Training a Simple LSTM
In this tutorial we will go over using a recurrent neural network to classify clockwise and anticlockwise spirals. By the end of this tutorial you will be able to:
Create custom Lux models.
Become familiar with the Lux recurrent neural network API.
Training using Optimisers.jl and Zygote.jl.
Package Imports
Note: If you wish to use AutoZygote() for automatic differentiation, add Zygote to your project dependencies and include using Zygote.
julia
using ADTypes, Lux, JLD2, MLUtils, Optimisers, Printf, Reactant, RandomDataset
We will use MLUtils to generate 500 (noisy) clockwise and 500 (noisy) anticlockwise spirals. Using this data we will create a MLUtils.DataLoader. Our dataloader will give us sequences of size 2 × seq_len × batch_size and we need to predict a binary value whether the sequence is clockwise or anticlockwise.
julia
function create_dataset(; dataset_size=1000, sequence_length=50)
# Create the spirals
data = [MLUtils.Datasets.make_spiral(sequence_length) for _ in 1:dataset_size]
# Get the labels
labels = vcat(repeat([0.0f0], dataset_size ÷ 2), repeat([1.0f0], dataset_size ÷ 2))
clockwise_spirals = [
reshape(d[1][:, 1:sequence_length], :, sequence_length, 1) for
d in data[1:(dataset_size ÷ 2)]
]
anticlockwise_spirals = [
reshape(d[1][:, (sequence_length + 1):end], :, sequence_length, 1) for
d in data[((dataset_size ÷ 2) + 1):end]
]
x_data = Float32.(cat(clockwise_spirals..., anticlockwise_spirals...; dims=3))
return x_data, labels
end
function get_dataloaders(; dataset_size=1000, sequence_length=50)
x_data, labels = create_dataset(; dataset_size, sequence_length)
# Split the dataset
(x_train, y_train), (x_val, y_val) = splitobs((x_data, labels); at=0.8, shuffle=true)
# Create DataLoaders
return (
# Use DataLoader to automatically minibatch and shuffle the data
DataLoader(
collect.((x_train, y_train)); batchsize=128, shuffle=true, partial=false
),
# Don't shuffle the validation data
DataLoader(collect.((x_val, y_val)); batchsize=128, shuffle=false, partial=false),
)
endCreating a Classifier
We will be extending the Lux.AbstractLuxContainerLayer type for our custom model since it will contain a LSTM block and a classifier head.
We pass the field names lstm_cell and classifier to the type to ensure that the parameters and states are automatically populated and we don't have to define Lux.initialparameters and Lux.initialstates.
To understand more about container layers, please look at Container Layer.
julia
struct SpiralClassifier{L,C} <: AbstractLuxContainerLayer{(:lstm_cell, :classifier)}
lstm_cell::L
classifier::C
endWe won't define the model from scratch but rather use the Lux.LSTMCell and Lux.Dense.
julia
function SpiralClassifier(in_dims, hidden_dims, out_dims)
return SpiralClassifier(
LSTMCell(in_dims => hidden_dims), Dense(hidden_dims => out_dims, sigmoid)
)
endWe can use default Lux blocks – Recurrence(LSTMCell(in_dims => hidden_dims) – instead of defining the following. But let's still do it for the sake of it.
Now we need to define the behavior of the Classifier when it is invoked.
julia
function (s::SpiralClassifier)(
x::AbstractArray{T,3}, ps::NamedTuple, st::NamedTuple
) where {T}
# First we will have to run the sequence through the LSTM Cell
# The first call to LSTM Cell will create the initial hidden state
# See that the parameters and states are automatically populated into a field called
# `lstm_cell` We use `eachslice` to get the elements in the sequence without copying,
# and `Iterators.peel` to split out the first element for LSTM initialization.
x_init, x_rest = Iterators.peel(LuxOps.eachslice(x, Val(2)))
(y, carry), st_lstm = s.lstm_cell(x_init, ps.lstm_cell, st.lstm_cell)
# Now that we have the hidden state and memory in `carry` we will pass the input and
# `carry` jointly
for x in x_rest
(y, carry), st_lstm = s.lstm_cell((x, carry), ps.lstm_cell, st_lstm)
end
# After running through the sequence we will pass the output through the classifier
y, st_classifier = s.classifier(y, ps.classifier, st.classifier)
# Finally remember to create the updated state
st = merge(st, (classifier=st_classifier, lstm_cell=st_lstm))
return vec(y), st
endUsing the @compact API
We can also define the model using the Lux.@compact API, which is a more concise way of defining models. This macro automatically handles the boilerplate code for you and as such we recommend this way of defining custom layers
julia
function SpiralClassifierCompact(in_dims, hidden_dims, out_dims)
return @compact(;
lstm_cell=LSTMCell(in_dims => hidden_dims),
classifier=Dense(hidden_dims => out_dims, sigmoid)
) do x::AbstractArray{T,3} where {T}
x_init, x_rest = Iterators.peel(LuxOps.eachslice(x, Val(2)))
y, carry = lstm_cell(x_init)
for x in x_rest
y, carry = lstm_cell((x, carry))
end
@return vec(classifier(y))
end
endDefining Accuracy, Loss and Optimiser
Now let's define the binary cross-entropy loss. Typically it is recommended to use logitbinarycrossentropy since it is more numerically stable, but for the sake of simplicity we will use binarycrossentropy.
julia
const lossfn = BinaryCrossEntropyLoss()
function compute_loss(model, ps, st, (x, y))
ŷ, st_ = model(x, ps, st)
loss = lossfn(ŷ, y)
return loss, st_, (; y_pred=ŷ)
end
matches(y_pred, y_true) = sum((y_pred .> 0.5f0) .== y_true)
accuracy(y_pred, y_true) = matches(y_pred, y_true) / length(y_pred)Training the Model
julia
function main(model_type)
dev = reactant_device()
cdev = cpu_device()
# Get the dataloaders
train_loader, val_loader = get_dataloaders() |> dev
# Create the model
model = model_type(2, 8, 1)
ps, st = Lux.setup(Random.default_rng(), model) |> dev
train_state = Training.TrainState(model, ps, st, Adam(0.01f0))
model_compiled = if dev isa ReactantDevice
@compile model(first(train_loader)[1], ps, Lux.testmode(st))
else
model
end
ad = dev isa ReactantDevice ? AutoReactant() : AutoZygote()
for epoch in 1:25
# Train the model
total_loss = 0.0f0
total_samples = 0
for (x, y) in train_loader
(_, loss, _, train_state) = Training.single_train_step!(
ad, lossfn, (x, y), train_state
)
total_loss += loss * length(y)
total_samples += length(y)
end
@printf("Epoch [%3d]: Loss %4.5f\n", epoch, total_loss / total_samples)
# Validate the model
total_acc = 0.0f0
total_loss = 0.0f0
total_samples = 0
st_ = Lux.testmode(train_state.states)
for (x, y) in val_loader
ŷ, st_ = model_compiled(x, train_state.parameters, st_)
ŷ, y = cdev(ŷ), cdev(y)
total_acc += accuracy(ŷ, y) * length(y)
total_loss += lossfn(ŷ, y) * length(y)
total_samples += length(y)
end
@printf(
"Validation:\tLoss %4.5f\tAccuracy %4.5f\n",
total_loss / total_samples,
total_acc / total_samples
)
end
return (train_state.parameters, train_state.states) |> cdev
end
ps_trained, st_trained = main(SpiralClassifier)┌ Warning: `replicate` doesn't work for `TaskLocalRNG`. Returning the same `TaskLocalRNG`.
└ @ LuxCore ~/work/Lux.jl/Lux.jl/lib/LuxCore/src/LuxCore.jl:18
┌ Warning: You are using code generated by an older version of ProtoBuf.jl, which was deprecated. Please regenerate your protobuf definitions with the current version of ProtoBuf.jl. The new version will allow for defining custom AbstractProtoDecoder variants. This warning is only printed once per session.
└ @ ProtoBuf.Codecs ~/.julia/packages/ProtoBuf/85REE/src/codec/decode.jl:194
Epoch [ 1]: Loss 0.71583
Validation: Loss 0.64015 Accuracy 0.70312
Epoch [ 2]: Loss 0.58941
Validation: Loss 0.52401 Accuracy 1.00000
Epoch [ 3]: Loss 0.48436
Validation: Loss 0.41896 Accuracy 1.00000
Epoch [ 4]: Loss 0.37822
Validation: Loss 0.31871 Accuracy 1.00000
Epoch [ 5]: Loss 0.29578
Validation: Loss 0.25745 Accuracy 1.00000
Epoch [ 6]: Loss 0.23930
Validation: Loss 0.20704 Accuracy 1.00000
Epoch [ 7]: Loss 0.19130
Validation: Loss 0.16395 Accuracy 1.00000
Epoch [ 8]: Loss 0.15027
Validation: Loss 0.12868 Accuracy 1.00000
Epoch [ 9]: Loss 0.11825
Validation: Loss 0.09970 Accuracy 1.00000
Epoch [ 10]: Loss 0.09159
Validation: Loss 0.07773 Accuracy 1.00000
Epoch [ 11]: Loss 0.07272
Validation: Loss 0.06244 Accuracy 1.00000
Epoch [ 12]: Loss 0.05927
Validation: Loss 0.05194 Accuracy 1.00000
Epoch [ 13]: Loss 0.04980
Validation: Loss 0.04436 Accuracy 1.00000
Epoch [ 14]: Loss 0.04313
Validation: Loss 0.03862 Accuracy 1.00000
Epoch [ 15]: Loss 0.03798
Validation: Loss 0.03417 Accuracy 1.00000
Epoch [ 16]: Loss 0.03370
Validation: Loss 0.03054 Accuracy 1.00000
Epoch [ 17]: Loss 0.03008
Validation: Loss 0.02748 Accuracy 1.00000
Epoch [ 18]: Loss 0.02680
Validation: Loss 0.02409 Accuracy 1.00000
Epoch [ 19]: Loss 0.02229
Validation: Loss 0.01819 Accuracy 1.00000
Epoch [ 20]: Loss 0.01595
Validation: Loss 0.01218 Accuracy 1.00000
Epoch [ 21]: Loss 0.01034
Validation: Loss 0.00896 Accuracy 1.00000
Epoch [ 22]: Loss 0.00822
Validation: Loss 0.00769 Accuracy 1.00000
Epoch [ 23]: Loss 0.00714
Validation: Loss 0.00682 Accuracy 1.00000
Epoch [ 24]: Loss 0.00636
Validation: Loss 0.00613 Accuracy 1.00000
Epoch [ 25]: Loss 0.00581
Validation: Loss 0.00561 Accuracy 1.00000We can also train the compact model with the exact same code!
julia
ps_trained2, st_trained2 = main(SpiralClassifierCompact)┌ Warning: `replicate` doesn't work for `TaskLocalRNG`. Returning the same `TaskLocalRNG`.
└ @ LuxCore ~/work/Lux.jl/Lux.jl/lib/LuxCore/src/LuxCore.jl:18
Epoch [ 1]: Loss 0.77134
Validation: Loss 0.60913 Accuracy 0.53125
Epoch [ 2]: Loss 0.54649
Validation: Loss 0.43598 Accuracy 1.00000
Epoch [ 3]: Loss 0.37718
Validation: Loss 0.30647 Accuracy 1.00000
Epoch [ 4]: Loss 0.26789
Validation: Loss 0.21552 Accuracy 1.00000
Epoch [ 5]: Loss 0.18781
Validation: Loss 0.15210 Accuracy 1.00000
Epoch [ 6]: Loss 0.13776
Validation: Loss 0.11700 Accuracy 1.00000
Epoch [ 7]: Loss 0.10731
Validation: Loss 0.09276 Accuracy 1.00000
Epoch [ 8]: Loss 0.08600
Validation: Loss 0.07551 Accuracy 1.00000
Epoch [ 9]: Loss 0.07019
Validation: Loss 0.06240 Accuracy 1.00000
Epoch [ 10]: Loss 0.05839
Validation: Loss 0.05239 Accuracy 1.00000
Epoch [ 11]: Loss 0.04939
Validation: Loss 0.04478 Accuracy 1.00000
Epoch [ 12]: Loss 0.04260
Validation: Loss 0.03888 Accuracy 1.00000
Epoch [ 13]: Loss 0.03711
Validation: Loss 0.03419 Accuracy 1.00000
Epoch [ 14]: Loss 0.03277
Validation: Loss 0.03039 Accuracy 1.00000
Epoch [ 15]: Loss 0.02920
Validation: Loss 0.02725 Accuracy 1.00000
Epoch [ 16]: Loss 0.02627
Validation: Loss 0.02462 Accuracy 1.00000
Epoch [ 17]: Loss 0.02381
Validation: Loss 0.02237 Accuracy 1.00000
Epoch [ 18]: Loss 0.02164
Validation: Loss 0.02043 Accuracy 1.00000
Epoch [ 19]: Loss 0.01982
Validation: Loss 0.01874 Accuracy 1.00000
Epoch [ 20]: Loss 0.01823
Validation: Loss 0.01726 Accuracy 1.00000
Epoch [ 21]: Loss 0.01680
Validation: Loss 0.01596 Accuracy 1.00000
Epoch [ 22]: Loss 0.01552
Validation: Loss 0.01481 Accuracy 1.00000
Epoch [ 23]: Loss 0.01444
Validation: Loss 0.01378 Accuracy 1.00000
Epoch [ 24]: Loss 0.01346
Validation: Loss 0.01285 Accuracy 1.00000
Epoch [ 25]: Loss 0.01255
Validation: Loss 0.01201 Accuracy 1.00000Saving the Model
We can save the model using JLD2 (and any other serialization library of your choice) Note that we transfer the model to CPU before saving. Additionally, we recommend that you don't save the model struct and only save the parameters and states.
julia
@save "trained_model.jld2" ps_trained st_trainedLet's try loading the model
julia
@load "trained_model.jld2" ps_trained st_trained2-element Vector{Symbol}:
:ps_trained
:st_trainedAppendix
julia
using InteractiveUtils
InteractiveUtils.versioninfo()
if @isdefined(MLDataDevices)
if @isdefined(CUDA) && MLDataDevices.functional(CUDADevice)
println()
CUDA.versioninfo()
end
if @isdefined(AMDGPU) && MLDataDevices.functional(AMDGPUDevice)
println()
AMDGPU.versioninfo()
end
endJulia Version 1.12.5
Commit 5fe89b8ddc1 (2026-02-09 16:05 UTC)
Build Info:
Official https://julialang.org release
Platform Info:
OS: Linux (x86_64-linux-gnu)
CPU: 4 × Intel(R) Xeon(R) Platinum 8370C CPU @ 2.80GHz
WORD_SIZE: 64
LLVM: libLLVM-18.1.7 (ORCJIT, icelake-server)
GC: Built with stock GC
Threads: 4 default, 1 interactive, 4 GC (on 4 virtual cores)
Environment:
JULIA_DEBUG = Literate
LD_LIBRARY_PATH =
JULIA_NUM_THREADS = 4
JULIA_CPU_HARD_MEMORY_LIMIT = 100%
JULIA_PKG_PRECOMPILE_AUTO = 0This page was generated using Literate.jl.