package consul import ( "fmt" "github.com/armon/gomdb" "github.com/hashicorp/consul/consul/structs" "io" "io/ioutil" "log" "os" "runtime" ) const ( dbNodes = "nodes" dbServices = "services" dbChecks = "checks" dbKVS = "kvs" dbMaxMapSize32bit uint64 = 512 * 1024 * 1024 // 512MB maximum size dbMaxMapSize64bit uint64 = 32 * 1024 * 1024 * 1024 // 32GB maximum size ) // The StateStore is responsible for maintaining all the Consul // state. It is manipulated by the FSM which maintains consistency // through the use of Raft. The goals of the StateStore are to provide // high concurrency for read operations without blocking writes, and // to provide write availability in the face of reads. The current // implementation uses the Lightning Memory-Mapped Database (MDB). // This gives us Multi-Version Concurrency Control for "free" type StateStore struct { logger *log.Logger path string env *mdb.Env nodeTable *MDBTable serviceTable *MDBTable checkTable *MDBTable kvsTable *MDBTable tables MDBTables watch map[*MDBTable]*NotifyGroup queryTables map[string]MDBTables } // StateSnapshot is used to provide a point-in-time snapshot // It works by starting a readonly transaction against all tables. type StateSnapshot struct { store *StateStore tx *MDBTxn lastIndex uint64 } // Close is used to abort the transaction and allow for cleanup func (s *StateSnapshot) Close() error { s.tx.Abort() return nil } // NewStateStore is used to create a new state store func NewStateStore(logOutput io.Writer) (*StateStore, error) { // Create a new temp dir path, err := ioutil.TempDir("", "consul") if err != nil { return nil, err } // Open the env env, err := mdb.NewEnv() if err != nil { return nil, err } s := &StateStore{ logger: log.New(logOutput, "", log.LstdFlags), path: path, env: env, watch: make(map[*MDBTable]*NotifyGroup), } // Ensure we can initialize if err := s.initialize(); err != nil { env.Close() os.RemoveAll(path) return nil, err } return s, nil } // Close is used to safely shutdown the state store func (s *StateStore) Close() error { s.env.Close() os.RemoveAll(s.path) return nil } // initialize is used to setup the store for use func (s *StateStore) initialize() error { // Setup the Env first if err := s.env.SetMaxDBs(mdb.DBI(32)); err != nil { return err } // Set the maximum db size based on 32/64bit. Since we are // doing an mmap underneath, we need to limit our use of virtual // address space on 32bit, but don't have to care on 64bit. dbSize := dbMaxMapSize32bit if runtime.GOARCH == "amd64" { dbSize = dbMaxMapSize64bit } // Increase the maximum map size if err := s.env.SetMapSize(dbSize); err != nil { return err } // Optimize our flags for speed over safety, since the Raft log + snapshots // are durable. We treat this as an ephemeral in-memory DB, since we nuke // the data anyways. var flags uint = mdb.NOMETASYNC | mdb.NOSYNC | mdb.NOTLS if err := s.env.Open(s.path, flags, 0755); err != nil { return err } // Tables use a generic struct encoder encoder := func(obj interface{}) []byte { buf, err := structs.Encode(255, obj) if err != nil { panic(err) } return buf[1:] } // Setup our tables s.nodeTable = &MDBTable{ Name: dbNodes, Indexes: map[string]*MDBIndex{ "id": &MDBIndex{ Unique: true, Fields: []string{"Node"}, }, }, Decoder: func(buf []byte) interface{} { out := new(structs.Node) if err := structs.Decode(buf, out); err != nil { panic(err) } return out }, } s.serviceTable = &MDBTable{ Name: dbServices, Indexes: map[string]*MDBIndex{ "id": &MDBIndex{ Unique: true, Fields: []string{"Node", "ServiceID"}, }, "service": &MDBIndex{ AllowBlank: true, Fields: []string{"ServiceName"}, }, }, Decoder: func(buf []byte) interface{} { out := new(structs.ServiceNode) if err := structs.Decode(buf, out); err != nil { panic(err) } return out }, } s.checkTable = &MDBTable{ Name: dbChecks, Indexes: map[string]*MDBIndex{ "id": &MDBIndex{ Unique: true, Fields: []string{"Node", "CheckID"}, }, "status": &MDBIndex{ Fields: []string{"Status"}, }, "service": &MDBIndex{ AllowBlank: true, Fields: []string{"ServiceName"}, }, "node": &MDBIndex{ AllowBlank: true, Fields: []string{"Node", "ServiceID"}, }, }, Decoder: func(buf []byte) interface{} { out := new(structs.HealthCheck) if err := structs.Decode(buf, out); err != nil { panic(err) } return out }, } s.kvsTable = &MDBTable{ Name: dbKVS, Indexes: map[string]*MDBIndex{ "id": &MDBIndex{ Unique: true, Fields: []string{"Key"}, }, "id_prefix": &MDBIndex{ Virtual: true, RealIndex: "id", Fields: []string{"Key"}, IdxFunc: DefaultIndexPrefixFunc, }, }, Decoder: func(buf []byte) interface{} { out := new(structs.DirEntry) if err := structs.Decode(buf, out); err != nil { panic(err) } return out }, } // Store the set of tables s.tables = []*MDBTable{s.nodeTable, s.serviceTable, s.checkTable, s.kvsTable} for _, table := range s.tables { table.Env = s.env table.Encoder = encoder if err := table.Init(); err != nil { return err } // Setup a notification group per table s.watch[table] = &NotifyGroup{} } // Setup the query tables s.queryTables = map[string]MDBTables{ "Nodes": MDBTables{s.nodeTable}, "Services": MDBTables{s.serviceTable}, "ServiceNodes": MDBTables{s.nodeTable, s.serviceTable}, "NodeServices": MDBTables{s.nodeTable, s.serviceTable}, "ChecksInState": MDBTables{s.checkTable}, "NodeChecks": MDBTables{s.checkTable}, "ServiceChecks": MDBTables{s.checkTable}, "CheckServiceNodes": MDBTables{s.nodeTable, s.serviceTable, s.checkTable}, "KVSGet": MDBTables{s.kvsTable}, "KVSList": MDBTables{s.kvsTable}, } return nil } // Watch is used to subscribe a channel to a set of MDBTables func (s *StateStore) Watch(tables MDBTables, notify chan struct{}) { for _, t := range tables { s.watch[t].Wait(notify) } } // QueryTables returns the Tables that are queried for a given query func (s *StateStore) QueryTables(q string) MDBTables { return s.queryTables[q] } // EnsureNode is used to ensure a given node exists, with the provided address func (s *StateStore) EnsureNode(index uint64, node structs.Node) error { // Start a new txn tx, err := s.nodeTable.StartTxn(false, nil) if err != nil { return err } defer tx.Abort() if err := s.nodeTable.InsertTxn(tx, node); err != nil { return err } if err := s.nodeTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.nodeTable].Notify() return tx.Commit() } // GetNode returns all the address of the known and if it was found func (s *StateStore) GetNode(name string) (uint64, bool, string) { idx, res, err := s.nodeTable.Get("id", name) if err != nil { s.logger.Printf("[ERR] consul.state: Error during node lookup: %v", err) return 0, false, "" } if len(res) == 0 { return idx, false, "" } return idx, true, res[0].(*structs.Node).Address } // GetNodes returns all the known nodes, the slice alternates between // the node name and address func (s *StateStore) Nodes() (uint64, structs.Nodes) { idx, res, err := s.nodeTable.Get("id") if err != nil { s.logger.Printf("[ERR] consul.state: Error getting nodes: %v", err) } results := make([]structs.Node, len(res)) for i, r := range res { results[i] = *r.(*structs.Node) } return idx, results } // EnsureService is used to ensure a given node exposes a service func (s *StateStore) EnsureService(index uint64, node string, ns *structs.NodeService) error { tables := MDBTables{s.nodeTable, s.serviceTable} tx, err := tables.StartTxn(false) if err != nil { panic(fmt.Errorf("Failed to start txn: %v", err)) } defer tx.Abort() // Ensure the node exists res, err := s.nodeTable.GetTxn(tx, "id", node) if err != nil { return err } if len(res) == 0 { return fmt.Errorf("Missing node registration") } // Create the entry entry := structs.ServiceNode{ Node: node, ServiceID: ns.ID, ServiceName: ns.Service, ServiceTags: ns.Tags, ServicePort: ns.Port, } // Ensure the service entry is set if err := s.serviceTable.InsertTxn(tx, &entry); err != nil { return err } if err := s.serviceTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.serviceTable].Notify() return tx.Commit() } // NodeServices is used to return all the services of a given node func (s *StateStore) NodeServices(name string) (uint64, *structs.NodeServices) { tables := s.queryTables["NodeServices"] tx, err := tables.StartTxn(true) if err != nil { panic(fmt.Errorf("Failed to start txn: %v", err)) } defer tx.Abort() return s.parseNodeServices(tables, tx, name) } // parseNodeServices is used to get the services belonging to a // node, using a given txn func (s *StateStore) parseNodeServices(tables MDBTables, tx *MDBTxn, name string) (uint64, *structs.NodeServices) { ns := &structs.NodeServices{ Services: make(map[string]*structs.NodeService), } // Get the maximum index index, err := tables.LastIndexTxn(tx) if err != nil { panic(fmt.Errorf("Failed to get last index: %v", err)) } // Get the node first res, err := s.nodeTable.GetTxn(tx, "id", name) if err != nil { s.logger.Printf("[ERR] consul.state: Failed to get node: %v", err) } if len(res) == 0 { return index, nil } // Set the address node := res[0].(*structs.Node) ns.Node = *node // Get the services res, err = s.serviceTable.GetTxn(tx, "id", name) if err != nil { s.logger.Printf("[ERR] consul.state: Failed to get node '%s' services: %v", name, err) } // Add each service for _, r := range res { service := r.(*structs.ServiceNode) srv := &structs.NodeService{ ID: service.ServiceID, Service: service.ServiceName, Tags: service.ServiceTags, Port: service.ServicePort, } ns.Services[srv.ID] = srv } return index, ns } // DeleteNodeService is used to delete a node service func (s *StateStore) DeleteNodeService(index uint64, node, id string) error { tables := MDBTables{s.serviceTable, s.checkTable} tx, err := tables.StartTxn(false) if err != nil { panic(fmt.Errorf("Failed to start txn: %v", err)) } defer tx.Abort() if n, err := s.serviceTable.DeleteTxn(tx, "id", node, id); err != nil { return err } else if n > 0 { if err := s.serviceTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.serviceTable].Notify() } if n, err := s.checkTable.DeleteTxn(tx, "node", node, id); err != nil { return err } else if n > 0 { if err := s.checkTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.checkTable].Notify() } return tx.Commit() } // DeleteNode is used to delete a node and all it's services func (s *StateStore) DeleteNode(index uint64, node string) error { tables := MDBTables{s.nodeTable, s.serviceTable, s.checkTable} tx, err := tables.StartTxn(false) if err != nil { panic(fmt.Errorf("Failed to start txn: %v", err)) } defer tx.Abort() if n, err := s.serviceTable.DeleteTxn(tx, "id", node); err != nil { return err } else if n > 0 { if err := s.serviceTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.serviceTable].Notify() } if n, err := s.checkTable.DeleteTxn(tx, "id", node); err != nil { return err } else if n > 0 { if err := s.checkTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.checkTable].Notify() } if n, err := s.nodeTable.DeleteTxn(tx, "id", node); err != nil { return err } else if n > 0 { if err := s.nodeTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.nodeTable].Notify() } return tx.Commit() } // Services is used to return all the services with a list of associated tags func (s *StateStore) Services() (uint64, map[string][]string) { services := make(map[string][]string) idx, res, err := s.serviceTable.Get("id") if err != nil { s.logger.Printf("[ERR] consul.state: Failed to get services: %v", err) return idx, services } for _, r := range res { srv := r.(*structs.ServiceNode) tags, ok := services[srv.ServiceName] if !ok { services[srv.ServiceName] = tags } for _, tag := range srv.ServiceTags { if !strContains(tags, tag) { tags = append(tags, tag) services[srv.ServiceName] = tags } } } return idx, services } // ServiceNodes returns the nodes associated with a given service func (s *StateStore) ServiceNodes(service string) (uint64, structs.ServiceNodes) { tables := s.queryTables["ServiceNodes"] tx, err := tables.StartTxn(true) if err != nil { panic(fmt.Errorf("Failed to start txn: %v", err)) } defer tx.Abort() idx, err := tables.LastIndexTxn(tx) if err != nil { panic(fmt.Errorf("Failed to get last index: %v", err)) } res, err := s.serviceTable.GetTxn(tx, "service", service) return idx, s.parseServiceNodes(tx, s.nodeTable, res, err) } // ServiceTagNodes returns the nodes associated with a given service matching a tag func (s *StateStore) ServiceTagNodes(service, tag string) (uint64, structs.ServiceNodes) { tables := s.queryTables["ServiceNodes"] tx, err := tables.StartTxn(true) if err != nil { panic(fmt.Errorf("Failed to start txn: %v", err)) } defer tx.Abort() idx, err := tables.LastIndexTxn(tx) if err != nil { panic(fmt.Errorf("Failed to get last index: %v", err)) } res, err := s.serviceTable.GetTxn(tx, "service", service) res = serviceTagFilter(res, tag) return idx, s.parseServiceNodes(tx, s.nodeTable, res, err) } // serviceTagFilter is used to filter a list of *structs.ServiceNode which do // not have the specified tag func serviceTagFilter(l []interface{}, tag string) []interface{} { n := len(l) for i := 0; i < n; i++ { srv := l[i].(*structs.ServiceNode) if !strContains(srv.ServiceTags, tag) { l[i], l[n-1] = l[n-1], nil i-- n-- } } return l[:n] } // parseServiceNodes parses results ServiceNodes and ServiceTagNodes func (s *StateStore) parseServiceNodes(tx *MDBTxn, table *MDBTable, res []interface{}, err error) structs.ServiceNodes { nodes := make(structs.ServiceNodes, len(res)) if err != nil { s.logger.Printf("[ERR] consul.state: Failed to get service nodes: %v", err) return nodes } for i, r := range res { srv := r.(*structs.ServiceNode) // Get the address of the node nodeRes, err := table.GetTxn(tx, "id", srv.Node) if err != nil || len(nodeRes) != 1 { s.logger.Printf("[ERR] consul.state: Failed to join service node %#v with node: %v", *srv, err) continue } srv.Address = nodeRes[0].(*structs.Node).Address nodes[i] = *srv } return nodes } // EnsureCheck is used to create a check or updates it's state func (s *StateStore) EnsureCheck(index uint64, check *structs.HealthCheck) error { // Ensure we have a status if check.Status == "" { check.Status = structs.HealthUnknown } // Start the txn tables := MDBTables{s.nodeTable, s.serviceTable, s.checkTable} tx, err := tables.StartTxn(false) if err != nil { panic(fmt.Errorf("Failed to start txn: %v", err)) } defer tx.Abort() // Ensure the node exists res, err := s.nodeTable.GetTxn(tx, "id", check.Node) if err != nil { return err } if len(res) == 0 { return fmt.Errorf("Missing node registration") } // Ensure the service exists if specified if check.ServiceID != "" { res, err = s.serviceTable.GetTxn(tx, "id", check.Node, check.ServiceID) if err != nil { return err } if len(res) == 0 { return fmt.Errorf("Missing service registration") } // Ensure we set the correct service srv := res[0].(*structs.ServiceNode) check.ServiceName = srv.ServiceName } // Ensure the check is set if err := s.checkTable.InsertTxn(tx, check); err != nil { return err } if err := s.checkTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.checkTable].Notify() return tx.Commit() } // DeleteNodeCheck is used to delete a node health check func (s *StateStore) DeleteNodeCheck(index uint64, node, id string) error { tx, err := s.checkTable.StartTxn(false, nil) if err != nil { return err } defer tx.Abort() if n, err := s.checkTable.DeleteTxn(tx, "id", node, id); err != nil { return err } else if n > 0 { if err := s.checkTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.checkTable].Notify() } return tx.Commit() } // NodeChecks is used to get all the checks for a node func (s *StateStore) NodeChecks(node string) (uint64, structs.HealthChecks) { return s.parseHealthChecks(s.checkTable.Get("id", node)) } // ServiceChecks is used to get all the checks for a service func (s *StateStore) ServiceChecks(service string) (uint64, structs.HealthChecks) { return s.parseHealthChecks(s.checkTable.Get("service", service)) } // CheckInState is used to get all the checks for a service in a given state func (s *StateStore) ChecksInState(state string) (uint64, structs.HealthChecks) { return s.parseHealthChecks(s.checkTable.Get("status", state)) } // parseHealthChecks is used to handle the resutls of a Get against // the checkTable func (s *StateStore) parseHealthChecks(idx uint64, res []interface{}, err error) (uint64, structs.HealthChecks) { results := make([]*structs.HealthCheck, len(res)) if err != nil { s.logger.Printf("[ERR] consul.state: Failed to get health checks: %v", err) return idx, results } for i, r := range res { results[i] = r.(*structs.HealthCheck) } return idx, results } // CheckServiceNodes returns the nodes associated with a given service, along // with any associated check func (s *StateStore) CheckServiceNodes(service string) (uint64, structs.CheckServiceNodes) { tables := s.queryTables["CheckServiceNodes"] tx, err := tables.StartTxn(true) if err != nil { panic(fmt.Errorf("Failed to start txn: %v", err)) } defer tx.Abort() idx, err := tables.LastIndexTxn(tx) if err != nil { panic(fmt.Errorf("Failed to get last index: %v", err)) } res, err := s.serviceTable.GetTxn(tx, "service", service) return idx, s.parseCheckServiceNodes(tx, res, err) } // CheckServiceNodes returns the nodes associated with a given service, along // with any associated checks func (s *StateStore) CheckServiceTagNodes(service, tag string) (uint64, structs.CheckServiceNodes) { tables := s.queryTables["CheckServiceNodes"] tx, err := tables.StartTxn(true) if err != nil { panic(fmt.Errorf("Failed to start txn: %v", err)) } defer tx.Abort() idx, err := tables.LastIndexTxn(tx) if err != nil { panic(fmt.Errorf("Failed to get last index: %v", err)) } res, err := s.serviceTable.GetTxn(tx, "service", service) res = serviceTagFilter(res, tag) return idx, s.parseCheckServiceNodes(tx, res, err) } // parseCheckServiceNodes parses results CheckServiceNodes and CheckServiceTagNodes func (s *StateStore) parseCheckServiceNodes(tx *MDBTxn, res []interface{}, err error) structs.CheckServiceNodes { nodes := make(structs.CheckServiceNodes, len(res)) if err != nil { s.logger.Printf("[ERR] consul.state: Failed to get service nodes: %v", err) return nodes } for i, r := range res { srv := r.(*structs.ServiceNode) // Get the node nodeRes, err := s.nodeTable.GetTxn(tx, "id", srv.Node) if err != nil || len(nodeRes) != 1 { s.logger.Printf("[ERR] consul.state: Failed to join service node %#v with node: %v", *srv, err) continue } // Get any associated checks of the service res, err := s.checkTable.GetTxn(tx, "node", srv.Node, srv.ServiceID) _, checks := s.parseHealthChecks(0, res, err) // Get any checks of the node, not assciated with any service res, err = s.checkTable.GetTxn(tx, "node", srv.Node, "") _, nodeChecks := s.parseHealthChecks(0, res, err) checks = append(checks, nodeChecks...) // Setup the node nodes[i].Node = *nodeRes[0].(*structs.Node) nodes[i].Service = structs.NodeService{ ID: srv.ServiceID, Service: srv.ServiceName, Tags: srv.ServiceTags, Port: srv.ServicePort, } nodes[i].Checks = checks } return nodes } // KVSSet is used to create or update a KV entry func (s *StateStore) KVSSet(index uint64, d *structs.DirEntry) error { // Start a new txn tx, err := s.kvsTable.StartTxn(false, nil) if err != nil { return err } defer tx.Abort() // Get the existing node res, err := s.kvsTable.GetTxn(tx, "id", d.Key) if err != nil { return err } // Set the create and modify times if len(res) == 0 { d.CreateIndex = index } else { d.CreateIndex = res[0].(*structs.DirEntry).CreateIndex } d.ModifyIndex = index if err := s.kvsTable.InsertTxn(tx, d); err != nil { return err } if err := s.kvsTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.kvsTable].Notify() return tx.Commit() } // KVSRestore is used to restore a DirEntry. It should only be used when // doing a restore, otherwise KVSSet should be used. func (s *StateStore) KVSRestore(d *structs.DirEntry) error { // Start a new txn tx, err := s.kvsTable.StartTxn(false, nil) if err != nil { return err } defer tx.Abort() if err := s.kvsTable.InsertTxn(tx, d); err != nil { return err } return tx.Commit() } // KVSGet is used to get a KV entry func (s *StateStore) KVSGet(key string) (uint64, *structs.DirEntry, error) { idx, res, err := s.kvsTable.Get("id", key) var d *structs.DirEntry if len(res) > 0 { d = res[0].(*structs.DirEntry) } return idx, d, err } // KVSList is used to list all KV entries with a prefix func (s *StateStore) KVSList(prefix string) (uint64, structs.DirEntries, error) { idx, res, err := s.kvsTable.Get("id_prefix", prefix) ents := make(structs.DirEntries, len(res)) for idx, r := range res { ents[idx] = r.(*structs.DirEntry) } return idx, ents, err } // KVSDelete is used to delete a KVS entry func (s *StateStore) KVSDelete(index uint64, key string) error { return s.kvsDeleteWithIndex(index, "id", key) } // KVSDeleteTree is used to delete all keys with a given prefix func (s *StateStore) KVSDeleteTree(index uint64, prefix string) error { if prefix == "" { return s.kvsDeleteWithIndex(index, "id") } return s.kvsDeleteWithIndex(index, "id_prefix", prefix) } // kvsDeleteWithIndex does a delete with either the id or id_prefix func (s *StateStore) kvsDeleteWithIndex(index uint64, tableIndex string, parts ...string) error { // Start a new txn tx, err := s.kvsTable.StartTxn(false, nil) if err != nil { return err } defer tx.Abort() num, err := s.kvsTable.DeleteTxn(tx, tableIndex, parts...) if err != nil { return err } if num > 0 { if err := s.kvsTable.SetLastIndexTxn(tx, index); err != nil { return err } defer s.watch[s.kvsTable].Notify() } return tx.Commit() } // KVSCheckAndSet is used to perform an atomic check-and-set func (s *StateStore) KVSCheckAndSet(index uint64, d *structs.DirEntry) (bool, error) { // Start a new txn tx, err := s.kvsTable.StartTxn(false, nil) if err != nil { return false, err } defer tx.Abort() // Get the existing node res, err := s.kvsTable.GetTxn(tx, "id", d.Key) if err != nil { return false, err } // Get the existing node if any var exist *structs.DirEntry if len(res) > 0 { exist = res[0].(*structs.DirEntry) } // Use the ModifyIndex as the constraint. A modify of time of 0 // means we are doing a set-if-not-exists, while any other value // means we expect that modify time. if d.ModifyIndex == 0 && exist != nil { return false, nil } else if d.ModifyIndex > 0 && (exist == nil || exist.ModifyIndex != d.ModifyIndex) { return false, nil } // Set the create and modify times if exist == nil { d.CreateIndex = index } else { d.CreateIndex = exist.CreateIndex } d.ModifyIndex = index if err := s.kvsTable.InsertTxn(tx, d); err != nil { return false, err } if err := s.kvsTable.SetLastIndexTxn(tx, index); err != nil { return false, err } defer s.watch[s.kvsTable].Notify() return true, tx.Commit() } // Snapshot is used to create a point in time snapshot func (s *StateStore) Snapshot() (*StateSnapshot, error) { // Begin a new txn on all tables tx, err := s.tables.StartTxn(true) if err != nil { return nil, err } // Determine the max index index, err := s.tables.LastIndexTxn(tx) if err != nil { tx.Abort() return nil, err } // Return the snapshot snap := &StateSnapshot{ store: s, tx: tx, lastIndex: index, } return snap, nil } // LastIndex returns the last index that affects the snapshotted data func (s *StateSnapshot) LastIndex() uint64 { return s.lastIndex } // Nodes returns all the known nodes, the slice alternates between // the node name and address func (s *StateSnapshot) Nodes() structs.Nodes { res, err := s.store.nodeTable.GetTxn(s.tx, "id") if err != nil { s.store.logger.Printf("[ERR] consul.state: Failed to get nodes: %v", err) return nil } results := make([]structs.Node, len(res)) for i, r := range res { results[i] = *r.(*structs.Node) } return results } // NodeServices is used to return all the services of a given node func (s *StateSnapshot) NodeServices(name string) *structs.NodeServices { _, res := s.store.parseNodeServices(s.store.tables, s.tx, name) return res } // NodeChecks is used to return all the checks of a given node func (s *StateSnapshot) NodeChecks(node string) structs.HealthChecks { res, err := s.store.checkTable.GetTxn(s.tx, "id", node) _, checks := s.store.parseHealthChecks(s.lastIndex, res, err) return checks } // KVSDump is used to list all KV entries. It takes a channel and streams // back *struct.DirEntry objects. This will block and should be invoked // in a goroutine. func (s *StateSnapshot) KVSDump(stream chan<- interface{}) error { return s.store.kvsTable.StreamTxn(stream, s.tx, "id") }