async def test_assert_time_exceeds(self, two_nodes):

        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        # Farm blocks
        blocks = bt.get_consecutive_blocks(test_constants, num_blocks, [], 10,
                                           b"", coinbase_puzzlehash)
        full_node_1, full_node_2, server_1, server_2 = two_nodes

        for block in blocks:
            async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(block)):
                pass

        # Coinbase that gets spent
        block1 = blocks[1]

        # This condition requires block1 coinbase to be spent after 3 seconds from now
        current_time_plus3 = uint64(int(time.time() * 1000) + 3000)
        block1_cvp = ConditionVarPair(ConditionOpcode.ASSERT_TIME_EXCEEDS,
                                      int_to_bytes(current_time_plus3), None)
        block1_dic = {block1_cvp.opcode: [block1_cvp]}
        block1_spend_bundle = wallet_a.generate_signed_transaction(
            1000, receiver_puzzlehash, block1.get_coinbase(), block1_dic)

        # program that will be sent to early
        assert block1_spend_bundle is not None
        program = best_solution_program(block1_spend_bundle)
        aggsig = block1_spend_bundle.aggregated_signature

        # Create another block that includes our transaction
        dic_h = {11: (program, aggsig)}
        invalid_new_blocks = bt.get_consecutive_blocks(test_constants, 1,
                                                       blocks, 10, b"",
                                                       coinbase_puzzlehash,
                                                       dic_h)

        # Try to validate that block before 3 sec
        next_block = invalid_new_blocks[11]
        error = await full_node_1.blockchain._validate_transactions(
            next_block,
            next_block.get_fees_coin().amount)

        assert error is Err.ASSERT_TIME_EXCEEDS_FAILED

        # wait 3 sec to pass
        await asyncio.sleep(3.1)

        dic_h = {12: (program, aggsig)}
        valid_new_blocks = bt.get_consecutive_blocks(test_constants, 2,
                                                     blocks[:11], 10, b"",
                                                     coinbase_puzzlehash,
                                                     dic_h)

        for block in valid_new_blocks:
            async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(block)):
                pass

        # Try to validate that block after 3 sec have passed
        next_block = valid_new_blocks[12]

        error = await full_node_1.blockchain._validate_transactions(
            next_block,
            next_block.get_fees_coin().amount)

        assert error is None
Exemplo n.º 2
0
    async def test1(self, two_nodes):
        num_blocks = 5
        test_rpc_port = uint16(21522)
        nodes, _ = two_nodes
        full_node_api_1, full_node_api_2 = nodes
        server_1 = full_node_api_1.full_node.server
        server_2 = full_node_api_2.full_node.server

        def stop_node_cb():
            full_node_api_1._close()
            server_1.close_all()

        full_node_rpc_api = FullNodeRpcApi(full_node_api_1.full_node)

        config = bt.config
        hostname = config["self_hostname"]
        daemon_port = config["daemon_port"]

        rpc_cleanup = await start_rpc_server(
            full_node_rpc_api,
            hostname,
            daemon_port,
            test_rpc_port,
            stop_node_cb,
            bt.root_path,
            config,
            connect_to_daemon=False,
        )

        try:
            client = await FullNodeRpcClient.create(self_hostname,
                                                    test_rpc_port,
                                                    bt.root_path, config)
            await validate_get_routes(client, full_node_rpc_api)
            state = await client.get_blockchain_state()
            assert state["peak"] is None
            assert not state["sync"]["sync_mode"]
            assert state["difficulty"] > 0
            assert state["sub_slot_iters"] > 0

            blocks = bt.get_consecutive_blocks(num_blocks)
            blocks = bt.get_consecutive_blocks(
                num_blocks,
                block_list_input=blocks,
                guarantee_transaction_block=True)

            assert len(await client.get_unfinished_block_headers()) == 0
            assert len((await client.get_block_records(0, 100))) == 0
            for block in blocks:
                if is_overflow_block(
                        test_constants,
                        block.reward_chain_block.signage_point_index):
                    finished_ss = block.finished_sub_slots[:-1]
                else:
                    finished_ss = block.finished_sub_slots

                unf = UnfinishedBlock(
                    finished_ss,
                    block.reward_chain_block.get_unfinished(),
                    block.challenge_chain_sp_proof,
                    block.reward_chain_sp_proof,
                    block.foliage,
                    block.foliage_transaction_block,
                    block.transactions_info,
                    block.transactions_generator,
                    [],
                )
                await full_node_api_1.full_node.respond_unfinished_block(
                    full_node_protocol.RespondUnfinishedBlock(unf), None)
                await full_node_api_1.full_node.respond_block(
                    full_node_protocol.RespondBlock(block), None)

            assert len(await client.get_unfinished_block_headers()) > 0
            assert len(await client.get_all_block(0, 2)) == 2
            state = await client.get_blockchain_state()

            block = await client.get_block(state["peak"].header_hash)
            assert block == blocks[-1]
            assert (await client.get_block(bytes([1] * 32))) is None

            assert (await client.get_block_record_by_height(2)
                    ).header_hash == blocks[2].header_hash

            assert len((await client.get_block_records(0,
                                                       100))) == num_blocks * 2

            assert (await client.get_block_record_by_height(100)) is None

            ph = list(blocks[-1].get_included_reward_coins())[0].puzzle_hash
            coins = await client.get_coin_records_by_puzzle_hash(ph)
            print(coins)
            assert len(coins) >= 1

            pid = list(
                blocks[-1].get_included_reward_coins())[0].parent_coin_info
            pid_2 = list(
                blocks[-1].get_included_reward_coins())[1].parent_coin_info
            coins = await client.get_coin_records_by_parent_ids([pid, pid_2])
            print(coins)
            assert len(coins) == 2

            name = list(blocks[-1].get_included_reward_coins())[0].name()
            name_2 = list(blocks[-1].get_included_reward_coins())[1].name()
            coins = await client.get_coin_records_by_names([name, name_2])
            print(coins)
            assert len(coins) == 2

            additions, removals = await client.get_additions_and_removals(
                blocks[-1].header_hash)
            assert len(additions) >= 2 and len(removals) == 0

            wallet = WalletTool(full_node_api_1.full_node.constants)
            wallet_receiver = WalletTool(
                full_node_api_1.full_node.constants,
                AugSchemeMPL.key_gen(std_hash(b"123123")))
            ph = wallet.get_new_puzzlehash()
            ph_2 = wallet.get_new_puzzlehash()
            ph_receiver = wallet_receiver.get_new_puzzlehash()

            assert len(await client.get_coin_records_by_puzzle_hash(ph)) == 0
            assert len(
                await client.get_coin_records_by_puzzle_hash(ph_receiver)) == 0
            blocks = bt.get_consecutive_blocks(
                2,
                block_list_input=blocks,
                guarantee_transaction_block=True,
                farmer_reward_puzzle_hash=ph,
                pool_reward_puzzle_hash=ph,
            )
            for block in blocks[-2:]:
                await full_node_api_1.full_node.respond_block(
                    full_node_protocol.RespondBlock(block))
            assert len(await client.get_coin_records_by_puzzle_hash(ph)) == 2
            assert len(
                await client.get_coin_records_by_puzzle_hash(ph_receiver)) == 0

            coin_to_spend = list(blocks[-1].get_included_reward_coins())[0]

            spend_bundle = wallet.generate_signed_transaction(
                coin_to_spend.amount, ph_receiver, coin_to_spend)

            assert len(await client.get_all_mempool_items()) == 0
            assert len(await client.get_all_mempool_tx_ids()) == 0
            assert (await client.get_mempool_item_by_tx_id(spend_bundle.name()
                                                           )) is None

            await client.push_tx(spend_bundle)
            coin = spend_bundle.additions()[0]

            assert len(await client.get_all_mempool_items()) == 1
            assert len(await client.get_all_mempool_tx_ids()) == 1
            assert (SpendBundle.from_json_dict(
                list((await client.get_all_mempool_items()
                      ).values())[0]["spend_bundle"]) == spend_bundle)
            assert (await
                    client.get_all_mempool_tx_ids())[0] == spend_bundle.name()
            assert (SpendBundle.from_json_dict(
                (await client.get_mempool_item_by_tx_id(
                    spend_bundle.name()))["spend_bundle"]) == spend_bundle)
            assert (await client.get_coin_record_by_name(coin.name())) is None

            await full_node_api_1.farm_new_transaction_block(
                FarmNewBlockProtocol(ph_2))

            assert (await
                    client.get_coin_record_by_name(coin.name())).coin == coin

            assert len(
                await client.get_coin_records_by_puzzle_hash(ph_receiver)) == 1
            assert len(
                list(
                    filter(lambda cr: not cr.spent,
                           (await
                            client.get_coin_records_by_puzzle_hash(ph))))) == 3
            assert len(await client.get_coin_records_by_puzzle_hashes(
                [ph_receiver, ph])) == 5
            assert len(await
                       client.get_coin_records_by_puzzle_hash(ph, False)) == 3
            assert len(await client.get_coin_records_by_puzzle_hash(ph,
                                                                    True)) == 4

            assert len(await client.get_coin_records_by_puzzle_hash(
                ph, True, 0, 100)) == 4
            assert len(await client.get_coin_records_by_puzzle_hash(
                ph, True, 50, 100)) == 0
            assert len(await client.get_coin_records_by_puzzle_hash(
                ph, True, 0, blocks[-1].height + 1)) == 2
            assert len(await
                       client.get_coin_records_by_puzzle_hash(ph, True, 0,
                                                              1)) == 0

            assert len(await client.get_connections()) == 0

            await client.open_connection(self_hostname, server_2._port)

            async def num_connections():
                return len(await client.get_connections())

            await time_out_assert(10, num_connections, 1)
            connections = await client.get_connections()
            assert NodeType(connections[0]["type"]) == NodeType.FULL_NODE.value
            assert len(await client.get_connections(NodeType.FULL_NODE)) == 1
            assert len(await client.get_connections(NodeType.FARMER)) == 0
            await client.close_connection(connections[0]["node_id"])
            await time_out_assert(10, num_connections, 0)

            blocks: List[FullBlock] = await client.get_blocks(0, 5)
            assert len(blocks) == 5

            await full_node_api_1.reorg_from_index_to_new_index(
                ReorgProtocol(2, 55, bytes([0x2] * 32)))
            new_blocks_0: List[FullBlock] = await client.get_blocks(0, 5)
            assert len(new_blocks_0) == 7

            new_blocks: List[FullBlock] = await client.get_blocks(
                0, 5, exclude_reorged=True)
            assert len(new_blocks) == 5
            assert blocks[0].header_hash == new_blocks[0].header_hash
            assert blocks[1].header_hash == new_blocks[1].header_hash
            assert blocks[2].header_hash == new_blocks[2].header_hash
            assert blocks[3].header_hash != new_blocks[3].header_hash

        finally:
            # Checks that the RPC manages to stop the node
            client.close()
            await client.await_closed()
            await rpc_cleanup()
Exemplo n.º 3
0
    async def test_basic_coin_store(self):
        wallet_a = WALLET_A
        reward_ph = wallet_a.get_new_puzzlehash()

        # Generate some coins
        blocks = bt.get_consecutive_blocks(
            10,
            [],
            farmer_reward_puzzle_hash=reward_ph,
            pool_reward_puzzle_hash=reward_ph,
        )

        coins_to_spend: List[Coin] = []
        for block in blocks:
            if block.is_block():
                for coin in block.get_included_reward_coins():
                    if coin.puzzle_hash == reward_ph:
                        coins_to_spend.append(coin)

        spend_bundle = wallet_a.generate_signed_transaction(1000, wallet_a.get_new_puzzlehash(), coins_to_spend[0])

        db_path = Path("fndb_test.db")
        if db_path.exists():
            db_path.unlink()
        connection = await aiosqlite.connect(db_path)
        coin_store = await CoinStore.create(connection)

        blocks = bt.get_consecutive_blocks(
            10,
            blocks,
            farmer_reward_puzzle_hash=reward_ph,
            pool_reward_puzzle_hash=reward_ph,
            transaction_data=spend_bundle,
        )

        # Adding blocks to the coin store
        should_be_included_prev: Set[Coin] = set()
        should_be_included: Set[Coin] = set()
        for block in blocks:
            farmer_coin, pool_coin = get_future_reward_coins(block)
            should_be_included.add(farmer_coin)
            should_be_included.add(pool_coin)
            if block.is_block():
                removals, additions = block.tx_removals_and_additions()

                assert block.get_included_reward_coins() == should_be_included_prev

                await coin_store.new_block(block)

                for expected_coin in should_be_included_prev:
                    # Check that the coinbase rewards are added
                    record = await coin_store.get_coin_record(expected_coin.name())
                    assert record is not None
                    assert not record.spent
                    assert record.coin == expected_coin
                for coin_name in removals:
                    # Check that the removed coins are set to spent
                    record = await coin_store.get_coin_record(coin_name)
                    assert record.spent
                for coin in additions:
                    # Check that the added coins are added
                    record = await coin_store.get_coin_record(coin.name())
                    assert not record.spent
                    assert coin == record.coin

                should_be_included_prev = should_be_included.copy()
                should_be_included = set()

        await connection.close()
        Path("fndb_test.db").unlink()
Exemplo n.º 4
0
    async def test_assert_my_coin_id(self, two_nodes):
        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        # Farm blocks
        blocks = bt.get_consecutive_blocks(
            num_blocks, farmer_reward_puzzle_hash=coinbase_puzzlehash, guarantee_transaction_block=True
        )
        full_node_api_1, full_node_api_2, server_1, server_2 = two_nodes
        full_node_1 = full_node_api_1.full_node

        for block in blocks:
            await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))

        # Coinbase that gets spent

        spend_block = blocks[2]
        bad_block = blocks[3]
        spend_coin = None
        bad_spend_coin = None
        for coin in list(spend_block.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                spend_coin = coin
        for coin in list(bad_block.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                bad_spend_coin = coin
        valid_cvp = ConditionVarPair(ConditionOpcode.ASSERT_MY_COIN_ID, [spend_coin.name()])
        valid_dic = {valid_cvp.opcode: [valid_cvp]}
        bad_cvp = ConditionVarPair(ConditionOpcode.ASSERT_MY_COIN_ID, [bad_spend_coin.name()])

        bad_dic = {bad_cvp.opcode: [bad_cvp]}
        bad_spend_bundle = wallet_a.generate_signed_transaction(1000, receiver_puzzlehash, spend_coin, bad_dic)

        valid_spend_bundle = wallet_a.generate_signed_transaction(1000, receiver_puzzlehash, spend_coin, valid_dic)

        assert bad_spend_bundle is not None
        assert valid_spend_bundle is not None

        # Invalid block bundle
        # Create another block that includes our transaction
        invalid_new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=bad_spend_bundle,
            guarantee_transaction_block=True,
        )

        # Try to validate that block
        res, err, _ = await full_node_1.blockchain.receive_block(invalid_new_blocks[-1])
        assert res == ReceiveBlockResult.INVALID_BLOCK
        assert err == Err.ASSERT_MY_COIN_ID_FAILED

        # Valid block bundle
        # Create another block that includes our transaction
        new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=valid_spend_bundle,
            guarantee_transaction_block=True,
        )
        res, err, _ = await full_node_1.blockchain.receive_block(new_blocks[-1])
        assert res == ReceiveBlockResult.NEW_PEAK
        assert err is None
Exemplo n.º 5
0
    async def test_assert_block_age_exceeds(self, two_nodes):
        num_blocks = 11
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        # Farm blocks
        blocks = bt.get_consecutive_blocks(
            num_blocks, farmer_reward_puzzle_hash=coinbase_puzzlehash, guarantee_transaction_block=True
        )
        full_node_api_1, full_node_api_2, server_1, server_2 = two_nodes
        full_node_1 = full_node_api_1.full_node

        for block in blocks:
            await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))

        # Coinbase that gets spent
        block1 = blocks[2]
        spend_coin_block_1 = None
        for coin in list(block1.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                spend_coin_block_1 = coin

        # This condition requires block1 coinbase to be spent after index 11
        # This condition requires block1 coinbase to be spent more than 10 block after it was farmed
        # block index has to be greater than (2 + 9 = 11)
        block1_cvp = ConditionVarPair(ConditionOpcode.ASSERT_HEIGHT_AGE_EXCEEDS, [int_to_bytes(9)])
        block1_dic = {block1_cvp.opcode: [block1_cvp]}
        block1_spend_bundle = wallet_a.generate_signed_transaction(
            1000, receiver_puzzlehash, spend_coin_block_1, block1_dic
        )

        # program that will be sent too early
        assert block1_spend_bundle is not None
        invalid_new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=block1_spend_bundle,
            guarantee_transaction_block=True,
        )

        # Try to validate that block at index 11
        res, err, _ = await full_node_1.blockchain.receive_block(invalid_new_blocks[-1])
        assert res == ReceiveBlockResult.INVALID_BLOCK
        assert err == Err.ASSERT_HEIGHT_AGE_EXCEEDS_FAILED

        new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True,
        )
        res, _, _ = await full_node_1.blockchain.receive_block(new_blocks[-1])
        assert res == ReceiveBlockResult.NEW_PEAK

        # At index 12, it can be spent
        new_blocks = bt.get_consecutive_blocks(
            1,
            new_blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=block1_spend_bundle,
            guarantee_transaction_block=True,
        )
        res, err, _ = await full_node_1.blockchain.receive_block(new_blocks[-1])
        assert err is None
        assert res == ReceiveBlockResult.NEW_PEAK
Exemplo n.º 6
0
    async def test_basic_reorg(self):
        initial_block_count = 30
        reorg_length = 15
        blocks = bt.get_consecutive_blocks(initial_block_count)
        db_path = Path("blockchain_test.db")
        if db_path.exists():
            db_path.unlink()
        connection = await aiosqlite.connect(db_path)
        coin_store = await CoinStore.create(connection)
        store = await BlockStore.create(connection)
        b: Blockchain = await Blockchain.create(coin_store, store,
                                                test_constants)
        try:

            for block in blocks:
                await b.receive_block(block)
            assert b.get_peak().height == initial_block_count - 1

            for c, block in enumerate(blocks):
                if block.is_transaction_block():
                    coins = block.get_included_reward_coins()
                    records: List[Optional[CoinRecord]] = [
                        await coin_store.get_coin_record(coin.name())
                        for coin in coins
                    ]
                    for record in records:
                        assert not record.spent
                        assert record.confirmed_block_index == block.height
                        assert record.spent_block_index == 0

            blocks_reorg_chain = bt.get_consecutive_blocks(
                reorg_length, blocks[:initial_block_count - 10], seed=b"2")

            for reorg_block in blocks_reorg_chain:
                result, error_code, _ = await b.receive_block(reorg_block)
                print(
                    f"Height {reorg_block.height} {initial_block_count - 10} result {result}"
                )
                if reorg_block.height < initial_block_count - 10:
                    assert result == ReceiveBlockResult.ALREADY_HAVE_BLOCK
                elif reorg_block.height < initial_block_count - 1:
                    assert result == ReceiveBlockResult.ADDED_AS_ORPHAN
                elif reorg_block.height >= initial_block_count:
                    assert result == ReceiveBlockResult.NEW_PEAK
                    if reorg_block.is_transaction_block():
                        coins = reorg_block.get_included_reward_coins()
                        records: List[Optional[CoinRecord]] = [
                            await coin_store.get_coin_record(coin.name())
                            for coin in coins
                        ]
                        for record in records:
                            assert not record.spent
                            assert record.confirmed_block_index == reorg_block.height
                            assert record.spent_block_index == 0
                assert error_code is None
            assert b.get_peak(
            ).height == initial_block_count - 10 + reorg_length - 1
        except Exception as e:
            await connection.close()
            Path("blockchain_test.db").unlink()
            b.shut_down()
            raise e

        await connection.close()
        Path("blockchain_test.db").unlink()
        b.shut_down()
Exemplo n.º 7
0
    async def test_validate_blockchain_with_reorg_double_spend(self, two_nodes):
        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        blocks = bt.get_consecutive_blocks(
            num_blocks, farmer_reward_puzzle_hash=coinbase_puzzlehash, guarantee_transaction_block=True
        )
        full_node_api_1, full_node_api_2, server_1, server_2 = two_nodes

        for block in blocks:
            await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))

        spend_block = blocks[2]

        spend_coin = None
        for coin in list(spend_block.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                spend_coin = coin

        spend_bundle = wallet_a.generate_signed_transaction(1000, receiver_puzzlehash, spend_coin)

        blocks_spend = bt.get_consecutive_blocks(
            1,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True,
            transaction_data=spend_bundle,
        )
        # Move chain to height 10, with a spend at height 10
        for block in blocks_spend:
            await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))

        # Reorg at height 5, add up to and including height 12
        new_blocks = bt.get_consecutive_blocks(
            7,
            blocks[:6],
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True,
            seed=b"another seed",
        )

        for block in new_blocks:
            await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))

        # Spend the same coin in the new reorg chain at height 13
        new_blocks = bt.get_consecutive_blocks(
            1,
            new_blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True,
            transaction_data=spend_bundle,
        )

        res, err, _ = await full_node_api_1.full_node.blockchain.receive_block(new_blocks[-1])
        assert err is None
        assert res == ReceiveBlockResult.NEW_PEAK

        # But can't spend it twice
        new_blocks_double = bt.get_consecutive_blocks(
            1,
            new_blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True,
            transaction_data=spend_bundle,
        )

        res, err, _ = await full_node_api_1.full_node.blockchain.receive_block(new_blocks_double[-1])
        assert err is Err.DOUBLE_SPEND
        assert res == ReceiveBlockResult.INVALID_BLOCK

        # Now test Reorg at block 5, same spend at block height 12
        new_blocks_reorg = bt.get_consecutive_blocks(
            1,
            new_blocks[:12],
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True,
            transaction_data=spend_bundle,
            seed=b"spend at 12 is ok",
        )
        for block in new_blocks_reorg:
            await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))

        # Spend at height 13 is also OK (same height)
        new_blocks_reorg = bt.get_consecutive_blocks(
            1,
            new_blocks[:13],
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True,
            transaction_data=spend_bundle,
            seed=b"spend at 13 is ok",
        )
        for block in new_blocks_reorg:
            await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))

        # Spend at height 14 is not OK (already spend)
        new_blocks_reorg = bt.get_consecutive_blocks(
            1,
            new_blocks[:14],
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True,
            transaction_data=spend_bundle,
            seed=b"spend at 14 is double spend",
        )
        with pytest.raises(ConsensusError):
            for block in new_blocks_reorg:
                await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))
Exemplo n.º 8
0
    async def test_weight_proof_edge_cases(self, default_400_blocks):
        blocks: List[FullBlock] = default_400_blocks

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
            skip_slots=2)

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
            skip_slots=1)

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
            skip_slots=2)

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
            skip_slots=4,
            normalized_to_identity_cc_eos=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            10,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
            skip_slots=4,
            normalized_to_identity_icc_eos=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            10,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
            skip_slots=4,
            normalized_to_identity_cc_ip=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            10,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
            skip_slots=4,
            normalized_to_identity_cc_sp=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
            skip_slots=4)

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            10,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=True,
        )

        blocks: List[FullBlock] = bt.get_consecutive_blocks(
            300,
            block_list_input=blocks,
            seed=b"asdfghjkl",
            force_overflow=False,
        )

        header_cache, height_to_hash, sub_blocks, summaries = await load_blocks_dont_validate(
            blocks)
        wpf = WeightProofHandler(
            test_constants,
            BlockCache(sub_blocks, header_cache, height_to_hash, summaries))
        wp = await wpf.get_proof_of_weight(blocks[-1].header_hash)
        assert wp is not None
        wpf = WeightProofHandler(
            test_constants,
            BlockCache(sub_blocks, header_cache, height_to_hash, {}))
        valid, fork_point = wpf.validate_weight_proof_single_proc(wp)

        assert valid
        assert fork_point == 0
Exemplo n.º 9
0
    async def test_block_store(self):
        assert sqlite3.threadsafety == 1
        blocks = bt.get_consecutive_blocks(test_constants, 9, [], 9, b"0")
        blocks_alt = bt.get_consecutive_blocks(test_constants, 3, [], 9, b"1")
        db_filename = Path("blockchain_test.db")
        db_filename_2 = Path("blockchain_test_2.db")
        db_filename_3 = Path("blockchain_test_3.db")

        if db_filename.exists():
            db_filename.unlink()
        if db_filename_2.exists():
            db_filename_2.unlink()
        if db_filename_3.exists():
            db_filename_3.unlink()

        connection = await aiosqlite.connect(db_filename)
        connection_2 = await aiosqlite.connect(db_filename_2)
        connection_3 = await aiosqlite.connect(db_filename_3)

        db = await BlockStore.create(connection)
        # db_2 = await BlockStore.create(connection_2)
        await BlockStore.create(connection_2)
        db_3 = await BlockStore.create(connection_3)
        try:
            genesis = FullBlock.from_bytes(test_constants["GENESIS_BLOCK"])

            # Save/get block
            for block in blocks:
                await db.add_block(block)
                assert block == await db.get_block(block.header_hash)

            await db.add_block(blocks_alt[2])
            assert len(await db.get_blocks_at([1, 2])) == 3

            # Get headers (added alt block also, so +1)
            assert len(await db.get_headers()) == len(blocks) + 1

            # Test LCA
            assert (await db.get_lca()) is None
            await db.set_lca(blocks[-3].header_hash)
            assert (await db.get_lca()) == blocks[-3].header
            await db.set_tips([blocks[-2].header_hash, blocks[-1].header_hash])
            assert (await db.get_tips()) == [blocks[-2].header, blocks[-1].header]

            coin_store: CoinStore = await CoinStore.create(connection_3)
            b: Blockchain = await Blockchain.create(coin_store, db_3, test_constants)

            assert b.lca_block == genesis.header
            assert b.tips == [genesis.header]
            assert await db_3.get_lca() == genesis.header
            assert await db_3.get_tips() == [genesis.header]

            for block in blocks:
                await b.receive_block(block)

            assert b.lca_block == blocks[-3].header
            assert set(b.tips) == set(
                [blocks[-3].header, blocks[-2].header, blocks[-1].header]
            )
            left = sorted(b.tips, key=lambda t: t.height)
            right = sorted((await db_3.get_tips()), key=lambda t: t.height)
            assert left == right

        except Exception:
            await connection.close()
            await connection_2.close()
            await connection_3.close()
            db_filename.unlink()
            db_filename_2.unlink()
            db_filename_3.unlink()
            b.shut_down()
            raise

        await connection.close()
        await connection_2.close()
        await connection_3.close()
        db_filename.unlink()
        db_filename_2.unlink()
        db_filename_3.unlink()
        b.shut_down()
    async def test1(self, two_nodes):
        num_blocks = 5
        test_rpc_port = uint16(21522)
        full_node_api_1, full_node_api_2, server_1, server_2 = two_nodes

        def stop_node_cb():
            full_node_api_1._close()
            server_1.close_all()

        full_node_rpc_api = FullNodeRpcApi(full_node_api_1.full_node)

        config = bt.config
        hostname = config["self_hostname"]
        daemon_port = config["daemon_port"]

        rpc_cleanup = await start_rpc_server(
            full_node_rpc_api,
            hostname,
            daemon_port,
            test_rpc_port,
            stop_node_cb,
            bt.root_path,
            config,
            connect_to_daemon=False,
        )

        try:
            client = await FullNodeRpcClient.create(self_hostname,
                                                    test_rpc_port,
                                                    bt.root_path, config)
            state = await client.get_blockchain_state()
            assert state["peak"] is None
            assert not state["sync"]["sync_mode"]
            assert state["difficulty"] > 0
            assert state["sub_slot_iters"] > 0

            blocks = bt.get_consecutive_blocks(num_blocks)
            blocks = bt.get_consecutive_blocks(1,
                                               block_list_input=blocks,
                                               guarantee_block=True)

            assert len(await client.get_unfinished_sub_block_headers()) == 0
            assert len((await client.get_sub_block_records(0, 100))) == 0
            for block in blocks:
                if is_overflow_sub_block(
                        test_constants,
                        block.reward_chain_sub_block.signage_point_index):
                    finished_ss = block.finished_sub_slots[:-1]
                else:
                    finished_ss = block.finished_sub_slots

                unf = UnfinishedBlock(
                    finished_ss,
                    block.reward_chain_sub_block.get_unfinished(),
                    block.challenge_chain_sp_proof,
                    block.reward_chain_sp_proof,
                    block.foliage_sub_block,
                    block.foliage_block,
                    block.transactions_info,
                    block.transactions_generator,
                )
                await full_node_api_1.full_node.respond_unfinished_sub_block(
                    full_node_protocol.RespondUnfinishedSubBlock(unf), None)
                await full_node_api_1.full_node.respond_sub_block(
                    full_node_protocol.RespondSubBlock(block), None)

            assert len(await client.get_unfinished_sub_block_headers()) > 0
            assert len(await client.get_all_block(0, 2)) == 2
            state = await client.get_blockchain_state()

            block = await client.get_sub_block(state["peak"].header_hash)
            assert block == blocks[-1]
            assert (await client.get_sub_block(bytes([1] * 32))) is None

            assert (await client.get_sub_block_record_by_height(2)
                    ).header_hash == blocks[2].header_hash

            assert len(
                (await client.get_sub_block_records(0, 100))) == num_blocks + 1

            assert (await client.get_sub_block_record_by_height(100)) is None

            ph = list(blocks[-1].get_included_reward_coins())[0].puzzle_hash
            coins = await client.get_unspent_coins(ph)
            assert len(coins) >= 1

            additions, removals = await client.get_additions_and_removals(
                blocks[-1].header_hash)
            assert len(additions) >= 2 and len(removals) == 0

            assert len(await client.get_connections()) == 0

            await client.open_connection(self_hostname, server_2._port)

            async def num_connections():
                return len(await client.get_connections())

            await time_out_assert(10, num_connections, 1)
            connections = await client.get_connections()

            await client.close_connection(connections[0]["node_id"])
            await time_out_assert(10, num_connections, 0)
        finally:
            # Checks that the RPC manages to stop the node
            client.close()
            await client.await_closed()
            await rpc_cleanup()
Exemplo n.º 11
0
    async def test_basic_coin_store(self):
        wallet_a = WALLET_A
        reward_ph = wallet_a.get_new_puzzlehash()

        for cache_size in [0]:
            # Generate some coins
            blocks = bt.get_consecutive_blocks(
                10,
                [],
                farmer_reward_puzzle_hash=reward_ph,
                pool_reward_puzzle_hash=reward_ph,
            )

            coins_to_spend: List[Coin] = []
            for block in blocks:
                if block.is_transaction_block():
                    for coin in block.get_included_reward_coins():
                        if coin.puzzle_hash == reward_ph:
                            coins_to_spend.append(coin)

            spend_bundle = wallet_a.generate_signed_transaction(
                1000, wallet_a.get_new_puzzlehash(), coins_to_spend[0])

            db_path = Path("fndb_test.db")
            if db_path.exists():
                db_path.unlink()
            connection = await aiosqlite.connect(db_path)
            db_wrapper = DBWrapper(connection)
            coin_store = await CoinStore.create(db_wrapper,
                                                cache_size=uint32(cache_size))

            blocks = bt.get_consecutive_blocks(
                10,
                blocks,
                farmer_reward_puzzle_hash=reward_ph,
                pool_reward_puzzle_hash=reward_ph,
                transaction_data=spend_bundle,
            )

            # Adding blocks to the coin store
            should_be_included_prev: Set[Coin] = set()
            should_be_included: Set[Coin] = set()
            for block in blocks:
                farmer_coin, pool_coin = get_future_reward_coins(block)
                should_be_included.add(farmer_coin)
                should_be_included.add(pool_coin)
                if block.is_transaction_block():
                    if block.transactions_generator is not None:
                        block_gen: BlockGenerator = BlockGenerator(
                            block.transactions_generator, [])
                        npc_result = get_name_puzzle_conditions(
                            block_gen, bt.constants.MAX_BLOCK_COST_CLVM, False)
                        tx_removals, tx_additions = tx_removals_and_additions(
                            npc_result.npc_list)
                    else:
                        tx_removals, tx_additions = [], []

                    assert block.get_included_reward_coins(
                    ) == should_be_included_prev

                    await coin_store.new_block(block, tx_additions,
                                               tx_removals)

                    if block.height != 0:
                        with pytest.raises(Exception):
                            await coin_store.new_block(block, tx_additions,
                                                       tx_removals)

                    for expected_coin in should_be_included_prev:
                        # Check that the coinbase rewards are added
                        record = await coin_store.get_coin_record(
                            expected_coin.name())
                        assert record is not None
                        assert not record.spent
                        assert record.coin == expected_coin
                    for coin_name in tx_removals:
                        # Check that the removed coins are set to spent
                        record = await coin_store.get_coin_record(coin_name)
                        assert record.spent
                    for coin in tx_additions:
                        # Check that the added coins are added
                        record = await coin_store.get_coin_record(coin.name())
                        assert not record.spent
                        assert coin == record.coin

                    should_be_included_prev = should_be_included.copy()
                    should_be_included = set()

            await connection.close()
            Path("fndb_test.db").unlink()
Exemplo n.º 12
0
    async def test_block_store(self):
        assert sqlite3.threadsafety == 1
        blocks = bt.get_consecutive_blocks(10)

        db_filename = Path("blockchain_test.db")
        db_filename_2 = Path("blockchain_test2.db")

        if db_filename.exists():
            db_filename.unlink()
        if db_filename_2.exists():
            db_filename_2.unlink()

        connection = await aiosqlite.connect(db_filename)
        connection_2 = await aiosqlite.connect(db_filename_2)
        db_wrapper = DBWrapper(connection)
        db_wrapper_2 = DBWrapper(connection_2)

        # Use a different file for the blockchain
        coin_store_2 = await CoinStore.create(db_wrapper_2)
        store_2 = await BlockStore.create(db_wrapper_2)
        bc = await Blockchain.create(coin_store_2, store_2, test_constants)

        store = await BlockStore.create(db_wrapper)
        await BlockStore.create(db_wrapper_2)
        try:
            # Save/get block
            for block in blocks:
                await bc.receive_block(block)
                block_record = bc.block_record(block.header_hash)
                block_record_hh = block_record.header_hash
                await store.add_full_block(block.header_hash, block,
                                           block_record)
                await store.add_full_block(block.header_hash, block,
                                           block_record)
                assert block == await store.get_full_block(block.header_hash)
                assert block == await store.get_full_block(block.header_hash)
                assert block_record == (
                    await store.get_block_record(block_record_hh))
                await store.set_peak(block_record.header_hash)
                await store.set_peak(block_record.header_hash)

            assert len(await store.get_full_blocks_at([1])) == 1
            assert len(await store.get_full_blocks_at([0])) == 1
            assert len(await store.get_full_blocks_at([100])) == 0

            # Get blocks
            block_record_records = await store.get_block_records_in_range(
                0, 0xFFFFFFFF)
            assert len(block_record_records) == len(blocks)

        except Exception:
            await connection.close()
            await connection_2.close()
            db_filename.unlink()
            db_filename_2.unlink()
            raise

        await connection.close()
        await connection_2.close()
        db_filename.unlink()
        db_filename_2.unlink()
Exemplo n.º 13
0
    async def test_stealing_fee(self, two_nodes):
        receiver_puzzlehash = BURN_PUZZLE_HASH
        num_blocks = 2
        wallet_receiver = bt.get_farmer_wallet_tool()

        blocks = bt.get_consecutive_blocks(test_constants, num_blocks, [], 10, b"")

        blocks = bt.get_consecutive_blocks(test_constants, num_blocks, blocks, 10, b"")

        full_node_1, full_node_2, server_1, server_2 = two_nodes

        block = blocks[1]
        wallet_2_block = blocks[3]

        for b in blocks:
            async for _ in full_node_1.respond_block(
                full_node_protocol.RespondBlock(b)
            ):
                pass

        cvp = ConditionVarPair(
            ConditionOpcode.ASSERT_FEE,
            int_to_bytes(10),
            None,
        )
        dic = {cvp.opcode: [cvp]}

        fee = 9
        spend_bundle1 = generate_test_spend_bundle(block.get_coinbase(), dic, fee)

        wallet_2_fees = wallet_2_block.get_fees_coin()
        steal_fee_spendbundle = wallet_receiver.generate_signed_transaction(
            wallet_2_fees.amount + fee - 4, receiver_puzzlehash, wallet_2_fees
        )

        assert spend_bundle1 is not None
        assert steal_fee_spendbundle is not None

        combined = SpendBundle.aggregate([spend_bundle1, steal_fee_spendbundle])

        assert combined.fees() == 4

        tx1: full_node_protocol.RespondTransaction = (
            full_node_protocol.RespondTransaction(spend_bundle1)
        )

        outbound_messages: List[OutboundMessage] = []
        async for outbound in full_node_1.respond_transaction(tx1):
            outbound_messages.append(outbound)

        new_transaction = False
        for msg in outbound_messages:
            if msg.message.function == "new_transaction":
                new_transaction = True

        assert new_transaction is False

        mempool_bundle = full_node_1.mempool_manager.get_spendbundle(
            spend_bundle1.name()
        )

        assert mempool_bundle is None
    async def test_invalid_filter(self, two_nodes):
        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        blocks = bt.get_consecutive_blocks(test_constants, num_blocks, [], 10,
                                           b"", coinbase_puzzlehash)
        full_node_1, full_node_2, server_1, server_2 = two_nodes

        for block in blocks:
            async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(block)):
                pass

        spent_block = blocks[1]

        spend_bundle = wallet_a.generate_signed_transaction(
            1000, receiver_puzzlehash, spent_block.get_coinbase())

        assert spend_bundle is not None
        tx: full_node_protocol.RespondTransaction = (
            full_node_protocol.RespondTransaction(spend_bundle))
        async for _ in full_node_1.respond_transaction(tx):
            outbound: OutboundMessage = _
            # Maybe transaction means that it's accepted in mempool
            assert outbound.message.function == "new_transaction"

        sb = full_node_1.mempool_manager.get_spendbundle(spend_bundle.name())
        assert sb is spend_bundle

        last_block = blocks[10]
        next_spendbundle = await full_node_1.mempool_manager.create_bundle_for_tip(
            last_block.header)
        assert next_spendbundle is not None

        program = best_solution_program(next_spendbundle)
        aggsig = next_spendbundle.aggregated_signature

        dic_h = {11: (program, aggsig)}
        new_blocks = bt.get_consecutive_blocks(test_constants, 1, blocks, 10,
                                               b"", coinbase_puzzlehash, dic_h)

        next_block = new_blocks[11]

        bad_header = HeaderData(
            next_block.header.data.height,
            next_block.header.data.prev_header_hash,
            next_block.header.data.timestamp,
            bytes32(bytes([3] * 32)),
            next_block.header.data.proof_of_space_hash,
            next_block.header.data.weight,
            next_block.header.data.total_iters,
            next_block.header.data.additions_root,
            next_block.header.data.removals_root,
            next_block.header.data.farmer_rewards_puzzle_hash,
            next_block.header.data.total_transaction_fees,
            next_block.header.data.pool_target,
            next_block.header.data.aggregated_signature,
            next_block.header.data.cost,
            next_block.header.data.extension_data,
            next_block.header.data.generator_hash,
        )
        bad_block = FullBlock(
            next_block.proof_of_space,
            next_block.proof_of_time,
            Header(
                bad_header,
                bt.get_plot_signature(
                    bad_header, next_block.proof_of_space.plot_public_key),
            ),
            next_block.transactions_generator,
            next_block.transactions_filter,
        )
        result, removed, error_code = await full_node_1.blockchain.receive_block(
            bad_block)
        assert result == ReceiveBlockResult.INVALID_BLOCK
        assert error_code == Err.INVALID_TRANSACTIONS_FILTER_HASH

        result, removed, error_code = await full_node_1.blockchain.receive_block(
            next_block)
        assert result == ReceiveBlockResult.ADDED_TO_HEAD
Exemplo n.º 15
0
    async def test_short_sync_with_transactions_wallet(self, wallet_node):
        BURN_PUZZLE_HASH_1 = b"0" * 32
        BURN_PUZZLE_HASH_2 = b"1" * 32
        full_node_1, wallet_node, server_1, server_2 = wallet_node
        wallet_a = wallet_node.wallet_state_manager.main_wallet
        coinbase_puzzlehash = await wallet_a.get_new_puzzlehash()
        coinbase_puzzlehash_rest = BURN_PUZZLE_HASH_1
        puzzle_hashes = [
            await wallet_a.get_new_puzzlehash() for _ in range(10)
        ]
        puzzle_hashes.append(BURN_PUZZLE_HASH_2)

        blocks = bt.get_consecutive_blocks(test_constants, 3, [], 10, b"",
                                           coinbase_puzzlehash)
        for block in blocks:
            [
                _ async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(block))
            ]
        await server_2.start_client(
            PeerInfo("localhost", uint16(server_1._port)), None)
        await time_out_assert(60, wallet_height_at_least, True, wallet_node, 1)

        server_2.global_connections.close_all_connections()

        dic_h = {}
        prev_coin = blocks[1].get_coinbase()
        for i in range(11):
            pk, sk = await wallet_a.wallet_state_manager.get_keys(
                prev_coin.puzzle_hash)
            transaction_unsigned = await wallet_a.generate_unsigned_transaction(
                1000, puzzle_hashes[i], coins=[prev_coin])
            spend_bundle = await wallet_a.sign_transaction(transaction_unsigned
                                                           )
            block_spendbundle = SpendBundle.aggregate([spend_bundle])
            program = best_solution_program(block_spendbundle)
            aggsig = block_spendbundle.aggregated_signature
            prev_coin = Coin(prev_coin.name(), puzzle_hashes[i], uint64(1000))
            dic_h[i + 4] = (program, aggsig)

        blocks = bt.get_consecutive_blocks(test_constants, 13, blocks, 10, b"",
                                           coinbase_puzzlehash_rest, dic_h)
        # Move chain to height 16, with consecutive transactions in blocks 4 to 14
        for block in blocks:
            async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(block)):
                pass

        # Do a short sync from 0 to 14
        await server_2.start_client(
            PeerInfo("localhost", uint16(server_1._port)), None)
        await time_out_assert(60, wallet_height_at_least, True, wallet_node,
                              14)

        server_2.global_connections.close_all_connections()

        # 3 block rewards and 3 fees - 1000 coins spent
        assert (await wallet_a.get_confirmed_balance() ==
                (blocks[1].get_coinbase().amount * 3) +
                (blocks[1].get_fees_coin().amount * 3) - 1000)
        # All of our coins are spent and puzzle hashes present
        for puzzle_hash in puzzle_hashes[:-1]:
            records = await wallet_node.wallet_state_manager.wallet_store.get_coin_records_by_puzzle_hash(
                puzzle_hash)
            assert len(records) == 1
            assert records[0].spent and not records[0].coinbase

        # Then do the same but in a reorg chain
        dic_h = {}
        prev_coin = blocks[1].get_coinbase()
        for i in range(11):
            pk, sk = await wallet_a.wallet_state_manager.get_keys(
                prev_coin.puzzle_hash)
            transaction_unsigned = await wallet_a.generate_unsigned_transaction(
                1000,
                puzzle_hashes[i],
                coins=[prev_coin],
            )
            spend_bundle = await wallet_a.sign_transaction(transaction_unsigned
                                                           )
            block_spendbundle = SpendBundle.aggregate([spend_bundle])
            program = best_solution_program(block_spendbundle)
            aggsig = block_spendbundle.aggregated_signature
            prev_coin = Coin(prev_coin.name(), puzzle_hashes[i], uint64(1000))
            dic_h[i + 4] = (program, aggsig)

        blocks = bt.get_consecutive_blocks(
            test_constants,
            31,
            blocks[:4],
            10,
            b"this is a reorg",
            coinbase_puzzlehash_rest,
            dic_h,
        )

        # Move chain to height 34, with consecutive transactions in blocks 4 to 14
        for block in blocks:
            async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(block)):
                pass

        # Do a sync from 0 to 22
        await server_2.start_client(
            PeerInfo("localhost", uint16(server_1._port)), None)

        await time_out_assert(60, wallet_height_at_least, True, wallet_node,
                              28)
        server_2.global_connections.close_all_connections()

        # 3 block rewards and 3 fees - 1000 coins spent
        assert (await wallet_a.get_confirmed_balance() ==
                (blocks[1].get_coinbase().amount * 3) +
                (blocks[1].get_fees_coin().amount * 3) - 1000)
        # All of our coins are spent and puzzle hashes present
        for puzzle_hash in puzzle_hashes[:-1]:
            records = await wallet_node.wallet_state_manager.wallet_store.get_coin_records_by_puzzle_hash(
                puzzle_hash)
            assert len(records) == 1
            assert records[0].spent and not records[0].coinbase

        # Test spending the rewards earned in reorg
        new_coinbase_puzzlehash = await wallet_a.get_new_puzzlehash()
        another_puzzlehash = await wallet_a.get_new_puzzlehash()

        dic_h = {}
        pk, sk = await wallet_a.wallet_state_manager.get_keys(
            new_coinbase_puzzlehash)
        coinbase_coin = create_coinbase_coin(uint32(25),
                                             new_coinbase_puzzlehash,
                                             uint64(14000000000000))
        transaction_unsigned = await wallet_a.generate_unsigned_transaction(
            7000000000000,
            another_puzzlehash,
            coins=[coinbase_coin],
        )
        spend_bundle = await wallet_a.sign_transaction(transaction_unsigned)
        block_spendbundle = SpendBundle.aggregate([spend_bundle])
        program = best_solution_program(block_spendbundle)
        aggsig = block_spendbundle.aggregated_signature
        dic_h[26] = (program, aggsig)

        # Farm a block (25) to ourselves
        blocks = bt.get_consecutive_blocks(
            test_constants,
            1,
            blocks[:25],
            10,
            b"this is yet another reorg",
            new_coinbase_puzzlehash,
        )

        # Brings height up to 40, with block 31 having half our reward spent to us
        blocks = bt.get_consecutive_blocks(
            test_constants,
            15,
            blocks,
            10,
            b"this is yet another reorg more blocks",
            coinbase_puzzlehash_rest,
            dic_h,
        )
        for block in blocks:
            async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(block)):
                pass

        await server_2.start_client(
            PeerInfo("localhost", uint16(server_1._port)), None)
        await time_out_assert(60, wallet_height_at_least, True, wallet_node,
                              38)

        # 4 block rewards and 4 fees - 1000 coins spent
        assert (await wallet_a.get_confirmed_balance() ==
                (blocks[1].get_coinbase().amount * 4) +
                (blocks[1].get_fees_coin().amount * 4) - 1000)
        records = await wallet_node.wallet_state_manager.wallet_store.get_coin_records_by_puzzle_hash(
            new_coinbase_puzzlehash)
        # Fee and coinbase
        assert len(records) == 2
        print(records)
        assert records[0].spent != records[1].spent
        assert records[0].coinbase == records[1].coinbase
        records = await wallet_node.wallet_state_manager.wallet_store.get_coin_records_by_puzzle_hash(
            another_puzzlehash)
        assert len(records) == 1
        assert not records[0].spent
        assert not records[0].coinbase
    async def test_basic_blockchain_tx(self, two_nodes):
        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        blocks = bt.get_consecutive_blocks(
            num_blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True)
        full_node_api_1, full_node_api_2, server_1, server_2 = two_nodes
        peer = await connect_and_get_peer(server_1, server_2)
        full_node_1 = full_node_api_1.full_node

        for block in blocks:
            await full_node_api_1.full_node.respond_block(
                full_node_protocol.RespondBlock(block), None)

        spend_block = blocks[2]
        spend_coin = None
        for coin in list(spend_block.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                spend_coin = coin

        spend_bundle = wallet_a.generate_signed_transaction(
            1000, receiver_puzzlehash, spend_coin)

        assert spend_bundle is not None
        tx: full_node_protocol.RespondTransaction = full_node_protocol.RespondTransaction(
            spend_bundle)
        await full_node_api_1.respond_transaction(tx, peer)

        sb = full_node_1.mempool_manager.get_spendbundle(spend_bundle.name())
        assert sb is spend_bundle

        last_block = blocks[-1]
        next_spendbundle, additions, removals = await full_node_1.mempool_manager.create_bundle_from_mempool(
            last_block.header_hash)
        assert next_spendbundle is not None

        new_blocks = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=next_spendbundle,
            guarantee_transaction_block=True,
        )

        next_block = new_blocks[-1]
        await full_node_1.respond_block(
            full_node_protocol.RespondBlock(next_block))

        assert next_block.header_hash == full_node_1.blockchain.get_peak(
        ).header_hash

        added_coins = next_spendbundle.additions()

        # Two coins are added, main spend and change
        assert len(added_coins) == 2
        for coin in added_coins:
            unspent = await full_node_1.coin_store.get_coin_record(coin.name())
            assert unspent is not None
            assert not unspent.spent
            assert not unspent.coinbase
Exemplo n.º 17
0
    async def test1(self, two_nodes):
        num_blocks = 5
        test_rpc_port = uint16(21522)
        full_node_1, full_node_2, server_1, server_2 = two_nodes
        blocks = bt.get_consecutive_blocks(test_constants, num_blocks, [], 10)

        for i in range(1, num_blocks):
            async for _ in full_node_1.respond_unfinished_block(
                    full_node_protocol.RespondUnfinishedBlock(blocks[i])):
                pass
            async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(blocks[i])):
                pass

        def stop_node_cb():
            full_node_1._close()
            server_1.close_all()

        full_node_rpc_api = FullNodeRpcApi(full_node_1)

        config = load_config(bt.root_path, "config.yaml")
        hostname = config["self_hostname"]
        daemon_port = config["daemon_port"]

        rpc_cleanup = await start_rpc_server(
            full_node_rpc_api,
            hostname,
            daemon_port,
            test_rpc_port,
            stop_node_cb,
            connect_to_daemon=False,
        )

        try:
            client = await FullNodeRpcClient.create("localhost", test_rpc_port)
            state = await client.get_blockchain_state()
            assert state["lca"].header_hash is not None
            assert not state["sync"]["sync_mode"]
            assert len(state["tips"]) > 0
            assert state["difficulty"] > 0
            assert state["ips"] > 0
            assert state["min_iters"] > 0

            block = await client.get_block(state["lca"].header_hash)
            assert block == blocks[2]
            assert (await client.get_block(bytes([1] * 32))) is None

            unf_block_headers = await client.get_unfinished_block_headers(4)
            assert len(unf_block_headers) == 1
            assert unf_block_headers[0] == blocks[4].header

            header = await client.get_header(state["lca"].header_hash)
            assert header == blocks[2].header

            assert (await client.get_header_by_height(2)) == blocks[2].header

            assert (await client.get_header_by_height(100)) is None

            coins = await client.get_unspent_coins(
                blocks[-1].get_coinbase().puzzle_hash, blocks[-1].header_hash)
            assert len(coins) == 3
            coins_lca = await client.get_unspent_coins(
                blocks[-1].get_coinbase().puzzle_hash)
            assert len(coins_lca) == 3

            assert len(await client.get_connections()) == 0

            await client.open_connection("localhost", server_2._port)

            async def num_connections():
                return len(await client.get_connections())

            await time_out_assert(10, num_connections, 1)
            connections = await client.get_connections()

            await client.close_connection(connections[0]["node_id"])
            await time_out_assert(10, num_connections, 0)
        except AssertionError:
            # Checks that the RPC manages to stop the node
            client.close()
            await client.await_closed()
            await rpc_cleanup()
            raise

        client.close()
        await client.await_closed()
        await rpc_cleanup()
    async def test_assert_time_exceeds(self, two_nodes):

        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        # Farm blocks
        blocks = bt.get_consecutive_blocks(
            num_blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True)
        full_node_api_1, full_node_api_2, server_1, server_2 = two_nodes
        full_node_1 = full_node_api_1.full_node

        for block in blocks:
            await full_node_api_1.full_node.respond_block(
                full_node_protocol.RespondBlock(block))

        # Coinbase that gets spent
        block1 = blocks[2]
        spend_coin_block_1 = None
        for coin in list(block1.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                spend_coin_block_1 = coin

        # This condition requires block1 coinbase to be spent after 30 seconds from now
        current_time_plus3 = uint64(
            blocks[-1].foliage_transaction_block.timestamp + 30)
        block1_cvp = ConditionVarPair(
            ConditionOpcode.ASSERT_SECONDS_NOW_EXCEEDS,
            [int_to_bytes(current_time_plus3)])
        block1_dic = {block1_cvp.opcode: [block1_cvp]}
        block1_spend_bundle = wallet_a.generate_signed_transaction(
            1000, receiver_puzzlehash, spend_coin_block_1, block1_dic)

        # program that will be sent to early
        assert block1_spend_bundle is not None
        invalid_new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=block1_spend_bundle,
            time_per_block=20,
            guarantee_transaction_block=True,
        )

        # Try to validate that block before 3 sec
        res, err, _ = await full_node_1.blockchain.receive_block(
            invalid_new_blocks[-1])
        assert res == ReceiveBlockResult.INVALID_BLOCK
        assert err == Err.ASSERT_SECONDS_NOW_EXCEEDS_FAILED

        valid_new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=block1_spend_bundle,
            guarantee_transaction_block=True,
            time_per_block=31,
        )
        res, err, _ = await full_node_1.blockchain.receive_block(
            valid_new_blocks[-1])
        assert err is None
        assert res == ReceiveBlockResult.NEW_PEAK
    async def test_basic_store(self,
                               empty_blockchain,
                               normalized_to_identity: bool = False):
        blockchain = empty_blockchain
        blocks = bt.get_consecutive_blocks(
            10,
            seed=b"1234",
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )

        store = await FullNodeStore.create(test_constants)

        unfinished_blocks = []
        for block in blocks:
            unfinished_blocks.append(
                UnfinishedBlock(
                    block.finished_sub_slots,
                    block.reward_chain_block.get_unfinished(),
                    block.challenge_chain_sp_proof,
                    block.reward_chain_sp_proof,
                    block.foliage,
                    block.foliage_transaction_block,
                    block.transactions_info,
                    block.transactions_generator,
                    [],
                ))

        # Add/get candidate block
        assert store.get_candidate_block(
            unfinished_blocks[0].get_hash()) is None
        for height, unf_block in enumerate(unfinished_blocks):
            store.add_candidate_block(unf_block.get_hash(), height, unf_block)

        assert store.get_candidate_block(
            unfinished_blocks[4].get_hash())[1] == unfinished_blocks[4]
        store.clear_candidate_blocks_below(uint32(8))
        assert store.get_candidate_block(
            unfinished_blocks[5].get_hash()) is None
        assert store.get_candidate_block(
            unfinished_blocks[8].get_hash()) is not None

        # Test seen unfinished blocks
        h_hash_1 = bytes32(token_bytes(32))
        assert not store.seen_unfinished_block(h_hash_1)
        assert store.seen_unfinished_block(h_hash_1)
        store.clear_seen_unfinished_blocks()
        assert not store.seen_unfinished_block(h_hash_1)

        # Add/get unfinished block
        for height, unf_block in enumerate(unfinished_blocks):
            assert store.get_unfinished_block(unf_block.partial_hash) is None
            store.add_unfinished_block(
                height, unf_block,
                PreValidationResult(None, uint64(123532), None))
            assert store.get_unfinished_block(
                unf_block.partial_hash) == unf_block
            store.remove_unfinished_block(unf_block.partial_hash)
            assert store.get_unfinished_block(unf_block.partial_hash) is None

        blocks = bt.get_consecutive_blocks(
            1,
            skip_slots=5,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
        )
        sub_slots = blocks[0].finished_sub_slots
        assert len(sub_slots) == 5

        assert (store.get_finished_sub_slots(
            BlockCache({}),
            None,
            sub_slots[0].challenge_chain.challenge_chain_end_of_slot_vdf.
            challenge,
        ) == [])
        # Test adding non-connecting sub-slots genesis
        assert store.get_sub_slot(test_constants.GENESIS_CHALLENGE) is None
        assert store.get_sub_slot(
            sub_slots[0].challenge_chain.get_hash()) is None
        assert store.get_sub_slot(
            sub_slots[1].challenge_chain.get_hash()) is None
        assert store.new_finished_sub_slot(sub_slots[1], {}, None,
                                           None) is None
        assert store.new_finished_sub_slot(sub_slots[2], {}, None,
                                           None) is None

        # Test adding sub-slots after genesis
        assert store.new_finished_sub_slot(sub_slots[0], {}, None,
                                           None) is not None
        assert store.get_sub_slot(
            sub_slots[0].challenge_chain.get_hash())[0] == sub_slots[0]
        assert store.get_sub_slot(
            sub_slots[1].challenge_chain.get_hash()) is None
        assert store.new_finished_sub_slot(sub_slots[1], {}, None,
                                           None) is not None
        for i in range(len(sub_slots)):
            assert store.new_finished_sub_slot(sub_slots[i], {}, None,
                                               None) is not None
            assert store.get_sub_slot(
                sub_slots[i].challenge_chain.get_hash())[0] == sub_slots[i]

        assert store.get_finished_sub_slots(
            BlockCache({}), None,
            sub_slots[-1].challenge_chain.get_hash()) == sub_slots
        assert store.get_finished_sub_slots(BlockCache(
            {}), None, std_hash(b"not a valid hash")) is None

        assert (store.get_finished_sub_slots(
            BlockCache({}), None,
            sub_slots[-2].challenge_chain.get_hash()) == sub_slots[:-1])

        # Test adding genesis peak
        await blockchain.receive_block(blocks[0])
        peak = blockchain.get_peak()
        peak_full_block = await blockchain.get_full_peak()
        if peak.overflow:
            store.new_peak(peak, peak_full_block, sub_slots[-2], sub_slots[-1],
                           False, {})
        else:
            store.new_peak(peak, peak_full_block, None, sub_slots[-1], False,
                           {})

        assert store.get_sub_slot(
            sub_slots[0].challenge_chain.get_hash()) is None
        assert store.get_sub_slot(
            sub_slots[1].challenge_chain.get_hash()) is None
        assert store.get_sub_slot(
            sub_slots[2].challenge_chain.get_hash()) is None
        if peak.overflow:
            assert store.get_sub_slot(
                sub_slots[3].challenge_chain.get_hash())[0] == sub_slots[3]
        else:
            assert store.get_sub_slot(
                sub_slots[3].challenge_chain.get_hash()) is None
        assert store.get_sub_slot(
            sub_slots[4].challenge_chain.get_hash())[0] == sub_slots[4]

        assert (store.get_finished_sub_slots(
            blockchain,
            peak,
            sub_slots[-1].challenge_chain.get_hash(),
        ) == [])

        # Test adding non genesis peak directly
        blocks = bt.get_consecutive_blocks(
            2,
            skip_slots=2,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )
        blocks = bt.get_consecutive_blocks(
            3,
            block_list_input=blocks,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )
        for block in blocks:
            await blockchain.receive_block(block)
            sb = blockchain.block_record(block.header_hash)
            sp_sub_slot, ip_sub_slot = await blockchain.get_sp_and_ip_sub_slots(
                block.header_hash)
            res = store.new_peak(sb, block, sp_sub_slot, ip_sub_slot, False,
                                 blockchain)
            assert res[0] is None

        # Add reorg blocks
        blocks_reorg = bt.get_consecutive_blocks(
            20,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )
        for block in blocks_reorg:
            res, _, _ = await blockchain.receive_block(block)
            if res == ReceiveBlockResult.NEW_PEAK:
                sb = blockchain.block_record(block.header_hash)
                sp_sub_slot, ip_sub_slot = await blockchain.get_sp_and_ip_sub_slots(
                    block.header_hash)
                res = store.new_peak(sb, block, sp_sub_slot, ip_sub_slot, True,
                                     blockchain)
                assert res[0] is None

        # Add slots to the end
        blocks_2 = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks_reorg,
            skip_slots=2,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )
        for slot in blocks_2[-1].finished_sub_slots:
            store.new_finished_sub_slot(slot, blockchain,
                                        blockchain.get_peak(), await
                                        blockchain.get_full_peak())

        assert store.get_sub_slot(
            sub_slots[3].challenge_chain.get_hash()) is None
        assert store.get_sub_slot(
            sub_slots[4].challenge_chain.get_hash()) is None

        # Test adding signage point
        peak = blockchain.get_peak()
        ss_start_iters = peak.ip_sub_slot_total_iters(test_constants)
        for i in range(
                1, test_constants.NUM_SPS_SUB_SLOT -
                test_constants.NUM_SP_INTERVALS_EXTRA):
            sp = get_signage_point(
                test_constants,
                blockchain,
                peak,
                ss_start_iters,
                uint8(i),
                [],
                peak.sub_slot_iters,
            )
            assert store.new_signage_point(i, blockchain, peak,
                                           peak.sub_slot_iters, sp)

        blocks = blocks_reorg
        while True:
            blocks = bt.get_consecutive_blocks(
                1,
                block_list_input=blocks,
                normalized_to_identity_cc_eos=normalized_to_identity,
                normalized_to_identity_icc_eos=normalized_to_identity,
                normalized_to_identity_cc_ip=normalized_to_identity,
                normalized_to_identity_cc_sp=normalized_to_identity,
            )
            res, _, _ = await blockchain.receive_block(blocks[-1])
            if res == ReceiveBlockResult.NEW_PEAK:
                sb = blockchain.block_record(blocks[-1].header_hash)
                sp_sub_slot, ip_sub_slot = await blockchain.get_sp_and_ip_sub_slots(
                    blocks[-1].header_hash)

                res = store.new_peak(sb, blocks[-1], sp_sub_slot, ip_sub_slot,
                                     True, blockchain)
                assert res[0] is None
                if sb.overflow and sp_sub_slot is not None:
                    assert sp_sub_slot != ip_sub_slot
                    break

        peak = blockchain.get_peak()
        assert peak.overflow
        # Overflow peak should result in 2 finished sub slots
        assert len(store.finished_sub_slots) == 2

        # Add slots to the end, except for the last one, which we will use to test invalid SP
        blocks_2 = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks,
            skip_slots=3,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )
        for slot in blocks_2[-1].finished_sub_slots[:-1]:
            store.new_finished_sub_slot(slot, blockchain,
                                        blockchain.get_peak(), await
                                        blockchain.get_full_peak())
        finished_sub_slots = blocks_2[-1].finished_sub_slots
        assert len(store.finished_sub_slots) == 4

        # Test adding signage points for overflow blocks (sp_sub_slot)
        ss_start_iters = peak.sp_sub_slot_total_iters(test_constants)
        # for i in range(peak.signage_point_index, test_constants.NUM_SPS_SUB_SLOT):
        #     if i < peak.signage_point_index:
        #         continue
        #     latest = peak
        #     while latest.total_iters > peak.sp_total_iters(test_constants):
        #         latest = blockchain.blocks[latest.prev_hash]
        #     sp = get_signage_point(
        #         test_constants,
        #         blockchain.blocks,
        #         latest,
        #         ss_start_iters,
        #         uint8(i),
        #         [],
        #         peak.sub_slot_iters,
        #     )
        #     assert store.new_signage_point(i, blockchain.blocks, peak, peak.sub_slot_iters, sp)

        # Test adding signage points for overflow blocks (ip_sub_slot)
        for i in range(
                1, test_constants.NUM_SPS_SUB_SLOT -
                test_constants.NUM_SP_INTERVALS_EXTRA):
            sp = get_signage_point(
                test_constants,
                blockchain,
                peak,
                peak.ip_sub_slot_total_iters(test_constants),
                uint8(i),
                [],
                peak.sub_slot_iters,
            )
            assert store.new_signage_point(i, blockchain, peak,
                                           peak.sub_slot_iters, sp)

        # Test adding future signage point, a few slots forward (good)
        saved_sp_hash = None
        for slot_offset in range(1, len(finished_sub_slots)):
            for i in range(
                    1,
                    test_constants.NUM_SPS_SUB_SLOT -
                    test_constants.NUM_SP_INTERVALS_EXTRA,
            ):
                sp = get_signage_point(
                    test_constants,
                    blockchain,
                    peak,
                    peak.ip_sub_slot_total_iters(test_constants) +
                    slot_offset * peak.sub_slot_iters,
                    uint8(i),
                    finished_sub_slots[:slot_offset],
                    peak.sub_slot_iters,
                )
                assert sp.cc_vdf is not None
                saved_sp_hash = sp.cc_vdf.output.get_hash()
                assert store.new_signage_point(i, blockchain, peak,
                                               peak.sub_slot_iters, sp)

        # Test adding future signage point (bad)
        for i in range(
                1, test_constants.NUM_SPS_SUB_SLOT -
                test_constants.NUM_SP_INTERVALS_EXTRA):
            sp = get_signage_point(
                test_constants,
                blockchain,
                peak,
                peak.ip_sub_slot_total_iters(test_constants) +
                len(finished_sub_slots) * peak.sub_slot_iters,
                uint8(i),
                finished_sub_slots[:len(finished_sub_slots)],
                peak.sub_slot_iters,
            )
            assert not store.new_signage_point(i, blockchain, peak,
                                               peak.sub_slot_iters, sp)

        # Test adding past signage point
        sp = SignagePoint(
            blocks[1].reward_chain_block.challenge_chain_sp_vdf,
            blocks[1].challenge_chain_sp_proof,
            blocks[1].reward_chain_block.reward_chain_sp_vdf,
            blocks[1].reward_chain_sp_proof,
        )
        assert not store.new_signage_point(
            blocks[1].reward_chain_block.signage_point_index,
            {},
            peak,
            blockchain.block_record(
                blocks[1].header_hash).sp_sub_slot_total_iters(test_constants),
            sp,
        )

        # Get signage point by index
        assert (store.get_signage_point_by_index(
            finished_sub_slots[0].challenge_chain.get_hash(),
            4,
            finished_sub_slots[0].reward_chain.get_hash(),
        ) is not None)

        assert (store.get_signage_point_by_index(
            finished_sub_slots[0].challenge_chain.get_hash(), 4,
            std_hash(b"1")) is None)

        # Get signage point by hash
        assert store.get_signage_point(saved_sp_hash) is not None
        assert store.get_signage_point(std_hash(b"2")) is None

        # Test adding signage points before genesis
        store.initialize_genesis_sub_slot()
        assert len(store.finished_sub_slots) == 1
        for i in range(
                1, test_constants.NUM_SPS_SUB_SLOT -
                test_constants.NUM_SP_INTERVALS_EXTRA):
            sp = get_signage_point(
                test_constants,
                BlockCache({}, {}),
                None,
                uint128(0),
                uint8(i),
                [],
                peak.sub_slot_iters,
            )
            assert store.new_signage_point(i, {}, None, peak.sub_slot_iters,
                                           sp)

        blocks_3 = bt.get_consecutive_blocks(
            1,
            skip_slots=2,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )
        for slot in blocks_3[-1].finished_sub_slots:
            store.new_finished_sub_slot(slot, {}, None, None)
        assert len(store.finished_sub_slots) == 3
        finished_sub_slots = blocks_3[-1].finished_sub_slots

        for slot_offset in range(1, len(finished_sub_slots) + 1):
            for i in range(
                    1,
                    test_constants.NUM_SPS_SUB_SLOT -
                    test_constants.NUM_SP_INTERVALS_EXTRA,
            ):
                sp = get_signage_point(
                    test_constants,
                    BlockCache({}, {}),
                    None,
                    slot_offset * peak.sub_slot_iters,
                    uint8(i),
                    finished_sub_slots[:slot_offset],
                    peak.sub_slot_iters,
                )
                assert store.new_signage_point(i, {}, None,
                                               peak.sub_slot_iters, sp)

        # Test adding signage points after genesis
        blocks_4 = bt.get_consecutive_blocks(
            1,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )
        blocks_5 = bt.get_consecutive_blocks(
            1,
            block_list_input=blocks_4,
            skip_slots=1,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )

        # If this is not the case, fix test to find a block that is
        assert (blocks_4[-1].reward_chain_block.signage_point_index <
                test_constants.NUM_SPS_SUB_SLOT -
                test_constants.NUM_SP_INTERVALS_EXTRA)
        await blockchain.receive_block(blocks_4[-1])
        sb = blockchain.block_record(blocks_4[-1].header_hash)
        store.new_peak(sb, blocks_4[-1], None, None, False, blockchain)
        for i in range(
                sb.signage_point_index + test_constants.NUM_SP_INTERVALS_EXTRA,
                test_constants.NUM_SPS_SUB_SLOT,
        ):
            if is_overflow_block(test_constants, uint8(i)):
                finished_sub_slots = blocks_5[-1].finished_sub_slots
            else:
                finished_sub_slots = []

            sp = get_signage_point(
                test_constants,
                blockchain,
                sb,
                uint128(0),
                uint8(i),
                finished_sub_slots,
                peak.sub_slot_iters,
            )
            assert store.new_signage_point(i, empty_blockchain, sb,
                                           peak.sub_slot_iters, sp)

        # Test future EOS cache
        store.initialize_genesis_sub_slot()
        blocks = bt.get_consecutive_blocks(
            1,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
        )
        await blockchain.receive_block(blocks[-1])
        while True:
            blocks = bt.get_consecutive_blocks(
                1,
                block_list_input=blocks,
                normalized_to_identity_cc_eos=normalized_to_identity,
                normalized_to_identity_icc_eos=normalized_to_identity,
                normalized_to_identity_cc_ip=normalized_to_identity,
                normalized_to_identity_cc_sp=normalized_to_identity,
            )
            await blockchain.receive_block(blocks[-1])
            sb = blockchain.block_record(blocks[-1].header_hash)
            if sb.first_in_sub_slot:
                break
        assert len(blocks) >= 2
        dependant_sub_slots = blocks[-1].finished_sub_slots
        peak = blockchain.get_peak()
        peak_full_block = await blockchain.get_full_peak()
        for block in blocks[:-2]:
            sb = blockchain.block_record(block.header_hash)
            sp_sub_slot, ip_sub_slot = await blockchain.get_sp_and_ip_sub_slots(
                block.header_hash)
            peak = sb
            peak_full_block = block
            res = store.new_peak(sb, block, sp_sub_slot, ip_sub_slot, False,
                                 blockchain)
            assert res[0] is None

        assert store.new_finished_sub_slot(dependant_sub_slots[0], blockchain,
                                           peak, peak_full_block) is None
        block = blocks[-2]
        sb = blockchain.block_record(block.header_hash)
        sp_sub_slot, ip_sub_slot = await blockchain.get_sp_and_ip_sub_slots(
            block.header_hash)
        res = store.new_peak(sb, block, sp_sub_slot, ip_sub_slot, False,
                             blockchain)
        assert res[0] == dependant_sub_slots[0]
        assert res[1] == res[2] == []

        # Test future IP cache
        store.initialize_genesis_sub_slot()
        blocks = bt.get_consecutive_blocks(
            60,
            normalized_to_identity_cc_ip=normalized_to_identity,
            normalized_to_identity_cc_sp=normalized_to_identity,
            normalized_to_identity_cc_eos=normalized_to_identity,
            normalized_to_identity_icc_eos=normalized_to_identity,
        )

        for block in blocks[:5]:
            await blockchain.receive_block(block)
            sb = blockchain.block_record(block.header_hash)

            sp_sub_slot, ip_sub_slot = await blockchain.get_sp_and_ip_sub_slots(
                block.header_hash)
            res = store.new_peak(sb, block, sp_sub_slot, ip_sub_slot, False,
                                 blockchain)
            assert res[0] is None

        case_0, case_1 = False, False
        for i in range(5, len(blocks) - 1):
            prev_block = blocks[i]
            block = blocks[i + 1]
            new_ip = NewInfusionPointVDF(
                block.reward_chain_block.get_unfinished().get_hash(),
                block.reward_chain_block.challenge_chain_ip_vdf,
                block.challenge_chain_ip_proof,
                block.reward_chain_block.reward_chain_ip_vdf,
                block.reward_chain_ip_proof,
                block.reward_chain_block.infused_challenge_chain_ip_vdf,
                block.infused_challenge_chain_ip_proof,
            )
            store.add_to_future_ip(new_ip)

            await blockchain.receive_block(prev_block)
            sp_sub_slot, ip_sub_slot = await blockchain.get_sp_and_ip_sub_slots(
                prev_block.header_hash)
            sb = blockchain.block_record(prev_block.header_hash)
            res = store.new_peak(sb, prev_block, sp_sub_slot, ip_sub_slot,
                                 False, blockchain)
            if len(block.finished_sub_slots) == 0:
                case_0 = True
                assert res[2] == [new_ip]
            else:
                case_1 = True
                assert res[2] == []
                found_ips = []
                for ss in block.finished_sub_slots:
                    found_ips += store.new_finished_sub_slot(
                        ss, blockchain, sb, prev_block)
                assert found_ips == [new_ip]

        # If flaky, increase the number of blocks created
        assert case_0 and case_1
Exemplo n.º 20
0
    async def test_long_sync_from_zero(self, five_nodes, default_400_blocks):
        # Must be larger than "sync_block_behind_threshold" in the config
        num_blocks = len(default_400_blocks)
        blocks: List[FullBlock] = default_400_blocks
        full_node_1, full_node_2, full_node_3, full_node_4, full_node_5 = five_nodes
        server_1 = full_node_1.full_node.server
        server_2 = full_node_2.full_node.server
        server_3 = full_node_3.full_node.server
        server_4 = full_node_4.full_node.server
        server_5 = full_node_5.full_node.server

        # If this constant is changed, update the tests to use more blocks
        assert test_constants.WEIGHT_PROOF_RECENT_BLOCKS < 400

        # Syncs up less than recent blocks
        for block in blocks[:test_constants.WEIGHT_PROOF_RECENT_BLOCKS - 5]:
            await full_node_1.full_node.respond_block(
                full_node_protocol.RespondBlock(block))

        await server_2.start_client(
            PeerInfo(self_hostname, uint16(server_1._port)),
            on_connect=full_node_2.full_node.on_connect)

        # The second node should eventually catch up to the first one
        await time_out_assert(
            150, node_height_exactly, True, full_node_2,
            test_constants.WEIGHT_PROOF_RECENT_BLOCKS - 5 - 1)

        for block in blocks[test_constants.WEIGHT_PROOF_RECENT_BLOCKS -
                            5:test_constants.WEIGHT_PROOF_RECENT_BLOCKS + 5]:
            await full_node_1.full_node.respond_block(
                full_node_protocol.RespondBlock(block))

        await server_3.start_client(
            PeerInfo(self_hostname, uint16(server_1._port)),
            on_connect=full_node_3.full_node.on_connect)

        timeout_seconds = 150

        # Node 3 and Node 2 sync up to node 1
        await time_out_assert(
            timeout_seconds, node_height_exactly, True, full_node_2,
            test_constants.WEIGHT_PROOF_RECENT_BLOCKS + 5 - 1)
        await time_out_assert(
            timeout_seconds, node_height_exactly, True, full_node_3,
            test_constants.WEIGHT_PROOF_RECENT_BLOCKS + 5 - 1)

        cons = list(server_1.all_connections.values())[:]
        for con in cons:
            await con.close()
        for block in blocks[test_constants.WEIGHT_PROOF_RECENT_BLOCKS + 5:]:
            await full_node_1.full_node.respond_block(
                full_node_protocol.RespondBlock(block))

        await server_2.start_client(
            PeerInfo(self_hostname, uint16(server_1._port)),
            on_connect=full_node_2.full_node.on_connect)
        await server_3.start_client(
            PeerInfo(self_hostname, uint16(server_1._port)),
            on_connect=full_node_3.full_node.on_connect)
        await server_4.start_client(
            PeerInfo(self_hostname, uint16(server_1._port)),
            on_connect=full_node_4.full_node.on_connect)
        await server_3.start_client(
            PeerInfo(self_hostname, uint16(server_2._port)),
            on_connect=full_node_3.full_node.on_connect)
        await server_4.start_client(
            PeerInfo(self_hostname, uint16(server_3._port)),
            on_connect=full_node_4.full_node.on_connect)
        await server_4.start_client(
            PeerInfo(self_hostname, uint16(server_2._port)),
            on_connect=full_node_4.full_node.on_connect)

        # All four nodes are synced
        await time_out_assert(timeout_seconds, node_height_exactly, True,
                              full_node_1, num_blocks - 1)
        await time_out_assert(timeout_seconds, node_height_exactly, True,
                              full_node_2, num_blocks - 1)
        await time_out_assert(timeout_seconds, node_height_exactly, True,
                              full_node_3, num_blocks - 1)
        await time_out_assert(timeout_seconds, node_height_exactly, True,
                              full_node_4, num_blocks - 1)

        # Deep reorg, fall back from batch sync to long sync
        blocks_node_5 = bt.get_consecutive_blocks(
            60, block_list_input=blocks[:350], seed=b"node5")
        for block in blocks_node_5:
            await full_node_5.full_node.respond_block(
                full_node_protocol.RespondBlock(block))
        await server_5.start_client(
            PeerInfo(self_hostname, uint16(server_1._port)),
            on_connect=full_node_5.full_node.on_connect)
        await time_out_assert(timeout_seconds, node_height_exactly, True,
                              full_node_5, 409)
        await time_out_assert(timeout_seconds, node_height_exactly, True,
                              full_node_1, 409)
Exemplo n.º 21
0
    async def test_validate_blockchain_spend_reorg_coin(self, two_nodes):
        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_1_puzzlehash = WALLET_A_PUZZLE_HASHES[1]
        receiver_2_puzzlehash = WALLET_A_PUZZLE_HASHES[2]
        receiver_3_puzzlehash = WALLET_A_PUZZLE_HASHES[3]

        blocks = bt.get_consecutive_blocks(
            num_blocks, farmer_reward_puzzle_hash=coinbase_puzzlehash, guarantee_transaction_block=True
        )
        full_node_api_1, full_node_api_2, server_1, server_2 = two_nodes

        for block in blocks:
            await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))

        spend_block = blocks[2]

        spend_coin = None
        for coin in list(spend_block.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                spend_coin = coin

        spend_bundle = wallet_a.generate_signed_transaction(1000, receiver_1_puzzlehash, spend_coin)

        new_blocks = bt.get_consecutive_blocks(
            1,
            blocks[:5],
            seed=b"spend_reorg_coin",
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=spend_bundle,
            guarantee_transaction_block=True,
        )

        await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(new_blocks[-1]))

        coin_2 = None
        for coin in new_blocks[-1].additions():
            if coin.puzzle_hash == receiver_1_puzzlehash:
                coin_2 = coin
                break
        assert coin_2 is not None

        spend_bundle = wallet_a.generate_signed_transaction(1000, receiver_2_puzzlehash, coin_2)

        new_blocks = bt.get_consecutive_blocks(
            1,
            new_blocks[:6],
            seed=b"spend_reorg_coin",
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=spend_bundle,
            guarantee_transaction_block=True,
        )
        await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(new_blocks[-1]))

        coin_3 = None
        for coin in new_blocks[-1].additions():
            if coin.puzzle_hash == receiver_2_puzzlehash:
                coin_3 = coin
                break
        assert coin_3 is not None

        spend_bundle = wallet_a.generate_signed_transaction(1000, receiver_3_puzzlehash, coin_3)

        new_blocks = bt.get_consecutive_blocks(
            1,
            new_blocks[:7],
            seed=b"spend_reorg_coin",
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=spend_bundle,
            guarantee_transaction_block=True,
        )

        await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(new_blocks[-1]))

        coin_4 = None
        for coin in new_blocks[-1].additions():
            if coin.puzzle_hash == receiver_3_puzzlehash:
                coin_4 = coin
                break
        assert coin_4 is not None
Exemplo n.º 22
0
    async def test_full_block_performance(self, wallet_nodes):
        full_node_1, server_1, wallet_a, wallet_receiver = wallet_nodes
        blocks = await full_node_1.get_all_full_blocks()
        full_node_1.full_node.mempool_manager.limit_factor = 1

        wallet_ph = wallet_a.get_new_puzzlehash()
        blocks = bt.get_consecutive_blocks(
            10,
            block_list_input=blocks,
            guarantee_transaction_block=True,
            farmer_reward_puzzle_hash=wallet_ph,
            pool_reward_puzzle_hash=wallet_ph,
        )
        for block in blocks:
            await full_node_1.full_node.respond_block(fnp.RespondBlock(block))

        start_height = (full_node_1.full_node.blockchain.get_peak().height
                        if full_node_1.full_node.blockchain.get_peak()
                        is not None else -1)
        incoming_queue, node_id = await add_dummy_connection(server_1, 12312)
        fake_peer = server_1.all_connections[node_id]
        # Mempool has capacity of 100, make 110 unspents that we can use
        puzzle_hashes = []

        # Makes a bunch of coins
        for i in range(20):
            conditions_dict: Dict = {ConditionOpcode.CREATE_COIN: []}
            # This should fit in one transaction
            for _ in range(100):
                receiver_puzzlehash = wallet_receiver.get_new_puzzlehash()
                puzzle_hashes.append(receiver_puzzlehash)
                output = ConditionWithArgs(
                    ConditionOpcode.CREATE_COIN,
                    [receiver_puzzlehash,
                     int_to_bytes(100000000)])

                conditions_dict[ConditionOpcode.CREATE_COIN].append(output)

            spend_bundle = wallet_a.generate_signed_transaction(
                100,
                puzzle_hashes[0],
                get_future_reward_coins(blocks[1 + i])[0],
                condition_dic=conditions_dict,
            )
            assert spend_bundle is not None

            respond_transaction_2 = fnp.RespondTransaction(spend_bundle)
            await full_node_1.respond_transaction(respond_transaction_2,
                                                  fake_peer)

            blocks = bt.get_consecutive_blocks(
                1,
                block_list_input=blocks,
                guarantee_transaction_block=True,
                transaction_data=spend_bundle,
            )
            await full_node_1.full_node.respond_block(
                fnp.RespondBlock(blocks[-1]), fake_peer)

        await time_out_assert(10, node_height_at_least, True, full_node_1,
                              start_height + 20)

        spend_bundles = []
        spend_bundle_ids = []

        # Fill mempool
        for puzzle_hash in puzzle_hashes[1:]:
            coin_record = (await full_node_1.full_node.coin_store.
                           get_coin_records_by_puzzle_hash(True,
                                                           puzzle_hash))[0]
            receiver_puzzlehash = wallet_receiver.get_new_puzzlehash()
            if puzzle_hash == puzzle_hashes[-1]:
                fee = 100000000  # 100 million (20 fee per cost)
            else:
                fee = random.randint(1, 100000000)
            spend_bundle = wallet_receiver.generate_signed_transaction(
                uint64(500), receiver_puzzlehash, coin_record.coin, fee=fee)
            spend_bundles.append(spend_bundle)
            spend_bundle_ids.append(spend_bundle.get_hash())

        pr = cProfile.Profile()
        pr.enable()

        start = time.time()
        num_tx: int = 0
        for spend_bundle, spend_bundle_id in zip(spend_bundles,
                                                 spend_bundle_ids):
            num_tx += 1
            respond_transaction = fnp.RespondTransaction(spend_bundle)

            await full_node_1.respond_transaction(respond_transaction,
                                                  fake_peer)

            request = fnp.RequestTransaction(spend_bundle_id)
            req = await full_node_1.request_transaction(request)

            if req is None:
                break
        log.warning(f"Num Tx: {num_tx}")
        log.warning(f"Time for mempool: {time.time() - start}")
        pr.create_stats()
        pr.dump_stats("./mempool-benchmark.pstats")

        # Create an unfinished block
        peak = full_node_1.full_node.blockchain.get_peak()
        assert peak is not None
        curr: BlockRecord = peak
        while not curr.is_transaction_block:
            curr = full_node_1.full_node.blockchain.block_record(
                curr.prev_hash)
        mempool_bundle = await full_node_1.full_node.mempool_manager.create_bundle_from_mempool(
            curr.header_hash)
        if mempool_bundle is None:
            spend_bundle = None
        else:
            spend_bundle = mempool_bundle[0]

        current_blocks = await full_node_1.get_all_full_blocks()
        blocks = bt.get_consecutive_blocks(
            1,
            transaction_data=spend_bundle,
            block_list_input=current_blocks,
            guarantee_transaction_block=True,
        )
        block = blocks[-1]
        unfinished = UnfinishedBlock(
            block.finished_sub_slots,
            block.reward_chain_block.get_unfinished(),
            block.challenge_chain_sp_proof,
            block.reward_chain_sp_proof,
            block.foliage,
            block.foliage_transaction_block,
            block.transactions_info,
            block.transactions_generator,
            [],
        )

        pr = cProfile.Profile()
        pr.enable()

        start = time.time()
        res = await full_node_1.respond_unfinished_block(
            fnp.RespondUnfinishedBlock(unfinished), fake_peer)
        log.warning(f"Res: {res}")
        log.warning(f"Time for unfinished: {time.time() - start}")

        pr.create_stats()
        pr.dump_stats("./unfinished-benchmark.pstats")

        pr = cProfile.Profile()
        pr.enable()

        start = time.time()
        # No transactions generator, the full node already cached it from the unfinished block
        block_small = dataclasses.replace(block, transactions_generator=None)
        res = await full_node_1.full_node.respond_block(
            fnp.RespondBlock(block_small))
        log.warning(f"Res: {res}")
        log.warning(f"Time for full block: {time.time() - start}")

        pr.create_stats()
        pr.dump_stats("./full-block-benchmark.pstats")
Exemplo n.º 23
0
    async def test_assert_announcement_consumed(self, two_nodes):

        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        # Farm blocks
        blocks = bt.get_consecutive_blocks(
            num_blocks, farmer_reward_puzzle_hash=coinbase_puzzlehash, guarantee_transaction_block=True
        )
        full_node_api_1, full_node_api_2, server_1, server_2 = two_nodes
        full_node_1 = full_node_api_1.full_node

        for block in blocks:
            await full_node_api_1.full_node.respond_block(full_node_protocol.RespondBlock(block))

        # Coinbase that gets spent
        block1 = blocks[2]
        block2 = blocks[3]

        spend_coin_block_1 = None
        spend_coin_block_2 = None
        for coin in list(block1.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                spend_coin_block_1 = coin
        for coin in list(block2.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                spend_coin_block_2 = coin

        # This condition requires block2 coinbase to be spent
        block1_cvp = ConditionVarPair(
            ConditionOpcode.ASSERT_ANNOUNCEMENT,
            [Announcement(spend_coin_block_2.name(), bytes("test", "utf-8")).name()],
        )
        block1_dic = {block1_cvp.opcode: [block1_cvp]}
        block1_spend_bundle = wallet_a.generate_signed_transaction(
            1000, receiver_puzzlehash, spend_coin_block_1, block1_dic
        )

        # This condition requires block1 coinbase to be spent
        block2_cvp = ConditionVarPair(
            ConditionOpcode.CREATE_ANNOUNCEMENT,
            [bytes("test", "utf-8")],
        )
        block2_dic = {block2_cvp.opcode: [block2_cvp]}
        block2_spend_bundle = wallet_a.generate_signed_transaction(
            1000, receiver_puzzlehash, spend_coin_block_2, block2_dic
        )

        # Invalid block bundle
        assert block1_spend_bundle is not None
        # Create another block that includes our transaction
        invalid_new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=block1_spend_bundle,
            guarantee_transaction_block=True,
        )

        # Try to validate that block
        res, err, _ = await full_node_1.blockchain.receive_block(invalid_new_blocks[-1])
        assert res == ReceiveBlockResult.INVALID_BLOCK
        assert err == Err.ASSERT_ANNOUNCE_CONSUMED_FAILED

        # bundle_together contains both transactions
        bundle_together = SpendBundle.aggregate([block1_spend_bundle, block2_spend_bundle])

        # Create another block that includes our transaction
        new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=bundle_together,
            guarantee_transaction_block=True,
        )

        # Try to validate newly created block
        res, err, _ = await full_node_1.blockchain.receive_block(new_blocks[-1])
        assert res == ReceiveBlockResult.NEW_PEAK
        assert err is None
Exemplo n.º 24
0
    async def test_basic_coin_store(self, cache_size: uint32, db_version, softfork_height):
        wallet_a = WALLET_A
        reward_ph = wallet_a.get_new_puzzlehash()

        # Generate some coins
        blocks = bt.get_consecutive_blocks(
            10,
            [],
            farmer_reward_puzzle_hash=reward_ph,
            pool_reward_puzzle_hash=reward_ph,
        )

        coins_to_spend: List[Coin] = []
        for block in blocks:
            if block.is_transaction_block():
                for coin in block.get_included_reward_coins():
                    if coin.puzzle_hash == reward_ph:
                        coins_to_spend.append(coin)

        spend_bundle = wallet_a.generate_signed_transaction(
            uint64(1000), wallet_a.get_new_puzzlehash(), coins_to_spend[0]
        )

        async with DBConnection(db_version) as db_wrapper:
            coin_store = await CoinStore.create(db_wrapper, cache_size=cache_size)

            blocks = bt.get_consecutive_blocks(
                10,
                blocks,
                farmer_reward_puzzle_hash=reward_ph,
                pool_reward_puzzle_hash=reward_ph,
                transaction_data=spend_bundle,
            )

            # Adding blocks to the coin store
            should_be_included_prev: Set[Coin] = set()
            should_be_included: Set[Coin] = set()
            for block in blocks:
                farmer_coin, pool_coin = get_future_reward_coins(block)
                should_be_included.add(farmer_coin)
                should_be_included.add(pool_coin)
                if block.is_transaction_block():
                    if block.transactions_generator is not None:
                        block_gen: BlockGenerator = BlockGenerator(block.transactions_generator, [], [])
                        npc_result = get_name_puzzle_conditions(
                            block_gen,
                            bt.constants.MAX_BLOCK_COST_CLVM,
                            cost_per_byte=bt.constants.COST_PER_BYTE,
                            mempool_mode=False,
                            height=softfork_height,
                        )
                        tx_removals, tx_additions = tx_removals_and_additions(npc_result.npc_list)
                    else:
                        tx_removals, tx_additions = [], []

                    assert block.get_included_reward_coins() == should_be_included_prev

                    if block.is_transaction_block():
                        assert block.foliage_transaction_block is not None
                        await coin_store.new_block(
                            block.height,
                            block.foliage_transaction_block.timestamp,
                            block.get_included_reward_coins(),
                            tx_additions,
                            tx_removals,
                        )

                        if block.height != 0:
                            with pytest.raises(Exception):
                                await coin_store.new_block(
                                    block.height,
                                    block.foliage_transaction_block.timestamp,
                                    block.get_included_reward_coins(),
                                    tx_additions,
                                    tx_removals,
                                )

                    for expected_coin in should_be_included_prev:
                        # Check that the coinbase rewards are added
                        record = await coin_store.get_coin_record(expected_coin.name())
                        assert record is not None
                        assert not record.spent
                        assert record.coin == expected_coin
                    for coin_name in tx_removals:
                        # Check that the removed coins are set to spent
                        record = await coin_store.get_coin_record(coin_name)
                        assert record.spent
                    for coin in tx_additions:
                        # Check that the added coins are added
                        record = await coin_store.get_coin_record(coin.name())
                        assert not record.spent
                        assert coin == record.coin

                    should_be_included_prev = should_be_included.copy()
                    should_be_included = set()
Exemplo n.º 25
0
    async def test_signage_points(self, two_nodes, empty_blockchain):
        test_rpc_port = uint16(21522)
        nodes, _ = two_nodes
        full_node_api_1, full_node_api_2 = nodes
        server_1 = full_node_api_1.full_node.server
        server_2 = full_node_api_2.full_node.server

        peer = await connect_and_get_peer(server_1, server_2)

        def stop_node_cb():
            full_node_api_1._close()
            server_1.close_all()

        full_node_rpc_api = FullNodeRpcApi(full_node_api_1.full_node)

        config = bt.config
        hostname = config["self_hostname"]
        daemon_port = config["daemon_port"]

        rpc_cleanup = await start_rpc_server(
            full_node_rpc_api,
            hostname,
            daemon_port,
            test_rpc_port,
            stop_node_cb,
            bt.root_path,
            config,
            connect_to_daemon=False,
        )

        try:
            client = await FullNodeRpcClient.create(self_hostname,
                                                    test_rpc_port,
                                                    bt.root_path, config)

            # Only provide one
            res = await client.get_recent_signage_point_or_eos(None, None)
            assert res is None
            res = await client.get_recent_signage_point_or_eos(
                std_hash(b"0"), std_hash(b"1"))
            assert res is None

            # Not found
            res = await client.get_recent_signage_point_or_eos(
                std_hash(b"0"), None)
            assert res is None
            res = await client.get_recent_signage_point_or_eos(
                None, std_hash(b"0"))
            assert res is None

            blocks = bt.get_consecutive_blocks(5)
            for block in blocks:
                await full_node_api_1.full_node.respond_block(
                    full_node_protocol.RespondBlock(block))

            blocks = bt.get_consecutive_blocks(1,
                                               block_list_input=blocks,
                                               skip_slots=1,
                                               force_overflow=True)

            blockchain = full_node_api_1.full_node.blockchain
            second_blockchain = empty_blockchain

            for block in blocks:
                await _validate_and_add_block(second_blockchain, block)

            # Creates a signage point based on the last block
            peak_2 = second_blockchain.get_peak()
            sp: SignagePoint = get_signage_point(
                test_constants,
                blockchain,
                peak_2,
                peak_2.ip_sub_slot_total_iters(test_constants),
                uint8(4),
                [],
                peak_2.sub_slot_iters,
            )

            # Don't have SP yet
            res = await client.get_recent_signage_point_or_eos(
                sp.cc_vdf.output.get_hash(), None)
            assert res is None

            # Add the last block
            await full_node_api_1.full_node.respond_block(
                full_node_protocol.RespondBlock(blocks[-1]))
            await full_node_api_1.respond_signage_point(
                full_node_protocol.RespondSignagePoint(uint8(4), sp.cc_vdf,
                                                       sp.cc_proof, sp.rc_vdf,
                                                       sp.rc_proof), peer)

            assert full_node_api_1.full_node.full_node_store.get_signage_point(
                sp.cc_vdf.output.get_hash()) is not None

            # Properly fetch a signage point
            res = await client.get_recent_signage_point_or_eos(
                sp.cc_vdf.output.get_hash(), None)

            assert res is not None
            assert "eos" not in res
            assert res["signage_point"] == sp
            assert not res["reverted"]

            blocks = bt.get_consecutive_blocks(1,
                                               block_list_input=blocks,
                                               skip_slots=1)
            selected_eos = blocks[-1].finished_sub_slots[0]

            # Don't have EOS yet
            res = await client.get_recent_signage_point_or_eos(
                None, selected_eos.challenge_chain.get_hash())
            assert res is None

            # Properly fetch an EOS
            for eos in blocks[-1].finished_sub_slots:
                await full_node_api_1.full_node.respond_end_of_sub_slot(
                    full_node_protocol.RespondEndOfSubSlot(eos), peer)

            res = await client.get_recent_signage_point_or_eos(
                None, selected_eos.challenge_chain.get_hash())
            assert res is not None
            assert "signage_point" not in res
            assert res["eos"] == selected_eos
            assert not res["reverted"]

            # Do another one but without sending the slot
            await full_node_api_1.full_node.respond_block(
                full_node_protocol.RespondBlock(blocks[-1]))
            blocks = bt.get_consecutive_blocks(1,
                                               block_list_input=blocks,
                                               skip_slots=1)
            selected_eos = blocks[-1].finished_sub_slots[-1]
            await full_node_api_1.full_node.respond_block(
                full_node_protocol.RespondBlock(blocks[-1]))

            res = await client.get_recent_signage_point_or_eos(
                None, selected_eos.challenge_chain.get_hash())
            assert res is not None
            assert "signage_point" not in res
            assert res["eos"] == selected_eos
            assert not res["reverted"]

            # Perform a reorg
            blocks = bt.get_consecutive_blocks(12, seed=b"1234")
            for block in blocks:
                await full_node_api_1.full_node.respond_block(
                    full_node_protocol.RespondBlock(block))

            # Signage point is no longer in the blockchain
            res = await client.get_recent_signage_point_or_eos(
                sp.cc_vdf.output.get_hash(), None)
            assert res["reverted"]
            assert res["signage_point"] == sp
            assert "eos" not in res

            # EOS is no longer in the blockchain
            res = await client.get_recent_signage_point_or_eos(
                None, selected_eos.challenge_chain.get_hash())
            assert res is not None
            assert "signage_point" not in res
            assert res["eos"] == selected_eos
            assert res["reverted"]

        finally:
            # Checks that the RPC manages to stop the node
            client.close()
            await client.await_closed()
            await rpc_cleanup()
Exemplo n.º 26
0
    async def test_invalid_block(self, wallet_node_30_freeze):
        num_blocks = 5
        full_nodes, wallets = wallet_node_30_freeze
        full_node_api: FullNodeSimulator = full_nodes[0]
        full_node_server = full_node_api.server
        wallet_node, server_2 = wallets[0]
        wallet = wallet_node.wallet_state_manager.main_wallet
        ph = await wallet.get_new_puzzlehash()

        await server_2.start_client(
            PeerInfo(self_hostname, uint16(full_node_server._port)), None)
        for i in range(num_blocks):
            await full_node_api.farm_new_transaction_block(
                FarmNewBlockProtocol(ph))

        funds = sum([
            calculate_pool_reward(uint32(i)) +
            calculate_base_farmer_reward(uint32(i))
            for i in range(1, num_blocks)
        ])
        # funds += calculate_base_farmer_reward(0)
        await asyncio.sleep(2)
        print(await wallet.get_confirmed_balance(), funds)
        await time_out_assert(10, wallet.get_confirmed_balance, funds)

        tx: TransactionRecord = await wallet.generate_signed_transaction(
            100, ph, 0)

        current_blocks = await full_node_api.get_all_full_blocks()
        new_blocks = bt.get_consecutive_blocks(
            1,
            block_list_input=current_blocks,
            transaction_data=tx.spend_bundle,
            guarantee_transaction_block=True)
        last_block = new_blocks[-1:][0]

        new_blocks_no_tx = bt.get_consecutive_blocks(
            1,
            block_list_input=current_blocks,
            guarantee_transaction_block=True)
        last_block_no_tx = new_blocks_no_tx[-1:][0]

        result, error, fork = await full_node_api.full_node.blockchain.receive_block(
            last_block, None)
        assert error is not None
        assert error is Err.INITIAL_TRANSACTION_FREEZE
        assert result is ReceiveBlockResult.INVALID_BLOCK

        result, error, fork = await full_node_api.full_node.blockchain.receive_block(
            last_block_no_tx, None)
        assert error is None
        assert result is ReceiveBlockResult.NEW_PEAK

        after_freeze_blocks = bt.get_consecutive_blocks(
            24, block_list_input=new_blocks_no_tx)
        for block in after_freeze_blocks:
            await full_node_api.full_node.blockchain.receive_block(block, None)

        assert full_node_api.full_node.blockchain.get_peak_height() == 30

        new_blocks = bt.get_consecutive_blocks(
            1,
            block_list_input=after_freeze_blocks,
            transaction_data=tx.spend_bundle,
            guarantee_transaction_block=True)
        last_block = new_blocks[-1:][0]
        result, error, fork = await full_node_api.full_node.blockchain.receive_block(
            last_block, None)
        assert error is None
        assert result is ReceiveBlockResult.NEW_PEAK
Exemplo n.º 27
0
    async def test1(self, two_nodes):
        num_blocks = 10
        test_rpc_port = uint16(21522)
        full_node_1, full_node_2, server_1, server_2 = two_nodes
        blocks = bt.get_consecutive_blocks(test_constants, num_blocks, [], 10)

        for i in range(1, num_blocks):
            async for _ in full_node_1.respond_unfinished_block(
                full_node_protocol.RespondUnfinishedBlock(blocks[i])
            ):
                pass
            async for _ in full_node_1.respond_block(
                full_node_protocol.RespondBlock(blocks[i])
            ):
                pass

        def stop_node_cb():
            full_node_1._close()
            server_1.close_all()

        rpc_cleanup = await start_full_node_rpc_server(
            full_node_1, stop_node_cb, test_rpc_port
        )

        try:
            client = await FullNodeRpcClient.create(test_rpc_port)
            state = await client.get_blockchain_state()
            assert state["lca"].header_hash is not None
            assert not state["sync"]["sync_mode"]
            assert len(state["tips"]) > 0
            assert state["difficulty"] > 0
            assert state["ips"] > 0
            assert state["min_iters"] > 0

            block = await client.get_block(state["lca"].header_hash)
            assert block == blocks[7]
            assert (await client.get_block(bytes([1] * 32))) is None

            unf_block_headers = await client.get_unfinished_block_headers(5)
            assert len(unf_block_headers) == 1
            assert unf_block_headers[0] == blocks[5].header

            header = await client.get_header(state["lca"].header_hash)
            assert header == blocks[7].header

            assert (await client.get_header_by_height(7)) == blocks[7].header

            assert (await client.get_header_by_height(100)) is None

            coins = await client.get_unspent_coins(
                blocks[-1].header.data.coinbase.puzzle_hash, blocks[-1].header_hash
            )
            assert len(coins) == 16
            coins_lca = await client.get_unspent_coins(
                blocks[-1].header.data.coinbase.puzzle_hash
            )
            assert len(coins_lca) == 16

            assert len(await client.get_connections()) == 0

            await client.open_connection("localhost", server_2._port)
            await asyncio.sleep(2)
            connections = await client.get_connections()
            assert len(connections) == 1

            await client.close_connection(connections[0]["node_id"])
            assert len(await client.get_connections()) == 0

            await asyncio.sleep(2)  # Allow server to start
        except AssertionError:
            # Checks that the RPC manages to stop the node
            client.close()
            await client.await_closed()
            await rpc_cleanup()
            raise

        client.close()
        await client.await_closed()
        await rpc_cleanup()
Exemplo n.º 28
0
    async def test_basic_reorg(self):
        initial_block_count = 20
        reorg_length = 15
        blocks = bt.get_consecutive_blocks(test_constants, initial_block_count,
                                           [], 9)
        db_path = Path("blockchain_test.db")
        if db_path.exists():
            db_path.unlink()
        connection = await aiosqlite.connect(db_path)
        coin_store = await CoinStore.create(connection)
        store = await BlockStore.create(connection)
        b: Blockchain = await Blockchain.create(coin_store, store,
                                                test_constants)
        try:

            for i in range(1, len(blocks)):
                await b.receive_block(blocks[i])
            assert b.get_current_tips()[0].height == initial_block_count

            for c, block in enumerate(blocks):
                unspent = await coin_store.get_coin_record(
                    block.get_coinbase().name(), block.header)
                unspent_fee = await coin_store.get_coin_record(
                    block.get_fees_coin().name(), block.header)
                assert unspent.spent == 0
                assert unspent_fee.spent == 0
                assert unspent.confirmed_block_index == block.height
                assert unspent.spent_block_index == 0
                assert unspent.name == block.get_coinbase().name()
                assert unspent_fee.name == block.get_fees_coin().name()

            blocks_reorg_chain = bt.get_consecutive_blocks(
                test_constants,
                reorg_length,
                blocks[:initial_block_count - 10],
                9,
                b"1",
            )

            for i in range(1, len(blocks_reorg_chain)):
                reorg_block = blocks_reorg_chain[i]
                result, removed, error_code = await b.receive_block(reorg_block
                                                                    )
                if reorg_block.height < initial_block_count - 10:
                    assert result == ReceiveBlockResult.ALREADY_HAVE_BLOCK
                elif reorg_block.height < initial_block_count - 1:
                    assert result == ReceiveBlockResult.ADDED_AS_ORPHAN
                elif reorg_block.height >= initial_block_count:
                    assert result == ReceiveBlockResult.ADDED_TO_HEAD
                    unspent = await coin_store.get_coin_record(
                        reorg_block.get_coinbase().name(), reorg_block.header)
                    assert unspent.name == reorg_block.get_coinbase().name()
                    assert unspent.confirmed_block_index == reorg_block.height
                    assert unspent.spent == 0
                    assert unspent.spent_block_index == 0
                assert error_code is None
            assert (b.get_current_tips()[0].height == initial_block_count -
                    10 + reorg_length - 1)
        except Exception as e:
            await connection.close()
            Path("blockchain_test.db").unlink()
            b.shut_down()
            raise e

        await connection.close()
        Path("blockchain_test.db").unlink()
        b.shut_down()
Exemplo n.º 29
0
    async def test_assert_fee_condition(self, two_nodes):

        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        # Farm blocks
        blocks = bt.get_consecutive_blocks(
            num_blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            guarantee_transaction_block=True)
        full_node_api_1, full_node_api_2, server_1, server_2 = two_nodes
        full_node_1 = full_node_api_1.full_node

        for block in blocks:
            await full_node_api_1.full_node.respond_block(
                full_node_protocol.RespondBlock(block))

        # Coinbase that gets spent
        block1 = blocks[2]
        spend_coin_block_1 = None
        for coin in list(block1.get_included_reward_coins()):
            if coin.puzzle_hash == coinbase_puzzlehash:
                spend_coin_block_1 = coin

        # This condition requires fee to be 10 mojo
        cvp_fee = ConditionWithArgs(ConditionOpcode.RESERVE_FEE,
                                    [int_to_bytes(10)])
        # This spend bundle has 9 mojo as fee
        block1_dic_bad = {cvp_fee.opcode: [cvp_fee]}
        block1_dic_good = {cvp_fee.opcode: [cvp_fee]}
        block1_spend_bundle_bad = wallet_a.generate_signed_transaction(
            1000,
            receiver_puzzlehash,
            spend_coin_block_1,
            block1_dic_bad,
            fee=9)
        block1_spend_bundle_good = wallet_a.generate_signed_transaction(
            1000,
            receiver_puzzlehash,
            spend_coin_block_1,
            block1_dic_good,
            fee=10)
        log.warning(block1_spend_bundle_good.additions())
        log.warning(f"Spend bundle fees: {block1_spend_bundle_good.fees()}")
        invalid_new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=block1_spend_bundle_bad,
            guarantee_transaction_block=True,
        )

        res, err, _ = await full_node_1.blockchain.receive_block(
            invalid_new_blocks[-1])
        assert res == ReceiveBlockResult.INVALID_BLOCK
        assert err == Err.RESERVE_FEE_CONDITION_FAILED

        valid_new_blocks = bt.get_consecutive_blocks(
            1,
            blocks,
            farmer_reward_puzzle_hash=coinbase_puzzlehash,
            transaction_data=block1_spend_bundle_good,
            guarantee_transaction_block=True,
        )
        res, err, _ = await full_node_1.blockchain.receive_block(
            valid_new_blocks[-1])
        assert err is None
        assert res == ReceiveBlockResult.NEW_PEAK
    async def test_assert_block_age_exceeds(self, two_nodes):

        num_blocks = 10
        wallet_a = WALLET_A
        coinbase_puzzlehash = WALLET_A_PUZZLE_HASHES[0]
        receiver_puzzlehash = BURN_PUZZLE_HASH

        # Farm blocks
        blocks = bt.get_consecutive_blocks(test_constants, num_blocks, [], 10,
                                           b"", coinbase_puzzlehash)
        full_node_1, full_node_2, server_1, server_2 = two_nodes

        for block in blocks:
            async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(block)):
                pass

        # Coinbase that gets spent
        block1 = blocks[1]

        # This condition requires block1 coinbase to be spent more than 10 block after it was farmed
        # block index has to be greater than (1 + 10 = 11)
        block1_cvp = ConditionVarPair(ConditionOpcode.ASSERT_BLOCK_AGE_EXCEEDS,
                                      int_to_bytes(10), None)
        block1_dic = {block1_cvp.opcode: [block1_cvp]}
        block1_spend_bundle = wallet_a.generate_signed_transaction(
            1000, receiver_puzzlehash, block1.get_coinbase(), block1_dic)

        # program that will be sent to early
        assert block1_spend_bundle is not None
        program = best_solution_program(block1_spend_bundle)
        aggsig = block1_spend_bundle.aggregated_signature

        # Create another block that includes our transaction
        dic_h = {11: (program, aggsig)}
        invalid_new_blocks = bt.get_consecutive_blocks(test_constants, 1,
                                                       blocks, 10, b"",
                                                       coinbase_puzzlehash,
                                                       dic_h)

        # Try to validate that block at index 11
        next_block = invalid_new_blocks[11]
        error = await full_node_1.blockchain._validate_transactions(
            next_block,
            next_block.get_fees_coin().amount)

        assert error is Err.ASSERT_BLOCK_AGE_EXCEEDS_FAILED

        dic_h = {12: (program, aggsig)}
        valid_new_blocks = bt.get_consecutive_blocks(test_constants, 2,
                                                     blocks[:11], 10, b"",
                                                     coinbase_puzzlehash,
                                                     dic_h)

        for block in valid_new_blocks:
            async for _ in full_node_1.respond_block(
                    full_node_protocol.RespondBlock(block)):
                pass

        # Try to validate that block at index 12
        next_block = valid_new_blocks[12]

        error = await full_node_1.blockchain._validate_transactions(
            next_block,
            next_block.get_fees_coin().amount)

        assert error is None