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@@ -147,13 +147,14 @@ std::vector<InetAddress> SelfAwareness::getSymmetricNatPredictions()
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* read or modify traffic, but they could gather meta-data for forensics
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* purpsoes or use this as a DOS attack vector. */
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- std::map< uint32_t,std::pair<uint64_t,unsigned int> > maxPortByIp;
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+ std::map< uint32_t,unsigned int > maxPortByIp;
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InetAddress theOneTrueSurface;
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- bool symmetric = false;
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{
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Mutex::Lock _l(_phy_m);
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- { // First get IPs from only trusted peers, and perform basic NAT type characterization
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+ // First check to see if this is a symmetric NAT and enumerate external IPs learned from trusted peers
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+ bool symmetric = false;
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+ {
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Hashtable< PhySurfaceKey,PhySurfaceEntry >::Iterator i(_phy);
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PhySurfaceKey *k = (PhySurfaceKey *)0;
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PhySurfaceEntry *e = (PhySurfaceEntry *)0;
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@@ -163,42 +164,47 @@ std::vector<InetAddress> SelfAwareness::getSymmetricNatPredictions()
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theOneTrueSurface = e->mySurface;
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else if (theOneTrueSurface != e->mySurface)
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symmetric = true;
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- maxPortByIp[reinterpret_cast<const struct sockaddr_in *>(&(e->mySurface))->sin_addr.s_addr] = std::pair<uint64_t,unsigned int>(e->ts,e->mySurface.port());
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+ maxPortByIp[reinterpret_cast<const struct sockaddr_in *>(&(e->mySurface))->sin_addr.s_addr] = e->mySurface.port();
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}
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}
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}
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+ if (!symmetric)
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+ return std::vector<InetAddress>();
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- { // Then find max port per IP from a trusted peer
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+ { // Then find the highest issued port per IP
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Hashtable< PhySurfaceKey,PhySurfaceEntry >::Iterator i(_phy);
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PhySurfaceKey *k = (PhySurfaceKey *)0;
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PhySurfaceEntry *e = (PhySurfaceEntry *)0;
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while (i.next(k,e)) {
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if ((e->mySurface.ss_family == AF_INET)&&(e->mySurface.ipScope() == InetAddress::IP_SCOPE_GLOBAL)) {
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- std::map< uint32_t,std::pair<uint64_t,unsigned int> >::iterator mp(maxPortByIp.find(reinterpret_cast<const struct sockaddr_in *>(&(e->mySurface))->sin_addr.s_addr));
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- if ((mp != maxPortByIp.end())&&(mp->second.first < e->ts)) {
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- mp->second.first = e->ts;
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- mp->second.second = e->mySurface.port();
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- }
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+ const unsigned int port = e->mySurface.port();
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+ std::map< uint32_t,unsigned int >::iterator mp(maxPortByIp.find(reinterpret_cast<const struct sockaddr_in *>(&(e->mySurface))->sin_addr.s_addr));
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+ if ((mp != maxPortByIp.end())&&(mp->second < port))
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+ mp->second = port;
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}
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}
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}
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}
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- if (symmetric) {
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- std::vector<InetAddress> r;
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- for(unsigned int k=1;k<=3;++k) {
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- for(std::map< uint32_t,std::pair<uint64_t,unsigned int> >::iterator i(maxPortByIp.begin());i!=maxPortByIp.end();++i) {
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- unsigned int p = i->second.second + k;
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- if (p > 65535) p -= 64511;
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- InetAddress pred(&(i->first),4,p);
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- if (std::find(r.begin(),r.end(),pred) == r.end())
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- r.push_back(pred);
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- }
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- }
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- return r;
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+ std::vector<InetAddress> r;
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+
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+ // Try next port up from max for each
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+ for(std::map< uint32_t,unsigned int >::iterator i(maxPortByIp.begin());i!=maxPortByIp.end();++i) {
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+ unsigned int p = i->second + 1;
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+ if (p > 65535) p -= 64511;
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+ const InetAddress pred(&(i->first),4,p);
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+ if (std::find(r.begin(),r.end(),pred) == r.end())
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+ r.push_back(pred);
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+ }
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+
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+ // Try a random port for each -- there are only 65535 so eventually it should work
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+ for(std::map< uint32_t,unsigned int >::iterator i(maxPortByIp.begin());i!=maxPortByIp.end();++i) {
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+ const InetAddress pred(&(i->first),4,1024 + ((unsigned int)RR->node->prng() % 64511));
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+ if (std::find(r.begin(),r.end(),pred) == r.end())
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+ r.push_back(pred);
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}
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- return std::vector<InetAddress>();
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+ return r;
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}
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} // namespace ZeroTier
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Adam Ierymenko