Get a taste of protocol-oriented differentiable programming.
This repository hosts Swift for TensorFlow's deep learning library, available both as a part of Swift for TensorFlow toolchains and as a Swift package.
This library is being automatically integrated in Swift for TensorFlow toolchains. You do not need to add this library as a Swift Package Manager dependency.
Open an empty Colaboratory now to try out Swift, TensorFlow, differentiable programming, and deep learning.
For detailed usage and troubleshooting, see Usage on the Swift for TensorFlow project homepage.
Simply import TensorFlow
to get the full power of TensorFlow.
import TensorFlow
let hiddenSize: Int = 10
struct Model: Layer {
var layer1 = Dense<Float>(inputSize: 4, outputSize: hiddenSize, activation: relu)
var layer2 = Dense<Float>(inputSize: hiddenSize, outputSize: hiddenSize, activation: relu)
var layer3 = Dense<Float>(inputSize: hiddenSize, outputSize: 3, activation: identity)
@differentiable
func callAsFunction(_ input: Tensor<Float>) -> Tensor<Float> {
return input.sequenced(through: layer1, layer2, layer3)
}
}
var classifier = Model()
let optimizer = SGD(for: classifier, learningRate: 0.02)
Context.local.learningPhase = .training
// Dummy data.
let x: Tensor<Float> = Tensor(randomNormal: [100, 4])
let y: Tensor<Int32> = Tensor(randomUniform: [100])
One way to define a training epoch is to use the
gradient(at:in:)
function.
for _ in 0..<1000 {
let 𝛁model = gradient(at: classifier) { classifier -> Tensor<Float> in
let ŷ = classifier(x)
let loss = softmaxCrossEntropy(logits: ŷ, labels: y)
print("Loss: \(loss)")
return loss
}
optimizer.update(&classifier, along: 𝛁model)
}
Another way is to make use of methods on Differentiable
or Layer
that
produce a backpropagation function. This allows you to compose your derivative
computation with great flexibility.
for _ in 0..<1000 {
let (ŷ, backprop) = classifier.appliedForBackpropagation(to: x)
let (loss, 𝛁ŷ) = valueWithGradient(at: ŷ) { ŷ in softmaxCrossEntropy(logits: ŷ, labels: y) }
print("Model output: \(ŷ), Loss: \(loss)")
let (𝛁model, _) = backprop(𝛁ŷ)
optimizer.update(&classifier, along: 𝛁model)
}
For more models, go to tensorflow/swift-models.
Documentation covering development can be found in the Developer Guide.
Please report bugs and feature requests using GitHub issues in this repository.
Discussion about Swift for TensorFlow happens on the [email protected] mailing list.
We welcome contributions: please read the Contributor Guide to get started. It's always a good idea to discuss your plans on the mailing list before making any major submissions.
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