glibc/support/test-container.c

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/* Run a test case in an isolated namespace.
Copyright (C) 2018-2019 Free Software Foundation, Inc.
This file is part of the GNU C Library.
The GNU C Library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
The GNU C Library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with the GNU C Library; if not, see
<http://www.gnu.org/licenses/>. */
#define _FILE_OFFSET_BITS 64
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sched.h>
#include <sys/syscall.h>
#include <unistd.h>
#include <sys/types.h>
#include <dirent.h>
#include <string.h>
#include <sys/stat.h>
#include <sys/fcntl.h>
#include <sys/file.h>
#include <sys/wait.h>
#include <stdarg.h>
#include <sys/sysmacros.h>
#include <ctype.h>
#include <utime.h>
#include <errno.h>
#include <error.h>
#include <libc-pointer-arith.h>
#ifdef __linux__
#include <sys/mount.h>
#endif
#include <support/support.h>
#include <support/xunistd.h>
#include "check.h"
#include "test-driver.h"
#ifndef __linux__
#define mount(s,t,fs,f,d) no_mount()
int no_mount (void)
{
FAIL_UNSUPPORTED("mount not supported; port needed");
}
#endif
int verbose = 0;
/* Running a test in a container is tricky. There are two main
categories of things to do:
1. "Once" actions, like setting up the container and doing an
install into it.
2. "Per-test" actions, like copying in support files and
configuring the container.
"Once" actions:
* mkdir $buildroot/testroot.pristine/
* install into it
* rsync to $buildroot/testroot.root/
"Per-test" actions:
* maybe rsync to $buildroot/testroot.root/
* copy support files and test binary
* chroot/unshare
* set up any mounts (like /proc)
Magic files:
For test $srcdir/foo/mytest.c we look for $srcdir/foo/mytest.root
and, if found...
* mytest.root/ is rsync'd into container
* mytest.root/preclean.req causes fresh rsync (with delete) before
test if present
* mytest.root/mytest.script has a list of "commands" to run:
syntax:
# comment
su
mv FILE FILE
cp FILE FILE
rm FILE
FILE must start with $B/, $S/, $I/, $L/, or /
(expands to build dir, source dir, install dir, library dir
(in container), or container's root)
details:
- '#': A comment.
- 'su': Enables running test as root in the container.
- 'mv': A minimal move files command.
- 'cp': A minimal copy files command.
- 'rm': A minimal remove files command.
* mytest.root/postclean.req causes fresh rsync (with delete) after
test if present
Note that $srcdir/foo/mytest.script may be used instead of a
$srcdir/foo/mytest.root/mytest.script in the sysroot template, if
there is no other reason for a sysroot.
Design goals:
* independent of other packages which may not be installed (like
rsync or Docker, or even "cp")
* Simple, easy to review code (i.e. prefer simple naive code over
complex efficient code)
* The current implementation ist parallel-make-safe, but only in
that it uses a lock to prevent parallel access to the testroot. */
/* Utility Functions */
/* Like xunlink, but it's OK if the file already doesn't exist. */
void
maybe_xunlink (const char *path)
{
int rv = unlink (path);
if (rv < 0 && errno != ENOENT)
FAIL_EXIT1 ("unlink (\"%s\"): %m", path);
}
/* Like xmkdir, but it's OK if the directory already exists. */
void
maybe_xmkdir (const char *path, mode_t mode)
{
struct stat st;
if (stat (path, &st) == 0
&& S_ISDIR (st.st_mode))
return;
xmkdir (path, mode);
}
/* Temporarily concatenate multiple strings into one. Allows up to 10
temporary results; use strdup () if you need them to be
permanent. */
static char *
concat (const char *str, ...)
{
/* Assume initialized to NULL/zero. */
static char *bufs[10];
static size_t buflens[10];
static int bufn = 0;
int n;
size_t len;
va_list ap, ap2;
char *cp;
char *next;
va_start (ap, str);
va_copy (ap2, ap);
n = bufn;
bufn = (bufn + 1) % 10;
len = strlen (str);
while ((next = va_arg (ap, char *)) != NULL)
len = len + strlen (next);
va_end (ap);
if (bufs[n] == NULL)
{
bufs[n] = xmalloc (len + 1); /* NUL */
buflens[n] = len + 1;
}
else if (buflens[n] < len + 1)
{
bufs[n] = xrealloc (bufs[n], len + 1); /* NUL */
buflens[n] = len + 1;
}
strcpy (bufs[n], str);
cp = strchr (bufs[n], '\0');
while ((next = va_arg (ap2, char *)) != NULL)
{
strcpy (cp, next);
cp = strchr (cp, '\0');
}
*cp = 0;
va_end (ap2);
return bufs[n];
}
/* Try to mount SRC onto DEST. */
static void
trymount (const char *src, const char *dest)
{
if (mount (src, dest, "", MS_BIND, NULL) < 0)
FAIL_EXIT1 ("can't mount %s onto %s\n", src, dest);
}
/* Special case of above for devices like /dev/zero where we have to
mount a device over a device, not a directory over a directory. */
static void
devmount (const char *new_root_path, const char *which)
{
int fd;
fd = open (concat (new_root_path, "/dev/", which, NULL),
O_CREAT | O_TRUNC | O_RDWR, 0777);
xclose (fd);
trymount (concat ("/dev/", which, NULL),
concat (new_root_path, "/dev/", which, NULL));
}
/* Returns true if the string "looks like" an environement variable
being set. */
static int
is_env_setting (const char *a)
{
int count_name = 0;
while (*a)
{
if (isalnum (*a) || *a == '_')
++count_name;
else if (*a == '=' && count_name > 0)
return 1;
else
return 0;
++a;
}
return 0;
}
/* Break the_line into words and store in the_words. Max nwords,
returns actual count. */
static int
tokenize (char *the_line, char **the_words, int nwords)
{
int rv = 0;
while (nwords > 0)
{
/* Skip leading whitespace, if any. */
while (*the_line && isspace (*the_line))
++the_line;
/* End of line? */
if (*the_line == 0)
return rv;
/* THE_LINE points to a non-whitespace character, so we have a
word. */
*the_words = the_line;
++the_words;
nwords--;
++rv;
/* Skip leading whitespace, if any. */
while (*the_line && ! isspace (*the_line))
++the_line;
/* We now point at the trailing NUL *or* some whitespace. */
if (*the_line == 0)
return rv;
/* It was whitespace, skip and keep tokenizing. */
*the_line++ = 0;
}
/* We get here if we filled the words buffer. */
return rv;
}
/* Mini-RSYNC implementation. Optimize later. */
/* A few routines for an "rsync buffer" which stores the paths we're
working on. We continuously grow and shrink the paths in each
buffer so there's lot of re-use. */
/* We rely on "initialized to zero" to set these up. */
typedef struct
{
char *buf;
size_t len;
size_t size;
} path_buf;
static path_buf spath, dpath;
static void
r_setup (char *path, path_buf * pb)
{
size_t len = strlen (path);
if (pb->buf == NULL || pb->size < len + 1)
{
/* Round up. This is an arbitrary number, just to keep from
reallocing too often. */
size_t sz = ALIGN_UP (len + 1, 512);
if (pb->buf == NULL)
pb->buf = (char *) xmalloc (sz);
else
pb->buf = (char *) xrealloc (pb->buf, sz);
if (pb->buf == NULL)
FAIL_EXIT1 ("Out of memory while rsyncing\n");
pb->size = sz;
}
strcpy (pb->buf, path);
pb->len = len;
}
static void
r_append (const char *path, path_buf * pb)
{
size_t len = strlen (path) + pb->len;
if (pb->size < len + 1)
{
/* Round up */
size_t sz = ALIGN_UP (len + 1, 512);
pb->buf = (char *) xrealloc (pb->buf, sz);
if (pb->buf == NULL)
FAIL_EXIT1 ("Out of memory while rsyncing\n");
pb->size = sz;
}
strcpy (pb->buf + pb->len, path);
pb->len = len;
}
static int
file_exists (char *path)
{
struct stat st;
if (lstat (path, &st) == 0)
return 1;
return 0;
}
static void
recursive_remove (char *path)
{
pid_t child;
int status;
child = fork ();
switch (child) {
case -1:
perror("fork");
FAIL_EXIT1 ("Unable to fork");
case 0:
/* Child. */
execlp ("rm", "rm", "-rf", path, NULL);
FAIL_EXIT1 ("exec rm: %m");
default:
/* Parent. */
waitpid (child, &status, 0);
/* "rm" would have already printed a suitable error message. */
if (! WIFEXITED (status)
|| WEXITSTATUS (status) != 0)
exit (1);
break;
}
}
/* Used for both rsync and the mytest.script "cp" command. */
static void
copy_one_file (const char *sname, const char *dname)
{
int sfd, dfd;
struct stat st;
struct utimbuf times;
sfd = open (sname, O_RDONLY);
if (sfd < 0)
FAIL_EXIT1 ("unable to open %s for reading\n", sname);
if (fstat (sfd, &st) < 0)
FAIL_EXIT1 ("unable to fstat %s\n", sname);
dfd = open (dname, O_WRONLY | O_TRUNC | O_CREAT, 0600);
if (dfd < 0)
FAIL_EXIT1 ("unable to open %s for writing\n", dname);
xcopy_file_range (sfd, 0, dfd, 0, st.st_size, 0);
xclose (sfd);
xclose (dfd);
if (chmod (dname, st.st_mode & 0777) < 0)
FAIL_EXIT1 ("chmod %s: %s\n", dname, strerror (errno));
times.actime = st.st_atime;
times.modtime = st.st_mtime;
if (utime (dname, &times) < 0)
FAIL_EXIT1 ("utime %s: %s\n", dname, strerror (errno));
}
/* We don't check *everything* about the two files to see if a copy is
needed, just the minimum to make sure we get the latest copy. */
static int
need_sync (char *ap, char *bp, struct stat *a, struct stat *b)
{
if ((a->st_mode & S_IFMT) != (b->st_mode & S_IFMT))
return 1;
if (S_ISLNK (a->st_mode))
{
int rv;
char *al, *bl;
if (a->st_size != b->st_size)
return 1;
al = xreadlink (ap);
bl = xreadlink (bp);
rv = strcmp (al, bl);
free (al);
free (bl);
if (rv == 0)
return 0; /* links are same */
return 1; /* links differ */
}
if (verbose)
{
if (a->st_size != b->st_size)
printf ("SIZE\n");
if ((a->st_mode & 0777) != (b->st_mode & 0777))
printf ("MODE\n");
if (a->st_mtime != b->st_mtime)
printf ("TIME\n");
}
if (a->st_size == b->st_size
&& ((a->st_mode & 0777) == (b->st_mode & 0777))
&& a->st_mtime == b->st_mtime)
return 0;
return 1;
}
static void
rsync_1 (path_buf * src, path_buf * dest, int and_delete)
{
DIR *dir;
struct dirent *de;
struct stat s, d;
r_append ("/", src);
r_append ("/", dest);
if (verbose)
printf ("sync %s to %s %s\n", src->buf, dest->buf,
and_delete ? "and delete" : "");
size_t staillen = src->len;
size_t dtaillen = dest->len;
dir = opendir (src->buf);
while ((de = readdir (dir)) != NULL)
{
if (strcmp (de->d_name, ".") == 0
|| strcmp (de->d_name, "..") == 0)
continue;
src->len = staillen;
r_append (de->d_name, src);
dest->len = dtaillen;
r_append (de->d_name, dest);
s.st_mode = ~0;
d.st_mode = ~0;
if (lstat (src->buf, &s) != 0)
FAIL_EXIT1 ("%s obtained by readdir, but stat failed.\n", src->buf);
/* It's OK if this one fails, since we know the file might be
missing. */
lstat (dest->buf, &d);
if (! need_sync (src->buf, dest->buf, &s, &d))
{
if (S_ISDIR (s.st_mode))
rsync_1 (src, dest, and_delete);
continue;
}
if (d.st_mode != ~0)
switch (d.st_mode & S_IFMT)
{
case S_IFDIR:
if (!S_ISDIR (s.st_mode))
{
if (verbose)
printf ("-D %s\n", dest->buf);
recursive_remove (dest->buf);
}
break;
default:
if (verbose)
printf ("-F %s\n", dest->buf);
maybe_xunlink (dest->buf);
break;
}
switch (s.st_mode & S_IFMT)
{
case S_IFREG:
if (verbose)
printf ("+F %s\n", dest->buf);
copy_one_file (src->buf, dest->buf);
break;
case S_IFDIR:
if (verbose)
printf ("+D %s\n", dest->buf);
maybe_xmkdir (dest->buf, (s.st_mode & 0777) | 0700);
rsync_1 (src, dest, and_delete);
break;
case S_IFLNK:
{
char *lp;
if (verbose)
printf ("+L %s\n", dest->buf);
lp = xreadlink (src->buf);
xsymlink (lp, dest->buf);
free (lp);
break;
}
default:
break;
}
}
closedir (dir);
src->len = staillen;
src->buf[staillen] = 0;
dest->len = dtaillen;
dest->buf[dtaillen] = 0;
if (!and_delete)
return;
/* The rest of this function removes any files/directories in DEST
that do not exist in SRC. This is triggered as part of a
preclean or postsclean step. */
dir = opendir (dest->buf);
while ((de = readdir (dir)) != NULL)
{
if (strcmp (de->d_name, ".") == 0
|| strcmp (de->d_name, "..") == 0)
continue;
src->len = staillen;
r_append (de->d_name, src);
dest->len = dtaillen;
r_append (de->d_name, dest);
s.st_mode = ~0;
d.st_mode = ~0;
lstat (src->buf, &s);
if (lstat (dest->buf, &d) != 0)
FAIL_EXIT1 ("%s obtained by readdir, but stat failed.\n", dest->buf);
if (s.st_mode == ~0)
{
/* dest exists and src doesn't, clean it. */
switch (d.st_mode & S_IFMT)
{
case S_IFDIR:
if (!S_ISDIR (s.st_mode))
{
if (verbose)
printf ("-D %s\n", dest->buf);
recursive_remove (dest->buf);
}
break;
default:
if (verbose)
printf ("-F %s\n", dest->buf);
maybe_xunlink (dest->buf);
break;
}
}
}
closedir (dir);
}
static void
rsync (char *src, char *dest, int and_delete)
{
r_setup (src, &spath);
r_setup (dest, &dpath);
rsync_1 (&spath, &dpath, and_delete);
}
/* See if we can detect what the user needs to do to get unshare
support working for us. */
void
check_for_unshare_hints (void)
{
FILE *f;
int i;
/* Default Debian Linux disables user namespaces, but allows a way
to enable them. */
f = fopen ("/proc/sys/kernel/unprivileged_userns_clone", "r");
if (f != NULL)
{
i = 99; /* Sentinel. */
fscanf (f, "%d", &i);
if (i == 0)
{
printf ("To enable test-container, please run this as root:\n");
printf (" echo 1 > /proc/sys/kernel/unprivileged_userns_clone\n");
}
fclose (f);
return;
}
/* ALT Linux has an alternate way of doing the same. */
f = fopen ("/proc/sys/kernel/userns_restrict", "r");
if (f != NULL)
{
i = 99; /* Sentinel. */
fscanf (f, "%d", &i);
if (i == 1)
{
printf ("To enable test-container, please run this as root:\n");
printf (" echo 0 > /proc/sys/kernel/userns_restrict\n");
}
fclose (f);
return;
}
}
int
main (int argc, char **argv)
{
pid_t child;
char *pristine_root_path;
char *new_root_path;
char *new_cwd_path;
char *new_objdir_path;
char *new_srcdir_path;
char **new_child_proc;
char *command_root;
char *command_base;
char *command_basename;
char *so_base;
int do_postclean = 0;
uid_t original_uid;
gid_t original_gid;
/* If set, the test runs as root instead of the user running the testsuite. */
int be_su = 0;
int UMAP;
int GMAP;
/* Used for "%lld %lld 1" so need not be large. */
char tmp[100];
struct stat st;
int lock_fd;
setbuf (stdout, NULL);
/* The command line we're expecting looks like this:
env <set some vars> ld.so <library path> test-binary
We need to peel off any "env" or "ld.so" portion of the command
line, and keep track of which env vars we should preserve and
which we drop. */
if (argc < 2)
{
fprintf (stderr, "Usage: containerize <program to run> <args...>\n");
exit (1);
}
if (strcmp (argv[1], "-v") == 0)
{
verbose = 1;
++argv;
--argc;
}
if (strcmp (argv[1], "env") == 0)
{
++argv;
--argc;
while (is_env_setting (argv[1]))
{
/* If there are variables we do NOT want to propogate, this
is where the test for them goes. */
{
/* Need to keep these. Note that putenv stores a
pointer to our argv. */
putenv (argv[1]);
}
++argv;
--argc;
}
}
if (strcmp (argv[1], support_objdir_elf_ldso) == 0)
{
++argv;
--argc;
while (argv[1][0] == '-')
{
if (strcmp (argv[1], "--library-path") == 0)
{
++argv;
--argc;
}
++argv;
--argc;
}
}
pristine_root_path = strdup (concat (support_objdir_root,
"/testroot.pristine", NULL));
new_root_path = strdup (concat (support_objdir_root,
"/testroot.root", NULL));
new_cwd_path = get_current_dir_name ();
new_child_proc = argv + 1;
lock_fd = open (concat (pristine_root_path, "/lock.fd", NULL),
O_CREAT | O_TRUNC | O_RDWR, 0666);
if (lock_fd < 0)
FAIL_EXIT1 ("Cannot create testroot lock.\n");
while (flock (lock_fd, LOCK_EX) != 0)
{
if (errno != EINTR)
FAIL_EXIT1 ("Cannot lock testroot.\n");
}
xmkdirp (new_root_path, 0755);
/* We look for extra setup info in a subdir in the same spot as the
test, with the same name but a ".root" extension. This is that
directory. We try to look in the source tree if the path we're
given refers to the build tree, but we rely on the path to be
absolute. This is what the glibc makefiles do. */
command_root = concat (argv[1], ".root", NULL);
if (strncmp (command_root, support_objdir_root,
strlen (support_objdir_root)) == 0
&& command_root[strlen (support_objdir_root)] == '/')
command_root = concat (support_srcdir_root,
argv[1] + strlen (support_objdir_root),
".root", NULL);
command_root = strdup (command_root);
/* This cuts off the ".root" we appended above. */
command_base = strdup (command_root);
command_base[strlen (command_base) - 5] = 0;
/* This is the basename of the test we're running. */
command_basename = strrchr (command_base, '/');
if (command_basename == NULL)
command_basename = command_base;
else
++command_basename;
/* Shared object base directory. */
so_base = strdup (argv[1]);
if (strrchr (so_base, '/') != NULL)
strrchr (so_base, '/')[1] = 0;
if (file_exists (concat (command_root, "/postclean.req", NULL)))
do_postclean = 1;
rsync (pristine_root_path, new_root_path,
file_exists (concat (command_root, "/preclean.req", NULL)));
if (stat (command_root, &st) >= 0
&& S_ISDIR (st.st_mode))
rsync (command_root, new_root_path, 0);
new_objdir_path = strdup (concat (new_root_path,
support_objdir_root, NULL));
new_srcdir_path = strdup (concat (new_root_path,
support_srcdir_root, NULL));
/* new_cwd_path starts with '/' so no "/" needed between the two. */
xmkdirp (concat (new_root_path, new_cwd_path, NULL), 0755);
xmkdirp (new_srcdir_path, 0755);
xmkdirp (new_objdir_path, 0755);
original_uid = getuid ();
original_gid = getgid ();
/* Handle the cp/mv/rm "script" here. */
{
char *the_line = NULL;
size_t line_len = 0;
char *fname = concat (command_root, "/",
command_basename, ".script", NULL);
char *the_words[3];
FILE *f = fopen (fname, "r");
if (verbose && f)
fprintf (stderr, "running %s\n", fname);
if (f == NULL)
{
/* Try foo.script instead of foo.root/foo.script, as a shortcut. */
fname = concat (command_base, ".script", NULL);
f = fopen (fname, "r");
if (verbose && f)
fprintf (stderr, "running %s\n", fname);
}
/* Note that we do NOT look for a Makefile-generated foo.script in
the build directory. If that is ever needed, this is the place
to add it. */
/* This is where we "interpret" the mini-script which is <test>.script. */
if (f != NULL)
{
while (getline (&the_line, &line_len, f) > 0)
{
int nt = tokenize (the_line, the_words, 3);
int i;
for (i = 1; i < nt; ++i)
{
if (memcmp (the_words[i], "$B/", 3) == 0)
the_words[i] = concat (support_objdir_root,
the_words[i] + 2, NULL);
else if (memcmp (the_words[i], "$S/", 3) == 0)
the_words[i] = concat (support_srcdir_root,
the_words[i] + 2, NULL);
else if (memcmp (the_words[i], "$I/", 3) == 0)
the_words[i] = concat (new_root_path,
support_install_prefix,
the_words[i] + 2, NULL);
else if (memcmp (the_words[i], "$L/", 3) == 0)
the_words[i] = concat (new_root_path,
support_libdir_prefix,
the_words[i] + 2, NULL);
else if (the_words[i][0] == '/')
the_words[i] = concat (new_root_path,
the_words[i], NULL);
}
if (nt == 3 && the_words[2][strlen (the_words[2]) - 1] == '/')
{
char *r = strrchr (the_words[1], '/');
if (r)
the_words[2] = concat (the_words[2], r + 1, NULL);
else
the_words[2] = concat (the_words[2], the_words[1], NULL);
}
if (nt == 2 && strcmp (the_words[0], "so") == 0)
{
the_words[2] = concat (new_root_path, support_libdir_prefix,
"/", the_words[1], NULL);
the_words[1] = concat (so_base, the_words[1], NULL);
copy_one_file (the_words[1], the_words[2]);
}
else if (nt == 3 && strcmp (the_words[0], "cp") == 0)
{
copy_one_file (the_words[1], the_words[2]);
}
else if (nt == 3 && strcmp (the_words[0], "mv") == 0)
{
if (rename (the_words[1], the_words[2]) < 0)
FAIL_EXIT1 ("rename %s -> %s: %s", the_words[1],
the_words[2], strerror (errno));
}
else if (nt == 3 && strcmp (the_words[0], "chmod") == 0)
{
long int m;
m = strtol (the_words[1], NULL, 0);
if (chmod (the_words[2], m) < 0)
FAIL_EXIT1 ("chmod %s: %s\n",
the_words[2], strerror (errno));
}
else if (nt == 2 && strcmp (the_words[0], "rm") == 0)
{
maybe_xunlink (the_words[1]);
}
else if (nt == 1 && strcmp (the_words[0], "su") == 0)
{
be_su = 1;
}
else if (nt > 0 && the_words[0][0] != '#')
{
printf ("\033[31minvalid [%s]\033[0m\n", the_words[0]);
}
}
fclose (f);
}
}
if (do_postclean)
{
pid_t pc_pid = fork ();
if (pc_pid < 0)
{
FAIL_EXIT1 ("Can't fork for post-clean");
}
else if (pc_pid > 0)
{
/* Parent. */
int status;
waitpid (pc_pid, &status, 0);
/* Child has exited, we can post-clean the test root. */
printf("running post-clean rsync\n");
rsync (pristine_root_path, new_root_path, 1);
if (WIFEXITED (status))
exit (WEXITSTATUS (status));
if (WIFSIGNALED (status))
{
printf ("%%SIGNALLED%%\n");
exit (77);
}
printf ("%%EXITERROR%%\n");
exit (78);
}
/* Child continues. */
}
/* This is the last point in the program where we're still in the
"normal" namespace. */
#ifdef CLONE_NEWNS
/* The unshare here gives us our own spaces and capabilities. */
if (unshare (CLONE_NEWUSER | CLONE_NEWPID | CLONE_NEWNS) < 0)
{
/* Older kernels may not support all the options, or security
policy may block this call. */
if (errno == EINVAL || errno == EPERM)
{
int saved_errno = errno;
if (errno == EPERM)
check_for_unshare_hints ();
FAIL_UNSUPPORTED ("unable to unshare user/fs: %s", strerror (saved_errno));
}
else
FAIL_EXIT1 ("unable to unshare user/fs: %s", strerror (errno));
}
#else
/* Some targets may not support unshare at all. */
FAIL_UNSUPPORTED ("unshare support missing");
#endif
/* Some systems, by default, all mounts leak out of the namespace. */
if (mount ("none", "/", NULL, MS_REC | MS_PRIVATE, NULL) != 0)
FAIL_EXIT1 ("could not create a private mount namespace\n");
trymount (support_srcdir_root, new_srcdir_path);
trymount (support_objdir_root, new_objdir_path);
xmkdirp (concat (new_root_path, "/dev", NULL), 0755);
devmount (new_root_path, "null");
devmount (new_root_path, "zero");
devmount (new_root_path, "urandom");
/* We're done with the "old" root, switch to the new one. */
if (chroot (new_root_path) < 0)
FAIL_EXIT1 ("Can't chroot to %s - ", new_root_path);
if (chdir (new_cwd_path) < 0)
FAIL_EXIT1 ("Can't cd to new %s - ", new_cwd_path);
/* To complete the containerization, we need to fork () at least
once. We can't exec, nor can we somehow link the new child to
our parent. So we run the child and propogate it's exit status
up. */
child = fork ();
if (child < 0)
FAIL_EXIT1 ("Unable to fork");
else if (child > 0)
{
/* Parent. */
int status;
waitpid (child, &status, 0);
if (WIFEXITED (status))
exit (WEXITSTATUS (status));
if (WIFSIGNALED (status))
{
printf ("%%SIGNALLED%%\n");
exit (77);
}
printf ("%%EXITERROR%%\n");
exit (78);
}
/* The rest is the child process, which is now PID 1 and "in" the
new root. */
maybe_xmkdir ("/tmp", 0755);
/* Now that we're pid 1 (effectively "root") we can mount /proc */
maybe_xmkdir ("/proc", 0777);
if (mount ("proc", "/proc", "proc", 0, NULL) < 0)
FAIL_EXIT1 ("Unable to mount /proc: ");
/* We map our original UID to the same UID in the container so we
can own our own files normally. */
UMAP = open ("/proc/self/uid_map", O_WRONLY);
if (UMAP < 0)
FAIL_EXIT1 ("can't write to /proc/self/uid_map\n");
sprintf (tmp, "%lld %lld 1\n",
(long long) (be_su ? 0 : original_uid), (long long) original_uid);
write (UMAP, tmp, strlen (tmp));
xclose (UMAP);
/* We must disable setgroups () before we can map our groups, else we
get EPERM. */
GMAP = open ("/proc/self/setgroups", O_WRONLY);
if (GMAP >= 0)
{
/* We support kernels old enough to not have this. */
write (GMAP, "deny\n", 5);
xclose (GMAP);
}
/* We map our original GID to the same GID in the container so we
can own our own files normally. */
GMAP = open ("/proc/self/gid_map", O_WRONLY);
if (GMAP < 0)
FAIL_EXIT1 ("can't write to /proc/self/gid_map\n");
sprintf (tmp, "%lld %lld 1\n",
(long long) (be_su ? 0 : original_gid), (long long) original_gid);
write (GMAP, tmp, strlen (tmp));
xclose (GMAP);
/* Now run the child. */
execvp (new_child_proc[0], new_child_proc);
/* Or don't run the child? */
FAIL_EXIT1 ("Unable to exec %s\n", new_child_proc[0]);
/* Because gcc won't know error () never returns... */
exit (EXIT_UNSUPPORTED);
}