示例#1
0
def test_crops_data_loader_regression():
    """Test CropsDataLoader."""

    # Convert data from volt to millivolt
    # Pytorch expects float32 for input and int64 for labels.
    rng = np.random.RandomState(42)
    X = rng.randn(60, 64, 343).astype(np.float32)
    y = rng.randint(0, 2, size=len(X))

    train_set = SignalAndTarget(X, y=y)
    input_time_length = X.shape[2]
    n_preds_per_input = X.shape[2] // 4

    n_times_input = input_time_length  # size of signal passed to nn
    batch_size = 32

    iterator = CropsFromTrialsIterator(batch_size=batch_size,
                                       input_time_length=n_times_input,
                                       n_preds_per_input=n_preds_per_input)

    ds = EEGDataSet(train_set.X, train_set.y)

    loader = \
        CropsDataLoader(ds, batch_size=batch_size,
                        input_time_length=input_time_length,
                        n_preds_per_input=n_preds_per_input,
                        num_workers=0)

    for (X1b, y1b), (X2b, y2b) in \
            zip(iterator.get_batches(train_set, shuffle=False), loader):
        np.testing.assert_array_equal(y1b, y2b)
        np.testing.assert_array_equal(X1b, X2b)
def predict(model, data, labels, n_channels=22, input_time_length=500):

    # n_classes = 4
    # if n_classes == 4:
    #     labels = labels - 1

    # # # # # # # # CREATE CROPPED ITERATOR # # # # # # # # #
    val_set = SignalAndTarget(data, y=labels)

    # determine output size
    test_input = np_to_var(
        np.ones((2, n_channels, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    # print("{:d} predictions per input/trial".format(n_preds_per_input))

    iterator = CropsFromTrialsIterator(batch_size=32,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)

    model.eval()

    # Collect all predictions and losses
    all_preds = []
    batch_sizes = []
    for batch_X, batch_y in iterator.get_batches(val_set, shuffle=False):
        net_in = np_to_var(batch_X)
        if cuda:
            net_in = net_in.cuda()
        outputs = model(net_in)
        all_preds.append(var_to_np(outputs))
        outputs = th.mean(outputs, dim=2, keepdim=False)
        batch_sizes.append(len(batch_X))
    # Assign the predictions to the trials
    preds_per_trial = compute_preds_per_trial_from_crops(
        all_preds, input_time_length, val_set.X)
    # preds per trial are now trials x classes x timesteps/predictions
    # Now mean across timesteps for each trial to get per-trial predictions
    meaned_preds_per_trial = np.array(
        [np.mean(p, axis=1) for p in preds_per_trial])
    meaned_preds_per_trial_rec = -1 / meaned_preds_per_trial
    label_cert = np.max(meaned_preds_per_trial_rec)
    predicted_labels = np.argmax(meaned_preds_per_trial, axis=1)
    accuracy = np.mean(predicted_labels == val_set.y)
    # print("{:6s} Accuracy: {:.2f}%".format('Validation', accuracy * 100))

    print('predicted_labels shape')
    print(predicted_labels.shape)

    return predicted_labels, label_cert
def train(config):
    cuda = True
    model = config['model']
    if model == 'deep':
        model = Deep4Net(n_chans,
                         n_classes,
                         input_time_length=input_time_length,
                         final_conv_length=2,
                         config=config).create_network()

    to_dense_prediction_model(model)
    if cuda:
        model.cuda()

    log.info("Model: \n{:s}".format(str(model)))
    dummy_input = np_to_var(train_set.X[:1, :, :, None])
    if cuda:
        dummy_input = dummy_input.cuda()
    out = model(dummy_input)

    n_preds_per_input = out.cpu().data.numpy().shape[2]

    optimizer = optim.Adam(model.parameters())

    iterator = CropsFromTrialsIterator(batch_size=60,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)

    stop_criterion = Or([MaxEpochs(20), NoDecrease('valid_misclass', 80)])

    monitors = [
        LossMonitor(),
        MisclassMonitor(col_suffix='sample_misclass'),
        CroppedTrialMisclassMonitor(input_time_length=input_time_length),
        RuntimeMonitor()
    ]

    model_constraint = MaxNormDefaultConstraint()

    loss_function = lambda preds, targets: F.nll_loss(
        th.mean(preds, dim=2, keepdim=False), targets)

    exp = Experiment(model,
                     train_set,
                     valid_set,
                     test_set,
                     iterator=iterator,
                     loss_function=loss_function,
                     optimizer=optimizer,
                     model_constraint=model_constraint,
                     monitors=monitors,
                     stop_criterion=stop_criterion,
                     remember_best_column='valid_misclass',
                     run_after_early_stop=True,
                     cuda=cuda)
    exp.run()
    print(exp.rememberer)
    return exp.rememberer.lowest_val
示例#4
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def get_cropped_settings():
    stop_criterion = Or([MaxEpochs(global_vars.get('max_epochs')),
                         NoIncreaseDecrease(f'valid_{global_vars.get("nn_objective")}', global_vars.get('max_increase_epochs'))])
    iterator = CropsFromTrialsIterator(batch_size=global_vars.get('batch_size'),
                                       input_time_length=global_vars.get('input_time_len'),
                                       n_preds_per_input=global_vars.get('n_preds_per_input'))
    loss_function = lambda preds, targets: F.nll_loss(torch.mean(preds, dim=2, keepdim=False), targets)
    monitors = [LossMonitor(), GenericMonitor('accuracy', acc_func),
                CroppedTrialGenericMonitor('accuracy', acc_func,
                                           input_time_length=global_vars.get('input_time_len')), RuntimeMonitor()]
    if global_vars.get('dataset') in ['NER15', 'Cho', 'SonarSub']:
        monitors.append(CroppedTrialGenericMonitor('auc', auc_func,
                                                   input_time_length=global_vars.get('input_time_len')))
    if global_vars.get('dataset') in ['BCI_IV_2b']:
        monitors.append(CroppedGenericMonitorPerTimeStep('kappa', kappa_func,
                                                         input_time_length=global_vars.get('input_time_len')))
    return stop_criterion, iterator, loss_function, monitors
示例#5
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def get_iterator(model, dataset, config):
    # Config
    cropped_input_time_length = config['cropped']['input_time_length']
    batch_size = config['train']['batch_size']

    # Set up iterator
    if config['cropped']['use']:
        # Determine number of predictions per input/trial,
        #   used for cropped batch iterator
        dummy_input = np_to_var(dataset.train_set.X[:1, :, :, None])
        if config['cuda']:
            dummy_input = dummy_input.cuda()
        out = model(dummy_input)
        n_preds_per_input = out.cpu().data.numpy().shape[2]
        return CropsFromTrialsIterator(
            batch_size=batch_size,
            input_time_length=cropped_input_time_length,
            n_preds_per_input=n_preds_per_input)
    if config['experiment']['type'] == 'ccsa_da':
        return PairedDataBalancedBatchSizeIterator(batch_size=batch_size)
    return BalancedBatchSizeIterator(batch_size=batch_size)
def run_exp(max_epochs, only_return_exp):
    from collections import OrderedDict
    filenames = [
        'data/robot-hall/NiRiNBD6.ds_1-1_500Hz.BBCI.mat',
        'data/robot-hall/NiRiNBD8.ds_1-1_500Hz.BBCI.mat',
        'data/robot-hall/NiRiNBD9.ds_1-1_500Hz.BBCI.mat',
        'data/robot-hall/NiRiNBD10.ds_1-1_500Hz.BBCI.mat',
        'data/robot-hall/NiRiNBD12_cursor_250Hz.BBCI.mat',
        'data/robot-hall/NiRiNBD13_cursorS000R01_onlyFullRuns_250Hz.BBCI.mat',
        'data/robot-hall/NiRiNBD14_cursor_250Hz.BBCI.mat',
        'data/robot-hall/NiRiNBD15_cursor_250Hz.BBCI.mat'
    ]
    sensor_names = [
        'Fp1', 'Fpz', 'Fp2', 'AF7', 'AF3', 'AF4', 'AF8', 'F7', 'F5', 'F3',
        'F1', 'Fz', 'F2', 'F4', 'F6', 'F8', 'FT7', 'FC5', 'FC3', 'FC1', 'FCz',
        'FC2', 'FC4', 'FC6', 'FT8', 'M1', 'T7', 'C5', 'C3', 'C1', 'Cz', 'C2',
        'C4', 'C6', 'T8', 'M2', 'TP7', 'CP5', 'CP3', 'CP1', 'CPz', 'CP2',
        'CP4', 'CP6', 'TP8', 'P7', 'P5', 'P3', 'P1', 'Pz', 'P2', 'P4', 'P6',
        'P8', 'PO7', 'PO5', 'PO3', 'POz', 'PO4', 'PO6', 'PO8', 'O1', 'Oz', 'O2'
    ]
    name_to_start_codes = OrderedDict([('Right Hand', [1]), ('Feet', [2]),
                                       ('Rotation', [3]), ('Words', [4])])
    name_to_stop_codes = OrderedDict([('Right Hand', [10]), ('Feet', [20]),
                                      ('Rotation', [30]), ('Words', [40])])

    trial_ival = [500, 0]
    min_break_length_ms = 6000
    max_break_length_ms = 8000
    break_ival = [1000, -500]

    input_time_length = 700

    filename_to_extra_args = {
        'data/robot-hall/NiRiNBD12_cursor_250Hz.BBCI.mat':
        dict(
            name_to_start_codes=OrderedDict([('Right Hand', [1]),
                                             ('Feet', [2]), ('Rotation', [3]),
                                             ('Words', [4]), ('Rest', [5])]),
            name_to_stop_codes=OrderedDict([('Right Hand', [10]),
                                            ('Feet', [20]), ('Rotation', [30]),
                                            ('Words', [40]), ('Rest', [50])]),
            min_break_length_ms=3700,
            max_break_length_ms=3900,
        ),
        'data/robot-hall/NiRiNBD13_cursorS000R01_onlyFullRuns_250Hz.BBCI.mat':
        dict(
            name_to_start_codes=OrderedDict([('Right Hand', [1]),
                                             ('Feet', [2]), ('Rotation', [3]),
                                             ('Words', [4]), ('Rest', [5])]),
            name_to_stop_codes=OrderedDict([('Right Hand', [10]),
                                            ('Feet', [20]), ('Rotation', [30]),
                                            ('Words', [40]), ('Rest', [50])]),
            min_break_length_ms=3700,
            max_break_length_ms=3900,
        ),
        'data/robot-hall/NiRiNBD14_cursor_250Hz.BBCI.mat':
        dict(
            name_to_start_codes=OrderedDict([('Right Hand', [1]),
                                             ('Feet', [2]), ('Rotation', [3]),
                                             ('Words', [4]), ('Rest', [5])]),
            name_to_stop_codes=OrderedDict([('Right Hand', [10]),
                                            ('Feet', [20]), ('Rotation', [30]),
                                            ('Words', [40]), ('Rest', [50])]),
            min_break_length_ms=3700,
            max_break_length_ms=3900,
        ),
        'data/robot-hall/NiRiNBD15_cursor_250Hz.BBCI.mat':
        dict(
            name_to_start_codes=OrderedDict([('Right Hand', [1]),
                                             ('Feet', [2]), ('Rotation', [3]),
                                             ('Words', [4]), ('Rest', [5])]),
            name_to_stop_codes=OrderedDict([('Right Hand', [10]),
                                            ('Feet', [20]), ('Rotation', [30]),
                                            ('Words', [40]), ('Rest', [50])]),
            min_break_length_ms=3700,
            max_break_length_ms=3900,
        ),
    }
    from braindecode.datautil.trial_segment import \
        create_signal_target_with_breaks_from_mne
    from copy import deepcopy

    def load_data(filenames, sensor_names, name_to_start_codes,
                  name_to_stop_codes, trial_ival, break_ival,
                  min_break_length_ms, max_break_length_ms, input_time_length,
                  filename_to_extra_args):
        all_sets = []
        original_args = locals()
        for filename in filenames:
            kwargs = deepcopy(original_args)
            if filename in filename_to_extra_args:
                kwargs.update(filename_to_extra_args[filename])
            log.info("Loading {:s}...".format(filename))
            cnt = BBCIDataset(filename, load_sensor_names=sensor_names).load()
            cnt = cnt.drop_channels(['STI 014'])
            log.info("Resampling...")
            cnt = resample_cnt(cnt, 100)
            log.info("Standardizing...")
            cnt = mne_apply(
                lambda a: exponential_running_standardize(
                    a.T, init_block_size=50).T, cnt)

            log.info("Transform to set...")
            full_set = (create_signal_target_with_breaks_from_mne(
                cnt,
                kwargs['name_to_start_codes'],
                kwargs['trial_ival'],
                kwargs['name_to_stop_codes'],
                kwargs['min_break_length_ms'],
                kwargs['max_break_length_ms'],
                kwargs['break_ival'],
                prepad_trials_to_n_samples=kwargs['input_time_length'],
            ))
            all_sets.append(full_set)
        return all_sets

    sensor_names = [
        'Fp1', 'Fpz', 'Fp2', 'AF7', 'AF3', 'AF4', 'AF8', 'F7', 'F5', 'F3',
        'F1', 'Fz', 'F2', 'F4', 'F6', 'F8', 'FT7', 'FC5', 'FC3', 'FC1', 'FCz',
        'FC2', 'FC4', 'FC6', 'FT8', 'M1', 'T7', 'C5', 'C3', 'C1', 'Cz', 'C2',
        'C4', 'C6', 'T8', 'M2', 'TP7', 'CP5', 'CP3', 'CP1', 'CPz', 'CP2',
        'CP4', 'CP6', 'TP8', 'P7', 'P5', 'P3', 'P1', 'Pz', 'P2', 'P4', 'P6',
        'P8', 'PO7', 'PO5', 'PO3', 'POz', 'PO4', 'PO6', 'PO8', 'O1', 'Oz', 'O2'
    ]
    #sensor_names = ['C3', 'C4']
    n_chans = len(sensor_names)
    if not only_return_exp:
        all_sets = load_data(filenames, sensor_names, name_to_start_codes,
                             name_to_stop_codes, trial_ival, break_ival,
                             min_break_length_ms, max_break_length_ms,
                             input_time_length, filename_to_extra_args)
        from braindecode.datautil.signal_target import SignalAndTarget
        from braindecode.datautil.splitters import concatenate_sets

        train_set = concatenate_sets(all_sets[:6])
        valid_set = all_sets[6]
        test_set = all_sets[7]
    else:
        train_set = None
        valid_set = None
        test_set = None
    set_random_seeds(seed=20171017, cuda=True)
    n_classes = 5
    # final_conv_length determines the size of the receptive field of the ConvNet
    model = ShallowFBCSPNet(in_chans=n_chans,
                            n_classes=n_classes,
                            input_time_length=input_time_length,
                            final_conv_length=30).create_network()
    to_dense_prediction_model(model)

    model.cuda()

    from torch import optim
    import numpy as np

    optimizer = optim.Adam(model.parameters())

    from braindecode.torch_ext.util import np_to_var
    # determine output size
    test_input = np_to_var(
        np.ones((2, n_chans, input_time_length, 1), dtype=np.float32))
    test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    print("{:d} predictions per input/trial".format(n_preds_per_input))

    from braindecode.datautil.iterators import CropsFromTrialsIterator
    iterator = CropsFromTrialsIterator(batch_size=32,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)

    from braindecode.experiments.experiment import Experiment
    from braindecode.experiments.monitors import RuntimeMonitor, LossMonitor, \
        CroppedTrialMisclassMonitor, MisclassMonitor
    from braindecode.experiments.stopcriteria import MaxEpochs
    from braindecode.torch_ext.losses import log_categorical_crossentropy
    import torch.nn.functional as F
    import torch as th
    from braindecode.torch_ext.modules import Expression

    loss_function = log_categorical_crossentropy

    model_constraint = MaxNormDefaultConstraint()
    monitors = [
        LossMonitor(),
        MisclassMonitor(col_suffix='sample_misclass'),
        CroppedTrialMisclassMonitor(input_time_length),
        RuntimeMonitor(),
    ]
    stop_criterion = MaxEpochs(max_epochs)
    exp = Experiment(model,
                     train_set,
                     valid_set,
                     test_set,
                     iterator,
                     loss_function,
                     optimizer,
                     model_constraint,
                     monitors,
                     stop_criterion,
                     remember_best_column='valid_sample_misclass',
                     run_after_early_stop=True,
                     batch_modifier=None,
                     cuda=True)
    if not only_return_exp:
        exp.run()

    return exp
def run_experiment(train_set, valid_set, test_set, model_name, optimizer_name,
                   init_lr, scheduler_name, use_norm_constraint, weight_decay,
                   schedule_weight_decay, restarts, max_epochs,
                   max_increase_epochs, np_th_seed):
    set_random_seeds(np_th_seed, cuda=True)
    #torch.backends.cudnn.benchmark = True# sometimes crashes?
    if valid_set is not None:
        assert max_increase_epochs is not None
    assert (max_epochs is None) != (restarts is None)
    if max_epochs is None:
        max_epochs = np.sum(restarts)
    n_classes = int(np.max(train_set.y) + 1)
    n_chans = int(train_set.X.shape[1])
    input_time_length = 1000
    if model_name == 'deep':
        model = Deep4Net(n_chans,
                         n_classes,
                         input_time_length=input_time_length,
                         final_conv_length=2).create_network()
    elif model_name == 'shallow':
        model = ShallowFBCSPNet(n_chans,
                                n_classes,
                                input_time_length=input_time_length,
                                final_conv_length=30).create_network()
    elif model_name in [
            'resnet-he-uniform', 'resnet-he-normal', 'resnet-xavier-normal',
            'resnet-xavier-uniform'
    ]:
        init_name = model_name.lstrip('resnet-')
        from torch.nn import init
        init_fn = {
            'he-uniform': lambda w: init.kaiming_uniform(w, a=0),
            'he-normal': lambda w: init.kaiming_normal(w, a=0),
            'xavier-uniform': lambda w: init.xavier_uniform(w, gain=1),
            'xavier-normal': lambda w: init.xavier_normal(w, gain=1)
        }[init_name]
        model = EEGResNet(in_chans=n_chans,
                          n_classes=n_classes,
                          input_time_length=input_time_length,
                          final_pool_length=10,
                          n_first_filters=48,
                          conv_weight_init_fn=init_fn).create_network()
    else:
        raise ValueError("Unknown model name {:s}".format(model_name))
    if 'resnet' not in model_name:
        to_dense_prediction_model(model)
    model.cuda()
    model.eval()

    out = model(np_to_var(train_set.X[:1, :, :input_time_length, None]).cuda())

    n_preds_per_input = out.cpu().data.numpy().shape[2]

    if optimizer_name == 'adam':
        optimizer = optim.Adam(model.parameters(),
                               weight_decay=weight_decay,
                               lr=init_lr)
    elif optimizer_name == 'adamw':
        optimizer = AdamW(model.parameters(),
                          weight_decay=weight_decay,
                          lr=init_lr)

    iterator = CropsFromTrialsIterator(batch_size=60,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input,
                                       seed=np_th_seed)

    if scheduler_name is not None:
        assert schedule_weight_decay == (optimizer_name == 'adamw')
        if scheduler_name == 'cosine':
            n_updates_per_epoch = sum(
                [1 for _ in iterator.get_batches(train_set, shuffle=True)])
            if restarts is None:
                n_updates_per_period = n_updates_per_epoch * max_epochs
            else:
                n_updates_per_period = np.array(restarts) * n_updates_per_epoch
            scheduler = CosineAnnealing(n_updates_per_period)
            optimizer = ScheduledOptimizer(
                scheduler,
                optimizer,
                schedule_weight_decay=schedule_weight_decay)
        elif scheduler_name == 'cut_cosine':
            # TODO: integrate with if clause before, now just separate
            # to avoid messing with code
            n_updates_per_epoch = sum(
                [1 for _ in iterator.get_batches(train_set, shuffle=True)])
            if restarts is None:
                n_updates_per_period = n_updates_per_epoch * max_epochs
            else:
                n_updates_per_period = np.array(restarts) * n_updates_per_epoch
            scheduler = CutCosineAnnealing(n_updates_per_period)
            optimizer = ScheduledOptimizer(
                scheduler,
                optimizer,
                schedule_weight_decay=schedule_weight_decay)
        else:
            raise ValueError("Unknown scheduler")
    monitors = [
        LossMonitor(),
        MisclassMonitor(col_suffix='sample_misclass'),
        CroppedTrialMisclassMonitor(input_time_length=input_time_length),
        RuntimeMonitor()
    ]

    if use_norm_constraint:
        model_constraint = MaxNormDefaultConstraint()
    else:
        model_constraint = None
    # change here this cell
    loss_function = lambda preds, targets: F.nll_loss(th.mean(preds, dim=2),
                                                      targets)

    if valid_set is not None:
        run_after_early_stop = True
        do_early_stop = True
        remember_best_column = 'valid_misclass'
        stop_criterion = Or([
            MaxEpochs(max_epochs),
            NoDecrease('valid_misclass', max_increase_epochs)
        ])
    else:
        run_after_early_stop = False
        do_early_stop = False
        remember_best_column = None
        stop_criterion = MaxEpochs(max_epochs)

    exp = Experiment(model,
                     train_set,
                     valid_set,
                     test_set,
                     iterator=iterator,
                     loss_function=loss_function,
                     optimizer=optimizer,
                     model_constraint=model_constraint,
                     monitors=monitors,
                     stop_criterion=stop_criterion,
                     remember_best_column=remember_best_column,
                     run_after_early_stop=run_after_early_stop,
                     cuda=True,
                     do_early_stop=do_early_stop)
    exp.run()
    return exp
示例#8
0
def test_cropped_decoding():
    # 5,6,7,10,13,14 are codes for executed and imagined hands/feet
    subject_id = 1
    event_codes = [5, 6, 9, 10, 13, 14]

    # This will download the files if you don't have them yet,
    # and then return the paths to the files.
    physionet_paths = mne.datasets.eegbci.load_data(subject_id,
                                                    event_codes,
                                                    update_path=False)

    # Load each of the files
    parts = [
        mne.io.read_raw_edf(path,
                            preload=True,
                            stim_channel="auto",
                            verbose="WARNING") for path in physionet_paths
    ]

    # Concatenate them
    raw = concatenate_raws(parts)

    # Find the events in this dataset
    events, _ = mne.events_from_annotations(raw)

    # Use only EEG channels
    eeg_channel_inds = mne.pick_types(raw.info,
                                      meg=False,
                                      eeg=True,
                                      stim=False,
                                      eog=False,
                                      exclude="bads")

    # Extract trials, only using EEG channels
    epoched = mne.Epochs(
        raw,
        events,
        dict(hands=2, feet=3),
        tmin=1,
        tmax=4.1,
        proj=False,
        picks=eeg_channel_inds,
        baseline=None,
        preload=True,
    )
    # Convert data from volt to millivolt
    # Pytorch expects float32 for input and int64 for labels.
    X = (epoched.get_data() * 1e6).astype(np.float32)
    y = (epoched.events[:, 2] - 2).astype(np.int64)  # 2,3 -> 0,1

    SignalAndTarget = namedtuple("SignalAndTarget", "X y")

    train_set = SignalAndTarget(X[:60], y=y[:60])
    test_set = SignalAndTarget(X[60:], y=y[60:])

    # Set if you want to use GPU
    # You can also use torch.cuda.is_available() to determine if cuda is available on your machine.
    cuda = False
    set_random_seeds(seed=20170629, cuda=cuda)

    # This will determine how many crops are processed in parallel
    input_time_length = 450
    n_classes = 2
    in_chans = train_set.X.shape[1]
    # final_conv_length determines the size of the receptive field of the ConvNet
    model = ShallowFBCSPNet(
        in_chans=in_chans,
        n_classes=n_classes,
        input_time_length=input_time_length,
        final_conv_length=12,
    )
    to_dense_prediction_model(model)

    if cuda:
        model.cuda()

    optimizer = optim.Adam(model.parameters())
    # determine output size
    test_input = np_to_var(
        np.ones((2, in_chans, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    print("{:d} predictions per input/trial".format(n_preds_per_input))

    iterator = CropsFromTrialsIterator(
        batch_size=32,
        input_time_length=input_time_length,
        n_preds_per_input=n_preds_per_input,
    )

    losses = []
    accuracies = []
    for i_epoch in range(4):
        # Set model to training mode
        model.train()
        for batch_X, batch_y in iterator.get_batches(train_set, shuffle=False):
            net_in = np_to_var(batch_X)
            if cuda:
                net_in = net_in.cuda()
            net_target = np_to_var(batch_y)
            if cuda:
                net_target = net_target.cuda()
            # Remove gradients of last backward pass from all parameters
            optimizer.zero_grad()
            outputs = model(net_in)
            # Mean predictions across trial
            # Note that this will give identical gradients to computing
            # a per-prediction loss (at least for the combination of log softmax activation
            # and negative log likelihood loss which we are using here)
            outputs = th.mean(outputs, dim=2, keepdim=False)
            loss = F.nll_loss(outputs, net_target)
            loss.backward()
            optimizer.step()

        # Print some statistics each epoch
        model.eval()
        print("Epoch {:d}".format(i_epoch))
        for setname, dataset in (("Train", train_set), ("Test", test_set)):
            # Collect all predictions and losses
            all_preds = []
            all_losses = []
            batch_sizes = []
            for batch_X, batch_y in iterator.get_batches(dataset,
                                                         shuffle=False):
                net_in = np_to_var(batch_X)
                if cuda:
                    net_in = net_in.cuda()
                net_target = np_to_var(batch_y)
                if cuda:
                    net_target = net_target.cuda()
                outputs = model(net_in)
                all_preds.append(var_to_np(outputs))
                outputs = th.mean(outputs, dim=2, keepdim=False)
                loss = F.nll_loss(outputs, net_target)
                loss = float(var_to_np(loss))
                all_losses.append(loss)
                batch_sizes.append(len(batch_X))
            # Compute mean per-input loss
            loss = np.mean(
                np.array(all_losses) * np.array(batch_sizes) /
                np.mean(batch_sizes))
            print("{:6s} Loss: {:.5f}".format(setname, loss))
            losses.append(loss)
            # Assign the predictions to the trials
            preds_per_trial = compute_preds_per_trial_from_crops(
                all_preds, input_time_length, dataset.X)
            # preds per trial are now trials x classes x timesteps/predictions
            # Now mean across timesteps for each trial to get per-trial predictions
            meaned_preds_per_trial = np.array(
                [np.mean(p, axis=1) for p in preds_per_trial])
            predicted_labels = np.argmax(meaned_preds_per_trial, axis=1)
            accuracy = np.mean(predicted_labels == dataset.y)
            accuracies.append(accuracy * 100)
            print("{:6s} Accuracy: {:.1f}%".format(setname, accuracy * 100))
    np.testing.assert_allclose(
        np.array(losses),
        np.array([
            1.31657708,
            1.73548156,
            1.02950428,
            1.43932164,
            0.78677772,
            1.12382019,
            0.55920881,
            0.87277424,
        ]),
        rtol=1e-4,
        atol=1e-5,
    )
    np.testing.assert_allclose(
        np.array(accuracies),
        np.array([
            50.0,
            46.66666667,
            50.0,
            46.66666667,
            50.0,
            46.66666667,
            66.66666667,
            50.0,
        ]),
        rtol=1e-4,
        atol=1e-5,
    )
示例#9
0
def run_exp(data_folder, subject_id, low_cut_hz, model, cuda):
    train_filename = 'A{:01d}T.gdf'.format(subject_id)
    test_filename = 'A{:01d}E.gdf'.format(subject_id)

    train_filepath = os.path.join(data_folder, train_filename)
    test_filepath = os.path.join(data_folder, test_filename)

    train_label_filepath = train_filepath.replace('.gdf', '.mat')

    test_label_filepath = test_filepath.replace('.gdf', '.mat')

    train_loader = BCICompetition4Set2A(
        train_filepath, labels_filename=train_label_filepath)
    test_loader = BCICompetition4Set2A(
        test_filepath, labels_filename=test_label_filepath)
    #print(train_loader)
    train_cnt = train_loader.load()
    test_cnt = test_loader.load()

    # Preprocessing

    train_cnt = train_cnt.drop_channels(['STI 014', 'EOG-left',
                                         'EOG-central', 'EOG-right'])
    assert len(train_cnt.ch_names) == 22
    # lets convert to millvolt for numerical stability of next operations
    train_cnt = mne_apply(lambda a: a * 1e6, train_cnt)
    train_cnt = mne_apply(
        lambda a: bandpass_cnt(a, low_cut_hz, 38, train_cnt.info['sfreq'],
                               filt_order=3,
                               axis=1), train_cnt)
    train_cnt = mne_apply(
        lambda a: exponential_running_standardize(a.T, factor_new=1e-3,
                                                  init_block_size=1000,
                                                  eps=1e-4).T,
        train_cnt)

    test_cnt = test_cnt.drop_channels(['STI 014', 'EOG-left',
                                       'EOG-central', 'EOG-right'])
    assert len(test_cnt.ch_names) == 22
    test_cnt = mne_apply(lambda a: a * 1e6, test_cnt)
    test_cnt = mne_apply(
        lambda a: bandpass_cnt(a, low_cut_hz, 38, test_cnt.info['sfreq'],
                               filt_order=3,
                               axis=1), test_cnt)
    test_cnt = mne_apply(
        lambda a: exponential_running_standardize(a.T, factor_new=1e-3,
                                                  init_block_size=1000,
                                                  eps=1e-4).T,
        test_cnt)

    marker_def = OrderedDict([('Left Hand', [1]), ('Right Hand', [2],),
                              ('Foot', [3]), ('Tongue', [4])])
    ival = [-500, 4000]

    train_set = create_signal_target_from_raw_mne(train_cnt, marker_def, ival)
    test_set = create_signal_target_from_raw_mne(test_cnt, marker_def, ival)

    train_set, valid_set = split_into_two_sets(train_set,
                                               first_set_fraction=0.8)

    set_random_seeds(seed=20190706, cuda=cuda)

    n_classes = 4
    n_chans = int(train_set.X.shape[1])
    input_time_length=1000
    if model == 'shallow':
        model = ShallowFBCSPNet(n_chans, n_classes, input_time_length=input_time_length,
                            final_conv_length=30).create_network()
    elif model == 'deep':
        model = Deep4Net(n_chans, n_classes, input_time_length=input_time_length,
                            final_conv_length=2).create_network()


    to_dense_prediction_model(model)
    if cuda:
        model.cuda()

    log.info("Model: \n{:s}".format(str(model)))
    dummy_input = np_to_var(train_set.X[:1, :, :, None])
    if cuda:
        dummy_input = dummy_input.cuda()
    out = model(dummy_input)

    n_preds_per_input = out.cpu().data.numpy().shape[2]

    optimizer = optim.Adam(model.parameters())

    iterator = CropsFromTrialsIterator(batch_size=60,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)

    stop_criterion = Or([MaxEpochs(800),
                         NoDecrease('valid_misclass', 80)])

    monitors = [LossMonitor(), MisclassMonitor(col_suffix='sample_misclass'),
                CroppedTrialMisclassMonitor(
                    input_time_length=input_time_length), RuntimeMonitor()]

    model_constraint = MaxNormDefaultConstraint()

    loss_function = lambda preds, targets: F.nll_loss(
        th.mean(preds, dim=2, keepdim=False), targets)

    exp = Experiment(model, train_set, valid_set, test_set, iterator=iterator,
                     loss_function=loss_function, optimizer=optimizer,
                     model_constraint=model_constraint,
                     monitors=monitors,
                     stop_criterion=stop_criterion,
                     remember_best_column='valid_misclass',
                     run_after_early_stop=True, cuda=cuda)
    exp.run()
    return exp
def run_exp(
    data_folders,
    n_recordings,
    sensor_types,
    n_chans,
    max_recording_mins,
    sec_to_cut,
    duration_recording_mins,
    test_recording_mins,
    max_abs_val,
    sampling_freq,
    divisor,
    test_on_eval,
    n_folds,
    i_test_fold,
    shuffle,
    model_name,
    n_start_chans,
    n_chan_factor,
    input_time_length,
    final_conv_length,
    model_constraint,
    init_lr,
    batch_size,
    max_epochs,
    cuda,
):

    import torch.backends.cudnn as cudnn
    cudnn.benchmark = True
    preproc_functions = []
    preproc_functions.append(lambda data, fs: (
        data[:, int(sec_to_cut * fs):-int(sec_to_cut * fs)], fs))
    preproc_functions.append(lambda data, fs: (data[:, :int(
        duration_recording_mins * 60 * fs)], fs))
    if max_abs_val is not None:
        preproc_functions.append(
            lambda data, fs: (np.clip(data, -max_abs_val, max_abs_val), fs))

    preproc_functions.append(lambda data, fs: (resampy.resample(
        data, fs, sampling_freq, axis=1, filter='kaiser_fast'), sampling_freq))

    if divisor is not None:
        preproc_functions.append(lambda data, fs: (data / divisor, fs))

    dataset = DiagnosisSet(n_recordings=n_recordings,
                           max_recording_mins=max_recording_mins,
                           preproc_functions=preproc_functions,
                           data_folders=data_folders,
                           train_or_eval='train',
                           sensor_types=sensor_types)
    if test_on_eval:
        if test_recording_mins is None:
            test_recording_mins = duration_recording_mins
        test_preproc_functions = copy(preproc_functions)
        test_preproc_functions[1] = lambda data, fs: (data[:, :int(
            test_recording_mins * 60 * fs)], fs)
        test_dataset = DiagnosisSet(n_recordings=n_recordings,
                                    max_recording_mins=None,
                                    preproc_functions=test_preproc_functions,
                                    data_folders=data_folders,
                                    train_or_eval='eval',
                                    sensor_types=sensor_types)
    X, y = dataset.load()
    max_shape = np.max([list(x.shape) for x in X], axis=0)
    assert max_shape[1] == int(duration_recording_mins * sampling_freq * 60)
    if test_on_eval:
        test_X, test_y = test_dataset.load()
        max_shape = np.max([list(x.shape) for x in test_X], axis=0)
        assert max_shape[1] == int(test_recording_mins * sampling_freq * 60)
    if not test_on_eval:
        splitter = TrainValidTestSplitter(n_folds,
                                          i_test_fold,
                                          shuffle=shuffle)
        train_set, valid_set, test_set = splitter.split(X, y)
    else:
        splitter = TrainValidSplitter(n_folds,
                                      i_valid_fold=i_test_fold,
                                      shuffle=shuffle)
        train_set, valid_set = splitter.split(X, y)
        test_set = SignalAndTarget(test_X, test_y)
        del test_X, test_y
    del X, y  # shouldn't be necessary, but just to make sure

    set_random_seeds(seed=20170629, cuda=cuda)
    n_classes = 2
    if model_name == 'shallow':
        model = ShallowFBCSPNet(
            in_chans=n_chans,
            n_classes=n_classes,
            n_filters_time=n_start_chans,
            n_filters_spat=n_start_chans,
            input_time_length=input_time_length,
            final_conv_length=final_conv_length).create_network()
    elif model_name == 'deep':
        model = Deep4Net(n_chans,
                         n_classes,
                         n_filters_time=n_start_chans,
                         n_filters_spat=n_start_chans,
                         input_time_length=input_time_length,
                         n_filters_2=int(n_start_chans * n_chan_factor),
                         n_filters_3=int(n_start_chans * (n_chan_factor**2.0)),
                         n_filters_4=int(n_start_chans * (n_chan_factor**3.0)),
                         final_conv_length=final_conv_length,
                         stride_before_pool=True).create_network()
    elif (model_name == 'deep_smac'):
        if model_name == 'deep_smac':
            do_batch_norm = False
        else:
            assert model_name == 'deep_smac_bnorm'
            do_batch_norm = True
        double_time_convs = False
        drop_prob = 0.244445
        filter_length_2 = 12
        filter_length_3 = 14
        filter_length_4 = 12
        filter_time_length = 21
        final_conv_length = 1
        first_nonlin = elu
        first_pool_mode = 'mean'
        first_pool_nonlin = identity
        later_nonlin = elu
        later_pool_mode = 'mean'
        later_pool_nonlin = identity
        n_filters_factor = 1.679066
        n_filters_start = 32
        pool_time_length = 1
        pool_time_stride = 2
        split_first_layer = True
        n_chan_factor = n_filters_factor
        n_start_chans = n_filters_start
        model = Deep4Net(n_chans,
                         n_classes,
                         n_filters_time=n_start_chans,
                         n_filters_spat=n_start_chans,
                         input_time_length=input_time_length,
                         n_filters_2=int(n_start_chans * n_chan_factor),
                         n_filters_3=int(n_start_chans * (n_chan_factor**2.0)),
                         n_filters_4=int(n_start_chans * (n_chan_factor**3.0)),
                         final_conv_length=final_conv_length,
                         batch_norm=do_batch_norm,
                         double_time_convs=double_time_convs,
                         drop_prob=drop_prob,
                         filter_length_2=filter_length_2,
                         filter_length_3=filter_length_3,
                         filter_length_4=filter_length_4,
                         filter_time_length=filter_time_length,
                         first_nonlin=first_nonlin,
                         first_pool_mode=first_pool_mode,
                         first_pool_nonlin=first_pool_nonlin,
                         later_nonlin=later_nonlin,
                         later_pool_mode=later_pool_mode,
                         later_pool_nonlin=later_pool_nonlin,
                         pool_time_length=pool_time_length,
                         pool_time_stride=pool_time_stride,
                         split_first_layer=split_first_layer,
                         stride_before_pool=True).create_network()
    elif model_name == 'shallow_smac':
        conv_nonlin = identity
        do_batch_norm = True
        drop_prob = 0.328794
        filter_time_length = 56
        final_conv_length = 22
        n_filters_spat = 73
        n_filters_time = 24
        pool_mode = 'max'
        pool_nonlin = identity
        pool_time_length = 84
        pool_time_stride = 3
        split_first_layer = True
        model = ShallowFBCSPNet(
            in_chans=n_chans,
            n_classes=n_classes,
            n_filters_time=n_filters_time,
            n_filters_spat=n_filters_spat,
            input_time_length=input_time_length,
            final_conv_length=final_conv_length,
            conv_nonlin=conv_nonlin,
            batch_norm=do_batch_norm,
            drop_prob=drop_prob,
            filter_time_length=filter_time_length,
            pool_mode=pool_mode,
            pool_nonlin=pool_nonlin,
            pool_time_length=pool_time_length,
            pool_time_stride=pool_time_stride,
            split_first_layer=split_first_layer,
        ).create_network()
    elif model_name == 'linear':
        model = nn.Sequential()
        model.add_module("conv_classifier",
                         nn.Conv2d(n_chans, n_classes, (600, 1)))
        model.add_module('softmax', nn.LogSoftmax())
        model.add_module('squeeze', Expression(lambda x: x.squeeze(3)))
    else:
        assert False, "unknown model name {:s}".format(model_name)
    to_dense_prediction_model(model)
    log.info("Model:\n{:s}".format(str(model)))
    if cuda:
        model.cuda()
    # determine output size
    test_input = np_to_var(
        np.ones((2, n_chans, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    log.info("In shape: {:s}".format(str(test_input.cpu().data.numpy().shape)))

    out = model(test_input)
    log.info("Out shape: {:s}".format(str(out.cpu().data.numpy().shape)))
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    log.info("{:d} predictions per input/trial".format(n_preds_per_input))
    iterator = CropsFromTrialsIterator(batch_size=batch_size,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)
    optimizer = optim.Adam(model.parameters(), lr=init_lr)

    loss_function = lambda preds, targets: F.nll_loss(
        th.mean(preds, dim=2, keepdim=False), targets)

    if model_constraint is not None:
        assert model_constraint == 'defaultnorm'
        model_constraint = MaxNormDefaultConstraint()
    monitors = [
        LossMonitor(),
        MisclassMonitor(col_suffix='sample_misclass'),
        CroppedDiagnosisMonitor(input_time_length, n_preds_per_input),
        RuntimeMonitor(),
    ]
    stop_criterion = MaxEpochs(max_epochs)
    batch_modifier = None
    run_after_early_stop = True
    exp = Experiment(model,
                     train_set,
                     valid_set,
                     test_set,
                     iterator,
                     loss_function,
                     optimizer,
                     model_constraint,
                     monitors,
                     stop_criterion,
                     remember_best_column='valid_misclass',
                     run_after_early_stop=run_after_early_stop,
                     batch_modifier=batch_modifier,
                     cuda=cuda)
    exp.run()
    return exp
def fit_transform_2(model,
                    optimizer,
                    train_data,
                    y_train,
                    test_data,
                    y_test,
                    num_epochs=20,
                    n_channels=22,
                    input_time_length=500):

    train_set = SignalAndTarget(train_data, y=y_train)
    test_set = SignalAndTarget(test_data, y=y_test)

    # # # # # # # # CREATE CROPPED ITERATOR # # # # # # # # #

    # determine output size
    test_input = np_to_var(
        np.ones((2, n_channels, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]

    iterator = CropsFromTrialsIterator(batch_size=32,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)

    accuracy_out = []
    min_loss = 1000
    for i_epoch in range(num_epochs):
        # Set model to training mode
        model.train()
        for batch_X, batch_y in iterator.get_batches(train_set, shuffle=False):
            net_in = np_to_var(batch_X)
            if cuda:
                net_in = net_in.cuda()
            # print(batch_y)
            net_target = np_to_var(batch_y)
            if cuda:
                net_target = net_target.cuda()
            # Remove gradients of last backward pass from all parameters
            optimizer.zero_grad()
            outputs = model(net_in)
            # Mean predictions across trial
            # Note that this will give identical gradients to computing
            # a per-prediction loss (at least for the combination of log softmax activation
            # and negative log likelihood loss which we are using here)
            outputs = th.mean(outputs, dim=2, keepdim=False)
            loss = F.nll_loss(outputs, net_target)
            loss.backward()
            optimizer.step()

        # Print some statistics each epoch
        model.eval()
        # print("Epoch {:d}".format(i_epoch))
        for setname, dataset in (('Train', train_set), ('Test', test_set)):
            # Collect all predictions and losses
            all_preds = []
            all_losses = []
            batch_sizes = []
            for batch_X, batch_y in iterator.get_batches(dataset,
                                                         shuffle=False):
                net_in = np_to_var(batch_X)
                if cuda:
                    net_in = net_in.cuda()
                net_target = np_to_var(batch_y)
                if cuda:
                    net_target = net_target.cuda()
                outputs = model(net_in)
                all_preds.append(var_to_np(outputs))
                outputs = th.mean(outputs, dim=2, keepdim=False)
                loss = F.nll_loss(outputs, net_target)
                loss = float(var_to_np(loss))
                all_losses.append(loss)
                batch_sizes.append(len(batch_X))
            # Compute mean per-input loss
            loss = np.mean(
                np.array(all_losses) * np.array(batch_sizes) /
                np.mean(batch_sizes))
            # print("{:6s} Loss: {:.5f}".format(setname, loss))
            # Assign the predictions to the trials
            preds_per_trial = compute_preds_per_trial_from_crops(
                all_preds, input_time_length, dataset.X)
            # preds per trial are now trials x classes x timesteps/predictions
            # Now mean across timesteps for each trial to get per-trial predictions
            meaned_preds_per_trial = np.array(
                [np.mean(p, axis=1) for p in preds_per_trial])
            predicted_labels = np.argmax(meaned_preds_per_trial, axis=1)
            accuracy = np.mean(predicted_labels == dataset.y)
            # print("{:6s} Accuracy: {:.2f}%".format(setname, accuracy * 100))
            if setname == 'Test':
                accuracy_out.append(accuracy)
                if loss < min_loss:
                    min_loss = loss
                elif loss > min_loss * 1.1:
                    print("Training Stopping")
                    return model, np.asarray(accuracy_out)

    return model, np.asarray(accuracy_out)
示例#12
0
def runModel(mode):
    cudnn.benchmark = True

    start = time.time()

    #mode = str(sys.argv[1])
    #X,y,test_X,test_y = loadSubNormData(mode='all')
    #X,y,test_X,test_y = loadNEDCdata(mode=mode)

    #data = np.load('sessionsData/data%s-sessions.npy'%mode[:3])
    #labels = np.load('sessionsData/labels%s-sessions.npy'%mode[:3])

    data = np.load('data%s.npy' % mode[:3])
    labels = np.load('labels%s.npy' % mode[:3])

    X, y, test_X, test_y = splitDataRandom_Loaded(data, labels, mode)

    print('Mode - %s Total n: %d, Test n: %d' %
          (mode, len(y) + len(test_y), len(test_y)))
    #return 0

    #X = addDataNoise(X,band=[1,4])
    #test_X = addDataNoise(test_X,band=[1,4])

    max_shape = np.max([list(x.shape) for x in X], axis=0)

    assert max_shape[1] == int(config.duration_recording_mins *
                               config.sampling_freq * 60)

    n_classes = 2
    n_recordings = None  # set to an integer, if you want to restrict the set size
    sensor_types = ["EEG"]
    n_chans = 19  #21
    max_recording_mins = 35  # exclude larger recordings from training set
    sec_to_cut = 60  # cut away at start of each recording
    duration_recording_mins = 5  #20  # how many minutes to use per recording
    test_recording_mins = 5  #20
    max_abs_val = 800  # for clipping
    sampling_freq = 100
    divisor = 10  # divide signal by this
    test_on_eval = True  # teston evaluation set or on training set
    # in case of test on eval, n_folds and i_testfold determine
    # validation fold in training set for training until first stop
    n_folds = 10
    i_test_fold = 9
    shuffle = True
    model_name = 'linear'  #'deep'#'shallow' 'linear'
    n_start_chans = 25
    n_chan_factor = 2  # relevant for deep model only
    input_time_length = 6000
    final_conv_length = 1
    model_constraint = 'defaultnorm'
    init_lr = 1e-3
    batch_size = 64
    max_epochs = 35  # until first stop, the continue train on train+valid
    cuda = True  # False

    if model_name == 'shallow':
        model = ShallowFBCSPNet(
            in_chans=n_chans,
            n_classes=n_classes,
            n_filters_time=n_start_chans,
            n_filters_spat=n_start_chans,
            input_time_length=input_time_length,
            final_conv_length=final_conv_length).create_network()
    elif model_name == 'deep':
        model = Deep4Net(n_chans,
                         n_classes,
                         n_filters_time=n_start_chans,
                         n_filters_spat=n_start_chans,
                         input_time_length=input_time_length,
                         n_filters_2=int(n_start_chans * n_chan_factor),
                         n_filters_3=int(n_start_chans * (n_chan_factor**2.0)),
                         n_filters_4=int(n_start_chans * (n_chan_factor**3.0)),
                         final_conv_length=final_conv_length,
                         stride_before_pool=True).create_network()
    elif (model_name == 'deep_smac'):
        if model_name == 'deep_smac':
            do_batch_norm = False
        else:
            assert model_name == 'deep_smac_bnorm'
            do_batch_norm = True
        double_time_convs = False
        drop_prob = 0.244445
        filter_length_2 = 12
        filter_length_3 = 14
        filter_length_4 = 12
        filter_time_length = 21
        final_conv_length = 1
        first_nonlin = elu
        first_pool_mode = 'mean'
        first_pool_nonlin = identity
        later_nonlin = elu
        later_pool_mode = 'mean'
        later_pool_nonlin = identity
        n_filters_factor = 1.679066
        n_filters_start = 32
        pool_time_length = 1
        pool_time_stride = 2
        split_first_layer = True
        n_chan_factor = n_filters_factor
        n_start_chans = n_filters_start
        model = Deep4Net(n_chans,
                         n_classes,
                         n_filters_time=n_start_chans,
                         n_filters_spat=n_start_chans,
                         input_time_length=input_time_length,
                         n_filters_2=int(n_start_chans * n_chan_factor),
                         n_filters_3=int(n_start_chans * (n_chan_factor**2.0)),
                         n_filters_4=int(n_start_chans * (n_chan_factor**3.0)),
                         final_conv_length=final_conv_length,
                         batch_norm=do_batch_norm,
                         double_time_convs=double_time_convs,
                         drop_prob=drop_prob,
                         filter_length_2=filter_length_2,
                         filter_length_3=filter_length_3,
                         filter_length_4=filter_length_4,
                         filter_time_length=filter_time_length,
                         first_nonlin=first_nonlin,
                         first_pool_mode=first_pool_mode,
                         first_pool_nonlin=first_pool_nonlin,
                         later_nonlin=later_nonlin,
                         later_pool_mode=later_pool_mode,
                         later_pool_nonlin=later_pool_nonlin,
                         pool_time_length=pool_time_length,
                         pool_time_stride=pool_time_stride,
                         split_first_layer=split_first_layer,
                         stride_before_pool=True).create_network()
    elif model_name == 'shallow_smac':
        conv_nonlin = identity
        do_batch_norm = True
        drop_prob = 0.328794
        filter_time_length = 56
        final_conv_length = 22
        n_filters_spat = 73
        n_filters_time = 24
        pool_mode = 'max'
        pool_nonlin = identity
        pool_time_length = 84
        pool_time_stride = 3
        split_first_layer = True
        model = ShallowFBCSPNet(
            in_chans=n_chans,
            n_classes=n_classes,
            n_filters_time=n_filters_time,
            n_filters_spat=n_filters_spat,
            input_time_length=input_time_length,
            final_conv_length=final_conv_length,
            conv_nonlin=conv_nonlin,
            batch_norm=do_batch_norm,
            drop_prob=drop_prob,
            filter_time_length=filter_time_length,
            pool_mode=pool_mode,
            pool_nonlin=pool_nonlin,
            pool_time_length=pool_time_length,
            pool_time_stride=pool_time_stride,
            split_first_layer=split_first_layer,
        ).create_network()
    elif model_name == 'linear':
        model = nn.Sequential()
        model.add_module("conv_classifier",
                         nn.Conv2d(n_chans, n_classes, (600, 1)))
        model.add_module('softmax', nn.LogSoftmax(dim=1))
        model.add_module('squeeze', Expression(lambda x: x.squeeze(3)))
    else:
        assert False, "unknown model name {:s}".format(model_name)

    to_dense_prediction_model(model)

    if config.cuda:
        model.cuda()
    test_input = np_to_var(
        np.ones((2, config.n_chans, config.input_time_length, 1),
                dtype=np.float32))
    if config.cuda:
        test_input = test_input.cuda()

    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    iterator = CropsFromTrialsIterator(
        batch_size=config.batch_size,
        input_time_length=config.input_time_length,
        n_preds_per_input=n_preds_per_input)

    #model.add_module('softmax', nn.LogSoftmax(dim=1))

    model.eval()

    mode[2] = str(mode[2])
    mode[3] = str(mode[3])
    modelName = '-'.join(mode[:4])

    #params = th.load('sessionsData/%sModel%s-sessions.pt'%(modelName,mode[4]))
    #params = th.load('%sModel%s.pt'%(modelName,mode[4]))
    params = th.load('linear/%sModel%s.pt' % (modelName, mode[4]))

    model.load_state_dict(params)

    if config.test_on_eval:
        #test_X, test_y = test_dataset.load()
        #test_X, test_y = loadNEDCdata(mode='eval')
        max_shape = np.max([list(x.shape) for x in test_X], axis=0)
        assert max_shape[1] == int(config.test_recording_mins *
                                   config.sampling_freq * 60)
    if not config.test_on_eval:
        splitter = TrainValidTestSplitter(config.n_folds,
                                          config.i_test_fold,
                                          shuffle=config.shuffle)
        train_set, valid_set, test_set = splitter.split(X, y)
    else:
        splitter = TrainValidSplitter(config.n_folds,
                                      i_valid_fold=config.i_test_fold,
                                      shuffle=config.shuffle)
        train_set, valid_set = splitter.split(X, y)
        test_set = SignalAndTarget(test_X, test_y)
        del test_X, test_y
    del X, y  # shouldn't be necessary, but just to make sure

    datasets = OrderedDict(
        (('train', train_set), ('valid', valid_set), ('test', test_set)))

    for setname in ('train', 'valid', 'test'):
        #setname = 'test'
        #print("Compute predictions for {:s}...".format(setname))
        dataset = datasets[setname]
        if config.cuda:
            preds_per_batch = [
                var_to_np(model(np_to_var(b[0]).cuda()))
                for b in iterator.get_batches(dataset, shuffle=False)
            ]
        else:
            preds_per_batch = [
                var_to_np(model(np_to_var(b[0])))
                for b in iterator.get_batches(dataset, shuffle=False)
            ]
        preds_per_trial = compute_preds_per_trial(
            preds_per_batch,
            dataset,
            input_time_length=iterator.input_time_length,
            n_stride=iterator.n_preds_per_input)
        mean_preds_per_trial = [
            np.mean(preds, axis=(0, 2)) for preds in preds_per_trial
        ]
        mean_preds_per_trial = np.array(mean_preds_per_trial)

        all_pred_labels = np.argmax(mean_preds_per_trial, axis=1).squeeze()
        all_target_labels = dataset.y
        acc_per_class = []
        for i_class in range(n_classes):
            mask = all_target_labels == i_class
            acc = np.mean(all_pred_labels[mask] == all_target_labels[mask])
            acc_per_class.append(acc)
        misclass = 1 - np.mean(acc_per_class)
        #print('Acc:{}, Class 0:{}, Class 1:{}'.format(np.mean(acc_per_class),acc_per_class[0],acc_per_class[1]))

        if setname == 'test':
            testResult = np.mean(acc_per_class)

    return testResult
def run_exp(max_recording_mins, n_recordings, sec_to_cut,
            duration_recording_mins, max_abs_val, max_min_threshold,
            max_min_expected, shrink_val, max_min_remove, batch_set_zero_val,
            batch_set_zero_test, sampling_freq, low_cut_hz, high_cut_hz,
            exp_demean, exp_standardize, moving_demean, moving_standardize,
            channel_demean, channel_standardize, divisor, n_folds, i_test_fold,
            input_time_length, final_conv_length, pool_stride, n_blocks_to_add,
            sigmoid, model_constraint, batch_size, max_epochs,
            only_return_exp):
    cuda = True

    preproc_functions = []
    preproc_functions.append(lambda data, fs: (
        data[:, int(sec_to_cut * fs):-int(sec_to_cut * fs)], fs))
    preproc_functions.append(lambda data, fs: (data[:, :int(
        duration_recording_mins * 60 * fs)], fs))
    if max_abs_val is not None:
        preproc_functions.append(
            lambda data, fs: (np.clip(data, -max_abs_val, max_abs_val), fs))
    if max_min_threshold is not None:
        preproc_functions.append(lambda data, fs: (clean_jumps(
            data, 200, max_min_threshold, max_min_expected, cuda), fs))
    if max_min_remove is not None:
        window_len = 200
        preproc_functions.append(lambda data, fs: (set_jumps_to_zero(
            data,
            window_len=window_len,
            threshold=max_min_remove,
            cuda=cuda,
            clip_min_max_to_zero=True), fs))

    if shrink_val is not None:
        preproc_functions.append(lambda data, fs: (shrink_spikes(
            data,
            shrink_val,
            1,
            9,
        ), fs))

    preproc_functions.append(lambda data, fs: (resampy.resample(
        data, fs, sampling_freq, axis=1, filter='kaiser_fast'), sampling_freq))
    preproc_functions.append(lambda data, fs: (bandpass_cnt(
        data, low_cut_hz, high_cut_hz, fs, filt_order=4, axis=1), fs))

    if exp_demean:
        preproc_functions.append(lambda data, fs: (exponential_running_demean(
            data.T, factor_new=0.001, init_block_size=100).T, fs))
    if exp_standardize:
        preproc_functions.append(
            lambda data, fs: (exponential_running_standardize(
                data.T, factor_new=0.001, init_block_size=100).T, fs))
    if moving_demean:
        preproc_functions.append(lambda data, fs: (padded_moving_demean(
            data, axis=1, n_window=201), fs))
    if moving_standardize:
        preproc_functions.append(lambda data, fs: (padded_moving_standardize(
            data, axis=1, n_window=201), fs))
    if channel_demean:
        preproc_functions.append(lambda data, fs: (demean(data, axis=1), fs))
    if channel_standardize:
        preproc_functions.append(lambda data, fs:
                                 (standardize(data, axis=1), fs))
    if divisor is not None:
        preproc_functions.append(lambda data, fs: (data / divisor, fs))

    dataset = DiagnosisSet(n_recordings=n_recordings,
                           max_recording_mins=max_recording_mins,
                           preproc_functions=preproc_functions)
    if not only_return_exp:
        X, y = dataset.load()

    splitter = Splitter(
        n_folds,
        i_test_fold,
    )
    if not only_return_exp:
        train_set, valid_set, test_set = splitter.split(X, y)
        del X, y  # shouldn't be necessary, but just to make sure
    else:
        train_set = None
        valid_set = None
        test_set = None

    set_random_seeds(seed=20170629, cuda=cuda)
    if sigmoid:
        n_classes = 1
    else:
        n_classes = 2
    in_chans = 21

    net = Deep4Net(
        in_chans=in_chans,
        n_classes=n_classes,
        input_time_length=input_time_length,
        final_conv_length=final_conv_length,
        pool_time_length=pool_stride,
        pool_time_stride=pool_stride,
        n_filters_2=50,
        n_filters_3=80,
        n_filters_4=120,
    )
    model = net_with_more_layers(net, n_blocks_to_add, nn.MaxPool2d)
    if sigmoid:
        model = to_linear_plus_minus_net(model)
    optimizer = optim.Adam(model.parameters())
    to_dense_prediction_model(model)
    log.info("Model:\n{:s}".format(str(model)))
    if cuda:
        model.cuda()
    # determine output size
    test_input = np_to_var(
        np.ones((2, in_chans, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    log.info("{:d} predictions per input/trial".format(n_preds_per_input))
    iterator = CropsFromTrialsIterator(batch_size=batch_size,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)
    if sigmoid:
        loss_function = lambda preds, targets: binary_cross_entropy_with_logits(
            th.mean(preds, dim=2)[:, 1, 0], targets.type_as(preds))
    else:
        loss_function = lambda preds, targets: F.nll_loss(
            th.mean(preds, dim=2)[:, :, 0], targets)

    if model_constraint is not None:
        model_constraint = MaxNormDefaultConstraint()
    monitors = [
        LossMonitor(),
        MisclassMonitor(col_suffix='sample_misclass'),
        CroppedTrialMisclassMonitor(input_time_length),
        RuntimeMonitor(),
    ]
    stop_criterion = MaxEpochs(max_epochs)
    batch_modifier = None
    if batch_set_zero_val is not None:
        batch_modifier = RemoveMinMaxDiff(batch_set_zero_val,
                                          clip_max_abs=True,
                                          set_zero=True)
    if (batch_set_zero_val is not None) and (batch_set_zero_test == True):
        iterator = ModifiedIterator(
            iterator,
            batch_modifier,
        )
        batch_modifier = None
    exp = Experiment(model,
                     train_set,
                     valid_set,
                     test_set,
                     iterator,
                     loss_function,
                     optimizer,
                     model_constraint,
                     monitors,
                     stop_criterion,
                     remember_best_column='valid_misclass',
                     run_after_early_stop=True,
                     batch_modifier=batch_modifier,
                     cuda=cuda)
    if not only_return_exp:
        exp.run()
    else:
        exp.dataset = dataset
        exp.splitter = splitter

    return exp
示例#14
0
文件: croped.py 项目: sd12037/pytorch
if cuda:
    model.cuda()

optimizer = optim.Adam(model.parameters())

# determine output size
test_input = np_to_var(
    np.ones((2, in_chans, input_time_length, 1), dtype=np.float32))
if cuda:
    test_input = test_input.cuda()
out = model(test_input)
n_preds_per_input = out.cpu().data.numpy().shape[2]
print("{:d} predictions per input/trial".format(n_preds_per_input))

iterator = CropsFromTrialsIterator(batch_size=16,
                                   input_time_length=input_time_length,
                                   n_preds_per_input=n_preds_per_input)

rng = RandomState((2017, 6, 30))
for i_epoch in range(20):
    # Set model to training mode
    model.train()
    for batch_X, batch_y in iterator.get_batches(train_set, shuffle=False):

        net_in = np_to_var(batch_X)
        if cuda:
            net_in = net_in.cuda()
        net_target = np_to_var(batch_y)
        if cuda:
            net_target = net_target.cuda()
        # Remove gradients of last backward pass from all parameters
示例#15
0
    def fit(self,
            train_X,
            train_y,
            epochs,
            batch_size,
            input_time_length=None,
            validation_data=None,
            model_constraint=None,
            remember_best_column=None,
            scheduler=None):
        if not self.compiled:
            raise ValueError(
                "Compile the model first by calling model.compile(loss, optimizer, metrics)"
            )

        if self.cropped and input_time_length is None:
            raise ValueError(
                "In cropped mode, need to specify input_time_length,"
                "which is the number of timesteps that will be pushed through"
                "the network in a single pass.")
        if self.cropped:
            test_input = np_to_var(train_X[0:1], dtype=np.float32)
            while len(test_input.size()) < 4:
                test_input = test_input.unsqueeze(-1)
            if self.cuda:
                test_input = test_input.cuda()
            out = self.network(test_input)
            n_preds_per_input = out.cpu().data.numpy().shape[2]
            iterator = CropsFromTrialsIterator(
                batch_size=batch_size,
                input_time_length=input_time_length,
                n_preds_per_input=n_preds_per_input,
                seed=self.seed_rng.randint(0, 4294967295))
        else:
            iterator = BalancedBatchSizeIterator(batch_size=batch_size,
                                                 seed=self.seed_rng.randint(
                                                     0, 4294967295))
        stop_criterion = MaxEpochs(
            epochs - 1
        )  # -1 since we dont print 0 epoch, which matters for this stop criterion
        train_set = SignalAndTarget(train_X, train_y)
        optimizer = self.optimizer
        if scheduler is not None:
            assert scheduler == 'cosine'
            n_updates_per_epoch = sum(
                [1 for _ in iterator.get_batches(train_set, shuffle=True)])
            n_updates_per_period = n_updates_per_epoch * epochs
            if scheduler == 'cosine':
                scheduler = CosineAnnealing(n_updates_per_period)
            schedule_weight_decay = False
            if optimizer.__class__.__name__ == 'AdamW':
                schedule_weight_decay = True
            optimizer = ScheduledOptimizer(
                scheduler,
                self.optimizer,
                schedule_weight_decay=schedule_weight_decay)
        loss_function = self.loss
        if self.cropped:
            loss_function = lambda outputs, targets:\
                self.loss(th.mean(outputs, dim=2), targets)
        if validation_data is not None:
            valid_set = SignalAndTarget(validation_data[0], validation_data[1])
        else:
            valid_set = None
        test_set = None
        if self.cropped:
            monitor_dict = {
                'acc': lambda: CroppedTrialMisclassMonitor(input_time_length)
            }
        else:
            monitor_dict = {'acc': MisclassMonitor}
        self.monitors = [LossMonitor()]
        extra_monitors = [monitor_dict[m]() for m in self.metrics]
        self.monitors += extra_monitors
        self.monitors += [RuntimeMonitor()]
        exp = Experiment(self.network,
                         train_set,
                         valid_set,
                         test_set,
                         iterator=iterator,
                         loss_function=loss_function,
                         optimizer=optimizer,
                         model_constraint=model_constraint,
                         monitors=self.monitors,
                         stop_criterion=stop_criterion,
                         remember_best_column=remember_best_column,
                         run_after_early_stop=False,
                         cuda=self.cuda,
                         print_0_epoch=False,
                         do_early_stop=(remember_best_column is not None))
        exp.run()
        self.epochs_df = exp.epochs_df
        return exp
示例#16
0
def run_exp(max_recording_mins, n_recordings, sec_to_cut,
            duration_recording_mins, max_abs_val, max_min_threshold,
            max_min_expected, shrink_val, max_min_remove, batch_set_zero_val,
            batch_set_zero_test, sampling_freq, low_cut_hz, high_cut_hz,
            exp_demean, exp_standardize, moving_demean, moving_standardize,
            channel_demean, channel_standardize, divisor, n_folds, i_test_fold,
            model_name, input_time_length, final_conv_length, batch_size,
            max_epochs, only_return_exp):
    cuda = True

    preproc_functions = []
    preproc_functions.append(lambda data, fs: (
        data[:, int(sec_to_cut * fs):-int(sec_to_cut * fs)], fs))
    preproc_functions.append(lambda data, fs: (data[:, :int(
        duration_recording_mins * 60 * fs)], fs))
    if max_abs_val is not None:
        preproc_functions.append(
            lambda data, fs: (np.clip(data, -max_abs_val, max_abs_val), fs))
    if max_min_threshold is not None:
        preproc_functions.append(lambda data, fs: (clean_jumps(
            data, 200, max_min_threshold, max_min_expected, cuda), fs))
    if max_min_remove is not None:
        window_len = 200
        preproc_functions.append(lambda data, fs: (set_jumps_to_zero(
            data,
            window_len=window_len,
            threshold=max_min_remove,
            cuda=cuda,
            clip_min_max_to_zero=True), fs))

    if shrink_val is not None:
        preproc_functions.append(lambda data, fs: (shrink_spikes(
            data,
            shrink_val,
            1,
            9,
        ), fs))

    preproc_functions.append(lambda data, fs: (resampy.resample(
        data, fs, sampling_freq, axis=1, filter='kaiser_fast'), sampling_freq))
    preproc_functions.append(lambda data, fs: (bandpass_cnt(
        data, low_cut_hz, high_cut_hz, fs, filt_order=4, axis=1), fs))

    if exp_demean:
        preproc_functions.append(lambda data, fs: (exponential_running_demean(
            data.T, factor_new=0.001, init_block_size=100).T, fs))
    if exp_standardize:
        preproc_functions.append(
            lambda data, fs: (exponential_running_standardize(
                data.T, factor_new=0.001, init_block_size=100).T, fs))
    if moving_demean:
        preproc_functions.append(lambda data, fs: (padded_moving_demean(
            data, axis=1, n_window=201), fs))
    if moving_standardize:
        preproc_functions.append(lambda data, fs: (padded_moving_standardize(
            data, axis=1, n_window=201), fs))
    if channel_demean:
        preproc_functions.append(lambda data, fs: (demean(data, axis=1), fs))
    if channel_standardize:
        preproc_functions.append(lambda data, fs:
                                 (standardize(data, axis=1), fs))
    if divisor is not None:
        preproc_functions.append(lambda data, fs: (data / divisor, fs))

    all_file_names, labels = get_all_sorted_file_names_and_labels()
    lengths = np.load(
        '/home/schirrmr/code/auto-diagnosis/sorted-recording-lengths.npy')
    mask = lengths < max_recording_mins * 60
    cleaned_file_names = np.array(all_file_names)[mask]
    cleaned_labels = labels[mask]

    diffs_per_rec = np.load(
        '/home/schirrmr/code/auto-diagnosis/diffs_per_recording.npy')

    def create_set(inds):
        X = []
        for i in inds:
            log.info("Load {:s}".format(cleaned_file_names[i]))
            x = load_data(cleaned_file_names[i], preproc_functions)
            X.append(x)
        y = cleaned_labels[inds].astype(np.int64)
        return SignalAndTarget(X, y)

    if not only_return_exp:
        folds = get_balanced_batches(n_recordings,
                                     None,
                                     False,
                                     n_batches=n_folds)
        test_inds = folds[i_test_fold]
        valid_inds = folds[i_test_fold - 1]
        all_inds = list(range(n_recordings))
        train_inds = np.setdiff1d(all_inds, np.union1d(test_inds, valid_inds))

        rec_nr_sorted_by_diff = np.argsort(diffs_per_rec)[::-1]
        train_inds = rec_nr_sorted_by_diff[train_inds]
        valid_inds = rec_nr_sorted_by_diff[valid_inds]
        test_inds = rec_nr_sorted_by_diff[test_inds]

        train_set = create_set(train_inds)
        valid_set = create_set(valid_inds)
        test_set = create_set(test_inds)
    else:
        train_set = None
        valid_set = None
        test_set = None

    set_random_seeds(seed=20170629, cuda=cuda)
    # This will determine how many crops are processed in parallel
    n_classes = 2
    in_chans = 21
    if model_name == 'shallow':
        model = ShallowFBCSPNet(
            in_chans=in_chans,
            n_classes=n_classes,
            input_time_length=input_time_length,
            final_conv_length=final_conv_length).create_network()
    elif model_name == 'deep':
        model = Deep4Net(in_chans,
                         n_classes,
                         input_time_length=input_time_length,
                         final_conv_length=final_conv_length).create_network()

    optimizer = optim.Adam(model.parameters())
    to_dense_prediction_model(model)
    log.info("Model:\n{:s}".format(str(model)))
    if cuda:
        model.cuda()
    # determine output size
    test_input = np_to_var(
        np.ones((2, in_chans, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    log.info("{:d} predictions per input/trial".format(n_preds_per_input))
    iterator = CropsFromTrialsIterator(batch_size=batch_size,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)
    loss_function = lambda preds, targets: F.nll_loss(
        th.mean(preds, dim=2)[:, :, 0], targets)
    model_constraint = None
    monitors = [
        LossMonitor(),
        MisclassMonitor(col_suffix='sample_misclass'),
        CroppedTrialMisclassMonitor(input_time_length),
        RuntimeMonitor(),
    ]
    stop_criterion = MaxEpochs(max_epochs)
    batch_modifier = None
    if batch_set_zero_val is not None:
        batch_modifier = RemoveMinMaxDiff(batch_set_zero_val,
                                          clip_max_abs=True,
                                          set_zero=True)
    if (batch_set_zero_val is not None) and (batch_set_zero_test == True):
        iterator = ModifiedIterator(
            iterator,
            batch_modifier,
        )
        batch_modifier = None
    exp = Experiment(model,
                     train_set,
                     valid_set,
                     test_set,
                     iterator,
                     loss_function,
                     optimizer,
                     model_constraint,
                     monitors,
                     stop_criterion,
                     remember_best_column='valid_misclass',
                     run_after_early_stop=True,
                     batch_modifier=batch_modifier,
                     cuda=cuda)
    if not only_return_exp:
        exp.run()
    else:
        exp.dataset = None
        exp.splitter = None

    return exp
示例#17
0
def test_experiment_class():
    import mne
    from mne.io import concatenate_raws

    # 5,6,7,10,13,14 are codes for executed and imagined hands/feet
    subject_id = 1
    event_codes = [5, 6, 9, 10, 13, 14]

    # This will download the files if you don't have them yet,
    # and then return the paths to the files.
    physionet_paths = mne.datasets.eegbci.load_data(subject_id, event_codes)

    # Load each of the files
    parts = [
        mne.io.read_raw_edf(path,
                            preload=True,
                            stim_channel='auto',
                            verbose='WARNING') for path in physionet_paths
    ]

    # Concatenate them
    raw = concatenate_raws(parts)

    # Find the events in this dataset
    events = mne.find_events(raw, shortest_event=0, stim_channel='STI 014')

    # Use only EEG channels
    eeg_channel_inds = mne.pick_types(raw.info,
                                      meg=False,
                                      eeg=True,
                                      stim=False,
                                      eog=False,
                                      exclude='bads')

    # Extract trials, only using EEG channels
    epoched = mne.Epochs(raw,
                         events,
                         dict(hands=2, feet=3),
                         tmin=1,
                         tmax=4.1,
                         proj=False,
                         picks=eeg_channel_inds,
                         baseline=None,
                         preload=True)
    import numpy as np
    from braindecode.datautil.signal_target import SignalAndTarget
    from braindecode.datautil.splitters import split_into_two_sets
    # Convert data from volt to millivolt
    # Pytorch expects float32 for input and int64 for labels.
    X = (epoched.get_data() * 1e6).astype(np.float32)
    y = (epoched.events[:, 2] - 2).astype(np.int64)  # 2,3 -> 0,1

    train_set = SignalAndTarget(X[:60], y=y[:60])
    test_set = SignalAndTarget(X[60:], y=y[60:])

    train_set, valid_set = split_into_two_sets(train_set,
                                               first_set_fraction=0.8)
    from braindecode.models.shallow_fbcsp import ShallowFBCSPNet
    from torch import nn
    from braindecode.torch_ext.util import set_random_seeds
    from braindecode.models.util import to_dense_prediction_model

    # Set if you want to use GPU
    # You can also use torch.cuda.is_available() to determine if cuda is available on your machine.
    cuda = False
    set_random_seeds(seed=20170629, cuda=cuda)

    # This will determine how many crops are processed in parallel
    input_time_length = 450
    n_classes = 2
    in_chans = train_set.X.shape[1]
    # final_conv_length determines the size of the receptive field of the ConvNet
    model = ShallowFBCSPNet(in_chans=in_chans,
                            n_classes=n_classes,
                            input_time_length=input_time_length,
                            final_conv_length=12).create_network()
    to_dense_prediction_model(model)

    if cuda:
        model.cuda()

    from torch import optim

    optimizer = optim.Adam(model.parameters())

    from braindecode.torch_ext.util import np_to_var
    # determine output size
    test_input = np_to_var(
        np.ones((2, in_chans, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    print("{:d} predictions per input/trial".format(n_preds_per_input))

    from braindecode.experiments.experiment import Experiment
    from braindecode.datautil.iterators import CropsFromTrialsIterator
    from braindecode.experiments.monitors import RuntimeMonitor, LossMonitor, \
        CroppedTrialMisclassMonitor, MisclassMonitor
    from braindecode.experiments.stopcriteria import MaxEpochs
    import torch.nn.functional as F
    import torch as th
    from braindecode.torch_ext.modules import Expression
    # Iterator is used to iterate over datasets both for training
    # and evaluation
    iterator = CropsFromTrialsIterator(batch_size=32,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)

    # Loss function takes predictions as they come out of the network and the targets
    # and returns a loss
    loss_function = lambda preds, targets: F.nll_loss(
        th.mean(preds, dim=2, keepdim=False), targets)

    # Could be used to apply some constraint on the models, then should be object
    # with apply method that accepts a module
    model_constraint = None
    # Monitors log the training progress
    monitors = [
        LossMonitor(),
        MisclassMonitor(col_suffix='sample_misclass'),
        CroppedTrialMisclassMonitor(input_time_length),
        RuntimeMonitor(),
    ]
    # Stop criterion determines when the first stop happens
    stop_criterion = MaxEpochs(4)
    exp = Experiment(model,
                     train_set,
                     valid_set,
                     test_set,
                     iterator,
                     loss_function,
                     optimizer,
                     model_constraint,
                     monitors,
                     stop_criterion,
                     remember_best_column='valid_misclass',
                     run_after_early_stop=True,
                     batch_modifier=None,
                     cuda=cuda)

    # need to setup python logging before to be able to see anything
    import logging
    import sys
    logging.basicConfig(format='%(asctime)s %(levelname)s : %(message)s',
                        level=logging.DEBUG,
                        stream=sys.stdout)
    exp.run()

    import pandas as pd
    from io import StringIO
    compare_df = pd.read_csv(
        StringIO(
            u'train_loss,valid_loss,test_loss,train_sample_misclass,valid_sample_misclass,'
            'test_sample_misclass,train_misclass,valid_misclass,test_misclass\n'
            '0,0.8692976435025532,0.7483791708946228,0.6975634694099426,'
            '0.5389371657754011,0.47103386809269165,0.4425133689839572,'
            '0.6041666666666667,0.5,0.4\n1,2.3362590074539185,'
            '2.317707061767578,2.1407743096351624,0.4827874331550802,'
            '0.5,0.4666666666666667,0.5,0.5,0.4666666666666667\n'
            '2,0.5981490015983582,0.785034716129303,0.7005959153175354,'
            '0.3391822638146168,0.47994652406417115,0.41996434937611404,'
            '0.22916666666666663,0.41666666666666663,0.43333333333333335\n'
            '3,0.6355261653661728,0.785034716129303,'
            '0.7005959153175354,0.3673351158645276,0.47994652406417115,'
            '0.41996434937611404,0.2666666666666667,0.41666666666666663,'
            '0.43333333333333335\n4,0.625280424952507,'
            '0.802731990814209,0.7048938572406769,0.3367201426024955,'
            '0.43137254901960786,0.4229946524064171,0.3666666666666667,'
            '0.5833333333333333,0.33333333333333337\n'))

    for col in compare_df:
        np.testing.assert_allclose(np.array(compare_df[col]),
                                   exp.epochs_df[col],
                                   rtol=1e-4,
                                   atol=1e-5)
示例#18
0
        data, fs, sampling_freq, axis=1, filter='kaiser_fast'), sampling_freq))

    preproc_functions.append(lambda data, fs: (data / divisor, fs))
    dataset = DiagnosisSet(n_recordings=n_recordings,
                           max_recording_mins=max_recording_mins,
                           preproc_functions=preproc_functions,
                           train_or_eval='train')

    X, y = dataset.load()
    dataset = SignalAndTarget(X, y)

    batch_size = 64
    input_time_length = 1200
    n_preds_per_input = 600
    iterator = CropsFromTrialsIterator(batch_size=batch_size,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)

    w = scipy.signal.windows.blackmanharris(input_time_length)
    w = w / np.linalg.norm(w)
    w = w.astype(np.float32)
    for setname, y_class in (('normal', 0), ('abnormal', 1)):
        this_X = [x for x, y in zip(dataset.X, dataset.y) if y == y_class]

        this_y = dataset.y[dataset.y == y_class]

        assert np.all(this_y == y_class)
        this_set = SignalAndTarget(this_X, this_y)
        log.info("Create batches...")
        batches_arr = [
            b[0] for b in iterator.get_batches(this_set, shuffle=False)
示例#19
0
    def fit(
        self,
        train_X,
        train_y,
        epochs,
        batch_size,
        input_time_length=None,
        validation_data=None,
        model_constraint=None,
        remember_best_column=None,
        scheduler=None,
        log_0_epoch=True,
    ):
        """
        Fit the model using the given training data.
        
        Will set `epochs_df` variable with a pandas dataframe to the history
        of the training process.
        
        Parameters
        ----------
        train_X: ndarray
            Training input data
        train_y: 1darray
            Training labels
        epochs: int
            Number of epochs to train
        batch_size: int
        input_time_length: int, optional
            Super crop size, what temporal size is pushed forward through 
            the network, see cropped decoding tuturial.
        validation_data: (ndarray, 1darray), optional
            X and y for validation set if wanted
        model_constraint: object, optional
            You can supply :class:`.MaxNormDefaultConstraint` if wanted.
        remember_best_column: string, optional
            In case you want to do an early stopping/reset parameters to some
            "best" epoch, define here the monitored value whose minimum
            determines the best epoch.
        scheduler: 'cosine' or None, optional
            Whether to use cosine annealing (:class:`.CosineAnnealing`).
        log_0_epoch: bool
            Whether to compute the metrics once before training as well.

        Returns
        -------
        exp: 
            Underlying braindecode :class:`.Experiment`
        """
        if (not hasattr(self, "compiled")) or (not self.compiled):
            raise ValueError(
                "Compile the model first by calling model.compile(loss, optimizer, metrics)"
            )

        if self.cropped and input_time_length is None:
            raise ValueError(
                "In cropped mode, need to specify input_time_length,"
                "which is the number of timesteps that will be pushed through"
                "the network in a single pass.")

        train_X = _ensure_float32(train_X)
        if self.cropped:
            self.network.eval()
            test_input = np_to_var(
                np.ones(
                    (1, train_X[0].shape[0], input_time_length) +
                    train_X[0].shape[2:],
                    dtype=np.float32,
                ))
            while len(test_input.size()) < 4:
                test_input = test_input.unsqueeze(-1)
            if self.is_cuda:
                test_input = test_input.cuda()
            out = self.network(test_input)
            n_preds_per_input = out.cpu().data.numpy().shape[2]
            self.iterator = CropsFromTrialsIterator(
                batch_size=batch_size,
                input_time_length=input_time_length,
                n_preds_per_input=n_preds_per_input,
                seed=self.seed_rng.randint(0,
                                           np.iinfo(np.int32).max - 1),
            )
        else:
            self.iterator = BalancedBatchSizeIterator(
                batch_size=batch_size,
                seed=self.seed_rng.randint(0,
                                           np.iinfo(np.int32).max - 1),
            )
        if log_0_epoch:
            stop_criterion = MaxEpochs(epochs)
        else:
            stop_criterion = MaxEpochs(epochs - 1)
        train_set = SignalAndTarget(train_X, train_y)
        optimizer = self.optimizer
        if scheduler is not None:
            assert (scheduler == "cosine"
                    ), "Supply either 'cosine' or None as scheduler."
            n_updates_per_epoch = sum([
                1 for _ in self.iterator.get_batches(train_set, shuffle=True)
            ])
            n_updates_per_period = n_updates_per_epoch * epochs
            if scheduler == "cosine":
                scheduler = CosineAnnealing(n_updates_per_period)
            schedule_weight_decay = False
            if optimizer.__class__.__name__ == "AdamW":
                schedule_weight_decay = True
            optimizer = ScheduledOptimizer(
                scheduler,
                self.optimizer,
                schedule_weight_decay=schedule_weight_decay,
            )
        loss_function = self.loss
        if self.cropped:
            loss_function = lambda outputs, targets: self.loss(
                th.mean(outputs, dim=2), targets)
        if validation_data is not None:
            valid_X = _ensure_float32(validation_data[0])
            valid_y = validation_data[1]
            valid_set = SignalAndTarget(valid_X, valid_y)
        else:
            valid_set = None
        test_set = None
        self.monitors = [LossMonitor()]
        if self.cropped:
            self.monitors.append(
                CroppedTrialMisclassMonitor(input_time_length))
        else:
            self.monitors.append(MisclassMonitor())
        if self.extra_monitors is not None:
            self.monitors.extend(self.extra_monitors)
        self.monitors.append(RuntimeMonitor())
        exp = Experiment(
            self.network,
            train_set,
            valid_set,
            test_set,
            iterator=self.iterator,
            loss_function=loss_function,
            optimizer=optimizer,
            model_constraint=model_constraint,
            monitors=self.monitors,
            stop_criterion=stop_criterion,
            remember_best_column=remember_best_column,
            run_after_early_stop=False,
            cuda=self.is_cuda,
            log_0_epoch=log_0_epoch,
            do_early_stop=(remember_best_column is not None),
        )
        exp.run()
        self.epochs_df = exp.epochs_df
        return exp
示例#20
0
def test_experiment_class():
    import mne
    from mne.io import concatenate_raws

    # 5,6,7,10,13,14 are codes for executed and imagined hands/feet
    subject_id = 1
    event_codes = [5, 6, 9, 10, 13, 14]

    # This will download the files if you don't have them yet,
    # and then return the paths to the files.
    physionet_paths = mne.datasets.eegbci.load_data(subject_id, event_codes)

    # Load each of the files
    parts = [mne.io.read_raw_edf(path, preload=True, stim_channel='auto',
                                 verbose='WARNING')
             for path in physionet_paths]

    # Concatenate them
    raw = concatenate_raws(parts)

    # Find the events in this dataset
    events, _ = mne.events_from_annotations(raw)

    # Use only EEG channels
    eeg_channel_inds = mne.pick_types(raw.info, meg=False, eeg=True, stim=False,
                                      eog=False,
                                      exclude='bads')

    # Extract trials, only using EEG channels
    epoched = mne.Epochs(raw, events, dict(hands=2, feet=3), tmin=1, tmax=4.1,
                         proj=False, picks=eeg_channel_inds,
                         baseline=None, preload=True)
    import numpy as np
    from braindecode.datautil.signal_target import SignalAndTarget
    from braindecode.datautil.splitters import split_into_two_sets
    # Convert data from volt to millivolt
    # Pytorch expects float32 for input and int64 for labels.
    X = (epoched.get_data() * 1e6).astype(np.float32)
    y = (epoched.events[:, 2] - 2).astype(np.int64)  # 2,3 -> 0,1

    train_set = SignalAndTarget(X[:60], y=y[:60])
    test_set = SignalAndTarget(X[60:], y=y[60:])

    train_set, valid_set = split_into_two_sets(train_set,
                                               first_set_fraction=0.8)
    from braindecode.models.shallow_fbcsp import ShallowFBCSPNet
    from torch import nn
    from braindecode.torch_ext.util import set_random_seeds
    from braindecode.models.util import to_dense_prediction_model

    # Set if you want to use GPU
    # You can also use torch.cuda.is_available() to determine if cuda is available on your machine.
    cuda = False
    set_random_seeds(seed=20170629, cuda=cuda)

    # This will determine how many crops are processed in parallel
    input_time_length = 450
    n_classes = 2
    in_chans = train_set.X.shape[1]
    # final_conv_length determines the size of the receptive field of the ConvNet
    model = ShallowFBCSPNet(in_chans=in_chans, n_classes=n_classes,
                            input_time_length=input_time_length,
                            final_conv_length=12).create_network()
    to_dense_prediction_model(model)

    if cuda:
        model.cuda()

    from torch import optim

    optimizer = optim.Adam(model.parameters())

    from braindecode.torch_ext.util import np_to_var
    # determine output size
    test_input = np_to_var(
        np.ones((2, in_chans, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    print("{:d} predictions per input/trial".format(n_preds_per_input))

    from braindecode.experiments.experiment import Experiment
    from braindecode.datautil.iterators import CropsFromTrialsIterator
    from braindecode.experiments.monitors import RuntimeMonitor, LossMonitor, \
        CroppedTrialMisclassMonitor, MisclassMonitor
    from braindecode.experiments.stopcriteria import MaxEpochs
    import torch.nn.functional as F
    import torch as th
    from braindecode.torch_ext.modules import Expression
    # Iterator is used to iterate over datasets both for training
    # and evaluation
    iterator = CropsFromTrialsIterator(batch_size=32,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)

    # Loss function takes predictions as they come out of the network and the targets
    # and returns a loss
    loss_function = lambda preds, targets: F.nll_loss(
        th.mean(preds, dim=2, keepdim=False), targets)

    # Could be used to apply some constraint on the models, then should be object
    # with apply method that accepts a module
    model_constraint = None
    # Monitors log the training progress
    monitors = [LossMonitor(), MisclassMonitor(col_suffix='sample_misclass'),
                CroppedTrialMisclassMonitor(input_time_length),
                RuntimeMonitor(), ]
    # Stop criterion determines when the first stop happens
    stop_criterion = MaxEpochs(4)
    exp = Experiment(model, train_set, valid_set, test_set, iterator,
                     loss_function, optimizer, model_constraint,
                     monitors, stop_criterion,
                     remember_best_column='valid_misclass',
                     run_after_early_stop=True, batch_modifier=None, cuda=cuda)

    # need to setup python logging before to be able to see anything
    import logging
    import sys
    logging.basicConfig(format='%(asctime)s %(levelname)s : %(message)s',
                        level=logging.DEBUG, stream=sys.stdout)
    exp.run()

    import pandas as pd
    from io import StringIO
    compare_df = pd.read_csv(StringIO(
        'train_loss,valid_loss,test_loss,train_sample_misclass,valid_sample_misclass,'
        'test_sample_misclass,train_misclass,valid_misclass,test_misclass\n'
        '14.167170524597168,13.910758018493652,15.945781707763672,0.5,0.5,'
        '0.5333333333333333,0.5,0.5,0.5333333333333333\n'
        '1.1735659837722778,1.4342904090881348,1.8664429187774658,0.4629567736185384,'
        '0.5120320855614973,0.5336007130124778,0.5,0.5,0.5333333333333333\n'
        '1.3168460130691528,1.60431969165802,1.9181344509124756,0.49298128342245995,'
        '0.5109180035650625,0.531729055258467,0.5,0.5,0.5333333333333333\n'
        '0.8465543389320374,1.280307412147522,1.439755916595459,0.4413435828877005,'
        '0.5461229946524064,0.5283422459893048,0.47916666666666663,0.5,'
        '0.5333333333333333\n0.6977059841156006,1.1762590408325195,1.2779350280761719,'
        '0.40290775401069523,0.588903743315508,0.5307486631016043,0.5,0.5,0.5\n'
        '0.7934166193008423,1.1762590408325195,1.2779350280761719,0.4401069518716577,'
        '0.588903743315508,0.5307486631016043,0.5,0.5,0.5\n0.5982189178466797,'
        '0.8581563830375671,0.9598925113677979,0.32032085561497325,0.47660427807486627,'
        '0.4672905525846702,0.31666666666666665,0.5,0.4666666666666667\n0.5044312477111816,'
        '0.7133197784423828,0.8164243102073669,0.2591354723707665,0.45699643493761144,'
        '0.4393048128342246,0.16666666666666663,0.41666666666666663,0.43333333333333335\n'
        '0.4815250039100647,0.6736412644386292,0.8016976714134216,0.23413547237076648,'
        '0.39505347593582885,0.42932263814616756,0.15000000000000002,0.41666666666666663,0.5\n'))

    for col in compare_df:
        np.testing.assert_allclose(np.array(compare_df[col]),
                                   exp.epochs_df[col],
                                   rtol=1e-3, atol=1e-4)
def test_cropped_decoding():
    import mne
    from mne.io import concatenate_raws

    # 5,6,7,10,13,14 are codes for executed and imagined hands/feet
    subject_id = 1
    event_codes = [5, 6, 9, 10, 13, 14]

    # This will download the files if you don't have them yet,
    # and then return the paths to the files.
    physionet_paths = mne.datasets.eegbci.load_data(subject_id, event_codes)

    # Load each of the files
    parts = [mne.io.read_raw_edf(path, preload=True, stim_channel='auto',
                                 verbose='WARNING')
             for path in physionet_paths]

    # Concatenate them
    raw = concatenate_raws(parts)

    # Find the events in this dataset
    events = mne.find_events(raw, shortest_event=0, stim_channel='STI 014')

    # Use only EEG channels
    eeg_channel_inds = mne.pick_types(raw.info, meg=False, eeg=True, stim=False,
                                      eog=False,
                                      exclude='bads')

    # Extract trials, only using EEG channels
    epoched = mne.Epochs(raw, events, dict(hands=2, feet=3), tmin=1, tmax=4.1,
                         proj=False, picks=eeg_channel_inds,
                         baseline=None, preload=True)
    import numpy as np
    from braindecode.datautil.signal_target import SignalAndTarget
    # Convert data from volt to millivolt
    # Pytorch expects float32 for input and int64 for labels.
    X = (epoched.get_data() * 1e6).astype(np.float32)
    y = (epoched.events[:, 2] - 2).astype(np.int64)  # 2,3 -> 0,1

    train_set = SignalAndTarget(X[:60], y=y[:60])
    test_set = SignalAndTarget(X[60:], y=y[60:])
    from braindecode.models.shallow_fbcsp import ShallowFBCSPNet
    from torch import nn
    from braindecode.torch_ext.util import set_random_seeds
    from braindecode.models.util import to_dense_prediction_model

    # Set if you want to use GPU
    # You can also use torch.cuda.is_available() to determine if cuda is available on your machine.
    cuda = False
    set_random_seeds(seed=20170629, cuda=cuda)

    # This will determine how many crops are processed in parallel
    input_time_length = 450
    n_classes = 2
    in_chans = train_set.X.shape[1]
    # final_conv_length determines the size of the receptive field of the ConvNet
    model = ShallowFBCSPNet(in_chans=in_chans, n_classes=n_classes,
                            input_time_length=input_time_length,
                            final_conv_length=12).create_network()
    to_dense_prediction_model(model)

    if cuda:
        model.cuda()

    from torch import optim

    optimizer = optim.Adam(model.parameters())
    from braindecode.torch_ext.util import np_to_var
    # determine output size
    test_input = np_to_var(
        np.ones((2, in_chans, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    print("{:d} predictions per input/trial".format(n_preds_per_input))
    from braindecode.datautil.iterators import CropsFromTrialsIterator
    iterator = CropsFromTrialsIterator(batch_size=32,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)
    from braindecode.torch_ext.util import np_to_var, var_to_np
    import torch.nn.functional as F
    from numpy.random import RandomState
    import torch as th
    from braindecode.experiments.monitors import compute_preds_per_trial_from_crops
    rng = RandomState((2017, 6, 30))
    losses = []
    accuracies = []
    for i_epoch in range(4):
        # Set model to training mode
        model.train()
        for batch_X, batch_y in iterator.get_batches(train_set, shuffle=False):
            net_in = np_to_var(batch_X)
            if cuda:
                net_in = net_in.cuda()
            net_target = np_to_var(batch_y)
            if cuda:
                net_target = net_target.cuda()
            # Remove gradients of last backward pass from all parameters
            optimizer.zero_grad()
            outputs = model(net_in)
            # Mean predictions across trial
            # Note that this will give identical gradients to computing
            # a per-prediction loss (at least for the combination of log softmax activation
            # and negative log likelihood loss which we are using here)
            outputs = th.mean(outputs, dim=2, keepdim=False)
            loss = F.nll_loss(outputs, net_target)
            loss.backward()
            optimizer.step()

        # Print some statistics each epoch
        model.eval()
        print("Epoch {:d}".format(i_epoch))
        for setname, dataset in (('Train', train_set), ('Test', test_set)):
            # Collect all predictions and losses
            all_preds = []
            all_losses = []
            batch_sizes = []
            for batch_X, batch_y in iterator.get_batches(dataset,
                                                         shuffle=False):
                net_in = np_to_var(batch_X)
                if cuda:
                    net_in = net_in.cuda()
                net_target = np_to_var(batch_y)
                if cuda:
                    net_target = net_target.cuda()
                outputs = model(net_in)
                all_preds.append(var_to_np(outputs))
                outputs = th.mean(outputs, dim=2, keepdim=False)
                loss = F.nll_loss(outputs, net_target)
                loss = float(var_to_np(loss))
                all_losses.append(loss)
                batch_sizes.append(len(batch_X))
            # Compute mean per-input loss
            loss = np.mean(np.array(all_losses) * np.array(batch_sizes) /
                           np.mean(batch_sizes))
            print("{:6s} Loss: {:.5f}".format(setname, loss))
            losses.append(loss)
            # Assign the predictions to the trials
            preds_per_trial = compute_preds_per_trial_from_crops(all_preds,
                                                              input_time_length,
                                                              dataset.X)
            # preds per trial are now trials x classes x timesteps/predictions
            # Now mean across timesteps for each trial to get per-trial predictions
            meaned_preds_per_trial = np.array(
                [np.mean(p, axis=1) for p in preds_per_trial])
            predicted_labels = np.argmax(meaned_preds_per_trial, axis=1)
            accuracy = np.mean(predicted_labels == dataset.y)
            accuracies.append(accuracy * 100)
            print("{:6s} Accuracy: {:.1f}%".format(
                setname, accuracy * 100))
    np.testing.assert_allclose(
        np.array(losses),
        np.array([1.703004002571106,
                  1.6295261979103088,
                  0.71168938279151917,
                  0.70825588703155518,
                  0.58231228590011597,
                  0.60176041722297668,
                  0.46629951894283295,
                  0.51184913516044617]),
        rtol=1e-4, atol=1e-5)
    np.testing.assert_allclose(
        np.array(accuracies),
        np.array(
            [50.0,
             46.666666666666664,
             60.0,
             53.333333333333336,
             68.333333333333329,
             66.666666666666657,
             88.333333333333329,
             83.333333333333343]),
        rtol=1e-4, atol=1e-5)
示例#22
0
# Compute correlation: amplitude perturbation - prediction change
# ---------------------------------------------------------------
#
# First collect all batches and concatenate them into one array of examples:

from braindecode.datautil.iterators import CropsFromTrialsIterator
from braindecode.torch_ext.util import np_to_var

test_input = np_to_var(np.ones((2, 64, input_time_length, 1), dtype=np.float32))
if cuda:
    test_input = test_input.cuda()
out = model.network(test_input)
n_preds_per_input = out.cpu().data.numpy().shape[2]
iterator = CropsFromTrialsIterator(
    batch_size=32,
    input_time_length=input_time_length,
    n_preds_per_input=n_preds_per_input,
)

train_batches = list(iterator.get_batches(train_set, shuffle=False))
train_X_batches = np.concatenate(list(zip(*train_batches))[0])

# Next, create a prediction function that wraps the model prediction
# function and returns the predictions as numpy arrays. We use the predition
# before the softmax, so we create a new module with all the layers of the
# old until before the softmax.

from braindecode.util import var_to_np
import torch as th

new_model = nn.Sequential()
示例#23
0
            # %% # determine output size
            from braindecode.torch_ext.util import np_to_var
            test_input = np_to_var(
                np.ones((2, in_chans, input_time_length, 1), dtype=np.float32))
            if cuda:
                test_input = test_input.cuda()
            out = model(test_input)
            n_preds_per_input = out.cpu().data.numpy().shape[1]
            log.info(
                "predictor length = {:d} samples".format(n_preds_per_input))
            log.info("predictor length = {:f} s".format(n_preds_per_input /
                                                        samplingRate))

            iterator = CropsFromTrialsIterator(
                batch_size=batch_size,
                input_time_length=input_time_length,
                n_preds_per_input=n_preds_per_input)

            # %% Loss function takes predictions as they come out of the network and the targets and returns a loss
            loss_function = F.mse_loss

            # Could be used to apply some constraint on the models, then should be object with apply method that accepts a module
            model_constraint = None

            # %% Monitors log the training progress
            monitors = [
                LossMonitor(),
                CorrelationMonitor1d(input_time_length),
                RuntimeMonitor(),
            ]
示例#24
0
def run_exp_on_high_gamma_dataset(train_filename, test_filename, low_cut_hz,
                                  model_name, max_epochs, max_increase_epochs,
                                  np_th_seed, debug):
    train_set, valid_set, test_set = load_train_valid_test(
        train_filename=train_filename,
        test_filename=test_filename,
        low_cut_hz=low_cut_hz,
        debug=debug)
    if debug:
        max_epochs = 4

    set_random_seeds(np_th_seed, cuda=True)
    #torch.backends.cudnn.benchmark = True# sometimes crashes?
    n_classes = int(np.max(train_set.y) + 1)
    n_chans = int(train_set.X.shape[1])
    input_time_length = 1000
    if model_name == 'deep':
        model = Deep4Net(n_chans,
                         n_classes,
                         input_time_length=input_time_length,
                         final_conv_length=2).create_network()
    elif model_name == 'shallow':
        model = ShallowFBCSPNet(n_chans,
                                n_classes,
                                input_time_length=input_time_length,
                                final_conv_length=30).create_network()

    to_dense_prediction_model(model)
    model.cuda()
    model.eval()

    out = model(np_to_var(train_set.X[:1, :, :input_time_length, None]).cuda())

    n_preds_per_input = out.cpu().data.numpy().shape[2]
    optimizer = optim.Adam(model.parameters(), weight_decay=0, lr=1e-3)

    iterator = CropsFromTrialsIterator(batch_size=60,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input,
                                       seed=np_th_seed)

    monitors = [
        LossMonitor(),
        MisclassMonitor(col_suffix='sample_misclass'),
        CroppedTrialMisclassMonitor(input_time_length=input_time_length),
        RuntimeMonitor()
    ]

    model_constraint = MaxNormDefaultConstraint()

    loss_function = lambda preds, targets: F.nll_loss(th.mean(preds, dim=2),
                                                      targets)

    run_after_early_stop = True
    do_early_stop = True
    remember_best_column = 'valid_misclass'
    stop_criterion = Or([
        MaxEpochs(max_epochs),
        NoDecrease('valid_misclass', max_increase_epochs)
    ])

    exp = Experiment(model,
                     train_set,
                     valid_set,
                     test_set,
                     iterator=iterator,
                     loss_function=loss_function,
                     optimizer=optimizer,
                     model_constraint=model_constraint,
                     monitors=monitors,
                     stop_criterion=stop_criterion,
                     remember_best_column=remember_best_column,
                     run_after_early_stop=run_after_early_stop,
                     cuda=True,
                     do_early_stop=do_early_stop)
    exp.run()
    return exp
示例#25
0
def run_exp(max_recording_mins,
            n_recordings,
            sec_to_cut_at_start,
            sec_to_cut_at_end,
            duration_recording_mins,
            max_abs_val,
            clip_before_resample,
            sampling_freq,
            divisor,
            n_folds,
            i_test_fold,
            shuffle,
            merge_train_valid,
            model,
            input_time_length,
            optimizer,
            learning_rate,
            weight_decay,
            scheduler,
            model_constraint,
            batch_size,
            max_epochs,
            only_return_exp,
            time_cut_off_sec,
            start_time,
            test_on_eval,
            test_recording_mins,
            sensor_types,
            log_dir,
            np_th_seed,
            cuda=True):
    import torch.backends.cudnn as cudnn
    cudnn.benchmark = True
    if optimizer == 'adam':
        assert merge_train_valid == False
    else:
        assert optimizer == 'adamw'
        assert merge_train_valid == True

    preproc_functions = create_preproc_functions(
        sec_to_cut_at_start=sec_to_cut_at_start,
        sec_to_cut_at_end=sec_to_cut_at_end,
        duration_recording_mins=duration_recording_mins,
        max_abs_val=max_abs_val,
        clip_before_resample=clip_before_resample,
        sampling_freq=sampling_freq,
        divisor=divisor)

    dataset = DiagnosisSet(n_recordings=n_recordings,
                           max_recording_mins=max_recording_mins,
                           preproc_functions=preproc_functions,
                           train_or_eval='train',
                           sensor_types=sensor_types)

    if test_on_eval:
        if test_recording_mins is None:
            test_recording_mins = duration_recording_mins

        test_preproc_functions = create_preproc_functions(
            sec_to_cut_at_start=sec_to_cut_at_start,
            sec_to_cut_at_end=sec_to_cut_at_end,
            duration_recording_mins=test_recording_mins,
            max_abs_val=max_abs_val,
            clip_before_resample=clip_before_resample,
            sampling_freq=sampling_freq,
            divisor=divisor)
        test_dataset = DiagnosisSet(n_recordings=n_recordings,
                                    max_recording_mins=None,
                                    preproc_functions=test_preproc_functions,
                                    train_or_eval='eval',
                                    sensor_types=sensor_types)
    if not only_return_exp:
        X, y = dataset.load()
        max_shape = np.max([list(x.shape) for x in X], axis=0)
        assert max_shape[1] == int(duration_recording_mins * sampling_freq *
                                   60)
        if test_on_eval:
            test_X, test_y = test_dataset.load()
            max_shape = np.max([list(x.shape) for x in test_X], axis=0)
            assert max_shape[1] == int(test_recording_mins * sampling_freq *
                                       60)
    if not test_on_eval:
        splitter = TrainValidTestSplitter(n_folds,
                                          i_test_fold,
                                          shuffle=shuffle)
    else:
        splitter = TrainValidSplitter(n_folds,
                                      i_valid_fold=i_test_fold,
                                      shuffle=shuffle)
    if not only_return_exp:
        if not test_on_eval:
            train_set, valid_set, test_set = splitter.split(X, y)
        else:

            train_set, valid_set = splitter.split(X, y)
            test_set = SignalAndTarget(test_X, test_y)
            del test_X, test_y
        del X, y  # shouldn't be necessary, but just to make sure
        if merge_train_valid:
            train_set = concatenate_sets([train_set, valid_set])
            # just reduce valid for faster computations
            valid_set.X = valid_set.X[:8]
            valid_set.y = valid_set.y[:8]
            # np.save('/data/schirrmr/schirrmr/auto-diag/lukasrepr/compare/mne-0-16-2/train_X.npy', train_set.X)
            # np.save('/data/schirrmr/schirrmr/auto-diag/lukasrepr/compare/mne-0-16-2/train_y.npy', train_set.y)
            # np.save('/data/schirrmr/schirrmr/auto-diag/lukasrepr/compare/mne-0-16-2/valid_X.npy', valid_set.X)
            # np.save('/data/schirrmr/schirrmr/auto-diag/lukasrepr/compare/mne-0-16-2/valid_y.npy', valid_set.y)
            # np.save('/data/schirrmr/schirrmr/auto-diag/lukasrepr/compare/mne-0-16-2/test_X.npy', test_set.X)
            # np.save('/data/schirrmr/schirrmr/auto-diag/lukasrepr/compare/mne-0-16-2/test_y.npy', test_set.y)
    else:
        train_set = None
        valid_set = None
        test_set = None

    log.info("Model:\n{:s}".format(str(model)))
    if cuda:
        model.cuda()
    model.eval()
    in_chans = 21
    # determine output size
    test_input = np_to_var(
        np.ones((2, in_chans, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    log.info("{:d} predictions per input/trial".format(n_preds_per_input))
    iterator = CropsFromTrialsIterator(batch_size=batch_size,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input,
                                       seed=np_th_seed)
    assert optimizer in ['adam', 'adamw'], ("Expect optimizer to be either "
                                            "adam or adamw")
    schedule_weight_decay = optimizer == 'adamw'
    if optimizer == 'adam':
        optim_class = optim.Adam
        assert schedule_weight_decay == False
        assert merge_train_valid == False
    else:
        optim_class = AdamW
        assert schedule_weight_decay == True
        assert merge_train_valid == True

    optimizer = optim_class(model.parameters(),
                            lr=learning_rate,
                            weight_decay=weight_decay)
    if scheduler is not None:
        assert scheduler == 'cosine'
        n_updates_per_epoch = sum(
            [1 for _ in iterator.get_batches(train_set, shuffle=True)])
        # Adapt if you have a different number of epochs
        n_updates_per_period = n_updates_per_epoch * max_epochs
        scheduler = CosineAnnealing(n_updates_per_period)
        optimizer = ScheduledOptimizer(
            scheduler, optimizer, schedule_weight_decay=schedule_weight_decay)
    loss_function = nll_loss_on_mean

    if model_constraint is not None:
        assert model_constraint == 'defaultnorm'
        model_constraint = MaxNormDefaultConstraint()
    monitors = [
        LossMonitor(),
        MisclassMonitor(col_suffix='sample_misclass'),
        CroppedDiagnosisMonitor(input_time_length, n_preds_per_input),
        RuntimeMonitor(),
    ]

    stop_criterion = MaxEpochs(max_epochs)
    loggers = [Printer(), TensorboardWriter(log_dir)]
    batch_modifier = None
    exp = Experiment(model,
                     train_set,
                     valid_set,
                     test_set,
                     iterator,
                     loss_function,
                     optimizer,
                     model_constraint,
                     monitors,
                     stop_criterion,
                     remember_best_column='valid_misclass',
                     run_after_early_stop=True,
                     batch_modifier=batch_modifier,
                     cuda=cuda,
                     loggers=loggers)

    if not only_return_exp:
        # Until first stop
        exp.setup_training()
        exp.monitor_epoch(exp.datasets)
        exp.log_epoch()
        exp.rememberer.remember_epoch(exp.epochs_df, exp.model, exp.optimizer)

        exp.iterator.reset_rng()
        while not exp.stop_criterion.should_stop(exp.epochs_df):
            if (time.time() - start_time) > time_cut_off_sec:
                log.info(
                    "Ran out of time after {:.2f} sec.".format(time.time() -
                                                               start_time))
                return exp
            log.info("Still in time after {:.2f} sec.".format(time.time() -
                                                              start_time))
            exp.run_one_epoch(exp.datasets, remember_best=True)
        if (time.time() - start_time) > time_cut_off_sec:
            log.info("Ran out of time after {:.2f} sec.".format(time.time() -
                                                                start_time))
            return exp
        if not merge_train_valid:
            exp.setup_after_stop_training()
            # Run until second stop
            datasets = exp.datasets
            datasets['train'] = concatenate_sets(
                [datasets['train'], datasets['valid']])
            exp.monitor_epoch(datasets)
            exp.log_epoch()

            exp.iterator.reset_rng()
            while not exp.stop_criterion.should_stop(exp.epochs_df):
                if (time.time() - start_time) > time_cut_off_sec:
                    log.info("Ran out of time after {:.2f} sec.".format(
                        time.time() - start_time))
                    return exp
                log.info("Still in time after {:.2f} sec.".format(time.time() -
                                                                  start_time))
                exp.run_one_epoch(datasets, remember_best=False)

    else:
        exp.dataset = dataset
        exp.splitter = splitter
    if test_on_eval:
        exp.test_dataset = test_dataset

    return exp
示例#26
0
from braindecode.torch_ext.losses import log_categorical_crossentropy
from braindecode.experiments.experiment import Experiment
from braindecode.datautil.iterators import CropsFromTrialsIterator
from braindecode.experiments.monitors import RuntimeMonitor, LossMonitor, CroppedTrialMisclassMonitor, MisclassMonitor
from braindecode.experiments.stopcriteria import MaxEpochs
import torch.nn.functional as F
import torch as th
from braindecode.torch_ext.modules import Expression
from seizure_monitor import *
from model import *
# Iterator is used to iterate over datasets both for training
# and evaluation
iterator = CropsFromTrialsIterator(batch_size=32,
                                   input_time_length=input_time_length,
                                   n_preds_per_input=n_preds_per_input)

# Loss function takes predictions as they come out of the network and the targets
# and returns a loss
loss_function = lambda preds, targets: log_categorical_crossentropy(
    preds, targets)
# Could be used to apply some constraint on the models, then should be object
# with apply method that accepts a module
model_constraint = None
# Monitors log the training progress
monitors = [
    LossMonitor(),
    MisclassMonitor(col_suffix='misclass'),
    SeizureMonitor(input_time_length),
    RuntimeMonitor(),
]
# Stop criterion determines when the first stop happens
def fit_transform(model,
                  optimizer,
                  data,
                  labels,
                  num_epochs=10,
                  n_channels=22,
                  input_time_length=500):
    # # # # # # # # CREATE CROPPED ITERATOR # # # # # # # # #

    train_set = SignalAndTarget(data, y=labels)

    # determine output size
    test_input = np_to_var(
        np.ones((2, n_channels, input_time_length, 1), dtype=np.float32))
    if cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]
    # print("{:d} predictions per input/trial".format(n_preds_per_input))

    iterator = CropsFromTrialsIterator(batch_size=32,
                                       input_time_length=input_time_length,
                                       n_preds_per_input=n_preds_per_input)

    # # # # # # # # TRAINING LOOP # # # # # # #

    for i_epoch in range(num_epochs):
        # Set model to training mode
        model.train()
        for batch_X, batch_y in iterator.get_batches(train_set, shuffle=False):
            net_in = np_to_var(batch_X)
            if cuda:
                net_in = net_in.cuda()
            net_target = np_to_var(batch_y)
            if cuda:
                net_target = net_target.cuda()
            # Remove gradients of last backward pass from all parameters
            optimizer.zero_grad()
            outputs = model(net_in)

            outputs = th.mean(outputs, dim=2, keepdim=False)
            loss = F.nll_loss(outputs, net_target)
            loss.backward()
            optimizer.step()

        model.eval()
        # print("Epoch {:d}".format(i_epoch))

        # Collect all predictions and losses
        all_preds = []
        all_losses = []
        batch_sizes = []
        for batch_X, batch_y in iterator.get_batches(train_set, shuffle=False):
            net_in = np_to_var(batch_X)
            if cuda:
                net_in = net_in.cuda()
            net_target = np_to_var(batch_y)
            if cuda:
                net_target = net_target.cuda()
            outputs = model(net_in)
            all_preds.append(var_to_np(outputs))
            outputs = th.mean(outputs, dim=2, keepdim=False)
            loss = F.nll_loss(outputs, net_target)
            loss = float(var_to_np(loss))
            all_losses.append(loss)
            batch_sizes.append(len(batch_X))
        # Compute mean per-input loss
        loss = np.mean(
            np.array(all_losses) * np.array(batch_sizes) /
            np.mean(batch_sizes))
        # print("{:6s} Loss: {:.5f}".format('Train', loss))
        # Assign the predictions to the trials
        preds_per_trial = compute_preds_per_trial_from_crops(
            all_preds, input_time_length, train_set)
        # preds per trial are now trials x classes x timesteps/predictions
        # Now mean across timesteps for each trial to get per-trial predictions
        meaned_preds_per_trial = np.array(
            [np.mean(p, axis=1) for p in preds_per_trial])
        predicted_labels = np.argmax(meaned_preds_per_trial, axis=1)
        accuracy = np.mean(predicted_labels == train_set.y)
        # print("{:6s} Accuracy: {:.2f}%".format('Train', accuracy * 100))

    return model
示例#28
0
def setup_exp(
    train_folder,
    n_recordings,
    n_chans,
    model_name,
    n_start_chans,
    n_chan_factor,
    input_time_length,
    final_conv_length,
    model_constraint,
    stride_before_pool,
    init_lr,
    batch_size,
    max_epochs,
    cuda,
    num_workers,
    task,
    weight_decay,
    n_folds,
    shuffle_folds,
    lazy_loading,
    eval_folder,
    result_folder,
    run_on_normals,
    run_on_abnormals,
    seed,
    l2_decay,
    gradient_clip,
):
    info_msg = "using {}, {}".format(
        os.environ["SLURM_JOB_PARTITION"],
        os.environ["SLURMD_NODENAME"],
    )
    info_msg += ", gpu {}".format(os.environ["CUDA_VISIBLE_DEVICES"])
    logging.info(info_msg)

    logging.info("Targets for this task: <{}>".format(task))

    import torch.backends.cudnn as cudnn
    cudnn.benchmark = True

    if task == "age":
        loss_function = mse_loss_on_mean
        remember_best_column = "valid_rmse"
        n_classes = 1
    else:
        loss_function = nll_loss_on_mean
        remember_best_column = "valid_misclass"
        n_classes = 2

    if model_constraint is not None:
        assert model_constraint == 'defaultnorm'
        model_constraint = MaxNormDefaultConstraint()

    stop_criterion = MaxEpochs(max_epochs)

    set_random_seeds(seed=seed, cuda=cuda)
    if model_name == 'shallow':
        model = ShallowFBCSPNet(
            in_chans=n_chans,
            n_classes=n_classes,
            n_filters_time=n_start_chans,
            n_filters_spat=n_start_chans,
            input_time_length=input_time_length,
            final_conv_length=final_conv_length).create_network()
    elif model_name == 'deep':
        model = Deep4Net(
            n_chans,
            n_classes,
            n_filters_time=n_start_chans,
            n_filters_spat=n_start_chans,
            input_time_length=input_time_length,
            n_filters_2=int(n_start_chans * n_chan_factor),
            n_filters_3=int(n_start_chans * (n_chan_factor**2.0)),
            n_filters_4=int(n_start_chans * (n_chan_factor**3.0)),
            final_conv_length=final_conv_length,
            stride_before_pool=stride_before_pool).create_network()
    elif model_name == 'eegnet':
        model = EEGNetv4(n_chans,
                         n_classes,
                         input_time_length=input_time_length,
                         final_conv_length=final_conv_length).create_network()
    elif model_name == "tcn":
        assert task != "age", "what to change to do regression with tcn?!"
        model = TemporalConvNet(input_size=n_chans,
                                output_size=n_classes,
                                context_size=0,
                                num_channels=55,
                                num_levels=5,
                                kernel_size=16,
                                dropout=0.05270154233150525,
                                skip_mode=None,
                                use_context=0,
                                lasso_selection=0.0,
                                rnn_normalization=None)
    else:
        assert False, "unknown model name {:s}".format(model_name)

    if task == "age":
        # remove softmax layer, set n_classes to 1
        model.n_classes = 1
        new_model = nn.Sequential()
        for name, module_ in model.named_children():
            if name == "softmax":
                continue
            new_model.add_module(name, module_)
        model = new_model

    # maybe check if this works and wait / re-try after some time?
    # in case of all cuda devices are busy
    if cuda:
        model.cuda()

    if model_name != "tcn":
        to_dense_prediction_model(model)
    logging.info("Model:\n{:s}".format(str(model)))

    test_input = np_to_var(
        np.ones((2, n_chans, input_time_length, 1), dtype=np.float32))
    if list(model.parameters())[0].is_cuda:
        test_input = test_input.cuda()
    out = model(test_input)
    n_preds_per_input = out.cpu().data.numpy().shape[2]

    if eval_folder is None:
        logging.info("will do validation")
        if lazy_loading:
            logging.info(
                "using lazy loading to load {} recs".format(n_recordings))
            dataset = TuhLazy(train_folder,
                              target=task,
                              n_recordings=n_recordings)
        else:
            logging.info("using traditional loading to load {} recs".format(
                n_recordings))
            dataset = Tuh(train_folder, n_recordings=n_recordings, target=task)

        assert not (run_on_normals and run_on_abnormals), (
            "decide whether to run on normal or abnormal subjects")
        # only run on normal subjects
        if run_on_normals:
            ids = [
                i for i in range(len(dataset)) if dataset.pathologicals[i] == 0
            ]  # 0 is non-pathological
            dataset = TuhSubset(dataset, ids)
            logging.info("only using {} normal subjects".format(len(dataset)))
        if run_on_abnormals:
            ids = [
                i for i in range(len(dataset)) if dataset.pathologicals[i] == 1
            ]  # 1 is pathological
            dataset = TuhSubset(dataset, ids)
            logging.info("only using {} abnormal subjects".format(
                len(dataset)))

        indices = np.arange(len(dataset))
        kf = KFold(n_splits=n_folds, shuffle=shuffle_folds)
        for i, (train_ind, test_ind) in enumerate(kf.split(indices)):
            assert len(np.intersect1d(
                train_ind, test_ind)) == 0, ("train and test set overlap!")

            # seed is in range of number of folds and was set by submit script
            if i == seed:
                break

        if lazy_loading:
            test_subset = TuhLazySubset(dataset, test_ind)
            train_subset = TuhLazySubset(dataset, train_ind)
        else:
            test_subset = TuhSubset(dataset, test_ind)
            train_subset = TuhSubset(dataset, train_ind)
    else:
        logging.info("will do final evaluation")
        if lazy_loading:
            train_subset = TuhLazy(train_folder, target=task)
            test_subset = TuhLazy(eval_folder, target=task)
        else:
            train_subset = Tuh(train_folder, target=task)
            test_subset = Tuh(eval_folder, target=task)

        # remove rec:
        # train/abnormal/01_tcp_ar/081/00008184/s001_2011_09_21/00008184_s001_t001
        # since it contains no crop without outliers (channels A1, A2 broken)
        subjects = [f.split("/")[-3] for f in train_subset.file_paths]
        if "00008184" in subjects:
            bad_id = subjects.index("00008184")
            train_subset = remove_file_from_dataset(
                train_subset,
                file_id=bad_id,
                file=("train/abnormal/01_tcp_ar/081/00008184/s001_2011_09_21/"
                      "00008184_s001_t001"))
        subjects = [f.split("/")[-3] for f in test_subset.file_paths]
        if "00008184" in subjects:
            bad_id = subjects.index("00008184")
            test_subset = remove_file_from_dataset(
                test_subset,
                file_id=bad_id,
                file=("train/abnormal/01_tcp_ar/081/00008184/s001_2011_09_21/"
                      "00008184_s001_t001"))

    if task == "age":
        # standardize ages based on train set
        y_train = train_subset.y
        y_train_mean = np.mean(y_train)
        y_train_std = np.std(y_train)
        train_subset.y = (y_train - y_train_mean) / y_train_std
        y_test = test_subset.y
        test_subset.y = (y_test - y_train_mean) / y_train_std

    if lazy_loading:
        iterator = LazyCropsFromTrialsIterator(
            input_time_length,
            n_preds_per_input,
            batch_size,
            seed=seed,
            num_workers=num_workers,
            reset_rng_after_each_batch=False,
            check_preds_smaller_trial_len=False)  # True!
    else:
        iterator = CropsFromTrialsIterator(batch_size, input_time_length,
                                           n_preds_per_input, seed)

    monitors = []
    monitors.append(LossMonitor())
    monitors.append(RAMMonitor())
    monitors.append(RuntimeMonitor())
    if task == "age":
        monitors.append(
            RMSEMonitor(input_time_length,
                        n_preds_per_input,
                        mean=y_train_mean,
                        std=y_train_std))
    else:
        monitors.append(
            CroppedDiagnosisMonitor(input_time_length, n_preds_per_input))
        monitors.append(LazyMisclassMonitor(col_suffix='sample_misclass'))

    if lazy_loading:
        n_updates_per_epoch = len(
            iterator.get_batches(train_subset, shuffle=False))
    else:
        n_updates_per_epoch = sum(
            [1 for _ in iterator.get_batches(train_subset, shuffle=False)])
    n_updates_per_period = n_updates_per_epoch * max_epochs
    logging.info("there are {} updates per epoch".format(n_updates_per_epoch))

    if model_name == "tcn":
        adamw = ExtendedAdam(model.parameters(),
                             lr=init_lr,
                             weight_decay=weight_decay,
                             l2_decay=l2_decay,
                             gradient_clip=gradient_clip)
    else:
        adamw = AdamWWithTracking(model.parameters(),
                                  init_lr,
                                  weight_decay=weight_decay)

    scheduler = CosineAnnealing(n_updates_per_period)
    optimizer = ScheduledOptimizer(scheduler,
                                   adamw,
                                   schedule_weight_decay=True)

    exp = Experiment(model=model,
                     train_set=train_subset,
                     valid_set=None,
                     test_set=test_subset,
                     iterator=iterator,
                     loss_function=loss_function,
                     optimizer=optimizer,
                     model_constraint=model_constraint,
                     monitors=monitors,
                     stop_criterion=stop_criterion,
                     remember_best_column=remember_best_column,
                     run_after_early_stop=False,
                     batch_modifier=None,
                     cuda=cuda,
                     do_early_stop=False,
                     reset_after_second_run=False)
    return exp