| blob | 5e63b5e674d763f4f9975745913e71ce06d44831 |
1 /* Target-dependent code for AMD64.
3 Copyright (C) 2001-2015 Free Software Foundation, Inc.
5 Contributed by Jiri Smid, SuSE Labs.
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 3 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, see <http://www.gnu.org/licenses/>. */
56 /* Note that the AMD64 architecture was previously known as x86-64.
57 The latter is (forever) engraved into the canonical system name as
58 returned by config.guess, and used as the name for the AMD64 port
59 of GNU/Linux. The BSD's have renamed their ports to amd64; they
60 don't like to shout. For GDB we prefer the amd64_-prefix over the
61 x86_64_-prefix since it's so much easier to type. */
63 /* Register information. */
66 {
69 /* %r8 is indeed register number 8. */
73 /* %st0 is register number 24. */
77 /* %xmm0 is register number 40. */
81 };
84 {
89 };
92 {
97 };
100 {
105 };
108 {
113 };
116 {
118 };
121 {
124 };
127 {
136 };
139 {
148 };
155 };
157 /* DWARF Register Number Mapping as defined in the System V psABI,
158 section 3.6. */
161 {
162 /* General Purpose Registers RAX, RDX, RCX, RBX, RSI, RDI. */
167 /* Frame Pointer Register RBP. */
168 AMD64_RBP_REGNUM,
170 /* Stack Pointer Register RSP. */
171 AMD64_RSP_REGNUM,
173 /* Extended Integer Registers 8 - 15. */
183 /* Return Address RA. Mapped to RIP. */
184 AMD64_RIP_REGNUM,
186 /* SSE Registers 0 - 7. */
192 /* Extended SSE Registers 8 - 15. */
198 /* Floating Point Registers 0-7. */
204 /* MMX Registers 0 - 7.
205 We have to handle those registers specifically, as their register
206 number within GDB depends on the target (or they may even not be
207 available at all). */
210 /* Control and Status Flags Register. */
211 AMD64_EFLAGS_REGNUM,
213 /* Selector Registers. */
214 AMD64_ES_REGNUM,
215 AMD64_CS_REGNUM,
216 AMD64_SS_REGNUM,
217 AMD64_DS_REGNUM,
218 AMD64_FS_REGNUM,
219 AMD64_GS_REGNUM,
223 /* Segment Base Address Registers. */
229 /* Special Selector Registers. */
233 /* Floating Point Control Registers. */
234 AMD64_MXCSR_REGNUM,
235 AMD64_FCTRL_REGNUM,
236 AMD64_FSTAT_REGNUM
237 };
242 /* Convert DWARF register number REG to the appropriate register
243 number used by GDB. */
245 static int
247 {
262 }
264 /* Map architectural register numbers to gdb register numbers. */
267 {
283 AMD64_R15_REGNUM /* %r15 */
284 };
289 /* Convert architectural register number REG to the appropriate register
290 number used by GDB. */
292 static int
294 {
298 }
300 /* Register names for byte pseudo-registers. */
303 {
307 };
309 /* Number of lower byte registers. */
310 #define AMD64_NUM_LOWER_BYTE_REGS 16
312 /* Register names for word pseudo-registers. */
315 {
318 };
320 /* Register names for dword pseudo-registers. */
323 {
326 "eip"
327 };
329 /* Return the name of register REGNUM. */
333 {
347 else
349 }
355 {
368 {
371 /* Extract (always little endian). */
373 {
374 /* Special handling for AH, BH, CH, DH. */
377 raw_buf);
380 else
383 }
384 else
385 {
389 else
392 }
393 }
395 {
397 /* Extract (always little endian). */
401 else
404 }
405 else
407 result_value);
410 }
412 static void
416 {
421 {
425 {
426 /* Read ... AH, BH, CH, DH. */
429 /* ... Modify ... (always little endian). */
431 /* ... Write. */
434 }
435 else
436 {
437 /* Read ... */
439 /* ... Modify ... (always little endian). */
441 /* ... Write. */
443 }
444 }
446 {
449 /* Read ... */
451 /* ... Modify ... (always little endian). */
453 /* ... Write. */
455 }
456 else
458 }
460 \f
462 /* Register classes as defined in the psABI. */
464 enum amd64_reg_class
465 {
466 AMD64_INTEGER,
467 AMD64_SSE,
468 AMD64_SSEUP,
469 AMD64_X87,
470 AMD64_X87UP,
471 AMD64_COMPLEX_X87,
472 AMD64_NO_CLASS,
473 AMD64_MEMORY
474 };
476 /* Return the union class of CLASS1 and CLASS2. See the psABI for
477 details. */
479 static enum amd64_reg_class
481 {
482 /* Rule (a): If both classes are equal, this is the resulting class. */
486 /* Rule (b): If one of the classes is NO_CLASS, the resulting class
487 is the other class. */
493 /* Rule (c): If one of the classes is MEMORY, the result is MEMORY. */
497 /* Rule (d): If one of the classes is INTEGER, the result is INTEGER. */
501 /* Rule (e): If one of the classes is X87, X87UP, COMPLEX_X87 class,
502 MEMORY is used as class. */
508 /* Rule (f): Otherwise class SSE is used. */
510 }
514 /* Return non-zero if TYPE is a non-POD structure or union type. */
516 static int
518 {
519 /* ??? A class with a base class certainly isn't POD, but does this
520 catch all non-POD structure types? */
525 }
527 /* Classify TYPE according to the rules for aggregate (structures and
528 arrays) and union types, and store the result in CLASS. */
530 static void
532 {
533 /* 1. If the size of an object is larger than two eightbytes, or in
534 C++, is a non-POD structure or union type, or contains
535 unaligned fields, it has class memory. */
537 {
540 }
542 /* 2. Both eightbytes get initialized to class NO_CLASS. */
545 /* 3. Each field of an object is classified recursively so that
546 always two fields are considered. The resulting class is
547 calculated according to the classes of the fields in the
548 eightbyte: */
551 {
554 /* All fields in an array have the same type. */
558 }
559 else
560 {
563 /* Structure or union. */
568 {
579 /* Ignore static fields. */
588 /* This is a bit of an odd case: We have a field that would
589 normally fit in one of the two eightbytes, except that
590 it is placed in a way that this field straddles them.
591 This has been seen with a structure containing an array.
593 The ABI is a bit unclear in this case, but we assume that
594 this field's class (stored in subclass[0]) must also be merged
595 into class[1]. In other words, our field has a piece stored
596 in the second eight-byte, and thus its class applies to
597 the second eight-byte as well.
599 In the case where the field length exceeds 8 bytes,
600 it should not be necessary to merge the field class
601 into class[1]. As LEN > 8, subclass[1] is necessarily
602 different from AMD64_NO_CLASS. If subclass[1] is equal
603 to subclass[0], then the normal class[1]/subclass[1]
604 merging will take care of everything. For subclass[1]
605 to be different from subclass[0], I can only see the case
606 where we have a SSE/SSEUP or X87/X87UP pair, which both
607 use up all 16 bytes of the aggregate, and are already
608 handled just fine (because each portion sits on its own
609 8-byte). */
613 }
614 }
616 /* 4. Then a post merger cleanup is done: */
618 /* Rule (a): If one of the classes is MEMORY, the whole argument is
619 passed in memory. */
623 /* Rule (b): If SSEUP is not preceded by SSE, it is converted to
624 SSE. */
629 }
631 /* Classify TYPE, and store the result in CLASS. */
633 static void
635 {
641 /* Arguments of types (signed and unsigned) _Bool, char, short, int,
642 long, long long, and pointers are in the INTEGER class. Similarly,
643 range types, used by languages such as Ada, are also in the INTEGER
644 class. */
652 /* Arguments of types float, double, _Decimal32, _Decimal64 and __m64
653 are in class SSE. */
656 /* FIXME: __m64 . */
659 /* Arguments of types __float128, _Decimal128 and __m128 are split into
660 two halves. The least significant ones belong to class SSE, the most
661 significant one to class SSEUP. */
663 /* FIXME: __float128, __m128. */
666 /* The 64-bit mantissa of arguments of type long double belongs to
667 class X87, the 16-bit exponent plus 6 bytes of padding belongs to
668 class X87UP. */
670 /* Class X87 and X87UP. */
673 /* Arguments of complex T where T is one of the types float or
674 double get treated as if they are implemented as:
676 struct complexT {
677 T real;
678 T imag;
679 };
681 */
687 /* A variable of type complex long double is classified as type
688 COMPLEX_X87. */
692 /* Aggregates. */
696 }
698 static enum return_value_convention
702 {
713 /* 1. Classify the return type with the classification algorithm. */
716 /* 2. If the type has class MEMORY, then the caller provides space
717 for the return value and passes the address of this storage in
718 %rdi as if it were the first argument to the function. In effect,
719 this address becomes a hidden first argument.
721 On return %rax will contain the address that has been passed in
722 by the caller in %rdi. */
724 {
725 /* As indicated by the comment above, the ABI guarantees that we
726 can always find the return value just after the function has
727 returned. */
730 {
731 ULONGEST addr;
735 }
738 }
740 /* 8. If the class is COMPLEX_X87, the real part of the value is
741 returned in %st0 and the imaginary part in %st1. */
743 {
745 {
748 }
751 {
756 /* Fix up the tag word such that both %st(0) and %st(1) are
757 marked as valid. */
759 }
762 }
768 {
773 {
775 /* 3. If the class is INTEGER, the next available register
776 of the sequence %rax, %rdx is used. */
781 /* 4. If the class is SSE, the next available SSE register
782 of the sequence %xmm0, %xmm1 is used. */
787 /* 5. If the class is SSEUP, the eightbyte is passed in the
788 upper half of the last used SSE register. */
795 /* 6. If the class is X87, the value is returned on the X87
796 stack in %st0 as 80-bit x87 number. */
803 /* 7. If the class is X87UP, the value is returned together
804 with the previous X87 value in %st0. */
816 }
826 }
829 }
830 \f
832 static CORE_ADDR
835 {
837 {
843 AMD64_R9_REGNUM /* %r9 */
844 };
846 {
847 /* %xmm0 ... %xmm7 */
852 };
861 /* Reserve a register for the "hidden" argument. */
863 integer_reg++;
866 {
874 /* Classify argument. */
877 /* Calculate the number of integer and SSE registers needed for
878 this argument. */
880 {
882 needed_integer_regs++;
884 needed_sse_regs++;
885 }
887 /* Check whether enough registers are available, and if the
888 argument should be passed in registers at all. */
892 {
893 /* The argument will be passed on the stack. */
896 }
897 else
898 {
899 /* The argument will be passed in registers. */
906 {
911 {
928 }
934 }
935 }
936 }
938 /* Allocate space for the arguments on the stack. */
941 /* The psABI says that "The end of the input argument area shall be
942 aligned on a 16 byte boundary." */
945 /* Write out the arguments to the stack. */
947 {
954 }
956 /* The psABI says that "For calls that may call functions that use
957 varargs or stdargs (prototype-less calls or calls to functions
958 containing ellipsis (...) in the declaration) %al is used as
959 hidden argument to specify the number of SSE registers used. */
962 }
964 static CORE_ADDR
969 {
973 /* Pass arguments. */
976 /* Pass "hidden" argument". */
978 {
981 }
983 /* Store return address. */
988 /* Finally, update the stack pointer... */
992 /* ...and fake a frame pointer. */
996 }
997 \f
998 /* Displaced instruction handling. */
1000 /* A partially decoded instruction.
1001 This contains enough details for displaced stepping purposes. */
1003 struct amd64_insn
1004 {
1005 /* The number of opcode bytes. */
1007 /* The offset of the rex prefix or -1 if not present. */
1009 /* The offset to the first opcode byte. */
1011 /* The offset to the modrm byte or -1 if not present. */
1014 /* The raw instruction. */
1016 };
1018 struct displaced_step_closure
1019 {
1020 /* For rip-relative insns, saved copy of the reg we use instead of %rip. */
1023 ULONGEST tmp_save;
1025 /* Details of the instruction. */
1028 /* Amount of space allocated to insn_buf. */
1031 /* The possibly modified insn.
1032 This is a variable-length field. */
1034 };
1036 /* WARNING: Keep onebyte_has_modrm, twobyte_has_modrm in sync with
1037 ../opcodes/i386-dis.c (until libopcodes exports them, or an alternative,
1038 at which point delete these in favor of libopcodes' versions). */
1041 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
1042 /* ------------------------------- */
1059 /* ------------------------------- */
1060 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
1061 };
1064 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
1065 /* ------------------------------- */
1082 /* ------------------------------- */
1083 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
1084 };
1088 static int
1090 {
1092 }
1094 /* Skip the legacy instruction prefixes in INSN.
1095 We assume INSN is properly sentineled so we don't have to worry
1096 about falling off the end of the buffer. */
1100 {
1102 {
1104 {
1120 }
1122 }
1125 }
1127 /* Return an integer register (other than RSP) that is unused as an input
1128 operand in INSN.
1129 In order to not require adding a rex prefix if the insn doesn't already
1130 have one, the result is restricted to RAX ... RDI, sans RSP.
1131 The register numbering of the result follows architecture ordering,
1132 e.g. RDI = 7. */
1134 static int
1136 {
1137 /* 1 bit for each reg */
1140 /* There can be at most 3 int regs used as inputs in an insn, and we have
1141 7 to choose from (RAX ... RDI, sans RSP).
1142 This allows us to take a conservative approach and keep things simple.
1143 E.g. By avoiding RAX, we don't have to specifically watch for opcodes
1144 that implicitly specify RAX. */
1146 /* Avoid RAX. */
1148 /* Similarily avoid RDX, implicit operand in divides. */
1150 /* Avoid RSP. */
1153 /* If the opcode is one byte long and there's no ModRM byte,
1154 assume the opcode specifies a register. */
1158 /* Mark used regs in the modrm/sib bytes. */
1160 {
1167 /* Assume the reg field of the modrm byte specifies a register. */
1171 {
1176 }
1177 else
1178 {
1180 }
1181 }
1186 /* Finally, find a free reg. */
1187 {
1191 {
1194 }
1196 /* We shouldn't get here. */
1198 }
1199 }
1201 /* Extract the details of INSN that we need. */
1203 static void
1205 {
1216 /* Skip legacy instruction prefixes. */
1219 /* Skip REX instruction prefix. */
1221 {
1224 }
1229 {
1230 /* Two or three-byte opcode. */
1234 /* Check for three-byte opcode. */
1236 {
1249 }
1250 }
1251 else
1252 {
1253 /* One-byte opcode. */
1256 }
1259 {
1262 }
1263 }
1265 /* Update %rip-relative addressing in INSN.
1267 %rip-relative addressing only uses a 32-bit displacement.
1268 32 bits is not enough to be guaranteed to cover the distance between where
1269 the real instruction is and where its copy is.
1270 Convert the insn to use base+disp addressing.
1271 We set base = pc + insn_length so we can leave disp unchanged. */
1273 static void
1276 {
1281 CORE_ADDR rip_base;
1285 ULONGEST orig_value;
1287 /* %rip+disp32 addressing mode, displacement follows ModRM byte. */
1290 /* Compute the rip-relative address. */
1296 /* We need a register to hold the address.
1297 Pick one not used in the insn.
1298 NOTE: arch_tmp_regno uses architecture ordering, e.g. RDI = 7. */
1302 /* REX.B should be unset as we were using rip-relative addressing,
1303 but ensure it's unset anyway, tmp_regno is not r8-r15. */
1312 /* Convert the ModRM field to be base+disp. */
1323 }
1325 static void
1329 {
1333 {
1337 {
1338 /* The insn uses rip-relative addressing.
1339 Deal with it. */
1341 }
1342 }
1343 }
1349 {
1351 /* Extra space for sentinels so fixup_{riprel,displaced_copy} don't have to
1352 continually watch for running off the end of the buffer. */
1364 /* Set up the sentinel space so we don't have to worry about running
1365 off the end of the buffer. An excessive number of leading prefixes
1366 could otherwise cause this. */
1371 /* GDB may get control back after the insn after the syscall.
1372 Presumably this is a kernel bug.
1373 If this is a syscall, make sure there's a nop afterwards. */
1374 {
1379 }
1381 /* Modify the insn to cope with the address where it will be executed from.
1382 In particular, handle any rip-relative addressing. */
1388 {
1392 }
1395 }
1397 static int
1399 {
1403 {
1404 /* jump near, absolute indirect (/4) */
1408 /* jump far, absolute indirect (/5) */
1411 }
1414 }
1416 /* Return non-zero if the instruction DETAILS is a jump, zero otherwise. */
1418 static int
1420 {
1423 /* jump short, relative. */
1427 /* jump near, relative. */
1432 }
1434 static int
1436 {
1440 {
1441 /* Call near, absolute indirect (/2) */
1445 /* Call far, absolute indirect (/3) */
1448 }
1451 }
1453 static int
1455 {
1456 /* NOTE: gcc can emit "repz ; ret". */
1460 {
1470 }
1471 }
1473 static int
1475 {
1481 /* call near, relative */
1486 }
1488 /* Return non-zero if INSN is a system call, and set *LENGTHP to its
1489 length in bytes. Otherwise, return zero. */
1491 static int
1493 {
1497 {
1500 }
1503 }
1505 /* Classify the instruction at ADDR using PRED.
1506 Throw an error if the memory can't be read. */
1508 static int
1511 {
1525 }
1527 /* The gdbarch insn_is_call method. */
1529 static int
1531 {
1533 }
1535 /* The gdbarch insn_is_ret method. */
1537 static int
1539 {
1541 }
1543 /* The gdbarch insn_is_jump method. */
1545 static int
1547 {
1549 }
1551 /* Fix up the state of registers and memory after having single-stepped
1552 a displaced instruction. */
1554 void
1559 {
1561 /* The offset we applied to the instruction's address. */
1568 "displaced: fixup (%s, %s), "
1573 /* If we used a tmp reg, restore it. */
1576 {
1581 }
1583 /* The list of issues to contend with here is taken from
1584 resume_execution in arch/x86/kernel/kprobes.c, Linux 2.6.28.
1585 Yay for Free Software! */
1587 /* Relocate the %rip back to the program's instruction stream,
1588 if necessary. */
1590 /* Except in the case of absolute or indirect jump or call
1591 instructions, or a return instruction, the new rip is relative to
1592 the displaced instruction; make it relative to the original insn.
1593 Well, signal handler returns don't need relocation either, but we use the
1594 value of %rip to recognize those; see below. */
1598 {
1599 ULONGEST orig_rip;
1604 /* A signal trampoline system call changes the %rip, resuming
1605 execution of the main program after the signal handler has
1606 returned. That makes them like 'return' instructions; we
1607 shouldn't relocate %rip.
1609 But most system calls don't, and we do need to relocate %rip.
1611 Our heuristic for distinguishing these cases: if stepping
1612 over the system call instruction left control directly after
1613 the instruction, the we relocate --- control almost certainly
1614 doesn't belong in the displaced copy. Otherwise, we assume
1615 the instruction has put control where it belongs, and leave
1616 it unrelocated. Goodness help us if there are PC-relative
1617 system calls. */
1620 /* GDB can get control back after the insn after the syscall.
1621 Presumably this is a kernel bug.
1622 Fixup ensures its a nop, we add one to the length for it. */
1624 {
1627 "displaced: syscall changed %%rip; "
1629 }
1630 else
1631 {
1634 /* If we just stepped over a breakpoint insn, we don't backup
1635 the pc on purpose; this is to match behaviour without
1636 stepping. */
1642 "displaced: "
1646 }
1647 }
1649 /* If the instruction was PUSHFL, then the TF bit will be set in the
1650 pushed value, and should be cleared. We'll leave this for later,
1651 since GDB already messes up the TF flag when stepping over a
1652 pushfl. */
1654 /* If the instruction was a call, the return address now atop the
1655 stack is the address following the copied instruction. We need
1656 to make it the address following the original instruction. */
1658 {
1659 ULONGEST rsp;
1660 ULONGEST retaddr;
1670 "displaced: relocated return addr at %s "
1674 }
1675 }
1677 /* If the instruction INSN uses RIP-relative addressing, return the
1678 offset into the raw INSN where the displacement to be adjusted is
1679 found. Returns 0 if the instruction doesn't use RIP-relative
1680 addressing. */
1682 static int
1684 {
1686 {
1690 {
1691 /* The displacement is found right after the ModRM byte. */
1693 }
1694 }
1697 }
1699 static void
1701 {
1704 }
1706 static void
1709 {
1712 /* Extra space for sentinels. */
1723 /* Set up the sentinel space so we don't have to worry about running
1724 off the end of the buffer. An excessive number of leading prefixes
1725 could otherwise cause this. */
1733 /* Skip legacy instruction prefixes. */
1736 /* Adjust calls with 32-bit relative addresses as push/jump, with
1737 the address pushed being the location where the original call in
1738 the user program would return to. */
1740 {
1744 /* Where "ret" in the original code will return to. */
1748 /* Push the push. */
1751 /* Convert the relative call to a relative jump. */
1754 /* Adjust the destination offset. */
1761 "Adjusted insn rel32=%s at %s to"
1766 /* Write the adjusted jump into its displaced location. */
1769 }
1773 {
1774 /* Adjust jumps with 32-bit relative addresses. Calls are
1775 already handled above. */
1778 /* Adjust conditional jumps. */
1781 }
1784 {
1790 "Adjusted insn rel32=%s at %s to"
1794 }
1796 /* Write the adjusted instruction into its displaced location. */
1798 }
1800 \f
1801 /* The maximum number of saved registers. This should include %rip. */
1802 #define AMD64_NUM_SAVED_REGS AMD64_NUM_GREGS
1804 struct amd64_frame_cache
1805 {
1806 /* Base address. */
1807 CORE_ADDR base;
1809 CORE_ADDR sp_offset;
1810 CORE_ADDR pc;
1812 /* Saved registers. */
1814 CORE_ADDR saved_sp;
1817 /* Do we have a frame? */
1819 };
1821 /* Initialize a frame cache. */
1823 static void
1825 {
1828 /* Base address. */
1834 /* Saved registers. We initialize these to -1 since zero is a valid
1835 offset (that's where %rbp is supposed to be stored).
1836 The values start out as being offsets, and are later converted to
1837 addresses (at which point -1 is interpreted as an address, still meaning
1838 "invalid"). */
1844 /* Frameless until proven otherwise. */
1846 }
1848 /* Allocate and initialize a frame cache. */
1852 {
1858 }
1860 /* GCC 4.4 and later, can put code in the prologue to realign the
1861 stack pointer. Check whether PC points to such code, and update
1862 CACHE accordingly. Return the first instruction after the code
1863 sequence or CURRENT_PC, whichever is smaller. If we don't
1864 recognize the code, return PC. */
1866 static CORE_ADDR
1869 {
1870 /* There are 2 code sequences to re-align stack before the frame
1871 gets set up:
1873 1. Use a caller-saved saved register:
1875 leaq 8(%rsp), %reg
1876 andq $-XXX, %rsp
1877 pushq -8(%reg)
1879 2. Use a callee-saved saved register:
1881 pushq %reg
1882 leaq 16(%rsp), %reg
1883 andq $-XXX, %rsp
1884 pushq -8(%reg)
1886 "andq $-XXX, %rsp" can be either 4 bytes or 7 bytes:
1888 0x48 0x83 0xe4 0xf0 andq $-16, %rsp
1889 0x48 0x81 0xe4 0x00 0xff 0xff 0xff andq $-256, %rsp
1890 */
1899 /* Check caller-saved saved register. The first instruction has
1900 to be "leaq 8(%rsp), %reg". */
1905 {
1906 /* MOD must be binary 10 and R/M must be binary 100. */
1910 /* REG has register number. */
1913 /* Check the REX.R bit. */
1918 }
1919 else
1920 {
1921 /* Check callee-saved saved register. The first instruction
1922 has to be "pushq %reg". */
1928 {
1929 /* Check the REX.B bit. */
1934 }
1935 else
1938 /* Get register. */
1941 offset++;
1943 /* The next instruction has to be "leaq 16(%rsp), %reg". */
1950 /* MOD must be binary 10 and R/M must be binary 100. */
1954 /* REG has register number. */
1957 /* Check the REX.R bit. */
1961 /* Registers in pushq and leaq have to be the same. */
1966 }
1968 /* Rigister can't be %rsp nor %rbp. */
1972 /* The next instruction has to be "andq $-XXX, %rsp". */
1981 /* The next instruction has to be "pushq -8(%reg)". */
1984 offset++;
1987 {
1988 /* Check the REX.B bit. */
1992 }
1993 else
1996 /* 8bit -8 is 0xf8. REG must be binary 110 and MOD must be binary
1997 01. */
2002 /* R/M has register. */
2005 /* Registers in leaq and pushq have to be the same. */
2013 }
2015 /* Similar to amd64_analyze_stack_align for x32. */
2017 static CORE_ADDR
2020 {
2021 /* There are 2 code sequences to re-align stack before the frame
2022 gets set up:
2024 1. Use a caller-saved saved register:
2026 leaq 8(%rsp), %reg
2027 andq $-XXX, %rsp
2028 pushq -8(%reg)
2030 or
2032 [addr32] leal 8(%rsp), %reg
2033 andl $-XXX, %esp
2034 [addr32] pushq -8(%reg)
2036 2. Use a callee-saved saved register:
2038 pushq %reg
2039 leaq 16(%rsp), %reg
2040 andq $-XXX, %rsp
2041 pushq -8(%reg)
2043 or
2045 pushq %reg
2046 [addr32] leal 16(%rsp), %reg
2047 andl $-XXX, %esp
2048 [addr32] pushq -8(%reg)
2050 "andq $-XXX, %rsp" can be either 4 bytes or 7 bytes:
2052 0x48 0x83 0xe4 0xf0 andq $-16, %rsp
2053 0x48 0x81 0xe4 0x00 0xff 0xff 0xff andq $-256, %rsp
2055 "andl $-XXX, %esp" can be either 3 bytes or 6 bytes:
2057 0x83 0xe4 0xf0 andl $-16, %esp
2058 0x81 0xe4 0x00 0xff 0xff 0xff andl $-256, %esp
2059 */
2068 /* Skip optional addr32 prefix. */
2071 /* Check caller-saved saved register. The first instruction has
2072 to be "leaq 8(%rsp), %reg" or "leal 8(%rsp), %reg". */
2077 {
2078 /* MOD must be binary 10 and R/M must be binary 100. */
2082 /* REG has register number. */
2085 /* Check the REX.R bit. */
2090 }
2091 else
2092 {
2093 /* Check callee-saved saved register. The first instruction
2094 has to be "pushq %reg". */
2098 {
2099 /* Check the REX.B bit. */
2104 }
2108 /* Get register. */
2111 offset++;
2113 /* Skip optional addr32 prefix. */
2115 offset++;
2117 /* The next instruction has to be "leaq 16(%rsp), %reg" or
2118 "leal 16(%rsp), %reg". */
2125 /* MOD must be binary 10 and R/M must be binary 100. */
2129 /* REG has register number. */
2132 /* Check the REX.R bit. */
2136 /* Registers in pushq and leaq have to be the same. */
2141 }
2143 /* Rigister can't be %rsp nor %rbp. */
2147 /* The next instruction may be "andq $-XXX, %rsp" or
2148 "andl $-XXX, %esp". */
2150 offset--;
2159 /* Skip optional addr32 prefix. */
2161 offset++;
2163 /* The next instruction has to be "pushq -8(%reg)". */
2166 offset++;
2169 {
2170 /* Check the REX.B bit. */
2174 }
2175 else
2178 /* 8bit -8 is 0xf8. REG must be binary 110 and MOD must be binary
2179 01. */
2184 /* R/M has register. */
2187 /* Registers in leaq and pushq have to be the same. */
2195 }
2197 /* Do a limited analysis of the prologue at PC and update CACHE
2198 accordingly. Bail out early if CURRENT_PC is reached. Return the
2199 address where the analysis stopped.
2201 We will handle only functions beginning with:
2203 pushq %rbp 0x55
2204 movq %rsp, %rbp 0x48 0x89 0xe5 (or 0x48 0x8b 0xec)
2206 or (for the X32 ABI):
2208 pushq %rbp 0x55
2209 movl %esp, %ebp 0x89 0xe5 (or 0x8b 0xec)
2211 Any function that doesn't start with one of these sequences will be
2212 assumed to have no prologue and thus no valid frame pointer in
2213 %rbp. */
2215 static CORE_ADDR
2219 {
2221 /* There are two variations of movq %rsp, %rbp. */
2224 /* Ditto for movl %esp, %ebp. */
2229 gdb_byte op;
2236 else
2242 {
2243 /* Take into account that we've executed the `pushq %rbp' that
2244 starts this instruction sequence. */
2248 /* If that's all, return now. */
2254 /* Check for `movq %rsp, %rbp'. */
2257 {
2258 /* OK, we actually have a frame. */
2261 }
2263 /* For X32, also check for `movq %esp, %ebp'. */
2265 {
2268 {
2269 /* OK, we actually have a frame. */
2272 }
2273 }
2276 }
2279 }
2281 /* Work around false termination of prologue - GCC PR debug/48827.
2283 START_PC is the first instruction of a function, PC is its minimal already
2284 determined advanced address. Function returns PC if it has nothing to do.
2286 84 c0 test %al,%al
2287 74 23 je after
2288 <-- here is 0 lines advance - the false prologue end marker.
2289 0f 29 85 70 ff ff ff movaps %xmm0,-0x90(%rbp)
2290 0f 29 4d 80 movaps %xmm1,-0x80(%rbp)
2291 0f 29 55 90 movaps %xmm2,-0x70(%rbp)
2292 0f 29 5d a0 movaps %xmm3,-0x60(%rbp)
2293 0f 29 65 b0 movaps %xmm4,-0x50(%rbp)
2294 0f 29 6d c0 movaps %xmm5,-0x40(%rbp)
2295 0f 29 75 d0 movaps %xmm6,-0x30(%rbp)
2296 0f 29 7d e0 movaps %xmm7,-0x20(%rbp)
2297 after: */
2299 static CORE_ADDR
2301 {
2320 /* START_PC can be from overlayed memory, ignored here. */
2324 /* test %al,%al */
2327 /* je AFTER */
2333 {
2334 /* 0x0f 0x29 0b??000101 movaps %xmmreg?,-0x??(%rbp) */
2339 /* 0b01?????? */
2341 {
2342 /* 8-bit displacement. */
2344 }
2345 /* 0b10?????? */
2347 {
2348 /* 32-bit displacement. */
2350 }
2351 else
2353 }
2355 /* je AFTER */
2360 }
2362 /* Return PC of first real instruction. */
2364 static CORE_ADDR
2366 {
2368 CORE_ADDR pc;
2369 CORE_ADDR func_addr;
2372 {
2373 CORE_ADDR post_prologue_pc
2377 /* Clang always emits a line note before the prologue and another
2378 one after. We trust clang to emit usable line notes. */
2384 }
2393 }
2394 \f
2396 /* Normal frames. */
2398 static void
2401 {
2410 cache);
2413 {
2414 /* We didn't find a valid frame. If we're at the start of a
2415 function, or somewhere half-way its prologue, the function's
2416 frame probably hasn't been fully setup yet. Try to
2417 reconstruct the base address for the stack frame by looking
2418 at the stack pointer. For truly "frameless" functions this
2419 might work too. */
2422 {
2423 /* Stack pointer has been saved. */
2427 /* We're halfway aligning the stack. */
2431 /* This will be added back below. */
2433 }
2434 else
2435 {
2439 }
2440 }
2441 else
2442 {
2445 }
2447 /* Now that we have the base address for the stack frame we can
2448 calculate the value of %rsp in the calling frame. */
2451 /* For normal frames, %rip is stored at 8(%rbp). If we don't have a
2452 frame we find it at the same offset from the reconstructed base
2453 address. If we're halfway aligning the stack, %rip is handled
2454 differently (see above). */
2458 /* Adjust all the saved registers such that they contain addresses
2459 instead of offsets. */
2465 }
2469 {
2478 TRY
2479 {
2481 }
2483 {
2486 }
2487 END_CATCH
2490 }
2492 static enum unwind_stop_reason
2495 {
2502 /* This marks the outermost frame. */
2507 }
2509 static void
2512 {
2519 {
2520 /* This marks the outermost frame. */
2522 }
2523 else
2525 }
2530 {
2545 }
2548 {
2549 NORMAL_FRAME,
2550 amd64_frame_unwind_stop_reason,
2551 amd64_frame_this_id,
2552 amd64_frame_prev_register,
2553 NULL,
2554 default_frame_sniffer
2555 };
2556 \f
2557 /* Generate a bytecode expression to get the value of the saved PC. */
2559 static void
2562 CORE_ADDR scope)
2563 {
2564 /* The following sequence assumes the traditional use of the base
2565 register. */
2571 }
2572 \f
2574 /* Signal trampolines. */
2576 /* FIXME: kettenis/20030419: Perhaps, we can unify the 32-bit and
2577 64-bit variants. This would require using identical frame caches
2578 on both platforms. */
2582 {
2587 CORE_ADDR addr;
2596 TRY
2597 {
2609 }
2611 {
2614 }
2615 END_CATCH
2619 }
2621 static enum unwind_stop_reason
2624 {
2632 }
2634 static void
2637 {
2644 {
2645 /* This marks the outermost frame. */
2647 }
2648 else
2650 }
2655 {
2656 /* Make sure we've initialized the cache. */
2660 }
2662 static int
2666 {
2669 /* We shouldn't even bother if we don't have a sigcontext_addr
2670 handler. */
2675 {
2678 }
2681 {
2687 }
2690 }
2693 {
2694 SIGTRAMP_FRAME,
2695 amd64_sigtramp_frame_unwind_stop_reason,
2696 amd64_sigtramp_frame_this_id,
2697 amd64_sigtramp_frame_prev_register,
2698 NULL,
2699 amd64_sigtramp_frame_sniffer
2700 };
2701 \f
2703 static CORE_ADDR
2705 {
2710 }
2713 {
2715 amd64_frame_base_address,
2716 amd64_frame_base_address,
2717 amd64_frame_base_address
2718 };
2720 /* Normal frames, but in a function epilogue. */
2722 /* Implement the stack_frame_destroyed_p gdbarch method.
2724 The epilogue is defined here as the 'ret' instruction, which will
2725 follow any instruction such as 'leave' or 'pop %ebp' that destroys
2726 the function's stack frame. */
2728 static int
2730 {
2731 gdb_byte insn;
2745 }
2747 static int
2751 {
2755 else
2757 }
2761 {
2773 TRY
2774 {
2775 /* Cache base will be %esp plus cache->sp_offset (-8). */
2780 /* Cache pc will be the frame func. */
2783 /* The saved %esp will be at cache->base plus 16. */
2786 /* The saved %eip will be at cache->base plus 8. */
2790 }
2792 {
2795 }
2796 END_CATCH
2799 }
2801 static enum unwind_stop_reason
2804 {
2812 }
2814 static void
2818 {
2820 this_cache);
2824 else
2826 }
2829 {
2830 NORMAL_FRAME,
2831 amd64_epilogue_frame_unwind_stop_reason,
2832 amd64_epilogue_frame_this_id,
2833 amd64_frame_prev_register,
2834 NULL,
2835 amd64_epilogue_frame_sniffer
2836 };
2838 static struct frame_id
2840 {
2841 CORE_ADDR fp;
2846 }
2848 /* 16 byte align the SP per frame requirements. */
2850 static CORE_ADDR
2852 {
2854 }
2855 \f
2857 /* Supply register REGNUM from the buffer specified by FPREGS and LEN
2858 in the floating-point register set REGSET to register cache
2859 REGCACHE. If REGNUM is -1, do this for all registers in REGSET. */
2861 static void
2864 {
2870 }
2872 /* Collect register REGNUM from the register cache REGCACHE and store
2873 it in the buffer specified by FPREGS and LEN as described by the
2874 floating-point register set REGSET. If REGNUM is -1, do this for
2875 all registers in REGSET. */
2877 static void
2881 {
2887 }
2890 {
2892 };
2893 \f
2895 /* Figure out where the longjmp will land. Slurp the jmp_buf out of
2896 %rdi. We expect its value to be a pointer to the jmp_buf structure
2897 from which we extract the address that we will land at. This
2898 address is copied into PC. This routine returns non-zero on
2899 success. */
2901 static int
2903 {
2905 CORE_ADDR jb_addr;
2910 /* If JB_PC_OFFSET is -1, we have no way to find out where the
2911 longjmp will land. */
2916 jb_addr= extract_typed_address
2924 }
2927 {
2934 };
2936 void
2938 {
2944 NULL };
2946 NULL };
2948 /* AMD64 generally uses `fxsave' instead of `fsave' for saving its
2949 floating-point registers. */
2961 {
2975 }
2978 {
2982 }
2985 {
2989 }
2994 /* Avoid wiring in the MMX registers for now. */
2998 amd64_pseudo_register_read_value);
3000 amd64_pseudo_register_write);
3004 /* AMD64 has an FPU and 16 SSE registers. */
3008 /* This is what all the fuss is about. */
3013 /* In contrast to the i386, on AMD64 a `long double' actually takes
3014 up 128 bits, even though it's still based on the i387 extended
3015 floating-point format which has only 80 significant bits. */
3020 /* Register numbers of various important registers. */
3026 /* The "default" register numbering scheme for AMD64 is referred to
3027 as the "DWARF Register Number Mapping" in the System V psABI.
3028 The preferred debugging format for all known AMD64 targets is
3029 actually DWARF2, and GCC doesn't seem to support DWARF (that is
3030 DWARF-1), but we provide the same mapping just in case. This
3031 mapping is also used for stabs, which GCC does support. */
3035 /* We don't override SDB_REG_RO_REGNUM, since COFF doesn't seem to
3036 be in use on any of the supported AMD64 targets. */
3038 /* Call dummy code. */
3055 /* Hook the function epilogue frame unwinder. This unwinder is
3056 appended to the list first, so that it supercedes the other
3057 unwinders in function epilogues. */
3060 /* Hook the prologue-based frame unwinders. */
3071 /* SystemTap variables and functions. */
3075 stap_register_indirection_prefixes);
3077 stap_register_indirection_suffixes);
3079 i386_stap_is_single_operand);
3081 i386_stap_parse_special_token);
3085 }
3086 \f
3090 {
3094 {
3100 }
3103 }
3105 void
3107 {
3122 }
3124 /* Return the target description for a specified XSAVE feature mask. */
3128 {
3130 {
3140 }
3141 }
3143 /* Provide a prototype to silence -Wmissing-prototypes. */
3146 void
3148 {
3157 }
3158 \f
3160 /* The 64-bit FXSAVE format differs from the 32-bit format in the
3161 sense that the instruction pointer and data pointer are simply
3162 64-bit offsets into the code segment and the data segment instead
3163 of a selector offset pair. The functions below store the upper 32
3164 bits of these pointers (instead of just the 16-bits of the segment
3165 selector). */
3167 /* Fill register REGNUM in REGCACHE with the appropriate
3168 floating-point or SSE register value from *FXSAVE. If REGNUM is
3169 -1, do this for all registers. This function masks off any of the
3170 reserved bits in *FXSAVE. */
3172 void
3175 {
3183 {
3190 }
3191 }
3193 /* Similar to amd64_supply_fxsave, but use XSAVE extended state. */
3195 void
3198 {
3206 {
3215 }
3216 }
3218 /* Fill register REGNUM (if it is a floating-point or SSE register) in
3219 *FXSAVE with the value from REGCACHE. If REGNUM is -1, do this for
3220 all registers. This function doesn't touch any of the reserved
3221 bits in *FXSAVE. */
3223 void
3226 {
3234 {
3239 }
3240 }
3242 /* Similar to amd64_collect_fxsave, but use XSAVE extended state. */
3244 void
3247 {
3255 {
3262 }
3263 }