consul/agent/xds/clusters.go

1920 lines
64 KiB
Go

package xds
import (
"errors"
"fmt"
"sort"
"strings"
"time"
envoy_cluster_v3 "github.com/envoyproxy/go-control-plane/envoy/config/cluster/v3"
envoy_core_v3 "github.com/envoyproxy/go-control-plane/envoy/config/core/v3"
envoy_endpoint_v3 "github.com/envoyproxy/go-control-plane/envoy/config/endpoint/v3"
envoy_aggregate_cluster_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/clusters/aggregate/v3"
envoy_tls_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/transport_sockets/tls/v3"
envoy_upstreams_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/upstreams/http/v3"
envoy_matcher_v3 "github.com/envoyproxy/go-control-plane/envoy/type/matcher/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/any"
"github.com/golang/protobuf/ptypes/wrappers"
"github.com/hashicorp/go-hclog"
"google.golang.org/protobuf/types/known/anypb"
"google.golang.org/protobuf/types/known/durationpb"
"github.com/hashicorp/consul/agent/connect"
"github.com/hashicorp/consul/agent/proxycfg"
"github.com/hashicorp/consul/agent/structs"
"github.com/hashicorp/consul/proto/pbpeering"
)
const (
meshGatewayExportedClusterNamePrefix = "exported~"
failoverClusterNamePrefix = "failover-target~"
)
// clustersFromSnapshot returns the xDS API representation of the "clusters" in the snapshot.
func (s *ResourceGenerator) clustersFromSnapshot(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
if cfgSnap == nil {
return nil, errors.New("nil config given")
}
switch cfgSnap.Kind {
case structs.ServiceKindConnectProxy:
return s.clustersFromSnapshotConnectProxy(cfgSnap)
case structs.ServiceKindTerminatingGateway:
res, err := s.clustersFromSnapshotTerminatingGateway(cfgSnap)
if err != nil {
return nil, err
}
return res, nil
case structs.ServiceKindMeshGateway:
res, err := s.clustersFromSnapshotMeshGateway(cfgSnap)
if err != nil {
return nil, err
}
return res, nil
case structs.ServiceKindIngressGateway:
res, err := s.clustersFromSnapshotIngressGateway(cfgSnap)
if err != nil {
return nil, err
}
return res, nil
default:
return nil, fmt.Errorf("Invalid service kind: %v", cfgSnap.Kind)
}
}
// clustersFromSnapshot returns the xDS API representation of the "clusters"
// (upstreams) in the snapshot.
func (s *ResourceGenerator) clustersFromSnapshotConnectProxy(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
// This sizing is a lower bound.
clusters := make([]proto.Message, 0, len(cfgSnap.ConnectProxy.DiscoveryChain)+1)
// Include the "app" cluster for the public listener
appCluster, err := s.makeAppCluster(cfgSnap, LocalAppClusterName, "", cfgSnap.Proxy.LocalServicePort)
if err != nil {
return nil, err
}
clusters = append(clusters, appCluster)
if cfgSnap.Proxy.Mode == structs.ProxyModeTransparent {
passthroughs, err := makePassthroughClusters(cfgSnap)
if err != nil {
return nil, fmt.Errorf("failed to make passthrough clusters for transparent proxy: %v", err)
}
clusters = append(clusters, passthroughs...)
}
getUpstream := func(uid proxycfg.UpstreamID) (*structs.Upstream, bool) {
upstream := cfgSnap.ConnectProxy.UpstreamConfig[uid]
explicit := upstream.HasLocalPortOrSocket()
implicit := cfgSnap.ConnectProxy.IsImplicitUpstream(uid)
return upstream, !implicit && !explicit
}
// NOTE: Any time we skip a chain below we MUST also skip that discovery chain in endpoints.go
// so that the sets of endpoints generated matches the sets of clusters.
for uid, chain := range cfgSnap.ConnectProxy.DiscoveryChain {
upstream, skip := getUpstream(uid)
if skip {
continue
}
upstreamClusters, err := s.makeUpstreamClustersForDiscoveryChain(
uid,
upstream,
chain,
cfgSnap,
false,
)
if err != nil {
return nil, err
}
for _, cluster := range upstreamClusters {
clusters = append(clusters, cluster)
}
}
// NOTE: Any time we skip an upstream below we MUST also skip that same
// upstream in endpoints.go so that the sets of endpoints generated matches
// the sets of clusters.
for _, uid := range cfgSnap.ConnectProxy.PeeredUpstreamIDs() {
upstream, skip := getUpstream(uid)
if skip {
continue
}
peerMeta := cfgSnap.ConnectProxy.UpstreamPeerMeta(uid)
cfg := s.getAndModifyUpstreamConfigForPeeredListener(uid, upstream, peerMeta)
upstreamCluster, err := s.makeUpstreamClusterForPeerService(uid, cfg, peerMeta, cfgSnap)
if err != nil {
return nil, err
}
clusters = append(clusters, upstreamCluster)
}
for _, u := range cfgSnap.Proxy.Upstreams {
if u.DestinationType != structs.UpstreamDestTypePreparedQuery {
continue
}
upstreamCluster, err := s.makeUpstreamClusterForPreparedQuery(u, cfgSnap)
if err != nil {
return nil, err
}
clusters = append(clusters, upstreamCluster)
}
cfgSnap.Proxy.Expose.Finalize()
paths := cfgSnap.Proxy.Expose.Paths
// Add service health checks to the list of paths to create clusters 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 cluster for", "check", check.CheckID, "error", err)
continue
}
paths = append(paths, p)
}
}
// Create a new cluster if we need to expose a port that is different from the service port
for _, path := range paths {
if path.LocalPathPort == cfgSnap.Proxy.LocalServicePort {
continue
}
c, err := s.makeAppCluster(cfgSnap, makeExposeClusterName(path.LocalPathPort), path.Protocol, path.LocalPathPort)
if err != nil {
s.Logger.Warn("failed to make local cluster", "path", path.Path, "error", err)
continue
}
clusters = append(clusters, c)
}
return clusters, nil
}
func makeExposeClusterName(destinationPort int) string {
return fmt.Sprintf("exposed_cluster_%d", destinationPort)
}
// In transparent proxy mode there are potentially multiple passthrough clusters added.
// The first is for destinations outside of Consul's catalog. This is for a plain TCP proxy.
// All of these use Envoy's ORIGINAL_DST listener filter, which forwards to the original
// destination address (before the iptables redirection).
// The rest are for destinations inside the mesh, which require certificates for mTLS.
func makePassthroughClusters(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
// This size is an upper bound.
clusters := make([]proto.Message, 0, len(cfgSnap.ConnectProxy.PassthroughUpstreams)+1)
if meshConf := cfgSnap.MeshConfig(); meshConf == nil ||
!meshConf.TransparentProxy.MeshDestinationsOnly {
clusters = append(clusters, &envoy_cluster_v3.Cluster{
Name: OriginalDestinationClusterName,
ClusterDiscoveryType: &envoy_cluster_v3.Cluster_Type{
Type: envoy_cluster_v3.Cluster_ORIGINAL_DST,
},
LbPolicy: envoy_cluster_v3.Cluster_CLUSTER_PROVIDED,
ConnectTimeout: durationpb.New(5 * time.Second),
})
}
for uid, chain := range cfgSnap.ConnectProxy.DiscoveryChain {
targetMap, ok := cfgSnap.ConnectProxy.PassthroughUpstreams[uid]
if !ok {
continue
}
for targetID := range targetMap {
uid := proxycfg.NewUpstreamIDFromTargetID(targetID)
sni := connect.ServiceSNI(
uid.Name, "", uid.NamespaceOrDefault(), uid.PartitionOrDefault(), cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain)
// Prefixed with passthrough to distinguish from non-passthrough clusters for the same upstream.
name := "passthrough~" + sni
c := envoy_cluster_v3.Cluster{
Name: name,
ClusterDiscoveryType: &envoy_cluster_v3.Cluster_Type{
Type: envoy_cluster_v3.Cluster_ORIGINAL_DST,
},
LbPolicy: envoy_cluster_v3.Cluster_CLUSTER_PROVIDED,
ConnectTimeout: durationpb.New(5 * time.Second),
}
if discoTarget, ok := chain.Targets[targetID]; ok && discoTarget.ConnectTimeout > 0 {
c.ConnectTimeout = durationpb.New(discoTarget.ConnectTimeout)
}
transportSocket, err := makeMTLSTransportSocket(cfgSnap, uid, sni)
if err != nil {
return nil, err
}
c.TransportSocket = transportSocket
clusters = append(clusters, &c)
}
}
err := cfgSnap.ConnectProxy.DestinationsUpstream.ForEachKeyE(func(uid proxycfg.UpstreamID) error {
svcConfig, ok := cfgSnap.ConnectProxy.DestinationsUpstream.Get(uid)
if !ok || svcConfig.Destination == nil {
return nil
}
// One Cluster per Destination Address
for _, address := range svcConfig.Destination.Addresses {
name := clusterNameForDestination(cfgSnap, uid.Name, address, uid.NamespaceOrDefault(), uid.PartitionOrDefault())
c := envoy_cluster_v3.Cluster{
Name: name,
AltStatName: name,
ConnectTimeout: durationpb.New(5 * time.Second),
CommonLbConfig: &envoy_cluster_v3.Cluster_CommonLbConfig{
HealthyPanicThreshold: &envoy_type_v3.Percent{
Value: 0, // disable panic threshold
},
},
ClusterDiscoveryType: &envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_EDS},
EdsClusterConfig: &envoy_cluster_v3.Cluster_EdsClusterConfig{
EdsConfig: &envoy_core_v3.ConfigSource{
ResourceApiVersion: envoy_core_v3.ApiVersion_V3,
ConfigSourceSpecifier: &envoy_core_v3.ConfigSource_Ads{
Ads: &envoy_core_v3.AggregatedConfigSource{},
},
},
},
// Endpoints are managed separately by EDS
// Having an empty config enables outlier detection with default config.
OutlierDetection: &envoy_cluster_v3.OutlierDetection{},
}
// Use the cluster name as the SNI to match on in the terminating gateway
transportSocket, err := makeMTLSTransportSocket(cfgSnap, uid, name)
if err != nil {
return err
}
c.TransportSocket = transportSocket
clusters = append(clusters, &c)
}
return nil
})
if err != nil {
return nil, err
}
return clusters, nil
}
func makeMTLSTransportSocket(cfgSnap *proxycfg.ConfigSnapshot, uid proxycfg.UpstreamID, sni string) (*envoy_core_v3.TransportSocket, error) {
spiffeID := connect.SpiffeIDService{
Host: cfgSnap.Roots.TrustDomain,
Partition: uid.PartitionOrDefault(),
Namespace: uid.NamespaceOrDefault(),
Datacenter: cfgSnap.Datacenter,
Service: uid.Name,
}
commonTLSContext := makeCommonTLSContext(
cfgSnap.Leaf(),
cfgSnap.RootPEMs(),
makeTLSParametersFromProxyTLSConfig(cfgSnap.MeshConfigTLSOutgoing()),
)
err := injectSANMatcher(commonTLSContext, spiffeID.URI().String())
if err != nil {
return nil, fmt.Errorf("failed to inject SAN matcher rules for cluster %q: %v", sni, err)
}
tlsContext := envoy_tls_v3.UpstreamTlsContext{
CommonTlsContext: commonTLSContext,
Sni: sni,
}
transportSocket, err := makeUpstreamTLSTransportSocket(&tlsContext)
if err != nil {
return nil, err
}
return transportSocket, nil
}
func clusterNameForDestination(cfgSnap *proxycfg.ConfigSnapshot, name string, address string, namespace string, partition string) string {
name = destinationSpecificServiceName(name, address)
sni := connect.ServiceSNI(name, "", namespace, partition, cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain)
// Prefixed with destination to distinguish from non-passthrough clusters for the same upstream.
return "destination." + sni
}
func destinationSpecificServiceName(name string, address string) string {
address = strings.ReplaceAll(address, ":", "-")
address = strings.ReplaceAll(address, ".", "-")
return fmt.Sprintf("%s.%s", address, name)
}
// clustersFromSnapshotMeshGateway returns the xDS API representation of the "clusters"
// for a mesh gateway. This will include 1 cluster per remote datacenter as well as
// 1 cluster for each service subset.
func (s *ResourceGenerator) clustersFromSnapshotMeshGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
keys := cfgSnap.MeshGateway.GatewayKeys()
// Allocation count (this is a lower bound - all subset specific clusters will be appended):
// 1 cluster per remote dc/partition
// 1 cluster per local service
// 1 cluster per unique peer server (control plane traffic)
clusters := make([]proto.Message, 0, len(keys)+len(cfgSnap.MeshGateway.ServiceGroups)+len(cfgSnap.MeshGateway.PeerServers))
// Generate the remote clusters
for _, key := range keys {
if key.Matches(cfgSnap.Datacenter, cfgSnap.ProxyID.PartitionOrDefault()) {
continue // skip local
}
opts := clusterOpts{
name: connect.GatewaySNI(key.Datacenter, key.Partition, cfgSnap.Roots.TrustDomain),
hostnameEndpoints: cfgSnap.MeshGateway.HostnameDatacenters[key.String()],
isRemote: true,
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
clusters = append(clusters, cluster)
}
if cfgSnap.ProxyID.InDefaultPartition() &&
cfgSnap.ServiceMeta[structs.MetaWANFederationKey] == "1" &&
cfgSnap.ServerSNIFn != nil {
// Add all of the remote wildcard datacenter mappings for servers.
for _, key := range keys {
hostnameEndpoints := cfgSnap.MeshGateway.HostnameDatacenters[key.String()]
// If the DC is our current DC then this cluster is for traffic from a remote DC to a local server.
// HostnameDatacenters is populated with gateway addresses, so it does not apply here.
if key.Datacenter == cfgSnap.Datacenter {
hostnameEndpoints = nil
}
opts := clusterOpts{
name: cfgSnap.ServerSNIFn(key.Datacenter, ""),
hostnameEndpoints: hostnameEndpoints,
isRemote: !key.Matches(cfgSnap.Datacenter, cfgSnap.ProxyID.PartitionOrDefault()),
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
clusters = append(clusters, cluster)
}
// And for the current datacenter, send all flavors appropriately.
servers, _ := cfgSnap.MeshGateway.WatchedLocalServers.Get(structs.ConsulServiceName)
for _, srv := range servers {
opts := clusterOpts{
name: cfgSnap.ServerSNIFn(cfgSnap.Datacenter, srv.Node.Node),
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
clusters = append(clusters, cluster)
}
}
// Create a single cluster for local servers to be dialed by peers.
// When peering through gateways we load balance across the local servers. They cannot be addressed individually.
if cfg := cfgSnap.MeshConfig(); cfg.PeerThroughMeshGateways() {
servers, _ := cfgSnap.MeshGateway.WatchedLocalServers.Get(structs.ConsulServiceName)
// Peering control-plane traffic can only ever be handled by the local leader.
// We avoid routing to read replicas since they will never be Raft voters.
if haveVoters(servers) {
cluster := s.makeGatewayCluster(cfgSnap, clusterOpts{
name: connect.PeeringServerSAN(cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain),
})
clusters = append(clusters, cluster)
}
}
// generate the per-service/subset clusters
c, err := s.makeGatewayServiceClusters(cfgSnap, cfgSnap.MeshGateway.ServiceGroups, cfgSnap.MeshGateway.ServiceResolvers)
if err != nil {
return nil, err
}
clusters = append(clusters, c...)
// generate the outgoing clusters for imported peer services.
c, err = s.makeGatewayOutgoingClusterPeeringServiceClusters(cfgSnap)
if err != nil {
return nil, err
}
clusters = append(clusters, c...)
// Generate per-target clusters for all exported discovery chains.
c, err = s.makeExportedUpstreamClustersForMeshGateway(cfgSnap)
if err != nil {
return nil, err
}
clusters = append(clusters, c...)
// Generate one cluster for each unique peer server for control plane traffic
c, err = s.makePeerServerClusters(cfgSnap)
if err != nil {
return nil, err
}
clusters = append(clusters, c...)
return clusters, nil
}
func haveVoters(servers structs.CheckServiceNodes) bool {
for _, srv := range servers {
if isReplica := srv.Service.Meta["read_replica"]; isReplica == "true" {
continue
}
return true
}
return false
}
func (s *ResourceGenerator) makePeerServerClusters(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
if cfgSnap.Kind != structs.ServiceKindMeshGateway {
return nil, fmt.Errorf("unsupported gateway kind %q", cfgSnap.Kind)
}
clusters := make([]proto.Message, 0, len(cfgSnap.MeshGateway.PeerServers))
// Peer server names are assumed to already be formatted in SNI notation:
// server.<datacenter>.peering.<trust-domain>
for name, servers := range cfgSnap.MeshGateway.PeerServers {
if len(servers.Addresses) == 0 {
continue
}
var cluster *envoy_cluster_v3.Cluster
if servers.UseCDS {
cluster = s.makeExternalHostnameCluster(cfgSnap, clusterOpts{
name: name,
addresses: servers.Addresses,
})
} else {
cluster = s.makeGatewayCluster(cfgSnap, clusterOpts{
name: name,
})
}
clusters = append(clusters, cluster)
}
return clusters, nil
}
// clustersFromSnapshotTerminatingGateway returns the xDS API representation of the "clusters"
// for a terminating gateway. This will include 1 cluster per Destination associated with this terminating gateway.
func (s *ResourceGenerator) clustersFromSnapshotTerminatingGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
res := []proto.Message{}
gwClusters, err := s.makeGatewayServiceClusters(cfgSnap, cfgSnap.TerminatingGateway.ServiceGroups, cfgSnap.TerminatingGateway.ServiceResolvers)
if err != nil {
return nil, err
}
res = append(res, gwClusters...)
destClusters, err := s.makeDestinationClusters(cfgSnap)
if err != nil {
return nil, err
}
res = append(res, destClusters...)
return res, nil
}
func (s *ResourceGenerator) makeGatewayServiceClusters(
cfgSnap *proxycfg.ConfigSnapshot,
services map[structs.ServiceName]structs.CheckServiceNodes,
resolvers map[structs.ServiceName]*structs.ServiceResolverConfigEntry,
) ([]proto.Message, error) {
var hostnameEndpoints structs.CheckServiceNodes
switch cfgSnap.Kind {
case structs.ServiceKindTerminatingGateway, structs.ServiceKindMeshGateway:
default:
return nil, fmt.Errorf("unsupported gateway kind %q", cfgSnap.Kind)
}
clusters := make([]proto.Message, 0, len(services))
for svc := range services {
clusterName := connect.ServiceSNI(svc.Name, "", svc.NamespaceOrDefault(), svc.PartitionOrDefault(), cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain)
resolver, hasResolver := resolvers[svc]
var loadBalancer *structs.LoadBalancer
if !hasResolver {
// Use a zero value resolver with no timeout and no subsets
resolver = &structs.ServiceResolverConfigEntry{}
}
if resolver.LoadBalancer != nil {
loadBalancer = resolver.LoadBalancer
}
// When making service clusters we only pass endpoints with hostnames if the kind is a terminating gateway
// This is because the services a mesh gateway will route to are not external services and are not addressed by a hostname.
if cfgSnap.Kind == structs.ServiceKindTerminatingGateway {
hostnameEndpoints = cfgSnap.TerminatingGateway.HostnameServices[svc]
}
var isRemote bool
if len(services[svc]) > 0 {
isRemote = !cfgSnap.Locality.Matches(services[svc][0].Node.Datacenter, services[svc][0].Node.PartitionOrDefault())
}
opts := clusterOpts{
name: clusterName,
hostnameEndpoints: hostnameEndpoints,
connectTimeout: resolver.ConnectTimeout,
isRemote: isRemote,
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
if err := s.injectGatewayServiceAddons(cfgSnap, cluster, svc, loadBalancer); err != nil {
return nil, err
}
clusters = append(clusters, cluster)
svcConfig, ok := cfgSnap.TerminatingGateway.ServiceConfigs[svc]
isHTTP2 := false
if ok {
upstreamCfg, err := structs.ParseUpstreamConfig(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", "upstream", svc, "error", err)
}
isHTTP2 = upstreamCfg.Protocol == "http2" || upstreamCfg.Protocol == "grpc"
}
if isHTTP2 {
if err := s.setHttp2ProtocolOptions(cluster); err != nil {
return nil, err
}
}
// If there is a service-resolver for this service then also setup a cluster for each subset
for name, subset := range resolver.Subsets {
subsetHostnameEndpoints, err := s.filterSubsetEndpoints(&subset, hostnameEndpoints)
if err != nil {
return nil, err
}
opts := clusterOpts{
name: connect.ServiceSNI(svc.Name, name, svc.NamespaceOrDefault(), svc.PartitionOrDefault(), cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain),
hostnameEndpoints: subsetHostnameEndpoints,
onlyPassing: subset.OnlyPassing,
connectTimeout: resolver.ConnectTimeout,
isRemote: isRemote,
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
if err := s.injectGatewayServiceAddons(cfgSnap, cluster, svc, loadBalancer); err != nil {
return nil, err
}
if isHTTP2 {
if err := s.setHttp2ProtocolOptions(cluster); err != nil {
return nil, err
}
}
clusters = append(clusters, cluster)
}
}
return clusters, nil
}
func (s *ResourceGenerator) makeGatewayOutgoingClusterPeeringServiceClusters(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
if cfgSnap.Kind != structs.ServiceKindMeshGateway {
return nil, fmt.Errorf("unsupported gateway kind %q", cfgSnap.Kind)
}
var clusters []proto.Message
for _, serviceGroups := range cfgSnap.MeshGateway.PeeringServices {
for sn, serviceGroup := range serviceGroups {
if len(serviceGroup.Nodes) == 0 {
continue
}
node := serviceGroup.Nodes[0]
if node.Service == nil {
return nil, fmt.Errorf("couldn't get SNI for peered service %s", sn.String())
}
// This uses the SNI in the accepting cluster peer so the remote mesh
// gateway can distinguish between an exported service as opposed to the
// usual mesh gateway route for a service.
clusterName := node.Service.Connect.PeerMeta.PrimarySNI()
var hostnameEndpoints structs.CheckServiceNodes
if serviceGroup.UseCDS {
hostnameEndpoints = serviceGroup.Nodes
}
opts := clusterOpts{
name: clusterName,
isRemote: true,
hostnameEndpoints: hostnameEndpoints,
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
if serviceGroup.UseCDS {
configureClusterWithHostnames(
s.Logger,
cluster,
"", /*TODO:make configurable?*/
serviceGroup.Nodes,
true, /*isRemote*/
false, /*onlyPassing*/
)
} else {
cluster.ClusterDiscoveryType = &envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_EDS}
cluster.EdsClusterConfig = &envoy_cluster_v3.Cluster_EdsClusterConfig{
EdsConfig: &envoy_core_v3.ConfigSource{
ResourceApiVersion: envoy_core_v3.ApiVersion_V3,
ConfigSourceSpecifier: &envoy_core_v3.ConfigSource_Ads{
Ads: &envoy_core_v3.AggregatedConfigSource{},
},
},
}
}
clusters = append(clusters, cluster)
}
}
return clusters, nil
}
func (s *ResourceGenerator) makeDestinationClusters(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
serviceConfigs := cfgSnap.TerminatingGateway.ServiceConfigs
clusters := make([]proto.Message, 0, len(cfgSnap.TerminatingGateway.DestinationServices))
for _, svcName := range cfgSnap.TerminatingGateway.ValidDestinations() {
svcConfig, _ := serviceConfigs[svcName]
dest := svcConfig.Destination
for _, address := range dest.Addresses {
opts := clusterOpts{
name: clusterNameForDestination(cfgSnap, svcName.Name, address, svcName.NamespaceOrDefault(), svcName.PartitionOrDefault()),
addresses: []structs.ServiceAddress{
{
Address: address,
Port: dest.Port,
},
},
}
var cluster *envoy_cluster_v3.Cluster
if structs.IsIP(address) {
cluster = s.makeExternalIPCluster(cfgSnap, opts)
} else {
cluster = s.makeExternalHostnameCluster(cfgSnap, opts)
}
if err := s.injectGatewayDestinationAddons(cfgSnap, cluster, svcName); err != nil {
return nil, err
}
clusters = append(clusters, cluster)
}
}
return clusters, nil
}
func (s *ResourceGenerator) injectGatewayServiceAddons(cfgSnap *proxycfg.ConfigSnapshot, c *envoy_cluster_v3.Cluster, svc structs.ServiceName, lb *structs.LoadBalancer) error {
switch cfgSnap.Kind {
case structs.ServiceKindMeshGateway:
// We can't apply hash based LB config to mesh gateways because they rely on inspecting HTTP attributes
// and mesh gateways do not decrypt traffic
if !lb.IsHashBased() {
if err := injectLBToCluster(lb, c); err != nil {
return fmt.Errorf("failed to apply load balancer configuration to cluster %q: %v", c.Name, err)
}
}
case structs.ServiceKindTerminatingGateway:
// Context used for TLS origination to the cluster
if mapping, ok := cfgSnap.TerminatingGateway.GatewayServices[svc]; ok && mapping.CAFile != "" {
tlsContext := &envoy_tls_v3.UpstreamTlsContext{
CommonTlsContext: makeCommonTLSContextFromFiles(mapping.CAFile, mapping.CertFile, mapping.KeyFile),
}
if mapping.SNI != "" {
tlsContext.Sni = mapping.SNI
if err := injectSANMatcher(tlsContext.CommonTlsContext, mapping.SNI); err != nil {
return fmt.Errorf("failed to inject SNI matcher into TLS context: %v", err)
}
}
transportSocket, err := makeUpstreamTLSTransportSocket(tlsContext)
if err != nil {
return err
}
c.TransportSocket = transportSocket
}
if err := injectLBToCluster(lb, c); err != nil {
return fmt.Errorf("failed to apply load balancer configuration to cluster %q: %v", c.Name, err)
}
}
return nil
}
func (s *ResourceGenerator) injectGatewayDestinationAddons(cfgSnap *proxycfg.ConfigSnapshot, c *envoy_cluster_v3.Cluster, svc structs.ServiceName) error {
switch cfgSnap.Kind {
case structs.ServiceKindTerminatingGateway:
// Context used for TLS origination to the cluster
if mapping, ok := cfgSnap.TerminatingGateway.DestinationServices[svc]; ok && mapping.CAFile != "" {
tlsContext := &envoy_tls_v3.UpstreamTlsContext{
CommonTlsContext: makeCommonTLSContextFromFiles(mapping.CAFile, mapping.CertFile, mapping.KeyFile),
}
if mapping.SNI != "" {
tlsContext.Sni = mapping.SNI
if err := injectSANMatcher(tlsContext.CommonTlsContext, mapping.SNI); err != nil {
return fmt.Errorf("failed to inject SNI matcher into TLS context: %v", err)
}
}
transportSocket, err := makeUpstreamTLSTransportSocket(tlsContext)
if err != nil {
return err
}
c.TransportSocket = transportSocket
}
}
return nil
}
func (s *ResourceGenerator) clustersFromSnapshotIngressGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
var clusters []proto.Message
createdClusters := make(map[proxycfg.UpstreamID]bool)
for listenerKey, upstreams := range cfgSnap.IngressGateway.Upstreams {
for _, u := range upstreams {
uid := proxycfg.NewUpstreamID(&u)
// If we've already created a cluster for this upstream, skip it. Multiple listeners may
// reference the same upstream, so we don't need to create duplicate clusters in that case.
if createdClusters[uid] {
continue
}
chain, ok := cfgSnap.IngressGateway.DiscoveryChain[uid]
if !ok {
// this should not happen
return nil, fmt.Errorf("no discovery chain for upstream %q", uid)
}
upstreamClusters, err := s.makeUpstreamClustersForDiscoveryChain(
uid,
&u,
chain,
cfgSnap,
false,
)
if err != nil {
return nil, err
}
for _, c := range upstreamClusters {
s.configIngressUpstreamCluster(c, cfgSnap, listenerKey, &u)
clusters = append(clusters, c)
}
createdClusters[uid] = true
}
}
return clusters, nil
}
func (s *ResourceGenerator) configIngressUpstreamCluster(c *envoy_cluster_v3.Cluster, cfgSnap *proxycfg.ConfigSnapshot, listenerKey proxycfg.IngressListenerKey, u *structs.Upstream) {
var threshold *envoy_cluster_v3.CircuitBreakers_Thresholds
setThresholdLimit := func(limitType string, limit int) {
if limit <= 0 {
return
}
if threshold == nil {
threshold = &envoy_cluster_v3.CircuitBreakers_Thresholds{}
}
switch limitType {
case "max_connections":
threshold.MaxConnections = makeUint32Value(limit)
case "max_pending_requests":
threshold.MaxPendingRequests = makeUint32Value(limit)
case "max_requests":
threshold.MaxRequests = makeUint32Value(limit)
}
}
setThresholdLimit("max_connections", int(cfgSnap.IngressGateway.Defaults.MaxConnections))
setThresholdLimit("max_pending_requests", int(cfgSnap.IngressGateway.Defaults.MaxPendingRequests))
setThresholdLimit("max_requests", int(cfgSnap.IngressGateway.Defaults.MaxConcurrentRequests))
// Adjust the limit for upstream service
// Lookup listener and service config details from ingress gateway
// definition.
var svc *structs.IngressService
if lCfg, ok := cfgSnap.IngressGateway.Listeners[listenerKey]; ok {
svc = findIngressServiceMatchingUpstream(lCfg, *u)
}
if svc != nil {
setThresholdLimit("max_connections", int(svc.MaxConnections))
setThresholdLimit("max_pending_requests", int(svc.MaxPendingRequests))
setThresholdLimit("max_requests", int(svc.MaxConcurrentRequests))
}
if threshold != nil {
c.CircuitBreakers.Thresholds = []*envoy_cluster_v3.CircuitBreakers_Thresholds{threshold}
}
// Configure the outlier detector for upstream service
var override *structs.PassiveHealthCheck
if svc != nil {
override = svc.PassiveHealthCheck
}
outlierDetection := ToOutlierDetection(cfgSnap.IngressGateway.Defaults.PassiveHealthCheck, override, false)
// Specail handling for failover peering service, which has set MaxEjectionPercent
if c.OutlierDetection != nil && c.OutlierDetection.MaxEjectionPercent != nil {
outlierDetection.MaxEjectionPercent = &wrappers.UInt32Value{Value: c.OutlierDetection.MaxEjectionPercent.Value}
}
c.OutlierDetection = outlierDetection
}
func (s *ResourceGenerator) makeAppCluster(cfgSnap *proxycfg.ConfigSnapshot, name, pathProtocol string, port int) (*envoy_cluster_v3.Cluster, error) {
var c *envoy_cluster_v3.Cluster
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)
}
// If we have overridden local cluster config try to parse it into an Envoy cluster
if cfg.LocalClusterJSON != "" {
return makeClusterFromUserConfig(cfg.LocalClusterJSON)
}
var endpoint *envoy_endpoint_v3.LbEndpoint
if cfgSnap.Proxy.LocalServiceSocketPath != "" {
endpoint = makePipeEndpoint(cfgSnap.Proxy.LocalServiceSocketPath)
} else {
addr := cfgSnap.Proxy.LocalServiceAddress
if addr == "" {
addr = "127.0.0.1"
}
endpoint = makeEndpoint(addr, port)
}
c = &envoy_cluster_v3.Cluster{
Name: name,
ConnectTimeout: durationpb.New(time.Duration(cfg.LocalConnectTimeoutMs) * time.Millisecond),
ClusterDiscoveryType: &envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_STATIC},
LoadAssignment: &envoy_endpoint_v3.ClusterLoadAssignment{
ClusterName: name,
Endpoints: []*envoy_endpoint_v3.LocalityLbEndpoints{
{
LbEndpoints: []*envoy_endpoint_v3.LbEndpoint{
endpoint,
},
},
},
},
}
protocol := pathProtocol
if protocol == "" {
protocol = cfg.Protocol
}
if protocol == "http2" || protocol == "grpc" {
if err := s.setHttp2ProtocolOptions(c); err != nil {
return c, err
}
}
if cfg.MaxInboundConnections > 0 {
c.CircuitBreakers = &envoy_cluster_v3.CircuitBreakers{
Thresholds: []*envoy_cluster_v3.CircuitBreakers_Thresholds{
{
MaxConnections: makeUint32Value(cfg.MaxInboundConnections),
},
},
}
}
return c, err
}
func (s *ResourceGenerator) makeUpstreamClusterForPeerService(
uid proxycfg.UpstreamID,
upstreamConfig structs.UpstreamConfig,
peerMeta structs.PeeringServiceMeta,
cfgSnap *proxycfg.ConfigSnapshot,
) (*envoy_cluster_v3.Cluster, error) {
var (
c *envoy_cluster_v3.Cluster
err error
)
if upstreamConfig.EnvoyClusterJSON != "" {
c, err = makeClusterFromUserConfig(upstreamConfig.EnvoyClusterJSON)
if err != nil {
return c, err
}
// In the happy path don't return yet as we need to inject TLS config still.
}
upstreamsSnapshot, err := cfgSnap.ToConfigSnapshotUpstreams()
if err != nil {
return c, err
}
tbs, ok := upstreamsSnapshot.UpstreamPeerTrustBundles.Get(uid.Peer)
if !ok {
// this should never happen since we loop through upstreams with
// set trust bundles
return c, fmt.Errorf("trust bundle not ready for peer %s", uid.Peer)
}
clusterName := generatePeeredClusterName(uid, tbs)
outlierDetection := ToOutlierDetection(upstreamConfig.PassiveHealthCheck, nil, true)
// We can't rely on health checks for services on cluster peers because they
// don't take into account service resolvers, splitters and routers. Setting
// MaxEjectionPercent too 100% gives outlier detection the power to eject the
// entire cluster.
outlierDetection.MaxEjectionPercent = &wrappers.UInt32Value{Value: 100}
s.Logger.Trace("generating cluster for", "cluster", clusterName)
if c == nil {
c = &envoy_cluster_v3.Cluster{
Name: clusterName,
ConnectTimeout: durationpb.New(time.Duration(upstreamConfig.ConnectTimeoutMs) * time.Millisecond),
CommonLbConfig: &envoy_cluster_v3.Cluster_CommonLbConfig{
HealthyPanicThreshold: &envoy_type_v3.Percent{
Value: 0, // disable panic threshold
},
},
CircuitBreakers: &envoy_cluster_v3.CircuitBreakers{
Thresholds: makeThresholdsIfNeeded(upstreamConfig.Limits),
},
OutlierDetection: outlierDetection,
}
if upstreamConfig.Protocol == "http2" || upstreamConfig.Protocol == "grpc" {
if err := s.setHttp2ProtocolOptions(c); err != nil {
return c, err
}
}
useEDS := true
if _, ok := cfgSnap.ConnectProxy.PeerUpstreamEndpointsUseHostnames[uid]; ok {
// If we're using local mesh gw, the fact that upstreams use hostnames don't matter.
// If we're not using local mesh gw, then resort to CDS.
if upstreamConfig.MeshGateway.Mode != structs.MeshGatewayModeLocal {
useEDS = false
}
}
// If none of the service instances are addressed by a hostname we
// provide the endpoint IP addresses via EDS
if useEDS {
c.ClusterDiscoveryType = &envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_EDS}
c.EdsClusterConfig = &envoy_cluster_v3.Cluster_EdsClusterConfig{
EdsConfig: &envoy_core_v3.ConfigSource{
ResourceApiVersion: envoy_core_v3.ApiVersion_V3,
ConfigSourceSpecifier: &envoy_core_v3.ConfigSource_Ads{
Ads: &envoy_core_v3.AggregatedConfigSource{},
},
},
}
} else {
ep, _ := cfgSnap.ConnectProxy.PeerUpstreamEndpoints.Get(uid)
configureClusterWithHostnames(
s.Logger,
c,
"", /*TODO:make configurable?*/
ep,
true, /*isRemote*/
false, /*onlyPassing*/
)
}
}
rootPEMs := cfgSnap.RootPEMs()
if uid.Peer != "" {
tbs, _ := upstreamsSnapshot.UpstreamPeerTrustBundles.Get(uid.Peer)
rootPEMs = tbs.ConcatenatedRootPEMs()
}
// Enable TLS upstream with the configured client certificate.
commonTLSContext := makeCommonTLSContext(
cfgSnap.Leaf(),
rootPEMs,
makeTLSParametersFromProxyTLSConfig(cfgSnap.MeshConfigTLSOutgoing()),
)
err = injectSANMatcher(commonTLSContext, peerMeta.SpiffeID...)
if err != nil {
return nil, fmt.Errorf("failed to inject SAN matcher rules for cluster %q: %v", clusterName, err)
}
tlsContext := &envoy_tls_v3.UpstreamTlsContext{
CommonTlsContext: commonTLSContext,
Sni: peerMeta.PrimarySNI(),
}
transportSocket, err := makeUpstreamTLSTransportSocket(tlsContext)
if err != nil {
return nil, err
}
c.TransportSocket = transportSocket
return c, nil
}
func (s *ResourceGenerator) makeUpstreamClusterForPreparedQuery(upstream structs.Upstream, cfgSnap *proxycfg.ConfigSnapshot) (*envoy_cluster_v3.Cluster, error) {
var c *envoy_cluster_v3.Cluster
var err error
uid := proxycfg.NewUpstreamID(&upstream)
dc := upstream.Datacenter
if dc == "" {
dc = cfgSnap.Datacenter
}
sni := connect.UpstreamSNI(&upstream, "", dc, cfgSnap.Roots.TrustDomain)
cfg, err := structs.ParseUpstreamConfig(upstream.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 cfg.EnvoyClusterJSON != "" {
c, err = makeClusterFromUserConfig(cfg.EnvoyClusterJSON)
if err != nil {
return c, err
}
// In the happy path don't return yet as we need to inject TLS config still.
}
if c == nil {
c = &envoy_cluster_v3.Cluster{
Name: sni,
ConnectTimeout: durationpb.New(time.Duration(cfg.ConnectTimeoutMs) * time.Millisecond),
ClusterDiscoveryType: &envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_EDS},
EdsClusterConfig: &envoy_cluster_v3.Cluster_EdsClusterConfig{
EdsConfig: &envoy_core_v3.ConfigSource{
ResourceApiVersion: envoy_core_v3.ApiVersion_V3,
ConfigSourceSpecifier: &envoy_core_v3.ConfigSource_Ads{
Ads: &envoy_core_v3.AggregatedConfigSource{},
},
},
},
CircuitBreakers: &envoy_cluster_v3.CircuitBreakers{
Thresholds: makeThresholdsIfNeeded(cfg.Limits),
},
OutlierDetection: ToOutlierDetection(cfg.PassiveHealthCheck, nil, true),
}
if cfg.Protocol == "http2" || cfg.Protocol == "grpc" {
if err := s.setHttp2ProtocolOptions(c); err != nil {
return c, err
}
}
}
endpoints := cfgSnap.ConnectProxy.PreparedQueryEndpoints[uid]
var (
spiffeIDs = make([]string, 0)
seen = make(map[string]struct{})
)
for _, e := range endpoints {
id := fmt.Sprintf("%s/%s", e.Node.Datacenter, e.Service.CompoundServiceName())
if _, ok := seen[id]; ok {
continue
}
seen[id] = struct{}{}
name := e.Service.Proxy.DestinationServiceName
if e.Service.Connect.Native {
name = e.Service.Service
}
spiffeIDs = append(spiffeIDs, connect.SpiffeIDService{
Host: cfgSnap.Roots.TrustDomain,
Namespace: e.Service.NamespaceOrDefault(),
Partition: e.Service.PartitionOrDefault(),
Datacenter: e.Node.Datacenter,
Service: name,
}.URI().String())
}
// Enable TLS upstream with the configured client certificate.
commonTLSContext := makeCommonTLSContext(
cfgSnap.Leaf(),
cfgSnap.RootPEMs(),
makeTLSParametersFromProxyTLSConfig(cfgSnap.MeshConfigTLSOutgoing()),
)
err = injectSANMatcher(commonTLSContext, spiffeIDs...)
if err != nil {
return nil, fmt.Errorf("failed to inject SAN matcher rules for cluster %q: %v", sni, err)
}
tlsContext := &envoy_tls_v3.UpstreamTlsContext{
CommonTlsContext: commonTLSContext,
Sni: sni,
}
transportSocket, err := makeUpstreamTLSTransportSocket(tlsContext)
if err != nil {
return nil, err
}
c.TransportSocket = transportSocket
return c, nil
}
func (s *ResourceGenerator) makeUpstreamClustersForDiscoveryChain(
uid proxycfg.UpstreamID,
upstream *structs.Upstream,
chain *structs.CompiledDiscoveryChain,
cfgSnap *proxycfg.ConfigSnapshot,
forMeshGateway bool,
) ([]*envoy_cluster_v3.Cluster, error) {
if chain == nil {
return nil, fmt.Errorf("cannot create upstream cluster without discovery chain for %s", uid)
}
if uid.Peer != "" && forMeshGateway {
return nil, fmt.Errorf("impossible to get a peer discovery chain in a mesh gateway")
}
upstreamConfigMap := make(map[string]interface{})
if upstream != nil {
upstreamConfigMap = upstream.Config
}
upstreamsSnapshot, err := cfgSnap.ToConfigSnapshotUpstreams()
// Mesh gateways are exempt because upstreamsSnapshot is only used for
// cluster peering targets and transative failover/redirects are unsupported.
if err != nil && !forMeshGateway {
return nil, err
}
rawUpstreamConfig, err := structs.ParseUpstreamConfigNoDefaults(upstreamConfigMap)
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)
}
finalizeUpstreamConfig := func(cfg structs.UpstreamConfig, connectTimeout time.Duration) structs.UpstreamConfig {
if cfg.Protocol == "" {
cfg.Protocol = chain.Protocol
}
if cfg.Protocol == "" {
cfg.Protocol = "tcp"
}
if cfg.ConnectTimeoutMs == 0 {
cfg.ConnectTimeoutMs = int(connectTimeout / time.Millisecond)
}
return cfg
}
var escapeHatchCluster *envoy_cluster_v3.Cluster
if !forMeshGateway {
if rawUpstreamConfig.EnvoyClusterJSON != "" {
if chain.Default {
// If you haven't done anything to setup the discovery chain, then
// you can use the envoy_cluster_json escape hatch.
escapeHatchCluster, err = makeClusterFromUserConfig(rawUpstreamConfig.EnvoyClusterJSON)
if err != nil {
return nil, err
}
} else {
s.Logger.Warn("ignoring escape hatch setting, because a discovery chain is configured for",
"discovery chain", chain.ServiceName, "upstream", uid,
"envoy_cluster_json", chain.ServiceName)
}
}
}
var out []*envoy_cluster_v3.Cluster
for _, node := range chain.Nodes {
switch {
case node == nil:
return nil, fmt.Errorf("impossible to process a nil node")
case node.Type != structs.DiscoveryGraphNodeTypeResolver:
continue
case node.Resolver == nil:
return nil, fmt.Errorf("impossible to process a non-resolver node")
}
failover := node.Resolver.Failover
// These variables are prefixed with primary to avoid shaddowing bugs.
primaryTargetID := node.Resolver.Target
primaryTarget := chain.Targets[primaryTargetID]
primaryTargetClusterData, ok := s.getTargetClusterData(upstreamsSnapshot, chain, primaryTargetID, forMeshGateway, false)
if !ok {
continue
}
upstreamConfig := finalizeUpstreamConfig(rawUpstreamConfig, node.Resolver.ConnectTimeout)
if forMeshGateway && !cfgSnap.Locality.Matches(primaryTarget.Datacenter, primaryTarget.Partition) {
s.Logger.Warn("ignoring discovery chain target that crosses a datacenter or partition boundary in a mesh gateway",
"target", primaryTarget,
"gatewayLocality", cfgSnap.Locality,
)
continue
}
// Construct the information required to make target clusters. When
// failover is configured, create the aggregate cluster.
var targetClustersData []targetClusterData
if failover != nil && !forMeshGateway {
var failoverClusterNames []string
for _, tid := range append([]string{primaryTargetID}, failover.Targets...) {
if td, ok := s.getTargetClusterData(upstreamsSnapshot, chain, tid, forMeshGateway, true); ok {
targetClustersData = append(targetClustersData, td)
failoverClusterNames = append(failoverClusterNames, td.clusterName)
}
}
aggregateClusterConfig, err := anypb.New(&envoy_aggregate_cluster_v3.ClusterConfig{
Clusters: failoverClusterNames,
})
if err != nil {
return nil, fmt.Errorf("failed to construct the aggregate cluster %q: %v", primaryTargetClusterData.clusterName, err)
}
c := &envoy_cluster_v3.Cluster{
Name: primaryTargetClusterData.clusterName,
AltStatName: primaryTargetClusterData.clusterName,
ConnectTimeout: durationpb.New(node.Resolver.ConnectTimeout),
LbPolicy: envoy_cluster_v3.Cluster_CLUSTER_PROVIDED,
ClusterDiscoveryType: &envoy_cluster_v3.Cluster_ClusterType{
ClusterType: &envoy_cluster_v3.Cluster_CustomClusterType{
Name: "envoy.clusters.aggregate",
TypedConfig: aggregateClusterConfig,
},
},
}
out = append(out, c)
} else {
targetClustersData = append(targetClustersData, primaryTargetClusterData)
}
// Construct the target clusters.
for _, targetData := range targetClustersData {
target := chain.Targets[targetData.targetID]
sni := target.SNI
var additionalSpiffeIDs []string
targetSpiffeID := connect.SpiffeIDService{
Host: cfgSnap.Roots.TrustDomain,
Namespace: target.Namespace,
Partition: target.Partition,
Datacenter: target.Datacenter,
Service: target.Service,
}.URI().String()
targetUID := proxycfg.NewUpstreamIDFromTargetID(targetData.targetID)
if targetUID.Peer != "" {
peerMeta := upstreamsSnapshot.UpstreamPeerMeta(targetUID)
upstreamCluster, err := s.makeUpstreamClusterForPeerService(targetUID, upstreamConfig, peerMeta, cfgSnap)
if err != nil {
continue
}
// Override the cluster name to include the failover-target~ prefix.
upstreamCluster.Name = targetData.clusterName
out = append(out, upstreamCluster)
continue
}
s.Logger.Debug("generating cluster for", "cluster", targetData.clusterName)
c := &envoy_cluster_v3.Cluster{
Name: targetData.clusterName,
AltStatName: targetData.clusterName,
ConnectTimeout: durationpb.New(node.Resolver.ConnectTimeout),
ClusterDiscoveryType: &envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_EDS},
CommonLbConfig: &envoy_cluster_v3.Cluster_CommonLbConfig{
HealthyPanicThreshold: &envoy_type_v3.Percent{
Value: 0, // disable panic threshold
},
},
EdsClusterConfig: &envoy_cluster_v3.Cluster_EdsClusterConfig{
EdsConfig: &envoy_core_v3.ConfigSource{
ResourceApiVersion: envoy_core_v3.ApiVersion_V3,
ConfigSourceSpecifier: &envoy_core_v3.ConfigSource_Ads{
Ads: &envoy_core_v3.AggregatedConfigSource{},
},
},
},
// TODO(peering): make circuit breakers or outlier detection work?
CircuitBreakers: &envoy_cluster_v3.CircuitBreakers{
Thresholds: makeThresholdsIfNeeded(upstreamConfig.Limits),
},
OutlierDetection: ToOutlierDetection(upstreamConfig.PassiveHealthCheck, nil, true),
}
var lb *structs.LoadBalancer
if node.LoadBalancer != nil {
lb = node.LoadBalancer
}
if err := injectLBToCluster(lb, c); err != nil {
return nil, fmt.Errorf("failed to apply load balancer configuration to cluster %q: %v", targetData.clusterName, err)
}
if upstreamConfig.Protocol == "http2" || upstreamConfig.Protocol == "grpc" {
if err := s.setHttp2ProtocolOptions(c); err != nil {
return nil, err
}
}
configureTLS := true
if forMeshGateway {
// We only initiate TLS if we're doing an L7 proxy.
configureTLS = structs.IsProtocolHTTPLike(upstreamConfig.Protocol)
}
if configureTLS {
commonTLSContext := makeCommonTLSContext(
cfgSnap.Leaf(),
cfgSnap.RootPEMs(),
makeTLSParametersFromProxyTLSConfig(cfgSnap.MeshConfigTLSOutgoing()),
)
spiffeIDs := append([]string{targetSpiffeID}, additionalSpiffeIDs...)
sort.Strings(spiffeIDs)
err = injectSANMatcher(commonTLSContext, spiffeIDs...)
if err != nil {
return nil, fmt.Errorf("failed to inject SAN matcher rules for cluster %q: %v", sni, err)
}
tlsContext := &envoy_tls_v3.UpstreamTlsContext{
CommonTlsContext: commonTLSContext,
Sni: sni,
}
transportSocket, err := makeUpstreamTLSTransportSocket(tlsContext)
if err != nil {
return nil, err
}
c.TransportSocket = transportSocket
}
out = append(out, c)
}
}
if escapeHatchCluster != nil {
if len(out) != 1 {
return nil, fmt.Errorf("cannot inject escape hatch cluster when discovery chain had no nodes")
}
defaultCluster := out[0]
// Overlay what the user provided.
escapeHatchCluster.TransportSocket = defaultCluster.TransportSocket
out = []*envoy_cluster_v3.Cluster{escapeHatchCluster}
}
return out, nil
}
func (s *ResourceGenerator) makeExportedUpstreamClustersForMeshGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
// NOTE: Despite the mesh gateway already having one cluster per service
// (and subset) in the local datacenter we cannot reliably use those to
// send inbound peered traffic targeting a discovery chain.
//
// For starters, none of those add TLS so they'd be unusable for http-like
// L7 protocols.
//
// Additionally, those other clusters are all thin wrappers around simple
// catalog resolutions and are largely not impacted by various
// customizations related to a service-resolver, such as configuring the
// failover section.
//
// Instead we create brand new clusters solely to accept incoming peered
// traffic and give them a unique cluster prefix name to avoid collisions
// to keep the two use cases separate.
var clusters []proto.Message
createdExportedClusters := make(map[string]struct{}) // key=clusterName
for _, svc := range cfgSnap.MeshGatewayValidExportedServices() {
chain := cfgSnap.MeshGateway.DiscoveryChain[svc]
exportClusters, err := s.makeUpstreamClustersForDiscoveryChain(
proxycfg.NewUpstreamIDFromServiceName(svc),
nil,
chain,
cfgSnap,
true,
)
if err != nil {
return nil, err
}
for _, cluster := range exportClusters {
if _, ok := createdExportedClusters[cluster.Name]; ok {
continue
}
createdExportedClusters[cluster.Name] = struct{}{}
clusters = append(clusters, cluster)
}
}
return clusters, nil
}
// injectSANMatcher updates a TLS context so that it verifies the upstream SAN.
func injectSANMatcher(tlsContext *envoy_tls_v3.CommonTlsContext, matchStrings ...string) error {
validationCtx, ok := tlsContext.ValidationContextType.(*envoy_tls_v3.CommonTlsContext_ValidationContext)
if !ok {
return fmt.Errorf("invalid type: expected CommonTlsContext_ValidationContext, got %T",
tlsContext.ValidationContextType)
}
var matchers []*envoy_matcher_v3.StringMatcher
for _, m := range matchStrings {
matchers = append(matchers, &envoy_matcher_v3.StringMatcher{
MatchPattern: &envoy_matcher_v3.StringMatcher_Exact{
Exact: m,
},
})
}
//nolint:staticcheck
validationCtx.ValidationContext.MatchSubjectAltNames = matchers
return nil
}
// makeClusterFromUserConfig 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 makeClusterFromUserConfig(configJSON string) (*envoy_cluster_v3.Cluster, error) {
// Type field is present so decode it as a types.Any
var any any.Any
err := jsonpb.UnmarshalString(configJSON, &any)
if err != nil {
return nil, err
}
// And then unmarshal the listener again...
var c envoy_cluster_v3.Cluster
err = proto.Unmarshal(any.Value, &c)
if err != nil {
return nil, err
}
return &c, err
}
type addressPair struct {
host string
port int
}
type clusterOpts struct {
// name for the cluster
name string
// isRemote determines whether the cluster is in a remote DC and we should prefer a WAN address
isRemote bool
// onlyPassing determines whether endpoints that do not have a passing status should be considered unhealthy
onlyPassing bool
// connectTimeout is the timeout for new network connections to hosts in the cluster
connectTimeout time.Duration
// hostnameEndpoints is a list of endpoints with a hostname as their address
hostnameEndpoints structs.CheckServiceNodes
// Corresponds to a valid address/port pairs to be routed externally
// these addresses will be embedded in the cluster configuration and will never use EDS
addresses []structs.ServiceAddress
}
// makeGatewayCluster creates an Envoy cluster for a mesh or terminating gateway
func (s *ResourceGenerator) makeGatewayCluster(snap *proxycfg.ConfigSnapshot, opts clusterOpts) *envoy_cluster_v3.Cluster {
cfg, err := ParseGatewayConfig(snap.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 gateway config", "error", err)
}
if opts.connectTimeout <= 0 {
opts.connectTimeout = time.Duration(cfg.ConnectTimeoutMs) * time.Millisecond
}
cluster := &envoy_cluster_v3.Cluster{
Name: opts.name,
ConnectTimeout: durationpb.New(opts.connectTimeout),
// Having an empty config enables outlier detection with default config.
OutlierDetection: &envoy_cluster_v3.OutlierDetection{},
}
useEDS := true
if len(opts.hostnameEndpoints) > 0 {
useEDS = false
}
// TCP keepalive settings can be enabled for terminating gateway upstreams or remote mesh gateways.
remoteUpstream := opts.isRemote || snap.Kind == structs.ServiceKindTerminatingGateway
if remoteUpstream && cfg.TcpKeepaliveEnable {
cluster.UpstreamConnectionOptions = &envoy_cluster_v3.UpstreamConnectionOptions{
TcpKeepalive: &envoy_core_v3.TcpKeepalive{},
}
if cfg.TcpKeepaliveTime != 0 {
cluster.UpstreamConnectionOptions.TcpKeepalive.KeepaliveTime = makeUint32Value(cfg.TcpKeepaliveTime)
}
if cfg.TcpKeepaliveInterval != 0 {
cluster.UpstreamConnectionOptions.TcpKeepalive.KeepaliveInterval = makeUint32Value(cfg.TcpKeepaliveInterval)
}
if cfg.TcpKeepaliveProbes != 0 {
cluster.UpstreamConnectionOptions.TcpKeepalive.KeepaliveProbes = makeUint32Value(cfg.TcpKeepaliveProbes)
}
}
// If none of the service instances are addressed by a hostname we provide the endpoint IP addresses via EDS
if useEDS {
cluster.ClusterDiscoveryType = &envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_EDS}
cluster.EdsClusterConfig = &envoy_cluster_v3.Cluster_EdsClusterConfig{
EdsConfig: &envoy_core_v3.ConfigSource{
ResourceApiVersion: envoy_core_v3.ApiVersion_V3,
ConfigSourceSpecifier: &envoy_core_v3.ConfigSource_Ads{
Ads: &envoy_core_v3.AggregatedConfigSource{},
},
},
}
} else {
configureClusterWithHostnames(
s.Logger,
cluster,
cfg.DNSDiscoveryType,
opts.hostnameEndpoints,
opts.isRemote,
opts.onlyPassing,
)
}
return cluster
}
func configureClusterWithHostnames(
logger hclog.Logger,
cluster *envoy_cluster_v3.Cluster,
dnsDiscoveryType string,
// hostnameEndpoints is a list of endpoints with a hostname as their address
hostnameEndpoints structs.CheckServiceNodes,
// isRemote determines whether the cluster is in a remote DC or partition and we should prefer a WAN address
isRemote bool,
// onlyPassing determines whether endpoints that do not have a passing status should be considered unhealthy
onlyPassing bool,
) {
// When a service instance is addressed by a hostname we have Envoy do the DNS resolution
// by setting a DNS cluster type and passing the hostname endpoints via CDS.
rate := 10 * time.Second
cluster.DnsRefreshRate = durationpb.New(rate)
cluster.DnsLookupFamily = envoy_cluster_v3.Cluster_V4_ONLY
discoveryType := envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_LOGICAL_DNS}
if dnsDiscoveryType == "strict_dns" {
discoveryType.Type = envoy_cluster_v3.Cluster_STRICT_DNS
}
cluster.ClusterDiscoveryType = &discoveryType
endpoints := make([]*envoy_endpoint_v3.LbEndpoint, 0, 1)
uniqueHostnames := make(map[string]bool)
var (
hostname string
idx int
fallback *envoy_endpoint_v3.LbEndpoint
)
for i, e := range hostnameEndpoints {
_, addr, port := e.BestAddress(isRemote)
uniqueHostnames[addr] = true
health, weight := calculateEndpointHealthAndWeight(e, onlyPassing)
if health == envoy_core_v3.HealthStatus_UNHEALTHY {
fallback = makeLbEndpoint(addr, port, health, weight)
continue
}
if len(endpoints) == 0 {
endpoints = append(endpoints, makeLbEndpoint(addr, port, health, weight))
hostname = addr
idx = i
break
}
}
dc := hostnameEndpoints[idx].Node.Datacenter
service := hostnameEndpoints[idx].Service.CompoundServiceName()
// Fall back to last unhealthy endpoint if none were healthy
if len(endpoints) == 0 {
logger.Warn("upstream service does not contain any healthy instances",
"dc", dc, "service", service.String())
endpoints = append(endpoints, fallback)
}
if len(uniqueHostnames) > 1 {
logger.Warn(fmt.Sprintf("service contains instances with more than one unique hostname; only %q be resolved by Envoy", hostname),
"dc", dc, "service", service.String())
}
cluster.LoadAssignment = &envoy_endpoint_v3.ClusterLoadAssignment{
ClusterName: cluster.Name,
Endpoints: []*envoy_endpoint_v3.LocalityLbEndpoints{
{
LbEndpoints: endpoints,
},
},
}
}
// makeExternalIPCluster creates an Envoy cluster for routing to IP addresses outside of Consul
// This is used by terminating gateways for Destinations
func (s *ResourceGenerator) makeExternalIPCluster(snap *proxycfg.ConfigSnapshot, opts clusterOpts) *envoy_cluster_v3.Cluster {
cfg, err := ParseGatewayConfig(snap.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 gateway config", "error", err)
}
if opts.connectTimeout <= 0 {
opts.connectTimeout = time.Duration(cfg.ConnectTimeoutMs) * time.Millisecond
}
cluster := &envoy_cluster_v3.Cluster{
Name: opts.name,
ConnectTimeout: durationpb.New(opts.connectTimeout),
// Having an empty config enables outlier detection with default config.
OutlierDetection: &envoy_cluster_v3.OutlierDetection{},
ClusterDiscoveryType: &envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_STATIC},
}
endpoints := make([]*envoy_endpoint_v3.LbEndpoint, 0, len(opts.addresses))
for _, pair := range opts.addresses {
endpoints = append(endpoints, makeEndpoint(pair.Address, pair.Port))
}
cluster.LoadAssignment = &envoy_endpoint_v3.ClusterLoadAssignment{
ClusterName: cluster.Name,
Endpoints: []*envoy_endpoint_v3.LocalityLbEndpoints{
{
LbEndpoints: endpoints,
},
},
}
return cluster
}
// makeExternalHostnameCluster creates an Envoy cluster for hostname endpoints that will be resolved with DNS
// This is used by both terminating gateways for Destinations, and Mesh Gateways for peering control plane traffice
func (s *ResourceGenerator) makeExternalHostnameCluster(snap *proxycfg.ConfigSnapshot, opts clusterOpts) *envoy_cluster_v3.Cluster {
cfg, err := ParseGatewayConfig(snap.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 gateway config", "error", err)
}
opts.connectTimeout = time.Duration(cfg.ConnectTimeoutMs) * time.Millisecond
cluster := &envoy_cluster_v3.Cluster{
Name: opts.name,
ConnectTimeout: durationpb.New(opts.connectTimeout),
// Having an empty config enables outlier detection with default config.
OutlierDetection: &envoy_cluster_v3.OutlierDetection{},
ClusterDiscoveryType: &envoy_cluster_v3.Cluster_Type{Type: envoy_cluster_v3.Cluster_LOGICAL_DNS},
DnsLookupFamily: envoy_cluster_v3.Cluster_V4_ONLY,
}
rate := 10 * time.Second
cluster.DnsRefreshRate = durationpb.New(rate)
endpoints := make([]*envoy_endpoint_v3.LbEndpoint, 0, len(opts.addresses))
for _, pair := range opts.addresses {
address := makeAddress(pair.Address, pair.Port)
endpoint := &envoy_endpoint_v3.LbEndpoint{
HostIdentifier: &envoy_endpoint_v3.LbEndpoint_Endpoint{
Endpoint: &envoy_endpoint_v3.Endpoint{
Address: address,
},
},
}
endpoints = append(endpoints, endpoint)
}
cluster.LoadAssignment = &envoy_endpoint_v3.ClusterLoadAssignment{
ClusterName: cluster.Name,
Endpoints: []*envoy_endpoint_v3.LocalityLbEndpoints{{
LbEndpoints: endpoints,
}},
}
return cluster
}
func makeThresholdsIfNeeded(limits *structs.UpstreamLimits) []*envoy_cluster_v3.CircuitBreakers_Thresholds {
if limits == nil {
return nil
}
threshold := &envoy_cluster_v3.CircuitBreakers_Thresholds{}
// Likewise, make sure to not set any threshold values on the zero-value in
// order to rely on Envoy defaults
if limits.MaxConnections != nil {
threshold.MaxConnections = makeUint32Value(*limits.MaxConnections)
}
if limits.MaxPendingRequests != nil {
threshold.MaxPendingRequests = makeUint32Value(*limits.MaxPendingRequests)
}
if limits.MaxConcurrentRequests != nil {
threshold.MaxRequests = makeUint32Value(*limits.MaxConcurrentRequests)
}
return []*envoy_cluster_v3.CircuitBreakers_Thresholds{threshold}
}
func makeLbEndpoint(addr string, port int, health envoy_core_v3.HealthStatus, weight int) *envoy_endpoint_v3.LbEndpoint {
return &envoy_endpoint_v3.LbEndpoint{
HostIdentifier: &envoy_endpoint_v3.LbEndpoint_Endpoint{
Endpoint: &envoy_endpoint_v3.Endpoint{
Address: &envoy_core_v3.Address{
Address: &envoy_core_v3.Address_SocketAddress{
SocketAddress: &envoy_core_v3.SocketAddress{
Address: addr,
PortSpecifier: &envoy_core_v3.SocketAddress_PortValue{
PortValue: uint32(port),
},
},
},
},
},
},
HealthStatus: health,
LoadBalancingWeight: makeUint32Value(weight),
}
}
func injectLBToCluster(ec *structs.LoadBalancer, c *envoy_cluster_v3.Cluster) error {
if ec == nil {
return nil
}
switch ec.Policy {
case "":
return nil
case structs.LBPolicyLeastRequest:
c.LbPolicy = envoy_cluster_v3.Cluster_LEAST_REQUEST
if ec.LeastRequestConfig != nil {
c.LbConfig = &envoy_cluster_v3.Cluster_LeastRequestLbConfig_{
LeastRequestLbConfig: &envoy_cluster_v3.Cluster_LeastRequestLbConfig{
ChoiceCount: &wrappers.UInt32Value{Value: ec.LeastRequestConfig.ChoiceCount},
},
}
}
case structs.LBPolicyRoundRobin:
c.LbPolicy = envoy_cluster_v3.Cluster_ROUND_ROBIN
case structs.LBPolicyRandom:
c.LbPolicy = envoy_cluster_v3.Cluster_RANDOM
case structs.LBPolicyRingHash:
c.LbPolicy = envoy_cluster_v3.Cluster_RING_HASH
if ec.RingHashConfig != nil {
c.LbConfig = &envoy_cluster_v3.Cluster_RingHashLbConfig_{
RingHashLbConfig: &envoy_cluster_v3.Cluster_RingHashLbConfig{
MinimumRingSize: &wrappers.UInt64Value{Value: ec.RingHashConfig.MinimumRingSize},
MaximumRingSize: &wrappers.UInt64Value{Value: ec.RingHashConfig.MaximumRingSize},
},
}
}
case structs.LBPolicyMaglev:
c.LbPolicy = envoy_cluster_v3.Cluster_MAGLEV
default:
return fmt.Errorf("unsupported load balancer policy %q for cluster %q", ec.Policy, c.Name)
}
return nil
}
func (s *ResourceGenerator) setHttp2ProtocolOptions(c *envoy_cluster_v3.Cluster) error {
cfg := &envoy_upstreams_v3.HttpProtocolOptions{
UpstreamProtocolOptions: &envoy_upstreams_v3.HttpProtocolOptions_ExplicitHttpConfig_{
ExplicitHttpConfig: &envoy_upstreams_v3.HttpProtocolOptions_ExplicitHttpConfig{
ProtocolConfig: &envoy_upstreams_v3.HttpProtocolOptions_ExplicitHttpConfig_Http2ProtocolOptions{
Http2ProtocolOptions: &envoy_core_v3.Http2ProtocolOptions{},
},
},
},
}
any, err := anypb.New(cfg)
if err != nil {
return err
}
c.TypedExtensionProtocolOptions = map[string]*anypb.Any{
"envoy.extensions.upstreams.http.v3.HttpProtocolOptions": any,
}
return nil
}
// generatePeeredClusterName returns an SNI-like cluster name which mimics PeeredServiceSNI
// but excludes partition information which could be ambiguous (local vs remote partition).
func generatePeeredClusterName(uid proxycfg.UpstreamID, tb *pbpeering.PeeringTrustBundle) string {
return strings.Join([]string{
uid.Name,
uid.NamespaceOrDefault(),
uid.Peer,
"external",
tb.TrustDomain,
}, ".")
}
type targetClusterData struct {
targetID string
clusterName string
}
func (s *ResourceGenerator) getTargetClusterData(upstreamsSnapshot *proxycfg.ConfigSnapshotUpstreams, chain *structs.CompiledDiscoveryChain, tid string, forMeshGateway bool, failover bool) (targetClusterData, bool) {
target := chain.Targets[tid]
clusterName := target.Name
targetUID := proxycfg.NewUpstreamIDFromTargetID(tid)
if targetUID.Peer != "" {
tbs, ok := upstreamsSnapshot.UpstreamPeerTrustBundles.Get(targetUID.Peer)
// We can't generate cluster on peers without the trust bundle. The
// trust bundle should be ready soon.
if !ok {
s.Logger.Debug("peer trust bundle not ready for discovery chain target",
"peer", targetUID.Peer,
"target", tid,
)
return targetClusterData{}, false
}
clusterName = generatePeeredClusterName(targetUID, tbs)
}
clusterName = CustomizeClusterName(clusterName, chain)
if failover {
clusterName = failoverClusterNamePrefix + clusterName
}
if forMeshGateway {
clusterName = meshGatewayExportedClusterNamePrefix + clusterName
}
return targetClusterData{
targetID: tid,
clusterName: clusterName,
}, true
}