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[/] [or1k/] [trunk/] [rc203soc/] [sw/] [uClinux/] [arch/] [i386/] [kernel/] [head.S] - Rev 1623
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/*
* linux/arch/i386/head.S
*
* Copyright (C) 1991, 1992 Linus Torvalds
*/
/*
* head.S contains the 32-bit startup code.
*/
.text
#include <linux/config.h>
#include <linux/tasks.h>
#include <linux/linkage.h>
#include <asm/segment.h>
#include <linux/config.h>
#include <asm/page.h>
#include <asm/pgtable.h>
#define CL_MAGIC_ADDR 0x90020
#define CL_MAGIC 0xA33F
#define CL_BASE_ADDR 0x90000
#define CL_OFFSET 0x90022
/*
* swapper_pg_dir is the main page directory, address 0x00001000 (or at
* address 0x00101000 for a compressed boot).
*/
ENTRY(stext)
ENTRY(_stext)
startup_32:
cld
movl $(KERNEL_DS),%eax
mov %ax,%ds
mov %ax,%es
mov %ax,%fs
mov %ax,%gs
#ifdef __SMP__
orw %bx,%bx
jz 1f /* Initial CPU cleans BSS */
/*
* Set up the stack
*/
mov %ax,%ss
xorl %eax,%eax
movw %cx, %ax
movl %eax,%esp
pushl $0
popfl
jmp checkCPUtype
1:
lss stack_start,%esp
#endif __SMP__
/*
* Clear BSS first so that there are no surprises...
*/
xorl %eax,%eax
movl $ SYMBOL_NAME(_edata),%edi
movl $ SYMBOL_NAME(_end),%ecx
subl %edi,%ecx
cld
rep
stosb
/*
* start system 32-bit setup. We need to re-do some of the things done
* in 16-bit mode for the "real" operations.
*/
call setup_idt
xorl %eax,%eax
1: incl %eax # check that A20 really IS enabled
movl %eax,0x000000 # loop forever if it isn't
cmpl %eax,0x100000
je 1b
/*
* Initialize eflags. Some BIOS's leave bits like NT set. This would
* confuse the debugger if this code is traced.
* XXX - best to initialize before switching to protected mode.
*/
pushl $0
popfl
/*
* Copy bootup parameters out of the way. First 2kB of
* _empty_zero_page is for boot parameters, second 2kB
* is for the command line.
*/
movl $0x90000,%esi
movl $ SYMBOL_NAME(empty_zero_page),%edi
movl $512,%ecx
cld
rep
movsl
xorl %eax,%eax
movl $512,%ecx
rep
stosl
cmpw $(CL_MAGIC),CL_MAGIC_ADDR
jne 1f
movl $ SYMBOL_NAME(empty_zero_page)+2048,%edi
movzwl CL_OFFSET,%esi
addl $(CL_BASE_ADDR),%esi
movl $2048,%ecx
rep
movsb
1:
#ifdef __SMP__
checkCPUtype:
#endif
/* check Processor type: 386, 486, 6x86(L) or CPUID capable processor */
/*
* XXX - this does a lot of unnecessary setup. Alignment checks don't
* apply at our cpl of 0 and the stack ought to be aligned already, and
* we don't need to preserve eflags.
*/
movl $3, SYMBOL_NAME(x86)
pushfl # push EFLAGS
popl %eax # get EFLAGS
movl %eax,%ecx # save original EFLAGS in ecx
xorl $0x40000,%eax # flip AC bit in EFLAGS
pushl %eax # copy to EFLAGS
popfl # set EFLAGS
pushfl # get new EFLAGS
popl %eax # put it in eax
xorl %ecx,%eax # change in flags
andl $0x40000,%eax # check if AC bit changed
je is386
movl $4,SYMBOL_NAME(x86)
movl %ecx,%eax
xorl $0x200000,%eax # check ID flag
pushl %eax
popfl # if we are on a straight 486DX, SX, or
pushfl # 487SX we can't change it
popl %eax # Also if we are on a Cyrix 6x86(L)
xorl %ecx,%eax # OTOH 6x86MXs and MIIs check OK
andl $0x200000,%eax
je is486x
isnew: pushl %ecx # restore original EFLAGS
popfl
incl SYMBOL_NAME(have_cpuid) # we have CPUID
/*
* Technically we should use CPUID 0 to see if we have CPUID 1!
*/
/* get processor type */
movl $1, %eax # Use the CPUID instruction to
#ifdef GAS_KNOWS_CPUID
cpuid # check the processor type
#else
.byte 0x0f, 0xa2 # check the processor type
#endif
movb %al, %cl # save reg for future use
andb $0x0f,%ah # mask processor family
movb %ah,SYMBOL_NAME(x86)
andb $0xf0, %al # mask model
shrb $4, %al
movb %al,SYMBOL_NAME(x86_model)
andb $0x0f, %cl # mask mask revision
movb %cl,SYMBOL_NAME(x86_mask)
movl %edx,SYMBOL_NAME(x86_capability)
/* get vendor info */
xorl %eax, %eax # call CPUID with 0 -> return vendor ID
#ifdef GAS_KNOWS_CPUID
cpuid
#else
.byte 0x0f, 0xa2 # CPUID
#endif
movl %ebx,SYMBOL_NAME(x86_vendor_id) # lo 4 chars
movl %edx,SYMBOL_NAME(x86_vendor_id)+4 # next 4 chars
movl %ecx,SYMBOL_NAME(x86_vendor_id)+8 # last 4 chars
movl %cr0,%eax # 486+
andl $0x80000011,%eax # Save PG,PE,ET
orl $0x50022,%eax # set AM, WP, NE and MP
jmp 2f
/* Now we test if we have a Cyrix 6x86(L). We didn't test before to avoid
* clobbering the new BX chipset used with the Pentium II, which has a register
* at the same addresses as those used to access the Cyrix special configuration
* registers (CCRs).
*/
/*
* A Cyrix/IBM 6x86(L) preserves flags after dividing 5 by 2
* (and it _must_ be 5 divided by 2) while other CPUs change
* them in undefined ways. We need to know this since we may
* need to enable the CPUID instruction at least.
* We couldn't use this test before since the PPro and PII behave
* like Cyrix chips in this respect.
*/
is486x: xor %ax,%ax
sahf
movb $5,%ax
movb $2,%bx
div %bl
lahf
cmpb $2,%ah
jne ncyrix
/*
* N.B. The pattern of accesses to 0x22 and 0x23 is *essential*
* so do not try to "optimize" it! For the same reason we
* do all this with interrupts off.
*/
#define setCx86(reg, val) \
movb reg,%ax; \
outb %ax,$0x22; \
movb val,%ax; \
outb %ax,$0x23
#define getCx86(reg) \
movb reg,%ax; \
outb %ax,$0x22; \
inb $0x23,%ax
cli
getCx86($0xc3) # get CCR3
movb %ax,%cx # Save old value
movb %ax,%bx
andb $0x0f,%bx # Enable access to all config registers
orb $0x10,%bx # by setting bit 4
setCx86($0xc3,%bx)
getCx86($0xfe) # DIR0 : let's check this is a 6x86(L)
andb $0xf0,%ax # should be 3xh
cmpb $0x30,%ax #
jne n6x86
getCx86($0xe8) # now we can get CCR4
orb $0x80,%ax # and set bit 7 (CPUIDEN)
movb %ax,%bx # to enable CPUID execution
setCx86($0xe8,%bx)
getCx86($0xe9) # CCR5 : we reset the SLOP bit
andb $0xfd,%ax # so that udelay calculation
movb %ax,%bx # is correct on 6x86(L) CPUs
setCx86($0xe9,%bx)
setCx86($0xc3,%cx) # Restore old CCR3
sti
jmp isnew # We enabled CPUID now
n6x86: setCx86($0xc3,%cx) # Restore old CCR3
sti
ncyrix: pushl %ecx # restore original EFLAGS
popfl
movl %cr0,%eax # 486
andl $0x80000011,%eax # Save PG,PE,ET
orl $0x50022,%eax # set AM, WP, NE and MP
jmp 2f
is386: pushl %ecx # restore original EFLAGS
popfl
movl %cr0,%eax # 386
andl $0x80000011,%eax # Save PG,PE,ET
orl $2,%eax # set MP
2: movl %eax,%cr0
call check_x87
#ifdef __SMP__
movb ready,%al
orb %al,%al
jz 3f
movl $ SYMBOL_NAME(swapper_pg_dir), %eax
movl %eax, %cr3
#ifdef GAS_KNOWS_CR4
movl %cr4,%eax
orl $16,%eax
movl %eax,%cr4
#else
.byte 0x0f,0x20,0xe0
orl $16,%eax
.byte 0x0f,0x22,0xe0
#endif
movl %cr0, %eax
orl $0x80000000, %eax
movl %eax, %cr0
jmp 4f
#endif
3:
call setup_paging
#ifdef __SMP__
incb ready
#endif
4:
lgdt gdt_descr
lidt idt_descr
ljmp $(KERNEL_CS),$1f
1: movl $(KERNEL_DS),%eax # reload all the segment registers
mov %ax,%ds # after changing gdt.
mov %ax,%es
mov %ax,%fs
mov %ax,%gs
#ifdef __SMP__
movl $(KERNEL_DS), %eax
mov %ax,%ss # Reload the stack pointer (segment only)
#else
lss stack_start,%esp # Load processor stack
#endif
xorl %eax,%eax
lldt %ax
pushl %eax # These are the parameters to main :-)
pushl %eax
pushl %eax
cld # gcc2 wants the direction flag cleared at all times
call SYMBOL_NAME(start_kernel)
L6:
jmp L6 # main should never return here, but
# just in case, we know what happens.
#ifdef __SMP__
ready: .byte 0
#endif
/*
* We depend on ET to be correct. This checks for 287/387.
*/
check_x87:
movb $0,SYMBOL_NAME(hard_math)
clts
fninit
fstsw %ax
cmpb $0,%al
je 1f
movl %cr0,%eax /* no coprocessor: have to set bits */
xorl $4,%eax /* set EM */
movl %eax,%cr0
ret
ALIGN
1: movb $1,SYMBOL_NAME(hard_math)
.byte 0xDB,0xE4 /* fsetpm for 287, ignored by 387 */
ret
/*
* setup_idt
*
* sets up a idt with 256 entries pointing to
* ignore_int, interrupt gates. It doesn't actually load
* idt - that can be done only after paging has been enabled
* and the kernel moved to PAGE_OFFSET. Interrupts
* are enabled elsewhere, when we can be relatively
* sure everything is ok.
*/
setup_idt:
lea ignore_int,%edx
movl $(KERNEL_CS << 16),%eax
movw %dx,%ax /* selector = 0x0010 = cs */
movw $0x8E00,%dx /* interrupt gate - dpl=0, present */
lea SYMBOL_NAME(idt),%edi
mov $256,%ecx
rp_sidt:
movl %eax,(%edi)
movl %edx,4(%edi)
addl $8,%edi
dec %ecx
jne rp_sidt
ret
/*
* Setup_paging
*
* This routine sets up paging by setting the page bit
* in cr0. The page tables are set up, identity-mapping
* the first 4MB. The rest are initialized later.
*
* (ref: added support for up to 32mb, 17Apr92) -- Rik Faith
* (ref: update, 25Sept92) -- croutons@crunchy.uucp
* (ref: 92.10.11 - Linus Torvalds. Corrected 16M limit - no upper memory limit)
*/
ALIGN
setup_paging:
movl $1024*2,%ecx /* 2 pages - swapper_pg_dir+1 page table */
xorl %eax,%eax
movl $ SYMBOL_NAME(swapper_pg_dir),%edi /* swapper_pg_dir is at 0x1000 */
cld;rep;stosl
/* Identity-map the kernel in low 4MB memory for ease of transition */
/* set present bit/user r/w */
movl $ SYMBOL_NAME(pg0)+7,SYMBOL_NAME(swapper_pg_dir)
/* But the real place is at PAGE_OFFSET */
/* set present bit/user r/w */
movl $ SYMBOL_NAME(pg0)+7,SYMBOL_NAME(swapper_pg_dir)+__USER_PGD_PTRS*4
movl $ SYMBOL_NAME(pg0)+4092,%edi
movl $0x03ff007,%eax /* 4Mb - 4096 + 7 (r/w user,p) */
std
1: stosl /* fill the page backwards - more efficient :-) */
subl $0x1000,%eax
jge 1b
cld
movl $ SYMBOL_NAME(swapper_pg_dir),%eax
movl %eax,%cr3 /* cr3 - page directory start */
movl %cr0,%eax
orl $0x80000000,%eax
movl %eax,%cr0 /* set paging (PG) bit */
ret /* this also flushes the prefetch-queue */
/*
* page 0 is made non-existent, so that kernel NULL pointer references get
* caught. Thus the swapper page directory has been moved to 0x1000
*
* XXX Actually, the swapper page directory is at 0x1000 plus 1 megabyte,
* with the introduction of the compressed boot code. Theoretically,
* the original design of overlaying the startup code with the swapper
* page directory is still possible --- it would reduce the size of the kernel
* by 2-3k. This would be a good thing to do at some point.....
*/
.org 0x1000
ENTRY(swapper_pg_dir)
/*
* The page tables are initialized to only 4MB here - the final page
* tables are set up later depending on memory size.
*/
.org 0x2000
ENTRY(pg0)
.org 0x3000
ENTRY(empty_bad_page)
.org 0x4000
ENTRY(empty_bad_page_table)
.org 0x5000
ENTRY(empty_zero_page)
.org 0x6000
stack_start:
.long SYMBOL_NAME(init_user_stack)+4096
.long KERNEL_DS
/* NOTE: keep the idt short behind the above '.org 0x6000'
It must fit completely within _one_ page */
ENTRY(idt)
.fill 256,8,0 # idt is uninitialized
/* This is the default interrupt "handler" :-) */
int_msg:
.asciz "Unknown interrupt\n"
ALIGN
ignore_int:
cld
pushl %eax
pushl %ecx
pushl %edx
push %ds
push %es
push %fs
movl $(KERNEL_DS),%eax
mov %ax,%ds
mov %ax,%es
mov %ax,%fs
pushl $int_msg
call SYMBOL_NAME(printk)
popl %eax
pop %fs
pop %es
pop %ds
popl %edx
popl %ecx
popl %eax
iret
/*
* The interrupt descriptor table has room for 256 idt's
*/
ALIGN
.word 0
idt_descr:
.word 256*8-1 # idt contains 256 entries
.long __PAGE_OFFSET+SYMBOL_NAME(idt)
ALIGN
.word 0
gdt_descr:
#ifdef CONFIG_APM
.word (11+2*NR_TASKS)*8-1
#else
.word (8+2*NR_TASKS)*8-1
#endif
.long __PAGE_OFFSET+SYMBOL_NAME(gdt)
/*
* This gdt setup gives the kernel a 1GB address space at virtual
* address PAGE_OFFSET - space enough for expansion, I hope.
*/
#define upper_seg(type,dpl,base,limit) \
((base) & 0xff000000) | \
(((base) & 0x00ff0000)>>16) | \
(((limit)>>12) & 0xf0000) | \
((dpl)<<13) | \
(0x00c09000) | \
((type)<<8)
#define lower_seg(type,dpl,base,limit) \
(((base) & 0x0000ffff)<<16) | \
(((limit)>>12) & 0x0ffff)
#define x86_seg(type,dpl,base,limit) \
.long lower_seg(type,dpl,base,limit); \
.long upper_seg(type,dpl,base,limit)
ENTRY(gdt)
.quad 0x0000000000000000 /* NULL descriptor */
.quad 0x0000000000000000 /* not used */
/* 0x10 kernel 1GB code at 0xC0000000: */
x86_seg(0xa,0,__PAGE_OFFSET,0xffffffff-__PAGE_OFFSET)
/* 0x18 kernel 1GB data at 0xC0000000: */
x86_seg(0x2,0,__PAGE_OFFSET,0xffffffff-__PAGE_OFFSET)
/* 0x23 user 3GB code at 0x00000000: */
x86_seg(0xa,3,0,__PAGE_OFFSET-1)
/* 0x2b user 3GB data at 0x00000000: */
x86_seg(0x2,3,0,__PAGE_OFFSET-1)
.quad 0x0000000000000000 /* not used */
.quad 0x0000000000000000 /* not used */
.fill 2*NR_TASKS,8,0 /* space for LDT's and TSS's etc */
#ifdef CONFIG_APM
.quad 0x00c09a0000000000 /* APM CS code */
.quad 0x00809a0000000000 /* APM CS 16 code (16 bit) */
.quad 0x00c0920000000000 /* APM DS data */
#endif
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