binutils-gdb/gdb/arm-linux-tdep.c
2001-07-15 20:10:02 +00:00

523 lines
17 KiB
C

/* GNU/Linux on ARM target support.
Copyright 1999, 2000, 2001 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 "target.h"
#include "value.h"
#include "gdbtypes.h"
#include "floatformat.h"
#include "gdbcore.h"
#include "frame.h"
#include "regcache.h"
/* For arm_linux_skip_solib_resolver. */
#include "symtab.h"
#include "symfile.h"
#include "objfiles.h"
#ifdef GET_LONGJMP_TARGET
/* Figure out where the longjmp will land. We expect that we have
just entered longjmp and haven't yet altered r0, r1, so the
arguments are still in the registers. (A1_REGNUM) points at the
jmp_buf structure from which we extract the pc (JB_PC) that we will
land at. The pc is copied into ADDR. This routine returns true on
success. */
#define LONGJMP_TARGET_SIZE sizeof(int)
#define JB_ELEMENT_SIZE sizeof(int)
#define JB_SL 18
#define JB_FP 19
#define JB_SP 20
#define JB_PC 21
int
arm_get_longjmp_target (CORE_ADDR * pc)
{
CORE_ADDR jb_addr;
char buf[LONGJMP_TARGET_SIZE];
jb_addr = read_register (A1_REGNUM);
if (target_read_memory (jb_addr + JB_PC * JB_ELEMENT_SIZE, buf,
LONGJMP_TARGET_SIZE))
return 0;
*pc = extract_address (buf, LONGJMP_TARGET_SIZE);
return 1;
}
#endif /* GET_LONGJMP_TARGET */
/* Extract from an array REGBUF containing the (raw) register state
a function return value of type TYPE, and copy that, in virtual format,
into VALBUF. */
void
arm_linux_extract_return_value (struct type *type,
char regbuf[REGISTER_BYTES],
char *valbuf)
{
/* ScottB: This needs to be looked at to handle the different
floating point emulators on ARM Linux. Right now the code
assumes that fetch inferior registers does the right thing for
GDB. I suspect this won't handle NWFPE registers correctly, nor
will the default ARM version (arm_extract_return_value()). */
int regnum = (TYPE_CODE_FLT == TYPE_CODE (type)) ? F0_REGNUM : A1_REGNUM;
memcpy (valbuf, &regbuf[REGISTER_BYTE (regnum)], TYPE_LENGTH (type));
}
/* Note: ScottB
This function does not support passing parameters using the FPA
variant of the APCS. It passes any floating point arguments in the
general registers and/or on the stack.
FIXME: This and arm_push_arguments should be merged. However this
function breaks on a little endian host, big endian target
using the COFF file format. ELF is ok.
ScottB. */
/* Addresses for calling Thumb functions have the bit 0 set.
Here are some macros to test, set, or clear bit 0 of addresses. */
#define IS_THUMB_ADDR(addr) ((addr) & 1)
#define MAKE_THUMB_ADDR(addr) ((addr) | 1)
#define UNMAKE_THUMB_ADDR(addr) ((addr) & ~1)
CORE_ADDR
arm_linux_push_arguments (int nargs, struct value **args, CORE_ADDR sp,
int struct_return, CORE_ADDR struct_addr)
{
char *fp;
int argnum, argreg, nstack_size;
/* Walk through the list of args and determine how large a temporary
stack is required. Need to take care here as structs may be
passed on the stack, and we have to to push them. */
nstack_size = -4 * REGISTER_SIZE; /* Some arguments go into A1-A4. */
if (struct_return) /* The struct address goes in A1. */
nstack_size += REGISTER_SIZE;
/* Walk through the arguments and add their size to nstack_size. */
for (argnum = 0; argnum < nargs; argnum++)
{
int len;
struct type *arg_type;
arg_type = check_typedef (VALUE_TYPE (args[argnum]));
len = TYPE_LENGTH (arg_type);
/* ANSI C code passes float arguments as integers, K&R code
passes float arguments as doubles. Correct for this here. */
if (TYPE_CODE_FLT == TYPE_CODE (arg_type) && REGISTER_SIZE == len)
nstack_size += FP_REGISTER_VIRTUAL_SIZE;
else
nstack_size += len;
}
/* Allocate room on the stack, and initialize our stack frame
pointer. */
fp = NULL;
if (nstack_size > 0)
{
sp -= nstack_size;
fp = (char *) sp;
}
/* Initialize the integer argument register pointer. */
argreg = A1_REGNUM;
/* The struct_return pointer occupies the first parameter passing
register. */
if (struct_return)
write_register (argreg++, struct_addr);
/* Process arguments from left to right. Store as many as allowed
in the parameter passing registers (A1-A4), and save the rest on
the temporary stack. */
for (argnum = 0; argnum < nargs; argnum++)
{
int len;
char *val;
double dbl_arg;
CORE_ADDR regval;
enum type_code typecode;
struct type *arg_type, *target_type;
arg_type = check_typedef (VALUE_TYPE (args[argnum]));
target_type = TYPE_TARGET_TYPE (arg_type);
len = TYPE_LENGTH (arg_type);
typecode = TYPE_CODE (arg_type);
val = (char *) VALUE_CONTENTS (args[argnum]);
/* ANSI C code passes float arguments as integers, K&R code
passes float arguments as doubles. The .stabs record for
for ANSI prototype floating point arguments records the
type as FP_INTEGER, while a K&R style (no prototype)
.stabs records the type as FP_FLOAT. In this latter case
the compiler converts the float arguments to double before
calling the function. */
if (TYPE_CODE_FLT == typecode && REGISTER_SIZE == len)
{
/* Float argument in buffer is in host format. Read it and
convert to DOUBLEST, and store it in target double. */
DOUBLEST dblval;
len = TARGET_DOUBLE_BIT / TARGET_CHAR_BIT;
floatformat_to_doublest (HOST_FLOAT_FORMAT, val, &dblval);
store_floating (&dbl_arg, len, dblval);
val = (char *) &dbl_arg;
}
/* If the argument is a pointer to a function, and it is a Thumb
function, set the low bit of the pointer. */
if (TYPE_CODE_PTR == typecode
&& NULL != target_type
&& TYPE_CODE_FUNC == TYPE_CODE (target_type))
{
CORE_ADDR regval = extract_address (val, len);
if (arm_pc_is_thumb (regval))
store_address (val, len, MAKE_THUMB_ADDR (regval));
}
/* Copy the argument to general registers or the stack in
register-sized pieces. Large arguments are split between
registers and stack. */
while (len > 0)
{
int partial_len = len < REGISTER_SIZE ? len : REGISTER_SIZE;
if (argreg <= ARM_LAST_ARG_REGNUM)
{
/* It's an argument being passed in a general register. */
regval = extract_address (val, partial_len);
write_register (argreg++, regval);
}
else
{
/* Push the arguments onto the stack. */
write_memory ((CORE_ADDR) fp, val, REGISTER_SIZE);
fp += REGISTER_SIZE;
}
len -= partial_len;
val += partial_len;
}
}
/* Return adjusted stack pointer. */
return sp;
}
/*
Dynamic Linking on ARM Linux
----------------------------
Note: PLT = procedure linkage table
GOT = global offset table
As much as possible, ELF dynamic linking defers the resolution of
jump/call addresses until the last minute. The technique used is
inspired by the i386 ELF design, and is based on the following
constraints.
1) The calling technique should not force a change in the assembly
code produced for apps; it MAY cause changes in the way assembly
code is produced for position independent code (i.e. shared
libraries).
2) The technique must be such that all executable areas must not be
modified; and any modified areas must not be executed.
To do this, there are three steps involved in a typical jump:
1) in the code
2) through the PLT
3) using a pointer from the GOT
When the executable or library is first loaded, each GOT entry is
initialized to point to the code which implements dynamic name
resolution and code finding. This is normally a function in the
program interpreter (on ARM Linux this is usually ld-linux.so.2,
but it does not have to be). On the first invocation, the function
is located and the GOT entry is replaced with the real function
address. Subsequent calls go through steps 1, 2 and 3 and end up
calling the real code.
1) In the code:
b function_call
bl function_call
This is typical ARM code using the 26 bit relative branch or branch
and link instructions. The target of the instruction
(function_call is usually the address of the function to be called.
In position independent code, the target of the instruction is
actually an entry in the PLT when calling functions in a shared
library. Note that this call is identical to a normal function
call, only the target differs.
2) In the PLT:
The PLT is a synthetic area, created by the linker. It exists in
both executables and libraries. It is an array of stubs, one per
imported function call. It looks like this:
PLT[0]:
str lr, [sp, #-4]! @push the return address (lr)
ldr lr, [pc, #16] @load from 6 words ahead
add lr, pc, lr @form an address for GOT[0]
ldr pc, [lr, #8]! @jump to the contents of that addr
The return address (lr) is pushed on the stack and used for
calculations. The load on the second line loads the lr with
&GOT[3] - . - 20. The addition on the third leaves:
lr = (&GOT[3] - . - 20) + (. + 8)
lr = (&GOT[3] - 12)
lr = &GOT[0]
On the fourth line, the pc and lr are both updated, so that:
pc = GOT[2]
lr = &GOT[0] + 8
= &GOT[2]
NOTE: PLT[0] borrows an offset .word from PLT[1]. This is a little
"tight", but allows us to keep all the PLT entries the same size.
PLT[n+1]:
ldr ip, [pc, #4] @load offset from gotoff
add ip, pc, ip @add the offset to the pc
ldr pc, [ip] @jump to that address
gotoff: .word GOT[n+3] - .
The load on the first line, gets an offset from the fourth word of
the PLT entry. The add on the second line makes ip = &GOT[n+3],
which contains either a pointer to PLT[0] (the fixup trampoline) or
a pointer to the actual code.
3) In the GOT:
The GOT contains helper pointers for both code (PLT) fixups and
data fixups. The first 3 entries of the GOT are special. The next
M entries (where M is the number of entries in the PLT) belong to
the PLT fixups. The next D (all remaining) entries belong to
various data fixups. The actual size of the GOT is 3 + M + D.
The GOT is also a synthetic area, created by the linker. It exists
in both executables and libraries. When the GOT is first
initialized , all the GOT entries relating to PLT fixups are
pointing to code back at PLT[0].
The special entries in the GOT are:
GOT[0] = linked list pointer used by the dynamic loader
GOT[1] = pointer to the reloc table for this module
GOT[2] = pointer to the fixup/resolver code
The first invocation of function call comes through and uses the
fixup/resolver code. On the entry to the fixup/resolver code:
ip = &GOT[n+3]
lr = &GOT[2]
stack[0] = return address (lr) of the function call
[r0, r1, r2, r3] are still the arguments to the function call
This is enough information for the fixup/resolver code to work
with. Before the fixup/resolver code returns, it actually calls
the requested function and repairs &GOT[n+3]. */
/* Find the minimal symbol named NAME, and return both the minsym
struct and its objfile. This probably ought to be in minsym.c, but
everything there is trying to deal with things like C++ and
SOFUN_ADDRESS_MAYBE_TURQUOISE, ... Since this is so simple, it may
be considered too special-purpose for general consumption. */
static struct minimal_symbol *
find_minsym_and_objfile (char *name, struct objfile **objfile_p)
{
struct objfile *objfile;
ALL_OBJFILES (objfile)
{
struct minimal_symbol *msym;
ALL_OBJFILE_MSYMBOLS (objfile, msym)
{
if (SYMBOL_NAME (msym)
&& STREQ (SYMBOL_NAME (msym), name))
{
*objfile_p = objfile;
return msym;
}
}
}
return 0;
}
static CORE_ADDR
skip_hurd_resolver (CORE_ADDR pc)
{
/* The HURD dynamic linker is part of the GNU C library, so many
GNU/Linux distributions use it. (All ELF versions, as far as I
know.) An unresolved PLT entry points to "_dl_runtime_resolve",
which calls "fixup" to patch the PLT, and then passes control to
the function.
We look for the symbol `_dl_runtime_resolve', and find `fixup' in
the same objfile. If we are at the entry point of `fixup', then
we set a breakpoint at the return address (at the top of the
stack), and continue.
It's kind of gross to do all these checks every time we're
called, since they don't change once the executable has gotten
started. But this is only a temporary hack --- upcoming versions
of Linux will provide a portable, efficient interface for
debugging programs that use shared libraries. */
struct objfile *objfile;
struct minimal_symbol *resolver
= find_minsym_and_objfile ("_dl_runtime_resolve", &objfile);
if (resolver)
{
struct minimal_symbol *fixup
= lookup_minimal_symbol ("fixup", 0, objfile);
if (fixup && SYMBOL_VALUE_ADDRESS (fixup) == pc)
return (SAVED_PC_AFTER_CALL (get_current_frame ()));
}
return 0;
}
/* See the comments for SKIP_SOLIB_RESOLVER at the top of infrun.c.
This function:
1) decides whether a PLT has sent us into the linker to resolve
a function reference, and
2) if so, tells us where to set a temporary breakpoint that will
trigger when the dynamic linker is done. */
CORE_ADDR
arm_linux_skip_solib_resolver (CORE_ADDR pc)
{
CORE_ADDR result;
/* Plug in functions for other kinds of resolvers here. */
result = skip_hurd_resolver (pc);
if (result)
return result;
return 0;
}
/* The constants below were determined by examining the following files
in the linux kernel sources:
arch/arm/kernel/signal.c
- see SWI_SYS_SIGRETURN and SWI_SYS_RT_SIGRETURN
include/asm-arm/unistd.h
- see __NR_sigreturn, __NR_rt_sigreturn, and __NR_SYSCALL_BASE */
#define ARM_LINUX_SIGRETURN_INSTR 0xef900077
#define ARM_LINUX_RT_SIGRETURN_INSTR 0xef9000ad
/* arm_linux_in_sigtramp determines if PC points at one of the
instructions which cause control to return to the Linux kernel upon
return from a signal handler. FUNC_NAME is unused. */
int
arm_linux_in_sigtramp (CORE_ADDR pc, char *func_name)
{
unsigned long inst;
inst = read_memory_integer (pc, 4);
return (inst == ARM_LINUX_SIGRETURN_INSTR
|| inst == ARM_LINUX_RT_SIGRETURN_INSTR);
}
/* arm_linux_sigcontext_register_address returns the address in the
sigcontext of register REGNO given a stack pointer value SP and
program counter value PC. The value 0 is returned if PC is not
pointing at one of the signal return instructions or if REGNO is
not saved in the sigcontext struct. */
CORE_ADDR
arm_linux_sigcontext_register_address (CORE_ADDR sp, CORE_ADDR pc, int regno)
{
unsigned long inst;
CORE_ADDR reg_addr = 0;
inst = read_memory_integer (pc, 4);
if (inst == ARM_LINUX_SIGRETURN_INSTR || inst == ARM_LINUX_RT_SIGRETURN_INSTR)
{
CORE_ADDR sigcontext_addr;
/* The sigcontext structure is at different places for the two
signal return instructions. For ARM_LINUX_SIGRETURN_INSTR,
it starts at the SP value. For ARM_LINUX_RT_SIGRETURN_INSTR,
it is at SP+8. For the latter instruction, it may also be
the case that the address of this structure may be determined
by reading the 4 bytes at SP, but I'm not convinced this is
reliable.
In any event, these magic constants (0 and 8) may be
determined by examining struct sigframe and struct
rt_sigframe in arch/arm/kernel/signal.c in the Linux kernel
sources. */
if (inst == ARM_LINUX_RT_SIGRETURN_INSTR)
sigcontext_addr = sp + 8;
else /* inst == ARM_LINUX_SIGRETURN_INSTR */
sigcontext_addr = sp + 0;
/* The layout of the sigcontext structure for ARM GNU/Linux is
in include/asm-arm/sigcontext.h in the Linux kernel sources.
There are three 4-byte fields which precede the saved r0
field. (This accounts for the 12 in the code below.) The
sixteen registers (4 bytes per field) follow in order. The
PSR value follows the sixteen registers which accounts for
the constant 19 below. */
if (0 <= regno && regno <= PC_REGNUM)
reg_addr = sigcontext_addr + 12 + (4 * regno);
else if (regno == PS_REGNUM)
reg_addr = sigcontext_addr + 19 * 4;
}
return reg_addr;
}
void
_initialize_arm_linux_tdep (void)
{
}