/* * This file is part of PowerDNS or dnsdist. * Copyright -- PowerDNS.COM B.V. and its contributors * * This program is free software; you can redistribute it and/or modify * it under the terms of version 2 of the GNU General Public License as * published by the Free Software Foundation. * * In addition, for the avoidance of any doubt, permission is granted to * link this program with OpenSSL and to (re)distribute the binaries * produced as the result of such linking. * * 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, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "config.h" #include #include #include #include #include #include #include #include #include #include #ifdef HAVE_LIBEDIT #if defined (__OpenBSD__) || defined(__NetBSD__) // If this is not undeffed, __attribute__ wil be redefined by /usr/include/readline/rlstdc.h #undef __STRICT_ANSI__ #include #else #include #endif #endif /* HAVE_LIBEDIT */ #include "dnsdist-systemd.hh" #ifdef HAVE_SYSTEMD #include #endif #include "dnsdist.hh" #include "dnsdist-async.hh" #include "dnsdist-cache.hh" #include "dnsdist-carbon.hh" #include "dnsdist-console.hh" #include "dnsdist-crypto.hh" #include "dnsdist-discovery.hh" #include "dnsdist-dnsparser.hh" #include "dnsdist-dynblocks.hh" #include "dnsdist-ecs.hh" #include "dnsdist-edns.hh" #include "dnsdist-healthchecks.hh" #include "dnsdist-lua.hh" #include "dnsdist-lua-hooks.hh" #include "dnsdist-nghttp2.hh" #include "dnsdist-proxy-protocol.hh" #include "dnsdist-random.hh" #include "dnsdist-rings.hh" #include "dnsdist-secpoll.hh" #include "dnsdist-tcp.hh" #include "dnsdist-web.hh" #include "dnsdist-xpf.hh" #include "dnsdist-xsk.hh" #include "base64.hh" #include "capabilities.hh" #include "coverage.hh" #include "delaypipe.hh" #include "doh.hh" #include "dolog.hh" #include "dnsname.hh" #include "dnsparser.hh" #include "ednsoptions.hh" #include "gettime.hh" #include "lock.hh" #include "misc.hh" #include "sstuff.hh" #include "threadname.hh" #include "xsk.hh" /* Known sins: Receiver is currently single threaded not *that* bad actually, but now that we are thread safe, might want to scale */ /* the RuleAction plan Set of Rules, if one matches, it leads to an Action Both rules and actions could conceivably be Lua based. On the C++ side, both could be inherited from a class Rule and a class Action, on the Lua side we can't do that. */ using std::thread; bool g_verbose; uint16_t g_maxOutstanding{std::numeric_limits::max()}; uint32_t g_staleCacheEntriesTTL{0}; bool g_allowEmptyResponse{false}; GlobalStateHolder g_ACL; string g_outputBuffer; std::vector> g_tlslocals; std::vector> g_dohlocals; std::vector> g_doqlocals; std::vector> g_doh3locals; std::vector> g_dnsCryptLocals; shared_ptr g_defaultBPFFilter{nullptr}; std::vector > g_dynBPFFilters; std::vector> g_frontends; GlobalStateHolder g_pools; size_t g_udpVectorSize{1}; std::vector g_TCPFastOpenKey; /* UDP: the grand design. Per socket we listen on for incoming queries there is one thread. Then we have a bunch of connected sockets for talking to downstream servers. We send directly to those sockets. For the return path, per downstream server we have a thread that listens to responses. Per socket there is an array of 2^16 states, when we send out a packet downstream, we note there the original requestor and the original id. The new ID is the offset in the array. When an answer comes in on a socket, we look up the offset by the id, and lob it to the original requestor. IDs are assigned by atomic increments of the socket offset. */ GlobalStateHolder > g_ruleactions; GlobalStateHolder > g_respruleactions; GlobalStateHolder > g_cachehitrespruleactions; GlobalStateHolder > g_cacheInsertedRespRuleActions; GlobalStateHolder > g_selfansweredrespruleactions; Rings g_rings; QueryCount g_qcount; GlobalStateHolder g_dstates; bool g_servFailOnNoPolicy{false}; bool g_truncateTC{false}; bool g_fixupCase{false}; bool g_dropEmptyQueries{false}; uint32_t g_socketUDPSendBuffer{0}; uint32_t g_socketUDPRecvBuffer{0}; std::set g_capabilitiesToRetain; // we are not willing to receive a bigger UDP response than that, no matter what static constexpr size_t s_maxUDPResponsePacketSize{4096U}; static size_t const s_initialUDPPacketBufferSize = s_maxUDPResponsePacketSize + DNSCRYPT_MAX_RESPONSE_PADDING_AND_MAC_SIZE; static_assert(s_initialUDPPacketBufferSize <= UINT16_MAX, "Packet size should fit in a uint16_t"); static void sendfromto(int sock, const PacketBuffer& buffer, const ComboAddress& from, const ComboAddress& dest) { const int flags = 0; if (from.sin4.sin_family == 0) { // NOLINTNEXTLINE(cppcoreguidelines-pro-type-reinterpret-cast) auto ret = sendto(sock, buffer.data(), buffer.size(), flags, reinterpret_cast(&dest), dest.getSocklen()); if (ret == -1) { int error = errno; vinfolog("Error sending UDP response to %s: %s", dest.toStringWithPort(), stringerror(error)); } return; } try { sendMsgWithOptions(sock, buffer.data(), buffer.size(), &dest, &from, 0, 0); } catch (const std::exception& exp) { vinfolog("Error sending UDP response from %s to %s: %s", from.toStringWithPort(), dest.toStringWithPort(), exp.what()); } } static void truncateTC(PacketBuffer& packet, size_t maximumSize, unsigned int qnameWireLength) { try { bool hadEDNS = false; uint16_t payloadSize = 0; uint16_t z = 0; if (g_addEDNSToSelfGeneratedResponses) { hadEDNS = getEDNSUDPPayloadSizeAndZ(reinterpret_cast(packet.data()), packet.size(), &payloadSize, &z); } packet.resize(static_cast(sizeof(dnsheader)+qnameWireLength+DNS_TYPE_SIZE+DNS_CLASS_SIZE)); dnsdist::PacketMangling::editDNSHeaderFromPacket(packet, [](dnsheader& header) { header.ancount = 0; header.arcount = 0; header.nscount = 0; return true; }); if (hadEDNS) { addEDNS(packet, maximumSize, z & EDNS_HEADER_FLAG_DO, payloadSize, 0); } } catch(...) { ++dnsdist::metrics::g_stats.truncFail; } } #ifndef DISABLE_DELAY_PIPE struct DelayedPacket { int fd; PacketBuffer packet; ComboAddress destination; ComboAddress origDest; void operator()() const { sendfromto(fd, packet, origDest, destination); } }; static std::unique_ptr> g_delay{nullptr}; #endif /* DISABLE_DELAY_PIPE */ std::string DNSQuestion::getTrailingData() const { // NOLINTNEXTLINE(cppcoreguidelines-pro-type-reinterpret-cast) const auto* message = reinterpret_cast(this->getData().data()); const uint16_t messageLen = getDNSPacketLength(message, this->getData().size()); return std::string(message + messageLen, this->getData().size() - messageLen); } bool DNSQuestion::setTrailingData(const std::string& tail) { const char* message = reinterpret_cast(this->data.data()); const uint16_t messageLen = getDNSPacketLength(message, this->data.size()); this->data.resize(messageLen); if (tail.size() > 0) { if (!hasRoomFor(tail.size())) { return false; } this->data.insert(this->data.end(), tail.begin(), tail.end()); } return true; } bool DNSQuestion::editHeader(const std::function& editFunction) { if (data.size() < sizeof(dnsheader)) { throw std::runtime_error("Trying to access the dnsheader of a too small (" + std::to_string(data.size()) + ") DNSQuestion buffer"); } return dnsdist::PacketMangling::editDNSHeaderFromPacket(data, editFunction); } static void doLatencyStats(dnsdist::Protocol protocol, double udiff) { constexpr auto doAvg = [](double& var, double n, double weight) { var = (weight -1) * var/weight + n/weight; }; if (protocol == dnsdist::Protocol::DoUDP || protocol == dnsdist::Protocol::DNSCryptUDP) { if (udiff < 1000) { ++dnsdist::metrics::g_stats.latency0_1; } else if (udiff < 10000) { ++dnsdist::metrics::g_stats.latency1_10; } else if (udiff < 50000) { ++dnsdist::metrics::g_stats.latency10_50; } else if (udiff < 100000) { ++dnsdist::metrics::g_stats.latency50_100; } else if (udiff < 1000000) { ++dnsdist::metrics::g_stats.latency100_1000; } else { ++dnsdist::metrics::g_stats.latencySlow; } dnsdist::metrics::g_stats.latencySum += udiff / 1000; ++dnsdist::metrics::g_stats.latencyCount; doAvg(dnsdist::metrics::g_stats.latencyAvg100, udiff, 100); doAvg(dnsdist::metrics::g_stats.latencyAvg1000, udiff, 1000); doAvg(dnsdist::metrics::g_stats.latencyAvg10000, udiff, 10000); doAvg(dnsdist::metrics::g_stats.latencyAvg1000000, udiff, 1000000); } else if (protocol == dnsdist::Protocol::DoTCP || protocol == dnsdist::Protocol::DNSCryptTCP) { doAvg(dnsdist::metrics::g_stats.latencyTCPAvg100, udiff, 100); doAvg(dnsdist::metrics::g_stats.latencyTCPAvg1000, udiff, 1000); doAvg(dnsdist::metrics::g_stats.latencyTCPAvg10000, udiff, 10000); doAvg(dnsdist::metrics::g_stats.latencyTCPAvg1000000, udiff, 1000000); } else if (protocol == dnsdist::Protocol::DoT) { doAvg(dnsdist::metrics::g_stats.latencyDoTAvg100, udiff, 100); doAvg(dnsdist::metrics::g_stats.latencyDoTAvg1000, udiff, 1000); doAvg(dnsdist::metrics::g_stats.latencyDoTAvg10000, udiff, 10000); doAvg(dnsdist::metrics::g_stats.latencyDoTAvg1000000, udiff, 1000000); } else if (protocol == dnsdist::Protocol::DoH) { doAvg(dnsdist::metrics::g_stats.latencyDoHAvg100, udiff, 100); doAvg(dnsdist::metrics::g_stats.latencyDoHAvg1000, udiff, 1000); doAvg(dnsdist::metrics::g_stats.latencyDoHAvg10000, udiff, 10000); doAvg(dnsdist::metrics::g_stats.latencyDoHAvg1000000, udiff, 1000000); } else if (protocol == dnsdist::Protocol::DoQ) { doAvg(dnsdist::metrics::g_stats.latencyDoQAvg100, udiff, 100); doAvg(dnsdist::metrics::g_stats.latencyDoQAvg1000, udiff, 1000); doAvg(dnsdist::metrics::g_stats.latencyDoQAvg10000, udiff, 10000); doAvg(dnsdist::metrics::g_stats.latencyDoQAvg1000000, udiff, 1000000); } else if (protocol == dnsdist::Protocol::DoH3) { doAvg(dnsdist::metrics::g_stats.latencyDoH3Avg100, udiff, 100); doAvg(dnsdist::metrics::g_stats.latencyDoH3Avg1000, udiff, 1000); doAvg(dnsdist::metrics::g_stats.latencyDoH3Avg10000, udiff, 10000); doAvg(dnsdist::metrics::g_stats.latencyDoH3Avg1000000, udiff, 1000000); } } bool responseContentMatches(const PacketBuffer& response, const DNSName& qname, const uint16_t qtype, const uint16_t qclass, const std::shared_ptr& remote) { if (response.size() < sizeof(dnsheader)) { return false; } const dnsheader_aligned dh(response.data()); if (dh->qr == 0) { ++dnsdist::metrics::g_stats.nonCompliantResponses; if (remote) { ++remote->nonCompliantResponses; } return false; } if (dh->qdcount == 0) { if ((dh->rcode != RCode::NoError && dh->rcode != RCode::NXDomain) || g_allowEmptyResponse) { return true; } else { ++dnsdist::metrics::g_stats.nonCompliantResponses; if (remote) { ++remote->nonCompliantResponses; } return false; } } uint16_t rqtype, rqclass; DNSName rqname; try { // NOLINTNEXTLINE(cppcoreguidelines-pro-type-reinterpret-cast) rqname = DNSName(reinterpret_cast(response.data()), response.size(), sizeof(dnsheader), false, &rqtype, &rqclass); } catch (const std::exception& e) { if (remote && response.size() > 0 && static_cast(response.size()) > sizeof(dnsheader)) { infolog("Backend %s sent us a response with id %d that did not parse: %s", remote->d_config.remote.toStringWithPort(), ntohs(dh->id), e.what()); } ++dnsdist::metrics::g_stats.nonCompliantResponses; if (remote) { ++remote->nonCompliantResponses; } return false; } if (rqtype != qtype || rqclass != qclass || rqname != qname) { return false; } return true; } static void restoreFlags(struct dnsheader* dh, uint16_t origFlags) { static const uint16_t rdMask = 1 << FLAGS_RD_OFFSET; static const uint16_t cdMask = 1 << FLAGS_CD_OFFSET; static const uint16_t restoreFlagsMask = UINT16_MAX & ~(rdMask | cdMask); uint16_t* flags = getFlagsFromDNSHeader(dh); /* clear the flags we are about to restore */ *flags &= restoreFlagsMask; /* only keep the flags we want to restore */ origFlags &= ~restoreFlagsMask; /* set the saved flags as they were */ *flags |= origFlags; } static bool fixUpQueryTurnedResponse(DNSQuestion& dnsQuestion, const uint16_t origFlags) { dnsdist::PacketMangling::editDNSHeaderFromPacket(dnsQuestion.getMutableData(), [origFlags](dnsheader& header) { restoreFlags(&header, origFlags); return true; }); return addEDNSToQueryTurnedResponse(dnsQuestion); } static bool fixUpResponse(PacketBuffer& response, const DNSName& qname, uint16_t origFlags, bool ednsAdded, bool ecsAdded, bool* zeroScope) { if (response.size() < sizeof(dnsheader)) { return false; } dnsdist::PacketMangling::editDNSHeaderFromPacket(response, [origFlags](dnsheader& header) { restoreFlags(&header, origFlags); return true; }); if (response.size() == sizeof(dnsheader)) { return true; } if (g_fixupCase) { const auto& realname = qname.getStorage(); if (response.size() >= (sizeof(dnsheader) + realname.length())) { memcpy(&response.at(sizeof(dnsheader)), realname.c_str(), realname.length()); } } if (ednsAdded || ecsAdded) { uint16_t optStart; size_t optLen = 0; bool last = false; int res = locateEDNSOptRR(response, &optStart, &optLen, &last); if (res == 0) { if (zeroScope) { // this finds if an EDNS Client Subnet scope was set, and if it is 0 size_t optContentStart = 0; uint16_t optContentLen = 0; /* we need at least 4 bytes after the option length (family: 2, source prefix-length: 1, scope prefix-length: 1) */ if (isEDNSOptionInOpt(response, optStart, optLen, EDNSOptionCode::ECS, &optContentStart, &optContentLen) && optContentLen >= 4) { /* see if the EDNS Client Subnet SCOPE PREFIX-LENGTH byte in position 3 is set to 0, which is the only thing we care about. */ *zeroScope = response.at(optContentStart + 3) == 0; } } if (ednsAdded) { /* we added the entire OPT RR, therefore we need to remove it entirely */ if (last) { /* simply remove the last AR */ response.resize(response.size() - optLen); dnsdist::PacketMangling::editDNSHeaderFromPacket(response, [](dnsheader& header) { uint16_t arcount = ntohs(header.arcount); arcount--; header.arcount = htons(arcount); return true; }); } else { /* Removing an intermediary RR could lead to compression error */ PacketBuffer rewrittenResponse; if (rewriteResponseWithoutEDNS(response, rewrittenResponse) == 0) { response = std::move(rewrittenResponse); } else { warnlog("Error rewriting content"); } } } else { /* the OPT RR was already present, but without ECS, we need to remove the ECS option if any */ if (last) { /* nothing after the OPT RR, we can simply remove the ECS option */ size_t existingOptLen = optLen; removeEDNSOptionFromOPT(reinterpret_cast(&response.at(optStart)), &optLen, EDNSOptionCode::ECS); response.resize(response.size() - (existingOptLen - optLen)); } else { PacketBuffer rewrittenResponse; /* Removing an intermediary RR could lead to compression error */ if (rewriteResponseWithoutEDNSOption(response, EDNSOptionCode::ECS, rewrittenResponse) == 0) { response = std::move(rewrittenResponse); } else { warnlog("Error rewriting content"); } } } } } return true; } #ifdef HAVE_DNSCRYPT static bool encryptResponse(PacketBuffer& response, size_t maximumSize, bool tcp, std::unique_ptr& dnsCryptQuery) { if (dnsCryptQuery) { int res = dnsCryptQuery->encryptResponse(response, maximumSize, tcp); if (res != 0) { /* dropping response */ vinfolog("Error encrypting the response, dropping."); return false; } } return true; } #endif /* HAVE_DNSCRYPT */ static bool applyRulesToResponse(const std::vector& respRuleActions, DNSResponse& dr) { DNSResponseAction::Action action = DNSResponseAction::Action::None; std::string ruleresult; for (const auto& lr : respRuleActions) { if (lr.d_rule->matches(&dr)) { ++lr.d_rule->d_matches; action = (*lr.d_action)(&dr, &ruleresult); switch (action) { case DNSResponseAction::Action::Allow: return true; break; case DNSResponseAction::Action::Drop: return false; break; case DNSResponseAction::Action::HeaderModify: return true; break; case DNSResponseAction::Action::ServFail: dnsdist::PacketMangling::editDNSHeaderFromPacket(dr.getMutableData(), [](dnsheader& header) { header.rcode = RCode::ServFail; return true; }); return true; break; case DNSResponseAction::Action::Truncate: if (!dr.overTCP()) { dnsdist::PacketMangling::editDNSHeaderFromPacket(dr.getMutableData(), [](dnsheader& header) { header.tc = true; header.qr = true; return true; }); truncateTC(dr.getMutableData(), dr.getMaximumSize(), dr.ids.qname.wirelength()); ++dnsdist::metrics::g_stats.ruleTruncated; return true; } break; /* non-terminal actions follow */ case DNSResponseAction::Action::Delay: pdns::checked_stoi_into(dr.ids.delayMsec, ruleresult); // sorry break; case DNSResponseAction::Action::None: break; } } } return true; } bool processResponseAfterRules(PacketBuffer& response, const std::vector& cacheInsertedRespRuleActions, DNSResponse& dr, bool muted) { bool zeroScope = false; if (!fixUpResponse(response, dr.ids.qname, dr.ids.origFlags, dr.ids.ednsAdded, dr.ids.ecsAdded, dr.ids.useZeroScope ? &zeroScope : nullptr)) { return false; } if (dr.ids.packetCache && !dr.ids.selfGenerated && !dr.ids.skipCache && (!dr.ids.forwardedOverUDP || response.size() <= s_maxUDPResponsePacketSize)) { if (!dr.ids.useZeroScope) { /* if the query was not suitable for zero-scope, for example because it had an existing ECS entry so the hash is not really 'no ECS', so just insert it for the existing subnet since: - we don't have the correct hash for a non-ECS query - inserting with hash computed before the ECS replacement but with the subnet extracted _after_ the replacement would not work. */ zeroScope = false; } uint32_t cacheKey = dr.ids.cacheKey; if (dr.ids.protocol == dnsdist::Protocol::DoH && dr.ids.forwardedOverUDP) { cacheKey = dr.ids.cacheKeyUDP; } else if (zeroScope) { // if zeroScope, pass the pre-ECS hash-key and do not pass the subnet to the cache cacheKey = dr.ids.cacheKeyNoECS; } dr.ids.packetCache->insert(cacheKey, zeroScope ? boost::none : dr.ids.subnet, dr.ids.cacheFlags, dr.ids.dnssecOK, dr.ids.qname, dr.ids.qtype, dr.ids.qclass, response, dr.ids.forwardedOverUDP, dr.getHeader()->rcode, dr.ids.tempFailureTTL); if (!applyRulesToResponse(cacheInsertedRespRuleActions, dr)) { return false; } } if (dr.ids.ttlCap > 0) { std::string result; LimitTTLResponseAction ac(0, dr.ids.ttlCap, {}); ac(&dr, &result); } if (dr.ids.d_extendedError) { dnsdist::edns::addExtendedDNSError(dr.getMutableData(), dr.getMaximumSize(), dr.ids.d_extendedError->infoCode, dr.ids.d_extendedError->extraText); } #ifdef HAVE_DNSCRYPT if (!muted) { if (!encryptResponse(response, dr.getMaximumSize(), dr.overTCP(), dr.ids.dnsCryptQuery)) { return false; } } #endif /* HAVE_DNSCRYPT */ return true; } bool processResponse(PacketBuffer& response, const std::vector& respRuleActions, const std::vector& cacheInsertedRespRuleActions, DNSResponse& dr, bool muted) { if (!applyRulesToResponse(respRuleActions, dr)) { return false; } if (dr.isAsynchronous()) { return true; } return processResponseAfterRules(response, cacheInsertedRespRuleActions, dr, muted); } static size_t getInitialUDPPacketBufferSize(bool expectProxyProtocol) { static_assert(s_udpIncomingBufferSize <= s_initialUDPPacketBufferSize, "The incoming buffer size should not be larger than s_initialUDPPacketBufferSize"); if (!expectProxyProtocol || g_proxyProtocolACL.empty()) { return s_initialUDPPacketBufferSize; } return s_initialUDPPacketBufferSize + g_proxyProtocolMaximumSize; } static size_t getMaximumIncomingPacketSize(const ClientState& cs) { if (cs.dnscryptCtx) { return getInitialUDPPacketBufferSize(cs.d_enableProxyProtocol); } if (!cs.d_enableProxyProtocol || g_proxyProtocolACL.empty()) { return s_udpIncomingBufferSize; } return s_udpIncomingBufferSize + g_proxyProtocolMaximumSize; } bool sendUDPResponse(int origFD, const PacketBuffer& response, const int delayMsec, const ComboAddress& origDest, const ComboAddress& origRemote) { #ifndef DISABLE_DELAY_PIPE if (delayMsec > 0 && g_delay != nullptr) { DelayedPacket dp{origFD, response, origRemote, origDest}; g_delay->submit(dp, delayMsec); return true; } #endif /* DISABLE_DELAY_PIPE */ // NOLINTNEXTLINE(readability-suspicious-call-argument) sendfromto(origFD, response, origDest, origRemote); return true; } void handleResponseSent(const InternalQueryState& ids, double udiff, const ComboAddress& client, const ComboAddress& backend, unsigned int size, const dnsheader& cleartextDH, dnsdist::Protocol outgoingProtocol, bool fromBackend) { handleResponseSent(ids.qname, ids.qtype, udiff, client, backend, size, cleartextDH, outgoingProtocol, ids.protocol, fromBackend); } void handleResponseSent(const DNSName& qname, const QType& qtype, double udiff, const ComboAddress& client, const ComboAddress& backend, unsigned int size, const dnsheader& cleartextDH, dnsdist::Protocol outgoingProtocol, dnsdist::Protocol incomingProtocol, bool fromBackend) { if (g_rings.shouldRecordResponses()) { struct timespec ts; gettime(&ts); g_rings.insertResponse(ts, client, qname, qtype, static_cast(udiff), size, cleartextDH, backend, outgoingProtocol); } switch (cleartextDH.rcode) { case RCode::NXDomain: ++dnsdist::metrics::g_stats.frontendNXDomain; break; case RCode::ServFail: if (fromBackend) { ++dnsdist::metrics::g_stats.servfailResponses; } ++dnsdist::metrics::g_stats.frontendServFail; break; case RCode::NoError: ++dnsdist::metrics::g_stats.frontendNoError; break; } doLatencyStats(incomingProtocol, udiff); } static void handleResponseForUDPClient(InternalQueryState& ids, PacketBuffer& response, const std::vector& respRuleActions, const std::vector& cacheInsertedRespRuleActions, const std::shared_ptr& ds, bool isAsync, bool selfGenerated) { DNSResponse dr(ids, response, ds); if (ids.udpPayloadSize > 0 && response.size() > ids.udpPayloadSize) { vinfolog("Got a response of size %d while the initial UDP payload size was %d, truncating", response.size(), ids.udpPayloadSize); truncateTC(dr.getMutableData(), dr.getMaximumSize(), dr.ids.qname.wirelength()); dnsdist::PacketMangling::editDNSHeaderFromPacket(dr.getMutableData(), [](dnsheader& header) { header.tc = true; return true; }); } else if (dr.getHeader()->tc && g_truncateTC) { truncateTC(response, dr.getMaximumSize(), dr.ids.qname.wirelength()); } /* when the answer is encrypted in place, we need to get a copy of the original header before encryption to fill the ring buffer */ dnsheader cleartextDH; memcpy(&cleartextDH, dr.getHeader().get(), sizeof(cleartextDH)); if (!isAsync) { if (!processResponse(response, respRuleActions, cacheInsertedRespRuleActions, dr, ids.cs && ids.cs->muted)) { return; } if (dr.isAsynchronous()) { return; } } ++dnsdist::metrics::g_stats.responses; if (ids.cs) { ++ids.cs->responses; } bool muted = true; if (ids.cs != nullptr && !ids.cs->muted && !ids.isXSK()) { sendUDPResponse(ids.cs->udpFD, response, dr.ids.delayMsec, ids.hopLocal, ids.hopRemote); muted = false; } if (!selfGenerated) { double udiff = ids.queryRealTime.udiff(); if (!muted) { vinfolog("Got answer from %s, relayed to %s (UDP), took %f us", ds->d_config.remote.toStringWithPort(), ids.origRemote.toStringWithPort(), udiff); } else { if (!ids.isXSK()) { vinfolog("Got answer from %s, NOT relayed to %s (UDP) since that frontend is muted, took %f us", ds->d_config.remote.toStringWithPort(), ids.origRemote.toStringWithPort(), udiff); } else { vinfolog("Got answer from %s, relayed to %s (UDP via XSK), took %f us", ds->d_config.remote.toStringWithPort(), ids.origRemote.toStringWithPort(), udiff); } } handleResponseSent(ids, udiff, dr.ids.origRemote, ds->d_config.remote, response.size(), cleartextDH, ds->getProtocol(), true); } else { handleResponseSent(ids, 0., dr.ids.origRemote, ComboAddress(), response.size(), cleartextDH, dnsdist::Protocol::DoUDP, false); } } bool processResponderPacket(std::shared_ptr& dss, PacketBuffer& response, const std::vector& localRespRuleActions, const std::vector& cacheInsertedRespRuleActions, InternalQueryState&& ids) { const dnsheader_aligned dnsHeader(response.data()); auto queryId = dnsHeader->id; if (!responseContentMatches(response, ids.qname, ids.qtype, ids.qclass, dss)) { dss->restoreState(queryId, std::move(ids)); return false; } auto dohUnit = std::move(ids.du); dnsdist::PacketMangling::editDNSHeaderFromPacket(response, [&ids](dnsheader& header) { header.id = ids.origID; return true; }); ++dss->responses; double udiff = ids.queryRealTime.udiff(); // do that _before_ the processing, otherwise it's not fair to the backend dss->latencyUsec = (127.0 * dss->latencyUsec / 128.0) + udiff / 128.0; dss->reportResponse(dnsHeader->rcode); /* don't call processResponse for DOH */ if (dohUnit) { #ifdef HAVE_DNS_OVER_HTTPS // DoH query, we cannot touch dohUnit after that DOHUnitInterface::handleUDPResponse(std::move(dohUnit), std::move(response), std::move(ids), dss); #endif return false; } handleResponseForUDPClient(ids, response, localRespRuleActions, cacheInsertedRespRuleActions, dss, false, false); return true; } // listens on a dedicated socket, lobs answers from downstream servers to original requestors void responderThread(std::shared_ptr dss) { try { setThreadName("dnsdist/respond"); auto localRespRuleActions = g_respruleactions.getLocal(); auto localCacheInsertedRespRuleActions = g_cacheInsertedRespRuleActions.getLocal(); const size_t initialBufferSize = getInitialUDPPacketBufferSize(false); /* allocate one more byte so we can detect truncation */ PacketBuffer response(initialBufferSize + 1); uint16_t queryId = 0; std::vector sockets; sockets.reserve(dss->sockets.size()); for (;;) { try { if (dss->isStopped()) { break; } if (!dss->connected) { /* the sockets are not connected yet, likely because we detected a problem, tried to reconnect and it failed. We will try to reconnect after the next successful health-check (unless reconnectOnUp is false), or when trying to send in the UDP listener thread, but until then we simply need to wait. */ dss->waitUntilConnected(); continue; } dss->pickSocketsReadyForReceiving(sockets); /* check a second time here because we might have waited quite a bit since the first check */ if (dss->isStopped()) { break; } for (const auto& fd : sockets) { /* allocate one more byte so we can detect truncation */ // NOLINTNEXTLINE(bugprone-use-after-move): resizing a vector has no preconditions so it is valid to do so after moving it response.resize(initialBufferSize + 1); ssize_t got = recv(fd, response.data(), response.size(), 0); if (got == 0 && dss->isStopped()) { break; } if (got < 0 || static_cast(got) < sizeof(dnsheader) || static_cast(got) == (initialBufferSize + 1)) { continue; } response.resize(static_cast(got)); const dnsheader_aligned dnsHeader(response.data()); queryId = dnsHeader->id; auto ids = dss->getState(queryId); if (!ids) { continue; } if (!ids->isXSK() && fd != ids->backendFD) { dss->restoreState(queryId, std::move(*ids)); continue; } if (processResponderPacket(dss, response, *localRespRuleActions, *localCacheInsertedRespRuleActions, std::move(*ids)) && ids->isXSK() && ids->cs->xskInfoResponder) { #ifdef HAVE_XSK auto& xskInfo = ids->cs->xskInfoResponder; auto xskPacket = xskInfo->getEmptyFrame(); if (!xskPacket) { continue; } xskPacket->setHeader(ids->xskPacketHeader); if (!xskPacket->setPayload(response)) { } if (ids->delayMsec > 0) { xskPacket->addDelay(ids->delayMsec); } xskPacket->updatePacket(); xskInfo->pushToSendQueue(*xskPacket); xskInfo->notifyXskSocket(); #endif /* HAVE_XSK */ } } } catch (const std::exception& e) { vinfolog("Got an error in UDP responder thread while parsing a response from %s, id %d: %s", dss->d_config.remote.toStringWithPort(), queryId, e.what()); } } } catch (const std::exception& e) { errlog("UDP responder thread died because of exception: %s", e.what()); } catch (const PDNSException& e) { errlog("UDP responder thread died because of PowerDNS exception: %s", e.reason); } catch (...) { errlog("UDP responder thread died because of an exception: %s", "unknown"); } } RecursiveLockGuarded g_lua{LuaContext()}; ComboAddress g_serverControl{"127.0.0.1:5199"}; static void spoofResponseFromString(DNSQuestion& dq, const string& spoofContent, bool raw) { string result; if (raw) { std::vector raws; stringtok(raws, spoofContent, ","); SpoofAction tempSpoofAction(raws, std::nullopt); tempSpoofAction(&dq, &result); } else { std::vector addrs; stringtok(addrs, spoofContent, " ,"); if (addrs.size() == 1) { try { ComboAddress spoofAddr(spoofContent); SpoofAction tempSpoofAction({spoofAddr}); tempSpoofAction(&dq, &result); } catch(const PDNSException &e) { DNSName cname(spoofContent); SpoofAction tempSpoofAction(cname); // CNAME then tempSpoofAction(&dq, &result); } } else { std::vector cas; for (const auto& addr : addrs) { try { cas.push_back(ComboAddress(addr)); } catch (...) { } } SpoofAction tempSpoofAction(cas); tempSpoofAction(&dq, &result); } } } static void spoofPacketFromString(DNSQuestion& dq, const string& spoofContent) { string result; SpoofAction tempSpoofAction(spoofContent.c_str(), spoofContent.size()); tempSpoofAction(&dq, &result); } bool processRulesResult(const DNSAction::Action& action, DNSQuestion& dq, std::string& ruleresult, bool& drop) { if (dq.isAsynchronous()) { return false; } auto setRCode = [&dq](uint8_t rcode) { dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [rcode](dnsheader& header) { header.rcode = rcode; header.qr = true; return true; }); }; switch (action) { case DNSAction::Action::Allow: return true; break; case DNSAction::Action::Drop: ++dnsdist::metrics::g_stats.ruleDrop; drop = true; return true; break; case DNSAction::Action::Nxdomain: setRCode(RCode::NXDomain); return true; break; case DNSAction::Action::Refused: setRCode(RCode::Refused); return true; break; case DNSAction::Action::ServFail: setRCode(RCode::ServFail); return true; break; case DNSAction::Action::Spoof: spoofResponseFromString(dq, ruleresult, false); return true; break; case DNSAction::Action::SpoofPacket: spoofPacketFromString(dq, ruleresult); return true; break; case DNSAction::Action::SpoofRaw: spoofResponseFromString(dq, ruleresult, true); return true; break; case DNSAction::Action::Truncate: if (!dq.overTCP()) { dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [](dnsheader& header) { header.tc = true; header.qr = true; header.ra = header.rd; header.aa = false; header.ad = false; return true; }); ++dnsdist::metrics::g_stats.ruleTruncated; return true; } break; case DNSAction::Action::HeaderModify: return true; break; case DNSAction::Action::Pool: /* we need to keep this because a custom Lua action can return DNSAction.Spoof, 'poolname' */ dq.ids.poolName = ruleresult; return true; break; case DNSAction::Action::NoRecurse: dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [](dnsheader& header) { header.rd = false; return true; }); return true; break; /* non-terminal actions follow */ case DNSAction::Action::Delay: pdns::checked_stoi_into(dq.ids.delayMsec, ruleresult); // sorry break; case DNSAction::Action::None: /* fall-through */ case DNSAction::Action::NoOp: break; } /* false means that we don't stop the processing */ return false; } static bool applyRulesToQuery(LocalHolders& holders, DNSQuestion& dq, const struct timespec& now) { if (g_rings.shouldRecordQueries()) { g_rings.insertQuery(now, dq.ids.origRemote, dq.ids.qname, dq.ids.qtype, dq.getData().size(), *dq.getHeader(), dq.getProtocol()); } if (g_qcount.enabled) { string qname = dq.ids.qname.toLogString(); bool countQuery{true}; if (g_qcount.filter) { auto lock = g_lua.lock(); std::tie (countQuery, qname) = g_qcount.filter(&dq); } if (countQuery) { auto records = g_qcount.records.write_lock(); if (!records->count(qname)) { (*records)[qname] = 0; } (*records)[qname]++; } } #ifndef DISABLE_DYNBLOCKS auto setRCode = [&dq](uint8_t rcode) { dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [rcode](dnsheader& header) { header.rcode = rcode; header.qr = true; return true; }); }; /* the Dynamic Block mechanism supports address and port ranges, so we need to pass the full address and port */ if (auto got = holders.dynNMGBlock->lookup(AddressAndPortRange(dq.ids.origRemote, dq.ids.origRemote.isIPv4() ? 32 : 128, 16))) { auto updateBlockStats = [&got]() { ++dnsdist::metrics::g_stats.dynBlocked; got->second.blocks++; }; if (now < got->second.until) { DNSAction::Action action = got->second.action; if (action == DNSAction::Action::None) { action = g_dynBlockAction; } switch (action) { case DNSAction::Action::NoOp: /* do nothing */ break; case DNSAction::Action::Nxdomain: vinfolog("Query from %s turned into NXDomain because of dynamic block", dq.ids.origRemote.toStringWithPort()); updateBlockStats(); setRCode(RCode::NXDomain); return true; case DNSAction::Action::Refused: vinfolog("Query from %s refused because of dynamic block", dq.ids.origRemote.toStringWithPort()); updateBlockStats(); setRCode(RCode::Refused); return true; case DNSAction::Action::Truncate: if (!dq.overTCP()) { updateBlockStats(); vinfolog("Query from %s truncated because of dynamic block", dq.ids.origRemote.toStringWithPort()); dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [](dnsheader& header) { header.tc = true; header.qr = true; header.ra = header.rd; header.aa = false; header.ad = false; return true; }); return true; } else { vinfolog("Query from %s for %s over TCP *not* truncated because of dynamic block", dq.ids.origRemote.toStringWithPort(), dq.ids.qname.toLogString()); } break; case DNSAction::Action::NoRecurse: updateBlockStats(); vinfolog("Query from %s setting rd=0 because of dynamic block", dq.ids.origRemote.toStringWithPort()); dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [](dnsheader& header) { header.rd = false; return true; }); return true; default: updateBlockStats(); vinfolog("Query from %s dropped because of dynamic block", dq.ids.origRemote.toStringWithPort()); return false; } } } if (auto got = holders.dynSMTBlock->lookup(dq.ids.qname)) { auto updateBlockStats = [&got]() { ++dnsdist::metrics::g_stats.dynBlocked; got->blocks++; }; if (now < got->until) { DNSAction::Action action = got->action; if (action == DNSAction::Action::None) { action = g_dynBlockAction; } switch (action) { case DNSAction::Action::NoOp: /* do nothing */ break; case DNSAction::Action::Nxdomain: vinfolog("Query from %s for %s turned into NXDomain because of dynamic block", dq.ids.origRemote.toStringWithPort(), dq.ids.qname.toLogString()); updateBlockStats(); setRCode(RCode::NXDomain); return true; case DNSAction::Action::Refused: vinfolog("Query from %s for %s refused because of dynamic block", dq.ids.origRemote.toStringWithPort(), dq.ids.qname.toLogString()); updateBlockStats(); setRCode(RCode::Refused); return true; case DNSAction::Action::Truncate: if (!dq.overTCP()) { updateBlockStats(); vinfolog("Query from %s for %s truncated because of dynamic block", dq.ids.origRemote.toStringWithPort(), dq.ids.qname.toLogString()); dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [](dnsheader& header) { header.tc = true; header.qr = true; header.ra = header.rd; header.aa = false; header.ad = false; return true; }); return true; } else { vinfolog("Query from %s for %s over TCP *not* truncated because of dynamic block", dq.ids.origRemote.toStringWithPort(), dq.ids.qname.toLogString()); } break; case DNSAction::Action::NoRecurse: updateBlockStats(); vinfolog("Query from %s setting rd=0 because of dynamic block", dq.ids.origRemote.toStringWithPort()); dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [](dnsheader& header) { header.rd = false; return true; }); return true; default: updateBlockStats(); vinfolog("Query from %s for %s dropped because of dynamic block", dq.ids.origRemote.toStringWithPort(), dq.ids.qname.toLogString()); return false; } } } #endif /* DISABLE_DYNBLOCKS */ DNSAction::Action action = DNSAction::Action::None; string ruleresult; bool drop = false; for (const auto& lr : *holders.ruleactions) { if (lr.d_rule->matches(&dq)) { lr.d_rule->d_matches++; action = (*lr.d_action)(&dq, &ruleresult); if (processRulesResult(action, dq, ruleresult, drop)) { break; } } } if (drop) { return false; } return true; } ssize_t udpClientSendRequestToBackend(const std::shared_ptr& backend, const int socketDesc, const PacketBuffer& request, bool healthCheck) { ssize_t result; if (backend->d_config.sourceItf == 0) { result = send(socketDesc, request.data(), request.size(), 0); } else { struct msghdr msgh; struct iovec iov; cmsgbuf_aligned cbuf; ComboAddress remote(backend->d_config.remote); fillMSGHdr(&msgh, &iov, &cbuf, sizeof(cbuf), const_cast(reinterpret_cast(request.data())), request.size(), &remote); addCMsgSrcAddr(&msgh, &cbuf, &backend->d_config.sourceAddr, static_cast(backend->d_config.sourceItf)); result = sendmsg(socketDesc, &msgh, 0); } if (result == -1) { int savederrno = errno; vinfolog("Error sending request to backend %s: %s", backend->d_config.remote.toStringWithPort(), stringerror(savederrno)); /* This might sound silly, but on Linux send() might fail with EINVAL if the interface the socket was bound to doesn't exist anymore. We don't want to reconnect the real socket if the healthcheck failed, because it's not using the same socket. */ if (!healthCheck) { if (savederrno == EINVAL || savederrno == ENODEV || savederrno == ENETUNREACH || savederrno == EHOSTUNREACH || savederrno == EBADF) { backend->reconnect(); } backend->reportTimeoutOrError(); } } return result; } static bool isUDPQueryAcceptable(ClientState& cs, LocalHolders& holders, const struct msghdr* msgh, const ComboAddress& remote, ComboAddress& dest, bool& expectProxyProtocol) { if (msgh->msg_flags & MSG_TRUNC) { /* message was too large for our buffer */ vinfolog("Dropping message too large for our buffer"); ++cs.nonCompliantQueries; ++dnsdist::metrics::g_stats.nonCompliantQueries; return false; } expectProxyProtocol = cs.d_enableProxyProtocol && expectProxyProtocolFrom(remote); if (!holders.acl->match(remote) && !expectProxyProtocol) { vinfolog("Query from %s dropped because of ACL", remote.toStringWithPort()); ++dnsdist::metrics::g_stats.aclDrops; return false; } if (HarvestDestinationAddress(msgh, &dest)) { /* so it turns out that sometimes the kernel lies to us: the address is set to 0.0.0.0:0 which makes our sendfromto() use the wrong address. In that case it's better to let the kernel do the work by itself and use sendto() instead. This is indicated by setting the family to 0 which is acted upon in sendUDPResponse() and DelayedPacket::(). */ const ComboAddress bogusV4("0.0.0.0:0"); const ComboAddress bogusV6("[::]:0"); if (dest.sin4.sin_family == AF_INET && dest == bogusV4) { dest.sin4.sin_family = 0; } else if (dest.sin4.sin_family == AF_INET6 && dest == bogusV6) { dest.sin4.sin_family = 0; } else { /* we don't get the port, only the address */ dest.sin4.sin_port = cs.local.sin4.sin_port; } } else { dest.sin4.sin_family = 0; } ++cs.queries; ++dnsdist::metrics::g_stats.queries; return true; } bool checkDNSCryptQuery(const ClientState& cs, PacketBuffer& query, std::unique_ptr& dnsCryptQuery, time_t now, bool tcp) { if (cs.dnscryptCtx) { #ifdef HAVE_DNSCRYPT PacketBuffer response; dnsCryptQuery = std::make_unique(cs.dnscryptCtx); bool decrypted = handleDNSCryptQuery(query, *dnsCryptQuery, tcp, now, response); if (!decrypted) { if (response.size() > 0) { query = std::move(response); return true; } throw std::runtime_error("Unable to decrypt DNSCrypt query, dropping."); } #endif /* HAVE_DNSCRYPT */ } return false; } bool checkQueryHeaders(const struct dnsheader& dnsHeader, ClientState& clientState) { if (dnsHeader.qr) { // don't respond to responses ++dnsdist::metrics::g_stats.nonCompliantQueries; ++clientState.nonCompliantQueries; return false; } if (dnsHeader.qdcount == 0) { ++dnsdist::metrics::g_stats.emptyQueries; if (g_dropEmptyQueries) { return false; } } if (dnsHeader.rd) { ++dnsdist::metrics::g_stats.rdQueries; } return true; } #ifndef DISABLE_RECVMMSG #if defined(HAVE_RECVMMSG) && defined(HAVE_SENDMMSG) && defined(MSG_WAITFORONE) static void queueResponse(const ClientState& cs, const PacketBuffer& response, const ComboAddress& dest, const ComboAddress& remote, struct mmsghdr& outMsg, struct iovec* iov, cmsgbuf_aligned* cbuf) { outMsg.msg_len = 0; fillMSGHdr(&outMsg.msg_hdr, iov, nullptr, 0, const_cast(reinterpret_cast(&response.at(0))), response.size(), const_cast(&remote)); if (dest.sin4.sin_family == 0) { outMsg.msg_hdr.msg_control = nullptr; } else { addCMsgSrcAddr(&outMsg.msg_hdr, cbuf, &dest, 0); } } #endif /* defined(HAVE_RECVMMSG) && defined(HAVE_SENDMMSG) && defined(MSG_WAITFORONE) */ #endif /* DISABLE_RECVMMSG */ /* self-generated responses or cache hits */ static bool prepareOutgoingResponse(LocalHolders& holders, const ClientState& cs, DNSQuestion& dq, bool cacheHit) { std::shared_ptr ds{nullptr}; DNSResponse dr(dq.ids, dq.getMutableData(), ds); dr.d_incomingTCPState = dq.d_incomingTCPState; dr.ids.selfGenerated = true; if (!applyRulesToResponse(cacheHit ? *holders.cacheHitRespRuleactions : *holders.selfAnsweredRespRuleactions, dr)) { return false; } if (dr.ids.ttlCap > 0) { std::string result; LimitTTLResponseAction ac(0, dr.ids.ttlCap, {}); ac(&dr, &result); } if (dr.ids.d_extendedError) { dnsdist::edns::addExtendedDNSError(dr.getMutableData(), dr.getMaximumSize(), dr.ids.d_extendedError->infoCode, dr.ids.d_extendedError->extraText); } if (cacheHit) { ++dnsdist::metrics::g_stats.cacheHits; } if (dr.isAsynchronous()) { return false; } #ifdef HAVE_DNSCRYPT if (!cs.muted) { if (!encryptResponse(dq.getMutableData(), dq.getMaximumSize(), dq.overTCP(), dq.ids.dnsCryptQuery)) { return false; } } #endif /* HAVE_DNSCRYPT */ return true; } ProcessQueryResult processQueryAfterRules(DNSQuestion& dq, LocalHolders& holders, std::shared_ptr& selectedBackend) { const uint16_t queryId = ntohs(dq.getHeader()->id); try { if (dq.getHeader()->qr) { // something turned it into a response fixUpQueryTurnedResponse(dq, dq.ids.origFlags); if (!prepareOutgoingResponse(holders, *dq.ids.cs, dq, false)) { return ProcessQueryResult::Drop; } const auto rcode = dq.getHeader()->rcode; if (rcode == RCode::NXDomain) { ++dnsdist::metrics::g_stats.ruleNXDomain; } else if (rcode == RCode::Refused) { ++dnsdist::metrics::g_stats.ruleRefused; } else if (rcode == RCode::ServFail) { ++dnsdist::metrics::g_stats.ruleServFail; } ++dnsdist::metrics::g_stats.selfAnswered; ++dq.ids.cs->responses; return ProcessQueryResult::SendAnswer; } std::shared_ptr serverPool = getPool(*holders.pools, dq.ids.poolName); std::shared_ptr poolPolicy = serverPool->policy; dq.ids.packetCache = serverPool->packetCache; const auto& policy = poolPolicy != nullptr ? *poolPolicy : *(holders.policy); const auto servers = serverPool->getServers(); selectedBackend = policy.getSelectedBackend(*servers, dq); uint32_t allowExpired = selectedBackend ? 0 : g_staleCacheEntriesTTL; if (dq.ids.packetCache && !dq.ids.skipCache) { dq.ids.dnssecOK = (getEDNSZ(dq) & EDNS_HEADER_FLAG_DO); } if (dq.useECS && ((selectedBackend && selectedBackend->d_config.useECS) || (!selectedBackend && serverPool->getECS()))) { // we special case our cache in case a downstream explicitly gave us a universally valid response with a 0 scope // we need ECS parsing (parseECS) to be true so we can be sure that the initial incoming query did not have an existing // ECS option, which would make it unsuitable for the zero-scope feature. if (dq.ids.packetCache && !dq.ids.skipCache && (!selectedBackend || !selectedBackend->d_config.disableZeroScope) && dq.ids.packetCache->isECSParsingEnabled()) { if (dq.ids.packetCache->get(dq, dq.getHeader()->id, &dq.ids.cacheKeyNoECS, dq.ids.subnet, dq.ids.dnssecOK, !dq.overTCP(), allowExpired, false, true, false)) { vinfolog("Packet cache hit for query for %s|%s from %s (%s, %d bytes)", dq.ids.qname.toLogString(), QType(dq.ids.qtype).toString(), dq.ids.origRemote.toStringWithPort(), dq.ids.protocol.toString(), dq.getData().size()); if (!prepareOutgoingResponse(holders, *dq.ids.cs, dq, true)) { return ProcessQueryResult::Drop; } ++dnsdist::metrics::g_stats.responses; ++dq.ids.cs->responses; return ProcessQueryResult::SendAnswer; } if (!dq.ids.subnet) { /* there was no existing ECS on the query, enable the zero-scope feature */ dq.ids.useZeroScope = true; } } if (!handleEDNSClientSubnet(dq, dq.ids.ednsAdded, dq.ids.ecsAdded)) { vinfolog("Dropping query from %s because we couldn't insert the ECS value", dq.ids.origRemote.toStringWithPort()); return ProcessQueryResult::Drop; } } if (dq.ids.packetCache && !dq.ids.skipCache) { bool forwardedOverUDP = !dq.overTCP(); if (selectedBackend && selectedBackend->isTCPOnly()) { forwardedOverUDP = false; } /* we do not record a miss for queries received over DoH and forwarded over TCP yet, as we will do a second-lookup */ if (dq.ids.packetCache->get(dq, dq.getHeader()->id, &dq.ids.cacheKey, dq.ids.subnet, dq.ids.dnssecOK, forwardedOverUDP, allowExpired, false, true, dq.ids.protocol != dnsdist::Protocol::DoH || forwardedOverUDP)) { dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [flags=dq.ids.origFlags](dnsheader& header) { restoreFlags(&header, flags); return true; }); vinfolog("Packet cache hit for query for %s|%s from %s (%s, %d bytes)", dq.ids.qname.toLogString(), QType(dq.ids.qtype).toString(), dq.ids.origRemote.toStringWithPort(), dq.ids.protocol.toString(), dq.getData().size()); if (!prepareOutgoingResponse(holders, *dq.ids.cs, dq, true)) { return ProcessQueryResult::Drop; } ++dnsdist::metrics::g_stats.responses; ++dq.ids.cs->responses; return ProcessQueryResult::SendAnswer; } else if (dq.ids.protocol == dnsdist::Protocol::DoH && !forwardedOverUDP) { /* do a second-lookup for UDP responses, but we do not want TC=1 answers */ if (dq.ids.packetCache->get(dq, dq.getHeader()->id, &dq.ids.cacheKeyUDP, dq.ids.subnet, dq.ids.dnssecOK, true, allowExpired, false, false, true)) { if (!prepareOutgoingResponse(holders, *dq.ids.cs, dq, true)) { return ProcessQueryResult::Drop; } ++dnsdist::metrics::g_stats.responses; ++dq.ids.cs->responses; return ProcessQueryResult::SendAnswer; } } vinfolog("Packet cache miss for query for %s|%s from %s (%s, %d bytes)", dq.ids.qname.toLogString(), QType(dq.ids.qtype).toString(), dq.ids.origRemote.toStringWithPort(), dq.ids.protocol.toString(), dq.getData().size()); ++dnsdist::metrics::g_stats.cacheMisses; } if (!selectedBackend) { ++dnsdist::metrics::g_stats.noPolicy; vinfolog("%s query for %s|%s from %s, no downstream server available", g_servFailOnNoPolicy ? "ServFailed" : "Dropped", dq.ids.qname.toLogString(), QType(dq.ids.qtype).toString(), dq.ids.origRemote.toStringWithPort()); if (g_servFailOnNoPolicy) { dnsdist::PacketMangling::editDNSHeaderFromPacket(dq.getMutableData(), [](dnsheader& header) { header.rcode = RCode::ServFail; header.qr = true; return true; }); fixUpQueryTurnedResponse(dq, dq.ids.origFlags); if (!prepareOutgoingResponse(holders, *dq.ids.cs, dq, false)) { return ProcessQueryResult::Drop; } ++dnsdist::metrics::g_stats.responses; ++dq.ids.cs->responses; // no response-only statistics counter to update. return ProcessQueryResult::SendAnswer; } return ProcessQueryResult::Drop; } /* save the DNS flags as sent to the backend so we can cache the answer with the right flags later */ dq.ids.cacheFlags = *getFlagsFromDNSHeader(dq.getHeader().get()); if (dq.addXPF && selectedBackend->d_config.xpfRRCode != 0) { addXPF(dq, selectedBackend->d_config.xpfRRCode); } if (selectedBackend->d_config.useProxyProtocol && dq.getProtocol().isEncrypted() && selectedBackend->d_config.d_proxyProtocolAdvertiseTLS) { if (!dq.proxyProtocolValues) { dq.proxyProtocolValues = std::make_unique>(); } dq.proxyProtocolValues->push_back(ProxyProtocolValue{"", static_cast(ProxyProtocolValue::Types::PP_TLV_SSL)}); } selectedBackend->incQueriesCount(); return ProcessQueryResult::PassToBackend; } catch (const std::exception& e){ vinfolog("Got an error while parsing a %s query (after applying rules) from %s, id %d: %s", (dq.overTCP() ? "TCP" : "UDP"), dq.ids.origRemote.toStringWithPort(), queryId, e.what()); } return ProcessQueryResult::Drop; } class UDPTCPCrossQuerySender : public TCPQuerySender { public: UDPTCPCrossQuerySender() { } ~UDPTCPCrossQuerySender() { } bool active() const override { return true; } void handleResponse(const struct timeval& now, TCPResponse&& response) override { if (!response.d_ds && !response.d_idstate.selfGenerated) { throw std::runtime_error("Passing a cross-protocol answer originated from UDP without a valid downstream"); } auto& ids = response.d_idstate; static thread_local LocalStateHolder> localRespRuleActions = g_respruleactions.getLocal(); static thread_local LocalStateHolder> localCacheInsertedRespRuleActions = g_cacheInsertedRespRuleActions.getLocal(); handleResponseForUDPClient(ids, response.d_buffer, *localRespRuleActions, *localCacheInsertedRespRuleActions, response.d_ds, response.isAsync(), response.d_idstate.selfGenerated); } void handleXFRResponse(const struct timeval& now, TCPResponse&& response) override { return handleResponse(now, std::move(response)); } void notifyIOError(const struct timeval&, TCPResponse&&) override { // nothing to do } }; class UDPCrossProtocolQuery : public CrossProtocolQuery { public: UDPCrossProtocolQuery(PacketBuffer&& buffer_, InternalQueryState&& ids_, std::shared_ptr ds): CrossProtocolQuery(InternalQuery(std::move(buffer_), std::move(ids_)), ds) { auto& ids = query.d_idstate; const auto& buffer = query.d_buffer; if (ids.udpPayloadSize == 0) { uint16_t z = 0; getEDNSUDPPayloadSizeAndZ(reinterpret_cast(buffer.data()), buffer.size(), &ids.udpPayloadSize, &z); if (ids.udpPayloadSize < 512) { ids.udpPayloadSize = 512; } } } ~UDPCrossProtocolQuery() { } std::shared_ptr getTCPQuerySender() override { return s_sender; } private: static std::shared_ptr s_sender; }; std::shared_ptr UDPCrossProtocolQuery::s_sender = std::make_shared(); std::unique_ptr getUDPCrossProtocolQueryFromDQ(DNSQuestion& dq); std::unique_ptr getUDPCrossProtocolQueryFromDQ(DNSQuestion& dq) { dq.ids.origID = dq.getHeader()->id; return std::make_unique(std::move(dq.getMutableData()), std::move(dq.ids), nullptr); } ProcessQueryResult processQuery(DNSQuestion& dq, LocalHolders& holders, std::shared_ptr& selectedBackend) { const uint16_t queryId = ntohs(dq.getHeader()->id); try { /* we need an accurate ("real") value for the response and to store into the IDS, but not for insertion into the rings for example */ timespec now{}; gettime(&now); if ((dq.ids.qtype == QType::AXFR || dq.ids.qtype == QType::IXFR) && (dq.getProtocol() == dnsdist::Protocol::DoH || dq.getProtocol() == dnsdist::Protocol::DoQ || dq.getProtocol() == dnsdist::Protocol::DoH3)) { dq.editHeader([](dnsheader& header) { header.rcode = RCode::NotImp; header.qr = true; return true; }); return processQueryAfterRules(dq, holders, selectedBackend); } if (!applyRulesToQuery(holders, dq, now)) { return ProcessQueryResult::Drop; } if (dq.isAsynchronous()) { return ProcessQueryResult::Asynchronous; } return processQueryAfterRules(dq, holders, selectedBackend); } catch (const std::exception& e){ vinfolog("Got an error while parsing a %s query from %s, id %d: %s", (dq.overTCP() ? "TCP" : "UDP"), dq.ids.origRemote.toStringWithPort(), queryId, e.what()); } return ProcessQueryResult::Drop; } bool assignOutgoingUDPQueryToBackend(std::shared_ptr& downstream, uint16_t queryID, DNSQuestion& dnsQuestion, PacketBuffer& query, bool actuallySend) { bool doh = dnsQuestion.ids.du != nullptr; bool failed = false; if (downstream->d_config.useProxyProtocol) { try { addProxyProtocol(dnsQuestion, &dnsQuestion.ids.d_proxyProtocolPayloadSize); } catch (const std::exception& e) { vinfolog("Adding proxy protocol payload to %s query from %s failed: %s", (dnsQuestion.ids.du ? "DoH" : ""), dnsQuestion.ids.origDest.toStringWithPort(), e.what()); return false; } } if (doh && !dnsQuestion.ids.d_packet) { dnsQuestion.ids.d_packet = std::make_unique(query); } try { int descriptor = downstream->pickSocketForSending(); if (actuallySend) { dnsQuestion.ids.backendFD = descriptor; } dnsQuestion.ids.origID = queryID; dnsQuestion.ids.forwardedOverUDP = true; vinfolog("Got query for %s|%s from %s%s, relayed to %s%s", dnsQuestion.ids.qname.toLogString(), QType(dnsQuestion.ids.qtype).toString(), dnsQuestion.ids.origRemote.toStringWithPort(), (doh ? " (https)" : ""), downstream->getNameWithAddr(), actuallySend ? "" : " (xsk)"); /* make a copy since we cannot touch dnsQuestion.ids after the move */ auto proxyProtocolPayloadSize = dnsQuestion.ids.d_proxyProtocolPayloadSize; auto idOffset = downstream->saveState(std::move(dnsQuestion.ids)); /* set the correct ID */ memcpy(&query.at(proxyProtocolPayloadSize), &idOffset, sizeof(idOffset)); if (!actuallySend) { return true; } /* you can't touch ids or du after this line, unless the call returned a non-negative value, because it might already have been freed */ ssize_t ret = udpClientSendRequestToBackend(downstream, descriptor, query); if (ret < 0) { failed = true; } if (failed) { /* clear up the state. In the very unlikely event it was reused in the meantime, so be it. */ auto cleared = downstream->getState(idOffset); if (cleared) { dnsQuestion.ids.du = std::move(cleared->du); } ++dnsdist::metrics::g_stats.downstreamSendErrors; ++downstream->sendErrors; return false; } } catch (const std::exception& e) { throw; } return true; } static void processUDPQuery(ClientState& cs, LocalHolders& holders, const struct msghdr* msgh, const ComboAddress& remote, ComboAddress& dest, PacketBuffer& query, struct mmsghdr* responsesVect, unsigned int* queuedResponses, struct iovec* respIOV, cmsgbuf_aligned* respCBuf) { assert(responsesVect == nullptr || (queuedResponses != nullptr && respIOV != nullptr && respCBuf != nullptr)); uint16_t queryId = 0; InternalQueryState ids; ids.cs = &cs; ids.origRemote = remote; ids.hopRemote = remote; ids.protocol = dnsdist::Protocol::DoUDP; try { bool expectProxyProtocol = false; if (!isUDPQueryAcceptable(cs, holders, msgh, remote, dest, expectProxyProtocol)) { return; } /* dest might have been updated, if we managed to harvest the destination address */ if (dest.sin4.sin_family != 0) { ids.origDest = dest; ids.hopLocal = dest; } else { /* if we have not been able to harvest the destination address, we do NOT want to update dest or hopLocal, to let the kernel pick the less terrible option, but we want to update origDest which is used by rules and actions to at least the correct address family */ ids.origDest = cs.local; ids.hopLocal.sin4.sin_family = 0; } std::vector proxyProtocolValues; if (expectProxyProtocol && !handleProxyProtocol(remote, false, *holders.acl, query, ids.origRemote, ids.origDest, proxyProtocolValues)) { return; } ids.queryRealTime.start(); auto dnsCryptResponse = checkDNSCryptQuery(cs, query, ids.dnsCryptQuery, ids.queryRealTime.d_start.tv_sec, false); if (dnsCryptResponse) { sendUDPResponse(cs.udpFD, query, 0, dest, remote); return; } { /* this pointer will be invalidated the second the buffer is resized, don't hold onto it! */ const dnsheader_aligned dnsHeader(query.data()); queryId = ntohs(dnsHeader->id); if (!checkQueryHeaders(*dnsHeader, cs)) { return; } if (dnsHeader->qdcount == 0) { dnsdist::PacketMangling::editDNSHeaderFromPacket(query, [](dnsheader& header) { header.rcode = RCode::NotImp; header.qr = true; return true; }); sendUDPResponse(cs.udpFD, query, 0, dest, remote); return; } } ids.qname = DNSName(reinterpret_cast(query.data()), query.size(), sizeof(dnsheader), false, &ids.qtype, &ids.qclass); if (ids.dnsCryptQuery) { ids.protocol = dnsdist::Protocol::DNSCryptUDP; } DNSQuestion dq(ids, query); const uint16_t* flags = getFlagsFromDNSHeader(dq.getHeader().get()); ids.origFlags = *flags; if (!proxyProtocolValues.empty()) { dq.proxyProtocolValues = make_unique>(std::move(proxyProtocolValues)); } std::shared_ptr ss{nullptr}; auto result = processQuery(dq, holders, ss); if (result == ProcessQueryResult::Drop || result == ProcessQueryResult::Asynchronous) { return; } // the buffer might have been invalidated by now (resized) const auto dh = dq.getHeader(); if (result == ProcessQueryResult::SendAnswer) { #ifndef DISABLE_RECVMMSG #if defined(HAVE_RECVMMSG) && defined(HAVE_SENDMMSG) && defined(MSG_WAITFORONE) if (dq.ids.delayMsec == 0 && responsesVect != nullptr) { queueResponse(cs, query, dest, remote, responsesVect[*queuedResponses], respIOV, respCBuf); (*queuedResponses)++; handleResponseSent(dq.ids.qname, dq.ids.qtype, 0., remote, ComboAddress(), query.size(), *dh, dnsdist::Protocol::DoUDP, dnsdist::Protocol::DoUDP, false); return; } #endif /* defined(HAVE_RECVMMSG) && defined(HAVE_SENDMMSG) && defined(MSG_WAITFORONE) */ #endif /* DISABLE_RECVMMSG */ /* we use dest, always, because we don't want to use the listening address to send a response since it could be 0.0.0.0 */ sendUDPResponse(cs.udpFD, query, dq.ids.delayMsec, dest, remote); handleResponseSent(dq.ids.qname, dq.ids.qtype, 0., remote, ComboAddress(), query.size(), *dh, dnsdist::Protocol::DoUDP, dnsdist::Protocol::DoUDP, false); return; } if (result != ProcessQueryResult::PassToBackend || ss == nullptr) { return; } if (ss->isTCPOnly()) { std::string proxyProtocolPayload; /* we need to do this _before_ creating the cross protocol query because after that the buffer will have been moved */ if (ss->d_config.useProxyProtocol) { proxyProtocolPayload = getProxyProtocolPayload(dq); } ids.origID = dh->id; auto cpq = std::make_unique(std::move(query), std::move(ids), ss); cpq->query.d_proxyProtocolPayload = std::move(proxyProtocolPayload); ss->passCrossProtocolQuery(std::move(cpq)); return; } assignOutgoingUDPQueryToBackend(ss, dh->id, dq, query); } catch(const std::exception& e){ vinfolog("Got an error in UDP question thread while parsing a query from %s, id %d: %s", ids.origRemote.toStringWithPort(), queryId, e.what()); } } #ifdef HAVE_XSK namespace dnsdist::xsk { bool XskProcessQuery(ClientState& cs, LocalHolders& holders, XskPacket& packet) { uint16_t queryId = 0; const auto& remote = packet.getFromAddr(); const auto& dest = packet.getToAddr(); InternalQueryState ids; ids.cs = &cs; ids.origRemote = remote; ids.hopRemote = remote; ids.origDest = dest; ids.hopLocal = dest; ids.protocol = dnsdist::Protocol::DoUDP; ids.xskPacketHeader = packet.cloneHeaderToPacketBuffer(); try { bool expectProxyProtocol = false; if (!XskIsQueryAcceptable(packet, cs, holders, expectProxyProtocol)) { return false; } auto query = packet.clonePacketBuffer(); std::vector proxyProtocolValues; if (expectProxyProtocol && !handleProxyProtocol(remote, false, *holders.acl, query, ids.origRemote, ids.origDest, proxyProtocolValues)) { return false; } ids.queryRealTime.start(); auto dnsCryptResponse = checkDNSCryptQuery(cs, query, ids.dnsCryptQuery, ids.queryRealTime.d_start.tv_sec, false); if (dnsCryptResponse) { packet.setPayload(query); return true; } { /* this pointer will be invalidated the second the buffer is resized, don't hold onto it! */ dnsheader_aligned dnsHeader(query.data()); queryId = ntohs(dnsHeader->id); if (!checkQueryHeaders(*dnsHeader.get(), cs)) { return false; } if (dnsHeader->qdcount == 0) { dnsdist::PacketMangling::editDNSHeaderFromPacket(query, [](dnsheader& header) { header.rcode = RCode::NotImp; header.qr = true; return true; }); packet.setPayload(query); return true; } } ids.qname = DNSName(reinterpret_cast(query.data()), query.size(), sizeof(dnsheader), false, &ids.qtype, &ids.qclass); if (ids.origDest.sin4.sin_family == 0) { ids.origDest = cs.local; } if (ids.dnsCryptQuery) { ids.protocol = dnsdist::Protocol::DNSCryptUDP; } DNSQuestion dq(ids, query); if (!proxyProtocolValues.empty()) { dq.proxyProtocolValues = make_unique>(std::move(proxyProtocolValues)); } std::shared_ptr ss{nullptr}; auto result = processQuery(dq, holders, ss); if (result == ProcessQueryResult::Drop) { return false; } if (result == ProcessQueryResult::SendAnswer) { packet.setPayload(query); if (dq.ids.delayMsec > 0) { packet.addDelay(dq.ids.delayMsec); } const auto dh = dq.getHeader(); handleResponseSent(ids.qname, ids.qtype, 0., remote, ComboAddress(), query.size(), *dh, dnsdist::Protocol::DoUDP, dnsdist::Protocol::DoUDP, false); return true; } if (result != ProcessQueryResult::PassToBackend || ss == nullptr) { return false; } // the buffer might have been invalidated by now (resized) const auto dh = dq.getHeader(); if (ss->isTCPOnly()) { std::string proxyProtocolPayload; /* we need to do this _before_ creating the cross protocol query because after that the buffer will have been moved */ if (ss->d_config.useProxyProtocol) { proxyProtocolPayload = getProxyProtocolPayload(dq); } ids.origID = dh->id; auto cpq = std::make_unique(std::move(query), std::move(ids), ss); cpq->query.d_proxyProtocolPayload = std::move(proxyProtocolPayload); ss->passCrossProtocolQuery(std::move(cpq)); return false; } if (ss->d_xskInfos.empty()) { assignOutgoingUDPQueryToBackend(ss, dh->id, dq, query, true); return false; } else { assignOutgoingUDPQueryToBackend(ss, dh->id, dq, query, false); auto sourceAddr = ss->pickSourceAddressForSending(); packet.setAddr(sourceAddr, ss->d_config.sourceMACAddr, ss->d_config.remote, ss->d_config.destMACAddr); packet.setPayload(query); packet.rewrite(); return true; } } catch (const std::exception& e) { vinfolog("Got an error in UDP question thread while parsing a query from %s, id %d: %s", remote.toStringWithPort(), queryId, e.what()); } return false; } } #endif /* HAVE_XSK */ #ifndef DISABLE_RECVMMSG #if defined(HAVE_RECVMMSG) && defined(HAVE_SENDMMSG) && defined(MSG_WAITFORONE) static void MultipleMessagesUDPClientThread(ClientState* cs, LocalHolders& holders) { struct MMReceiver { PacketBuffer packet; ComboAddress remote; ComboAddress dest; struct iovec iov; /* used by HarvestDestinationAddress */ cmsgbuf_aligned cbuf; }; const size_t vectSize = g_udpVectorSize; if (vectSize > std::numeric_limits::max()) { throw std::runtime_error("The value of setUDPMultipleMessagesVectorSize is too high, the maximum value is " + std::to_string(std::numeric_limits::max())); } auto recvData = std::make_unique(vectSize); auto msgVec = std::make_unique(vectSize); auto outMsgVec = std::make_unique(vectSize); /* the actual buffer is larger because: - we may have to add EDNS and/or ECS - we use it for self-generated responses (from rule or cache) but we only accept incoming payloads up to that size */ const size_t initialBufferSize = getInitialUDPPacketBufferSize(cs->d_enableProxyProtocol); const size_t maxIncomingPacketSize = getMaximumIncomingPacketSize(*cs); /* initialize the structures needed to receive our messages */ for (size_t idx = 0; idx < vectSize; idx++) { recvData[idx].remote.sin4.sin_family = cs->local.sin4.sin_family; recvData[idx].packet.resize(initialBufferSize); fillMSGHdr(&msgVec[idx].msg_hdr, &recvData[idx].iov, &recvData[idx].cbuf, sizeof(recvData[idx].cbuf), reinterpret_cast(&recvData[idx].packet.at(0)), maxIncomingPacketSize, &recvData[idx].remote); } /* go now */ for(;;) { /* reset the IO vector, since it's also used to send the vector of responses to avoid having to copy the data around */ for (size_t idx = 0; idx < vectSize; idx++) { recvData[idx].packet.resize(initialBufferSize); recvData[idx].iov.iov_base = &recvData[idx].packet.at(0); recvData[idx].iov.iov_len = recvData[idx].packet.size(); } /* block until we have at least one message ready, but return as many as possible to save the syscall costs */ int msgsGot = recvmmsg(cs->udpFD, msgVec.get(), vectSize, MSG_WAITFORONE | MSG_TRUNC, nullptr); if (msgsGot <= 0) { vinfolog("Getting UDP messages via recvmmsg() failed with: %s", stringerror()); continue; } unsigned int msgsToSend = 0; /* process the received messages */ for (int msgIdx = 0; msgIdx < msgsGot; msgIdx++) { const struct msghdr* msgh = &msgVec[msgIdx].msg_hdr; unsigned int got = msgVec[msgIdx].msg_len; const ComboAddress& remote = recvData[msgIdx].remote; if (static_cast(got) < sizeof(struct dnsheader)) { ++dnsdist::metrics::g_stats.nonCompliantQueries; ++cs->nonCompliantQueries; continue; } recvData[msgIdx].packet.resize(got); processUDPQuery(*cs, holders, msgh, remote, recvData[msgIdx].dest, recvData[msgIdx].packet, outMsgVec.get(), &msgsToSend, &recvData[msgIdx].iov, &recvData[msgIdx].cbuf); } /* immediate (not delayed or sent to a backend) responses (mostly from a rule, dynamic block or the cache) can be sent in batch too */ if (msgsToSend > 0 && msgsToSend <= static_cast(msgsGot)) { int sent = sendmmsg(cs->udpFD, outMsgVec.get(), msgsToSend, 0); if (sent < 0 || static_cast(sent) != msgsToSend) { vinfolog("Error sending responses with sendmmsg() (%d on %u): %s", sent, msgsToSend, stringerror()); } } } } #endif /* defined(HAVE_RECVMMSG) && defined(HAVE_SENDMMSG) && defined(MSG_WAITFORONE) */ #endif /* DISABLE_RECVMMSG */ // listens to incoming queries, sends out to downstream servers, noting the intended return path static void udpClientThread(std::vector states) { try { setThreadName("dnsdist/udpClie"); LocalHolders holders; #ifndef DISABLE_RECVMMSG #if defined(HAVE_RECVMMSG) && defined(HAVE_SENDMMSG) && defined(MSG_WAITFORONE) if (g_udpVectorSize > 1) { MultipleMessagesUDPClientThread(states.at(0), holders); } else #endif /* defined(HAVE_RECVMMSG) && defined(HAVE_SENDMMSG) && defined(MSG_WAITFORONE) */ #endif /* DISABLE_RECVMMSG */ { /* the actual buffer is larger because: - we may have to add EDNS and/or ECS - we use it for self-generated responses (from rule or cache) but we only accept incoming payloads up to that size */ struct UDPStateParam { ClientState* cs{nullptr}; size_t maxIncomingPacketSize{0}; int socket{-1}; }; const size_t initialBufferSize = getInitialUDPPacketBufferSize(true); PacketBuffer packet(initialBufferSize); struct msghdr msgh; struct iovec iov; ComboAddress remote; ComboAddress dest; auto handleOnePacket = [&packet, &iov, &holders, &msgh, &remote, &dest, initialBufferSize](const UDPStateParam& param) { packet.resize(initialBufferSize); iov.iov_base = &packet.at(0); iov.iov_len = packet.size(); ssize_t got = recvmsg(param.socket, &msgh, 0); if (got < 0 || static_cast(got) < sizeof(struct dnsheader)) { ++dnsdist::metrics::g_stats.nonCompliantQueries; ++param.cs->nonCompliantQueries; return; } packet.resize(static_cast(got)); processUDPQuery(*param.cs, holders, &msgh, remote, dest, packet, nullptr, nullptr, nullptr, nullptr); }; std::vector params; for (auto& state : states) { const size_t maxIncomingPacketSize = getMaximumIncomingPacketSize(*state); params.emplace_back(UDPStateParam{state, maxIncomingPacketSize, state->udpFD}); } if (params.size() == 1) { const auto& param = params.at(0); remote.sin4.sin_family = param.cs->local.sin4.sin_family; /* used by HarvestDestinationAddress */ cmsgbuf_aligned cbuf; fillMSGHdr(&msgh, &iov, &cbuf, sizeof(cbuf), reinterpret_cast(&packet.at(0)), param.maxIncomingPacketSize, &remote); while (true) { try { handleOnePacket(param); } catch (const std::bad_alloc& e) { /* most exceptions are handled by handleOnePacket(), but we might be out of memory (std::bad_alloc) in which case we DO NOT want to log (as it would trigger another memory allocation attempt that might throw as well) but wait a bit (one millisecond) and then try to recover */ usleep(1000); } } } else { auto callback = [&remote, &msgh, &iov, &packet, &handleOnePacket, initialBufferSize](int socket, FDMultiplexer::funcparam_t& funcparam) { auto param = boost::any_cast(funcparam); try { remote.sin4.sin_family = param->cs->local.sin4.sin_family; packet.resize(initialBufferSize); /* used by HarvestDestinationAddress */ cmsgbuf_aligned cbuf; fillMSGHdr(&msgh, &iov, &cbuf, sizeof(cbuf), reinterpret_cast(&packet.at(0)), param->maxIncomingPacketSize, &remote); handleOnePacket(*param); } catch (const std::bad_alloc& e) { /* most exceptions are handled by handleOnePacket(), but we might be out of memory (std::bad_alloc) in which case we DO NOT want to log (as it would trigger another memory allocation attempt that might throw as well) but wait a bit (one millisecond) and then try to recover */ usleep(1000); } }; auto mplexer = std::unique_ptr(FDMultiplexer::getMultiplexerSilent(params.size())); for (size_t idx = 0; idx < params.size(); idx++) { const auto& param = params.at(idx); mplexer->addReadFD(param.socket, callback, ¶m); } struct timeval tv; while (true) { mplexer->run(&tv, -1); } } } } catch (const std::exception &e) { errlog("UDP client thread died because of exception: %s", e.what()); } catch (const PDNSException &e) { errlog("UDP client thread died because of PowerDNS exception: %s", e.reason); } catch (...) { errlog("UDP client thread died because of an exception: %s", "unknown"); } } boost::optional g_maxTCPClientThreads{boost::none}; pdns::stat16_t g_cacheCleaningDelay{60}; pdns::stat16_t g_cacheCleaningPercentage{100}; static void maintThread() { setThreadName("dnsdist/main"); constexpr int interval = 1; size_t counter = 0; int32_t secondsToWaitLog = 0; for (;;) { std::this_thread::sleep_for(std::chrono::seconds(interval)); { auto lua = g_lua.lock(); try { auto maintenanceCallback = lua->readVariable > >("maintenance"); if (maintenanceCallback) { (*maintenanceCallback)(); } dnsdist::lua::hooks::runMaintenanceHooks(*lua); secondsToWaitLog = 0; } catch (const std::exception &e) { if (secondsToWaitLog <= 0) { warnlog("Error during execution of maintenance function(s): %s", e.what()); secondsToWaitLog = 61; } secondsToWaitLog -= interval; } } counter++; if (counter >= g_cacheCleaningDelay) { /* keep track, for each cache, of whether we should keep expired entries */ std::map, bool> caches; /* gather all caches actually used by at least one pool, and see if something prevents us from cleaning the expired entries */ auto localPools = g_pools.getLocal(); for (const auto& entry : *localPools) { const auto& pool = entry.second; auto packetCache = pool->packetCache; if (!packetCache) { continue; } auto pair = caches.insert({packetCache, false}); auto& iter = pair.first; /* if we need to keep stale data for this cache (ie, not clear expired entries when at least one pool using this cache has all its backends down) */ if (packetCache->keepStaleData() && !iter->second) { /* so far all pools had at least one backend up */ if (pool->countServers(true) == 0) { iter->second = true; } } } const time_t now = time(nullptr); for (const auto& pair : caches) { /* shall we keep expired entries ? */ if (pair.second) { continue; } const auto& packetCache = pair.first; size_t upTo = (packetCache->getMaxEntries()* (100 - g_cacheCleaningPercentage)) / 100; packetCache->purgeExpired(upTo, now); } counter = 0; } } } #ifndef DISABLE_DYNBLOCKS static void dynBlockMaintenanceThread() { setThreadName("dnsdist/dynBloc"); DynBlockMaintenance::run(); } #endif #ifndef DISABLE_SECPOLL static void secPollThread() { setThreadName("dnsdist/secpoll"); for (;;) { try { doSecPoll(g_secPollSuffix); } catch(...) { } // coverity[store_truncates_time_t] sleep(g_secPollInterval); } } #endif /* DISABLE_SECPOLL */ static void healthChecksThread() { setThreadName("dnsdist/healthC"); constexpr int intervalUsec = 1000 * 1000; struct timeval lastRound{ .tv_sec = 0, .tv_usec = 0 }; auto states = g_dstates.getLocal(); // this points to the actual shared_ptrs! for (;;) { struct timeval now; gettimeofday(&now, nullptr); auto elapsedTimeUsec = uSec(now - lastRound); if (elapsedTimeUsec < intervalUsec) { usleep(intervalUsec - elapsedTimeUsec); gettimeofday(&lastRound, nullptr); } else { lastRound = now; } std::unique_ptr mplexer{nullptr}; for (auto& dss : *states) { dss->updateStatisticsInfo(); dss->handleUDPTimeouts(); if (!dss->healthCheckRequired()) { continue; } if (!mplexer) { mplexer = std::unique_ptr(FDMultiplexer::getMultiplexerSilent(states->size())); } if (!queueHealthCheck(mplexer, dss)) { dss->submitHealthCheckResult(false, false); } } if (mplexer) { handleQueuedHealthChecks(*mplexer); } } } static void bindAny(int af, int sock) { __attribute__((unused)) int one = 1; #ifdef IP_FREEBIND if (setsockopt(sock, IPPROTO_IP, IP_FREEBIND, &one, sizeof(one)) < 0) warnlog("Warning: IP_FREEBIND setsockopt failed: %s", stringerror()); #endif #ifdef IP_BINDANY if (af == AF_INET) if (setsockopt(sock, IPPROTO_IP, IP_BINDANY, &one, sizeof(one)) < 0) warnlog("Warning: IP_BINDANY setsockopt failed: %s", stringerror()); #endif #ifdef IPV6_BINDANY if (af == AF_INET6) if (setsockopt(sock, IPPROTO_IPV6, IPV6_BINDANY, &one, sizeof(one)) < 0) warnlog("Warning: IPV6_BINDANY setsockopt failed: %s", stringerror()); #endif #ifdef SO_BINDANY if (setsockopt(sock, SOL_SOCKET, SO_BINDANY, &one, sizeof(one)) < 0) warnlog("Warning: SO_BINDANY setsockopt failed: %s", stringerror()); #endif } static void dropGroupPrivs(gid_t gid) { if (gid != 0) { if (setgid(gid) == 0) { if (setgroups(0, nullptr) < 0) { warnlog("Warning: Unable to drop supplementary gids: %s", stringerror()); } } else { warnlog("Warning: Unable to set group ID to %d: %s", gid, stringerror()); } } } static void dropUserPrivs(uid_t uid) { if (uid != 0) { if (setuid(uid) < 0) { warnlog("Warning: Unable to set user ID to %d: %s", uid, stringerror()); } } } static void checkFileDescriptorsLimits(size_t udpBindsCount, size_t tcpBindsCount) { /* stdin, stdout, stderr */ rlim_t requiredFDsCount = 3; auto backends = g_dstates.getLocal(); /* UDP sockets to backends */ size_t backendUDPSocketsCount = 0; for (const auto& backend : *backends) { backendUDPSocketsCount += backend->sockets.size(); } requiredFDsCount += backendUDPSocketsCount; /* TCP sockets to backends */ if (g_maxTCPClientThreads) { requiredFDsCount += (backends->size() * (*g_maxTCPClientThreads)); } /* listening sockets */ requiredFDsCount += udpBindsCount; requiredFDsCount += tcpBindsCount; /* number of TCP connections currently served, assuming 1 connection per worker thread which is of course not right */ if (g_maxTCPClientThreads) { requiredFDsCount += *g_maxTCPClientThreads; /* max pipes for communicating between TCP acceptors and client threads */ requiredFDsCount += (*g_maxTCPClientThreads * 2); } /* max TCP queued connections */ requiredFDsCount += g_maxTCPQueuedConnections; /* DelayPipe pipe */ requiredFDsCount += 2; /* syslog socket */ requiredFDsCount++; /* webserver main socket */ requiredFDsCount++; /* console main socket */ requiredFDsCount++; /* carbon export */ requiredFDsCount++; /* history file */ requiredFDsCount++; struct rlimit rl; getrlimit(RLIMIT_NOFILE, &rl); if (rl.rlim_cur <= requiredFDsCount) { warnlog("Warning, this configuration can use more than %d file descriptors, web server and console connections not included, and the current limit is %d.", std::to_string(requiredFDsCount), std::to_string(rl.rlim_cur)); #ifdef HAVE_SYSTEMD warnlog("You can increase this value by using LimitNOFILE= in the systemd unit file or ulimit."); #else warnlog("You can increase this value by using ulimit."); #endif } } static bool g_warned_ipv6_recvpktinfo = false; static void setupLocalSocket(ClientState& clientState, const ComboAddress& addr, int& socket, bool tcp, bool warn) { (void) warn; socket = SSocket(addr.sin4.sin_family, !tcp ? SOCK_DGRAM : SOCK_STREAM, 0); if (tcp) { SSetsockopt(socket, SOL_SOCKET, SO_REUSEADDR, 1); #ifdef TCP_DEFER_ACCEPT SSetsockopt(socket, IPPROTO_TCP, TCP_DEFER_ACCEPT, 1); #endif if (clientState.fastOpenQueueSize > 0) { #ifdef TCP_FASTOPEN SSetsockopt(socket, IPPROTO_TCP, TCP_FASTOPEN, clientState.fastOpenQueueSize); #ifdef TCP_FASTOPEN_KEY if (!g_TCPFastOpenKey.empty()) { auto res = setsockopt(socket, IPPROTO_IP, TCP_FASTOPEN_KEY, g_TCPFastOpenKey.data(), g_TCPFastOpenKey.size() * sizeof(g_TCPFastOpenKey[0])); if (res == -1) { throw runtime_error("setsockopt for level IPPROTO_TCP and opname TCP_FASTOPEN_KEY failed: " + stringerror()); } } #endif /* TCP_FASTOPEN_KEY */ #else /* TCP_FASTOPEN */ if (warn) { warnlog("TCP Fast Open has been configured on local address '%s' but is not supported", addr.toStringWithPort()); } #endif /* TCP_FASTOPEN */ } } if (addr.sin4.sin_family == AF_INET6) { SSetsockopt(socket, IPPROTO_IPV6, IPV6_V6ONLY, 1); } bindAny(addr.sin4.sin_family, socket); if (!tcp && IsAnyAddress(addr)) { int one = 1; (void) setsockopt(socket, IPPROTO_IP, GEN_IP_PKTINFO, &one, sizeof(one)); // linux supports this, so why not - might fail on other systems #ifdef IPV6_RECVPKTINFO if (addr.isIPv6() && setsockopt(socket, IPPROTO_IPV6, IPV6_RECVPKTINFO, &one, sizeof(one)) < 0 && !g_warned_ipv6_recvpktinfo) { warnlog("Warning: IPV6_RECVPKTINFO setsockopt failed: %s", stringerror()); g_warned_ipv6_recvpktinfo = true; } #endif } if (clientState.reuseport) { if (!setReusePort(socket)) { if (warn) { /* no need to warn again if configured but support is not available, we already did for UDP */ warnlog("SO_REUSEPORT has been configured on local address '%s' but is not supported", addr.toStringWithPort()); } } } const bool isQUIC = clientState.doqFrontend != nullptr || clientState.doh3Frontend != nullptr; if (isQUIC) { /* disable fragmentation and force PMTU discovery for QUIC-enabled sockets */ try { setSocketForcePMTU(socket, addr.sin4.sin_family); } catch (const std::exception& e) { warnlog("Failed to set IP_MTU_DISCOVER on QUIC server socket for local address '%s': %s", addr.toStringWithPort(), e.what()); } } else if (!tcp && !clientState.dnscryptCtx) { /* Only set this on IPv4 UDP sockets. Don't set it for DNSCrypt binds. DNSCrypt pads queries for privacy purposes, so we do receive large, sometimes fragmented datagrams. */ try { setSocketIgnorePMTU(socket, addr.sin4.sin_family); } catch (const std::exception& e) { warnlog("Failed to set IP_MTU_DISCOVER on UDP server socket for local address '%s': %s", addr.toStringWithPort(), e.what()); } } if (!tcp) { if (g_socketUDPSendBuffer > 0) { try { setSocketSendBuffer(socket, g_socketUDPSendBuffer); } catch (const std::exception& e) { warnlog(e.what()); } } else { try { auto result = raiseSocketSendBufferToMax(socket); if (result > 0) { infolog("Raised send buffer to %u for local address '%s'", result, addr.toStringWithPort()); } } catch (const std::exception& e) { warnlog(e.what()); } } if (g_socketUDPRecvBuffer > 0) { try { setSocketReceiveBuffer(socket, g_socketUDPRecvBuffer); } catch (const std::exception& e) { warnlog(e.what()); } } else { try { auto result = raiseSocketReceiveBufferToMax(socket); if (result > 0) { infolog("Raised receive buffer to %u for local address '%s'", result, addr.toStringWithPort()); } } catch (const std::exception& e) { warnlog(e.what()); } } } const std::string& itf = clientState.interface; if (!itf.empty()) { #ifdef SO_BINDTODEVICE int res = setsockopt(socket, SOL_SOCKET, SO_BINDTODEVICE, itf.c_str(), itf.length()); if (res != 0) { warnlog("Error setting up the interface on local address '%s': %s", addr.toStringWithPort(), stringerror()); } #else if (warn) { warnlog("An interface has been configured on local address '%s' but SO_BINDTODEVICE is not supported", addr.toStringWithPort()); } #endif } #ifdef HAVE_EBPF if (g_defaultBPFFilter && !g_defaultBPFFilter->isExternal()) { clientState.attachFilter(g_defaultBPFFilter, socket); vinfolog("Attaching default BPF Filter to %s frontend %s", (!tcp ? std::string("UDP") : std::string("TCP")), addr.toStringWithPort()); } #endif /* HAVE_EBPF */ SBind(socket, addr); if (tcp) { SListen(socket, clientState.tcpListenQueueSize); if (clientState.tlsFrontend != nullptr) { infolog("Listening on %s for TLS", addr.toStringWithPort()); } else if (clientState.dohFrontend != nullptr) { infolog("Listening on %s for DoH", addr.toStringWithPort()); } else if (clientState.dnscryptCtx != nullptr) { infolog("Listening on %s for DNSCrypt", addr.toStringWithPort()); } else { infolog("Listening on %s", addr.toStringWithPort()); } } else { if (clientState.doqFrontend != nullptr) { infolog("Listening on %s for DoQ", addr.toStringWithPort()); } else if (clientState.doh3Frontend != nullptr) { infolog("Listening on %s for DoH3", addr.toStringWithPort()); } #ifdef HAVE_XSK else if (clientState.xskInfo != nullptr) { infolog("Listening on %s (XSK-enabled)", addr.toStringWithPort()); } #endif } } static void setUpLocalBind(std::unique_ptr& cstate) { /* skip some warnings if there is an identical UDP context */ bool warn = !cstate->tcp || cstate->tlsFrontend != nullptr || cstate->dohFrontend != nullptr; int& descriptor = !cstate->tcp ? cstate->udpFD : cstate->tcpFD; (void) warn; setupLocalSocket(*cstate, cstate->local, descriptor, cstate->tcp, warn); for (auto& [addr, socket] : cstate->d_additionalAddresses) { setupLocalSocket(*cstate, addr, socket, true, false); } if (cstate->tlsFrontend != nullptr) { if (!cstate->tlsFrontend->setupTLS()) { errlog("Error while setting up TLS on local address '%s', exiting", cstate->local.toStringWithPort()); _exit(EXIT_FAILURE); } } if (cstate->dohFrontend != nullptr) { cstate->dohFrontend->setup(); } if (cstate->doqFrontend != nullptr) { cstate->doqFrontend->setup(); } if (cstate->doh3Frontend != nullptr) { cstate->doh3Frontend->setup(); } cstate->ready = true; } struct { vector locals; vector remotes; bool checkConfig{false}; bool beClient{false}; bool beSupervised{false}; string command; string config; string uid; string gid; } g_cmdLine; std::atomic g_configurationDone{false}; static void usage() { cout< longopts{{ {"acl", required_argument, nullptr, 'a'}, {"check-config", no_argument, nullptr, 1}, {"client", no_argument, nullptr, 'c'}, {"config", required_argument, nullptr, 'C'}, {"disable-syslog", no_argument, nullptr, 2}, {"execute", required_argument, nullptr, 'e'}, {"gid", required_argument, nullptr, 'g'}, {"help", no_argument, nullptr, 'h'}, {"local", required_argument, nullptr, 'l'}, {"log-timestamps", no_argument, nullptr, 4}, {"setkey", required_argument, nullptr, 'k'}, {"supervised", no_argument, nullptr, 3}, {"uid", required_argument, nullptr, 'u'}, {"verbose", no_argument, nullptr, 'v'}, {"version", no_argument, nullptr, 'V'}, {nullptr, 0, nullptr, 0} }}; int longindex = 0; string optstring; while (true) { // NOLINTNEXTLINE(concurrency-mt-unsafe): only one thread at this point int gotChar = getopt_long(argc, argv, "a:cC:e:g:hk:l:u:vV", longopts.data(), &longindex); if (gotChar == -1) { break; } switch (gotChar) { case 1: g_cmdLine.checkConfig = true; break; case 2: dnsdist::logging::LoggingConfiguration::setSyslog(false); break; case 3: g_cmdLine.beSupervised = true; break; case 4: dnsdist::logging::LoggingConfiguration::setLogTimestamps(true); break; case 'C': g_cmdLine.config = optarg; break; case 'c': g_cmdLine.beClient = true; break; case 'e': g_cmdLine.command = optarg; break; case 'g': g_cmdLine.gid = optarg; break; case 'h': cout<<"dnsdist "<getName() == "chashed") { precompute = true; } else { for (const auto& entry: pools) { if (entry.second->policy != nullptr && entry.second->policy->getName() == "chashed") { precompute = true; break ; } } } if (precompute) { vinfolog("Pre-computing hashes for consistent hash load-balancing policy"); // pre compute hashes auto backends = g_dstates.getLocal(); for (const auto& backend: *backends) { if (backend->d_config.d_weight < 100) { vinfolog("Warning, the backend '%s' has a very low weight (%d), which will not yield a good distribution of queries with the 'chashed' policy. Please consider raising it to at least '100'.", backend->getName(), backend->d_config.d_weight); } backend->hash(); } } } } static void dropPrivileges() { uid_t newgid = getegid(); gid_t newuid = geteuid(); if (!g_cmdLine.gid.empty()) { newgid = strToGID(g_cmdLine.gid); } if (!g_cmdLine.uid.empty()) { newuid = strToUID(g_cmdLine.uid); } bool retainedCapabilities = true; if (!g_capabilitiesToRetain.empty() && (getegid() != newgid || geteuid() != newuid)) { retainedCapabilities = keepCapabilitiesAfterSwitchingIDs(); } if (getegid() != newgid) { if (running_in_service_mgr()) { errlog("--gid/-g set on command-line, but dnsdist was started as a systemd service. Use the 'Group' setting in the systemd unit file to set the group to run as"); _exit(EXIT_FAILURE); } dropGroupPrivs(newgid); } if (geteuid() != newuid) { if (running_in_service_mgr()) { errlog("--uid/-u set on command-line, but dnsdist was started as a systemd service. Use the 'User' setting in the systemd unit file to set the user to run as"); _exit(EXIT_FAILURE); } dropUserPrivs(newuid); } if (retainedCapabilities) { dropCapabilitiesAfterSwitchingIDs(); } try { /* we might still have capabilities remaining, for example if we have been started as root without --uid or --gid (please don't do that) or as an unprivileged user with ambient capabilities like CAP_NET_BIND_SERVICE. */ dropCapabilities(g_capabilitiesToRetain); } catch (const std::exception& e) { warnlog("%s", e.what()); } } static void initFrontends() { if (!g_cmdLine.locals.empty()) { for (auto it = g_frontends.begin(); it != g_frontends.end(); ) { /* DoH, DoT and DNSCrypt frontends are separate */ if ((*it)->dohFrontend == nullptr && (*it)->tlsFrontend == nullptr && (*it)->dnscryptCtx == nullptr && (*it)->doqFrontend == nullptr && (*it)->doh3Frontend == nullptr) { it = g_frontends.erase(it); } else { ++it; } } for (const auto& loc : g_cmdLine.locals) { /* UDP */ g_frontends.emplace_back(std::make_unique(ComboAddress(loc, 53), false, false, 0, "", std::set{}, true)); /* TCP */ g_frontends.emplace_back(std::make_unique(ComboAddress(loc, 53), true, false, 0, "", std::set{}, true)); } } if (g_frontends.empty()) { /* UDP */ g_frontends.emplace_back(std::make_unique(ComboAddress("127.0.0.1", 53), false, false, 0, "", std::set{}, true)); /* TCP */ g_frontends.emplace_back(std::make_unique(ComboAddress("127.0.0.1", 53), true, false, 0, "", std::set{}, true)); } } namespace dnsdist { static void startFrontends() { #ifdef HAVE_XSK for (auto& xskContext : dnsdist::xsk::g_xsk) { std::thread xskThread(dnsdist::xsk::XskRouter, std::move(xskContext)); xskThread.detach(); } #endif /* HAVE_XSK */ std::vector tcpStates; std::vector udpStates; for (auto& clientState : g_frontends) { #ifdef HAVE_XSK if (clientState->xskInfo) { dnsdist::xsk::addDestinationAddress(clientState->local); std::thread xskCT(dnsdist::xsk::XskClientThread, clientState.get()); if (!clientState->cpus.empty()) { mapThreadToCPUList(xskCT.native_handle(), clientState->cpus); } xskCT.detach(); } #endif /* HAVE_XSK */ if (clientState->dohFrontend != nullptr && clientState->dohFrontend->d_library == "h2o") { #ifdef HAVE_DNS_OVER_HTTPS #ifdef HAVE_LIBH2OEVLOOP std::thread dotThreadHandle(dohThread, clientState.get()); if (!clientState->cpus.empty()) { mapThreadToCPUList(dotThreadHandle.native_handle(), clientState->cpus); } dotThreadHandle.detach(); #endif /* HAVE_LIBH2OEVLOOP */ #endif /* HAVE_DNS_OVER_HTTPS */ continue; } if (clientState->doqFrontend != nullptr) { #ifdef HAVE_DNS_OVER_QUIC std::thread doqThreadHandle(doqThread, clientState.get()); if (!clientState->cpus.empty()) { mapThreadToCPUList(doqThreadHandle.native_handle(), clientState->cpus); } doqThreadHandle.detach(); #endif /* HAVE_DNS_OVER_QUIC */ continue; } if (clientState->doh3Frontend != nullptr) { #ifdef HAVE_DNS_OVER_HTTP3 std::thread doh3ThreadHandle(doh3Thread, clientState.get()); if (!clientState->cpus.empty()) { mapThreadToCPUList(doh3ThreadHandle.native_handle(), clientState->cpus); } doh3ThreadHandle.detach(); #endif /* HAVE_DNS_OVER_HTTP3 */ continue; } if (clientState->udpFD >= 0) { #ifdef USE_SINGLE_ACCEPTOR_THREAD udpStates.push_back(clientState.get()); #else /* USE_SINGLE_ACCEPTOR_THREAD */ std::thread udpClientThreadHandle(udpClientThread, std::vector{ clientState.get() }); if (!clientState->cpus.empty()) { mapThreadToCPUList(udpClientThreadHandle.native_handle(), clientState->cpus); } udpClientThreadHandle.detach(); #endif /* USE_SINGLE_ACCEPTOR_THREAD */ } else if (clientState->tcpFD >= 0) { #ifdef USE_SINGLE_ACCEPTOR_THREAD tcpStates.push_back(clientState.get()); #else /* USE_SINGLE_ACCEPTOR_THREAD */ std::thread tcpAcceptorThreadHandle(tcpAcceptorThread, std::vector{clientState.get() }); if (!clientState->cpus.empty()) { mapThreadToCPUList(tcpAcceptorThreadHandle.native_handle(), clientState->cpus); } tcpAcceptorThreadHandle.detach(); #endif /* USE_SINGLE_ACCEPTOR_THREAD */ } } #ifdef USE_SINGLE_ACCEPTOR_THREAD if (!udpStates.empty()) { std::thread udpThreadHandle(udpClientThread, udpStates); udpThreadHandle.detach(); } if (!tcpStates.empty()) { g_tcpclientthreads = std::make_unique(1, tcpStates); } #endif /* USE_SINGLE_ACCEPTOR_THREAD */ } } int main(int argc, char** argv) { try { size_t udpBindsCount = 0; size_t tcpBindsCount = 0; #ifdef HAVE_LIBEDIT #ifndef DISABLE_COMPLETION rl_attempted_completion_function = my_completion; rl_completion_append_character = 0; #endif /* DISABLE_COMPLETION */ #endif /* HAVE_LIBEDIT */ // NOLINTNEXTLINE(cppcoreguidelines-pro-type-cstyle-cast): SIG_IGN macro signal(SIGPIPE, SIG_IGN); // NOLINTNEXTLINE(cppcoreguidelines-pro-type-cstyle-cast): SIG_IGN macro signal(SIGCHLD, SIG_IGN); signal(SIGTERM, sigTermHandler); openlog("dnsdist", LOG_PID|LOG_NDELAY, LOG_DAEMON); #ifdef HAVE_LIBSODIUM if (sodium_init() == -1) { cerr<<"Unable to initialize crypto library"<(); auto todo = setupLua(*(g_lua.lock()), false, false, g_cmdLine.config); setupPools(); initFrontends(); g_configurationDone = true; g_rings.init(); for (auto& frontend : g_frontends) { setUpLocalBind(frontend); if (!frontend->tcp) { ++udpBindsCount; } else { ++tcpBindsCount; } } { std::string acls; auto aclEntries = g_ACL.getLocal()->toStringVector(); for (const auto& aclEntry : aclEntries) { if (!acls.empty()) { acls += ", "; } acls += aclEntry; } infolog("ACL allowing queries from: %s", acls); } { std::string acls; auto aclEntries = g_consoleACL.getLocal()->toStringVector(); for (const auto& entry : aclEntries) { if (!acls.empty()) { acls += ", "; } acls += entry; } infolog("Console ACL allowing connections from: %s", acls.c_str()); } #if defined(HAVE_LIBSODIUM) || defined(HAVE_LIBCRYPTO) if (g_consoleEnabled && g_consoleKey.empty()) { warnlog("Warning, the console has been enabled via 'controlSocket()' but no key has been set with 'setKey()' so all connections will fail until a key has been set"); } #endif dropPrivileges(); /* this need to be done _after_ dropping privileges */ #ifndef DISABLE_DELAY_PIPE g_delay = std::make_unique>(); #endif /* DISABLE_DELAY_PIPE */ if (g_snmpAgent != nullptr) { g_snmpAgent->run(); } if (!g_maxTCPClientThreads) { g_maxTCPClientThreads = static_cast(10); } else if (*g_maxTCPClientThreads == 0 && tcpBindsCount > 0) { warnlog("setMaxTCPClientThreads() has been set to 0 while we are accepting TCP connections, raising to 1"); g_maxTCPClientThreads = 1; } /* we need to create the TCP worker threads before the acceptor ones, otherwise we might crash when processing the first TCP query */ #ifndef USE_SINGLE_ACCEPTOR_THREAD g_tcpclientthreads = std::make_unique(*g_maxTCPClientThreads, std::vector()); #endif #if defined(HAVE_DNS_OVER_HTTPS) && defined(HAVE_NGHTTP2) initDoHWorkers(); #endif for (auto& todoItem : todo) { todoItem(); } auto localPools = g_pools.getCopy(); /* create the default pool no matter what */ createPoolIfNotExists(localPools, ""); if (!g_cmdLine.remotes.empty()) { for (const auto& address : g_cmdLine.remotes) { DownstreamState::Config config; config.remote = ComboAddress(address, 53); auto ret = std::make_shared(std::move(config), nullptr, true); addServerToPool(localPools, "", ret); ret->start(); g_dstates.modify([&ret](servers_t& servers) { servers.push_back(std::move(ret)); }); } } g_pools.setState(localPools); if (g_dstates.getLocal()->empty()) { errlog("No downstream servers defined: all packets will get dropped"); // you might define them later, but you need to know } checkFileDescriptorsLimits(udpBindsCount, tcpBindsCount); { auto states = g_dstates.getCopy(); // it is a copy, but the internal shared_ptrs are the real deal auto mplexer = std::unique_ptr(FDMultiplexer::getMultiplexerSilent(states.size())); for (auto& dss : states) { if (dss->d_config.availability == DownstreamState::Availability::Auto || dss->d_config.availability == DownstreamState::Availability::Lazy) { if (dss->d_config.availability == DownstreamState::Availability::Auto) { dss->d_nextCheck = dss->d_config.checkInterval; } if (!queueHealthCheck(mplexer, dss, true)) { dss->submitHealthCheckResult(true, false); dss->setUpStatus(false); warnlog("Marking downstream %s as 'down'", dss->getNameWithAddr()); } } } handleQueuedHealthChecks(*mplexer, true); } dnsdist::startFrontends(); dnsdist::ServiceDiscovery::run(); #ifndef DISABLE_CARBON dnsdist::Carbon::run(); #endif /* DISABLE_CARBON */ thread stattid(maintThread); stattid.detach(); thread healththread(healthChecksThread); #ifndef DISABLE_DYNBLOCKS thread dynBlockMaintThread(dynBlockMaintenanceThread); dynBlockMaintThread.detach(); #endif /* DISABLE_DYNBLOCKS */ #ifndef DISABLE_SECPOLL if (!g_secPollSuffix.empty()) { thread secpollthread(secPollThread); secpollthread.detach(); } #endif /* DISABLE_SECPOLL */ if(g_cmdLine.beSupervised) { #ifdef HAVE_SYSTEMD sd_notify(0, "READY=1"); #endif healththread.join(); } else { healththread.detach(); doConsole(); } #ifdef COVERAGE cleanupLuaObjects(); exit(EXIT_SUCCESS); #else _exit(EXIT_SUCCESS); #endif } catch (const LuaContext::ExecutionErrorException& e) { try { errlog("Fatal Lua error: %s", e.what()); std::rethrow_if_nested(e); } catch(const std::exception& ne) { errlog("Details: %s", ne.what()); } catch (const PDNSException &ae) { errlog("Fatal pdns error: %s", ae.reason); } #ifdef COVERAGE cleanupLuaObjects(); exit(EXIT_FAILURE); #else _exit(EXIT_FAILURE); #endif } catch (const std::exception &e) { errlog("Fatal error: %s", e.what()); #ifdef COVERAGE cleanupLuaObjects(); exit(EXIT_FAILURE); #else _exit(EXIT_FAILURE); #endif } catch (const PDNSException &ae) { errlog("Fatal pdns error: %s", ae.reason); #ifdef COVERAGE cleanupLuaObjects(); exit(EXIT_FAILURE); #else _exit(EXIT_FAILURE); #endif } }