Ejemplo n.º 1
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    def __init__(self, state: BaseState, message: Message,
                 transaction_context: BaseTransactionContext) -> None:

        self.state = state
        self.msg = message
        self.transaction_context = transaction_context

        self._memory = Memory()
        self._stack = Stack()
        self._gas_meter = GasMeter(message.gas)

        self.children = []
        self.accounts_to_delete = {}
        self._log_entries = []

        code = message.code
        self.code = CodeStream(code)
Ejemplo n.º 2
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 def get_gas_meter(self) -> GasMeter:
     return GasMeter(self.msg.gas, allow_negative_refund_strategy)
Ejemplo n.º 3
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 def get_gas_meter(self) -> GasMeter:
     return GasMeter(self.msg.gas)
Ejemplo n.º 4
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def test_instantiation_invalid_value(value):
    with pytest.raises(ValidationError):
        GasMeter(value)
Ejemplo n.º 5
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def test_start_gas_on_instantiation(value):
    meter = GasMeter(value)
    assert meter.start_gas == value
    assert meter.gas_remaining == value
    assert meter.gas_refunded == 0
Ejemplo n.º 6
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def gas_meter(request):
    return GasMeter(request.param)
Ejemplo n.º 7
0
class BaseComputation(Configurable, ABC):
    """
    The base class for all execution computations.

      .. note::

        Each :class:`~eth.vm.computation.BaseComputation` class must be configured with:

        ``opcodes``: A mapping from the opcode integer value to the logic function for the opcode.

        ``_precompiles``: A mapping of contract address to the precompile function for execution
        of precompiled contracts.
    """
    state = None
    msg = None
    transaction_context = None

    _memory = None
    _stack = None
    _gas_meter = None

    code = None

    children = None  # type: List[BaseComputation]

    _output = b''
    return_data = b''
    _error = None  # type: VMError

    _log_entries = None  # type: List[Tuple[int, bytes, List[int], bytes]]
    accounts_to_delete = None  # type: Dict[bytes, bytes]

    # VM configuration
    opcodes = None  # type: Dict[int, Opcode]
    _precompiles = None  # type: Dict[bytes, Callable[['BaseComputation'], Any]]

    logger = cast(TraceLogger,
                  logging.getLogger('eth.vm.computation.Computation'))

    def __init__(self, state: BaseState, message: Message,
                 transaction_context: BaseTransactionContext) -> None:

        self.state = state
        self.msg = message
        self.transaction_context = transaction_context

        self._memory = Memory()
        self._stack = Stack()
        self._gas_meter = GasMeter(message.gas)

        self.children = []
        self.accounts_to_delete = {}
        self._log_entries = []

        code = message.code
        self.code = CodeStream(code)

    #
    # Convenience
    #
    @property
    def is_origin_computation(self) -> bool:
        """
        Return ``True`` if this computation is the outermost computation at ``depth == 0``.
        """
        return self.msg.sender == self.transaction_context.origin

    @property
    def is_success(self) -> bool:
        """
        Return ``True`` if the computation did not result in an error.
        """
        return self._error is None

    @property
    def is_error(self) -> bool:
        """
        Return ``True`` if the computation resulted in an error.
        """
        return not self.is_success

    @property
    def should_burn_gas(self) -> bool:
        """
        Return ``True`` if the remaining gas should be burned.
        """
        return self.is_error and self._error.burns_gas

    @property
    def should_return_gas(self) -> bool:
        """
        Return ``True`` if the remaining gas should be returned.
        """
        return not self.should_burn_gas

    @property
    def should_erase_return_data(self) -> bool:
        """
        Return ``True`` if the return data should be zerod out due to an error.
        """
        return self.is_error and self._error.erases_return_data

    #
    # Execution
    #
    def prepare_child_message(self, gas: int, to: bytes, value: int,
                              data: bytes, code: bytes,
                              **kwargs: Any) -> Message:
        """
        Helper method for creating a child computation.
        """
        kwargs.setdefault('sender', self.msg.storage_address)

        child_message = Message(gas=gas,
                                to=to,
                                value=value,
                                data=data,
                                code=code,
                                depth=self.msg.depth + 1,
                                **kwargs)
        return child_message

    #
    # Memory Management
    #
    def extend_memory(self, start_position: int, size: int) -> None:
        """
        Extend the size of the memory to be at minimum ``start_position + size``
        bytes in length.  Raise `eth.exceptions.OutOfGas` if there is not enough
        gas to pay for extending the memory.
        """
        validate_uint256(start_position, title="Memory start position")
        validate_uint256(size, title="Memory size")

        before_size = ceil32(len(self._memory))
        after_size = ceil32(start_position + size)

        before_cost = memory_gas_cost(before_size)
        after_cost = memory_gas_cost(after_size)

        self.logger.trace(
            "MEMORY: size (%s -> %s) | cost (%s -> %s)",
            before_size,
            after_size,
            before_cost,
            after_cost,
        )

        if size:
            if before_cost < after_cost:
                gas_fee = after_cost - before_cost
                self._gas_meter.consume_gas(gas_fee,
                                            reason=" ".join((
                                                "Expanding memory",
                                                str(before_size),
                                                "->",
                                                str(after_size),
                                            )))

            self._memory.extend(start_position, size)

    def memory_write(self, start_position: int, size: int,
                     value: bytes) -> None:
        """
        Write ``value`` to memory at ``start_position``. Require that ``len(value) == size``.
        """
        return self._memory.write(start_position, size, value)

    def memory_read(self, start_position: int, size: int) -> bytes:
        """
        Read and return ``size`` bytes from memory starting at ``start_position``.
        """
        return self._memory.read(start_position, size)

    def consume_gas(self, amount: int, reason: str) -> None:
        """
        Consume ``amount`` of gas from the remaining gas.
        Raise `eth.exceptions.OutOfGas` if there is not enough gas remaining.
        """
        return self._gas_meter.consume_gas(amount, reason)

    def return_gas(self, amount: int) -> None:
        """
        Return ``amount`` of gas to the available gas pool.
        """
        return self._gas_meter.return_gas(amount)

    def refund_gas(self, amount: int) -> None:
        """
        Add ``amount`` of gas to the pool of gas marked to be refunded.
        """
        return self._gas_meter.refund_gas(amount)

    def stack_pop(self, num_items=1, type_hint=None):
        """
        Pop and return a number of items equal to ``num_items`` from the stack.
        ``type_hint`` can be either ``'uint256'`` or ``'bytes'``.  The return value
        will be an ``int`` or ``bytes`` type depending on the value provided for
        the ``type_hint``.

        Raise `eth.exceptions.InsufficientStack` if there are not enough items on
        the stack.
        """
        return self._stack.pop(num_items, type_hint)

    def stack_push(self, value):
        """
        Push ``value`` onto the stack.

        Raise `eth.exceptions.StackDepthLimit` if the stack is full.
        """
        return self._stack.push(value)

    def stack_swap(self, position):
        """
        Swap the item on the top of the stack with the item at ``position``.
        """
        return self._stack.swap(position)

    def stack_dup(self, position):
        """
        Duplicate the stack item at ``position`` and pushes it onto the stack.
        """
        return self._stack.dup(position)

    #
    # Computed properties.
    #
    @property
    def output(self) -> bytes:
        """
        Get the return value of the computation.
        """
        if self.should_erase_return_data:
            return b''
        else:
            return self._output

    @output.setter
    def output(self, value: bytes) -> None:
        """
        Set the return value of the computation.
        """
        validate_is_bytes(value)
        self._output = value

    #
    # Runtime operations
    #
    def apply_child_computation(self, child_msg: Message) -> 'BaseComputation':
        """
        Apply the vm message ``child_msg`` as a child computation.
        """
        child_computation = self.generate_child_computation(child_msg)
        self.add_child_computation(child_computation)
        return child_computation

    def generate_child_computation(self,
                                   child_msg: Message) -> 'BaseComputation':
        if child_msg.is_create:
            child_computation = self.__class__(
                self.state,
                child_msg,
                self.transaction_context,
            ).apply_create_message()
        else:
            child_computation = self.__class__(
                self.state,
                child_msg,
                self.transaction_context,
            ).apply_message()
        return child_computation

    def add_child_computation(self,
                              child_computation: 'BaseComputation') -> None:
        if child_computation.is_error:
            if child_computation.msg.is_create:
                self.return_data = child_computation.output
            elif child_computation.should_burn_gas:
                self.return_data = b''
            else:
                self.return_data = child_computation.output
        else:
            if child_computation.msg.is_create:
                self.return_data = b''
            else:
                self.return_data = child_computation.output
        self.children.append(child_computation)

    def register_account_for_deletion(self, beneficiary: Address) -> None:
        validate_canonical_address(beneficiary,
                                   title="Self destruct beneficiary address")

        if self.msg.storage_address in self.accounts_to_delete:
            raise ValueError(
                "Invariant.  Should be impossible for an account to be "
                "registered for deletion multiple times")
        self.accounts_to_delete[self.msg.storage_address] = beneficiary

    def add_log_entry(self, account: Address, topics: List[int],
                      data: bytes) -> None:
        validate_canonical_address(account, title="Log entry address")
        for topic in topics:
            validate_uint256(topic, title="Log entry topic")
        validate_is_bytes(data, title="Log entry data")
        self._log_entries.append(
            (self.transaction_context.get_next_log_counter(), account, topics,
             data))

    #
    # Getters
    #
    def get_accounts_for_deletion(self) -> Tuple[Tuple[bytes, bytes], ...]:
        if self.is_error:
            return tuple()
        else:
            return tuple(
                dict(
                    itertools.chain(
                        self.accounts_to_delete.items(),
                        *(child.get_accounts_for_deletion()
                          for child in self.children))).items())

    def _get_log_entries(self) -> List[Tuple[int, bytes, List[int], bytes]]:
        """
        Return the log entries for this computation and its children.

        They are sorted in the same order they were emitted during the transaction processing, and
        include the sequential counter as the first element of the tuple representing every entry.
        """
        if self.is_error:
            return []
        else:
            return sorted(
                itertools.chain(
                    self._log_entries,
                    *(child._get_log_entries() for child in self.children)))

    def get_log_entries(self) -> Tuple[Tuple[bytes, List[int], bytes], ...]:
        return tuple(log[1:] for log in self._get_log_entries())

    def get_gas_refund(self) -> int:
        if self.is_error:
            return 0
        else:
            return self._gas_meter.gas_refunded + sum(c.get_gas_refund()
                                                      for c in self.children)

    def get_gas_used(self) -> int:
        if self.should_burn_gas:
            return self.msg.gas
        else:
            return max(
                0,
                self.msg.gas - self._gas_meter.gas_remaining,
            )

    def get_gas_remaining(self) -> int:
        if self.should_burn_gas:
            return 0
        else:
            return self._gas_meter.gas_remaining

    #
    # Context Manager API
    #
    def __enter__(self) -> 'BaseComputation':
        self.logger.trace(
            ("COMPUTATION STARTING: gas: %s | from: %s | to: %s | value: %s "
             "| depth %s | static: %s"),
            self.msg.gas,
            encode_hex(self.msg.sender),
            encode_hex(self.msg.to),
            self.msg.value,
            self.msg.depth,
            "y" if self.msg.is_static else "n",
        )

        return self

    def __exit__(self, exc_type: None, exc_value: None,
                 traceback: None) -> None:
        if exc_value and isinstance(exc_value, VMError):
            self.logger.trace(
                ("COMPUTATION ERROR: gas: %s | from: %s | to: %s | value: %s | "
                 "depth: %s | static: %s | error: %s"),
                self.msg.gas,
                encode_hex(self.msg.sender),
                encode_hex(self.msg.to),
                self.msg.value,
                self.msg.depth,
                "y" if self.msg.is_static else "n",
                exc_value,
            )
            self._error = exc_value
            if self.should_burn_gas:
                self.consume_gas(
                    self._gas_meter.gas_remaining,
                    reason=" ".join((
                        "Zeroing gas due to VM Exception:",
                        str(exc_value),
                    )),
                )

            # suppress VM exceptions
            return True
        elif exc_type is None:
            self.logger.trace(
                ("COMPUTATION SUCCESS: from: %s | to: %s | value: %s | "
                 "depth: %s | static: %s | gas-used: %s | gas-remaining: %s"),
                encode_hex(self.msg.sender),
                encode_hex(self.msg.to),
                self.msg.value,
                self.msg.depth,
                "y" if self.msg.is_static else "n",
                self.msg.gas - self._gas_meter.gas_remaining,
                self._gas_meter.gas_remaining,
            )

    #
    # State Transition
    #
    @abstractmethod
    def apply_message(self) -> 'BaseComputation':
        """
        Execution of an VM message.
        """
        raise NotImplementedError("Must be implemented by subclasses")

    @abstractmethod
    def apply_create_message(self) -> 'BaseComputation':
        """
        Execution of an VM message to create a new contract.
        """
        raise NotImplementedError("Must be implemented by subclasses")

    @classmethod
    def apply_computation(
            cls, state: BaseState, message: Message,
            transaction_context: BaseTransactionContext) -> 'BaseComputation':
        """
        Perform the computation that would be triggered by the VM message.
        """
        with cls(state, message, transaction_context) as computation:
            # Early exit on pre-compiles
            if message.code_address in computation.precompiles:
                computation.precompiles[message.code_address](computation)
                return computation

            for opcode in computation.code:
                opcode_fn = computation.get_opcode_fn(opcode)

                computation.logger.trace(
                    "OPCODE: 0x%x (%s) | pc: %s",
                    opcode,
                    opcode_fn.mnemonic,
                    max(0, computation.code.pc - 1),
                )

                try:
                    opcode_fn(computation=computation)
                except Halt:
                    break
        return computation

    #
    # Opcode API
    #
    @property
    def precompiles(self) -> Dict[bytes, Callable[['BaseComputation'], Any]]:
        if self._precompiles is None:
            return dict()
        else:
            return self._precompiles

    def get_opcode_fn(self, opcode):
        try:
            return self.opcodes[opcode]
        except KeyError:
            return InvalidOpcode(opcode)