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1 /* Swing Modulo Scheduling implementation.
2 Copyright (C) 2004, 2005, 2006, 2007, 2008
3 Free Software Foundation, Inc.
4 Contributed by Ayal Zaks and Mustafa Hagog <zaks,mustafa@il.ibm.com>
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it under
9 the terms of the GNU General Public License as published by the Free
10 Software Foundation; either version 3, or (at your option) any later
11 version.
13 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14 WARRANTY; without even the implied warranty of MERCHANTABILITY or
15 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
16 for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING3. If not see
20 <http://www.gnu.org/licenses/>. */
52 #ifdef INSN_SCHEDULING
54 /* This file contains the implementation of the Swing Modulo Scheduler,
55 described in the following references:
56 [1] J. Llosa, A. Gonzalez, E. Ayguade, M. Valero., and J. Eckhardt.
57 Lifetime--sensitive modulo scheduling in a production environment.
58 IEEE Trans. on Comps., 50(3), March 2001
59 [2] J. Llosa, A. Gonzalez, E. Ayguade, and M. Valero.
60 Swing Modulo Scheduling: A Lifetime Sensitive Approach.
61 PACT '96 , pages 80-87, October 1996 (Boston - Massachusetts - USA).
63 The basic structure is:
64 1. Build a data-dependence graph (DDG) for each loop.
65 2. Use the DDG to order the insns of a loop (not in topological order
66 necessarily, but rather) trying to place each insn after all its
67 predecessors _or_ after all its successors.
68 3. Compute MII: a lower bound on the number of cycles to schedule the loop.
69 4. Use the ordering to perform list-scheduling of the loop:
70 1. Set II = MII. We will try to schedule the loop within II cycles.
71 2. Try to schedule the insns one by one according to the ordering.
72 For each insn compute an interval of cycles by considering already-
73 scheduled preds and succs (and associated latencies); try to place
74 the insn in the cycles of this window checking for potential
75 resource conflicts (using the DFA interface).
76 Note: this is different from the cycle-scheduling of schedule_insns;
77 here the insns are not scheduled monotonically top-down (nor bottom-
78 up).
79 3. If failed in scheduling all insns - bump II++ and try again, unless
80 II reaches an upper bound MaxII, in which case report failure.
81 5. If we succeeded in scheduling the loop within II cycles, we now
82 generate prolog and epilog, decrease the counter of the loop, and
83 perform modulo variable expansion for live ranges that span more than
84 II cycles (i.e. use register copies to prevent a def from overwriting
85 itself before reaching the use).
87 SMS works with countable loops (1) whose control part can be easily
88 decoupled from the rest of the loop and (2) whose loop count can
89 be easily adjusted. This is because we peel a constant number of
90 iterations into a prologue and epilogue for which we want to avoid
91 emitting the control part, and a kernel which is to iterate that
92 constant number of iterations less than the original loop. So the
93 control part should be a set of insns clearly identified and having
94 its own iv, not otherwise used in the loop (at-least for now), which
95 initializes a register before the loop to the number of iterations.
96 Currently SMS relies on the do-loop pattern to recognize such loops,
97 where (1) the control part comprises of all insns defining and/or
98 using a certain 'count' register and (2) the loop count can be
99 adjusted by modifying this register prior to the loop.
100 TODO: Rely on cfgloop analysis instead. */
101 \f
102 /* This page defines partial-schedule structures and functions for
103 modulo scheduling. */
108 /* The minimum (absolute) cycle that a node of ps was scheduled in. */
109 #define PS_MIN_CYCLE(ps) (((partial_schedule_ptr)(ps))->min_cycle)
111 /* The maximum (absolute) cycle that a node of ps was scheduled in. */
112 #define PS_MAX_CYCLE(ps) (((partial_schedule_ptr)(ps))->max_cycle)
114 /* Perform signed modulo, always returning a non-negative value. */
115 #define SMODULO(x,y) ((x) % (y) < 0 ? ((x) % (y) + (y)) : (x) % (y))
117 /* The number of different iterations the nodes in ps span, assuming
118 the stage boundaries are placed efficiently. */
119 #define PS_STAGE_COUNT(ps) ((PS_MAX_CYCLE (ps) - PS_MIN_CYCLE (ps) \
120 + 1 + (ps)->ii - 1) / (ps)->ii)
122 /* A single instruction in the partial schedule. */
123 struct ps_insn
124 {
125 /* The corresponding DDG_NODE. */
126 ddg_node_ptr node;
128 /* The (absolute) cycle in which the PS instruction is scheduled.
129 Same as SCHED_TIME (node). */
132 /* The next/prev PS_INSN in the same row. */
133 ps_insn_ptr next_in_row,
134 prev_in_row;
136 /* The number of nodes in the same row that come after this node. */
138 };
140 /* Holds the partial schedule as an array of II rows. Each entry of the
141 array points to a linked list of PS_INSNs, which represents the
142 instructions that are scheduled for that row. */
143 struct partial_schedule
144 {
148 /* rows[i] points to linked list of insns scheduled in row i (0<=i<ii). */
151 /* The earliest absolute cycle of an insn in the partial schedule. */
154 /* The latest absolute cycle of an insn in the partial schedule. */
158 };
160 /* We use this to record all the register replacements we do in
161 the kernel so we can undo SMS if it is not profitable. */
162 struct undo_replace_buff_elem
163 {
164 rtx insn;
165 rtx orig_reg;
166 rtx new_reg;
168 };
179 sbitmap must_precede,
180 sbitmap must_follow);
186 \f
187 /* This page defines constants and structures for the modulo scheduling
188 driver. */
199 #define SCHED_ASAP(x) (((node_sched_params_ptr)(x)->aux.info)->asap)
200 #define SCHED_TIME(x) (((node_sched_params_ptr)(x)->aux.info)->time)
201 #define SCHED_FIRST_REG_MOVE(x) \
202 (((node_sched_params_ptr)(x)->aux.info)->first_reg_move)
203 #define SCHED_NREG_MOVES(x) \
204 (((node_sched_params_ptr)(x)->aux.info)->nreg_moves)
205 #define SCHED_ROW(x) (((node_sched_params_ptr)(x)->aux.info)->row)
206 #define SCHED_STAGE(x) (((node_sched_params_ptr)(x)->aux.info)->stage)
207 #define SCHED_COLUMN(x) (((node_sched_params_ptr)(x)->aux.info)->column)
209 /* The scheduling parameters held for each node. */
211 {
215 /* The following field (first_reg_move) is a pointer to the first
216 register-move instruction added to handle the modulo-variable-expansion
217 of the register defined by this node. This register-move copies the
218 original register defined by the node. */
219 rtx first_reg_move;
221 /* The number of register-move instructions added, immediately preceding
222 first_reg_move. */
228 /* The column of a node inside the ps. If nodes u, v are on the same row,
229 u will precede v if column (u) < column (v). */
233 \f
234 /* The following three functions are copied from the current scheduler
235 code in order to use sched_analyze() for computing the dependencies.
236 They are used when initializing the sched_info structure. */
239 {
244 }
246 static void
248 regset cond_exec ATTRIBUTE_UNUSED,
249 regset used ATTRIBUTE_UNUSED,
250 regset set ATTRIBUTE_UNUSED)
251 {
252 }
257 {
258 compute_jump_reg_dependencies,
260 NULL,
262 };
265 {
266 NULL,
267 NULL,
268 NULL,
269 NULL,
270 NULL,
271 sms_print_insn,
272 NULL,
279 0
280 };
282 /* Given HEAD and TAIL which are the first and last insns in a loop;
283 return the register which controls the loop. Return zero if it has
284 more than one occurrence in the loop besides the control part or the
285 do-loop pattern is not of the form we expect. */
286 static rtx
288 {
289 #ifdef HAVE_doloop_end
295 /* TODO: Free SMS's dependence on doloop_condition_get. */
305 else
308 /* Check that the COUNT_REG has no other occurrences in the loop
309 until the decrement. We assume the control part consists of
310 either a single (parallel) branch-on-count or a (non-parallel)
311 branch immediately preceded by a single (decrement) insn. */
317 {
319 {
324 }
327 }
330 #else
332 #endif
333 }
335 /* Check if COUNT_REG is set to a constant in the PRE_HEADER block, so
336 that the number of iterations is a compile-time constant. If so,
337 return the rtx that sets COUNT_REG to a constant, and set COUNT to
338 this constant. Otherwise return 0. */
339 static rtx
342 {
343 rtx insn;
354 {
358 {
361 }
364 }
367 }
369 /* A very simple resource-based lower bound on the initiation interval.
370 ??? Improve the accuracy of this bound by considering the
371 utilization of various units. */
372 static int
374 {
379 }
382 /* Points to the array that contains the sched data for each node. */
385 /* Allocate sched_params for each node and initialize it. Assumes that
386 the aux field of each node contain the asap bound (computed earlier),
387 and copies it into the sched_params field. */
388 static void
390 {
393 /* Allocate for each node in the DDG a place to hold the "sched_data". */
394 /* Initialize ASAP/ALAP/HIGHT to zero. */
399 /* Set the pointer of the general data of the node to point to the
400 appropriate sched_params structure. */
402 {
403 /* Watch out for aliasing problems? */
406 }
407 }
409 static void
411 {
417 {
428 {
432 }
433 }
434 }
436 /*
437 Breaking intra-loop register anti-dependences:
438 Each intra-loop register anti-dependence implies a cross-iteration true
439 dependence of distance 1. Therefore, we can remove such false dependencies
440 and figure out if the partial schedule broke them by checking if (for a
441 true-dependence of distance 1): SCHED_TIME (def) < SCHED_TIME (use) and
442 if so generate a register move. The number of such moves is equal to:
443 SCHED_TIME (use) - SCHED_TIME (def) { 0 broken
444 nreg_moves = ----------------------------------- + 1 - { dependence.
445 ii { 1 if not.
446 */
449 {
456 {
458 ddg_edge_ptr e;
461 rtx last_reg_move;
464 /* Compute the number of reg_moves needed for u, by looking at life
465 ranges started at u (excluding self-loops). */
468 {
474 /* If dest precedes src in the schedule of the kernel, then dest
475 will read before src writes and we can save one reg_copy. */
478 nreg_moves4e--;
481 }
486 /* Every use of the register defined by node may require a different
487 copy of this register, depending on the time the use is scheduled.
488 Set a bitmap vector, telling which nodes use each copy of this
489 register. */
494 {
502 dest_copy--;
506 }
508 /* Now generate the reg_moves, attaching relevant uses to them. */
511 /* Insert the reg-moves right before the notes which precede
512 the insn they relates to. */
516 {
520 sbitmap_iterator sbi;
529 {
540 else
541 {
544 }
549 }
552 }
554 }
556 }
558 /* Free memory allocated for the undo buffer. */
559 static void
561 {
564 {
569 }
570 }
572 /* Bump the SCHED_TIMEs of all nodes to start from zero. Set the values
573 of SCHED_ROW and SCHED_STAGE. */
574 static void
576 {
580 ps_insn_ptr crr_insn;
584 {
597 }
598 }
600 /* Set SCHED_COLUMN of each node according to its position in PS. */
601 static void
603 {
607 {
613 }
614 }
616 /* Permute the insns according to their order in PS, from row 0 to
617 row ii-1, and position them right before LAST. This schedules
618 the insns of the loop kernel. */
619 static void
621 {
624 ps_insn_ptr ps_ij;
631 }
633 static void
636 {
638 ps_insn_ptr ps_ij;
642 {
647 /* Do not duplicate any insn which refers to count_reg as it
648 belongs to the control part.
649 TODO: This should be done by analyzing the control part of
650 the loop. */
655 {
656 /* SCHED_STAGE (u_node) >= from_stage == 0. Generate increasing
657 number of reg_moves starting with the second occurrence of
658 u_node, which is generated if its SCHED_STAGE <= to_stage. */
663 /* The reg_moves start from the *first* reg_move backwards. */
665 {
669 }
670 }
672 {
673 /* SCHED_STAGE (u_node) <= to_stage. Generate all reg_moves,
674 starting to decrease one stage after u_node no longer occurs;
675 that is, generate all reg_moves until
676 SCHED_STAGE (u_node) == from_stage - 1. */
682 /* The reg_moves start from the *last* reg_move forwards. */
684 {
688 }
689 }
696 }
697 }
700 /* Generate the instructions (including reg_moves) for prolog & epilog. */
701 static void
704 {
707 edge e;
709 /* Generate the prolog, inserting its insns on the loop-entry edge. */
713 {
714 /* Generate instructions at the beginning of the prolog to
715 adjust the loop count by STAGE_COUNT. If loop count is constant
716 (count_init), this constant is adjusted by STAGE_COUNT in
717 generate_prolog_epilog function. */
726 }
731 /* Put the prolog on the entry edge. */
737 /* Generate the epilog, inserting its insns on the loop-exit edge. */
743 /* Put the epilogue on the exit edge. */
748 }
750 /* Return true if all the BBs of the loop are empty except the
751 loop header. */
752 static bool
754 {
759 {
766 /* Make sure that basic blocks other than the header
767 have only notes labels or jumps. */
770 {
776 }
779 {
782 }
783 }
786 }
788 /* A simple loop from SMS point of view; it is a loop that is composed of
789 either a single basic block or two BBs - a header and a latch. */
790 #define SIMPLE_SMS_LOOP_P(loop) ((loop->num_nodes < 3 ) \
791 && (EDGE_COUNT (loop->latch->preds) == 1) \
792 && (EDGE_COUNT (loop->latch->succs) == 1))
794 /* Return true if the loop is in its canonical form and false if not.
795 i.e. SIMPLE_SMS_LOOP_P and have one preheader block, and single exit. */
796 static bool
798 {
801 {
805 }
808 {
810 {
816 }
818 }
821 {
823 {
829 }
831 }
834 }
836 /* If there are more than one entry for the loop,
837 make it one by splitting the first entry edge and
838 redirecting the others to the new BB. */
839 static void
841 {
842 edge e;
843 edge_iterator i;
845 /* Avoid annoying special cases of edges going to exit
846 block. */
853 {
858 }
859 }
861 /* Setup infos. */
862 static void
864 {
872 }
874 /* Probability in % that the sms-ed loop rolls enough so that optimized
875 version may be entered. Just a guess. */
876 #define PROB_SMS_ENOUGH_ITERATIONS 80
878 /* Used to calculate the upper bound of ii. */
879 #define MAXII_FACTOR 2
881 /* Main entry point, perform SMS scheduling on the loops of the function
882 that consist of single basic blocks. */
883 static void
885 {
886 rtx insn;
890 loop_iterator li;
891 partial_schedule_ptr ps;
895 edge latch_edge;
901 {
904 }
906 /* Initialize issue_rate. */
908 {
914 }
915 else
918 /* Initialize the scheduler. */
922 /* Allocate memory to hold the DDG array one entry for each loop.
923 We use loop->num as index into this array. */
927 {
930 }
932 /* Build DDGs for all the relevant loops and hold them in G_ARR
933 indexed by the loop index. */
935 {
937 rtx count_reg;
939 /* For debugging. */
941 {
946 }
949 {
955 }
961 {
965 }
975 /* Perform SMS only on loops that their average count is above threshold. */
979 {
981 {
986 {
999 }
1000 }
1002 }
1004 /* Make sure this is a doloop. */
1006 {
1010 }
1012 /* Don't handle BBs with calls or barriers, or !single_set insns,
1013 or auto-increment insns (to avoid creating invalid reg-moves
1014 for the auto-increment insns).
1015 ??? Should handle auto-increment insns.
1016 ??? Should handle insns defining subregs. */
1018 {
1019 rtx set;
1029 }
1032 {
1034 {
1044 else
1047 }
1050 }
1053 {
1057 }
1063 }
1065 {
1068 }
1070 /* We don't want to perform SMS on new loops - created by versioning. */
1072 {
1083 {
1090 }
1100 {
1105 {
1114 }
1119 }
1122 /* In case of th loop have doloop register it gets special
1123 handling. */
1126 {
1127 basic_block pre_header;
1132 }
1136 {
1139 loop_count);
1141 }
1154 /* After sms_order_nodes and before sms_schedule_by_order, to copy over
1155 ASAP. */
1163 }
1165 /* Stage count of 1 means that there is no interleaving between
1166 iterations, let the scheduling passes do the job. */
1170 {
1172 {
1179 }
1181 }
1182 else
1183 {
1187 {
1190 stage_count);
1195 }
1197 /* Set the stage boundaries. If the DDG is built with closing_branch_deps,
1198 the closing_branch was scheduled and should appear in the last (ii-1)
1199 row. Otherwise, we are free to schedule the branch, and we let nodes
1200 that were scheduled at the first PS_MIN_CYCLE cycle appear in the first
1201 row; this should reduce stage_count to minimum.
1202 TODO: Revisit the issue of scheduling the insns of the
1203 control part relative to the branch when the control part
1204 has more than one insn. */
1211 /* case the BCT count is not known , Do loop-versioning */
1213 {
1222 }
1224 /* Set new iteration count of loop kernel. */
1229 /* Now apply the scheduled kernel to the RTL of the loop. */
1232 /* Mark this loop as software pipelined so the later
1233 scheduling passes doesn't touch it. */
1236 /* The life-info is not valid any more. */
1242 /* Generate prolog and epilog. */
1246 }
1252 }
1256 /* Release scheduler data, needed until now because of DFA. */
1259 }
1261 /* The SMS scheduling algorithm itself
1262 -----------------------------------
1263 Input: 'O' an ordered list of insns of a loop.
1264 Output: A scheduling of the loop - kernel, prolog, and epilogue.
1266 'Q' is the empty Set
1267 'PS' is the partial schedule; it holds the currently scheduled nodes with
1268 their cycle/slot.
1269 'PSP' previously scheduled predecessors.
1270 'PSS' previously scheduled successors.
1271 't(u)' the cycle where u is scheduled.
1272 'l(u)' is the latency of u.
1273 'd(v,u)' is the dependence distance from v to u.
1274 'ASAP(u)' the earliest time at which u could be scheduled as computed in
1275 the node ordering phase.
1276 'check_hardware_resources_conflicts(u, PS, c)'
1277 run a trace around cycle/slot through DFA model
1278 to check resource conflicts involving instruction u
1279 at cycle c given the partial schedule PS.
1280 'add_to_partial_schedule_at_time(u, PS, c)'
1281 Add the node/instruction u to the partial schedule
1282 PS at time c.
1283 'calculate_register_pressure(PS)'
1284 Given a schedule of instructions, calculate the register
1285 pressure it implies. One implementation could be the
1286 maximum number of overlapping live ranges.
1287 'maxRP' The maximum allowed register pressure, it is usually derived from the number
1288 registers available in the hardware.
1290 1. II = MII.
1291 2. PS = empty list
1292 3. for each node u in O in pre-computed order
1293 4. if (PSP(u) != Q && PSS(u) == Q) then
1294 5. Early_start(u) = max ( t(v) + l(v) - d(v,u)*II ) over all every v in PSP(u).
1295 6. start = Early_start; end = Early_start + II - 1; step = 1
1296 11. else if (PSP(u) == Q && PSS(u) != Q) then
1297 12. Late_start(u) = min ( t(v) - l(v) + d(v,u)*II ) over all every v in PSS(u).
1298 13. start = Late_start; end = Late_start - II + 1; step = -1
1299 14. else if (PSP(u) != Q && PSS(u) != Q) then
1300 15. Early_start(u) = max ( t(v) + l(v) - d(v,u)*II ) over all every v in PSP(u).
1301 16. Late_start(u) = min ( t(v) - l(v) + d(v,u)*II ) over all every v in PSS(u).
1302 17. start = Early_start;
1303 18. end = min(Early_start + II - 1 , Late_start);
1304 19. step = 1
1305 20. else "if (PSP(u) == Q && PSS(u) == Q)"
1306 21. start = ASAP(u); end = start + II - 1; step = 1
1307 22. endif
1309 23. success = false
1310 24. for (c = start ; c != end ; c += step)
1311 25. if check_hardware_resources_conflicts(u, PS, c) then
1312 26. add_to_partial_schedule_at_time(u, PS, c)
1313 27. success = true
1314 28. break
1315 29. endif
1316 30. endfor
1317 31. if (success == false) then
1318 32. II = II + 1
1319 33. if (II > maxII) then
1320 34. finish - failed to schedule
1321 35. endif
1322 36. goto 2.
1323 37. endif
1324 38. endfor
1325 39. if (calculate_register_pressure(PS) > maxRP) then
1326 40. goto 32.
1327 41. endif
1328 42. compute epilogue & prologue
1329 43. finish - succeeded to schedule
1330 */
1332 /* A limit on the number of cycles that resource conflicts can span. ??? Should
1333 be provided by DFA, and be dependent on the type of insn scheduled. Currently
1334 set to 0 to save compile time. */
1335 #define DFA_HISTORY SMS_DFA_HISTORY
1337 /* A threshold for the number of repeated unsuccessful attempts to insert
1338 an empty row, before we flush the partial schedule and start over. */
1339 #define MAX_SPLIT_NUM 10
1340 /* Given the partial schedule PS, this function calculates and returns the
1341 cycles in which we can schedule the node with the given index I.
1342 NOTE: Here we do the backtracking in SMS, in some special cases. We have
1343 noticed that there are several cases in which we fail to SMS the loop
1344 because the sched window of a node is empty due to tight data-deps. In
1345 such cases we want to unschedule some of the predecessors/successors
1346 until we get non-empty scheduling window. It returns -1 if the
1347 scheduling window is empty and zero otherwise. */
1349 static int
1352 {
1354 ddg_edge_ptr e;
1364 /* 1. compute sched window for u (start, end, step). */
1371 {
1376 {
1380 {
1388 }
1391 {
1394 early_start =
1404 }
1407 }
1410 /* Schedule the node close to it's predecessors. */
1417 }
1420 {
1425 {
1429 {
1437 }
1440 {
1456 }
1460 }
1463 /* Schedule the node close to it's successors. */
1471 }
1474 {
1483 {
1487 {
1495 }
1498 {
1511 count_preds++;
1515 }
1519 }
1521 {
1525 {
1533 }
1536 {
1549 count_succs++;
1553 }
1557 }
1561 /* If there are more successors than predecessors schedule the
1562 node close to it's successors. */
1564 {
1570 }
1571 }
1573 {
1577 }
1586 {
1591 }
1594 }
1596 /* Calculate MUST_PRECEDE/MUST_FOLLOW bitmaps of U_NODE; which is the
1597 node currently been scheduled. At the end of the calculation
1598 MUST_PRECEDE/MUST_FOLLOW contains all predecessors/successors of
1599 U_NODE which are (1) already scheduled in the first/last row of
1600 U_NODE's scheduling window, (2) whose dependence inequality with U
1601 becomes an equality when U is scheduled in this same row, and (3)
1602 whose dependence latency is zero.
1604 The first and last rows are calculated using the following parameters:
1605 START/END rows - The cycles that begins/ends the traversal on the window;
1606 searching for an empty cycle to schedule U_NODE.
1607 STEP - The direction in which we traverse the window.
1608 II - The initiation interval. */
1610 static void
1614 {
1615 ddg_edge_ptr e;
1620 /* Consider the following scheduling window:
1621 {first_cycle_in_window, first_cycle_in_window+1, ...,
1622 last_cycle_in_window}. If step is 1 then the following will be
1623 the order we traverse the window: {start=first_cycle_in_window,
1624 first_cycle_in_window+1, ..., end=last_cycle_in_window+1},
1625 or {start=last_cycle_in_window, last_cycle_in_window-1, ...,
1626 end=first_cycle_in_window-1} if step is -1. */
1636 /* Instead of checking if:
1637 (SMODULO (SCHED_TIME (e->src), ii) == first_row_in_window)
1638 && ((SCHED_TIME (e->src) + e->latency - (e->distance * ii)) ==
1639 first_cycle_in_window)
1640 && e->latency == 0
1641 we use the fact that latency is non-negative:
1642 SCHED_TIME (e->src) - (e->distance * ii) <=
1643 SCHED_TIME (e->src) + e->latency - (e->distance * ii)) <=
1644 first_cycle_in_window
1645 and check only if
1646 SCHED_TIME (e->src) - (e->distance * ii) == first_cycle_in_window */
1650 first_cycle_in_window))
1651 {
1656 }
1661 /* Instead of checking if:
1662 (SMODULO (SCHED_TIME (e->dest), ii) == last_row_in_window)
1663 && ((SCHED_TIME (e->dest) - e->latency + (e->distance * ii)) ==
1664 last_cycle_in_window)
1665 && e->latency == 0
1666 we use the fact that latency is non-negative:
1667 SCHED_TIME (e->dest) + (e->distance * ii) >=
1668 SCHED_TIME (e->dest) - e->latency + (e->distance * ii)) >=
1669 last_cycle_in_window
1670 and check only if
1671 SCHED_TIME (e->dest) + (e->distance * ii) == last_cycle_in_window */
1675 last_cycle_in_window))
1676 {
1681 }
1685 }
1687 /* Return 1 if U_NODE can be scheduled in CYCLE. Use the following
1688 parameters to decide if that's possible:
1689 PS - The partial schedule.
1690 U - The serial number of U_NODE.
1691 NUM_SPLITS - The number of row splits made so far.
1692 MUST_PRECEDE - The nodes that must precede U_NODE. (only valid at
1693 the first row of the scheduling window)
1694 MUST_FOLLOW - The nodes that must follow U_NODE. (only valid at the
1695 last row of the scheduling window) */
1697 static bool
1701 sbitmap must_follow)
1702 {
1703 ps_insn_ptr psi;
1710 {
1718 }
1721 }
1723 /* This function implements the scheduling algorithm for SMS according to the
1724 above algorithm. */
1725 static partial_schedule_ptr
1727 {
1744 {
1752 {
1758 {
1761 }
1764 {
1767 }
1772 /* Try to get non-empty scheduling window. */
1776 {
1787 must_follow);
1790 {
1795 {
1800 }
1802 {
1807 }
1809 success =
1811 sched_nodes,
1813 tmp_follow);
1816 }
1819 }
1821 {
1828 {
1835 }
1837 num_splits++;
1838 /* The scheduling window is exclusive of 'end'
1839 whereas compute_split_window() expects an inclusive,
1840 ordered range. */
1844 else
1853 }
1855 /* ??? If (success), check register pressure estimates. */
1859 {
1862 }
1863 else
1872 }
1874 /* This function inserts a new empty row into PS at the position
1875 according to SPLITROW, keeping all already scheduled instructions
1876 intact and updating their SCHED_TIME and cycle accordingly. */
1877 static void
1879 sbitmap sched_nodes)
1880 {
1881 ps_insn_ptr crr_insn;
1889 /* We normalize sched_time and rotate ps to have only non-negative sched
1890 times, for simplicity of updating cycles after inserting new row. */
1901 {
1906 {
1914 }
1916 }
1921 {
1926 {
1934 }
1935 }
1937 /* Updating ps. */
1952 }
1954 /* Given U_NODE which is the node that failed to be scheduled; LOW and
1955 UP which are the boundaries of it's scheduling window; compute using
1956 SCHED_NODES and II a row in the partial schedule that can be split
1957 which will separate a critical predecessor from a critical successor
1958 thereby expanding the window, and return it. */
1959 static int
1961 ddg_node_ptr u_node)
1962 {
1963 ddg_edge_ptr e;
1970 {
1976 {
1979 }
1980 }
1983 {
1986 }
1989 {
1994 {
1997 }
1998 }
2001 {
2004 }
2010 }
2012 static void
2014 {
2016 ps_insn_ptr crr_insn;
2020 {
2024 /* ??? Test also that all nodes of sched_nodes are in ps, perhaps by
2025 popcount (sched_nodes) == number of insns in ps. */
2028 }
2029 }
2031 \f
2032 /* This page implements the algorithm for ordering the nodes of a DDG
2033 for modulo scheduling, activated through the
2034 "int sms_order_nodes (ddg_ptr, int mii, int * result)" API. */
2036 #define ORDER_PARAMS(x) ((struct node_order_params *) (x)->aux.info)
2037 #define ASAP(x) (ORDER_PARAMS ((x))->asap)
2038 #define ALAP(x) (ORDER_PARAMS ((x))->alap)
2039 #define HEIGHT(x) (ORDER_PARAMS ((x))->height)
2040 #define MOB(x) (ALAP ((x)) - ASAP ((x)))
2041 #define DEPTH(x) (ASAP ((x)))
2054 struct node_order_params
2055 {
2059 };
2061 /* Check if NODE_ORDER contains a permutation of 0 .. NUM_NODES-1. */
2062 static void
2064 {
2074 {
2082 }
2088 }
2090 /* Order the nodes of G for scheduling and pass the result in
2091 NODE_ORDER. Also set aux.count of each node to ASAP.
2092 Put maximal ASAP to PMAX_ASAP. Return the recMII for the given DDG. */
2093 static int
2095 {
2108 /* First SCC has the largest recurrence_length. */
2111 /* Save ASAP before destroying node_order_params. */
2113 {
2116 }
2123 }
2125 static void
2127 {
2139 /* Perform the node ordering starting from the SCC with the highest recMII.
2140 For each SCC order the nodes according to their ASAP/ALAP/HEIGHT etc. */
2142 {
2145 /* Add nodes on paths from previous SCCs to the current SCC. */
2149 /* Add nodes on paths from the current SCC to previous SCCs. */
2153 /* Remove nodes of previous SCCs from current extended SCC. */
2157 /* Above call to order_nodes_in_scc updated prev_sccs |= tmp. */
2158 }
2160 /* Handle the remaining nodes that do not belong to any scc. Each call
2161 to order_nodes_in_scc handles a single connected component. */
2163 {
2166 }
2171 }
2173 /* MII is needed if we consider backarcs (that do not close recursive cycles). */
2176 {
2180 ddg_edge_ptr e;
2181 /* Allocate a place to hold ordering params for each node in the DDG. */
2182 nopa node_order_params_arr;
2184 /* Initialize of ASAP/ALAP/HEIGHT to zero. */
2188 /* Set the aux pointer of each node to point to its order_params structure. */
2192 /* Disregarding a backarc from each recursive cycle to obtain a DAG,
2193 calculate ASAP, ALAP, mobility, distance, and height for each node
2194 in the dependence (direct acyclic) graph. */
2196 /* We assume that the nodes in the array are in topological order. */
2200 {
2209 }
2212 {
2219 {
2224 }
2225 }
2227 {
2230 {
2235 }
2236 }
2240 }
2242 static int
2244 {
2248 sbitmap_iterator sbi;
2251 {
2255 {
2258 }
2259 }
2261 }
2263 static int
2265 {
2270 sbitmap_iterator sbi;
2273 {
2277 {
2281 }
2284 {
2287 }
2288 }
2290 }
2292 static int
2294 {
2299 sbitmap_iterator sbi;
2302 {
2306 {
2310 }
2313 {
2316 }
2317 }
2319 }
2321 /* Places the nodes of SCC into the NODE_ORDER array starting
2322 at position POS, according to the SMS ordering algorithm.
2323 NODES_ORDERED (in&out parameter) holds the bitset of all nodes in
2324 the NODE_ORDER array, starting from position zero. */
2325 static int
2328 {
2345 {
2348 }
2350 {
2353 }
2354 else
2355 {
2362 }
2366 {
2368 ddg_node_ptr v_node;
2369 sbitmap v_node_preds;
2370 sbitmap v_node_succs;
2373 {
2375 {
2382 /* Don't consider the already ordered successors again. */
2387 }
2392 }
2393 else
2394 {
2396 {
2403 /* Don't consider the already ordered predecessors again. */
2408 }
2413 }
2414 }
2421 }
2423 \f
2424 /* This page contains functions for manipulating partial-schedules during
2425 modulo scheduling. */
2427 /* Create a partial schedule and allocate a memory to hold II rows. */
2429 static partial_schedule_ptr
2431 {
2441 }
2443 /* Free the PS_INSNs in rows array of the given partial schedule.
2444 ??? Consider caching the PS_INSN's. */
2445 static void
2447 {
2451 {
2453 {
2458 }
2460 }
2461 }
2463 /* Free all the memory allocated to the partial schedule. */
2465 static void
2467 {
2473 }
2475 /* Clear the rows array with its PS_INSNs, and create a new one with
2476 NEW_II rows. */
2478 static void
2480 {
2492 }
2494 /* Prints the partial schedule as an ii rows array, for each rows
2495 print the ids of the insns in it. */
2496 void
2498 {
2502 {
2507 {
2511 }
2512 }
2513 }
2515 /* Creates an object of PS_INSN and initializes it to the given parameters. */
2516 static ps_insn_ptr
2518 {
2528 }
2531 /* Removes the given PS_INSN from the partial schedule. Returns false if the
2532 node is not found in the partial schedule, else returns true. */
2533 static bool
2535 {
2543 {
2550 }
2551 else
2552 {
2556 }
2559 }
2561 /* Unlike what literature describes for modulo scheduling (which focuses
2562 on VLIW machines) the order of the instructions inside a cycle is
2563 important. Given the bitmaps MUST_FOLLOW and MUST_PRECEDE we know
2564 where the current instruction should go relative to the already
2565 scheduled instructions in the given cycle. Go over these
2566 instructions and find the first possible column to put it in. */
2567 static bool
2570 {
2571 ps_insn_ptr next_ps_i;
2581 /* Find the first must follow and the last must precede
2582 and insert the node immediately after the must precede
2583 but make sure that it there is no must follow after it. */
2585 next_ps_i;
2587 {
2592 {
2593 /* If we have already met a node that must follow, then
2594 there is no possible column. */
2597 else
2599 }
2600 }
2602 /* Now insert the node after INSERT_AFTER_PSI. */
2605 {
2611 }
2612 else
2613 {
2619 }
2622 }
2624 /* Advances the PS_INSN one column in its current row; returns false
2625 in failure and true in success. Bit N is set in MUST_FOLLOW if
2626 the node with cuid N must be come after the node pointed to by
2627 PS_I when scheduled in the same cycle. */
2628 static int
2630 sbitmap must_follow)
2631 {
2634 ddg_node_ptr next_node;
2646 /* Check if next_in_row is dependent on ps_i, both having same sched
2647 times (typically ANTI_DEP). If so, ps_i cannot skip over it. */
2651 /* Advance PS_I over its next_in_row in the doubly linked list. */
2671 }
2673 /* Inserts a DDG_NODE to the given partial schedule at the given cycle.
2674 Returns 0 if this is not possible and a PS_INSN otherwise. Bit N is
2675 set in MUST_PRECEDE/MUST_FOLLOW if the node with cuid N must be come
2676 before/after (respectively) the node pointed to by PS_I when scheduled
2677 in the same cycle. */
2678 static ps_insn_ptr
2681 {
2682 ps_insn_ptr ps_i;
2695 /* Finds and inserts PS_I according to MUST_FOLLOW and
2696 MUST_PRECEDE. */
2698 {
2701 }
2704 }
2706 /* Advance time one cycle. Assumes DFA is being used. */
2707 static void
2709 {
2719 }
2723 /* Checks if PS has resource conflicts according to DFA, starting from
2724 FROM cycle to TO cycle; returns true if there are conflicts and false
2725 if there are no conflicts. Assumes DFA is being used. */
2726 static int
2728 {
2734 {
2735 ps_insn_ptr crr_insn;
2736 /* Holds the remaining issue slots in the current row. */
2739 /* Walk through the DFA for the current row. */
2741 crr_insn;
2743 {
2749 /* Check if there is room for the current insn. */
2753 /* Update the DFA state and return with failure if the DFA found
2754 resource conflicts. */
2759 can_issue_more =
2762 /* A naked CLOBBER or USE generates no instruction, so don't
2763 let them consume issue slots. */
2766 can_issue_more--;
2767 }
2769 /* Advance the DFA to the next cycle. */
2771 }
2773 }
2775 /* Checks if the given node causes resource conflicts when added to PS at
2776 cycle C. If not the node is added to PS and returned; otherwise zero
2777 is returned. Bit N is set in MUST_PRECEDE/MUST_FOLLOW if the node with
2778 cuid N must be come before/after (respectively) the node pointed to by
2779 PS_I when scheduled in the same cycle. */
2780 ps_insn_ptr
2783 sbitmap must_follow)
2784 {
2786 ps_insn_ptr ps_i;
2788 /* First add the node to the PS, if this succeeds check for
2789 conflicts, trying different issue slots in the same row. */
2799 /* Try different issue slots to find one that the given node can be
2800 scheduled in without conflicts. */
2802 {
2810 }
2813 {
2816 }
2821 }
2823 /* Rotate the rows of PS such that insns scheduled at time
2824 START_CYCLE will appear in row 0. Updates max/min_cycles. */
2825 void
2827 {
2836 /* Revisit later and optimize this into a single loop. */
2838 {
2845 }
2849 }
2852 \f
2853 static bool
2855 {
2857 }
2860 /* Run instruction scheduler. */
2861 /* Perform SMS module scheduling. */
2862 static unsigned int
2864 {
2865 #ifdef INSN_SCHEDULING
2866 basic_block bb;
2868 /* Collect loop information to be used in SMS. */
2872 /* Update the life information, because we add pseudos. */
2875 /* Finalize layout changes. */
2883 }
2886 {
2887 {
2888 RTL_PASS,
2901 TODO_dump_func |
2902 TODO_ggc_collect /* todo_flags_finish */
2903 }
2904 };