// Copyright (c) HashiCorp, Inc. // SPDX-License-Identifier: BUSL-1.1 package discovery import ( "context" "errors" "fmt" "net" "strings" "sync/atomic" "time" "github.com/armon/go-metrics" "github.com/armon/go-metrics/prometheus" "github.com/hashicorp/go-hclog" "github.com/hashicorp/consul/acl" "github.com/hashicorp/consul/agent/cache" cachetype "github.com/hashicorp/consul/agent/cache-types" "github.com/hashicorp/consul/agent/config" "github.com/hashicorp/consul/agent/structs" "github.com/hashicorp/consul/api" ) const ( // Increment a counter when requests staler than this are served staleCounterThreshold = 5 * time.Second ) // DNSCounters pre-registers the staleness metric. // This value is used by both the V1 and V2 DNS (V1 Catalog-only) servers. var DNSCounters = []prometheus.CounterDefinition{ { Name: []string{"dns", "stale_queries"}, Help: "Increments when an agent serves a query within the allowed stale threshold.", }, } // v1DataFetcherDynamicConfig is used to store the dynamic configuration of the V1 data fetcher. type v1DataFetcherDynamicConfig struct { // Default request tenancy datacenter string segmentName string nodeName string nodePartition string // Catalog configuration allowStale bool maxStale time.Duration useCache bool cacheMaxAge time.Duration onlyPassing bool } // V1DataFetcher is used to fetch data from the V1 catalog. type V1DataFetcher struct { defaultEnterpriseMeta acl.EnterpriseMeta dynamicConfig atomic.Value logger hclog.Logger getFromCacheFunc func(ctx context.Context, t string, r cache.Request) (interface{}, cache.ResultMeta, error) rpcFunc func(ctx context.Context, method string, args interface{}, reply interface{}) error rpcFuncForServiceNodes func(ctx context.Context, req structs.ServiceSpecificRequest) (structs.IndexedCheckServiceNodes, cache.ResultMeta, error) rpcFuncForSamenessGroup func(ctx context.Context, req *structs.ConfigEntryQuery) (structs.SamenessGroupConfigEntry, cache.ResultMeta, error) translateServicePortFunc func(dc string, port int, taggedAddresses map[string]structs.ServiceAddress) int } // NewV1DataFetcher creates a new V1 data fetcher. func NewV1DataFetcher(config *config.RuntimeConfig, entMeta *acl.EnterpriseMeta, getFromCacheFunc func(ctx context.Context, t string, r cache.Request) (interface{}, cache.ResultMeta, error), rpcFunc func(ctx context.Context, method string, args interface{}, reply interface{}) error, rpcFuncForServiceNodes func(ctx context.Context, req structs.ServiceSpecificRequest) (structs.IndexedCheckServiceNodes, cache.ResultMeta, error), rpcFuncForSamenessGroup func(ctx context.Context, req *structs.ConfigEntryQuery) (structs.SamenessGroupConfigEntry, cache.ResultMeta, error), translateServicePortFunc func(dc string, port int, taggedAddresses map[string]structs.ServiceAddress) int, logger hclog.Logger) *V1DataFetcher { f := &V1DataFetcher{ defaultEnterpriseMeta: *entMeta, getFromCacheFunc: getFromCacheFunc, rpcFunc: rpcFunc, rpcFuncForServiceNodes: rpcFuncForServiceNodes, rpcFuncForSamenessGroup: rpcFuncForSamenessGroup, translateServicePortFunc: translateServicePortFunc, logger: logger, } f.LoadConfig(config) return f } // LoadConfig loads the configuration for the V1 data fetcher. func (f *V1DataFetcher) LoadConfig(config *config.RuntimeConfig) { dynamicConfig := &v1DataFetcherDynamicConfig{ allowStale: config.DNSAllowStale, maxStale: config.DNSMaxStale, useCache: config.DNSUseCache, cacheMaxAge: config.DNSCacheMaxAge, onlyPassing: config.DNSOnlyPassing, datacenter: config.Datacenter, segmentName: config.SegmentName, nodeName: config.NodeName, } f.dynamicConfig.Store(dynamicConfig) } // FetchNodes fetches A/AAAA/CNAME func (f *V1DataFetcher) FetchNodes(ctx Context, req *QueryPayload) ([]*Result, error) { if req.Tenancy.Namespace != "" && req.Tenancy.Namespace != acl.DefaultNamespaceName { // Nodes are not namespaced, so this is a name error return nil, ErrNotFound } cfg := f.dynamicConfig.Load().(*v1DataFetcherDynamicConfig) // Make an RPC request args := &structs.NodeSpecificRequest{ Datacenter: req.Tenancy.Datacenter, PeerName: req.Tenancy.Peer, Node: req.Name, QueryOptions: structs.QueryOptions{ Token: ctx.Token, AllowStale: cfg.allowStale, }, EnterpriseMeta: queryTenancyToEntMeta(req.Tenancy), } out, err := f.fetchNode(cfg, args) if err != nil { return nil, fmt.Errorf("failed rpc request: %w", err) } // If we have no out.NodeServices.Nodeaddress, return not found! if out.NodeServices == nil { return nil, ErrNotFound } results := make([]*Result, 0, 1) n := out.NodeServices.Node results = append(results, &Result{ Node: &Location{ Name: n.Node, Address: n.Address, TaggedAddresses: makeTaggedAddressesFromStrings(n.TaggedAddresses), }, Type: ResultTypeNode, Metadata: n.Meta, Tenancy: ResultTenancy{ // Namespace is not required because nodes are not namespaced Partition: n.GetEnterpriseMeta().PartitionOrDefault(), Datacenter: n.Datacenter, }, }) return results, nil } // FetchEndpoints fetches records for A/AAAA/CNAME or SRV requests for services func (f *V1DataFetcher) FetchEndpoints(ctx Context, req *QueryPayload, lookupType LookupType) ([]*Result, error) { f.logger.Trace(fmt.Sprintf("FetchEndpoints - req: %+v / lookupType: %+v", req, lookupType)) cfg := f.dynamicConfig.Load().(*v1DataFetcherDynamicConfig) return f.fetchService(ctx, req, cfg, lookupType) } // FetchVirtualIP fetches A/AAAA records for virtual IPs func (f *V1DataFetcher) FetchVirtualIP(ctx Context, req *QueryPayload) (*Result, error) { args := structs.ServiceSpecificRequest{ // The datacenter of the request is not specified because cross-datacenter virtual IP // queries are not supported. This guard rail is in place because virtual IPs are allocated // within a DC, therefore their uniqueness is not guaranteed globally. PeerName: req.Tenancy.Peer, ServiceName: req.Name, EnterpriseMeta: queryTenancyToEntMeta(req.Tenancy), QueryOptions: structs.QueryOptions{ Token: ctx.Token, }, } var out string if err := f.rpcFunc(context.Background(), "Catalog.VirtualIPForService", &args, &out); err != nil { return nil, err } result := &Result{ Service: &Location{ Name: req.Name, Address: out, }, Type: ResultTypeVirtual, } return result, nil } // FetchRecordsByIp is used for PTR requests to look up a service/node from an IP. // The search is performed in the agent's partition and over all namespaces (or those allowed by the ACL token). func (f *V1DataFetcher) FetchRecordsByIp(reqCtx Context, ip net.IP) ([]*Result, error) { if ip == nil { return nil, ErrNotSupported } configCtx := f.dynamicConfig.Load().(*v1DataFetcherDynamicConfig) targetIP := ip.String() var results []*Result args := structs.DCSpecificRequest{ Datacenter: configCtx.datacenter, QueryOptions: structs.QueryOptions{ Token: reqCtx.Token, AllowStale: configCtx.allowStale, }, } var out structs.IndexedNodes // TODO: Replace ListNodes with an internal RPC that can do the filter // server side to avoid transferring the entire node list. if err := f.rpcFunc(context.Background(), "Catalog.ListNodes", &args, &out); err == nil { for _, n := range out.Nodes { if targetIP == n.Address { results = append(results, &Result{ Node: &Location{ Name: n.Node, Address: n.Address, TaggedAddresses: makeTaggedAddressesFromStrings(n.TaggedAddresses), }, Type: ResultTypeNode, Tenancy: ResultTenancy{ Namespace: f.defaultEnterpriseMeta.NamespaceOrDefault(), Partition: f.defaultEnterpriseMeta.PartitionOrDefault(), Datacenter: configCtx.datacenter, }, }) return results, nil } } } // only look into the services if we didn't find a node sargs := structs.ServiceSpecificRequest{ Datacenter: configCtx.datacenter, QueryOptions: structs.QueryOptions{ Token: reqCtx.Token, AllowStale: configCtx.allowStale, }, ServiceAddress: targetIP, EnterpriseMeta: *f.defaultEnterpriseMeta.WithWildcardNamespace(), } var sout structs.IndexedServiceNodes if err := f.rpcFunc(context.Background(), "Catalog.ServiceNodes", &sargs, &sout); err == nil { for _, n := range sout.ServiceNodes { if n.ServiceAddress == targetIP { results = append(results, &Result{ Service: &Location{ Name: n.ServiceName, Address: n.ServiceAddress, }, Type: ResultTypeService, Node: &Location{ Name: n.Node, Address: n.Address, }, Tenancy: ResultTenancy{ Namespace: n.NamespaceOrEmpty(), Partition: n.PartitionOrEmpty(), Datacenter: n.Datacenter, }, }) return results, nil } } } // nothing found locally, recurse // TODO: (v2-dns) implement recursion (NET-7883) //d.handleRecurse(resp, req) return nil, fmt.Errorf("unhandled error in FetchRecordsByIp") } // FetchWorkload fetches a single Result associated with // V2 Workload. V2-only. func (f *V1DataFetcher) FetchWorkload(ctx Context, req *QueryPayload) (*Result, error) { return nil, ErrNotSupported } // FetchPreparedQuery evaluates the results of a prepared query. // deprecated in V2 func (f *V1DataFetcher) FetchPreparedQuery(ctx Context, req *QueryPayload) ([]*Result, error) { cfg := f.dynamicConfig.Load().(*v1DataFetcherDynamicConfig) // Execute the prepared query. args := structs.PreparedQueryExecuteRequest{ Datacenter: req.Tenancy.Datacenter, QueryIDOrName: req.Name, QueryOptions: structs.QueryOptions{ Token: ctx.Token, AllowStale: cfg.allowStale, MaxAge: cfg.cacheMaxAge, }, // Always pass the local agent through. In the DNS interface, there // is no provision for passing additional query parameters, so we // send the local agent's data through to allow distance sorting // relative to ourself on the server side. Agent: structs.QuerySource{ Datacenter: cfg.datacenter, Segment: cfg.segmentName, Node: cfg.nodeName, NodePartition: cfg.nodePartition, }, Source: structs.QuerySource{ Ip: req.SourceIP.String(), }, } out, err := f.executePreparedQuery(cfg, args) if err != nil { // errors.Is() doesn't work with errors.New() so we need to check the error message. if err.Error() == structs.ErrQueryNotFound.Error() { err = ErrNotFound } return nil, ECSNotGlobalError{err} } // TODO (slackpad) - What's a safe limit we can set here? It seems like // with dup filtering done at this level we need to get everything to // match the previous behavior. We can optimize by pushing more filtering // into the query execution, but for now I think we need to get the full // response. We could also choose a large arbitrary number that will // likely work in practice, like 10*maxUDPAnswerLimit which should help // reduce bandwidth if there are thousands of nodes available. // Determine the TTL. The parse should never fail since we vet it when // the query is created, but we check anyway. If the query didn't // specify a TTL then we will try to use the agent's service-specific // TTL configs. // Check is there is a TTL provided as part of the prepared query var ttlOverride *uint32 if out.DNS.TTL != "" { ttl, err := time.ParseDuration(out.DNS.TTL) if err == nil { ttlSec := uint32(ttl / time.Second) ttlOverride = &ttlSec } f.logger.Warn("Failed to parse TTL for prepared query , ignoring", "ttl", out.DNS.TTL, "prepared_query", req.Name, ) } // If we have no nodes, return not found! if len(out.Nodes) == 0 { return nil, ECSNotGlobalError{ErrNotFound} } // Perform a random shuffle out.Nodes.Shuffle() return f.buildResultsFromServiceNodes(out.Nodes, req, ttlOverride), ECSNotGlobalError{} } // executePreparedQuery is used to execute a PreparedQuery against the Consul catalog. // If the config is set to UseCache, it will use agent cache. func (f *V1DataFetcher) executePreparedQuery(cfg *v1DataFetcherDynamicConfig, args structs.PreparedQueryExecuteRequest) (*structs.PreparedQueryExecuteResponse, error) { var out structs.PreparedQueryExecuteResponse RPC: if cfg.useCache { raw, m, err := f.getFromCacheFunc(context.TODO(), cachetype.PreparedQueryName, &args) if err != nil { return nil, err } reply, ok := raw.(*structs.PreparedQueryExecuteResponse) if !ok { // This should never happen, but we want to protect against panics return nil, err } f.logger.Trace("cache results for prepared query", "cache_hit", m.Hit, "prepared_query", args.QueryIDOrName, ) out = *reply } else { if err := f.rpcFunc(context.Background(), "PreparedQuery.Execute", &args, &out); err != nil { return nil, err } } // Verify that request is not too stale, redo the request. if args.AllowStale { if out.LastContact > cfg.maxStale { args.AllowStale = false f.logger.Warn("Query results too stale, re-requesting") goto RPC } else if out.LastContact > staleCounterThreshold { metrics.IncrCounter([]string{"dns", "stale_queries"}, 1) } } return &out, nil } func (f *V1DataFetcher) ValidateRequest(_ Context, req *QueryPayload) error { if req.EnableFailover { return ErrNotSupported } if req.PortName != "" { return ErrNotSupported } return validateEnterpriseTenancy(req.Tenancy) } // buildResultsFromServiceNodes builds a list of results from a list of nodes. func (f *V1DataFetcher) buildResultsFromServiceNodes(nodes []structs.CheckServiceNode, req *QueryPayload, ttlOverride *uint32) []*Result { // Convert the service endpoints to results up to the limit limit := req.Limit if len(nodes) < limit || limit == 0 { limit = len(nodes) } results := make([]*Result, 0, limit) for idx := 0; idx < limit; idx++ { n := nodes[idx] results = append(results, &Result{ Service: &Location{ Name: n.Service.Service, Address: n.Service.Address, TaggedAddresses: makeTaggedAddressesFromServiceAddresses(n.Service.TaggedAddresses), }, Node: &Location{ Name: n.Node.Node, Address: n.Node.Address, TaggedAddresses: makeTaggedAddressesFromStrings(n.Node.TaggedAddresses), }, Type: ResultTypeService, DNS: DNSConfig{ TTL: ttlOverride, Weight: uint32(findWeight(n)), }, Ports: []Port{ {Number: uint32(f.translateServicePortFunc(n.Node.Datacenter, n.Service.Port, n.Service.TaggedAddresses))}, }, Metadata: n.Node.Meta, Tenancy: ResultTenancy{ Namespace: n.Service.NamespaceOrEmpty(), Partition: n.Service.PartitionOrEmpty(), Datacenter: n.Node.Datacenter, PeerName: req.Tenancy.Peer, }, }) } return results } // makeTaggedAddressesFromServiceAddresses is used to convert a map of service addresses to a map of Locations. func makeTaggedAddressesFromServiceAddresses(tagged map[string]structs.ServiceAddress) map[string]*TaggedAddress { taggedAddresses := make(map[string]*TaggedAddress) for k, v := range tagged { taggedAddresses[k] = &TaggedAddress{ Name: k, Address: v.Address, Port: Port{ Number: uint32(v.Port), }, } } return taggedAddresses } // makeTaggedAddressesFromStrings is used to convert a map of strings to a map of Locations. func makeTaggedAddressesFromStrings(tagged map[string]string) map[string]*TaggedAddress { taggedAddresses := make(map[string]*TaggedAddress) for k, v := range tagged { taggedAddresses[k] = &TaggedAddress{ Name: k, Address: v, } } return taggedAddresses } // fetchNode is used to look up a node in the Consul catalog within NodeServices. // If the config is set to UseCache, it will get the record from the agent cache. func (f *V1DataFetcher) fetchNode(cfg *v1DataFetcherDynamicConfig, args *structs.NodeSpecificRequest) (*structs.IndexedNodeServices, error) { var out structs.IndexedNodeServices useCache := cfg.useCache RPC: if useCache { raw, _, err := f.getFromCacheFunc(context.TODO(), cachetype.NodeServicesName, args) if err != nil { return nil, err } reply, ok := raw.(*structs.IndexedNodeServices) if !ok { // This should never happen, but we want to protect against panics return nil, fmt.Errorf("internal error: response type not correct") } out = *reply } else { if err := f.rpcFunc(context.Background(), "Catalog.NodeServices", &args, &out); err != nil { return nil, err } } // Verify that request is not too stale, redo the request if args.AllowStale { if out.LastContact > cfg.maxStale { args.AllowStale = false useCache = false f.logger.Warn("Query results too stale, re-requesting") goto RPC } else if out.LastContact > staleCounterThreshold { metrics.IncrCounter([]string{"dns", "stale_queries"}, 1) } } return &out, nil } func (f *V1DataFetcher) fetchService(ctx Context, req *QueryPayload, cfg *v1DataFetcherDynamicConfig, lookupType LookupType) ([]*Result, error) { f.logger.Trace("fetchService", "req", req) if req.Tenancy.SamenessGroup == "" { return f.fetchServiceBasedOnTenancy(ctx, req, cfg, lookupType) } return f.fetchServiceFromSamenessGroup(ctx, req, cfg, lookupType) } // fetchServiceBasedOnTenancy is used to look up a service in the Consul catalog based on its tenancy or default tenancy. func (f *V1DataFetcher) fetchServiceBasedOnTenancy(ctx Context, req *QueryPayload, cfg *v1DataFetcherDynamicConfig, lookupType LookupType) ([]*Result, error) { f.logger.Trace(fmt.Sprintf("fetchServiceBasedOnTenancy - req: %+v", req)) if req.Tenancy.SamenessGroup != "" { return nil, errors.New("sameness groups are not allowed for service lookups based on tenancy") } datacenter := req.Tenancy.Datacenter if req.Tenancy.Peer != "" { datacenter = "" } serviceTags := []string{} if req.Tag != "" { serviceTags = []string{req.Tag} } args := structs.ServiceSpecificRequest{ PeerName: req.Tenancy.Peer, Connect: lookupType == LookupTypeConnect, Ingress: lookupType == LookupTypeIngress, Datacenter: datacenter, ServiceName: req.Name, ServiceTags: serviceTags, TagFilter: req.Tag != "", QueryOptions: structs.QueryOptions{ Token: ctx.Token, AllowStale: cfg.allowStale, MaxAge: cfg.cacheMaxAge, UseCache: cfg.useCache, MaxStaleDuration: cfg.maxStale, }, EnterpriseMeta: queryTenancyToEntMeta(req.Tenancy), } out, _, err := f.rpcFuncForServiceNodes(context.TODO(), args) if err != nil { if strings.Contains(err.Error(), structs.ErrNoDCPath.Error()) { return nil, ErrNoPathToDatacenter } return nil, fmt.Errorf("rpc request failed: %w", err) } // If we have no nodes, return not found! if len(out.Nodes) == 0 { return nil, ErrNotFound } // Filter out any service nodes due to health checks // We copy the slice to avoid modifying the result if it comes from the cache nodes := make(structs.CheckServiceNodes, len(out.Nodes)) copy(nodes, out.Nodes) out.Nodes = nodes.Filter(cfg.onlyPassing) if err != nil { return nil, fmt.Errorf("rpc request failed: %w", err) } // If we have no nodes, return not found! if len(out.Nodes) == 0 { return nil, ErrNotFound } // Perform a random shuffle out.Nodes.Shuffle() return f.buildResultsFromServiceNodes(out.Nodes, req, nil), nil } // findWeight returns the weight of a service node. func findWeight(node structs.CheckServiceNode) int { // By default, when only_passing is false, warning and passing nodes are returned // Those values will be used if using a client with support while server has no // support for weights weightPassing := 1 weightWarning := 1 if node.Service.Weights != nil { weightPassing = node.Service.Weights.Passing weightWarning = node.Service.Weights.Warning } serviceChecks := make(api.HealthChecks, 0, len(node.Checks)) for _, c := range node.Checks { if c.ServiceName == node.Service.Service || c.ServiceName == "" { healthCheck := &api.HealthCheck{ Node: c.Node, CheckID: string(c.CheckID), Name: c.Name, Status: c.Status, Notes: c.Notes, Output: c.Output, ServiceID: c.ServiceID, ServiceName: c.ServiceName, ServiceTags: c.ServiceTags, } serviceChecks = append(serviceChecks, healthCheck) } } status := serviceChecks.AggregatedStatus() switch status { case api.HealthWarning: return weightWarning case api.HealthPassing: return weightPassing case api.HealthMaint: // Not used in theory return 0 case api.HealthCritical: // Should not happen since already filtered return 0 default: // When non-standard status, return 1 return 1 } }