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I have been playing around with yasm in an attempt to grasp a basic understanding of x86 assembly. From my tests, it seems you call functions from the kernel by setting the EAX register with the number of the function you want. Then, you push the function arguments onto the stack and issue a syscall (0x80) to execute the instruction. This is Mac OS X / BSD style, I know Linux uses registers to hold arguments instead of using the stack. Does this sound right? Is this the basic idea?

I am a little confused because where are the functions documented? How would I know what arguments, and in what order, to push them onto the stack? Should I look in syscall.h for the answers? It seems there would be a specific reference for supported kernel calls other than C headers.

Also, do standard C functions like printf() rely on the kernel's built-in functions for say, writing to stdout? In other words, does the C compiler know what the kernel functions are and is it trying to "figure out" how to take C code and translate it to kernel functions (which the assembler then translates to machine code)?

C code -> C compiler -> kernel calls / asm -> assembler -> machine binary

I'm sure these are really basic questions, but my understanding of everything that happens after the C compiler is rather muddy.

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If you wanted documentation for all the system calls, use syscall.h for the system call numbers and check out the Section 2 of the UNIX manpages for your platform (click Section 2 on that page) for the specific usage information. You can also run man 2 syscall_name (i.e. man 2 read). –  James O'Doherty Sep 7 '11 at 12:07

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System Call Documentation

Make sure you have the XCode Developer Tools installed for the UNIX manpages for Mac OS X and then run man 2 intro on the commandline. For a list of system calls, you can use syscall.h (which is useful for the system call numbers) or you can run man 2 syscalls. Then to look up each specific system call, you can run man 2 syscall_name i.e. for read, you can run man 2 read.

UNIX manpages are a historically significant documentation reference for UNIX systems. Pretty much any low-level POSIX function or system call will be documented using them, as well as most commands. Section 2 covers just system calls, and so when you run man 2 pagename, you're asking for the manpage in the system calls section. Section 3 also deals with library functions, so you can run man 3 sprintf the next time you want to read about sprintf.

How C Libraries relate to System Calls

As for how C libraries implement their functionality, usually they build everything on top of system calls, especially in UNIX-like operating systems. malloc internally uses mmap() or brk() on a lot of platforms to get a hold of the actual memory for your process and I/O functions will often use buffers with read, write calls. If there's some other mechanism or library providing the needed functionality, they may also choose to use those instead (i.e. some C libraries for DOS may make use of direct BIOS interrupts instead of calling only DOS interrupts, whereas C libraries for Windows might use Win32 API calls).

Often only a subset of the library functions will need system calls or underlying mechanisms to be implemented though, since the remainder can be written in terms of that subset.

To actually know what's going on with your specific implementation, you should investigate what's happening in a debugger (just keep stepping into all the function calls) or browse the source code of the C library you're using.

How your C code using C libraries relates to machine code

In your question you also suggested:

C code -> C compiler -> kernel calls / asm -> assembler -> machine binary

This is combining two very different concepts. Functions and function calls are supported at the machine code and assembly level, so your C code has a very direct mapping to machine code:

C code -> C compiler -> Assembler -> Linker -> Machine Binary

That is, the compiler translates your function calls in C to function calls in Assembly and system calls in C to system calls in Assembly.

However on most platforms, that machine code contains references to shared libraries and functions in those libraries, so your machine code might have a function that calls other functions from a shared library. The OS then loads that shared library's machine code (if it hasn't been loaded yet for something else) and then runs the machine code for the library function. Then if that library function calls system calls via interrupts, the kernel receives the system call request and does low-level operations directly with the hardware or the BIOS.

So in a protected mode OS, your machine code can be seen as doing the following:

Function call to -> Other function calls --+
              or -> System calls to -> Direct hardware access (inside kernel)
                                 or -> BIOS calls (inside kernel)

You can, of course, call system calls directly in your program as well, skipping the need for any libraries, but unless you're writing your own library, there's usually very little need to do this. If you want even lower-level access, you have to write kernel-level code such as drivers or kernel subsystems.

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When you say, "Other Library calls," do you mean calls to say, the standard C library? Are you saying I could make system calls from within C (instead of printf, let's say) without using libraries or are you talking strictly about assembly code? –  Synthetix Sep 7 '11 at 15:58
By "library calls" I basically mean any function calls to userspace code, whether they're in the C library or any other library. As for calling system calls in C, that's basically what you do when you use functions like read and write. If you want to completely avoid all libraries in your C code though, you'll have to write a function to generate a system call interrupt using inline assembly (like that in man 2 syscall), use _start as your entrypoint instead of main, and link without the C standard library by using the -nostdlib compiler flag (i.e. gcc -o hello hello.c -nostdlib). –  James O'Doherty Sep 7 '11 at 21:08
Thanks. Tried what you wrote here, but the "syscall" function is actually part of the standard C lib. So, I need to have it linked anyway! That is, unless I just use inline assembly -- but then the code just ends up looking more like assembly than C anyway. Am I missing something? –  Synthetix Sep 10 '11 at 11:28
What I was suggesting in the last comment was writing your own syscall function using inline assembly (not just using the one in the C library -- instead make one that works like it), and calling that instead of using inline assembly everywhere (so you only have inline assembly in one or two places). Then you can also define macros make the system calls look like C function calls (i.e. #define read(d,buf,nbytes) syscall(SYS_read, d, buf, nbytes) ). After you've done that, the rest of your code should be really clean and easy to read. –  James O'Doherty Sep 10 '11 at 14:30

The recommended way is not doing INT 0x80 by yourself, but to use the wrapper functions from the stdlib. These are, of course, available for assembly as well.

Concerning printf, this works this way:

printf internally calls fprintf(stdout, ...), which in turn uses the FILE * stdout to write to the file descriptor 1 and does write(1, ...). This calls a small wrapper function to set the proper registers to the arguments and perform the kernel call.

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Right, I just mentioned 0x80 for brevity. What I actually use in OS X is a function _syscall, which consists of int 0x80 and ret. –  Synthetix Sep 7 '11 at 16:18

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