; This is the kernel's entry point. We could either call main here,

; or we can use this to setup the stack or other nice stuff, like

; perhaps setting up the GDT and segments. Please note that interrupts

; are disabled at this point: More on interrupts later!

[BITS 32]

global start

start:

mov esp, _sys_stack ; This points the stack to our new stack area

jmp stublet

; This part MUST be 4byte aligned, so we solve that issue using 'ALIGN 4'

ALIGN 4

mboot:

; Multiboot macros to make a few lines later more readable

MULTIBOOT_PAGE_ALIGN equ 1<<0

MULTIBOOT_MEMORY_INFO equ 1<<1

MULTIBOOT_AOUT_KLUDGE equ 1<<16

MULTIBOOT_HEADER_MAGIC equ 0x1BADB002

MULTIBOOT_HEADER_FLAGS equ MULTIBOOT_PAGE_ALIGN | MULTIBOOT_MEMORY_INFO | MULTIBOOT_AOUT_KLUDGE

MULTIBOOT_CHECKSUM equ -(MULTIBOOT_HEADER_MAGIC + MULTIBOOT_HEADER_FLAGS)

EXTERN code, bss, end

; This is the GRUB Multiboot header. A boot signature

dd MULTIBOOT_HEADER_MAGIC

dd MULTIBOOT_HEADER_FLAGS

dd MULTIBOOT_CHECKSUM

; AOUT kludge - must be physical addresses. Make a note of these:

; The linker script fills in the data for these ones!

dd mboot

dd code

dd bss

dd end

dd start

; This is an endless loop here. Make a note of this: Later on, we

; will insert an 'extern _main', followed by 'call _main', right

; before the 'jmp $'.

stublet:

extern _main

call _main

jmp $

; Shortly we will add code for loading the GDT right here!

; This will set up our new segment registers. We need to do

; something special in order to set CS. We do what is called a

; far jump. A jump that includes a segment as well as an offset.

; This is declared in C as 'extern void gdt_flush();'

global _gdt_flush ; Allows the C code to link to this

extern _gp ; Says that '_gp' is in another file

_gdt_flush :

lgdt [_gp] ; Load the GDT with our '_gp' which is a special pointer

mov ax, 0x10 ; 0x10 is the offset in the GDT to our data segment

mov ds, ax

mov es, ax

mov fs, ax

mov gs, ax

mov ss, ax

jmp 0x08:flush2 ; 0x08 is the offset to our code segment: Far jump!

flush2:

ret ; Returns back to the C code!

global _idt_flush ; Allows the C code to call idt_flush().

extern _id

_idt_flush:

lidt [_id] ; Load the IDT pointer.

ret

; In just a few pages in this tutorial, we will add our Interrupt

; Service Routines (ISRs) right here!

%macro ISR_NOERRCODE 1 ; define a macro, taking one parameter

global _isr%1 ; %1 accesses the first parameter.

_isr%1:

cli

push byte 0

push byte %1

jmp isr_common_stub

%endmacro

%macro ISR_ERRCODE 1

global _isr%1

_isr%1:

cli

push byte %1

jmp isr_common_stub

%endmacro

ISR_NOERRCODE 0

ISR_NOERRCODE 1

ISR_NOERRCODE 2

ISR_NOERRCODE 3

ISR_NOERRCODE 4

ISR_NOERRCODE 5

ISR_NOERRCODE 6

ISR_NOERRCODE 7

ISR_ERRCODE 8

ISR_NOERRCODE 9

ISR_ERRCODE 10

ISR_ERRCODE 11

ISR_ERRCODE 12

ISR_ERRCODE 13

ISR_ERRCODE 14

ISR_NOERRCODE 15

ISR_NOERRCODE 16

ISR_NOERRCODE 17

ISR_NOERRCODE 18

ISR_NOERRCODE 19

ISR_NOERRCODE 20

ISR_NOERRCODE 21

ISR_NOERRCODE 22

ISR_NOERRCODE 23

ISR_NOERRCODE 24

ISR_NOERRCODE 25

ISR_NOERRCODE 26

ISR_NOERRCODE 27

ISR_NOERRCODE 28

ISR_NOERRCODE 29

ISR_NOERRCODE 30

ISR_NOERRCODE 31

%macro IRQ 2

global _irq%1

_irq%1:

cli

push byte 0

push byte %2

jmp irq_common_stub

%endmacro

IRQ 0, 32

IRQ 1, 33

IRQ 2, 34

IRQ 3, 35

IRQ 4, 36

IRQ 5, 37

IRQ 6, 38

IRQ 7, 39

IRQ 8, 40

IRQ 9, 41

IRQ 10, 42

IRQ 11, 43

IRQ 12, 44

IRQ 13, 45

IRQ 14, 46

IRQ 15, 47

extern _isr_handler

; This is our common ISR stub. It saves the processor state, sets

; up for kernel mode segments, calls the C-level fault handler,

; and finally restores the stack frame.

isr_common_stub:

pusha ; Pushes edi,esi,ebp,esp,ebx,edx,ecx,eax

mov ax, ds ; Lower 16-bits of eax = ds.

push eax ; save the data segment descriptor

mov ax, 0x10 ; load the kernel data segment descriptor

mov ds, ax

mov es, ax

mov fs, ax

mov gs, ax

call _isr_handler

pop eax ; reload the original data segment descriptor

mov ds, ax

mov es, ax

mov fs, ax

mov gs, ax

popa ; Pops edi,esi,ebp...

add esp, 8 ; Cleans up the pushed error code and pushed ISR number

sti

iret ; pops 5 things at once: CS, EIP, EFLAGS, SS, and ESP

extern _irq_handler

irq_common_stub:

pusha ; Pushes edi,esi,ebp,esp,ebx,edx,ecx,eax

mov ax, ds ; Lower 16-bits of eax = ds.

push eax ; save the data segment descriptor

mov ax, 0x10 ; load the kernel data segment descriptor

mov ds, ax

mov es, ax

mov fs, ax

mov gs, ax

call _irq_handler

pop ebx ; reload the original data segment descriptor

mov ds, bx

mov es, bx

mov fs, bx

mov gs, bx

popa ; Pops edi,esi,ebp...

add esp, 8 ; Cleans up the pushed error code and pushed ISR number

sti

iret ; pops 5 things at once: CS, EIP, EFLAGS, SS, and ESP

; Here is the definition of our BSS section. Right now, we'll use

; it just to store the stack. Remember that a stack actually grows

; downwards, so we declare the size of the data before declaring

; the identifier '_sys_stack'

SECTION .bss

resb 8192 ; This reserves 8KBytes of memory here

_sys_stack: