An implementation of multilayer perceptrons in PyTorch.
Project description
The nerva-jax library
NOTE: This page is a stub. The library has not yet been released!
This repository contains an implementation of multilayer perceptrons in JAX. It is part of a group of five Python packages that can be installed via pip:
- nerva-jax An implementation in JAX.
- nerva-numpy An implementation in NumPy.
- nerva-sympy An implementation in SymPy, used for validation and testing.
- nerva-tensorflow An implementation in TensorFlow.
- nerva-torch An implementation in PyTorch.
The packages can be installed standalone, except for nerva-sympy
which requires
installation of the other four. Each package has its own GitHub repository:
- https://github.com/wiegerw/nerva-jax
- https://github.com/wiegerw/nerva-numpy
- https://github.com/wiegerw/nerva-sympy
- https://github.com/wiegerw/nerva-tensorflow
- https://github.com/wiegerw/nerva-torch
Purpose
The main purpose of these repositories is on the practical implementation of neural networks. We aim to achieve the following goals:
- To provide precise mathematical specifications of the execution of multilayer perceptrons.
- To provide an overview of the equations for common layers, activation functions and loss functions.
- To provide easily understandable implementations that match the specifications closely.
An important advantage of our implementations is that they are fully transparent: even the implementation of backpropagation is provided in an accessible manner. Currently, the scope is limited to multilayer perceptrons. However, the approach can easily be generalized to more complex neural network architectures.
Documentation
TODO
Installation
The code is available as the PyPI package CONEstrip. It can be installed using
pip install nerva-jax
Licensing
The code is available under the Boost Software License 1.0. A local copy is included in the repository.
Using the library
Multilayer perceptrons
Our multilayer perceptron class has a straightforward implementation:
class MultilayerPerceptron(object):
def feedforward(self, X: Matrix) -> Matrix:
for layer in self.layers:
X = layer.feedforward(X)
return X
def backpropagate(self, Y: Matrix, DY: Matrix) -> None:
for layer in reversed(self.layers):
layer.backpropagate(Y, DY)
Y, DY = layer.X, layer.DX
def optimize(self, lr: float):
for layer in self.layers:
layer.optimize(lr)
A multilayer perceptron can be constructed like this:
M = MultilayerPerceptron()
input_size = 3072
output_size = 1024
act = AllReLUActivation(0.3)
layer = ActivationLayer(input_size, output_size, act)
layer.set_optimizer('Momentum(0.9)')
layer.set_weights('Xavier')
M.layers.append(layer)
...
An example of a layer is the softmax layer. Note that the feedforward and backpropagation implementations exactly match with the equations given in the documentation.
class SoftmaxLayer(LinearLayer):
def feedforward(self, X: Matrix) -> Matrix:
...
Z = W @ X + column_repeat(b, N)
Y = softmax_colwise(Z)
...
def backpropagate(self, Y: Matrix, DY: Matrix) -> None:
...
DZ = hadamard(Y, DY - row_repeat(diag(Y.T @ DY).T, K))
DW = DZ @ X.T
Db = rows_sum(DZ)
DX = W.T @ DZ
...
The gradients computed by backpropagation are used to update the parameters of the neural network using an optimizer. The user has full control over how to update them. The composite design pattern is used to achieve this:
optimizer_W = MomentumOptimizer(layer.W, layer.DW, 0.9)
optimizer_b = NesterovOptimizer(layer.b, layer.Db, 0.9)
layer.optimizer = CompositeOptimizer(optimizer_W, optimizer_b)
Here W
and b
are the weights and bias of a linear layer, and DW
and
Db
are the gradients of these parameters with respect to the loss function.
Other parameters can be learned as well, see for example the SReLU layer.
Training
For training of an MLP we provide an implementation of stochastic gradient descent
in the file training.py
that looks like this:
def stochastic_gradient_descent(M: MultilayerPerceptron,
epochs: int,
loss: LossFunction,
learning_rate: LearningRateScheduler,
train_loader: DataLoader):
for epoch in range(epochs):
lr = learning_rate(epoch)
for (X, T) in train_loader:
Y = M.feedforward(X)
DY = loss.gradient(Y, T) / Y.shape[0] # divide by the number of examples
M.backpropagate(Y, DY)
M.optimize(lr)
Here train_loader
is an object similar to a DataLoader
in PyTorch that splits
a dataset into batches of inputs X
and expected outputs T
.
Training of an MLP consists of three steps:
- feedforward Given an input batch
X
and expected outputsT
, compute the outputY
. - backpropagation Given outputs
Y
and expected outputsT
, compute the gradient of the MLP parameters with respect to a given loss functionL
. - optimization Update the MLP parameters using the gradient computed in step 2.
These steps are performed for each input batch of a dataset, and this process is
repeated epoch
times.
Command line script
For convenience, a command line script tools/mlp.py
is included that can be
used to do a training experiment. An example invocation of this script is
provided in examples/cifar10.sh
:
mlp.py --layers="ReLU;ReLU;Linear" \
--sizes="3072,1024,512,10" \
--optimizers="Momentum(0.9);Momentum(0.9);Momentum(0.9)" \
--init-weights="Xavier,Xavier,Xavier" \
--batch-size=100 \
--epochs=10 \
--loss=SoftmaxCrossEntropy \
--learning-rate="Constant(0.01)" \
--dataset="cifar10.npz"
The output of this script may look like this:
$ ./cifar10.sh
Loading dataset from file ../data/cifar10.npz
epoch 0 lr: 0.01000000 loss: 2.49815798 train accuracy: 0.10048000 test accuracy: 0.10110000 time: 0.00000000s
epoch 1 lr: 0.01000000 loss: 1.64330590 train accuracy: 0.41250000 test accuracy: 0.40890000 time: 11.27521224s
epoch 2 lr: 0.01000000 loss: 1.54620886 train accuracy: 0.44674000 test accuracy: 0.43910000 time: 11.33507117s
epoch 3 lr: 0.01000000 loss: 1.46849191 train accuracy: 0.47462000 test accuracy: 0.46280000 time: 11.30941587s
epoch 4 lr: 0.01000000 loss: 1.40283990 train accuracy: 0.49964000 test accuracy: 0.48370000 time: 11.30728618s
epoch 5 lr: 0.01000000 loss: 1.36808932 train accuracy: 0.51214000 test accuracy: 0.49030000 time: 11.32811917s
epoch 6 lr: 0.01000000 loss: 1.33309329 train accuracy: 0.52786000 test accuracy: 0.49490000 time: 11.27888232s
epoch 7 lr: 0.01000000 loss: 1.31322646 train accuracy: 0.53440000 test accuracy: 0.49800000 time: 11.29106200s
epoch 8 lr: 0.01000000 loss: 1.29327416 train accuracy: 0.53940000 test accuracy: 0.49850000 time: 11.42966828s
epoch 9 lr: 0.01000000 loss: 1.27069771 train accuracy: 0.55052000 test accuracy: 0.50120000 time: 11.30879241s
epoch 10 lr: 0.01000000 loss: 1.24060512 train accuracy: 0.56160000 test accuracy: 0.50690000 time: 11.42121017s
Total training time for the 10 epochs: 113.28471981s
Validation
We do not rely on auto differentiation for the backpropagation. Instead, we provide
explicit implementations for it. Since the derivation of these equations is
error-prone, the results have to be validated. A common way to do this is to
rely on gradient checking using numerical approximations. Instead, we are using
symbolic differentation of SymPy. This is provided in the nerva-sympy
package.
Gradient checking of the softmax layer looks like this:
# backpropagation
DZ = hadamard(Y, DY - row_repeat(diag(Y.T * DY).T, K))
DW = DZ * X.T
Db = rows_sum(DZ)
DX = W.T * DZ
# check gradients using symbolic differentiation
DW1 = diff(loss(Y), w)
Db1 = diff(loss(Y), b)
DX1 = diff(loss(Y), x)
DZ1 = diff(loss(Y), z)
self.assertTrue(equal_matrices(DW, DW1))
self.assertTrue(equal_matrices(Db, Db1))
self.assertTrue(equal_matrices(DX, DX1))
self.assertTrue(equal_matrices(DZ, DZ1))
An advantage of this approach is that errors can be found in an early stage. Moreover, the source of such errors can be detected by checking intermediate results.
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