autocast.models.autoencoder#
- class AELoss(losses=None, weights=None)[source]#
Bases:
ModuleAutoencoder Loss Function.
- forward(model, batch)[source]#
Define the computation performed at every call.
Should be overridden by all subclasses.
Note
Although the recipe for forward pass needs to be defined within this function, one should call the
Moduleinstance afterwards instead of this since the former takes care of running the registered hooks while the latter silently ignores them.- Parameters:
model (EncoderDecoder)
batch (Batch)
- Return type:
- class VMSELoss(eps=0.01)[source]#
Bases:
ModuleVariance-scaled MSE loss reduced over batch/time/channels.
- Parameters:
eps (float)
- forward(y_pred, y_true)[source]#
Define the computation performed at every call.
Should be overridden by all subclasses.
Note
Although the recipe for forward pass needs to be defined within this function, one should call the
Moduleinstance afterwards instead of this since the former takes care of running the registered hooks while the latter silently ignores them.- Parameters:
y_pred (Float[Tensor, 'batch time spatial *spatial channel'])
y_true (Float[Tensor, 'batch time spatial *spatial channel'])
- Return type:
- class AE(encoder, decoder, loss_func=None, optimizer_config=None, train_metrics=[], val_metrics=None, test_metrics=None, norm=None)[source]#
Bases:
EncoderDecoderAutoencoder Model.
- Parameters:
- encoder: EncoderWithCond#
- forward(batch)[source]#
Same as
torch.nn.Module.forward().- Parameters:
*args – Whatever you decide to pass into the forward method.
**kwargs – Keyword arguments are also possible.
batch (Batch)
- Returns:
Your model’s output
- Return type:
Float[Tensor, ‘batch *optional_dims channel’]
- training_step(batch, batch_idx)[source]#
Here you compute and return the training loss and some additional metrics for e.g. the progress bar or logger.
- Parameters:
batch (Batch) – The output of your data iterable, normally a
DataLoader.batch_idx (int) – The index of this batch.
dataloader_idx – The index of the dataloader that produced this batch. (only if multiple dataloaders used)
- Returns:
Tensor- The loss tensordict- A dictionary which can include any keys, but must include the key'loss'in the case of automatic optimization.None- In automatic optimization, this will skip to the next batch (but is not supported for multi-GPU, TPU, or DeepSpeed). For manual optimization, this has no special meaning, as returning the loss is not required.
- Return type:
In this step you’d normally do the forward pass and calculate the loss for a batch. You can also do fancier things like multiple forward passes or something model specific.
Example:
def training_step(self, batch, batch_idx): x, y, z = batch out = self.encoder(x) loss = self.loss(out, x) return loss
To use multiple optimizers, you can switch to ‘manual optimization’ and control their stepping:
def __init__(self): super().__init__() self.automatic_optimization = False # Multiple optimizers (e.g.: GANs) def training_step(self, batch, batch_idx): opt1, opt2 = self.optimizers() # do training_step with encoder ... opt1.step() # do training_step with decoder ... opt2.step()
Note
When
accumulate_grad_batches> 1, the loss returned here will be automatically normalized byaccumulate_grad_batchesinternally.
- validation_step(batch, batch_idx)[source]#
Operates on a single batch of data from the validation set. In this step you’d might generate examples or calculate anything of interest like accuracy.
- Parameters:
batch (Batch) – The output of your data iterable, normally a
DataLoader.batch_idx (int) – The index of this batch.
dataloader_idx – The index of the dataloader that produced this batch. (only if multiple dataloaders used)
- Returns:
Tensor- The loss tensordict- A dictionary. Can include any keys, but must include the key'loss'.None- Skip to the next batch.
- Return type:
# if you have one val dataloader: def validation_step(self, batch, batch_idx): ... # if you have multiple val dataloaders: def validation_step(self, batch, batch_idx, dataloader_idx=0): ...
Examples:
# CASE 1: A single validation dataset def validation_step(self, batch, batch_idx): x, y = batch # implement your own out = self(x) loss = self.loss(out, y) # log 6 example images # or generated text... or whatever sample_imgs = x[:6] grid = torchvision.utils.make_grid(sample_imgs) self.logger.experiment.add_image('example_images', grid, 0) # calculate acc labels_hat = torch.argmax(out, dim=1) val_acc = torch.sum(y == labels_hat).item() / (len(y) * 1.0) # log the outputs! self.log_dict({'val_loss': loss, 'val_acc': val_acc})
If you pass in multiple val dataloaders,
validation_step()will have an additional argument. We recommend setting the default value of 0 so that you can quickly switch between single and multiple dataloaders.# CASE 2: multiple validation dataloaders def validation_step(self, batch, batch_idx, dataloader_idx=0): # dataloader_idx tells you which dataset this is. x, y = batch # implement your own out = self(x) if dataloader_idx == 0: loss = self.loss0(out, y) else: loss = self.loss1(out, y) # calculate acc labels_hat = torch.argmax(out, dim=1) acc = torch.sum(y == labels_hat).item() / (len(y) * 1.0) # log the outputs separately for each dataloader self.log_dict({f"val_loss_{dataloader_idx}": loss, f"val_acc_{dataloader_idx}": acc})
Note
If you don’t need to validate you don’t need to implement this method.
Note
When the
validation_step()is called, the model has been put in eval mode and PyTorch gradients have been disabled. At the end of validation, the model goes back to training mode and gradients are enabled.
- test_step(batch, batch_idx)[source]#
Operates on a single batch of data from the test set. In this step you’d normally generate examples or calculate anything of interest such as accuracy.
- Parameters:
batch (Batch) – The output of your data iterable, normally a
DataLoader.batch_idx (int) – The index of this batch.
dataloader_idx – The index of the dataloader that produced this batch. (only if multiple dataloaders used)
- Returns:
Tensor- The loss tensordict- A dictionary. Can include any keys, but must include the key'loss'.None- Skip to the next batch.
- Return type:
# if you have one test dataloader: def test_step(self, batch, batch_idx): ... # if you have multiple test dataloaders: def test_step(self, batch, batch_idx, dataloader_idx=0): ...
Examples:
# CASE 1: A single test dataset def test_step(self, batch, batch_idx): x, y = batch # implement your own out = self(x) loss = self.loss(out, y) # log 6 example images # or generated text... or whatever sample_imgs = x[:6] grid = torchvision.utils.make_grid(sample_imgs) self.logger.experiment.add_image('example_images', grid, 0) # calculate acc labels_hat = torch.argmax(out, dim=1) test_acc = torch.sum(y == labels_hat).item() / (len(y) * 1.0) # log the outputs! self.log_dict({'test_loss': loss, 'test_acc': test_acc})
If you pass in multiple test dataloaders,
test_step()will have an additional argument. We recommend setting the default value of 0 so that you can quickly switch between single and multiple dataloaders.# CASE 2: multiple test dataloaders def test_step(self, batch, batch_idx, dataloader_idx=0): # dataloader_idx tells you which dataset this is. x, y = batch # implement your own out = self(x) if dataloader_idx == 0: loss = self.loss0(out, y) else: loss = self.loss1(out, y) # calculate acc labels_hat = torch.argmax(out, dim=1) acc = torch.sum(y == labels_hat).item() / (len(y) * 1.0) # log the outputs separately for each dataloader self.log_dict({f"test_loss_{dataloader_idx}": loss, f"test_acc_{dataloader_idx}": acc})
Note
If you don’t need to test you don’t need to implement this method.
Note
When the
test_step()is called, the model has been put in eval mode and PyTorch gradients have been disabled. At the end of the test epoch, the model goes back to training mode and gradients are enabled.