Exemple #1
0
void xfree(void *ptr)
{     LIBENV *env = lib_link_env();
      LIBMEM *desc;
      int size_of_desc = align_datasize(sizeof(LIBMEM));
      if (ptr == NULL)
         xfault("xfree: ptr = %p; null pointer\n", ptr);
      desc = (void *)((char *)ptr - size_of_desc);
      if (desc->flag != LIB_MEM_FLAG)
         xfault("xfree: ptr = %p; invalid pointer\n", ptr);
      if (env->mem_count == 0 ||
          ulcmp(env->mem_total, ulset(0, desc->size)) < 0)
         xfault("xfree: memory allocation error\n");
      if (desc->prev == NULL)
         env->mem_ptr = desc->next;
      else
         desc->prev->next = desc->next;
      if (desc->next == NULL)
         ;
      else
         desc->next->prev = desc->prev;
      env->mem_count--;
      env->mem_total = ulsub(env->mem_total, ulset(0, desc->size));
      memset(desc, '?', size_of_desc);
      free(desc);
      return;
}
Exemple #2
0
void *xmalloc(int size)
{     LIBENV *env = lib_link_env();
      LIBMEM *desc;
      int size_of_desc = align_datasize(sizeof(LIBMEM));
      if (size < 1 || size > INT_MAX - size_of_desc)
         xfault("xmalloc: size = %d; invalid parameter\n", size);
      size += size_of_desc;
      if (ulcmp(ulset(0, size),
          ulsub(env->mem_limit, env->mem_total)) > 0)
         xfault("xmalloc: memory limit exceeded\n");
      if (env->mem_count == INT_MAX)
         xfault("xmalloc: too many memory blocks allocated\n");
      desc = malloc(size);
      if (desc == NULL)
         xfault("xmalloc: no memory available\n");
      memset(desc, '?', size);
      desc->flag = LIB_MEM_FLAG;
      desc->size = size;
      desc->prev = NULL;
      desc->next = env->mem_ptr;
      if (desc->next != NULL) desc->next->prev = desc;
      env->mem_ptr = desc;
      env->mem_count++;
      if (env->mem_cpeak < env->mem_count)
         env->mem_cpeak = env->mem_count;
      env->mem_total = uladd(env->mem_total, ulset(0, size));
      if (ulcmp(env->mem_tpeak, env->mem_total) < 0)
         env->mem_tpeak = env->mem_total;
      return (void *)((char *)desc + size_of_desc);
}
Exemple #3
0
void mpl_put_col_value(MPL *mpl, int j, double val)
{     if (mpl->phase != 3)
         xfault("mpl_put_col_value: invalid call sequence\n");
      if (!(1 <= j && j <= mpl->n))
         xfault(
         "mpl_put_col_value: j = %d; column number out of range\n", j);
      mpl->col[j]->prim = val;
      return;
}
Exemple #4
0
void *xcalloc(int n, int size)
{     if (n < 1)
         xfault("xcalloc: n = %d; invalid parameter\n", n);
      if (size < 1)
         xfault("xcalloc: size = %d; invalid parameter\n", size);
      if (n > INT_MAX / size)
         xfault("xcalloc: n = %d; size = %d; array too big\n", n, size);
      return xmalloc(n * size);
}
Exemple #5
0
int fhv_factorize(FHV *fhv, int m, int (*col)(void *info, int j,
      int ind[], double val[]), void *info)
{     int ret;
      if (m < 1)
         xfault("fhv_factorize: m = %d; invalid parameter\n", m);
      if (m > M_MAX)
         xfault("fhv_factorize: m = %d; matrix too big\n", m);
      fhv->m = m;
      /* invalidate the factorization */
      fhv->valid = 0;
      /* allocate/reallocate arrays, if necessary */
      if (fhv->hh_ind == NULL)
         fhv->hh_ind = xcalloc(1+fhv->hh_max, sizeof(int));
      if (fhv->hh_ptr == NULL)
         fhv->hh_ptr = xcalloc(1+fhv->hh_max, sizeof(int));
      if (fhv->hh_len == NULL)
         fhv->hh_len = xcalloc(1+fhv->hh_max, sizeof(int));
      if (fhv->m_max < m)
      {  if (fhv->p0_row != NULL) xfree(fhv->p0_row);
         if (fhv->p0_col != NULL) xfree(fhv->p0_col);
         if (fhv->cc_ind != NULL) xfree(fhv->cc_ind);
         if (fhv->cc_val != NULL) xfree(fhv->cc_val);
         fhv->m_max = m + 100;
         fhv->p0_row = xcalloc(1+fhv->m_max, sizeof(int));
         fhv->p0_col = xcalloc(1+fhv->m_max, sizeof(int));
         fhv->cc_ind = xcalloc(1+fhv->m_max, sizeof(int));
         fhv->cc_val = xcalloc(1+fhv->m_max, sizeof(double));
      }
      /* try to factorize the basis matrix */
      switch (luf_factorize(fhv->luf, m, col, info))
      {  case 0:
            break;
         case LUF_ESING:
            ret = FHV_ESING;
            goto done;
         case LUF_ECOND:
            ret = FHV_ECOND;
            goto done;
         default:
            xassert(fhv != fhv);
      }
      /* the basis matrix has been successfully factorized */
      fhv->valid = 1;
      /* H := I */
      fhv->hh_nfs = 0;
      /* P0 := P */
      memcpy(&fhv->p0_row[1], &fhv->luf->pp_row[1], sizeof(int) * m);
      memcpy(&fhv->p0_col[1], &fhv->luf->pp_col[1], sizeof(int) * m);
      /* currently H has no factors */
      fhv->nnz_h = 0;
      ret = 0;
done: /* return to the calling program */
      return ret;
}
Exemple #6
0
double mpl_get_row_c0(MPL *mpl, int i)
{     ELEMCON *con;
      double c0;
      if (mpl->phase != 3)
         xfault("mpl_get_row_c0: invalid call sequence\n");
      if (!(1 <= i && i <= mpl->m))
         xfault("mpl_get_row_c0: i = %d; row number out of range\n",
            i);
      con = mpl->row[i];
      if (con->con->lbnd == NULL && con->con->ubnd == NULL)
         c0 = - con->lbnd;
      else
         c0 = 0.0;
      return c0;
}
Exemple #7
0
void lpx_set_class(LPX *lp, int klass)
{     /* set problem class */
      xassert(lp == lp);
      if (!(klass == LPX_LP || klass == LPX_MIP))
         xfault("lpx_set_class: invalid problem class\n");
      return;
}
Exemple #8
0
LUX *lux_create(int n)
{     LUX *lux;
      int k;
      if (n < 1)
         xfault("lux_create: n = %d; invalid parameter\n", n);
      lux = xmalloc(sizeof(LUX));
      lux->n = n;
      lux->pool = dmp_create_poolx(sizeof(LUXELM));
      lux->F_row = xcalloc(1+n, sizeof(LUXELM *));
      lux->F_col = xcalloc(1+n, sizeof(LUXELM *));
      lux->V_piv = xcalloc(1+n, sizeof(mpq_t));
      lux->V_row = xcalloc(1+n, sizeof(LUXELM *));
      lux->V_col = xcalloc(1+n, sizeof(LUXELM *));
      lux->P_row = xcalloc(1+n, sizeof(int));
      lux->P_col = xcalloc(1+n, sizeof(int));
      lux->Q_row = xcalloc(1+n, sizeof(int));
      lux->Q_col = xcalloc(1+n, sizeof(int));
      for (k = 1; k <= n; k++)
      {  lux->F_row[k] = lux->F_col[k] = NULL;
         mpq_init(lux->V_piv[k]);
         mpq_set_si(lux->V_piv[k], 1, 1);
         lux->V_row[k] = lux->V_col[k] = NULL;
         lux->P_row[k] = lux->P_col[k] = k;
         lux->Q_row[k] = lux->Q_col[k] = k;
      }
      lux->rank = n;
      return lux;
}
/*******************************************************************************
* Function Name  : HardFault_Handler
* Description    : This function handles Hard Fault exception.
* Input          : None
* Output         : None
* Return         : None
*******************************************************************************/
void HardFault_Handler(void)
{
  xfault();
  /* Go to infinite loop when Hard Fault exception occurs */
  while (1)
  {
  }
}
Exemple #10
0
int mpl_get_mat_row(MPL *mpl, int i, int ndx[], double val[])
{     FORMULA *term;
      int len = 0;
      if (mpl->phase != 3)
         xfault("mpl_get_mat_row: invalid call sequence\n");
      if (!(1 <= i && i <= mpl->m))
         xfault("mpl_get_mat_row: i = %d; row number out of range\n",
            i);
      for (term = mpl->row[i]->form; term != NULL; term = term->next)
      {  xassert(term->var != NULL);
         len++;
         xassert(len <= mpl->n);
         if (ndx != NULL) ndx[len] = term->var->j;
         if (val != NULL) val[len] = term->coef;
      }
      return len;
}
/*******************************************************************************
* Function Name  : MemManage_Handler
* Description    : This function handles Memory Manage exception.
* Input          : None
* Output         : None
* Return         : None
*******************************************************************************/
void MemManage_Handler(void)
{
  xfault();
  /* Go to infinite loop when Memory Manage exception occurs */
  while (1)
  {
  }
}
Exemple #12
0
double rng_uniform(RNG *rand, double a, double b)
{     double x;
      if (a >= b)
         xfault("rng_uniform: a = %g, b = %g; invalid range\n", a, b);
      x = rng_unif_01(rand);
      x = a * (1.0 - x) + b * x;
      xassert(a <= x && x <= b);
      return x;
}
Exemple #13
0
void scf_solve_it(SCF *scf, int tr, double x[])
{     if (scf->rank < scf->n)
         xfault("scf_solve_it: singular matrix\n");
      if (!tr)
         solve(scf, x);
      else
         tsolve(scf, x);
      return;
}
Exemple #14
0
SSX *ssx_create(int m, int n, int nnz)
{     SSX *ssx;
      int i, j, k;
      if (m < 1)
         xfault("ssx_create: m = %d; invalid number of rows\n", m);
      if (n < 1)
         xfault("ssx_create: n = %d; invalid number of columns\n", n);
      if (nnz < 0)
         xfault("ssx_create: nnz = %d; invalid number of non-zero const"
            "raint coefficients\n", nnz);
      ssx = xmalloc(sizeof(SSX));
      ssx->m = m;
      ssx->n = n;
      ssx->type = xcalloc(1+m+n, sizeof(int));
      ssx->lb = xcalloc(1+m+n, sizeof(mpq_t));
      for (k = 1; k <= m+n; k++) mpq_init(ssx->lb[k]);
      ssx->ub = xcalloc(1+m+n, sizeof(mpq_t));
      for (k = 1; k <= m+n; k++) mpq_init(ssx->ub[k]);
      ssx->coef = xcalloc(1+m+n, sizeof(mpq_t));
      for (k = 0; k <= m+n; k++) mpq_init(ssx->coef[k]);
      ssx->A_ptr = xcalloc(1+n+1, sizeof(int));
      ssx->A_ptr[n+1] = nnz+1;
      ssx->A_ind = xcalloc(1+nnz, sizeof(int));
      ssx->A_val = xcalloc(1+nnz, sizeof(mpq_t));
      for (k = 1; k <= nnz; k++) mpq_init(ssx->A_val[k]);
      ssx->stat = xcalloc(1+m+n, sizeof(int));
      ssx->Q_row = xcalloc(1+m+n, sizeof(int));
      ssx->Q_col = xcalloc(1+m+n, sizeof(int));
      ssx->binv = bfx_create_binv();
      ssx->bbar = xcalloc(1+m, sizeof(mpq_t));
      for (i = 0; i <= m; i++) mpq_init(ssx->bbar[i]);
      ssx->pi = xcalloc(1+m, sizeof(mpq_t));
      for (i = 1; i <= m; i++) mpq_init(ssx->pi[i]);
      ssx->cbar = xcalloc(1+n, sizeof(mpq_t));
      for (j = 1; j <= n; j++) mpq_init(ssx->cbar[j]);
      ssx->rho = xcalloc(1+m, sizeof(mpq_t));
      for (i = 1; i <= m; i++) mpq_init(ssx->rho[i]);
      ssx->ap = xcalloc(1+n, sizeof(mpq_t));
      for (j = 1; j <= n; j++) mpq_init(ssx->ap[j]);
      ssx->aq = xcalloc(1+m, sizeof(mpq_t));
      for (i = 1; i <= m; i++) mpq_init(ssx->aq[i]);
      mpq_init(ssx->delta);
      return ssx;
}
Exemple #15
0
int mpl_read_model(MPL *mpl, char *file, int skip_data)
{     if (mpl->phase != 0)
         xfault("mpl_read_model: invalid call sequence\n");
      if (file == NULL)
         xfault("mpl_read_model: no input filename specified\n");
      /* set up error handler */
      if (setjmp(mpl->jump)) goto done;
      /* translate model section */
      mpl->phase = 1;
      xprintf("Reading model section from %s...\n", file);
      open_input(mpl, file);
      model_section(mpl);
      if (mpl->model == NULL)
         error(mpl, "empty model section not allowed");
      /* save name of the input text file containing model section for
         error diagnostics during the generation phase */
      mpl->mod_file = xcalloc(strlen(file)+1, sizeof(char));
      strcpy(mpl->mod_file, mpl->in_file);
      /* allocate content arrays for all model objects */
      alloc_content(mpl);
      /* optional data section may begin with the keyword 'data' */
      if (is_keyword(mpl, "data"))
      {  if (skip_data)
         {  warning(mpl, "data section ignored");
            goto skip;
         }
         mpl->flag_d = 1;
         get_token(mpl /* data */);
         if (mpl->token != T_SEMICOLON)
            error(mpl, "semicolon missing where expected");
         get_token(mpl /* ; */);
         /* translate data section */
         mpl->phase = 2;
         xprintf("Reading data section from %s...\n", file);
         data_section(mpl);
      }
      /* process end statement */
      end_statement(mpl);
skip: xprintf("%d line%s were read\n",
         mpl->line, mpl->line == 1 ? "" : "s");
      close_input(mpl);
done: /* return to the calling program */
      return mpl->phase;
}
Exemple #16
0
int mpl_get_col_kind(MPL *mpl, int j)
{     int kind;
      if (mpl->phase != 3)
         xfault("mpl_get_col_kind: invalid call sequence\n");
      if (!(1 <= j && j <= mpl->n))
         xfault("mpl_get_col_kind: j = %d; column number out of range\n"
            , j);
      switch (mpl->col[j]->var->type)
      {  case A_NUMERIC:
            kind = MPL_NUM; break;
         case A_INTEGER:
            kind = MPL_INT; break;
         case A_BINARY:
            kind = MPL_BIN; break;
         default:
            xassert(mpl != mpl);
      }
      return kind;
}
Exemple #17
0
int mpl_get_row_kind(MPL *mpl, int i)
{     int kind;
      if (mpl->phase != 3)
         xfault("mpl_get_row_kind: invalid call sequence\n");
      if (!(1 <= i && i <= mpl->m))
         xfault("mpl_get_row_kind: i = %d; row number out of range\n",
            i);
      switch (mpl->row[i]->con->type)
      {  case A_CONSTRAINT:
            kind = MPL_ST; break;
         case A_MINIMIZE:
            kind = MPL_MIN; break;
         case A_MAXIMIZE:
            kind = MPL_MAX; break;
         default:
            xassert(mpl != mpl);
      }
      return kind;
}
Exemple #18
0
int bfd_update_it(BFD *bfd, int j, int bh, int len, const int ind[],
      const double val[])
{     int ret;
      if (!bfd->valid)
         xfault("bfd_update_it: the factorization is not valid\n");
      /* try to update the factorization */
      if (bfd->fhv != NULL)
      {  switch (fhv_update_it(bfd->fhv, j, len, ind, val))
         {  case 0:
               break;
            case FHV_ESING:
               bfd->valid = 0;
               ret = BFD_ESING;
               goto done;
            case FHV_ECHECK:
               bfd->valid = 0;
               ret = BFD_ECHECK;
               goto done;
            case FHV_ELIMIT:
               bfd->valid = 0;
               ret = BFD_ELIMIT;
               goto done;
            case FHV_EROOM:
               bfd->valid = 0;
               ret = BFD_EROOM;
               goto done;
            default:
               xassert(bfd != bfd);
         }
      }
      else if (bfd->lpf != NULL)
      {  switch (lpf_update_it(bfd->lpf, j, bh, len, ind, val))
         {  case 0:
               break;
            case LPF_ESING:
               bfd->valid = 0;
               ret = BFD_ESING;
               goto done;
            case LPF_ELIMIT:
               bfd->valid = 0;
               ret = BFD_ELIMIT;
               goto done;
            default:
               xassert(bfd != bfd);
         }
      }
      else
         xassert(bfd != bfd);
      /* the factorization has been successfully updated */
      /* increase the update count */
      bfd->upd_cnt++;
      ret = 0;
done: /* return to the calling program */
      return ret;
}
Exemple #19
0
void lpf_btran(LPF *lpf, double x[])
{     int m0 = lpf->m0;
      int m = lpf->m;
      int n = lpf->n;
      int *P_row = lpf->P_row;
      int *Q_row = lpf->Q_row;
      double *fg = lpf->work1;
      double *f = fg;
      double *g = fg + m0;
      int i, ii;
#if GLPLPF_DEBUG
      double *b;
#endif
      if (!lpf->valid)
         xfault("lpf_btran: the factorization is not valid\n");
      xassert(0 <= m && m <= m0 + n);
#if GLPLPF_DEBUG
      /* save the right-hand side vector */
      b = xcalloc(1+m, sizeof(double));
      for (i = 1; i <= m; i++) b[i] = x[i];
#endif
      /* (f g) := Q * (b 0) */
      for (i = 1; i <= m0 + n; i++)
         fg[i] = ((ii = Q_row[i]) <= m ? x[ii] : 0.0);
      /* f1 := inv(U'0) * f */
#if 0 /* 06/VI-2013 */
      luf_v_solve(lpf->luf, 1, f);
#else
      {  double *work = lpf->lufint->sgf->work;
         luf_vt_solve(lpf->lufint->luf, f, work);
         memcpy(&f[1], &work[1], m0 * sizeof(double));
      }
#endif
      /* g1 := inv(C') * (g - R' * f1) */
      rt_prod(lpf, g, -1.0, f);
      scf_solve_it(lpf->scf, 1, g);
      /* g2 := g1 */
      g = g;
      /* f2 := inv(L'0) * (f1 - S' * g2) */
      st_prod(lpf, f, -1.0, g);
#if 0 /* 06/VI-2013 */
      luf_f_solve(lpf->luf, 1, f);
#else
      luf_ft_solve(lpf->lufint->luf, f);
#endif
      /* (x y) := P * (f2 g2) */
      for (i = 1; i <= m; i++)
         x[i] = fg[P_row[i]];
#if GLPLPF_DEBUG
      /* check relative error in solution */
      check_error(lpf, 1, x, b);
      xfree(b);
#endif
      return;
}
Exemple #20
0
void bfd_btran(BFD *bfd, double x[])
{     if (!bfd->valid)
         xfault("bfd_btran: the factorization is not valid\n");
      if (bfd->fhv != NULL)
         fhv_btran(bfd->fhv, x);
      else if (bfd->lpf != NULL)
         lpf_btran(bfd->lpf, x);
      else
         xassert(bfd != bfd);
      return;
}
Exemple #21
0
char *mpl_get_row_name(MPL *mpl, int i)
{     char *name = mpl->mpl_buf, *t;
      int len;
      if (mpl->phase != 3)
         xfault("mpl_get_row_name: invalid call sequence\n");
      if (!(1 <= i && i <= mpl->m))
         xfault("mpl_get_row_name: i = %d; row number out of range\n",
            i);
      strcpy(name, mpl->row[i]->con->name);
      len = strlen(name);
      xassert(len <= 255);
      t = format_tuple(mpl, '[', mpl->row[i]->memb->tuple);
      while (*t)
      {  if (len == 255) break;
         name[len++] = *t++;
      }
      name[len] = '\0';
      if (len == 255) strcpy(name+252, "...");
      xassert(strlen(name) <= 255);
      return name;
}
Exemple #22
0
char *mpl_get_col_name(MPL *mpl, int j)
{     char *name = mpl->mpl_buf, *t;
      int len;
      if (mpl->phase != 3)
         xfault("mpl_get_col_name: invalid call sequence\n");
      if (!(1 <= j && j <= mpl->n))
         xfault("mpl_get_col_name: j = %d; column number out of range\n"
            , j);
      strcpy(name, mpl->col[j]->var->name);
      len = strlen(name);
      xassert(len <= 255);
      t = format_tuple(mpl, '[', mpl->col[j]->memb->tuple);
      while (*t)
      {  if (len == 255) break;
         name[len++] = *t++;
      }
      name[len] = '\0';
      if (len == 255) strcpy(name+252, "...");
      xassert(strlen(name) <= 255);
      return name;
}
Exemple #23
0
int mpl_get_row_bnds(MPL *mpl, int i, double *_lb, double *_ub)
{     ELEMCON *con;
      int type;
      double lb, ub;
      if (mpl->phase != 3)
         xfault("mpl_get_row_bnds: invalid call sequence\n");
      if (!(1 <= i && i <= mpl->m))
         xfault("mpl_get_row_bnds: i = %d; row number out of range\n",
            i);
      con = mpl->row[i];
#if 0 /* 21/VII-2006 */
      if (con->con->lbnd == NULL && con->con->ubnd == NULL)
         type = MPL_FR, lb = ub = 0.0;
      else if (con->con->ubnd == NULL)
         type = MPL_LO, lb = con->lbnd, ub = 0.0;
      else if (con->con->lbnd == NULL)
         type = MPL_UP, lb = 0.0, ub = con->ubnd;
      else if (con->con->lbnd != con->con->ubnd)
         type = MPL_DB, lb = con->lbnd, ub = con->ubnd;
      else
         type = MPL_FX, lb = ub = con->lbnd;
#else
      lb = (con->con->lbnd == NULL ? -DBL_MAX : con->lbnd);
      ub = (con->con->ubnd == NULL ? +DBL_MAX : con->ubnd);
      if (lb == -DBL_MAX && ub == +DBL_MAX)
         type = MPL_FR, lb = ub = 0.0;
      else if (ub == +DBL_MAX)
         type = MPL_LO, ub = 0.0;
      else if (lb == -DBL_MAX)
         type = MPL_UP, lb = 0.0;
      else if (con->con->lbnd != con->con->ubnd)
         type = MPL_DB;
      else
         type = MPL_FX;
#endif
      if (_lb != NULL) *_lb = lb;
      if (_ub != NULL) *_ub = ub;
      return type;
}
int lpx_transform_col(LPX *lp, int len, int ind[], double val[])
{     int i, m, t;
      double *a, *alfa;
      if (!lpx_is_b_avail(lp))
         xfault("lpx_transform_col: LP basis is not available\n");
      m = lpx_get_num_rows(lp);
      /* unpack the column to be transformed to the array a */
      a = xcalloc(1+m, sizeof(double));
      for (i = 1; i <= m; i++) a[i] = 0.0;
      if (!(0 <= len && len <= m))
         xfault("lpx_transform_col: len = %d; invalid column length\n",
            len);
      for (t = 1; t <= len; t++)
      {  i = ind[t];
         if (!(1 <= i && i <= m))
            xfault("lpx_transform_col: ind[%d] = %d; row index out of r"
               "ange\n", t, i);
         if (val[t] == 0.0)
            xfault("lpx_transform_col: val[%d] = 0; zero coefficient no"
               "t allowed\n", t);
         if (a[i] != 0.0)
            xfault("lpx_transform_col: ind[%d] = %d; duplicate row indi"
               "ces not allowed\n", t, i);
         a[i] = val[t];
      }
      /* solve the system B*a = alfa to compute the vector alfa */
      alfa = a, lpx_ftran(lp, alfa);
      /* store resultant coefficients */
      len = 0;
      for (i = 1; i <= m; i++)
      {  if (alfa[i] != 0.0)
         {  len++;
            ind[len] = lpx_get_b_info(lp, i);
            val[len] = alfa[i];
         }
      }
      xfree(a);
      return len;
}
Exemple #25
0
int mpl_postsolve(MPL *mpl)
{     if (!(mpl->phase == 3 && !mpl->flag_p))
         xfault("mpl_postsolve: invalid call sequence\n");
      /* set up error handler */
      if (setjmp(mpl->jump)) goto done;
      /* perform postsolving */
      postsolve_model(mpl);
      flush_output(mpl);
      /* postsolving phase has been finished */
      xprintf("Model has been successfully processed\n");
done: /* return to the calling program */
      return mpl->phase;
}
Exemple #26
0
int mpl_get_col_bnds(MPL *mpl, int j, double *_lb, double *_ub)
{     ELEMVAR *var;
      int type;
      double lb, ub;
      if (mpl->phase != 3)
         xfault("mpl_get_col_bnds: invalid call sequence\n");
      if (!(1 <= j && j <= mpl->n))
         xfault("mpl_get_col_bnds: j = %d; column number out of range\n"
            , j);
      var = mpl->col[j];
#if 0 /* 21/VII-2006 */
      if (var->var->lbnd == NULL && var->var->ubnd == NULL)
         type = MPL_FR, lb = ub = 0.0;
      else if (var->var->ubnd == NULL)
         type = MPL_LO, lb = var->lbnd, ub = 0.0;
      else if (var->var->lbnd == NULL)
         type = MPL_UP, lb = 0.0, ub = var->ubnd;
      else if (var->var->lbnd != var->var->ubnd)
         type = MPL_DB, lb = var->lbnd, ub = var->ubnd;
      else
         type = MPL_FX, lb = ub = var->lbnd;
#else
      lb = (var->var->lbnd == NULL ? -DBL_MAX : var->lbnd);
      ub = (var->var->ubnd == NULL ? +DBL_MAX : var->ubnd);
      if (lb == -DBL_MAX && ub == +DBL_MAX)
         type = MPL_FR, lb = ub = 0.0;
      else if (ub == +DBL_MAX)
         type = MPL_LO, ub = 0.0;
      else if (lb == -DBL_MAX)
         type = MPL_UP, lb = 0.0;
      else if (var->var->lbnd != var->var->ubnd)
         type = MPL_DB;
      else
         type = MPL_FX;
#endif
      if (_lb != NULL) *_lb = lb;
      if (_ub != NULL) *_ub = ub;
      return type;
}
Exemple #27
0
void lux_solve(LUX *lux, int tr, mpq_t x[])
{     if (lux->rank < lux->n)
         xfault("lux_solve: LU-factorization has incomplete rank\n");
      if (!tr)
      {  /* A = F*V, therefore inv(A) = inv(V)*inv(F) */
         lux_f_solve(lux, 0, x);
         lux_v_solve(lux, 0, x);
      }
      else
      {  /* A' = V'*F', therefore inv(A') = inv(F')*inv(V') */
         lux_v_solve(lux, 1, x);
         lux_f_solve(lux, 1, x);
      }
      return;
}
void lpx_eval_b_dual(LPX *lp, double row_dual[], double col_dual[])
{     int i, j, k, m, n, len, *ind;
      double dj, *cB, *pi, *val;
      if (!lpx_is_b_avail(lp))
         xfault("lpx_eval_b_dual: LP basis is not available\n");
      m = lpx_get_num_rows(lp);
      n = lpx_get_num_cols(lp);
      /* store zero reduced costs of basic auxiliary and structural
         variables and build the vector cB of objective coefficients at
         basic variables */
      cB = xcalloc(1+m, sizeof(double));
      for (i = 1; i <= m; i++)
      {  k = lpx_get_b_info(lp, i);
         /* xB[i] is k-th original variable */
         xassert(1 <= k && k <= m+n);
         if (k <= m)
         {  row_dual[k] = 0.0;
            cB[i] = 0.0;
         }
         else
         {  col_dual[k-m] = 0.0;
            cB[i] = lpx_get_obj_coef(lp, k-m);
         }
      }
      /* solve the system B'*pi = cB to compute the vector pi */
      pi = cB, lpx_btran(lp, pi);
      /* compute reduced costs of non-basic auxiliary variables */
      for (i = 1; i <= m; i++)
      {  if (lpx_get_row_stat(lp, i) != LPX_BS)
            row_dual[i] = - pi[i];
      }
      /* compute reduced costs of non-basic structural variables */
      ind = xcalloc(1+m, sizeof(int));
      val = xcalloc(1+m, sizeof(double));
      for (j = 1; j <= n; j++)
      {  if (lpx_get_col_stat(lp, j) != LPX_BS)
         {  dj = lpx_get_obj_coef(lp, j);
            len = lpx_get_mat_col(lp, j, ind, val);
            for (k = 1; k <= len; k++) dj += val[k] * pi[ind[k]];
            col_dual[j] = dj;
         }
      }
      xfree(ind);
      xfree(val);
      xfree(cB);
      return;
}
Exemple #29
0
void fhv_btran(FHV *fhv, double x[])
{     int *pp_row = fhv->luf->pp_row;
      int *pp_col = fhv->luf->pp_col;
      int *p0_row = fhv->p0_row;
      int *p0_col = fhv->p0_col;
      if (!fhv->valid)
         xfault("fhv_btran: the factorization is not valid\n");
      /* B = F*H*V, therefore inv(B') = inv(F')*inv(H')*inv(V') */
      luf_v_solve(fhv->luf, 1, x);
      fhv_h_solve(fhv, 1, x);
      fhv->luf->pp_row = p0_row;
      fhv->luf->pp_col = p0_col;
      luf_f_solve(fhv->luf, 1, x);
      fhv->luf->pp_row = pp_row;
      fhv->luf->pp_col = pp_col;
      return;
}
Exemple #30
0
void lpf_ftran(LPF *lpf, double x[])
{     int m0 = lpf->m0;
      int m = lpf->m;
      int n  = lpf->n;
      int *P_col = lpf->P_col;
      int *Q_col = lpf->Q_col;
      double *fg = lpf->work1;
      double *f = fg;
      double *g = fg + m0;
      int i, ii;
#if _GLPLPF_DEBUG
      double *b;
#endif
      if (!lpf->valid)
         xfault("lpf_ftran: the factorization is not valid\n");
      xassert(0 <= m && m <= m0 + n);
#if _GLPLPF_DEBUG
      /* save the right-hand side vector */
      b = xcalloc(1+m, sizeof(double));
      for (i = 1; i <= m; i++) b[i] = x[i];
#endif
      /* (f g) := inv(P) * (b 0) */
      for (i = 1; i <= m0 + n; i++)
         fg[i] = ((ii = P_col[i]) <= m ? x[ii] : 0.0);
      /* f1 := inv(L0) * f */
      luf_f_solve(lpf->luf, 0, f);
      /* g1 := g - S * f1 */
      s_prod(lpf, g, -1.0, f);
      /* g2 := inv(C) * g1 */
      scf_solve_it(lpf->scf, 0, g);
      /* f2 := inv(U0) * (f1 - R * g2) */
      r_prod(lpf, f, -1.0, g);
      luf_v_solve(lpf->luf, 0, f);
      /* (x y) := inv(Q) * (f2 g2) */
      for (i = 1; i <= m; i++)
         x[i] = fg[Q_col[i]];
#if _GLPLPF_DEBUG
      /* check relative error in solution */
      check_error(lpf, 0, x, b);
      xfree(b);
#endif
      return;
}