/* GNU's read utmp module.
Copyright (C) 1992-2001, 2003-2006, 2009-2023 Free Software Foundation, Inc.
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see . */
/* Written by jla; revised by djm */
#include
#include "readutmp.h"
#include
#include
#include
#include
#include
#include
#include
#include
#if defined __linux__ || defined __ANDROID__
# include
# include
#endif
#if READUTMP_USE_SYSTEMD
# include
# include
#endif
#if HAVE_SYS_SYSCTL_H && !(defined __GLIBC__ && defined __linux__) && !defined __minix
# if HAVE_SYS_PARAM_H
# include
# endif
# include
#endif
#if HAVE_OS_H
# include
#endif
#include "stat-time.h"
#include "xalloc.h"
/* Each of the FILE streams in this file is only used in a single thread. */
#include "unlocked-io.h"
/* Some helper functions. */
#include "boot-time-aux.h"
/* The following macros describe the 'struct UTMP_STRUCT_NAME',
*not* 'struct gl_utmp'. */
#undef UT_USER
#undef UT_TIME_MEMBER
#undef UT_PID
#undef UT_TYPE_EQ
#undef UT_TYPE_NOT_DEFINED
#undef UT_EXIT_E_TERMINATION
#undef UT_EXIT_E_EXIT
/* Accessor macro for the member named ut_user or ut_name. */
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_NAME \
: HAVE_UTMP_H && HAVE_STRUCT_UTMP_UT_NAME)
# define UT_USER(UT) ((UT)->ut_name)
#else
# define UT_USER(UT) ((UT)->ut_user)
#endif
/* Accessor macro for the member of type time_t (or 'unsigned int'). */
#if HAVE_UTMPX_H || (HAVE_UTMP_H && HAVE_STRUCT_UTMP_UT_TV)
# define UT_TIME_MEMBER(UT) ((UT)->ut_tv.tv_sec)
#else
# define UT_TIME_MEMBER(UT) ((UT)->ut_time)
#endif
/* Accessor macro for the member named ut_pid. */
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_PID : HAVE_STRUCT_UTMP_UT_PID)
# define UT_PID(UT) ((UT)->ut_pid)
#else
# define UT_PID(UT) 0
#endif
/* Accessor macros for the member named ut_type. */
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_TYPE : HAVE_STRUCT_UTMP_UT_TYPE)
# define UT_TYPE_EQ(UT, V) ((UT)->ut_type == (V))
# define UT_TYPE_NOT_DEFINED 0
#else
# define UT_TYPE_EQ(UT, V) 0
# define UT_TYPE_NOT_DEFINED 1
#endif
#if HAVE_UTMPX_H
# if HAVE_STRUCT_UTMPX_UT_EXIT_E_TERMINATION
# define UT_EXIT_E_TERMINATION(UT) ((UT)->ut_exit.e_termination)
# elif HAVE_STRUCT_UTMPX_UT_EXIT_UT_TERMINATION /* OSF/1 */
# define UT_EXIT_E_TERMINATION(UT) ((UT)->ut_exit.ut_termination)
# else
# define UT_EXIT_E_TERMINATION(UT) 0
# endif
#elif HAVE_UTMP_H
# if HAVE_STRUCT_UTMP_UT_EXIT_E_TERMINATION
# define UT_EXIT_E_TERMINATION(UT) ((UT)->ut_exit.e_termination)
# else
# define UT_EXIT_E_TERMINATION(UT) 0
# endif
#endif
#if HAVE_UTMPX_H
# if HAVE_STRUCT_UTMPX_UT_EXIT_E_EXIT
# define UT_EXIT_E_EXIT(UT) ((UT)->ut_exit.e_exit)
# elif HAVE_STRUCT_UTMPX_UT_EXIT_UT_EXIT /* OSF/1 */
# define UT_EXIT_E_EXIT(UT) ((UT)->ut_exit.ut_exit)
# else
# define UT_EXIT_E_EXIT(UT) 0
# endif
#elif HAVE_UTMP_H
# if HAVE_STRUCT_UTMP_UT_EXIT_E_EXIT
# define UT_EXIT_E_EXIT(UT) ((UT)->ut_exit.e_exit)
# else
# define UT_EXIT_E_EXIT(UT) 0
# endif
#endif
/* Size of the UT_USER (ut) member. */
#define UT_USER_SIZE sizeof UT_USER ((struct UTMP_STRUCT_NAME *) 0)
/* Size of the ut->ut_id member. */
#define UT_ID_SIZE sizeof (((struct UTMP_STRUCT_NAME *) 0)->ut_id)
/* Size of the ut->ut_line member. */
#define UT_LINE_SIZE sizeof (((struct UTMP_STRUCT_NAME *) 0)->ut_line)
/* Size of the ut->ut_host member. */
#define UT_HOST_SIZE sizeof (((struct UTMP_STRUCT_NAME *) 0)->ut_host)
#if 8 <= __GNUC__
# pragma GCC diagnostic ignored "-Wsizeof-pointer-memaccess"
#endif
/* Copy UT->ut_user into storage obtained from malloc. Then remove any
trailing spaces from the copy, NUL terminate it, and return the copy. */
char *
extract_trimmed_name (const STRUCT_UTMP *ut)
{
char const *name = ut->ut_user;
idx_t len = strlen (name);
char const *p;
for (p = name + len; name < p && p[-1] == ' '; p--)
continue;
return ximemdup0 (name, p - name);
}
#if READ_UTMP_SUPPORTED
/* Is the utmp entry UT desired by the user who asked for OPTIONS? */
static bool
desirable_utmp_entry (STRUCT_UTMP const *ut, int options)
{
# if defined __OpenBSD__ && !HAVE_UTMPX_H
/* Eliminate entirely empty entries. */
if (ut->ut_ts.tv_sec == 0 && ut->ut_user[0] == '\0'
&& ut->ut_line[0] == '\0' && ut->ut_host[0] == '\0')
return false;
# endif
bool boot_time = UT_TYPE_BOOT_TIME (ut);
if ((options & READ_UTMP_BOOT_TIME) && !boot_time)
return false;
if ((options & READ_UTMP_NO_BOOT_TIME) && boot_time)
return false;
bool user_proc = IS_USER_PROCESS (ut);
if ((options & READ_UTMP_USER_PROCESS) && !user_proc)
return false;
# if !(defined __CYGWIN__ || defined _WIN32)
if ((options & READ_UTMP_CHECK_PIDS)
&& user_proc
&& 0 < UT_PID (ut)
&& (kill (UT_PID (ut), 0) < 0 && errno == ESRCH))
return false;
# endif
return true;
}
/* A memory allocation for an in-progress read_utmp. */
struct utmp_alloc
{
/* A pointer to a possibly-empty array of utmp entries,
followed by a possibly-empty sequence of unused bytes,
followed by a possibly-empty sequence of string bytes.
UTMP is either null or allocated by malloc. */
struct gl_utmp *utmp;
/* The number of utmp entries. */
idx_t filled;
/* The string byte sequence length. Strings are null-terminated. */
idx_t string_bytes;
/* The total number of bytes allocated. This equals
FILLED * sizeof *UTMP + [size of free area] + STRING_BYTES. */
idx_t alloc_bytes;
};
/* Use the memory allocation A, and if the read_utmp options OPTIONS
permit it, add a new entry with the given USER, etc. Grow A as
needed, reporting an error and exit on memory allocation failure.
Return the resulting memory allocation. */
static struct utmp_alloc
add_utmp (struct utmp_alloc a, int options,
char const *user, idx_t user_len,
char const *id, idx_t id_len,
char const *line, idx_t line_len,
char const *host, idx_t host_len,
pid_t pid, short type, struct timespec ts, long session,
int termination, int exit)
{
int entry_bytes = sizeof (struct gl_utmp);
idx_t avail = a.alloc_bytes - (entry_bytes * a.filled + a.string_bytes);
idx_t needed_string_bytes =
(user_len + 1) + (id_len + 1) + (line_len + 1) + (host_len + 1);
idx_t needed = entry_bytes + needed_string_bytes;
if (avail < needed)
{
idx_t old_string_offset = a.alloc_bytes - a.string_bytes;
void *new = xpalloc (a.utmp, &a.alloc_bytes, needed - avail, -1, 1);
idx_t new_string_offset = a.alloc_bytes - a.string_bytes;
a.utmp = new;
char *q = new;
memmove (q + new_string_offset, q + old_string_offset, a.string_bytes);
}
struct gl_utmp *ut = &a.utmp[a.filled];
char *stringlim = (char *) a.utmp + a.alloc_bytes;
char *p = stringlim - a.string_bytes;
*--p = '\0'; /* NUL-terminate ut->ut_user */
ut->ut_user = p = memcpy (p - user_len, user, user_len);
*--p = '\0'; /* NUL-terminate ut->ut_id */
ut->ut_id = p = memcpy (p - id_len, id, id_len);
*--p = '\0'; /* NUL-terminate ut->ut_line */
ut->ut_line = p = memcpy (p - line_len, line, line_len);
*--p = '\0'; /* NUL-terminate ut->ut_host */
ut->ut_host = memcpy (p - host_len, host, host_len);
ut->ut_ts = ts;
ut->ut_pid = pid;
ut->ut_session = session;
ut->ut_type = type;
ut->ut_exit.e_termination = termination;
ut->ut_exit.e_exit = exit;
if (desirable_utmp_entry (ut, options))
{
/* Now that UT has been checked, relocate its string slots to be
relative to the end of the allocated storage, so that these
slots survive realloc. The slots will be relocated back just
before read_utmp returns. */
ut->ut_user = (char *) (intptr_t) (ut->ut_user - stringlim);
ut->ut_id = (char *) (intptr_t) (ut->ut_id - stringlim);
ut->ut_line = (char *) (intptr_t) (ut->ut_line - stringlim);
ut->ut_host = (char *) (intptr_t) (ut->ut_host - stringlim);
a.filled++;
a.string_bytes += needed_string_bytes;
}
return a;
}
/* Relocate the string pointers in A back to their natural position. */
static struct utmp_alloc
finish_utmp (struct utmp_alloc a)
{
char *stringlim = (char *) a.utmp + a.alloc_bytes;
for (idx_t i = 0; i < a.filled; i++)
{
a.utmp[i].ut_user = (intptr_t) a.utmp[i].ut_user + stringlim;
a.utmp[i].ut_id = (intptr_t) a.utmp[i].ut_id + stringlim;
a.utmp[i].ut_line = (intptr_t) a.utmp[i].ut_line + stringlim;
a.utmp[i].ut_host = (intptr_t) a.utmp[i].ut_host + stringlim;
}
return a;
}
/* Determine whether A already contains an entry of type BOOT_TIME. */
_GL_ATTRIBUTE_MAYBE_UNUSED
static bool
have_boot_time (struct utmp_alloc a)
{
for (idx_t i = 0; i < a.filled; i++)
{
struct gl_utmp *ut = &a.utmp[i];
if (UT_TYPE_BOOT_TIME (ut))
return true;
}
return false;
}
#if !HAVE_UTMPX_H && HAVE_UTMP_H && defined UTMP_NAME_FUNCTION
# if !HAVE_DECL_ENDUTENT /* Android */
void endutent (void);
# endif
#endif
static int
read_utmp_from_file (char const *file, idx_t *n_entries, STRUCT_UTMP **utmp_buf,
int options)
{
if ((options & READ_UTMP_BOOT_TIME) != 0
&& (options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) != 0)
{
/* No entries can match the given options. */
*n_entries = 0;
*utmp_buf = NULL;
return 0;
}
struct utmp_alloc a = {0};
# if READUTMP_USE_SYSTEMD || HAVE_UTMPX_H || HAVE_UTMP_H
# if defined UTMP_NAME_FUNCTION /* glibc, musl, macOS, FreeBSD, NetBSD, Minix, AIX, IRIX, Solaris, Cygwin, Android */
/* Ignore the return value for now.
Solaris' utmpname returns 1 upon success -- which is contrary
to what the GNU libc version does. In addition, older GNU libc
versions are actually void. */
UTMP_NAME_FUNCTION ((char *) file);
SET_UTMP_ENT ();
# if (defined __linux__ && !defined __ANDROID__) || defined __minix
bool file_is_utmp = (strcmp (file, UTMP_FILE) == 0);
/* Timestamp of the "runlevel" entry, if any. */
struct timespec runlevel_ts = {0};
# endif
void const *entry;
while ((entry = GET_UTMP_ENT ()) != NULL)
{
struct UTMP_STRUCT_NAME const *ut = (struct UTMP_STRUCT_NAME const *) entry;
struct timespec ts =
#if (HAVE_UTMPX_H ? 1 : HAVE_STRUCT_UTMP_UT_TV)
{ .tv_sec = ut->ut_tv.tv_sec, .tv_nsec = ut->ut_tv.tv_usec * 1000 };
#else
{ .tv_sec = ut->ut_time, .tv_nsec = 0 };
#endif
a = add_utmp (a, options,
UT_USER (ut), strnlen (UT_USER (ut), UT_USER_SIZE),
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_ID : HAVE_STRUCT_UTMP_UT_ID)
ut->ut_id, strnlen (ut->ut_id, UT_ID_SIZE),
#else
"", 0,
#endif
ut->ut_line, strnlen (ut->ut_line, UT_LINE_SIZE),
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_HOST : HAVE_STRUCT_UTMP_UT_HOST)
ut->ut_host, strnlen (ut->ut_host, UT_HOST_SIZE),
#else
"", 0,
#endif
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_PID : HAVE_STRUCT_UTMP_UT_PID)
ut->ut_pid,
#else
0,
#endif
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_TYPE : HAVE_STRUCT_UTMP_UT_TYPE)
ut->ut_type,
#else
0,
#endif
ts,
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_SESSION : HAVE_STRUCT_UTMP_UT_SESSION)
ut->ut_session,
#else
0,
#endif
UT_EXIT_E_TERMINATION (ut), UT_EXIT_E_EXIT (ut)
);
# if defined __linux__ && !defined __ANDROID__
if (file_is_utmp
&& memcmp (UT_USER (ut), "runlevel", strlen ("runlevel") + 1) == 0
&& memcmp (ut->ut_line, "~", strlen ("~") + 1) == 0)
runlevel_ts = ts;
# endif
# if defined __minix
if (file_is_utmp
&& UT_USER (ut)[0] == '\0'
&& memcmp (ut->ut_line, "run-level ", strlen ("run-level ")) == 0)
runlevel_ts = ts;
# endif
}
END_UTMP_ENT ();
# if defined __linux__ && !defined __ANDROID__
/* On Alpine Linux, UTMP_FILE is not filled. It is always empty.
So, fake a BOOT_TIME entry, by getting the time stamp of a file that
gets touched only during the boot process.
On Raspbian, which runs on hardware without a real-time clock, during boot,
1. the clock gets set to 1970-01-01 00:00:00,
2. an entry gets written into /var/run/utmp, with ut_type = BOOT_TIME,
ut_user = "reboot", ut_line = "~", time = 1970-01-01 00:00:05 or so,
3. the clock gets set to a correct value through NTP,
4. an entry gets written into /var/run/utmp, with
ut_user = "runlevel", ut_line = "~", time = correct value.
In this case, copy the time from the "runlevel" entry to the "reboot"
entry. */
if ((options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) == 0
&& file_is_utmp)
{
for (idx_t i = 0; i < a.filled; i++)
{
struct gl_utmp *ut = &a.utmp[i];
if (UT_TYPE_BOOT_TIME (ut))
{
/* Workaround for Raspbian: */
if (ut->ut_ts.tv_sec <= 60 && runlevel_ts.tv_sec != 0)
ut->ut_ts = runlevel_ts;
break;
}
}
if (!have_boot_time (a))
{
/* Workaround for Alpine Linux: */
struct timespec boot_time;
if (get_linux_boot_time_fallback (&boot_time) >= 0)
a = add_utmp (a, options,
"reboot", strlen ("reboot"),
"", 0,
"~", strlen ("~"),
"", 0,
0, BOOT_TIME, boot_time, 0, 0, 0);
}
}
# endif
# if defined __ANDROID__
/* On Android, there is no /var, and normal processes don't have access
to system files. Therefore use the kernel's uptime counter, although
it produces wrong values after the date has been bumped in the running
system. */
if ((options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) == 0
&& strcmp (file, UTMP_FILE) == 0
&& !have_boot_time (a))
{
struct timespec boot_time;
if (get_android_boot_time (&boot_time) >= 0)
a = add_utmp (a, options,
"reboot", strlen ("reboot"),
"", 0,
"", 0,
"", 0,
0, BOOT_TIME, boot_time, 0, 0, 0);
}
# endif
# if defined __minix
/* On Minix, during boot,
1. an entry gets written into /var/run/utmp, with ut_type = BOOT_TIME,
ut_user = "", ut_line = "system boot", time = 1970-01-01 00:00:00,
2. an entry gets written into /var/run/utmp, with
ut_user = "", ut_line = "run-level m", time = correct value.
In this case, copy the time from the "run-level m" entry to the
"system boot" entry. */
if ((options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) == 0
&& file_is_utmp)
{
for (idx_t i = 0; i < a.filled; i++)
{
struct gl_utmp *ut = &a.utmp[i];
if (UT_TYPE_BOOT_TIME (ut))
{
if (ut->ut_ts.tv_sec <= 60 && runlevel_ts.tv_sec != 0)
ut->ut_ts = runlevel_ts;
break;
}
}
}
# endif
# else /* old FreeBSD, OpenBSD, HP-UX, Haiku */
FILE *f = fopen (file, "re");
if (f != NULL)
{
for (;;)
{
struct UTMP_STRUCT_NAME ut;
if (fread (&ut, sizeof ut, 1, f) == 0)
break;
a = add_utmp (a, options,
UT_USER (&ut), strnlen (UT_USER (&ut), UT_USER_SIZE),
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_ID : HAVE_STRUCT_UTMP_UT_ID)
ut.ut_id, strnlen (ut.ut_id, UT_ID_SIZE),
#else
"", 0,
#endif
ut.ut_line, strnlen (ut.ut_line, UT_LINE_SIZE),
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_HOST : HAVE_STRUCT_UTMP_UT_HOST)
ut.ut_host, strnlen (ut.ut_host, UT_HOST_SIZE),
#else
"", 0,
#endif
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_PID : HAVE_STRUCT_UTMP_UT_PID)
ut.ut_pid,
#else
0,
#endif
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_TYPE : HAVE_STRUCT_UTMP_UT_TYPE)
ut.ut_type,
#else
0,
#endif
#if (HAVE_UTMPX_H ? 1 : HAVE_STRUCT_UTMP_UT_TV)
(struct timespec) { .tv_sec = ut.ut_tv.tv_sec, .tv_nsec = ut.ut_tv.tv_usec * 1000 },
#else
(struct timespec) { .tv_sec = ut.ut_time, .tv_nsec = 0 },
#endif
#if (HAVE_UTMPX_H ? HAVE_STRUCT_UTMPX_UT_SESSION : HAVE_STRUCT_UTMP_UT_SESSION)
ut.ut_session,
#else
0,
#endif
UT_EXIT_E_TERMINATION (&ut), UT_EXIT_E_EXIT (&ut)
);
}
int saved_errno = ferror (f) ? errno : 0;
if (fclose (f) != 0)
saved_errno = errno;
if (saved_errno != 0)
{
free (a.utmp);
errno = saved_errno;
return -1;
}
}
else
{
if (strcmp (file, UTMP_FILE) != 0)
{
int saved_errno = errno;
free (a.utmp);
errno = saved_errno;
return -1;
}
}
# if defined __OpenBSD__
if ((options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) == 0
&& strcmp (file, UTMP_FILE) == 0
&& !have_boot_time (a))
{
struct timespec boot_time;
if (get_openbsd_boot_time (&boot_time) >= 0)
a = add_utmp (a, options,
"reboot", strlen ("reboot"),
"", 0,
"", 0,
"", 0,
0, BOOT_TIME, boot_time, 0, 0, 0);
}
# endif
# endif
# if defined __linux__ && !defined __ANDROID__
if ((options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) == 0
&& strcmp (file, UTMP_FILE) == 0
&& !have_boot_time (a))
{
struct timespec boot_time;
if (get_linux_boot_time_final_fallback (&boot_time) >= 0)
a = add_utmp (a, options,
"reboot", strlen ("reboot"),
"", 0,
"~", strlen ("~"),
"", 0,
0, BOOT_TIME, boot_time, 0, 0, 0);
}
# endif
# if HAVE_SYS_SYSCTL_H && HAVE_SYSCTL \
&& defined CTL_KERN && defined KERN_BOOTTIME \
&& !defined __minix
if ((options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) == 0
&& strcmp (file, UTMP_FILE) == 0
&& !have_boot_time (a))
{
struct timespec boot_time;
if (get_bsd_boot_time_final_fallback (&boot_time) >= 0)
a = add_utmp (a, options,
"reboot", strlen ("reboot"),
"", 0,
"", 0,
"", 0,
0, BOOT_TIME, boot_time, 0, 0, 0);
}
# endif
# if defined __HAIKU__
if ((options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) == 0
&& strcmp (file, UTMP_FILE) == 0
&& !have_boot_time (a))
{
struct timespec boot_time;
if (get_haiku_boot_time (&boot_time) >= 0)
a = add_utmp (a, options,
"reboot", strlen ("reboot"),
"", 0,
"", 0,
"", 0,
0, BOOT_TIME, boot_time, 0, 0, 0);
}
# endif
# if HAVE_OS_H /* BeOS, Haiku */
if ((options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) == 0
&& strcmp (file, UTMP_FILE) == 0
&& !have_boot_time (a))
{
struct timespec boot_time;
if (get_haiku_boot_time_final_fallback (&boot_time) >= 0)
a = add_utmp (a, options,
"reboot", strlen ("reboot"),
"", 0,
"", 0,
"", 0,
0, BOOT_TIME, boot_time, 0, 0, 0);
}
# endif
# endif
# if defined __CYGWIN__ || defined _WIN32
if ((options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)) == 0
&& strcmp (file, UTMP_FILE) == 0
&& !have_boot_time (a))
{
struct timespec boot_time;
if (get_windows_boot_time (&boot_time) >= 0)
a = add_utmp (a, options,
"reboot", strlen ("reboot"),
"", 0,
"", 0,
"", 0,
0, BOOT_TIME, boot_time, 0, 0, 0);
}
# endif
a = finish_utmp (a);
*n_entries = a.filled;
*utmp_buf = a.utmp;
return 0;
}
# if READUTMP_USE_SYSTEMD
/* Use systemd and Linux /proc and kernel APIs. */
static struct timespec
get_boot_time_uncached (void)
{
/* Try to find the boot time in the /var/run/utmp file. */
{
idx_t n_entries = 0;
STRUCT_UTMP *utmp = NULL;
read_utmp_from_file (UTMP_FILE, &n_entries, &utmp, READ_UTMP_BOOT_TIME);
if (n_entries > 0)
{
struct timespec result = utmp[0].ut_ts;
free (utmp);
return result;
}
free (utmp);
}
/* We shouldn't get here. */
return (struct timespec) {0};
}
static struct timespec
get_boot_time (void)
{
static bool volatile cached;
static struct timespec volatile boot_time;
if (!cached)
{
boot_time = get_boot_time_uncached ();
cached = true;
}
return boot_time;
}
/* Guess the pty name that was opened for the given user right after
the given time AT. */
static char *
guess_pty_name (uid_t uid, const struct timespec at)
{
/* Traverse the entries of the /dev/pts/ directory, looking for devices
which are owned by UID and whose ctime is shortly after AT. */
DIR *dirp = opendir ("/dev/pts");
if (dirp != NULL)
{
/* Buffer containing /dev/pts/N. */
char name_buf[9 + 10 + 1];
memcpy (name_buf, "/dev/pts/", 9);
char best_name[9 + 10 + 1];
struct timespec best_time = { .tv_sec = 0, .tv_nsec = 0 };
for (;;)
{
struct dirent *dp = readdir (dirp);
if (dp == NULL)
break;
if (dp->d_name[0] != '.' && strlen (dp->d_name) <= 10)
{
/* Compose the absolute file name /dev/pts/N. */
strcpy (name_buf + 9, dp->d_name);
/* Find its owner and ctime. */
struct stat st;
if (stat (name_buf, &st) >= 0
&& st.st_uid == uid
&& (st.st_ctim.tv_sec > at.tv_sec
|| (st.st_ctim.tv_sec == at.tv_sec
&& st.st_ctim.tv_nsec >= at.tv_nsec)))
{
/* This entry has the owner UID and a ctime >= AT. */
/* Is this entry the best one so far? */
if ((best_time.tv_sec == 0 && best_time.tv_nsec == 0)
|| (st.st_ctim.tv_sec < best_time.tv_sec
|| (st.st_ctim.tv_sec == best_time.tv_sec
&& st.st_ctim.tv_nsec < best_time.tv_nsec)))
{
strcpy (best_name, name_buf);
best_time = st.st_ctim;
}
}
}
}
closedir (dirp);
/* Did we find an entry owned by ID, and is it at most 5 seconds
after AT? */
if (!(best_time.tv_sec == 0 && best_time.tv_nsec == 0)
&& (best_time.tv_sec < at.tv_sec + 5
|| (best_time.tv_sec == at.tv_sec + 5
&& best_time.tv_nsec <= at.tv_nsec)))
return xstrdup (best_name + 5);
}
return NULL;
}
static int
read_utmp_from_systemd (idx_t *n_entries, STRUCT_UTMP **utmp_buf, int options)
{
/* Fill entries, simulating what a utmp file would contain. */
struct utmp_alloc a = {0};
/* Synthesize a BOOT_TIME entry. */
if (!(options & (READ_UTMP_USER_PROCESS | READ_UTMP_NO_BOOT_TIME)))
a = add_utmp (a, options,
"reboot", strlen ("reboot"),
"", 0,
"~", strlen ("~"),
"", 0,
0, BOOT_TIME, get_boot_time (), 0, 0, 0);
/* Synthesize USER_PROCESS entries. */
if (!(options & READ_UTMP_BOOT_TIME))
{
char **sessions;
int num_sessions = sd_get_sessions (&sessions);
if (num_sessions >= 0)
{
char **session_ptr;
for (session_ptr = sessions; *session_ptr != NULL; session_ptr++)
{
char *session = *session_ptr;
uint64_t start_usec;
if (sd_session_get_start_time (session, &start_usec) < 0)
start_usec = 0;
struct timespec start_ts;
start_ts.tv_sec = start_usec / 1000000;
start_ts.tv_nsec = start_usec % 1000000 * 1000;
char *seat;
if (sd_session_get_seat (session, &seat) < 0)
seat = NULL;
char missing[] = "";
char *type = NULL;
char *tty;
if (sd_session_get_tty (session, &tty) < 0)
{
tty = NULL;
/* Try harder to get a sensible value for the tty. */
if (sd_session_get_type (session, &type) < 0)
type = missing;
if (strcmp (type, "tty") == 0)
{
char *service;
if (sd_session_get_service (session, &service) < 0)
service = NULL;
uid_t uid;
char *pty = (sd_session_get_uid (session, &uid) < 0 ? NULL
: guess_pty_name (uid, start_ts));
if (service != NULL && pty != NULL)
{
tty = xmalloc (strlen (service) + 1 + strlen (pty) + 1);
stpcpy (stpcpy (stpcpy (tty, service), " "), pty);
free (pty);
free (service);
}
else if (service != NULL)
tty = service;
else if (pty != NULL)
tty = pty;
}
}
/* Create up to two USER_PROCESS entries: one for the seat,
one for the tty. */
if (seat != NULL || tty != NULL)
{
char *user;
if (sd_session_get_username (session, &user) < 0)
user = missing;
pid_t leader_pid;
if (sd_session_get_leader (session, &leader_pid) < 0)
leader_pid = 0;
char *host;
char *remote_host;
if (sd_session_get_remote_host (session, &remote_host) < 0)
{
host = missing;
/* For backward compatibility, put the X11 display into the
host field. */
if (!type && sd_session_get_type (session, &type) < 0)
type = missing;
if (strcmp (type, "x11") == 0)
{
char *display;
if (sd_session_get_display (session, &display) < 0)
display = NULL;
host = display;
}
}
else
{
char *remote_user;
if (sd_session_get_remote_user (session, &remote_user) < 0)
host = remote_host;
else
{
host = xmalloc (strlen (remote_user) + 1
+ strlen (remote_host) + 1);
stpcpy (stpcpy (stpcpy (host, remote_user), "@"),
remote_host);
free (remote_user);
free (remote_host);
}
}
if (seat != NULL)
a = add_utmp (a, options,
user, strlen (user),
session, strlen (session),
seat, strlen (seat),
host, strlen (host),
leader_pid /* the best we have */,
USER_PROCESS, start_ts, leader_pid, 0, 0);
if (tty != NULL)
a = add_utmp (a, options,
user, strlen (user),
session, strlen (session),
tty, strlen (tty),
host, strlen (host),
leader_pid /* the best we have */,
USER_PROCESS, start_ts, leader_pid, 0, 0);
if (host != missing)
free (host);
if (user != missing)
free (user);
}
if (type != missing)
free (type);
free (tty);
free (seat);
free (session);
}
free (sessions);
}
}
a = finish_utmp (a);
*n_entries = a.filled;
*utmp_buf = a.utmp;
return 0;
}
# endif
int
read_utmp (char const *file, idx_t *n_entries, STRUCT_UTMP **utmp_buf,
int options)
{
# if READUTMP_USE_SYSTEMD
if (strcmp (file, UTMP_FILE) == 0)
/* Imitate reading UTMP_FILE, using systemd and Linux APIs. */
return read_utmp_from_systemd (n_entries, utmp_buf, options);
# endif
return read_utmp_from_file (file, n_entries, utmp_buf, options);
}
#else /* dummy fallback */
int
read_utmp (char const *file, idx_t *n_entries, STRUCT_UTMP **utmp_buf,
int options)
{
errno = ENOSYS;
return -1;
}
#endif