Tinychain源码阅读笔记2-检测区块有效性

in #cn6 years ago

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_chainNone,所以chains = [active_chain, *side_branches],我们找下active_chainside_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。

Sort:  

Congratulations @derekray! You have completed the following achievement on the Steem blockchain and have been rewarded with new badge(s) :

You got a First Vote

Click here to view your Board of Honor
If you no longer want to receive notifications, reply to this comment with the word STOP

Support SteemitBoard's project! Vote for its witness and get one more award!

Coin Marketplace

STEEM 0.23
TRX 0.21
JST 0.035
BTC 96557.13
ETH 3328.16
USDT 1.00
SBD 3.18