25

I am learning Device Driver and Kernel programming.According to Jonathan Corbet book we do not have main() function in device drivers.

#include <linux/init.h>
#include <linux/module.h>

static int my_init(void)
{
     return  0;
}

static void my_exit(void)
{
     return;
}

module_init(my_init);
module_exit(my_exit);

Here I have two questions :

  1. Why we do not need main() function in Device Drivers?
  2. Does Kernel have main() function?
8
  • 1
    If no one knows the answer why you down vote my question?
    – someone
    Aug 16, 2013 at 5:03
  • 1
    With main() you propably mean what main() is to a program, namely its "entry point"?
    – alk
    Aug 16, 2013 at 5:23
  • 1
    @alk..Book says that we have init_module as entry point and exit_module as exit point. I am coming from C background, and learn that none program can execute without main() function. so just want to know how drivers working without main().
    – someone
    Aug 16, 2013 at 5:26
  • 1
    @alk... No it is not written there. That`s why i am asking this.
    – someone
    Aug 16, 2013 at 5:32
  • 1
    @alk.. Book name is Linux Device Driver by Jonathan Corbet.
    – someone
    Aug 16, 2013 at 5:36

6 Answers 6

19

start_kernel

On 4.2, start_kernel from init/main.c is a considerable initialization process and could be compared to a main function.

It is the first arch independent code to run, and sets up a large part of the kernel. So much like main, start_kernel is preceded by some lower level setup code (done in the crt* objects in userland main), after which the "main" generic C code runs.

How start_kernel gets called in x86_64

arch/x86/kernel/vmlinux.lds.S, a linker script, sets:

ENTRY(phys_startup_64)

and

phys_startup_64 = startup_64 - LOAD_OFFSET;

and:

#define LOAD_OFFSET __START_KERNEL_map

arch/x86/include/asm/page_64_types.h defines __START_KERNEL_map as:

#define __START_KERNEL_map  _AC(0xffffffff80000000, UL)

which is the kernel entry address. TODO how is that address reached exactly? I have to understand the interface Linux exposes to bootloaders.

arch/x86/kernel/vmlinux.lds.S sets the very first bootloader section as:

.text :  AT(ADDR(.text) - LOAD_OFFSET) {
    _text = .;
    /* bootstrapping code */
    HEAD_TEXT

include/asm-generic/vmlinux.lds.h defines HEAD_TEXT:

#define HEAD_TEXT  *(.head.text)

arch/x86/kernel/head_64.S defines startup_64. That is the very first x86 kernel code that runs. It does a lot of low level setup, including segmentation and paging.

That is then the first thing that runs because the file starts with:

.text
__HEAD
.code64
.globl startup_64

and include/linux/init.h defines __HEAD as:

#define __HEAD      .section    ".head.text","ax"

so the same as the very first thing of the linker script.

At the end it calls x86_64_start_kernel a bit awkwardly with and lretq:

movq    initial_code(%rip),%rax
pushq   $0      # fake return address to stop unwinder
pushq   $__KERNEL_CS    # set correct cs
pushq   %rax        # target address in negative space
lretq

and:

.balign 8
GLOBAL(initial_code)
.quad   x86_64_start_kernel

arch/x86/kernel/head64.c defines x86_64_start_kernel which calls x86_64_start_reservations which calls start_kernel.

arm64 entry point

The very first arm64 that runs on an v5.7 uncompressed kernel is defined at https://github.com/cirosantilli/linux/blob/v5.7/arch/arm64/kernel/head.S#L72 so either the add x13, x18, #0x16 or b stext depending on CONFIG_EFI:

    __HEAD
_head:
    /*
     * DO NOT MODIFY. Image header expected by Linux boot-loaders.
     */
#ifdef CONFIG_EFI
    /*
     * This add instruction has no meaningful effect except that
     * its opcode forms the magic "MZ" signature required by UEFI.
     */
    add x13, x18, #0x16
    b   stext
#else
    b   stext               // branch to kernel start, magic
    .long   0               // reserved
#endif
    le64sym _kernel_offset_le       // Image load offset from start of RAM, little-endian
    le64sym _kernel_size_le         // Effective size of kernel image, little-endian
    le64sym _kernel_flags_le        // Informative flags, little-endian
    .quad   0               // reserved
    .quad   0               // reserved
    .quad   0               // reserved
    .ascii  ARM64_IMAGE_MAGIC       // Magic number
#ifdef CONFIG_EFI
    .long   pe_header - _head       // Offset to the PE header.

This is also the very first byte of an uncompressed kernel image.

Both of those cases jump to stext which starts the "real" action.

As mentioned in the comment, these two instructions are the first 64 bytes of a documented header described at: https://github.com/cirosantilli/linux/blob/v5.7/Documentation/arm64/booting.rst#4-call-the-kernel-image

arm64 first MMU enabled instruction: __primary_switched

I think it is __primary_switched in head.S:

/*
 * The following fragment of code is executed with the MMU enabled.
 *
 *   x0 = __PHYS_OFFSET
 */
__primary_switched:

At this point, the kernel appears to create page tables + maybe relocate itself such that the PC addresses match the symbols of the vmlinux ELF file. Therefore at this point you should be able to see meaningful function names in GDB without extra magic.

arm64 secondary CPU entry point

secondary_holding_pen defined at: https://github.com/cirosantilli/linux/blob/v5.7/arch/arm64/kernel/head.S#L691

Entry procedure further described at: https://github.com/cirosantilli/linux/blob/v5.7/arch/arm64/kernel/head.S#L691

6
  • 1
    Interesting answer. I'm voting up. and what does in a file /arch/um/kernel/um_arch.c function linux_main(int argc, char ** argv) than?
    – zviad
    Jan 18, 2017 at 10:52
  • 1
    @zviad I have no idea! But since it is inside arch/um, I think that is that User Mode Linux thing en.wikipedia.org/wiki/User-mode_Linux which looks cool but I think is never use in regular operation. Jan 19, 2017 at 21:29
  • from #define __START_KERNEL_map _AC(0xffffffff80000000, UL) can we deduce that the load address for stock vmlinux is 0xffffffff80000000 ?
    – Skegg
    Mar 25, 2023 at 10:08
  • @AjB I'd need to think re/better understand things. Better just objdump + QEMU step debug it! :-) Mar 25, 2023 at 10:15
  • 1
    @CiroSantilliOurBigBook.com I believe you have a skeleton setup somewhere for just that right? Qemu/kvm + rootfs + linux Kernel
    – Skegg
    Mar 26, 2023 at 1:25
12

Fundamentally, there is nothing special about a routine being named main(). As alluded to above, main() serves as the entry point for an executable load module. However, you can define different entry points for a load module. In fact, you can define more than one entry point, for example, refer to your favorite dll.

From the operating system's (OS) point of view, all it really needs is the address of the entry point of the code that will function as a device driver. The OS will pass control to that entry point when the device driver is required to perform I/O to the device.

A system programmer defines (each OS has its own method) the connection between a device, a load module that functions as the device's driver, and the name of the entry point in the load module.

Each OS has its own kernel (obviously) and some might/maybe start with main() but I would be surprised to find a kernel that used main() other than in a simple one, such as UNIX! By the time you are writing kernel code you have long moved past the requirement to name every module you write as main().

Hope this helps?

Found this code snippet from the kernel for Unix Version 6. As you can see main() is just another program, trying to get started!

main()
{
     extern schar;
     register i, *p;
     /*
     * zero and free all of core
     */

     updlock = 0;
     i = *ka6 + USIZE;
     UISD->r[0] = 077406;
     for(;;) {
        if(fuibyte(0) < 0) break;
        clearsig(i);
        maxmem++;
        mfree(coremap, 1, i);
         i++;
     }
     if(cputype == 70) 
     for(i=0; i<62; i=+2) {
       UBMAP->r[i] = i<<12;
       UBMAP->r[i+1] = 0;
      }

    // etc. etc. etc.
4
  • JackCColeman... So Kernel code can have main().if you can provide some snippet of such code, it would be a great help.
    – someone
    Aug 16, 2013 at 5:58
  • @Krishna, no I did NOT mean to imply this. Rather, when writing a kernel a programmer is experienced enough to know how to define the entry point of a module in the code and to the linkage editor, and is NOT bound by using the main() convention used in application (i.e. non-kernel code). Aug 16, 2013 at 6:07
  • 3
    @Krishna, well, I can just eat my words! Found a book on Unix Version 6 that lists the source to Unix (the "Lions" book) and it lists a module named main() that initializes Unix control blocks. But, like I said naming a module main() does NOT give it any special status. Aug 16, 2013 at 6:21
  • @Krishna, why did you uncheck my answer? Aug 16, 2013 at 19:24
4

Several ways to look at it:

  1. Device drivers are not programs. They are modules that are loaded into another program (the kernel). As such, they do not have a main() function.

  2. The fact that all programs must have a main() function is only true for userspace applications. It does not apply to the kernel, nor to device drivers.

2
  • 1
    "...only true for userspace apps...", because they are mostly linked with libc which does initialization and then calls main. The name main() is just a convention of libc. Apr 25, 2017 at 7:38
  • Well, an application could choose to implement _start directly, or explicitly set an entry point with the linker. But that would remove the isolation of the C code against the platform dependent communication of command line args to the the application, force it to take care of running its constructor codes itself (which the compiler and linker helpfully emit), and force a explicit call to exit() before falling over the end of _start, as there is nothing _start can return to. Usually, the standard library takes care of all these gory details, and applications better make use of it. Sep 24, 2020 at 15:54
3

With main() you propably mean what main() is to a program, namely its "entry point".

For a module that is init_module().

From Linux Device Driver's 2nd Edition:

Whereas an application performs a single task from beginning to end, a module registers itself in order to serve future requests, and its "main" function terminates immediately. In other words, the task of the function init_module (the module's entry point) is to prepare for later invocation of the module's functions; it's as though the module were saying, "Here I am, and this is what I can do." The second entry point of a module, cleanup_module, gets invoked just before the module is unloaded. It should tell the kernel, "I'm not there anymore; don't ask me to do anything else."

1
  • @alk, you should write a description in your own words. Aug 16, 2013 at 5:53
2

Yes, the Linux kernel has a main function, it is located in arch/x86/boot/main.c file. But Kernel execution starts from arch/x86/boot/header.S assembly file and the main() function is called from there by "calll main" instruction. Here is that main function:

void main(void)
{
    /* First, copy the boot header into the "zeropage" */
    copy_boot_params();

    /* Initialize the early-boot console */
    console_init();
    if (cmdline_find_option_bool("debug"))
        puts("early console in setup code.\n");

    /* End of heap check */
    init_heap();

    /* Make sure we have all the proper CPU support */
    if (validate_cpu()) {
        puts("Unable to boot - please use a kernel appropriate "
             "for your CPU.\n");
        die();
    }

    /* Tell the BIOS what CPU mode we intend to run in. */
    set_bios_mode();

    /* Detect memory layout */
    detect_memory();

    /* Set keyboard repeat rate (why?) and query the lock flags */
    keyboard_init();

    /* Query Intel SpeedStep (IST) information */
    query_ist();

    /* Query APM information */
#if defined(CONFIG_APM) || defined(CONFIG_APM_MODULE)
    query_apm_bios();
#endif

    /* Query EDD information */
#if defined(CONFIG_EDD) || defined(CONFIG_EDD_MODULE)
    query_edd();
#endif

    /* Set the video mode */
    set_video();

    /* Do the last things and invoke protected mode */
    go_to_protected_mode();
}
0

While the function name main() is just a common convention (there is no real reason to use it in kernel mode) the linux kernel does have a main() function for many architectures, and of course usermode linux has a main function.

Note the OS runtime loads the main() function to start an app, when an operating system boots there is no runtime, the kernel is simply loaded to a address by the boot loader which is loaded by the MBR which is loaded by the hardware. So while a kernel may contain a function called main it need not be the entry point.

See Also:

http://msdn.microsoft.com/en-us/library/windows/desktop/ms633559%28v=vs.85%29.aspx

Linux kernel source:

x86: linux-3.10-rc6/arch/x86/boot/main.c

arm64: linux-3.10-rc6/arch/arm64/kernel/asm-offsets.c

0

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