In this project I will implement my own library for processing numerical matrices in the C programming language.
A matrix is a collection of numbers arranged into a fixed number of rows and columns.
Matrix A is a rectangular table of numbers arranged in m rows and n columns
1 2 3
A = 4 5 6
7 8 9
1 2 3 4
В = 5 6 7 8
9 10 11 12
You can get the desired element with the help of indices, as follows A[1,1] = 1, where the first index is the row number, the second is the column number.
Matrix A will have elements with the following indices:
(1,1) (1,2) (1,3)
A = (2,1) (2,2) (2,3)
(3,1) (3,2) (3,3)
The order of a matrix is the number of its rows or columns.
The main diagonal of a square matrix is the diagonal from the upper left to the lower right corner.
A rectangular matrix (B) is a matrix with the number of rows not equal to the number of columns.
A square matrix (A) is a matrix with the number of rows equal to the number of columns.
A column matrix is a matrix with only one column:
(1,1)
A = (2,1)
(n,1)
A row matrix is a matrix that has only one row:
A = (1,1) (1,2) (1,m)
Tip: A column matrix and a row matrix are also often called vectors.
A diagonal matrix is a square matrix in which all elements outside the main diagonal are zero.
An identity matrix is a diagonal matrix with all diagonal elements equal to one:
1 0 0
A = 0 1 0
0 0 1
A triangular matrix is a square matrix with all elements on one side of the main diagonal equal to zero.
1 2 3
A = 0 4 5
0 0 6
typedef struct matrix_struct {
double** matrix;
int rows;
int columns;
} matrix_t;All operations (except matrix comparison) should return the resulting code:
- 0 - OK
- 1 - Error, incorrect matrix
- 2 - Calculation error (mismatched matrix sizes; matrix for which calculations cannot be performed, etc.)
int s21_create_matrix(int rows, int columns, matrix_t *result);void s21_remove_matrix(matrix_t *A);#define SUCCESS 1
#define FAILURE 0
int s21_eq_matrix(matrix_t *A, matrix_t *B);The matrices A, B are equal |A = B| if they have the same dimensions and the corresponding elements are identical, thus for all i and j: A(i,j) = B(i,j)
The comparison must be up to and including 7 decimal places.
int s21_sum_matrix(matrix_t *A, matrix_t *B, matrix_t *result);
int s21_sub_matrix(matrix_t *A, matrix_t *B, matrix_t *result);The sum of two matrices A = m × n and B = m × n of the same size is a matrix C = m × n = A + B of the same size whose elements are defined by the equations C(i,j) = A(i,j) + B(i,j).
The difference of two matrices A = m × n and B = m × n of the same size is a matrix C = m × n = A - B of the same size whose elements are defined by the equations C(i,j) = A(i,j) - B(i,j).
1 2 3 1 0 0 2 2 3
С = A + B = 0 4 5 + 2 0 0 = 2 4 5
0 0 6 3 4 1 3 4 7
int s21_mult_number(matrix_t *A, double number, matrix_t *result);
int s21_mult_matrix(matrix_t *A, matrix_t *B, matrix_t *result);The product of the matrix A = m × n by the number λ is the matrix B = m × n = λ × A whose elements are defined by the equations B = λ × A(i,j).
1 2 3 2 4 6
B = 2 × A = 2 × 0 4 2 = 0 8 4
2 3 4 4 6 8
The product of A = m × k by B = k × n is a matrix C = m × n = A × B of size m × n whose elements are defined by the equation C(i,j) = A(i,1) × B(1,j) + A(i,2) × B(2,j) + ... + A(i,k) × B(k,j).
1 4 1 -1 1 9 11 17
C = A × B = 2 5 × 2 3 4 = 12 13 22
3 6 15 15 27
The components of matrix C are calculated as follows:
C(1,1) = A(1,1) × B(1,1) + A(1,2) × B(2,1) = 1 × 1 + 4 × 2 = 1 + 8 = 9
C(1,2) = A(1,1) × B(1,2) + A(1,2) × B(2,2) = 1 × (-1) + 4 × 3 = (-1) + 12 = 11
C(1,3) = A(1,1) × B(1,3) + A(1,2) × B(2,3) = 1 × 1 + 4 × 4 = 1 + 16 = 17
C(2,1) = A(2,1) × B(1,1) + A(2,2) × B(2,1) = 2 × 1 + 5 × 2 = 2 + 10 = 12
C(2,2) = A(2,1) × B(1,2) + A(2,2) × B(2,2) = 2 × (-1) + 5 × 3 = (-2) + 15 = 13
C(2,3) = A(2,1) × B(1,3) + A(2,2) × B(2,3) = 2 × 1 + 5 × 4 = 2 + 20 = 22
C(3,1) = A(3,1) × B(1,1) + A(3,2) × B(2,1) = 3 × 1 + 6 × 2 = 3 + 12 = 15
C(3,2) = A(3,1) × B(1,2) + A(3,2) × B(2,2) = 3 × (-1) + 6 × 3 = (-3) + 18 = 15
C(3,3) = A(3,1) × B(1,3) + A(3,2) × B(2,3) = 3 × 1 + 6 × 4 = 3 + 24 = 27
int s21_transpose(matrix_t *A, matrix_t *result);The transpose of matrix A is in switching its rows with its columns with their numbers retained
1 4 1 2 3
A = A^T = 2 5 = 4 5 6
3 6
int s21_calc_complements(matrix_t *A, matrix_t *result);Minor M(i,j) is a (n-1)-order determinant obtained by deleting out the i-th row and the j-th column from the matrix A.
For the following matrix:
1 2 3
A = 0 4 2
5 2 1
The minor of the first element of the first row is:
M(1,1) = 4 2
2 1
|M| = 4 - 4 = 0
The minors of matrix will look like this:
0 -10 -20
M = -4 -14 -8
-8 2 4
The algebraic complement of a matrix element is the value of the minor multiplied by -1^(i+j).
The matrix of algebraic complement will look like this:
0 10 -20
M. = 4 -14 8
-8 -2 4
int s21_determinant(matrix_t *A, double *result);The determinant is a number that is associated to each square matrix and calculated from the elements using special formulas.
Tip: The determinant can only be calculated for a square matrix.
The determinant of a matrix equals the sum of the products of elements of the row (column) and the corresponding algebraic complements.
Finding the determinant of matrix A by the first row:
1 2 3
A = 4 5 6
7 8 9
|A| = 1 × 5 6 - 2 × 4 6 + 3 × 4 5 = 1 × (5 × 9 - 8 × 6) - 2 × (4 × 9 - 6 × 7) + 3 × (4 × 8 - 7 × 5)
8 9 7 9 7 8
|A| = 1 × (45 - 48) - 2 × (36 - 42) + 3 × (32 - 35) = -3 + 12 + (-9) = 0
|A| = 0
int s21_inverse_matrix(matrix_t *A, matrix_t *result);A matrix A to the power of -1 is called the inverse of a square matrix A if the product of these matrices equals the identity matrix.
If the determinant of the matrix is zero, then it does not have an inverse.
The formula to calculate the inverse of matrix is
The following matrix is given:
2 5 7
A = 6 3 4
5 -2 -3
Finding the determinant:
|A| = -1
Determinant |A| != 0 -> matrix has an inverse.
Construction of minor matrix:
-1 -38 -27
М = -1 -41 -29
-1 -34 -24
The matrix of algebraic complements:
-1 38 -27
М. = 1 -41 29
-1 34 -24
The transpose of matrix of algebraic complements:
-1 1 -1
М^T. = 38 -41 34
-27 29 -24
The inverse matrix will look like this:
1 -1 1
A^(-1) = 1/|A| * M^T. = -38 41 -34
27 -29 24
Implement basic operations with matrices (partially described above): create_matrix (creation), remove_matrix (cleaning and destruction), eq_matrix (comparison), sum_matrix (addition), sub_matrix (subtraction), mult_matrix (multiplication), mult_number (multiplication by number), transpose (transpose), determinant (calculation of determinant), calc_complements (calculation of matrix of algebraic complements), inverse_matrix (finding inverse of the matrix).
- The library must be developed in C language of C11 standard using gcc compiler
- The library code must be located in the src folder on the develop branch
- Do not use outdated and legacy language constructions and library functions. Pay attention to the legacy and obsolete marks in the official documentation on the language and the libraries used. Use the POSIX.1-2017 standard.
- When writing code it is necessary to follow the Google style
- Make it as a static library (with the s21_matrix.h header file)
- The library must be developed according to the principles of structured programming;
- Use prefix s21_ before each function
- Prepare full coverage of library functions code with unit-tests using the Check library
- Unit tests must cover at least 80% of each function (checked using gcov)
- Provide a Makefile for building the library and tests (with targets all, clean, test, s21_matrix.a, gcov_report)
- The gcov_report target should generate a gcov report in the form of an html page. Unit tests must be run with gcov flags to do this
- The matrix must be implemented as the structure described above
- Verifiable accuracy of the fractional part is up to 6 decimal places