4.4 KiB
Build your engine & Customize your trainer
Build your engine
To better understand how Engine
class works, let's start from the conception of the process function in common engines. The process function
usually controls the behavior over a batch of a dataset, Engine
class just controls the process function. Here we give a standard process
function in the following code block.
def process_function(dataloader, model, criterion, optim):
optim.zero_grad()
data, label = next(dataloader)
output = model(data)
loss = criterion(output, label)
loss.backward()
optim.setp()
In ignite.engine
or keras.engine
, the process function is always provided by users. However, it is tricky for users to write their own process
functions for pipeline parallelism. Aiming at offering accessible hybrid parallelism for users, we provide the powerful Engine
class. This class
enables pipeline parallelism and offers one-forward-one-backward non-interleaving strategy. Also, you can use pre-defined learning rate scheduler
in the Engine
class to adjust learning rate during training.
In order to build your engine, just set variables model
, criterion
, optimizer
, lr_scheduler
and schedule
. The following code block provides
an example.
import torch
import torch.nn as nn
import torchvision.models as models
import colossalai
model = models.resnet18()
criterion = nn.CrossEntropyLoss()
optimizer = torch.optim.Adam(model)
lr_scheduler = colossalai.nn.lr_scheduler.CosineAnnealingLR(optimizer, 1000)
schedule = colossalai.engine.schedule.NoPipelineSchedule()
MyEngine = Engine(
model=model,
criterion=criterion,
optimizer=optimizer,
lr_scheduler=lr_scheduler,
schedule=schedule
)
More information regarding the class can be found in the API references.
Customize your trainer
Overview
To learn how to customize a trainer which meets your needs, let's first give a look at the Trainer
class. We highly recommend that you read Get Started
section and Build your engine first.
The Trainer
class enables researchers and engineers to use our system more conveniently. Instead of having to write your own scripts, you can simply
construct your own trainer by calling the Trainer
class, just like what we did in the following code block.
MyTrainer = Trainer(MyEngine)
After that, you can use the fit
method to train or evaluate your model. In order to make our Trainer
class even more powerful, we incorporate a set of
handy tools to the class. For example, you can monitor or record the running states and metrics which indicate the current performance of the model. These
functions are realized by hooks. The BasicHook
class allows you to execute your hook functions at specified time. We have already created some practical
hooks for you, as listed below. What you need to do is just picking the right ones which suit your needs. Detailed descriptions of the class can be found
in the API references.
hooks = [
dict(type='LogMetricByEpochHook'),
dict(type='LogTimingByEpochHook'),
dict(type='LogMemoryByEpochHook'),
dict(type='AccuracyHook'),
dict(type='LossHook'),
dict(type='TensorboardHook', log_dir='./tfb_logs'),
dict(type='SaveCheckpointHook', interval=5, checkpoint_dir='./ckpt'),
dict(type='LoadCheckpointHook', epoch=20, checkpoint_dir='./ckpt')
]
These hook functions will record metrics, elapsed time and memory usage and write them to log after each epoch. Besides, they print the current loss and accuracy to let users monitor the performance of the model.
Hook
If you have your specific needs, feel free to extend our BaseHook
class to add your own functions, or our MetricHook
class to write a metric collector.
These hook functions can be called at twelve timing in the trainer's life cycle. Besides, you can define the priorities of all hooks to arrange the execution order of them.
More information can be found in the API references.
Metric
You can write your own metrics by extending our Metric
class. It should be used with the MetricHook
class. When your write your own metric hooks, please set
the priority carefully and make sure the hook is called before other hooks which might require the results of the metric hook.
We've already provided some metric hooks and we store metric objects in runner.states['metrics']
. It is a dictionary and metrics can be accessed by their names.