NumFlat is a numerical computation library written entirely in C#.
The goal of this project is to provide a lightweight package for handling various mathematical and computational tasks, including linear algebra, multivariable analysis, clustering, and signal processing, using only C#.
NumFlat provides types named Vec<T>
and Mat<T>
for representing vectors and matrices.
These type names are intentionally chosen to avoid confusion with vector and matrix types (like Vector<T>
) from the System.Numerics
namespace.
Various linear algebra-related operations can be performed on these types through operator overloading and extension methods.
Vec<T>
and Mat<T>
can hold numerical types that implement the INumberBase<T>
interface, which was newly added in .NET 7.
The primary supported types are float
, double
, and Complex
.
Other types can be used as well, but support beyond simple arithmetic operations is not provided.
Vec<double> vec = [1, 2, 3];
Mat<double> mat =
[
[1, 2, 3],
[4, 5, 6],
[7, 8, 9],
];
Console.WriteLine(mat * vec);
.NET 8 is required.
The NuGet package is available.
Install-Package NumFlat
Most classes are in the NumFlat
namespace.
using NumFlat;
A new vector can be created by listing elements inside []
.
// Create a new vector.
Vec<double> vector = [1, 2, 3];
// Show the vector.
Console.WriteLine(vector);
Vector 3-Double
1
2
3
Vectors can also be created from objects that implement IEnumerable<T>
.
Since the vector itself is an IEnumerable<T>
, it is also possible to call LINQ methods on the vector if needed.
// Some enumerable.
var enumerable = Enumerable.Range(0, 10).Select(i => i / 10.0);
// Create a vector from an enumerable.
var vector = enumerable.ToVector();
// Show the vector.
Console.WriteLine(vector);
Vector 10-Double
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
Elements in a vector can be accessed or modified through the indexer.
// Create a new vector.
var vector = new Vec<double>(3);
// Element-wise access.
vector[0] = 4;
vector[1] = 5;
vector[2] = 6;
// Show the vector.
Console.WriteLine(vector);
Vector 3-Double
4
5
6
Basic operations on vectors are provided through operator overloading and extension methods.
// Some vectors.
Vec<double> x = [1, 2, 3];
Vec<double> y = [4, 5, 6];
// Addition.
var add = x y;
// Subtraction.
var sub = x - y;
// Multiplication by a scalar.
var ms = x * 3;
// Division by a scalar.
var ds = x / 3;
// Pointwise multiplication.
var pm = x.PointwiseMul(y);
// Pointwise division.
var pd = x.PointwiseDiv(y);
// Dot product.
var dot = x * y;
// Outer product.
var outer = x.Outer(y);
// L2 norm.
var l2Norm = x.Norm();
// L1 norm.
var l1Norm = x.L1Norm();
// Infinity norm.
var infinityNorm = x.InfinityNorm();
// Normalization.
var normalized = x.Normalize();
A subvector can be created from a vector. The subvector acts as a view of the original vector, and changes to the subvector will affect the original vector.
// Some vector.
Vec<double> x = [3, 3, 3, 3, 3];
// Create a subvector of the vector.
var sub = x[1..4];
// Modify the subvector.
sub.Fill(100);
// Show the original vector.
Console.WriteLine(x);
Vector 5-Double
3
100
100
100
3
Matrices can be generated from 2D arrays.
// Create a new matrix.
Mat<double> matrix =
[
[1, 2, 3],
[4, 5, 6],
[7, 8, 9],
];
// Show the matrix.
Console.WriteLine(matrix);
Matrix 3x3-Double
1 2 3
4 5 6
7 8 9
Elements in a matrix can be accessed or modified through the indexer.
// Creat a new matrix.
var matrix = new Mat<double>(3, 3);
// Element-wise access.
for (var row = 0; row < matrix.RowCount; row )
{
for (var col = 0; col < matrix.ColCount; col )
{
matrix[row, col] = 10 * row col;
}
}
// Show the matrix.
Console.WriteLine(matrix);
Matrix 3x3-Double
0 1 2
10 11 12
20 21 22
Basic operations on matrices are provided through operator overloading and extension methods.
// Some matrices.
Mat<double> x =
[
[1, 2, 3],
[0, 1, 2],
[0, 0, 1],
];
Mat<double> y =
[
[1, 0, 0],
[2, 1, 0],
[3, 2, 1],
];
// Addition.
var add = x y;
// Subtraction.
var sub = x - y;
// Multiplication.
var mul = x * y;
// Multiplication by a scalar.
var ms = x * 3;
// Division by a scalar.
var ds = x / 3;
// Pointwise multiplication.
var pm = x.PointwiseMul(y);
// Pointwise division.
var pd = x.PointwiseDiv(y);
// Transposition.
var transposed = x.Transpose();
// Trace.
var trace = x.Trace();
// Determinant.
var determinant = x.Determinant();
// Rank.
var rank = x.Rank();
// Inverse.
var inverse = x.Inverse();
// Pseudo-inverse.
var pseudoInverse = x.PseudoInverse();
// Frobenius norm.
var frobeniusNorm = x.FrobeniusNorm();
// L1 norm.
var l1Norm = x.L1Norm();
// L2 norm.
var l2Norm = x.L2Norm();
// Infinity norm.
var infinityNorm = x.InfinityNorm();
A submatrix can be created from a matrix. The submatrix acts as a view of the original matrix, and changes to the submatrix will affect the original matrix.
// Creat a new matrix.
var x = new Mat<double>(5, 5);
x.Fill(3);
// Create a submatrix of the matrix.
var sub = x[1..3, 2..4];
// Modify the subvector.
sub.Fill(100);
// Show the original matrix.
Console.WriteLine(x);
Matrix 5x5-Double
3 3 3 3 3
3 3 100 100 3
3 3 100 100 3
3 3 3 3 3
3 3 3 3 3
Views of rows or columns as vectors can be obtained through the Rows
or Cols
properties.
Similar to a submatrix, changes to the view will affect the original matrix.
These properties implement IEnumerable<Vec<T>>
, allowing for LINQ methods to be called on collections of vectors.
// Some matrix.
Mat<double> x =
[
[1, 2, 3],
[4, 5, 6],
[7, 8, 9],
];
// Create a view of a row of the matrix.
Vec<double> row = x.Rows[0];
// Create a view of a column of the matrix.
Vec<double> col = x.Cols[1];
// Convert a matrix to a row-major jagged array.
var array = x.Rows.Select(row => row.ToArray()).ToArray();
// Enumerate all the elements in column-major order.
var elements = x.Cols.SelectMany(col => col);
// The mean vector of the row vectors.
var rowMean = x.Rows.Mean();
// The covariance matrix of the column vectors.
var colCov = x.Cols.Covariance();
The LU, QR, Cholesky, SVD, EVD, and GEVD for all three major number types float
, double
, and Complex
are available. Below is an example to decompose a matrix using SVD.
// Some matrix.
Mat<double> x =
[
[1, 2, 3],
[4, 5, 6],
[7, 8, 9],
];
// Do SVD.
var decomposition = x.Svd();
// Decomposed matrices.
var s = decomposition.S.ToDiagonalMatrix();
var u = decomposition.U;
var vt = decomposition.VT;
// Reconstruct the matrix.
var reconstructed = u * s * vt;
// Show the reconstructed matrix.
Console.WriteLine(reconstructed);
Matrix 3x3-Double
1 2 3
4 5 6
7 8 9
Linear equations like Ax = b
can be solved with the matrix decomposition methods above. Use Solve()
method to get the solution vector of a given right-hand side vector b
.
// Some coefficient matrix.
Mat<double> a =
[
[1, 2, 3],
[1, 4, 9],
[2, 3, 5],
];
// Do LU decomposition.
var lu = a.Lu();
// The right-hand vector.
Vec<double> b = [1, 2, 3];
// Compute the solution vector.
var x = lu.Solve(b);
// Show the solution.
Console.WriteLine(x);
Vector 3-Double
2.25
-1.75
0.75
Most of the operations have an in-place version, which directly modifies the target vector or matrix without creating a new one.
// Some vector.
Vec<double> vector = [1, 2, 3];
// This allocates a new vector.
var normalized = vector.Normalize();
// This modifies the original vector.
vector.NormalizeInplace();
// Some matrix.
Mat<double> matrix =
[
[1, 2, 3],
[4, 5, 6],
[7, 8, 9],
];
// In-place methods can also directly modify a part of vector or matrix.
matrix.Rows[0].NormalizeInplace();
Most of the operations have a non-allocation version, which requires a destination buffer provided by user. Below is an example of matrix addition without heap allocation.
// Some matrices.
Mat<double> x =
[
[1, 2],
[3, 4],
];
Mat<double> y =
[
[5, 6],
[7, 8],
];
// This allocates a new matrix.
var answer = x y;
// The buffer to store the answer.
var destination = new Mat<double>(2, 2);
// This is the same as 'x y', but does not allocate heap.
Mat.Add(x, y, destination);
The NumFlat.MultivariateAnalyses
namespace provides functionality related to multivariate analysis.
It currently supports the following methods, with plans to add more methods in the future.
- Linear regression
- Logistic regression
- PCA (principal component analysis)
- LDA (linear discriminant analysis)
- ICA (independent component analysis)
- NMF (non-negative matrix factorization)
using NumFlat.MultivariateAnalyses;
// Read some data.
IReadOnlyList<Vec<double>> xs = ReadSomeData();
// Do PCA.
var pca = xs.Pca();
foreach (var x in xs)
{
// Transform the vector based on the PCA.
var transformed = pca.Transform(x);
}
// Read some label.
IReadOnlyList<int> ys = ReadSomeLabel();
// Do LDA.
var lda = xs.Lda(ys);
foreach (var x in xs)
{
// Transform the vector based on the LDA.
var transformed = lda.Transform(x);
}
The NumFlat.Distributions
namespace provides functionality related to probability distributions.
It currently supports the multivariate Gaussian distribution and its diagonal covariance matrix variation.
Maximum likelihood estimation from data, probability density function calculation, and random number generation are possible.
using NumFlat.Distributions;
// Read some data.
IEnumerable<Vec<double>> xs = ReadSomeData();
// Compute the maximum likelihood Gaussian distribution.
var gaussian = xs.ToGaussian();
foreach (var x in xs)
{
// Compute the log PDF.
var pdf = gaussian.LogPdf(x);
}
The NumFlat.Clustering
namespace provides functionality related to clustering.
It currently supports the following methods, with plans to add more methods in the future.
- k-means
- GMM (Gaussian mixture model)
- DBSCAN (density-based spatial clustering of applications with noise)
using NumFlat.Clustering;
// Read some data.
IReadOnlyList<Vec<double>> xs = ReadSomeData();
// Compute a k-means model with 3 clusters.
var kMeans = xs.ToKMeans(3);
// Compute a GMM with 3 clusters.
var gmm = xs.ToGmm(3);
The NumFlat.SignalProcessing
namespace provides functionality related to signal processing.
It currently supports the following methods, with plans to add more methods in the future.
- Extract frames using the window function
- Overlap addition
- FFT and IFFT
- STFT and ISTFT
- Convolution
- Resampling
using NumFlat.SignalProcessing;
// Some complex vector.
var samples = new Vec<Complex>(256);
samples[0] = 1;
// Do FFT.
var spectrum = samples.Fft();
// Do IFFT.
samples = spectrum.Ifft();
NumFlat's vector and matrix memory formats are compatible with BLAS and LAPACK, allowing you to leverage faster linear algebra libraries like OpenBLAS. The following code example demonstrates how to perform SVD using a C# binding of OpenBLAS, OpenBlasSharp. While NumFlat provides its own SVD implementation, the SVD implementation in OpenBLAS can be expected to offer performance improvements, especially for large matrices.
Mat<double> a =
[
[1, 2, 3],
[4, 5, 6],
[7, 8, 9],
];
var s = new Vec<double>(Math.Min(a.RowCount, a.ColCount));
var u = new Mat<double>(a.RowCount, a.RowCount);
var vt = new Mat<double>(a.ColCount, a.ColCount);
var work = new Vec<double>(s.Count - 1);
fixed (double* pa = a.Memory.Span)
fixed (double* ps = s.Memory.Span)
fixed (double* pu = u.Memory.Span)
fixed (double* pvt = vt.Memory.Span)
fixed (double* pwork = work.Memory.Span)
{
Lapack.Dgesvd(
MatrixLayout.ColMajor,
'A', 'A',
a.RowCount, a.ColCount,
pa, a.Stride, // The content of 'a' will be destroyed.
ps,
pu, u.Stride,
pvt, vt.Stride,
pwork);
}
Console.WriteLine(u * s.ToDiagonalMatrix() * vt);
Matrix 3x3-Double
1 2 3
4 5 6
7 8 9
- ✅ Vector operations
- ✅ Builder
- ✅ Indexer
- ✅ Subvector
- ✅ Copy, fill, clear
- ✅ Arithmetic operations
- ✅ Dot and outer products
- ✅ Norm and normalization
- ✅ In-place operations
- ✅ Matrix operations
- ✅ Builder
- ✅ Indexer
- ✅ Submatrix
- ✅ Copy, fill, clear
- ✅ Arithmetic operations
- ✅ Transposition
- ✅ Trace
- ✅ Determinant
- ✅ Rank
- ✅ Inversion
- ✅ Pseudo-inverse
- ✅ Norm
- ✅ In-place operations
- ✅ Matrix Decomposition
- ✅ LU decomposition
- ✅ QR decomposition
- ✅ Cholesky decomposition
- ✅ SVD (singular value decomposition)
- ✅ EVD (eigenvalue decomposition)
- ✅ GEVD (generalized eigenvalue decomposition)
- ✅ LINQ-like operations
- ✅ Sum, mean, variance, covariance for scalars
- ✅ Sum, mean, variance, covariancee for vectors
- ✅ Sum, mean, variance for matrices
- ✅ Weighted sum, mean, variance, covariance for scalars
- ✅ Weighted sum, mean, variance, covariance for vectors
- ✅ Weighted sum, mean, variance for matrices
- ✅ Higher-order statistics
- ⬜ Multivariate analysis
- ✅ Linear regression
- ✅ Logistic regression
- ✅ PCA (principal component analysis)
- ✅ LDA (linear discriminant analysis)
- ✅ ICA (independent component analysis)
- ✅ NMF (non-negative matrix factorization)
- ⬜ Multinomial logistic regression
- ⬜ Kernel PCA
- ⬜ Kernel discriminant analysis
- ⬜ t-SNE
- ⬜ UMAP
- ⬜ Distributions
- ✅ Gaussian
- ✅ Diagonal Gaussian
- ⬜ Other distributions
- 🚧 Clustering
- ✅ k-means
- ✅ GMM (gaussian mixture model)
- ✅ DBSCAN (density-based spatial clustering of applications with noise)
- ⬜ OPTICS
- ⬜ Classification
- ⬜ Bayes classifier
- ⬜ SVM (support vector machine)
- ⬜ Time series
- ⬜ DTW (dynamic time warping)
- ⬜ HMM (hidden Markov model)
- 🚧 Signal processing
- ✅ FFT (fast Fourier transform)
- ✅ Real FFT
- ✅ STFT (short-time Fourier transform)
- ✅ Convolution
- ✅ Resampling
- 🚧 Feature extraction
- ⬜ Filtering
- ✅ File IO
- ✅ CSV
- ✅ WAV
NumFlat depends on the following libraries.
NumFlat is available under the MIT license.