boot/head.s - pub/scm/linux/kernel/git/nico/archive - Git at Google

 /*
  *  head.s contains the 32-bit startup code.
  *
  * NOTE!!! Startup happens at absolute address 0x00000000, which is also where
  * the page directory will exist. The startup code will be overwritten by
  * the page directory.
  */
 .text
 .globl _idt,_gdt,_pg_dir
 _pg_dir:
 startup_32:
 	movl $0x10,%eax
 	mov %ax,%ds
 	mov %ax,%es
 	mov %ax,%fs
 	mov %ax,%gs
 	lss _stack_start,%esp
 	call setup_idt
 	call setup_gdt
 	movl $0x10,%eax		# reload all the segment registers
 	mov %ax,%ds		# after changing gdt. CS was already
 	mov %ax,%es		# reloaded in 'setup_gdt'
 	mov %ax,%fs
 	mov %ax,%gs
 	lss _stack_start,%esp
 	xorl %eax,%eax
 1:	incl %eax		# check that A20 really IS enabled
 	movl %eax,0x000000
 	cmpl %eax,0x100000
 	je 1b
 	movl %cr0,%eax		# check math chip
 	andl $0x80000011,%eax	# Save PG,ET,PE
 	testl $0x10,%eax
 	jne 1f			# ET is set - 387 is present
 	orl $4,%eax		# else set emulate bit
 1:	movl %eax,%cr0
 	jmp after_page_tables

 /*
  *  setup_idt
  *
  *  sets up a idt with 256 entries pointing to
  *  ignore_int, interrupt gates. It then loads
  *  idt. Everything that wants to install itself
  *  in the idt-table may do so themselves. Interrupts
  *  are enabled elsewhere, when we can be relatively
  *  sure everything is ok. This routine will be over-
  *  written by the page tables.
  */
 setup_idt:
 	lea ignore_int,%edx
 	movl $0x00080000,%eax
 	movw %dx,%ax		/* selector = 0x0008 = cs */
 	movw $0x8E00,%dx	/* interrupt gate - dpl=0, present */

 	lea _idt,%edi
 	mov $256,%ecx
 rp_sidt:
 	movl %eax,(%edi)
 	movl %edx,4(%edi)
 	addl $8,%edi
 	dec %ecx
 	jne rp_sidt
 	lidt idt_descr
 	ret

 /*
  *  setup_gdt
  *
  *  This routines sets up a new gdt and loads it.
  *  Only two entries are currently built, the same
  *  ones that were built in init.s. The routine
  *  is VERY complicated at two whole lines, so this
  *  rather long comment is certainly needed :-).
  *  This routine will beoverwritten by the page tables.
  */
 setup_gdt:
 	lgdt gdt_descr
 	ret

 .org 0x1000
 pg0:

 .org 0x2000
 pg1:

 .org 0x3000
 pg2:		# This is not used yet, but if you
 		# want to expand past 8 Mb, you'll have
 		# to use it.

 .org 0x4000
 after_page_tables:
 	pushl $0		# These are the parameters to main :-)
 	pushl $0
 	pushl $0
 	pushl $L6		# return address for main, if it decides to.
 	pushl $_main
 	jmp setup_paging
 L6:
 	jmp L6			# main should never return here, but
 				# just in case, we know what happens.

 /* This is the default interrupt "handler" :-) */
 .align 2
 ignore_int:
 	incb 0xb8000+160		# put something on the screen
 	movb $2,0xb8000+161		# so that we know something
 	iret				# happened


 /*
  * Setup_paging
  *
  * This routine sets up paging by setting the page bit
  * in cr0. The page tables are set up, identity-mapping
  * the first 8MB. The pager assumes that no illegal
  * addresses are produced (ie >4Mb on a 4Mb machine).
  *
  * NOTE! Although all physical memory should be identity
  * mapped by this routine, only the kernel page functions
  * use the >1Mb addresses directly. All "normal" functions
  * use just the lower 1Mb, or the local data space, which
  * will be mapped to some other place - mm keeps track of
  * that.
  *
  * For those with more memory than 8 Mb - tough luck. I've
  * not got it, why should you :-) The source is here. Change
  * it. (Seriously - it shouldn't be too difficult. Mostly
  * change some constants etc. I left it at 8Mb, as my machine
  * even cannot be extended past that (ok, but it was cheap :-)
  * I've tried to show which constants to change by having
  * some kind of marker at them (search for "8Mb"), but I
  * won't guarantee that's all :-( )
  */
 .align 2
 setup_paging:
 	movl $1024*3,%ecx
 	xorl %eax,%eax
 	xorl %edi,%edi			/* pg_dir is at 0x000 */
 	cld;rep;stosl
 	movl $pg0+7,_pg_dir		/* set present bit/user r/w */
 	movl $pg1+7,_pg_dir+4		/*  --------- " " --------- */
 	movl $pg1+4092,%edi
 	movl $0x7ff007,%eax		/*  8Mb - 4096 + 7 (r/w user,p) */
 	std
 1:	stosl			/* fill pages backwards - more efficient :-) */
 	subl $0x1000,%eax
 	jge 1b
 	xorl %eax,%eax		/* pg_dir is at 0x0000 */
 	movl %eax,%cr3		/* cr3 - page directory start */
 	movl %cr0,%eax
 	orl $0x80000000,%eax
 	movl %eax,%cr0		/* set paging (PG) bit */
 	ret			/* this also flushes prefetch-queue */

 .align 2
 .word 0
 idt_descr:
 	.word 256*8-1		# idt contains 256 entries
 	.long _idt
 .align 2
 .word 0
 gdt_descr:
 	.word 256*8-1		# so does gdt (not that that's any
 	.long _gdt		# magic number, but it works for me :^)

 	.align 3
 _idt:	.fill 256,8,0		# idt is uninitialized

 _gdt:	.quad 0x0000000000000000	/* NULL descriptor */
 	.quad 0x00c09a00000007ff	/* 8Mb */
 	.quad 0x00c09200000007ff	/* 8Mb */
 	.quad 0x0000000000000000	/* TEMPORARY - don't use */
 	.fill 252,8,0			/* space for LDT's and TSS's etc */
	/*
	* head.s contains the 32-bit startup code.
	*
	* NOTE!!! Startup happens at absolute address 0x00000000, which is also where
	* the page directory will exist. The startup code will be overwritten by
	* the page directory.
	*/
	.text
	.globl _idt,_gdt,_pg_dir
	_pg_dir:
	startup_32:
	movl $0x10,%eax
	mov %ax,%ds
	mov %ax,%es
	mov %ax,%fs
	mov %ax,%gs
	lss _stack_start,%esp
	call setup_idt
	call setup_gdt
	movl $0x10,%eax # reload all the segment registers
	mov %ax,%ds # after changing gdt. CS was already
	mov %ax,%es # reloaded in 'setup_gdt'
	mov %ax,%fs
	mov %ax,%gs
	lss _stack_start,%esp
	xorl %eax,%eax
	1: incl %eax # check that A20 really IS enabled
	movl %eax,0x000000
	cmpl %eax,0x100000
	je 1b
	movl %cr0,%eax # check math chip
	andl $0x80000011,%eax # Save PG,ET,PE
	testl $0x10,%eax
	jne 1f # ET is set - 387 is present
	orl $4,%eax # else set emulate bit
	1: movl %eax,%cr0
	jmp after_page_tables

	/*
	* setup_idt
	*
	* sets up a idt with 256 entries pointing to
	* ignore_int, interrupt gates. It then loads
	* idt. Everything that wants to install itself
	* in the idt-table may do so themselves. Interrupts
	* are enabled elsewhere, when we can be relatively
	* sure everything is ok. This routine will be over-
	* written by the page tables.
	*/
	setup_idt:
	lea ignore_int,%edx
	movl $0x00080000,%eax
	movw %dx,%ax /* selector = 0x0008 = cs */
	movw $0x8E00,%dx /* interrupt gate - dpl=0, present */

	lea _idt,%edi
	mov $256,%ecx
	rp_sidt:
	movl %eax,(%edi)
	movl %edx,4(%edi)
	addl $8,%edi
	dec %ecx
	jne rp_sidt
	lidt idt_descr
	ret

	/*
	* setup_gdt
	*
	* This routines sets up a new gdt and loads it.
	* Only two entries are currently built, the same
	* ones that were built in init.s. The routine
	* is VERY complicated at two whole lines, so this
	* rather long comment is certainly needed :-).
	* This routine will beoverwritten by the page tables.
	*/
	setup_gdt:
	lgdt gdt_descr
	ret

	.org 0x1000
	pg0:

	.org 0x2000
	pg1:

	.org 0x3000
	pg2: # This is not used yet, but if you
	# want to expand past 8 Mb, you'll have
	# to use it.

	.org 0x4000
	after_page_tables:
	pushl $0 # These are the parameters to main :-)
	pushl $0
	pushl $0
	pushl $L6 # return address for main, if it decides to.
	pushl $_main
	jmp setup_paging
	L6:
	jmp L6 # main should never return here, but
	# just in case, we know what happens.

	/* This is the default interrupt "handler" :-) */
	.align 2
	ignore_int:
	incb 0xb8000+160 # put something on the screen
	movb $2,0xb8000+161 # so that we know something
	iret # happened


	/*
	* Setup_paging
	*
	* This routine sets up paging by setting the page bit
	* in cr0. The page tables are set up, identity-mapping
	* the first 8MB. The pager assumes that no illegal
	* addresses are produced (ie >4Mb on a 4Mb machine).
	*
	* NOTE! Although all physical memory should be identity
	* mapped by this routine, only the kernel page functions
	* use the >1Mb addresses directly. All "normal" functions
	* use just the lower 1Mb, or the local data space, which
	* will be mapped to some other place - mm keeps track of
	* that.
	*
	* For those with more memory than 8 Mb - tough luck. I've
	* not got it, why should you :-) The source is here. Change
	* it. (Seriously - it shouldn't be too difficult. Mostly
	* change some constants etc. I left it at 8Mb, as my machine
	* even cannot be extended past that (ok, but it was cheap :-)
	* I've tried to show which constants to change by having
	* some kind of marker at them (search for "8Mb"), but I
	* won't guarantee that's all :-( )
	*/
	.align 2
	setup_paging:
	movl $1024*3,%ecx
	xorl %eax,%eax
	xorl %edi,%edi /* pg_dir is at 0x000 */
	cld;rep;stosl
	movl $pg0+7,_pg_dir /* set present bit/user r/w */
	movl $pg1+7,_pg_dir+4 /* --------- " " --------- */
	movl $pg1+4092,%edi
	movl $0x7ff007,%eax /* 8Mb - 4096 + 7 (r/w user,p) */
	std
	1: stosl /* fill pages backwards - more efficient :-) */
	subl $0x1000,%eax
	jge 1b
	xorl %eax,%eax /* pg_dir is at 0x0000 */
	movl %eax,%cr3 /* cr3 - page directory start */
	movl %cr0,%eax
	orl $0x80000000,%eax
	movl %eax,%cr0 /* set paging (PG) bit */
	ret /* this also flushes prefetch-queue */

	.align 2
	.word 0
	idt_descr:
	.word 256*8-1 # idt contains 256 entries
	.long _idt
	.align 2
	.word 0
	gdt_descr:
	.word 256*8-1 # so does gdt (not that that's any
	.long _gdt # magic number, but it works for me :^)

	.align 3
	_idt: .fill 256,8,0 # idt is uninitialized

	_gdt: .quad 0x0000000000000000 /* NULL descriptor */
	.quad 0x00c09a00000007ff /* 8Mb */
	.quad 0x00c09200000007ff /* 8Mb */
	.quad 0x0000000000000000 /* TEMPORARY - don't use */
	.fill 252,8,0 /* space for LDT's and TSS's etc */