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Implementation of Standard scaler (#143)

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* docs: Fix typo in doc for categorical transformer.
* feat: Add option to take a column from Matrix.
I created the method `Matrix::take_column` that uses the `Matrix::take`-interface to extract a single column from a matrix. I need that feature in the implementation of  `StandardScaler`.
* feat: Add `StandardScaler`.
Authored-by: titoeb <timtoebrock@googlemail.com>
This commit is contained in:
Tim Toebrock
2022-08-26 16:20:20 +02:00
committed by morenol
parent 09d9205696
commit df766eaf79
3 changed files with 428 additions and 1 deletions
Download Patch File Download Diff File Expand all files Collapse all files
src/linalg/mod.rs
+21
View File
@@ -651,6 +651,10 @@ pub trait BaseMatrix<T: RealNumber>: Clone + Debug {
result result
} }
/// Take an individual column from the matrix.
fn take_column(&self, column_index: usize) -> Self {
self.take(&[column_index], 1)
}
} }
/// Generic matrix with additional mixins like various factorization methods. /// Generic matrix with additional mixins like various factorization methods.
@@ -761,4 +765,21 @@ mod tests {
assert_eq!(m.take(&vec!(1, 1, 3), 0), expected_0); assert_eq!(m.take(&vec!(1, 1, 3), 0), expected_0);
assert_eq!(m.take(&vec!(1, 0), 1), expected_1); assert_eq!(m.take(&vec!(1, 0), 1), expected_1);
} }
#[test]
fn take_second_column_from_matrix() {
let four_columns: DenseMatrix<f64> = DenseMatrix::from_2d_array(&[
&[0.0, 1.0, 2.0, 3.0],
&[0.0, 1.0, 2.0, 3.0],
&[0.0, 1.0, 2.0, 3.0],
&[0.0, 1.0, 2.0, 3.0],
]);
let second_column = four_columns.take_column(1);
assert_eq!(
second_column,
DenseMatrix::from_2d_array(&[&[1.0], &[1.0], &[1.0], &[1.0]]),
"The second column was not extracted correctly"
);
}
} }
src/preprocessing/mod.rs
+3 -1
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@@ -1,5 +1,7 @@
/// Transform a data matrix by replaceing all categorical variables with their one-hot vector equivalents /// Transform a data matrix by replacing all categorical variables with their one-hot vector equivalents
pub mod categorical; pub mod categorical;
mod data_traits; mod data_traits;
/// Preprocess numerical matrices.
pub mod numerical;
/// Encode a series (column, array) of categorical variables as one-hot vectors /// Encode a series (column, array) of categorical variables as one-hot vectors
pub mod series_encoder; pub mod series_encoder;
src/preprocessing/numerical.rs
+404
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@@ -0,0 +1,404 @@
//! # Standard-Scaling For [RealNumber](../../math/num/trait.RealNumber.html) Matricies
//! Transform a data [Matrix](../../linalg/trait.BaseMatrix.html) by removing the mean and scaling to unit variance.
//!
//! ### Usage Example
//! ```
//! use smartcore::api::{Transformer, UnsupervisedEstimator};
//! use smartcore::linalg::naive::dense_matrix::DenseMatrix;
//! use smartcore::preprocessing::numerical;
//! let data = DenseMatrix::from_2d_vec(&vec![
//! vec![0.0, 0.0],
//! vec![0.0, 0.0],
//! vec![1.0, 1.0],
//! vec![1.0, 1.0],
//! ]);
//!
//! let standard_scaler =
//! numerical::StandardScaler::fit(&data, numerical::StandardScalerParameters::default())
//! .unwrap();
//! let transformed_data = standard_scaler.transform(&data).unwrap();
//! assert_eq!(
//! transformed_data,
//! DenseMatrix::from_2d_vec(&vec![
//! vec![-1.0, -1.0],
//! vec![-1.0, -1.0],
//! vec![1.0, 1.0],
//! vec![1.0, 1.0],
//! ])
//! );
//! ```
use crate::api::{Transformer, UnsupervisedEstimator};
use crate::error::{Failed, FailedError};
use crate::linalg::Matrix;
use crate::math::num::RealNumber;
/// Configure Behaviour of `StandardScaler`.
#[derive(Clone, Debug, Copy, Eq, PartialEq)]
pub struct StandardScalerParameters {
/// Optionaly adjust mean to be zero.
with_mean: bool,
/// Optionally adjust standard-deviation to be one.
with_std: bool,
}
impl Default for StandardScalerParameters {
fn default() -> Self {
StandardScalerParameters {
with_mean: true,
with_std: true,
}
}
}
/// With the `StandardScaler` data can be adjusted so
/// that every column has a mean of zero and a standard
/// deviation of one. This can improve model training for
/// scaling sensitive models like neural network or nearest
/// neighbors based models.
#[derive(Clone, Debug, Default, Eq, PartialEq)]
pub struct StandardScaler<T: RealNumber> {
means: Vec<T>,
stds: Vec<T>,
parameters: StandardScalerParameters,
}
impl<T: RealNumber> StandardScaler<T> {
/// When the mean should be adjusted, the column mean
/// should be kept. Otherwise, replace it by zero.
fn adjust_column_mean(&self, mean: T) -> T {
if self.parameters.with_mean {
mean
} else {
T::zero()
}
}
/// When the standard-deviation should be adjusted, the column
/// standard-deviation should be kept. Otherwise, replace it by one.
fn adjust_column_std(&self, std: T) -> T {
if self.parameters.with_std {
ensure_std_valid(std)
} else {
T::one()
}
}
}
/// Make sure the standard deviation is valid. If it is
/// negative or zero, it should replaced by the smallest
/// positive value the type can have. That way we can savely
/// divide the columns with the resulting scalar.
fn ensure_std_valid<T: RealNumber>(value: T) -> T {
value.max(T::min_positive_value())
}
/// During `fit` the `StandardScaler` computes the column means and standard deviation.
impl<T: RealNumber, M: Matrix<T>> UnsupervisedEstimator<M, StandardScalerParameters>
for StandardScaler<T>
{
fn fit(x: &M, parameters: StandardScalerParameters) -> Result<Self, Failed> {
Ok(Self {
means: x.column_mean(),
stds: x.std(0),
parameters,
})
}
}
/// During `transform` the `StandardScaler` applies the summary statistics
/// computed during `fit` to set the mean of each column to zero and the
/// standard deviation to one.
impl<T: RealNumber, M: Matrix<T>> Transformer<M> for StandardScaler<T> {
fn transform(&self, x: &M) -> Result<M, Failed> {
let (_, n_cols) = x.shape();
if n_cols != self.means.len() {
return Err(Failed::because(
FailedError::TransformFailed,
&format!(
"Expected {} columns, but got {} columns instead.",
self.means.len(),
n_cols,
),
));
}
Ok(build_matrix_from_columns(
self.means
.iter()
.zip(self.stds.iter())
.enumerate()
.map(|(column_index, (column_mean, column_std))| {
x.take_column(column_index)
.sub_scalar(self.adjust_column_mean(*column_mean))
.div_scalar(self.adjust_column_std(*column_std))
})
.collect(),
)
.unwrap())
}
}
/// From a collection of matrices, that contain columns, construct
/// a matrix by stacking the columns horizontally.
fn build_matrix_from_columns<T, M>(columns: Vec<M>) -> Option<M>
where
T: RealNumber,
M: Matrix<T>,
{
if let Some(output_matrix) = columns.first().cloned() {
return Some(
columns
.iter()
.skip(1)
.fold(output_matrix, |current_matrix, new_colum| {
current_matrix.h_stack(new_colum)
}),
);
} else {
None
}
}
#[cfg(test)]
mod tests {
mod helper_functionality {
use super::super::{build_matrix_from_columns, ensure_std_valid};
use crate::linalg::naive::dense_matrix::DenseMatrix;
#[test]
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],])
]),
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]
]))
)
}
#[test]
fn negative_value_should_be_replace_with_minimal_positive_value() {
assert_eq!(ensure_std_valid(-1.0), f64::MIN_POSITIVE)
}
#[test]
fn zero_should_be_replace_with_minimal_positive_value() {
assert_eq!(ensure_std_valid(0.0), f64::MIN_POSITIVE)
}
}
mod standard_scaler {
use super::super::{StandardScaler, StandardScalerParameters};
use crate::api::{Transformer, UnsupervisedEstimator};
use crate::linalg::naive::dense_matrix::DenseMatrix;
use crate::linalg::BaseMatrix;
#[test]
fn dont_adjust_mean_if_used() {
assert_eq!(
(StandardScaler {
means: vec![],
stds: vec![],
parameters: StandardScalerParameters {
with_mean: true,
with_std: true
}
})
.adjust_column_mean(1.0),
1.0
)
}
#[test]
fn replace_mean_with_zero_if_not_used() {
assert_eq!(
(StandardScaler {
means: vec![],
stds: vec![],
parameters: StandardScalerParameters {
with_mean: false,
with_std: true
}
})
.adjust_column_mean(1.0),
0.0
)
}
#[test]
fn dont_adjust_std_if_used() {
assert_eq!(
(StandardScaler {
means: vec![],
stds: vec![],
parameters: StandardScalerParameters {
with_mean: true,
with_std: true
}
})
.adjust_column_std(10.0),
10.0
)
}
#[test]
fn replace_std_with_one_if_not_used() {
assert_eq!(
(StandardScaler {
means: vec![],
stds: vec![],
parameters: StandardScalerParameters {
with_mean: true,
with_std: false
}
})
.adjust_column_std(10.0),
1.0
)
}
/// Helper function to apply fit as well as transform at the same time.
fn fit_transform_with_default_standard_scaler(
values_to_be_transformed: &DenseMatrix<f64>,
) -> DenseMatrix<f64> {
StandardScaler::fit(
values_to_be_transformed,
StandardScalerParameters::default(),
)
.unwrap()
.transform(values_to_be_transformed)
.unwrap()
}
/// Fit transform with random generated values, expected values taken from
/// sklearn.
#[test]
fn fit_transform_random_values() {
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);
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],
]),
1.0
))
}
/// Test `fit` and `transform` for a column with zero variance.
#[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]]),
"When scaling values with zero variance, zero is expected as return value"
)
}
/// Test `fit` for columns with nice summary statistics.
#[test]
fn fit_for_simple_values() {
assert_eq!(
StandardScaler::fit(
&DenseMatrix::from_2d_array(&[
&[1.0, 1.0, 1.0],
&[1.0, 2.0, 5.0],
&[1.0, 1.0, 1.0],
&[1.0, 2.0, 5.0]
]),
StandardScalerParameters::default(),
),
Ok(StandardScaler {
means: vec![1.0, 1.5, 3.0],
stds: vec![0.0, 0.5, 2.0],
parameters: StandardScalerParameters {
with_mean: true,
with_std: true
}
})
)
}
/// Test `fit` for random generated values.
#[test]
fn fit_for_random_values() {
let fitted_scaler = StandardScaler::fit(
&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],
]),
StandardScalerParameters::default(),
)
.unwrap();
assert_eq!(
fitted_scaler.means,
vec![0.42864544605, 0.2869813741, 0.737752073825, 0.431011663625],
);
assert!(
&DenseMatrix::from_2d_vec(&vec![fitted_scaler.stds]).approximate_eq(
&DenseMatrix::from_2d_array(&[&[
0.29426447500954,
0.16758497615485,
0.20820945786863,
0.23329718831165
],]),
0.00000000000001
)
)
}
/// If `with_std` is set to `false` the values should not be
/// adjusted to have a std of one.
#[test]
fn transform_without_std() {
let standard_scaler = StandardScaler {
means: vec![1.0, 3.0],
stds: vec![1.0, 2.0],
parameters: StandardScalerParameters {
with_mean: true,
with_std: false,
},
};
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]]))
)
}
/// If `with_mean` is set to `false` the values should not be adjusted
/// to have a mean of zero.
#[test]
fn transform_without_mean() {
let standard_scaler = StandardScaler {
means: vec![1.0, 2.0],
stds: vec![2.0, 3.0],
parameters: StandardScalerParameters {
with_mean: false,
with_std: true,
},
};
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]]))
)
}
}
}