Accelerate documentation

DataLoaders, Optimizers, and Schedulers

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DataLoaders, Optimizers, and Schedulers

The internal classes Accelerate uses to prepare objects for distributed training when calling prepare().

DataLoader utilities

accelerate.data_loader.prepare_data_loader

< >

( dataloader: DataLoader device: typing.Optional[torch.device] = None num_processes: typing.Optional[int] = None process_index: typing.Optional[int] = None split_batches: bool = False put_on_device: bool = False rng_types: typing.Optional[typing.List[typing.Union[str, accelerate.utils.dataclasses.RNGType]]] = None dispatch_batches: typing.Optional[bool] = None even_batches: bool = True slice_fn_for_dispatch: typing.Optional[typing.Callable] = None use_seedable_sampler: bool = False data_seed: typing.Optional[int] = None non_blocking: bool = False use_stateful_dataloader: bool = False ) torch.utils.data.dataloader.DataLoader

Parameters

  • dataloader (torch.utils.data.dataloader.DataLoader) — The data loader to split across several devices.
  • device (torch.device) — The target device for the returned DataLoader.
  • num_processes (int, optional) — The number of processes running concurrently. Will default to the value given by PartialState.
  • process_index (int, optional) — The index of the current process. Will default to the value given by PartialState.
  • split_batches (bool, optional, defaults to False) — Whether the resulting DataLoader should split the batches of the original data loader across devices or yield full batches (in which case it will yield batches starting at the process_index-th and advancing of num_processes batches at each iteration).

    Another way to see this is that the observed batch size will be the same as the initial dataloader if this option is set to True, the batch size of the initial dataloader multiplied by num_processes otherwise.

    Setting this option to True requires that the batch size of the dataloader is a round multiple of batch_size.

  • put_on_device (bool, optional, defaults to False) — Whether or not to put the batches on device (only works if the batches are nested list, tuples or dictionaries of tensors).
  • rng_types (list of str or RNGType) — The list of random number generators to synchronize at the beginning of each iteration. Should be one or several of:

    • "torch": the base torch random number generator
    • "cuda": the CUDA random number generator (GPU only)
    • "xla": the XLA random number generator (TPU only)
    • "generator": the torch.Generator of the sampler (or batch sampler if there is no sampler in your dataloader) or of the iterable dataset (if it exists) if the underlying dataset is of that type.
  • dispatch_batches (bool, optional) — If set to True, the dataloader prepared is only iterated through on the main process and then the batches are split and broadcast to each process. Will default to True when the underlying dataset is an IterableDataset, False otherwise.
  • even_batches (bool, optional, defaults to True) — If set to True, in cases where the total batch size across all processes does not exactly divide the dataset, samples at the start of the dataset will be duplicated so the batch can be divided equally among all workers.
  • slice_fn_for_dispatch (Callable, optional) -- If passed, this function will be used to slice tensors across num_processes. Will default to [slice_tensors()](/docs/accelerate/v1.2.1/en/package_reference/utilities#accelerate.utils.slice_tensors). This argument is used only when dispatch_batchesis set toTrue` and will be ignored otherwise.
  • use_seedable_sampler (bool, optional, defaults to False) — Whether to use the SeedableRandomSampler instead of a RandomSampler for better reproducability. Comes at a cost of potentially different performances due to different shuffling algorithms but ensures results will be the exact same. Should be paired with set_seed() at every self.set_epoch
  • data_seed (int, optional, defaults to None) — The seed to use for the underlying generator when using use_seedable_sampler. If None, the generator will use the current default seed from torch.
  • non_blocking (bool, optional, defaults to False) — If set to True, dataloader will utilize non-blocking host-to-device transfers. If the dataloader has pin_memory set to True, this will help to increase overlap between data transfer and computations.
  • use_stateful_dataloader (bool, optional, defaults to False) — “If set to true, the dataloader prepared by the Accelerator will be backed by ” ”torchdata.StatefulDataLoader. This requires torchdata version 0.8.0 or higher that supports StatefulDataLoader to be installed.”

Returns

torch.utils.data.dataloader.DataLoader

A new data loader that will yield the portion of the batches

Wraps a PyTorch DataLoader to generate batches for one of the processes only.

Depending on the value of the drop_last attribute of the dataloader passed, it will either stop the iteration at the first batch that would be too small / not present on all processes or loop with indices from the beginning.

BatchSamplers with varying batch sizes are not enabled by default. To enable this behaviour, set even_batches equal to False

accelerate.skip_first_batches

< >

( dataloader num_batches = 0 )

Creates a torch.utils.data.DataLoader that will efficiently skip the first num_batches. Should not be used if the original dataloader is a StatefulDataLoader.

BatchSamplerShard

class accelerate.data_loader.BatchSamplerShard

< >

( batch_sampler: BatchSampler num_processes: int = 1 process_index: int = 0 split_batches: bool = False even_batches: bool = True )

Parameters

  • batch_sampler (torch.utils.data.sampler.BatchSampler) — The batch sampler to split in several shards.
  • num_processes (int, optional, defaults to 1) — The number of processes running concurrently.
  • process_index (int, optional, defaults to 0) — The index of the current process.
  • split_batches (bool, optional, defaults to False) — Whether the shards should be created by splitting a batch to give a piece of it on each process, or by yielding different full batches on each process.

    On two processes with a sampler of [[0, 1, 2, 3], [4, 5, 6, 7]], this will result in:

    • the sampler on process 0 to yield [0, 1, 2, 3] and the sampler on process 1 to yield [4, 5, 6, 7] if this argument is set to False.
    • the sampler on process 0 to yield [0, 1] then [4, 5] and the sampler on process 1 to yield [2, 3] then [6, 7] if this argument is set to True.
  • even_batches (bool, optional, defaults to True) — Whether or not to loop back at the beginning of the sampler when the number of samples is not a round multiple of (original batch size / number of processes).

Wraps a PyTorch BatchSampler to generate batches for one of the processes only. Instances of this class will always yield a number of batches that is a round multiple of num_processes and that all have the same size. Depending on the value of the drop_last attribute of the batch sampler passed, it will either stop the iteration at the first batch that would be too small / not present on all processes or loop with indices from the beginning.

BatchSamplers with varying batch sizes are not enabled by default. To enable this behaviour, set even_batches equal to False

IterableDatasetShard

class accelerate.data_loader.IterableDatasetShard

< >

( dataset: IterableDataset batch_size: int = 1 drop_last: bool = False num_processes: int = 1 process_index: int = 0 split_batches: bool = False )

Parameters

  • dataset (torch.utils.data.dataset.IterableDataset) — The batch sampler to split in several shards.
  • batch_size (int, optional, defaults to 1) — The size of the batches per shard (if split_batches=False) or the size of the batches (if split_batches=True).
  • drop_last (bool, optional, defaults to False) — Whether or not to drop the last incomplete batch or complete the last batches by using the samples from the beginning.
  • num_processes (int, optional, defaults to 1) — The number of processes running concurrently.
  • process_index (int, optional, defaults to 0) — The index of the current process.
  • split_batches (bool, optional, defaults to False) — Whether the shards should be created by splitting a batch to give a piece of it on each process, or by yielding different full batches on each process.

    On two processes with an iterable dataset yielding of [0, 1, 2, 3, 4, 5, 6, 7], this will result in:

    • the shard on process 0 to yield [0, 1, 2, 3] and the shard on process 1 to yield [4, 5, 6, 7] if this argument is set to False.
    • the shard on process 0 to yield [0, 1, 4, 5] and the sampler on process 1 to yield [2, 3, 6, 7] if this argument is set to True.

Wraps a PyTorch IterableDataset to generate samples for one of the processes only. Instances of this class will always yield a number of samples that is a round multiple of the actual batch size (depending of the value of split_batches, this is either batch_size or batch_size x num_processes). Depending on the value of the drop_last attribute of the batch sampler passed, it will either stop the iteration at the first batch that would be too small or loop with indices from the beginning.

DataLoaderShard

class accelerate.data_loader.DataLoaderShard

< >

( dataset device = None rng_types = None synchronized_generator = None skip_batches = 0 use_stateful_dataloader = False _drop_last: bool = False _non_blocking: bool = False **kwargs )

Parameters

  • dataset (torch.utils.data.dataset.Dataset) — The dataset to use to build this dataloader.
  • device (torch.device, optional) — If passed, the device to put all batches on.
  • rng_types (list of str or RNGType) — The list of random number generators to synchronize at the beginning of each iteration. Should be one or several of:

    • "torch": the base torch random number generator
    • "cuda": the CUDA random number generator (GPU only)
    • "xla": the XLA random number generator (TPU only)
    • "generator": an optional torch.Generator
  • synchronized_generator (torch.Generator, optional) — A random number generator to keep synchronized across processes.
  • skip_batches (int, optional, defaults to 0) — The number of batches to skip at the beginning.
  • use_stateful_dataloader (bool, optional, defaults to False) — Whether to have this class adapt StatefulDataLoader from torchdata instead of the regular DataLoader.
  • **kwargs (additional keyword arguments, optional) — All other keyword arguments to pass to the regular DataLoader initialization.

Subclass of DataLoaderAdapter that will deal with device placement and current distributed setup.

Available attributes:

  • total_batch_size (int) — Total batch size of the dataloader across all processes. Equal to the original batch size when split_batches=True; otherwise the original batch size * the total number of processes

  • total_dataset_length (int) — Total length of the inner dataset across all processes.

DataLoaderDispatcher

class accelerate.data_loader.DataLoaderDispatcher

< >

( dataset split_batches: bool = False skip_batches = 0 use_stateful_dataloader = False _drop_last: bool = False _non_blocking: bool = False slice_fn = None **kwargs )

Parameters

  • split_batches (bool, optional, defaults to False) — Whether the resulting DataLoader should split the batches of the original data loader across devices or yield full batches (in which case it will yield batches starting at the process_index-th and advancing of num_processes batches at each iteration). Another way to see this is that the observed batch size will be the same as the initial dataloader if this option is set to True, the batch size of the initial dataloader multiplied by num_processes otherwise. Setting this option to True requires that the batch size of the dataloader is a round multiple of batch_size.
  • skip_batches (int, optional, defaults to 0) — The number of batches to skip at the beginning of an iteration.
  • use_stateful_dataloader (bool, optional, defaults to False) — Whether to have this class adapt StatefulDataLoader from torchdata instead of the regular DataLoader.

Subclass of DataLoaderAdapter that will iterate and preprocess on process 0 only, then dispatch on each process their part of the batch.

Available attributes:

  • total_batch_size (int) — Total batch size of the dataloader across all processes. Equal to the original batch size when split_batches=True; otherwise the original batch size * the total number of processes

  • total_dataset_length (int) — Total length of the inner dataset across all processes.

AcceleratedOptimizer

class accelerate.optimizer.AcceleratedOptimizer

< >

( optimizer device_placement = True scaler = None )

Parameters

  • optimizer (torch.optim.optimizer.Optimizer) — The optimizer to wrap.
  • device_placement (bool, optional, defaults to True) — Whether or not the optimizer should handle device placement. If so, it will place the state dictionary of optimizer on the right device.
  • scaler (torch.cuda.amp.grad_scaler.GradScaler, optional) — The scaler to use in the step function if training with mixed precision.

Internal wrapper around a torch optimizer.

Conditionally will perform step and zero_grad if gradients should be synchronized when performing gradient accumulation.

eval

< >

( )

Sets the optimizer to “eval” mode. Useful for optimizers like schedule_free

train

< >

( )

Sets the optimizer to “train” mode. Useful for optimizers like schedule_free

AcceleratedScheduler

class accelerate.scheduler.AcceleratedScheduler

< >

( scheduler optimizers step_with_optimizer: bool = True split_batches: bool = False )

Parameters

  • scheduler (torch.optim.lr_scheduler._LRScheduler) — The scheduler to wrap.
  • optimizers (one or a list of torch.optim.Optimizer) — The optimizers used.
  • step_with_optimizer (bool, optional, defaults to True) — Whether or not the scheduler should be stepped at each optimizer step.
  • split_batches (bool, optional, defaults to False) — Whether or not the dataloaders split one batch across the different processes (so batch size is the same regardless of the number of processes) or create batches on each process (so batch size is the original batch size multiplied by the number of processes).

A wrapper around a learning rate scheduler that will only step when the optimizer(s) have a training step. Useful to avoid making a scheduler step too fast when gradients went overflow and there was no training step (in mixed precision training)

When performing gradient accumulation scheduler lengths should not be changed accordingly, Accelerate will always step the scheduler to account for it.

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