| blob | 77f0c07bbba6a6237c1df411a7623c1e18c1fab2 |
1 /* Subroutines for manipulating rtx's in semantically interesting ways.
2 Copyright (C) 1987-2020 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it under
7 the terms of the GNU General Public License as published by the Free
8 Software Foundation; either version 3, or (at your option) any later
9 version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
12 WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 for more details.
16 You should have received a copy of the GNU General Public License
17 along with GCC; see the file COPYING3. If not see
18 <http://www.gnu.org/licenses/>. */
49 /* Truncate and perhaps sign-extend C as appropriate for MODE. */
51 HOST_WIDE_INT
53 {
54 /* Not scalar_int_mode because we also allow pointer bound modes. */
58 /* You want to truncate to a _what_? */
61 /* Canonicalize BImode to 0 and STORE_FLAG_VALUE. */
65 /* Sign-extend for the requested mode. */
68 {
74 }
77 }
79 /* Likewise for polynomial values, using the sign-extended representation
80 for each individual coefficient. */
82 poly_int64
84 {
88 }
90 /* Return an rtx for the sum of X and the integer C, given that X has
91 mode MODE. INPLACE is true if X can be modified inplace or false
92 if it must be treated as immutable. */
94 rtx
96 {
97 RTX_CODE code;
98 rtx y;
99 rtx tem;
107 restart:
113 {
114 CASE_CONST_SCALAR_INT:
117 /* If this is a reference to the constant pool, try replacing it with
118 a reference to a new constant. If the resulting address isn't
119 valid, don't return it because we have no way to validize it. */
122 {
127 {
130 }
132 {
135 /* Targets may disallow some constants in the constant pool, thus
136 force_const_mem may return NULL_RTX. */
139 }
140 }
144 /* If adding to something entirely constant, set a flag
145 so that we can add a CONST around the result. */
158 /* The interesting case is adding the integer to a sum. Look
159 for constant term in the sum and combine with C. For an
160 integer constant term or a constant term that is not an
161 explicit integer, we combine or group them together anyway.
163 We may not immediately return from the recursive call here, lest
164 all_constant gets lost. */
167 {
173 else
176 }
178 {
180 {
181 /* We need to be careful since X may be shared and we can't
182 modify it in place. */
185 }
188 }
195 }
204 else
206 }
207 \f
208 /* If X is a sum, return a new sum like X but lacking any constant terms.
209 Add all the removed constant terms into *CONSTPTR.
210 X itself is not altered. The result != X if and only if
211 it is not isomorphic to X. */
213 rtx
215 {
217 rtx tem;
222 /* First handle constants appearing at this level explicitly. */
227 {
230 }
239 {
242 }
245 }
247 \f
248 /* Return a copy of X in which all memory references
249 and all constants that involve symbol refs
250 have been replaced with new temporary registers.
251 Also emit code to load the memory locations and constants
252 into those registers.
254 If X contains no such constants or memory references,
255 X itself (not a copy) is returned.
257 If a constant is found in the address that is not a legitimate constant
258 in an insn, it is left alone in the hope that it might be valid in the
259 address.
261 X may contain no arithmetic except addition, subtraction and multiplication.
262 Values returned by expand_expr with 1 for sum_ok fit this constraint. */
264 static rtx
266 {
273 {
279 }
282 }
284 /* Given X, a memory address in address space AS' pointer mode, convert it to
285 an address in the address space's address mode, or vice versa (TO_MODE says
286 which way). We take advantage of the fact that pointers are not allowed to
287 overflow by commuting arithmetic operations over conversions so that address
288 arithmetic insns can be used. IN_CONST is true if this conversion is inside
289 a CONST. NO_EMIT is true if no insns should be emitted, and instead
290 it should return NULL if it can't be simplified without emitting insns. */
292 rtx
297 {
298 #ifndef POINTERS_EXTEND_UNSIGNED
303 rtx temp;
306 /* If X already has the right mode, just return it. */
314 /* Here we handle some special cases. If none of them apply, fall through
315 to the default case. */
317 {
318 CASE_CONST_SCALAR_INT:
325 else
355 /* For addition we can safely permute the conversion and addition
356 operation if one operand is a constant and converting the constant
357 does not change it or if one operand is a constant and we are
358 using a ptr_extend instruction (POINTERS_EXTEND_UNSIGNED < 0).
359 We can always safely permute them if we are making the address
360 narrower. Inside a CONST RTL, this is safe for both pointers
361 zero or sign extended as pointers cannot wrap. */
368 no_emit)
370 {
376 }
381 }
389 }
391 /* Given X, a memory address in address space AS' pointer mode, convert it to
392 an address in the address space's address mode, or vice versa (TO_MODE says
393 which way). We take advantage of the fact that pointers are not allowed to
394 overflow by commuting arithmetic operations over conversions so that address
395 arithmetic insns can be used. */
397 rtx
399 addr_space_t as)
400 {
402 }
403 \f
405 /* Return something equivalent to X but valid as a memory address for something
406 of mode MODE in the named address space AS. When X is not itself valid,
407 this works by copying X or subexpressions of it into registers. */
409 rtx
411 {
417 /* By passing constant addresses through registers
418 we get a chance to cse them. */
422 /* We get better cse by rejecting indirect addressing at this stage.
423 Let the combiner create indirect addresses where appropriate.
424 For now, generate the code so that the subexpressions useful to share
425 are visible. But not if cse won't be done! */
426 else
427 {
431 /* At this point, any valid address is accepted. */
435 /* If it was valid before but breaking out memory refs invalidated it,
436 use it the old way. */
438 {
441 }
443 /* Perform machine-dependent transformations on X
444 in certain cases. This is not necessary since the code
445 below can handle all possible cases, but machine-dependent
446 transformations can make better code. */
447 {
452 }
454 /* PLUS and MULT can appear in special ways
455 as the result of attempts to make an address usable for indexing.
456 Usually they are dealt with by calling force_operand, below.
457 But a sum containing constant terms is special
458 if removing them makes the sum a valid address:
459 then we generate that address in a register
460 and index off of it. We do this because it often makes
461 shorter code, and because the addresses thus generated
462 in registers often become common subexpressions. */
464 {
470 else
471 {
475 else
477 }
478 }
483 /* If we have a register that's an invalid address,
484 it must be a hard reg of the wrong class. Copy it to a pseudo. */
488 /* Last resort: copy the value to a register, since
489 the register is a valid address. */
490 else
492 }
494 done:
497 /* If we didn't change the address, we are done. Otherwise, mark
498 a reg as a pointer if we have REG or REG + CONST_INT. */
508 /* OLDX may have been the address on a temporary. Update the address
509 to indicate that X is now used. */
513 }
515 /* Convert a mem ref into one with a valid memory address.
516 Pass through anything else unchanged. */
518 rtx
520 {
528 /* Don't alter REF itself, since that is probably a stack slot. */
530 }
532 /* If X is a memory reference to a member of an object block, try rewriting
533 it to use an anchor instead. Return the new memory reference on success
534 and the old one on failure. */
536 rtx
538 {
539 rtx base;
540 HOST_WIDE_INT offset;
541 machine_mode mode;
549 /* Split the address into a base and offset. */
555 {
558 }
560 /* Check whether BASE is suitable for anchors. */
568 /* Decide where BASE is going to be. */
571 /* Get the anchor we need to use. */
576 /* Work out the offset from the anchor. */
579 /* If we're going to run a CSE pass, force the anchor into a register.
580 We will then be able to reuse registers for several accesses, if the
581 target costs say that that's worthwhile. */
587 }
588 \f
589 /* Copy the value or contents of X to a new temp reg and return that reg. */
591 rtx
593 {
596 /* If not an operand, must be an address with PLUS and MULT so
597 do the computation. */
605 }
607 /* Like copy_to_reg but always give the new register mode Pmode
608 in case X is a constant. */
610 rtx
612 {
614 }
616 /* Like copy_to_reg but always give the new register mode MODE
617 in case X is a constant. */
619 rtx
621 {
624 /* If not an operand, must be an address with PLUS and MULT so
625 do the computation. */
633 }
635 /* Load X into a register if it is not already one.
636 Use mode MODE for the register.
637 X should be valid for mode MODE, but it may be a constant which
638 is valid for all integer modes; that's why caller must specify MODE.
640 The caller must not alter the value in the register we return,
641 since we mark it as a "constant" register. */
643 rtx
645 {
653 {
656 }
657 else
658 {
662 else
663 {
667 }
668 }
670 /* Let optimizers know that TEMP's value never changes
671 and that X can be substituted for it. Don't get confused
672 if INSN set something else (such as a SUBREG of TEMP). */
679 /* Let optimizers know that TEMP is a pointer, and if so, the
680 known alignment of that pointer. */
681 {
684 {
688 }
695 {
706 else
707 {
710 }
711 }
715 }
718 }
720 /* If X is a memory ref, copy its contents to a new temp reg and return
721 that reg. Otherwise, return X. */
723 rtx
725 {
726 rtx temp;
738 }
740 /* Copy X to TARGET (if it's nonzero and a reg)
741 or to a new temp reg and return that reg.
742 MODE is the mode to use for X in case it is a constant. */
744 rtx
746 {
747 rtx temp;
751 else
756 }
757 \f
758 /* Return the mode to use to pass or return a scalar of TYPE and MODE.
759 PUNSIGNEDP points to the signedness of the type and may be adjusted
760 to show what signedness to use on extension operations.
762 FOR_RETURN is nonzero if the caller is promoting the return value
763 of FNDECL, else it is for promoting args. */
765 machine_mode
768 {
769 /* Called without a type node for a libcall. */
771 {
775 for_return);
776 else
778 }
781 {
786 for_return);
790 }
791 }
792 /* Return the mode to use to store a scalar of TYPE and MODE.
793 PUNSIGNEDP points to the signedness of the type and may be adjusted
794 to show what signedness to use on extension operations. */
796 machine_mode
799 {
800 #ifdef PROMOTE_MODE
803 scalar_mode smode;
804 #endif
806 /* For libcalls this is invoked without TYPE from the backends
807 TARGET_PROMOTE_FUNCTION_MODE hooks. Don't do anything in that
808 case. */
812 /* FIXME: this is the same logic that was there until GCC 4.4, but we
813 probably want to test POINTERS_EXTEND_UNSIGNED even if PROMOTE_MODE
814 is not defined. The affected targets are M32C, S390, SPARC. */
815 #ifdef PROMOTE_MODE
820 {
823 /* Values of these types always have scalar mode. */
829 #ifdef POINTERS_EXTEND_UNSIGNED
835 #endif
839 }
840 #else
842 #endif
843 }
846 /* Use one of promote_mode or promote_function_mode to find the promoted
847 mode of DECL. If PUNSIGNEDP is not NULL, store there the unsignedness
848 of DECL after promotion. */
850 machine_mode
852 {
856 machine_mode pmode;
864 else
870 }
872 /* Return the promoted mode for name. If it is a named SSA_NAME, it
873 is the same as promote_decl_mode. Otherwise, it is the promoted
874 mode of a temp decl of same type as the SSA_NAME, if we had created
875 one. */
877 machine_mode
879 {
882 /* Partitions holding parms and results must be promoted as expected
883 by function.c. */
887 {
891 }
900 }
903 \f
904 /* Controls the behavior of {anti_,}adjust_stack. */
907 /* A helper for adjust_stack and anti_adjust_stack. */
909 static void
911 {
912 rtx temp;
915 /* Hereafter anti_p means subtract_p. */
922 OPTAB_LIB_WIDEN);
926 else
927 {
931 }
935 }
937 /* Adjust the stack pointer by ADJUST (an rtx for a number of bytes).
938 This pops when ADJUST is positive. ADJUST need not be constant. */
940 void
942 {
946 /* We expect all variable sized adjustments to be multiple of
947 PREFERRED_STACK_BOUNDARY. */
948 poly_int64 const_adjust;
953 }
955 /* Adjust the stack pointer by minus ADJUST (an rtx for a number of bytes).
956 This pushes when ADJUST is positive. ADJUST need not be constant. */
958 void
960 {
964 /* We expect all variable sized adjustments to be multiple of
965 PREFERRED_STACK_BOUNDARY. */
966 poly_int64 const_adjust;
971 }
973 /* Round the size of a block to be pushed up to the boundary required
974 by this machine. SIZE is the desired size, which need not be constant. */
976 static rtx
978 {
983 {
990 {
996 }
1000 }
1001 else
1002 {
1003 /* If crtl->preferred_stack_boundary might still grow, use
1004 virtual_preferred_stack_boundary_rtx instead. This will be
1005 substituted by the right value in vregs pass and optimized
1006 during combine. */
1009 NULL_RTX);
1010 }
1012 /* CEIL_DIV_EXPR needs to worry about the addition overflowing,
1013 but we know it can't. So add ourselves and then do
1014 TRUNC_DIV_EXPR. */
1022 }
1023 \f
1024 /* Save the stack pointer for the purpose in SAVE_LEVEL. PSAVE is a pointer
1025 to a previously-created save area. If no save area has been allocated,
1026 this function will allocate one. If a save area is specified, it
1027 must be of the proper mode. */
1029 void
1031 {
1033 /* The default is that we use a move insn and save in a Pmode object. */
1037 /* See if this machine has anything special to do for this kind of save. */
1039 {
1054 }
1056 /* If there is no save area and we have to allocate one, do so. Otherwise
1057 verify the save area is the proper mode. */
1060 {
1062 {
1065 else
1067 }
1068 }
1074 }
1076 /* Restore the stack pointer for the purpose in SAVE_LEVEL. SA is the save
1077 area made by emit_stack_save. If it is zero, we have nothing to do. */
1079 void
1081 {
1082 /* The default is that we use a move insn. */
1085 /* If stack_realign_drap, the x86 backend emits a prologue that aligns both
1086 STACK_POINTER and HARD_FRAME_POINTER.
1087 If stack_realign_fp, the x86 backend emits a prologue that aligns only
1088 STACK_POINTER. This renders the HARD_FRAME_POINTER unusable for accessing
1089 aligned variables, which is reflected in ix86_can_eliminate.
1090 We normally still have the realigned STACK_POINTER that we can use.
1091 But if there is a stack restore still present at reload, it can trigger
1092 mark_not_eliminable for the STACK_POINTER, leaving no way to eliminate
1093 FRAME_POINTER into a hard reg.
1094 To prevent this situation, we force need_drap if we emit a stack
1095 restore. */
1099 /* See if this machine has anything special to do for this kind of save. */
1101 {
1116 }
1119 {
1121 /* These clobbers prevent the scheduler from moving
1122 references to variable arrays below the code
1123 that deletes (pops) the arrays. */
1126 }
1131 }
1133 /* Invoke emit_stack_save on the nonlocal_goto_save_area for the current
1134 function. This should be called whenever we allocate or deallocate
1135 dynamic stack space. */
1137 void
1139 {
1140 tree t_save;
1141 rtx r_save;
1143 /* The nonlocal_goto_save_area object is an array of N pointers. The
1144 first one is used for the frame pointer save; the rest are sized by
1145 STACK_SAVEAREA_MODE. Create a reference to array index 1, the first
1146 of the stack save area slots. */
1154 }
1156 /* Record a new stack level for the current function. This should be called
1157 whenever we allocate or deallocate dynamic stack space. */
1159 void
1161 {
1162 /* Record the new stack level for nonlocal gotos. */
1166 /* Record the new stack level for SJLJ exceptions. */
1169 }
1171 /* Return an rtx doing runtime alignment to REQUIRED_ALIGN on TARGET. */
1173 rtx
1175 {
1176 /* CEIL_DIV_EXPR needs to worry about the addition overflowing,
1177 but we know it can't. So add ourselves and then do
1178 TRUNC_DIV_EXPR. */
1181 Pmode),
1185 Pmode),
1189 Pmode),
1193 }
1195 /* Return an rtx through *PSIZE, representing the size of an area of memory to
1196 be dynamically pushed on the stack.
1198 *PSIZE is an rtx representing the size of the area.
1200 SIZE_ALIGN is the alignment (in bits) that we know SIZE has. This
1201 parameter may be zero. If so, a proper value will be extracted
1202 from SIZE if it is constant, otherwise BITS_PER_UNIT will be assumed.
1204 REQUIRED_ALIGN is the alignment (in bits) required for the region
1205 of memory.
1207 If PSTACK_USAGE_SIZE is not NULL it points to a value that is increased for
1208 the additional size returned. */
1209 void
1213 {
1216 /* Ensure the size is in the proper mode. */
1221 {
1227 /* Watch out for overflow truncating to "unsigned". */
1230 else
1232 }
1236 /* We can't attempt to minimize alignment necessary, because we don't
1237 know the final value of preferred_stack_boundary yet while executing
1238 this code. */
1242 /* We will need to ensure that the address we return is aligned to
1243 REQUIRED_ALIGN. At this point in the compilation, we don't always
1244 know the final value of the STACK_DYNAMIC_OFFSET used in function.c
1245 (it might depend on the size of the outgoing parameter lists, for
1246 example), so we must preventively align the value. We leave space
1247 in SIZE for the hole that might result from the alignment operation. */
1253 {
1262 }
1264 /* Round the size to a multiple of the required stack alignment.
1265 Since the stack is presumed to be rounded before this allocation,
1266 this will maintain the required alignment.
1268 If the stack grows downward, we could save an insn by subtracting
1269 SIZE from the stack pointer and then aligning the stack pointer.
1270 The problem with this is that the stack pointer may be unaligned
1271 between the execution of the subtraction and alignment insns and
1272 some machines do not allow this. Even on those that do, some
1273 signal handlers malfunction if a signal should occur between those
1274 insns. Since this is an extremely rare event, we have no reliable
1275 way of knowing which systems have this problem. So we avoid even
1276 momentarily mis-aligning the stack. */
1278 {
1282 {
1286 }
1287 }
1290 }
1292 /* Return the number of bytes to "protect" on the stack for -fstack-check.
1294 "protect" in the context of -fstack-check means how many bytes we
1295 should always ensure are available on the stack. More importantly
1296 this is how many bytes are skipped when probing the stack.
1298 On some targets we want to reuse the -fstack-check prologue support
1299 to give a degree of protection against stack clashing style attacks.
1301 In that scenario we do not want to skip bytes before probing as that
1302 would render the stack clash protections useless.
1304 So we never use STACK_CHECK_PROTECT directly. Instead we indirect though
1305 this helper which allows us to provide different values for
1306 -fstack-check and -fstack-clash-protection. */
1307 HOST_WIDE_INT
1309 {
1313 }
1315 /* Return an rtx representing the address of an area of memory dynamically
1316 pushed on the stack.
1318 Any required stack pointer alignment is preserved.
1320 SIZE is an rtx representing the size of the area.
1322 SIZE_ALIGN is the alignment (in bits) that we know SIZE has. This
1323 parameter may be zero. If so, a proper value will be extracted
1324 from SIZE if it is constant, otherwise BITS_PER_UNIT will be assumed.
1326 REQUIRED_ALIGN is the alignment (in bits) required for the region
1327 of memory.
1329 MAX_SIZE is an upper bound for SIZE, if SIZE is not constant, or -1 if
1330 no such upper bound is known.
1332 If CANNOT_ACCUMULATE is set to TRUE, the caller guarantees that the
1333 stack space allocated by the generated code cannot be added with itself
1334 in the course of the execution of the function. It is always safe to
1335 pass FALSE here and the following criterion is sufficient in order to
1336 pass TRUE: every path in the CFG that starts at the allocation point and
1337 loops to it executes the associated deallocation code. */
1339 rtx
1342 HOST_WIDE_INT max_size,
1344 {
1349 /* If we're asking for zero bytes, it doesn't matter what we point
1350 to since we can't dereference it. But return a reasonable
1351 address anyway. */
1355 /* Otherwise, show we're calling alloca or equivalent. */
1358 /* If stack usage info is requested, look into the size we are passed.
1359 We need to do so this early to avoid the obfuscation that may be
1360 introduced later by the various alignment operations. */
1362 {
1366 {
1367 /* Look into the last emitted insn and see if we can deduce
1368 something for the register. */
1373 {
1379 }
1380 }
1382 /* If the size is not constant, try the maximum size. */
1386 /* If the size is still not constant, we can't say anything. */
1388 {
1391 }
1392 }
1398 /* The size is supposed to be fully adjusted at this point so record it
1399 if stack usage info is requested. */
1401 {
1404 /* ??? This is gross but the only safe stance in the absence
1405 of stack usage oriented flow analysis. */
1408 }
1415 /* If we are splitting the stack, we need to ask the backend whether
1416 there is enough room on the current stack. If there isn't, or if
1417 the backend doesn't know how to tell is, then we need to call a
1418 function to allocate memory in some other way. This memory will
1419 be released when we release the current stack segment. The
1420 effect is that stack allocation becomes less efficient, but at
1421 least it doesn't cause a stack overflow. */
1423 {
1430 {
1433 /* This instruction will branch to AVAILABLE_LABEL if there
1434 are SIZE bytes available on the stack. */
1437 }
1439 /* The __morestack_allocate_stack_space function will allocate
1440 memory using malloc. If the alignment of the memory returned
1441 by malloc does not meet REQUIRED_ALIGN, we increase SIZE to
1442 make sure we allocate enough space. */
1445 else
1448 Pmode),
1467 }
1469 /* We ought to be called always on the toplevel and stack ought to be aligned
1470 properly. */
1474 /* If needed, check that we have the required amount of stack. Take into
1475 account what has already been checked. */
1477 ;
1480 size);
1484 /* Don't let anti_adjust_stack emit notes. */
1487 /* Perform the required allocation from the stack. Some systems do
1488 this differently than simply incrementing/decrementing from the
1489 stack pointer, such as acquiring the space by calling malloc(). */
1491 {
1493 /* We don't have to check against the predicate for operand 0 since
1494 TARGET is known to be a pseudo of the proper mode, which must
1495 be valid for the operand. */
1499 }
1500 else
1501 {
1502 poly_int64 saved_stack_pointer_delta;
1507 /* Check stack bounds if necessary. */
1509 {
1510 rtx available;
1516 else
1522 space_available);
1525 else
1529 }
1537 else
1540 /* Even if size is constant, don't modify stack_pointer_delta.
1541 The constant size alloca should preserve
1542 crtl->preferred_stack_boundary alignment. */
1547 }
1551 /* Finish up the split stack handling. */
1553 {
1558 }
1562 /* Now that we've committed to a return value, mark its alignment. */
1565 /* Record the new stack level. */
1569 }
1571 /* Return an rtx representing the address of an area of memory already
1572 statically pushed onto the stack in the virtual stack vars area. (It is
1573 assumed that the area is allocated in the function prologue.)
1575 Any required stack pointer alignment is preserved.
1577 OFFSET is the offset of the area into the virtual stack vars area.
1579 REQUIRED_ALIGN is the alignment (in bits) required for the region
1580 of memory. */
1582 rtx
1584 {
1585 rtx target;
1597 /* Now that we've committed to a return value, mark its alignment. */
1601 }
1602 \f
1603 /* A front end may want to override GCC's stack checking by providing a
1604 run-time routine to call to check the stack, so provide a mechanism for
1605 calling that routine. */
1609 void
1611 {
1618 }
1619 \f
1620 /* Emit one stack probe at ADDRESS, an address within the stack. */
1622 void
1624 {
1626 {
1632 }
1633 else
1634 {
1640 /* See if we have an insn to probe the stack. */
1643 else
1645 }
1646 }
1648 /* Probe a range of stack addresses from FIRST to FIRST+SIZE, inclusive.
1649 FIRST is a constant and size is a Pmode RTX. These are offsets from
1650 the current stack pointer. STACK_GROWS_DOWNWARD says whether to add
1651 or subtract them from the stack pointer. */
1653 #define PROBE_INTERVAL (1 << STACK_CHECK_PROBE_INTERVAL_EXP)
1655 #if STACK_GROWS_DOWNWARD
1656 #define STACK_GROW_OP MINUS
1657 #define STACK_GROW_OPTAB sub_optab
1658 #define STACK_GROW_OFF(off) -(off)
1659 #else
1660 #define STACK_GROW_OP PLUS
1661 #define STACK_GROW_OPTAB add_optab
1662 #define STACK_GROW_OFF(off) (off)
1663 #endif
1665 void
1667 {
1668 /* First ensure SIZE is Pmode. */
1672 /* Next see if we have a function to check the stack. */
1674 {
1677 stack_pointer_rtx,
1682 }
1684 /* Next see if we have an insn to check the stack. */
1686 {
1690 stack_pointer_rtx,
1697 }
1699 /* Otherwise we have to generate explicit probes. If we have a constant
1700 small number of them to generate, that's the easy case. */
1702 {
1704 rtx addr;
1706 /* Probe at FIRST + N * PROBE_INTERVAL for values of N from 1 until
1707 it exceeds SIZE. If only one probe is needed, this will not
1708 generate any code. Then probe at FIRST + SIZE. */
1710 {
1715 }
1721 }
1723 /* In the variable case, do the same as above, but in a loop. Note that we
1724 must be extra careful with variables wrapping around because we might be
1725 at the very top (or the very bottom) of the address space and we have to
1726 be able to handle this case properly; in particular, we use an equality
1727 test for the loop condition. */
1728 else
1729 {
1734 /* Step 1: round SIZE to the previous multiple of the interval. */
1736 /* ROUNDED_SIZE = SIZE & -PROBE_INTERVAL */
1737 rounded_size
1743 /* Step 2: compute initial and final value of the loop counter. */
1745 /* TEST_ADDR = SP + FIRST. */
1747 stack_pointer_rtx,
1749 NULL_RTX);
1751 /* LAST_ADDR = SP + FIRST + ROUNDED_SIZE. */
1753 test_addr,
1757 /* Step 3: the loop
1759 while (TEST_ADDR != LAST_ADDR)
1760 {
1761 TEST_ADDR = TEST_ADDR + PROBE_INTERVAL
1762 probe at TEST_ADDR
1763 }
1765 probes at FIRST + N * PROBE_INTERVAL for values of N from 1
1766 until it is equal to ROUNDED_SIZE. */
1770 /* Jump to END_LAB if TEST_ADDR == LAST_ADDR. */
1772 end_lab);
1774 /* TEST_ADDR = TEST_ADDR + PROBE_INTERVAL. */
1781 /* Probe at TEST_ADDR. */
1789 /* Step 4: probe at FIRST + SIZE if we cannot assert at compile-time
1790 that SIZE is equal to ROUNDED_SIZE. */
1792 /* TEMP = SIZE - ROUNDED_SIZE. */
1795 {
1796 rtx addr;
1799 {
1800 /* Use [base + disp} addressing mode if supported. */
1805 }
1806 else
1807 {
1808 /* Manual CSE if the difference is not known at compile-time. */
1813 }
1816 }
1817 }
1819 /* Make sure nothing is scheduled before we are done. */
1821 }
1823 /* Compute parameters for stack clash probing a dynamic stack
1824 allocation of SIZE bytes.
1826 We compute ROUNDED_SIZE, LAST_ADDR, RESIDUAL and PROBE_INTERVAL.
1828 Additionally we conditionally dump the type of probing that will
1829 be needed given the values computed. */
1831 void
1835 rtx size)
1836 {
1837 /* Round SIZE down to STACK_CLASH_PROTECTION_PROBE_INTERVAL */
1838 *probe_interval
1843 /* Compute the value of the stack pointer for the last iteration.
1844 It's just SP + ROUNDED_SIZE. */
1847 stack_pointer_rtx,
1848 rounded_size_op),
1849 NULL_RTX);
1851 /* Compute any residuals not allocated by the loop above. Residuals
1852 are just the ROUNDED_SIZE - SIZE. */
1855 /* Dump key information to make writing tests easy. */
1857 {
1867 "Stack clash dynamic allocation and probing in "
1869 else
1876 else
1878 "Stack clash skipped dynamic allocation and "
1880 }
1881 }
1883 /* Emit the start of an allocate/probe loop for stack
1884 clash protection.
1886 LOOP_LAB and END_LAB are returned for use when we emit the
1887 end of the loop.
1889 LAST addr is the value for SP which stops the loop. */
1890 void
1893 rtx last_addr,
1895 {
1896 /* Essentially we want to emit any setup code, the top of loop
1897 label and the comparison at the top of the loop. */
1905 }
1907 /* Emit the end of a stack clash probing loop.
1909 This consists of just the jump back to LOOP_LAB and
1910 emitting END_LOOP after the loop. */
1912 void
1915 {
1919 else
1924 }
1926 /* Adjust the stack pointer by minus SIZE (an rtx for a number of bytes)
1927 while probing it. This pushes when SIZE is positive. SIZE need not
1928 be constant.
1930 This is subtly different than anti_adjust_stack_and_probe to try and
1931 prevent stack-clash attacks
1933 1. It must assume no knowledge of the probing state, any allocation
1934 must probe.
1936 Consider the case of a 1 byte alloca in a loop. If the sum of the
1937 allocations is large, then this could be used to jump the guard if
1938 probes were not emitted.
1940 2. It never skips probes, whereas anti_adjust_stack_and_probe will
1941 skip probes on the first couple PROBE_INTERVALs on the assumption
1942 they're done elsewhere.
1944 3. It only allocates and probes SIZE bytes, it does not need to
1945 allocate/probe beyond that because this probing style does not
1946 guarantee signal handling capability if the guard is hit. */
1948 static void
1950 {
1951 /* First ensure SIZE is Pmode. */
1955 /* We can get here with a constant size on some targets. */
1962 /* Get the back-end specific probe ranges. */
1967 /* If no back-end specific range defined, default to the top of the newly
1968 allocated range. */
1973 {
1976 {
1980 {
1982 /* The prologue does not probe residuals. Thus the offset
1983 here to probe just beyond what the prologue had already
1984 allocated. */
1986 probe_range));
1989 }
1990 }
1991 else
1992 {
2000 /* The prologue does not probe residuals. Thus the offset here
2001 to probe just beyond what the prologue had already
2002 allocated. */
2004 probe_range));
2009 }
2010 }
2013 {
2015 /* RESIDUAL could be zero at runtime and in that case *sp could
2016 hold live data. Furthermore, we do not want to probe into the
2017 red zone.
2019 If TARGET_PROBE_RANGE_P then the target has promised it's safe to
2020 probe at offset 0. In which case we no longer have to check for
2021 RESIDUAL == 0. However we still need to probe at the right offset
2022 when RESIDUAL > PROBE_RANGE, in which case we probe at PROBE_RANGE.
2024 If !TARGET_PROBE_RANGE_P then go ahead and just guard the probe at *sp
2025 on RESIDUAL != 0 at runtime if RESIDUAL is not a compile time constant.
2026 */
2030 {
2033 rtx probe_cmp_value = target_probe_range_p
2042 }
2046 /* If RESIDUAL isn't a constant and TARGET_PROBE_RANGE_P then we probe up
2047 by the ABI defined safe value. */
2050 /* If RESIDUAL is a constant but smaller than the ABI defined safe value,
2051 we still want to probe up, but the safest amount if a word. */
2053 {
2056 else
2058 }
2059 else
2060 /* If nothing else, probe at the top of the new allocation. */
2068 }
2069 }
2072 /* Adjust the stack pointer by minus SIZE (an rtx for a number of bytes)
2073 while probing it. This pushes when SIZE is positive. SIZE need not
2074 be constant. If ADJUST_BACK is true, adjust back the stack pointer
2075 by plus SIZE at the end. */
2077 void
2079 {
2080 /* We skip the probe for the first interval + a small dope of 4 words and
2081 probe that many bytes past the specified size to maintain a protection
2082 area at the botton of the stack. */
2085 /* First ensure SIZE is Pmode. */
2089 /* If we have a constant small number of probes to generate, that's the
2090 easy case. */
2092 {
2096 /* Adjust SP and probe at PROBE_INTERVAL + N * PROBE_INTERVAL for
2097 values of N from 1 until it exceeds SIZE. If only one probe is
2098 needed, this will not generate any code. Then adjust and probe
2099 to PROBE_INTERVAL + SIZE. */
2101 {
2103 {
2106 }
2107 else
2110 }
2114 else
2117 }
2119 /* In the variable case, do the same as above, but in a loop. Note that we
2120 must be extra careful with variables wrapping around because we might be
2121 at the very top (or the very bottom) of the address space and we have to
2122 be able to handle this case properly; in particular, we use an equality
2123 test for the loop condition. */
2124 else
2125 {
2131 /* Step 1: round SIZE to the previous multiple of the interval. */
2133 /* ROUNDED_SIZE = SIZE & -PROBE_INTERVAL */
2134 rounded_size
2140 /* Step 2: compute initial and final value of the loop counter. */
2142 /* SP = SP_0 + PROBE_INTERVAL. */
2145 /* LAST_ADDR = SP_0 + PROBE_INTERVAL + ROUNDED_SIZE. */
2147 stack_pointer_rtx,
2151 /* Step 3: the loop
2153 while (SP != LAST_ADDR)
2154 {
2155 SP = SP + PROBE_INTERVAL
2156 probe at SP
2157 }
2159 adjusts SP and probes at PROBE_INTERVAL + N * PROBE_INTERVAL for
2160 values of N from 1 until it is equal to ROUNDED_SIZE. */
2164 /* Jump to END_LAB if SP == LAST_ADDR. */
2168 /* SP = SP + PROBE_INTERVAL and probe at SP. */
2177 /* Step 4: adjust SP and probe at PROBE_INTERVAL + SIZE if we cannot
2178 assert at compile-time that SIZE is equal to ROUNDED_SIZE. */
2180 /* TEMP = SIZE - ROUNDED_SIZE. */
2183 {
2184 /* Manual CSE if the difference is not known at compile-time. */
2189 }
2190 }
2192 /* Adjust back and account for the additional first interval. */
2195 else
2197 }
2199 /* Return an rtx representing the register or memory location
2200 in which a scalar value of data type VALTYPE
2201 was returned by a function call to function FUNC.
2202 FUNC is a FUNCTION_DECL, FNTYPE a FUNCTION_TYPE node if the precise
2203 function is known, otherwise 0.
2204 OUTGOING is 1 if on a machine with register windows this function
2205 should return the register in which the function will put its result
2206 and 0 otherwise. */
2208 rtx
2211 {
2212 rtx val;
2218 {
2220 opt_scalar_int_mode tmpmode;
2222 /* int_size_in_bytes can return -1. We don't need a check here
2223 since the value of bytes will then be large enough that no
2224 mode will match anyway. */
2227 {
2228 /* Have we found a large enough mode? */
2231 }
2234 }
2236 }
2238 /* Return an rtx representing the register or memory location
2239 in which a scalar value of mode MODE was returned by a library call. */
2241 rtx
2243 {
2245 }
2247 /* Look up the tree code for a given rtx code
2248 to provide the arithmetic operation for real_arithmetic.
2249 The function returns an int because the caller may not know
2250 what `enum tree_code' means. */
2252 int
2254 {
2258 {
2280 }
2282 }