dcrd/blockchain/process.go
Dave Collins 66010e4134
multi: Return fork len from ProcessBlock.
This modifies the ProcessBlock function in the blockchain package to
return the fork length for the connected block and updates all callers
and tests accordingly.  Several of the internal functions which
ProcessBlock calls are also updated in order to bubble the necessary
information back up so it can be returned.  It does not make any
behavioral changes.

This is being done to better expose information about the position of
the block within the chain to callers without them having to make
additional queries.
2018-05-27 20:20:43 -05:00

260 lines
9.1 KiB
Go

// Copyright (c) 2013-2016 The btcsuite developers
// Copyright (c) 2015-2018 The Decred developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package blockchain
import (
"fmt"
"time"
"github.com/decred/dcrd/chaincfg/chainhash"
"github.com/decred/dcrd/database"
"github.com/decred/dcrd/dcrutil"
)
// BehaviorFlags is a bitmask defining tweaks to the normal behavior when
// performing chain processing and consensus rules checks.
type BehaviorFlags uint32
const (
// BFFastAdd may be set to indicate that several checks can be avoided
// for the block since it is already known to fit into the chain due to
// already proving it correct links into the chain up to a known
// checkpoint. This is primarily used for headers-first mode.
BFFastAdd BehaviorFlags = 1 << iota
// BFNoPoWCheck may be set to indicate the proof of work check which
// ensures a block hashes to a value less than the required target will
// not be performed.
BFNoPoWCheck
// BFNone is a convenience value to specifically indicate no flags.
BFNone BehaviorFlags = 0
)
// blockExists determines whether a block with the given hash exists either in
// the main chain or any side chains.
//
// This function MUST be called with the chain state lock held (for reads).
func (b *BlockChain) blockExists(hash *chainhash.Hash) (bool, error) {
// Check block index first (could be main chain or side chain blocks).
if b.index.HaveBlock(hash) {
return true, nil
}
// Check in the database.
var exists bool
err := b.db.View(func(dbTx database.Tx) error {
var err error
exists, err = dbTx.HasBlock(hash)
if err != nil || !exists {
return err
}
// Ignore side chain blocks in the database. This is necessary
// because there is not currently any record of the associated
// block index data, so it's not yet possible to efficiently load the
// block and do anything useful with it.
//
// Ultimately the entire block index should be serialized
// instead of only the current main chain so it can be consulted
// directly.
_, err = dbFetchHeightByHash(dbTx, hash)
if isNotInMainChainErr(err) {
exists = false
return nil
}
return err
})
return exists, err
}
// processOrphans determines if there are any orphans which depend on the passed
// block hash (they are no longer orphans if true) and potentially accepts them.
// It repeats the process for the newly accepted blocks (to detect further
// orphans which may no longer be orphans) until there are no more.
//
// The flags do not modify the behavior of this function directly, however they
// are needed to pass along to maybeAcceptBlock.
//
// This function MUST be called with the chain state lock held (for writes).
func (b *BlockChain) processOrphans(hash *chainhash.Hash, flags BehaviorFlags) error {
// Start with processing at least the passed hash. Leave a little room
// for additional orphan blocks that need to be processed without
// needing to grow the array in the common case.
processHashes := make([]*chainhash.Hash, 0, 10)
processHashes = append(processHashes, hash)
for len(processHashes) > 0 {
// Pop the first hash to process from the slice.
processHash := processHashes[0]
processHashes[0] = nil // Prevent GC leak.
processHashes = processHashes[1:]
// Look up all orphans that are parented by the block we just
// accepted. This will typically only be one, but it could
// be multiple if multiple blocks are mined and broadcast
// around the same time. The one with the most proof of work
// will eventually win out. An indexing for loop is
// intentionally used over a range here as range does not
// reevaluate the slice on each iteration nor does it adjust the
// index for the modified slice.
for i := 0; i < len(b.prevOrphans[*processHash]); i++ {
orphan := b.prevOrphans[*processHash][i]
if orphan == nil {
log.Warnf("Found a nil entry at index %d in the "+
"orphan dependency list for block %v", i,
processHash)
continue
}
// Remove the orphan from the orphan pool.
orphanHash := orphan.block.Hash()
b.removeOrphanBlock(orphan)
i--
// Potentially accept the block into the block chain.
_, err := b.maybeAcceptBlock(orphan.block, flags)
if err != nil {
return err
}
// Add this block to the list of blocks to process so
// any orphan blocks that depend on this block are
// handled too.
processHashes = append(processHashes, orphanHash)
}
}
return nil
}
// ProcessBlock is the main workhorse for handling insertion of new blocks into
// the block chain. It includes functionality such as rejecting duplicate
// blocks, ensuring blocks follow all rules, orphan handling, and insertion into
// the block chain along with best chain selection and reorganization.
//
// When no errors occurred during processing, the first return value indicates
// the length of the fork the block extended. In the case it either exteneded
// the best chain or is now the tip of the best chain due to causing a
// reorganize, the fork length will be 0. The second return value indicates
// whether or not the block is an orphan, in which case the fork length will
// also be zero as expected, because it, by definition, does not connect ot the
// best chain.
//
// This function is safe for concurrent access.
func (b *BlockChain) ProcessBlock(block *dcrutil.Block, flags BehaviorFlags) (int64, bool, error) {
b.chainLock.Lock()
defer b.chainLock.Unlock()
fastAdd := flags&BFFastAdd == BFFastAdd
blockHash := block.Hash()
log.Tracef("Processing block %v", blockHash)
currentTime := time.Now()
defer func() {
elapsedTime := time.Since(currentTime)
log.Debugf("Block %v (height %v) finished processing in %s",
blockHash, block.Height(), elapsedTime)
}()
// The block must not already exist in the main chain or side chains.
exists, err := b.blockExists(blockHash)
if err != nil {
return 0, false, err
}
if exists {
str := fmt.Sprintf("already have block %v", blockHash)
return 0, false, ruleError(ErrDuplicateBlock, str)
}
// The block must not already exist as an orphan.
if _, exists := b.orphans[*blockHash]; exists {
str := fmt.Sprintf("already have block (orphan) %v", blockHash)
return 0, false, ruleError(ErrDuplicateBlock, str)
}
// Perform preliminary sanity checks on the block and its transactions.
err = checkBlockSanity(block, b.timeSource, flags, b.chainParams)
if err != nil {
return 0, false, err
}
// Find the previous checkpoint and perform some additional checks based
// on the checkpoint. This provides a few nice properties such as
// preventing old side chain blocks before the last checkpoint,
// rejecting easy to mine, but otherwise bogus, blocks that could be
// used to eat memory, and ensuring expected (versus claimed) proof of
// work requirements since the previous checkpoint are met.
blockHeader := &block.MsgBlock().Header
checkpointBlock, err := b.findPreviousCheckpoint()
if err != nil {
return 0, false, err
}
if checkpointBlock != nil {
// Ensure the block timestamp is after the checkpoint timestamp.
checkpointHeader := &checkpointBlock.MsgBlock().Header
checkpointTime := checkpointHeader.Timestamp
if blockHeader.Timestamp.Before(checkpointTime) {
str := fmt.Sprintf("block %v has timestamp %v before "+
"last checkpoint timestamp %v", blockHash,
blockHeader.Timestamp, checkpointTime)
return 0, false, ruleError(ErrCheckpointTimeTooOld, str)
}
if !fastAdd {
// Even though the checks prior to now have already ensured the
// proof of work exceeds the claimed amount, the claimed amount
// is a field in the block header which could be forged. This
// check ensures the proof of work is at least the minimum
// expected based on elapsed time since the last checkpoint and
// maximum adjustment allowed by the retarget rules.
duration := blockHeader.Timestamp.Sub(checkpointTime)
requiredTarget := CompactToBig(b.calcEasiestDifficulty(
checkpointHeader.Bits, duration))
currentTarget := CompactToBig(blockHeader.Bits)
if currentTarget.Cmp(requiredTarget) > 0 {
str := fmt.Sprintf("block target difficulty of %064x "+
"is too low when compared to the previous "+
"checkpoint", currentTarget)
return 0, false, ruleError(ErrDifficultyTooLow, str)
}
}
}
// Handle orphan blocks.
prevHash := &blockHeader.PrevBlock
prevHashExists, err := b.blockExists(prevHash)
if err != nil {
return 0, false, err
}
if !prevHashExists {
log.Infof("Adding orphan block %v with parent %v", blockHash,
prevHash)
b.addOrphanBlock(block)
// The fork length of orphans is unknown since they, by definition, do
// not connect to the best chain.
return 0, true, nil
}
// The block has passed all context independent checks and appears sane
// enough to potentially accept it into the block chain.
forkLen, err := b.maybeAcceptBlock(block, flags)
if err != nil {
return 0, false, err
}
// Accept any orphan blocks that depend on this block (they are no
// longer orphans) and repeat for those accepted blocks until there are
// no more.
err = b.processOrphans(blockHash, flags)
if err != nil {
return 0, false, err
}
log.Debugf("Accepted block %v", blockHash)
return forkLen, false, nil
}