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A fast and easy to use dense and sparse matrix linear algebra library written in Java.
/*
* Copyright (c) 2022, Peter Abeles. All Rights Reserved.
*
* This file is part of Efficient Java Matrix Library (EJML).
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package org.ejml.simple;
import org.ejml.UtilEjml;
import org.ejml.data.DMatrixRMaj;
import org.ejml.data.FMatrixRMaj;
import org.ejml.data.Matrix;
import org.ejml.dense.row.SingularOps_DDRM;
import org.ejml.dense.row.SingularOps_FDRM;
import org.ejml.dense.row.factory.DecompositionFactory_DDRM;
import org.ejml.dense.row.factory.DecompositionFactory_FDRM;
import org.ejml.interfaces.decomposition.SingularValueDecomposition;
import org.ejml.interfaces.decomposition.SingularValueDecomposition_F32;
import org.ejml.interfaces.decomposition.SingularValueDecomposition_F64;
/**
*
* Wrapper around SVD for simple matrix. See {@link SingularValueDecomposition} for more details.
*
* SVD is defined as the following decomposition:
* A = U * W * V T
* where A is m by n, and U and V are orthogonal matrices, and W is a diagonal matrix
*
*
* Tolerance for singular values is
* Math.max(mat.numRows,mat.numCols) * W.get(0,0) * UtilEjml.EPS;
* where W.get(0,0) is the largest singular value.
*
*
* @author Peter Abeles
*/
@SuppressWarnings({"unchecked"})
public class SimpleSVD {
private SingularValueDecomposition svd;
private T U;
private T W;
private T V;
private Matrix mat;
final boolean is64;
// tolerance for singular values
double tol;
public SimpleSVD( Matrix mat, boolean compact ) {
this.mat = mat;
this.is64 = mat instanceof DMatrixRMaj;
if (is64) {
DMatrixRMaj m = (DMatrixRMaj)mat;
svd = DecompositionFactory_DDRM.svd(m.numRows, m.numCols, true, true, compact);
} else {
FMatrixRMaj m = (FMatrixRMaj)mat;
svd = DecompositionFactory_FDRM.svd(m.numRows, m.numCols, true, true, compact);
}
if (!svd.decompose(mat))
throw new RuntimeException("Decomposition failed");
U = (T)SimpleMatrix.wrap(svd.getU(null, false));
W = (T)SimpleMatrix.wrap(svd.getW(null));
V = (T)SimpleMatrix.wrap(svd.getV(null, false));
// order singular values from largest to smallest
if (is64) {
SingularOps_DDRM.descendingOrder(
(DMatrixRMaj)U.getMatrix(), false, (DMatrixRMaj)W.getMatrix(),
(DMatrixRMaj)V.getMatrix(), false);
tol = SingularOps_DDRM.singularThreshold((SingularValueDecomposition_F64)svd);
} else {
SingularOps_FDRM.descendingOrder(
(FMatrixRMaj)U.getMatrix(), false, (FMatrixRMaj)W.getMatrix(),
(FMatrixRMaj)V.getMatrix(), false);
tol = SingularOps_FDRM.singularThreshold((SingularValueDecomposition_F32)svd);
}
}
/**
*
* Returns the orthogonal 'U' matrix.
*
*
* @return An orthogonal m by m matrix.
*/
public T getU() {
return U;
}
/**
* Returns a diagonal matrix with the singular values. The singular values are ordered
* from largest to smallest.
*
* @return Diagonal matrix with singular values along the diagonal.
*/
public T getW() {
return W;
}
/**
*
* Returns the orthogonal 'V' matrix.
*
*
* @return An orthogonal n by n matrix.
*/
public T getV() {
return V;
}
/**
*
* Computes the quality of the computed decomposition. A value close to or less than 1e-15
* is considered to be within machine precision.
*
*
*
* This function must be called before the original matrix has been modified or else it will
* produce meaningless results.
*
*
* @return Quality of the decomposition.
*/
public /**/double quality() {
if (is64) {
return DecompositionFactory_DDRM.quality((DMatrixRMaj)mat, (DMatrixRMaj)U.getMatrix(),
(DMatrixRMaj)W.getMatrix(), (DMatrixRMaj)V.transpose().getMatrix());
} else {
return DecompositionFactory_FDRM.quality((FMatrixRMaj)mat, (FMatrixRMaj)U.getMatrix(),
(FMatrixRMaj)W.getMatrix(), (FMatrixRMaj)V.transpose().getMatrix());
}
}
/**
* Computes the null space from an SVD. For more information see {@link SingularOps_DDRM#nullSpace}.
*
* @return Null space vector.
*/
public SimpleMatrix nullSpace() {
// TODO take advantage of the singular values being ordered already
if (is64) {
return SimpleMatrix.wrap(SingularOps_DDRM.nullSpace((SingularValueDecomposition_F64)svd, null, tol));
} else {
return SimpleMatrix.wrap(SingularOps_FDRM.nullSpace((SingularValueDecomposition_F32)svd, null, (float)tol));
}
}
/**
* Returns the specified singular value.
*
* @param index Which singular value is to be returned.
* @return A singular value.
*/
public double getSingleValue( int index ) {
return W.get(index, index);
}
/**
* Returns an array of all the singular values
*/
public double[] getSingularValues() {
double[] ret = new double[W.numCols()];
for (int i = 0; i < ret.length; i++) {
ret[i] = getSingleValue(i);
}
return ret;
}
/**
* Returns the rank of the decomposed matrix.
*
* @return The matrix's rank
* @see SingularOps_DDRM#rank(SingularValueDecomposition_F64, double)
*/
public int rank() {
if (is64) {
return SingularOps_DDRM.rank((SingularValueDecomposition_F64)svd, tol);
} else {
return SingularOps_FDRM.rank((SingularValueDecomposition_F32)svd, (float)tol);
}
}
/**
* The nullity of the decomposed matrix.
*
* @return The matrix's nullity
* @see SingularOps_DDRM#nullity(SingularValueDecomposition_F64, double)
*/
public int nullity() {
if (is64) {
return SingularOps_DDRM.nullity((SingularValueDecomposition_F64)svd, 10.0*UtilEjml.EPS);
} else {
return SingularOps_FDRM.nullity((SingularValueDecomposition_F32)svd, 5.0f*UtilEjml.F_EPS);
}
}
/**
* Returns the underlying decomposition that this is a wrapper around.
*
* @return SingularValueDecomposition
*/
public SingularValueDecomposition getSVD() {
return svd;
}
}