PyTorch Elastic
PyTorch Elastic (torchelastic) is a framework that enables distributed training jobs to be executed in a fault tolerant and elastic manner. It provides the primitives and interfaces for you to write your distributed PyTorch job in such a way that it can be run on multiple machines with elasticity; that is, your distributed job is able to start as soon as min number of workers are present and allowed to grow up to max number of workers without being stopped or restarted.
Use cases
Fault Tolerant Jobs
Jobs that run on infrastructure where nodes get replaced frequently, either due to flaky hardware or by design. Or mission critical production grade jobs that need to be run with resilience to failures.
Dynamic Capacity Management
Jobs that run on leased capacity that can be taken away at any time (e.g. AWS spot instances) or shared pools where the pool size can change dynamically based on demand.
Quickstart
Use one of the included examples and get a job running by following our Quickstart guide.
Requirements
torchelastic requires
Installation
How torchelastic works
torchelastic induces users to think about their PyTorch jobs as a train_step
and state
. It provides the basic control loop that repetitively executes the user provided train_step
being aware of faults, exceptions, and cluster membership changes.
Train Step
The train_step
is a unit of work, typically (although not necessarily) mapping to the processing of a mini-batch of training data. All k
workers in a distributed torchelastic job run the train_step()
, each contributing to the final output. What each worker does in a train_step
and what input data it consumes is a user-defined.
In the simplest use-case, torchelastic drives the execution of train_step
until either:
- the input data is exhausted
- an unrecoverable failure condition is encountered
- some other user-defined end of job criteria is met
Each train_step
may not be fully independent since the computations performed in the previous train_step
can be used and/or updated in the next one. Information is carried across train_step
calls using the state
object.
State
The state
, as the name implies, is an object that carries persistent information throughout the lifetime of the job and is expected to be updated on each train_step
. For example, in a training job, one of the information that the state
carries is the model weights. In practice it contains other (meta)data that must be persisted between train_steps
, for instance, the offset or index of the data stream. The state
object is the only input parameter to the train_step
.
Train Loop
The train_step
is executed in a train_loop
by torchelastic. The train_loop
is a fancy while
-loop that enables the execution of the job with fault tolerance and elasticity. torchelastic works at train_step
granularity, hence when a fault occurs during a train_step
the computations performed during the failed train_step
are considered lost and the state is restored to the previously succeeded train_step
.
Rendezvous
Torchelastic jobs define a [min, max]
range of number of workers that it can run with. For instance, [2, 10]
means that the job can start when at least two workers are present, and can be scaled up to ten workers at runtime.
Each time there is a change in membership in the set of workers, torchelastic runs arendezvous
, which serves the following purposes:
- barrier - all nodes will block until
rendezvous
is complete before resuming execution. - role assignment - on each
rendezvous
each node is assigned a unique integer valued rank between[0, n)
wheren
is the world size (total number of workers). - world size broadcast - on each
rendezvous
all nodes receive the newworld_size
.
The resource manager is free to add/remove instances from a torchelastic job as long as the total number of workers remain within [2, 10]
. This is what we refer to as elasticity. Additionally, in the event of a worker node failure, as long as the failed node is replaced, torchelastic will detect this event as a membership change and admit the new worker into the group, making the job fault-tolerant.
For additional details refer to the README in the rendezvous module.
Usage
Please refer to the usage documentation for details on how to write and configure a torchelastic job.
See the CONTRIBUTING file for how to help out.
License
torchelastic is BSD licensed, as found in the LICENSE file.
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