Hacking Your ELF For Fun And Profit 10 May 2013

Have you ever wondered how the Linux kernel module_init and *_initcall (e.g. subsys_initcall ) macros work? Even after a quick glance at their definition things might not be exactly clear:

The key to understanding what’s going on here is understanding that __attribute__((__section__(...))) business. Normally, variables are placed in sections like data or bss . But with gcc, you can use the section attribute to manually specify which section of the ELF (assuming you’re compiling to ELF) you’d like that variable to live in.

Custom ELF Sections

Using custom ELF sections, you can essentially build dynamic arrays of arbitrary data at compile time. No need to modify the calling code or register your function at runtime.

We’ll walk through the Linux kernel example a little later, but first let’s look at a simple example of how this works in plain-ol’ C.

Simple Plugin Architecture

Imagine that you’re building a C program that you would like others to be able to easily extend. One way you could accomplish this is by providing a plugin system based on custom ELF sections. Maybe you want other developers to be able to add functions to permute and print out some text without having to modify your main program source code. The following types and macros should do the trick:

Notice the __attribute((__section__("my_formatters"))) . That’s the key. With this, the REGISTER_FORMATTER macro will put functions inside an ELF section called my_formatters . The macro can then be used like so:

You can then iterate over all of the functions in the my_formatters ELF section (all those that were registered with REGISTER_FORMATTER ) in your main program, like so:

Note the usage of the special variables __start_my_formatters and __stop_my_formatters . gcc ( ld , rather) includes these variables for extra ELF sections as long as the section name will result in a valid C variable name (e.g. it can’t start with a “.” (which is one way to prevent these variables from being generated automatically)). In general, the variables will be named __start_SECTION and __stop_SECTION . I couldn’t find any formal documentation for this feature, only a few obscure mailing list references. If you know where the docs are, drop a comment!

In the end, the main code for your program might look something like this:

And someone could provide a plugin file like this:

Compile with this:

And you’ll get the following output when you run your program:

Linux Kernel Init Calls

Back to our original example of the Linux kernel init calls. The idea here is to collect a bunch of different functions that correspond to the various stages of boot into separate ELF sections so that they can be executed in sequence, without having to modify the code that actually calls them. At boot time, for each section, the kernel simply takes the address of the section and starts iterating over the functions it finds there, calling them in sequence. The code that does that is the following three functions: do_initcalls , do_initcall_level , and do_one_initcall , shown here:

This simply iterates over each section, and for each function found within a section, simply calls the function. It’s really pretty simple and quite elegant if you ask me.

Note that rather than relying on gcc to emit those magical __start_SECTION and __stop_SECTION variables, the Linux kernel actually sets up its custom ELF sections by hand in a linker script:

If you’re curious, the call path from start_kernel (the entry point to the Linux kernel) to do_initcalls is as follows:

start_kernel | `--> rest_init | `--> kernel_init | `--> do_basic_setup | `--> do_initcalls

Summary

Custom ELF sections can be useful for accumulating similar data (function pointers, for example) at compile time. With gcc magic variables or custom linker scripts you can access the start and end of those sections at runtime.

Now go hack some ELFs!

Please enable JavaScript to view the comments powered by Disqus.

Disqus