/* Interfaces to system-dependent kernel and library entries. Copyright (C) 1985-1988, 1993-1995, 1999-2021 Free Software Foundation, Inc. This file is part of GNU Emacs. GNU Emacs 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. GNU Emacs 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 Emacs. If not, see . */ #include #include #include "sysstdio.h" #ifdef HAVE_PWD_H #include #include #endif /* HAVE_PWD_H */ #include #include #include #include #include #include #include #include #include "lisp.h" #include "sheap.h" #include "sysselect.h" #include "blockinput.h" #ifdef HAVE_LINUX_FS_H # include # include #endif #ifdef CYGWIN # include #endif #if defined DARWIN_OS || defined __FreeBSD__ || defined __OpenBSD__ # include #endif #if defined __OpenBSD__ # include #endif #ifdef DARWIN_OS # include #endif #ifdef __FreeBSD__ /* Sparc/ARM machine/frame.h has 'struct frame' which conflicts with Emacs's 'struct frame', so rename it. */ # define frame freebsd_frame # include # undef frame # include #endif #ifdef HAVE_SOCKETS #include #include #endif /* HAVE_SOCKETS */ #ifdef WINDOWSNT #define read sys_read #define write sys_write #ifndef STDERR_FILENO #define STDERR_FILENO fileno(GetStdHandle(STD_ERROR_HANDLE)) #endif #include "w32.h" #endif /* WINDOWSNT */ #include #include #include /* Get SI_SRPC_DOMAIN, if it is available. */ #ifdef HAVE_SYS_SYSTEMINFO_H #include #endif #ifdef MSDOS /* Demacs 1.1.2 91/10/20 Manabu Higashida, MW Aug 1993 */ #include "msdos.h" #endif #include #include #include #include "syssignal.h" #include "systime.h" #include "systty.h" #include "syswait.h" #ifdef HAVE_SYS_RESOURCE_H # include #endif #ifdef HAVE_SYS_UTSNAME_H # include # include #endif #include "keyboard.h" #include "frame.h" #include "termhooks.h" #include "termchar.h" #include "termopts.h" #include "process.h" #include "cm.h" #ifdef WINDOWSNT # include /* In process.h which conflicts with the local copy. */ # define _P_WAIT 0 int _cdecl _spawnlp (int, const char *, const char *, ...); /* The following is needed for O_CLOEXEC, F_SETFD, FD_CLOEXEC, and several prototypes of functions called below. */ # include #endif /* Declare here, including term.h is problematic on some systems. */ extern void tputs (const char *, int, int (*)(int)); static const int baud_convert[] = { 0, 50, 75, 110, 135, 150, 200, 300, 600, 1200, 1800, 2400, 4800, 9600, 19200, 38400 }; #ifdef HAVE_PERSONALITY_ADDR_NO_RANDOMIZE # include /* If not -1, the personality that should be restored before exec. */ static int exec_personality; /* Try to disable randomization if the current process needs it and does not appear to have it already. */ int maybe_disable_address_randomization (int argc, char **argv) { /* Undocumented Emacs option used only by this function. */ static char const aslr_disabled_option[] = "--__aslr-disabled"; if (argc < 2 || strcmp (argv[1], aslr_disabled_option) != 0) { /* If dumping via unexec, ASLR must be disabled, as otherwise data may be scattered and undumpable as a simple executable. If pdumping, disabling ASLR lessens differences in the .pdmp file. */ bool disable_aslr = will_dump_p (); # ifdef __PPC64__ disable_aslr = true; # endif exec_personality = disable_aslr ? personality (0xffffffff) : -1; if (exec_personality & ADDR_NO_RANDOMIZE) exec_personality = -1; if (exec_personality != -1 && personality (exec_personality | ADDR_NO_RANDOMIZE) != -1) { char **newargv = malloc ((argc + 2) * sizeof *newargv); if (newargv) { /* Invoke self with undocumented option. */ newargv[0] = argv[0]; newargv[1] = (char *) aslr_disabled_option; memcpy (&newargv[2], &argv[1], argc * sizeof *newargv); execvp (newargv[0], newargv); } /* If malloc or execvp fails, warn and then try anyway. */ perror (argv[0]); free (newargv); } } else { /* Our earlier incarnation already disabled ASLR. */ argc--; memmove (&argv[1], &argv[2], argc * sizeof *argv); } return argc; } #endif #ifndef WINDOWSNT /* Execute the program in FILE, with argument vector ARGV and environ ENVP. Return an error number if unsuccessful. This is like execve except it reenables ASLR in the executed program if necessary, and on error it returns an error number rather than -1. */ int emacs_exec_file (char const *file, char *const *argv, char *const *envp) { #ifdef HAVE_PERSONALITY_ADDR_NO_RANDOMIZE if (exec_personality != -1) personality (exec_personality); #endif execve (file, argv, envp); return errno; } #endif /* !WINDOWSNT */ /* If FD is not already open, arrange for it to be open with FLAGS. */ static void force_open (int fd, int flags) { if (dup2 (fd, fd) < 0 && errno == EBADF) { int n = open (NULL_DEVICE, flags); if (n < 0 || (fd != n && (dup2 (n, fd) < 0 || emacs_close (n) != 0))) { emacs_perror (NULL_DEVICE); exit (EXIT_FAILURE); } } } /* A stream that is like stderr, except line buffered. It is NULL during startup, or if line buffering is not in use. */ static FILE *buferr; /* Make sure stdin, stdout, and stderr are open to something, so that their file descriptors are not hijacked by later system calls. */ void init_standard_fds (void) { /* Open stdin for *writing*, and stdout and stderr for *reading*. That way, any attempt to do normal I/O will result in an error, just as if the files were closed, and the file descriptors will not be reused by later opens. */ force_open (STDIN_FILENO, O_WRONLY); force_open (STDOUT_FILENO, O_RDONLY); force_open (STDERR_FILENO, O_RDONLY); /* Set buferr if possible on platforms defining _PC_PIPE_BUF, as they support the notion of atomic writes to pipes. */ #ifdef _PC_PIPE_BUF buferr = fdopen (STDERR_FILENO, "w"); if (buferr) setvbuf (buferr, NULL, _IOLBF, 0); #endif } /* Return the current working directory. The result should be freed with 'free'. Return NULL (setting errno) on errors. If the current directory is unreachable, return either NULL or a string beginning with '('. */ static char * get_current_dir_name_or_unreachable (void) { /* Use malloc, not xmalloc, since this function can be called before the xmalloc exception machinery is available. */ char *pwd; /* The maximum size of a directory name, including the terminating null. Leave room so that the caller can append a trailing slash. */ ptrdiff_t dirsize_max = min (PTRDIFF_MAX, SIZE_MAX) - 1; /* The maximum size of a buffer for a file name, including the terminating null. This is bounded by PATH_MAX, if available. */ ptrdiff_t bufsize_max = dirsize_max; #ifdef PATH_MAX bufsize_max = min (bufsize_max, PATH_MAX); #endif # if HAVE_GET_CURRENT_DIR_NAME && !BROKEN_GET_CURRENT_DIR_NAME # ifdef HYBRID_MALLOC bool use_libc = will_dump_with_unexec_p (); # else bool use_libc = true; # endif if (use_libc) { /* For an unreachable directory, this returns a string that starts with "(unreachable)"; see Bug#27871. */ pwd = get_current_dir_name (); if (pwd) { if (strnlen (pwd, dirsize_max) < dirsize_max) return pwd; free (pwd); errno = ERANGE; } return NULL; } # endif size_t pwdlen; struct stat dotstat, pwdstat; pwd = getenv ("PWD"); /* If PWD is accurate, use it instead of calling getcwd. PWD is sometimes a nicer name, and using it may avoid a fatal error if a parent directory is searchable but not readable. */ if (pwd && (pwdlen = strnlen (pwd, bufsize_max)) < bufsize_max && IS_DIRECTORY_SEP (pwd[pwdlen && IS_DEVICE_SEP (pwd[1]) ? 2 : 0]) && emacs_fstatat (AT_FDCWD, pwd, &pwdstat, 0) == 0 && emacs_fstatat (AT_FDCWD, ".", &dotstat, 0) == 0 && dotstat.st_ino == pwdstat.st_ino && dotstat.st_dev == pwdstat.st_dev) return strdup (pwd); else { ptrdiff_t buf_size = min (bufsize_max, 1024); for (;;) { char *buf = malloc (buf_size); if (!buf) return NULL; if (getcwd (buf, buf_size) == buf) return buf; free (buf); if (errno != ERANGE || buf_size == bufsize_max) return NULL; buf_size = buf_size <= bufsize_max / 2 ? 2 * buf_size : bufsize_max; } } } /* Return the current working directory. The result should be freed with 'free'. Return NULL (setting errno) on errors; an unreachable directory (e.g., its name starts with '(') counts as an error. */ char * emacs_get_current_dir_name (void) { char *dir = get_current_dir_name_or_unreachable (); if (dir && *dir == '(') { free (dir); errno = ENOENT; return NULL; } return dir; } /* Discard pending input on all input descriptors. */ void discard_tty_input (void) { #ifndef WINDOWSNT struct emacs_tty buf; if (noninteractive) return; #ifdef MSDOS /* Demacs 1.1.1 91/10/16 HIRANO Satoshi */ while (dos_keyread () != -1) ; #else /* not MSDOS */ { struct tty_display_info *tty; for (tty = tty_list; tty; tty = tty->next) { if (tty->input) /* Is the device suspended? */ { emacs_get_tty (fileno (tty->input), &buf); emacs_set_tty (fileno (tty->input), &buf, 0); } } } #endif /* not MSDOS */ #endif /* not WINDOWSNT */ } #ifdef SIGTSTP /* Arrange for character C to be read as the next input from the terminal. XXX What if we have multiple ttys? */ void stuff_char (char c) { if (! (FRAMEP (selected_frame) && FRAME_LIVE_P (XFRAME (selected_frame)) && FRAME_TERMCAP_P (XFRAME (selected_frame)))) return; /* Should perhaps error if in batch mode */ #ifdef TIOCSTI ioctl (fileno (CURTTY()->input), TIOCSTI, &c); #else /* no TIOCSTI */ error ("Cannot stuff terminal input characters in this version of Unix"); #endif /* no TIOCSTI */ } #endif /* SIGTSTP */ void init_baud_rate (int fd) { int emacs_ospeed; if (noninteractive) emacs_ospeed = 0; else { #ifdef DOS_NT emacs_ospeed = 15; #else /* not DOS_NT */ struct termios sg; sg.c_cflag = B9600; tcgetattr (fd, &sg); emacs_ospeed = cfgetospeed (&sg); #endif /* not DOS_NT */ } baud_rate = (emacs_ospeed < ARRAYELTS (baud_convert) ? baud_convert[emacs_ospeed] : 9600); if (baud_rate == 0) baud_rate = 1200; } #ifndef MSDOS /* Wait for the subprocess with process id CHILD to terminate or change status. CHILD must be a child process that has not been reaped. If STATUS is non-null, store the waitpid-style exit status into *STATUS and tell wait_reading_process_output that it needs to look around. Use waitpid-style OPTIONS when waiting. If INTERRUPTIBLE, this function is interruptible by a signal. Return CHILD if successful, 0 if no status is available, and a negative value (setting errno) if waitpid is buggy. */ static pid_t get_child_status (pid_t child, int *status, int options, bool interruptible) { pid_t pid; /* Invoke waitpid only with a known process ID; do not invoke waitpid with a nonpositive argument. Otherwise, Emacs might reap an unwanted process by mistake. For example, invoking waitpid (-1, ...) can mess up glib by reaping glib's subprocesses, so that another thread running glib won't find them. */ eassert (child > 0); while (true) { /* Note: the MS-Windows emulation of waitpid calls maybe_quit internally. */ if (interruptible) maybe_quit (); pid = waitpid (child, status, options); if (0 <= pid) break; if (errno != EINTR) { /* Most likely, waitpid is buggy and the operating system lost track of the child somehow. Return -1 and let the caller try to figure things out. Possibly the bug could cause Emacs to kill the wrong process. Oh well. */ return pid; } } /* If successful and status is requested, tell wait_reading_process_output that it needs to wake up and look around. */ if (pid && status && input_available_clear_time) *input_available_clear_time = make_timespec (0, 0); return pid; } /* Wait for the subprocess with process id CHILD to terminate. CHILD must be a child process that has not been reaped. If STATUS is non-null, store the waitpid-style exit status into *STATUS and tell wait_reading_process_output that it needs to look around. If INTERRUPTIBLE, this function is interruptible by a signal. Return true if successful, false (setting errno) if CHILD cannot be waited for because waitpid is buggy. */ bool wait_for_termination (pid_t child, int *status, bool interruptible) { return 0 <= get_child_status (child, status, 0, interruptible); } /* Report whether the subprocess with process id CHILD has changed status. Termination counts as a change of status. CHILD must be a child process that has not been reaped. If STATUS is non-null, store the waitpid-style exit status into *STATUS and tell wait_reading_process_output that it needs to look around. Use waitpid-style OPTIONS to check status, but do not wait. Return CHILD if successful, 0 if no status is available because the process's state has not changed. */ pid_t child_status_changed (pid_t child, int *status, int options) { return get_child_status (child, status, WNOHANG | options, 0); } /* Set up the terminal at the other end of a pseudo-terminal that we will be controlling an inferior through. It should not echo or do line-editing, since that is done in Emacs. No padding needed for insertion into an Emacs buffer. */ void child_setup_tty (int out) { #ifndef WINDOWSNT struct emacs_tty s; emacs_get_tty (out, &s); s.main.c_oflag |= OPOST; /* Enable output postprocessing */ s.main.c_oflag &= ~ONLCR; /* Disable map of NL to CR-NL on output */ #ifdef NLDLY /* https://lists.gnu.org/r/emacs-devel/2008-05/msg00406.html Some versions of GNU Hurd do not have FFDLY? */ #ifdef FFDLY s.main.c_oflag &= ~(NLDLY|CRDLY|TABDLY|BSDLY|VTDLY|FFDLY); /* No output delays */ #else s.main.c_oflag &= ~(NLDLY|CRDLY|TABDLY|BSDLY|VTDLY); /* No output delays */ #endif #endif s.main.c_lflag &= ~ECHO; /* Disable echo */ s.main.c_lflag |= ISIG; /* Enable signals */ #ifdef IUCLC s.main.c_iflag &= ~IUCLC; /* Disable downcasing on input. */ #endif #ifdef ISTRIP s.main.c_iflag &= ~ISTRIP; /* don't strip 8th bit on input */ #endif #ifdef OLCUC s.main.c_oflag &= ~OLCUC; /* Disable upcasing on output. */ #endif s.main.c_oflag &= ~TAB3; /* Disable tab expansion */ s.main.c_cflag = (s.main.c_cflag & ~CSIZE) | CS8; /* Don't strip 8th bit */ s.main.c_cc[VERASE] = CDISABLE; /* disable erase processing */ s.main.c_cc[VKILL] = CDISABLE; /* disable kill processing */ #ifdef HPUX s.main.c_cflag = (s.main.c_cflag & ~CBAUD) | B9600; /* baud rate sanity */ #endif /* HPUX */ #ifdef SIGNALS_VIA_CHARACTERS /* the QUIT and INTR character are used in process_send_signal so set them here to something useful. */ if (s.main.c_cc[VQUIT] == CDISABLE) s.main.c_cc[VQUIT] = '\\'&037; /* Control-\ */ if (s.main.c_cc[VINTR] == CDISABLE) s.main.c_cc[VINTR] = 'C'&037; /* Control-C */ #endif /* not SIGNALS_VIA_CHARACTERS */ #ifdef AIX /* Also, PTY overloads NUL and BREAK. don't ignore break, but don't signal either, so it looks like NUL. */ s.main.c_iflag &= ~IGNBRK; s.main.c_iflag &= ~BRKINT; /* rms: Formerly it set s.main.c_cc[VINTR] to 0377 here unconditionally. Then a SIGNALS_VIA_CHARACTERS conditional would force it to 0377. That looks like duplicated code. */ s.main.c_cflag = (s.main.c_cflag & ~CBAUD) | B9600; /* baud rate sanity */ #endif /* AIX */ /* We originally enabled ICANON (and set VEOF to 04), and then had process.c send additional EOF chars to flush the output when faced with long lines, but this leads to weird effects when the subprocess has disabled ICANON and ends up seeing those spurious extra EOFs. So we don't send EOFs any more in process.c:send_process. First we tried to disable ICANON by default, so if a subsprocess sets up ICANON, it's his problem (or the Elisp package that talks to it) to deal with lines that are too long. But this disables some features, such as the ability to send EOF signals. So we re-enabled ICANON but there is no more "send eof to flush" going on (which is wrong and unportable in itself). The correct way to handle too much output is to buffer what could not be written and then write it again when select returns ok for writing. This has it own set of problems. Write is now asynchronous, is that a problem? How much do we buffer, and what do we do when that limit is reached? */ s.main.c_lflag |= ICANON; /* Enable line editing and eof processing */ s.main.c_cc[VEOF] = 'D'&037; /* Control-D */ #if 0 /* These settings only apply to non-ICANON mode. */ s.main.c_cc[VMIN] = 1; s.main.c_cc[VTIME] = 0; #endif emacs_set_tty (out, &s, 0); #endif /* not WINDOWSNT */ } #endif /* not MSDOS */ /* Record a signal code and the action for it. */ struct save_signal { int code; struct sigaction action; }; static void save_signal_handlers (struct save_signal *); static void restore_signal_handlers (struct save_signal *); /* Suspend the Emacs process; give terminal to its superior. */ void sys_suspend (void) { #ifndef DOS_NT kill (0, SIGTSTP); #else /* On a system where suspending is not implemented, instead fork a subshell and let it talk directly to the terminal while we wait. */ sys_subshell (); #endif } /* Fork a subshell. */ void sys_subshell (void) { #ifdef DOS_NT /* Demacs 1.1.2 91/10/20 Manabu Higashida */ #ifdef MSDOS int st; char oldwd[MAXPATHLEN+1]; /* Fixed length is safe on MSDOS. */ #else char oldwd[MAX_UTF8_PATH]; #endif /* MSDOS */ #else /* !DOS_NT */ int status; #endif pid_t pid; struct save_signal saved_handlers[5]; char *str = SSDATA (get_current_directory (true)); #ifdef DOS_NT pid = 0; #else { char *volatile str_volatile = str; pid = vfork (); str = str_volatile; } #endif if (pid < 0) error ("Can't spawn subshell"); saved_handlers[0].code = SIGINT; saved_handlers[1].code = SIGQUIT; saved_handlers[2].code = SIGTERM; #ifdef USABLE_SIGIO saved_handlers[3].code = SIGIO; saved_handlers[4].code = 0; #elif defined (USABLE_SIGPOLL) saved_handlers[3].code = SIGPOLL; saved_handlers[4].code = 0; #else saved_handlers[3].code = 0; #endif #ifdef DOS_NT save_signal_handlers (saved_handlers); #endif if (pid == 0) { const char *sh = 0; #ifdef DOS_NT /* MW, Aug 1993 */ getcwd (oldwd, sizeof oldwd); if (sh == 0) sh = egetenv ("SUSPEND"); /* KFS, 1994-12-14 */ #endif if (sh == 0) sh = egetenv ("SHELL"); if (sh == 0) sh = "sh"; /* Use our buffer's default directory for the subshell. */ if (chdir (str) != 0) { #ifndef DOS_NT emacs_perror (str); _exit (EXIT_CANCELED); #endif } #ifdef MSDOS /* Demacs 1.1.2 91/10/20 Manabu Higashida */ { char *epwd = getenv ("PWD"); char old_pwd[MAXPATHLEN+1+4]; /* If PWD is set, pass it with corrected value. */ if (epwd) { strcpy (old_pwd, epwd); setenv ("PWD", str, 1); } st = system (sh); chdir (oldwd); /* FIXME: Do the right thing on chdir failure. */ if (epwd) putenv (old_pwd); /* restore previous value */ } #else /* not MSDOS */ #ifdef WINDOWSNT /* Waits for process completion */ pid = _spawnlp (_P_WAIT, sh, sh, NULL); chdir (oldwd); /* FIXME: Do the right thing on chdir failure. */ if (pid == -1) write (1, "Can't execute subshell", 22); #else /* not WINDOWSNT */ execlp (sh, sh, (char *) 0); emacs_perror (sh); _exit (errno == ENOENT ? EXIT_ENOENT : EXIT_CANNOT_INVOKE); #endif /* not WINDOWSNT */ #endif /* not MSDOS */ } /* Do this now if we did not do it before. */ #ifndef MSDOS save_signal_handlers (saved_handlers); #endif #ifndef DOS_NT wait_for_termination (pid, &status, 0); #endif restore_signal_handlers (saved_handlers); } static void save_signal_handlers (struct save_signal *saved_handlers) { while (saved_handlers->code) { struct sigaction action; emacs_sigaction_init (&action, SIG_IGN); sigaction (saved_handlers->code, &action, &saved_handlers->action); saved_handlers++; } } static void restore_signal_handlers (struct save_signal *saved_handlers) { while (saved_handlers->code) { sigaction (saved_handlers->code, &saved_handlers->action, 0); saved_handlers++; } } #ifdef USABLE_SIGIO static int old_fcntl_flags[FD_SETSIZE]; #endif void init_sigio (int fd) { #ifdef USABLE_SIGIO old_fcntl_flags[fd] = fcntl (fd, F_GETFL, 0) & ~FASYNC; fcntl (fd, F_SETFL, old_fcntl_flags[fd] | FASYNC); interrupts_deferred = 0; #endif } #ifndef DOS_NT #ifdef F_SETOWN static void reset_sigio (int fd) { #ifdef USABLE_SIGIO fcntl (fd, F_SETFL, old_fcntl_flags[fd]); #endif } #endif /* F_SETOWN */ #endif void request_sigio (void) { #if defined (USABLE_SIGIO) || defined (USABLE_SIGPOLL) sigset_t unblocked; if (noninteractive) return; sigemptyset (&unblocked); # ifdef SIGWINCH sigaddset (&unblocked, SIGWINCH); # endif # ifdef USABLE_SIGIO sigaddset (&unblocked, SIGIO); # else sigaddset (&unblocked, SIGPOLL); # endif pthread_sigmask (SIG_UNBLOCK, &unblocked, 0); interrupts_deferred = 0; #endif } void unrequest_sigio (void) { #if defined (USABLE_SIGIO) || defined (USABLE_SIGPOLL) sigset_t blocked; if (noninteractive) return; sigemptyset (&blocked); # ifdef SIGWINCH sigaddset (&blocked, SIGWINCH); # endif # ifdef USABLE_SIGIO sigaddset (&blocked, SIGIO); # else sigaddset (&blocked, SIGPOLL); # endif pthread_sigmask (SIG_BLOCK, &blocked, 0); interrupts_deferred = 1; #endif } #ifndef MSDOS /* Block SIGCHLD. */ void block_child_signal (sigset_t *oldset) { sigset_t blocked; sigemptyset (&blocked); sigaddset (&blocked, SIGCHLD); sigaddset (&blocked, SIGINT); pthread_sigmask (SIG_BLOCK, &blocked, oldset); } /* Unblock SIGCHLD. */ void unblock_child_signal (sigset_t const *oldset) { pthread_sigmask (SIG_SETMASK, oldset, 0); } #endif /* !MSDOS */ /* Block SIGINT. */ void block_interrupt_signal (sigset_t *oldset) { sigset_t blocked; sigemptyset (&blocked); sigaddset (&blocked, SIGINT); pthread_sigmask (SIG_BLOCK, &blocked, oldset); } /* Restore previously saved signal mask. */ void restore_signal_mask (sigset_t const *oldset) { pthread_sigmask (SIG_SETMASK, oldset, 0); } /* Saving and restoring the process group of Emacs's terminal. */ /* The process group of which Emacs was a member when it initially started. If Emacs was in its own process group (i.e. inherited_pgroup == getpid ()), then we know we're running under a shell with job control (Emacs would never be run as part of a pipeline). Everything is fine. If Emacs was not in its own process group, then we know we're running under a shell (or a caller) that doesn't know how to separate itself from Emacs (like sh). Emacs must be in its own process group in order to receive SIGIO correctly. In this situation, we put ourselves in our own pgroup, forcibly set the tty's pgroup to our pgroup, and make sure to restore and reinstate the tty's pgroup just like any other terminal setting. If inherited_group was not the tty's pgroup, then we'll get a SIGTTmumble when we try to change the tty's pgroup, and a CONT if it goes foreground in the future, which is what should happen. */ static pid_t inherited_pgroup; void init_foreground_group (void) { pid_t pgrp = getpgrp (); inherited_pgroup = getpid () == pgrp ? 0 : pgrp; } /* Block and unblock SIGTTOU. */ void block_tty_out_signal (sigset_t *oldset) { #ifdef SIGTTOU sigset_t blocked; sigemptyset (&blocked); sigaddset (&blocked, SIGTTOU); pthread_sigmask (SIG_BLOCK, &blocked, oldset); #endif } void unblock_tty_out_signal (sigset_t const *oldset) { #ifdef SIGTTOU pthread_sigmask (SIG_SETMASK, oldset, 0); #endif } /* Safely set a controlling terminal FD's process group to PGID. If we are not in the foreground already, POSIX requires tcsetpgrp to deliver a SIGTTOU signal, which would stop us. This is an annoyance, so temporarily ignore the signal. In practice, platforms lacking SIGTTOU also lack tcsetpgrp, so skip all this unless SIGTTOU is defined. */ static void tcsetpgrp_without_stopping (int fd, pid_t pgid) { #ifdef SIGTTOU sigset_t oldset; block_input (); block_tty_out_signal (&oldset); tcsetpgrp (fd, pgid); unblock_tty_out_signal (&oldset); unblock_input (); #endif } /* Split off the foreground process group to Emacs alone. When we are in the foreground, but not started in our own process group, redirect the tty device handle FD to point to our own process group. FD must be the file descriptor of the controlling tty. */ static void narrow_foreground_group (int fd) { if (inherited_pgroup && setpgid (0, 0) == 0) tcsetpgrp_without_stopping (fd, getpid ()); } /* Set the tty to our original foreground group. */ static void widen_foreground_group (int fd) { if (inherited_pgroup && setpgid (0, inherited_pgroup) == 0) tcsetpgrp_without_stopping (fd, inherited_pgroup); } /* Getting and setting emacs_tty structures. */ /* Set *TC to the parameters associated with the terminal FD, or clear it if the parameters are not available. Return 0 on success, -1 on failure. */ int emacs_get_tty (int fd, struct emacs_tty *settings) { /* Retrieve the primary parameters - baud rate, character size, etcetera. */ memset (&settings->main, 0, sizeof (settings->main)); #ifdef DOS_NT #ifdef WINDOWSNT HANDLE h = (HANDLE)_get_osfhandle (fd); DWORD console_mode; if (h && h != INVALID_HANDLE_VALUE && GetConsoleMode (h, &console_mode)) { settings->main = console_mode; return 0; } #endif /* WINDOWSNT */ return -1; #else /* !DOS_NT */ /* We have those nifty POSIX tcmumbleattr functions. */ return tcgetattr (fd, &settings->main); #endif } /* Set the parameters of the tty on FD according to the contents of *SETTINGS. If FLUSHP, discard input. Return 0 if all went well, and -1 (setting errno) if anything failed. */ int emacs_set_tty (int fd, struct emacs_tty *settings, bool flushp) { /* Set the primary parameters - baud rate, character size, etcetera. */ #ifdef DOS_NT #ifdef WINDOWSNT HANDLE h = (HANDLE)_get_osfhandle (fd); if (h && h != INVALID_HANDLE_VALUE) { DWORD new_mode; /* Assume the handle is open for input. */ if (flushp) FlushConsoleInputBuffer (h); new_mode = settings->main; SetConsoleMode (h, new_mode); } #endif /* WINDOWSNT */ #else /* !DOS_NT */ int i; /* We have those nifty POSIX tcmumbleattr functions. William J. Smith writes: "POSIX 1003.1 defines tcsetattr to return success if it was able to perform any of the requested actions, even if some of the requested actions could not be performed. We must read settings back to ensure tty setup properly. AIX requires this to keep tty from hanging occasionally." */ /* This make sure that we don't loop indefinitely in here. */ for (i = 0 ; i < 10 ; i++) if (tcsetattr (fd, flushp ? TCSAFLUSH : TCSADRAIN, &settings->main) < 0) { if (errno == EINTR) continue; else return -1; } else { struct termios new; memset (&new, 0, sizeof (new)); /* Get the current settings, and see if they're what we asked for. */ tcgetattr (fd, &new); /* We cannot use memcmp on the whole structure here because under * aix386 the termios structure has some reserved field that may * not be filled in. */ if ( new.c_iflag == settings->main.c_iflag && new.c_oflag == settings->main.c_oflag && new.c_cflag == settings->main.c_cflag && new.c_lflag == settings->main.c_lflag && memcmp (new.c_cc, settings->main.c_cc, NCCS) == 0) break; else continue; } #endif /* We have survived the tempest. */ return 0; } #ifdef F_SETOWN static int old_fcntl_owner[FD_SETSIZE]; #endif /* F_SETOWN */ /* Initialize the terminal mode on all tty devices that are currently open. */ void init_all_sys_modes (void) { struct tty_display_info *tty; for (tty = tty_list; tty; tty = tty->next) init_sys_modes (tty); } /* Initialize the terminal mode on the given tty device. */ void init_sys_modes (struct tty_display_info *tty_out) { struct emacs_tty tty; #ifndef DOS_NT Lisp_Object terminal; #endif Vtty_erase_char = Qnil; if (noninteractive) return; if (!tty_out->output) return; /* The tty is suspended. */ narrow_foreground_group (fileno (tty_out->input)); if (! tty_out->old_tty) tty_out->old_tty = xmalloc (sizeof *tty_out->old_tty); emacs_get_tty (fileno (tty_out->input), tty_out->old_tty); tty = *tty_out->old_tty; #if !defined (DOS_NT) XSETINT (Vtty_erase_char, tty.main.c_cc[VERASE]); tty.main.c_iflag |= (IGNBRK); /* Ignore break condition */ tty.main.c_iflag &= ~ICRNL; /* Disable map of CR to NL on input */ #ifdef INLCR /* I'm just being cautious, since I can't check how widespread INLCR is--rms. */ tty.main.c_iflag &= ~INLCR; /* Disable map of NL to CR on input */ #endif #ifdef ISTRIP tty.main.c_iflag &= ~ISTRIP; /* don't strip 8th bit on input */ #endif tty.main.c_lflag &= ~ECHO; /* Disable echo */ tty.main.c_lflag &= ~ICANON; /* Disable erase/kill processing */ #ifdef IEXTEN tty.main.c_lflag &= ~IEXTEN; /* Disable other editing characters. */ #endif tty.main.c_lflag |= ISIG; /* Enable signals */ if (tty_out->flow_control) { tty.main.c_iflag |= IXON; /* Enable start/stop output control */ #ifdef IXANY tty.main.c_iflag &= ~IXANY; #endif /* IXANY */ } else tty.main.c_iflag &= ~IXON; /* Disable start/stop output control */ tty.main.c_oflag &= ~ONLCR; /* Disable map of NL to CR-NL on output */ tty.main.c_oflag &= ~TAB3; /* Disable tab expansion */ #ifdef CS8 if (tty_out->meta_key) { tty.main.c_cflag |= CS8; /* allow 8th bit on input */ tty.main.c_cflag &= ~PARENB;/* Don't check parity */ } #endif XSETTERMINAL(terminal, tty_out->terminal); if (!NILP (Fcontrolling_tty_p (terminal))) { tty.main.c_cc[VINTR] = quit_char; /* C-g (usually) gives SIGINT */ /* Set up C-g for both SIGQUIT and SIGINT. We don't know which we will get, but we handle both alike so which one it really gives us does not matter. */ tty.main.c_cc[VQUIT] = quit_char; } else { /* We normally don't get interrupt or quit signals from tty devices other than our controlling terminal; therefore, we must handle C-g as normal input. Unfortunately, this means that the interrupt and quit feature must be disabled on secondary ttys, or we would not even see the keypress. Note that even though emacsclient could have special code to pass SIGINT to Emacs, we should _not_ enable interrupt/quit keys for emacsclient frames. This means that we can't break out of loops in C code from a secondary tty frame, but we can always decide what display the C-g came from, which is more important from a usability point of view. (Consider the case when two people work together using the same Emacs instance.) */ tty.main.c_cc[VINTR] = CDISABLE; tty.main.c_cc[VQUIT] = CDISABLE; } tty.main.c_cc[VMIN] = 1; /* Input should wait for at least 1 char */ tty.main.c_cc[VTIME] = 0; /* no matter how long that takes. */ #ifdef VSWTCH tty.main.c_cc[VSWTCH] = CDISABLE; /* Turn off shell layering use of C-z */ #endif /* VSWTCH */ #ifdef VSUSP tty.main.c_cc[VSUSP] = CDISABLE; /* Turn off handling of C-z. */ #endif /* VSUSP */ #ifdef V_DSUSP tty.main.c_cc[V_DSUSP] = CDISABLE; /* Turn off handling of C-y. */ #endif /* V_DSUSP */ #ifdef VDSUSP /* Some systems have VDSUSP, some have V_DSUSP. */ tty.main.c_cc[VDSUSP] = CDISABLE; #endif /* VDSUSP */ #ifdef VLNEXT tty.main.c_cc[VLNEXT] = CDISABLE; #endif /* VLNEXT */ #ifdef VREPRINT tty.main.c_cc[VREPRINT] = CDISABLE; #endif /* VREPRINT */ #ifdef VWERASE tty.main.c_cc[VWERASE] = CDISABLE; #endif /* VWERASE */ #ifdef VDISCARD tty.main.c_cc[VDISCARD] = CDISABLE; #endif /* VDISCARD */ if (tty_out->flow_control) { #ifdef VSTART tty.main.c_cc[VSTART] = '\021'; #endif /* VSTART */ #ifdef VSTOP tty.main.c_cc[VSTOP] = '\023'; #endif /* VSTOP */ } else { #ifdef VSTART tty.main.c_cc[VSTART] = CDISABLE; #endif /* VSTART */ #ifdef VSTOP tty.main.c_cc[VSTOP] = CDISABLE; #endif /* VSTOP */ } #ifdef AIX tty.main.c_cc[VSTRT] = CDISABLE; tty.main.c_cc[VSTOP] = CDISABLE; tty.main.c_cc[VSUSP] = CDISABLE; tty.main.c_cc[VDSUSP] = CDISABLE; if (tty_out->flow_control) { #ifdef VSTART tty.main.c_cc[VSTART] = '\021'; #endif /* VSTART */ #ifdef VSTOP tty.main.c_cc[VSTOP] = '\023'; #endif /* VSTOP */ } /* Also, PTY overloads NUL and BREAK. don't ignore break, but don't signal either, so it looks like NUL. This really serves a purpose only if running in an XTERM window or via TELNET or the like, but does no harm elsewhere. */ tty.main.c_iflag &= ~IGNBRK; tty.main.c_iflag &= ~BRKINT; #endif #endif /* not DOS_NT */ #ifdef MSDOS /* Demacs 1.1.2 91/10/20 Manabu Higashida, MW Aug 1993 */ if (!tty_out->term_initted) internal_terminal_init (); dos_ttraw (tty_out); #endif emacs_set_tty (fileno (tty_out->input), &tty, 0); /* This code added to insure that, if flow-control is not to be used, we have an unlocked terminal at the start. */ #ifndef HAIKU /* On Haiku, TCXONC is a no-op and causes spurious compiler warnings. */ #ifdef TCXONC if (!tty_out->flow_control) ioctl (fileno (tty_out->input), TCXONC, 1); #endif #endif /* HAIKU */ #ifdef TIOCSTART if (!tty_out->flow_control) ioctl (fileno (tty_out->input), TIOCSTART, 0); #endif #if !defined (DOS_NT) #ifdef TCOON if (!tty_out->flow_control) tcflow (fileno (tty_out->input), TCOON); #endif #endif #ifdef F_GETOWN if (interrupt_input) { old_fcntl_owner[fileno (tty_out->input)] = fcntl (fileno (tty_out->input), F_GETOWN, 0); fcntl (fileno (tty_out->input), F_SETOWN, getpid ()); init_sigio (fileno (tty_out->input)); #ifdef HAVE_GPM if (gpm_tty == tty_out) { /* Arrange for mouse events to give us SIGIO signals. */ fcntl (gpm_fd, F_SETOWN, getpid ()); fcntl (gpm_fd, F_SETFL, fcntl (gpm_fd, F_GETFL, 0) | O_NONBLOCK); init_sigio (gpm_fd); } #endif /* HAVE_GPM */ } #endif /* F_GETOWN */ setvbuf (tty_out->output, NULL, _IOFBF, BUFSIZ); if (tty_out->terminal->set_terminal_modes_hook) tty_out->terminal->set_terminal_modes_hook (tty_out->terminal); if (!tty_out->term_initted) { Lisp_Object tail, frame; FOR_EACH_FRAME (tail, frame) { /* XXX This needs to be revised. */ if (FRAME_TERMCAP_P (XFRAME (frame)) && FRAME_TTY (XFRAME (frame)) == tty_out) init_frame_faces (XFRAME (frame)); } } if (tty_out->term_initted && no_redraw_on_reenter) { /* We used to call "direct_output_forward_char(0)" here, but it's not clear why, since it may not do anything anyway. */ } else { Lisp_Object tail, frame; frame_garbaged = 1; FOR_EACH_FRAME (tail, frame) { if ((FRAME_TERMCAP_P (XFRAME (frame)) || FRAME_MSDOS_P (XFRAME (frame))) && FRAME_TTY (XFRAME (frame)) == tty_out) FRAME_GARBAGED_P (XFRAME (frame)) = 1; } } tty_out->term_initted = 1; } /* Return true if safe to use tabs in output. At the time this is called, init_sys_modes has not been done yet. */ bool tabs_safe_p (int fd) { struct emacs_tty etty; emacs_get_tty (fd, &etty); #ifndef DOS_NT #ifdef TABDLY return ((etty.main.c_oflag & TABDLY) != TAB3); #else /* not TABDLY */ return 1; #endif /* not TABDLY */ #else /* DOS_NT */ return 0; #endif /* DOS_NT */ } /* Discard echoing. */ void suppress_echo_on_tty (int fd) { struct emacs_tty etty; emacs_get_tty (fd, &etty); #ifdef DOS_NT /* Set raw input mode. */ etty.main = 0; #else etty.main.c_lflag &= ~ICANON; /* Disable buffering */ etty.main.c_lflag &= ~ECHO; /* Disable echoing */ #endif /* ! WINDOWSNT */ emacs_set_tty (fd, &etty, 0); } /* Get terminal size from system. Store number of lines into *HEIGHTP and width into *WIDTHP. We store 0 if there's no valid information. */ void get_tty_size (int fd, int *widthp, int *heightp) { #if defined TIOCGWINSZ /* BSD-style. */ struct winsize size; if (ioctl (fd, TIOCGWINSZ, &size) == -1) *widthp = *heightp = 0; else { *widthp = size.ws_col; *heightp = size.ws_row; } #elif defined TIOCGSIZE /* SunOS - style. */ struct ttysize size; if (ioctl (fd, TIOCGSIZE, &size) == -1) *widthp = *heightp = 0; else { *widthp = size.ts_cols; *heightp = size.ts_lines; } #elif defined WINDOWSNT CONSOLE_SCREEN_BUFFER_INFO info; if (GetConsoleScreenBufferInfo (GetStdHandle (STD_OUTPUT_HANDLE), &info)) { *widthp = info.srWindow.Right - info.srWindow.Left + 1; *heightp = info.srWindow.Bottom - info.srWindow.Top + 1; } else *widthp = *heightp = 0; #elif defined MSDOS *widthp = ScreenCols (); *heightp = ScreenRows (); #else /* system doesn't know size */ *widthp = 0; *heightp = 0; #endif } /* Set the logical window size associated with descriptor FD to HEIGHT and WIDTH. This is used mainly with ptys. Return a negative value on failure. */ int set_window_size (int fd, int height, int width) { #ifdef TIOCSWINSZ /* BSD-style. */ struct winsize size; memset (&size, 0, sizeof (size)); size.ws_row = height; size.ws_col = width; return ioctl (fd, TIOCSWINSZ, &size); #else #ifdef TIOCSSIZE /* SunOS - style. */ struct ttysize size; memset (&size, 0, sizeof (size)); size.ts_lines = height; size.ts_cols = width; return ioctl (fd, TIOCGSIZE, &size); #else return -1; #endif /* not SunOS-style */ #endif /* not BSD-style */ } /* Prepare all terminal devices for exiting Emacs. */ void reset_all_sys_modes (void) { struct tty_display_info *tty; for (tty = tty_list; tty; tty = tty->next) reset_sys_modes (tty); } /* Prepare the terminal for closing it; move the cursor to the bottom of the frame, turn off interrupt-driven I/O, etc. */ void reset_sys_modes (struct tty_display_info *tty_out) { if (noninteractive) { fflush (stdout); return; } if (!tty_out->term_initted) return; if (!tty_out->output) return; /* The tty is suspended. */ /* Go to and clear the last line of the terminal. */ cmgoto (tty_out, FrameRows (tty_out) - 1, 0); /* Code adapted from tty_clear_end_of_line. */ if (tty_out->TS_clr_line) { emacs_tputs (tty_out, tty_out->TS_clr_line, 1, cmputc); } else { /* have to do it the hard way */ tty_turn_off_insert (tty_out); for (int i = cursorX (tty_out); i < FrameCols (tty_out) - 1; i++) putc (' ', tty_out->output); } cmgoto (tty_out, FrameRows (tty_out) - 1, 0); fflush (tty_out->output); if (tty_out->terminal->reset_terminal_modes_hook) tty_out->terminal->reset_terminal_modes_hook (tty_out->terminal); /* Avoid possible loss of output when changing terminal modes. */ while (tcdrain (fileno (tty_out->output)) != 0 && errno == EINTR) continue; #ifndef DOS_NT # ifdef F_SETOWN if (interrupt_input) { reset_sigio (fileno (tty_out->input)); fcntl (fileno (tty_out->input), F_SETOWN, old_fcntl_owner[fileno (tty_out->input)]); } # endif /* F_SETOWN */ fcntl (fileno (tty_out->input), F_SETFL, fcntl (fileno (tty_out->input), F_GETFL, 0) & ~O_NONBLOCK); #endif if (tty_out->old_tty) while (emacs_set_tty (fileno (tty_out->input), tty_out->old_tty, 0) < 0 && errno == EINTR) ; #ifdef MSDOS /* Demacs 1.1.2 91/10/20 Manabu Higashida */ dos_ttcooked (); #endif widen_foreground_group (fileno (tty_out->input)); } #ifdef HAVE_PTYS /* Set up the proper status flags for use of a pty. */ void setup_pty (int fd) { /* I'm told that TOICREMOTE does not mean control chars "can't be sent" but rather that they don't have input-editing or signaling effects. That should be good, because we have other ways to do those things in Emacs. However, telnet mode seems not to work on 4.2. So TIOCREMOTE is turned off now. */ /* Under hp-ux, if TIOCREMOTE is turned on, some calls will hang. In particular, the "timeout" feature (which causes a read to return if there is no data available) does this. Also it is known that telnet mode will hang in such a way that Emacs must be stopped (perhaps this is the same problem). If TIOCREMOTE is turned off, then there is a bug in hp-ux which sometimes loses data. Apparently the code which blocks the master process when the internal buffer fills up does not work. Other than this, though, everything else seems to work fine. Since the latter lossage is more benign, we may as well lose that way. -- cph */ #ifdef FIONBIO #if defined (UNIX98_PTYS) { int on = 1; ioctl (fd, FIONBIO, &on); } #endif #endif } #endif /* HAVE_PTYS */ void init_system_name (void) { if (!build_details) { /* Set system-name to nil so that the build is deterministic. */ Vsystem_name = Qnil; return; } char *hostname_alloc = NULL; char *hostname; #ifndef HAVE_GETHOSTNAME struct utsname uts; uname (&uts); hostname = uts.nodename; #else /* HAVE_GETHOSTNAME */ char hostname_buf[256]; ptrdiff_t hostname_size = sizeof hostname_buf; hostname = hostname_buf; /* Try to get the host name; if the buffer is too short, try again. Apparently, the only indication gethostname gives of whether the buffer was large enough is the presence or absence of a '\0' in the string. Eech. */ for (;;) { gethostname (hostname, hostname_size - 1); hostname[hostname_size - 1] = '\0'; /* Was the buffer large enough for the '\0'? */ if (strlen (hostname) < hostname_size - 1) break; hostname = hostname_alloc = xpalloc (hostname_alloc, &hostname_size, 1, min (PTRDIFF_MAX, SIZE_MAX), 1); } #endif /* HAVE_GETHOSTNAME */ char *p; for (p = hostname; *p; p++) if (*p == ' ' || *p == '\t') *p = '-'; if (! (STRINGP (Vsystem_name) && SBYTES (Vsystem_name) == p - hostname && strcmp (SSDATA (Vsystem_name), hostname) == 0)) Vsystem_name = build_string (hostname); xfree (hostname_alloc); } sigset_t empty_mask; static struct sigaction process_fatal_action; static int emacs_sigaction_flags (void) { #ifdef SA_RESTART /* SA_RESTART causes interruptible functions with timeouts (e.g., 'select') to reset their timeout on some platforms (e.g., HP-UX 11), which is not what we want. Also, when Emacs is interactive, we don't want SA_RESTART because we need to poll for pending input so we need long-running syscalls to be interrupted after a signal that sets pending_signals. Non-interactive keyboard input goes through stdio, where we always want restartable system calls. */ if (noninteractive) return SA_RESTART; #endif return 0; } /* Store into *ACTION a signal action suitable for Emacs, with handler HANDLER. */ void emacs_sigaction_init (struct sigaction *action, signal_handler_t handler) { sigemptyset (&action->sa_mask); /* When handling a signal, block nonfatal system signals that are caught by Emacs. This makes race conditions less likely. */ sigaddset (&action->sa_mask, SIGALRM); #ifdef SIGCHLD sigaddset (&action->sa_mask, SIGCHLD); #endif #ifdef SIGDANGER sigaddset (&action->sa_mask, SIGDANGER); #endif #ifdef PROFILER_CPU_SUPPORT sigaddset (&action->sa_mask, SIGPROF); #endif #ifdef SIGWINCH sigaddset (&action->sa_mask, SIGWINCH); #endif if (! noninteractive) { sigaddset (&action->sa_mask, SIGINT); sigaddset (&action->sa_mask, SIGQUIT); #ifdef USABLE_SIGIO sigaddset (&action->sa_mask, SIGIO); #elif defined (USABLE_SIGPOLL) sigaddset (&action->sa_mask, SIGPOLL); #endif } action->sa_handler = handler; action->sa_flags = emacs_sigaction_flags (); } #ifdef FORWARD_SIGNAL_TO_MAIN_THREAD static pthread_t main_thread_id; #endif /* SIG has arrived at the current process. Deliver it to the main thread, which should handle it with HANDLER. (Delivering the signal to some other thread might not work if the other thread is about to exit.) If we are on the main thread, handle the signal SIG with HANDLER. Otherwise, redirect the signal to the main thread, blocking it from this thread. POSIX says any thread can receive a signal that is associated with a process, process group, or asynchronous event. On GNU/Linux the main thread typically gets a process signal unless it's blocked, but other systems (FreeBSD at least) can deliver the signal to other threads. */ void deliver_process_signal (int sig, signal_handler_t handler) { /* Preserve errno, to avoid race conditions with signal handlers that might change errno. Races can occur even in single-threaded hosts. */ int old_errno = errno; bool on_main_thread = true; #ifdef FORWARD_SIGNAL_TO_MAIN_THREAD if (! pthread_equal (pthread_self (), main_thread_id)) { sigset_t blocked; sigemptyset (&blocked); sigaddset (&blocked, sig); pthread_sigmask (SIG_BLOCK, &blocked, 0); pthread_kill (main_thread_id, sig); on_main_thread = false; } #endif if (on_main_thread) handler (sig); errno = old_errno; } /* Static location to save a fatal backtrace in a thread. FIXME: If two subsidiary threads fail simultaneously, the resulting backtrace may be garbage. */ enum { BACKTRACE_LIMIT_MAX = 500 }; static void *thread_backtrace_buffer[BACKTRACE_LIMIT_MAX + 1]; static int thread_backtrace_npointers; /* SIG has arrived at the current thread. If we are on the main thread, handle the signal SIG with HANDLER. Otherwise, this is a fatal error in the handling thread. */ static void deliver_thread_signal (int sig, signal_handler_t handler) { int old_errno = errno; #ifdef FORWARD_SIGNAL_TO_MAIN_THREAD if (! pthread_equal (pthread_self (), main_thread_id)) { thread_backtrace_npointers = backtrace (thread_backtrace_buffer, BACKTRACE_LIMIT_MAX); sigaction (sig, &process_fatal_action, 0); pthread_kill (main_thread_id, sig); /* Avoid further damage while the main thread is exiting. */ while (1) sigsuspend (&empty_mask); } #endif handler (sig); errno = old_errno; } /* Handle bus errors, invalid instruction, etc. */ static void handle_fatal_signal (int sig) { terminate_due_to_signal (sig, 40); } static void deliver_fatal_signal (int sig) { deliver_process_signal (sig, handle_fatal_signal); } static void deliver_fatal_thread_signal (int sig) { deliver_thread_signal (sig, handle_fatal_signal); } static AVOID handle_arith_signal (int sig) { pthread_sigmask (SIG_SETMASK, &empty_mask, 0); xsignal0 (Qarith_error); } #if defined HAVE_STACK_OVERFLOW_HANDLING && !defined WINDOWSNT /* Alternate stack used by SIGSEGV handler below. */ /* Storage for the alternate signal stack. 64 KiB is not too large for Emacs, and is large enough for all known platforms. Smaller sizes may run into trouble. For example, libsigsegv 2.6 through 2.8 have a bug where some architectures use more than the Linux default of an 8 KiB alternate stack when deciding if a fault was caused by stack overflow. */ static max_align_t sigsegv_stack[(64 * 1024 + sizeof (max_align_t) - 1) / sizeof (max_align_t)]; /* Return true if SIGINFO indicates a stack overflow. */ static bool stack_overflow (siginfo_t *siginfo) { if (!attempt_stack_overflow_recovery) return false; /* In theory, a more-accurate heuristic can be obtained by using GNU/Linux pthread_getattr_np along with POSIX pthread_attr_getstack and pthread_attr_getguardsize to find the location and size of the guard area. In practice, though, these functions are so hard to use reliably that they're not worth bothering with. E.g., see: https://sourceware.org/bugzilla/show_bug.cgi?id=16291 Other operating systems also have problems, e.g., Solaris's stack_violation function is tailor-made for this problem, but it doesn't work on Solaris 11.2 x86-64 with a 32-bit executable. GNU libsigsegv is overkill for Emacs; otherwise it might be a candidate here. */ if (!siginfo) return false; /* The faulting address. */ char *addr = siginfo->si_addr; if (!addr) return false; /* The known top and bottom of the stack. The actual stack may extend a bit beyond these boundaries. */ char const *bot = stack_bottom; char const *top = current_thread->stack_top; /* Log base 2 of the stack heuristic ratio. This ratio is the size of the known stack divided by the size of the guard area past the end of the stack top. The heuristic is that a bad address is considered to be a stack overflow if it occurs within stacksize>>LG_STACK_HEURISTIC bytes above the top of the known stack. This heuristic is not exactly correct but it's good enough in practice. */ enum { LG_STACK_HEURISTIC = 8 }; if (bot < top) return 0 <= addr - top && addr - top < (top - bot) >> LG_STACK_HEURISTIC; else return 0 <= top - addr && top - addr < (bot - top) >> LG_STACK_HEURISTIC; } /* Attempt to recover from SIGSEGV caused by C stack overflow. */ static void handle_sigsegv (int sig, siginfo_t *siginfo, void *arg) { /* Hard GC error may lead to stack overflow caused by too nested calls to mark_object. No way to survive. */ bool fatal = gc_in_progress; #ifdef FORWARD_SIGNAL_TO_MAIN_THREAD if (!fatal && !pthread_equal (pthread_self (), main_thread_id)) fatal = true; #endif if (!fatal && stack_overflow (siginfo)) siglongjmp (return_to_command_loop, 1); /* Otherwise we can't do anything with this. */ deliver_fatal_thread_signal (sig); } /* Return true if we have successfully set up SIGSEGV handler on alternate stack. Otherwise we just treat SIGSEGV among the rest of fatal signals. */ static bool init_sigsegv (void) { struct sigaction sa; stack_t ss; ss.ss_sp = sigsegv_stack; ss.ss_size = sizeof (sigsegv_stack); ss.ss_flags = 0; if (sigaltstack (&ss, NULL) < 0) return 0; sigfillset (&sa.sa_mask); sa.sa_sigaction = handle_sigsegv; sa.sa_flags = SA_SIGINFO | SA_ONSTACK | emacs_sigaction_flags (); if (sigaction (SIGSEGV, &sa, NULL) < 0) return 0; return 1; } #else /* not HAVE_STACK_OVERFLOW_HANDLING or WINDOWSNT */ static bool init_sigsegv (void) { return 0; } #endif /* HAVE_STACK_OVERFLOW_HANDLING && !WINDOWSNT */ static void deliver_arith_signal (int sig) { deliver_thread_signal (sig, handle_arith_signal); } #ifdef SIGDANGER /* Handler for SIGDANGER. */ static void handle_danger_signal (int sig) { malloc_warning ("Operating system warns that virtual memory is running low.\n"); /* It might be unsafe to call do_auto_save now. */ force_auto_save_soon (); } static void deliver_danger_signal (int sig) { deliver_process_signal (sig, handle_danger_signal); } #endif /* Treat SIG as a terminating signal, unless it is already ignored and we are in --batch mode. Among other things, this makes nohup work. */ static void maybe_fatal_sig (int sig) { bool catch_sig = !noninteractive; if (!catch_sig) { struct sigaction old_action; sigaction (sig, 0, &old_action); catch_sig = old_action.sa_handler != SIG_IGN; } if (catch_sig) sigaction (sig, &process_fatal_action, 0); } void init_signals (void) { struct sigaction thread_fatal_action; struct sigaction action; sigemptyset (&empty_mask); #ifdef FORWARD_SIGNAL_TO_MAIN_THREAD main_thread_id = pthread_self (); #endif /* Don't alter signal handlers if dumping. On some machines, changing signal handlers sets static data that would make signals fail to work right when the dumped Emacs is run. */ if (will_dump_p ()) return; sigfillset (&process_fatal_action.sa_mask); process_fatal_action.sa_handler = deliver_fatal_signal; process_fatal_action.sa_flags = emacs_sigaction_flags (); sigfillset (&thread_fatal_action.sa_mask); thread_fatal_action.sa_handler = deliver_fatal_thread_signal; thread_fatal_action.sa_flags = process_fatal_action.sa_flags; /* SIGINT may need special treatment on MS-Windows. See https://lists.gnu.org/r/emacs-devel/2010-09/msg01062.html Please update the doc of kill-emacs, kill-emacs-hook, and NEWS if you change this. */ maybe_fatal_sig (SIGHUP); maybe_fatal_sig (SIGINT); maybe_fatal_sig (SIGTERM); /* Emacs checks for write errors, so it can safely ignore SIGPIPE. However, in batch mode leave SIGPIPE alone, as that causes Emacs to behave more like typical batch applications do. */ if (! noninteractive) signal (SIGPIPE, SIG_IGN); sigaction (SIGQUIT, &process_fatal_action, 0); sigaction (SIGILL, &thread_fatal_action, 0); sigaction (SIGTRAP, &thread_fatal_action, 0); /* Typically SIGFPE is thread-specific and is fatal, like SIGILL. But on a non-IEEE host SIGFPE can come from a trap in the Lisp interpreter's floating point operations, so treat SIGFPE as an arith-error if it arises in the main thread. */ if (IEEE_FLOATING_POINT) sigaction (SIGFPE, &thread_fatal_action, 0); else { emacs_sigaction_init (&action, deliver_arith_signal); sigaction (SIGFPE, &action, 0); } #ifdef SIGUSR1 add_user_signal (SIGUSR1, "sigusr1"); #endif #ifdef SIGUSR2 add_user_signal (SIGUSR2, "sigusr2"); #endif sigaction (SIGABRT, &thread_fatal_action, 0); #ifdef SIGPRE sigaction (SIGPRE, &thread_fatal_action, 0); #endif #ifdef SIGORE sigaction (SIGORE, &thread_fatal_action, 0); #endif #ifdef SIGUME sigaction (SIGUME, &thread_fatal_action, 0); #endif #ifdef SIGDLK sigaction (SIGDLK, &process_fatal_action, 0); #endif #ifdef SIGCPULIM sigaction (SIGCPULIM, &process_fatal_action, 0); #endif #ifdef SIGIOT sigaction (SIGIOT, &thread_fatal_action, 0); #endif #ifdef SIGEMT sigaction (SIGEMT, &thread_fatal_action, 0); #endif #ifdef SIGBUS sigaction (SIGBUS, &thread_fatal_action, 0); #endif if (!init_sigsegv ()) sigaction (SIGSEGV, &thread_fatal_action, 0); #ifdef SIGSYS sigaction (SIGSYS, &thread_fatal_action, 0); #endif sigaction (SIGTERM, &process_fatal_action, 0); #ifdef SIGPROF signal (SIGPROF, SIG_IGN); #endif #ifdef SIGVTALRM sigaction (SIGVTALRM, &process_fatal_action, 0); #endif #ifdef SIGXCPU sigaction (SIGXCPU, &process_fatal_action, 0); #endif #ifdef SIGXFSZ sigaction (SIGXFSZ, &process_fatal_action, 0); #endif #ifdef SIGDANGER /* This just means available memory is getting low. */ emacs_sigaction_init (&action, deliver_danger_signal); sigaction (SIGDANGER, &action, 0); #endif /* AIX-specific signals. */ #ifdef SIGGRANT sigaction (SIGGRANT, &process_fatal_action, 0); #endif #ifdef SIGMIGRATE sigaction (SIGMIGRATE, &process_fatal_action, 0); #endif #ifdef SIGMSG sigaction (SIGMSG, &process_fatal_action, 0); #endif #ifdef SIGRETRACT sigaction (SIGRETRACT, &process_fatal_action, 0); #endif #ifdef SIGSAK sigaction (SIGSAK, &process_fatal_action, 0); #endif #ifdef SIGSOUND sigaction (SIGSOUND, &process_fatal_action, 0); #endif #ifdef SIGTALRM sigaction (SIGTALRM, &thread_fatal_action, 0); #endif } #ifndef HAVE_RANDOM #ifdef random #define HAVE_RANDOM #endif #endif /* Figure out how many bits the system's random number generator uses. `random' and `lrand48' are assumed to return 31 usable bits. BSD `rand' returns a 31 bit value but the low order bits are unusable; so we'll shift it and treat it like the 15-bit USG `rand'. */ #ifndef RAND_BITS # ifdef HAVE_RANDOM # define RAND_BITS 31 # else /* !HAVE_RANDOM */ # ifdef HAVE_LRAND48 # define RAND_BITS 31 # define random lrand48 # else /* !HAVE_LRAND48 */ # define RAND_BITS 15 # if RAND_MAX == 32767 # define random rand # else /* RAND_MAX != 32767 */ # if RAND_MAX == 2147483647 # define random() (rand () >> 16) # else /* RAND_MAX != 2147483647 */ # ifdef USG # define random rand # else # define random() (rand () >> 16) # endif /* !USG */ # endif /* RAND_MAX != 2147483647 */ # endif /* RAND_MAX != 32767 */ # endif /* !HAVE_LRAND48 */ # endif /* !HAVE_RANDOM */ #endif /* !RAND_BITS */ #ifdef HAVE_RANDOM typedef unsigned int random_seed; static void set_random_seed (random_seed arg) { srandom (arg); } #elif defined HAVE_LRAND48 typedef long int random_seed; static void set_random_seed (random_seed arg) { srand48 (arg); } #else typedef unsigned int random_seed; static void set_random_seed (random_seed arg) { srand (arg); } #endif void seed_random (void *seed, ptrdiff_t seed_size) { random_seed arg = 0; unsigned char *argp = (unsigned char *) &arg; unsigned char *seedp = seed; for (ptrdiff_t i = 0; i < seed_size; i++) argp[i % sizeof arg] ^= seedp[i]; set_random_seed (arg); } void init_random (void) { random_seed v; bool success = false; /* First, try seeding the PRNG from the operating system's entropy source. This approach is both fast and secure. */ #ifdef WINDOWSNT /* FIXME: Perhaps getrandom can be used here too? */ success = w32_init_random (&v, sizeof v) == 0; #else verify (sizeof v <= 256); success = getrandom (&v, sizeof v, 0) == sizeof v; #endif /* If that didn't work, just use the current time value and PID. It's at least better than XKCD 221. */ if (!success) { struct timespec t = current_timespec (); v = getpid () ^ t.tv_sec ^ t.tv_nsec; } set_random_seed (v); } /* * Return a nonnegative random integer out of whatever we've got. * It contains enough bits to make a random (signed) Emacs fixnum. * This suffices even for a 64-bit architecture with a 15-bit rand. */ EMACS_INT get_random (void) { EMACS_UINT val = 0; int i; for (i = 0; i < (FIXNUM_BITS + RAND_BITS - 1) / RAND_BITS; i++) val = (random () ^ (val << RAND_BITS) ^ (val >> (EMACS_INT_WIDTH - RAND_BITS))); val ^= val >> (EMACS_INT_WIDTH - FIXNUM_BITS); return val & INTMASK; } #ifndef HAVE_SNPRINTF /* Approximate snprintf as best we can on ancient hosts that lack it. */ int snprintf (char *buf, size_t bufsize, char const *format, ...) { ptrdiff_t size = min (bufsize, PTRDIFF_MAX); ptrdiff_t nbytes = size - 1; va_list ap; if (size) { va_start (ap, format); nbytes = doprnt (buf, size, format, 0, ap); va_end (ap); } if (nbytes == size - 1) { /* Calculate the length of the string that would have been created had the buffer been large enough. */ char stackbuf[4000]; char *b = stackbuf; ptrdiff_t bsize = sizeof stackbuf; va_start (ap, format); nbytes = evxprintf (&b, &bsize, stackbuf, -1, format, ap); va_end (ap); if (b != stackbuf) xfree (b); } if (INT_MAX < nbytes) { #ifdef EOVERFLOW errno = EOVERFLOW; #else errno = EDOM; #endif return -1; } return nbytes; } #endif /* If a backtrace is available, output the top lines of it to stderr. Do not output more than BACKTRACE_LIMIT or BACKTRACE_LIMIT_MAX lines. This function may be called from a signal handler, so it should not invoke async-unsafe functions like malloc. If BACKTRACE_LIMIT is -1, initialize tables that 'backtrace' uses but do not output anything. This avoids some problems that can otherwise occur if the malloc arena is corrupted before 'backtrace' is called, since 'backtrace' may call malloc if the tables are not initialized. If the static variable THREAD_BACKTRACE_NPOINTERS is nonzero, a fatal error has occurred in some other thread; generate a thread backtrace instead, ignoring BACKTRACE_LIMIT. */ void emacs_backtrace (int backtrace_limit) { void *main_backtrace_buffer[BACKTRACE_LIMIT_MAX + 1]; int bounded_limit = min (backtrace_limit, BACKTRACE_LIMIT_MAX); void *buffer; int npointers; if (thread_backtrace_npointers) { buffer = thread_backtrace_buffer; npointers = thread_backtrace_npointers; } else { buffer = main_backtrace_buffer; /* Work around 'backtrace' bug; see Bug#19959 and glibc bug#18084. */ if (bounded_limit < 0) { backtrace (buffer, 1); return; } npointers = backtrace (buffer, bounded_limit + 1); } if (npointers) { emacs_write (STDERR_FILENO, "Backtrace:\n", 11); backtrace_symbols_fd (buffer, npointers, STDERR_FILENO); if (bounded_limit < npointers) emacs_write (STDERR_FILENO, "...\n", 4); } } #ifndef HAVE_NTGUI void emacs_abort (void) { terminate_due_to_signal (SIGABRT, 40); } #endif /* Assuming the directory DIRFD, store information about FILENAME into *ST, using FLAGS to control how the status is obtained. Do not fail merely because fetching info was interrupted by a signal. Allow the user to quit. The type of ST is void * instead of struct stat * because the latter type would be problematic in lisp.h. Some platforms may play tricks like "#define stat stat64" in , and lisp.h does not include . */ int emacs_fstatat (int dirfd, char const *filename, void *st, int flags) { int r; while ((r = fstatat (dirfd, filename, st, flags)) != 0 && errno == EINTR) maybe_quit (); return r; } /* Assuming the directory DIRFD, open FILE for Emacs use, using open flags OFLAGS and mode MODE. Use binary I/O on systems that care about text vs binary I/O. Arrange for subprograms to not inherit the file descriptor. Prefer a method that is multithread-safe, if available. Do not fail merely because the open was interrupted by a signal. Allow the user to quit. */ int emacs_openat (int dirfd, char const *file, int oflags, int mode) { int fd; if (! (oflags & O_TEXT)) oflags |= O_BINARY; oflags |= O_CLOEXEC; while ((fd = openat (dirfd, file, oflags, mode)) < 0 && errno == EINTR) maybe_quit (); return fd; } int emacs_open (char const *file, int oflags, int mode) { return emacs_openat (AT_FDCWD, file, oflags, mode); } /* Same as above, but doesn't allow the user to quit. */ static int emacs_openat_noquit (int dirfd, const char *file, int oflags, int mode) { int fd; if (! (oflags & O_TEXT)) oflags |= O_BINARY; oflags |= O_CLOEXEC; do fd = openat (dirfd, file, oflags, mode); while (fd < 0 && errno == EINTR); return fd; } int emacs_open_noquit (char const *file, int oflags, int mode) { return emacs_openat_noquit (AT_FDCWD, file, oflags, mode); } /* Open FILE as a stream for Emacs use, with mode MODE. Act like emacs_open with respect to threads, signals, and quits. */ FILE * emacs_fopen (char const *file, char const *mode) { int fd, omode, oflags; int bflag = 0; char const *m = mode; switch (*m++) { case 'r': omode = O_RDONLY; oflags = 0; break; case 'w': omode = O_WRONLY; oflags = O_CREAT | O_TRUNC; break; case 'a': omode = O_WRONLY; oflags = O_CREAT | O_APPEND; break; default: emacs_abort (); } while (*m) switch (*m++) { case '+': omode = O_RDWR; break; case 't': bflag = O_TEXT; break; default: /* Ignore. */ break; } fd = emacs_open (file, omode | oflags | bflag, 0666); return fd < 0 ? 0 : fdopen (fd, mode); } /* Create a pipe for Emacs use. */ int emacs_pipe (int fd[2]) { #ifdef MSDOS return pipe (fd); #else /* !MSDOS */ return pipe2 (fd, O_BINARY | O_CLOEXEC); #endif /* !MSDOS */ } /* Approximate posix_close and POSIX_CLOSE_RESTART well enough for Emacs. For the background behind this mess, please see Austin Group defect 529 . */ #ifndef POSIX_CLOSE_RESTART # define POSIX_CLOSE_RESTART 1 static int posix_close (int fd, int flag) { /* Only the POSIX_CLOSE_RESTART case is emulated. */ eassert (flag == POSIX_CLOSE_RESTART); /* Things are tricky if close (fd) returns -1 with errno == EINTR on a system that does not define POSIX_CLOSE_RESTART. In this case, in some systems (e.g., GNU/Linux, AIX) FD is closed, and retrying the close could inadvertently close a file descriptor allocated by some other thread. In other systems (e.g., HP/UX) FD is not closed. And in still other systems (e.g., macOS, Solaris), maybe FD is closed, maybe not, and in a multithreaded program there can be no way to tell. So, in this case, pretend that the close succeeded. This works well on systems like GNU/Linux that close FD. Although it may leak a file descriptor on other systems, the leak is unlikely and it's better to leak than to close a random victim. */ return close (fd) == 0 || errno == EINTR ? 0 : -1; } #endif /* Close FD, retrying if interrupted. If successful, return 0; otherwise, return -1 and set errno to a non-EINTR value. Consider an EINPROGRESS error to be successful, as that's merely a signal arriving. FD is always closed when this function returns, even when it returns -1. Do not call this function if FD is nonnegative and might already be closed, as that might close an innocent victim opened by some other thread. */ int emacs_close (int fd) { while (1) { int r = posix_close (fd, POSIX_CLOSE_RESTART); if (r == 0) return r; if (!POSIX_CLOSE_RESTART || errno != EINTR) { eassert (errno != EBADF || fd < 0); return errno == EINPROGRESS ? 0 : r; } } } /* Maximum number of bytes to read or write in a single system call. This works around a serious bug in Linux kernels before 2.6.16; see . It's likely to work around similar bugs in other operating systems, so do it on all platforms. Round INT_MAX down to a page size, with the conservative assumption that page sizes are at most 2**18 bytes (any kernel with a page size larger than that shouldn't have the bug). */ #ifndef MAX_RW_COUNT #define MAX_RW_COUNT (INT_MAX >> 18 << 18) #endif /* Verify that MAX_RW_COUNT fits in the relevant standard types. */ #ifndef SSIZE_MAX # define SSIZE_MAX TYPE_MAXIMUM (ssize_t) #endif verify (MAX_RW_COUNT <= PTRDIFF_MAX); verify (MAX_RW_COUNT <= SIZE_MAX); verify (MAX_RW_COUNT <= SSIZE_MAX); #ifdef WINDOWSNT /* Verify that Emacs read requests cannot cause trouble, even in 64-bit builds. The last argument of 'read' is 'unsigned int', and the return value's type (see 'sys_read') is 'int'. */ verify (MAX_RW_COUNT <= INT_MAX); verify (MAX_RW_COUNT <= UINT_MAX); #endif /* Read from FD to a buffer BUF with size NBYTE. If interrupted, process any quits and pending signals immediately if INTERRUPTIBLE, and then retry the read unless quitting. Return the number of bytes read, which might be less than NBYTE. On error, set errno to a value other than EINTR, and return -1. */ static ptrdiff_t emacs_intr_read (int fd, void *buf, ptrdiff_t nbyte, bool interruptible) { /* No caller should ever pass a too-large size to emacs_read. */ eassert (nbyte <= MAX_RW_COUNT); ssize_t result; do { if (interruptible) maybe_quit (); result = read (fd, buf, nbyte); } while (result < 0 && errno == EINTR); return result; } /* Read from FD to a buffer BUF with size NBYTE. If interrupted, retry the read. Return the number of bytes read, which might be less than NBYTE. On error, set errno to a value other than EINTR, and return -1. */ ptrdiff_t emacs_read (int fd, void *buf, ptrdiff_t nbyte) { return emacs_intr_read (fd, buf, nbyte, false); } /* Like emacs_read, but also process quits and pending signals. */ ptrdiff_t emacs_read_quit (int fd, void *buf, ptrdiff_t nbyte) { return emacs_intr_read (fd, buf, nbyte, true); } /* Write to FILEDES from a buffer BUF with size NBYTE, retrying if interrupted or if a partial write occurs. Process any quits immediately if INTERRUPTIBLE is positive, and process any pending signals immediately if INTERRUPTIBLE is nonzero. Return the number of bytes written; if this is less than NBYTE, set errno to a value other than EINTR. */ static ptrdiff_t emacs_full_write (int fd, char const *buf, ptrdiff_t nbyte, int interruptible) { ptrdiff_t bytes_written = 0; while (nbyte > 0) { ssize_t n = write (fd, buf, min (nbyte, MAX_RW_COUNT)); if (n < 0) { if (errno != EINTR) break; if (interruptible) { if (0 < interruptible) maybe_quit (); if (pending_signals) process_pending_signals (); } } else { buf += n; nbyte -= n; bytes_written += n; } } return bytes_written; } /* Write to FD from a buffer BUF with size NBYTE, retrying if interrupted or if a partial write occurs. Do not process quits or pending signals. Return the number of bytes written, setting errno if this is less than NBYTE. */ ptrdiff_t emacs_write (int fd, void const *buf, ptrdiff_t nbyte) { return emacs_full_write (fd, buf, nbyte, 0); } /* Like emacs_write, but also process pending signals. */ ptrdiff_t emacs_write_sig (int fd, void const *buf, ptrdiff_t nbyte) { return emacs_full_write (fd, buf, nbyte, -1); } /* Like emacs_write, but also process quits and pending signals. */ ptrdiff_t emacs_write_quit (int fd, void const *buf, ptrdiff_t nbyte) { return emacs_full_write (fd, buf, nbyte, 1); } /* Write a diagnostic to standard error that contains MESSAGE and a string derived from errno. Preserve errno. Do not buffer stderr. Do not process quits or pending signals if interrupted. */ void emacs_perror (char const *message) { int err = errno; char const *error_string = emacs_strerror (err); char const *command = (initial_argv && initial_argv[0] ? initial_argv[0] : "emacs"); /* Write it out all at once, if it's short; this is less likely to be interleaved with other output. */ char buf[min (PIPE_BUF, MAX_ALLOCA)]; int nbytes = snprintf (buf, sizeof buf, "%s: %s: %s\n", command, message, error_string); if (0 <= nbytes && nbytes < sizeof buf) emacs_write (STDERR_FILENO, buf, nbytes); else { emacs_write (STDERR_FILENO, command, strlen (command)); emacs_write (STDERR_FILENO, ": ", 2); emacs_write (STDERR_FILENO, message, strlen (message)); emacs_write (STDERR_FILENO, ": ", 2); emacs_write (STDERR_FILENO, error_string, strlen (error_string)); emacs_write (STDERR_FILENO, "\n", 1); } errno = err; } /* Rename directory SRCFD's entry SRC to directory DSTFD's entry DST. This is like renameat except that it fails if DST already exists, or if this operation is not supported atomically. Return 0 if successful, -1 (setting errno) otherwise. */ int renameat_noreplace (int srcfd, char const *src, int dstfd, char const *dst) { #if defined SYS_renameat2 && defined RENAME_NOREPLACE return syscall (SYS_renameat2, srcfd, src, dstfd, dst, RENAME_NOREPLACE); #elif defined CYGWIN && defined RENAME_NOREPLACE return renameat2 (srcfd, src, dstfd, dst, RENAME_NOREPLACE); #elif defined RENAME_EXCL return renameatx_np (srcfd, src, dstfd, dst, RENAME_EXCL); #else # ifdef WINDOWSNT if (srcfd == AT_FDCWD && dstfd == AT_FDCWD) return sys_rename_replace (src, dst, 0); # endif errno = ENOSYS; return -1; #endif } /* Like strsignal, except async-signal-safe, and this function returns a string in the C locale rather than the current locale. */ char const * safe_strsignal (int code) { char const *signame = sigdescr_np (code); if (! signame) signame = "Unknown signal"; return signame; } /* Output to stderr. */ /* Return the error output stream. */ static FILE * errstream (void) { FILE *err = buferr; if (!err) return stderr; fflush_unlocked (stderr); return err; } /* These functions are like fputc, vfprintf, and fwrite, except that they output to stderr and buffer better on platforms that support line buffering. This avoids interleaving output when Emacs and other processes write to stderr simultaneously, so long as the lines are short enough. When a single diagnostic is emitted via a sequence of calls of one or more of these functions, the caller should arrange for the last called function to output a newline at the end. */ void errputc (int c) { fputc_unlocked (c, errstream ()); #ifdef WINDOWSNT /* Flush stderr after outputting a newline since stderr is fully buffered when redirected to a pipe, contrary to POSIX. */ if (c == '\n') fflush_unlocked (stderr); #endif } void errwrite (void const *buf, ptrdiff_t nbuf) { fwrite_unlocked (buf, 1, nbuf, errstream ()); } /* Close standard output and standard error, reporting any write errors as best we can. This is intended for use with atexit. */ void close_output_streams (void) { if (close_stream (stdout) != 0) { emacs_perror ("Write error to standard output"); _exit (EXIT_FAILURE); } /* Do not close stderr if addresses are being sanitized, as the sanitizer might report to stderr after this function is invoked. */ bool err = buferr && (fflush (buferr) != 0 || ferror (buferr)); if (err | (ADDRESS_SANITIZER ? fflush (stderr) != 0 || ferror (stderr) : close_stream (stderr) != 0)) _exit (EXIT_FAILURE); } #ifndef DOS_NT /* For make-serial-process */ int serial_open (Lisp_Object port) { int fd = emacs_open (SSDATA (port), O_RDWR | O_NOCTTY | O_NONBLOCK, 0); if (fd < 0) report_file_error ("Opening serial port", port); #ifdef TIOCEXCL ioctl (fd, TIOCEXCL, (char *) 0); #endif return fd; } #if !defined (HAVE_CFMAKERAW) /* Workaround for targets which are missing cfmakeraw. */ /* Pasted from man page. */ static void cfmakeraw (struct termios *termios_p) { termios_p->c_iflag &= ~(IGNBRK|BRKINT|PARMRK|ISTRIP|INLCR|IGNCR|ICRNL|IXON); termios_p->c_oflag &= ~OPOST; termios_p->c_lflag &= ~(ECHO|ECHONL|ICANON|ISIG|IEXTEN); termios_p->c_cflag &= ~(CSIZE|PARENB); termios_p->c_cflag |= CS8; } #endif /* !defined (HAVE_CFMAKERAW */ #if !defined (HAVE_CFSETSPEED) /* Workaround for targets which are missing cfsetspeed. */ static int cfsetspeed (struct termios *termios_p, speed_t vitesse) { return (cfsetispeed (termios_p, vitesse) + cfsetospeed (termios_p, vitesse)); } #endif /* The following is based on the glibc implementation of cfsetspeed. */ struct speed_struct { speed_t value; speed_t internal; }; static const struct speed_struct speeds[] = { #ifdef B0 { 0, B0 }, #endif #ifdef B50 { 50, B50 }, #endif #ifdef B75 { 75, B75 }, #endif #ifdef B110 { 110, B110 }, #endif #ifdef B134 { 134, B134 }, #endif #ifdef B150 { 150, B150 }, #endif #ifndef HAVE_TINY_SPEED_T #ifdef B200 { 200, B200 }, #endif #ifdef B300 { 300, B300 }, #endif #ifdef B600 { 600, B600 }, #endif #ifdef B1200 { 1200, B1200 }, #endif #ifdef B1200 { 1200, B1200 }, #endif #ifdef B1800 { 1800, B1800 }, #endif #ifdef B2400 { 2400, B2400 }, #endif #ifdef B4800 { 4800, B4800 }, #endif #ifdef B9600 { 9600, B9600 }, #endif #ifdef B19200 { 19200, B19200 }, #endif #ifdef B38400 { 38400, B38400 }, #endif #ifdef B57600 { 57600, B57600 }, #endif #ifdef B76800 { 76800, B76800 }, #endif #ifdef B115200 { 115200, B115200 }, #endif #ifdef B153600 { 153600, B153600 }, #endif #ifdef B230400 { 230400, B230400 }, #endif #ifdef B307200 { 307200, B307200 }, #endif #ifdef B460800 { 460800, B460800 }, #endif #ifdef B500000 { 500000, B500000 }, #endif #ifdef B576000 { 576000, B576000 }, #endif #ifdef B921600 { 921600, B921600 }, #endif #ifdef B1000000 { 1000000, B1000000 }, #endif #ifdef B1152000 { 1152000, B1152000 }, #endif #ifdef B1500000 { 1500000, B1500000 }, #endif #ifdef B2000000 { 2000000, B2000000 }, #endif #ifdef B2500000 { 2500000, B2500000 }, #endif #ifdef B3000000 { 3000000, B3000000 }, #endif #ifdef B3500000 { 3500000, B3500000 }, #endif #ifdef B4000000 { 4000000, B4000000 }, #endif #endif /* HAVE_TINY_SPEED_T */ }; /* Convert a numerical speed (e.g., 9600) to a Bnnn constant (e.g., B9600); see bug#49524. */ static speed_t convert_speed (speed_t speed) { for (size_t i = 0; i < sizeof speeds / sizeof speeds[0]; i++) { if (speed == speeds[i].internal) return speed; else if (speed == speeds[i].value) return speeds[i].internal; } return speed; } /* For serial-process-configure */ void serial_configure (struct Lisp_Process *p, Lisp_Object contact) { Lisp_Object childp2 = Qnil; Lisp_Object tem = Qnil; struct termios attr; int err; char summary[4] = "???"; /* This usually becomes "8N1". */ childp2 = Fcopy_sequence (p->childp); /* Read port attributes and prepare default configuration. */ err = tcgetattr (p->outfd, &attr); if (err != 0) report_file_error ("Failed tcgetattr", Qnil); cfmakeraw (&attr); #if defined (CLOCAL) attr.c_cflag |= CLOCAL; #endif #if defined (CREAD) attr.c_cflag |= CREAD; #endif /* Configure speed. */ if (!NILP (Fplist_member (contact, QCspeed))) tem = Fplist_get (contact, QCspeed); else tem = Fplist_get (p->childp, QCspeed); CHECK_FIXNUM (tem); err = cfsetspeed (&attr, convert_speed (XFIXNUM (tem))); if (err != 0) report_file_error ("Failed cfsetspeed", tem); childp2 = Fplist_put (childp2, QCspeed, tem); /* Configure bytesize. */ if (!NILP (Fplist_member (contact, QCbytesize))) tem = Fplist_get (contact, QCbytesize); else tem = Fplist_get (p->childp, QCbytesize); if (NILP (tem)) tem = make_fixnum (8); CHECK_FIXNUM (tem); if (XFIXNUM (tem) != 7 && XFIXNUM (tem) != 8) error (":bytesize must be nil (8), 7, or 8"); summary[0] = XFIXNUM (tem) + '0'; #if defined (CSIZE) && defined (CS7) && defined (CS8) attr.c_cflag &= ~CSIZE; attr.c_cflag |= ((XFIXNUM (tem) == 7) ? CS7 : CS8); #else /* Don't error on bytesize 8, which should be set by cfmakeraw. */ if (XFIXNUM (tem) != 8) error ("Bytesize cannot be changed"); #endif childp2 = Fplist_put (childp2, QCbytesize, tem); /* Configure parity. */ if (!NILP (Fplist_member (contact, QCparity))) tem = Fplist_get (contact, QCparity); else tem = Fplist_get (p->childp, QCparity); if (!NILP (tem) && !EQ (tem, Qeven) && !EQ (tem, Qodd)) error (":parity must be nil (no parity), `even', or `odd'"); #if defined (PARENB) && defined (PARODD) && defined (IGNPAR) && defined (INPCK) attr.c_cflag &= ~(PARENB | PARODD); attr.c_iflag &= ~(IGNPAR | INPCK); if (NILP (tem)) { summary[1] = 'N'; } else if (EQ (tem, Qeven)) { summary[1] = 'E'; attr.c_cflag |= PARENB; attr.c_iflag |= (IGNPAR | INPCK); } else if (EQ (tem, Qodd)) { summary[1] = 'O'; attr.c_cflag |= (PARENB | PARODD); attr.c_iflag |= (IGNPAR | INPCK); } #else /* Don't error on no parity, which should be set by cfmakeraw. */ if (!NILP (tem)) error ("Parity cannot be configured"); #endif childp2 = Fplist_put (childp2, QCparity, tem); /* Configure stopbits. */ if (!NILP (Fplist_member (contact, QCstopbits))) tem = Fplist_get (contact, QCstopbits); else tem = Fplist_get (p->childp, QCstopbits); if (NILP (tem)) tem = make_fixnum (1); CHECK_FIXNUM (tem); if (XFIXNUM (tem) != 1 && XFIXNUM (tem) != 2) error (":stopbits must be nil (1 stopbit), 1, or 2"); summary[2] = XFIXNUM (tem) + '0'; #if defined (CSTOPB) attr.c_cflag &= ~CSTOPB; if (XFIXNUM (tem) == 2) attr.c_cflag |= CSTOPB; #else /* Don't error on 1 stopbit, which should be set by cfmakeraw. */ if (XFIXNUM (tem) != 1) error ("Stopbits cannot be configured"); #endif childp2 = Fplist_put (childp2, QCstopbits, tem); /* Configure flowcontrol. */ if (!NILP (Fplist_member (contact, QCflowcontrol))) tem = Fplist_get (contact, QCflowcontrol); else tem = Fplist_get (p->childp, QCflowcontrol); if (!NILP (tem) && !EQ (tem, Qhw) && !EQ (tem, Qsw)) error (":flowcontrol must be nil (no flowcontrol), `hw', or `sw'"); #if defined (CRTSCTS) attr.c_cflag &= ~CRTSCTS; #endif #if defined (CNEW_RTSCTS) attr.c_cflag &= ~CNEW_RTSCTS; #endif #if defined (IXON) && defined (IXOFF) attr.c_iflag &= ~(IXON | IXOFF); #endif if (NILP (tem)) { /* Already configured. */ } else if (EQ (tem, Qhw)) { #if defined (CRTSCTS) attr.c_cflag |= CRTSCTS; #elif defined (CNEW_RTSCTS) attr.c_cflag |= CNEW_RTSCTS; #else error ("Hardware flowcontrol (RTS/CTS) not supported"); #endif } else if (EQ (tem, Qsw)) { #if defined (IXON) && defined (IXOFF) attr.c_iflag |= (IXON | IXOFF); #else error ("Software flowcontrol (XON/XOFF) not supported"); #endif } childp2 = Fplist_put (childp2, QCflowcontrol, tem); /* Activate configuration. */ err = tcsetattr (p->outfd, TCSANOW, &attr); if (err != 0) report_file_error ("Failed tcsetattr", Qnil); childp2 = Fplist_put (childp2, QCsummary, build_string (summary)); pset_childp (p, childp2); } #endif /* not DOS_NT */ /* System depended enumeration of and access to system processes a-la ps(1). */ #ifdef HAVE_PROCFS /* Process enumeration and access via /proc. */ Lisp_Object list_system_processes (void) { Lisp_Object procdir, match, proclist, next; Lisp_Object tail; /* For every process on the system, there's a directory in the "/proc" pseudo-directory whose name is the numeric ID of that process. */ procdir = build_string ("/proc"); match = build_string ("[0-9]+"); proclist = directory_files_internal (procdir, Qnil, match, Qt, false, Qnil, Qnil); /* `proclist' gives process IDs as strings. Destructively convert each string into a number. */ for (tail = proclist; CONSP (tail); tail = next) { next = XCDR (tail); XSETCAR (tail, Fstring_to_number (XCAR (tail), Qnil)); } /* directory_files_internal returns the files in reverse order; undo that. */ proclist = Fnreverse (proclist); return proclist; } #elif defined DARWIN_OS || defined __FreeBSD__ || defined __OpenBSD__ Lisp_Object list_system_processes (void) { #ifdef DARWIN_OS int mib[] = {CTL_KERN, KERN_PROC, KERN_PROC_ALL}; #elif defined __OpenBSD__ int mib[] = {CTL_KERN, KERN_PROC, KERN_PROC_ALL, 0, sizeof (struct kinfo_proc), 4096}; #else int mib[] = {CTL_KERN, KERN_PROC, KERN_PROC_PROC}; #endif size_t len; size_t mibsize = sizeof mib / sizeof mib[0]; struct kinfo_proc *procs; size_t i; Lisp_Object proclist = Qnil; if (sysctl (mib, mibsize, NULL, &len, NULL, 0) != 0 || len == 0) return proclist; procs = xmalloc (len); if (sysctl (mib, mibsize, procs, &len, NULL, 0) != 0 || len == 0) { xfree (procs); return proclist; } len /= sizeof procs[0]; for (i = 0; i < len; i++) { #ifdef DARWIN_OS proclist = Fcons (INT_TO_INTEGER (procs[i].kp_proc.p_pid), proclist); #elif defined __OpenBSD__ proclist = Fcons (INT_TO_INTEGER (procs[i].p_pid), proclist); #else proclist = Fcons (INT_TO_INTEGER (procs[i].ki_pid), proclist); #endif } xfree (procs); return proclist; } /* The WINDOWSNT implementation is in w32.c. The MSDOS implementation is in dosfns.c. The Haiku implementation is in haiku.c. */ #elif !defined (WINDOWSNT) && !defined (MSDOS) && !defined (HAIKU) Lisp_Object list_system_processes (void) { return Qnil; } #endif /* !defined (WINDOWSNT) */ #if defined __FreeBSD__ || defined DARWIN_OS static struct timespec timeval_to_timespec (struct timeval t) { return make_timespec (t.tv_sec, t.tv_usec * 1000); } static Lisp_Object make_lisp_timeval (struct timeval t) { return make_lisp_time (timeval_to_timespec (t)); } #elif defined __OpenBSD__ static Lisp_Object make_lisp_timeval (long sec, long usec) { return make_lisp_time(make_timespec(sec, usec * 1000)); } #endif #ifdef GNU_LINUX static struct timespec time_from_jiffies (unsigned long long tval, long hz) { unsigned long long s = tval / hz; unsigned long long frac = tval % hz; int ns; if (TYPE_MAXIMUM (time_t) < s) time_overflow (); if (LONG_MAX - 1 <= ULLONG_MAX / TIMESPEC_HZ || frac <= ULLONG_MAX / TIMESPEC_HZ) ns = frac * TIMESPEC_HZ / hz; else { /* This is reachable only in the unlikely case that HZ * HZ exceeds ULLONG_MAX. It calculates an approximation that is guaranteed to be in range. */ long hz_per_ns = hz / TIMESPEC_HZ + (hz % TIMESPEC_HZ != 0); ns = frac / hz_per_ns; } return make_timespec (s, ns); } static Lisp_Object ltime_from_jiffies (unsigned long long tval, long hz) { struct timespec t = time_from_jiffies (tval, hz); return make_lisp_time (t); } static struct timespec get_up_time (void) { FILE *fup; struct timespec up = make_timespec (0, 0); block_input (); fup = emacs_fopen ("/proc/uptime", "r"); if (fup) { unsigned long long upsec, upfrac; int upfrac_start, upfrac_end; if (fscanf (fup, "%llu.%n%llu%n", &upsec, &upfrac_start, &upfrac, &upfrac_end) == 2) { if (TYPE_MAXIMUM (time_t) < upsec) { upsec = TYPE_MAXIMUM (time_t); upfrac = TIMESPEC_HZ - 1; } else { int upfraclen = upfrac_end - upfrac_start; for (; upfraclen < LOG10_TIMESPEC_HZ; upfraclen++) upfrac *= 10; for (; LOG10_TIMESPEC_HZ < upfraclen; upfraclen--) upfrac /= 10; upfrac = min (upfrac, TIMESPEC_HZ - 1); } up = make_timespec (upsec, upfrac); } fclose (fup); } unblock_input (); return up; } #define MAJOR(d) (((unsigned)(d) >> 8) & 0xfff) #define MINOR(d) (((unsigned)(d) & 0xff) | (((unsigned)(d) & 0xfff00000) >> 12)) static Lisp_Object procfs_ttyname (int rdev) { FILE *fdev; char name[PATH_MAX]; block_input (); fdev = emacs_fopen ("/proc/tty/drivers", "r"); name[0] = 0; if (fdev) { unsigned major; unsigned long minor_beg, minor_end; char minor[25]; /* 2 32-bit numbers + dash */ char *endp; for (; !feof (fdev) && !ferror (fdev); name[0] = 0) { if (fscanf (fdev, "%*s %s %u %s %*s\n", name, &major, minor) >= 3 && major == MAJOR (rdev)) { minor_beg = strtoul (minor, &endp, 0); if (*endp == '\0') minor_end = minor_beg; else if (*endp == '-') minor_end = strtoul (endp + 1, &endp, 0); else continue; if (MINOR (rdev) >= minor_beg && MINOR (rdev) <= minor_end) { sprintf (name + strlen (name), "%u", MINOR (rdev)); break; } } } fclose (fdev); } unblock_input (); return build_string (name); } static uintmax_t procfs_get_total_memory (void) { FILE *fmem; uintmax_t retval = 2 * 1024 * 1024; /* default: 2 GiB */ int c; block_input (); fmem = emacs_fopen ("/proc/meminfo", "r"); if (fmem) { uintmax_t entry_value; bool done; do switch (fscanf (fmem, "MemTotal: %"SCNuMAX, &entry_value)) { case 1: retval = entry_value; done = 1; break; case 0: while ((c = getc (fmem)) != EOF && c != '\n') continue; done = c == EOF; break; default: done = 1; break; } while (!done); fclose (fmem); } unblock_input (); return retval; } Lisp_Object system_process_attributes (Lisp_Object pid) { char procfn[PATH_MAX], fn[PATH_MAX]; struct stat st; struct passwd *pw; struct group *gr; long clocks_per_sec; char *procfn_end; char procbuf[1025], *p, *q UNINIT; int fd; ssize_t nread; static char const default_cmd[] = "???"; const char *cmd = default_cmd; int cmdsize = sizeof default_cmd - 1; char *cmdline = NULL; ptrdiff_t cmdline_size; char c; intmax_t proc_id; int ppid, pgrp, sess, tty, tpgid, thcount; uid_t uid; gid_t gid; unsigned long long u_time, s_time, cutime, cstime, start; long priority, niceness, rss; unsigned long minflt, majflt, cminflt, cmajflt, vsize; struct timespec tnow, tstart, tboot, telapsed, us_time; double pcpu, pmem; Lisp_Object attrs = Qnil; Lisp_Object decoded_cmd; ptrdiff_t count; CHECK_NUMBER (pid); CONS_TO_INTEGER (pid, pid_t, proc_id); sprintf (procfn, "/proc/%"PRIdMAX, proc_id); if (stat (procfn, &st) < 0) return attrs; /* euid egid */ uid = st.st_uid; attrs = Fcons (Fcons (Qeuid, INT_TO_INTEGER (uid)), attrs); block_input (); pw = getpwuid (uid); unblock_input (); if (pw) attrs = Fcons (Fcons (Quser, build_string (pw->pw_name)), attrs); gid = st.st_gid; attrs = Fcons (Fcons (Qegid, INT_TO_INTEGER (gid)), attrs); block_input (); gr = getgrgid (gid); unblock_input (); if (gr) attrs = Fcons (Fcons (Qgroup, build_string (gr->gr_name)), attrs); count = SPECPDL_INDEX (); strcpy (fn, procfn); procfn_end = fn + strlen (fn); strcpy (procfn_end, "/stat"); fd = emacs_open (fn, O_RDONLY, 0); if (fd < 0) nread = 0; else { record_unwind_protect_int (close_file_unwind, fd); nread = emacs_read_quit (fd, procbuf, sizeof procbuf - 1); } if (0 < nread) { procbuf[nread] = '\0'; p = procbuf; p = strchr (p, '('); if (p != NULL) { q = strrchr (p + 1, ')'); /* comm */ if (q != NULL) { cmd = p + 1; cmdsize = q - cmd; } } else q = NULL; /* Command name is encoded in locale-coding-system; decode it. */ AUTO_STRING_WITH_LEN (cmd_str, cmd, cmdsize); decoded_cmd = code_convert_string_norecord (cmd_str, Vlocale_coding_system, 0); attrs = Fcons (Fcons (Qcomm, decoded_cmd), attrs); /* state ppid pgrp sess tty tpgid . minflt cminflt majflt cmajflt utime stime cutime cstime priority nice thcount . start vsize rss */ if (q && (sscanf (q + 2, ("%c %d %d %d %d %d %*u %lu %lu %lu %lu " "%Lu %Lu %Lu %Lu %ld %ld %d %*d %Lu %lu %ld"), &c, &ppid, &pgrp, &sess, &tty, &tpgid, &minflt, &cminflt, &majflt, &cmajflt, &u_time, &s_time, &cutime, &cstime, &priority, &niceness, &thcount, &start, &vsize, &rss) == 20)) { char state_str[2]; state_str[0] = c; state_str[1] = '\0'; attrs = Fcons (Fcons (Qstate, build_string (state_str)), attrs); attrs = Fcons (Fcons (Qppid, INT_TO_INTEGER (ppid)), attrs); attrs = Fcons (Fcons (Qpgrp, INT_TO_INTEGER (pgrp)), attrs); attrs = Fcons (Fcons (Qsess, INT_TO_INTEGER (sess)), attrs); attrs = Fcons (Fcons (Qttname, procfs_ttyname (tty)), attrs); attrs = Fcons (Fcons (Qtpgid, INT_TO_INTEGER (tpgid)), attrs); attrs = Fcons (Fcons (Qminflt, INT_TO_INTEGER (minflt)), attrs); attrs = Fcons (Fcons (Qmajflt, INT_TO_INTEGER (majflt)), attrs); attrs = Fcons (Fcons (Qcminflt, INT_TO_INTEGER (cminflt)), attrs); attrs = Fcons (Fcons (Qcmajflt, INT_TO_INTEGER (cmajflt)), attrs); clocks_per_sec = sysconf (_SC_CLK_TCK); if (clocks_per_sec < 0) clocks_per_sec = 100; attrs = Fcons (Fcons (Qutime, ltime_from_jiffies (u_time, clocks_per_sec)), attrs); attrs = Fcons (Fcons (Qstime, ltime_from_jiffies (s_time, clocks_per_sec)), attrs); attrs = Fcons (Fcons (Qtime, ltime_from_jiffies (s_time + u_time, clocks_per_sec)), attrs); attrs = Fcons (Fcons (Qcutime, ltime_from_jiffies (cutime, clocks_per_sec)), attrs); attrs = Fcons (Fcons (Qcstime, ltime_from_jiffies (cstime, clocks_per_sec)), attrs); attrs = Fcons (Fcons (Qctime, ltime_from_jiffies (cstime + cutime, clocks_per_sec)), attrs); attrs = Fcons (Fcons (Qpri, make_fixnum (priority)), attrs); attrs = Fcons (Fcons (Qnice, make_fixnum (niceness)), attrs); attrs = Fcons (Fcons (Qthcount, INT_TO_INTEGER (thcount)), attrs); tnow = current_timespec (); telapsed = get_up_time (); tboot = timespec_sub (tnow, telapsed); tstart = time_from_jiffies (start, clocks_per_sec); tstart = timespec_add (tboot, tstart); attrs = Fcons (Fcons (Qstart, make_lisp_time (tstart)), attrs); attrs = Fcons (Fcons (Qvsize, INT_TO_INTEGER (vsize / 1024)), attrs); attrs = Fcons (Fcons (Qrss, INT_TO_INTEGER (4 * rss)), attrs); telapsed = timespec_sub (tnow, tstart); attrs = Fcons (Fcons (Qetime, make_lisp_time (telapsed)), attrs); us_time = time_from_jiffies (u_time + s_time, clocks_per_sec); pcpu = timespectod (us_time) / timespectod (telapsed); if (pcpu > 1.0) pcpu = 1.0; attrs = Fcons (Fcons (Qpcpu, make_float (100 * pcpu)), attrs); pmem = 4.0 * 100 * rss / procfs_get_total_memory (); if (pmem > 100) pmem = 100; attrs = Fcons (Fcons (Qpmem, make_float (pmem)), attrs); } } unbind_to (count, Qnil); /* args */ strcpy (procfn_end, "/cmdline"); fd = emacs_open (fn, O_RDONLY, 0); if (fd >= 0) { ptrdiff_t readsize, nread_incr; record_unwind_protect_int (close_file_unwind, fd); record_unwind_protect_nothing (); nread = cmdline_size = 0; do { cmdline = xpalloc (cmdline, &cmdline_size, 2, STRING_BYTES_BOUND, 1); set_unwind_protect_ptr (count + 1, xfree, cmdline); /* Leave room even if every byte needs escaping below. */ readsize = (cmdline_size >> 1) - nread; nread_incr = emacs_read_quit (fd, cmdline + nread, readsize); nread += max (0, nread_incr); } while (nread_incr == readsize); if (nread) { /* We don't want trailing null characters. */ for (p = cmdline + nread; cmdline < p && !p[-1]; p--) continue; /* Escape-quote whitespace and backslashes. */ q = cmdline + cmdline_size; while (cmdline < p) { char c = *--p; *--q = c ? c : ' '; if (c_isspace (c) || c == '\\') *--q = '\\'; } nread = cmdline + cmdline_size - q; } if (!nread) { nread = cmdsize + 2; cmdline_size = nread + 1; q = cmdline = xrealloc (cmdline, cmdline_size); set_unwind_protect_ptr (count + 1, xfree, cmdline); sprintf (cmdline, "[%.*s]", cmdsize, cmd); } /* Command line is encoded in locale-coding-system; decode it. */ AUTO_STRING_WITH_LEN (cmd_str, q, nread); decoded_cmd = code_convert_string_norecord (cmd_str, Vlocale_coding_system, 0); unbind_to (count, Qnil); attrs = Fcons (Fcons (Qargs, decoded_cmd), attrs); } return attrs; } #elif defined (SOLARIS2) && defined (HAVE_PROCFS) /* The header does not like to be included if _LP64 is defined and __FILE_OFFSET_BITS == 64. This is an ugly workaround that. */ #if !defined (_LP64) && defined (_FILE_OFFSET_BITS) && (_FILE_OFFSET_BITS == 64) #define PROCFS_FILE_OFFSET_BITS_HACK 1 #undef _FILE_OFFSET_BITS #else #define PROCFS_FILE_OFFSET_BITS_HACK 0 #endif #include #if PROCFS_FILE_OFFSET_BITS_HACK == 1 #define _FILE_OFFSET_BITS 64 #ifdef _FILE_OFFSET_BITS /* Avoid unused-macro warnings. */ #endif #endif /* PROCFS_FILE_OFFSET_BITS_HACK == 1 */ Lisp_Object system_process_attributes (Lisp_Object pid) { char procfn[PATH_MAX], fn[PATH_MAX]; struct stat st; struct passwd *pw; struct group *gr; char *procfn_end; struct psinfo pinfo; int fd; ssize_t nread; intmax_t proc_id; uid_t uid; gid_t gid; Lisp_Object attrs = Qnil; Lisp_Object decoded_cmd; ptrdiff_t count; CHECK_NUMBER (pid); CONS_TO_INTEGER (pid, pid_t, proc_id); sprintf (procfn, "/proc/%"PRIdMAX, proc_id); if (stat (procfn, &st) < 0) return attrs; /* euid egid */ uid = st.st_uid; attrs = Fcons (Fcons (Qeuid, INT_TO_INTEGER (uid)), attrs); block_input (); pw = getpwuid (uid); unblock_input (); if (pw) attrs = Fcons (Fcons (Quser, build_string (pw->pw_name)), attrs); gid = st.st_gid; attrs = Fcons (Fcons (Qegid, INT_TO_INTEGER (gid)), attrs); block_input (); gr = getgrgid (gid); unblock_input (); if (gr) attrs = Fcons (Fcons (Qgroup, build_string (gr->gr_name)), attrs); count = SPECPDL_INDEX (); strcpy (fn, procfn); procfn_end = fn + strlen (fn); strcpy (procfn_end, "/psinfo"); fd = emacs_open (fn, O_RDONLY, 0); if (fd < 0) nread = 0; else { record_unwind_protect_int (close_file_unwind, fd); nread = emacs_read_quit (fd, &pinfo, sizeof pinfo); } if (nread == sizeof pinfo) { attrs = Fcons (Fcons (Qppid, INT_TO_INTEGER (pinfo.pr_ppid)), attrs); attrs = Fcons (Fcons (Qpgrp, INT_TO_INTEGER (pinfo.pr_pgid)), attrs); attrs = Fcons (Fcons (Qsess, INT_TO_INTEGER (pinfo.pr_sid)), attrs); { char state_str[2]; state_str[0] = pinfo.pr_lwp.pr_sname; state_str[1] = '\0'; attrs = Fcons (Fcons (Qstate, build_string (state_str)), attrs); } /* FIXME: missing Qttyname. psinfo.pr_ttydev is a dev_t, need to get a string from it. */ /* FIXME: missing: Qtpgid */ /* FIXME: missing: Qminflt Qmajflt Qcminflt Qcmajflt Qutime Qcutime Qstime Qcstime Are they available? */ attrs = Fcons (Fcons (Qtime, make_lisp_time (pinfo.pr_time)), attrs); attrs = Fcons (Fcons (Qctime, make_lisp_time (pinfo.pr_ctime)), attrs); attrs = Fcons (Fcons (Qpri, make_fixnum (pinfo.pr_lwp.pr_pri)), attrs); attrs = Fcons (Fcons (Qnice, make_fixnum (pinfo.pr_lwp.pr_nice)), attrs); attrs = Fcons (Fcons (Qthcount, INT_TO_INTEGER (pinfo.pr_nlwp)), attrs); attrs = Fcons (Fcons (Qstart, make_lisp_time (pinfo.pr_start)), attrs); attrs = Fcons (Fcons (Qvsize, INT_TO_INTEGER (pinfo.pr_size)), attrs); attrs = Fcons (Fcons (Qrss, INT_TO_INTEGER (pinfo.pr_rssize)), attrs); /* pr_pctcpu and pr_pctmem are unsigned integers in the range 0 .. 2**15, representing 0.0 .. 1.0. */ attrs = Fcons (Fcons (Qpcpu, make_float (100.0 / 0x8000 * pinfo.pr_pctcpu)), attrs); attrs = Fcons (Fcons (Qpmem, make_float (100.0 / 0x8000 * pinfo.pr_pctmem)), attrs); AUTO_STRING (fname, pinfo.pr_fname); decoded_cmd = code_convert_string_norecord (fname, Vlocale_coding_system, 0); attrs = Fcons (Fcons (Qcomm, decoded_cmd), attrs); AUTO_STRING (psargs, pinfo.pr_psargs); decoded_cmd = code_convert_string_norecord (psargs, Vlocale_coding_system, 0); attrs = Fcons (Fcons (Qargs, decoded_cmd), attrs); } return unbind_to (count, attrs); } #elif defined __FreeBSD__ Lisp_Object system_process_attributes (Lisp_Object pid) { int proc_id; int pagesize = getpagesize (); unsigned long npages; int fscale; struct passwd *pw; struct group *gr; char *ttyname; size_t len; char args[MAXPATHLEN]; struct timespec t, now; int mib[4] = {CTL_KERN, KERN_PROC, KERN_PROC_PID}; struct kinfo_proc proc; size_t proclen = sizeof proc; Lisp_Object attrs = Qnil; Lisp_Object decoded_comm; CHECK_NUMBER (pid); CONS_TO_INTEGER (pid, int, proc_id); mib[3] = proc_id; if (sysctl (mib, 4, &proc, &proclen, NULL, 0) != 0 || proclen == 0) return attrs; attrs = Fcons (Fcons (Qeuid, INT_TO_INTEGER (proc.ki_uid)), attrs); block_input (); pw = getpwuid (proc.ki_uid); unblock_input (); if (pw) attrs = Fcons (Fcons (Quser, build_string (pw->pw_name)), attrs); attrs = Fcons (Fcons (Qegid, INT_TO_INTEGER (proc.ki_svgid)), attrs); block_input (); gr = getgrgid (proc.ki_svgid); unblock_input (); if (gr) attrs = Fcons (Fcons (Qgroup, build_string (gr->gr_name)), attrs); AUTO_STRING (comm, proc.ki_comm); decoded_comm = code_convert_string_norecord (comm, Vlocale_coding_system, 0); attrs = Fcons (Fcons (Qcomm, decoded_comm), attrs); { char state[2] = {'\0', '\0'}; switch (proc.ki_stat) { case SRUN: state[0] = 'R'; break; case SSLEEP: state[0] = 'S'; break; case SLOCK: state[0] = 'D'; break; case SZOMB: state[0] = 'Z'; break; case SSTOP: state[0] = 'T'; break; } attrs = Fcons (Fcons (Qstate, build_string (state)), attrs); } attrs = Fcons (Fcons (Qppid, INT_TO_INTEGER (proc.ki_ppid)), attrs); attrs = Fcons (Fcons (Qpgrp, INT_TO_INTEGER (proc.ki_pgid)), attrs); attrs = Fcons (Fcons (Qsess, INT_TO_INTEGER (proc.ki_sid)), attrs); block_input (); ttyname = proc.ki_tdev == NODEV ? NULL : devname (proc.ki_tdev, S_IFCHR); unblock_input (); if (ttyname) attrs = Fcons (Fcons (Qttname, build_string (ttyname)), attrs); attrs = Fcons (Fcons (Qtpgid, INT_TO_INTEGER (proc.ki_tpgid)), attrs); attrs = Fcons (Fcons (Qminflt, INT_TO_INTEGER (proc.ki_rusage.ru_minflt)), attrs); attrs = Fcons (Fcons (Qmajflt, INT_TO_INTEGER (proc.ki_rusage.ru_majflt)), attrs); attrs = Fcons (Fcons (Qcminflt, make_fixnum (proc.ki_rusage_ch.ru_minflt)), attrs); attrs = Fcons (Fcons (Qcmajflt, make_fixnum (proc.ki_rusage_ch.ru_majflt)), attrs); attrs = Fcons (Fcons (Qutime, make_lisp_timeval (proc.ki_rusage.ru_utime)), attrs); attrs = Fcons (Fcons (Qstime, make_lisp_timeval (proc.ki_rusage.ru_stime)), attrs); t = timespec_add (timeval_to_timespec (proc.ki_rusage.ru_utime), timeval_to_timespec (proc.ki_rusage.ru_stime)); attrs = Fcons (Fcons (Qtime, make_lisp_time (t)), attrs); attrs = Fcons (Fcons (Qcutime, make_lisp_timeval (proc.ki_rusage_ch.ru_utime)), attrs); attrs = Fcons (Fcons (Qcstime, make_lisp_timeval (proc.ki_rusage_ch.ru_utime)), attrs); t = timespec_add (timeval_to_timespec (proc.ki_rusage_ch.ru_utime), timeval_to_timespec (proc.ki_rusage_ch.ru_stime)); attrs = Fcons (Fcons (Qctime, make_lisp_time (t)), attrs); attrs = Fcons (Fcons (Qthcount, INT_TO_INTEGER (proc.ki_numthreads)), attrs); attrs = Fcons (Fcons (Qpri, make_fixnum (proc.ki_pri.pri_native)), attrs); attrs = Fcons (Fcons (Qnice, make_fixnum (proc.ki_nice)), attrs); attrs = Fcons (Fcons (Qstart, make_lisp_timeval (proc.ki_start)), attrs); attrs = Fcons (Fcons (Qvsize, make_fixnum (proc.ki_size >> 10)), attrs); attrs = Fcons (Fcons (Qrss, make_fixnum (proc.ki_rssize * pagesize >> 10)), attrs); now = current_timespec (); t = timespec_sub (now, timeval_to_timespec (proc.ki_start)); attrs = Fcons (Fcons (Qetime, make_lisp_time (t)), attrs); len = sizeof fscale; if (sysctlbyname ("kern.fscale", &fscale, &len, NULL, 0) == 0) { double pcpu; fixpt_t ccpu; len = sizeof ccpu; if (sysctlbyname ("kern.ccpu", &ccpu, &len, NULL, 0) == 0) { pcpu = (100.0 * proc.ki_pctcpu / fscale / (1 - exp (proc.ki_swtime * log ((double) ccpu / fscale)))); attrs = Fcons (Fcons (Qpcpu, INT_TO_INTEGER (pcpu)), attrs); } } len = sizeof npages; if (sysctlbyname ("hw.availpages", &npages, &len, NULL, 0) == 0) { double pmem = (proc.ki_flag & P_INMEM ? 100.0 * proc.ki_rssize / npages : 0); attrs = Fcons (Fcons (Qpmem, INT_TO_INTEGER (pmem)), attrs); } mib[2] = KERN_PROC_ARGS; len = MAXPATHLEN; if (sysctl (mib, 4, args, &len, NULL, 0) == 0 && len != 0) { int i; for (i = 0; i < len; i++) { if (! args[i] && i < len - 1) args[i] = ' '; } AUTO_STRING (comm, args); decoded_comm = code_convert_string_norecord (comm, Vlocale_coding_system, 0); attrs = Fcons (Fcons (Qargs, decoded_comm), attrs); } return attrs; } #elif defined __OpenBSD__ Lisp_Object system_process_attributes (Lisp_Object pid) { int proc_id, nentries, fscale, i; int pagesize = getpagesize (); int mib[6]; size_t len; double pct; char *ttyname, args[ARG_MAX]; struct kinfo_proc proc; struct passwd *pw; struct group *gr; struct timespec t; struct uvmexp uvmexp; Lisp_Object attrs = Qnil; Lisp_Object decoded_comm; CHECK_NUMBER (pid); CONS_TO_INTEGER (pid, int, proc_id); len = sizeof proc; mib[0] = CTL_KERN; mib[1] = KERN_PROC; mib[2] = KERN_PROC_PID; mib[3] = proc_id; mib[4] = len; mib[5] = 1; if (sysctl (mib, 6, &proc, &len, NULL, 0) != 0) return attrs; attrs = Fcons (Fcons (Qeuid, INT_TO_INTEGER (proc.p_uid)), attrs); block_input (); pw = getpwuid (proc.p_uid); unblock_input (); if (pw) attrs = Fcons (Fcons (Quser, build_string(pw->pw_name)), attrs); attrs = Fcons (Fcons (Qegid, INT_TO_INTEGER(proc.p_svgid)), attrs); block_input (); gr = getgrgid (proc.p_svgid); unblock_input (); if (gr) attrs = Fcons (Fcons (Qgroup, build_string (gr->gr_name)), attrs); AUTO_STRING (comm, proc.p_comm); decoded_comm = code_convert_string_norecord (comm, Vlocale_coding_system, 0); attrs = Fcons (Fcons (Qcomm, decoded_comm), attrs); { char state[2] = {'\0', '\0'}; switch (proc.p_stat) { case SIDL: state[0] = 'I'; break; case SRUN: state[0] = 'R'; break; case SSLEEP: state[0] = 'S'; break; case SSTOP: state[0] = 'T'; break; case SZOMB: state[0] = 'Z'; break; case SDEAD: state[0] = 'D'; break; } attrs = Fcons (Fcons (Qstate, build_string (state)), attrs); } attrs = Fcons (Fcons (Qppid, INT_TO_INTEGER (proc.p_ppid)), attrs); attrs = Fcons (Fcons (Qpgrp, INT_TO_INTEGER (proc.p_gid)), attrs); attrs = Fcons (Fcons (Qsess, INT_TO_INTEGER (proc.p_sid)), attrs); block_input (); ttyname = proc.p_tdev == NODEV ? NULL : devname (proc.p_tdev, S_IFCHR); unblock_input (); if (ttyname) attrs = Fcons (Fcons (Qttname, build_string (ttyname)), attrs); attrs = Fcons (Fcons (Qtpgid, INT_TO_INTEGER (proc.p_tpgid)), attrs); attrs = Fcons (Fcons (Qminflt, INT_TO_INTEGER (proc.p_uru_minflt)), attrs); attrs = Fcons (Fcons (Qmajflt, INT_TO_INTEGER (proc.p_uru_majflt)), attrs); /* FIXME: missing cminflt, cmajflt. */ attrs = Fcons (Fcons (Qutime, make_lisp_timeval (proc.p_uutime_sec, proc.p_uutime_usec)), attrs); attrs = Fcons (Fcons (Qstime, make_lisp_timeval (proc.p_ustime_sec, proc.p_ustime_usec)), attrs); t = timespec_add (make_timespec (proc.p_uutime_sec, proc.p_uutime_usec * 1000), make_timespec (proc.p_ustime_sec, proc.p_ustime_usec * 1000)); attrs = Fcons (Fcons (Qtime, make_lisp_time (t)), attrs); attrs = Fcons (Fcons (Qcutime, make_lisp_timeval (proc.p_uctime_sec, proc.p_uctime_usec)), attrs); /* FIXME: missing cstime and thus ctime. */ attrs = Fcons (Fcons (Qpri, make_fixnum (proc.p_priority)), attrs); attrs = Fcons (Fcons (Qnice, make_fixnum (proc.p_nice)), attrs); /* FIXME: missing thcount (thread count) */ attrs = Fcons (Fcons (Qstart, make_lisp_timeval (proc.p_ustart_sec, proc.p_ustart_usec)), attrs); len = (proc.p_vm_tsize + proc.p_vm_dsize + proc.p_vm_ssize) * pagesize >> 10; attrs = Fcons (Fcons (Qvsize, make_fixnum (len)), attrs); attrs = Fcons (Fcons (Qrss, make_fixnum (proc.p_vm_rssize * pagesize >> 10)), attrs); t = make_timespec (proc.p_ustart_sec, proc.p_ustart_usec * 1000); t = timespec_sub (current_timespec (), t); attrs = Fcons (Fcons (Qetime, make_lisp_time (t)), attrs); len = sizeof (fscale); mib[0] = CTL_KERN; mib[1] = KERN_FSCALE; if (sysctl (mib, 2, &fscale, &len, NULL, 0) != -1) { pct = (double)proc.p_pctcpu / fscale * 100.0; attrs = Fcons (Fcons (Qpcpu, make_float (pct)), attrs); } len = sizeof (uvmexp); mib[0] = CTL_VM; mib[1] = VM_UVMEXP; if (sysctl (mib, 2, &uvmexp, &len, NULL, 0) != -1) { pct = (100.0 * (double)proc.p_vm_rssize / uvmexp.npages); attrs = Fcons (Fcons (Qpmem, make_float (pct)), attrs); } len = sizeof args; mib[0] = CTL_KERN; mib[1] = KERN_PROC_ARGS; mib[2] = proc_id; mib[3] = KERN_PROC_ARGV; if (sysctl (mib, 4, &args, &len, NULL, 0) == 0 && len != 0) { char **argv = (char**)args; /* concatenate argv reusing the existing storage storage. sysctl(8) guarantees that "the buffer pointed to by oldp is filled with an array of char pointers followed by the strings themselves." */ for (i = 0; argv[i] != NULL; ++i) { if (argv[i+1] != NULL) { len = strlen (argv[i]); argv[i][len] = ' '; } } AUTO_STRING (comm, *argv); decoded_comm = code_convert_string_norecord (comm, Vlocale_coding_system, 0); attrs = Fcons (Fcons (Qargs, decoded_comm), attrs); } return attrs; } #elif defined DARWIN_OS Lisp_Object system_process_attributes (Lisp_Object pid) { int proc_id, i; struct passwd *pw; struct group *gr; char *ttyname; struct timeval starttime; struct timespec t, now; dev_t tdev; uid_t uid; gid_t gid; int mib[4] = {CTL_KERN, KERN_PROC, KERN_PROC_PID}; struct kinfo_proc proc; size_t len = sizeof proc; Lisp_Object attrs = Qnil; Lisp_Object decoded_comm; CHECK_NUMBER (pid); CONS_TO_INTEGER (pid, int, proc_id); mib[3] = proc_id; if (sysctl (mib, 4, &proc, &len, NULL, 0) != 0 || len == 0) return attrs; uid = proc.kp_eproc.e_ucred.cr_uid; attrs = Fcons (Fcons (Qeuid, INT_TO_INTEGER (uid)), attrs); block_input (); pw = getpwuid (uid); unblock_input (); if (pw) attrs = Fcons (Fcons (Quser, build_string (pw->pw_name)), attrs); gid = proc.kp_eproc.e_pcred.p_svgid; attrs = Fcons (Fcons (Qegid, INT_TO_INTEGER (gid)), attrs); block_input (); gr = getgrgid (gid); unblock_input (); if (gr) attrs = Fcons (Fcons (Qgroup, build_string (gr->gr_name)), attrs); char pathbuf[PROC_PIDPATHINFO_MAXSIZE]; char *comm; if (proc_pidpath (proc_id, pathbuf, sizeof(pathbuf)) > 0) { if ((comm = strrchr (pathbuf, '/'))) comm++; else comm = pathbuf; } else comm = proc.kp_proc.p_comm; decoded_comm = (code_convert_string_norecord (build_unibyte_string (comm), Vlocale_coding_system, 0)); attrs = Fcons (Fcons (Qcomm, decoded_comm), attrs); { char state[2] = {'\0', '\0'}; switch (proc.kp_proc.p_stat) { case SRUN: state[0] = 'R'; break; case SSLEEP: state[0] = 'S'; break; case SZOMB: state[0] = 'Z'; break; case SSTOP: state[0] = 'T'; break; case SIDL: state[0] = 'I'; break; } attrs = Fcons (Fcons (Qstate, build_string (state)), attrs); } attrs = Fcons (Fcons (Qppid, INT_TO_INTEGER (proc.kp_eproc.e_ppid)), attrs); attrs = Fcons (Fcons (Qpgrp, INT_TO_INTEGER (proc.kp_eproc.e_pgid)), attrs); tdev = proc.kp_eproc.e_tdev; block_input (); ttyname = tdev == NODEV ? NULL : devname (tdev, S_IFCHR); unblock_input (); if (ttyname) attrs = Fcons (Fcons (Qttname, build_string (ttyname)), attrs); attrs = Fcons (Fcons (Qtpgid, INT_TO_INTEGER (proc.kp_eproc.e_tpgid)), attrs); rusage_info_current ri; if (proc_pid_rusage(proc_id, RUSAGE_INFO_CURRENT, (rusage_info_t *) &ri) == 0) { struct timespec utime = make_timespec (ri.ri_user_time / TIMESPEC_HZ, ri.ri_user_time % TIMESPEC_HZ); struct timespec stime = make_timespec (ri.ri_system_time / TIMESPEC_HZ, ri.ri_system_time % TIMESPEC_HZ); attrs = Fcons (Fcons (Qutime, make_lisp_time (utime)), attrs); attrs = Fcons (Fcons (Qstime, make_lisp_time (stime)), attrs); attrs = Fcons (Fcons (Qtime, make_lisp_time (timespec_add (utime, stime))), attrs); attrs = Fcons (Fcons (Qmajflt, INT_TO_INTEGER (ri.ri_pageins)), attrs); } starttime = proc.kp_proc.p_starttime; attrs = Fcons (Fcons (Qnice, make_fixnum (proc.kp_proc.p_nice)), attrs); attrs = Fcons (Fcons (Qstart, make_lisp_timeval (starttime)), attrs); now = current_timespec (); t = timespec_sub (now, timeval_to_timespec (starttime)); attrs = Fcons (Fcons (Qetime, make_lisp_time (t)), attrs); struct proc_taskinfo taskinfo; if (proc_pidinfo (proc_id, PROC_PIDTASKINFO, 0, &taskinfo, sizeof (taskinfo)) > 0) { attrs = Fcons (Fcons (Qvsize, make_fixnum (taskinfo.pti_virtual_size / 1024)), attrs); attrs = Fcons (Fcons (Qrss, make_fixnum (taskinfo.pti_resident_size / 1024)), attrs); attrs = Fcons (Fcons (Qthcount, make_fixnum (taskinfo.pti_threadnum)), attrs); } #ifdef KERN_PROCARGS2 char args[ARG_MAX]; mib[1] = KERN_PROCARGS2; mib[2] = proc_id; len = sizeof args; if (sysctl (mib, 3, &args, &len, NULL, 0) == 0 && len != 0) { char *start, *end; int argc = *(int*)args; /* argc is the first int */ start = args + sizeof (int); start += strlen (start) + 1; /* skip executable name and any '\0's */ while ((start - args < len) && ! *start) start++; /* skip argv to find real end */ for (i = 0, end = start; i < argc && (end - args) < len; i++) { end += strlen (end) + 1; } len = end - start; for (int i = 0; i < len; i++) { if (! start[i] && i < len - 1) start[i] = ' '; } AUTO_STRING (comm, start); decoded_comm = code_convert_string_norecord (comm, Vlocale_coding_system, 0); attrs = Fcons (Fcons (Qargs, decoded_comm), attrs); } #endif /* KERN_PROCARGS2 */ return attrs; } /* The WINDOWSNT implementation is in w32.c. The MSDOS implementation is in dosfns.c. The HAIKU implementation is in haiku.c. */ #elif !defined (WINDOWSNT) && !defined (MSDOS) && !defined (HAIKU) Lisp_Object system_process_attributes (Lisp_Object pid) { return Qnil; } #endif /* !defined (WINDOWSNT) */ DEFUN ("get-internal-run-time", Fget_internal_run_time, Sget_internal_run_time, 0, 0, 0, doc: /* Return the current run time used by Emacs. The time is returned as in the style of `current-time'. On systems that can't determine the run time, `get-internal-run-time' does the same thing as `current-time'. */) (void) { #ifdef HAVE_GETRUSAGE struct rusage usage; time_t secs; int usecs; if (getrusage (RUSAGE_SELF, &usage) < 0) /* This shouldn't happen. What action is appropriate? */ xsignal0 (Qerror); /* Sum up user time and system time. */ secs = usage.ru_utime.tv_sec + usage.ru_stime.tv_sec; usecs = usage.ru_utime.tv_usec + usage.ru_stime.tv_usec; if (usecs >= 1000000) { usecs -= 1000000; secs++; } return make_lisp_time (make_timespec (secs, usecs * 1000)); #else /* ! HAVE_GETRUSAGE */ #ifdef WINDOWSNT return w32_get_internal_run_time (); #else /* ! WINDOWSNT */ return Fcurrent_time (); #endif /* WINDOWSNT */ #endif /* HAVE_GETRUSAGE */ } /* Wide character string collation. */ #ifdef __STDC_ISO_10646__ # include # include # if defined HAVE_NEWLOCALE || defined HAVE_SETLOCALE # include # endif # ifndef LC_COLLATE # define LC_COLLATE 0 # endif # ifndef LC_COLLATE_MASK # define LC_COLLATE_MASK 0 # endif # ifndef LC_CTYPE # define LC_CTYPE 0 # endif # ifndef LC_CTYPE_MASK # define LC_CTYPE_MASK 0 # endif # ifndef HAVE_NEWLOCALE # undef freelocale # undef locale_t # undef newlocale # undef wcscoll_l # undef towlower_l # define freelocale emacs_freelocale # define locale_t emacs_locale_t # define newlocale emacs_newlocale # define wcscoll_l emacs_wcscoll_l # define towlower_l emacs_towlower_l typedef char const *locale_t; static locale_t newlocale (int category_mask, char const *locale, locale_t loc) { return locale; } static void freelocale (locale_t loc) { } static char * emacs_setlocale (int category, char const *locale) { # ifdef HAVE_SETLOCALE errno = 0; char *loc = setlocale (category, locale); if (loc || errno) return loc; errno = EINVAL; # else errno = ENOTSUP; # endif return 0; } static int wcscoll_l (wchar_t const *a, wchar_t const *b, locale_t loc) { int result = 0; char *oldloc = emacs_setlocale (LC_COLLATE, NULL); int err; if (! oldloc) err = errno; else { USE_SAFE_ALLOCA; char *oldcopy = SAFE_ALLOCA (strlen (oldloc) + 1); strcpy (oldcopy, oldloc); if (! emacs_setlocale (LC_COLLATE, loc)) err = errno; else { errno = 0; result = wcscoll (a, b); err = errno; if (! emacs_setlocale (LC_COLLATE, oldcopy)) err = errno; } SAFE_FREE (); } errno = err; return result; } static wint_t towlower_l (wint_t wc, locale_t loc) { wint_t result = wc; char *oldloc = emacs_setlocale (LC_CTYPE, NULL); if (oldloc) { USE_SAFE_ALLOCA; char *oldcopy = SAFE_ALLOCA (strlen (oldloc) + 1); strcpy (oldcopy, oldloc); if (emacs_setlocale (LC_CTYPE, loc)) { result = towlower (wc); emacs_setlocale (LC_COLLATE, oldcopy); } SAFE_FREE (); } return result; } # endif int str_collate (Lisp_Object s1, Lisp_Object s2, Lisp_Object locale, Lisp_Object ignore_case) { int res, err; ptrdiff_t len, i, i_byte; wchar_t *p1, *p2; USE_SAFE_ALLOCA; /* Convert byte stream to code points. */ len = SCHARS (s1); i = i_byte = 0; SAFE_NALLOCA (p1, 1, len + 1); while (i < len) { wchar_t *p = &p1[i]; *p = fetch_string_char_advance (s1, &i, &i_byte); } p1[len] = 0; len = SCHARS (s2); i = i_byte = 0; SAFE_NALLOCA (p2, 1, len + 1); while (i < len) { wchar_t *p = &p2[i]; *p = fetch_string_char_advance (s2, &i, &i_byte); } p2[len] = 0; if (STRINGP (locale)) { locale_t loc = newlocale (LC_COLLATE_MASK | LC_CTYPE_MASK, SSDATA (locale), 0); if (!loc) error ("Invalid locale %s: %s", SSDATA (locale), emacs_strerror (errno)); if (! NILP (ignore_case)) for (int i = 1; i < 3; i++) { wchar_t *p = (i == 1) ? p1 : p2; for (; *p; p++) *p = towlower_l (*p, loc); } errno = 0; res = wcscoll_l (p1, p2, loc); err = errno; freelocale (loc); } else { if (! NILP (ignore_case)) for (int i = 1; i < 3; i++) { wchar_t *p = (i == 1) ? p1 : p2; for (; *p; p++) *p = towlower (*p); } errno = 0; res = wcscoll (p1, p2); err = errno; } # ifndef HAVE_NEWLOCALE if (err) error ("Invalid locale or string for collation: %s", emacs_strerror (err)); # else if (err) error ("Invalid string for collation: %s", emacs_strerror (err)); # endif SAFE_FREE (); return res; } #endif /* __STDC_ISO_10646__ */ #ifdef WINDOWSNT int str_collate (Lisp_Object s1, Lisp_Object s2, Lisp_Object locale, Lisp_Object ignore_case) { char *loc = STRINGP (locale) ? SSDATA (locale) : NULL; int res, err = errno; errno = 0; res = w32_compare_strings (SSDATA (s1), SSDATA (s2), loc, !NILP (ignore_case)); if (errno) error ("Invalid string for collation: %s", strerror (errno)); errno = err; return res; } #endif /* WINDOWSNT */ void syms_of_sysdep (void) { defsubr (&Sget_internal_run_time); }