/** Copyright (c)2013-2020 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年01月01日** 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.*//****/#include <stdio.h>#include <stdlib.h>#include <algorithm>#include <utility>#include <stdexcept>#include "../version.h"#include "../include/ZeroTierOne.h"#include "Constants.hpp"#include "RuntimeEnvironment.hpp"#include "Switch.hpp"#include "Node.hpp"#include "InetAddress.hpp"#include "Topology.hpp"#include "Peer.hpp"#include "SelfAwareness.hpp"#include "Packet.hpp"#include "Trace.hpp"namespace ZeroTier {Switch::Switch(const RuntimeEnvironment *renv) :RR(renv),_lastBeaconResponse(0),_lastCheckedQueues(0),_lastUniteAttempt(8) // only really used on root servers and upstreams, and it'll grow there just fine{}// Returns true if packet appears valid; pos and proto will be setstatic bool _ipv6GetPayload(const uint8_t *frameData,unsigned int frameLen,unsigned int &pos,unsigned int &proto){if (frameLen < 40)return false;pos = 40;proto = frameData[6];while (pos <= frameLen) {switch(proto) {case 0: // hop-by-hop optionscase 43: // routingcase 60: // destination optionscase 135: // mobility optionsif ((pos + 8) > frameLen)return false; // invalid!proto = frameData[pos];pos += ((unsigned int)frameData[pos + 1] * 8) + 8;break;//case 44: // fragment -- we currently can't parse these and they are deprecated in IPv6 anyway//case 50://case 51: // IPSec ESP and AH -- we have to stop here since this is encrypted stuffdefault:return true;}}return false; // overflow == invalid}void Switch::onRemotePacket(void *tPtr,const int64_t localSocket,const InetAddress &fromAddr,const void *data,unsigned int len){int32_t flowId = ZT_QOS_NO_FLOW;try {const int64_t now = RR->node->now();const SharedPtr<Path> path(RR->topology->getPath(localSocket,fromAddr));path->received(now);if (len == 13) {/* LEGACY: before VERB_PUSH_DIRECT_PATHS, peers used broadcast* announcements on the LAN to solve the 'same network problem.' We* no longer send these, but we'll listen for them for a while to* locate peers with versions <1.0.4. */const Address beaconAddr(reinterpret_cast<const char *>(data) + 8,5);if (beaconAddr == RR->identity.address())return;if (!RR->node->shouldUsePathForZeroTierTraffic(tPtr,beaconAddr,localSocket,fromAddr))return;const SharedPtr<Peer> peer(RR->topology->getPeer(tPtr,beaconAddr));if (peer) { // we'll only respond to beacons from known peersif ((now - _lastBeaconResponse) >= 2500) { // limit rate of responses_lastBeaconResponse = now;Packet outp(peer->address(),RR->identity.address(),Packet::VERB_NOP);outp.armor(peer->key(),true,peer->aesKeysIfSupported());path->send(RR,tPtr,outp.data(),outp.size(),now);}}} else if (len > ZT_PROTO_MIN_FRAGMENT_LENGTH) { // SECURITY: min length check is important since we do some C-style stuff below!if (reinterpret_cast<const uint8_t *>(data)[ZT_PACKET_FRAGMENT_IDX_FRAGMENT_INDICATOR] == ZT_PACKET_FRAGMENT_INDICATOR) {// Handle fragment ----------------------------------------------------Packet::Fragment fragment(data,len);const Address destination(fragment.destination());if (destination != RR->identity.address()) {if ( (!RR->topology->amUpstream()) && (!path->trustEstablished(now)) )return;if (fragment.hops() < ZT_RELAY_MAX_HOPS) {fragment.incrementHops();// Note: we don't bother initiating NAT-t for fragments, since heads will set that off.// It wouldn't hurt anything, just redundant and unnecessary.SharedPtr<Peer> relayTo = RR->topology->getPeer(tPtr,destination);if ((!relayTo)||(!relayTo->sendDirect(tPtr,fragment.data(),fragment.size(),now,false))) {// Don't know peer or no direct path -- so relay via someone upstreamrelayTo = RR->topology->getUpstreamPeer();if (relayTo)relayTo->sendDirect(tPtr,fragment.data(),fragment.size(),now,true);}}} else {// Fragment looks like oursconst uint64_t fragmentPacketId = fragment.packetId();const unsigned int fragmentNumber = fragment.fragmentNumber();const unsigned int totalFragments = fragment.totalFragments();if ((totalFragments <= ZT_MAX_PACKET_FRAGMENTS)&&(fragmentNumber < ZT_MAX_PACKET_FRAGMENTS)&&(fragmentNumber > 0)&&(totalFragments > 1)) {// Fragment appears basically sane. Its fragment number must be// 1 or more, since a Packet with fragmented bit set is fragment 0.// Total fragments must be more than 1, otherwise why are we// seeing a Packet::Fragment?RXQueueEntry *const rq = _findRXQueueEntry(fragmentPacketId);Mutex::Lock rql(rq->lock);if (rq->packetId != fragmentPacketId) {// No packet found, so we received a fragment without its head.rq->flowId = flowId;rq->timestamp = now;rq->packetId = fragmentPacketId;rq->frags[fragmentNumber - 1] = fragment;rq->totalFragments = totalFragments; // total fragment count is knownrq->haveFragments = 1 << fragmentNumber; // we have only this fragmentrq->complete = false;} else if (!(rq->haveFragments & (1 << fragmentNumber))) {// We have other fragments and maybe the head, so add this one and checkrq->frags[fragmentNumber - 1] = fragment;rq->totalFragments = totalFragments;if (Utils::countBits(rq->haveFragments |= (1 << fragmentNumber)) == totalFragments) {// We have all fragments -- assemble and process full Packetfor(unsigned int f=1;f<totalFragments;++f)rq->frag0.append(rq->frags[f - 1].payload(),rq->frags[f - 1].payloadLength());if (rq->frag0.tryDecode(RR,tPtr,flowId)) {rq->timestamp = 0; // packet decoded, free entry} else {rq->complete = true; // set complete flag but leave entry since it probably needs WHOIS or something}}} // else this is a duplicate fragment, ignore}}// --------------------------------------------------------------------} else if (len >= ZT_PROTO_MIN_PACKET_LENGTH) { // min length check is important!// Handle packet head -------------------------------------------------const Address destination(reinterpret_cast<const uint8_t *>(data) + 8,ZT_ADDRESS_LENGTH);const Address source(reinterpret_cast<const uint8_t *>(data) + 13,ZT_ADDRESS_LENGTH);if (source == RR->identity.address())return;if (destination != RR->identity.address()) {if ( (!RR->topology->amUpstream()) && (!path->trustEstablished(now)) && (source != RR->identity.address()) )return;Packet packet(data,len);if (packet.hops() < ZT_RELAY_MAX_HOPS) {packet.incrementHops();SharedPtr<Peer> relayTo = RR->topology->getPeer(tPtr,destination);if ((relayTo)&&(relayTo->sendDirect(tPtr,packet.data(),packet.size(),now,false))) {if ((source != RR->identity.address())&&(_shouldUnite(now,source,destination))) {const SharedPtr<Peer> sourcePeer(RR->topology->getPeer(tPtr,source));if (sourcePeer)relayTo->introduce(tPtr,now,sourcePeer);}} else {relayTo = RR->topology->getUpstreamPeer();if ((relayTo)&&(relayTo->address() != source)) {if (relayTo->sendDirect(tPtr,packet.data(),packet.size(),now,true)) {const SharedPtr<Peer> sourcePeer(RR->topology->getPeer(tPtr,source));if (sourcePeer)relayTo->introduce(tPtr,now,sourcePeer);}}}}} else if ((reinterpret_cast<const uint8_t *>(data)[ZT_PACKET_IDX_FLAGS] & ZT_PROTO_FLAG_FRAGMENTED) != 0) {// Packet is the head of a fragmented packet seriesconst uint64_t packetId = ((((uint64_t)reinterpret_cast<const uint8_t *>(data)[0]) << 56) |(((uint64_t)reinterpret_cast<const uint8_t *>(data)[1]) << 48) |(((uint64_t)reinterpret_cast<const uint8_t *>(data)[2]) << 40) |(((uint64_t)reinterpret_cast<const uint8_t *>(data)[3]) << 32) |(((uint64_t)reinterpret_cast<const uint8_t *>(data)[4]) << 24) |(((uint64_t)reinterpret_cast<const uint8_t *>(data)[5]) << 16) |(((uint64_t)reinterpret_cast<const uint8_t *>(data)[6]) << 8) |((uint64_t)reinterpret_cast<const uint8_t *>(data)[7]));RXQueueEntry *const rq = _findRXQueueEntry(packetId);Mutex::Lock rql(rq->lock);if (rq->packetId != packetId) {// If we have no other fragments yet, create an entry and save the headrq->flowId = flowId;rq->timestamp = now;rq->packetId = packetId;rq->frag0.init(data,len,path,now);rq->totalFragments = 0;rq->haveFragments = 1;rq->complete = false;} else if (!(rq->haveFragments & 1)) {// If we have other fragments but no head, see if we are complete with the headif ((rq->totalFragments > 1)&&(Utils::countBits(rq->haveFragments |= 1) == rq->totalFragments)) {// We have all fragments -- assemble and process full Packetrq->frag0.init(data,len,path,now);for(unsigned int f=1;f<rq->totalFragments;++f)rq->frag0.append(rq->frags[f - 1].payload(),rq->frags[f - 1].payloadLength());if (rq->frag0.tryDecode(RR,tPtr,flowId)) {rq->timestamp = 0; // packet decoded, free entry} else {rq->complete = true; // set complete flag but leave entry since it probably needs WHOIS or something}} else {// Still waiting on more fragments, but keep the headrq->frag0.init(data,len,path,now);}} // else this is a duplicate head, ignore} else {// Packet is unfragmented, so just process itIncomingPacket packet(data,len,path,now);if (!packet.tryDecode(RR,tPtr,flowId)) {RXQueueEntry *const rq = _nextRXQueueEntry();Mutex::Lock rql(rq->lock);rq->flowId = flowId;rq->timestamp = now;rq->packetId = packet.packetId();rq->frag0 = packet;rq->totalFragments = 1;rq->haveFragments = 1;rq->complete = true;}}// --------------------------------------------------------------------}}} catch ( ... ) {} // sanity check, should be caught elsewhere}void Switch::onLocalEthernet(void *tPtr,const SharedPtr<Network> &network,const MAC &from,const MAC &to,unsigned int etherType,unsigned int vlanId,const void *data,unsigned int len){if (!network->hasConfig())return;// Check if this packet is from someone other than the tap -- i.e. bridged inbool fromBridged;if ((fromBridged = (from != network->mac()))) {if (!network->config().permitsBridging(RR->identity.address())) {RR->t->outgoingNetworkFrameDropped(tPtr,network,from,to,etherType,vlanId,len,"not a bridge");return;}}uint8_t qosBucket = ZT_AQM_DEFAULT_BUCKET;/*** A pseudo-unique identifier used by balancing and bonding policies to* categorize individual flows/conversations for assignment to a specific* physical path. This identifier consists of the source port and* destination port of the encapsulated frame.** A flowId of -1 will indicate that there is no preference for how this* packet shall be sent. An example of this would be an ICMP packet.*/int32_t flowId = ZT_QOS_NO_FLOW;if (etherType == ZT_ETHERTYPE_IPV4 && (len >= 20)) {uint16_t srcPort = 0;uint16_t dstPort = 0;uint8_t proto = (reinterpret_cast<const uint8_t *>(data)[9]);const unsigned int headerLen = 4 * (reinterpret_cast<const uint8_t *>(data)[0] & 0xf);switch(proto) {case 0x01: // ICMP//flowId = 0x01;break;// All these start with 16-bit source and destination port in that ordercase 0x06: // TCPcase 0x11: // UDPcase 0x84: // SCTPcase 0x88: // UDPLiteif (len > (headerLen + 4)) {unsigned int pos = headerLen + 0;srcPort = (reinterpret_cast<const uint8_t *>(data)[pos++]) << 8;srcPort |= (reinterpret_cast<const uint8_t *>(data)[pos]);pos++;dstPort = (reinterpret_cast<const uint8_t *>(data)[pos++]) << 8;dstPort |= (reinterpret_cast<const uint8_t *>(data)[pos]);flowId = dstPort ^ srcPort ^ proto;}break;}}if (etherType == ZT_ETHERTYPE_IPV6 && (len >= 40)) {uint16_t srcPort = 0;uint16_t dstPort = 0;unsigned int pos;unsigned int proto;_ipv6GetPayload((const uint8_t *)data, len, pos, proto);switch(proto) {case 0x3A: // ICMPv6//flowId = 0x3A;break;// All these start with 16-bit source and destination port in that ordercase 0x06: // TCPcase 0x11: // UDPcase 0x84: // SCTPcase 0x88: // UDPLiteif (len > (pos + 4)) {srcPort = (reinterpret_cast<const uint8_t *>(data)[pos++]) << 8;srcPort |= (reinterpret_cast<const uint8_t *>(data)[pos]);pos++;dstPort = (reinterpret_cast<const uint8_t *>(data)[pos++]) << 8;dstPort |= (reinterpret_cast<const uint8_t *>(data)[pos]);flowId = dstPort ^ srcPort ^ proto;}break;default:break;}}if (to.isMulticast()) {MulticastGroup multicastGroup(to,0);if (to.isBroadcast()) {if ( (etherType == ZT_ETHERTYPE_ARP) && (len >= 28) && ((((const uint8_t *)data)[2] == 0x08)&&(((const uint8_t *)data)[3] == 0x00)&&(((const uint8_t *)data)[4] == 6)&&(((const uint8_t *)data)[5] == 4)&&(((const uint8_t *)data)[7] == 0x01)) ) {/* IPv4 ARP is one of the few special cases that we impose upon what is* otherwise a straightforward Ethernet switch emulation. Vanilla ARP* is dumb old broadcast and simply doesn't scale. ZeroTier multicast* groups have an additional field called ADI (additional distinguishing* information) which was added specifically for ARP though it could* be used for other things too. We then take ARP broadcasts and turn* them into multicasts by stuffing the IP address being queried into* the 32-bit ADI field. In practice this uses our multicast pub/sub* system to implement a kind of extended/distributed ARP table. */multicastGroup = MulticastGroup::deriveMulticastGroupForAddressResolution(InetAddress(((const unsigned char *)data) + 24,4,0));} else if (!network->config().enableBroadcast()) {// Don't transmit broadcasts if this network doesn't want themRR->t->outgoingNetworkFrameDropped(tPtr,network,from,to,etherType,vlanId,len,"broadcast disabled");return;}} else if ((etherType == ZT_ETHERTYPE_IPV6)&&(len >= (40 + 8 + 16))) {// IPv6 NDP emulation for certain very special patterns of private IPv6 addresses -- if enabledif ((network->config().ndpEmulation())&&(reinterpret_cast<const uint8_t *>(data)[6] == 0x3a)&&(reinterpret_cast<const uint8_t *>(data)[40] == 0x87)) { // ICMPv6 neighbor solicitationAddress v6EmbeddedAddress;const uint8_t *const pkt6 = reinterpret_cast<const uint8_t *>(data) + 40 + 8;const uint8_t *my6 = (const uint8_t *)0;// ZT-RFC4193 address: fdNN:NNNN:NNNN:NNNN:NN99:93DD:DDDD:DDDD / 88 (one /128 per actual host)// ZT-6PLANE address: fcXX:XXXX:XXDD:DDDD:DDDD:####:####:#### / 40 (one /80 per actual host)// (XX - lower 32 bits of network ID XORed with higher 32 bits)// For these to work, we must have a ZT-managed address assigned in one of the// above formats, and the query must match its prefix.for(unsigned int sipk=0;sipk<network->config().staticIpCount;++sipk) {const InetAddress *const sip = &(network->config().staticIps[sipk]);if (sip->ss_family == AF_INET6) {my6 = reinterpret_cast<const uint8_t *>(reinterpret_cast<const struct sockaddr_in6 *>(&(*sip))->sin6_addr.s6_addr);const unsigned int sipNetmaskBits = Utils::ntoh((uint16_t)reinterpret_cast<const struct sockaddr_in6 *>(&(*sip))->sin6_port);if ((sipNetmaskBits == 88)&&(my6[0] == 0xfd)&&(my6[9] == 0x99)&&(my6[10] == 0x93)) { // ZT-RFC4193 /88 ???unsigned int ptr = 0;while (ptr != 11) {if (pkt6[ptr] != my6[ptr])break;++ptr;}if (ptr == 11) { // prefix match!v6EmbeddedAddress.setTo(pkt6 + ptr,5);break;}} else if (sipNetmaskBits == 40) { // ZT-6PLANE /40 ???const uint32_t nwid32 = (uint32_t)((network->id() ^ (network->id() >> 32)) & 0xffffffff);if ( (my6[0] == 0xfc) && (my6[1] == (uint8_t)((nwid32 >> 24) & 0xff)) && (my6[2] == (uint8_t)((nwid32 >> 16) & 0xff)) && (my6[3] == (uint8_t)((nwid32 >> 8) & 0xff)) && (my6[4] == (uint8_t)(nwid32 & 0xff))) {unsigned int ptr = 0;while (ptr != 5) {if (pkt6[ptr] != my6[ptr])break;++ptr;}if (ptr == 5) { // prefix match!v6EmbeddedAddress.setTo(pkt6 + ptr,5);break;}}}}}if ((v6EmbeddedAddress)&&(v6EmbeddedAddress != RR->identity.address())) {const MAC peerMac(v6EmbeddedAddress,network->id());uint8_t adv[72];adv[0] = 0x60; adv[1] = 0x00; adv[2] = 0x00; adv[3] = 0x00;adv[4] = 0x00; adv[5] = 0x20;adv[6] = 0x3a; adv[7] = 0xff;for(int i=0;i<16;++i) adv[8 + i] = pkt6[i];for(int i=0;i<16;++i) adv[24 + i] = my6[i];adv[40] = 0x88; adv[41] = 0x00;adv[42] = 0x00; adv[43] = 0x00; // future home of checksumadv[44] = 0x60; adv[45] = 0x00; adv[46] = 0x00; adv[47] = 0x00;for(int i=0;i<16;++i) adv[48 + i] = pkt6[i];adv[64] = 0x02; adv[65] = 0x01;adv[66] = peerMac[0]; adv[67] = peerMac[1]; adv[68] = peerMac[2]; adv[69] = peerMac[3]; adv[70] = peerMac[4]; adv[71] = peerMac[5];uint16_t pseudo_[36];uint8_t *const pseudo = reinterpret_cast<uint8_t *>(pseudo_);for(int i=0;i<32;++i) pseudo[i] = adv[8 + i];pseudo[32] = 0x00; pseudo[33] = 0x00; pseudo[34] = 0x00; pseudo[35] = 0x20;pseudo[36] = 0x00; pseudo[37] = 0x00; pseudo[38] = 0x00; pseudo[39] = 0x3a;for(int i=0;i<32;++i) pseudo[40 + i] = adv[40 + i];uint32_t checksum = 0;for(int i=0;i<36;++i) checksum += Utils::hton(pseudo_[i]);while ((checksum >> 16)) checksum = (checksum & 0xffff) + (checksum >> 16);checksum = ~checksum;adv[42] = (checksum >> 8) & 0xff;adv[43] = checksum & 0xff;RR->node->putFrame(tPtr,network->id(),network->userPtr(),peerMac,from,ZT_ETHERTYPE_IPV6,0,adv,72);return; // NDP emulation done. We have forged a "fake" reply, so no need to send actual NDP query.} // else no NDP emulation} // else no NDP emulation}// Check this after NDP emulation, since that has to be allowed in exactly this caseif (network->config().multicastLimit == 0) {RR->t->outgoingNetworkFrameDropped(tPtr,network,from,to,etherType,vlanId,len,"multicast disabled");return;}/* Learn multicast groups for bridged-in hosts.* Note that some OSes, most notably Linux, do this for you by learning* multicast addresses on bridge interfaces and subscribing each slave.* But in that case this does no harm, as the sets are just merged. */if (fromBridged)network->learnBridgedMulticastGroup(tPtr,multicastGroup,RR->node->now());// First pass sets noTee to false, but noTee is set to true in OutboundMulticast to prevent duplicates.if (!network->filterOutgoingPacket(tPtr,false,RR->identity.address(),Address(),from,to,(const uint8_t *)data,len,etherType,vlanId,qosBucket)) {RR->t->outgoingNetworkFrameDropped(tPtr,network,from,to,etherType,vlanId,len,"filter blocked");return;}RR->mc->send(tPtr,RR->node->now(),network,Address(),multicastGroup,(fromBridged) ? from : MAC(),etherType,data,len);} else if (to == network->mac()) {// Destination is this node, so just reinject itRR->node->putFrame(tPtr,network->id(),network->userPtr(),from,to,etherType,vlanId,data,len);} else if (to[0] == MAC::firstOctetForNetwork(network->id())) {// Destination is another ZeroTier peer on the same networkAddress toZT(to.toAddress(network->id())); // since in-network MACs are derived from addresses and network IDs, we can reverse thisSharedPtr<Peer> toPeer(RR->topology->getPeer(tPtr,toZT));if (!network->filterOutgoingPacket(tPtr,false,RR->identity.address(),toZT,from,to,(const uint8_t *)data,len,etherType,vlanId,qosBucket)) {RR->t->outgoingNetworkFrameDropped(tPtr,network,from,to,etherType,vlanId,len,"filter blocked");return;}network->pushCredentialsIfNeeded(tPtr,toZT,RR->node->now());if (!fromBridged) {Packet outp(toZT,RR->identity.address(),Packet::VERB_FRAME);outp.append(network->id());outp.append((uint16_t)etherType);outp.append(data,len);// 1.4.8: disable compression for unicast as it almost never helps//if (!network->config().disableCompression())// outp.compress();aqm_enqueue(tPtr,network,outp,true,qosBucket,flowId);} else {Packet outp(toZT,RR->identity.address(),Packet::VERB_EXT_FRAME);outp.append(network->id());outp.append((unsigned char)0x00);to.appendTo(outp);from.appendTo(outp);outp.append((uint16_t)etherType);outp.append(data,len);// 1.4.8: disable compression for unicast as it almost never helps//if (!network->config().disableCompression())// outp.compress();aqm_enqueue(tPtr,network,outp,true,qosBucket,flowId);}} else {// Destination is bridged behind a remote peer// We filter with a NULL destination ZeroTier address first. Filtrations// for each ZT destination are also done below. This is the same rationale// and design as for multicast.if (!network->filterOutgoingPacket(tPtr,false,RR->identity.address(),Address(),from,to,(const uint8_t *)data,len,etherType,vlanId,qosBucket)) {RR->t->outgoingNetworkFrameDropped(tPtr,network,from,to,etherType,vlanId,len,"filter blocked");return;}Address bridges[ZT_MAX_BRIDGE_SPAM];unsigned int numBridges = 0;/* Create an array of up to ZT_MAX_BRIDGE_SPAM recipients for this bridged frame. */bridges[0] = network->findBridgeTo(to);std::vector<Address> activeBridges(network->config().activeBridges());if ((bridges[0])&&(bridges[0] != RR->identity.address())&&(network->config().permitsBridging(bridges[0]))) {/* We have a known bridge route for this MAC, send it there. */++numBridges;} else if (!activeBridges.empty()) {/* If there is no known route, spam to up to ZT_MAX_BRIDGE_SPAM active* bridges. If someone responds, we'll learn the route. */std::vector<Address>::const_iterator ab(activeBridges.begin());if (activeBridges.size() <= ZT_MAX_BRIDGE_SPAM) {// If there are <= ZT_MAX_BRIDGE_SPAM active bridges, spam them allwhile (ab != activeBridges.end()) {bridges[numBridges++] = *ab;++ab;}} else {// Otherwise pick a random set of themwhile (numBridges < ZT_MAX_BRIDGE_SPAM) {if (ab == activeBridges.end())ab = activeBridges.begin();if (((unsigned long)RR->node->prng() % (unsigned long)activeBridges.size()) == 0) {bridges[numBridges++] = *ab;++ab;} else ++ab;}}}for(unsigned int b=0;b<numBridges;++b) {if (network->filterOutgoingPacket(tPtr,true,RR->identity.address(),bridges[b],from,to,(const uint8_t *)data,len,etherType,vlanId,qosBucket)) {Packet outp(bridges[b],RR->identity.address(),Packet::VERB_EXT_FRAME);outp.append(network->id());outp.append((uint8_t)0x00);to.appendTo(outp);from.appendTo(outp);outp.append((uint16_t)etherType);outp.append(data,len);// 1.4.8: disable compression for unicast as it almost never helps//if (!network->config().disableCompression())// outp.compress();aqm_enqueue(tPtr,network,outp,true,qosBucket,flowId);} else {RR->t->outgoingNetworkFrameDropped(tPtr,network,from,to,etherType,vlanId,len,"filter blocked (bridge replication)");}}}}void Switch::aqm_enqueue(void *tPtr, const SharedPtr<Network> &network, Packet &packet,bool encrypt,int qosBucket,int32_t flowId){if(!network->qosEnabled()) {send(tPtr, packet, encrypt, flowId);return;}NetworkQoSControlBlock *nqcb = _netQueueControlBlock[network->id()];if (!nqcb) {nqcb = new NetworkQoSControlBlock();_netQueueControlBlock[network->id()] = nqcb;// Initialize ZT_QOS_NUM_BUCKETS queues and place them in the INACTIVE list// These queues will be shuffled between the new/old/inactive lists by the enqueue/dequeue algorithmfor (int i=0; i<ZT_AQM_NUM_BUCKETS; i++) {nqcb->inactiveQueues.push_back(new ManagedQueue(i));}}// Don't apply QoS scheduling to ZT protocol trafficif (packet.verb() != Packet::VERB_FRAME && packet.verb() != Packet::VERB_EXT_FRAME) {send(tPtr, packet, encrypt, flowId);}_aqm_m.lock();// Enqueue packet and move queue to appropriate listconst Address dest(packet.destination());TXQueueEntry *txEntry = new TXQueueEntry(dest,RR->node->now(),packet,encrypt,flowId);ManagedQueue *selectedQueue = nullptr;for (size_t i=0; i<ZT_AQM_NUM_BUCKETS; i++) {if (i < nqcb->oldQueues.size()) { // search old queues first (I think this is best since old would imply most recent usage of the queue)if (nqcb->oldQueues[i]->id == qosBucket) {selectedQueue = nqcb->oldQueues[i];}} if (i < nqcb->newQueues.size()) { // search new queues (this would imply not often-used queues)if (nqcb->newQueues[i]->id == qosBucket) {selectedQueue = nqcb->newQueues[i];}} if (i < nqcb->inactiveQueues.size()) { // search inactive queuesif (nqcb->inactiveQueues[i]->id == qosBucket) {selectedQueue = nqcb->inactiveQueues[i];// move queue to end of NEW queue listselectedQueue->byteCredit = ZT_AQM_QUANTUM;// DEBUG_INFO("moving q=%p from INACTIVE to NEW list", selectedQueue);nqcb->newQueues.push_back(selectedQueue);nqcb->inactiveQueues.erase(nqcb->inactiveQueues.begin() + i);}}}if (!selectedQueue) {return;}selectedQueue->q.push_back(txEntry);selectedQueue->byteLength+=txEntry->packet.payloadLength();nqcb->_currEnqueuedPackets++;// DEBUG_INFO("nq=%2lu, oq=%2lu, iq=%2lu, nqcb.size()=%3d, bucket=%2d, q=%p", nqcb->newQueues.size(), nqcb->oldQueues.size(), nqcb->inactiveQueues.size(), nqcb->_currEnqueuedPackets, qosBucket, selectedQueue);// Drop a packet if necessaryManagedQueue *selectedQueueToDropFrom = nullptr;if (nqcb->_currEnqueuedPackets > ZT_AQM_MAX_ENQUEUED_PACKETS){// DEBUG_INFO("too many enqueued packets (%d), finding packet to drop", nqcb->_currEnqueuedPackets);int maxQueueLength = 0;for (size_t i=0; i<ZT_AQM_NUM_BUCKETS; i++) {if (i < nqcb->oldQueues.size()) {if (nqcb->oldQueues[i]->byteLength > maxQueueLength) {maxQueueLength = nqcb->oldQueues[i]->byteLength;selectedQueueToDropFrom = nqcb->oldQueues[i];}} if (i < nqcb->newQueues.size()) {if (nqcb->newQueues[i]->byteLength > maxQueueLength) {maxQueueLength = nqcb->newQueues[i]->byteLength;selectedQueueToDropFrom = nqcb->newQueues[i];}} if (i < nqcb->inactiveQueues.size()) {if (nqcb->inactiveQueues[i]->byteLength > maxQueueLength) {maxQueueLength = nqcb->inactiveQueues[i]->byteLength;selectedQueueToDropFrom = nqcb->inactiveQueues[i];}}}if (selectedQueueToDropFrom) {// DEBUG_INFO("dropping packet from head of largest queue (%d payload bytes)", maxQueueLength);int sizeOfDroppedPacket = selectedQueueToDropFrom->q.front()->packet.payloadLength();delete selectedQueueToDropFrom->q.front();selectedQueueToDropFrom->q.pop_front();selectedQueueToDropFrom->byteLength-=sizeOfDroppedPacket;nqcb->_currEnqueuedPackets--;}}_aqm_m.unlock();aqm_dequeue(tPtr);}uint64_t Switch::control_law(uint64_t t, int count){return (uint64_t)(t + ZT_AQM_INTERVAL / sqrt(count));}Switch::dqr Switch::dodequeue(ManagedQueue *q, uint64_t now){dqr r;r.ok_to_drop = false;r.p = q->q.front();if (r.p == NULL) {q->first_above_time = 0;return r;}uint64_t sojourn_time = now - r.p->creationTime;if (sojourn_time < ZT_AQM_TARGET || q->byteLength <= ZT_DEFAULT_MTU) {// went below - stay below for at least intervalq->first_above_time = 0;} else {if (q->first_above_time == 0) {// just went above from below. if still above at// first_above_time, will say it's ok to drop.q->first_above_time = now + ZT_AQM_INTERVAL;} else if (now >= q->first_above_time) {r.ok_to_drop = true;}}return r;}Switch::TXQueueEntry * Switch::CoDelDequeue(ManagedQueue *q, bool isNew, uint64_t now){dqr r = dodequeue(q, now);if (q->dropping) {if (!r.ok_to_drop) {q->dropping = false;}while (now >= q->drop_next && q->dropping) {q->q.pop_front(); // dropr = dodequeue(q, now);if (!r.ok_to_drop) {// leave dropping stateq->dropping = false;} else {++(q->count);// schedule the next drop.q->drop_next = control_law(q->drop_next, q->count);}}} else if (r.ok_to_drop) {q->q.pop_front(); // dropr = dodequeue(q, now);q->dropping = true;q->count = (q->count > 2 && now - q->drop_next < 8*ZT_AQM_INTERVAL)?q->count - 2 : 1;q->drop_next = control_law(now, q->count);}return r.p;}void Switch::aqm_dequeue(void *tPtr){// Cycle through network-specific QoS control blocksfor(std::map<uint64_t,NetworkQoSControlBlock*>::iterator nqcb(_netQueueControlBlock.begin());nqcb!=_netQueueControlBlock.end();) {if (!(*nqcb).second->_currEnqueuedPackets) {return;}uint64_t now = RR->node->now();TXQueueEntry *entryToEmit = nullptr;std::vector<ManagedQueue*> *currQueues = &((*nqcb).second->newQueues);std::vector<ManagedQueue*> *oldQueues = &((*nqcb).second->oldQueues);std::vector<ManagedQueue*> *inactiveQueues = &((*nqcb).second->inactiveQueues);_aqm_m.lock();// Attempt dequeue from queues in NEW listbool examiningNewQueues = true;while (currQueues->size()) {ManagedQueue *queueAtFrontOfList = currQueues->front();if (queueAtFrontOfList->byteCredit < 0) {queueAtFrontOfList->byteCredit += ZT_AQM_QUANTUM;// Move to list of OLD queues// DEBUG_INFO("moving q=%p from NEW to OLD list", queueAtFrontOfList);oldQueues->push_back(queueAtFrontOfList);currQueues->erase(currQueues->begin());} else {entryToEmit = CoDelDequeue(queueAtFrontOfList, examiningNewQueues, now);if (!entryToEmit) {// Move to end of list of OLD queues// DEBUG_INFO("moving q=%p from NEW to OLD list", queueAtFrontOfList);oldQueues->push_back(queueAtFrontOfList);currQueues->erase(currQueues->begin());}else {int len = entryToEmit->packet.payloadLength();queueAtFrontOfList->byteLength -= len;queueAtFrontOfList->byteCredit -= len;// Send the packet!queueAtFrontOfList->q.pop_front();send(tPtr, entryToEmit->packet, entryToEmit->encrypt, entryToEmit->flowId);(*nqcb).second->_currEnqueuedPackets--;}if (queueAtFrontOfList) {//DEBUG_INFO("dequeuing from q=%p, len=%lu in NEW list (byteCredit=%d)", queueAtFrontOfList, queueAtFrontOfList->q.size(), queueAtFrontOfList->byteCredit);}break;}}// Attempt dequeue from queues in OLD listexaminingNewQueues = false;currQueues = &((*nqcb).second->oldQueues);while (currQueues->size()) {ManagedQueue *queueAtFrontOfList = currQueues->front();if (queueAtFrontOfList->byteCredit < 0) {queueAtFrontOfList->byteCredit += ZT_AQM_QUANTUM;oldQueues->push_back(queueAtFrontOfList);currQueues->erase(currQueues->begin());} else {entryToEmit = CoDelDequeue(queueAtFrontOfList, examiningNewQueues, now);if (!entryToEmit) {//DEBUG_INFO("moving q=%p from OLD to INACTIVE list", queueAtFrontOfList);// Move to inactive list of queuesinactiveQueues->push_back(queueAtFrontOfList);currQueues->erase(currQueues->begin());}else {int len = entryToEmit->packet.payloadLength();queueAtFrontOfList->byteLength -= len;queueAtFrontOfList->byteCredit -= len;queueAtFrontOfList->q.pop_front();send(tPtr, entryToEmit->packet, entryToEmit->encrypt, entryToEmit->flowId);(*nqcb).second->_currEnqueuedPackets--;}if (queueAtFrontOfList) {//DEBUG_INFO("dequeuing from q=%p, len=%lu in OLD list (byteCredit=%d)", queueAtFrontOfList, queueAtFrontOfList->q.size(), queueAtFrontOfList->byteCredit);}break;}}nqcb++;_aqm_m.unlock();}}void Switch::removeNetworkQoSControlBlock(uint64_t nwid){NetworkQoSControlBlock *nq = _netQueueControlBlock[nwid];if (nq) {_netQueueControlBlock.erase(nwid);delete nq;nq = NULL;}}void Switch::send(void *tPtr,Packet &packet,bool encrypt,int32_t flowId){const Address dest(packet.destination());if (dest == RR->identity.address())return;if (!_trySend(tPtr,packet,encrypt,flowId)) {{Mutex::Lock _l(_txQueue_m);if (_txQueue.size() >= ZT_TX_QUEUE_SIZE) {_txQueue.pop_front();}_txQueue.push_back(TXQueueEntry(dest,RR->node->now(),packet,encrypt,flowId));}if (!RR->topology->getPeer(tPtr,dest))requestWhois(tPtr,RR->node->now(),dest);}}void Switch::requestWhois(void *tPtr,const int64_t now,const Address &addr){if (addr == RR->identity.address())return;{Mutex::Lock _l(_lastSentWhoisRequest_m);int64_t &last = _lastSentWhoisRequest[addr];if ((now - last) < ZT_WHOIS_RETRY_DELAY)return;else last = now;}const SharedPtr<Peer> upstream(RR->topology->getUpstreamPeer());if (upstream) {int32_t flowId = ZT_QOS_NO_FLOW;Packet outp(upstream->address(),RR->identity.address(),Packet::VERB_WHOIS);addr.appendTo(outp);send(tPtr,outp,true,flowId);}}void Switch::doAnythingWaitingForPeer(void *tPtr,const SharedPtr<Peer> &peer){{Mutex::Lock _l(_lastSentWhoisRequest_m);_lastSentWhoisRequest.erase(peer->address());}const int64_t now = RR->node->now();for(unsigned int ptr=0;ptr<ZT_RX_QUEUE_SIZE;++ptr) {RXQueueEntry *const rq = &(_rxQueue[ptr]);Mutex::Lock rql(rq->lock);if ((rq->timestamp)&&(rq->complete)) {if ((rq->frag0.tryDecode(RR,tPtr,rq->flowId))||((now - rq->timestamp) > ZT_RECEIVE_QUEUE_TIMEOUT))rq->timestamp = 0;}}{Mutex::Lock _l(_txQueue_m);for(std::list< TXQueueEntry >::iterator txi(_txQueue.begin());txi!=_txQueue.end();) {if (txi->dest == peer->address()) {if (_trySend(tPtr,txi->packet,txi->encrypt,txi->flowId)) {_txQueue.erase(txi++);} else {++txi;}} else {++txi;}}}}unsigned long Switch::doTimerTasks(void *tPtr,int64_t now){const uint64_t timeSinceLastCheck = now - _lastCheckedQueues;if (timeSinceLastCheck < ZT_WHOIS_RETRY_DELAY)return (unsigned long)(ZT_WHOIS_RETRY_DELAY - timeSinceLastCheck);_lastCheckedQueues = now;std::vector<Address> needWhois;{Mutex::Lock _l(_txQueue_m);for(std::list< TXQueueEntry >::iterator txi(_txQueue.begin());txi!=_txQueue.end();) {if (_trySend(tPtr,txi->packet,txi->encrypt,txi->flowId)) {_txQueue.erase(txi++);} else if ((now - txi->creationTime) > ZT_TRANSMIT_QUEUE_TIMEOUT) {_txQueue.erase(txi++);} else {if (!RR->topology->getPeer(tPtr,txi->dest))needWhois.push_back(txi->dest);++txi;}}}for(std::vector<Address>::const_iterator i(needWhois.begin());i!=needWhois.end();++i)requestWhois(tPtr,now,*i);for(unsigned int ptr=0;ptr<ZT_RX_QUEUE_SIZE;++ptr) {RXQueueEntry *const rq = &(_rxQueue[ptr]);Mutex::Lock rql(rq->lock);if ((rq->timestamp)&&(rq->complete)) {if ((rq->frag0.tryDecode(RR,tPtr,rq->flowId))||((now - rq->timestamp) > ZT_RECEIVE_QUEUE_TIMEOUT)) {rq->timestamp = 0;} else {const Address src(rq->frag0.source());if (!RR->topology->getPeer(tPtr,src))requestWhois(tPtr,now,src);}}}{Mutex::Lock _l(_lastUniteAttempt_m);Hashtable< _LastUniteKey,uint64_t >::Iterator i(_lastUniteAttempt);_LastUniteKey *k = (_LastUniteKey *)0;uint64_t *v = (uint64_t *)0;while (i.next(k,v)) {if ((now - *v) >= (ZT_MIN_UNITE_INTERVAL * 8))_lastUniteAttempt.erase(*k);}}{Mutex::Lock _l(_lastSentWhoisRequest_m);Hashtable< Address,int64_t >::Iterator i(_lastSentWhoisRequest);Address *a = (Address *)0;int64_t *ts = (int64_t *)0;while (i.next(a,ts)) {if ((now - *ts) > (ZT_WHOIS_RETRY_DELAY * 2))_lastSentWhoisRequest.erase(*a);}}return ZT_WHOIS_RETRY_DELAY;}bool Switch::_shouldUnite(const int64_t now,const Address &source,const Address &destination){Mutex::Lock _l(_lastUniteAttempt_m);uint64_t &ts = _lastUniteAttempt[_LastUniteKey(source,destination)];if ((now - ts) >= ZT_MIN_UNITE_INTERVAL) {ts = now;return true;}return false;}bool Switch::_trySend(void *tPtr,Packet &packet,bool encrypt,int32_t flowId){SharedPtr<Path> viaPath;const int64_t now = RR->node->now();const Address destination(packet.destination());const SharedPtr<Peer> peer(RR->topology->getPeer(tPtr,destination));if (peer) {if ((peer->bondingPolicy() == ZT_BOND_POLICY_BROADCAST)&& (packet.verb() == Packet::VERB_FRAME || packet.verb() == Packet::VERB_EXT_FRAME)) {const SharedPtr<Peer> relay(RR->topology->getUpstreamPeer());Mutex::Lock _l(peer->_paths_m);for(int i=0;i<ZT_MAX_PEER_NETWORK_PATHS;++i) {if (peer->_paths[i].p && peer->_paths[i].p->alive(now)) {uint16_t userSpecifiedMtu = peer->_paths[i].p->mtu();_sendViaSpecificPath(tPtr,peer,peer->_paths[i].p, userSpecifiedMtu,now,packet,encrypt,flowId);}}return true;}else {viaPath = peer->getAppropriatePath(now,false,flowId);if (!viaPath) {peer->tryMemorizedPath(tPtr,now); // periodically attempt memorized or statically defined paths, if any are knownconst SharedPtr<Peer> relay(RR->topology->getUpstreamPeer());if ( (!relay) || (!(viaPath = relay->getAppropriatePath(now,false,flowId))) ) {if (!(viaPath = peer->getAppropriatePath(now,true,flowId)))return false;}}if (viaPath) {uint16_t userSpecifiedMtu = viaPath->mtu();_sendViaSpecificPath(tPtr,peer,viaPath,userSpecifiedMtu,now,packet,encrypt,flowId);return true;}}}return false;}void Switch::_sendViaSpecificPath(void *tPtr,SharedPtr<Peer> peer,SharedPtr<Path> viaPath,uint16_t userSpecifiedMtu, int64_t now,Packet &packet,bool encrypt,int32_t flowId){unsigned int mtu = ZT_DEFAULT_PHYSMTU;uint64_t trustedPathId = 0;RR->topology->getOutboundPathInfo(viaPath->address(),mtu,trustedPathId);if (userSpecifiedMtu > 0) {mtu = userSpecifiedMtu;}unsigned int chunkSize = std::min(packet.size(),mtu);packet.setFragmented(chunkSize < packet.size());if (trustedPathId) {packet.setTrusted(trustedPathId);} else {if (!packet.isEncrypted()) {packet.armor(peer->key(),encrypt,peer->aesKeysIfSupported());}RR->node->expectReplyTo(packet.packetId());}peer->recordOutgoingPacket(viaPath, packet.packetId(), packet.payloadLength(), packet.verb(), flowId, now);if (viaPath->send(RR,tPtr,packet.data(),chunkSize,now)) {if (chunkSize < packet.size()) {// Too big for one packet, fragment the restunsigned int fragStart = chunkSize;unsigned int remaining = packet.size() - chunkSize;unsigned int fragsRemaining = (remaining / (mtu - ZT_PROTO_MIN_FRAGMENT_LENGTH));if ((fragsRemaining * (mtu - ZT_PROTO_MIN_FRAGMENT_LENGTH)) < remaining)++fragsRemaining;const unsigned int totalFragments = fragsRemaining + 1;for(unsigned int fno=1;fno<totalFragments;++fno) {chunkSize = std::min(remaining,(unsigned int)(mtu - ZT_PROTO_MIN_FRAGMENT_LENGTH));Packet::Fragment frag(packet,fragStart,chunkSize,fno,totalFragments);viaPath->send(RR,tPtr,frag.data(),frag.size(),now);fragStart += chunkSize;remaining -= chunkSize;}}}}} // namespace ZeroTier
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