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[tor-bugs] #24400 [Core Tor/Tor]: Seccomp filter incorrectly tries to act on strings, allowing sandbox bypass



#24400: Seccomp filter incorrectly tries to act on strings, allowing sandbox bypass
------------------------------+--------------------------------
     Reporter:  Sebastian     |      Owner:  (none)
         Type:  defect        |     Status:  new
     Priority:  Medium        |  Milestone:  Tor: 0.3.3.x-final
    Component:  Core Tor/Tor  |    Version:
     Severity:  Normal        |   Keywords:  sandbox
Actual Points:                |  Parent ID:
       Points:                |   Reviewer:
      Sponsor:                |
------------------------------+--------------------------------
 I am filing this on behalf of cypherpunks who cannot use our trac because
 of its javascript requirements for posting some stuff.

 Currently, the Tor seccomp sandbox attempts to whitelist internal strings.
 This is a bug, because seccomp is incapable of whitelisting memory
 contents, only register contents (i.e. the pointer itself). That is, when
 you call `open(path, mode)`, the first argument is actually an address,
 such as `0x368a227dec3`. When you attempt to use the seccomp filter to
 whitelist this, you are not whitelisting the string, only the pointer to
 the string. The only reason it works is because compilers deduplicate
 identical strings, allowing two strings that are the same (e.g. the string
 given to seccomp for whitelisting, and the string being given to a
 syscall) point to the same location in `.rodata`.

 **A demonstration showing deduplication:**

 {{{
 cat $ hello.c
 #include <stdio.h>

 void main(int argc, char *argv[])
 {
     char *s1 = "Hello, world!";
     char *s2 = "Hello, world!";
     char *s3 = argv[1];

     printf("%p\t%s\n%p\t%s\n%p\t%s\n", s1, s1, s2, s2, s3, s3);
 }

 $ gcc hello.c

 $ ./a.out "Hello, world!"
 0x64a4b457b4    Hello, world!
 0x64a4b457b4    Hello, world!
 0x3eb7d22b37d   Hello, world!

 $ readelf -x .rodata a.out

 Hex dump of section '.rodata':
   0x000007b0 01000200 48656c6c 6f2c2077 6f726c64 ....Hello, world
   0x000007c0 21002570 0925730a 25700925 730a2570 !.%p.%s.%p.%s.%p
   0x000007d0 0925730a 00                         .%s..

 }}}

 Despite the strings being identical in all cases, only the first two,
 which were defined internally, point to the same data. Only when the
 string is accessed at runtime does the value change. This means that
 hardcoding a string with a seccomp sandbox may seem to work, but provides
 no protection, as all an attacker would have to do is write their own
 strings to those addresses (changing the permissions of `.rodata` first if
 it is stored there).

 **A demonstration which shows how a whitelisted string can be bypassed:**

 {{{
 $ cat seccomp.c
 #include <seccomp.h>
 #include <unistd.h>
 #include <string.h>
 #include <stdlib.h>

 void main(void)
 {
     char *s = malloc(14);

     memcpy(s, "Hello, world!\n", 14);

     scmp_filter_ctx ctx = seccomp_init(SCMP_ACT_TRAP);
     seccomp_rule_add(ctx, SCMP_ACT_ALLOW, SCMP_SYS(exit_group), 0);
     seccomp_rule_add(ctx, SCMP_ACT_ALLOW, SCMP_SYS(write), 1,
         SCMP_A1(SCMP_CMP_EQ, (scmp_datum_t)s));
     seccomp_load(ctx);

     write(1, s, 14);
     memcpy(s, "Hallo, world!\n", 14);
     write(1, s, 14);
 }

 $ gcc seccomp.c -lseccomp

 $ ./a.out
 Hello, world!
 Hallo, world!
 }}}

 See "Why does seccomp-filter is not enough?" [sic] from
 https://lwn.net/Articles/698226/, which explains why an LSM (currently in
 development) is required to provide seccomp with the ability to filter
 paths and other memory-resident values:

 >A seccomp filter can access to raw syscall arguments which means that it
 is not
 >possible to filter according to pointed data as a file path. As
 demonstrated
 >the first version of this patch series, filtering at the syscall level is
 >complicated (e.g. need to take care of race conditions). This is mainly
 because
 >the access control checkpoints of the kernel are not at this high-level
 but
 >more underneath, at LSM hooks level. The LSM hooks are designed to handle
 this
 >kind of checks. This series use this approach to leverage the ability of
 >unprivileged users to limit themselves.

 It may seem like it would be enough to ensure the buffers are read-only
 and disallow `mprotect()` accessing that address. Unfortunately, other
 syscalls like `brk()` can bypass this. In the end, it's extremely
 difficult to ensure that a memory region cannot be written to by malicious
 code without disabling virtually all memory-related syscalls.

 The entirety of `src/common/sandbox.c:sandbox_intern_string` is poorly
 thought out and relies on incorrect and dangerous assumptions. This
 results in 6 syscalls so far which devs believe to be filtered but which
 in fact can be bypassed:
 * chown  - pathname argument
 * chmod  - pathname argument
 * open   - pathname argument
 * openat - pathname argument
 * rename - oldpath and newpath arguments
 * stat64 - pathname argument

 The solution is to use the syscalls before enabling the sandbox, or
 whitelisting them (excluding arguments in memory) and eventually
 blacklisting them in a stage 2 sandbox.

--
Ticket URL: <https://trac.torproject.org/projects/tor/ticket/24400>
Tor Bug Tracker & Wiki <https://trac.torproject.org/>
The Tor Project: anonymity online
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