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In drivers I often see these three types of init functions being used.

  1. Under what circumstances should I use them?
  2. Also, are there any other ways of init?
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up vote 26 down vote accepted

They determine the initialization order of built-in modules. Drivers will use device_initcall (or module_init; see below) most of the time. Early initialization (early_initcall) is normally used by architecture-specific code to initialize hardware subsystems (power management, DMAs, etc.) before any real driver gets initialized.

Technical stuff for understanding below

Look at init/main.c. After a few architecture-specific initialization done by code in arch/<arch>/boot and arch/<arch>/kernel, the portable start_kernel function will be called. Eventually, in the same file, do_basic_setup is called:

 * Ok, the machine is now initialized. None of the devices
 * have been touched yet, but the CPU subsystem is up and
 * running, and memory and process management works.
 * Now we can finally start doing some real work..
static void __init do_basic_setup(void)

which ends with a call to do_initcalls:

static initcall_t *initcall_levels[] __initdata = {

/* Keep these in sync with initcalls in include/linux/init.h */
static char *initcall_level_names[] __initdata = {

static void __init do_initcall_level(int level)
    extern const struct kernel_param __start___param[], __stop___param[];
    initcall_t *fn;

    strcpy(static_command_line, saved_command_line);
           static_command_line, __start___param,
           __stop___param - __start___param,
           level, level,

    for (fn = initcall_levels[level]; fn < initcall_levels[level+1]; fn++)

static void __init do_initcalls(void)
    int level;

    for (level = 0; level < ARRAY_SIZE(initcall_levels) - 1; level++)

You can see the names above with their associated index: early is 0, core is 1, etc. Each of those __initcall*_start entries point to an array of function pointers which get called one after the other. Those function pointers are the actual modules and built-in initialization functions, the ones you specify with module_init, early_initcall, etc.

What determines which function pointer gets into which __initcall*_start array? The linker does this, using hints from the module_init and *_initcall macros. Those macros, for built-in modules, assign the function pointers to a specific ELF section.

Example with module_init

Considering a built-in module (configured with y in .config), module_init simply expands like this (include/linux/init.h):

#define module_init(x)  __initcall(x);

and then we follow this:

#define __initcall(fn) device_initcall(fn)
#define device_initcall(fn)             __define_initcall(fn, 6)

So, now, module_init(my_func) means __define_initcall(my_func, 6). This is _define_initcall:

#define __define_initcall(fn, id) \
    static initcall_t __initcall_##fn##id __used \
    __attribute__((__section__(".initcall" #id ".init"))) = fn

which means, so far, we have:

static initcall_t __initcall_my_func6 __used
__attribute__((__section__(".initcall6.init"))) = my_func;

Wow, lots of GCC stuff, but it only means that a new symbol is created, __initcall_my_func6, that's put in the ELF section named .initcall6.init, and as you can see, points to the specified function (my_func). Adding all the functions to this section eventually creates the complete array of function pointers, all stored within the .initcall6.init ELF section.

Initialization example

Look again at this chunk:

for (fn = initcall_levels[level]; fn < initcall_levels[level+1]; fn++)

Let's take level 6, which represents all the built-in modules initialized with module_init. It starts from __initcall6_start, its value being the address of the first function pointer registered within the .initcall6.init section, and ends at __initcall7_start (excluded), incrementing each time with the size of *fn (which is an initcall_t, which is a void*, which is 32-bit or 64-bit depending on the architecture).

do_one_initcall will simply call the function pointed to by the current entry.

Within a specific initialization section, what determines why an initialization function is called before another is simply the order of the files within the Makefiles since the linker will concatenate the __initcall_* symbols one after the other in their respective ELF init. sections.

This fact is actually used in the kernel, e.g. with device drivers (drivers/Makefile):

# GPIO must come after pinctrl as gpios may need to mux pins etc
obj-y                           += pinctrl/
obj-y                           += gpio/

tl;dr: the Linux kernel initialization mechanism is really beautiful, albeit highlight GCC-dependent.

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What module_init will be expanded depends on if it's obj-y or obj-m ? How does it happen? – demonguy May 29 '15 at 8:37

module_init is used to mark a function to be used as the entry-point of a Linux device-driver.
It is called

  • during do_initcalls() (for a builtin driver)
  • at module insertion time (for a *.ko module)

There can be ONLY 1 module_init() per driver module.

The *_initcall() functions are usually used to set the function-pointers for initialising various subsystems.

do_initcalls() within Linux kernel source code contains the invocation of the list of various initcalls and the relative order in which they are called during the Linux kernel boot-up.

  1. early_initcall()
  2. core_initcall()
  3. postcore_initcall()
  4. arch_initcall()
  5. subsys_initcall()
  6. fs_initcall()
  7. device_initcall()
  8. late_initcall()
    end of built-in modules
  9. modprobe or insmod of *.ko modules.

Using module_init() in a device driver is equivalent to registering a device_initcall().

Keep in mind that during compilation, the order of linking the various driver object files(*.o) within the Linux kernel is significant; it determines the order in which they are called at runtime.

*_initcall functions of the same level
will be called during boot in the order they are linked.

For example changing the link order of SCSI drivers in drivers/scsi/Makefile will change the order in which the SCSI controllers are detected, and thus the numbering of the disks.

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