr+18)<=pkt.size();ptr+=18) {
const uint64_t nwid = pkt.template at<uint64_t>(ptr);
const MulticastGroup mg(MAC(pkt.field(ptr + 8,6),6),pkt.template at<uint32_t>(ptr + 14));
multicastSubscriptions[nwid][mg][peer->id.address()] = now;
//printf("%s subscribes to %s/%.8lx on network %.16llx" ZT_EOL_S,ip->toString(ipstr),mg.mac().toString(tmpstr),(unsigned long)mg.adi(),(unsigned long long)nwid);
}
} catch ( ... ) {
printf("* unexpected exception handling MULTICAST_LIKE from %s" ZT_EOL_S,ip->toString(ipstr));
}
break;
case Packet::VERB_MULTICAST_GATHER:
try {
const uint64_t nwid = pkt.template at<uint64_t>(ZT_PROTO_VERB_MULTICAST_GATHER_IDX_NETWORK_ID);
const unsigned int flags = pkt[ZT_PROTO_VERB_MULTICAST_GATHER_IDX_FLAGS];
const MulticastGroup mg(MAC(pkt.field(ZT_PROTO_VERB_MULTICAST_GATHER_IDX_MAC,6),6),pkt.template at<uint32_t>(ZT_PROTO_VERB_MULTICAST_GATHER_IDX_ADI));
unsigned int gatherLimit = pkt.template at<uint32_t>(ZT_PROTO_VERB_MULTICAST_GATHER_IDX_GATHER_LIMIT);
if (gatherLimit > 255)
gatherLimit = 255;
const uint64_t origId = pkt.packetId();
pkt.reset(source,self.address(),Packet::VERB_OK);
pkt.append((uint8_t)Packet::VERB_MULTICAST_GATHER);
pkt.append(origId);
pkt.append(nwid);
mg.mac().appendTo(pkt);
pkt.append((uint32_t)mg.adi());
{
std::lock_guard<std::mutex> l(multicastSubscriptions_l);
auto forNet = multicastSubscriptions.find(nwid);
if (forNet != multicastSubscriptions.end()) {
auto forGroup = forNet->second.find(mg);
if (forGroup != forNet->second.end()) {
pkt.append((uint32_t)forGroup->second.size());
pkt.append((uint16_t)std::min(std::min((unsigned int)forGroup->second.size(),(unsigned int)65535),gatherLimit));
auto g = forGroup->second.begin();
unsigned int l = 0;
for(;((l<gatherLimit)&&(g!=forGroup->second.end()));++l,++g)
g->first.appendTo(pkt);
if (l > 0) {
sendto(sock,pkt.data(),pkt.size(),0,(const struct sockaddr *)ip,(socklen_t)((ip->ss_family == AF_INET) ? sizeof(struct sockaddr_in) : sizeof(struct sockaddr_in6)));
//printf("%s gathered %u subscribers to %s/%.8lx on network %.16llx" ZT_EOL_S,ip->toString(ipstr),l,mg.mac().toString(tmpstr),(unsigned long)mg.adi(),(unsigned long long)nwid);
}
}
}
}
} catch ( ... ) {
printf("* unexpected exception handling MULTICAST_GATHER from %s" ZT_EOL_S,ip->toString(ipstr));
}
break;
default:
break;
}
return;
}
}
// If we made it here, we are forwarding this packet to someone else and also possibly
// sending a RENDEZVOUS message.
bool introduce = false;
{
RendezvousKey rk(source,dest);
std::lock_guard<std::mutex> l(lastRendezvous_l);
int64_t &lr = lastRendezvous[rk];
if ((now - lr) >= 45000) {
lr = now;
introduce = true;
}
}
std::vector< std::pair< InetAddress *,SharedPtr<RootPeer> > > toAddrs;
{
std::lock_guard<std::mutex> pbv_l(peersByVirtAddr_l);
auto peers = peersByVirtAddr.find(dest);
if (peers != peersByVirtAddr.end()) {
for(auto p=peers->second.begin();p!=peers->second.end();++p) {
if ((now - (*p)->lastReceive) < ZT_PEER_ACTIVITY_TIMEOUT) {
if ((*p)->ip6) {
toAddrs.push_back(std::pair< InetAddress *,SharedPtr<RootPeer> >(&((*p)->ip6),*p));
} else if ((*p)->ip4) {
toAddrs.push_back(std::pair< InetAddress *,SharedPtr<RootPeer> >(&((*p)->ip4),*p));
}
}
}
}
}
if (toAddrs.empty()) {
//printf("%s not forwarding to %s: no destinations found" ZT_EOL_S,ip->toString(ipstr),dest().toString(astr));
return;
}
if (introduce) {
std::lock_guard<std::mutex> l(peersByVirtAddr_l);
auto sources = peersByVirtAddr.find(source);
for(auto a=sources->second.begin();a!=sources->second.end();++a) {
for(auto b=toAddrs.begin();b!=toAddrs.end();++b) {
if (((*a)->ip6 == *ip)&&(b->second->ip6)) {
printf("* introducing %s(%s) to %s(%s)" ZT_EOL_S,ip->toString(ipstr),source.toString(astr),b->second->ip6.toString(ipstr2),dest.toString(astr2));
Packet outp(source,self.address(),Packet::VERB_RENDEZVOUS);
outp.append((uint8_t)0);
dest.appendTo(outp);
outp.append((uint16_t)b->second->ip6.port());
outp.append((uint8_t)16);
outp.append((const uint8_t *)b->second->ip6.rawIpData(),16);
outp.armor((*a)->key,true);
sendto(sock,pkt.data(),pkt.size(),0,(const struct sockaddr *)ip,(socklen_t)sizeof(struct sockaddr_in6));
outp.reset(dest,self.address(),Packet::VERB_RENDEZVOUS);
outp.append((uint8_t)0);
source.appendTo(outp);
outp.append((uint16_t)ip->port());
outp.append((uint8_t)16);
outp.append((const uint8_t *)ip->rawIpData(),16);
outp.armor(b->second->key,true);
sendto(sock,pkt.data(),pkt.size(),0,(const struct sockaddr *)&(b->second->ip6),(socklen_t)sizeof(struct sockaddr_in6));
} else if (((*a)->ip4 == *ip)&&(b->second->ip4)) {
printf("* introducing %s(%s) to %s(%s)" ZT_EOL_S,ip->toString(ipstr),source.toString(astr),b->second->ip4.toString(ipstr2),dest.toString(astr2));
Packet outp(source,self.address(),Packet::VERB_RENDEZVOUS);
outp.append((uint8_t)0);
dest.appendTo(outp);
outp.append((uint16_t)b->second->ip4.port());
outp.append((uint8_t)4);
outp.append((const uint8_t *)b->second->ip4.rawIpData(),4);
outp.armor((*a)->key,true);
sendto(sock,pkt.data(),pkt.size(),0,(const struct sockaddr *)ip,(socklen_t)sizeof(struct sockaddr_in));
outp.reset(dest,self.address(),Packet::VERB_RENDEZVOUS);
outp.append((uint8_t)0);
source.appendTo(outp);
outp.append((uint16_t)ip->port());
outp.append((uint8_t)4);
outp.append((const uint8_t *)ip->rawIpData(),4);
outp.armor(b->second->key,true);
sendto(sock,pkt.data(),pkt.size(),0,(const struct sockaddr *)&(b->second->ip4),(socklen_t)sizeof(struct sockaddr_in));
}
}
}
}
if (fragment) {
if (reinterpret_cast<Packet::Fragment *>(&pkt)->incrementHops() >= ZT_PROTO_MAX_HOPS) {
printf("%s refused to forward to %s: max hop count exceeded" ZT_EOL_S,ip->toString(ipstr),dest.toString(astr));
return;
}
} else {
if (pkt.incrementHops() >= ZT_PROTO_MAX_HOPS) {
printf("%s refused to forward to %s: max hop count exceeded" ZT_EOL_S,ip->toString(ipstr),dest.toString(astr));
return;
}
}
for(auto i=toAddrs.begin();i!=toAddrs.end();++i) {
//printf("%s -> %s for %s" ZT_EOL_S,ip->toString(ipstr),i->toString(ipstr2),dest().toString(astr));
sendto(sock,pkt.data(),pkt.size(),0,(const struct sockaddr *)i->first,(socklen_t)((i->first->ss_family == AF_INET) ? sizeof(struct sockaddr_in) : sizeof(struct sockaddr_in6)));
}
}
static int bindSocket(struct sockaddr *bindAddr)
{
int s = socket(bindAddr->sa_family,SOCK_DGRAM,0);
if (s < 0) {
close(s);
return -1;
}
int f = 131072;
setsockopt(s,SOL_SOCKET,SO_RCVBUF,(const char *)&f,sizeof(f));
f = 131072;
setsockopt(s,SOL_SOCKET,SO_SNDBUF,(const char *)&f,sizeof(f));
if (bindAddr->sa_family == AF_INET6) {
f = 1; setsockopt(s,IPPROTO_IPV6,IPV6_V6ONLY,(void *)&f,sizeof(f));
#ifdef IPV6_MTU_DISCOVER
f = 0; setsockopt(s,IPPROTO_IPV6,IPV6_MTU_DISCOVER,&f,sizeof(f));
#endif
#ifdef IPV6_DONTFRAG
f = 0; setsockopt(s,IPPROTO_IPV6,IPV6_DONTFRAG,&f,sizeof(f));
#endif
}
f = 1; setsockopt(s,SOL_SOCKET,SO_REUSEADDR,(void *)&f,sizeof(f));
f = 1; setsockopt(s,SOL_SOCKET,SO_REUSEPORT,(void *)&f,sizeof(f));
f = 1; setsockopt(s,SOL_SOCKET,SO_BROADCAST,(void *)&f,sizeof(f));
#ifdef IP_DONTFRAG
f = 0; setsockopt(s,IPPROTO_IP,IP_DONTFRAG,&f,sizeof(f));
#endif
#ifdef IP_MTU_DISCOVER
f = IP_PMTUDISC_DONT; setsockopt(s,IPPROTO_IP,IP_MTU_DISCOVER,&f,sizeof(f));
#endif
#ifdef SO_NO_CHECK
if (bindAddr->sa_family == AF_INET) {
f = 1; setsockopt(s,SOL_SOCKET,SO_NO_CHECK,(void *)&f,sizeof(f));
}
#endif
if (bind(s,bindAddr,(bindAddr->sa_family == AF_INET) ? sizeof(struct sockaddr_in) : sizeof(struct sockaddr_in6))) {
close(s);
return -1;
}
return s;
}
void shutdownSigHandler(int sig)
{
run = false;
}
int main(int argc,char **argv)
{
signal(SIGTERM,shutdownSigHandler);
signal(SIGINT,shutdownSigHandler);
signal(SIGQUIT,shutdownSigHandler);
signal(SIGPIPE,SIG_IGN);
signal(SIGUSR1,SIG_IGN);
signal(SIGUSR2,SIG_IGN);
if (argc < 2) {
printf("Usage: zerotier-root <identity.secret> [<port>]" ZT_EOL_S);
return 1;
}
std::string myIdStr;
if (!OSUtils::readFile(argv[1],myIdStr)) {
printf("FATAL: cannot read identity.secret at %s" ZT_EOL_S,argv[1]);
return 1;
}
if (!self.fromString(myIdStr.c_str())) {
printf("FATAL: cannot read identity.secret at %s (invalid identity)" ZT_EOL_S,argv[1]);
return 1;
}
if (!self.hasPrivate()) {
printf("FATAL: cannot read identity.secret at %s (missing secret key)" ZT_EOL_S,argv[1]);
return 1;
}
unsigned int ncores = std::thread::hardware_concurrency();
if (ncores == 0) ncores = 1;
run = true;
std::vector<std::thread> threads;
std::vector<int> sockets;
for(unsigned int tn=0;tn<ncores;++tn) {
struct sockaddr_in6 in6;
memset(&in6,0,sizeof(in6));
in6.sin6_family = AF_INET6;
in6.sin6_port = htons(ZT_DEFAULT_PORT);
const int s6 = bindSocket((struct sockaddr *)&in6);
if (s6 < 0) {
std::cout << "ERROR: unable to bind to port " << ZT_DEFAULT_PORT << ZT_EOL_S;
exit(1);
}
struct sockaddr_in in4;
memset(&in4,0,sizeof(in4));
in4.sin_family = AF_INET;
in4.sin_port = htons(ZT_DEFAULT_PORT);
const int s4 = bindSocket((struct sockaddr *)&in4);
if (s4 < 0) {
std::cout << "ERROR: unable to bind to port " << ZT_DEFAULT_PORT << ZT_EOL_S;
exit(1);
}
sockets.push_back(s6);
sockets.push_back(s4);
threads.push_back(std::thread([s6]() {
struct sockaddr_in6 in6;
Packet pkt;
memset(&in6,0,sizeof(in6));
for(;;) {
socklen_t sl = sizeof(in6);
const int pl = (int)recvfrom(s6,pkt.unsafeData(),pkt.capacity(),0,(struct sockaddr *)&in6,&sl);
if (pl > 0) {
if (pl >= ZT_PROTO_MIN_FRAGMENT_LENGTH) {
try {
pkt.setSize((unsigned int)pl);
handlePacket(s6,reinterpret_cast<const InetAddress *>(&in6),pkt);
} catch ( ... ) {
char ipstr[128];
printf("* unexpected exception handling packet from %s" ZT_EOL_S,reinterpret_cast<const InetAddress *>(&in6)->toString(ipstr));
}
}
} else {
break;
}
}
}));
threads.push_back(std::thread([s4]() {
struct sockaddr_in in4;
Packet pkt;
memset(&in4,0,sizeof(in4));
for(;;) {
socklen_t sl = sizeof(in4);
const int pl = (int)recvfrom(s4,pkt.unsafeData(),pkt.capacity(),0,(struct sockaddr *)&in4,&sl);
if (pl > 0) {
if (pl >= ZT_PROTO_MIN_FRAGMENT_LENGTH) {
try {
pkt.setSize((unsigned int)pl);
handlePacket(s4,reinterpret_cast<const InetAddress *>(&in4),pkt);
} catch ( ... ) {
char ipstr[128];
printf("* unexpected exception handling packet from %s" ZT_EOL_S,reinterpret_cast<const InetAddress *>(&in4)->toString(ipstr));
}
}
} else {
break;
}
}
}));
}
int64_t lastCleanedMulticastSubscriptions = 0;
int64_t lastCleanedPeers = 0;
while (run) {
peersByIdentity_l.lock();
peersByPhysAddr_l.lock();
printf("*** have %lu peers at %lu physical endpoints" ZT_EOL_S,(unsigned long)peersByIdentity.size(),(unsigned long)peersByPhysAddr.size());
peersByPhysAddr_l.unlock();
peersByIdentity_l.unlock();
sleep(1);
const int64_t now = OSUtils::now();
if ((now - lastCleanedMulticastSubscriptions) > 120000) {
lastCleanedMulticastSubscriptions = now;
std::lock_guard<std::mutex> l(multicastSubscriptions_l);
for(auto a=multicastSubscriptions.begin();a!=multicastSubscriptions.end();) {
for(auto b=a->second.begin();b!=a->second.end();) {
for(auto c=b->second.begin();c!=b->second.end();) {
if ((now - c->second) > ZT_MULTICAST_LIKE_EXPIRE)
b->second.erase(c++);
else ++c;
}
if (b->second.empty())
a->second.erase(b++);
else ++b;
}
if (a->second.empty())
multicastSubscriptions.erase(a++);
else ++a;
}
}
if ((now - lastCleanedPeers) > 120000) {
lastCleanedPeers = now;
std::lock_guard<std::mutex> pbi_l(peersByIdentity_l);
for(auto p=peersByIdentity.begin();p!=peersByIdentity.end();) {
if ((now - p->second->lastReceive) > ZT_PEER_ACTIVITY_TIMEOUT) {
std::lock_guard<std::mutex> pbv_l(peersByVirtAddr_l);
std::lock_guard<std::mutex> pbp_l(peersByPhysAddr_l);
auto pbv = peersByVirtAddr.find(p->second->id.address());
if (pbv != peersByVirtAddr.end()) {
pbv->second.erase(p->second);
if (pbv->second.empty())
peersByVirtAddr.erase(pbv);
}
if (p->second->ip4) {
auto pbp = peersByPhysAddr.find(p->second->ip4);
if (pbp != peersByPhysAddr.end()) {
pbp->second.erase(p->second);
if (pbp->second.empty())
peersByPhysAddr.erase(pbp);
}
}
if (p->second->ip6) {
auto pbp = peersByPhysAddr.find(p->second->ip6);
if (pbp != peersByPhysAddr.end()) {
pbp->second.erase(p->second);
if (pbp->second.empty())
peersByPhysAddr.erase(pbp);
}
}
peersByIdentity.erase(p++);
} else ++p;
}
}
}
for(auto s=sockets.begin();s!=sockets.end();++s) {
shutdown(*s,SHUT_RDWR);
close(*s);
}
for(auto t=threads.begin();t!=threads.end();++t)
t->join();
return 0;
}