// Copyright (c) HashiCorp, Inc. // SPDX-License-Identifier: BUSL-1.1 package topology import ( crand "crypto/rand" "encoding/hex" "errors" "fmt" "reflect" "regexp" "sort" "github.com/google/go-cmp/cmp" pbauth "github.com/hashicorp/consul/proto-public/pbauth/v2beta1" pbcatalog "github.com/hashicorp/consul/proto-public/pbcatalog/v2beta1" pbmesh "github.com/hashicorp/consul/proto-public/pbmesh/v2beta1" "github.com/hashicorp/consul/proto-public/pbresource" "github.com/hashicorp/go-hclog" "golang.org/x/exp/maps" "github.com/hashicorp/consul/testing/deployer/util" ) const DockerPrefix = "cslc" // ConSuLCluster func Compile(logger hclog.Logger, raw *Config) (*Topology, error) { return compile(logger, raw, nil) } func Recompile(logger hclog.Logger, raw *Config, prev *Topology) (*Topology, error) { if prev == nil { return nil, errors.New("missing previous topology") } return compile(logger, raw, prev) } func compile(logger hclog.Logger, raw *Config, prev *Topology) (*Topology, error) { var id string if prev == nil { var err error id, err = newTopologyID() if err != nil { return nil, err } } else { id = prev.ID } images := DefaultImages().OverrideWith(raw.Images) if images.Consul != "" { return nil, fmt.Errorf("topology.images.consul cannot be set at this level") } if len(raw.Networks) == 0 { return nil, fmt.Errorf("topology.networks is empty") } networks := make(map[string]*Network) for _, net := range raw.Networks { if net.DockerName != "" { return nil, fmt.Errorf("network %q should not specify DockerName", net.Name) } if !IsValidLabel(net.Name) { return nil, fmt.Errorf("network name is not valid: %s", net.Name) } if _, exists := networks[net.Name]; exists { return nil, fmt.Errorf("cannot have two networks with the same name %q", net.Name) } switch net.Type { case "": net.Type = "lan" case "wan", "lan": default: return nil, fmt.Errorf("network %q has unknown type %q", net.Name, net.Type) } networks[net.Name] = net net.DockerName = DockerPrefix + "-" + net.Name + "-" + id } if len(raw.Clusters) == 0 { return nil, fmt.Errorf("topology.clusters is empty") } var ( clusters = make(map[string]*Cluster) nextIndex int // use a global index so any shared networks work properly with assignments ) foundPeerNames := make(map[string]map[string]struct{}) for _, c := range raw.Clusters { if c.Name == "" { return nil, fmt.Errorf("cluster has no name") } foundPeerNames[c.Name] = make(map[string]struct{}) if !IsValidLabel(c.Name) { return nil, fmt.Errorf("cluster name is not valid: %s", c.Name) } if _, exists := clusters[c.Name]; exists { return nil, fmt.Errorf("cannot have two clusters with the same name %q; use unique names and override the Datacenter field if that's what you want", c.Name) } if c.Datacenter == "" { c.Datacenter = c.Name } else { if !IsValidLabel(c.Datacenter) { return nil, fmt.Errorf("datacenter name is not valid: %s", c.Datacenter) } } clusters[c.Name] = c if c.NetworkName == "" { c.NetworkName = c.Name } c.Images = images.OverrideWith(c.Images).ChooseConsul(c.Enterprise) if _, ok := networks[c.NetworkName]; !ok { return nil, fmt.Errorf("cluster %q uses network name %q that does not exist", c.Name, c.NetworkName) } if len(c.Nodes) == 0 { return nil, fmt.Errorf("cluster %q has no nodes", c.Name) } if len(c.Services) == 0 { // always initialize this regardless of v2-ness, because we might late-enable it below c.Services = make(map[ID]*pbcatalog.Service) } var implicitV2Services bool if len(c.Services) > 0 { c.EnableV2 = true for name, svc := range c.Services { if svc.Workloads != nil { return nil, fmt.Errorf("the workloads field for v2 service %q is not user settable", name) } } } else { implicitV2Services = true } if c.TLSVolumeName != "" { return nil, fmt.Errorf("user cannot specify the TLSVolumeName field") } tenancies := make(map[string]map[string]struct{}) addTenancy := func(partition, namespace string) { partition = PartitionOrDefault(partition) namespace = NamespaceOrDefault(namespace) m, ok := tenancies[partition] if !ok { m = make(map[string]struct{}) tenancies[partition] = m } m[namespace] = struct{}{} } for _, ap := range c.Partitions { addTenancy(ap.Name, "default") for _, ns := range ap.Namespaces { addTenancy(ap.Name, ns) } } for _, ce := range c.InitialConfigEntries { addTenancy(ce.GetPartition(), ce.GetNamespace()) } if len(c.InitialResources) > 0 { c.EnableV2 = true } for _, res := range c.InitialResources { if res.Id.Tenancy == nil { res.Id.Tenancy = &pbresource.Tenancy{} } // TODO(peering/v2) prevent non-local peer resources res.Id.Tenancy.Partition = PartitionOrDefault(res.Id.Tenancy.Partition) if !util.IsTypePartitionScoped(res.Id.Type) { res.Id.Tenancy.Namespace = NamespaceOrDefault(res.Id.Tenancy.Namespace) } switch { case util.EqualType(pbauth.ComputedTrafficPermissionsType, res.Id.GetType()), util.EqualType(pbauth.WorkloadIdentityType, res.Id.GetType()): fallthrough case util.EqualType(pbmesh.ComputedRoutesType, res.Id.GetType()), util.EqualType(pbmesh.ProxyStateTemplateType, res.Id.GetType()): fallthrough case util.EqualType(pbcatalog.HealthChecksType, res.Id.GetType()), util.EqualType(pbcatalog.HealthStatusType, res.Id.GetType()), util.EqualType(pbcatalog.NodeType, res.Id.GetType()), util.EqualType(pbcatalog.ServiceEndpointsType, res.Id.GetType()), util.EqualType(pbcatalog.WorkloadType, res.Id.GetType()): return nil, fmt.Errorf("you should not create a resource of type %q this way", util.TypeToString(res.Id.Type)) } addTenancy(res.Id.Tenancy.Partition, res.Id.Tenancy.Namespace) } seenNodes := make(map[NodeID]struct{}) for _, n := range c.Nodes { if n.Name == "" { return nil, fmt.Errorf("cluster %q node has no name", c.Name) } if !IsValidLabel(n.Name) { return nil, fmt.Errorf("node name is not valid: %s", n.Name) } switch n.Kind { case NodeKindServer, NodeKindClient, NodeKindDataplane: default: return nil, fmt.Errorf("cluster %q node %q has invalid kind: %s", c.Name, n.Name, n.Kind) } if n.Version == NodeVersionUnknown { n.Version = NodeVersionV1 } switch n.Version { case NodeVersionV1: case NodeVersionV2: if n.Kind == NodeKindClient { return nil, fmt.Errorf("v2 does not support client agents at this time") } c.EnableV2 = true default: return nil, fmt.Errorf("cluster %q node %q has invalid version: %s", c.Name, n.Name, n.Version) } n.Partition = PartitionOrDefault(n.Partition) if !IsValidLabel(n.Partition) { return nil, fmt.Errorf("node partition is not valid: %s", n.Partition) } addTenancy(n.Partition, "default") if _, exists := seenNodes[n.ID()]; exists { return nil, fmt.Errorf("cannot have two nodes in the same cluster %q with the same name %q", c.Name, n.ID()) } seenNodes[n.ID()] = struct{}{} if len(n.usedPorts) != 0 { return nil, fmt.Errorf("user cannot specify the usedPorts field") } n.usedPorts = make(map[int]int) exposePort := func(v int) bool { if _, ok := n.usedPorts[v]; ok { return false } n.usedPorts[v] = 0 return true } if n.IsAgent() { // TODO: the ux here is awful; we should be able to examine the topology to guess properly exposePort(8500) if n.IsServer() { exposePort(8503) } else { exposePort(8502) } } if n.Index != 0 { return nil, fmt.Errorf("user cannot specify the node index") } n.Index = nextIndex nextIndex++ n.Images = c.Images.OverrideWith(n.Images.ChooseConsul(c.Enterprise)).ChooseNode(n.Kind) n.Cluster = c.Name n.Datacenter = c.Datacenter n.dockerName = DockerPrefix + "-" + n.Name + "-" + id if len(n.Addresses) == 0 { n.Addresses = append(n.Addresses, &Address{Network: c.NetworkName}) } var ( numPublic int numLocal int ) for _, addr := range n.Addresses { if addr.Network == "" { return nil, fmt.Errorf("cluster %q node %q has invalid address", c.Name, n.Name) } if addr.Type != "" { return nil, fmt.Errorf("user cannot specify the address type directly") } net, ok := networks[addr.Network] if !ok { return nil, fmt.Errorf("cluster %q node %q uses network name %q that does not exist", c.Name, n.Name, addr.Network) } if net.IsPublic() { numPublic++ } else if net.IsLocal() { numLocal++ } addr.Type = net.Type addr.DockerNetworkName = net.DockerName } if numLocal == 0 { return nil, fmt.Errorf("cluster %q node %q has no local addresses", c.Name, n.Name) } if numPublic > 1 { return nil, fmt.Errorf("cluster %q node %q has more than one public address", c.Name, n.Name) } if len(n.Services) > 0 { logger.Warn("please use Node.Workloads instead of Node.Services") n.Workloads = append(n.Workloads, n.Services...) n.Services = nil } if n.IsDataplane() && len(n.Workloads) > 1 { // Our use of consul-dataplane here is supposed to mimic that // of consul-k8s, which ultimately has one IP per Service, so // we introduce the same limitation here. return nil, fmt.Errorf("cluster %q node %q uses dataplane, but has more than one service", c.Name, n.Name) } seenServices := make(map[ID]struct{}) for _, wrk := range n.Workloads { if n.IsAgent() { // Default to that of the enclosing node. wrk.ID.Partition = n.Partition } wrk.ID.Normalize() // Denormalize wrk.Node = n wrk.NodeVersion = n.Version if n.IsV2() { wrk.Workload = wrk.ID.Name + "-" + n.Name } if !IsValidLabel(wrk.ID.Partition) { return nil, fmt.Errorf("service partition is not valid: %s", wrk.ID.Partition) } if !IsValidLabel(wrk.ID.Namespace) { return nil, fmt.Errorf("service namespace is not valid: %s", wrk.ID.Namespace) } if !IsValidLabel(wrk.ID.Name) { return nil, fmt.Errorf("service name is not valid: %s", wrk.ID.Name) } if wrk.ID.Partition != n.Partition { return nil, fmt.Errorf("service %s on node %s has mismatched partitions: %s != %s", wrk.ID.Name, n.Name, wrk.ID.Partition, n.Partition) } addTenancy(wrk.ID.Partition, wrk.ID.Namespace) if _, exists := seenServices[wrk.ID]; exists { return nil, fmt.Errorf("cannot have two services on the same node %q in the same cluster %q with the same name %q", n.ID(), c.Name, wrk.ID) } seenServices[wrk.ID] = struct{}{} if !wrk.DisableServiceMesh && n.IsDataplane() { if wrk.EnvoyPublicListenerPort <= 0 { if _, ok := n.usedPorts[20000]; !ok { // For convenience the FIRST service on a node can get 20000 for free. wrk.EnvoyPublicListenerPort = 20000 } else { return nil, fmt.Errorf("envoy public listener port is required") } } } // add all of the service ports for _, port := range wrk.ports() { if ok := exposePort(port); !ok { return nil, fmt.Errorf("port used more than once on cluster %q node %q: %d", c.Name, n.ID(), port) } } // TODO(rb): re-expose? // switch wrk.Protocol { // case "": // wrk.Protocol = "tcp" // fallthrough // case "tcp": // if wrk.CheckHTTP != "" { // return nil, fmt.Errorf("cannot set CheckHTTP for tcp service") // } // case "http": // if wrk.CheckTCP != "" { // return nil, fmt.Errorf("cannot set CheckTCP for tcp service") // } // default: // return nil, fmt.Errorf("service has invalid protocol: %s", wrk.Protocol) // } defaultDestination := func(dest *Destination) error { // Default to that of the enclosing service. if dest.Peer == "" { if dest.ID.Partition == "" { dest.ID.Partition = wrk.ID.Partition } if dest.ID.Namespace == "" { dest.ID.Namespace = wrk.ID.Namespace } } else { if dest.ID.Partition != "" { dest.ID.Partition = "" // irrelevant here; we'll set it to the value of the OTHER side for plumbing purposes in tests } dest.ID.Namespace = NamespaceOrDefault(dest.ID.Namespace) foundPeerNames[c.Name][dest.Peer] = struct{}{} } addTenancy(dest.ID.Partition, dest.ID.Namespace) if dest.Implied { if dest.PortName == "" { return fmt.Errorf("implicit destinations must use port names in v2") } } else { if dest.LocalAddress == "" { // v1 defaults to 127.0.0.1 but v2 does not. Safe to do this generally though. dest.LocalAddress = "127.0.0.1" } if dest.PortName != "" && n.IsV1() { return fmt.Errorf("explicit destinations cannot use port names in v1") } if dest.PortName == "" && n.IsV2() { // Assume this is a v1->v2 conversion and name it. dest.PortName = "legacy" } } return nil } for _, dest := range wrk.Destinations { if err := defaultDestination(dest); err != nil { return nil, err } } if n.IsV2() { for _, dest := range wrk.ImpliedDestinations { dest.Implied = true if err := defaultDestination(dest); err != nil { return nil, err } } } else { if len(wrk.ImpliedDestinations) > 0 { return nil, fmt.Errorf("v1 does not support implied destinations yet") } } if err := wrk.Validate(); err != nil { return nil, fmt.Errorf("cluster %q node %q service %q is not valid: %w", c.Name, n.Name, wrk.ID.String(), err) } if wrk.EnableTransparentProxy && !n.IsDataplane() { return nil, fmt.Errorf("cannot enable tproxy on a non-dataplane node") } if n.IsV2() { if implicitV2Services { wrk.V2Services = []string{wrk.ID.Name} var svcPorts []*pbcatalog.ServicePort for name, cfg := range wrk.Ports { svcPorts = append(svcPorts, &pbcatalog.ServicePort{ TargetPort: name, Protocol: cfg.ActualProtocol, }) } v2svc := &pbcatalog.Service{ Workloads: &pbcatalog.WorkloadSelector{}, Ports: svcPorts, } prev, ok := c.Services[wrk.ID] if !ok { c.Services[wrk.ID] = v2svc prev = v2svc } if prev.Workloads == nil { prev.Workloads = &pbcatalog.WorkloadSelector{} } prev.Workloads.Names = append(prev.Workloads.Names, wrk.Workload) } else { for _, name := range wrk.V2Services { v2ID := NewServiceID(name, wrk.ID.Namespace, wrk.ID.Partition) v2svc, ok := c.Services[v2ID] if !ok { return nil, fmt.Errorf("cluster %q node %q service %q has a v2 service reference that does not exist %q", c.Name, n.Name, wrk.ID.String(), name) } if v2svc.Workloads == nil { v2svc.Workloads = &pbcatalog.WorkloadSelector{} } v2svc.Workloads.Names = append(v2svc.Workloads.Names, wrk.Workload) } } if wrk.WorkloadIdentity == "" { wrk.WorkloadIdentity = wrk.ID.Name } } else { if len(wrk.V2Services) > 0 { return nil, fmt.Errorf("cannot specify v2 services for v1") } if wrk.WorkloadIdentity != "" { return nil, fmt.Errorf("cannot specify workload identities for v1") } } } } if err := assignVirtualIPs(c); err != nil { return nil, err } if c.EnableV2 { // Populate the VirtualPort field on all destinations. for _, n := range c.Nodes { for _, wrk := range n.Workloads { for _, dest := range wrk.ImpliedDestinations { res, ok := c.Services[dest.ID] if ok { for _, sp := range res.Ports { if sp.Protocol == pbcatalog.Protocol_PROTOCOL_MESH { continue } if sp.MatchesPortId(dest.PortName) { dest.VirtualPort = sp.VirtualPort } } } } for _, dest := range wrk.Destinations { res, ok := c.Services[dest.ID] if ok { for _, sp := range res.Ports { if sp.Protocol == pbcatalog.Protocol_PROTOCOL_MESH { continue } if sp.MatchesPortId(dest.PortName) { dest.VirtualPort = sp.VirtualPort } } } } } } } // Explode this into the explicit list based on stray references made. c.Partitions = nil for ap, nsMap := range tenancies { p := &Partition{ Name: ap, } for ns := range nsMap { p.Namespaces = append(p.Namespaces, ns) } sort.Strings(p.Namespaces) c.Partitions = append(c.Partitions, p) } sort.Slice(c.Partitions, func(i, j int) bool { return c.Partitions[i].Name < c.Partitions[j].Name }) if !c.Enterprise { expect := []*Partition{{Name: "default", Namespaces: []string{"default"}}} if !reflect.DeepEqual(c.Partitions, expect) { return nil, fmt.Errorf("cluster %q references non-default partitions or namespaces but is CE", c.Name) } } } clusteredPeerings := make(map[string]map[string]*PeerCluster) // local-cluster -> local-peer -> info addPeerMapEntry := func(pc PeerCluster) { pm, ok := clusteredPeerings[pc.Name] if !ok { pm = make(map[string]*PeerCluster) clusteredPeerings[pc.Name] = pm } pm[pc.PeerName] = &pc } for _, p := range raw.Peerings { dialingCluster, ok := clusters[p.Dialing.Name] if !ok { return nil, fmt.Errorf("peering references a dialing cluster that does not exist: %s", p.Dialing.Name) } acceptingCluster, ok := clusters[p.Accepting.Name] if !ok { return nil, fmt.Errorf("peering references an accepting cluster that does not exist: %s", p.Accepting.Name) } if p.Dialing.Name == p.Accepting.Name { return nil, fmt.Errorf("self peerings are not allowed: %s", p.Dialing.Name) } p.Dialing.Partition = PartitionOrDefault(p.Dialing.Partition) p.Accepting.Partition = PartitionOrDefault(p.Accepting.Partition) if dialingCluster.Enterprise { if !dialingCluster.hasPartition(p.Dialing.Partition) { return nil, fmt.Errorf("dialing side of peering cannot reference a partition that does not exist: %s", p.Dialing.Partition) } } else { if p.Dialing.Partition != "default" { return nil, fmt.Errorf("dialing side of peering cannot reference a partition when CE") } } if acceptingCluster.Enterprise { if !acceptingCluster.hasPartition(p.Accepting.Partition) { return nil, fmt.Errorf("accepting side of peering cannot reference a partition that does not exist: %s", p.Accepting.Partition) } } else { if p.Accepting.Partition != "default" { return nil, fmt.Errorf("accepting side of peering cannot reference a partition when CE") } } if p.Dialing.PeerName == "" { p.Dialing.PeerName = "peer-" + p.Accepting.Name + "-" + p.Accepting.Partition } if p.Accepting.PeerName == "" { p.Accepting.PeerName = "peer-" + p.Dialing.Name + "-" + p.Dialing.Partition } { // Ensure the link fields do not have recursive links. p.Dialing.Link = nil p.Accepting.Link = nil // Copy the un-linked data before setting the link pa := p.Accepting pd := p.Dialing p.Accepting.Link = &pd p.Dialing.Link = &pa } addPeerMapEntry(p.Accepting) addPeerMapEntry(p.Dialing) delete(foundPeerNames[p.Accepting.Name], p.Accepting.PeerName) delete(foundPeerNames[p.Dialing.Name], p.Dialing.PeerName) } for cluster, peers := range foundPeerNames { if len(peers) > 0 { var pretty []string for name := range peers { pretty = append(pretty, name) } sort.Strings(pretty) return nil, fmt.Errorf("cluster[%s] found topology references to peerings that do not exist: %v", cluster, pretty) } } // after we decoded the peering stuff, we can fill in some computed data in the destinations for _, c := range clusters { c.Peerings = clusteredPeerings[c.Name] for _, n := range c.Nodes { for _, wrk := range n.Workloads { for _, dest := range wrk.Destinations { if dest.Peer == "" { dest.Cluster = c.Name dest.Peering = nil continue } remotePeer, ok := c.Peerings[dest.Peer] if !ok { return nil, fmt.Errorf("not possible") } dest.Cluster = remotePeer.Link.Name dest.Peering = remotePeer.Link // this helps in generating fortio assertions; otherwise field is ignored dest.ID.Partition = remotePeer.Link.Partition } for _, dest := range wrk.ImpliedDestinations { if dest.Peer == "" { dest.Cluster = c.Name dest.Peering = nil continue } remotePeer, ok := c.Peerings[dest.Peer] if !ok { return nil, fmt.Errorf("not possible") } dest.Cluster = remotePeer.Link.Name dest.Peering = remotePeer.Link // this helps in generating fortio assertions; otherwise field is ignored dest.ID.Partition = remotePeer.Link.Partition } } } } t := &Topology{ ID: id, Networks: networks, Clusters: clusters, Images: images, Peerings: raw.Peerings, NetworkAreas: raw.NetworkAreas, } if prev != nil { // networks cannot change if !sameKeys(prev.Networks, t.Networks) { return nil, fmt.Errorf("cannot create or destroy networks") } for _, newNetwork := range t.Networks { oldNetwork := prev.Networks[newNetwork.Name] // Carryover newNetwork.inheritFromExisting(oldNetwork) if err := isSame(oldNetwork, newNetwork); err != nil { return nil, fmt.Errorf("networks cannot change: %w", err) } } // cannot add or remove an entire cluster if !sameKeys(prev.Clusters, t.Clusters) { return nil, fmt.Errorf("cannot create or destroy clusters") } for _, newCluster := range t.Clusters { oldCluster := prev.Clusters[newCluster.Name] // Carryover newCluster.inheritFromExisting(oldCluster) if newCluster.Name != oldCluster.Name || newCluster.NetworkName != oldCluster.NetworkName || newCluster.Datacenter != oldCluster.Datacenter || newCluster.Enterprise != oldCluster.Enterprise { return nil, fmt.Errorf("cannot edit some cluster fields for %q", newCluster.Name) } // WARN on presence of some things. if len(newCluster.InitialConfigEntries) > 0 { logger.Warn("initial config entries were provided, but are skipped on recompile") } if len(newCluster.InitialResources) > 0 { logger.Warn("initial resources were provided, but are skipped on recompile") } // Check NODES if err := inheritAndValidateNodes(oldCluster.Nodes, newCluster.Nodes); err != nil { return nil, fmt.Errorf("some immutable aspects of nodes were changed in cluster %q: %w", newCluster.Name, err) } } } return t, nil } func assignVirtualIPs(c *Cluster) error { lastVIPIndex := 1 for _, svcData := range c.Services { lastVIPIndex++ if lastVIPIndex > 250 { return fmt.Errorf("too many ips using this approach to VIPs") } svcData.VirtualIps = []string{ fmt.Sprintf("10.244.0.%d", lastVIPIndex), } // populate virtual ports where we forgot them var ( usedPorts = make(map[uint32]struct{}) next = uint32(8080) ) for _, sp := range svcData.Ports { if sp.Protocol == pbcatalog.Protocol_PROTOCOL_MESH { continue } if sp.VirtualPort > 0 { usedPorts[sp.VirtualPort] = struct{}{} } } for _, sp := range svcData.Ports { if sp.Protocol == pbcatalog.Protocol_PROTOCOL_MESH { continue } if sp.VirtualPort > 0 { continue } RETRY: attempt := next next++ _, used := usedPorts[attempt] if used { goto RETRY } usedPorts[attempt] = struct{}{} sp.VirtualPort = attempt } } return nil } const permutedWarning = "use the disabled node kind if you want to ignore a node" func inheritAndValidateNodes( prev, curr []*Node, ) error { nodeMap := mapifyNodes(curr) for prevIdx, node := range prev { currNode, ok := nodeMap[node.ID()] if !ok { return fmt.Errorf("node %q has vanished; "+permutedWarning, node.ID()) } // Ensure it hasn't been permuted. if currNode.Pos != prevIdx { return fmt.Errorf( "node %q has been shuffled %d -> %d; "+permutedWarning, node.ID(), prevIdx, currNode.Pos, ) } if currNode.Node.Kind != node.Kind || currNode.Node.Version != node.Version || currNode.Node.Partition != node.Partition || currNode.Node.Name != node.Name || currNode.Node.Index != node.Index || len(currNode.Node.Addresses) != len(node.Addresses) || !sameKeys(currNode.Node.usedPorts, node.usedPorts) { return fmt.Errorf("cannot edit some node fields for %q", node.ID()) } currNode.Node.inheritFromExisting(node) for i := 0; i < len(currNode.Node.Addresses); i++ { prevAddr := node.Addresses[i] currAddr := currNode.Node.Addresses[i] if prevAddr.Network != currAddr.Network { return fmt.Errorf("addresses were shuffled for node %q", node.ID()) } if prevAddr.Type != currAddr.Type { return fmt.Errorf("cannot edit some address fields for %q", node.ID()) } currAddr.inheritFromExisting(prevAddr) } wrkMap := mapifyWorkloads(currNode.Node.Workloads) for _, wrk := range node.Workloads { currWrk, ok := wrkMap[wrk.ID] if !ok { continue // service has vanished, this is ok } // don't care about index permutation if currWrk.ID != wrk.ID || currWrk.Port != wrk.Port || !maps.Equal(currWrk.Ports, wrk.Ports) || currWrk.EnvoyAdminPort != wrk.EnvoyAdminPort || currWrk.EnvoyPublicListenerPort != wrk.EnvoyPublicListenerPort || isSame(currWrk.Command, wrk.Command) != nil || isSame(currWrk.Env, wrk.Env) != nil { return fmt.Errorf("cannot edit some address fields for %q", wrk.ID) } currWrk.inheritFromExisting(wrk) } } return nil } func newTopologyID() (string, error) { const n = 16 id := make([]byte, n) if _, err := crand.Read(id[:]); err != nil { return "", err } return hex.EncodeToString(id)[:n], nil } // matches valid DNS labels according to RFC 1123, should be at most 63 // characters according to the RFC var validLabel = regexp.MustCompile(`^[a-zA-Z0-9]([a-zA-Z0-9\-]{0,61}[a-zA-Z0-9])?$`) // IsValidLabel returns true if the string given is a valid DNS label (RFC 1123). // Note: the only difference between RFC 1035 and RFC 1123 labels is that in // RFC 1123 labels can begin with a number. func IsValidLabel(name string) bool { return validLabel.MatchString(name) } // ValidateLabel is similar to IsValidLabel except it returns an error // instead of false when name is not a valid DNS label. The error will contain // reference to what constitutes a valid DNS label. func ValidateLabel(name string) error { if !IsValidLabel(name) { return errors.New("a valid DNS label must consist of lower case alphanumeric characters or '-', and must start and end with an alphanumeric character") } return nil } func isSame(x, y any) error { diff := cmp.Diff(x, y) if diff != "" { return fmt.Errorf("values are not equal\n--- expected\n+++ actual\n%v", diff) } return nil } func sameKeys[K comparable, V any](x, y map[K]V) bool { if len(x) != len(y) { return false } for kx := range x { if _, ok := y[kx]; !ok { return false } } return true } func mapifyNodes(nodes []*Node) map[NodeID]nodeWithPosition { m := make(map[NodeID]nodeWithPosition) for i, node := range nodes { m[node.ID()] = nodeWithPosition{ Pos: i, Node: node, } } return m } type nodeWithPosition struct { Pos int Node *Node } func mapifyWorkloads(workloads []*Service) map[ID]*Service { m := make(map[ID]*Service) for _, wrk := range workloads { m[wrk.ID] = wrk } return m }