/* nag_opt_nlp_solve (e04wdc) Example Program. * * Copyright 2004 Numerical Algorithms Group. * * Mark 8, 2004. */ #include #include #include #include #ifdef __cplusplus extern "C" { #endif static void NAG_CALL confun(Integer *mode, Integer ncnln, Integer n, Integer ldcj, const Integer needc[], const double x[], double ccon[], double cjac[], Integer nstate, Nag_Comm *comm); static void NAG_CALL objfun(Integer *mode, Integer n, const double x[], double *objf, double grad[], Integer nstate, Nag_Comm *comm); #ifdef __cplusplus } #endif int main(void) { /* Scalars */ double objf; Integer exit_status, i, j, majits, n, nclin, ncnln, nctotal, pda, pdcj, pdh; /* Arrays */ double *a = 0, *bl = 0, *bu = 0, *ccon = 0, *cjac = 0, *clamda = 0; double *grad = 0, *h = 0, *x = 0; Integer *istate = 0; /* Nag Types */ Nag_E04State state; NagError fail; Nag_Comm comm; Nag_FileID fileid; #define A(I, J) a[(I-1)*pda + J - 1] exit_status = 0; INIT_FAIL(fail); printf("nag_opt_nlp_solve (e04wdc) Example Program Results\n"); /* Skip heading in data file */ scanf("%*[^\n] "); scanf("%ld%ld%ld%*[^\n] ", &n, &nclin, &ncnln); if (n > 0 && nclin >= 0 && ncnln >= 0) { /* Allocate memory */ nctotal = n + nclin + ncnln; if (!(a = NAG_ALLOC(nclin*n, double)) || !(bl = NAG_ALLOC(nctotal, double)) || !(bu = NAG_ALLOC(nctotal, double)) || !(ccon = NAG_ALLOC(ncnln, double)) || !(cjac = NAG_ALLOC(ncnln*n, double)) || !(clamda = NAG_ALLOC(nctotal, double)) || !(grad = NAG_ALLOC(n, double)) || !(h = NAG_ALLOC(n*n, double)) || !(x = NAG_ALLOC(n, double)) || !(istate = NAG_ALLOC(nctotal, Integer))) { printf("Allocation failure\n"); exit_status = -1; goto END; } pda = n; pdcj = n; pdh = n; /* Read a, bl, bu and x from data file */ if (nclin > 0) { for (i = 1; i <= nclin; ++i) { for (j = 1; j <= n; ++j) { scanf("%lf", &A(i, j)); } } scanf("%*[^\n] "); } for (i = 1; i <= n+nclin+ncnln; ++i) { scanf("%lf", &bl[i - 1]); } scanf("%*[^\n] "); for (i = 1; i <= n+nclin+ncnln; ++i) { scanf("%lf", &bu[i - 1]); } scanf("%*[^\n] "); for (i = 1; i <= n; ++i) { scanf("%lf", &x[i - 1]); } scanf("%*[^\n] "); /* nag_opt_nlp_init (e04wcc). * Initialization function for nag_opt_nlp_solve (e04wdc) */ nag_opt_nlp_init(&state, &fail); if (fail.code != NE_NOERROR) { printf( "Initialisation of nag_opt_nlp_init (e04wcc) failed.\n%s\n", fail.message); exit_status = 1; goto END; } /* By default nag_opt_nlp_solve (e04wdc) does not print monitoring * information. Call nag_open_file (x04acc) to set the print file fileid. */ /* nag_open_file (x04acc). * Open unit number for reading, writing or appending, and * associate unit with named file */ nag_open_file("", 2, &fileid, &fail); if (fail.code != NE_NOERROR) { exit_status = 2; goto END; } /* nag_opt_nlp_option_set_integer (e04wgc). * Set a single option for nag_opt_nlp_solve (e04wdc) from * an integer argument */ fflush(stdout); nag_opt_nlp_option_set_integer("Print file", fileid, &state, &fail); /* Solve the problem. */ /* nag_opt_nlp_solve (e04wdc). * Solves the nonlinear programming (NP) problem */ nag_opt_nlp_solve(n, nclin, ncnln, pda, pdcj, pdh, a, bl, bu, confun, objfun, &majits, istate, ccon, cjac, clamda, &objf, grad, h, x, &state, &comm, &fail); if (fail.code == NE_NOERROR) { printf("\n\nFinal objective value = %11.3f\n", objf); printf("Optimal X = "); for (i = 1; i <= n; ++i) { printf("%9.2f%s", x[i - 1], i%7 == 0 || i == n?"\n":" "); } } else { printf( "Error message from nag_opt_nlp_solve (e04wdc).\n%s\n", fail.message); exit_status = 1; goto END; } if (fail.code != NE_NOERROR) { exit_status = 2; } } END: if (a) NAG_FREE(a); if (bl) NAG_FREE(bl); if (bu) NAG_FREE(bu); if (ccon) NAG_FREE(ccon); if (cjac) NAG_FREE(cjac); if (clamda) NAG_FREE(clamda); if (grad) NAG_FREE(grad); if (h) NAG_FREE(h); if (x) NAG_FREE(x); if (istate) NAG_FREE(istate); return exit_status; } #undef A static void NAG_CALL objfun(Integer *mode, Integer n, const double x[], double *objf, double grad[], Integer nstate, Nag_Comm *comm) { /* Routine to evaluate objective function and its 1st derivatives. */ /* Function Body */ if (*mode == 0 || *mode == 2) { *objf = x[0] * x[3] * (x[0] + x[1] + x[2]) + x[2]; } if (*mode == 1 || *mode == 2) { grad[0] = x[3] * (x[0] * 2. + x[1] + x[2]); grad[1] = x[0] * x[3]; grad[2] = x[0] * x[3] + 1.; grad[3] = x[0] * (x[0] + x[1] + x[2]); } return; } /* objfun */ static void NAG_CALL confun(Integer *mode, Integer ncnln, Integer n, Integer pdcj, const Integer needc[], const double x[], double ccon[], double cjac[], Integer nstate, Nag_Comm *comm) { /* Scalars */ Integer i, j; #define CJAC(I, J) cjac[(I-1)*pdcj + J-1] /* Routine to evaluate the nonlinear constraints and their 1st */ /* derivatives. */ /* Function Body */ if (nstate == 1) { /* First call to confun. Set all Jacobian elements to zero. */ /* Note that this will only work when 'Derivative Level = 3' */ /* (the default; see Section 11.2). */ for (j = 1; j <= n; ++j) { for (i = 1; i <= ncnln; ++i) { CJAC(i, j) = 0.; } } } if (needc[0] > 0) { if (*mode == 0 || *mode == 2) { ccon[0] = x[0] * x[0] + x[1] * x[1] + x[2] * x[2] + x[3] * x[3]; } if (*mode == 1 || *mode == 2) { CJAC(1, 1) = x[0] * 2.; CJAC(1, 2) = x[1] * 2.; CJAC(1, 3) = x[2] * 2.; CJAC(1, 4) = x[3] * 2.; } } if (needc[1] > 0) { if (*mode == 0 || *mode == 2) { ccon[1] = x[0] * x[1] * x[2] * x[3]; } if (*mode == 1 || *mode == 2) { CJAC(2, 1) = x[1] * x[2] * x[3]; CJAC(2, 2) = x[0] * x[2] * x[3]; CJAC(2, 3) = x[0] * x[1] * x[3]; CJAC(2, 4) = x[0] * x[1] * x[2]; } } return; } /* confun */ #undef CJAC