| blob | 7e9ca6cadbb0c21289811f12bf161919956a30bc |
1 /* Common target dependent code for GDB on ARM systems.
3 Copyright (C) 1988, 1989, 1991, 1992, 1993, 1995, 1996, 1998, 1999,
4 2000, 2001, 2002, 2003, 2004, 2005, 2006
5 Free Software Foundation, Inc.
7 This file is part of GDB.
9 This program is free software; you can redistribute it and/or modify
10 it under the terms of the GNU General Public License as published by
11 the Free Software Foundation; either version 2 of the License, or
12 (at your option) any later version.
14 This program is distributed in the hope that it will be useful,
15 but WITHOUT ANY WARRANTY; without even the implied warranty of
16 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17 GNU General Public License for more details.
19 You should have received a copy of the GNU General Public License
20 along with this program; if not, write to the Free Software
21 Foundation, Inc., 51 Franklin Street, Fifth Floor,
22 Boston, MA 02110-1301, USA. */
55 /* Macros for setting and testing a bit in a minimal symbol that marks
56 it as Thumb function. The MSB of the minimal symbol's "info" field
57 is used for this purpose.
59 MSYMBOL_SET_SPECIAL Actually sets the "special" bit.
60 MSYMBOL_IS_SPECIAL Tests the "special" bit in a minimal symbol. */
62 #define MSYMBOL_SET_SPECIAL(msym) \
63 MSYMBOL_INFO (msym) = (char *) (((long) MSYMBOL_INFO (msym)) \
64 | 0x80000000)
66 #define MSYMBOL_IS_SPECIAL(msym) \
67 (((long) MSYMBOL_INFO (msym) & 0x80000000) != 0)
69 /* The list of available "set arm ..." and "show arm ..." commands. */
73 /* The type of floating-point to use. Keep this in sync with enum
74 arm_float_model, and the help string in _initialize_arm_tdep. */
76 {
82 NULL
83 };
85 /* A variable that can be configured by the user. */
89 /* The ABI to use. Keep this in sync with arm_abi_kind. */
91 {
95 NULL
96 };
98 /* A variable that can be configured by the user. */
102 /* Number of different reg name sets (options). */
105 /* We have more registers than the disassembler as gdb can print the value
106 of special registers as well.
107 The general register names are overwritten by whatever is being used by
108 the disassembler at the moment. We also adjust the case of cpsr and fps. */
110 /* Initial value: Register names used in ARM's ISA documentation. */
121 /* Valid register name styles. */
124 /* Disassembly style to use. Default to "std" register names. */
126 /* Index to that option in the opcodes table. */
129 /* This is used to keep the bfd arch_info in sync with the disassembly
130 style. */
140 struct arm_prologue_cache
141 {
142 /* The stack pointer at the time this frame was created; i.e. the
143 caller's stack pointer when this function was called. It is used
144 to identify this frame. */
145 CORE_ADDR prev_sp;
147 /* The frame base for this frame is just prev_sp + frame offset -
148 frame size. FRAMESIZE is the size of this stack frame, and
149 FRAMEOFFSET if the initial offset from the stack pointer (this
150 frame's stack pointer, not PREV_SP) to the frame base. */
155 /* The register used to hold the frame pointer for this frame. */
158 /* Saved register offsets. */
160 };
162 /* Addresses for calling Thumb functions have the bit 0 set.
163 Here are some macros to test, set, or clear bit 0 of addresses. */
164 #define IS_THUMB_ADDR(addr) ((addr) & 1)
165 #define MAKE_THUMB_ADDR(addr) ((addr) | 1)
166 #define UNMAKE_THUMB_ADDR(addr) ((addr) & ~1)
168 /* Set to true if the 32-bit mode is in use. */
172 /* Determine if the program counter specified in MEMADDR is in a Thumb
173 function. */
175 int
177 {
180 /* If bit 0 of the address is set, assume this is a Thumb address. */
184 /* Thumb functions have a "special" bit set in minimal symbols. */
187 {
189 }
190 else
191 {
193 }
194 }
196 /* Remove useless bits from addresses in a running program. */
197 static CORE_ADDR
199 {
202 else
204 }
206 /* When reading symbols, we need to zap the low bit of the address,
207 which may be set to 1 for Thumb functions. */
208 static CORE_ADDR
210 {
212 }
214 /* Immediately after a function call, return the saved pc. Can't
215 always go through the frames for this because on some machines the
216 new frame is not set up until the new function executes some
217 instructions. */
219 static CORE_ADDR
221 {
223 }
225 /* A typical Thumb prologue looks like this:
226 push {r7, lr}
227 add sp, sp, #-28
228 add r7, sp, #12
229 Sometimes the latter instruction may be replaced by:
230 mov r7, sp
232 or like this:
233 push {r7, lr}
234 mov r7, sp
235 sub sp, #12
237 or, on tpcs, like this:
238 sub sp,#16
239 push {r7, lr}
240 (many instructions)
241 mov r7, sp
242 sub sp, #12
244 There is always one instruction of three classes:
245 1 - push
246 2 - setting of r7
247 3 - adjusting of sp
249 When we have found at least one of each class we are done with the prolog.
250 Note that the "sub sp, #NN" before the push does not count.
251 */
253 static CORE_ADDR
255 {
256 CORE_ADDR current_pc;
257 /* findmask:
258 bit 0 - push { rlist }
259 bit 1 - mov r7, sp OR add r7, sp, #imm (setting of r7)
260 bit 2 - sub sp, #simm OR add sp, #simm (adjusting of sp)
261 */
267 {
271 {
273 }
275 sub sp, #simm */
276 {
279 else
281 }
283 {
285 }
287 {
289 }
291 {
292 /* We have found one of each type of prologue instruction */
294 }
295 else
296 /* Something in the prolog that we don't care about or some
297 instruction from outside the prolog scheduled here for
298 optimization. */
300 }
303 }
305 /* Advance the PC across any function entry prologue instructions to
306 reach some "real" code.
308 The APCS (ARM Procedure Call Standard) defines the following
309 prologue:
311 mov ip, sp
312 [stmfd sp!, {a1,a2,a3,a4}]
313 stmfd sp!, {...,fp,ip,lr,pc}
314 [stfe f7, [sp, #-12]!]
315 [stfe f6, [sp, #-12]!]
316 [stfe f5, [sp, #-12]!]
317 [stfe f4, [sp, #-12]!]
318 sub fp, ip, #nn @@ nn == 20 or 4 depending on second insn */
320 static CORE_ADDR
322 {
324 CORE_ADDR skip_pc;
329 /* If we're in a dummy frame, don't even try to skip the prologue. */
333 /* See what the symbol table says. */
336 {
339 /* Found a function. */
342 {
343 /* Don't use this trick for assembly source files. */
347 }
348 }
350 /* Check if this is Thumb code. */
354 /* Can't find the prologue end in the symbol table, try it the hard way
355 by disassembling the instructions. */
357 /* Like arm_scan_prologue, stop no later than pc + 64. */
362 {
365 /* "mov ip, sp" is no longer a required part of the prologue. */
375 /* Some prologues begin with "str lr, [sp, #-4]!". */
385 /* Any insns after this point may float into the code, if it makes
386 for better instruction scheduling, so we skip them only if we
387 find them, but still consider the function to be frame-ful. */
389 /* We may have either one sfmfd instruction here, or several stfe
390 insns, depending on the version of floating point code we
391 support. */
414 /* Un-recognized instruction; stop scanning. */
416 }
419 }
421 /* *INDENT-OFF* */
422 /* Function: thumb_scan_prologue (helper function for arm_scan_prologue)
423 This function decodes a Thumb function prologue to determine:
424 1) the size of the stack frame
425 2) which registers are saved on it
426 3) the offsets of saved regs
427 4) the offset from the stack pointer to the frame pointer
429 A typical Thumb function prologue would create this stack frame
430 (offsets relative to FP)
431 old SP -> 24 stack parameters
432 20 LR
433 16 R7
434 R7 -> 0 local variables (16 bytes)
435 SP -> -12 additional stack space (12 bytes)
436 The frame size would thus be 36 bytes, and the frame offset would be
437 12 bytes. The frame register is R7.
439 The comments for thumb_skip_prolog() describe the algorithm we use
440 to detect the end of the prolog. */
441 /* *INDENT-ON* */
443 static void
445 {
446 CORE_ADDR prologue_start;
447 CORE_ADDR prologue_end;
448 CORE_ADDR current_pc;
449 /* Which register has been copied to register n? */
451 /* findmask:
452 bit 0 - push { rlist }
453 bit 1 - mov r7, sp OR add r7, sp, #imm (setting of r7)
454 bit 2 - sub sp, #simm OR add sp, #simm (adjusting of sp)
455 */
460 {
467 }
468 else
469 /* We're in the boondocks: we have no idea where the start of the
470 function is. */
475 /* Initialize the saved register map. When register H is copied to
476 register L, we will put H in saved_reg[L]. */
480 /* Search the prologue looking for instructions that set up the
481 frame pointer, adjust the stack pointer, and save registers.
482 Do this until all basic prolog instructions are found. */
488 {
496 {
499 /* Bits 0-7 contain a mask for registers R0-R7. Bit 8 says
500 whether to save LR (R14). */
503 /* Calculate offsets of saved R0-R7 and LR. */
506 {
509 /* Reset saved register map. */
511 }
512 }
514 sub sp, #simm */
515 {
518 else
523 {
526 }
528 }
530 {
533 /* get scaled offset */
535 }
537 {
542 }
544 {
548 }
549 else
550 /* Something in the prolog that we don't care about or some
551 instruction from outside the prolog scheduled here for
552 optimization. */
554 }
555 }
557 /* This function decodes an ARM function prologue to determine:
558 1) the size of the stack frame
559 2) which registers are saved on it
560 3) the offsets of saved regs
561 4) the offset from the stack pointer to the frame pointer
562 This information is stored in the "extra" fields of the frame_info.
564 There are two basic forms for the ARM prologue. The fixed argument
565 function call will look like:
567 mov ip, sp
568 stmfd sp!, {fp, ip, lr, pc}
569 sub fp, ip, #4
570 [sub sp, sp, #4]
572 Which would create this stack frame (offsets relative to FP):
573 IP -> 4 (caller's stack)
574 FP -> 0 PC (points to address of stmfd instruction + 8 in callee)
575 -4 LR (return address in caller)
576 -8 IP (copy of caller's SP)
577 -12 FP (caller's FP)
578 SP -> -28 Local variables
580 The frame size would thus be 32 bytes, and the frame offset would be
581 28 bytes. The stmfd call can also save any of the vN registers it
582 plans to use, which increases the frame size accordingly.
584 Note: The stored PC is 8 off of the STMFD instruction that stored it
585 because the ARM Store instructions always store PC + 8 when you read
586 the PC register.
588 A variable argument function call will look like:
590 mov ip, sp
591 stmfd sp!, {a1, a2, a3, a4}
592 stmfd sp!, {fp, ip, lr, pc}
593 sub fp, ip, #20
595 Which would create this stack frame (offsets relative to FP):
596 IP -> 20 (caller's stack)
597 16 A4
598 12 A3
599 8 A2
600 4 A1
601 FP -> 0 PC (points to address of stmfd instruction + 8 in callee)
602 -4 LR (return address in caller)
603 -8 IP (copy of caller's SP)
604 -12 FP (caller's FP)
605 SP -> -28 Local variables
607 The frame size would thus be 48 bytes, and the frame offset would be
608 28 bytes.
610 There is another potential complication, which is that the optimizer
611 will try to separate the store of fp in the "stmfd" instruction from
612 the "sub fp, ip, #NN" instruction. Almost anything can be there, so
613 we just key on the stmfd, and then scan for the "sub fp, ip, #NN"...
615 Also, note, the original version of the ARM toolchain claimed that there
616 should be an
618 instruction at the end of the prologue. I have never seen GCC produce
619 this, and the ARM docs don't mention it. We still test for it below in
620 case it happens...
622 */
624 static void
626 {
631 /* Assume there is no frame until proven otherwise. */
636 /* Check for Thumb prologue. */
638 {
641 }
643 /* Find the function prologue. If we can't find the function in
644 the symbol table, peek in the stack frame to find the PC. */
646 {
647 /* One way to find the end of the prologue (which works well
648 for unoptimized code) is to do the following:
650 struct symtab_and_line sal = find_pc_line (prologue_start, 0);
652 if (sal.line == 0)
653 prologue_end = prev_pc;
654 else if (sal.end < prologue_end)
655 prologue_end = sal.end;
657 This mechanism is very accurate so long as the optimizer
658 doesn't move any instructions from the function body into the
659 prologue. If this happens, sal.end will be the last
660 instruction in the first hunk of prologue code just before
661 the first instruction that the scheduler has moved from
662 the body to the prologue.
664 In order to make sure that we scan all of the prologue
665 instructions, we use a slightly less accurate mechanism which
666 may scan more than necessary. To help compensate for this
667 lack of accuracy, the prologue scanning loop below contains
668 several clauses which'll cause the loop to terminate early if
669 an implausible prologue instruction is encountered.
671 The expression
673 prologue_start + 64
675 is a suitable endpoint since it accounts for the largest
676 possible prologue plus up to five instructions inserted by
677 the scheduler. */
680 {
682 }
683 }
684 else
685 {
686 /* We have no symbol information. Our only option is to assume this
687 function has a standard stack frame and the normal frame register.
688 Then, we can find the value of our frame pointer on entrance to
689 the callee (or at the present moment if this is the innermost frame).
690 The value stored there should be the address of the stmfd + 8. */
691 CORE_ADDR frame_loc;
692 LONGEST return_value;
697 else
698 {
701 }
702 }
707 /* Now search the prologue looking for instructions that set up the
708 frame pointer, adjust the stack pointer, and save registers.
710 Be careful, however, and if it doesn't look like a prologue,
711 don't try to scan it. If, for instance, a frameless function
712 begins with stmfd sp!, then we will tell ourselves there is
713 a frame, which will confuse stack traceback, as well as "finish"
714 and other operations that rely on a knowledge of the stack
715 traceback.
717 In the APCS, the prologue should start with "mov ip, sp" so
718 if we don't see this as the first insn, we will stop.
720 [Note: This doesn't seem to be true any longer, so it's now an
721 optional part of the prologue. - Kevin Buettner, 2001-11-20]
723 [Note further: The "mov ip,sp" only seems to be missing in
724 frameless functions at optimization level "-O2" or above,
725 in which case it is often (but not always) replaced by
726 "str lr, [sp, #-4]!". - Michael Snyder, 2002-04-23] */
733 {
737 {
740 }
742 {
748 }
750 {
756 }
758 {
762 }
764 /* stmfd sp!, {..., fp, ip, lr, pc}
765 or
766 stmfd sp!, {a1, a2, a3, a4} */
767 {
770 /* Calculate offsets of saved registers. */
773 {
776 }
777 }
781 {
782 /* No need to add this to saved_regs -- it's just an arg reg. */
784 }
788 {
789 /* No need to add this to saved_regs -- it's just an arg reg. */
791 }
793 {
799 }
801 {
806 }
808 {
812 }
814 {
819 {
822 else
824 }
825 else
826 {
829 else
831 }
836 {
839 }
840 }
845 else
846 /* The optimizer might shove anything into the prologue,
847 so we just skip what we don't recognize. */
849 }
851 /* The frame size is just the negative of the offset (from the
852 original SP) of the last thing thing we pushed on the stack.
853 The frame offset is [new FP] - [new SP]. */
857 else
859 }
863 {
866 CORE_ADDR unwound_fp;
879 /* Calculate actual addresses of saved registers using offsets
880 determined by arm_scan_prologue. */
886 }
888 /* Our frame ID for a normal frame is the current function's starting PC
889 and the caller's SP when we were called. */
891 static void
895 {
898 CORE_ADDR func;
906 /* This is meant to halt the backtrace at "_start". Make sure we
907 don't halt it at a generic dummy frame. */
911 /* If we've hit a wall, stop. */
917 }
919 static void
928 {
935 /* If we are asked to unwind the PC, then we need to return the LR
936 instead. The saved value of PC points into this frame's
937 prologue, not the next frame's resume location. */
941 /* SP is generally not saved to the stack, but this frame is
942 identified by NEXT_FRAME's stack pointer at the time of the call.
943 The value was already reconstructed into PREV_SP. */
945 {
950 }
954 }
957 NORMAL_FRAME,
958 arm_prologue_this_id,
959 arm_prologue_prev_register
960 };
964 {
966 }
970 {
973 CORE_ADDR unwound_fp;
981 }
983 /* Our frame ID for a stub frame is the current SP and LR. */
985 static void
989 {
998 }
1001 NORMAL_FRAME,
1002 arm_stub_this_id,
1003 arm_prologue_prev_register
1004 };
1008 {
1016 }
1018 static CORE_ADDR
1020 {
1028 }
1032 arm_normal_frame_base,
1033 arm_normal_frame_base,
1034 arm_normal_frame_base
1035 };
1037 /* Assuming NEXT_FRAME->prev is a dummy, return the frame ID of that
1038 dummy frame. The frame ID's base needs to match the TOS value
1039 saved by save_dummy_frame_tos() and returned from
1040 arm_push_dummy_call, and the PC needs to match the dummy frame's
1041 breakpoint. */
1043 static struct frame_id
1045 {
1048 }
1050 /* Given THIS_FRAME, find the previous frame's resume PC (which will
1051 be used to construct the previous frame's ID, after looking up the
1052 containing function). */
1054 static CORE_ADDR
1056 {
1057 CORE_ADDR pc;
1060 }
1062 static CORE_ADDR
1064 {
1066 }
1068 /* When arguments must be pushed onto the stack, they go on in reverse
1069 order. The code below implements a FILO (stack) to do this. */
1071 struct stack_item
1072 {
1076 };
1080 {
1088 }
1092 {
1098 }
1101 /* Return the alignment (in bytes) of the given type. */
1103 static int
1105 {
1112 {
1114 /* Should never happen. */
1132 /* TODO: What about vector types? */
1139 {
1143 }
1145 }
1146 }
1148 /* We currently only support passing parameters in integer registers. This
1149 conforms with GCC's default model. Several other variants exist and
1150 we should probably support some of them based on the selected ABI. */
1152 static CORE_ADDR
1156 CORE_ADDR struct_addr)
1157 {
1163 /* Set the return address. For the ARM, the return breakpoint is
1164 always at BP_ADDR. */
1165 /* XXX Fix for Thumb. */
1168 /* Walk through the list of args and determine how large a temporary
1169 stack is required. Need to take care here as structs may be
1170 passed on the stack, and we have to to push them. */
1176 /* The struct_return pointer occupies the first parameter
1177 passing register. */
1179 {
1184 argreg++;
1185 }
1188 {
1203 /* Round alignment up to a whole number of words. */
1205 /* Different ABIs have different maximum alignments. */
1207 {
1208 /* The APCS ABI only requires word alignment. */
1210 }
1211 else
1212 {
1213 /* The AAPCS requires at most doubleword alignment. */
1216 }
1218 /* Push stack padding for dowubleword alignment. */
1220 {
1223 }
1225 /* Doubleword aligned quantities must go in even register pairs. */
1229 argreg++;
1231 /* If the argument is a pointer to a function, and it is a
1232 Thumb function, create a LOCAL copy of the value and set
1233 the THUMB bit in it. */
1237 {
1240 {
1243 }
1244 }
1246 /* Copy the argument to general registers or the stack in
1247 register-sized pieces. Large arguments are split between
1248 registers and stack. */
1250 {
1254 {
1255 /* The argument is being passed in a general purpose
1256 register. */
1263 argreg++;
1264 }
1265 else
1266 {
1267 /* Push the arguments onto the stack. */
1273 }
1277 }
1278 }
1279 /* If we have an odd number of words to push, then decrement the stack
1280 by one word now, so first stack argument will be dword aligned. */
1285 {
1289 }
1291 /* Finally, update teh SP register. */
1295 }
1298 /* Always align the frame to an 8-byte boundary. This is required on
1299 some platforms and harmless on the rest. */
1301 static CORE_ADDR
1303 {
1304 /* Align the stack to eight bytes. */
1306 }
1308 static void
1310 {
1322 }
1324 /* Print interesting information about the floating point processor
1325 (if present) or emulator. */
1326 static void
1329 {
1336 else
1338 /* i18n: [floating point unit] mask */
1341 /* i18n: [floating point unit] flags */
1344 }
1346 /* Return the GDB type object for the "standard" data type of data in
1347 register N. */
1351 {
1353 {
1356 else
1358 }
1359 else
1361 }
1363 /* Index within `registers' of the first byte of the space for
1364 register N. */
1366 static int
1368 {
1374 else
1378 }
1380 /* Map GDB internal REGNUM onto the Arm simulator register numbers. */
1381 static int
1383 {
1400 }
1402 /* NOTE: cagney/2001-08-20: Both convert_from_extended() and
1403 convert_to_extended() use floatformat_arm_ext_littlebyte_bigword.
1404 It is thought that this is is the floating-point register format on
1405 little-endian systems. */
1407 static void
1410 {
1411 DOUBLEST d;
1414 else
1418 }
1420 static void
1422 {
1423 DOUBLEST d;
1427 else
1430 }
1432 static int
1434 {
1439 {
1470 }
1472 }
1474 /* Support routines for single stepping. Calculate the next PC value. */
1475 #define submask(x) ((1L << ((x) + 1)) - 1)
1476 #define bit(obj,st) (((obj) >> (st)) & 1)
1477 #define bits(obj,st,fn) (((obj) >> (st)) & submask ((fn) - (st)))
1478 #define sbits(obj,st,fn) \
1479 ((long) (bits(obj,st,fn) | ((long) bit(obj,fn) * ~ submask (fn - st))))
1480 #define BranchDest(addr,instr) \
1481 ((CORE_ADDR) (((long) (addr)) + 8 + (sbits (instr, 0, 23) << 2)))
1482 #define ARM_PC_32 1
1484 static unsigned long
1487 {
1493 {
1496 }
1497 else
1506 {
1526 else
1529 }
1532 }
1534 /* Return number of 1-bits in VAL. */
1536 static int
1538 {
1543 }
1545 CORE_ADDR
1547 {
1554 {
1555 CORE_ADDR sp;
1557 /* Fetch the saved PC from the stack. It's stored above
1558 all of the other registers. */
1565 }
1567 {
1572 }
1574 {
1576 }
1578 {
1582 /* For BLX make sure to clear the low bits. */
1585 }
1587 {
1590 else
1596 }
1599 }
1601 CORE_ADDR
1603 {
1607 CORE_ADDR nextpc;
1618 {
1620 {
1625 {
1637 /* BX <reg>, BLX <reg> */
1640 {
1649 }
1651 /* Multiply into PC */
1657 {
1662 }
1667 {
1712 /* Always step into a function. */
1723 }
1729 }
1736 {
1737 /* load */
1739 {
1740 /* rd == pc */
1747 /* byte write to PC */
1751 {
1752 /* pre-indexed */
1761 else
1763 }
1771 }
1772 }
1778 {
1779 /* LDM */
1781 {
1782 /* loading pc */
1786 {
1787 /* up */
1792 }
1796 {
1799 nextpc =
1803 }
1807 }
1808 }
1813 {
1816 /* BLX */
1824 }
1835 }
1836 }
1839 }
1841 /* single_step() is called just before we want to resume the inferior,
1842 if we want to single-step it but there is no hardware or kernel
1843 single-step support. We find the target of the coming instruction
1844 and breakpoint it.
1846 single_step() is also called just after the inferior stops. If we
1847 had set up a simulated single-step, we undo our damage. */
1849 static void
1851 {
1852 /* NOTE: This may insert the wrong breakpoint instruction when
1853 single-stepping over a mode-changing instruction, if the
1854 CPSR heuristics are used. */
1857 {
1861 }
1862 else
1864 }
1869 static int
1871 {
1873 {
1881 {
1882 /* Create a fake symbol vector containing a Thumb symbol.
1883 This is solely so that the code in print_insn_little_arm()
1884 and print_insn_big_arm() in opcodes/arm-dis.c will detect
1885 the presence of a Thumb symbol and switch to decoding
1886 Thumb instructions. */
1895 }
1899 }
1900 else
1905 else
1907 }
1909 /* The following define instruction sequences that will cause ARM
1910 cpu's to take an undefined instruction trap. These are used to
1911 signal a breakpoint to GDB.
1913 The newer ARMv4T cpu's are capable of operating in ARM or Thumb
1914 modes. A different instruction is required for each mode. The ARM
1915 cpu's can also be big or little endian. Thus four different
1916 instructions are needed to support all cases.
1918 Note: ARMv4 defines several new instructions that will take the
1919 undefined instruction trap. ARM7TDMI is nominally ARMv4T, but does
1920 not in fact add the new instructions. The new undefined
1921 instructions in ARMv4 are all instructions that had no defined
1922 behaviour in earlier chips. There is no guarantee that they will
1923 raise an exception, but may be treated as NOP's. In practice, it
1924 may only safe to rely on instructions matching:
1926 3 3 2 2 2 2 2 2 2 2 2 2 1 1 1 1 1 1 1 1 1 1
1927 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
1928 C C C C 0 1 1 x x x x x x x x x x x x x x x x x x x x 1 x x x x
1930 Even this may only true if the condition predicate is true. The
1931 following use a condition predicate of ALWAYS so it is always TRUE.
1933 There are other ways of forcing a breakpoint. GNU/Linux, RISC iX,
1934 and NetBSD all use a software interrupt rather than an undefined
1935 instruction to force a trap. This can be handled by by the
1936 abi-specific code during establishment of the gdbarch vector. */
1939 /* NOTE rearnsha 2002-02-18: for now we allow a non-multi-arch gdb to
1940 override these definitions. */
1941 #ifndef ARM_LE_BREAKPOINT
1942 #define ARM_LE_BREAKPOINT {0xFE,0xDE,0xFF,0xE7}
1943 #endif
1944 #ifndef ARM_BE_BREAKPOINT
1945 #define ARM_BE_BREAKPOINT {0xE7,0xFF,0xDE,0xFE}
1946 #endif
1947 #ifndef THUMB_LE_BREAKPOINT
1948 #define THUMB_LE_BREAKPOINT {0xfe,0xdf}
1949 #endif
1950 #ifndef THUMB_BE_BREAKPOINT
1951 #define THUMB_BE_BREAKPOINT {0xdf,0xfe}
1952 #endif
1959 /* Determine the type and size of breakpoint to insert at PCPTR. Uses
1960 the program counter value to determine whether a 16-bit or 32-bit
1961 breakpoint should be used. It returns a pointer to a string of
1962 bytes that encode a breakpoint instruction, stores the length of
1963 the string to *lenptr, and adjusts the program counter (if
1964 necessary) to point to the actual memory location where the
1965 breakpoint should be inserted. */
1967 /* XXX ??? from old tm-arm.h: if we're using RDP, then we're inserting
1968 breakpoints and storing their handles instread of what was in
1969 memory. It is nice that this is the same size as a handle -
1970 otherwise remote-rdp will have to change. */
1974 {
1978 {
1982 }
1983 else
1984 {
1987 }
1988 }
1990 /* Extract from an array REGBUF containing the (raw) register state a
1991 function return value of type TYPE, and copy that, in virtual
1992 format, into VALBUF. */
1994 static void
1997 {
1999 {
2001 {
2003 {
2004 /* The value is in register F0 in internal format. We need to
2005 extract the raw value and then convert it to the desired
2006 internal type. */
2011 valbuf);
2012 }
2024 internal_error
2028 }
2029 }
2036 {
2037 /* If the the type is a plain integer, then the access is
2038 straight-forward. Otherwise we have to play around a bit more. */
2041 ULONGEST tmp;
2044 {
2045 /* By using store_unsigned_integer we avoid having to do
2046 anything special for small big-endian values. */
2051 tmp);
2054 }
2055 }
2056 else
2057 {
2058 /* For a structure or union the behaviour is as if the value had
2059 been stored to word-aligned memory and then loaded into
2060 registers with 32-bit load instruction(s). */
2066 {
2072 }
2073 }
2074 }
2077 /* Will a function return an aggregate type in memory or in a
2078 register? Return 0 if an aggregate type can be returned in a
2079 register, 1 if it must be returned in memory. */
2081 static int
2083 {
2089 /* In the ARM ABI, "integer" like aggregate types are returned in
2090 registers. For an aggregate type to be integer like, its size
2091 must be less than or equal to DEPRECATED_REGISTER_SIZE and the
2092 offset of each addressable subfield must be zero. Note that bit
2093 fields are not addressable, and all addressable subfields of
2094 unions always start at offset zero.
2096 This function is based on the behaviour of GCC 2.95.1.
2097 See: gcc/arm.c: arm_return_in_memory() for details.
2099 Note: All versions of GCC before GCC 2.95.2 do not set up the
2100 parameters correctly for a function returning the following
2101 structure: struct { float f;}; This should be returned in memory,
2102 not a register. Richard Earnshaw sent me a patch, but I do not
2103 know of any way to detect if a function like the above has been
2104 compiled with the correct calling convention. */
2106 /* All aggregate types that won't fit in a register must be returned
2107 in memory. */
2109 {
2111 }
2113 /* The AAPCS says all aggregates not larger than a word are returned
2114 in a register. */
2118 /* The only aggregate types that can be returned in a register are
2119 structs and unions. Arrays must be returned in memory. */
2122 {
2124 }
2126 /* Assume all other aggregate types can be returned in a register.
2127 Run a check for structures, unions and arrays. */
2131 {
2133 /* Need to check if this struct/union is "integer" like. For
2134 this to be true, its size must be less than or equal to
2135 DEPRECATED_REGISTER_SIZE and the offset of each addressable
2136 subfield must be zero. Note that bit fields are not
2137 addressable, and unions always start at offset zero. If any
2138 of the subfields is a floating point type, the struct/union
2139 cannot be an integer type. */
2141 /* For each field in the object, check:
2142 1) Is it FP? --> yes, nRc = 1;
2143 2) Is it addressable (bitpos != 0) and
2144 not packed (bitsize == 0)?
2145 --> yes, nRc = 1
2146 */
2149 {
2153 /* Is it a floating point type field? */
2155 {
2158 }
2160 /* If bitpos != 0, then we have to care about it. */
2162 {
2163 /* Bitfields are not addressable. If the field bitsize is
2164 zero, then the field is not packed. Hence it cannot be
2165 a bitfield or any other packed type. */
2167 {
2170 }
2171 }
2172 }
2173 }
2176 }
2178 /* Write into appropriate registers a function return value of type
2179 TYPE, given in virtual format. */
2181 static void
2184 {
2186 {
2190 {
2206 internal_error
2210 }
2211 }
2218 {
2220 {
2221 /* Values of one word or less are zero/sign-extended and
2222 returned in r0. */
2228 }
2229 else
2230 {
2231 /* Integral values greater than one word are stored in consecutive
2232 registers starting with r0. This will always be a multiple of
2233 the regiser size. */
2238 {
2242 }
2243 }
2244 }
2245 else
2246 {
2247 /* For a structure or union the behaviour is as if the value had
2248 been stored to word-aligned memory and then loaded into
2249 registers with 32-bit load instruction(s). */
2255 {
2261 }
2262 }
2263 }
2266 /* Handle function return values. */
2268 static enum return_value_convention
2272 {
2276 {
2279 }
2288 }
2291 static int
2293 {
2294 CORE_ADDR jb_addr;
2301 INT_REGISTER_SIZE))
2306 }
2308 /* Return non-zero if the PC is inside a thumb call thunk. */
2310 int
2312 {
2313 CORE_ADDR start_addr;
2315 /* Find the starting address of the function containing the PC. If
2316 the caller didn't give us a name, look it up at the same time. */
2322 }
2324 /* If PC is in a Thumb call or return stub, return the address of the
2325 target PC, which is in a register. The thunk functions are called
2326 _called_via_xx, where x is the register name. The possible names
2327 are r0-r9, sl, fp, ip, sp, and lr. */
2329 CORE_ADDR
2331 {
2333 CORE_ADDR start_addr;
2335 /* Find the starting address and name of the function containing the PC. */
2339 /* Call thunks always start with "_call_via_". */
2341 {
2342 /* Use the name suffix to determine which register contains the
2343 target PC. */
2347 };
2353 }
2356 }
2358 static void
2360 {
2364 }
2366 static void
2368 {
2370 }
2372 static void
2374 {
2377 /* If the current architecture is not ARM, we have nothing to do. */
2381 /* Update the architecture. */
2386 }
2388 static void
2391 {
2396 {
2399 }
2403 current_fp_model);
2406 }
2408 static void
2411 {
2419 else
2423 }
2425 static void
2428 {
2433 {
2436 }
2440 arm_abi_string);
2443 }
2445 static void
2448 {
2456 else
2458 arm_abi_string);
2459 }
2461 /* If the user changes the register disassembly style used for info
2462 register and other commands, we have to also switch the style used
2463 in opcodes for disassembly output. This function is run in the "set
2464 arm disassembly" command, and does that. */
2466 static void
2469 {
2471 }
2472 \f
2473 /* Return the ARM register name corresponding to register I. */
2476 {
2478 }
2480 static void
2482 {
2486 /* Find the style that the user wants in the opcodes table. */
2494 /* Fill our copy. */
2498 /* Adjust case. */
2500 {
2503 }
2504 else
2505 {
2508 }
2510 /* Synchronize the disassembler. */
2512 }
2514 /* Test whether the coff symbol specific value corresponds to a Thumb
2515 function. */
2517 static int
2519 {
2525 }
2527 /* arm_coff_make_msymbol_special()
2528 arm_elf_make_msymbol_special()
2530 These functions test whether the COFF or ELF symbol corresponds to
2531 an address in thumb code, and set a "special" bit in a minimal
2532 symbol to indicate that it does. */
2534 static void
2536 {
2537 /* Thumb symbols are of type STT_LOPROC, (synonymous with
2538 STT_ARM_TFUNC). */
2542 }
2544 static void
2546 {
2549 }
2551 static void
2553 {
2556 /* If necessary, set the T bit. */
2558 {
2562 else
2564 }
2565 }
2566 \f
2567 static enum gdb_osabi
2569 {
2576 /* GNU tools use this value. Check note sections in this case,
2577 as well. */
2579 generic_elf_osabi_sniff_abi_tag_sections,
2582 /* Anything else will be handled by the generic ELF sniffer. */
2584 }
2586 \f
2587 /* Initialize the current architecture based on INFO. If possible,
2588 re-use an architecture from ARCHES, which is a list of
2589 architectures already created during this debugging session.
2591 Called e.g. at program startup, when reading a core file, and when
2592 reading a binary file. */
2596 {
2603 /* If we have an object to base this architecture on, try to determine
2604 its ABI. */
2607 {
2611 {
2613 /* Assume it's an old APCS-style ABI. */
2618 /* Assume it's an old APCS-style ABI. */
2619 /* XXX WinCE? */
2626 {
2627 /* GNU tools used to use this value, but do not for EABI
2628 objects. There's nowhere to tag an EABI version anyway,
2629 so assume APCS. */
2631 }
2633 {
2640 {
2642 /* Assume GNU tools. */
2648 /* EABI binaries default to VFP float ordering. */
2657 }
2658 }
2662 /* Leave it as "auto". */
2664 }
2665 }
2667 /* Now that we have inferred any architecture settings that we
2668 can, try to inherit from the last ARM ABI. */
2670 {
2676 }
2677 else
2678 {
2679 /* There was no prior ARM architecture; fill in default values. */
2684 /* We used to default to FPA for generic ARM, but almost nobody
2685 uses that now, and we now provide a way for the user to force
2686 the model. So default to the most useful variant. */
2689 }
2691 /* If there is already a candidate, use it. */
2695 {
2702 /* Found a match. */
2704 }
2712 /* Record additional information about the architecture we are defining.
2713 These are gdbarch discriminators, like the OSABI. */
2717 /* Breakpoints. */
2719 {
2739 }
2741 /* On ARM targets char defaults to unsigned. */
2744 /* This should be low enough for everything. */
2753 /* Frame handling. */
2760 /* Address manipulation. */
2764 /* Advance PC across function entry code. */
2767 /* Get the PC when a frame might not be available. */
2770 /* The stack grows downward. */
2773 /* Breakpoint manipulation. */
2776 /* Information about registers, etc. */
2785 /* Internal <-> external register number maps. */
2788 /* Integer registers are 4 bytes. */
2792 /* Returning results. */
2795 /* Single stepping. */
2796 /* XXX For an RDI target we should ask the target if it can single-step. */
2799 /* Disassembly. */
2802 /* Minsymbol frobbing. */
2805 arm_coff_make_msymbol_special);
2807 /* Hook in the ABI-specific overrides, if they have been registered. */
2810 /* Add some default predicates. */
2815 /* Now we have tuned the configuration, set a few final things,
2816 based on what the OS ABI has told us. */
2821 /* Floating point sizes and format. */
2823 {
2833 {
2834 set_gdbarch_double_format
2836 set_gdbarch_long_double_format
2838 }
2839 else
2840 {
2844 }
2850 }
2853 }
2855 static void
2857 {
2865 }
2869 void
2871 {
2885 /* Register an ELF OS ABI sniffer for ARM binaries. */
2887 bfd_target_elf_flavour,
2888 arm_elf_osabi_sniffer);
2890 /* Get the number of possible sets of register names defined in opcodes. */
2893 /* Add root prefix command for all "set arm"/"show arm" commands. */
2902 /* Sync the opcode insn printer with our register viewer. */
2905 /* Initialize the array that will be passed to
2906 add_setshow_enum_cmd(). */
2907 valid_disassembly_styles
2910 {
2916 /* Copy the default names (if found) and synchronize disassembler. */
2918 {
2924 }
2925 }
2926 /* Mark the end of valid options. */
2929 /* Create the help text. */
2933 regdesc,
2942 helptext,
2943 set_disassembly_style_sfunc,
2951 NULL,
2955 /* Add a command to allow the user to force the FPU model. */
2967 /* Add a command to allow the user to force the ABI. */
2974 /* Debugging flag. */
2979 NULL,
2982 }