lnd.xprv/lnwire/message.go
BitfuryLightning 327768f4ad routing: Move tools inside lnd. Refactor and delete unneeded stuff
Use [33]byte for graph vertex representation.
Delete unneeded stuff:
1. DeepEqual for graph comparison
2. EdgePath
3. 2-thread BFS
4. Table transfer messages and neighborhood radius
5. Beacons

Refactor:
1. Change ID to Vertex
2. Test use table driven approach
3. Add comments
4. Make graph internal representation private
5. Use wire.OutPoint as  EdgeId
6. Decouple routing messages from routing implementation
7. Delete Async methods
8. Delete unneeded channels and priority buffer from manager
9. Delete unneeded interfaces in internal graph realisation
10. Renamed ID to Vertex
2016-11-23 20:37:43 -06:00

310 lines
9.1 KiB
Go

// Code derived from https:// github.com/btcsuite/btcd/blob/master/wire/message.go
package lnwire
import (
"bytes"
"fmt"
"io"
"github.com/roasbeef/btcd/wire"
)
// MessageHeaderSize is the number of bytes in a lightning message header.
// The bytes are allocated as follows: network magic 4 bytes + command 4
// bytes + payload length 4 bytes. Note that a checksum is omitted as lightning
// messages are assumed to be transmitted over an AEAD secured connection which
// provides integrity over the entire message.
const MessageHeaderSize = 12
// MaxMessagePayload is the maximum bytes a message can be regardless of other
// individual limits imposed by messages themselves.
const MaxMessagePayload = 1024 * 1024 * 32 // 32MB
// Commands used in lightning message headers which detail the type of message.
const (
// Commands for opening a channel funded by one party (single funder).
CmdSingleFundingRequest = uint32(100)
CmdSingleFundingResponse = uint32(110)
CmdSingleFundingComplete = uint32(120)
CmdSingleFundingSignComplete = uint32(130)
CmdSingleFundingOpenProof = uint32(140)
// Commands for the workflow of cooperatively closing an active channel.
CmdCloseRequest = uint32(300)
CmdCloseComplete = uint32(310)
// Commands for negotiating HTLCs.
CmdHTLCAddRequest = uint32(1000)
CmdHTLCAddAccept = uint32(1010)
CmdHTLCAddReject = uint32(1020)
CmdHTLCSettleRequest = uint32(1100)
CmdCancelHTLC = uint32(1300)
// Commands for modifying commitment transactions.
CmdCommitSignature = uint32(2000)
CmdCommitRevocation = uint32(2010)
// Commands for routing
CmdNeighborHelloMessage = uint32(3000)
CmdNeighborUpdMessage = uint32(3010)
CmdNeighborAckMessage = uint32(3020)
CmdNeighborRstMessage = uint32(3030)
CmdRoutingTableRequestMessage = uint32(3040)
CmdRoutingTableTransferMessage = uint32(3050)
// Commands for reporting protocol errors.
CmdErrorGeneric = uint32(4000)
// Commands for connection keep-alive.
CmdPing = uint32(5000)
CmdPong = uint32(5010)
)
// Message is an interface that defines a lightning wire protocol message. The
// interface is general in order to allow implementing types full control over
// the representation of its data.
type Message interface {
Decode(io.Reader, uint32) error
Encode(io.Writer, uint32) error
Command() uint32
MaxPayloadLength(uint32) uint32
Validate() error
String() string
}
// makeEmptyMessage creates a new empty message of the proper concrete type
// based on the command ID.
func makeEmptyMessage(command uint32) (Message, error) {
var msg Message
switch command {
case CmdSingleFundingRequest:
msg = &SingleFundingRequest{}
case CmdSingleFundingResponse:
msg = &SingleFundingResponse{}
case CmdSingleFundingComplete:
msg = &SingleFundingComplete{}
case CmdSingleFundingSignComplete:
msg = &SingleFundingSignComplete{}
case CmdSingleFundingOpenProof:
msg = &SingleFundingOpenProof{}
case CmdCloseRequest:
msg = &CloseRequest{}
case CmdCloseComplete:
msg = &CloseComplete{}
case CmdHTLCAddRequest:
msg = &HTLCAddRequest{}
case CmdHTLCAddReject:
msg = &HTLCAddReject{}
case CmdHTLCSettleRequest:
msg = &HTLCSettleRequest{}
case CmdCancelHTLC:
msg = &CancelHTLC{}
case CmdCommitSignature:
msg = &CommitSignature{}
case CmdCommitRevocation:
msg = &CommitRevocation{}
case CmdErrorGeneric:
msg = &ErrorGeneric{}
case CmdNeighborHelloMessage:
msg = &NeighborHelloMessage{}
case CmdNeighborUpdMessage:
msg = &NeighborUpdMessage{}
case CmdNeighborAckMessage:
msg = &NeighborAckMessage{}
case CmdNeighborRstMessage:
msg = &NeighborRstMessage{}
case CmdPing:
msg = &Ping{}
case CmdPong:
msg = &Pong{}
default:
return nil, fmt.Errorf("unhandled command [%d]", command)
}
return msg, nil
}
// messageHeader represents the header structure for all lightning protocol
// messages.
type messageHeader struct {
// magic represents Which Blockchain Technology(TM) to use.
// NOTE(j): We don't need to worry about the magic overlapping with
// bitcoin since this is inside encrypted comms anyway, but maybe we
// should use the XOR (^wire.TestNet3) just in case???
magic wire.BitcoinNet // 4 bytes
command uint32 // 4 bytes
length uint32 // 4 bytes
}
// readMessageHeader reads a lightning protocol message header from r.
func readMessageHeader(r io.Reader) (int, *messageHeader, error) {
// As the message header is a fixed size structure, read bytes for the
// entire header at once.
var headerBytes [MessageHeaderSize]byte
n, err := io.ReadFull(r, headerBytes[:])
if err != nil {
return n, nil, err
}
hr := bytes.NewReader(headerBytes[:])
// Create and populate the message header from the raw header bytes.
hdr := messageHeader{}
err = readElements(hr,
&hdr.magic,
&hdr.command,
&hdr.length)
if err != nil {
return n, nil, err
}
return n, &hdr, nil
}
// discardInput reads n bytes from reader r in chunks and discards the read
// bytes. This is used to skip payloads when various errors occur and helps
// prevent rogue nodes from causing massive memory allocation through forging
// header length.
func discardInput(r io.Reader, n uint32) {
maxSize := uint32(10 * 1024) // 10k at a time
numReads := n / maxSize
bytesRemaining := n % maxSize
if n > 0 {
buf := make([]byte, maxSize)
for i := uint32(0); i < numReads; i++ {
io.ReadFull(r, buf)
}
}
if bytesRemaining > 0 {
buf := make([]byte, bytesRemaining)
io.ReadFull(r, buf)
}
}
// WriteMessage writes a lightning Message to w including the necessary header
// information and returns the number of bytes written.
func WriteMessage(w io.Writer, msg Message, pver uint32, btcnet wire.BitcoinNet) (int, error) {
totalBytes := 0
cmd := msg.Command()
// Encode the message payload
var bw bytes.Buffer
err := msg.Encode(&bw, pver)
if err != nil {
return totalBytes, err
}
payload := bw.Bytes()
lenp := len(payload)
// Enforce maximum overall message payload
if lenp > MaxMessagePayload {
return totalBytes, fmt.Errorf("message payload is too large - "+
"encoded %d bytes, but maximum message payload is %d bytes",
lenp, MaxMessagePayload)
}
// Enforce maximum message payload on the message type
mpl := msg.MaxPayloadLength(pver)
if uint32(lenp) > mpl {
return totalBytes, fmt.Errorf("message payload is too large - "+
"encoded %d bytes, but maximum message payload of "+
"type %x is %d bytes", lenp, cmd, mpl)
}
// Create header for the message.
hdr := messageHeader{magic: btcnet, command: cmd, length: uint32(lenp)}
// Encode the header for the message. This is done to a buffer
// rather than directly to the writer since writeElements doesn't
// return the number of bytes written.
hw := bytes.NewBuffer(make([]byte, 0, MessageHeaderSize))
if err := writeElements(hw, hdr.magic, hdr.command, hdr.length); err != nil {
return 0, nil
}
// Write the header first.
n, err := w.Write(hw.Bytes())
totalBytes += n
if err != nil {
return totalBytes, err
}
// Write payload the payload itself after the header.
n, err = w.Write(payload)
totalBytes += n
if err != nil {
return totalBytes, err
}
return totalBytes, nil
}
// ReadMessageN reads, validates, and parses the next bitcoin Message from r for
// the provided protocol version and bitcoin network. It returns the number of
// bytes read in addition to the parsed Message and raw bytes which comprise the
// message. This function is the same as ReadMessage except it also returns the
// number of bytes read.
func ReadMessage(r io.Reader, pver uint32, btcnet wire.BitcoinNet) (int, Message, []byte, error) {
totalBytes := 0
n, hdr, err := readMessageHeader(r)
totalBytes += n
if err != nil {
return totalBytes, nil, nil, err
}
// Enforce maximum message payload
if hdr.length > MaxMessagePayload {
return totalBytes, nil, nil, fmt.Errorf("message payload is "+
"too large - header indicates %d bytes, but max "+
"message payload is %d bytes.", hdr.length,
MaxMessagePayload)
}
// Check for messages in the wrong network.
if hdr.magic != btcnet {
discardInput(r, hdr.length)
return totalBytes, nil, nil, fmt.Errorf("message from other "+
"network [%v]", hdr.magic)
}
// Create struct of appropriate message type based on the command.
command := hdr.command
msg, err := makeEmptyMessage(command)
if err != nil {
discardInput(r, hdr.length)
return totalBytes, nil, nil, fmt.Errorf("ReadMessage %s",
err.Error())
}
// Check for maximum length based on the message type.
mpl := msg.MaxPayloadLength(pver)
if hdr.length > mpl {
discardInput(r, hdr.length)
return totalBytes, nil, nil, fmt.Errorf("payload exceeds max "+
"length. indicates %v bytes, but max of message type %v is %v.",
hdr.length, command, mpl)
}
// Read payload.
payload := make([]byte, hdr.length)
n, err = io.ReadFull(r, payload)
totalBytes += n
if err != nil {
return totalBytes, nil, nil, err
}
// Unmarshal message.
pr := bytes.NewBuffer(payload)
if err = msg.Decode(pr, pver); err != nil {
return totalBytes, nil, nil, err
}
// Validate the data.
if err = msg.Validate(); err != nil {
return totalBytes, nil, nil, err
}
return totalBytes, msg, payload, nil
}