package netmapcontract import ( "github.com/nspcc-dev/neo-go/pkg/interop/binary" "github.com/nspcc-dev/neo-go/pkg/interop/blockchain" "github.com/nspcc-dev/neo-go/pkg/interop/crypto" "github.com/nspcc-dev/neo-go/pkg/interop/iterator" "github.com/nspcc-dev/neo-go/pkg/interop/runtime" "github.com/nspcc-dev/neo-go/pkg/interop/storage" "github.com/nspcc-dev/neo-go/pkg/interop/util" ) type ( irNode struct { key []byte } storageNode struct { info []byte } ballot struct { id []byte // id of the voting decision n [][]byte // already voted inner ring nodes block int // block with the last vote } netmapNode struct { node storageNode state nodeState } nodeState int record struct { key []byte val []byte } ) const ( version = 1 blockDiff = 20 // change base on performance evaluation voteKey = "ballots" netmapKey = "netmap" innerRingKey = "innerring" configuredKey = "initconfig" snapshot0Key = "snapshotCurrent" snapshot1Key = "snapshotPrevious" snapshotEpoch = "snapshotEpoch" ) const ( _ nodeState = iota onlineState offlineState ) var ( configPrefix = []byte("config") ctx storage.Context ) func init() { if runtime.GetTrigger() != runtime.Application { panic("contract has not been called in application node") } ctx = storage.GetContext() } // Init function sets up initial list of inner ring public keys and should // be invoked once at neofs infrastructure setup. func Init(keys [][]byte) { if storage.Get(ctx, innerRingKey) != nil { panic("netmap: contract already initialized") } var irList []irNode for i := 0; i < len(keys); i++ { key := keys[i] irList = append(irList, irNode{key: key}) } setSerialized(ctx, innerRingKey, irList) // epoch number is a little endian int, it doesn't need to be serialized storage.Put(ctx, snapshotEpoch, 0) // simplified: this used for const sysfee in AddPeer method setSerialized(ctx, netmapKey, []netmapNode{}) setSerialized(ctx, snapshot0Key, []netmapNode{}) setSerialized(ctx, snapshot1Key, []netmapNode{}) setSerialized(ctx, voteKey, []ballot{}) runtime.Log("netmap contract initialized") } func InnerRingList() []irNode { return getIRNodes(ctx) } func UpdateInnerRing(keys [][]byte) bool { innerRing := getIRNodes(ctx) threshold := len(innerRing)/3*2 + 1 irKey := innerRingInvoker(innerRing) if len(irKey) == 0 { panic("updateInnerRing: this method must be invoked by inner ring nodes") } var irList []irNode for i := 0; i < len(keys); i++ { key := keys[i] irList = append(irList, irNode{key: key}) } rawIRList := binary.Serialize(irList) hashIRList := crypto.SHA256(rawIRList) n := vote(ctx, hashIRList, irKey) if n >= threshold { runtime.Log("updateInnerRing: inner ring list updated") setSerialized(ctx, innerRingKey, irList) removeVotes(ctx, hashIRList) } else { runtime.Log("updateInnerRing: processed invoke from inner ring") } return true } func AddPeer(nodeInfo []byte) bool { innerRing := getIRNodes(ctx) threshold := len(innerRing)/3*2 + 1 irKey := innerRingInvoker(innerRing) if len(irKey) == 0 { publicKey := nodeInfo[2:35] // offset:2, len:33 if !runtime.CheckWitness(publicKey) { panic("addPeer: witness check failed") } runtime.Notify("AddPeer", nodeInfo) return true } candidate := storageNode{ info: nodeInfo, } rawCandidate := binary.Serialize(candidate) hashCandidate := crypto.SHA256(rawCandidate) nm := addToNetmap(ctx, candidate) n := vote(ctx, hashCandidate, irKey) if n >= threshold { if nm == nil { runtime.Log("addPeer: storage node already in the netmap") } else { setSerialized(ctx, netmapKey, nm) runtime.Log("addPeer: add storage node to the network map") } removeVotes(ctx, hashCandidate) } else { runtime.Log("addPeer: processed invoke from inner ring") } return true } func UpdateState(state int, publicKey []byte) bool { if len(publicKey) != 33 { panic("updateState: incorrect public key") } innerRing := getIRNodes(ctx) threshold := len(innerRing)/3*2 + 1 irKey := innerRingInvoker(innerRing) if len(irKey) == 0 { if !runtime.CheckWitness(publicKey) { panic("updateState: witness check failed") } runtime.Notify("UpdateState", state, publicKey) return true } switch nodeState(state) { case offlineState: newNetmap := removeFromNetmap(ctx, publicKey) hashID := invokeID([]interface{}{publicKey}, []byte("delete")) n := vote(ctx, hashID, irKey) if n >= threshold { runtime.Log("updateState: remove storage node from the network map") setSerialized(ctx, netmapKey, newNetmap) removeVotes(ctx, hashID) } else { runtime.Log("updateState: processed invoke from inner ring") } default: panic("updateState: unsupported state") } return true } func NewEpoch(epochNum int) bool { innerRing := getIRNodes(ctx) threshold := len(innerRing)/3*2 + 1 irKey := innerRingInvoker(innerRing) if len(irKey) == 0 { panic("newEpoch: this method must be invoked by inner ring nodes") } currentEpoch := storage.Get(ctx, snapshotEpoch).(int) if epochNum <= currentEpoch { return false // ignore invocations with invalid epoch } data0snapshot := getSnapshot(ctx, snapshot0Key) dataOnlineState := filterNetmap(ctx, onlineState) hashID := invokeID([]interface{}{epochNum}, []byte("epoch")) n := vote(ctx, hashID, irKey) if n >= threshold { runtime.Log("newEpoch: process new epoch") // todo: check if provided epoch number is bigger than current storage.Put(ctx, snapshotEpoch, epochNum) // put actual snapshot into previous snapshot setSerialized(ctx, snapshot1Key, data0snapshot) // put netmap into actual snapshot setSerialized(ctx, snapshot0Key, dataOnlineState) removeVotes(ctx, hashID) runtime.Notify("NewEpoch", epochNum) } else { runtime.Log("newEpoch: processed invoke from inner ring") } return true } func Epoch() int { return storage.Get(ctx, snapshotEpoch).(int) } func Netmap() []storageNode { return getSnapshot(ctx, snapshot0Key) } func Snapshot(diff int) []storageNode { var key string switch diff { case 0: key = snapshot0Key case 1: key = snapshot1Key default: panic("snapshot: incorrect diff") } return getSnapshot(ctx, key) } func SnapshotByEpoch(epoch int) []storageNode { currentEpoch := storage.Get(ctx, snapshotEpoch).(int) return Snapshot(currentEpoch - epoch) } func Config(key []byte) interface{} { return getConfig(ctx, key) } func SetConfig(id, key, val []byte) bool { // check if it is inner ring invocation innerRing := getIRNodes(ctx) threshold := len(innerRing)/3*2 + 1 irKey := innerRingInvoker(innerRing) if len(irKey) == 0 { panic("setConfig: invoked by non inner ring node") } // check unique id of the operation hashID := invokeID([]interface{}{id, key, val}, []byte("config")) n := vote(ctx, hashID, irKey) if n >= threshold { removeVotes(ctx, hashID) setConfig(ctx, key, val) runtime.Log("setConfig: configuration has been updated") } return true } func InitConfig(args [][]byte) bool { if storage.Get(ctx, configuredKey) != nil { panic("netmap: configuration already installed") } ln := len(args) if ln%2 != 0 { panic("initConfig: bad arguments") } for i := 0; i < ln/2; i++ { key := args[i*2] val := args[i*2+1] setConfig(ctx, key, val) } storage.Put(ctx, configuredKey, true) runtime.Log("netmap: config has been installed") return true } func ListConfig() []record { var config []record it := storage.Find(ctx, configPrefix) for iterator.Next(it) { key := iterator.Key(it).([]byte) val := iterator.Value(it).([]byte) r := record{key: key[len(configPrefix):], val: val} config = append(config, r) } return config } func Version() int { return version } func innerRingInvoker(ir []irNode) []byte { for i := 0; i < len(ir); i++ { node := ir[i] if runtime.CheckWitness(node.key) { return node.key } } return nil } func addToNetmap(ctx storage.Context, n storageNode) []netmapNode { var ( newNode = n.info newNodeKey = newNode[2:35] netmap = getNetmapNodes(ctx) node = netmapNode{ node: n, state: onlineState, } ) for i := range netmap { netmapNode := netmap[i].node.info netmapNodeKey := netmapNode[2:35] if bytesEqual(newNodeKey, netmapNodeKey) { return nil } } netmap = append(netmap, node) return netmap } func removeFromNetmap(ctx storage.Context, key []byte) []netmapNode { var ( netmap = getNetmapNodes(ctx) newNetmap = []netmapNode{} ) for i := 0; i < len(netmap); i++ { item := netmap[i] node := item.node.info publicKey := node[2:35] // offset:2, len:33 if !bytesEqual(publicKey, key) { newNetmap = append(newNetmap, item) } } return newNetmap } func filterNetmap(ctx storage.Context, st nodeState) []storageNode { var ( netmap = getNetmapNodes(ctx) result = []storageNode{} ) for i := 0; i < len(netmap); i++ { item := netmap[i] if item.state == st { result = append(result, item.node) } } return result } func vote(ctx storage.Context, id, from []byte) int { var ( newCandidates []ballot candidates = getBallots(ctx) found = -1 blockHeight = blockchain.GetHeight() ) for i := 0; i < len(candidates); i++ { cnd := candidates[i] if blockHeight-cnd.block > blockDiff { continue } if bytesEqual(cnd.id, id) { voters := cnd.n for j := range voters { if bytesEqual(voters[j], from) { return len(voters) } } voters = append(voters, from) cnd = ballot{id: id, n: voters, block: blockHeight} found = len(voters) } newCandidates = append(newCandidates, cnd) } if found < 0 { voters := [][]byte{from} newCandidates = append(newCandidates, ballot{ id: id, n: voters, block: blockHeight}) found = 1 } setSerialized(ctx, voteKey, newCandidates) return found } func removeVotes(ctx storage.Context, id []byte) { var ( newCandidates []ballot candidates = getBallots(ctx) ) for i := 0; i < len(candidates); i++ { cnd := candidates[i] if !bytesEqual(cnd.id, id) { newCandidates = append(newCandidates, cnd) } } setSerialized(ctx, voteKey, newCandidates) } func getIRNodes(ctx storage.Context) []irNode { data := storage.Get(ctx, innerRingKey) if data != nil { return binary.Deserialize(data.([]byte)).([]irNode) } return []irNode{} } func getNetmapNodes(ctx storage.Context) []netmapNode { data := storage.Get(ctx, netmapKey) if data != nil { return binary.Deserialize(data.([]byte)).([]netmapNode) } return []netmapNode{} } func getSnapshot(ctx storage.Context, key string) []storageNode { data := storage.Get(ctx, key) if data != nil { return binary.Deserialize(data.([]byte)).([]storageNode) } return []storageNode{} } func getBallots(ctx storage.Context) []ballot { data := storage.Get(ctx, voteKey) if data != nil { return binary.Deserialize(data.([]byte)).([]ballot) } return []ballot{} } func setSerialized(ctx storage.Context, key interface{}, value interface{}) { data := binary.Serialize(value) storage.Put(ctx, key, data) } func getConfig(ctx storage.Context, key interface{}) interface{} { postfix := key.([]byte) storageKey := append(configPrefix, postfix...) return storage.Get(ctx, storageKey) } func setConfig(ctx storage.Context, key, val interface{}) { postfix := key.([]byte) storageKey := append(configPrefix, postfix...) storage.Put(ctx, storageKey, val) } func invokeID(args []interface{}, prefix []byte) []byte { for i := range args { arg := args[i].([]byte) prefix = append(prefix, arg...) } return crypto.SHA256(prefix) } // neo-go#1176 func bytesEqual(a []byte, b []byte) bool { return util.Equals(string(a), string(b)) }