Implementation of an Operating System :- Week 6( User Modes )
Welcome all !
This is the sixth blog article of our blog series about implementing an Operating System. In this week I will explain you how to easily execute a small program in kernel mode.
6.1 Loading an External Program:
Where do we get the external program from? Somehow we need to load the code we want to execute into memory. More feature-complete operating systems usually have drivers and file systems that enable them to load the software from a CD-ROM drive, a hard disk or other persistent media.
Instead of creating all these drivers and file systems we will use a feature in GRUB called modules to load the program.
6.1.1 GRUB Modules
GRUB can load arbitrary files into memory from the ISO image, and these files are usually referred to as modules. To make GRUB load a module, edit the file iso/boot/grub/menu.lst
and add the following line at the end of the file:
module /modules/program
Now create the folder iso/modules
:
mkdir -p iso/modules
The application program
will be created later in this article
The code that calls kmain
must be updated to pass information to kmain
about where it can find the modules. We also want to tell GRUB that it should align all the modules on page boundaries when loading them .
To instruct GRUB how to load our modules, the “multiboot header” — the first bytes of the kernel — must be updated as follows:
; in file `loader.s`
MAGIC_NUMBER equ 0x1BADB002 ; define the magic number constant
ALIGN_MODULES equ 0x00000001 ; tell GRUB to align modules ; calculate the checksum (all options + checksum should equal 0)
CHECKSUM equ -(MAGIC_NUMBER + ALIGN_MODULES) section .text: ; start of the text (code) section
align 4 ; the code must be 4 byte aligned
dd MAGIC_NUMBER ; write the magic number
dd ALIGN_MODULES ; write the align modules instruction
dd CHECKSUM ; write the checksum
GRUB will also store a pointer to a struct
in the register ebx
that, among other things, describes at which addresses the modules are loaded. Therefore, you probably want to push ebx
on the stack before calling kmain
to make it an argument for kmain
.
6.2 Executing a Program:
6.2.1 A Very Simple Program
A program written at this stage can only perform a few actions. Therefore, a very short program that writes a value to a register suffices as a test program. Halting Bochs after a while and then check that register contains the correct number by looking in the Bochs log will verify that the program has run. This is an example of such a short program:
; set eax to some distinguishable number, to read from the log afterwards
mov eax, 0xDEADBEEF ; enter infinite loop, nothing more to do
; $ means "beginning of line", ie. the same instruction
jmp $
6.2.2 Compiling
Since our kernel cannot parse advanced executable formats we need to compile the code into a flat binary. NASM can do this with the flag -f
:
nasm -f bin program.s -o program
This is all we need. You must now move the file program
to the folder iso/modules
.
6.2.3 Finding the Program in Memory
Before jumping to the program we must find where it resides in memory. Assuming that the contents of ebx
is passed as an argument to kmain
, we can do this entirely from C.
The pointer in ebx
points to a multiboot structure. Download the multiboot.h
file from http://www.gnu.org/software/grub/manual/multiboot/html_node/multiboot.h.html, which describes the structure.
The pointer passed to kmain
in the ebx
register can be cast to a multiboot_info_t
pointer. The address of the first module is in the field mods_addr
. The following code shows an example:
int kmain(/* additional arguments */ unsigned int ebx)
{
multiboot_info_t *mbinfo = (multiboot_info_t *) ebx;
unsigned int address_of_module = mbinfo->mods_addr;
}
However, before just blindly following the pointer, you should check that the module got loaded correctly by GRUB. This can be done by checking the flags
field of the multiboot_info_t
structure. You should also check the field mods_count
to make sure it is exactly 1.
6.2.4 Jumping to the Code
The only thing left to do is to jump to the code loaded by GRUB. Since it is easier to parse the multiboot structure in C than assembly code, calling the code from C is more convenient (it can of course be done with jmp
or call
in assembly code as well). The C code could look like this:
typedef void (*call_module_t)(void);
/* ... */
call_module_t start_program = (call_module_t) address_of_module;
start_program();
/* we'll never get here, unless the module code returns */
If we start the kernel, wait until it has run and entered the infinite loop in the program, and then halt Bochs, we should see 0xDEADBEEF
in the register eax
via the Bochs log. We have successfully started a program in our OS!
6.3 The Beginning of User Mode:
The program we’ve written now runs at the same privilege level as the kernel — we’ve just entered it in a somewhat peculiar way. To enable applications to execute at a different privilege level we’ll need to, beside segmentation, do paging and page frame allocation.
Finally you can execute “make run” command in the terminal window. Following are the final outputs of our program.
When you open bochslog.txt file there is a code “ EAX = deadbeef ” as following;
You can visit my Github Repository of this os development project from following link;
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