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1 /* Swing Modulo Scheduling implementation.
2 Copyright (C) 2004-2015 Free Software Foundation, Inc.
3 Contributed by Ayal Zaks and Mustafa Hagog <zaks,mustafa@il.ibm.com>
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify it under
8 the terms of the GNU General Public License as published by the Free
9 Software Foundation; either version 3, or (at your option) any later
10 version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
13 WARRANTY; without even the implied warranty of MERCHANTABILITY or
14 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
15 for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING3. If not see
19 <http://www.gnu.org/licenses/>. */
61 #ifdef INSN_SCHEDULING
63 /* This file contains the implementation of the Swing Modulo Scheduler,
64 described in the following references:
65 [1] J. Llosa, A. Gonzalez, E. Ayguade, M. Valero., and J. Eckhardt.
66 Lifetime--sensitive modulo scheduling in a production environment.
67 IEEE Trans. on Comps., 50(3), March 2001
68 [2] J. Llosa, A. Gonzalez, E. Ayguade, and M. Valero.
69 Swing Modulo Scheduling: A Lifetime Sensitive Approach.
70 PACT '96 , pages 80-87, October 1996 (Boston - Massachusetts - USA).
72 The basic structure is:
73 1. Build a data-dependence graph (DDG) for each loop.
74 2. Use the DDG to order the insns of a loop (not in topological order
75 necessarily, but rather) trying to place each insn after all its
76 predecessors _or_ after all its successors.
77 3. Compute MII: a lower bound on the number of cycles to schedule the loop.
78 4. Use the ordering to perform list-scheduling of the loop:
79 1. Set II = MII. We will try to schedule the loop within II cycles.
80 2. Try to schedule the insns one by one according to the ordering.
81 For each insn compute an interval of cycles by considering already-
82 scheduled preds and succs (and associated latencies); try to place
83 the insn in the cycles of this window checking for potential
84 resource conflicts (using the DFA interface).
85 Note: this is different from the cycle-scheduling of schedule_insns;
86 here the insns are not scheduled monotonically top-down (nor bottom-
87 up).
88 3. If failed in scheduling all insns - bump II++ and try again, unless
89 II reaches an upper bound MaxII, in which case report failure.
90 5. If we succeeded in scheduling the loop within II cycles, we now
91 generate prolog and epilog, decrease the counter of the loop, and
92 perform modulo variable expansion for live ranges that span more than
93 II cycles (i.e. use register copies to prevent a def from overwriting
94 itself before reaching the use).
96 SMS works with countable loops (1) whose control part can be easily
97 decoupled from the rest of the loop and (2) whose loop count can
98 be easily adjusted. This is because we peel a constant number of
99 iterations into a prologue and epilogue for which we want to avoid
100 emitting the control part, and a kernel which is to iterate that
101 constant number of iterations less than the original loop. So the
102 control part should be a set of insns clearly identified and having
103 its own iv, not otherwise used in the loop (at-least for now), which
104 initializes a register before the loop to the number of iterations.
105 Currently SMS relies on the do-loop pattern to recognize such loops,
106 where (1) the control part comprises of all insns defining and/or
107 using a certain 'count' register and (2) the loop count can be
108 adjusted by modifying this register prior to the loop.
109 TODO: Rely on cfgloop analysis instead. */
110 \f
111 /* This page defines partial-schedule structures and functions for
112 modulo scheduling. */
117 /* The minimum (absolute) cycle that a node of ps was scheduled in. */
118 #define PS_MIN_CYCLE(ps) (((partial_schedule_ptr)(ps))->min_cycle)
120 /* The maximum (absolute) cycle that a node of ps was scheduled in. */
121 #define PS_MAX_CYCLE(ps) (((partial_schedule_ptr)(ps))->max_cycle)
123 /* Perform signed modulo, always returning a non-negative value. */
124 #define SMODULO(x,y) ((x) % (y) < 0 ? ((x) % (y) + (y)) : (x) % (y))
126 /* The number of different iterations the nodes in ps span, assuming
127 the stage boundaries are placed efficiently. */
128 #define CALC_STAGE_COUNT(max_cycle,min_cycle,ii) ((max_cycle - min_cycle \
129 + 1 + ii - 1) / ii)
130 /* The stage count of ps. */
131 #define PS_STAGE_COUNT(ps) (((partial_schedule_ptr)(ps))->stage_count)
133 /* A single instruction in the partial schedule. */
134 struct ps_insn
135 {
136 /* Identifies the instruction to be scheduled. Values smaller than
137 the ddg's num_nodes refer directly to ddg nodes. A value of
138 X - num_nodes refers to register move X. */
141 /* The (absolute) cycle in which the PS instruction is scheduled.
142 Same as SCHED_TIME (node). */
145 /* The next/prev PS_INSN in the same row. */
146 ps_insn_ptr next_in_row,
147 prev_in_row;
149 };
151 /* Information about a register move that has been added to a partial
152 schedule. */
153 struct ps_reg_move_info
154 {
155 /* The source of the move is defined by the ps_insn with id DEF.
156 The destination is used by the ps_insns with the ids in USES. */
158 sbitmap uses;
160 /* The original form of USES' instructions used OLD_REG, but they
161 should now use NEW_REG. */
162 rtx old_reg;
163 rtx new_reg;
165 /* The number of consecutive stages that the move occupies. */
168 /* An instruction that sets NEW_REG to the correct value. The first
169 move associated with DEF will have an rhs of OLD_REG; later moves
170 use the result of the previous move. */
172 };
174 /* Holds the partial schedule as an array of II rows. Each entry of the
175 array points to a linked list of PS_INSNs, which represents the
176 instructions that are scheduled for that row. */
177 struct partial_schedule
178 {
182 /* rows[i] points to linked list of insns scheduled in row i (0<=i<ii). */
185 /* All the moves added for this partial schedule. Index X has
186 a ps_insn id of X + g->num_nodes. */
189 /* rows_length[i] holds the number of instructions in the row.
190 It is used only (as an optimization) to back off quickly from
191 trying to schedule a node in a full row; that is, to avoid running
192 through futile DFA state transitions. */
195 /* The earliest absolute cycle of an insn in the partial schedule. */
198 /* The latest absolute cycle of an insn in the partial schedule. */
204 };
219 \f
220 /* This page defines constants and structures for the modulo scheduling
221 driver. */
238 #define NODE_ASAP(node) ((node)->aux.count)
240 #define SCHED_PARAMS(x) (&node_sched_param_vec[x])
241 #define SCHED_TIME(x) (SCHED_PARAMS (x)->time)
242 #define SCHED_ROW(x) (SCHED_PARAMS (x)->row)
243 #define SCHED_STAGE(x) (SCHED_PARAMS (x)->stage)
244 #define SCHED_COLUMN(x) (SCHED_PARAMS (x)->column)
246 /* The scheduling parameters held for each node. */
248 {
254 /* The column of a node inside the ps. If nodes u, v are on the same row,
255 u will precede v if column (u) < column (v). */
258 \f
259 /* The following three functions are copied from the current scheduler
260 code in order to use sched_analyze() for computing the dependencies.
261 They are used when initializing the sched_info structure. */
264 {
269 }
271 static void
273 regset used ATTRIBUTE_UNUSED)
274 {
275 }
280 {
281 compute_jump_reg_dependencies,
283 NULL,
285 };
288 {
289 NULL,
290 NULL,
291 NULL,
292 NULL,
293 NULL,
294 sms_print_insn,
295 NULL,
303 0
304 };
306 /* Partial schedule instruction ID in PS is a register move. Return
307 information about it. */
310 {
313 }
315 /* Return the rtl instruction that is being scheduled by partial schedule
316 instruction ID, which belongs to schedule PS. */
319 {
322 else
324 }
326 /* Partial schedule instruction ID, which belongs to PS, occurred in
327 the original (unscheduled) loop. Return the first instruction
328 in the loop that was associated with ps_rtl_insn (PS, ID).
329 If the instruction had some notes before it, this is the first
330 of those notes. */
333 {
336 }
338 /* Return the number of consecutive stages that are occupied by
339 partial schedule instruction ID in PS. */
340 static int
342 {
345 else
347 }
349 /* Given HEAD and TAIL which are the first and last insns in a loop;
350 return the register which controls the loop. Return zero if it has
351 more than one occurrence in the loop besides the control part or the
352 do-loop pattern is not of the form we expect. */
353 static rtx
355 {
365 /* TODO: Free SMS's dependence on doloop_condition_get. */
375 else
378 /* Check that the COUNT_REG has no other occurrences in the loop
379 until the decrement. We assume the control part consists of
380 either a single (parallel) branch-on-count or a (non-parallel)
381 branch immediately preceded by a single (decrement) insn. */
387 {
389 {
394 }
397 }
400 }
402 /* Check if COUNT_REG is set to a constant in the PRE_HEADER block, so
403 that the number of iterations is a compile-time constant. If so,
404 return the rtx_insn that sets COUNT_REG to a constant, and set COUNT to
405 this constant. Otherwise return 0. */
409 {
421 {
425 {
428 }
431 }
434 }
436 /* A very simple resource-based lower bound on the initiation interval.
437 ??? Improve the accuracy of this bound by considering the
438 utilization of various units. */
439 static int
441 {
446 }
449 /* A vector that contains the sched data for each ps_insn. */
452 /* Allocate sched_params for each node and initialize it. */
453 static void
455 {
458 }
460 /* Make sure that node_sched_param_vec has an entry for every move in PS. */
461 static void
463 {
466 }
468 /* Update the sched_params (time, row and stage) for node U using the II,
469 the CYCLE of U and MIN_CYCLE.
470 We're not simply taking the following
471 SCHED_STAGE (u) = CALC_STAGE_COUNT (SCHED_TIME (u), min_cycle, ii);
472 because the stages may not be aligned on cycle 0. */
473 static void
475 {
482 /* The calculation of stage count is done adding the number
483 of stages before cycle zero and after cycle zero. */
487 {
490 }
491 else
492 {
495 }
496 }
498 static void
500 {
506 {
514 }
515 }
517 /* Set SCHED_COLUMN for each instruction in row ROW of PS. */
518 static void
520 {
521 ps_insn_ptr cur_insn;
527 }
529 /* Set SCHED_COLUMN for each instruction in PS. */
530 static void
532 {
537 }
539 /* Try to schedule the move with ps_insn identifier I_REG_MOVE in PS.
540 Its single predecessor has already been scheduled, as has its
541 ddg node successors. (The move may have also another move as its
542 successor, in which case that successor will be scheduled later.)
544 The move is part of a chain that satisfies register dependencies
545 between a producing ddg node and various consuming ddg nodes.
546 If some of these dependencies have a distance of 1 (meaning that
547 the use is upward-exposed) then DISTANCE1_USES is nonnull and
548 contains the set of uses with distance-1 dependencies.
549 DISTANCE1_USES is null otherwise.
551 MUST_FOLLOW is a scratch bitmap that is big enough to hold
552 all current ps_insn ids.
554 Return true on success. */
555 static bool
558 {
562 sbitmap_iterator sbi;
565 ps_insn_ptr psi;
570 {
577 }
582 /* For dependencies of distance 1 between a producer ddg node A
583 and consumer ddg node B, we have a chain of dependencies:
585 A --(T,L1,1)--> M1 --(T,L2,0)--> M2 ... --(T,Ln,0)--> B
587 where Mi is the ith move. For dependencies of distance 0 between
588 a producer ddg node A and consumer ddg node C, we have a chain of
589 dependencies:
591 A --(T,L1',0)--> M1' --(T,L2',0)--> M2' ... --(T,Ln',0)--> C
593 where Mi' occupies the same position as Mi but occurs a stage later.
594 We can only schedule each move once, so if we have both types of
595 chain, we model the second as:
597 A --(T,L1',1)--> M1 --(T,L2',0)--> M2 ... --(T,Ln',-1)--> C
599 First handle the dependencies between the previously-scheduled
600 predecessor and the move. */
618 /* Handle the dependencies between the move and previously-scheduled
619 successors. */
621 {
626 else
640 }
643 {
646 }
653 {
657 {
664 }
665 }
671 }
673 /*
674 Breaking intra-loop register anti-dependences:
675 Each intra-loop register anti-dependence implies a cross-iteration true
676 dependence of distance 1. Therefore, we can remove such false dependencies
677 and figure out if the partial schedule broke them by checking if (for a
678 true-dependence of distance 1): SCHED_TIME (def) < SCHED_TIME (use) and
679 if so generate a register move. The number of such moves is equal to:
680 SCHED_TIME (use) - SCHED_TIME (def) { 0 broken
681 nreg_moves = ----------------------------------- + 1 - { dependence.
682 ii { 1 if not.
683 */
684 static bool
686 {
692 {
694 ddg_edge_ptr e;
699 sbitmap must_follow;
700 sbitmap distance1_uses;
703 /* Skip instructions that do not set a register. */
707 /* Compute the number of reg_moves needed for u, by looking at life
708 ranges started at u (excluding self-loops). */
712 {
720 /* If dest precedes src in the schedule of the kernel, then dest
721 will read before src writes and we can save one reg_copy. */
724 nreg_moves4e--;
727 {
728 /* !single_set instructions are not supported yet and
729 thus we do not except to encounter them in the loop
730 except from the doloop part. For the latter case
731 we assume no regmoves are generated as the doloop
732 instructions are tied to the branch with an edge. */
734 /* If the instruction contains auto-inc register then
735 validate that the regmov is being generated for the
736 target regsiter rather then the inc'ed register. */
738 }
741 {
744 }
746 }
751 /* Create NREG_MOVES register moves. */
756 /* Record the moves associated with this node. */
759 /* Generate each move. */
762 {
774 }
781 /* Every use of the register defined by node may require a different
782 copy of this register, depending on the time the use is scheduled.
783 Record which uses require which move results. */
786 {
796 dest_copy--;
799 {
806 }
807 }
819 }
821 }
823 /* Emit the moves associatied with PS. Apply the substitutions
824 associated with them. */
825 static void
827 {
832 {
834 sbitmap_iterator sbi;
837 {
840 }
841 }
842 }
844 /* Bump the SCHED_TIMEs of all nodes by AMOUNT. Set the values of
845 SCHED_ROW and SCHED_STAGE. Instruction scheduled on cycle AMOUNT
846 will move to cycle zero. */
847 static void
849 {
852 ps_insn_ptr crr_insn;
856 {
862 {
863 /* Print the scheduling times after the rotation. */
872 }
879 }
880 }
882 /* Permute the insns according to their order in PS, from row 0 to
883 row ii-1, and position them right before LAST. This schedules
884 the insns of the loop kernel. */
885 static void
887 {
890 ps_insn_ptr ps_ij;
894 {
898 {
902 else
904 }
905 }
906 }
908 /* Set bitmaps TMP_FOLLOW and TMP_PRECEDE to MUST_FOLLOW and MUST_PRECEDE
909 respectively only if cycle C falls on the border of the scheduling
910 window boundaries marked by START and END cycles. STEP is the
911 direction of the window. */
916 {
921 {
926 }
928 {
933 }
935 }
937 /* Return True if the branch can be moved to row ii-1 while
938 normalizing the partial schedule PS to start from cycle zero and thus
939 optimize the SC. Otherwise return False. */
940 static bool
942 {
950 /* Compare the SC after normalization and SC after bringing the branch
951 to row ii-1. If they are equal just bail out. */
953 stage_count_curr =
957 {
963 }
966 {
970 }
972 /* First, normalize the partial scheduling. */
976 {
981 }
984 {
987 }
991 /* Calculate the new placement of the branch. It should be in row
992 ii-1 and fall into it's scheduling window. */
995 {
997 ps_insn_ptr next_ps_i;
1012 {
1016 {
1022 }
1023 }
1024 else
1025 {
1030 {
1036 }
1037 }
1042 /* Try to schedule the branch is it's new cycle. */
1050 /* Find the element in the partial schedule related to the closing
1051 branch so we can remove it from it's current cycle. */
1058 success =
1064 {
1067 "SMS failed to schedule branch at cycle: %d, "
1070 /* The branch was failed to be placed in row ii - 1.
1071 Put it back in it's original place in the partial
1072 schedualing. */
1075 step);
1076 success =
1080 tmp_follow);
1083 }
1084 else
1085 {
1086 /* The branch is placed in row ii - 1. */
1094 }
1098 }
1100 clear:
1103 }
1105 static void
1108 {
1110 ps_insn_ptr ps_ij;
1114 {
1119 /* Do not duplicate any insn which refers to count_reg as it
1120 belongs to the control part.
1121 The closing branch is scheduled as well and thus should
1122 be ignored.
1123 TODO: This should be done by analyzing the control part of
1124 the loop. */
1133 {
1136 else
1138 }
1139 }
1140 }
1143 /* Generate the instructions (including reg_moves) for prolog & epilog. */
1144 static void
1147 {
1150 edge e;
1152 /* Generate the prolog, inserting its insns on the loop-entry edge. */
1156 {
1157 /* Generate instructions at the beginning of the prolog to
1158 adjust the loop count by STAGE_COUNT. If loop count is constant
1159 (count_init), this constant is adjusted by STAGE_COUNT in
1160 generate_prolog_epilog function. */
1170 }
1175 /* Put the prolog on the entry edge. */
1183 /* Generate the epilog, inserting its insns on the loop-exit edge. */
1189 /* Put the epilogue on the exit edge. */
1197 }
1199 /* Mark LOOP as software pipelined so the later
1200 scheduling passes don't touch it. */
1201 static void
1203 {
1211 }
1213 /* Return true if all the BBs of the loop are empty except the
1214 loop header. */
1215 static bool
1217 {
1222 {
1229 /* Make sure that basic blocks other than the header
1230 have only notes labels or jumps. */
1233 {
1239 }
1242 {
1245 }
1246 }
1249 }
1251 /* Dump file:line from INSN's location info to dump_file. */
1253 static void
1255 {
1257 {
1260 }
1261 }
1263 /* A simple loop from SMS point of view; it is a loop that is composed of
1264 either a single basic block or two BBs - a header and a latch. */
1265 #define SIMPLE_SMS_LOOP_P(loop) ((loop->num_nodes < 3 ) \
1266 && (EDGE_COUNT (loop->latch->preds) == 1) \
1267 && (EDGE_COUNT (loop->latch->succs) == 1))
1269 /* Return true if the loop is in its canonical form and false if not.
1270 i.e. SIMPLE_SMS_LOOP_P and have one preheader block, and single exit. */
1271 static bool
1273 {
1276 {
1280 }
1283 {
1285 {
1291 }
1293 }
1296 {
1298 {
1304 }
1306 }
1309 }
1311 /* If there are more than one entry for the loop,
1312 make it one by splitting the first entry edge and
1313 redirecting the others to the new BB. */
1314 static void
1316 {
1317 edge e;
1318 edge_iterator i;
1320 /* Avoid annoying special cases of edges going to exit
1321 block. */
1328 {
1333 }
1334 }
1336 /* Setup infos. */
1337 static void
1339 {
1347 }
1349 /* Probability in % that the sms-ed loop rolls enough so that optimized
1350 version may be entered. Just a guess. */
1351 #define PROB_SMS_ENOUGH_ITERATIONS 80
1353 /* Used to calculate the upper bound of ii. */
1354 #define MAXII_FACTOR 2
1356 /* Main entry point, perform SMS scheduling on the loops of the function
1357 that consist of single basic blocks. */
1358 static void
1360 {
1365 partial_schedule_ptr ps;
1369 edge latch_edge;
1375 {
1378 }
1380 /* Initialize issue_rate. */
1382 {
1388 }
1389 else
1392 /* Initialize the scheduler. */
1396 /* Allocate memory to hold the DDG array one entry for each loop.
1397 We use loop->num as index into this array. */
1401 {
1404 }
1406 /* Build DDGs for all the relevant loops and hold them in G_ARR
1407 indexed by the loop index. */
1409 {
1411 rtx count_reg;
1413 /* For debugging. */
1415 {
1420 }
1423 {
1429 }
1435 {
1439 }
1449 /* Perform SMS only on loops that their average count is above threshold. */
1453 {
1455 {
1459 {
1472 }
1473 }
1475 }
1477 /* Make sure this is a doloop. */
1479 {
1483 }
1485 /* Don't handle BBs with calls or barriers
1486 or !single_set with the exception of instructions that include
1487 count_reg---these instructions are part of the control part
1488 that do-loop recognizes.
1489 ??? Should handle insns defining subregs. */
1491 {
1492 rtx set;
1502 }
1505 {
1507 {
1515 else
1518 }
1521 }
1523 /* Always schedule the closing branch with the rest of the
1524 instructions. The branch is rotated to be in row ii-1 at the
1525 end of the scheduling procedure to make sure it's the last
1526 instruction in the iteration. */
1528 {
1532 }
1538 }
1540 {
1543 }
1545 /* We don't want to perform SMS on new loops - created by versioning. */
1547 {
1549 rtx count_reg;
1559 {
1567 }
1577 {
1581 {
1590 }
1595 }
1598 /* In case of th loop have doloop register it gets special
1599 handling. */
1602 {
1603 basic_block pre_header;
1608 }
1612 {
1615 loop_count);
1617 }
1631 {
1639 {
1640 /* Try to achieve optimized SC by normalizing the partial
1641 schedule (having the cycles start from cycle zero).
1642 The branch location must be placed in row ii-1 in the
1643 final scheduling. If failed, shift all instructions to
1644 position the branch in row ii-1. */
1648 else
1649 {
1650 /* Bring the branch to cycle ii-1. */
1658 }
1661 }
1663 /* The default value of PARAM_SMS_MIN_SC is 2 as stage count of
1664 1 means that there is no interleaving between iterations thus
1665 we let the scheduling passes do the job in this case. */
1669 {
1671 {
1679 }
1681 }
1684 {
1685 /* Rotate the partial schedule to have the branch in row ii-1. */
1690 }
1696 {
1700 }
1702 /* Moves that handle incoming values might have been added
1703 to a new first stage. Bump the stage count if so.
1705 ??? Perhaps we could consider rotating the schedule here
1706 instead? */
1708 {
1710 stage_count++;
1711 }
1713 /* The stage count should now be correct without rotation. */
1720 {
1725 }
1727 /* case the BCT count is not known , Do loop-versioning */
1729 {
1739 }
1741 /* Set new iteration count of loop kernel. */
1746 /* Now apply the scheduled kernel to the RTL of the loop. */
1749 /* Mark this loop as software pipelined so the later
1750 scheduling passes don't touch it. */
1754 /* The life-info is not valid any more. */
1760 /* Generate prolog and epilog. */
1763 }
1769 }
1773 /* Release scheduler data, needed until now because of DFA. */
1776 }
1778 /* The SMS scheduling algorithm itself
1779 -----------------------------------
1780 Input: 'O' an ordered list of insns of a loop.
1781 Output: A scheduling of the loop - kernel, prolog, and epilogue.
1783 'Q' is the empty Set
1784 'PS' is the partial schedule; it holds the currently scheduled nodes with
1785 their cycle/slot.
1786 'PSP' previously scheduled predecessors.
1787 'PSS' previously scheduled successors.
1788 't(u)' the cycle where u is scheduled.
1789 'l(u)' is the latency of u.
1790 'd(v,u)' is the dependence distance from v to u.
1791 'ASAP(u)' the earliest time at which u could be scheduled as computed in
1792 the node ordering phase.
1793 'check_hardware_resources_conflicts(u, PS, c)'
1794 run a trace around cycle/slot through DFA model
1795 to check resource conflicts involving instruction u
1796 at cycle c given the partial schedule PS.
1797 'add_to_partial_schedule_at_time(u, PS, c)'
1798 Add the node/instruction u to the partial schedule
1799 PS at time c.
1800 'calculate_register_pressure(PS)'
1801 Given a schedule of instructions, calculate the register
1802 pressure it implies. One implementation could be the
1803 maximum number of overlapping live ranges.
1804 'maxRP' The maximum allowed register pressure, it is usually derived from the number
1805 registers available in the hardware.
1807 1. II = MII.
1808 2. PS = empty list
1809 3. for each node u in O in pre-computed order
1810 4. if (PSP(u) != Q && PSS(u) == Q) then
1811 5. Early_start(u) = max ( t(v) + l(v) - d(v,u)*II ) over all every v in PSP(u).
1812 6. start = Early_start; end = Early_start + II - 1; step = 1
1813 11. else if (PSP(u) == Q && PSS(u) != Q) then
1814 12. Late_start(u) = min ( t(v) - l(v) + d(v,u)*II ) over all every v in PSS(u).
1815 13. start = Late_start; end = Late_start - II + 1; step = -1
1816 14. else if (PSP(u) != Q && PSS(u) != Q) then
1817 15. Early_start(u) = max ( t(v) + l(v) - d(v,u)*II ) over all every v in PSP(u).
1818 16. Late_start(u) = min ( t(v) - l(v) + d(v,u)*II ) over all every v in PSS(u).
1819 17. start = Early_start;
1820 18. end = min(Early_start + II - 1 , Late_start);
1821 19. step = 1
1822 20. else "if (PSP(u) == Q && PSS(u) == Q)"
1823 21. start = ASAP(u); end = start + II - 1; step = 1
1824 22. endif
1826 23. success = false
1827 24. for (c = start ; c != end ; c += step)
1828 25. if check_hardware_resources_conflicts(u, PS, c) then
1829 26. add_to_partial_schedule_at_time(u, PS, c)
1830 27. success = true
1831 28. break
1832 29. endif
1833 30. endfor
1834 31. if (success == false) then
1835 32. II = II + 1
1836 33. if (II > maxII) then
1837 34. finish - failed to schedule
1838 35. endif
1839 36. goto 2.
1840 37. endif
1841 38. endfor
1842 39. if (calculate_register_pressure(PS) > maxRP) then
1843 40. goto 32.
1844 41. endif
1845 42. compute epilogue & prologue
1846 43. finish - succeeded to schedule
1848 ??? The algorithm restricts the scheduling window to II cycles.
1849 In rare cases, it may be better to allow windows of II+1 cycles.
1850 The window would then start and end on the same row, but with
1851 different "must precede" and "must follow" requirements. */
1853 /* A limit on the number of cycles that resource conflicts can span. ??? Should
1854 be provided by DFA, and be dependent on the type of insn scheduled. Currently
1855 set to 0 to save compile time. */
1856 #define DFA_HISTORY SMS_DFA_HISTORY
1858 /* A threshold for the number of repeated unsuccessful attempts to insert
1859 an empty row, before we flush the partial schedule and start over. */
1860 #define MAX_SPLIT_NUM 10
1861 /* Given the partial schedule PS, this function calculates and returns the
1862 cycles in which we can schedule the node with the given index I.
1863 NOTE: Here we do the backtracking in SMS, in some special cases. We have
1864 noticed that there are several cases in which we fail to SMS the loop
1865 because the sched window of a node is empty due to tight data-deps. In
1866 such cases we want to unschedule some of the predecessors/successors
1867 until we get non-empty scheduling window. It returns -1 if the
1868 scheduling window is empty and zero otherwise. */
1870 static int
1874 {
1877 ddg_edge_ptr e;
1887 /* 1. compute sched window for u (start, end, step). */
1893 /* We first compute a forward range (start <= end), then decide whether
1894 to reverse it. */
1905 {
1912 }
1913 /* Calculate early_start and limit end. Both bounds are inclusive. */
1916 {
1920 {
1926 {
1931 }
1937 count_preds++;
1938 }
1939 }
1941 /* Calculate late_start and limit start. Both bounds are inclusive. */
1944 {
1948 {
1954 {
1959 }
1965 count_succs++;
1966 }
1967 }
1970 {
1976 }
1978 /* Get a target scheduling window no bigger than ii. */
1985 /* Apply memory dependence limits. */
1993 /* If there are at least as many successors as predecessors, schedule the
1994 node close to its successors. */
1996 {
1999 }
2001 /* Now that we've finalized the window, make END an exclusive rather
2002 than an inclusive bound. */
2012 {
2017 }
2020 }
2022 /* Calculate MUST_PRECEDE/MUST_FOLLOW bitmaps of U_NODE; which is the
2023 node currently been scheduled. At the end of the calculation
2024 MUST_PRECEDE/MUST_FOLLOW contains all predecessors/successors of
2025 U_NODE which are (1) already scheduled in the first/last row of
2026 U_NODE's scheduling window, (2) whose dependence inequality with U
2027 becomes an equality when U is scheduled in this same row, and (3)
2028 whose dependence latency is zero.
2030 The first and last rows are calculated using the following parameters:
2031 START/END rows - The cycles that begins/ends the traversal on the window;
2032 searching for an empty cycle to schedule U_NODE.
2033 STEP - The direction in which we traverse the window.
2034 II - The initiation interval. */
2036 static void
2040 {
2041 ddg_edge_ptr e;
2046 /* Consider the following scheduling window:
2047 {first_cycle_in_window, first_cycle_in_window+1, ...,
2048 last_cycle_in_window}. If step is 1 then the following will be
2049 the order we traverse the window: {start=first_cycle_in_window,
2050 first_cycle_in_window+1, ..., end=last_cycle_in_window+1},
2051 or {start=last_cycle_in_window, last_cycle_in_window-1, ...,
2052 end=first_cycle_in_window-1} if step is -1. */
2062 /* Instead of checking if:
2063 (SMODULO (SCHED_TIME (e->src), ii) == first_row_in_window)
2064 && ((SCHED_TIME (e->src) + e->latency - (e->distance * ii)) ==
2065 first_cycle_in_window)
2066 && e->latency == 0
2067 we use the fact that latency is non-negative:
2068 SCHED_TIME (e->src) - (e->distance * ii) <=
2069 SCHED_TIME (e->src) + e->latency - (e->distance * ii)) <=
2070 first_cycle_in_window
2071 and check only if
2072 SCHED_TIME (e->src) - (e->distance * ii) == first_cycle_in_window */
2076 first_cycle_in_window))
2077 {
2082 }
2087 /* Instead of checking if:
2088 (SMODULO (SCHED_TIME (e->dest), ii) == last_row_in_window)
2089 && ((SCHED_TIME (e->dest) - e->latency + (e->distance * ii)) ==
2090 last_cycle_in_window)
2091 && e->latency == 0
2092 we use the fact that latency is non-negative:
2093 SCHED_TIME (e->dest) + (e->distance * ii) >=
2094 SCHED_TIME (e->dest) - e->latency + (e->distance * ii)) >=
2095 last_cycle_in_window
2096 and check only if
2097 SCHED_TIME (e->dest) + (e->distance * ii) == last_cycle_in_window */
2101 last_cycle_in_window))
2102 {
2107 }
2111 }
2113 /* Return 1 if U_NODE can be scheduled in CYCLE. Use the following
2114 parameters to decide if that's possible:
2115 PS - The partial schedule.
2116 U - The serial number of U_NODE.
2117 NUM_SPLITS - The number of row splits made so far.
2118 MUST_PRECEDE - The nodes that must precede U_NODE. (only valid at
2119 the first row of the scheduling window)
2120 MUST_FOLLOW - The nodes that must follow U_NODE. (only valid at the
2121 last row of the scheduling window) */
2123 static bool
2127 sbitmap must_follow)
2128 {
2129 ps_insn_ptr psi;
2135 {
2143 }
2146 }
2148 /* This function implements the scheduling algorithm for SMS according to the
2149 above algorithm. */
2150 static partial_schedule_ptr
2152 {
2169 {
2177 {
2183 {
2186 }
2191 /* Try to get non-empty scheduling window. */
2195 {
2206 must_follow);
2209 {
2215 success =
2217 sched_nodes,
2219 tmp_follow);
2222 }
2225 }
2227 {
2234 {
2241 }
2243 num_splits++;
2244 /* The scheduling window is exclusive of 'end'
2245 whereas compute_split_window() expects an inclusive,
2246 ordered range. */
2250 else
2259 }
2261 /* ??? If (success), check register pressure estimates. */
2265 {
2268 }
2269 else
2278 }
2280 /* This function inserts a new empty row into PS at the position
2281 according to SPLITROW, keeping all already scheduled instructions
2282 intact and updating their SCHED_TIME and cycle accordingly. */
2283 static void
2285 sbitmap sched_nodes)
2286 {
2287 ps_insn_ptr crr_insn;
2296 /* We normalize sched_time and rotate ps to have only non-negative sched
2297 times, for simplicity of updating cycles after inserting new row. */
2309 {
2315 {
2323 }
2325 }
2330 {
2336 {
2344 }
2345 }
2347 /* Updating ps. */
2364 }
2366 /* Given U_NODE which is the node that failed to be scheduled; LOW and
2367 UP which are the boundaries of it's scheduling window; compute using
2368 SCHED_NODES and II a row in the partial schedule that can be split
2369 which will separate a critical predecessor from a critical successor
2370 thereby expanding the window, and return it. */
2371 static int
2373 ddg_node_ptr u_node)
2374 {
2375 ddg_edge_ptr e;
2382 {
2388 {
2391 }
2392 }
2395 {
2398 }
2401 {
2407 {
2410 }
2411 }
2414 {
2417 }
2423 }
2425 static void
2427 {
2429 ps_insn_ptr crr_insn;
2432 {
2436 {
2439 length++;
2441 /* ??? Test also that all nodes of sched_nodes are in ps, perhaps by
2442 popcount (sched_nodes) == number of insns in ps. */
2445 }
2448 }
2449 }
2451 \f
2452 /* This page implements the algorithm for ordering the nodes of a DDG
2453 for modulo scheduling, activated through the
2454 "int sms_order_nodes (ddg_ptr, int mii, int * result)" API. */
2456 #define ORDER_PARAMS(x) ((struct node_order_params *) (x)->aux.info)
2457 #define ASAP(x) (ORDER_PARAMS ((x))->asap)
2458 #define ALAP(x) (ORDER_PARAMS ((x))->alap)
2459 #define HEIGHT(x) (ORDER_PARAMS ((x))->height)
2460 #define MOB(x) (ALAP ((x)) - ASAP ((x)))
2461 #define DEPTH(x) (ASAP ((x)))
2474 struct node_order_params
2475 {
2479 };
2481 /* Check if NODE_ORDER contains a permutation of 0 .. NUM_NODES-1. */
2482 static void
2484 {
2494 {
2502 }
2508 }
2510 /* Order the nodes of G for scheduling and pass the result in
2511 NODE_ORDER. Also set aux.count of each node to ASAP.
2512 Put maximal ASAP to PMAX_ASAP. Return the recMII for the given DDG. */
2513 static int
2515 {
2528 /* First SCC has the largest recurrence_length. */
2531 /* Save ASAP before destroying node_order_params. */
2533 {
2536 }
2543 }
2545 static void
2547 {
2559 /* Perform the node ordering starting from the SCC with the highest recMII.
2560 For each SCC order the nodes according to their ASAP/ALAP/HEIGHT etc. */
2562 {
2565 /* Add nodes on paths from previous SCCs to the current SCC. */
2569 /* Add nodes on paths from the current SCC to previous SCCs. */
2573 /* Remove nodes of previous SCCs from current extended SCC. */
2577 /* Above call to order_nodes_in_scc updated prev_sccs |= tmp. */
2578 }
2580 /* Handle the remaining nodes that do not belong to any scc. Each call
2581 to order_nodes_in_scc handles a single connected component. */
2583 {
2586 }
2591 }
2593 /* MII is needed if we consider backarcs (that do not close recursive cycles). */
2596 {
2600 ddg_edge_ptr e;
2601 /* Allocate a place to hold ordering params for each node in the DDG. */
2602 nopa node_order_params_arr;
2604 /* Initialize of ASAP/ALAP/HEIGHT to zero. */
2608 /* Set the aux pointer of each node to point to its order_params structure. */
2612 /* Disregarding a backarc from each recursive cycle to obtain a DAG,
2613 calculate ASAP, ALAP, mobility, distance, and height for each node
2614 in the dependence (direct acyclic) graph. */
2616 /* We assume that the nodes in the array are in topological order. */
2620 {
2629 }
2632 {
2639 {
2644 }
2645 }
2647 {
2650 {
2655 }
2656 }
2660 }
2662 static int
2664 {
2668 sbitmap_iterator sbi;
2671 {
2675 {
2678 }
2679 }
2681 }
2683 static int
2685 {
2690 sbitmap_iterator sbi;
2693 {
2697 {
2701 }
2704 {
2707 }
2708 }
2710 }
2712 static int
2714 {
2719 sbitmap_iterator sbi;
2722 {
2726 {
2730 }
2733 {
2736 }
2737 }
2739 }
2741 /* Places the nodes of SCC into the NODE_ORDER array starting
2742 at position POS, according to the SMS ordering algorithm.
2743 NODES_ORDERED (in&out parameter) holds the bitset of all nodes in
2744 the NODE_ORDER array, starting from position zero. */
2745 static int
2748 {
2765 {
2768 }
2770 {
2773 }
2774 else
2775 {
2782 }
2786 {
2788 ddg_node_ptr v_node;
2789 sbitmap v_node_preds;
2790 sbitmap v_node_succs;
2793 {
2795 {
2802 /* Don't consider the already ordered successors again. */
2807 }
2812 }
2813 else
2814 {
2816 {
2823 /* Don't consider the already ordered predecessors again. */
2828 }
2833 }
2834 }
2841 }
2843 \f
2844 /* This page contains functions for manipulating partial-schedules during
2845 modulo scheduling. */
2847 /* Create a partial schedule and allocate a memory to hold II rows. */
2849 static partial_schedule_ptr
2851 {
2863 }
2865 /* Free the PS_INSNs in rows array of the given partial schedule.
2866 ??? Consider caching the PS_INSN's. */
2867 static void
2869 {
2873 {
2875 {
2880 }
2882 }
2883 }
2885 /* Free all the memory allocated to the partial schedule. */
2887 static void
2889 {
2904 }
2906 /* Clear the rows array with its PS_INSNs, and create a new one with
2907 NEW_II rows. */
2909 static void
2911 {
2925 }
2927 /* Prints the partial schedule as an ii rows array, for each rows
2928 print the ids of the insns in it. */
2929 void
2931 {
2935 {
2940 {
2945 else
2949 }
2950 }
2951 }
2953 /* Creates an object of PS_INSN and initializes it to the given parameters. */
2954 static ps_insn_ptr
2956 {
2965 }
2968 /* Removes the given PS_INSN from the partial schedule. */
2969 static void
2971 {
2978 {
2983 }
2984 else
2985 {
2989 }
2994 }
2996 /* Unlike what literature describes for modulo scheduling (which focuses
2997 on VLIW machines) the order of the instructions inside a cycle is
2998 important. Given the bitmaps MUST_FOLLOW and MUST_PRECEDE we know
2999 where the current instruction should go relative to the already
3000 scheduled instructions in the given cycle. Go over these
3001 instructions and find the first possible column to put it in. */
3002 static bool
3005 {
3006 ps_insn_ptr next_ps_i;
3017 /* Find the first must follow and the last must precede
3018 and insert the node immediately after the must precede
3019 but make sure that it there is no must follow after it. */
3021 next_ps_i;
3023 {
3029 {
3030 /* If we have already met a node that must follow, then
3031 there is no possible column. */
3034 else
3036 }
3037 /* The closing branch must be the last in the row. */
3044 }
3046 /* The closing branch is scheduled as well. Make sure there is no
3047 dependent instruction after it as the branch should be the last
3048 instruction in the row. */
3050 {
3054 {
3055 /* Make the branch the last in the row. New instructions
3056 will be inserted at the beginning of the row or after the
3057 last must_precede instruction thus the branch is guaranteed
3058 to remain the last instruction in the row. */
3062 }
3063 else
3066 }
3068 /* Now insert the node after INSERT_AFTER_PSI. */
3071 {
3077 }
3078 else
3079 {
3085 }
3088 }
3090 /* Advances the PS_INSN one column in its current row; returns false
3091 in failure and true in success. Bit N is set in MUST_FOLLOW if
3092 the node with cuid N must be come after the node pointed to by
3093 PS_I when scheduled in the same cycle. */
3094 static int
3096 sbitmap must_follow)
3097 {
3109 /* Check if next_in_row is dependent on ps_i, both having same sched
3110 times (typically ANTI_DEP). If so, ps_i cannot skip over it. */
3114 /* Advance PS_I over its next_in_row in the doubly linked list. */
3134 }
3136 /* Inserts a DDG_NODE to the given partial schedule at the given cycle.
3137 Returns 0 if this is not possible and a PS_INSN otherwise. Bit N is
3138 set in MUST_PRECEDE/MUST_FOLLOW if the node with cuid N must be come
3139 before/after (respectively) the node pointed to by PS_I when scheduled
3140 in the same cycle. */
3141 static ps_insn_ptr
3144 {
3145 ps_insn_ptr ps_i;
3153 /* Finds and inserts PS_I according to MUST_FOLLOW and
3154 MUST_PRECEDE. */
3156 {
3159 }
3163 }
3165 /* Advance time one cycle. Assumes DFA is being used. */
3166 static void
3168 {
3178 }
3182 /* Checks if PS has resource conflicts according to DFA, starting from
3183 FROM cycle to TO cycle; returns true if there are conflicts and false
3184 if there are no conflicts. Assumes DFA is being used. */
3185 static int
3187 {
3193 {
3194 ps_insn_ptr crr_insn;
3195 /* Holds the remaining issue slots in the current row. */
3198 /* Walk through the DFA for the current row. */
3200 crr_insn;
3202 {
3208 /* Check if there is room for the current insn. */
3212 /* Update the DFA state and return with failure if the DFA found
3213 resource conflicts. */
3218 can_issue_more =
3221 /* A naked CLOBBER or USE generates no instruction, so don't
3222 let them consume issue slots. */
3225 can_issue_more--;
3226 }
3228 /* Advance the DFA to the next cycle. */
3230 }
3232 }
3234 /* Checks if the given node causes resource conflicts when added to PS at
3235 cycle C. If not the node is added to PS and returned; otherwise zero
3236 is returned. Bit N is set in MUST_PRECEDE/MUST_FOLLOW if the node with
3237 cuid N must be come before/after (respectively) the node pointed to by
3238 PS_I when scheduled in the same cycle. */
3239 ps_insn_ptr
3242 sbitmap must_follow)
3243 {
3245 ps_insn_ptr ps_i;
3247 /* First add the node to the PS, if this succeeds check for
3248 conflicts, trying different issue slots in the same row. */
3258 /* Try different issue slots to find one that the given node can be
3259 scheduled in without conflicts. */
3261 {
3269 }
3272 {
3275 }
3280 }
3282 /* Calculate the stage count of the partial schedule PS. The calculation
3283 takes into account the rotation amount passed in ROTATION_AMOUNT. */
3284 int
3286 {
3291 /* The calculation of stage count is done adding the number of stages
3292 before cycle zero and after cycle zero. */
3296 }
3298 /* Rotate the rows of PS such that insns scheduled at time
3299 START_CYCLE will appear in row 0. Updates max/min_cycles. */
3300 void
3302 {
3311 /* Revisit later and optimize this into a single loop. */
3313 {
3318 {
3321 }
3325 }
3329 }
3332 \f
3333 /* Run instruction scheduler. */
3334 /* Perform SMS module scheduling. */
3339 {
3349 };
3352 {
3356 {}
3358 /* opt_pass methods: */
3360 {
3362 }
3368 unsigned int
3370 {
3371 #ifdef INSN_SCHEDULING
3372 basic_block bb;
3374 /* Collect loop information to be used in SMS. */
3378 /* Update the life information, because we add pseudos. */
3381 /* Finalize layout changes. */
3389 }
3393 rtl_opt_pass *
3395 {
3397 }