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sortix--sortix/kernel/x86/interrupt.S
2014-03-01 14:37:40 +01:00

598 lines
14 KiB
ArmAsm

/*******************************************************************************
Copyright(C) Jonas 'Sortie' Termansen 2011, 2012.
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/>.
x86/interrupt.S
Transfers control to interrupt handlers when interrupts happen.
*******************************************************************************/
.section .text
.global isr0
.type isr0, @function
isr0:
cli
pushl $0 # err_code
pushl $0 # int_no
jmp interrupt_handler_prepare
.global isr1
.type isr1, @function
isr1:
cli
pushl $0 # err_code
pushl $1 # int_no
jmp interrupt_handler_prepare
.global isr2
.type isr2, @function
isr2:
cli
pushl $0 # err_code
pushl $2 # int_no
jmp interrupt_handler_prepare
.global isr3
.type isr3, @function
isr3:
cli
pushl $0 # err_code
pushl $3 # int_no
jmp interrupt_handler_prepare
.global isr4
.type isr4, @function
isr4:
cli
pushl $0 # err_code
pushl $4 # int_no
jmp interrupt_handler_prepare
.global isr5
.type isr5, @function
isr5:
cli
pushl $0 # err_code
pushl $5 # int_no
jmp interrupt_handler_prepare
.global isr6
.type isr6, @function
isr6:
cli
pushl $0 # err_code
pushl $6 # int_no
jmp interrupt_handler_prepare
.global isr7
.type isr7, @function
isr7:
cli
pushl $0 # err_code
pushl $7 # int_no
jmp interrupt_handler_prepare
.global isr8
.type isr8, @function
isr8:
cli
# pushl $0 # err_code pushed by CPU
pushl $8 # int_no
jmp interrupt_handler_prepare
.global isr9
.type isr9, @function
isr9:
cli
pushl $0 # err_code
pushl $9 # int_no
jmp interrupt_handler_prepare
.global isr10
.type isr10, @function
isr10:
cli
# pushl $0 # err_code pushed by CPU
pushl $10 # int_no
jmp interrupt_handler_prepare
.global isr11
.type isr11, @function
isr11:
cli
# pushl $0 # err_code pushed by CPU
pushl $11 # int_no
jmp interrupt_handler_prepare
.global isr12
.type isr12, @function
isr12:
cli
# pushl $0 # err_code pushed by CPU
pushl $12 # int_no
jmp interrupt_handler_prepare
.global isr13
.type isr13, @function
isr13:
cli
# pushl $0 # err_code pushed by CPU
pushl $13 # int_no
jmp interrupt_handler_prepare
.global isr14
.type isr14, @function
isr14:
cli
# pushl $0 # err_code pushed by CPU
pushl $14 # int_no
jmp interrupt_handler_prepare
.global isr15
.type isr15, @function
isr15:
cli
pushl $0 # err_code
pushl $15 # int_no
jmp interrupt_handler_prepare
.global isr16
.type isr16, @function
isr16:
cli
pushl $0 # err_code
pushl $16 # int_no
jmp interrupt_handler_prepare
.global isr17
.type isr17, @function
isr17:
cli
pushl $0 # err_code
pushl $17 # int_no
jmp interrupt_handler_prepare
.global isr18
.type isr18, @function
isr18:
cli
pushl $0 # err_code
pushl $18 # int_no
jmp interrupt_handler_prepare
.global isr19
.type isr19, @function
isr19:
cli
pushl $0 # err_code
pushl $19 # int_no
jmp interrupt_handler_prepare
.global isr20
.type isr20, @function
isr20:
cli
pushl $0 # err_code
pushl $20 # int_no
jmp interrupt_handler_prepare
.global isr21
.type isr21, @function
isr21:
cli
pushl $0 # err_code
pushl $21 # int_no
jmp interrupt_handler_prepare
.global isr22
.type isr22, @function
isr22:
cli
pushl $0 # err_code
pushl $22 # int_no
jmp interrupt_handler_prepare
.global isr23
.type isr23, @function
isr23:
cli
pushl $0 # err_code
pushl $23 # int_no
jmp interrupt_handler_prepare
.global isr24
.type isr24, @function
isr24:
cli
pushl $0 # err_code
pushl $24 # int_no
jmp interrupt_handler_prepare
.global isr25
.type isr25, @function
isr25:
cli
pushl $0 # err_code
pushl $25 # int_no
jmp interrupt_handler_prepare
.global isr26
.type isr26, @function
isr26:
cli
pushl $0 # err_code
pushl $26 # int_no
jmp interrupt_handler_prepare
.global isr27
.type isr27, @function
isr27:
cli
pushl $0 # err_code
pushl $27 # int_no
jmp interrupt_handler_prepare
.global isr28
.type isr28, @function
isr28:
cli
pushl $0 # err_code
pushl $28 # int_no
jmp interrupt_handler_prepare
.global isr29
.type isr29, @function
isr29:
cli
pushl $0 # err_code
pushl $29 # int_no
jmp interrupt_handler_prepare
.global isr30
.type isr30, @function
isr30:
cli
pushl $0 # err_code
pushl $30 # int_no
jmp interrupt_handler_prepare
.global isr31
.type isr31, @function
isr31:
cli
pushl $0 # err_code
pushl $31 # int_no
jmp interrupt_handler_prepare
.global isr128
.type isr128, @function
isr128:
cli
pushl $0 # err_code
pushl $128 # int_no
jmp interrupt_handler_prepare
.global isr130
.type isr130, @function
isr130:
cli
pushl $0 # err_code
pushl $130 # int_no
jmp interrupt_handler_prepare
.global isr131
.type isr131, @function
isr131:
cli
pushl $0 # err_code
pushl $131 # int_no
jmp interrupt_handler_prepare
.global irq0
.type irq0, @function
irq0:
cli
pushl $0 # err_code
pushl $32 # int_no
jmp interrupt_handler_prepare
.global irq1
.type irq1, @function
irq1:
cli
pushl $0 # err_code
pushl $33 # int_no
jmp interrupt_handler_prepare
.global irq2
.type irq2, @function
irq2:
cli
pushl $0 # err_code
pushl $34 # int_no
jmp interrupt_handler_prepare
.global irq3
.type irq3, @function
irq3:
cli
pushl $0 # err_code
pushl $35 # int_no
jmp interrupt_handler_prepare
.global irq4
.type irq4, @function
irq4:
cli
pushl $0 # err_code
pushl $36 # int_no
jmp interrupt_handler_prepare
.global irq5
.type irq5, @function
irq5:
cli
pushl $0 # err_code
pushl $37 # int_no
jmp interrupt_handler_prepare
.global irq6
.type irq6, @function
irq6:
cli
pushl $0 # err_code
pushl $38 # int_no
jmp interrupt_handler_prepare
.global irq7
.type irq7, @function
irq7:
cli
pushl $0 # err_code
pushl $39 # int_no
jmp interrupt_handler_prepare
.global irq8
.type irq8, @function
irq8:
cli
pushl $0 # err_code
pushl $40 # int_no
jmp interrupt_handler_prepare
.global irq9
.type irq9, @function
irq9:
cli
pushl $0 # err_code
pushl $41 # int_no
jmp interrupt_handler_prepare
.global irq10
.type irq10, @function
irq10:
cli
pushl $0 # err_code
pushl $42 # int_no
jmp interrupt_handler_prepare
.global irq11
.type irq11, @function
irq11:
cli
pushl $0 # err_code
pushl $43 # int_no
jmp interrupt_handler_prepare
.global irq12
.type irq12, @function
irq12:
cli
pushl $0 # err_code
pushl $44 # int_no
jmp interrupt_handler_prepare
.global irq13
.type irq13, @function
irq13:
cli
pushl $0 # err_code
pushl $45 # int_no
jmp interrupt_handler_prepare
.global irq14
.type irq14, @function
irq14:
cli
pushl $0 # err_code
pushl $46 # int_no
jmp interrupt_handler_prepare
.global irq15
.type irq15, @function
irq15:
cli
pushl $0 # err_code
pushl $47 # int_no
jmp interrupt_handler_prepare
.global yield_cpu_handler
.type yield_cpu_handler, @function
yield_cpu_handler:
cli
pushl $0 # err_code
pushl $129 # int_no
jmp interrupt_handler_prepare
.global thread_exit_handler
.type thread_exit_handler, @function
thread_exit_handler:
cli
pushl $0 # err_code
pushl $132 # int_no
jmp interrupt_handler_prepare
interrupt_handler_prepare:
movl $1, asm_is_cpu_interrupted
# Check if an interrupt happened while having kernel permissions.
testw $0x3, 12(%esp) # cs
jz fixup_relocate_stack
fixup_relocate_stack_complete:
pushl %eax
pushl %ecx
pushl %edx
pushl %ebx
pushl %esp
pushl %ebp
pushl %esi
pushl %edi
# Push the user-space data segment.
movl %ds, %ebp
pushl %ebp
# Load the kernel data segment.
movw $0x10, %bp
movl %ebp, %ds
movl %ebp, %es
movl %ebp, %fs
movl %ebp, %gs
# Push CR2 in case of page faults
movl %cr2, %ebp
pushl %ebp
# Push the current kernel errno value.
movl global_errno, %ebp
pushl %ebp
# Push whether a signal is pending.
movl asm_signal_is_pending, %ebp
pushl %ebp
# Now call the interrupt handler.
pushl %esp
call interrupt_handler
addl $4, %esp
load_interrupted_registers:
# Restore whether signals are pending.
popl %ebp
movl %ebp, asm_signal_is_pending
# Restore the previous kernel errno.
popl %ebp
movl %ebp, global_errno
# Remove CR2 from the stack.
addl $4, %esp
# Restore the user-space data segment.
popl %ebp
movl %ebp, %ds
movl %ebp, %es
movl %ebp, %fs
movl %ebp, %gs
popl %edi
popl %esi
popl %ebp
addl $4, %esp # Don't pop %esp, may not be defined.
popl %ebx
popl %edx
popl %ecx
popl %eax
# Remove int_no and err_code
addl $8, %esp
movl $0, asm_is_cpu_interrupted
# If interrupted with kernel permissions we may need to switch stack.
testw $0x3, 4(%esp) # int_no and err_code now gone, so cs is at 4(%esp).
jz fixup_switch_stack
fixup_switch_stack_complete:
# Return to where we came from.
iret
fixup_relocate_stack:
# Ok, so some genius at Intel decided that if the permission level does not
# change during an interrupt then the CPU won't push the stack pointer and
# it won't reload it during iret. This seriously messes up the scheduler
# that wants to preempt kernel threads each with their own stack. The
# scheduler will attempt to read (and modify) the stack value which doesn't
# exist and worse: the value at that location is likely used by the
# interrupted kernel thread. A quick and dirty solution is to simply move
# the stack 8 bytes down the stack. Right now there are the 5 elements on
# the stack (eflags, cs, eip, err_code, int_no) of 5 bytes each.
mov %eax, -4-8(%esp) # Save eax
mov 0(%esp), %eax # int_no
mov %eax, 0-8(%esp)
mov 4(%esp), %eax # err_code
mov %eax, 4-8(%esp)
mov 8(%esp), %eax # eip
mov %eax, 8-8(%esp)
mov 12(%esp), %eax # cs
mov %eax, 12-8(%esp)
mov 16(%esp), %eax # eflags
mov %eax, 16-8(%esp)
# Next up we have to fake what the CPU should have done: pushed ss and esp.
mov %esp, %eax
addl $5*4, %eax # Calculate original esp
mov %eax, 20-8(%esp)
mov %ss, %eax
mov %eax, 24-8(%esp)
# Now that we moved the stack, it's time to really handle the interrupt.
mov -4-8(%esp), %eax
subl $8, %esp
jmp fixup_relocate_stack_complete
fixup_switch_stack:
# Yup, we also have to do special processing when we return from the
# interrupt. The problem is that if the iret instruction won't load a new
# stack if interrupted with kernel permissions and that the scheduler may
# wish to change the current stack during a context switch. We will then
# switch the stack before calling iret; but iret needs the return
# information on the stack (and now it isn't), so we'll copy our stack onto
# our new stack and then fire the interrupt and everyone is happy.
# In the following code, %esp will point our fixed iret return parameters
# that has stack data. However, the processor does not expect this
# information as cs hasn't changed. %ebx will point to the new stack plus
# room for three 32-bit values (eip, cs, eflags) that will be given to the
# actual iret. We will then load the new stack and copy the eip, cs and
# eflags to the new stack. However, we have to be careful in the case that
# we are switching to the same stack (in which case stuff on the same
# horizontal location in the diagram is actually on the same memory
# location). We therefore copy to the new stack and carefully avoid
# corrupting the destination if %esp + 8 = %ebx, This diagram show the
# structure of the stacks and where temporaries will be stored:
# -12 -8 -4 %esp 4 8 12 16 20
# old: IECX IEBX IEAX EIP CS EFLAGS ESP SS ...
# new: IECX IEBX IEAX - - EIP CS EFLAGS ...
# -20 -16 -12 -8 -4 %ebx 4 8 12
mov %eax, -4(%esp) # IEAX, Clobbered as copying temporary
mov %ebx, -8(%esp) # IEBX, Clobbered as pointer to new stack
mov %ecx, -12(%esp) # IECX, Clobbered as new stack selector
mov 12(%esp), %ebx # Pointer to new stack
sub $3*4, %ebx # Point to eip on the new stack (see diagram)
movw 16(%esp), %cx # New ss
# The order of these does not matter if we are switching to the same stack,
# as the memory would be copied to the same location (see diagram).
mov -4(%esp), %eax # interrupted eax value
mov %eax, -12(%ebx)
mov -8(%esp), %eax # interrupted ebx value
mov %eax, -16(%ebx)
mov -12(%esp), %eax # interrupted ecx value
mov %eax, -20(%ebx)
# The order of these three copies matter if switching to the same stack.
mov 8(%esp), %eax # eflags
mov %eax, 8(%ebx)
mov 4(%esp), %eax # cs
mov %eax, 4(%ebx)
mov 0(%esp), %eax # eip
mov %eax, 0(%ebx)
mov %cx, %ss # Load new stack selector
mov %ebx, %esp # Load new stack pointer
mov -12(%esp), %eax # restore interrupted eax value
mov -16(%esp), %ebx # restore interrupted ebx value
mov -20(%esp), %ecx # restore interrupted ecx value
jmp fixup_switch_stack_complete
.size interrupt_handler_prepare, . - interrupt_handler_prepare
.global interrupt_handler_null
.type interrupt_handler_null, @function
interrupt_handler_null:
iret
.size interrupt_handler_null, . - interrupt_handler_null
.global asm_interrupts_are_enabled
.type asm_interrupts_are_enabled, @function
asm_interrupts_are_enabled:
pushfl
popl %eax
andl $0x000200, %eax # FLAGS_INTERRUPT
retl
.size asm_interrupts_are_enabled, . - asm_interrupts_are_enabled
.global load_registers
.type load_registers, @function
load_registers:
# Let the register struct become our temporary stack
movl 4(%esp), %esp
jmp load_interrupted_registers
.size load_registers, . - load_registers