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sortix--sortix/sortix/x64/boot.s

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2011-08-05 08:25:00 -04:00
/******************************************************************************
COPYRIGHT(C) JONAS 'SORTIE' TERMANSEN 2011.
This file is part of Sortix.
Sortix is free software: you can redistribute it and/or modify it under the
terms of the GNU General Public License as published by the Free Software
Foundation, either version 3 of the License, or (at your option) any later
version.
Sortix is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY# without even the implied warranty of MERCHANTABILITY or FITNESS
FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
details.
You should have received a copy of the GNU General Public License along
with Sortix. If not, see <http://www.gnu.org/licenses/>.
boot.s
Bootstraps the kernel and passes over control from the boot-loader to the
kernel main function. It also jumps into long mode!
******************************************************************************/
.globl start, _start
.section .text
.text 0x100000
.type _start, @function
.code32
start:
_start:
jmp multiboot_entry
# Align 32 bits boundary.
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.align 4
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# Multiboot header.
multiboot_header:
# Magic.
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.long 0x1BADB002
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# Flags.
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.long 0x00000003
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# Checksum.
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.long -(0x1BADB002 + 0x00000003)
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multiboot_entry:
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# We got our multiboot information in various registers. But we are going
# to need these registers. But where can we store them then? Oh hey, let's
# store then in the code already run!
# Store the pointer to the Multiboot information structure.
mov %ebx, 0x100000
# Store the magic value.
mov %eax, 0x100004
# Clear the first $0xE000 bytes following 0x21000.
movl $0x21000, %edi
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mov %edi, %cr3
xorl %eax, %eax
movl $0xE000, %ecx
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rep stosl
movl %cr3, %edi
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# Set the initial page tables.
# Note that we OR with 0x7 here to allow user-space access, except in the
# first 2 MiB. We also do this with 0x200 to allow forking the page.
# Page-Map Level 4
movl $0x22207, (%edi)
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addl $0x1000, %edi
# Page-Directory Pointer Table
movl $0x23207, (%edi)
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addl $0x1000, %edi
# Page-Directory (no user-space access here)
movl $0x24003, (%edi) # (First 2 MiB)
movl $0x25003, 8(%edi) # (Second 2 MiB)
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addl $0x1000, %edi
# Page-Table
# Memory map the first 4 MiB.
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movl $0x3, %ebx
movl $1024, %ecx
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SetEntry:
mov %ebx, (%edi)
add $0x1000, %ebx
add $8, %edi
loop SetEntry
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# Enable PAE.
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mov %cr4, %eax
orl $0x20, %eax
mov %eax, %cr4
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# Enable long mode.
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mov $0xC0000080, %ecx
rdmsr
orl $0x100, %eax
wrmsr
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# Enable paging and enter long mode (still 32-bit)
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mov %cr0, %eax
orl $0x80000000, %eax
mov %eax, %cr0
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# Load the long mode GDT.
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mov GDTPointer, %eax
lgdtl GDTPointer
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# Now use the 64-bit code segment, and we are in full 64-bit mode.
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ljmp $0x10, $Realm64
.code64
Realm64:
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# Now, set up the other segment registers.
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cli
mov $0x18, %ax
mov %ax, %ds
mov %ax, %es
mov %ax, %fs
mov %ax, %gs
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# Alright, that was the bootstrap code. Now begin preparing to run the
# actual 64-bit kernel.
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jmp Main
.section .data
GDT64: # Global Descriptor Table (64-bit).
GDTNull: # The null descriptor.
.word 0 # Limit (low).
.word 0 # Base (low).
.byte 0 # Base (middle)
.byte 0 # Access.
.byte 0 # Granularity.
.byte 0 # Base (high).
GDTUnused: # The null descriptor.
.word 0 # Limit (low).
.word 0 # Base (low).
.byte 0 # Base (middle)
.byte 0 # Access.
.byte 0 # Granularity.
.byte 0 # Base (high).
GDTCode: # The code descriptor.
.word 0xFFFF # Limit (low).
.word 0 # Base (low).
.byte 0 # Base (middle)
.byte 0x9A # Access.
.byte 0xAF # Granularity.
.byte 0 # Base (high).
GDTData: # The data descriptor.
.word 0xFFFF # Limit (low).
.word 0 # Base (low).
.byte 0 # Base (middle)
.byte 0x92 # Access.
.byte 0x8F # Granularity.
.byte 0 # Base (high).
GDTPointer: # The GDT-pointer.
.word GDTPointer - GDT64 - 1 # Limit.
.long GDT64 # Base.
.long 0
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Main:
# Copy the character B onto the screen so we know it works.
movq $0x242, %r15
movq %r15, %rax
movw %ax, 0xB8000
# Load the pointer to the Multiboot information structure.
mov 0x100000, %ebx
# Load the magic value.
mov 0x100004, %eax
jmp beginkernel
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