metalsvm/arch/x86/kernel/entry.asm

; 
; Copyright 2010 Stefan Lankes, Chair for Operating Systems,
;                               RWTH Aachen University
;
; Licensed under the Apache License, Version 2.0 (the "License");
; you may not use this file except in compliance with the License.
; You may obtain a copy of the License at
;
;     http://www.apache.org/licenses/LICENSE-2.0
;
; Unless required by applicable law or agreed to in writing, software
; distributed under the License is distributed on an "AS IS" BASIS,
; WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
; See the License for the specific language governing permissions and
; limitations under the License.
;
; This file is part of metalsvm.

; 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]
; We use a special name to map this section at the begin of our kernel
; =>  Multiboot needs its magic number at the begin of the kernel
SECTION .osstart
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 $

; 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
extern gp
gdt_flush:
    lgdt [gp]
    mov ax, 0x10
    mov ds, ax
    mov es, ax
    mov fs, ax
    mov gs, ax
    mov ss, ax
    jmp 0x08:flush2
flush2:
    ret

; Loads the IDT defined in '_idtp' into the processor.
; This is declared in C as 'extern void idt_load();'
global idt_load
extern idtp
idt_load:
    lidt [idtp]
    ret

; In just a few pages in this tutorial, we will add our Interrupt
; Service Routines (ISRs) right here!
global isr0
global isr1
global isr2
global isr3
global isr4
global isr5
global isr6
global isr7
global isr8
global isr9
global isr10
global isr11
global isr12
global isr13
global isr14
global isr15
global isr16
global isr17
global isr18
global isr19
global isr20
global isr21
global isr22
global isr23
global isr24
global isr25
global isr26
global isr27
global isr28
global isr29
global isr30
global isr31

;  0: Divide By Zero Exception
isr0:
    cli
    push byte 0
    push byte 0
    jmp isr_common_stub

;  1: Debug Exception
isr1:
    cli
    push byte 0
    push byte 1
    jmp isr_common_stub

;  2: Non Maskable Interrupt Exception
isr2:
    cli
    push byte 0
    push byte 2
    jmp isr_common_stub

;  3: Int 3 Exception
isr3:
    cli
    push byte 0
    push byte 3
    jmp isr_common_stub

;  4: INTO Exception
isr4:
    cli
    push byte 0
    push byte 4
    jmp isr_common_stub

;  5: Out of Bounds Exception
isr5:
    cli
    push byte 0
    push byte 5
    jmp isr_common_stub

;  6: Invalid Opcode Exception
isr6:
    cli
    push byte 0
    push byte 6
    jmp isr_common_stub

;  7: Coprocessor Not Available Exception
isr7:
    cli
    push byte 0
    push byte 7
    jmp isr_common_stub

;  8: Double Fault Exception (With Error Code!)
isr8:
    cli
    push byte 8
    jmp isr_common_stub

;  9: Coprocessor Segment Overrun Exception
isr9:
    cli
    push byte 0
    push byte 9
    jmp isr_common_stub

; 10: Bad TSS Exception (With Error Code!)
isr10:
    cli
    push byte 10
    jmp isr_common_stub

; 11: Segment Not Present Exception (With Error Code!)
isr11:
    cli
    push byte 11
    jmp isr_common_stub

; 12: Stack Fault Exception (With Error Code!)
isr12:
    cli
    push byte 12
    jmp isr_common_stub

; 13: General Protection Fault Exception (With Error Code!)
isr13:
    cli
    push byte 13
    jmp isr_common_stub

; 14: Page Fault Exception (With Error Code!)
isr14:
    cli
    push byte 14
    jmp isr_common_stub

; 15: Reserved Exception
isr15:
    cli
    push byte 0
    push byte 15
    jmp isr_common_stub

; 16: Floating Point Exception
isr16:
    cli
    push byte 0
    push byte 16
    jmp isr_common_stub

; 17: Alignment Check Exception
isr17:
    cli
    push byte 0
    push byte 17
    jmp isr_common_stub

; 18: Machine Check Exception
isr18:
    cli
    push byte 0
    push byte 18
    jmp isr_common_stub

; 19: Reserved
isr19:
    cli
    push byte 0
    push byte 19
    jmp isr_common_stub

; 20: Reserved
isr20:
    cli
    push byte 0
    push byte 20
    jmp isr_common_stub

; 21: Reserved
isr21:
    cli
    push byte 0
    push byte 21
    jmp isr_common_stub

; 22: Reserved
isr22:
    cli
    push byte 0
    push byte 22
    jmp isr_common_stub

; 23: Reserved
isr23:
    cli
    push byte 0
    push byte 23
    jmp isr_common_stub

; 24: Reserved
isr24:
    cli
    push byte 0
    push byte 24
    jmp isr_common_stub

; 25: Reserved
isr25:
    cli
    push byte 0
    push byte 25
    jmp isr_common_stub

; 26: Reserved
isr26:
    cli
    push byte 0
    push byte 26
    jmp isr_common_stub

; 27: Reserved
isr27:
    cli
    push byte 0
    push byte 27
    jmp isr_common_stub

; 28: Reserved
isr28:
    cli
    push byte 0
    push byte 28
    jmp isr_common_stub

; 29: Reserved
isr29:
    cli
    push byte 0
    push byte 29
    jmp isr_common_stub

; 30: Reserved
isr30:
    cli
    push byte 0
    push byte 30
    jmp isr_common_stub

; 31: Reserved
isr31:
    cli
    push byte 0
    push byte 31
    jmp isr_common_stub

; We call a C function in here. We need to let the assembler know
; that 'fault_handler' exists in another file
extern fault_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
    push ds
    push es
    push fs
    push gs
    mov ax, 0x10
    mov ds, ax
    mov es, ax
    mov fs, ax
    mov gs, ax
    mov eax, esp
    push eax
    mov eax, fault_handler
    call eax
    pop eax
    pop gs
    pop fs
    pop es
    pop ds
    popa
    add esp, 8
    iret

global irq0
global irq1
global irq2
global irq3
global irq4
global irq5
global irq6
global irq7
global irq8
global irq9
global irq10
global irq11
global irq12
global irq13
global irq14
global irq15

; 32: IRQ0
irq0:
    cli
    push byte 0
    push byte 32
    jmp irq_common_stub

; 33: IRQ1
irq1:
    cli
    push byte 0
    push byte 33
    jmp irq_common_stub

; 34: IRQ2
irq2:
    cli
    push byte 0
    push byte 34
    jmp irq_common_stub

; 35: IRQ3
irq3:
    cli
    push byte 0
    push byte 35
    jmp irq_common_stub

; 36: IRQ4
irq4:
    cli
    push byte 0
    push byte 36
    jmp irq_common_stub

; 37: IRQ5
irq5:
    cli
    push byte 0
    push byte 37
    jmp irq_common_stub

; 38: IRQ6
irq6:
    cli
    push byte 0
    push byte 38
    jmp irq_common_stub

; 39: IRQ7
irq7:
    cli
    push byte 0
    push byte 39
    jmp irq_common_stub

; 40: IRQ8
irq8:
    cli
    push byte 0
    push byte 40
    jmp irq_common_stub

; 41: IRQ9
irq9:
    cli
    push byte 0
    push byte 41
    jmp irq_common_stub

; 42: IRQ10
irq10:
    cli
    push byte 0
    push byte 42
    jmp irq_common_stub

; 43: IRQ11
irq11:
    cli
    push byte 0
    push byte 43
    jmp irq_common_stub

; 44: IRQ12
irq12:
    cli
    push byte 0
    push byte 44
    jmp irq_common_stub

; 45: IRQ13
irq13:
    cli
    push byte 0
    push byte 45
    jmp irq_common_stub

; 46: IRQ14
irq14:
    cli
    push byte 0
    push byte 46
    jmp irq_common_stub

; 47: IRQ15
irq15:
    cli
    push byte 0
    push byte 47
    jmp irq_common_stub

extern irq_handler

irq_common_stub:
    pusha
    push ds
    push es
    push fs
    push gs

    mov ax, 0x10
    mov ds, ax
    mov es, ax
    mov fs, ax
    mov gs, ax
    mov eax, esp

    push eax
    mov eax, irq_handler
    call eax
    pop eax

    pop gs
    pop fs
    pop es
    pop ds
    popa
    add esp, 8
    iret

; 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: