func (r *Renter) newHostUploader(settings modules.HostSettings, filesize uint64, duration types.BlockHeight, masterKey crypto.TwofishKey) (*hostUploader, error) {
hu := &hostUploader{
settings: settings,
masterKey: masterKey,
tree: crypto.NewTree(),
renter: r,
}
// TODO: maybe do this later?
err := hu.negotiateContract(filesize, duration)
if err != nil {
return nil, err
}
// initiate the revision loop
hu.conn, err = net.DialTimeout("tcp", string(hu.settings.IPAddress), 15*time.Second)
if err != nil {
return nil, err
}
if err := encoding.WriteObject(hu.conn, modules.RPCRevise); err != nil {
return nil, err
}
if err := encoding.WriteObject(hu.conn, hu.contract.ID); err != nil {
return nil, err
}
return hu, nil
}
// newHostUploader initiates the contract revision process with a host, and
// returns a hostUploader, which satisfies the Uploader interface.
func (hdb *HostDB) newHostUploader(hc hostContract) (*hostUploader, error) {
hdb.mu.RLock()
settings, ok := hdb.allHosts[hc.IP] // or activeHosts?
hdb.mu.RUnlock()
if !ok {
return nil, errors.New("no record of that host")
}
// TODO: check for excessive price again?
// initiate revision loop
conn, err := net.DialTimeout("tcp", string(hc.IP), 15*time.Second)
if err != nil {
return nil, err
}
if err := encoding.WriteObject(conn, modules.RPCRevise); err != nil {
return nil, err
}
if err := encoding.WriteObject(conn, hc.ID); err != nil {
return nil, err
}
// TODO: some sort of acceptance would be good here, so that we know the
// uploader will actually work. Maybe send the Merkle root?
hu := &hostUploader{
contract: hc,
price: settings.Price,
tree: crypto.NewTree(),
conn: conn,
hdb: hdb,
}
return hu, nil
}
// UnlockHash calculates the root hash of a Merkle tree of the
// UnlockConditions object. The leaves of this tree are formed by taking the
// hash of the timelock, the hash of the public keys (one leaf each), and the
// hash of the number of signatures. The keys are put in the middle because
// Timelock and SignaturesRequired are both low entropy fields; they can be
// protected by having random public keys next to them.
func (uc UnlockConditions) UnlockHash() UnlockHash {
tree := crypto.NewTree()
tree.PushObject(uc.Timelock)
for i := range uc.PublicKeys {
tree.PushObject(uc.PublicKeys[i])
}
tree.PushObject(uc.SignaturesRequired)
return UnlockHash(tree.Root())
}
// MerkleRoot calculates the Merkle root of a Block. The leaves of the Merkle
// tree are composed of the Timestamp, the miner outputs (one leaf per
// payout), and the transactions (one leaf per transaction).
func (b Block) MerkleRoot() crypto.Hash {
tree := crypto.NewTree()
for _, payout := range b.MinerPayouts {
tree.PushObject(payout)
}
for _, txn := range b.Transactions {
tree.PushObject(txn)
}
return tree.Root()
}
// consensusChecksum grabs a checksum of the consensus set by pushing all of
// the elements in sorted order into a merkle tree and taking the root. All
// consensus sets with the same current block should have identical consensus
// checksums.
func consensusChecksum(tx *bolt.Tx) crypto.Hash {
// Create a checksum tree.
tree := crypto.NewTree()
// For all of the constant buckets, push every key and every value. Buckets
// are sorted in byte-order, therefore this operation is deterministic.
consensusSetBuckets := []*bolt.Bucket{
tx.Bucket(BlockPath),
tx.Bucket(SiacoinOutputs),
tx.Bucket(FileContracts),
tx.Bucket(SiafundOutputs),
tx.Bucket(SiafundPool),
}
for i := range consensusSetBuckets {
err := consensusSetBuckets[i].ForEach(func(k, v []byte) error {
tree.Push(k)
tree.Push(v)
return nil
})
if err != nil {
manageErr(tx, err)
}
}
// Iterate through all the buckets looking for buckets prefixed with
// prefixDSCO or prefixFCEX. Buckets are presented in byte-sorted order by
// name.
err := tx.ForEach(func(name []byte, b *bolt.Bucket) error {
// If the bucket is not a delayed siacoin output bucket or a file
// contract expiration bucket, skip.
if !bytes.HasPrefix(name, prefixDSCO) && !bytes.HasPrefix(name, prefixFCEX) {
return nil
}
// The bucket is a prefixed bucket - add all elements to the tree.
return b.ForEach(func(k, v []byte) error {
tree.Push(k)
tree.Push(v)
return nil
})
})
if err != nil {
manageErr(tx, err)
}
return tree.Root()
}
// newHostUploader negotiates an initial file contract with the specified host
// and returns a hostUploader, which satisfies the uploader interface.
func (r *Renter) newHostUploader(settings modules.HostSettings, filesize uint64, duration types.BlockHeight, masterKey crypto.TwofishKey) (*hostUploader, error) {
// reject hosts that are too expensive
if settings.Price.Cmp(maxPrice) > 0 {
return nil, errTooExpensive
}
hu := &hostUploader{
settings: settings,
masterKey: masterKey,
tree: crypto.NewTree(),
renter: r,
}
// get an address to use for negotiation
// TODO: use more than one shared address
if r.cachedAddress == (types.UnlockHash{}) {
uc, err := r.wallet.NextAddress()
if err != nil {
return nil, err
}
r.cachedAddress = uc.UnlockHash()
}
// TODO: check for existing contract?
err := hu.negotiateContract(filesize, duration, r.cachedAddress)
if err != nil {
return nil, err
}
// if negotiation was sucessful, clear the cached address
r.cachedAddress = types.UnlockHash{}
// initiate the revision loop
hu.conn, err = net.DialTimeout("tcp", string(hu.settings.IPAddress), 15*time.Second)
if err != nil {
return nil, err
}
if err := encoding.WriteObject(hu.conn, modules.RPCRevise); err != nil {
return nil, err
}
if err := encoding.WriteObject(hu.conn, hu.contract.ID); err != nil {
return nil, err
}
return hu, nil
}
// managedRPCRevise is an RPC that allows a renter to revise a file contract. It will
// read new revisions in a loop until the renter sends a termination signal.
func (h *Host) managedRPCRevise(conn net.Conn) error {
// read ID of contract to be revised
var fcid types.FileContractID
if err := encoding.ReadObject(conn, &fcid, crypto.HashSize); err != nil {
return errors.New("couldn't read contract ID: " + err.Error())
}
// remove conn deadline while we wait for lock and rebuild the Merkle tree.
err := conn.SetDeadline(time.Now().Add(15 * time.Minute))
if err != nil {
return err
}
h.mu.RLock()
obligation, exists := h.obligationsByID[fcid]
h.mu.RUnlock()
if !exists {
return errors.New("no record of that contract")
}
// need to protect against two simultaneous revisions to the same
// contract; this can cause inconsistency and data loss, making storage
// proofs impossible
//
// TODO: DOS vector - the host has locked the obligation even though the
// renter has not proven themselves to be the owner of the file contract.
obligation.mu.Lock()
defer obligation.mu.Unlock()
// open the file in append mode
file, err := os.OpenFile(obligation.Path, os.O_CREATE|os.O_RDWR|os.O_APPEND, 0660)
if err != nil {
return err
}
// rebuild current Merkle tree
tree := crypto.NewTree()
err = tree.ReadSegments(file)
if err != nil {
// Error does not need to be checked when closing the file, already
// there have been issues related to the filesystem.
_ = file.Close()
return err
}
// accept new revisions in a loop. The final good transaction will be
// submitted to the blockchain.
revisionErr := func() error {
for {
// allow 5 minutes between revisions
err := conn.SetDeadline(time.Now().Add(5 * time.Minute))
if err != nil {
return err
}
// read proposed revision
var revTxn types.Transaction
if err = encoding.ReadObject(conn, &revTxn, types.BlockSizeLimit); err != nil {
return errors.New("couldn't read revision: " + err.Error())
}
// an empty transaction indicates completion
if revTxn.ID() == (types.Transaction{}).ID() {
return nil
}
// allow 5 minutes for each revision
err = conn.SetDeadline(time.Now().Add(5 * time.Minute))
if err != nil {
return err
}
// check revision against original file contract
h.mu.RLock()
err = h.considerRevision(revTxn, obligation)
h.mu.RUnlock()
if err != nil {
// There is nothing that can be done if there is an error while
// writing to a connection.
_ = encoding.WriteObject(conn, err.Error())
return err
}
// indicate acceptance
if err := encoding.WriteObject(conn, modules.AcceptResponse); err != nil {
return errors.New("couldn't write acceptance: " + err.Error())
}
// read piece
// TODO: simultaneously read into tree and file
rev := revTxn.FileContractRevisions[0]
piece := make([]byte, rev.NewFileSize-obligation.fileSize())
_, err = io.ReadFull(conn, piece)
if err != nil {
return errors.New("couldn't read piece data: " + err.Error())
}
// verify Merkle root
err = tree.ReadSegments(bytes.NewReader(piece))
if err != nil {
return errors.New("couldn't verify Merkle root: " + err.Error())
}
if tree.Root() != rev.NewFileMerkleRoot {
return errors.New("revision has bad Merkle root")
}
// manually sign the transaction
revTxn.TransactionSignatures = append(revTxn.TransactionSignatures, types.TransactionSignature{
ParentID: crypto.Hash(fcid),
CoveredFields: types.CoveredFields{FileContractRevisions: []uint64{0}},
PublicKeyIndex: 1, // host key is always second
})
encodedSig, err := crypto.SignHash(revTxn.SigHash(1), h.secretKey)
if err != nil {
return err
}
revTxn.TransactionSignatures[1].Signature = encodedSig[:]
// append piece to file
if _, err := file.Write(piece); err != nil {
return errors.New("couldn't write new data to file: " + err.Error())
}
// save updated obligation to disk
h.mu.Lock()
h.reviseObligation(revTxn)
h.mu.Unlock()
// send the signed transaction - this must be the last thing that happens.
if err := encoding.WriteObject(conn, revTxn); err != nil {
return errors.New("couldn't write signed revision transaction: " + err.Error())
}
}
}()
err = file.Close()
if err != nil {
return err
}
err = h.tpool.AcceptTransactionSet([]types.Transaction{obligation.RevisionTransaction})
if err != nil {
h.log.Println("WARN: transaction pool rejected revision transaction: " + err.Error())
}
return revisionErr
}
// consensusSetHash returns the Merkle root of the current state of consensus.
func (cs *ConsensusSet) consensusSetHash() crypto.Hash {
// Check is too slow to be done on a full node.
if build.Release == "standard" {
return crypto.Hash{}
}
// Items of interest:
// 1. genesis block
// 3. current height
// 4. current target
// 5. current depth
// 6. current path + diffs
// (7) earliest allowed timestamp of next block
// 8. unspent siacoin outputs, sorted by id.
// 9. open file contracts, sorted by id.
// 10. unspent siafund outputs, sorted by id.
// 11. delayed siacoin outputs, sorted by height, then sorted by id.
// 12. siafund pool
// Create a slice of hashes representing all items of interest.
tree := crypto.NewTree()
tree.PushObject(cs.blockRoot.Block)
tree.PushObject(cs.height())
tree.PushObject(cs.currentProcessedBlock().ChildTarget)
tree.PushObject(cs.currentProcessedBlock().Depth)
// tree.PushObject(cs.earliestChildTimestamp(cs.currentProcessedBlock()))
// Add all the blocks in the current path TODO: along with their diffs.
for i := 0; i < int(cs.db.pathHeight()); i++ {
tree.PushObject(cs.db.getPath(types.BlockHeight(i)))
}
// Add all of the siacoin outputs, sorted by id.
var openSiacoinOutputs crypto.HashSlice
cs.db.forEachSiacoinOutputs(func(scoid types.SiacoinOutputID, sco types.SiacoinOutput) {
openSiacoinOutputs = append(openSiacoinOutputs, crypto.Hash(scoid))
})
sort.Sort(openSiacoinOutputs)
for _, id := range openSiacoinOutputs {
sco := cs.db.getSiacoinOutputs(types.SiacoinOutputID(id))
tree.PushObject(id)
tree.PushObject(sco)
}
// Add all of the file contracts, sorted by id.
var openFileContracts crypto.HashSlice
cs.db.forEachFileContracts(func(fcid types.FileContractID, fc types.FileContract) {
openFileContracts = append(openFileContracts, crypto.Hash(fcid))
})
sort.Sort(openFileContracts)
for _, id := range openFileContracts {
// Sanity Check - file contract should exist.
fc := cs.db.getFileContracts(types.FileContractID(id))
tree.PushObject(id)
tree.PushObject(fc)
}
// Add all of the siafund outputs, sorted by id.
var openSiafundOutputs crypto.HashSlice
cs.db.forEachSiafundOutputs(func(sfoid types.SiafundOutputID, sfo types.SiafundOutput) {
openSiafundOutputs = append(openSiafundOutputs, crypto.Hash(sfoid))
})
sort.Sort(openSiafundOutputs)
for _, id := range openSiafundOutputs {
sco := cs.db.getSiafundOutputs(types.SiafundOutputID(id))
tree.PushObject(id)
tree.PushObject(sco)
}
// Get the set of delayed siacoin outputs, sorted by maturity height then
// sorted by id and add them.
for i := cs.height() + 1; i <= cs.height()+types.MaturityDelay; i++ {
var delayedSiacoinOutputs crypto.HashSlice
if cs.db.inDelayedSiacoinOutputs(i) {
cs.db.forEachDelayedSiacoinOutputsHeight(i, func(id types.SiacoinOutputID, output types.SiacoinOutput) {
delayedSiacoinOutputs = append(delayedSiacoinOutputs, crypto.Hash(id))
})
}
sort.Sort(delayedSiacoinOutputs)
for _, delayedSiacoinOutputID := range delayedSiacoinOutputs {
delayedSiacoinOutput := cs.db.getDelayedSiacoinOutputs(i, types.SiacoinOutputID(delayedSiacoinOutputID))
tree.PushObject(delayedSiacoinOutput)
tree.PushObject(delayedSiacoinOutputID)
}
}
// Add the siafund pool
var siafundPool types.Currency
err := cs.db.Update(func(tx *bolt.Tx) error {
siafundPool = getSiafundPool(tx)
return nil
})
if err != nil {
panic(err)
}
tree.PushObject(siafundPool)
return tree.Root()
}
// consensusSetHash returns the Merkle root of the current state of consensus.
func (cs *State) consensusSetHash() crypto.Hash {
// Items of interest:
// 1. genesis block
// 3. current height
// 4. current target
// 5. current depth
// 6. earliest allowed timestamp of next block
// 7. current path, ordered by height.
// 8. unspent siacoin outputs, sorted by id.
// 9. open file contracts, sorted by id.
// 10. unspent siafund outputs, sorted by id.
// 11. delayed siacoin outputs, sorted by height, then sorted by id.
// TODO: Add the diff set ?
// Create a slice of hashes representing all items of interest.
tree := crypto.NewTree()
tree.PushObject(cs.blockRoot.block)
tree.PushObject(cs.height())
tree.PushObject(cs.currentBlockNode().childTarget)
tree.PushObject(cs.currentBlockNode().depth)
tree.PushObject(cs.currentBlockNode().earliestChildTimestamp())
// Add all the blocks in the current path.
for i := 0; i < len(cs.currentPath); i++ {
tree.PushObject(cs.currentPath[types.BlockHeight(i)])
}
// Add all of the siacoin outputs, sorted by id.
var openSiacoinOutputs crypto.HashSlice
for siacoinOutputID, _ := range cs.siacoinOutputs {
openSiacoinOutputs = append(openSiacoinOutputs, crypto.Hash(siacoinOutputID))
}
sort.Sort(openSiacoinOutputs)
for _, id := range openSiacoinOutputs {
sco, exists := cs.siacoinOutputs[types.SiacoinOutputID(id)]
if !exists {
panic("trying to push nonexistent siacoin output")
}
tree.PushObject(id)
tree.PushObject(sco)
}
// Add all of the file contracts, sorted by id.
var openFileContracts crypto.HashSlice
for fileContractID, _ := range cs.fileContracts {
openFileContracts = append(openFileContracts, crypto.Hash(fileContractID))
}
sort.Sort(openFileContracts)
for _, id := range openFileContracts {
// Sanity Check - file contract should exist.
fc, exists := cs.fileContracts[types.FileContractID(id)]
if !exists {
panic("trying to push a nonexistent file contract")
}
tree.PushObject(id)
tree.PushObject(fc)
}
// Add all of the siafund outputs, sorted by id.
var openSiafundOutputs crypto.HashSlice
for siafundOutputID, _ := range cs.siafundOutputs {
openSiafundOutputs = append(openSiafundOutputs, crypto.Hash(siafundOutputID))
}
sort.Sort(openSiafundOutputs)
for _, id := range openSiafundOutputs {
sco, exists := cs.siafundOutputs[types.SiafundOutputID(id)]
if !exists {
panic("trying to push nonexistent siafund output")
}
tree.PushObject(id)
tree.PushObject(sco)
}
// Get the set of delayed siacoin outputs, sorted by maturity height then
// sorted by id and add them.
for i := cs.height() + 1; i <= cs.height()+types.MaturityDelay; i++ {
var delayedSiacoinOutputs crypto.HashSlice
for id := range cs.delayedSiacoinOutputs[i] {
delayedSiacoinOutputs = append(delayedSiacoinOutputs, crypto.Hash(id))
}
sort.Sort(delayedSiacoinOutputs)
for _, delayedSiacoinOutputID := range delayedSiacoinOutputs {
delayedSiacoinOutput, exists := cs.delayedSiacoinOutputs[i][types.SiacoinOutputID(delayedSiacoinOutputID)]
if !exists {
panic("trying to push nonexistent delayed siacoin output")
}
tree.PushObject(delayedSiacoinOutput)
tree.PushObject(delayedSiacoinOutputID)
}
}
return tree.Root()
}
// rpcRevise is an RPC that allows a renter to revise a file contract. It will
// read new revisions in a loop until the renter sends a termination signal.
func (h *Host) rpcRevise(conn net.Conn) error {
// read ID of contract to be revised
var fcid types.FileContractID
if err := encoding.ReadObject(conn, &fcid, crypto.HashSize); err != nil {
return err
}
lockID := h.mu.RLock()
obligation, exists := h.obligationsByID[fcid]
h.mu.RUnlock(lockID)
if !exists {
return errors.New("no record of that contract")
}
// need to protect against two simultaneous revisions to the same
// contract; this can cause inconsistency and data loss, making storage
// proofs impossible
obligation.mu.Lock()
defer obligation.mu.Unlock()
// open the file in append mode
file, err := os.OpenFile(obligation.Path, os.O_CREATE|os.O_RDWR|os.O_APPEND, 0660)
if err != nil {
return err
}
defer func() {
// if a newly-created file was not updated, remove it
if stat, _ := file.Stat(); stat.Size() == 0 {
os.Remove(obligation.Path)
}
file.Close()
}()
// rebuild current Merkle tree
tree := crypto.NewTree()
buf := make([]byte, crypto.SegmentSize)
for {
_, err := io.ReadFull(file, buf)
if err == io.EOF {
break
} else if err != nil && err != io.ErrUnexpectedEOF {
return err
}
tree.Push(buf)
}
// accept new revisions in a loop. The final good transaction will be
// submitted to the blockchain.
var finalTxn types.Transaction
defer func() {
h.tpool.AcceptTransactionSet([]types.Transaction{finalTxn})
}()
for {
// read proposed revision
var revTxn types.Transaction
if err := encoding.ReadObject(conn, &revTxn, types.BlockSizeLimit); err != nil {
return err
}
// an empty transaction indicates completion
if revTxn.ID() == (types.Transaction{}).ID() {
break
}
// check revision against original file contract
lockID = h.mu.RLock()
err := h.considerRevision(revTxn, obligation)
h.mu.RUnlock(lockID)
if err != nil {
encoding.WriteObject(conn, err.Error())
continue // don't terminate loop; subsequent revisions may be okay
}
// indicate acceptance
if err := encoding.WriteObject(conn, modules.AcceptResponse); err != nil {
return err
}
// read piece
// TODO: simultaneously read into tree?
rev := revTxn.FileContractRevisions[0]
piece := make([]byte, rev.NewFileSize-obligation.FileContract.FileSize)
_, err = io.ReadFull(conn, piece)
if err != nil {
return err
}
// verify Merkle root
r := bytes.NewReader(piece)
for {
_, err := io.ReadFull(r, buf)
if err == io.EOF {
break
} else if err != nil && err != io.ErrUnexpectedEOF {
return err
}
tree.Push(buf)
}
if tree.Root() != rev.NewFileMerkleRoot {
return errors.New("revision has bad Merkle root")
}
// manually sign the transaction
revTxn.TransactionSignatures = append(revTxn.TransactionSignatures, types.TransactionSignature{
ParentID: crypto.Hash(fcid),
CoveredFields: types.CoveredFields{FileContractRevisions: []uint64{0}},
PublicKeyIndex: 1, // host key is always second
})
encodedSig, err := crypto.SignHash(revTxn.SigHash(1), h.secretKey)
if err != nil {
return err
}
revTxn.TransactionSignatures[1].Signature = encodedSig[:]
// send the signed transaction
if err := encoding.WriteObject(conn, revTxn); err != nil {
return err
}
// append piece to file
if _, err := file.Write(piece); err != nil {
return err
}
// save updated obligation to disk
lockID = h.mu.Lock()
h.spaceRemaining -= int64(len(piece))
obligation.FileContract.RevisionNumber = rev.NewRevisionNumber
obligation.FileContract.FileSize = rev.NewFileSize
obligation.FileContract.FileMerkleRoot = rev.NewFileMerkleRoot
h.obligationsByID[obligation.ID] = obligation
heightObligations := h.obligationsByHeight[obligation.FileContract.WindowStart+StorageProofReorgDepth]
for i := range heightObligations {
if heightObligations[i].ID == obligation.ID {
heightObligations[i] = obligation
}
}
h.save()
h.mu.Unlock(lockID)
finalTxn = revTxn
}
return nil
}
// rpcRevise is an RPC that allows a renter to revise a file contract. It will
// read new revisions in a loop until the renter sends a termination signal.
func (h *Host) rpcRevise(conn net.Conn) error {
// read ID of contract to be revised
var fcid types.FileContractID
if err := encoding.ReadObject(conn, &fcid, crypto.HashSize); err != nil {
return errors.New("couldn't read contract ID: " + err.Error())
}
// remove conn deadline while we wait for lock and rebuild the Merkle tree
conn.SetDeadline(time.Time{})
h.mu.RLock()
obligation, exists := h.obligationsByID[fcid]
h.mu.RUnlock()
if !exists {
return errors.New("no record of that contract")
}
// need to protect against two simultaneous revisions to the same
// contract; this can cause inconsistency and data loss, making storage
// proofs impossible
obligation.mu.Lock()
defer obligation.mu.Unlock()
// open the file in append mode
file, err := os.OpenFile(obligation.Path, os.O_CREATE|os.O_RDWR|os.O_APPEND, 0660)
if err != nil {
return err
}
// rebuild current Merkle tree
tree := crypto.NewTree()
err = tree.ReadSegments(file)
if err != nil {
file.Close()
return err
}
// accept new revisions in a loop. The final good transaction will be
// submitted to the blockchain.
revisionErr := func() error {
for {
// allow 2 minutes between revisions
conn.SetDeadline(time.Now().Add(2 * time.Minute))
// read proposed revision
var revTxn types.Transaction
if err := encoding.ReadObject(conn, &revTxn, types.BlockSizeLimit); err != nil {
return errors.New("couldn't read revision: " + err.Error())
}
// an empty transaction indicates completion
if revTxn.ID() == (types.Transaction{}).ID() {
return nil
}
// allow 5 minutes for each revision
conn.SetDeadline(time.Now().Add(5 * time.Minute))
// check revision against original file contract
h.mu.RLock()
err := h.considerRevision(revTxn, *obligation)
h.mu.RUnlock()
if err != nil {
encoding.WriteObject(conn, err.Error())
continue // don't terminate loop; subsequent revisions may be okay
}
// indicate acceptance
if err := encoding.WriteObject(conn, modules.AcceptResponse); err != nil {
return errors.New("couldn't write acceptance: " + err.Error())
}
// read piece
// TODO: simultaneously read into tree and file
rev := revTxn.FileContractRevisions[0]
last := obligation.LastRevisionTxn.FileContractRevisions[0]
piece := make([]byte, rev.NewFileSize-last.NewFileSize)
_, err = io.ReadFull(conn, piece)
if err != nil {
return errors.New("couldn't read piece data: " + err.Error())
}
// verify Merkle root
err = tree.ReadSegments(bytes.NewReader(piece))
if err != nil {
return errors.New("couldn't verify Merkle root: " + err.Error())
}
if tree.Root() != rev.NewFileMerkleRoot {
return errors.New("revision has bad Merkle root")
}
// manually sign the transaction
revTxn.TransactionSignatures = append(revTxn.TransactionSignatures, types.TransactionSignature{
ParentID: crypto.Hash(fcid),
CoveredFields: types.CoveredFields{FileContractRevisions: []uint64{0}},
PublicKeyIndex: 1, // host key is always second
})
encodedSig, err := crypto.SignHash(revTxn.SigHash(1), h.secretKey)
if err != nil {
return err
}
revTxn.TransactionSignatures[1].Signature = encodedSig[:]
// send the signed transaction
if err := encoding.WriteObject(conn, revTxn); err != nil {
return errors.New("couldn't write signed revision transaction: " + err.Error())
}
// append piece to file
if _, err := file.Write(piece); err != nil {
return errors.New("couldn't write new data to file: " + err.Error())
}
// save updated obligation to disk
h.mu.Lock()
obligation.LastRevisionTxn = revTxn
h.spaceRemaining -= int64(len(piece))
h.save()
h.mu.Unlock()
}
}()
file.Close()
// if a newly-created file was not updated, remove it
if obligation.LastRevisionTxn.FileContractRevisions[0].NewRevisionNumber == 0 {
os.Remove(obligation.Path)
return revisionErr
}
err = h.tpool.AcceptTransactionSet([]types.Transaction{obligation.LastRevisionTxn})
if err != nil {
h.log.Println("WARN: transaction pool rejected revision transaction: " + err.Error())
}
return revisionErr
}
