If you're looking for some formal guarantees, I cannot help you. You would have to look in the documentation of the compiler and OS that you're using - however I doubt that you would find the necessary guarantees - except possibly for some specialized embedded systems OS'.
I can however provide you with one scenario where I'm 99.99% sure that it will work without any problems:
- 32 bit process
- Function is located in a module that doesn't have relocation information
- The module in question is already loaded & initialized on the client side
- The module in question is 100% identical on both sides
- A compiler that doesn't do very crazy stuff (e.g. MSVC and GCC should both be fine)
If you want to call a function in a DLL you might run into problems. As per the list above the module (=DLL) may not have relocation information, which of course makes it impossible to relocate it (which is what we need). Unfortunately that also means that loading the DLL will fail, if the "preferred load address" is used by something else. So that would be kind-of risky.
If the function resides in the EXE however, you should be fine. A 32 bit EXE doesn't need relocation information, and most don't include it (MSVC default settings). BTW: ASLR is not an issue here since a) ASLR does only move modules that are tagged as wanting to be moved and b) ASLR could not move a 32 bit windows module without relocation information, even if it wanted to.
Most of the above just makes sure that the function will have the same address on both sides. The only remaining question - at least that I can think of - is: is it safe to call a function via a pointer that we initialized by memcpy-ing over some bytes that we received from the network, assuming that the byte-pattern is the same that we would have gotten if we had taken the address of the desired function? That surely is something that the C++ standard doesn't guarantee, but I don't expect any real-world problems from current real-world compilers.
That being said, I would not recommend to do that, except for situations where security and robustness really aren't important.