feat: Add getters for naive bayes structs (#74)
* feat: Add getters for GaussianNB * Add classes getter to BernoulliNB Add classes getter to CategoricalNB Add classes getter to MultinomialNB * Add feature_log_prob getter to MultinomialNB * Add class_count to NB structs * Add n_features getter for NB * Add feature_count to MultinomialNB and BernoulliNB * Add n_categories to CategoricalNB * Implement feature_log_prob and category_count getter for CategoricalNB * Implement feature_log_prob for BernoulliNB
This commit is contained in:
Luis Moreno
+127
-17
@@ -47,12 +47,44 @@ use serde::{Deserialize, Serialize};
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/// Naive Bayes classifier for Bearnoulli features
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#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
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#[derive(Debug, PartialEq)]
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#[derive(Debug)]
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struct BernoulliNBDistribution<T: RealNumber> {
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/// class labels known to the classifier
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class_labels: Vec<T>,
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/// number of training samples observed in each class
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class_count: Vec<usize>,
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/// probability of each class
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class_priors: Vec<T>,
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feature_prob: Vec<Vec<T>>,
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/// Number of samples encountered for each (class, feature)
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feature_count: Vec<Vec<usize>>,
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/// probability of features per class
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feature_log_prob: Vec<Vec<T>>,
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/// Number of features of each sample
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n_features: usize,
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}
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impl<T: RealNumber> PartialEq for BernoulliNBDistribution<T> {
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fn eq(&self, other: &Self) -> bool {
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if self.class_labels == other.class_labels
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&& self.class_count == other.class_count
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&& self.class_priors == other.class_priors
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&& self.feature_count == other.feature_count
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&& self.n_features == other.n_features
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{
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for (a, b) in self
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.feature_log_prob
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.iter()
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.zip(other.feature_log_prob.iter())
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{
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if !a.approximate_eq(b, T::epsilon()) {
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return false;
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}
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}
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true
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} else {
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false
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}
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}
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}
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impl<T: RealNumber, M: Matrix<T>> NBDistribution<T, M> for BernoulliNBDistribution<T> {
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@@ -65,9 +97,9 @@ impl<T: RealNumber, M: Matrix<T>> NBDistribution<T, M> for BernoulliNBDistributi
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for feature in 0..j.len() {
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let value = j.get(feature);
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if value == T::one() {
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likelihood += self.feature_prob[class_index][feature].ln();
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likelihood += self.feature_log_prob[class_index][feature];
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} else {
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likelihood += (T::one() - self.feature_prob[class_index][feature]).ln();
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likelihood += (T::one() - self.feature_log_prob[class_index][feature].exp()).ln();
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}
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}
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likelihood
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@@ -157,10 +189,10 @@ impl<T: RealNumber> BernoulliNBDistribution<T> {
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let y = y.to_vec();
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let (class_labels, indices) = <Vec<T> as RealNumberVector<T>>::unique_with_indices(&y);
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let mut class_count = vec![T::zero(); class_labels.len()];
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let mut class_count = vec![0_usize; class_labels.len()];
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for class_index in indices.iter() {
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class_count[*class_index] += T::one();
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class_count[*class_index] += 1;
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}
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let class_priors = if let Some(class_priors) = priors {
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@@ -173,25 +205,35 @@ impl<T: RealNumber> BernoulliNBDistribution<T> {
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} else {
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class_count
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.iter()
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.map(|&c| c / T::from(n_samples).unwrap())
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.map(|&c| T::from(c).unwrap() / T::from(n_samples).unwrap())
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.collect()
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};
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let mut feature_in_class_counter = vec![vec![T::zero(); n_features]; class_labels.len()];
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let mut feature_in_class_counter = vec![vec![0_usize; n_features]; class_labels.len()];
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for (row, class_index) in row_iter(x).zip(indices) {
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for (idx, row_i) in row.iter().enumerate().take(n_features) {
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feature_in_class_counter[class_index][idx] += *row_i;
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feature_in_class_counter[class_index][idx] +=
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row_i.to_usize().ok_or_else(|| {
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Failed::fit(&format!(
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"Elements of the matrix should be 1.0 or 0.0 |found|=[{}]",
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row_i
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))
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})?;
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}
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}
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let feature_prob = feature_in_class_counter
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let feature_log_prob = feature_in_class_counter
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.iter()
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.enumerate()
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.map(|(class_index, feature_count)| {
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feature_count
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.iter()
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.map(|&count| (count + alpha) / (class_count[class_index] + alpha * T::two()))
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.map(|&count| {
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((T::from(count).unwrap() + alpha)
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/ (T::from(class_count[class_index]).unwrap() + alpha * T::two()))
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.ln()
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})
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.collect()
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})
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.collect();
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@@ -199,7 +241,10 @@ impl<T: RealNumber> BernoulliNBDistribution<T> {
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Ok(Self {
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class_labels,
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class_priors,
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feature_prob,
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class_count,
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feature_count: feature_in_class_counter,
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feature_log_prob,
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n_features,
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})
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}
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}
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@@ -266,6 +311,34 @@ impl<T: RealNumber, M: Matrix<T>> BernoulliNB<T, M> {
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self.inner.predict(x)
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}
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}
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/// Class labels known to the classifier.
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/// Returns a vector of size n_classes.
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pub fn classes(&self) -> &Vec<T> {
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&self.inner.distribution.class_labels
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}
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/// Number of training samples observed in each class.
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/// Returns a vector of size n_classes.
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pub fn class_count(&self) -> &Vec<usize> {
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&self.inner.distribution.class_count
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}
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/// Number of features of each sample
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pub fn n_features(&self) -> usize {
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self.inner.distribution.n_features
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}
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/// Number of samples encountered for each (class, feature)
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/// Returns a 2d vector of shape (n_classes, n_features)
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pub fn feature_count(&self) -> &Vec<Vec<usize>> {
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&self.inner.distribution.feature_count
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}
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/// Empirical log probability of features given a class
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pub fn feature_log_prob(&self) -> &Vec<Vec<T>> {
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&self.inner.distribution.feature_log_prob
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}
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}
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#[cfg(test)]
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@@ -296,10 +369,24 @@ mod tests {
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assert_eq!(bnb.inner.distribution.class_priors, &[0.75, 0.25]);
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assert_eq!(
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bnb.inner.distribution.feature_prob,
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bnb.feature_log_prob(),
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&[
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&[0.4, 0.8, 0.2, 0.4, 0.4, 0.2],
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&[1. / 3.0, 2. / 3.0, 2. / 3.0, 1. / 3.0, 1. / 3.0, 2. / 3.0]
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&[
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-0.916290731874155,
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-0.2231435513142097,
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-1.6094379124341003,
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-0.916290731874155,
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-0.916290731874155,
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-1.6094379124341003
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],
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&[
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-1.0986122886681098,
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-0.40546510810816444,
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-0.40546510810816444,
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-1.0986122886681098,
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-1.0986122886681098,
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-0.40546510810816444
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]
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]
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);
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@@ -335,13 +422,36 @@ mod tests {
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let y_hat = bnb.predict(&x).unwrap();
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assert_eq!(bnb.classes(), &[0., 1., 2.]);
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assert_eq!(bnb.class_count(), &[7, 3, 5]);
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assert_eq!(bnb.n_features(), 10);
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assert_eq!(
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bnb.feature_count(),
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&[
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&[5, 6, 6, 7, 6, 4, 6, 7, 7, 7],
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&[3, 3, 3, 1, 3, 2, 3, 2, 2, 3],
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&[4, 4, 3, 4, 5, 2, 4, 5, 3, 4]
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]
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);
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assert!(bnb
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.inner
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.distribution
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.class_priors
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.approximate_eq(&vec!(0.46, 0.2, 0.33), 1e-2));
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assert!(bnb.inner.distribution.feature_prob[1].approximate_eq(
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&vec!(0.8, 0.8, 0.8, 0.4, 0.8, 0.6, 0.8, 0.6, 0.6, 0.8),
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assert!(bnb.feature_log_prob()[1].approximate_eq(
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&vec![
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-0.22314355,
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-0.22314355,
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-0.22314355,
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-0.91629073,
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-0.22314355,
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-0.51082562,
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-0.22314355,
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-0.51082562,
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-0.51082562,
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-0.22314355
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],
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1e-1
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));
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assert!(y_hat.approximate_eq(
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+132
-21
@@ -43,14 +43,31 @@ use serde::{Deserialize, Serialize};
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#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
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#[derive(Debug)]
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struct CategoricalNBDistribution<T: RealNumber> {
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/// number of training samples observed in each class
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class_count: Vec<usize>,
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/// class labels known to the classifier
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class_labels: Vec<T>,
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/// probability of each class
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class_priors: Vec<T>,
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coefficients: Vec<Vec<Vec<T>>>,
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/// Number of features of each sample
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n_features: usize,
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/// Number of categories for each feature
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n_categories: Vec<usize>,
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/// Holds arrays of shape (n_classes, n_categories of respective feature)
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/// for each feature. Each array provides the number of samples
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/// encountered for each class and category of the specific feature.
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category_count: Vec<Vec<Vec<usize>>>,
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}
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impl<T: RealNumber> PartialEq for CategoricalNBDistribution<T> {
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fn eq(&self, other: &Self) -> bool {
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if self.class_labels == other.class_labels && self.class_priors == other.class_priors {
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if self.class_labels == other.class_labels
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&& self.class_priors == other.class_priors
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&& self.n_features == other.n_features
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&& self.n_categories == other.n_categories
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&& self.class_count == other.class_count
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{
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if self.coefficients.len() != other.coefficients.len() {
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return false;
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}
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@@ -90,8 +107,8 @@ impl<T: RealNumber, M: Matrix<T>> NBDistribution<T, M> for CategoricalNBDistribu
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let mut likelihood = T::zero();
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for feature in 0..j.len() {
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let value = j.get(feature).floor().to_usize().unwrap();
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if self.coefficients[class_index][feature].len() > value {
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likelihood += self.coefficients[class_index][feature][value];
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if self.coefficients[feature][class_index].len() > value {
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likelihood += self.coefficients[feature][class_index][value];
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} else {
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return T::zero();
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}
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@@ -149,12 +166,12 @@ impl<T: RealNumber> CategoricalNBDistribution<T> {
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let class_labels: Vec<T> = (0..*y_max + 1)
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.map(|label| T::from(label).unwrap())
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.collect();
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let mut classes_count: Vec<T> = vec![T::zero(); class_labels.len()];
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let mut class_count = vec![0_usize; class_labels.len()];
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for elem in y.iter() {
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classes_count[*elem] += T::one();
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class_count[*elem] += 1;
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}
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let mut feature_categories: Vec<Vec<T>> = Vec::with_capacity(n_features);
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let mut n_categories: Vec<usize> = Vec::with_capacity(n_features);
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for feature in 0..n_features {
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let feature_max = x
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.get_col_as_vec(feature)
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@@ -167,18 +184,15 @@ impl<T: RealNumber> CategoricalNBDistribution<T> {
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feature
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))
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})?;
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let feature_types = (0..feature_max + 1)
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.map(|feat| T::from(feat).unwrap())
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.collect();
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feature_categories.push(feature_types);
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n_categories.push(feature_max + 1);
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}
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let mut coefficients: Vec<Vec<Vec<T>>> = Vec::with_capacity(class_labels.len());
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for (label, label_count) in class_labels.iter().zip(classes_count.iter()) {
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let mut category_count: Vec<Vec<Vec<usize>>> = Vec::with_capacity(class_labels.len());
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for (feature_index, &n_categories_i) in n_categories.iter().enumerate().take(n_features) {
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let mut coef_i: Vec<Vec<T>> = Vec::with_capacity(n_features);
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for (feature_index, feature_options) in
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feature_categories.iter().enumerate().take(n_features)
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{
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let mut category_count_i: Vec<Vec<usize>> = Vec::with_capacity(n_features);
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for (label, &label_count) in class_labels.iter().zip(class_count.iter()) {
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let col = x
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.get_col_as_vec(feature_index)
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.iter()
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@@ -186,33 +200,41 @@ impl<T: RealNumber> CategoricalNBDistribution<T> {
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.filter(|(i, _j)| T::from(y[*i]).unwrap() == *label)
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.map(|(_, j)| *j)
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.collect::<Vec<T>>();
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let mut feat_count: Vec<T> = vec![T::zero(); feature_options.len()];
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let mut feat_count: Vec<usize> = vec![0_usize; n_categories_i];
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for row in col.iter() {
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let index = row.floor().to_usize().unwrap();
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feat_count[index] += T::one();
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feat_count[index] += 1;
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}
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let coef_i_j = feat_count
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.iter()
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.map(|c| {
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((*c + alpha)
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/ (*label_count + T::from(feature_options.len()).unwrap() * alpha))
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((T::from(*c).unwrap() + alpha)
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/ (T::from(label_count).unwrap()
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+ T::from(n_categories_i).unwrap() * alpha))
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.ln()
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})
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.collect::<Vec<T>>();
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category_count_i.push(feat_count);
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coef_i.push(coef_i_j);
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}
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category_count.push(category_count_i);
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coefficients.push(coef_i);
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}
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let class_priors = classes_count
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.into_iter()
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.map(|count| count / T::from(n_samples).unwrap())
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let class_priors = class_count
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.iter()
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.map(|&count| T::from(count).unwrap() / T::from(n_samples).unwrap())
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.collect::<Vec<T>>();
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Ok(Self {
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class_count,
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class_labels,
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class_priors,
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coefficients,
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n_categories,
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n_features,
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category_count,
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})
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}
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}
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@@ -287,6 +309,41 @@ impl<T: RealNumber, M: Matrix<T>> CategoricalNB<T, M> {
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pub fn predict(&self, x: &M) -> Result<M::RowVector, Failed> {
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self.inner.predict(x)
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}
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/// Class labels known to the classifier.
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/// Returns a vector of size n_classes.
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pub fn classes(&self) -> &Vec<T> {
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&self.inner.distribution.class_labels
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}
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|
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/// Number of training samples observed in each class.
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/// Returns a vector of size n_classes.
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pub fn class_count(&self) -> &Vec<usize> {
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&self.inner.distribution.class_count
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}
|
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|
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/// Number of features of each sample
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pub fn n_features(&self) -> usize {
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self.inner.distribution.n_features
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}
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|
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/// Number of features of each sample
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pub fn n_categories(&self) -> &Vec<usize> {
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&self.inner.distribution.n_categories
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}
|
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|
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/// Holds arrays of shape (n_classes, n_categories of respective feature)
|
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/// for each feature. Each array provides the number of samples
|
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/// encountered for each class and category of the specific feature.
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pub fn category_count(&self) -> &Vec<Vec<Vec<usize>>> {
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&self.inner.distribution.category_count
|
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}
|
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/// Holds arrays of shape (n_classes, n_categories of respective feature)
|
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/// for each feature. Each array provides the empirical log probability
|
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/// of categories given the respective feature and class, ``P(x_i|y)``.
|
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pub fn feature_log_prob(&self) -> &Vec<Vec<Vec<T>>> {
|
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&self.inner.distribution.coefficients
|
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}
|
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}
|
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|
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#[cfg(test)]
|
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@@ -315,6 +372,60 @@ mod tests {
|
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let y = vec![0., 0., 1., 1., 1., 0., 1., 0., 1., 1., 1., 1., 1., 0.];
|
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|
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let cnb = CategoricalNB::fit(&x, &y, Default::default()).unwrap();
|
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|
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// checking parity with scikit
|
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assert_eq!(cnb.classes(), &[0., 1.]);
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assert_eq!(cnb.class_count(), &[5, 9]);
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assert_eq!(cnb.n_features(), 4);
|
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assert_eq!(cnb.n_categories(), &[3, 3, 2, 2]);
|
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assert_eq!(
|
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cnb.category_count(),
|
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&vec![
|
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vec![vec![3, 0, 2], vec![2, 4, 3]],
|
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vec![vec![1, 2, 2], vec![3, 4, 2]],
|
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vec![vec![1, 4], vec![6, 3]],
|
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vec![vec![2, 3], vec![6, 3]]
|
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]
|
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);
|
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|
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assert_eq!(
|
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cnb.feature_log_prob(),
|
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&vec![
|
||||
vec![
|
||||
vec![
|
||||
-0.6931471805599453,
|
||||
-2.0794415416798357,
|
||||
-0.9808292530117262
|
||||
],
|
||||
vec![
|
||||
-1.3862943611198906,
|
||||
-0.8754687373538999,
|
||||
-1.0986122886681098
|
||||
]
|
||||
],
|
||||
vec![
|
||||
vec![
|
||||
-1.3862943611198906,
|
||||
-0.9808292530117262,
|
||||
-0.9808292530117262
|
||||
],
|
||||
vec![
|
||||
-1.0986122886681098,
|
||||
-0.8754687373538999,
|
||||
-1.3862943611198906
|
||||
]
|
||||
],
|
||||
vec![
|
||||
vec![-1.252762968495368, -0.3364722366212129],
|
||||
vec![-0.45198512374305727, -1.0116009116784799]
|
||||
],
|
||||
vec![
|
||||
vec![-0.8472978603872037, -0.5596157879354228],
|
||||
vec![-0.45198512374305727, -1.0116009116784799]
|
||||
]
|
||||
]
|
||||
);
|
||||
|
||||
let x_test = DenseMatrix::from_2d_array(&[&[0., 2., 1., 0.], &[2., 2., 0., 0.]]);
|
||||
let y_hat = cnb.predict(&x_test).unwrap();
|
||||
assert_eq!(y_hat, vec![0., 1.]);
|
||||
|
||||
+56
-22
@@ -39,10 +39,12 @@ use serde::{Deserialize, Serialize};
|
||||
struct GaussianNBDistribution<T: RealNumber> {
|
||||
/// class labels known to the classifier
|
||||
class_labels: Vec<T>,
|
||||
/// number of training samples observed in each class
|
||||
class_count: Vec<usize>,
|
||||
/// probability of each class.
|
||||
class_priors: Vec<T>,
|
||||
/// variance of each feature per class
|
||||
sigma: Vec<Vec<T>>,
|
||||
var: Vec<Vec<T>>,
|
||||
/// mean of each feature per class
|
||||
theta: Vec<Vec<T>>,
|
||||
}
|
||||
@@ -57,18 +59,14 @@ impl<T: RealNumber, M: Matrix<T>> NBDistribution<T, M> for GaussianNBDistributio
|
||||
}
|
||||
|
||||
fn log_likelihood(&self, class_index: usize, j: &M::RowVector) -> T {
|
||||
if class_index < self.class_labels.len() {
|
||||
let mut likelihood = T::zero();
|
||||
for feature in 0..j.len() {
|
||||
let value = j.get(feature);
|
||||
let mean = self.theta[class_index][feature];
|
||||
let variance = self.sigma[class_index][feature];
|
||||
likelihood += self.calculate_log_probability(value, mean, variance);
|
||||
}
|
||||
likelihood
|
||||
} else {
|
||||
T::zero()
|
||||
let mut likelihood = T::zero();
|
||||
for feature in 0..j.len() {
|
||||
let value = j.get(feature);
|
||||
let mean = self.theta[class_index][feature];
|
||||
let variance = self.var[class_index][feature];
|
||||
likelihood += self.calculate_log_probability(value, mean, variance);
|
||||
}
|
||||
likelihood
|
||||
}
|
||||
|
||||
fn classes(&self) -> &Vec<T> {
|
||||
@@ -121,12 +119,12 @@ impl<T: RealNumber> GaussianNBDistribution<T> {
|
||||
let y = y.to_vec();
|
||||
let (class_labels, indices) = <Vec<T> as RealNumberVector<T>>::unique_with_indices(&y);
|
||||
|
||||
let mut class_count = vec![T::zero(); class_labels.len()];
|
||||
let mut class_count = vec![0_usize; class_labels.len()];
|
||||
|
||||
let mut subdataset: Vec<Vec<Vec<T>>> = vec![vec![]; class_labels.len()];
|
||||
|
||||
for (row, class_index) in row_iter(x).zip(indices.iter()) {
|
||||
class_count[*class_index] += T::one();
|
||||
class_count[*class_index] += 1;
|
||||
subdataset[*class_index].push(row);
|
||||
}
|
||||
|
||||
@@ -139,8 +137,8 @@ impl<T: RealNumber> GaussianNBDistribution<T> {
|
||||
class_priors
|
||||
} else {
|
||||
class_count
|
||||
.into_iter()
|
||||
.map(|c| c / T::from(n_samples).unwrap())
|
||||
.iter()
|
||||
.map(|&c| T::from(c).unwrap() / T::from(n_samples).unwrap())
|
||||
.collect()
|
||||
};
|
||||
|
||||
@@ -157,15 +155,16 @@ impl<T: RealNumber> GaussianNBDistribution<T> {
|
||||
})
|
||||
.collect();
|
||||
|
||||
let (sigma, theta): (Vec<Vec<T>>, Vec<Vec<T>>) = subdataset
|
||||
let (var, theta): (Vec<Vec<T>>, Vec<Vec<T>>) = subdataset
|
||||
.iter()
|
||||
.map(|data| (data.var(0), data.mean(0)))
|
||||
.unzip();
|
||||
|
||||
Ok(Self {
|
||||
class_labels,
|
||||
class_count,
|
||||
class_priors,
|
||||
sigma,
|
||||
var,
|
||||
theta,
|
||||
})
|
||||
}
|
||||
@@ -223,6 +222,36 @@ impl<T: RealNumber, M: Matrix<T>> GaussianNB<T, M> {
|
||||
pub fn predict(&self, x: &M) -> Result<M::RowVector, Failed> {
|
||||
self.inner.predict(x)
|
||||
}
|
||||
|
||||
/// Class labels known to the classifier.
|
||||
/// Returns a vector of size n_classes.
|
||||
pub fn classes(&self) -> &Vec<T> {
|
||||
&self.inner.distribution.class_labels
|
||||
}
|
||||
|
||||
/// Number of training samples observed in each class.
|
||||
/// Returns a vector of size n_classes.
|
||||
pub fn class_count(&self) -> &Vec<usize> {
|
||||
&self.inner.distribution.class_count
|
||||
}
|
||||
|
||||
/// Probability of each class
|
||||
/// Returns a vector of size n_classes.
|
||||
pub fn class_priors(&self) -> &Vec<T> {
|
||||
&self.inner.distribution.class_priors
|
||||
}
|
||||
|
||||
/// Mean of each feature per class
|
||||
/// Returns a 2d vector of shape (n_classes, n_features).
|
||||
pub fn theta(&self) -> &Vec<Vec<T>> {
|
||||
&self.inner.distribution.theta
|
||||
}
|
||||
|
||||
/// Variance of each feature per class
|
||||
/// Returns a 2d vector of shape (n_classes, n_features).
|
||||
pub fn var(&self) -> &Vec<Vec<T>> {
|
||||
&self.inner.distribution.var
|
||||
}
|
||||
}
|
||||
|
||||
#[cfg(test)]
|
||||
@@ -245,18 +274,23 @@ mod tests {
|
||||
let gnb = GaussianNB::fit(&x, &y, Default::default()).unwrap();
|
||||
let y_hat = gnb.predict(&x).unwrap();
|
||||
assert_eq!(y_hat, y);
|
||||
|
||||
assert_eq!(gnb.classes(), &[1., 2.]);
|
||||
|
||||
assert_eq!(gnb.class_count(), &[3, 3]);
|
||||
|
||||
assert_eq!(
|
||||
gnb.inner.distribution.sigma,
|
||||
gnb.var(),
|
||||
&[
|
||||
&[0.666666666666667, 0.22222222222222232],
|
||||
&[0.666666666666667, 0.22222222222222232]
|
||||
]
|
||||
);
|
||||
|
||||
assert_eq!(gnb.inner.distribution.class_priors, &[0.5, 0.5]);
|
||||
assert_eq!(gnb.class_priors(), &[0.5, 0.5]);
|
||||
|
||||
assert_eq!(
|
||||
gnb.inner.distribution.theta,
|
||||
gnb.theta(),
|
||||
&[&[-2., -1.3333333333333333], &[2., 1.3333333333333333]]
|
||||
);
|
||||
}
|
||||
@@ -277,7 +311,7 @@ mod tests {
|
||||
let parameters = GaussianNBParameters::default().with_priors(priors.clone());
|
||||
let gnb = GaussianNB::fit(&x, &y, parameters).unwrap();
|
||||
|
||||
assert_eq!(gnb.inner.distribution.class_priors, priors);
|
||||
assert_eq!(gnb.class_priors(), &priors);
|
||||
}
|
||||
|
||||
#[test]
|
||||
|
||||
+105
-17
@@ -51,8 +51,16 @@ use serde::{Deserialize, Serialize};
|
||||
struct MultinomialNBDistribution<T: RealNumber> {
|
||||
/// class labels known to the classifier
|
||||
class_labels: Vec<T>,
|
||||
/// number of training samples observed in each class
|
||||
class_count: Vec<usize>,
|
||||
/// probability of each class
|
||||
class_priors: Vec<T>,
|
||||
feature_prob: Vec<Vec<T>>,
|
||||
/// Empirical log probability of features given a class
|
||||
feature_log_prob: Vec<Vec<T>>,
|
||||
/// Number of samples encountered for each (class, feature)
|
||||
feature_count: Vec<Vec<usize>>,
|
||||
/// Number of features of each sample
|
||||
n_features: usize,
|
||||
}
|
||||
|
||||
impl<T: RealNumber, M: Matrix<T>> NBDistribution<T, M> for MultinomialNBDistribution<T> {
|
||||
@@ -64,7 +72,7 @@ impl<T: RealNumber, M: Matrix<T>> NBDistribution<T, M> for MultinomialNBDistribu
|
||||
let mut likelihood = T::zero();
|
||||
for feature in 0..j.len() {
|
||||
let value = j.get(feature);
|
||||
likelihood += value * self.feature_prob[class_index][feature].ln();
|
||||
likelihood += value * self.feature_log_prob[class_index][feature];
|
||||
}
|
||||
likelihood
|
||||
}
|
||||
@@ -144,10 +152,10 @@ impl<T: RealNumber> MultinomialNBDistribution<T> {
|
||||
let y = y.to_vec();
|
||||
|
||||
let (class_labels, indices) = <Vec<T> as RealNumberVector<T>>::unique_with_indices(&y);
|
||||
let mut class_count = vec![T::zero(); class_labels.len()];
|
||||
let mut class_count = vec![0_usize; class_labels.len()];
|
||||
|
||||
for class_index in indices.iter() {
|
||||
class_count[*class_index] += T::one();
|
||||
class_count[*class_index] += 1;
|
||||
}
|
||||
|
||||
let class_priors = if let Some(class_priors) = priors {
|
||||
@@ -160,33 +168,46 @@ impl<T: RealNumber> MultinomialNBDistribution<T> {
|
||||
} else {
|
||||
class_count
|
||||
.iter()
|
||||
.map(|&c| c / T::from(n_samples).unwrap())
|
||||
.map(|&c| T::from(c).unwrap() / T::from(n_samples).unwrap())
|
||||
.collect()
|
||||
};
|
||||
|
||||
let mut feature_in_class_counter = vec![vec![T::zero(); n_features]; class_labels.len()];
|
||||
let mut feature_in_class_counter = vec![vec![0_usize; n_features]; class_labels.len()];
|
||||
|
||||
for (row, class_index) in row_iter(x).zip(indices) {
|
||||
for (idx, row_i) in row.iter().enumerate().take(n_features) {
|
||||
feature_in_class_counter[class_index][idx] += *row_i;
|
||||
feature_in_class_counter[class_index][idx] +=
|
||||
row_i.to_usize().ok_or_else(|| {
|
||||
Failed::fit(&format!(
|
||||
"Elements of the matrix should be convertible to usize |found|=[{}]",
|
||||
row_i
|
||||
))
|
||||
})?;
|
||||
}
|
||||
}
|
||||
|
||||
let feature_prob = feature_in_class_counter
|
||||
let feature_log_prob = feature_in_class_counter
|
||||
.iter()
|
||||
.map(|feature_count| {
|
||||
let n_c = feature_count.sum();
|
||||
let n_c: usize = feature_count.iter().sum();
|
||||
feature_count
|
||||
.iter()
|
||||
.map(|&count| (count + alpha) / (n_c + alpha * T::from(n_features).unwrap()))
|
||||
.map(|&count| {
|
||||
((T::from(count).unwrap() + alpha)
|
||||
/ (T::from(n_c).unwrap() + alpha * T::from(n_features).unwrap()))
|
||||
.ln()
|
||||
})
|
||||
.collect()
|
||||
})
|
||||
.collect();
|
||||
|
||||
Ok(Self {
|
||||
class_count,
|
||||
class_labels,
|
||||
class_priors,
|
||||
feature_prob,
|
||||
feature_log_prob,
|
||||
feature_count: feature_in_class_counter,
|
||||
n_features,
|
||||
})
|
||||
}
|
||||
}
|
||||
@@ -240,6 +261,35 @@ impl<T: RealNumber, M: Matrix<T>> MultinomialNB<T, M> {
|
||||
pub fn predict(&self, x: &M) -> Result<M::RowVector, Failed> {
|
||||
self.inner.predict(x)
|
||||
}
|
||||
|
||||
/// Class labels known to the classifier.
|
||||
/// Returns a vector of size n_classes.
|
||||
pub fn classes(&self) -> &Vec<T> {
|
||||
&self.inner.distribution.class_labels
|
||||
}
|
||||
|
||||
/// Number of training samples observed in each class.
|
||||
/// Returns a vector of size n_classes.
|
||||
pub fn class_count(&self) -> &Vec<usize> {
|
||||
&self.inner.distribution.class_count
|
||||
}
|
||||
|
||||
/// Empirical log probability of features given a class, P(x_i|y).
|
||||
/// Returns a 2d vector of shape (n_classes, n_features)
|
||||
pub fn feature_log_prob(&self) -> &Vec<Vec<T>> {
|
||||
&self.inner.distribution.feature_log_prob
|
||||
}
|
||||
|
||||
/// Number of features of each sample
|
||||
pub fn n_features(&self) -> usize {
|
||||
self.inner.distribution.n_features
|
||||
}
|
||||
|
||||
/// Number of samples encountered for each (class, feature)
|
||||
/// Returns a 2d vector of shape (n_classes, n_features)
|
||||
pub fn feature_count(&self) -> &Vec<Vec<usize>> {
|
||||
&self.inner.distribution.feature_count
|
||||
}
|
||||
}
|
||||
|
||||
#[cfg(test)]
|
||||
@@ -268,12 +318,29 @@ mod tests {
|
||||
let y = vec![0., 0., 0., 1.];
|
||||
let mnb = MultinomialNB::fit(&x, &y, Default::default()).unwrap();
|
||||
|
||||
assert_eq!(mnb.classes(), &[0., 1.]);
|
||||
assert_eq!(mnb.class_count(), &[3, 1]);
|
||||
|
||||
assert_eq!(mnb.inner.distribution.class_priors, &[0.75, 0.25]);
|
||||
assert_eq!(
|
||||
mnb.inner.distribution.feature_prob,
|
||||
mnb.feature_log_prob(),
|
||||
&[
|
||||
&[1. / 7., 3. / 7., 1. / 14., 1. / 7., 1. / 7., 1. / 14.],
|
||||
&[1. / 9., 2. / 9.0, 2. / 9.0, 1. / 9.0, 1. / 9.0, 2. / 9.0]
|
||||
&[
|
||||
(1_f64 / 7_f64).ln(),
|
||||
(3_f64 / 7_f64).ln(),
|
||||
(1_f64 / 14_f64).ln(),
|
||||
(1_f64 / 7_f64).ln(),
|
||||
(1_f64 / 7_f64).ln(),
|
||||
(1_f64 / 14_f64).ln()
|
||||
],
|
||||
&[
|
||||
(1_f64 / 9_f64).ln(),
|
||||
(2_f64 / 9_f64).ln(),
|
||||
(2_f64 / 9_f64).ln(),
|
||||
(1_f64 / 9_f64).ln(),
|
||||
(1_f64 / 9_f64).ln(),
|
||||
(2_f64 / 9_f64).ln()
|
||||
]
|
||||
]
|
||||
);
|
||||
|
||||
@@ -307,6 +374,16 @@ mod tests {
|
||||
let y = vec![2., 2., 0., 0., 0., 2., 1., 1., 0., 1., 0., 0., 2., 0., 2.];
|
||||
let nb = MultinomialNB::fit(&x, &y, Default::default()).unwrap();
|
||||
|
||||
assert_eq!(nb.n_features(), 10);
|
||||
assert_eq!(
|
||||
nb.feature_count(),
|
||||
&[
|
||||
&[12, 20, 11, 24, 12, 14, 13, 17, 13, 18],
|
||||
&[9, 6, 9, 4, 7, 3, 8, 5, 4, 9],
|
||||
&[10, 12, 9, 9, 11, 3, 9, 18, 10, 10]
|
||||
]
|
||||
);
|
||||
|
||||
let y_hat = nb.predict(&x).unwrap();
|
||||
|
||||
assert!(nb
|
||||
@@ -314,9 +391,20 @@ mod tests {
|
||||
.distribution
|
||||
.class_priors
|
||||
.approximate_eq(&vec!(0.46, 0.2, 0.33), 1e-2));
|
||||
assert!(nb.inner.distribution.feature_prob[1].approximate_eq(
|
||||
&vec!(0.07, 0.12, 0.07, 0.15, 0.07, 0.09, 0.08, 0.10, 0.08, 0.11),
|
||||
1e-1
|
||||
assert!(nb.feature_log_prob()[1].approximate_eq(
|
||||
&vec![
|
||||
-2.00148,
|
||||
-2.35815494,
|
||||
-2.00148,
|
||||
-2.69462718,
|
||||
-2.22462355,
|
||||
-2.91777073,
|
||||
-2.10684052,
|
||||
-2.51230562,
|
||||
-2.69462718,
|
||||
-2.00148
|
||||
],
|
||||
1e-5
|
||||
));
|
||||
assert!(y_hat.approximate_eq(
|
||||
&vec!(2.0, 2.0, 0.0, 0.0, 0.0, 2.0, 2.0, 1.0, 0.0, 1.0, 0.0, 2.0, 0.0, 0.0, 2.0),
|
||||
|
||||
Reference in New Issue
Block a user