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1 /*
2 * Copyright 2011 Leiden University. All rights reserved.
3 * Copyright 2012-2014 Ecole Normale Superieure. All rights reserved.
4 *
5 * Redistribution and use in source and binary forms, with or without
6 * modification, are permitted provided that the following conditions
7 * are met:
8 *
9 * 1. Redistributions of source code must retain the above copyright
10 * notice, this list of conditions and the following disclaimer.
11 *
12 * 2. Redistributions in binary form must reproduce the above
13 * copyright notice, this list of conditions and the following
14 * disclaimer in the documentation and/or other materials provided
15 * with the distribution.
16 *
17 * THIS SOFTWARE IS PROVIDED BY LEIDEN UNIVERSITY ''AS IS'' AND ANY
18 * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
19 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
20 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL LEIDEN UNIVERSITY OR
21 * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
22 * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
23 * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
24 * OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
25 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
26 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
27 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
28 *
29 * The views and conclusions contained in the software and documentation
30 * are those of the authors and should not be interpreted as
31 * representing official policies, either expressed or implied, of
32 * Leiden University.
33 */
35 #include <stdlib.h>
36 #include <string.h>
38 #include <isl/id_to_pw_aff.h>
39 #include <isl/union_set.h>
50 /* Update "pc" by taking into account the writes in "stmt".
51 * That is, clear any previously assigned values to variables
52 * that are written by "stmt".
53 */
56 {
58 }
60 /* Update "pc" based on the write accesses in "scop".
61 */
64 {
73 }
75 /* Wrapper around pet_expr_resolve_assume
76 * for use as a callback to pet_tree_map_expr.
77 */
80 {
84 }
86 /* Check if any expression inside "tree" is an assume expression and
87 * if its single argument can be converted to an affine expression
88 * in the context of "pc".
89 * If so, replace the argument by the affine expression.
90 */
93 {
95 }
97 /* Convert a pet_tree to a pet_scop with one statement within the context "pc".
98 * "tree" has already been evaluated in the context of "pc".
99 * This mainly involves resolving nested expression parameters
100 * and setting the name of the iteration space.
101 * The name is given by tree->label if it is non-NULL. Otherwise,
102 * it is of the form S_<stmt_nr>.
103 */
106 {
119 }
121 /* Convert a top-level pet_expr to a pet_scop with one statement
122 * within the context "pc".
123 * "expr" has already been evaluated in the context of "pc".
124 * We construct a pet_tree from "expr" and continue with
125 * scop_from_evaluated_tree.
126 * The name is of the form S_<stmt_nr>.
127 * The location of the statement is set to "loc".
128 */
131 {
137 }
139 /* Convert a pet_tree to a pet_scop with one statement within the context "pc".
140 * "tree" has not yet been evaluated in the context of "pc".
141 * We evaluate "tree" in the context of "pc" and continue with
142 * scop_from_evaluated_tree.
143 * The statement name is given by tree->label if it is non-NULL. Otherwise,
144 * it is of the form S_<stmt_nr>.
145 */
148 {
151 }
153 /* Convert a top-level pet_expr to a pet_scop with one statement
154 * within the context "pc", where "expr" has not yet been evaluated
155 * in the context of "pc".
156 * We construct a pet_tree from "expr" and continue with
157 * scop_from_unevaluated_tree.
158 * The statement name is of the form S_<stmt_nr>.
159 * The location of the statement is set to "loc".
160 */
163 {
169 }
171 /* Construct a pet_scop with a single statement killing the entire
172 * array "array".
173 * The location of the statement is set to "loc".
174 */
177 {
196 error:
199 }
201 /* Construct and return a pet_array corresponding to the variable
202 * accessed by "access" by calling the extract_array callback.
203 */
206 {
208 }
210 /* Construct a pet_scop for a (single) variable declaration
211 * within the context "pc".
212 *
213 * The scop contains the variable being declared (as an array)
214 * and a statement killing the array.
215 *
216 * If the declaration comes with an initialization, then the scop
217 * also contains an assignment to the variable.
218 */
221 {
247 }
249 /* Does "tree" represent a kill statement?
250 * That is, is it an expression statement that "calls" __pencil_kill?
251 */
253 {
268 }
270 /* Add a kill to "scop" that kills what is accessed by
271 * the access expression "expr".
272 *
273 * Mark the access as a write prior to evaluation to avoid
274 * the access being replaced by a possible known value
275 * during the evaluation.
276 *
277 * If the access expression has any arguments (after evaluation
278 * in the context of "pc"), then we ignore it, since we cannot
279 * tell which elements are definitely killed.
280 *
281 * Otherwise, we extend the index expression to the dimension
282 * of the accessed array and intersect with the extent of the array and
283 * add a kill expression that kills these array elements is added to "scop".
284 */
288 {
305 }
324 error:
328 }
330 /* For each argument of the __pencil_kill call in "tree" that
331 * represents an access, add a kill statement to "scop" killing the accessed
332 * elements.
333 */
336 {
356 }
359 }
362 }
364 /* Construct a pet_scop for an expression statement within the context "pc".
365 *
366 * If the expression calls __pencil_kill, then it needs to be converted
367 * into zero or more kill statements.
368 * Otherwise, a scop is extracted directly from the tree.
369 */
372 {
382 }
384 /* Return those elements in the space of "cond" that come after
385 * (based on "sign") an element in "cond" in the final dimension.
386 */
388 {
402 else
409 }
411 /* Remove those iterations of "domain" that have an earlier iteration
412 * (based on "sign") in the final dimension where "skip" is satisfied.
413 * If "apply_skip_map" is set, then "skip_map" is first applied
414 * to the embedded skip condition before removing it from the domain.
415 */
419 {
424 }
426 /* Create a single-dimensional multi-affine expression on the domain space
427 * of "pc" that is equal to the final dimension of this domain.
428 * "loop_nr" is the sequence number of the corresponding loop.
429 * If "id" is not NULL, then it is used as the output tuple name.
430 * Otherwise, the name is constructed as L_<loop_nr>.
431 */
434 {
454 }
458 }
460 /* Create an affine expression that maps elements
461 * of an array "id_test" to the previous element in the final dimension
462 * (according to "inc"), provided this element belongs to "domain".
463 * That is, create the affine expression
464 *
465 * { id[outer,x] -> id[outer,x - inc] : (outer,x - inc) in domain }
466 */
469 {
492 }
494 /* Add an implication to "scop" expressing that if an element of
495 * virtual array "id_test" has value "satisfied" then all previous elements
496 * of this array (in the final dimension) also have that value.
497 * The set of previous elements is bounded by "domain".
498 * If "sign" is negative then the iterator
499 * is decreasing and we express that all subsequent array elements
500 * (but still defined previously) have the same value.
501 */
505 {
519 else
526 }
528 /* Add a filter to "scop" that imposes that it is only executed
529 * when the variable identified by "id_test" has a zero value
530 * for all previous iterations of "domain".
531 *
532 * In particular, add a filter that imposes that the array
533 * has a zero value at the previous iteration of domain and
534 * add an implication that implies that it then has that
535 * value for all previous iterations.
536 */
540 {
549 }
554 /* Construct a pet_scop for an infinite loop around the given body
555 * within the context "pc".
556 * "loop_id" is the label on the loop or NULL if there is no such label.
557 *
558 * The domain of "pc" has already been extended with an infinite loop
559 *
560 * { [t] : t >= 0 }
561 *
562 * We extract a pet_scop for the body and then embed it in a loop with
563 * schedule
564 *
565 * { [outer,t] -> [t] }
566 *
567 * If the body contains any break, then it is taken into
568 * account in apply_affine_break (if the skip condition is affine)
569 * or in scop_add_break (if the skip condition is not affine).
570 *
571 * Note that in case of an affine skip condition,
572 * since we are dealing with a loop without loop iterator,
573 * the skip condition cannot refer to the current loop iterator and
574 * so effectively, the effect on the iteration domain is of the form
575 *
576 * { [outer,0]; [outer,t] : t >= 1 and not skip }
577 */
581 {
610 }
613 else
617 }
619 /* Construct a pet_scop for an infinite loop, i.e., a loop of the form
620 *
621 * for (;;)
622 * body
623 *
624 * within the context "pc".
625 *
626 * Extend the domain of "pc" with an extra inner loop
627 *
628 * { [t] : t >= 0 }
629 *
630 * and construct the scop in scop_from_infinite_loop.
631 */
634 {
647 }
649 /* Construct a pet_scop for a while loop of the form
650 *
651 * while (pa)
652 * body
653 *
654 * within the context "pc".
655 *
656 * The domain of "pc" has already been extended with an infinite loop
657 *
658 * { [t] : t >= 0 }
659 *
660 * Here, we add the constraints on the outer loop iterators
661 * implied by "pa" and construct the scop in scop_from_infinite_loop.
662 * Note that the intersection with these constraints
663 * may result in an empty loop.
664 */
668 {
683 }
685 /* Construct a scop for a while, given the scops for the condition
686 * and the body, the filter identifier and the iteration domain of
687 * the while loop.
688 *
689 * In particular, the scop for the condition is filtered to depend
690 * on "id_test" evaluating to true for all previous iterations
691 * of the loop, while the scop for the body is filtered to depend
692 * on "id_test" evaluating to true for all iterations up to the
693 * current iteration.
694 * The actual filter only imposes that this virtual array has
695 * value one on the previous or the current iteration.
696 * The fact that this condition also applies to the previous
697 * iterations is enforced by an implication.
698 *
699 * These filtered scops are then combined into a single scop,
700 * with the condition scop scheduled before the body scop.
701 *
702 * "sign" is positive if the iterator increases and negative
703 * if it decreases.
704 */
708 {
729 }
731 /* Create a pet_scop with a single statement with name S_<stmt_nr>,
732 * evaluating "cond" and writing the result to a virtual scalar,
733 * as expressed by "index".
734 * The expression "cond" has not yet been evaluated in the context of "pc".
735 * Do so within the context "pc".
736 * The location of the statement is set to "loc".
737 */
742 {
753 }
755 /* Given that "scop" has an affine skip condition of type pet_skip_now,
756 * apply this skip condition to the domain of "pc".
757 * That is, remove the elements satisfying the skip condition from
758 * the domain of "pc".
759 */
762 {
771 }
773 /* Add a scop for evaluating the loop increment "inc" at the end
774 * of a loop body "scop" within the context "pc".
775 *
776 * The skip conditions resulting from continue statements inside
777 * the body do not apply to "inc", but those resulting from break
778 * statements do need to get applied.
779 */
783 {
802 }
804 /* Construct a generic while scop, with iteration domain
805 * { [t] : t >= 0 } around the scop for "tree_body" within the context "pc".
806 * "loop_id" is the label on the loop or NULL if there is no such label.
807 * The domain of "pc" has already been extended with this infinite loop
808 *
809 * { [t] : t >= 0 }
810 *
811 * The scop consists of two parts,
812 * one for evaluating the condition "cond" and one for the body.
813 * If "expr_inc" is not NULL, then a scop for evaluating this expression
814 * is added at the end of the body,
815 * after replacing any skip conditions resulting from continue statements
816 * by the skip conditions resulting from break statements (if any).
817 *
818 * The schedules are combined as a sequence to reflect that the condition is
819 * evaluated before the body is executed and the body is filtered to depend
820 * on the result of the condition evaluating to true on all iterations
821 * up to the current iteration, while the evaluation of the condition itself
822 * is filtered to depend on the result of the condition evaluating to true
823 * on all previous iterations.
824 * The context of the scop representing the body is dropped
825 * because we don't know how many times the body will be executed,
826 * if at all.
827 *
828 * If the body contains any break, then it is taken into
829 * account in apply_affine_break (if the skip condition is affine)
830 * or in scop_add_break (if the skip condition is not affine).
831 *
832 * Note that in case of an affine skip condition,
833 * since we are dealing with a loop without loop iterator,
834 * the skip condition cannot refer to the current loop iterator and
835 * so effectively, the effect on the iteration domain is of the form
836 *
837 * { [outer,0]; [outer,t] : t >= 1 and not skip }
838 */
843 {
873 pet_skip_later);
881 else
891 }
897 }
905 }
907 /* Check if the while loop is of the form
908 *
909 * while (affine expression)
910 * body
911 *
912 * If so, call scop_from_affine_while to construct a scop.
913 *
914 * Otherwise, pass control to scop_from_non_affine_while.
915 *
916 * "pc" is the context in which the affine expressions in the scop are created.
917 * The domain of "pc" is extended with an infinite loop
918 *
919 * { [t] : t >= 0 }
920 *
921 * before passing control to scop_from_affine_while or
922 * scop_from_non_affine_while.
923 */
926 {
952 error:
955 }
957 /* Check whether "cond" expresses a simple loop bound
958 * on the final set dimension.
959 * In particular, if "up" is set then "cond" should contain only
960 * upper bounds on the final set dimension.
961 * Otherwise, it should contain only lower bounds.
962 */
964 {
970 else
972 }
974 /* Extend a condition on a given iteration of a loop to one that
975 * imposes the same condition on all previous iterations.
976 * "domain" expresses the lower [upper] bound on the iterations
977 * when inc is positive [negative] in its final dimension.
978 *
979 * In particular, we construct the condition (when inc is positive)
980 *
981 * forall i' : (domain(i') and i' <= i) => cond(i')
982 *
983 * (where "<=" applies to the final dimension)
984 * which is equivalent to
985 *
986 * not exists i' : domain(i') and i' <= i and not cond(i')
987 *
988 * We construct this set by subtracting the satisfying cond from domain,
989 * applying a map
990 *
991 * { [i'] -> [i] : i' <= i }
992 *
993 * and then subtracting the result from domain again.
994 */
997 {
1011 else
1022 }
1024 /* Given an initial value of the form
1025 *
1026 * { [outer,i] -> init(outer) }
1027 *
1028 * construct a domain of the form
1029 *
1030 * { [outer,i] : exists a: i = init(outer) + a * inc and a >= 0 }
1031 */
1034 {
1057 }
1059 /* Assuming "cond" represents a bound on a loop where the loop
1060 * iterator "iv" is incremented (or decremented) by one, check if wrapping
1061 * is possible.
1062 *
1063 * Under the given assumptions, wrapping is only possible if "cond" allows
1064 * for the last value before wrapping, i.e., 2^width - 1 in case of an
1065 * increasing iterator and 0 in case of a decreasing iterator.
1066 */
1069 {
1084 }
1091 }
1093 /* Given a space
1094 *
1095 * { [outer, v] },
1096 *
1097 * construct the following affine expression on this space
1098 *
1099 * { [outer, v] -> [outer, v mod 2^width] }
1100 *
1101 * where width is the number of bits used to represent the values
1102 * of the unsigned variable "iv".
1103 */
1106 {
1121 }
1123 /* Given two sets in the space
1124 *
1125 * { [l,i] },
1126 *
1127 * where l represents the outer loop iterators, compute the set
1128 * of values of l that ensure that "set1" is a subset of "set2".
1129 *
1130 * set1 is a subset of set2 if
1131 *
1132 * forall i: set1(l,i) => set2(l,i)
1133 *
1134 * or
1135 *
1136 * not exists i: set1(l,i) and not set2(l,i)
1137 *
1138 * i.e.,
1139 *
1140 * not exists i: (set1 \ set2)(l,i)
1141 */
1144 {
1151 }
1153 /* Compute the set of outer iterator values for which "cond" holds
1154 * on the next iteration of the inner loop for each element of "dom".
1155 *
1156 * We first construct mapping { [l,i] -> [l,i + inc] } (where l refers
1157 * to the outer loop iterators), plug that into "cond"
1158 * and then compute the set of outer iterators for which "dom" is a subset
1159 * of the result.
1160 */
1163 {
1179 }
1181 /* Construct a pet_scop for the initialization of the iterator
1182 * of the for loop "tree" within the context "pc" (i.e., the context
1183 * of the loop).
1184 */
1187 {
1197 }
1199 /* Extract the for loop "tree" as a while loop within the context "pc_init".
1200 * In particular, "pc_init" represents the context of the loop,
1201 * whereas "pc" represents the context of the body of the loop and
1202 * has already had its domain extended with an infinite loop
1203 *
1204 * { [t] : t >= 0 }
1205 *
1206 * The for loop has the form
1207 *
1208 * for (iv = init; cond; iv += inc)
1209 * body;
1210 *
1211 * and is treated as
1212 *
1213 * iv = init;
1214 * while (cond) {
1215 * body;
1216 * iv += inc;
1217 * }
1218 *
1219 * except that the skips resulting from any continue statements
1220 * in body do not apply to the increment, but are replaced by the skips
1221 * resulting from break statements.
1222 *
1223 * If the loop iterator is declared in the for loop, then it is killed before
1224 * and after the loop.
1225 */
1229 {
1271 }
1273 /* Given an access expression "expr", is the variable accessed by
1274 * "expr" assigned anywhere inside "tree"?
1275 */
1277 {
1286 }
1288 /* Are all nested access parameters in "pa" allowed given "tree".
1289 * In particular, is none of them written by anywhere inside "tree".
1290 *
1291 * If "tree" has any continue or break nodes in the current loop level,
1292 * then no nested access parameters are allowed.
1293 * In particular, if there is any nested access in a guard
1294 * for a piece of code containing a "continue", then we want to introduce
1295 * a separate statement for evaluating this guard so that we can express
1296 * that the result is false for all previous iterations.
1297 */
1300 {
1321 }
1332 }
1335 }
1337 /* Internal data structure for collect_local.
1338 * "pc" and "state" are needed to extract pet_arrays for the local variables.
1339 * "local" collects the results.
1340 */
1345 };
1347 /* Add the variable accessed by "var" to data->local.
1348 * We extract a representation of the variable from
1349 * the pet_array constructed using extract_array
1350 * to ensure consistency with the rest of the scop.
1351 */
1354 {
1367 }
1369 /* If the node "tree" declares a variable, then add it to
1370 * data->local.
1371 */
1373 {
1382 }
1384 /* If the node "tree" is a for loop that declares its induction variable,
1385 * then add it this induction variable to data->local.
1386 */
1388 {
1395 }
1397 /* Collect and return all local variables of the for loop represented
1398 * by "tree", with "scop" the corresponding pet_scop.
1399 * "pc" and "state" are needed to extract pet_arrays for the local variables.
1400 *
1401 * We collect not only the variables that are declared inside "tree",
1402 * but also the loop iterators that are declared anywhere inside
1403 * any possible macro statements in "scop".
1404 * The latter also appear as declared variable in the scop,
1405 * whereas other declared loop iterators only appear implicitly
1406 * in the iteration domains.
1407 */
1411 {
1427 }
1430 }
1432 /* Add an independence to "scop" if the for node "tree" was marked
1433 * independent.
1434 * "domain" is the set of loop iterators, with the current for loop
1435 * innermost. If "sign" is positive, then the inner iterator increases.
1436 * Otherwise it decreases.
1437 * "pc" and "state" are needed to extract pet_arrays for the local variables.
1438 *
1439 * If the tree was marked, then collect all local variables and
1440 * add an independence.
1441 */
1445 {
1455 }
1457 /* Add a scop for assigning to the variable corresponding to the loop
1458 * iterator the result of adding the increment to the loop iterator
1459 * at the end of a loop body "scop" within the context "pc".
1460 * "tree" represents the for loop.
1461 *
1462 * The increment is of the form
1463 *
1464 * iv = iv + inc
1465 *
1466 * Note that "iv" on the right hand side will be evaluated in terms
1467 * of the (possibly virtual) loop iterator, i.e., the inner dimension
1468 * of the domain, while "iv" on the left hand side will not be evaluated
1469 * (because it is a write) and will continue to refer to the original
1470 * variable.
1471 */
1475 {
1491 }
1493 /* Construct a pet_scop for a for tree with static affine initialization
1494 * and constant increment within the context "pc".
1495 * The domain of "pc" has already been extended with an (at this point
1496 * unbounded) inner loop iterator corresponding to the current for loop.
1497 *
1498 * The condition is allowed to contain nested accesses, provided
1499 * they are not being written to inside the body of the loop.
1500 * Otherwise, or if the condition is otherwise non-affine, the for loop is
1501 * essentially treated as a while loop, with iteration domain
1502 * { [l,i] : i >= init }, where l refers to the outer loop iterators.
1503 *
1504 * We extract a pet_scop for the body after intersecting the domain of "pc"
1505 *
1506 * { [l,i] : i >= init and condition' }
1507 *
1508 * or
1509 *
1510 * { [l,i] : i <= init and condition' }
1511 *
1512 * Where condition' is equal to condition if the latter is
1513 * a simple upper [lower] bound and a condition that is extended
1514 * to apply to all previous iterations otherwise.
1515 * Afterwards, the schedule of the pet_scop is extended with
1516 *
1517 * { [l,i] -> [i] }
1518 *
1519 * or
1520 *
1521 * { [l,i] -> [-i] }
1522 *
1523 * If the condition is non-affine, then we drop the condition from the
1524 * iteration domain and instead create a separate statement
1525 * for evaluating the condition. The body is then filtered to depend
1526 * on the result of the condition evaluating to true on all iterations
1527 * up to the current iteration, while the evaluation the condition itself
1528 * is filtered to depend on the result of the condition evaluating to true
1529 * on all previous iterations.
1530 * The context of the scop representing the body is dropped
1531 * because we don't know how many times the body will be executed,
1532 * if at all.
1533 *
1534 * If the stride of the loop is not 1, then "i >= init" is replaced by
1535 *
1536 * (exists a: i = init + stride * a and a >= 0)
1537 *
1538 * If the loop iterator i is unsigned, then wrapping may occur.
1539 * We therefore use a virtual iterator instead that does not wrap.
1540 * However, the condition in the code applies
1541 * to the wrapped value, so we need to change condition(l,i)
1542 * into condition([l,i % 2^width]). Similarly, we replace all accesses
1543 * to the original iterator by the wrapping of the virtual iterator.
1544 * Note that there may be no need to perform this final wrapping
1545 * if the loop condition (after wrapping) satisfies certain conditions.
1546 * However, the is_simple_bound condition is not enough since it doesn't
1547 * check if there even is an upper bound.
1548 *
1549 * Wrapping on unsigned iterators can be avoided entirely if
1550 * the loop condition is simple, the loop iterator is incremented
1551 * [decremented] by one and the last value before wrapping cannot
1552 * possibly satisfy the loop condition.
1553 *
1554 * Valid outer iterators for a for loop are those for which the initial
1555 * value itself, the increment on each domain iteration and
1556 * the condition on both the initial value and
1557 * the result of incrementing the iterator for each iteration of the domain
1558 * can be evaluated.
1559 * If the loop condition is non-affine, then we only consider validity
1560 * of the initial value.
1561 *
1562 * If the loop iterator was not declared inside the loop header,
1563 * then the variable corresponding to this loop iterator is assigned
1564 * the result of adding the increment at the end of the loop body.
1565 * The assignment of the initial value is taken care of by
1566 * scop_from_affine_for_init.
1567 *
1568 * If the body contains any break, then we keep track of it in "skip"
1569 * (if the skip condition is affine) or it is handled in scop_add_break
1570 * (if the skip condition is not affine).
1571 * Note that the affine break condition needs to be considered with
1572 * respect to previous iterations in the virtual domain (if any).
1573 */
1578 {
1657 }
1668 }
1673 }
1699 isl_dim_out);
1703 }
1715 }
1725 }
1734 else
1745 }
1754 }
1756 /* Construct a pet_scop for a for tree with static affine initialization
1757 * and constant increment within the context "pc_init".
1758 * In particular, "pc_init" represents the context of the loop,
1759 * whereas the domain of "pc" has already been extended with an (at this point
1760 * unbounded) inner loop iterator corresponding to the current for loop.
1761 *
1762 * If the loop iterator was not declared inside the loop header,
1763 * then add an assignment of the initial value to the loop iterator
1764 * before the loop. The construction of a pet_scop for the loop itself,
1765 * including updates to the loop iterator, is handled by scop_from_affine_for.
1766 */
1771 {
1783 }
1785 /* Construct a pet_scop for a for statement within the context of "pc".
1786 *
1787 * We update the context to reflect the writes to the loop variable and
1788 * the writes inside the body.
1789 *
1790 * Then we check if the initialization of the for loop
1791 * is a static affine value and the increment is a constant.
1792 * If so, we construct the pet_scop using scop_from_affine_for_init.
1793 * Otherwise, we treat the for loop as a while loop
1794 * in scop_from_non_affine_for.
1795 *
1796 * Note that the initialization and the increment are extracted
1797 * in a context where the current loop iterator has been added
1798 * to the context. If these turn out not be affine, then we
1799 * have reconstruct the body context without an assignment
1800 * to this loop iterator, as this variable will then not be
1801 * treated as a dimension of the iteration domain, but as any
1802 * other variable.
1803 */
1806 {
1842 error:
1848 }
1850 /* Check whether "expr" is an affine constraint within the context "pc".
1851 */
1854 {
1865 }
1867 /* Check if the given if statement is a conditional assignement
1868 * with a non-affine condition.
1869 *
1870 * In particular we check if "stmt" is of the form
1871 *
1872 * if (condition)
1873 * a = f(...);
1874 * else
1875 * a = g(...);
1876 *
1877 * where the condition is non-affine and a is some array or scalar access.
1878 */
1881 {
1916 }
1918 /* Given that "tree" is of the form
1919 *
1920 * if (condition)
1921 * a = f(...);
1922 * else
1923 * a = g(...);
1924 *
1925 * where a is some array or scalar access, construct a pet_scop
1926 * corresponding to this conditional assignment within the context "pc".
1927 * "cond_pa" is an affine expression with nested accesses representing
1928 * the condition.
1929 *
1930 * The constructed pet_scop then corresponds to the expression
1931 *
1932 * a = condition ? f(...) : g(...)
1933 *
1934 * All access relations in f(...) are intersected with condition
1935 * while all access relation in g(...) are intersected with the complement.
1936 */
1940 {
1976 }
1978 /* Construct a pet_scop for a non-affine if statement within the context "pc".
1979 *
1980 * We create a separate statement that writes the result
1981 * of the non-affine condition to a virtual scalar.
1982 * A constraint requiring the value of this virtual scalar to be one
1983 * is added to the iteration domains of the then branch.
1984 * Similarly, a constraint requiring the value of this virtual scalar
1985 * to be zero is added to the iteration domains of the else branch, if any.
1986 * We combine the schedules as a sequence to ensure that the virtual scalar
1987 * is written before it is read.
1988 *
1989 * If there are any breaks or continues in the then and/or else
1990 * branches, then we may have to compute a new skip condition.
1991 * This is handled using a pet_skip_info object.
1992 * On initialization, the object checks if skip conditions need
1993 * to be computed. If so, it does so in pet_skip_info_if_extract_index and
1994 * adds them in pet_skip_info_add.
1995 */
1998 {
2039 }
2041 /* Construct a pet_scop for an affine if statement within the context "pc".
2042 *
2043 * The condition is added to the iteration domains of the then branch,
2044 * while the opposite of the condition in added to the iteration domains
2045 * of the else branch, if any.
2046 *
2047 * If there are any breaks or continues in the then and/or else
2048 * branches, then we may have to compute a new skip condition.
2049 * This is handled using a pet_skip_info_if object.
2050 * On initialization, the object checks if skip conditions need
2051 * to be computed. If so, it does so in pet_skip_info_if_extract_cond and
2052 * adds them in pet_skip_info_add.
2053 */
2057 {
2085 }
2096 }
2104 }
2106 /* Construct a pet_scop for an if statement within the context "pc".
2107 *
2108 * If the condition fits the pattern of a conditional assignment,
2109 * then it is handled by scop_from_conditional_assignment.
2110 * Note that the condition is only considered for a conditional assignment
2111 * if it is not static-affine. However, it should still convert
2112 * to an affine expression when nesting is allowed.
2113 *
2114 * Otherwise, we check if the condition is affine.
2115 * If so, we construct the scop in scop_from_affine_if.
2116 * Otherwise, we construct the scop in scop_from_non_affine_if.
2117 *
2118 * We allow the condition to be dynamic, i.e., to refer to
2119 * scalars or array elements that may be written to outside
2120 * of the given if statement. These nested accesses are then represented
2121 * as output dimensions in the wrapping iteration domain.
2122 * If it is also written _inside_ the then or else branch, then
2123 * we treat the condition as non-affine.
2124 * As explained in extract_non_affine_if, this will introduce
2125 * an extra statement.
2126 * For aesthetic reasons, we want this statement to have a statement
2127 * number that is lower than those of the then and else branches.
2128 * In order to evaluate if we will need such a statement, however, we
2129 * first construct scops for the then and else branches.
2130 * We therefore reserve a statement number if we might have to
2131 * introduce such an extra statement.
2132 */
2135 {
2162 }
2167 }
2176 }
2179 }
2181 /* Return a one-dimensional multi piecewise affine expression that is equal
2182 * to the constant 1 and is defined over the given domain.
2183 */
2185 {
2194 }
2196 /* Construct a pet_scop for a continue statement with the given domain space.
2197 *
2198 * We simply create an empty scop with a universal pet_skip_now
2199 * skip condition. This skip condition will then be taken into
2200 * account by the enclosing loop construct, possibly after
2201 * being incorporated into outer skip conditions.
2202 */
2205 {
2213 }
2215 /* Construct a pet_scop for a break statement with the given domain space.
2216 *
2217 * We simply create an empty scop with both a universal pet_skip_now
2218 * skip condition and a universal pet_skip_later skip condition.
2219 * These skip conditions will then be taken into
2220 * account by the enclosing loop construct, possibly after
2221 * being incorporated into outer skip conditions.
2222 */
2225 {
2237 }
2239 /* Extract a clone of the kill statement "stmt".
2240 * The domain of the clone is given by "domain".
2241 */
2244 {
2264 }
2266 /* Extract a clone of the kill statements in "scop".
2267 * The domain of each clone is given by "domain".
2268 * "scop" is expected to have been created from a DeclStmt
2269 * and should have (one of) the kill(s) as its first statement.
2270 * If "scop" was created from a declaration group, then there
2271 * may be multiple kill statements inside.
2272 */
2275 {
2303 }
2306 }
2308 /* Has "tree" been created from a DeclStmt?
2309 * That is, is it either a declaration or a group of declarations?
2310 */
2312 {
2333 }
2336 }
2338 /* Does "tree" represent an assignment to a variable?
2339 *
2340 * The assignment may be one of
2341 * - a declaration with initialization
2342 * - an expression with a top-level assignment operator
2343 */
2345 {
2351 }
2353 /* Update "pc" by taking into account the assignment performed by "tree",
2354 * where "tree" satisfies is_assignment.
2355 *
2356 * In particular, if the lhs of the assignment is a scalar variable and
2357 * if the rhs is an affine expression, then keep track of this value in "pc"
2358 * so that we can plug it in when we later come across the same variable.
2359 *
2360 * Any previously assigned value to the variable has already been removed
2361 * by scop_handle_writes.
2362 */
2365 {
2379 }
2385 }
2396 }
2401 }
2403 /* Mark all arrays in "scop" as being exposed.
2404 */
2406 {
2414 }
2416 /* Try and construct a pet_scop corresponding to (part of)
2417 * a sequence of statements within the context "pc".
2418 *
2419 * After extracting a statement, we update "pc"
2420 * based on the top-level assignments in the statement
2421 * so that we can exploit them in subsequent statements in the same block.
2422 *
2423 * If there are any breaks or continues in the individual statements,
2424 * then we may have to compute a new skip condition.
2425 * This is handled using a pet_skip_info object.
2426 * On initialization, the object checks if skip conditions need
2427 * to be computed. If so, it does so in pet_skip_info_seq_extract and
2428 * adds them in pet_skip_info_add.
2429 *
2430 * If "block" is set, then we need to insert kill statements at
2431 * the end of the block for any array that has been declared by
2432 * one of the statements in the sequence. Each of these declarations
2433 * results in the construction of a kill statement at the place
2434 * of the declaration, so we simply collect duplicates of
2435 * those kill statements and append these duplicates to the constructed scop.
2436 *
2437 * If "block" is not set, then any array declared by one of the statements
2438 * in the sequence is marked as being exposed.
2439 *
2440 * If autodetect is set, then we allow the extraction of only a subrange
2441 * of the sequence of statements. However, if there is at least one statement
2442 * for which we could not construct a scop and the final range contains
2443 * either no statements or at least one kill, then we discard the entire
2444 * range.
2445 */
2448 {
2481 }
2488 }
2496 }
2498 /* Internal data structure for extract_declared_arrays.
2499 *
2500 * "pc" and "state" are used to create pet_array objects and kill statements.
2501 * "any" is initialized to 0 by the caller and set to 1 as soon as we have
2502 * found any declared array.
2503 * "scop" has been initialized by the caller and is used to attach
2504 * the created pet_array objects.
2505 * "kill_before" and "kill_after" are created and updated by
2506 * extract_declared_arrays to collect the kills of the arrays.
2507 */
2518 };
2520 /* Check if the node "node" declares any array or scalar.
2521 * If so, create the corresponding pet_array and attach it to data->scop.
2522 * Additionally, create two kill statements for the array and add them
2523 * to data->kill_before and data->kill_after.
2524 */
2526 {
2538 else
2549 else
2556 else
2563 }
2565 /* Convert a pet_tree that consists of more than a single leaf
2566 * to a pet_scop with a single statement encapsulating the entire pet_tree.
2567 * Do so within the context of "pc", taking into account the writes inside
2568 * "tree". That is, first clear any previously assigned values to variables
2569 * that are written by "tree".
2570 *
2571 * After constructing the core scop, we also look for any arrays (or scalars)
2572 * that are declared inside "tree". Each of those arrays is marked as
2573 * having been declared and kill statements for these arrays
2574 * are introduced before and after the core scop.
2575 * Note that the input tree is not a leaf so that the declaration
2576 * cannot occur at the outer level.
2577 */
2580 {
2603 }
2605 /* Construct a pet_scop that corresponds to the pet_tree "tree"
2606 * within the context "pc" by calling the appropriate function
2607 * based on the type of "tree".
2608 *
2609 * If the initially constructed pet_scop turns out to involve
2610 * dynamic control and if the user has requested an encapsulation
2611 * of all dynamic control, then this pet_scop is discarded and
2612 * a new pet_scop is created with a single statement representing
2613 * the entire "tree".
2614 * However, if the scop contains any active continue or break,
2615 * then we need to include the loop containing the continue or break
2616 * in the encapsulation. We therefore postpone the encapsulation
2617 * until we have constructed a pet_scop for this enclosing loop.
2618 */
2621 {
2656 }
2668 }
2670 /* If "tree" has a label that is of the form S_<nr>, then make
2671 * sure that state->n_stmt is greater than nr to ensure that
2672 * we will not generate S_<nr> ourselves.
2673 */
2675 {
2692 }
2694 /* Construct a pet_scop that corresponds to the pet_tree "tree".
2695 * "int_size" is the number of bytes need to represent an integer.
2696 * "extract_array" is a callback that we can use to create a pet_array
2697 * that corresponds to the variable accessed by an expression.
2698 *
2699 * Initialize the global state, construct a context and then
2700 * construct the pet_scop by recursively visiting the tree.
2701 *
2702 * state.n_stmt is initialized to point beyond any explicit S_<nr> label.
2703 */
2708 {
2731 }