| blob | f3d31e178afd09887f13164eff53100e4a99c656 |
1 /* IRA hard register and memory cost calculation for allocnos or pseudos.
2 Copyright (C) 2006-2016 Free Software Foundation, Inc.
3 Contributed by Vladimir Makarov <vmakarov@redhat.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/>. */
37 /* The flags is set up every time when we calculate pseudo register
38 classes through function ira_set_pseudo_classes. */
41 /* TRUE if we work with allocnos. Otherwise we work with pseudos. */
44 /* Number of elements in array `costs'. */
47 /* The `costs' struct records the cost of using hard registers of each
48 class considered for the calculation and of using memory for each
49 allocno or pseudo. */
50 struct costs
51 {
53 /* Costs for register classes start here. We process only some
54 allocno classes. */
56 };
58 #define max_struct_costs_size \
59 (this_target_ira_int->x_max_struct_costs_size)
60 #define init_cost \
61 (this_target_ira_int->x_init_cost)
62 #define temp_costs \
63 (this_target_ira_int->x_temp_costs)
64 #define op_costs \
65 (this_target_ira_int->x_op_costs)
66 #define this_op_costs \
67 (this_target_ira_int->x_this_op_costs)
69 /* Costs of each class for each allocno or pseudo. */
72 /* Accumulated costs of each class for each allocno. */
75 /* It is the current size of struct costs. */
78 /* Return pointer to structure containing costs of allocno or pseudo
79 with given NUM in array ARR. */
80 #define COSTS(arr, num) \
81 ((struct costs *) ((char *) (arr) + (num) * struct_costs_size))
83 /* Return index in COSTS when processing reg with REGNO. */
84 #define COST_INDEX(regno) (allocno_p \
85 ? ALLOCNO_NUM (ira_curr_regno_allocno_map[regno]) \
86 : (int) regno)
88 /* Record register class preferences of each allocno or pseudo. Null
89 value means no preferences. It happens on the 1st iteration of the
90 cost calculation. */
93 /* Allocated buffers for pref. */
96 /* Record allocno class of each allocno with the same regno. */
99 /* Record cost gains for not allocating a register with an invariant
100 equivalence. */
103 /* Execution frequency of the current insn. */
106 \f
108 /* Info about reg classes whose costs are calculated for a pseudo. */
109 struct cost_classes
110 {
111 /* Number of the cost classes in the subsequent array. */
113 /* Container of the cost classes. */
115 /* Map reg class -> index of the reg class in the previous array.
116 -1 if it is not a cost class. */
118 /* Map hard regno index of first class in array CLASSES containing
119 the hard regno, -1 otherwise. */
121 };
123 /* Types of pointers to the structure above. */
127 /* Info about cost classes for each pseudo. */
130 /* Helper for cost_classes hashing. */
133 {
137 };
139 /* Returns hash value for cost classes info HV. */
140 inline hashval_t
142 {
144 }
146 /* Compares cost classes info HV1 and HV2. */
149 {
153 }
155 /* Delete cost classes info V from the hash table. */
158 {
160 }
162 /* Hash table of unique cost classes. */
165 /* Map allocno class -> cost classes for pseudo of given allocno
166 class. */
169 /* Map mode -> cost classes for pseudo of give mode. */
172 /* Cost classes that include all classes in ira_important_classes. */
175 /* Use the array of classes in CLASSES_PTR to fill out the rest of
176 the structure. */
177 static void
179 {
185 {
189 {
193 }
194 }
195 }
197 /* Initialize info about the cost classes for each pseudo. */
198 static void
200 {
214 }
216 /* Create new cost classes from cost classes FROM and set up members
217 index and hard_regno_index. Return the new classes. The function
218 implements some common code of two functions
219 setup_regno_cost_classes_by_aclass and
220 setup_regno_cost_classes_by_mode. */
221 static cost_classes_t
223 {
224 cost_classes_t classes_ptr;
232 }
234 /* Return a version of FULL that only considers registers in REGS that are
235 valid for mode MODE. Both FULL and the returned class are globally
236 allocated. */
237 static cost_classes_t
240 {
245 {
246 /* Assume that we'll drop the class. */
249 /* Ignore classes that are too small for the mode. */
254 /* Calculate the set of registers in CL that belong to REGS and
255 are valid for MODE. */
256 HARD_REG_SET valid_for_cl;
265 /* Don't use this class if the set of valid registers is a subset
266 of an existing class. For example, suppose we have two classes
267 GR_REGS and FR_REGS and a union class GR_AND_FR_REGS. Suppose
268 that the mode changes allowed by FR_REGS are not as general as
269 the mode changes allowed by GR_REGS.
271 In this situation, the mode changes for GR_AND_FR_REGS could
272 either be seen as the union or the intersection of the mode
273 changes allowed by the two subclasses. The justification for
274 the union-based definition would be that, if you want a mode
275 change that's only allowed by GR_REGS, you can pick a register
276 from the GR_REGS subclass. The justification for the
277 intersection-based definition would be that every register
278 from the class would allow the mode change.
280 However, if we have a register that needs to be in GR_REGS,
281 using GR_AND_FR_REGS with the intersection-based definition
282 would be too pessimistic, since it would bring in restrictions
283 that only apply to FR_REGS. Conversely, if we have a register
284 that needs to be in FR_REGS, using GR_AND_FR_REGS with the
285 union-based definition would lose the extra restrictions
286 placed on FR_REGS. GR_AND_FR_REGS is therefore only useful
287 for cases where GR_REGS and FP_REGS are both valid. */
290 {
294 }
297 {
298 /* If several classes are equivalent, prefer to use the one
299 that was chosen as the allocno class. */
304 }
305 }
311 {
313 /* Map equivalent classes to the representative that we chose above. */
315 {
320 }
322 }
324 }
326 /* Setup cost classes for pseudo REGNO whose allocno class is ACLASS.
327 This function is used when we know an initial approximation of
328 allocno class of the pseudo already, e.g. on the second iteration
329 of class cost calculation or after class cost calculation in
330 register-pressure sensitive insn scheduling or register-pressure
331 sensitive loop-invariant motion. */
332 static void
334 {
336 cost_classes_t classes_ptr;
344 {
347 /* We exclude classes from consideration which are subsets of
348 ACLASS only if ACLASS is an uniform class. */
352 {
355 {
356 /* Exclude non-uniform classes which are subsets of
357 ACLASS. */
362 }
364 }
367 {
370 }
372 }
374 {
375 /* Restrict the classes to those that are valid for REGNO's mode
376 (which might for example exclude singleton classes if the mode
377 requires two registers). Also restrict the classes to those that
378 are valid for subregs of REGNO. */
385 }
387 }
389 /* Setup cost classes for pseudo REGNO with MODE. Usage of MODE can
390 decrease number of cost classes for the pseudo, if hard registers
391 of some important classes can not hold a value of MODE. So the
392 pseudo can not get hard register of some important classes and cost
393 calculation for such important classes is only wasting CPU
394 time. */
395 static void
397 {
401 else
402 {
408 }
409 }
411 /* Finalize info about the cost classes for each pseudo. */
412 static void
414 {
418 }
420 \f
422 /* Compute the cost of loading X into (if TO_P is TRUE) or from (if
423 TO_P is FALSE) a register of class RCLASS in mode MODE. X must not
424 be a pseudo register. */
425 static int
428 {
429 secondary_reload_info sri;
432 /* If X is a SCRATCH, there is actually nothing to move since we are
433 assuming optimal allocation. */
437 /* Get the class we will actually use for a reload. */
440 /* If we need a secondary reload for an intermediate, the cost is
441 that to load the input into the intermediate register, then to
442 copy it. */
445 /* PR 68770: Secondary reload might examine the t_icode field. */
451 {
456 }
458 /* For memory, use the memory move cost, for (hard) registers, use
459 the cost to move between the register classes, and use 2 for
460 everything else (constants). */
465 {
471 }
472 else
473 /* If this is a constant, we may eventually want to call rtx_cost
474 here. */
476 }
478 \f
480 /* Record the cost of using memory or hard registers of various
481 classes for the operands in INSN.
483 N_ALTS is the number of alternatives.
484 N_OPS is the number of operands.
485 OPS is an array of the operands.
486 MODES are the modes of the operands, in case any are VOIDmode.
487 CONSTRAINTS are the constraints to use for the operands. This array
488 is modified by this procedure.
490 This procedure works alternative by alternative. For each
491 alternative we assume that we will be able to allocate all allocnos
492 to their ideal register class and calculate the cost of using that
493 alternative. Then we compute, for each operand that is a
494 pseudo-register, the cost of having the allocno allocated to each
495 register class and using it in that alternative. To this cost is
496 added the cost of the alternative.
498 The cost of each class for this insn is its lowest cost among all
499 the alternatives. */
500 static void
504 {
514 /* Process each alternative, each time minimizing an operand's cost
515 with the cost for each operand in that alternative. */
518 {
526 {
531 }
534 {
542 /* Initially show we know nothing about the register class. */
546 /* If this operand has no constraints at all, we can
547 conclude nothing about it since anything is valid. */
549 {
553 }
555 /* If this alternative is only relevant when this operand
556 matches a previous operand, we do different things
557 depending on whether this operand is a allocno-reg or not.
558 We must process any modifiers for the operand before we
559 can make this test. */
561 p++;
564 {
565 /* Copy class and whether memory is allowed from the
566 matching alternative. Then perform any needed cost
567 computations and/or adjustments. */
575 {
576 /* If this matches the other operand, we have no
577 added cost and we win. */
580 /* If we can put the other operand into a register,
581 add to the cost of this alternative the cost to
582 copy this operand to the register used for the
583 other operand. */
585 {
588 }
589 }
592 {
593 /* This op is an allocno but the one it matches is
594 not. */
596 /* If we can't put the other operand into a
597 register, this alternative can't be used. */
601 /* Otherwise, add to the cost of this alternative
602 the cost to copy the other operand to the hard
603 register used for this operand. */
604 else
606 }
607 else
608 {
609 /* The costs of this operand are not the same as the
610 other operand since move costs are not symmetric.
611 Moreover, if we cannot tie them, this alternative
612 needs to do a copy, which is one insn. */
615 cost_classes_t cost_classes_ptr
624 {
627 {
630 {
633 }
634 }
635 else
636 {
639 {
643 }
644 }
645 }
647 {
650 {
653 {
656 }
657 }
658 else
659 {
662 {
666 }
667 }
668 }
669 else
670 {
672 {
675 {
680 }
681 }
682 else
683 {
687 {
692 }
693 }
694 }
696 /* If the alternative actually allows memory, make
697 things a bit cheaper since we won't need an extra
698 insn to load it. */
699 pp->mem_cost
704 /* If we have assigned a class to this allocno in
705 our first pass, add a cost to this alternative
706 corresponding to what we would add if this
707 allocno were not in the appropriate class. */
709 {
713 alt_cost
714 += ((out_p
716 + (in_p
721 alt_cost
723 }
728 p++;
729 }
730 }
732 /* Scan all the constraint letters. See if the operand
733 matches any of the constraints. Collect the valid
734 register classes and see if this operand accepts
735 memory. */
737 {
739 {
741 /* Ignore the next letter for this pass. */
766 {
780 /* Every MEM can be reloaded to fit. */
793 /* Every address can be reloaded to fit. */
798 /* We know this operand is an address, so we
799 want it to be allocated to a hard register
800 that can be the base of an address,
801 i.e. BASE_REG_CLASS. */
812 }
814 }
818 }
822 /* How we account for this operand now depends on whether it
823 is a pseudo register or not. If it is, we first check if
824 any register classes are valid. If not, we ignore this
825 alternative, since we want to assume that all allocnos get
826 allocated for register preferencing. If some register
827 class is valid, compute the costs of moving the allocno
828 into that class. */
830 {
832 {
833 /* We must always fail if the operand is a REG, but
834 we did not find a suitable class and memory is
835 not allowed.
837 Otherwise we may perform an uninitialized read
838 from this_op_costs after the `continue' statement
839 below. */
841 }
842 else
843 {
855 {
858 {
861 {
864 }
865 }
866 else
867 {
870 {
874 }
875 }
876 }
878 {
881 {
884 {
887 }
888 }
889 else
890 {
893 {
897 }
898 }
899 }
900 else
901 {
903 {
906 {
911 }
912 }
913 else
914 {
918 {
923 }
924 }
925 }
928 /* Although we don't need insn to reload from
929 memory, still accessing memory is usually more
930 expensive than a register. */
932 else
933 /* If the alternative actually allows memory, make
934 things a bit cheaper since we won't need an
935 extra insn to load it. */
936 pp->mem_cost
940 /* If we have assigned a class to this allocno in
941 our first pass, add a cost to this alternative
942 corresponding to what we would add if this
943 allocno were not in the appropriate class. */
945 {
949 {
951 alt_cost
952 += ((out_p
955 + (in_p
958 }
960 alt_cost
961 += ((out_p
964 + (in_p
969 alt_cost += (ira_register_move_cost
971 }
972 }
973 }
975 /* Otherwise, if this alternative wins, either because we
976 have already determined that or if we have a hard
977 register of the proper class, there is no cost for this
978 alternative. */
982 ;
984 /* If registers are valid, the cost of this alternative
985 includes copying the object to and/or from a
986 register. */
988 {
994 }
995 /* The only other way this alternative can be used is if
996 this is a constant that could be placed into memory. */
999 else
1001 }
1007 /* Finally, update the costs with the information we've
1008 calculated about this alternative. */
1011 {
1015 cost_classes_t cost_classes_ptr
1024 }
1025 }
1029 {
1030 ira_allocno_t a;
1038 }
1040 }
1042 \f
1044 /* Wrapper around REGNO_OK_FOR_INDEX_P, to allow pseudo registers. */
1047 {
1051 }
1053 /* A version of regno_ok_for_base_p for use here, when all
1054 pseudo-registers should count as OK. Arguments as for
1055 regno_ok_for_base_p. */
1059 {
1065 }
1067 /* Record the pseudo registers we must reload into hard registers in a
1068 subexpression of a memory address, X.
1070 If CONTEXT is 0, we are looking at the base part of an address,
1071 otherwise we are looking at the index part.
1073 MODE and AS are the mode and address space of the memory reference;
1074 OUTER_CODE and INDEX_CODE give the context that the rtx appears in.
1075 These four arguments are passed down to base_reg_class.
1077 SCALE is twice the amount to multiply the cost by (it is twice so
1078 we can represent half-cost adjustments). */
1079 static void
1083 {
1089 else
1093 {
1103 /* When we have an address that is a sum, we must determine
1104 whether registers are "base" or "index" regs. If there is a
1105 sum of two registers, we must choose one to be the "base".
1106 Luckily, we can use the REG_POINTER to make a good choice
1107 most of the time. We only need to do this on machines that
1108 can have two registers in an address and where the base and
1109 index register classes are different.
1111 ??? This code used to set REGNO_POINTER_FLAG in some cases,
1112 but that seems bogus since it should only be set when we are
1113 sure the register is being used as a pointer. */
1114 {
1120 /* Look inside subregs. */
1126 /* If this machine only allows one register per address, it
1127 must be in the first operand. */
1131 /* If index and base registers are the same on this machine,
1132 just record registers in any non-constant operands. We
1133 assume here, as well as in the tests below, that all
1134 addresses are in canonical form. */
1137 {
1141 }
1143 /* If the second operand is a constant integer, it doesn't
1144 change what class the first operand must be. */
1147 /* If the second operand is a symbolic constant, the first
1148 operand must be an index register. */
1151 /* If both operands are registers but one is already a hard
1152 register of index or reg-base class, give the other the
1153 class that the hard register is not. */
1170 /* If one operand is known to be a pointer, it must be the
1171 base with the other operand the index. Likewise if the
1172 other operand is a MULT. */
1174 {
1177 }
1179 {
1182 }
1183 /* Otherwise, count equal chances that each might be a base or
1184 index register. This case should be rare. */
1185 else
1186 {
1191 }
1192 }
1195 /* Double the importance of an allocno that is incremented or
1196 decremented, since it would take two extra insns if it ends
1197 up in the wrong place. */
1211 /* Double the importance of an allocno that is incremented or
1212 decremented, since it would take two extra insns if it ends
1213 up in the wrong place. */
1218 {
1223 cost_classes_t cost_classes_ptr;
1237 else
1245 {
1250 else
1252 }
1253 }
1257 {
1263 scale);
1264 }
1265 }
1266 }
1268 \f
1270 /* Calculate the costs of insn operands. */
1271 static void
1273 {
1277 rtx set;
1281 {
1284 }
1286 /* If we get here, we are set up to record the costs of all the
1287 operands for this insn. Start by initializing the costs. Then
1288 handle any address registers. Finally record the desired classes
1289 for any allocnos, doing it twice if some pair of operands are
1290 commutative. */
1292 {
1305 || (insn_extra_address_constraint
1310 }
1312 /* Check for commutative in a separate loop so everything will have
1313 been initialized. We must do this even if one operand is a
1314 constant--see addsi3 in m68k.md. */
1317 {
1321 /* Handle commutative operands by swapping the constraints.
1322 We assume the modes are the same. */
1331 }
1336 /* If this insn is a single set copying operand 1 to operand 0 and
1337 one operand is an allocno with the other a hard reg or an allocno
1338 that prefers a hard register that is in its own register class
1339 then we may want to adjust the cost of that register class to -1.
1341 Avoid the adjustment if the source does not die to avoid
1342 stressing of register allocator by preferencing two colliding
1343 registers into single class.
1345 Also avoid the adjustment if a copy between hard registers of the
1346 class is expensive (ten times the cost of a default copy is
1347 considered arbitrarily expensive). This avoids losing when the
1348 preferred class is very expensive as the source of a copy
1349 instruction. */
1351 /* In rare cases the single set insn might have less 2 operands
1352 as the source can be a fixed special reg. */
1355 {
1374 {
1378 reg_class_t rclass;
1383 {
1388 {
1391 else
1392 {
1395 nr++)
1402 }
1403 }
1404 }
1405 }
1406 }
1407 }
1409 \f
1411 /* Process one insn INSN. Scan it and record each time it would save
1412 code to put a certain allocnos in a certain class. Return the last
1413 insn processed, so that the scan can be continued from there. */
1416 {
1433 /* If this insn loads a parameter from its stack slot, then it
1434 represents a savings, rather than a cost, if the parameter is
1435 stored in memory. Record this fact.
1437 Similarly if we're loading other constants from memory (constant
1438 pool, TOC references, small data areas, etc) and this is the only
1439 assignment to the destination pseudo.
1441 Don't do this if SET_SRC (set) isn't a general operand, if it is
1442 a memory requiring special instructions to load it, decreasing
1443 mem_cost might result in it being loaded using the specialized
1444 instruction into a register, then stored into stack and loaded
1445 again from the stack. See PR52208.
1447 Don't do this if SET_SRC (set) has side effect. See PR56124. */
1457 {
1469 }
1473 /* Now add the cost for each operand to the total costs for its
1474 allocno. */
1478 {
1486 /* If the already accounted for the memory "cost" above, don't
1487 do so again. */
1489 {
1493 else
1495 }
1497 {
1501 else
1503 }
1504 }
1507 }
1509 \f
1511 /* Print allocnos costs to file F. */
1512 static void
1514 {
1516 ira_allocno_t a;
1517 ira_allocno_iterator ai;
1522 {
1524 basic_block bb;
1533 else
1537 {
1544 }
1550 }
1551 }
1553 /* Print pseudo costs to file F. */
1554 static void
1556 {
1559 cost_classes_t cost_classes_ptr;
1565 {
1572 {
1576 }
1578 }
1579 }
1581 /* Traverse the BB represented by LOOP_TREE_NODE to update the allocno
1582 costs. */
1583 static void
1585 {
1593 }
1595 /* Traverse the BB represented by LOOP_TREE_NODE to update the allocno
1596 costs. */
1597 static void
1599 {
1600 basic_block bb;
1605 }
1607 /* Find costs of register classes and memory for allocnos or pseudos
1608 and their best costs. Set up preferred, alternative and allocno
1609 classes for pseudos. */
1610 static void
1612 {
1615 basic_block bb;
1619 regno_best_class
1626 {
1627 ira_allocno_t a;
1628 ira_allocno_iterator ai;
1633 {
1635 setup_regno_cost_classes_by_aclass
1637 max_cost_classes_num
1640 }
1642 }
1643 else
1644 {
1650 else
1653 }
1655 /* Clear the flag for the next compiled function. */
1657 /* Normally we scan the insns once and determine the best class to
1658 use for each allocno. However, if -fexpensive-optimizations are
1659 on, we do so twice, the second time using the tentative best
1660 classes to guide the selection. */
1662 {
1668 {
1671 {
1673 max_cost_classes_num
1675 }
1676 }
1678 struct_costs_size
1680 /* Zero out our accumulation of the cost of each class for each
1681 allocno. */
1685 {
1686 /* Scan the instructions and record each time it would save code
1687 to put a certain allocno in a certain class. */
1693 }
1694 else
1695 {
1696 basic_block bb;
1700 }
1705 /* Now for each allocno look at how desirable each class is and
1706 find which class is preferred. */
1708 {
1711 ira_loop_tree_node_t parent;
1721 {
1726 }
1727 else
1728 {
1733 /* Find cost of all allocnos with the same regno. */
1737 {
1745 /* There are no caps yet. */
1749 {
1750 /* Propagate costs to upper levels in the region
1751 tree. */
1756 {
1760 else
1762 }
1770 else
1776 }
1779 {
1783 else
1785 }
1789 else
1791 }
1792 }
1798 {
1802 }
1807 /* Find best common class for all allocnos with the same
1808 regno. */
1810 {
1813 {
1816 }
1820 /* We still prefer registers to memory even at this
1821 stage if their costs are the same. We will make
1822 a final decision during assigning hard registers
1823 when we have all info including more accurate
1824 costs which might be affected by assigning hard
1825 registers to other pseudos because the pseudos
1826 involved in moves can be coalesced. */
1831 }
1837 /* Registers in the alternative class are likely to need
1838 longer or slower sequences than registers in the best class.
1839 When optimizing we make some effort to use the best class
1840 over the alternative class where possible, but at -O0 we
1841 effectively give the alternative class equal weight.
1842 We then run the risk of using slower alternative registers
1843 when plenty of registers from the best class are still free.
1844 This is especially true because live ranges tend to be very
1845 short in -O0 code and so register pressure tends to be low.
1847 Avoid that by ignoring the alternative class if the best
1848 class has plenty of registers. */
1850 else
1851 {
1852 /* Make the common class the biggest class of best and
1853 alt_class. */
1858 }
1862 {
1870 }
1872 {
1874 /* Do not assign NO_REGS to static chain pointer
1875 pseudo when non-local goto is used. */
1887 }
1890 {
1895 }
1899 {
1907 else
1908 {
1909 /* Finding best class which is subset of the common
1910 class. */
1915 {
1920 {
1924 }
1926 {
1929 }
1930 }
1932 }
1935 {
1939 else
1945 }
1951 {
1958 / (ira_register_move_cost
1963 }
1964 }
1965 }
1968 {
1971 else
1974 }
1975 }
1977 }
1979 \f
1981 /* Process moves involving hard regs to modify allocno hard register
1982 costs. We can do this only after determining allocno class. If a
1983 hard register forms a register class, then moves with the hard
1984 register are already taken into account in class costs for the
1985 allocno. */
1986 static void
1988 {
1992 ira_loop_tree_node_t curr_loop_tree_node;
1994 basic_block bb;
2005 {
2019 {
2023 }
2026 {
2030 }
2031 else
2045 {
2048 machine_mode mode;
2063 }
2064 }
2065 }
2067 /* After we find hard register and memory costs for allocnos, define
2068 its class and modify hard register cost because insns moving
2069 allocno to/from hard registers. */
2070 static void
2072 {
2076 ira_allocno_t a;
2077 ira_allocno_iterator ai;
2078 cost_classes_t cost_classes_ptr;
2082 {
2093 {
2098 {
2102 else
2103 {
2107 {
2110 }
2112 }
2113 }
2114 }
2115 }
2119 }
2121 \f
2123 /* Function called once during compiler work. */
2124 void
2126 {
2131 {
2134 }
2136 }
2138 /* Free allocated temporary cost vectors. */
2139 void
2141 {
2147 {
2151 }
2154 }
2156 /* This is called each time register related information is
2157 changed. */
2158 void
2160 {
2164 max_struct_costs_size
2166 /* Don't use ira_allocate because vectors live through several IRA
2167 calls. */
2173 {
2176 }
2178 }
2180 \f
2182 /* Common initialization function for ira_costs and
2183 ira_set_pseudo_classes. */
2184 static void
2186 {
2196 }
2198 /* Common finalization function for ira_costs and
2199 ira_set_pseudo_classes. */
2200 static void
2202 {
2208 }
2210 /* Entry function which defines register class, memory and hard
2211 register costs for each allocno. */
2212 void
2214 {
2227 }
2229 /* Entry function which defines classes for pseudos.
2230 Set pseudo_classes_defined_p only if DEFINE_PSEUDO_CLASSES is true. */
2231 void
2233 {
2245 }
2247 \f
2249 /* Change hard register costs for allocnos which lives through
2250 function calls. This is called only when we found all intersected
2251 calls during building allocno live ranges. */
2252 void
2254 {
2258 machine_mode mode;
2259 ira_allocno_t a;
2260 ira_allocno_iterator ai;
2261 ira_allocno_object_iterator oi;
2262 ira_object_t obj;
2267 {
2276 {
2277 ira_allocate_and_set_costs
2282 {
2286 {
2288 OBJECT_CONFLICT_HARD_REGS
2290 {
2293 }
2294 }
2299 crossed_calls_clobber_regs
2304 call_used_reg_set)
2309 #ifdef IRA_HARD_REGNO_ADD_COST_MULTIPLIER
2314 #endif
2317 else
2321 }
2322 }
2326 /* Some targets allow pseudos to be allocated to unaligned sequences
2327 of hard registers. However, selecting an unaligned sequence can
2328 unnecessarily restrict later allocations. So increase the cost of
2329 unaligned hard regs to encourage the use of aligned hard regs. */
2330 {
2334 {
2335 ira_allocate_and_set_costs
2339 {
2342 {
2346 }
2347 }
2348 }
2349 }
2350 }
2351 }
2353 /* Add COST to the estimated gain for eliminating REGNO with its
2354 equivalence. If COST is zero, record that no such elimination is
2355 possible. */
2357 void
2359 {
2362 else
2364 }
2366 void
2368 {
2370 }