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/*
setup.s is second stage bootloader loaded at 0x90200 (by
first stage), is responsible for getting the system data
from the BIOS.
System data puts at special place: 0x90000-0x901FF.
*/
.code16 # Tell GAS to generate 16 bit code
.include "bios.inc"
.include "rm_seg.inc"
.set ENDSEG, KERNSEG + KERNSIZE # Where to stop loading kernel
# Define some constants for the GDT segment descriptor offsets
.set CODESEG, gdt_code - gdt_start
.set DATASEG, gdt_data - gdt_start
# Keyboard Controller commands:
.set READ_OUTP, 0xD0 # Read Output Port
.set WRITE_OUTP, 0xD1 # Write Output Port
.global _start # Make the symbol visible to ld
_start:
mov $SDATASEG, %ax
mov %ax, %ds
mov %ax, %ss
mov $KERNSEG, %ax
mov %ax, %es
mov $0xFF00, %bp # Set up the stack at 0x9ff00
mov %bp, %sp
BIOS_PRINT $get_data_msg
# Get current cursor position
mov $0x3, %ah
xor %bh, %bh # Page Number = 0
int $0x10
add $3, %dh # Add number of next BIOS_PRINTs
mov %dx, (2) # Save it
# Get disk drive parameters
xor %ax, %ax
mov %ax, %es # ES:DI = 0x0000:0x0000 to guard
mov %ax, %di # against BIOS bugs
mov (0), %dl # Set drive boot
mov $0x8, %ah
int $0x13
jc disk_error
# Interrupt return:
# - CH = low eight bits of maximum cylinder number
# - CL = maximum sector number (bits 5-0)
# high two bits of maximum cylinder number (bits 7-6)
# - DH = maximum head number
xor %ch, %ch
and $0b00111111, %cl
xor %dl, %dl
mov %dx, heads
mov %cx, sectors
# TODO: get memory size
# TODO: get video infos
load_kernel: # Load our kernel
BIOS_PRINT $boot_load_kern_msg
# Load the system at $KERNSEG address:
mov $KERNSEG, %ax
mov %ax, %es # ES - starting address segment
xor %bx, %bx # BX is offset within segment
# A few words about the algorithm:
# We read 0x10000 bytes (64 kB) and overflow BX (16 bytes register),
# then add 0x1000 to ES reg, after that compare with $ENDSEG
#
# If KERNSIZE != 0x10000 * N we read some unnecessary data, but
# i think it's not a problem
repeat_read:
mov %es, %ax
cmp $ENDSEG, %ax
jae enable_a20 # Jump if AX >= $ENDSEG
get_sects_for_read:
mov sectors, %ax # AX = amount of sectors - current sector
sub csect, %ax # AX has 6 significant bytes
mov %ax, %cx # Calculate how many bytes we get by
# reading AX sectors
shl $9, %cx # One sector = 2^9 = 512
add %bx, %cx # CX = 0@@@.@@@0.0000.0000 + BX
jnc read_sects # if not overflow, then jump
jz read_sects # if CX = 0, then jump
xor %ax, %ax # AX = 0
sub %bx, %ax # AX = amount of sectors that we must
shr $9, %ax # read for overflow BX
read_sects:
call read_track # INPUT: AX
mov %ax, %cx # CX = amount of sectors that we read
add csect, %ax
cmp sectors, %ax # Current sector = amount of sectors?
jne check_read # If not equal, jump
mov chead, %ax
cmp heads, %ax # Current head = amount of heads?
jne inc_chead # If not equal, jump
movw $0xffff, chead # Current head will overflow and equal 0
# after INC instuction in inc_chead
incw ctrack # Go to next cylinder
# We don't check cylinder overflow
# because it makes no sense
inc_chead:
incw chead
xor %ax, %ax
check_read:
mov %ax, csect # Calculate how many bytes we get by
shl $9, %cx # reading AX sectors
add %cx, %bx # Add it to BX
jnc repeat_read # If BX not overflow, jjmp
mov %es, %ax
add $0x1000, %ax # We read 0x10000 = 65536 bytes
mov %ax, %es
xor %bx, %bx
jmp repeat_read
# INPUT:
# AX - amount of sectors that we want to read
read_track:
push %ax
push %bx
push %cx
push %dx
mov ctrack, %dx
mov csect, %cx # Set sector
inc %cx # Add +1 because sector has a base of 1
mov %dl, %ch # Set cylinder
mov chead, %dh # Set head
mov %dl, %dh
mov (0), %dl # Set boot
mov $0x02, %ah # Set BIOS read sector routine
int $0x13
jc . # Error :(
pop %dx
pop %cx
pop %bx
pop %ax
ret
enable_a20:
BIOS_PRINT $enable_a20_msg
cli # Switch of interrupt until we have set
# up the protected mode interrupt vector
call wait_input
mov $READ_OUTP, %al
out %al, $0x64
call wait_output
in $0x60, %al # Read input buffer and store on stack
push %ax
call wait_input
mov $WRITE_OUTP, %al
out %al, $0x64
call wait_input
pop %ax # Pop the output port data from stack
or $2, %al # Set bit 1 (A20) to enable
out %al, $0x60 # Write the data to the output port
call wait_input
switch_to_pm:
BIOS_PRINT $boot_prot_mode_msg
lgdt gdt_descriptor # Load our global descriptor table
mov %cr0, %eax # Set the first bit of CR0
or $0x01, %eax # to make the switch to protected mode
mov %eax, %cr0
# Make a far jump to our 32-bit code.
# This also forces the CPU to flush its cache of pre-fetched
# and real-mode decoded instructions, which can cause problems
jmp $CODESEG, $KERNADDR
disk_error:
BIOS_PRINT $disk_error_msg
jmp .
wait_input:
in $0x64, %al # Read status
test $2, %al # Is input buffer full?
jnz wait_input # yes - continue waiting
ret
wait_output:
in $0x64, %al
test $1, %al # Is output buffer full?
jz wait_output # no - continue waiting
ret
# Global Descriptor Table (contains 8-byte entries)
gdt_start:
gdt_null: # The mandatory null descriptor
.quad 0x0
gdt_code: # The code segment descriptor
# Base = 0x0, limit = 0xfffff
# 1st flags: (present)1 (privilege)00 (descriptor type)1 -> b1001
# Type flags: (code)1 (conforming)0 (readable)1 (accessed)0 -> b1010
# 2nd flags: (granularity)1 (size)1 (64-bit seg)0 (AVL)0 -> b1100
.word 0xffff # Limit (bits 0-15)
.word 0x0 # Base (bits 0-15)
.byte 0x0 # Base (bits 16-23)
.byte 0b10011010 # 1st flags, type flags
.byte 0b11001111 # 2nd flags, limit (bits 16-19)
.byte 0x0 # Base (bits 24-31)
gdt_data: # the data segment descriptor
# Same as code segment except for the type flags:
# Type flags: (code)0 (direction)0 (writable)1, (accessed)0 -> b0010
# P.S: direction bit: 0 the segment grows up
.word 0xffff # Limit (bits 0-15)
.word 0x0 # Base (bits 0-15)
.byte 0x0 # Base (bits 16-23)
.byte 0b10010010 # 1st flags, type flags
.byte 0b11001111 # 2nd flags, limit (bits 16-19)
.byte 0x0 # Base (bits 24-31)
gdt_end:
# Global variables
# Total amount of HDD components:
heads: # 8 significant bytes
.word 0x0
sectors: # 6 significant bytes
.word 0x0
# The number of the current component with which we interact:
ctrack: # track/cylinder
.word 0x0
chead:
.word 0x0
csect:
.word 1 + SETUPLEN
gdt_descriptor:
# The 6-byte GDT structure containing:
# - GDT size, 2 bytes (size always less one of the real size):
.word gdt_end - gdt_start - 1
# - GDT address, 4 bytes:
.word gdt_start, 0x9
get_data_msg:
.asciz "Getting the system data from the BIOS\r\n"
boot_prot_mode_msg:
.asciz "Entering 32-bit protected mode\r\n"
boot_load_kern_msg:
.asciz "Loading kernel into memory\r\n"
enable_a20_msg:
.asciz "Enabling A20 line\r\n"
disk_error_msg:
.asciz "Disk read error!"
.space (512 * SETUPLEN) - (. - _start), 0
|
