/* Machine independent support for SVR4 /proc (process file system) for GDB.
Copyright (C) 1991 Free Software Foundation, Inc.
Written by Fred Fish at Cygnus Support.
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., 675 Mass Ave, Cambridge, MA 02139, USA. */
/* N O T E S
For information on the details of using /proc consult section proc(4)
in the UNIX System V Release 4 System Administrator's Reference Manual.
The general register and floating point register sets are manipulated by
separate ioctl's. This file makes the assumption that if FP0_REGNUM is
defined, then support for the floating point register set is desired,
regardless of whether or not the actual target has floating point hardware.
*/
#include "defs.h"
#ifdef USE_PROC_FS /* Entire file goes away if not using /proc */
#include <stdio.h>
#include <sys/procfs.h>
#include <fcntl.h>
#include <errno.h>
#include "ansidecl.h"
#include "inferior.h"
#include "target.h"
#ifndef PROC_NAME_FMT
#define PROC_NAME_FMT "/proc/%d"
#endif
extern void EXFUN(supply_gregset, (gregset_t *gregsetp));
extern void EXFUN(fill_gregset, (gregset_t *gresetp, int regno));
#if defined (FP0_REGNUM)
extern void EXFUN(supply_fpregset, (fpregset_t *fpregsetp));
extern void EXFUN(fill_fpregset, (fpregset_t *fpresetp, int regno));
#endif
#if 1 /* FIXME: Gross and ugly hack to resolve coredep.c global */
CORE_ADDR kernel_u_addr;
#endif
/* All access to the inferior, either one started by gdb or one that has
been attached to, is controlled by an instance of a procinfo structure,
defined below. Since gdb currently only handles one inferior at a time,
the procinfo structure is statically allocated and only one exists at
any given time. */
struct procinfo {
int valid; /* Nonzero if pid, fd, & pathname are valid */
int pid; /* Process ID of inferior */
int fd; /* File descriptor for /proc entry */
char *pathname; /* Pathname to /proc entry */
int was_stopped; /* Nonzero if was stopped prior to attach */
prrun_t prrun; /* Control state when it is run */
prstatus_t prstatus; /* Current process status info */
gregset_t gregset; /* General register set */
fpregset_t fpregset; /* Floating point register set */
fltset_t fltset; /* Current traced hardware fault set */
sigset_t trace; /* Current traced signal set */
sysset_t exitset; /* Current traced system call exit set */
sysset_t entryset; /* Current traced system call entry set */
} pi;
/* Forward declarations of static functions so we don't have to worry
about ordering within this file. The EXFUN macro may be slightly
misleading. Should probably be called DCLFUN instead, or something
more intuitive, since it can be used for both static and external
definitions. */
static void EXFUN(proc_init_failed, (char *why));
static int EXFUN(open_proc_file, (int pid));
static void EXFUN(close_proc_file, (void));
static void EXFUN(unconditionally_kill_inferior, (void));
/*
GLOBAL FUNCTION
ptrace -- override library version to force errors for /proc version
SYNOPSIS
int ptrace (int request, int pid, int arg3, int arg4)
DESCRIPTION
When gdb is configured to use /proc, it should not be calling
or otherwise attempting to use ptrace. In order to catch errors
where use of /proc is configured, but some routine is still calling
ptrace, we provide a local version of a function with that name
that does nothing but issue an error message.
*/
int
DEFUN(ptrace, (request, pid, arg3, arg4),
int request AND
int pid AND
int arg3 AND
int arg4)
{
error ("internal error - there is a call to ptrace() somewhere");
/*NOTREACHED*/
}
/*
GLOBAL FUNCTION
kill_inferior_fast -- kill inferior while gdb is exiting
SYNOPSIS
void kill_inferior_fast (void)
DESCRIPTION
This is used when GDB is exiting. It gives less chance of error.
NOTES
Don't attempt to kill attached inferiors since we may be called
when gdb is in the process of aborting, and killing the attached
inferior may be very anti-social. This is particularly true if we
were attached just so we could use the /proc facilities to get
detailed information about it's status.
*/
void
DEFUN_VOID(kill_inferior_fast)
{
if (inferior_pid != 0 && !attach_flag)
{
unconditionally_kill_inferior ();
}
}
/*
GLOBAL FUNCTION
kill_inferior - kill any currently inferior
SYNOPSIS
void kill_inferior (void)
DESCRIPTION
Kill any current inferior.
NOTES
Kills even attached inferiors. Presumably the user has already
been prompted that the inferior is an attached one rather than
one started by gdb. (FIXME?)
*/
void
DEFUN_VOID(kill_inferior)
{
if (inferior_pid != 0)
{
unconditionally_kill_inferior ();
target_mourn_inferior ();
}
}
/*
LOCAL FUNCTION
unconditionally_kill_inferior - terminate the inferior
SYNOPSIS
static void unconditionally_kill_inferior (void)
DESCRIPTION
Kill the current inferior. Should not be called until it
is at least tested that there is an inferior.
NOTE
A possibly useful enhancement would be to first try sending
the inferior a terminate signal, politely asking it to commit
suicide, before we murder it.
*/
static void
DEFUN_VOID(unconditionally_kill_inferior)
{
int signo;
signo = SIGKILL;
(void) ioctl (pi.fd, PIOCKILL, &signo);
close_proc_file ();
wait ((int *) 0);
}
/*
GLOBAL FUNCTION
child_xfer_memory -- copy data to or from inferior memory space
SYNOPSIS
int child_xfer_memory (CORE_ADDR memaddr, char *myaddr, int len,
int dowrite, struct target_ops target)
DESCRIPTION
Copy LEN bytes to/from inferior's memory starting at MEMADDR
from/to debugger memory starting at MYADDR. Copy from inferior
if DOWRITE is zero or to inferior if DOWRITE is nonzero.
Returns the length copied, which is either the LEN argument or
zero. This xfer function does not do partial moves, since child_ops
doesn't allow memory operations to cross below us in the target stack
anyway.
NOTES
The /proc interface makes this an almost trivial task.
*/
int
DEFUN(child_xfer_memory, (memaddr, myaddr, len, dowrite, target),
CORE_ADDR memaddr AND
char *myaddr AND
int len AND
int dowrite AND
struct target_ops target /* ignored */)
{
int nbytes = 0;
if (lseek (pi.fd, (off_t) memaddr, 0) == (off_t) memaddr)
{
if (dowrite)
{
nbytes = write (pi.fd, myaddr, len);
}
else
{
nbytes = read (pi.fd, myaddr, len);
}
if (nbytes < 0)
{
nbytes = 0;
}
}
return (nbytes);
}
/*
GLOBAL FUNCTION
store_inferior_registers -- copy register values back to inferior
SYNOPSIS
void store_inferior_registers (int regno)
DESCRIPTION
Store our current register values back into the inferior. If
REGNO is -1 then store all the register, otherwise store just
the value specified by REGNO.
NOTES
If we are storing only a single register, we first have to get all
the current values from the process, overwrite the desired register
in the gregset with the one we want from gdb's registers, and then
send the whole set back to the process. For writing all the
registers, all we have to do is generate the gregset and send it to
the process.
Also note that the process has to be stopped on an event of interest
for this to work, which basically means that it has to have been
run under the control of one of the other /proc ioctl calls and not
ptrace. Since we don't use ptrace anyway, we don't worry about this
fine point, but it is worth noting for future reference.
Gdb is confused about what this function is supposed to return.
Some versions return a value, others return nothing. Some are
declared to return a value and actually return nothing. Gdb ignores
anything returned. (FIXME)
*/
void
DEFUN(store_inferior_registers, (regno),
int regno)
{
if (regno != -1)
{
(void) ioctl (pi.fd, PIOCGREG, &pi.gregset);
}
fill_gregset (&pi.gregset, regno);
(void) ioctl (pi.fd, PIOCSREG, &pi.gregset);
#if defined (FP0_REGNUM)
/* Now repeat everything using the floating point register set, if the
target has floating point hardware. Since we ignore the returned value,
we'll never know whether it worked or not anyway. */
if (regno != -1)
{
(void) ioctl (pi.fd, PIOCGFPREG, &pi.fpregset);
}
fill_fpregset (&pi.fpregset, regno);
(void) ioctl (pi.fd, PIOCSFPREG, &pi.fpregset);
#endif /* FP0_REGNUM */
}
/*
GLOBAL FUNCTION
inferior_proc_init - initialize access to a /proc entry
SYNOPSIS
void inferior_proc_init (int pid)
DESCRIPTION
When gdb starts an inferior, this function is called in the parent
process immediately after the fork. It waits for the child to stop
on the return from the exec system call (the child itself takes care
of ensuring that this is set up), then sets up the set of signals
and faults that are to be traced.
NOTES
If proc_init_failed ever gets called, control returns to the command
processing loop via the standard error handling code.
*/
void
DEFUN(inferior_proc_init, (int pid),
int pid)
{
if (!open_proc_file (pid))
{
proc_init_failed ("can't open process file");
}
else
{
(void) memset (&pi.prrun, 0, sizeof (pi.prrun));
prfillset (&pi.prrun.pr_trace);
prfillset (&pi.prrun.pr_fault);
prdelset (&pi.prrun.pr_fault, FLTPAGE);
if (ioctl (pi.fd, PIOCWSTOP, &pi.prstatus) < 0)
{
proc_init_failed ("PIOCWSTOP failed");
}
else if (ioctl (pi.fd, PIOCSTRACE, &pi.prrun.pr_trace) < 0)
{
proc_init_failed ("PIOCSTRACE failed");
}
else if (ioctl (pi.fd, PIOCSFAULT, &pi.prrun.pr_fault) < 0)
{
proc_init_failed ("PIOCSFAULT failed");
}
}
}
/*
GLOBAL FUNCTION
proc_set_exec_trap -- arrange for exec'd child to halt at startup
SYNOPSIS
void proc_set_exec_trap (void)
DESCRIPTION
This function is called in the child process when starting up
an inferior, prior to doing the exec of the actual inferior.
It sets the child process's exitset to make exit from the exec
system call an event of interest to stop on, and then simply
returns. The child does the exec, the system call returns, and
the child stops at the first instruction, ready for the gdb
parent process to take control of it.
NOTE
We need to use all local variables since the child may be sharing
it's data space with the parent, if vfork was used rather than
fork.
*/
void
DEFUN_VOID(proc_set_exec_trap)
{
sysset_t exitset;
auto char procname[32];
int fd;
(void) sprintf (procname, PROC_NAME_FMT, getpid ());
if ((fd = open (procname, O_RDWR)) < 0)
{
perror (procname);
fflush (stderr);
_exit (127);
}
premptyset (&exitset);
praddset (&exitset, SYS_exec);
praddset (&exitset, SYS_execve);
if (ioctl (fd, PIOCSEXIT, &exitset) < 0)
{
perror (procname);
fflush (stderr);
_exit (127);
}
}
/*
GLOBAL FUNCTION
proc_base_address -- find base address for segment containing address
SYNOPSIS
CORE_ADDR proc_base_address (CORE_ADDR addr)
DESCRIPTION
Given an address of a location in the inferior, find and return
the base address of the mapped segment containing that address.
This is used for example, by the shared library support code,
where we have the pc value for some location in the shared library
where we are stopped, and need to know the base address of the
segment containing that address.
*/
CORE_ADDR
DEFUN(proc_base_address, (addr),
CORE_ADDR addr)
{
int nmap;
struct prmap *prmaps;
struct prmap *prmap;
CORE_ADDR baseaddr = 0;
if (ioctl (pi.fd, PIOCNMAP, &nmap) == 0)
{
prmaps = alloca ((nmap + 1) * sizeof (*prmaps));
if (ioctl (pi.fd, PIOCMAP, prmaps) == 0)
{
for (prmap = prmaps; prmap -> pr_size; ++prmap)
{
if ((prmap -> pr_vaddr <= (caddr_t) addr) &&
(prmap -> pr_vaddr + prmap -> pr_size > (caddr_t) addr))
{
baseaddr = (CORE_ADDR) prmap -> pr_vaddr;
break;
}
}
}
}
return (baseaddr);
}
/*
GLOBAL_FUNCTION
proc_address_to_fd -- return open fd for file mapped to address
SYNOPSIS
int proc_address_to_fd (CORE_ADDR addr)
DESCRIPTION
Given an address in the current inferior's address space, use the
/proc interface to find an open file descriptor for the file that
this address was mapped in from. Return -1 if there is no current
inferior. Print a warning message if there is an inferior but
the address corresponds to no file (IE a bogus address).
*/
int
DEFUN(proc_address_to_fd, (addr),
CORE_ADDR addr)
{
int fd = -1;
if (pi.valid)
{
if ((fd = ioctl (pi.fd, PIOCOPENM, (caddr_t *) &addr)) < 0)
{
print_sys_errmsg (pi.pathname, errno);
warning ("can't find mapped file for address 0x%x", addr);
}
}
return (fd);
}
#ifdef ATTACH_DETACH
/*
GLOBAL FUNCTION
attach -- attach to an already existing process
SYNOPSIS
int attach (int pid)
DESCRIPTION
Attach to an already existing process with the specified process
id. If the process is not already stopped, query whether to
stop it or not.
NOTES
The option of stopping at attach time is specific to the /proc
versions of gdb. Versions using ptrace force the attachee
to stop.
*/
int
DEFUN(attach, (pid),
int pid)
{
if (!open_proc_file (pid))
{
perror_with_name (pi.pathname);
/* NOTREACHED */
}
/* Get current status of process and if it is not already stopped,
then stop it. Remember whether or not it was stopped when we first
examined it. */
if (ioctl (pi.fd, PIOCSTATUS, &pi.prstatus) < 0)
{
print_sys_errmsg (pi.pathname, errno);
close_proc_file ();
error ("PIOCSTATUS failed");
}
if (pi.prstatus.pr_flags & (PR_STOPPED | PR_ISTOP))
{
pi.was_stopped = 1;
}
else
{
pi.was_stopped = 0;
if (query ("Process is currently running, stop it? "))
{
if (ioctl (pi.fd, PIOCSTOP, &pi.prstatus) < 0)
{
print_sys_errmsg (pi.pathname, errno);
close_proc_file ();
error ("PIOCSTOP failed");
}
}
}
/* Remember some things about the inferior that we will, or might, change
so that we can restore them when we detach. */
(void) ioctl (pi.fd, PIOCGTRACE, &pi.trace);
(void) ioctl (pi.fd, PIOCGFAULT, &pi.fltset);
(void) ioctl (pi.fd, PIOCGENTRY, &pi.entryset);
(void) ioctl (pi.fd, PIOCGEXIT, &pi.exitset);
/* Set up trace and fault sets, as gdb expects them. */
(void) memset (&pi.prrun, 0, sizeof (pi.prrun));
prfillset (&pi.prrun.pr_trace);
prfillset (&pi.prrun.pr_fault);
prdelset (&pi.prrun.pr_fault, FLTPAGE);
if (ioctl (pi.fd, PIOCSFAULT, &pi.prrun.pr_fault))
{
print_sys_errmsg ("PIOCSFAULT failed");
}
if (ioctl (pi.fd, PIOCSTRACE, &pi.prrun.pr_trace))
{
print_sys_errmsg ("PIOCSTRACE failed");
}
attach_flag = 1;
return (pid);
}
/*
GLOBAL FUNCTION
detach -- detach from an attached-to process
SYNOPSIS
void detach (int signal)
DESCRIPTION
Detach from the current attachee.
If signal is non-zero, the attachee is started running again and sent
the specified signal.
If signal is zero and the attachee was not already stopped when we
attached to it, then we make it runnable again when we detach.
Otherwise, we query whether or not to make the attachee runnable
again, since we may simply want to leave it in the state it was in
when we attached.
We report any problems, but do not consider them errors, since we
MUST detach even if some things don't seem to go right. This may not
be the ideal situation. (FIXME).
*/
void
DEFUN(detach, (signal),
int signal)
{
if (signal)
{
struct siginfo siginfo;
siginfo.si_signo = signal;
siginfo.si_code = 0;
siginfo.si_errno = 0;
if (ioctl (pi.fd, PIOCSSIG, &siginfo) < 0)
{
print_sys_errmsg (pi.pathname, errno);
printf ("PIOCSSIG failed.\n");
}
}
if (ioctl (pi.fd, PIOCSEXIT, &pi.exitset) < 0)
{
print_sys_errmsg (pi.pathname, errno);
printf ("PIOCSEXIT failed.\n");
}
if (ioctl (pi.fd, PIOCSENTRY, &pi.entryset) < 0)
{
print_sys_errmsg (pi.pathname, errno);
printf ("PIOCSENTRY failed.\n");
}
if (ioctl (pi.fd, PIOCSTRACE, &pi.trace) < 0)
{
print_sys_errmsg (pi.pathname, errno);
printf ("PIOCSTRACE failed.\n");
}
if (ioctl (pi.fd, PIOCSFAULT, &pi.fltset) < 0)
{
print_sys_errmsg (pi.pathname, errno);
printf ("PIOCSFAULT failed.\n");
}
if (ioctl (pi.fd, PIOCSTATUS, &pi.prstatus) < 0)
{
print_sys_errmsg (pi.pathname, errno);
printf ("PIOCSTATUS failed.\n");
}
else
{
if (signal || (pi.prstatus.pr_flags & (PR_STOPPED | PR_ISTOP)))
{
if (signal || !pi.was_stopped ||
query ("Was stopped when attached, make it runnable again? "))
{
(void) memset (&pi.prrun, 0, sizeof (pi.prrun));
pi.prrun.pr_flags = PRCFAULT;
if (ioctl (pi.fd, PIOCRUN, &pi.prrun))
{
print_sys_errmsg (pi.pathname, errno);
printf ("PIOCRUN failed.\n");
}
}
}
}
close_proc_file ();
attach_flag = 0;
}
#endif /* ATTACH_DETACH */
/*
GLOBAL FUNCTION
proc_wait -- emulate wait() as much as possible
SYNOPSIS
int proc_wait (int *statloc)
DESCRIPTION
Try to emulate wait() as much as possible. Not sure why we can't
just use wait(), but it seems to have problems when applied to a
process being controlled with the /proc interface.
NOTES
We have a race problem here with no obvious solution. We need to let
the inferior run until it stops on an event of interest, which means
that we need to use the PIOCWSTOP ioctl. However, we cannot use this
ioctl if the process is already stopped on something that is not an
event of interest, or the call will hang indefinitely. Thus we first
use PIOCSTATUS to see if the process is not stopped. If not, then we
use PIOCWSTOP. But during the window between the two, if the process
stops for any reason that is not an event of interest (such as a job
control signal) then gdb will hang. One possible workaround is to set
an alarm to wake up every minute of so and check to see if the process
is still running, and if so, then reissue the PIOCWSTOP. But this is
a real kludge, so has not been implemented. FIXME: investigate
alternatives.
FIXME: Investigate why wait() seems to have problems with programs
being control by /proc routines.
*/
int
DEFUN(proc_wait, (statloc),
int *statloc)
{
short what;
short why;
int statval = 0;
int checkerr = 0;
int rtnval = -1;
if (ioctl (pi.fd, PIOCSTATUS, &pi.prstatus) < 0)
{
checkerr++;
}
else if (!(pi.prstatus.pr_flags & (PR_STOPPED | PR_ISTOP)))
{
if (ioctl (pi.fd, PIOCWSTOP, &pi.prstatus) < 0)
{
checkerr++;
}
}
if (checkerr)
{
if (errno == ENOENT)
{
rtnval = wait (&statval);
if (rtnval != inferior_pid)
{
error ("PIOCWSTOP, wait failed, returned %d", rtnval);
/* NOTREACHED */
}
}
else
{
print_sys_errmsg (pi.pathname, errno);
error ("PIOCSTATUS or PIOCWSTOP failed.");
/* NOTREACHED */
}
}
else if (pi.prstatus.pr_flags & (PR_STOPPED | PR_ISTOP))
{
rtnval = pi.prstatus.pr_pid;
why = pi.prstatus.pr_why;
what = pi.prstatus.pr_what;
if (why == PR_SIGNALLED)
{
statval = (what << 8) | 0177;
}
else if ((why == PR_SYSEXIT) &&
(what == SYS_exec || what == SYS_execve))
{
statval = (SIGTRAP << 8) | 0177;
}
else if (why == PR_REQUESTED)
{
statval = (SIGSTOP << 8) | 0177;
}
else if (why == PR_JOBCONTROL)
{
statval = (what << 8) | 0177;
}
else if (why == PR_FAULTED)
{
switch (what)
{
case FLTPRIV:
case FLTILL:
statval = (SIGILL << 8) | 0177;
break;
case FLTBPT:
case FLTTRACE:
statval = (SIGTRAP << 8) | 0177;
break;
case FLTSTACK:
case FLTACCESS:
case FLTBOUNDS:
statval = (SIGSEGV << 8) | 0177;
break;
case FLTIOVF:
case FLTIZDIV:
case FLTFPE:
statval = (SIGFPE << 8) | 0177;
break;
case FLTPAGE: /* Recoverable page fault */
default:
rtnval = -1;
error ("PIOCWSTOP, unknown why %d, what %d", why, what);
/* NOTREACHED */
}
}
else
{
rtnval = -1;
error ("PIOCWSTOP, unknown why %d, what %d", why, what);
/* NOTREACHED */
}
}
else
{
error ("PIOCWSTOP, stopped for unknown/unhandled reason, flags %#x",
pi.prstatus.pr_flags);
/* NOTREACHED */
}
if (statloc)
{
*statloc = statval;
}
return (rtnval);
}
/*
GLOBAL FUNCTION
child_resume -- resume execution of the inferior process
SYNOPSIS
void child_resume (int step, int signal)
DESCRIPTION
Resume execution of the inferior process. If STEP is nozero, then
just single step it. If SIGNAL is nonzero, restart it with that
signal activated.
NOTE
It may not be absolutely necessary to specify the PC value for
restarting, but to be safe we use the value that gdb considers
to be current. One case where this might be necessary is if the
user explicitly changes the PC value that gdb considers to be
current. FIXME: Investigate if this is necessary or not.
*/
void
DEFUN(child_resume, (step, signal),
int step AND
int signal)
{
errno = 0;
pi.prrun.pr_flags = PRSVADDR | PRSTRACE | PRSFAULT | PRCFAULT;
pi.prrun.pr_vaddr = (caddr_t) *(int *) ®isters[REGISTER_BYTE (PC_REGNUM)];
if (signal)
{
if (signal != pi.prstatus.pr_cursig)
{
struct siginfo siginfo;
siginfo.si_signo = signal;
siginfo.si_code = 0;
siginfo.si_errno = 0;
(void) ioctl (pi.fd, PIOCSSIG, &siginfo);
}
}
else
{
pi.prrun.pr_flags |= PRCSIG;
}
if (step)
{
pi.prrun.pr_flags |= PRSTEP;
}
if (ioctl (pi.fd, PIOCRUN, &pi.prrun) != 0)
{
perror_with_name (pi.pathname);
/* NOTREACHED */
}
}
/*
GLOBAL FUNCTION
fetch_inferior_registers -- fetch current registers from inferior
SYNOPSIS
void fetch_inferior_registers (void)
DESCRIPTION
Read the current values of the inferior's registers, both the
general register set and floating point registers (if supported)
and update gdb's idea of their current values.
*/
void
DEFUN_VOID(fetch_inferior_registers)
{
if (ioctl (pi.fd, PIOCGREG, &pi.gregset) != -1)
{
supply_gregset (&pi.gregset);
}
#if defined (FP0_REGNUM)
if (ioctl (pi.fd, PIOCGFPREG, &pi.fpregset) != -1)
{
supply_fpregset (&pi.fpregset);
}
#endif
}
/*
GLOBAL FUNCTION
fetch_core_registers -- fetch current registers from core file data
SYNOPSIS
void fetch_core_registers (char *core_reg_sect, unsigned core_reg_size,
int which)
DESCRIPTION
Read the values of either the general register set (WHICH equals 0)
or the floating point register set (WHICH equals 2) from the core
file data (pointed to by CORE_REG_SECT), and update gdb's idea of
their current values. The CORE_REG_SIZE parameter is ignored.
NOTES
Use the indicated sizes to validate the gregset and fpregset
structures.
*/
void
fetch_core_registers (core_reg_sect, core_reg_size, which)
char *core_reg_sect;
unsigned core_reg_size;
int which;
{
if (which == 0)
{
if (core_reg_size != sizeof (pi.gregset))
{
warning ("wrong size gregset struct in core file");
}
else
{
(void) memcpy ((char *) &pi.gregset, core_reg_sect,
sizeof (pi.gregset));
supply_gregset (&pi.gregset);
}
}
else if (which == 2)
{
if (core_reg_size != sizeof (pi.fpregset))
{
warning ("wrong size fpregset struct in core file");
}
else
{
(void) memcpy ((char *) &pi.fpregset, core_reg_sect,
sizeof (pi.fpregset));
#if defined (FP0_REGNUM)
supply_fpregset (&pi.fpregset);
#endif
}
}
}
/*
LOCAL FUNCTION
proc_init_failed - called whenever /proc access initialization fails
SYNOPSIS
static void proc_init_failed (char *why)
DESCRIPTION
This function is called whenever initialization of access to a /proc
entry fails. It prints a suitable error message, does some cleanup,
and then invokes the standard error processing routine which dumps
us back into the command loop.
*/
static void
DEFUN(proc_init_failed, (why),
char *why)
{
print_sys_errmsg (pi.pathname, errno);
(void) kill (pi.pid, SIGKILL);
close_proc_file ();
error (why);
/* NOTREACHED */
}
/*
LOCAL FUNCTION
close_proc_file - close any currently open /proc entry
SYNOPSIS
static void close_proc_file (void)
DESCRIPTION
Close any currently open /proc entry and mark the process information
entry as invalid. In order to ensure that we don't try to reuse any
stale information, the pid, fd, and pathnames are explicitly
invalidated, which may be overkill.
*/
static void
DEFUN_VOID(close_proc_file)
{
pi.pid = 0;
if (pi.valid)
{
(void) close (pi.fd);
}
pi.fd = -1;
if (pi.pathname)
{
free (pi.pathname);
pi.pathname = NULL;
}
pi.valid = 0;
}
/*
LOCAL FUNCTION
open_proc_file - open a /proc entry for a given process id
SYNOPSIS
static int open_proc_file (pid)
DESCRIPTION
Given a process id, close the existing open /proc entry (if any)
and open one for the new process id. Once it is open, then
mark the local process information structure as valid, which
guarantees that the pid, fd, and pathname fields match an open
/proc entry. Returns zero if the open fails, nonzero otherwise.
Note that the pathname is left intact, even when the open fails,
so that callers can use it to construct meaningful error messages
rather than just "file open failed".
*/
static int
DEFUN(open_proc_file, (pid),
int pid)
{
pi.valid = 0;
if (pi.valid)
{
(void) close (pi.fd);
}
if (pi.pathname == NULL)
{
pi.pathname = xmalloc (32);
}
sprintf (pi.pathname, PROC_NAME_FMT, pid);
if ((pi.fd = open (pi.pathname, O_RDWR)) >= 0)
{
pi.valid = 1;
pi.pid = pid;
}
return (pi.valid);
}
#endif /* USE_PROC_FS */