lnd/lnwire/open_channel.go

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package lnwire
import (
"bytes"
"io"
"github.com/btcsuite/btcd/btcec"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcutil"
"github.com/lightningnetwork/lnd/tlv"
)
// FundingFlag represents the possible bit mask values for the ChannelFlags
// field within the OpenChannel struct.
type FundingFlag uint8
const (
// FFAnnounceChannel is a FundingFlag that when set, indicates the
// initiator of a funding flow wishes to announce the channel to the
// greater network.
FFAnnounceChannel FundingFlag = 1 << iota
)
// OpenChannel is the message Alice sends to Bob if we should like to create a
// channel with Bob where she's the sole provider of funds to the channel.
// Single funder channels simplify the initial funding workflow, are supported
// by nodes backed by SPV Bitcoin clients, and have a simpler security models
// than dual funded channels.
type OpenChannel struct {
// ChainHash is the target chain that the initiator wishes to open a
// channel within.
ChainHash chainhash.Hash
// PendingChannelID serves to uniquely identify the future channel
// created by the initiated single funder workflow.
PendingChannelID [32]byte
// FundingAmount is the amount of satoshis that the initiator of the
// channel wishes to use as the total capacity of the channel. The
// initial balance of the funding will be this value minus the push
// amount (if set).
FundingAmount btcutil.Amount
// PushAmount is the value that the initiating party wishes to "push"
// to the responding as part of the first commitment state. If the
// responder accepts, then this will be their initial balance.
PushAmount MilliSatoshi
// DustLimit is the specific dust limit the sender of this message
// would like enforced on their version of the commitment transaction.
// Any output below this value will be "trimmed" from the commitment
// transaction, with the amount of the HTLC going to dust.
DustLimit btcutil.Amount
// MaxValueInFlight represents the maximum amount of coins that can be
// pending within the channel at any given time. If the amount of funds
// in limbo exceeds this amount, then the channel will be failed.
MaxValueInFlight MilliSatoshi
// ChannelReserve is the amount of BTC that the receiving party MUST
// maintain a balance above at all times. This is a safety mechanism to
// ensure that both sides always have skin in the game during the
// channel's lifetime.
ChannelReserve btcutil.Amount
// HtlcMinimum is the smallest HTLC that the sender of this message
// will accept.
HtlcMinimum MilliSatoshi
// FeePerKiloWeight is the initial fee rate that the initiator suggests
// for both commitment transaction. This value is expressed in sat per
// kilo-weight.
//
// TODO(halseth): make SatPerKWeight when fee estimation is in own
// package. Currently this will cause an import cycle.
FeePerKiloWeight uint32
// CsvDelay is the number of blocks to use for the relative time lock
// in the pay-to-self output of both commitment transactions.
CsvDelay uint16
// MaxAcceptedHTLCs is the total number of incoming HTLC's that the
// sender of this channel will accept.
MaxAcceptedHTLCs uint16
// FundingKey is the key that should be used on behalf of the sender
// within the 2-of-2 multi-sig output that it contained within the
// funding transaction.
FundingKey *btcec.PublicKey
// RevocationPoint is the base revocation point for the sending party.
// Any commitment transaction belonging to the receiver of this message
// should use this key and their per-commitment point to derive the
// revocation key for the commitment transaction.
RevocationPoint *btcec.PublicKey
// PaymentPoint is the base payment point for the sending party. This
// key should be combined with the per commitment point for a
// particular commitment state in order to create the key that should
// be used in any output that pays directly to the sending party, and
// also within the HTLC covenant transactions.
PaymentPoint *btcec.PublicKey
// DelayedPaymentPoint is the delay point for the sending party. This
// key should be combined with the per commitment point to derive the
// keys that are used in outputs of the sender's commitment transaction
// where they claim funds.
DelayedPaymentPoint *btcec.PublicKey
// HtlcPoint is the base point used to derive the set of keys for this
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// party that will be used within the HTLC public key scripts. This
// value is combined with the receiver's revocation base point in order
// to derive the keys that are used within HTLC scripts.
HtlcPoint *btcec.PublicKey
// FirstCommitmentPoint is the first commitment point for the sending
// party. This value should be combined with the receiver's revocation
// base point in order to derive the revocation keys that are placed
// within the commitment transaction of the sender.
FirstCommitmentPoint *btcec.PublicKey
// ChannelFlags is a bit-field which allows the initiator of the
// channel to specify further behavior surrounding the channel.
// Currently, the least significant bit of this bit field indicates the
// initiator of the channel wishes to advertise this channel publicly.
ChannelFlags FundingFlag
// UpfrontShutdownScript is the script to which the channel funds should
// be paid when mutually closing the channel. This field is optional, and
// and has a length prefix, so a zero will be written if it is not set
// and its length followed by the script will be written if it is set.
UpfrontShutdownScript DeliveryAddress
// ChannelType is the explicit channel type the initiator wishes to
// open.
ChannelType *ChannelType
// LeaseExpiry represents the absolute expiration height of a channel
// lease. This is a custom TLV record that will only apply when a leased
// channel is being opened using the script enforced lease commitment
// type.
LeaseExpiry *LeaseExpiry
// ExtraData is the set of data that was appended to this message to
// fill out the full maximum transport message size. These fields can
// be used to specify optional data such as custom TLV fields.
//
// NOTE: Since the upfront shutdown script MUST be present (though can
// be zero-length) if any TLV data is available, the script will be
// extracted and removed from this blob when decoding. ExtraData will
// contain all TLV records _except_ the DeliveryAddress record in that
// case.
ExtraData ExtraOpaqueData
}
// A compile time check to ensure OpenChannel implements the lnwire.Message
// interface.
var _ Message = (*OpenChannel)(nil)
// Encode serializes the target OpenChannel into the passed io.Writer
// implementation. Serialization will observe the rules defined by the passed
// protocol version.
//
func (o *OpenChannel) Encode(w *bytes.Buffer, pver uint32) error {
recordProducers := []tlv.RecordProducer{&o.UpfrontShutdownScript}
if o.ChannelType != nil {
recordProducers = append(recordProducers, o.ChannelType)
}
if o.LeaseExpiry != nil {
recordProducers = append(recordProducers, o.LeaseExpiry)
}
err := EncodeMessageExtraData(&o.ExtraData, recordProducers...)
if err != nil {
return err
}
if err := WriteBytes(w, o.ChainHash[:]); err != nil {
return err
}
if err := WriteBytes(w, o.PendingChannelID[:]); err != nil {
return err
}
if err := WriteSatoshi(w, o.FundingAmount); err != nil {
return err
}
if err := WriteMilliSatoshi(w, o.PushAmount); err != nil {
return err
}
if err := WriteSatoshi(w, o.DustLimit); err != nil {
return err
}
if err := WriteMilliSatoshi(w, o.MaxValueInFlight); err != nil {
return err
}
if err := WriteSatoshi(w, o.ChannelReserve); err != nil {
return err
}
if err := WriteMilliSatoshi(w, o.HtlcMinimum); err != nil {
return err
}
if err := WriteUint32(w, o.FeePerKiloWeight); err != nil {
return err
}
if err := WriteUint16(w, o.CsvDelay); err != nil {
return err
}
if err := WriteUint16(w, o.MaxAcceptedHTLCs); err != nil {
return err
}
if err := WritePublicKey(w, o.FundingKey); err != nil {
return err
}
if err := WritePublicKey(w, o.RevocationPoint); err != nil {
return err
}
if err := WritePublicKey(w, o.PaymentPoint); err != nil {
return err
}
if err := WritePublicKey(w, o.DelayedPaymentPoint); err != nil {
return err
}
if err := WritePublicKey(w, o.HtlcPoint); err != nil {
return err
}
if err := WritePublicKey(w, o.FirstCommitmentPoint); err != nil {
return err
}
if err := WriteFundingFlag(w, o.ChannelFlags); err != nil {
return err
}
return WriteBytes(w, o.ExtraData)
}
// Decode deserializes the serialized OpenChannel stored in the passed
// io.Reader into the target OpenChannel using the deserialization rules
// defined by the passed protocol version.
//
// This is part of the lnwire.Message interface.
func (o *OpenChannel) Decode(r io.Reader, pver uint32) error {
// Read all the mandatory fields in the open message.
err := ReadElements(r,
o.ChainHash[:],
o.PendingChannelID[:],
&o.FundingAmount,
&o.PushAmount,
&o.DustLimit,
&o.MaxValueInFlight,
&o.ChannelReserve,
&o.HtlcMinimum,
&o.FeePerKiloWeight,
&o.CsvDelay,
&o.MaxAcceptedHTLCs,
&o.FundingKey,
&o.RevocationPoint,
&o.PaymentPoint,
&o.DelayedPaymentPoint,
&o.HtlcPoint,
&o.FirstCommitmentPoint,
&o.ChannelFlags,
)
if err != nil {
return err
}
// For backwards compatibility, the optional extra data blob for
// OpenChannel must contain an entry for the upfront shutdown script.
// We'll read it out and attempt to parse it.
var tlvRecords ExtraOpaqueData
if err := ReadElements(r, &tlvRecords); err != nil {
return err
}
// Next we'll parse out the set of known records, keeping the raw tlv
// bytes untouched to ensure we don't drop any bytes erroneously.
var (
chanType ChannelType
leaseExpiry LeaseExpiry
)
typeMap, err := tlvRecords.ExtractRecords(
&o.UpfrontShutdownScript, &chanType, &leaseExpiry,
)
if err != nil {
return err
}
// Set the corresponding TLV types if they were included in the stream.
if val, ok := typeMap[ChannelTypeRecordType]; ok && val == nil {
o.ChannelType = &chanType
}
if val, ok := typeMap[LeaseExpiryRecordType]; ok && val == nil {
o.LeaseExpiry = &leaseExpiry
}
o.ExtraData = tlvRecords
return nil
}
// MsgType returns the MessageType code which uniquely identifies this message
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// as an OpenChannel on the wire.
//
// This is part of the lnwire.Message interface.
func (o *OpenChannel) MsgType() MessageType {
return MsgOpenChannel
}