Speed up Training¶
Distributed Training¶
MMEngine supports training models with CPU, single GPU, multiple GPUs in single machine and multiple machines. When multiple GPUs are available in the environment, we can use the following command to enable multiple GPUs in single machine or multiple machines to shorten the training time of the model.
multiple GPUs in single machine
Assuming the current machine has 8 GPUs, you can enable multiple GPUs training with the following command:
python -m torch.distributed.launch --nproc_per_node=8 examples/train.py --launcher pytorch
If you need to specify the GPU index, you can set the
CUDA_VISIBLE_DEVICES
environment variable, e.g. use the 0th and 3rd GPU.CUDA_VISIBLE_DEVICES=0,3 python -m torch.distributed.launch --nproc_per_node=2 examples/train.py --launcher pytorch
multiple machines
Assume that there are 2 machines connected with ethernet, you can simply run following commands.
On the first machine:
python -m torch.distributed.launch \ --nnodes 8 \ --node_rank 0 \ --master_addr 127.0.0.1 \ --master_port 29500 \ --nproc_per_node=8 \ examples/train.py --launcher pytorch
On the second machine:
python -m torch.distributed.launch \ --nnodes 8 \ --node_rank 1 \ --master_addr 127.0.0.1 \ --master_port 29500 \ --nproc_per_node=8 \
If you are running MMEngine in a slurm cluster, simply run the following command to enable training for 2 machines and 16 GPUs.
srun -p mm_dev \ --job-name=test \ --gres=gpu:8 \ --ntasks=16 \ --ntasks-per-node=8 \ --cpus-per-task=5 \ --kill-on-bad-exit=1 \ python examples/train.py --launcher="slurm"
Mixed Precision Training¶
Nvidia introduced the Tensor Core unit into the Volta and Turing architectures to support FP32 and FP16 mixed precision computing. They further support BF16 in Ampere architectures. With automatic mixed precision training enabled, some operators operate at FP16/BF16 and the rest operate at FP32, which reduces training time and storage requirements without changing the model or degrading its training precision, thus supporting training with larger batch sizes, larger models, and larger input sizes.
PyTorch officially supports amp from 1.6. If you are interested in the implementation of automatic mixing precision, you can refer to Mixed Precision Training.
MMEngine provides the wrapper AmpOptimWrapper for auto-mixing precision training, just set type='AmpOptimWrapper'
in optim_wrapper
to enable auto-mixing precision training, no other code changes are needed.
runner = Runner(
model=ResNet18(),
work_dir='./work_dir',
train_dataloader=train_dataloader_cfg,
optim_wrapper=dict(
type='AmpOptimWrapper',
# If you want to use bfloat16, uncomment the following line
# dtype='bfloat16', # valid values: ('float16', 'bfloat16', None)
optimizer=dict(type='SGD', lr=0.001, momentum=0.9)),
train_cfg=dict(by_epoch=True, max_epochs=3),
)
runner.train()
Warning
Up till PyTorch 1.13, torch.bfloat16
performance on Convolution
is bad unless manually set environment variable TORCH_CUDNN_V8_API_ENABLED=1
. More context at PyTorch issue
Model Compilation¶
PyTorch introduced torch.compile in its 2.0 release. It compiles your model to speedup trainning & validation. This feature can be enabled since MMEngine v0.7.0, by passing to Runner
an extra cfg
dict with compile
keyword:
runner = Runner(
model=ResNet18(),
... # other arguments you want
cfg=dict(compile=True)
)
For advanced usage, you can also change compile options as illustrated in torch.compile API Documentation. For example:
compile_options = dict(backend='inductor', mode='max-autotune')
runner = Runner(
model=ResNet18(),
... # other arguments you want
cfg=dict(compile=compile_options)
)
This feature is only available for PyTorch >= 2.0.0.
Warning
torch.compile
is still under development by PyTorch team. Some models may fail compilation. If you encounter errors during compilation, you can refer to PyTorch Dynamo FAQ for quick fix, or TorchDynamo Troubleshooting to post an issue in PyTorch.