Exemplo n.º 1
0
class LookupFeedback(AbstractFeedback, Initializable):
    """A feedback brick for the case when readout are integers.

    Stores and retrieves distributed representations of integers.

    Notes
    -----
    Currently works only with lazy initialization (can not be initialized
    with a single constructor call).

    """
    def __init__(self, num_outputs=None, feedback_dim=None, **kwargs):
        super(LookupFeedback, self).__init__(**kwargs)
        self.num_outputs = num_outputs
        self.feedback_dim = feedback_dim

        self.lookup = LookupTable(num_outputs,
                                  feedback_dim,
                                  weights_init=self.weights_init)
        self.children = [self.lookup]

    def _push_allocation_config(self):
        self.lookup.length = self.num_outputs
        self.lookup.dim = self.feedback_dim

    @application
    def feedback(self, outputs):
        assert self.output_dim == 0
        return self.lookup.lookup(outputs)

    def get_dim(self, name):
        if name == 'feedback':
            return self.feedback_dim
        return super(LookupFeedback, self).get_dim(name)
Exemplo n.º 2
0
class LookupFeedback(AbstractFeedback, Initializeable):
    """A feedback brick for the case when readout are integers.

    Stores and retrieves distributed representations of integers.

    Notes
    -----
        Currently works only with lazy initialization
        (can not be initialized with a single constructor call).

    """
    def __init__(self, num_outputs=None, feedback_dim=None, **kwargs):
        super(LookupFeedback, self).__init__(**kwargs)
        update_instance(self, locals())

        self.lookup = LookupTable(num_outputs, feedback_dim,
                                  kwargs.get("weights_init"))
        self.children = [self.lookup]

    def _push_allocation_config(self):
        self.lookup.length = self.num_outputs
        self.lookup.dim = self.feedback_dim

    @application
    def feedback(self, outputs, **kwargs):
        assert self.output_dim == 0
        return self.lookup.lookup(outputs)

    def get_dim(self, name):
        if name == 'feedback':
            return self.feedback_dim
        return super(LookupFeedback, self).get_dim(name)
Exemplo n.º 3
0
def test_lookup_table():
    lt = LookupTable(5, 3)
    lt.allocate()

    lt.W.set_value(numpy.arange(15).reshape(5, 3).astype(floatX))

    x = tensor.lmatrix("x")
    y = lt.lookup(x)
    f = theano.function([x], [y])

    x_val = [[1, 2], [0, 3]]
    desired = numpy.array([[[3, 4, 5], [6, 7, 8]], [[0, 1, 2], [9, 10, 11]]],
                          dtype=floatX)
    assert_equal(f(x_val)[0], desired)
Exemplo n.º 4
0
def main(mode, save_path, num_batches, from_dump):
    if mode == "train":
        # Experiment configuration
        dimension = 100
        readout_dimension = len(char2code)

        # Data processing pipeline
        data_stream = DataStreamMapping(
            mapping=lambda data: tuple(array.T for array in data),
            data_stream=PaddingDataStream(
                BatchDataStream(
                    iteration_scheme=ConstantScheme(10),
                    data_stream=DataStreamMapping(
                        mapping=reverse_words,
                        add_sources=("targets", ),
                        data_stream=DataStreamFilter(
                            predicate=lambda data: len(data[0]) <= 100,
                            data_stream=OneBillionWord(
                                "training", [99],
                                char2code,
                                level="character",
                                preprocess=str.lower).get_default_stream())))))

        # Build the model
        chars = tensor.lmatrix("features")
        chars_mask = tensor.matrix("features_mask")
        targets = tensor.lmatrix("targets")
        targets_mask = tensor.matrix("targets_mask")

        encoder = Bidirectional(GatedRecurrent(dim=dimension,
                                               activation=Tanh()),
                                weights_init=Orthogonal())
        encoder.initialize()
        fork = Fork([
            name
            for name in encoder.prototype.apply.sequences if name != 'mask'
        ],
                    weights_init=IsotropicGaussian(0.1),
                    biases_init=Constant(0))
        fork.input_dim = dimension
        fork.fork_dims = {name: dimension for name in fork.fork_names}
        fork.initialize()
        lookup = LookupTable(readout_dimension,
                             dimension,
                             weights_init=IsotropicGaussian(0.1))
        lookup.initialize()
        transition = Transition(activation=Tanh(),
                                dim=dimension,
                                attended_dim=2 * dimension,
                                name="transition")
        attention = SequenceContentAttention(
            state_names=transition.apply.states,
            match_dim=dimension,
            name="attention")
        readout = LinearReadout(readout_dim=readout_dimension,
                                source_names=["states"],
                                emitter=SoftmaxEmitter(name="emitter"),
                                feedbacker=LookupFeedback(
                                    readout_dimension, dimension),
                                name="readout")
        generator = SequenceGenerator(readout=readout,
                                      transition=transition,
                                      attention=attention,
                                      weights_init=IsotropicGaussian(0.1),
                                      biases_init=Constant(0),
                                      name="generator")
        generator.push_initialization_config()
        transition.weights_init = Orthogonal()
        generator.initialize()
        bricks = [encoder, fork, lookup, generator]

        # Give an idea of what's going on
        params = Selector(bricks).get_params()
        logger.info("Parameters:\n" +
                    pprint.pformat([(key, value.get_value().shape)
                                    for key, value in params.items()],
                                   width=120))

        # Build the cost computation graph
        batch_cost = generator.cost(
            targets,
            targets_mask,
            attended=encoder.apply(**dict_union(fork.apply(
                lookup.lookup(chars), return_dict=True),
                                                mask=chars_mask)),
            attended_mask=chars_mask).sum()
        batch_size = named_copy(chars.shape[1], "batch_size")
        cost = aggregation.mean(batch_cost, batch_size)
        cost.name = "sequence_log_likelihood"
        logger.info("Cost graph is built")

        # Fetch variables useful for debugging
        max_length = named_copy(chars.shape[0], "max_length")
        cost_per_character = named_copy(
            aggregation.mean(batch_cost, batch_size * max_length),
            "character_log_likelihood")
        cg = ComputationGraph(cost)
        energies = unpack(VariableFilter(application=readout.readout,
                                         name="output")(cg.variables),
                          singleton=True)
        min_energy = named_copy(energies.min(), "min_energy")
        max_energy = named_copy(energies.max(), "max_energy")
        (activations, ) = VariableFilter(
            application=generator.transition.apply,
            name="states")(cg.variables)
        mean_activation = named_copy(activations.mean(), "mean_activation")

        # Define the training algorithm.
        algorithm = GradientDescent(cost=cost,
                                    step_rule=CompositeRule([
                                        GradientClipping(10.0),
                                        SteepestDescent(0.01)
                                    ]))

        observables = [
            cost, min_energy, max_energy, mean_activation, batch_size,
            max_length, cost_per_character, algorithm.total_step_norm,
            algorithm.total_gradient_norm
        ]
        for name, param in params.items():
            observables.append(named_copy(param.norm(2), name + "_norm"))
            observables.append(
                named_copy(algorithm.gradients[param].norm(2),
                           name + "_grad_norm"))

        main_loop = MainLoop(
            model=bricks,
            data_stream=data_stream,
            algorithm=algorithm,
            extensions=([LoadFromDump(from_dump)] if from_dump else []) + [
                Timing(),
                TrainingDataMonitoring(observables, after_every_batch=True),
                TrainingDataMonitoring(
                    observables, prefix="average", every_n_batches=10),
                FinishAfter(after_n_batches=num_batches).add_condition(
                    "after_batch", lambda log: math.isnan(
                        log.current_row.total_gradient_norm)),
                Plot(os.path.basename(save_path),
                     [["average_" + cost.name],
                      ["average_" + cost_per_character.name]],
                     every_n_batches=10),
                SerializeMainLoop(save_path,
                                  every_n_batches=500,
                                  save_separately=["model", "log"]),
                Printing(every_n_batches=1)
            ])
        main_loop.run()
    elif mode == "test":
        with open(save_path, "rb") as source:
            encoder, fork, lookup, generator = dill.load(source)
        logger.info("Model is loaded")
        chars = tensor.lmatrix("features")
        generated = generator.generate(
            n_steps=3 * chars.shape[0],
            batch_size=chars.shape[1],
            attended=encoder.apply(**dict_union(
                fork.apply(lookup.lookup(chars), return_dict=True))),
            attended_mask=tensor.ones(chars.shape))
        sample_function = ComputationGraph(generated).get_theano_function()
        logging.info("Sampling function is compiled")

        while True:
            # Python 2-3 compatibility
            line = input("Enter a sentence\n")
            batch_size = int(input("Enter a number of samples\n"))
            encoded_input = [
                char2code.get(char, char2code["<UNK>"])
                for char in line.lower().strip()
            ]
            encoded_input = ([char2code['<S>']] + encoded_input +
                             [char2code['</S>']])
            print("Encoder input:", encoded_input)
            target = reverse_words((encoded_input, ))[0]
            print("Target: ", target)
            states, samples, glimpses, weights, costs = sample_function(
                numpy.repeat(numpy.array(encoded_input)[:, None],
                             batch_size,
                             axis=1))

            messages = []
            for i in range(samples.shape[1]):
                sample = list(samples[:, i])
                try:
                    true_length = sample.index(char2code['</S>']) + 1
                except ValueError:
                    true_length = len(sample)
                sample = sample[:true_length]
                cost = costs[:true_length, i].sum()
                message = "({})".format(cost)
                message += "".join(code2char[code] for code in sample)
                if sample == target:
                    message += " CORRECT!"
                messages.append((cost, message))
            messages.sort(key=lambda tuple_: -tuple_[0])
            for _, message in messages:
                print(message)