.----------------. .----------------. .----------------.
| .--------------. || .--------------. || .--------------. |
| | ____ _____ | || | ____ ____ | || | _____ | |
| ||_ \|_ _| | || ||_ \ / _|| || | |_ _| | |
| | | \ | | | || | | \/ | | || | | | | |
| | | |\ \| | | || | | |\ /| | | || | | | _ | |
| | _| |_\ |_ | || | _| |_\/_| |_ | || | _| |__/ | | |
| ||_____|\____| | || ||_____||_____|| || | |________| | |
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| '--------------' || '--------------' || '--------------' | Neat Matrix Library
'----------------' '----------------' '----------------'
nml is a simple matrix and linear algebra library written in standard C.
Code should be portable and there are no dependencies.
For a detailed explanation of the library code please check this blog post.
It currently supports:
- Basic Matrix Operations (row swaps, colum swaps, multiplication, addition, etc.)
- LU Decomposition;
- Inverse(A);
- Determinant(A)
- Solving linear systems of equations;
- Row Echelon Form;
- Reduced Row Echelon Form (Gauss-Jordan);
- QR decomposition
The library is still under development, but a few thousands test cases are already implemented, covering the most complex algorithms (REF, RREF, LUP, QR, DET, INV, BACKWARD SUBSTITION, FORWARD SUBSTITION, etc.)
- Compile / Run Examples
- How to use the library
The build file for the library it's called nml.sh.
It's actually a bash script (not a makefile!).
./nml.sh clean buildThis will compile the library, create a dist folder where you will find *.a static library file and the header files.
gcc and ar should be available in $PATH.
If you want to use the clang compiler instead of gcc you need to manually edit the ./nml.sh file, changing the variable CC from gcc to clang.
Nothing else should be changed.
# COMPILING RELATED
CC=clang #<----------------- here
CCFLAGS="-Wall -c"
CCFLAGS_EXAMPLES="-Wall"Examples can be found in the ./examples folder.
To build the code examples:
./nml.sh clean examples- This will create an
examples/libfolder where thelibnml.aand the header files will be copied; - The
examples/*.cwill be compiled with the latest version oflibnml; - For each
examples/*.can executable (*.ex) will be created.
To run an example:
# ./nml.sh clean examples && ./examples/<example name>.ex
./nml.sh clean examples && ./examples/playground.exTo run the tests
./nml.sh clean test- This will create a
test/libfolder where thelibnml.aand the header files will be copied; - Each test
tests/*.cwill be compiled with the latest version oflibnml; - For each test
tests/*/can executable (*.ex) will be created.
The test data was generated using sympy.
In the tests/generators/ folder you can find the python3 (.py) scripts used to generate the data.
./nml.sh cleanThis will clean everything (*.o,*.ex,*.a) and will leave the library folder in a clean state.
A few examples can be found in the ./examples folder folder.
All the methods are interacting with the nml_mat struct:
typedef struct nml_mat_s {
unsigned int num_rows;
unsigned int num_cols;
double **data;
int is_square;
} nml_mat;To interact the elements of the matrix:
nml_mat *m = ...
m->data[i][j] = ...The methods for a creating a new matrix are:
nml_mat *nml_mat_new(unsigned int num_rows, unsigned int num_cols)- Creates a
num_rows * num_colsmatrix of zeroes.
- Creates a
nml_mat *nml_mat_sqr(unsigned int size)- Creates a square
size * sizematrix of zeroes.
- Creates a square
nml_mat *nml_mat_eye(unsigned int size)- Creates an identity
size * sizematrix.
- Creates an identity
nml_mat *nml_mat_cp(nml_mat *m)- Returns a new identitcal copy of matrix
m.
- Returns a new identitcal copy of matrix
Everytime we create a matrix, we dynamically allocate memory.
To free the memory please use: nml_mat_free(nml_mat *m).
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat* m, *mx;
printf("\nCreating an empty matrix with 2x3\n");
m = nml_mat_new(2,3);
nml_mat_print(m);
nml_mat_free(m);
printf("\nCreating a square matrix 5x5 \n");
m = nml_mat_sqr(5);
nml_mat_print(m);
nml_mat_free(m);
printf("\nCreating an ID 7x7 Matrix and copying it into another matrix:\n");
m = nml_mat_eye(7);
mx = nml_mat_cp(m);
nml_mat_print(m);
nml_mat_print(mx);
nml_mat_free(m);
nml_mat_free(mx);
return 0;
}To run the example:
./nml.sh clean examples && examples/creating_a_matrix.exAn array can be used as the "data source" for the Matrix by using:
nml_mat *nml_mat_from(unsigned int num_rows, unsigned int num_cols, unsigned int n_vals, double *vals)num_rowsandnum_colsrepresent the dimensions of the matrix;n_valshow many values to read from thevalssource. Ifn_valsis smaller than the productnum_cols * num_rows,0.0will be used as the default value;valsthe array containing double values.
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
double array[6] = {
1.0, 0.2, 3.0, 4.0, 5.0, 3.1
};
nml_mat* my;
// 3 rows, 2 columns
// read exactly 6 numbers from array[6]
my = nml_mat_from(3, 2, 6, array);
nml_mat_print(my);
nml_mat_free(my);
// 4 rows, 2 columns
// read exactly 3 numbers from array[6]
my = nml_mat_from(4, 2, 3, array);
nml_mat_print(my);
nml_mat_free(my);
return 0;
}To run the example:
./nml.sh clean examples && examples/creating_a_matrix_from_an_array.exThe two methods that can be used to create a matrix from a file on disk are:
nml_mat *nml_mat_fromfile(const char *file)- Create a matrix from the
filepath. If the file cannot be opened aNULLmatrix will be returned.
- Create a matrix from the
nml_mat *nml_mat_fromfilef(FILE *f)- Creates a matrix from am already opened stream
f. Does not automatically close the stream (FILE).
- Creates a matrix from am already opened stream
In the file, the matrix has the following format:
4 5
0.0 1.0 2.0 5.0 3.0
3.0 8.0 9.0 1.0 4.0
2.0 3.0 7.0 1.0 1.0
0.0 0.0 4.0 3.0 8.0
On the first line 4 represents the number of rows and 5 represents the number of columns of the Matrix
Then next lines contain the matrix elements: 4 * 5 = 20 numbers.
Example code:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
const char *f = "examples/data/matrix1.data";
nml_mat *from_file = nml_mat_fromfile(f);
nml_mat_print(from_file);
nml_mat_free(from_file);
// Or if the file is already opened
FILE *m_file = fopen("examples/data/matrix2.data", "r");
nml_mat *from_file2 = nml_mat_fromfilef(m_file);
nml_mat_print(from_file2);
nml_mat_free(from_file2);
fclose(m_file);
return 0;
}To run the example:
./nml.sh clean examples && ./examples/creating_a_matrix_from_file.exThe nml_mat *nml_mat_fromfilef(FILE *f) can be called, with f=stdin.
Code example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *from_file2 = nml_mat_fromfilef(stdin);
nml_mat_print(from_file2);
nml_mat_free(from_file2);
return 0;
}To run the example:
./nml.sh clean examples && examples/creating_a_matrix_from_user_input.exCreating a randomized matrix can be done with the following two methods:
nml_mat *nml_mat_rnd(unsigned int num_rows, unsigned int num_cols, double min, double max)- Creates a randomized matrix of size
num_rows * num_cols; - The random values are between
minandmax;
- Creates a randomized matrix of size
nml_mat *nml_mat_sqr_rnd(unsigned int size, double min, double max)- Creates a randomized matrix of size
size * size; - The random values are between
minandmax;
- Creates a randomized matrix of size
#include <stdlib.h>
#include <stdio.h>
#include <time.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
srand(time(NULL)); // Should be called once per program
nml_mat *m = nml_mat_rnd(5, 5, -10.0, 10.0);
nml_mat_print(m);
nml_mat_free(m);
return 0;
}To run the example:
./nml.sh clean examples && examples/create_randomized_matrix.exThere are two "equality" methods for matrices:
-
int nml_mat_eqdim(nml_mat *m1, nml_mat *m2)- Tests if two matrices have the same dimension.
-
int nml_mat_eq(nml_mat *m1, nml_mat *m2, double tolerance)- Test if two matrices are equal:
- They have the same dimensions
- The elements are equal or close of being equal.
- If you want the elements to be "exactly" eqaul,
tolerance=0.0
- Test if two matrices are equal:
#include <stdlib.h>
#include <stdio.h>
#include <time.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
srand(time(NULL));
nml_mat *m1 = nml_mat_rnd(2, 3, 1.0, 10.0);
nml_mat *m2 = nml_mat_rnd(2, 3, 1.0, 10.0);
if (nml_mat_eq(m1, m2, 0.001)) {
printf("Wow, what were the oddss..\n");
} else {
printf("It's ok, nobody is that lucky!\n");
}
if (nml_mat_eqdim(m1, m2)) {
printf("At least we know they both have the same number of rows and columns.\n");
}
nml_mat_free(m1);
nml_mat_free(m2);
return 0;
}To run the example:
./nml.sh clean examples && ./examples/matrix_equality.exTwo methods can be used to select rows and columns from a source matrix (nml_mat*):
nml_mat *nml_mat_col_get(nml_mat *m, unsigned int col)nml_mat *nml_mat_row_get(nml_mat *m, unsigned int row)
The following code extracts every column of a given random matrix into a temporary column matrix (nml_mat*):
#include <stdlib.h>
#include <stdio.h>
#include <time.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
printf("\nExtract all matrix columns from a Matrix as matrices\n");
srand(time(NULL));
nml_mat *m = nml_mat_rnd(5, 5, -10.0, 10.0);
nml_mat *col;
nml_mat_print(m);
int i = 0;
for(i = 0; i < m->num_cols; i++) {
col = nml_mat_col_get(m, i);
nml_mat_print(col);
nml_mat_free(col);
}
nml_mat_free(m);
return 0;
}To run the example:
./nml.sh clean examples && examples/select_columns.exUse: void nml_mat_all_set(nml_mat *matrix, double value)
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
// Creates a matrix of zeros of size = 5
nml_mat *pi_mat = nml_mat_sqr(5);
// Sets all elements to PI
nml_mat_all_set(pi_mat, M_PI);
nml_mat_print(pi_mat);
nml_mat_free(pi_mat);
return 0;
}To run the example:
./nml.sh clean examples && ./examples/set_all_elements.exUse: int nml_mat_diag_set(nml_mat *matrix, double value)
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
// Creates a matrix of zeros of size = 5
nml_mat *pi_mat = nml_mat_sqr(5);
// Sets the first diagonal to PI
nml_mat_diag_set(pi_mat, M_PI);
nml_mat_print(pi_mat);
nml_mat_free(pi_mat);
return 0;
}To run the example:
./nml.sh clean examples && examples/set_diagonal_elements.exUse:
nml_mat *nml_mat_smult(nml_mat *m, double num)- Multiplies all elements of matrix
mwithnum. A new matrix is returned.
- Multiplies all elements of matrix
int nml_mat_smult_r(nml_mat *m, double num)- Multiplies all elements of matrix
mwithnum. All changes are done on matrixm.
- Multiplies all elements of matrix
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *m = nml_mat_eye(5);
// Multiply all elements of m with 2.0
// and return a new matrix
nml_mat *new_m = nml_mat_smult(m, 2.0);
if (!(nml_mat_eq(m, new_m, 0.0))) {
printf("It's normal to see this message.\n");
}
// Multiply all elements of m with 2.0
// m is modified, no new matrix is created
nml_mat_smult_r(m, 2.0);
if (nml_mat_eq(m, new_m, 0.0)) {
printf("It's even more normal to see this message.\n");
}
nml_mat_free(m);
nml_mat_free(new_m);
return 0;
}To run the example:
./nml.sh clean examples && examples/scalar_multiply.exUse:
nml_mat *nml_mat_row_mult(nml_mat *m, unsigned int row, double num)- Multiplies all elements from row
rowin matrixmwith scalarnum. A new matrix is returned.mremains un-altered.
- Multiplies all elements from row
int nml_mat_row_mult_r(nml_mat *m, unsigned int row, double num)- Multiplies all elements from row
rowin matrixmwith scalarnum. The changes are done directly on matrixm.
- Multiplies all elements from row
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *a = nml_mat_new(4,5);
nml_mat_all_set(a, 1.0);
int i = 0;
for(; i < a->num_rows; ++i) {
// Changes are doing on matrix a
// row[i] is multiplied with (double) i
nml_mat_row_mult_r(a, i, (double)i);
}
nml_mat_print(a);
// Create a new matrix b by multiplying row[1]
// in matrix a with 5.0.
// Matrix a remains unchanged
nml_mat *b = nml_mat_row_mult(a, 1, 5.0);
nml_mat_print(b);
nml_mat_free(a);
nml_mat_free(b);
return 0;
}To run the example:
./nml.sh clean examples && examples/multiply_rows.exTo run the example:
./nml.sh clean examples && examples/multiply_rows.exThe following methods are used to add a row to another row (with a multiplicator). This method is usally used when implementing various forms of matrix reduction or decompositions.
Use:
nml_mat *nml_mat_row_addrow(nml_mat *m, unsigned int where, unsigned int row, double multiplier)- This will do the following:
m->data[where][...] *= m->data[row][...] * multiplier. The results will be kept in a new matrix. Matrixmremains unchanged.
- This will do the following:
int nml_mat_row_addrow_r(nml_mat *m, unsigned int where, unsigned int row, double multiplier)- This will do the following:
m->data[where][...] *= m->data[row][...] * multiplier. The changes are done directly onm.
- This will do the following:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *m = nml_mat_rnd(5, 4, 1.0, 2.0);
nml_mat_print(m);
// Add row[1] elements to row[2] elements
nml_mat_row_addrow_r(m, 2, 1, 1.0);
// Add row[1] to row[0] with a multiplier of 2.0
nml_mat_row_addrow_r(m, 0, 1, 2.0);
nml_mat_print(m);
nml_mat_free(m);
return 0;
}To run the example:
./nml.sh clean examples && ./examples/row_plus_row.exTo remove columns:
nml_mat *nml_mat_col_rem(nml_mat *m, unsigned int column)- A new matrix is being created,
mremains the same.
- A new matrix is being created,
To remove rows:
nml_mat *nml_mat_row_rem(nml_mat *m, unsigned int row)- A new matrix is being created,
mremains the same.
- A new matrix is being created,
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *m = nml_mat_sqr_rnd(4, 1.0, 2.0);
nml_mat_print(m);
// Remove column[1] from m
// m remains the same
// less_columns is another matrix
nml_mat *less_columns = nml_mat_col_rem(m, 1);
nml_mat_print(less_columns);
// Remove row[0] from less_columns
// less_columns remains the same
// less_rows is another matrix
nml_mat *less_rows = nml_mat_row_rem(less_columns, 0);
nml_mat_print(less_rows);
nml_mat_free(m);
nml_mat_free(less_columns);
nml_mat_free(less_rows);
return 0;
}To run the example:
./nml.sh examples && ./examples/remove_columns_rows.exUse:
nml_mat *nml_mat_row_swap(nml_mat *m, unsigned int row1, unsigned int row2)int nml_mat_row_swap_r(nml_mat *m, unsigned int row1, unsigned int row2)nml_mat *nml_mat_col_swap(nml_mat *m, unsigned int col1, unsigned int col2)int nml_mat_col_swap_r(nml_mat *m, unsigned int col1, unsigned int col2)
#include <stdlib.h>
#include <stdio.h>
#include <time.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
srand(time(NULL));
nml_mat *m = nml_mat_sqr_rnd(8, 0.0, 10.0);
printf("m=");
nml_mat_print(m);
printf("m= (...after swapping col1=%d with col2=%d):\n", 1, 2);
nml_mat_col_swap_r(m, 1, 2);
nml_mat_print(m);
printf("newm= (...after swapping col1=%d with col2=%d and creating a new matrix):\n", 0, 1);
nml_mat *newm = nml_mat_col_swap(m, 0, 1);
nml_mat_print(newm);
printf("m= (...after swapping row1=%d with row2=%d)\n", 0, 2);
nml_mat_row_swap_r(m, 0, 2);
nml_mat_print(m);
nml_mat_free(m);
nml_mat_free(newm);
return 0;
}Output:
m=
3.467541 8.965948 0.685298 7.802247 2.363902 0.097955 6.325767 7.162469
9.613042 6.399923 3.512556 5.528620 9.520015 2.886378 1.363232 1.838682
2.722997 5.410983 2.397803 9.870863 9.601451 1.591262 4.335792 1.660161
2.318266 3.094436 8.189400 9.242210 3.818718 1.198454 2.423213 6.939399
0.471069 7.252268 8.869578 0.994544 5.301898 9.007567 0.172999 7.586261
2.295128 4.212713 3.072580 0.849523 7.941120 6.407214 6.049472 3.469933
9.157250 5.896395 0.705688 0.491878 6.985944 2.762460 8.673238 1.114106
4.783565 7.369584 0.592299 4.774641 7.395844 1.942471 7.115440 9.204845
m= (...after swapping col1=1 with col2=2):
3.467541 0.685298 8.965948 7.802247 2.363902 0.097955 6.325767 7.162469
9.613042 3.512556 6.399923 5.528620 9.520015 2.886378 1.363232 1.838682
2.722997 2.397803 5.410983 9.870863 9.601451 1.591262 4.335792 1.660161
2.318266 8.189400 3.094436 9.242210 3.818718 1.198454 2.423213 6.939399
0.471069 8.869578 7.252268 0.994544 5.301898 9.007567 0.172999 7.586261
2.295128 3.072580 4.212713 0.849523 7.941120 6.407214 6.049472 3.469933
9.157250 0.705688 5.896395 0.491878 6.985944 2.762460 8.673238 1.114106
4.783565 0.592299 7.369584 4.774641 7.395844 1.942471 7.115440 9.204845
newm= (...after swapping col1=0 with col2=1 and creating a new matrix):
0.685298 3.467541 8.965948 7.802247 2.363902 0.097955 6.325767 7.162469
3.512556 9.613042 6.399923 5.528620 9.520015 2.886378 1.363232 1.838682
2.397803 2.722997 5.410983 9.870863 9.601451 1.591262 4.335792 1.660161
8.189400 2.318266 3.094436 9.242210 3.818718 1.198454 2.423213 6.939399
8.869578 0.471069 7.252268 0.994544 5.301898 9.007567 0.172999 7.586261
3.072580 2.295128 4.212713 0.849523 7.941120 6.407214 6.049472 3.469933
0.705688 9.157250 5.896395 0.491878 6.985944 2.762460 8.673238 1.114106
0.592299 4.783565 7.369584 4.774641 7.395844 1.942471 7.115440 9.204845
m= (...after swapping row1=0 with row2=2)
2.722997 2.397803 5.410983 9.870863 9.601451 1.591262 4.335792 1.660161
9.613042 3.512556 6.399923 5.528620 9.520015 2.886378 1.363232 1.838682
3.467541 0.685298 8.965948 7.802247 2.363902 0.097955 6.325767 7.162469
2.318266 8.189400 3.094436 9.242210 3.818718 1.198454 2.423213 6.939399
0.471069 8.869578 7.252268 0.994544 5.301898 9.007567 0.172999 7.586261
2.295128 3.072580 4.212713 0.849523 7.941120 6.407214 6.049472 3.469933
9.157250 0.705688 5.896395 0.491878 6.985944 2.762460 8.673238 1.114106
4.783565 0.592299 7.369584 4.774641 7.395844 1.942471 7.115440 9.204845
To run the example:
./nml.sh examples && ./examples/swap_rows_and_columns.exTwo or more matrices can be concatenated (horizontally) or (vertically) into one matrix.
To achieve this, please use:
nml_mat *nml_mat_cath(unsigned int mnun, nml_mat **matrices)- For horizontal concatenation. A new matrix is returned.
numrepresents the number of matrices to concatenate.matricesthe matrices to be concatenated.
nml_mat *nml_mat_catv(unsigned int mnum, nml_mat **matrices)- For vertical concatenation. A new matrix is returned.
numrepresents the number of matrices to concatenate.matricesthe matrices to be concatenated.
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *I = nml_mat_eye(3);
nml_mat *Ix2 = nml_mat_smult(I, 2.0);
nml_mat *rndm = nml_mat_rnd(3, 4, 1.0, 5.0);
nml_mat **ms = malloc(sizeof(*ms) * 2);
ms[0] = I;
ms[1] = Ix2;
nml_mat *concats1 = nml_mat_cath(2, ms);
ms[0] = concats1;
ms[1] = rndm;
nml_mat *concats2 = nml_mat_cath(2, ms);
printf("\nConcatenate horizontally\n");
printf("I=\n");
nml_mat_print(I);
printf("Ix2=\n");
nml_mat_print(Ix2);
printf("rndm=\n");
nml_mat_print(rndm);
printf("concats1=\n");
nml_mat_print(concats1);
printf("concats2=\n");
nml_mat_print(concats2);
free(ms);
nml_mat_free(I);
nml_mat_free(Ix2);
nml_mat_free(concats1);
nml_mat_free(concats2);
nml_mat_free(rndm);
// -------------------------------------
// Vertical concatenation
// -------------------------------------
nml_mat *A = nml_mat_rnd(3, 4, 1.0, 4.0);
nml_mat *B = nml_mat_rnd(5, 4, 10.0, 20.0);
nml_mat *C = nml_mat_eye(4);
nml_mat **ABarr = malloc(sizeof(*ABarr) * 2);
ABarr[0] = A;
ABarr[1] = B;
nml_mat *ABCat = nml_mat_catv(2, ABarr);
printf("\nA=\n");
nml_mat_print(A);
printf("\nB=\n");
nml_mat_print(B);
printf("\nC=\n");
nml_mat_print(C);
printf("\nA concat B =\n");
nml_mat_print(ABCat);
free(ABarr);
nml_mat_free(A);
nml_mat_free(B);
nml_mat_free(C);
return 0;
}To run the example:
./nml.sh clean examples && ./examples/concatenate_matrices.exTo add or subtract two matrices, the following methods can be used:
nml_mat *nml_mat_add(nml_mat *m1, nml_mat *m2)- Adds two matrices, the results are kept in a new
nml_mat*.m1andm2remain unchanged.
- Adds two matrices, the results are kept in a new
int nml_mat_add_r(nml_mat *m1, nml_mat *m2)- Add two matrices, the results are kept in
m1.m2remains unchanged.
- Add two matrices, the results are kept in
nml_mat *nml_mat_sub(nml_mat *m1, nml_mat *m2)- Subtracts two matrices, the results are kept in a new
nml_mat*.m1andm2remain unchanged.
- Subtracts two matrices, the results are kept in a new
int nml_mat_sub_r(nml_mat *m1, nml_mat *m2)- Subtracts two matrices, the results are kept in
m1.m2remains unchanged.
- Subtracts two matrices, the results are kept in
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *m1 = nml_mat_sqr_rnd(4, 0.0, 10.0);
nml_mat *m2 = nml_mat_sqr_rnd(4, 0.0, 10.0);
printf("m1=\n");
nml_mat_print(m1);
printf("m2=\n");
nml_mat_print(m2);
// Add the matrices to, result is kept in m3
// m1 and m2 remain unchanged
nml_mat *m3 = nml_mat_add(m1, m2);
printf("m3=\n");
nml_mat_print(m3);
// Add the matrices, the result is kept in m1
// m1 is modified, m2 remains unchanged
nml_mat_add_r(m1, m2);
printf("m1=\n");
nml_mat_print(m1);
nml_mat_free(m1);
nml_mat_free(m2);
nml_mat_free(m3);
return 0;
}To run the example:
./nml.sh examples && examples/add_matrices.exTo multiply two matrices, the following method can be used:
nml_mat *nml_mat_dot(nml_mat *m1, nml_mat *m2)- Multiplies two matrices, the result is kept in a new
nml_mat*.m1andm2remain unchanged.
- Multiplies two matrices, the result is kept in a new
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *m1 = nml_mat_sqr_rnd(4, 0.0, 10.0);
nml_mat *m2 = nml_mat_sqr_rnd(4, 0.0, 10.0);
printf("m1=\n");
nml_mat_print(m1);
printf("m2=\n");
nml_mat_print(m2);
// Multiply matrices
nml_mat *m3 = nml_mat_dot(m1, m2);
printf("m3=\n");
nml_mat_print(m3);
nml_mat_free(m1);
nml_mat_free(m2);
nml_mat_free(m3);
return 0;
}To run the example:
./nml.sh examples && examples/dot_matrices.exTo transpose a matrix, the following method can be used:
nml_mat *nml_mat_transp(nml_mat *m)- A new
nml_mat*will be created, representing the transpose matrix ofm.mremains unchanged.
- A new
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *m1 = nml_mat_rnd(1, 5, 1.0, 10.0);
nml_mat_print(m1);
nml_mat *m2 = nml_mat_transp(m1);
nml_mat_print(m2);
nml_mat_free(m1);
nml_mat_free(m2);
return 0;
}To run the example:
./nml.sh clean examples && examples/transpose.exTo calculate the trace of the matrix the following method can be used: double nml_mat_trace(nml_mat* m).
To bring the matrix in Row Echelon Form the following method can be used: nml_mat *nml_mat_ref(nml_mat *m).
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
double v1[9] = {
0.0, 1.0, 2.0,
1.0, 2.0, 1.0,
2.0, 7.0, 8.0
};
nml_mat *m1 = nml_mat_from(3, 3, 9, v1);
printf("\nm1=\n");
nml_mat_print(m1);
nml_mat *refm1 = nml_mat_ref(m1);
printf("\nrefm1=\n");
nml_mat_print(refm1);
nml_mat_free(m1);
nml_mat_free(refm1);
return 0;
}Output:
m1=
0.000000 1.000000 2.000000
1.000000 2.000000 1.000000
2.000000 7.000000 8.000000
refm1=
1.000000 2.000000 1.000000
0.000000 1.000000 2.000000
0.000000 0.000000 0.000000
To run the example:
./nml.sh examples && ./examples/row_echelon.exTo bring the matrix in Reduced Row Echelon Form the following method can be used: nml_mat *nml_mat_rref(nml_mat *m).
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
double v1[9] = {
0.0, 1.0, 2.0,
1.0, 2.0, 1.0,
2.0, 7.0, 8.0
};
nml_mat *m1 = nml_mat_from(3, 3, 9, v1);
printf("\nm1=\n");
nml_mat_print(m1);
nml_mat *rrefm1 = nml_mat_rref(m1);
printf("\nrrefm1=\n");
nml_mat_print(rrefm1);
nml_mat_free(m1);
nml_mat_free(rrefm1);
return 0;
}Output:
m1=
0.000000 1.000000 2.000000
1.000000 2.000000 1.000000
2.000000 7.000000 8.000000
rrefm1=
1.000000 0.000000 -3.000000
-0.000000 1.000000 2.000000
0.000000 0.000000 0.000000
To run the example:
./nml.sh clean examples && examples/reduced_row_echelon.exTo decompose a matrix using LU you can use: nml_mat_lup *nml_mat_lup_solve(nml_mat *m).
The result is a pointer nml_mat_lup*:
typedef struct nml_mat_lup_s {
nml_mat *L;
nml_mat *U;
nml_mat *P;
unsigned int num_permutations;
} nml_mat_lup;To free the nml_mat_lup*. Please use void nml_mat_lup_free(nml_mat_lup* lu). This will also deallocate the memory for the three internal nml_mat* pointers.
LU decomposition is used for solving linear systems of equations, computing the determinant and the inverse of a matrix.
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *m1 = nml_mat_sqr_rnd(4, 0.0, 10.0);
printf("m1=\n");
nml_mat_print(m1);
nml_mat_lup *m1_lup = nml_mat_lup_solve(m1);
printf("L, U, P:\n");
nml_mat_lup_print(m1_lup);
nml_mat_free(m1);
nml_mat_lup_free(m1_lup);
return 0;
}Output:
m1=
0.000078 1.315378 7.556053 4.586501
5.327672 2.189592 0.470446 6.788647
6.792964 9.346929 3.835021 5.194164
8.309653 0.345721 0.534616 5.297002
L, U, P:
1.000000 0.000000 0.000000 0.000000
0.817479 1.000000 0.000000 0.000000
0.000009 0.145116 1.000000 0.000000
0.641143 0.217108 -0.086373 1.000000
8.309653 0.345721 0.534616 5.297002
0.000000 9.064309 3.397983 0.863978
0.000000 0.000000 7.062947 4.461075
0.000000 0.000000 0.000000 3.590254
0.000000 0.000000 0.000000 1.000000
0.000000 0.000000 1.000000 0.000000
1.000000 0.000000 0.000000 0.000000
0.000000 1.000000 0.000000 0.000000
Running the example:
./nml.sh clean examples && examples/lup.exCalculating the inverse requires to decompose the matrix LU(P) decomposition first.
Afterwards obtaining the inverse is straightforward: nml_mat *nml_mat_inv(nml_mat_lup *m).
Example:
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
printf("\nInverse of a matrix:\n");
double m_v[16] = {
2.0, 7.0, 6.0, 1.0,
9.0, 5.0, 0.0, 2.0,
4.0, 3.0, 8.0, 3.0,
3.0, 5.0, 1.0, 9.0
};
nml_mat *m = nml_mat_from(4,4,16, m_v);
nml_mat_lup *lup = nml_mat_lup_solve(m);
nml_mat* minv = nml_mat_inv(lup);
nml_mat *mdotminv = nml_mat_dot(m, minv);
printf("m=");
nml_mat_print(m);
printf("minv=");
nml_mat_print(minv);
printf("(%%e) m * minv=");
nml_mat_printf(mdotminv, "%e\t");
printf("(%%f) m * minv=");
nml_mat_printf(mdotminv, "%f\t");
nml_mat_free(m);
nml_mat_free(minv);
nml_mat_free(mdotminv);
return 0;
}Output:
m=
2.000000 7.000000 6.000000 1.000000
9.000000 5.000000 0.000000 2.000000
4.000000 3.000000 8.000000 3.000000
3.000000 5.000000 1.000000 9.000000
minv=
-0.081577 0.112583 0.065924 -0.037929
0.174895 0.013245 -0.133955 0.022276
0.001505 -0.046358 0.127935 -0.032511
-0.070138 -0.039735 0.038230 0.114991
(%e) m * minv=
1.000000e+00 4.163336e-17 4.163336e-17 -1.387779e-17
0.000000e+00 1.000000e+00 -2.775558e-17 2.775558e-17
5.551115e-17 6.938894e-17 1.000000e+00 5.551115e-17
0.000000e+00 5.551115e-17 -5.551115e-17 1.000000e+00
(%f) m * minv=
1.000000 0.000000 0.000000 -0.000000
0.000000 1.000000 -0.000000 0.000000
0.000000 0.000000 1.000000 0.000000
0.000000 0.000000 -0.000000 1.000000
To run the example:
./nml.sh clean examples && ./examples/inverse.exCalculating the determinant requires to decompose the matrix LU(P) decomposition first.
Afterwards obtaining the determinant is straightforward: double nml_mat_det(nml_mat_lup* lup).
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *m1 = nml_mat_sqr_rnd(4, 0.0, 10.0);
nml_mat_lup *m1_lup = nml_mat_lup_solve(m1);
printf("m1=\n");
nml_mat_print(m1);
printf("determinant=%lf\n", nml_mat_det(m1_lup));
nml_mat_free(m1);
nml_mat_lup_free(m1_lup);
return 0;
}Output:
m1=
0.000078 1.315378 7.556053 4.586501
5.327672 2.189592 0.470446 6.788647
6.792964 9.346929 3.835021 5.194164
8.309653 0.345721 0.534616 5.297002
determinant=-1909.979877
Runnning the example:
./nml.sh clean examples && examples/determinant.exUse: nml_mat *nml_ls_solvefwd(nml_mat *low_triang, nml_mat *b).
Note: no validation will be performed to check is low_triang is a lower triangular matrix
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
FILE *input = fopen("./examples/data/matrix9_lower_triangular.data", "r");
nml_mat *A = nml_mat_fromfilef(input);
nml_mat *B = nml_mat_fromfilef(input);
nml_mat *x = nml_ls_solvefwd(A, B);
nml_mat_print(A);
nml_mat_print(B);
nml_mat_print(x);
nml_mat_free(A);
nml_mat_free(B);
nml_mat_free(x);
fclose(input);
return 0;
}To run the example:
./nml.sh clean examples && examples/forward_substition.exUse: nml_mat *nml_ls_solvebck(nml_mat *upper_triang, nml_mat *b).
Note: no validation will be performed to check is upper_triang is an upper triangular matrix
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
FILE *input = fopen("./examples/data/matrix10_upper_triangular.data", "r");
nml_mat *A = nml_mat_fromfilef(input);
nml_mat *B = nml_mat_fromfilef(input);
nml_mat *x = nml_ls_solvebck(A, B);
nml_mat_print(A);
nml_mat_print(B);
nml_mat_print(x);
nml_mat_free(A);
nml_mat_free(B);
nml_mat_free(x);
fclose(input);
return 0;
}To run the example:
./nml.sh clean examples && examples/backward_substitution.exUse: nml_mat *nml_ls_solve(nml_mat_lup *lup, nml_mat* b).
#include <stdlib.h>
#include <stdio.h>
#include "lib/nml.h"
int main(int argc, char *argv[]) {
nml_mat *A = nml_mat_sqr_rnd(4, 1.0, 10.0);
nml_mat *B = nml_mat_rnd(4, 1, 1.0, 10.0);
nml_mat_lup *LUP = nml_mat_lup_solve(A);
nml_mat *x = nml_ls_solve(LUP, B);
nml_mat_print(x);
nml_mat_free(A);
nml_mat_free(B);
nml_mat_free(x);
nml_mat_lup_free(LUP);
}To run the example:
./nml.sh clean examples && ./examples/ls_solve.ex