| blob | d94e51f594a6b11c15a78c8a9eae1d2abbbb7b75 |
1 /*
2 * Copyright 2008-2009 Katholieke Universiteit Leuven
3 * Copyright 2010 INRIA Saclay
4 *
5 * Use of this software is governed by the GNU LGPLv2.1 license
6 *
7 * Written by Sven Verdoolaege, K.U.Leuven, Departement
8 * Computerwetenschappen, Celestijnenlaan 200A, B-3001 Leuven, Belgium
9 * and INRIA Saclay - Ile-de-France, Parc Club Orsay Universite,
10 * ZAC des vignes, 4 rue Jacques Monod, 91893 Orsay, France
11 */
13 #include <isl_ctx_private.h>
15 #include <isl/seq.h>
18 #include <isl_mat_private.h>
19 #include <isl_aff_private.h>
20 #include <isl_options_private.h>
21 #include <isl_config.h>
23 /*
24 * The implementation of parametric integer linear programming in this file
25 * was inspired by the paper "Parametric Integer Programming" and the
26 * report "Solving systems of affine (in)equalities" by Paul Feautrier
27 * (and others).
28 *
29 * The strategy used for obtaining a feasible solution is different
30 * from the one used in isl_tab.c. In particular, in isl_tab.c,
31 * upon finding a constraint that is not yet satisfied, we pivot
32 * in a row that increases the constant term of the row holding the
33 * constraint, making sure the sample solution remains feasible
34 * for all the constraints it already satisfied.
35 * Here, we always pivot in the row holding the constraint,
36 * choosing a column that induces the lexicographically smallest
37 * increment to the sample solution.
38 *
39 * By starting out from a sample value that is lexicographically
40 * smaller than any integer point in the problem space, the first
41 * feasible integer sample point we find will also be the lexicographically
42 * smallest. If all variables can be assumed to be non-negative,
43 * then the initial sample value may be chosen equal to zero.
44 * However, we will not make this assumption. Instead, we apply
45 * the "big parameter" trick. Any variable x is then not directly
46 * used in the tableau, but instead it is represented by another
47 * variable x' = M + x, where M is an arbitrarily large (positive)
48 * value. x' is therefore always non-negative, whatever the value of x.
49 * Taking as initial sample value x' = 0 corresponds to x = -M,
50 * which is always smaller than any possible value of x.
51 *
52 * The big parameter trick is used in the main tableau and
53 * also in the context tableau if isl_context_lex is used.
54 * In this case, each tableaus has its own big parameter.
55 * Before doing any real work, we check if all the parameters
56 * happen to be non-negative. If so, we drop the column corresponding
57 * to M from the initial context tableau.
58 * If isl_context_gbr is used, then the big parameter trick is only
59 * used in the main tableau.
60 */
64 /* detect nonnegative parameters in context and mark them in tab */
67 /* return temporary reference to basic set representation of context */
69 /* return temporary reference to tableau representation of context */
71 /* add equality; check is 1 if eq may not be valid;
72 * update is 1 if we may want to call ineq_sign on context later.
73 */
76 /* add inequality; check is 1 if ineq may not be valid;
77 * update is 1 if we may want to call ineq_sign on context later.
78 */
81 /* check sign of ineq based on previous information.
82 * strict is 1 if saturation should be treated as a positive sign.
83 */
86 /* check if inequality maintains feasibility */
88 /* return index of a div that corresponds to "div" */
91 /* add div "div" to context and return non-negativity */
95 /* return row index of "best" split */
97 /* check if context has already been determined to be empty */
99 /* check if context is still usable */
101 /* save a copy/snapshot of context */
103 /* restore saved context */
105 /* invalidate context */
107 /* free context */
109 };
113 };
118 };
126 };
132 };
134 /* isl_sol is an interface for constructing a solution to
135 * a parametric integer linear programming problem.
136 * Every time the algorithm reaches a state where a solution
137 * can be read off from the tableau (including cases where the tableau
138 * is empty), the function "add" is called on the isl_sol passed
139 * to find_solutions_main.
140 *
141 * The context tableau is owned by isl_sol and is updated incrementally.
142 *
143 * There are currently two implementations of this interface,
144 * isl_sol_map, which simply collects the solutions in an isl_map
145 * and (optionally) the parts of the context where there is no solution
146 * in an isl_set, and
147 * isl_sol_for, which calls a user-defined function for each part of
148 * the solution.
149 */
163 };
166 {
175 }
177 }
179 /* Push a partial solution represented by a domain and mapping M
180 * onto the stack of partial solutions.
181 */
184 {
202 error:
205 }
207 /* Pop one partial solution from the partial solution stack and
208 * pass it on to sol->add or sol->add_empty.
209 */
211 {
219 else
222 }
224 /* Return a fresh copy of the domain represented by the context tableau.
225 */
227 {
238 }
240 /* Check whether two partial solutions have the same mapping, where n_div
241 * is the number of divs that the two partial solutions have in common.
242 */
245 {
265 }
267 }
269 /* Pop all solutions from the partial solution stack that were pushed onto
270 * the stack at levels that are deeper than the current level.
271 * If the two topmost elements on the stack have the same level
272 * and represent the same solution, then their domains are combined.
273 * This combined domain is the same as the current context domain
274 * as sol_pop is called each time we move back to a higher level.
275 */
277 {
288 }
300 isl_dim_div);
318 }
321 }
324 {
331 }
334 {
340 }
342 /* Move down to next level and push callback onto context tableau
343 * to decrease the level again when it gets rolled back across
344 * the current state. That is, dec_level will be called with
345 * the context tableau in the same state as it is when inc_level
346 * is called.
347 */
349 {
359 }
362 {
370 }
372 /* Add the solution identified by the tableau and the context tableau.
373 *
374 * The layout of the variables is as follows.
375 * tab->n_var is equal to the total number of variables in the input
376 * map (including divs that were copied from the context)
377 * + the number of extra divs constructed
378 * Of these, the first tab->n_param and the last tab->n_div variables
379 * correspond to the variables in the context, i.e.,
380 * tab->n_param + tab->n_div = context_tab->n_var
381 * tab->n_param is equal to the number of parameters and input
382 * dimensions in the input map
383 * tab->n_div is equal to the number of divs in the context
384 *
385 * If there is no solution, then call add_empty with a basic set
386 * that corresponds to the context tableau. (If add_empty is NULL,
387 * then do nothing).
388 *
389 * If there is a solution, then first construct a matrix that maps
390 * all dimensions of the context to the output variables, i.e.,
391 * the output dimensions in the input map.
392 * The divs in the input map (if any) that do not correspond to any
393 * div in the context do not appear in the solution.
394 * The algorithm will make sure that they have an integer value,
395 * but these values themselves are of no interest.
396 * We have to be careful not to drop or rearrange any divs in the
397 * context because that would change the meaning of the matrix.
398 *
399 * To extract the value of the output variables, it should be noted
400 * that we always use a big parameter M in the main tableau and so
401 * the variable stored in this tableau is not an output variable x itself, but
402 * x' = M + x (in case of minimization)
403 * or
404 * x' = M - x (in case of maximization)
405 * If x' appears in a column, then its optimal value is zero,
406 * which means that the optimal value of x is an unbounded number
407 * (-M for minimization and M for maximization).
408 * We currently assume that the output dimensions in the original map
409 * are bounded, so this cannot occur.
410 * Similarly, when x' appears in a row, then the coefficient of M in that
411 * row is necessarily 1.
412 * If the row in the tableau represents
413 * d x' = c + d M + e(y)
414 * then, in case of minimization, the corresponding row in the matrix
415 * will be
416 * a c + a e(y)
417 * with a d = m, the (updated) common denominator of the matrix.
418 * In case of maximization, the row will be
419 * -a c - a e(y)
420 */
422 {
427 isl_int m;
440 }
463 }
482 }
490 }
494 }
500 error2:
502 error:
506 }
512 };
515 {
523 }
526 {
528 }
530 /* This function is called for parts of the context where there is
531 * no solution, with "bset" corresponding to the context tableau.
532 * Simply add the basic set to the set "empty".
533 */
536 {
549 error:
552 }
556 {
558 }
560 /* Given a basic map "dom" that represents the context and an affine
561 * matrix "M" that maps the dimensions of the context to the
562 * output variables, construct a basic map with the same parameters
563 * and divs as the context, the dimensions of the context as input
564 * dimensions and a number of output dimensions that is equal to
565 * the number of output dimensions in the input map.
566 *
567 * The constraints and divs of the context are simply copied
568 * from "dom". For each row
569 * x = c + e(y)
570 * an equality
571 * c + e(y) - d x = 0
572 * is added, with d the common denominator of M.
573 */
576 {
609 }
618 }
627 }
637 }
647 error:
652 }
656 {
658 }
661 /* Store the "parametric constant" of row "row" of tableau "tab" in "line",
662 * i.e., the constant term and the coefficients of all variables that
663 * appear in the context tableau.
664 * Note that the coefficient of the big parameter M is NOT copied.
665 * The context tableau may not have a big parameter and even when it
666 * does, it is a different big parameter.
667 */
669 {
680 }
681 }
689 }
690 }
691 }
693 /* Check if rows "row1" and "row2" have identical "parametric constants",
694 * as explained above.
695 * In this case, we also insist that the coefficients of the big parameter
696 * be the same as the values of the constants will only be the same
697 * if these coefficients are also the same.
698 */
700 {
722 }
724 }
726 /* Return an inequality that expresses that the "parametric constant"
727 * should be non-negative.
728 * This function is only called when the coefficient of the big parameter
729 * is equal to zero.
730 */
732 {
744 }
746 /* Return a integer division for use in a parametric cut based on the given row.
747 * In particular, let the parametric constant of the row be
748 *
749 * \sum_i a_i y_i
750 *
751 * where y_0 = 1, but none of the y_i corresponds to the big parameter M.
752 * The div returned is equal to
753 *
754 * floor(\sum_i {-a_i} y_i) = floor((\sum_i (-a_i mod d) y_i)/d)
755 */
757 {
771 }
773 /* Return a integer division for use in transferring an integrality constraint
774 * to the context.
775 * In particular, let the parametric constant of the row be
776 *
777 * \sum_i a_i y_i
778 *
779 * where y_0 = 1, but none of the y_i corresponds to the big parameter M.
780 * The the returned div is equal to
781 *
782 * floor(\sum_i {a_i} y_i) = floor((\sum_i (a_i mod d) y_i)/d)
783 */
785 {
798 }
800 /* Construct and return an inequality that expresses an upper bound
801 * on the given div.
802 * In particular, if the div is given by
803 *
804 * d = floor(e/m)
805 *
806 * then the inequality expresses
807 *
808 * m d <= e
809 */
811 {
829 }
831 /* Given a row in the tableau and a div that was created
832 * using get_row_split_div and that has been constrained to equality, i.e.,
833 *
834 * d = floor(\sum_i {a_i} y_i) = \sum_i {a_i} y_i
835 *
836 * replace the expression "\sum_i {a_i} y_i" in the row by d,
837 * i.e., we subtract "\sum_i {a_i} y_i" and add 1 d.
838 * The coefficients of the non-parameters in the tableau have been
839 * verified to be integral. We can therefore simply replace coefficient b
840 * by floor(b). For the coefficients of the parameters we have
841 * floor(a_i) = a_i - {a_i}, while for the other coefficients, we have
842 * floor(b) = b.
843 */
845 {
865 }
868 error:
871 }
873 /* Check if the (parametric) constant of the given row is obviously
874 * negative, meaning that we don't need to consult the context tableau.
875 * If there is a big parameter and its coefficient is non-zero,
876 * then this coefficient determines the outcome.
877 * Otherwise, we check whether the constant is negative and
878 * all non-zero coefficients of parameters are negative and
879 * belong to non-negative parameters.
880 */
882 {
892 }
897 /* Eliminated parameter */
907 }
918 }
920 }
922 /* Check if the (parametric) constant of the given row is obviously
923 * non-negative, meaning that we don't need to consult the context tableau.
924 * If there is a big parameter and its coefficient is non-zero,
925 * then this coefficient determines the outcome.
926 * Otherwise, we check whether the constant is non-negative and
927 * all non-zero coefficients of parameters are positive and
928 * belong to non-negative parameters.
929 */
931 {
941 }
946 /* Eliminated parameter */
956 }
967 }
969 }
971 /* Given a row r and two columns, return the column that would
972 * lead to the lexicographically smallest increment in the sample
973 * solution when leaving the basis in favor of the row.
974 * Pivoting with column c will increment the sample value by a non-negative
975 * constant times a_{V,c}/a_{r,c}, with a_{V,c} the elements of column c
976 * corresponding to the non-parametric variables.
977 * If variable v appears in a column c_v, the a_{v,c} = 1 iff c = c_v,
978 * with all other entries in this virtual row equal to zero.
979 * If variable v appears in a row, then a_{v,c} is the element in column c
980 * of that row.
981 *
982 * Let v be the first variable with a_{v,c1}/a_{r,c1} != a_{v,c2}/a_{r,c2}.
983 * Then if a_{v,c1}/a_{r,c1} < a_{v,c2}/a_{r,c2}, i.e.,
984 * a_{v,c2} a_{r,c1} - a_{v,c1} a_{r,c2} > 0, c1 results in the minimal
985 * increment. Otherwise, it's c2.
986 */
989 {
1005 }
1026 }
1028 }
1030 /* Given a row in the tableau, find and return the column that would
1031 * result in the lexicographically smallest, but positive, increment
1032 * in the sample point.
1033 * If there is no such column, then return tab->n_col.
1034 * If anything goes wrong, return -1.
1035 */
1037 {
1041 isl_int tmp;
1058 else
1061 }
1065 error:
1068 }
1070 /* Return the first known violated constraint, i.e., a non-negative
1071 * constraint that currently has an either obviously negative value
1072 * or a previously determined to be negative value.
1073 *
1074 * If any constraint has a negative coefficient for the big parameter,
1075 * if any, then we return one of these first.
1076 */
1078 {
1090 }
1103 }
1105 }
1107 /* Check whether the invariant that all columns are lexico-positive
1108 * is satisfied. This function is not called from the current code
1109 * but is useful during debugging.
1110 */
1113 {
1128 else
1130 }
1138 }
1141 }
1142 }
1144 /* Report to the caller that the given constraint is part of an encountered
1145 * conflict.
1146 */
1148 {
1150 }
1152 /* Given a conflicting row in the tableau, report all constraints
1153 * involved in the row to the caller. That is, the row itself
1154 * (if represents a constraint) and all constraint columns with
1155 * non-zero (and therefore negative) coefficient.
1156 */
1158 {
1183 }
1186 }
1188 /* Resolve all known or obviously violated constraints through pivoting.
1189 * In particular, as long as we can find any violated constraint, we
1190 * look for a pivoting column that would result in the lexicographically
1191 * smallest increment in the sample point. If there is no such column
1192 * then the tableau is infeasible.
1193 */
1196 {
1211 }
1216 }
1218 }
1220 /* Given a row that represents an equality, look for an appropriate
1221 * pivoting column.
1222 * In particular, if there are any non-zero coefficients among
1223 * the non-parameter variables, then we take the last of these
1224 * variables. Eliminating this variable in terms of the other
1225 * variables and/or parameters does not influence the property
1226 * that all column in the initial tableau are lexicographically
1227 * positive. The row corresponding to the eliminated variable
1228 * will only have non-zero entries below the diagonal of the
1229 * initial tableau. That is, we transform
1230 *
1231 * I I
1232 * 1 into a
1233 * I I
1234 *
1235 * If there is no such non-parameter variable, then we are dealing with
1236 * pure parameter equality and we pick any parameter with coefficient 1 or -1
1237 * for elimination. This will ensure that the eliminated parameter
1238 * always has an integer value whenever all the other parameters are integral.
1239 * If there is no such parameter then we return -1.
1240 */
1242 {
1255 }
1261 }
1263 }
1265 /* Add an equality that is known to be valid to the tableau.
1266 * We first check if we can eliminate a variable or a parameter.
1267 * If not, we add the equality as two inequalities.
1268 * In this case, the equality was a pure parameter equality and there
1269 * is no need to resolve any constraint violations.
1270 */
1272 {
1301 }
1304 error:
1307 }
1309 /* Check if the given row is a pure constant.
1310 */
1312 {
1317 }
1319 /* Add an equality that may or may not be valid to the tableau.
1320 * If the resulting row is a pure constant, then it must be zero.
1321 * Otherwise, the resulting tableau is empty.
1322 *
1323 * If the row is not a pure constant, then we add two inequalities,
1324 * each time checking that they can be satisfied.
1325 * In the end we try to use one of the two constraints to eliminate
1326 * a column.
1327 */
1330 {
1352 }
1356 }
1383 }
1396 }
1399 }
1401 /* Add an inequality to the tableau, resolving violations using
1402 * restore_lexmin.
1403 */
1405 {
1416 }
1427 }
1436 error:
1439 }
1441 /* Check if the coefficients of the parameters are all integral.
1442 */
1444 {
1450 /* Eliminated parameter */
1457 }
1465 }
1467 }
1469 /* Check if the coefficients of the non-parameter variables are all integral.
1470 */
1472 {
1484 }
1486 }
1488 /* Check if the constant term is integral.
1489 */
1491 {
1494 }
1496 #define I_CST 1 << 0
1497 #define I_PAR 1 << 1
1498 #define I_VAR 1 << 2
1500 /* Check for next (non-parameter) variable after "var" (first if var == -1)
1501 * that is non-integer and therefore requires a cut and return
1502 * the index of the variable.
1503 * For parametric tableaus, there are three parts in a row,
1504 * the constant, the coefficients of the parameters and the rest.
1505 * For each part, we check whether the coefficients in that part
1506 * are all integral and if so, set the corresponding flag in *f.
1507 * If the constant and the parameter part are integral, then the
1508 * current sample value is integral and no cut is required
1509 * (irrespective of whether the variable part is integral).
1510 */
1512 {
1531 }
1533 }
1535 /* Check for first (non-parameter) variable that is non-integer and
1536 * therefore requires a cut and return the corresponding row.
1537 * For parametric tableaus, there are three parts in a row,
1538 * the constant, the coefficients of the parameters and the rest.
1539 * For each part, we check whether the coefficients in that part
1540 * are all integral and if so, set the corresponding flag in *f.
1541 * If the constant and the parameter part are integral, then the
1542 * current sample value is integral and no cut is required
1543 * (irrespective of whether the variable part is integral).
1544 */
1546 {
1550 }
1552 /* Add a (non-parametric) cut to cut away the non-integral sample
1553 * value of the given row.
1554 *
1555 * If the row is given by
1556 *
1557 * m r = f + \sum_i a_i y_i
1558 *
1559 * then the cut is
1560 *
1561 * c = - {-f/m} + \sum_i {a_i/m} y_i >= 0
1562 *
1563 * The big parameter, if any, is ignored, since it is assumed to be big
1564 * enough to be divisible by any integer.
1565 * If the tableau is actually a parametric tableau, then this function
1566 * is only called when all coefficients of the parameters are integral.
1567 * The cut therefore has zero coefficients for the parameters.
1568 *
1569 * The current value is known to be negative, so row_sign, if it
1570 * exists, is set accordingly.
1571 *
1572 * Return the row of the cut or -1.
1573 */
1575 {
1605 }
1607 /* Given a non-parametric tableau, add cuts until an integer
1608 * sample point is obtained or until the tableau is determined
1609 * to be integer infeasible.
1610 * As long as there is any non-integer value in the sample point,
1611 * we add appropriate cuts, if possible, for each of these
1612 * non-integer values and then resolve the violated
1613 * cut constraints using restore_lexmin.
1614 * If one of the corresponding rows is equal to an integral
1615 * combination of variables/constraints plus a non-integral constant,
1616 * then there is no way to obtain an integer point and we return
1617 * a tableau that is marked empty.
1618 */
1620 {
1636 }
1646 }
1648 error:
1651 }
1653 /* Check whether all the currently active samples also satisfy the inequality
1654 * "ineq" (treated as an equality if eq is set).
1655 * Remove those samples that do not.
1656 */
1658 {
1660 isl_int v;
1680 }
1684 error:
1687 }
1689 /* Check whether the sample value of the tableau is finite,
1690 * i.e., either the tableau does not use a big parameter, or
1691 * all values of the variables are equal to the big parameter plus
1692 * some constant. This constant is the actual sample value.
1693 */
1695 {
1708 }
1710 }
1712 /* Check if the context tableau of sol has any integer points.
1713 * Leave tab in empty state if no integer point can be found.
1714 * If an integer point can be found and if moreover it is finite,
1715 * then it is added to the list of sample values.
1716 *
1717 * This function is only called when none of the currently active sample
1718 * values satisfies the most recently added constraint.
1719 */
1721 {
1741 }
1747 error:
1750 }
1752 /* Check if any of the currently active sample values satisfies
1753 * the inequality "ineq" (an equality if eq is set).
1754 */
1756 {
1758 isl_int v;
1775 }
1779 }
1781 /* Add a div specified by "div" to the tableau "tab" and return
1782 * 1 if the div is obviously non-negative.
1783 */
1786 {
1808 }
1811 }
1813 /* Add a div specified by "div" to both the main tableau and
1814 * the context tableau. In case of the main tableau, we only
1815 * need to add an extra div. In the context tableau, we also
1816 * need to express the meaning of the div.
1817 * Return the index of the div or -1 if anything went wrong.
1818 */
1821 {
1842 error:
1845 }
1848 {
1858 }
1860 }
1862 /* Return the index of a div that corresponds to "div".
1863 * We first check if we already have such a div and if not, we create one.
1864 */
1867 {
1879 }
1881 /* Add a parametric cut to cut away the non-integral sample value
1882 * of the give row.
1883 * Let a_i be the coefficients of the constant term and the parameters
1884 * and let b_i be the coefficients of the variables or constraints
1885 * in basis of the tableau.
1886 * Let q be the div q = floor(\sum_i {-a_i} y_i).
1887 *
1888 * The cut is expressed as
1889 *
1890 * c = \sum_i -{-a_i} y_i + \sum_i {b_i} x_i + q >= 0
1891 *
1892 * If q did not already exist in the context tableau, then it is added first.
1893 * If q is in a column of the main tableau then the "+ q" can be accomplished
1894 * by setting the corresponding entry to the denominator of the constraint.
1895 * If q happens to be in a row of the main tableau, then the corresponding
1896 * row needs to be added instead (taking care of the denominators).
1897 * Note that this is very unlikely, but perhaps not entirely impossible.
1898 *
1899 * The current value of the cut is known to be negative (or at least
1900 * non-positive), so row_sign is set accordingly.
1901 *
1902 * Return the row of the cut or -1.
1903 */
1906 {
1949 }
1958 }
1966 }
1968 isl_int gcd;
1982 }
1998 }
2000 /* Construct a tableau for bmap that can be used for computing
2001 * the lexicographic minimum (or maximum) of bmap.
2002 * If not NULL, then dom is the domain where the minimum
2003 * should be computed. In this case, we set up a parametric
2004 * tableau with row signs (initialized to "unknown").
2005 * If M is set, then the tableau will use a big parameter.
2006 * If max is set, then a maximum should be computed instead of a minimum.
2007 * This means that for each variable x, the tableau will contain the variable
2008 * x' = M - x, rather than x' = M + x. This in turn means that the coefficient
2009 * of the variables in all constraints are negated prior to adding them
2010 * to the tableau.
2011 */
2014 {
2031 }
2036 }
2041 }
2054 }
2069 }
2071 error:
2074 }
2076 /* Given a main tableau where more than one row requires a split,
2077 * determine and return the "best" row to split on.
2078 *
2079 * Given two rows in the main tableau, if the inequality corresponding
2080 * to the first row is redundant with respect to that of the second row
2081 * in the current tableau, then it is better to split on the second row,
2082 * since in the positive part, both row will be positive.
2083 * (In the negative part a pivot will have to be performed and just about
2084 * anything can happen to the sign of the other row.)
2085 *
2086 * As a simple heuristic, we therefore select the row that makes the most
2087 * of the other rows redundant.
2088 *
2089 * Perhaps it would also be useful to look at the number of constraints
2090 * that conflict with any given constraint.
2091 */
2093 {
2146 r++;
2149 }
2153 }
2156 }
2159 }
2163 {
2168 }
2171 {
2174 }
2178 {
2190 }
2194 error:
2197 }
2201 {
2212 }
2216 error:
2219 }
2222 {
2226 }
2228 /* Check which signs can be obtained by "ineq" on all the currently
2229 * active sample values. See row_sign for more information.
2230 */
2233 {
2236 isl_int tmp;
2253 }
2259 }
2262 }
2266 }
2270 {
2273 }
2275 /* Check whether "ineq" can be added to the tableau without rendering
2276 * it infeasible.
2277 */
2279 {
2302 }
2306 {
2308 }
2310 /* Add a div specified by "div" to the context tableau and return
2311 * 1 if the div is obviously non-negative.
2312 * context_tab_add_div will always return 1, because all variables
2313 * in a isl_context_lex tableau are non-negative.
2314 * However, if we are using a big parameter in the context, then this only
2315 * reflects the non-negativity of the variable used to _encode_ the
2316 * div, i.e., div' = M + div, so we can't draw any conclusions.
2317 */
2319 {
2329 }
2333 {
2335 }
2339 {
2353 }
2356 {
2361 }
2364 {
2375 }
2378 {
2383 }
2384 }
2387 {
2390 }
2392 /* For each variable in the context tableau, check if the variable can
2393 * only attain non-negative values. If so, mark the parameter as non-negative
2394 * in the main tableau. This allows for a more direct identification of some
2395 * cases of violated constraints.
2396 */
2399 {
2431 n++;
2432 }
2436 }
2441 }
2445 error:
2449 }
2453 {
2470 error:
2473 }
2476 {
2480 }
2483 {
2487 }
2490 context_lex_detect_nonnegative_parameters,
2491 context_lex_peek_basic_set,
2492 context_lex_peek_tab,
2493 context_lex_add_eq,
2494 context_lex_add_ineq,
2495 context_lex_ineq_sign,
2496 context_lex_test_ineq,
2497 context_lex_get_div,
2498 context_lex_add_div,
2499 context_lex_detect_equalities,
2500 context_lex_best_split,
2501 context_lex_is_empty,
2502 context_lex_is_ok,
2503 context_lex_save,
2504 context_lex_restore,
2505 context_lex_invalidate,
2506 context_lex_free,
2507 };
2510 {
2522 error:
2525 }
2528 {
2548 error:
2551 }
2558 };
2562 {
2567 }
2571 {
2576 }
2579 {
2582 }
2584 /* Initialize the "shifted" tableau of the context, which
2585 * contains the constraints of the original tableau shifted
2586 * by the sum of all negative coefficients. This ensures
2587 * that any rational point in the shifted tableau can
2588 * be rounded up to yield an integer point in the original tableau.
2589 */
2591 {
2608 }
2609 }
2617 }
2619 /* Check if the shifted tableau is non-empty, and if so
2620 * use the sample point to construct an integer point
2621 * of the context tableau.
2622 */
2624 {
2638 }
2641 {
2654 }
2657 {
2659 }
2662 {
2677 }
2687 }
2699 }
2702 }
2711 }
2714 }
2728 }
2731 {
2749 }
2754 error:
2757 }
2760 {
2771 error:
2774 }
2778 {
2788 }
2796 }
2800 error:
2803 }
2806 {
2828 }
2837 }
2838 }
2845 }
2848 error:
2851 }
2855 {
2868 }
2872 error:
2875 }
2878 {
2882 }
2886 {
2889 }
2891 /* Check whether "ineq" can be added to the tableau without rendering
2892 * it infeasible.
2893 */
2895 {
2926 }
2933 }
2936 }
2938 /* Return the column of the last of the variables associated to
2939 * a column that has a non-zero coefficient.
2940 * This function is called in a context where only coefficients
2941 * of parameters or divs can be non-zero.
2942 */
2944 {
2959 }
2962 }
2964 /* Look through all the recently added equalities in the context
2965 * to see if we can propagate any of them to the main tableau.
2966 *
2967 * The newly added equalities in the context are encoded as pairs
2968 * of inequalities starting at inequality "first".
2969 *
2970 * We tentatively add each of these equalities to the main tableau
2971 * and if this happens to result in a row with a final coefficient
2972 * that is one or negative one, we use it to kill a column
2973 * in the main tableau. Otherwise, we discard the tentatively
2974 * added row.
2975 */
2978 {
3014 }
3022 }
3027 error:
3031 }
3035 {
3050 }
3060 error:
3064 }
3068 {
3070 }
3073 {
3093 }
3096 }
3100 {
3112 }
3115 {
3120 }
3126 };
3129 {
3143 else
3148 else
3152 error:
3155 }
3158 {
3166 }
3174 }
3182 }
3187 error:
3191 }
3194 {
3197 }
3200 {
3204 }
3207 {
3213 }
3216 context_gbr_detect_nonnegative_parameters,
3217 context_gbr_peek_basic_set,
3218 context_gbr_peek_tab,
3219 context_gbr_add_eq,
3220 context_gbr_add_ineq,
3221 context_gbr_ineq_sign,
3222 context_gbr_test_ineq,
3223 context_gbr_get_div,
3224 context_gbr_add_div,
3225 context_gbr_detect_equalities,
3226 context_gbr_best_split,
3227 context_gbr_is_empty,
3228 context_gbr_is_ok,
3229 context_gbr_save,
3230 context_gbr_restore,
3231 context_gbr_invalidate,
3232 context_gbr_free,
3233 };
3236 {
3257 error:
3260 }
3263 {
3269 else
3271 }
3273 /* Construct an isl_sol_map structure for accumulating the solution.
3274 * If track_empty is set, then we also keep track of the parts
3275 * of the context where there is no solution.
3276 * If max is set, then we are solving a maximization, rather than
3277 * a minimization problem, which means that the variables in the
3278 * tableau have value "M - x" rather than "M + x".
3279 */
3282 {
3301 ISL_MAP_DISJOINT);
3314 }
3318 error:
3322 }
3324 /* Check whether all coefficients of (non-parameter) variables
3325 * are non-positive, meaning that no pivots can be performed on the row.
3326 */
3328 {
3340 }
3343 }
3345 /* Check whether the inequality represented by vec is strict over the integers,
3346 * i.e., there are no integer values satisfying the constraint with
3347 * equality. This happens if the gcd of the coefficients is not a divisor
3348 * of the constant term. If so, scale the constraint down by the gcd
3349 * of the coefficients.
3350 */
3352 {
3353 isl_int gcd;
3362 }
3366 }
3368 /* Determine the sign of the given row of the main tableau.
3369 * The result is one of
3370 * isl_tab_row_pos: always non-negative; no pivot needed
3371 * isl_tab_row_neg: always non-positive; pivot
3372 * isl_tab_row_any: can be both positive and negative; split
3373 *
3374 * We first handle some simple cases
3375 * - the row sign may be known already
3376 * - the row may be obviously non-negative
3377 * - the parametric constant may be equal to that of another row
3378 * for which we know the sign. This sign will be either "pos" or
3379 * "any". If it had been "neg" then we would have pivoted before.
3380 *
3381 * If none of these cases hold, we check the value of the row for each
3382 * of the currently active samples. Based on the signs of these values
3383 * we make an initial determination of the sign of the row.
3384 *
3385 * all zero -> unk(nown)
3386 * all non-negative -> pos
3387 * all non-positive -> neg
3388 * both negative and positive -> all
3389 *
3390 * If we end up with "all", we are done.
3391 * Otherwise, we perform a check for positive and/or negative
3392 * values as follows.
3393 *
3394 * samples neg unk pos
3395 * <0 ? Y N Y N
3396 * pos any pos
3397 * >0 ? Y N Y N
3398 * any neg any neg
3399 *
3400 * There is no special sign for "zero", because we can usually treat zero
3401 * as either non-negative or non-positive, whatever works out best.
3402 * However, if the row is "critical", meaning that pivoting is impossible
3403 * then we don't want to limp zero with the non-positive case, because
3404 * then we we would lose the solution for those values of the parameters
3405 * where the value of the row is zero. Instead, we treat 0 as non-negative
3406 * ensuring a split if the row can attain both zero and negative values.
3407 * The same happens when the original constraint was one that could not
3408 * be satisfied with equality by any integer values of the parameters.
3409 * In this case, we normalize the constraint, but then a value of zero
3410 * for the normalized constraint is actually a positive value for the
3411 * original constraint, so again we need to treat zero as non-negative.
3412 * In both these cases, we have the following decision tree instead:
3413 *
3414 * all non-negative -> pos
3415 * all negative -> neg
3416 * both negative and non-negative -> all
3417 *
3418 * samples neg pos
3419 * <0 ? Y N
3420 * any pos
3421 * >=0 ? Y N
3422 * any neg
3423 */
3426 {
3442 }
3456 /* test for negative values */
3466 else
3472 }
3473 }
3476 /* test for positive values */
3486 }
3490 error:
3493 }
3497 /* Find solutions for values of the parameters that satisfy the given
3498 * inequality.
3499 *
3500 * We currently take a snapshot of the context tableau that is reset
3501 * when we return from this function, while we make a copy of the main
3502 * tableau, leaving the original main tableau untouched.
3503 * These are fairly arbitrary choices. Making a copy also of the context
3504 * tableau would obviate the need to undo any changes made to it later,
3505 * while taking a snapshot of the main tableau could reduce memory usage.
3506 * If we were to switch to taking a snapshot of the main tableau,
3507 * we would have to keep in mind that we need to save the row signs
3508 * and that we need to do this before saving the current basis
3509 * such that the basis has been restore before we restore the row signs.
3510 */
3512 {
3530 error:
3532 }
3534 /* Record the absence of solutions for those values of the parameters
3535 * that do not satisfy the given inequality with equality.
3536 */
3539 {
3562 error:
3564 }
3566 /* Compute the lexicographic minimum of the set represented by the main
3567 * tableau "tab" within the context "sol->context_tab".
3568 * On entry the sample value of the main tableau is lexicographically
3569 * less than or equal to this lexicographic minimum.
3570 * Pivots are performed until a feasible point is found, which is then
3571 * necessarily equal to the minimum, or until the tableau is found to
3572 * be infeasible. Some pivots may need to be performed for only some
3573 * feasible values of the context tableau. If so, the context tableau
3574 * is split into a part where the pivot is needed and a part where it is not.
3575 *
3576 * Whenever we enter the main loop, the main tableau is such that no
3577 * "obvious" pivots need to be performed on it, where "obvious" means
3578 * that the given row can be seen to be negative without looking at
3579 * the context tableau. In particular, for non-parametric problems,
3580 * no pivots need to be performed on the main tableau.
3581 * The caller of find_solutions is responsible for making this property
3582 * hold prior to the first iteration of the loop, while restore_lexmin
3583 * is called before every other iteration.
3584 *
3585 * Inside the main loop, we first examine the signs of the rows of
3586 * the main tableau within the context of the context tableau.
3587 * If we find a row that is always non-positive for all values of
3588 * the parameters satisfying the context tableau and negative for at
3589 * least one value of the parameters, we perform the appropriate pivot
3590 * and start over. An exception is the case where no pivot can be
3591 * performed on the row. In this case, we require that the sign of
3592 * the row is negative for all values of the parameters (rather than just
3593 * non-positive). This special case is handled inside row_sign, which
3594 * will say that the row can have any sign if it determines that it can
3595 * attain both negative and zero values.
3596 *
3597 * If we can't find a row that always requires a pivot, but we can find
3598 * one or more rows that require a pivot for some values of the parameters
3599 * (i.e., the row can attain both positive and negative signs), then we split
3600 * the context tableau into two parts, one where we force the sign to be
3601 * non-negative and one where we force is to be negative.
3602 * The non-negative part is handled by a recursive call (through find_in_pos).
3603 * Upon returning from this call, we continue with the negative part and
3604 * perform the required pivot.
3605 *
3606 * If no such rows can be found, all rows are non-negative and we have
3607 * found a (rational) feasible point. If we only wanted a rational point
3608 * then we are done.
3609 * Otherwise, we check if all values of the sample point of the tableau
3610 * are integral for the variables. If so, we have found the minimal
3611 * integral point and we are done.
3612 * If the sample point is not integral, then we need to make a distinction
3613 * based on whether the constant term is non-integral or the coefficients
3614 * of the parameters. Furthermore, in order to decide how to handle
3615 * the non-integrality, we also need to know whether the coefficients
3616 * of the other columns in the tableau are integral. This leads
3617 * to the following table. The first two rows do not correspond
3618 * to a non-integral sample point and are only mentioned for completeness.
3619 *
3620 * constant parameters other
3621 *
3622 * int int int |
3623 * int int rat | -> no problem
3624 *
3625 * rat int int -> fail
3626 *
3627 * rat int rat -> cut
3628 *
3629 * int rat rat |
3630 * rat rat rat | -> parametric cut
3631 *
3632 * int rat int |
3633 * rat rat int | -> split context
3634 *
3635 * If the parametric constant is completely integral, then there is nothing
3636 * to be done. If the constant term is non-integral, but all the other
3637 * coefficient are integral, then there is nothing that can be done
3638 * and the tableau has no integral solution.
3639 * If, on the other hand, one or more of the other columns have rational
3640 * coefficients, but the parameter coefficients are all integral, then
3641 * we can perform a regular (non-parametric) cut.
3642 * Finally, if there is any parameter coefficient that is non-integral,
3643 * then we need to involve the context tableau. There are two cases here.
3644 * If at least one other column has a rational coefficient, then we
3645 * can perform a parametric cut in the main tableau by adding a new
3646 * integer division in the context tableau.
3647 * If all other columns have integral coefficients, then we need to
3648 * enforce that the rational combination of parameters (c + \sum a_i y_i)/m
3649 * is always integral. We do this by introducing an integer division
3650 * q = floor((c + \sum a_i y_i)/m) and stipulating that its argument should
3651 * always be integral in the context tableau, i.e., m q = c + \sum a_i y_i.
3652 * Since q is expressed in the tableau as
3653 * c + \sum a_i y_i - m q >= 0
3654 * -c - \sum a_i y_i + m q + m - 1 >= 0
3655 * it is sufficient to add the inequality
3656 * -c - \sum a_i y_i + m q >= 0
3657 * In the part of the context where this inequality does not hold, the
3658 * main tableau is marked as being empty.
3659 */
3661 {
3690 n_split++;
3695 }
3713 }
3727 }
3738 }
3768 }
3771 done:
3775 error:
3778 }
3780 /* Compute the lexicographic minimum of the set represented by the main
3781 * tableau "tab" within the context "sol->context_tab".
3782 *
3783 * As a preprocessing step, we first transfer all the purely parametric
3784 * equalities from the main tableau to the context tableau, i.e.,
3785 * parameters that have been pivoted to a row.
3786 * These equalities are ignored by the main algorithm, because the
3787 * corresponding rows may not be marked as being non-negative.
3788 * In parts of the context where the added equality does not hold,
3789 * the main tableau is marked as being empty.
3790 */
3792 {
3811 else
3841 }
3849 error:
3852 }
3854 /* Check if integer division "div" of "dom" also occurs in "bmap".
3855 * If so, return its position within the divs.
3856 * If not, return -1.
3857 */
3860 {
3878 }
3880 }
3882 /* The correspondence between the variables in the main tableau,
3883 * the context tableau, and the input map and domain is as follows.
3884 * The first n_param and the last n_div variables of the main tableau
3885 * form the variables of the context tableau.
3886 * In the basic map, these n_param variables correspond to the
3887 * parameters and the input dimensions. In the domain, they correspond
3888 * to the parameters and the set dimensions.
3889 * The n_div variables correspond to the integer divisions in the domain.
3890 * To ensure that everything lines up, we may need to copy some of the
3891 * integer divisions of the domain to the map. These have to be placed
3892 * in the same order as those in the context and they have to be placed
3893 * after any other integer divisions that the map may have.
3894 * This function performs the required reordering.
3895 */
3898 {
3905 common++;
3912 }
3920 }
3923 }
3925 error:
3928 }
3930 /* Base case of isl_tab_basic_map_partial_lexopt, after removing
3931 * some obvious symmetries.
3932 *
3933 * We make sure the divs in the domain are properly ordered,
3934 * because they will be added one by one in the given order
3935 * during the construction of the solution map.
3936 */
3942 {
3950 }
3967 }
3973 error:
3977 }
3979 /* Base case of isl_tab_basic_map_partial_lexopt, after removing
3980 * some obvious symmetries.
3981 *
3982 * We call basic_map_partial_lexopt_base and extract the results.
3983 */
3987 {
4003 }
4005 /* Structure used during detection of parallel constraints.
4006 * n_in: number of "input" variables: isl_dim_param + isl_dim_in
4007 * n_out: number of "output" variables: isl_dim_out + isl_dim_div
4008 * val: the coefficients of the output variables
4009 */
4015 };
4017 /* Check whether the coefficients of the output variables
4018 * of the constraint in "entry" are equal to info->val.
4019 */
4021 {
4026 }
4028 /* Check whether "bmap" has a pair of constraints that have
4029 * the same coefficients for the output variables.
4030 * Note that the coefficients of the existentially quantified
4031 * variables need to be zero since the existentially quantified
4032 * of the result are usually not the same as those of the input.
4033 * the isl_dim_out and isl_dim_div dimensions.
4034 * If so, return 1 and return the row indices of the two constraints
4035 * in *first and *second.
4036 */
4039 {
4075 }
4080 }
4085 error:
4088 }
4090 /* Given a set of upper bounds in "var", add constraints to "bset"
4091 * that make the i-th bound smallest.
4092 *
4093 * In particular, if there are n bounds b_i, then add the constraints
4094 *
4095 * b_i <= b_j for j > i
4096 * b_i < b_j for j < i
4097 */
4100 {
4117 }
4122 error:
4125 }
4127 /* Given a set of upper bounds on the last "input" variable m,
4128 * construct a set that assigns the minimal upper bound to m, i.e.,
4129 * construct a set that divides the space into cells where one
4130 * of the upper bounds is smaller than all the others and assign
4131 * this upper bound to m.
4132 *
4133 * In particular, if there are n bounds b_i, then the result
4134 * consists of n basic sets, each one of the form
4135 *
4136 * m = b_i
4137 * b_i <= b_j for j > i
4138 * b_i < b_j for j < i
4139 */
4142 {
4165 }
4170 error:
4176 }
4178 /* Given that the last input variable of "bmap" represents the minimum
4179 * of the bounds in "cst", check whether we need to split the domain
4180 * based on which bound attains the minimum.
4181 *
4182 * A split is needed when the minimum appears in an integer division
4183 * or in an equality. Otherwise, it is only needed if it appears in
4184 * an upper bound that is different from the upper bounds on which it
4185 * is defined.
4186 */
4189 {
4219 }
4222 }
4224 /* Given that the last set variable of "bset" represents the minimum
4225 * of the bounds in "cst", check whether we need to split the domain
4226 * based on which bound attains the minimum.
4227 *
4228 * We simply call need_split_basic_map here. This is safe because
4229 * the position of the minimum is computed from "cst" and not
4230 * from "bmap".
4231 */
4234 {
4236 }
4238 /* Given that the last set variable of "set" represents the minimum
4239 * of the bounds in "cst", check whether we need to split the domain
4240 * based on which bound attains the minimum.
4241 */
4243 {
4251 }
4253 /* Given a set of which the last set variable is the minimum
4254 * of the bounds in "cst", split each basic set in the set
4255 * in pieces where one of the bounds is (strictly) smaller than the others.
4256 * This subdivision is given in "min_expr".
4257 * The variable is subsequently projected out.
4258 *
4259 * We only do the split when it is needed.
4260 * For example if the last input variable m = min(a,b) and the only
4261 * constraints in the given basic set are lower bounds on m,
4262 * i.e., l <= m = min(a,b), then we can simply project out m
4263 * to obtain l <= a and l <= b, without having to split on whether
4264 * m is equal to a or b.
4265 */
4268 {
4291 }
4297 error:
4302 }
4304 /* Given a map of which the last input variable is the minimum
4305 * of the bounds in "cst", split each basic set in the set
4306 * in pieces where one of the bounds is (strictly) smaller than the others.
4307 * This subdivision is given in "min_expr".
4308 * The variable is subsequently projected out.
4309 *
4310 * The implementation is essentially the same as that of "split".
4311 */
4314 {
4338 }
4344 error:
4349 }
4359 };
4361 /* This function is called from basic_map_partial_lexopt_symm.
4362 * The last variable of "bmap" and "dom" corresponds to the minimum
4363 * of the bounds in "cst". "map_space" is the space of the original
4364 * input relation (of basic_map_partial_lexopt_symm) and "set_space"
4365 * is the space of the original domain.
4366 *
4367 * We recursively call basic_map_partial_lexopt and then plug in
4368 * the definition of the minimum in the result.
4369 */
4374 {
4387 }
4394 }
4396 /* Given a basic map with at least two parallel constraints (as found
4397 * by the function parallel_constraints), first look for more constraints
4398 * parallel to the two constraint and replace the found list of parallel
4399 * constraints by a single constraint with as "input" part the minimum
4400 * of the input parts of the list of constraints. Then, recursively call
4401 * basic_map_partial_lexopt (possibly finding more parallel constraints)
4402 * and plug in the definition of the minimum in the result.
4403 *
4404 * More specifically, given a set of constraints
4405 *
4406 * a x + b_i(p) >= 0
4407 *
4408 * Replace this set by a single constraint
4409 *
4410 * a x + u >= 0
4411 *
4412 * with u a new parameter with constraints
4413 *
4414 * u <= b_i(p)
4415 *
4416 * Any solution to the new system is also a solution for the original system
4417 * since
4418 *
4419 * a x >= -u >= -b_i(p)
4420 *
4421 * Moreover, m = min_i(b_i(p)) satisfies the constraints on u and can
4422 * therefore be plugged into the solution.
4423 */
4433 {
4462 }
4498 }
4504 error:
4514 }
4519 {
4522 }
4524 /* Recursive part of isl_tab_basic_map_partial_lexopt, after detecting
4525 * equalities and removing redundant constraints.
4526 *
4527 * We first check if there are any parallel constraints (left).
4528 * If not, we are in the base case.
4529 * If there are parallel constraints, we replace them by a single
4530 * constraint in basic_map_partial_lexopt_symm and then call
4531 * this function recursively to look for more parallel constraints.
4532 */
4536 {
4552 error:
4556 }
4558 /* Compute the lexicographic minimum (or maximum if "max" is set)
4559 * of "bmap" over the domain "dom" and return the result as a map.
4560 * If "empty" is not NULL, then *empty is assigned a set that
4561 * contains those parts of the domain where there is no solution.
4562 * If "bmap" is marked as rational (ISL_BASIC_MAP_RATIONAL),
4563 * then we compute the rational optimum. Otherwise, we compute
4564 * the integral optimum.
4565 *
4566 * We perform some preprocessing. As the PILP solver does not
4567 * handle implicit equalities very well, we first make sure all
4568 * the equalities are explicitly available.
4569 *
4570 * We also add context constraints to the basic map and remove
4571 * redundant constraints. This is only needed because of the
4572 * way we handle simple symmetries. In particular, we currently look
4573 * for symmetries on the constraints, before we set up the main tableau.
4574 * It is then no good to look for symmetries on possibly redundant constraints.
4575 */
4579 {
4596 error:
4600 }
4607 };
4610 {
4614 }
4617 {
4619 }
4621 /* Add the solution identified by the tableau and the context tableau.
4622 *
4623 * See documentation of sol_add for more details.
4624 *
4625 * Instead of constructing a basic map, this function calls a user
4626 * defined function with the current context as a basic set and
4627 * a list of affine expressions representing the relation between
4628 * the input and output. The space over which the affine expressions
4629 * are defined is the same as that of the domain. The number of
4630 * affine expressions in the list is equal to the number of output variables.
4631 */
4634 {
4652 }
4654 }
4665 error:
4669 }
4673 {
4675 }
4681 {
4710 error:
4714 }
4718 {
4720 }
4726 {
4747 }
4752 error:
4756 }
4762 {
4764 }
4766 /* Check if the given sequence of len variables starting at pos
4767 * represents a trivial (i.e., zero) solution.
4768 * The variables are assumed to be non-negative and to come in pairs,
4769 * with each pair representing a variable of unrestricted sign.
4770 * The solution is trivial if each such pair in the sequence consists
4771 * of two identical values, meaning that the variable being represented
4772 * has value zero.
4773 */
4775 {
4801 }
4804 }
4806 /* Return the index of the first trivial region or -1 if all regions
4807 * are non-trivial.
4808 */
4811 {
4817 }
4820 }
4822 /* Check if the solution is optimal, i.e., whether the first
4823 * n_op entries are zero.
4824 */
4826 {
4833 }
4835 /* Add constraints to "tab" that ensure that any solution is significantly
4836 * better that that represented by "sol". That is, find the first
4837 * relevant (within first n_op) non-zero coefficient and force it (along
4838 * with all previous coefficients) to be zero.
4839 * If the solution is already optimal (all relevant coefficients are zero),
4840 * then just mark the table as empty.
4841 */
4844 {
4860 }
4872 }
4876 error:
4879 }
4886 };
4888 /* Return the lexicographically smallest non-trivial solution of the
4889 * given ILP problem.
4890 *
4891 * All variables are assumed to be non-negative.
4892 *
4893 * n_op is the number of initial coordinates to optimize.
4894 * That is, once a solution has been found, we will only continue looking
4895 * for solution that result in significantly better values for those
4896 * initial coordinates. That is, we only continue looking for solutions
4897 * that increase the number of initial zeros in this sequence.
4898 *
4899 * A solution is non-trivial, if it is non-trivial on each of the
4900 * specified regions. Each region represents a sequence of pairs
4901 * of variables. A solution is non-trivial on such a region if
4902 * at least one of these pairs consists of different values, i.e.,
4903 * such that the non-negative variable represented by the pair is non-zero.
4904 *
4905 * Whenever a conflict is encountered, all constraints involved are
4906 * reported to the caller through a call to "conflict".
4907 *
4908 * We perform a simple branch-and-bound backtracking search.
4909 * Each level in the search represents initially trivial region that is forced
4910 * to be non-trivial.
4911 * At each level we consider n cases, where n is the length of the region.
4912 * In terms of the n/2 variables of unrestricted signs being encoded by
4913 * the region, we consider the cases
4914 * x_0 >= 1
4915 * x_0 <= -1
4916 * x_0 = 0 and x_1 >= 1
4917 * x_0 = 0 and x_1 <= -1
4918 * x_0 = 0 and x_1 = 0 and x_2 >= 1
4919 * x_0 = 0 and x_1 = 0 and x_2 <= -1
4920 * ...
4921 * The cases are considered in this order, assuming that each pair
4922 * x_i_a x_i_b represents the value x_i_b - x_i_a.
4923 * That is, x_0 >= 1 is enforced by adding the constraint
4924 * x_0_b - x_0_a >= 1
4925 */
4930 {
4974 }
4983 }
4990 backtrack:
4991 level--;
4997 }
5003 }
5011 }
5012 }
5025 level++;
5027 }
5035 error:
5042 }
5044 /* Return the lexicographically smallest rational point in "bset",
5045 * assuming that all variables are non-negative.
5046 * If "bset" is empty, then return a zero-length vector.
5047 */
5050 {
5060 else
5065 error:
5069 }
5075 };
5078 {
5086 }
5088 /* This function is called for parts of the context where there is
5089 * no solution, with "bset" corresponding to the context tableau.
5090 * Simply add the basic set to the set "empty".
5091 */
5094 {
5106 error:
5109 }
5111 /* Given a basic map "dom" that represents the context and an affine
5112 * matrix "M" that maps the dimensions of the context to the
5113 * output variables, construct an isl_pw_multi_aff with a single
5114 * cell corresponding to "dom" and affine expressions copied from "M".
5115 */
5118 {
5132 }
5135 }
5144 }
5147 {
5149 }
5153 {
5155 }
5159 {
5161 }
5163 /* Construct an isl_sol_pma structure for accumulating the solution.
5164 * If track_empty is set, then we also keep track of the parts
5165 * of the context where there is no solution.
5166 * If max is set, then we are solving a maximization, rather than
5167 * a minimization problem, which means that the variables in the
5168 * tableau have value "M - x" rather than "M + x".
5169 */
5172 {
5203 }
5207 error:
5211 }
5213 /* Base case of isl_tab_basic_map_partial_lexopt, after removing
5214 * some obvious symmetries.
5215 *
5216 * We call basic_map_partial_lexopt_base and extract the results.
5217 */
5221 {
5237 }
5239 /* Given that the last input variable of "maff" represents the minimum
5240 * of some bounds, check whether we need to plug in the expression
5241 * of the minimum.
5242 *
5243 * In particular, check if the last input variable appears in any
5244 * of the expressions in "maff".
5245 */
5247 {
5258 }
5260 /* Given a set of upper bounds on the last "input" variable m,
5261 * construct a piecewise affine expression that selects
5262 * the minimal upper bound to m, i.e.,
5263 * divide the space into cells where one
5264 * of the upper bounds is smaller than all the others and select
5265 * this upper bound on that cell.
5266 *
5267 * In particular, if there are n bounds b_i, then the result
5268 * consists of n cell, each one of the form
5269 *
5270 * b_i <= b_j for j > i
5271 * b_i < b_j for j < i
5272 *
5273 * The affine expression on this cell is
5274 *
5275 * b_i
5276 */
5279 {
5312 }
5318 error:
5326 }
5328 /* Given a piecewise multi-affine expression of which the last input variable
5329 * is the minimum of the bounds in "cst", plug in the value of the minimum.
5330 * This minimum expression is given in "min_expr_pa".
5331 * The set "min_expr" contains the same information, but in the form of a set.
5332 * The variable is subsequently projected out.
5333 *
5334 * The implementation is similar to those of "split" and "split_domain".
5335 * If the variable appears in a given expression, then minimum expression
5336 * is plugged in. Otherwise, if the variable appears in the constraints
5337 * and a split is required, then the domain is split. Otherwise, no split
5338 * is performed.
5339 */
5343 {
5372 }
5379 error:
5385 }
5391 /* This function is called from basic_map_partial_lexopt_symm.
5392 * The last variable of "bmap" and "dom" corresponds to the minimum
5393 * of the bounds in "cst". "map_space" is the space of the original
5394 * input relation (of basic_map_partial_lexopt_symm) and "set_space"
5395 * is the space of the original domain.
5396 *
5397 * We recursively call basic_map_partial_lexopt and then plug in
5398 * the definition of the minimum in the result.
5399 */
5404 {
5420 }
5427 }
5432 {
5435 }
5437 /* Recursive part of isl_basic_map_partial_lexopt_pw_multi_aff, after detecting
5438 * equalities and removing redundant constraints.
5439 *
5440 * We first check if there are any parallel constraints (left).
5441 * If not, we are in the base case.
5442 * If there are parallel constraints, we replace them by a single
5443 * constraint in basic_map_partial_lexopt_symm_pma and then call
5444 * this function recursively to look for more parallel constraints.
5445 */
5449 {
5465 error:
5469 }
5471 /* Compute the lexicographic minimum (or maximum if "max" is set)
5472 * of "bmap" over the domain "dom" and return the result as a piecewise
5473 * multi-affine expression.
5474 * If "empty" is not NULL, then *empty is assigned a set that
5475 * contains those parts of the domain where there is no solution.
5476 * If "bmap" is marked as rational (ISL_BASIC_MAP_RATIONAL),
5477 * then we compute the rational optimum. Otherwise, we compute
5478 * the integral optimum.
5479 *
5480 * We perform some preprocessing. As the PILP solver does not
5481 * handle implicit equalities very well, we first make sure all
5482 * the equalities are explicitly available.
5483 *
5484 * We also add context constraints to the basic map and remove
5485 * redundant constraints. This is only needed because of the
5486 * way we handle simple symmetries. In particular, we currently look
5487 * for symmetries on the constraints, before we set up the main tableau.
5488 * It is then no good to look for symmetries on possibly redundant constraints.
5489 */
5493 {
5510 error:
5514 }