package peering import ( "context" "errors" "fmt" "strings" "time" "github.com/armon/go-metrics" "github.com/hashicorp/go-hclog" "github.com/hashicorp/go-memdb" "google.golang.org/grpc" "google.golang.org/grpc/codes" grpcstatus "google.golang.org/grpc/status" "google.golang.org/protobuf/proto" "github.com/hashicorp/consul/acl" "github.com/hashicorp/consul/acl/resolver" "github.com/hashicorp/consul/agent/consul/state" "github.com/hashicorp/consul/agent/consul/stream" "github.com/hashicorp/consul/agent/dns" external "github.com/hashicorp/consul/agent/grpc-external" "github.com/hashicorp/consul/agent/grpc-external/services/peerstream" "github.com/hashicorp/consul/agent/structs" "github.com/hashicorp/consul/lib" "github.com/hashicorp/consul/proto/pbpeering" ) var ( errPeeringTokenInvalidCA = errors.New("peering token CA value is invalid") errPeeringTokenEmptyServerAddresses = errors.New("peering token server addresses value is empty") errPeeringTokenEmptyServerName = errors.New("peering token server name value is empty") errPeeringTokenEmptyPeerID = errors.New("peering token peer ID value is empty") ) // errPeeringInvalidServerAddress is returned when an establish request contains // an invalid server address. type errPeeringInvalidServerAddress struct { addr string } // Error implements the error interface func (e *errPeeringInvalidServerAddress) Error() string { return fmt.Sprintf("%s is not a valid peering server address", e.addr) } // For private/internal gRPC handlers, protoc-gen-rpc-glue generates the // requisite methods to satisfy the structs.RPCInfo interface using fields // from the pbcommon package. This service is public, so we can't use those // fields in our proto definition. Instead, we construct our RPCInfo manually. var writeRequest struct { structs.WriteRequest structs.DCSpecificRequest } var readRequest struct { structs.QueryOptions structs.DCSpecificRequest } // Server implements pbpeering.PeeringService to provide RPC operations for // managing peering relationships. type Server struct { Config } type Config struct { Backend Backend Tracker *peerstream.Tracker Logger hclog.Logger ForwardRPC func(structs.RPCInfo, func(*grpc.ClientConn) error) (bool, error) Datacenter string ConnectEnabled bool PeeringEnabled bool } func NewServer(cfg Config) *Server { requireNotNil(cfg.Backend, "Backend") requireNotNil(cfg.Tracker, "Tracker") requireNotNil(cfg.Logger, "Logger") requireNotNil(cfg.ForwardRPC, "ForwardRPC") if cfg.Datacenter == "" { panic("Datacenter is required") } return &Server{ Config: cfg, } } func requireNotNil(v interface{}, name string) { if v == nil { panic(name + " is required") } } var _ pbpeering.PeeringServiceServer = (*Server)(nil) func (s *Server) Register(grpcServer *grpc.Server) { pbpeering.RegisterPeeringServiceServer(grpcServer, s) } // Backend defines the core integrations the Peering endpoint depends on. A // functional implementation will integrate with various subcomponents of Consul // such as the State store for reading and writing data, the CA machinery for // providing access to CA data and the RPC system for forwarding requests to // other servers. type Backend interface { // ResolveTokenAndDefaultMeta returns an acl.Authorizer which authorizes // actions based on the permissions granted to the token. // If either entMeta or authzContext are non-nil they will be populated with the // partition and namespace from the token. ResolveTokenAndDefaultMeta(token string, entMeta *acl.EnterpriseMeta, authzCtx *acl.AuthorizerContext) (resolver.Result, error) // GetAgentCACertificates returns the CA certificate to be returned in the peering token data GetAgentCACertificates() ([]string, error) // GetServerAddresses returns the addresses used for establishing a peering connection GetServerAddresses() ([]string, error) // GetServerName returns the SNI to be returned in the peering token data which // will be used by peers when establishing peering connections over TLS. GetServerName() string // EncodeToken packages a peering token into a slice of bytes. EncodeToken(tok *structs.PeeringToken) ([]byte, error) // DecodeToken unpackages a peering token from a slice of bytes. DecodeToken([]byte) (*structs.PeeringToken, error) EnterpriseCheckPartitions(partition string) error EnterpriseCheckNamespaces(namespace string) error Subscribe(req *stream.SubscribeRequest) (*stream.Subscription, error) // IsLeader indicates whether the consul server is in a leader state or not. IsLeader() bool // SetLeaderAddress is called on a raft.LeaderObservation in a go routine // in the consul server; see trackLeaderChanges() SetLeaderAddress(string) // GetLeaderAddress provides the best hint for the current address of the // leader. There is no guarantee that this is the actual address of the // leader. GetLeaderAddress() string CheckPeeringUUID(id string) (bool, error) PeeringWrite(req *pbpeering.PeeringWriteRequest) error Store() Store } // Store provides a read-only interface for querying Peering data. type Store interface { PeeringRead(ws memdb.WatchSet, q state.Query) (uint64, *pbpeering.Peering, error) PeeringReadByID(ws memdb.WatchSet, id string) (uint64, *pbpeering.Peering, error) PeeringList(ws memdb.WatchSet, entMeta acl.EnterpriseMeta) (uint64, []*pbpeering.Peering, error) PeeringTrustBundleRead(ws memdb.WatchSet, q state.Query) (uint64, *pbpeering.PeeringTrustBundle, error) PeeringTrustBundleList(ws memdb.WatchSet, entMeta acl.EnterpriseMeta) (uint64, []*pbpeering.PeeringTrustBundle, error) TrustBundleListByService(ws memdb.WatchSet, service, dc string, entMeta acl.EnterpriseMeta) (uint64, []*pbpeering.PeeringTrustBundle, error) } var peeringNotEnabledErr = grpcstatus.Error(codes.FailedPrecondition, "peering must be enabled to use this endpoint") // GenerateToken implements the PeeringService RPC method to generate a // peering token which is the initial step in establishing a peering relationship // with other Consul clusters. func (s *Server) GenerateToken( ctx context.Context, req *pbpeering.GenerateTokenRequest, ) (*pbpeering.GenerateTokenResponse, error) { if !s.Config.PeeringEnabled { return nil, peeringNotEnabledErr } if err := s.Backend.EnterpriseCheckPartitions(req.Partition); err != nil { return nil, grpcstatus.Error(codes.InvalidArgument, err.Error()) } // validate prior to forwarding to the leader, this saves a network hop if err := dns.ValidateLabel(req.PeerName); err != nil { return nil, fmt.Errorf("%s is not a valid peer name: %w", req.PeerName, err) } if err := structs.ValidateMetaTags(req.Meta); err != nil { return nil, fmt.Errorf("meta tags failed validation: %w", err) } defer metrics.MeasureSince([]string{"peering", "generate_token"}, time.Now()) resp := &pbpeering.GenerateTokenResponse{} handled, err := s.ForwardRPC(&writeRequest, func(conn *grpc.ClientConn) error { ctx := external.ForwardMetadataContext(ctx) var err error resp, err = pbpeering.NewPeeringServiceClient(conn).GenerateToken(ctx, req) return err }) if handled || err != nil { return resp, err } var authzCtx acl.AuthorizerContext entMeta := structs.DefaultEnterpriseMetaInPartition(req.Partition) authz, err := s.Backend.ResolveTokenAndDefaultMeta(external.TokenFromContext(ctx), entMeta, &authzCtx) if err != nil { return nil, err } if err := authz.ToAllowAuthorizer().PeeringWriteAllowed(&authzCtx); err != nil { return nil, err } var peering *pbpeering.Peering // This loop ensures at most one retry in the case of a race condition. for canRetry := true; canRetry; canRetry = false { peering, err = s.getExistingPeering(req.PeerName, entMeta.PartitionOrDefault()) if err != nil { return nil, err } if peering == nil { id, err := lib.GenerateUUID(s.Backend.CheckPeeringUUID) if err != nil { return resp, err } peering = &pbpeering.Peering{ ID: id, Name: req.PeerName, Meta: req.Meta, // PartitionOrEmpty is used to avoid writing "default" in OSS. Partition: entMeta.PartitionOrEmpty(), } } else { // validate that this peer name is not being used as a dialer already if err := validatePeer(peering, false); err != nil { return nil, err } } writeReq := pbpeering.PeeringWriteRequest{ Peering: peering, } if err := s.Backend.PeeringWrite(&writeReq); err != nil { // There's a possible race where two servers call Generate Token at the // same time with the same peer name for the first time. They both // generate an ID and try to insert and only one wins. This detects the // collision and forces the loser to discard its generated ID and use // the one from the other server. if strings.Contains(err.Error(), "A peering already exists with the name") { // retry to fetch existing peering continue } return nil, fmt.Errorf("failed to write peering: %w", err) } // write succeeded, break loop early break } ca, err := s.Backend.GetAgentCACertificates() if err != nil { return nil, err } // ServerExternalAddresses must be formatted as addr:port. var serverAddrs []string if len(req.ServerExternalAddresses) > 0 { serverAddrs = req.ServerExternalAddresses } else { serverAddrs, err = s.Backend.GetServerAddresses() if err != nil { return nil, err } } tok := structs.PeeringToken{ // Store the UUID so that we can do a global search when handling inbound streams. PeerID: peering.ID, CA: ca, ServerAddresses: serverAddrs, ServerName: s.Backend.GetServerName(), } encoded, err := s.Backend.EncodeToken(&tok) if err != nil { return nil, err } resp.PeeringToken = string(encoded) return resp, err } // Establish implements the PeeringService RPC method to finalize peering // registration. Given a valid token output from a peer's GenerateToken endpoint, // a peering is registered. func (s *Server) Establish( ctx context.Context, req *pbpeering.EstablishRequest, ) (*pbpeering.EstablishResponse, error) { if !s.Config.PeeringEnabled { return nil, peeringNotEnabledErr } // validate prior to forwarding to the leader, this saves a network hop if err := dns.ValidateLabel(req.PeerName); err != nil { return nil, fmt.Errorf("%s is not a valid peer name: %w", req.PeerName, err) } tok, err := s.Backend.DecodeToken([]byte(req.PeeringToken)) if err != nil { return nil, err } if err := validatePeeringToken(tok); err != nil { return nil, err } if err := structs.ValidateMetaTags(req.Meta); err != nil { return nil, fmt.Errorf("meta tags failed validation: %w", err) } resp := &pbpeering.EstablishResponse{} handled, err := s.ForwardRPC(&writeRequest, func(conn *grpc.ClientConn) error { ctx := external.ForwardMetadataContext(ctx) var err error resp, err = pbpeering.NewPeeringServiceClient(conn).Establish(ctx, req) return err }) if handled || err != nil { return resp, err } defer metrics.MeasureSince([]string{"peering", "establish"}, time.Now()) var authzCtx acl.AuthorizerContext entMeta := structs.DefaultEnterpriseMetaInPartition(req.Partition) authz, err := s.Backend.ResolveTokenAndDefaultMeta(external.TokenFromContext(ctx), entMeta, &authzCtx) if err != nil { return nil, err } if err := authz.ToAllowAuthorizer().PeeringWriteAllowed(&authzCtx); err != nil { return nil, err } peering, err := s.getExistingPeering(req.PeerName, entMeta.PartitionOrDefault()) if err != nil { return nil, err } // we don't want to default req.Partition unlike because partitions are empty in OSS if err := s.validatePeeringInPartition(tok.PeerID, req.Partition); err != nil { return nil, err } var id string if peering == nil { id, err = lib.GenerateUUID(s.Backend.CheckPeeringUUID) if err != nil { return nil, err } } else { id = peering.ID } // validate that this peer name is not being used as an acceptor already if err := validatePeer(peering, true); err != nil { return nil, err } // convert ServiceAddress values to strings serverAddrs := make([]string, len(tok.ServerAddresses)) for i, addr := range tok.ServerAddresses { serverAddrs[i] = addr } // as soon as a peering is written with a list of ServerAddresses that is // non-empty, the leader routine will see the peering and attempt to // establish a connection with the remote peer. // // This peer now has a record of both the LocalPeerID(ID) and // RemotePeerID(PeerID) but at this point the other peer does not. writeReq := &pbpeering.PeeringWriteRequest{ Peering: &pbpeering.Peering{ ID: id, Name: req.PeerName, PeerCAPems: tok.CA, PeerServerAddresses: serverAddrs, PeerServerName: tok.ServerName, PeerID: tok.PeerID, Meta: req.Meta, State: pbpeering.PeeringState_ESTABLISHING, // PartitionOrEmpty is used to avoid writing "default" in OSS. Partition: entMeta.PartitionOrEmpty(), }, } if err := s.Backend.PeeringWrite(writeReq); err != nil { return nil, fmt.Errorf("failed to write peering: %w", err) } // TODO(peering): low prio: consider adding response details return resp, nil } // validatePeeringInPartition makes sure that we don't create a peering in the same partition. We validate by looking at // the remotePeerID from the PeeringToken and looking up for a peering in the partition. If there is one and the // request partition is the same, then we are attempting to peer within the partition, which we shouldn't. func (s *Server) validatePeeringInPartition(remotePeerID, partition string) error { _, peering, err := s.Backend.Store().PeeringReadByID(nil, remotePeerID) if err != nil { return fmt.Errorf("cannot read peering by ID: %w", err) } if peering != nil && peering.Partition == partition { return fmt.Errorf("cannot create a peering within the same partition (ENT) or cluster (OSS)") } return nil } // OPTIMIZE: Handle blocking queries func (s *Server) PeeringRead(ctx context.Context, req *pbpeering.PeeringReadRequest) (*pbpeering.PeeringReadResponse, error) { if !s.Config.PeeringEnabled { return nil, peeringNotEnabledErr } if err := s.Backend.EnterpriseCheckPartitions(req.Partition); err != nil { return nil, grpcstatus.Error(codes.InvalidArgument, err.Error()) } var resp *pbpeering.PeeringReadResponse handled, err := s.ForwardRPC(&readRequest, func(conn *grpc.ClientConn) error { ctx := external.ForwardMetadataContext(ctx) var err error resp, err = pbpeering.NewPeeringServiceClient(conn).PeeringRead(ctx, req) return err }) if handled || err != nil { return resp, err } defer metrics.MeasureSince([]string{"peering", "read"}, time.Now()) var authzCtx acl.AuthorizerContext entMeta := structs.DefaultEnterpriseMetaInPartition(req.Partition) authz, err := s.Backend.ResolveTokenAndDefaultMeta(external.TokenFromContext(ctx), entMeta, &authzCtx) if err != nil { return nil, err } if err := authz.ToAllowAuthorizer().PeeringReadAllowed(&authzCtx); err != nil { return nil, err } q := state.Query{ Value: strings.ToLower(req.Name), EnterpriseMeta: *entMeta, } _, peering, err := s.Backend.Store().PeeringRead(nil, q) if err != nil { return nil, err } if peering == nil { return &pbpeering.PeeringReadResponse{Peering: nil}, nil } cp := s.reconcilePeering(peering) return &pbpeering.PeeringReadResponse{Peering: cp}, nil } // OPTIMIZE: Handle blocking queries func (s *Server) PeeringList(ctx context.Context, req *pbpeering.PeeringListRequest) (*pbpeering.PeeringListResponse, error) { if !s.Config.PeeringEnabled { return nil, peeringNotEnabledErr } if err := s.Backend.EnterpriseCheckPartitions(req.Partition); err != nil { return nil, grpcstatus.Error(codes.InvalidArgument, err.Error()) } var resp *pbpeering.PeeringListResponse handled, err := s.ForwardRPC(&readRequest, func(conn *grpc.ClientConn) error { ctx := external.ForwardMetadataContext(ctx) var err error resp, err = pbpeering.NewPeeringServiceClient(conn).PeeringList(ctx, req) return err }) if handled || err != nil { return resp, err } var authzCtx acl.AuthorizerContext entMeta := structs.DefaultEnterpriseMetaInPartition(req.Partition) authz, err := s.Backend.ResolveTokenAndDefaultMeta(external.TokenFromContext(ctx), entMeta, &authzCtx) if err != nil { return nil, err } if err := authz.ToAllowAuthorizer().PeeringReadAllowed(&authzCtx); err != nil { return nil, err } defer metrics.MeasureSince([]string{"peering", "list"}, time.Now()) _, peerings, err := s.Backend.Store().PeeringList(nil, *entMeta) if err != nil { return nil, err } // reconcile the actual peering state; need to copy over the ds for peering var cPeerings []*pbpeering.Peering for _, p := range peerings { cp := s.reconcilePeering(p) cPeerings = append(cPeerings, cp) } return &pbpeering.PeeringListResponse{Peerings: cPeerings}, nil } // TODO(peering): Get rid of this func when we stop using the stream tracker for imported/ exported services and the peering state // reconcilePeering enriches the peering with the following information: // -- PeeringState.Active if the peering is active // -- ImportedServicesCount and ExportedServicesCount // NOTE: we return a new peering with this additional data func (s *Server) reconcilePeering(peering *pbpeering.Peering) *pbpeering.Peering { streamState, found := s.Tracker.StreamStatus(peering.ID) if !found { s.Logger.Warn("did not find peer in stream tracker; cannot populate imported and"+ " exported services count or reconcile peering state", "peerID", peering.ID) return peering } else { cp := copyPeering(peering) // reconcile pbpeering.PeeringState_Active if streamState.Connected { cp.State = pbpeering.PeeringState_ACTIVE } else if streamState.DisconnectErrorMessage != "" { cp.State = pbpeering.PeeringState_FAILING } // add imported & exported services counts cp.ImportedServiceCount = streamState.GetImportedServicesCount() cp.ExportedServiceCount = streamState.GetExportedServicesCount() return cp } } // TODO(peering): As of writing, this method is only used in tests to set up Peerings in the state store. // Consider removing if we can find another way to populate state store in peering_endpoint_test.go func (s *Server) PeeringWrite(ctx context.Context, req *pbpeering.PeeringWriteRequest) (*pbpeering.PeeringWriteResponse, error) { if !s.Config.PeeringEnabled { return nil, peeringNotEnabledErr } if err := s.Backend.EnterpriseCheckPartitions(req.Peering.Partition); err != nil { return nil, grpcstatus.Error(codes.InvalidArgument, err.Error()) } var resp *pbpeering.PeeringWriteResponse handled, err := s.ForwardRPC(&writeRequest, func(conn *grpc.ClientConn) error { ctx := external.ForwardMetadataContext(ctx) var err error resp, err = pbpeering.NewPeeringServiceClient(conn).PeeringWrite(ctx, req) return err }) if handled || err != nil { return resp, err } defer metrics.MeasureSince([]string{"peering", "write"}, time.Now()) var authzCtx acl.AuthorizerContext entMeta := structs.DefaultEnterpriseMetaInPartition(req.Peering.Partition) authz, err := s.Backend.ResolveTokenAndDefaultMeta(external.TokenFromContext(ctx), entMeta, &authzCtx) if err != nil { return nil, err } if err := authz.ToAllowAuthorizer().PeeringWriteAllowed(&authzCtx); err != nil { return nil, err } if req.Peering == nil { return nil, fmt.Errorf("missing required peering body") } var id string peering, err := s.getExistingPeering(req.Peering.Name, entMeta.PartitionOrDefault()) if err != nil { return nil, err } if peering == nil { id, err = lib.GenerateUUID(s.Backend.CheckPeeringUUID) if err != nil { return nil, err } } else { id = peering.ID } req.Peering.ID = id err = s.Backend.PeeringWrite(req) if err != nil { return nil, err } return &pbpeering.PeeringWriteResponse{}, nil } func (s *Server) PeeringDelete(ctx context.Context, req *pbpeering.PeeringDeleteRequest) (*pbpeering.PeeringDeleteResponse, error) { if !s.Config.PeeringEnabled { return nil, peeringNotEnabledErr } if err := s.Backend.EnterpriseCheckPartitions(req.Partition); err != nil { return nil, grpcstatus.Error(codes.InvalidArgument, err.Error()) } var resp *pbpeering.PeeringDeleteResponse handled, err := s.ForwardRPC(&writeRequest, func(conn *grpc.ClientConn) error { ctx := external.ForwardMetadataContext(ctx) var err error resp, err = pbpeering.NewPeeringServiceClient(conn).PeeringDelete(ctx, req) return err }) if handled || err != nil { return resp, err } defer metrics.MeasureSince([]string{"peering", "delete"}, time.Now()) var authzCtx acl.AuthorizerContext entMeta := structs.DefaultEnterpriseMetaInPartition(req.Partition) authz, err := s.Backend.ResolveTokenAndDefaultMeta(external.TokenFromContext(ctx), entMeta, &authzCtx) if err != nil { return nil, err } if err := authz.ToAllowAuthorizer().PeeringWriteAllowed(&authzCtx); err != nil { return nil, err } q := state.Query{ Value: strings.ToLower(req.Name), EnterpriseMeta: *entMeta, } _, existing, err := s.Backend.Store().PeeringRead(nil, q) if err != nil { return nil, err } if existing == nil || !existing.IsActive() { // Return early when the Peering doesn't exist or is already marked for deletion. // We don't return nil because the pb will fail to marshal. return &pbpeering.PeeringDeleteResponse{}, nil } // We are using a write request due to needing to perform a deferred deletion. // The peering gets marked for deletion by setting the DeletedAt field, // and a leader routine will handle deleting the peering. writeReq := &pbpeering.PeeringWriteRequest{ Peering: &pbpeering.Peering{ // We only need to include the name and partition for the peering to be identified. // All other data associated with the peering can be discarded because once marked // for deletion the peering is effectively gone. ID: existing.ID, Name: req.Name, State: pbpeering.PeeringState_DELETING, DeletedAt: structs.TimeToProto(time.Now().UTC()), // PartitionOrEmpty is used to avoid writing "default" in OSS. Partition: entMeta.PartitionOrEmpty(), }, } err = s.Backend.PeeringWrite(writeReq) if err != nil { return nil, err } return &pbpeering.PeeringDeleteResponse{}, nil } // OPTIMIZE: Handle blocking queries func (s *Server) TrustBundleRead(ctx context.Context, req *pbpeering.TrustBundleReadRequest) (*pbpeering.TrustBundleReadResponse, error) { if !s.Config.PeeringEnabled { return nil, peeringNotEnabledErr } if err := s.Backend.EnterpriseCheckPartitions(req.Partition); err != nil { return nil, grpcstatus.Error(codes.InvalidArgument, err.Error()) } var resp *pbpeering.TrustBundleReadResponse handled, err := s.ForwardRPC(&readRequest, func(conn *grpc.ClientConn) error { ctx := external.ForwardMetadataContext(ctx) var err error resp, err = pbpeering.NewPeeringServiceClient(conn).TrustBundleRead(ctx, req) return err }) if handled || err != nil { return resp, err } defer metrics.MeasureSince([]string{"peering", "trust_bundle_read"}, time.Now()) var authzCtx acl.AuthorizerContext entMeta := structs.DefaultEnterpriseMetaInPartition(req.Partition) authz, err := s.Backend.ResolveTokenAndDefaultMeta(external.TokenFromContext(ctx), entMeta, &authzCtx) if err != nil { return nil, err } if err := authz.ToAllowAuthorizer().ServiceWriteAnyAllowed(&authzCtx); err != nil { return nil, err } idx, trustBundle, err := s.Backend.Store().PeeringTrustBundleRead(nil, state.Query{ Value: req.Name, EnterpriseMeta: *entMeta, }) if err != nil { return nil, fmt.Errorf("failed to read trust bundle for peer %s: %w", req.Name, err) } return &pbpeering.TrustBundleReadResponse{ Index: idx, Bundle: trustBundle, }, nil } // TODO(peering): rename rpc & request/response to drop the "service" part // OPTIMIZE: Handle blocking queries func (s *Server) TrustBundleListByService(ctx context.Context, req *pbpeering.TrustBundleListByServiceRequest) (*pbpeering.TrustBundleListByServiceResponse, error) { if !s.Config.PeeringEnabled { return nil, peeringNotEnabledErr } if err := s.Backend.EnterpriseCheckPartitions(req.Partition); err != nil { return nil, grpcstatus.Error(codes.InvalidArgument, err.Error()) } if err := s.Backend.EnterpriseCheckNamespaces(req.Namespace); err != nil { return nil, grpcstatus.Error(codes.InvalidArgument, err.Error()) } if req.ServiceName == "" { return nil, errors.New("missing service name") } var resp *pbpeering.TrustBundleListByServiceResponse handled, err := s.ForwardRPC(&readRequest, func(conn *grpc.ClientConn) error { ctx := external.ForwardMetadataContext(ctx) var err error resp, err = pbpeering.NewPeeringServiceClient(conn).TrustBundleListByService(ctx, req) return err }) if handled || err != nil { return resp, err } defer metrics.MeasureSince([]string{"peering", "trust_bundle_list_by_service"}, time.Now()) var authzCtx acl.AuthorizerContext entMeta := acl.NewEnterpriseMetaWithPartition(req.Partition, req.Namespace) authz, err := s.Backend.ResolveTokenAndDefaultMeta(external.TokenFromContext(ctx), &entMeta, &authzCtx) if err != nil { return nil, err } if err := authz.ToAllowAuthorizer().ServiceWriteAllowed(req.ServiceName, &authzCtx); err != nil { return nil, err } var ( idx uint64 bundles []*pbpeering.PeeringTrustBundle ) switch { case req.Kind == string(structs.ServiceKindMeshGateway): idx, bundles, err = s.Backend.Store().PeeringTrustBundleList(nil, entMeta) case req.ServiceName != "": idx, bundles, err = s.Backend.Store().TrustBundleListByService(nil, req.ServiceName, s.Datacenter, entMeta) case req.Kind != "": return nil, grpcstatus.Error(codes.InvalidArgument, "kind must be mesh-gateway if set") default: return nil, grpcstatus.Error(codes.InvalidArgument, "one of service or kind is required") } if err != nil { return nil, err } return &pbpeering.TrustBundleListByServiceResponse{Index: idx, Bundles: bundles}, nil } func (s *Server) getExistingPeering(peerName, partition string) (*pbpeering.Peering, error) { q := state.Query{ Value: strings.ToLower(peerName), EnterpriseMeta: *structs.NodeEnterpriseMetaInPartition(partition), } _, peering, err := s.Backend.Store().PeeringRead(nil, q) if err != nil { return nil, err } return peering, nil } // validatePeer enforces the following rule for an existing peering: // - if a peering already exists, it can only be used as an acceptor or dialer // // We define a DIALER as a peering that has server addresses (or a peering that is created via the Establish endpoint) // Conversely, we define an ACCEPTOR as a peering that is created via the GenerateToken endpoint func validatePeer(peering *pbpeering.Peering, shouldDial bool) error { if peering != nil && peering.ShouldDial() != shouldDial { if shouldDial { return fmt.Errorf("cannot create peering with name: %q; there is an existing peering expecting to be dialed", peering.Name) } else { return fmt.Errorf("cannot create peering with name: %q; there is already an established peering", peering.Name) } } return nil } func copyPeering(p *pbpeering.Peering) *pbpeering.Peering { var copyP pbpeering.Peering proto.Merge(©P, p) return ©P }