Example #1
0
def command_line():
    p = OptionParser()
    p.add_option('-H', '--host', dest='host', action='store',
                 help='IMAP host connect to')
    p.add_option('-u', '--username', dest='username', action='store',
                 help='Username to login with')
    p.add_option('-p', '--password', dest='password', action='store',
                 help='Password to login with')
    p.add_option('-P', '--port', dest='port', action='store',
                 default=None, help='IMAP port to use (default is 143)')
    p.add_option('-s', '--ssl', dest='ssl', action='store_true', default=False,
                 help='Use SSL connection')
    p.add_option('-f', '--file', dest='file', action='store', default=None,
                 help='Config file (same as livetest)')

    opts, args = p.parse_args()
    if args:
        p.error('unexpected arguments %s' % ' '.join(args))

    if opts.file:
        if opts.host or opts.username or opts.password or opts.port or opts.ssl:
            p.error('If -f/--file is given no other options can be used')
        # Use the options in the config file
        opts = parse_config_file(opts.file)
    else:
        # Get compulsory options if not given on the command line
        for opt_name in ('host', 'username', 'password'):
            if not getattr(opts, opt_name):
                setattr(opts, opt_name, getpass(opt_name + ': '))
        if not opts.port:
            opts.port = 143
        opts.oauth = False     # OAUTH not supported on command line
    return opts
def main():
  args = parse_args()
  cfg = parse_config_file(args.config_file)
  visualize(
    tfrecords=args.tfrecords,
    cfg=cfg
  )
Example #3
0
def main():
  args = parse_args()
  print "Command line arguments:"
  pprint.pprint(vars(args))
  print

  cfg = parse_config_file(args.config_file)
  print "Configurations:"
  pprint.pprint(cfg)
  print 

  if args.max_number_of_steps != None:
    cfg.NUM_TRAIN_ITERATIONS = args.max_number_of_steps
  
  if args.batch_size != None:
    cfg.BATCH_SIZE = args.batch_size

  with open(args.priors) as f:
      bbox_priors = pickle.load(f)
  bbox_priors = np.array(bbox_priors).astype(np.float32)

  train(
    tfrecords=args.tfrecords,
    bbox_priors=bbox_priors,
    logdir=args.logdir,
    cfg=cfg,
    pretrained_model_path=args.pretrained_model,
    fine_tune = args.fine_tune,
    extract_feats = args.extract_features,
    trainable_scopes = args.trainable_scopes,
    use_moving_averages = args.use_moving_averages,
    restore_moving_averages = args.restore_moving_averages
  )
Example #4
0
def parse_argv():
    args = sys.argv[1:]
    if not args:
        argv_error('Please specify a host configuration file. See livetest-sample.ini for an example.')
    ini_path = sys.argv.pop(1)  # 2nd arg should be the INI file
    if not os.path.isfile(ini_path):
        argv_error('%r is not a livetest INI file' % ini_path)
    host_config = parse_config_file(ini_path)
    return host_config
Example #5
0
def main():
    if options.debug:
        define('settings', '%s/wechat.conf' % config.PROJDIR)
    else:
        define('settings', '')
    parse_command_line()
    debug = options.debug

    config.parse_config_file(options.settings)
    if not debug:
        options.debug = False

    if options.debug:
        logging.info('Starting server at port %s in debug mode' % options.port)
    else:
        logging.info('Starting server at port %s' % options.port)

    server = HTTPServer(Application(), xheaders=True)
    server.listen(int(options.port))
    IOLoop.instance().start()
Example #6
0
def main():
    if options.debug:
        define('settings', '%s/wechat.conf' % config.PROJDIR)
    else:
        define('settings', '')
    parse_command_line()
    debug = options.debug

    config.parse_config_file(options.settings)
    if not debug:
        options.debug = False

    if options.debug:
        logging.info('Starting server at port %s in debug mode' % options.port)
    else:
        logging.info('Starting server at port %s' % options.port)

    server = HTTPServer(Application(), xheaders=True)
    server.listen(int(options.port))
    IOLoop.instance().start()
Example #7
0
def main():
    logging.basicConfig(level=logging.INFO,
                        format="%(asctime)s %(levelname)s: %(message)s [in "
                        "%(funcName)s %(filename)s:%(lineno)d]",
                        datefmt="%H:%M")
    args = parse_cmdline()
    if args.debug:
        logging.getLogger().setLevel(logging.DEBUG)
    config = parse_config_file(args.config)
    stdin_pw = handle_stdin()
    if stdin_pw:
        config['general']['password'] = stdin_pw

    run_command(args, config)
Example #8
0
def debug(tfrecord_path, config_path = None):
  
  tfrecords = [tfrecord_path]
  cfg = parse_config_file(config_path)
  
  graph = tf.Graph()
  sess = tf.Session(graph = graph)
  
  # run a session to look at the images...
  with sess.as_default(), graph.as_default():

    # Input Nodes
    images, batched_bboxes, batched_num_bboxes, image_ids = inputs.input_nodes(
      tfrecords=tfrecords,
      max_num_bboxes = cfg.MAX_NUM_BBOXES,
      num_epochs=None,
      batch_size=cfg.BATCH_SIZE,
      num_threads=cfg.NUM_INPUT_THREADS,
      add_summaries = True,
      augment=cfg.AUGMENT_IMAGE,
      shuffle_batch=False,
      cfg=cfg
    )
    
    
    coord = tf.train.Coordinator()
    
    plt.ion()

    tf.initialize_all_variables().run()
    threads = tf.train.start_queue_runners(sess=sess, coord=coord)
    done = False
    while not done:
      
      output = sess.run([images, batched_bboxes])
      for image, bboxes in zip(output[0], output[1]):
          
          plt.imshow((image * cfg.IMAGE_STD + cfg.IMAGE_MEAN).astype(np.uint8))
          
          # plot the ground truth bounding boxes
          for bbox in bboxes:
            xmin, ymin, xmax, ymax = bbox * cfg.INPUT_SIZE
            plt.plot([xmin, xmax, xmax, xmin, xmin], [ymin, ymin, ymax, ymax, ymin], 'b-')
          
          plt.show(block=False)
          
          t = raw_input("push button")
          if t != '':
            done = True
          plt.clf()
Example #9
0
def main():
    args = parse_args()

    cfg = parse_config_file(args.config_file)

    if args.batch_size != None:
        cfg.BATCH_SIZE = args.batch_size

    if args.model_name != None:
        cfg.MODEL_NAME = args.model_name

    extract_and_save(tfrecords=args.tfrecords,
                     checkpoint_path=args.checkpoint_path,
                     save_path=args.save_path,
                     num_iterations=args.batches,
                     feature_keys=args.features,
                     cfg=cfg)
Example #10
0
def main():
    args = parse_args()
    print "Command line arguments:"
    pprint.pprint(vars(args))
    print

    cfg = parse_config_file(args.config_file)
    print "Configurations:"
    pprint.pprint(cfg)
    print

    with open(args.priors) as f:
        bbox_priors = pickle.load(f)
    bbox_priors = np.array(bbox_priors).astype(np.float32)

    detect_visualize(tfrecords=args.tfrecords,
                     bbox_priors=bbox_priors,
                     checkpoint_path=args.checkpoint_path,
                     cfg=cfg)
Example #11
0
def debug(tfrecord_path, config_path):

  graph = tf.get_default_graph()

  tfrecords = [tfrecord_path]

  cfg = parse_config_file(config_path)

  # Input Nodes
  images, labels_sparse, instance_ids = construct_network_input_nodes(
    tfrecords=tfrecords,
    input_type=cfg.INPUT_TYPE,
    num_epochs=None,
    batch_size=cfg.BATCH_SIZE,
    num_threads=cfg.NUM_INPUT_THREADS,
    add_summaries = False,
    augment=cfg.AUGMENT_IMAGE,
    shuffle_batch=False,
    cfg=cfg
  )

  coord = tf.train.Coordinator()
  
  plt.ion()
  
  # run a session to look at the images...
  with tf.Session() as sess:

      tf.initialize_all_variables().run()
      threads = tf.train.start_queue_runners(sess=sess, coord=coord)

      while True:
        output = sess.run([images, labels_sparse, instance_ids])
        for image, label, image_id in zip(output[0], output[1], output[2]):

            plt.imshow((image * cfg.IMAGE_STD + cfg.IMAGE_MEAN).astype(np.uint8))
            plt.title("Class: %d\tImage: %s" % (label,image_id))
            plt.show(block=False)
            t = raw_input("push button")
            if t != '':
              return
Example #12
0
def main():
    args = parse_args()
    print "Command line arguments:"
    pprint.pprint(vars(args))
    print

    cfg = parse_config_file(args.config_file)
    print "Configurations:"
    pprint.pprint(cfg)
    print

    with open(args.priors) as f:
        bbox_priors = pickle.load(f)
    bbox_priors = np.array(bbox_priors).astype(np.float32)

    eval(tfrecords=args.tfrecords,
         bbox_priors=bbox_priors,
         summary_dir=args.summary_dir,
         checkpoint_path=args.checkpoint_path,
         max_iterations=args.max_iterations,
         cfg=cfg)
Example #13
0
def main():
    # Parse command-line arguments
    args = parse_args()

    config_file = args.pop('config', None)
    no_ssl = args.pop('nossl', False)

    # Read config file if the option was specified
    if config_file is not None:
        opts = config.parse_config_file(config_file)
    else:
        opts = config.DEFAULTS

    # Command-line arguments override config file settings
    opts.update(args)

    if no_ssl:
        opts['ssl'] = False

    # Check for label rules
    if 'labels' not in opts or not opts['labels']:
        raise AppError("Please specify some label definitions")

    # If the user or password is not specified, prompt for them now
    for opt in ('user', 'password'):
        if opt not in opts or opts[opt] is None:
            opts[opt] = getpass.getpass(opt + ': ')

    imap_args = opts.copy()
    del imap_args['folder']
    del imap_args['labels']

    client = create_imap_client(**imap_args)
    observer = ConsoleObserver()

    weighmail(client, opts['folder'], opts['labels'], observer)
    client.logout()
Example #14
0
                        action='store_true')

    if len(sys.argv) == 1:
        parser.print_help()
        sys.exit(1)

    args = parser.parse_args()
    return args

if __name__ == '__main__':

    args = parse_args()
    print "Called with:"
    print args

    cfg = parse_config_file(args.config_file)
    # Modify the configuration hyper-parameters for prep purposes.
    cfg.PHASE = "TRAIN"
    cfg.USE_BATCH_STATISTICS = True

    print "Configurations:"
    print cfg
    
    with open(args.priors) as f:
        bbox_priors = pickle.load(f)
    
    train(
      tfrecords=args.tfrecords,
      bbox_priors=bbox_priors,
      logdir=args.logdir,
      cfg=cfg,
Example #15
0
def main():
    device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')

    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    modelfile = options.modelfile

    cfg = {}
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))

    cfg.update(config.parse_variable_assignments(options.var))

    sample_rate = cfg['sample_rate']
    frame_len = cfg['frame_len']
    fps = cfg['fps']
    mel_bands = cfg['mel_bands']
    mel_min = cfg['mel_min']
    mel_max = cfg['mel_max']
    blocklen = cfg['blocklen']
    batchsize = cfg['batchsize']

    bin_nyquist = frame_len // 2 + 1
    bin_mel_max = bin_nyquist * 2 * mel_max // sample_rate

    # prepare dataset
    datadir = os.path.join(os.path.dirname(__file__), os.path.pardir,
                           'datasets', options.dataset)

    # - load filelist
    with io.open(os.path.join(datadir, 'filelists', 'train')) as f:
        filelist = [l.rstrip() for l in f if l.rstrip()]
    if options.validate:
        with io.open(os.path.join(datadir, 'filelists', 'valid')) as f:
            filelist_val = [l.strip() for l in f if l.strip()]
        filelist.extend(filelist_val)
    else:
        filelist_val = []
    # - compute spectra
    print("Computing%s spectra..." %
          (" or loading" if options.cache_spectra else ""))
    spects = []
    for fn in progress(filelist, 'File '):
        cache_fn = (options.cache_spectra
                    and os.path.join(options.cache_spectra, fn + '.npy'))
        spects.append(
            cached(cache_fn, audio.extract_spect,
                   os.path.join(datadir, 'audio', fn), sample_rate, frame_len,
                   fps))

    # - load and convert corresponding labels
    print("Loading labels...")
    labels = []
    for fn, spect in zip(filelist, spects):
        fn = os.path.join(datadir, 'labels', fn.rsplit('.', 1)[0] + '.lab')
        with io.open(fn) as f:
            segments = [l.rstrip().split() for l in f if l.rstrip()]
        segments = [(float(start), float(end), label == 'sing')
                    for start, end, label in segments]
        timestamps = np.arange(len(spect)) / float(fps)
        labels.append(create_aligned_targets(segments, timestamps, np.bool))

    # - prepare mel filterbank
    filterbank = audio.create_mel_filterbank(sample_rate, frame_len, mel_bands,
                                             mel_min, mel_max)
    filterbank = filterbank[:bin_mel_max].astype(floatX)

    if options.validate:
        spects_val = spects[-len(filelist_val):]
        spects = spects[:-len(filelist_val)]
        labels_val = labels[-len(filelist_val):]
        labels = labels[:-len(filelist_val)]

    # - precompute mel spectra, if needed, otherwise just define a generator
    mel_spects = (np.log(
        np.maximum(np.dot(spect[:, :bin_mel_max], filterbank), 1e-7))
                  for spect in spects)

    if not options.augment:
        mel_spects = list(mel_spects)
        del spects

    # - load mean/std or compute it, if not computed yet
    meanstd_file = os.path.join(os.path.dirname(__file__),
                                '%s_meanstd.npz' % options.dataset)
    try:
        with np.load(meanstd_file) as f:
            mean = f['mean']
            std = f['std']
    except (IOError, KeyError):
        print("Computing mean and standard deviation...")
        mean, std = znorm.compute_mean_std(mel_spects)
        np.savez(meanstd_file, mean=mean, std=std)
    mean = mean.astype(floatX)
    istd = np.reciprocal(std).astype(floatX)

    # - prepare training data generator
    print("Preparing training data feed...")
    if not options.augment:
        # Without augmentation, we just precompute the normalized mel spectra
        # and create a generator that returns mini-batches of random excerpts
        mel_spects = [(spect - mean) * istd for spect in mel_spects]
        batches = augment.grab_random_excerpts(mel_spects, labels, batchsize,
                                               blocklen)
    else:
        # For time stretching and pitch shifting, it pays off to preapply the
        # spline filter to each input spectrogram, so it does not need to be
        # applied to each mini-batch later.
        spline_order = cfg['spline_order']
        if spline_order > 1:
            from scipy.ndimage import spline_filter
            spects = [
                spline_filter(spect, spline_order).astype(floatX)
                for spect in spects
            ]

        # We define a function to create the mini-batch generator. This allows
        # us to easily create multiple generators for multithreading if needed.
        def create_datafeed(spects, labels):
            # With augmentation, as we want to apply random time-stretching,
            # we request longer excerpts than we finally need to return.
            max_stretch = cfg['max_stretch']
            batches = augment.grab_random_excerpts(
                spects,
                labels,
                batchsize=batchsize,
                frames=int(blocklen / (1 - max_stretch)))

            # We wrap the generator in another one that applies random time
            # stretching and pitch shifting, keeping a given number of frames
            # and bins only.
            max_shift = cfg['max_shift']
            batches = augment.apply_random_stretch_shift(batches,
                                                         max_stretch,
                                                         max_shift,
                                                         keep_frames=blocklen,
                                                         keep_bins=bin_mel_max,
                                                         order=spline_order,
                                                         prefiltered=True)

            # We transform the excerpts to mel frequency and log magnitude.
            batches = augment.apply_filterbank(batches, filterbank)
            batches = augment.apply_logarithm(batches)

            # We apply random frequency filters
            max_db = cfg['max_db']
            batches = augment.apply_random_filters(batches,
                                                   filterbank,
                                                   mel_max,
                                                   max_db=max_db)

            # We apply normalization
            batches = augment.apply_znorm(batches, mean, istd)

            return batches

        # We start the mini-batch generator and augmenter in one or more
        # background threads or processes (unless disabled).
        bg_threads = cfg['bg_threads']
        bg_processes = cfg['bg_processes']
        if not bg_threads and not bg_processes:
            # no background processing: just create a single generator
            batches = create_datafeed(spects, labels)
        elif bg_threads:
            # multithreading: create a separate generator per thread
            batches = augment.generate_in_background(
                [create_datafeed(spects, labels) for _ in range(bg_threads)],
                num_cached=bg_threads * 5)
        elif bg_processes:
            # multiprocessing: single generator is forked along with processes
            batches = augment.generate_in_background(
                [create_datafeed(spects, labels)] * bg_processes,
                num_cached=bg_processes * 25,
                in_processes=True)

    ###########################################################################
    #-----------Main changes to code to make it work with pytorch-------------#
    ###########################################################################

    print("preparing training function...")
    mdl = model.CNNModel()
    mdl = mdl.to(device)

    #Setting up learning rate and learning rate parameters
    initial_eta = cfg['initial_eta']
    eta_decay = cfg['eta_decay']
    momentum = cfg['momentum']
    eta_decay_every = cfg.get('eta_decay_every', 1)
    eta = initial_eta

    #set up loss
    criterion = torch.nn.BCELoss()

    #set up optimizer
    optimizer = torch.optim.SGD(mdl.parameters(),
                                lr=eta,
                                momentum=momentum,
                                nesterov=True)
    scheduler = torch.optim.lr_scheduler.StepLR(optimizer,
                                                step_size=eta_decay_every,
                                                gamma=eta_decay)

    #set up optimizer
    writer = SummaryWriter(os.path.join(modelfile, 'runs'))

    epochs = cfg['epochs']
    epochsize = cfg['epochsize']
    batches = iter(batches)

    #conditions to save model
    best_val_loss = 100000.
    best_val_error = 1.

    for epoch in range(epochs):
        # - Initialize certain parameters that are used to monitor training
        err = 0
        total_norm = 0
        loss_accum = 0
        mdl.train(True)
        # - Compute the L-2 norm of the gradients
        for p in mdl.parameters():
            if p.grad is not None:
                param_norm = p.grad.data.norm(2)
                total_norm += param_norm.item()**2
        total_norm = total_norm**(1. / 2)

        # - Start the training for this epoch
        for batch in progress(range(epochsize),
                              min_delay=0.5,
                              desc='Epoch %d/%d: Batch ' %
                              (epoch + 1, epochs)):
            data = next(batches)
            input_data = np.transpose(data[0][:, :, :, np.newaxis],
                                      (0, 3, 1, 2))
            labels = data[1][:, np.newaxis].astype(np.float32)

            #map labels to make them softer
            labels = (0.02 + 0.96 * labels)
            optimizer.zero_grad()

            outputs = mdl(torch.from_numpy(input_data).to(device))
            loss = criterion(outputs, torch.from_numpy(labels).to(device))
            loss.backward()
            optimizer.step()
            loss_accum += loss.item()

        # - Compute validation loss and error if desired
        if options.validate:

            from eval import evaluate
            mdl.train(False)
            val_loss = 0
            preds = []
            labs = []
            max_len = fps

            mel_spects_val = (np.log(
                np.maximum(np.dot(spect[:, :bin_mel_max], filterbank), 1e-7))
                              for spect in spects_val)

            mel_spects_val = [(spect - mean) * istd
                              for spect in mel_spects_val]

            num_iter = 0

            for spect, label in zip(mel_spects_val, labels_val):
                num_excerpts = len(spect) - blocklen + 1
                excerpts = np.lib.stride_tricks.as_strided(
                    spect,
                    shape=(num_excerpts, blocklen, spect.shape[1]),
                    strides=(spect.strides[0], spect.strides[0],
                             spect.strides[1]))

                # - Pass mini-batches through the network and concatenate results
                for pos in range(0, num_excerpts, batchsize):
                    input_data = np.transpose(
                        excerpts[pos:pos + batchsize, :, :, np.newaxis],
                        (0, 3, 1, 2))
                    if (pos + batchsize > num_excerpts):
                        label_batch = label[blocklen // 2 + pos:blocklen // 2 +
                                            num_excerpts,
                                            np.newaxis].astype(np.float32)
                    else:
                        label_batch = label[blocklen // 2 + pos:blocklen // 2 +
                                            pos + batchsize,
                                            np.newaxis].astype(np.float32)

                    pred = mdl(torch.from_numpy(input_data).to(device))
                    e = criterion(pred,
                                  torch.from_numpy(label_batch).to(device))
                    preds = np.append(preds, pred[:, 0].cpu().detach().numpy())
                    labs = np.append(labs, label_batch)
                    val_loss += e.item()
                    num_iter += 1

            print("Validation loss: %.3f" % (val_loss / num_iter))
            _, results = evaluate(preds, labs)
            print("Validation error: %.3f" % (1 - results['accuracy']))

            if (val_loss / num_iter < best_val_loss
                    and (1 - results['accuracy']) < best_val_error):
                torch.save(mdl.state_dict(),
                           os.path.join(modelfile, 'model.pth'))
                best_val_loss = val_loss / num_iter
                best_val_error = 1 - results['accuracy']
                print('New saved model', best_val_loss, best_val_error)

        #Update the learning rate
        scheduler.step()

        print('Training Loss per epoch', loss_accum / epochsize)

        # - Save parameters for examining
        writer.add_scalar('Training Loss', loss_accum / epochsize, epoch)
        writer.add_scalar('Validation loss', val_loss / num_iter, epoch)
        writer.add_scalar('Gradient norm', total_norm, epoch)
        writer.add_scalar('Validation error', 1 - results['accuracy'])
        for param_group in optimizer.param_groups:
            print(param_group['lr'])

    if not options.validate:
        torch.save(mdl.state_dict(), os.path.join(modelfile, 'model.pth'))
Example #16
0
def main():
    print(torch.cuda.is_available())
    device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    modelfile = options.modelfile
    lossgradient = options.lossgradient

    cfg = {}
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))

    cfg.update(config.parse_variable_assignments(options.var))

    outfile = options.outfile
    sample_rate = cfg['sample_rate']
    frame_len = cfg['frame_len']
    fps = cfg['fps']
    mel_bands = cfg['mel_bands']
    mel_min = cfg['mel_min']
    mel_max = cfg['mel_max']
    blocklen = cfg['blocklen']
    batchsize = cfg['batchsize']

    bin_nyquist = frame_len // 2 + 1
    bin_mel_max = bin_nyquist * 2 * mel_max // sample_rate

    # prepare dataset
    print("Preparing data reading...")
    datadir = os.path.join(os.path.dirname(__file__), os.path.pardir,
                           'datasets', options.dataset)

    # - load filelist
    with io.open(os.path.join(datadir, 'filelists', 'valid')) as f:
        filelist = [l.rstrip() for l in f if l.rstrip()]
    with io.open(os.path.join(datadir, 'filelists', 'test')) as f:
        filelist += [l.rstrip() for l in f if l.rstrip()]

    # - load mean/std
    meanstd_file = os.path.join(os.path.dirname(__file__),
                                '%s_meanstd.npz' % options.dataset)

    dataloader = DatasetLoader(options.dataset,
                               options.cache_spectra,
                               datadir,
                               input_type=options.input_type,
                               filelist=filelist)
    mel_spects, labels = dataloader.prepare_batches(sample_rate,
                                                    frame_len,
                                                    fps,
                                                    mel_bands,
                                                    mel_min,
                                                    mel_max,
                                                    blocklen,
                                                    batchsize,
                                                    batch_data=False)

    with np.load(meanstd_file) as f:
        mean = f['mean']
        std = f['std']
    mean = mean.astype(floatX)
    istd = np.reciprocal(std).astype(floatX)

    mdl = model.CNNModel(input_type='mel_spects_norm',
                         is_zeromean=False,
                         meanstd_file=meanstd_file,
                         device=device)
    mdl.load_state_dict(torch.load(modelfile))
    mdl.to(device)
    mdl.eval()

    if (lossgradient != 'None'):
        mdl_lossgrad = model.CNNModel(input_type=options.input_type,
                                      is_zeromean=False,
                                      sample_rate=sample_rate,
                                      frame_len=frame_len,
                                      fps=fps,
                                      mel_bands=mel_bands,
                                      mel_min=mel_min,
                                      mel_max=mel_max,
                                      bin_mel_max=bin_mel_max,
                                      meanstd_file=meanstd_file,
                                      device=device)
        mdl_lossgrad.load_state_dict(torch.load(lossgradient))
        mdl_lossgrad.to(device)
        mdl_lossgrad.eval()
        criterion = torch.nn.BCELoss()
        loss_grad_val = dataloader.prepare_loss_grad_batches(
            options.loss_grad_save, mel_spects, labels, mdl_lossgrad,
            criterion, blocklen, batchsize, device)

    # run prediction loop
    print("Predicting:")
    predictions = []
    #for spect, g in zip(mel_spects, loss_grad_val):
    c = 0
    for spect in progress(mel_spects, total=len(filelist), desc='File '):
        if (lossgradient != 'None'):
            g = loss_grad_val[c]
        c += 1
        # naive way: pass excerpts of the size used during training
        # - view spectrogram memory as a 3-tensor of overlapping excerpts
        num_excerpts = len(spect) - blocklen + 1
        excerpts = np.lib.stride_tricks.as_strided(
            spect.astype(floatX),
            shape=(num_excerpts, blocklen, spect.shape[1]),
            strides=(spect.strides[0], spect.strides[0], spect.strides[1]))
        preds = np.zeros((num_excerpts, 1))
        count = 0
        for pos in range(0, num_excerpts, batchsize):
            input_data = np.transpose(
                excerpts[pos:pos + batchsize, :, :, np.newaxis], (0, 3, 1, 2))
            input_data = (input_data - mean) * istd
            if lossgradient != 'None':
                for i in range(input_data.shape[0]):
                    if (options.lossgrad_algorithm == 'grad'):
                        rank_matrix = np.abs(g[i + pos])
                    elif (options.lossgrad_algorithm == 'gradxinp'):
                        rank_matrix = np.squeeze(g[i + pos] *
                                                 input_data[i, :, :, :])
                    elif (options.lossgrad_algorithm == 'gradorig'):
                        rank_matrix = g[i + pos]
                    if (options.ROAR == 1):
                        v = np.argsort(rank_matrix,
                                       axis=None)[-cfg['occlude']:]
                    else:
                        v = np.argsort(rank_matrix, axis=None)[:cfg['occlude']]
                    input_data[i, :, v // 80, v % 80] = 0
            else:
                for i in range(input_data.shape[0]):
                    #print('random')
                    v = np.random.choice(115 * 80,
                                         cfg['occlude'],
                                         replace=False)
                    input_data[i, :, v // 80, v % 80] = 0

            count += 1

            #print('Here')
            #preds = np.vstack(mdl.forward(torch.from_numpy(
            #            np.transpose(excerpts[pos:pos + batchsize,:,:,
            #            np.newaxis],(0,3,1,2))).to(device)).cpu().detach().numpy()
            #        for pos in range(0, num_excerpts, batchsize))

            preds[pos:pos + batchsize, :] = mdl(
                torch.from_numpy(input_data).to(
                    device)).cpu().detach().numpy()
        print('Here')
        predictions.append(preds)
    # save predictions
    print("Saving predictions")
    np.savez(outfile, **{fn: pred for fn, pred in zip(filelist, predictions)})
                          required=True, type=str)

    parser.add_argument('--export_path', dest='export_path',
                          help='Path to a directory where the exported model will be saved.',
                          required=True, type=str)
    
    parser.add_argument('--export_version', dest='export_version',
                        help='Version number of the model.',
                        required=True, type=int)
    
    parser.add_argument('--config', dest='config_file',
                        help='Path to the configuration file.',
                        required=True, type=str)
    

    args = parser.parse_args()
    
    return args

if __name__ == '__main__':

    args = parse_args()
    print "Called with:"
    print pprint.pprint(args)

    cfg = parse_config_file(args.config_file)

    print "Configurations:"
    print pprint.pprint(cfg)

    export(args.checkpoint_path, args.export_path, args.export_version, cfg=cfg)
Example #18
0
def main():
    print(torch.cuda.is_available())
    device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    modelfile = options.modelfile

    cfg = {}
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))

    cfg.update(config.parse_variable_assignments(options.var))

    outfile = options.outfile
    sample_rate = cfg['sample_rate']
    frame_len = cfg['frame_len']
    fps = cfg['fps']
    mel_bands = cfg['mel_bands']
    mel_min = cfg['mel_min']
    mel_max = cfg['mel_max']
    blocklen = cfg['blocklen']
    batchsize = cfg['batchsize']

    bin_nyquist = frame_len // 2 + 1
    bin_mel_max = bin_nyquist * 2 * mel_max // sample_rate

    # prepare dataset
    print("Preparing data reading...")
    datadir = os.path.join(os.path.dirname(__file__), os.path.pardir,
                           'datasets', options.dataset)

    # - load filelist
    with io.open(os.path.join(datadir, 'filelists', 'valid')) as f:
        filelist = [l.rstrip() for l in f if l.rstrip()]
    with io.open(os.path.join(datadir, 'filelists', 'test')) as f:
        filelist += [l.rstrip() for l in f if l.rstrip()]

    # - create generator for spectra
    spects = (cached(
        options.cache_spectra
        and os.path.join(options.cache_spectra, fn + '.npy'),
        audio.extract_spect, os.path.join(datadir, 'audio',
                                          fn), sample_rate, frame_len, fps)
              for fn in filelist)

    # - pitch-shift if needed
    if options.pitchshift:
        import scipy.ndimage
        spline_order = 2
        spects = (scipy.ndimage.affine_transform(
            spect, (1, 1 / (1 + options.pitchshift / 100.)),
            output_shape=(len(spect), mel_max),
            order=spline_order) for spect in spects)

    # - prepare mel filterbank
    filterbank = audio.create_mel_filterbank(sample_rate, frame_len, mel_bands,
                                             mel_min, mel_max)
    filterbank = filterbank[:bin_mel_max].astype(floatX)

    # - define generator for mel spectra
    spects = (np.log(
        np.maximum(np.dot(spect[:, :bin_mel_max], filterbank), 1e-7))
              for spect in spects)

    # - load mean/std
    meanstd_file = os.path.join(os.path.dirname(__file__),
                                '%s_meanstd.npz' % options.dataset)
    with np.load(meanstd_file) as f:
        mean = f['mean']
        std = f['std']
    mean = mean.astype(floatX)
    istd = np.reciprocal(std).astype(floatX)

    # - define generator for Z-scoring
    spects = ((spect - mean) * istd for spect in spects)

    # - define generator for silence-padding
    pad = np.tile((np.log(1e-7) - mean) * istd, (blocklen // 2, 1))
    spects = (np.concatenate((pad, spect, pad), axis=0) for spect in spects)

    # - we start the generator in a background thread (not required)
    spects = augment.generate_in_background([spects], num_cached=1)

    mdl = model.CNNModel()
    mdl.load_state_dict(torch.load(modelfile))
    mdl.to(device)
    mdl.eval()

    # run prediction loop
    print("Predicting:")
    predictions = []
    for spect in progress(spects, total=len(filelist), desc='File '):
        # naive way: pass excerpts of the size used during training
        # - view spectrogram memory as a 3-tensor of overlapping excerpts
        num_excerpts = len(spect) - blocklen + 1
        excerpts = np.lib.stride_tricks.as_strided(
            spect,
            shape=(num_excerpts, blocklen, spect.shape[1]),
            strides=(spect.strides[0], spect.strides[0], spect.strides[1]))

        # - pass mini-batches through the network and concatenate results
        preds = np.vstack(
            mdl(
                torch.from_numpy(
                    np.transpose(
                        excerpts[pos:pos + batchsize, :, :, np.newaxis], (
                            0, 3, 1, 2))).to(device)).cpu().detach().numpy()
            for pos in range(0, num_excerpts, batchsize))
        predictions.append(preds)

    # save predictions
    print("Saving predictions")
    np.savez(outfile, **{fn: pred for fn, pred in zip(filelist, predictions)})
Example #19
0
def main():
    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    modelfile = options.modelfile
    if options.load_spectra != 'memory' and not options.cache_spectra:
        parser.error('option --load-spectra=%s requires --cache-spectra' %
                     options.load_spectra)

    # read configuration files and immediate settings
    cfg = {}
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))
    cfg.update(config.parse_variable_assignments(options.var))

    # read some settings into local variables
    sample_rate = cfg['sample_rate']
    frame_len = cfg['frame_len']
    fps = cfg['fps']
    mel_bands = cfg['mel_bands']
    mel_min = cfg['mel_min']
    mel_max = cfg['mel_max']
    blocklen = cfg['blocklen']
    batchsize = cfg['batchsize']

    bin_nyquist = frame_len // 2 + 1
    if cfg['filterbank'] == 'mel_learn':
        bin_mel_max = bin_nyquist
    else:
        bin_mel_max = bin_nyquist * 2 * mel_max // sample_rate

    # prepare dataset
    datadir = os.path.join(os.path.dirname(__file__), os.path.pardir,
                           'datasets', options.dataset)

    # - load filelist
    with io.open(
            os.path.join(datadir, 'filelists',
                         cfg.get('filelist.train', 'train'))) as f:
        filelist = [l.rstrip() for l in f if l.rstrip()]
    if options.validate:
        with io.open(
                os.path.join(datadir, 'filelists',
                             cfg.get('filelist.valid', 'valid'))) as f:
            filelist_val = [l.rstrip() for l in f if l.rstrip()]
        filelist.extend(filelist_val)
    else:
        filelist_val = []

    # - compute spectra
    print("Computing%s spectra..." %
          (" or loading" if options.cache_spectra else ""))
    spects = []
    for fn in progress(filelist, 'File '):
        cache_fn = (options.cache_spectra
                    and os.path.join(options.cache_spectra, fn + '.npy'))
        spects.append(
            cached(cache_fn,
                   audio.extract_spect,
                   os.path.join(datadir, 'audio', fn),
                   sample_rate,
                   frame_len,
                   fps,
                   loading_mode=options.load_spectra))

    # - load and convert corresponding labels
    print("Loading labels...")
    labels = []
    for fn, spect in zip(filelist, spects):
        fn = os.path.join(datadir, 'labels', fn.rsplit('.', 1)[0] + '.lab')
        with io.open(fn) as f:
            segments = [l.rstrip().split() for l in f if l.rstrip()]
        segments = [(float(start), float(end), label == 'sing')
                    for start, end, label in segments]
        timestamps = np.arange(len(spect)) / float(fps)
        labels.append(create_aligned_targets(segments, timestamps, np.bool))

    # - split off validation data, if needed
    if options.validate:
        spects_val = spects[-len(filelist_val):]
        spects = spects[:-len(filelist_val)]
        labels_val = labels[-len(filelist_val):]
        labels = labels[:-len(filelist_val)]

    # - prepare training data generator
    print("Preparing training data feed...")
    if not options.augment:
        # Without augmentation, we just create a generator that returns
        # mini-batches of random excerpts
        batches = augment.grab_random_excerpts(spects, labels, batchsize,
                                               blocklen, bin_mel_max)
        batches = augment.generate_in_background([batches], num_cached=15)
    else:
        # For time stretching and pitch shifting, it pays off to preapply the
        # spline filter to each input spectrogram, so it does not need to be
        # applied to each mini-batch later.
        spline_order = cfg['spline_order']
        if spline_order > 1 and options.load_spectra == 'memory':
            from scipy.ndimage import spline_filter
            spects = [
                spline_filter(spect, spline_order).astype(floatX)
                for spect in spects
            ]
            prefiltered = True
        else:
            prefiltered = False

        # We define a function to create the mini-batch generator. This allows
        # us to easily create multiple generators for multithreading if needed.
        def create_datafeed(spects, labels):
            # With augmentation, as we want to apply random time-stretching,
            # we request longer excerpts than we finally need to return.
            max_stretch = cfg['max_stretch']
            batches = augment.grab_random_excerpts(
                spects,
                labels,
                batchsize=batchsize,
                frames=int(blocklen / (1 - max_stretch)))

            # We wrap the generator in another one that applies random time
            # stretching and pitch shifting, keeping a given number of frames
            # and bins only.
            max_shift = cfg['max_shift']
            batches = augment.apply_random_stretch_shift(
                batches,
                max_stretch,
                max_shift,
                keep_frames=blocklen,
                keep_bins=bin_mel_max,
                order=spline_order,
                prefiltered=prefiltered)

            # We apply random frequency filters
            max_db = cfg['max_db']
            batches = augment.apply_random_filters(batches, mel_max, max_db)

            # We apply random loudness changes
            max_loudness = cfg['max_loudness']
            if max_loudness:
                batches = augment.apply_random_loudness(batches, max_loudness)

            return batches

        # We start the mini-batch generator and augmenter in one or more
        # background threads or processes (unless disabled).
        bg_threads = cfg['bg_threads']
        bg_processes = cfg['bg_processes']
        if not bg_threads and not bg_processes:
            # no background processing: just create a single generator
            batches = create_datafeed(spects, labels)
        elif bg_threads:
            # multithreading: create a separate generator per thread
            batches = augment.generate_in_background(
                [create_datafeed(spects, labels) for _ in range(bg_threads)],
                num_cached=bg_threads * 5)
        elif bg_processes:
            # multiprocessing: single generator is forked along with processes
            batches = augment.generate_in_background(
                [create_datafeed(spects, labels)] * bg_processes,
                num_cached=bg_processes * 25,
                in_processes=True)

    print("Preparing training function...")
    # instantiate neural network
    input_var = T.tensor3('input')
    inputs = input_var.dimshuffle(0, 'x', 1, 2)  # insert "channels" dimension
    network = model.architecture(inputs, (None, 1, blocklen, bin_mel_max), cfg)
    print(
        "- %d layers (%d with weights), %f mio params" %
        (len(lasagne.layers.get_all_layers(network)),
         sum(hasattr(l, 'W') for l in lasagne.layers.get_all_layers(network)),
         lasagne.layers.count_params(network, trainable=True) / 1e6))
    print("- weight shapes: %r" % [
        l.W.get_value().shape for l in lasagne.layers.get_all_layers(network)
        if hasattr(l, 'W') and hasattr(l.W, 'get_value')
    ])

    # create cost expression
    target_var = T.vector('targets')
    targets = (0.02 + 0.96 * target_var)  # map 0 -> 0.02, 1 -> 0.98
    targets = targets.dimshuffle(0, 'x')  # turn into column vector
    outputs = lasagne.layers.get_output(network, deterministic=False)
    cost = T.mean(lasagne.objectives.binary_crossentropy(outputs, targets))
    if cfg.get('l2_decay', 0):
        cost_l2 = lasagne.regularization.regularize_network_params(
            network, lasagne.regularization.l2) * cfg['l2_decay']
    else:
        cost_l2 = 0

    # prepare and compile training function
    params = lasagne.layers.get_all_params(network, trainable=True)
    initial_eta = cfg['initial_eta']
    eta_decay = cfg['eta_decay']
    eta_decay_every = cfg.get('eta_decay_every', 1)
    patience = cfg.get('patience', 0)
    trials_of_patience = cfg.get('trials_of_patience', 1)
    patience_criterion = cfg.get(
        'patience_criterion',
        'valid_loss' if options.validate else 'train_loss')
    momentum = cfg['momentum']
    first_params = params[:cfg['first_params']]
    first_params_eta_scale = cfg['first_params_eta_scale']
    if cfg['learn_scheme'] == 'nesterov':
        learn_scheme = lasagne.updates.nesterov_momentum
    elif cfg['learn_scheme'] == 'momentum':
        learn_scheme = lasagne.update.momentum
    elif cfg['learn_scheme'] == 'adam':
        learn_scheme = lasagne.updates.adam
    else:
        raise ValueError('Unknown learn_scheme=%s' % cfg['learn_scheme'])
    eta = theano.shared(lasagne.utils.floatX(initial_eta))
    if not first_params or first_params_eta_scale == 1:
        updates = learn_scheme(cost + cost_l2, params, eta, momentum)
    else:
        grads = theano.grad(cost + cost_l2, params)
        updates = learn_scheme(grads[len(first_params):],
                               params[len(first_params):], eta, momentum)
        if first_params_eta_scale > 0:
            updates.update(
                learn_scheme(grads[:len(first_params)], first_params,
                             eta * first_params_eta_scale, momentum))
    print("Compiling training function...")
    train_fn = theano.function([input_var, target_var], cost, updates=updates)

    # prepare and compile validation function, if requested
    if options.validate:
        print("Compiling validation function...")
        import model_to_fcn
        network_test = model_to_fcn.model_to_fcn(network, allow_unlink=False)
        outputs_test = lasagne.layers.get_output(network_test,
                                                 deterministic=True)
        cost_test = T.mean(
            lasagne.objectives.binary_crossentropy(outputs_test, targets))
        val_fn = theano.function([input_var, target_var],
                                 [cost_test, outputs_test])

    # run training loop
    print("Training:")
    epochs = cfg['epochs']
    epochsize = cfg['epochsize']
    batches = iter(batches)
    if options.save_errors:
        errors = []
    if first_params and cfg['first_params_log']:
        first_params_hist = []
    if patience > 0:
        best_error = np.inf
        best_state = get_state(network, updates)
    for epoch in range(epochs):
        # actual training
        err = 0
        for batch in progress(range(epochsize),
                              min_delay=.5,
                              desc='Epoch %d/%d: Batch ' %
                              (epoch + 1, epochs)):
            err += train_fn(*next(batches))
            if not np.isfinite(err):
                print("\nEncountered NaN loss in training. Aborting.")
                sys.exit(1)
            if first_params and cfg['first_params_log'] and (
                    batch % cfg['first_params_log'] == 0):
                first_params_hist.append(
                    tuple(param.get_value() for param in first_params))
                np.savez(
                    modelfile[:-4] + '.hist.npz', **{
                        'param%d' % i: param
                        for i, param in enumerate(zip(*first_params_hist))
                    })

        # report training loss
        print("Train loss: %.3f" % (err / epochsize))
        if options.save_errors:
            errors.append(err / epochsize)

        # compute and report validation loss, if requested
        if options.validate:
            val_err = 0
            preds = []
            max_len = int(fps * cfg.get('val.max_len', 30))
            for spect, label in zip(spects_val, labels_val):
                # pick excerpt of val.max_len seconds in center of file
                excerpt = slice(max(0, (len(spect) - max_len) // 2),
                                (len(spect) + max_len) // 2)
                # crop to maximum length and required spectral bins
                spect = spect[None, excerpt, :bin_mel_max]
                # crop to maximum length and remove edges lost in the network
                label = label[excerpt][blocklen // 2:-(blocklen // 2)]
                e, pred = val_fn(spect, label)
                val_err += e
                preds.append((pred[:, 0], label))
            print("Validation loss: %.3f" % (val_err / len(filelist_val)))
            from eval import evaluate
            _, results = evaluate(*zip(*preds))
            print("Validation error: %.3f" % (1 - results['accuracy']))
            if options.save_errors:
                errors.append(val_err / len(filelist_val))
                errors.append(1 - results['accuracy'])

        # update learning rate and/or apply early stopping, if needed
        if patience > 0:
            if patience_criterion == 'train_loss':
                cur_error = err / epochsize
            elif patience_criterion == 'valid_loss':
                cur_error = val_err / len(filelist_val)
            elif patience_criterion == 'valid_error':
                cur_error = 1 - results['accuracy']
            if cur_error <= best_error:
                best_error = cur_error
                best_state = get_state(network, updates)
                patience = cfg['patience']
            else:
                patience -= 1
                if patience == 0:
                    if eta_decay_every == 'trial_of_patience' and eta_decay != 1:
                        eta.set_value(eta.get_value() *
                                      lasagne.utils.floatX(eta_decay))
                    restore_state(network, updates, best_state)
                    patience = cfg['patience']
                    trials_of_patience -= 1
                    print("Lost patience (%d remaining trials)." %
                          trials_of_patience)
                    if trials_of_patience == 0:
                        break
        if eta_decay_every != 'trial_of_patience' and eta_decay != 1 and \
                (epoch + 1) % eta_decay_every == 0:
            eta.set_value(eta.get_value() * lasagne.utils.floatX(eta_decay))

    # save final network
    print("Saving final model")
    np.savez(
        modelfile, **{
            'param%d' % i: p
            for i, p in enumerate(lasagne.layers.get_all_param_values(network))
        })
    with io.open(modelfile + '.vars', 'wb') as f:
        f.writelines('%s=%s\n' % kv for kv in cfg.items())
    if options.save_errors:
        np.savez(modelfile[:-len('.npz')] + '.err.npz',
                 np.asarray(errors).reshape(epoch + 1, -1))
Example #20
0
def main():
    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    modelfile = options.modelfile

    # read configuration files and immediate settings
    cfg = {}
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))
    cfg.update(config.parse_variable_assignments(options.var))

    # prepare dataset
    datadir = os.path.join(os.path.dirname(__file__), os.path.pardir,
                           'datasets', options.dataset)

    print("Preparing training data feed...")
    with io.open(os.path.join(datadir, 'filelists', 'train')) as f:
        filelist = [l.rstrip() for l in f if l.rstrip()]
    train_feed, train_formats = data.prepare_datafeed(filelist, datadir,
                                                      'train', cfg)

    # If told so, we plot some mini-batches on screen.
    if cfg.get('plot_datafeed'):
        import matplotlib.pyplot as plt
        for batch in data.run_datafeed(train_feed, cfg):
            plt.matshow(np.log(batch['spect'][0]).T,
                        aspect='auto',
                        origin='lower',
                        cmap='hot',
                        interpolation='nearest')
            plt.colorbar()
            plt.title(str(batch['label'][0]))
            plt.show()

    # We start the mini-batch generator and augmenter in one or more
    # background threads or processes (unless disabled).
    bg_threads = cfg['bg_threads']
    bg_processes = cfg['bg_processes']
    if not bg_threads and not bg_processes:
        # no background processing: just create a single generator
        batches = data.run_datafeed(train_feed, cfg)
    elif bg_threads:
        # multithreading: create a separate generator per thread
        batches = augment.generate_in_background([
            data.run_datafeed(feed, cfg)
            for feed in data.split_datafeed(train_feed, bg_threads, cfg)
        ],
                                                 num_cached=bg_threads * 2)
    elif bg_processes:
        # multiprocessing: single generator is forked along with processes
        batches = augment.generate_in_background(
            [data.run_datafeed(train_feed, cfg)] * bg_processes,
            num_cached=bg_processes * 25,
            in_processes=True)

    # If told so, we benchmark the creation of a given number of mini-batches.
    if cfg.get('benchmark_datafeed'):
        print("Benchmark: %d mini-batches of %d items " %
              (cfg['benchmark_datafeed'], cfg['batchsize']),
              end='')
        if bg_threads:
            print("(in %d threads): " % bg_threads)
        elif bg_processes:
            print("(in %d processes): " % bg_processes)
        else:
            print("(in main thread): ")
        import time
        import itertools
        t0 = time.time()
        next(
            itertools.islice(batches, cfg['benchmark_datafeed'],
                             cfg['benchmark_datafeed']), None)
        t1 = time.time()
        print(t1 - t0)
        return

    # - prepare validation data generator
    if options.validate:
        print("Preparing validation data feed...")
        with io.open(os.path.join(datadir, 'filelists', 'valid')) as f:
            filelist_val = [l.rstrip() for l in f if l.rstrip()]
        val_feed, val_formats = data.prepare_datafeed(filelist_val, datadir,
                                                      'valid', cfg)
        if bg_threads or bg_processes:
            multi = bg_threads or bg_processes
            val_feed = data.split_datafeed(val_feed, multi, cfg)

        def run_val_datafeed():
            if bg_threads or bg_processes:
                return augment.generate_in_background(
                    [data.run_datafeed(feed, cfg) for feed in val_feed],
                    num_cached=multi,
                    in_processes=bool(bg_processes))
            else:
                return data.run_datafeed(val_feed, cfg)

    print("Preparing training function...")
    # instantiate neural network
    input_vars = {
        name: T.TensorType(str(np.dtype(dtype)), (False, ) * len(shape))(name)
        for name, (dtype, shape) in train_formats.items()
    }
    input_shapes = {
        name: shape
        for name, (dtype, shape) in train_formats.items()
    }
    network = model.architecture(input_vars, input_shapes, cfg)
    print(
        "- %d layers (%d with weights), %f mio params" %
        (len(lasagne.layers.get_all_layers(network)),
         sum(hasattr(l, 'W') for l in lasagne.layers.get_all_layers(network)),
         lasagne.layers.count_params(network, trainable=True) / 1e6))
    print("- weight shapes: %r" % [
        l.W.get_value().shape for l in lasagne.layers.get_all_layers(network)
        if hasattr(l, 'W') and hasattr(l.W, 'get_value')
    ])
    cost_vars = dict(input_vars)

    # prepare for born-again-network, if needed
    if cfg.get('ban'):
        network2 = model.architecture(input_vars, input_shapes, cfg)
        with np.load(cfg['ban'], encoding='latin1') as f:
            lasagne.layers.set_all_param_values(
                network2, [f['param%d' % i] for i in range(len(f.files))])
        cost_vars['pseudo_label'] = lasagne.layers.get_output(
            network2, deterministic=True)

    # load pre-trained weights, if needed
    if cfg.get('init_from'):
        param_values = []
        for fn in cfg['init_from'].split(':'):
            with np.load(fn, encoding='latin1') as f:
                param_values.extend(f['param%d' % i]
                                    for i in range(len(f.files)))
        lasagne.layers.set_all_param_values(network, param_values)
        del param_values

    # create cost expression
    outputs = lasagne.layers.get_output(network, deterministic=False)
    cost = T.mean(model.cost(outputs, cost_vars, 'train', cfg))
    if cfg.get('l2_decay', 0):
        cost_l2 = lasagne.regularization.regularize_network_params(
            network, lasagne.regularization.l2) * cfg['l2_decay']
    else:
        cost_l2 = 0

    # prepare and compile training function
    params = lasagne.layers.get_all_params(network, trainable=True)
    initial_eta = cfg['initial_eta']
    eta_decay = cfg['eta_decay']
    eta_decay_every = cfg.get('eta_decay_every', 1)
    eta_cycle = tuple(map(float, str(cfg['eta_cycle']).split(':')))
    if eta_cycle == (0, ):
        eta_cycle = (1, )  # so eta_cycle=0 equals disabling it
    patience = cfg.get('patience', 0)
    trials_of_patience = cfg.get('trials_of_patience', 1)
    patience_criterion = cfg.get(
        'patience_criterion',
        'valid_loss' if options.validate else 'train_loss')
    momentum = cfg['momentum']
    first_params = params[:cfg['first_params']]
    first_params_eta_scale = cfg['first_params_eta_scale']
    if cfg['learn_scheme'] == 'nesterov':
        learn_scheme = lasagne.updates.nesterov_momentum
    elif cfg['learn_scheme'] == 'momentum':
        learn_scheme = lasagne.update.momentum
    elif cfg['learn_scheme'] == 'adam':
        learn_scheme = lasagne.updates.adam
    else:
        raise ValueError('Unknown learn_scheme=%s' % cfg['learn_scheme'])
    eta = theano.shared(lasagne.utils.floatX(initial_eta))
    if not first_params or first_params_eta_scale == 1:
        updates = learn_scheme(cost + cost_l2, params, eta, momentum)
    else:
        grads = theano.grad(cost + cost_l2, params)
        updates = learn_scheme(grads[len(first_params):],
                               params[len(first_params):], eta, momentum)
        if first_params_eta_scale > 0:
            updates.update(
                learn_scheme(grads[:len(first_params)], first_params,
                             eta * first_params_eta_scale, momentum))
    print("Compiling training function...")
    train_fn = theano.function(list(input_vars.values()),
                               cost,
                               updates=updates,
                               on_unused_input='ignore')

    # prepare and compile validation function, if requested
    if options.validate:
        print("Compiling validation function...")
        outputs_test = lasagne.layers.get_output(network, deterministic=True)
        cost_test = T.mean(model.cost(outputs_test, input_vars, 'valid', cfg))
        if isinstance(outputs_test, (list, tuple)):
            outputs_test = outputs_test[0]
        val_fn = theano.function([input_vars[k] for k in val_formats],
                                 [cost_test, outputs_test],
                                 on_unused_input='ignore')

    # restore previous training state, or create fresh training state
    state = {}
    if options.keep_state:
        statefile = modelfile[:-len('.npz')] + '.state'
        if os.path.exists(statefile):
            print("Restoring training state...")
            state = np.load(modelfile[:-len('.npz')] + '.state',
                            encoding='latin1')
            restore_state(network, updates, state['network'])
    epochs = cfg['epochs']
    epochsize = cfg['epochsize']
    batches = iter(batches)
    if options.save_errors:
        errors = state.get('errors', [])
    if first_params and cfg['first_params_log']:
        first_params_hist = []
        if options.keep_state and os.path.exists(modelfile[:-4] + '.hist.npz'):
            with np.load(modelfile[:-4] + '.hist.npz') as f:
                first_params_hist = list(
                    zip(*(f['param%d' % i] for i in range(len(first_params)))))
    if patience > 0:
        best_error = state.get('best_error', np.inf)
        best_state = state.get('best_state') or get_state(network, updates)
        patience = state.get('patience', patience)
        trials_of_patience = state.get('trials_of_patience',
                                       trials_of_patience)
    epoch = state.get('epoch', 0)
    del state

    # run training loop
    print("Training:")
    for epoch in range(epoch, epochs):
        # actual training
        err = 0
        for batch in progress(range(epochsize),
                              min_delay=.5,
                              desc='Epoch %d/%d: Batch ' %
                              (epoch + 1, epochs)):
            err += train_fn(**next(batches))
            if not np.isfinite(err):
                print("\nEncountered NaN loss in training. Aborting.")
                sys.exit(1)
            if first_params and cfg['first_params_log'] and (
                    batch % cfg['first_params_log'] == 0):
                first_params_hist.append(
                    tuple(param.get_value() for param in first_params))
                np.savez(
                    modelfile[:-4] + '.hist.npz', **{
                        'param%d' % i: param
                        for i, param in enumerate(zip(*first_params_hist))
                    })

        # report training loss
        print("Train loss: %.3f" % (err / epochsize))
        if options.save_errors:
            errors.append(err / epochsize)

        # compute and report validation loss, if requested
        if options.validate:
            import time
            t0 = time.time()
            # predict in mini-batches
            val_err = 0
            val_batches = 0
            preds = []
            truth = []
            for batch in run_val_datafeed():
                e, p = val_fn(**batch)
                val_err += np.sum(e)
                val_batches += 1
                preds.append(p)
                truth.append(batch['label'])
            t1 = time.time()
            # join mini-batches
            preds = np.concatenate(preds) if len(preds) > 1 else preds[0]
            truth = np.concatenate(truth) if len(truth) > 1 else truth[0]
            # show results
            print("Validation loss: %.3f" % (val_err / val_batches))
            from eval import evaluate
            results = evaluate(preds, truth)
            print("Validation error: %.3f" % (1 - results['accuracy']))
            print("Validation MAP: %.3f" % results['map'])
            print("(took %.2f seconds)" % (t1 - t0))
            if options.save_errors:
                errors.append(val_err / val_batches)
                errors.append(1 - results['accuracy'])
                errors.append(results['map'])

        # update learning rate and/or apply early stopping, if needed
        if patience > 0:
            if patience_criterion == 'train_loss':
                cur_error = err / epochsize
            elif patience_criterion == 'valid_loss':
                cur_error = val_err / val_batches
            elif patience_criterion == 'valid_error':
                cur_error = 1 - results['accuracy']
            elif patience_criterion == 'valid_map':
                cur_error = 1 - results['map']
            if cur_error <= best_error:
                best_error = cur_error
                best_state = get_state(network, updates)
                patience = cfg['patience']
            else:
                patience -= 1
                if patience == 0:
                    if eta_decay_every == 'trial_of_patience' and eta_decay != 1:
                        eta.set_value(eta.get_value() *
                                      lasagne.utils.floatX(eta_decay))
                    restore_state(network, updates, best_state)
                    patience = cfg['patience']
                    trials_of_patience -= 1
                    print("Lost patience (%d remaining trials)." %
                          trials_of_patience)
                    if trials_of_patience == 0:
                        break
        if eta_decay_every != 'trial_of_patience' and eta_decay != 1 and \
                (epoch + 1) % eta_decay_every == 0:
            eta.set_value(eta.get_value() * lasagne.utils.floatX(eta_decay))
        if eta_cycle[epoch % len(eta_cycle)] != 1:
            eta.set_value(
                eta.get_value() *
                lasagne.utils.floatX(eta_cycle[epoch % len(eta_cycle)]))

        # store current training state, if needed
        if options.keep_state:
            state = {}
            state['epoch'] = epoch + 1
            state['network'] = get_state(network, updates)
            if options.save_errors:
                state['errors'] = errors
            if patience > 0:
                state['best_error'] = best_error
                state['best_state'] = best_state
                state['patience'] = patience
                state['trials_of_patience'] = trials_of_patience
            with open(statefile, 'wb') as f:
                pickle.dump(state, f, -1)
            del state

        # for debugging: print memory use and break into debugger
        #import resource, psutil
        #print("Memory usage: %.3f MiB / %.3f MiB" %
        #      (resource.getrusage(resource.RUSAGE_SELF).ru_maxrss / 1024.,
        #       psutil.Process().memory_info()[0] / float(1024**2)))
        #import pdb; pdb.set_trace()

    # save final network
    print("Saving final model")
    save_model(modelfile, network, cfg)
    if options.save_errors:
        np.savez(modelfile[:-len('.npz')] + '.err.npz',
                 np.asarray(errors).reshape(epoch + 1, -1))
Example #21
0
        db_query = ''

        for key, value in kwargs.iteritems():
            db_query += "%s='%s' " % (key, value)

        try:
            conn = psycopg2.connect(db_query)
            cursor = conn.cursor()
            print "Opened database successfully"
        except:
            print "I am unable to connect to the database"
        return True

    def db_create():
        cursor.execute('''CREATE TABLE HOSTEL
              (ID INT PRIMARY KEY     NOT NULL,
              NAME            TEXT    NOT NULL,
              PLACES          INT     NOT NULL,
              ADDRESS         CHAR(50),
              PRICE           REAL);''')
        print "Table created successfully"


kwargs = parse_config_file("db_access")
PostgreSQLCRUD.db_connect(**kwargs)
PostgreSQLCRUD.db_create()

# conn.commit()
# conn.close()
Example #22
0
def main():
    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    modelfile = options.modelfile
    outfile = options.outfile
    if options.split_pool and options.saliency:
        parser.error("--split-pool and --saliency cannot be combined.")

    # read configuration files and immediate settings
    cfg = {}
    if os.path.exists(modelfile + '.vars'):
        options.vars.insert(1, modelfile + '.vars')
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))
    cfg.update(config.parse_variable_assignments(options.var))

    # read some settings into local variables
    fps = cfg['fps']
    len_min = cfg['len_min']
    len_max = cfg['len_max']

    # prepare dataset
    print("Preparing data reading...")
    datadir = os.path.join(os.path.dirname(__file__),
                           os.path.pardir, 'datasets', options.dataset)

    # - load filelists
    filelist = []
    for d in options.filelists.split(','):
        with io.open(os.path.join(datadir, 'filelists', d)) as f:
            filelist.extend(l.rstrip() for l in f if l.rstrip())

    # - create data feed
    feed, input_formats = data.prepare_datafeed(filelist, datadir, 'test', cfg)

    # - we start the generator in a background thread
    if not options.plot:
        batches = augment.generate_in_background([data.run_datafeed(feed, cfg)],
                                                 num_cached=1)
    else:
        # unless we're plotting; this would mess up the progress counter
        batches = data.run_datafeed(feed, cfg)

    print("Preparing prediction function...")
    # instantiate neural network
    input_vars = {name: T.TensorType(str(np.dtype(dtype)),
                                     (False,) * len(shape))(name)
                  for name, (dtype, shape) in input_formats.items()}
    input_shapes = {name: shape
                    for name, (dtype, shape) in input_formats.items()}
    network = model.architecture(input_vars, input_shapes, cfg)
    if isinstance(network, list) and not options.include_side_outputs:
        network = network[0]  # only use the main output

    # load saved weights
    with np.load(modelfile, encoding='latin1') as f:
        lasagne.layers.set_all_param_values(
                network, [f['param%d' % i] for i in range(len(f.files))])

    # insert guided backprop, if needed for saliency
    if options.saliency:
        from gbprop import replace_nonlinearities
        replace_nonlinearities(network, lasagne.nonlinearities.leaky_rectify)

    # create output expression(s)
    if options.split_pool:
        network_end = network
        network = next(l for l in lasagne.layers.get_all_layers(network)[::-1]
                       if l.name == 'before_pool')
    outputs = lasagne.layers.get_output(network, deterministic=True)
    if options.split_pool:
        split_input_var = T.tensor4('input2')
        split_outputs = lasagne.layers.get_output(
            network_end, {network: split_input_var}, deterministic=True)
        split_input_vars = [v for v in theano.gof.graph.inputs([split_outputs])
                            if not isinstance(v, theano.compile.SharedVariable)
                            and not isinstance(v, theano.tensor.Constant)]

    # create saliency map expression, if needed
    if options.saliency:
        saliency = theano.grad(outputs[:, options.saliency].sum(), input_vars['spect'])
        outputs = outputs + [saliency] if isinstance(outputs, list) else [outputs, saliency]

    # prepare and compile prediction function
    print("Compiling prediction function...")
    test_fn = theano.function(list(input_vars.values()), outputs,
                              on_unused_input='ignore')
    if options.split_pool:
        pool_fn = theano.function(split_input_vars, split_outputs,
                                  on_unused_input='ignore')

    # prepare plotting, if needed
    if options.plot:
        import matplotlib
        if os.environ.get('MPLBACKEND'):
            matplotlib.use(os.environ['MPLBACKEND'])  # for old versions
        import matplotlib.pyplot as plt
        with open(os.path.join(datadir, 'labels', 'labelset'), 'rb') as f:
            labelset = [l.rstrip('\r\n') for l in f]

    # run prediction loop
    print("Predicting:")
    predictions = []
    for batch in batches:
        spect = batch.pop('spect')
        if spect.shape[-2] <= len_max * fps or len_max == 0:
            # predict on full spectrogram at once
            preds = test_fn(spect=spect, **batch)
        else:
            # predict in segments of len_max, with overlap len_min
            # drop any reminder shorter than len_min (len_max if len_min == 0)
            preds = [test_fn(spect=spect[..., pos:pos + len_max * fps, :],
                     **batch)
                     for pos in range(0, (spect.shape[-2] + 1 -
                                          (len_min or len_max) * fps),
                                      (len_max - len_min) * fps)]
            if isinstance(preds[0], list):
                preds = [np.concatenate(p, axis=2 if p[0].ndim > 2 else 0)
                         for p in zip(*preds)]
            else:
                preds = np.concatenate(preds,
                                       axis=2 if preds[0].ndim > 2 else 0)
        if cfg['arch.pool'] == 'none' or '_nopool' in cfg['arch.pool']:
            if isinstance(preds, list):
                preds = [p[0, :, :, 0].T if p.ndim == 4 else p for p in preds]
            else:
                preds = preds[0, :, :, 0].T
        elif options.split_pool:
            preds = pool_fn(preds, **batch)
        predictions.append(preds)
        if options.plot:
            if spect.ndim == 4:
                spect = spect[0]  # remove batch axis
            if spect.ndim == 3:
                spect = spect[0]  # remove channel axis
            if isinstance(preds, list):
                preds, sides = preds[0], preds[1:]
            else:
                sides = []
            fig, axs = plt.subplots(2 + len(sides), 1, sharex=True)
            axs[0].imshow(np.log1p(1e-3 * spect).T[::-1], cmap='hot',
                          aspect='auto', interpolation='nearest')
            K = 5
            top_k = lme(preds, axis=0).argpartition(preds.shape[1] - 1 -
                                                    np.arange(K))[::-1][:K]
            #top_k = (preds * softmax(sides[0], axis=0).mean(axis=1, keepdims=True)).sum(axis=0).argpartition(preds.shape[1] - 1 - np.arange(K))[::-1][:K]
            #top_k = softmax(preds, axis=-1).max(axis=0).argpartition(preds.shape[1] - 1 - np.arange(K))[::-1][:K]
            #top_k[-1] = labelset.index('mphbjm')
            preds = softmax(preds, axis=-1)
            x = np.arange(len(preds)) * (len(spect) / float(len(preds)))
            for k in top_k:
                axs[1].plot(x, preds[:, k], label=labelset[k])
            #axs[1].set_ylim(0, 1.1)
            axs[1].legend(loc='best')
            for side, ax in zip(sides, axs[2:]):
                side = softmax(side, axis=0)
                ax.plot(x, side)
            plt.show()

    # save predictions
    print("Saving predictions")
    predictions = dict(zip(filelist, predictions))
    if outfile.endswith('.pkl'):
        try:
            import cPickle as pickle
        except ImportError:
            import pickle
        with io.open(outfile, 'wb') as f:
            pickle.dump(predictions, f, protocol=-1)
    else:
        np.savez(outfile, **predictions)
Example #23
0
import time
import pynput
import pynput.keyboard as keyboard
from pynput.keyboard import Key
import pyperclip
import os
import win32clipboard
import shutil

from config import parse_config_file


controller = keyboard.Controller()
capture_keys = True

config = parse_config_file()

# 1. F2 (optional)
# 2. Type what is in clipboard
# 3. Enter (*)
def do_paste_magic():
    capture_keys = False
    controller.release(Key.ctrl_l)
    time.sleep(0.01)
    if config['RENAME_PRESS_F2']:
        press_f2()
        time.sleep(0.01)
    time.sleep(0.01)
    type_string(get_clipboard_text(remove_newline=True) + config['TEXT'])
    if config['RENAME_PRESS_ENTER']:
        time.sleep(0.01)
Example #24
0
def main():
    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    modelfile = options.modelfile
    outfile = options.outfile

    # read configuration files and immediate settings
    cfg = {}
    if os.path.exists(modelfile + '.vars'):
        options.vars.insert(1, modelfile + '.vars')
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))
    cfg.update(config.parse_variable_assignments(options.var))

    # read some settings into local variables
    sample_rate = cfg['sample_rate']
    frame_len = cfg['frame_len']
    fps = cfg['fps']
    mel_bands = cfg['mel_bands']
    mel_min = cfg['mel_min']
    mel_max = cfg['mel_max']
    blocklen = cfg['blocklen']
    batchsize = cfg['batchsize']

    bin_nyquist = frame_len // 2 + 1
    bin_mel_max = bin_nyquist * 2 * mel_max // sample_rate

    # prepare dataset
    print("Preparing data reading...")
    datadir = os.path.join(os.path.dirname(__file__), os.path.pardir,
                           'datasets', options.dataset)

    # - load filelist
    filelist = []
    for d in options.filelists.split(','):
        with io.open(os.path.join(datadir, 'filelists', d)) as f:
            filelist.extend(l.rstrip() for l in f if l.rstrip())

    # - create generator for spectra
    spects = (cached(
        options.cache_spectra
        and os.path.join(options.cache_spectra, fn + '.npy'),
        audio.extract_spect, os.path.join(datadir, 'audio',
                                          fn), sample_rate, frame_len, fps)
              for fn in filelist)

    # - pitch-shift if needed
    if options.pitchshift:
        import scipy.ndimage
        spline_order = 2
        spects = (scipy.ndimage.affine_transform(
            spect, (1, 1 / (1 + options.pitchshift / 100.)),
            output_shape=(len(spect), mel_max),
            order=spline_order) for spect in spects)

    # - define generator for cropped spectra
    spects = (spect[:, :bin_mel_max] for spect in spects)

    # - adjust loudness if needed
    if options.loudness:
        spects = (spect * float(10.**(options.loudness / 10.))
                  for spect in spects)

    # - define generator for silence-padding
    pad = np.zeros((blocklen // 2, bin_mel_max), dtype=floatX)
    spects = (np.concatenate((pad, spect, pad), axis=0) for spect in spects)

    # - we start the generator in a background thread (not required)
    spects = augment.generate_in_background([spects], num_cached=1)

    print("Preparing prediction function...")
    # instantiate neural network
    input_var = T.tensor3('input')
    inputs = input_var.dimshuffle(0, 'x', 1, 2)  # insert "channels" dimension
    network = model.architecture(inputs, (None, 1, blocklen, bin_mel_max), cfg)

    # load saved weights
    with np.load(modelfile) as f:
        lasagne.layers.set_all_param_values(
            network, [f['param%d' % i] for i in range(len(f.files))])

    # performant way: convert to fully-convolutional network
    if not options.mem_use == 'low':
        import model_to_fcn
        network = model_to_fcn.model_to_fcn(network, allow_unlink=True)

    # create output expression
    outputs = lasagne.layers.get_output(network, deterministic=True)

    # prepare and compile prediction function
    print("Compiling prediction function...")
    test_fn = theano.function([input_var], outputs)

    # run prediction loop
    print("Predicting:")
    predictions = []
    for spect in progress(spects, total=len(filelist), desc='File '):
        if options.mem_use == 'high':
            # fastest way: pass full spectrogram through network at once
            preds = test_fn(spect[np.newaxis])  # insert batch dimension
        elif options.mem_use == 'mid':
            # performant way: pass spectrogram in equal chunks of up to one
            # minute, taking care to overlap by `blocklen // 2` frames and to
            # not pass a chunk shorter than `blocklen` frames
            chunks = np.ceil(len(spect) / (fps * 60.))
            hopsize = int(np.ceil(len(spect) / chunks))
            chunksize = hopsize + blocklen - 1
            preds = np.vstack(
                test_fn(spect[np.newaxis, pos:pos + chunksize])
                for pos in range(0, len(spect), hopsize))
        else:
            # naive way: pass excerpts of the size used during training
            # - view spectrogram memory as a 3-tensor of overlapping excerpts
            num_excerpts = len(spect) - blocklen + 1
            excerpts = np.lib.stride_tricks.as_strided(
                spect,
                shape=(num_excerpts, blocklen, spect.shape[1]),
                strides=(spect.strides[0], spect.strides[0], spect.strides[1]))
            # - pass mini-batches through the network and concatenate results
            preds = np.vstack(
                test_fn(excerpts[pos:pos + batchsize])
                for pos in range(0, num_excerpts, batchsize))
        predictions.append(preds)
        if options.plot:
            if spect.ndim == 3:
                spect = spect[0]  # remove channel axis
            spect = spect[blocklen // 2:-blocklen // 2]  # remove zero padding
            import matplotlib.pyplot as plt
            fig, (ax1, ax2) = plt.subplots(2, 1, sharex=True)
            ax1.imshow(spect.T[::-1],
                       vmin=-3,
                       cmap='hot',
                       aspect='auto',
                       interpolation='nearest')
            ax2.plot(preds)
            ax2.set_ylim(0, 1.1)
            plt.show()

    # save predictions
    print("Saving predictions")
    data = dict(zip(filelist, predictions))
    if outfile.endswith('.pkl'):
        try:
            import cPickle as pickle
        except ImportError:
            import pickle
        with io.open(outfile, 'wb') as f:
            pickle.dump(data, f, protocol=-1)
    else:
        np.savez(outfile, **data)
Example #25
0
def main():
    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    outdir = options.outdir
    if options.load_spectra != 'memory' and not options.cache_spectra:
        parser.error('option --load-spectra=%s requires --cache-spectra' %
                     options.load_spectra)

    # read configuration files and immediate settings
    cfg = {}
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))
    cfg.update(config.parse_variable_assignments(options.var))

    # read some settings into local variables
    sample_rate = cfg['sample_rate']
    frame_len = cfg['frame_len']
    fps = cfg['fps']
    mel_bands = cfg['mel_bands']
    mel_min = cfg['mel_min']
    mel_max = cfg['mel_max']

    # prepare dataset
    datadir = os.path.join(os.path.dirname(__file__), os.path.pardir,
                           'datasets', options.dataset)

    # - load filelist
    filelist = []
    ranges = {}
    for part in 'train', 'valid', 'test':
        a = len(filelist)
        with io.open(
                os.path.join(datadir, 'filelists',
                             cfg.get('filelist.%s' % part, part))) as f:
            filelist.extend(l.rstrip() for l in f if l.rstrip())
        ranges[part] = slice(a, len(filelist))

    # - compute spectra
    print("Computing%s spectra..." %
          (" or loading" if options.cache_spectra else ""))
    spects = []
    for fn in progress(filelist, 'File '):
        cache_fn = (options.cache_spectra
                    and os.path.join(options.cache_spectra, fn + '.npy'))
        spects.append(
            cached(cache_fn,
                   audio.extract_spect,
                   os.path.join(datadir, 'audio', fn),
                   sample_rate,
                   frame_len,
                   fps,
                   loading_mode=options.load_spectra))

    # - load and convert corresponding labels
    print("Loading labels...")
    labels = []
    for fn, spect in zip(filelist, spects):
        fn = os.path.join(datadir, 'labels', fn.rsplit('.', 1)[0] + '.lab')
        with io.open(fn) as f:
            segments = [l.rstrip().split() for l in f if l.rstrip()]
        segments = [(float(start), float(end), label == 'sing')
                    for start, end, label in segments]
        timestamps = np.arange(len(spect)) / float(fps)
        labels.append(create_aligned_targets(segments, timestamps, np.bool))

    # compute and save different variants of summarized magnitudes
    print("Saving files...")

    # - ground truth
    outfile = os.path.join(outdir, '%s_gt.pkl' % options.dataset)
    print(outfile)
    with io.open(outfile, 'wb') as f:
        pickle.dump({'labels': labels, 'splits': ranges}, f, protocol=-1)

    # - summarized spectra
    save_spectral_sums(
        os.path.join(outdir, '%s_spect_sum.pkl' % options.dataset), spects)

    # - summarized mel spectra
    bank = audio.create_mel_filterbank(sample_rate, frame_len, mel_bands,
                                       mel_min, mel_max).astype(np.float32)
    spects = [np.dot(spect[:, ], bank) for spect in spects]
    save_spectral_sums(
        os.path.join(outdir, '%s_spect_mel_sum.pkl' % options.dataset), spects)

    # - summarized log-mel spectra
    spects = [np.log(np.maximum(1e-7, spect)) for spect in spects]
    save_spectral_sums(
        os.path.join(outdir, '%s_spect_mel_log_sum.pkl' % options.dataset),
        spects)

    # - summarized standardized log-mel spectra
    m, s = znorm.compute_mean_std(spects[ranges['train']], axis=0)
    spects = [((spect - m) / s).astype(np.float32) for spect in spects]
    save_spectral_sums(
        os.path.join(outdir, '%s_spect_mel_log_std_sum.pkl' % options.dataset),
        spects)
Example #26
0
def main():
    device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')

    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    modelfile = options.modelfile

    cfg = {}
    print(options.vars)
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))

    cfg.update(config.parse_variable_assignments(options.var))

    sample_rate = cfg['sample_rate']
    frame_len = cfg['frame_len']
    fps = cfg['fps']
    mel_bands = cfg['mel_bands']
    mel_min = cfg['mel_min']
    mel_max = cfg['mel_max']
    blocklen = cfg['blocklen']
    batchsize = cfg['batchsize']

    bin_nyquist = frame_len // 2 + 1
    bin_mel_max = bin_nyquist * 2 * mel_max // sample_rate

    # prepare dataset
    datadir = os.path.join(os.path.dirname(__file__), os.path.pardir,
                           'datasets', options.dataset)

    meanstd_file = os.path.join(os.path.dirname(__file__),
                                '%s_meanstd.npz' % options.dataset)

    if (options.input_type == 'audio'):
        dataloader = DatasetLoader(options.dataset,
                                   options.cache_spectra,
                                   datadir,
                                   input_type=options.input_type)
        batches = dataloader.prepare_audio_batches(sample_rate, frame_len, fps,
                                                   blocklen, batchsize)
    else:
        dataloader = DatasetLoader(options.dataset,
                                   options.cache_spectra,
                                   datadir,
                                   input_type=options.input_type)
        batches = dataloader.prepare_batches(sample_rate, frame_len, fps,
                                             mel_bands, mel_min, mel_max,
                                             blocklen, batchsize)

    validation_data = DatasetLoader(options.dataset,
                                    '../ismir2015/experiments/mel_data/',
                                    datadir,
                                    dataset_split='valid',
                                    input_type='mel_spects')
    mel_spects_val, labels_val = validation_data.prepare_batches(
        sample_rate,
        frame_len,
        fps,
        mel_bands,
        mel_min,
        mel_max,
        blocklen,
        batchsize,
        batch_data=False)

    mdl = model.CNNModel(model_type=options.model_type,
                         input_type=options.input_type,
                         is_zeromean=False,
                         sample_rate=sample_rate,
                         frame_len=frame_len,
                         fps=fps,
                         mel_bands=mel_bands,
                         mel_min=mel_min,
                         mel_max=mel_max,
                         bin_mel_max=bin_mel_max,
                         meanstd_file=meanstd_file,
                         device=device)
    mdl = mdl.to(device)

    #Setting up learning rate and learning rate parameters
    initial_eta = cfg['initial_eta']
    eta_decay = cfg['eta_decay']
    momentum = cfg['momentum']
    eta_decay_every = cfg.get('eta_decay_every', 1)
    eta = initial_eta

    #set up loss
    criterion = torch.nn.BCELoss()

    #set up optimizer
    optimizer = torch.optim.SGD(mdl.parameters(),
                                lr=eta,
                                momentum=momentum,
                                nesterov=True)
    scheduler = torch.optim.lr_scheduler.StepLR(optimizer,
                                                step_size=eta_decay_every,
                                                gamma=eta_decay)

    #set up optimizer
    writer = SummaryWriter(os.path.join(modelfile, 'runs'))

    epochs = cfg['epochs']
    epochsize = cfg['epochsize']
    batches = iter(batches)

    #conditions to save model
    best_val_loss = 100000.
    best_val_error = 1.

    for epoch in range(epochs):
        # - Initialize certain parameters that are used to monitor training
        err = 0
        total_norm = 0
        loss_accum = 0
        mdl.train(True)
        # - Compute the L-2 norm of the gradients
        for p in mdl.parameters():
            if p.grad is not None:
                param_norm = p.grad.data.norm(2)
                total_norm += param_norm.item()**2
        total_norm = total_norm**(1. / 2)

        # - Start the training for this epoch
        for batch in progress(range(epochsize),
                              min_delay=0.5,
                              desc='Epoch %d/%d: Batch ' %
                              (epoch + 1, epochs)):
            data = next(batches)
            if (options.input_type == 'audio' or options.input_type == 'stft'):
                input_data = data[0]
            else:
                input_data = np.transpose(data[0][:, :, :, np.newaxis],
                                          (0, 3, 1, 2))
            labels = data[1][:, np.newaxis].astype(np.float32)

            #map labels to make them softer
            if not options.adversarial_training:
                labels = (0.02 + 0.96 * labels)
            optimizer.zero_grad()

            if (options.adversarial_training):
                mdl.train(False)
                if (options.input_type == 'stft'):
                    input_data_adv = attacks.PGD(
                        mdl,
                        torch.from_numpy(input_data).to(device),
                        target=torch.from_numpy(labels).to(device),
                        eps=cfg['eps'],
                        step_size=cfg['eps_iter'],
                        iterations=cfg['nb_iter'],
                        use_best=True,
                        random_start=True,
                        clip_min=0,
                        clip_max=1e8).cpu().detach().numpy()
                else:
                    input_data_adv = attacks.PGD(
                        mdl,
                        torch.from_numpy(input_data).to(device),
                        target=torch.from_numpy(labels).to(device),
                        eps=cfg['eps'],
                        step_size=cfg['eps_iter'],
                        iterations=cfg['nb_iter'],
                        use_best=True,
                        random_start=True).cpu().detach().numpy()

                mdl.train(True)
                optimizer.zero_grad()
                outputs = mdl(torch.from_numpy(input_data_adv).to(device))
            else:
                optimizer.zero_grad()
                outputs = mdl(torch.from_numpy(input_data).to(device))
            #input(outputs.size())
            #input(mdl.conv(torch.from_numpy(input_data).to(device)).cpu().detach().numpy().shape)
            loss = criterion(outputs, torch.from_numpy(labels).to(device))
            loss.backward()
            optimizer.step()
            print(loss.item())
            loss_accum += loss.item()

        # - Compute validation loss and error if desired
        if options.validate:
            mdl.input_type = 'mel_spects'
            from eval import evaluate
            mdl.train(False)
            val_loss = 0
            preds = []
            labs = []
            max_len = fps

            num_iter = 0

            for spect, label in zip(mel_spects_val, labels_val):
                num_excerpts = len(spect) - blocklen + 1
                excerpts = np.lib.stride_tricks.as_strided(
                    spect,
                    shape=(num_excerpts, blocklen, spect.shape[1]),
                    strides=(spect.strides[0], spect.strides[0],
                             spect.strides[1]))
                # - Pass mini-batches through the network and concatenate results
                for pos in range(0, num_excerpts, batchsize):
                    input_data = np.transpose(
                        excerpts[pos:pos + batchsize, :, :, np.newaxis],
                        (0, 3, 1, 2))
                    #if (pos+batchsize>num_excerpts):
                    #    label_batch = label[blocklen//2+pos:blocklen//2+num_excerpts,
                    #            np.newaxis].astype(np.float32)
                    #else:
                    #    label_batch = label[blocklen//2+pos:blocklen//2+pos+batchsize,
                    #            np.newaxis].astype(np.float32)
                    if (pos + batchsize > num_excerpts):
                        label_batch = label[pos:num_excerpts,
                                            np.newaxis].astype(np.float32)
                    else:
                        label_batch = label[pos:pos + batchsize,
                                            np.newaxis].astype(np.float32)

                    pred = mdl(torch.from_numpy(input_data).to(device))
                    e = criterion(pred,
                                  torch.from_numpy(label_batch).to(device))
                    preds = np.append(preds, pred[:, 0].cpu().detach().numpy())
                    labs = np.append(labs, label_batch)
                    val_loss += e.item()
                    num_iter += 1
            mdl.input_type = options.input_type
            print("Validation loss: %.3f" % (val_loss / num_iter))
            _, results = evaluate(preds, labs)
            print("Validation error: %.3f" % (1 - results['accuracy']))

            if (1 - results['accuracy'] < best_val_error):
                torch.save(mdl.state_dict(),
                           os.path.join(modelfile, 'model.pth'))
                best_val_loss = val_loss / num_iter
                best_val_error = 1 - results['accuracy']
                print('New saved model', best_val_loss, best_val_error)

        #Update the learning rate
        scheduler.step()

        print('Training Loss per epoch', loss_accum / epochsize)

        # - Save parameters for examining
        writer.add_scalar('Training Loss', loss_accum / epochsize, epoch)
        writer.add_scalar('Validation loss', val_loss / num_iter, epoch)
        writer.add_scalar('Gradient norm', total_norm, epoch)
        writer.add_scalar('Validation error', 1 - results['accuracy'])
        #for param_group in optimizer.param_groups:
        #print(param_group['lr'])

    if not options.validate:
        torch.save(mdl.state_dict(), os.path.join(modelfile, 'model.pth'))
    with io.open(os.path.join(modelfile, 'model.vars'), 'w') as f:
        f.writelines('%s=%s\n' % kv for kv in cfg.items())
def main():
    device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')

    # parse command line
    parser = opts_parser()
    options = parser.parse_args()
    modelfile = options.modelfile
    lossgradient = options.lossgradient
    cfg = {}
    print(options.vars)
    print('Model save file:', modelfile)
    print('Lossgrad file:', lossgradient)
    for fn in options.vars:
        cfg.update(config.parse_config_file(fn))

    cfg.update(config.parse_variable_assignments(options.var))
    
    sample_rate = cfg['sample_rate']
    frame_len = cfg['frame_len']
    fps = cfg['fps']
    mel_bands = cfg['mel_bands']
    mel_min = cfg['mel_min']
    mel_max = cfg['mel_max']
    blocklen = cfg['blocklen']
    batchsize = cfg['batchsize']
    print('Occluded amount:',cfg['occlude'])
    bin_nyquist = frame_len // 2 + 1
    bin_mel_max = bin_nyquist * 2 * mel_max // sample_rate

    # prepare dataset
    datadir = os.path.join(os.path.dirname(__file__),
                           os.path.pardir, 'datasets', options.dataset)
    
    meanstd_file = os.path.join(os.path.dirname(__file__),
                                '%s_meanstd.npz' % options.dataset)
 
    dataloader = DatasetLoader(options.dataset, options.cache_spectra, datadir, input_type=options.input_type)
    batches = dataloader.prepare_batches(sample_rate, frame_len, fps,
            mel_bands, mel_min, mel_max, blocklen, batchsize)
    
    validation_data = DatasetLoader(options.dataset, '../ismir2015/experiments/mel_data/', datadir,
            dataset_split='valid', input_type='mel_spects')
    mel_spects_val, labels_val = validation_data.prepare_batches(sample_rate, frame_len, fps,
            mel_bands, mel_min, mel_max, blocklen, batchsize, batch_data=False)

    with np.load(meanstd_file) as f:
        mean = f['mean']
        std = f['std']
    mean = mean.astype(floatX)
    istd = np.reciprocal(std).astype(floatX)
    if(options.input_type=='mel_spects'):
        mdl = model.CNNModel(input_type='mel_spects_norm', is_zeromean=False,
            sample_rate=sample_rate, frame_len=frame_len, fps=fps,
            mel_bands=mel_bands, mel_min=mel_min, mel_max=mel_max,
            bin_mel_max=bin_mel_max, meanstd_file=meanstd_file, device=device)
        if(lossgradient!='None'):
            mdl_lossgrad =  model.CNNModel(input_type=options.input_type,
                is_zeromean=False, sample_rate=sample_rate, frame_len=frame_len, fps=fps,
                mel_bands=mel_bands, mel_min=mel_min, mel_max=mel_max,
                bin_mel_max=bin_mel_max, meanstd_file=meanstd_file, device=device)
            mdl_lossgrad.load_state_dict(torch.load(lossgradient))
            mdl_lossgrad.to(device)
            mdl_lossgrad.eval()
 
    mdl = mdl.to(device)
    
    #Setting up learning rate and learning rate parameters
    initial_eta = cfg['initial_eta']
    eta_decay = cfg['eta_decay']
    momentum = cfg['momentum']
    eta_decay_every = cfg.get('eta_decay_every', 1)
    eta = initial_eta

    #set up loss
    criterion = torch.nn.BCELoss()

    #set up optimizer
    optimizer = torch.optim.SGD(mdl.parameters(),lr=eta,momentum=momentum,nesterov=True)
    #optimizer = torch.optim.Adam(mdl.parameters(), lr=eta, betas=(0.9, 0.999), eps=1e-08, weight_decay=0, amsgrad=False)
    scheduler = torch.optim.lr_scheduler.StepLR(optimizer,step_size=eta_decay_every,gamma=eta_decay)

    #set up optimizer 
    writer = SummaryWriter(os.path.join(modelfile,'runs'))

    
    epochs = cfg['epochs']
    epochsize = cfg['epochsize']
    batches = iter(batches)
    
    #conditions to save model
    best_val_loss = 100000.
    best_val_error = 1.
    
    #loss gradient values for validation data
    loss_grad_val = validation_data.prepare_loss_grad_batches(options.loss_grad_save,
            mel_spects_val, labels_val, mdl_lossgrad, criterion, blocklen, batchsize, device)
    for epoch in range(epochs):
        # - Initialize certain parameters that are used to monitor training
        err = 0
        total_norm = 0
        loss_accum = 0
        mdl.train(True)
        # - Compute the L-2 norm of the gradients
        for p in mdl.parameters():
            if p.grad is not None:
                param_norm = p.grad.data.norm(2)
                total_norm += param_norm.item() ** 2
        total_norm = total_norm ** (1. / 2)
        
        # - Start the training for this epoch
        for batch in progress(range(epochsize), min_delay=0.5,desc='Epoch %d/%d: Batch ' % (epoch+1, epochs)):
            data = next(batches)
            if(options.input_type=='audio' or options.input_type=='stft'):
                input_data = data[0]
            else:
                input_data = np.transpose(data[0][:,:,:,np.newaxis],(0,3,1,2))
            labels = data[1][:,np.newaxis].astype(np.float32)
            input_data_loss = input_data
            
            if lossgradient!='None':
                g = loss_grad(mdl_lossgrad, torch.from_numpy(input_data_loss).to(device).requires_grad_(True), torch.from_numpy(labels).to(device), criterion)
                g = np.squeeze(g)
                input_data = (input_data-mean) * istd
                for i in range(batchsize):
                    if(options.lossgrad_algorithm=='grad'):
                        rank_matrix = np.abs(g[i])
                    elif(options.lossgrad_algorithm=='gradxinp'):
                        rank_matrix = np.squeeze(g[i]*input_data[i,:,:,:])
                    elif(options.lossgrad_algorithm=='gradorig'):
                        rank_matrix = g[i]
                    v = np.argsort(rank_matrix, axis=None)[-cfg['occlude']:]
                    input_data[i,:,v//80,v%80] = 0
 
            else:
                for i in range(batchsize):
                    #print('random')
                    v = np.random.choice(115*80, cfg['occlude'], replace=False)
                    input_data[i,:,v//80,v%80] = 0
          
            input_data = input_data.astype(floatX)

            labels = (0.02 + 0.96*labels)
            
            optimizer.zero_grad()
            outputs = mdl(torch.from_numpy(input_data).to(device))
        
            loss = criterion(outputs, torch.from_numpy(labels).to(device))
            loss.backward()
            optimizer.step()
            #print(loss.item())
            loss_accum += loss.item()
   
        # - Compute validation loss and error if desired
        if options.validate:
            #mdl.model_type = 'mel_spects'
            from eval import evaluate
            mdl.train(False) 
            val_loss = 0
            preds = []
            labs = []
            max_len = fps
            
            num_iter = 0 

            for spect, label, g in zip(mel_spects_val, labels_val, loss_grad_val):
                num_excerpts = len(spect) - blocklen + 1
                excerpts = np.lib.stride_tricks.as_strided(
                    spect, shape=(num_excerpts, blocklen, spect.shape[1]),
                    strides=(spect.strides[0], spect.strides[0], spect.strides[1]))
                
                # - Pass mini-batches through the network and concatenate results
                for pos in range(0, num_excerpts, batchsize):
                    input_data = np.transpose(excerpts[pos:pos + batchsize,:,:,np.newaxis],(0,3,1,2))
                    #if (pos+batchsize>num_excerpts):
                    #    label_batch = label[blocklen//2+pos:blocklen//2+num_excerpts,
                    #            np.newaxis].astype(np.float32)
                    #else:
                    #    label_batch = label[blocklen//2+pos:blocklen//2+pos+batchsize,
                    #            np.newaxis].astype(np.float32)
                    if (pos+batchsize>num_excerpts):
                        label_batch = label[pos:num_excerpts,
                               np.newaxis].astype(np.float32)
                    else:
                        label_batch = label[pos:pos+batchsize,
                                np.newaxis].astype(np.float32)
                    
                    #input_data_loss = input_data  
                    if lossgradient!='None':
                        #grads = loss_grad(mdl_lossgrad, torch.from_numpy(input_data_loss).to(device).requires_grad_(True), torch.from_numpy(label_batch).to(device), criterion)
                        input_data = (input_data-mean) * istd
                        for i in range(input_data.shape[0]):
                            if(options.lossgrad_algorithm=='grad'):
                                rank_matrix = np.abs(g[i])
                            elif(options.lossgrad_algorithm=='gradxinp'):
                                rank_matrix = np.squeeze(g[i]*input_data[i,:,:,:])
                            elif(options.lossgrad_algorithm=='gradorig'):
                                rank_matrix = g[i]
                
                            v = np.argsort(np.abs(rank_matrix), axis=None)[-cfg['occlude']:]
                            input_data[i,:,v//80,v%80] = 0
                    else:
                        for i in range(input_data.shape[0]):
                            #print('random')
                            v = np.random.choice(115*80, cfg['occlude'], replace=False)
                            input_data[i,:,v//80,v%80] = 0
          
                    input_data = input_data.astype(floatX)
          
                    pred = mdl(torch.from_numpy(input_data).to(device))
                    e = criterion(pred,torch.from_numpy(label_batch).to(device))
                    preds = np.append(preds,pred[:,0].cpu().detach().numpy())
                    labs = np.append(labs,label_batch)
                    val_loss +=e.item()
                    num_iter+=1
            #mdl.model_type = 'mel_spects_norm'
            print("Validation loss: %.3f" % (val_loss / num_iter))
            _, results = evaluate(preds,labs)
            print("Validation error: %.3f" % (1 - results['accuracy']))
            
            if(1-results['accuracy']<best_val_error):
                torch.save(mdl.state_dict(), os.path.join(modelfile, 'model.pth'))
                best_val_loss = val_loss/num_iter
                best_val_error = 1-results['accuracy']
                print('New saved model',best_val_loss, best_val_error)
                    
        #Update the learning rate
        scheduler.step()
        
        print('Training Loss per epoch', loss_accum/epochsize) 
        
        # - Save parameters for examining
        writer.add_scalar('Training Loss',loss_accum/epochsize,epoch)
        if(options.validate):
            writer.add_scalar('Validation loss', val_loss/num_iter,epoch)
            writer.add_scalar('Gradient norm', total_norm, epoch)
            writer.add_scalar('Validation error', 1-results['accuracy'])
        #for param_group in optimizer.param_groups:
            #print(param_group['lr'])
    
    if not options.validate:
        torch.save(mdl.state_dict(), os.path.join(modelfile, 'model.pth'))
    with io.open(os.path.join(modelfile, 'model.vars'), 'w') as f:
        f.writelines('%s=%s\n' % kv for kv in cfg.items())