Assume a Linux binary foobar which has two different modes of operation:

  • Mode A: A well-behaved mode in which syscalls a, b and c are used.
  • Mode B: A things-gone-wrong mode in which syscalls a, b, c and d are used.

Syscalls a, b and c are harmless, whereas syscall d is potentially dangerous and could cause instability to the machine.

Assume further that which of the two modes the application runs is random: the application runs in mode A with probability 95 % and in mode B with probability 5 %. The application comes without source code so it cannot be modified, only run as-is.

I want to make sure that the application cannot execute syscall d. When executing syscall d the result should be either a NOOP or an immediate termination of the application.

How do I achieve that in a Linux environment?

  • Could you perhaps clarify the meaning of "probability" in your question in case there is something to misunderstand there? – Pascal Cuoq Jan 27 '10 at 10:35
  • Pascal: Sure! Post edited with a clarification. For the purpose of this questions the "mode choice" is random. – knorv Jan 27 '10 at 10:39

Is the application linked statically?

If not, you may override some symbols, for example, let's redefine socket:

int socket(int domain, int type, int protocol)
        return -1;

Then build a shared library:

gcc -fPIC -shared test.c -o libtest.so

Let's run:

nc -l -p 6000


And now:

$ LD_PRELOAD=./libtest.so nc -l -p 6000
Can't get socket

What happens when you run with variable LD_PRELOAD=./libtest.so? It overrides with symbols defined in libtest.so over those defined in the C library.

  • This actually does not fulfil the security requirements? It is fairly easy to get code to load an appropriate syscall number in eax or whatever the CPU conventions is and then transfer control to the tail end of 'a', 'b', or 'c' syscalls. Altering a syscall table per process and loader changes (like SELinux) are the only way to stop user space corruption. See for instance ROP at wikipedia. At least this answer assumes several things in the system are beyond compromise. – artless noise Nov 3 '15 at 15:39

It seems that systrace does exactly what you need. From the Wikipedia page:

An application is allowed to make only those system calls specified as permitted in the policy. If the application attempts to execute a system call that is not explicitly permitted an alarm gets raised.


This is one possible application of sandboxing (specifically, Rule-based Execution). One popular implementation is SELinux.

You will have to write the policy that corresponds to what you want to allow the process to do.

  • This is certainly the use case for SELinux. Other sandboxing technologies are available. – stsquad Jan 27 '10 at 15:06
  • @stsquad I incorporated your comment. You were perhaps reacting partly to the "claims" in the previous version… I phrased it this way because of having heard some people SELinux is not so usable in practice, precisely because of the need for adequate policies. Not having tried it, I do not have an opinion one way or the other, so perhaps the new version is better from this point of view. – Pascal Cuoq Jan 27 '10 at 15:27

That's exactly what seccomp-bpf is for. See an example how to restrict access to syscalls.

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