/* * 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. */ #pragma once #include "config.h" #include "ext/luawrapper/include/LuaContext.hpp" #include #include #include #include #include #include #include #include #include #include "circular_buffer.hh" #include "dnscrypt.hh" #include "dnsdist-cache.hh" #include "dnsdist-dynbpf.hh" #include "dnsdist-idstate.hh" #include "dnsdist-lbpolicies.hh" #include "dnsdist-protocols.hh" #include "dnsname.hh" #include "dnsdist-doh-common.hh" #include "doq.hh" #include "doh3.hh" #include "ednsoptions.hh" #include "iputils.hh" #include "misc.hh" #include "mplexer.hh" #include "noinitvector.hh" #include "sholder.hh" #include "tcpiohandler.hh" #include "uuid-utils.hh" #include "proxy-protocol.hh" #include "stat_t.hh" uint64_t uptimeOfProcess(const std::string& str); extern uint16_t g_ECSSourcePrefixV4; extern uint16_t g_ECSSourcePrefixV6; extern bool g_ECSOverride; using QTag = std::unordered_map; class IncomingTCPConnectionState; struct ClientState; struct DNSQuestion { DNSQuestion(InternalQueryState& ids_, PacketBuffer& data_): data(data_), ids(ids_), ecsPrefixLength(ids.origRemote.sin4.sin_family == AF_INET ? g_ECSSourcePrefixV4 : g_ECSSourcePrefixV6), ecsOverride(g_ECSOverride) { } DNSQuestion(const DNSQuestion&) = delete; DNSQuestion& operator=(const DNSQuestion&) = delete; DNSQuestion(DNSQuestion&&) = default; virtual ~DNSQuestion() = default; std::string getTrailingData() const; bool setTrailingData(const std::string&); const PacketBuffer& getData() const { return data; } PacketBuffer& getMutableData() { return data; } bool editHeader(const std::function& editFunction); const dnsheader_aligned getHeader() const { 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"); } dnsheader_aligned dh(data.data()); return dh; } /* this function is not safe against unaligned access, you should use editHeader() instead, but we need it for the Lua bindings */ dnsheader* getMutableHeader() const { 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"); } // NOLINTNEXTLINE(cppcoreguidelines-pro-type-reinterpret-cast) return reinterpret_cast(data.data()); } bool hasRoomFor(size_t more) const { return data.size() <= getMaximumSize() && (getMaximumSize() - data.size()) >= more; } size_t getMaximumSize() const { if (overTCP()) { return std::numeric_limits::max(); } return 4096; } dnsdist::Protocol getProtocol() const { return ids.protocol; } bool overTCP() const { return !(ids.protocol == dnsdist::Protocol::DoUDP || ids.protocol == dnsdist::Protocol::DNSCryptUDP); } void setTag(std::string&& key, std::string&& value) { if (!ids.qTag) { ids.qTag = std::make_unique(); } ids.qTag->insert_or_assign(std::move(key), std::move(value)); } void setTag(const std::string& key, const std::string& value) { if (!ids.qTag) { ids.qTag = std::make_unique(); } ids.qTag->insert_or_assign(key, value); } void setTag(const std::string& key, std::string&& value) { if (!ids.qTag) { ids.qTag = std::make_unique(); } ids.qTag->insert_or_assign(key, std::move(value)); } const struct timespec& getQueryRealTime() const { return ids.queryRealTime.d_start; } bool isAsynchronous() const { return asynchronous; } std::shared_ptr getIncomingTCPState() const { return d_incomingTCPState; } ClientState* getFrontend() const { return ids.cs; } protected: PacketBuffer& data; public: InternalQueryState& ids; std::unique_ptr ecs{nullptr}; std::string sni; /* Server Name Indication, if any (DoT or DoH) */ mutable std::unique_ptr ednsOptions; /* this needs to be mutable because it is parsed just in time, when DNSQuestion is read-only */ std::shared_ptr d_incomingTCPState{nullptr}; std::unique_ptr> proxyProtocolValues{nullptr}; uint16_t ecsPrefixLength; uint8_t ednsRCode{0}; bool ecsOverride; bool useECS{true}; bool addXPF{true}; bool asynchronous{false}; }; struct DownstreamState; struct DNSResponse : DNSQuestion { DNSResponse(InternalQueryState& ids_, PacketBuffer& data_, const std::shared_ptr& downstream): DNSQuestion(ids_, data_), d_downstream(downstream) { } DNSResponse(const DNSResponse&) = delete; DNSResponse& operator=(const DNSResponse&) = delete; DNSResponse(DNSResponse&&) = default; const std::shared_ptr& d_downstream; }; /* so what could you do: drop, fake up nxdomain, provide actual answer, allow & and stop processing, continue processing, modify header: (servfail|refused|notimp), set TC=1, send to pool */ class DNSAction { public: enum class Action : uint8_t { Drop, Nxdomain, Refused, Spoof, Allow, HeaderModify, Pool, Delay, Truncate, ServFail, None, NoOp, NoRecurse, SpoofRaw, SpoofPacket }; static std::string typeToString(const Action& action) { switch(action) { case Action::Drop: return "Drop"; case Action::Nxdomain: return "Send NXDomain"; case Action::Refused: return "Send Refused"; case Action::Spoof: return "Spoof an answer"; case Action::SpoofPacket: return "Spoof a raw answer from bytes"; case Action::SpoofRaw: return "Spoof an answer from raw bytes"; case Action::Allow: return "Allow"; case Action::HeaderModify: return "Modify the header"; case Action::Pool: return "Route to a pool"; case Action::Delay: return "Delay"; case Action::Truncate: return "Truncate over UDP"; case Action::ServFail: return "Send ServFail"; case Action::None: case Action::NoOp: return "Do nothing"; case Action::NoRecurse: return "Set rd=0"; } return "Unknown"; } virtual Action operator()(DNSQuestion*, string* ruleresult) const =0; virtual ~DNSAction() { } virtual string toString() const = 0; virtual std::map getStats() const { return {{}}; } virtual void reload() { } }; class DNSResponseAction { public: enum class Action : uint8_t { Allow, Delay, Drop, HeaderModify, ServFail, Truncate, None }; virtual Action operator()(DNSResponse*, string* ruleresult) const =0; virtual ~DNSResponseAction() { } virtual string toString() const = 0; virtual void reload() { } }; struct DynBlock { DynBlock(): action(DNSAction::Action::None), warning(false) { until.tv_sec = 0; until.tv_nsec = 0; } DynBlock(const std::string& reason_, const struct timespec& until_, const DNSName& domain_, DNSAction::Action action_): reason(reason_), domain(domain_), until(until_), action(action_), warning(false) { } DynBlock(const DynBlock& rhs): reason(rhs.reason), domain(rhs.domain), until(rhs.until), action(rhs.action), warning(rhs.warning), bpf(rhs.bpf) { blocks.store(rhs.blocks); } DynBlock(DynBlock&& rhs): reason(std::move(rhs.reason)), domain(std::move(rhs.domain)), until(rhs.until), action(rhs.action), warning(rhs.warning), bpf(rhs.bpf) { blocks.store(rhs.blocks); } DynBlock& operator=(const DynBlock& rhs) { reason = rhs.reason; until = rhs.until; domain = rhs.domain; action = rhs.action; blocks.store(rhs.blocks); warning = rhs.warning; bpf = rhs.bpf; return *this; } DynBlock& operator=(DynBlock&& rhs) { reason = std::move(rhs.reason); until = rhs.until; domain = std::move(rhs.domain); action = rhs.action; blocks.store(rhs.blocks); warning = rhs.warning; bpf = rhs.bpf; return *this; } string reason; DNSName domain; struct timespec until; mutable std::atomic blocks; DNSAction::Action action{DNSAction::Action::None}; bool warning{false}; bool bpf{false}; }; extern GlobalStateHolder> g_dynblockNMG; extern vector > g_confDelta; using pdns::stat_t; class BasicQPSLimiter { public: BasicQPSLimiter() { } BasicQPSLimiter(unsigned int burst): d_tokens(burst) { d_prev.start(); } virtual ~BasicQPSLimiter() { } bool check(unsigned int rate, unsigned int burst) const // this is not quite fair { if (checkOnly(rate, burst)) { addHit(); return true; } return false; } bool checkOnly(unsigned int rate, unsigned int burst) const // this is not quite fair { auto delta = d_prev.udiffAndSet(); if (delta > 0.0) { // time, frequently, does go backwards.. d_tokens += 1.0 * rate * (delta/1000000.0); } if (d_tokens > burst) { d_tokens = burst; } bool ret = false; if (d_tokens >= 1.0) { // we need this because burst=1 is weird otherwise ret = true; } return ret; } virtual void addHit() const { --d_tokens; } bool seenSince(const struct timespec& cutOff) const { return cutOff < d_prev.d_start; } protected: mutable StopWatch d_prev; mutable double d_tokens{0.0}; }; class QPSLimiter : public BasicQPSLimiter { public: QPSLimiter(): BasicQPSLimiter() { } QPSLimiter(unsigned int rate, unsigned int burst): BasicQPSLimiter(burst), d_rate(rate), d_burst(burst), d_passthrough(false) { d_prev.start(); } unsigned int getRate() const { return d_passthrough ? 0 : d_rate; } bool check() const // this is not quite fair { if (d_passthrough) { return true; } return BasicQPSLimiter::check(d_rate, d_burst); } bool checkOnly() const { if (d_passthrough) { return true; } return BasicQPSLimiter::checkOnly(d_rate, d_burst); } void addHit() const override { if (!d_passthrough) { --d_tokens; } } private: unsigned int d_rate{0}; unsigned int d_burst{0}; bool d_passthrough{true}; }; typedef std::unordered_map QueryCountRecords; typedef std::function(const DNSQuestion* dq)> QueryCountFilter; struct QueryCount { QueryCount() { } ~QueryCount() { } SharedLockGuarded records; QueryCountFilter filter; bool enabled{false}; }; extern QueryCount g_qcount; class XskPacket; class XskSocket; class XskWorker; struct ClientState { ClientState(const ComboAddress& local_, bool isTCP_, bool doReusePort, int fastOpenQueue, const std::string& itfName, const std::set& cpus_, bool enableProxyProtocol): cpus(cpus_), interface(itfName), local(local_), fastOpenQueueSize(fastOpenQueue), tcp(isTCP_), reuseport(doReusePort), d_enableProxyProtocol(enableProxyProtocol) { } stat_t queries{0}; stat_t nonCompliantQueries{0}; mutable stat_t responses{0}; mutable stat_t tcpDiedReadingQuery{0}; mutable stat_t tcpDiedSendingResponse{0}; mutable stat_t tcpGaveUp{0}; mutable stat_t tcpClientTimeouts{0}; mutable stat_t tcpDownstreamTimeouts{0}; /* current number of connections to this frontend */ mutable stat_t tcpCurrentConnections{0}; /* maximum number of concurrent connections to this frontend reached */ mutable stat_t tcpMaxConcurrentConnections{0}; stat_t tlsNewSessions{0}; // A new TLS session has been negotiated, no resumption stat_t tlsResumptions{0}; // A TLS session has been resumed, either via session id or via a TLS ticket stat_t tlsUnknownTicketKey{0}; // A TLS ticket has been presented but we don't have the associated key (might have expired) stat_t tlsInactiveTicketKey{0}; // A TLS ticket has been successfully resumed but the key is no longer active, we should issue a new one stat_t tls10queries{0}; // valid DNS queries received via TLSv1.0 stat_t tls11queries{0}; // valid DNS queries received via TLSv1.1 stat_t tls12queries{0}; // valid DNS queries received via TLSv1.2 stat_t tls13queries{0}; // valid DNS queries received via TLSv1.3 stat_t tlsUnknownqueries{0}; // valid DNS queries received via unknown TLS version pdns::stat_t_trait tcpAvgQueriesPerConnection{0.0}; /* in ms */ pdns::stat_t_trait tcpAvgConnectionDuration{0.0}; std::set cpus; std::string interface; ComboAddress local; std::vector> d_additionalAddresses; std::shared_ptr dnscryptCtx{nullptr}; std::shared_ptr tlsFrontend{nullptr}; std::shared_ptr dohFrontend{nullptr}; std::shared_ptr doqFrontend{nullptr}; std::shared_ptr doh3Frontend{nullptr}; std::shared_ptr d_filter{nullptr}; std::shared_ptr xskInfo{nullptr}; std::shared_ptr xskInfoResponder{nullptr}; size_t d_maxInFlightQueriesPerConn{1}; size_t d_tcpConcurrentConnectionsLimit{0}; int udpFD{-1}; int tcpFD{-1}; int tcpListenQueueSize{SOMAXCONN}; int fastOpenQueueSize{0}; bool muted{false}; bool tcp; bool reuseport; bool d_enableProxyProtocol{true}; // the global proxy protocol ACL still applies bool ready{false}; int getSocket() const { return udpFD != -1 ? udpFD : tcpFD; } bool isUDP() const { return udpFD != -1; } bool isTCP() const { return udpFD == -1; } bool isDoH() const { return dohFrontend != nullptr; } bool hasTLS() const { return tlsFrontend != nullptr || (dohFrontend != nullptr && dohFrontend->isHTTPS()); } const TLSFrontend& getTLSFrontend() const { if (tlsFrontend != nullptr) { return *tlsFrontend; } if (dohFrontend) { return dohFrontend->d_tlsContext; } throw std::runtime_error("Trying to get a TLS frontend from a non-TLS ClientState"); } dnsdist::Protocol getProtocol() const { if (dnscryptCtx) { if (udpFD != -1) { return dnsdist::Protocol::DNSCryptUDP; } return dnsdist::Protocol::DNSCryptTCP; } if (isDoH()) { return dnsdist::Protocol::DoH; } else if (hasTLS()) { return dnsdist::Protocol::DoT; } else if (doqFrontend != nullptr) { return dnsdist::Protocol::DoQ; } else if (doh3Frontend != nullptr) { return dnsdist::Protocol::DoH3; } else if (udpFD != -1) { return dnsdist::Protocol::DoUDP; } else { return dnsdist::Protocol::DoTCP; } } std::string getType() const { std::string result = udpFD != -1 ? "UDP" : "TCP"; if (doqFrontend) { result += " (DNS over QUIC)"; } else if (doh3Frontend) { result += " (DNS over HTTP/3)"; } else if (dohFrontend) { if (dohFrontend->isHTTPS()) { result += " (DNS over HTTPS)"; } else { result += " (DNS over HTTP)"; } } else if (tlsFrontend) { result += " (DNS over TLS)"; } else if (dnscryptCtx) { result += " (DNSCrypt)"; } return result; } void detachFilter(int socket) { if (d_filter) { d_filter->removeSocket(socket); d_filter = nullptr; } } void attachFilter(shared_ptr& bpf, int socket) { detachFilter(socket); bpf->addSocket(socket); d_filter = bpf; } void detachFilter() { if (d_filter) { detachFilter(getSocket()); for (const auto& [addr, socket] : d_additionalAddresses) { (void) addr; if (socket != -1) { detachFilter(socket); } } d_filter = nullptr; } } void attachFilter(shared_ptr& bpf) { detachFilter(); bpf->addSocket(getSocket()); for (const auto& [addr, socket] : d_additionalAddresses) { (void) addr; if (socket != -1) { bpf->addSocket(socket); } } d_filter = bpf; } void updateTCPMetrics(size_t nbQueries, uint64_t durationMs) { tcpAvgQueriesPerConnection = (99.0 * tcpAvgQueriesPerConnection / 100.0) + (nbQueries / 100.0); tcpAvgConnectionDuration = (99.0 * tcpAvgConnectionDuration / 100.0) + (durationMs / 100.0); } }; struct CrossProtocolQuery; struct DownstreamState: public std::enable_shared_from_this { DownstreamState(const DownstreamState&) = delete; DownstreamState(DownstreamState&&) = delete; DownstreamState& operator=(const DownstreamState&) = delete; DownstreamState& operator=(DownstreamState&&) = delete; typedef std::function(const DNSName&, uint16_t, uint16_t, dnsheader*)> checkfunc_t; enum class Availability : uint8_t { Up, Down, Auto, Lazy }; enum class LazyHealthCheckMode : uint8_t { TimeoutOnly, TimeoutOrServFail }; struct Config { Config() { } Config(const ComboAddress& remote_): remote(remote_) { } TLSContextParameters d_tlsParams; set pools; std::set d_cpus; checkfunc_t checkFunction; std::optional id; DNSName checkName{"a.root-servers.net."}; ComboAddress remote; ComboAddress sourceAddr; std::string sourceItfName; std::string d_tlsSubjectName; std::string d_dohPath; std::string name; std::string nameWithAddr; #ifdef HAVE_XSK std::array sourceMACAddr; std::array destMACAddr; #endif /* HAVE_XSK */ size_t d_numberOfSockets{1}; size_t d_maxInFlightQueriesPerConn{1}; size_t d_tcpConcurrentConnectionsLimit{0}; int order{1}; int d_weight{1}; int tcpConnectTimeout{5}; int tcpRecvTimeout{30}; int tcpSendTimeout{30}; int d_qpsLimit{0}; unsigned int checkInterval{1}; unsigned int sourceItf{0}; QType checkType{QType::A}; uint16_t checkClass{QClass::IN}; uint16_t d_retries{5}; uint16_t xpfRRCode{0}; uint16_t checkTimeout{1000}; /* in milliseconds */ uint16_t d_lazyHealthCheckSampleSize{100}; uint16_t d_lazyHealthCheckMinSampleCount{1}; uint16_t d_lazyHealthCheckFailedInterval{30}; uint16_t d_lazyHealthCheckMaxBackOff{3600}; uint8_t d_lazyHealthCheckThreshold{20}; LazyHealthCheckMode d_lazyHealthCheckMode{LazyHealthCheckMode::TimeoutOrServFail}; uint8_t maxCheckFailures{1}; uint8_t minRiseSuccesses{1}; Availability availability{Availability::Auto}; bool d_tlsSubjectIsAddr{false}; bool mustResolve{false}; bool useECS{false}; bool useProxyProtocol{false}; bool d_proxyProtocolAdvertiseTLS{false}; bool setCD{false}; bool disableZeroScope{false}; bool tcpFastOpen{false}; bool ipBindAddrNoPort{true}; bool reconnectOnUp{false}; bool d_tcpCheck{false}; bool d_tcpOnly{false}; bool d_addXForwardedHeaders{false}; // for DoH backends bool d_lazyHealthCheckUseExponentialBackOff{false}; bool d_upgradeToLazyHealthChecks{false}; }; struct HealthCheckMetrics { stat_t d_failures{0}; stat_t d_timeOuts{0}; stat_t d_parseErrors{0}; stat_t d_networkErrors{0}; stat_t d_mismatchErrors{0}; stat_t d_invalidResponseErrors{0}; }; DownstreamState(DownstreamState::Config&& config, std::shared_ptr tlsCtx, bool connect); DownstreamState(const ComboAddress& remote): DownstreamState(DownstreamState::Config(remote), nullptr, false) { } ~DownstreamState(); Config d_config; HealthCheckMetrics d_healthCheckMetrics; stat_t sendErrors{0}; stat_t outstanding{0}; stat_t reuseds{0}; stat_t queries{0}; stat_t responses{0}; stat_t nonCompliantResponses{0}; struct { stat_t sendErrors{0}; stat_t reuseds{0}; stat_t queries{0}; } prev; stat_t tcpDiedSendingQuery{0}; stat_t tcpDiedReadingResponse{0}; stat_t tcpGaveUp{0}; stat_t tcpReadTimeouts{0}; stat_t tcpWriteTimeouts{0}; stat_t tcpConnectTimeouts{0}; /* current number of connections to this backend */ stat_t tcpCurrentConnections{0}; /* maximum number of concurrent connections to this backend reached */ stat_t tcpMaxConcurrentConnections{0}; /* number of times we had to enforce the maximum concurrent connections limit */ stat_t tcpTooManyConcurrentConnections{0}; stat_t tcpReusedConnections{0}; stat_t tcpNewConnections{0}; stat_t tlsResumptions{0}; pdns::stat_t_trait tcpAvgQueriesPerConnection{0.0}; /* in ms */ pdns::stat_t_trait tcpAvgConnectionDuration{0.0}; pdns::stat_t_trait queryLoad{0.0}; pdns::stat_t_trait dropRate{0.0}; SharedLockGuarded> hashes; LockGuarded> mplexer{nullptr}; private: LockGuarded> d_idStatesMap; vector idStates; struct LazyHealthCheckStats { boost::circular_buffer d_lastResults; time_t d_nextCheck{0}; enum class LazyStatus: uint8_t { Healthy = 0, PotentialFailure, Failed }; LazyStatus d_status{LazyStatus::Healthy}; }; LockGuarded d_lazyHealthCheckStats; public: std::shared_ptr d_tlsCtx{nullptr}; std::vector sockets; StopWatch sw; QPSLimiter qps; #ifdef HAVE_XSK std::vector> d_xskInfos; std::vector> d_xskSockets; #endif std::atomic idOffset{0}; size_t socketsOffset{0}; double latencyUsec{0.0}; double latencyUsecTCP{0.0}; unsigned int d_nextCheck{0}; uint16_t currentCheckFailures{0}; std::atomic hashesComputed{false}; std::atomic connected{false}; bool upStatus{false}; private: void handleUDPTimeout(IDState& ids); void updateNextLazyHealthCheck(LazyHealthCheckStats& stats, bool checkScheduled, std::optional currentTime = std::nullopt); void connectUDPSockets(); #ifdef HAVE_XSK void addXSKDestination(int fd); void removeXSKDestination(int fd); #endif /* HAVE_XSK */ std::mutex connectLock; std::condition_variable d_connectedWait; #ifdef HAVE_XSK SharedLockGuarded> d_socketSourceAddresses; #endif std::atomic_flag threadStarted; uint8_t consecutiveSuccessfulChecks{0}; bool d_stopped{false}; public: void updateStatisticsInfo() { auto delta = sw.udiffAndSet() / 1000000.0; queryLoad.store(1.0 * (queries.load() - prev.queries.load()) / delta); dropRate.store(1.0 * (reuseds.load() - prev.reuseds.load()) / delta); prev.queries.store(queries.load()); prev.reuseds.store(reuseds.load()); } void start(); bool isUp() const { if (d_config.availability == Availability::Down) { return false; } else if (d_config.availability == Availability::Up) { return true; } return upStatus; } void setUp() { d_config.availability = Availability::Up; } void setUpStatus(bool newStatus) { upStatus = newStatus; if (!upStatus) { latencyUsec = 0.0; latencyUsecTCP = 0.0; } } void setDown() { d_config.availability = Availability::Down; latencyUsec = 0.0; latencyUsecTCP = 0.0; } void setAuto() { d_config.availability = Availability::Auto; } void setLazyAuto() { d_config.availability = Availability::Lazy; d_lazyHealthCheckStats.lock()->d_lastResults.set_capacity(d_config.d_lazyHealthCheckSampleSize); } bool healthCheckRequired(std::optional currentTime = std::nullopt); const string& getName() const { return d_config.name; } const string& getNameWithAddr() const { return d_config.nameWithAddr; } void setName(const std::string& newName) { d_config.name = newName; d_config.nameWithAddr = newName.empty() ? d_config.remote.toStringWithPort() : (d_config.name + " (" + d_config.remote.toStringWithPort()+ ")"); } string getStatus() const { string status; if (d_config.availability == DownstreamState::Availability::Up) { status = "UP"; } else if (d_config.availability == DownstreamState::Availability::Down) { status = "DOWN"; } else { status = (upStatus ? "up" : "down"); } return status; } bool reconnect(bool initialAttempt = false); void waitUntilConnected(); void hash(); void setId(const boost::uuids::uuid& newId); void setWeight(int newWeight); void stop(); bool isStopped() const { return d_stopped; } const boost::uuids::uuid& getID() const { return *d_config.id; } void updateTCPMetrics(size_t nbQueries, uint64_t durationMs) { tcpAvgQueriesPerConnection = (99.0 * tcpAvgQueriesPerConnection / 100.0) + (nbQueries / 100.0); tcpAvgConnectionDuration = (99.0 * tcpAvgConnectionDuration / 100.0) + (durationMs / 100.0); } void updateTCPLatency(double udiff) { latencyUsecTCP = (127.0 * latencyUsecTCP / 128.0) + udiff / 128.0; } void incQueriesCount() { ++queries; qps.addHit(); } void incCurrentConnectionsCount(); bool doHealthcheckOverTCP() const { return d_config.d_tcpOnly || d_config.d_tcpCheck || d_tlsCtx != nullptr; } bool isTCPOnly() const { return d_config.d_tcpOnly || d_tlsCtx != nullptr; } bool isDoH() const { return !d_config.d_dohPath.empty(); } bool passCrossProtocolQuery(std::unique_ptr&& cpq); int pickSocketForSending(); void pickSocketsReadyForReceiving(std::vector& ready); void handleUDPTimeouts(); void reportTimeoutOrError(); void reportResponse(uint8_t rcode); void submitHealthCheckResult(bool initial, bool newResult); time_t getNextLazyHealthCheck(); uint16_t saveState(InternalQueryState&&); void restoreState(uint16_t id, InternalQueryState&&); std::optional getState(uint16_t id); #ifdef HAVE_XSK void registerXsk(std::vector>& xsks); [[nodiscard]] ComboAddress pickSourceAddressForSending(); #endif /* HAVE_XSK */ dnsdist::Protocol getProtocol() const { if (isDoH()) { return dnsdist::Protocol::DoH; } if (d_tlsCtx != nullptr) { return dnsdist::Protocol::DoT; } if (isTCPOnly()) { return dnsdist::Protocol::DoTCP; } return dnsdist::Protocol::DoUDP; } double getRelevantLatencyUsec() const { if (isTCPOnly()) { return latencyUsecTCP; } return latencyUsec; } static int s_udpTimeout; static bool s_randomizeSockets; static bool s_randomizeIDs; }; using servers_t = vector>; void responderThread(std::shared_ptr state); extern RecursiveLockGuarded g_lua; extern std::string g_outputBuffer; // locking for this is ok, as locked by g_luamutex class DNSRule { public: virtual ~DNSRule () { } virtual bool matches(const DNSQuestion* dq) const = 0; virtual string toString() const = 0; mutable stat_t d_matches{0}; }; struct ServerPool { ServerPool(): d_servers(std::make_shared()) { } ~ServerPool() { } const std::shared_ptr getCache() const { return packetCache; }; bool getECS() const { return d_useECS; } void setECS(bool useECS) { d_useECS = useECS; } std::shared_ptr packetCache{nullptr}; std::shared_ptr policy{nullptr}; size_t poolLoad(); size_t countServers(bool upOnly); const std::shared_ptr getServers(); void addServer(shared_ptr& server); void removeServer(shared_ptr& server); private: SharedLockGuarded> d_servers; bool d_useECS{false}; }; enum ednsHeaderFlags { EDNS_HEADER_FLAG_NONE = 0, EDNS_HEADER_FLAG_DO = 32768 }; struct DNSDistRuleAction { std::shared_ptr d_rule; std::shared_ptr d_action; std::string d_name; boost::uuids::uuid d_id; uint64_t d_creationOrder; }; struct DNSDistResponseRuleAction { std::shared_ptr d_rule; std::shared_ptr d_action; std::string d_name; boost::uuids::uuid d_id; uint64_t d_creationOrder; }; extern GlobalStateHolder> g_dynblockSMT; extern DNSAction::Action g_dynBlockAction; extern GlobalStateHolder g_policy; extern GlobalStateHolder g_dstates; extern GlobalStateHolder g_pools; extern GlobalStateHolder > g_ruleactions; extern GlobalStateHolder > g_respruleactions; extern GlobalStateHolder > g_cachehitrespruleactions; extern GlobalStateHolder > g_selfansweredrespruleactions; extern GlobalStateHolder > g_cacheInsertedRespRuleActions; extern GlobalStateHolder g_ACL; extern ComboAddress g_serverControl; // not changed during runtime extern std::vector> g_tlslocals; extern std::vector> g_dohlocals; extern std::vector> g_doqlocals; extern std::vector> g_doh3locals; extern std::vector> g_frontends; extern bool g_truncateTC; extern bool g_fixupCase; extern int g_tcpRecvTimeout; extern int g_tcpSendTimeout; extern uint16_t g_maxOutstanding; extern std::atomic g_configurationDone; extern boost::optional g_maxTCPClientThreads; extern uint64_t g_maxTCPQueuedConnections; extern size_t g_maxTCPQueriesPerConn; extern size_t g_maxTCPConnectionDuration; extern size_t g_tcpInternalPipeBufferSize; extern pdns::stat16_t g_cacheCleaningDelay; extern pdns::stat16_t g_cacheCleaningPercentage; extern uint32_t g_staleCacheEntriesTTL; extern bool g_apiReadWrite; extern std::string g_apiConfigDirectory; extern bool g_servFailOnNoPolicy; extern size_t g_udpVectorSize; extern bool g_allowEmptyResponse; extern uint32_t g_socketUDPSendBuffer; extern uint32_t g_socketUDPRecvBuffer; extern shared_ptr g_defaultBPFFilter; extern std::vector > g_dynBPFFilters; struct LocalHolders { LocalHolders(): acl(g_ACL.getLocal()), policy(g_policy.getLocal()), ruleactions(g_ruleactions.getLocal()), cacheHitRespRuleactions(g_cachehitrespruleactions.getLocal()), cacheInsertedRespRuleActions(g_cacheInsertedRespRuleActions.getLocal()), selfAnsweredRespRuleactions(g_selfansweredrespruleactions.getLocal()), servers(g_dstates.getLocal()), dynNMGBlock(g_dynblockNMG.getLocal()), dynSMTBlock(g_dynblockSMT.getLocal()), pools(g_pools.getLocal()) { } LocalStateHolder acl; LocalStateHolder policy; LocalStateHolder > ruleactions; LocalStateHolder > cacheHitRespRuleactions; LocalStateHolder > cacheInsertedRespRuleActions; LocalStateHolder > selfAnsweredRespRuleactions; LocalStateHolder servers; LocalStateHolder > dynNMGBlock; LocalStateHolder > dynSMTBlock; LocalStateHolder pools; }; void tcpAcceptorThread(const std::vector& states); void setLuaNoSideEffect(); // if nothing has been declared, set that there are no side effects void setLuaSideEffect(); // set to report a side effect, cancelling all _no_ side effect calls bool getLuaNoSideEffect(); // set if there were only explicit declarations of _no_ side effect void resetLuaSideEffect(); // reset to indeterminate state bool responseContentMatches(const PacketBuffer& response, const DNSName& qname, const uint16_t qtype, const uint16_t qclass, const std::shared_ptr& remote); bool checkQueryHeaders(const struct dnsheader& dnsHeader, ClientState& clientState); extern std::vector> g_dnsCryptLocals; int handleDNSCryptQuery(PacketBuffer& packet, DNSCryptQuery& query, bool tcp, time_t now, PacketBuffer& response); bool checkDNSCryptQuery(const ClientState& cs, PacketBuffer& query, std::unique_ptr& dnsCryptQuery, time_t now, bool tcp); #include "dnsdist-snmp.hh" extern bool g_snmpEnabled; extern bool g_snmpTrapsEnabled; extern DNSDistSNMPAgent* g_snmpAgent; extern bool g_addEDNSToSelfGeneratedResponses; extern std::set g_capabilitiesToRetain; static const uint16_t s_udpIncomingBufferSize{1500}; // don't accept UDP queries larger than this value enum class ProcessQueryResult : uint8_t { Drop, SendAnswer, PassToBackend, Asynchronous }; ProcessQueryResult processQuery(DNSQuestion& dq, LocalHolders& holders, std::shared_ptr& selectedBackend); ProcessQueryResult processQueryAfterRules(DNSQuestion& dq, LocalHolders& holders, std::shared_ptr& selectedBackend); bool processResponse(PacketBuffer& response, const std::vector& respRuleActions, const std::vector& insertedRespRuleActions, DNSResponse& dr, bool muted); bool processRulesResult(const DNSAction::Action& action, DNSQuestion& dq, std::string& ruleresult, bool& drop); bool processResponseAfterRules(PacketBuffer& response, const std::vector& cacheInsertedRespRuleActions, DNSResponse& dr, bool muted); bool processResponderPacket(std::shared_ptr& dss, PacketBuffer& response, const std::vector& localRespRuleActions, const std::vector& cacheInsertedRespRuleActions, InternalQueryState&& ids); bool assignOutgoingUDPQueryToBackend(std::shared_ptr& downstream, uint16_t queryID, DNSQuestion& dnsQuestion, PacketBuffer& query, bool actuallySend = true); ssize_t udpClientSendRequestToBackend(const std::shared_ptr& backend, const int socketDesc, const PacketBuffer& request, bool healthCheck = false); bool sendUDPResponse(int origFD, const PacketBuffer& response, const int delayMsec, const ComboAddress& origDest, const ComboAddress& origRemote); 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); void handleResponseSent(const InternalQueryState& ids, double udiff, const ComboAddress& client, const ComboAddress& backend, unsigned int size, const dnsheader& cleartextDH, dnsdist::Protocol outgoingProtocol, bool fromBackend);