Exemplo n.º 1
0
 def test_resize_sequence_with_permutation(self):
     sub_sequence, seq_lengths, _ = utils.resize_sequence(
         sequence=np.array([[1, 1], [2, 2], [3, 3]]),
         cluster_id=np.array([1, 2, 1]),
         num_permutations=None)
     self.assertEqual(len(sub_sequence), 2)
     self.assertTrue((sub_sequence[0] == [[1, 1], [3, 3]]).all())
     self.assertTrue((sub_sequence[1] == [[2, 2]]).all())
     self.assertListEqual(seq_lengths, [3, 2])
Exemplo n.º 2
0
    def fit(self, train_sequence, train_cluster_id, args):
        """Fit UISRNN model.

    Args:
      train_sequence: 2-dim numpy array of real numbers, size: N * D
        - the training observation sequence.
        N - summation of lengths of all utterances
        D - observation dimension
        For example, train_sequence =
        [[1.2 3.0 -4.1 6.0]    --> an entry of speaker #0 from utterance 'iaaa'
         [0.8 -1.1 0.4 0.5]    --> an entry of speaker #1 from utterance 'iaaa'
         [-0.2 1.0 3.8 5.7]    --> an entry of speaker #0 from utterance 'iaaa'
         [3.8 -0.1 1.5 2.3]    --> an entry of speaker #0 from utterance 'ibbb'
         [1.2 1.4 3.6 -2.7]]   --> an entry of speaker #0 from utterance 'ibbb'
        Here N=5, D=4.
        We concatenate all training utterances into a single sequence.
      train_cluster_id: 1-dim list or numpy array of strings, size: N
        - the speaker id sequence.
        For example, train_cluster_id =
        ['iaaa_0', 'iaaa_1', 'iaaa_0', 'ibbb_0', 'ibbb_0']
        'iaaa_0' means the entry belongs to speaker #0 in utterance 'iaaa'.
        Note that the order of entries within an utterance are preserved,
        and all utterances are simply concatenated together.
      args: Training configurations. See arguments.py for details.

    Raises:
      TypeError: If train_sequence or train_cluster_id is of wrong type.
      ValueError: If train_sequence or train_cluster_id has wrong dimension.
    """
        # check type
        if (not isinstance(train_sequence, np.ndarray)
                or train_sequence.dtype != float):
            raise TypeError(
                'train_sequence should be a numpy array of float type.')
        if isinstance(train_cluster_id, list):
            train_cluster_id = np.array(train_cluster_id)
        if (not isinstance(train_cluster_id, np.ndarray)
                or not train_cluster_id.dtype.name.startswith('str')):
            raise TypeError(
                'train_cluster_id type be a numpy array of strings.')
        # check dimension
        if train_sequence.ndim != 2:
            raise ValueError('train_sequence must be 2-dim array.')
        if train_cluster_id.ndim != 1:
            raise ValueError('train_cluster_id must be 1-dim array.')
        # check length and size
        train_total_length, observation_dim = train_sequence.shape
        if observation_dim != self.observation_dim:
            raise ValueError(
                'train_sequence does not match the dimension specified '
                'by args.observation_dim.')
        if train_total_length != len(train_cluster_id):
            raise ValueError('train_sequence length is not equal to '
                             'train_cluster_id length.')

        self.rnn_model.train()
        optimizer = self._get_optimizer(optimizer=args.optimizer,
                                        learning_rate=args.learning_rate)

        sub_sequences, seq_lengths, transition_bias = utils.resize_sequence(
            sequence=train_sequence,
            cluster_id=train_cluster_id,
            num_permutations=args.num_permutations)
        if self.transition_bias is None:
            self.transition_bias = transition_bias
        # For batch learning, pack the entire dataset.
        if args.batch_size is None:
            packed_train_sequence, rnn_truth = utils.pack_sequence(
                sub_sequences, seq_lengths, args.batch_size,
                self.observation_dim, self.device)
        train_loss = []
        for t in range(args.train_iteration):
            # Update learning rate if half life is specified.
            if args.learning_rate_half_life > 0:
                if t > 0 and t % args.learning_rate_half_life == 0:
                    optimizer.param_groups[0]['lr'] /= 2.0
                    print('Changing learning rate to: {}'.format(
                        optimizer.param_groups[0]['lr']))
            optimizer.zero_grad()
            # For online learning, pack a subset in each iteration.
            if args.batch_size is not None:
                packed_train_sequence, rnn_truth = utils.pack_sequence(
                    sub_sequences, seq_lengths, args.batch_size,
                    self.observation_dim, self.device)
            hidden = self.rnn_init_hidden.repeat(1, args.batch_size, 1)
            mean, _ = self.rnn_model(packed_train_sequence, hidden)
            # use mean to predict
            mean = torch.cumsum(mean, dim=0)
            mean_size = mean.size()
            mean = torch.mm(
                torch.diag(
                    1.0 /
                    torch.arange(1, mean_size[0] + 1).float().to(self.device)),
                mean.view(mean_size[0], -1))
            mean = mean.view(mean_size)

            # Likelihood part.
            loss1 = utils.weighted_mse_loss(
                input_tensor=(rnn_truth != 0).float() * mean[:-1, :, :],
                target_tensor=rnn_truth,
                weight=1 / (2 * self.sigma2))

            weight = (((rnn_truth != 0).float() * mean[:-1, :, :] -
                       rnn_truth)**2).view(-1, observation_dim)
            num_non_zero = torch.sum((weight != 0).float(), dim=0).squeeze()
            loss2 = ((2 * args.sigma_alpha + num_non_zero + 2) /
                     (2 * num_non_zero) * torch.log(self.sigma2)).sum() + (
                         args.sigma_beta / (self.sigma2 * num_non_zero)).sum()
            # regularization
            l2_reg = 0
            for param in self.rnn_model.parameters():
                l2_reg += torch.norm(param)
            loss3 = args.regularization_weight * l2_reg

            loss = loss1 + loss2 + loss3
            loss.backward()
            nn.utils.clip_grad_norm_(self.rnn_model.parameters(), 5.0)
            # nn.utils.clip_grad_norm_(self.sigma2, 1.0)
            optimizer.step()
            # avoid numerical issues
            self.sigma2.data.clamp_(min=1e-6)

            if np.remainder(t, 10) == 0:
                print('Iter: {:d}  \t'
                      'Training Loss: {:.4f}    \n'
                      '    Negative Log Likelihood: {:.4f}\t'
                      'Sigma2 Prior: {:.4f}\t'
                      'Regularization: {:.4f}'.format(t, float(loss.data),
                                                      float(loss1.data),
                                                      float(loss2.data),
                                                      float(loss3.data)))
            train_loss.append(float(
                loss1.data))  # only save the likelihood part
        print('Done training with {} iterations'.format(args.train_iteration))
Exemplo n.º 3
0
    def fit(self, train_sequence, train_cluster_id, args):
        """Fit UISRNN model.

    Args:
      train_sequence: (real 2d numpy array, size: N by D)
        - the training d_vector sequence.
        N - summation of lengths of all utterances
        D - observation dimension
        For example, train_sequence =
        [[1.2 3.0 -4.1 6.0]    --> an entry of speaker #0 from utterance 'iaaa'
         [0.8 -1.1 0.4 0.5]    --> an entry of speaker #1 from utterance 'iaaa'
         [-0.2 1.0 3.8 5.7]    --> an entry of speaker #0 from utterance 'iaaa'
         [3.8 -0.1 1.5 2.3]    --> an entry of speaker #0 from utterance 'ibbb'
         [1.2 1.4 3.6 -2.7]]   --> an entry of speaker #0 from utterance 'ibbb'
        Here N=5, d=4.
        We concatenate all training utterances into a single sequence.
      train_cluster_id: (a vector of strings, size: N)
        - the speaker id sequence.
        For example, train_cluster_id =
        ['iaaa_0', 'iaaa_1', 'iaaa_0', 'ibbb_0', 'ibbb_0']
        'iaaa_0' means the entry belongs to speaker #0 in utterance 'iaaa'.
        Note that the order of entries within an utterance are preserved,
        and all utterances are simply concatenated together.
      args: Training configurations. See arguments.py for details.

    Raises:
      ValueError: If train_sequence has wrong dimension.
    """

        train_total_length, observation_dim = train_sequence.shape
        if observation_dim != self.observation_dim:
            raise ValueError(
                'train_sequence does not match the dimension specified '
                'by args.observation_dim.')
        if train_total_length != len(train_cluster_id):
            raise ValueError('train_sequence length is not equal to '
                             'train_cluster_id length.')
        if type(train_sequence).__module__ != np.__name__:
            raise TypeError('train_sequence type should be an numpy array.')
        if type(train_cluster_id).__module__ != np.__name__:
            raise TypeError('train_cluster_id type should be an numpy array.')

        self.rnn_model.train()
        optimizer = self._get_optimizer(optimizer=args.optimizer,
                                        learning_rate=args.learning_rate)

        sub_sequences, seq_lengths, transition_bias = utils.resize_sequence(
            sequence=train_sequence,
            cluster_id=train_cluster_id,
            num_permutations=args.num_permutations)
        num_clusters = len(seq_lengths)
        sorted_seq_lengths = np.sort(seq_lengths)[::-1]
        permute_index = np.argsort(seq_lengths)[::-1]
        if self.transition_bias is None:
            self.transition_bias = transition_bias
        if args.batch_size is None:
            # Packing sequences.
            rnn_input = np.zeros(
                (sorted_seq_lengths[0], num_clusters, self.observation_dim))
            for i in range(num_clusters):
                rnn_input[1:sorted_seq_lengths[i],
                          i, :] = sub_sequences[permute_index[i]]
            rnn_input = autograd.Variable(
                torch.from_numpy(rnn_input).float()).to(self.device)
            packed_train_sequence, rnn_truth = utils.pack_seq(
                rnn_input, sorted_seq_lengths)

        train_loss = []
        for t in range(args.train_iteration):
            optimizer.zero_grad()
            if args.batch_size is not None:
                mini_batch = np.sort(
                    np.random.choice(num_clusters, args.batch_size))
                mini_batch_rnn_input = np.zeros(
                    (sorted_seq_lengths[mini_batch[0]], args.batch_size,
                     self.observation_dim))
                for i in range(args.batch_size):
                    mini_batch_rnn_input[1:sorted_seq_lengths[mini_batch[i]],
                                         i, :] = sub_sequences[permute_index[
                                             mini_batch[i]]]
                mini_batch_rnn_input = autograd.Variable(
                    torch.from_numpy(mini_batch_rnn_input).float()).to(
                        self.device)
                packed_train_sequence, rnn_truth = utils.pack_seq(
                    mini_batch_rnn_input, sorted_seq_lengths[mini_batch])

            hidden = self.rnn_init_hidden.repeat(1, args.batch_size, 1)
            mean, _ = self.rnn_model(packed_train_sequence, hidden)
            # use mean to predict
            mean = torch.cumsum(mean, dim=0)
            mean_size = mean.size()
            mean = torch.mm(
                torch.diag(
                    1.0 /
                    torch.arange(1, mean_size[0] + 1).float().to(self.device)),
                mean.view(mean_size[0], -1))
            mean = mean.view(mean_size)

            # Likelihood part.
            loss1 = utils.weighted_mse_loss(
                input_tensor=(rnn_truth != 0).float() * mean[:-1, :, :],
                target_tensor=rnn_truth,
                weight=1 / (2 * self.sigma2))

            weight = (((rnn_truth != 0).float() * mean[:-1, :, :] -
                       rnn_truth)**2).view(-1, observation_dim)
            num_non_zero = torch.sum((weight != 0).float(), dim=0).squeeze()
            loss2 = ((2 * args.sigma_alpha + num_non_zero + 2) /
                     (2 * num_non_zero) * torch.log(self.sigma2)).sum() + (
                         args.sigma_beta / (self.sigma2 * num_non_zero)).sum()
            # regularization
            l2_reg = 0
            for param in self.rnn_model.parameters():
                l2_reg += torch.norm(param)
            loss3 = args.regularization_weight * l2_reg

            loss = loss1 + loss2 + loss3
            loss.backward()
            nn.utils.clip_grad_norm_(self.rnn_model.parameters(), 5.0)
            # nn.utils.clip_grad_norm_(self.sigma2, 1.0)
            optimizer.step()
            # avoid numerical issues
            self.sigma2.data.clamp_(min=1e-6)

            if np.remainder(t, 10) == 0:
                print('Iter: {:d}  \t'
                      'Training Loss: {:.4f}    \n'
                      '    Negative Log Likelihood: {:.4f}\t'
                      'Sigma2 Prior: {:.4f}\t'
                      'Regularization: {:.4f}'.format(t, float(loss.data),
                                                      float(loss1.data),
                                                      float(loss2.data),
                                                      float(loss3.data)))
            train_loss.append(float(
                loss1.data))  # only save the likelihood part
        print('Done training with {} iterations'.format(args.train_iteration))