consul/agent/xds/clusters.go

829 lines
27 KiB
Go

package xds
import (
"encoding/json"
"errors"
"fmt"
"time"
envoy "github.com/envoyproxy/go-control-plane/envoy/api/v2"
envoyauth "github.com/envoyproxy/go-control-plane/envoy/api/v2/auth"
envoycluster "github.com/envoyproxy/go-control-plane/envoy/api/v2/cluster"
envoycore "github.com/envoyproxy/go-control-plane/envoy/api/v2/core"
envoyendpoint "github.com/envoyproxy/go-control-plane/envoy/api/v2/endpoint"
envoytype "github.com/envoyproxy/go-control-plane/envoy/type"
"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"
"github.com/hashicorp/consul/agent/connect"
"github.com/hashicorp/consul/agent/proxycfg"
"github.com/hashicorp/consul/agent/structs"
"github.com/hashicorp/consul/logging"
)
// clustersFromSnapshot returns the xDS API representation of the "clusters" in the snapshot.
func (s *Server) clustersFromSnapshot(_ connectionInfo, 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:
return s.makeGatewayServiceClusters(cfgSnap)
case structs.ServiceKindMeshGateway:
return s.clustersFromSnapshotMeshGateway(cfgSnap)
case structs.ServiceKindIngressGateway:
return s.clustersFromSnapshotIngressGateway(cfgSnap)
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 *Server) clustersFromSnapshotConnectProxy(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
// TODO(rb): this sizing is a low bound.
clusters := make([]proto.Message, 0, len(cfgSnap.Proxy.Upstreams)+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)
for _, u := range cfgSnap.Proxy.Upstreams {
id := u.Identifier()
if u.DestinationType == structs.UpstreamDestTypePreparedQuery {
upstreamCluster, err := s.makeUpstreamClusterForPreparedQuery(u, cfgSnap)
if err != nil {
return nil, err
}
clusters = append(clusters, upstreamCluster)
} else {
chain := cfgSnap.ConnectProxy.DiscoveryChain[id]
chainEndpoints, ok := cfgSnap.ConnectProxy.WatchedUpstreamEndpoints[id]
if !ok {
// this should not happen
return nil, fmt.Errorf("no endpoint map for upstream %q", id)
}
upstreamClusters, err := s.makeUpstreamClustersForDiscoveryChain(u, chain, chainEndpoints, cfgSnap)
if err != nil {
return nil, err
}
for _, cluster := range upstreamClusters {
clusters = append(clusters, cluster)
}
}
}
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 s.CheckFetcher.ServiceHTTPBasedChecks(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)
}
// 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 *Server) clustersFromSnapshotMeshGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
datacenters := cfgSnap.MeshGateway.Datacenters()
// 1 cluster per remote dc + 1 cluster per local service (this is a lower bound - all subset specific clusters will be appended)
clusters := make([]proto.Message, 0, len(datacenters)+len(cfgSnap.MeshGateway.ServiceGroups))
// generate the remote dc clusters
for _, dc := range datacenters {
if dc == cfgSnap.Datacenter {
continue // skip local
}
opts := gatewayClusterOpts{
name: connect.DatacenterSNI(dc, cfgSnap.Roots.TrustDomain),
hostnameEndpoints: cfgSnap.MeshGateway.HostnameDatacenters[dc],
isRemote: dc != cfgSnap.Datacenter,
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
clusters = append(clusters, cluster)
}
if cfgSnap.ServiceMeta[structs.MetaWANFederationKey] == "1" && cfgSnap.ServerSNIFn != nil {
// Add all of the remote wildcard datacenter mappings for servers.
for _, dc := range datacenters {
hostnameEndpoints := cfgSnap.MeshGateway.HostnameDatacenters[dc]
// 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 dc == cfgSnap.Datacenter {
hostnameEndpoints = nil
}
opts := gatewayClusterOpts{
name: cfgSnap.ServerSNIFn(dc, ""),
hostnameEndpoints: hostnameEndpoints,
isRemote: dc != cfgSnap.Datacenter,
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
clusters = append(clusters, cluster)
}
// And for the current datacenter, send all flavors appropriately.
for _, srv := range cfgSnap.MeshGateway.ConsulServers {
opts := gatewayClusterOpts{
name: cfgSnap.ServerSNIFn(cfgSnap.Datacenter, srv.Node.Node),
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
clusters = append(clusters, cluster)
}
}
// generate the per-service/subset clusters
c, err := s.makeGatewayServiceClusters(cfgSnap)
if err != nil {
return nil, err
}
clusters = append(clusters, c...)
return clusters, nil
}
func (s *Server) makeGatewayServiceClusters(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
var services map[structs.ServiceName]structs.CheckServiceNodes
var resolvers map[structs.ServiceName]*structs.ServiceResolverConfigEntry
var hostnameEndpoints structs.CheckServiceNodes
switch cfgSnap.Kind {
case structs.ServiceKindTerminatingGateway:
services = cfgSnap.TerminatingGateway.ServiceGroups
resolvers = cfgSnap.TerminatingGateway.ServiceResolvers
case structs.ServiceKindMeshGateway:
services = cfgSnap.MeshGateway.ServiceGroups
resolvers = cfgSnap.MeshGateway.ServiceResolvers
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(), cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain)
resolver, hasResolver := resolvers[svc]
var loadBalancer *structs.EnvoyLBConfig
if !hasResolver {
// Use a zero value resolver with no timeout and no subsets
resolver = &structs.ServiceResolverConfigEntry{}
}
if resolver.LoadBalancer != nil {
loadBalancer = resolver.LoadBalancer.EnvoyConfig
}
// 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]
}
opts := gatewayClusterOpts{
name: clusterName,
hostnameEndpoints: hostnameEndpoints,
connectTimeout: resolver.ConnectTimeout,
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
switch cfgSnap.Kind {
case structs.ServiceKindTerminatingGateway:
injectTerminatingGatewayTLSContext(cfgSnap, cluster, svc)
if err := injectLBToCluster(loadBalancer, cluster); err != nil {
return nil, fmt.Errorf("failed to apply load balancer configuration to cluster %q: %v", clusterName, err)
}
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 !loadBalancer.IsHashBased() {
if err := injectLBToCluster(loadBalancer, cluster); err != nil {
return nil, fmt.Errorf("failed to apply load balancer configuration to cluster %q: %v", clusterName, err)
}
}
}
clusters = append(clusters, cluster)
// 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 := gatewayClusterOpts{
name: connect.ServiceSNI(svc.Name, name, svc.NamespaceOrDefault(), cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain),
hostnameEndpoints: subsetHostnameEndpoints,
onlyPassing: subset.OnlyPassing,
connectTimeout: resolver.ConnectTimeout,
}
cluster := s.makeGatewayCluster(cfgSnap, opts)
switch cfgSnap.Kind {
case structs.ServiceKindTerminatingGateway:
injectTerminatingGatewayTLSContext(cfgSnap, cluster, svc)
if err := injectLBToCluster(loadBalancer, cluster); err != nil {
return nil, fmt.Errorf("failed to apply load balancer configuration to cluster %q: %v", clusterName, err)
}
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 !loadBalancer.IsHashBased() {
if err := injectLBToCluster(loadBalancer, cluster); err != nil {
return nil, fmt.Errorf("failed to apply load balancer configuration to cluster %q: %v", clusterName, err)
}
}
}
clusters = append(clusters, cluster)
}
}
return clusters, nil
}
func (s *Server) clustersFromSnapshotIngressGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
var clusters []proto.Message
createdClusters := make(map[string]bool)
for _, upstreams := range cfgSnap.IngressGateway.Upstreams {
for _, u := range upstreams {
id := u.Identifier()
// 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[id] {
continue
}
chain, ok := cfgSnap.IngressGateway.DiscoveryChain[id]
if !ok {
// this should not happen
return nil, fmt.Errorf("no discovery chain for upstream %q", id)
}
chainEndpoints, ok := cfgSnap.IngressGateway.WatchedUpstreamEndpoints[id]
if !ok {
// this should not happen
return nil, fmt.Errorf("no endpoint map for upstream %q", id)
}
upstreamClusters, err := s.makeUpstreamClustersForDiscoveryChain(u, chain, chainEndpoints, cfgSnap)
if err != nil {
return nil, err
}
for _, c := range upstreamClusters {
clusters = append(clusters, c)
}
createdClusters[id] = true
}
}
return clusters, nil
}
func (s *Server) makeAppCluster(cfgSnap *proxycfg.ConfigSnapshot, name, pathProtocol string, port int) (*envoy.Cluster, error) {
var c *envoy.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)
}
addr := cfgSnap.Proxy.LocalServiceAddress
if addr == "" {
addr = "127.0.0.1"
}
c = &envoy.Cluster{
Name: name,
ConnectTimeout: ptypes.DurationProto(time.Duration(cfg.LocalConnectTimeoutMs) * time.Millisecond),
ClusterDiscoveryType: &envoy.Cluster_Type{Type: envoy.Cluster_STATIC},
LoadAssignment: &envoy.ClusterLoadAssignment{
ClusterName: name,
Endpoints: []*envoyendpoint.LocalityLbEndpoints{
{
LbEndpoints: []*envoyendpoint.LbEndpoint{
makeEndpoint(addr, port),
},
},
},
},
}
protocol := pathProtocol
if protocol == "" {
protocol = cfg.Protocol
}
if protocol == "http2" || protocol == "grpc" {
c.Http2ProtocolOptions = &envoycore.Http2ProtocolOptions{}
}
return c, err
}
func (s *Server) makeUpstreamClusterForPreparedQuery(upstream structs.Upstream, cfgSnap *proxycfg.ConfigSnapshot) (*envoy.Cluster, error) {
var c *envoy.Cluster
var err error
dc := upstream.Datacenter
if dc == "" {
dc = cfgSnap.Datacenter
}
sni := connect.UpstreamSNI(&upstream, "", dc, cfgSnap.Roots.TrustDomain)
cfg, err := 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", upstream.Identifier(), "error", err)
}
if cfg.ClusterJSON != "" {
c, err = makeClusterFromUserConfig(cfg.ClusterJSON)
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{
Name: sni,
ConnectTimeout: ptypes.DurationProto(time.Duration(cfg.ConnectTimeoutMs) * time.Millisecond),
ClusterDiscoveryType: &envoy.Cluster_Type{Type: envoy.Cluster_EDS},
EdsClusterConfig: &envoy.Cluster_EdsClusterConfig{
EdsConfig: &envoycore.ConfigSource{
ConfigSourceSpecifier: &envoycore.ConfigSource_Ads{
Ads: &envoycore.AggregatedConfigSource{},
},
},
},
CircuitBreakers: &envoycluster.CircuitBreakers{
Thresholds: makeThresholdsIfNeeded(cfg.Limits),
},
OutlierDetection: cfg.PassiveHealthCheck.AsOutlierDetection(),
}
if cfg.Protocol == "http2" || cfg.Protocol == "grpc" {
c.Http2ProtocolOptions = &envoycore.Http2ProtocolOptions{}
}
}
// Enable TLS upstream with the configured client certificate.
c.TlsContext = &envoyauth.UpstreamTlsContext{
CommonTlsContext: makeCommonTLSContextFromLeaf(cfgSnap, cfgSnap.Leaf()),
Sni: sni,
}
return c, nil
}
func (s *Server) makeUpstreamClustersForDiscoveryChain(
upstream structs.Upstream,
chain *structs.CompiledDiscoveryChain,
chainEndpoints map[string]structs.CheckServiceNodes,
cfgSnap *proxycfg.ConfigSnapshot,
) ([]*envoy.Cluster, error) {
if chain == nil {
return nil, fmt.Errorf("cannot create upstream cluster without discovery chain for %s", upstream.Identifier())
}
cfg, err := ParseUpstreamConfigNoDefaults(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", upstream.Identifier(),
"error", err)
}
var escapeHatchCluster *envoy.Cluster
if cfg.ClusterJSON != "" {
if chain.IsDefault() {
// If you haven't done anything to setup the discovery chain, then
// you can use the envoy_cluster_json escape hatch.
escapeHatchCluster, err = makeClusterFromUserConfig(cfg.ClusterJSON)
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", upstream.Identifier(),
"envoy_cluster_json", chain.ServiceName)
}
}
var out []*envoy.Cluster
for _, node := range chain.Nodes {
if node.Type != structs.DiscoveryGraphNodeTypeResolver {
continue
}
failover := node.Resolver.Failover
targetID := node.Resolver.Target
target := chain.Targets[targetID]
// Determine if we have to generate the entire cluster differently.
failoverThroughMeshGateway := chain.WillFailoverThroughMeshGateway(node)
sni := target.SNI
clusterName := CustomizeClusterName(target.Name, chain)
if failoverThroughMeshGateway {
actualTargetID := firstHealthyTarget(
chain.Targets,
chainEndpoints,
targetID,
failover.Targets,
)
if actualTargetID != targetID {
actualTarget := chain.Targets[actualTargetID]
sni = actualTarget.SNI
}
}
s.Logger.Debug("generating cluster for", "cluster", clusterName)
c := &envoy.Cluster{
Name: clusterName,
AltStatName: clusterName,
ConnectTimeout: ptypes.DurationProto(node.Resolver.ConnectTimeout),
ClusterDiscoveryType: &envoy.Cluster_Type{Type: envoy.Cluster_EDS},
CommonLbConfig: &envoy.Cluster_CommonLbConfig{
HealthyPanicThreshold: &envoytype.Percent{
Value: 0, // disable panic threshold
},
},
EdsClusterConfig: &envoy.Cluster_EdsClusterConfig{
EdsConfig: &envoycore.ConfigSource{
ConfigSourceSpecifier: &envoycore.ConfigSource_Ads{
Ads: &envoycore.AggregatedConfigSource{},
},
},
},
CircuitBreakers: &envoycluster.CircuitBreakers{
Thresholds: makeThresholdsIfNeeded(cfg.Limits),
},
OutlierDetection: cfg.PassiveHealthCheck.AsOutlierDetection(),
}
var lb *structs.EnvoyLBConfig
if node.LoadBalancer != nil {
lb = node.LoadBalancer.EnvoyConfig
}
if err := injectLBToCluster(lb, c); err != nil {
return nil, fmt.Errorf("failed to apply load balancer configuration to cluster %q: %v", clusterName, err)
}
proto := cfg.Protocol
if proto == "" {
proto = chain.Protocol
}
if proto == "" {
proto = "tcp"
}
if proto == "http2" || proto == "grpc" {
c.Http2ProtocolOptions = &envoycore.Http2ProtocolOptions{}
}
// Enable TLS upstream with the configured client certificate.
c.TlsContext = &envoyauth.UpstreamTlsContext{
CommonTlsContext: makeCommonTLSContextFromLeaf(cfgSnap, cfgSnap.Leaf()),
Sni: sni,
}
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.TlsContext = defaultCluster.TlsContext
out = []*envoy.Cluster{escapeHatchCluster}
}
return out, 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, error) {
var jsonFields map[string]*json.RawMessage
if err := json.Unmarshal([]byte(configJSON), &jsonFields); err != nil {
fmt.Println("Custom error", err, configJSON)
return nil, err
}
var c envoy.Cluster
if _, ok := jsonFields["@type"]; ok {
// 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...
err = proto.Unmarshal(any.Value, &c)
if err != nil {
return nil, err
}
return &c, err
}
// No @type so try decoding as a straight listener.
err := jsonpb.UnmarshalString(configJSON, &c)
return &c, err
}
type gatewayClusterOpts 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
}
// makeGatewayCluster creates an Envoy cluster for a mesh or terminating gateway
func (s *Server) makeGatewayCluster(snap *proxycfg.ConfigSnapshot, opts gatewayClusterOpts) *envoy.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{
Name: opts.name,
ConnectTimeout: ptypes.DurationProto(opts.connectTimeout),
// Having an empty config enables outlier detection with default config.
OutlierDetection: &envoycluster.OutlierDetection{},
}
useEDS := true
if len(opts.hostnameEndpoints) > 0 {
useEDS = false
}
// 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_Type{Type: envoy.Cluster_EDS}
cluster.EdsClusterConfig = &envoy.Cluster_EdsClusterConfig{
EdsConfig: &envoycore.ConfigSource{
ConfigSourceSpecifier: &envoycore.ConfigSource_Ads{
Ads: &envoycore.AggregatedConfigSource{},
},
},
}
return cluster
}
// 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 = ptypes.DurationProto(rate)
cluster.DnsLookupFamily = envoy.Cluster_V4_ONLY
discoveryType := envoy.Cluster_Type{Type: envoy.Cluster_LOGICAL_DNS}
if cfg.DNSDiscoveryType == "strict_dns" {
discoveryType.Type = envoy.Cluster_STRICT_DNS
}
cluster.ClusterDiscoveryType = &discoveryType
endpoints := make([]*envoyendpoint.LbEndpoint, 0, 1)
uniqueHostnames := make(map[string]bool)
var (
hostname string
idx int
fallback *envoyendpoint.LbEndpoint
)
for i, e := range opts.hostnameEndpoints {
addr, port := e.BestAddress(opts.isRemote)
uniqueHostnames[addr] = true
health, weight := calculateEndpointHealthAndWeight(e, opts.onlyPassing)
if health == envoycore.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 := opts.hostnameEndpoints[idx].Node.Datacenter
service := opts.hostnameEndpoints[idx].Service.CompoundServiceName()
loggerName := logging.TerminatingGateway
if snap.Kind == structs.ServiceKindMeshGateway {
loggerName = logging.MeshGateway
}
// Fall back to last unhealthy endpoint if none were healthy
if len(endpoints) == 0 {
s.Logger.Named(loggerName).Warn("upstream service does not contain any healthy instances",
"dc", dc, "service", service.String())
endpoints = append(endpoints, fallback)
}
if len(uniqueHostnames) > 1 {
s.Logger.Named(loggerName).
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.ClusterLoadAssignment{
ClusterName: cluster.Name,
Endpoints: []*envoyendpoint.LocalityLbEndpoints{
{
LbEndpoints: endpoints,
},
},
}
return cluster
}
// injectTerminatingGatewayTLSContext adds an UpstreamTlsContext to a cluster for TLS origination
func injectTerminatingGatewayTLSContext(cfgSnap *proxycfg.ConfigSnapshot, cluster *envoy.Cluster, service structs.ServiceName) {
if mapping, ok := cfgSnap.TerminatingGateway.GatewayServices[service]; ok && mapping.CAFile != "" {
cluster.TlsContext = &envoyauth.UpstreamTlsContext{
CommonTlsContext: makeCommonTLSContextFromFiles(mapping.CAFile, mapping.CertFile, mapping.KeyFile),
// TODO (gateways) (freddy) If mapping.SNI is empty, does Envoy behave any differently if TlsContext.Sni is excluded?
Sni: mapping.SNI,
}
}
}
func makeThresholdsIfNeeded(limits UpstreamLimits) []*envoycluster.CircuitBreakers_Thresholds {
var empty UpstreamLimits
// Make sure to not create any thresholds when passed the zero-value in order
// to rely on Envoy defaults
if limits == empty {
return nil
}
threshold := &envoycluster.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 []*envoycluster.CircuitBreakers_Thresholds{threshold}
}
func makeLbEndpoint(addr string, port int, health envoycore.HealthStatus, weight int) *envoyendpoint.LbEndpoint {
return &envoyendpoint.LbEndpoint{
HostIdentifier: &envoyendpoint.LbEndpoint_Endpoint{
Endpoint: &envoyendpoint.Endpoint{
Address: &envoycore.Address{
Address: &envoycore.Address_SocketAddress{
SocketAddress: &envoycore.SocketAddress{
Address: addr,
PortSpecifier: &envoycore.SocketAddress_PortValue{
PortValue: uint32(port),
},
},
},
},
},
},
HealthStatus: health,
LoadBalancingWeight: makeUint32Value(weight),
}
}
func injectLBToCluster(ec *structs.EnvoyLBConfig, c *envoy.Cluster) error {
if ec == nil {
return nil
}
switch ec.Policy {
case "":
return nil
case structs.LBPolicyLeastRequest:
c.LbPolicy = envoy.Cluster_LEAST_REQUEST
if ec.LeastRequestConfig != nil {
c.LbConfig = &envoy.Cluster_LeastRequestLbConfig_{
LeastRequestLbConfig: &envoy.Cluster_LeastRequestLbConfig{
ChoiceCount: &wrappers.UInt32Value{Value: ec.LeastRequestConfig.ChoiceCount},
},
}
}
case structs.LBPolicyRoundRobin:
c.LbPolicy = envoy.Cluster_ROUND_ROBIN
case structs.LBPolicyRandom:
c.LbPolicy = envoy.Cluster_RANDOM
case structs.LBPolicyRingHash:
c.LbPolicy = envoy.Cluster_RING_HASH
if ec.RingHashConfig != nil {
c.LbConfig = &envoy.Cluster_RingHashLbConfig_{
RingHashLbConfig: &envoy.Cluster_RingHashLbConfig{
MinimumRingSize: &wrappers.UInt64Value{Value: ec.RingHashConfig.MinimumRingSize},
MaximumRingSize: &wrappers.UInt64Value{Value: ec.RingHashConfig.MaximumRingSize},
},
}
}
case structs.LBPolicyMaglev:
c.LbPolicy = envoy.Cluster_MAGLEV
default:
return fmt.Errorf("unsupported load balancer policy %q for cluster %q", ec.Policy, c.Name)
}
return nil
}