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    Click :ref:`here <sphx_glr_download_beginner_basics_buildmodel_tutorial.py>` to download the full example code
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.. _sphx_glr_beginner_basics_buildmodel_tutorial.py:


`Learn the Basics <intro.html>`_ ||
`Quickstart <quickstart_tutorial.html>`_ || 
`Tensors <tensorqs_tutorial.html>`_ ||
`Datasets & DataLoaders <data_tutorial.html>`_ ||
`Transforms <transforms_tutorial.html>`_ ||
**Build Model** ||
`Autograd <autogradqs_tutorial.html>`_ ||
`Optimization <optimization_tutorial.html>`_ ||
`Save & Load Model <saveloadrun_tutorial.html>`_

Build the Neural Network
===================

Neural networks comprise of layers/modules that perform operations on data. 
The `torch.nn <https://pytorch.org/docs/stable/nn.html>`_ namespace provides all the building blocks you need to 
build your own neural network. Every module in PyTorch subclasses the `nn.Module <https://pytorch.org/docs/stable/generated/torch.nn.Module.html>`_. 
A neural network is a module itself that consists of other modules (layers). This nested structure allows for
building and managing complex architectures easily.

In the following sections, we'll build a neural network to classify images in the FashionMNIST dataset.



.. code-block:: default


    import os
    import torch
    from torch import nn
    from torch.utils.data import DataLoader
    from torchvision import datasets, transforms



Get Device for Training
-----------------------
We want to be able to train our model on a hardware accelerator like the GPU, 
if it is available. Let's check to see if 
`torch.cuda <https://pytorch.org/docs/stable/notes/cuda.html>`_ is available, else we 
continue to use the CPU. 


.. code-block:: default


    device = 'cuda' if torch.cuda.is_available() else 'cpu'
    print('Using {} device'.format(device))


Define the Class
-------------------------
We define our neural network by subclassing ``nn.Module``, and 
initialize the neural network layers in ``__init__``. Every ``nn.Module`` subclass implements
the operations on input data in the ``forward`` method. 


.. code-block:: default


    class NeuralNetwork(nn.Module):
        def __init__(self):
            super(NeuralNetwork, self).__init__()
            self.flatten = nn.Flatten()
            self.linear_relu_stack = nn.Sequential(
                nn.Linear(28*28, 512),
                nn.ReLU(),
                nn.Linear(512, 512),
                nn.ReLU(),
                nn.Linear(512, 10),
                nn.ReLU()
            )

        def forward(self, x):
            x = self.flatten(x)
            logits = self.linear_relu_stack(x)
            return logits


We create an instance of ``NeuralNetwork``, and move it to the ``device``, and print 
its structure.


.. code-block:: default


    model = NeuralNetwork().to(device)
    print(model)



To use the model, we pass it the input data. This executes the model's ``forward``,
along with some `background operations <https://github.com/pytorch/pytorch/blob/270111b7b611d174967ed204776985cefca9c144/torch/nn/modules/module.py#L866>`_. 
Do not call ``model.forward()`` directly!

Calling the model on the input returns a 10-dimensional tensor with raw predicted values for each class.
We get the prediction probabilities by passing it through an instance of the ``nn.Softmax`` module.


.. code-block:: default


    X = torch.rand(1, 28, 28, device=device)
    logits = model(X) 
    pred_probab = nn.Softmax(dim=1)(logits)
    y_pred = pred_probab.argmax(1)
    print(f"Predicted class: {y_pred}")



--------------


Model Layers
-------------------------

Lets break down the layers in the FashionMNIST model. To illustrate it, we 
will take a sample minibatch of 3 images of size 28x28 and see what happens to it as 
we pass it through the network. 


.. code-block:: default


    input_image = torch.rand(3,28,28)
    print(input_image.size())


nn.Flatten
^^^^^^^^^^^^^^^^^^^^^^
We initialize the `nn.Flatten  <https://pytorch.org/docs/stable/generated/torch.nn.Flatten.html>`_ 
layer to convert each 2D 28x28 image into a contiguous array of 784 pixel values (
the minibatch dimension (at dim=0) is maintained).


.. code-block:: default

 
    flatten = nn.Flatten()
    flat_image = flatten(input_image)
    print(flat_image.size())


nn.Linear 
^^^^^^^^^^^^^^^^^^^^^^
The `linear layer <https://pytorch.org/docs/stable/generated/torch.nn.Linear.html>`_
is a module that applies a linear transformation on the input using its stored weights and biases.



.. code-block:: default

    layer1 = nn.Linear(in_features=28*28, out_features=20)
    hidden1 = layer1(flat_image)
    print(hidden1.size())



nn.ReLU
^^^^^^^^^^^^^^^^^^^^^^
Non-linear activations are what create the complex mappings between the model's inputs and outputs.
They are applied after linear transformations to introduce *nonlinearity*, helping neural networks
learn a wide variety of phenomena.

In this model, we use `nn.ReLU <https://pytorch.org/docs/stable/generated/torch.nn.ReLU.html>`_ between our
linear layers, but there's other activations to introduce non-linearity in your model.


.. code-block:: default


    print(f"Before ReLU: {hidden1}\n\n")
    hidden1 = nn.ReLU()(hidden1)
    print(f"After ReLU: {hidden1}")




nn.Sequential
^^^^^^^^^^^^^^^^^^^^^^
`nn.Sequential <https://pytorch.org/docs/stable/generated/torch.nn.Sequential.html>`_ is an ordered 
container of modules. The data is passed through all the modules in the same order as defined. You can use
sequential containers to put together a quick network like ``seq_modules``.


.. code-block:: default


    seq_modules = nn.Sequential(
        flatten,
        layer1,
        nn.ReLU(),
        nn.Linear(20, 10)
    )
    input_image = torch.rand(3,28,28)
    logits = seq_modules(input_image)


nn.Softmax
^^^^^^^^^^^^^^^^^^^^^^
The last linear layer of the neural network returns `logits` - raw values in [-\infty, \infty] - which are passed to the
`nn.Softmax <https://pytorch.org/docs/stable/generated/torch.nn.Softmax.html>`_ module. The logits are scaled to values 
[0, 1] representing the model's predicted probabilities for each class. ``dim`` parameter indicates the dimension along 
which the values must sum to 1. 


.. code-block:: default


    softmax = nn.Softmax(dim=1)
    pred_probab = softmax(logits)



Model Parameters
-------------------------
Many layers inside a neural network are *parameterized*, i.e. have associated weights 
and biases that are optimized during training. Subclassing ``nn.Module`` automatically 
tracks all fields defined inside your model object, and makes all parameters 
accessible using your model's ``parameters()`` or ``named_parameters()`` methods. 

In this example, we iterate over each parameter, and print its size and a preview of its values. 



.. code-block:: default



    print("Model structure: ", model, "\n\n")

    for name, param in model.named_parameters():
        print(f"Layer: {name} | Size: {param.size()} | Values : {param[:2]} \n")


--------------


Further Reading
--------------
- `torch.nn API <https://pytorch.org/docs/stable/nn.html>`_


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