forked from kscience/kmath
262 lines
7.8 KiB
Markdown
262 lines
7.8 KiB
Markdown
# Module kmath-noa
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A general purpose differentiable programming library over
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[NOA](https://github.com/grinisrit/noa.git)
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together with relevant functionality from
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[LibTorch](https://pytorch.org/cppdocs).
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Our aim is to cover a wide set of applications
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from bayesian computation and deep learning to particle physics
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simulations. In fact, we support any
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differentiable program written on top of
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`AutoGrad` & `ATen`.
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## Installation from source
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Currently, we support only the linux platform for the native artifacts.
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For `GPU` kernels, we require a compatible
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[CUDA](https://docs.nvidia.com/cuda/cuda-installation-guide-linux/index.html)
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installation. If you are on Windows, we recommend setting up
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everything on [WSL](https://docs.nvidia.com/cuda/wsl-user-guide/index.html).
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To install the library, you can simply publish `KMath` to the local
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Maven repository:
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```
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$ ./gradlew -Dorg.gradle.java.home=/path/to/local/jdk -q publishToMavenLocal
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```
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This will fetch and build the `JNI` wrapper `jnoa`.
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In your own application add the local dependency:
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```kotlin
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repositories {
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mavenCentral()
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mavenLocal()
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}
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dependencies {
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implementation("space.kscience:kmath-noa:0.3.0-dev-14")
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}
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```
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To load the native library you will need to add to the VM options:
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```
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-Djava.library.path=${HOME}/.konan/third-party/noa-v0.0.1/cpp-build/jnoa
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```
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## Usage
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The library is under active development. Many more features
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will be available soon.
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### Tensors and Linear Algebra
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We implement the tensor algebra interfaces
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from [kmath-tensors](../kmath-tensors):
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```kotlin
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NoaFloat {
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val tensor =
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randNormal(
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shape = intArrayOf(7, 5, 3),
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device = Device.CPU) // or Device.CUDA(0) for GPU
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// Compute SVD
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val (tensorU, tensorS, tensorV) = tensor.svd()
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// Reconstruct tensor
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val tensorReg =
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tensorU dot (diagonalEmbedding(tensorS) dot tensorV.transpose(-2, -1))
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// Serialise tensor for later
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tensorReg.save("tensorReg.pt")
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}
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```
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The saved tensor can be loaded in `C++` or in `python`:
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```python
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import torch
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tensor_reg = list(torch.jit.load('tensorReg.pt').parameters())[0]
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```
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The most efficient way passing data between the `JVM` and the native backend
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is to rely on primitive arrays:
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```kotlin
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val array = (1..8).map { 100f * it }.toFloatArray()
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val updateArray = floatArrayOf(15f, 20f)
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val resArray = NoaFloat {
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val tensor = copyFromArray(array, intArrayOf(2, 2, 2))
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NoaFloat {
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// The call `tensor[0]` creates a native tensor instance pointing to a slice of `tensor`
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// The second call `[1]` is a setter call and does not create any new instances
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tensor[0][1] = updateArray
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// The instance `tensor[0]` is destroyed as we move out of the scope
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}!! // if the computation fails the result fill be null
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tensor.copyToArray()
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// the instance `tensor` is destroyed here
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}!!
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```
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### Automatic Differentiation
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The [AutoGrad](https://pytorch.org/tutorials/beginner/blitz/autograd_tutorial.html)
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engine is exposed:
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```kotlin
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NoaFloat {
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// Create a quadratic function
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val dim = 3
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val tensorX = randNormal(shape = intArrayOf(dim))
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val randFeatures = randNormal(shape = intArrayOf(dim, dim))
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val tensorSigma = randFeatures + randFeatures.transpose(0, 1)
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val tensorMu = randNormal(shape = intArrayOf(dim))
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// Create a differentiable expression
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val expressionAtX = withGradAt(tensorX) { x ->
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0.5f * (x dot (tensorSigma dot x)) + (tensorMu dot x) + 25.9f
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}
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// Evaluate the gradient at tensorX
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// retaining the graph for the hessian computation
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val gradientAtX = expressionAtX.autoGradient(tensorX, retainGraph = true)
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// Compute the hessian at tensorX
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val hessianAtX = expressionAtX.autoHessian(tensorX)
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}
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```
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### Deep Learning
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You can train any [TorchScript](https://pytorch.org/docs/stable/jit.html) model.
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For example, you can build in `python` the following neural network
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and prepare the training data:
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```python
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import torch
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n_tr = 7
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n_val = 300
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x_val = torch.linspace(-5, 5, n_val).view(-1, 1)
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y_val = torch.sin(x_val)
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x_train = torch.linspace(-3.14, 3.14, n_tr).view(-1, 1)
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y_train = torch.sin(x_train) + torch.randn_like(x_train) * 0.1
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class Data(torch.nn.Module):
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def __init__(self):
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super(Data, self).__init__()
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self.register_buffer('x_val', x_val)
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self.register_buffer('y_val', y_val)
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self.register_buffer('x_train', x_train)
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self.register_buffer('y_train', y_train)
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class Net(torch.nn.Module):
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def __init__(self):
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super(Net, self).__init__()
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self.l1 = torch.nn.Linear(1, 10, bias = True)
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self.l2 = torch.nn.Linear(10, 10, bias = True)
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self.l3 = torch.nn.Linear(10, 1, bias = True)
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def forward(self, x):
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x = self.l1(x)
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x = torch.relu(x)
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x = self.l2(x)
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x = torch.relu(x)
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x = self.l3(x)
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return x
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class Loss(torch.nn.Module):
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def __init__(self, target):
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super(Loss, self).__init__()
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self.register_buffer('target', target)
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self.loss = torch.nn.MSELoss()
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def forward(self, x):
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return self.loss(x, self.target)
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# Generate TorchScript modules and serialise them
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torch.jit.script(Data()).save('data.pt')
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torch.jit.script(Net()).save('net.pt')
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torch.jit.script(Loss(y_train)).save('loss.pt')
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```
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You can then load the modules into `kotlin` and train them:
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```kotlin
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NoaFloat {
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// Load the serialised JIT modules
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// The training data
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val dataModule = loadJitModule("data.pt")
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// The DL model
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val netModule = loadJitModule("net.pt")
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// The loss function
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val lossModule = loadJitModule("loss.pt")
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// Get the tensors from the module
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val xTrain = dataModule.getBuffer("x_train")
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val yTrain = dataModule.getBuffer("y_train")
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val xVal = dataModule.getBuffer("x_val")
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val yVal = dataModule.getBuffer("y_val")
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// Set the model in training mode
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netModule.train(true)
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// Loss function for training
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lossModule.setBuffer("target", yTrain)
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// Compute the predictions
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val yPred = netModule.forward(xTrain)
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// Compute the training loss
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val loss = lossModule.forward(yPred)
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println(loss)
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// Set-up the Adam optimiser with learning rate 0.005
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val optimiser = netModule.adamOptimiser(0.005)
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// Train for 250 epochs
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repeat(250){
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// Clean gradients
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optimiser.zeroGrad()
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// Use forwardAssign to for better memory management
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netModule.forwardAssign(xTrain, yPred)
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lossModule.forwardAssign(yPred, loss)
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// Backward pass
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loss.backward()
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// Update model parameters
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optimiser.step()
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if(it % 50 == 0)
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println("Training loss: $loss")
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}
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// Finally validate the model
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// Compute the predictions for the validation features
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netModule.forwardAssign(xVal, yPred)
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// Set the loss for validation
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lossModule.setBuffer("target", yVal)
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// Compute the loss on validation dataset
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lossModule.forwardAssign(yPred, loss)
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println("Validation loss: $loss")
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// The model can be serialised in its current state
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netModule.save("trained_net.pt")
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}
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```
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### Custom memory management
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Native memory management relies on scoping
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with [NoaScope](src/main/kotlin/space/kscience/kmath/noa/memory/NoaScope.kt)
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which is readily available within an algebra context.
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Manual management is also possible:
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```kotlin
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// Create a scope
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val scope = NoaScope()
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val tensor = NoaFloat(scope){
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full(5f, intArrayOf(1))
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}!! // the result might be null
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// If the computation fails resources will be freed automatically
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// Otherwise it's your responsibility:
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scope.disposeAll()
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// Attempts to use tensor here is undefined behaviour
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```
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For more examples have a look at
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[NOA](https://github.com/grinisrit/noa) docs.
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Contributed by [Roland Grinis](https://github.com/grinisrit)
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