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1 /* Register to Stack convert for GNU compiler.
2 Copyright (C) 1992, 1993, 1994, 1995, 1996 Free Software Foundation, Inc.
4 This file is part of GNU CC.
6 GNU CC is free software; you can redistribute it and/or modify
7 it under the terms of the GNU General Public License as published by
8 the Free Software Foundation; either version 2, or (at your option)
9 any later version.
11 GNU CC is distributed in the hope that it will be useful,
12 but WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 GNU General Public License for more details.
16 You should have received a copy of the GNU General Public License
17 along with GNU CC; see the file COPYING. If not, write to
18 the Free Software Foundation, 59 Temple Place - Suite 330,
19 Boston, MA 02111-1307, USA. */
21 /* This pass converts stack-like registers from the "flat register
22 file" model that gcc uses, to a stack convention that the 387 uses.
24 * The form of the input:
26 On input, the function consists of insn that have had their
27 registers fully allocated to a set of "virtual" registers. Note that
28 the word "virtual" is used differently here than elsewhere in gcc: for
29 each virtual stack reg, there is a hard reg, but the mapping between
30 them is not known until this pass is run. On output, hard register
31 numbers have been substituted, and various pop and exchange insns have
32 been emitted. The hard register numbers and the virtual register
33 numbers completely overlap - before this pass, all stack register
34 numbers are virtual, and afterward they are all hard.
36 The virtual registers can be manipulated normally by gcc, and their
37 semantics are the same as for normal registers. After the hard
38 register numbers are substituted, the semantics of an insn containing
39 stack-like regs are not the same as for an insn with normal regs: for
40 instance, it is not safe to delete an insn that appears to be a no-op
41 move. In general, no insn containing hard regs should be changed
42 after this pass is done.
44 * The form of the output:
46 After this pass, hard register numbers represent the distance from
47 the current top of stack to the desired register. A reference to
48 FIRST_STACK_REG references the top of stack, FIRST_STACK_REG + 1,
49 represents the register just below that, and so forth. Also, REG_DEAD
50 notes indicate whether or not a stack register should be popped.
52 A "swap" insn looks like a parallel of two patterns, where each
53 pattern is a SET: one sets A to B, the other B to A.
55 A "push" or "load" insn is a SET whose SET_DEST is FIRST_STACK_REG
56 and whose SET_DEST is REG or MEM. Any other SET_DEST, such as PLUS,
57 will replace the existing stack top, not push a new value.
59 A store insn is a SET whose SET_DEST is FIRST_STACK_REG, and whose
60 SET_SRC is REG or MEM.
62 The case where the SET_SRC and SET_DEST are both FIRST_STACK_REG
63 appears ambiguous. As a special case, the presence of a REG_DEAD note
64 for FIRST_STACK_REG differentiates between a load insn and a pop.
66 If a REG_DEAD is present, the insn represents a "pop" that discards
67 the top of the register stack. If there is no REG_DEAD note, then the
68 insn represents a "dup" or a push of the current top of stack onto the
69 stack.
71 * Methodology:
73 Existing REG_DEAD and REG_UNUSED notes for stack registers are
74 deleted and recreated from scratch. REG_DEAD is never created for a
75 SET_DEST, only REG_UNUSED.
77 Before life analysis, the mode of each insn is set based on whether
78 or not any stack registers are mentioned within that insn. VOIDmode
79 means that no regs are mentioned anyway, and QImode means that at
80 least one pattern within the insn mentions stack registers. This
81 information is valid until after reg_to_stack returns, and is used
82 from jump_optimize.
84 * asm_operands:
86 There are several rules on the usage of stack-like regs in
87 asm_operands insns. These rules apply only to the operands that are
88 stack-like regs:
90 1. Given a set of input regs that die in an asm_operands, it is
91 necessary to know which are implicitly popped by the asm, and
92 which must be explicitly popped by gcc.
94 An input reg that is implicitly popped by the asm must be
95 explicitly clobbered, unless it is constrained to match an
96 output operand.
98 2. For any input reg that is implicitly popped by an asm, it is
99 necessary to know how to adjust the stack to compensate for the pop.
100 If any non-popped input is closer to the top of the reg-stack than
101 the implicitly popped reg, it would not be possible to know what the
102 stack looked like - it's not clear how the rest of the stack "slides
103 up".
105 All implicitly popped input regs must be closer to the top of
106 the reg-stack than any input that is not implicitly popped.
108 3. It is possible that if an input dies in an insn, reload might
109 use the input reg for an output reload. Consider this example:
111 asm ("foo" : "=t" (a) : "f" (b));
113 This asm says that input B is not popped by the asm, and that
114 the asm pushes a result onto the reg-stack, ie, the stack is one
115 deeper after the asm than it was before. But, it is possible that
116 reload will think that it can use the same reg for both the input and
117 the output, if input B dies in this insn.
119 If any input operand uses the "f" constraint, all output reg
120 constraints must use the "&" earlyclobber.
122 The asm above would be written as
124 asm ("foo" : "=&t" (a) : "f" (b));
126 4. Some operands need to be in particular places on the stack. All
127 output operands fall in this category - there is no other way to
128 know which regs the outputs appear in unless the user indicates
129 this in the constraints.
131 Output operands must specifically indicate which reg an output
132 appears in after an asm. "=f" is not allowed: the operand
133 constraints must select a class with a single reg.
135 5. Output operands may not be "inserted" between existing stack regs.
136 Since no 387 opcode uses a read/write operand, all output operands
137 are dead before the asm_operands, and are pushed by the asm_operands.
138 It makes no sense to push anywhere but the top of the reg-stack.
140 Output operands must start at the top of the reg-stack: output
141 operands may not "skip" a reg.
143 6. Some asm statements may need extra stack space for internal
144 calculations. This can be guaranteed by clobbering stack registers
145 unrelated to the inputs and outputs.
147 Here are a couple of reasonable asms to want to write. This asm
148 takes one input, which is internally popped, and produces two outputs.
150 asm ("fsincos" : "=t" (cos), "=u" (sin) : "0" (inp));
152 This asm takes two inputs, which are popped by the fyl2xp1 opcode,
153 and replaces them with one output. The user must code the "st(1)"
154 clobber for reg-stack.c to know that fyl2xp1 pops both inputs.
156 asm ("fyl2xp1" : "=t" (result) : "0" (x), "u" (y) : "st(1)");
158 */
159 \f
160 #include <stdio.h>
170 #ifdef STACK_REGS
172 #define REG_STACK_SIZE (LAST_STACK_REG - FIRST_STACK_REG + 1)
174 /* This is the basic stack record. TOP is an index into REG[] such
175 that REG[TOP] is the top of stack. If TOP is -1 the stack is empty.
177 If TOP is -2, REG[] is not yet initialized. Stack initialization
178 consists of placing each live reg in array `reg' and setting `top'
179 appropriately.
181 REG_SET indicates which registers are live. */
184 {
190 /* highest instruction uid */
193 /* Number of basic blocks in the current function. */
196 /* Element N is first insn in basic block N.
197 This info lasts until we finish compiling the function. */
200 /* Element N is last insn in basic block N.
201 This info lasts until we finish compiling the function. */
204 /* Element N is nonzero if control can drop into basic block N */
207 /* Element N says all about the stack at entry block N */
210 /* Element N says all about the stack life at the end of block N */
213 /* This is where the BLOCK_NUM values are really stored. This is set
214 up by find_blocks and used there and in life_analysis. It can be used
215 later, but only to look up an insn that is the head or tail of some
216 block. life_analysis and the stack register conversion process can
217 add insns within a block. */
220 /* This is the register file for all register after conversion */
221 static rtx
224 #define FP_MODE_REG(regno,mode) \
225 (FP_mode_reg[(regno)-FIRST_STACK_REG][(int)(mode)])
227 /* Get the basic block number of an insn. See note at block_number
228 definition are validity of this information. */
230 #define BLOCK_NUM(INSN) \
231 ((INSN_UID (INSN) > max_uid) \
232 ? (abort() , -1) : block_number[INSN_UID (INSN)])
236 /* Forward declarations */
274 \f
275 /* Mark all registers needed for this pattern. */
277 static void
279 rtx pat;
281 {
287 {
291 }
292 else
298 }
299 \f
300 /* Reorganise the stack into ascending numbers,
301 after this insn. */
303 static void
305 rtx insn;
306 stack regstack;
307 {
317 }
318 \f
319 /* Return non-zero if any stack register is mentioned somewhere within PAT. */
321 int
323 rtx pat;
324 {
333 {
335 {
341 }
344 }
347 }
348 \f
349 /* Convert register usage from "flat" register file usage to a "stack
350 register file. FIRST is the first insn in the function, FILE is the
351 dump file, if used.
353 First compute the beginning and end of each basic block. Do a
354 register life analysis on the stack registers, recording the result
355 for the head and tail of each basic block. The convert each insn one
356 by one. Run a last jump_optimize() pass, if optimizing, to eliminate
357 any cross-jumping created when the converter inserts pop insns.*/
359 void
361 rtx first;
363 {
368 HARD_REG_SET stackentry;
372 {
375 {
376 #if 0
378 initialised, because the rtx's are
379 thrown away between compilations of
380 functions. */
381 #endif
383 {
390 }
391 }
392 }
394 /* Count the basic blocks. Also find maximum insn uid. */
395 {
403 {
404 /* Note that this loop must select the same block boundaries
405 as code in find_blocks. Also note that this code is not the
406 same as that used in flow.c. */
418 blocks++;
423 /* Remember whether or not this insn mentions an FP regs.
424 Check JUMP_INSNs too, in case someone creates a funny PARALLEL. */
428 {
432 /* Note any register passing parameters. */
438 }
439 else
447 }
448 }
450 /* If no stack register reference exists in this insn, there isn't
451 anything to convert. */
456 /* If there are stack registers, there must be at least one block. */
461 /* Allocate some tables that last till end of compiling this function
462 and some needed only in find_blocks and life_analysis. */
478 /* Dump the life analysis debug information before jump
479 optimization, as that will destroy the LABEL_REFS we keep the
480 information in. */
489 }
490 \f
491 /* Check PAT, which is in INSN, for LABEL_REFs. Add INSN to the
492 label's chain of references, and note which insn contains each
493 reference. */
495 static void
498 {
504 {
511 /* If this is an undefined label, LABEL_REFS (label) contains
512 garbage. */
516 /* Don't make a duplicate in the code_label's chain. */
529 }
533 {
537 {
541 }
542 }
543 }
544 \f
545 /* Return a pointer to the REG expression within PAT. If PAT is not a
546 REG, possible enclosed by a conversion rtx, return the inner part of
547 PAT that stopped the search. */
552 {
555 {
557 /* eliminate FP subregister accesses in favour of the
558 actual FP register in use. */
559 {
560 rtx subreg;
562 {
567 }
568 }
573 }
574 }
575 \f
576 /* Scan the OPERANDS and OPERAND_CONSTRAINTS of an asm_operands.
577 N_OPERANDS is the total number of operands. Return which alternative
578 matched, or -1 is no alternative matches.
580 OPERAND_MATCHES is an array which indicates which operand this
581 operand matches due to the constraints, or -1 if no match is required.
582 If two operands match by coincidence, but are not required to match by
583 the constraints, -1 is returned.
585 OPERAND_CLASS is an array which indicates the smallest class
586 required by the constraints. If the alternative that matches calls
587 for some class `class', and the operand matches a subclass of `class',
588 OPERAND_CLASS is set to `class' as required by the constraints, not to
589 the subclass. If an alternative allows more than one class,
590 OPERAND_CLASS is set to the smallest class that is a union of the
591 allowed classes. */
593 static int
601 {
611 /* Compute the number of alternatives in the operands. reload has
612 already guaranteed that all operands have the same number of
613 alternatives. */
621 {
625 /* No operands match, no narrow class requirements yet. */
627 {
630 }
633 {
642 {
647 }
649 /* An empty constraint or empty alternative
650 allows anything which matched the pattern. */
656 {
664 /* Ignore these. */
668 /* Ignore rest of this alternative. */
678 /* This operand must be the same as a previous one.
679 This kind of constraint is used for instructions such
680 as add when they take only two operands.
682 Note that the lower-numbered operand is passed first. */
686 {
689 }
693 /* p is used for address_operands. Since this is an asm,
694 just to make sure that the operand is valid for Pmode. */
701 /* Anything goes unless it is a REG and really has a hard reg
702 but the hard reg is not in the class GENERAL_REGS. */
706 {
711 }
718 {
722 }
726 /* This is used for a MATCH_SCRATCH in the cases when we
727 don't actually need anything. So anything goes any time. */
751 /* Match any CONST_DOUBLE, but only if
752 we can examine the bits of it reliably. */
778 /* Fall through */
804 #ifdef EXTRA_CONSTRAINT
813 #endif
829 {
833 }
834 }
837 /* If this operand did not win somehow,
838 this alternative loses. */
841 }
842 /* This alternative won; the operands are ok.
843 Change whichever operands this alternative says to change. */
847 this_alternative++;
848 }
850 /* For operands constrained to match another operand, copy the other
851 operand's class to this operand's class. */
857 }
858 \f
859 /* Record the life info of each stack reg in INSN, updating REGSTACK.
860 N_INPUTS is the number of inputs; N_OUTPUTS the outputs. CONSTRAINTS
861 is an array of the constraint strings used in the asm statement.
862 OPERANDS is an array of all operands for the insn, and is assumed to
863 contain all output operands, then all inputs operands.
865 There are many rules that an asm statement for stack-like regs must
866 follow. Those rules are explained at the top of this file: the rule
867 numbers below refer to that explanation. */
869 static void
872 rtx insn;
873 stack regstack;
877 {
895 /* Find out what the constraints require. If no constraint
896 alternative matches, this asm is malformed. */
902 /* Strip SUBREGs here to make the following code simpler. */
908 /* Set up CLOBBER_REG. */
913 {
918 {
926 {
928 n_clobbers++;
929 }
930 }
931 }
933 /* Enforce rule #4: Output operands must specifically indicate which
934 reg an output appears in after an asm. "=f" is not allowed: the
935 operand constraints must select a class with a single reg.
937 Also enforce rule #5: Output operands must start at the top of
938 the reg-stack: output operands may not "skip" a reg. */
944 {
945 error_for_asm
948 }
949 else
953 /* Search for first non-popped reg. */
958 /* If there are any other popped regs, that's an error. */
964 {
967 }
969 /* Enforce rule #2: All implicitly popped input regs must be closer
970 to the top of the reg-stack than any input that is not implicitly
971 popped. */
976 {
977 /* An input reg is implicitly popped if it is tied to an
978 output, or if there is a CLOBBER for it. */
987 }
989 /* Search for first non-popped reg. */
994 /* If there are any other popped regs, that's an error. */
1000 {
1004 }
1006 /* Enfore rule #3: If any input operand uses the "f" constraint, all
1007 output constraints must use the "&" earlyclobber.
1009 ??? Detect this more deterministically by having constraint_asm_operands
1010 record any earlyclobber. */
1014 {
1019 {
1023 }
1024 }
1027 {
1028 /* Avoid further trouble with this insn. */
1032 }
1034 /* Process all outputs */
1036 {
1042 else
1045 /* Each destination is dead before this insn. If the
1046 destination is not used after this insn, record this with
1047 REG_UNUSED. */
1054 }
1056 /* Process all inputs */
1058 {
1062 else
1065 /* If an input is dead after the insn, record a death note.
1066 But don't record a death note if there is already a death note,
1067 or if the input is also an output. */
1076 }
1077 }
1079 /* Scan PAT, which is part of INSN, and record registers appearing in
1080 a SET_DEST in DEST, and other registers in SRC.
1082 This function does not know about SET_DESTs that are both input and
1083 output (such as ZERO_EXTRACT) - this cannot happen on a 387. */
1085 static void
1087 rtx pat;
1090 {
1096 {
1104 }
1107 {
1111 }
1113 /* We don't need to consider either of these cases. */
1119 {
1121 {
1126 }
1129 }
1130 }
1131 \f
1132 /* Calculate the number of inputs and outputs in BODY, an
1133 asm_operands. N_OPERANDS is the total number of operands, and
1134 N_INPUTS and N_OUTPUTS are pointers to ints into which the results are
1135 placed. */
1137 static void
1139 rtx body;
1142 {
1156 else
1160 }
1161 \f
1162 /* Scan INSN, which is in BLOCK, and record the life & death of stack
1163 registers in REGSTACK. This function is called to process insns from
1164 the last insn in a block to the first. The actual scanning is done in
1165 record_reg_life_pat.
1167 If a register is live after a CALL_INSN, but is not a value return
1168 register for that CALL_INSN, then code is emitted to initialize that
1169 register. The block_end[] data is kept accurate.
1171 Existing death and unset notes for stack registers are deleted
1172 before processing the insn. */
1174 static void
1176 rtx insn;
1178 stack regstack;
1179 {
1187 /* Strip death notes for stack regs from this insn */
1195 else
1198 /* Process all patterns in the insn. */
1202 {
1203 /* This insn is an `asm' with operands. Decode the operands,
1204 decide how many are inputs, and record the life information. */
1216 }
1218 {
1227 note;
1235 {
1245 }
1248 {
1251 /* There might be a reg that is live after a function call.
1252 Initialize it to zero so that the program does not crash. See
1253 comment towards the end of stack_reg_life_analysis(). */
1258 {
1261 /* The insn will use virtual register numbers, and so
1262 convert_regs is expected to process these. But BLOCK_NUM
1263 cannot be used on these insns, because they do not appear in
1264 block_number[]. */
1273 /* If the CALL_INSN was the end of a block, move the
1274 block_end to point to the new insn. */
1278 }
1280 /* Some regs do not survive a CALL */
1282 }
1286 }
1287 }
1288 \f
1289 /* Find all basic blocks of the function, which starts with FIRST.
1290 For each JUMP_INSN, build the chain of LABEL_REFS on each CODE_LABEL. */
1292 static void
1294 rtx first;
1295 {
1302 /* Record where all the blocks start and end.
1303 Record which basic blocks control can drop in to. */
1307 {
1308 /* Note that this loop must select the same block boundaries
1309 as code in reg_to_stack, but that these are not the same
1310 as those selected in flow.c. */
1319 {
1323 }
1328 {
1329 rtx note;
1331 /* Make a list of all labels referred to other than by jumps. */
1335 label_value_list);
1336 }
1342 }
1347 /* generate all label references to the corresponding jump insn */
1349 {
1353 {
1356 rtx x;
1359 {
1375 }
1382 {
1392 }
1395 }
1396 }
1397 }
1399 /* Return 1 if X contain a REG or MEM that is not in the constant pool. */
1401 static int
1403 rtx x;
1404 {
1417 {
1426 }
1429 }
1431 /* If current function returns its result in an fp stack register,
1432 return the REG. Otherwise, return 0. */
1434 static rtx
1436 tree decl;
1437 {
1443 {
1444 #ifdef FUNCTION_OUTGOING_VALUE
1445 result
1447 #else
1449 #endif
1450 }
1453 }
1454 \f
1455 /* Determine the which registers are live at the start of each basic
1456 block of the function whose first insn is FIRST.
1458 First, if the function returns a real_type, mark the function
1459 return type as live at each return point, as the RTL may not give any
1460 hint that the register is live.
1462 Then, start with the last block and work back to the first block.
1463 Similarly, work backwards within each block, insn by insn, recording
1464 which regs are dead and which are used (and therefore live) in the
1465 hard reg set of block_stack_in[].
1467 After processing each basic block, if there is a label at the start
1468 of the block, propagate the live registers to all jumps to this block.
1470 As a special case, if there are regs live in this block, that are
1471 not live in a block containing a jump to this label, and the block
1472 containing the jump has already been processed, we must propagate this
1473 block's entry register life back to the block containing the jump, and
1474 restart life analysis from there.
1476 In the worst case, this function may traverse the insns
1477 REG_STACK_SIZE times. This is necessary, since a jump towards the end
1478 of the insns may not know that a reg is live at a target that is early
1479 in the insns. So we back up and start over with the new reg live.
1481 If there are registers that are live at the start of the function,
1482 insns are emitted to initialize these registers. Something similar is
1483 done after CALL_INSNs in record_reg_life. */
1485 static void
1487 rtx first;
1489 {
1493 {
1494 rtx retvalue;
1497 {
1498 /* Find all RETURN insns and mark them. */
1505 /* Mark off the end of last block if we "fall off" the end of the
1506 function into the epilogue. */
1511 }
1512 }
1514 /* now scan all blocks backward for stack register use */
1518 {
1521 /* current register status at last instruction */
1526 do
1527 {
1531 /* If the insn is a CALL_INSN, we need to ensure that
1532 everything dies. But otherwise don't process unless there
1533 are some stack regs present. */
1540 /* Set the state at the start of the block. Mark that no
1541 register mapping information known yet. */
1546 /* If there is a label, propagate our register life to all jumps
1547 to this label. */
1550 {
1556 {
1562 else
1563 {
1564 /* The block containing the jump has already been
1565 processed. If there are registers that were not known
1566 to be live then, but are live now, we must back up
1567 and restart life analysis from that point with the new
1568 life information. */
1572 win);
1580 win:
1581 ;
1582 }
1583 }
1586 }
1593 }
1595 /* If any reg is live at the start of the first block of a
1596 function, then we must guarantee that the reg holds some value by
1597 generating our own "load" of that register. Otherwise a 387 would
1598 fault trying to access an empty register. */
1600 /* Load zero into each live register. The fact that a register
1601 appears live at the function start necessarily implies an error
1602 in the user program: it means that (unless the offending code is *never*
1603 executed) this program is using uninitialised floating point
1604 variables. In order to keep broken code like this happy, we initialise
1605 those variables with zero.
1607 Note that we are inserting virtual register references here:
1608 these insns must be processed by convert_regs later. Also, these
1609 insns will not be in block_number, so BLOCK_NUM() will fail for them. */
1614 {
1615 rtx init_rtx;
1623 }
1624 }
1625 \f
1626 /*****************************************************************************
1627 This section deals with stack register substitution, and forms the second
1628 pass over the RTL.
1629 *****************************************************************************/
1631 /* Replace REG, which is a pointer to a stack reg RTX, with an RTX for
1632 the desired hard REGNO. */
1634 static void
1638 {
1644 {
1648 }
1651 }
1653 /* Remove a note of type NOTE, which must be found, for register
1654 number REGNO from INSN. Remove only one such note. */
1656 static void
1658 rtx insn;
1661 {
1668 {
1671 }
1672 else
1676 }
1678 /* Find the hard register number of virtual register REG in REGSTACK.
1679 The hard register number is relative to the top of the stack. -1 is
1680 returned if the register is not found. */
1682 static int
1684 stack regstack;
1685 rtx reg;
1686 {
1697 }
1699 /* Delete INSN from the RTL. Mark the insn, but don't remove it from
1700 the chain of insns. Doing so could confuse block_begin and block_end
1701 if this were the only insn in the block. */
1703 static void
1705 rtx insn;
1706 {
1710 }
1711 \f
1712 /* Emit an insn to pop virtual register REG before or after INSN.
1713 REGSTACK is the stack state after INSN and is updated to reflect this
1714 pop. WHEN is either emit_insn_before or emit_insn_after. A pop insn
1715 is represented as a SET whose destination is the register to be popped
1716 and source is the top of stack. A death note for the top of stack
1717 cases the movdf pattern to pop. */
1719 static rtx
1721 rtx insn;
1722 stack regstack;
1723 rtx reg;
1725 {
1738 /* ??? This used to be VOIDmode, but that seems wrong. */
1751 }
1752 \f
1753 /* Emit an insn before or after INSN to swap virtual register REG with the
1754 top of stack. WHEN should be `emit_insn_before' or `emit_insn_before'
1755 REGSTACK is the stack state before the swap, and is updated to reflect
1756 the swap. A swap insn is represented as a PARALLEL of two patterns:
1757 each pattern moves one reg to the other.
1759 If REG is already at the top of the stack, no insn is emitted. */
1761 static void
1763 rtx insn;
1764 stack regstack;
1765 rtx reg;
1766 {
1787 /* Find the previous insn involving stack regs, but don't go past
1788 any labels, calls or jumps. */
1797 {
1802 /* If the previous register stack push was from the reg we are to
1803 swap with, omit the swap. */
1810 /* If the previous insn wrote to the reg we are to swap with,
1811 omit the swap. */
1817 }
1820 {
1824 }
1829 /* ??? This used to be VOIDmode, but that seems wrong. */
1831 }
1832 \f
1833 /* Handle a move to or from a stack register in PAT, which is in INSN.
1834 REGSTACK is the current stack. */
1836 static void
1838 rtx insn;
1839 stack regstack;
1840 rtx pat;
1841 {
1845 rtx note;
1850 {
1851 /* Write from one stack reg to another. If SRC dies here, then
1852 just change the register mapping and delete the insn. */
1856 {
1859 /* If this is a no-op move, there must not be a REG_DEAD note. */
1867 /* The source must be live, and the dest must be dead. */
1871 /* It is possible that the dest is unused after this insn.
1872 If so, just pop the src. */
1875 {
1880 }
1890 }
1892 /* The source reg does not die. */
1894 /* If this appears to be a no-op move, delete it, or else it
1895 will confuse the machine description output patterns. But if
1896 it is REG_UNUSED, we must pop the reg now, as per-insn processing
1897 for REG_UNUSED will not work for deleted insns. */
1900 {
1906 }
1908 /* The destination ought to be dead */
1917 }
1919 {
1920 /* Save from a stack reg to MEM, or possibly integer reg. Since
1921 only top of stack may be saved, emit an exchange first if
1922 needs be. */
1928 {
1932 }
1934 {
1935 /* A 387 cannot write an XFmode value to a MEM without
1936 clobbering the source reg. The output code can handle
1937 this by reading back the value from the MEM.
1938 But it is more efficient to use a temp register if one is
1939 available. Push the source value here if the register
1940 stack is not full, and then write the value to memory via
1941 a pop. */
1950 }
1953 }
1955 {
1956 /* Load from MEM, or possibly integer REG or constant, into the
1957 stack regs. The actual target is always the top of the
1958 stack. The stack mapping is changed to reflect that DEST is
1959 now at top of stack. */
1961 /* The destination ought to be dead */
1971 }
1972 else
1974 }
1975 \f
1976 static void
1978 rtx pat;
1979 {
1984 {
1987 }
1991 {
1993 {
1998 }
2001 }
2002 }
2004 /* Handle a comparison. Special care needs to be taken to avoid
2005 causing comparisons that a 387 cannot do correctly, such as EQ.
2007 Also, a pop insn may need to be emitted. The 387 does have an
2008 `fcompp' insn that can pop two regs, but it is sometimes too expensive
2009 to do this - a `fcomp' followed by a `fstpl %st(0)' may be easier to
2010 set up. */
2012 static void
2014 rtx insn;
2015 stack regstack;
2016 rtx pat;
2017 {
2020 rtx cc0_user;
2026 /* If the insn that uses cc0 is a conditional move, then the destination
2027 must be the top of stack */
2031 {
2036 {
2038 }
2039 }
2041 /* ??? If fxch turns out to be cheaper than fstp, give priority to
2042 registers that die in this insn - move those to stack top first. */
2046 {
2063 }
2065 /* We will fix any death note later. */
2071 else
2082 {
2086 }
2088 /* If the second operand dies, handle that. But if the operands are
2089 the same stack register, don't bother, because only one death is
2090 needed, and it was just handled. */
2095 {
2096 /* As a special case, two regs may die in this insn if src2 is
2097 next to top of stack and the top of stack also dies. Since
2098 we have already popped src1, "next to top of stack" is really
2099 at top (FIRST_STACK_REG) now. */
2103 {
2107 }
2108 else
2109 {
2110 /* The 386 can only represent death of the first operand in
2111 the case handled above. In all other cases, emit a separate
2112 pop and remove the death note from here. */
2119 emit_insn_after);
2120 }
2121 }
2122 }
2123 \f
2124 /* Substitute new registers in PAT, which is part of INSN. REGSTACK
2125 is the current register layout. */
2127 static void
2129 rtx insn;
2130 stack regstack;
2131 rtx pat;
2132 {
2143 /* See if this is a `movM' pattern, and handle elsewhere if so. */
2151 else
2153 {
2159 {
2163 {
2166 }
2167 }
2172 /* This is a `tstM2' case. */
2178 /* Fall through. */
2184 /* These insns only operate on the top of the stack. DEST might
2185 be cc0_rtx if we're processing a tstM pattern. Also, it's
2186 possible that the tstM case results in a REG_DEAD note on the
2187 source. */
2200 {
2204 }
2212 /* On i386, reversed forms of subM3 and divM3 exist for
2213 MODE_FLOAT, so the same code that works for addM3 and mulM3
2214 can be used. */
2217 /* These insns can accept the top of stack as a destination
2218 from a stack reg or mem, or can use the top of stack as a
2219 source and some other stack register (possibly top of stack)
2220 as a destination. */
2225 /* We will fix any death note later. */
2229 else
2233 else
2236 /* If either operand is not a stack register, then the dest
2237 must be top of stack. */
2241 else
2242 {
2243 /* Both operands are REG. If neither operand is already
2244 at the top of stack, choose to make the one that is the dest
2245 the new top of stack. */
2257 }
2265 {
2266 /* If the register that dies is at the top of stack, then
2267 the destination is somewhere else - merely substitute it.
2268 But if the reg that dies is not at top of stack, then
2269 move the top of stack to the dead reg, as though we had
2270 done the insn and then a store-with-pop. */
2273 {
2276 }
2277 else
2278 {
2286 }
2292 }
2294 {
2296 {
2299 }
2300 else
2301 {
2309 }
2315 }
2316 else
2317 {
2320 }
2326 {
2329 /* These insns only operate on the top of the stack. */
2341 {
2345 }
2353 }
2357 /* This insn requires the top of stack to be the destination. */
2365 {
2380 {
2383 /* If the register that dies is not at the top of stack, then
2384 move the top of stack to the dead reg */
2387 {
2391 emit_insn_after);
2392 }
2393 else
2394 {
2399 }
2401 }
2405 }
2411 }
2412 }
2413 \f
2414 /* Substitute hard regnums for any stack regs in INSN, which has
2415 N_INPUTS inputs and N_OUTPUTS outputs. REGSTACK is the stack info
2416 before the insn, and is updated with changes made here. CONSTRAINTS is
2417 an array of the constraint strings used in the asm statement.
2419 OPERANDS is an array of the operands, and OPERANDS_LOC is a
2420 parallel array of where the operands were found. The output operands
2421 all precede the input operands.
2423 There are several requirements and assumptions about the use of
2424 stack-like regs in asm statements. These rules are enforced by
2425 record_asm_stack_regs; see comments there for details. Any
2426 asm_operands left in the RTL at this point may be assume to meet the
2427 requirements, since record_asm_stack_regs removes any problem asm. */
2429 static void
2432 rtx insn;
2433 stack regstack;
2437 {
2456 rtx note;
2459 /* Find out what the constraints required. If no constraint
2460 alternative matches, that is a compiler bug: we should have caught
2461 such an insn during the life analysis pass (and reload should have
2462 caught it regardless). */
2469 /* Strip SUBREGs here to make the following code simpler. */
2473 {
2476 }
2478 /* Set up NOTE_REG, NOTE_LOC and NOTE_KIND. */
2481 i++;
2489 {
2494 {
2497 }
2502 {
2506 n_notes++;
2507 }
2508 }
2510 /* Set up CLOBBER_REG and CLOBBER_LOC. */
2515 {
2521 {
2527 {
2530 }
2533 {
2536 n_clobbers++;
2537 }
2538 }
2539 }
2543 /* Put the input regs into the desired place in TEMP_STACK. */
2549 {
2550 /* If an operand needs to be in a particular reg in
2551 FLOAT_REGS, the constraint was either 't' or 'u'. Since
2552 these constraints are for single register classes, and reload
2553 guaranteed that operand[i] is already in that class, we can
2554 just use REGNO (operands[i]) to know which actual reg this
2555 operand needs to be in. */
2563 {
2564 /* operands[i] is not in the right place. Find it
2565 and swap it with whatever is already in I's place.
2566 K is where operands[i] is now. J is where it should
2567 be. */
2577 }
2578 }
2580 /* emit insns before INSN to make sure the reg-stack is in the right
2581 order. */
2585 /* Make the needed input register substitutions. Do death notes and
2586 clobbers too, because these are for inputs, not outputs. */
2590 {
2597 }
2601 {
2608 }
2611 {
2612 /* It's OK for a CLOBBER to reference a reg that is not live.
2613 Don't try to replace it in that case. */
2617 {
2618 /* Sigh - clobbers always have QImode. But replace_reg knows
2619 that these regs can't be MODE_INT and will abort. Just put
2620 the right reg there without calling replace_reg. */
2623 }
2624 }
2626 /* Now remove from REGSTACK any inputs that the asm implicitly popped. */
2630 {
2631 /* An input reg is implicitly popped if it is tied to an
2632 output, or if there is a CLOBBER for it. */
2640 {
2641 /* operands[i] might not be at the top of stack. But that's OK,
2642 because all we need to do is pop the right number of regs
2643 off of the top of the reg-stack. record_asm_stack_regs
2644 guaranteed that all implicitly popped regs were grouped
2645 at the top of the reg-stack. */
2650 }
2651 }
2653 /* Now add to REGSTACK any outputs that the asm implicitly pushed.
2654 Note that there isn't any need to substitute register numbers.
2655 ??? Explain why this is true. */
2658 {
2659 /* See if there is an output for this hard reg. */
2664 {
2668 }
2669 }
2671 /* Now emit a pop insn for any REG_UNUSED output, or any REG_DEAD
2672 input that the asm didn't implicitly pop. If the asm didn't
2673 implicitly pop an input reg, that reg will still be live.
2675 Note that we can't use find_regno_note here: the register numbers
2676 in the death notes have already been substituted. */
2680 {
2686 {
2688 emit_insn_after);
2690 }
2691 }
2695 {
2702 {
2704 emit_insn_after);
2706 }
2707 }
2708 }
2709 \f
2710 /* Substitute stack hard reg numbers for stack virtual registers in
2711 INSN. Non-stack register numbers are not changed. REGSTACK is the
2712 current stack content. Insns may be emitted as needed to arrange the
2713 stack for the 387 based on the contents of the insn. */
2715 static void
2717 rtx insn;
2718 stack regstack;
2719 {
2725 {
2728 /* If there are any floating point parameters to be passed in
2729 registers for this call, make sure they are in the right
2730 order. */
2733 {
2736 /* Now mark the arguments as dead after the call. */
2739 {
2742 }
2743 }
2744 }
2746 /* Do the actual substitution if any stack regs are mentioned.
2747 Since we only record whether entire insn mentions stack regs, and
2748 subst_stack_regs_pat only works for patterns that contain stack regs,
2749 we must check each pattern in a parallel here. A call_value_pop could
2750 fail otherwise. */
2753 {
2756 {
2757 /* This insn is an `asm' with operands. Decode the operands,
2758 decide how many are inputs, and do register substitution.
2759 Any REG_UNUSED notes will be handled by subst_asm_stack_regs. */
2774 }
2778 {
2782 }
2783 else
2785 }
2787 /* subst_stack_regs_pat may have deleted a no-op insn. If so, any
2788 REG_UNUSED will already have been dealt with, so just return. */
2793 /* If there is a REG_UNUSED note on a stack register on this insn,
2794 the indicated reg must be popped. The REG_UNUSED note is removed,
2795 since the form of the newly emitted pop insn references the reg,
2796 making it no longer `unset'. */
2801 {
2804 }
2805 else
2807 }
2808 \f
2809 /* Change the organization of the stack so that it fits a new basic
2810 block. Some registers might have to be popped, but there can never be
2811 a register live in the new block that is not now live.
2813 Insert any needed insns before or after INSN. WHEN is emit_insn_before
2814 or emit_insn_after. OLD is the original stack layout, and NEW is
2815 the desired form. OLD is updated to reflect the code emitted, ie, it
2816 will be the same as NEW upon return.
2818 This function will not preserve block_end[]. But that information
2819 is no longer needed once this has executed. */
2821 static void
2823 rtx insn;
2824 stack old;
2827 {
2830 /* We will be inserting new insns "backwards", by calling emit_insn_before.
2831 If we are to insert after INSN, find the next insn, and insert before
2832 it. */
2837 /* Pop any registers that are not needed in the new block. */
2842 emit_insn_before);
2845 {
2846 /* If the new block has never been processed, then it can inherit
2847 the old stack order. */
2851 }
2852 else
2853 {
2854 /* This block has been entered before, and we must match the
2855 previously selected stack order. */
2857 /* By now, the only difference should be the order of the stack,
2858 not their depth or liveliness. */
2864 win:
2869 /* Loop here emitting swaps until the stack is correct. The
2870 worst case number of swaps emitted is N + 2, where N is the
2871 depth of the stack. In some cases, the reg at the top of
2872 stack may be correct, but swapped anyway in order to fix
2873 other regs. But since we never swap any other reg away from
2874 its correct slot, this algorithm will converge. */
2876 do
2877 {
2878 /* Swap the reg at top of stack into the position it is
2879 supposed to be in, until the correct top of stack appears. */
2882 {
2892 }
2894 /* See if any regs remain incorrect. If so, bring an
2895 incorrect reg to the top of stack, and let the while loop
2896 above fix it. */
2900 {
2904 }
2907 /* At this point there must be no differences. */
2912 }
2913 }
2914 \f
2915 /* Check PAT, which points to RTL in INSN, for a LABEL_REF. If it is
2916 found, ensure that a jump from INSN to the code_label to which the
2917 label_ref points ends up with the same stack as that at the
2918 code_label. Do this by inserting insns just before the code_label to
2919 pop and rotate the stack until it is in the correct order. REGSTACK
2920 is the order of the register stack in INSN.
2922 Any code that is emitted here must not be later processed as part
2923 of any block, as it will already contain hard register numbers. */
2925 static void
2927 rtx insn;
2928 stack regstack;
2929 rtx pat;
2930 {
2931 rtx label;
2934 stack label_stack;
2939 {
2944 {
2949 {
2955 }
2957 }
2959 }
2965 /* First, see if in fact anything needs to be done to the stack at all. */
2972 {
2973 /* If the target block hasn't had a stack order selected, then
2974 we need merely ensure that no pops are needed. */
2981 {
2982 /* change_stack will not emit any code in this case. */
2986 }
2987 }
2989 {
2996 }
2998 /* At least one insn will need to be inserted before label. Insert
2999 a jump around the code we are about to emit. Emit a label for the new
3000 code, and point the original insn at this new label. We can't use
3001 redirect_jump here, because we're using fld[4] of the code labels as
3002 LABEL_REF chains, no NUSES counters. */
3014 /* The old label_ref will no longer point to the code_label if now uses,
3015 so strip the label_ref from the code_label's chain of references. */
3032 /* Now emit the needed code. */
3037 }
3038 \f
3039 /* Traverse all basic blocks in a function, converting the register
3040 references in each insn from the "flat" register file that gcc uses, to
3041 the stack-like registers the 387 uses. */
3043 static void
3045 {
3051 {
3053 {
3054 /* This block has not been previously encountered. Choose a
3055 default mapping for any stack regs live on entry */
3062 }
3064 /* Process all insns in this block. Keep track of `next' here,
3065 so that we don't process any insns emitted while making
3066 substitutions in INSN. */
3070 do
3071 {
3075 /* Don't bother processing unless there is a stack reg
3076 mentioned or if it's a CALL_INSN (register passing of
3077 floating point values). */
3084 /* Something failed if the stack life doesn't match. */
3090 win:
3092 /* Adjust the stack of this block on exit to match the stack of
3093 the target block, or copy stack information into stack of
3094 jump target if the target block's stack order hasn't been set
3095 yet. */
3100 /* Likewise handle the case where we fall into the next block. */
3104 emit_insn_after);
3105 }
3107 /* If the last basic block is the end of a loop, and that loop has
3108 regs live at its start, then the last basic block will have regs live
3109 at its end that need to be popped before the function returns. */
3111 {
3114 {
3115 rtx retvalue;
3117 {
3121 }
3123 }
3129 emit_insn_after);
3130 }
3132 }
3133 \f
3134 /* Check expression PAT, which is in INSN, for label references. if
3135 one is found, print the block number of destination to FILE. */
3137 static void
3141 {
3147 {
3156 }
3160 {
3164 {
3168 }
3169 }
3170 }
3171 \f
3172 /* Write information about stack registers and stack blocks into FILE.
3173 This is part of making a debugging dump. */
3175 static void
3178 {
3183 {
3198 {
3201 }
3207 {
3210 }
3214 {
3217 }
3233 }
3234 }