Add MatrixRank
(#4571)
* feat: adding matrix rank algorithm * fix: formatting * fix: adding comments, refactor and handling edge cases * refactor: minor refactor * enhancement: check matrix validity * refactor: minor refactor and fixes * Update src/main/java/com/thealgorithms/maths/MatrixRank.java * feat: add unit test to check if input matrix is not modified while calculating the rank --------- Co-authored-by: Anup Omkar <anup_omkar@intuit.com> Co-authored-by: Piotr Idzik <65706193+vil02@users.noreply.github.com> Co-authored-by: Andrii Siriak <siryaka@gmail.com>
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src/main/java/com/thealgorithms/maths/MatrixRank.java
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src/main/java/com/thealgorithms/maths/MatrixRank.java
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package com.thealgorithms.maths;
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/**
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* This class provides a method to compute the rank of a matrix.
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* In linear algebra, the rank of a matrix is the maximum number of linearly independent rows or columns in the matrix.
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* For example, consider the following 3x3 matrix:
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* 1 2 3
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* 2 4 6
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* 3 6 9
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* Despite having 3 rows and 3 columns, this matrix only has a rank of 1 because all rows (and columns) are multiples of each other.
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* It's a fundamental concept that gives key insights into the structure of the matrix.
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* It's important to note that the rank is not only defined for square matrices but for any m x n matrix.
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*
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* @author Anup Omkar
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*/
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public final class MatrixRank {
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private MatrixRank() {
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}
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private static final double EPSILON = 1e-10;
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/**
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* @brief Computes the rank of the input matrix
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*
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* @param matrix The input matrix
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* @return The rank of the input matrix
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*/
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public static int computeRank(double[][] matrix) {
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validateInputMatrix(matrix);
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int numRows = matrix.length;
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int numColumns = matrix[0].length;
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int rank = 0;
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boolean[] rowMarked = new boolean[numRows];
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double[][] matrixCopy = deepCopy(matrix);
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for (int colIndex = 0; colIndex < numColumns; ++colIndex) {
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int pivotRow = findPivotRow(matrixCopy, rowMarked, colIndex);
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if (pivotRow != numRows) {
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++rank;
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rowMarked[pivotRow] = true;
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normalizePivotRow(matrixCopy, pivotRow, colIndex);
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eliminateRows(matrixCopy, pivotRow, colIndex);
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}
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}
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return rank;
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}
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private static boolean isZero(double value) {
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return Math.abs(value) < EPSILON;
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}
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private static double[][] deepCopy(double[][] matrix) {
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int numRows = matrix.length;
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int numColumns = matrix[0].length;
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double[][] matrixCopy = new double[numRows][numColumns];
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for (int rowIndex = 0; rowIndex < numRows; ++rowIndex) {
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System.arraycopy(matrix[rowIndex], 0, matrixCopy[rowIndex], 0, numColumns);
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}
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return matrixCopy;
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}
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private static void validateInputMatrix(double[][] matrix) {
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if (matrix == null) {
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throw new IllegalArgumentException("The input matrix cannot be null");
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}
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if (matrix.length == 0) {
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throw new IllegalArgumentException("The input matrix cannot be empty");
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}
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if (!hasValidRows(matrix)) {
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throw new IllegalArgumentException("The input matrix cannot have null or empty rows");
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}
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if (isJaggedMatrix(matrix)) {
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throw new IllegalArgumentException("The input matrix cannot be jagged");
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}
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}
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private static boolean hasValidRows(double[][] matrix) {
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for (double[] row : matrix) {
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if (row == null || row.length == 0) {
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return false;
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}
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}
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return true;
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}
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/**
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* @brief Checks if the input matrix is a jagged matrix.
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* Jagged matrix is a matrix where the number of columns in each row is not the same.
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*
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* @param matrix The input matrix
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* @return True if the input matrix is a jagged matrix, false otherwise
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*/
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private static boolean isJaggedMatrix(double[][] matrix) {
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int numColumns = matrix[0].length;
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for (double[] row : matrix) {
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if (row.length != numColumns) {
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return true;
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}
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}
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return false;
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}
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/**
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* @brief The pivot row is the row in the matrix that is used to eliminate other rows and reduce the matrix to its row echelon form.
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* The pivot row is selected as the first row (from top to bottom) where the value in the current column (the pivot column) is not zero.
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* This row is then used to "eliminate" other rows, by subtracting multiples of the pivot row from them, so that all other entries in the pivot column become zero.
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* This process is repeated for each column, each time selecting a new pivot row, until the matrix is in row echelon form.
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* The number of pivot rows (rows with a leading entry, or pivot) then gives the rank of the matrix.
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*
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* @param matrix The input matrix
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* @param rowMarked An array indicating which rows have been marked
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* @param colIndex The column index
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* @return The pivot row index, or the number of rows if no suitable pivot row was found
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*/
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private static int findPivotRow(double[][] matrix, boolean[] rowMarked, int colIndex) {
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int numRows = matrix.length;
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for (int pivotRow = 0; pivotRow < numRows; ++pivotRow) {
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if (!rowMarked[pivotRow] && !isZero(matrix[pivotRow][colIndex])) {
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return pivotRow;
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}
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}
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return numRows;
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}
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/**
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* @brief This method divides all values in the pivot row by the value in the given column.
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* This ensures that the pivot value itself will be 1, which simplifies further calculations.
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*
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* @param matrix The input matrix
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* @param pivotRow The pivot row index
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* @param colIndex The column index
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*/
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private static void normalizePivotRow(double[][] matrix, int pivotRow, int colIndex) {
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int numColumns = matrix[0].length;
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for (int nextCol = colIndex + 1; nextCol < numColumns; ++nextCol) {
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matrix[pivotRow][nextCol] /= matrix[pivotRow][colIndex];
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}
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}
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/**
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* @brief This method subtracts multiples of the pivot row from all other rows,
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* so that all values in the given column of other rows will be zero.
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* This is a key step in reducing the matrix to row echelon form.
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*
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* @param matrix The input matrix
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* @param pivotRow The pivot row index
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* @param colIndex The column index
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*/
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private static void eliminateRows(double[][] matrix, int pivotRow, int colIndex) {
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int numRows = matrix.length;
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int numColumns = matrix[0].length;
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for (int otherRow = 0; otherRow < numRows; ++otherRow) {
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if (otherRow != pivotRow && !isZero(matrix[otherRow][colIndex])) {
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for (int col2 = colIndex + 1; col2 < numColumns; ++col2) {
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matrix[otherRow][col2] -= matrix[pivotRow][col2] * matrix[otherRow][colIndex];
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}
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}
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}
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}
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}
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src/test/java/com/thealgorithms/maths/MatrixRankTest.java
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src/test/java/com/thealgorithms/maths/MatrixRankTest.java
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package com.thealgorithms.maths;
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import static org.junit.jupiter.api.Assertions.assertEquals;
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import static org.junit.jupiter.api.Assertions.assertThrows;
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import java.util.Arrays;
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import java.util.stream.Stream;
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import org.junit.jupiter.params.ParameterizedTest;
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import org.junit.jupiter.params.provider.Arguments;
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import org.junit.jupiter.params.provider.MethodSource;
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class MatrixRankTest {
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private static Stream<Arguments> validInputStream() {
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return Stream.of(Arguments.of(3, new double[][] {{1, 0, 0}, {0, 1, 0}, {0, 0, 1}}), Arguments.of(0, new double[][] {{0, 0, 0}, {0, 0, 0}, {0, 0, 0}}), Arguments.of(1, new double[][] {{1}}), Arguments.of(2, new double[][] {{1, 2}, {3, 4}}),
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Arguments.of(2, new double[][] {{3, -1, 2}, {-3, 1, 2}, {-6, 2, 4}}), Arguments.of(3, new double[][] {{2, 3, 0, 1}, {1, 0, 1, 2}, {-1, 1, 1, -2}, {1, 5, 3, -1}}), Arguments.of(1, new double[][] {{1, 2, 3}, {3, 6, 9}}),
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Arguments.of(2, new double[][] {{0.25, 0.5, 0.75, 2}, {1.5, 3, 4.5, 6}, {1, 2, 3, 4}}));
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}
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private static Stream<Arguments> invalidInputStream() {
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return Stream.of(Arguments.of((Object) new double[][] {{1, 2}, {10}, {100, 200, 300}}), // jagged array
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Arguments.of((Object) new double[][] {}), // empty matrix
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Arguments.of((Object) new double[][] {{}, {}}), // empty row
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Arguments.of((Object) null), // null matrix
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Arguments.of((Object) new double[][] {{1, 2}, null}) // null row
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);
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}
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@ParameterizedTest
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@MethodSource("validInputStream")
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void computeRankTests(int expectedRank, double[][] matrix) {
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int originalHashCode = Arrays.deepHashCode(matrix);
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int rank = MatrixRank.computeRank(matrix);
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int newHashCode = Arrays.deepHashCode(matrix);
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assertEquals(expectedRank, rank);
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assertEquals(originalHashCode, newHashCode);
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}
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@ParameterizedTest
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@MethodSource("invalidInputStream")
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void computeRankWithInvalidMatrix(double[][] matrix) {
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assertThrows(IllegalArgumentException.class, () -> MatrixRank.computeRank(matrix));
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}
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}
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