def visualize_states(hidden_states, updates,
                     train_stream, valid_stream,
                     args):

    # Get all the hidden_states
    filter_states = VariableFilter(theano_name_regex="hidden_state_.*")
    all_states = filter_states(hidden_states)
    all_states = sorted(all_states, key=lambda var: var.name[-1])

    # Get all the hidden_cells
    filter_cells = VariableFilter(theano_name_regex="hidden_cells_.*")
    all_cells = filter_cells(hidden_states)
    all_cells = sorted(all_cells, key=lambda var: var.name[-1])

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(updates, 1,
                                           not(has_indices(args.dataset)))

    # Compile the function
    logger.info("The compilation of the function has started")
    if args.rnn_type == "lstm" and args.visualize_cells:
        compiled = theano.function(inputs=ComputationGraph(all_cells).inputs,
                                   outputs=all_cells,
                                   givens=givens, updates=f_updates,
                                   mode=Mode(optimizer='fast_compile'))
    else:
        compiled = theano.function(inputs=ComputationGraph(all_states).inputs,
                                   outputs=all_states,
                                   givens=givens, updates=f_updates,
                                   mode=Mode(optimizer='fast_compile'))

    # Plot the function
    plot("hidden_state", train_stream, compiled, args)
    def __init__(self, cost, generation_length, dataset,
                 initial_text_length, softmax_sampling,
                 updates, ploting_path=None,
                 interactive_mode=False, **kwargs):
        self.generation_length = generation_length
        self.init_length = initial_text_length
        self.dataset = dataset
        self.output_size = get_output_size(dataset)
        self.ploting_path = ploting_path
        self.softmax_sampling = softmax_sampling
        self.interactive_mode = interactive_mode
        self.has_indices = has_indices(dataset)
        super(TextGenerationExtension, self).__init__(**kwargs)

        # Get presoft and its computation graph
        filter_presoft = VariableFilter(theano_name="presoft")
        presoft = filter_presoft(ComputationGraph(cost).variables)
        cg = ComputationGraph(presoft)

        # Handle the theano shared variables that allow carrying the hidden
        # state
        givens, f_updates = carry_hidden_state(updates, 1,
                                               reset=not(self.has_indices))

        # Compile the theano function
        self.generate = theano.function(inputs=cg.inputs, outputs=presoft,
                                        givens=givens, updates=f_updates)
    def _compile(self, state_updates):
        """Compiles Theano functions.
        .. todo::
            The current compilation method does not account for updates
            attached to `ComputationGraph` elements. Compiling should
            be out-sourced to `ComputationGraph` to deal with it.
        """
        inputs = []
        outputs = []
        updates = None

        givens, f_updates = carry_hidden_state(state_updates,
                                               self.mini_batch_size,
                                               reset=not(has_indices(self.dataset)))

        if self.theano_buffer.accumulation_updates:
            updates = OrderedDict()
            updates.update(self.theano_buffer.accumulation_updates)
            if self.updates:
                updates.update(self.updates)
            inputs += self.theano_buffer.inputs
        inputs += self.monitored_quantities_buffer.inputs
        outputs = self.monitored_quantities_buffer.requires

        if inputs != []:
            self.unique_inputs = list(set(inputs))
            updates.update(f_updates)
            self._accumulate_fun = theano.function(self.unique_inputs,
                                                   outputs,
                                                   givens=givens,
                                                   updates=updates)
        else:
            self._accumulate_fun = None
def visualize_states(hidden_states, updates, train_stream, valid_stream, args):

    # Get all the hidden_states
    filter_states = VariableFilter(theano_name_regex="hidden_state_.*")
    all_states = filter_states(hidden_states)
    all_states = sorted(all_states, key=lambda var: var.name[-1])

    # Get all the hidden_cells
    filter_cells = VariableFilter(theano_name_regex="hidden_cells_.*")
    all_cells = filter_cells(hidden_states)
    all_cells = sorted(all_cells, key=lambda var: var.name[-1])

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(updates, 1,
                                           not (has_indices(args.dataset)))

    # Compile the function
    logger.info("The compilation of the function has started")
    if args.rnn_type == "lstm" and args.visualize_cells:
        compiled = theano.function(inputs=ComputationGraph(all_cells).inputs,
                                   outputs=all_cells,
                                   givens=givens,
                                   updates=f_updates,
                                   mode=Mode(optimizer='fast_compile'))
    else:
        compiled = theano.function(inputs=ComputationGraph(all_states).inputs,
                                   outputs=all_states,
                                   givens=givens,
                                   updates=f_updates,
                                   mode=Mode(optimizer='fast_compile'))

    # Plot the function
    plot("hidden_state", train_stream, compiled, args)
Exemple #5
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    def _compile(self, state_updates):
        """Compiles Theano functions.
        .. todo::
            The current compilation method does not account for updates
            attached to `ComputationGraph` elements. Compiling should
            be out-sourced to `ComputationGraph` to deal with it.
        """
        inputs = []
        outputs = []
        updates = None

        givens, f_updates = carry_hidden_state(
            state_updates,
            self.mini_batch_size,
            reset=not (has_indices(self.dataset)))

        if self.theano_buffer.accumulation_updates:
            updates = OrderedDict()
            updates.update(self.theano_buffer.accumulation_updates)
            if self.updates:
                updates.update(self.updates)
            inputs += self.theano_buffer.inputs
        inputs += self.monitored_quantities_buffer.inputs
        outputs = self.monitored_quantities_buffer.requires

        if inputs != []:
            self.unique_inputs = list(set(inputs))
            updates.update(f_updates)
            self._accumulate_fun = theano.function(self.unique_inputs,
                                                   outputs,
                                                   givens=givens,
                                                   updates=updates)
        else:
            self._accumulate_fun = None
def visualize_gates_soft(gate_values, hidden_states, updates,
                         train_stream, valid_stream,
                         args):

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(updates, 1,
                                           not(has_indices(args.dataset)))

    # Compile the function
    compiled = theano.function(inputs=ComputationGraph(gate_values).inputs,
                               outputs=gate_values,
                               givens=givens, updates=f_updates,
                               mode=Mode(optimizer='fast_compile'))

    plot("gates_soft", train_stream, compiled, args)
Exemple #7
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def visualize_gates_soft(gate_values, hidden_states, updates, train_stream,
                         valid_stream, args):

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(updates, 1,
                                           not (has_indices(args.dataset)))

    # Compile the function
    compiled = theano.function(inputs=ComputationGraph(gate_values).inputs,
                               outputs=gate_values,
                               givens=givens,
                               updates=f_updates,
                               mode=Mode(optimizer='fast_compile'))

    plot("gates_soft", train_stream, compiled, args)
    def __init__(self,
                 cost,
                 generation_length,
                 dataset,
                 initial_text_length,
                 softmax_sampling,
                 updates,
                 ploting_path=None,
                 interactive_mode=False,
                 **kwargs):
        self.generation_length = generation_length
        self.init_length = initial_text_length
        self.dataset = dataset
        self.output_size = get_output_size(dataset)
        self.ploting_path = ploting_path
        self.softmax_sampling = softmax_sampling
        self.interactive_mode = interactive_mode
        self.has_indices = has_indices(dataset)
        super(TextGenerationExtension, self).__init__(**kwargs)

        # Get presoft and its computation graph
        filter_presoft = VariableFilter(theano_name="presoft")
        presoft = filter_presoft(ComputationGraph(cost).variables)
        cg = ComputationGraph(presoft)

        # Handle the theano shared variables that allow carrying the hidden
        # state
        givens, f_updates = carry_hidden_state(updates,
                                               1,
                                               reset=not (self.has_indices))

        # Compile the theano function
        self.generate = theano.function(inputs=cg.inputs,
                                        outputs=presoft,
                                        givens=givens,
                                        updates=f_updates)
def visualize_generate(cost, hidden_states, updates,
                       train_stream, valid_stream,
                       args):

    use_indices = has_indices(args.dataset)
    output_size = get_output_size(args.dataset)

    # Get presoft and its computation graph
    filter_presoft = VariableFilter(theano_name="presoft")
    presoft = filter_presoft(ComputationGraph(cost).variables)[0]
    cg = ComputationGraph(presoft)

    # Handle the theano shared variables that allow carrying the hidden
    # state
    givens, f_updates = carry_hidden_state(updates, 1, reset=not(use_indices))

    if args.hide_all_except is not None:
        pass

    # Compile the theano function
    compiled = theano.function(inputs=cg.inputs, outputs=presoft,
                               givens=givens, updates=f_updates)

    epoch_iterator = train_stream.get_epoch_iterator()
    for num in range(10):
        all_ = next(epoch_iterator)
        all_sequence = all_[0][:, 0:1]
        targets = all_[1][:, 0:1]

        # In the case of characters and text
        if use_indices:
            init_ = all_sequence[:args.initial_text_length]

            # Time X Features
            probability_array = np.zeros((0, output_size))
            generated_text = init_

            for i in range(args.generated_text_lenght):
                presoft = compiled(generated_text)
                # Get the last value of presoft
                last_presoft = presoft[-1:, 0, :]

                # Compute the probability distribution
                probabilities = softmax(last_presoft)
                # Store it in the list
                probability_array = np.vstack([probability_array,
                                               probabilities])

                # Sample a character out of the probability distribution
                argmax = (args.softmax_sampling == 'argmax')
                last_output_sample = sample(probabilities, argmax)[:, None, :]

                # Concatenate the new value to the text
                generated_text = np.vstack(
                    [generated_text, last_output_sample])

                ploting_path = None
                if args.save_path is not None:
                    ploting_path = os.path.join(
                        args.save_path, 'prob_plot.png')

                # Convert with real characters
                whole_sentence = conv_into_char(
                    generated_text[:, 0], args.dataset)
                initial_sentence = whole_sentence[:init_.shape[0]]
                selected_sentence = whole_sentence[init_.shape[0]:]

                logger.info(''.join(initial_sentence) + '...')
                logger.info(''.join(whole_sentence))

                if ploting_path is not None:
                    probability_plot(probability_array, selected_sentence,
                                     args.dataset, ploting_path)

        # In the case of sine wave dataset for example
        else:
            presoft = compiled(all_sequence)

            time_plot = presoft.shape[0] - 1

            plt.plot(np.arange(time_plot),
                     targets[:time_plot, 0, 0],
                     label="target")
            plt.plot(np.arange(time_plot), presoft[:time_plot, 0, 0],
                     label="predicted")
            plt.legend()
            plt.grid(True)
            plt.show()
def visualize_gates_lstm(gate_values, hidden_states, updates,
                         train_stream, valid_stream,
                         args):

    in_gates = gate_values["in_gates"]
    out_gates = gate_values["out_gates"]
    forget_gates = gate_values["forget_gates"]

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(updates, 1,
                                           not(has_indices(args.dataset)))

    generate_in = theano.function(inputs=ComputationGraph(in_gates).inputs,
                                  outputs=in_gates,
                                  givens=givens,
                                  updates=f_updates,
                                  mode=Mode(optimizer='fast_compile'))
    generate_out = theano.function(inputs=ComputationGraph(out_gates).inputs,
                                   outputs=out_gates,
                                   givens=givens,
                                   updates=f_updates,
                                   mode=Mode(optimizer='fast_compile'))
    generate_forget = theano.function(inputs=ComputationGraph(forget_gates).inputs,
                                      outputs=forget_gates,
                                      givens=givens,
                                      updates=f_updates,
                                      mode=Mode(optimizer='fast_compile'))

    # Generate
    epoch_iterator = valid_stream.get_epoch_iterator()
    for num in range(10):
        init_ = next(epoch_iterator)[0][0: args.visualize_length, 0:1]

        last_output_in = generate_in(init_)
        last_output_out = generate_out(init_)
        last_output_forget = generate_forget(init_)
        layers = len(last_output_in)

        time = last_output_in[0].shape[0]
        if has_indices(args.dataset):
            ticks = tuple(conv_into_char(init_[:, 0], args.dataset))
        else:
            ticks = tuple(np.arange(time))

        for i in range(layers):

            plt.subplot(3, layers, 1 + i)
            plt.plot(np.arange(time), np.mean(
                np.abs(last_output_in[i][:, 0, :]), axis=1))
            plt.xticks(range(args.visualize_length), ticks)
            plt.grid(True)
            plt.title("in_gate of layer " + str(i))

            plt.subplot(3, layers, layers + 1 + i)
            plt.plot(np.arange(time), np.mean(
                np.abs(last_output_out[i][:, 0, :]), axis=1))
            plt.xticks(range(args.visualize_length), ticks)
            plt.grid(True)
            plt.title("out_gate of layer " + str(i))

            plt.subplot(3, layers, 2 * layers + 1 + i)
            plt.plot(np.arange(time), np.mean(
                np.abs(last_output_forget[i][:, 0, :]), axis=1))
            plt.xticks(range(args.visualize_length), ticks)
            plt.grid(True)
            plt.title("forget_gate of layer " + str(i))
        if args.local:
            plt.show()
        else:
            plt.savefig(
                args.save_path + "/visualize_gates_" + str(num) + ".png")
            logger.info("Figure \"visualize_gates_" + str(num) +
                        ".png\" saved at directory: " + args.save_path)
def visualize_generate(cost, hidden_states, updates,
                       train_stream, valid_stream,
                       args):

    use_indices = has_indices(args.dataset)
    output_size = get_output_size(args.dataset)

    # Get presoft and its computation graph
    filter_presoft = VariableFilter(theano_name="presoft")
    presoft = filter_presoft(ComputationGraph(cost).variables)[0]
    cg = ComputationGraph(presoft)

    # Handle the theano shared variables that allow carrying the hidden
    # state
    givens, f_updates = carry_hidden_state(updates, 1, reset=not(use_indices))

    # Compile the theano function
    compiled = theano.function(inputs=cg.inputs, outputs=presoft,
                               givens=givens, updates=f_updates)

    epoch_iterator = train_stream.get_epoch_iterator()
    for num in range(10):
        all_ = next(epoch_iterator)
        all_sequence = all_[0][:, 0:1]
        targets = all_[1][:, 0:1]

        # In the case of characters and text
        if use_indices:
            init_ = all_sequence[:args.initial_text_length]

            # Time X Features
            probability_array = np.zeros((0, output_size))
            generated_text = init_

            for i in range(args.generated_text_lenght):
                presoft = compiled(generated_text)
                # Get the last value of presoft
                last_presoft = presoft[-1:, 0, :]

                # Compute the probability distribution
                probabilities = softmax(last_presoft)
                # Store it in the list
                probability_array = np.vstack([probability_array,
                                               probabilities])

                # Sample a character out of the probability distribution
                argmax = (args.softmax_sampling == 'argmax')
                last_output_sample = sample(probabilities, argmax)[:, None, :]

                # Concatenate the new value to the text
                generated_text = np.vstack(
                    [generated_text, last_output_sample])

                ploting_path = None
                if args.save_path is not None:
                    ploting_path = os.path.join(
                        args.save_path, 'prob_plot.png')

                # Convert with real characters
                whole_sentence = conv_into_char(
                    generated_text[:, 0], args.dataset)
                initial_sentence = whole_sentence[:init_.shape[0]]
                selected_sentence = whole_sentence[init_.shape[0]:]

                logger.info(''.join(initial_sentence) + '...')
                logger.info(''.join(whole_sentence))

                if ploting_path is not None:
                    probability_plot(probability_array, selected_sentence,
                                     args.dataset, ploting_path)

        # In the case of sine wave dataset for example
        else:
            presoft = compiled(all_sequence)

            time_plot = presoft.shape[0] - 1

            plt.plot(np.arange(time_plot),
                     targets[:time_plot, 0, 0],
                     label="target")
            plt.plot(np.arange(time_plot), presoft[:time_plot, 0, 0],
                     label="predicted")
            plt.legend()
            plt.grid(True)
            plt.show()
def visualize_gradients(hidden_states, updates,
                        train_stream, valid_stream,
                        args):

    # Get all the hidden_states
    filter_states = VariableFilter(theano_name_regex="hidden_state_.*")
    all_states = filter_states(hidden_states)
    all_states = sorted(all_states, key=lambda var: var.name[-1])

    # Get all the hidden_cells
    filter_cells = VariableFilter(theano_name_regex="hidden_cell_.*")
    all_cells = filter_cells(hidden_states)
    all_cells = sorted(all_cells, key=lambda var: var.name[-1])

    # Get the variable on which we compute the gradients
    filter_pre_rnn = VariableFilter(theano_name_regex="pre_rnn.*")
    wrt = filter_pre_rnn(ComputationGraph(hidden_states).variables)
    wrt = sorted(wrt, key=lambda var: var.name[-1])
    len_wrt = len(wrt)

    # We have wrt = [pre_rnn] or [pre_rnn_0, pre_rnn_1, ...]

    # Assertion part
    assert len(all_states) == args.layers
    assert len(all_cells) == (args.layers * (args.rnn_type == "lstm"))
    if args.skip_connections:
        assert len_wrt == args.layers
    else:
        assert len_wrt == 1

    # Comupute the gradients of states or cells
    if args.rnn_type == "lstm" and args.visualize_cells:
        states = all_cells
    else:
        states = all_states

    logger.info("The computation of the gradients has started")
    gradients = []
    for i, state in enumerate(states):
        gradients.extend(
            tensor.grad(tensor.mean(tensor.abs_(
                state[-1, 0, :])), wrt[:i + 1]))
    # -1 indicates that gradient is gradient of the last time-step.c
    logger.info("The computation of the gradients is done")

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(updates, 1,
                                           reset=not(has_indices(args.dataset)))

    # Compile the function
    logger.info("The compilation of the function has started")
    compiled = theano.function(inputs=ComputationGraph(states).inputs,
                               outputs=gradients,
                               givens=givens, updates=f_updates,
                               mode=Mode(optimizer='fast_compile'))
    logger.info("The function has been compiled")

    # Generate
    epoch_iterator = train_stream.get_epoch_iterator()
    for num in range(10):
        init_ = next(epoch_iterator)[0][
            0: args.visualize_length, 0:1]

        # [layers * len_wrt] [Time, 1, Hidden_dim]
        gradients = compiled(init_)

        if args.skip_connections:
            assert len(gradients) == (args.layers * (args.layers + 1)) / 2
        else:
            assert len(gradients) == args.layers

        time = gradients[0].shape[0]
        if has_indices(args.dataset):
            ticks = tuple(conv_into_char(init_[:, 0], args.dataset))
        else:
            ticks = tuple(np.arange(time))

        # One row subplot for each variable wrt which we are computing
        # the gradients
        for var in range(len_wrt):
            plt.subplot(len_wrt, 1, var + 1)
            for d in range(args.layers - var):
                plt.plot(
                    np.arange(time),
                    np.mean(np.abs(gradients[d][:, 0, :]), axis=1),
                    label="layer " + str(d + var))
            plt.xticks(range(args.visualize_length), ticks)
            plt.grid(True)
            plt.yscale('log')
            axes = plt.gca()
            axes.set_ylim([5e-20, 5e-1])
            plt.title("gradients plotting w.r.t pre_rrn" + str(var))
            plt.legend()
        plt.tight_layout()
        if args.local:
            plt.show()
        else:
            plt.savefig(
                args.save_path + "/visualize_gradients_" + str(num) + ".png")
            logger.info("Figure \"visualize_gradients_" + str(num) +
                        ".png\" saved at directory: " + args.save_path)
def visualize_presoft(cost, hidden_states, updates,
                      train_stream, valid_stream,
                      args):

    filter_presoft = VariableFilter(theano_name="presoft")
    presoft = filter_presoft(ComputationGraph(cost).variables)[0]

    # Get all the hidden_states
    filter_states = VariableFilter(theano_name_regex="hidden_state_.*")
    all_states = filter_states(hidden_states)
    all_states = sorted(all_states, key=lambda var: var.name[-1])

    # Assertion part
    assert len(all_states) == args.layers

    logger.info("The computation of the gradients has started")
    gradients = []

    for i in range(args.visualize_length - args.context):
        gradients.extend(
            tensor.grad(tensor.mean(tensor.abs_(presoft[i, 0, :])),
                        all_states))
    logger.info("The computation of the gradients is done")

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(updates, 1,
                                           not(has_indices(args.dataset)))

    # Compile the function
    logger.info("The compilation of the function has started")
    compiled = theano.function(inputs=ComputationGraph(presoft).inputs,
                               outputs=gradients,
                               givens=givens, updates=f_updates,
                               mode=Mode(optimizer='fast_compile'))
    logger.info("The function has been compiled")

    # Generate
    epoch_iterator = train_stream.get_epoch_iterator()
    for num in range(10):
        init_ = next(epoch_iterator)[0][
            0: args.visualize_length, 0:1]

        hidden_state = compiled(init_)

        value_of_layer = {}
        for d in range(args.layers):
            value_of_layer[d] = 0

        for i in range(len(hidden_state) / args.layers):
            for d in range(args.layers):
                value_of_layer[d] += hidden_state[d + i * args.layers]

        time = hidden_state[0].shape[0]
        if has_indices(args.dataset):
            ticks = tuple(conv_into_char(init_[:, 0], args.dataset))
        else:
            ticks = tuple(np.arange(time))

        for d in range(args.layers):
            plt.plot(
                np.arange(time),
                np.mean(np.abs(value_of_layer[d][:, 0, :]), axis=1),
                label="Layer " + str(d))
        plt.xticks(range(args.visualize_length), ticks)
        plt.grid(True)
        plt.title("hidden_state_of_layer_" + str(d))
        plt.legend()
        plt.tight_layout()
        if args.local:
            plt.show()
        else:
            plt.savefig(
                args.save_path + "/visualize_presoft_" + str(num) + ".png")
            logger.info("Figure \"visualize_presoft_" + str(num) +
                        ".png\" saved at directory: " + args.save_path)
Exemple #14
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def visualize_presoft(cost, hidden_states, updates, train_stream, valid_stream,
                      args):

    filter_presoft = VariableFilter(theano_name="presoft")
    presoft = filter_presoft(ComputationGraph(cost).variables)[0]

    # Get all the hidden_states
    filter_states = VariableFilter(theano_name_regex="hidden_state_.*")
    all_states = filter_states(hidden_states)
    all_states = sorted(all_states, key=lambda var: var.name[-1])

    # Assertion part
    assert len(all_states) == args.layers

    logger.info("The computation of the gradients has started")
    gradients = []

    for i in range(args.visualize_length - args.context):
        gradients.extend(
            tensor.grad(tensor.mean(tensor.abs_(presoft[i, 0, :])),
                        all_states))
    logger.info("The computation of the gradients is done")

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(updates, 1,
                                           not (has_indices(args.dataset)))

    # Compile the function
    logger.info("The compilation of the function has started")
    compiled = theano.function(inputs=ComputationGraph(presoft).inputs,
                               outputs=gradients,
                               givens=givens,
                               updates=f_updates,
                               mode=Mode(optimizer='fast_compile'))
    logger.info("The function has been compiled")

    # Generate
    epoch_iterator = train_stream.get_epoch_iterator()
    for num in range(10):
        init_ = next(epoch_iterator)[0][0:args.visualize_length, 0:1]

        hidden_state = compiled(init_)

        value_of_layer = {}
        for d in range(args.layers):
            value_of_layer[d] = 0

        for i in range(len(hidden_state) / args.layers):
            for d in range(args.layers):
                value_of_layer[d] += hidden_state[d + i * args.layers]

        time = hidden_state[0].shape[0]
        if has_indices(args.dataset):
            ticks = tuple(conv_into_char(init_[:, 0], args.dataset))
        else:
            ticks = tuple(np.arange(time))

        for d in range(args.layers):
            plt.plot(np.arange(time),
                     np.mean(np.abs(value_of_layer[d][:, 0, :]), axis=1),
                     label="Layer " + str(d))
        plt.xticks(range(args.visualize_length), ticks)
        plt.grid(True)
        plt.title("hidden_state_of_layer_" + str(d))
        plt.legend()
        plt.tight_layout()
        if args.local:
            plt.show()
        else:
            plt.savefig(args.save_path + "/visualize_presoft_" + str(num) +
                        ".png")
            logger.info("Figure \"visualize_presoft_" + str(num) +
                        ".png\" saved at directory: " + args.save_path)
Exemple #15
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def visualize_gradients(hidden_states, updates, train_stream, valid_stream,
                        args):

    # Get all the hidden_states
    filter_states = VariableFilter(theano_name_regex="hidden_state_.*")
    all_states = filter_states(hidden_states)
    all_states = sorted(all_states, key=lambda var: var.name[-1])

    # Get all the hidden_cells
    filter_cells = VariableFilter(theano_name_regex="hidden_cell_.*")
    all_cells = filter_cells(hidden_states)
    all_cells = sorted(all_cells, key=lambda var: var.name[-1])

    # Get the variable on which we compute the gradients
    filter_pre_rnn = VariableFilter(theano_name_regex="pre_rnn.*")
    wrt = filter_pre_rnn(ComputationGraph(hidden_states).variables)
    wrt = sorted(wrt, key=lambda var: var.name[-1])
    len_wrt = len(wrt)

    # We have wrt = [pre_rnn] or [pre_rnn_0, pre_rnn_1, ...]

    # Assertion part
    assert len(all_states) == args.layers
    assert len(all_cells) == (args.layers * (args.rnn_type == "lstm"))
    if args.skip_connections:
        assert len_wrt == args.layers
    else:
        assert len_wrt == 1

    # Comupute the gradients of states or cells
    if args.rnn_type == "lstm" and args.visualize_cells:
        states = all_cells
    else:
        states = all_states

    logger.info("The computation of the gradients has started")
    gradients = []
    for i, state in enumerate(states):
        gradients.extend(
            tensor.grad(tensor.mean(tensor.abs_(state[-1, 0, :])),
                        wrt[:i + 1]))
    # -1 indicates that gradient is gradient of the last time-step.c
    logger.info("The computation of the gradients is done")

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(
        updates, 1, reset=not (has_indices(args.dataset)))

    # Compile the function
    logger.info("The compilation of the function has started")
    compiled = theano.function(inputs=ComputationGraph(states).inputs,
                               outputs=gradients,
                               givens=givens,
                               updates=f_updates,
                               mode=Mode(optimizer='fast_compile'))
    logger.info("The function has been compiled")

    # Generate
    epoch_iterator = train_stream.get_epoch_iterator()
    for num in range(10):
        init_ = next(epoch_iterator)[0][0:args.visualize_length, 0:1]

        # [layers * len_wrt] [Time, 1, Hidden_dim]
        gradients = compiled(init_)

        if args.skip_connections:
            assert len(gradients) == (args.layers * (args.layers + 1)) / 2
        else:
            assert len(gradients) == args.layers

        time = gradients[0].shape[0]
        if has_indices(args.dataset):
            ticks = tuple(conv_into_char(init_[:, 0], args.dataset))
        else:
            ticks = tuple(np.arange(time))

        # One row subplot for each variable wrt which we are computing
        # the gradients
        for var in range(len_wrt):
            plt.subplot(len_wrt, 1, var + 1)
            for d in range(args.layers - var):
                plt.plot(np.arange(time),
                         np.mean(np.abs(gradients[d][:, 0, :]), axis=1),
                         label="layer " + str(d + var))
            plt.xticks(range(args.visualize_length), ticks)
            plt.grid(True)
            plt.yscale('log')
            axes = plt.gca()
            axes.set_ylim([5e-20, 5e-1])
            plt.title("gradients plotting w.r.t pre_rrn" + str(var))
            plt.legend()
        plt.tight_layout()
        if args.local:
            plt.show()
        else:
            plt.savefig(args.save_path + "/visualize_gradients_" + str(num) +
                        ".png")
            logger.info("Figure \"visualize_gradients_" + str(num) +
                        ".png\" saved at directory: " + args.save_path)
Exemple #16
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def visualize_gates_lstm(gate_values, hidden_states, updates, train_stream,
                         valid_stream, args):

    in_gates = gate_values["in_gates"]
    out_gates = gate_values["out_gates"]
    forget_gates = gate_values["forget_gates"]

    # Handle the theano shared variables that allow carrying the hidden state
    givens, f_updates = carry_hidden_state(updates, 1,
                                           not (has_indices(args.dataset)))

    generate_in = theano.function(inputs=ComputationGraph(in_gates).inputs,
                                  outputs=in_gates,
                                  givens=givens,
                                  updates=f_updates,
                                  mode=Mode(optimizer='fast_compile'))
    generate_out = theano.function(inputs=ComputationGraph(out_gates).inputs,
                                   outputs=out_gates,
                                   givens=givens,
                                   updates=f_updates,
                                   mode=Mode(optimizer='fast_compile'))
    generate_forget = theano.function(
        inputs=ComputationGraph(forget_gates).inputs,
        outputs=forget_gates,
        givens=givens,
        updates=f_updates,
        mode=Mode(optimizer='fast_compile'))

    # Generate
    epoch_iterator = valid_stream.get_epoch_iterator()
    for num in range(10):
        init_ = next(epoch_iterator)[0][0:args.visualize_length, 0:1]

        last_output_in = generate_in(init_)
        last_output_out = generate_out(init_)
        last_output_forget = generate_forget(init_)
        layers = len(last_output_in)

        time = last_output_in[0].shape[0]
        if has_indices(args.dataset):
            ticks = tuple(conv_into_char(init_[:, 0], args.dataset))
        else:
            ticks = tuple(np.arange(time))

        for i in range(layers):

            plt.subplot(3, layers, 1 + i)
            plt.plot(np.arange(time),
                     np.mean(np.abs(last_output_in[i][:, 0, :]), axis=1))
            plt.xticks(range(args.visualize_length), ticks)
            plt.grid(True)
            plt.title("in_gate of layer " + str(i))

            plt.subplot(3, layers, layers + 1 + i)
            plt.plot(np.arange(time),
                     np.mean(np.abs(last_output_out[i][:, 0, :]), axis=1))
            plt.xticks(range(args.visualize_length), ticks)
            plt.grid(True)
            plt.title("out_gate of layer " + str(i))

            plt.subplot(3, layers, 2 * layers + 1 + i)
            plt.plot(np.arange(time),
                     np.mean(np.abs(last_output_forget[i][:, 0, :]), axis=1))
            plt.xticks(range(args.visualize_length), ticks)
            plt.grid(True)
            plt.title("forget_gate of layer " + str(i))
        if args.local:
            plt.show()
        else:
            plt.savefig(args.save_path + "/visualize_gates_" + str(num) +
                        ".png")
            logger.info("Figure \"visualize_gates_" + str(num) +
                        ".png\" saved at directory: " + args.save_path)