blob: 3c54ac1110ad71375bb6c85121160b5c605decf2 [file] [log] [blame] [raw]
/* SPDX-License-Identifier: LGPL-2.1+ */
#include <errno.h>
#include <fcntl.h>
#include <glob.h>
#include <grp.h>
#include <poll.h>
#include <signal.h>
#include <string.h>
#include <sys/capability.h>
#include <sys/eventfd.h>
#include <sys/mman.h>
#include <sys/personality.h>
#include <sys/prctl.h>
#include <sys/shm.h>
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <sys/un.h>
#include <unistd.h>
#include <utmpx.h>
#if HAVE_PAM
#include <security/pam_appl.h>
#endif
#if HAVE_SELINUX
#include <selinux/selinux.h>
#endif
#if HAVE_SECCOMP
#include <seccomp.h>
#endif
#if HAVE_APPARMOR
#include <sys/apparmor.h>
#endif
#include "sd-messages.h"
#include "af-list.h"
#include "alloc-util.h"
#if HAVE_APPARMOR
#include "apparmor-util.h"
#endif
#include "async.h"
#include "barrier.h"
#include "cap-list.h"
#include "capability-util.h"
#include "chown-recursive.h"
#include "cpu-set-util.h"
#include "def.h"
#include "env-util.h"
#include "errno-list.h"
#include "execute.h"
#include "exit-status.h"
#include "fd-util.h"
#include "fileio.h"
#include "format-util.h"
#include "fs-util.h"
#include "glob-util.h"
#include "io-util.h"
#include "ioprio.h"
#include "label.h"
#include "log.h"
#include "macro.h"
#include "manager.h"
#include "missing.h"
#include "mkdir.h"
#include "namespace.h"
#include "parse-util.h"
#include "path-util.h"
#include "process-util.h"
#include "rlimit-util.h"
#include "rm-rf.h"
#if HAVE_SECCOMP
#include "seccomp-util.h"
#endif
#include "securebits.h"
#include "securebits-util.h"
#include "selinux-util.h"
#include "signal-util.h"
#include "smack-util.h"
#include "socket-util.h"
#include "special.h"
#include "stat-util.h"
#include "string-table.h"
#include "string-util.h"
#include "strv.h"
#include "syslog-util.h"
#include "terminal-util.h"
#include "umask-util.h"
#include "unit.h"
#include "user-util.h"
#include "util.h"
#include "utmp-wtmp.h"
#define IDLE_TIMEOUT_USEC (5*USEC_PER_SEC)
#define IDLE_TIMEOUT2_USEC (1*USEC_PER_SEC)
/* This assumes there is a 'tty' group */
#define TTY_MODE 0620
#define SNDBUF_SIZE (8*1024*1024)
static int shift_fds(int fds[], size_t n_fds) {
int start, restart_from;
if (n_fds <= 0)
return 0;
/* Modifies the fds array! (sorts it) */
assert(fds);
start = 0;
for (;;) {
int i;
restart_from = -1;
for (i = start; i < (int) n_fds; i++) {
int nfd;
/* Already at right index? */
if (fds[i] == i+3)
continue;
nfd = fcntl(fds[i], F_DUPFD, i + 3);
if (nfd < 0)
return -errno;
safe_close(fds[i]);
fds[i] = nfd;
/* Hmm, the fd we wanted isn't free? Then
* let's remember that and try again from here */
if (nfd != i+3 && restart_from < 0)
restart_from = i;
}
if (restart_from < 0)
break;
start = restart_from;
}
return 0;
}
static int flags_fds(const int fds[], size_t n_socket_fds, size_t n_storage_fds, bool nonblock) {
size_t i, n_fds;
int r;
n_fds = n_socket_fds + n_storage_fds;
if (n_fds <= 0)
return 0;
assert(fds);
/* Drops/Sets O_NONBLOCK and FD_CLOEXEC from the file flags.
* O_NONBLOCK only applies to socket activation though. */
for (i = 0; i < n_fds; i++) {
if (i < n_socket_fds) {
r = fd_nonblock(fds[i], nonblock);
if (r < 0)
return r;
}
/* We unconditionally drop FD_CLOEXEC from the fds,
* since after all we want to pass these fds to our
* children */
r = fd_cloexec(fds[i], false);
if (r < 0)
return r;
}
return 0;
}
static const char *exec_context_tty_path(const ExecContext *context) {
assert(context);
if (context->stdio_as_fds)
return NULL;
if (context->tty_path)
return context->tty_path;
return "/dev/console";
}
static void exec_context_tty_reset(const ExecContext *context, const ExecParameters *p) {
const char *path;
assert(context);
path = exec_context_tty_path(context);
if (context->tty_vhangup) {
if (p && p->stdin_fd >= 0)
(void) terminal_vhangup_fd(p->stdin_fd);
else if (path)
(void) terminal_vhangup(path);
}
if (context->tty_reset) {
if (p && p->stdin_fd >= 0)
(void) reset_terminal_fd(p->stdin_fd, true);
else if (path)
(void) reset_terminal(path);
}
if (context->tty_vt_disallocate && path)
(void) vt_disallocate(path);
}
static bool is_terminal_input(ExecInput i) {
return IN_SET(i,
EXEC_INPUT_TTY,
EXEC_INPUT_TTY_FORCE,
EXEC_INPUT_TTY_FAIL);
}
static bool is_terminal_output(ExecOutput o) {
return IN_SET(o,
EXEC_OUTPUT_TTY,
EXEC_OUTPUT_SYSLOG_AND_CONSOLE,
EXEC_OUTPUT_KMSG_AND_CONSOLE,
EXEC_OUTPUT_JOURNAL_AND_CONSOLE);
}
static bool is_syslog_output(ExecOutput o) {
return IN_SET(o,
EXEC_OUTPUT_SYSLOG,
EXEC_OUTPUT_SYSLOG_AND_CONSOLE);
}
static bool is_kmsg_output(ExecOutput o) {
return IN_SET(o,
EXEC_OUTPUT_KMSG,
EXEC_OUTPUT_KMSG_AND_CONSOLE);
}
static bool exec_context_needs_term(const ExecContext *c) {
assert(c);
/* Return true if the execution context suggests we should set $TERM to something useful. */
if (is_terminal_input(c->std_input))
return true;
if (is_terminal_output(c->std_output))
return true;
if (is_terminal_output(c->std_error))
return true;
return !!c->tty_path;
}
static int open_null_as(int flags, int nfd) {
int fd;
assert(nfd >= 0);
fd = open("/dev/null", flags|O_NOCTTY);
if (fd < 0)
return -errno;
return move_fd(fd, nfd, false);
}
static int connect_journal_socket(int fd, uid_t uid, gid_t gid) {
static const union sockaddr_union sa = {
.un.sun_family = AF_UNIX,
.un.sun_path = "/run/systemd/journal/stdout",
};
uid_t olduid = UID_INVALID;
gid_t oldgid = GID_INVALID;
int r;
if (gid_is_valid(gid)) {
oldgid = getgid();
if (setegid(gid) < 0)
return -errno;
}
if (uid_is_valid(uid)) {
olduid = getuid();
if (seteuid(uid) < 0) {
r = -errno;
goto restore_gid;
}
}
r = connect(fd, &sa.sa, SOCKADDR_UN_LEN(sa.un)) < 0 ? -errno : 0;
/* If we fail to restore the uid or gid, things will likely
fail later on. This should only happen if an LSM interferes. */
if (uid_is_valid(uid))
(void) seteuid(olduid);
restore_gid:
if (gid_is_valid(gid))
(void) setegid(oldgid);
return r;
}
static int connect_logger_as(
const Unit *unit,
const ExecContext *context,
const ExecParameters *params,
ExecOutput output,
const char *ident,
int nfd,
uid_t uid,
gid_t gid) {
int fd, r;
assert(context);
assert(params);
assert(output < _EXEC_OUTPUT_MAX);
assert(ident);
assert(nfd >= 0);
fd = socket(AF_UNIX, SOCK_STREAM, 0);
if (fd < 0)
return -errno;
r = connect_journal_socket(fd, uid, gid);
if (r < 0)
return r;
if (shutdown(fd, SHUT_RD) < 0) {
safe_close(fd);
return -errno;
}
(void) fd_inc_sndbuf(fd, SNDBUF_SIZE);
dprintf(fd,
"%s\n"
"%s\n"
"%i\n"
"%i\n"
"%i\n"
"%i\n"
"%i\n",
context->syslog_identifier ?: ident,
params->flags & EXEC_PASS_LOG_UNIT ? unit->id : "",
context->syslog_priority,
!!context->syslog_level_prefix,
is_syslog_output(output),
is_kmsg_output(output),
is_terminal_output(output));
return move_fd(fd, nfd, false);
}
static int open_terminal_as(const char *path, int flags, int nfd) {
int fd;
assert(path);
assert(nfd >= 0);
fd = open_terminal(path, flags | O_NOCTTY);
if (fd < 0)
return fd;
return move_fd(fd, nfd, false);
}
static int acquire_path(const char *path, int flags, mode_t mode) {
union sockaddr_union sa = {
.sa.sa_family = AF_UNIX,
};
int fd, r;
assert(path);
if (IN_SET(flags & O_ACCMODE, O_WRONLY, O_RDWR))
flags |= O_CREAT;
fd = open(path, flags|O_NOCTTY, mode);
if (fd >= 0)
return fd;
if (errno != ENXIO) /* ENXIO is returned when we try to open() an AF_UNIX file system socket on Linux */
return -errno;
if (strlen(path) > sizeof(sa.un.sun_path)) /* Too long, can't be a UNIX socket */
return -ENXIO;
/* So, it appears the specified path could be an AF_UNIX socket. Let's see if we can connect to it. */
fd = socket(AF_UNIX, SOCK_STREAM, 0);
if (fd < 0)
return -errno;
strncpy(sa.un.sun_path, path, sizeof(sa.un.sun_path));
if (connect(fd, &sa.sa, SOCKADDR_UN_LEN(sa.un)) < 0) {
safe_close(fd);
return errno == EINVAL ? -ENXIO : -errno; /* Propagate initial error if we get EINVAL, i.e. we have
* indication that his wasn't an AF_UNIX socket after all */
}
if ((flags & O_ACCMODE) == O_RDONLY)
r = shutdown(fd, SHUT_WR);
else if ((flags & O_ACCMODE) == O_WRONLY)
r = shutdown(fd, SHUT_RD);
else
return fd;
if (r < 0) {
safe_close(fd);
return -errno;
}
return fd;
}
static int fixup_input(
const ExecContext *context,
int socket_fd,
bool apply_tty_stdin) {
ExecInput std_input;
assert(context);
std_input = context->std_input;
if (is_terminal_input(std_input) && !apply_tty_stdin)
return EXEC_INPUT_NULL;
if (std_input == EXEC_INPUT_SOCKET && socket_fd < 0)
return EXEC_INPUT_NULL;
if (std_input == EXEC_INPUT_DATA && context->stdin_data_size == 0)
return EXEC_INPUT_NULL;
return std_input;
}
static int fixup_output(ExecOutput std_output, int socket_fd) {
if (std_output == EXEC_OUTPUT_SOCKET && socket_fd < 0)
return EXEC_OUTPUT_INHERIT;
return std_output;
}
static int setup_input(
const ExecContext *context,
const ExecParameters *params,
int socket_fd,
int named_iofds[3]) {
ExecInput i;
assert(context);
assert(params);
if (params->stdin_fd >= 0) {
if (dup2(params->stdin_fd, STDIN_FILENO) < 0)
return -errno;
/* Try to make this the controlling tty, if it is a tty, and reset it */
if (isatty(STDIN_FILENO)) {
(void) ioctl(STDIN_FILENO, TIOCSCTTY, context->std_input == EXEC_INPUT_TTY_FORCE);
(void) reset_terminal_fd(STDIN_FILENO, true);
}
return STDIN_FILENO;
}
i = fixup_input(context, socket_fd, params->flags & EXEC_APPLY_TTY_STDIN);
switch (i) {
case EXEC_INPUT_NULL:
return open_null_as(O_RDONLY, STDIN_FILENO);
case EXEC_INPUT_TTY:
case EXEC_INPUT_TTY_FORCE:
case EXEC_INPUT_TTY_FAIL: {
int fd;
fd = acquire_terminal(exec_context_tty_path(context),
i == EXEC_INPUT_TTY_FAIL ? ACQUIRE_TERMINAL_TRY :
i == EXEC_INPUT_TTY_FORCE ? ACQUIRE_TERMINAL_FORCE :
ACQUIRE_TERMINAL_WAIT,
USEC_INFINITY);
if (fd < 0)
return fd;
return move_fd(fd, STDIN_FILENO, false);
}
case EXEC_INPUT_SOCKET:
assert(socket_fd >= 0);
return dup2(socket_fd, STDIN_FILENO) < 0 ? -errno : STDIN_FILENO;
case EXEC_INPUT_NAMED_FD:
assert(named_iofds[STDIN_FILENO] >= 0);
(void) fd_nonblock(named_iofds[STDIN_FILENO], false);
return dup2(named_iofds[STDIN_FILENO], STDIN_FILENO) < 0 ? -errno : STDIN_FILENO;
case EXEC_INPUT_DATA: {
int fd;
fd = acquire_data_fd(context->stdin_data, context->stdin_data_size, 0);
if (fd < 0)
return fd;
return move_fd(fd, STDIN_FILENO, false);
}
case EXEC_INPUT_FILE: {
bool rw;
int fd;
assert(context->stdio_file[STDIN_FILENO]);
rw = (context->std_output == EXEC_OUTPUT_FILE && streq_ptr(context->stdio_file[STDIN_FILENO], context->stdio_file[STDOUT_FILENO])) ||
(context->std_error == EXEC_OUTPUT_FILE && streq_ptr(context->stdio_file[STDIN_FILENO], context->stdio_file[STDERR_FILENO]));
fd = acquire_path(context->stdio_file[STDIN_FILENO], rw ? O_RDWR : O_RDONLY, 0666 & ~context->umask);
if (fd < 0)
return fd;
return move_fd(fd, STDIN_FILENO, false);
}
default:
assert_not_reached("Unknown input type");
}
}
static int setup_output(
const Unit *unit,
const ExecContext *context,
const ExecParameters *params,
int fileno,
int socket_fd,
int named_iofds[3],
const char *ident,
uid_t uid,
gid_t gid,
dev_t *journal_stream_dev,
ino_t *journal_stream_ino) {
ExecOutput o;
ExecInput i;
int r;
assert(unit);
assert(context);
assert(params);
assert(ident);
assert(journal_stream_dev);
assert(journal_stream_ino);
if (fileno == STDOUT_FILENO && params->stdout_fd >= 0) {
if (dup2(params->stdout_fd, STDOUT_FILENO) < 0)
return -errno;
return STDOUT_FILENO;
}
if (fileno == STDERR_FILENO && params->stderr_fd >= 0) {
if (dup2(params->stderr_fd, STDERR_FILENO) < 0)
return -errno;
return STDERR_FILENO;
}
i = fixup_input(context, socket_fd, params->flags & EXEC_APPLY_TTY_STDIN);
o = fixup_output(context->std_output, socket_fd);
if (fileno == STDERR_FILENO) {
ExecOutput e;
e = fixup_output(context->std_error, socket_fd);
/* This expects the input and output are already set up */
/* Don't change the stderr file descriptor if we inherit all
* the way and are not on a tty */
if (e == EXEC_OUTPUT_INHERIT &&
o == EXEC_OUTPUT_INHERIT &&
i == EXEC_INPUT_NULL &&
!is_terminal_input(context->std_input) &&
getppid () != 1)
return fileno;
/* Duplicate from stdout if possible */
if ((e == o && e != EXEC_OUTPUT_NAMED_FD) || e == EXEC_OUTPUT_INHERIT)
return dup2(STDOUT_FILENO, fileno) < 0 ? -errno : fileno;
o = e;
} else if (o == EXEC_OUTPUT_INHERIT) {
/* If input got downgraded, inherit the original value */
if (i == EXEC_INPUT_NULL && is_terminal_input(context->std_input))
return open_terminal_as(exec_context_tty_path(context), O_WRONLY, fileno);
/* If the input is connected to anything that's not a /dev/null or a data fd, inherit that... */
if (!IN_SET(i, EXEC_INPUT_NULL, EXEC_INPUT_DATA))
return dup2(STDIN_FILENO, fileno) < 0 ? -errno : fileno;
/* If we are not started from PID 1 we just inherit STDOUT from our parent process. */
if (getppid() != 1)
return fileno;
/* We need to open /dev/null here anew, to get the right access mode. */
return open_null_as(O_WRONLY, fileno);
}
switch (o) {
case EXEC_OUTPUT_NULL:
return open_null_as(O_WRONLY, fileno);
case EXEC_OUTPUT_TTY:
if (is_terminal_input(i))
return dup2(STDIN_FILENO, fileno) < 0 ? -errno : fileno;
/* We don't reset the terminal if this is just about output */
return open_terminal_as(exec_context_tty_path(context), O_WRONLY, fileno);
case EXEC_OUTPUT_SYSLOG:
case EXEC_OUTPUT_SYSLOG_AND_CONSOLE:
case EXEC_OUTPUT_KMSG:
case EXEC_OUTPUT_KMSG_AND_CONSOLE:
case EXEC_OUTPUT_JOURNAL:
case EXEC_OUTPUT_JOURNAL_AND_CONSOLE:
r = connect_logger_as(unit, context, params, o, ident, fileno, uid, gid);
if (r < 0) {
log_unit_warning_errno(unit, r, "Failed to connect %s to the journal socket, ignoring: %m", fileno == STDOUT_FILENO ? "stdout" : "stderr");
r = open_null_as(O_WRONLY, fileno);
} else {
struct stat st;
/* If we connected this fd to the journal via a stream, patch the device/inode into the passed
* parameters, but only then. This is useful so that we can set $JOURNAL_STREAM that permits
* services to detect whether they are connected to the journal or not.
*
* If both stdout and stderr are connected to a stream then let's make sure to store the data
* about STDERR as that's usually the best way to do logging. */
if (fstat(fileno, &st) >= 0 &&
(*journal_stream_ino == 0 || fileno == STDERR_FILENO)) {
*journal_stream_dev = st.st_dev;
*journal_stream_ino = st.st_ino;
}
}
return r;
case EXEC_OUTPUT_SOCKET:
assert(socket_fd >= 0);
return dup2(socket_fd, fileno) < 0 ? -errno : fileno;
case EXEC_OUTPUT_NAMED_FD:
assert(named_iofds[fileno] >= 0);
(void) fd_nonblock(named_iofds[fileno], false);
return dup2(named_iofds[fileno], fileno) < 0 ? -errno : fileno;
case EXEC_OUTPUT_FILE:
case EXEC_OUTPUT_FILE_APPEND: {
bool rw;
int fd, flags;
assert(context->stdio_file[fileno]);
rw = context->std_input == EXEC_INPUT_FILE &&
streq_ptr(context->stdio_file[fileno], context->stdio_file[STDIN_FILENO]);
if (rw)
return dup2(STDIN_FILENO, fileno) < 0 ? -errno : fileno;
flags = O_WRONLY;
if (o == EXEC_OUTPUT_FILE_APPEND)
flags |= O_APPEND;
fd = acquire_path(context->stdio_file[fileno], flags, 0666 & ~context->umask);
if (fd < 0)
return fd;
return move_fd(fd, fileno, 0);
}
default:
assert_not_reached("Unknown error type");
}
}
static int chown_terminal(int fd, uid_t uid) {
struct stat st;
assert(fd >= 0);
/* Before we chown/chmod the TTY, let's ensure this is actually a tty */
if (isatty(fd) < 1)
return 0;
/* This might fail. What matters are the results. */
(void) fchown(fd, uid, -1);
(void) fchmod(fd, TTY_MODE);
if (fstat(fd, &st) < 0)
return -errno;
if (st.st_uid != uid || (st.st_mode & 0777) != TTY_MODE)
return -EPERM;
return 0;
}
static int setup_confirm_stdio(const char *vc, int *_saved_stdin, int *_saved_stdout) {
_cleanup_close_ int fd = -1, saved_stdin = -1, saved_stdout = -1;
int r;
assert(_saved_stdin);
assert(_saved_stdout);
saved_stdin = fcntl(STDIN_FILENO, F_DUPFD, 3);
if (saved_stdin < 0)
return -errno;
saved_stdout = fcntl(STDOUT_FILENO, F_DUPFD, 3);
if (saved_stdout < 0)
return -errno;
fd = acquire_terminal(vc, ACQUIRE_TERMINAL_WAIT, DEFAULT_CONFIRM_USEC);
if (fd < 0)
return fd;
r = chown_terminal(fd, getuid());
if (r < 0)
return r;
r = reset_terminal_fd(fd, true);
if (r < 0)
return r;
r = rearrange_stdio(fd, fd, STDERR_FILENO);
fd = -1;
if (r < 0)
return r;
*_saved_stdin = saved_stdin;
*_saved_stdout = saved_stdout;
saved_stdin = saved_stdout = -1;
return 0;
}
static void write_confirm_error_fd(int err, int fd, const Unit *u) {
assert(err < 0);
if (err == -ETIMEDOUT)
dprintf(fd, "Confirmation question timed out for %s, assuming positive response.\n", u->id);
else {
errno = -err;
dprintf(fd, "Couldn't ask confirmation for %s: %m, assuming positive response.\n", u->id);
}
}
static void write_confirm_error(int err, const char *vc, const Unit *u) {
_cleanup_close_ int fd = -1;
assert(vc);
fd = open_terminal(vc, O_WRONLY|O_NOCTTY|O_CLOEXEC);
if (fd < 0)
return;
write_confirm_error_fd(err, fd, u);
}
static int restore_confirm_stdio(int *saved_stdin, int *saved_stdout) {
int r = 0;
assert(saved_stdin);
assert(saved_stdout);
release_terminal();
if (*saved_stdin >= 0)
if (dup2(*saved_stdin, STDIN_FILENO) < 0)
r = -errno;
if (*saved_stdout >= 0)
if (dup2(*saved_stdout, STDOUT_FILENO) < 0)
r = -errno;
*saved_stdin = safe_close(*saved_stdin);
*saved_stdout = safe_close(*saved_stdout);
return r;
}
enum {
CONFIRM_PRETEND_FAILURE = -1,
CONFIRM_PRETEND_SUCCESS = 0,
CONFIRM_EXECUTE = 1,
};
static int ask_for_confirmation(const char *vc, Unit *u, const char *cmdline) {
int saved_stdout = -1, saved_stdin = -1, r;
_cleanup_free_ char *e = NULL;
char c;
/* For any internal errors, assume a positive response. */
r = setup_confirm_stdio(vc, &saved_stdin, &saved_stdout);
if (r < 0) {
write_confirm_error(r, vc, u);
return CONFIRM_EXECUTE;
}
/* confirm_spawn might have been disabled while we were sleeping. */
if (manager_is_confirm_spawn_disabled(u->manager)) {
r = 1;
goto restore_stdio;
}
e = ellipsize(cmdline, 60, 100);
if (!e) {
log_oom();
r = CONFIRM_EXECUTE;
goto restore_stdio;
}
for (;;) {
r = ask_char(&c, "yfshiDjcn", "Execute %s? [y, f, s – h for help] ", e);
if (r < 0) {
write_confirm_error_fd(r, STDOUT_FILENO, u);
r = CONFIRM_EXECUTE;
goto restore_stdio;
}
switch (c) {
case 'c':
printf("Resuming normal execution.\n");
manager_disable_confirm_spawn();
r = 1;
break;
case 'D':
unit_dump(u, stdout, " ");
continue; /* ask again */
case 'f':
printf("Failing execution.\n");
r = CONFIRM_PRETEND_FAILURE;
break;
case 'h':
printf(" c - continue, proceed without asking anymore\n"
" D - dump, show the state of the unit\n"
" f - fail, don't execute the command and pretend it failed\n"
" h - help\n"
" i - info, show a short summary of the unit\n"
" j - jobs, show jobs that are in progress\n"
" s - skip, don't execute the command and pretend it succeeded\n"
" y - yes, execute the command\n");
continue; /* ask again */
case 'i':
printf(" Description: %s\n"
" Unit: %s\n"
" Command: %s\n",
u->id, u->description, cmdline);
continue; /* ask again */
case 'j':
manager_dump_jobs(u->manager, stdout, " ");
continue; /* ask again */
case 'n':
/* 'n' was removed in favor of 'f'. */
printf("Didn't understand 'n', did you mean 'f'?\n");
continue; /* ask again */
case 's':
printf("Skipping execution.\n");
r = CONFIRM_PRETEND_SUCCESS;
break;
case 'y':
r = CONFIRM_EXECUTE;
break;
default:
assert_not_reached("Unhandled choice");
}
break;
}
restore_stdio:
restore_confirm_stdio(&saved_stdin, &saved_stdout);
return r;
}
static int get_fixed_user(const ExecContext *c, const char **user,
uid_t *uid, gid_t *gid,
const char **home, const char **shell) {
int r;
const char *name;
assert(c);
if (!c->user)
return 0;
/* Note that we don't set $HOME or $SHELL if they are not particularly enlightening anyway
* (i.e. are "/" or "/bin/nologin"). */
name = c->user;
r = get_user_creds_clean(&name, uid, gid, home, shell);
if (r < 0)
return r;
*user = name;
return 0;
}
static int get_fixed_group(const ExecContext *c, const char **group, gid_t *gid) {
int r;
const char *name;
assert(c);
if (!c->group)
return 0;
name = c->group;
r = get_group_creds(&name, gid);
if (r < 0)
return r;
*group = name;
return 0;
}
static int get_supplementary_groups(const ExecContext *c, const char *user,
const char *group, gid_t gid,
gid_t **supplementary_gids, int *ngids) {
char **i;
int r, k = 0;
int ngroups_max;
bool keep_groups = false;
gid_t *groups = NULL;
_cleanup_free_ gid_t *l_gids = NULL;
assert(c);
/*
* If user is given, then lookup GID and supplementary groups list.
* We avoid NSS lookups for gid=0. Also we have to initialize groups
* here and as early as possible so we keep the list of supplementary
* groups of the caller.
*/
if (user && gid_is_valid(gid) && gid != 0) {
/* First step, initialize groups from /etc/groups */
if (initgroups(user, gid) < 0)
return -errno;
keep_groups = true;
}
if (strv_isempty(c->supplementary_groups))
return 0;
/*
* If SupplementaryGroups= was passed then NGROUPS_MAX has to
* be positive, otherwise fail.
*/
errno = 0;
ngroups_max = (int) sysconf(_SC_NGROUPS_MAX);
if (ngroups_max <= 0) {
if (errno > 0)
return -errno;
else
return -EOPNOTSUPP; /* For all other values */
}
l_gids = new(gid_t, ngroups_max);
if (!l_gids)
return -ENOMEM;
if (keep_groups) {
/*
* Lookup the list of groups that the user belongs to, we
* avoid NSS lookups here too for gid=0.
*/
k = ngroups_max;
if (getgrouplist(user, gid, l_gids, &k) < 0)
return -EINVAL;
} else
k = 0;
STRV_FOREACH(i, c->supplementary_groups) {
const char *g;
if (k >= ngroups_max)
return -E2BIG;
g = *i;
r = get_group_creds(&g, l_gids+k);
if (r < 0)
return r;
k++;
}
/*
* Sets ngids to zero to drop all supplementary groups, happens
* when we are under root and SupplementaryGroups= is empty.
*/
if (k == 0) {
*ngids = 0;
return 0;
}
/* Otherwise get the final list of supplementary groups */
groups = memdup(l_gids, sizeof(gid_t) * k);
if (!groups)
return -ENOMEM;
*supplementary_gids = groups;
*ngids = k;
groups = NULL;
return 0;
}
static int enforce_groups(gid_t gid, const gid_t *supplementary_gids, int ngids) {
int r;
/* Handle SupplementaryGroups= if it is not empty */
if (ngids > 0) {
r = maybe_setgroups(ngids, supplementary_gids);
if (r < 0)
return r;
}
if (gid_is_valid(gid)) {
/* Then set our gids */
if (setresgid(gid, gid, gid) < 0)
return -errno;
}
return 0;
}
static int enforce_user(const ExecContext *context, uid_t uid) {
assert(context);
if (!uid_is_valid(uid))
return 0;
/* Sets (but doesn't look up) the uid and make sure we keep the
* capabilities while doing so. */
if (context->capability_ambient_set != 0) {
/* First step: If we need to keep capabilities but
* drop privileges we need to make sure we keep our
* caps, while we drop privileges. */
if (uid != 0) {
int sb = context->secure_bits | 1<<SECURE_KEEP_CAPS;
if (prctl(PR_GET_SECUREBITS) != sb)
if (prctl(PR_SET_SECUREBITS, sb) < 0)
return -errno;
}
}
/* Second step: actually set the uids */
if (setresuid(uid, uid, uid) < 0)
return -errno;
/* At this point we should have all necessary capabilities but
are otherwise a normal user. However, the caps might got
corrupted due to the setresuid() so we need clean them up
later. This is done outside of this call. */
return 0;
}
#if HAVE_PAM
static int null_conv(
int num_msg,
const struct pam_message **msg,
struct pam_response **resp,
void *appdata_ptr) {
/* We don't support conversations */
return PAM_CONV_ERR;
}
#endif
static int setup_pam(
const char *name,
const char *user,
uid_t uid,
gid_t gid,
const char *tty,
char ***env,
int fds[], size_t n_fds) {
#if HAVE_PAM
static const struct pam_conv conv = {
.conv = null_conv,
.appdata_ptr = NULL
};
_cleanup_(barrier_destroy) Barrier barrier = BARRIER_NULL;
pam_handle_t *handle = NULL;
sigset_t old_ss;
int pam_code = PAM_SUCCESS, r;
char **nv, **e = NULL;
bool close_session = false;
pid_t pam_pid = 0, parent_pid;
int flags = 0;
assert(name);
assert(user);
assert(env);
/* We set up PAM in the parent process, then fork. The child
* will then stay around until killed via PR_GET_PDEATHSIG or
* systemd via the cgroup logic. It will then remove the PAM
* session again. The parent process will exec() the actual
* daemon. We do things this way to ensure that the main PID
* of the daemon is the one we initially fork()ed. */
r = barrier_create(&barrier);
if (r < 0)
goto fail;
if (log_get_max_level() < LOG_DEBUG)
flags |= PAM_SILENT;
pam_code = pam_start(name, user, &conv, &handle);
if (pam_code != PAM_SUCCESS) {
handle = NULL;
goto fail;
}
if (tty) {
pam_code = pam_set_item(handle, PAM_TTY, tty);
if (pam_code != PAM_SUCCESS)
goto fail;
}
STRV_FOREACH(nv, *env) {
pam_code = pam_putenv(handle, *nv);
if (pam_code != PAM_SUCCESS)
goto fail;
}
pam_code = pam_acct_mgmt(handle, flags);
if (pam_code != PAM_SUCCESS)
goto fail;
pam_code = pam_open_session(handle, flags);
if (pam_code != PAM_SUCCESS)
goto fail;
close_session = true;
e = pam_getenvlist(handle);
if (!e) {
pam_code = PAM_BUF_ERR;
goto fail;
}
/* Block SIGTERM, so that we know that it won't get lost in
* the child */
assert_se(sigprocmask_many(SIG_BLOCK, &old_ss, SIGTERM, -1) >= 0);
parent_pid = getpid_cached();
r = safe_fork("(sd-pam)", 0, &pam_pid);
if (r < 0)
goto fail;
if (r == 0) {
int sig, ret = EXIT_PAM;
/* The child's job is to reset the PAM session on
* termination */
barrier_set_role(&barrier, BARRIER_CHILD);
/* Make sure we don't keep open the passed fds in this child. We assume that otherwise only those fds
* are open here that have been opened by PAM. */
(void) close_many(fds, n_fds);
/* Drop privileges - we don't need any to pam_close_session
* and this will make PR_SET_PDEATHSIG work in most cases.
* If this fails, ignore the error - but expect sd-pam threads
* to fail to exit normally */
r = maybe_setgroups(0, NULL);
if (r < 0)
log_warning_errno(r, "Failed to setgroups() in sd-pam: %m");
if (setresgid(gid, gid, gid) < 0)
log_warning_errno(errno, "Failed to setresgid() in sd-pam: %m");
if (setresuid(uid, uid, uid) < 0)
log_warning_errno(errno, "Failed to setresuid() in sd-pam: %m");
(void) ignore_signals(SIGPIPE, -1);
/* Wait until our parent died. This will only work if
* the above setresuid() succeeds, otherwise the kernel
* will not allow unprivileged parents kill their privileged
* children this way. We rely on the control groups kill logic
* to do the rest for us. */
if (prctl(PR_SET_PDEATHSIG, SIGTERM) < 0)
goto child_finish;
/* Tell the parent that our setup is done. This is especially
* important regarding dropping privileges. Otherwise, unit
* setup might race against our setresuid(2) call.
*
* If the parent aborted, we'll detect this below, hence ignore
* return failure here. */
(void) barrier_place(&barrier);
/* Check if our parent process might already have died? */
if (getppid() == parent_pid) {
sigset_t ss;
assert_se(sigemptyset(&ss) >= 0);
assert_se(sigaddset(&ss, SIGTERM) >= 0);
for (;;) {
if (sigwait(&ss, &sig) < 0) {
if (errno == EINTR)
continue;
goto child_finish;
}
assert(sig == SIGTERM);
break;
}
}
/* If our parent died we'll end the session */
if (getppid() != parent_pid) {
pam_code = pam_close_session(handle, flags);
if (pam_code != PAM_SUCCESS)
goto child_finish;
}
ret = 0;
child_finish:
pam_end(handle, pam_code | flags);
_exit(ret);
}
barrier_set_role(&barrier, BARRIER_PARENT);
/* If the child was forked off successfully it will do all the
* cleanups, so forget about the handle here. */
handle = NULL;
/* Unblock SIGTERM again in the parent */
assert_se(sigprocmask(SIG_SETMASK, &old_ss, NULL) >= 0);
/* We close the log explicitly here, since the PAM modules
* might have opened it, but we don't want this fd around. */
closelog();
/* Synchronously wait for the child to initialize. We don't care for
* errors as we cannot recover. However, warn loudly if it happens. */
if (!barrier_place_and_sync(&barrier))
log_error("PAM initialization failed");
return strv_free_and_replace(*env, e);
fail:
if (pam_code != PAM_SUCCESS) {
log_error("PAM failed: %s", pam_strerror(handle, pam_code));
r = -EPERM; /* PAM errors do not map to errno */
} else
log_error_errno(r, "PAM failed: %m");
if (handle) {
if (close_session)
pam_code = pam_close_session(handle, flags);
pam_end(handle, pam_code | flags);
}
strv_free(e);
closelog();
return r;
#else
return 0;
#endif
}
static void rename_process_from_path(const char *path) {
char process_name[11];
const char *p;
size_t l;
/* This resulting string must fit in 10 chars (i.e. the length
* of "/sbin/init") to look pretty in /bin/ps */
p = basename(path);
if (isempty(p)) {
rename_process("(...)");
return;
}
l = strlen(p);
if (l > 8) {
/* The end of the process name is usually more
* interesting, since the first bit might just be
* "systemd-" */
p = p + l - 8;
l = 8;
}
process_name[0] = '(';
memcpy(process_name+1, p, l);
process_name[1+l] = ')';
process_name[1+l+1] = 0;
rename_process(process_name);
}
static bool context_has_address_families(const ExecContext *c) {
assert(c);
return c->address_families_whitelist ||
!set_isempty(c->address_families);
}
static bool context_has_syscall_filters(const ExecContext *c) {
assert(c);
return c->syscall_whitelist ||
!hashmap_isempty(c->syscall_filter);
}
static bool context_has_no_new_privileges(const ExecContext *c) {
assert(c);
if (c->no_new_privileges)
return true;
if (have_effective_cap(CAP_SYS_ADMIN)) /* if we are privileged, we don't need NNP */
return false;
/* We need NNP if we have any form of seccomp and are unprivileged */
return context_has_address_families(c) ||
c->memory_deny_write_execute ||
c->restrict_realtime ||
c->restrict_suid_sgid ||
exec_context_restrict_namespaces_set(c) ||
c->protect_kernel_tunables ||
c->protect_kernel_modules ||
c->private_devices ||
context_has_syscall_filters(c) ||
!set_isempty(c->syscall_archs) ||
c->lock_personality;
}
#if HAVE_SECCOMP
static bool skip_seccomp_unavailable(const Unit* u, const char* msg) {
if (is_seccomp_available())
return false;
log_unit_debug(u, "SECCOMP features not detected in the kernel, skipping %s", msg);
return true;
}
static int apply_syscall_filter(const Unit* u, const ExecContext *c, bool needs_ambient_hack) {
uint32_t negative_action, default_action, action;
int r;
assert(u);
assert(c);
if (!context_has_syscall_filters(c))
return 0;
if (skip_seccomp_unavailable(u, "SystemCallFilter="))
return 0;
negative_action = c->syscall_errno == 0 ? SCMP_ACT_KILL : SCMP_ACT_ERRNO(c->syscall_errno);
if (c->syscall_whitelist) {
default_action = negative_action;
action = SCMP_ACT_ALLOW;
} else {
default_action = SCMP_ACT_ALLOW;
action = negative_action;
}
if (needs_ambient_hack) {
r = seccomp_filter_set_add(c->syscall_filter, c->syscall_whitelist, syscall_filter_sets + SYSCALL_FILTER_SET_SETUID);
if (r < 0)
return r;
}
return seccomp_load_syscall_filter_set_raw(default_action, c->syscall_filter, action, false);
}
static int apply_syscall_archs(const Unit *u, const ExecContext *c) {
assert(u);
assert(c);
if (set_isempty(c->syscall_archs))
return 0;
if (skip_seccomp_unavailable(u, "SystemCallArchitectures="))
return 0;
return seccomp_restrict_archs(c->syscall_archs);
}
static int apply_address_families(const Unit* u, const ExecContext *c) {
assert(u);
assert(c);
if (!context_has_address_families(c))
return 0;
if (skip_seccomp_unavailable(u, "RestrictAddressFamilies="))
return 0;
return seccomp_restrict_address_families(c->address_families, c->address_families_whitelist);
}
static int apply_memory_deny_write_execute(const Unit* u, const ExecContext *c) {
assert(u);
assert(c);
if (!c->memory_deny_write_execute)
return 0;
if (skip_seccomp_unavailable(u, "MemoryDenyWriteExecute="))
return 0;
return seccomp_memory_deny_write_execute();
}
static int apply_restrict_realtime(const Unit* u, const ExecContext *c) {
assert(u);
assert(c);
if (!c->restrict_realtime)
return 0;
if (skip_seccomp_unavailable(u, "RestrictRealtime="))
return 0;
return seccomp_restrict_realtime();
}
static int apply_restrict_suid_sgid(const Unit* u, const ExecContext *c) {
assert(u);
assert(c);
if (!c->restrict_suid_sgid)
return 0;
if (skip_seccomp_unavailable(u, "RestrictSUIDSGID="))
return 0;
return seccomp_restrict_suid_sgid();
}
static int apply_protect_sysctl(const Unit *u, const ExecContext *c) {
assert(u);
assert(c);
/* Turn off the legacy sysctl() system call. Many distributions turn this off while building the kernel, but
* let's protect even those systems where this is left on in the kernel. */
if (!c->protect_kernel_tunables)
return 0;
if (skip_seccomp_unavailable(u, "ProtectKernelTunables="))
return 0;
return seccomp_protect_sysctl();
}
static int apply_protect_kernel_modules(const Unit *u, const ExecContext *c) {
assert(u);
assert(c);
/* Turn off module syscalls on ProtectKernelModules=yes */
if (!c->protect_kernel_modules)
return 0;
if (skip_seccomp_unavailable(u, "ProtectKernelModules="))
return 0;
return seccomp_load_syscall_filter_set(SCMP_ACT_ALLOW, syscall_filter_sets + SYSCALL_FILTER_SET_MODULE, SCMP_ACT_ERRNO(EPERM), false);
}
static int apply_private_devices(const Unit *u, const ExecContext *c) {
assert(u);
assert(c);
/* If PrivateDevices= is set, also turn off iopl and all @raw-io syscalls. */
if (!c->private_devices)
return 0;
if (skip_seccomp_unavailable(u, "PrivateDevices="))
return 0;
return seccomp_load_syscall_filter_set(SCMP_ACT_ALLOW, syscall_filter_sets + SYSCALL_FILTER_SET_RAW_IO, SCMP_ACT_ERRNO(EPERM), false);
}
static int apply_restrict_namespaces(const Unit *u, const ExecContext *c) {
assert(u);
assert(c);
if (!exec_context_restrict_namespaces_set(c))
return 0;
if (skip_seccomp_unavailable(u, "RestrictNamespaces="))
return 0;
return seccomp_restrict_namespaces(c->restrict_namespaces);
}
static int apply_lock_personality(const Unit* u, const ExecContext *c) {
unsigned long personality;
int r;
assert(u);
assert(c);
if (!c->lock_personality)
return 0;
if (skip_seccomp_unavailable(u, "LockPersonality="))
return 0;
personality = c->personality;
/* If personality is not specified, use either PER_LINUX or PER_LINUX32 depending on what is currently set. */
if (personality == PERSONALITY_INVALID) {
r = opinionated_personality(&personality);
if (r < 0)
return r;
}
return seccomp_lock_personality(personality);
}
#endif
static void do_idle_pipe_dance(int idle_pipe[4]) {
assert(idle_pipe);
idle_pipe[1] = safe_close(idle_pipe[1]);
idle_pipe[2] = safe_close(idle_pipe[2]);
if (idle_pipe[0] >= 0) {
int r;
r = fd_wait_for_event(idle_pipe[0], POLLHUP, IDLE_TIMEOUT_USEC);
if (idle_pipe[3] >= 0 && r == 0 /* timeout */) {
ssize_t n;
/* Signal systemd that we are bored and want to continue. */
n = write(idle_pipe[3], "x", 1);
if (n > 0)
/* Wait for systemd to react to the signal above. */
fd_wait_for_event(idle_pipe[0], POLLHUP, IDLE_TIMEOUT2_USEC);
}
idle_pipe[0] = safe_close(idle_pipe[0]);
}
idle_pipe[3] = safe_close(idle_pipe[3]);
}
static int build_environment(
const Unit *u,
const ExecContext *c,
const ExecParameters *p,
size_t n_fds,
const char *home,
const char *username,
const char *shell,
dev_t journal_stream_dev,
ino_t journal_stream_ino,
char ***ret) {
_cleanup_strv_free_ char **our_env = NULL;
size_t n_env = 0;
char *x;
assert(u);
assert(c);
assert(ret);
our_env = new0(char*, 14);
if (!our_env)
return -ENOMEM;
if (n_fds > 0) {
_cleanup_free_ char *joined = NULL;
if (asprintf(&x, "LISTEN_PID="PID_FMT, getpid_cached()) < 0)
return -ENOMEM;
our_env[n_env++] = x;
if (asprintf(&x, "LISTEN_FDS=%zu", n_fds) < 0)
return -ENOMEM;
our_env[n_env++] = x;
joined = strv_join(p->fd_names, ":");
if (!joined)
return -ENOMEM;
x = strjoin("LISTEN_FDNAMES=", joined);
if (!x)
return -ENOMEM;
our_env[n_env++] = x;
}
if ((p->flags & EXEC_SET_WATCHDOG) && p->watchdog_usec > 0) {
if (asprintf(&x, "WATCHDOG_PID="PID_FMT, getpid_cached()) < 0)
return -ENOMEM;
our_env[n_env++] = x;
if (asprintf(&x, "WATCHDOG_USEC="USEC_FMT, p->watchdog_usec) < 0)
return -ENOMEM;
our_env[n_env++] = x;
}
/* If this is D-Bus, tell the nss-systemd module, since it relies on being able to use D-Bus look up dynamic
* users via PID 1, possibly dead-locking the dbus daemon. This way it will not use D-Bus to resolve names, but
* check the database directly. */
if (p->flags & EXEC_NSS_BYPASS_BUS) {
x = strdup("SYSTEMD_NSS_BYPASS_BUS=1");
if (!x)
return -ENOMEM;
our_env[n_env++] = x;
}
if (home) {
x = strappend("HOME=", home);
if (!x)
return -ENOMEM;
our_env[n_env++] = x;
}
if (username) {
x = strappend("LOGNAME=", username);
if (!x)
return -ENOMEM;
our_env[n_env++] = x;
x = strappend("USER=", username);
if (!x)
return -ENOMEM;
our_env[n_env++] = x;
}
if (shell) {
x = strappend("SHELL=", shell);
if (!x)
return -ENOMEM;
our_env[n_env++] = x;
}
if (!sd_id128_is_null(u->invocation_id)) {
if (asprintf(&x, "INVOCATION_ID=" SD_ID128_FORMAT_STR, SD_ID128_FORMAT_VAL(u->invocation_id)) < 0)
return -ENOMEM;
our_env[n_env++] = x;
}
if (exec_context_needs_term(c)) {
const char *tty_path, *term = NULL;
tty_path = exec_context_tty_path(c);
/* If we are forked off PID 1 and we are supposed to operate on /dev/console, then let's try to inherit
* the $TERM set for PID 1. This is useful for containers so that the $TERM the container manager
* passes to PID 1 ends up all the way in the console login shown. */
if (path_equal(tty_path, "/dev/console") && getppid() == 1)
term = getenv("TERM");
if (!term)
term = default_term_for_tty(tty_path);
x = strappend("TERM=", term);
if (!x)
return -ENOMEM;
our_env[n_env++] = x;
}
if (journal_stream_dev != 0 && journal_stream_ino != 0) {
if (asprintf(&x, "JOURNAL_STREAM=" DEV_FMT ":" INO_FMT, journal_stream_dev, journal_stream_ino) < 0)
return -ENOMEM;
our_env[n_env++] = x;
}
our_env[n_env++] = NULL;
assert(n_env <= 12);
*ret = TAKE_PTR(our_env);
return 0;
}
static int build_pass_environment(const ExecContext *c, char ***ret) {
_cleanup_strv_free_ char **pass_env = NULL;
size_t n_env = 0, n_bufsize = 0;
char **i;
STRV_FOREACH(i, c->pass_environment) {
_cleanup_free_ char *x = NULL;
char *v;
v = getenv(*i);
if (!v)
continue;
x = strjoin(*i, "=", v);
if (!x)
return -ENOMEM;
if (!GREEDY_REALLOC(pass_env, n_bufsize, n_env + 2))
return -ENOMEM;
pass_env[n_env++] = TAKE_PTR(x);
pass_env[n_env] = NULL;
}
*ret = TAKE_PTR(pass_env);
return 0;
}
static bool exec_needs_mount_namespace(
const ExecContext *context,
const ExecParameters *params,
const ExecRuntime *runtime) {
assert(context);
assert(params);
if (context->root_image)
return true;
if (!strv_isempty(context->read_write_paths) ||
!strv_isempty(context->read_only_paths) ||
!strv_isempty(context->inaccessible_paths))
return true;
if (context->n_bind_mounts > 0)
return true;
if (context->n_temporary_filesystems > 0)
return true;
if (context->mount_flags != 0)
return true;
if (context->private_tmp && runtime && (runtime->tmp_dir || runtime->var_tmp_dir))
return true;
if (context->private_devices ||
context->private_mounts ||
context->protect_system != PROTECT_SYSTEM_NO ||
context->protect_home != PROTECT_HOME_NO ||
context->protect_kernel_tunables ||
context->protect_kernel_modules ||
context->protect_control_groups)
return true;
if (context->root_directory) {
ExecDirectoryType t;
if (context->mount_apivfs)
return true;
for (t = 0; t < _EXEC_DIRECTORY_TYPE_MAX; t++) {
if (!params->prefix[t])
continue;
if (!strv_isempty(context->directories[t].paths))
return true;
}
}
if (context->dynamic_user &&
(!strv_isempty(context->directories[EXEC_DIRECTORY_STATE].paths) ||
!strv_isempty(context->directories[EXEC_DIRECTORY_CACHE].paths) ||
!strv_isempty(context->directories[EXEC_DIRECTORY_LOGS].paths)))
return true;
return false;
}
static int setup_private_users(uid_t uid, gid_t gid) {
_cleanup_free_ char *uid_map = NULL, *gid_map = NULL;
_cleanup_close_pair_ int errno_pipe[2] = { -1, -1 };
_cleanup_close_ int unshare_ready_fd = -1;
_cleanup_(sigkill_waitp) pid_t pid = 0;
uint64_t c = 1;
ssize_t n;
int r;
/* Set up a user namespace and map root to root, the selected UID/GID to itself, and everything else to
* nobody. In order to be able to write this mapping we need CAP_SETUID in the original user namespace, which
* we however lack after opening the user namespace. To work around this we fork() a temporary child process,
* which waits for the parent to create the new user namespace while staying in the original namespace. The
* child then writes the UID mapping, under full privileges. The parent waits for the child to finish and
* continues execution normally. */
if (uid != 0 && uid_is_valid(uid)) {
r = asprintf(&uid_map,
"0 0 1\n" /* Map root → root */
UID_FMT " " UID_FMT " 1\n", /* Map $UID → $UID */
uid, uid);
if (r < 0)
return -ENOMEM;
} else {
uid_map = strdup("0 0 1\n"); /* The case where the above is the same */
if (!uid_map)
return -ENOMEM;
}
if (gid != 0 && gid_is_valid(gid)) {
r = asprintf(&gid_map,
"0 0 1\n" /* Map root → root */
GID_FMT " " GID_FMT " 1\n", /* Map $GID → $GID */
gid, gid);
if (r < 0)
return -ENOMEM;
} else {
gid_map = strdup("0 0 1\n"); /* The case where the above is the same */
if (!gid_map)
return -ENOMEM;
}
/* Create a communication channel so that the parent can tell the child when it finished creating the user
* namespace. */
unshare_ready_fd = eventfd(0, EFD_CLOEXEC);
if (unshare_ready_fd < 0)
return -errno;
/* Create a communication channel so that the child can tell the parent a proper error code in case it
* failed. */
if (pipe2(errno_pipe, O_CLOEXEC) < 0)
return -errno;
r = safe_fork("(sd-userns)", FORK_RESET_SIGNALS|FORK_DEATHSIG, &pid);
if (r < 0)
return r;
if (r == 0) {
_cleanup_close_ int fd = -1;
const char *a;
pid_t ppid;
/* Child process, running in the original user namespace. Let's update the parent's UID/GID map from
* here, after the parent opened its own user namespace. */
ppid = getppid();
errno_pipe[0] = safe_close(errno_pipe[0]);
/* Wait until the parent unshared the user namespace */
if (read(unshare_ready_fd, &c, sizeof(c)) < 0) {
r = -errno;
goto child_fail;
}
/* Disable the setgroups() system call in the child user namespace, for good. */
a = procfs_file_alloca(ppid, "setgroups");
fd = open(a, O_WRONLY|O_CLOEXEC);
if (fd < 0) {
if (errno != ENOENT) {
r = -errno;
goto child_fail;
}
/* If the file is missing the kernel is too old, let's continue anyway. */
} else {
if (write(fd, "deny\n", 5) < 0) {
r = -errno;
goto child_fail;
}
fd = safe_close(fd);
}
/* First write the GID map */
a = procfs_file_alloca(ppid, "gid_map");
fd = open(a, O_WRONLY|O_CLOEXEC);
if (fd < 0) {
r = -errno;
goto child_fail;
}
if (write(fd, gid_map, strlen(gid_map)) < 0) {
r = -errno;
goto child_fail;
}
fd = safe_close(fd);
/* The write the UID map */
a = procfs_file_alloca(ppid, "uid_map");
fd = open(a, O_WRONLY|O_CLOEXEC);
if (fd < 0) {
r = -errno;
goto child_fail;
}
if (write(fd, uid_map, strlen(uid_map)) < 0) {
r = -errno;
goto child_fail;
}
_exit(EXIT_SUCCESS);
child_fail:
(void) write(errno_pipe[1], &r, sizeof(r));
_exit(EXIT_FAILURE);
}
errno_pipe[1] = safe_close(errno_pipe[1]);
if (unshare(CLONE_NEWUSER) < 0)
return -errno;
/* Let the child know that the namespace is ready now */
if (write(unshare_ready_fd, &c, sizeof(c)) < 0)
return -errno;
/* Try to read an error code from the child */
n = read(errno_pipe[0], &r, sizeof(r));
if (n < 0)
return -errno;
if (n == sizeof(r)) { /* an error code was sent to us */
if (r < 0)
return r;
return -EIO;
}
if (n != 0) /* on success we should have read 0 bytes */
return -EIO;
r = wait_for_terminate_and_check("(sd-userns)", pid, 0);
pid = 0;
if (r < 0)
return r;
if (r != EXIT_SUCCESS) /* If something strange happened with the child, let's consider this fatal, too */
return -EIO;
return 0;
}
static int setup_exec_directory(
const ExecContext *context,
const ExecParameters *params,
uid_t uid,
gid_t gid,
ExecDirectoryType type,
int *exit_status) {
static const int exit_status_table[_EXEC_DIRECTORY_TYPE_MAX] = {
[EXEC_DIRECTORY_RUNTIME] = EXIT_RUNTIME_DIRECTORY,
[EXEC_DIRECTORY_STATE] = EXIT_STATE_DIRECTORY,
[EXEC_DIRECTORY_CACHE] = EXIT_CACHE_DIRECTORY,
[EXEC_DIRECTORY_LOGS] = EXIT_LOGS_DIRECTORY,
[EXEC_DIRECTORY_CONFIGURATION] = EXIT_CONFIGURATION_DIRECTORY,
};
char **rt;
int r;
assert(context);
assert(params);
assert(type >= 0 && type < _EXEC_DIRECTORY_TYPE_MAX);
assert(exit_status);
if (!params->prefix[type])
return 0;
if (params->flags & EXEC_CHOWN_DIRECTORIES) {
if (!uid_is_valid(uid))
uid = 0;
if (!gid_is_valid(gid))
gid = 0;
}
STRV_FOREACH(rt, context->directories[type].paths) {
_cleanup_free_ char *p = NULL, *pp = NULL;
p = strjoin(params->prefix[type], "/", *rt);
if (!p) {
r = -ENOMEM;
goto fail;
}
r = mkdir_parents_label(p, 0755);
if (r < 0)
goto fail;
if (context->dynamic_user &&
!IN_SET(type, EXEC_DIRECTORY_RUNTIME, EXEC_DIRECTORY_CONFIGURATION)) {
_cleanup_free_ char *private_root = NULL, *relative = NULL, *parent = NULL;
/* So, here's one extra complication when dealing with DynamicUser=1 units. In that case we
* want to avoid leaving a directory around fully accessible that is owned by a dynamic user
* whose UID is later on reused. To lock this down we use the same trick used by container
* managers to prohibit host users to get access to files of the same UID in containers: we
* place everything inside a directory that has an access mode of 0700 and is owned root:root,
* so that it acts as security boundary for unprivileged host code. We then use fs namespacing
* to make this directory permeable for the service itself.
*
* Specifically: for a service which wants a special directory "foo/" we first create a
* directory "private/" with access mode 0700 owned by root:root. Then we place "foo" inside of
* that directory (i.e. "private/foo/"), and make "foo" a symlink to "private/foo". This way,
* privileged host users can access "foo/" as usual, but unprivileged host users can't look
* into it. Inside of the namespaceof the container "private/" is replaced by a more liberally
* accessible tmpfs, into which the host's "private/foo/" is mounted under the same name, thus
* disabling the access boundary for the service and making sure it only gets access to the
* dirs it needs but no others. Tricky? Yes, absolutely, but it works!
*
* Note that we don't do this for EXEC_DIRECTORY_CONFIGURATION as that's assumed not to be
* owned by the service itself.
* Also, note that we don't do this for EXEC_DIRECTORY_RUNTIME as that's often used for sharing
* files or sockets with other services. */
private_root = strjoin(params->prefix[type], "/private");
if (!private_root) {
r = -ENOMEM;
goto fail;
}
/* First set up private root if it doesn't exist yet, with access mode 0700 and owned by root:root */
r = mkdir_safe_label(private_root, 0700, 0, 0, MKDIR_WARN_MODE);
if (r < 0)
goto fail;
pp = strjoin(private_root, "/", *rt);
if (!pp) {
r = -ENOMEM;
goto fail;
}
/* Create all directories between the configured directory and this private root, and mark them 0755 */
r = mkdir_parents_label(pp, 0755);
if (r < 0)
goto fail;
if (is_dir(p, false) > 0 &&
(laccess(pp, F_OK) < 0 && errno == ENOENT)) {
/* Hmm, the private directory doesn't exist yet, but the normal one exists? If so, move
* it over. Most likely the service has been upgraded from one that didn't use
* DynamicUser=1, to one that does. */
if (rename(p, pp) < 0) {
r = -errno;
goto fail;
}
} else {
/* Otherwise, create the actual directory for the service */
r = mkdir_label(pp, context->directories[type].mode);
if (r < 0 && r != -EEXIST)
goto fail;
}
parent = dirname_malloc(p);
if (!parent) {
r = -ENOMEM;
goto fail;
}
r = path_make_relative(parent, pp, &relative);
if (r < 0)
goto fail;
/* And link it up from the original place */
r = symlink_idempotent(relative, p);
if (r < 0)
goto fail;
} else {
r = mkdir_label(p, context->directories[type].mode);
if (r < 0) {
if (r != -EEXIST)
goto fail;
if (type == EXEC_DIRECTORY_CONFIGURATION) {
struct stat st;
/* Don't change the owner/access mode of the configuration directory,
* as in the common case it is not written to by a service, and shall
* not be writable. */
if (stat(p, &st) < 0) {
r = -errno;
goto fail;
}
/* Still complain if the access mode doesn't match */
if (((st.st_mode ^ context->directories[type].mode) & 07777) != 0)
log_warning("%s \'%s\' already exists but the mode is different. "
"(File system: %o %sMode: %o)",
exec_directory_type_to_string(type), *rt,
st.st_mode & 07777, exec_directory_type_to_string(type), context->directories[type].mode & 07777);
continue;
}
}
}
/* Lock down the access mode (we use chmod_and_chown() to make this idempotent. We don't
* specifiy UID/GID here, so that path_chown_recursive() can optimize things depending on the
* current UID/GID ownership.) */
r = chmod_and_chown(pp ?: p, context->directories[type].mode, UID_INVALID, GID_INVALID);
if (r < 0)
goto fail;
/* Then, change the ownership of the whole tree, if necessary */
r = path_chown_recursive(pp ?: p, uid, gid);
if (r < 0)
goto fail;
}
return 0;
fail:
*exit_status = exit_status_table[type];
return r;
}
#if ENABLE_SMACK
static int setup_smack(
const ExecContext *context,
const ExecCommand *command) {
int r;
assert(context);
assert(command);
if (context->smack_process_label) {
r = mac_smack_apply_pid(0, context->smack_process_label);
if (r < 0)
return r;
}
#ifdef SMACK_DEFAULT_PROCESS_LABEL
else {
_cleanup_free_ char *exec_label = NULL;
r = mac_smack_read(command->path, SMACK_ATTR_EXEC, &exec_label);
if (r < 0 && !IN_SET(r, -ENODATA, -EOPNOTSUPP))
return r;
r = mac_smack_apply_pid(0, exec_label ? : SMACK_DEFAULT_PROCESS_LABEL);
if (r < 0)
return r;
}
#endif
return 0;
}
#endif
static int compile_bind_mounts(
const ExecContext *context,
const ExecParameters *params,
BindMount **ret_bind_mounts,
size_t *ret_n_bind_mounts,
char ***ret_empty_directories) {
_cleanup_strv_free_ char **empty_directories = NULL;
BindMount *bind_mounts;
size_t n, h = 0, i;
ExecDirectoryType t;
int r;
assert(context);
assert(params);
assert(ret_bind_mounts);
assert(ret_n_bind_mounts);
assert(ret_empty_directories);
n = context->n_bind_mounts;
for (t = 0; t < _EXEC_DIRECTORY_TYPE_MAX; t++) {
if (!params->prefix[t])
continue;
n += strv_length(context->directories[t].paths);
}
if (n <= 0) {
*ret_bind_mounts = NULL;
*ret_n_bind_mounts = 0;
*ret_empty_directories = NULL;
return 0;
}
bind_mounts = new(BindMount, n);
if (!bind_mounts)
return -ENOMEM;
for (i = 0; i < context->n_bind_mounts; i++) {
BindMount *item = context->bind_mounts + i;
char *s, *d;
s = strdup(item->source);
if (!s) {
r = -ENOMEM;
goto finish;
}
d = strdup(item->destination);
if (!d) {
free(s);
r = -ENOMEM;
goto finish;
}
bind_mounts[h++] = (BindMount) {
.source = s,
.destination = d,
.read_only = item->read_only,
.recursive = item->recursive,
.ignore_enoent = item->ignore_enoent,
};
}
for (t = 0; t < _EXEC_DIRECTORY_TYPE_MAX; t++) {
char **suffix;
if (!params->prefix[t])
continue;
if (strv_isempty(context->directories[t].paths))
continue;
if (context->dynamic_user &&
!IN_SET(t, EXEC_DIRECTORY_RUNTIME, EXEC_DIRECTORY_CONFIGURATION) &&
!(context->root_directory || context->root_image)) {
char *private_root;
/* So this is for a dynamic user, and we need to make sure the process can access its own
* directory. For that we overmount the usually inaccessible "private" subdirectory with a
* tmpfs that makes it accessible and is empty except for the submounts we do this for. */
private_root = strjoin(params->prefix[t], "/private");
if (!private_root) {
r = -ENOMEM;
goto finish;
}
r = strv_consume(&empty_directories, private_root);
if (r < 0)
goto finish;
}
STRV_FOREACH(suffix, context->directories[t].paths) {
char *s, *d;
if (context->dynamic_user &&
!IN_SET(t, EXEC_DIRECTORY_RUNTIME, EXEC_DIRECTORY_CONFIGURATION))
s = strjoin(params->prefix[t], "/private/", *suffix);
else
s = strjoin(params->prefix[t], "/", *suffix);
if (!s) {
r = -ENOMEM;
goto finish;
}
if (context->dynamic_user &&
!IN_SET(t, EXEC_DIRECTORY_RUNTIME, EXEC_DIRECTORY_CONFIGURATION) &&
(context->root_directory || context->root_image))
/* When RootDirectory= or RootImage= are set, then the symbolic link to the private
* directory is not created on the root directory. So, let's bind-mount the directory
* on the 'non-private' place. */
d = strjoin(params->prefix[t], "/", *suffix);
else
d = strdup(s);
if (!d) {
free(s);
r = -ENOMEM;
goto finish;
}
bind_mounts[h++] = (BindMount) {
.source = s,
.destination = d,
.read_only = false,
.recursive = true,
.ignore_enoent = false,
};
}
}
assert(h == n);
*ret_bind_mounts = bind_mounts;
*ret_n_bind_mounts = n;
*ret_empty_directories = TAKE_PTR(empty_directories);
return (int) n;
finish:
bind_mount_free_many(bind_mounts, h);
return r;
}
static int apply_mount_namespace(
const Unit *u,
const ExecCommand *command,
const ExecContext *context,
const ExecParameters *params,
const ExecRuntime *runtime) {
_cleanup_strv_free_ char **empty_directories = NULL;
char *tmp = NULL, *var = NULL;
const char *root_dir = NULL, *root_image = NULL;
NamespaceInfo ns_info;
bool needs_sandboxing;
BindMount *bind_mounts = NULL;
size_t n_bind_mounts = 0;
int r;
assert(context);
/* The runtime struct only contains the parent of the private /tmp,
* which is non-accessible to world users. Inside of it there's a /tmp
* that is sticky, and that's the one we want to use here. */
if (context->private_tmp && runtime) {
if (runtime->tmp_dir)
tmp = strjoina(runtime->tmp_dir, "/tmp");
if (runtime->var_tmp_dir)
var = strjoina(runtime->var_tmp_dir, "/tmp");
}
if (params->flags & EXEC_APPLY_CHROOT) {
root_image = context->root_image;
if (!root_image)
root_dir = context->root_directory;
}
r = compile_bind_mounts(context, params, &bind_mounts, &n_bind_mounts, &empty_directories);
if (r < 0)
return r;
needs_sandboxing = (params->flags & EXEC_APPLY_SANDBOXING) && !(command->flags & EXEC_COMMAND_FULLY_PRIVILEGED);
if (needs_sandboxing)
ns_info = (NamespaceInfo) {
.ignore_protect_paths = false,
.private_dev = context->private_devices,
.protect_control_groups = context->protect_control_groups,
.protect_kernel_tunables = context->protect_kernel_tunables,
.protect_kernel_modules = context->protect_kernel_modules,
.mount_apivfs = context->mount_apivfs,
.private_mounts = context->private_mounts,
};
else if (!context->dynamic_user && root_dir)
/*
* If DynamicUser=no and RootDirectory= is set then lets pass a relaxed
* sandbox info, otherwise enforce it, don't ignore protected paths and
* fail if we are enable to apply the sandbox inside the mount namespace.
*/
ns_info = (NamespaceInfo) {
.ignore_protect_paths = true,
};
else
ns_info = (NamespaceInfo) {};
r = setup_namespace(root_dir, root_image,
&ns_info, context->read_write_paths,
needs_sandboxing ? context->read_only_paths : NULL,
needs_sandboxing ? context->inaccessible_paths : NULL,
empty_directories,
bind_mounts,
n_bind_mounts,
context->temporary_filesystems,
context->n_temporary_filesystems,
tmp,
var,
needs_sandboxing ? context->protect_home : PROTECT_HOME_NO,
needs_sandboxing ? context->protect_system : PROTECT_SYSTEM_NO,
context->mount_flags,
DISSECT_IMAGE_DISCARD_ON_LOOP);
bind_mount_free_many(bind_mounts, n_bind_mounts);
/* If we couldn't set up the namespace this is probably due to a
* missing capability. In this case, silently proceeed. */
if (IN_SET(r, -EPERM, -EACCES)) {
log_unit_debug_errno(u, r, "Failed to set up namespace, assuming containerized execution, ignoring: %m");
return 0;
}
return r;
}
static int apply_working_directory(
const ExecContext *context,
const ExecParameters *params,
const char *home,
const bool needs_mount_ns,
int *exit_status) {
const char *d, *wd;
assert(context);
assert(exit_status);
if (context->working_directory_home) {
if (!home) {
*exit_status = EXIT_CHDIR;
return -ENXIO;
}
wd = home;
} else if (context->working_directory)
wd = context->working_directory;
else
wd = "/";
if (params->flags & EXEC_APPLY_CHROOT) {
if (!needs_mount_ns && context->root_directory)
if (chroot(context->root_directory) < 0) {
*exit_status = EXIT_CHROOT;
return -errno;
}
d = wd;
} else
d = prefix_roota(context->root_directory, wd);
if (chdir(d) < 0 && !context->working_directory_missing_ok) {
*exit_status = EXIT_CHDIR;
return -errno;
}
return 0;
}
static int setup_keyring(
const Unit *u,
const ExecContext *context,
const ExecParameters *p,
uid_t uid, gid_t gid) {
key_serial_t keyring;
int r = 0;
uid_t saved_uid;
gid_t saved_gid;
assert(u);
assert(context);
assert(p);
/* Let's set up a new per-service "session" kernel keyring for each system service. This has the benefit that
* each service runs with its own keyring shared among all processes of the service, but with no hook-up beyond
* that scope, and in particular no link to the per-UID keyring. If we don't do this the keyring will be
* automatically created on-demand and then linked to the per-UID keyring, by the kernel. The kernel's built-in
* on-demand behaviour is very appropriate for login users, but probably not so much for system services, where
* UIDs are not necessarily specific to a service but reused (at least in the case of UID 0). */
if (!(p->flags & EXEC_NEW_KEYRING))
return 0;
if (context->keyring_mode == EXEC_KEYRING_INHERIT)
return 0;
/* Acquiring a reference to the user keyring is nasty. We briefly change identity in order to get things set up
* properly by the kernel. If we don't do that then we can't create it atomically, and that sucks for parallel
* execution. This mimics what pam_keyinit does, too. Setting up session keyring, to be owned by the right user
* & group is just as nasty as acquiring a reference to the user keyring. */
saved_uid = getuid();
saved_gid = getgid();
if (gid_is_valid(gid) && gid != saved_gid) {
if (setregid(gid, -1) < 0)
return log_unit_error_errno(u, errno, "Failed to change GID for user keyring: %m");
}
if (uid_is_valid(uid) && uid != saved_uid) {
if (setreuid(uid, -1) < 0) {
r = log_unit_error_errno(u, errno, "Failed to change UID for user keyring: %m");
goto out;
}
}
keyring = keyctl(KEYCTL_JOIN_SESSION_KEYRING, 0, 0, 0, 0);
if (keyring == -1) {
if (errno == ENOSYS)
log_unit_debug_errno(u, errno, "Kernel keyring not supported, ignoring.");
else if (IN_SET(errno, EACCES, EPERM))
log_unit_debug_errno(u, errno, "Kernel keyring access prohibited, ignoring.");
else if (errno == EDQUOT)
log_unit_debug_errno(u, errno, "Out of kernel keyrings to allocate, ignoring.");
else
r = log_unit_error_errno(u, errno, "Setting up kernel keyring failed: %m");
goto out;
}
/* When requested link the user keyring into the session keyring. */
if (context->keyring_mode == EXEC_KEYRING_SHARED) {
if (keyctl(KEYCTL_LINK,
KEY_SPEC_USER_KEYRING,
KEY_SPEC_SESSION_KEYRING, 0, 0) < 0) {
r = log_unit_error_errno(u, errno, "Failed to link user keyring into session keyring: %m");
goto out;
}
}
/* Restore uid/gid back */
if (uid_is_valid(uid) && uid != saved_uid) {
if (setreuid(saved_uid, -1) < 0) {
r = log_unit_error_errno(u, errno, "Failed to change UID back for user keyring: %m");
goto out;
}
}
if (gid_is_valid(gid) && gid != saved_gid) {
if (setregid(saved_gid, -1) < 0)
return log_unit_error_errno(u, errno, "Failed to change GID back for user keyring: %m");
}
/* Populate they keyring with the invocation ID by default, as original saved_uid. */
if (!sd_id128_is_null(u->invocation_id)) {
key_serial_t key;
key = add_key("user", "invocation_id", &u->invocation_id, sizeof(u->invocation_id), KEY_SPEC_SESSION_KEYRING);
if (key == -1)
log_unit_debug_errno(u, errno, "Failed to add invocation ID to keyring, ignoring: %m");
else {
if (keyctl(KEYCTL_SETPERM, key,
KEY_POS_VIEW|KEY_POS_READ|KEY_POS_SEARCH|
KEY_USR_VIEW|KEY_USR_READ|KEY_USR_SEARCH, 0, 0) < 0)
r = log_unit_error_errno(u, errno, "Failed to restrict invocation ID permission: %m");
}
}
out:
/* Revert back uid & gid for the the last time, and exit */
/* no extra logging, as only the first already reported error matters */
if (getuid() != saved_uid)
(void) setreuid(saved_uid, -1);
if (getgid() != saved_gid)
(void) setregid(saved_gid, -1);
return r;
}
static void append_socket_pair(int *array, size_t *n, const int pair[2]) {
assert(array);
assert(n);
if (!pair)
return;
if (pair[0] >= 0)
array[(*n)++] = pair[0];
if (pair[1] >= 0)
array[(*n)++] = pair[1];
}
static int close_remaining_fds(
const ExecParameters *params,
const ExecRuntime *runtime,
const DynamicCreds *dcreds,
int user_lookup_fd,
int socket_fd,
int exec_fd,
int *fds, size_t n_fds) {
size_t n_dont_close = 0;
int dont_close[n_fds + 12];
assert(params);
if (params->stdin_fd >= 0)
dont_close[n_dont_close++] = params->stdin_fd;
if (params->stdout_fd >= 0)
dont_close[n_dont_close++] = params->stdout_fd;
if (params->stderr_fd >= 0)
dont_close[n_dont_close++] = params->stderr_fd;
if (socket_fd >= 0)
dont_close[n_dont_close++] = socket_fd;
if (exec_fd >= 0)
dont_close[n_dont_close++] = exec_fd;
if (n_fds > 0) {
memcpy(dont_close + n_dont_close, fds, sizeof(int) * n_fds);
n_dont_close += n_fds;
}
if (runtime)
append_socket_pair(dont_close, &n_dont_close, runtime->netns_storage_socket);
if (dcreds) {
if (dcreds->user)
append_socket_pair(dont_close, &n_dont_close, dcreds->user->storage_socket);
if (dcreds->group)
append_socket_pair(dont_close, &n_dont_close, dcreds->group->storage_socket);
}
if (user_lookup_fd >= 0)
dont_close[n_dont_close++] = user_lookup_fd;
return close_all_fds(dont_close, n_dont_close);
}
static int send_user_lookup(
Unit *unit,
int user_lookup_fd,
uid_t uid,
gid_t gid) {
assert(unit);
/* Send the resolved UID/GID to PID 1 after we learnt it. We send a single datagram, containing the UID/GID
* data as well as the unit name. Note that we suppress sending this if no user/group to resolve was
* specified. */
if (user_lookup_fd < 0)
return 0;
if (!uid_is_valid(uid) && !gid_is_valid(gid))
return 0;
if (writev(user_lookup_fd,
(struct iovec[]) {
IOVEC_INIT(&uid, sizeof(uid)),
IOVEC_INIT(&gid, sizeof(gid)),
IOVEC_INIT_STRING(unit->id) }, 3) < 0)
return -errno;
return 0;
}
static int acquire_home(const ExecContext *c, uid_t uid, const char** home, char **buf) {
int r;
assert(c);
assert(home);
assert(buf);
/* If WorkingDirectory=~ is set, try to acquire a usable home directory. */
if (*home)
return 0;
if (!c->working_directory_home)
return 0;
if (uid == 0) {
/* Hardcode /root as home directory for UID 0 */
*home = "/root";
return 1;
}
r = get_home_dir(buf);
if (r < 0)
return r;
*home = *buf;
return 1;
}
static int compile_suggested_paths(const ExecContext *c, const ExecParameters *p, char ***ret) {
_cleanup_strv_free_ char ** list = NULL;
ExecDirectoryType t;
int r;
assert(c);
assert(p);
assert(ret);
assert(c->dynamic_user);
/* Compile a list of paths that it might make sense to read the owning UID from to use as initial candidate for
* dynamic UID allocation, in order to save us from doing costly recursive chown()s of the special
* directories. */
for (t = 0; t < _EXEC_DIRECTORY_TYPE_MAX; t++) {
char **i;
if (t == EXEC_DIRECTORY_CONFIGURATION)
continue;
if (!p->prefix[t])
continue;
STRV_FOREACH(i, c->directories[t].paths) {
char *e;
if (t == EXEC_DIRECTORY_RUNTIME)
e = strjoin(p->prefix[t], "/", *i);
else
e = strjoin(p->prefix[t], "/private/", *i);
if (!e)
return -ENOMEM;
r = strv_consume(&list, e);
if (r < 0)
return r;
}
}
*ret = TAKE_PTR(list);
return 0;
}
static char *exec_command_line(char **argv);
static int exec_child(
Unit *unit,
const ExecCommand *command,
const ExecContext *context,
const ExecParameters *params,
ExecRuntime *runtime,
DynamicCreds *dcreds,
char **argv,
int socket_fd,
int named_iofds[3],
int *fds,
size_t n_socket_fds,
size_t n_storage_fds,
char **files_env,
int user_lookup_fd,
int *exit_status) {
_cleanup_strv_free_ char **our_env = NULL, **pass_env = NULL, **accum_env = NULL, **final_argv = NULL;
int *fds_with_exec_fd, n_fds_with_exec_fd, r, ngids = 0, exec_fd = -1;
_cleanup_free_ gid_t *supplementary_gids = NULL;
const char *username = NULL, *groupname = NULL;
_cleanup_free_ char *home_buffer = NULL;
const char *home = NULL, *shell = NULL;
dev_t journal_stream_dev = 0;
ino_t journal_stream_ino = 0;
bool needs_sandboxing, /* Do we need to set up full sandboxing? (i.e. all namespacing, all MAC stuff, caps, yadda yadda */
needs_setuid, /* Do we need to do the actual setresuid()/setresgid() calls? */
needs_mount_namespace, /* Do we need to set up a mount namespace for this kernel? */
needs_ambient_hack; /* Do we need to apply the ambient capabilities hack? */
#if HAVE_SELINUX
_cleanup_free_ char *mac_selinux_context_net = NULL;
bool use_selinux = false;
#endif
#if ENABLE_SMACK
bool use_smack = false;
#endif
#if HAVE_APPARMOR
bool use_apparmor = false;
#endif
uid_t uid = UID_INVALID;
gid_t gid = GID_INVALID;
size_t n_fds;
ExecDirectoryType dt;
int secure_bits;
assert(unit);
assert(command);
assert(context);
assert(params);
assert(exit_status);
rename_process_from_path(command->path);
/* We reset exactly these signals, since they are the
* only ones we set to SIG_IGN in the main daemon. All
* others we leave untouched because we set them to
* SIG_DFL or a valid handler initially, both of which
* will be demoted to SIG_DFL. */
(void) default_signals(SIGNALS_CRASH_HANDLER,
SIGNALS_IGNORE, -1);
if (context->ignore_sigpipe)
(void) ignore_signals(SIGPIPE, -1);
r = reset_signal_mask();
if (r < 0) {
*exit_status = EXIT_SIGNAL_MASK;
return log_unit_error_errno(unit, r, "Failed to set process signal mask: %m");
}
if (params->idle_pipe)
do_idle_pipe_dance(params->idle_pipe);
/* Close fds we don't need very early to make sure we don't block init reexecution because it cannot bind its
* sockets. Among the fds we close are the logging fds, and we want to keep them closed, so that we don't have
* any fds open we don't really want open during the transition. In order to make logging work, we switch the
* log subsystem into open_when_needed mode, so that it reopens the logs on every single log call. */
log_forget_fds();
log_set_open_when_needed(true);
/* In case anything used libc syslog(), close this here, too */
closelog();
n_fds = n_socket_fds + n_storage_fds;
r = close_remaining_fds(params, runtime, dcreds, user_lookup_fd, socket_fd, params->exec_fd, fds, n_fds);
if (r < 0) {
*exit_status = EXIT_FDS;
return log_unit_error_errno(unit, r, "Failed to close unwanted file descriptors: %m");
}
if (!context->same_pgrp)
if (setsid() < 0) {
*exit_status = EXIT_SETSID;
return log_unit_error_errno(unit, errno, "Failed to create new process session: %m");
}
exec_context_tty_reset(context, params);
if (unit_shall_confirm_spawn(unit)) {
const char *vc = params->confirm_spawn;
_cleanup_free_ char *cmdline = NULL;
cmdline = exec_command_line(argv);
if (!cmdline) {
*exit_status = EXIT_MEMORY;
return log_oom();
}
r = ask_for_confirmation(vc, unit, cmdline);
if (r != CONFIRM_EXECUTE) {
if (r == CONFIRM_PRETEND_SUCCESS) {
*exit_status = EXIT_SUCCESS;
return 0;
}
*exit_status = EXIT_CONFIRM;
log_unit_error(unit, "Execution cancelled by the user");
return -ECANCELED;
}
}
if (context->dynamic_user && dcreds) {
_cleanup_strv_free_ char **suggested_paths = NULL;
/* Make sure we bypass our own NSS module for any NSS checks */
if (putenv((char*) "SYSTEMD_NSS_DYNAMIC_BYPASS=1") != 0) {
*exit_status = EXIT_USER;
return log_unit_error_errno(unit, errno, "Failed to update environment: %m");
}
r = compile_suggested_paths(context, params, &suggested_paths);
if (r < 0) {
*exit_status = EXIT_MEMORY;
return log_oom();
}
r = dynamic_creds_realize(dcreds, suggested_paths, &uid, &gid);
if (r < 0) {
*exit_status = EXIT_USER;
if (r == -EILSEQ) {
log_unit_error(unit, "Failed to update dynamic user credentials: User or group with specified name already exists.");
return -EOPNOTSUPP;
}
return log_unit_error_errno(unit, r, "Failed to update dynamic user credentials: %m");
}
if (!uid_is_valid(uid)) {
*exit_status = EXIT_USER;
log_unit_error(unit, "UID validation failed for \""UID_FMT"\"", uid);
return -ESRCH;
}
if (!gid_is_valid(gid)) {
*exit_status = EXIT_USER;
log_unit_error(unit, "GID validation failed for \""GID_FMT"\"", gid);
return -ESRCH;
}
if (dcreds->user)
username = dcreds->user->name;
} else {
r = get_fixed_user(context, &username, &uid, &gid, &home, &shell);
if (r < 0) {
*exit_status = EXIT_USER;
return log_unit_error_errno(unit, r, "Failed to determine user credentials: %m");
}
r = get_fixed_group(context, &groupname, &gid);
if (r < 0) {
*exit_status = EXIT_GROUP;
return log_unit_error_errno(unit, r, "Failed to determine group credentials: %m");
}
}
/* Initialize user supplementary groups and get SupplementaryGroups= ones */
r = get_supplementary_groups(context, username, groupname, gid,
&supplementary_gids, &ngids);
if (r < 0) {
*exit_status = EXIT_GROUP;
return log_unit_error_errno(unit, r, "Failed to determine supplementary groups: %m");
}
r = send_user_lookup(unit, user_lookup_fd, uid, gid);
if (r < 0) {
*exit_status = EXIT_USER;
return log_unit_error_errno(unit, r, "Failed to send user credentials to PID1: %m");
}
user_lookup_fd = safe_close(user_lookup_fd);
r = acquire_home(context, uid, &home, &home_buffer);
if (r < 0) {
*exit_status = EXIT_CHDIR;
return log_unit_error_errno(unit, r, "Failed to determine $HOME for user: %m");
}
/* If a socket is connected to STDIN/STDOUT/STDERR, we
* must sure to drop O_NONBLOCK */
if (socket_fd >= 0)
(void) fd_nonblock(socket_fd, false);
r = setup_input(context, params, socket_fd, named_iofds);
if (r < 0) {
*exit_status = EXIT_STDIN;
return log_unit_error_errno(unit, r, "Failed to set up standard input: %m");
}
r = setup_output(unit, context, params, STDOUT_FILENO, socket_fd, named_iofds, basename(command->path), uid, gid, &journal_stream_dev, &journal_stream_ino);
if (r < 0) {
*exit_status = EXIT_STDOUT;
return log_unit_error_errno(unit, r, "Failed to set up standard output: %m");
}
r = setup_output(unit, context, params, STDERR_FILENO, socket_fd, named_iofds, basename(command->path), uid, gid, &journal_stream_dev, &journal_stream_ino);
if (r < 0) {
*exit_status = EXIT_STDERR;
return log_unit_error_errno(unit, r, "Failed to set up standard error output: %m");
}
if (params->cgroup_path) {
r = cg_attach_everywhere(params->cgroup_supported, params->cgroup_path, 0, NULL, NULL);
if (r < 0) {
*exit_status = EXIT_CGROUP;
return log_unit_error_errno(unit, r, "Failed to attach to cgroup %s: %m", params->cgroup_path);
}
}
if (context->oom_score_adjust_set) {
/* When we can't make this change due to EPERM, then let's silently skip over it. User namespaces
* prohibit write access to this file, and we shouldn't trip up over that. */
r = set_oom_score_adjust(context->oom_score_adjust);
if (IN_SET(r, -EPERM, -EACCES))
log_unit_debug_errno(unit, r, "Failed to adjust OOM setting, assuming containerized execution, ignoring: %m");
else if (r < 0) {
*exit_status = EXIT_OOM_ADJUST;
return log_unit_error_errno(unit, r, "Failed to adjust OOM setting: %m");
}
}
if (context->nice_set)
if (setpriority(PRIO_PROCESS, 0, context->nice) < 0) {
*exit_status = EXIT_NICE;
return log_unit_error_errno(unit, errno, "Failed to set up process scheduling priority (nice level): %m");
}
if (context->cpu_sched_set) {
struct sched_param param = {
.sched_priority = context->cpu_sched_priority,
};
r = sched_setscheduler(0,
context->cpu_sched_policy |
(context->cpu_sched_reset_on_fork ?
SCHED_RESET_ON_FORK : 0),
&param);
if (r < 0) {
*exit_status = EXIT_SETSCHEDULER;
return log_unit_error_errno(unit, errno, "Failed to set up CPU scheduling: %m");
}
}
if (context->cpu_set.set)
if (sched_setaffinity(0, context->cpu_set.allocated, context->cpu_set.set) < 0) {
*exit_status = EXIT_CPUAFFINITY;
return log_unit_error_errno(unit, errno, "Failed to set up CPU affinity: %m");
}
if (mpol_is_valid(numa_policy_get_type(&context->numa_policy))) {
r = apply_numa_policy(&context->numa_policy);
if (r == -EOPNOTSUPP)
log_unit_debug_errno(unit, r, "NUMA support not available, ignoring.");
else if (r < 0) {
*exit_status = EXIT_NUMA_POLICY;
return log_unit_error_errno(unit, r, "Failed to set NUMA memory policy: %m");
}
}
if (context->ioprio_set)
if (ioprio_set(IOPRIO_WHO_PROCESS, 0, context->ioprio) < 0) {
*exit_status = EXIT_IOPRIO;
return log_unit_error_errno(unit, errno, "Failed to set up IO scheduling priority: %m");
}
if (context->timer_slack_nsec != NSEC_INFINITY)
if (prctl(PR_SET_TIMERSLACK, context->timer_slack_nsec) < 0) {
*exit_status = EXIT_TIMERSLACK;
return log_unit_error_errno(unit, errno, "Failed to set up timer slack: %m");
}
if (context->personality != PERSONALITY_INVALID) {
r = safe_personality(context->personality);
if (r < 0) {
*exit_status = EXIT_PERSONALITY;
return log_unit_error_errno(unit, r, "Failed to set up execution domain (personality): %m");
}
}
if (context->utmp_id)
utmp_put_init_process(context->utmp_id, getpid_cached(), getsid(0),
context->tty_path,
context->utmp_mode == EXEC_UTMP_INIT ? INIT_PROCESS :
context->utmp_mode == EXEC_UTMP_LOGIN ? LOGIN_PROCESS :
USER_PROCESS,
username);
if (context->user) {
r = chown_terminal(STDIN_FILENO, uid);
if (r < 0) {
*exit_status = EXIT_STDIN;
return log_unit_error_errno(unit, r, "Failed to change ownership of terminal: %m");
}
}
/* If delegation is enabled we'll pass ownership of the cgroup to the user of the new process. On cgroupsv1
* this is only about systemd's own hierarchy, i.e. not the controller hierarchies, simply because that's not
* safe. On cgroupsv2 there's only one hierarchy anyway, and delegation is safe there, hence in that case only
* touch a single hierarchy too. */
if (params->cgroup_path && context->user && (params->flags & EXEC_CGROUP_DELEGATE)) {
r = cg_set_access(SYSTEMD_CGROUP_CONTROLLER, params->cgroup_path, uid, gid);
if (r < 0) {
*exit_status = EXIT_CGROUP;
return log_unit_error_errno(unit, r, "Failed to adjust control group access: %m");
}
}
for (dt = 0; dt < _EXEC_DIRECTORY_TYPE_MAX; dt++) {
r = setup_exec_directory(context, params, uid, gid, dt, exit_status);
if (r < 0)
return log_unit_error_errno(unit, r, "Failed to set up special execution directory in %s: %m", params->prefix[dt]);
}
r = build_environment(
unit,
context,
params,
n_fds,
home,
username,
shell,
journal_stream_dev,
journal_stream_ino,
&our_env);
if (r < 0) {
*exit_status = EXIT_MEMORY;
return log_oom();
}
r = build_pass_environment(context, &pass_env);
if (r < 0) {
*exit_status = EXIT_MEMORY;
return log_oom();
}
accum_env = strv_env_merge(5,
params->environment,
our_env,
pass_env,
context->environment,
files_env,
NULL);
if (!accum_env) {
*exit_status = EXIT_MEMORY;
return log_oom();
}
accum_env = strv_env_clean(accum_env);
(void) umask(context->umask);
r = setup_keyring(unit, context, params, uid, gid);
if (r < 0) {
*exit_status = EXIT_KEYRING;
return log_unit_error_errno(unit, r, "Failed to set up kernel keyring: %m");
}
/* We need sandboxing if the caller asked us to apply it and the command isn't explicitly excepted from it */
needs_sandboxing = (params->flags & EXEC_APPLY_SANDBOXING) && !(command->flags & EXEC_COMMAND_FULLY_PRIVILEGED);
/* We need the ambient capability hack, if the caller asked us to apply it and the command is marked for it, and the kernel doesn't actually support ambient caps */
needs_ambient_hack = (params->flags & EXEC_APPLY_SANDBOXING) && (command->flags & EXEC_COMMAND_AMBIENT_MAGIC) && !ambient_capabilities_supported();
/* We need setresuid() if the caller asked us to apply sandboxing and the command isn't explicitly excepted from either whole sandboxing or just setresuid() itself, and the ambient hack is not desired */
if (needs_ambient_hack)
needs_setuid = false;
else
needs_setuid = (params->flags & EXEC_APPLY_SANDBOXING) && !(command->flags & (EXEC_COMMAND_FULLY_PRIVILEGED|EXEC_COMMAND_NO_SETUID));
if (needs_sandboxing) {
/* MAC enablement checks need to be done before a new mount ns is created, as they rely on /sys being
* present. The actual MAC context application will happen later, as late as possible, to avoid
* impacting our own code paths. */
#if HAVE_SELINUX
use_selinux = mac_selinux_use();
#endif
#if ENABLE_SMACK
use_smack = mac_smack_use();
#endif
#if HAVE_APPARMOR
use_apparmor = mac_apparmor_use();
#endif
}
if (needs_setuid) {
if (context->pam_name && username) {
r = setup_pam(context->pam_name, username, uid, gid, context->tty_path, &accum_env, fds, n_fds);
if (r < 0) {
*exit_status = EXIT_PAM;
return log_unit_error_errno(unit, r, "Failed to set up PAM session: %m");
}
}
}
if (context->private_network && runtime && runtime->netns_storage_socket[0] >= 0) {
if (ns_type_supported(NAMESPACE_NET)) {
r = setup_netns(runtime->netns_storage_socket);
if (r < 0) {
*exit_status = EXIT_NETWORK;
return log_unit_error_errno(unit, r, "Failed to set up network namespacing: %m");
}
} else
log_unit_warning(unit, "PrivateNetwork=yes is configured, but the kernel does not support network namespaces, ignoring.");
}
needs_mount_namespace = exec_needs_mount_namespace(context, params, runtime);
if (needs_mount_namespace) {
r = apply_mount_namespace(unit, command, context, params, runtime);
if (r < 0) {
*exit_status = EXIT_NAMESPACE;
return log_unit_error_errno(unit, r, "Failed to set up mount namespacing: %m");
}
}
/* Apply just after mount namespace setup */
r = apply_working_directory(context, params, home, needs_mount_namespace, exit_status);
if (r < 0)
return log_unit_error_errno(unit, r, "Changing to the requested working directory failed: %m");
/* Drop groups as early as possbile */
if (needs_setuid) {
r = enforce_groups(gid, supplementary_gids, ngids);
if (r < 0) {
*exit_status = EXIT_GROUP;
return log_unit_error_errno(unit, r, "Changing group credentials failed: %m");
}
}
if (needs_sandboxing) {
#if HAVE_SELINUX
if (use_selinux && params->selinux_context_net && socket_fd >= 0) {
r = mac_selinux_get_child_mls_label(socket_fd, command->path, context->selinux_context, &mac_selinux_context_net);
if (r < 0) {
*exit_status = EXIT_SELINUX_CONTEXT;
return log_unit_error_errno(unit, r, "Failed to determine SELinux context: %m");
}
}
#endif
if (context->private_users) {
r = setup_private_users(uid, gid);
if (r < 0) {
*exit_status = EXIT_USER;
return log_unit_error_errno(unit, r, "Failed to set up user namespacing: %m");
}
}
}
/* We repeat the fd closing here, to make sure that nothing is leaked from the PAM modules. Note that we are
* more aggressive this time since socket_fd and the netns fds we don't need anymore. We do keep the exec_fd
* however if we have it as we want to keep it open until the final execve(). */
if (params->exec_fd >= 0) {
exec_fd = params->exec_fd;
if (exec_fd < 3 + (int) n_fds) {
int moved_fd;
/* Let's move the exec fd far up, so that it's outside of the fd range we want to pass to the
* process we are about to execute. */
moved_fd = fcntl(exec_fd, F_DUPFD_CLOEXEC, 3 + (int) n_fds);
if (moved_fd < 0) {
*exit_status = EXIT_FDS;
return log_unit_error_errno(unit, errno, "Couldn't move exec fd up: %m");
}
safe_close(exec_fd);
exec_fd = moved_fd;
} else {
/* This fd should be FD_CLOEXEC already, but let's make sure. */
r = fd_cloexec(exec_fd, true);
if (r < 0) {
*exit_status = EXIT_FDS;
return log_unit_error_errno(unit, r, "Failed to make exec fd FD_CLOEXEC: %m");
}
}
fds_with_exec_fd = newa(int, n_fds + 1);
memcpy(fds_with_exec_fd, fds, n_fds * sizeof(int));
fds_with_exec_fd[n_fds] = exec_fd;
n_fds_with_exec_fd = n_fds + 1;
} else {
fds_with_exec_fd = fds;
n_fds_with_exec_fd = n_fds;
}
r = close_all_fds(fds_with_exec_fd, n_fds_with_exec_fd);
if (r >= 0)
r = shift_fds(fds, n_fds);
if (r >= 0)
r = flags_fds(fds, n_socket_fds, n_storage_fds, context->non_blocking);
if (r < 0) {
*exit_status = EXIT_FDS;
return log_unit_error_errno(unit, r, "Failed to adjust passed file descriptors: %m");
}
/* At this point, the fds we want to pass to the program are all ready and set up, with O_CLOEXEC turned off
* and at the right fd numbers. The are no other fds open, with one exception: the exec_fd if it is defined,
* and it has O_CLOEXEC set, after all we want it to be closed by the execve(), so that our parent knows we
* came this far. */
secure_bits = context->secure_bits;
if (needs_sandboxing) {
uint64_t bset;
int which_failed;
r = setrlimit_closest_all((const struct rlimit* const *) context->rlimit, &which_failed);
if (r < 0) {
*exit_status = EXIT_LIMITS;
return log_unit_error_errno(unit, r, "Failed to adjust resource limit RLIMIT_%s: %m", rlimit_to_string(which_failed));
}
/* Set the RTPRIO resource limit to 0, but only if nothing else was explicitly requested. */
if (context->restrict_realtime && !context->rlimit[RLIMIT_RTPRIO]) {
if (setrlimit(RLIMIT_RTPRIO, &RLIMIT_MAKE_CONST(0)) < 0) {
*exit_status = EXIT_LIMITS;
return log_unit_error_errno(unit, errno, "Failed to adjust RLIMIT_RTPRIO resource limit: %m");
}
}
#if ENABLE_SMACK
/* LSM Smack needs the capability CAP_MAC_ADMIN to change the current execution security context of the
* process. This is the latest place before dropping capabilities. Other MAC context are set later. */
if (use_smack) {
r = setup_smack(context, command);
if (r < 0) {
*exit_status = EXIT_SMACK_PROCESS_LABEL;
return log_unit_error_errno(unit, r, "Failed to set SMACK process label: %m");
}
}
#endif
bset = context->capability_bounding_set;
/* If the ambient caps hack is enabled (which means the kernel can't do them, and the user asked for
* our magic fallback), then let's add some extra caps, so that the service can drop privs of its own,
* instead of us doing that */
if (needs_ambient_hack)
bset |= (UINT64_C(1) << CAP_SETPCAP) |
(UINT64_C(1) << CAP_SETUID) |
(UINT64_C(1) << CAP_SETGID);
if (!cap_test_all(bset)) {
r = capability_bounding_set_drop(bset, false);
if (r < 0) {
*exit_status = EXIT_CAPABILITIES;
return log_unit_error_errno(unit, r, "Failed to drop capabilities: %m");
}
}
/* This is done before enforce_user, but ambient set
* does not survive over setresuid() if keep_caps is not set. */
if (!needs_ambient_hack &&
context->capability_ambient_set != 0) {
r = capability_ambient_set_apply(context->capability_ambient_set, true);
if (r < 0) {
*exit_status = EXIT_CAPABILITIES;
return log_unit_error_errno(unit, r, "Failed to apply ambient capabilities (before UID change): %m");
}
}
}
if (needs_setuid) {
if (context->user) {
r = enforce_user(context, uid);
if (r < 0) {
*exit_status = EXIT_USER;
return log_unit_error_errno(unit, r, "Failed to change UID to " UID_FMT ": %m", uid);
}
if (!needs_ambient_hack &&
context->capability_ambient_set != 0) {
/* Fix the ambient capabilities after user change. */
r = capability_ambient_set_apply(context->capability_ambient_set, false);
if (r < 0) {
*exit_status = EXIT_CAPABILITIES;
return log_unit_error_errno(unit, r, "Failed to apply ambient capabilities (after UID change): %m");
}
/* If we were asked to change user and ambient capabilities
* were requested, we had to add keep-caps to the securebits
* so that we would maintain the inherited capability set
* through the setresuid(). Make sure that the bit is added
* also to the context secure_bits so that we don't try to
* drop the bit away next. */
secure_bits |= 1<<SECURE_KEEP_CAPS;
}
}
}
if (needs_sandboxing) {
/* Apply other MAC contexts late, but before seccomp syscall filtering, as those should really be last to
* influence our own codepaths as little as possible. Moreover, applying MAC contexts usually requires
* syscalls that are subject to seccomp filtering, hence should probably be applied before the syscalls
* are restricted. */
#if HAVE_SELINUX
if (use_selinux) {
char *exec_context = mac_selinux_context_net ?: context->selinux_context;
if (exec_context) {
r = setexeccon(exec_context);
if (r < 0) {
*exit_status = EXIT_SELINUX_CONTEXT;
return log_unit_error_errno(unit, r, "Failed to change SELinux context to %s: %m", exec_context);
}
}
}
#endif
#if HAVE_APPARMOR
if (use_apparmor && context->apparmor_profile) {
r = aa_change_onexec(context->apparmor_profile);
if (r < 0 && !context->apparmor_profile_ignore) {
*exit_status = EXIT_APPARMOR_PROFILE;
return log_unit_error_errno(unit, errno, "Failed to prepare AppArmor profile change to %s: %m", context->apparmor_profile);
}
}
#endif
/* PR_GET_SECUREBITS is not privileged, while PR_SET_SECUREBITS is. So to suppress potential EPERMs
* we'll try not to call PR_SET_SECUREBITS unless necessary. */
if (prctl(PR_GET_SECUREBITS) != secure_bits)
if (prctl(PR_SET_SECUREBITS, secure_bits) < 0) {
*exit_status = EXIT_SECUREBITS;
return log_unit_error_errno(unit, errno, "Failed to set process secure bits: %m");
}
if (context_has_no_new_privileges(context))
if (prctl(PR_SET_NO_NEW_PRIVS, 1, 0, 0, 0) < 0) {
*exit_status = EXIT_NO_NEW_PRIVILEGES;
return log_unit_error_errno(unit, errno, "Failed to disable new privileges: %m");
}
#if HAVE_SECCOMP
r = apply_address_families(unit, context);
if (r < 0) {
*exit_status = EXIT_ADDRESS_FAMILIES;
return log_unit_error_errno(unit, r, "Failed to restrict address families: %m");
}
r = apply_memory_deny_write_execute(unit, context);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to disable writing to executable memory: %m");
}
r = apply_restrict_realtime(unit, context);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to apply realtime restrictions: %m");
}
r = apply_restrict_suid_sgid(unit, context);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to apply SUID/SGID restrictions: %m");
}
r = apply_restrict_namespaces(unit, context);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to apply namespace restrictions: %m");
}
r = apply_protect_sysctl(unit, context);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to apply sysctl restrictions: %m");
}
r = apply_protect_kernel_modules(unit, context);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to apply module loading restrictions: %m");
}
r = apply_private_devices(unit, context);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to set up private devices: %m");
}
r = apply_syscall_archs(unit, context);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to apply syscall architecture restrictions: %m");
}
r = apply_lock_personality(unit, context);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to lock personalities: %m");
}
/* This really should remain the last step before the execve(), to make sure our own code is unaffected
* by the filter as little as possible. */
r = apply_syscall_filter(unit, context, needs_ambient_hack);
if (r < 0) {
*exit_status = EXIT_SECCOMP;
return log_unit_error_errno(unit, r, "Failed to apply system call filters: %m");
}
#endif
}
if (!strv_isempty(context->unset_environment)) {
char **ee = NULL;
ee = strv_env_delete(accum_env, 1, context->unset_environment);
if (!ee) {
*exit_status = EXIT_MEMORY;
return log_oom();
}
strv_free_and_replace(accum_env, ee);
}
final_argv = replace_env_argv(argv, accum_env);
if (!final_argv) {
*exit_status = EXIT_MEMORY;
return log_oom();
}
if (DEBUG_LOGGING) {
_cleanup_free_ char *line;
line = exec_command_line(final_argv);
if (line)
log_struct(LOG_DEBUG,
"EXECUTABLE=%s", command->path,
LOG_UNIT_MESSAGE(unit, "Executing: %s", line),
LOG_UNIT_ID(unit),
LOG_UNIT_INVOCATION_ID(unit));
}
if (exec_fd >= 0) {
uint8_t hot = 1;
/* We have finished with all our initializations. Let's now let the manager know that. From this point
* on, if the manager sees POLLHUP on the exec_fd, then execve() was successful. */
if (write(exec_fd, &hot, sizeof(hot)) < 0) {
*exit_status = EXIT_EXEC;
return log_unit_error_errno(unit, errno, "Failed to enable exec_fd: %m");
}
}
execve(command->path, final_argv, accum_env);
r = -errno;
if (exec_fd >= 0) {
uint8_t hot = 0;
/* The execve() failed. This means the exec_fd is still open. Which means we need to tell the manager
* that POLLHUP on it no longer means execve() succeeded. */
if (write(exec_fd, &hot, sizeof(hot)) < 0) {
*exit_status = EXIT_EXEC;
return log_unit_error_errno(unit, errno, "Failed to disable exec_fd: %m");
}
}
if (r == -ENOENT && (command->flags & EXEC_COMMAND_IGNORE_FAILURE)) {
log_struct_errno(LOG_INFO, r,
"MESSAGE_ID=" SD_MESSAGE_SPAWN_FAILED_STR,
LOG_UNIT_ID(unit),
LOG_UNIT_INVOCATION_ID(unit),
LOG_UNIT_MESSAGE(unit, "Executable %s missing, skipping: %m",
command->path),
"EXECUTABLE=%s", command->path);
return 0;
}
*exit_status = EXIT_EXEC;
return log_unit_error_errno(unit, r, "Failed to execute command: %m");
}
static int exec_context_load_environment(const Unit *unit, const ExecContext *c, char ***l);
static int exec_context_named_iofds(const ExecContext *c, const ExecParameters *p, int named_iofds[3]);
int exec_spawn(Unit *unit,
ExecCommand *command,
const ExecContext *context,
const ExecParameters *params,
ExecRuntime *runtime,
DynamicCreds *dcreds,
pid_t *ret) {
_cleanup_strv_free_ char **files_env = NULL;
int *fds = NULL;
size_t n_storage_fds = 0, n_socket_fds = 0;
_cleanup_free_ char *line = NULL;
int socket_fd, r;
int named_iofds[3] = { -1, -1, -1 };
char **argv;
pid_t pid;
assert(unit);
assert(command);
assert(context);
assert(ret);
assert(params);
assert(params->fds || (params->n_socket_fds + params->n_storage_fds <= 0));
if (context->std_input == EXEC_INPUT_SOCKET ||
context->std_output == EXEC_OUTPUT_SOCKET ||
context->std_error == EXEC_OUTPUT_SOCKET) {
if (params->n_socket_fds > 1) {
log_unit_error(unit, "Got more than one socket.");
return -EINVAL;
}
if (params->n_socket_fds == 0) {
log_unit_error(unit, "Got no socket.");
return -EINVAL;
}
socket_fd = params->fds[0];
} else {
socket_fd = -1;
fds = params->fds;
n_socket_fds = params->n_socket_fds;
n_storage_fds = params->n_storage_fds;
}
r = exec_context_named_iofds(context, params, named_iofds);
if (r < 0)
return log_unit_error_errno(unit, r, "Failed to load a named file descriptor: %m");
r = exec_context_load_environment(unit, context, &files_env);
if (r < 0)
return log_unit_error_errno(unit, r, "Failed to load environment files: %m");
argv = params->argv ?: command->argv;
line = exec_command_line(argv);
if (!line)
return log_oom();
log_struct(LOG_DEBUG,
LOG_UNIT_MESSAGE(unit, "About to execute: %s", line),
"EXECUTABLE=%s", command->path,
LOG_UNIT_ID(unit),
LOG_UNIT_INVOCATION_ID(unit));
pid = fork();
if (pid < 0)
return log_unit_error_errno(unit, errno, "Failed to fork: %m");
if (pid == 0) {
int exit_status = EXIT_SUCCESS;
r = exec_child(unit,
command,
context,
params,
runtime,
dcreds,
argv,
socket_fd,
named_iofds,
fds,
n_socket_fds,
n_storage_fds,
files_env,
unit->manager->user_lookup_fds[1],
&exit_status);
if (r < 0)
log_struct_errno(LOG_ERR, r,
"MESSAGE_ID=" SD_MESSAGE_SPAWN_FAILED_STR,
LOG_UNIT_ID(unit),
LOG_UNIT_INVOCATION_ID(unit),
LOG_UNIT_MESSAGE(unit, "Failed at step %s spawning %s: %m",
exit_status_to_string(exit_status, EXIT_STATUS_SYSTEMD),
command->path),
"EXECUTABLE=%s", command->path);
_exit(exit_status);
}
log_unit_debug(unit, "Forked %s as "PID_FMT, command->path, pid);
/* We add the new process to the cgroup both in the child (so
* that we can be sure that no user code is ever executed
* outside of the cgroup) and in the parent (so that we can be
* sure that when we kill the cgroup the process will be
* killed too). */
if (params->cgroup_path)
(void) cg_attach(SYSTEMD_CGROUP_CONTROLLER, params->cgroup_path, pid);
exec_status_start(&command->exec_status, pid);
*ret = pid;
return 0;
}
void exec_context_init(ExecContext *c) {
ExecDirectoryType i;
assert(c);
c->umask = 0022;
c->ioprio = IOPRIO_PRIO_VALUE(IOPRIO_CLASS_BE, 0);
c->cpu_sched_policy = SCHED_OTHER;
c->syslog_priority = LOG_DAEMON|LOG_INFO;
c->syslog_level_prefix = true;
c->ignore_sigpipe = true;
c->timer_slack_nsec = NSEC_INFINITY;
c->personality = PERSONALITY_INVALID;
for (i = 0; i < _EXEC_DIRECTORY_TYPE_MAX; i++)
c->directories[i].mode = 0755;
c->capability_bounding_set = CAP_ALL;
assert_cc(NAMESPACE_FLAGS_INITIAL != NAMESPACE_FLAGS_ALL);
c->restrict_namespaces = NAMESPACE_FLAGS_INITIAL;
c->log_level_max = -1;
numa_policy_reset(&c->numa_policy);
}
void exec_context_done(ExecContext *c) {
ExecDirectoryType i;
size_t l;
assert(c);
c->environment = strv_free(c->environment);
c->environment_files = strv_free(c->environment_files);
c->pass_environment = strv_free(c->pass_environment);
c->unset_environment = strv_free(c->unset_environment);
rlimit_free_all(c->rlimit);
for (l = 0; l < 3; l++) {
c->stdio_fdname[l] = mfree(c->stdio_fdname[l]);
c->stdio_file[l] = mfree(c->stdio_file[l]);
}
c->working_directory = mfree(c->working_directory);
c->root_directory = mfree(c->root_directory);
c->root_image = mfree(c->root_image);
c->tty_path = mfree(c->tty_path);
c->syslog_identifier = mfree(c->syslog_identifier);
c->user = mfree(c->user);
c->group = mfree(c->group);
c->supplementary_groups = strv_free(c->supplementary_groups);
c->pam_name = mfree(c->pam_name);
c->read_only_paths = strv_free(c->read_only_paths);
c->read_write_paths = strv_free(c->read_write_paths);
c->inaccessible_paths = strv_free(c->inaccessible_paths);
bind_mount_free_many(c->bind_mounts, c->n_bind_mounts);
c->bind_mounts = NULL;
c->n_bind_mounts = 0;
temporary_filesystem_free_many(c->temporary_filesystems, c->n_temporary_filesystems);
c->temporary_filesystems = NULL;
c->n_temporary_filesystems = 0;
cpu_set_reset(&c->cpu_set);
numa_policy_reset(&c->numa_policy);
c->utmp_id = mfree(c->utmp_id);
c->selinux_context = mfree(c->selinux_context);
c->apparmor_profile = mfree(c->apparmor_profile);
c->smack_process_label = mfree(c->smack_process_label);
c->syscall_filter = hashmap_free(c->syscall_filter);
c->syscall_archs = set_free(c->syscall_archs);
c->address_families = set_free(c->address_families);
for (i = 0; i < _EXEC_DIRECTORY_TYPE_MAX; i++)
c->directories[i].paths = strv_free(c->directories[i].paths);
c->log_level_max = -1;
exec_context_free_log_extra_fields(c);
c->log_rate_limit_interval_usec = 0;
c->log_rate_limit_burst = 0;
c->stdin_data = mfree(c->stdin_data);
c->stdin_data_size = 0;
}
int exec_context_destroy_runtime_directory(const ExecContext *c, const char *runtime_prefix) {
char **i;
assert(c);
if (!runtime_prefix)
return 0;
STRV_FOREACH(i, c->directories[EXEC_DIRECTORY_RUNTIME].paths) {
_cleanup_free_ char *p;
p = strjoin(runtime_prefix, "/", *i);
if (!p)
return -ENOMEM;
/* We execute this synchronously, since we need to be sure this is gone when we start the service
* next. */
(void) rm_rf(p, REMOVE_ROOT);
}
return 0;
}
static void exec_command_done(ExecCommand *c) {
assert(c);
c->path = mfree(c->path);
c->argv = strv_free(c->argv);
}
void exec_command_done_array(ExecCommand *c, size_t n) {
size_t i;
for (i = 0; i < n; i++)
exec_command_done(c+i);
}
ExecCommand* exec_command_free_list(ExecCommand *c) {
ExecCommand *i;
while ((i = c)) {
LIST_REMOVE(command, c, i);
exec_command_done(i);
free(i);
}
return NULL;
}
void exec_command_free_array(ExecCommand **c, size_t n) {
size_t i;
for (i = 0; i < n; i++)
c[i] = exec_command_free_list(c[i]);
}
typedef struct InvalidEnvInfo {
const Unit *unit;
const char *path;
} InvalidEnvInfo;
static void invalid_env(const char *p, void *userdata) {
InvalidEnvInfo *info = userdata;
log_unit_error(info->unit, "Ignoring invalid environment assignment '%s': %s", p, info->path);
}
const char* exec_context_fdname(const ExecContext *c, int fd_index) {
assert(c);
switch (fd_index) {
case STDIN_FILENO:
if (c->std_input != EXEC_INPUT_NAMED_FD)
return NULL;
return c->stdio_fdname[STDIN_FILENO] ?: "stdin";
case STDOUT_FILENO:
if (c->std_output != EXEC_OUTPUT_NAMED_FD)
return NULL;
return c->stdio_fdname[STDOUT_FILENO] ?: "stdout";
case STDERR_FILENO:
if (c->std_error != EXEC_OUTPUT_NAMED_FD)
return NULL;
return c->stdio_fdname[STDERR_FILENO] ?: "stderr";
default:
return NULL;
}
}
static int exec_context_named_iofds(const ExecContext *c, const ExecParameters *p, int named_iofds[3]) {
size_t i, targets;
const char* stdio_fdname[3];
size_t n_fds;
assert(c);
assert(p);
targets = (c->std_input == EXEC_INPUT_NAMED_FD) +
(c->std_output == EXEC_OUTPUT_NAMED_FD) +
(c->std_error == EXEC_OUTPUT_NAMED_FD);
for (i = 0; i < 3; i++)
stdio_fdname[i] = exec_context_fdname(c, i);
n_fds = p->n_storage_fds + p->n_socket_fds;
for (i = 0; i < n_fds && targets > 0; i++)
if (named_iofds[STDIN_FILENO] < 0 &&
c->std_input == EXEC_INPUT_NAMED_FD &&
stdio_fdname[STDIN_FILENO] &&
streq(p->fd_names[i], stdio_fdname[STDIN_FILENO])) {
named_iofds[STDIN_FILENO] = p->fds[i];
targets--;
} else if (named_iofds[STDOUT_FILENO] < 0 &&
c->std_output == EXEC_OUTPUT_NAMED_FD &&
stdio_fdname[STDOUT_FILENO] &&
streq(p->fd_names[i], stdio_fdname[STDOUT_FILENO])) {
named_iofds[STDOUT_FILENO] = p->fds[i];
targets--;
} else if (named_iofds[STDERR_FILENO] < 0 &&
c->std_error == EXEC_OUTPUT_NAMED_FD &&
stdio_fdname[STDERR_FILENO] &&
streq(p->fd_names[i], stdio_fdname[STDERR_FILENO])) {
named_iofds[STDERR_FILENO] = p->fds[i];
targets--;
}
return targets == 0 ? 0 : -ENOENT;
}
static int exec_context_load_environment(const Unit *unit, const ExecContext *c, char ***l) {
char **i, **r = NULL;
assert(c);
assert(l);
STRV_FOREACH(i, c->environment_files) {
char *fn;
int k;
unsigned n;
bool ignore = false;
char **p;
_cleanup_globfree_ glob_t pglob = {};
fn = *i;
if (fn[0] == '-') {
ignore = true;
fn++;
}
if (!path_is_absolute(fn)) {
if (ignore)
continue;
strv_free(r);
return -EINVAL;
}
/* Filename supports globbing, take all matching files */
k = safe_glob(fn, 0, &pglob);
if (k < 0) {
if (ignore)
continue;
strv_free(r);
return k;
}
/* When we don't match anything, -ENOENT should be returned */
assert(pglob.gl_pathc > 0);
for (n = 0; n < pglob.gl_pathc; n++) {
k = load_env_file(NULL, pglob.gl_pathv[n], NULL, &p);
if (k < 0) {
if (ignore)
continue;
strv_free(r);
return k;
}
/* Log invalid environment variables with filename */
if (p) {
InvalidEnvInfo info = {
.unit = unit,
.path = pglob.gl_pathv[n]
};
p = strv_env_clean_with_callback(p, invalid_env, &info);
}
if (!r)
r = p;
else {
char **m;
m = strv_env_merge(2, r, p);
strv_free(r);
strv_free(p);
if (!m)
return -ENOMEM;
r = m;
}
}
}
*l = r;
return 0;
}
static bool tty_may_match_dev_console(const char *tty) {
_cleanup_free_ char *resolved = NULL;
if (!tty)
return true;
tty = skip_dev_prefix(tty);
/* trivial identity? */
if (streq(tty, "console"))
return true;
if (resolve_dev_console(&resolved) < 0)
return true; /* if we could not resolve, assume it may */
/* "tty0" means the active VC, so it may be the same sometimes */
return streq(resolved, tty) || (streq(resolved, "tty0") && tty_is_vc(tty));
}
bool exec_context_may_touch_console(const ExecContext *ec) {
return (ec->tty_reset ||
ec->tty_vhangup ||
ec->tty_vt_disallocate ||
is_terminal_input(ec->std_input) ||
is_terminal_output(ec->std_output) ||
is_terminal_output(ec->std_error)) &&
tty_may_match_dev_console(exec_context_tty_path(ec));
}
static void strv_fprintf(FILE *f, char **l) {
char **g;
assert(f);
STRV_FOREACH(g, l)
fprintf(f, " %s", *g);
}
void exec_context_dump(const ExecContext *c, FILE* f, const char *prefix) {
ExecDirectoryType dt;
char **e, **d;
unsigned i;
int r;
assert(c);
assert(f);
prefix = strempty(prefix);
fprintf(f,
"%sUMask: %04o\n"
"%sWorkingDirectory: %s\n"
"%sRootDirectory: %s\n"
"%sNonBlocking: %s\n"
"%sPrivateTmp: %s\n"
"%sPrivateDevices: %s\n"
"%sProtectKernelTunables: %s\n"
"%sProtectKernelModules: %s\n"
"%sProtectControlGroups: %s\n"
"%sPrivateNetwork: %s\n"
"%sPrivateUsers: %s\n"
"%sProtectHome: %s\n"
"%sProtectSystem: %s\n"
"%sMountAPIVFS: %s\n"
"%sIgnoreSIGPIPE: %s\n"
"%sMemoryDenyWriteExecute: %s\n"
"%sRestrictRealtime: %s\n"
"%sRestrictSUIDSGID: %s\n"
"%sKeyringMode: %s\n",
prefix, c->umask,
prefix, c->working_directory ? c->working_directory : "/",
prefix, c->root_directory ? c->root_directory : "/",
prefix, yes_no(c->non_blocking),
prefix, yes_no(c->private_tmp),
prefix, yes_no(c->private_devices),
prefix, yes_no(c->protect_kernel_tunables),
prefix, yes_no(c->protect_kernel_modules),
prefix, yes_no(c->protect_control_groups),
prefix, yes_no(c->private_network),
prefix, yes_no(c->private_users),
prefix, protect_home_to_string(c->protect_home),
prefix, protect_system_to_string(c->protect_system),
prefix, yes_no(c->mount_apivfs),
prefix, yes_no(c->ignore_sigpipe),
prefix, yes_no(c->memory_deny_write_execute),
prefix, yes_no(c->restrict_realtime),
prefix, yes_no(c->restrict_suid_sgid),
prefix, exec_keyring_mode_to_string(c->keyring_mode));
if (c->root_image)
fprintf(f, "%sRootImage: %s\n", prefix, c->root_image);
STRV_FOREACH(e, c->environment)
fprintf(f, "%sEnvironment: %s\n", prefix, *e);
STRV_FOREACH(e, c->environment_files)
fprintf(f, "%sEnvironmentFile: %s\n", prefix, *e);
STRV_FOREACH(e, c->pass_environment)
fprintf(f, "%sPassEnvironment: %s\n", prefix, *e);
STRV_FOREACH(e, c->unset_environment)
fprintf(f, "%sUnsetEnvironment: %s\n", prefix, *e);
fprintf(f, "%sRuntimeDirectoryPreserve: %s\n", prefix, exec_preserve_mode_to_string(c->runtime_directory_preserve_mode));
for (dt = 0; dt < _EXEC_DIRECTORY_TYPE_MAX; dt++) {
fprintf(f, "%s%sMode: %04o\n", prefix, exec_directory_type_to_string(dt), c->directories[dt].mode);
STRV_FOREACH(d, c->directories[dt].paths)
fprintf(f, "%s%s: %s\n", prefix, exec_directory_type_to_string(dt), *d);
}
if (c->nice_set)
fprintf(f,
"%sNice: %i\n",
prefix, c->nice);
if (c->oom_score_adjust_set)
fprintf(f,
"%sOOMScoreAdjust: %i\n",
prefix, c->oom_score_adjust);
for (i = 0; i < RLIM_NLIMITS; i++)
if (c->rlimit[i]) {
fprintf(f, "Limit%s%s: " RLIM_FMT "\n",
prefix, rlimit_to_string(i), c->rlimit[i]->rlim_max);
fprintf(f, "Limit%s%sSoft: " RLIM_FMT "\n",
prefix, rlimit_to_string(i), c->rlimit[i]->rlim_cur);
}
if (c->ioprio_set) {
_cleanup_free_ char *class_str = NULL;
r = ioprio_class_to_string_alloc(IOPRIO_PRIO_CLASS(c->ioprio), &class_str);
if (r >= 0)
fprintf(f, "%sIOSchedulingClass: %s\n", prefix, class_str);
fprintf(f, "%sIOPriority: %lu\n", prefix, IOPRIO_PRIO_DATA(c->ioprio));
}
if (c->cpu_sched_set) {
_cleanup_free_ char *policy_str = NULL;
r = sched_policy_to_string_alloc(c->cpu_sched_policy, &policy_str);
if (r >= 0)
fprintf(f, "%sCPUSchedulingPolicy: %s\n", prefix, policy_str);
fprintf(f,
"%sCPUSchedulingPriority: %i\n"
"%sCPUSchedulingResetOnFork: %s\n",
prefix, c->cpu_sched_priority,
prefix, yes_no(c->cpu_sched_reset_on_fork));
}
if (c->cpu_set.set) {
_cleanup_free_ char *affinity = NULL;
affinity = cpu_set_to_range_string(&c->cpu_set);
fprintf(f, "%sCPUAffinity: %s\n", prefix, affinity);
}
if (mpol_is_valid(numa_policy_get_type(&c->numa_policy))) {
_cleanup_free_ char *nodes = NULL;
nodes = cpu_set_to_range_string(&c->numa_policy.nodes);
fprintf(f, "%sNUMAPolicy: %s\n", prefix, mpol_to_string(numa_policy_get_type(&c->numa_policy)));
fprintf(f, "%sNUMAMask: %s\n", prefix, strnull(nodes));
}
if (c->timer_slack_nsec != NSEC_INFINITY)
fprintf(f, "%sTimerSlackNSec: "NSEC_FMT "\n", prefix, c->timer_slack_nsec);
fprintf(f,
"%sStandardInput: %s\n"
"%sStandardOutput: %s\n"
"%sStandardError: %s\n",
prefix, exec_input_to_string(c->std_input),
prefix, exec_output_to_string(c->std_output),
prefix, exec_output_to_string(c->std_error));
if (c->std_input == EXEC_INPUT_NAMED_FD)
fprintf(f, "%sStandardInputFileDescriptorName: %s\n", prefix, c->stdio_fdname[STDIN_FILENO]);
if (c->std_output == EXEC_OUTPUT_NAMED_FD)
fprintf(f, "%sStandardOutputFileDescriptorName: %s\n", prefix, c->stdio_fdname[STDOUT_FILENO]);
if (c->std_error == EXEC_OUTPUT_NAMED_FD)
fprintf(f, "%sStandardErrorFileDescriptorName: %s\n", prefix, c->stdio_fdname[STDERR_FILENO]);
if (c->std_input == EXEC_INPUT_FILE)
fprintf(f, "%sStandardInputFile: %s\n", prefix, c->stdio_file[STDIN_FILENO]);
if (c->std_output == EXEC_OUTPUT_FILE)
fprintf(f, "%sStandardOutputFile: %s\n", prefix, c->stdio_file[STDOUT_FILENO]);
if (c->std_output == EXEC_OUTPUT_FILE_APPEND)
fprintf(f, "%sStandardOutputFileToAppend: %s\n", prefix, c->stdio_file[STDOUT_FILENO]);
if (c->std_error == EXEC_OUTPUT_FILE)
fprintf(f, "%sStandardErrorFile: %s\n", prefix, c->stdio_file[STDERR_FILENO]);
if (c->std_error == EXEC_OUTPUT_FILE_APPEND)
fprintf(f, "%sStandardErrorFileToAppend: %s\n", prefix, c->stdio_file[STDERR_FILENO]);
if (c->tty_path)
fprintf(f,
"%sTTYPath: %s\n"
"%sTTYReset: %s\n"
"%sTTYVHangup: %s\n"
"%sTTYVTDisallocate: %s\n",
prefix, c->tty_path,
prefix, yes_no(c->tty_reset),
prefix, yes_no(c->tty_vhangup),
prefix, yes_no(c->tty_vt_disallocate));
if (IN_SET(c->std_output,
EXEC_OUTPUT_SYSLOG,
EXEC_OUTPUT_KMSG,
EXEC_OUTPUT_JOURNAL,
EXEC_OUTPUT_SYSLOG_AND_CONSOLE,
EXEC_OUTPUT_KMSG_AND_CONSOLE,
EXEC_OUTPUT_JOURNAL_AND_CONSOLE) ||
IN_SET(c->std_error,
EXEC_OUTPUT_SYSLOG,
EXEC_OUTPUT_KMSG,
EXEC_OUTPUT_JOURNAL,
EXEC_OUTPUT_SYSLOG_AND_CONSOLE,
EXEC_OUTPUT_KMSG_AND_CONSOLE,
EXEC_OUTPUT_JOURNAL_AND_CONSOLE)) {
_cleanup_free_ char *fac_str = NULL, *lvl_str = NULL;
r = log_facility_unshifted_to_string_alloc(c->syslog_priority >> 3, &fac_str);
if (r >= 0)
fprintf(f, "%sSyslogFacility: %s\n", prefix, fac_str);
r = log_level_to_string_alloc(LOG_PRI(c->syslog_priority), &lvl_str);
if (r >= 0)
fprintf(f, "%sSyslogLevel: %s\n", prefix, lvl_str);
}
if (c->log_level_max >= 0) {
_cleanup_free_ char *t = NULL;
(void) log_level_to_string_alloc(c->log_level_max, &t);
fprintf(f, "%sLogLevelMax: %s\n", prefix, strna(t));
}
if (c->log_rate_limit_interval_usec > 0) {
char buf_timespan[FORMAT_TIMESPAN_MAX];
fprintf(f,
"%sLogRateLimitIntervalSec: %s\n",
prefix, format_timespan(buf_timespan, sizeof(buf_timespan), c->log_rate_limit_interval_usec, USEC_PER_SEC));
}
if (c->log_rate_limit_burst > 0)
fprintf(f, "%sLogRateLimitBurst: %u\n", prefix, c->log_rate_limit_burst);
if (c->n_log_extra_fields > 0) {
size_t j;
for (j = 0; j < c->n_log_extra_fields; j++) {
fprintf(f, "%sLogExtraFields: ", prefix);
fwrite(c->log_extra_fields[j].iov_base,
1, c->log_extra_fields[j].iov_len,
f);
fputc('\n', f);
}
}
if (c->secure_bits) {
_cleanup_free_ char *str = NULL;
r = secure_bits_to_string_alloc(c->secure_bits, &str);
if (r >= 0)
fprintf(f, "%sSecure Bits: %s\n", prefix, str);
}
if (c->capability_bounding_set != CAP_ALL) {
_cleanup_free_ char *str = NULL;
r = capability_set_to_string_alloc(c->capability_bounding_set, &str);
if (r >= 0)
fprintf(f, "%sCapabilityBoundingSet: %s\n", prefix, str);
}
if (c->capability_ambient_set != 0) {
_cleanup_free_ char *str = NULL;
r = capability_set_to_string_alloc(c->capability_ambient_set, &str);
if (r >= 0)
fprintf(f, "%sAmbientCapabilities: %s\n", prefix, str);
}
if (c->user)
fprintf(f, "%sUser: %s\n", prefix, c->user);
if (c->group)
fprintf(f, "%sGroup: %s\n", prefix, c->group);
fprintf(f, "%sDynamicUser: %s\n", prefix, yes_no(c->dynamic_user));
if (!strv_isempty(c->supplementary_groups)) {
fprintf(f, "%sSupplementaryGroups:", prefix);
strv_fprintf(f, c->supplementary_groups);
fputs("\n", f);
}
if (c->pam_name)
fprintf(f, "%sPAMName: %s\n", prefix, c->pam_name);
if (!strv_isempty(c->read_write_paths)) {
fprintf(f, "%sReadWritePaths:", prefix);
strv_fprintf(f, c->read_write_paths);
fputs("\n", f);
}
if (!strv_isempty(c->read_only_paths)) {
fprintf(f, "%sReadOnlyPaths:", prefix);
strv_fprintf(f, c->read_only_paths);
fputs("\n", f);
}
if (!strv_isempty(c->inaccessible_paths)) {
fprintf(f, "%sInaccessiblePaths:", prefix);
strv_fprintf(f, c->inaccessible_paths);
fputs("\n", f);
}
if (c->n_bind_mounts > 0)
for (i = 0; i < c->n_bind_mounts; i++)
fprintf(f, "%s%s: %s%s:%s:%s\n", prefix,
c->bind_mounts[i].read_only ? "BindReadOnlyPaths" : "BindPaths",
c->bind_mounts[i].ignore_enoent ? "-": "",
c->bind_mounts[i].source,
c->bind_mounts[i].destination,
c->bind_mounts[i].recursive ? "rbind" : "norbind");
if (c->n_temporary_filesystems > 0)
for (i = 0; i < c->n_temporary_filesystems; i++) {
TemporaryFileSystem *t = c->temporary_filesystems + i;
fprintf(f, "%sTemporaryFileSystem: %s%s%s\n", prefix,
t->path,
isempty(t->options) ? "" : ":",
strempty(t->options));
}
if (c->utmp_id)
fprintf(f,
"%sUtmpIdentifier: %s\n",
prefix, c->utmp_id);
if (c->selinux_context)
fprintf(f,
"%sSELinuxContext: %s%s\n",
prefix, c->selinux_context_ignore ? "-" : "", c->selinux_context);
if (c->apparmor_profile)
fprintf(f,
"%sAppArmorProfile: %s%s\n",
prefix, c->apparmor_profile_ignore ? "-" : "", c->apparmor_profile);
if (c->smack_process_label)
fprintf(f,
"%sSmackProcessLabel: %s%s\n",
prefix, c->smack_process_label_ignore ? "-" : "", c->smack_process_label);
if (c->personality != PERSONALITY_INVALID)
fprintf(f,
"%sPersonality: %s\n",
prefix, strna(personality_to_string(c->personality)));
fprintf(f,
"%sLockPersonality: %s\n",
prefix, yes_no(c->lock_personality));
if (c->syscall_filter) {
#if HAVE_SECCOMP
Iterator j;
void *id, *val;
bool first = true;
#endif
fprintf(f,
"%sSystemCallFilter: ",
prefix);
if (!c->syscall_whitelist)
fputc('~', f);
#if HAVE_SECCOMP
HASHMAP_FOREACH_KEY(val, id, c->syscall_filter, j) {
_cleanup_free_ char *name = NULL;
const char *errno_name = NULL;
int num = PTR_TO_INT(val);
if (first)
first = false;
else
fputc(' ', f);
name = seccomp_syscall_resolve_num_arch(SCMP_ARCH_NATIVE, PTR_TO_INT(id) - 1);
fputs(strna(name), f);
if (num >= 0) {
errno_name = errno_to_name(num);
if (errno_name)
fprintf(f, ":%s", errno_name);
else
fprintf(f, ":%d", num);
}
}
#endif
fputc('\n', f);
}
if (c->syscall_archs) {
#if HAVE_SECCOMP
Iterator j;
void *id;
#endif
fprintf(f,
"%sSystemCallArchitectures:",
prefix);
#if HAVE_SECCOMP
SET_FOREACH(id, c->syscall_archs, j)
fprintf(f, " %s", strna(seccomp_arch_to_string(PTR_TO_UINT32(id) - 1)));
#endif
fputc('\n', f);
}
if (exec_context_restrict_namespaces_set(c)) {
_cleanup_free_ char *s = NULL;
r = namespace_flags_to_string(c->restrict_namespaces, &s);
if (r >= 0)
fprintf(f, "%sRestrictNamespaces: %s\n",
prefix, s);
}
if (c->syscall_errno > 0) {
const char *errno_name;
fprintf(f, "%sSystemCallErrorNumber: ", prefix);
errno_name = errno_to_name(c->syscall_errno);
if (errno_name)
fprintf(f, "%s\n", errno_name);
else
fprintf(f, "%d\n", c->syscall_errno);
}
if (c->apparmor_profile)
fprintf(f,
"%sAppArmorProfile: %s%s\n",
prefix, c->apparmor_profile_ignore ? "-" : "", c->apparmor_profile);
}
bool exec_context_maintains_privileges(const ExecContext *c) {
assert(c);
/* Returns true if the process forked off would run under
* an unchanged UID or as root. */
if (!c->user)
return true;
if (streq(c->user, "root") || streq(c->user, "0"))
return true;
return false;
}
int exec_context_get_effective_ioprio(const ExecContext *c) {
int p;
assert(c);
if (c->ioprio_set)
return c->ioprio;
p = ioprio_get(IOPRIO_WHO_PROCESS, 0);
if (p < 0)
return IOPRIO_PRIO_VALUE(IOPRIO_CLASS_BE, 4);
return p;
}
void exec_context_free_log_extra_fields(ExecContext *c) {
size_t l;
assert(c);
for (l = 0; l < c->n_log_extra_fields; l++)
free(c->log_extra_fields[l].iov_base);
c->log_extra_fields = mfree(c->log_extra_fields);
c->n_log_extra_fields = 0;
}
void exec_status_start(ExecStatus *s, pid_t pid) {
assert(s);
zero(*s);
s->pid = pid;
dual_timestamp_get(&s->start_timestamp);
}
void exec_status_exit(ExecStatus *s, const ExecContext *context, pid_t pid, int code, int status) {
assert(s);
if (s->pid && s->pid != pid)
zero(*s);
s->pid = pid;
dual_timestamp_get(&s->exit_timestamp);
s->code = code;
s->status = status;
if (context) {
if (context->utmp_id)
utmp_put_dead_process(context->utmp_id, pid, code, status);
exec_context_tty_reset(context, NULL);
}
}
void exec_status_dump(const ExecStatus *s, FILE *f, const char *prefix) {
char buf[FORMAT_TIMESTAMP_MAX];
assert(s);
assert(f);
if (s->pid <= 0)
return;
prefix = strempty(prefix);
fprintf(f,
"%sPID: "PID_FMT"\n",
prefix, s->pid);
if (dual_timestamp_is_set(&s->start_timestamp))
fprintf(f,
"%sStart Timestamp: %s\n",
prefix, format_timestamp(buf, sizeof(buf), s->start_timestamp.realtime));
if (dual_timestamp_is_set(&s->exit_timestamp))
fprintf(f,
"%sExit Timestamp: %s\n"
"%sExit Code: %s\n"
"%sExit Status: %i\n",
prefix, format_timestamp(buf, sizeof(buf), s->exit_timestamp.realtime),
prefix, sigchld_code_to_string(s->code),
prefix, s->status);
}
static char *exec_command_line(char **argv) {
size_t k;
char *n, *p, **a;
bool first = true;
assert(argv);
k = 1;
STRV_FOREACH(a, argv)
k += strlen(*a)+3;
n = new(char, k);
if (!n)
return NULL;
p = n;
STRV_FOREACH(a, argv) {
if (!first)
*(p++) = ' ';
else
first = false;
if (strpbrk(*a, WHITESPACE)) {
*(p++) = '\'';
p = stpcpy(p, *a);
*(p++) = '\'';
} else
p = stpcpy(p, *a);
}
*p = 0;
/* FIXME: this doesn't really handle arguments that have
* spaces and ticks in them */
return n;
}
static void exec_command_dump(ExecCommand *c, FILE *f, const char *prefix) {
_cleanup_free_ char *cmd = NULL;
const char *prefix2;
assert(c);
assert(f);
prefix = strempty(prefix);
prefix2 = strjoina(prefix, "\t");
cmd = exec_command_line(c->argv);
fprintf(f,
"%sCommand Line: %s\n",
prefix, cmd ? cmd : strerror(ENOMEM));
exec_status_dump(&c->exec_status, f, prefix2);
}
void exec_command_dump_list(ExecCommand *c, FILE *f, const char *prefix) {
assert(f);
prefix = strempty(prefix);
LIST_FOREACH(command, c, c)
exec_command_dump(c, f, prefix);
}
void exec_command_append_list(ExecCommand **l, ExecCommand *e) {
ExecCommand *end;
assert(l);
assert(e);
if (*l) {
/* It's kind of important, that we keep the order here */
LIST_FIND_TAIL(command, *l, end);
LIST_INSERT_AFTER(command, *l, end, e);
} else
*l = e;
}
int exec_command_set(ExecCommand *c, const char *path, ...) {
va_list ap;
char **l, *p;
assert(c);
assert(path);
va_start(ap, path);
l = strv_new_ap(path, ap);
va_end(ap);
if (!l)
return -ENOMEM;
p = strdup(path);
if (!p) {
strv_free(l);
return -ENOMEM;
}
free(c->path);
c->path = p;
return strv_free_and_replace(c->argv, l);
}
int exec_command_append(ExecCommand *c, const char *path, ...) {
_cleanup_strv_free_ char **l = NULL;
va_list ap;
int r;
assert(c);
assert(path);
va_start(ap, path);
l = strv_new_ap(path, ap);
va_end(ap);
if (!l)
return -ENOMEM;
r = strv_extend_strv(&c->argv, l, false);
if (r < 0)
return r;
return 0;
}
static void *remove_tmpdir_thread(void *p) {
_cleanup_free_ char *path = p;
(void) rm_rf(path, REMOVE_ROOT|REMOVE_PHYSICAL);
return NULL;
}
static ExecRuntime* exec_runtime_free(ExecRuntime *rt, bool destroy) {
int r;
if (!rt)
return NULL;
if (rt->manager)
(void) hashmap_remove(rt->manager->exec_runtime_by_id, rt->id);
/* When destroy is true, then rm_rf tmp_dir and var_tmp_dir. */
if (destroy && rt->tmp_dir) {
log_debug("Spawning thread to nuke %s", rt->tmp_dir);
r = asynchronous_job(remove_tmpdir_thread, rt->tmp_dir);
if (r < 0) {
log_warning_errno(r, "Failed to nuke %s: %m", rt->tmp_dir);
free(rt->tmp_dir);
}
rt->tmp_dir = NULL;
}
if (destroy && rt->var_tmp_dir) {
log_debug("Spawning thread to nuke %s", rt->var_tmp_dir);
r = asynchronous_job(remove_tmpdir_thread, rt->var_tmp_dir);
if (r < 0) {
log_warning_errno(r, "Failed to nuke %s: %m", rt->var_tmp_dir);
free(rt->var_tmp_dir);
}
rt->var_tmp_dir = NULL;
}
rt->id = mfree(rt->id);
rt->tmp_dir = mfree(rt->tmp_dir);
rt->var_tmp_dir = mfree(rt->var_tmp_dir);
safe_close_pair(rt->netns_storage_socket);
return mfree(rt);
}
static void exec_runtime_freep(ExecRuntime **rt) {
if (*rt)
(void) exec_runtime_free(*rt, false);
}
static int exec_runtime_allocate(ExecRuntime **rt) {
assert(rt);
*rt = new0(ExecRuntime, 1);
if (!*rt)
return -ENOMEM;
(*rt)->netns_storage_socket[0] = (*rt)->netns_storage_socket[1] = -1;
return 0;
}
static int exec_runtime_add(
Manager *m,
const char *id,
const char *tmp_dir,
const char *var_tmp_dir,
const int netns_storage_socket[2],
ExecRuntime **ret) {
_cleanup_(exec_runtime_freep) ExecRuntime *rt = NULL;
int r;
assert(m);
assert(id);
r = hashmap_ensure_allocated(&m->exec_runtime_by_id, &string_hash_ops);
if (r < 0)
return r;
r = exec_runtime_allocate(&rt);
if (r < 0)
return r;
rt->id = strdup(id);
if (!rt->id)
return -ENOMEM;
if (tmp_dir) {
rt->tmp_dir = strdup(tmp_dir);
if (!rt->tmp_dir)
return -ENOMEM;
/* When tmp_dir is set, then we require var_tmp_dir is also set. */
assert(var_tmp_dir);
rt->var_tmp_dir = strdup(var_tmp_dir);
if (!rt->var_tmp_dir)
return -ENOMEM;
}
if (netns_storage_socket) {
rt->netns_storage_socket[0] = netns_storage_socket[0];
rt->netns_storage_socket[1] = netns_storage_socket[1];
}
r = hashmap_put(m->exec_runtime_by_id, rt->id, rt);
if (r < 0)
return r;
rt->manager = m;
if (ret)
*ret = rt;
/* do not remove created ExecRuntime object when the operation succeeds. */
rt = NULL;
return 0;
}
static int exec_runtime_make(Manager *m, const ExecContext *c, const char *id, ExecRuntime **ret) {
_cleanup_free_ char *tmp_dir = NULL, *var_tmp_dir = NULL;
_cleanup_close_pair_ int netns_storage_socket[2] = {-1, -1};
int r;
assert(m);
assert(c);
assert(id);
/* It is not necessary to create ExecRuntime object. */
if (!c->private_network && !c->private_tmp)
return 0;
if (c->private_tmp) {
r = setup_tmp_dirs(id, &tmp_dir, &var_tmp_dir);
if (r < 0)
return r;
}
if (c->private_network) {
if (socketpair(AF_UNIX, SOCK_DGRAM|SOCK_CLOEXEC, 0, netns_storage_socket) < 0)
return -errno;
}
r = exec_runtime_add(m, id, tmp_dir, var_tmp_dir, netns_storage_socket, ret);
if (r < 0)
return r;
/* Avoid cleanup */
netns_storage_socket[0] = -1;
netns_storage_socket[1] = -1;
return 1;
}
int exec_runtime_acquire(Manager *m, const ExecContext *c, const char *id, bool create, ExecRuntime **ret) {
ExecRuntime *rt;
int r;
assert(m);
assert(id);
assert(ret);
rt = hashmap_get(m->exec_runtime_by_id, id);
if (rt)
/* We already have a ExecRuntime object, let's increase the ref count and reuse it */
goto ref;
if (!create)
return 0;
/* If not found, then create a new object. */
r = exec_runtime_make(m, c, id, &rt);
if (r <= 0)
/* When r == 0, it is not necessary to create ExecRuntime object. */
return r;
ref:
/* increment reference counter. */
rt->n_ref++;
*ret = rt;
return 1;
}
ExecRuntime *exec_runtime_unref(ExecRuntime *rt, bool destroy) {
if (!rt)
return NULL;
assert(rt->n_ref > 0);
rt->n_ref--;
if (rt->n_ref > 0)
return NULL;
return exec_runtime_free(rt, destroy);
}
int exec_runtime_serialize(const Manager *m, FILE *f, FDSet *fds) {
ExecRuntime *rt;
Iterator i;
assert(m);
assert(f);
assert(fds);
HASHMAP_FOREACH(rt, m->exec_runtime_by_id, i) {
fprintf(f, "exec-runtime=%s", rt->id);
if (rt->tmp_dir)
fprintf(f, " tmp-dir=%s", rt->tmp_dir);
if (rt->var_tmp_dir)
fprintf(f, " var-tmp-dir=%s", rt->var_tmp_dir);
if (rt->netns_storage_socket[0] >= 0) {
int copy;
copy = fdset_put_dup(fds, rt->netns_storage_socket[0]);
if (copy < 0)
return copy;
fprintf(f, " netns-socket-0=%i", copy);
}
if (rt->netns_storage_socket[1] >= 0) {
int copy;
copy = fdset_put_dup(fds, rt->netns_storage_socket[1]);
if (copy < 0)
return copy;
fprintf(f, " netns-socket-1=%i", copy);
}
fputc('\n', f);
}
return 0;
}
int exec_runtime_deserialize_compat(Unit *u, const char *key, const char *value, FDSet *fds) {
_cleanup_(exec_runtime_freep) ExecRuntime *rt_create = NULL;
ExecRuntime *rt;
int r;
/* This is for the migration from old (v237 or earlier) deserialization text.
* Due to the bug #7790, this may not work with the units that use JoinsNamespaceOf=.
* Even if the ExecRuntime object originally created by the other unit, we cannot judge
* so or not from the serialized text, then we always creates a new object owned by this. */
assert(u);
assert(key);
assert(value);
/* Manager manages ExecRuntime objects by the unit id.
* So, we omit the serialized text when the unit does not have id (yet?)... */
if (isempty(u->id)) {
log_unit_debug(u, "Invocation ID not found. Dropping runtime parameter.");
return 0;
}
r = hashmap_ensure_allocated(&u->manager->exec_runtime_by_id, &string_hash_ops);
if (r < 0) {
log_unit_debug_errno(u, r, "Failed to allocate storage for runtime parameter: %m");
return 0;
}
rt = hashmap_get(u->manager->exec_runtime_by_id, u->id);
if (!rt) {
r = exec_runtime_allocate(&rt_create);
if (r < 0)
return log_oom();
rt_create->id = strdup(u->id);
if (!rt_create->id)
return log_oom();
rt = rt_create;
}
if (streq(key, "tmp-dir")) {
char *copy;
copy = strdup(value);
if (!copy)
return log_oom();
free_and_replace(rt->tmp_dir, copy);
} else if (streq(key, "var-tmp-dir")) {
char *copy;
copy = strdup(value);
if (!copy)
return log_oom();
free_and_replace(rt->var_tmp_dir, copy);
} else if (streq(key, "netns-socket-0")) {
int fd;
if (safe_atoi(value, &fd) < 0 || !fdset_contains(fds, fd)) {
log_unit_debug(u, "Failed to parse netns socket value: %s", value);
return 0;
}
safe_close(rt->netns_storage_socket[0]);
rt->netns_storage_socket[0] = fdset_remove(fds, fd);
} else if (streq(key, "netns-socket-1")) {
int fd;
if (safe_atoi(value, &fd) < 0 || !fdset_contains(fds, fd)) {
log_unit_debug(u, "Failed to parse netns socket value: %s", value);
return 0;
}
safe_close(rt->netns_storage_socket[1]);
rt->netns_storage_socket[1] = fdset_remove(fds, fd);
} else
return 0;
/* If the object is newly created, then put it to the hashmap which manages ExecRuntime objects. */
if (rt_create) {
r = hashmap_put(u->manager->exec_runtime_by_id, rt_create->id, rt_create);
if (r < 0) {
log_unit_debug_errno(u, r, "Failed to put runtime parameter to manager's storage: %m");
return 0;
}
rt_create->manager = u->manager;
/* Avoid cleanup */
rt_create = NULL;
}
return 1;
}
void exec_runtime_deserialize_one(Manager *m, const char *value, FDSet *fds) {
char *id = NULL, *tmp_dir = NULL, *var_tmp_dir = NULL;
int r, fd0 = -1, fd1 = -1;
const char *p, *v = value;
size_t n;
assert(m);
assert(value);
assert(fds);
n = strcspn(v, " ");
id = strndupa(v, n);
if (v[n] != ' ')
goto finalize;
p = v + n + 1;
v = startswith(p, "tmp-dir=");
if (v) {
n = strcspn(v, " ");
tmp_dir = strndupa(v, n);
if (v[n] != ' ')
goto finalize;
p = v + n + 1;
}
v = startswith(p, "var-tmp-dir=");
if (v) {
n = strcspn(v, " ");
var_tmp_dir = strndupa(v, n);
if (v[n] != ' ')
goto finalize;
p = v + n + 1;
}
v = startswith(p, "netns-socket-0=");
if (v) {
char *buf;
n = strcspn(v, " ");
buf = strndupa(v, n);
if (safe_atoi(buf, &fd0) < 0 || !fdset_contains(fds, fd0)) {
log_debug("Unable to process exec-runtime netns fd specification.");
return;
}
fd0 = fdset_remove(fds, fd0);
if (v[n] != ' ')
goto finalize;
p = v + n + 1;
}
v = startswith(p, "netns-socket-1=");
if (v) {
char *buf;
n = strcspn(v, " ");
buf = strndupa(v, n);
if (safe_atoi(buf, &fd1) < 0 || !fdset_contains(fds, fd1)) {
log_debug("Unable to process exec-runtime netns fd specification.");
return;
}
fd1 = fdset_remove(fds, fd1);
}
finalize:
r = exec_runtime_add(m, id, tmp_dir, var_tmp_dir, (int[]) { fd0, fd1 }, NULL);
if (r < 0) {
log_debug_errno(r, "Failed to add exec-runtime: %m");
return;
}
}
void exec_runtime_vacuum(Manager *m) {
ExecRuntime *rt;
Iterator i;
assert(m);
/* Free unreferenced ExecRuntime objects. This is used after manager deserialization process. */
HASHMAP_FOREACH(rt, m->exec_runtime_by_id, i) {
if (rt->n_ref > 0)
continue;
(void) exec_runtime_free(rt, false);
}
}
static const char* const exec_input_table[_EXEC_INPUT_MAX] = {
[EXEC_INPUT_NULL] = "null",
[EXEC_INPUT_TTY] = "tty",
[EXEC_INPUT_TTY_FORCE] = "tty-force",
[EXEC_INPUT_TTY_FAIL] = "tty-fail",
[EXEC_INPUT_SOCKET] = "socket",
[EXEC_INPUT_NAMED_FD] = "fd",
[EXEC_INPUT_DATA] = "data",
[EXEC_INPUT_FILE] = "file",
};
DEFINE_STRING_TABLE_LOOKUP(exec_input, ExecInput);
static const char* const exec_output_table[_EXEC_OUTPUT_MAX] = {
[EXEC_OUTPUT_INHERIT] = "inherit",
[EXEC_OUTPUT_NULL] = "null",
[EXEC_OUTPUT_TTY] = "tty",
[EXEC_OUTPUT_SYSLOG] = "syslog",
[EXEC_OUTPUT_SYSLOG_AND_CONSOLE] = "syslog+console",
[EXEC_OUTPUT_KMSG] = "kmsg",
[EXEC_OUTPUT_KMSG_AND_CONSOLE] = "kmsg+console",
[EXEC_OUTPUT_JOURNAL] = "journal",
[EXEC_OUTPUT_JOURNAL_AND_CONSOLE] = "journal+console",
[EXEC_OUTPUT_SOCKET] = "socket",
[EXEC_OUTPUT_NAMED_FD] = "fd",
[EXEC_OUTPUT_FILE] = "file",
[EXEC_OUTPUT_FILE_APPEND] = "append",
};
DEFINE_STRING_TABLE_LOOKUP(exec_output, ExecOutput);
static const char* const exec_utmp_mode_table[_EXEC_UTMP_MODE_MAX] = {
[EXEC_UTMP_INIT] = "init",
[EXEC_UTMP_LOGIN] = "login",
[EXEC_UTMP_USER] = "user",
};
DEFINE_STRING_TABLE_LOOKUP(exec_utmp_mode, ExecUtmpMode);
static const char* const exec_preserve_mode_table[_EXEC_PRESERVE_MODE_MAX] = {
[EXEC_PRESERVE_NO] = "no",
[EXEC_PRESERVE_YES] = "yes",
[EXEC_PRESERVE_RESTART] = "restart",
};
DEFINE_STRING_TABLE_LOOKUP_WITH_BOOLEAN(exec_preserve_mode, ExecPreserveMode, EXEC_PRESERVE_YES);
static const char* const exec_directory_type_table[_EXEC_DIRECTORY_TYPE_MAX] = {
[EXEC_DIRECTORY_RUNTIME] = "RuntimeDirectory",
[EXEC_DIRECTORY_STATE] = "StateDirectory",
[EXEC_DIRECTORY_CACHE] = "CacheDirectory",
[EXEC_DIRECTORY_LOGS] = "LogsDirectory",
[EXEC_DIRECTORY_CONFIGURATION] = "ConfigurationDirectory",
};
DEFINE_STRING_TABLE_LOOKUP(exec_directory_type, ExecDirectoryType);
static const char* const exec_keyring_mode_table[_EXEC_KEYRING_MODE_MAX] = {
[EXEC_KEYRING_INHERIT] = "inherit",
[EXEC_KEYRING_PRIVATE] = "private",
[EXEC_KEYRING_SHARED] = "shared",
};
DEFINE_STRING_TABLE_LOOKUP(exec_keyring_mode, ExecKeyringMode);