Tinychain源码阅读笔记2-检测区块有效性
Tinychain源码阅读笔记2-检测区块有效性
上次我们分析到load_from_disk如何将chain.dat中的区块数据解析出来的,接下来的工作便是验证区块的有效性了,直接看 connect_block函数:
@with_lock(chain_lock)
def connect_block(block: Union[str, Block],
doing_reorg=False,
) -> Union[None, Block]:
"""Accept a block and return the chain index we append it to."""
# Only exit early on already seen in active_chain when reorging.
connect_block函数接受Block,还有个默认值为False的doing_reorg参数,我们暂时不关心这个参数,继续看代码。
search_chain = active_chain if doing_reorg else None
if locate_block(block.id, chain=search_chain)[0]:
logger.debug(f'ignore block already seen: {block.id}')
return None
doing_reorg默认是false,所以这里search_chain是None,接着是locate_block,这个函数是为了检测区块是否与历史区块重复。
@with_lock(chain_lock)
def locate_block(block_hash: str, chain=None) -> (Block, int, int):
chains = [chain] if chain else [active_chain, *side_branches]
for chain_idx, chain in enumerate(chains):
for height, block in enumerate(chain):
if block.id == block_hash:
return (block, height, chain_idx)
return (None, None, None)
因为传进来的search_chain
是None
,所以chains = [active_chain, *side_branches]
,我们找下active_chain
和side_branches
的定义
active_chain: Iterable[Block] = [genesis_block]
side_branches: Iterable[Iterable[Block]] = []
active_chain
默认是包含创世区块的list,side_branches
则是包含list的list,最里面的list包含区块。所以chains
实际是不同链组成的list,也就是主链与分叉链,关于分叉详细情况后面再分析。
随后遍历chains,如果当前block.id与历史区块重复,则返回这个区块和区块高度以及该区块所处的链id。
try:
block, chain_idx = validate_block(block)
except BlockValidationError as e:
logger.exception('block %s failed validation', block.id)
if e.to_orphan:
logger.info(f"saw orphan block {block.id}")
orphan_blocks.append(e.to_orphan)
return None
后续要检测区块的有效性
@with_lock(chain_lock)
def validate_block(block: Block) -> Block:
if not block.txns:
raise BlockValidationError('txns empty')
if block.timestamp - time.time() > Params.MAX_FUTURE_BLOCK_TIME:
raise BlockValidationError('Block timestamp too far in future')
首先区块交易是None,连coinbase交易都没有,肯定是个无效区块。随后这个判断我没有理解作者的意思,block.timestamp - time.time()
肯定是个负值,区块难道可能来自未来???继续看代码
if int(block.id, 16) > (1 << (256 - block.bits)):
raise BlockValidationError("Block header doesn't satisfy bits")
bits这个元素是决定区块创建难度的,区块生成要满足int(sha256d(block.header(nonce)), 16) < (1 << (256 - block.bits))
这个条件,后续会介绍区块难度的变化情况。
if [i for (i, tx) in enumerate(block.txns) if tx.is_coinbase] != [0]:
raise BlockValidationError('First txn must be coinbase and no more')
区块的coinbase交易顺序应在交易列表的第一位,接下来
try:
for i, txn in enumerate(block.txns):
txn.validate_basics(as_coinbase=(i == 0))
except TxnValidationError:
logger.exception(f"Transaction {txn} in {block} failed to validate")
raise BlockValidationError('Invalid txn {txn.id}')
这段代码是为了验证区块交易的基本有效性,看看validate_basics函数的代码
def validate_basics(self, as_coinbase=False):
if (not self.txouts) or (not self.txins and not as_coinbase):
raise TxnValidationError('Missing txouts or txins')
if len(serialize(self)) > Params.MAX_BLOCK_SERIALIZED_SIZE:
raise TxnValidationError('Too large')
if sum(t.value for t in self.txouts) > Params.MAX_MONEY:
raise TxnValidationError('Spend value too high')
当没有交易输出或者非coinbase交易没有输入,交易无效。还有交易总字节大小超过1MB以及交易输出金额超过总上限,交易都是无效的。
if get_merkle_root_of_txns(block.txns).val != block.merkle_hash:
raise BlockValidationError('Merkle hash invalid')
接下来验证的是交易merkleTree
def get_merkle_root_of_txns(txns):
return get_merkle_root(*[t.id for t in txns])
将所有交易id传递给get_merkel_root
@lru_cache(maxsize=1024)
def get_merkle_root(*leaves: Tuple[str]) -> MerkleNode:
"""Builds a Merkle tree and returns the root given some leaf values."""
if len(leaves) % 2 == 1:
leaves = leaves + (leaves[-1],)
def find_root(nodes):
newlevel = [
MerkleNode(sha256d(i1.val + i2.val), children=[i1, i2])
for [i1, i2] in _chunks(nodes, 2)
]
return find_root(newlevel) if len(newlevel) > 1 else newlevel[0]
return find_root([MerkleNode(sha256d(l)) for l in leaves])
所有传进来的交易id,把它们称之为叶子,首先判断叶子节点个数,是奇数的话,复制最后一个叶子到叶子群中,使叶子总数为偶数。get_merkle_root内部定义了find_root函数,显然又是一个递归函数。
class MerkleNode(NamedTuple):
val: str
children: Iterable = None
def _chunks(l, n) -> Iterable[Iterable]:
return (l[i:i + n] for i in range(0, len(l), n))
看到MerkleNode和_chunks的定义后,这段代码就很容易理解了,每两个相邻叶子的哈希值拼接在一起,对其双哈希生成了一个新的叶子,不断的递归调用,直至剩下一个节点,这个节点的值也就是merkleroot。每次递归的计算量是源叶子节点的一半,因此该算法的时间复杂度是log(n)。
if block.timestamp <= get_median_time_past(11):
raise BlockValidationError('timestamp too old')
计算最近11个区块中间区块的时间戳,如果当前区块的时间戳不大于这个时间戳,区块无效
if not block.prev_block_hash and not active_chain:
# This is the genesis block.
prev_block_chain_idx = ACTIVE_CHAIN_IDX
else:
prev_block, prev_block_height, prev_block_chain_idx = locate_block(
block.prev_block_hash)
if not prev_block:
raise BlockValidationError(
f'prev block {block.prev_block_hash} not found in any chain',
to_orphan=block)
当active_chain为None时,没有prev_block_hash的区块判定其为创世区块,并将父区块的链id设为ACTIVE_CHAIN_IDX。不满足上述条件则调用locate_block,获取prev_block, prev_block_height, prev_block_chain_idx,prev_block为None则报错,判定其为孤块。
# No more validation for a block getting attached to a branch.
if prev_block_chain_idx != ACTIVE_CHAIN_IDX:
return block, prev_block_chain_idx
# Prev. block found in active chain, but isn't tip => new fork.
elif prev_block != active_chain[-1]:
return block, prev_block_chain_idx + 1 # Non-existent
如果父区块的链id不为ACTIVE_CHAIN_IDX,则返回该父区块及其的链id。否则如果父区块不在active_chain末尾,则返回目前的区块和prev_block_chain_idx + 1。
if get_next_work_required(block.prev_block_hash) != block.bits:
raise BlockValidationError('bits is incorrect')
这段代码是为了验证该区块的难度值是否正确,子区块的难度是由父区块决定的。看一下get_next_work_required这个函数,传进的参数是区块哈希值
def get_next_work_required(prev_block_hash: str) -> int:
"""
Based on the chain, return the number of difficulty bits the next block
must solve.
"""
if not prev_block_hash:
return Params.INITIAL_DIFFICULTY_BITS
(prev_block, prev_height, _) = locate_block(prev_block_hash)
if (prev_height + 1) % Params.DIFFICULTY_PERIOD_IN_BLOCKS != 0:
return prev_block.bits
with chain_lock:
# #realname CalculateNextWorkRequired
period_start_block = active_chain[max(
prev_height - (Params.DIFFICULTY_PERIOD_IN_BLOCKS - 1), 0)]
actual_time_taken = prev_block.timestamp - period_start_block.timestamp
if actual_time_taken < Params.DIFFICULTY_PERIOD_IN_SECS_TARGET:
# Increase the difficulty
return prev_block.bits + 1
elif actual_time_taken > Params.DIFFICULTY_PERIOD_IN_SECS_TARGET:
return prev_block.bits - 1
else:
# Wow, that's unlikely.
return prev_block.bits
当prev_block_hash为None,会认定为此区块是创世区块,则把难度值设置为初始值INITIAL_DIFFICULTY_BITS,这个值为24.随后要获取父区块及其区块高度,tinychain定义了DIFFICULTY_PERIOD_IN_BLOCKS这个全局变量,它的值是600,意思是,从创世区块开始,每600个区块是一个难度周期,也就是说这600个区块的bits值都是一样的。如果目前的区块与父区块在同一个周期内,那么它的bits与父区块相等。如果当前区块处于一个新的难度周期,那么它的bits如何计算呢?这与上一个难度周期内的600个区块全部生成的总时间有关,即actual_time_taken这个量,看最后的判断代码,DIFFICULTY_PERIOD_IN_SECS_TARGET这个值是36000,难度周期的总时间比它大就减少难度,小就增加难度。这样做的目的是让这600个区块生成的时间趋近于36000秒,与算力变化有关,即无论算力如何变化,区块生成的速度总是稳定的,保障了tinychain的稳定性。
for txn in block.txns[1:]:
try:
validate_txn(txn, siblings_in_block=block.txns[1:],
allow_utxo_from_mempool=False)
except TxnValidationError:
msg = f"{txn} failed to validate"
logger.exception(msg)
raise BlockValidationError(msg)
最后验证非coinbase交易的有效性,交易是tinychain的核心内容,比较复杂,下次再分析。
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