Generic Join Context Manager¶
The generic join context manager facilitates distributed training on uneven
inputs. This page outlines the API of the relevant classes:
JoinHook. For a tutorial, see
Distributed Training with Uneven Inputs Using the Join Context Manager.
Join(joinables, enable=True, throw_on_early_termination=False, **kwargs)[source]¶
This class defines the generic join context manager, which allows custom hooks to be called after a process joins. These hooks should shadow the collective communications of non-joined processes to prevent hanging and erroring and to ensure algorithmic correctness. Refer to
JoinHookfor details about the hook definition.
The context manager requires each participating
Joinableto call the method
notify_join_context()before its own per- iteration collective communications to ensure correctness.
The context manager requires that all
process_groupattributes in the
JoinHookobjects are the same. If there are multiple
JoinHookobjects, then the
deviceof the first is used. The process group and device information is used for checking for non- joined processes and for notifying processes to throw an exception if
throw_on_early_terminationis enabled, both of which using an all- reduce.
joinables (List[Joinable]) – a list of the participating
Joinables; their hooks are iterated over in the given order.
enable (bool) – a flag enabling uneven input detection; setting to
Falsedisables the context manager’s functionality and should only be set when the user knows the inputs will not be uneven (default:
throw_on_early_termination (bool) – a flag controlling whether to throw an exception upon detecting uneven inputs (default:
>>> import os >>> import torch >>> import torch.distributed as dist >>> import torch.multiprocessing as mp >>> import torch.nn.parallel.DistributedDataParallel as DDP >>> import torch.distributed.optim.ZeroRedundancyOptimizer as ZeRO >>> from torch.distributed.algorithms.join import Join >>> >>> # On each spawned worker >>> def worker(rank): >>> dist.init_process_group("nccl", rank=rank, world_size=2) >>> model = DDP(torch.nn.Linear(1, 1).to(rank), device_ids=[rank]) >>> optim = ZeRO(model.parameters(), torch.optim.Adam, lr=0.01) >>> # Rank 1 gets one more input than rank 0 >>> inputs = [torch.tensor([1.]).to(rank) for _ in range(10 + rank)] >>> with Join([model, optim]): >>> for input in inputs: >>> loss = model(input).sum() >>> loss.backward() >>> optim.step() >>> # All ranks reach here without hanging/erroring
Notifies the join context manager that the calling process has not yet joined; then, if
throw_on_early_termination=True, checks if uneven inputs have been detected (i.e. if one process has already joined) and throws an exception if so.
This method should be called from a
Joinableobject before its per-iteration collective communications. For example, this should be called at the beginning of the forward pass in
Only the first
Joinableobject passed into the context manager performs the collective communications in this method, and for the others, this method is vacuous.
This defines an abstract base class for joinable classes. A joinable class (inheriting from
Joinable) should implement
join_hook(), which returns a
JoinHookinstance, in addition to
join_process_group()that return device and process group information, respectively.
Returns the device from which to perform collective communications needed by the join context manager implementation itself.
Returns the process group for the collective communications needed by the join context manager itself.
- abstract property
This defines a join hook, which provides two entry points in the join context manager: a main hook, which is called repeatedly while there exists a non-joined process, and a post-hook, which is called once all processes have joined.
To implement a join hook for the generic join context manager, define a class that inherits from
This hook is called repeatedly while there exists a non-joined process to shadow collective communications in one training iteration (i.e. in one forward pass, backward pass, and optimizer step).