Launching Multi-Node Training from a Jupyter Environment
This tutorial teaches you how to fine tune a computer vision model with 🤗 Accelerate from a Jupyter Notebook on a distributed system. You will also learn how to setup a few requirements needed for ensuring your environment is configured properly, your data has been prepared properly, and finally how to launch training.
This tutorial is also available as a Jupyter Notebook here
Configuring the Environment
Before any training can be performed, a 🤗 Accelerate config file must exist in the system. Usually this can be done by running the following in a terminal and answering the prompts:
accelerate config
However, if general defaults are fine and you are not running on a TPU, 🤗Accelerate has a utility to quickly write your GPU configuration into a config file via utils.write_basic_config().
The following code will restart Jupyter after writing the configuration, as CUDA code was called to perform this.
CUDA can’t be initialized more than once on a multi-node system. It’s fine to debug in the notebook and have calls to CUDA, but in order to finally train a full cleanup and restart will need to be performed.
import os
from accelerate.utils import write_basic_config
write_basic_config() # Write a config file
os._exit(00) # Restart the notebook
Preparing the Dataset and Model
Next you should prepare your dataset. As mentioned at earlier, great care should be taken when preparing the DataLoaders
and model to make sure that nothing is put on any GPU.
If you do, it is recommended to put that specific code into a function and call that from within the notebook launcher interface, which will be shown later.
Make sure the dataset is downloaded based on the directions here
import os, re, torch, PIL
import numpy as np
from torch.optim.lr_scheduler import OneCycleLR
from torch.utils.data import DataLoader, Dataset
from torchvision.transforms import Compose, RandomResizedCrop, Resize, ToTensor
from accelerate import Accelerator
from accelerate.utils import set_seed
from timm import create_model
First you need to create a function to extract the class name based on a filename:
import os
data_dir = "../../images"
fnames = os.listdir(data_dir)
fname = fnames[0]
print(fname)
beagle_32.jpg
In the case here, the label is beagle
. Using regex you can extract the label from the filename:
import re
def extract_label(fname):
stem = fname.split(os.path.sep)[-1]
return re.search(r"^(.*)_\d+\.jpg$", stem).groups()[0]
extract_label(fname)
And you can see it properly returned the right name for our file:
"beagle"
Next a Dataset
class should be made to handle grabbing the image and the label:
class PetsDataset(Dataset):
def __init__(self, file_names, image_transform=None, label_to_id=None):
self.file_names = file_names
self.image_transform = image_transform
self.label_to_id = label_to_id
def __len__(self):
return len(self.file_names)
def __getitem__(self, idx):
fname = self.file_names[idx]
raw_image = PIL.Image.open(fname)
image = raw_image.convert("RGB")
if self.image_transform is not None:
image = self.image_transform(image)
label = extract_label(fname)
if self.label_to_id is not None:
label = self.label_to_id[label]
return {"image": image, "label": label}
Now to build the dataset. Outside the training function you can find and declare all the filenames and labels and use them as references inside the launched function:
fnames = [os.path.join("../../images", fname) for fname in fnames if fname.endswith(".jpg")]
Next gather all the labels:
all_labels = [extract_label(fname) for fname in fnames]
id_to_label = list(set(all_labels))
id_to_label.sort()
label_to_id = {lbl: i for i, lbl in enumerate(id_to_label)}
Next, you should make a get_dataloaders
function that will return your built dataloaders for you. As mentioned earlier, if data is automatically
sent to the GPU or a TPU device when building your DataLoaders
, they must be built using this method.
def get_dataloaders(batch_size: int = 64):
"Builds a set of dataloaders with a batch_size"
random_perm = np.random.permutation(len(fnames))
cut = int(0.8 * len(fnames))
train_split = random_perm[:cut]
eval_split = random_perm[cut:]
# For training a simple RandomResizedCrop will be used
train_tfm = Compose([RandomResizedCrop((224, 224), scale=(0.5, 1.0)), ToTensor()])
train_dataset = PetsDataset([fnames[i] for i in train_split], image_transform=train_tfm, label_to_id=label_to_id)
# For evaluation a deterministic Resize will be used
eval_tfm = Compose([Resize((224, 224)), ToTensor()])
eval_dataset = PetsDataset([fnames[i] for i in eval_split], image_transform=eval_tfm, label_to_id=label_to_id)
# Instantiate dataloaders
train_dataloader = DataLoader(train_dataset, shuffle=True, batch_size=batch_size, num_workers=4)
eval_dataloader = DataLoader(eval_dataset, shuffle=False, batch_size=batch_size * 2, num_workers=4)
return train_dataloader, eval_dataloader
Finally, you should import the scheduler to be used later:
from torch.optim.lr_scheduler import CosineAnnealingLR
Writing the Training Function
Now you can build the training loop. notebook_launcher() works by passing in a function to call that will be ran across the distributed system.
Here is a basic training loop for the animal classification problem:
The code has been split up to allow for explainations on each section. A full version that can be copy and pasted will be available at the end
def training_loop(mixed_precision="fp16", seed: int = 42, batch_size: int = 64):
set_seed(seed)
accelerator = Accelerator(mixed_precision=mixed_precision)
First you should set the seed and create an Accelerator object as early in the training loop as possible.
If training on the TPU, your training loop should take in the model as a parameter and it should be instantiated outside of the training loop function. See the TPU best practices to learn why
Next you should build your dataloaders and create your model:
train_dataloader, eval_dataloader = get_dataloaders(batch_size)
model = create_model("resnet50d", pretrained=True, num_classes=len(label_to_id))
You build the model here so that the seed also controls the new weight initialization
As you are performing transfer learning in this example, the encoder of the model starts out frozen so the head of the model can be trained only initially:
for param in model.parameters():
param.requires_grad = False
for param in model.get_classifier().parameters():
param.requires_grad = True
Normalizing the batches of images will make training a little faster:
mean = torch.tensor(model.default_cfg["mean"])[None, :, None, None]
std = torch.tensor(model.default_cfg["std"])[None, :, None, None]
To make these constants available on the active device, you should set it to the Accelerator’s device:
mean = mean.to(accelerator.device) std = std.to(accelerator.device)
Next instantiate the rest of the PyTorch classes used for training:
optimizer = torch.optim.Adam(params=model.parameters(), lr=3e-2 / 25)
lr_scheduler = OneCycleLR(optimizer=optimizer, max_lr=3e-2, epochs=5, steps_per_epoch=len(train_dataloader))
Before passing everything to prepare().
There is no specific order to remember, you just need to unpack the objects in the same order you gave them to the prepare method.
model, optimizer, train_dataloader, eval_dataloader, lr_scheduler = accelerator.prepare( model, optimizer, train_dataloader, eval_dataloader, lr_scheduler )
Now train the model:
for epoch in range(5):
model.train()
for batch in train_dataloader:
inputs = (batch["image"] - mean) / std
outputs = model(inputs)
loss = torch.nn.functional.cross_entropy(outputs, batch["label"])
accelerator.backward(loss)
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
The evaluation loop will look slightly different compared to the training loop. The number of elements passed as well as the overall total accuracy of each batch will be added to two constants:
model.eval()
accurate = 0
num_elems = 0
Next you have the rest of your standard PyTorch loop:
for batch in eval_dataloader:
inputs = (batch["image"] - mean) / std
with torch.no_grad():
outputs = model(inputs)
predictions = outputs.argmax(dim=-1)
Before finally the last major difference.
When performing distributed evaluation, the predictions and labels need to be passed through gather() so that all of the data is available on the current device and a properly calculated metric can be achieved:
accurate_preds = accelerator.gather(predictions) == accelerator.gather(batch["label"])
num_elems += accurate_preds.shape[0]
accurate += accurate_preds.long().sum()
Now you just need to calculate the actual metric for this problem, and you can print it on the main process using print():
eval_metric = accurate.item() / num_elems
accelerator.print(f"epoch {epoch}: {100 * eval_metric:.2f}")
A full version of this training loop is available below:
def training_loop(mixed_precision="fp16", seed: int = 42, batch_size: int = 64):
set_seed(seed)
# Initialize accelerator
accelerator = Accelerator(mixed_precision=mixed_precision)
# Build dataloaders
train_dataloader, eval_dataloader = get_dataloaders(batch_size)
# Instantiate the model (you build the model here so that the seed also controls new weight initaliziations)
model = create_model("resnet50d", pretrained=True, num_classes=len(label_to_id))
# Freeze the base model
for param in model.parameters():
param.requires_grad = False
for param in model.get_classifier().parameters():
param.requires_grad = True
# You can normalize the batches of images to be a bit faster
mean = torch.tensor(model.default_cfg["mean"])[None, :, None, None]
std = torch.tensor(model.default_cfg["std"])[None, :, None, None]
# To make these constants available on the active device, set it to the accelerator device
mean = mean.to(accelerator.device)
std = std.to(accelerator.device)
# Intantiate the optimizer
optimizer = torch.optim.Adam(params=model.parameters(), lr=3e-2 / 25)
# Instantiate the learning rate scheduler
lr_scheduler = OneCycleLR(optimizer=optimizer, max_lr=3e-2, epochs=5, steps_per_epoch=len(train_dataloader))
# Prepare everything
# There is no specific order to remember, you just need to unpack the objects in the same order you gave them to the
# prepare method.
model, optimizer, train_dataloader, eval_dataloader, lr_scheduler = accelerator.prepare(
model, optimizer, train_dataloader, eval_dataloader, lr_scheduler
)
# Now you train the model
for epoch in range(5):
model.train()
for batch in train_dataloader:
inputs = (batch["image"] - mean) / std
outputs = model(inputs)
loss = torch.nn.functional.cross_entropy(outputs, batch["label"])
accelerator.backward(loss)
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
model.eval()
accurate = 0
num_elems = 0
for batch in eval_dataloader:
inputs = (batch["image"] - mean) / std
with torch.no_grad():
outputs = model(inputs)
predictions = outputs.argmax(dim=-1)
accurate_preds = accelerator.gather(predictions) == accelerator.gather(batch["label"])
num_elems += accurate_preds.shape[0]
accurate += accurate_preds.long().sum()
eval_metric = accurate.item() / num_elems
# Use accelerator.print to print only on the main process.
accelerator.print(f"epoch {epoch}: {100 * eval_metric:.2f}")
Using the notebook_launcher
All that’s left is to use the notebook_launcher().
You pass in the function, the arguments (as a tuple), and the number of processes to train on. (See the documentation for more information)
from accelerate import notebook_launcher
args = ("fp16", 42, 64)
notebook_launcher(training_loop, args, num_processes=2)
In the case of running on the TPU, it would look like so:
model = create_model("resnet50d", pretrained=True, num_classes=len(label_to_id))
args = (model, "fp16", 42, 64)
notebook_launcher(training_loop, args, num_processes=8)
As it’s running it will print the progress as well as state how many devices you ran on. This tutorial was ran with two GPUs:
Launching training on 2 GPUs.
epoch 0: 88.12
epoch 1: 91.73
epoch 2: 92.58
epoch 3: 93.90
epoch 4: 94.71
And that’s it!
Conclusion
This notebook showed how to perform distributed training from inside of a Jupyter Notebook. Some key notes to remember:
- Make sure to save any code that use CUDA (or CUDA imports) for the function passed to notebook_launcher()
- Set the
num_processes
to be the number of devices used for training (such as number of GPUs, CPUs, TPUs, etc) - If using the TPU, declare your model outside the training loop function