gdb/nat/fork-inferior.c - binutils-gdb - Git at Google

 /* Fork a Unix child process, and set up to debug it, for GDB and GDBserver.

    Copyright (C) 1990-2021 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 3 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, see <http://www.gnu.org/licenses/>.  */

 #include "gdbsupport/common-defs.h"
 #include "fork-inferior.h"
 #include "target/waitstatus.h"
 #include "gdbsupport/filestuff.h"
 #include "target/target.h"
 #include "gdbsupport/common-inferior.h"
 #include "gdbsupport/common-gdbthread.h"
 #include "gdbsupport/pathstuff.h"
 #include "gdbsupport/signals-state-save-restore.h"
 #include "gdbsupport/gdb_tilde_expand.h"
 #include <vector>

 extern char **environ;

 /* Build the argument vector for execv(3).  */

 class execv_argv
 {
 public:
   /* EXEC_FILE is the file to run.  ALLARGS is a string containing the
      arguments to the program.  If starting with a shell, SHELL_FILE
      is the shell to run.  Otherwise, SHELL_FILE is NULL.  */
   execv_argv (const char *exec_file, const std::string &allargs,
 	      const char *shell_file);

   /* Return a pointer to the built argv, in the type expected by
      execv.  The result is (only) valid for as long as this execv_argv
      object is live.  We return a "char **" because that's the type
      that the execv functions expect.  Note that it is guaranteed that
      the execv functions do not modify the argv[] array nor the
      strings to which the array point.  */
   char **argv ()
   {
     return const_cast<char **> (&m_argv[0]);
   }

 private:
   DISABLE_COPY_AND_ASSIGN (execv_argv);

   /* Helper methods for constructing the argument vector.  */

   /* Used when building an argv for a straight execv call, without
      going via the shell.  */
   void init_for_no_shell (const char *exec_file,
 			  const std::string &allargs);

   /* Used when building an argv for execing a shell that execs the
      child program.  */
   void init_for_shell (const char *exec_file,
 		       const std::string &allargs,
 		       const char *shell_file);

   /* The argument vector built.  Holds non-owning pointers.  Elements
      either point to the strings passed to the execv_argv ctor, or
      inside M_STORAGE.  */
   std::vector<const char *> m_argv;

   /* Storage.  In the no-shell case, this contains a copy of the
      arguments passed to the ctor, split by '\0'.  In the shell case,
      this contains the quoted shell command.  I.e., SHELL_COMMAND in
      {"$SHELL" "-c", SHELL_COMMAND, NULL}.  */
   std::string m_storage;
 };

 /* Create argument vector for straight call to execvp.  Breaks up
    ALLARGS into an argument vector suitable for passing to execvp and
    stores it in M_ARGV.  E.g., on "run a b c d" this routine would get
    as input the string "a b c d", and as output it would fill in
    M_ARGV with the four arguments "a", "b", "c", "d".  Each argument
    in M_ARGV points to a substring of a copy of ALLARGS stored in
    M_STORAGE.  */

 void
 execv_argv::init_for_no_shell (const char *exec_file,
 			       const std::string &allargs)
 {

   /* Save/work with a copy stored in our storage.  The pointers pushed
      to M_ARGV point directly into M_STORAGE, which is modified in
      place with the necessary NULL terminators.  This avoids N heap
      allocations and string dups when 1 is sufficient.  */
   std::string &args_copy = m_storage = allargs;

   m_argv.push_back (exec_file);

   for (size_t cur_pos = 0; cur_pos < args_copy.size ();)
     {
       /* Skip whitespace-like chars.  */
       std::size_t pos = args_copy.find_first_not_of (" \t\n", cur_pos);

       if (pos != std::string::npos)
 	cur_pos = pos;

       /* Find the position of the next separator.  */
       std::size_t next_sep = args_copy.find_first_of (" \t\n", cur_pos);

       if (next_sep == std::string::npos)
 	{
 	  /* No separator found, which means this is the last
 	     argument.  */
 	  next_sep = args_copy.size ();
 	}
       else
 	{
 	  /* Replace the separator with a terminator.  */
 	  args_copy[next_sep++] = '\0';
 	}

       m_argv.push_back (&args_copy[cur_pos]);

       cur_pos = next_sep;
     }

   /* NULL-terminate the vector.  */
   m_argv.push_back (NULL);
 }

 /* When executing a command under the given shell, return true if the
    '!' character should be escaped when embedded in a quoted
    command-line argument.  */

 static bool
 escape_bang_in_quoted_argument (const char *shell_file)
 {
   size_t shell_file_len = strlen (shell_file);

   /* Bang should be escaped only in C Shells.  For now, simply check
      that the shell name ends with 'csh', which covers at least csh
      and tcsh.  This should be good enough for now.  */

   if (shell_file_len < 3)
     return false;

   if (shell_file[shell_file_len - 3] == 'c'
       && shell_file[shell_file_len - 2] == 's'
       && shell_file[shell_file_len - 1] == 'h')
     return true;

   return false;
 }

 /* See declaration.  */

 execv_argv::execv_argv (const char *exec_file,
 			const std::string &allargs,
 			const char *shell_file)
 {
   if (shell_file == NULL)
     init_for_no_shell (exec_file, allargs);
   else
     init_for_shell (exec_file, allargs, shell_file);
 }

 /* See declaration.  */

 void
 execv_argv::init_for_shell (const char *exec_file,
 			    const std::string &allargs,
 			    const char *shell_file)
 {
   const char *exec_wrapper = get_exec_wrapper ();

   /* We're going to call a shell.  */
   bool escape_bang = escape_bang_in_quoted_argument (shell_file);

   /* We need to build a new shell command string, and make argv point
      to it.  So build it in the storage.  */
   std::string &shell_command = m_storage;

   shell_command = "exec ";

   /* Add any exec wrapper.  That may be a program name with arguments,
      so the user must handle quoting.  */
   if (exec_wrapper != NULL)
     {
       shell_command += exec_wrapper;
       shell_command += ' ';
     }

   /* Now add exec_file, quoting as necessary.  */

   /* Quoting in this style is said to work with all shells.  But csh
      on IRIX 4.0.1 can't deal with it.  So we only quote it if we need
      to.  */
   bool need_to_quote;
   const char *p = exec_file;
   while (1)
     {
       switch (*p)
 	{
 	case '\'':
 	case '!':
 	case '"':
 	case '(':
 	case ')':
 	case '$':
 	case '&':
 	case ';':
 	case '<':
 	case '>':
 	case ' ':
 	case '\n':
 	case '\t':
 	  need_to_quote = true;
 	  goto end_scan;

 	case '\0':
 	  need_to_quote = false;
 	  goto end_scan;

 	default:
 	  break;
 	}
       ++p;
     }
  end_scan:
   if (need_to_quote)
     {
       shell_command += '\'';
       for (p = exec_file; *p != '\0'; ++p)
 	{
 	  if (*p == '\'')
 	    shell_command += "'\\''";
 	  else if (*p == '!' && escape_bang)
 	    shell_command += "\\!";
 	  else
 	    shell_command += *p;
 	}
       shell_command += '\'';
     }
   else
     shell_command += exec_file;

   shell_command += ' ' + allargs;

   /* If we decided above to start up with a shell, we exec the shell.
      "-c" says to interpret the next arg as a shell command to
      execute, and this command is "exec <target-program> <args>".  */
   m_argv.reserve (4);
   m_argv.push_back (shell_file);
   m_argv.push_back ("-c");
   m_argv.push_back (shell_command.c_str ());
   m_argv.push_back (NULL);
 }

 /* See nat/fork-inferior.h.  */

 pid_t
 fork_inferior (const char *exec_file_arg, const std::string &allargs,
 	       char **env, void (*traceme_fun) (),
 	       gdb::function_view<void (int)> init_trace_fun,
 	       void (*pre_trace_fun) (),
 	       const char *shell_file_arg,
 	       void (*exec_fun)(const char *file, char * const *argv,
 				char * const *env))
 {
   pid_t pid;
   /* Set debug_fork then attach to the child while it sleeps, to debug.  */
   int debug_fork = 0;
   const char *shell_file;
   const char *exec_file;
   char **save_our_env;
   int i;
   int save_errno;

   /* If no exec file handed to us, get it from the exec-file command
      -- with a good, common error message if none is specified.  */
   if (exec_file_arg == NULL)
     exec_file = get_exec_file (1);
   else
     exec_file = exec_file_arg;

   /* 'startup_with_shell' is declared in inferior.h and bound to the
      "set startup-with-shell" option.  If 0, we'll just do a
      fork/exec, no shell, so don't bother figuring out what shell.  */
   if (startup_with_shell)
     {
       shell_file = shell_file_arg;

       /* Figure out what shell to start up the user program under.  */
       if (shell_file == NULL)
 	shell_file = get_shell ();

       gdb_assert (shell_file != NULL);
     }
   else
     shell_file = NULL;

   /* Build the argument vector.  */
   execv_argv child_argv (exec_file, allargs, shell_file);

   /* Retain a copy of our environment variables, since the child will
      replace the value of environ and if we're vforked, we have to
      restore it.  */
   save_our_env = environ;

   /* Perform any necessary actions regarding to TTY before the
      fork/vfork call.  */
   prefork_hook (allargs.c_str ());

   /* It is generally good practice to flush any possible pending stdio
      output prior to doing a fork, to avoid the possibility of both
      the parent and child flushing the same data after the fork.  */
   gdb_flush_out_err ();

   /* Check if the user wants to set a different working directory for
      the inferior.  */
   std::string inferior_cwd = get_inferior_cwd ();

   if (!inferior_cwd.empty ())
     {
       /* Expand before forking because between fork and exec, the child
 	 process may only execute async-signal-safe operations.  */
       inferior_cwd = gdb_tilde_expand (inferior_cwd.c_str ());
     }

   /* If there's any initialization of the target layers that must
      happen to prepare to handle the child we're about fork, do it
      now...  */
   if (pre_trace_fun != NULL)
     (*pre_trace_fun) ();

   /* Create the child process.  Since the child process is going to
      exec(3) shortly afterwards, try to reduce the overhead by
      calling vfork(2).  However, if PRE_TRACE_FUN is non-null, it's
      likely that this optimization won't work since there's too much
      work to do between the vfork(2) and the exec(3).  This is known
      to be the case on ttrace(2)-based HP-UX, where some handshaking
      between parent and child needs to happen between fork(2) and
      exec(2).  However, since the parent is suspended in the vforked
      state, this doesn't work.  Also note that the vfork(2) call might
      actually be a call to fork(2) due to the fact that autoconf will
      ``#define vfork fork'' on certain platforms.  */
 #if !(defined(__UCLIBC__) && defined(HAS_NOMMU))
   if (pre_trace_fun || debug_fork)
     pid = fork ();
   else
 #endif
     pid = vfork ();

   if (pid < 0)
     perror_with_name (("vfork"));

   if (pid == 0)
     {
       /* Close all file descriptors except those that gdb inherited
 	 (usually 0/1/2), so they don't leak to the inferior.  Note
 	 that this closes the file descriptors of all secondary
 	 UIs.  */
       close_most_fds ();

       /* Change to the requested working directory if the user
 	 requested it.  */
       if (!inferior_cwd.empty ())
 	{
 	  if (chdir (inferior_cwd.c_str ()) < 0)
 	    trace_start_error_with_name (inferior_cwd.c_str ());
 	}

       if (debug_fork)
 	sleep (debug_fork);

       /* Execute any necessary post-fork actions before we exec.  */
       postfork_child_hook ();

       /* Changing the signal handlers for the inferior after
 	 a vfork can also change them for the superior, so we don't mess
 	 with signals here.  See comments in
 	 initialize_signals for how we get the right signal handlers
 	 for the inferior.  */

       /* "Trace me, Dr. Memory!"  */
       (*traceme_fun) ();

       /* The call above set this process (the "child") as debuggable
 	by the original gdb process (the "parent").  Since processes
 	(unlike people) can have only one parent, if you are debugging
 	gdb itself (and your debugger is thus _already_ the
 	controller/parent for this child), code from here on out is
 	undebuggable.  Indeed, you probably got an error message
 	saying "not parent".  Sorry; you'll have to use print
 	statements!  */

       restore_original_signals_state ();

       /* There is no execlpe call, so we have to set the environment
 	 for our child in the global variable.  If we've vforked, this
 	 clobbers the parent, but environ is restored a few lines down
 	 in the parent.  By the way, yes we do need to look down the
 	 path to find $SHELL.  Rich Pixley says so, and I agree.  */
       environ = env;

       char **argv = child_argv.argv ();

       if (exec_fun != NULL)
 	(*exec_fun) (argv[0], &argv[0], env);
       else
 	execvp (argv[0], &argv[0]);

       /* If we get here, it's an error.  */
       save_errno = errno;
       warning ("Cannot exec %s", argv[0]);

       for (i = 1; argv[i] != NULL; i++)
 	warning (" %s", argv[i]);

       warning ("Error: %s", safe_strerror (save_errno));

       _exit (0177);
     }

   /* Restore our environment in case a vforked child clob'd it.  */
   environ = save_our_env;

   postfork_hook (pid);

   /* Now that we have a child process, make it our target, and
      initialize anything target-vector-specific that needs
      initializing.  */
   if (init_trace_fun)
     init_trace_fun (pid);

   /* We are now in the child process of interest, having exec'd the
      correct program, and are poised at the first instruction of the
      new program.  */
   return pid;
 }

 /* See nat/fork-inferior.h.  */

 ptid_t
 startup_inferior (process_stratum_target *proc_target, pid_t pid, int ntraps,
 		  struct target_waitstatus *last_waitstatus,
 		  ptid_t *last_ptid)
 {
   int pending_execs = ntraps;
   int terminal_initted = 0;
   ptid_t resume_ptid;

   if (startup_with_shell)
     {
       /* One trap extra for exec'ing the shell.  */
       pending_execs++;
     }

   if (target_supports_multi_process ())
     resume_ptid = ptid_t (pid);
   else
     resume_ptid = minus_one_ptid;

   /* The process was started by the fork that created it, but it will
      have stopped one instruction after execing the shell.  Here we
      must get it up to actual execution of the real program.  */
   if (get_exec_wrapper () != NULL)
     pending_execs++;

   while (1)
     {
       enum gdb_signal resume_signal = GDB_SIGNAL_0;
       ptid_t event_ptid;

       struct target_waitstatus ws;
       memset (&ws, 0, sizeof (ws));
       event_ptid = target_wait (resume_ptid, &ws, 0);

       if (last_waitstatus != NULL)
 	*last_waitstatus = ws;
       if (last_ptid != NULL)
 	*last_ptid = event_ptid;

       if (ws.kind == TARGET_WAITKIND_IGNORE)
 	/* The inferior didn't really stop, keep waiting.  */
 	continue;

       switch (ws.kind)
 	{
 	  case TARGET_WAITKIND_SPURIOUS:
 	  case TARGET_WAITKIND_LOADED:
 	  case TARGET_WAITKIND_FORKED:
 	  case TARGET_WAITKIND_VFORKED:
 	  case TARGET_WAITKIND_SYSCALL_ENTRY:
 	  case TARGET_WAITKIND_SYSCALL_RETURN:
 	    /* Ignore gracefully during startup of the inferior.  */
 	    switch_to_thread (proc_target, event_ptid);
 	    break;

 	  case TARGET_WAITKIND_SIGNALLED:
 	    target_terminal::ours ();
 	    target_mourn_inferior (event_ptid);
 	    error (_("During startup program terminated with signal %s, %s."),
 		   gdb_signal_to_name (ws.value.sig),
 		   gdb_signal_to_string (ws.value.sig));
 	    return resume_ptid;

 	  case TARGET_WAITKIND_EXITED:
 	    target_terminal::ours ();
 	    target_mourn_inferior (event_ptid);
 	    if (ws.value.integer)
 	      error (_("During startup program exited with code %d."),
 		     ws.value.integer);
 	    else
 	      error (_("During startup program exited normally."));
 	    return resume_ptid;

 	  case TARGET_WAITKIND_EXECD:
 	    /* Handle EXEC signals as if they were SIGTRAP signals.  */
 	    /* Free the exec'ed pathname, but only if this isn't the
 	       waitstatus we are returning to the caller.  */
 	    if (pending_execs != 1)
 	      xfree (ws.value.execd_pathname);
 	    resume_signal = GDB_SIGNAL_TRAP;
 	    switch_to_thread (proc_target, event_ptid);
 	    break;

 	  case TARGET_WAITKIND_STOPPED:
 	    resume_signal = ws.value.sig;
 	    switch_to_thread (proc_target, event_ptid);
 	    break;
 	}

       if (resume_signal != GDB_SIGNAL_TRAP)
 	{
 	  /* Let shell child handle its own signals in its own way.  */
 	  target_continue (resume_ptid, resume_signal);
 	}
       else
 	{
 	  /* We handle SIGTRAP, however; it means child did an exec.  */
 	  if (!terminal_initted)
 	    {
 	      /* Now that the child has exec'd we know it has already
 		 set its process group.  On POSIX systems, tcsetpgrp
 		 will fail with EPERM if we try it before the child's
 		 setpgid.  */

 	      /* Set up the "saved terminal modes" of the inferior
 		 based on what modes we are starting it with.  */
 	      target_terminal::init ();

 	      /* Install inferior's terminal modes.  */
 	      target_terminal::inferior ();

 	      terminal_initted = 1;
 	    }

 	  if (--pending_execs == 0)
 	    break;

 	  /* Just make it go on.  */
 	  target_continue_no_signal (resume_ptid);
 	}
     }

   return resume_ptid;
 }

 /* See nat/fork-inferior.h.  */

 void
 trace_start_error (const char *fmt, ...)
 {
   va_list ap;

   va_start (ap, fmt);
   warning ("Could not trace the inferior process.");
   vwarning (fmt, ap);
   va_end (ap);

   gdb_flush_out_err ();
   _exit (0177);
 }

 /* See nat/fork-inferior.h.  */

 void
 trace_start_error_with_name (const char *string)
 {
   trace_start_error ("%s: %s", string, safe_strerror (errno));
 }
	/* Fork a Unix child process, and set up to debug it, for GDB and GDBserver.

	Copyright (C) 1990-2021 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 3 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, see <http://www.gnu.org/licenses/>. */

	#include "gdbsupport/common-defs.h"
	#include "fork-inferior.h"
	#include "target/waitstatus.h"
	#include "gdbsupport/filestuff.h"
	#include "target/target.h"
	#include "gdbsupport/common-inferior.h"
	#include "gdbsupport/common-gdbthread.h"
	#include "gdbsupport/pathstuff.h"
	#include "gdbsupport/signals-state-save-restore.h"
	#include "gdbsupport/gdb_tilde_expand.h"
	#include <vector>

	extern char **environ;

	/* Build the argument vector for execv(3). */

	class execv_argv
	{
	public:
	/* EXEC_FILE is the file to run. ALLARGS is a string containing the
	arguments to the program. If starting with a shell, SHELL_FILE
	is the shell to run. Otherwise, SHELL_FILE is NULL. */
	execv_argv (const char *exec_file, const std::string &allargs,
	const char *shell_file);

	/* Return a pointer to the built argv, in the type expected by
	execv. The result is (only) valid for as long as this execv_argv
	object is live. We return a "char **" because that's the type
	that the execv functions expect. Note that it is guaranteed that
	the execv functions do not modify the argv[] array nor the
	strings to which the array point. */
	char **argv ()
	{
	return const_cast<char **> (&m_argv[0]);
	}

	private:
	DISABLE_COPY_AND_ASSIGN (execv_argv);

	/* Helper methods for constructing the argument vector. */

	/* Used when building an argv for a straight execv call, without
	going via the shell. */
	void init_for_no_shell (const char *exec_file,
	const std::string &allargs);

	/* Used when building an argv for execing a shell that execs the
	child program. */
	void init_for_shell (const char *exec_file,
	const std::string &allargs,
	const char *shell_file);

	/* The argument vector built. Holds non-owning pointers. Elements
	either point to the strings passed to the execv_argv ctor, or
	inside M_STORAGE. */
	std::vector<const char *> m_argv;

	/* Storage. In the no-shell case, this contains a copy of the
	arguments passed to the ctor, split by '\0'. In the shell case,
	this contains the quoted shell command. I.e., SHELL_COMMAND in
	{"$SHELL" "-c", SHELL_COMMAND, NULL}. */
	std::string m_storage;
	};

	/* Create argument vector for straight call to execvp. Breaks up
	ALLARGS into an argument vector suitable for passing to execvp and
	stores it in M_ARGV. E.g., on "run a b c d" this routine would get
	as input the string "a b c d", and as output it would fill in
	M_ARGV with the four arguments "a", "b", "c", "d". Each argument
	in M_ARGV points to a substring of a copy of ALLARGS stored in
	M_STORAGE. */

	void
	execv_argv::init_for_no_shell (const char *exec_file,
	const std::string &allargs)
	{

	/* Save/work with a copy stored in our storage. The pointers pushed
	to M_ARGV point directly into M_STORAGE, which is modified in
	place with the necessary NULL terminators. This avoids N heap
	allocations and string dups when 1 is sufficient. */
	std::string &args_copy = m_storage = allargs;

	m_argv.push_back (exec_file);

	for (size_t cur_pos = 0; cur_pos < args_copy.size ();)
	{
	/* Skip whitespace-like chars. */
	std::size_t pos = args_copy.find_first_not_of (" \t\n", cur_pos);

	if (pos != std::string::npos)
	cur_pos = pos;

	/* Find the position of the next separator. */
	std::size_t next_sep = args_copy.find_first_of (" \t\n", cur_pos);

	if (next_sep == std::string::npos)
	{
	/* No separator found, which means this is the last
	argument. */
	next_sep = args_copy.size ();
	}
	else
	{
	/* Replace the separator with a terminator. */
	args_copy[next_sep++] = '\0';
	}

	m_argv.push_back (&args_copy[cur_pos]);

	cur_pos = next_sep;
	}

	/* NULL-terminate the vector. */
	m_argv.push_back (NULL);
	}

	/* When executing a command under the given shell, return true if the
	'!' character should be escaped when embedded in a quoted
	command-line argument. */

	static bool
	escape_bang_in_quoted_argument (const char *shell_file)
	{
	size_t shell_file_len = strlen (shell_file);

	/* Bang should be escaped only in C Shells. For now, simply check
	that the shell name ends with 'csh', which covers at least csh
	and tcsh. This should be good enough for now. */

	if (shell_file_len < 3)
	return false;

	if (shell_file[shell_file_len - 3] == 'c'
	&& shell_file[shell_file_len - 2] == 's'
	&& shell_file[shell_file_len - 1] == 'h')
	return true;

	return false;
	}

	/* See declaration. */

	execv_argv::execv_argv (const char *exec_file,
	const std::string &allargs,
	const char *shell_file)
	{
	if (shell_file == NULL)
	init_for_no_shell (exec_file, allargs);
	else
	init_for_shell (exec_file, allargs, shell_file);
	}

	/* See declaration. */

	void
	execv_argv::init_for_shell (const char *exec_file,
	const std::string &allargs,
	const char *shell_file)
	{
	const char *exec_wrapper = get_exec_wrapper ();

	/* We're going to call a shell. */
	bool escape_bang = escape_bang_in_quoted_argument (shell_file);

	/* We need to build a new shell command string, and make argv point
	to it. So build it in the storage. */
	std::string &shell_command = m_storage;

	shell_command = "exec ";

	/* Add any exec wrapper. That may be a program name with arguments,
	so the user must handle quoting. */
	if (exec_wrapper != NULL)
	{
	shell_command += exec_wrapper;
	shell_command += ' ';
	}

	/* Now add exec_file, quoting as necessary. */

	/* Quoting in this style is said to work with all shells. But csh
	on IRIX 4.0.1 can't deal with it. So we only quote it if we need
	to. */
	bool need_to_quote;
	const char *p = exec_file;
	while (1)
	{
	switch (*p)
	{
	case '\'':
	case '!':
	case '"':
	case '(':
	case ')':
	case '$':
	case '&':
	case ';':
	case '<':
	case '>':
	case ' ':
	case '\n':
	case '\t':
	need_to_quote = true;
	goto end_scan;

	case '\0':
	need_to_quote = false;
	goto end_scan;

	default:
	break;
	}
	++p;
	}
	end_scan:
	if (need_to_quote)
	{
	shell_command += '\'';
	for (p = exec_file; *p != '\0'; ++p)
	{
	if (*p == '\'')
	shell_command += "'\\''";
	else if (*p == '!' && escape_bang)
	shell_command += "\\!";
	else
	shell_command += *p;
	}
	shell_command += '\'';
	}
	else
	shell_command += exec_file;

	shell_command += ' ' + allargs;

	/* If we decided above to start up with a shell, we exec the shell.
	"-c" says to interpret the next arg as a shell command to
	execute, and this command is "exec <target-program> <args>". */
	m_argv.reserve (4);
	m_argv.push_back (shell_file);
	m_argv.push_back ("-c");
	m_argv.push_back (shell_command.c_str ());
	m_argv.push_back (NULL);
	}

	/* See nat/fork-inferior.h. */

	pid_t
	fork_inferior (const char *exec_file_arg, const std::string &allargs,
	char *env, void (traceme_fun) (),
	gdb::function_view<void (int)> init_trace_fun,
	void (*pre_trace_fun) (),
	const char *shell_file_arg,
	void (exec_fun)(const char file, char * const *argv,
	char * const *env))
	{
	pid_t pid;
	/* Set debug_fork then attach to the child while it sleeps, to debug. */
	int debug_fork = 0;
	const char *shell_file;
	const char *exec_file;
	char **save_our_env;
	int i;
	int save_errno;

	/* If no exec file handed to us, get it from the exec-file command
	-- with a good, common error message if none is specified. */
	if (exec_file_arg == NULL)
	exec_file = get_exec_file (1);
	else
	exec_file = exec_file_arg;

	/* 'startup_with_shell' is declared in inferior.h and bound to the
	"set startup-with-shell" option. If 0, we'll just do a
	fork/exec, no shell, so don't bother figuring out what shell. */
	if (startup_with_shell)
	{
	shell_file = shell_file_arg;

	/* Figure out what shell to start up the user program under. */
	if (shell_file == NULL)
	shell_file = get_shell ();

	gdb_assert (shell_file != NULL);
	}
	else
	shell_file = NULL;

	/* Build the argument vector. */
	execv_argv child_argv (exec_file, allargs, shell_file);

	/* Retain a copy of our environment variables, since the child will
	replace the value of environ and if we're vforked, we have to
	restore it. */
	save_our_env = environ;

	/* Perform any necessary actions regarding to TTY before the
	fork/vfork call. */
	prefork_hook (allargs.c_str ());

	/* It is generally good practice to flush any possible pending stdio
	output prior to doing a fork, to avoid the possibility of both
	the parent and child flushing the same data after the fork. */
	gdb_flush_out_err ();

	/* Check if the user wants to set a different working directory for
	the inferior. */
	std::string inferior_cwd = get_inferior_cwd ();

	if (!inferior_cwd.empty ())
	{
	/* Expand before forking because between fork and exec, the child
	process may only execute async-signal-safe operations. */
	inferior_cwd = gdb_tilde_expand (inferior_cwd.c_str ());
	}

	/* If there's any initialization of the target layers that must
	happen to prepare to handle the child we're about fork, do it
	now... */
	if (pre_trace_fun != NULL)
	(*pre_trace_fun) ();

	/* Create the child process. Since the child process is going to
	exec(3) shortly afterwards, try to reduce the overhead by
	calling vfork(2). However, if PRE_TRACE_FUN is non-null, it's
	likely that this optimization won't work since there's too much
	work to do between the vfork(2) and the exec(3). This is known
	to be the case on ttrace(2)-based HP-UX, where some handshaking
	between parent and child needs to happen between fork(2) and
	exec(2). However, since the parent is suspended in the vforked
	state, this doesn't work. Also note that the vfork(2) call might
	actually be a call to fork(2) due to the fact that autoconf will
	``#define vfork fork'' on certain platforms. */
	#if !(defined(__UCLIBC__) && defined(HAS_NOMMU))
	if (pre_trace_fun \|\| debug_fork)
	pid = fork ();
	else
	#endif
	pid = vfork ();

	if (pid < 0)
	perror_with_name (("vfork"));

	if (pid == 0)
	{
	/* Close all file descriptors except those that gdb inherited
	(usually 0/1/2), so they don't leak to the inferior. Note
	that this closes the file descriptors of all secondary
	UIs. */
	close_most_fds ();

	/* Change to the requested working directory if the user
	requested it. */
	if (!inferior_cwd.empty ())
	{
	if (chdir (inferior_cwd.c_str ()) < 0)
	trace_start_error_with_name (inferior_cwd.c_str ());
	}

	if (debug_fork)
	sleep (debug_fork);

	/* Execute any necessary post-fork actions before we exec. */
	postfork_child_hook ();

	/* Changing the signal handlers for the inferior after
	a vfork can also change them for the superior, so we don't mess
	with signals here. See comments in
	initialize_signals for how we get the right signal handlers
	for the inferior. */

	/* "Trace me, Dr. Memory!" */
	(*traceme_fun) ();

	/* The call above set this process (the "child") as debuggable
	by the original gdb process (the "parent"). Since processes
	(unlike people) can have only one parent, if you are debugging
	gdb itself (and your debugger is thus _already_ the
	controller/parent for this child), code from here on out is
	undebuggable. Indeed, you probably got an error message
	saying "not parent". Sorry; you'll have to use print
	statements! */

	restore_original_signals_state ();

	/* There is no execlpe call, so we have to set the environment
	for our child in the global variable. If we've vforked, this
	clobbers the parent, but environ is restored a few lines down
	in the parent. By the way, yes we do need to look down the
	path to find $SHELL. Rich Pixley says so, and I agree. */
	environ = env;

	char **argv = child_argv.argv ();

	if (exec_fun != NULL)
	(*exec_fun) (argv[0], &argv[0], env);
	else
	execvp (argv[0], &argv[0]);

	/* If we get here, it's an error. */
	save_errno = errno;
	warning ("Cannot exec %s", argv[0]);

	for (i = 1; argv[i] != NULL; i++)
	warning (" %s", argv[i]);

	warning ("Error: %s", safe_strerror (save_errno));

	_exit (0177);
	}

	/* Restore our environment in case a vforked child clob'd it. */
	environ = save_our_env;

	postfork_hook (pid);

	/* Now that we have a child process, make it our target, and
	initialize anything target-vector-specific that needs
	initializing. */
	if (init_trace_fun)
	init_trace_fun (pid);

	/* We are now in the child process of interest, having exec'd the
	correct program, and are poised at the first instruction of the
	new program. */
	return pid;
	}

	/* See nat/fork-inferior.h. */

	ptid_t
	startup_inferior (process_stratum_target *proc_target, pid_t pid, int ntraps,
	struct target_waitstatus *last_waitstatus,
	ptid_t *last_ptid)
	{
	int pending_execs = ntraps;
	int terminal_initted = 0;
	ptid_t resume_ptid;

	if (startup_with_shell)
	{
	/* One trap extra for exec'ing the shell. */
	pending_execs++;
	}

	if (target_supports_multi_process ())
	resume_ptid = ptid_t (pid);
	else
	resume_ptid = minus_one_ptid;

	/* The process was started by the fork that created it, but it will
	have stopped one instruction after execing the shell. Here we
	must get it up to actual execution of the real program. */
	if (get_exec_wrapper () != NULL)
	pending_execs++;

	while (1)
	{
	enum gdb_signal resume_signal = GDB_SIGNAL_0;
	ptid_t event_ptid;

	struct target_waitstatus ws;
	memset (&ws, 0, sizeof (ws));
	event_ptid = target_wait (resume_ptid, &ws, 0);

	if (last_waitstatus != NULL)
	*last_waitstatus = ws;
	if (last_ptid != NULL)
	*last_ptid = event_ptid;

	if (ws.kind == TARGET_WAITKIND_IGNORE)
	/* The inferior didn't really stop, keep waiting. */
	continue;

	switch (ws.kind)
	{
	case TARGET_WAITKIND_SPURIOUS:
	case TARGET_WAITKIND_LOADED:
	case TARGET_WAITKIND_FORKED:
	case TARGET_WAITKIND_VFORKED:
	case TARGET_WAITKIND_SYSCALL_ENTRY:
	case TARGET_WAITKIND_SYSCALL_RETURN:
	/* Ignore gracefully during startup of the inferior. */
	switch_to_thread (proc_target, event_ptid);
	break;

	case TARGET_WAITKIND_SIGNALLED:
	target_terminal::ours ();
	target_mourn_inferior (event_ptid);
	error (_("During startup program terminated with signal %s, %s."),
	gdb_signal_to_name (ws.value.sig),
	gdb_signal_to_string (ws.value.sig));
	return resume_ptid;

	case TARGET_WAITKIND_EXITED:
	target_terminal::ours ();
	target_mourn_inferior (event_ptid);
	if (ws.value.integer)
	error (_("During startup program exited with code %d."),
	ws.value.integer);
	else
	error (_("During startup program exited normally."));
	return resume_ptid;

	case TARGET_WAITKIND_EXECD:
	/* Handle EXEC signals as if they were SIGTRAP signals. */
	/* Free the exec'ed pathname, but only if this isn't the
	waitstatus we are returning to the caller. */
	if (pending_execs != 1)
	xfree (ws.value.execd_pathname);
	resume_signal = GDB_SIGNAL_TRAP;
	switch_to_thread (proc_target, event_ptid);
	break;

	case TARGET_WAITKIND_STOPPED:
	resume_signal = ws.value.sig;
	switch_to_thread (proc_target, event_ptid);
	break;
	}

	if (resume_signal != GDB_SIGNAL_TRAP)
	{
	/* Let shell child handle its own signals in its own way. */
	target_continue (resume_ptid, resume_signal);
	}
	else
	{
	/* We handle SIGTRAP, however; it means child did an exec. */
	if (!terminal_initted)
	{
	/* Now that the child has exec'd we know it has already
	set its process group. On POSIX systems, tcsetpgrp
	will fail with EPERM if we try it before the child's
	setpgid. */

	/* Set up the "saved terminal modes" of the inferior
	based on what modes we are starting it with. */
	target_terminal::init ();

	/* Install inferior's terminal modes. */
	target_terminal::inferior ();

	terminal_initted = 1;
	}

	if (--pending_execs == 0)
	break;

	/* Just make it go on. */
	target_continue_no_signal (resume_ptid);
	}
	}

	return resume_ptid;
	}

	/* See nat/fork-inferior.h. */

	void
	trace_start_error (const char *fmt, ...)
	{
	va_list ap;

	va_start (ap, fmt);
	warning ("Could not trace the inferior process.");
	vwarning (fmt, ap);
	va_end (ap);

	gdb_flush_out_err ();
	_exit (0177);
	}

	/* See nat/fork-inferior.h. */

	void
	trace_start_error_with_name (const char *string)
	{
	trace_start_error ("%s: %s", string, safe_strerror (errno));
	}