int main() { int L1 = 500, L2=500, n; /*printf("Enter the number of sensor nodes\n"); scanf("%d", &n); */ n=600; FILE *fp2; fp2=fopen("deployment_201506511.txt", "w"); if(fp2==NULL) { perror("Error opening file."); } FILE *fp1; fp1=fopen("name.gp", "w"); char string[10000] = "plot[0:500][0:500] \""; strcat(string, "deployment_201506511.txt"); strcat(string, "\" every ::1 using 1:2"); fprintf(fp1,"%s", string); fclose(fp1); generating_random_numbers(n, fp2); finding_neighbour_sensor_nodes(n); //printing_neighbour_list(n); //Finding primitive root of Finite Field GF(q) where q is large prime int k=4; long long int primitive_root_g, q; bool value = false; while(value!=true) { q = oddrand(1, 10000); value = isPrime(q, k); if(value==true) { primitive_root_g=finding_primitive_root(q); } } printf("Primitie Root: %lld, Prime Number: %lld\n", primitive_root_g, q); creation_of_matrixG(primitive_root_g, 600, q); // printing_matrixG(matrix_G, 600, 100); matrix_D_generation(100, q); multiply_matrics_matrix_Dmatrix_G(100, 600, q); creation_of_matrixK_multiplyAG(100, 600, q); system("gnuplot -p 'name.gp'"); return 0; }
int main( int argc, char *argv[] ) { if(argc==4) { printf("Enter the no of sensor nodes\n"); int argument_2,argument_3; char argument_1[100],string[10000]="plot[0:500][0:500] \""; memset(argument_1, '\0', sizeof(argument_1)); strcpy(argument_1,argv[1]); strcat(string, argument_1); strcat(string, "\" every ::1 using 1:2"); scanf("%d",&n); FILE *fp1; fp1=fopen("kalpish", "w"); fprintf(fp1,"%s", string); fclose(fp1); //fprintf(fp1,"%s", string); FILE *fp; fp=fopen(argument_1, "w"); if(fp==NULL) { perror("Error opening file."); } argument_2=atoi(argv[2]); argument_3=atoi(argv[3]); generating_random_numbers(argument_2,fp,argument_3); finding_physical_and_key_neighbours(argument_2); //printing_sensor_nodes(argument_2); simulating_path_key_establishment(argument_2,argument_3); finding_network_connectivity(argument_2,argument_3); } else { printf("invalid number of arguments\n"); exit(0); } system("gnuplot -p 'kalpish'"); }
int main() { int L1 = 500, L2=500; FILE *fp2; fp2=fopen("deployment_201506511.txt", "w"); if(fp2==NULL) { perror("Error opening file."); } FILE *fp1; fp1=fopen("name.gp", "w"); char string[10000] = "plot[0:500][0:500] \""; strcat(string, "deployment_201506511.txt"); strcat(string, "\" every ::1 using 1:2"); fprintf(fp1,"%s", string); fclose(fp1); generating_random_numbers(totalnodes, fp2); finding_neighbour_sensor_nodes(totalnodes); //printing_neighbour_list(n); //Finding primitive root of Finite Field GF(q) where q is large prime int k=10; long long int primitive_root_g, q; bool value = false; while(value!=true) { q = oddrand(qmin, qmax); value = isPrime(q, k); if(value==true) { primitive_root_g=finding_primitive_root(q); } } printf("Primitie Root Genarated : %lld, For Prime Number: %lld\n", primitive_root_g, q); creation_of_matrixG(primitive_root_g, totalnodes, q); printing_matrixG(matrix_G, 600, 100); matrix_D_generation(lambda_value, q); multiply_matrics_matrix_Dmatrix_G(lambda_value, totalnodes, q); creation_of_matrixK_multiplyAG(lambda_value, totalnodes, q); //Writing NEIGHBOUR LIST TO FILE FILE *fp3; fp3=fopen("keys.txt", "w"); int i, j; fprintf(fp3, "Physical Neighout List of Sensor Nodes\n"); for(i=0; i<totalnodes; i++) { fprintf(fp3, "NL%d : ", i); for(j=0; j<sensor_node[i].neighbour_size; j++) { fprintf(fp3, "%d ", sensor_node[i].phynbr[j]); } fprintf(fp3, "\n"); } fprintf(fp3, "\n"); fprintf(fp3, "Key Neighbours : Key(i,j) of Sensor Nodes\n"); for(i=0; i<totalnodes; i++) { fprintf(fp3, "Key(i,j) %d : ", i); for(j=0; j<sensor_node[i].neighbour_size; j++) { fprintf(fp3, "%lld ", matrix_K[i][sensor_node[i].phynbr[j]]); } fprintf(fp3, "\n"); } fclose(fp3); system("gnuplot -p 'name.gp'"); return 0; }