| blob | 8f149a3203fd5bf4b780afdab6d8215dbc1cccfc |
1 /*
2 * Copyright 2012-2014 Ecole Normale Superieure
3 * Copyright 2014 INRIA Rocquencourt
4 *
5 * Use of this software is governed by the MIT license
6 *
7 * Written by Sven Verdoolaege,
8 * Ecole Normale Superieure, 45 rue d’Ulm, 75230 Paris, France
9 * and Inria Paris - Rocquencourt, Domaine de Voluceau - Rocquencourt,
10 * B.P. 105 - 78153 Le Chesnay, France
11 */
13 #include <isl/id.h>
14 #include <isl/space.h>
15 #include <isl/constraint.h>
16 #include <isl/ilp.h>
17 #include <isl/val.h>
18 #include <isl_ast_build_expr.h>
19 #include <isl_ast_private.h>
20 #include <isl_ast_build_private.h>
21 #include <isl_sort.h>
23 /* Compute the "opposite" of the (numerator of the) argument of a div
24 * with denominator "d".
25 *
26 * In particular, compute
27 *
28 * -aff + (d - 1)
29 */
32 {
38 }
40 /* Internal data structure used inside isl_ast_expr_add_term.
41 * The domain of "build" is used to simplify the expressions.
42 * "build" needs to be set by the caller of isl_ast_expr_add_term.
43 * "cst" is the constant term of the expression in which the added term
44 * appears. It may be modified by isl_ast_expr_add_term.
45 *
46 * "v" is the coefficient of the term that is being constructed and
47 * is set internally by isl_ast_expr_add_term.
48 */
53 };
55 /* Given the numerator "aff" of the argument of an integer division
56 * with denominator "d", check if it can be made non-negative over
57 * data->build->domain by stealing part of the constant term of
58 * the expression in which the integer division appears.
59 *
60 * In particular, the outer expression is of the form
61 *
62 * v * floor(aff/d) + cst
63 *
64 * We already know that "aff" itself may attain negative values.
65 * Here we check if aff + d*floor(cst/v) is non-negative, such
66 * that we could rewrite the expression to
67 *
68 * v * floor((aff + d*floor(cst/v))/d) + cst - v*floor(cst/v)
69 *
70 * Note that aff + d*floor(cst/v) can only possibly be non-negative
71 * if data->cst and data->v have the same sign.
72 * Similarly, if floor(cst/v) is zero, then there is no point in
73 * checking again.
74 */
77 {
92 }
100 }
102 /* Given the numerator "aff' of the argument of an integer division
103 * with denominator "d", steal part of the constant term of
104 * the expression in which the integer division appears to make it
105 * non-negative over data->build->domain.
106 *
107 * In particular, the outer expression is of the form
108 *
109 * v * floor(aff/d) + cst
110 *
111 * We know that "aff" itself may attain negative values,
112 * but that aff + d*floor(cst/v) is non-negative.
113 * Find the minimal positive value that we need to add to "aff"
114 * to make it positive and adjust data->cst accordingly.
115 * That is, compute the minimal value "m" of "aff" over
116 * data->build->domain and take
117 *
118 * s = ceil(m/d)
119 *
120 * such that
121 *
122 * aff + d * s >= 0
123 *
124 * and rewrite the expression to
125 *
126 * v * floor((aff + s*d)/d) + (cst - v*s)
127 */
130 {
148 }
150 /* Create an isl_ast_expr evaluating the div at position "pos" in "ls".
151 * The result is simplified in terms of data->build->domain.
152 * This function may change (the sign of) data->v.
153 *
154 * "ls" is known to be non-NULL.
155 *
156 * Let the div be of the form floor(e/d).
157 * If the ast_build_prefer_pdiv option is set then we check if "e"
158 * is non-negative, so that we can generate
159 *
160 * (pdiv_q, expr(e), expr(d))
161 *
162 * instead of
163 *
164 * (fdiv_q, expr(e), expr(d))
165 *
166 * If the ast_build_prefer_pdiv option is set and
167 * if "e" is not non-negative, then we check if "-e + d - 1" is non-negative.
168 * If so, we can rewrite
169 *
170 * floor(e/d) = -ceil(-e/d) = -floor((-e + d - 1)/d)
171 *
172 * and still use pdiv_q, while changing the sign of data->v.
173 *
174 * Otherwise, we check if
175 *
176 * e + d*floor(cst/v)
177 *
178 * is non-negative and if so, replace floor(e/d) by
179 *
180 * floor((e + s*d)/d) - s
181 *
182 * with s the minimal shift that makes the argument non-negative.
183 */
186 {
211 }
216 }
221 }
226 }
228 /* Create an isl_ast_expr evaluating the specified dimension of "ls".
229 * The result is simplified in terms of data->build->domain.
230 * This function may change (the sign of) data->v.
231 *
232 * The isl_ast_expr is constructed based on the type of the dimension.
233 * - divs are constructed by var_div
234 * - set variables are constructed from the iterator isl_ids in data->build
235 * - parameters are constructed from the isl_ids in "ls"
236 */
239 {
249 }
256 }
258 /* Does "expr" represent the zero integer?
259 */
261 {
267 }
269 /* Create an expression representing the sum of "expr1" and "expr2",
270 * provided neither of the two expressions is identically zero.
271 */
274 {
281 }
286 }
289 error:
293 }
295 /* Subtract expr2 from expr1.
296 *
297 * If expr2 is zero, we simply return expr1.
298 * If expr1 is zero, we return
299 *
300 * (isl_ast_op_minus, expr2)
301 *
302 * Otherwise, we return
303 *
304 * (isl_ast_op_sub, expr1, expr2)
305 */
308 {
315 }
320 }
323 error:
327 }
329 /* Return an isl_ast_expr that represents
330 *
331 * v * (aff mod d)
332 *
333 * v is assumed to be non-negative.
334 * The result is simplified in terms of build->domain.
335 */
339 {
354 }
357 }
359 /* Create an isl_ast_expr that scales "expr" by "v".
360 *
361 * If v is 1, we simply return expr.
362 * If v is -1, we return
363 *
364 * (isl_ast_op_minus, expr)
365 *
366 * Otherwise, we return
367 *
368 * (isl_ast_op_mul, expr(v), expr)
369 */
372 {
380 }
388 }
391 error:
395 }
397 /* Add an expression for "*v" times the specified dimension of "ls"
398 * to expr.
399 * If the dimension is an integer division, then this function
400 * may modify data->cst in order to make the numerator non-negative.
401 * The result is simplified in terms of data->build->domain.
402 *
403 * Let e be the expression for the specified dimension,
404 * multiplied by the absolute value of "*v".
405 * If "*v" is negative, we create
406 *
407 * (isl_ast_op_sub, expr, e)
408 *
409 * except when expr is trivially zero, in which case we create
410 *
411 * (isl_ast_op_minus, e)
412 *
413 * instead.
414 *
415 * If "*v" is positive, we simply create
416 *
417 * (isl_ast_op_add, expr, e)
418 *
419 */
424 {
441 }
442 }
444 /* Add an expression for "v" to expr.
445 */
448 {
457 }
466 }
467 error:
471 }
473 /* Internal data structure used inside extract_modulos.
474 *
475 * If any modulo expressions are detected in "aff", then the
476 * expression is removed from "aff" and added to either "pos" or "neg"
477 * depending on the sign of the coefficient of the modulo expression
478 * inside "aff".
479 *
480 * "add" is an expression that needs to be added to "aff" at the end of
481 * the computation. It is NULL as long as no modulos have been extracted.
482 *
483 * "i" is the position in "aff" of the div under investigation
484 * "v" is the coefficient in "aff" of the div
485 * "div" is the argument of the div, with the denominator removed
486 * "d" is the original denominator of the argument of the div
487 *
488 * "nonneg" is an affine expression that is non-negative over "build"
489 * and that can be used to extract a modulo expression from "div".
490 * In particular, if "sign" is 1, then the coefficients of "nonneg"
491 * are equal to those of "div" modulo "d". If "sign" is -1, then
492 * the coefficients of "nonneg" are opposite to those of "div" modulo "d".
493 * If "sign" is 0, then no such affine expression has been found (yet).
494 */
511 };
513 /* Given that data->v * div_i in data->aff is equal to
514 *
515 * f * (term - (arg mod d))
516 *
517 * with data->d * f = data->v, add
518 *
519 * f * term
520 *
521 * to data->add and
522 *
523 * abs(f) * (arg mod d)
524 *
525 * to data->neg or data->pos depending on the sign of -f.
526 */
529 {
540 else
550 else
556 }
558 /* Given that data->v * div_i in data->aff is of the form
559 *
560 * f * d * floor(div/d)
561 *
562 * with div nonnegative on data->build, rewrite it as
563 *
564 * f * (div - (div mod d)) = f * div - f * (div mod d)
565 *
566 * and add
567 *
568 * f * div
569 *
570 * to data->add and
571 *
572 * abs(f) * (div mod d)
573 *
574 * to data->neg or data->pos depending on the sign of -f.
575 */
577 {
580 }
582 /* Given that data->v * div_i in data->aff is of the form
583 *
584 * f * d * floor(div/d) (1)
585 *
586 * check if div is non-negative on data->build and, if so,
587 * extract the corresponding modulo from data->aff.
588 * If not, then check if
589 *
590 * -div + d - 1
591 *
592 * is non-negative on data->build. If so, replace (1) by
593 *
594 * -f * d * floor((-div + d - 1)/d)
595 *
596 * and extract the corresponding modulo from data->aff.
597 *
598 * This function may modify data->div.
599 */
601 {
617 }
620 error:
623 }
625 /* Is the affine expression of constraint "c" "simpler" than data->nonneg
626 * for use in extracting a modulo expression?
627 *
628 * We currently only consider the constant term of the affine expression.
629 * In particular, we prefer the affine expression with the smallest constant
630 * term.
631 * This means that if there are two constraints, say x >= 0 and -x + 10 >= 0,
632 * then we would pick x >= 0
633 *
634 * More detailed heuristics could be used if it turns out that there is a need.
635 */
638 {
652 }
654 /* Check if the coefficients of "c" are either equal or opposite to those
655 * of data->div modulo data->d. If so, and if "c" is "simpler" than
656 * data->nonneg, then replace data->nonneg by the affine expression of "c"
657 * and set data->sign accordingly.
658 *
659 * Both "c" and data->div are assumed not to involve any integer divisions.
660 *
661 * Before we start the actual comparison, we first quickly check if
662 * "c" and data->div have the same non-zero coefficients.
663 * If not, then we assume that "c" is not of the desired form.
664 * Note that while the coefficients of data->div can be reasonably expected
665 * not to involve any coefficients that are multiples of d, "c" may
666 * very well involve such coefficients. This means that we may actually
667 * miss some cases.
668 *
669 * If the constant term is "too large", then the constraint is rejected,
670 * where "too large" is fairly arbitrarily set to 1 << 15.
671 * We do this to avoid picking up constraints that bound a variable
672 * by a very large number, say the largest or smallest possible
673 * variable in the representation of some integer type.
674 */
677 {
696 }
697 }
706 }
722 }
726 }
729 }
730 }
736 }
744 }
746 /* Given that data->v * div_i in data->aff is of the form
747 *
748 * f * d * floor(div/d) (1)
749 *
750 * see if we can find an expression div' that is non-negative over data->build
751 * and that is related to div through
752 *
753 * div' = div + d * e
754 *
755 * or
756 *
757 * div' = -div + d - 1 + d * e
758 *
759 * with e some affine expression.
760 * If so, we write (1) as
761 *
762 * f * div + f * (div' mod d)
763 *
764 * or
765 *
766 * -f * (-div + d - 1) - f * (div' mod d)
767 *
768 * exploiting (in the second case) the fact that
769 *
770 * f * d * floor(div/d) = -f * d * floor((-div + d - 1)/d)
771 *
772 *
773 * We first try to find an appropriate expression for div'
774 * from the constraints of data->build->domain (which is therefore
775 * guaranteed to be non-negative on data->build), where we remove
776 * any integer divisions from the constraints and skip this step
777 * if "div" itself involves any integer divisions.
778 * If we cannot find an appropriate expression this way, then
779 * we pass control to extract_nonneg_mod where check
780 * if div or "-div + d -1" themselves happen to be
781 * non-negative on data->build.
782 *
783 * While looking for an appropriate constraint in data->build->domain,
784 * we ignore the constant term, so after finding such a constraint,
785 * we still need to fix up the constant term.
786 * In particular, if a is the constant term of "div"
787 * (or d - 1 - the constant term of "div" if data->sign < 0)
788 * and b is the constant term of the constraint, then we need to find
789 * a non-negative constant c such that
790 *
791 * b + c \equiv a mod d
792 *
793 * We therefore take
794 *
795 * c = (a - b) mod d
796 *
797 * and add it to b to obtain the constant term of div'.
798 * If this constant term is "too negative", then we add an appropriate
799 * multiple of d to make it positive.
800 *
801 *
802 * Note that the above is a only a very simple heuristic for finding an
803 * appropriate expression. We could try a bit harder by also considering
804 * sums of constraints that involve disjoint sets of variables or
805 * we could consider arbitrary linear combinations of constraints,
806 * although that could potentially be much more expensive as it involves
807 * the solution of an LP problem.
808 *
809 * In particular, if v_i is a column vector representing constraint i,
810 * w represents div and e_i is the i-th unit vector, then we are looking
811 * for a solution of the constraints
812 *
813 * \sum_i lambda_i v_i = w + \sum_i alpha_i d e_i
814 *
815 * with \lambda_i >= 0 and alpha_i of unrestricted sign.
816 * If we are not just interested in a non-negative expression, but
817 * also in one with a minimal range, then we don't just want
818 * c = \sum_i lambda_i v_i to be non-negative over the domain,
819 * but also beta - c = \sum_i mu_i v_i, where beta is a scalar
820 * that we want to minimize and we now also have to take into account
821 * the constant terms of the constraints.
822 * Alternatively, we could first compute the dual of the domain
823 * and plug in the constraints on the coefficients.
824 */
826 {
829 isl_stat r;
830 isl_size n;
847 data);
855 }
863 }
872 }
879 }
883 error:
886 }
888 /* Check if "data->aff" involves any (implicit) modulo computations based
889 * on div "data->i".
890 * If so, remove them from aff and add expressions corresponding
891 * to those modulo computations to data->pos and/or data->neg.
892 *
893 * "aff" is assumed to be an integer affine expression.
894 *
895 * In particular, check if (v * div_j) is of the form
896 *
897 * f * m * floor(a / m)
898 *
899 * and, if so, rewrite it as
900 *
901 * f * (a - (a mod m)) = f * a - f * (a mod m)
902 *
903 * and extract out -f * (a mod m).
904 * In particular, if f > 0, we add (f * (a mod m)) to *neg.
905 * If f < 0, we add ((-f) * (a mod m)) to *pos.
906 *
907 * Note that in order to represent "a mod m" as
908 *
909 * (isl_ast_op_pdiv_r, a, m)
910 *
911 * we need to make sure that a is non-negative.
912 * If not, we check if "-a + m - 1" is non-negative.
913 * If so, we can rewrite
914 *
915 * floor(a/m) = -ceil(-a/m) = -floor((-a + m - 1)/m)
916 *
917 * and still extract a modulo.
918 */
920 {
927 }
931 }
933 /* Check if "aff" involves any (implicit) modulo computations.
934 * If so, remove them from aff and add expressions corresponding
935 * to those modulo computations to *pos and/or *neg.
936 * We only do this if the option ast_build_prefer_pdiv is set.
937 *
938 * "aff" is assumed to be an integer affine expression.
939 *
940 * A modulo expression is of the form
941 *
942 * a mod m = a - m * floor(a / m)
943 *
944 * To detect them in aff, we look for terms of the form
945 *
946 * f * m * floor(a / m)
947 *
948 * rewrite them as
949 *
950 * f * (a - (a mod m)) = f * a - f * (a mod m)
951 *
952 * and extract out -f * (a mod m).
953 * In particular, if f > 0, we add (f * (a mod m)) to *neg.
954 * If f < 0, we add ((-f) * (a mod m)) to *pos.
955 */
959 {
962 isl_size n;
983 }
989 }
997 }
999 /* Check if aff involves any non-integer coefficients.
1000 * If so, split aff into
1001 *
1002 * aff = aff1 + (aff2 / d)
1003 *
1004 * with both aff1 and aff2 having only integer coefficients.
1005 * Return aff1 and add (aff2 / d) to *expr.
1006 */
1009 {
1011 isl_size n;
1027 }
1047 }
1052 }
1053 }
1063 }
1075 error:
1081 }
1083 /* Construct an isl_ast_expr that evaluates the affine expression "aff",
1084 * The result is simplified in terms of build->domain.
1085 *
1086 * We first extract hidden modulo computations from the affine expression
1087 * and then add terms for each variable with a non-zero coefficient.
1088 * Finally, if the affine expression has a non-trivial denominator,
1089 * we divide the resulting isl_ast_expr by this denominator.
1090 */
1093 {
1095 isl_size n;
1130 }
1133 }
1134 }
1141 }
1143 /* Add terms to "expr" for each variable in "aff" with a coefficient
1144 * with sign equal to "sign".
1145 * The result is simplified in terms of data->build->domain.
1146 */
1149 {
1167 }
1171 }
1172 }
1177 }
1179 /* Should the constant term "v" be considered positive?
1180 *
1181 * A positive constant will be added to "pos" by the caller,
1182 * while a negative constant will be added to "neg".
1183 * If either "pos" or "neg" is exactly zero, then we prefer
1184 * to add the constant "v" to that side, irrespective of the sign of "v".
1185 * This results in slightly shorter expressions and may reduce the risk
1186 * of overflows.
1187 */
1190 {
1196 }
1198 /* Check if the equality
1199 *
1200 * aff = 0
1201 *
1202 * represents a stride constraint on the integer division "pos".
1203 *
1204 * In particular, if the integer division "pos" is equal to
1205 *
1206 * floor(e/d)
1207 *
1208 * then check if aff is equal to
1209 *
1210 * e - d floor(e/d)
1211 *
1212 * or its opposite.
1213 *
1214 * If so, the equality is exactly
1215 *
1216 * e mod d = 0
1217 *
1218 * Note that in principle we could also accept
1219 *
1220 * e - d floor(e'/d)
1221 *
1222 * where e and e' differ by a constant.
1223 */
1225 {
1248 }
1250 /* Are all coefficients of "aff" (zero or) negative?
1251 */
1253 {
1255 isl_size n;
1272 }
1274 /* Give an equality of the form
1275 *
1276 * aff = e - d floor(e/d) = 0
1277 *
1278 * or
1279 *
1280 * aff = -e + d floor(e/d) = 0
1281 *
1282 * with the integer division "pos" equal to floor(e/d),
1283 * construct the AST expression
1284 *
1285 * (isl_ast_op_eq, (isl_ast_op_zdiv_r, expr(e), expr(d)), expr(0))
1286 *
1287 * If e only has negative coefficients, then construct
1288 *
1289 * (isl_ast_op_eq, (isl_ast_op_zdiv_r, expr(-e), expr(d)), expr(0))
1290 *
1291 * instead.
1292 */
1295 {
1296 isl_bool all_neg;
1323 }
1325 /* Construct an isl_ast_expr that evaluates the condition "constraint",
1326 * The result is simplified in terms of build->domain.
1327 *
1328 * We first check if the constraint is an equality of the form
1329 *
1330 * e - d floor(e/d) = 0
1331 *
1332 * i.e.,
1333 *
1334 * e mod d = 0
1335 *
1336 * If so, we convert it to
1337 *
1338 * (isl_ast_op_eq, (isl_ast_op_zdiv_r, expr(e), expr(d)), expr(0))
1339 *
1340 * Otherwise, let the constraint by either "a >= 0" or "a == 0".
1341 * We first extract hidden modulo computations from "a"
1342 * and then collect all the terms with a positive coefficient in cons_pos
1343 * and the terms with a negative coefficient in cons_neg.
1344 *
1345 * The result is then of the form
1346 *
1347 * (isl_ast_op_ge, expr(pos), expr(-neg)))
1348 *
1349 * or
1350 *
1351 * (isl_ast_op_eq, expr(pos), expr(-neg)))
1352 *
1353 * However, if the first expression is an integer constant (and the second
1354 * is not), then we swap the two expressions. This ensures that we construct,
1355 * e.g., "i <= 5" rather than "5 >= i".
1356 *
1357 * Furthermore, is there are no terms with positive coefficients (or no terms
1358 * with negative coefficients), then the constant term is added to "pos"
1359 * (or "neg"), ignoring the sign of the constant term.
1360 */
1363 {
1365 isl_size n;
1393 }
1413 }
1422 }
1426 error:
1429 }
1431 /* Wrapper around isl_constraint_cmp_last_non_zero for use
1432 * as a callback to isl_constraint_list_sort.
1433 * If isl_constraint_cmp_last_non_zero cannot tell the constraints
1434 * apart, then use isl_constraint_plain_cmp instead.
1435 */
1438 {
1445 }
1447 /* Construct an isl_ast_expr that evaluates the conditions defining "bset".
1448 * The result is simplified in terms of build->domain.
1449 *
1450 * If "bset" is not bounded by any constraint, then we construct
1451 * the expression "1", i.e., "true".
1452 *
1453 * Otherwise, we sort the constraints, putting constraints that involve
1454 * integer divisions after those that do not, and construct an "and"
1455 * of the ast expressions of the individual constraints.
1456 *
1457 * Each constraint is added to the generated constraints of the build
1458 * after it has been converted to an AST expression so that it can be used
1459 * to simplify the following constraints. This may change the truth value
1460 * of subsequent constraints that do not satisfy the earlier constraints,
1461 * but this does not affect the outcome of the conjunction as it is
1462 * only true if all the conjuncts are true (no matter in what order
1463 * they are evaluated). In particular, the constraints that do not
1464 * involve integer divisions may serve to simplify some constraints
1465 * that do involve integer divisions.
1466 */
1469 {
1486 }
1505 }
1510 }
1512 /* Construct an isl_ast_expr that evaluates the conditions defining "set".
1513 * The result is simplified in terms of build->domain.
1514 *
1515 * If "set" is an (obviously) empty set, then return the expression "0".
1516 *
1517 * If there are multiple disjuncts in the description of the set,
1518 * then subsequent disjuncts are simplified in a context where
1519 * the previous disjuncts have been removed from build->domain.
1520 * In particular, constraints that ensure that there is no overlap
1521 * with these previous disjuncts, can be removed.
1522 * This is mostly useful for disjuncts that are only defined by
1523 * a single constraint (relative to the build domain) as the opposite
1524 * of that single constraint can then be removed from the other disjuncts.
1525 * In order not to increase the number of disjuncts in the build domain
1526 * after subtracting the previous disjuncts of "set", the simple hull
1527 * is computed after taking the difference with each of these disjuncts.
1528 * This means that constraints that prevent overlap with a union
1529 * of multiple previous disjuncts are not removed.
1530 *
1531 * "set" lives in the internal schedule space.
1532 */
1535 {
1552 }
1573 }
1579 }
1581 /* Construct an isl_ast_expr that evaluates the conditions defining "set".
1582 * The result is simplified in terms of build->domain.
1583 *
1584 * If "set" is an (obviously) empty set, then return the expression "0".
1585 *
1586 * "set" lives in the external schedule space.
1587 *
1588 * The internal AST expression generation assumes that there are
1589 * no unknown divs, so make sure an explicit representation is available.
1590 * Since the set comes from the outside, it may have constraints that
1591 * are redundant with respect to the build domain. Remove them first.
1592 */
1595 {
1596 isl_bool needs_map;
1605 }
1610 }
1612 /* State of data about previous pieces in
1613 * isl_ast_build_expr_from_pw_aff_internal.
1614 *
1615 * isl_state_none: no data about previous pieces
1616 * isl_state_single: data about a single previous piece
1617 * isl_state_min: data represents minimum of several pieces
1618 * isl_state_max: data represents maximum of several pieces
1619 */
1621 isl_state_none,
1622 isl_state_single,
1623 isl_state_min,
1624 isl_state_max
1625 };
1627 /* Internal date structure representing a single piece in the input of
1628 * isl_ast_build_expr_from_pw_aff_internal.
1629 *
1630 * If "state" is isl_state_none, then "set_list" and "aff_list" are not used.
1631 * If "state" is isl_state_single, then "set_list" and "aff_list" contain the
1632 * single previous subpiece.
1633 * If "state" is isl_state_min, then "set_list" and "aff_list" contain
1634 * a sequence of several previous subpieces that are equal to the minimum
1635 * of the entries in "aff_list" over the union of "set_list"
1636 * If "state" is isl_state_max, then "set_list" and "aff_list" contain
1637 * a sequence of several previous subpieces that are equal to the maximum
1638 * of the entries in "aff_list" over the union of "set_list"
1639 *
1640 * During the construction of the pieces, "set" is NULL.
1641 * After the construction, "set" is set to the union of the elements
1642 * in "set_list", at which point "set_list" is set to NULL.
1643 */
1649 };
1651 /* Internal data structure for isl_ast_build_expr_from_pw_aff_internal.
1652 *
1653 * "build" specifies the domain against which the result is simplified.
1654 * "dom" is the domain of the entire isl_pw_aff.
1655 *
1656 * "n" is the number of pieces constructed already.
1657 * In particular, during the construction of the pieces, "n" points to
1658 * the piece that is being constructed. After the construction of the
1659 * pieces, "n" is set to the total number of pieces.
1660 * "max" is the total number of allocated entries.
1661 * "p" contains the individual pieces.
1662 */
1670 };
1672 /* Initialize "data" based on "build" and "pa".
1673 */
1676 {
1694 }
1696 /* Free all memory allocated for "data".
1697 */
1699 {
1710 }
1712 }
1714 /* Initialize the current entry of "data" to an unused piece.
1715 */
1717 {
1721 }
1723 /* Store "set" and "aff" in the current entry of "data" as a single subpiece.
1724 */
1727 {
1731 }
1733 /* Extend the current entry of "data" with "set" and "aff"
1734 * as a minimum expression.
1735 */
1738 {
1747 }
1749 /* Extend the current entry of "data" with "set" and "aff"
1750 * as a maximum expression.
1751 */
1754 {
1763 }
1765 /* Extend the domain of the current entry of "data", which is assumed
1766 * to contain a single subpiece, with "set". If "replace" is set,
1767 * then also replace the affine function by "aff". Otherwise,
1768 * simply free "aff".
1769 */
1772 {
1784 else
1790 }
1792 /* Construct an isl_ast_expr from "list" within "build".
1793 * If "state" is isl_state_single, then "list" contains a single entry and
1794 * an isl_ast_expr is constructed for that entry.
1795 * Otherwise a min or max expression is constructed from "list"
1796 * depending on "state".
1797 */
1801 {
1811 }
1826 }
1830 error:
1834 }
1836 /* Extend the expression in "next" to take into account
1837 * the piece at position "pos" in "data", allowing for a further extension
1838 * for the next piece(s).
1839 * In particular, "next" is set to a select operation that selects
1840 * an isl_ast_expr corresponding to data->aff_list on data->set and
1841 * to an expression that will be filled in by later calls.
1842 * Return a pointer to this location.
1843 * Afterwards, the state of "data" is set to isl_state_none.
1844 *
1845 * The constraints of data->set are added to the generated
1846 * constraints of the build such that they can be exploited to simplify
1847 * the AST expression constructed from data->aff_list.
1848 */
1851 {
1877 }
1879 /* Extend the expression in "next" to take into account
1880 * the final piece, located at position "pos" in "data".
1881 * In particular, "next" is set to evaluate data->aff_list
1882 * and the domain is ignored.
1883 * Return isl_stat_ok on success and isl_stat_error on failure.
1884 *
1885 * The constraints of data->set are however added to the generated
1886 * constraints of the build such that they can be exploited to simplify
1887 * the AST expression constructed from data->aff_list.
1888 */
1891 {
1910 }
1912 /* Return -1 if the piece "p1" should be sorted before "p2"
1913 * and 1 if it should be sorted after "p2".
1914 * Return 0 if they do not need to be sorted in a specific order.
1915 *
1916 * Pieces are sorted according to the number of disjuncts
1917 * in their domains.
1918 */
1920 {
1929 }
1931 /* Construct an isl_ast_expr from the pieces in "data".
1932 * Return the result or NULL on failure.
1933 *
1934 * When this function is called, data->n points to the current piece.
1935 * If this is an effective piece, then first increment data->n such
1936 * that data->n contains the number of pieces.
1937 * The "set_list" fields are subsequently replaced by the corresponding
1938 * "set" fields, after which the pieces are sorted according to
1939 * the number of disjuncts in these "set" fields.
1940 *
1941 * Construct intermediate AST expressions for the initial pieces and
1942 * finish off with the final pieces.
1943 */
1945 {
1961 }
1971 }
1977 }
1979 /* Is the domain of the current entry of "data", which is assumed
1980 * to contain a single subpiece, a subset of "set"?
1981 */
1984 {
1985 isl_bool subset;
1993 }
1995 /* Is "aff" a rational expression, i.e., does it have a denominator
1996 * different from one?
1997 */
1999 {
2000 isl_bool rational;
2008 }
2010 /* Does "list" consist of a single rational affine expression?
2011 */
2013 {
2014 isl_bool rational;
2024 }
2026 /* Can the list of subpieces in the last piece of "data" be extended with
2027 * "set" and "aff" based on "test"?
2028 * In particular, is it the case for each entry (set_i, aff_i) that
2029 *
2030 * test(aff, aff_i) holds on set_i, and
2031 * test(aff_i, aff) holds on set?
2032 *
2033 * "test" returns the set of elements where the tests holds, meaning
2034 * that test(aff_i, aff) holds on set if set is a subset of test(aff_i, aff).
2035 *
2036 * This function is used to detect min/max expressions.
2037 * If the ast_build_detect_min_max option is turned off, then
2038 * do not even try and perform any detection and return false instead.
2039 *
2040 * Rational affine expressions are not considered for min/max expressions
2041 * since the combined expression will be defined on the union of the domains,
2042 * while a rational expression may only yield integer values
2043 * on its own definition domain.
2044 */
2049 {
2051 isl_bool is_rational;
2073 isl_bool is_valid;
2086 }
2095 }
2096 }
2100 }
2102 /* Can the list of pieces in "data" be extended with "set" and "aff"
2103 * to form/preserve a minimum expression?
2104 * In particular, is it the case for each entry (set_i, aff_i) that
2105 *
2106 * aff >= aff_i on set_i, and
2107 * aff_i >= aff on set?
2108 */
2111 {
2113 }
2115 /* Can the list of pieces in "data" be extended with "set" and "aff"
2116 * to form/preserve a maximum expression?
2117 * In particular, is it the case for each entry (set_i, aff_i) that
2118 *
2119 * aff <= aff_i on set_i, and
2120 * aff_i <= aff on set?
2121 */
2124 {
2126 }
2128 /* This function is called during the construction of an isl_ast_expr
2129 * that evaluates an isl_pw_aff.
2130 * If the last piece of "data" contains a single subpiece and
2131 * if its affine function is equal to "aff" on a part of the domain
2132 * that includes either "set" or the domain of that single subpiece,
2133 * then extend the domain of that single subpiece with "set".
2134 * If it was the original domain of the single subpiece where
2135 * the two affine functions are equal, then also replace
2136 * the affine function of the single subpiece by "aff".
2137 * If the last piece of "data" contains either a single subpiece
2138 * or a minimum, then check if this minimum expression can be extended
2139 * with (set, aff).
2140 * If so, extend the sequence and return.
2141 * Perform the same operation for maximum expressions.
2142 * If no such extension can be performed, then move to the next piece
2143 * in "data" (if the current piece contains any data), and then store
2144 * the current subpiece in the current piece of "data" for later handling.
2145 */
2148 {
2150 isl_bool test;
2170 }
2177 }
2184 }
2190 error:
2194 }
2196 /* Construct an isl_ast_expr that evaluates "pa".
2197 * The result is simplified in terms of build->domain.
2198 *
2199 * The domain of "pa" lives in the internal schedule space.
2200 */
2203 {
2222 error:
2226 }
2228 /* Construct an isl_ast_expr that evaluates "pa".
2229 * The result is simplified in terms of build->domain.
2230 *
2231 * The domain of "pa" lives in the external schedule space.
2232 */
2235 {
2237 isl_bool needs_map;
2246 }
2249 }
2251 /* Set the ids of the input dimensions of "mpa" to the iterator ids
2252 * of "build".
2253 *
2254 * The domain of "mpa" is assumed to live in the internal schedule domain.
2255 */
2258 {
2260 isl_size n;
2270 }
2273 }
2275 /* Construct an isl_ast_expr of type "type" with as first argument "arg0" and
2276 * the remaining arguments derived from "mpa".
2277 * That is, construct a call or access expression that calls/accesses "arg0"
2278 * with arguments/indices specified by "mpa".
2279 */
2283 {
2285 isl_size n;
2301 }
2305 }
2311 /* Construct an isl_ast_expr that accesses the member specified by "mpa".
2312 * The range of "mpa" is assumed to be wrapped relation.
2313 * The domain of this wrapped relation specifies the structure being
2314 * accessed, while the range of this wrapped relation spacifies the
2315 * member of the structure being accessed.
2316 *
2317 * The domain of "mpa" is assumed to live in the internal schedule domain.
2318 */
2321 {
2339 error:
2342 }
2344 /* Construct an isl_ast_expr of type "type" that calls or accesses
2345 * the element specified by "mpa".
2346 * The first argument is obtained from the output tuple name.
2347 * The remaining arguments are given by the piecewise affine expressions.
2348 *
2349 * If the range of "mpa" is a mapped relation, then we assume it
2350 * represents an access to a member of a structure.
2351 *
2352 * The domain of "mpa" is assumed to live in the internal schedule domain.
2353 */
2357 {
2377 else
2382 error:
2385 }
2387 /* Construct an isl_ast_expr of type "type" that calls or accesses
2388 * the element specified by "pma".
2389 * The first argument is obtained from the output tuple name.
2390 * The remaining arguments are given by the piecewise affine expressions.
2391 *
2392 * The domain of "pma" is assumed to live in the internal schedule domain.
2393 */
2397 {
2402 }
2404 /* Construct an isl_ast_expr of type "type" that calls or accesses
2405 * the element specified by "mpa".
2406 * The first argument is obtained from the output tuple name.
2407 * The remaining arguments are given by the piecewise affine expressions.
2408 *
2409 * The domain of "mpa" is assumed to live in the external schedule domain.
2410 */
2414 {
2415 isl_bool is_domain;
2416 isl_bool needs_map;
2439 }
2443 error:
2446 }
2448 /* Construct an isl_ast_expr that calls the domain element specified by "mpa".
2449 * The name of the function is obtained from the output tuple name.
2450 * The arguments are given by the piecewise affine expressions.
2451 *
2452 * The domain of "mpa" is assumed to live in the external schedule domain.
2453 */
2456 {
2458 }
2460 /* Construct an isl_ast_expr that accesses the array element specified by "mpa".
2461 * The name of the array is obtained from the output tuple name.
2462 * The index expressions are given by the piecewise affine expressions.
2463 *
2464 * The domain of "mpa" is assumed to live in the external schedule domain.
2465 */
2468 {
2470 }
2472 /* Construct an isl_ast_expr of type "type" that calls or accesses
2473 * the element specified by "pma".
2474 * The first argument is obtained from the output tuple name.
2475 * The remaining arguments are given by the piecewise affine expressions.
2476 *
2477 * The domain of "pma" is assumed to live in the external schedule domain.
2478 */
2482 {
2487 }
2489 /* Construct an isl_ast_expr that calls the domain element specified by "pma".
2490 * The name of the function is obtained from the output tuple name.
2491 * The arguments are given by the piecewise affine expressions.
2492 *
2493 * The domain of "pma" is assumed to live in the external schedule domain.
2494 */
2497 {
2499 }
2501 /* Construct an isl_ast_expr that accesses the array element specified by "pma".
2502 * The name of the array is obtained from the output tuple name.
2503 * The index expressions are given by the piecewise affine expressions.
2504 *
2505 * The domain of "pma" is assumed to live in the external schedule domain.
2506 */
2509 {
2511 }
2513 /* Construct an isl_ast_expr that calls the domain element
2514 * specified by "executed".
2515 *
2516 * "executed" is assumed to be single-valued, with a domain that lives
2517 * in the internal schedule space.
2518 */
2521 {
2530 iteration);
2532 }