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work:development work:dependabot/cargo/bincode-3.0.0 work:dependabot/cargo/ndarray-0.17 work:dependabot/cargo/rand-0.9.2 work:dependabot/cargo/rand_distr-0.5 work:dependabot/cargo/getrandom-0.3.4 work:release-v0.4.8 work:single_linkage work:add-other-pairwise-distance work:issue-50-predict-proba-for-randomforest work:prdct-prb work:kmeans-with-fastpair work:main work:release-0.3 work:mec-is/predict-probability work:issue-11-hierarchical-clustering work:alanrace-predict-probs work:release-0.2.1 work:release-0.2.0 work:release-0.1.0
work:v0.4.9 work:v0.4.8 work:v0.4.6 work:v0.4.5 work:v0.4.4 work:v0.4.3 work:v0.4.2 work:v0.4.1 work:v0.4.0 work:v0.3.1 work:v0.3.0
..
compare: work:v0.4.0
Branches Tags
work:development work:dependabot/cargo/bincode-3.0.0 work:dependabot/cargo/ndarray-0.17 work:dependabot/cargo/rand-0.9.2 work:dependabot/cargo/rand_distr-0.5 work:dependabot/cargo/getrandom-0.3.4 work:release-v0.4.8 work:single_linkage work:add-other-pairwise-distance work:issue-50-predict-proba-for-randomforest work:prdct-prb work:kmeans-with-fastpair work:main work:release-0.3 work:mec-is/predict-probability work:issue-11-hierarchical-clustering work:alanrace-predict-probs work:release-0.2.1 work:release-0.2.0 work:release-0.1.0
work:v0.4.9 work:v0.4.8 work:v0.4.6 work:v0.4.5 work:v0.4.4 work:v0.4.3 work:v0.4.2 work:v0.4.1 work:v0.4.0 work:v0.3.1 work:v0.3.0

20 Commits
release-0.3 .. v0.4.0

Author SHA1 Message Date
dependabot[bot]
4523ac73ff Update itertools requirement from 0.12.0 to 0.13.0 (#280) 
Updates the requirements on [itertools](https://github.com/rust-itertools/itertools) to permit the latest version.
- [Changelog](https://github.com/rust-itertools/itertools/blob/master/CHANGELOG.md)
- [Commits](https://github.com/rust-itertools/itertools/compare/v0.12.0...v0.13.0)

---
updated-dependencies:
- dependency-name: itertools
  dependency-type: direct:production
...

Signed-off-by: dependabot[bot] <support@github.com>
Co-authored-by: dependabot[bot] <49699333+dependabot[bot]@users.noreply.github.com>
 2024-11-25 11:47:23 -04:00
morenol
ba75f9ffad chore: fix clippy (#283) 
* chore: fix clippy


Co-authored-by: Luis Moreno <morenol@users.noreply.github.com>
 2024-11-25 11:34:29 -04:00
Lorenzo
239c00428f Patch to version 0.4.0 (#257) 
* uncomment test

* Add random test for logistic regression

* linting

* Bump version

* Add test for logistic regression

* linting

* initial commit

* final

* final-clean

* Bump to 0.4.0

* Fix linter

* cleanup

* Update CHANDELOG with breaking changes

* Update CHANDELOG date

* Add functional methods to DenseMatrix implementation

* linting

* add type declaration in test

* Fix Wasm tests failing

* linting

* fix tests

* linting

* Add type annotations on BBDTree constructor

* fix clippy

* fix clippy

* fix tests

* bump version

* run fmt. fix changelog

---------

Co-authored-by: Edmund Cape <edmund@Edmunds-MacBook-Pro.local>
 2024-03-04 08:51:27 -05:00
morenol
80a93c1a0e chore: fix clippy (#276) 
Co-authored-by: Luis Moreno <morenol@users.noreply.github.com>
 2024-02-25 00:17:30 -05:00
Tushushu
4eadd16ce4 Implement the feature importance for Decision Tree Classifier (#275) 
* store impurity in the node

* add number of features

* add a TODO

* draft feature importance

* feat

* n_samples of node

* compute_feature_importances

* unit tests

* always calculate impurity

* fix bug

* fix linter
 2024-02-24 23:37:30 -05:00
Frédéric Meyer
886b5631b7 In Naive Bayes, avoid using Option::unwrap and so avoid panicking from NaN values (#274) 2024-01-10 14:59:10 -04:00
dependabot[bot]
9c07925d8a Update itertools requirement from 0.11.0 to 0.12.0 (#271) 
Updates the requirements on [itertools](https://github.com/rust-itertools/itertools) to permit the latest version.
- [Changelog](https://github.com/rust-itertools/itertools/blob/master/CHANGELOG.md)
- [Commits](https://github.com/rust-itertools/itertools/compare/v0.11.0...v0.12.0)

---
updated-dependencies:
- dependency-name: itertools
  dependency-type: direct:production
...

Signed-off-by: dependabot[bot] <support@github.com>
Co-authored-by: dependabot[bot] <49699333+dependabot[bot]@users.noreply.github.com>
 2023-11-20 22:00:34 -04:00
morenol
6f22bbd150 chore: update clippy lints (#272) 
* chore: fix clippy lints
---------

Co-authored-by: Luis Moreno <morenol@users.noreply.github.com>
 2023-11-20 21:54:09 -04:00
dependabot[bot]
dbdc2b2a77 Update itertools requirement from 0.10.5 to 0.11.0 (#266) 
Updates the requirements on [itertools](https://github.com/rust-itertools/itertools) to permit the latest version.
- [Changelog](https://github.com/rust-itertools/itertools/blob/master/CHANGELOG.md)
- [Commits](https://github.com/rust-itertools/itertools/compare/v0.10.5...v0.11.0)

---
updated-dependencies:
- dependency-name: itertools
  dependency-type: direct:production
...

Signed-off-by: dependabot[bot] <support@github.com>
Co-authored-by: dependabot[bot] <49699333+dependabot[bot]@users.noreply.github.com>
 2023-06-22 17:56:42 +01:00
Lorenzo
2d7c055154 Bump version 2023-05-01 13:20:17 +01:00
Ruben De Smet
545ed6ce2b Remove some allocations (#262) 
* Remove some allocations

* Remove some more allocations
 2023-04-26 21:46:26 +08:00
morenol
8939ed93b9 chore: fix clippy warnings from Rust release 1.69 (#263) 
* chore: fix clippy warnings from Rust release 1.69

* chore: run `cargo fmt`

* refactor: remove unused type parameter

---------

Co-authored-by: Luis Moreno <morenol@users.noreply.github.com>
 2023-04-26 01:35:58 +09:00
Lorenzo
9cd7348403 Update CONTRIBUTING.md 2023-04-10 15:13:27 +01:00
Hsiang-Cheng Yang
d52830a818 Update arrays.rs (#253) 
fix a typo
 2023-03-23 19:15:54 -04:00
Lorenzo
d15ea43975 Remove failure in case of failed upload to codecov.io 2023-03-20 15:08:30 +00:00
Lorenzo
f498f9629e Implement realnum::rand (#251) 
Co-authored-by: Luis Moreno <morenol@users.noreply.github.com>
Co-authored-by: Lorenzo <tunedconsulting@gmail.com>

* Implement rand. Use the new derive [#default]
* Use custom range
* Use range seed
* Bump version
* Add array length checks for
 2023-03-20 14:45:44 +00:00
Lorenzo
7d059c4fb1 Update README.md 2023-03-20 11:54:10 +00:00
morenol
c7353d0b57 Run cargo clippy --fix (#250) 
* Run `cargo clippy --fix`
* Run `cargo clippy --all-features --fix`
* Fix other clippy warnings
* cargo fmt

Co-authored-by: Luis Moreno <morenol@users.noreply.github.com>
 2023-01-27 10:41:18 +00:00
Lorenzo
83dcf9a8ac Delete iml file 2022-11-10 14:09:55 +00:00
Lorenzo (Mec-iS)
3126ee87d3 Pin deps version 2022-11-09 12:03:03 +00:00
78 changed files with 1498 additions and 1076 deletions
Expand all files Collapse all files
.github/CONTRIBUTING.md
+2
View File
@@ -37,6 +37,8 @@ $ rust-code-analysis-cli -p src/algorithm/neighbour/fastpair.rs --ls 22 --le 213
```
* find more information about what happens in your binary with [`twiggy`](https://rustwasm.github.io/twiggy/install.html). This need a compiled binary so create a brief `main {}` function using `smartcore` and then point `twiggy` to that file.
* Please take a look to the output of a profiler to spot most evident performance problems, see [this guide about using a profiler](http://www.codeofview.com/fix-rs/2017/01/24/how-to-optimize-rust-programs-on-linux/).
## Issue Report Process
1. Go to the project's issues.
.github/workflows/ci.yml
+1 -1
View File
@@ -36,7 +36,7 @@ jobs:
- name: Install Rust toolchain
uses: actions-rs/toolchain@v1
with:
toolchain: stable
toolchain: 1.81 # 1.82 seems to break wasm32 tests https://github.com/rustwasm/wasm-bindgen/issues/4274
target: ${{ matrix.platform.target }}
profile: minimal
default: true
.github/workflows/coverage.yml
+1 -1
View File
@@ -41,4 +41,4 @@ jobs:
- name: Upload to codecov.io
uses: codecov/codecov-action@v2
with:
fail_ci_if_error: true
fail_ci_if_error: false
CHANGELOG.md
+6
View File
@@ -4,6 +4,12 @@ All notable changes to this project will be documented in this file.
The format is based on [Keep a Changelog](https://keepachangelog.com/en/1.0.0/),
and this project adheres to [Semantic Versioning](https://semver.org/spec/v2.0.0.html).
## [0.4.0] - 2023-04-05
## Added
- WARNING: Breaking changes!
- `DenseMatrix` constructor now returns `Result` to avoid user instantiating inconsistent rows/cols count. Their return values need to be unwrapped with `unwrap()`, see tests
## [0.3.0] - 2022-11-09
## Added
Cargo.toml
+3 -3
View File
@@ -2,7 +2,7 @@
name = "smartcore"
description = "Machine Learning in Rust."
homepage = "https://smartcorelib.org"
version = "0.3.0"
version = "0.4.0"
authors = ["smartcore Developers"]
edition = "2021"
license = "Apache-2.0"
@@ -42,13 +42,13 @@ std_rand = ["rand/std_rng", "rand/std"]
js = ["getrandom/js"]
[target.'cfg(target_arch = "wasm32")'.dependencies]
getrandom = { version = "*", optional = true }
getrandom = { version = "0.2.8", optional = true }
[target.'cfg(all(target_arch = "wasm32", not(target_os = "wasi")))'.dev-dependencies]
wasm-bindgen-test = "0.3"
[dev-dependencies]
itertools = "*"
itertools = "0.13.0"
serde_json = "1.0"
bincode = "1.3.1"
README.md
+1 -1
View File
@@ -18,4 +18,4 @@
-----
[![CI](https://github.com/smartcorelib/smartcore/actions/workflows/ci.yml/badge.svg)](https://github.com/smartcorelib/smartcore/actions/workflows/ci.yml)
To start getting familiar with the new smartcore v0.5 API, there is now available a [**Jupyter Notebook environment repository**](https://github.com/smartcorelib/smartcore-jupyter). Please see instructions there, contributions welcome see [CONTRIBUTING](.github/CONTRIBUTING.md).
To start getting familiar with the new smartcore v0.3 API, there is now available a [**Jupyter Notebook environment repository**](https://github.com/smartcorelib/smartcore-jupyter). Please see instructions there, contributions welcome see [CONTRIBUTING](.github/CONTRIBUTING.md).
smartcore.iml
-15
View File
@@ -1,15 +0,0 @@
<?xml version="1.0" encoding="UTF-8"?>
<module type="RUST_MODULE" version="4">
<component name="NewModuleRootManager" inherit-compiler-output="true">
<exclude-output />
<content url="file://$MODULE_DIR$">
<sourceFolder url="file://$MODULE_DIR$/src" isTestSource="false" />
<sourceFolder url="file://$MODULE_DIR$/examples" isTestSource="false" />
<sourceFolder url="file://$MODULE_DIR$/tests" isTestSource="true" />
<sourceFolder url="file://$MODULE_DIR$/benches" isTestSource="true" />
<excludeFolder url="file://$MODULE_DIR$/target" />
</content>
<orderEntry type="inheritedJdk" />
<orderEntry type="sourceFolder" forTests="false" />
</component>
</module>
src/algorithm/neighbour/bbd_tree.rs
+4 -3
View File
@@ -40,11 +40,11 @@ impl BBDTreeNode {
impl BBDTree {
pub fn new<T: Number, M: Array2<T>>(data: &M) -> BBDTree {
let nodes = Vec::new();
let nodes: Vec<BBDTreeNode> = Vec::new();
let (n, _) = data.shape();
let index = (0..n).collect::<Vec<_>>();
let index = (0..n).collect::<Vec<usize>>();
let mut tree = BBDTree {
nodes,
@@ -343,7 +343,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let tree = BBDTree::new(&data);
src/algorithm/neighbour/cover_tree.rs
+4 -4
View File
@@ -124,7 +124,7 @@ impl<T: Debug + PartialEq, D: Distance<T>> CoverTree<T, D> {
current_cover_set.push((d, &self.root));
let mut heap = HeapSelection::with_capacity(k);
heap.add(std::f64::MAX);
heap.add(f64::MAX);
let mut empty_heap = true;
if !self.identical_excluded || self.get_data_value(self.root.idx) != p {
@@ -145,7 +145,7 @@ impl<T: Debug + PartialEq, D: Distance<T>> CoverTree<T, D> {
}
let upper_bound = if empty_heap {
std::f64::INFINITY
f64::INFINITY
} else {
*heap.peek()
};
@@ -291,7 +291,7 @@ impl<T: Debug + PartialEq, D: Distance<T>> CoverTree<T, D> {
} else {
let max_dist = self.max(point_set);
let next_scale = (max_scale - 1).min(self.get_scale(max_dist));
if next_scale == std::i64::MIN {
if next_scale == i64::MIN {
let mut children: Vec<Node> = Vec::new();
let mut leaf = self.new_leaf(p);
children.push(leaf);
@@ -435,7 +435,7 @@ impl<T: Debug + PartialEq, D: Distance<T>> CoverTree<T, D> {
fn get_scale(&self, d: f64) -> i64 {
if d == 0f64 {
std::i64::MIN
i64::MIN
} else {
(self.inv_log_base * d.ln()).ceil() as i64
}
src/algorithm/neighbour/fastpair.rs
+21 -29
View File
@@ -17,7 +17,7 @@
/// &[4.6, 3.1, 1.5, 0.2],
/// &[5.0, 3.6, 1.4, 0.2],
/// &[5.4, 3.9, 1.7, 0.4],
/// ]);
/// ]).unwrap();
/// let fastpair = FastPair::new(&x);
/// let closest_pair: PairwiseDistance<f64> = fastpair.unwrap().closest_pair();
/// ```
@@ -52,10 +52,8 @@ pub struct FastPair<'a, T: RealNumber + FloatNumber, M: Array2<T>> {
}
impl<'a, T: RealNumber + FloatNumber, M: Array2<T>> FastPair<'a, T, M> {
///
/// Constructor
/// Instantiate and inizialise the algorithm
///
/// Instantiate and initialize the algorithm
pub fn new(m: &'a M) -> Result<Self, Failed> {
if m.shape().0 < 3 {
return Err(Failed::because(
@@ -74,10 +72,8 @@ impl<'a, T: RealNumber + FloatNumber, M: Array2<T>> FastPair<'a, T, M> {
Ok(init)
}
///
/// Initialise `FastPair` by passing a `Array2`.
/// Build a FastPairs data-structure from a set of (new) points.
///
fn init(&mut self) {
// basic measures
let len = self.samples.shape().0;
@@ -158,9 +154,7 @@ impl<'a, T: RealNumber + FloatNumber, M: Array2<T>> FastPair<'a, T, M> {
self.neighbours = neighbours;
}
///
/// Find closest pair by scanning list of nearest neighbors.
///
#[allow(dead_code)]
pub fn closest_pair(&self) -> PairwiseDistance<T> {
let mut a = self.neighbours[0]; // Start with first point
@@ -217,9 +211,7 @@ mod tests_fastpair {
use super::*;
use crate::linalg::basic::{arrays::Array, matrix::DenseMatrix};
///
/// Brute force algorithm, used only for comparison and testing
///
pub fn closest_pair_brute(fastpair: &FastPair<f64, DenseMatrix<f64>>) -> PairwiseDistance<f64> {
use itertools::Itertools;
let m = fastpair.samples.shape().0;
@@ -260,8 +252,8 @@ mod tests_fastpair {
let distances = fastpair.distances;
let neighbours = fastpair.neighbours;
assert!(distances.len() != 0);
assert!(neighbours.len() != 0);
assert!(!distances.is_empty());
assert!(!neighbours.is_empty());
assert_eq!(10, neighbours.len());
assert_eq!(10, distances.len());
@@ -271,28 +263,24 @@ mod tests_fastpair {
fn dataset_has_at_least_three_points() {
// Create a dataset which consists of only two points:
// A(0.0, 0.0) and B(1.0, 1.0).
let dataset = DenseMatrix::<f64>::from_2d_array(&[&[0.0, 0.0], &[1.0, 1.0]]);
let dataset = DenseMatrix::<f64>::from_2d_array(&[&[0.0, 0.0], &[1.0, 1.0]]).unwrap();
// We expect an error when we run `FastPair` on this dataset,
// becuase `FastPair` currently only works on a minimum of 3
// points.
let _fastpair = FastPair::new(&dataset);
let fastpair = FastPair::new(&dataset);
assert!(fastpair.is_err());
match _fastpair {
Err(e) => {
let expected_error =
Failed::because(FailedError::FindFailed, "min number of rows should be 3");
assert_eq!(e, expected_error)
}
_ => {
assert!(false);
}
if let Err(e) = fastpair {
let expected_error =
Failed::because(FailedError::FindFailed, "min number of rows should be 3");
assert_eq!(e, expected_error)
}
}
#[test]
fn one_dimensional_dataset_minimal() {
let dataset = DenseMatrix::<f64>::from_2d_array(&[&[0.0], &[2.0], &[9.0]]);
let dataset = DenseMatrix::<f64>::from_2d_array(&[&[0.0], &[2.0], &[9.0]]).unwrap();
let result = FastPair::new(&dataset);
assert!(result.is_ok());
@@ -312,7 +300,8 @@ mod tests_fastpair {
#[test]
fn one_dimensional_dataset_2() {
let dataset = DenseMatrix::<f64>::from_2d_array(&[&[27.0], &[0.0], &[9.0], &[2.0]]);
let dataset =
DenseMatrix::<f64>::from_2d_array(&[&[27.0], &[0.0], &[9.0], &[2.0]]).unwrap();
let result = FastPair::new(&dataset);
assert!(result.is_ok());
@@ -347,7 +336,8 @@ mod tests_fastpair {
&[6.9, 3.1, 4.9, 1.5],
&[5.5, 2.3, 4.0, 1.3],
&[6.5, 2.8, 4.6, 1.5],
]);
])
.unwrap();
let fastpair = FastPair::new(&x);
assert!(fastpair.is_ok());
@@ -520,7 +510,8 @@ mod tests_fastpair {
&[6.9, 3.1, 4.9, 1.5],
&[5.5, 2.3, 4.0, 1.3],
&[6.5, 2.8, 4.6, 1.5],
]);
])
.unwrap();
// compute
let fastpair = FastPair::new(&x);
assert!(fastpair.is_ok());
@@ -568,7 +559,8 @@ mod tests_fastpair {
&[6.9, 3.1, 4.9, 1.5],
&[5.5, 2.3, 4.0, 1.3],
&[6.5, 2.8, 4.6, 1.5],
]);
])
.unwrap();
// compute
let fastpair = FastPair::new(&x);
assert!(fastpair.is_ok());
@@ -582,7 +574,7 @@ mod tests_fastpair {
};
for p in dissimilarities.iter() {
if p.distance.unwrap() < min_dissimilarity.distance.unwrap() {
min_dissimilarity = p.clone()
min_dissimilarity = *p
}
}
src/algorithm/neighbour/linear_search.rs
+2 -2
View File
@@ -61,7 +61,7 @@ impl<T, D: Distance<T>> LinearKNNSearch<T, D> {
for _ in 0..k {
heap.add(KNNPoint {
distance: std::f64::INFINITY,
distance: f64::INFINITY,
index: None,
});
}
@@ -215,7 +215,7 @@ mod tests {
};
let point_inf = KNNPoint {
distance: std::f64::INFINITY,
distance: f64::INFINITY,
index: Some(3),
};
src/algorithm/neighbour/mod.rs
+2 -7
View File
@@ -49,20 +49,15 @@ pub mod linear_search;
/// Both, KNN classifier and regressor benefits from underlying search algorithms that helps to speed up queries.
/// `KNNAlgorithmName` maintains a list of supported search algorithms, see [KNN algorithms](../algorithm/neighbour/index.html)
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Clone)]
#[derive(Debug, Clone, Default)]
pub enum KNNAlgorithmName {
/// Heap Search algorithm, see [`LinearSearch`](../algorithm/neighbour/linear_search/index.html)
LinearSearch,
/// Cover Tree Search algorithm, see [`CoverTree`](../algorithm/neighbour/cover_tree/index.html)
#[default]
CoverTree,
}
impl Default for KNNAlgorithmName {
fn default() -> Self {
KNNAlgorithmName::CoverTree
}
}
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug)]
pub(crate) enum KNNAlgorithm<T: Number, D: Distance<Vec<T>>> {
src/algorithm/sort/heap_select.rs
+2 -2
View File
@@ -133,7 +133,7 @@ mod tests {
#[test]
fn test_add1() {
let mut heap = HeapSelection::with_capacity(3);
heap.add(std::f64::INFINITY);
heap.add(f64::INFINITY);
heap.add(-5f64);
heap.add(4f64);
heap.add(-1f64);
@@ -151,7 +151,7 @@ mod tests {
#[test]
fn test_add2() {
let mut heap = HeapSelection::with_capacity(3);
heap.add(std::f64::INFINITY);
heap.add(f64::INFINITY);
heap.add(0.0);
heap.add(8.4852);
heap.add(5.6568);
src/algorithm/sort/quick_sort.rs
+1
View File
@@ -3,6 +3,7 @@ use num_traits::Num;
pub trait QuickArgSort {
fn quick_argsort_mut(&mut self) -> Vec<usize>;
#[allow(dead_code)]
fn quick_argsort(&self) -> Vec<usize>;
}
src/cluster/dbscan.rs
+7 -6
View File
@@ -18,7 +18,7 @@
//!
//! Example:
//!
//! ```
//! ```ignore
//! use smartcore::linalg::basic::matrix::DenseMatrix;
//! use smartcore::linalg::basic::arrays::Array2;
//! use smartcore::cluster::dbscan::*;
@@ -315,8 +315,7 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>, D: Distance<Vec<TX>>>
}
}
while !neighbors.is_empty() {
let neighbor = neighbors.pop().unwrap();
while let Some(neighbor) = neighbors.pop() {
let index = neighbor.0;
if y[index] == outlier {
@@ -443,7 +442,8 @@ mod tests {
&[2.2, 1.2],
&[1.8, 0.8],
&[3.0, 5.0],
]);
])
.unwrap();
let expected_labels = vec![1, 1, 1, 1, 1, 2, 2, 2, 2, 2, 0];
@@ -488,7 +488,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let dbscan = DBSCAN::fit(&x, Default::default()).unwrap();
@@ -511,6 +512,6 @@ mod tests {
.and_then(|dbscan| dbscan.predict(&x))
.unwrap();
println!("{:?}", labels);
println!("{labels:?}");
}
}
src/cluster/kmeans.rs
+13 -11
View File
@@ -41,7 +41,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//!
//! let kmeans = KMeans::fit(&x, KMeansParameters::default().with_k(2)).unwrap(); // Fit to data, 2 clusters
//! let y_hat: Vec<u8> = kmeans.predict(&x).unwrap(); // use the same points for prediction
@@ -96,7 +96,7 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>> PartialEq for KMeans<
return false;
}
for j in 0..self.centroids[i].len() {
if (self.centroids[i][j] - other.centroids[i][j]).abs() > std::f64::EPSILON {
if (self.centroids[i][j] - other.centroids[i][j]).abs() > f64::EPSILON {
return false;
}
}
@@ -249,7 +249,7 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>> Predictor<X, Y>
impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>> KMeans<TX, TY, X, Y> {
/// Fit algorithm to _NxM_ matrix where _N_ is number of samples and _M_ is number of features.
/// * `data` - training instances to cluster
/// * `data` - training instances to cluster
/// * `parameters` - cluster parameters
pub fn fit(data: &X, parameters: KMeansParameters) -> Result<KMeans<TX, TY, X, Y>, Failed> {
let bbd = BBDTree::new(data);
@@ -270,7 +270,7 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>> KMeans<TX, TY, X, Y>
let (n, d) = data.shape();
let mut distortion = std::f64::MAX;
let mut distortion = f64::MAX;
let mut y = KMeans::<TX, TY, X, Y>::kmeans_plus_plus(data, parameters.k, parameters.seed);
let mut size = vec![0; parameters.k];
let mut centroids = vec![vec![0f64; d]; parameters.k];
@@ -331,7 +331,7 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>> KMeans<TX, TY, X, Y>
let mut row = vec![0f64; x.shape().1];
for i in 0..n {
let mut min_dist = std::f64::MAX;
let mut min_dist = f64::MAX;
let mut best_cluster = 0;
for j in 0..self.k {
@@ -361,7 +361,7 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>> KMeans<TX, TY, X, Y>
.cloned()
.collect();
let mut d = vec![std::f64::MAX; n];
let mut d = vec![f64::MAX; n];
let mut row = vec![TX::zero(); data.shape().1];
for j in 1..k {
@@ -424,7 +424,7 @@ mod tests {
)]
#[test]
fn invalid_k() {
let x = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6]]);
let x = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6]]).unwrap();
assert!(KMeans::<i32, i32, DenseMatrix<i32>, Vec<i32>>::fit(
&x,
@@ -492,14 +492,15 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let kmeans = KMeans::fit(&x, Default::default()).unwrap();
let y: Vec<usize> = kmeans.predict(&x).unwrap();
for i in 0..y.len() {
assert_eq!(y[i] as usize, kmeans._y[i]);
for (i, _y_i) in y.iter().enumerate() {
assert_eq!({ y[i] }, kmeans._y[i]);
}
}
@@ -531,7 +532,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let kmeans: KMeans<f32, f32, DenseMatrix<f32>, Vec<f32>> =
KMeans::fit(&x, Default::default()).unwrap();
src/dataset/boston.rs
+1 -1
View File
@@ -31,7 +31,7 @@ use crate::dataset::Dataset;
pub fn load_dataset() -> Dataset<f32, f32> {
let (x, y, num_samples, num_features) = match deserialize_data(std::include_bytes!("boston.xy"))
{
Err(why) => panic!("Can't deserialize boston.xy. {}", why),
Err(why) => panic!("Can't deserialize boston.xy. {why}"),
Ok((x, y, num_samples, num_features)) => (x, y, num_samples, num_features),
};
src/dataset/breast_cancer.rs
+1 -1
View File
@@ -33,7 +33,7 @@ use crate::dataset::Dataset;
pub fn load_dataset() -> Dataset<f32, u32> {
let (x, y, num_samples, num_features) =
match deserialize_data(std::include_bytes!("breast_cancer.xy")) {
Err(why) => panic!("Can't deserialize breast_cancer.xy. {}", why),
Err(why) => panic!("Can't deserialize breast_cancer.xy. {why}"),
Ok((x, y, num_samples, num_features)) => (
x,
y.into_iter().map(|x| x as u32).collect(),
src/dataset/diabetes.rs
+2 -2
View File
@@ -26,7 +26,7 @@ use crate::dataset::Dataset;
pub fn load_dataset() -> Dataset<f32, u32> {
let (x, y, num_samples, num_features) =
match deserialize_data(std::include_bytes!("diabetes.xy")) {
Err(why) => panic!("Can't deserialize diabetes.xy. {}", why),
Err(why) => panic!("Can't deserialize diabetes.xy. {why}"),
Ok((x, y, num_samples, num_features)) => (
x,
y.into_iter().map(|x| x as u32).collect(),
@@ -40,7 +40,7 @@ pub fn load_dataset() -> Dataset<f32, u32> {
target: y,
num_samples,
num_features,
feature_names: vec![
feature_names: [
"Age", "Sex", "BMI", "BP", "S1", "S2", "S3", "S4", "S5", "S6",
]
.iter()
src/dataset/digits.rs
+4 -6
View File
@@ -16,7 +16,7 @@ use crate::dataset::Dataset;
pub fn load_dataset() -> Dataset<f32, f32> {
let (x, y, num_samples, num_features) = match deserialize_data(std::include_bytes!("digits.xy"))
{
Err(why) => panic!("Can't deserialize digits.xy. {}", why),
Err(why) => panic!("Can't deserialize digits.xy. {why}"),
Ok((x, y, num_samples, num_features)) => (x, y, num_samples, num_features),
};
@@ -25,16 +25,14 @@ pub fn load_dataset() -> Dataset<f32, f32> {
target: y,
num_samples,
num_features,
feature_names: vec![
"sepal length (cm)",
feature_names: ["sepal length (cm)",
"sepal width (cm)",
"petal length (cm)",
"petal width (cm)",
]
"petal width (cm)"]
.iter()
.map(|s| s.to_string())
.collect(),
target_names: vec!["setosa", "versicolor", "virginica"]
target_names: ["setosa", "versicolor", "virginica"]
.iter()
.map(|s| s.to_string())
.collect(),
src/dataset/iris.rs
+3 -3
View File
@@ -22,7 +22,7 @@ use crate::dataset::Dataset;
pub fn load_dataset() -> Dataset<f32, u32> {
let (x, y, num_samples, num_features): (Vec<f32>, Vec<u32>, usize, usize) =
match deserialize_data(std::include_bytes!("iris.xy")) {
Err(why) => panic!("Can't deserialize iris.xy. {}", why),
Err(why) => panic!("Can't deserialize iris.xy. {why}"),
Ok((x, y, num_samples, num_features)) => (
x,
y.into_iter().map(|x| x as u32).collect(),
@@ -36,7 +36,7 @@ pub fn load_dataset() -> Dataset<f32, u32> {
target: y,
num_samples,
num_features,
feature_names: vec![
feature_names: [
"sepal length (cm)",
"sepal width (cm)",
"petal length (cm)",
@@ -45,7 +45,7 @@ pub fn load_dataset() -> Dataset<f32, u32> {
.iter()
.map(|s| s.to_string())
.collect(),
target_names: vec!["setosa", "versicolor", "virginica"]
target_names: ["setosa", "versicolor", "virginica"]
.iter()
.map(|s| s.to_string())
.collect(),
src/dataset/mod.rs
+1 -1
View File
@@ -78,7 +78,7 @@ pub(crate) fn serialize_data<X: Number + RealNumber, Y: RealNumber>(
.collect();
file.write_all(&y)?;
}
Err(why) => panic!("couldn't create {}: {}", filename, why),
Err(why) => panic!("couldn't create {filename}: {why}"),
}
Ok(())
}
src/decomposition/pca.rs
+22 -18
View File
@@ -35,7 +35,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//!
//! let pca = PCA::fit(&iris, PCAParameters::default().with_n_components(2)).unwrap(); // Reduce number of features to 2
//!
@@ -231,8 +231,7 @@ impl<T: Number + RealNumber, X: Array2<T> + SVDDecomposable<T> + EVDDecomposable
if parameters.n_components > n {
return Err(Failed::fit(&format!(
"Number of components, n_components should be <= number of attributes ({})",
n
"Number of components, n_components should be <= number of attributes ({n})"
)));
}
@@ -374,21 +373,20 @@ mod tests {
let parameters = PCASearchParameters {
n_components: vec![2, 4],
use_correlation_matrix: vec![true, false],
..Default::default()
};
let mut iter = parameters.into_iter();
let next = iter.next().unwrap();
assert_eq!(next.n_components, 2);
assert_eq!(next.use_correlation_matrix, true);
assert!(next.use_correlation_matrix);
let next = iter.next().unwrap();
assert_eq!(next.n_components, 4);
assert_eq!(next.use_correlation_matrix, true);
assert!(next.use_correlation_matrix);
let next = iter.next().unwrap();
assert_eq!(next.n_components, 2);
assert_eq!(next.use_correlation_matrix, false);
assert!(!next.use_correlation_matrix);
let next = iter.next().unwrap();
assert_eq!(next.n_components, 4);
assert_eq!(next.use_correlation_matrix, false);
assert!(!next.use_correlation_matrix);
assert!(iter.next().is_none());
}
@@ -445,6 +443,7 @@ mod tests {
&[2.6, 53.0, 66.0, 10.8],
&[6.8, 161.0, 60.0, 15.6],
])
.unwrap()
}
#[cfg_attr(
all(target_arch = "wasm32", not(target_os = "wasi")),
@@ -459,7 +458,8 @@ mod tests {
&[0.9952, 0.0588],
&[0.0463, 0.9769],
&[0.0752, 0.2007],
]);
])
.unwrap();
let pca = PCA::fit(&us_arrests, Default::default()).unwrap();
@@ -502,7 +502,8 @@ mod tests {
-0.974080592182491,
0.0723250196376097,
],
]);
])
.unwrap();
let expected_projection = DenseMatrix::from_2d_array(&[
&[-64.8022, -11.448, 2.4949, -2.4079],
@@ -555,7 +556,8 @@ mod tests {
&[91.5446, -22.9529, 0.402, -0.7369],
&[118.1763, 5.5076, 2.7113, -0.205],
&[10.4345, -5.9245, 3.7944, 0.5179],
]);
])
.unwrap();
let expected_eigenvalues: Vec<f64> = vec![
343544.6277001563,
@@ -572,8 +574,8 @@ mod tests {
epsilon = 1e-4
));
for i in 0..pca.eigenvalues.len() {
assert!((pca.eigenvalues[i].abs() - expected_eigenvalues[i].abs()).abs() < 1e-8);
for (i, pca_eigenvalues_i) in pca.eigenvalues.iter().enumerate() {
assert!((pca_eigenvalues_i.abs() - expected_eigenvalues[i].abs()).abs() < 1e-8);
}
let us_arrests_t = pca.transform(&us_arrests).unwrap();
@@ -618,7 +620,8 @@ mod tests {
-0.0881962972508558,
-0.0096011588898465,
],
]);
])
.unwrap();
let expected_projection = DenseMatrix::from_2d_array(&[
&[0.9856, -1.1334, 0.4443, -0.1563],
@@ -671,7 +674,8 @@ mod tests {
&[-2.1086, -1.4248, -0.1048, -0.1319],
&[-2.0797, 0.6113, 0.1389, -0.1841],
&[-0.6294, -0.321, 0.2407, 0.1667],
]);
])
.unwrap();
let expected_eigenvalues: Vec<f64> = vec![
2.480241579149493,
@@ -694,8 +698,8 @@ mod tests {
epsilon = 1e-4
));
for i in 0..pca.eigenvalues.len() {
assert!((pca.eigenvalues[i].abs() - expected_eigenvalues[i].abs()).abs() < 1e-8);
for (i, pca_eigenvalues_i) in pca.eigenvalues.iter().enumerate() {
assert!((pca_eigenvalues_i.abs() - expected_eigenvalues[i].abs()).abs() < 1e-8);
}
let us_arrests_t = pca.transform(&us_arrests).unwrap();
@@ -734,7 +738,7 @@ mod tests {
// &[4.9, 2.4, 3.3, 1.0],
// &[6.6, 2.9, 4.6, 1.3],
// &[5.2, 2.7, 3.9, 1.4],
// ]);
// ]).unwrap();
// let pca = PCA::fit(&iris, Default::default()).unwrap();
src/decomposition/svd.rs
+8 -9
View File
@@ -32,7 +32,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//!
//! let svd = SVD::fit(&iris, SVDParameters::default().
//! with_n_components(2)).unwrap(); // Reduce number of features to 2
@@ -180,8 +180,7 @@ impl<T: Number + RealNumber, X: Array2<T> + SVDDecomposable<T> + EVDDecomposable
if parameters.n_components >= p {
return Err(Failed::fit(&format!(
"Number of components, n_components should be < number of attributes ({})",
p
"Number of components, n_components should be < number of attributes ({p})"
)));
}
@@ -202,8 +201,7 @@ impl<T: Number + RealNumber, X: Array2<T> + SVDDecomposable<T> + EVDDecomposable
let (p_c, k) = self.components.shape();
if p_c != p {
return Err(Failed::transform(&format!(
"Can not transform a {}x{} matrix into {}x{} matrix, incorrect input dimentions",
n, p, n, k
"Can not transform a {n}x{p} matrix into {n}x{k} matrix, incorrect input dimentions"
)));
}
@@ -227,7 +225,6 @@ mod tests {
fn search_parameters() {
let parameters = SVDSearchParameters {
n_components: vec![10, 100],
..Default::default()
};
let mut iter = parameters.into_iter();
let next = iter.next().unwrap();
@@ -295,7 +292,8 @@ mod tests {
&[5.7, 81.0, 39.0, 9.3],
&[2.6, 53.0, 66.0, 10.8],
&[6.8, 161.0, 60.0, 15.6],
]);
])
.unwrap();
let expected = DenseMatrix::from_2d_array(&[
&[243.54655757, -18.76673788],
@@ -303,7 +301,8 @@ mod tests {
&[305.93972467, -15.39087376],
&[197.28420365, -11.66808306],
&[293.43187394, 1.91163633],
]);
])
.unwrap();
let svd = SVD::fit(&x, Default::default()).unwrap();
let x_transformed = svd.transform(&x).unwrap();
@@ -344,7 +343,7 @@ mod tests {
// &[4.9, 2.4, 3.3, 1.0],
// &[6.6, 2.9, 4.6, 1.3],
// &[5.2, 2.7, 3.9, 1.4],
// ]);
// ]).unwrap();
// let svd = SVD::fit(&iris, Default::default()).unwrap();
src/ensemble/random_forest_classifier.rs
+36 -5
View File
@@ -33,7 +33,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//! let y = vec![
//! 0, 0, 0, 0, 0, 0, 0, 0,
//! 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
@@ -454,8 +454,12 @@ impl<TX: FloatNumber + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY
y: &Y,
parameters: RandomForestClassifierParameters,
) -> Result<RandomForestClassifier<TX, TY, X, Y>, Failed> {
let (_, num_attributes) = x.shape();
let (x_nrows, num_attributes) = x.shape();
let y_ncols = y.shape();
if x_nrows != y_ncols {
return Err(Failed::fit("Number of rows in X should = len(y)"));
}
let mut yi: Vec<usize> = vec![0; y_ncols];
let classes = y.unique();
@@ -656,7 +660,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y = vec![0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
let classifier = RandomForestClassifier::fit(
@@ -678,6 +683,30 @@ mod tests {
assert!(accuracy(&y, &classifier.predict(&x).unwrap()) >= 0.95);
}
#[test]
fn test_random_matrix_with_wrong_rownum() {
let x_rand: DenseMatrix<f64> = DenseMatrix::<f64>::rand(21, 200);
let y: Vec<u32> = vec![0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
let fail = RandomForestClassifier::fit(
&x_rand,
&y,
RandomForestClassifierParameters {
criterion: SplitCriterion::Gini,
max_depth: Option::None,
min_samples_leaf: 1,
min_samples_split: 2,
n_trees: 100,
m: Option::None,
keep_samples: false,
seed: 87,
},
);
assert!(fail.is_err());
}
#[cfg_attr(
all(target_arch = "wasm32", not(target_os = "wasi")),
wasm_bindgen_test::wasm_bindgen_test
@@ -705,7 +734,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y = vec![0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
let classifier = RandomForestClassifier::fit(
@@ -758,7 +788,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y = vec![0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
let forest = RandomForestClassifier::fit(&x, &y, Default::default()).unwrap();
src/ensemble/random_forest_regressor.rs
+37 -4
View File
@@ -29,7 +29,7 @@
//! &[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
//! &[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
//! &[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
//! ]);
//! ]).unwrap();
//! let y = vec![
//! 83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2,
//! 104.6, 108.4, 110.8, 112.6, 114.2, 115.7, 116.9
@@ -399,6 +399,10 @@ impl<TX: Number + FloatNumber + PartialOrd, TY: Number, X: Array2<TX>, Y: Array1
) -> Result<RandomForestRegressor<TX, TY, X, Y>, Failed> {
let (n_rows, num_attributes) = x.shape();
if n_rows != y.shape() {
return Err(Failed::fit("Number of rows in X should = len(y)"));
}
let mtry = parameters
.m
.unwrap_or((num_attributes as f64).sqrt().floor() as usize);
@@ -570,7 +574,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
114.2, 115.7, 116.9,
@@ -595,6 +600,32 @@ mod tests {
assert!(mean_absolute_error(&y, &y_hat) < 1.0);
}
#[test]
fn test_random_matrix_with_wrong_rownum() {
let x_rand: DenseMatrix<f64> = DenseMatrix::<f64>::rand(17, 200);
let y = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
114.2, 115.7, 116.9,
];
let fail = RandomForestRegressor::fit(
&x_rand,
&y,
RandomForestRegressorParameters {
max_depth: Option::None,
min_samples_leaf: 1,
min_samples_split: 2,
n_trees: 1000,
m: Option::None,
keep_samples: false,
seed: 87,
},
);
assert!(fail.is_err());
}
#[cfg_attr(
all(target_arch = "wasm32", not(target_os = "wasi")),
wasm_bindgen_test::wasm_bindgen_test
@@ -618,7 +649,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
114.2, 115.7, 116.9,
@@ -672,7 +704,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
114.2, 115.7, 116.9,
src/error/mod.rs
+21 -2
View File
@@ -30,8 +30,10 @@ pub enum FailedError {
DecompositionFailed,
/// Can't solve for x
SolutionFailed,
/// Erro in input
/// Error in input parameters
ParametersError,
/// Invalid state error (should never happen)
InvalidStateError,
}
impl Failed {
@@ -64,6 +66,22 @@ impl Failed {
}
}
/// new instance of `FailedError::ParametersError`
pub fn input(msg: &str) -> Self {
Failed {
err: FailedError::ParametersError,
msg: msg.to_string(),
}
}
/// new instance of `FailedError::InvalidStateError`
pub fn invalid_state(msg: &str) -> Self {
Failed {
err: FailedError::InvalidStateError,
msg: msg.to_string(),
}
}
/// new instance of `err`
pub fn because(err: FailedError, msg: &str) -> Self {
Failed {
@@ -97,8 +115,9 @@ impl fmt::Display for FailedError {
FailedError::DecompositionFailed => "Decomposition failed",
FailedError::SolutionFailed => "Can't find solution",
FailedError::ParametersError => "Error in input, check parameters",
FailedError::InvalidStateError => "Invalid state, this should never happen", // useful in development phase of lib
};
write!(f, "{}", failed_err_str)
write!(f, "{failed_err_str}")
}
}
src/lib.rs
+3 -2
View File
@@ -3,7 +3,8 @@
clippy::too_many_arguments,
clippy::many_single_char_names,
clippy::unnecessary_wraps,
clippy::upper_case_acronyms
clippy::upper_case_acronyms,
clippy::approx_constant
)]
#![warn(missing_docs)]
#![warn(rustdoc::missing_doc_code_examples)]
@@ -63,7 +64,7 @@
//! &[3., 4.],
//! &[5., 6.],
//! &[7., 8.],
//! &[9., 10.]]);
//! &[9., 10.]]).unwrap();
//! // Our classes are defined as a vector
//! let y = vec![2, 2, 2, 3, 3];
//!
src/linalg/basic/arrays.rs
+213 -194
View File
File diff suppressed because it is too large Load Diff
src/linalg/basic/matrix.rs
+223 -94
View File
@@ -19,6 +19,8 @@ use crate::linalg::traits::svd::SVDDecomposable;
use crate::numbers::basenum::Number;
use crate::numbers::realnum::RealNumber;
use crate::error::Failed;
/// Dense matrix
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Clone)]
@@ -50,26 +52,26 @@ pub struct DenseMatrixMutView<'a, T: Debug + Display + Copy + Sized> {
}
impl<'a, T: Debug + Display + Copy + Sized> DenseMatrixView<'a, T> {
fn new(m: &'a DenseMatrix<T>, rows: Range<usize>, cols: Range<usize>) -> Self {
let (start, end, stride) = if m.column_major {
(
rows.start + cols.start * m.nrows,
rows.end + (cols.end - 1) * m.nrows,
m.nrows,
)
fn new(
m: &'a DenseMatrix<T>,
vrows: Range<usize>,
vcols: Range<usize>,
) -> Result<Self, Failed> {
if m.is_valid_view(m.shape().0, m.shape().1, &vrows, &vcols) {
Err(Failed::input(
"The specified view is outside of the matrix range",
))
} else {
(
rows.start * m.ncols + cols.start,
(rows.end - 1) * m.ncols + cols.end,
m.ncols,
)
};
DenseMatrixView {
values: &m.values[start..end],
stride,
nrows: rows.end - rows.start,
ncols: cols.end - cols.start,
column_major: m.column_major,
let (start, end, stride) =
m.stride_range(m.shape().0, m.shape().1, &vrows, &vcols, m.column_major);
Ok(DenseMatrixView {
values: &m.values[start..end],
stride,
nrows: vrows.end - vrows.start,
ncols: vcols.end - vcols.start,
column_major: m.column_major,
})
}
}
@@ -102,26 +104,26 @@ impl<'a, T: Debug + Display + Copy + Sized> fmt::Display for DenseMatrixView<'a,
}
impl<'a, T: Debug + Display + Copy + Sized> DenseMatrixMutView<'a, T> {
fn new(m: &'a mut DenseMatrix<T>, rows: Range<usize>, cols: Range<usize>) -> Self {
let (start, end, stride) = if m.column_major {
(
rows.start + cols.start * m.nrows,
rows.end + (cols.end - 1) * m.nrows,
m.nrows,
)
fn new(
m: &'a mut DenseMatrix<T>,
vrows: Range<usize>,
vcols: Range<usize>,
) -> Result<Self, Failed> {
if m.is_valid_view(m.shape().0, m.shape().1, &vrows, &vcols) {
Err(Failed::input(
"The specified view is outside of the matrix range",
))
} else {
(
rows.start * m.ncols + cols.start,
(rows.end - 1) * m.ncols + cols.end,
m.ncols,
)
};
DenseMatrixMutView {
values: &mut m.values[start..end],
stride,
nrows: rows.end - rows.start,
ncols: cols.end - cols.start,
column_major: m.column_major,
let (start, end, stride) =
m.stride_range(m.shape().0, m.shape().1, &vrows, &vcols, m.column_major);
Ok(DenseMatrixMutView {
values: &mut m.values[start..end],
stride,
nrows: vrows.end - vrows.start,
ncols: vcols.end - vcols.start,
column_major: m.column_major,
})
}
}
@@ -182,42 +184,102 @@ impl<'a, T: Debug + Display + Copy + Sized> fmt::Display for DenseMatrixMutView<
impl<T: Debug + Display + Copy + Sized> DenseMatrix<T> {
/// Create new instance of `DenseMatrix` without copying data.
/// `values` should be in column-major order.
pub fn new(nrows: usize, ncols: usize, values: Vec<T>, column_major: bool) -> Self {
DenseMatrix {
ncols,
nrows,
values,
column_major,
pub fn new(
nrows: usize,
ncols: usize,
values: Vec<T>,
column_major: bool,
) -> Result<Self, Failed> {
let data_len = values.len();
if nrows * ncols != values.len() {
Err(Failed::input(&format!(
"The specified shape: (cols: {ncols}, rows: {nrows}) does not align with data len: {data_len}"
)))
} else {
Ok(DenseMatrix {
ncols,
nrows,
values,
column_major,
})
}
}
/// New instance of `DenseMatrix` from 2d array.
pub fn from_2d_array(values: &[&[T]]) -> Self {
pub fn from_2d_array(values: &[&[T]]) -> Result<Self, Failed> {
DenseMatrix::from_2d_vec(&values.iter().map(|row| Vec::from(*row)).collect())
}
/// New instance of `DenseMatrix` from 2d vector.
pub fn from_2d_vec(values: &Vec<Vec<T>>) -> Self {
let nrows = values.len();
let ncols = values
.first()
.unwrap_or_else(|| panic!("Cannot create 2d matrix from an empty vector"))
.len();
let mut m_values = Vec::with_capacity(nrows * ncols);
#[allow(clippy::ptr_arg)]
pub fn from_2d_vec(values: &Vec<Vec<T>>) -> Result<Self, Failed> {
if values.is_empty() || values[0].is_empty() {
Err(Failed::input(
"The 2d vec provided is empty; cannot instantiate the matrix",
))
} else {
let nrows = values.len();
let ncols = values
.first()
.unwrap_or_else(|| {
panic!("Invalid state: Cannot create 2d matrix from an empty vector")
})
.len();
let mut m_values = Vec::with_capacity(nrows * ncols);
for c in 0..ncols {
for r in values.iter().take(nrows) {
m_values.push(r[c])
for c in 0..ncols {
for r in values.iter().take(nrows) {
m_values.push(r[c])
}
}
}
DenseMatrix::new(nrows, ncols, m_values, true)
DenseMatrix::new(nrows, ncols, m_values, true)
}
}
/// Iterate over values of matrix
pub fn iter(&self) -> Iter<'_, T> {
self.values.iter()
}
/// Check if the size of the requested view is bounded to matrix rows/cols count
fn is_valid_view(
&self,
n_rows: usize,
n_cols: usize,
vrows: &Range<usize>,
vcols: &Range<usize>,
) -> bool {
!(vrows.end <= n_rows
&& vcols.end <= n_cols
&& vrows.start <= n_rows
&& vcols.start <= n_cols)
}
/// Compute the range of the requested view: start, end, size of the slice
fn stride_range(
&self,
n_rows: usize,
n_cols: usize,
vrows: &Range<usize>,
vcols: &Range<usize>,
column_major: bool,
) -> (usize, usize, usize) {
let (start, end, stride) = if column_major {
(
vrows.start + vcols.start * n_rows,
vrows.end + (vcols.end - 1) * n_rows,
n_rows,
)
} else {
(
vrows.start * n_cols + vcols.start,
(vrows.end - 1) * n_cols + vcols.end,
n_cols,
)
};
(start, end, stride)
}
}
impl<T: Debug + Display + Copy + Sized> fmt::Display for DenseMatrix<T> {
@@ -304,6 +366,7 @@ where
impl<T: Debug + Display + Copy + Sized> Array<T, (usize, usize)> for DenseMatrix<T> {
fn get(&self, pos: (usize, usize)) -> &T {
let (row, col) = pos;
if row >= self.nrows || col >= self.ncols {
panic!(
"Invalid index ({},{}) for {}x{} matrix",
@@ -383,15 +446,15 @@ impl<T: Debug + Display + Copy + Sized> MutArrayView2<T> for DenseMatrix<T> {}
impl<T: Debug + Display + Copy + Sized> Array2<T> for DenseMatrix<T> {
fn get_row<'a>(&'a self, row: usize) -> Box<dyn ArrayView1<T> + 'a> {
Box::new(DenseMatrixView::new(self, row..row + 1, 0..self.ncols))
Box::new(DenseMatrixView::new(self, row..row + 1, 0..self.ncols).unwrap())
}
fn get_col<'a>(&'a self, col: usize) -> Box<dyn ArrayView1<T> + 'a> {
Box::new(DenseMatrixView::new(self, 0..self.nrows, col..col + 1))
Box::new(DenseMatrixView::new(self, 0..self.nrows, col..col + 1).unwrap())
}
fn slice<'a>(&'a self, rows: Range<usize>, cols: Range<usize>) -> Box<dyn ArrayView2<T> + 'a> {
Box::new(DenseMatrixView::new(self, rows, cols))
Box::new(DenseMatrixView::new(self, rows, cols).unwrap())
}
fn slice_mut<'a>(
@@ -402,15 +465,17 @@ impl<T: Debug + Display + Copy + Sized> Array2<T> for DenseMatrix<T> {
where
Self: Sized,
{
Box::new(DenseMatrixMutView::new(self, rows, cols))
Box::new(DenseMatrixMutView::new(self, rows, cols).unwrap())
}
// private function so for now assume infalible
fn fill(nrows: usize, ncols: usize, value: T) -> Self {
DenseMatrix::new(nrows, ncols, vec![value; nrows * ncols], true)
DenseMatrix::new(nrows, ncols, vec![value; nrows * ncols], true).unwrap()
}
// private function so for now assume infalible
fn from_iterator<I: Iterator<Item = T>>(iter: I, nrows: usize, ncols: usize, axis: u8) -> Self {
DenseMatrix::new(nrows, ncols, iter.collect(), axis != 0)
DenseMatrix::new(nrows, ncols, iter.collect(), axis != 0).unwrap()
}
fn transpose(&self) -> Self {
@@ -431,9 +496,9 @@ impl<T: Number + RealNumber> SVDDecomposable<T> for DenseMatrix<T> {}
impl<'a, T: Debug + Display + Copy + Sized> Array<T, (usize, usize)> for DenseMatrixView<'a, T> {
fn get(&self, pos: (usize, usize)) -> &T {
if self.column_major {
&self.values[(pos.0 + pos.1 * self.stride)]
&self.values[pos.0 + pos.1 * self.stride]
} else {
&self.values[(pos.0 * self.stride + pos.1)]
&self.values[pos.0 * self.stride + pos.1]
}
}
@@ -495,9 +560,9 @@ impl<'a, T: Debug + Display + Copy + Sized> ArrayView1<T> for DenseMatrixView<'a
impl<'a, T: Debug + Display + Copy + Sized> Array<T, (usize, usize)> for DenseMatrixMutView<'a, T> {
fn get(&self, pos: (usize, usize)) -> &T {
if self.column_major {
&self.values[(pos.0 + pos.1 * self.stride)]
&self.values[pos.0 + pos.1 * self.stride]
} else {
&self.values[(pos.0 * self.stride + pos.1)]
&self.values[pos.0 * self.stride + pos.1]
}
}
@@ -519,9 +584,9 @@ impl<'a, T: Debug + Display + Copy + Sized> MutArray<T, (usize, usize)>
{
fn set(&mut self, pos: (usize, usize), x: T) {
if self.column_major {
self.values[(pos.0 + pos.1 * self.stride)] = x;
self.values[pos.0 + pos.1 * self.stride] = x;
} else {
self.values[(pos.0 * self.stride + pos.1)] = x;
self.values[pos.0 * self.stride + pos.1] = x;
}
}
@@ -544,15 +609,74 @@ mod tests {
use approx::relative_eq;
#[test]
fn test_display() {
fn test_instantiate_from_2d() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]);
assert!(x.is_ok());
}
#[test]
fn test_instantiate_from_2d_empty() {
let input: &[&[f64]] = &[&[]];
let x = DenseMatrix::from_2d_array(input);
assert!(x.is_err());
}
#[test]
fn test_instantiate_from_2d_empty2() {
let input: &[&[f64]] = &[&[], &[]];
let x = DenseMatrix::from_2d_array(input);
assert!(x.is_err());
}
#[test]
fn test_instantiate_ok_view1() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
let v = DenseMatrixView::new(&x, 0..2, 0..2);
assert!(v.is_ok());
}
#[test]
fn test_instantiate_ok_view2() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
let v = DenseMatrixView::new(&x, 0..3, 0..3);
assert!(v.is_ok());
}
#[test]
fn test_instantiate_ok_view3() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
let v = DenseMatrixView::new(&x, 2..3, 0..3);
assert!(v.is_ok());
}
#[test]
fn test_instantiate_ok_view4() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
let v = DenseMatrixView::new(&x, 3..3, 0..3);
assert!(v.is_ok());
}
#[test]
fn test_instantiate_err_view1() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
let v = DenseMatrixView::new(&x, 3..4, 0..3);
assert!(v.is_err());
}
#[test]
fn test_instantiate_err_view2() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
let v = DenseMatrixView::new(&x, 0..3, 3..4);
assert!(v.is_err());
}
#[test]
fn test_instantiate_err_view3() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
let v = DenseMatrixView::new(&x, 0..3, 4..3);
assert!(v.is_err());
}
#[test]
fn test_display() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
println!("{}", &x);
}
#[test]
fn test_get_row_col() {
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]);
let x = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
assert_eq!(15.0, x.get_col(1).sum());
assert_eq!(15.0, x.get_row(1).sum());
@@ -561,7 +685,7 @@ mod tests {
#[test]
fn test_row_major() {
let mut x = DenseMatrix::new(2, 3, vec![1, 2, 3, 4, 5, 6], false);
let mut x = DenseMatrix::new(2, 3, vec![1, 2, 3, 4, 5, 6], false).unwrap();
assert_eq!(5, *x.get_col(1).get(1));
assert_eq!(7, x.get_col(1).sum());
@@ -575,21 +699,22 @@ mod tests {
#[test]
fn test_get_slice() {
let x = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6], &[7, 8, 9], &[10, 11, 12]]);
let x = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6], &[7, 8, 9], &[10, 11, 12]])
.unwrap();
assert_eq!(
vec![4, 5, 6],
DenseMatrix::from_slice(&(*x.slice(1..2, 0..3))).values
);
let second_row: Vec<i32> = x.slice(1..2, 0..3).iterator(0).map(|x| *x).collect();
let second_row: Vec<i32> = x.slice(1..2, 0..3).iterator(0).copied().collect();
assert_eq!(vec![4, 5, 6], second_row);
let second_col: Vec<i32> = x.slice(0..3, 1..2).iterator(0).map(|x| *x).collect();
let second_col: Vec<i32> = x.slice(0..3, 1..2).iterator(0).copied().collect();
assert_eq!(vec![2, 5, 8], second_col);
}
#[test]
fn test_iter_mut() {
let mut x = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6], &[7, 8, 9]]);
let mut x = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6], &[7, 8, 9]]).unwrap();
assert_eq!(vec![1, 4, 7, 2, 5, 8, 3, 6, 9], x.values);
// add +2 to some elements
@@ -625,7 +750,8 @@ mod tests {
#[test]
fn test_str_array() {
let mut x =
DenseMatrix::from_2d_array(&[&["1", "2", "3"], &["4", "5", "6"], &["7", "8", "9"]]);
DenseMatrix::from_2d_array(&[&["1", "2", "3"], &["4", "5", "6"], &["7", "8", "9"]])
.unwrap();
assert_eq!(vec!["1", "4", "7", "2", "5", "8", "3", "6", "9"], x.values);
x.iterator_mut(0).for_each(|v| *v = "str");
@@ -637,20 +763,20 @@ mod tests {
#[test]
fn test_transpose() {
let x = DenseMatrix::<&str>::from_2d_array(&[&["1", "2", "3"], &["4", "5", "6"]]);
let x = DenseMatrix::<&str>::from_2d_array(&[&["1", "2", "3"], &["4", "5", "6"]]).unwrap();
assert_eq!(vec!["1", "4", "2", "5", "3", "6"], x.values);
assert!(x.column_major == true);
assert!(x.column_major);
// transpose
let x = x.transpose();
assert_eq!(vec!["1", "4", "2", "5", "3", "6"], x.values);
assert!(x.column_major == false); // should change column_major
assert!(!x.column_major); // should change column_major
}
#[test]
fn test_from_iterator() {
let data = vec![1, 2, 3, 4, 5, 6];
let data = [1, 2, 3, 4, 5, 6];
let m = DenseMatrix::from_iterator(data.iter(), 2, 3, 0);
@@ -659,25 +785,25 @@ mod tests {
vec![1, 2, 3, 4, 5, 6],
m.values.iter().map(|e| **e).collect::<Vec<i32>>()
);
assert!(m.column_major == false);
assert!(!m.column_major);
}
#[test]
fn test_take() {
let a = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6]]);
let b = DenseMatrix::from_2d_array(&[&[1, 2], &[3, 4], &[5, 6]]);
let a = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6]]).unwrap();
let b = DenseMatrix::from_2d_array(&[&[1, 2], &[3, 4], &[5, 6]]).unwrap();
println!("{}", a);
println!("{a}");
// take column 0 and 2
assert_eq!(vec![1, 3, 4, 6], a.take(&[0, 2], 1).values);
println!("{}", b);
println!("{b}");
// take rows 0 and 2
assert_eq!(vec![1, 2, 5, 6], b.take(&[0, 2], 0).values);
}
#[test]
fn test_mut() {
let a = DenseMatrix::from_2d_array(&[&[1.3, -2.1, 3.4], &[-4., -5.3, 6.1]]);
let a = DenseMatrix::from_2d_array(&[&[1.3, -2.1, 3.4], &[-4., -5.3, 6.1]]).unwrap();
let a = a.abs();
assert_eq!(vec![1.3, 4.0, 2.1, 5.3, 3.4, 6.1], a.values);
@@ -688,26 +814,29 @@ mod tests {
#[test]
fn test_reshape() {
let a = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6], &[7, 8, 9], &[10, 11, 12]]);
let a = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6], &[7, 8, 9], &[10, 11, 12]])
.unwrap();
let a = a.reshape(2, 6, 0);
assert_eq!(vec![1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12], a.values);
assert!(a.ncols == 6 && a.nrows == 2 && a.column_major == false);
assert!(a.ncols == 6 && a.nrows == 2 && !a.column_major);
let a = a.reshape(3, 4, 1);
assert_eq!(vec![1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12], a.values);
assert!(a.ncols == 4 && a.nrows == 3 && a.column_major == true);
assert!(a.ncols == 4 && a.nrows == 3 && a.column_major);
}
#[test]
fn test_eq() {
let a = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.]]);
let b = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]);
let a = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.]]).unwrap();
let b = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[4., 5., 6.], &[7., 8., 9.]]).unwrap();
let c = DenseMatrix::from_2d_array(&[
&[1. + f32::EPSILON, 2., 3.],
&[4., 5., 6. + f32::EPSILON],
]);
let d = DenseMatrix::from_2d_array(&[&[1. + 0.5, 2., 3.], &[4., 5., 6. + f32::EPSILON]]);
])
.unwrap();
let d = DenseMatrix::from_2d_array(&[&[1. + 0.5, 2., 3.], &[4., 5., 6. + f32::EPSILON]])
.unwrap();
assert!(!relative_eq!(a, b));
assert!(!relative_eq!(a, d));
src/linalg/basic/vector.rs
+25 -4
View File
@@ -15,6 +15,25 @@ pub struct VecView<'a, T: Debug + Display + Copy + Sized> {
ptr: &'a [T],
}
impl<T: Debug + Display + Copy + Sized> Array<T, usize> for &[T] {
fn get(&self, i: usize) -> &T {
&self[i]
}
fn shape(&self) -> usize {
self.len()
}
fn is_empty(&self) -> bool {
self.len() > 0
}
fn iterator<'b>(&'b self, axis: u8) -> Box<dyn Iterator<Item = &'b T> + 'b> {
assert!(axis == 0, "For one dimensional array `axis` should == 0");
Box::new(self.iter())
}
}
impl<T: Debug + Display + Copy + Sized> Array<T, usize> for Vec<T> {
fn get(&self, i: usize) -> &T {
&self[i]
@@ -36,6 +55,7 @@ impl<T: Debug + Display + Copy + Sized> Array<T, usize> for Vec<T> {
impl<T: Debug + Display + Copy + Sized> MutArray<T, usize> for Vec<T> {
fn set(&mut self, i: usize, x: T) {
// NOTE: this panics in case of out of bounds index
self[i] = x
}
@@ -46,6 +66,7 @@ impl<T: Debug + Display + Copy + Sized> MutArray<T, usize> for Vec<T> {
}
impl<T: Debug + Display + Copy + Sized> ArrayView1<T> for Vec<T> {}
impl<T: Debug + Display + Copy + Sized> ArrayView1<T> for &[T] {}
impl<T: Debug + Display + Copy + Sized> MutArrayView1<T> for Vec<T> {}
@@ -160,8 +181,8 @@ mod tests {
fn dot_product<T: Number, V: Array1<T>>(v: &V) -> T {
let vv = V::zeros(10);
let v_s = vv.slice(0..3);
let dot = v_s.dot(v);
dot
v_s.dot(v)
}
fn vector_ops<T: Number + PartialOrd, V: Array1<T>>(_: &V) -> T {
@@ -191,7 +212,7 @@ mod tests {
#[test]
fn test_len() {
let x = vec![1, 2, 3];
let x = [1, 2, 3];
assert_eq!(3, x.len());
}
@@ -216,7 +237,7 @@ mod tests {
#[test]
fn test_mut_iterator() {
let mut x = vec![1, 2, 3];
x.iterator_mut(0).for_each(|v| *v = *v * 2);
x.iterator_mut(0).for_each(|v| *v *= 2);
assert_eq!(vec![2, 4, 6], x);
}
src/linalg/ndarray/matrix.rs
+6 -6
View File
@@ -217,7 +217,7 @@ mod tests {
fn test_iterator() {
let a = arr2(&[[1, 2, 3], [4, 5, 6]]);
let v: Vec<i32> = a.iterator(0).map(|&v| v).collect();
let v: Vec<i32> = a.iterator(0).copied().collect();
assert_eq!(v, vec!(1, 2, 3, 4, 5, 6));
}
@@ -236,7 +236,7 @@ mod tests {
let x = arr2(&[[1, 2, 3], [4, 5, 6]]);
let x_slice = Array2::slice(&x, 0..2, 1..2);
assert_eq!((2, 1), x_slice.shape());
let v: Vec<i32> = x_slice.iterator(0).map(|&v| v).collect();
let v: Vec<i32> = x_slice.iterator(0).copied().collect();
assert_eq!(v, [2, 5]);
}
@@ -245,11 +245,11 @@ mod tests {
let x = arr2(&[[1, 2, 3], [4, 5, 6]]);
let x_slice = Array2::slice(&x, 0..2, 0..3);
assert_eq!(
x_slice.iterator(0).map(|&v| v).collect::<Vec<i32>>(),
x_slice.iterator(0).copied().collect::<Vec<i32>>(),
vec![1, 2, 3, 4, 5, 6]
);
assert_eq!(
x_slice.iterator(1).map(|&v| v).collect::<Vec<i32>>(),
x_slice.iterator(1).copied().collect::<Vec<i32>>(),
vec![1, 4, 2, 5, 3, 6]
);
}
@@ -279,8 +279,8 @@ mod tests {
fn test_c_from_iterator() {
let data = vec![1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12];
let a: NDArray2<i32> = Array2::from_iterator(data.clone().into_iter(), 4, 3, 0);
println!("{}", a);
println!("{a}");
let a: NDArray2<i32> = Array2::from_iterator(data.into_iter(), 4, 3, 1);
println!("{}", a);
println!("{a}");
}
}
src/linalg/ndarray/vector.rs
+1 -1
View File
@@ -152,7 +152,7 @@ mod tests {
fn test_iterator() {
let a = arr1(&[1, 2, 3]);
let v: Vec<i32> = a.iterator(0).map(|&v| v).collect();
let v: Vec<i32> = a.iterator(0).copied().collect();
assert_eq!(v, vec!(1, 2, 3));
}
src/linalg/traits/cholesky.rs
+11 -7
View File
@@ -15,7 +15,7 @@
//! &[25., 15., -5.],
//! &[15., 18., 0.],
//! &[-5., 0., 11.]
//! ]);
//! ]).unwrap();
//!
//! let cholesky = A.cholesky().unwrap();
//! let lower_triangular: DenseMatrix<f64> = cholesky.L();
@@ -175,11 +175,14 @@ mod tests {
)]
#[test]
fn cholesky_decompose() {
let a = DenseMatrix::from_2d_array(&[&[25., 15., -5.], &[15., 18., 0.], &[-5., 0., 11.]]);
let a = DenseMatrix::from_2d_array(&[&[25., 15., -5.], &[15., 18., 0.], &[-5., 0., 11.]])
.unwrap();
let l =
DenseMatrix::from_2d_array(&[&[5.0, 0.0, 0.0], &[3.0, 3.0, 0.0], &[-1.0, 1.0, 3.0]]);
DenseMatrix::from_2d_array(&[&[5.0, 0.0, 0.0], &[3.0, 3.0, 0.0], &[-1.0, 1.0, 3.0]])
.unwrap();
let u =
DenseMatrix::from_2d_array(&[&[5.0, 3.0, -1.0], &[0.0, 3.0, 1.0], &[0.0, 0.0, 3.0]]);
DenseMatrix::from_2d_array(&[&[5.0, 3.0, -1.0], &[0.0, 3.0, 1.0], &[0.0, 0.0, 3.0]])
.unwrap();
let cholesky = a.cholesky().unwrap();
assert!(relative_eq!(cholesky.L().abs(), l.abs(), epsilon = 1e-4));
@@ -197,9 +200,10 @@ mod tests {
)]
#[test]
fn cholesky_solve_mut() {
let a = DenseMatrix::from_2d_array(&[&[25., 15., -5.], &[15., 18., 0.], &[-5., 0., 11.]]);
let b = DenseMatrix::from_2d_array(&[&[40., 51., 28.]]);
let expected = DenseMatrix::from_2d_array(&[&[1.0, 2.0, 3.0]]);
let a = DenseMatrix::from_2d_array(&[&[25., 15., -5.], &[15., 18., 0.], &[-5., 0., 11.]])
.unwrap();
let b = DenseMatrix::from_2d_array(&[&[40., 51., 28.]]).unwrap();
let expected = DenseMatrix::from_2d_array(&[&[1.0, 2.0, 3.0]]).unwrap();
let cholesky = a.cholesky().unwrap();
src/linalg/traits/evd.rs
+24 -22
View File
@@ -19,7 +19,7 @@
//! &[0.9000, 0.4000, 0.7000],
//! &[0.4000, 0.5000, 0.3000],
//! &[0.7000, 0.3000, 0.8000],
//! ]);
//! ]).unwrap();
//!
//! let evd = A.evd(true).unwrap();
//! let eigenvectors: DenseMatrix<f64> = evd.V;
@@ -66,7 +66,7 @@ pub trait EVDDecomposable<T: Number + RealNumber>: Array2<T> {
fn evd_mut(mut self, symmetric: bool) -> Result<EVD<T, Self>, Failed> {
let (nrows, ncols) = self.shape();
if ncols != nrows {
panic!("Matrix is not square: {} x {}", nrows, ncols);
panic!("Matrix is not square: {nrows} x {ncols}");
}
let n = nrows;
@@ -820,7 +820,8 @@ mod tests {
&[0.9000, 0.4000, 0.7000],
&[0.4000, 0.5000, 0.3000],
&[0.7000, 0.3000, 0.8000],
]);
])
.unwrap();
let eigen_values: Vec<f64> = vec![1.7498382, 0.3165784, 0.1335834];
@@ -828,7 +829,8 @@ mod tests {
&[0.6881997, -0.07121225, 0.7220180],
&[0.3700456, 0.89044952, -0.2648886],
&[0.6240573, -0.44947578, -0.6391588],
]);
])
.unwrap();
let evd = A.evd(true).unwrap();
@@ -837,11 +839,9 @@ mod tests {
evd.V.abs(),
epsilon = 1e-4
));
for i in 0..eigen_values.len() {
assert!((eigen_values[i] - evd.d[i]).abs() < 1e-4);
}
for i in 0..eigen_values.len() {
assert!((0f64 - evd.e[i]).abs() < std::f64::EPSILON);
for (i, eigen_values_i) in eigen_values.iter().enumerate() {
assert!((eigen_values_i - evd.d[i]).abs() < 1e-4);
assert!((0f64 - evd.e[i]).abs() < f64::EPSILON);
}
}
#[cfg_attr(
@@ -854,7 +854,8 @@ mod tests {
&[0.9000, 0.4000, 0.7000],
&[0.4000, 0.5000, 0.3000],
&[0.8000, 0.3000, 0.8000],
]);
])
.unwrap();
let eigen_values: Vec<f64> = vec![1.79171122, 0.31908143, 0.08920735];
@@ -862,7 +863,8 @@ mod tests {
&[0.7178958, 0.05322098, 0.6812010],
&[0.3837711, -0.84702111, -0.1494582],
&[0.6952105, 0.43984484, -0.7036135],
]);
])
.unwrap();
let evd = A.evd(false).unwrap();
@@ -871,11 +873,9 @@ mod tests {
evd.V.abs(),
epsilon = 1e-4
));
for i in 0..eigen_values.len() {
assert!((eigen_values[i] - evd.d[i]).abs() < 1e-4);
}
for i in 0..eigen_values.len() {
assert!((0f64 - evd.e[i]).abs() < std::f64::EPSILON);
for (i, eigen_values_i) in eigen_values.iter().enumerate() {
assert!((eigen_values_i - evd.d[i]).abs() < 1e-4);
assert!((0f64 - evd.e[i]).abs() < f64::EPSILON);
}
}
#[cfg_attr(
@@ -889,7 +889,8 @@ mod tests {
&[4.0, -1.0, 1.0, 1.0],
&[1.0, 1.0, 3.0, -2.0],
&[1.0, 1.0, 4.0, -1.0],
]);
])
.unwrap();
let eigen_values_d: Vec<f64> = vec![0.0, 2.0, 2.0, 0.0];
let eigen_values_e: Vec<f64> = vec![2.2361, 0.9999, -0.9999, -2.2361];
@@ -899,7 +900,8 @@ mod tests {
&[-0.6707, 0.1059, 0.901, 0.6289],
&[0.9159, -0.1378, 0.3816, 0.0806],
&[0.6707, 0.1059, 0.901, -0.6289],
]);
])
.unwrap();
let evd = A.evd(false).unwrap();
@@ -908,11 +910,11 @@ mod tests {
evd.V.abs(),
epsilon = 1e-4
));
for i in 0..eigen_values_d.len() {
assert!((eigen_values_d[i] - evd.d[i]).abs() < 1e-4);
for (i, eigen_values_d_i) in eigen_values_d.iter().enumerate() {
assert!((eigen_values_d_i - evd.d[i]).abs() < 1e-4);
}
for i in 0..eigen_values_e.len() {
assert!((eigen_values_e[i] - evd.e[i]).abs() < 1e-4);
for (i, eigen_values_e_i) in eigen_values_e.iter().enumerate() {
assert!((eigen_values_e_i - evd.e[i]).abs() < 1e-4);
}
}
}
src/linalg/traits/high_order.rs
+3 -3
View File
@@ -12,9 +12,9 @@ pub trait HighOrderOperations<T: Number>: Array2<T> {
/// use smartcore::linalg::traits::high_order::HighOrderOperations;
/// use smartcore::linalg::basic::arrays::Array2;
///
/// let a = DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.]]);
/// let b = DenseMatrix::from_2d_array(&[&[5., 6.], &[7., 8.], &[9., 10.]]);
/// let expected = DenseMatrix::from_2d_array(&[&[71., 80.], &[92., 104.]]);
/// let a = DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.]]).unwrap();
/// let b = DenseMatrix::from_2d_array(&[&[5., 6.], &[7., 8.], &[9., 10.]]).unwrap();
/// let expected = DenseMatrix::from_2d_array(&[&[71., 80.], &[92., 104.]]).unwrap();
///
/// assert_eq!(a.ab(true, &b, false), expected);
/// ```
src/linalg/traits/lu.rs
+10 -12
View File
@@ -18,7 +18,7 @@
//! &[1., 2., 3.],
//! &[0., 1., 5.],
//! &[5., 6., 0.]
//! ]);
//! ]).unwrap();
//!
//! let lu = A.lu().unwrap();
//! let lower: DenseMatrix<f64> = lu.L();
@@ -126,7 +126,7 @@ impl<T: Number + RealNumber, M: Array2<T>> LU<T, M> {
let (m, n) = self.LU.shape();
if m != n {
panic!("Matrix is not square: {}x{}", m, n);
panic!("Matrix is not square: {m}x{n}");
}
let mut inv = M::zeros(n, n);
@@ -143,10 +143,7 @@ impl<T: Number + RealNumber, M: Array2<T>> LU<T, M> {
let (b_m, b_n) = b.shape();
if b_m != m {
panic!(
"Row dimensions do not agree: A is {} x {}, but B is {} x {}",
m, n, b_m, b_n
);
panic!("Row dimensions do not agree: A is {m} x {n}, but B is {b_m} x {b_n}");
}
if self.singular {
@@ -266,13 +263,13 @@ mod tests {
)]
#[test]
fn decompose() {
let a = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[0., 1., 5.], &[5., 6., 0.]]);
let a = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[0., 1., 5.], &[5., 6., 0.]]).unwrap();
let expected_L =
DenseMatrix::from_2d_array(&[&[1., 0., 0.], &[0., 1., 0.], &[0.2, 0.8, 1.]]);
DenseMatrix::from_2d_array(&[&[1., 0., 0.], &[0., 1., 0.], &[0.2, 0.8, 1.]]).unwrap();
let expected_U =
DenseMatrix::from_2d_array(&[&[5., 6., 0.], &[0., 1., 5.], &[0., 0., -1.]]);
DenseMatrix::from_2d_array(&[&[5., 6., 0.], &[0., 1., 5.], &[0., 0., -1.]]).unwrap();
let expected_pivot =
DenseMatrix::from_2d_array(&[&[0., 0., 1.], &[0., 1., 0.], &[1., 0., 0.]]);
DenseMatrix::from_2d_array(&[&[0., 0., 1.], &[0., 1., 0.], &[1., 0., 0.]]).unwrap();
let lu = a.lu().unwrap();
assert!(relative_eq!(lu.L(), expected_L, epsilon = 1e-4));
assert!(relative_eq!(lu.U(), expected_U, epsilon = 1e-4));
@@ -284,9 +281,10 @@ mod tests {
)]
#[test]
fn inverse() {
let a = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[0., 1., 5.], &[5., 6., 0.]]);
let a = DenseMatrix::from_2d_array(&[&[1., 2., 3.], &[0., 1., 5.], &[5., 6., 0.]]).unwrap();
let expected =
DenseMatrix::from_2d_array(&[&[-6.0, 3.6, 1.4], &[5.0, -3.0, -1.0], &[-1.0, 0.8, 0.2]]);
DenseMatrix::from_2d_array(&[&[-6.0, 3.6, 1.4], &[5.0, -3.0, -1.0], &[-1.0, 0.8, 0.2]])
.unwrap();
let a_inv = a.lu().and_then(|lu| lu.inverse()).unwrap();
assert!(relative_eq!(a_inv, expected, epsilon = 1e-4));
}
src/linalg/traits/qr.rs
+13 -11
View File
@@ -13,7 +13,7 @@
//! &[0.9, 0.4, 0.7],
//! &[0.4, 0.5, 0.3],
//! &[0.7, 0.3, 0.8]
//! ]);
//! ]).unwrap();
//!
//! let qr = A.qr().unwrap();
//! let orthogonal: DenseMatrix<f64> = qr.Q();
@@ -102,10 +102,7 @@ impl<T: Number + RealNumber, M: Array2<T>> QR<T, M> {
let (b_nrows, b_ncols) = b.shape();
if b_nrows != m {
panic!(
"Row dimensions do not agree: A is {} x {}, but B is {} x {}",
m, n, b_nrows, b_ncols
);
panic!("Row dimensions do not agree: A is {m} x {n}, but B is {b_nrows} x {b_ncols}");
}
if self.singular {
@@ -204,17 +201,20 @@ mod tests {
)]
#[test]
fn decompose() {
let a = DenseMatrix::from_2d_array(&[&[0.9, 0.4, 0.7], &[0.4, 0.5, 0.3], &[0.7, 0.3, 0.8]]);
let a = DenseMatrix::from_2d_array(&[&[0.9, 0.4, 0.7], &[0.4, 0.5, 0.3], &[0.7, 0.3, 0.8]])
.unwrap();
let q = DenseMatrix::from_2d_array(&[
&[-0.7448, 0.2436, 0.6212],
&[-0.331, -0.9432, -0.027],
&[-0.5793, 0.2257, -0.7832],
]);
])
.unwrap();
let r = DenseMatrix::from_2d_array(&[
&[-1.2083, -0.6373, -1.0842],
&[0.0, -0.3064, 0.0682],
&[0.0, 0.0, -0.1999],
]);
])
.unwrap();
let qr = a.qr().unwrap();
assert!(relative_eq!(qr.Q().abs(), q.abs(), epsilon = 1e-4));
assert!(relative_eq!(qr.R().abs(), r.abs(), epsilon = 1e-4));
@@ -226,13 +226,15 @@ mod tests {
)]
#[test]
fn qr_solve_mut() {
let a = DenseMatrix::from_2d_array(&[&[0.9, 0.4, 0.7], &[0.4, 0.5, 0.3], &[0.7, 0.3, 0.8]]);
let b = DenseMatrix::from_2d_array(&[&[0.5, 0.2], &[0.5, 0.8], &[0.5, 0.3]]);
let a = DenseMatrix::from_2d_array(&[&[0.9, 0.4, 0.7], &[0.4, 0.5, 0.3], &[0.7, 0.3, 0.8]])
.unwrap();
let b = DenseMatrix::from_2d_array(&[&[0.5, 0.2], &[0.5, 0.8], &[0.5, 0.3]]).unwrap();
let expected_w = DenseMatrix::from_2d_array(&[
&[-0.2027027, -1.2837838],
&[0.8783784, 2.2297297],
&[0.4729730, 0.6621622],
]);
])
.unwrap();
let w = a.qr_solve_mut(b).unwrap();
assert!(relative_eq!(w, expected_w, epsilon = 1e-2));
}
src/linalg/traits/stats.rs
+18 -14
View File
@@ -136,8 +136,8 @@ pub trait MatrixPreprocessing<T: RealNumber>: MutArrayView2<T> + Clone {
/// ```rust
/// use smartcore::linalg::basic::matrix::DenseMatrix;
/// use smartcore::linalg::traits::stats::MatrixPreprocessing;
/// let mut a = DenseMatrix::from_2d_array(&[&[0., 2., 3.], &[-5., -6., -7.]]);
/// let expected = DenseMatrix::from_2d_array(&[&[0., 1., 1.],&[0., 0., 0.]]);
/// let mut a = DenseMatrix::from_2d_array(&[&[0., 2., 3.], &[-5., -6., -7.]]).unwrap();
/// let expected = DenseMatrix::from_2d_array(&[&[0., 1., 1.],&[0., 0., 0.]]).unwrap();
/// a.binarize_mut(0.);
///
/// assert_eq!(a, expected);
@@ -159,8 +159,8 @@ pub trait MatrixPreprocessing<T: RealNumber>: MutArrayView2<T> + Clone {
/// ```rust
/// use smartcore::linalg::basic::matrix::DenseMatrix;
/// use smartcore::linalg::traits::stats::MatrixPreprocessing;
/// let a = DenseMatrix::from_2d_array(&[&[0., 2., 3.], &[-5., -6., -7.]]);
/// let expected = DenseMatrix::from_2d_array(&[&[0., 1., 1.],&[0., 0., 0.]]);
/// let a = DenseMatrix::from_2d_array(&[&[0., 2., 3.], &[-5., -6., -7.]]).unwrap();
/// let expected = DenseMatrix::from_2d_array(&[&[0., 1., 1.],&[0., 0., 0.]]).unwrap();
///
/// assert_eq!(a.binarize(0.), expected);
/// ```
@@ -186,7 +186,8 @@ mod tests {
&[1., 2., 3., 1., 2.],
&[4., 5., 6., 3., 4.],
&[7., 8., 9., 5., 6.],
]);
])
.unwrap();
let expected_0 = vec![4., 5., 6., 3., 4.];
let expected_1 = vec![1.8, 4.4, 7.];
@@ -196,7 +197,7 @@ mod tests {
#[test]
fn test_var() {
let m = DenseMatrix::from_2d_array(&[&[1., 2., 3., 4.], &[5., 6., 7., 8.]]);
let m = DenseMatrix::from_2d_array(&[&[1., 2., 3., 4.], &[5., 6., 7., 8.]]).unwrap();
let expected_0 = vec![4., 4., 4., 4.];
let expected_1 = vec![1.25, 1.25];
@@ -211,12 +212,13 @@ mod tests {
let m = DenseMatrix::from_2d_array(&[
&[0.0, 0.25, 0.25, 1.25, 1.5, 1.75, 2.75, 3.25],
&[0.0, 0.25, 0.25, 1.25, 1.5, 1.75, 2.75, 3.25],
]);
])
.unwrap();
let expected_0 = vec![0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0];
let expected_1 = vec![1.25, 1.25];
assert!(m.var(0).approximate_eq(&expected_0, std::f64::EPSILON));
assert!(m.var(1).approximate_eq(&expected_1, std::f64::EPSILON));
assert!(m.var(0).approximate_eq(&expected_0, f64::EPSILON));
assert!(m.var(1).approximate_eq(&expected_1, f64::EPSILON));
assert_eq!(
m.mean(0),
vec![0.0, 0.25, 0.25, 1.25, 1.5, 1.75, 2.75, 3.25]
@@ -230,7 +232,8 @@ mod tests {
&[1., 2., 3., 1., 2.],
&[4., 5., 6., 3., 4.],
&[7., 8., 9., 5., 6.],
]);
])
.unwrap();
let expected_0 = vec![
2.449489742783178,
2.449489742783178,
@@ -251,10 +254,10 @@ mod tests {
#[test]
fn test_scale() {
let m: DenseMatrix<f64> =
DenseMatrix::from_2d_array(&[&[1., 2., 3., 4.], &[5., 6., 7., 8.]]);
DenseMatrix::from_2d_array(&[&[1., 2., 3., 4.], &[5., 6., 7., 8.]]).unwrap();
let expected_0: DenseMatrix<f64> =
DenseMatrix::from_2d_array(&[&[-1., -1., -1., -1.], &[1., 1., 1., 1.]]);
DenseMatrix::from_2d_array(&[&[-1., -1., -1., -1.], &[1., 1., 1., 1.]]).unwrap();
let expected_1: DenseMatrix<f64> = DenseMatrix::from_2d_array(&[
&[
-1.3416407864998738,
@@ -268,7 +271,8 @@ mod tests {
0.4472135954999579,
1.3416407864998738,
],
]);
])
.unwrap();
assert_eq!(m.mean(0), vec![3.0, 4.0, 5.0, 6.0]);
assert_eq!(m.mean(1), vec![2.5, 6.5]);
@@ -286,7 +290,7 @@ mod tests {
}
{
let mut m = m.clone();
let mut m = m;
m.standard_scale_mut(&m.mean(1), &m.std(1), 1);
assert_eq!(&m, &expected_1);
}
src/linalg/traits/svd.rs
+24 -18
View File
@@ -17,7 +17,7 @@
//! &[0.9, 0.4, 0.7],
//! &[0.4, 0.5, 0.3],
//! &[0.7, 0.3, 0.8]
//! ]);
//! ]).unwrap();
//!
//! let svd = A.svd().unwrap();
//! let u: DenseMatrix<f64> = svd.U;
@@ -48,11 +48,9 @@ pub struct SVD<T: Number + RealNumber, M: SVDDecomposable<T>> {
pub V: M,
/// Singular values of the original matrix
pub s: Vec<T>,
///
m: usize,
///
n: usize,
///
/// Tolerance
tol: T,
}
@@ -489,7 +487,8 @@ mod tests {
&[0.9000, 0.4000, 0.7000],
&[0.4000, 0.5000, 0.3000],
&[0.7000, 0.3000, 0.8000],
]);
])
.unwrap();
let s: Vec<f64> = vec![1.7498382, 0.3165784, 0.1335834];
@@ -497,20 +496,22 @@ mod tests {
&[0.6881997, -0.07121225, 0.7220180],
&[0.3700456, 0.89044952, -0.2648886],
&[0.6240573, -0.44947578, -0.639158],
]);
])
.unwrap();
let V = DenseMatrix::from_2d_array(&[
&[0.6881997, -0.07121225, 0.7220180],
&[0.3700456, 0.89044952, -0.2648886],
&[0.6240573, -0.44947578, -0.6391588],
]);
])
.unwrap();
let svd = A.svd().unwrap();
assert!(relative_eq!(V.abs(), svd.V.abs(), epsilon = 1e-4));
assert!(relative_eq!(U.abs(), svd.U.abs(), epsilon = 1e-4));
for i in 0..s.len() {
assert!((s[i] - svd.s[i]).abs() < 1e-4);
for (i, s_i) in s.iter().enumerate() {
assert!((s_i - svd.s[i]).abs() < 1e-4);
}
}
#[cfg_attr(
@@ -577,7 +578,8 @@ mod tests {
-0.2158704,
-0.27529472,
],
]);
])
.unwrap();
let s: Vec<f64> = vec![
3.8589375, 3.4396766, 2.6487176, 2.2317399, 1.5165054, 0.8109055, 0.2706515,
@@ -647,7 +649,8 @@ mod tests {
0.73034065,
-0.43965505,
],
]);
])
.unwrap();
let V = DenseMatrix::from_2d_array(&[
&[
@@ -707,14 +710,15 @@ mod tests {
0.1654796,
-0.32346758,
],
]);
])
.unwrap();
let svd = A.svd().unwrap();
assert!(relative_eq!(V.abs(), svd.V.abs(), epsilon = 1e-4));
assert!(relative_eq!(U.abs(), svd.U.abs(), epsilon = 1e-4));
for i in 0..s.len() {
assert!((s[i] - svd.s[i]).abs() < 1e-4);
for (i, s_i) in s.iter().enumerate() {
assert!((s_i - svd.s[i]).abs() < 1e-4);
}
}
#[cfg_attr(
@@ -723,10 +727,11 @@ mod tests {
)]
#[test]
fn solve() {
let a = DenseMatrix::from_2d_array(&[&[0.9, 0.4, 0.7], &[0.4, 0.5, 0.3], &[0.7, 0.3, 0.8]]);
let b = DenseMatrix::from_2d_array(&[&[0.5, 0.2], &[0.5, 0.8], &[0.5, 0.3]]);
let a = DenseMatrix::from_2d_array(&[&[0.9, 0.4, 0.7], &[0.4, 0.5, 0.3], &[0.7, 0.3, 0.8]])
.unwrap();
let b = DenseMatrix::from_2d_array(&[&[0.5, 0.2], &[0.5, 0.8], &[0.5, 0.3]]).unwrap();
let expected_w =
DenseMatrix::from_2d_array(&[&[-0.20, -1.28], &[0.87, 2.22], &[0.47, 0.66]]);
DenseMatrix::from_2d_array(&[&[-0.20, -1.28], &[0.87, 2.22], &[0.47, 0.66]]).unwrap();
let w = a.svd_solve_mut(b).unwrap();
assert!(relative_eq!(w, expected_w, epsilon = 1e-2));
}
@@ -737,7 +742,8 @@ mod tests {
)]
#[test]
fn decompose_restore() {
let a = DenseMatrix::from_2d_array(&[&[1.0, 2.0, 3.0, 4.0], &[5.0, 6.0, 7.0, 8.0]]);
let a =
DenseMatrix::from_2d_array(&[&[1.0, 2.0, 3.0, 4.0], &[5.0, 6.0, 7.0, 8.0]]).unwrap();
let svd = a.svd().unwrap();
let u: &DenseMatrix<f32> = &svd.U; //U
let v: &DenseMatrix<f32> = &svd.V; // V
src/linear/bg_solver.rs
+9 -7
View File
@@ -12,7 +12,8 @@
//! pub struct BGSolver {}
//! impl<'a, T: FloatNumber, X: Array2<T>> BiconjugateGradientSolver<'a, T, X> for BGSolver {}
//!
//! let a = DenseMatrix::from_2d_array(&[&[25., 15., -5.], &[15., 18., 0.], &[-5., 0., 11.]]);
//! let a = DenseMatrix::from_2d_array(&[&[25., 15., -5.], &[15., 18., 0.], &[-5., 0.,
//! 11.]]).unwrap();
//! let b = vec![40., 51., 28.];
//! let expected = vec![1.0, 2.0, 3.0];
//! let mut x = Vec::zeros(3);
@@ -26,9 +27,9 @@ use crate::error::Failed;
use crate::linalg::basic::arrays::{Array, Array1, Array2, ArrayView1, MutArrayView1};
use crate::numbers::floatnum::FloatNumber;
///
/// Trait for Biconjugate Gradient Solver
pub trait BiconjugateGradientSolver<'a, T: FloatNumber, X: Array2<T>> {
///
/// Solve Ax = b
fn solve_mut(
&self,
a: &'a X,
@@ -108,7 +109,7 @@ pub trait BiconjugateGradientSolver<'a, T: FloatNumber, X: Array2<T>> {
Ok(err)
}
///
/// solve preconditioner
fn solve_preconditioner(&self, a: &'a X, b: &[T], x: &mut [T]) {
let diag = Self::diag(a);
let n = diag.len();
@@ -132,7 +133,7 @@ pub trait BiconjugateGradientSolver<'a, T: FloatNumber, X: Array2<T>> {
y.copy_from(&x.xa(true, a));
}
///
/// Extract the diagonal from a matrix
fn diag(a: &X) -> Vec<T> {
let (nrows, ncols) = a.shape();
let n = nrows.min(ncols);
@@ -158,9 +159,10 @@ mod tests {
#[test]
fn bg_solver() {
let a = DenseMatrix::from_2d_array(&[&[25., 15., -5.], &[15., 18., 0.], &[-5., 0., 11.]]);
let a = DenseMatrix::from_2d_array(&[&[25., 15., -5.], &[15., 18., 0.], &[-5., 0., 11.]])
.unwrap();
let b = vec![40., 51., 28.];
let expected = vec![1.0, 2.0, 3.0];
let expected = [1.0, 2.0, 3.0];
let mut x = Vec::zeros(3);
src/linear/elastic_net.rs
+7 -8
View File
@@ -38,7 +38,7 @@
//! &[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
//! &[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
//! &[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
//! ]);
//! ]).unwrap();
//!
//! let y: Vec<f64> = vec![83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0,
//! 100.0, 101.2, 104.6, 108.4, 110.8, 112.6, 114.2, 115.7, 116.9];
@@ -425,10 +425,7 @@ impl<TX: FloatNumber + RealNumber, TY: Number, X: Array2<TX>, Y: Array1<TY>>
for (i, col_std_i) in col_std.iter().enumerate() {
if (*col_std_i - TX::zero()).abs() < TX::epsilon() {
return Err(Failed::fit(&format!(
"Cannot rescale constant column {}",
i
)));
return Err(Failed::fit(&format!("Cannot rescale constant column {i}")));
}
}
@@ -514,7 +511,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y: Vec<f64> = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
@@ -565,7 +563,8 @@ mod tests {
&[17.0, 1918.0, 1.4054969025700674],
&[18.0, 1929.0, 1.3271699396384906],
&[19.0, 1915.0, 1.1373332337674806],
]);
])
.unwrap();
let y: Vec<f64> = vec![
1.48, 2.72, 4.52, 5.72, 5.25, 4.07, 3.75, 4.75, 6.77, 4.72, 6.78, 6.79, 8.3, 7.42,
@@ -630,7 +629,7 @@ mod tests {
// &[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
// &[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
// &[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
// ]);
// ]).unwrap();
// let y = vec![
// 83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
src/linear/lasso.rs
+3 -5
View File
@@ -356,10 +356,7 @@ impl<TX: FloatNumber + RealNumber, TY: Number, X: Array2<TX>, Y: Array1<TY>> Las
for (i, col_std_i) in col_std.iter().enumerate() {
if (*col_std_i - TX::zero()).abs() < TX::epsilon() {
return Err(Failed::fit(&format!(
"Cannot rescale constant column {}",
i
)));
return Err(Failed::fit(&format!("Cannot rescale constant column {i}")));
}
}
@@ -421,7 +418,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y: Vec<f64> = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
src/linear/lasso_optimizer.rs
+4 -10
View File
@@ -16,7 +16,7 @@ use crate::linalg::basic::arrays::{Array1, Array2, ArrayView1, MutArray, MutArra
use crate::linear::bg_solver::BiconjugateGradientSolver;
use crate::numbers::floatnum::FloatNumber;
///
/// Interior Point Optimizer
pub struct InteriorPointOptimizer<T: FloatNumber, X: Array2<T>> {
ata: X,
d1: Vec<T>,
@@ -25,9 +25,8 @@ pub struct InteriorPointOptimizer<T: FloatNumber, X: Array2<T>> {
prs: Vec<T>,
}
///
impl<T: FloatNumber, X: Array2<T>> InteriorPointOptimizer<T, X> {
///
/// Initialize a new Interior Point Optimizer
pub fn new(a: &X, n: usize) -> InteriorPointOptimizer<T, X> {
InteriorPointOptimizer {
ata: a.ab(true, a, false),
@@ -38,7 +37,7 @@ impl<T: FloatNumber, X: Array2<T>> InteriorPointOptimizer<T, X> {
}
}
///
/// Run the optimization
pub fn optimize(
&mut self,
x: &X,
@@ -101,7 +100,7 @@ impl<T: FloatNumber, X: Array2<T>> InteriorPointOptimizer<T, X> {
// CALCULATE DUALITY GAP
let xnu = nu.xa(false, x);
let max_xnu = xnu.norm(std::f64::INFINITY);
let max_xnu = xnu.norm(f64::INFINITY);
if max_xnu > lambda_f64 {
let lnu = T::from_f64(lambda_f64 / max_xnu).unwrap();
nu.mul_scalar_mut(lnu);
@@ -208,7 +207,6 @@ impl<T: FloatNumber, X: Array2<T>> InteriorPointOptimizer<T, X> {
Ok(w)
}
///
fn sumlogneg(f: &X) -> T {
let (n, _) = f.shape();
let mut sum = T::zero();
@@ -220,11 +218,9 @@ impl<T: FloatNumber, X: Array2<T>> InteriorPointOptimizer<T, X> {
}
}
///
impl<'a, T: FloatNumber, X: Array2<T>> BiconjugateGradientSolver<'a, T, X>
for InteriorPointOptimizer<T, X>
{
///
fn solve_preconditioner(&self, a: &'a X, b: &[T], x: &mut [T]) {
let (_, p) = a.shape();
@@ -234,7 +230,6 @@ impl<'a, T: FloatNumber, X: Array2<T>> BiconjugateGradientSolver<'a, T, X>
}
}
///
fn mat_vec_mul(&self, _: &X, x: &Vec<T>, y: &mut Vec<T>) {
let (_, p) = self.ata.shape();
let x_slice = Vec::from_slice(x.slice(0..p).as_ref());
@@ -246,7 +241,6 @@ impl<'a, T: FloatNumber, X: Array2<T>> BiconjugateGradientSolver<'a, T, X>
}
}
///
fn mat_t_vec_mul(&self, a: &X, x: &Vec<T>, y: &mut Vec<T>) {
self.mat_vec_mul(a, x, y);
}
src/linear/linear_regression.rs
+4 -3
View File
@@ -40,7 +40,7 @@
//! &[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
//! &[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
//! &[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
//! ]);
//! ]).unwrap();
//!
//! let y: Vec<f64> = vec![83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0,
//! 100.0, 101.2, 104.6, 108.4, 110.8, 112.6, 114.2, 115.7, 116.9];
@@ -341,7 +341,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y: Vec<f64> = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8,
@@ -393,7 +394,7 @@ mod tests {
// &[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
// &[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
// &[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
// ]);
// ]).unwrap();
// let y = vec![
// 83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
src/linear/logistic_regression.rs
+100 -63
View File
@@ -35,7 +35,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//! let y: Vec<i32> = vec![
//! 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
//! ];
@@ -71,19 +71,14 @@ use crate::optimization::line_search::Backtracking;
use crate::optimization::FunctionOrder;
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Clone, Eq, PartialEq)]
#[derive(Debug, Clone, Eq, PartialEq, Default)]
/// Solver options for Logistic regression. Right now only LBFGS solver is supported.
pub enum LogisticRegressionSolverName {
/// Limited-memory BroydenFletcherGoldfarbShanno method, see [LBFGS paper](http://users.iems.northwestern.edu/~nocedal/lbfgsb.html)
#[default]
LBFGS,
}
impl Default for LogisticRegressionSolverName {
fn default() -> Self {
LogisticRegressionSolverName::LBFGS
}
}
/// Logistic Regression parameters
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Clone)]
@@ -188,14 +183,11 @@ pub struct LogisticRegression<
}
trait ObjectiveFunction<T: Number + FloatNumber, X: Array2<T>> {
///
fn f(&self, w_bias: &[T]) -> T;
///
#[allow(clippy::ptr_arg)]
fn df(&self, g: &mut Vec<T>, w_bias: &Vec<T>);
///
#[allow(clippy::ptr_arg)]
fn partial_dot(w: &[T], x: &X, v_col: usize, m_row: usize) -> T {
let mut sum = T::zero();
@@ -421,7 +413,7 @@ impl<TX: Number + FloatNumber + RealNumber, TY: Number + Ord, X: Array2<TX>, Y:
/// Fits Logistic Regression to your data.
/// * `x` - _NxM_ matrix with _N_ observations and _M_ features in each observation.
/// * `y` - target class values
/// * `parameters` - other parameters, use `Default::default()` to set parameters to default values.
/// * `parameters` - other parameters, use `Default::default()` to set parameters to default values.
pub fn fit(
x: &X,
y: &Y,
@@ -449,8 +441,7 @@ impl<TX: Number + FloatNumber + RealNumber, TY: Number + Ord, X: Array2<TX>, Y:
match k.cmp(&2) {
Ordering::Less => Err(Failed::fit(&format!(
"incorrect number of classes: {}. Should be >= 2.",
k
"incorrect number of classes: {k}. Should be >= 2."
))),
Ordering::Equal => {
let x0 = Vec::zeros(num_attributes + 1);
@@ -617,7 +608,8 @@ mod tests {
&[10., -2.],
&[8., 2.],
&[9., 0.],
]);
])
.unwrap();
let y = vec![0, 0, 1, 1, 2, 1, 1, 0, 0, 2, 1, 1, 0, 0, 1];
@@ -634,21 +626,21 @@ mod tests {
objective.df(&mut g, &vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
objective.df(&mut g, &vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
assert!((g[0] + 33.000068218163484).abs() < std::f64::EPSILON);
assert!((g[0] + 33.000068218163484).abs() < f64::EPSILON);
let f = objective.f(&vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
let f = objective.f(&[1., 2., 3., 4., 5., 6., 7., 8., 9.]);
assert!((f - 408.0052230582765).abs() < std::f64::EPSILON);
assert!((f - 408.0052230582765).abs() < f64::EPSILON);
let objective_reg = MultiClassObjectiveFunction {
x: &x,
y: y.clone(),
y,
k: 3,
alpha: 1.0,
_phantom_t: PhantomData,
};
let f = objective_reg.f(&vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
let f = objective_reg.f(&[1., 2., 3., 4., 5., 6., 7., 8., 9.]);
assert!((f - 487.5052).abs() < 1e-4);
objective_reg.df(&mut g, &vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
@@ -677,7 +669,8 @@ mod tests {
&[10., -2.],
&[8., 2.],
&[9., 0.],
]);
])
.unwrap();
let y = vec![0, 0, 1, 1, 1, 1, 1, 0, 0, 1, 1, 1, 0, 0, 1];
@@ -693,22 +686,22 @@ mod tests {
objective.df(&mut g, &vec![1., 2., 3.]);
objective.df(&mut g, &vec![1., 2., 3.]);
assert!((g[0] - 26.051064349381285).abs() < std::f64::EPSILON);
assert!((g[1] - 10.239000702928523).abs() < std::f64::EPSILON);
assert!((g[2] - 3.869294270156324).abs() < std::f64::EPSILON);
assert!((g[0] - 26.051064349381285).abs() < f64::EPSILON);
assert!((g[1] - 10.239000702928523).abs() < f64::EPSILON);
assert!((g[2] - 3.869294270156324).abs() < f64::EPSILON);
let f = objective.f(&vec![1., 2., 3.]);
let f = objective.f(&[1., 2., 3.]);
assert!((f - 59.76994756647412).abs() < std::f64::EPSILON);
assert!((f - 59.76994756647412).abs() < f64::EPSILON);
let objective_reg = BinaryObjectiveFunction {
x: &x,
y: y.clone(),
y,
alpha: 1.0,
_phantom_t: PhantomData,
};
let f = objective_reg.f(&vec![1., 2., 3.]);
let f = objective_reg.f(&[1., 2., 3.]);
assert!((f - 62.2699).abs() < 1e-4);
objective_reg.df(&mut g, &vec![1., 2., 3.]);
@@ -739,7 +732,8 @@ mod tests {
&[10., -2.],
&[8., 2.],
&[9., 0.],
]);
])
.unwrap();
let y: Vec<i32> = vec![0, 0, 1, 1, 2, 1, 1, 0, 0, 2, 1, 1, 0, 0, 1];
let lr = LogisticRegression::fit(&x, &y, Default::default()).unwrap();
@@ -824,37 +818,41 @@ mod tests {
assert!(reg_coeff_sum < coeff);
}
// TODO: serialization for the new DenseMatrix needs to be implemented
// #[cfg_attr(all(target_arch = "wasm32", not(target_os = "wasi")), wasm_bindgen_test::wasm_bindgen_test)]
// #[test]
// #[cfg(feature = "serde")]
// fn serde() {
// let x = DenseMatrix::from_2d_array(&[
// &[1., -5.],
// &[2., 5.],
// &[3., -2.],
// &[1., 2.],
// &[2., 0.],
// &[6., -5.],
// &[7., 5.],
// &[6., -2.],
// &[7., 2.],
// &[6., 0.],
// &[8., -5.],
// &[9., 5.],
// &[10., -2.],
// &[8., 2.],
// &[9., 0.],
// ]);
// let y: Vec<i32> = vec![0, 0, 1, 1, 2, 1, 1, 0, 0, 2, 1, 1, 0, 0, 1];
//TODO: serialization for the new DenseMatrix needs to be implemented
#[cfg_attr(
all(target_arch = "wasm32", not(target_os = "wasi")),
wasm_bindgen_test::wasm_bindgen_test
)]
#[test]
#[cfg(feature = "serde")]
fn serde() {
let x: DenseMatrix<f64> = DenseMatrix::from_2d_array(&[
&[1., -5.],
&[2., 5.],
&[3., -2.],
&[1., 2.],
&[2., 0.],
&[6., -5.],
&[7., 5.],
&[6., -2.],
&[7., 2.],
&[6., 0.],
&[8., -5.],
&[9., 5.],
&[10., -2.],
&[8., 2.],
&[9., 0.],
])
.unwrap();
let y: Vec<i32> = vec![0, 0, 1, 1, 2, 1, 1, 0, 0, 2, 1, 1, 0, 0, 1];
// let lr = LogisticRegression::fit(&x, &y, Default::default()).unwrap();
let lr = LogisticRegression::fit(&x, &y, Default::default()).unwrap();
// let deserialized_lr: LogisticRegression<f64, i32, DenseMatrix<f64>, Vec<i32>> =
// serde_json::from_str(&serde_json::to_string(&lr).unwrap()).unwrap();
let deserialized_lr: LogisticRegression<f64, i32, DenseMatrix<f64>, Vec<i32>> =
serde_json::from_str(&serde_json::to_string(&lr).unwrap()).unwrap();
// assert_eq!(lr, deserialized_lr);
// }
assert_eq!(lr, deserialized_lr);
}
#[cfg_attr(
all(target_arch = "wasm32", not(target_os = "wasi")),
@@ -883,7 +881,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y: Vec<i32> = vec![0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
let lr = LogisticRegression::fit(&x, &y, Default::default()).unwrap();
@@ -896,11 +895,7 @@ mod tests {
let y_hat = lr.predict(&x).unwrap();
let error: i32 = y
.into_iter()
.zip(y_hat.into_iter())
.map(|(a, b)| (a - b).abs())
.sum();
let error: i32 = y.into_iter().zip(y_hat).map(|(a, b)| (a - b).abs()).sum();
assert!(error <= 1);
@@ -909,4 +904,46 @@ mod tests {
assert!(reg_coeff_sum < coeff);
}
#[cfg_attr(
all(target_arch = "wasm32", not(target_os = "wasi")),
wasm_bindgen_test::wasm_bindgen_test
)]
#[test]
fn lr_fit_predict_random() {
let x: DenseMatrix<f32> = DenseMatrix::rand(52181, 94);
let y1: Vec<i32> = vec![1; 2181];
let y2: Vec<i32> = vec![0; 50000];
let y: Vec<i32> = y1.into_iter().chain(y2).collect();
let lr = LogisticRegression::fit(&x, &y, Default::default()).unwrap();
let lr_reg = LogisticRegression::fit(
&x,
&y,
LogisticRegressionParameters::default().with_alpha(1.0),
)
.unwrap();
let y_hat = lr.predict(&x).unwrap();
let y_hat_reg = lr_reg.predict(&x).unwrap();
assert_eq!(y.len(), y_hat.len());
assert_eq!(y.len(), y_hat_reg.len());
}
#[test]
fn test_logit() {
let x: &DenseMatrix<f64> = &DenseMatrix::rand(52181, 94);
let y1: Vec<u32> = vec![1; 2181];
let y2: Vec<u32> = vec![0; 50000];
let y: &Vec<u32> = &(y1.into_iter().chain(y2).collect());
println!("y vec height: {:?}", y.len());
println!("x matrix shape: {:?}", x.shape());
let lr = LogisticRegression::fit(x, y, Default::default()).unwrap();
let y_hat = lr.predict(x).unwrap();
println!("y_hat shape: {:?}", y_hat.shape());
assert_eq!(y_hat.shape(), 52181);
}
}
src/linear/ridge_regression.rs
+7 -14
View File
@@ -40,7 +40,7 @@
//! &[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
//! &[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
//! &[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
//! ]);
//! ]).unwrap();
//!
//! let y: Vec<f64> = vec![83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0,
//! 100.0, 101.2, 104.6, 108.4, 110.8, 112.6, 114.2, 115.7, 116.9];
@@ -71,21 +71,16 @@ use crate::numbers::basenum::Number;
use crate::numbers::realnum::RealNumber;
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Clone, Eq, PartialEq)]
#[derive(Debug, Clone, Eq, PartialEq, Default)]
/// Approach to use for estimation of regression coefficients. Cholesky is more efficient but SVD is more stable.
pub enum RidgeRegressionSolverName {
/// Cholesky decomposition, see [Cholesky](../../linalg/cholesky/index.html)
#[default]
Cholesky,
/// SVD decomposition, see [SVD](../../linalg/svd/index.html)
SVD,
}
impl Default for RidgeRegressionSolverName {
fn default() -> Self {
RidgeRegressionSolverName::Cholesky
}
}
/// Ridge Regression parameters
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Clone)]
@@ -384,10 +379,7 @@ impl<
for (i, col_std_i) in col_std.iter().enumerate() {
if (*col_std_i - TX::zero()).abs() < TX::epsilon() {
return Err(Failed::fit(&format!(
"Cannot rescale constant column {}",
i
)));
return Err(Failed::fit(&format!("Cannot rescale constant column {i}")));
}
}
@@ -463,7 +455,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y: Vec<f64> = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
@@ -521,7 +514,7 @@ mod tests {
// &[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
// &[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
// &[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
// ]);
// ]).unwrap();
// let y = vec![
// 83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
src/metrics/cluster_hcv.rs
+3 -3
View File
@@ -98,8 +98,8 @@ mod tests {
let mut scores = HCVScore::new();
scores.compute(&v1, &v2);
assert!((0.2548 - scores.homogeneity.unwrap() as f64).abs() < 1e-4);
assert!((0.5440 - scores.completeness.unwrap() as f64).abs() < 1e-4);
assert!((0.3471 - scores.v_measure.unwrap() as f64).abs() < 1e-4);
assert!((0.2548 - scores.homogeneity.unwrap()).abs() < 1e-4);
assert!((0.5440 - scores.completeness.unwrap()).abs() < 1e-4);
assert!((0.3471 - scores.v_measure.unwrap()).abs() < 1e-4);
}
}
src/metrics/cluster_helpers.rs
+1 -1
View File
@@ -125,7 +125,7 @@ mod tests {
fn entropy_test() {
let v1 = vec![0, 0, 1, 1, 2, 0, 4];
assert!((1.2770 - entropy(&v1).unwrap() as f64).abs() < 1e-4);
assert!((1.2770 - entropy(&v1).unwrap()).abs() < 1e-4);
}
#[cfg_attr(
src/metrics/distance/mahalanobis.rs
+3 -2
View File
@@ -25,7 +25,7 @@
//! &[68., 590., 37.],
//! &[69., 660., 46.],
//! &[73., 600., 55.],
//! ]);
//! ]).unwrap();
//!
//! let a = data.mean_by(0);
//! let b = vec![66., 640., 44.];
@@ -151,7 +151,8 @@ mod tests {
&[68., 590., 37.],
&[69., 660., 46.],
&[73., 600., 55.],
]);
])
.unwrap();
let a = data.mean_by(0);
let b = vec![66., 640., 44.];
src/metrics/f1.rs
+2 -2
View File
@@ -95,8 +95,8 @@ mod tests {
let score1: f64 = F1::new_with(beta).get_score(&y_true, &y_pred);
let score2: f64 = F1::new_with(beta).get_score(&y_true, &y_true);
println!("{:?}", score1);
println!("{:?}", score2);
println!("{score1:?}");
println!("{score2:?}");
assert!((score1 - 0.57142857).abs() < 1e-8);
assert!((score2 - 1.0).abs() < 1e-8);
src/metrics/mod.rs
+1 -1
View File
@@ -37,7 +37,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//! let y: Vec<i8> = vec![
//! 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
//! ];
src/model_selection/hyper_tuning/grid_search.rs
+2 -2
View File
@@ -3,9 +3,9 @@
use crate::{
api::{Predictor, SupervisedEstimator},
error::{Failed, FailedError},
linalg::basic::arrays::{Array2, Array1},
numbers::realnum::RealNumber,
linalg::basic::arrays::{Array1, Array2},
numbers::basenum::Number,
numbers::realnum::RealNumber,
};
use crate::model_selection::{cross_validate, BaseKFold, CrossValidationResult};
src/model_selection/kfold.rs
+6 -10
View File
@@ -213,17 +213,17 @@ mod tests {
for t in &test_masks[0][0..11] {
// TODO: this can be prob done better
assert_eq!(*t, true)
assert!(*t)
}
for t in &test_masks[0][11..22] {
assert_eq!(*t, false)
assert!(!*t)
}
for t in &test_masks[1][0..11] {
assert_eq!(*t, false)
assert!(!*t)
}
for t in &test_masks[1][11..22] {
assert_eq!(*t, true)
assert!(*t)
}
}
@@ -283,9 +283,7 @@ mod tests {
(vec![0, 1, 2, 3, 7, 8, 9], vec![4, 5, 6]),
(vec![0, 1, 2, 3, 4, 5, 6], vec![7, 8, 9]),
];
for ((train, test), (expected_train, expected_test)) in
k.split(&x).into_iter().zip(expected)
{
for ((train, test), (expected_train, expected_test)) in k.split(&x).zip(expected) {
assert_eq!(test, expected_test);
assert_eq!(train, expected_train);
}
@@ -307,9 +305,7 @@ mod tests {
(vec![0, 1, 2, 3, 7, 8, 9], vec![4, 5, 6]),
(vec![0, 1, 2, 3, 4, 5, 6], vec![7, 8, 9]),
];
for ((train, test), (expected_train, expected_test)) in
k.split(&x).into_iter().zip(expected)
{
for ((train, test), (expected_train, expected_test)) in k.split(&x).zip(expected) {
assert_eq!(test.len(), expected_test.len());
assert_eq!(train.len(), expected_train.len());
}
src/model_selection/mod.rs
+12 -8
View File
@@ -36,7 +36,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//! let y: Vec<f64> = vec![
//! 0., 0., 0., 0., 0., 0., 0., 0., 0., 0., 1., 1., 1., 1., 1., 1., 1., 1., 1., 1.,
//! ];
@@ -84,7 +84,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//! let y: Vec<i32> = vec![
//! 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
//! ];
@@ -169,7 +169,7 @@ pub fn train_test_split<
let n_test = ((n as f32) * test_size) as usize;
if n_test < 1 {
panic!("number of sample is too small {}", n);
panic!("number of sample is too small {n}");
}
let mut indices: Vec<usize> = (0..n).collect();
@@ -396,7 +396,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y: Vec<u32> = vec![0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
let cv = KFold {
@@ -441,7 +442,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
114.2, 115.7, 116.9,
@@ -489,7 +491,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y: Vec<f64> = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
114.2, 115.7, 116.9,
@@ -539,7 +542,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y: Vec<i32> = vec![0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
let cv = KFold::default().with_n_splits(3);
@@ -553,6 +557,6 @@ mod tests {
&accuracy,
)
.unwrap();
println!("{:?}", results);
println!("{results:?}");
}
}
src/naive_bayes/bernoulli.rs
+17 -17
View File
@@ -19,14 +19,14 @@
//! &[0, 1, 0, 0, 1, 0],
//! &[0, 1, 0, 1, 0, 0],
//! &[0, 1, 1, 0, 0, 1],
//! ]);
//! ]).unwrap();
//! let y: Vec<u32> = vec![0, 0, 0, 1];
//!
//! let nb = BernoulliNB::fit(&x, &y, Default::default()).unwrap();
//!
//! // Testing data point is:
//! // Chinese Chinese Chinese Tokyo Japan
//! let x_test = DenseMatrix::from_2d_array(&[&[0, 1, 1, 0, 0, 1]]);
//! let x_test = DenseMatrix::from_2d_array(&[&[0, 1, 1, 0, 0, 1]]).unwrap();
//! let y_hat = nb.predict(&x_test).unwrap();
//! ```
//!
@@ -258,7 +258,7 @@ impl<TY: Number + Ord + Unsigned> BernoulliNBDistribution<TY> {
/// * `x` - training data.
/// * `y` - vector with target values (classes) of length N.
/// * `priors` - Optional vector with prior probabilities of the classes. If not defined,
/// priors are adjusted according to the data.
/// priors are adjusted according to the data.
/// * `alpha` - Additive (Laplace/Lidstone) smoothing parameter.
/// * `binarize` - Threshold for binarizing.
fn fit<TX: Number + PartialOrd, X: Array2<TX>, Y: Array1<TY>>(
@@ -271,21 +271,18 @@ impl<TY: Number + Ord + Unsigned> BernoulliNBDistribution<TY> {
let y_samples = y.shape();
if y_samples != n_samples {
return Err(Failed::fit(&format!(
"Size of x should equal size of y; |x|=[{}], |y|=[{}]",
n_samples, y_samples
"Size of x should equal size of y; |x|=[{n_samples}], |y|=[{y_samples}]"
)));
}
if n_samples == 0 {
return Err(Failed::fit(&format!(
"Size of x and y should greater than 0; |x|=[{}]",
n_samples
"Size of x and y should greater than 0; |x|=[{n_samples}]"
)));
}
if alpha < 0f64 {
return Err(Failed::fit(&format!(
"Alpha should be greater than 0; |alpha|=[{}]",
alpha
"Alpha should be greater than 0; |alpha|=[{alpha}]"
)));
}
@@ -318,8 +315,7 @@ impl<TY: Number + Ord + Unsigned> BernoulliNBDistribution<TY> {
feature_in_class_counter[class_index][idx] +=
row_i.to_usize().ok_or_else(|| {
Failed::fit(&format!(
"Elements of the matrix should be 1.0 or 0.0 |found|=[{}]",
row_i
"Elements of the matrix should be 1.0 or 0.0 |found|=[{row_i}]"
))
})?;
}
@@ -406,10 +402,10 @@ impl<TX: Number + PartialOrd, TY: Number + Ord + Unsigned, X: Array2<TX>, Y: Arr
{
/// Fits BernoulliNB with given data
/// * `x` - training data of size NxM where N is the number of samples and M is the number of
/// features.
/// features.
/// * `y` - vector with target values (classes) of length N.
/// * `parameters` - additional parameters like class priors, alpha for smoothing and
/// binarizing threshold.
/// binarizing threshold.
pub fn fit(x: &X, y: &Y, parameters: BernoulliNBParameters<TX>) -> Result<Self, Failed> {
let distribution = if let Some(threshold) = parameters.binarize {
BernoulliNBDistribution::fit(
@@ -431,6 +427,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord + Unsigned, X: Array2<TX>, Y: Arr
/// Estimates the class labels for the provided data.
/// * `x` - data of shape NxM where N is number of data points to estimate and M is number of features.
///
/// Returns a vector of size N with class estimates.
pub fn predict(&self, x: &X) -> Result<Y, Failed> {
if let Some(threshold) = self.binarize {
@@ -531,7 +528,8 @@ mod tests {
&[0.0, 1.0, 0.0, 0.0, 1.0, 0.0],
&[0.0, 1.0, 0.0, 1.0, 0.0, 0.0],
&[0.0, 1.0, 1.0, 0.0, 0.0, 1.0],
]);
])
.unwrap();
let y: Vec<u32> = vec![0, 0, 0, 1];
let bnb = BernoulliNB::fit(&x, &y, Default::default()).unwrap();
@@ -562,7 +560,7 @@ mod tests {
// Testing data point is:
// Chinese Chinese Chinese Tokyo Japan
let x_test = DenseMatrix::from_2d_array(&[&[0.0, 1.0, 1.0, 0.0, 0.0, 1.0]]);
let x_test = DenseMatrix::from_2d_array(&[&[0.0, 1.0, 1.0, 0.0, 0.0, 1.0]]).unwrap();
let y_hat = bnb.predict(&x_test).unwrap();
assert_eq!(y_hat, &[1]);
@@ -590,7 +588,8 @@ mod tests {
&[2, 0, 3, 3, 1, 2, 0, 2, 4, 1],
&[2, 4, 0, 4, 2, 4, 1, 3, 1, 4],
&[0, 2, 2, 3, 4, 0, 4, 4, 4, 4],
]);
])
.unwrap();
let y: Vec<u32> = vec![2, 2, 0, 0, 0, 2, 1, 1, 0, 1, 0, 0, 2, 0, 2];
let bnb = BernoulliNB::fit(&x, &y, Default::default()).unwrap();
@@ -647,7 +646,8 @@ mod tests {
&[0, 1, 0, 0, 1, 0],
&[0, 1, 0, 1, 0, 0],
&[0, 1, 1, 0, 0, 1],
]);
])
.unwrap();
let y: Vec<u32> = vec![0, 0, 0, 1];
let bnb = BernoulliNB::fit(&x, &y, Default::default()).unwrap();
src/naive_bayes/categorical.rs
+15 -16
View File
@@ -24,7 +24,7 @@
//! &[3, 4, 2, 4],
//! &[0, 3, 1, 2],
//! &[0, 4, 1, 2],
//! ]);
//! ]).unwrap();
//! let y: Vec<u32> = vec![0, 0, 1, 1, 1, 0, 1, 0, 1, 1, 1, 1, 1, 0];
//!
//! let nb = CategoricalNB::fit(&x, &y, Default::default()).unwrap();
@@ -95,7 +95,7 @@ impl<T: Number + Unsigned> PartialEq for CategoricalNBDistribution<T> {
return false;
}
for (a_i_j, b_i_j) in a_i.iter().zip(b_i.iter()) {
if (*a_i_j - *b_i_j).abs() > std::f64::EPSILON {
if (*a_i_j - *b_i_j).abs() > f64::EPSILON {
return false;
}
}
@@ -158,8 +158,7 @@ impl<T: Number + Unsigned> CategoricalNBDistribution<T> {
pub fn fit<X: Array2<T>, Y: Array1<T>>(x: &X, y: &Y, alpha: f64) -> Result<Self, Failed> {
if alpha < 0f64 {
return Err(Failed::fit(&format!(
"alpha should be >= 0, alpha=[{}]",
alpha
"alpha should be >= 0, alpha=[{alpha}]"
)));
}
@@ -167,15 +166,13 @@ impl<T: Number + Unsigned> CategoricalNBDistribution<T> {
let y_samples = y.shape();
if y_samples != n_samples {
return Err(Failed::fit(&format!(
"Size of x should equal size of y; |x|=[{}], |y|=[{}]",
n_samples, y_samples
"Size of x should equal size of y; |x|=[{n_samples}], |y|=[{y_samples}]"
)));
}
if n_samples == 0 {
return Err(Failed::fit(&format!(
"Size of x and y should greater than 0; |x|=[{}]",
n_samples
"Size of x and y should greater than 0; |x|=[{n_samples}]"
)));
}
let y: Vec<usize> = y.iterator(0).map(|y_i| y_i.to_usize().unwrap()).collect();
@@ -202,8 +199,7 @@ impl<T: Number + Unsigned> CategoricalNBDistribution<T> {
.max()
.ok_or_else(|| {
Failed::fit(&format!(
"Failed to get the categories for feature = {}",
feature
"Failed to get the categories for feature = {feature}"
))
})?;
n_categories.push(feature_max + 1);
@@ -367,7 +363,7 @@ impl<T: Number + Unsigned, X: Array2<T>, Y: Array1<T>> Predictor<X, Y> for Categ
impl<T: Number + Unsigned, X: Array2<T>, Y: Array1<T>> CategoricalNB<T, X, Y> {
/// Fits CategoricalNB with given data
/// * `x` - training data of size NxM where N is the number of samples and M is the number of
/// features.
/// features.
/// * `y` - vector with target values (classes) of length N.
/// * `parameters` - additional parameters like alpha for smoothing
pub fn fit(x: &X, y: &Y, parameters: CategoricalNBParameters) -> Result<Self, Failed> {
@@ -379,6 +375,7 @@ impl<T: Number + Unsigned, X: Array2<T>, Y: Array1<T>> CategoricalNB<T, X, Y> {
/// Estimates the class labels for the provided data.
/// * `x` - data of shape NxM where N is number of data points to estimate and M is number of features.
///
/// Returns a vector of size N with class estimates.
pub fn predict(&self, x: &X) -> Result<Y, Failed> {
self.inner.as_ref().unwrap().predict(x)
@@ -429,7 +426,6 @@ mod tests {
fn search_parameters() {
let parameters = CategoricalNBSearchParameters {
alpha: vec![1., 2.],
..Default::default()
};
let mut iter = parameters.into_iter();
let next = iter.next().unwrap();
@@ -460,7 +456,8 @@ mod tests {
&[1, 1, 1, 1],
&[1, 2, 0, 0],
&[2, 1, 1, 1],
]);
])
.unwrap();
let y: Vec<u32> = vec![0, 0, 1, 1, 1, 0, 1, 0, 1, 1, 1, 1, 1, 0];
let cnb = CategoricalNB::fit(&x, &y, Default::default()).unwrap();
@@ -518,7 +515,7 @@ mod tests {
]
);
let x_test = DenseMatrix::from_2d_array(&[&[0, 2, 1, 0], &[2, 2, 0, 0]]);
let x_test = DenseMatrix::from_2d_array(&[&[0, 2, 1, 0], &[2, 2, 0, 0]]).unwrap();
let y_hat = cnb.predict(&x_test).unwrap();
assert_eq!(y_hat, vec![0, 1]);
}
@@ -544,7 +541,8 @@ mod tests {
&[3, 4, 2, 4],
&[0, 3, 1, 2],
&[0, 4, 1, 2],
]);
])
.unwrap();
let y: Vec<u32> = vec![0, 0, 1, 1, 1, 0, 1, 0, 1, 1, 1, 1, 1, 0];
let cnb = CategoricalNB::fit(&x, &y, Default::default()).unwrap();
@@ -576,7 +574,8 @@ mod tests {
&[3, 4, 2, 4],
&[0, 3, 1, 2],
&[0, 4, 1, 2],
]);
])
.unwrap();
let y: Vec<u32> = vec![0, 0, 1, 1, 1, 0, 1, 0, 1, 1, 1, 1, 1, 0];
let cnb = CategoricalNB::fit(&x, &y, Default::default()).unwrap();
src/naive_bayes/gaussian.rs
+12 -11
View File
@@ -16,7 +16,7 @@
//! &[ 1., 1.],
//! &[ 2., 1.],
//! &[ 3., 2.],
//! ]);
//! ]).unwrap();
//! let y: Vec<u32> = vec![1, 1, 1, 2, 2, 2];
//!
//! let nb = GaussianNB::fit(&x, &y, Default::default()).unwrap();
@@ -175,7 +175,7 @@ impl<TY: Number + Ord + Unsigned> GaussianNBDistribution<TY> {
/// * `x` - training data.
/// * `y` - vector with target values (classes) of length N.
/// * `priors` - Optional vector with prior probabilities of the classes. If not defined,
/// priors are adjusted according to the data.
/// priors are adjusted according to the data.
pub fn fit<TX: Number + RealNumber, X: Array2<TX>, Y: Array1<TY>>(
x: &X,
y: &Y,
@@ -185,15 +185,13 @@ impl<TY: Number + Ord + Unsigned> GaussianNBDistribution<TY> {
let y_samples = y.shape();
if y_samples != n_samples {
return Err(Failed::fit(&format!(
"Size of x should equal size of y; |x|=[{}], |y|=[{}]",
n_samples, y_samples
"Size of x should equal size of y; |x|=[{n_samples}], |y|=[{y_samples}]"
)));
}
if n_samples == 0 {
return Err(Failed::fit(&format!(
"Size of x and y should greater than 0; |x|=[{}]",
n_samples
"Size of x and y should greater than 0; |x|=[{n_samples}]"
)));
}
let (class_labels, indices) = y.unique_with_indices();
@@ -319,7 +317,7 @@ impl<TX: Number + RealNumber, TY: Number + Ord + Unsigned, X: Array2<TX>, Y: Arr
{
/// Fits GaussianNB with given data
/// * `x` - training data of size NxM where N is the number of samples and M is the number of
/// features.
/// features.
/// * `y` - vector with target values (classes) of length N.
/// * `parameters` - additional parameters like class priors.
pub fn fit(x: &X, y: &Y, parameters: GaussianNBParameters) -> Result<Self, Failed> {
@@ -330,6 +328,7 @@ impl<TX: Number + RealNumber, TY: Number + Ord + Unsigned, X: Array2<TX>, Y: Arr
/// Estimates the class labels for the provided data.
/// * `x` - data of shape NxM where N is number of data points to estimate and M is number of features.
///
/// Returns a vector of size N with class estimates.
pub fn predict(&self, x: &X) -> Result<Y, Failed> {
self.inner.as_ref().unwrap().predict(x)
@@ -375,7 +374,6 @@ mod tests {
fn search_parameters() {
let parameters = GaussianNBSearchParameters {
priors: vec![Some(vec![1.]), Some(vec![2.])],
..Default::default()
};
let mut iter = parameters.into_iter();
let next = iter.next().unwrap();
@@ -398,7 +396,8 @@ mod tests {
&[1., 1.],
&[2., 1.],
&[3., 2.],
]);
])
.unwrap();
let y: Vec<u32> = vec![1, 1, 1, 2, 2, 2];
let gnb = GaussianNB::fit(&x, &y, Default::default()).unwrap();
@@ -438,7 +437,8 @@ mod tests {
&[1., 1.],
&[2., 1.],
&[3., 2.],
]);
])
.unwrap();
let y: Vec<u32> = vec![1, 1, 1, 2, 2, 2];
let priors = vec![0.3, 0.7];
@@ -465,7 +465,8 @@ mod tests {
&[1., 1.],
&[2., 1.],
&[3., 2.],
]);
])
.unwrap();
let y: Vec<u32> = vec![1, 1, 1, 2, 2, 2];
let gnb = GaussianNB::fit(&x, &y, Default::default()).unwrap();
src/naive_bayes/mod.rs
+85 -10
View File
@@ -40,7 +40,7 @@ use crate::linalg::basic::arrays::{Array1, Array2, ArrayView1};
use crate::numbers::basenum::Number;
#[cfg(feature = "serde")]
use serde::{Deserialize, Serialize};
use std::marker::PhantomData;
use std::{cmp::Ordering, marker::PhantomData};
/// Distribution used in the Naive Bayes classifier.
pub(crate) trait NBDistribution<X: Number, Y: Number>: Clone {
@@ -89,14 +89,14 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>, D: NBDistribution<TX,
/// Estimates the class labels for the provided data.
/// * `x` - data of shape NxM where N is number of data points to estimate and M is number of features.
///
/// Returns a vector of size N with class estimates.
pub fn predict(&self, x: &X) -> Result<Y, Failed> {
let y_classes = self.distribution.classes();
let (rows, _) = x.shape();
let predictions = (0..rows)
.map(|row_index| {
let row = x.get_row(row_index);
let (prediction, _probability) = y_classes
let predictions = x
.row_iter()
.map(|row| {
y_classes
.iter()
.enumerate()
.map(|(class_index, class)| {
@@ -106,11 +106,26 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>, D: NBDistribution<TX,
+ self.distribution.prior(class_index).ln(),
)
})
.max_by(|(_, p1), (_, p2)| p1.partial_cmp(p2).unwrap())
.unwrap();
*prediction
// For some reason, the max_by method cannot use NaNs for finding the maximum value, it panics.
// NaN must be considered as minimum values,
// therefore it's like NaNs would not be considered for choosing the maximum value.
// So we need to handle this case for avoiding panicking by using `Option::unwrap`.
.max_by(|(_, p1), (_, p2)| match p1.partial_cmp(p2) {
Some(ordering) => ordering,
None => {
if p1.is_nan() {
Ordering::Less
} else if p2.is_nan() {
Ordering::Greater
} else {
Ordering::Equal
}
}
})
.map(|(prediction, _probability)| *prediction)
.ok_or_else(|| Failed::predict("Failed to predict, there is no result"))
})
.collect::<Vec<TY>>();
.collect::<Result<Vec<TY>, Failed>>()?;
let y_hat = Y::from_vec_slice(&predictions);
Ok(y_hat)
}
@@ -119,3 +134,63 @@ pub mod bernoulli;
pub mod categorical;
pub mod gaussian;
pub mod multinomial;
#[cfg(test)]
mod tests {
use super::*;
use crate::linalg::basic::arrays::Array;
use crate::linalg::basic::matrix::DenseMatrix;
use num_traits::float::Float;
type Model<'d> = BaseNaiveBayes<i32, i32, DenseMatrix<i32>, Vec<i32>, TestDistribution<'d>>;
#[derive(Debug, PartialEq, Clone)]
struct TestDistribution<'d>(&'d Vec<i32>);
impl<'d> NBDistribution<i32, i32> for TestDistribution<'d> {
fn prior(&self, _class_index: usize) -> f64 {
1.
}
fn log_likelihood<'a>(
&'a self,
class_index: usize,
_j: &'a Box<dyn ArrayView1<i32> + 'a>,
) -> f64 {
match self.0.get(class_index) {
&v @ 2 | &v @ 10 | &v @ 20 => v as f64,
_ => f64::nan(),
}
}
fn classes(&self) -> &Vec<i32> {
self.0
}
}
#[test]
fn test_predict() {
let matrix = DenseMatrix::from_2d_array(&[&[1, 2, 3], &[4, 5, 6], &[7, 8, 9]]).unwrap();
let val = vec![];
match Model::fit(TestDistribution(&val)).unwrap().predict(&matrix) {
Ok(_) => panic!("Should return error in case of empty classes"),
Err(err) => assert_eq!(
err.to_string(),
"Predict failed: Failed to predict, there is no result"
),
}
let val = vec![1, 2, 3];
match Model::fit(TestDistribution(&val)).unwrap().predict(&matrix) {
Ok(r) => assert_eq!(r, vec![2, 2, 2]),
Err(_) => panic!("Should success in normal case with NaNs"),
}
let val = vec![20, 2, 10];
match Model::fit(TestDistribution(&val)).unwrap().predict(&matrix) {
Ok(r) => assert_eq!(r, vec![20, 20, 20]),
Err(_) => panic!("Should success in normal case without NaNs"),
}
}
}
src/naive_bayes/multinomial.rs
+17 -17
View File
@@ -20,13 +20,13 @@
//! &[0, 2, 0, 0, 1, 0],
//! &[0, 1, 0, 1, 0, 0],
//! &[0, 1, 1, 0, 0, 1],
//! ]);
//! ]).unwrap();
//! let y: Vec<u32> = vec![0, 0, 0, 1];
//! let nb = MultinomialNB::fit(&x, &y, Default::default()).unwrap();
//!
//! // Testing data point is:
//! // Chinese Chinese Chinese Tokyo Japan
//! let x_test = DenseMatrix::from_2d_array(&[&[0, 3, 1, 0, 0, 1]]);
//! let x_test = DenseMatrix::from_2d_array(&[&[0, 3, 1, 0, 0, 1]]).unwrap();
//! let y_hat = nb.predict(&x_test).unwrap();
//! ```
//!
@@ -208,7 +208,7 @@ impl<TY: Number + Ord + Unsigned> MultinomialNBDistribution<TY> {
/// * `x` - training data.
/// * `y` - vector with target values (classes) of length N.
/// * `priors` - Optional vector with prior probabilities of the classes. If not defined,
/// priors are adjusted according to the data.
/// priors are adjusted according to the data.
/// * `alpha` - Additive (Laplace/Lidstone) smoothing parameter.
pub fn fit<TX: Number + Unsigned, X: Array2<TX>, Y: Array1<TY>>(
x: &X,
@@ -220,21 +220,18 @@ impl<TY: Number + Ord + Unsigned> MultinomialNBDistribution<TY> {
let y_samples = y.shape();
if y_samples != n_samples {
return Err(Failed::fit(&format!(
"Size of x should equal size of y; |x|=[{}], |y|=[{}]",
n_samples, y_samples
"Size of x should equal size of y; |x|=[{n_samples}], |y|=[{y_samples}]"
)));
}
if n_samples == 0 {
return Err(Failed::fit(&format!(
"Size of x and y should greater than 0; |x|=[{}]",
n_samples
"Size of x and y should greater than 0; |x|=[{n_samples}]"
)));
}
if alpha < 0f64 {
return Err(Failed::fit(&format!(
"Alpha should be greater than 0; |alpha|=[{}]",
alpha
"Alpha should be greater than 0; |alpha|=[{alpha}]"
)));
}
@@ -266,8 +263,7 @@ impl<TY: Number + Ord + Unsigned> MultinomialNBDistribution<TY> {
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
"Elements of the matrix should be convertible to usize |found|=[{row_i}]"
))
})?;
}
@@ -349,10 +345,10 @@ impl<TX: Number + Unsigned, TY: Number + Ord + Unsigned, X: Array2<TX>, Y: Array
{
/// Fits MultinomialNB with given data
/// * `x` - training data of size NxM where N is the number of samples and M is the number of
/// features.
/// features.
/// * `y` - vector with target values (classes) of length N.
/// * `parameters` - additional parameters like class priors, alpha for smoothing and
/// binarizing threshold.
/// binarizing threshold.
pub fn fit(x: &X, y: &Y, parameters: MultinomialNBParameters) -> Result<Self, Failed> {
let distribution =
MultinomialNBDistribution::fit(x, y, parameters.alpha, parameters.priors)?;
@@ -362,6 +358,7 @@ impl<TX: Number + Unsigned, TY: Number + Ord + Unsigned, X: Array2<TX>, Y: Array
/// Estimates the class labels for the provided data.
/// * `x` - data of shape NxM where N is number of data points to estimate and M is number of features.
///
/// Returns a vector of size N with class estimates.
pub fn predict(&self, x: &X) -> Result<Y, Failed> {
self.inner.as_ref().unwrap().predict(x)
@@ -437,7 +434,8 @@ mod tests {
&[0, 2, 0, 0, 1, 0],
&[0, 1, 0, 1, 0, 0],
&[0, 1, 1, 0, 0, 1],
]);
])
.unwrap();
let y: Vec<u32> = vec![0, 0, 0, 1];
let mnb = MultinomialNB::fit(&x, &y, Default::default()).unwrap();
@@ -471,7 +469,7 @@ mod tests {
// Testing data point is:
// Chinese Chinese Chinese Tokyo Japan
let x_test = DenseMatrix::<u32>::from_2d_array(&[&[0, 3, 1, 0, 0, 1]]);
let x_test = DenseMatrix::<u32>::from_2d_array(&[&[0, 3, 1, 0, 0, 1]]).unwrap();
let y_hat = mnb.predict(&x_test).unwrap();
assert_eq!(y_hat, &[0]);
@@ -499,7 +497,8 @@ mod tests {
&[2, 0, 3, 3, 1, 2, 0, 2, 4, 1],
&[2, 4, 0, 4, 2, 4, 1, 3, 1, 4],
&[0, 2, 2, 3, 4, 0, 4, 4, 4, 4],
]);
])
.unwrap();
let y: Vec<u32> = 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();
@@ -558,7 +557,8 @@ mod tests {
&[0, 1, 0, 0, 1, 0],
&[0, 1, 0, 1, 0, 0],
&[0, 1, 1, 0, 0, 1],
]);
])
.unwrap();
let y = vec![0, 0, 0, 1];
let mnb = MultinomialNB::fit(&x, &y, Default::default()).unwrap();
src/neighbors/knn_classifier.rs
+12 -8
View File
@@ -22,7 +22,7 @@
//! &[3., 4.],
//! &[5., 6.],
//! &[7., 8.],
//! &[9., 10.]]);
//! &[9., 10.]]).unwrap();
//! let y = vec![2, 2, 2, 3, 3]; //your class labels
//!
//! let knn = KNNClassifier::fit(&x, &y, Default::default()).unwrap();
@@ -211,7 +211,7 @@ impl<TX: Number, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>, D: Distance<Vec
{
/// Fits KNN classifier to a NxM matrix where N is number of samples and M is number of features.
/// * `x` - training data
/// * `y` - vector with target values (classes) of length N
/// * `y` - vector with target values (classes) of length N
/// * `parameters` - additional parameters like search algorithm and k
pub fn fit(
x: &X,
@@ -236,8 +236,7 @@ impl<TX: Number, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>, D: Distance<Vec
if x_n != y_n {
return Err(Failed::fit(&format!(
"Size of x should equal size of y; |x|=[{}], |y|=[{}]",
x_n, y_n
"Size of x should equal size of y; |x|=[{x_n}], |y|=[{y_n}]"
)));
}
@@ -262,6 +261,7 @@ impl<TX: Number, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>, D: Distance<Vec
/// Estimates the class labels for the provided data.
/// * `x` - data of shape NxM where N is number of data points to estimate and M is number of features.
///
/// Returns a vector of size N with class estimates.
pub fn predict(&self, x: &X) -> Result<Y, Failed> {
let mut result = Y::zeros(x.shape().0);
@@ -312,7 +312,8 @@ mod tests {
#[test]
fn knn_fit_predict() {
let x =
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]]);
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]])
.unwrap();
let y = vec![2, 2, 2, 3, 3];
let knn = KNNClassifier::fit(&x, &y, Default::default()).unwrap();
let y_hat = knn.predict(&x).unwrap();
@@ -326,7 +327,7 @@ mod tests {
)]
#[test]
fn knn_fit_predict_weighted() {
let x = DenseMatrix::from_2d_array(&[&[1.], &[2.], &[3.], &[4.], &[5.]]);
let x = DenseMatrix::from_2d_array(&[&[1.], &[2.], &[3.], &[4.], &[5.]]).unwrap();
let y = vec![2, 2, 2, 3, 3];
let knn = KNNClassifier::fit(
&x,
@@ -337,7 +338,9 @@ mod tests {
.with_weight(KNNWeightFunction::Distance),
)
.unwrap();
let y_hat = knn.predict(&DenseMatrix::from_2d_array(&[&[4.1]])).unwrap();
let y_hat = knn
.predict(&DenseMatrix::from_2d_array(&[&[4.1]]).unwrap())
.unwrap();
assert_eq!(vec![3], y_hat);
}
@@ -349,7 +352,8 @@ mod tests {
#[cfg(feature = "serde")]
fn serde() {
let x =
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]]);
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]])
.unwrap();
let y = vec![2, 2, 2, 3, 3];
let knn = KNNClassifier::fit(&x, &y, Default::default()).unwrap();
src/neighbors/knn_regressor.rs
+13 -14
View File
@@ -24,7 +24,7 @@
//! &[2., 2.],
//! &[3., 3.],
//! &[4., 4.],
//! &[5., 5.]]);
//! &[5., 5.]]).unwrap();
//! let y = vec![1., 2., 3., 4., 5.]; //your target values
//!
//! let knn = KNNRegressor::fit(&x, &y, Default::default()).unwrap();
@@ -88,25 +88,21 @@ pub struct KNNRegressor<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>, D:
impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>, D: Distance<Vec<TX>>>
KNNRegressor<TX, TY, X, Y, D>
{
///
fn y(&self) -> &Y {
self.y.as_ref().unwrap()
}
///
fn knn_algorithm(&self) -> &KNNAlgorithm<TX, D> {
self.knn_algorithm
.as_ref()
.expect("Missing parameter: KNNAlgorithm")
}
///
fn weight(&self) -> &KNNWeightFunction {
self.weight.as_ref().expect("Missing parameter: weight")
}
#[allow(dead_code)]
///
fn k(&self) -> usize {
self.k.unwrap()
}
@@ -207,7 +203,7 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>, D: Distance<Vec<TX>>>
{
/// Fits KNN regressor to a NxM matrix where N is number of samples and M is number of features.
/// * `x` - training data
/// * `y` - vector with real values
/// * `y` - vector with real values
/// * `parameters` - additional parameters like search algorithm and k
pub fn fit(
x: &X,
@@ -224,8 +220,7 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>, D: Distance<Vec<TX>>>
if x_n != y_n {
return Err(Failed::fit(&format!(
"Size of x should equal size of y; |x|=[{}], |y|=[{}]",
x_n, y_n
"Size of x should equal size of y; |x|=[{x_n}], |y|=[{y_n}]"
)));
}
@@ -251,6 +246,7 @@ impl<TX: Number, TY: Number, X: Array2<TX>, Y: Array1<TY>, D: Distance<Vec<TX>>>
/// Predict the target for the provided data.
/// * `x` - data of shape NxM where N is number of data points to estimate and M is number of features.
///
/// Returns a vector of size N with estimates.
pub fn predict(&self, x: &X) -> Result<Y, Failed> {
let mut result = Y::zeros(x.shape().0);
@@ -296,9 +292,10 @@ mod tests {
#[test]
fn knn_fit_predict_weighted() {
let x =
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]]);
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]])
.unwrap();
let y: Vec<f64> = vec![1., 2., 3., 4., 5.];
let y_exp = vec![1., 2., 3., 4., 5.];
let y_exp = [1., 2., 3., 4., 5.];
let knn = KNNRegressor::fit(
&x,
&y,
@@ -312,7 +309,7 @@ mod tests {
let y_hat = knn.predict(&x).unwrap();
assert_eq!(5, Vec::len(&y_hat));
for i in 0..y_hat.len() {
assert!((y_hat[i] - y_exp[i]).abs() < std::f64::EPSILON);
assert!((y_hat[i] - y_exp[i]).abs() < f64::EPSILON);
}
}
@@ -323,9 +320,10 @@ mod tests {
#[test]
fn knn_fit_predict_uniform() {
let x =
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]]);
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]])
.unwrap();
let y: Vec<f64> = vec![1., 2., 3., 4., 5.];
let y_exp = vec![2., 2., 3., 4., 4.];
let y_exp = [2., 2., 3., 4., 4.];
let knn = KNNRegressor::fit(&x, &y, Default::default()).unwrap();
let y_hat = knn.predict(&x).unwrap();
assert_eq!(5, Vec::len(&y_hat));
@@ -342,7 +340,8 @@ mod tests {
#[cfg(feature = "serde")]
fn serde() {
let x =
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]]);
DenseMatrix::from_2d_array(&[&[1., 2.], &[3., 4.], &[5., 6.], &[7., 8.], &[9., 10.]])
.unwrap();
let y = vec![1., 2., 3., 4., 5.];
let knn = KNNRegressor::fit(&x, &y, Default::default()).unwrap();
src/neighbors/mod.rs
+2 -7
View File
@@ -49,20 +49,15 @@ pub type KNNAlgorithmName = crate::algorithm::neighbour::KNNAlgorithmName;
/// Weight function that is used to determine estimated value.
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Clone)]
#[derive(Debug, Clone, Default)]
pub enum KNNWeightFunction {
/// All k nearest points are weighted equally
#[default]
Uniform,
/// k nearest points are weighted by the inverse of their distance. Closer neighbors will have a greater influence than neighbors which are further away.
Distance,
}
impl Default for KNNWeightFunction {
fn default() -> Self {
KNNWeightFunction::Uniform
}
}
impl KNNWeightFunction {
fn calc_weights(&self, distances: Vec<f64>) -> std::vec::Vec<f64> {
match *self {
src/numbers/realnum.rs
+26 -3
View File
@@ -2,9 +2,13 @@
//! Most algorithms in `smartcore` rely on basic linear algebra operations like dot product, matrix decomposition and other subroutines that are defined for a set of real numbers, .
//! This module defines real number and some useful functions that are used in [Linear Algebra](../../linalg/index.html) module.
use rand::rngs::SmallRng;
use rand::{Rng, SeedableRng};
use num_traits::Float;
use crate::numbers::basenum::Number;
use crate::rand_custom::get_rng_impl;
/// Defines real number
/// <script type="text/javascript" src="https://cdnjs.cloudflare.com/ajax/libs/mathjax/2.7.0/MathJax.js?config=TeX-AMS_CHTML"></script>
@@ -63,8 +67,12 @@ impl RealNumber for f64 {
}
fn rand() -> f64 {
// TODO: to be implemented, see issue smartcore#214
1.0
let mut small_rng = get_rng_impl(None);
let mut rngs: Vec<SmallRng> = (0..3)
.map(|_| SmallRng::from_rng(&mut small_rng).unwrap())
.collect();
rngs[0].gen::<f64>()
}
fn two() -> Self {
@@ -108,7 +116,12 @@ impl RealNumber for f32 {
}
fn rand() -> f32 {
1.0
let mut small_rng = get_rng_impl(None);
let mut rngs: Vec<SmallRng> = (0..3)
.map(|_| SmallRng::from_rng(&mut small_rng).unwrap())
.collect();
rngs[0].gen::<f32>()
}
fn two() -> Self {
@@ -149,4 +162,14 @@ mod tests {
fn f64_from_string() {
assert_eq!(f64::from_str("1.111111111").unwrap(), 1.111111111)
}
#[test]
fn f64_rand() {
f64::rand();
}
#[test]
fn f32_rand() {
f32::rand();
}
}
src/optimization/first_order/gradient_descent.rs
+10 -14
View File
@@ -1,5 +1,3 @@
// TODO: missing documentation
use std::default::Default;
use crate::linalg::basic::arrays::Array1;
@@ -8,30 +6,27 @@ use crate::optimization::first_order::{FirstOrderOptimizer, OptimizerResult};
use crate::optimization::line_search::LineSearchMethod;
use crate::optimization::{DF, F};
///
/// Gradient Descent optimization algorithm
pub struct GradientDescent {
///
/// Maximum number of iterations
pub max_iter: usize,
///
/// Relative tolerance for the gradient norm
pub g_rtol: f64,
///
/// Absolute tolerance for the gradient norm
pub g_atol: f64,
}
///
impl Default for GradientDescent {
fn default() -> Self {
GradientDescent {
max_iter: 10000,
g_rtol: std::f64::EPSILON.sqrt(),
g_atol: std::f64::EPSILON,
g_rtol: f64::EPSILON.sqrt(),
g_atol: f64::EPSILON,
}
}
}
///
impl<T: FloatNumber> FirstOrderOptimizer<T> for GradientDescent {
///
fn optimize<'a, X: Array1<T>, LS: LineSearchMethod<T>>(
&self,
f: &'a F<'_, T, X>,
@@ -113,12 +108,13 @@ mod tests {
g[1] = 200. * (x[1] - x[0].powf(2.));
};
let mut ls: Backtracking<f64> = Default::default();
ls.order = FunctionOrder::THIRD;
let ls: Backtracking<f64> = Backtracking::<f64> {
order: FunctionOrder::THIRD,
..Default::default()
};
let optimizer: GradientDescent = Default::default();
let result = optimizer.optimize(&f, &df, &x0, &ls);
println!("{:?}", result);
assert!((result.f_x - 0.0).abs() < 1e-5);
assert!((result.x[0] - 1.0).abs() < 1e-2);
src/optimization/first_order/lbfgs.rs
+20 -29
View File
@@ -11,31 +11,29 @@ use crate::optimization::first_order::{FirstOrderOptimizer, OptimizerResult};
use crate::optimization::line_search::LineSearchMethod;
use crate::optimization::{DF, F};
///
/// Limited-memory BFGS optimization algorithm
pub struct LBFGS {
///
/// Maximum number of iterations
pub max_iter: usize,
///
/// TODO: Add documentation
pub g_rtol: f64,
///
/// TODO: Add documentation
pub g_atol: f64,
///
/// TODO: Add documentation
pub x_atol: f64,
///
/// TODO: Add documentation
pub x_rtol: f64,
///
/// TODO: Add documentation
pub f_abstol: f64,
///
/// TODO: Add documentation
pub f_reltol: f64,
///
/// TODO: Add documentation
pub successive_f_tol: usize,
///
/// TODO: Add documentation
pub m: usize,
}
///
impl Default for LBFGS {
///
fn default() -> Self {
LBFGS {
max_iter: 1000,
@@ -51,9 +49,7 @@ impl Default for LBFGS {
}
}
///
impl LBFGS {
///
fn two_loops<T: FloatNumber + RealNumber, X: Array1<T>>(&self, state: &mut LBFGSState<T, X>) {
let lower = state.iteration.max(self.m) - self.m;
let upper = state.iteration;
@@ -95,7 +91,6 @@ impl LBFGS {
state.s.mul_scalar_mut(-T::one());
}
///
fn init_state<T: FloatNumber + RealNumber, X: Array1<T>>(&self, x: &X) -> LBFGSState<T, X> {
LBFGSState {
x: x.clone(),
@@ -119,7 +114,6 @@ impl LBFGS {
}
}
///
fn update_state<'a, T: FloatNumber + RealNumber, X: Array1<T>, LS: LineSearchMethod<T>>(
&self,
f: &'a F<'_, T, X>,
@@ -161,7 +155,6 @@ impl LBFGS {
df(&mut state.x_df, &state.x);
}
///
fn assess_convergence<T: FloatNumber, X: Array1<T>>(
&self,
state: &mut LBFGSState<T, X>,
@@ -173,7 +166,7 @@ impl LBFGS {
}
if state.x.max_diff(&state.x_prev)
<= T::from_f64(self.x_rtol * state.x.norm(std::f64::INFINITY)).unwrap()
<= T::from_f64(self.x_rtol * state.x.norm(f64::INFINITY)).unwrap()
{
x_converged = true;
}
@@ -188,17 +181,16 @@ impl LBFGS {
state.counter_f_tol += 1;
}
if state.x_df.norm(std::f64::INFINITY) <= self.g_atol {
if state.x_df.norm(f64::INFINITY) <= self.g_atol {
g_converged = true;
}
g_converged || x_converged || state.counter_f_tol > self.successive_f_tol
}
///
fn update_hessian<'a, T: FloatNumber, X: Array1<T>>(
fn update_hessian<T: FloatNumber, X: Array1<T>>(
&self,
_: &'a DF<'_, X>,
_: &DF<'_, X>,
state: &mut LBFGSState<T, X>,
) {
state.dg = state.x_df.sub(&state.x_df_prev);
@@ -212,7 +204,6 @@ impl LBFGS {
}
}
///
#[derive(Debug)]
struct LBFGSState<T: FloatNumber, X: Array1<T>> {
x: X,
@@ -234,9 +225,7 @@ struct LBFGSState<T: FloatNumber, X: Array1<T>> {
alpha: T,
}
///
impl<T: FloatNumber + RealNumber> FirstOrderOptimizer<T> for LBFGS {
///
fn optimize<'a, X: Array1<T>, LS: LineSearchMethod<T>>(
&self,
f: &F<'_, T, X>,
@@ -248,7 +237,7 @@ impl<T: FloatNumber + RealNumber> FirstOrderOptimizer<T> for LBFGS {
df(&mut state.x_df, x0);
let g_converged = state.x_df.norm(std::f64::INFINITY) < self.g_atol;
let g_converged = state.x_df.norm(f64::INFINITY) < self.g_atol;
let mut converged = g_converged;
let stopped = false;
@@ -291,13 +280,15 @@ mod tests {
g[0] = -2. * (1. - x[0]) - 400. * (x[1] - x[0].powf(2.)) * x[0];
g[1] = 200. * (x[1] - x[0].powf(2.));
};
let mut ls: Backtracking<f64> = Default::default();
ls.order = FunctionOrder::THIRD;
let ls: Backtracking<f64> = Backtracking::<f64> {
order: FunctionOrder::THIRD,
..Default::default()
};
let optimizer: LBFGS = Default::default();
let result = optimizer.optimize(&f, &df, &x0, &ls);
assert!((result.f_x - 0.0).abs() < std::f64::EPSILON);
assert!((result.f_x - 0.0).abs() < f64::EPSILON);
assert!((result.x[0] - 1.0).abs() < 1e-8);
assert!((result.x[1] - 1.0).abs() < 1e-8);
assert!(result.iterations <= 24);
src/optimization/first_order/mod.rs
+8 -8
View File
@@ -1,6 +1,6 @@
///
/// Gradient descent optimization algorithm
pub mod gradient_descent;
///
/// Limited-memory BFGS optimization algorithm
pub mod lbfgs;
use std::clone::Clone;
@@ -11,9 +11,9 @@ use crate::numbers::floatnum::FloatNumber;
use crate::optimization::line_search::LineSearchMethod;
use crate::optimization::{DF, F};
///
/// First-order optimization is a class of algorithms that use the first derivative of a function to find optimal solutions.
pub trait FirstOrderOptimizer<T: FloatNumber> {
///
/// run first order optimization
fn optimize<'a, X: Array1<T>, LS: LineSearchMethod<T>>(
&self,
f: &F<'_, T, X>,
@@ -23,13 +23,13 @@ pub trait FirstOrderOptimizer<T: FloatNumber> {
) -> OptimizerResult<T, X>;
}
///
/// Result of optimization
#[derive(Debug, Clone)]
pub struct OptimizerResult<T: FloatNumber, X: Array1<T>> {
///
/// Solution
pub x: X,
///
/// f(x) value
pub f_x: T,
///
/// number of iterations
pub iterations: usize,
}
src/optimization/line_search.rs
+12 -17
View File
@@ -1,11 +1,9 @@
// TODO: missing documentation
use crate::optimization::FunctionOrder;
use num_traits::Float;
///
/// Line search optimization.
pub trait LineSearchMethod<T: Float> {
///
/// Find alpha that satisfies strong Wolfe conditions.
fn search(
&self,
f: &(dyn Fn(T) -> T),
@@ -16,32 +14,31 @@ pub trait LineSearchMethod<T: Float> {
) -> LineSearchResult<T>;
}
///
/// Line search result
#[derive(Debug, Clone)]
pub struct LineSearchResult<T: Float> {
///
/// Alpha value
pub alpha: T,
///
/// f(alpha) value
pub f_x: T,
}
///
/// Backtracking line search method.
pub struct Backtracking<T: Float> {
///
/// TODO: Add documentation
pub c1: T,
///
/// Maximum number of iterations for Backtracking single run
pub max_iterations: usize,
///
/// TODO: Add documentation
pub max_infinity_iterations: usize,
///
/// TODO: Add documentation
pub phi: T,
///
/// TODO: Add documentation
pub plo: T,
///
/// function order
pub order: FunctionOrder,
}
///
impl<T: Float> Default for Backtracking<T> {
fn default() -> Self {
Backtracking {
@@ -55,9 +52,7 @@ impl<T: Float> Default for Backtracking<T> {
}
}
///
impl<T: Float> LineSearchMethod<T> for Backtracking<T> {
///
fn search(
&self,
f: &(dyn Fn(T) -> T),
src/optimization/mod.rs
+7 -9
View File
@@ -1,21 +1,19 @@
// TODO: missing documentation
///
/// first order optimization algorithms
pub mod first_order;
///
/// line search algorithms
pub mod line_search;
///
/// Function f(x) = y
pub type F<'a, T, X> = dyn for<'b> Fn(&'b X) -> T + 'a;
///
/// Function df(x)
pub type DF<'a, X> = dyn for<'b> Fn(&'b mut X, &'b X) + 'a;
///
/// Function order
#[allow(clippy::upper_case_acronyms)]
#[derive(Debug, PartialEq, Eq)]
pub enum FunctionOrder {
///
/// Second order
SECOND,
///
/// Third order
THIRD,
}
src/preprocessing/categorical.rs
+16 -16
View File
@@ -12,7 +12,7 @@
//! &[1.5, 2.0, 1.5, 4.0],
//! &[1.5, 1.0, 1.5, 5.0],
//! &[1.5, 2.0, 1.5, 6.0],
//! ]);
//! ]).unwrap();
//! let encoder_params = OneHotEncoderParams::from_cat_idx(&[1, 3]);
//! // Infer number of categories from data and return a reusable encoder
//! let encoder = OneHotEncoder::fit(&data, encoder_params).unwrap();
@@ -132,8 +132,7 @@ impl OneHotEncoder {
data.copy_col_as_vec(idx, &mut col_buf);
if !validate_col_is_categorical(&col_buf) {
let msg = format!(
"Column {} of data matrix containts non categorizable (integer) values",
idx
"Column {idx} of data matrix containts non categorizable (integer) values"
);
return Err(Failed::fit(&msg[..]));
}
@@ -182,7 +181,7 @@ impl OneHotEncoder {
match oh_vec {
None => {
// Since we support T types, bad value in a series causes in to be invalid
let msg = format!("At least one value in column {} doesn't conform to category definition", old_cidx);
let msg = format!("At least one value in column {old_cidx} doesn't conform to category definition");
return Err(Failed::transform(&msg[..]));
}
Some(v) => {
@@ -241,14 +240,16 @@ mod tests {
&[2.0, 1.5, 4.0],
&[1.0, 1.5, 5.0],
&[2.0, 1.5, 6.0],
]);
])
.unwrap();
let oh_enc = DenseMatrix::from_2d_array(&[
&[1.0, 0.0, 1.5, 1.0, 0.0, 0.0, 0.0],
&[0.0, 1.0, 1.5, 0.0, 1.0, 0.0, 0.0],
&[1.0, 0.0, 1.5, 0.0, 0.0, 1.0, 0.0],
&[0.0, 1.0, 1.5, 0.0, 0.0, 0.0, 1.0],
]);
])
.unwrap();
(orig, oh_enc)
}
@@ -260,14 +261,16 @@ mod tests {
&[1.5, 2.0, 1.5, 4.0],
&[1.5, 1.0, 1.5, 5.0],
&[1.5, 2.0, 1.5, 6.0],
]);
])
.unwrap();
let oh_enc = DenseMatrix::from_2d_array(&[
&[1.5, 1.0, 0.0, 1.5, 1.0, 0.0, 0.0, 0.0],
&[1.5, 0.0, 1.0, 1.5, 0.0, 1.0, 0.0, 0.0],
&[1.5, 1.0, 0.0, 1.5, 0.0, 0.0, 1.0, 0.0],
&[1.5, 0.0, 1.0, 1.5, 0.0, 0.0, 0.0, 1.0],
]);
])
.unwrap();
(orig, oh_enc)
}
@@ -278,7 +281,7 @@ mod tests {
)]
#[test]
fn hash_encode_f64_series() {
let series = vec![3.0, 1.0, 2.0, 1.0];
let series = [3.0, 1.0, 2.0, 1.0];
let hashable_series: Vec<CategoricalFloat> =
series.iter().map(|v| v.to_category()).collect();
let enc = CategoryMapper::from_positional_category_vec(hashable_series);
@@ -335,14 +338,11 @@ mod tests {
&[2.0, 1.5, 4.0],
&[1.0, 1.5, 5.0],
&[2.0, 1.5, 6.0],
]);
])
.unwrap();
let params = OneHotEncoderParams::from_cat_idx(&[1]);
match OneHotEncoder::fit(&m, params) {
Err(_) => {
assert!(true);
}
_ => assert!(false),
}
let result = OneHotEncoder::fit(&m, params);
assert!(result.is_err());
}
}
src/preprocessing/numerical.rs
+48 -39
View File
@@ -11,7 +11,7 @@
//! vec![0.0, 0.0],
//! vec![1.0, 1.0],
//! vec![1.0, 1.0],
//! ]);
//! ]).unwrap();
//!
//! let standard_scaler =
//! numerical::StandardScaler::fit(&data, numerical::StandardScalerParameters::default())
@@ -24,7 +24,7 @@
//! vec![-1.0, -1.0],
//! vec![1.0, 1.0],
//! vec![1.0, 1.0],
//! ])
//! ]).unwrap()
//! );
//! ```
use std::marker::PhantomData;
@@ -197,15 +197,18 @@ mod tests {
fn combine_three_columns() {
assert_eq!(
build_matrix_from_columns(vec![
DenseMatrix::from_2d_vec(&vec![vec![1.0], vec![1.0], vec![1.0],]),
DenseMatrix::from_2d_vec(&vec![vec![2.0], vec![2.0], vec![2.0],]),
DenseMatrix::from_2d_vec(&vec![vec![3.0], vec![3.0], vec![3.0],])
DenseMatrix::from_2d_vec(&vec![vec![1.0], vec![1.0], vec![1.0],]).unwrap(),
DenseMatrix::from_2d_vec(&vec![vec![2.0], vec![2.0], vec![2.0],]).unwrap(),
DenseMatrix::from_2d_vec(&vec![vec![3.0], vec![3.0], vec![3.0],]).unwrap()
]),
Some(DenseMatrix::from_2d_vec(&vec![
vec![1.0, 2.0, 3.0],
vec![1.0, 2.0, 3.0],
vec![1.0, 2.0, 3.0]
]))
Some(
DenseMatrix::from_2d_vec(&vec![
vec![1.0, 2.0, 3.0],
vec![1.0, 2.0, 3.0],
vec![1.0, 2.0, 3.0]
])
.unwrap()
)
)
}
@@ -287,21 +290,24 @@ mod tests {
/// sklearn.
#[test]
fn fit_transform_random_values() {
let transformed_values =
fit_transform_with_default_standard_scaler(&DenseMatrix::from_2d_array(&[
let transformed_values = fit_transform_with_default_standard_scaler(
&DenseMatrix::from_2d_array(&[
&[0.1004222429, 0.2194113576, 0.9310663354, 0.3313593793],
&[0.2045493861, 0.1683865411, 0.5071506765, 0.7257355264],
&[0.5708488802, 0.1846414616, 0.9590802982, 0.5591871046],
&[0.8387612750, 0.5754861361, 0.5537109852, 0.1077646442],
]));
println!("{}", transformed_values);
])
.unwrap(),
);
println!("{transformed_values}");
assert!(transformed_values.approximate_eq(
&DenseMatrix::from_2d_array(&[
&[-1.1154020653, -0.4031985330, 0.9284605204, -0.4271473866],
&[-0.7615464283, -0.7076698384, -1.1075452562, 1.2632979631],
&[0.4832504303, -0.6106747444, 1.0630075435, 0.5494084257],
&[1.3936980634, 1.7215431158, -0.8839228078, -1.3855590021],
]),
])
.unwrap(),
1.0
))
}
@@ -310,13 +316,10 @@ mod tests {
#[test]
fn fit_transform_with_zero_variance() {
assert_eq!(
fit_transform_with_default_standard_scaler(&DenseMatrix::from_2d_array(&[
&[1.0],
&[1.0],
&[1.0],
&[1.0]
])),
DenseMatrix::from_2d_array(&[&[0.0], &[0.0], &[0.0], &[0.0]]),
fit_transform_with_default_standard_scaler(
&DenseMatrix::from_2d_array(&[&[1.0], &[1.0], &[1.0], &[1.0]]).unwrap()
),
DenseMatrix::from_2d_array(&[&[0.0], &[0.0], &[0.0], &[0.0]]).unwrap(),
"When scaling values with zero variance, zero is expected as return value"
)
}
@@ -331,7 +334,8 @@ mod tests {
&[1.0, 2.0, 5.0],
&[1.0, 1.0, 1.0],
&[1.0, 2.0, 5.0]
]),
])
.unwrap(),
StandardScalerParameters::default(),
),
Ok(StandardScaler {
@@ -354,7 +358,8 @@ mod tests {
&[0.2045493861, 0.1683865411, 0.5071506765, 0.7257355264],
&[0.5708488802, 0.1846414616, 0.9590802982, 0.5591871046],
&[0.8387612750, 0.5754861361, 0.5537109852, 0.1077646442],
]),
])
.unwrap(),
StandardScalerParameters::default(),
)
.unwrap();
@@ -364,17 +369,18 @@ mod tests {
vec![0.42864544605, 0.2869813741, 0.737752073825, 0.431011663625],
);
assert!(
&DenseMatrix::<f64>::from_2d_vec(&vec![fitted_scaler.stds]).approximate_eq(
assert!(&DenseMatrix::<f64>::from_2d_vec(&vec![fitted_scaler.stds])
.unwrap()
.approximate_eq(
&DenseMatrix::from_2d_array(&[&[
0.29426447500954,
0.16758497615485,
0.20820945786863,
0.23329718831165
],]),
],])
.unwrap(),
0.00000000000001
)
)
))
}
/// If `with_std` is set to `false` the values should not be
@@ -392,8 +398,9 @@ mod tests {
};
assert_eq!(
standard_scaler.transform(&DenseMatrix::from_2d_array(&[&[0.0, 2.0], &[2.0, 4.0]])),
Ok(DenseMatrix::from_2d_array(&[&[-1.0, -1.0], &[1.0, 1.0]]))
standard_scaler
.transform(&DenseMatrix::from_2d_array(&[&[0.0, 2.0], &[2.0, 4.0]]).unwrap()),
Ok(DenseMatrix::from_2d_array(&[&[-1.0, -1.0], &[1.0, 1.0]]).unwrap())
)
}
@@ -413,8 +420,8 @@ mod tests {
assert_eq!(
standard_scaler
.transform(&DenseMatrix::from_2d_array(&[&[0.0, 9.0], &[4.0, 12.0]])),
Ok(DenseMatrix::from_2d_array(&[&[0.0, 3.0], &[2.0, 4.0]]))
.transform(&DenseMatrix::from_2d_array(&[&[0.0, 9.0], &[4.0, 12.0]]).unwrap()),
Ok(DenseMatrix::from_2d_array(&[&[0.0, 3.0], &[2.0, 4.0]]).unwrap())
)
}
@@ -433,7 +440,8 @@ mod tests {
&[0.2045493861, 0.1683865411, 0.5071506765, 0.7257355264],
&[0.5708488802, 0.1846414616, 0.9590802982, 0.5591871046],
&[0.8387612750, 0.5754861361, 0.5537109852, 0.1077646442],
]),
])
.unwrap(),
StandardScalerParameters::default(),
)
.unwrap();
@@ -446,17 +454,18 @@ mod tests {
vec![0.42864544605, 0.2869813741, 0.737752073825, 0.431011663625],
);
assert!(
&DenseMatrix::from_2d_vec(&vec![deserialized_scaler.stds]).approximate_eq(
assert!(&DenseMatrix::from_2d_vec(&vec![deserialized_scaler.stds])
.unwrap()
.approximate_eq(
&DenseMatrix::from_2d_array(&[&[
0.29426447500954,
0.16758497615485,
0.20820945786863,
0.23329718831165
],]),
],])
.unwrap(),
0.00000000000001
)
)
))
}
}
}
src/preprocessing/series_encoder.rs
+4 -4
View File
@@ -206,7 +206,7 @@ mod tests {
#[test]
fn from_categories() {
let fake_categories: Vec<usize> = vec![1, 2, 3, 4, 5, 3, 5, 3, 1, 2, 4];
let it = fake_categories.iter().map(|&a| a);
let it = fake_categories.iter().copied();
let enc = CategoryMapper::<usize>::fit_to_iter(it);
let oh_vec: Vec<f64> = match enc.get_one_hot(&1) {
None => panic!("Wrong categories"),
@@ -218,8 +218,8 @@ mod tests {
fn build_fake_str_enc<'a>() -> CategoryMapper<&'a str> {
let fake_category_pos = vec!["background", "dog", "cat"];
let enc = CategoryMapper::<&str>::from_positional_category_vec(fake_category_pos);
enc
CategoryMapper::<&str>::from_positional_category_vec(fake_category_pos)
}
#[cfg_attr(
all(target_arch = "wasm32", not(target_os = "wasi")),
@@ -275,7 +275,7 @@ mod tests {
let lab = enc.invert_one_hot(res).unwrap();
assert_eq!(lab, "dog");
if let Err(e) = enc.invert_one_hot(vec![0.0, 0.0, 0.0]) {
let pos_entries = format!("Expected a single positive entry, 0 entires found");
let pos_entries = "Expected a single positive entry, 0 entires found".to_string();
assert_eq!(e, Failed::transform(&pos_entries[..]));
};
}
src/readers/csv.rs
+8 -13
View File
@@ -83,7 +83,7 @@ where
Matrix: Array2<T>,
{
let csv_text = read_string_from_source(source)?;
let rows: Vec<Vec<T>> = extract_row_vectors_from_csv_text::<T, RowVector, Matrix>(
let rows: Vec<Vec<T>> = extract_row_vectors_from_csv_text(
&csv_text,
&definition,
detect_row_format(&csv_text, &definition)?,
@@ -103,12 +103,7 @@ where
/// Given a string containing the contents of a csv file, extract its value
/// into row-vectors.
fn extract_row_vectors_from_csv_text<
'a,
T: Number + RealNumber + std::str::FromStr,
RowVector: Array1<T>,
Matrix: Array2<T>,
>(
fn extract_row_vectors_from_csv_text<'a, T: Number + RealNumber + std::str::FromStr>(
csv_text: &'a str,
definition: &'a CSVDefinition<'_>,
row_format: CSVRowFormat<'_>,
@@ -167,7 +162,7 @@ where
}
/// Ensure that a string containing a csv row conforms to a specified row format.
fn validate_csv_row<'a>(row: &'a str, row_format: &CSVRowFormat<'_>) -> Result<(), ReadingError> {
fn validate_csv_row(row: &str, row_format: &CSVRowFormat<'_>) -> Result<(), ReadingError> {
let actual_number_of_fields = row.split(row_format.field_seperator).count();
if row_format.n_fields == actual_number_of_fields {
Ok(())
@@ -208,7 +203,7 @@ where
match value_string.parse::<T>().ok() {
Some(value) => Ok(value),
None => Err(ReadingError::InvalidField {
msg: format!("Value '{}' could not be read.", value_string,),
msg: format!("Value '{value_string}' could not be read.",),
}),
}
}
@@ -243,7 +238,8 @@ mod tests {
&[5.1, 3.5, 1.4, 0.2],
&[4.9, 3.0, 1.4, 0.2],
&[4.7, 3.2, 1.3, 0.2],
]))
])
.unwrap())
)
}
#[test]
@@ -266,7 +262,7 @@ mod tests {
&[5.1, 3.5, 1.4, 0.2],
&[4.9, 3.0, 1.4, 0.2],
&[4.7, 3.2, 1.3, 0.2],
]))
]).unwrap())
)
}
#[test]
@@ -305,12 +301,11 @@ mod tests {
}
mod extract_row_vectors_from_csv_text {
use super::super::{extract_row_vectors_from_csv_text, CSVDefinition, CSVRowFormat};
use crate::linalg::basic::matrix::DenseMatrix;
#[test]
fn read_default_csv() {
assert_eq!(
extract_row_vectors_from_csv_text::<f64, Vec<_>, DenseMatrix<_>>(
extract_row_vectors_from_csv_text::<f64>(
"column 1, column 2, column3\n1.0,2.0,3.0\n4.0,5.0,6.0",
&CSVDefinition::default(),
CSVRowFormat {
src/svm/mod.rs
+2 -2
View File
@@ -56,7 +56,7 @@ pub struct Kernels;
impl Kernels {
/// Return a default linear
pub fn linear() -> LinearKernel {
LinearKernel::default()
LinearKernel
}
/// Return a default RBF
pub fn rbf() -> RBFKernel {
@@ -292,7 +292,7 @@ mod tests {
.unwrap()
.abs();
assert!((4913f64 - result) < std::f64::EPSILON);
assert!((4913f64 - result).abs() < f64::EPSILON);
}
#[cfg_attr(
src/svm/svc.rs
+68 -80
View File
@@ -53,7 +53,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//! let y = vec![ -1, -1, -1, -1, -1, -1, -1, -1,
//! 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
//!
@@ -322,19 +322,26 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX> + 'a, Y: Array
let (n, _) = x.shape();
let mut y_hat: Vec<TX> = Array1::zeros(n);
let mut row = Vec::with_capacity(n);
for i in 0..n {
let row_pred: TX =
self.predict_for_row(Vec::from_iterator(x.get_row(i).iterator(0).copied(), n));
row.clear();
row.extend(x.get_row(i).iterator(0).copied());
let row_pred: TX = self.predict_for_row(&row);
y_hat.set(i, row_pred);
}
Ok(y_hat)
}
fn predict_for_row(&self, x: Vec<TX>) -> TX {
fn predict_for_row(&self, x: &[TX]) -> TX {
let mut f = self.b.unwrap();
let xi: Vec<_> = x.iter().map(|e| e.to_f64().unwrap()).collect();
for i in 0..self.instances.as_ref().unwrap().len() {
let xj: Vec<_> = self.instances.as_ref().unwrap()[i]
.iter()
.map(|e| e.to_f64().unwrap())
.collect();
f += self.w.as_ref().unwrap()[i]
* TX::from(
self.parameters
@@ -343,13 +350,7 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX> + 'a, Y: Array
.kernel
.as_ref()
.unwrap()
.apply(
&x.iter().map(|e| e.to_f64().unwrap()).collect(),
&self.instances.as_ref().unwrap()[i]
.iter()
.map(|e| e.to_f64().unwrap())
.collect(),
)
.apply(&xi, &xj)
.unwrap(),
)
.unwrap();
@@ -472,14 +473,12 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
let tol = self.parameters.tol;
let good_enough = TX::from_i32(1000).unwrap();
let mut x = Vec::with_capacity(n);
for _ in 0..self.parameters.epoch {
for i in self.permutate(n) {
self.process(
i,
Vec::from_iterator(self.x.get_row(i).iterator(0).copied(), n),
*self.y.get(i),
&mut cache,
);
x.clear();
x.extend(self.x.get_row(i).iterator(0).take(n).copied());
self.process(i, &x, *self.y.get(i), &mut cache);
loop {
self.reprocess(tol, &mut cache);
self.find_min_max_gradient();
@@ -511,24 +510,17 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
let mut cp = 0;
let mut cn = 0;
let mut x = Vec::with_capacity(n);
for i in self.permutate(n) {
x.clear();
x.extend(self.x.get_row(i).iterator(0).take(n).copied());
if *self.y.get(i) == TY::one() && cp < few {
if self.process(
i,
Vec::from_iterator(self.x.get_row(i).iterator(0).copied(), n),
*self.y.get(i),
cache,
) {
if self.process(i, &x, *self.y.get(i), cache) {
cp += 1;
}
} else if *self.y.get(i) == TY::from(-1).unwrap()
&& cn < few
&& self.process(
i,
Vec::from_iterator(self.x.get_row(i).iterator(0).copied(), n),
*self.y.get(i),
cache,
)
&& self.process(i, &x, *self.y.get(i), cache)
{
cn += 1;
}
@@ -539,7 +531,7 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
}
}
fn process(&mut self, i: usize, x: Vec<TX>, y: TY, cache: &mut Cache<TX, TY, X, Y>) -> bool {
fn process(&mut self, i: usize, x: &[TX], y: TY, cache: &mut Cache<TX, TY, X, Y>) -> bool {
for j in 0..self.sv.len() {
if self.sv[j].index == i {
return true;
@@ -551,15 +543,14 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
let mut cache_values: Vec<((usize, usize), TX)> = Vec::new();
for v in self.sv.iter() {
let xi: Vec<_> = v.x.iter().map(|e| e.to_f64().unwrap()).collect();
let xj: Vec<_> = x.iter().map(|e| e.to_f64().unwrap()).collect();
let k = self
.parameters
.kernel
.as_ref()
.unwrap()
.apply(
&v.x.iter().map(|e| e.to_f64().unwrap()).collect(),
&x.iter().map(|e| e.to_f64().unwrap()).collect(),
)
.apply(&xi, &xj)
.unwrap();
cache_values.push(((i, v.index), TX::from(k).unwrap()));
g -= v.alpha * k;
@@ -578,7 +569,7 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
cache.insert(v.0, v.1.to_f64().unwrap());
}
let x_f64 = x.iter().map(|e| e.to_f64().unwrap()).collect();
let x_f64: Vec<_> = x.iter().map(|e| e.to_f64().unwrap()).collect();
let k_v = self
.parameters
.kernel
@@ -701,8 +692,10 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
let km = sv1.k;
let gm = sv1.grad;
let mut best = 0f64;
let xi: Vec<_> = sv1.x.iter().map(|e| e.to_f64().unwrap()).collect();
for i in 0..self.sv.len() {
let v = &self.sv[i];
let xj: Vec<_> = v.x.iter().map(|e| e.to_f64().unwrap()).collect();
let z = v.grad - gm;
let k = cache.get(
sv1,
@@ -711,10 +704,7 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
.kernel
.as_ref()
.unwrap()
.apply(
&sv1.x.iter().map(|e| e.to_f64().unwrap()).collect(),
&v.x.iter().map(|e| e.to_f64().unwrap()).collect(),
)
.apply(&xi, &xj)
.unwrap(),
);
let mut curv = km + v.k - 2f64 * k;
@@ -732,6 +722,12 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
}
}
let xi: Vec<_> = self.sv[idx_1]
.x
.iter()
.map(|e| e.to_f64().unwrap())
.collect::<Vec<_>>();
idx_2.map(|idx_2| {
(
idx_1,
@@ -742,16 +738,12 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
.as_ref()
.unwrap()
.apply(
&self.sv[idx_1]
.x
.iter()
.map(|e| e.to_f64().unwrap())
.collect(),
&xi,
&self.sv[idx_2]
.x
.iter()
.map(|e| e.to_f64().unwrap())
.collect(),
.collect::<Vec<_>>(),
)
.unwrap()
}),
@@ -765,8 +757,11 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
let km = sv2.k;
let gm = sv2.grad;
let mut best = 0f64;
let xi: Vec<_> = sv2.x.iter().map(|e| e.to_f64().unwrap()).collect();
for i in 0..self.sv.len() {
let v = &self.sv[i];
let xj: Vec<_> = v.x.iter().map(|e| e.to_f64().unwrap()).collect();
let z = gm - v.grad;
let k = cache.get(
sv2,
@@ -775,10 +770,7 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
.kernel
.as_ref()
.unwrap()
.apply(
&sv2.x.iter().map(|e| e.to_f64().unwrap()).collect(),
&v.x.iter().map(|e| e.to_f64().unwrap()).collect(),
)
.apply(&xi, &xj)
.unwrap(),
);
let mut curv = km + v.k - 2f64 * k;
@@ -797,6 +789,12 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
}
}
let xj: Vec<_> = self.sv[idx_2]
.x
.iter()
.map(|e| e.to_f64().unwrap())
.collect();
idx_1.map(|idx_1| {
(
idx_1,
@@ -811,12 +809,8 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
.x
.iter()
.map(|e| e.to_f64().unwrap())
.collect(),
&self.sv[idx_2]
.x
.iter()
.map(|e| e.to_f64().unwrap())
.collect(),
.collect::<Vec<_>>(),
&xj,
)
.unwrap()
}),
@@ -835,12 +829,12 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
.x
.iter()
.map(|e| e.to_f64().unwrap())
.collect(),
.collect::<Vec<_>>(),
&self.sv[idx_2]
.x
.iter()
.map(|e| e.to_f64().unwrap())
.collect(),
.collect::<Vec<_>>(),
)
.unwrap(),
)),
@@ -895,7 +889,10 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
self.sv[v1].alpha -= step.to_f64().unwrap();
self.sv[v2].alpha += step.to_f64().unwrap();
let xi_v1: Vec<_> = self.sv[v1].x.iter().map(|e| e.to_f64().unwrap()).collect();
let xi_v2: Vec<_> = self.sv[v2].x.iter().map(|e| e.to_f64().unwrap()).collect();
for i in 0..self.sv.len() {
let xj: Vec<_> = self.sv[i].x.iter().map(|e| e.to_f64().unwrap()).collect();
let k2 = cache.get(
&self.sv[v2],
&self.sv[i],
@@ -903,10 +900,7 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
.kernel
.as_ref()
.unwrap()
.apply(
&self.sv[v2].x.iter().map(|e| e.to_f64().unwrap()).collect(),
&self.sv[i].x.iter().map(|e| e.to_f64().unwrap()).collect(),
)
.apply(&xi_v2, &xj)
.unwrap(),
);
let k1 = cache.get(
@@ -916,10 +910,7 @@ impl<'a, TX: Number + RealNumber, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>
.kernel
.as_ref()
.unwrap()
.apply(
&self.sv[v1].x.iter().map(|e| e.to_f64().unwrap()).collect(),
&self.sv[i].x.iter().map(|e| e.to_f64().unwrap()).collect(),
)
.apply(&xi_v1, &xj)
.unwrap(),
);
self.sv[i].grad -= step.to_f64().unwrap() * (k2 - k1);
@@ -966,7 +957,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y: Vec<i32> = vec![
-1, -1, -1, -1, -1, -1, -1, -1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
@@ -983,11 +975,7 @@ mod tests {
.unwrap();
let acc = accuracy(&y, &(y_hat.iter().map(|e| e.to_i32().unwrap()).collect()));
assert!(
acc >= 0.9,
"accuracy ({}) is not larger or equal to 0.9",
acc
);
assert!(acc >= 0.9, "accuracy ({acc}) is not larger or equal to 0.9");
}
#[cfg_attr(
@@ -996,7 +984,8 @@ mod tests {
)]
#[test]
fn svc_fit_decision_function() {
let x = DenseMatrix::from_2d_array(&[&[4.0, 0.0], &[0.0, 4.0], &[8.0, 0.0], &[0.0, 8.0]]);
let x = DenseMatrix::from_2d_array(&[&[4.0, 0.0], &[0.0, 4.0], &[8.0, 0.0], &[0.0, 8.0]])
.unwrap();
let x2 = DenseMatrix::from_2d_array(&[
&[3.0, 3.0],
@@ -1005,7 +994,8 @@ mod tests {
&[10.0, 10.0],
&[1.0, 1.0],
&[0.0, 0.0],
]);
])
.unwrap();
let y: Vec<i32> = vec![-1, -1, 1, 1];
@@ -1058,7 +1048,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y: Vec<i32> = vec![
-1, -1, -1, -1, -1, -1, -1, -1, -1, -1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
@@ -1076,11 +1067,7 @@ mod tests {
let acc = accuracy(&y, &(y_hat.iter().map(|e| e.to_i32().unwrap()).collect()));
assert!(
acc >= 0.9,
"accuracy ({}) is not larger or equal to 0.9",
acc
);
assert!(acc >= 0.9, "accuracy ({acc}) is not larger or equal to 0.9");
}
#[cfg_attr(
@@ -1111,7 +1098,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y: Vec<i32> = vec![
-1, -1, -1, -1, -1, -1, -1, -1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
src/svm/svr.rs
+13 -13
View File
@@ -44,7 +44,7 @@
//! &[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
//! &[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
//! &[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
//! ]);
//! ]).unwrap();
//!
//! let y: Vec<f64> = vec![83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0,
//! 100.0, 101.2, 104.6, 108.4, 110.8, 112.6, 114.2, 115.7, 116.9];
@@ -248,19 +248,20 @@ impl<'a, T: Number + FloatNumber + PartialOrd, X: Array2<T>, Y: Array1<T>> SVR<'
let mut y_hat: Vec<T> = Vec::<T>::zeros(n);
let mut x_i = Vec::with_capacity(n);
for i in 0..n {
y_hat.set(
i,
self.predict_for_row(Vec::from_iterator(x.get_row(i).iterator(0).copied(), n)),
);
x_i.clear();
x_i.extend(x.get_row(i).iterator(0).copied());
y_hat.set(i, self.predict_for_row(&x_i));
}
Ok(y_hat)
}
pub(crate) fn predict_for_row(&self, x: Vec<T>) -> T {
pub(crate) fn predict_for_row(&self, x: &[T]) -> T {
let mut f = self.b;
let xi: Vec<_> = x.iter().map(|e| e.to_f64().unwrap()).collect();
for i in 0..self.instances.as_ref().unwrap().len() {
f += self.w.as_ref().unwrap()[i]
* T::from(
@@ -270,10 +271,7 @@ impl<'a, T: Number + FloatNumber + PartialOrd, X: Array2<T>, Y: Array1<T>> SVR<'
.kernel
.as_ref()
.unwrap()
.apply(
&x.iter().map(|e| e.to_f64().unwrap()).collect(),
&self.instances.as_ref().unwrap()[i],
)
.apply(&xi, &self.instances.as_ref().unwrap()[i])
.unwrap(),
)
.unwrap()
@@ -642,7 +640,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y: Vec<f64> = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
@@ -662,7 +661,7 @@ mod tests {
.unwrap();
let t = mean_squared_error(&y_hat, &y);
println!("{:?}", t);
println!("{t:?}");
assert!(t < 2.5);
}
@@ -690,7 +689,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y: Vec<f64> = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
src/tree/decision_tree_classifier.rs
+122 -51
View File
@@ -48,7 +48,7 @@
//! &[4.9, 2.4, 3.3, 1.0],
//! &[6.6, 2.9, 4.6, 1.3],
//! &[5.2, 2.7, 3.9, 1.4],
//! ]);
//! ]).unwrap();
//! let y = vec![ 0, 0, 0, 0, 0, 0, 0, 0,
//! 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
//!
@@ -116,6 +116,7 @@ pub struct DecisionTreeClassifier<
num_classes: usize,
classes: Vec<TY>,
depth: u16,
num_features: usize,
_phantom_tx: PhantomData<TX>,
_phantom_x: PhantomData<X>,
_phantom_y: PhantomData<Y>,
@@ -137,16 +138,17 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
self.classes.as_ref()
}
/// Get depth of tree
fn depth(&self) -> u16 {
pub fn depth(&self) -> u16 {
self.depth
}
}
/// The function to measure the quality of a split.
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Clone)]
#[derive(Debug, Clone, Default)]
pub enum SplitCriterion {
/// [Gini index](../decision_tree_classifier/index.html)
#[default]
Gini,
/// [Entropy](../decision_tree_classifier/index.html)
Entropy,
@@ -154,21 +156,17 @@ pub enum SplitCriterion {
ClassificationError,
}
impl Default for SplitCriterion {
fn default() -> Self {
SplitCriterion::Gini
}
}
#[cfg_attr(feature = "serde", derive(Serialize, Deserialize))]
#[derive(Debug, Clone)]
struct Node {
output: usize,
n_node_samples: usize,
split_feature: usize,
split_value: Option<f64>,
split_score: Option<f64>,
true_child: Option<usize>,
false_child: Option<usize>,
impurity: Option<f64>,
}
impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>> PartialEq
@@ -199,12 +197,12 @@ impl PartialEq for Node {
self.output == other.output
&& self.split_feature == other.split_feature
&& match (self.split_value, other.split_value) {
(Some(a), Some(b)) => (a - b).abs() < std::f64::EPSILON,
(Some(a), Some(b)) => (a - b).abs() < f64::EPSILON,
(None, None) => true,
_ => false,
}
&& match (self.split_score, other.split_score) {
(Some(a), Some(b)) => (a - b).abs() < std::f64::EPSILON,
(Some(a), Some(b)) => (a - b).abs() < f64::EPSILON,
(None, None) => true,
_ => false,
}
@@ -405,14 +403,16 @@ impl Default for DecisionTreeClassifierSearchParameters {
}
impl Node {
fn new(output: usize) -> Self {
fn new(output: usize, n_node_samples: usize) -> Self {
Node {
output,
n_node_samples,
split_feature: 0,
split_value: Option::None,
split_score: Option::None,
true_child: Option::None,
false_child: Option::None,
impurity: Option::None,
}
}
}
@@ -512,6 +512,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
num_classes: 0usize,
classes: vec![],
depth: 0u16,
num_features: 0usize,
_phantom_tx: PhantomData,
_phantom_x: PhantomData,
_phantom_y: PhantomData,
@@ -543,6 +544,10 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
parameters: DecisionTreeClassifierParameters,
) -> Result<DecisionTreeClassifier<TX, TY, X, Y>, Failed> {
let (x_nrows, num_attributes) = x.shape();
if x_nrows != y.shape() {
return Err(Failed::fit("Size of x should equal size of y"));
}
let samples = vec![1; x_nrows];
DecisionTreeClassifier::fit_weak_learner(x, y, samples, num_attributes, parameters)
}
@@ -560,8 +565,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
let k = classes.len();
if k < 2 {
return Err(Failed::fit(&format!(
"Incorrect number of classes: {}. Should be >= 2.",
k
"Incorrect number of classes: {k}. Should be >= 2."
)));
}
@@ -580,7 +584,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
count[yi[i]] += samples[i];
}
let root = Node::new(which_max(&count));
let root = Node::new(which_max(&count), y_ncols);
change_nodes.push(root);
let mut order: Vec<Vec<usize>> = Vec::new();
@@ -595,6 +599,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
num_classes: k,
classes,
depth: 0u16,
num_features: num_attributes,
_phantom_tx: PhantomData,
_phantom_x: PhantomData,
_phantom_y: PhantomData,
@@ -608,7 +613,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
visitor_queue.push_back(visitor);
}
while tree.depth() < tree.parameters().max_depth.unwrap_or(std::u16::MAX) {
while tree.depth() < tree.parameters().max_depth.unwrap_or(u16::MAX) {
match visitor_queue.pop_front() {
Some(node) => tree.split(node, mtry, &mut visitor_queue, &mut rng),
None => break,
@@ -645,7 +650,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
if node.true_child.is_none() && node.false_child.is_none() {
result = node.output;
} else if x.get((row, node.split_feature)).to_f64().unwrap()
<= node.split_value.unwrap_or(std::f64::NAN)
<= node.split_value.unwrap_or(f64::NAN)
{
queue.push_back(node.true_child.unwrap());
} else {
@@ -680,16 +685,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
}
}
if is_pure {
return false;
}
let n = visitor.samples.iter().sum();
if n <= self.parameters().min_samples_split {
return false;
}
let mut count = vec![0; self.num_classes];
let mut false_count = vec![0; self.num_classes];
for i in 0..n_rows {
@@ -698,7 +694,15 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
}
}
let parent_impurity = impurity(&self.parameters().criterion, &count, n);
self.nodes[visitor.node].impurity = Some(impurity(&self.parameters().criterion, &count, n));
if is_pure {
return false;
}
if n <= self.parameters().min_samples_split {
return false;
}
let mut variables = (0..n_attr).collect::<Vec<_>>();
@@ -707,14 +711,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
}
for variable in variables.iter().take(mtry) {
self.find_best_split(
visitor,
n,
&count,
&mut false_count,
parent_impurity,
*variable,
);
self.find_best_split(visitor, n, &count, &mut false_count, *variable);
}
self.nodes()[visitor.node].split_score.is_some()
@@ -726,7 +723,6 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
n: usize,
count: &[usize],
false_count: &mut [usize],
parent_impurity: f64,
j: usize,
) {
let mut true_count = vec![0; self.num_classes];
@@ -762,6 +758,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
let true_label = which_max(&true_count);
let false_label = which_max(false_count);
let parent_impurity = self.nodes()[visitor.node].impurity.unwrap();
let gain = parent_impurity
- tc as f64 / n as f64
* impurity(&self.parameters().criterion, &true_count, tc)
@@ -806,9 +803,7 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
.get((i, self.nodes()[visitor.node].split_feature))
.to_f64()
.unwrap()
<= self.nodes()[visitor.node]
.split_value
.unwrap_or(std::f64::NAN)
<= self.nodes()[visitor.node].split_value.unwrap_or(f64::NAN)
{
*true_sample = visitor.samples[i];
tc += *true_sample;
@@ -829,9 +824,9 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
let true_child_idx = self.nodes().len();
self.nodes.push(Node::new(visitor.true_child_output));
self.nodes.push(Node::new(visitor.true_child_output, tc));
let false_child_idx = self.nodes().len();
self.nodes.push(Node::new(visitor.false_child_output));
self.nodes.push(Node::new(visitor.false_child_output, fc));
self.nodes[visitor.node].true_child = Some(true_child_idx);
self.nodes[visitor.node].false_child = Some(false_child_idx);
@@ -865,6 +860,33 @@ impl<TX: Number + PartialOrd, TY: Number + Ord, X: Array2<TX>, Y: Array1<TY>>
true
}
/// Compute feature importances for the fitted tree.
pub fn compute_feature_importances(&self, normalize: bool) -> Vec<f64> {
let mut importances = vec![0f64; self.num_features];
for node in self.nodes().iter() {
if node.true_child.is_none() && node.false_child.is_none() {
continue;
}
let left = &self.nodes()[node.true_child.unwrap()];
let right = &self.nodes()[node.false_child.unwrap()];
importances[node.split_feature] += node.n_node_samples as f64 * node.impurity.unwrap()
- left.n_node_samples as f64 * left.impurity.unwrap()
- right.n_node_samples as f64 * right.impurity.unwrap();
}
for item in importances.iter_mut() {
*item /= self.nodes()[0].n_node_samples as f64;
}
if normalize {
let sum = importances.iter().sum::<f64>();
for importance in importances.iter_mut() {
*importance /= sum;
}
}
importances
}
}
#[cfg(test)]
@@ -901,16 +923,14 @@ mod tests {
)]
#[test]
fn gini_impurity() {
assert!((impurity(&SplitCriterion::Gini, &[7, 3], 10) - 0.42).abs() < f64::EPSILON);
assert!(
(impurity(&SplitCriterion::Gini, &vec![7, 3], 10) - 0.42).abs() < std::f64::EPSILON
(impurity(&SplitCriterion::Entropy, &[7, 3], 10) - 0.8812908992306927).abs()
< f64::EPSILON
);
assert!(
(impurity(&SplitCriterion::Entropy, &vec![7, 3], 10) - 0.8812908992306927).abs()
< std::f64::EPSILON
);
assert!(
(impurity(&SplitCriterion::ClassificationError, &vec![7, 3], 10) - 0.3).abs()
< std::f64::EPSILON
(impurity(&SplitCriterion::ClassificationError, &[7, 3], 10) - 0.3).abs()
< f64::EPSILON
);
}
@@ -942,7 +962,8 @@ mod tests {
&[4.9, 2.4, 3.3, 1.0],
&[6.6, 2.9, 4.6, 1.3],
&[5.2, 2.7, 3.9, 1.4],
]);
])
.unwrap();
let y: Vec<u32> = vec![0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
assert_eq!(
@@ -971,6 +992,17 @@ mod tests {
);
}
#[test]
fn test_random_matrix_with_wrong_rownum() {
let x_rand: DenseMatrix<f64> = DenseMatrix::<f64>::rand(21, 200);
let y: Vec<u32> = vec![0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1];
let fail = DecisionTreeClassifier::fit(&x_rand, &y, Default::default());
assert!(fail.is_err());
}
#[cfg_attr(
all(target_arch = "wasm32", not(target_os = "wasi")),
wasm_bindgen_test::wasm_bindgen_test
@@ -998,7 +1030,8 @@ mod tests {
&[0., 0., 1., 1.],
&[0., 0., 0., 0.],
&[0., 0., 0., 1.],
]);
])
.unwrap();
let y: Vec<u32> = vec![1, 1, 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 0, 0, 0];
assert_eq!(
@@ -1009,6 +1042,43 @@ mod tests {
);
}
#[test]
fn test_compute_feature_importances() {
let x: DenseMatrix<f64> = DenseMatrix::from_2d_array(&[
&[1., 1., 1., 0.],
&[1., 1., 1., 0.],
&[1., 1., 1., 1.],
&[1., 1., 0., 0.],
&[1., 1., 0., 1.],
&[1., 0., 1., 0.],
&[1., 0., 1., 0.],
&[1., 0., 1., 1.],
&[1., 0., 0., 0.],
&[1., 0., 0., 1.],
&[0., 1., 1., 0.],
&[0., 1., 1., 0.],
&[0., 1., 1., 1.],
&[0., 1., 0., 0.],
&[0., 1., 0., 1.],
&[0., 0., 1., 0.],
&[0., 0., 1., 0.],
&[0., 0., 1., 1.],
&[0., 0., 0., 0.],
&[0., 0., 0., 1.],
])
.unwrap();
let y: Vec<u32> = vec![1, 1, 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 0, 0, 0];
let tree = DecisionTreeClassifier::fit(&x, &y, Default::default()).unwrap();
assert_eq!(
tree.compute_feature_importances(false),
vec![0., 0., 0.21333333333333332, 0.26666666666666666]
);
assert_eq!(
tree.compute_feature_importances(true),
vec![0., 0., 0.4444444444444444, 0.5555555555555556]
);
}
#[cfg_attr(
all(target_arch = "wasm32", not(target_os = "wasi")),
wasm_bindgen_test::wasm_bindgen_test
@@ -1037,7 +1107,8 @@ mod tests {
&[0., 0., 1., 1.],
&[0., 0., 0., 0.],
&[0., 0., 0., 1.],
]);
])
.unwrap();
let y = vec![1, 1, 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 0, 0, 0];
let tree = DecisionTreeClassifier::fit(&x, &y, Default::default()).unwrap();
src/tree/decision_tree_regressor.rs
+17 -14
View File
@@ -18,7 +18,6 @@
//! Example:
//!
//! ```
//! use rand::thread_rng;
//! use smartcore::linalg::basic::matrix::DenseMatrix;
//! use smartcore::tree::decision_tree_regressor::*;
//!
@@ -40,7 +39,7 @@
//! &[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
//! &[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
//! &[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
//! ]);
//! ]).unwrap();
//! let y: Vec<f64> = vec![
//! 83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0,
//! 101.2, 104.6, 108.4, 110.8, 112.6, 114.2, 115.7, 116.9,
@@ -312,15 +311,15 @@ impl Node {
impl PartialEq for Node {
fn eq(&self, other: &Self) -> bool {
(self.output - other.output).abs() < std::f64::EPSILON
(self.output - other.output).abs() < f64::EPSILON
&& self.split_feature == other.split_feature
&& match (self.split_value, other.split_value) {
(Some(a), Some(b)) => (a - b).abs() < std::f64::EPSILON,
(Some(a), Some(b)) => (a - b).abs() < f64::EPSILON,
(None, None) => true,
_ => false,
}
&& match (self.split_score, other.split_score) {
(Some(a), Some(b)) => (a - b).abs() < std::f64::EPSILON,
(Some(a), Some(b)) => (a - b).abs() < f64::EPSILON,
(None, None) => true,
_ => false,
}
@@ -422,6 +421,10 @@ impl<TX: Number + PartialOrd, TY: Number, X: Array2<TX>, Y: Array1<TY>>
parameters: DecisionTreeRegressorParameters,
) -> Result<DecisionTreeRegressor<TX, TY, X, Y>, Failed> {
let (x_nrows, num_attributes) = x.shape();
if x_nrows != y.shape() {
return Err(Failed::fit("Size of x should equal size of y"));
}
let samples = vec![1; x_nrows];
DecisionTreeRegressor::fit_weak_learner(x, y, samples, num_attributes, parameters)
}
@@ -475,7 +478,7 @@ impl<TX: Number + PartialOrd, TY: Number, X: Array2<TX>, Y: Array1<TY>>
visitor_queue.push_back(visitor);
}
while tree.depth() < tree.parameters().max_depth.unwrap_or(std::u16::MAX) {
while tree.depth() < tree.parameters().max_depth.unwrap_or(u16::MAX) {
match visitor_queue.pop_front() {
Some(node) => tree.split(node, mtry, &mut visitor_queue, &mut rng),
None => break,
@@ -512,7 +515,7 @@ impl<TX: Number + PartialOrd, TY: Number, X: Array2<TX>, Y: Array1<TY>>
if node.true_child.is_none() && node.false_child.is_none() {
result = node.output;
} else if x.get((row, node.split_feature)).to_f64().unwrap()
<= node.split_value.unwrap_or(std::f64::NAN)
<= node.split_value.unwrap_or(f64::NAN)
{
queue.push_back(node.true_child.unwrap());
} else {
@@ -637,9 +640,7 @@ impl<TX: Number + PartialOrd, TY: Number, X: Array2<TX>, Y: Array1<TY>>
.get((i, self.nodes()[visitor.node].split_feature))
.to_f64()
.unwrap()
<= self.nodes()[visitor.node]
.split_value
.unwrap_or(std::f64::NAN)
<= self.nodes()[visitor.node].split_value.unwrap_or(f64::NAN)
{
*true_sample = visitor.samples[i];
tc += *true_sample;
@@ -750,7 +751,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y: Vec<f64> = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
114.2, 115.7, 116.9,
@@ -764,7 +766,7 @@ mod tests {
assert!((y_hat[i] - y[i]).abs() < 0.1);
}
let expected_y = vec![
let expected_y = [
87.3, 87.3, 87.3, 87.3, 98.9, 98.9, 98.9, 98.9, 98.9, 107.9, 107.9, 107.9, 114.85,
114.85, 114.85, 114.85,
];
@@ -785,7 +787,7 @@ mod tests {
assert!((y_hat[i] - expected_y[i]).abs() < 0.1);
}
let expected_y = vec![
let expected_y = [
83.0, 88.35, 88.35, 89.5, 97.15, 97.15, 99.5, 99.5, 101.2, 104.6, 109.6, 109.6, 113.4,
113.4, 116.30, 116.30,
];
@@ -831,7 +833,8 @@ mod tests {
&[502.601, 393.1, 251.4, 125.368, 1960., 69.564],
&[518.173, 480.6, 257.2, 127.852, 1961., 69.331],
&[554.894, 400.7, 282.7, 130.081, 1962., 70.551],
]);
])
.unwrap();
let y: Vec<f64> = vec![
83.0, 88.5, 88.2, 89.5, 96.2, 98.1, 99.0, 100.0, 101.2, 104.6, 108.4, 110.8, 112.6,
114.2, 115.7, 116.9,