2023-01-15 23:18:58 +01:00
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extern crate rust_nn;
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use std::error::Error;
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use std::f64::consts::PI;
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2023-01-21 15:19:55 +01:00
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use ndarray::Array1;
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2023-01-15 23:18:58 +01:00
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use ndarray_rand::rand_distr::Uniform;
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2023-01-21 15:19:55 +01:00
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use ndarray_rand::RandomExt;
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2023-01-15 23:18:58 +01:00
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use plotters::prelude::*;
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use rust_nn::functions::{activation_functions, loss_functions};
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use rust_nn::layers::activation_layer::ActivationLayer;
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use rust_nn::layers::fc_layer::{FCLayer, Initializer};
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2023-01-21 15:19:55 +01:00
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use rust_nn::Network;
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2023-01-15 23:18:58 +01:00
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fn main() -> Result<(), Box<dyn Error>> {
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// training data
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let training_interval = (0.0f64, 2.0f64 * PI);
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let steps = 100000;
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2023-01-21 15:19:55 +01:00
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let training_values = Array1::random(
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steps,
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Uniform::new(training_interval.0, training_interval.1),
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)
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.to_vec();
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2023-01-15 23:18:58 +01:00
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let mut x_train = Vec::new();
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let mut y_train = Vec::new();
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for x in training_values {
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x_train.push(Array1::from_elem(1usize, x));
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y_train.push(Array1::from_elem(1usize, x.sin()));
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}
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// test data
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let test_steps = 1000;
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let interval_length = training_interval.1 - training_interval.0;
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let step_size = interval_length / test_steps as f64;
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let testing_values = Array1::range(training_interval.0, training_interval.1, step_size);
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let mut x_test = Vec::new();
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let mut y_test_true = Vec::new();
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for x in testing_values {
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x_test.push(Array1::from_elem(1usize, x));
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y_test_true.push(Array1::from_elem(1usize, x.sin()));
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}
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// initialize neural network
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let mut network = Network::new(loss_functions::Type::MSE);
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// add layers
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network.add_layer(Box::new(FCLayer::new(
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8,
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Initializer::GaussianWFactor(0.0, 1.0, 0.1),
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2023-01-21 15:19:55 +01:00
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Initializer::GaussianWFactor(0.0, 1.0, 0.1),
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)));
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network.add_layer(Box::new(ActivationLayer::new(
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activation_functions::Type::LeakyRelu,
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)));
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network.add_layer(Box::new(FCLayer::new(
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8,
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Initializer::GaussianWFactor(0.0, 1.0, 0.1),
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2023-01-21 15:19:55 +01:00
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Initializer::GaussianWFactor(0.0, 1.0, 0.1),
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)));
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network.add_layer(Box::new(ActivationLayer::new(
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activation_functions::Type::LeakyRelu,
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)));
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network.add_layer(Box::new(FCLayer::new(
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1,
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Initializer::GaussianWFactor(0.0, 1.0, 0.1),
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Initializer::GaussianWFactor(0.0, 1.0, 0.1),
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2023-01-15 23:18:58 +01:00
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)));
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// train network on training data
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network.fit(x_train, y_train, 100, 0.05, true);
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// predict test dataset
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let y_test_pred = network.predict(x_test.clone());
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// create the chart
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let buf = BitMapBackend::new("./examples/sine.png", (800, 600)).into_drawing_area();
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buf.fill(&WHITE)?;
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let mut chart = ChartBuilder::on(&buf)
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//.caption("sin(x)", ("sans-serif", 30))
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.x_label_area_size(30)
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.y_label_area_size(30)
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.build_cartesian_2d(training_interval.0..training_interval.1, -1.0f64..1.0f64)?;
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chart
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.configure_mesh()
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.disable_x_mesh()
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.disable_y_mesh()
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.draw()?;
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// add the first plot
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let data1: Vec<(f64, f64)> = x_test
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.iter()
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.zip(y_test_true.iter())
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.map(|(x, y)| (x[0], y[0]))
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.collect();
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chart
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.draw_series(LineSeries::new(data1, &RED))
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.unwrap()
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.label("true values")
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.legend(|(x, y)| PathElement::new(vec![(x, y), (x + 1, y)], &RED));
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// add the second plot
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let data2: Vec<(f64, f64)> = x_test
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.iter()
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.zip(y_test_pred.iter())
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.map(|(x, y)| (x[0], y[0]))
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.collect();
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chart
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.draw_series(LineSeries::new(data2, &BLUE))
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.unwrap()
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.label("predicted values")
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.legend(|(x, y)| PathElement::new(vec![(x, y), (x + 1, y)], &BLUE));
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Ok(())
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}
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