// Copyright 2020 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . package nodestate import ( "errors" "reflect" "sync" "time" "unsafe" "github.com/ethereum/go-ethereum/common/mclock" "github.com/ethereum/go-ethereum/ethdb" "github.com/ethereum/go-ethereum/log" "github.com/ethereum/go-ethereum/metrics" "github.com/ethereum/go-ethereum/p2p/enode" "github.com/ethereum/go-ethereum/p2p/enr" "github.com/ethereum/go-ethereum/rlp" ) var ( ErrInvalidField = errors.New("invalid field type") ErrClosed = errors.New("already closed") ) type ( // NodeStateMachine implements a network node-related event subscription system. // It can assign binary state flags and fields of arbitrary type to each node and allows // subscriptions to flag/field changes which can also modify further flags and fields, // potentially triggering further subscriptions. An operation includes an initial change // and all resulting subsequent changes and always ends in a consistent global state. // It is initiated by a "top level" SetState/SetField call that blocks (also blocking other // top-level functions) until the operation is finished. Callbacks making further changes // should use the non-blocking SetStateSub/SetFieldSub functions. The tree of events // resulting from the initial changes is traversed in a breadth-first order, ensuring for // each subscription callback that all other callbacks caused by the same change triggering // the current callback are processed before anything is triggered by the changes made in the // current callback. In practice this logic ensures that all subscriptions "see" events in // the logical order, callbacks are never called concurrently and "back and forth" effects // are also possible. The state machine design should ensure that infinite event cycles // cannot happen. // The caller can also add timeouts assigned to a certain node and a subset of state flags. // If the timeout elapses, the flags are reset. If all relevant flags are reset then the timer // is dropped. State flags with no timeout are persisted in the database if the flag // descriptor enables saving. If a node has no state flags set at any moment then it is discarded. // Note: in order to avoid mutex deadlocks the callbacks should never lock a mutex that // might be locked when the top level SetState/SetField functions are called. If a function // potentially performs state/field changes then it is recommended to mention this fact in the // function description, along with whether it should run inside an operation callback. NodeStateMachine struct { started, closed bool lock sync.Mutex clock mclock.Clock db ethdb.KeyValueStore dbNodeKey []byte nodes map[enode.ID]*nodeInfo offlineCallbackList []offlineCallback opFlag bool // an operation has started opWait *sync.Cond // signaled when the operation ends opPending []func() // pending callback list of the current operation // Registered state flags or fields. Modifications are allowed // only when the node state machine has not been started. setup *Setup fields []*fieldInfo saveFlags bitMask // Installed callbacks. Modifications are allowed only when the // node state machine has not been started. stateSubs []stateSub // Testing hooks, only for testing purposes. saveNodeHook func(*nodeInfo) } // Flags represents a set of flags from a certain setup Flags struct { mask bitMask setup *Setup } // Field represents a field from a certain setup Field struct { index int setup *Setup } // flagDefinition describes a node state flag. Each registered instance is automatically // mapped to a bit of the 64 bit node states. // If persistent is true then the node is saved when state machine is shutdown. flagDefinition struct { name string persistent bool } // fieldDefinition describes an optional node field of the given type. The contents // of the field are only retained for each node as long as at least one of the // state flags is set. fieldDefinition struct { name string ftype reflect.Type encode func(interface{}) ([]byte, error) decode func([]byte) (interface{}, error) } // stateSetup contains the list of flags and fields used by the application Setup struct { Version uint flags []flagDefinition fields []fieldDefinition } // bitMask describes a node state or state mask. It represents a subset // of node flags with each bit assigned to a flag index (LSB represents flag 0). bitMask uint64 // StateCallback is a subscription callback which is called when one of the // state flags that is included in the subscription state mask is changed. // Note: oldState and newState are also masked with the subscription mask so only // the relevant bits are included. StateCallback func(n *enode.Node, oldState, newState Flags) // FieldCallback is a subscription callback which is called when the value of // a specific field is changed. FieldCallback func(n *enode.Node, state Flags, oldValue, newValue interface{}) // nodeInfo contains node state, fields and state timeouts nodeInfo struct { node *enode.Node state bitMask timeouts []*nodeStateTimeout fields []interface{} fieldCount int db, dirty bool } nodeInfoEnc struct { Enr enr.Record Version uint State bitMask Fields [][]byte } stateSub struct { mask bitMask callback StateCallback } nodeStateTimeout struct { mask bitMask timer mclock.Timer } fieldInfo struct { fieldDefinition subs []FieldCallback } offlineCallback struct { node *nodeInfo state bitMask fields []interface{} } ) // offlineState is a special state that is assumed to be set before a node is loaded from // the database and after it is shut down. const offlineState = bitMask(1) // NewFlag creates a new node state flag func (s *Setup) NewFlag(name string) Flags { if s.flags == nil { s.flags = []flagDefinition{{name: "offline"}} } f := Flags{mask: bitMask(1) << uint(len(s.flags)), setup: s} s.flags = append(s.flags, flagDefinition{name: name}) return f } // NewPersistentFlag creates a new persistent node state flag func (s *Setup) NewPersistentFlag(name string) Flags { if s.flags == nil { s.flags = []flagDefinition{{name: "offline"}} } f := Flags{mask: bitMask(1) << uint(len(s.flags)), setup: s} s.flags = append(s.flags, flagDefinition{name: name, persistent: true}) return f } // OfflineFlag returns the system-defined offline flag belonging to the given setup func (s *Setup) OfflineFlag() Flags { return Flags{mask: offlineState, setup: s} } // NewField creates a new node state field func (s *Setup) NewField(name string, ftype reflect.Type) Field { f := Field{index: len(s.fields), setup: s} s.fields = append(s.fields, fieldDefinition{ name: name, ftype: ftype, }) return f } // NewPersistentField creates a new persistent node field func (s *Setup) NewPersistentField(name string, ftype reflect.Type, encode func(interface{}) ([]byte, error), decode func([]byte) (interface{}, error)) Field { f := Field{index: len(s.fields), setup: s} s.fields = append(s.fields, fieldDefinition{ name: name, ftype: ftype, encode: encode, decode: decode, }) return f } // flagOp implements binary flag operations and also checks whether the operands belong to the same setup func flagOp(a, b Flags, trueIfA, trueIfB, trueIfBoth bool) Flags { if a.setup == nil { if a.mask != 0 { panic("Node state flags have no setup reference") } a.setup = b.setup } if b.setup == nil { if b.mask != 0 { panic("Node state flags have no setup reference") } b.setup = a.setup } if a.setup != b.setup { panic("Node state flags belong to a different setup") } res := Flags{setup: a.setup} if trueIfA { res.mask |= a.mask & ^b.mask } if trueIfB { res.mask |= b.mask & ^a.mask } if trueIfBoth { res.mask |= a.mask & b.mask } return res } // And returns the set of flags present in both a and b func (a Flags) And(b Flags) Flags { return flagOp(a, b, false, false, true) } // AndNot returns the set of flags present in a but not in b func (a Flags) AndNot(b Flags) Flags { return flagOp(a, b, true, false, false) } // Or returns the set of flags present in either a or b func (a Flags) Or(b Flags) Flags { return flagOp(a, b, true, true, true) } // Xor returns the set of flags present in either a or b but not both func (a Flags) Xor(b Flags) Flags { return flagOp(a, b, true, true, false) } // HasAll returns true if b is a subset of a func (a Flags) HasAll(b Flags) bool { return flagOp(a, b, false, true, false).mask == 0 } // HasNone returns true if a and b have no shared flags func (a Flags) HasNone(b Flags) bool { return flagOp(a, b, false, false, true).mask == 0 } // Equals returns true if a and b have the same flags set func (a Flags) Equals(b Flags) bool { return flagOp(a, b, true, true, false).mask == 0 } // IsEmpty returns true if a has no flags set func (a Flags) IsEmpty() bool { return a.mask == 0 } // MergeFlags merges multiple sets of state flags func MergeFlags(list ...Flags) Flags { if len(list) == 0 { return Flags{} } res := list[0] for i := 1; i < len(list); i++ { res = res.Or(list[i]) } return res } // String returns a list of the names of the flags specified in the bit mask func (f Flags) String() string { if f.mask == 0 { return "[]" } s := "[" comma := false for index, flag := range f.setup.flags { if f.mask&(bitMask(1)< 8*int(unsafe.Sizeof(bitMask(0))) { panic("Too many node state flags") } ns := &NodeStateMachine{ db: db, dbNodeKey: dbKey, clock: clock, setup: setup, nodes: make(map[enode.ID]*nodeInfo), fields: make([]*fieldInfo, len(setup.fields)), } ns.opWait = sync.NewCond(&ns.lock) stateNameMap := make(map[string]int) for index, flag := range setup.flags { if _, ok := stateNameMap[flag.name]; ok { panic("Node state flag name collision: " + flag.name) } stateNameMap[flag.name] = index if flag.persistent { ns.saveFlags |= bitMask(1) << uint(index) } } fieldNameMap := make(map[string]int) for index, field := range setup.fields { if _, ok := fieldNameMap[field.name]; ok { panic("Node field name collision: " + field.name) } ns.fields[index] = &fieldInfo{fieldDefinition: field} fieldNameMap[field.name] = index } return ns } // stateMask checks whether the set of flags belongs to the same setup and returns its internal bit mask func (ns *NodeStateMachine) stateMask(flags Flags) bitMask { if flags.setup != ns.setup && flags.mask != 0 { panic("Node state flags belong to a different setup") } return flags.mask } // fieldIndex checks whether the field belongs to the same setup and returns its internal index func (ns *NodeStateMachine) fieldIndex(field Field) int { if field.setup != ns.setup { panic("Node field belongs to a different setup") } return field.index } // SubscribeState adds a node state subscription. The callback is called while the state // machine mutex is not held and it is allowed to make further state updates using the // non-blocking SetStateSub/SetFieldSub functions. All callbacks of an operation are running // from the thread/goroutine of the initial caller and parallel operations are not permitted. // Therefore the callback is never called concurrently. It is the responsibility of the // implemented state logic to avoid deadlocks and to reach a stable state in a finite amount // of steps. // State subscriptions should be installed before loading the node database or making the // first state update. func (ns *NodeStateMachine) SubscribeState(flags Flags, callback StateCallback) { ns.lock.Lock() defer ns.lock.Unlock() if ns.started { panic("state machine already started") } ns.stateSubs = append(ns.stateSubs, stateSub{ns.stateMask(flags), callback}) } // SubscribeField adds a node field subscription. Same rules apply as for SubscribeState. func (ns *NodeStateMachine) SubscribeField(field Field, callback FieldCallback) { ns.lock.Lock() defer ns.lock.Unlock() if ns.started { panic("state machine already started") } f := ns.fields[ns.fieldIndex(field)] f.subs = append(f.subs, callback) } // newNode creates a new nodeInfo func (ns *NodeStateMachine) newNode(n *enode.Node) *nodeInfo { return &nodeInfo{node: n, fields: make([]interface{}, len(ns.fields))} } // checkStarted checks whether the state machine has already been started and panics otherwise. func (ns *NodeStateMachine) checkStarted() { if !ns.started { panic("state machine not started yet") } } // Start starts the state machine, enabling state and field operations and disabling // further subscriptions. func (ns *NodeStateMachine) Start() { ns.lock.Lock() if ns.started { panic("state machine already started") } ns.started = true if ns.db != nil { ns.loadFromDb() } ns.opStart() ns.offlineCallbacks(true) ns.opFinish() ns.lock.Unlock() } // Stop stops the state machine and saves its state if a database was supplied func (ns *NodeStateMachine) Stop() { ns.lock.Lock() defer ns.lock.Unlock() ns.checkStarted() if !ns.opStart() { panic("already closed") } for _, node := range ns.nodes { fields := make([]interface{}, len(node.fields)) copy(fields, node.fields) ns.offlineCallbackList = append(ns.offlineCallbackList, offlineCallback{node, node.state, fields}) } if ns.db != nil { ns.saveToDb() } ns.offlineCallbacks(false) ns.closed = true ns.opFinish() } // loadFromDb loads persisted node states from the database func (ns *NodeStateMachine) loadFromDb() { it := ns.db.NewIterator(ns.dbNodeKey, nil) for it.Next() { var id enode.ID if len(it.Key()) != len(ns.dbNodeKey)+len(id) { log.Error("Node state db entry with invalid length", "found", len(it.Key()), "expected", len(ns.dbNodeKey)+len(id)) continue } copy(id[:], it.Key()[len(ns.dbNodeKey):]) ns.decodeNode(id, it.Value()) } } type dummyIdentity enode.ID func (id dummyIdentity) Verify(r *enr.Record, sig []byte) error { return nil } func (id dummyIdentity) NodeAddr(r *enr.Record) []byte { return id[:] } // decodeNode decodes a node database entry and adds it to the node set if successful func (ns *NodeStateMachine) decodeNode(id enode.ID, data []byte) { var enc nodeInfoEnc if err := rlp.DecodeBytes(data, &enc); err != nil { log.Error("Failed to decode node info", "id", id, "error", err) return } n, _ := enode.New(dummyIdentity(id), &enc.Enr) node := ns.newNode(n) node.db = true if enc.Version != ns.setup.Version { log.Debug("Removing stored node with unknown version", "current", ns.setup.Version, "stored", enc.Version) ns.deleteNode(id) return } if len(enc.Fields) > len(ns.setup.fields) { log.Error("Invalid node field count", "id", id, "stored", len(enc.Fields)) return } // Resolve persisted node fields for i, encField := range enc.Fields { if len(encField) == 0 { continue } if decode := ns.fields[i].decode; decode != nil { if field, err := decode(encField); err == nil { node.fields[i] = field node.fieldCount++ } else { log.Error("Failed to decode node field", "id", id, "field name", ns.fields[i].name, "error", err) return } } else { log.Error("Cannot decode node field", "id", id, "field name", ns.fields[i].name) return } } // It's a compatible node record, add it to set. ns.nodes[id] = node node.state = enc.State fields := make([]interface{}, len(node.fields)) copy(fields, node.fields) ns.offlineCallbackList = append(ns.offlineCallbackList, offlineCallback{node, node.state, fields}) log.Debug("Loaded node state", "id", id, "state", Flags{mask: enc.State, setup: ns.setup}) } // saveNode saves the given node info to the database func (ns *NodeStateMachine) saveNode(id enode.ID, node *nodeInfo) error { if ns.db == nil { return nil } storedState := node.state & ns.saveFlags for _, t := range node.timeouts { storedState &= ^t.mask } enc := nodeInfoEnc{ Enr: *node.node.Record(), Version: ns.setup.Version, State: storedState, Fields: make([][]byte, len(ns.fields)), } log.Debug("Saved node state", "id", id, "state", Flags{mask: enc.State, setup: ns.setup}) lastIndex := -1 for i, f := range node.fields { if f == nil { continue } encode := ns.fields[i].encode if encode == nil { continue } blob, err := encode(f) if err != nil { return err } enc.Fields[i] = blob lastIndex = i } if storedState == 0 && lastIndex == -1 { if node.db { node.db = false ns.deleteNode(id) } node.dirty = false return nil } enc.Fields = enc.Fields[:lastIndex+1] data, err := rlp.EncodeToBytes(&enc) if err != nil { return err } if err := ns.db.Put(append(ns.dbNodeKey, id[:]...), data); err != nil { return err } node.dirty, node.db = false, true if ns.saveNodeHook != nil { ns.saveNodeHook(node) } return nil } // deleteNode removes a node info from the database func (ns *NodeStateMachine) deleteNode(id enode.ID) { ns.db.Delete(append(ns.dbNodeKey, id[:]...)) } // saveToDb saves the persistent flags and fields of all nodes that have been changed func (ns *NodeStateMachine) saveToDb() { for id, node := range ns.nodes { if node.dirty { err := ns.saveNode(id, node) if err != nil { log.Error("Failed to save node", "id", id, "error", err) } } } } // updateEnode updates the enode entry belonging to the given node if it already exists func (ns *NodeStateMachine) updateEnode(n *enode.Node) (enode.ID, *nodeInfo) { id := n.ID() node := ns.nodes[id] if node != nil && n.Seq() > node.node.Seq() { node.node = n } return id, node } // Persist saves the persistent state and fields of the given node immediately func (ns *NodeStateMachine) Persist(n *enode.Node) error { ns.lock.Lock() defer ns.lock.Unlock() ns.checkStarted() if id, node := ns.updateEnode(n); node != nil && node.dirty { err := ns.saveNode(id, node) if err != nil { log.Error("Failed to save node", "id", id, "error", err) } return err } return nil } // SetState updates the given node state flags and blocks until the operation is finished. // If a flag with a timeout is set again, the operation removes or replaces the existing timeout. func (ns *NodeStateMachine) SetState(n *enode.Node, setFlags, resetFlags Flags, timeout time.Duration) error { ns.lock.Lock() defer ns.lock.Unlock() if !ns.opStart() { return ErrClosed } ns.setState(n, setFlags, resetFlags, timeout) ns.opFinish() return nil } // SetStateSub updates the given node state flags without blocking (should be called // from a subscription/operation callback). func (ns *NodeStateMachine) SetStateSub(n *enode.Node, setFlags, resetFlags Flags, timeout time.Duration) { ns.lock.Lock() defer ns.lock.Unlock() ns.opCheck() ns.setState(n, setFlags, resetFlags, timeout) } func (ns *NodeStateMachine) setState(n *enode.Node, setFlags, resetFlags Flags, timeout time.Duration) { ns.checkStarted() set, reset := ns.stateMask(setFlags), ns.stateMask(resetFlags) id, node := ns.updateEnode(n) if node == nil { if set == 0 { return } node = ns.newNode(n) ns.nodes[id] = node } oldState := node.state newState := (node.state & (^reset)) | set changed := oldState ^ newState node.state = newState // Remove the timeout callbacks for all reset and set flags, // even they are not existent(it's noop). ns.removeTimeouts(node, set|reset) // Register the timeout callback if required if timeout != 0 && set != 0 { ns.addTimeout(n, set, timeout) } if newState == oldState { return } if newState == 0 && node.fieldCount == 0 { delete(ns.nodes, id) if node.db { ns.deleteNode(id) } } else { if changed&ns.saveFlags != 0 { node.dirty = true } } callback := func() { for _, sub := range ns.stateSubs { if changed&sub.mask != 0 { sub.callback(n, Flags{mask: oldState & sub.mask, setup: ns.setup}, Flags{mask: newState & sub.mask, setup: ns.setup}) } } } ns.opPending = append(ns.opPending, callback) } // opCheck checks whether an operation is active func (ns *NodeStateMachine) opCheck() { if !ns.opFlag { panic("Operation has not started") } } // opStart waits until other operations are finished and starts a new one func (ns *NodeStateMachine) opStart() bool { for ns.opFlag { ns.opWait.Wait() } if ns.closed { return false } ns.opFlag = true return true } // opFinish finishes the current operation by running all pending callbacks. // Callbacks resulting from a state/field change performed in a previous callback are always // put at the end of the pending list and therefore processed after all callbacks resulting // from the previous state/field change. func (ns *NodeStateMachine) opFinish() { for len(ns.opPending) != 0 { list := ns.opPending ns.lock.Unlock() for _, cb := range list { cb() } ns.lock.Lock() ns.opPending = ns.opPending[len(list):] } ns.opPending = nil ns.opFlag = false ns.opWait.Broadcast() } // Operation calls the given function as an operation callback. This allows the caller // to start an operation with multiple initial changes. The same rules apply as for // subscription callbacks. func (ns *NodeStateMachine) Operation(fn func()) error { ns.lock.Lock() started := ns.opStart() ns.lock.Unlock() if !started { return ErrClosed } fn() ns.lock.Lock() ns.opFinish() ns.lock.Unlock() return nil } // offlineCallbacks calls state update callbacks at startup or shutdown func (ns *NodeStateMachine) offlineCallbacks(start bool) { for _, cb := range ns.offlineCallbackList { cb := cb callback := func() { for _, sub := range ns.stateSubs { offState := offlineState & sub.mask onState := cb.state & sub.mask if offState == onState { continue } if start { sub.callback(cb.node.node, Flags{mask: offState, setup: ns.setup}, Flags{mask: onState, setup: ns.setup}) } else { sub.callback(cb.node.node, Flags{mask: onState, setup: ns.setup}, Flags{mask: offState, setup: ns.setup}) } } for i, f := range cb.fields { if f == nil || ns.fields[i].subs == nil { continue } for _, fsub := range ns.fields[i].subs { if start { fsub(cb.node.node, Flags{mask: offlineState, setup: ns.setup}, nil, f) } else { fsub(cb.node.node, Flags{mask: offlineState, setup: ns.setup}, f, nil) } } } } ns.opPending = append(ns.opPending, callback) } ns.offlineCallbackList = nil } // AddTimeout adds a node state timeout associated to the given state flag(s). // After the specified time interval, the relevant states will be reset. func (ns *NodeStateMachine) AddTimeout(n *enode.Node, flags Flags, timeout time.Duration) error { ns.lock.Lock() defer ns.lock.Unlock() ns.checkStarted() if ns.closed { return ErrClosed } ns.addTimeout(n, ns.stateMask(flags), timeout) return nil } // addTimeout adds a node state timeout associated to the given state flag(s). func (ns *NodeStateMachine) addTimeout(n *enode.Node, mask bitMask, timeout time.Duration) { _, node := ns.updateEnode(n) if node == nil { return } mask &= node.state if mask == 0 { return } ns.removeTimeouts(node, mask) t := &nodeStateTimeout{mask: mask} t.timer = ns.clock.AfterFunc(timeout, func() { ns.SetState(n, Flags{}, Flags{mask: t.mask, setup: ns.setup}, 0) }) node.timeouts = append(node.timeouts, t) if mask&ns.saveFlags != 0 { node.dirty = true } } // removeTimeout removes node state timeouts associated to the given state flag(s). // If a timeout was associated to multiple flags which are not all included in the // specified remove mask then only the included flags are de-associated and the timer // stays active. func (ns *NodeStateMachine) removeTimeouts(node *nodeInfo, mask bitMask) { for i := 0; i < len(node.timeouts); i++ { t := node.timeouts[i] match := t.mask & mask if match == 0 { continue } t.mask -= match if t.mask != 0 { continue } t.timer.Stop() node.timeouts[i] = node.timeouts[len(node.timeouts)-1] node.timeouts = node.timeouts[:len(node.timeouts)-1] i-- if match&ns.saveFlags != 0 { node.dirty = true } } } // GetField retrieves the given field of the given node. Note that when used in a // subscription callback the result can be out of sync with the state change represented // by the callback parameters so extra safety checks might be necessary. func (ns *NodeStateMachine) GetField(n *enode.Node, field Field) interface{} { ns.lock.Lock() defer ns.lock.Unlock() ns.checkStarted() if ns.closed { return nil } if _, node := ns.updateEnode(n); node != nil { return node.fields[ns.fieldIndex(field)] } return nil } // SetField sets the given field of the given node and blocks until the operation is finished func (ns *NodeStateMachine) SetField(n *enode.Node, field Field, value interface{}) error { ns.lock.Lock() defer ns.lock.Unlock() if !ns.opStart() { return ErrClosed } err := ns.setField(n, field, value) ns.opFinish() return err } // SetFieldSub sets the given field of the given node without blocking (should be called // from a subscription/operation callback). func (ns *NodeStateMachine) SetFieldSub(n *enode.Node, field Field, value interface{}) error { ns.lock.Lock() defer ns.lock.Unlock() ns.opCheck() return ns.setField(n, field, value) } func (ns *NodeStateMachine) setField(n *enode.Node, field Field, value interface{}) error { ns.checkStarted() id, node := ns.updateEnode(n) if node == nil { if value == nil { return nil } node = ns.newNode(n) ns.nodes[id] = node } fieldIndex := ns.fieldIndex(field) f := ns.fields[fieldIndex] if value != nil && reflect.TypeOf(value) != f.ftype { log.Error("Invalid field type", "type", reflect.TypeOf(value), "required", f.ftype) return ErrInvalidField } oldValue := node.fields[fieldIndex] if value == oldValue { return nil } if oldValue != nil { node.fieldCount-- } if value != nil { node.fieldCount++ } node.fields[fieldIndex] = value if node.state == 0 && node.fieldCount == 0 { delete(ns.nodes, id) if node.db { ns.deleteNode(id) } } else { if f.encode != nil { node.dirty = true } } state := node.state callback := func() { for _, cb := range f.subs { cb(n, Flags{mask: state, setup: ns.setup}, oldValue, value) } } ns.opPending = append(ns.opPending, callback) return nil } // ForEach calls the callback for each node having all of the required and none of the // disabled flags set. // Note that this callback is not an operation callback but ForEach can be called from an // Operation callback or Operation can also be called from a ForEach callback if necessary. func (ns *NodeStateMachine) ForEach(requireFlags, disableFlags Flags, cb func(n *enode.Node, state Flags)) { ns.lock.Lock() ns.checkStarted() type callback struct { node *enode.Node state bitMask } require, disable := ns.stateMask(requireFlags), ns.stateMask(disableFlags) var callbacks []callback for _, node := range ns.nodes { if node.state&require == require && node.state&disable == 0 { callbacks = append(callbacks, callback{node.node, node.state & (require | disable)}) } } ns.lock.Unlock() for _, c := range callbacks { cb(c.node, Flags{mask: c.state, setup: ns.setup}) } } // GetNode returns the enode currently associated with the given ID func (ns *NodeStateMachine) GetNode(id enode.ID) *enode.Node { ns.lock.Lock() defer ns.lock.Unlock() ns.checkStarted() if node := ns.nodes[id]; node != nil { return node.node } return nil } // AddLogMetrics adds logging and/or metrics for nodes entering, exiting and currently // being in a given set specified by required and disabled state flags func (ns *NodeStateMachine) AddLogMetrics(requireFlags, disableFlags Flags, name string, inMeter, outMeter metrics.Meter, gauge metrics.Gauge) { var count int64 ns.SubscribeState(requireFlags.Or(disableFlags), func(n *enode.Node, oldState, newState Flags) { oldMatch := oldState.HasAll(requireFlags) && oldState.HasNone(disableFlags) newMatch := newState.HasAll(requireFlags) && newState.HasNone(disableFlags) if newMatch == oldMatch { return } if newMatch { count++ if name != "" { log.Debug("Node entered", "set", name, "id", n.ID(), "count", count) } if inMeter != nil { inMeter.Mark(1) } } else { count-- if name != "" { log.Debug("Node left", "set", name, "id", n.ID(), "count", count) } if outMeter != nil { outMeter.Mark(1) } } if gauge != nil { gauge.Update(count) } }) }