polly/lib/External/isl/basis_reduction_tab.c - llvm-project - Git at Google

 /*
  * Copyright 2008-2009 Katholieke Universiteit Leuven
  *
  * Use of this software is governed by the MIT license
  *
  * Written by Sven Verdoolaege, K.U.Leuven, Departement
  * Computerwetenschappen, Celestijnenlaan 200A, B-3001 Leuven, Belgium
  */

 #include <assert.h>
 #include <isl_map_private.h>
 #include <isl_seq.h>
 #include "isl_tab.h"
 #include <isl_int.h>
 #include <isl_config.h>

 struct tab_lp {
 	struct isl_ctx  *ctx;
 	struct isl_vec  *row;
 	struct isl_tab  *tab;
 	struct isl_tab_undo	**stack;
 	isl_int		*obj;
 	isl_int		 opt;
 	isl_int		 opt_denom;
 	isl_int		 tmp;
 	isl_int		 tmp2;
 	int	         neq;
 	unsigned	 dim;
 	/* number of constraints in initial product tableau */
 	int		 con_offset;
 	/* objective function has fixed or no integer value */
 	int		 is_fixed;
 };

 #ifdef USE_GMP_FOR_MP
 #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_is_zero(a)			    (mpq_sgn(a) == 0)
 #define GBR_numref(a)			    mpq_numref(a)
 #define GBR_denref(a)			    mpq_denref(a)
 #define GBR_floor(a,b)			    mpz_fdiv_q(a,GBR_numref(b),GBR_denref(b))
 #define GBR_ceil(a,b)			    mpz_cdiv_q(a,GBR_numref(b),GBR_denref(b))
 #define GBR_set_num_neg(a, b)		    mpz_neg(GBR_numref(*a), b);
 #define GBR_set_den(a, b)		    mpz_set(GBR_denref(*a), b);
 #endif /* USE_GMP_FOR_MP */

 #ifdef USE_IMATH_FOR_MP
 #include <imrat.h>

 #define GBR_type		    	    mp_rat
 #define GBR_init(v)		    	    v = mp_rat_alloc()
 #define GBR_clear(v)		    	    mp_rat_free(v)
 #define GBR_set(a,b)			    mp_rat_copy(b,a)
 #define GBR_set_ui(a,b)			    mp_rat_set_uvalue(a,b,1)
 #define GBR_mul(a,b,c)			    mp_rat_mul(b,c,a)
 #define GBR_lt(a,b)			    (mp_rat_compare(a,b) < 0)
 #define GBR_is_zero(a)			    (mp_rat_compare_zero(a) == 0)
 #ifdef USE_SMALL_INT_OPT
 #define GBR_numref(a)	isl_sioimath_encode_big(mp_rat_numer_ref(a))
 #define GBR_denref(a)	isl_sioimath_encode_big(mp_rat_denom_ref(a))
 #define GBR_floor(a, b)	isl_sioimath_fdiv_q((a), GBR_numref(b), GBR_denref(b))
 #define GBR_ceil(a, b)	isl_sioimath_cdiv_q((a), GBR_numref(b), GBR_denref(b))
 #define GBR_set_num_neg(a, b)                              \
 	do {                                               \
 		isl_sioimath_scratchspace_t scratch;       \
 		impz_neg(mp_rat_numer_ref(*a),             \
 		    isl_sioimath_bigarg_src(*b, &scratch));\
 	} while (0)
 #define GBR_set_den(a, b)                                  \
 	do {                                               \
 		isl_sioimath_scratchspace_t scratch;       \
 		impz_set(mp_rat_denom_ref(*a),             \
 		    isl_sioimath_bigarg_src(*b, &scratch));\
 	} while (0)
 #else /* USE_SMALL_INT_OPT */
 #define GBR_numref(a)		mp_rat_numer_ref(a)
 #define GBR_denref(a)		mp_rat_denom_ref(a)
 #define GBR_floor(a,b)		impz_fdiv_q(a,GBR_numref(b),GBR_denref(b))
 #define GBR_ceil(a,b)		impz_cdiv_q(a,GBR_numref(b),GBR_denref(b))
 #define GBR_set_num_neg(a, b)	impz_neg(GBR_numref(*a), b)
 #define GBR_set_den(a, b)	impz_set(GBR_denref(*a), b)
 #endif /* USE_SMALL_INT_OPT */
 #endif /* USE_IMATH_FOR_MP */

 static struct tab_lp *init_lp(struct isl_tab *tab);
 static void set_lp_obj(struct tab_lp *lp, isl_int *row, int dim);
 static int solve_lp(struct tab_lp *lp);
 static void get_obj_val(struct tab_lp* lp, GBR_type *F);
 static void delete_lp(struct tab_lp *lp);
 static int add_lp_row(struct tab_lp *lp, isl_int *row, int dim);
 static void get_alpha(struct tab_lp* lp, int row, GBR_type *alpha);
 static int del_lp_row(struct tab_lp *lp) WARN_UNUSED;
 static int cut_lp_to_hyperplane(struct tab_lp *lp, isl_int *row);

 #define GBR_LP			    	    struct tab_lp
 #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 GBR_lp_is_fixed(lp)		    (lp)->is_fixed
 #define GBR_lp_cut(lp, obj)	    	    cut_lp_to_hyperplane(lp, obj)
 #include "basis_reduction_templ.c"

 /* Set up a tableau for the Cartesian product of bset with itself.
  * This could be optimized by first setting up a tableau for bset
  * and then performing the Cartesian product on the tableau.
  */
 static struct isl_tab *gbr_tab(struct isl_tab *tab, struct isl_vec *row)
 {
 	unsigned dim;
 	struct isl_tab *prod;

 	if (!tab || !row)
 		return NULL;

 	dim = tab->n_var;
 	prod = isl_tab_product(tab, tab);
 	if (isl_tab_extend_cons(prod, 3 * dim + 1) < 0) {
 		isl_tab_free(prod);
 		return NULL;
 	}
 	return prod;
 }

 static struct tab_lp *init_lp(struct isl_tab *tab)
 {
 	struct tab_lp *lp = NULL;

 	if (!tab)
 		return NULL;

 	lp = isl_calloc_type(tab->mat->ctx, struct tab_lp);
 	if (!lp)
 		return NULL;

 	isl_int_init(lp->opt);
 	isl_int_init(lp->opt_denom);
 	isl_int_init(lp->tmp);
 	isl_int_init(lp->tmp2);

 	lp->dim = tab->n_var;

 	lp->ctx = tab->mat->ctx;
 	isl_ctx_ref(lp->ctx);

 	lp->stack = isl_alloc_array(lp->ctx, struct isl_tab_undo *, lp->dim);

 	lp->row = isl_vec_alloc(lp->ctx, 1 + 2 * lp->dim);
 	if (!lp->row)
 		goto error;
 	lp->tab = gbr_tab(tab, lp->row);
 	if (!lp->tab)
 		goto error;
 	lp->con_offset = lp->tab->n_con;
 	lp->obj = NULL;
 	lp->neq = 0;

 	return lp;
 error:
 	delete_lp(lp);
 	return NULL;
 }

 static void set_lp_obj(struct tab_lp *lp, isl_int *row, int dim)
 {
 	lp->obj = row;
 }

 static int solve_lp(struct tab_lp *lp)
 {
 	enum isl_lp_result res;
 	unsigned flags = 0;

 	lp->is_fixed = 0;

 	isl_int_set_si(lp->row->el[0], 0);
 	isl_seq_cpy(lp->row->el + 1, lp->obj, lp->dim);
 	isl_seq_neg(lp->row->el + 1 + lp->dim, lp->obj, lp->dim);
 	if (lp->neq)
 		flags = ISL_TAB_SAVE_DUAL;
 	res = isl_tab_min(lp->tab, lp->row->el, lp->ctx->one,
 			  &lp->opt, &lp->opt_denom, flags);
 	isl_int_mul_ui(lp->opt_denom, lp->opt_denom, 2);
 	if (isl_int_abs_lt(lp->opt, lp->opt_denom)) {
 		struct isl_vec *sample = isl_tab_get_sample_value(lp->tab);
 		if (!sample)
 			return -1;
 		isl_seq_inner_product(lp->obj, sample->el + 1, lp->dim, &lp->tmp);
 		isl_seq_inner_product(lp->obj, sample->el + 1 + lp->dim, lp->dim, &lp->tmp2);
 		isl_int_cdiv_q(lp->tmp, lp->tmp, sample->el[0]);
 		isl_int_fdiv_q(lp->tmp2, lp->tmp2, sample->el[0]);
 		if (isl_int_ge(lp->tmp, lp->tmp2))
 			lp->is_fixed = 1;
 		isl_vec_free(sample);
 	}
 	isl_int_divexact_ui(lp->opt_denom, lp->opt_denom, 2);
 	if (res < 0)
 		return -1;
 	if (res != isl_lp_ok)
 		isl_die(lp->ctx, isl_error_internal,
 			"unexpected missing (bounded) solution", return -1);
 	return 0;
 }

 /* The current objective function has a fixed (or no) integer value.
  * Cut the tableau to the hyperplane that fixes this value in
  * both halves of the tableau.
  * Return 1 if the resulting tableau is empty.
  */
 static int cut_lp_to_hyperplane(struct tab_lp *lp, isl_int *row)
 {
 	enum isl_lp_result res;

 	isl_int_set_si(lp->row->el[0], 0);
 	isl_seq_cpy(lp->row->el + 1, row, lp->dim);
 	isl_seq_clr(lp->row->el + 1 + lp->dim, lp->dim);
 	res = isl_tab_min(lp->tab, lp->row->el, lp->ctx->one,
 			  &lp->tmp, NULL, 0);
 	if (res != isl_lp_ok)
 		return -1;

 	isl_int_neg(lp->row->el[0], lp->tmp);
 	if (isl_tab_add_eq(lp->tab, lp->row->el) < 0)
 		return -1;

 	isl_seq_cpy(lp->row->el + 1 + lp->dim, row, lp->dim);
 	isl_seq_clr(lp->row->el + 1, lp->dim);
 	if (isl_tab_add_eq(lp->tab, lp->row->el) < 0)
 		return -1;

 	lp->con_offset += 2;

 	return lp->tab->empty;
 }

 static void get_obj_val(struct tab_lp* lp, GBR_type *F)
 {
 	GBR_set_num_neg(F, lp->opt);
 	GBR_set_den(F, lp->opt_denom);
 }

 static void delete_lp(struct tab_lp *lp)
 {
 	if (!lp)
 		return;

 	isl_int_clear(lp->opt);
 	isl_int_clear(lp->opt_denom);
 	isl_int_clear(lp->tmp);
 	isl_int_clear(lp->tmp2);
 	isl_vec_free(lp->row);
 	free(lp->stack);
 	isl_tab_free(lp->tab);
 	isl_ctx_deref(lp->ctx);
 	free(lp);
 }

 static int add_lp_row(struct tab_lp *lp, isl_int *row, int dim)
 {
 	lp->stack[lp->neq] = isl_tab_snap(lp->tab);

 	isl_int_set_si(lp->row->el[0], 0);
 	isl_seq_cpy(lp->row->el + 1, row, lp->dim);
 	isl_seq_neg(lp->row->el + 1 + lp->dim, row, lp->dim);

 	if (isl_tab_add_valid_eq(lp->tab, lp->row->el) < 0)
 		return -1;

 	return lp->neq++;
 }

 static void get_alpha(struct tab_lp* lp, int row, GBR_type *alpha)
 {
 	row += lp->con_offset;
 	GBR_set_num_neg(alpha, lp->tab->dual->el[1 + row]);
 	GBR_set_den(alpha, lp->tab->dual->el[0]);
 }

 static int del_lp_row(struct tab_lp *lp)
 {
 	lp->neq--;
 	return isl_tab_rollback(lp->tab, lp->stack[lp->neq]);
 }
	/*
	* Copyright 2008-2009 Katholieke Universiteit Leuven
	*
	* Use of this software is governed by the MIT license
	*
	* Written by Sven Verdoolaege, K.U.Leuven, Departement
	* Computerwetenschappen, Celestijnenlaan 200A, B-3001 Leuven, Belgium
	*/

	#include <assert.h>
	#include <isl_map_private.h>
	#include <isl_seq.h>
	#include "isl_tab.h"
	#include <isl_int.h>
	#include <isl_config.h>

	struct tab_lp {
	struct isl_ctx *ctx;
	struct isl_vec *row;
	struct isl_tab *tab;
	struct isl_tab_undo **stack;
	isl_int *obj;
	isl_int opt;
	isl_int opt_denom;
	isl_int tmp;
	isl_int tmp2;
	int neq;
	unsigned dim;
	/* number of constraints in initial product tableau */
	int con_offset;
	/* objective function has fixed or no integer value */
	int is_fixed;
	};

	#ifdef USE_GMP_FOR_MP
	#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_is_zero(a) (mpq_sgn(a) == 0)
	#define GBR_numref(a) mpq_numref(a)
	#define GBR_denref(a) mpq_denref(a)
	#define GBR_floor(a,b) mpz_fdiv_q(a,GBR_numref(b),GBR_denref(b))
	#define GBR_ceil(a,b) mpz_cdiv_q(a,GBR_numref(b),GBR_denref(b))
	#define GBR_set_num_neg(a, b) mpz_neg(GBR_numref(*a), b);
	#define GBR_set_den(a, b) mpz_set(GBR_denref(*a), b);
	#endif /* USE_GMP_FOR_MP */

	#ifdef USE_IMATH_FOR_MP
	#include <imrat.h>

	#define GBR_type mp_rat
	#define GBR_init(v) v = mp_rat_alloc()
	#define GBR_clear(v) mp_rat_free(v)
	#define GBR_set(a,b) mp_rat_copy(b,a)
	#define GBR_set_ui(a,b) mp_rat_set_uvalue(a,b,1)
	#define GBR_mul(a,b,c) mp_rat_mul(b,c,a)
	#define GBR_lt(a,b) (mp_rat_compare(a,b) < 0)
	#define GBR_is_zero(a) (mp_rat_compare_zero(a) == 0)
	#ifdef USE_SMALL_INT_OPT
	#define GBR_numref(a) isl_sioimath_encode_big(mp_rat_numer_ref(a))
	#define GBR_denref(a) isl_sioimath_encode_big(mp_rat_denom_ref(a))
	#define GBR_floor(a, b) isl_sioimath_fdiv_q((a), GBR_numref(b), GBR_denref(b))
	#define GBR_ceil(a, b) isl_sioimath_cdiv_q((a), GBR_numref(b), GBR_denref(b))
	#define GBR_set_num_neg(a, b) \
	do { \
	isl_sioimath_scratchspace_t scratch; \
	impz_neg(mp_rat_numer_ref(*a), \
	isl_sioimath_bigarg_src(*b, &scratch));\
	} while (0)
	#define GBR_set_den(a, b) \
	do { \
	isl_sioimath_scratchspace_t scratch; \
	impz_set(mp_rat_denom_ref(*a), \
	isl_sioimath_bigarg_src(*b, &scratch));\
	} while (0)
	#else /* USE_SMALL_INT_OPT */
	#define GBR_numref(a) mp_rat_numer_ref(a)
	#define GBR_denref(a) mp_rat_denom_ref(a)
	#define GBR_floor(a,b) impz_fdiv_q(a,GBR_numref(b),GBR_denref(b))
	#define GBR_ceil(a,b) impz_cdiv_q(a,GBR_numref(b),GBR_denref(b))
	#define GBR_set_num_neg(a, b) impz_neg(GBR_numref(*a), b)
	#define GBR_set_den(a, b) impz_set(GBR_denref(*a), b)
	#endif /* USE_SMALL_INT_OPT */
	#endif /* USE_IMATH_FOR_MP */

	static struct tab_lp init_lp(struct isl_tab tab);
	static void set_lp_obj(struct tab_lp lp, isl_int row, int dim);
	static int solve_lp(struct tab_lp *lp);
	static void get_obj_val(struct tab_lp* lp, GBR_type *F);
	static void delete_lp(struct tab_lp *lp);
	static int add_lp_row(struct tab_lp lp, isl_int row, int dim);
	static void get_alpha(struct tab_lp* lp, int row, GBR_type *alpha);
	static int del_lp_row(struct tab_lp *lp) WARN_UNUSED;
	static int cut_lp_to_hyperplane(struct tab_lp lp, isl_int row);

	#define GBR_LP struct tab_lp
	#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 GBR_lp_is_fixed(lp) (lp)->is_fixed
	#define GBR_lp_cut(lp, obj) cut_lp_to_hyperplane(lp, obj)
	#include "basis_reduction_templ.c"

	/* Set up a tableau for the Cartesian product of bset with itself.
	* This could be optimized by first setting up a tableau for bset
	* and then performing the Cartesian product on the tableau.
	*/
	static struct isl_tab gbr_tab(struct isl_tab tab, struct isl_vec *row)
	{
	unsigned dim;
	struct isl_tab *prod;

	if (!tab \|\| !row)
	return NULL;

	dim = tab->n_var;
	prod = isl_tab_product(tab, tab);
	if (isl_tab_extend_cons(prod, 3 * dim + 1) < 0) {
	isl_tab_free(prod);
	return NULL;
	}
	return prod;
	}

	static struct tab_lp init_lp(struct isl_tab tab)
	{
	struct tab_lp *lp = NULL;

	if (!tab)
	return NULL;

	lp = isl_calloc_type(tab->mat->ctx, struct tab_lp);
	if (!lp)
	return NULL;

	isl_int_init(lp->opt);
	isl_int_init(lp->opt_denom);
	isl_int_init(lp->tmp);
	isl_int_init(lp->tmp2);

	lp->dim = tab->n_var;

	lp->ctx = tab->mat->ctx;
	isl_ctx_ref(lp->ctx);

	lp->stack = isl_alloc_array(lp->ctx, struct isl_tab_undo *, lp->dim);

	lp->row = isl_vec_alloc(lp->ctx, 1 + 2 * lp->dim);
	if (!lp->row)
	goto error;
	lp->tab = gbr_tab(tab, lp->row);
	if (!lp->tab)
	goto error;
	lp->con_offset = lp->tab->n_con;
	lp->obj = NULL;
	lp->neq = 0;

	return lp;
	error:
	delete_lp(lp);
	return NULL;
	}

	static void set_lp_obj(struct tab_lp lp, isl_int row, int dim)
	{
	lp->obj = row;
	}

	static int solve_lp(struct tab_lp *lp)
	{
	enum isl_lp_result res;
	unsigned flags = 0;

	lp->is_fixed = 0;

	isl_int_set_si(lp->row->el[0], 0);
	isl_seq_cpy(lp->row->el + 1, lp->obj, lp->dim);
	isl_seq_neg(lp->row->el + 1 + lp->dim, lp->obj, lp->dim);
	if (lp->neq)
	flags = ISL_TAB_SAVE_DUAL;
	res = isl_tab_min(lp->tab, lp->row->el, lp->ctx->one,
	&lp->opt, &lp->opt_denom, flags);
	isl_int_mul_ui(lp->opt_denom, lp->opt_denom, 2);
	if (isl_int_abs_lt(lp->opt, lp->opt_denom)) {
	struct isl_vec *sample = isl_tab_get_sample_value(lp->tab);
	if (!sample)
	return -1;
	isl_seq_inner_product(lp->obj, sample->el + 1, lp->dim, &lp->tmp);
	isl_seq_inner_product(lp->obj, sample->el + 1 + lp->dim, lp->dim, &lp->tmp2);
	isl_int_cdiv_q(lp->tmp, lp->tmp, sample->el[0]);
	isl_int_fdiv_q(lp->tmp2, lp->tmp2, sample->el[0]);
	if (isl_int_ge(lp->tmp, lp->tmp2))
	lp->is_fixed = 1;
	isl_vec_free(sample);
	}
	isl_int_divexact_ui(lp->opt_denom, lp->opt_denom, 2);
	if (res < 0)
	return -1;
	if (res != isl_lp_ok)
	isl_die(lp->ctx, isl_error_internal,
	"unexpected missing (bounded) solution", return -1);
	return 0;
	}

	/* The current objective function has a fixed (or no) integer value.
	* Cut the tableau to the hyperplane that fixes this value in
	* both halves of the tableau.
	* Return 1 if the resulting tableau is empty.
	*/
	static int cut_lp_to_hyperplane(struct tab_lp lp, isl_int row)
	{
	enum isl_lp_result res;

	isl_int_set_si(lp->row->el[0], 0);
	isl_seq_cpy(lp->row->el + 1, row, lp->dim);
	isl_seq_clr(lp->row->el + 1 + lp->dim, lp->dim);
	res = isl_tab_min(lp->tab, lp->row->el, lp->ctx->one,
	&lp->tmp, NULL, 0);
	if (res != isl_lp_ok)
	return -1;

	isl_int_neg(lp->row->el[0], lp->tmp);
	if (isl_tab_add_eq(lp->tab, lp->row->el) < 0)
	return -1;

	isl_seq_cpy(lp->row->el + 1 + lp->dim, row, lp->dim);
	isl_seq_clr(lp->row->el + 1, lp->dim);
	if (isl_tab_add_eq(lp->tab, lp->row->el) < 0)
	return -1;

	lp->con_offset += 2;

	return lp->tab->empty;
	}

	static void get_obj_val(struct tab_lp* lp, GBR_type *F)
	{
	GBR_set_num_neg(F, lp->opt);
	GBR_set_den(F, lp->opt_denom);
	}

	static void delete_lp(struct tab_lp *lp)
	{
	if (!lp)
	return;

	isl_int_clear(lp->opt);
	isl_int_clear(lp->opt_denom);
	isl_int_clear(lp->tmp);
	isl_int_clear(lp->tmp2);
	isl_vec_free(lp->row);
	free(lp->stack);
	isl_tab_free(lp->tab);
	isl_ctx_deref(lp->ctx);
	free(lp);
	}

	static int add_lp_row(struct tab_lp lp, isl_int row, int dim)
	{
	lp->stack[lp->neq] = isl_tab_snap(lp->tab);

	isl_int_set_si(lp->row->el[0], 0);
	isl_seq_cpy(lp->row->el + 1, row, lp->dim);
	isl_seq_neg(lp->row->el + 1 + lp->dim, row, lp->dim);

	if (isl_tab_add_valid_eq(lp->tab, lp->row->el) < 0)
	return -1;

	return lp->neq++;
	}

	static void get_alpha(struct tab_lp* lp, int row, GBR_type *alpha)
	{
	row += lp->con_offset;
	GBR_set_num_neg(alpha, lp->tab->dual->el[1 + row]);
	GBR_set_den(alpha, lp->tab->dual->el[0]);
	}

	static int del_lp_row(struct tab_lp *lp)
	{
	lp->neq--;
	return isl_tab_rollback(lp->tab, lp->stack[lp->neq]);
	}