metalsvm/newlib/examples/jacobi.c

/*
 * Copyright 2010-2011 Stefan Lankes
 *                     Chair for Operating Systems, RWTH Aachen University
 *
 * 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.
 *
 */

#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <time.h>
#include <unistd.h>
#include <errno.h>

#define MATRIX_SIZE 	128
#define MAXVALUE	1337
#define PAGE_SIZE	4096
#define CACHE_SIZE	(256*1024)
#define ALIGN(x,a)	(((x)+(a)-1)&~((a)-1))

static int generate_empty_matrix(double*** A , unsigned int N) {
	unsigned int iCnt;
	int i,j;

	*A = (double**) malloc((N+1)*sizeof(double*));

	if (*A == NULL) 
		return -2;	/* Error */

	(*A)[0] = (double*) malloc((N+1)*N*sizeof(double));

	if (**A == NULL)
		return -2;	/* Error */

	for(iCnt=1; iCnt<N; iCnt++) { /* Assign pointers in the first "real index"; Value from 1 to N (0 yet set, value N means N+1) */
		(*A)[iCnt] = &((*A)[0][iCnt*(N+1)]);
	}

	memset(**A, 0, (N+1)*N*sizeof(double));      /* Fill matrix values with 0 */

	srand( 42 /*(unsigned) time(NULL)*/ ) ; /* init random number generator */

	/* 
	 * initialize the system of linear equations
	 * the result vector is one
	 */
	for (i = 0; i < N; i++) 
	{
		double sum = 0.0;

		for (j = 0; j < N; j++) 
		{
			if (i != j) 
			{
				double c = ((double)rand()) / ((double)RAND_MAX) * MAXVALUE;

				sum += fabs(c);
				(*A)[i][j] = c;
				(*A)[i][N] += c;
			}
		}

		/*
		 * The Jacobi method will always converge if the matrix A is strictly or irreducibly diagonally dominant. 
		 * Strict row diagonal dominance means that for each row, the absolute value of the diagonal term is 
		 * greater than the sum of absolute values of other terms: |A[i][i]| > Sum |A[i][j]| with (i != j)
		 */

		(*A)[i][i] = sum + 2.0;
		(*A)[i][N] += sum + 2.0;
	}

	return 0;
}

int main(int argc, char **argv)
{
	double*		temp;
	unsigned int	i, j, iter_start, iter_end;
	unsigned int	iterations = 0;
	double		error, norm, max = 0.0;
	double**	A=0;
	double*		X;
	double*		X_old, xi;
	clock_t		start, end;

	if (generate_empty_matrix(&A,MATRIX_SIZE) < 0)
	{
		printf("generate_empty_matrix() failed...\n");
		exit(-1);

	}

	printf("generate_empty_matrix() done...\n");

	X = (double*) malloc(MATRIX_SIZE*sizeof(double));
	X_old = (double*) malloc(MATRIX_SIZE*sizeof(double));
	if(X == NULL || X_old == NULL)
	{
		printf("X or X_old is NULL...\n");
		exit(-1);
	}

	for(i=0; i<MATRIX_SIZE; i++) 
	{
		X[i] = ((double)rand()) / ((double)RAND_MAX) * 10.0;
		X_old[i] = 0.0;
	}

	printf("start calculation...\n");

	iter_start = 0;
	iter_end = MATRIX_SIZE;

	start = clock();

	while(1) 
	{
		iterations++;
	
		temp = X_old;
		X_old = X;
		X = temp;

		for (i=iter_start; i<iter_end; i++) 
		{	
			for(j=0, xi=0.0; j<i; j++)
				xi += A[i][j] * X_old[j];

			for(j=i+1; j<MATRIX_SIZE; j++)
				xi += A[i][j] * X_old[j];
			X[i] = (A[i][MATRIX_SIZE] - xi) / A[i][i];
		}

		if (iterations % 5000 == 0 ) {/* calculate the Euclidean norm between X_old and X*/
			norm = 0.0;
			for (i=iter_start; i<iter_end; i++)
				norm += (X_old[i] - X[i]) * (X_old[i] - X[i]);

			/* check the break condition */
			norm /= (double) MATRIX_SIZE;		
			if (norm < 0.0000001)
				break;
		}
	}

	end = clock();
	
	if (MATRIX_SIZE < 16) {
		printf("Print the solution...\n");
		/* print solution */
		for(i=0; i<MATRIX_SIZE; i++) {
			for(j=0; j<MATRIX_SIZE; j++) 
				printf("%8.2f\t", A[i][j]);
			printf("*\t%8.2f\t=\t%8.2f\n", X[i], A[i][MATRIX_SIZE]);
		}
	}
	printf("Check the result...\n");

	/* 
	 * check the result 
	 * X[i] have to be 1
	 */
	for(i=0; i<MATRIX_SIZE; i++) {
		error = fabs(X[i] - 1.0f);

		if (max < error)
			max = error;
		if (error > 0.01f) {
			printf("Result is on position %d wrong (%f != 1.0)\n", i, X[i]);
			exit(1);
		}
	}
	printf("maximal error is %f\n", max);

	printf("\nmatrix size: %d x %d\n", MATRIX_SIZE, MATRIX_SIZE);
	printf("number of iterations: %d\n", iterations);
	printf("calculation time: %f s\n", (float) (end-start) / (float) CLOCKS_PER_SEC);

	free((void*) X_old);
	free((void*) X);

	return 0;
}
add jacobi solver as example program 2011-04-19 20:18:38 +02:00			`/*`
remove bug in the calulation of the break condition 2011-04-20 20:41:51 +02:00			`* Copyright 2010-2011 Stefan Lankes`
			`* Chair for Operating Systems, RWTH Aachen University`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00			`*`
			`* 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.`
			`*`
			`*/`

			`#include <stdio.h>`
			`#include <stdlib.h>`
			`#include <string.h>`
			`#include <math.h>`
			`#include <time.h>`
			`#include <unistd.h>`
			`#include <errno.h>`

remove bug in the calulation of the break condition 2011-04-20 20:41:51 +02:00			`#define MATRIX_SIZE 128`
			`#define MAXVALUE 1337`
			`#define PAGE_SIZE 4096`
			`#define CACHE_SIZE (256*1024)`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00			`#define ALIGN(x,a) (((x)+(a)-1)&~((a)-1))`

			`static int generate_empty_matrix(double*** A , unsigned int N) {`
			`unsigned int iCnt;`
			`int i,j;`

			`A = (double) malloc((N+1)sizeof(double*));`

			`if (*A == NULL)`
			`return -2; /* Error */`

			`(A)[0] = (double) malloc((N+1)Nsizeof(double));`

			`if (**A == NULL)`
			`return -2; /* Error */`

			`for(iCnt=1; iCnt<N; iCnt++) { /* Assign pointers in the first "real index"; Value from 1 to N (0 yet set, value N means N+1) */`
			`(A)[iCnt] = &((A)[0][iCnt*(N+1)]);`
			`}`

			`memset(*A, 0, (N+1)Nsizeof(double)); / Fill matrix values with 0 */`

			`srand( 42 /(unsigned) time(NULL)/ ) ; /* init random number generator */`

			`/*`
			`* initialize the system of linear equations`
			`* the result vector is one`
			`*/`
			`for (i = 0; i < N; i++)`
			`{`
			`double sum = 0.0;`

			`for (j = 0; j < N; j++)`
			`{`
			`if (i != j)`
			`{`
			`double c = ((double)rand()) / ((double)RAND_MAX) * MAXVALUE;`

			`sum += fabs(c);`
			`(*A)[i][j] = c;`
			`(*A)[i][N] += c;`
			`}`
			`}`

			`/*`
			`* The Jacobi method will always converge if the matrix A is strictly or irreducibly diagonally dominant.`
			`* Strict row diagonal dominance means that for each row, the absolute value of the diagonal term is`
			`* greater than the sum of absolute values of other terms: \|A[i][i]\| > Sum \|A[i][j]\| with (i != j)`
			`*/`

			`(*A)[i][i] = sum + 2.0;`
			`(*A)[i][N] += sum + 2.0;`
			`}`

			`return 0;`
			`}`

			`int main(int argc, char **argv)`
			`{`
remove bug in the calulation of the break condition 2011-04-20 20:41:51 +02:00			`double* temp;`
			`unsigned int i, j, iter_start, iter_end;`
			`unsigned int iterations = 0;`
			`double error, norm, max = 0.0;`
			`double** A=0;`
			`double* X;`
			`double* X_old, xi;`
add rudimental support of the system call times - no full support of the POSIX API - however, the libc function clock works correctly 2011-04-21 10:13:58 +02:00			`clock_t start, end;`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00
			`if (generate_empty_matrix(&A,MATRIX_SIZE) < 0)`
			`{`
			`printf("generate_empty_matrix() failed...\n");`
			`exit(-1);`

			`}`

			`printf("generate_empty_matrix() done...\n");`

remove bug in the calulation of the break condition 2011-04-20 20:41:51 +02:00			`X = (double) malloc(MATRIX_SIZEsizeof(double));`
			`X_old = (double) malloc(MATRIX_SIZEsizeof(double));`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00			`if(X == NULL \|\| X_old == NULL)`
			`{`
			`printf("X or X_old is NULL...\n");`
			`exit(-1);`
			`}`

			`for(i=0; i<MATRIX_SIZE; i++)`
			`{`
			`X[i] = ((double)rand()) / ((double)RAND_MAX) * 10.0;`
			`X_old[i] = 0.0;`
			`}`

			`printf("start calculation...\n");`

			`iter_start = 0;`
			`iter_end = MATRIX_SIZE;`

add rudimental support of the system call times - no full support of the POSIX API - however, the libc function clock works correctly 2011-04-21 10:13:58 +02:00			`start = clock();`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00
			`while(1)`
			`{`
			`iterations++;`

			`temp = X_old;`
			`X_old = X;`
			`X = temp;`

			`for (i=iter_start; i<iter_end; i++)`
			`{`
			`for(j=0, xi=0.0; j<i; j++)`
remove bug in the calulation of the break condition 2011-04-20 20:41:51 +02:00			`xi += A[i][j] * X_old[j];`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00
			`for(j=i+1; j<MATRIX_SIZE; j++)`
			`xi += A[i][j] * X_old[j];`
			`X[i] = (A[i][MATRIX_SIZE] - xi) / A[i][i];`
			`}`

			`if (iterations % 5000 == 0 ) {/* calculate the Euclidean norm between X_old and X*/`
remove bug in the calulation of the break condition 2011-04-20 20:41:51 +02:00			`norm = 0.0;`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00			`for (i=iter_start; i<iter_end; i++)`
			`norm += (X_old[i] - X[i]) * (X_old[i] - X[i]);`

			`/* check the break condition */`
remove bug in the calulation of the break condition 2011-04-20 20:41:51 +02:00			`norm /= (double) MATRIX_SIZE;`
			`if (norm < 0.0000001)`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00			`break;`
			`}`
			`}`

add rudimental support of the system call times - no full support of the POSIX API - however, the libc function clock works correctly 2011-04-21 10:13:58 +02:00			`end = clock();`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00
			`if (MATRIX_SIZE < 16) {`
			`printf("Print the solution...\n");`
			`/* print solution */`
			`for(i=0; i<MATRIX_SIZE; i++) {`
			`for(j=0; j<MATRIX_SIZE; j++)`
			`printf("%8.2f\t", A[i][j]);`
			`printf("*\t%8.2f\t=\t%8.2f\n", X[i], A[i][MATRIX_SIZE]);`
			`}`
			`}`
			`printf("Check the result...\n");`

			`/*`
			`* check the result`
			`* X[i] have to be 1`
			`*/`
			`for(i=0; i<MATRIX_SIZE; i++) {`
			`error = fabs(X[i] - 1.0f);`

			`if (max < error)`
			`max = error;`
Added changes to the user space apps hello.c and jacobi.c to make them return something not equal 0 if there was some kind of error. 2012-09-16 16:43:40 +02:00			`if (error > 0.01f) {`
			`printf("Result is on position %d wrong (%f != 1.0)\n", i, X[i]);`
			`exit(1);`
			`}`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00			`}`
			`printf("maximal error is %f\n", max);`

			`printf("\nmatrix size: %d x %d\n", MATRIX_SIZE, MATRIX_SIZE);`
			`printf("number of iterations: %d\n", iterations);`
add rudimental support of the system call times - no full support of the POSIX API - however, the libc function clock works correctly 2011-04-21 10:13:58 +02:00			`printf("calculation time: %f s\n", (float) (end-start) / (float) CLOCKS_PER_SEC);`
add jacobi solver as example program 2011-04-19 20:18:38 +02:00
			`free((void*) X_old);`
			`free((void*) X);`

			`return 0;`
			`}`