package xds import ( "errors" "fmt" envoy_extensions_filters_listener_http_inspector_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/listener/http_inspector/v3" "net" "net/url" "regexp" "sort" "strconv" "strings" "time" envoy_core_v3 "github.com/envoyproxy/go-control-plane/envoy/config/core/v3" envoy_listener_v3 "github.com/envoyproxy/go-control-plane/envoy/config/listener/v3" envoy_route_v3 "github.com/envoyproxy/go-control-plane/envoy/config/route/v3" envoy_grpc_http1_bridge_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/http/grpc_http1_bridge/v3" envoy_grpc_stats_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/http/grpc_stats/v3" envoy_http_router_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/http/router/v3" envoy_original_dst_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/listener/original_dst/v3" envoy_tls_inspector_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/listener/tls_inspector/v3" envoy_connection_limit_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/network/connection_limit/v3" envoy_http_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/network/http_connection_manager/v3" envoy_sni_cluster_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/network/sni_cluster/v3" envoy_tcp_proxy_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/network/tcp_proxy/v3" envoy_tls_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/transport_sockets/tls/v3" envoy_type_v3 "github.com/envoyproxy/go-control-plane/envoy/type/v3" "github.com/golang/protobuf/jsonpb" "github.com/golang/protobuf/proto" "github.com/golang/protobuf/ptypes" "github.com/golang/protobuf/ptypes/any" "github.com/golang/protobuf/ptypes/wrappers" "google.golang.org/protobuf/types/known/durationpb" "google.golang.org/protobuf/types/known/wrapperspb" "github.com/hashicorp/consul/acl" "github.com/hashicorp/consul/agent/connect" "github.com/hashicorp/consul/agent/proxycfg" "github.com/hashicorp/consul/agent/structs" "github.com/hashicorp/consul/lib" "github.com/hashicorp/consul/lib/stringslice" "github.com/hashicorp/consul/proto/pbpeering" "github.com/hashicorp/consul/sdk/iptables" "github.com/hashicorp/consul/types" ) const virtualIPTag = "virtual" // listenersFromSnapshot returns the xDS API representation of the "listeners" in the snapshot. func (s *ResourceGenerator) listenersFromSnapshot(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) { if cfgSnap == nil { return nil, errors.New("nil config given") } switch cfgSnap.Kind { case structs.ServiceKindConnectProxy: return s.listenersFromSnapshotConnectProxy(cfgSnap) case structs.ServiceKindTerminatingGateway: return s.listenersFromSnapshotGateway(cfgSnap) case structs.ServiceKindMeshGateway: return s.listenersFromSnapshotGateway(cfgSnap) case structs.ServiceKindIngressGateway: return s.listenersFromSnapshotGateway(cfgSnap) default: return nil, fmt.Errorf("Invalid service kind: %v", cfgSnap.Kind) } } // listenersFromSnapshotConnectProxy returns the "listeners" for a connect proxy service func (s *ResourceGenerator) listenersFromSnapshotConnectProxy(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) { resources := make([]proto.Message, 1) var err error // Configure inbound listener. resources[0], err = s.makeInboundListener(cfgSnap, PublicListenerName) if err != nil { return nil, err } // This outboundListener is exclusively used when transparent proxy mode is active. // In that situation there is a single listener where we are redirecting outbound traffic, // and each upstream gets a filter chain attached to that listener. var outboundListener *envoy_listener_v3.Listener if cfgSnap.Proxy.Mode == structs.ProxyModeTransparent { port := iptables.DefaultTProxyOutboundPort if cfgSnap.Proxy.TransparentProxy.OutboundListenerPort != 0 { port = cfgSnap.Proxy.TransparentProxy.OutboundListenerPort } originalDstFilter, err := makeEnvoyListenerFilter("envoy.filters.listener.original_dst", &envoy_original_dst_v3.OriginalDst{}) if err != nil { return nil, err } outboundListener = makePortListener(OutboundListenerName, "127.0.0.1", port, envoy_core_v3.TrafficDirection_OUTBOUND) outboundListener.FilterChains = make([]*envoy_listener_v3.FilterChain, 0) outboundListener.ListenerFilters = []*envoy_listener_v3.ListenerFilter{ // The original_dst filter is a listener filter that recovers the original destination // address before the iptables redirection. This filter is needed for transparent // proxies because they route to upstreams using filter chains that match on the // destination IP address. If the filter is not present, no chain will match. originalDstFilter, } } for uid, chain := range cfgSnap.ConnectProxy.DiscoveryChain { upstreamCfg := cfgSnap.ConnectProxy.UpstreamConfig[uid] explicit := upstreamCfg.HasLocalPortOrSocket() implicit := cfgSnap.ConnectProxy.IsImplicitUpstream(uid) if !implicit && !explicit { // Discovery chain is not associated with a known explicit or implicit upstream so it is skipped. continue } cfg := s.getAndModifyUpstreamConfigForListener(uid, upstreamCfg, chain) // If escape hatch is present, create a listener from it and move on to the next if cfg.EnvoyListenerJSON != "" { upstreamListener, err := makeListenerFromUserConfig(cfg.EnvoyListenerJSON) if err != nil { return nil, err } resources = append(resources, upstreamListener) continue } // RDS, Envoy's Route Discovery Service, is only used for HTTP services with a customized discovery chain. useRDS := chain.Protocol != "tcp" && !chain.Default var clusterName string if !useRDS { // When not using RDS we must generate a cluster name to attach to the filter chain. // With RDS, cluster names get attached to the dynamic routes instead. target, err := simpleChainTarget(chain) if err != nil { return nil, err } clusterName = CustomizeClusterName(target.Name, chain) } filterName := fmt.Sprintf("%s.%s.%s.%s", chain.ServiceName, chain.Namespace, chain.Partition, chain.Datacenter) // Generate the upstream listeners for when they are explicitly set with a local bind port or socket path if upstreamCfg != nil && upstreamCfg.HasLocalPortOrSocket() { filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ routeName: uid.EnvoyID(), clusterName: clusterName, filterName: filterName, protocol: cfg.Protocol, useRDS: useRDS, }) if err != nil { return nil, err } upstreamListener := makeListener(uid.EnvoyID(), upstreamCfg, envoy_core_v3.TrafficDirection_OUTBOUND) upstreamListener.FilterChains = []*envoy_listener_v3.FilterChain{ filterChain, } resources = append(resources, upstreamListener) // Avoid creating filter chains below for upstreams that have dedicated listeners continue } // The rest of this loop is used exclusively for transparent proxies. // Below we create a filter chain per upstream, rather than a listener per upstream // as we do for explicit upstreams above. filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ routeName: uid.EnvoyID(), clusterName: clusterName, filterName: filterName, protocol: cfg.Protocol, useRDS: useRDS, }) if err != nil { return nil, err } endpoints := cfgSnap.ConnectProxy.WatchedUpstreamEndpoints[uid][chain.ID()] uniqueAddrs := make(map[string]struct{}) // Match on the virtual IP for the upstream service (identified by the chain's ID). // We do not match on all endpoints here since it would lead to load balancing across // all instances when any instance address is dialed. for _, e := range endpoints { if e.Service.Kind == structs.ServiceKind(structs.TerminatingGateway) { key := structs.ServiceGatewayVirtualIPTag(chain.CompoundServiceName()) if vip := e.Service.TaggedAddresses[key]; vip.Address != "" { uniqueAddrs[vip.Address] = struct{}{} } continue } if vip := e.Service.TaggedAddresses[structs.TaggedAddressVirtualIP]; vip.Address != "" { uniqueAddrs[vip.Address] = struct{}{} } // The virtualIPTag is used by consul-k8s to store the ClusterIP for a service. // We only match on this virtual IP if the upstream is in the proxy's partition. // This is because the IP is not guaranteed to be unique across k8s clusters. if acl.EqualPartitions(e.Node.PartitionOrDefault(), cfgSnap.ProxyID.PartitionOrDefault()) { if vip := e.Service.TaggedAddresses[virtualIPTag]; vip.Address != "" { uniqueAddrs[vip.Address] = struct{}{} } } } if len(uniqueAddrs) > 2 { s.Logger.Debug("detected multiple virtual IPs for an upstream, all will be used to match traffic", "upstream", uid, "ip_count", len(uniqueAddrs)) } // For every potential address we collected, create the appropriate address prefix to match on. // In this case we are matching on exact addresses, so the prefix is the address itself, // and the prefix length is based on whether it's IPv4 or IPv6. filterChain.FilterChainMatch = makeFilterChainMatchFromAddrs(uniqueAddrs) // Only attach the filter chain if there are addresses to match on if filterChain.FilterChainMatch != nil && len(filterChain.FilterChainMatch.PrefixRanges) > 0 { outboundListener.FilterChains = append(outboundListener.FilterChains, filterChain) } } requiresTLSInspector := false requiresHTTPInspector := false configuredPorts := make(map[int]interface{}) err = cfgSnap.ConnectProxy.DestinationsUpstream.ForEachKeyE(func(uid proxycfg.UpstreamID) error { svcConfig, ok := cfgSnap.ConnectProxy.DestinationsUpstream.Get(uid) if !ok || svcConfig == nil { return nil } if structs.IsProtocolHTTPLike(svcConfig.Protocol) { if _, ok := configuredPorts[svcConfig.Destination.Port]; ok { return nil } configuredPorts[svcConfig.Destination.Port] = struct{}{} const name = "~http" //name used for the shared route name routeName := clusterNameForDestination(cfgSnap, name, fmt.Sprintf("%d", svcConfig.Destination.Port), svcConfig.NamespaceOrDefault(), svcConfig.PartitionOrDefault()) filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ routeName: routeName, filterName: routeName, protocol: svcConfig.Protocol, useRDS: true, }) if err != nil { return err } filterChain.FilterChainMatch = makeFilterChainMatchFromAddressWithPort("", svcConfig.Destination.Port) outboundListener.FilterChains = append(outboundListener.FilterChains, filterChain) requiresHTTPInspector = true } else { for _, address := range svcConfig.Destination.Addresses { clusterName := clusterNameForDestination(cfgSnap, uid.Name, address, uid.NamespaceOrDefault(), uid.PartitionOrDefault()) filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ routeName: uid.EnvoyID(), clusterName: clusterName, filterName: clusterName, protocol: svcConfig.Protocol, }) if err != nil { return err } filterChain.FilterChainMatch = makeFilterChainMatchFromAddressWithPort(address, svcConfig.Destination.Port) outboundListener.FilterChains = append(outboundListener.FilterChains, filterChain) requiresTLSInspector = len(filterChain.FilterChainMatch.ServerNames) != 0 || requiresTLSInspector } } return nil }) if err != nil { return nil, err } if requiresTLSInspector { tlsInspector, err := makeTLSInspectorListenerFilter() if err != nil { return nil, err } outboundListener.ListenerFilters = append(outboundListener.ListenerFilters, tlsInspector) } if requiresHTTPInspector { httpInspector, err := makeHTTPInspectorListenerFilter() if err != nil { return nil, err } outboundListener.ListenerFilters = append(outboundListener.ListenerFilters, httpInspector) } // Looping over explicit and implicit upstreams is only needed for cross-peer // because they do not have discovery chains. for _, uid := range cfgSnap.ConnectProxy.PeeredUpstreamIDs() { upstreamCfg := cfgSnap.ConnectProxy.UpstreamConfig[uid] explicit := upstreamCfg.HasLocalPortOrSocket() implicit := cfgSnap.ConnectProxy.IsImplicitUpstream(uid) if !implicit && !explicit { // Not associated with a known explicit or implicit upstream so it is skipped. continue } peerMeta := cfgSnap.ConnectProxy.UpstreamPeerMeta(uid) cfg := s.getAndModifyUpstreamConfigForPeeredListener(uid, upstreamCfg, peerMeta) // If escape hatch is present, create a listener from it and move on to the next if cfg.EnvoyListenerJSON != "" { upstreamListener, err := makeListenerFromUserConfig(cfg.EnvoyListenerJSON) if err != nil { s.Logger.Error("failed to parse envoy_listener_json", "upstream", uid, "error", err) continue } resources = append(resources, upstreamListener) continue } tbs, ok := cfgSnap.ConnectProxy.UpstreamPeerTrustBundles.Get(uid.Peer) if !ok { // this should never happen since we loop through upstreams with // set trust bundles return nil, fmt.Errorf("trust bundle not ready for peer %s", uid.Peer) } clusterName := generatePeeredClusterName(uid, tbs) // Generate the upstream listeners for when they are explicitly set with a local bind port or socket path if upstreamCfg != nil && upstreamCfg.HasLocalPortOrSocket() { filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ clusterName: clusterName, filterName: fmt.Sprintf("%s.%s.%s", upstreamCfg.DestinationName, upstreamCfg.DestinationNamespace, upstreamCfg.DestinationPeer), routeName: uid.EnvoyID(), protocol: cfg.Protocol, useRDS: false, statPrefix: "upstream_peered.", }) if err != nil { return nil, err } upstreamListener := makeListener(uid.EnvoyID(), upstreamCfg, envoy_core_v3.TrafficDirection_OUTBOUND) upstreamListener.FilterChains = []*envoy_listener_v3.FilterChain{ filterChain, } resources = append(resources, upstreamListener) // Avoid creating filter chains below for upstreams that have dedicated listeners continue } // The rest of this loop is used exclusively for transparent proxies. // Below we create a filter chain per upstream, rather than a listener per upstream // as we do for explicit upstreams above. filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ routeName: uid.EnvoyID(), clusterName: clusterName, filterName: fmt.Sprintf("%s.%s.%s", uid.Name, uid.NamespaceOrDefault(), uid.Peer), protocol: cfg.Protocol, useRDS: false, statPrefix: "upstream_peered.", }) if err != nil { return nil, err } endpoints, _ := cfgSnap.ConnectProxy.PeerUpstreamEndpoints.Get(uid) uniqueAddrs := make(map[string]struct{}) // Match on the virtual IP for the upstream service (identified by the chain's ID). // We do not match on all endpoints here since it would lead to load balancing across // all instances when any instance address is dialed. for _, e := range endpoints { if vip := e.Service.TaggedAddresses[structs.TaggedAddressVirtualIP]; vip.Address != "" { uniqueAddrs[vip.Address] = struct{}{} } // The virtualIPTag is used by consul-k8s to store the ClusterIP for a service. // For services imported from a peer,the partition will be equal in all cases. if acl.EqualPartitions(e.Node.PartitionOrDefault(), cfgSnap.ProxyID.PartitionOrDefault()) { if vip := e.Service.TaggedAddresses[virtualIPTag]; vip.Address != "" { uniqueAddrs[vip.Address] = struct{}{} } } } if len(uniqueAddrs) > 2 { s.Logger.Debug("detected multiple virtual IPs for an upstream, all will be used to match traffic", "upstream", uid, "ip_count", len(uniqueAddrs)) } // For every potential address we collected, create the appropriate address prefix to match on. // In this case we are matching on exact addresses, so the prefix is the address itself, // and the prefix length is based on whether it's IPv4 or IPv6. filterChain.FilterChainMatch = makeFilterChainMatchFromAddrs(uniqueAddrs) // Only attach the filter chain if there are addresses to match on if filterChain.FilterChainMatch != nil && len(filterChain.FilterChainMatch.PrefixRanges) > 0 { outboundListener.FilterChains = append(outboundListener.FilterChains, filterChain) } } if outboundListener != nil { // Add a passthrough for every mesh endpoint that can be dialed directly, // as opposed to via a virtual IP. var passthroughChains []*envoy_listener_v3.FilterChain for _, targets := range cfgSnap.ConnectProxy.PassthroughUpstreams { for tid, addrs := range targets { uid := proxycfg.NewUpstreamIDFromTargetID(tid) sni := connect.ServiceSNI( uid.Name, "", uid.NamespaceOrDefault(), uid.PartitionOrDefault(), cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain) filterName := fmt.Sprintf("%s.%s.%s.%s", uid.Name, uid.NamespaceOrDefault(), uid.PartitionOrDefault(), cfgSnap.Datacenter) filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ clusterName: "passthrough~" + sni, filterName: filterName, protocol: "tcp", }) if err != nil { return nil, err } filterChain.FilterChainMatch = makeFilterChainMatchFromAddrs(addrs) passthroughChains = append(passthroughChains, filterChain) } } outboundListener.FilterChains = append(outboundListener.FilterChains, passthroughChains...) // Filter chains are stable sorted to avoid draining if the list is provided out of order sort.SliceStable(outboundListener.FilterChains, func(i, j int) bool { si := "" sj := "" if len(outboundListener.FilterChains[i].FilterChainMatch.PrefixRanges) > 0 { si += outboundListener.FilterChains[i].FilterChainMatch.PrefixRanges[0].AddressPrefix + "/" + outboundListener.FilterChains[i].FilterChainMatch.PrefixRanges[0].PrefixLen.String() + ":" + outboundListener.FilterChains[i].FilterChainMatch.DestinationPort.String() } if len(outboundListener.FilterChains[i].FilterChainMatch.ServerNames) > 0 { si += outboundListener.FilterChains[i].FilterChainMatch.ServerNames[0] + ":" + outboundListener.FilterChains[i].FilterChainMatch.DestinationPort.String() } else { si += outboundListener.FilterChains[i].FilterChainMatch.DestinationPort.String() } if len(outboundListener.FilterChains[j].FilterChainMatch.PrefixRanges) > 0 { sj += outboundListener.FilterChains[j].FilterChainMatch.PrefixRanges[0].AddressPrefix + "/" + outboundListener.FilterChains[j].FilterChainMatch.PrefixRanges[0].PrefixLen.String() + ":" + outboundListener.FilterChains[j].FilterChainMatch.DestinationPort.String() } if len(outboundListener.FilterChains[j].FilterChainMatch.ServerNames) > 0 { sj += outboundListener.FilterChains[j].FilterChainMatch.ServerNames[0] + ":" + outboundListener.FilterChains[j].FilterChainMatch.DestinationPort.String() } else { sj += outboundListener.FilterChains[j].FilterChainMatch.DestinationPort.String() } return si < sj }) // Add a catch-all filter chain that acts as a TCP proxy to destinations outside the mesh if meshConf := cfgSnap.MeshConfig(); meshConf == nil || !meshConf.TransparentProxy.MeshDestinationsOnly { filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ clusterName: OriginalDestinationClusterName, filterName: OriginalDestinationClusterName, protocol: "tcp", }) if err != nil { return nil, err } outboundListener.DefaultFilterChain = filterChain } // Only add the outbound listener if configured. if len(outboundListener.FilterChains) > 0 || outboundListener.DefaultFilterChain != nil { resources = append(resources, outboundListener) } } // Looping over explicit upstreams is only needed for prepared queries because they do not have discovery chains for uid, u := range cfgSnap.ConnectProxy.UpstreamConfig { if u.DestinationType != structs.UpstreamDestTypePreparedQuery { continue } cfg, err := structs.ParseUpstreamConfig(u.Config) if err != nil { // Don't hard fail on a config typo, just warn. The parse func returns // default config if there is an error so it's safe to continue. s.Logger.Warn("failed to parse", "upstream", uid, "error", err) } // If escape hatch is present, create a listener from it and move on to the next if cfg.EnvoyListenerJSON != "" { upstreamListener, err := makeListenerFromUserConfig(cfg.EnvoyListenerJSON) if err != nil { s.Logger.Error("failed to parse envoy_listener_json", "upstream", uid, "error", err) continue } resources = append(resources, upstreamListener) continue } upstreamListener := makeListener(uid.EnvoyID(), u, envoy_core_v3.TrafficDirection_OUTBOUND) filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ // TODO (SNI partition) add partition for upstream SNI clusterName: connect.UpstreamSNI(u, "", cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain), filterName: uid.EnvoyID(), routeName: uid.EnvoyID(), protocol: cfg.Protocol, }) if err != nil { return nil, err } upstreamListener.FilterChains = []*envoy_listener_v3.FilterChain{ filterChain, } resources = append(resources, upstreamListener) } cfgSnap.Proxy.Expose.Finalize() paths := cfgSnap.Proxy.Expose.Paths // Add service health checks to the list of paths to create listeners for if needed if cfgSnap.Proxy.Expose.Checks { psid := structs.NewServiceID(cfgSnap.Proxy.DestinationServiceID, &cfgSnap.ProxyID.EnterpriseMeta) for _, check := range cfgSnap.ConnectProxy.WatchedServiceChecks[psid] { p, err := parseCheckPath(check) if err != nil { s.Logger.Warn("failed to create listener for", "check", check.CheckID, "error", err) continue } paths = append(paths, p) } } // Configure additional listener for exposed check paths for _, path := range paths { clusterName := LocalAppClusterName if path.LocalPathPort != cfgSnap.Proxy.LocalServicePort { clusterName = makeExposeClusterName(path.LocalPathPort) } l, err := s.makeExposedCheckListener(cfgSnap, clusterName, path) if err != nil { return nil, err } resources = append(resources, l) } return resources, nil } func makeFilterChainMatchFromAddrs(addrs map[string]struct{}) *envoy_listener_v3.FilterChainMatch { ranges := make([]*envoy_core_v3.CidrRange, 0) for addr := range addrs { ip := net.ParseIP(addr) if ip == nil { continue } pfxLen := uint32(32) if ip.To4() == nil { pfxLen = 128 } ranges = append(ranges, &envoy_core_v3.CidrRange{ AddressPrefix: addr, PrefixLen: &wrappers.UInt32Value{Value: pfxLen}, }) } // The match rules are stable sorted to avoid draining if the list is provided out of order sort.SliceStable(ranges, func(i, j int) bool { return ranges[i].AddressPrefix < ranges[j].AddressPrefix }) return &envoy_listener_v3.FilterChainMatch{ PrefixRanges: ranges, } } func makeFilterChainMatchFromAddressWithPort(address string, port int) *envoy_listener_v3.FilterChainMatch { ranges := make([]*envoy_core_v3.CidrRange, 0) ip := net.ParseIP(address) if ip == nil { if address != "" { return &envoy_listener_v3.FilterChainMatch{ ServerNames: []string{address}, DestinationPort: &wrappers.UInt32Value{Value: uint32(port)}, } } return &envoy_listener_v3.FilterChainMatch{ DestinationPort: &wrappers.UInt32Value{Value: uint32(port)}, } } pfxLen := uint32(32) if ip.To4() == nil { pfxLen = 128 } ranges = append(ranges, &envoy_core_v3.CidrRange{ AddressPrefix: address, PrefixLen: &wrappers.UInt32Value{Value: pfxLen}, }) return &envoy_listener_v3.FilterChainMatch{ PrefixRanges: ranges, DestinationPort: &wrappers.UInt32Value{Value: uint32(port)}, } } func parseCheckPath(check structs.CheckType) (structs.ExposePath, error) { var path structs.ExposePath if check.HTTP != "" { path.Protocol = "http" // Get path and local port from original HTTP target u, err := url.Parse(check.HTTP) if err != nil { return path, fmt.Errorf("failed to parse url '%s': %v", check.HTTP, err) } path.Path = u.Path _, portStr, err := net.SplitHostPort(u.Host) if err != nil { return path, fmt.Errorf("failed to parse port from '%s': %v", check.HTTP, err) } path.LocalPathPort, err = strconv.Atoi(portStr) if err != nil { return path, fmt.Errorf("failed to parse port from '%s': %v", check.HTTP, err) } // Get listener port from proxied HTTP target u, err = url.Parse(check.ProxyHTTP) if err != nil { return path, fmt.Errorf("failed to parse url '%s': %v", check.ProxyHTTP, err) } _, portStr, err = net.SplitHostPort(u.Host) if err != nil { return path, fmt.Errorf("failed to parse port from '%s': %v", check.ProxyHTTP, err) } path.ListenerPort, err = strconv.Atoi(portStr) if err != nil { return path, fmt.Errorf("failed to parse port from '%s': %v", check.ProxyHTTP, err) } } if check.GRPC != "" { path.Path = "/grpc.health.v1.Health/Check" path.Protocol = "http2" // Get local port from original GRPC target of the form: host/service proxyServerAndService := strings.SplitN(check.GRPC, "/", 2) _, portStr, err := net.SplitHostPort(proxyServerAndService[0]) if err != nil { return path, fmt.Errorf("failed to split host/port from '%s': %v", check.GRPC, err) } path.LocalPathPort, err = strconv.Atoi(portStr) if err != nil { return path, fmt.Errorf("failed to parse port from '%s': %v", check.GRPC, err) } // Get listener port from proxied GRPC target of the form: host/service proxyServerAndService = strings.SplitN(check.ProxyGRPC, "/", 2) _, portStr, err = net.SplitHostPort(proxyServerAndService[0]) if err != nil { return path, fmt.Errorf("failed to split host/port from '%s': %v", check.ProxyGRPC, err) } path.ListenerPort, err = strconv.Atoi(portStr) if err != nil { return path, fmt.Errorf("failed to parse port from '%s': %v", check.ProxyGRPC, err) } } path.ParsedFromCheck = true return path, nil } // listenersFromSnapshotGateway returns the "listener" for a terminating-gateway or mesh-gateway service func (s *ResourceGenerator) listenersFromSnapshotGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) { cfg, err := ParseGatewayConfig(cfgSnap.Proxy.Config) if err != nil { // Don't hard fail on a config typo, just warn. The parse func returns // default config if there is an error so it's safe to continue. s.Logger.Warn("failed to parse Connect.Proxy.Config", "error", err) } // We'll collect all of the desired listeners first, and deduplicate them later. type namedAddress struct { name string structs.ServiceAddress } addrs := make([]namedAddress, 0) var resources []proto.Message if !cfg.NoDefaultBind { addr := cfgSnap.Address if addr == "" { addr = "0.0.0.0" } a := structs.ServiceAddress{ Address: addr, Port: cfgSnap.Port, } addrs = append(addrs, namedAddress{name: "default", ServiceAddress: a}) } if cfg.BindTaggedAddresses { for name, addrCfg := range cfgSnap.TaggedAddresses { a := structs.ServiceAddress{ Address: addrCfg.Address, Port: addrCfg.Port, } addrs = append(addrs, namedAddress{name: name, ServiceAddress: a}) } } for name, addrCfg := range cfg.BindAddresses { a := structs.ServiceAddress{ Address: addrCfg.Address, Port: addrCfg.Port, } addrs = append(addrs, namedAddress{name: name, ServiceAddress: a}) } // Prevent invalid configurations of binding to the same port/addr twice // including with the any addresses // // Sort the list and then if two items share a service address, take the // first one to ensure we generate one listener per address and it's // stable. sort.Slice(addrs, func(i, j int) bool { return addrs[i].name < addrs[j].name }) // Make listeners and deduplicate on the fly. seen := make(map[structs.ServiceAddress]bool) for _, a := range addrs { if seen[a.ServiceAddress] { continue } seen[a.ServiceAddress] = true var l *envoy_listener_v3.Listener switch cfgSnap.Kind { case structs.ServiceKindTerminatingGateway: l, err = s.makeTerminatingGatewayListener(cfgSnap, a.name, a.Address, a.Port) if err != nil { return nil, err } case structs.ServiceKindIngressGateway: listeners, err := s.makeIngressGatewayListeners(a.Address, cfgSnap) if err != nil { return nil, err } resources = append(resources, listeners...) case structs.ServiceKindMeshGateway: l, err = s.makeMeshGatewayListener(a.name, a.Address, a.Port, cfgSnap) if err != nil { return nil, err } } if l != nil { resources = append(resources, l) } } return resources, err } // makeListener returns a listener with name and bind details set. Filters must // be added before it's useful. // // Note on names: Envoy listeners attempt graceful transitions of connections // when their config changes but that means they can't have their bind address // or port changed in a running instance. Since our users might choose to change // a bind address or port for the public or upstream listeners, we need to // encode those into the unique name for the listener such that if the user // changes them, we actually create a whole new listener on the new address and // port. Envoy should take care of closing the old one once it sees it's no // longer in the config. func makeListener(name string, upstream *structs.Upstream, trafficDirection envoy_core_v3.TrafficDirection) *envoy_listener_v3.Listener { if upstream.LocalBindPort == 0 && upstream.LocalBindSocketPath != "" { return makePipeListener(name, upstream.LocalBindSocketPath, upstream.LocalBindSocketMode, trafficDirection) } return makePortListenerWithDefault(name, upstream.LocalBindAddress, upstream.LocalBindPort, trafficDirection) } func makePortListener(name, addr string, port int, trafficDirection envoy_core_v3.TrafficDirection) *envoy_listener_v3.Listener { return &envoy_listener_v3.Listener{ Name: fmt.Sprintf("%s:%s:%d", name, addr, port), Address: makeAddress(addr, port), TrafficDirection: trafficDirection, } } func makePortListenerWithDefault(name, addr string, port int, trafficDirection envoy_core_v3.TrafficDirection) *envoy_listener_v3.Listener { if addr == "" { addr = "127.0.0.1" } return makePortListener(name, addr, port, trafficDirection) } func makePipeListener(name, path string, mode_str string, trafficDirection envoy_core_v3.TrafficDirection) *envoy_listener_v3.Listener { // We've already validated this, so it should not fail. mode, err := strconv.ParseUint(mode_str, 0, 32) if err != nil { mode = 0 } return &envoy_listener_v3.Listener{ Name: fmt.Sprintf("%s:%s", name, path), Address: makePipeAddress(path, uint32(mode)), TrafficDirection: trafficDirection, } } // makeListenerFromUserConfig returns the listener config decoded from an // arbitrary proto3 json format string or an error if it's invalid. // // For now we only support embedding in JSON strings because of the hcl parsing // pain (see Background section in the comment for decode.HookWeakDecodeFromSlice). // This may be fixed in decode.HookWeakDecodeFromSlice in the future. // // When we do that we can support just nesting the config directly into the // JSON/hcl naturally but this is a stop-gap that gets us an escape hatch // immediately. It's also probably not a bad thing to support long-term since // any config generated by other systems will likely be in canonical protobuf // from rather than our slight variant in JSON/hcl. func makeListenerFromUserConfig(configJSON string) (*envoy_listener_v3.Listener, error) { // Type field is present so decode it as a any.Any var any any.Any if err := jsonpb.UnmarshalString(configJSON, &any); err != nil { return nil, err } var l envoy_listener_v3.Listener if err := proto.Unmarshal(any.Value, &l); err != nil { return nil, err } return &l, nil } // Ensure that the first filter in each filter chain of a public listener is // the authz filter to prevent unauthorized access. func (s *ResourceGenerator) injectConnectFilters(cfgSnap *proxycfg.ConfigSnapshot, listener *envoy_listener_v3.Listener) error { authzFilter, err := makeRBACNetworkFilter( cfgSnap.ConnectProxy.Intentions, cfgSnap.IntentionDefaultAllow, rbacLocalInfo{ trustDomain: cfgSnap.Roots.TrustDomain, datacenter: cfgSnap.Datacenter, partition: cfgSnap.ProxyID.PartitionOrDefault(), }, cfgSnap.ConnectProxy.InboundPeerTrustBundles, ) if err != nil { return err } for idx := range listener.FilterChains { // Insert our authz filter before any others listener.FilterChains[idx].Filters = append([]*envoy_listener_v3.Filter{ authzFilter, }, listener.FilterChains[idx].Filters...) } return nil } const ( httpConnectionManagerOldName = "envoy.http_connection_manager" httpConnectionManagerNewName = "envoy.filters.network.http_connection_manager" ) func extractRdsResourceNames(listener *envoy_listener_v3.Listener) ([]string, error) { var found []string for chainIdx, chain := range listener.FilterChains { for filterIdx, filter := range chain.Filters { if filter.Name != httpConnectionManagerNewName { continue } tc, ok := filter.ConfigType.(*envoy_listener_v3.Filter_TypedConfig) if !ok { return nil, fmt.Errorf( "filter chain %d has a %q filter %d with an unsupported config type: %T", chainIdx, filter.Name, filterIdx, filter.ConfigType, ) } var hcm envoy_http_v3.HttpConnectionManager if err := ptypes.UnmarshalAny(tc.TypedConfig, &hcm); err != nil { return nil, err } if hcm.RouteSpecifier == nil { continue } rds, ok := hcm.RouteSpecifier.(*envoy_http_v3.HttpConnectionManager_Rds) if !ok { continue } if rds.Rds == nil { continue } found = append(found, rds.Rds.RouteConfigName) } } return found, nil } // Locate the existing http connect manager L4 filter and inject our RBAC filter at the top. func injectHTTPFilterOnFilterChains( listener *envoy_listener_v3.Listener, authzFilter *envoy_http_v3.HttpFilter, ) error { for chainIdx, chain := range listener.FilterChains { var ( hcmFilter *envoy_listener_v3.Filter hcmFilterIdx int ) for filterIdx, filter := range chain.Filters { if filter.Name == httpConnectionManagerOldName || filter.Name == httpConnectionManagerNewName { hcmFilter = filter hcmFilterIdx = filterIdx break } } if hcmFilter == nil { return fmt.Errorf( "filter chain %d lacks either a %q or %q filter", chainIdx, httpConnectionManagerOldName, httpConnectionManagerNewName, ) } var hcm envoy_http_v3.HttpConnectionManager tc, ok := hcmFilter.ConfigType.(*envoy_listener_v3.Filter_TypedConfig) if !ok { return fmt.Errorf( "filter chain %d has a %q filter with an unsupported config type: %T", chainIdx, hcmFilter.Name, hcmFilter.ConfigType, ) } if err := ptypes.UnmarshalAny(tc.TypedConfig, &hcm); err != nil { return err } // Insert our authz filter before any others hcm.HttpFilters = append([]*envoy_http_v3.HttpFilter{ authzFilter, }, hcm.HttpFilters...) // And persist the modified filter. newFilter, err := makeFilter(hcmFilter.Name, &hcm) if err != nil { return err } chain.Filters[hcmFilterIdx] = newFilter } return nil } // NOTE: This method MUST only be used for connect proxy public listeners, // since TLS validation will be done against root certs for all peers // that might dial this proxy. func (s *ResourceGenerator) injectConnectTLSForPublicListener(cfgSnap *proxycfg.ConfigSnapshot, listener *envoy_listener_v3.Listener) error { transportSocket, err := createDownstreamTransportSocketForConnectTLS(cfgSnap, cfgSnap.PeeringTrustBundles()) if err != nil { return err } for idx := range listener.FilterChains { listener.FilterChains[idx].TransportSocket = transportSocket } return nil } func createDownstreamTransportSocketForConnectTLS(cfgSnap *proxycfg.ConfigSnapshot, peerBundles []*pbpeering.PeeringTrustBundle) (*envoy_core_v3.TransportSocket, error) { switch cfgSnap.Kind { case structs.ServiceKindConnectProxy: case structs.ServiceKindMeshGateway: default: return nil, fmt.Errorf("cannot inject peering trust bundles for kind %q", cfgSnap.Kind) } // Create TLS validation context for mTLS with leaf certificate and root certs. tlsContext := makeCommonTLSContext( cfgSnap.Leaf(), cfgSnap.RootPEMs(), makeTLSParametersFromProxyTLSConfig(cfgSnap.MeshConfigTLSIncoming()), ) // Inject peering trust bundles if this service is exported to peered clusters. if len(peerBundles) > 0 { spiffeConfig, err := makeSpiffeValidatorConfig( cfgSnap.Roots.TrustDomain, cfgSnap.RootPEMs(), peerBundles, ) if err != nil { return nil, err } typ, ok := tlsContext.ValidationContextType.(*envoy_tls_v3.CommonTlsContext_ValidationContext) if !ok { return nil, fmt.Errorf("unexpected type for TLS context validation: %T", tlsContext.ValidationContextType) } // makeCommonTLSFromLead injects the local trust domain's CA root certs as the TrustedCA. // We nil it out here since the local roots are included in the SPIFFE validator config. typ.ValidationContext.TrustedCa = nil typ.ValidationContext.CustomValidatorConfig = &envoy_core_v3.TypedExtensionConfig{ // The typed config name is hard-coded because it is not available as a wellknown var in the control plane lib. Name: "envoy.tls.cert_validator.spiffe", TypedConfig: spiffeConfig, } } return makeDownstreamTLSTransportSocket(&envoy_tls_v3.DownstreamTlsContext{ CommonTlsContext: tlsContext, RequireClientCertificate: &wrappers.BoolValue{Value: true}, }) } // SPIFFECertValidatorConfig is used to validate certificates from trust domains other than our own. // With cluster peering we expect peered clusters to have independent certificate authorities. // This means that we cannot use a single set of root CA certificates to validate client certificates for mTLS, // but rather we need to validate against different roots depending on the trust domain of the certificate presented. func makeSpiffeValidatorConfig(trustDomain, roots string, peerBundles []*pbpeering.PeeringTrustBundle) (*any.Any, error) { // Store the trust bundle for the local trust domain. bundles := map[string]string{trustDomain: roots} // Store the trust bundle for each trust domain of the peers this proxy is exported to. // This allows us to validate traffic from other trust domains. for _, b := range peerBundles { var pems string for _, pem := range b.RootPEMs { pems += lib.EnsureTrailingNewline(pem) } bundles[b.TrustDomain] = pems } cfg := &envoy_tls_v3.SPIFFECertValidatorConfig{ TrustDomains: make([]*envoy_tls_v3.SPIFFECertValidatorConfig_TrustDomain, 0, len(bundles)), } for domain, bundle := range bundles { cfg.TrustDomains = append(cfg.TrustDomains, &envoy_tls_v3.SPIFFECertValidatorConfig_TrustDomain{ Name: domain, TrustBundle: &envoy_core_v3.DataSource{ Specifier: &envoy_core_v3.DataSource_InlineString{ InlineString: bundle, }, }, }) } // Sort the trust domains so that the output is stable. // This benefits tests but also prevents Envoy from mistakenly thinking the listener // changed and needs to be drained only because this ordering is different. sort.Slice(cfg.TrustDomains, func(i int, j int) bool { return cfg.TrustDomains[i].Name < cfg.TrustDomains[j].Name }) return ptypes.MarshalAny(cfg) } func (s *ResourceGenerator) makeInboundListener(cfgSnap *proxycfg.ConfigSnapshot, name string) (proto.Message, error) { var l *envoy_listener_v3.Listener var err error cfg, err := ParseProxyConfig(cfgSnap.Proxy.Config) if err != nil { // Don't hard fail on a config typo, just warn. The parse func returns // default config if there is an error so it's safe to continue. s.Logger.Warn("failed to parse Connect.Proxy.Config", "error", err) } // This controls if we do L4 or L7 intention checks. useHTTPFilter := structs.IsProtocolHTTPLike(cfg.Protocol) // Generate and return custom public listener from config if one was provided. if cfg.PublicListenerJSON != "" { l, err = makeListenerFromUserConfig(cfg.PublicListenerJSON) if err != nil { return nil, err } // For HTTP-like services attach an RBAC http filter and do a best-effort insert if useHTTPFilter { httpAuthzFilter, err := makeRBACHTTPFilter( cfgSnap.ConnectProxy.Intentions, cfgSnap.IntentionDefaultAllow, rbacLocalInfo{ trustDomain: cfgSnap.Roots.TrustDomain, datacenter: cfgSnap.Datacenter, partition: cfgSnap.ProxyID.PartitionOrDefault(), }, cfgSnap.ConnectProxy.InboundPeerTrustBundles, ) if err != nil { return nil, err } // Try our best to inject the HTTP RBAC filter. if err := injectHTTPFilterOnFilterChains(l, httpAuthzFilter); err != nil { s.Logger.Warn( "could not inject the HTTP RBAC filter to enforce intentions on user-provided "+ "'envoy_public_listener_json' config; falling back on the RBAC network filter instead", "proxy", cfgSnap.ProxyID, "error", err, ) // If we get an error inject the RBAC network filter instead. useHTTPFilter = false } } err := s.finalizePublicListenerFromConfig(l, cfgSnap, cfg, useHTTPFilter) if err != nil { return nil, fmt.Errorf("failed to attach Consul filters and TLS context to custom public listener: %v", err) } return l, nil } // No JSON user config, use default listener address // Default to listening on all addresses, but override with bind address if one is set. addr := cfgSnap.Address if addr == "" { addr = "0.0.0.0" } if cfg.BindAddress != "" { addr = cfg.BindAddress } // Override with bind port if one is set, otherwise default to // proxy service's address port := cfgSnap.Port if cfg.BindPort != 0 { port = cfg.BindPort } l = makePortListener(name, addr, port, envoy_core_v3.TrafficDirection_INBOUND) filterOpts := listenerFilterOpts{ protocol: cfg.Protocol, filterName: name, routeName: name, cluster: LocalAppClusterName, requestTimeoutMs: cfg.LocalRequestTimeoutMs, } if useHTTPFilter { filterOpts.httpAuthzFilter, err = makeRBACHTTPFilter( cfgSnap.ConnectProxy.Intentions, cfgSnap.IntentionDefaultAllow, rbacLocalInfo{ trustDomain: cfgSnap.Roots.TrustDomain, datacenter: cfgSnap.Datacenter, partition: cfgSnap.ProxyID.PartitionOrDefault(), }, cfgSnap.ConnectProxy.InboundPeerTrustBundles, ) if err != nil { return nil, err } if meshConfig := cfgSnap.MeshConfig(); meshConfig == nil || meshConfig.HTTP == nil || !meshConfig.HTTP.SanitizeXForwardedClientCert { filterOpts.forwardClientDetails = true filterOpts.forwardClientPolicy = envoy_http_v3.HttpConnectionManager_APPEND_FORWARD } } // If an inbound connect limit is set, inject a connection limit filter on each chain. if cfg.MaxInboundConnections > 0 { connectionLimitFilter, err := makeConnectionLimitFilter(cfg.MaxInboundConnections) if err != nil { return nil, err } l.FilterChains = []*envoy_listener_v3.FilterChain{ { Filters: []*envoy_listener_v3.Filter{ connectionLimitFilter, }, }, } } filter, err := makeListenerFilter(filterOpts) if err != nil { return nil, err } if len(l.FilterChains) > 0 { // The list of FilterChains has already been initialized l.FilterChains[0].Filters = append(l.FilterChains[0].Filters, filter) } else { l.FilterChains = []*envoy_listener_v3.FilterChain{ { Filters: []*envoy_listener_v3.Filter{ filter, }, }, } } err = s.finalizePublicListenerFromConfig(l, cfgSnap, cfg, useHTTPFilter) if err != nil { return nil, fmt.Errorf("failed to attach Consul filters and TLS context to custom public listener: %v", err) } return l, err } // finalizePublicListenerFromConfig is used for best-effort injection of Consul filter-chains onto listeners. // This include L4 authorization filters and TLS context. func (s *ResourceGenerator) finalizePublicListenerFromConfig(l *envoy_listener_v3.Listener, cfgSnap *proxycfg.ConfigSnapshot, proxyCfg ProxyConfig, useHTTPFilter bool) error { if !useHTTPFilter { // Best-effort injection of L4 intentions if err := s.injectConnectFilters(cfgSnap, l); err != nil { return nil } } // Always apply TLS certificates if err := s.injectConnectTLSForPublicListener(cfgSnap, l); err != nil { return nil } return nil } func (s *ResourceGenerator) makeExposedCheckListener(cfgSnap *proxycfg.ConfigSnapshot, cluster string, path structs.ExposePath) (proto.Message, error) { cfg, err := ParseProxyConfig(cfgSnap.Proxy.Config) if err != nil { // Don't hard fail on a config typo, just warn. The parse func returns // default config if there is an error so it's safe to continue. s.Logger.Warn("failed to parse Connect.Proxy.Config", "error", err) } // No user config, use default listener addr := cfgSnap.Address // Override with bind address if one is set, otherwise default to 0.0.0.0 if cfg.BindAddress != "" { addr = cfg.BindAddress } else if addr == "" { addr = "0.0.0.0" } // Strip any special characters from path to make a valid and hopefully unique name r := regexp.MustCompile(`[^a-zA-Z0-9]+`) strippedPath := r.ReplaceAllString(path.Path, "") listenerName := fmt.Sprintf("exposed_path_%s", strippedPath) l := makePortListener(listenerName, addr, path.ListenerPort, envoy_core_v3.TrafficDirection_INBOUND) filterName := fmt.Sprintf("exposed_path_filter_%s_%d", strippedPath, path.ListenerPort) opts := listenerFilterOpts{ useRDS: false, protocol: path.Protocol, filterName: filterName, routeName: filterName, cluster: cluster, statPrefix: "", routePath: path.Path, httpAuthzFilter: nil, } f, err := makeListenerFilter(opts) if err != nil { return nil, err } chain := &envoy_listener_v3.FilterChain{ Filters: []*envoy_listener_v3.Filter{f}, } // For registered checks restrict traffic sources to localhost and Consul's advertise addr if path.ParsedFromCheck { // For the advertise addr we use a CidrRange that only matches one address advertise := s.CfgFetcher.AdvertiseAddrLAN() // Get prefix length based on whether address is ipv4 (32 bits) or ipv6 (128 bits) advertiseLen := 32 ip := net.ParseIP(advertise) if ip != nil && strings.Contains(advertise, ":") { advertiseLen = 128 } ranges := make([]*envoy_core_v3.CidrRange, 0, 3) ranges = append(ranges, &envoy_core_v3.CidrRange{AddressPrefix: "127.0.0.1", PrefixLen: &wrappers.UInt32Value{Value: 8}}, &envoy_core_v3.CidrRange{AddressPrefix: advertise, PrefixLen: &wrappers.UInt32Value{Value: uint32(advertiseLen)}}, ) if ok, err := kernelSupportsIPv6(); err != nil { return nil, err } else if ok { ranges = append(ranges, &envoy_core_v3.CidrRange{AddressPrefix: "::1", PrefixLen: &wrappers.UInt32Value{Value: 128}}, ) } chain.FilterChainMatch = &envoy_listener_v3.FilterChainMatch{ SourcePrefixRanges: ranges, } } l.FilterChains = []*envoy_listener_v3.FilterChain{chain} return l, err } func (s *ResourceGenerator) makeTerminatingGatewayListener( cfgSnap *proxycfg.ConfigSnapshot, name, addr string, port int, ) (*envoy_listener_v3.Listener, error) { l := makePortListener(name, addr, port, envoy_core_v3.TrafficDirection_INBOUND) tlsInspector, err := makeTLSInspectorListenerFilter() if err != nil { return nil, err } l.ListenerFilters = []*envoy_listener_v3.ListenerFilter{tlsInspector} // Make a FilterChain for each linked service // Match on the cluster name, for _, svc := range cfgSnap.TerminatingGateway.ValidServices() { clusterName := connect.ServiceSNI(svc.Name, "", svc.NamespaceOrDefault(), svc.PartitionOrDefault(), cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain) // Resolvers are optional. resolver, hasResolver := cfgSnap.TerminatingGateway.ServiceResolvers[svc] intentions := cfgSnap.TerminatingGateway.Intentions[svc] svcConfig := cfgSnap.TerminatingGateway.ServiceConfigs[svc] cfg, err := ParseProxyConfig(svcConfig.ProxyConfig) if err != nil { // Don't hard fail on a config typo, just warn. The parse func returns // default config if there is an error so it's safe to continue. s.Logger.Warn( "failed to parse Connect.Proxy.Config for linked service", "service", svc.String(), "error", err, ) } opts := terminatingGatewayFilterChainOpts{ cluster: clusterName, service: svc, intentions: intentions, protocol: cfg.Protocol, } clusterChain, err := s.makeFilterChainTerminatingGateway(cfgSnap, opts) if err != nil { return nil, fmt.Errorf("failed to make filter chain for cluster %q: %v", clusterName, err) } l.FilterChains = append(l.FilterChains, clusterChain) // if there is a service-resolver for this service then also setup subset filter chains for it if hasResolver { // generate 1 filter chain for each service subset for subsetName := range resolver.Subsets { subsetClusterName := connect.ServiceSNI(svc.Name, subsetName, svc.NamespaceOrDefault(), svc.PartitionOrDefault(), cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain) opts.cluster = subsetClusterName subsetClusterChain, err := s.makeFilterChainTerminatingGateway(cfgSnap, opts) if err != nil { return nil, fmt.Errorf("failed to make filter chain for cluster %q: %v", subsetClusterName, err) } l.FilterChains = append(l.FilterChains, subsetClusterChain) } } } for _, svc := range cfgSnap.TerminatingGateway.ValidDestinations() { intentions := cfgSnap.TerminatingGateway.Intentions[svc] svcConfig := cfgSnap.TerminatingGateway.ServiceConfigs[svc] cfg, err := ParseProxyConfig(svcConfig.ProxyConfig) if err != nil { // Don't hard fail on a config typo, just warn. The parse func returns // default config if there is an error so it's safe to continue. s.Logger.Warn( "failed to parse Connect.Proxy.Config for linked destination", "destination", svc.String(), "error", err, ) } var dest *structs.DestinationConfig dest = &svcConfig.Destination opts := terminatingGatewayFilterChainOpts{ service: svc, intentions: intentions, protocol: cfg.Protocol, port: dest.Port, } for _, address := range dest.Addresses { clusterName := clusterNameForDestination(cfgSnap, svc.Name, address, svc.NamespaceOrDefault(), svc.PartitionOrDefault()) opts.cluster = clusterName opts.address = address clusterChain, err := s.makeFilterChainTerminatingGateway(cfgSnap, opts) if err != nil { return nil, fmt.Errorf("failed to make filter chain for cluster %q: %v", clusterName, err) } l.FilterChains = append(l.FilterChains, clusterChain) } } // Before we add the fallback, sort these chains by the matched name. All // of these filter chains are independent, but envoy requires them to be in // some order. If we put them in a random order then every xDS iteration // envoy will force the listener to be replaced. Sorting these has no // effect on how they operate, but it does mean that we won't churn // listeners at idle. sort.Slice(l.FilterChains, func(i, j int) bool { return l.FilterChains[i].FilterChainMatch.ServerNames[0] < l.FilterChains[j].FilterChainMatch.ServerNames[0] }) // This fallback catch-all filter ensures a listener will be present for health checks to pass // Envoy will reset these connections since known endpoints are caught by filter chain matches above tcpProxy, err := makeTCPProxyFilter(name, "", "terminating_gateway.") if err != nil { return nil, err } sniCluster, err := makeSNIClusterFilter() if err != nil { return nil, err } fallback := &envoy_listener_v3.FilterChain{ Filters: []*envoy_listener_v3.Filter{ sniCluster, tcpProxy, }, } l.FilterChains = append(l.FilterChains, fallback) return l, nil } type terminatingGatewayFilterChainOpts struct { cluster string service structs.ServiceName intentions structs.Intentions protocol string address string // only valid for destination listeners port int // only valid for destination listeners } func (s *ResourceGenerator) makeFilterChainTerminatingGateway(cfgSnap *proxycfg.ConfigSnapshot, tgtwyOpts terminatingGatewayFilterChainOpts) (*envoy_listener_v3.FilterChain, error) { tlsContext := &envoy_tls_v3.DownstreamTlsContext{ CommonTlsContext: makeCommonTLSContext( cfgSnap.TerminatingGateway.ServiceLeaves[tgtwyOpts.service], cfgSnap.RootPEMs(), makeTLSParametersFromProxyTLSConfig(cfgSnap.MeshConfigTLSIncoming()), ), RequireClientCertificate: &wrappers.BoolValue{Value: true}, } transportSocket, err := makeDownstreamTLSTransportSocket(tlsContext) if err != nil { return nil, err } filterChain := &envoy_listener_v3.FilterChain{ FilterChainMatch: makeSNIFilterChainMatch(tgtwyOpts.cluster), Filters: make([]*envoy_listener_v3.Filter, 0, 3), TransportSocket: transportSocket, } // This controls if we do L4 or L7 intention checks. useHTTPFilter := structs.IsProtocolHTTPLike(tgtwyOpts.protocol) // If this is L4, the first filter we setup is to do intention checks. if !useHTTPFilter { authFilter, err := makeRBACNetworkFilter( tgtwyOpts.intentions, cfgSnap.IntentionDefaultAllow, rbacLocalInfo{ trustDomain: cfgSnap.Roots.TrustDomain, datacenter: cfgSnap.Datacenter, partition: cfgSnap.ProxyID.PartitionOrDefault(), }, nil, // TODO(peering): verify intentions w peers don't apply to terminatingGateway ) if err != nil { return nil, err } filterChain.Filters = append(filterChain.Filters, authFilter) } // Lastly we setup the actual proxying component. For L4 this is a straight // tcp proxy. For L7 this is a very hands-off HTTP proxy just to inject an // HTTP filter to do intention checks here instead. opts := listenerFilterOpts{ protocol: tgtwyOpts.protocol, filterName: fmt.Sprintf("%s.%s.%s.%s", tgtwyOpts.service.Name, tgtwyOpts.service.NamespaceOrDefault(), tgtwyOpts.service.PartitionOrDefault(), cfgSnap.Datacenter), routeName: tgtwyOpts.cluster, // Set cluster name for route config since each will have its own cluster: tgtwyOpts.cluster, statPrefix: "upstream.", routePath: "", } if useHTTPFilter { var err error opts.httpAuthzFilter, err = makeRBACHTTPFilter( tgtwyOpts.intentions, cfgSnap.IntentionDefaultAllow, rbacLocalInfo{ trustDomain: cfgSnap.Roots.TrustDomain, datacenter: cfgSnap.Datacenter, partition: cfgSnap.ProxyID.PartitionOrDefault(), }, nil, // TODO(peering): verify intentions w peers don't apply to terminatingGateway ) if err != nil { return nil, err } opts.cluster = "" opts.useRDS = true if meshConfig := cfgSnap.MeshConfig(); meshConfig == nil || meshConfig.HTTP == nil || !meshConfig.HTTP.SanitizeXForwardedClientCert { opts.forwardClientDetails = true // This assumes that we have a client cert (mTLS) (implied by the context of this function) opts.forwardClientPolicy = envoy_http_v3.HttpConnectionManager_APPEND_FORWARD } } filter, err := makeListenerFilter(opts) if err != nil { s.Logger.Error("failed to make listener", "cluster", tgtwyOpts.cluster, "error", err) return nil, err } filterChain.Filters = append(filterChain.Filters, filter) return filterChain, nil } func (s *ResourceGenerator) makeMeshGatewayListener(name, addr string, port int, cfgSnap *proxycfg.ConfigSnapshot) (*envoy_listener_v3.Listener, error) { tlsInspector, err := makeTLSInspectorListenerFilter() if err != nil { return nil, err } sniCluster, err := makeSNIClusterFilter() if err != nil { return nil, err } // The cluster name here doesn't matter as the sni_cluster // filter will fill it in for us. tcpProxy, err := makeTCPProxyFilter(name, "", "mesh_gateway_local.") if err != nil { return nil, err } sniClusterChain := &envoy_listener_v3.FilterChain{ Filters: []*envoy_listener_v3.Filter{ sniCluster, tcpProxy, }, } l := makePortListener(name, addr, port, envoy_core_v3.TrafficDirection_UNSPECIFIED) l.ListenerFilters = []*envoy_listener_v3.ListenerFilter{tlsInspector} for _, svc := range cfgSnap.MeshGatewayValidExportedServices() { peerNames := cfgSnap.MeshGateway.ExportedServicesWithPeers[svc] chain := cfgSnap.MeshGateway.DiscoveryChain[svc] filterChain, err := s.makeMeshGatewayPeerFilterChain(cfgSnap, svc, peerNames, chain) if err != nil { return nil, err } else if filterChain == nil { continue } l.FilterChains = append(l.FilterChains, filterChain) } // We need 1 Filter Chain per remote cluster keys := cfgSnap.MeshGateway.GatewayKeys() for _, key := range keys { if key.Matches(cfgSnap.Datacenter, cfgSnap.ProxyID.PartitionOrEmpty()) { continue // skip local } clusterName := connect.GatewaySNI(key.Datacenter, key.Partition, cfgSnap.Roots.TrustDomain) filterName := fmt.Sprintf("%s.%s", name, key.String()) dcTCPProxy, err := makeTCPProxyFilter(filterName, clusterName, "mesh_gateway_remote.") if err != nil { return nil, err } l.FilterChains = append(l.FilterChains, &envoy_listener_v3.FilterChain{ FilterChainMatch: &envoy_listener_v3.FilterChainMatch{ ServerNames: []string{fmt.Sprintf("*.%s", clusterName)}, }, Filters: []*envoy_listener_v3.Filter{ dcTCPProxy, }, }) } if cfgSnap.ProxyID.InDefaultPartition() && cfgSnap.ServiceMeta[structs.MetaWANFederationKey] == "1" && cfgSnap.ServerSNIFn != nil { for _, key := range keys { if key.Datacenter == cfgSnap.Datacenter { continue // skip local } clusterName := cfgSnap.ServerSNIFn(key.Datacenter, "") filterName := fmt.Sprintf("%s.%s", name, key.String()) dcTCPProxy, err := makeTCPProxyFilter(filterName, clusterName, "mesh_gateway_remote.") if err != nil { return nil, err } l.FilterChains = append(l.FilterChains, &envoy_listener_v3.FilterChain{ FilterChainMatch: &envoy_listener_v3.FilterChainMatch{ ServerNames: []string{fmt.Sprintf("*.%s", clusterName)}, }, Filters: []*envoy_listener_v3.Filter{ dcTCPProxy, }, }) } // Wildcard all flavors to each server. for _, srv := range cfgSnap.MeshGateway.ConsulServers { clusterName := cfgSnap.ServerSNIFn(cfgSnap.Datacenter, srv.Node.Node) filterName := fmt.Sprintf("%s.%s", name, cfgSnap.Datacenter) dcTCPProxy, err := makeTCPProxyFilter(filterName, clusterName, "mesh_gateway_local_server.") if err != nil { return nil, err } l.FilterChains = append(l.FilterChains, &envoy_listener_v3.FilterChain{ FilterChainMatch: &envoy_listener_v3.FilterChainMatch{ ServerNames: []string{fmt.Sprintf("%s", clusterName)}, }, Filters: []*envoy_listener_v3.Filter{ dcTCPProxy, }, }) } } // This needs to get tacked on at the end as it has no // matching and will act as a catch all l.FilterChains = append(l.FilterChains, sniClusterChain) return l, nil } func (s *ResourceGenerator) makeMeshGatewayPeerFilterChain( cfgSnap *proxycfg.ConfigSnapshot, svc structs.ServiceName, peerNames []string, chain *structs.CompiledDiscoveryChain, ) (*envoy_listener_v3.FilterChain, error) { var ( useHTTPFilter = structs.IsProtocolHTTPLike(chain.Protocol) // RDS, Envoy's Route Discovery Service, is only used for HTTP services. useRDS = useHTTPFilter ) if useHTTPFilter && cfgSnap.MeshGateway.Leaf == nil { return nil, nil // ignore; not ready } var clusterName string if !useRDS { // When not using RDS we must generate a cluster name to attach to the filter chain. // With RDS, cluster names get attached to the dynamic routes instead. target, err := simpleChainTarget(chain) if err != nil { return nil, err } clusterName = meshGatewayExportedClusterNamePrefix + CustomizeClusterName(target.Name, chain) } uid := proxycfg.NewUpstreamIDFromServiceName(svc) filterName := fmt.Sprintf("%s.%s.%s.%s", chain.ServiceName, chain.Namespace, chain.Partition, chain.Datacenter) filterChain, err := s.makeUpstreamFilterChain(filterChainOpts{ routeName: uid.EnvoyID(), clusterName: clusterName, filterName: filterName, protocol: chain.Protocol, useRDS: useRDS, statPrefix: "mesh_gateway_local_peered.", forwardClientDetails: true, forwardClientPolicy: envoy_http_v3.HttpConnectionManager_SANITIZE_SET, }) if err != nil { return nil, err } var peeredServerNames []string for _, peerName := range peerNames { peeredSNI := connect.PeeredServiceSNI( svc.Name, svc.NamespaceOrDefault(), svc.PartitionOrDefault(), peerName, cfgSnap.Roots.TrustDomain, ) peeredServerNames = append(peeredServerNames, peeredSNI) } filterChain.FilterChainMatch = &envoy_listener_v3.FilterChainMatch{ ServerNames: peeredServerNames, } if useHTTPFilter { // We only terminate TLS if we're doing an L7 proxy. var peerBundles []*pbpeering.PeeringTrustBundle for _, bundle := range cfgSnap.MeshGateway.PeeringTrustBundles { if stringslice.Contains(peerNames, bundle.PeerName) { peerBundles = append(peerBundles, bundle) } } peeredTransportSocket, err := createDownstreamTransportSocketForConnectTLS(cfgSnap, peerBundles) if err != nil { return nil, err } filterChain.TransportSocket = peeredTransportSocket } return filterChain, nil } type filterChainOpts struct { routeName string clusterName string filterName string protocol string useRDS bool tlsContext *envoy_tls_v3.DownstreamTlsContext statPrefix string forwardClientDetails bool forwardClientPolicy envoy_http_v3.HttpConnectionManager_ForwardClientCertDetails } func (s *ResourceGenerator) makeUpstreamFilterChain(opts filterChainOpts) (*envoy_listener_v3.FilterChain, error) { if opts.statPrefix == "" { opts.statPrefix = "upstream." } filter, err := makeListenerFilter(listenerFilterOpts{ useRDS: opts.useRDS, protocol: opts.protocol, filterName: opts.filterName, routeName: opts.routeName, cluster: opts.clusterName, statPrefix: opts.statPrefix, forwardClientDetails: opts.forwardClientDetails, forwardClientPolicy: opts.forwardClientPolicy, }) if err != nil { return nil, err } transportSocket, err := makeDownstreamTLSTransportSocket(opts.tlsContext) if err != nil { return nil, err } return &envoy_listener_v3.FilterChain{ Filters: []*envoy_listener_v3.Filter{ filter, }, TransportSocket: transportSocket, }, nil } // simpleChainTarget returns the discovery target for a chain with a single node. // A chain can have a single target if it is for a TCP service or an HTTP service without // multiple splits/routes/failovers. func simpleChainTarget(chain *structs.CompiledDiscoveryChain) (*structs.DiscoveryTarget, error) { startNode := chain.Nodes[chain.StartNode] if startNode == nil { return nil, fmt.Errorf("missing first node in compiled discovery chain for: %s", chain.ServiceName) } if startNode.Type != structs.DiscoveryGraphNodeTypeResolver { return nil, fmt.Errorf("expected discovery chain with single node, found unexpected start node: %s", startNode.Type) } targetID := startNode.Resolver.Target return chain.Targets[targetID], nil } func (s *ResourceGenerator) getAndModifyUpstreamConfigForListener( uid proxycfg.UpstreamID, u *structs.Upstream, chain *structs.CompiledDiscoveryChain, ) structs.UpstreamConfig { var ( cfg structs.UpstreamConfig err error ) configMap := make(map[string]interface{}) if u != nil { configMap = u.Config } if chain == nil || chain.Default { cfg, err = structs.ParseUpstreamConfigNoDefaults(configMap) if err != nil { // Don't hard fail on a config typo, just warn. The parse func returns // default config if there is an error so it's safe to continue. s.Logger.Warn("failed to parse", "upstream", uid, "error", err) } } else { // Use NoDefaults here so that we can set the protocol to the chain // protocol if necessary cfg, err = structs.ParseUpstreamConfigNoDefaults(configMap) if err != nil { // Don't hard fail on a config typo, just warn. The parse func returns // default config if there is an error so it's safe to continue. s.Logger.Warn("failed to parse", "upstream", uid, "error", err) } if cfg.EnvoyListenerJSON != "" { s.Logger.Warn("ignoring escape hatch setting because already configured for", "discovery chain", chain.ServiceName, "upstream", uid, "config", "envoy_listener_json") // Remove from config struct so we don't use it later on cfg.EnvoyListenerJSON = "" } } protocol := cfg.Protocol if chain != nil { if protocol == "" { protocol = chain.Protocol } if protocol == "" { protocol = "tcp" } } else { protocol = "tcp" } // set back on the config so that we can use it from return value cfg.Protocol = protocol return cfg } func (s *ResourceGenerator) getAndModifyUpstreamConfigForPeeredListener( uid proxycfg.UpstreamID, u *structs.Upstream, peerMeta structs.PeeringServiceMeta, ) structs.UpstreamConfig { var ( cfg structs.UpstreamConfig err error ) configMap := make(map[string]interface{}) if u != nil { configMap = u.Config } cfg, err = structs.ParseUpstreamConfigNoDefaults(configMap) if err != nil { // Don't hard fail on a config typo, just warn. The parse func returns // default config if there is an error so it's safe to continue. s.Logger.Warn("failed to parse", "upstream", uid, "error", err) } protocol := cfg.Protocol if protocol == "" { protocol = peerMeta.Protocol } if protocol == "" { protocol = "tcp" } // set back on the config so that we can use it from return value cfg.Protocol = protocol if cfg.ConnectTimeoutMs == 0 { cfg.ConnectTimeoutMs = 5000 } return cfg } type listenerFilterOpts struct { useRDS bool protocol string filterName string routeName string cluster string statPrefix string routePath string requestTimeoutMs *int ingressGateway bool httpAuthzFilter *envoy_http_v3.HttpFilter forwardClientDetails bool forwardClientPolicy envoy_http_v3.HttpConnectionManager_ForwardClientCertDetails } func makeListenerFilter(opts listenerFilterOpts) (*envoy_listener_v3.Filter, error) { switch opts.protocol { case "grpc", "http2", "http": return makeHTTPFilter(opts) case "tcp": fallthrough default: if opts.useRDS { return nil, fmt.Errorf("RDS is not compatible with the tcp proxy filter") } else if opts.cluster == "" { return nil, fmt.Errorf("cluster name is required for a tcp proxy filter") } return makeTCPProxyFilter(opts.filterName, opts.cluster, opts.statPrefix) } } func makeTLSInspectorListenerFilter() (*envoy_listener_v3.ListenerFilter, error) { return makeEnvoyListenerFilter("envoy.filters.listener.tls_inspector", &envoy_tls_inspector_v3.TlsInspector{}) } func makeHTTPInspectorListenerFilter() (*envoy_listener_v3.ListenerFilter, error) { return makeEnvoyListenerFilter("envoy.filters.listener.http_inspector", &envoy_extensions_filters_listener_http_inspector_v3.HttpInspector{}) } func makeSNIFilterChainMatch(sniMatches ...string) *envoy_listener_v3.FilterChainMatch { return &envoy_listener_v3.FilterChainMatch{ ServerNames: sniMatches, } } func makeSNIClusterFilter() (*envoy_listener_v3.Filter, error) { return makeFilter("envoy.filters.network.sni_cluster", &envoy_sni_cluster_v3.SniCluster{}) } func makeTCPProxyFilter(filterName, cluster, statPrefix string) (*envoy_listener_v3.Filter, error) { cfg := &envoy_tcp_proxy_v3.TcpProxy{ StatPrefix: makeStatPrefix(statPrefix, filterName), ClusterSpecifier: &envoy_tcp_proxy_v3.TcpProxy_Cluster{Cluster: cluster}, } return makeFilter("envoy.filters.network.tcp_proxy", cfg) } func makeConnectionLimitFilter(limit int) (*envoy_listener_v3.Filter, error) { cfg := &envoy_connection_limit_v3.ConnectionLimit{ StatPrefix: "inbound_connection_limit", MaxConnections: wrapperspb.UInt64(uint64(limit)), } return makeFilter("envoy.filters.network.connection_limit", cfg) } func makeStatPrefix(prefix, filterName string) string { // Replace colons here because Envoy does that in the metrics for the actual // clusters but doesn't in the stat prefix here while dashboards assume they // will match. return fmt.Sprintf("%s%s", prefix, strings.Replace(filterName, ":", "_", -1)) } func makeHTTPFilter(opts listenerFilterOpts) (*envoy_listener_v3.Filter, error) { router, err := makeEnvoyHTTPFilter("envoy.filters.http.router", &envoy_http_router_v3.Router{}) if err != nil { return nil, err } cfg := &envoy_http_v3.HttpConnectionManager{ StatPrefix: makeStatPrefix(opts.statPrefix, opts.filterName), CodecType: envoy_http_v3.HttpConnectionManager_AUTO, HttpFilters: []*envoy_http_v3.HttpFilter{ router, }, Tracing: &envoy_http_v3.HttpConnectionManager_Tracing{ // Don't trace any requests by default unless the client application // explicitly propagates trace headers that indicate this should be // sampled. RandomSampling: &envoy_type_v3.Percent{Value: 0.0}, }, } if opts.useRDS { if opts.cluster != "" { return nil, fmt.Errorf("cannot specify cluster name when using RDS") } cfg.RouteSpecifier = &envoy_http_v3.HttpConnectionManager_Rds{ Rds: &envoy_http_v3.Rds{ RouteConfigName: opts.routeName, ConfigSource: &envoy_core_v3.ConfigSource{ ResourceApiVersion: envoy_core_v3.ApiVersion_V3, ConfigSourceSpecifier: &envoy_core_v3.ConfigSource_Ads{ Ads: &envoy_core_v3.AggregatedConfigSource{}, }, }, }, } } else { if opts.cluster == "" { return nil, fmt.Errorf("must specify cluster name when not using RDS") } route := &envoy_route_v3.Route{ Match: &envoy_route_v3.RouteMatch{ PathSpecifier: &envoy_route_v3.RouteMatch_Prefix{ Prefix: "/", }, // TODO(banks) Envoy supports matching only valid GRPC // requests which might be nice to add here for gRPC services // but it's not supported in our current envoy SDK version // although docs say it was supported by 1.8.0. Going to defer // that until we've updated the deps. }, Action: &envoy_route_v3.Route_Route{ Route: &envoy_route_v3.RouteAction{ ClusterSpecifier: &envoy_route_v3.RouteAction_Cluster{ Cluster: opts.cluster, }, }, }, } if opts.requestTimeoutMs != nil { r := route.GetRoute() r.Timeout = durationpb.New(time.Duration(*opts.requestTimeoutMs) * time.Millisecond) } // If a path is provided, do not match on a catch-all prefix if opts.routePath != "" { route.Match.PathSpecifier = &envoy_route_v3.RouteMatch_Path{Path: opts.routePath} } cfg.RouteSpecifier = &envoy_http_v3.HttpConnectionManager_RouteConfig{ RouteConfig: &envoy_route_v3.RouteConfiguration{ Name: opts.routeName, VirtualHosts: []*envoy_route_v3.VirtualHost{ { Name: opts.filterName, Domains: []string{"*"}, Routes: []*envoy_route_v3.Route{ route, }, }, }, }, } } if opts.protocol == "http2" || opts.protocol == "grpc" { cfg.Http2ProtocolOptions = &envoy_core_v3.Http2ProtocolOptions{} } // Note the default leads to setting HttpConnectionManager_SANITIZE if opts.forwardClientDetails { cfg.ForwardClientCertDetails = opts.forwardClientPolicy cfg.SetCurrentClientCertDetails = &envoy_http_v3.HttpConnectionManager_SetCurrentClientCertDetails{ Subject: &wrappers.BoolValue{Value: true}, Cert: true, Chain: true, Dns: true, Uri: true, } } // Like injectConnectFilters for L4, here we ensure that the first filter // (other than the "envoy.grpc_http1_bridge" filter) in the http filter // chain of a public listener is the authz filter to prevent unauthorized // access and that every filter chain uses our TLS certs. if opts.httpAuthzFilter != nil { cfg.HttpFilters = append([]*envoy_http_v3.HttpFilter{opts.httpAuthzFilter}, cfg.HttpFilters...) } if opts.protocol == "grpc" { grpcHttp1Bridge, err := makeEnvoyHTTPFilter( "envoy.filters.http.grpc_http1_bridge", &envoy_grpc_http1_bridge_v3.Config{}, ) if err != nil { return nil, err } // In envoy 1.14.x the default value "stats_for_all_methods=true" was // deprecated, and was changed to "false" in 1.18.x. Avoid using the // default. TODO: we may want to expose this to users somehow easily. grpcStatsFilter, err := makeEnvoyHTTPFilter( "envoy.filters.http.grpc_stats", &envoy_grpc_stats_v3.FilterConfig{ PerMethodStatSpecifier: &envoy_grpc_stats_v3.FilterConfig_StatsForAllMethods{ StatsForAllMethods: makeBoolValue(true), }, }, ) if err != nil { return nil, err } // Add grpc bridge before router and authz, and the stats in front of that. cfg.HttpFilters = append([]*envoy_http_v3.HttpFilter{ grpcStatsFilter, grpcHttp1Bridge, }, cfg.HttpFilters...) } return makeFilter("envoy.filters.network.http_connection_manager", cfg) } func makeEnvoyListenerFilter(name string, cfg proto.Message) (*envoy_listener_v3.ListenerFilter, error) { any, err := ptypes.MarshalAny(cfg) if err != nil { return nil, err } return &envoy_listener_v3.ListenerFilter{ Name: name, ConfigType: &envoy_listener_v3.ListenerFilter_TypedConfig{TypedConfig: any}, }, nil } func makeFilter(name string, cfg proto.Message) (*envoy_listener_v3.Filter, error) { any, err := ptypes.MarshalAny(cfg) if err != nil { return nil, err } return &envoy_listener_v3.Filter{ Name: name, ConfigType: &envoy_listener_v3.Filter_TypedConfig{TypedConfig: any}, }, nil } func makeEnvoyHTTPFilter(name string, cfg proto.Message) (*envoy_http_v3.HttpFilter, error) { any, err := ptypes.MarshalAny(cfg) if err != nil { return nil, err } return &envoy_http_v3.HttpFilter{ Name: name, ConfigType: &envoy_http_v3.HttpFilter_TypedConfig{TypedConfig: any}, }, nil } func makeCommonTLSContext( leaf *structs.IssuedCert, rootPEMs string, tlsParams *envoy_tls_v3.TlsParameters, ) *envoy_tls_v3.CommonTlsContext { if rootPEMs == "" { return nil } if tlsParams == nil { tlsParams = &envoy_tls_v3.TlsParameters{} } return &envoy_tls_v3.CommonTlsContext{ TlsParams: tlsParams, TlsCertificates: []*envoy_tls_v3.TlsCertificate{ { CertificateChain: &envoy_core_v3.DataSource{ Specifier: &envoy_core_v3.DataSource_InlineString{ InlineString: lib.EnsureTrailingNewline(leaf.CertPEM), }, }, PrivateKey: &envoy_core_v3.DataSource{ Specifier: &envoy_core_v3.DataSource_InlineString{ InlineString: lib.EnsureTrailingNewline(leaf.PrivateKeyPEM), }, }, }, }, ValidationContextType: &envoy_tls_v3.CommonTlsContext_ValidationContext{ ValidationContext: &envoy_tls_v3.CertificateValidationContext{ // TODO(banks): later for L7 support we may need to configure ALPN here. TrustedCa: &envoy_core_v3.DataSource{ Specifier: &envoy_core_v3.DataSource_InlineString{ InlineString: rootPEMs, }, }, }, }, } } func makeDownstreamTLSTransportSocket(tlsContext *envoy_tls_v3.DownstreamTlsContext) (*envoy_core_v3.TransportSocket, error) { if tlsContext == nil { return nil, nil } return makeTransportSocket("tls", tlsContext) } func makeUpstreamTLSTransportSocket(tlsContext *envoy_tls_v3.UpstreamTlsContext) (*envoy_core_v3.TransportSocket, error) { if tlsContext == nil { return nil, nil } return makeTransportSocket("tls", tlsContext) } func makeTransportSocket(name string, config proto.Message) (*envoy_core_v3.TransportSocket, error) { any, err := ptypes.MarshalAny(config) if err != nil { return nil, err } return &envoy_core_v3.TransportSocket{ Name: name, ConfigType: &envoy_core_v3.TransportSocket_TypedConfig{ TypedConfig: any, }, }, nil } func makeCommonTLSContextFromFiles(caFile, certFile, keyFile string) *envoy_tls_v3.CommonTlsContext { ctx := envoy_tls_v3.CommonTlsContext{ TlsParams: &envoy_tls_v3.TlsParameters{}, } // Verify certificate of peer if caFile is specified if caFile != "" { ctx.ValidationContextType = &envoy_tls_v3.CommonTlsContext_ValidationContext{ ValidationContext: &envoy_tls_v3.CertificateValidationContext{ TrustedCa: &envoy_core_v3.DataSource{ Specifier: &envoy_core_v3.DataSource_Filename{ Filename: caFile, }, }, }, } } // Present certificate for mTLS if cert and key files are specified if certFile != "" && keyFile != "" { ctx.TlsCertificates = []*envoy_tls_v3.TlsCertificate{ { CertificateChain: &envoy_core_v3.DataSource{ Specifier: &envoy_core_v3.DataSource_Filename{ Filename: certFile, }, }, PrivateKey: &envoy_core_v3.DataSource{ Specifier: &envoy_core_v3.DataSource_Filename{ Filename: keyFile, }, }, }, } } return &ctx } func validateListenerTLSConfig(tlsMinVersion types.TLSVersion, cipherSuites []types.TLSCipherSuite) error { // Validate. Configuring cipher suites is only applicable to connections negotiated // via TLS 1.2 or earlier. Other cases shouldn't be possible as we validate them at // input but be resilient to bugs later. if len(cipherSuites) != 0 { if _, ok := tlsVersionsWithConfigurableCipherSuites[tlsMinVersion]; !ok { return fmt.Errorf("configuring CipherSuites is only applicable to connections negotiated with TLS 1.2 or earlier, TLSMinVersion is set to %s in config", tlsMinVersion) } } return nil } var tlsVersionsWithConfigurableCipherSuites = map[types.TLSVersion]struct{}{ // Remove these two if Envoy ever sets TLS 1.3 as default minimum types.TLSVersionUnspecified: {}, types.TLSVersionAuto: {}, types.TLSv1_0: {}, types.TLSv1_1: {}, types.TLSv1_2: {}, } func makeTLSParametersFromProxyTLSConfig(tlsConf *structs.MeshDirectionalTLSConfig) *envoy_tls_v3.TlsParameters { if tlsConf == nil { return &envoy_tls_v3.TlsParameters{} } return makeTLSParametersFromTLSConfig(tlsConf.TLSMinVersion, tlsConf.TLSMaxVersion, tlsConf.CipherSuites) } func makeTLSParametersFromTLSConfig( tlsMinVersion types.TLSVersion, tlsMaxVersion types.TLSVersion, cipherSuites []types.TLSCipherSuite, ) *envoy_tls_v3.TlsParameters { tlsParams := envoy_tls_v3.TlsParameters{} if tlsMinVersion != types.TLSVersionUnspecified { if minVersion, ok := envoyTLSVersions[tlsMinVersion]; ok { tlsParams.TlsMinimumProtocolVersion = minVersion } } if tlsMaxVersion != types.TLSVersionUnspecified { if maxVersion, ok := envoyTLSVersions[tlsMaxVersion]; ok { tlsParams.TlsMaximumProtocolVersion = maxVersion } } if len(cipherSuites) != 0 { tlsParams.CipherSuites = types.MarshalEnvoyTLSCipherSuiteStrings(cipherSuites) } return &tlsParams } var envoyTLSVersions = map[types.TLSVersion]envoy_tls_v3.TlsParameters_TlsProtocol{ types.TLSVersionAuto: envoy_tls_v3.TlsParameters_TLS_AUTO, types.TLSv1_0: envoy_tls_v3.TlsParameters_TLSv1_0, types.TLSv1_1: envoy_tls_v3.TlsParameters_TLSv1_1, types.TLSv1_2: envoy_tls_v3.TlsParameters_TLSv1_2, types.TLSv1_3: envoy_tls_v3.TlsParameters_TLSv1_3, }