make-dfsg/job.c

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34 KiB
C
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1992-01-20 18:49:36 +00:00
/* Job execution and handling for GNU Make.
Copyright (C) 1988, 1989, 1990, 1991, 1992 Free Software Foundation, Inc.
This file is part of GNU Make.
GNU Make 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, or (at your option)
any later version.
GNU Make 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 GNU Make; see the file COPYING. If not, write to
the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */
#include "make.h"
#include "commands.h"
#include "job.h"
#include "file.h"
#include "variable.h"
#include <errno.h>
/* Default path to search for executables. */
static char default_path[] = ":/bin:/usr/bin";
/* Default shell to use. */
char default_shell[] = "/bin/sh";
extern int errno;
#if defined(POSIX) || defined(__GNU_LIBRARY__)
#include <limits.h>
#include <unistd.h>
#define GET_NGROUPS_MAX sysconf (_SC_NGROUPS_MAX)
#else /* Not POSIX. */
#ifndef USG
#include <sys/param.h>
#define NGROUPS_MAX NGROUPS
#endif /* Not USG. */
#endif /* POSIX. */
#ifdef POSIX
#include <sys/wait.h>
#define WAIT_NOHANG(status) waitpid(-1, (status), WNOHANG)
#else /* Not POSIX. */
#if defined(HAVE_SYS_WAIT) || !defined(USG)
#include <sys/wait.h>
#include <sys/time.h>
#include <sys/resource.h>
#ifndef wait3
extern int wait3 ();
#endif
#define WAIT_NOHANG(status) \
wait3((union wait *) (status), WNOHANG, (struct rusage *) 0)
#if !defined (wait) && !defined (POSIX)
extern int wait ();
#endif
#endif /* HAVE_SYS_WAIT || !USG */
#endif /* POSIX. */
#if defined(WTERMSIG) || (defined(USG) && !defined(HAVE_SYS_WAIT))
#define WAIT_T int
#ifndef WTERMSIG
#define WTERMSIG(x) ((x) & 0x7f)
#endif
#ifndef WCOREDUMP
#define WCOREDUMP(x) ((x) & 0x80)
#endif
#ifndef WEXITSTATUS
#define WEXITSTATUS(x) (((x) >> 8) & 0xff)
#endif
#ifndef WIFSIGNALED
#define WIFSIGNALED(x) (WTERMSIG (x) != 0)
#endif
#ifndef WIFEXITED
#define WIFEXITED(x) (WTERMSIG (x) == 0)
#endif
#else /* WTERMSIG not defined and have <sys/wait.h> or not USG. */
#define WAIT_T union wait
#define WTERMSIG(x) ((x).w_termsig)
#define WCOREDUMP(x) ((x).w_coredump)
#define WEXITSTATUS(x) ((x).w_retcode)
#ifndef WIFSIGNALED
#define WIFSIGNALED(x) (WTERMSIG(x) != 0)
#endif
#ifndef WIFEXITED
#define WIFEXITED(x) (WTERMSIG(x) == 0)
#endif
#endif /* WTERMSIG defined or USG and don't have <sys/wait.h>. */
#if defined(__GNU_LIBRARY__) || defined(POSIX)
#include <sys/types.h>
#define GID_T gid_t
#else /* Not GNU C library. */
#define GID_T int
extern int dup2 ();
extern int execve ();
extern void _exit ();
extern int geteuid (), getegid ();
extern int setgid (), getgid ();
#endif /* GNU C library. */
#ifndef USG
extern int getdtablesize ();
#else
#include <sys/param.h>
#define getdtablesize() NOFILE
#endif
extern void wait_to_start_job ();
extern int start_remote_job_p ();
extern int start_remote_job (), remote_status ();
#if (defined(USG) && !defined(HAVE_SIGLIST)) || defined(DGUX)
static char *sys_siglist[NSIG];
void init_siglist ();
#else /* Not (USG and HAVE_SIGLIST), or DGUX. */
extern char *sys_siglist[];
#endif /* USG and not HAVE_SIGLIST, or DGUX. */
int child_handler ();
static void free_child (), start_job ();
/* Chain of all children. */
struct child *children = 0;
/* Number of children currently running. */
unsigned int job_slots_used = 0;
/* Nonzero if the `good' standard input is in use. */
static int good_stdin_used = 0;
/* Write an error message describing the exit status given in
EXIT_CODE, EXIT_SIG, and COREDUMP, for the target TARGET_NAME.
Append "(ignored)" if IGNORED is nonzero. */
static void
child_error (target_name, exit_code, exit_sig, coredump, ignored)
char *target_name;
int exit_code, exit_sig, coredump;
int ignored;
{
char *ignore_string = ignored ? " (ignored)" : "";
if (exit_sig == 0)
error ("*** [%s] Error %d%s", target_name, exit_code, ignore_string);
else
{
char *coredump_string = coredump ? " (core dumped)" : "";
if (exit_sig > 0 && exit_sig < NSIG)
error ("*** [%s] %s%s",
target_name, sys_siglist[exit_sig], coredump_string);
else
error ("*** [%s] Signal %d%s", target_name, exit_sig, coredump_string);
}
}
extern void block_remote_children (), unblock_remote_children ();
extern int fatal_signal_mask;
#ifdef USG
/* Set nonzero in the interval when it's possible that we may see a dead
child that's not in the `children' chain. */
static int unknown_children_possible = 0;
#endif
/* Block the child termination signal and fatal signals. */
static void
block_signals ()
{
#ifdef USG
/* Tell child_handler that it might see children that aren't yet
in the `children' chain. */
unknown_children_possible = 1;
/* Ignoring SIGCLD makes wait always return -1.
Using the default action does the right thing. */
(void) SIGNAL (SIGCLD, SIG_DFL);
#else /* Not USG. */
/* Block the signals. */
(void) sigblock (fatal_signal_mask | sigmask (SIGCHLD));
#endif
block_remote_children ();
}
/* Unblock the child termination signal and fatal signals. */
static void
unblock_signals ()
{
#ifdef USG
(void) SIGNAL (SIGCLD, child_handler);
/* It should no longer be possible for children not in the chain to die. */
unknown_children_possible = 0;
#else /* Not USG. */
/* Unblock the signals. */
(void) sigsetmask (sigblock (0) & ~(fatal_signal_mask | sigmask (SIGCHLD)));
#endif
unblock_remote_children ();
}
static char *signals_blocked_p_stack = 0;
static unsigned int signals_blocked_p_max;
static unsigned int signals_blocked_p_depth;
/* Make signals blocked in FLAG is nonzero, unblocked if FLAG is zero.
Push this setting on the signals_blocked_p_stack, so it can be
popped off by pop_signals_blocked_p. */
void
push_signals_blocked_p (flag)
int flag;
{
int blocked;
if (signals_blocked_p_stack == 0)
{
signals_blocked_p_max = 8;
signals_blocked_p_stack = (char *) xmalloc (8);
signals_blocked_p_depth = 1;
signals_blocked_p_stack[0] = flag;
blocked = 0;
}
else
{
if (signals_blocked_p_depth == signals_blocked_p_max)
{
signals_blocked_p_max += 8;
signals_blocked_p_stack
= (char *) xrealloc(signals_blocked_p_stack,
signals_blocked_p_max);
}
blocked = (signals_blocked_p_depth > 0
&& signals_blocked_p_stack[signals_blocked_p_depth - 1]);
signals_blocked_p_stack[++signals_blocked_p_depth - 1] = flag;
}
if (blocked && !flag)
unblock_signals ();
else if (flag && !blocked)
block_signals ();
}
/* Pop the signals_blocked_p setting from the stack
and block or unblock signals as appropriate. */
void
pop_signals_blocked_p ()
{
int blocked, block;
blocked = (signals_blocked_p_depth > 0
&& signals_blocked_p_stack[signals_blocked_p_depth-- - 1]);
block = (signals_blocked_p_depth > 0
&& signals_blocked_p_stack[signals_blocked_p_depth - 1]);
if (block && !blocked)
block_signals ();
else if (blocked && !block)
unblock_signals ();
}
extern int shell_function_pid, shell_function_completed;
/* Handle a child-termination signal (SIGCHLD, or SIGCLD for USG),
storing the returned status and the new command state (`cs_finished')
in the `file' member of the `struct child' for the dead child,
and removing the child from the chain.
If we were called as a signal handler, SIG should be SIGCHLD
(SIGCLD for USG). If instead it is zero, we were called explicitly
and should block waiting for running children.
If SIG is < 0, - SIG is the maximum number of children to bury (record
status of and remove from the chain). */
int
child_handler (sig)
int sig;
{
WAIT_T status;
unsigned int dead_children = 0;
if (sig > 0)
block_signals ();
while (1)
{
int remote = 0;
register int pid;
int exit_code, exit_sig, coredump;
register struct child *lastc, *c;
int child_failed;
/* First, check for remote children. */
pid = remote_status (&exit_code, &exit_sig, &coredump, 0);
if (pid < 0)
{
/* No remote children. Check for local children. */
#ifdef WAIT_NOHANG
if (sig > 0)
pid = WAIT_NOHANG (&status);
else
pid = wait (&status);
#else /* USG and don't HAVE_SYS_WAIT. */
/* System V cannot do non-blocking waits, so we have two
choices if called as a signal handler: handle only one
child (there may be more if the signal was blocked),
or block waiting for more. The latter option makes
parallelism useless, so we must choose the former. */
pid = wait (&status);
#endif /* HAVE_SYS_WAIT or not USG. */
if (pid <= 0)
/* No local children. */
break;
else
{
/* Chop the status word up. */
exit_code = WEXITSTATUS (status);
exit_sig = WIFSIGNALED (status) ? WTERMSIG (status) : 0;
coredump = WCOREDUMP (status);
}
}
else
/* We got a remote child. */
remote = 1;
/* Check if this is the child of the `shell' function. */
if (!remote && pid == shell_function_pid)
{
/* It is. Leave an indicator for the `shell' function. */
if (exit_sig == 0 && exit_code == 127)
shell_function_completed = -1;
else
shell_function_completed = 1;
/* Check if we have reached our quota of children. */
++dead_children;
if (sig < 0 && dead_children == -sig)
break;
#if defined(USG) && !defined(HAVE_SYS_WAIT)
else if (sig > 0)
break;
#endif
else
continue;
}
child_failed = exit_sig != 0 || exit_code != 0;
/* Search for a child matching the deceased one. */
lastc = 0;
for (c = children; c != 0; lastc = c, c = c->next)
if (c->remote == remote && c->pid == pid)
break;
if (c == 0)
{
/* An unknown child died. */
#ifdef USG
if (!unknown_children_possible)
{
#endif
char buf[100];
sprintf (buf, "Unknown%s job %d", remote ? " remote" : "", pid);
if (child_failed)
child_error (buf, exit_code, exit_sig, coredump,
ignore_errors_flag);
else
error ("%s finished.", buf);
#ifdef USG
}
#endif
}
else
{
/* If this child had the good stdin, say it is now free. */
if (c->good_stdin)
good_stdin_used = 0;
if (child_failed && !c->noerror && !ignore_errors_flag)
{
/* The commands failed. Write an error message,
delete non-precious targets, and abort. */
child_error (c->file->name, exit_code, exit_sig, coredump, 0);
c->file->update_status = 1;
if (exit_sig != 0)
delete_child_targets (c);
}
else
{
if (child_failed)
{
/* The commands failed, but we don't care. */
child_error (c->file->name,
exit_code, exit_sig, coredump, 1);
child_failed = 0;
}
/* If there are more commands to run, try to start them. */
start_job (c);
switch (c->file->command_state)
{
case cs_running:
/* Successfully started. Loop to reap more children. */
continue;
case cs_finished:
if (c->file->update_status != 0)
{
/* We failed to start the commands. */
delete_child_targets (c);
}
break;
default:
error ("internal error: `%s' command_state \
%d in child_handler", c->file->name);
abort ();
break;
}
}
/* Set the state flag to say the commands have finished. */
notice_finished_file (c->file);
/* Remove the child from the chain and free it. */
if (lastc == 0)
children = c->next;
else
lastc->next = c->next;
free_child (c);
/* There is now another slot open. */
--job_slots_used;
/* If the job failed, and the -k flag was not given, die. */
if (child_failed && !keep_going_flag)
die (1);
/* See if we have reached our quota for blocking. */
++dead_children;
if (sig < 0 && dead_children == -sig)
break;
#if defined(USG) && !defined(HAVE_SYS_WAIT)
else if (sig > 0)
break;
#endif
}
}
#ifdef USG
if (sig > 0)
(void) SIGNAL (sig, child_handler);
#endif
if (sig > 0)
unblock_signals ();
return 0;
}
/* Wait for N children, blocking if necessary.
If N is zero, wait until we run out of children.
If ERR is nonzero and we have any children to wait for,
print a message on stderr. */
void
wait_for_children (n, err)
unsigned int n;
int err;
{
push_signals_blocked_p (1);
if (err && (children != 0 || shell_function_pid != 0))
{
fflush (stdout);
error ("*** Waiting for unfinished jobs....");
}
/* Call child_handler to do the work. */
(void) child_handler (- (int) n);
pop_signals_blocked_p ();
}
/* Free the storage allocated for CHILD. */
static void
free_child (child)
register struct child *child;
{
if (child->command_lines != 0)
{
register unsigned int i;
for (i = 0; i < child->file->cmds->ncommand_lines; ++i)
free (child->command_lines[i]);
free ((char *) child->command_lines);
}
if (child->environment != 0)
{
register char **ep = child->environment;
while (*ep != 0)
free (*ep++);
free ((char *) child->environment);
}
free ((char *) child);
}
/* Start a job to run the commands specified in CHILD.
CHILD is updated to reflect the commands and ID of the child process. */
static void
start_job (child)
register struct child *child;
{
static int bad_stdin = -1;
register char *p;
char noprint = 0, recursive;
char **argv;
if (child->command_ptr == 0 || *child->command_ptr == '\0')
{
/* There are no more lines in the expansion of this line. */
if (child->command_line == child->file->cmds->ncommand_lines)
{
/* There are no more lines to be expanded. */
child->command_ptr = 0;
child->file->command_state = cs_finished;
child->file->update_status = 0;
return;
}
else
{
/* Get the next line to run, and set RECURSIVE
if the unexpanded line contains $(MAKE). */
child->command_ptr = child->command_lines[child->command_line];
recursive = child->file->cmds->lines_recurse[child->command_line];
++child->command_line;
}
}
else
/* Still executing the last line we started. */
recursive = child->file->cmds->lines_recurse[child->command_line - 1];
p = child->command_ptr;
child->noerror = 0;
while (*p != '\0')
{
if (*p == '@')
noprint = 1;
else if (*p == '-')
child->noerror = 1;
else if (*p == '+')
recursive = 1;
else if (!isblank (*p))
break;
++p;
}
/* If -q was given, just say that updating `failed'. */
if (question_flag && !recursive)
goto error;
/* There may be some preceding whitespace left if there
was nothing but a backslash on the first line. */
p = next_token (p);
/* Figure out an argument list from this command line. */
{
char *end;
argv = construct_command_argv (p, &end, child->file);
if (end == NULL)
child->command_ptr = NULL;
else
{
*end++ = '\0';
child->command_ptr = end;
}
}
if (argv == 0)
{
/* This line has no commands. Go to the next. */
start_job (child);
return;
}
/* Print out the command. */
if (just_print_flag || (!noprint && !silent_flag))
puts (p);
/* If -n was given, recurse to get the next line in the sequence. */
if (just_print_flag && !recursive)
{
free (argv[0]);
free ((char *) argv);
start_job (child);
return;
}
/* Flush the output streams so they won't have things written twice. */
fflush (stdout);
fflush (stderr);
/* Set up a bad standard input that reads from a broken pipe. */
if (bad_stdin == -1)
{
/* Make a file descriptor that is the read end of a broken pipe.
This will be used for some children's standard inputs. */
int pd[2];
if (pipe (pd) == 0)
{
/* Close the write side. */
(void) close (pd[1]);
/* Save the read side. */
bad_stdin = pd[0];
}
}
/* Decide whether to give this child the `good' standard input
(one that points to the terminal or whatever), or the `bad' one
that points to the read side of a broken pipe. */
child->good_stdin = !good_stdin_used;
if (child->good_stdin)
good_stdin_used = 1;
child->deleted = 0;
/* Set up the environment for the child. */
if (child->environment == 0)
child->environment = target_environment (child->file);
if (start_remote_job_p ())
{
int is_remote, id, used_stdin;
if (start_remote_job (argv, child->good_stdin ? 0 : bad_stdin,
&is_remote, &id, &used_stdin))
goto error;
else
{
if (child->good_stdin && !used_stdin)
{
child->good_stdin = 0;
good_stdin_used = 0;
}
child->remote = is_remote;
child->pid = id;
}
}
else
{
if (child->command_line - 1 == 0)
{
/* Wait for the load to be low enough if this
is the first command in the sequence. */
make_access ();
wait_to_start_job ();
user_access ();
}
/* Fork the child process. */
child->remote = 0;
child->pid = vfork ();
if (child->pid == 0)
/* We are the child side. */
child_execute_job (child->good_stdin ? 0 : bad_stdin, 1,
argv, child->environment);
else if (child->pid < 0)
{
/* Fork failed! */
perror_with_name (VFORK_NAME, "");
goto error;
}
}
/* We are the parent side. Set the state to
say the commands are running and return. */
child->file->command_state = cs_running;
/* Free the storage used by the child's argument list. */
free (argv[0]);
free ((char *) argv);
return;
error:;
child->file->update_status = 1;
child->file->command_state = cs_finished;
}
/* Create a `struct child' for FILE and start its commands running. */
void
new_job (file)
register struct file *file;
{
register struct commands *cmds = file->cmds;
register struct child *c;
char **lines;
register unsigned int i;
/* Chop the commands up into lines if they aren't already. */
chop_commands (cmds);
if (job_slots != 0)
/* Wait for a job slot to be freed up. */
while (job_slots_used == job_slots)
wait_for_children (1, 0);
/* Expand the command lines and store the results in LINES. */
lines = (char **) xmalloc (cmds->ncommand_lines * sizeof (char *));
for (i = 0; i < cmds->ncommand_lines; ++i)
lines[i] = allocated_variable_expand_for_file (cmds->command_lines[i],
file);
/* Start the command sequence, record it in a new
`struct child', and add that to the chain. */
push_signals_blocked_p (1);
c = (struct child *) xmalloc (sizeof (struct child));
c->file = file;
c->command_lines = lines;
c->command_line = 0;
c->command_ptr = 0;
c->environment = 0;
start_job (c);
switch (file->command_state)
{
case cs_running:
c->next = children;
children = c;
/* One more job slot is in use. */
++job_slots_used;
break;
case cs_finished:
free_child (c);
notice_finished_file (file);
break;
default:
error ("internal error: `%s' command_state == %d in new_job",
file->name, (int) file->command_state);
abort ();
break;
}
pop_signals_blocked_p ();
if (job_slots == 1 && file->command_state == cs_running)
{
/* Since there is only one job slot, make things run linearly.
Wait for the child to finish, setting the state to `cs_finished'. */
while (file->command_state != cs_finished)
wait_for_children (1, 0);
}
}
/* Replace the current process with one executing the command in ARGV.
STDIN_FD and STDOUT_FD are used as the process's stdin and stdout; ENVP is
the environment of the new program. This function does not return. */
void
child_execute_job (stdin_fd, stdout_fd, argv, envp)
int stdin_fd, stdout_fd;
char **argv, **envp;
{
if (stdin_fd != 0)
(void) dup2 (stdin_fd, 0);
if (stdout_fd != 1)
(void) dup2 (stdout_fd, 1);
/* Free up file descriptors. */
{
register int d;
int max = getdtablesize ();
for (d = 3; d < max; ++d)
(void) close (d);
}
/* Don't block signals for the new process. */
unblock_signals ();
/* Run the command. */
exec_command (argv, envp);
}
/* Search PATH for FILE.
If successful, store the full pathname in PROGRAM and return 1.
If not sucessful, return zero. */
static int
search_path (file, path, program)
char *file, *path, *program;
{
if (path == 0 || path[0] == '\0')
path = default_path;
if (index (file, '/') != 0)
{
strcpy (program, file);
return 1;
}
else
{
unsigned int len;
#if !defined (USG) || defined (POSIX)
#ifndef POSIX
extern int getgroups ();
#endif
static int ngroups = -1;
#ifdef NGROUPS_MAX
static GID_T groups[NGROUPS_MAX];
#define ngroups_max NGROUPS_MAX
#else
static GID_T *groups = 0;
static int ngroups_max;
if (groups == 0)
{
ngroups_max = GET_NGROUPS_MAX;
groups = (GID_T *) malloc (ngroups_max * sizeof (GID_T));
}
#endif
if (groups != 0 && ngroups == -1)
ngroups = getgroups (ngroups_max, groups);
#endif /* POSIX or not USG. */
len = strlen (file) + 1;
do
{
struct stat st;
int perm;
char *p;
p = index (path, ':');
if (p == 0)
p = path + strlen (path);
if (p == path)
bcopy (file, program, len);
else
{
bcopy (path, program, p - path);
program[p - path] = '/';
bcopy (file, program + (p - path) + 1, len);
}
if (stat (program, &st) == 0
&& S_ISREG (st.st_mode))
{
if (st.st_uid == geteuid ())
perm = (st.st_mode & 0100);
else if (st.st_gid == getegid ())
perm = (st.st_mode & 0010);
else
{
#ifndef USG
register int i;
for (i = 0; i < ngroups; ++i)
if (groups[i] == st.st_gid)
break;
if (i < ngroups)
perm = (st.st_mode & 0010);
else
#endif /* Not USG. */
perm = (st.st_mode & 0001);
}
if (perm != 0)
return 1;
}
path = p + 1;
} while (*path != '\0');
}
return 0;
}
/* Replace the current process with one running the command in ARGV,
with environment ENVP. This function does not return. */
void
exec_command (argv, envp)
char **argv, **envp;
{
char *shell, *path;
PATH_VAR (program);
register char **ep;
shell = path = 0;
for (ep = envp; *ep != 0; ++ep)
{
if (shell == 0 && !strncmp(*ep, "SHELL=", 6))
shell = &(*ep)[6];
else if (path == 0 && !strncmp(*ep, "PATH=", 5))
path = &(*ep)[5];
else if (path != 0 && shell != 0)
break;
}
/* Be the user, permanently. */
child_access ();
if (!search_path (argv[0], path, program))
error ("%s: Command not found", argv[0]);
else
{
/* Run the program. */
execve (program, argv, envp);
if (errno == ENOEXEC)
{
PATH_VAR (shell_program);
char *shell_path;
if (shell == 0)
shell_path = default_shell;
else
{
if (search_path (shell, path, shell_program))
shell_path = shell_program;
else
{
shell_path = 0;
error ("%s: Shell program not found", shell);
}
}
if (shell_path != 0)
{
char **new_argv;
int argc;
argc = 1;
while (argv[argc] != 0)
++argc;
new_argv = (char **) alloca ((1 + argc + 1) * sizeof (char *));
new_argv[0] = shell_path;
new_argv[1] = program;
while (argc > 0)
{
new_argv[1 + argc] = argv[argc];
--argc;
}
execve (shell_path, new_argv, envp);
perror_with_name ("execve: ", shell_path);
}
}
else
perror_with_name ("execve: ", program);
}
_exit (127);
}
/* Figure out the argument list necessary to run LINE as a command.
Try to avoid using a shell. This routine handles only ' quoting.
Starting quotes may be escaped with a backslash. If any of the
characters in sh_chars[] is seen, or any of the builtin commands
listed in sh_cmds[] is the first word of a line, the shell is used.
If RESTP is not NULL, *RESTP is set to point to the first newline in LINE.
If *RESTP is NULL, newlines will be ignored.
SHELL is the shell to use, or nil to use the default shell.
IFS is the value of $IFS, or nil (meaning the default). */
static char **
construct_command_argv_internal (line, restp, shell, ifs)
char *line, **restp;
char *shell, *ifs;
{
static char sh_chars[] = "#;\"*?[]&|<>(){}=$`";
static char *sh_cmds[] = { "cd", "eval", "exec", "exit", "login",
"logout", "set", "umask", "wait", "while", "for",
"case", "if", ":", ".", "break", "continue",
"export", "read", "readonly", "shift", "times",
"trap", "switch", 0 };
register int i;
register char *p;
register char *ap;
char *end;
int instring;
char **new_argv = 0;
if (restp != NULL)
*restp = NULL;
/* Make sure not to bother processing an empty line. */
while (isblank (*line))
++line;
if (*line == '\0')
return 0;
/* See if it is safe to parse commands internally. */
if (shell == 0)
shell = default_shell;
else if (strcmp (shell, default_shell))
goto slow;
if (ifs != 0)
for (ap = ifs; *ap != '\0'; ++ap)
if (*ap != ' ' && *ap != '\t' && *ap != '\n')
goto slow;
i = strlen (line) + 1;
/* More than 1 arg per character is impossible. */
new_argv = (char **) xmalloc (i * sizeof (char *));
/* All the args can fit in a buffer as big as LINE is. */
ap = new_argv[0] = (char *) xmalloc (i);
end = ap + i;
/* I is how many complete arguments have been found. */
i = 0;
instring = 0;
for (p = line; *p != '\0'; ++p)
{
if (ap > end)
abort ();
if (instring)
{
/* Inside a string, just copy any char except a closing quote. */
if (*p == '\'')
instring = 0;
else
*ap++ = *p;
}
else if (index (sh_chars, *p) != 0)
/* Not inside a string, but it's a special char. */
goto slow;
else
/* Not a special char. */
switch (*p)
{
case '\\':
/* Backslash-newline combinations are eaten. */
if (p[1] == '\n')
{
/* Eat the backslash, the newline, and following whitespace,
replacing it all with a single space. */
p += 2;
/* If there is a tab after a backslash-newline,
remove it from the source line which will be echoed,
since it was most likely used to line
up the continued line with the previous one. */
if (*p == '\t')
strcpy (p, p + 1);
if (ap != new_argv[i])
/* Treat this as a space, ending the arg.
But if it's at the beginning of the arg, it should
just get eaten, rather than becoming an empty arg. */
goto end_of_arg;
else
--p;
}
else if (p[1] != '\0')
/* Copy and skip the following char. */
*ap++ = *++p;
break;
case '\'':
instring = 1;
break;
case '\n':
if (restp != NULL)
{
/* End of the command line. */
*restp = p;
goto end_of_line;
}
else
/* Newlines are not special. */
*ap++ = '\n';
break;
case ' ':
case '\t':
end_of_arg:
/* We have the end of an argument.
Terminate the text of the argument. */
*ap++ = '\0';
new_argv[++i] = ap;
/* If this argument is the command name,
see if it is a built-in shell command.
If so, have the shell handle it. */
if (i == 1)
{
register int j;
for (j = 0; sh_cmds[j] != 0; ++j)
if (streq (sh_cmds[j], new_argv[0]))
goto slow;
}
/* Ignore multiple whitespace chars. */
p = next_token (p);
/* Next iteration should examine the first nonwhite char. */
--p;
break;
default:
*ap++ = *p;
break;
}
}
end_of_line:
if (instring)
/* Let the shell deal with an unterminated quote. */
goto slow;
/* Terminate the last argument and the argument list. */
*ap = '\0';
if (new_argv[i][0] != '\0')
++i;
new_argv[i] = 0;
if (new_argv[0] == 0)
/* Line was empty. */
return 0;
else
return new_argv;
slow:;
/* We must use the shell. */
if (new_argv != 0)
{
/* Free the old argument list we were working on. */
free (new_argv[0]);
free (new_argv);
}
{
/* SHELL may be a multi-word command. Construct a command line
"SHELL -c LINE", with all special chars in LINE escaped.
Then recurse, expanding this command line to get the final
argument list. */
unsigned int shell_len = strlen (shell);
static char minus_c[] = " -c ";
unsigned int line_len = strlen (line);
char *new_line = (char *) alloca (shell_len + (sizeof (minus_c) - 1)
+ (line_len * 2) + 1);
ap = new_line;
bcopy (shell, ap, shell_len);
ap += shell_len;
bcopy (minus_c, ap, sizeof (minus_c) - 1);
ap += sizeof (minus_c) - 1;
for (p = line; *p != '\0'; ++p)
{
if (restp != NULL && *p == '\n')
{
*restp = p;
break;
}
else if (*p == '\\' && p[1] == '\n')
{
/* Eat the backslash, the newline, and following whitespace,
replacing it all with a single space (which is escaped
from the shell). */
p += 2;
/* If there is a tab after a backslash-newline,
remove it from the source line which will be echoed,
since it was most likely used to line
up the continued line with the previous one. */
if (*p == '\t')
strcpy (p, p + 1);
p = next_token (p);
--p;
*ap++ = '\\';
*ap++ = ' ';
continue;
}
if (*p == '\\' || *p == '\''
|| isspace (*p)
|| index (sh_chars, *p) != 0)
*ap++ = '\\';
*ap++ = *p;
}
*ap = '\0';
new_argv = construct_command_argv_internal (new_line, (char **) NULL,
(char *) 0, (char *) 0);
}
return new_argv;
}
/* Figure out the argument list necessary to run LINE as a command.
Try to avoid using a shell. This routine handles only ' quoting.
Starting quotes may be escaped with a backslash. If any of the
characters in sh_chars[] is seen, or any of the builtin commands
listed in sh_cmds[] is the first word of a line, the shell is used.
If RESTP is not NULL, *RESTP is set to point to the first newline in LINE.
If *RESTP is NULL, newlines will be ignored.
FILE is the target whose commands these are. It is used for
variable expansion for $(SHELL) and $(IFS). */
char **
construct_command_argv (line, restp, file)
char *line, **restp;
struct file *file;
{
char *shell = allocated_variable_expand_for_file ("$(SHELL)", file);
char *ifs = allocated_variable_expand_for_file ("$(IFS)", file);
char **argv;
argv = construct_command_argv_internal (line, restp, shell, ifs);
free (shell);
free (ifs);
return argv;
}
#if (defined(USG) && !defined(HAVE_SIGLIST)) || defined(DGUX)
/* Initialize sys_siglist. */
void
init_siglist ()
{
char buf[100];
register unsigned int i;
for (i = 0; i < NSIG; ++i)
switch (i)
{
default:
sprintf (buf, "Signal %u", i);
sys_siglist[i] = savestring (buf, strlen (buf));
break;
case SIGHUP:
sys_siglist[i] = "Hangup";
break;
case SIGINT:
sys_siglist[i] = "Interrupt";
break;
case SIGQUIT:
sys_siglist[i] = "Quit";
break;
case SIGILL:
sys_siglist[i] = "Illegal Instruction";
break;
case SIGTRAP:
sys_siglist[i] = "Trace Trap";
break;
case SIGIOT:
sys_siglist[i] = "IOT Trap";
break;
#ifdef SIGEMT
case SIGEMT:
sys_siglist[i] = "EMT Trap";
break;
#endif
#ifdef SIGDANGER
case SIGDANGER:
sys_siglist[i] = "Danger signal";
break;
#endif
case SIGFPE:
sys_siglist[i] = "Floating Point Exception";
break;
case SIGKILL:
sys_siglist[i] = "Killed";
break;
case SIGBUS:
sys_siglist[i] = "Bus Error";
break;
case SIGSEGV:
sys_siglist[i] = "Segmentation fault";
break;
case SIGSYS:
sys_siglist[i] = "Bad Argument to System Call";
break;
case SIGPIPE:
sys_siglist[i] = "Broken Pipe";
break;
case SIGALRM:
sys_siglist[i] = "Alarm Clock";
break;
case SIGTERM:
sys_siglist[i] = "Terminated";
break;
#if !defined (SIGIO) || SIGUSR1 != SIGIO
case SIGUSR1:
sys_siglist[i] = "User-defined signal 1";
break;
#endif
#if !defined (SIGURG) || SIGUSR2 != SIGURG
case SIGUSR2:
sys_siglist[i] = "User-defined signal 2";
break;
#endif
#ifdef SIGCLD
case SIGCLD:
#endif
#if defined(SIGCHLD) && !defined(SIGCLD)
case SIGCHLD:
#endif
sys_siglist[i] = "Child Process Exited";
break;
#ifdef SIGPWR
case SIGPWR:
sys_siglist[i] = "Power Failure";
break;
#endif
#ifdef SIGVTALRM
case SIGVTALRM:
sys_siglist[i] = "Virtual Timer Alarm";
break;
#endif
#ifdef SIGPROF
case SIGPROF:
sys_siglist[i] = "Profiling Alarm Clock";
break;
#endif
#ifdef SIGIO
case SIGIO:
sys_siglist[i] = "I/O Possible";
break;
#endif
#ifdef SIGWINDOW
case SIGWINDOW:
sys_siglist[i] = "Window System Signal";
break;
#endif
#ifdef SIGSTOP
case SIGSTOP:
sys_siglist[i] = "Stopped (signal)";
break;
#endif
#ifdef SIGTSTP
case SIGTSTP:
sys_siglist[i] = "Stopped";
break;
#endif
#ifdef SIGCONT
case SIGCONT:
sys_siglist[i] = "Continued";
break;
#endif
#ifdef SIGTTIN
case SIGTTIN:
sys_siglist[i] = "Stopped (tty input)";
break;
#endif
#ifdef SIGTTOU
case SIGTTOU:
sys_siglist[i] = "Stopped (tty output)";
break;
#endif
#ifdef SIGURG
case SIGURG:
sys_siglist[i] = "Urgent Condition on Socket";
break;
#endif
#ifdef SIGXCPU
case SIGXCPU:
sys_siglist[i] = "CPU Limit Exceeded";
break;
#endif
#ifdef SIGXFSZ
case SIGXFSZ:
sys_siglist[i] = "File Size Limit Exceeded";
break;
#endif
}
}
#endif /* USG and not HAVE_SIGLIST. */
#if defined(USG) && !defined(USGr3) && !defined(HAVE_DUP2)
int
dup2 (old, new)
int old, new;
{
int fd;
(void) close (new);
fd = dup (old);
if (fd != new)
{
(void) close (fd);
errno = EMFILE;
return -1;
}
return fd;
}
#endif /* USG and not USGr3 and not HAVE_DUP2. */