lnd.xprv/channeldb/reports.go

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package channeldb
import (
"bytes"
"errors"
"io"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
"github.com/lightningnetwork/lnd/channeldb/kvdb"
"github.com/lightningnetwork/lnd/tlv"
)
var (
// closeSummaryBucket is a top level bucket which holds additional
// information about channel closes. It nests channels by chainhash
// and channel point.
// [closeSummaryBucket]
// [chainHashBucket]
// [channelBucket]
// [resolversBucket]
closeSummaryBucket = []byte("close-summaries")
// resolversBucket holds the outcome of a channel's resolvers. It is
// nested under a channel and chainhash bucket in the close summaries
// bucket.
resolversBucket = []byte("resolvers-bucket")
)
var (
// ErrNoChainHashBucket is returned when we have not created a bucket
// for the current chain hash.
ErrNoChainHashBucket = errors.New("no chain hash bucket")
// ErrNoChannelSummaries is returned when a channel is not found in the
// chain hash bucket.
ErrNoChannelSummaries = errors.New("channel bucket not found")
amountType tlv.Type = 1
resolverType tlv.Type = 2
outcomeType tlv.Type = 3
spendTxIDType tlv.Type = 4
)
// ResolverType indicates the type of resolver that was resolved on chain.
type ResolverType uint8
const (
// ResolverTypeAnchor represents a resolver for an anchor output.
ResolverTypeAnchor ResolverType = 0
// ResolverTypeIncomingHtlc represents resolution of an incoming htlc.
ResolverTypeIncomingHtlc ResolverType = 1
// ResolverTypeOutgoingHtlc represents resolution of an outgoing htlc.
ResolverTypeOutgoingHtlc ResolverType = 2
)
// ResolverOutcome indicates the outcome for the resolver that that the contract
// court reached. This state is not necessarily final, since htlcs on our own
// commitment are resolved across two resolvers.
type ResolverOutcome uint8
const (
// ResolverOutcomeClaimed indicates that funds were claimed on chain.
ResolverOutcomeClaimed ResolverOutcome = 0
// ResolverOutcomeUnclaimed indicates that we did not claim our funds on
// chain. This may be the case for anchors that we did not sweep, or
// outputs that were not economical to sweep.
ResolverOutcomeUnclaimed ResolverOutcome = 1
// ResolverOutcomeAbandoned indicates that we did not attempt to claim
// an output on chain. This is the case for htlcs that we could not
// decode to claim, or invoice which we fail when an attempt is made
// to settle them on chain.
ResolverOutcomeAbandoned ResolverOutcome = 2
// ResolverOutcomeTimeout indicates that a contract was timed out on
// chain.
ResolverOutcomeTimeout ResolverOutcome = 3
// ResolverOutcomeFirstStage indicates that a htlc had to be claimed
// over two stages, with this outcome representing the confirmation
// of our success/timeout tx.
ResolverOutcomeFirstStage ResolverOutcome = 4
)
// ResolverReport provides an account of the outcome of a resolver. This differs
// from a ContractReport because it does not necessarily fully resolve the
// contract; each step of two stage htlc resolution is included.
type ResolverReport struct {
// OutPoint is the on chain outpoint that was spent as a result of this
// resolution. When an output is directly resolved (eg, commitment
// sweeps and single stage htlcs on the remote party's output) this
// is an output on the commitment tx that was broadcast. When we resolve
// across two stages (eg, htlcs on our own force close commit), the
// first stage outpoint is the output on our commitment and the second
// stage output is the spend from our htlc success/timeout tx.
OutPoint wire.OutPoint
// Amount is the value of the output referenced above.
Amount btcutil.Amount
// ResolverType indicates the type of resolution that occurred.
ResolverType
// ResolverOutcome indicates the outcome of the resolver.
ResolverOutcome
// SpendTxID is the transaction ID of the spending transaction that
// claimed the outpoint. This may be a sweep transaction, or a first
// stage success/timeout transaction.
SpendTxID *chainhash.Hash
}
// PutResolverReport creates and commits a transaction that is used to write a
// resolver report to disk.
func (d *DB) PutResolverReport(tx kvdb.RwTx, chainHash chainhash.Hash,
channelOutpoint *wire.OutPoint, report *ResolverReport) error {
putReportFunc := func(tx kvdb.RwTx) error {
return putReport(tx, chainHash, channelOutpoint, report)
}
// If the transaction is nil, we'll create a new one.
if tx == nil {
return kvdb.Update(d, putReportFunc)
}
// Otherwise, we can write the report to disk using the existing
// transaction.
return putReportFunc(tx)
}
// putReport puts a report in the bucket provided, with its outpoint as its key.
func putReport(tx kvdb.RwTx, chainHash chainhash.Hash,
channelOutpoint *wire.OutPoint, report *ResolverReport) error {
channelBucket, err := fetchReportWriteBucket(
tx, chainHash, channelOutpoint,
)
if err != nil {
return err
}
// If the resolvers bucket does not exist yet, create it.
resolvers, err := channelBucket.CreateBucketIfNotExists(
resolversBucket,
)
if err != nil {
return err
}
var valueBuf bytes.Buffer
if err := serializeReport(&valueBuf, report); err != nil {
return err
}
// Finally write our outpoint to be used as the key for this record.
var keyBuf bytes.Buffer
if err := writeOutpoint(&keyBuf, &report.OutPoint); err != nil {
return err
}
return resolvers.Put(keyBuf.Bytes(), valueBuf.Bytes())
}
// serializeReport serialized a report using a TLV stream to allow for optional
// fields.
func serializeReport(w io.Writer, report *ResolverReport) error {
amt := uint64(report.Amount)
resolver := uint8(report.ResolverType)
outcome := uint8(report.ResolverOutcome)
// Create a set of TLV records for the values we know to be present.
records := []tlv.Record{
tlv.MakePrimitiveRecord(amountType, &amt),
tlv.MakePrimitiveRecord(resolverType, &resolver),
tlv.MakePrimitiveRecord(outcomeType, &outcome),
}
// If our spend txid is non-nil, we add a tlv entry for it.
if report.SpendTxID != nil {
var spendBuf bytes.Buffer
err := WriteElement(&spendBuf, *report.SpendTxID)
if err != nil {
return err
}
spendBytes := spendBuf.Bytes()
records = append(records, tlv.MakePrimitiveRecord(
spendTxIDType, &spendBytes,
))
}
// Create our stream and encode it.
tlvStream, err := tlv.NewStream(records...)
if err != nil {
return err
}
return tlvStream.Encode(w)
}
// FetchChannelReports fetches the set of reports for a channel.
func (d DB) FetchChannelReports(chainHash chainhash.Hash,
outPoint *wire.OutPoint) ([]*ResolverReport, error) {
var reports []*ResolverReport
if err := kvdb.View(d, func(tx kvdb.RTx) error {
chanBucket, err := fetchReportReadBucket(
tx, chainHash, outPoint,
)
if err != nil {
return err
}
// If there are no resolvers for this channel, we simply
// return nil, because nothing has been persisted yet.
resolvers := chanBucket.NestedReadBucket(resolversBucket)
if resolvers == nil {
return nil
}
// Run through each resolution and add it to our set of
// resolutions.
return resolvers.ForEach(func(k, v []byte) error {
// Deserialize the contents of our field.
r := bytes.NewReader(v)
report, err := deserializeReport(r)
if err != nil {
return err
}
// Once we have read our values out, set the outpoint
// on the report using the key.
r = bytes.NewReader(k)
if err := ReadElement(r, &report.OutPoint); err != nil {
return err
}
reports = append(reports, report)
return nil
})
}); err != nil {
return nil, err
}
return reports, nil
}
// deserializeReport gets a resolver report from a tlv stream. The outpoint on
// the resolver will not be set because we key reports by their outpoint, and
// this function reads only the values saved in the stream.
func deserializeReport(r io.Reader) (*ResolverReport, error) {
var (
resolver, outcome uint8
amt uint64
spentTx []byte
)
tlvStream, err := tlv.NewStream(
tlv.MakePrimitiveRecord(amountType, &amt),
tlv.MakePrimitiveRecord(resolverType, &resolver),
tlv.MakePrimitiveRecord(outcomeType, &outcome),
tlv.MakePrimitiveRecord(spendTxIDType, &spentTx),
)
if err != nil {
return nil, err
}
if err := tlvStream.Decode(r); err != nil {
return nil, err
}
report := &ResolverReport{
Amount: btcutil.Amount(amt),
ResolverOutcome: ResolverOutcome(outcome),
ResolverType: ResolverType(resolver),
}
// If our spend tx is set, we set it on our report.
if len(spentTx) != 0 {
spendTx, err := chainhash.NewHash(spentTx)
if err != nil {
return nil, err
}
report.SpendTxID = spendTx
}
return report, nil
}
// fetchReportWriteBucket returns a write channel bucket within the reports
// top level bucket. If the channel's bucket does not yet exist, it will be
// created.
func fetchReportWriteBucket(tx kvdb.RwTx, chainHash chainhash.Hash,
outPoint *wire.OutPoint) (kvdb.RwBucket, error) {
// Get the channel close summary bucket.
closedBucket := tx.ReadWriteBucket(closeSummaryBucket)
// Create the chain hash bucket if it does not exist.
chainHashBkt, err := closedBucket.CreateBucketIfNotExists(chainHash[:])
if err != nil {
return nil, err
}
var chanPointBuf bytes.Buffer
if err := writeOutpoint(&chanPointBuf, outPoint); err != nil {
return nil, err
}
return chainHashBkt.CreateBucketIfNotExists(chanPointBuf.Bytes())
}
// fetchReportReadBucket returns a read channel bucket within the reports
// top level bucket. If any bucket along the way does not exist, it will error.
func fetchReportReadBucket(tx kvdb.RTx, chainHash chainhash.Hash,
outPoint *wire.OutPoint) (kvdb.RBucket, error) {
// First fetch the top level channel close summary bucket.
closeBucket := tx.ReadBucket(closeSummaryBucket)
// Next we get the chain hash bucket for our current chain.
chainHashBucket := closeBucket.NestedReadBucket(chainHash[:])
if chainHashBucket == nil {
return nil, ErrNoChainHashBucket
}
// With the bucket for the node and chain fetched, we can now go down
// another level, for the channel itself.
var chanPointBuf bytes.Buffer
if err := writeOutpoint(&chanPointBuf, outPoint); err != nil {
return nil, err
}
chanBucket := chainHashBucket.NestedReadBucket(chanPointBuf.Bytes())
if chanBucket == nil {
return nil, ErrNoChannelSummaries
}
return chanBucket, nil
}