// newTestingFile initializes a file object with random parameters.
func newTestingFile() *file {
key, _ := crypto.GenerateTwofishKey()
data, _ := crypto.RandBytes(8)
nData, _ := crypto.RandIntn(10)
nParity, _ := crypto.RandIntn(10)
rsc, _ := NewRSCode(nData+1, nParity+1)
return &file{
name: "testfile-" + strconv.Itoa(int(data[0])),
size: encoding.DecUint64(data[1:5]),
masterKey: key,
erasureCode: rsc,
pieceSize: encoding.DecUint64(data[6:8]),
}
}
// minimumValidChildTimestamp returns the earliest timestamp that a child node
// can have while still being valid. See section 'Block Timestamps' in
// Consensus.md.
//
// To boost performance, minimumValidChildTimestamp is passed a bucket that it
// can use from inside of a boltdb transaction.
func (rh stdBlockRuleHelper) minimumValidChildTimestamp(blockMap dbBucket, pb *processedBlock) types.Timestamp {
// Get the previous MedianTimestampWindow timestamps.
windowTimes := make(types.TimestampSlice, types.MedianTimestampWindow)
windowTimes[0] = pb.Block.Timestamp
parent := pb.Block.ParentID
for i := uint64(1); i < types.MedianTimestampWindow; i++ {
// If the genesis block is 'parent', use the genesis block timestamp
// for all remaining times.
if parent == (types.BlockID{}) {
windowTimes[i] = windowTimes[i-1]
continue
}
// Get the next parent's bytes. Because the ordering is specific, the
// parent does not need to be decoded entirely to get the desired
// information. This provides a performance boost. The id of the next
// parent lies at the first 32 bytes, and the timestamp of the block
// lies at bytes 40-48.
parentBytes := blockMap.Get(parent[:])
copy(parent[:], parentBytes[:32])
windowTimes[i] = types.Timestamp(encoding.DecUint64(parentBytes[40:48]))
}
sort.Sort(windowTimes)
// Return the median of the sorted timestamps.
return windowTimes[len(windowTimes)/2]
}
// targetAdjustmentBase returns the magnitude that the target should be
// adjusted by before a clamp is applied.
func (cs *ConsensusSet) targetAdjustmentBase(blockMap *bolt.Bucket, pb *processedBlock) *big.Rat {
// Grab the block that was generated 'TargetWindow' blocks prior to the
// parent. If there are not 'TargetWindow' blocks yet, stop at the genesis
// block.
var windowSize types.BlockHeight
parent := pb.Block.ParentID
current := pb.Block.ID()
for windowSize = 0; windowSize < types.TargetWindow && parent != (types.BlockID{}); windowSize++ {
current = parent
copy(parent[:], blockMap.Get(parent[:])[:32])
}
timestamp := types.Timestamp(encoding.DecUint64(blockMap.Get(current[:])[40:48]))
// The target of a child is determined by the amount of time that has
// passed between the generation of its immediate parent and its
// TargetWindow'th parent. The expected amount of seconds to have passed is
// TargetWindow*BlockFrequency. The target is adjusted in proportion to how
// time has passed vs. the expected amount of time to have passed.
//
// The target is converted to a big.Rat to provide infinite precision
// during the calculation. The big.Rat is just the int representation of a
// target.
timePassed := pb.Block.Timestamp - timestamp
expectedTimePassed := types.BlockFrequency * windowSize
return big.NewRat(int64(timePassed), int64(expectedTimePassed))
}
// UnmarshalSia implements the encoding.SiaUnmarshaler interface.
func (b *Block) UnmarshalSia(r io.Reader) error {
io.ReadFull(r, b.ParentID[:])
io.ReadFull(r, b.Nonce[:])
tsBytes := make([]byte, 8)
io.ReadFull(r, tsBytes)
b.Timestamp = Timestamp(encoding.DecUint64(tsBytes))
return encoding.NewDecoder(r).DecodeAll(&b.MinerPayouts, &b.Transactions)
}
// stopConsistencyGuard is the complement function to startConsistencyGuard.
// startConsistencyGuard should be called any time that consensus changes are
// starting, and stopConsistencyGuard should be called when the consensus
// changes are finished. The guards are necessary because one set of changes
// may occur over multiple boltdb transactions.
func (db *setDB) stopConsistencyGuard() {
err := db.Update(func(tx *bolt.Tx) error {
cg := tx.Bucket(ConsistencyGuard)
i := encoding.DecUint64(cg.Get(GuardEnd))
return cg.Put(GuardEnd, encoding.EncUint64(i+1))
})
if err != nil && build.DEBUG {
panic(err)
}
}
// startConsistencyGuard activates a consistency guard on the database. This is
// necessary because the consensus set makes one atomic database change, but
// does so using several boltdb transactions. The 'guard' is actually two
// values, a 'GuardStart' and a 'GuardEnd'. 'GuardStart' is incremented when
// consensus changes begin, and 'GuardEnd' is incremented when consensus
// changes finish. If 'GuardStart' is not equal to 'GuardEnd' when
// startConsistencyGuard is called, the database is likely corrupt.
func (db *setDB) startConsistencyGuard() error {
return db.Update(func(tx *bolt.Tx) error {
cg := tx.Bucket(ConsistencyGuard)
gs := cg.Get(GuardStart)
if !bytes.Equal(gs, cg.Get(GuardEnd)) {
return errDBInconsistent
}
i := encoding.DecUint64(gs)
return cg.Put(GuardStart, encoding.EncUint64(i+1))
})
}
// startConsistencyGuard activates a consistency guard on the database. This is
// necessary because the consensus set makes one atomic database change, but
// does so using several boltdb transactions. The 'guard' is actually two
// values, a 'GuardStart' and a 'GuardEnd'. 'GuardStart' is incremented when
// consensus changes begin, and 'GuardEnd' is incremented when consensus
// changes finish. If 'GuardStart' is not equal to 'GuardEnd' when
// startConsistencyGuard is called, the database is likely corrupt.
func (db *setDB) startConsistencyGuard() error {
return db.Update(func(tx *bolt.Tx) error {
cg := tx.Bucket(ConsistencyGuard)
gs := cg.Get(GuardStart)
if !bytes.Equal(gs, cg.Get(GuardEnd)) {
println("Database is inconsistent - please reset your database by redownloading it or loading a consistent backup. This can happen if you close Sia unexpectedly.")
return errDBInconsistent
}
i := encoding.DecUint64(gs)
return cg.Put(GuardStart, encoding.EncUint64(i+1))
})
}
