Esempio n. 1
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        def default_init():
            self.actions_executed = 0
            self.ntrain_called = 0
            self.nstore_called = 0
            self.experiences = []

            nxt_model = src_model.deep_clone()

            inshape = list(src_model.get_input().shape())
            batchin = [mbatch_size] + inshape

            # environment interaction
            self.obs = tc.EVariable(inshape, 0, 'obs', ctx=self.ctx)
            self.act_idx = tc.TenncorAPI(self.ctx).argmax(src_model.connect(self.obs))
            self.act_idx.tag("recovery", "act_idx")

            # training
            self.src_obs = tc.EVariable(batchin, 0, 'src_obs', ctx=self.ctx)
            self.nxt_obs = tc.EVariable(batchin, 0, 'nxt_obs', ctx=self.ctx)
            self.src_outmask = tc.EVariable([mbatch_size] + list(src_model.shape()), 1, 'src_outmask', ctx=self.ctx)
            self.nxt_outmask = tc.EVariable([mbatch_size], 1, 'nxt_outmask', ctx=self.ctx)
            self.rewards = tc.EVariable([mbatch_size], 0, 'rewards', ctx=self.ctx)

            self.prediction_err = tc.api.identity(tc.apply_update([src_model, nxt_model],
                get_dqnupdate(update_fn, target_update_rate),
                get_dqnerror(self, discount_rate), ctx=self.ctx))
            self.prediction_err.tag("recovery", "prediction_err")

            tc.optimize(optimize_cfg, self.ctx)
Esempio n. 2
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        def default_init():
            self.name = name
            self.dataset_idx = 0
            self.api = tc.TenncorAPI(self.ctx)

            # prevent shuffling to allow predictable recovery
            self.dataset = helper.load(self.oxfile)

            self.train_inputs = train_inputs
            labelled_inputs = [
                self.api.identity(train_input)
                for train_input in self.train_inputs
            ]

            outputs = connect_fn(labelled_inputs, self.ctx)
            if not isinstance(outputs, Iterable):
                outputs = [outputs]
            self.train_outputs = [
                self.api.identity(train_output) for train_output in outputs
            ]

            for i, linput in enumerate(labelled_inputs):
                linput.tag('recovery', 'input_{}'.format(i))

            for i, loutput in enumerate(self.train_outputs):
                loutput.tag('recovery', 'output_{}'.format(i))

            tc.optimize(optimize_cfg, self.ctx)
Esempio n. 3
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def tc_mlp_grad(matrix_dim):
    import client.profile.profile as tc_prof
    import tenncor as tc
    n_in = matrix_dim
    n_out = int(n_in / 2)
    batch_size = 1

    # regular mlp
    brain = tc.api.layer.link([
        tc.api.layer.dense([n_in], [matrix_dim]),
        tc.api.layer.bind(tc.api.sigmoid),
        tc.api.layer.dense([matrix_dim], [n_out]),
        tc.api.layer.bind(tc.api.sigmoid),
    ])

    invar = tc.Variable(np.zeros([batch_size, n_in], dtype=float), 'in')
    # out = brain.connect(invar)
    # expected_out = tc.Variable(np.zeros([batch_size, n_out], dtype=float), 'expected_out')
    # err = tc.api.square(expected_out - out)

    train_input = tc.Variable([batch_size, n_in], label='train_input')
    train_output = tc.Variable([batch_size, n_out], label='train_output')

    invar_batch = batch_generate(n_in, batch_size)
    test_batch = batch_generate(n_in, batch_size)
    test_batch_out = avgevry2(test_batch)

    invar.assign(invar_batch)
    train_input.assign(test_batch)
    train_output.assign(test_batch_out)

    train_err = tc.apply_update(
        [brain], lambda err, leaves: tc.api.approx.sgd(
            err, leaves, learning_rate=learning_rate), lambda models: tc.api.
        error.sqr_diff(train_output, models[0].connect(train_input)))
    tc.optimize("external/com_github_mingkaic_tenncor/cfg/optimizations.json")

    tc_prof.remote_profile('localhost:8069', [train_err])
Esempio n. 4
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def main(args):

    # default_ts = time.time()
    default_ts = 0

    parser = argparse.ArgumentParser(description=prog_description)
    parser.add_argument('--seed',
                        dest='seed',
                        type=str2bool,
                        nargs='?',
                        const=False,
                        default=True,
                        help='Whether to seed or not (default: True)')
    parser.add_argument('--seedval',
                        dest='seedval',
                        type=int,
                        nargs='?',
                        default=int(default_ts),
                        help='Random seed value (default: <current time>)')
    parser.add_argument('--nbatch',
                        dest='nbatch',
                        type=int,
                        nargs='?',
                        default=3,
                        help='Batch size when training (default: 3)')
    parser.add_argument('--n_train',
                        dest='n_train',
                        type=int,
                        nargs='?',
                        default=3000,
                        help='Number of times to train (default: 3000)')
    parser.add_argument('--n_test',
                        dest='n_test',
                        type=int,
                        nargs='?',
                        default=500,
                        help='Number of times to test (default: 500)')
    parser.add_argument('--save',
                        dest='save',
                        nargs='?',
                        default='',
                        help='Filename to save model (default: <blank>)')
    parser.add_argument(
        '--load',
        dest='load',
        nargs='?',
        default='models/gd.onnx',
        help='Filename to load pretrained model (default: models/gd.onnx)')
    args = parser.parse_args(args)

    if args.seed:
        print('seeding {}'.format(args.seedval))
        tc.seed(args.seedval)
        np.random.seed(args.seedval)

    nunits = 9
    ninput = 10
    noutput = int(ninput / 2)
    nbatch = args.nbatch

    train_input = tc.EVariable([nbatch, ninput])
    train_exout = tc.EVariable([nbatch, noutput])
    model = tc.api.layer.link([
        tc.api.layer.dense([ninput], [nunits]),
        tc.api.layer.bind(tc.api.sigmoid),
        tc.api.layer.dense([nunits], [noutput]),
        tc.api.layer.bind(tc.api.sigmoid),
    ], train_input)

    train = tc.apply_update(
        [model],
        lambda err, leaves: tc.api.approx.sgd(err, leaves, learning_rate=0.9),
        lambda models: tc.api.loss.mean_squared(train_exout, models[0].connect(
            train_input)))
    untrained = model.deep_clone()
    trained = model.deep_clone()
    try:
        print('loading ' + args.load)
        trained = tc.load_from_file(args.load)[0]
        print('successfully loaded from ' + args.load)
    except Exception as e:
        print(e)
        print('failed to load from "{}"'.format(args.load))

    testin = tc.EVariable([ninput], label='testin')
    untrained_out = untrained.connect(testin)
    trained_out = model.connect(testin)
    pretrained_out = trained.connect(testin)

    tc.optimize("cfg/optimizations.json")

    show_every_n = 500
    start = time.time()
    for i in range(args.n_train):
        batch, batch_out = batch_generate(ninput, nbatch)
        train_input.assign(batch.reshape(nbatch, ninput))
        train_exout.assign(batch_out.reshape(nbatch, noutput))
        err = train.get()
        if i % show_every_n == show_every_n - 1:
            print('training {}\ntraining error:\n{}'.format(i + 1, err))

    print('training time: {} seconds'.format(time.time() - start))

    untrained_err = 0
    trained_err = 0
    pretrained_err = 0

    for i in range(args.n_test):
        if i % show_every_n == show_every_n - 1:
            print('testing {}'.format(i + 1))

        test_batch, test_batch_out = batch_generate(ninput, 1)
        testin.assign(test_batch)

        untrained_data = untrained_out.get()
        trained_data = trained_out.get()
        pretrained_data = pretrained_out.get()

        untrained_err += np.mean(abs(untrained_data - test_batch_out))
        trained_err += np.mean(abs(trained_data - test_batch_out))
        pretrained_err += np.mean(abs(pretrained_data - test_batch_out))

    untrained_err /= args.n_test
    trained_err /= args.n_test
    pretrained_err /= args.n_test
    print('untrained mlp error rate: {}%'.format(untrained_err * 100))
    print('trained mlp error rate: {}%'.format(trained_err * 100))
    print('pretrained mlp error rate: {}%'.format(pretrained_err * 100))
    print('is structurally equal?:', cmp.is_equal(pretrained_out, trained_out))
    print('% data equal:', cmp.percent_dataeq(pretrained_out, trained_out))

    try:
        print('saving')
        if tc.save_to_file(args.save, [model]):
            print('successfully saved to {}'.format(args.save))
    except Exception as e:
        print(e)
        print('failed to write to "{}"'.format(args.save))
Esempio n. 5
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def main(args):

    default_ts = time.time()

    parser = argparse.ArgumentParser(description=prog_description)
    parser.add_argument('--seed',
                        dest='seed',
                        type=str2bool,
                        nargs='?',
                        const=False,
                        default=False,
                        help='Whether to seed or not (default: True)')
    parser.add_argument('--seedval',
                        dest='seedval',
                        type=int,
                        nargs='?',
                        default=int(default_ts),
                        help='Random seed value (default: <current time>)')
    parser.add_argument('--n_train',
                        dest='n_train',
                        type=int,
                        nargs='?',
                        default=10001,
                        help='Number of times of train (default: 10001)')
    parser.add_argument('--save',
                        dest='save',
                        nargs='?',
                        default='',
                        help='Filename to save model (default: <blank>)')
    parser.add_argument(
        '--load',
        dest='load',
        nargs='?',
        default='models/latin_lstm.onnx',
        help=
        'Filename to load pretrained model (default: models/latin_lstm.onnx)')
    args = parser.parse_args(args)

    if args.seed:
        print('seeding {}'.format(args.seedval))
        tc.seed(args.seedval)
        np.random.seed(args.seedval)
    else:
        np.random.seed(seed=0)

    # Read data and setup maps for integer encoding and decoding.
    data = open('models/data/latin_input.txt', 'r').read()
    chars = sorted(list(
        set(data)))  # Sort makes model predictable (if seeded).
    data_size, vocab_size = len(data), len(chars)
    print('data has %d characters, %d unique.' % (data_size, vocab_size))
    char_to_ix = {ch: i for i, ch in enumerate(chars)}
    ix_to_char = {i: ch for i, ch in enumerate(chars)}

    # Hyper parameters
    h_size, o_size, N = vocab_size, vocab_size, vocab_size  # Hidden size is set to vocab_size, assuming that level of abstractness is approximately proportional to vocab_size (but can be set to any other value).
    seq_length = 25  # Longer sequence lengths allow for lengthier latent dependencies to be trained.
    learning_rate = 1e-1

    print_interval = 100

    def old_winit(shape, label):
        return tc.variable(np.random.uniform(-0.05, 0.05, shape.as_list()),
                           label)

    model = tc.api.layer.link([
        tc.api.layer.lstm(tc.Shape([N]),
                          h_size,
                          seq_length,
                          kernel_init=tc.api.init.random_uniform(-0.05, 0.05)),
        tc.api.layer.dense([h_size], [o_size],
                           kernel_init=tc.api.init.random_uniform(-0.05,
                                                                  0.05)),
        tc.api.layer.bind(lambda x: tc.api.softmax(x, 0, 1)),
    ])
    untrained_model = model.deep_clone()
    pretrained_model = model.deep_clone()
    try:
        print('loading ' + args.load)
        pretrained_model = tc.load_from_file(args.load)[0]
        print('successfully loaded from ' + args.load)
    except Exception as e:
        print(e)
        print('failed to load from "{}"'.format(args.load))

    sample_inp = tc.EVariable([1, vocab_size], 0)

    trained_prob = tc.api.slice(model.connect(sample_inp), 0, 1, 1)
    untrained_prob = tc.api.slice(untrained_model.connect(sample_inp), 0, 1, 1)
    pretrained_prob = tc.api.slice(pretrained_model.connect(sample_inp), 0, 1,
                                   1)

    train_inps = tc.EVariable([seq_length, vocab_size], 0)
    train_exout = tc.EVariable([seq_length, vocab_size], 0)

    train_err = tc.apply_update(
        [model], lambda error, leaves: tc.api.approx.adagrad(
            error, leaves, learning_rate=learning_rate, epsilon=1e-8), lambda
        models: encoded_loss(train_exout, models[0].connect(train_inps)))

    tc.optimize("cfg/optimizations.json")

    smooth_loss = -np.log(1.0 / vocab_size) * seq_length
    p = 0
    start = time.time()
    for i in range(args.n_train):
        # Reset memory if appropriate
        if p + seq_length + 1 >= len(data) or i == 0:
            p = 0

        # Get input and target sequence
        inputs = [char_to_ix[ch] for ch in data[p:p + seq_length]]
        encoded_inp = one_encode(inputs, vocab_size)
        encoded_out = one_encode(
            [char_to_ix[ch] for ch in data[p + 1:p + seq_length + 1]],
            vocab_size)

        # Occasionally sample from oldModel and print result
        if i % print_interval == 0:
            sample_ix = sample(sample_inp, trained_prob, inputs[0], 1000)
            print('----\n%s\n----' % (''.join(ix_to_char[ix]
                                              for ix in sample_ix)))

        # Get gradients for current oldModel based on input and target sequences
        train_inps.assign(encoded_inp)
        train_exout.assign(encoded_out)
        loss = train_err.get()

        smooth_loss = smooth_loss * 0.999 + loss * 0.001

        # Occasionally print loss information
        if i % print_interval == 0:
            print('iter %d, loss: %f, smooth loss: %f' %
                  (i, loss, smooth_loss))
            print('batch training time: {} seconds'.format(time.time() -
                                                           start))
            start = time.time()

        # Prepare for next iteration
        p += seq_length

    untrained_sample = sample(sample_inp, untrained_prob, char_to_ix[data[0]],
                              1000)
    trained_sample = sample(sample_inp, trained_prob, char_to_ix[data[0]],
                            1000)
    pretrained_sample = sample(sample_inp, pretrained_prob,
                               char_to_ix[data[0]], 1000)
    print('--untrained--\n%s\n----' % (''.join(ix_to_char[ix]
                                               for ix in untrained_sample)))
    print('--trained--\n%s\n----' % (''.join(ix_to_char[ix]
                                             for ix in trained_sample)))
    print('--pretrained--\n%s\n----' % (''.join(ix_to_char[ix]
                                                for ix in pretrained_sample)))

    try:
        print('saving')
        if tc.save_to_file(args.save, [model]):
            print('successfully saved to {}'.format(args.save))
    except Exception as e:
        print(e)
        print('failed to write to "{}"'.format(args.save))
Esempio n. 6
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    tc.api.layer.bind(tc.api.softmax),
])

training_data = generate_training_data(embedding, corpus)

winput = tc.variable(np.random.rand(nwords) * 2 - 1, 'input')
woutput = tc.variable(np.random.rand(2 * window, nwords) * 2 - 1, 'output')

y_pred = model.connect(winput)

train_err = tc.apply_update([model],
    lambda error, leaves: tc.api.approx.sgd(error, leaves, lr),
    lambda models: tc.api.reduce_sum(tc.api.pow( \
        tc.api.extend(models[0].connect(winput), [1, 2 * window]) - woutput, 2.)))

tc.optimize("cfg/optimizations.json")

# Cycle through each epoch
for i in range(epochs):
    # Intialise loss to 0
    loss = 0

    # Cycle through each training sample
    # w_t = vector for target word, w_c = vectors for context words
    for w_t, w_c in training_data:
        wcdata = np.array(w_c)
        ydata = y_pred.get().reshape(1, nwords)
        for j in range(2 * window - wcdata.shape[0]):
            wcdata = np.concatenate((wcdata, ydata), 0)
        winput.assign(np.array(w_t))
        woutput.assign(wcdata)
Esempio n. 7
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def main(args):

    default_ts = time.time()

    parser = argparse.ArgumentParser(description=prog_description)
    parser.add_argument('--seed',
                        dest='seed',
                        type=str2bool,
                        nargs='?',
                        const=False,
                        default=False,
                        help='Whether to seed or not (default: True)')
    parser.add_argument('--seedval',
                        dest='seedval',
                        type=int,
                        nargs='?',
                        default=int(default_ts),
                        help='Random seed value (default: <current time>)')
    parser.add_argument('--n_batch',
                        dest='n_batch',
                        type=int,
                        nargs='?',
                        default=100,
                        help='Batch size when training (default: 100)')
    parser.add_argument('--n_train',
                        dest='n_train',
                        type=int,
                        nargs='?',
                        default=2000,
                        help='Number of times to train (default: 2000)')
    parser.add_argument('--n_test',
                        dest='n_test',
                        type=int,
                        nargs='?',
                        default=5,
                        help='Number of times to test (default: 5)')
    parser.add_argument('--save',
                        dest='save',
                        nargs='?',
                        default='',
                        help='Filename to save model (default: <blank>)')
    parser.add_argument(
        '--load',
        dest='load',
        nargs='?',
        default='models/rnn.onnx',
        help='Filename to load pretrained model (default: models/rnn.onnx)')
    args = parser.parse_args(args)

    if args.seed:
        print('seeding {}'.format(args.seedval))
        tc.seed(args.seedval)
        np.random.seed(args.seedval)
    else:
        np.random.seed(seed=1)

    # dataset parameters
    n_train = args.n_train
    n_test = args.n_test
    sequence_len = 7

    # training parameters
    n_batch = args.n_batch
    lmbd = 0.5
    learning_rate = 0.05
    momentum_term = 0.80
    eps = 1e-6

    # model parameters
    nunits = 3  # Number of states in the recurrent layer
    ninput = 2
    noutput = 1

    model = tc.api.layer.link([
        tc.api.layer.dense(inshape=[ninput],
                           hidden_dims=[nunits],
                           kernel_init=weight_init),
        tc.api.layer.rnn(indim=nunits,
                         hidden_dim=nunits,
                         activation=tc.api.tanh,
                         nseq=sequence_len,
                         seq_dim=2,
                         kernel_init=weight_init,
                         bias_init=tc.api.init.zeros()),
        tc.api.layer.dense(inshape=[nunits],
                           hidden_dims=[noutput],
                           kernel_init=weight_init),
        #tc.api.layer.dense(inshape=[ninput], hidden_dims=[nunits]),
        #tc.api.layer.rnn(indim=nunits, hidden_dim=nunits,
        #    activation=tc.api.tanh, nseq=sequence_len, seq_dim=2),
        #tc.api.layer.dense(inshape=[nunits], hidden_dims=[noutput]),
        tc.api.layer.bind(tc.api.sigmoid),
    ])
    untrained = model.deep_clone()
    trained = model.deep_clone()
    try:
        print('loading ' + args.load)
        trained = tc.load_from_file(args.load)[0]
        print('successfully loaded from ' + args.load)
    except Exception as e:
        print(e)
        print('failed to load from "{}"'.format(args.load))

    train_invar = tc.EVariable([n_batch, sequence_len, ninput])
    train_exout = tc.EVariable([n_batch, sequence_len, noutput])
    tinput = tc.api.permute(train_invar, [0, 2, 1])
    toutput = tc.api.permute(train_exout, [0, 2, 1])

    train_err = tc.apply_update(
        [model], lambda error, leaves: make_rms_prop(
            error, leaves, learning_rate, momentum_term, lmbd, eps),
        lambda models: loss(toutput, models[0].connect(tinput))
    )  #tc.api.reduce_mean(tc.api.loss.cross_entropy(toutput, models[0].connect(tinput))))

    # create training samples
    train_input, train_output = create_dataset(n_train, sequence_len)
    print(f'train_input tensor shape: {train_input.shape}')
    print(f'train_output tensor shape: {train_output.shape}')

    test_invar = tc.EVariable([n_test, sequence_len, ninput])
    tin = tc.api.permute(test_invar, [0, 2, 1])
    untrained_out = tc.api.round(untrained.connect(tin))
    trained_out = tc.api.round(model.connect(tin))
    pretrained_out = tc.api.round(trained.connect(tin))

    tc.optimize("cfg/optimizations.json")

    ls_of_loss = []
    start = time.time()
    for i in range(5):
        for j in range(n_train // n_batch):
            xbatch = train_input[j:j + n_batch, :, :]
            tbatch = train_output[j:j + n_batch, :, :]
            train_invar.assign(xbatch)
            train_exout.assign(tbatch)

            # Add loss to list to plot
            ls_of_loss.append(train_err.get())
    print('training time: {} seconds'.format(time.time() - start))

    # Plot the loss over the iterations
    fig = plt.figure(figsize=(5, 3))
    plt.plot(ls_of_loss, 'b-')
    plt.xlabel('minibatch iteration')
    plt.ylabel('$\\xi$', fontsize=15)
    plt.title('Loss over backprop iteration')
    plt.xlim(0, 99)
    fig.subplots_adjust(bottom=0.2)
    plt.show()

    test_input, test_output = create_dataset(n_test, sequence_len)

    test_invar.assign(test_input)
    got_untrained = untrained_out.get()
    got_trained = trained_out.get()
    got_pretrained = pretrained_out.get()

    for i in range(test_input.shape[0]):
        left = test_input[i, :, 0]
        right = test_input[i, :, 1]
        expected = test_output[i, :, :]
        yuntrained = got_untrained[:, i, :]
        ytrained = got_trained[:, i, :]
        ypretrained = got_pretrained[:, i, :]

        left = ''.join([str(int(d)) for d in left])
        left_num = int(''.join(reversed(left)), 2)
        right = ''.join([str(int(d)) for d in right])
        right_num = int(''.join(reversed(right)), 2)
        expected = ''.join([str(int(d[0])) for d in expected])
        expected_num = int(''.join(reversed(expected)), 2)
        yuntrained = ''.join([str(int(d[0])) for d in yuntrained])
        yuntrained_num = int(''.join(reversed(yuntrained)), 2)
        ytrained = ''.join([str(int(d[0])) for d in ytrained])
        ytrained_num = int(''.join(reversed(ytrained)), 2)
        ypretrained = ''.join([str(int(d[0])) for d in ypretrained])
        ypretrained_num = int(''.join(reversed(ypretrained)), 2)
        print(f'left:         {left:s}   {left_num:2d}')
        print(f'right:      + {right:s}   {right_num:2d}')
        print(f'              -------   --')
        print(f'expected:   = {expected:s}   {expected_num:2d}')
        print(f'untrained:  = {yuntrained:s}   {yuntrained_num:2d}')
        print(f'trained:    = {ytrained:s}   {ytrained_num:2d}')
        print(f'pretrained: = {ypretrained:s}   {ypretrained_num:2d}')

        print('')

    try:
        print('saving')
        if tc.save_to_file(args.save, [model]):
            print('successfully saved to {}'.format(args.save))
    except Exception as e:
        print(e)
        print('failed to write to "{}"'.format(args.save))
Esempio n. 8
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def main(args):

    default_ts = time.time()

    parser = argparse.ArgumentParser(description=prog_description)
    parser.add_argument('--seed',
                        dest='seed',
                        type=str2bool,
                        nargs='?',
                        const=False,
                        default=True,
                        help='Whether to seed or not (default: True)')
    parser.add_argument('--seedval',
                        dest='seedval',
                        type=int,
                        nargs='?',
                        default=int(default_ts),
                        help='Random seed value (default: <current time>)')
    parser.add_argument(
        '--pre_nepoch',
        dest='pretrain_epochs',
        type=int,
        nargs='?',
        default=1000,
        help='Number of epochs when pretraining (default: 1000)')
    parser.add_argument('--nepochs',
                        dest='finetune_epochs',
                        type=int,
                        nargs='?',
                        default=200,
                        help='Number of epochs when finetuning (default: 200)')
    parser.add_argument(
        '--cdk',
        dest='cdk',
        type=int,
        nargs='?',
        default=1,
        help='Length of the Contrastive divergence chain (default: 1)')
    parser.add_argument('--save',
                        dest='save',
                        nargs='?',
                        default='',
                        help='Filename to save model (default: <blank>)')
    parser.add_argument(
        '--load',
        dest='load',
        nargs='?',
        default='models/dbn.onnx',
        help='Filename to load pretrained model (default: models/dbn.onnx)')
    args = parser.parse_args(args)

    if args.seed:
        print('seeding {}'.format(args.seedval))
        tc.seed(args.seedval)
        np.random.seed(args.seedval)

    x = np.array([[1, 1, 1, 0, 0, 0], [1, 0, 1, 0, 0, 0], [1, 1, 1, 0, 0, 0],
                  [0, 0, 1, 1, 1, 0], [0, 0, 1, 1, 0, 0], [0, 0, 1, 1, 1, 0],
                  [0, 0, 1, 1, 0, 1]])
    y = np.array([[1, 0], [1, 0], [1, 0], [0, 1], [0, 1], [0, 1], [0, 0]])

    # construct DBN
    rbms = [
        tc.api.layer.rbm(6, 3),
        tc.api.layer.rbm(3, 3),
    ]
    dense = tc.api.layer.dense([3], [2], kernel_init=tc.api.init.zeros())
    softmax_dim = 0

    rbm_interlace = zip([rbm.fwd() for rbm in rbms],
                        len(rbms) * [tc.api.layer.bind(tc.api.sigmoid)])
    model = tc.api.layer.link(
        [e for inters in rbm_interlace for e in inters] + [
            dense,
            tc.api.layer.bind(lambda x: tc.api.softmax(x, softmax_dim, 1))
        ])
    untrained = model.deep_clone()
    trained = model.deep_clone()
    try:
        print('loading ' + args.load)
        trained = tc.load_from_file(args.load)[0]
        print('successfully loaded from ' + args.load)
    except Exception as e:
        print(e)
        print('failed to load from "{}"'.format(args.load))

    trainer = tc.DBNTrainer(rbms,
                            dense,
                            softmax_dim,
                            x.shape[0],
                            pretrain_lr=0.1,
                            train_lr=0.1,
                            cdk=args.cdk)

    def pretrain_log(epoch, layer):
        if epoch % 100 == 0:
            print('Pre-training layer {}, epoch {}, cost {}'.format(
                layer, epoch, trainer.reconstruction_cost(layer)))

    def finetune_log(epoch):
        if epoch % 100 == 0:
            print('Training epoch {}, cost {}'.format(epoch,
                                                      trainer.training_cost()))

    # pre-training (TrainUnsupervisedDBN)
    trainer.pretrain(x, nepochs=args.pretrain_epochs, logger=pretrain_log)

    # fine-tuning (DBNSupervisedFineTuning)
    trainer.finetune(x, y, nepochs=args.finetune_epochs, logger=finetune_log)

    # test
    x = np.array([1, 1, 0, 0, 0, 0])
    var = tc.variable(x)
    untrained_out = untrained.connect(var)
    out = model.connect(var)
    trained_out = trained.connect(var)

    tc.optimize("cfg/optimizations.json")

    # since x is similar to first 3 rows of x, expect results simlar to first 3 rows of y [1, 0]
    print('untrained_out: ', untrained_out.get())
    print('out: ', out.get())
    print('trained_out: ', trained_out.get())

    try:
        print('saving')
        if tc.save_to_file(args.save, [model]):
            print('successfully saved to {}'.format(args.save))
    except Exception as e:
        print(e)
        print('failed to write to "{}"'.format(args.save))
Esempio n. 9
0
def main(args):

    default_ts = time.time()

    parser = argparse.ArgumentParser(description=prog_description)
    parser.add_argument('--seed', dest='seed',
        type=str2bool, nargs='?', const=False, default=False,
        help='Whether to seed or not (default: True)')
    parser.add_argument('--seedval', dest='seedval', type=int, nargs='?', default=int(default_ts),
        help='Random seed value (default: <current time>)')
    parser.add_argument('--n_train', dest='n_train', type=int, nargs='?', default=100,
        help='Number of times of train (default: 100)')
    parser.add_argument('--save', dest='save', nargs='?', default='',
        help='Filename to save model (default: <blank>)')
    parser.add_argument('--load', dest='load', nargs='?', default='models/fast_lstm.onnx',
        help='Filename to load pretrained model (default: models/fast_lstm.onnx)')
    args = parser.parse_args(args)

    if args.seed:
        print('seeding {}'.format(args.seedval))
        tc.seed(args.seedval)
        np.random.seed(args.seedval)
    else:
        np.random.seed(seed=0)

    # parameters for input data dimension and lstm cell count
    mem_cell_ct = 100
    x_dim = 50
    y_list = [-0.5, 0.2, 0.1, -0.5]
    input_val_arr = [np.random.random(x_dim) for _ in y_list]

    model = tc.api.layer.lstm(tc.Shape([x_dim]), mem_cell_ct, len(y_list),
        kernel_init=tc.api.init.xavier_uniform(1),
        bias_init=tc.api.init.xavier_uniform(1))
    untrained_model = model.deep_clone()
    pretrained_model = model.deep_clone()
    try:
        print('loading ' + args.load)
        pretrained_model = tc.load_from_file(args.load)[0]
        print('successfully loaded from ' + args.load)
    except Exception as e:
        print(e)
        print('failed to load from "{}"'.format(args.load))

    test_inputs = tc.variable(np.array(input_val_arr), 'test_input')
    test_exout = tc.variable(np.array(y_list), 'test_exout')

    untrained = tc.api.slice(untrained_model.connect(test_inputs), 0, 1, 0)
    hiddens = tc.api.slice(model.connect(test_inputs), 0, 1, 0)
    pretrained = tc.api.slice(pretrained_model.connect(test_inputs), 0, 1, 0)

    err = tc.api.reduce_sum(loss(test_exout, hiddens))

    train_err = tc.apply_update([model],
        lambda error, leaves: tc.api.approx.sgd(error, leaves, learning_rate=0.1),
        lambda models: loss(test_exout, models[0].connect(test_inputs)))

    tc.optimize("cfg/optimizations.json")

    start = time.time()
    for cur_iter in range(args.n_train):
        train_err.get()
        print("iter {}: y_pred = {}, loss: {}".format(
            cur_iter, hiddens.get().flatten(), err.get()))

    print("expecting = {}".format(np.array(y_list)))
    print("untrained_y_pred = {}".format(untrained.get().flatten()))
    print("trained_y_pred = {}".format(hiddens.get().flatten()))
    print("pretrained_y_pred = {}".format(pretrained.get().flatten()))
    print('training time: {} seconds'.format(time.time() - start))

    try:
        print('saving')
        if tc.save_to_file(args.save, [model]):
            print('successfully saved to {}'.format(args.save))
    except Exception as e:
        print(e)
        print('failed to write to "{}"'.format(args.save))