Hivemind - training on unreliable mixed GPUs across the internet¶
Collaborative Training tries to solve the need for top-tier multi-GPU servers by allowing you to train across unreliable machines, such as local machines or even preemptible cloud compute across the internet.
Under the hood, we use Hivemind which provides de-centralized training across the internet.
경고
This is an experimental feature.
To use Collaborative Training, you need to first this extension.
pip install lightning-hivemind
This will install both the Hivemind package as well as the HivemindStrategy
for the Lightning Trainer:
Reducing Communication By Overlapping Communication¶
We can reduce the impact of communication across all machines by overlapping communication with our training iterations. In short, we enable communication to happen in the background of training.
Overlap Gradient and State Averaging¶
When the target batch size is reached, all processes that are included in the step send gradients and model states to each other. By enabling some flags through the strategy, communication can happen in the background. This allows training to continue (with slightly outdated weights) but provides us the means to overlap communication with computation.
경고
Enabling overlapping communication means convergence will slightly be affected.
참고
Enabling these flags means that you must pass in a scheduler_fn
to the HivemindStrategy
instead of relying on a scheduler from configure_optimizers
.
The optimizer is re-created by Hivemind, and as a result, the scheduler has to be re-created.
import torch
from functools import partial
from lightning import Trainer
from lightning_hivemind.strategy import HivemindStrategy
trainer = Trainer(
strategy=HivemindStrategy(
target_batch_size=8192,
delay_state_averaging=True,
delay_grad_averaging=True,
delay_optimizer_step=True,
offload_optimizer=True, # required to delay averaging
scheduler_fn=partial(torch.optim.lr_scheduler.ExponentialLR, gamma=...),
),
accelerator="gpu",
devices=1,
)
Reducing GPU Memory requirements by re-using buffers & CPU offloading¶
We can also offload the optimizer state to the CPU whilst re-using gradient buffers to reduce the memory requirement for machines.
Offloading Optimizer State to the CPU¶
Offloading the Optimizer state to the CPU works the same as Deepspeed Zero-stage-2-offload, where we save GPU memory by keeping all optimizer states on the CPU.
참고
Enabling these flags means that you must pass in a scheduler_fn
to the HivemindStrategy
instead of relying on a scheduler from configure_optimizers
.
The optimizer is re-created by Hivemind, and as a result, the scheduler has to be re-created.
We suggest enabling offloading and overlapping communication to hide the additional overhead from having to communicate with the CPU.
import torch
from functools import partial
from lightning import Trainer
from lightning_hivemind.strategy import HivemindStrategy
trainer = Trainer(
strategy=HivemindStrategy(
target_batch_size=8192,
offload_optimizer=True,
scheduler_fn=partial(torch.optim.lr_scheduler.ExponentialLR, gamma=...),
),
accelerator="gpu",
devices=1,
)
Re-using Gradient Buffers¶
By default, Hivemind accumulates gradients in a separate buffer. This means additional GPU memory is required to store gradients. You can enable re-using the model parameter gradient buffers by passing reuse_grad_buffers=True
to the HivemindStrategy
.
경고
The HivemindStrategy
will override zero_grad
in your LightningModule
to have no effect. This is because gradients are accumulated in the model
and Hivemind manages when they need to be cleared.
from pytorch_lightning import Trainer
from lightning_hivemind.strategy import HivemindStrategy
trainer = Trainer(
strategy=HivemindStrategy(target_batch_size=8192, reuse_grad_buffers=True), accelerator="gpu", devices=1
)