| blob | 0b28f420b263078a37da4b42edcbfe2637544ed2 |
1 #ifndef ISL_TAB_H
2 #define ISL_TAB_H
18 };
21 isl_tab_undo_bottom,
22 isl_tab_undo_empty,
23 isl_tab_undo_nonneg,
24 isl_tab_undo_redundant,
25 isl_tab_undo_zero,
26 isl_tab_undo_allocate,
27 isl_tab_undo_relax,
28 isl_tab_undo_bset_ineq,
29 isl_tab_undo_bset_eq,
30 isl_tab_undo_bset_div,
31 isl_tab_undo_saved_basis,
32 isl_tab_undo_drop_sample,
33 };
38 };
44 };
46 /* The tableau maintains equality relations.
47 * Each column and each row is associated to a variable or a constraint.
48 * The "value" of an inequality constraint is the value of the corresponding
49 * slack variable.
50 * The "row_var" and "col_var" arrays map column and row indices
51 * to indices in the "var" and "con" arrays. The elements of these
52 * arrays maintain extra information about the variables and the constraints.
53 * Each row expresses the corresponding row variable as an affine expression
54 * of the column variables.
55 * The first two columns in the matrix contain the common denominator of
56 * the row and the numerator of the constant term.
57 * If "M" is set, then the third column represents the "big parameter".
58 * The third (M = 0) or fourth (M = 1) column
59 * in the matrix is called column 0 with respect to the col_var array.
60 * The sample value of the tableau is the value that assigns zero
61 * to all the column variables and the constant term of each affine
62 * expression to the corresponding row variable.
63 * The operations on the tableau maintain the property that the sample
64 * value satisfies the non-negativity constraints (usually on the slack
65 * variables).
66 *
67 * The big parameter represents an arbitrarily big (and divisible)
68 * positive number. If present, then the sign of a row is determined
69 * lexicographically, with the sign of the big parameter coefficient
70 * considered first. The big parameter is only used while
71 * solving PILP problems.
72 *
73 * The first n_dead column variables have their values fixed to zero.
74 * The corresponding tab_vars are flagged "is_zero".
75 * Some of the rows that have have zero coefficients in all but
76 * the dead columns are also flagged "is_zero".
77 *
78 * The first n_redundant rows correspond to inequality constraints
79 * that are always satisfied for any value satisfying the non-redundant
80 * rows. The corresponding tab_vars are flagged "is_redundant".
81 * A row variable that is flagged "is_zero" is also flagged "is_redundant"
82 * since the constraint has been reduced to 0 = 0 and is therefore always
83 * satisfied.
84 *
85 * There are "n_var" variables in total. The first "n_param" of these
86 * are called parameters and the last "n_div" of these are called divs.
87 * The basic tableau operations makes no distinction between different
88 * kinds of variables. These special variables are only used while
89 * solving PILP problems.
90 *
91 * Dead columns and redundant rows are detected on the fly.
92 * However, the basic operations do not ensure that all dead columns
93 * or all redundant rows are detected.
94 * isl_tab_detect_equalities and isl_tab_detect_redundant can be used
95 * to perform and exhaustive search for dead columns and redundant rows.
96 *
97 * The samples matrix contains "n_sample" integer points that have at some
98 * point been elements satisfying the tableau. The first "n_outside"
99 * of them no longer satisfy the tableau. They are kept because they
100 * can be reinstated during rollback when the constraint that cut them
101 * out is removed. These samples are only maintained for the context
102 * tableau while solving PILP problems.
103 */
106 isl_tab_row_pos,
107 isl_tab_row_neg,
108 isl_tab_row_any,
109 };
146 };
162 #define ISL_TAB_SAVE_DUAL (1 << 0)
179 isl_ineq_redundant,
180 isl_ineq_separate,
181 isl_ineq_cut,
182 isl_ineq_adj_eq,
183 isl_ineq_adj_ineq,
184 };
200 /* private */
220 #endif