---
title: Customizing what happens in `fit()` with TensorFlow
date-created: 2020/04/15
last-modified: 2023/06/27
description: Overriding the training step of the Model class with TensorFlow.
output: rmarkdown::html_vignette
vignette: >
%\VignetteIndexEntry{Customizing what happens in `fit()` with TensorFlow}
%\VignetteEngine{knitr::rmarkdown}
%\VignetteEncoding{UTF-8}
---
## Introduction
When you're doing supervised learning, you can use `fit()` and everything works
smoothly.
When you need to take control of every little detail, you can write your own training
loop entirely from scratch.
But what if you need a custom training algorithm, but you still want to benefit from
the convenient features of `fit()`, such as callbacks, built-in distribution support,
or step fusing?
A core principle of Keras is **progressive disclosure of complexity**. You should
always be able to get into lower-level workflows in a gradual way. You shouldn't fall
off a cliff if the high-level functionality doesn't exactly match your use case. You
should be able to gain more control over the small details while retaining a
commensurate amount of high-level convenience.
When you need to customize what `fit()` does, you should **override the training step
function of the `Model` class**. This is the function that is called by `fit()` for
every batch of data. You will then be able to call `fit()` as usual -- and it will be
running your own learning algorithm.
Note that this pattern does not prevent you from building models with the Functional
API. You can do this whether you're building `Sequential` models, Functional API
models, or subclassed models.
Let's see how that works.
## Setup
``` r
library(reticulate)
library(tensorflow, exclude = c("set_random_seed", "shape"))
library(keras3)
```
## A first simple example
Let's start from a simple example:
- We create a new class that subclasses `Model`.
- We just override the method `train_step(self, data)`.
- We return a dictionary mapping metric names (including the loss) to their current
value.
The input argument `data` is what gets passed to fit as training data:
- If you pass arrays, by calling `fit(x, y, ...)`, then `data` will be the list
`(x, y)`
- If you pass a `tf_dataset`, by calling `fit(dataset, ...)`, then `data` will be
what gets yielded by `dataset` at each batch.
In the body of the `train_step()` method, we implement a regular training update,
similar to what you are already familiar with. Importantly, **we compute the loss via
`self.compute_loss()`**, which wraps the loss(es) function(s) that were passed to
`compile()`.
Similarly, we call `metric$update_state(y, y_pred)` on metrics from `self$metrics`,
to update the state of the metrics that were passed in `compile()`,
and we query results from `self$metrics` at the end to retrieve their current value.
``` r
CustomModel <- new_model_class(
"CustomModel",
train_step = function(data) {
c(x, y = NULL, sample_weight = NULL) %<-% data
with(tf$GradientTape() %as% tape, {
y_pred <- self(x, training = TRUE)
loss <- self$compute_loss(y = y, y_pred = y_pred,
sample_weight = sample_weight)
})
# Compute gradients
trainable_vars <- self$trainable_variables
gradients <- tape$gradient(loss, trainable_vars)
# Update weights
self$optimizer$apply(gradients, trainable_vars)
# Update metrics (includes the metric that tracks the loss)
for (metric in self$metrics) {
if (metric$name == "loss")
metric$update_state(loss)
else
metric$update_state(y, y_pred)
}
# Return a dict mapping metric names to current value
metrics <- lapply(self$metrics, function(m) m$result())
metrics <- setNames(metrics, sapply(self$metrics, function(m) m$name))
metrics
}
)
```
Let's try this out:
``` r
# Construct and compile an instance of CustomModel
inputs <- keras_input(shape = 32)
outputs <- layer_dense(inputs, 1)
model <- CustomModel(inputs, outputs)
model |> compile(optimizer = "adam", loss = "mse", metrics = "mae")
# Just use `fit` as usual
x <- random_normal(c(1000, 32))
y <- random_normal(c(1000, 1))
model |> fit(x, y, epochs = 3)
```
```
## Epoch 1/3
## 32/32 - 1s - 29ms/step - mae: 1.4339 - loss: 3.2271
## Epoch 2/3
## 32/32 - 0s - 2ms/step - mae: 1.3605 - loss: 2.9034
## Epoch 3/3
## 32/32 - 0s - 2ms/step - mae: 1.2960 - loss: 2.6272
```
## Going lower-level
Naturally, you could just skip passing a loss function in `compile()`, and instead do
everything *manually* in `train_step`. Likewise for metrics.
Here's a lower-level example, that only uses `compile()` to configure the optimizer:
- We start by creating `Metric` instances to track our loss and a MAE score (in `__init__()`).
- We implement a custom `train_step()` that updates the state of these metrics
(by calling `update_state()` on them), then query them (via `result()`) to return their current average value,
to be displayed by the progress bar and to be pass to any callback.
- Note that we would need to call `reset_states()` on our metrics between each epoch! Otherwise
calling `result()` would return an average since the start of training, whereas we usually work
with per-epoch averages. Thankfully, the framework can do that for us: just list any metric
you want to reset in the `metrics` property of the model. The model will call `reset_states()`
on any object listed here at the beginning of each `fit()` epoch or at the beginning of a call to
`evaluate()`.
``` r
CustomModel <- new_model_class(
"CustomModel",
initialize = function(...) {
super$initialize(...)
self$loss_tracker <- metric_mean(name = "loss")
self$mae_metric <- metric_mean_absolute_error(name = "mae")
self$loss_fn <- loss_mean_squared_error()
},
train_step = function(data) {
c(x, y = NULL, sample_weight = NULL) %<-% data
with(tf$GradientTape() %as% tape, {
y_pred <- self(x, training = TRUE)
loss <- self$loss_fn(y, y_pred, sample_weight = sample_weight)
})
# Compute gradients
trainable_vars <- self$trainable_variables
gradients <- tape$gradient(loss, trainable_vars)
# Update weights
self$optimizer$apply(gradients, trainable_vars)
# Compute our own metrics
self$loss_tracker$update_state(loss)
self$mae_metric$update_state(y, y_pred)
# Return a dict mapping metric names to current value
list(
loss = self$loss_tracker$result(),
mae = self$mae_metric$result()
)
},
metrics = mark_active(function() {
# We list our `Metric` objects here so that `reset_states()` can be
# called automatically at the start of each epoch
# or at the start of `evaluate()`.
list(self$loss_tracker, self$mae_metric)
})
)
# Construct and compile an instance of CustomModel
inputs <- keras_input(shape = 32)
outputs <- layer_dense(inputs, 1)
model <- CustomModel(inputs, outputs)
# We don't pass a loss or metrics here.
model |> compile(optimizer = "adam")
# Just use `fit` as usual
x <- random_normal(c(1000, 32))
y <- random_normal(c(1000, 1))
model |> fit(x, y, epochs = 3)
```
```
## Epoch 1/3
## 32/32 - 1s - 20ms/step - loss: 2.5170 - mae: 1.2923
## Epoch 2/3
## 32/32 - 0s - 2ms/step - loss: 2.2689 - mae: 1.2241
## Epoch 3/3
## 32/32 - 0s - 2ms/step - loss: 2.0578 - mae: 1.1633
```
## Supporting `sample_weight` & `class_weight`
You may have noticed that our first basic example didn't make any mention of sample
weighting. If you want to support the `fit()` arguments `sample_weight` and
`class_weight`, you'd simply do the following:
- Unpack `sample_weight` from the `data` argument
- Pass it to `compute_loss` & `update_state` (of course, you could also just apply
it manually if you don't rely on `compile()` for losses & metrics)
- That's it.
``` r
CustomModel <- new_model_class(
"CustomModel",
train_step = function(data) {
c(x, y = NULL, sample_weight = NULL) %<-% data
with(tf$GradientTape() %as% tape, {
y_pred <- self(x, training = TRUE)
loss <- self$compute_loss(y = y, y_pred = y_pred,
sample_weight = sample_weight)
})
# Compute gradients
trainable_vars <- self$trainable_variables
gradients <- tape$gradient(loss, trainable_vars)
# Update weights
self$optimizer$apply_gradients(zip_lists(gradients, trainable_vars))
# Update metrics (includes the metric that tracks the loss)
for (metric in self$metrics) {
if (metric$name == "loss") {
metric$update_state(loss)
} else {
metric$update_state(y, y_pred, sample_weight = sample_weight)
}
}
# Return a dict mapping metric names to current value
metrics <- lapply(self$metrics, function(m) m$result())
metrics <- setNames(metrics, sapply(self$metrics, function(m) m$name))
metrics
}
)
# Construct and compile an instance of CustomModel
inputs <- keras_input(shape = 32)
outputs <- layer_dense(inputs, units = 1)
model <- CustomModel(inputs, outputs)
model |> compile(optimizer = "adam", loss = "mse", metrics = "mae")
# You can now use sample_weight argument
x <- random_normal(c(1000, 32))
y <- random_normal(c(1000, 1))
sw <- random_normal(c(1000, 1))
model |> fit(x, y, sample_weight = sw, epochs = 3)
```
```
## Epoch 1/3
## 32/32 - 1s - 28ms/step - mae: 1.3434 - loss: 0.1681
## Epoch 2/3
## 32/32 - 0s - 3ms/step - mae: 1.3364 - loss: 0.1394
## Epoch 3/3
## 32/32 - 0s - 3ms/step - mae: 1.3286 - loss: 0.1148
```
## Providing your own evaluation step
What if you want to do the same for calls to `model.evaluate()`? Then you would
override `test_step` in exactly the same way. Here's what it looks like:
``` r
CustomModel <- new_model_class(
"CustomModel",
test_step = function(data) {
# Unpack the data
c(x, y = NULL, sw = NULL) %<-% data
# Compute predictions
y_pred = self(x, training = FALSE)
# Updates the metrics tracking the loss
self$compute_loss(y = y, y_pred = y_pred, sample_weight = sw)
# Update the metrics.
for (metric in self$metrics) {
if (metric$name != "loss") {
metric$update_state(y, y_pred, sample_weight = sw)
}
}
# Return a dict mapping metric names to current value.
# Note that it will include the loss (tracked in self.metrics).
metrics <- lapply(self$metrics, function(m) m$result())
metrics <- setNames(metrics, sapply(self$metrics, function(m) m$name))
metrics
}
)
# Construct an instance of CustomModel
inputs <- keras_input(shape = 32)
outputs <- layer_dense(inputs, 1)
model <- CustomModel(inputs, outputs)
model |> compile(loss = "mse", metrics = "mae")
# Evaluate with our custom test_step
x <- random_normal(c(1000, 32))
y <- random_normal(c(1000, 1))
model |> evaluate(x, y)
```
```
## 32/32 - 0s - 9ms/step - mae: 1.3871 - loss: 0.0000e+00
```
```
## $loss
## tf.Tensor(0.0, shape=(), dtype=float32)
##
## $compile_metrics
## $compile_metrics$mae
## tf.Tensor(1.3871489, shape=(), dtype=float32)
```
## Wrapping up: an end-to-end GAN example
Let's walk through an end-to-end example that leverages everything you just learned.
Let's consider:
- A generator network meant to generate 28x28x1 images.
- A discriminator network meant to classify 28x28x1 images into two classes ("fake" and
"real").
- One optimizer for each.
- A loss function to train the discriminator.
``` r
# Create the discriminator
discriminator <-
keras_model_sequential(name = "discriminator", input_shape = c(28, 28, 1)) |>
layer_conv_2d(filters = 64, kernel_size = c(3, 3),
strides = c(2, 2), padding = "same") |>
layer_activation_leaky_relu(negative_slope = 0.2) |>
layer_conv_2d(filters = 128, kernel_size = c(3, 3),
strides = c(2, 2), padding = "same") |>
layer_activation_leaky_relu(negative_slope = 0.2) |>
layer_global_max_pooling_2d() |>
layer_dense(units = 1)
# Create the generator
latent_dim <- 128
generator <-
keras_model_sequential(name = "generator", input_shape = latent_dim) |>
layer_dense(7 * 7 * 128) |>
layer_activation_leaky_relu(negative_slope = 0.2) |>
layer_reshape(target_shape = c(7, 7, 128)) |>
layer_conv_2d_transpose(filters = 128, kernel_size = c(4, 4),
strides = c(2, 2), padding = "same") |>
layer_activation_leaky_relu(negative_slope = 0.2) |>
layer_conv_2d_transpose(filters = 128, kernel_size = c(4, 4),
strides = c(2, 2), padding = "same") |>
layer_activation_leaky_relu(negative_slope = 0.2) |>
layer_conv_2d(filters = 1, kernel_size = c(7, 7), padding = "same",
activation = "sigmoid")
```
Here's a feature-complete GAN class, overriding `compile()` to use its own signature,
and implementing the entire GAN algorithm in 17 lines in `train_step`:
``` r
GAN <- Model(
classname = "GAN",
initialize = function(discriminator, generator, latent_dim, ...) {
super$initialize(...)
self$discriminator <- discriminator
self$generator <- generator
self$latent_dim <- as.integer(latent_dim)
self$d_loss_tracker <- metric_mean(name = "d_loss")
self$g_loss_tracker <- metric_mean(name = "g_loss")
},
compile = function(d_optimizer, g_optimizer, loss_fn, ...) {
super$compile(...)
self$d_optimizer <- d_optimizer
self$g_optimizer <- g_optimizer
self$loss_fn <- loss_fn
},
metrics = active_property(function() {
list(self$d_loss_tracker, self$g_loss_tracker)
}),
train_step = function(real_images) {
# Sample random points in the latent space
batch_size <- shape(real_images)[[1]]
random_latent_vectors <-
tf$random$normal(shape(batch_size, self$latent_dim))
# Decode them to fake images
generated_images <- self$generator(random_latent_vectors)
# Combine them with real images
combined_images <- op_concatenate(list(generated_images,
real_images))
# Assemble labels discriminating real from fake images
labels <- op_concatenate(list(op_ones(c(batch_size, 1)),
op_zeros(c(batch_size, 1))))
# Add random noise to the labels - important trick!
labels %<>% `+`(tf$random$uniform(shape(.), maxval = 0.05))
# Train the discriminator
with(tf$GradientTape() %as% tape, {
predictions <- self$discriminator(combined_images)
d_loss <- self$loss_fn(labels, predictions)
})
grads <- tape$gradient(d_loss, self$discriminator$trainable_weights)
self$d_optimizer$apply_gradients(
zip_lists(grads, self$discriminator$trainable_weights))
# Sample random points in the latent space
random_latent_vectors <-
tf$random$normal(shape(batch_size, self$latent_dim))
# Assemble labels that say "all real images"
misleading_labels <- op_zeros(c(batch_size, 1))
# Train the generator (note that we should *not* update the weights
# of the discriminator)!
with(tf$GradientTape() %as% tape, {
predictions <- self$discriminator(self$generator(random_latent_vectors))
g_loss <- self$loss_fn(misleading_labels, predictions)
})
grads <- tape$gradient(g_loss, self$generator$trainable_weights)
self$g_optimizer$apply_gradients(
zip_lists(grads, self$generator$trainable_weights))
list(d_loss = d_loss, g_loss = g_loss)
}
)
```
Let's test-drive it:
``` r
batch_size <- 64
c(c(x_train, .), c(x_test, .)) %<-% dataset_mnist()
all_digits <- op_concatenate(list(x_train, x_test))
all_digits <- op_reshape(all_digits, c(-1, 28, 28, 1))
dataset <- all_digits |>
tfdatasets::tensor_slices_dataset() |>
tfdatasets::dataset_map(\(x) op_cast(x, "float32") / 255) |>
tfdatasets::dataset_shuffle(buffer_size = 1024) |>
tfdatasets::dataset_batch(batch_size = batch_size)
gan <- GAN(discriminator = discriminator,
generator = generator,
latent_dim = latent_dim)
gan |> compile(
d_optimizer = optimizer_adam(learning_rate = 0.0003),
g_optimizer = optimizer_adam(learning_rate = 0.0003),
loss_fn = loss_binary_crossentropy(from_logits = TRUE)
)
# To limit the execution time, we only train on 100 batches. You can train on
# the entire dataset. You will need about 20 epochs to get nice results.
gan |> fit(
tfdatasets::dataset_take(dataset, 100),
epochs = 1
)
```
```
## 100/100 - 6s - 57ms/step - d_loss: 0.0000e+00 - g_loss: 0.0000e+00
```
The ideas behind deep learning are simple, so why should their implementation be painful?