int main(int argc, char **argv)
{
int termcode;
mpp_problem *mpp;
sym_environment *env = sym_open_environment();
sym_version();
CALL_FUNCTION( sym_get_user_data(env, (void **)&mpp) );
CALL_FUNCTION( sym_parse_command_line(env, argc, argv) );
if(mpp->par.test){
mpp_test(env);
} else {
CALL_FUNCTION( sym_load_problem(env) );
CALL_FUNCTION( sym_find_initial_bounds(env) );
CALL_FUNCTION( sym_solve(env) );
}
CALL_FUNCTION( sym_close_environment(env) );
return(0);
}
int main(int argc, char **argv)
{
sym_environment *env = sym_open_environment();
sym_parse_command_line(env, argc, argv);
sym_load_problem(env);
sym_set_int_param(env, "sensitivity_analysis", TRUE);
sym_solve(env);
int ind[2];
double val[2];
ind[0] = 4; val[0] = 0;
ind[1] = 7; val[1] = 0;
double lb = 0.0, ub =0.0;
sym_get_lb_for_new_rhs(env, 2, ind, val, &lb);
// sym_get_ub_for_new_rhs(env, 2, ind, val, &ub);
printf("\nBounds for the new rhs:\n lb: %f\n ub: %f \n\n", lb, ub);
sym_close_environment(env);
return(0);
}
int main(int argc, char **argv)
{
sym_environment *env = sym_open_environment();
sym_parse_command_line(env, argc, argv);
sym_load_problem(env);
sym_set_int_param(env, "keep_warm_start", true);
sym_set_int_param(env, "find_first_feasible", true);
/* set node selection rule to DEPTH_FIRST_SEARCH */
sym_set_int_param(env, "node_selection_rule", 3);
sym_solve(env);
sym_set_int_param(env, "find_first_feasible", true);
/* set node selection rule to BEST_FIRST_SEARCH */
sym_set_int_param(env, "node_selection_rule", 4);
sym_warm_solve(env);
sym_close_environment(env);
return(0);
}
int main(int argc, char **argv)
{
int num_solutions, num_cols, i;
double *sol, objval;
sym_environment *env = sym_open_environment();
sym_parse_command_line(env, argc, argv);
sym_load_problem(env);
sym_solve(env);
sym_get_num_cols(env, &num_cols);
sym_get_sp_size(env, &num_solutions);
sol = (double *) malloc(num_cols*sizeof(double));
for (i = 0; i < num_solutions; i++){
sym_get_sp_solution(env, i, sol, &objval);
printf("Solution of value %f found\n", objval);
}
free(sol);
sym_close_environment(env);
return(0);
}
int main(int argc, char **argv)
{
sym_environment *env = sym_open_environment();
warm_start_desc * ws;
sym_parse_command_line(env, argc, argv);
sym_load_problem(env);
sym_set_int_param(env, "keep_warm_start", TRUE);
sym_set_int_param(env, "node_limit", -1);
sym_set_int_param(env, "do_reduced_cost_fixing", 0);
sym_solve(env);
ws = sym_get_warm_start(env, true);
sym_set_int_param(env, "node_limit", 1000);
sym_warm_solve(env);
sym_set_obj_coeff(env, 0, 1);
sym_set_obj_coeff(env, 200, 150);
sym_set_warm_start(env, ws);
sym_warm_solve(env);
sym_close_environment(env);
return(0);
}
int mpp_test(sym_environment *env)
{
int termcode, i, file_num = 1;
char input_files[2][MAX_FILE_NAME_LENGTH +1] = {"sample.mpp"};
double sol[1] = {70.00};
char *input_dir = (char*)malloc(CSIZE*(MAX_FILE_NAME_LENGTH+1));
char *infile = (char*)malloc(CSIZE*(MAX_FILE_NAME_LENGTH+1));
double *obj_val = (double *)calloc(DSIZE,file_num);
double tol = 1e-03;
mpp_problem *mpp = (mpp_problem *) env->user;
if (strcmp(mpp->par.test_dir, "") == 0){
strcpy(input_dir, ".");
} else{
strcpy(input_dir, mpp->par.test_dir);
}
sym_set_int_param(env, "verbosity", -10);
for(i = 0; i<file_num; i++){
strcpy(infile, "");
sprintf(infile, "%s%s%s", input_dir, "/", input_files[i]);
strcpy(mpp->par.infile, infile);
CALL_FUNCTION( sym_load_problem(env) );
printf("Solving %s...\n", input_files[i]);
CALL_FUNCTION( sym_solve(env) );
sym_get_obj_val(env, &obj_val[i]);
if((obj_val[i] < sol[i] + tol) &&
(obj_val[i] > sol[i] - tol)){
printf("Success!\n");
} else {
printf("Failure!(%f, %f) \n", obj_val[i], sol[i]);
}
if(env->mip->n && i + 1 < file_num){
free_master_u(env);
strcpy(env->par.infile, "");
env->mip = (MIPdesc *) calloc(1, sizeof(MIPdesc));
}
}
mpp->par.test = FALSE;
FREE(input_dir);
FREE(infile);
FREE(obj_val);
return(0);
}
int main(int argc, char **argv)
{
sym_environment *env = sym_open_environment();
sym_parse_command_line(env, argc, argv);
sym_load_problem(env);
sym_set_obj2_coeff(env, 1, -1);
sym_mc_solve(env);
sym_close_environment(env);
return(0);
}
int main(int argc, char **argv)
{
#if USE_VRPH
// A few things required by VRPH
int i;
double best_sol=VRP_INFINITY;
int best_sol_buff[500];
#endif
vrp_problem *vrp;
sym_environment *env = sym_open_environment();
version();
sym_parse_command_line(env, argc, argv);
sym_get_user_data(env, (void**)&vrp);
#if USE_VRPH
// Get the size of the problem in the input file
int n=VRPGetDimension(vrp->par.infile);
// Declare a VRP object of size n
VRP V(n);
// Declare a ClarkeWright object of size n
ClarkeWright CW(n);
// Populate the VRP object with the input file
V.read_TSPLIB_file(vrp->par.infile);
// Now create NUM_VRPH_SOLUTIONS solutions using VRPH and set the
// upper bound to the best solution discovered
for(i=0;i<NUM_VRPH_SOLUTIONS;i++)
{
// Create default routes - each customer on its own route
V.create_default_routes();
// Create a new random feasible solution with Clarke Wright
CW.Construct(&V, .5+ lcgrand(1),false);
// Improve it with the RTR heuristic
V.RTR_solve(ONE_POINT_MOVE+TWO_POINT_MOVE+TWO_OPT+THREE_OPT,
30,5,1,.01,25,VRPH_LI_PERTURB,VRPH_BEST_ACCEPT,false);
if(V.get_total_route_length()-V.get_total_service_time()<best_sol)
{
best_sol=V.get_total_route_length()-V.get_total_service_time();
V.export_canonical_solution_buff(best_sol_buff);
}
// Reset VRPH's internal data structures
V.reset();
}
// Import the best solution and display it - if SYMPHONY claims an infeasibility
// because the VRPH solution is optimal, we wouldn't see it otherwise!
printf("VRPH set SYMPHONY upper bound to %f based on solution:\n",best_sol);
V.import_solution_buff(best_sol_buff);
V.summary();
// Set the upper bound using VRPH solution by accessing SYMPHONY's
// internal data structures
env->has_ub=1;
env->ub=best_sol ;
#if 0
// Note that this might be incorrect if the VRPH solution is not optimal
// So the # of trucks still needs to be passed in on the command line!
vrp->numroutes=V.get_total_number_of_routes();
#endif
#endif
// Now just let SYMPHONY do its thing. If an infeasibility is encountered,
// then this certifies that the solution found by VRPH is indeed optimal
// Note that the par.test will not work as we have processed only a single
// file. Thus, we changed the following line
// if (vrp->par.test){
if (0 && vrp->par.test){
vrp_test(env, argc, argv);
} else {
sym_load_problem(env);
sym_find_initial_bounds(env);
sym_set_str_param(env, "lp_executable_name", "vrp_lp_cg");
sym_set_str_param(env, "cp_executable_name", "vrp_cp");
sym_set_int_param(env, "generate_cgl_cuts", FALSE);
sym_solve(env);
}
sym_close_environment(env);
return(0);
}
int vrp_test(sym_environment *env, int argc, char **argv)
{
int termcode, i, file_num = 34;
char input_files[34][MAX_FILE_NAME_LENGTH +1] = {"A/A-n34-k5",
"A/A-n32-k5",
"A/A-n33-k5",
"E/E-n13-k4",
"E/E-n22-k4",
"E/E-n23-k3",
"E/E-n30-k3",
"E/E-n33-k4",
"V/att-n48-k4",
"E/E-n51-k5",
"A/A-n33-k6",
"A/A-n36-k5",
"A/A-n37-k5",
"A/A-n38-k5",
"A/A-n39-k5",
"A/A-n39-k6",
"A/A-n45-k6",
"A/A-n46-k7",
"B/B-n31-k5",
"B/B-n34-k5",
"B/B-n35-k5",
"B/B-n38-k6",
"B/B-n39-k5",
"B/B-n41-k6",
"B/B-n43-k6",
"B/B-n44-k7",
"B/B-n45-k5",
"B/B-n50-k7",
"B/B-n51-k7",
"B/B-n52-k7",
"B/B-n56-k7",
"B/B-n64-k9",
"A/A-n48-k7",
"A/A-n53-k7"};
double sol[34] = {778, 784, 661, 247, 375, 569, 534, 835, 40002, 521, 742,
799, 669, 730, 822, 831, 944, 914, 672, 788, 955, 805,
549, 829, 742, 909, 751, 741, 1032, 747, 707, 861,
1073, 1010};
char *input_dir = (char*)malloc(CSIZE*(MAX_FILE_NAME_LENGTH+1));
char *infile = (char*)malloc(CSIZE*(MAX_FILE_NAME_LENGTH+1));
char *sgfile = (char*)malloc(CSIZE*(MAX_FILE_NAME_LENGTH+1));
double *obj_val = (double *)calloc(DSIZE,file_num);
double tol = 1e-06, ub;
vrp_problem *vrp = (vrp_problem *) env->user;
if (strcmp(vrp->par.test_dir, "") == 0){
strcpy(input_dir, "../../../VRPLIB");
} else{
strcpy(input_dir, vrp->par.test_dir);
}
for(i = 0; i<file_num; i++){
strcpy(infile, "");
strcpy(sgfile, "");
sprintf(infile, "%s%s%s%s", input_dir, "/", input_files[i], ".vrp");
sprintf(sgfile, "%s%s%s", "./small_graph/", input_files[i], ".sg");
strcpy(vrp->par.infile, infile);
strcpy(vrp->par.small_graph_file, sgfile);
vrp->par.use_small_graph = LOAD_SMALL_GRAPH;
sym_load_problem(env);
sym_find_initial_bounds(env);
printf("Solving %s...\n", input_files[i]);
sym_solve(env);
sym_get_obj_val(env, &obj_val[i]);
if((obj_val[i] < sol[i] + tol) &&
(obj_val[i] > sol[i] - tol)){
printf("Success!\n");
} else {
printf("Failure!(%f, %f) \n", obj_val[i], sol[i]);
}
if(i+1 < file_num){
sym_close_environment(env);
env = sym_open_environment();
sym_parse_command_line(env, argc, argv);
}
}
return (0);
}