# Writing a Genetic Algorithm in Nx

## Numerical Computing for Elixir

📚 *Take advantage of 40 percent off all Elixir titles during The Pragmatic Bookshelf’s Black Friday event — now through November 29, 2021. Use promo code **turkeysale2021** to save on all Elixir ebooks, including **Genetic Algorithms in Elixir**.*

🎫 You can follow along with this post by importing this Livebook:https://gist.github.com/seanmor5/feff05877f3c5cb04b539bf24dda0c96

# Genetic Algorithms in Elixir

After writing *Genetic Algorithms in Elixir*, I had no real hopes or expectations that numerical computing would become a focus for Elixir. However, to my surprise, the Nx project developed rather quickly and proved that Elixir could be used for practical machine learning and numerical computing applications. While I don’t have any plans (yet) of reworking the examples in my book to take advantage of the acceleration enabled by Nx, EXLA, and other projects, I feel it’s necessary to show how you could go about rewriting your genetic algorithms to take advantage of Elixir’s new numerical computing libraries.

# Introducing `Nx for Elixir`

`Nx`

is a numerical computing library for Elixir which supports the creation and manipulation of multi-dimensional arrays (called `tensors`

in the API), automatic differentiation, and just-in-time (JIT) compilation to CPU, GPU, and other accelerators via pluggable backends and compilers. `Nx`

opens up a realm of possibilities for Elixir developers including the ability to conduct accelerated simulations, perform machine learning, and manipulate large amounts of data in ways that were otherwise not possible in Elixir.

The `Nx`

API is inspired by Python’s NumPy — which is an array programming library. Manipulating arrays or tensors in libraries such as `Nx`

and NumPy requires a different way of thinking. In *Genetic Algorithms in Elixir*, we created a framework that represented populations as lists and performed most of the computations using Elixir `Enumerable`

types. Constructs such as `map`

, `reduce`

, `filter`

, and so on were the fundamental parts of your genetic algorithms. At the time, using Elixir’s `Enum`

API was pretty much the only option.

`Nx`

represents data in-memory as flat binaries. While the `Nx`

API has some `map` and `reduce` functions, they’re inefficient compared to alternative options in the API. To take advantage of `Nx`

, you’ll need to rework your algorithms to work on tensors.

As a motivation to use `Nx`

, we’ll be solving a problem that would be incredibly slow using plain Elixir. We’ll be creating a genetic algorithm that reconstructs a handwritten digit.

# Requirements for Our Elixir Nx Project

For this project, you’ll need an installation of at least Elixir 1.12 and OTP 24. Additionally, you’ll need to be able to use `EXLA`

. `EXLA`

has precompiled binaries for Linux and macOS, as well as variants with CUDA support.

To follow along with the code, you’ll want to use a LiveBook.

We’ll start by installing our required libraries. SciData is a library for grabbing well-known datasets in formats that are easily ingestible by `Nx`

. Install the libraries as follows:

`Mix.install([`

{:exla, “~> 0.1.0-dev”, github: “elixir-nx/nx”, sparse: “exla”},

{:nx, “~> 0.1.0-dev”, github: “elixir-nx/nx”, sparse: “nx”, override: true},

{:scidata, “~> 0.1.0”}

])

## Setting Up the Data

Our objective is to write a genetic algorithm that is able to reconstruct an example image. To start, we’ll need to extract an example image. First, use `SciData`

to download the MNIST dataset:

`{images, _} = Scidata.MNIST.download()`

{data, type, shape} = images

We need only a single image, so we can do some binary pattern matching to extract the first image without dropping to `Nx`

yet. `shape`

is of the form `{n_images, channels, height, width}`

and the type of the data is `{:u, 8}`

, which means each value in the tensor would represent an unsigned 8-bit integer. That means each number in the binary represents a single pixel value from 0–255.

{_, channels, height, width} = shape

image_size = channels * height * width<<image::size(image_size)-binary, _::binary>> = data

To convert the data to a tensor, we can use the `Nx`

function `from_binary`

, which takes a flat binary and a type and returns a newly constructed tensor. We’ll also want to reshape the tensor to the desired shape and normalize pixel values to be between 0 and 1. This step will help us write our genetic algorithm later on:

`example_image =`

image

|> Nx.from_binary(type)

|> Nx.reshape({channels, height, width})

|> Nx.divide(255.0)

To verify that we’ve correctly extracted a single image, let’s visualize it using `Nx.to_heatmap/1`

:

`example_image |> Nx.to_heatmap()`

# Defining the Algorithm

With our example image extracted, we can start defining the genetic algorithm.

## Initialization

The first thing we need to do is initialize our population.

We’ll represent our population using a single tensor, where each row of the tensor represents a single flattened image.

Because we normalized our example image, we can also use normalized representations of generated images:

population_size = 1000initialize = fn ->

Nx.random_uniform(

{population_size, image_size},

backend: Nx.Defn.Expr

)

end

**One note**: we have to add `backend: Nx.Defn.Expr`

so `Nx`

doesn’t attempt to inline and evaluate the function as a constant during JIT compilation.

## Evaluation

The objective is to generate an image that is as close as possible to our example image. We can measure the fitness of a generated image by calculating the pixel-wise squared error (mean-squared error) between it and the example image:

evaluate = fn population, example ->

# Reshape example so it broadcasts for each image in population

example =

example

|> Nx.flatten()

|> Nx.new_axis(0)# Calculate MSE between each image and example

population

|> Nx.subtract(example)

|> Nx.power(2)

|> Nx.mean(axes: [-1])

end

In the code above, we start by flattening and then expanding the example image so it *broadcasts* correctly over the population. Broadcasting is outside the scope of this post; however, you should know that thanks to broadcasting, our code will subtract `example`

from every row in the population.

Next, we define the mean squared-error calculation for each image by taking the difference between each image in the population and the example image, squaring the difference, and then taking the mean along the last axis in the population. Taking the mean in this way will return a pixel-wise average error for each image.

## Selection

Now we need to define a selection strategy. To simplify things, we’ll select each image in our original population for crossover and replace the original population with children generated from crossover. As another simplification, we’ll simply use a best selection strategy that pairs the best chromosomes for crossover:

`select = fn population, target_image ->`

population

|> evaluate.(target_image)

|> Nx.argsort()

|> then(&Nx.take(population, &1))

end

## Crossover

Our selection strategy will ensure that parents are paired row-wise in the population. That type of pairing means the first two flattened images should be combined, the second two should be combined, and so on. We’ll combine our population such that each child is an average of its parents. This combination will create two identical children per pair of parents; however, we can add some variability in the mutation step:

crossover = fn population ->

{population_size, _} = Nx.shape(population)

half_pop = div(population_size, 2)

even_idx = Nx.multiply(Nx.iota({half_pop}), 2)

odd_idx = Nx.add(Nx.multiply(Nx.iota({half_pop}), 2), 1){evens, odds} = {

Nx.take(population, even_idx),

Nx.take(population, odd_idx)

}children = Nx.divide(Nx.add(evens, odds), 2)

Nx.concatenate([children, children], axis: 0)

end

In this implementation, we calculate exactly half of the population size, and then extract even and odd rows into separate tensors. We take the average of the two tensors, and then stack averages on top of one another such that we have a new population that matches the size of the original.

## Mutation

Our crossover strategy will lead to premature convergence rather quickly, so we need to introduce some variability with mutation. We’ll create variability by adding random noise to around 50 percent of the pixels in the new population:

mutate = fn population ->

mask = Nx.random_uniform(Nx.shape(population), backend: Nx.Defn.Expr)

noise = Nx.random_uniform(Nx.shape(population), -0.15, 0.15, backend: Nx.Defn.Expr)Nx.select(Nx.less(mask, 0.4), Nx.add(population, noise), population)

|> Nx.clip(0, 1)

end

Here we generate a mask and noise that have the same shape as the original population. We constrain noise values between `-0.1`

and `0.1`

so there are no extreme changes in pixel values. Finally, since there’s a possibility that pixel values become negative, we clamp the population back between 0 and 1.

## The Algorithm

We’ve implemented all of the required steps for our genetic algorithm. Now we need to run it. We’ll run the algorithm for a fixed number of generations to see how close we can get to the original image:

evolve = fn population, target_image ->

population

|> select.(target_image)

|> crossover.()

|> mutate.()

endpopulation = Nx.Defn.jit(initialize, [], compiler: EXLA)final_population =

Enum.reduce(1..2500, population, fn i, population ->

population = Nx.Defn.jit(evolve, [population, example_image], compiler: EXLA)best =

Nx.Defn.jit(

fn population, example_image ->

population

|> evaluate.(example_image)

|> Nx.reduce_min()

end,

[population, example_image],

compiler: EXLA

)

|> Nx.to_scalar()IO.write(“\rGeneration: #{i} Best: #{:io_lib.format(‘~.5f’, [best])}”)population

end)# Visualize the top 3

final_population

|> select.(example_image)

|> Nx.slice_axis(0, 3, 0)

|> Nx.reshape({3, 28, 28})

|> Nx.to_heatmap()

In the code above, we implement `evolve`

, which is the body of our genetic algorithm. Next, we initialize the population using `Nx.Defn.jit/3`

, which tells `Nx`

to JIT compile our functions using the `EXLA`

compiler. This step is necessary because we’re not working inside a module with `defn`

, so by default, our functions will not be JIT compiled. Next, we implement the genetic algorithm loop using `reduce`

, and keep track of progress over time by extracting the best chromosome from the population after each generation.

Finally, we take the final evolved population and extract the top three candidates from the pool to inspect. If you look hard enough, you can see how our random population converged to resemble the original target image! We can probably do better with more complex crossover, selection, and mutation schemes, or by messing with hyperparameters, but for a quick implementation — our results are pretty good!

As a final note, if you want to play with a legitimate evolutionary algorithm library built entirely on top of Nx, check out Meow.

Did you enjoy this article? You might also like *Genetic Algorithms in Elixir by *Sean Moriarity,* *available from The Pragmatic Bookshelf: