darling-gdb/gdb/ppc-linux-tdep.c
Andrew Cagney e8ce19c0cd 2004-10-31 Andrew Cagney <cagney@gnu.org>
* armnbsd-tdep.c (arm_netbsd_aout_init_abi)
	(arm_netbsd_aout_in_solib_call_trampoline): Do not set
	in_solib_call_trampoline, delete corresponding unused function.
	* vaxnbsd-tdep.c (vaxnbsd_aout_in_solib_call_trampoline)
	(vaxnbsd_aout_init_abi): Ditto.
	* sparcnbsd-tdep.c (sparcnbsd_aout_in_solib_call_trampoline)
	(sparc32nbsd_aout_init_abi): Ditto.
	* ppc-linux-tdep.c (ppc64_in_solib_call_trampoline)
	(ppc_linux_init_abi): Ditto.
	* ns32knbsd-tdep.c (ns32knbsd_aout_in_solib_call_trampoline)
	(ns32knbsd_init_abi_aout): Ditto.
	* mips-tdep.c (mips_in_call_stub, mips_gdbarch_init): Ditto.
	* mips-linux-tdep.c (mips_linux_init_abi): Ditto.
	* m68kbsd-tdep.c (m68kbsd_aout_in_solib_call_trampoline)
	(m68kbsd_aout_init_abi): Ditto.
	* i386-cygwin-tdep.c (i386_cygwin_in_solib_call_trampoline)
	(i386_cygwin_init_abi): Ditto.
	* i386bsd-tdep.c (i386bsd_aout_in_solib_call_trampoline)
	(i386bsd_init_abi): Ditto.
2004-10-31 20:24:32 +00:00

1085 lines
36 KiB
C

/* Target-dependent code for GDB, the GNU debugger.
Copyright 1986, 1987, 1989, 1991, 1992, 1993, 1994, 1995, 1996,
1997, 2000, 2001, 2002, 2003, 2004 Free Software Foundation, Inc.
This file is part of GDB.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA. */
#include "defs.h"
#include "frame.h"
#include "inferior.h"
#include "symtab.h"
#include "target.h"
#include "gdbcore.h"
#include "gdbcmd.h"
#include "symfile.h"
#include "objfiles.h"
#include "regcache.h"
#include "value.h"
#include "osabi.h"
#include "regset.h"
#include "solib-svr4.h"
#include "ppc-tdep.h"
#include "trad-frame.h"
#include "frame-unwind.h"
/* The following instructions are used in the signal trampoline code
on GNU/Linux PPC. The kernel used to use magic syscalls 0x6666 and
0x7777 but now uses the sigreturn syscalls. We check for both. */
#define INSTR_LI_R0_0x6666 0x38006666
#define INSTR_LI_R0_0x7777 0x38007777
#define INSTR_LI_R0_NR_sigreturn 0x38000077
#define INSTR_LI_R0_NR_rt_sigreturn 0x380000AC
#define INSTR_SC 0x44000002
/* Since the *-tdep.c files are platform independent (i.e, they may be
used to build cross platform debuggers), we can't include system
headers. Therefore, details concerning the sigcontext structure
must be painstakingly rerecorded. What's worse, if these details
ever change in the header files, they'll have to be changed here
as well. */
/* __SIGNAL_FRAMESIZE from <asm/ptrace.h> */
#define PPC_LINUX_SIGNAL_FRAMESIZE 64
/* From <asm/sigcontext.h>, offsetof(struct sigcontext_struct, regs) == 0x1c */
#define PPC_LINUX_REGS_PTR_OFFSET (PPC_LINUX_SIGNAL_FRAMESIZE + 0x1c)
/* From <asm/sigcontext.h>,
offsetof(struct sigcontext_struct, handler) == 0x14 */
#define PPC_LINUX_HANDLER_PTR_OFFSET (PPC_LINUX_SIGNAL_FRAMESIZE + 0x14)
/* From <asm/ptrace.h>, values for PT_NIP, PT_R1, and PT_LNK */
#define PPC_LINUX_PT_R0 0
#define PPC_LINUX_PT_R1 1
#define PPC_LINUX_PT_R2 2
#define PPC_LINUX_PT_R3 3
#define PPC_LINUX_PT_R4 4
#define PPC_LINUX_PT_R5 5
#define PPC_LINUX_PT_R6 6
#define PPC_LINUX_PT_R7 7
#define PPC_LINUX_PT_R8 8
#define PPC_LINUX_PT_R9 9
#define PPC_LINUX_PT_R10 10
#define PPC_LINUX_PT_R11 11
#define PPC_LINUX_PT_R12 12
#define PPC_LINUX_PT_R13 13
#define PPC_LINUX_PT_R14 14
#define PPC_LINUX_PT_R15 15
#define PPC_LINUX_PT_R16 16
#define PPC_LINUX_PT_R17 17
#define PPC_LINUX_PT_R18 18
#define PPC_LINUX_PT_R19 19
#define PPC_LINUX_PT_R20 20
#define PPC_LINUX_PT_R21 21
#define PPC_LINUX_PT_R22 22
#define PPC_LINUX_PT_R23 23
#define PPC_LINUX_PT_R24 24
#define PPC_LINUX_PT_R25 25
#define PPC_LINUX_PT_R26 26
#define PPC_LINUX_PT_R27 27
#define PPC_LINUX_PT_R28 28
#define PPC_LINUX_PT_R29 29
#define PPC_LINUX_PT_R30 30
#define PPC_LINUX_PT_R31 31
#define PPC_LINUX_PT_NIP 32
#define PPC_LINUX_PT_MSR 33
#define PPC_LINUX_PT_CTR 35
#define PPC_LINUX_PT_LNK 36
#define PPC_LINUX_PT_XER 37
#define PPC_LINUX_PT_CCR 38
#define PPC_LINUX_PT_MQ 39
#define PPC_LINUX_PT_FPR0 48 /* each FP reg occupies 2 slots in this space */
#define PPC_LINUX_PT_FPR31 (PPC_LINUX_PT_FPR0 + 2*31)
#define PPC_LINUX_PT_FPSCR (PPC_LINUX_PT_FPR0 + 2*32 + 1)
static int ppc_linux_at_sigtramp_return_path (CORE_ADDR pc);
/* Determine if pc is in a signal trampoline...
Ha! That's not what this does at all. wait_for_inferior in
infrun.c calls get_frame_type() in order to detect entry into a
signal trampoline just after delivery of a signal. But on
GNU/Linux, signal trampolines are used for the return path only.
The kernel sets things up so that the signal handler is called
directly.
If we use in_sigtramp2() in place of in_sigtramp() (see below)
we'll (often) end up with stop_pc in the trampoline and prev_pc in
the (now exited) handler. The code there will cause a temporary
breakpoint to be set on prev_pc which is not very likely to get hit
again.
If this is confusing, think of it this way... the code in
wait_for_inferior() needs to be able to detect entry into a signal
trampoline just after a signal is delivered, not after the handler
has been run.
So, we define in_sigtramp() below to return 1 if the following is
true:
1) The previous frame is a real signal trampoline.
- and -
2) pc is at the first or second instruction of the corresponding
handler.
Why the second instruction? It seems that wait_for_inferior()
never sees the first instruction when single stepping. When a
signal is delivered while stepping, the next instruction that
would've been stepped over isn't, instead a signal is delivered and
the first instruction of the handler is stepped over instead. That
puts us on the second instruction. (I added the test for the first
instruction long after the fact, just in case the observed behavior
is ever fixed.) */
int
ppc_linux_in_sigtramp (CORE_ADDR pc, char *func_name)
{
CORE_ADDR lr;
CORE_ADDR sp;
CORE_ADDR tramp_sp;
char buf[4];
CORE_ADDR handler;
lr = read_register (gdbarch_tdep (current_gdbarch)->ppc_lr_regnum);
if (!ppc_linux_at_sigtramp_return_path (lr))
return 0;
sp = read_register (SP_REGNUM);
if (target_read_memory (sp, buf, sizeof (buf)) != 0)
return 0;
tramp_sp = extract_unsigned_integer (buf, 4);
if (target_read_memory (tramp_sp + PPC_LINUX_HANDLER_PTR_OFFSET, buf,
sizeof (buf)) != 0)
return 0;
handler = extract_unsigned_integer (buf, 4);
return (pc == handler || pc == handler + 4);
}
static int
insn_is_sigreturn (unsigned long pcinsn)
{
switch(pcinsn)
{
case INSTR_LI_R0_0x6666:
case INSTR_LI_R0_0x7777:
case INSTR_LI_R0_NR_sigreturn:
case INSTR_LI_R0_NR_rt_sigreturn:
return 1;
default:
return 0;
}
}
/*
* The signal handler trampoline is on the stack and consists of exactly
* two instructions. The easiest and most accurate way of determining
* whether the pc is in one of these trampolines is by inspecting the
* instructions. It'd be faster though if we could find a way to do this
* via some simple address comparisons.
*/
static int
ppc_linux_at_sigtramp_return_path (CORE_ADDR pc)
{
char buf[12];
unsigned long pcinsn;
if (target_read_memory (pc - 4, buf, sizeof (buf)) != 0)
return 0;
/* extract the instruction at the pc */
pcinsn = extract_unsigned_integer (buf + 4, 4);
return (
(insn_is_sigreturn (pcinsn)
&& extract_unsigned_integer (buf + 8, 4) == INSTR_SC)
||
(pcinsn == INSTR_SC
&& insn_is_sigreturn (extract_unsigned_integer (buf, 4))));
}
static CORE_ADDR
ppc_linux_skip_trampoline_code (CORE_ADDR pc)
{
char buf[4];
struct obj_section *sect;
struct objfile *objfile;
unsigned long insn;
CORE_ADDR plt_start = 0;
CORE_ADDR symtab = 0;
CORE_ADDR strtab = 0;
int num_slots = -1;
int reloc_index = -1;
CORE_ADDR plt_table;
CORE_ADDR reloc;
CORE_ADDR sym;
long symidx;
char symname[1024];
struct minimal_symbol *msymbol;
/* Find the section pc is in; return if not in .plt */
sect = find_pc_section (pc);
if (!sect || strcmp (sect->the_bfd_section->name, ".plt") != 0)
return 0;
objfile = sect->objfile;
/* Pick up the instruction at pc. It had better be of the
form
li r11, IDX
where IDX is an index into the plt_table. */
if (target_read_memory (pc, buf, 4) != 0)
return 0;
insn = extract_unsigned_integer (buf, 4);
if ((insn & 0xffff0000) != 0x39600000 /* li r11, VAL */ )
return 0;
reloc_index = (insn << 16) >> 16;
/* Find the objfile that pc is in and obtain the information
necessary for finding the symbol name. */
for (sect = objfile->sections; sect < objfile->sections_end; ++sect)
{
const char *secname = sect->the_bfd_section->name;
if (strcmp (secname, ".plt") == 0)
plt_start = sect->addr;
else if (strcmp (secname, ".rela.plt") == 0)
num_slots = ((int) sect->endaddr - (int) sect->addr) / 12;
else if (strcmp (secname, ".dynsym") == 0)
symtab = sect->addr;
else if (strcmp (secname, ".dynstr") == 0)
strtab = sect->addr;
}
/* Make sure we have all the information we need. */
if (plt_start == 0 || num_slots == -1 || symtab == 0 || strtab == 0)
return 0;
/* Compute the value of the plt table */
plt_table = plt_start + 72 + 8 * num_slots;
/* Get address of the relocation entry (Elf32_Rela) */
if (target_read_memory (plt_table + reloc_index, buf, 4) != 0)
return 0;
reloc = extract_unsigned_integer (buf, 4);
sect = find_pc_section (reloc);
if (!sect)
return 0;
if (strcmp (sect->the_bfd_section->name, ".text") == 0)
return reloc;
/* Now get the r_info field which is the relocation type and symbol
index. */
if (target_read_memory (reloc + 4, buf, 4) != 0)
return 0;
symidx = extract_unsigned_integer (buf, 4);
/* Shift out the relocation type leaving just the symbol index */
/* symidx = ELF32_R_SYM(symidx); */
symidx = symidx >> 8;
/* compute the address of the symbol */
sym = symtab + symidx * 4;
/* Fetch the string table index */
if (target_read_memory (sym, buf, 4) != 0)
return 0;
symidx = extract_unsigned_integer (buf, 4);
/* Fetch the string; we don't know how long it is. Is it possible
that the following will fail because we're trying to fetch too
much? */
if (target_read_memory (strtab + symidx, symname, sizeof (symname)) != 0)
return 0;
/* This might not work right if we have multiple symbols with the
same name; the only way to really get it right is to perform
the same sort of lookup as the dynamic linker. */
msymbol = lookup_minimal_symbol_text (symname, NULL);
if (!msymbol)
return 0;
return SYMBOL_VALUE_ADDRESS (msymbol);
}
/* ppc_linux_memory_remove_breakpoints attempts to remove a breakpoint
in much the same fashion as memory_remove_breakpoint in mem-break.c,
but is careful not to write back the previous contents if the code
in question has changed in between inserting the breakpoint and
removing it.
Here is the problem that we're trying to solve...
Once upon a time, before introducing this function to remove
breakpoints from the inferior, setting a breakpoint on a shared
library function prior to running the program would not work
properly. In order to understand the problem, it is first
necessary to understand a little bit about dynamic linking on
this platform.
A call to a shared library function is accomplished via a bl
(branch-and-link) instruction whose branch target is an entry
in the procedure linkage table (PLT). The PLT in the object
file is uninitialized. To gdb, prior to running the program, the
entries in the PLT are all zeros.
Once the program starts running, the shared libraries are loaded
and the procedure linkage table is initialized, but the entries in
the table are not (necessarily) resolved. Once a function is
actually called, the code in the PLT is hit and the function is
resolved. In order to better illustrate this, an example is in
order; the following example is from the gdb testsuite.
We start the program shmain.
[kev@arroyo testsuite]$ ../gdb gdb.base/shmain
[...]
We place two breakpoints, one on shr1 and the other on main.
(gdb) b shr1
Breakpoint 1 at 0x100409d4
(gdb) b main
Breakpoint 2 at 0x100006a0: file gdb.base/shmain.c, line 44.
Examine the instruction (and the immediatly following instruction)
upon which the breakpoint was placed. Note that the PLT entry
for shr1 contains zeros.
(gdb) x/2i 0x100409d4
0x100409d4 <shr1>: .long 0x0
0x100409d8 <shr1+4>: .long 0x0
Now run 'til main.
(gdb) r
Starting program: gdb.base/shmain
Breakpoint 1 at 0xffaf790: file gdb.base/shr1.c, line 19.
Breakpoint 2, main ()
at gdb.base/shmain.c:44
44 g = 1;
Examine the PLT again. Note that the loading of the shared
library has initialized the PLT to code which loads a constant
(which I think is an index into the GOT) into r11 and then
branchs a short distance to the code which actually does the
resolving.
(gdb) x/2i 0x100409d4
0x100409d4 <shr1>: li r11,4
0x100409d8 <shr1+4>: b 0x10040984 <sg+4>
(gdb) c
Continuing.
Breakpoint 1, shr1 (x=1)
at gdb.base/shr1.c:19
19 l = 1;
Now we've hit the breakpoint at shr1. (The breakpoint was
reset from the PLT entry to the actual shr1 function after the
shared library was loaded.) Note that the PLT entry has been
resolved to contain a branch that takes us directly to shr1.
(The real one, not the PLT entry.)
(gdb) x/2i 0x100409d4
0x100409d4 <shr1>: b 0xffaf76c <shr1>
0x100409d8 <shr1+4>: b 0x10040984 <sg+4>
The thing to note here is that the PLT entry for shr1 has been
changed twice.
Now the problem should be obvious. GDB places a breakpoint (a
trap instruction) on the zero value of the PLT entry for shr1.
Later on, after the shared library had been loaded and the PLT
initialized, GDB gets a signal indicating this fact and attempts
(as it always does when it stops) to remove all the breakpoints.
The breakpoint removal was causing the former contents (a zero
word) to be written back to the now initialized PLT entry thus
destroying a portion of the initialization that had occurred only a
short time ago. When execution continued, the zero word would be
executed as an instruction an an illegal instruction trap was
generated instead. (0 is not a legal instruction.)
The fix for this problem was fairly straightforward. The function
memory_remove_breakpoint from mem-break.c was copied to this file,
modified slightly, and renamed to ppc_linux_memory_remove_breakpoint.
In tm-linux.h, MEMORY_REMOVE_BREAKPOINT is defined to call this new
function.
The differences between ppc_linux_memory_remove_breakpoint () and
memory_remove_breakpoint () are minor. All that the former does
that the latter does not is check to make sure that the breakpoint
location actually contains a breakpoint (trap instruction) prior
to attempting to write back the old contents. If it does contain
a trap instruction, we allow the old contents to be written back.
Otherwise, we silently do nothing.
The big question is whether memory_remove_breakpoint () should be
changed to have the same functionality. The downside is that more
traffic is generated for remote targets since we'll have an extra
fetch of a memory word each time a breakpoint is removed.
For the time being, we'll leave this self-modifying-code-friendly
version in ppc-linux-tdep.c, but it ought to be migrated somewhere
else in the event that some other platform has similar needs with
regard to removing breakpoints in some potentially self modifying
code. */
int
ppc_linux_memory_remove_breakpoint (CORE_ADDR addr, char *contents_cache)
{
const unsigned char *bp;
int val;
int bplen;
char old_contents[BREAKPOINT_MAX];
/* Determine appropriate breakpoint contents and size for this address. */
bp = BREAKPOINT_FROM_PC (&addr, &bplen);
if (bp == NULL)
error ("Software breakpoints not implemented for this target.");
val = target_read_memory (addr, old_contents, bplen);
/* If our breakpoint is no longer at the address, this means that the
program modified the code on us, so it is wrong to put back the
old value */
if (val == 0 && memcmp (bp, old_contents, bplen) == 0)
val = target_write_memory (addr, contents_cache, bplen);
return val;
}
/* For historic reasons, PPC 32 GNU/Linux follows PowerOpen rather
than the 32 bit SYSV R4 ABI structure return convention - all
structures, no matter their size, are put in memory. Vectors,
which were added later, do get returned in a register though. */
static enum return_value_convention
ppc_linux_return_value (struct gdbarch *gdbarch, struct type *valtype,
struct regcache *regcache, void *readbuf,
const void *writebuf)
{
if ((TYPE_CODE (valtype) == TYPE_CODE_STRUCT
|| TYPE_CODE (valtype) == TYPE_CODE_UNION)
&& !((TYPE_LENGTH (valtype) == 16 || TYPE_LENGTH (valtype) == 8)
&& TYPE_VECTOR (valtype)))
return RETURN_VALUE_STRUCT_CONVENTION;
else
return ppc_sysv_abi_return_value (gdbarch, valtype, regcache, readbuf,
writebuf);
}
/* Fetch (and possibly build) an appropriate link_map_offsets
structure for GNU/Linux PPC targets using the struct offsets
defined in link.h (but without actual reference to that file).
This makes it possible to access GNU/Linux PPC shared libraries
from a GDB that was not built on an GNU/Linux PPC host (for cross
debugging). */
struct link_map_offsets *
ppc_linux_svr4_fetch_link_map_offsets (void)
{
static struct link_map_offsets lmo;
static struct link_map_offsets *lmp = NULL;
if (lmp == NULL)
{
lmp = &lmo;
lmo.r_debug_size = 8; /* The actual size is 20 bytes, but
this is all we need. */
lmo.r_map_offset = 4;
lmo.r_map_size = 4;
lmo.link_map_size = 20; /* The actual size is 560 bytes, but
this is all we need. */
lmo.l_addr_offset = 0;
lmo.l_addr_size = 4;
lmo.l_name_offset = 4;
lmo.l_name_size = 4;
lmo.l_next_offset = 12;
lmo.l_next_size = 4;
lmo.l_prev_offset = 16;
lmo.l_prev_size = 4;
}
return lmp;
}
/* Macros for matching instructions. Note that, since all the
operands are masked off before they're or-ed into the instruction,
you can use -1 to make masks. */
#define insn_d(opcd, rts, ra, d) \
((((opcd) & 0x3f) << 26) \
| (((rts) & 0x1f) << 21) \
| (((ra) & 0x1f) << 16) \
| ((d) & 0xffff))
#define insn_ds(opcd, rts, ra, d, xo) \
((((opcd) & 0x3f) << 26) \
| (((rts) & 0x1f) << 21) \
| (((ra) & 0x1f) << 16) \
| ((d) & 0xfffc) \
| ((xo) & 0x3))
#define insn_xfx(opcd, rts, spr, xo) \
((((opcd) & 0x3f) << 26) \
| (((rts) & 0x1f) << 21) \
| (((spr) & 0x1f) << 16) \
| (((spr) & 0x3e0) << 6) \
| (((xo) & 0x3ff) << 1))
/* Read a PPC instruction from memory. PPC instructions are always
big-endian, no matter what endianness the program is running in, so
we can't use read_memory_integer or one of its friends here. */
static unsigned int
read_insn (CORE_ADDR pc)
{
unsigned char buf[4];
read_memory (pc, buf, 4);
return (buf[0] << 24) | (buf[1] << 16) | (buf[2] << 8) | buf[3];
}
/* An instruction to match. */
struct insn_pattern
{
unsigned int mask; /* mask the insn with this... */
unsigned int data; /* ...and see if it matches this. */
int optional; /* If non-zero, this insn may be absent. */
};
/* Return non-zero if the instructions at PC match the series
described in PATTERN, or zero otherwise. PATTERN is an array of
'struct insn_pattern' objects, terminated by an entry whose mask is
zero.
When the match is successful, fill INSN[i] with what PATTERN[i]
matched. If PATTERN[i] is optional, and the instruction wasn't
present, set INSN[i] to 0 (which is not a valid PPC instruction).
INSN should have as many elements as PATTERN. Note that, if
PATTERN contains optional instructions which aren't present in
memory, then INSN will have holes, so INSN[i] isn't necessarily the
i'th instruction in memory. */
static int
insns_match_pattern (CORE_ADDR pc,
struct insn_pattern *pattern,
unsigned int *insn)
{
int i;
for (i = 0; pattern[i].mask; i++)
{
insn[i] = read_insn (pc);
if ((insn[i] & pattern[i].mask) == pattern[i].data)
pc += 4;
else if (pattern[i].optional)
insn[i] = 0;
else
return 0;
}
return 1;
}
/* Return the 'd' field of the d-form instruction INSN, properly
sign-extended. */
static CORE_ADDR
insn_d_field (unsigned int insn)
{
return ((((CORE_ADDR) insn & 0xffff) ^ 0x8000) - 0x8000);
}
/* Return the 'ds' field of the ds-form instruction INSN, with the two
zero bits concatenated at the right, and properly
sign-extended. */
static CORE_ADDR
insn_ds_field (unsigned int insn)
{
return ((((CORE_ADDR) insn & 0xfffc) ^ 0x8000) - 0x8000);
}
/* If DESC is the address of a 64-bit PowerPC GNU/Linux function
descriptor, return the descriptor's entry point. */
static CORE_ADDR
ppc64_desc_entry_point (CORE_ADDR desc)
{
/* The first word of the descriptor is the entry point. */
return (CORE_ADDR) read_memory_unsigned_integer (desc, 8);
}
/* Pattern for the standard linkage function. These are built by
build_plt_stub in elf64-ppc.c, whose GLINK argument is always
zero. */
static struct insn_pattern ppc64_standard_linkage[] =
{
/* addis r12, r2, <any> */
{ insn_d (-1, -1, -1, 0), insn_d (15, 12, 2, 0), 0 },
/* std r2, 40(r1) */
{ -1, insn_ds (62, 2, 1, 40, 0), 0 },
/* ld r11, <any>(r12) */
{ insn_ds (-1, -1, -1, 0, -1), insn_ds (58, 11, 12, 0, 0), 0 },
/* addis r12, r12, 1 <optional> */
{ insn_d (-1, -1, -1, -1), insn_d (15, 12, 2, 1), 1 },
/* ld r2, <any>(r12) */
{ insn_ds (-1, -1, -1, 0, -1), insn_ds (58, 2, 12, 0, 0), 0 },
/* addis r12, r12, 1 <optional> */
{ insn_d (-1, -1, -1, -1), insn_d (15, 12, 2, 1), 1 },
/* mtctr r11 */
{ insn_xfx (-1, -1, -1, -1), insn_xfx (31, 11, 9, 467),
0 },
/* ld r11, <any>(r12) */
{ insn_ds (-1, -1, -1, 0, -1), insn_ds (58, 11, 12, 0, 0), 0 },
/* bctr */
{ -1, 0x4e800420, 0 },
{ 0, 0, 0 }
};
#define PPC64_STANDARD_LINKAGE_LEN \
(sizeof (ppc64_standard_linkage) / sizeof (ppc64_standard_linkage[0]))
/* When the dynamic linker is doing lazy symbol resolution, the first
call to a function in another object will go like this:
- The user's function calls the linkage function:
100007c4: 4b ff fc d5 bl 10000498
100007c8: e8 41 00 28 ld r2,40(r1)
- The linkage function loads the entry point (and other stuff) from
the function descriptor in the PLT, and jumps to it:
10000498: 3d 82 00 00 addis r12,r2,0
1000049c: f8 41 00 28 std r2,40(r1)
100004a0: e9 6c 80 98 ld r11,-32616(r12)
100004a4: e8 4c 80 a0 ld r2,-32608(r12)
100004a8: 7d 69 03 a6 mtctr r11
100004ac: e9 6c 80 a8 ld r11,-32600(r12)
100004b0: 4e 80 04 20 bctr
- But since this is the first time that PLT entry has been used, it
sends control to its glink entry. That loads the number of the
PLT entry and jumps to the common glink0 code:
10000c98: 38 00 00 00 li r0,0
10000c9c: 4b ff ff dc b 10000c78
- The common glink0 code then transfers control to the dynamic
linker's fixup code:
10000c78: e8 41 00 28 ld r2,40(r1)
10000c7c: 3d 82 00 00 addis r12,r2,0
10000c80: e9 6c 80 80 ld r11,-32640(r12)
10000c84: e8 4c 80 88 ld r2,-32632(r12)
10000c88: 7d 69 03 a6 mtctr r11
10000c8c: e9 6c 80 90 ld r11,-32624(r12)
10000c90: 4e 80 04 20 bctr
Eventually, this code will figure out how to skip all of this,
including the dynamic linker. At the moment, we just get through
the linkage function. */
/* If the current thread is about to execute a series of instructions
at PC matching the ppc64_standard_linkage pattern, and INSN is the result
from that pattern match, return the code address to which the
standard linkage function will send them. (This doesn't deal with
dynamic linker lazy symbol resolution stubs.) */
static CORE_ADDR
ppc64_standard_linkage_target (CORE_ADDR pc, unsigned int *insn)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (current_gdbarch);
/* The address of the function descriptor this linkage function
references. */
CORE_ADDR desc
= ((CORE_ADDR) read_register (tdep->ppc_gp0_regnum + 2)
+ (insn_d_field (insn[0]) << 16)
+ insn_ds_field (insn[2]));
/* The first word of the descriptor is the entry point. Return that. */
return ppc64_desc_entry_point (desc);
}
/* Given that we've begun executing a call trampoline at PC, return
the entry point of the function the trampoline will go to. */
static CORE_ADDR
ppc64_skip_trampoline_code (CORE_ADDR pc)
{
unsigned int ppc64_standard_linkage_insn[PPC64_STANDARD_LINKAGE_LEN];
if (insns_match_pattern (pc, ppc64_standard_linkage,
ppc64_standard_linkage_insn))
return ppc64_standard_linkage_target (pc, ppc64_standard_linkage_insn);
else
return 0;
}
/* Support for CONVERT_FROM_FUNC_PTR_ADDR (ARCH, ADDR, TARG) on PPC64
GNU/Linux.
Usually a function pointer's representation is simply the address
of the function. On GNU/Linux on the 64-bit PowerPC however, a
function pointer is represented by a pointer to a TOC entry. This
TOC entry contains three words, the first word is the address of
the function, the second word is the TOC pointer (r2), and the
third word is the static chain value. Throughout GDB it is
currently assumed that a function pointer contains the address of
the function, which is not easy to fix. In addition, the
conversion of a function address to a function pointer would
require allocation of a TOC entry in the inferior's memory space,
with all its drawbacks. To be able to call C++ virtual methods in
the inferior (which are called via function pointers),
find_function_addr uses this function to get the function address
from a function pointer. */
/* If ADDR points at what is clearly a function descriptor, transform
it into the address of the corresponding function. Be
conservative, otherwize GDB will do the transformation on any
random addresses such as occures when there is no symbol table. */
static CORE_ADDR
ppc64_linux_convert_from_func_ptr_addr (struct gdbarch *gdbarch,
CORE_ADDR addr,
struct target_ops *targ)
{
struct section_table *s = target_section_by_addr (targ, addr);
/* Check if ADDR points to a function descriptor. */
if (s && strcmp (s->the_bfd_section->name, ".opd") == 0)
return get_target_memory_unsigned (targ, addr, 8);
return addr;
}
static void
right_supply_register (struct regcache *regcache, int wordsize, int regnum,
const bfd_byte *buf)
{
regcache_raw_supply (regcache, regnum,
(buf + wordsize - register_size (current_gdbarch, regnum)));
}
/* Extract the register values found in the WORDSIZED ABI GREGSET,
storing their values in REGCACHE. Note that some are left-aligned,
while others are right aligned. */
void
ppc_linux_supply_gregset (struct regcache *regcache,
int regnum, const void *gregs, size_t size,
int wordsize)
{
int regi;
struct gdbarch *regcache_arch = get_regcache_arch (regcache);
struct gdbarch_tdep *regcache_tdep = gdbarch_tdep (regcache_arch);
const bfd_byte *buf = gregs;
for (regi = 0; regi < ppc_num_gprs; regi++)
right_supply_register (regcache, wordsize,
regcache_tdep->ppc_gp0_regnum + regi,
buf + wordsize * regi);
right_supply_register (regcache, wordsize, gdbarch_pc_regnum (regcache_arch),
buf + wordsize * PPC_LINUX_PT_NIP);
right_supply_register (regcache, wordsize, regcache_tdep->ppc_lr_regnum,
buf + wordsize * PPC_LINUX_PT_LNK);
regcache_raw_supply (regcache, regcache_tdep->ppc_cr_regnum,
buf + wordsize * PPC_LINUX_PT_CCR);
regcache_raw_supply (regcache, regcache_tdep->ppc_xer_regnum,
buf + wordsize * PPC_LINUX_PT_XER);
regcache_raw_supply (regcache, regcache_tdep->ppc_ctr_regnum,
buf + wordsize * PPC_LINUX_PT_CTR);
if (regcache_tdep->ppc_mq_regnum != -1)
right_supply_register (regcache, wordsize, regcache_tdep->ppc_mq_regnum,
buf + wordsize * PPC_LINUX_PT_MQ);
right_supply_register (regcache, wordsize, regcache_tdep->ppc_ps_regnum,
buf + wordsize * PPC_LINUX_PT_MSR);
}
static void
ppc32_linux_supply_gregset (const struct regset *regset,
struct regcache *regcache,
int regnum, const void *gregs, size_t size)
{
ppc_linux_supply_gregset (regcache, regnum, gregs, size, 4);
}
static struct regset ppc32_linux_gregset = {
NULL, ppc32_linux_supply_gregset
};
struct ppc_linux_sigtramp_cache
{
CORE_ADDR base;
struct trad_frame_saved_reg *saved_regs;
};
static struct ppc_linux_sigtramp_cache *
ppc_linux_sigtramp_cache (struct frame_info *next_frame, void **this_cache)
{
CORE_ADDR regs;
CORE_ADDR gpregs;
CORE_ADDR fpregs;
int i;
struct ppc_linux_sigtramp_cache *cache;
struct gdbarch *gdbarch = get_frame_arch (next_frame);
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
if ((*this_cache) != NULL)
return (*this_cache);
cache = FRAME_OBSTACK_ZALLOC (struct ppc_linux_sigtramp_cache);
(*this_cache) = cache;
cache->saved_regs = trad_frame_alloc_saved_regs (next_frame);
cache->base = frame_unwind_register_unsigned (next_frame, SP_REGNUM);
/* Find the register pointer, which gives the address of the
register buffers. */
if (tdep->wordsize == 4)
regs = (cache->base
+ 0xd0 /* Offset to ucontext_t. */
+ 0x30 /* Offset to .reg. */);
else
regs = (cache->base
+ 0x80 /* Offset to ucontext_t. */
+ 0xe0 /* Offset to .reg. */);
/* And the corresponding register buffers. */
gpregs = read_memory_unsigned_integer (regs, tdep->wordsize);
fpregs = gpregs + 48 * tdep->wordsize;
/* General purpose. */
for (i = 0; i < ppc_num_gprs; i++)
{
int regnum = i + tdep->ppc_gp0_regnum;
cache->saved_regs[regnum].addr = gpregs + i * tdep->wordsize;
}
cache->saved_regs[PC_REGNUM].addr = gpregs + 32 * tdep->wordsize;
cache->saved_regs[tdep->ppc_ctr_regnum].addr = gpregs + 35 * tdep->wordsize;
cache->saved_regs[tdep->ppc_lr_regnum].addr = gpregs + 36 * tdep->wordsize;
cache->saved_regs[tdep->ppc_xer_regnum].addr = gpregs + 37 * tdep->wordsize;
cache->saved_regs[tdep->ppc_cr_regnum].addr = gpregs + 38 * tdep->wordsize;
/* Floating point registers. */
if (ppc_floating_point_unit_p (gdbarch))
{
for (i = 0; i < ppc_num_fprs; i++)
{
int regnum = i + tdep->ppc_fp0_regnum;
cache->saved_regs[regnum].addr = fpregs + i * tdep->wordsize;
}
cache->saved_regs[tdep->ppc_fpscr_regnum].addr
= fpregs + 32 * tdep->wordsize;
}
return cache;
}
static void
ppc_linux_sigtramp_this_id (struct frame_info *next_frame, void **this_cache,
struct frame_id *this_id)
{
struct ppc_linux_sigtramp_cache *info
= ppc_linux_sigtramp_cache (next_frame, this_cache);
(*this_id) = frame_id_build (info->base, frame_pc_unwind (next_frame));
}
static void
ppc_linux_sigtramp_prev_register (struct frame_info *next_frame,
void **this_cache,
int regnum, int *optimizedp,
enum lval_type *lvalp, CORE_ADDR *addrp,
int *realnump, void *valuep)
{
struct ppc_linux_sigtramp_cache *info
= ppc_linux_sigtramp_cache (next_frame, this_cache);
trad_frame_get_prev_register (next_frame, info->saved_regs, regnum,
optimizedp, lvalp, addrp, realnump, valuep);
}
static const struct frame_unwind ppc_linux_sigtramp_unwind =
{
SIGTRAMP_FRAME,
ppc_linux_sigtramp_this_id,
ppc_linux_sigtramp_prev_register
};
static const struct frame_unwind *
ppc_linux_sigtramp_sniffer (struct frame_info *next_frame)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (get_frame_arch (next_frame));
if (frame_pc_unwind (next_frame)
> frame_unwind_register_unsigned (next_frame, SP_REGNUM))
/* Assume anything that is vaguely on the stack is a signal
trampoline. */
return &ppc_linux_sigtramp_unwind;
else
return NULL;
}
static void
ppc64_linux_supply_gregset (const struct regset *regset,
struct regcache * regcache,
int regnum, const void *gregs, size_t size)
{
ppc_linux_supply_gregset (regcache, regnum, gregs, size, 8);
}
static struct regset ppc64_linux_gregset = {
NULL, ppc64_linux_supply_gregset
};
void
ppc_linux_supply_fpregset (const struct regset *regset,
struct regcache * regcache,
int regnum, const void *fpset, size_t size)
{
int regi;
struct gdbarch *regcache_arch = get_regcache_arch (regcache);
struct gdbarch_tdep *regcache_tdep = gdbarch_tdep (regcache_arch);
const bfd_byte *buf = fpset;
if (! ppc_floating_point_unit_p (regcache_arch))
return;
for (regi = 0; regi < ppc_num_fprs; regi++)
regcache_raw_supply (regcache,
regcache_tdep->ppc_fp0_regnum + regi,
buf + 8 * regi);
/* The FPSCR is stored in the low order word of the last
doubleword in the fpregset. */
regcache_raw_supply (regcache, regcache_tdep->ppc_fpscr_regnum,
buf + 8 * 32 + 4);
}
static struct regset ppc_linux_fpregset = { NULL, ppc_linux_supply_fpregset };
static const struct regset *
ppc_linux_regset_from_core_section (struct gdbarch *core_arch,
const char *sect_name, size_t sect_size)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (core_arch);
if (strcmp (sect_name, ".reg") == 0)
{
if (tdep->wordsize == 4)
return &ppc32_linux_gregset;
else
return &ppc64_linux_gregset;
}
if (strcmp (sect_name, ".reg2") == 0)
return &ppc_linux_fpregset;
return NULL;
}
static void
ppc_linux_init_abi (struct gdbarch_info info,
struct gdbarch *gdbarch)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
if (tdep->wordsize == 4)
{
/* NOTE: jimb/2004-03-26: The System V ABI PowerPC Processor
Supplement says that long doubles are sixteen bytes long.
However, as one of the known warts of its ABI, PPC GNU/Linux
uses eight-byte long doubles. GCC only recently got 128-bit
long double support on PPC, so it may be changing soon. The
Linux[sic] Standards Base says that programs that use 'long
double' on PPC GNU/Linux are non-conformant. */
set_gdbarch_long_double_bit (gdbarch, 8 * TARGET_CHAR_BIT);
/* Until November 2001, gcc did not comply with the 32 bit SysV
R4 ABI requirement that structures less than or equal to 8
bytes should be returned in registers. Instead GCC was using
the the AIX/PowerOpen ABI - everything returned in memory
(well ignoring vectors that is). When this was corrected, it
wasn't fixed for GNU/Linux native platform. Use the
PowerOpen struct convention. */
set_gdbarch_return_value (gdbarch, ppc_linux_return_value);
set_gdbarch_memory_remove_breakpoint (gdbarch,
ppc_linux_memory_remove_breakpoint);
/* Shared library handling. */
set_gdbarch_skip_trampoline_code (gdbarch,
ppc_linux_skip_trampoline_code);
set_solib_svr4_fetch_link_map_offsets
(gdbarch, ppc_linux_svr4_fetch_link_map_offsets);
}
if (tdep->wordsize == 8)
{
/* Handle PPC64 GNU/Linux function pointers (which are really
function descriptors). */
set_gdbarch_convert_from_func_ptr_addr
(gdbarch, ppc64_linux_convert_from_func_ptr_addr);
set_gdbarch_skip_trampoline_code (gdbarch, ppc64_skip_trampoline_code);
/* PPC64 malloc's entry-point is called ".malloc". */
set_gdbarch_name_of_malloc (gdbarch, ".malloc");
}
set_gdbarch_regset_from_core_section (gdbarch, ppc_linux_regset_from_core_section);
frame_unwind_append_sniffer (gdbarch, ppc_linux_sigtramp_sniffer);
}
void
_initialize_ppc_linux_tdep (void)
{
/* Register for all sub-familes of the POWER/PowerPC: 32-bit and
64-bit PowerPC, and the older rs6k. */
gdbarch_register_osabi (bfd_arch_powerpc, bfd_mach_ppc, GDB_OSABI_LINUX,
ppc_linux_init_abi);
gdbarch_register_osabi (bfd_arch_powerpc, bfd_mach_ppc64, GDB_OSABI_LINUX,
ppc_linux_init_abi);
gdbarch_register_osabi (bfd_arch_rs6000, bfd_mach_rs6k, GDB_OSABI_LINUX,
ppc_linux_init_abi);
}