| blob | 3ae5b8e894f68b4221c56b782aa8f0ad746574f0 |
1 /* Dwarf2 Call Frame Information helper routines.
2 Copyright (C) 1992-2018 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/>. */
44 /* ??? Poison these here until it can be done generically. They've been
45 totally replaced in this file; make sure it stays that way. */
46 #undef DWARF2_UNWIND_INFO
47 #undef DWARF2_FRAME_INFO
48 #if (GCC_VERSION >= 3000)
49 #pragma GCC poison DWARF2_UNWIND_INFO DWARF2_FRAME_INFO
50 #endif
52 #ifndef INCOMING_RETURN_ADDR_RTX
53 #define INCOMING_RETURN_ADDR_RTX (gcc_unreachable (), NULL_RTX)
54 #endif
55 \f
56 /* A collected description of an entire row of the abstract CFI table. */
58 {
59 /* The expression that computes the CFA, expressed in two different ways.
60 The CFA member for the simple cases, and the full CFI expression for
61 the complex cases. The later will be a DW_CFA_cfa_expression. */
62 dw_cfa_location cfa;
63 dw_cfi_ref cfa_cfi;
65 /* The expressions for any register column that is saved. */
66 cfi_vec reg_save;
67 };
69 /* The caller's ORIG_REG is saved in SAVED_IN_REG. */
71 rtx orig_reg;
72 rtx saved_in_reg;
73 };
76 /* Since we no longer have a proper CFG, we're going to create a facsimile
77 of one on the fly while processing the frame-related insns.
79 We create dw_trace_info structures for each extended basic block beginning
80 and ending at a "save point". Save points are labels, barriers, certain
81 notes, and of course the beginning and end of the function.
83 As we encounter control transfer insns, we propagate the "current"
84 row state across the edges to the starts of traces. When checking is
85 enabled, we validate that we propagate the same data from all sources.
87 All traces are members of the TRACE_INFO array, in the order in which
88 they appear in the instruction stream.
90 All save points are present in the TRACE_INDEX hash, mapping the insn
91 starting a trace to the dw_trace_info describing the trace. */
93 struct dw_trace_info
94 {
95 /* The insn that begins the trace. */
98 /* The row state at the beginning and end of the trace. */
101 /* Tracking for DW_CFA_GNU_args_size. The "true" sizes are those we find
102 while scanning insns. However, the args_size value is irrelevant at
103 any point except can_throw_internal_p insns. Therefore the "delay"
104 sizes the values that must actually be emitted for this trace. */
108 /* The first EH insn in the trace, where beg_delay_args_size must be set. */
111 /* The following variables contain data used in interpreting frame related
112 expressions. These are not part of the "real" row state as defined by
113 Dwarf, but it seems like they need to be propagated into a trace in case
114 frame related expressions have been sunk. */
115 /* ??? This seems fragile. These variables are fragments of a larger
116 expression. If we do not keep the entire expression together, we risk
117 not being able to put it together properly. Consider forcing targets
118 to generate self-contained expressions and dropping all of the magic
119 interpretation code in this file. Or at least refusing to shrink wrap
120 any frame related insn that doesn't contain a complete expression. */
122 /* The register used for saving registers to the stack, and its offset
123 from the CFA. */
124 dw_cfa_location cfa_store;
126 /* A temporary register holding an integral value used in adjusting SP
127 or setting up the store_reg. The "offset" field holds the integer
128 value, not an offset. */
129 dw_cfa_location cfa_temp;
131 /* A set of registers saved in other registers. This is the inverse of
132 the row->reg_save info, if the entry is a DW_CFA_register. This is
133 implemented as a flat array because it normally contains zero or 1
134 entry, depending on the target. IA-64 is the big spender here, using
135 a maximum of 5 entries. */
138 /* An identifier for this trace. Used only for debugging dumps. */
141 /* True if this trace immediately follows NOTE_INSN_SWITCH_TEXT_SECTIONS. */
144 /* True if we've seen different values incoming to beg_true_args_size. */
146 };
149 /* Hashtable helpers. */
152 {
155 };
157 inline hashval_t
159 {
161 }
165 {
167 }
170 /* The variables making up the pseudo-cfg, as described above. */
175 /* A vector of call frame insns for the CIE. */
176 cfi_vec cie_cfi_vec;
178 /* The state of the first row of the FDE table, which includes the
179 state provided by the CIE. */
186 /* The insn after which a new CFI note should be emitted. */
189 /* When non-null, add_cfi will add the CFI to this vector. */
192 /* The current instruction trace. */
195 /* The current, i.e. most recently generated, row of the CFI table. */
198 /* A copy of the current CFA, for use during the processing of a
199 single insn. */
202 /* We delay emitting a register save until either (a) we reach the end
203 of the prologue or (b) the register is clobbered. This clusters
204 register saves so that there are fewer pc advances. */
207 rtx reg;
208 rtx saved_reg;
209 poly_int64_pod cfa_offset;
210 };
215 /* True if any CFI directives were emitted at the current insn. */
218 /* Short-hand for commonly used register numbers. */
221 \f
222 /* Hook used by __throw. */
224 rtx
226 {
229 }
231 /* MEM is a memory reference for the register size table, each element of
232 which has mode MODE. Initialize column C as a return address column. */
234 static void
236 {
241 }
243 /* Datastructure used by expand_builtin_init_dwarf_reg_sizes and
244 init_one_dwarf_reg_size to communicate on what has been done by the
245 latter. */
247 struct init_one_dwarf_reg_state
248 {
249 /* Whether the dwarf return column was initialized. */
252 /* For each hard register REGNO, whether init_one_dwarf_reg_size
253 was given REGNO to process already. */
256 };
258 /* Helper for expand_builtin_init_dwarf_reg_sizes. Generate code to
259 initialize the dwarf register size table entry corresponding to register
260 REGNO in REGMODE. TABLE is the table base address, SLOTMODE is the mode to
261 use for the size entry to initialize, and INIT_STATE is the communication
262 datastructure conveying what we're doing to our caller. */
264 static
268 {
282 {
286 }
288 /* ??? When is this true? Should it be a test based on DCOL instead? */
294 }
296 /* Generate code to initialize the dwarf register size table located
297 at the provided ADDRESS. */
299 void
301 {
307 init_one_dwarf_reg_state init_state;
312 {
313 machine_mode save_mode;
314 rtx span;
316 /* No point in processing a register multiple times. This could happen
317 with register spans, e.g. when a reg is first processed as a piece of
318 a span, then as a register on its own later on. */
328 else
329 {
331 {
334 init_one_dwarf_reg_size
336 }
337 }
338 }
343 #ifdef DWARF_ALT_FRAME_RETURN_COLUMN
345 #endif
348 }
350 \f
353 {
354 dw_trace_info dummy;
357 }
359 static bool
361 {
362 /* Labels, except those that are really jump tables. */
366 /* We split traces at the prologue/epilogue notes because those
367 are points at which the unwind info is usually stable. This
368 makes it easier to find spots with identical unwind info so
369 that we can use remember/restore_state opcodes. */
372 {
376 }
379 }
381 /* Divide OFF by DWARF_CIE_DATA_ALIGNMENT, asserting no remainder. */
385 {
389 }
391 /* Return true if we need a signed version of a given opcode
392 (e.g. DW_CFA_offset_extended_sf vs DW_CFA_offset_extended). */
396 {
398 }
400 /* Return a pointer to a newly allocated Call Frame Instruction. */
404 {
411 }
413 /* Return a newly allocated CFI row, with no defined data. */
417 {
423 }
425 /* Return a copy of an existing CFI row. */
429 {
436 }
438 /* Return a copy of an existing CFA location. */
442 {
446 }
448 /* Generate a new label for the CFI info to refer to. */
452 {
459 }
461 /* Add CFI either to the current insn stream or to a vector, or both. */
463 static void
465 {
469 {
472 }
476 }
478 static void
480 {
481 /* We don't yet have a representation for polynomial sizes. */
486 /* While we can occasionally have args_size < 0 internally, this state
487 should not persist at a point we actually need an opcode. */
494 }
496 static void
498 {
505 }
507 /* Perform ROW->REG_SAVE[COLUMN] = CFI. CFI may be null, indicating
508 that the register column is no longer saved. */
510 static void
512 {
516 }
518 /* This function fills in aa dw_cfa_location structure from a dwarf location
519 descriptor sequence. */
521 static void
523 {
531 {
535 {
620 }
621 }
622 }
624 /* Find the previous value for the CFA, iteratively. CFI is the opcode
625 to interpret, *LOC will be updated as necessary, *REMEMBER is used for
626 one level of remember/restore state processing. */
628 void
630 {
632 {
648 else
665 }
666 }
668 /* Determine if two dw_cfa_location structures define the same data. */
670 bool
672 {
678 }
680 /* Determine if two CFI operands are identical. */
682 static bool
684 {
686 {
700 }
702 }
704 /* Determine if two CFI entries are identical. */
706 static bool
708 {
711 /* Make things easier for our callers, including missing operands. */
717 /* Obviously, the opcodes must match. */
722 /* Compare the two operands, re-using the type of the operands as
723 already exposed elsewhere. */
728 }
730 /* Determine if two CFI_ROW structures are identical. */
732 static bool
734 {
738 {
741 }
750 {
760 }
763 }
765 /* The CFA is now calculated from NEW_CFA. Consider OLD_CFA in determining
766 what opcode to emit. Returns the CFI opcode to effect the change, or
767 NULL if NEW_CFA == OLD_CFA. */
769 static dw_cfi_ref
771 {
772 dw_cfi_ref cfi;
774 /* If nothing changed, no need to issue any call frame instructions. */
780 HOST_WIDE_INT const_offset;
785 {
786 /* Construct a "DW_CFA_def_cfa_offset <offset>" instruction, indicating
787 the CFA register did not change but the offset did. The data
788 factoring for DW_CFA_def_cfa_offset_sf happens in output_cfi, or
789 in the assembler via the .cfi_def_cfa_offset directive. */
792 else
795 }
801 {
802 /* Construct a "DW_CFA_def_cfa_register <register>" instruction,
803 indicating the CFA register has changed to <register> but the
804 offset has not changed. This requires the old CFA to have
805 been set as a register plus offset rather than a general
806 DW_CFA_def_cfa_expression. */
809 }
812 {
813 /* Construct a "DW_CFA_def_cfa <register> <offset>" instruction,
814 indicating the CFA register has changed to <register> with
815 the specified offset. The data factoring for DW_CFA_def_cfa_sf
816 happens in output_cfi, or in the assembler via the .cfi_def_cfa
817 directive. */
820 else
824 }
825 else
826 {
827 /* Construct a DW_CFA_def_cfa_expression instruction to
828 calculate the CFA using a full location expression since no
829 register-offset pair is available. */
837 /* It's hard to reconstruct the CFA location for a polynomial
838 expression, so just cache it instead. */
840 else
842 }
845 }
847 /* Similarly, but take OLD_CFA from CUR_ROW, and update it after the fact. */
849 static void
851 {
852 dw_cfi_ref cfi;
859 {
865 }
866 }
868 /* Add the CFI for saving a register. REG is the CFA column number.
869 If SREG is -1, the register is saved at OFFSET from the CFA;
870 otherwise it is saved in SREG. */
872 static void
874 {
881 {
882 HOST_WIDE_INT const_offset;
883 /* When stack is aligned, store REG using DW_CFA_expression with FP. */
885 {
891 }
893 {
898 else
901 }
902 else
903 {
908 }
909 }
911 {
912 /* While we could emit something like DW_CFA_same_value or
913 DW_CFA_restore, we never expect to see something like that
914 in a prologue. This is more likely to be a bug. A backend
915 can always bypass this by using REG_CFA_RESTORE directly. */
917 }
918 else
919 {
922 }
926 }
928 /* A subroutine of scan_trace. Check INSN for a REG_ARGS_SIZE note
929 and adjust data structures to match. */
931 static void
933 {
935 rtx note;
948 /* If the CFA is computed off the stack pointer, then we must adjust
949 the computation of the CFA as well. */
951 {
954 /* Convert a change in args_size (always a positive in the
955 direction of stack growth) to a change in stack pointer. */
960 }
961 }
963 /* A subroutine of scan_trace. INSN is can_throw_internal. Update the
964 data within the trace related to EH insns and args_size. */
966 static void
968 {
971 {
975 }
977 {
980 /* ??? If the CFA is the stack pointer, search backward for the last
981 CFI note and insert there. Given that the stack changed for the
982 args_size change, there *must* be such a note in between here and
983 the last eh insn. */
985 }
986 }
988 /* Short-hand inline for the very common D_F_R (REGNO (x)) operation. */
989 /* ??? This ought to go into dwarf2out.h, except that dwarf2out.h is
990 used in places where rtl is prohibited. */
994 {
997 }
999 /* Compare X and Y for equivalence. The inputs may be REGs or PC_RTX. */
1001 static bool
1003 {
1007 }
1009 /* Record SRC as being saved in DEST. DEST may be null to delete an
1010 existing entry. SRC may be a register or PC_RTX. */
1012 static void
1014 {
1020 {
1023 else
1026 }
1033 }
1035 /* Add an entry to QUEUED_REG_SAVES saying that REG is now saved at
1036 SREG, or if SREG is NULL then it is saved at OFFSET to the CFA. */
1038 static void
1040 {
1045 /* Duplicates waste space, but it's also necessary to remove them
1046 for correctness, since the queue gets output in reverse order. */
1049 {
1052 }
1055 }
1057 /* Output all the entries in QUEUED_REG_SAVES. */
1059 static void
1061 {
1066 {
1073 else
1077 else
1080 }
1083 }
1085 /* Does INSN clobber any register which QUEUED_REG_SAVES lists a saved
1086 location for? Or, does it clobber a register which we've previously
1087 said that some other register is saved in, and for which we now
1088 have a new location for? */
1090 static bool
1092 {
1097 {
1108 }
1111 }
1113 /* What register, if any, is currently saved in REG? */
1115 static rtx
1117 {
1132 }
1134 /* A subroutine of dwarf2out_frame_debug, process a REG_DEF_CFA note. */
1136 static void
1138 {
1143 {
1146 }
1147 /* ??? If this fails, we could be calling into the _loc functions to
1148 define a full expression. So far no port does that. */
1151 }
1153 /* A subroutine of dwarf2out_frame_debug, process a REG_ADJUST_CFA note. */
1155 static void
1157 {
1165 {
1176 }
1180 }
1182 /* A subroutine of dwarf2out_frame_debug, process a REG_CFA_OFFSET note. */
1184 static void
1186 {
1187 poly_int64 offset;
1196 /* As documented, only consider extremely simple addresses. */
1198 {
1209 }
1212 {
1215 }
1216 else
1217 {
1220 }
1222 /* ??? We'd like to use queue_reg_save, but we need to come up with
1223 a different flushing heuristic for epilogues. */
1226 else
1227 {
1228 /* We have a PARALLEL describing where the contents of SRC live.
1229 Adjust the offset for each piece of the PARALLEL. */
1236 {
1241 }
1242 }
1243 }
1245 /* A subroutine of dwarf2out_frame_debug, process a REG_CFA_REGISTER note. */
1247 static void
1249 {
1259 else
1264 /* ??? We'd like to use queue_reg_save, but we need to come up with
1265 a different flushing heuristic for epilogues. */
1267 }
1269 /* A subroutine of dwarf2out_frame_debug, process a REG_CFA_EXPRESSION note. */
1271 static void
1273 {
1295 /* ??? We'd like to use queue_reg_save, were the interface different,
1296 and, as above, we could manage flushing for epilogues. */
1299 }
1301 /* A subroutine of dwarf2out_frame_debug, process a REG_CFA_VAL_EXPRESSION
1302 note. */
1304 static void
1306 {
1322 }
1324 /* A subroutine of dwarf2out_frame_debug, process a REG_CFA_RESTORE note. */
1326 static void
1328 {
1333 {
1337 }
1338 else
1339 {
1340 /* We have a PARALLEL describing where the contents of REG live.
1341 Restore the register for each piece of the PARALLEL. */
1346 {
1352 }
1353 }
1354 }
1356 /* A subroutine of dwarf2out_frame_debug, process a REG_CFA_WINDOW_SAVE.
1357 ??? Perhaps we should note in the CIE where windows are saved (instead of
1358 assuming 0(cfa)) and what registers are in the window. */
1360 static void
1362 {
1367 }
1369 /* Record call frame debugging information for an expression EXPR,
1370 which either sets SP or FP (adjusting how we calculate the frame
1371 address) or saves a register to the stack or another register.
1372 LABEL indicates the address of EXPR.
1374 This function encodes a state machine mapping rtxes to actions on
1375 cfa, cfa_store, and cfa_temp.reg. We describe these rules so
1376 users need not read the source code.
1378 The High-Level Picture
1380 Changes in the register we use to calculate the CFA: Currently we
1381 assume that if you copy the CFA register into another register, we
1382 should take the other one as the new CFA register; this seems to
1383 work pretty well. If it's wrong for some target, it's simple
1384 enough not to set RTX_FRAME_RELATED_P on the insn in question.
1386 Changes in the register we use for saving registers to the stack:
1387 This is usually SP, but not always. Again, we deduce that if you
1388 copy SP into another register (and SP is not the CFA register),
1389 then the new register is the one we will be using for register
1390 saves. This also seems to work.
1392 Register saves: There's not much guesswork about this one; if
1393 RTX_FRAME_RELATED_P is set on an insn which modifies memory, it's a
1394 register save, and the register used to calculate the destination
1395 had better be the one we think we're using for this purpose.
1396 It's also assumed that a copy from a call-saved register to another
1397 register is saving that register if RTX_FRAME_RELATED_P is set on
1398 that instruction. If the copy is from a call-saved register to
1399 the *same* register, that means that the register is now the same
1400 value as in the caller.
1402 Except: If the register being saved is the CFA register, and the
1403 offset is nonzero, we are saving the CFA, so we assume we have to
1404 use DW_CFA_def_cfa_expression. If the offset is 0, we assume that
1405 the intent is to save the value of SP from the previous frame.
1407 In addition, if a register has previously been saved to a different
1408 register,
1410 Invariants / Summaries of Rules
1412 cfa current rule for calculating the CFA. It usually
1413 consists of a register and an offset. This is
1414 actually stored in *cur_cfa, but abbreviated
1415 for the purposes of this documentation.
1416 cfa_store register used by prologue code to save things to the stack
1417 cfa_store.offset is the offset from the value of
1418 cfa_store.reg to the actual CFA
1419 cfa_temp register holding an integral value. cfa_temp.offset
1420 stores the value, which will be used to adjust the
1421 stack pointer. cfa_temp is also used like cfa_store,
1422 to track stores to the stack via fp or a temp reg.
1424 Rules 1- 4: Setting a register's value to cfa.reg or an expression
1425 with cfa.reg as the first operand changes the cfa.reg and its
1426 cfa.offset. Rule 1 and 4 also set cfa_temp.reg and
1427 cfa_temp.offset.
1429 Rules 6- 9: Set a non-cfa.reg register value to a constant or an
1430 expression yielding a constant. This sets cfa_temp.reg
1431 and cfa_temp.offset.
1433 Rule 5: Create a new register cfa_store used to save items to the
1434 stack.
1436 Rules 10-14: Save a register to the stack. Define offset as the
1437 difference of the original location and cfa_store's
1438 location (or cfa_temp's location if cfa_temp is used).
1440 Rules 16-20: If AND operation happens on sp in prologue, we assume
1441 stack is realigned. We will use a group of DW_OP_XXX
1442 expressions to represent the location of the stored
1443 register instead of CFA+offset.
1445 The Rules
1447 "{a,b}" indicates a choice of a xor b.
1448 "<reg>:cfa.reg" indicates that <reg> must equal cfa.reg.
1450 Rule 1:
1451 (set <reg1> <reg2>:cfa.reg)
1452 effects: cfa.reg = <reg1>
1453 cfa.offset unchanged
1454 cfa_temp.reg = <reg1>
1455 cfa_temp.offset = cfa.offset
1457 Rule 2:
1458 (set sp ({minus,plus,losum} {sp,fp}:cfa.reg
1459 {<const_int>,<reg>:cfa_temp.reg}))
1460 effects: cfa.reg = sp if fp used
1461 cfa.offset += {+/- <const_int>, cfa_temp.offset} if cfa.reg==sp
1462 cfa_store.offset += {+/- <const_int>, cfa_temp.offset}
1463 if cfa_store.reg==sp
1465 Rule 3:
1466 (set fp ({minus,plus,losum} <reg>:cfa.reg <const_int>))
1467 effects: cfa.reg = fp
1468 cfa_offset += +/- <const_int>
1470 Rule 4:
1471 (set <reg1> ({plus,losum} <reg2>:cfa.reg <const_int>))
1472 constraints: <reg1> != fp
1473 <reg1> != sp
1474 effects: cfa.reg = <reg1>
1475 cfa_temp.reg = <reg1>
1476 cfa_temp.offset = cfa.offset
1478 Rule 5:
1479 (set <reg1> (plus <reg2>:cfa_temp.reg sp:cfa.reg))
1480 constraints: <reg1> != fp
1481 <reg1> != sp
1482 effects: cfa_store.reg = <reg1>
1483 cfa_store.offset = cfa.offset - cfa_temp.offset
1485 Rule 6:
1486 (set <reg> <const_int>)
1487 effects: cfa_temp.reg = <reg>
1488 cfa_temp.offset = <const_int>
1490 Rule 7:
1491 (set <reg1>:cfa_temp.reg (ior <reg2>:cfa_temp.reg <const_int>))
1492 effects: cfa_temp.reg = <reg1>
1493 cfa_temp.offset |= <const_int>
1495 Rule 8:
1496 (set <reg> (high <exp>))
1497 effects: none
1499 Rule 9:
1500 (set <reg> (lo_sum <exp> <const_int>))
1501 effects: cfa_temp.reg = <reg>
1502 cfa_temp.offset = <const_int>
1504 Rule 10:
1505 (set (mem ({pre,post}_modify sp:cfa_store (???? <reg1> <const_int>))) <reg2>)
1506 effects: cfa_store.offset -= <const_int>
1507 cfa.offset = cfa_store.offset if cfa.reg == sp
1508 cfa.reg = sp
1509 cfa.base_offset = -cfa_store.offset
1511 Rule 11:
1512 (set (mem ({pre_inc,pre_dec,post_dec} sp:cfa_store.reg)) <reg>)
1513 effects: cfa_store.offset += -/+ mode_size(mem)
1514 cfa.offset = cfa_store.offset if cfa.reg == sp
1515 cfa.reg = sp
1516 cfa.base_offset = -cfa_store.offset
1518 Rule 12:
1519 (set (mem ({minus,plus,losum} <reg1>:{cfa_store,cfa_temp} <const_int>))
1521 <reg2>)
1522 effects: cfa.reg = <reg1>
1523 cfa.base_offset = -/+ <const_int> - {cfa_store,cfa_temp}.offset
1525 Rule 13:
1526 (set (mem <reg1>:{cfa_store,cfa_temp}) <reg2>)
1527 effects: cfa.reg = <reg1>
1528 cfa.base_offset = -{cfa_store,cfa_temp}.offset
1530 Rule 14:
1531 (set (mem (post_inc <reg1>:cfa_temp <const_int>)) <reg2>)
1532 effects: cfa.reg = <reg1>
1533 cfa.base_offset = -cfa_temp.offset
1534 cfa_temp.offset -= mode_size(mem)
1536 Rule 15:
1537 (set <reg> {unspec, unspec_volatile})
1538 effects: target-dependent
1540 Rule 16:
1541 (set sp (and: sp <const_int>))
1542 constraints: cfa_store.reg == sp
1543 effects: cfun->fde.stack_realign = 1
1544 cfa_store.offset = 0
1545 fde->drap_reg = cfa.reg if cfa.reg != sp and cfa.reg != fp
1547 Rule 17:
1548 (set (mem ({pre_inc, pre_dec} sp)) (mem (plus (cfa.reg) (const_int))))
1549 effects: cfa_store.offset += -/+ mode_size(mem)
1551 Rule 18:
1552 (set (mem ({pre_inc, pre_dec} sp)) fp)
1553 constraints: fde->stack_realign == 1
1554 effects: cfa_store.offset = 0
1555 cfa.reg != HARD_FRAME_POINTER_REGNUM
1557 Rule 19:
1558 (set (mem ({pre_inc, pre_dec} sp)) cfa.reg)
1559 constraints: fde->stack_realign == 1
1560 && cfa.offset == 0
1561 && cfa.indirect == 0
1562 && cfa.reg != HARD_FRAME_POINTER_REGNUM
1563 effects: Use DW_CFA_def_cfa_expression to define cfa
1564 cfa.reg == fde->drap_reg */
1566 static void
1568 {
1570 poly_int64 offset;
1571 dw_fde_ref fde;
1573 /* If RTX_FRAME_RELATED_P is set on a PARALLEL, process each member of
1574 the PARALLEL independently. The first element is always processed if
1575 it is a SET. This is for backward compatibility. Other elements
1576 are processed only if they are SETs and the RTX_FRAME_RELATED_P
1577 flag is set in them. */
1579 {
1582 rtx elem;
1584 /* PARALLELs have strict read-modify-write semantics, so we
1585 ought to evaluate every rvalue before changing any lvalue.
1586 It's cumbersome to do that in general, but there's an
1587 easy approximation that is enough for all current users:
1588 handle register saves before register assignments. */
1591 {
1597 }
1600 {
1606 }
1608 }
1616 {
1620 }
1625 {
1628 {
1629 /* Setting FP from SP. */
1632 {
1633 /* Rule 1 */
1634 /* Update the CFA rule wrt SP or FP. Make sure src is
1635 relative to the current CFA register.
1637 We used to require that dest be either SP or FP, but the
1638 ARM copies SP to a temporary register, and from there to
1639 FP. So we just rely on the backends to only set
1640 RTX_FRAME_RELATED_P on appropriate insns. */
1644 }
1645 else
1646 {
1647 /* Saving a register in a register. */
1649 /* For the SPARC and its register window. */
1652 /* After stack is aligned, we can only save SP in FP
1653 if drap register is used. In this case, we have
1654 to restore stack pointer with the CFA value and we
1655 don't generate this DWARF information. */
1662 else
1664 }
1671 {
1672 /* Rule 2 */
1673 /* Adjusting SP. */
1675 {
1679 }
1684 {
1685 /* Restoring SP from FP in the epilogue. */
1688 }
1690 /* Assume we've set the source reg of the LO_SUM from sp. */
1691 ;
1692 else
1701 }
1703 {
1704 /* Rule 3 */
1705 /* Either setting the FP from an offset of the SP,
1706 or adjusting the FP */
1716 }
1717 else
1718 {
1721 /* Rule 4 */
1725 {
1726 /* Setting a temporary CFA register that will be copied
1727 into the FP later on. */
1731 /* Or used to save regs to the stack. */
1734 }
1736 /* Rule 5 */
1740 {
1741 /* Setting a scratch register that we will use instead
1742 of SP for saving registers to the stack. */
1747 }
1749 /* Rule 9 */
1754 else
1756 }
1759 /* Rule 6 */
1766 /* Rule 7 */
1775 /* The target shouldn't generate this kind of CFI note if we
1776 can't represent it. */
1780 /* Skip over HIGH, assuming it will be followed by a LO_SUM,
1781 which will fill in all of the bits. */
1782 /* Rule 8 */
1786 /* Rule 15 */
1789 /* All unspecs should be represented by REG_CFA_* notes. */
1793 /* Rule 16 */
1795 /* If this AND operation happens on stack pointer in prologue,
1796 we assume the stack is realigned and we extract the
1797 alignment. */
1799 {
1800 /* We interpret reg_save differently with stack_realign set.
1801 Thus we must flush whatever we have queued first. */
1813 }
1818 }
1823 /* Saving a register to the stack. Make sure dest is relative to the
1824 CFA register. */
1826 {
1827 /* Rule 10 */
1828 /* With a push. */
1831 /* We can't handle variable size modifications. */
1843 else
1847 /* Rule 11 */
1861 /* Rule 18: If stack is aligned, we will use FP as a
1862 reference to represent the address of the stored
1863 regiser. */
1868 {
1871 }
1878 else
1882 /* Rule 12 */
1883 /* With an offset. */
1887 {
1901 else
1902 {
1905 }
1906 }
1909 /* Rule 13 */
1910 /* Without an offset. */
1912 {
1919 else
1920 {
1923 }
1924 }
1927 /* Rule 14 */
1937 }
1939 /* Rule 17 */
1940 /* If the source operand of this MEM operation is a memory,
1941 we only care how much stack grew. */
1949 {
1950 /* We're storing the current CFA reg into the stack. */
1953 {
1954 /* Rule 19 */
1955 /* If stack is aligned, putting CFA reg into stack means
1956 we can no longer use reg + offset to represent CFA.
1957 Here we use DW_CFA_def_cfa_expression instead. The
1958 result of this expression equals to the original CFA
1959 value. */
1964 {
1974 }
1976 /* If the source register is exactly the CFA, assume
1977 we're saving SP like any other register; this happens
1978 on the ARM. */
1981 }
1982 else
1983 {
1984 /* Otherwise, we'll need to look in the stack to
1985 calculate the CFA. */
1996 }
1997 }
2001 else
2006 else
2007 {
2008 /* We have a PARALLEL describing where the contents of SRC live.
2009 Queue register saves for each piece of the PARALLEL. */
2016 {
2020 }
2021 }
2026 }
2027 }
2029 /* Record call frame debugging information for INSN, which either sets
2030 SP or FP (adjusting how we calculate the frame address) or saves a
2031 register to the stack. */
2033 static void
2035 {
2041 {
2054 {
2058 }
2074 {
2078 }
2091 else
2100 {
2105 }
2113 {
2116 {
2120 }
2121 }
2127 /* We overload both of these operations onto the same DWARF opcode. */
2133 /* The actual flush happens elsewhere. */
2139 }
2142 {
2144 do_frame_expr:
2147 /* Check again. A parallel can save and update the same register.
2148 We could probably check just once, here, but this is safer than
2149 removing the check at the start of the function. */
2152 }
2153 }
2155 /* Emit CFI info to change the state from OLD_ROW to NEW_ROW. */
2157 static void
2159 {
2161 dw_cfi_ref cfi;
2165 else
2166 {
2170 }
2177 {
2186 ;
2191 }
2192 }
2194 /* Examine CFI and return true if a cfi label and set_loc is needed
2195 beforehand. Even when generating CFI assembler instructions, we
2196 still have to add the cfi to the list so that lookup_cfa_1 works
2197 later on. When -g2 and above we even need to force emitting of
2198 CFI labels and add to list a DW_CFA_set_loc for convert_cfa_to_fb_loc_list
2199 purposes. If we're generating DWARF3 output we use DW_OP_call_frame_cfa
2200 and so don't use convert_cfa_to_fb_loc_list. */
2202 static bool
2204 {
2212 {
2214 {
2225 }
2226 }
2228 }
2230 /* Walk the function, looking for NOTE_INSN_CFI notes. Add the CFIs to the
2231 function's FDE, adding CFI labels and set_loc/advance_loc opcodes as
2232 necessary. */
2233 static void
2235 {
2240 {
2247 {
2251 {
2254 }
2259 else
2262 {
2265 dw_cfi_ref xcfi;
2267 /* Set the location counter to the new label. */
2275 }
2277 do
2278 {
2282 }
2284 }
2285 }
2286 }
2290 /* If LABEL is the start of a trace, then initialize the state of that
2291 trace from CUR_TRACE and CUR_ROW. */
2293 static void
2295 {
2302 {
2307 }
2311 {
2312 /* This is the first time we've encountered this trace. Propagate
2313 state across the edge and push the trace onto the work list. */
2325 }
2326 else
2327 {
2329 /* We ought to have the same state incoming to a given trace no
2330 matter how we arrive at the trace. Anything else means we've
2331 got some kind of optimization error. */
2332 #if CHECKING_P
2334 {
2336 {
2342 }
2345 }
2346 #endif
2348 /* The args_size is allowed to conflict if it isn't actually used. */
2351 }
2352 }
2354 /* Similarly, but handle the args_size and CFA reset across EH
2355 and non-local goto edges. */
2357 static void
2359 {
2361 dw_cfa_location save_cfa;
2365 {
2368 }
2375 {
2376 /* Convert a change in args_size (always a positive in the
2377 direction of stack growth) to a change in stack pointer. */
2382 }
2388 }
2390 /* Propagate CUR_TRACE state to the destinations implied by INSN. */
2391 /* ??? Sadly, this is in large part a duplicate of make_edges. */
2393 static void
2395 {
2396 rtx tmp;
2400 {
2407 {
2412 {
2415 }
2416 }
2418 {
2423 }
2425 ;
2427 {
2430 {
2434 }
2435 }
2436 else
2437 {
2441 }
2442 }
2444 {
2445 /* Sibling calls don't have edges inside this function. */
2449 /* Process non-local goto edges. */
2452 lab;
2455 }
2457 {
2462 }
2464 /* Process EH edges. */
2466 {
2470 }
2471 }
2473 /* A subroutine of scan_trace. Do what needs to be done "after" INSN. */
2475 static void
2477 {
2481 }
2483 /* Scan the trace beginning at INSN and create the CFI notes for the
2484 instructions therein. */
2486 static void
2488 {
2490 dw_cfa_location this_cfa;
2507 insn;
2509 {
2512 /* Do everything that happens "before" the insn. */
2515 /* Notice the end of a trace. */
2517 {
2518 /* Don't bother saving the unneeded queued registers at all. */
2521 }
2523 {
2524 /* Propagate across fallthru edges. */
2528 }
2533 /* Handle all changes to the row state. Sequences require special
2534 handling for the positioning of the notes. */
2536 {
2546 {
2547 /* ??? Hopefully multiple delay slots are not annulled. */
2555 {
2556 cfi_vec save_row_reg_save;
2558 /* If ELT is an instruction from target of an annulled
2559 branch, the effects are for the target only and so
2560 the args_size and CFA along the current path
2561 shouldn't change. */
2569 /* ??? Should we instead save the entire row state? */
2578 }
2579 else
2580 {
2581 /* If ELT is a annulled branch-taken instruction (i.e.
2582 executed only when branch is not taken), the args_size
2583 and CFA should not change through the jump. */
2586 /* Update and continue with the trace. */
2590 }
2592 }
2594 /* The insns in the delay slot should all be considered to happen
2595 "before" a call insn. Consider a call with a stack pointer
2596 adjustment in the delay slot. The backtrace from the callee
2597 should include the sp adjustment. Unfortunately, that leaves
2598 us with an unavoidable unwinding error exactly at the call insn
2599 itself. For jump insns we'd prefer to avoid this error by
2600 placing the notes after the sequence. */
2605 {
2608 }
2610 /* Make sure any register saves are visible at the jump target. */
2614 /* However, if there is some adjustment on the call itself, e.g.
2615 a call_pop, that action should be considered to happen after
2616 the call returns. */
2619 }
2620 else
2621 {
2622 /* Flush data before calls and jumps, and of course if necessary. */
2624 {
2627 }
2637 }
2639 /* Between frame-related-p and args_size we might have otherwise
2640 emitted two cfa adjustments. Do it now. */
2643 /* Minimize the number of advances by emitting the entire queue
2644 once anything is emitted. */
2649 /* Note that a test for control_flow_insn_p does exactly the
2650 same tests as are done to actually create the edges. So
2651 always call the routine and let it not create edges for
2652 non-control-flow insns. */
2654 }
2660 }
2662 /* Scan the function and create the initial set of CFI notes. */
2664 static void
2666 {
2672 /* Always begin at the entry trace. */
2677 {
2680 }
2684 }
2686 /* Return the insn before the first NOTE_INSN_CFI after START. */
2690 {
2693 {
2698 }
2700 }
2702 /* Insert CFI notes between traces to properly change state between them. */
2704 static void
2706 {
2710 /* ??? Ideally, we should have both queued and processed every trace.
2711 However the current representation of constant pools on various targets
2712 is indistinguishable from unreachable code. Assume for the moment that
2713 we can simply skip over such traces. */
2714 /* ??? Consider creating a DATA_INSN rtx code to indicate that
2715 these are not "real" instructions, and should not be considered.
2716 This could be generically useful for tablejump data as well. */
2717 /* Remove all unprocessed traces from the list. */
2719 {
2722 {
2725 }
2726 else
2728 }
2730 /* Work from the end back to the beginning. This lets us easily insert
2731 remember/restore_state notes in the correct order wrt other notes. */
2734 {
2742 /* In dwarf2out_switch_text_section, we'll begin a new FDE
2743 for the portion of the function in the alternate text
2744 section. The row state at the very beginning of that
2745 new FDE will be exactly the row state from the CIE. */
2748 else
2749 {
2751 /* If there's no change from the previous end state, fine. */
2753 ;
2754 /* Otherwise check for the common case of sharing state with
2755 the beginning of an epilogue, but not the end. Insert
2756 remember/restore opcodes in that case. */
2758 {
2759 dw_cfi_ref cfi;
2761 /* Note that if we blindly insert the remember at the
2762 start of the trace, we can wind up increasing the
2763 size of the unwind info due to extra advance opcodes.
2764 Instead, put the remember immediately before the next
2765 state change. We know there must be one, because the
2766 state at the beginning and head of the trace differ. */
2778 }
2779 /* Otherwise, we'll simply change state from the previous end. */
2780 }
2785 {
2792 do
2793 {
2797 }
2799 }
2800 }
2802 /* Connect args_size between traces that have can_throw_internal insns. */
2804 {
2808 {
2818 {
2819 /* ??? Search back to previous CFI note. */
2822 }
2825 }
2826 }
2827 }
2829 /* Set up the pseudo-cfg of instruction traces, as described at the
2830 block comment at the top of the file. */
2832 static void
2834 {
2836 dw_trace_info ti;
2840 /* The first trace begins at the start of the function,
2841 and begins with the CIE row state. */
2853 /* Walk all the insns, collecting start of trace locations. */
2857 {
2862 {
2863 /* We should have just seen a barrier. */
2866 }
2867 /* Watch out for save_point notes between basic blocks.
2868 In particular, a note after a barrier. Do not record these,
2869 delaying trace creation until the label. */
2872 {
2881 }
2882 }
2884 /* Create the trace index after we've finished building trace_info,
2885 avoiding stale pointer problems due to reallocation. */
2886 trace_index
2890 {
2901 }
2902 }
2904 /* Record the initial position of the return address. RTL is
2905 INCOMING_RETURN_ADDR_RTX. */
2907 static void
2909 {
2914 {
2916 /* RA is in a register. */
2921 /* RA is on the stack. */
2924 {
2942 }
2947 /* The return address is at some offset from any value we can
2948 actually load. For instance, on the SPARC it is in %i7+8. Just
2949 ignore the offset for now; it doesn't matter for unwinding frames. */
2956 }
2959 {
2963 }
2964 }
2966 static void
2968 {
2969 dw_cfa_location loc;
2970 dw_trace_info cie_trace;
2980 /* On entry, the Canonical Frame Address is at SP. */
2988 {
2991 /* For a few targets, we have the return address incoming into a
2992 register, but choose a different return column. This will result
2993 in a DW_CFA_register for the return, and an entry in
2994 regs_saved_in_regs to match. If the target later stores that
2995 return address register to the stack, we want to be able to emit
2996 the DW_CFA_offset against the return column, not the intermediate
2997 save register. Save the contents of regs_saved_in_regs so that
2998 we can re-initialize it at the start of each function. */
3000 {
3010 }
3011 }
3016 }
3018 /* Annotate the function with NOTE_INSN_CFI notes to record the CFI
3019 state at each location within the function. These notes will be
3020 emitted during pass_final. */
3022 static unsigned int
3024 {
3025 /* Different HARD_FRAME_POINTER_REGNUM might coexist in the same file. */
3028 /* The first time we're called, compute the incoming frame state. */
3036 /* Do the work. */
3041 /* Free all the data we allocated. */
3042 {
3048 }
3055 }
3056 \f
3057 /* Convert a DWARF call frame info. operation to its string name */
3061 {
3068 }
3070 /* This routine will generate the correct assembly data for a location
3071 description based on a cfi entry with a complex address. */
3073 static void
3075 {
3076 dw_loc_descr_ref loc;
3081 {
3086 }
3087 else
3090 /* Output the size of the block. */
3094 /* Now output the operations themselves. */
3096 }
3098 /* Similar, but used for .cfi_escape. */
3100 static void
3102 {
3103 dw_loc_descr_ref loc;
3108 {
3113 }
3114 else
3117 /* Output the size of the block. */
3122 /* Now output the operations themselves. */
3124 }
3126 /* Output a Call Frame Information opcode and its operand(s). */
3128 void
3130 {
3132 HOST_WIDE_INT off;
3141 {
3147 }
3149 {
3153 }
3154 else
3155 {
3160 {
3167 else
3259 /* Obsoleted by DW_CFA_offset_extended_sf. */
3264 }
3265 }
3266 }
3268 /* Similar, but do it via assembler directives instead. */
3270 void
3272 {
3276 {
3283 /* Should only be created in a code path not followed when emitting
3284 via directives. The assembler is going to take care of this for
3285 us. But this routines is also used for debugging dumps, so
3286 print something. */
3349 {
3356 }
3357 else
3358 {
3361 }
3372 {
3377 }
3385 }
3386 }
3388 void
3390 {
3393 }
3395 static void
3397 {
3398 dw_cfi_ref cfi;
3403 {
3404 dw_cfa_location dummy;
3408 }
3414 }
3418 void
3420 {
3422 }
3423 \f
3425 /* Save the result of dwarf2out_do_frame across PCH.
3426 This variable is tri-state, with 0 unset, >0 true, <0 false. */
3429 /* Decide whether to emit EH frame unwind information for the current
3430 translation unit. */
3432 bool
3434 {
3435 return
3438 }
3440 /* Decide whether we want to emit frame unwind information for the current
3441 translation unit. */
3443 bool
3445 {
3446 /* We want to emit correct CFA location expressions or lists, so we
3447 have to return true if we're going to output debug info, even if
3448 we're not going to output frame or unwind info. */
3462 }
3464 /* Decide whether to emit frame unwind via assembler directives. */
3466 bool
3468 {
3474 /* Assume failure for a moment. */
3482 /* Make sure the personality encoding is one the assembler can support.
3483 In particular, aligned addresses can't be handled. */
3491 /* If we can't get the assembler to emit only .debug_frame, and we don't need
3492 dwarf2 unwind info for exceptions, then emit .debug_frame by hand. */
3496 /* Success! */
3499 }
3504 {
3514 };
3517 {
3521 {}
3523 /* opt_pass methods: */
3529 bool
3531 {
3532 /* Targets which still implement the prologue in assembler text
3533 cannot use the generic dwarf2 unwinding. */
3537 /* ??? What to do for UI_TARGET unwinding? They might be able to benefit
3538 from the optimized shrink-wrapping annotations that we will compute.
3539 For now, only produce the CFI notes for dwarf2. */
3541 }
3545 rtl_opt_pass *
3547 {
3549 }