AdversarialStrategy#
- class deeplay.activelearning.strategies.adversarial.adversarial.AdversarialStrategy(*args, **kwargs)#
Bases:
StrategyMethods Summary
Choose what optimizers and learning-rate schedulers to use in your optimization.
forward(x)Same as
torch.nn.Module.forward().gradient_penalty(real, fake)query_strategy(pool, n)Implement the query strategy here.
An iterable or collection of iterables specifying training samples.
training_step(batch, batch_idx)Here you compute and return the training loss and some additional metrics for e.g. the progress bar or logger.
Methods Documentation
- configure_optimizers()#
Choose what optimizers and learning-rate schedulers to use in your optimization. Normally you’d need one. But in the case of GANs or similar you might have multiple. Optimization with multiple optimizers only works in the manual optimization mode.
- Return:
Any of these 6 options.
Single optimizer.
List or Tuple of optimizers.
Two lists - The first list has multiple optimizers, and the second has multiple LR schedulers (or multiple
lr_scheduler_config).Dictionary, with an
"optimizer"key, and (optionally) a"lr_scheduler"key whose value is a single LR scheduler orlr_scheduler_config.None - Fit will run without any optimizer.
The
lr_scheduler_configis a dictionary which contains the scheduler and its associated configuration. The default configuration is shown below.lr_scheduler_config = { # REQUIRED: The scheduler instance "scheduler": lr_scheduler, # The unit of the scheduler's step size, could also be 'step'. # 'epoch' updates the scheduler on epoch end whereas 'step' # updates it after a optimizer update. "interval": "epoch", # How many epochs/steps should pass between calls to # `scheduler.step()`. 1 corresponds to updating the learning # rate after every epoch/step. "frequency": 1, # Metric to monitor for schedulers like `ReduceLROnPlateau` "monitor": "val_loss", # If set to `True`, will enforce that the value specified 'monitor' # is available when the scheduler is updated, thus stopping # training if not found. If set to `False`, it will only produce a warning "strict": True, # If using the `LearningRateMonitor` callback to monitor the # learning rate progress, this keyword can be used to specify # a custom logged name "name": None, }
When there are schedulers in which the
.step()method is conditioned on a value, such as thetorch.optim.lr_scheduler.ReduceLROnPlateauscheduler, Lightning requires that thelr_scheduler_configcontains the keyword"monitor"set to the metric name that the scheduler should be conditioned on.Metrics can be made available to monitor by simply logging it using
self.log('metric_to_track', metric_val)in yourLightningModule.- Note:
Some things to know:
Lightning calls
.backward()and.step()automatically in case of automatic optimization.If a learning rate scheduler is specified in
configure_optimizers()with key"interval"(default “epoch”) in the scheduler configuration, Lightning will call the scheduler’s.step()method automatically in case of automatic optimization.If you use 16-bit precision (
precision=16), Lightning will automatically handle the optimizer.If you use
torch.optim.LBFGS, Lightning handles the closure function automatically for you.If you use multiple optimizers, you will have to switch to ‘manual optimization’ mode and step them yourself.
If you need to control how often the optimizer steps, override the
optimizer_step()hook.
- forward(x)#
Same as
torch.nn.Module.forward().
- gradient_penalty(real, fake)#
- query_strategy(pool, n)#
Implement the query strategy here.
- train_dataloader()#
An iterable or collection of iterables specifying training samples.
For more information about multiple dataloaders, see this section.
The dataloader you return will not be reloaded unless you set :paramref:`~lightning.pytorch.trainer.trainer.Trainer.reload_dataloaders_every_n_epochs` to a positive integer.
For data processing use the following pattern:
download in
prepare_data()process and split in
setup()
However, the above are only necessary for distributed processing.
Warning
do not assign state in prepare_data
fit()prepare_data()setup()
- Note:
Lightning tries to add the correct sampler for distributed and arbitrary hardware. There is no need to set it yourself.
- training_step(batch, batch_idx)#
Here you compute and return the training loss and some additional metrics for e.g. the progress bar or logger.
- Args:
batch: The output of your data iterable, normally a
DataLoader. batch_idx: The index of this batch. dataloader_idx: The index of the dataloader that produced this batch.(only if multiple dataloaders used)
- Return:
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.
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.