forked from cerc-io/plugeth
5110f80bba
There are now two deadlines, frameReadTimeout and payloadReadTimeout. The frame timeout is longer and allows for connections that are idle. The message timeout is still short and ensures that we don't get stuck in the middle of a message.
358 lines
9.4 KiB
Go
358 lines
9.4 KiB
Go
package p2p
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import (
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"bufio"
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"bytes"
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"encoding/binary"
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"errors"
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"fmt"
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"io"
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"io/ioutil"
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"math/big"
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"net"
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"sync"
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"sync/atomic"
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"time"
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"github.com/ethereum/go-ethereum/ethutil"
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"github.com/ethereum/go-ethereum/rlp"
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)
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// parameters for frameRW
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const (
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// maximum time allowed for reading a message header.
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// this is effectively the amount of time a connection can be idle.
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frameReadTimeout = 1 * time.Minute
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// maximum time allowed for reading the payload data of a message.
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// this is shorter than (and distinct from) frameReadTimeout because
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// the connection is not considered idle while a message is transferred.
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// this also limits the payload size of messages to how much the connection
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// can transfer within the timeout.
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payloadReadTimeout = 5 * time.Second
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// maximum amount of time allowed for writing a complete message.
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msgWriteTimeout = 5 * time.Second
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// messages smaller than this many bytes will be read at
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// once before passing them to a protocol. this increases
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// concurrency in the processing.
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wholePayloadSize = 64 * 1024
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)
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// Msg defines the structure of a p2p message.
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//
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// Note that a Msg can only be sent once since the Payload reader is
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// consumed during sending. It is not possible to create a Msg and
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// send it any number of times. If you want to reuse an encoded
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// structure, encode the payload into a byte array and create a
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// separate Msg with a bytes.Reader as Payload for each send.
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type Msg struct {
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Code uint64
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Size uint32 // size of the paylod
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Payload io.Reader
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}
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// NewMsg creates an RLP-encoded message with the given code.
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func NewMsg(code uint64, params ...interface{}) Msg {
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buf := new(bytes.Buffer)
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for _, p := range params {
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buf.Write(ethutil.Encode(p))
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}
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return Msg{Code: code, Size: uint32(buf.Len()), Payload: buf}
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}
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func encodePayload(params ...interface{}) []byte {
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buf := new(bytes.Buffer)
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for _, p := range params {
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buf.Write(ethutil.Encode(p))
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}
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return buf.Bytes()
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}
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// Decode parse the RLP content of a message into
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// the given value, which must be a pointer.
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//
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// For the decoding rules, please see package rlp.
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func (msg Msg) Decode(val interface{}) error {
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s := rlp.NewListStream(msg.Payload, uint64(msg.Size))
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if err := s.Decode(val); err != nil {
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return newPeerError(errInvalidMsg, "(code %#x) (size %d) %v", msg.Code, msg.Size, err)
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}
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return nil
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}
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func (msg Msg) String() string {
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return fmt.Sprintf("msg #%v (%v bytes)", msg.Code, msg.Size)
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}
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// Discard reads any remaining payload data into a black hole.
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func (msg Msg) Discard() error {
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_, err := io.Copy(ioutil.Discard, msg.Payload)
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return err
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}
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type MsgReader interface {
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ReadMsg() (Msg, error)
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}
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type MsgWriter interface {
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// WriteMsg sends a message. It will block until the message's
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// Payload has been consumed by the other end.
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//
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// Note that messages can be sent only once because their
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// payload reader is drained.
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WriteMsg(Msg) error
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}
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// MsgReadWriter provides reading and writing of encoded messages.
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// Implementations should ensure that ReadMsg and WriteMsg can be
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// called simultaneously from multiple goroutines.
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type MsgReadWriter interface {
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MsgReader
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MsgWriter
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}
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// EncodeMsg writes an RLP-encoded message with the given code and
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// data elements.
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func EncodeMsg(w MsgWriter, code uint64, data ...interface{}) error {
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return w.WriteMsg(NewMsg(code, data...))
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}
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// frameRW is a MsgReadWriter that reads and writes devp2p message frames.
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// As required by the interface, ReadMsg and WriteMsg can be called from
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// multiple goroutines.
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type frameRW struct {
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net.Conn // make Conn methods available. be careful.
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bufconn *bufio.ReadWriter
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// this channel is used to 'lend' bufconn to a caller of ReadMsg
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// until the message payload has been consumed. the channel
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// receives a value when EOF is reached on the payload, unblocking
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// a pending call to ReadMsg.
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rsync chan struct{}
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// this mutex guards writes to bufconn.
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writeMu sync.Mutex
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}
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func newFrameRW(conn net.Conn, timeout time.Duration) *frameRW {
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rsync := make(chan struct{}, 1)
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rsync <- struct{}{}
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return &frameRW{
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Conn: conn,
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bufconn: bufio.NewReadWriter(bufio.NewReader(conn), bufio.NewWriter(conn)),
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rsync: rsync,
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}
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}
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var magicToken = []byte{34, 64, 8, 145}
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func (rw *frameRW) WriteMsg(msg Msg) error {
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rw.writeMu.Lock()
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defer rw.writeMu.Unlock()
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rw.SetWriteDeadline(time.Now().Add(msgWriteTimeout))
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if err := writeMsg(rw.bufconn, msg); err != nil {
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return err
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}
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return rw.bufconn.Flush()
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}
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func writeMsg(w io.Writer, msg Msg) error {
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// TODO: handle case when Size + len(code) + len(listhdr) overflows uint32
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code := ethutil.Encode(uint32(msg.Code))
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listhdr := makeListHeader(msg.Size + uint32(len(code)))
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payloadLen := uint32(len(listhdr)) + uint32(len(code)) + msg.Size
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start := make([]byte, 8)
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copy(start, magicToken)
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binary.BigEndian.PutUint32(start[4:], payloadLen)
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for _, b := range [][]byte{start, listhdr, code} {
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if _, err := w.Write(b); err != nil {
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return err
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}
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}
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_, err := io.CopyN(w, msg.Payload, int64(msg.Size))
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return err
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}
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func makeListHeader(length uint32) []byte {
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if length < 56 {
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return []byte{byte(length + 0xc0)}
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}
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enc := big.NewInt(int64(length)).Bytes()
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lenb := byte(len(enc)) + 0xf7
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return append([]byte{lenb}, enc...)
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}
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func (rw *frameRW) ReadMsg() (msg Msg, err error) {
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<-rw.rsync // wait until bufconn is ours
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rw.SetReadDeadline(time.Now().Add(frameReadTimeout))
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// read magic and payload size
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start := make([]byte, 8)
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if _, err = io.ReadFull(rw.bufconn, start); err != nil {
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return msg, err
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}
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if !bytes.HasPrefix(start, magicToken) {
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return msg, fmt.Errorf("bad magic token %x", start[:4], magicToken)
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}
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size := binary.BigEndian.Uint32(start[4:])
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// decode start of RLP message to get the message code
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posr := &postrack{rw.bufconn, 0}
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s := rlp.NewStream(posr)
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if _, err := s.List(); err != nil {
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return msg, err
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}
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msg.Code, err = s.Uint()
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if err != nil {
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return msg, err
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}
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msg.Size = size - posr.p
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rw.SetReadDeadline(time.Now().Add(payloadReadTimeout))
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if msg.Size <= wholePayloadSize {
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// msg is small, read all of it and move on to the next message.
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pbuf := make([]byte, msg.Size)
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if _, err := io.ReadFull(rw.bufconn, pbuf); err != nil {
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return msg, err
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}
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rw.rsync <- struct{}{} // bufconn is available again
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msg.Payload = bytes.NewReader(pbuf)
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} else {
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// lend bufconn to the caller until it has
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// consumed the payload. eofSignal will send a value
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// on rw.rsync when EOF is reached.
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pr := &eofSignal{rw.bufconn, msg.Size, rw.rsync}
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msg.Payload = pr
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}
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return msg, nil
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}
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// postrack wraps an rlp.ByteReader with a position counter.
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type postrack struct {
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r rlp.ByteReader
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p uint32
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}
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func (r *postrack) Read(buf []byte) (int, error) {
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n, err := r.r.Read(buf)
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r.p += uint32(n)
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return n, err
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}
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func (r *postrack) ReadByte() (byte, error) {
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b, err := r.r.ReadByte()
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if err == nil {
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r.p++
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}
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return b, err
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}
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// eofSignal wraps a reader with eof signaling. the eof channel is
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// closed when the wrapped reader returns an error or when count bytes
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// have been read.
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type eofSignal struct {
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wrapped io.Reader
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count uint32 // number of bytes left
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eof chan<- struct{}
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}
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// note: when using eofSignal to detect whether a message payload
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// has been read, Read might not be called for zero sized messages.
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func (r *eofSignal) Read(buf []byte) (int, error) {
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if r.count == 0 {
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if r.eof != nil {
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r.eof <- struct{}{}
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r.eof = nil
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}
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return 0, io.EOF
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}
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max := len(buf)
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if int(r.count) < len(buf) {
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max = int(r.count)
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}
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n, err := r.wrapped.Read(buf[:max])
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r.count -= uint32(n)
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if (err != nil || r.count == 0) && r.eof != nil {
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r.eof <- struct{}{} // tell Peer that msg has been consumed
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r.eof = nil
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}
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return n, err
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}
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// MsgPipe creates a message pipe. Reads on one end are matched
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// with writes on the other. The pipe is full-duplex, both ends
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// implement MsgReadWriter.
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func MsgPipe() (*MsgPipeRW, *MsgPipeRW) {
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var (
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c1, c2 = make(chan Msg), make(chan Msg)
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closing = make(chan struct{})
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closed = new(int32)
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rw1 = &MsgPipeRW{c1, c2, closing, closed}
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rw2 = &MsgPipeRW{c2, c1, closing, closed}
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)
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return rw1, rw2
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}
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// ErrPipeClosed is returned from pipe operations after the
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// pipe has been closed.
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var ErrPipeClosed = errors.New("p2p: read or write on closed message pipe")
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// MsgPipeRW is an endpoint of a MsgReadWriter pipe.
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type MsgPipeRW struct {
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w chan<- Msg
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r <-chan Msg
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closing chan struct{}
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closed *int32
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}
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// WriteMsg sends a messsage on the pipe.
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// It blocks until the receiver has consumed the message payload.
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func (p *MsgPipeRW) WriteMsg(msg Msg) error {
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if atomic.LoadInt32(p.closed) == 0 {
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consumed := make(chan struct{}, 1)
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msg.Payload = &eofSignal{msg.Payload, msg.Size, consumed}
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select {
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case p.w <- msg:
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if msg.Size > 0 {
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// wait for payload read or discard
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<-consumed
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}
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return nil
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case <-p.closing:
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}
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}
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return ErrPipeClosed
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}
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// ReadMsg returns a message sent on the other end of the pipe.
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func (p *MsgPipeRW) ReadMsg() (Msg, error) {
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if atomic.LoadInt32(p.closed) == 0 {
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select {
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case msg := <-p.r:
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return msg, nil
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case <-p.closing:
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}
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}
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return Msg{}, ErrPipeClosed
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}
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// Close unblocks any pending ReadMsg and WriteMsg calls on both ends
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// of the pipe. They will return ErrPipeClosed. Note that Close does
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// not interrupt any reads from a message payload.
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func (p *MsgPipeRW) Close() error {
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if atomic.AddInt32(p.closed, 1) != 1 {
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// someone else is already closing
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atomic.StoreInt32(p.closed, 1) // avoid overflow
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return nil
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}
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close(p.closing)
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return nil
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}
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