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1 /* Register to Stack convert for GNU compiler.
2 Copyright (C) 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000,
3 2001, 2002, 2003, 2004, 2005, 2006, 2007
4 Free Software Foundation, Inc.
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it
9 under the terms of the GNU General Public License as published by
10 the Free Software Foundation; either version 3, or (at your option)
11 any later version.
13 GCC is distributed in the hope that it will be useful, but WITHOUT
14 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
15 or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
16 License for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING3. If not see
20 <http://www.gnu.org/licenses/>. */
22 /* This pass converts stack-like registers from the "flat register
23 file" model that gcc uses, to a stack convention that the 387 uses.
25 * The form of the input:
27 On input, the function consists of insn that have had their
28 registers fully allocated to a set of "virtual" registers. Note that
29 the word "virtual" is used differently here than elsewhere in gcc: for
30 each virtual stack reg, there is a hard reg, but the mapping between
31 them is not known until this pass is run. On output, hard register
32 numbers have been substituted, and various pop and exchange insns have
33 been emitted. The hard register numbers and the virtual register
34 numbers completely overlap - before this pass, all stack register
35 numbers are virtual, and afterward they are all hard.
37 The virtual registers can be manipulated normally by gcc, and their
38 semantics are the same as for normal registers. After the hard
39 register numbers are substituted, the semantics of an insn containing
40 stack-like regs are not the same as for an insn with normal regs: for
41 instance, it is not safe to delete an insn that appears to be a no-op
42 move. In general, no insn containing hard regs should be changed
43 after this pass is done.
45 * The form of the output:
47 After this pass, hard register numbers represent the distance from
48 the current top of stack to the desired register. A reference to
49 FIRST_STACK_REG references the top of stack, FIRST_STACK_REG + 1,
50 represents the register just below that, and so forth. Also, REG_DEAD
51 notes indicate whether or not a stack register should be popped.
53 A "swap" insn looks like a parallel of two patterns, where each
54 pattern is a SET: one sets A to B, the other B to A.
56 A "push" or "load" insn is a SET whose SET_DEST is FIRST_STACK_REG
57 and whose SET_DEST is REG or MEM. Any other SET_DEST, such as PLUS,
58 will replace the existing stack top, not push a new value.
60 A store insn is a SET whose SET_DEST is FIRST_STACK_REG, and whose
61 SET_SRC is REG or MEM.
63 The case where the SET_SRC and SET_DEST are both FIRST_STACK_REG
64 appears ambiguous. As a special case, the presence of a REG_DEAD note
65 for FIRST_STACK_REG differentiates between a load insn and a pop.
67 If a REG_DEAD is present, the insn represents a "pop" that discards
68 the top of the register stack. If there is no REG_DEAD note, then the
69 insn represents a "dup" or a push of the current top of stack onto the
70 stack.
72 * Methodology:
74 Existing REG_DEAD and REG_UNUSED notes for stack registers are
75 deleted and recreated from scratch. REG_DEAD is never created for a
76 SET_DEST, only REG_UNUSED.
78 * asm_operands:
80 There are several rules on the usage of stack-like regs in
81 asm_operands insns. These rules apply only to the operands that are
82 stack-like regs:
84 1. Given a set of input regs that die in an asm_operands, it is
85 necessary to know which are implicitly popped by the asm, and
86 which must be explicitly popped by gcc.
88 An input reg that is implicitly popped by the asm must be
89 explicitly clobbered, unless it is constrained to match an
90 output operand.
92 2. For any input reg that is implicitly popped by an asm, it is
93 necessary to know how to adjust the stack to compensate for the pop.
94 If any non-popped input is closer to the top of the reg-stack than
95 the implicitly popped reg, it would not be possible to know what the
96 stack looked like - it's not clear how the rest of the stack "slides
97 up".
99 All implicitly popped input regs must be closer to the top of
100 the reg-stack than any input that is not implicitly popped.
102 3. It is possible that if an input dies in an insn, reload might
103 use the input reg for an output reload. Consider this example:
105 asm ("foo" : "=t" (a) : "f" (b));
107 This asm says that input B is not popped by the asm, and that
108 the asm pushes a result onto the reg-stack, i.e., the stack is one
109 deeper after the asm than it was before. But, it is possible that
110 reload will think that it can use the same reg for both the input and
111 the output, if input B dies in this insn.
113 If any input operand uses the "f" constraint, all output reg
114 constraints must use the "&" earlyclobber.
116 The asm above would be written as
118 asm ("foo" : "=&t" (a) : "f" (b));
120 4. Some operands need to be in particular places on the stack. All
121 output operands fall in this category - there is no other way to
122 know which regs the outputs appear in unless the user indicates
123 this in the constraints.
125 Output operands must specifically indicate which reg an output
126 appears in after an asm. "=f" is not allowed: the operand
127 constraints must select a class with a single reg.
129 5. Output operands may not be "inserted" between existing stack regs.
130 Since no 387 opcode uses a read/write operand, all output operands
131 are dead before the asm_operands, and are pushed by the asm_operands.
132 It makes no sense to push anywhere but the top of the reg-stack.
134 Output operands must start at the top of the reg-stack: output
135 operands may not "skip" a reg.
137 6. Some asm statements may need extra stack space for internal
138 calculations. This can be guaranteed by clobbering stack registers
139 unrelated to the inputs and outputs.
141 Here are a couple of reasonable asms to want to write. This asm
142 takes one input, which is internally popped, and produces two outputs.
144 asm ("fsincos" : "=t" (cos), "=u" (sin) : "0" (inp));
146 This asm takes two inputs, which are popped by the fyl2xp1 opcode,
147 and replaces them with one output. The user must code the "st(1)"
148 clobber for reg-stack.c to know that fyl2xp1 pops both inputs.
150 asm ("fyl2xp1" : "=t" (result) : "0" (x), "u" (y) : "st(1)");
152 */
153 \f
180 #ifdef STACK_REGS
182 /* We use this array to cache info about insns, because otherwise we
183 spend too much time in stack_regs_mentioned_p.
185 Indexed by insn UIDs. A value of zero is uninitialized, one indicates
186 the insn uses stack registers, two indicates the insn does not use
187 stack registers. */
190 #define REG_STACK_SIZE (LAST_STACK_REG - FIRST_STACK_REG + 1)
194 /* This is the basic stack record. TOP is an index into REG[] such
195 that REG[TOP] is the top of stack. If TOP is -1 the stack is empty.
197 If TOP is -2, REG[] is not yet initialized. Stack initialization
198 consists of placing each live reg in array `reg' and setting `top'
199 appropriately.
201 REG_SET indicates which registers are live. */
204 {
210 /* This is used to carry information about basic blocks. It is
211 attached to the AUX field of the standard CFG block. */
214 {
220 to be visited. */
223 #define BLOCK_INFO(B) ((block_info) (B)->aux)
225 /* Passed to change_stack to indicate where to emit insns. */
226 enum emit_where
227 {
228 EMIT_AFTER,
229 EMIT_BEFORE
230 };
232 /* The block we're currently working on. */
235 /* In the current_block, whether we're processing the first register
236 stack or call instruction, i.e. the regstack is currently the
237 same as BLOCK_INFO(current_block)->stack_in. */
240 /* This is the register file for all register after conversion. */
241 static rtx
244 #define FP_MODE_REG(regno,mode) \
245 (FP_mode_reg[(regno)-FIRST_STACK_REG][(int) (mode)])
247 /* Used to initialize uninitialized registers. */
250 /* Forward declarations */
275 \f
276 /* Return nonzero if any stack register is mentioned somewhere within PAT. */
278 static int
280 {
289 {
291 {
297 }
300 }
303 }
305 /* Return nonzero if INSN mentions stacked registers, else return zero. */
307 int
309 {
319 {
320 /* Allocate some extra size to avoid too many reallocs, but
321 do not grow too quickly. */
324 }
328 {
329 /* This insn has yet to be examined. Do so now. */
332 }
335 }
336 \f
339 static rtx
341 {
342 /* Search forward looking for the first use of this value.
343 Stop at block boundaries. */
346 {
354 }
356 }
357 \f
358 /* Reorganize the stack into ascending numbers, before this insn. */
360 static void
362 {
366 /* If there is only a single register on the stack, then the stack is
367 already in increasing order and no reorganization is needed.
369 Similarly if the stack is empty. */
379 }
381 /* Pop a register from the stack. */
383 static void
385 {
390 /* If regno was not at the top of stack then adjust stack. */
392 {
396 {
401 }
402 }
403 }
404 \f
405 /* Return a pointer to the REG expression within PAT. If PAT is not a
406 REG, possible enclosed by a conversion rtx, return the inner part of
407 PAT that stopped the search. */
411 {
414 {
416 /* Eliminate FP subregister accesses in favor of the
417 actual FP register in use. */
418 {
419 rtx subreg;
421 {
429 }
430 }
450 }
451 }
452 \f
453 /* Set if we find any malformed asms in a block. */
456 /* There are many rules that an asm statement for stack-like regs must
457 follow. Those rules are explained at the top of this file: the rule
458 numbers below refer to that explanation. */
460 static int
462 {
475 /* Find out what the constraints require. If no constraint
476 alternative matches, this asm is malformed. */
487 {
489 /* Avoid further trouble with this insn. */
492 }
494 /* Strip SUBREGs here to make the following code simpler. */
500 /* Set up CLOBBER_REG. */
505 {
510 {
518 {
520 n_clobbers++;
521 }
522 }
523 }
525 /* Enforce rule #4: Output operands must specifically indicate which
526 reg an output appears in after an asm. "=f" is not allowed: the
527 operand constraints must select a class with a single reg.
529 Also enforce rule #5: Output operands must start at the top of
530 the reg-stack: output operands may not "skip" a reg. */
535 {
537 {
540 }
541 else
542 {
547 {
552 }
555 }
556 }
559 /* Search for first non-popped reg. */
564 /* If there are any other popped regs, that's an error. */
570 {
573 }
575 /* Enforce rule #2: All implicitly popped input regs must be closer
576 to the top of the reg-stack than any input that is not implicitly
577 popped. */
582 {
583 /* An input reg is implicitly popped if it is tied to an
584 output, or if there is a CLOBBER for it. */
593 }
595 /* Search for first non-popped reg. */
600 /* If there are any other popped regs, that's an error. */
606 {
610 }
612 /* Enforce rule #3: If any input operand uses the "f" constraint, all
613 output constraints must use the "&" earlyclobber.
615 ??? Detect this more deterministically by having constrain_asm_operands
616 record any earlyclobber. */
620 {
625 {
629 }
630 }
633 {
634 /* Avoid further trouble with this insn. */
638 }
641 }
642 \f
643 /* Calculate the number of inputs and outputs in BODY, an
644 asm_operands. N_OPERANDS is the total number of operands, and
645 N_INPUTS and N_OUTPUTS are pointers to ints into which the results are
646 placed. */
648 static int
650 {
652 {
665 }
666 }
668 /* If current function returns its result in an fp stack register,
669 return the REG. Otherwise, return 0. */
671 static rtx
673 {
674 rtx result;
676 /* If the value is supposed to be returned in memory, then clearly
677 it is not returned in a stack register. */
687 }
688 \f
690 /*
691 * This section deals with stack register substitution, and forms the second
692 * pass over the RTL.
693 */
695 /* Replace REG, which is a pointer to a stack reg RTX, with an RTX for
696 the desired hard REGNO. */
698 static void
700 {
708 }
710 /* Remove a note of type NOTE, which must be found, for register
711 number REGNO from INSN. Remove only one such note. */
713 static void
715 {
722 {
725 }
726 else
730 }
732 /* Find the hard register number of virtual register REG in REGSTACK.
733 The hard register number is relative to the top of the stack. -1 is
734 returned if the register is not found. */
736 static int
738 {
748 }
749 \f
750 /* Emit an insn to pop virtual register REG before or after INSN.
751 REGSTACK is the stack state after INSN and is updated to reflect this
752 pop. WHEN is either emit_insn_before or emit_insn_after. A pop insn
753 is represented as a SET whose destination is the register to be popped
754 and source is the top of stack. A death note for the top of stack
755 cases the movdf pattern to pop. */
757 static rtx
759 {
763 /* For complex types take care to pop both halves. These may survive in
764 CLOBBER and USE expressions. */
766 {
777 }
788 else
801 }
802 \f
803 /* Emit an insn before or after INSN to swap virtual register REG with
804 the top of stack. REGSTACK is the stack state before the swap, and
805 is updated to reflect the swap. A swap insn is represented as a
806 PARALLEL of two patterns: each pattern moves one reg to the other.
808 If REG is already at the top of the stack, no insn is emitted. */
810 static void
812 {
814 rtx swap_rtx;
824 {
825 /* Something failed if the register wasn't on the stack. If we had
826 malformed asms, we zapped the instruction itself, but that didn't
827 produce the same pattern of register sets as before. To prevent
828 further failure, adjust REGSTACK to include REG at TOP. */
832 }
841 /* Find the previous insn involving stack regs, but don't pass a
842 block boundary. */
845 {
849 {
855 {
858 }
860 }
861 }
865 {
869 /* If the previous register stack push was from the reg we are to
870 swap with, omit the swap. */
878 /* If the previous insn wrote to the reg we are to swap with,
879 omit the swap. */
885 }
887 /* Avoid emitting the swap if this is the first register stack insn
888 of the current_block. Instead update the current_block's stack_in
889 and let compensate edges take care of this for us. */
891 {
895 }
904 else
906 }
907 \f
908 /* Emit an insns before INSN to swap virtual register SRC1 with
909 the top of stack and virtual register SRC2 with second stack
910 slot. REGSTACK is the stack state before the swaps, and
911 is updated to reflect the swaps. A swap insn is represented as a
912 PARALLEL of two patterns: each pattern moves one reg to the other.
914 If SRC1 and/or SRC2 are already at the right place, no swap insn
915 is emitted. */
917 static void
919 {
925 /* Place operand 1 at the top of stack. */
929 {
936 }
938 /* Place operand 2 next on the stack. */
942 {
949 }
952 }
953 \f
954 /* Handle a move to or from a stack register in PAT, which is in INSN.
955 REGSTACK is the current stack. Return whether a control flow insn
956 was deleted in the process. */
958 static bool
960 {
964 rtx note;
970 {
971 /* Write from one stack reg to another. If SRC dies here, then
972 just change the register mapping and delete the insn. */
976 {
979 /* If this is a no-op move, there must not be a REG_DEAD note. */
986 /* The destination must be dead, or life analysis is borked. */
989 /* If the source is not live, this is yet another case of
990 uninitialized variables. Load up a NaN instead. */
994 /* It is possible that the dest is unused after this insn.
995 If so, just pop the src. */
999 else
1000 {
1004 }
1009 }
1011 /* The source reg does not die. */
1013 /* If this appears to be a no-op move, delete it, or else it
1014 will confuse the machine description output patterns. But if
1015 it is REG_UNUSED, we must pop the reg now, as per-insn processing
1016 for REG_UNUSED will not work for deleted insns. */
1019 {
1026 }
1028 /* The destination ought to be dead. */
1036 }
1038 {
1039 /* Save from a stack reg to MEM, or possibly integer reg. Since
1040 only top of stack may be saved, emit an exchange first if
1041 needs be. */
1047 {
1051 }
1054 {
1055 /* A 387 cannot write an XFmode value to a MEM without
1056 clobbering the source reg. The output code can handle
1057 this by reading back the value from the MEM.
1058 But it is more efficient to use a temp register if one is
1059 available. Push the source value here if the register
1060 stack is not full, and then write the value to memory via
1061 a pop. */
1062 rtx push_rtx;
1069 }
1072 }
1073 else
1074 {
1079 /* Load from MEM, or possibly integer REG or constant, into the
1080 stack regs. The actual target is always the top of the
1081 stack. The stack mapping is changed to reflect that DEST is
1082 now at top of stack. */
1084 /* The destination ought to be dead. However, there is a
1085 special case with i387 UNSPEC_TAN, where destination is live
1086 (an argument to fptan) but inherent load of 1.0 is modelled
1087 as a load from a constant. */
1094 else
1102 }
1105 }
1107 /* A helper function which replaces INSN with a pattern that loads up
1108 a NaN into DEST, then invokes move_for_stack_reg. */
1110 static bool
1112 {
1113 rtx pat;
1121 }
1122 \f
1123 /* Swap the condition on a branch, if there is one. Return true if we
1124 found a condition to swap. False if the condition was not used as
1125 such. */
1127 static int
1129 {
1134 {
1137 }
1138 else
1139 {
1142 {
1144 {
1149 }
1152 }
1153 }
1156 }
1158 static int
1160 {
1163 /* We're looking for a single set to cc0 or an HImode temporary. */
1168 {
1173 }
1175 /* See if this is, or ends in, a fnstsw. If so, we're not doing anything
1176 with the cc value right now. We may be able to search for one
1177 though. */
1182 {
1185 /* Search forward looking for the first use of this value.
1186 Stop at block boundaries. */
1188 {
1194 }
1196 /* We haven't found it. */
1200 /* So we've found the insn using this value. If it is anything
1201 other than sahf or the value does not die (meaning we'd have
1202 to search further), then we must give up. */
1210 /* Now we are prepared to handle this as a normal cc0 setter. */
1215 }
1218 {
1223 /* In case the flags don't die here, recurse to try fix
1224 following user too. */
1226 {
1230 }
1232 {
1235 }
1237 }
1239 }
1241 /* Handle a comparison. Special care needs to be taken to avoid
1242 causing comparisons that a 387 cannot do correctly, such as EQ.
1244 Also, a pop insn may need to be emitted. The 387 does have an
1245 `fcompp' insn that can pop two regs, but it is sometimes too expensive
1246 to do this - a `fcomp' followed by a `fstpl %st(0)' may be easier to
1247 set up. */
1249 static void
1251 {
1258 /* ??? If fxch turns out to be cheaper than fstp, give priority to
1259 registers that die in this insn - move those to stack top first. */
1264 {
1265 rtx temp;
1274 }
1276 /* We will fix any death note later. */
1282 else
1293 {
1296 }
1298 /* If the second operand dies, handle that. But if the operands are
1299 the same stack register, don't bother, because only one death is
1300 needed, and it was just handled. */
1305 {
1306 /* As a special case, two regs may die in this insn if src2 is
1307 next to top of stack and the top of stack also dies. Since
1308 we have already popped src1, "next to top of stack" is really
1309 at top (FIRST_STACK_REG) now. */
1313 {
1316 }
1317 else
1318 {
1319 /* The 386 can only represent death of the first operand in
1320 the case handled above. In all other cases, emit a separate
1321 pop and remove the death note from here. */
1323 /* link_cc0_insns (insn); */
1328 EMIT_AFTER);
1329 }
1330 }
1331 }
1332 \f
1333 /* Substitute new registers in PAT, which is part of INSN. REGSTACK
1334 is the current register layout. Return whether a control flow insn
1335 was deleted in the process. */
1337 static bool
1339 {
1344 {
1346 /* Deaths in USE insns can happen in non optimizing compilation.
1347 Handle them by popping the dying register. */
1351 {
1352 /* USEs are ignored for liveness information so USEs of dead
1353 register might happen. */
1357 }
1358 /* Uninitialized USE might happen for functions returning uninitialized
1359 value. We will properly initialize the USE on the edge to EXIT_BLOCK,
1360 so it is safe to ignore the use here. This is consistent with behavior
1361 of dataflow analyzer that ignores USE too. (This also imply that
1362 forcibly initializing the register to NaN here would lead to ICE later,
1363 since the REG_DEAD notes are not issued.) */
1367 {
1368 rtx note;
1372 {
1376 {
1377 /* The fix_truncdi_1 pattern wants to be able to allocate
1378 its own scratch register. It does this by clobbering
1379 an fp reg so that it is assured of an empty reg-stack
1380 register. If the register is live, kill it now.
1381 Remove the DEAD/UNUSED note so we don't try to kill it
1382 later too. */
1386 else
1387 {
1390 }
1393 }
1394 else
1395 {
1396 /* A top-level clobber with no REG_DEAD, and no hard-regnum
1397 indicates an uninitialized value. Because reload removed
1398 all other clobbers, this must be due to a function
1399 returning without a value. Load up a NaN. */
1402 {
1405 {
1408 {
1411 control_flow_insn_deleted
1413 }
1414 }
1416 control_flow_insn_deleted
1418 }
1419 }
1420 }
1422 }
1425 {
1428 rtx pat_src;
1434 /* See if this is a `movM' pattern, and handle elsewhere if so. */
1439 {
1442 }
1445 {
1451 {
1455 {
1458 }
1459 }
1464 /* This is a `tstM2' case. */
1468 /* Fall through. */
1474 /* These insns only operate on the top of the stack. DEST might
1475 be cc0_rtx if we're processing a tstM pattern. Also, it's
1476 possible that the tstM case results in a REG_DEAD note on the
1477 source. */
1490 {
1494 }
1501 /* On i386, reversed forms of subM3 and divM3 exist for
1502 MODE_FLOAT, so the same code that works for addM3 and mulM3
1503 can be used. */
1506 /* These insns can accept the top of stack as a destination
1507 from a stack reg or mem, or can use the top of stack as a
1508 source and some other stack register (possibly top of stack)
1509 as a destination. */
1514 /* We will fix any death note later. */
1518 else
1522 else
1525 /* If either operand is not a stack register, then the dest
1526 must be top of stack. */
1530 else
1531 {
1532 /* Both operands are REG. If neither operand is already
1533 at the top of stack, choose to make the one that is the dest
1534 the new top of stack. */
1546 }
1554 {
1557 /* If the register that dies is at the top of stack, then
1558 the destination is somewhere else - merely substitute it.
1559 But if the reg that dies is not at top of stack, then
1560 move the top of stack to the dead reg, as though we had
1561 done the insn and then a store-with-pop. */
1564 {
1567 }
1568 else
1569 {
1577 }
1583 }
1585 {
1588 {
1591 }
1592 else
1593 {
1601 }
1607 }
1608 else
1609 {
1612 }
1614 /* Keep operand 1 matching with destination. */
1618 {
1622 }
1627 {
1633 /* These insns only operate on the top of the stack. */
1644 {
1648 }
1655 /* This insn only operate on the top of the stack. */
1665 {
1669 EMIT_AFTER);
1670 }
1684 /* Above insns operate on the top of the stack. */
1689 /* Above insns operate on the top two stack slots,
1690 first part of one input, double output insn. */
1696 /* Input should never die, it is replaced with output. */
1709 /* These insns operate on the top two stack slots,
1710 second part of one input, double output insn. */
1713 /* FALLTHRU */
1717 /* For UNSPEC_TAN, regstack->top is already increased
1718 by inherent load of constant 1.0. */
1720 /* Output value is generated in the second stack slot.
1721 Move current value from second slot to the top. */
1739 /* These insns operate on the top two stack slots. */
1757 /* Pop both input operands from the stack. */
1764 /* Push the result back onto the stack. */
1773 /* These insns operate on the top two stack slots,
1774 first part of double input, double output insn. */
1782 /* Inputs should never die, they are
1783 replaced with outputs. */
1789 /* Push the result back onto stack. Empty stack slot
1790 will be filled in second part of insn. */
1792 {
1796 }
1805 /* These insns operate on the top two stack slots,
1806 second part of double input, double output insn. */
1811 /* Push the result back onto stack. Fill empty slot from
1812 first part of insn and fix top of stack pointer. */
1814 {
1818 }
1825 /* This insn operates on the top two stack slots,
1826 third part of C2 setting double input insn. */
1836 /* (unspec [(unspec [(compare)] UNSPEC_FNSTSW)] UNSPEC_SAHF)
1837 The combination matches the PPRO fcomi instruction. */
1842 /* Fall through. */
1845 /* Combined fcomp+fnstsw generated for doing well with
1846 CSE. When optimizing this would have been broken
1847 up before now. */
1857 }
1861 /* This insn requires the top of stack to be the destination. */
1869 /* If the comparison operator is an FP comparison operator,
1870 it is handled correctly by compare_for_stack_reg () who
1871 will move the destination to the top of stack. But if the
1872 comparison operator is not an FP comparison operator, we
1873 have to handle it here. */
1876 {
1877 /* In case one of operands is the top of stack and the operands
1878 dies, it is safe to make it the destination operand by
1879 reversing the direction of cmove and avoid fxch. */
1884 {
1890 /* Make reg-stack believe that the operands are already
1891 swapped on the stack */
1895 /* Reverse condition to compensate the operand swap.
1896 i386 do have comparison always reversible. */
1899 }
1900 else
1902 }
1904 {
1919 {
1922 /* If the register that dies is not at the top of
1923 stack, then move the top of stack to the dead reg.
1924 Top of stack should never die, as it is the
1925 destination. */
1929 EMIT_AFTER);
1930 }
1931 }
1933 /* Make dest the top of stack. Add dest to regstack if
1934 not present. */
1943 }
1945 }
1949 }
1952 }
1953 \f
1954 /* Substitute hard regnums for any stack regs in INSN, which has
1955 N_INPUTS inputs and N_OUTPUTS outputs. REGSTACK is the stack info
1956 before the insn, and is updated with changes made here.
1958 There are several requirements and assumptions about the use of
1959 stack-like regs in asm statements. These rules are enforced by
1960 record_asm_stack_regs; see comments there for details. Any
1961 asm_operands left in the RTL at this point may be assume to meet the
1962 requirements, since record_asm_stack_regs removes any problem asm. */
1964 static void
1966 {
1980 rtx note;
1987 /* Find out what the constraints required. If no constraint
1988 alternative matches, that is a compiler bug: we should have caught
1989 such an insn in check_asm_stack_operands. */
2001 /* Strip SUBREGs here to make the following code simpler. */
2005 {
2008 }
2010 /* Set up NOTE_REG, NOTE_LOC and NOTE_KIND. */
2013 i++;
2021 {
2026 {
2029 }
2034 {
2038 n_notes++;
2039 }
2040 }
2042 /* Set up CLOBBER_REG and CLOBBER_LOC. */
2047 {
2053 {
2059 {
2062 }
2065 {
2068 n_clobbers++;
2069 }
2070 }
2071 }
2075 /* Put the input regs into the desired place in TEMP_STACK. */
2080 FLOAT_REGS)
2082 {
2083 /* If an operand needs to be in a particular reg in
2084 FLOAT_REGS, the constraint was either 't' or 'u'. Since
2085 these constraints are for single register classes, and
2086 reload guaranteed that operand[i] is already in that class,
2087 we can just use REGNO (recog_data.operand[i]) to know which
2088 actual reg this operand needs to be in. */
2095 {
2096 /* recog_data.operand[i] is not in the right place. Find
2097 it and swap it with whatever is already in I's place.
2098 K is where recog_data.operand[i] is now. J is where it
2099 should be. */
2109 }
2110 }
2112 /* Emit insns before INSN to make sure the reg-stack is in the right
2113 order. */
2117 /* Make the needed input register substitutions. Do death notes and
2118 clobbers too, because these are for inputs, not outputs. */
2122 {
2128 }
2132 {
2138 }
2141 {
2142 /* It's OK for a CLOBBER to reference a reg that is not live.
2143 Don't try to replace it in that case. */
2147 {
2148 /* Sigh - clobbers always have QImode. But replace_reg knows
2149 that these regs can't be MODE_INT and will assert. Just put
2150 the right reg there without calling replace_reg. */
2153 }
2154 }
2156 /* Now remove from REGSTACK any inputs that the asm implicitly popped. */
2160 {
2161 /* An input reg is implicitly popped if it is tied to an
2162 output, or if there is a CLOBBER for it. */
2170 {
2171 /* recog_data.operand[i] might not be at the top of stack.
2172 But that's OK, because all we need to do is pop the
2173 right number of regs off of the top of the reg-stack.
2174 record_asm_stack_regs guaranteed that all implicitly
2175 popped regs were grouped at the top of the reg-stack. */
2180 }
2181 }
2183 /* Now add to REGSTACK any outputs that the asm implicitly pushed.
2184 Note that there isn't any need to substitute register numbers.
2185 ??? Explain why this is true. */
2188 {
2189 /* See if there is an output for this hard reg. */
2195 {
2199 }
2200 }
2202 /* Now emit a pop insn for any REG_UNUSED output, or any REG_DEAD
2203 input that the asm didn't implicitly pop. If the asm didn't
2204 implicitly pop an input reg, that reg will still be live.
2206 Note that we can't use find_regno_note here: the register numbers
2207 in the death notes have already been substituted. */
2211 {
2217 {
2219 EMIT_AFTER);
2221 }
2222 }
2226 {
2234 {
2236 EMIT_AFTER);
2238 }
2239 }
2240 }
2241 \f
2242 /* Substitute stack hard reg numbers for stack virtual registers in
2243 INSN. Non-stack register numbers are not changed. REGSTACK is the
2244 current stack content. Insns may be emitted as needed to arrange the
2245 stack for the 387 based on the contents of the insn. Return whether
2246 a control flow insn was deleted in the process. */
2248 static bool
2250 {
2256 {
2259 /* If there are any floating point parameters to be passed in
2260 registers for this call, make sure they are in the right
2261 order. */
2264 {
2267 /* Now mark the arguments as dead after the call. */
2270 {
2273 }
2274 }
2275 }
2277 /* Do the actual substitution if any stack regs are mentioned.
2278 Since we only record whether entire insn mentions stack regs, and
2279 subst_stack_regs_pat only works for patterns that contain stack regs,
2280 we must check each pattern in a parallel here. A call_value_pop could
2281 fail otherwise. */
2284 {
2287 {
2288 /* This insn is an `asm' with operands. Decode the operands,
2289 decide how many are inputs, and do register substitution.
2290 Any REG_UNUSED notes will be handled by subst_asm_stack_regs. */
2294 }
2298 {
2300 {
2304 control_flow_insn_deleted
2307 }
2308 }
2309 else
2310 control_flow_insn_deleted
2312 }
2314 /* subst_stack_regs_pat may have deleted a no-op insn. If so, any
2315 REG_UNUSED will already have been dealt with, so just return. */
2320 /* If this a noreturn call, we can't insert pop insns after it.
2321 Instead, reset the stack state to empty. */
2324 {
2328 }
2330 /* If there is a REG_UNUSED note on a stack register on this insn,
2331 the indicated reg must be popped. The REG_UNUSED note is removed,
2332 since the form of the newly emitted pop insn references the reg,
2333 making it no longer `unset'. */
2338 {
2341 }
2342 else
2346 }
2347 \f
2348 /* Change the organization of the stack so that it fits a new basic
2349 block. Some registers might have to be popped, but there can never be
2350 a register live in the new block that is not now live.
2352 Insert any needed insns before or after INSN, as indicated by
2353 WHERE. OLD is the original stack layout, and NEW is the desired
2354 form. OLD is updated to reflect the code emitted, i.e., it will be
2355 the same as NEW upon return.
2357 This function will not preserve block_end[]. But that information
2358 is no longer needed once this has executed. */
2360 static void
2362 {
2367 /* Stack adjustments for the first insn in a block update the
2368 current_block's stack_in instead of inserting insns directly.
2369 compensate_edges will add the necessary code later. */
2371 && starting_stack_p
2373 {
2378 }
2380 /* We will be inserting new insns "backwards". If we are to insert
2381 after INSN, find the next insn, and insert before it. */
2384 {
2388 }
2390 /* Initialize partially dead variables. */
2394 {
2399 }
2401 /* Pop any registers that are not needed in the new block. */
2403 /* If the destination block's stack already has a specified layout
2404 and contains two or more registers, use a more intelligent algorithm
2405 to pop registers that minimizes the number number of fxchs below. */
2407 {
2412 /* First pass to determine the free slots. */
2416 /* Second pass to allocate preferred slots. */
2420 {
2424 {
2425 /* If this is a preference for the new top of stack, record
2426 the fact by remembering it's old->reg in topsrc. */
2432 }
2434 }
2435 else
2438 /* Intentionally, avoid placing the top of stack in it's correct
2439 location, if we still need to permute the stack below and we
2440 can usefully place it somewhere else. This is the case if any
2441 slot is still unallocated, in which case we should place the
2442 top of stack there. */
2446 {
2451 }
2453 /* Third pass allocates remaining slots and emits pop insns. */
2456 {
2459 {
2460 /* Find next free slot. */
2462 next--;
2464 }
2466 EMIT_BEFORE);
2467 }
2468 }
2469 else
2470 {
2471 /* The following loop attempts to maximize the number of times we
2472 pop the top of the stack, as this permits the use of the faster
2473 ffreep instruction on platforms that support it. */
2479 live++;
2484 {
2486 next--;
2488 EMIT_BEFORE);
2489 }
2490 else
2492 EMIT_BEFORE);
2493 }
2496 {
2497 /* If the new block has never been processed, then it can inherit
2498 the old stack order. */
2502 }
2503 else
2504 {
2505 /* This block has been entered before, and we must match the
2506 previously selected stack order. */
2508 /* By now, the only difference should be the order of the stack,
2509 not their depth or liveliness. */
2514 /* If the stack is not empty (new->top != -1), loop here emitting
2515 swaps until the stack is correct.
2517 The worst case number of swaps emitted is N + 2, where N is the
2518 depth of the stack. In some cases, the reg at the top of
2519 stack may be correct, but swapped anyway in order to fix
2520 other regs. But since we never swap any other reg away from
2521 its correct slot, this algorithm will converge. */
2524 do
2525 {
2526 /* Swap the reg at top of stack into the position it is
2527 supposed to be in, until the correct top of stack appears. */
2530 {
2539 }
2541 /* See if any regs remain incorrect. If so, bring an
2542 incorrect reg to the top of stack, and let the while loop
2543 above fix it. */
2547 {
2551 }
2554 /* At this point there must be no differences. */
2558 }
2562 }
2563 \f
2564 /* Print stack configuration. */
2566 static void
2568 {
2576 else
2577 {
2583 }
2584 }
2585 \f
2586 /* This function was doing life analysis. We now let the regular live
2587 code do it's job, so we only need to check some extra invariants
2588 that reg-stack expects. Primary among these being that all registers
2589 are initialized before use.
2591 The function returns true when code was emitted to CFG edges and
2592 commit_edge_insertions needs to be called. */
2594 static int
2596 {
2598 edge e;
2599 edge_iterator ei;
2601 /* Load something into each stack register live at function entry.
2602 Such live registers can be caused by uninitialized variables or
2603 functions not returning values on all paths. In order to keep
2604 the push/pop code happy, and to not scrog the register stack, we
2605 must put something in these registers. Use a QNaN.
2607 Note that we are inserting converted code here. This code is
2608 never seen by the convert_regs pass. */
2611 {
2618 {
2619 rtx init;
2625 not_a_num);
2628 }
2631 }
2634 }
2636 /* Construct the desired stack for function exit. This will either
2637 be `empty', or the function return value at top-of-stack. */
2639 static void
2641 {
2643 stack output_stack;
2644 rtx retvalue;
2649 {
2652 }
2657 else
2658 {
2663 {
2666 }
2667 }
2668 }
2670 /* Copy the stack info from the end of edge E's source block to the
2671 start of E's destination block. */
2673 static void
2675 {
2680 /* Preserve the order of the original stack, but check whether
2681 any pops are needed. */
2687 /* Push in any partially dead values. */
2692 }
2695 /* Adjust the stack of edge E's source block on exit to match the stack
2696 of it's target block upon input. The stack layouts of both blocks
2697 should have been defined by now. */
2699 static bool
2701 {
2713 /* Check whether stacks are identical. */
2715 {
2721 {
2725 }
2726 }
2729 {
2732 }
2734 /* Abnormal calls may appear to have values live in st(0), but the
2735 abnormal return path will not have actually loaded the values. */
2737 {
2738 /* Assert that the lifetimes are as we expect -- one value
2739 live at st(0) on the end of the source block, and no
2740 values live at the beginning of the destination block.
2741 For complex return values, we may have st(1) live as well. */
2745 }
2747 /* Handle non-call EH edges specially. The normal return path have
2748 values in registers. These will be popped en masse by the unwind
2749 library. */
2751 {
2754 }
2756 /* We don't support abnormal edges. Global takes care to
2757 avoid any live register across them, so we should never
2758 have to insert instructions on such edges. */
2761 /* Make a copy of source_stack as change_stack is destructive. */
2764 /* It is better to output directly to the end of the block
2765 instead of to the edge, because emit_swap can do minimal
2766 insn scheduling. We can do this when there is only one
2767 edge out, and it is not abnormal. */
2769 {
2773 }
2774 else
2775 {
2781 /* ??? change_stack needs some point to emit insns after. */
2791 }
2793 }
2795 /* Traverse all non-entry edges in the CFG, and emit the necessary
2796 edge compensation code to change the stack from stack_out of the
2797 source block to the stack_in of the destination block. */
2799 static bool
2801 {
2803 basic_block bb;
2809 {
2810 edge e;
2811 edge_iterator ei;
2815 }
2817 }
2819 /* Select the better of two edges E1 and E2 to use to determine the
2820 stack layout for their shared destination basic block. This is
2821 typically the more frequently executed. The edge E1 may be NULL
2822 (in which case E2 is returned), but E2 is always non-NULL. */
2824 static edge
2826 {
2840 /* Prefer critical edges to minimize inserting compensation code on
2841 critical edges. */
2846 /* Avoid non-deterministic behavior. */
2848 }
2850 /* Convert stack register references in one block. */
2852 static void
2854 {
2863 /* Choose an initial stack layout, if one hasn't already been chosen. */
2865 {
2867 edge_iterator ei;
2869 /* Select the best incoming edge (typically the most frequent) to
2870 use as a template for this basic block. */
2877 else
2878 {
2879 /* No predecessors. Create an arbitrary input stack. */
2884 }
2885 }
2888 {
2891 }
2893 /* Process all insns in this block. Keep track of NEXT so that we
2894 don't process insns emitted while substituting in INSN. */
2900 do
2901 {
2905 /* Ensure we have not missed a block boundary. */
2910 /* Don't bother processing unless there is a stack reg
2911 mentioned or if it's a CALL_INSN. */
2914 {
2916 {
2920 }
2923 }
2924 }
2928 {
2935 }
2941 /* If the function is declared to return a value, but it returns one
2942 in only some cases, some registers might come live here. Emit
2943 necessary moves for them. */
2946 {
2949 {
2950 rtx set;
2958 }
2959 }
2961 /* Amongst the insns possibly deleted during the substitution process above,
2962 might have been the only trapping insn in the block. We purge the now
2963 possibly dead EH edges here to avoid an ICE from fixup_abnormal_edges,
2964 called at the end of convert_regs. The order in which we process the
2965 blocks ensures that we never delete an already processed edge.
2967 Note that, at this point, the CFG may have been damaged by the emission
2968 of instructions after an abnormal call, which moves the basic block end
2969 (and is the reason why we call fixup_abnormal_edges later). So we must
2970 be sure that the trapping insn has been deleted before trying to purge
2971 dead edges, otherwise we risk purging valid edges.
2973 ??? We are normally supposed not to delete trapping insns, so we pretend
2974 that the insns deleted above don't actually trap. It would have been
2975 better to detect this earlier and avoid creating the EH edge in the first
2976 place, still, but we don't have enough information at that time. */
2981 /* Something failed if the stack lives don't match. If we had malformed
2982 asms, we zapped the instruction itself, but that didn't produce the
2983 same pattern of register kills as before. */
2989 }
2991 /* Convert registers in all blocks reachable from BLOCK. */
2993 static void
2995 {
2998 /* We process the blocks in a top-down manner, in a way such that one block
2999 is only processed after all its predecessors. The number of predecessors
3000 of every block has already been computed. */
3007 do
3008 {
3009 edge e;
3010 edge_iterator ei;
3014 /* Processing BLOCK is achieved by convert_regs_1, which may purge
3015 some dead EH outgoing edge after the deletion of the trapping
3016 insn inside the block. Since the number of predecessors of
3017 BLOCK's successors was computed based on the initial edge set,
3018 we check the necessity to process some of these successors
3019 before such an edge deletion may happen. However, there is
3020 a pitfall: if BLOCK is the only predecessor of a successor and
3021 the edge between them happens to be deleted, the successor
3022 becomes unreachable and should not be processed. The problem
3023 is that there is no way to preventively detect this case so we
3024 stack the successor in all cases and hand over the task of
3025 fixing up the discrepancy to convert_regs_1. */
3029 {
3033 }
3036 }
3040 }
3042 /* Traverse all basic blocks in a function, converting the register
3043 references in each insn from the "flat" register file that gcc uses,
3044 to the stack-like registers the 387 uses. */
3046 static void
3048 {
3050 basic_block b;
3051 edge e;
3052 edge_iterator ei;
3054 /* Initialize uninitialized registers on function entry. */
3057 /* Construct the desired stack for function exit. */
3061 /* ??? Future: process inner loops first, and give them arbitrary
3062 initial stacks which emit_swap_insn can modify. This ought to
3063 prevent double fxch that often appears at the head of a loop. */
3065 /* Process all blocks reachable from all entry points. */
3069 /* ??? Process all unreachable blocks. Though there's no excuse
3070 for keeping these even when not optimizing. */
3072 {
3077 }
3089 }
3090 \f
3091 /* Convert register usage from "flat" register file usage to a "stack
3092 register file. FILE is the dump file, if used.
3094 Construct a CFG and run life analysis. Then convert each insn one
3095 by one. Run a last cleanup_cfg pass, if optimizing, to eliminate
3096 code duplication created when the converter inserts pop insns on
3097 the edges. */
3099 static bool
3101 {
3102 basic_block bb;
3106 /* Clean up previous run. */
3110 /* See if there is something to do. Flow analysis is quite
3111 expensive so we might save some compilation time. */
3123 /* Set up block info for each basic block. */
3126 {
3128 edge_iterator ei;
3129 edge e;
3137 /* Set current register status at last instruction `uninitialized'. */
3140 /* Copy live_at_end and live_at_start into temporaries. */
3142 {
3147 }
3148 }
3150 /* Create the replacement registers up front. */
3152 {
3162 }
3166 /* A QNaN for initializing uninitialized variables.
3168 ??? We can't load from constant memory in PIC mode, because
3169 we're inserting these instructions before the prologue and
3170 the PIC register hasn't been set up. In that case, fall back
3171 on zero, which we can get from `ldz'. */
3176 else
3177 {
3180 }
3182 /* Allocate a cache for stack_regs_mentioned. */
3192 }
3194 \f
3195 static bool
3197 {
3198 #ifdef STACK_REGS
3200 #else
3202 #endif
3203 }
3206 {
3220 };
3222 /* Convert register usage from flat register file usage to a stack
3223 register file. */
3224 static unsigned int
3226 {
3227 #ifdef STACK_REGS
3230 #endif
3232 }
3235 {
3248 TODO_dump_func |
3251 };