#!/usr/bin/env python2 # # Distributed under the GPLv3 software license, see the accompanying # file COPYING or https://www.gnu.org/licenses/gpl-3.0.en.html # from mininode import CBlock, CTransaction, CInv, NodeConn, NodeConnCB, \ msg_inv, msg_getheaders, msg_ping, msg_mempool, mininode_lock, MAX_INV_SZ from blockstore import BlockStore, TxStore from util import p2p_port import time ''' This is a tool for comparing two or more bitcoinds to each other using a script provided. To use, create a class that implements get_tests(), and pass it in as the test generator to TestManager. get_tests() should be a python generator that returns TestInstance objects. See below for definition. ''' # TestNode behaves as follows: # Configure with a BlockStore and TxStore # on_inv: log the message but don't request # on_headers: log the chain tip # on_pong: update ping response map (for synchronization) # on_getheaders: provide headers via BlockStore # on_getdata: provide blocks via BlockStore def wait_until(predicate, attempts=float('inf'), timeout=float('inf')): attempt = 0 elapsed = 0 while attempt < attempts and elapsed < timeout: with mininode_lock: if predicate(): return True attempt += 1 elapsed += 0.05 time.sleep(0.05) return False class TestNode(NodeConnCB): def __init__(self, block_store, tx_store): NodeConnCB.__init__(self) self.create_callback_map() self.conn = None self.bestblockhash = None self.block_store = block_store self.block_request_map = {} self.tx_store = tx_store self.tx_request_map = {} # When the pingmap is non-empty we're waiting for # a response self.pingMap = {} self.lastInv = [] self.closed = False def on_close(self, conn): self.closed = True def add_connection(self, conn): self.conn = conn def on_headers(self, conn, message): if len(message.headers) > 0: best_header = message.headers[-1] best_header.calc_sha256() self.bestblockhash = best_header.sha256 def on_getheaders(self, conn, message): response = self.block_store.headers_for(message.locator, message.hashstop) if response is not None: conn.send_message(response) def on_getdata(self, conn, message): [conn.send_message(r) for r in self.block_store.get_blocks(message.inv)] [conn.send_message(r) for r in self.tx_store.get_transactions(message.inv)] for i in message.inv: if i.type == 1: self.tx_request_map[i.hash] = True elif i.type == 2: self.block_request_map[i.hash] = True def on_inv(self, conn, message): self.lastInv = [x.hash for x in message.inv] def on_pong(self, conn, message): try: del self.pingMap[message.nonce] except KeyError: raise AssertionError("Got pong for unknown ping [%s]" % repr(message)) def send_inv(self, obj): mtype = 2 if isinstance(obj, CBlock) else 1 self.conn.send_message(msg_inv([CInv(mtype, obj.sha256)])) def send_getheaders(self): # We ask for headers from their last tip. m = msg_getheaders() m.locator = self.block_store.get_locator(self.bestblockhash) self.conn.send_message(m) # This assumes BIP31 def send_ping(self, nonce): self.pingMap[nonce] = True self.conn.send_message(msg_ping(nonce)) def received_ping_response(self, nonce): return nonce not in self.pingMap def send_mempool(self): self.lastInv = [] self.conn.send_message(msg_mempool()) # TestInstance: # # Instances of these are generated by the test generator, and fed into the # comptool. # # "blocks_and_transactions" should be an array of [obj, True/False/None]: # - obj is either a CBlock or a CTransaction, and # - the second value indicates whether the object should be accepted # into the blockchain or mempool (for tests where we expect a certain # answer), or "None" if we don't expect a certain answer and are just # comparing the behavior of the nodes being tested. # sync_every_block: if True, then each block will be inv'ed, synced, and # nodes will be tested based on the outcome for the block. If False, # then inv's accumulate until all blocks are processed (or max inv size # is reached) and then sent out in one inv message. Then the final block # will be synced across all connections, and the outcome of the final # block will be tested. # sync_every_tx: analogous to behavior for sync_every_block, except if outcome # on the final tx is None, then contents of entire mempool are compared # across all connections. (If outcome of final tx is specified as true # or false, then only the last tx is tested against outcome.) class TestInstance(object): def __init__(self, objects=None, sync_every_block=True, sync_every_tx=False): self.blocks_and_transactions = objects if objects else [] self.sync_every_block = sync_every_block self.sync_every_tx = sync_every_tx class TestManager(object): def __init__(self, testgen, datadir): self.test_generator = testgen self.connections = [] self.test_nodes = [] self.block_store = BlockStore(datadir) self.tx_store = TxStore(datadir) self.ping_counter = 1 def add_all_connections(self, nodes): for i in range(len(nodes)): # Create a p2p connection to each node test_node = TestNode(self.block_store, self.tx_store) self.test_nodes.append(test_node) self.connections.append(NodeConn('127.0.0.1', p2p_port(i), nodes[i], test_node)) # Make sure the TestNode (callback class) has a reference to its # associated NodeConn test_node.add_connection(self.connections[-1]) def wait_for_disconnections(self): def disconnected(): return all(node.closed for node in self.test_nodes) return wait_until(disconnected, timeout=10) def wait_for_verack(self): def veracked(): return all(node.verack_received for node in self.test_nodes) return wait_until(veracked, timeout=10) def wait_for_pings(self, counter): def received_pongs(): return all(node.received_ping_response(counter) for node in self.test_nodes) return wait_until(received_pongs) # sync_blocks: Wait for all connections to request the blockhash given # then send get_headers to find out the tip of each node, and synchronize # the response by using a ping (and waiting for pong with same nonce). def sync_blocks(self, blockhash, num_blocks): def blocks_requested(): return all( blockhash in node.block_request_map and node.block_request_map[blockhash] for node in self.test_nodes ) # --> error if not requested if not wait_until(blocks_requested, attempts=20*num_blocks): # print [ c.cb.block_request_map for c in self.connections ] raise AssertionError("Not all nodes requested block") # --> Answer request (we did this inline!) # Send getheaders message [ c.cb.send_getheaders() for c in self.connections ] # Send ping and wait for response -- synchronization hack [ c.cb.send_ping(self.ping_counter) for c in self.connections ] self.wait_for_pings(self.ping_counter) self.ping_counter += 1 # Analogous to sync_block (see above) def sync_transaction(self, txhash, num_events): # Wait for nodes to request transaction (50ms sleep * 20 tries * num_events) def transaction_requested(): return all( txhash in node.tx_request_map and node.tx_request_map[txhash] for node in self.test_nodes ) # --> error if not requested if not wait_until(transaction_requested, attempts=20*num_events): # print [ c.cb.tx_request_map for c in self.connections ] raise AssertionError("Not all nodes requested transaction") # --> Answer request (we did this inline!) # Get the mempool [ c.cb.send_mempool() for c in self.connections ] # Send ping and wait for response -- synchronization hack [ c.cb.send_ping(self.ping_counter) for c in self.connections ] self.wait_for_pings(self.ping_counter) self.ping_counter += 1 # Sort inv responses from each node with mininode_lock: [ c.cb.lastInv.sort() for c in self.connections ] # Verify that the tip of each connection all agree with each other, and # with the expected outcome (if given) def check_results(self, blockhash, outcome): with mininode_lock: for c in self.connections: if outcome is None: if c.cb.bestblockhash != self.connections[0].cb.bestblockhash: return False elif ((c.cb.bestblockhash == blockhash) != outcome): # print c.cb.bestblockhash, blockhash, outcome return False return True # Either check that the mempools all agree with each other, or that # txhash's presence in the mempool matches the outcome specified. # This is somewhat of a strange comparison, in that we're either comparing # a particular tx to an outcome, or the entire mempools altogether; # perhaps it would be useful to add the ability to check explicitly that # a particular tx's existence in the mempool is the same across all nodes. def check_mempool(self, txhash, outcome): with mininode_lock: for c in self.connections: if outcome is None: # Make sure the mempools agree with each other if c.cb.lastInv != self.connections[0].cb.lastInv: # print c.rpc.getrawmempool() return False elif ((txhash in c.cb.lastInv) != outcome): # print c.rpc.getrawmempool(), c.cb.lastInv return False return True def run(self): # Wait until verack is received self.wait_for_verack() test_number = 1 for test_instance in self.test_generator.get_tests(): # We use these variables to keep track of the last block # and last transaction in the tests, which are used # if we're not syncing on every block or every tx. [ block, block_outcome ] = [ None, None ] [ tx, tx_outcome ] = [ None, None ] invqueue = [] for b_or_t, outcome in test_instance.blocks_and_transactions: # Determine if we're dealing with a block or tx if isinstance(b_or_t, CBlock): # Block test runner block = b_or_t block_outcome = outcome # Add to shared block_store, set as current block with mininode_lock: self.block_store.add_block(block) for c in self.connections: c.cb.block_request_map[block.sha256] = False # Either send inv's to each node and sync, or add # to invqueue for later inv'ing. if (test_instance.sync_every_block): [ c.cb.send_inv(block) for c in self.connections ] self.sync_blocks(block.sha256, 1) if (not self.check_results(block.sha256, outcome)): raise AssertionError("Test failed at test %d" % test_number) else: invqueue.append(CInv(2, block.sha256)) else: # Tx test runner assert(isinstance(b_or_t, CTransaction)) tx = b_or_t tx_outcome = outcome # Add to shared tx store and clear map entry with mininode_lock: self.tx_store.add_transaction(tx) for c in self.connections: c.cb.tx_request_map[tx.sha256] = False # Again, either inv to all nodes or save for later if (test_instance.sync_every_tx): [ c.cb.send_inv(tx) for c in self.connections ] self.sync_transaction(tx.sha256, 1) if (not self.check_mempool(tx.sha256, outcome)): raise AssertionError("Test failed at test %d" % test_number) else: invqueue.append(CInv(1, tx.sha256)) # Ensure we're not overflowing the inv queue if len(invqueue) == MAX_INV_SZ: [ c.send_message(msg_inv(invqueue)) for c in self.connections ] invqueue = [] # Do final sync if we weren't syncing on every block or every tx. if (not test_instance.sync_every_block and block is not None): if len(invqueue) > 0: [ c.send_message(msg_inv(invqueue)) for c in self.connections ] invqueue = [] self.sync_blocks(block.sha256, len(test_instance.blocks_and_transactions)) if (not self.check_results(block.sha256, block_outcome)): raise AssertionError("Block test failed at test %d" % test_number) if (not test_instance.sync_every_tx and tx is not None): if len(invqueue) > 0: [ c.send_message(msg_inv(invqueue)) for c in self.connections ] invqueue = [] self.sync_transaction(tx.sha256, len(test_instance.blocks_and_transactions)) if (not self.check_mempool(tx.sha256, tx_outcome)): raise AssertionError("Mempool test failed at test %d" % test_number) print "Test %d: PASS" % test_number, [ c.rpc.getblockcount() for c in self.connections ] test_number += 1 [ c.disconnect_node() for c in self.connections ] self.wait_for_disconnections() self.block_store.close() self.tx_store.close()