gdb/i386-linux-tdep.c - binutils-gdb - Git at Google

 /* Target-dependent code for GNU/Linux running on i386's, for GDB.

    Copyright 2000, 2001, 2002, 2003 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 "gdbcore.h"
 #include "frame.h"
 #include "value.h"
 #include "regcache.h"
 #include "inferior.h"
 #include "reggroups.h"

 /* For i386_linux_skip_solib_resolver.  */
 #include "symtab.h"
 #include "symfile.h"
 #include "objfiles.h"

 #include "solib-svr4.h"		/* For struct link_map_offsets.  */

 #include "osabi.h"

 #include "i386-tdep.h"
 #include "i386-linux-tdep.h"

 /* Return the name of register REG.  */

 static const char *
 i386_linux_register_name (int reg)
 {
   /* Deal with the extra "orig_eax" pseudo register.  */
   if (reg == I386_LINUX_ORIG_EAX_REGNUM)
     return "orig_eax";

   return i386_register_name (reg);
 }

 /* Return non-zero, when the register is in the corresponding register
    group.  Put the LINUX_ORIG_EAX register in the system group.  */
 static int
 i386_linux_register_reggroup_p (struct gdbarch *gdbarch, int regnum,
 				struct reggroup *group)
 {
   if (regnum == I386_LINUX_ORIG_EAX_REGNUM)
     return (group == system_reggroup
 	    || group == save_reggroup
 	    || group == restore_reggroup);
   return i386_register_reggroup_p (gdbarch, regnum, group);
 }


 /* Recognizing signal handler frames.  */

 /* GNU/Linux has two flavors of signals.  Normal signal handlers, and
    "realtime" (RT) signals.  The RT signals can provide additional
    information to the signal handler if the SA_SIGINFO flag is set
    when establishing a signal handler using `sigaction'.  It is not
    unlikely that future versions of GNU/Linux will support SA_SIGINFO
    for normal signals too.  */

 /* When the i386 Linux kernel calls a signal handler and the
    SA_RESTORER flag isn't set, the return address points to a bit of
    code on the stack.  This function returns whether the PC appears to
    be within this bit of code.

    The instruction sequence for normal signals is
        pop    %eax
        mov    $0x77,%eax
        int    $0x80
    or 0x58 0xb8 0x77 0x00 0x00 0x00 0xcd 0x80.

    Checking for the code sequence should be somewhat reliable, because
    the effect is to call the system call sigreturn.  This is unlikely
    to occur anywhere other than a signal trampoline.

    It kind of sucks that we have to read memory from the process in
    order to identify a signal trampoline, but there doesn't seem to be
    any other way.  The PC_IN_SIGTRAMP macro in tm-linux.h arranges to
    only call us if no function name could be identified, which should
    be the case since the code is on the stack.

    Detection of signal trampolines for handlers that set the
    SA_RESTORER flag is in general not possible.  Unfortunately this is
    what the GNU C Library has been doing for quite some time now.
    However, as of version 2.1.2, the GNU C Library uses signal
    trampolines (named __restore and __restore_rt) that are identical
    to the ones used by the kernel.  Therefore, these trampolines are
    supported too.  */

 #define LINUX_SIGTRAMP_INSN0 (0x58)	/* pop %eax */
 #define LINUX_SIGTRAMP_OFFSET0 (0)
 #define LINUX_SIGTRAMP_INSN1 (0xb8)	/* mov $NNNN,%eax */
 #define LINUX_SIGTRAMP_OFFSET1 (1)
 #define LINUX_SIGTRAMP_INSN2 (0xcd)	/* int */
 #define LINUX_SIGTRAMP_OFFSET2 (6)

 static const unsigned char linux_sigtramp_code[] =
 {
   LINUX_SIGTRAMP_INSN0,					/* pop %eax */
   LINUX_SIGTRAMP_INSN1, 0x77, 0x00, 0x00, 0x00,		/* mov $0x77,%eax */
   LINUX_SIGTRAMP_INSN2, 0x80				/* int $0x80 */
 };

 #define LINUX_SIGTRAMP_LEN (sizeof linux_sigtramp_code)

 /* If PC is in a sigtramp routine, return the address of the start of
    the routine.  Otherwise, return 0.  */

 static CORE_ADDR
 i386_linux_sigtramp_start (CORE_ADDR pc)
 {
   unsigned char buf[LINUX_SIGTRAMP_LEN];

   /* We only recognize a signal trampoline if PC is at the start of
      one of the three instructions.  We optimize for finding the PC at
      the start, as will be the case when the trampoline is not the
      first frame on the stack.  We assume that in the case where the
      PC is not at the start of the instruction sequence, there will be
      a few trailing readable bytes on the stack.  */

   if (read_memory_nobpt (pc, (char *) buf, LINUX_SIGTRAMP_LEN) != 0)
     return 0;

   if (buf[0] != LINUX_SIGTRAMP_INSN0)
     {
       int adjust;

       switch (buf[0])
 	{
 	case LINUX_SIGTRAMP_INSN1:
 	  adjust = LINUX_SIGTRAMP_OFFSET1;
 	  break;
 	case LINUX_SIGTRAMP_INSN2:
 	  adjust = LINUX_SIGTRAMP_OFFSET2;
 	  break;
 	default:
 	  return 0;
 	}

       pc -= adjust;

       if (read_memory_nobpt (pc, (char *) buf, LINUX_SIGTRAMP_LEN) != 0)
 	return 0;
     }

   if (memcmp (buf, linux_sigtramp_code, LINUX_SIGTRAMP_LEN) != 0)
     return 0;

   return pc;
 }

 /* This function does the same for RT signals.  Here the instruction
    sequence is
        mov    $0xad,%eax
        int    $0x80
    or 0xb8 0xad 0x00 0x00 0x00 0xcd 0x80.

    The effect is to call the system call rt_sigreturn.  */

 #define LINUX_RT_SIGTRAMP_INSN0 (0xb8)	/* mov $NNNN,%eax */
 #define LINUX_RT_SIGTRAMP_OFFSET0 (0)
 #define LINUX_RT_SIGTRAMP_INSN1 (0xcd)	/* int */
 #define LINUX_RT_SIGTRAMP_OFFSET1 (5)

 static const unsigned char linux_rt_sigtramp_code[] =
 {
   LINUX_RT_SIGTRAMP_INSN0, 0xad, 0x00, 0x00, 0x00,	/* mov $0xad,%eax */
   LINUX_RT_SIGTRAMP_INSN1, 0x80				/* int $0x80 */
 };

 #define LINUX_RT_SIGTRAMP_LEN (sizeof linux_rt_sigtramp_code)

 /* If PC is in a RT sigtramp routine, return the address of the start
    of the routine.  Otherwise, return 0.  */

 static CORE_ADDR
 i386_linux_rt_sigtramp_start (CORE_ADDR pc)
 {
   unsigned char buf[LINUX_RT_SIGTRAMP_LEN];

   /* We only recognize a signal trampoline if PC is at the start of
      one of the two instructions.  We optimize for finding the PC at
      the start, as will be the case when the trampoline is not the
      first frame on the stack.  We assume that in the case where the
      PC is not at the start of the instruction sequence, there will be
      a few trailing readable bytes on the stack.  */

   if (read_memory_nobpt (pc, (char *) buf, LINUX_RT_SIGTRAMP_LEN) != 0)
     return 0;

   if (buf[0] != LINUX_RT_SIGTRAMP_INSN0)
     {
       if (buf[0] != LINUX_RT_SIGTRAMP_INSN1)
 	return 0;

       pc -= LINUX_RT_SIGTRAMP_OFFSET1;

       if (read_memory_nobpt (pc, (char *) buf, LINUX_RT_SIGTRAMP_LEN) != 0)
 	return 0;
     }

   if (memcmp (buf, linux_rt_sigtramp_code, LINUX_RT_SIGTRAMP_LEN) != 0)
     return 0;

   return pc;
 }

 /* Return whether PC is in a GNU/Linux sigtramp routine.  */

 static int
 i386_linux_pc_in_sigtramp (CORE_ADDR pc, char *name)
 {
   /* If we have NAME, we can optimize the search.  The trampolines are
      named __restore and __restore_rt.  However, they aren't dynamically
      exported from the shared C library, so the trampoline may appear to
      be part of the preceding function.  This should always be sigaction,
      __sigaction, or __libc_sigaction (all aliases to the same function).  */
   if (name == NULL || strstr (name, "sigaction") != NULL)
     return (i386_linux_sigtramp_start (pc) != 0
 	    || i386_linux_rt_sigtramp_start (pc) != 0);

   return (strcmp ("__restore", name) == 0
 	  || strcmp ("__restore_rt", name) == 0);
 }

 /* Assuming FRAME is for a GNU/Linux sigtramp routine, return the
    address of the associated sigcontext structure.  */

 static CORE_ADDR
 i386_linux_sigcontext_addr (struct frame_info *frame)
 {
   CORE_ADDR pc;

   pc = i386_linux_sigtramp_start (get_frame_pc (frame));
   if (pc)
     {
       CORE_ADDR sp;

       if (get_next_frame (frame))
 	/* If this isn't the top frame, the next frame must be for the
 	   signal handler itself.  The sigcontext structure lives on
 	   the stack, right after the signum argument.  */
 	return get_frame_base (get_next_frame (frame)) + 12;

       /* This is the top frame.  We'll have to find the address of the
 	 sigcontext structure by looking at the stack pointer.  Keep
 	 in mind that the first instruction of the sigtramp code is
 	 "pop %eax".  If the PC is at this instruction, adjust the
 	 returned value accordingly.  */
       sp = read_register (SP_REGNUM);
       if (pc == get_frame_pc (frame))
 	return sp + 4;
       return sp;
     }

   pc = i386_linux_rt_sigtramp_start (get_frame_pc (frame));
   if (pc)
     {
       if (get_next_frame (frame))
 	/* If this isn't the top frame, the next frame must be for the
 	   signal handler itself.  The sigcontext structure is part of
 	   the user context.  A pointer to the user context is passed
 	   as the third argument to the signal handler.  */
 	return read_memory_integer (get_frame_base (get_next_frame (frame))
 				    + 16, 4) + 20;

       /* This is the top frame.  Again, use the stack pointer to find
 	 the address of the sigcontext structure.  */
       return read_memory_integer (read_register (SP_REGNUM) + 8, 4) + 20;
     }

   error ("Couldn't recognize signal trampoline.");
   return 0;
 }

 /* Set the program counter for process PTID to PC.  */

 static void
 i386_linux_write_pc (CORE_ADDR pc, ptid_t ptid)
 {
   write_register_pid (PC_REGNUM, pc, ptid);

   /* We must be careful with modifying the program counter.  If we
      just interrupted a system call, the kernel might try to restart
      it when we resume the inferior.  On restarting the system call,
      the kernel will try backing up the program counter even though it
      no longer points at the system call.  This typically results in a
      SIGSEGV or SIGILL.  We can prevent this by writing `-1' in the
      "orig_eax" pseudo-register.

      Note that "orig_eax" is saved when setting up a dummy call frame.
      This means that it is properly restored when that frame is
      popped, and that the interrupted system call will be restarted
      when we resume the inferior on return from a function call from
      within GDB.  In all other cases the system call will not be
      restarted.  */
   write_register_pid (I386_LINUX_ORIG_EAX_REGNUM, -1, ptid);
 }

 /* Calling functions in shared libraries.  */

 /* 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_LINKAGE_NAME (msym)
 	      && strcmp (SYMBOL_LINKAGE_NAME (msym), name) == 0)
 	    {
 	      *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 GNU/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", NULL, objfile);

       if (fixup && SYMBOL_VALUE_ADDRESS (fixup) == pc)
 	return (DEPRECATED_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
 i386_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;
 }

 /* Fetch (and possibly build) an appropriate link_map_offsets
    structure for native GNU/Linux x86 targets using the struct offsets
    defined in link.h (but without actual reference to that file).

    This makes it possible to access GNU/Linux x86 shared libraries
    from a GDB that was not built on an GNU/Linux x86 host (for cross
    debugging).  */

 static struct link_map_offsets *
 i386_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 552 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;
 }


 static void
 i386_linux_init_abi (struct gdbarch_info info, struct gdbarch *gdbarch)
 {
   struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);

   /* GNU/Linux uses ELF.  */
   i386_elf_init_abi (info, gdbarch);

   /* We support the SSE registers on GNU/Linux.  */
   tdep->num_xmm_regs = I386_NUM_XREGS - 1;
   /* set_gdbarch_num_regs (gdbarch, I386_SSE_NUM_REGS); */

   /* Since we have the extra "orig_eax" register on GNU/Linux, we have
      to adjust a few things.  */

   set_gdbarch_write_pc (gdbarch, i386_linux_write_pc);
   set_gdbarch_num_regs (gdbarch, I386_SSE_NUM_REGS + 1);
   set_gdbarch_register_name (gdbarch, i386_linux_register_name);
   set_gdbarch_register_reggroup_p (gdbarch, i386_linux_register_reggroup_p);
   set_gdbarch_register_bytes (gdbarch, I386_SSE_SIZEOF_REGS + 4);

   tdep->jb_pc_offset = 20;	/* From <bits/setjmp.h>.  */

   tdep->sigcontext_addr = i386_linux_sigcontext_addr;
   tdep->sc_pc_offset = 14 * 4;	/* From <asm/sigcontext.h>.  */
   tdep->sc_sp_offset = 7 * 4;

   /* When the i386 Linux kernel calls a signal handler, the return
      address points to a bit of code on the stack.  This function is
      used to identify this bit of code as a signal trampoline in order
      to support backtracing through calls to signal handlers.  */
   set_gdbarch_pc_in_sigtramp (gdbarch, i386_linux_pc_in_sigtramp);

   set_solib_svr4_fetch_link_map_offsets (gdbarch,
 				       i386_linux_svr4_fetch_link_map_offsets);
 }

 /* Provide a prototype to silence -Wmissing-prototypes.  */
 extern void _initialize_i386_linux_tdep (void);

 void
 _initialize_i386_linux_tdep (void)
 {
   gdbarch_register_osabi (bfd_arch_i386, 0, GDB_OSABI_LINUX,
 			  i386_linux_init_abi);
 }
	/* Target-dependent code for GNU/Linux running on i386's, for GDB.

	Copyright 2000, 2001, 2002, 2003 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 "gdbcore.h"
	#include "frame.h"
	#include "value.h"
	#include "regcache.h"
	#include "inferior.h"
	#include "reggroups.h"

	/* For i386_linux_skip_solib_resolver. */
	#include "symtab.h"
	#include "symfile.h"
	#include "objfiles.h"

	#include "solib-svr4.h" /* For struct link_map_offsets. */

	#include "osabi.h"

	#include "i386-tdep.h"
	#include "i386-linux-tdep.h"

	/* Return the name of register REG. */

	static const char *
	i386_linux_register_name (int reg)
	{
	/* Deal with the extra "orig_eax" pseudo register. */
	if (reg == I386_LINUX_ORIG_EAX_REGNUM)
	return "orig_eax";

	return i386_register_name (reg);
	}

	/* Return non-zero, when the register is in the corresponding register
	group. Put the LINUX_ORIG_EAX register in the system group. */
	static int
	i386_linux_register_reggroup_p (struct gdbarch *gdbarch, int regnum,
	struct reggroup *group)
	{
	if (regnum == I386_LINUX_ORIG_EAX_REGNUM)
	return (group == system_reggroup
	\|\| group == save_reggroup
	\|\| group == restore_reggroup);
	return i386_register_reggroup_p (gdbarch, regnum, group);
	}


	/* Recognizing signal handler frames. */

	/* GNU/Linux has two flavors of signals. Normal signal handlers, and
	"realtime" (RT) signals. The RT signals can provide additional
	information to the signal handler if the SA_SIGINFO flag is set
	when establishing a signal handler using `sigaction'. It is not
	unlikely that future versions of GNU/Linux will support SA_SIGINFO
	for normal signals too. */

	/* When the i386 Linux kernel calls a signal handler and the
	SA_RESTORER flag isn't set, the return address points to a bit of
	code on the stack. This function returns whether the PC appears to
	be within this bit of code.

	The instruction sequence for normal signals is
	pop %eax
	mov $0x77,%eax
	int $0x80
	or 0x58 0xb8 0x77 0x00 0x00 0x00 0xcd 0x80.

	Checking for the code sequence should be somewhat reliable, because
	the effect is to call the system call sigreturn. This is unlikely
	to occur anywhere other than a signal trampoline.

	It kind of sucks that we have to read memory from the process in
	order to identify a signal trampoline, but there doesn't seem to be
	any other way. The PC_IN_SIGTRAMP macro in tm-linux.h arranges to
	only call us if no function name could be identified, which should
	be the case since the code is on the stack.

	Detection of signal trampolines for handlers that set the
	SA_RESTORER flag is in general not possible. Unfortunately this is
	what the GNU C Library has been doing for quite some time now.
	However, as of version 2.1.2, the GNU C Library uses signal
	trampolines (named __restore and __restore_rt) that are identical
	to the ones used by the kernel. Therefore, these trampolines are
	supported too. */

	#define LINUX_SIGTRAMP_INSN0 (0x58) /* pop %eax */
	#define LINUX_SIGTRAMP_OFFSET0 (0)
	#define LINUX_SIGTRAMP_INSN1 (0xb8) /* mov $NNNN,%eax */
	#define LINUX_SIGTRAMP_OFFSET1 (1)
	#define LINUX_SIGTRAMP_INSN2 (0xcd) /* int */
	#define LINUX_SIGTRAMP_OFFSET2 (6)

	static const unsigned char linux_sigtramp_code[] =
	{
	LINUX_SIGTRAMP_INSN0, /* pop %eax */
	LINUX_SIGTRAMP_INSN1, 0x77, 0x00, 0x00, 0x00, /* mov $0x77,%eax */
	LINUX_SIGTRAMP_INSN2, 0x80 /* int $0x80 */
	};

	#define LINUX_SIGTRAMP_LEN (sizeof linux_sigtramp_code)

	/* If PC is in a sigtramp routine, return the address of the start of
	the routine. Otherwise, return 0. */

	static CORE_ADDR
	i386_linux_sigtramp_start (CORE_ADDR pc)
	{
	unsigned char buf[LINUX_SIGTRAMP_LEN];

	/* We only recognize a signal trampoline if PC is at the start of
	one of the three instructions. We optimize for finding the PC at
	the start, as will be the case when the trampoline is not the
	first frame on the stack. We assume that in the case where the
	PC is not at the start of the instruction sequence, there will be
	a few trailing readable bytes on the stack. */

	if (read_memory_nobpt (pc, (char *) buf, LINUX_SIGTRAMP_LEN) != 0)
	return 0;

	if (buf[0] != LINUX_SIGTRAMP_INSN0)
	{
	int adjust;

	switch (buf[0])
	{
	case LINUX_SIGTRAMP_INSN1:
	adjust = LINUX_SIGTRAMP_OFFSET1;
	break;
	case LINUX_SIGTRAMP_INSN2:
	adjust = LINUX_SIGTRAMP_OFFSET2;
	break;
	default:
	return 0;
	}

	pc -= adjust;

	if (read_memory_nobpt (pc, (char *) buf, LINUX_SIGTRAMP_LEN) != 0)
	return 0;
	}

	if (memcmp (buf, linux_sigtramp_code, LINUX_SIGTRAMP_LEN) != 0)
	return 0;

	return pc;
	}

	/* This function does the same for RT signals. Here the instruction
	sequence is
	mov $0xad,%eax
	int $0x80
	or 0xb8 0xad 0x00 0x00 0x00 0xcd 0x80.

	The effect is to call the system call rt_sigreturn. */

	#define LINUX_RT_SIGTRAMP_INSN0 (0xb8) /* mov $NNNN,%eax */
	#define LINUX_RT_SIGTRAMP_OFFSET0 (0)
	#define LINUX_RT_SIGTRAMP_INSN1 (0xcd) /* int */
	#define LINUX_RT_SIGTRAMP_OFFSET1 (5)

	static const unsigned char linux_rt_sigtramp_code[] =
	{
	LINUX_RT_SIGTRAMP_INSN0, 0xad, 0x00, 0x00, 0x00, /* mov $0xad,%eax */
	LINUX_RT_SIGTRAMP_INSN1, 0x80 /* int $0x80 */
	};

	#define LINUX_RT_SIGTRAMP_LEN (sizeof linux_rt_sigtramp_code)

	/* If PC is in a RT sigtramp routine, return the address of the start
	of the routine. Otherwise, return 0. */

	static CORE_ADDR
	i386_linux_rt_sigtramp_start (CORE_ADDR pc)
	{
	unsigned char buf[LINUX_RT_SIGTRAMP_LEN];

	/* We only recognize a signal trampoline if PC is at the start of
	one of the two instructions. We optimize for finding the PC at
	the start, as will be the case when the trampoline is not the
	first frame on the stack. We assume that in the case where the
	PC is not at the start of the instruction sequence, there will be
	a few trailing readable bytes on the stack. */

	if (read_memory_nobpt (pc, (char *) buf, LINUX_RT_SIGTRAMP_LEN) != 0)
	return 0;

	if (buf[0] != LINUX_RT_SIGTRAMP_INSN0)
	{
	if (buf[0] != LINUX_RT_SIGTRAMP_INSN1)
	return 0;

	pc -= LINUX_RT_SIGTRAMP_OFFSET1;

	if (read_memory_nobpt (pc, (char *) buf, LINUX_RT_SIGTRAMP_LEN) != 0)
	return 0;
	}

	if (memcmp (buf, linux_rt_sigtramp_code, LINUX_RT_SIGTRAMP_LEN) != 0)
	return 0;

	return pc;
	}

	/* Return whether PC is in a GNU/Linux sigtramp routine. */

	static int
	i386_linux_pc_in_sigtramp (CORE_ADDR pc, char *name)
	{
	/* If we have NAME, we can optimize the search. The trampolines are
	named __restore and __restore_rt. However, they aren't dynamically
	exported from the shared C library, so the trampoline may appear to
	be part of the preceding function. This should always be sigaction,
	__sigaction, or __libc_sigaction (all aliases to the same function). */
	if (name == NULL \|\| strstr (name, "sigaction") != NULL)
	return (i386_linux_sigtramp_start (pc) != 0
	\|\| i386_linux_rt_sigtramp_start (pc) != 0);

	return (strcmp ("__restore", name) == 0
	\|\| strcmp ("__restore_rt", name) == 0);
	}

	/* Assuming FRAME is for a GNU/Linux sigtramp routine, return the
	address of the associated sigcontext structure. */

	static CORE_ADDR
	i386_linux_sigcontext_addr (struct frame_info *frame)
	{
	CORE_ADDR pc;

	pc = i386_linux_sigtramp_start (get_frame_pc (frame));
	if (pc)
	{
	CORE_ADDR sp;

	if (get_next_frame (frame))
	/* If this isn't the top frame, the next frame must be for the
	signal handler itself. The sigcontext structure lives on
	the stack, right after the signum argument. */
	return get_frame_base (get_next_frame (frame)) + 12;

	/* This is the top frame. We'll have to find the address of the
	sigcontext structure by looking at the stack pointer. Keep
	in mind that the first instruction of the sigtramp code is
	"pop %eax". If the PC is at this instruction, adjust the
	returned value accordingly. */
	sp = read_register (SP_REGNUM);
	if (pc == get_frame_pc (frame))
	return sp + 4;
	return sp;
	}

	pc = i386_linux_rt_sigtramp_start (get_frame_pc (frame));
	if (pc)
	{
	if (get_next_frame (frame))
	/* If this isn't the top frame, the next frame must be for the
	signal handler itself. The sigcontext structure is part of
	the user context. A pointer to the user context is passed
	as the third argument to the signal handler. */
	return read_memory_integer (get_frame_base (get_next_frame (frame))
	+ 16, 4) + 20;

	/* This is the top frame. Again, use the stack pointer to find
	the address of the sigcontext structure. */
	return read_memory_integer (read_register (SP_REGNUM) + 8, 4) + 20;
	}

	error ("Couldn't recognize signal trampoline.");
	return 0;
	}

	/* Set the program counter for process PTID to PC. */

	static void
	i386_linux_write_pc (CORE_ADDR pc, ptid_t ptid)
	{
	write_register_pid (PC_REGNUM, pc, ptid);

	/* We must be careful with modifying the program counter. If we
	just interrupted a system call, the kernel might try to restart
	it when we resume the inferior. On restarting the system call,
	the kernel will try backing up the program counter even though it
	no longer points at the system call. This typically results in a
	SIGSEGV or SIGILL. We can prevent this by writing `-1' in the
	"orig_eax" pseudo-register.

	Note that "orig_eax" is saved when setting up a dummy call frame.
	This means that it is properly restored when that frame is
	popped, and that the interrupted system call will be restarted
	when we resume the inferior on return from a function call from
	within GDB. In all other cases the system call will not be
	restarted. */
	write_register_pid (I386_LINUX_ORIG_EAX_REGNUM, -1, ptid);
	}

	/* Calling functions in shared libraries. */

	/* 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_LINKAGE_NAME (msym)
	&& strcmp (SYMBOL_LINKAGE_NAME (msym), name) == 0)
	{
	*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 GNU/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", NULL, objfile);

	if (fixup && SYMBOL_VALUE_ADDRESS (fixup) == pc)
	return (DEPRECATED_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
	i386_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;
	}

	/* Fetch (and possibly build) an appropriate link_map_offsets
	structure for native GNU/Linux x86 targets using the struct offsets
	defined in link.h (but without actual reference to that file).

	This makes it possible to access GNU/Linux x86 shared libraries
	from a GDB that was not built on an GNU/Linux x86 host (for cross
	debugging). */

	static struct link_map_offsets *
	i386_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 552 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;
	}


	static void
	i386_linux_init_abi (struct gdbarch_info info, struct gdbarch *gdbarch)
	{
	struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);

	/* GNU/Linux uses ELF. */
	i386_elf_init_abi (info, gdbarch);

	/* We support the SSE registers on GNU/Linux. */
	tdep->num_xmm_regs = I386_NUM_XREGS - 1;
	/* set_gdbarch_num_regs (gdbarch, I386_SSE_NUM_REGS); */

	/* Since we have the extra "orig_eax" register on GNU/Linux, we have
	to adjust a few things. */

	set_gdbarch_write_pc (gdbarch, i386_linux_write_pc);
	set_gdbarch_num_regs (gdbarch, I386_SSE_NUM_REGS + 1);
	set_gdbarch_register_name (gdbarch, i386_linux_register_name);
	set_gdbarch_register_reggroup_p (gdbarch, i386_linux_register_reggroup_p);
	set_gdbarch_register_bytes (gdbarch, I386_SSE_SIZEOF_REGS + 4);

	tdep->jb_pc_offset = 20; /* From <bits/setjmp.h>. */

	tdep->sigcontext_addr = i386_linux_sigcontext_addr;
	tdep->sc_pc_offset = 14 * 4; /* From <asm/sigcontext.h>. */
	tdep->sc_sp_offset = 7 * 4;

	/* When the i386 Linux kernel calls a signal handler, the return
	address points to a bit of code on the stack. This function is
	used to identify this bit of code as a signal trampoline in order
	to support backtracing through calls to signal handlers. */
	set_gdbarch_pc_in_sigtramp (gdbarch, i386_linux_pc_in_sigtramp);

	set_solib_svr4_fetch_link_map_offsets (gdbarch,
	i386_linux_svr4_fetch_link_map_offsets);
	}

	/* Provide a prototype to silence -Wmissing-prototypes. */
	extern void _initialize_i386_linux_tdep (void);

	void
	_initialize_i386_linux_tdep (void)
	{
	gdbarch_register_osabi (bfd_arch_i386, 0, GDB_OSABI_LINUX,
	i386_linux_init_abi);
	}