// 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 rpc import ( "bytes" "container/list" "context" "encoding/json" "errors" "fmt" "net" "net/url" "reflect" "strconv" "strings" "sync" "sync/atomic" "time" "github.com/ethereum/go-ethereum/log" ) var ( ErrClientQuit = errors.New("client is closed") ErrNoResult = errors.New("no result in JSON-RPC response") ErrSubscriptionQueueOverflow = errors.New("subscription queue overflow") ) const ( // Timeouts tcpKeepAliveInterval = 30 * time.Second defaultDialTimeout = 10 * time.Second // used when dialing if the context has no deadline defaultWriteTimeout = 10 * time.Second // used for calls if the context has no deadline subscribeTimeout = 5 * time.Second // overall timeout eth_subscribe, rpc_modules calls ) const ( // Subscriptions are removed when the subscriber cannot keep up. // // This can be worked around by supplying a channel with sufficiently sized buffer, // but this can be inconvenient and hard to explain in the docs. Another issue with // buffered channels is that the buffer is static even though it might not be needed // most of the time. // // The approach taken here is to maintain a per-subscription linked list buffer // shrinks on demand. If the buffer reaches the size below, the subscription is // dropped. maxClientSubscriptionBuffer = 8000 ) // BatchElem is an element in a batch request. type BatchElem struct { Method string Args []interface{} // The result is unmarshaled into this field. Result must be set to a // non-nil pointer value of the desired type, otherwise the response will be // discarded. Result interface{} // Error is set if the server returns an error for this request, or if // unmarshaling into Result fails. It is not set for I/O errors. Error error } // A value of this type can a JSON-RPC request, notification, successful response or // error response. Which one it is depends on the fields. type jsonrpcMessage struct { Version string `json:"jsonrpc"` ID json.RawMessage `json:"id,omitempty"` Method string `json:"method,omitempty"` Params json.RawMessage `json:"params,omitempty"` Error *jsonError `json:"error,omitempty"` Result json.RawMessage `json:"result,omitempty"` } func (msg *jsonrpcMessage) isNotification() bool { return msg.ID == nil && msg.Method != "" } func (msg *jsonrpcMessage) isResponse() bool { return msg.hasValidID() && msg.Method == "" && len(msg.Params) == 0 } func (msg *jsonrpcMessage) hasValidID() bool { return len(msg.ID) > 0 && msg.ID[0] != '{' && msg.ID[0] != '[' } func (msg *jsonrpcMessage) String() string { b, _ := json.Marshal(msg) return string(b) } // Client represents a connection to an RPC server. type Client struct { idCounter uint32 connectFunc func(ctx context.Context) (net.Conn, error) isHTTP bool // writeConn is only safe to access outside dispatch, with the // write lock held. The write lock is taken by sending on // requestOp and released by sending on sendDone. writeConn net.Conn // for dispatch close chan struct{} didQuit chan struct{} // closed when client quits reconnected chan net.Conn // where write/reconnect sends the new connection readErr chan error // errors from read readResp chan []*jsonrpcMessage // valid messages from read requestOp chan *requestOp // for registering response IDs sendDone chan error // signals write completion, releases write lock respWait map[string]*requestOp // active requests subs map[string]*ClientSubscription // active subscriptions } type requestOp struct { ids []json.RawMessage err error resp chan *jsonrpcMessage // receives up to len(ids) responses sub *ClientSubscription // only set for EthSubscribe requests } func (op *requestOp) wait(ctx context.Context) (*jsonrpcMessage, error) { select { case <-ctx.Done(): return nil, ctx.Err() case resp := <-op.resp: return resp, op.err } } // Dial creates a new client for the given URL. // // The currently supported URL schemes are "http", "https", "ws" and "wss". If rawurl is a // file name with no URL scheme, a local socket connection is established using UNIX // domain sockets on supported platforms and named pipes on Windows. If you want to // configure transport options, use DialHTTP, DialWebsocket or DialIPC instead. // // For websocket connections, the origin is set to the local host name. // // The client reconnects automatically if the connection is lost. func Dial(rawurl string) (*Client, error) { return DialContext(context.Background(), rawurl) } // DialContext creates a new RPC client, just like Dial. // // The context is used to cancel or time out the initial connection establishment. It does // not affect subsequent interactions with the client. func DialContext(ctx context.Context, rawurl string) (*Client, error) { u, err := url.Parse(rawurl) if err != nil { return nil, err } switch u.Scheme { case "http", "https": return DialHTTP(rawurl) case "ws", "wss": return DialWebsocket(ctx, rawurl, "") case "": return DialIPC(ctx, rawurl) default: return nil, fmt.Errorf("no known transport for URL scheme %q", u.Scheme) } } func newClient(initctx context.Context, connectFunc func(context.Context) (net.Conn, error)) (*Client, error) { conn, err := connectFunc(initctx) if err != nil { return nil, err } _, isHTTP := conn.(*httpConn) c := &Client{ writeConn: conn, isHTTP: isHTTP, connectFunc: connectFunc, close: make(chan struct{}), didQuit: make(chan struct{}), reconnected: make(chan net.Conn), readErr: make(chan error), readResp: make(chan []*jsonrpcMessage), requestOp: make(chan *requestOp), sendDone: make(chan error, 1), respWait: make(map[string]*requestOp), subs: make(map[string]*ClientSubscription), } if !isHTTP { go c.dispatch(conn) } return c, nil } func (c *Client) nextID() json.RawMessage { id := atomic.AddUint32(&c.idCounter, 1) return []byte(strconv.FormatUint(uint64(id), 10)) } // SupportedModules calls the rpc_modules method, retrieving the list of // APIs that are available on the server. func (c *Client) SupportedModules() (map[string]string, error) { var result map[string]string ctx, cancel := context.WithTimeout(context.Background(), subscribeTimeout) defer cancel() err := c.CallContext(ctx, &result, "rpc_modules") return result, err } // Close closes the client, aborting any in-flight requests. func (c *Client) Close() { if c.isHTTP { return } select { case c.close <- struct{}{}: <-c.didQuit case <-c.didQuit: } } // Call performs a JSON-RPC call with the given arguments and unmarshals into // result if no error occurred. // // The result must be a pointer so that package json can unmarshal into it. You // can also pass nil, in which case the result is ignored. func (c *Client) Call(result interface{}, method string, args ...interface{}) error { ctx := context.Background() return c.CallContext(ctx, result, method, args...) } // CallContext performs a JSON-RPC call with the given arguments. If the context is // canceled before the call has successfully returned, CallContext returns immediately. // // The result must be a pointer so that package json can unmarshal into it. You // can also pass nil, in which case the result is ignored. func (c *Client) CallContext(ctx context.Context, result interface{}, method string, args ...interface{}) error { msg, err := c.newMessage(method, args...) if err != nil { return err } op := &requestOp{ids: []json.RawMessage{msg.ID}, resp: make(chan *jsonrpcMessage, 1)} if c.isHTTP { err = c.sendHTTP(ctx, op, msg) } else { err = c.send(ctx, op, msg) } if err != nil { return err } // dispatch has accepted the request and will close the channel it when it quits. switch resp, err := op.wait(ctx); { case err != nil: return err case resp.Error != nil: return resp.Error case len(resp.Result) == 0: return ErrNoResult default: return json.Unmarshal(resp.Result, &result) } } // BatchCall sends all given requests as a single batch and waits for the server // to return a response for all of them. // // In contrast to Call, BatchCall only returns I/O errors. Any error specific to // a request is reported through the Error field of the corresponding BatchElem. // // Note that batch calls may not be executed atomically on the server side. func (c *Client) BatchCall(b []BatchElem) error { ctx := context.Background() return c.BatchCallContext(ctx, b) } // BatchCall sends all given requests as a single batch and waits for the server // to return a response for all of them. The wait duration is bounded by the // context's deadline. // // In contrast to CallContext, BatchCallContext only returns errors that have occurred // while sending the request. Any error specific to a request is reported through the // Error field of the corresponding BatchElem. // // Note that batch calls may not be executed atomically on the server side. func (c *Client) BatchCallContext(ctx context.Context, b []BatchElem) error { msgs := make([]*jsonrpcMessage, len(b)) op := &requestOp{ ids: make([]json.RawMessage, len(b)), resp: make(chan *jsonrpcMessage, len(b)), } for i, elem := range b { msg, err := c.newMessage(elem.Method, elem.Args...) if err != nil { return err } msgs[i] = msg op.ids[i] = msg.ID } var err error if c.isHTTP { err = c.sendBatchHTTP(ctx, op, msgs) } else { err = c.send(ctx, op, msgs) } // Wait for all responses to come back. for n := 0; n < len(b) && err == nil; n++ { var resp *jsonrpcMessage resp, err = op.wait(ctx) if err != nil { break } // Find the element corresponding to this response. // The element is guaranteed to be present because dispatch // only sends valid IDs to our channel. var elem *BatchElem for i := range msgs { if bytes.Equal(msgs[i].ID, resp.ID) { elem = &b[i] break } } if resp.Error != nil { elem.Error = resp.Error continue } if len(resp.Result) == 0 { elem.Error = ErrNoResult continue } elem.Error = json.Unmarshal(resp.Result, elem.Result) } return err } // EthSubscribe calls the "eth_subscribe" method with the given arguments, // registering a subscription. Server notifications for the subscription are // sent to the given channel. The element type of the channel must match the // expected type of content returned by the subscription. // // The context argument cancels the RPC request that sets up the subscription but has no // effect on the subscription after EthSubscribe has returned. // // Slow subscribers will be dropped eventually. Client buffers up to 8000 notifications // before considering the subscriber dead. The subscription Err channel will receive // ErrSubscriptionQueueOverflow. Use a sufficiently large buffer on the channel or ensure // that the channel usually has at least one reader to prevent this issue. func (c *Client) EthSubscribe(ctx context.Context, channel interface{}, args ...interface{}) (*ClientSubscription, error) { // Check type of channel first. chanVal := reflect.ValueOf(channel) if chanVal.Kind() != reflect.Chan || chanVal.Type().ChanDir()&reflect.SendDir == 0 { panic("first argument to EthSubscribe must be a writable channel") } if chanVal.IsNil() { panic("channel given to EthSubscribe must not be nil") } if c.isHTTP { return nil, ErrNotificationsUnsupported } msg, err := c.newMessage("eth"+subscribeMethodSuffix, args...) if err != nil { return nil, err } op := &requestOp{ ids: []json.RawMessage{msg.ID}, resp: make(chan *jsonrpcMessage), sub: newClientSubscription(c, "eth", chanVal), } // Send the subscription request. // The arrival and validity of the response is signaled on sub.quit. if err := c.send(ctx, op, msg); err != nil { return nil, err } if _, err := op.wait(ctx); err != nil { return nil, err } return op.sub, nil } func (c *Client) newMessage(method string, paramsIn ...interface{}) (*jsonrpcMessage, error) { params, err := json.Marshal(paramsIn) if err != nil { return nil, err } return &jsonrpcMessage{Version: "2.0", ID: c.nextID(), Method: method, Params: params}, nil } // send registers op with the dispatch loop, then sends msg on the connection. // if sending fails, op is deregistered. func (c *Client) send(ctx context.Context, op *requestOp, msg interface{}) error { select { case c.requestOp <- op: log.Trace("", "msg", log.Lazy{Fn: func() string { return fmt.Sprint("sending ", msg) }}) err := c.write(ctx, msg) c.sendDone <- err return err case <-ctx.Done(): // This can happen if the client is overloaded or unable to keep up with // subscription notifications. return ctx.Err() case <-c.didQuit: return ErrClientQuit } } func (c *Client) write(ctx context.Context, msg interface{}) error { deadline, ok := ctx.Deadline() if !ok { deadline = time.Now().Add(defaultWriteTimeout) } // The previous write failed. Try to establish a new connection. if c.writeConn == nil { if err := c.reconnect(ctx); err != nil { return err } } c.writeConn.SetWriteDeadline(deadline) err := json.NewEncoder(c.writeConn).Encode(msg) if err != nil { c.writeConn = nil } return err } func (c *Client) reconnect(ctx context.Context) error { newconn, err := c.connectFunc(ctx) if err != nil { log.Trace(fmt.Sprintf("reconnect failed: %v", err)) return err } select { case c.reconnected <- newconn: c.writeConn = newconn return nil case <-c.didQuit: newconn.Close() return ErrClientQuit } } // dispatch is the main loop of the client. // It sends read messages to waiting calls to Call and BatchCall // and subscription notifications to registered subscriptions. func (c *Client) dispatch(conn net.Conn) { // Spawn the initial read loop. go c.read(conn) var ( lastOp *requestOp // tracks last send operation requestOpLock = c.requestOp // nil while the send lock is held reading = true // if true, a read loop is running ) defer close(c.didQuit) defer func() { c.closeRequestOps(ErrClientQuit) conn.Close() if reading { // Empty read channels until read is dead. for { select { case <-c.readResp: case <-c.readErr: return } } } }() for { select { case <-c.close: return // Read path. case batch := <-c.readResp: for _, msg := range batch { switch { case msg.isNotification(): log.Trace("", "msg", log.Lazy{Fn: func() string { return fmt.Sprint("<-readResp: notification ", msg) }}) c.handleNotification(msg) case msg.isResponse(): log.Trace("", "msg", log.Lazy{Fn: func() string { return fmt.Sprint("<-readResp: response ", msg) }}) c.handleResponse(msg) default: log.Debug("", "msg", log.Lazy{Fn: func() string { return fmt.Sprint("<-readResp: dropping weird message", msg) }}) // TODO: maybe close } } case err := <-c.readErr: log.Debug(fmt.Sprintf("<-readErr: %v", err)) c.closeRequestOps(err) conn.Close() reading = false case newconn := <-c.reconnected: log.Debug(fmt.Sprintf("<-reconnected: (reading=%t) %v", reading, conn.RemoteAddr())) if reading { // Wait for the previous read loop to exit. This is a rare case. conn.Close() <-c.readErr } go c.read(newconn) reading = true conn = newconn // Send path. case op := <-requestOpLock: // Stop listening for further send ops until the current one is done. requestOpLock = nil lastOp = op for _, id := range op.ids { c.respWait[string(id)] = op } case err := <-c.sendDone: if err != nil { // Remove response handlers for the last send. We remove those here // because the error is already handled in Call or BatchCall. When the // read loop goes down, it will signal all other current operations. for _, id := range lastOp.ids { delete(c.respWait, string(id)) } } // Listen for send ops again. requestOpLock = c.requestOp lastOp = nil } } } // closeRequestOps unblocks pending send ops and active subscriptions. func (c *Client) closeRequestOps(err error) { didClose := make(map[*requestOp]bool) for id, op := range c.respWait { // Remove the op so that later calls will not close op.resp again. delete(c.respWait, id) if !didClose[op] { op.err = err close(op.resp) didClose[op] = true } } for id, sub := range c.subs { delete(c.subs, id) sub.quitWithError(err, false) } } func (c *Client) handleNotification(msg *jsonrpcMessage) { if !strings.HasSuffix(msg.Method, notificationMethodSuffix) { log.Debug(fmt.Sprint("dropping non-subscription message: ", msg)) return } var subResult struct { ID string `json:"subscription"` Result json.RawMessage `json:"result"` } if err := json.Unmarshal(msg.Params, &subResult); err != nil { log.Debug(fmt.Sprint("dropping invalid subscription message: ", msg)) return } if c.subs[subResult.ID] != nil { c.subs[subResult.ID].deliver(subResult.Result) } } func (c *Client) handleResponse(msg *jsonrpcMessage) { op := c.respWait[string(msg.ID)] if op == nil { log.Debug(fmt.Sprintf("unsolicited response %v", msg)) return } delete(c.respWait, string(msg.ID)) // For normal responses, just forward the reply to Call/BatchCall. if op.sub == nil { op.resp <- msg return } // For subscription responses, start the subscription if the server // indicates success. EthSubscribe gets unblocked in either case through // the op.resp channel. defer close(op.resp) if msg.Error != nil { op.err = msg.Error return } if op.err = json.Unmarshal(msg.Result, &op.sub.subid); op.err == nil { go op.sub.start() c.subs[op.sub.subid] = op.sub } } // Reading happens on a dedicated goroutine. func (c *Client) read(conn net.Conn) error { var ( buf json.RawMessage dec = json.NewDecoder(conn) ) readMessage := func() (rs []*jsonrpcMessage, err error) { buf = buf[:0] if err = dec.Decode(&buf); err != nil { return nil, err } if isBatch(buf) { err = json.Unmarshal(buf, &rs) } else { rs = make([]*jsonrpcMessage, 1) err = json.Unmarshal(buf, &rs[0]) } return rs, err } for { resp, err := readMessage() if err != nil { c.readErr <- err return err } c.readResp <- resp } } // Subscriptions. // A ClientSubscription represents a subscription established through EthSubscribe. type ClientSubscription struct { client *Client etype reflect.Type channel reflect.Value namespace string subid string in chan json.RawMessage quitOnce sync.Once // ensures quit is closed once quit chan struct{} // quit is closed when the subscription exits errOnce sync.Once // ensures err is closed once err chan error } func newClientSubscription(c *Client, namespace string, channel reflect.Value) *ClientSubscription { sub := &ClientSubscription{ client: c, namespace: namespace, etype: channel.Type().Elem(), channel: channel, quit: make(chan struct{}), err: make(chan error, 1), in: make(chan json.RawMessage), } return sub } // Err returns the subscription error channel. The intended use of Err is to schedule // resubscription when the client connection is closed unexpectedly. // // The error channel receives a value when the subscription has ended due // to an error. The received error is nil if Close has been called // on the underlying client and no other error has occurred. // // The error channel is closed when Unsubscribe is called on the subscription. func (sub *ClientSubscription) Err() <-chan error { return sub.err } // Unsubscribe unsubscribes the notification and closes the error channel. // It can safely be called more than once. func (sub *ClientSubscription) Unsubscribe() { sub.quitWithError(nil, true) sub.errOnce.Do(func() { close(sub.err) }) } func (sub *ClientSubscription) quitWithError(err error, unsubscribeServer bool) { sub.quitOnce.Do(func() { // The dispatch loop won't be able to execute the unsubscribe call // if it is blocked on deliver. Close sub.quit first because it // unblocks deliver. close(sub.quit) if unsubscribeServer { sub.requestUnsubscribe() } if err != nil { if err == ErrClientQuit { err = nil // Adhere to subscription semantics. } sub.err <- err } }) } func (sub *ClientSubscription) deliver(result json.RawMessage) (ok bool) { select { case sub.in <- result: return true case <-sub.quit: return false } } func (sub *ClientSubscription) start() { sub.quitWithError(sub.forward()) } func (sub *ClientSubscription) forward() (err error, unsubscribeServer bool) { cases := []reflect.SelectCase{ {Dir: reflect.SelectRecv, Chan: reflect.ValueOf(sub.quit)}, {Dir: reflect.SelectRecv, Chan: reflect.ValueOf(sub.in)}, {Dir: reflect.SelectSend, Chan: sub.channel}, } buffer := list.New() defer buffer.Init() for { var chosen int var recv reflect.Value if buffer.Len() == 0 { // Idle, omit send case. chosen, recv, _ = reflect.Select(cases[:2]) } else { // Non-empty buffer, send the first queued item. cases[2].Send = reflect.ValueOf(buffer.Front().Value) chosen, recv, _ = reflect.Select(cases) } switch chosen { case 0: // <-sub.quit return nil, false case 1: // <-sub.in val, err := sub.unmarshal(recv.Interface().(json.RawMessage)) if err != nil { return err, true } if buffer.Len() == maxClientSubscriptionBuffer { return ErrSubscriptionQueueOverflow, true } buffer.PushBack(val) case 2: // sub.channel<- cases[2].Send = reflect.Value{} // Don't hold onto the value. buffer.Remove(buffer.Front()) } } } func (sub *ClientSubscription) unmarshal(result json.RawMessage) (interface{}, error) { val := reflect.New(sub.etype) err := json.Unmarshal(result, val.Interface()) return val.Elem().Interface(), err } func (sub *ClientSubscription) requestUnsubscribe() error { var result interface{} return sub.client.Call(&result, sub.namespace+unsubscribeMethodSuffix, sub.subid) }