open-consul/agent/xds/endpoints.go

631 lines
20 KiB
Go

package xds
import (
"errors"
"fmt"
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"
"github.com/golang/protobuf/proto"
bexpr "github.com/hashicorp/go-bexpr"
"github.com/hashicorp/consul/agent/connect"
"github.com/hashicorp/consul/agent/proxycfg"
"github.com/hashicorp/consul/agent/structs"
"github.com/hashicorp/consul/api"
)
const (
UnnamedSubset = ""
)
// endpointsFromSnapshot returns the xDS API representation of the "endpoints"
func (s *ResourceGenerator) endpointsFromSnapshot(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
if cfgSnap == nil {
return nil, errors.New("nil config given")
}
switch cfgSnap.Kind {
case structs.ServiceKindConnectProxy:
return s.endpointsFromSnapshotConnectProxy(cfgSnap)
case structs.ServiceKindTerminatingGateway:
return s.endpointsFromSnapshotTerminatingGateway(cfgSnap)
case structs.ServiceKindMeshGateway:
return s.endpointsFromSnapshotMeshGateway(cfgSnap)
case structs.ServiceKindIngressGateway:
return s.endpointsFromSnapshotIngressGateway(cfgSnap)
default:
return nil, fmt.Errorf("Invalid service kind: %v", cfgSnap.Kind)
}
}
// endpointsFromSnapshotConnectProxy returns the xDS API representation of the "endpoints"
// (upstream instances) in the snapshot.
func (s *ResourceGenerator) endpointsFromSnapshotConnectProxy(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
resources := make([]proto.Message, 0,
len(cfgSnap.ConnectProxy.PreparedQueryEndpoints)+len(cfgSnap.ConnectProxy.WatchedUpstreamEndpoints))
for uid, chain := range cfgSnap.ConnectProxy.DiscoveryChain {
upstreamCfg := cfgSnap.ConnectProxy.UpstreamConfig[uid]
explicit := upstreamCfg.HasLocalPortOrSocket()
if _, implicit := cfgSnap.ConnectProxy.IntentionUpstreams[uid]; !implicit && !explicit {
// Discovery chain is not associated with a known explicit or implicit upstream so it is skipped.
continue
}
es := s.endpointsFromDiscoveryChain(
uid,
chain,
cfgSnap.Locality,
upstreamCfg,
cfgSnap.ConnectProxy.WatchedUpstreamEndpoints[uid],
cfgSnap.ConnectProxy.WatchedGatewayEndpoints[uid],
)
resources = append(resources, es...)
}
// Looping over explicit upstreams is only needed for prepared queries because they do not have discovery chains
for _, u := range cfgSnap.Proxy.Upstreams {
if u.DestinationType != structs.UpstreamDestTypePreparedQuery {
continue
}
uid := proxycfg.NewUpstreamID(&u)
dc := u.Datacenter
if dc == "" {
dc = cfgSnap.Datacenter
}
clusterName := connect.UpstreamSNI(&u, "", dc, cfgSnap.Roots.TrustDomain)
endpoints, ok := cfgSnap.ConnectProxy.PreparedQueryEndpoints[uid]
if ok {
la := makeLoadAssignment(
clusterName,
[]loadAssignmentEndpointGroup{
{Endpoints: endpoints},
},
cfgSnap.Locality,
)
resources = append(resources, la)
}
}
return resources, nil
}
func (s *ResourceGenerator) filterSubsetEndpoints(subset *structs.ServiceResolverSubset, endpoints structs.CheckServiceNodes) (structs.CheckServiceNodes, error) {
// locally execute the subsets filter
if subset.Filter != "" {
filter, err := bexpr.CreateFilter(subset.Filter, nil, endpoints)
if err != nil {
return nil, err
}
raw, err := filter.Execute(endpoints)
if err != nil {
return nil, err
}
return raw.(structs.CheckServiceNodes), nil
}
return endpoints, nil
}
func (s *ResourceGenerator) endpointsFromSnapshotTerminatingGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
return s.endpointsFromServicesAndResolvers(cfgSnap, cfgSnap.TerminatingGateway.ServiceGroups, cfgSnap.TerminatingGateway.ServiceResolvers)
}
func (s *ResourceGenerator) endpointsFromSnapshotMeshGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
keys := cfgSnap.MeshGateway.GatewayKeys()
resources := make([]proto.Message, 0, len(keys)+len(cfgSnap.MeshGateway.ServiceGroups))
for _, key := range keys {
if key.Matches(cfgSnap.Datacenter, cfgSnap.ProxyID.PartitionOrDefault()) {
continue // skip local
}
// Also skip gateways with a hostname as their address. EDS cannot resolve hostnames,
// so we provide them through CDS instead.
if len(cfgSnap.MeshGateway.HostnameDatacenters[key.String()]) > 0 {
continue
}
// Mesh gateways in remote DCs are discovered in two ways:
//
// 1. Via an Internal.ServiceDump RPC in the remote DC (GatewayGroups).
// 2. In the federation state that is replicated from the primary DC (FedStateGateways).
//
// We determine which set to use based on whichever contains the highest
// raft ModifyIndex (and is therefore most up-to-date).
//
// Previously, GatewayGroups was always given presedence over FedStateGateways
// but this was problematic when using mesh gateways for WAN federation.
//
// Consider the following example:
//
// - Primary and Secondary DCs are WAN Federated via local mesh gateways.
//
// - Secondary DC's mesh gateway is running on an ephemeral compute instance
// and is abruptly terminated and rescheduled with a *new IP address*.
//
// - Primary DC's mesh gateway is no longer able to connect to the Secondary
// DC as its proxy is configured with the old IP address. Therefore any RPC
// from the Primary to the Secondary DC will fail (including the one to
// discover the gateway's new IP address).
//
// - Secondary DC performs its regular anti-entropy of federation state data
// to the Primary DC (this succeeds as there is still connectivity in this
// direction).
//
// - At this point the Primary DC's mesh gateway should observe the new IP
// address and reconfigure its proxy, however as we always prioritised
// GatewayGroups this didn't happen and the connection remained severed.
maxModifyIndex := func(vals structs.CheckServiceNodes) uint64 {
var max uint64
for _, v := range vals {
if i := v.Service.RaftIndex.ModifyIndex; i > max {
max = i
}
}
return max
}
endpoints := cfgSnap.MeshGateway.GatewayGroups[key.String()]
fedStateEndpoints := cfgSnap.MeshGateway.FedStateGateways[key.String()]
if maxModifyIndex(fedStateEndpoints) > maxModifyIndex(endpoints) {
endpoints = fedStateEndpoints
}
if len(endpoints) == 0 {
s.Logger.Error("skipping mesh gateway endpoints because no definition found", "datacenter", key)
continue
}
{ // standard connect
clusterName := connect.GatewaySNI(key.Datacenter, key.Partition, cfgSnap.Roots.TrustDomain)
la := makeLoadAssignment(
clusterName,
[]loadAssignmentEndpointGroup{
{Endpoints: endpoints},
},
cfgSnap.Locality,
)
resources = append(resources, la)
}
if cfgSnap.ProxyID.InDefaultPartition() &&
cfgSnap.ServiceMeta[structs.MetaWANFederationKey] == "1" &&
cfgSnap.ServerSNIFn != nil {
clusterName := cfgSnap.ServerSNIFn(key.Datacenter, "")
la := makeLoadAssignment(
clusterName,
[]loadAssignmentEndpointGroup{
{Endpoints: endpoints},
},
cfgSnap.Locality,
)
resources = append(resources, la)
}
}
// generate endpoints for our servers if WAN federation is enabled
if cfgSnap.ProxyID.InDefaultPartition() &&
cfgSnap.ServiceMeta[structs.MetaWANFederationKey] == "1" &&
cfgSnap.ServerSNIFn != nil {
var allServersLbEndpoints []*envoy_endpoint_v3.LbEndpoint
for _, srv := range cfgSnap.MeshGateway.ConsulServers {
clusterName := cfgSnap.ServerSNIFn(cfgSnap.Datacenter, srv.Node.Node)
addr, port := srv.BestAddress(false /*wan*/)
lbEndpoint := &envoy_endpoint_v3.LbEndpoint{
HostIdentifier: &envoy_endpoint_v3.LbEndpoint_Endpoint{
Endpoint: &envoy_endpoint_v3.Endpoint{
Address: makeAddress(addr, port),
},
},
HealthStatus: envoy_core_v3.HealthStatus_UNKNOWN,
}
cla := &envoy_endpoint_v3.ClusterLoadAssignment{
ClusterName: clusterName,
Endpoints: []*envoy_endpoint_v3.LocalityLbEndpoints{{
LbEndpoints: []*envoy_endpoint_v3.LbEndpoint{lbEndpoint},
}},
}
allServersLbEndpoints = append(allServersLbEndpoints, lbEndpoint)
resources = append(resources, cla)
}
// And add one catch all so that remote datacenters can dial ANY server
// in this datacenter without knowing its name.
resources = append(resources, &envoy_endpoint_v3.ClusterLoadAssignment{
ClusterName: cfgSnap.ServerSNIFn(cfgSnap.Datacenter, ""),
Endpoints: []*envoy_endpoint_v3.LocalityLbEndpoints{{
LbEndpoints: allServersLbEndpoints,
}},
})
}
// Generate the endpoints for each service and its subsets
e, err := s.endpointsFromServicesAndResolvers(cfgSnap, cfgSnap.MeshGateway.ServiceGroups, cfgSnap.MeshGateway.ServiceResolvers)
if err != nil {
return nil, err
}
resources = append(resources, e...)
return resources, nil
}
func (s *ResourceGenerator) endpointsFromServicesAndResolvers(
cfgSnap *proxycfg.ConfigSnapshot,
services map[structs.ServiceName]structs.CheckServiceNodes,
resolvers map[structs.ServiceName]*structs.ServiceResolverConfigEntry,
) ([]proto.Message, error) {
resources := make([]proto.Message, 0, len(services))
// generate the endpoints for the linked service groups
for svc, endpoints := range services {
// Skip creating endpoints for services that have hostnames as addresses
// EDS cannot resolve hostnames so we provide them through CDS instead
if cfgSnap.Kind == structs.ServiceKindTerminatingGateway && len(cfgSnap.TerminatingGateway.HostnameServices[svc]) > 0 {
continue
}
clusterEndpoints := make(map[string][]loadAssignmentEndpointGroup)
clusterEndpoints[UnnamedSubset] = []loadAssignmentEndpointGroup{{Endpoints: endpoints, OnlyPassing: false}}
// Collect all of the loadAssignmentEndpointGroups for the various subsets. We do this before generating
// the endpoints for the default/unnamed subset so that we can take into account the DefaultSubset on the
// service-resolver which may prevent the default/unnamed cluster from creating endpoints for all service
// instances.
if resolver, hasResolver := resolvers[svc]; hasResolver {
for subsetName, subset := range resolver.Subsets {
subsetEndpoints, err := s.filterSubsetEndpoints(&subset, endpoints)
if err != nil {
return nil, err
}
groups := []loadAssignmentEndpointGroup{{Endpoints: subsetEndpoints, OnlyPassing: subset.OnlyPassing}}
clusterEndpoints[subsetName] = groups
// if this subset is the default then override the unnamed subset with this configuration
if subsetName == resolver.DefaultSubset {
clusterEndpoints[UnnamedSubset] = groups
}
}
}
// now generate the load assignment for all subsets
for subsetName, groups := range clusterEndpoints {
clusterName := connect.ServiceSNI(svc.Name, subsetName, svc.NamespaceOrDefault(), svc.PartitionOrDefault(), cfgSnap.Datacenter, cfgSnap.Roots.TrustDomain)
la := makeLoadAssignment(
clusterName,
groups,
cfgSnap.Locality,
)
resources = append(resources, la)
}
}
return resources, nil
}
func (s *ResourceGenerator) endpointsFromSnapshotIngressGateway(cfgSnap *proxycfg.ConfigSnapshot) ([]proto.Message, error) {
var resources []proto.Message
createdClusters := make(map[proxycfg.UpstreamID]bool)
for _, upstreams := range cfgSnap.IngressGateway.Upstreams {
for _, u := range upstreams {
uid := proxycfg.NewUpstreamID(&u)
// If we've already created endpoints for this upstream, skip it. Multiple listeners may
// reference the same upstream, so we don't need to create duplicate endpoints in that case.
if createdClusters[uid] {
continue
}
es := s.endpointsFromDiscoveryChain(
uid,
cfgSnap.IngressGateway.DiscoveryChain[uid],
proxycfg.GatewayKey{Datacenter: cfgSnap.Datacenter, Partition: u.DestinationPartition},
&u,
cfgSnap.IngressGateway.WatchedUpstreamEndpoints[uid],
cfgSnap.IngressGateway.WatchedGatewayEndpoints[uid],
)
resources = append(resources, es...)
createdClusters[uid] = true
}
}
return resources, nil
}
// used in clusters.go
func makeEndpoint(host string, port int) *envoy_endpoint_v3.LbEndpoint {
return &envoy_endpoint_v3.LbEndpoint{
HostIdentifier: &envoy_endpoint_v3.LbEndpoint_Endpoint{
Endpoint: &envoy_endpoint_v3.Endpoint{
Address: makeAddress(host, port),
},
},
}
}
func makePipeEndpoint(path string) *envoy_endpoint_v3.LbEndpoint {
return &envoy_endpoint_v3.LbEndpoint{
HostIdentifier: &envoy_endpoint_v3.LbEndpoint_Endpoint{
Endpoint: &envoy_endpoint_v3.Endpoint{
Address: makePipeAddress(path, 0),
},
},
}
}
func (s *ResourceGenerator) endpointsFromDiscoveryChain(
uid proxycfg.UpstreamID,
chain *structs.CompiledDiscoveryChain,
gatewayKey proxycfg.GatewayKey,
upstream *structs.Upstream,
upstreamEndpoints map[string]structs.CheckServiceNodes,
gatewayEndpoints map[string]structs.CheckServiceNodes,
) []proto.Message {
var resources []proto.Message
if chain == nil {
return resources
}
configMap := make(map[string]interface{})
if upstream != nil {
configMap = upstream.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)
}
var escapeHatchCluster *envoy_cluster_v3.Cluster
if cfg.EnvoyClusterJSON != "" {
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.EnvoyClusterJSON)
if err != nil {
return resources
}
} else {
s.Logger.Warn("ignoring escape hatch setting, because a discovery chain is configued for",
"discovery chain", chain.ServiceName, "upstream", uid,
"envoy_cluster_json", chain.ServiceName)
}
}
// Find all resolver nodes.
for _, node := range chain.Nodes {
if node.Type != structs.DiscoveryGraphNodeTypeResolver {
continue
}
failover := node.Resolver.Failover
targetID := node.Resolver.Target
target := chain.Targets[targetID]
clusterName := CustomizeClusterName(target.Name, chain)
if escapeHatchCluster != nil {
clusterName = escapeHatchCluster.Name
}
s.Logger.Debug("generating endpoints for", "cluster", clusterName)
// Determine if we have to generate the entire cluster differently.
failoverThroughMeshGateway := chain.WillFailoverThroughMeshGateway(node)
if failoverThroughMeshGateway {
actualTargetID := firstHealthyTarget(
chain.Targets,
upstreamEndpoints,
targetID,
failover.Targets,
)
if actualTargetID != targetID {
targetID = actualTargetID
}
failover = nil
}
primaryGroup, valid := makeLoadAssignmentEndpointGroup(
chain.Targets,
upstreamEndpoints,
gatewayEndpoints,
targetID,
gatewayKey,
)
if !valid {
continue // skip the cluster if we're still populating the snapshot
}
var endpointGroups []loadAssignmentEndpointGroup
if failover != nil && len(failover.Targets) > 0 {
endpointGroups = make([]loadAssignmentEndpointGroup, 0, len(failover.Targets)+1)
endpointGroups = append(endpointGroups, primaryGroup)
for _, failTargetID := range failover.Targets {
failoverGroup, valid := makeLoadAssignmentEndpointGroup(
chain.Targets,
upstreamEndpoints,
gatewayEndpoints,
failTargetID,
gatewayKey,
)
if !valid {
continue // skip the failover target if we're still populating the snapshot
}
endpointGroups = append(endpointGroups, failoverGroup)
}
} else {
endpointGroups = append(endpointGroups, primaryGroup)
}
la := makeLoadAssignment(
clusterName,
endpointGroups,
gatewayKey,
)
resources = append(resources, la)
}
return resources
}
type loadAssignmentEndpointGroup struct {
Endpoints structs.CheckServiceNodes
OnlyPassing bool
OverrideHealth envoy_core_v3.HealthStatus
}
func makeLoadAssignment(clusterName string, endpointGroups []loadAssignmentEndpointGroup, localKey proxycfg.GatewayKey) *envoy_endpoint_v3.ClusterLoadAssignment {
cla := &envoy_endpoint_v3.ClusterLoadAssignment{
ClusterName: clusterName,
Endpoints: make([]*envoy_endpoint_v3.LocalityLbEndpoints, 0, len(endpointGroups)),
}
if len(endpointGroups) > 1 {
cla.Policy = &envoy_endpoint_v3.ClusterLoadAssignment_Policy{
// We choose such a large value here that the failover math should
// in effect not happen until zero instances are healthy.
OverprovisioningFactor: makeUint32Value(100000),
}
}
for priority, endpointGroup := range endpointGroups {
endpoints := endpointGroup.Endpoints
es := make([]*envoy_endpoint_v3.LbEndpoint, 0, len(endpoints))
for _, ep := range endpoints {
// TODO (mesh-gateway) - should we respect the translate_wan_addrs configuration here or just always use the wan for cross-dc?
addr, port := ep.BestAddress(!localKey.Matches(ep.Node.Datacenter, ep.Node.PartitionOrDefault()))
healthStatus, weight := calculateEndpointHealthAndWeight(ep, endpointGroup.OnlyPassing)
if endpointGroup.OverrideHealth != envoy_core_v3.HealthStatus_UNKNOWN {
healthStatus = endpointGroup.OverrideHealth
}
es = append(es, &envoy_endpoint_v3.LbEndpoint{
HostIdentifier: &envoy_endpoint_v3.LbEndpoint_Endpoint{
Endpoint: &envoy_endpoint_v3.Endpoint{
Address: makeAddress(addr, port),
},
},
HealthStatus: healthStatus,
LoadBalancingWeight: makeUint32Value(weight),
})
}
cla.Endpoints = append(cla.Endpoints, &envoy_endpoint_v3.LocalityLbEndpoints{
Priority: uint32(priority),
LbEndpoints: es,
})
}
return cla
}
func makeLoadAssignmentEndpointGroup(
targets map[string]*structs.DiscoveryTarget,
targetHealth map[string]structs.CheckServiceNodes,
gatewayHealth map[string]structs.CheckServiceNodes,
targetID string,
localKey proxycfg.GatewayKey,
) (loadAssignmentEndpointGroup, bool) {
realEndpoints, ok := targetHealth[targetID]
if !ok {
// skip the cluster if we're still populating the snapshot
return loadAssignmentEndpointGroup{}, false
}
target := targets[targetID]
var gatewayKey proxycfg.GatewayKey
switch target.MeshGateway.Mode {
case structs.MeshGatewayModeRemote:
gatewayKey.Datacenter = target.Datacenter
gatewayKey.Partition = target.Partition
case structs.MeshGatewayModeLocal:
gatewayKey = localKey
}
if gatewayKey.IsEmpty() || (structs.EqualPartitions(localKey.Partition, target.Partition) && localKey.Datacenter == target.Datacenter) {
// Gateways are not needed if the request isn't for a remote DC or partition.
return loadAssignmentEndpointGroup{
Endpoints: realEndpoints,
OnlyPassing: target.Subset.OnlyPassing,
}, true
}
// If using a mesh gateway we need to pull those endpoints instead.
gatewayEndpoints, ok := gatewayHealth[gatewayKey.String()]
if !ok {
// skip the cluster if we're still populating the snapshot
return loadAssignmentEndpointGroup{}, false
}
// But we will use the health from the actual backend service.
overallHealth := envoy_core_v3.HealthStatus_UNHEALTHY
for _, ep := range realEndpoints {
health, _ := calculateEndpointHealthAndWeight(ep, target.Subset.OnlyPassing)
if health == envoy_core_v3.HealthStatus_HEALTHY {
overallHealth = envoy_core_v3.HealthStatus_HEALTHY
break
}
}
return loadAssignmentEndpointGroup{
Endpoints: gatewayEndpoints,
OverrideHealth: overallHealth,
}, true
}
func calculateEndpointHealthAndWeight(
ep structs.CheckServiceNode,
onlyPassing bool,
) (envoy_core_v3.HealthStatus, int) {
healthStatus := envoy_core_v3.HealthStatus_HEALTHY
weight := 1
if ep.Service.Weights != nil {
weight = ep.Service.Weights.Passing
}
for _, chk := range ep.Checks {
if chk.Status == api.HealthCritical {
healthStatus = envoy_core_v3.HealthStatus_UNHEALTHY
}
if onlyPassing && chk.Status != api.HealthPassing {
healthStatus = envoy_core_v3.HealthStatus_UNHEALTHY
}
if chk.Status == api.HealthWarning && ep.Service.Weights != nil {
weight = ep.Service.Weights.Warning
}
}
// Make weights fit Envoy's limits. A zero weight means that either Warning
// (likely) or Passing (weirdly) weight has been set to 0 effectively making
// this instance unhealthy and should not be sent traffic.
if weight < 1 {
healthStatus = envoy_core_v3.HealthStatus_UNHEALTHY
weight = 1
}
if weight > 128 {
weight = 128
}
return healthStatus, weight
}