// Copyright 2017 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 protocols is an extension to p2p. It offers a user friendly simple way to define devp2p subprotocols by abstracting away code standardly shared by protocols. * automate assigments of code indexes to messages * automate RLP decoding/encoding based on reflecting * provide the forever loop to read incoming messages * standardise error handling related to communication * standardised handshake negotiation * TODO: automatic generation of wire protocol specification for peers */ package protocols import ( "bufio" "bytes" "context" "fmt" "io" "reflect" "sync" "time" "github.com/ethereum/go-ethereum/log" "github.com/ethereum/go-ethereum/metrics" "github.com/ethereum/go-ethereum/p2p" "github.com/ethereum/go-ethereum/rlp" "github.com/ethereum/go-ethereum/swarm/spancontext" "github.com/ethereum/go-ethereum/swarm/tracing" opentracing "github.com/opentracing/opentracing-go" ) // error codes used by this protocol scheme const ( ErrMsgTooLong = iota ErrDecode ErrWrite ErrInvalidMsgCode ErrInvalidMsgType ErrHandshake ErrNoHandler ErrHandler ) // error description strings associated with the codes var errorToString = map[int]string{ ErrMsgTooLong: "Message too long", ErrDecode: "Invalid message (RLP error)", ErrWrite: "Error sending message", ErrInvalidMsgCode: "Invalid message code", ErrInvalidMsgType: "Invalid message type", ErrHandshake: "Handshake error", ErrNoHandler: "No handler registered error", ErrHandler: "Message handler error", } /* Error implements the standard go error interface. Use: errorf(code, format, params ...interface{}) Prints as: :
where description is given by code in errorToString and details is fmt.Sprintf(format, params...) exported field Code can be checked */ type Error struct { Code int message string format string params []interface{} } func (e Error) Error() (message string) { if len(e.message) == 0 { name, ok := errorToString[e.Code] if !ok { panic("invalid message code") } e.message = name if e.format != "" { e.message += ": " + fmt.Sprintf(e.format, e.params...) } } return e.message } func errorf(code int, format string, params ...interface{}) *Error { return &Error{ Code: code, format: format, params: params, } } // WrappedMsg is used to propagate marshalled context alongside message payloads type WrappedMsg struct { Context []byte Size uint32 Payload []byte } //For accounting, the design is to allow the Spec to describe which and how its messages are priced //To access this functionality, we provide a Hook interface which will call accounting methods //NOTE: there could be more such (horizontal) hooks in the future type Hook interface { //A hook for sending messages Send(peer *Peer, size uint32, msg interface{}) error //A hook for receiving messages Receive(peer *Peer, size uint32, msg interface{}) error } // Spec is a protocol specification including its name and version as well as // the types of messages which are exchanged type Spec struct { // Name is the name of the protocol, often a three-letter word Name string // Version is the version number of the protocol Version uint // MaxMsgSize is the maximum accepted length of the message payload MaxMsgSize uint32 // Messages is a list of message data types which this protocol uses, with // each message type being sent with its array index as the code (so // [&foo{}, &bar{}, &baz{}] would send foo, bar and baz with codes // 0, 1 and 2 respectively) // each message must have a single unique data type Messages []interface{} //hook for accounting (could be extended to multiple hooks in the future) Hook Hook initOnce sync.Once codes map[reflect.Type]uint64 types map[uint64]reflect.Type } func (s *Spec) init() { s.initOnce.Do(func() { s.codes = make(map[reflect.Type]uint64, len(s.Messages)) s.types = make(map[uint64]reflect.Type, len(s.Messages)) for i, msg := range s.Messages { code := uint64(i) typ := reflect.TypeOf(msg) if typ.Kind() == reflect.Ptr { typ = typ.Elem() } s.codes[typ] = code s.types[code] = typ } }) } // Length returns the number of message types in the protocol func (s *Spec) Length() uint64 { return uint64(len(s.Messages)) } // GetCode returns the message code of a type, and boolean second argument is // false if the message type is not found func (s *Spec) GetCode(msg interface{}) (uint64, bool) { s.init() typ := reflect.TypeOf(msg) if typ.Kind() == reflect.Ptr { typ = typ.Elem() } code, ok := s.codes[typ] return code, ok } // NewMsg construct a new message type given the code func (s *Spec) NewMsg(code uint64) (interface{}, bool) { s.init() typ, ok := s.types[code] if !ok { return nil, false } return reflect.New(typ).Interface(), true } // Peer represents a remote peer or protocol instance that is running on a peer connection with // a remote peer type Peer struct { *p2p.Peer // the p2p.Peer object representing the remote rw p2p.MsgReadWriter // p2p.MsgReadWriter to send messages to and read messages from spec *Spec } // NewPeer constructs a new peer // this constructor is called by the p2p.Protocol#Run function // the first two arguments are the arguments passed to p2p.Protocol.Run function // the third argument is the Spec describing the protocol func NewPeer(p *p2p.Peer, rw p2p.MsgReadWriter, spec *Spec) *Peer { return &Peer{ Peer: p, rw: rw, spec: spec, } } // Run starts the forever loop that handles incoming messages // called within the p2p.Protocol#Run function // the handler argument is a function which is called for each message received // from the remote peer, a returned error causes the loop to exit // resulting in disconnection func (p *Peer) Run(handler func(ctx context.Context, msg interface{}) error) error { for { if err := p.handleIncoming(handler); err != nil { if err != io.EOF { metrics.GetOrRegisterCounter("peer.handleincoming.error", nil).Inc(1) log.Error("peer.handleIncoming", "err", err) } return err } } } // Drop disconnects a peer. // TODO: may need to implement protocol drop only? don't want to kick off the peer // if they are useful for other protocols func (p *Peer) Drop() { p.Disconnect(p2p.DiscSubprotocolError) } // Send takes a message, encodes it in RLP, finds the right message code and sends the // message off to the peer // this low level call will be wrapped by libraries providing routed or broadcast sends // but often just used to forward and push messages to directly connected peers func (p *Peer) Send(ctx context.Context, msg interface{}) error { defer metrics.GetOrRegisterResettingTimer("peer.send_t", nil).UpdateSince(time.Now()) metrics.GetOrRegisterCounter("peer.send", nil).Inc(1) var b bytes.Buffer if tracing.Enabled { writer := bufio.NewWriter(&b) tracer := opentracing.GlobalTracer() sctx := spancontext.FromContext(ctx) if sctx != nil { err := tracer.Inject( sctx, opentracing.Binary, writer) if err != nil { return err } } writer.Flush() } r, err := rlp.EncodeToBytes(msg) if err != nil { return err } wmsg := WrappedMsg{ Context: b.Bytes(), Size: uint32(len(r)), Payload: r, } //if the accounting hook is set, call it if p.spec.Hook != nil { err := p.spec.Hook.Send(p, wmsg.Size, msg) if err != nil { p.Drop() return err } } code, found := p.spec.GetCode(msg) if !found { return errorf(ErrInvalidMsgType, "%v", code) } return p2p.Send(p.rw, code, wmsg) } // handleIncoming(code) // is called each cycle of the main forever loop that dispatches incoming messages // if this returns an error the loop returns and the peer is disconnected with the error // this generic handler // * checks message size, // * checks for out-of-range message codes, // * handles decoding with reflection, // * call handlers as callbacks func (p *Peer) handleIncoming(handle func(ctx context.Context, msg interface{}) error) error { msg, err := p.rw.ReadMsg() if err != nil { return err } // make sure that the payload has been fully consumed defer msg.Discard() if msg.Size > p.spec.MaxMsgSize { return errorf(ErrMsgTooLong, "%v > %v", msg.Size, p.spec.MaxMsgSize) } // unmarshal wrapped msg, which might contain context var wmsg WrappedMsg err = msg.Decode(&wmsg) if err != nil { log.Error(err.Error()) return err } ctx := context.Background() // if tracing is enabled and the context coming within the request is // not empty, try to unmarshal it if tracing.Enabled && len(wmsg.Context) > 0 { var sctx opentracing.SpanContext tracer := opentracing.GlobalTracer() sctx, err = tracer.Extract( opentracing.Binary, bytes.NewReader(wmsg.Context)) if err != nil { log.Error(err.Error()) return err } ctx = spancontext.WithContext(ctx, sctx) } val, ok := p.spec.NewMsg(msg.Code) if !ok { return errorf(ErrInvalidMsgCode, "%v", msg.Code) } if err := rlp.DecodeBytes(wmsg.Payload, val); err != nil { return errorf(ErrDecode, "<= %v: %v", msg, err) } //if the accounting hook is set, call it if p.spec.Hook != nil { err := p.spec.Hook.Receive(p, wmsg.Size, val) if err != nil { return err } } // call the registered handler callbacks // a registered callback take the decoded message as argument as an interface // which the handler is supposed to cast to the appropriate type // it is entirely safe not to check the cast in the handler since the handler is // chosen based on the proper type in the first place if err := handle(ctx, val); err != nil { return errorf(ErrHandler, "(msg code %v): %v", msg.Code, err) } return nil } // Handshake negotiates a handshake on the peer connection // * arguments // * context // * the local handshake to be sent to the remote peer // * function to be called on the remote handshake (can be nil) // * expects a remote handshake back of the same type // * the dialing peer needs to send the handshake first and then waits for remote // * the listening peer waits for the remote handshake and then sends it // returns the remote handshake and an error func (p *Peer) Handshake(ctx context.Context, hs interface{}, verify func(interface{}) error) (interface{}, error) { if _, ok := p.spec.GetCode(hs); !ok { return nil, errorf(ErrHandshake, "unknown handshake message type: %T", hs) } var rhs interface{} errc := make(chan error, 2) handle := func(ctx context.Context, msg interface{}) error { rhs = msg if verify != nil { return verify(rhs) } return nil } send := func() { errc <- p.Send(ctx, hs) } receive := func() { errc <- p.handleIncoming(handle) } go func() { if p.Inbound() { receive() send() } else { send() receive() } }() for i := 0; i < 2; i++ { var err error select { case err = <-errc: case <-ctx.Done(): err = ctx.Err() } if err != nil { return nil, errorf(ErrHandshake, err.Error()) } } return rhs, nil } // HasCap returns true if Peer has a capability // with provided name. func (p *Peer) HasCap(capName string) (yes bool) { if p == nil || p.Peer == nil { return false } for _, c := range p.Caps() { if c.Name == capName { return true } } return false }