remove polyhedron_range

[barvinok.git] / basis_reduction_pip.c

#include <assert.h>
#include <piplib/piplibMP.h>
#include <barvinok/basis_reduction.h>

struct pip_lp {
    Polyhedron *P;
    Value      *obj;
    Matrix     *eq;
    int         neq;
    PipQuast   *sol;
};

static struct pip_lp *init_lp(Polyhedron *P);
static void set_lp_obj(struct pip_lp *lp, Value *row, int dim);
static int solve_lp(struct pip_lp *lp);
static void get_obj_val(struct pip_lp* lp, mpq_t *F);
static void delete_lp(struct pip_lp *lp);
static int add_lp_row(struct pip_lp *lp, Value *row, int dim);
static void get_alpha(struct pip_lp* lp, int row, mpq_t *alpha);
static void del_lp_row(struct pip_lp *lp);

#define GBR_LP                              struct pip_lp
#define GBR_type                            mpq_t
#define GBR_init(v)                         mpq_init(v)
#define GBR_clear(v)                        mpq_clear(v)
#define GBR_set(a,b)                        mpq_set(a,b)
#define GBR_set_ui(a,b)                     mpq_set_ui(a,b,1)
#define GBR_mul(a,b,c)                      mpq_mul(a,b,c)
#define GBR_lt(a,b)                         (mpq_cmp(a,b) < 0)
#define GBR_floor(a,b)                      mpz_fdiv_q(a,mpq_numref(b),mpq_denref(b))
#define GBR_ceil(a,b)                       mpz_cdiv_q(a,mpq_numref(b),mpq_denref(b))
#define GBR_lp_init(P)                      init_lp(P)
#define GBR_lp_set_obj(lp, obj, dim)        set_lp_obj(lp, obj, dim)
#define GBR_lp_solve(lp)                    solve_lp(lp)
#define GBR_lp_get_obj_val(lp, F)           get_obj_val(lp, F)
#define GBR_lp_delete(lp)                   delete_lp(lp)
#define GBR_lp_next_row(lp)                 lp->neq
#define GBR_lp_add_row(lp, row, dim)        add_lp_row(lp, row, dim)
#define GBR_lp_get_alpha(lp, row, alpha)    get_alpha(lp, row, alpha)
#define GBR_lp_del_row(lp)                  del_lp_row(lp);
#define Polyhedron_Reduced_Basis            pip_Polyhedron_Reduced_Basis
#include "basis_reduction_templ.c"

#define ALLOC(type) (type*)malloc(sizeof(type))

static struct pip_lp *init_lp(Polyhedron *P)
{
    struct pip_lp *lp = ALLOC(struct pip_lp);
    lp->P = P;
    lp->eq = Matrix_Alloc(P->Dimension, P->Dimension);
    lp->neq = 0;
    lp->sol = NULL;

    return lp;
}

static void set_lp_obj(struct pip_lp *lp, Value *row, int dim)
{
    assert(lp->P->Dimension == dim);
    lp->obj = row;
}

static int solve_lp(struct pip_lp *lp)
{
    PipOptions  *options;
    PipMatrix   *domain;
    unsigned     dim = lp->P->Dimension;
    int          rows = 1 + 2*lp->P->NbConstraints + lp->neq;
    int          cols = 2*dim + 3;
    int          i, j;

    if (lp->sol)
        pip_quast_free(lp->sol);

    domain = pip_matrix_alloc(rows, cols);
    for (i = 0; i < lp->neq; ++i)
        for (j = 0; j < dim; ++j) {
            value_assign(domain->p[i][1+1+j], lp->eq->p[i][j]);
            value_oppose(domain->p[i][1+1+dim+j], lp->eq->p[i][j]);
        }
    value_set_si(domain->p[lp->neq][1], -1);
    for (j = 0; j < dim; ++j) {
        value_assign(domain->p[lp->neq][1+1+j], lp->obj[j]);
        value_oppose(domain->p[lp->neq][1+1+dim+j], lp->obj[j]);
    }
    for (i = 0; i < lp->P->NbConstraints; ++i) {
        value_assign(domain->p[lp->neq+1+i][0], lp->P->Constraint[i][0]);
        value_assign(domain->p[lp->neq+1+lp->P->NbConstraints+i][0],
                     lp->P->Constraint[i][0]);
        for (j = 0; j < dim; ++j) {
            value_assign(domain->p[lp->neq+1+i][2+j], lp->P->Constraint[i][1+j]);
            value_assign(domain->p[lp->neq+1+lp->P->NbConstraints+i][2+dim+j],
                         lp->P->Constraint[i][1+j]);
        }
        value_assign(domain->p[lp->neq+1+i][cols-1], lp->P->Constraint[i][1+dim]);
        value_assign(domain->p[lp->neq+1+lp->P->NbConstraints+i][cols-1],
                     lp->P->Constraint[i][1+dim]);
    }

    options = pip_options_init();
    options->Urs_unknowns = -1;
    options->Maximize = 1;
    options->Nq = 0;
    if (lp->neq)
        options->Compute_dual = 1;
    lp->sol = pip_solve(domain, NULL, -1, options);
    pip_matrix_free(domain);

    pip_options_free(options);

    /* We only call this function on a polytope that is known
     * to be (rationally) non-empty.
     * However, if the test for rational emptiness was inaccurate
     * (e.g., when using GLPK with big coefficients), the input
     * polytope may be empty.  It's better to just abort here
     * so the user can select a different linear solver.
     */
    assert(lp->sol->list);
    return value_zero_p(lp->sol->list->vector->the_deno[0]);
}

static void get_obj_val(struct pip_lp* lp, mpq_t *F)
{
    value_assign(mpq_numref(*F), lp->sol->list->vector->the_vector[0]);
    value_assign(mpq_denref(*F), lp->sol->list->vector->the_deno[0]);
}

static void delete_lp(struct pip_lp *lp)
{
    if (lp->sol)
        pip_quast_free(lp->sol);
    Matrix_Free(lp->eq);
    free(lp);
}

static int add_lp_row(struct pip_lp *lp, Value *row, int dim)
{
    assert(lp->P->Dimension == dim);
    Vector_Copy(row, lp->eq->p[lp->neq], dim);
    return lp->neq++;
}

static void get_alpha(struct pip_lp* lp, int row, mpq_t *alpha)
{
    PipList *list;
    int i = 0;

    assert(lp->sol->next_then);
    assert(lp->sol->next_then->list);

    for (i = 0, list = lp->sol->next_then->list; i < row; ++i, list = list->next)
        ;

    value_assign(mpq_numref(*alpha), list->vector->the_vector[0]);
    value_assign(mpq_denref(*alpha), list->vector->the_deno[0]);
}

static void del_lp_row(struct pip_lp *lp)
{
    assert(lp->neq > 0);
    lp->neq--;
}