We are happy to announce that luz
version 0.3.0 is now on CRAN. This
release brings a few improvements to the learning rate finder
first contributed by Chris
McMaster. As we didn’t have a
0.2.0 release post, we will also highlight a few improvements that
date back to that version.
What’s luz
?
Since it is relatively new
package, we are
starting this blog post with a quick recap of how luz
works. If you
already know what luz
is, feel free to move on to the next section.
luz
is a high-level API for torch
that aims to encapsulate the training
loop into a set of reusable pieces of code. It reduces the boilerplate
required to train a model with torch
, avoids the error-prone
zero_grad()
– backward()
– step()
sequence of calls, and also
simplifies the process of moving data and models between CPUs and GPUs.
With luz
you can take your torch
nn_module()
, for example the
two-layer perceptron defined below:
modnn <- nn_module(
initialize = function(input_size) {
self$hidden <- nn_linear(input_size, 50)
self$activation <- nn_relu()
self$dropout <- nn_dropout(0.4)
self$output <- nn_linear(50, 1)
},
forward = function(x) {
x %>%
self$hidden() %>%
self$activation() %>%
self$dropout() %>%
self$output()
}
)
and fit it to a specified dataset like so:
fitted <- modnn %>%
setup(
loss = nn_mse_loss(),
optimizer = optim_rmsprop,
metrics = list(luz_metric_mae())
) %>%
set_hparams(input_size = 50) %>%
fit(
data = list(x_train, y_train),
valid_data = list(x_valid, y_valid),
epochs = 20
)
luz
will automatically train your model on the GPU if it’s available,
display a nice progress bar during training, and handle logging of metrics,
all while making sure evaluation on validation data is performed in the correct way
(e.g., disabling dropout).
luz
can be extended in many different layers of abstraction, so you can
improve your knowledge gradually, as you need more advanced features in your
project. For example, you can implement custom
metrics,
callbacks,
or even customize the internal training
loop.
To learn about luz
, read the getting
started
section on the website, and browse the examples
gallery.
What’s new in luz
?
Learning rate finder
In deep learning, finding a good learning rate is essential to be able
to fit your model. If it’s too low, you will need too many iterations
for your loss to converge, and that might be impractical if your model
takes too long to run. If it’s too high, the loss can explode and you
might never be able to arrive at a minimum.
The lr_finder()
function implements the algorithm detailed in Cyclical Learning Rates for
Training Neural Networks
(Smith 2015) popularized in the FastAI framework (Howard and Gugger 2020). It
takes an nn_module()
and some data to produce a data frame with the
losses and the learning rate at each step.
model <- net %>% setup(
loss = torch::nn_cross_entropy_loss(),
optimizer = torch::optim_adam
)
records <- lr_finder(
object = model,
data = train_ds,
verbose = FALSE,
dataloader_options = list(batch_size = 32),
start_lr = 1e-6, # the smallest value that will be tried
end_lr = 1 # the largest value to be experimented with
)
str(records)
#> Classes 'lr_records' and 'data.frame': 100 obs. of 2 variables:
#> $ lr : num 1.15e-06 1.32e-06 1.51e-06 1.74e-06 2.00e-06 ...
#> $ loss: num 2.31 2.3 2.29 2.3 2.31 ...
You can use the built-in plot method to display the exact results, along
with an exponentially smoothed value of the loss.
plot(records) +
ggplot2::coord_cartesian(ylim = c(NA, 5))
If you want to learn how to interpret the results of this plot and learn
more about the methodology read the learning rate finder
article on the
luz
website.
Data handling
In the first release of luz
, the only kind of object that was allowed to
be used as input data to fit
was a torch
dataloader()
. As of version
0.2.0, luz
also support’s R matrices/arrays (or nested lists of them) as
input data, as well as torch
dataset()
s.
Supporting low level abstractions like dataloader()
as input data is
important, as with them the user has full control over how input
data is loaded. For example, you can create parallel dataloaders,
change how shuffling is done, and more. However, having to manually
define the dataloader seems unnecessarily tedious when you don’t need to
customize any of this.
Another small improvement from version 0.2.0, inspired by Keras, is that
you can pass a value between 0 and 1 to fit
’s valid_data
parameter, and luz
will
take a random sample of that proportion from the training set, to be used for
validation data.
Read more about this in the documentation of the
fit()
function.
New callbacks
In recent releases, new built-in callbacks were added to luz
:
luz_callback_gradient_clip()
: Helps avoiding loss divergence by
clipping large gradients.luz_callback_keep_best_model()
: Each epoch, if there’s improvement
in the monitored metric, we serialize the model weights to a temporary
file. When training is done, we reload weights from the best model.luz_callback_mixup()
: Implementation of ‘mixup: Beyond Empirical
Risk Minimization’
(Zhang et al. 2017). Mixup is a nice data augmentation technique that
helps improving model consistency and overall performance.
You can see the full changelog available
here.
In this post we would also like to thank:
-
@jonthegeek for valuable
improvements in theluz
getting-started guides. -
@mattwarkentin for many good
ideas, improvements and bug fixes. -
@cmcmaster1 for the initial
implementation of the learning rate finder and other bug fixes. -
@skeydan for the implementation of the Mixup callback and improvements in the learning rate finder.
Thank you!
Photo by Dil on Unsplash