# Copyright (c) 2016-2017, Neil Booth # Copyright (c) 2017, the ElectrumX authors # # All rights reserved. # # See the file "LICENCE" for information about the copyright # and warranty status of this software. """Block prefetcher and chain processor.""" import asyncio from struct import pack, unpack import time import torba from torba.server.daemon import DaemonError from torba.server.hash import hash_to_hex_str, HASHX_LEN from torba.server.util import chunks, class_logger from torba.server.db import FlushData class Prefetcher: """Prefetches blocks (in the forward direction only).""" def __init__(self, daemon, coin, blocks_event): self.logger = class_logger(__name__, self.__class__.__name__) self.daemon = daemon self.coin = coin self.blocks_event = blocks_event self.blocks = [] self.caught_up = False # Access to fetched_height should be protected by the semaphore self.fetched_height = None self.semaphore = asyncio.Semaphore() self.refill_event = asyncio.Event() # The prefetched block cache size. The min cache size has # little effect on sync time. self.cache_size = 0 self.min_cache_size = 10 * 1024 * 1024 # This makes the first fetch be 10 blocks self.ave_size = self.min_cache_size // 10 self.polling_delay = 5 async def main_loop(self, bp_height): """Loop forever polling for more blocks.""" await self.reset_height(bp_height) while True: try: # Sleep a while if there is nothing to prefetch await self.refill_event.wait() if not await self._prefetch_blocks(): await asyncio.sleep(self.polling_delay) except DaemonError as e: self.logger.info(f'ignoring daemon error: {e}') def get_prefetched_blocks(self): """Called by block processor when it is processing queued blocks.""" blocks = self.blocks self.blocks = [] self.cache_size = 0 self.refill_event.set() return blocks async def reset_height(self, height): """Reset to prefetch blocks from the block processor's height. Used in blockchain reorganisations. This coroutine can be called asynchronously to the _prefetch_blocks coroutine so we must synchronize with a semaphore. """ async with self.semaphore: self.blocks.clear() self.cache_size = 0 self.fetched_height = height self.refill_event.set() daemon_height = await self.daemon.height() behind = daemon_height - height if behind > 0: self.logger.info('catching up to daemon height {:,d} ' '({:,d} blocks behind)' .format(daemon_height, behind)) else: self.logger.info('caught up to daemon height {:,d}' .format(daemon_height)) async def _prefetch_blocks(self): """Prefetch some blocks and put them on the queue. Repeats until the queue is full or caught up. """ daemon = self.daemon daemon_height = await daemon.height() async with self.semaphore: while self.cache_size < self.min_cache_size: # Try and catch up all blocks but limit to room in cache. # Constrain fetch count to between 0 and 500 regardless; # testnet can be lumpy. cache_room = self.min_cache_size // self.ave_size count = min(daemon_height - self.fetched_height, cache_room) count = min(500, max(count, 0)) if not count: self.caught_up = True return False first = self.fetched_height + 1 hex_hashes = await daemon.block_hex_hashes(first, count) if self.caught_up: self.logger.info('new block height {:,d} hash {}' .format(first + count-1, hex_hashes[-1])) blocks = await daemon.raw_blocks(hex_hashes) assert count == len(blocks) # Special handling for genesis block if first == 0: blocks[0] = self.coin.genesis_block(blocks[0]) self.logger.info('verified genesis block with hash {}' .format(hex_hashes[0])) # Update our recent average block size estimate size = sum(len(block) for block in blocks) if count >= 10: self.ave_size = size // count else: self.ave_size = (size + (10 - count) * self.ave_size) // 10 self.blocks.extend(blocks) self.cache_size += size self.fetched_height += count self.blocks_event.set() self.refill_event.clear() return True class ChainError(Exception): """Raised on error processing blocks.""" class BlockProcessor: """Process blocks and update the DB state to match. Employ a prefetcher to prefetch blocks in batches for processing. Coordinate backing up in case of chain reorganisations. """ def __init__(self, env, db, daemon, notifications): self.env = env self.db = db self.daemon = daemon self.notifications = notifications self.coin = env.coin self.blocks_event = asyncio.Event() self.prefetcher = Prefetcher(daemon, env.coin, self.blocks_event) self.logger = class_logger(__name__, self.__class__.__name__) # Meta self.next_cache_check = 0 self.touched = set() self.reorg_count = 0 # Caches of unflushed items. self.headers = [] self.tx_hashes = [] self.undo_infos = [] # UTXO cache self.utxo_cache = {} self.db_deletes = [] # If the lock is successfully acquired, in-memory chain state # is consistent with self.height self.state_lock = asyncio.Lock() async def run_in_thread_with_lock(self, func, *args): # Run in a thread to prevent blocking. Shielded so that # cancellations from shutdown don't lose work - when the task # completes the data will be flushed and then we shut down. # Take the state lock to be certain in-memory state is # consistent and not being updated elsewhere. async def run_in_thread_locked(): async with self.state_lock: return await asyncio.get_event_loop().run_in_executor(None, func, *args) return await asyncio.shield(run_in_thread_locked()) async def check_and_advance_blocks(self, raw_blocks): """Process the list of raw blocks passed. Detects and handles reorgs. """ if not raw_blocks: return first = self.height + 1 blocks = [self.coin.block(raw_block, first + n) for n, raw_block in enumerate(raw_blocks)] headers = [block.header for block in blocks] hprevs = [self.coin.header_prevhash(h) for h in headers] chain = [self.tip] + [self.coin.header_hash(h) for h in headers[:-1]] if hprevs == chain: start = time.time() await self.run_in_thread_with_lock(self.advance_blocks, blocks) await self._maybe_flush() if not self.db.first_sync: s = '' if len(blocks) == 1 else 's' self.logger.info('processed {:,d} block{} in {:.1f}s' .format(len(blocks), s, time.time() - start)) if self._caught_up_event.is_set(): await self.notifications.on_block(self.touched, self.height) self.touched = set() elif hprevs[0] != chain[0]: await self.reorg_chain() else: # It is probably possible but extremely rare that what # bitcoind returns doesn't form a chain because it # reorg-ed the chain as it was processing the batched # block hash requests. Should this happen it's simplest # just to reset the prefetcher and try again. self.logger.warning('daemon blocks do not form a chain; ' 'resetting the prefetcher') await self.prefetcher.reset_height(self.height) async def reorg_chain(self, count=None): """Handle a chain reorganisation. Count is the number of blocks to simulate a reorg, or None for a real reorg.""" if count is None: self.logger.info('chain reorg detected') else: self.logger.info(f'faking a reorg of {count:,d} blocks') await self.flush(True) async def get_raw_blocks(last_height, hex_hashes): heights = range(last_height, last_height - len(hex_hashes), -1) try: blocks = [self.db.read_raw_block(height) for height in heights] self.logger.info(f'read {len(blocks)} blocks from disk') return blocks except FileNotFoundError: return await self.daemon.raw_blocks(hex_hashes) def flush_backup(): # self.touched can include other addresses which is # harmless, but remove None. self.touched.discard(None) self.db.flush_backup(self.flush_data(), self.touched) start, last, hashes = await self.reorg_hashes(count) # Reverse and convert to hex strings. hashes = [hash_to_hex_str(hash) for hash in reversed(hashes)] for hex_hashes in chunks(hashes, 50): raw_blocks = await get_raw_blocks(last, hex_hashes) await self.run_in_thread_with_lock(self.backup_blocks, raw_blocks) await self.run_in_thread_with_lock(flush_backup) last -= len(raw_blocks) await self.prefetcher.reset_height(self.height) async def reorg_hashes(self, count): """Return a pair (start, last, hashes) of blocks to back up during a reorg. The hashes are returned in order of increasing height. Start is the height of the first hash, last of the last. """ start, count = await self.calc_reorg_range(count) last = start + count - 1 s = '' if count == 1 else 's' self.logger.info(f'chain was reorganised replacing {count:,d} ' f'block{s} at heights {start:,d}-{last:,d}') return start, last, await self.db.fs_block_hashes(start, count) async def calc_reorg_range(self, count): """Calculate the reorg range""" def diff_pos(hashes1, hashes2): """Returns the index of the first difference in the hash lists. If both lists match returns their length.""" for n, (hash1, hash2) in enumerate(zip(hashes1, hashes2)): if hash1 != hash2: return n return len(hashes) if count is None: # A real reorg start = self.height - 1 count = 1 while start > 0: hashes = await self.db.fs_block_hashes(start, count) hex_hashes = [hash_to_hex_str(hash) for hash in hashes] d_hex_hashes = await self.daemon.block_hex_hashes(start, count) n = diff_pos(hex_hashes, d_hex_hashes) if n > 0: start += n break count = min(count * 2, start) start -= count count = (self.height - start) + 1 else: start = (self.height - count) + 1 return start, count def estimate_txs_remaining(self): # Try to estimate how many txs there are to go daemon_height = self.daemon.cached_height() coin = self.coin tail_count = daemon_height - max(self.height, coin.TX_COUNT_HEIGHT) # Damp the initial enthusiasm realism = max(2.0 - 0.9 * self.height / coin.TX_COUNT_HEIGHT, 1.0) return (tail_count * coin.TX_PER_BLOCK + max(coin.TX_COUNT - self.tx_count, 0)) * realism # - Flushing def flush_data(self): """The data for a flush. The lock must be taken.""" assert self.state_lock.locked() return FlushData(self.height, self.tx_count, self.headers, self.tx_hashes, self.undo_infos, self.utxo_cache, self.db_deletes, self.tip) async def flush(self, flush_utxos): def flush(): self.db.flush_dbs(self.flush_data(), flush_utxos, self.estimate_txs_remaining) await self.run_in_thread_with_lock(flush) async def _maybe_flush(self): # If caught up, flush everything as client queries are # performed on the DB. if self._caught_up_event.is_set(): await self.flush(True) elif time.time() > self.next_cache_check: flush_arg = self.check_cache_size() if flush_arg is not None: await self.flush(flush_arg) self.next_cache_check = time.time() + 30 def check_cache_size(self): """Flush a cache if it gets too big.""" # Good average estimates based on traversal of subobjects and # requesting size from Python (see deep_getsizeof). one_MB = 1000*1000 utxo_cache_size = len(self.utxo_cache) * 205 db_deletes_size = len(self.db_deletes) * 57 hist_cache_size = self.db.history.unflushed_memsize() # Roughly ntxs * 32 + nblocks * 42 tx_hash_size = ((self.tx_count - self.db.fs_tx_count) * 32 + (self.height - self.db.fs_height) * 42) utxo_MB = (db_deletes_size + utxo_cache_size) // one_MB hist_MB = (hist_cache_size + tx_hash_size) // one_MB self.logger.info('our height: {:,d} daemon: {:,d} ' 'UTXOs {:,d}MB hist {:,d}MB' .format(self.height, self.daemon.cached_height(), utxo_MB, hist_MB)) # Flush history if it takes up over 20% of cache memory. # Flush UTXOs once they take up 80% of cache memory. cache_MB = self.env.cache_MB if utxo_MB + hist_MB >= cache_MB or hist_MB >= cache_MB // 5: return utxo_MB >= cache_MB * 4 // 5 return None def advance_blocks(self, blocks): """Synchronously advance the blocks. It is already verified they correctly connect onto our tip. """ min_height = self.db.min_undo_height(self.daemon.cached_height()) height = self.height for block in blocks: height += 1 undo_info = self.advance_txs( height, block.transactions, self.coin.electrum_header(block.header, height) ) if height >= min_height: self.undo_infos.append((undo_info, height)) self.db.write_raw_block(block.raw, height) headers = [block.header for block in blocks] self.height = height self.headers.extend(headers) self.tip = self.coin.header_hash(headers[-1]) def advance_txs(self, height, txs, header): self.tx_hashes.append(b''.join(tx_hash for tx, tx_hash in txs)) # Use local vars for speed in the loops undo_info = [] tx_num = self.tx_count script_hashX = self.coin.hashX_from_script s_pack = pack put_utxo = self.utxo_cache.__setitem__ spend_utxo = self.spend_utxo undo_info_append = undo_info.append update_touched = self.touched.update hashXs_by_tx = [] append_hashXs = hashXs_by_tx.append for tx, tx_hash in txs: hashXs = [] append_hashX = hashXs.append tx_numb = s_pack('= len(raw_blocks) coin = self.coin for raw_block in raw_blocks: # Check and update self.tip block = coin.block(raw_block, self.height) header_hash = coin.header_hash(block.header) if header_hash != self.tip: raise ChainError('backup block {} not tip {} at height {:,d}' .format(hash_to_hex_str(header_hash), hash_to_hex_str(self.tip), self.height)) self.tip = coin.header_prevhash(block.header) self.backup_txs(block.transactions) self.height -= 1 self.db.tx_counts.pop() self.logger.info('backed up to height {:,d}'.format(self.height)) def backup_txs(self, txs): # Prevout values, in order down the block (coinbase first if present) # undo_info is in reverse block order undo_info = self.db.read_undo_info(self.height) if undo_info is None: raise ChainError('no undo information found for height {:,d}' .format(self.height)) n = len(undo_info) # Use local vars for speed in the loops s_pack = pack put_utxo = self.utxo_cache.__setitem__ spend_utxo = self.spend_utxo script_hashX = self.coin.hashX_from_script touched = self.touched undo_entry_len = 12 + HASHX_LEN for tx, tx_hash in reversed(txs): for idx, txout in enumerate(tx.outputs): # Spend the TX outputs. Be careful with unspendable # outputs - we didn't save those in the first place. hashX = script_hashX(txout.pk_script) if hashX: cache_value = spend_utxo(tx_hash, idx) touched.add(cache_value[:-12]) # Restore the inputs for txin in reversed(tx.inputs): if txin.is_generation(): continue n -= undo_entry_len undo_item = undo_info[n:n + undo_entry_len] put_utxo(txin.prev_hash + s_pack(' 1: tx_num, = unpack('False state. first_sync = self.db.first_sync self.db.first_sync = False await self.flush(True) if first_sync: self.logger.info(f'{torba.__version__} synced to ' f'height {self.height:,d}') # Reopen for serving await self.db.open_for_serving() async def _first_open_dbs(self): await self.db.open_for_sync() self.height = self.db.db_height self.tip = self.db.db_tip self.tx_count = self.db.db_tx_count # --- External API async def fetch_and_process_blocks(self, caught_up_event): """Fetch, process and index blocks from the daemon. Sets caught_up_event when first caught up. Flushes to disk and shuts down cleanly if cancelled. This is mainly because if, during initial sync ElectrumX is asked to shut down when a large number of blocks have been processed but not written to disk, it should write those to disk before exiting, as otherwise a significant amount of work could be lost. """ self._caught_up_event = caught_up_event await self._first_open_dbs() try: await asyncio.wait([ self.prefetcher.main_loop(self.height), self._process_prefetched_blocks() ]) finally: # Shut down block processing self.logger.info('flushing to DB for a clean shutdown...') await self.flush(True) self.db.close() def force_chain_reorg(self, count): """Force a reorg of the given number of blocks. Returns True if a reorg is queued, false if not caught up. """ if self._caught_up_event.is_set(): self.reorg_count = count self.blocks_event.set() return True return False class DecredBlockProcessor(BlockProcessor): async def calc_reorg_range(self, count): start, count = await super().calc_reorg_range(count) if start > 0: # A reorg in Decred can invalidate the previous block start -= 1 count += 1 return start, count class NamecoinBlockProcessor(BlockProcessor): def advance_txs(self, txs): result = super().advance_txs(txs) tx_num = self.tx_count - len(txs) script_name_hashX = self.coin.name_hashX_from_script update_touched = self.touched.update hashXs_by_tx = [] append_hashXs = hashXs_by_tx.append for tx, tx_hash in txs: hashXs = [] append_hashX = hashXs.append # Add the new UTXOs and associate them with the name script for idx, txout in enumerate(tx.outputs): # Get the hashX of the name script. Ignore non-name scripts. hashX = script_name_hashX(txout.pk_script) if hashX: append_hashX(hashX) append_hashXs(hashXs) update_touched(hashXs) tx_num += 1 self.db.history.add_unflushed(hashXs_by_tx, self.tx_count - len(txs)) return result