Shortcuts

CTCLoss

class torch.nn.CTCLoss(blank=0, reduction='mean', zero_infinity=False)[source]

The Connectionist Temporal Classification loss.

Calculates loss between a continuous (unsegmented) time series and a target sequence. CTCLoss sums over the probability of possible alignments of input to target, producing a loss value which is differentiable with respect to each input node. The alignment of input to target is assumed to be “many-to-one”, which limits the length of the target sequence such that it must be \leq the input length.

Parameters
  • blank (int, optional) – blank label. Default 00.

  • reduction (string, optional) – Specifies the reduction to apply to the output: 'none' | 'mean' | 'sum'. 'none': no reduction will be applied, 'mean': the output losses will be divided by the target lengths and then the mean over the batch is taken. Default: 'mean'

  • zero_infinity (bool, optional) – Whether to zero infinite losses and the associated gradients. Default: False Infinite losses mainly occur when the inputs are too short to be aligned to the targets.

Shape:
  • Log_probs: Tensor of size (T,N,C)(T, N, C), where T=input lengthT = \text{input length}, N=batch sizeN = \text{batch size}, and C=number of classes (including blank)C = \text{number of classes (including blank)}. The logarithmized probabilities of the outputs (e.g. obtained with torch.nn.functional.log_softmax()).

  • Targets: Tensor of size (N,S)(N, S) or (sum(target_lengths))(\operatorname{sum}(\text{target\_lengths})), where N=batch sizeN = \text{batch size} and S=max target length, if shape is (N,S)S = \text{max target length, if shape is } (N, S). It represent the target sequences. Each element in the target sequence is a class index. And the target index cannot be blank (default=0). In the (N,S)(N, S) form, targets are padded to the length of the longest sequence, and stacked. In the (sum(target_lengths))(\operatorname{sum}(\text{target\_lengths})) form, the targets are assumed to be un-padded and concatenated within 1 dimension.

  • Input_lengths: Tuple or tensor of size (N)(N), where N=batch sizeN = \text{batch size}. It represent the lengths of the inputs (must each be T\leq T). And the lengths are specified for each sequence to achieve masking under the assumption that sequences are padded to equal lengths.

  • Target_lengths: Tuple or tensor of size (N)(N), where N=batch sizeN = \text{batch size}. It represent lengths of the targets. Lengths are specified for each sequence to achieve masking under the assumption that sequences are padded to equal lengths. If target shape is (N,S)(N,S), target_lengths are effectively the stop index sns_n for each target sequence, such that target_n = targets[n,0:s_n] for each target in a batch. Lengths must each be S\leq S If the targets are given as a 1d tensor that is the concatenation of individual targets, the target_lengths must add up to the total length of the tensor.

  • Output: scalar. If reduction is 'none', then (N)(N), where N=batch sizeN = \text{batch size}.

Examples:

>>> # Target are to be padded
>>> T = 50      # Input sequence length
>>> C = 20      # Number of classes (including blank)
>>> N = 16      # Batch size
>>> S = 30      # Target sequence length of longest target in batch (padding length)
>>> S_min = 10  # Minimum target length, for demonstration purposes
>>>
>>> # Initialize random batch of input vectors, for *size = (T,N,C)
>>> input = torch.randn(T, N, C).log_softmax(2).detach().requires_grad_()
>>>
>>> # Initialize random batch of targets (0 = blank, 1:C = classes)
>>> target = torch.randint(low=1, high=C, size=(N, S), dtype=torch.long)
>>>
>>> input_lengths = torch.full(size=(N,), fill_value=T, dtype=torch.long)
>>> target_lengths = torch.randint(low=S_min, high=S, size=(N,), dtype=torch.long)
>>> ctc_loss = nn.CTCLoss()
>>> loss = ctc_loss(input, target, input_lengths, target_lengths)
>>> loss.backward()
>>>
>>>
>>> # Target are to be un-padded
>>> T = 50      # Input sequence length
>>> C = 20      # Number of classes (including blank)
>>> N = 16      # Batch size
>>>
>>> # Initialize random batch of input vectors, for *size = (T,N,C)
>>> input = torch.randn(T, N, C).log_softmax(2).detach().requires_grad_()
>>> input_lengths = torch.full(size=(N,), fill_value=T, dtype=torch.long)
>>>
>>> # Initialize random batch of targets (0 = blank, 1:C = classes)
>>> target_lengths = torch.randint(low=1, high=T, size=(N,), dtype=torch.long)
>>> target = torch.randint(low=1, high=C, size=(sum(target_lengths),), dtype=torch.long)
>>> ctc_loss = nn.CTCLoss()
>>> loss = ctc_loss(input, target, input_lengths, target_lengths)
>>> loss.backward()
Reference:

A. Graves et al.: Connectionist Temporal Classification: Labelling Unsegmented Sequence Data with Recurrent Neural Networks: https://www.cs.toronto.edu/~graves/icml_2006.pdf

Note

In order to use CuDNN, the following must be satisfied: targets must be in concatenated format, all input_lengths must be T. blank=0blank=0, target_lengths 256\leq 256, the integer arguments must be of dtype torch.int32.

The regular implementation uses the (more common in PyTorch) torch.long dtype.

Note

In some circumstances when using the CUDA backend with CuDNN, this operator may select a nondeterministic algorithm to increase performance. If this is undesirable, you can try to make the operation deterministic (potentially at a performance cost) by setting torch.backends.cudnn.deterministic = True. Please see the notes on Reproducibility for background.

Docs

Access comprehensive developer documentation for PyTorch

View Docs

Tutorials

Get in-depth tutorials for beginners and advanced developers

View Tutorials

Resources

Find development resources and get your questions answered

View Resources