// Copyright 2016 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 ethstats implements the network stats reporting service. package ethstats import ( "context" "encoding/json" "errors" "fmt" "math/big" "net/http" "regexp" "runtime" "strconv" "strings" "sync" "time" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/common/mclock" "github.com/ethereum/go-ethereum/consensus" "github.com/ethereum/go-ethereum/core" "github.com/ethereum/go-ethereum/core/types" "github.com/ethereum/go-ethereum/eth" "github.com/ethereum/go-ethereum/eth/downloader" "github.com/ethereum/go-ethereum/event" "github.com/ethereum/go-ethereum/les" "github.com/ethereum/go-ethereum/log" "github.com/ethereum/go-ethereum/miner" "github.com/ethereum/go-ethereum/node" "github.com/ethereum/go-ethereum/p2p" "github.com/ethereum/go-ethereum/rpc" "github.com/gorilla/websocket" ) const ( // historyUpdateRange is the number of blocks a node should report upon login or // history request. historyUpdateRange = 50 // txChanSize is the size of channel listening to NewTxsEvent. // The number is referenced from the size of tx pool. txChanSize = 4096 // chainHeadChanSize is the size of channel listening to ChainHeadEvent. chainHeadChanSize = 10 ) // backend encompasses the bare-minimum functionality needed for ethstats reporting type backend interface { SubscribeChainHeadEvent(ch chan<- core.ChainHeadEvent) event.Subscription SubscribeNewTxsEvent(ch chan<- core.NewTxsEvent) event.Subscription CurrentHeader() *types.Header HeaderByNumber(ctx context.Context, number rpc.BlockNumber) (*types.Header, error) GetTd(ctx context.Context, hash common.Hash) *big.Int Stats() (pending int, queued int) Downloader() *downloader.Downloader } // fullNodeBackend encompasses the functionality necessary for a full node // reporting to ethstats type fullNodeBackend interface { backend Miner() *miner.Miner BlockByNumber(ctx context.Context, number rpc.BlockNumber) (*types.Block, error) CurrentBlock() *types.Block SuggestPrice(ctx context.Context) (*big.Int, error) } // Service implements an Ethereum netstats reporting daemon that pushes local // chain statistics up to a monitoring server. type Service struct { server *p2p.Server // Peer-to-peer server to retrieve networking infos backend backend engine consensus.Engine // Consensus engine to retrieve variadic block fields node string // Name of the node to display on the monitoring page pass string // Password to authorize access to the monitoring page host string // Remote address of the monitoring service pongCh chan struct{} // Pong notifications are fed into this channel histCh chan []uint64 // History request block numbers are fed into this channel } // connWrapper is a wrapper to prevent concurrent-write or concurrent-read on the // websocket. // From Gorilla websocket docs: // Connections support one concurrent reader and one concurrent writer. // Applications are responsible for ensuring that no more than one goroutine calls the write methods // - NextWriter, SetWriteDeadline, WriteMessage, WriteJSON, EnableWriteCompression, SetCompressionLevel // concurrently and that no more than one goroutine calls the read methods // - NextReader, SetReadDeadline, ReadMessage, ReadJSON, SetPongHandler, SetPingHandler // concurrently. // The Close and WriteControl methods can be called concurrently with all other methods. // // The connWrapper uses a single mutex for both reading and writing. type connWrapper struct { conn *websocket.Conn mu sync.Mutex } func newConnectionWrapper(conn *websocket.Conn) *connWrapper { return &connWrapper{conn: conn} } // WriteJSON wraps corresponding method on the websocket but is safe for concurrent calling func (w *connWrapper) WriteJSON(v interface{}) error { w.mu.Lock() defer w.mu.Unlock() return w.conn.WriteJSON(v) } // ReadJSON wraps corresponding method on the websocket but is safe for concurrent calling func (w *connWrapper) ReadJSON(v interface{}) error { w.mu.Lock() defer w.mu.Unlock() return w.conn.ReadJSON(v) } // Close wraps corresponding method on the websocket but is safe for concurrent calling func (w *connWrapper) Close() error { // The Close and WriteControl methods can be called concurrently with all other methods, // so the mutex is not used here return w.conn.Close() } // New returns a monitoring service ready for stats reporting. func New(node *node.Node, backend backend, engine consensus.Engine, url string) error { // Parse the netstats connection url re := regexp.MustCompile("([^:@]*)(:([^@]*))?@(.+)") parts := re.FindStringSubmatch(url) if len(parts) != 5 { return fmt.Errorf("invalid netstats url: \"%s\", should be nodename:secret@host:port", url) } ethstats := &Service{ backend: backend, engine: engine, server: node.Server(), node: parts[1], pass: parts[3], host: parts[4], pongCh: make(chan struct{}), histCh: make(chan []uint64, 1), } node.RegisterLifecycle(ethstats) return nil } // Start implements node.Lifecycle, starting up the monitoring and reporting daemon. func (s *Service) Start() error { go s.loop() log.Info("Stats daemon started") return nil } // Stop implements node.Lifecycle, terminating the monitoring and reporting daemon. func (s *Service) Stop() error { log.Info("Stats daemon stopped") return nil } // loop keeps trying to connect to the netstats server, reporting chain events // until termination. func (s *Service) loop() { // Subscribe to chain events to execute updates on chainHeadCh := make(chan core.ChainHeadEvent, chainHeadChanSize) headSub := s.backend.SubscribeChainHeadEvent(chainHeadCh) defer headSub.Unsubscribe() txEventCh := make(chan core.NewTxsEvent, txChanSize) txSub := s.backend.SubscribeNewTxsEvent(txEventCh) defer txSub.Unsubscribe() // Start a goroutine that exhausts the subscriptions to avoid events piling up var ( quitCh = make(chan struct{}) headCh = make(chan *types.Block, 1) txCh = make(chan struct{}, 1) ) go func() { var lastTx mclock.AbsTime HandleLoop: for { select { // Notify of chain head events, but drop if too frequent case head := <-chainHeadCh: select { case headCh <- head.Block: default: } // Notify of new transaction events, but drop if too frequent case <-txEventCh: if time.Duration(mclock.Now()-lastTx) < time.Second { continue } lastTx = mclock.Now() select { case txCh <- struct{}{}: default: } // node stopped case <-txSub.Err(): break HandleLoop case <-headSub.Err(): break HandleLoop } } close(quitCh) }() // Resolve the URL, defaulting to TLS, but falling back to none too path := fmt.Sprintf("%s/api", s.host) urls := []string{path} // url.Parse and url.IsAbs is unsuitable (https://github.com/golang/go/issues/19779) if !strings.Contains(path, "://") { urls = []string{"wss://" + path, "ws://" + path} } errTimer := time.NewTimer(0) defer errTimer.Stop() // Loop reporting until termination for { select { case <-quitCh: return case <-errTimer.C: // Establish a websocket connection to the server on any supported URL var ( conn *connWrapper err error ) dialer := websocket.Dialer{HandshakeTimeout: 5 * time.Second} header := make(http.Header) header.Set("origin", "http://localhost") for _, url := range urls { c, _, e := dialer.Dial(url, header) err = e if err == nil { conn = newConnectionWrapper(c) break } } if err != nil { log.Warn("Stats server unreachable", "err", err) errTimer.Reset(10 * time.Second) continue } // Authenticate the client with the server if err = s.login(conn); err != nil { log.Warn("Stats login failed", "err", err) conn.Close() errTimer.Reset(10 * time.Second) continue } go s.readLoop(conn) // Send the initial stats so our node looks decent from the get go if err = s.report(conn); err != nil { log.Warn("Initial stats report failed", "err", err) conn.Close() errTimer.Reset(0) continue } // Keep sending status updates until the connection breaks fullReport := time.NewTicker(15 * time.Second) for err == nil { select { case <-quitCh: fullReport.Stop() // Make sure the connection is closed conn.Close() return case <-fullReport.C: if err = s.report(conn); err != nil { log.Warn("Full stats report failed", "err", err) } case list := <-s.histCh: if err = s.reportHistory(conn, list); err != nil { log.Warn("Requested history report failed", "err", err) } case head := <-headCh: if err = s.reportBlock(conn, head); err != nil { log.Warn("Block stats report failed", "err", err) } if err = s.reportPending(conn); err != nil { log.Warn("Post-block transaction stats report failed", "err", err) } case <-txCh: if err = s.reportPending(conn); err != nil { log.Warn("Transaction stats report failed", "err", err) } } } fullReport.Stop() // Close the current connection and establish a new one conn.Close() errTimer.Reset(0) } } } // readLoop loops as long as the connection is alive and retrieves data packets // from the network socket. If any of them match an active request, it forwards // it, if they themselves are requests it initiates a reply, and lastly it drops // unknown packets. func (s *Service) readLoop(conn *connWrapper) { // If the read loop exists, close the connection defer conn.Close() for { // Retrieve the next generic network packet and bail out on error var blob json.RawMessage if err := conn.ReadJSON(&blob); err != nil { log.Warn("Failed to retrieve stats server message", "err", err) return } // If the network packet is a system ping, respond to it directly var ping string if err := json.Unmarshal(blob, &ping); err == nil && strings.HasPrefix(ping, "primus::ping::") { if err := conn.WriteJSON(strings.Replace(ping, "ping", "pong", -1)); err != nil { log.Warn("Failed to respond to system ping message", "err", err) return } continue } // Not a system ping, try to decode an actual state message var msg map[string][]interface{} if err := json.Unmarshal(blob, &msg); err != nil { log.Warn("Failed to decode stats server message", "err", err) return } log.Trace("Received message from stats server", "msg", msg) if len(msg["emit"]) == 0 { log.Warn("Stats server sent non-broadcast", "msg", msg) return } command, ok := msg["emit"][0].(string) if !ok { log.Warn("Invalid stats server message type", "type", msg["emit"][0]) return } // If the message is a ping reply, deliver (someone must be listening!) if len(msg["emit"]) == 2 && command == "node-pong" { select { case s.pongCh <- struct{}{}: // Pong delivered, continue listening continue default: // Ping routine dead, abort log.Warn("Stats server pinger seems to have died") return } } // If the message is a history request, forward to the event processor if len(msg["emit"]) == 2 && command == "history" { // Make sure the request is valid and doesn't crash us request, ok := msg["emit"][1].(map[string]interface{}) if !ok { log.Warn("Invalid stats history request", "msg", msg["emit"][1]) select { case s.histCh <- nil: // Treat it as an no indexes request default: } continue } list, ok := request["list"].([]interface{}) if !ok { log.Warn("Invalid stats history block list", "list", request["list"]) return } // Convert the block number list to an integer list numbers := make([]uint64, len(list)) for i, num := range list { n, ok := num.(float64) if !ok { log.Warn("Invalid stats history block number", "number", num) return } numbers[i] = uint64(n) } select { case s.histCh <- numbers: continue default: } } // Report anything else and continue log.Info("Unknown stats message", "msg", msg) } } // nodeInfo is the collection of meta information about a node that is displayed // on the monitoring page. type nodeInfo struct { Name string `json:"name"` Node string `json:"node"` Port int `json:"port"` Network string `json:"net"` Protocol string `json:"protocol"` API string `json:"api"` Os string `json:"os"` OsVer string `json:"os_v"` Client string `json:"client"` History bool `json:"canUpdateHistory"` } // authMsg is the authentication infos needed to login to a monitoring server. type authMsg struct { ID string `json:"id"` Info nodeInfo `json:"info"` Secret string `json:"secret"` } // login tries to authorize the client at the remote server. func (s *Service) login(conn *connWrapper) error { // Construct and send the login authentication infos := s.server.NodeInfo() var network, protocol string if info := infos.Protocols["eth"]; info != nil { network = fmt.Sprintf("%d", info.(*eth.NodeInfo).Network) protocol = fmt.Sprintf("eth/%d", eth.ProtocolVersions[0]) } else { network = fmt.Sprintf("%d", infos.Protocols["les"].(*les.NodeInfo).Network) protocol = fmt.Sprintf("les/%d", les.ClientProtocolVersions[0]) } auth := &authMsg{ ID: s.node, Info: nodeInfo{ Name: s.node, Node: infos.Name, Port: infos.Ports.Listener, Network: network, Protocol: protocol, API: "No", Os: runtime.GOOS, OsVer: runtime.GOARCH, Client: "0.1.1", History: true, }, Secret: s.pass, } login := map[string][]interface{}{ "emit": {"hello", auth}, } if err := conn.WriteJSON(login); err != nil { return err } // Retrieve the remote ack or connection termination var ack map[string][]string if err := conn.ReadJSON(&ack); err != nil || len(ack["emit"]) != 1 || ack["emit"][0] != "ready" { return errors.New("unauthorized") } return nil } // report collects all possible data to report and send it to the stats server. // This should only be used on reconnects or rarely to avoid overloading the // server. Use the individual methods for reporting subscribed events. func (s *Service) report(conn *connWrapper) error { if err := s.reportLatency(conn); err != nil { return err } if err := s.reportBlock(conn, nil); err != nil { return err } if err := s.reportPending(conn); err != nil { return err } if err := s.reportStats(conn); err != nil { return err } return nil } // reportLatency sends a ping request to the server, measures the RTT time and // finally sends a latency update. func (s *Service) reportLatency(conn *connWrapper) error { // Send the current time to the ethstats server start := time.Now() ping := map[string][]interface{}{ "emit": {"node-ping", map[string]string{ "id": s.node, "clientTime": start.String(), }}, } if err := conn.WriteJSON(ping); err != nil { return err } // Wait for the pong request to arrive back select { case <-s.pongCh: // Pong delivered, report the latency case <-time.After(5 * time.Second): // Ping timeout, abort return errors.New("ping timed out") } latency := strconv.Itoa(int((time.Since(start) / time.Duration(2)).Nanoseconds() / 1000000)) // Send back the measured latency log.Trace("Sending measured latency to ethstats", "latency", latency) stats := map[string][]interface{}{ "emit": {"latency", map[string]string{ "id": s.node, "latency": latency, }}, } return conn.WriteJSON(stats) } // blockStats is the information to report about individual blocks. type blockStats struct { Number *big.Int `json:"number"` Hash common.Hash `json:"hash"` ParentHash common.Hash `json:"parentHash"` Timestamp *big.Int `json:"timestamp"` Miner common.Address `json:"miner"` GasUsed uint64 `json:"gasUsed"` GasLimit uint64 `json:"gasLimit"` Diff string `json:"difficulty"` TotalDiff string `json:"totalDifficulty"` Txs []txStats `json:"transactions"` TxHash common.Hash `json:"transactionsRoot"` Root common.Hash `json:"stateRoot"` Uncles uncleStats `json:"uncles"` } // txStats is the information to report about individual transactions. type txStats struct { Hash common.Hash `json:"hash"` } // uncleStats is a custom wrapper around an uncle array to force serializing // empty arrays instead of returning null for them. type uncleStats []*types.Header func (s uncleStats) MarshalJSON() ([]byte, error) { if uncles := ([]*types.Header)(s); len(uncles) > 0 { return json.Marshal(uncles) } return []byte("[]"), nil } // reportBlock retrieves the current chain head and reports it to the stats server. func (s *Service) reportBlock(conn *connWrapper, block *types.Block) error { // Gather the block details from the header or block chain details := s.assembleBlockStats(block) // Assemble the block report and send it to the server log.Trace("Sending new block to ethstats", "number", details.Number, "hash", details.Hash) stats := map[string]interface{}{ "id": s.node, "block": details, } report := map[string][]interface{}{ "emit": {"block", stats}, } return conn.WriteJSON(report) } // assembleBlockStats retrieves any required metadata to report a single block // and assembles the block stats. If block is nil, the current head is processed. func (s *Service) assembleBlockStats(block *types.Block) *blockStats { // Gather the block infos from the local blockchain var ( header *types.Header td *big.Int txs []txStats uncles []*types.Header ) // check if backend is a full node fullBackend, ok := s.backend.(fullNodeBackend) if ok { if block == nil { block = fullBackend.CurrentBlock() } header = block.Header() td = fullBackend.GetTd(context.Background(), header.Hash()) txs = make([]txStats, len(block.Transactions())) for i, tx := range block.Transactions() { txs[i].Hash = tx.Hash() } uncles = block.Uncles() } else { // Light nodes would need on-demand lookups for transactions/uncles, skip if block != nil { header = block.Header() } else { header = s.backend.CurrentHeader() } td = s.backend.GetTd(context.Background(), header.Hash()) txs = []txStats{} } // Assemble and return the block stats author, _ := s.engine.Author(header) return &blockStats{ Number: header.Number, Hash: header.Hash(), ParentHash: header.ParentHash, Timestamp: new(big.Int).SetUint64(header.Time), Miner: author, GasUsed: header.GasUsed, GasLimit: header.GasLimit, Diff: header.Difficulty.String(), TotalDiff: td.String(), Txs: txs, TxHash: header.TxHash, Root: header.Root, Uncles: uncles, } } // reportHistory retrieves the most recent batch of blocks and reports it to the // stats server. func (s *Service) reportHistory(conn *connWrapper, list []uint64) error { // Figure out the indexes that need reporting indexes := make([]uint64, 0, historyUpdateRange) if len(list) > 0 { // Specific indexes requested, send them back in particular indexes = append(indexes, list...) } else { // No indexes requested, send back the top ones head := s.backend.CurrentHeader().Number.Int64() start := head - historyUpdateRange + 1 if start < 0 { start = 0 } for i := uint64(start); i <= uint64(head); i++ { indexes = append(indexes, i) } } // Gather the batch of blocks to report history := make([]*blockStats, len(indexes)) for i, number := range indexes { fullBackend, ok := s.backend.(fullNodeBackend) // Retrieve the next block if it's known to us var block *types.Block if ok { block, _ = fullBackend.BlockByNumber(context.Background(), rpc.BlockNumber(number)) // TODO ignore error here ? } else { if header, _ := s.backend.HeaderByNumber(context.Background(), rpc.BlockNumber(number)); header != nil { block = types.NewBlockWithHeader(header) } } // If we do have the block, add to the history and continue if block != nil { history[len(history)-1-i] = s.assembleBlockStats(block) continue } // Ran out of blocks, cut the report short and send history = history[len(history)-i:] break } // Assemble the history report and send it to the server if len(history) > 0 { log.Trace("Sending historical blocks to ethstats", "first", history[0].Number, "last", history[len(history)-1].Number) } else { log.Trace("No history to send to stats server") } stats := map[string]interface{}{ "id": s.node, "history": history, } report := map[string][]interface{}{ "emit": {"history", stats}, } return conn.WriteJSON(report) } // pendStats is the information to report about pending transactions. type pendStats struct { Pending int `json:"pending"` } // reportPending retrieves the current number of pending transactions and reports // it to the stats server. func (s *Service) reportPending(conn *connWrapper) error { // Retrieve the pending count from the local blockchain pending, _ := s.backend.Stats() // Assemble the transaction stats and send it to the server log.Trace("Sending pending transactions to ethstats", "count", pending) stats := map[string]interface{}{ "id": s.node, "stats": &pendStats{ Pending: pending, }, } report := map[string][]interface{}{ "emit": {"pending", stats}, } return conn.WriteJSON(report) } // nodeStats is the information to report about the local node. type nodeStats struct { Active bool `json:"active"` Syncing bool `json:"syncing"` Mining bool `json:"mining"` Hashrate int `json:"hashrate"` Peers int `json:"peers"` GasPrice int `json:"gasPrice"` Uptime int `json:"uptime"` } // reportStats retrieves various stats about the node at the networking and // mining layer and reports it to the stats server. func (s *Service) reportStats(conn *connWrapper) error { // Gather the syncing and mining infos from the local miner instance var ( mining bool hashrate int syncing bool gasprice int ) // check if backend is a full node fullBackend, ok := s.backend.(fullNodeBackend) if ok { mining = fullBackend.Miner().Mining() hashrate = int(fullBackend.Miner().HashRate()) sync := fullBackend.Downloader().Progress() syncing = fullBackend.CurrentHeader().Number.Uint64() >= sync.HighestBlock price, _ := fullBackend.SuggestPrice(context.Background()) gasprice = int(price.Uint64()) } else { sync := s.backend.Downloader().Progress() syncing = s.backend.CurrentHeader().Number.Uint64() >= sync.HighestBlock } // Assemble the node stats and send it to the server log.Trace("Sending node details to ethstats") stats := map[string]interface{}{ "id": s.node, "stats": &nodeStats{ Active: true, Mining: mining, Hashrate: hashrate, Peers: s.server.PeerCount(), GasPrice: gasprice, Syncing: syncing, Uptime: 100, }, } report := map[string][]interface{}{ "emit": {"stats", stats}, } return conn.WriteJSON(report) }