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zircon-guest / third_party / linux / 9b37ccfc637be27d9a652fcedc35e6e782c3aa78 / . / arch / sparc / kernel / entry.S
blob: c2eed8f71516b80e7dd71a048f44cc2c174e399f [file] [log] [blame]
/* arch/sparc/kernel/entry.S: Sparc trap low-level entry points.
*
* Copyright (C) 1995, 2007 David S. Miller (davem@davemloft.net)
* Copyright (C) 1996 Eddie C. Dost (ecd@skynet.be)
* Copyright (C) 1996 Miguel de Icaza (miguel@nuclecu.unam.mx)
* Copyright (C) 1996-1999 Jakub Jelinek (jj@sunsite.mff.cuni.cz)
* Copyright (C) 1997 Anton Blanchard (anton@progsoc.uts.edu.au)
*/
#include <linux/errno.h>
#include <asm/head.h>
#include <asm/asi.h>
#include <asm/smp.h>
#include <asm/kgdb.h>
#include <asm/contregs.h>
#include <asm/ptrace.h>
#include <asm/asm-offsets.h>
#include <asm/psr.h>
#include <asm/vaddrs.h>
#include <asm/memreg.h>
#include <asm/page.h>
#ifdef CONFIG_SUN4
#include <asm/pgtsun4.h>
#else
#include <asm/pgtsun4c.h>
#endif
#include <asm/winmacro.h>
#include <asm/signal.h>
#include <asm/obio.h>
#include <asm/mxcc.h>
#include <asm/thread_info.h>
#include <asm/param.h>
#include <asm/unistd.h>
#include <asm/asmmacro.h>
#define curptr g6
/* These are just handy. */
#define _SV save %sp, -STACKFRAME_SZ, %sp
#define _RS restore
#define FLUSH_ALL_KERNEL_WINDOWS \
_SV; _SV; _SV; _SV; _SV; _SV; _SV; \
_RS; _RS; _RS; _RS; _RS; _RS; _RS;
/* First, KGDB low level things. This is a rewrite
* of the routines found in the sparc-stub.c asm() statement
* from the gdb distribution. This is also dual-purpose
* as a software trap for userlevel programs.
*/
.data
.align 4
in_trap_handler:
.word 0
.text
.align 4
#if 0 /* kgdb is dropped from 2.5.33 */
! This function is called when any SPARC trap (except window overflow or
! underflow) occurs. It makes sure that the invalid register window is still
! available before jumping into C code. It will also restore the world if you
! return from handle_exception.
.globl trap_low
trap_low:
rd %wim, %l3
SAVE_ALL
sethi %hi(in_trap_handler), %l4
ld [%lo(in_trap_handler) + %l4], %l5
inc %l5
st %l5, [%lo(in_trap_handler) + %l4]
/* Make sure kgdb sees the same state we just saved. */
LOAD_PT_GLOBALS(sp)
LOAD_PT_INS(sp)
ld [%sp + STACKFRAME_SZ + PT_Y], %l4
ld [%sp + STACKFRAME_SZ + PT_WIM], %l3
ld [%sp + STACKFRAME_SZ + PT_PSR], %l0
ld [%sp + STACKFRAME_SZ + PT_PC], %l1
ld [%sp + STACKFRAME_SZ + PT_NPC], %l2
rd %tbr, %l5 /* Never changes... */
/* Make kgdb exception frame. */
sub %sp,(16+1+6+1+72)*4,%sp ! Make room for input & locals
! + hidden arg + arg spill
! + doubleword alignment
! + registers[72] local var
SAVE_KGDB_GLOBALS(sp)
SAVE_KGDB_INS(sp)
SAVE_KGDB_SREGS(sp, l4, l0, l3, l5, l1, l2)
/* We are increasing PIL, so two writes. */
or %l0, PSR_PIL, %l0
wr %l0, 0, %psr
WRITE_PAUSE
wr %l0, PSR_ET, %psr
WRITE_PAUSE
call handle_exception
add %sp, STACKFRAME_SZ, %o0 ! Pass address of registers
/* Load new kgdb register set. */
LOAD_KGDB_GLOBALS(sp)
LOAD_KGDB_INS(sp)
LOAD_KGDB_SREGS(sp, l4, l0, l3, l5, l1, l2)
wr %l4, 0x0, %y
sethi %hi(in_trap_handler), %l4
ld [%lo(in_trap_handler) + %l4], %l5
dec %l5
st %l5, [%lo(in_trap_handler) + %l4]
add %sp,(16+1+6+1+72)*4,%sp ! Undo the kgdb trap frame.
/* Now take what kgdb did and place it into the pt_regs
* frame which SparcLinux RESTORE_ALL understands.,
*/
STORE_PT_INS(sp)
STORE_PT_GLOBALS(sp)
STORE_PT_YREG(sp, g2)
STORE_PT_PRIV(sp, l0, l1, l2)
RESTORE_ALL
#endif
#if defined(CONFIG_BLK_DEV_FD) || defined(CONFIG_BLK_DEV_FD_MODULE)
.text
.align 4
.globl floppy_hardint
floppy_hardint:
/*
* This code cannot touch registers %l0 %l1 and %l2
* because SAVE_ALL depends on their values. It depends
* on %l3 also, but we regenerate it before a call.
* Other registers are:
* %l3 -- base address of fdc registers
* %l4 -- pdma_vaddr
* %l5 -- scratch for ld/st address
* %l6 -- pdma_size
* %l7 -- scratch [floppy byte, ld/st address, aux. data]
*/
/* Do we have work to do? */
sethi %hi(doing_pdma), %l7
ld [%l7 + %lo(doing_pdma)], %l7
cmp %l7, 0
be floppy_dosoftint
nop
/* Load fdc register base */
sethi %hi(fdc_status), %l3
ld [%l3 + %lo(fdc_status)], %l3
/* Setup register addresses */
sethi %hi(pdma_vaddr), %l5 ! transfer buffer
ld [%l5 + %lo(pdma_vaddr)], %l4
sethi %hi(pdma_size), %l5 ! bytes to go
ld [%l5 + %lo(pdma_size)], %l6
next_byte:
ldub [%l3], %l7
andcc %l7, 0x80, %g0 ! Does fifo still have data
bz floppy_fifo_emptied ! fifo has been emptied...
andcc %l7, 0x20, %g0 ! in non-dma mode still?
bz floppy_overrun ! nope, overrun
andcc %l7, 0x40, %g0 ! 0=write 1=read
bz floppy_write
sub %l6, 0x1, %l6
/* Ok, actually read this byte */
ldub [%l3 + 1], %l7
orcc %g0, %l6, %g0
stb %l7, [%l4]
bne next_byte
add %l4, 0x1, %l4
b floppy_tdone
nop
floppy_write:
/* Ok, actually write this byte */
ldub [%l4], %l7
orcc %g0, %l6, %g0
stb %l7, [%l3 + 1]
bne next_byte
add %l4, 0x1, %l4
/* fall through... */
floppy_tdone:
sethi %hi(pdma_vaddr), %l5
st %l4, [%l5 + %lo(pdma_vaddr)]
sethi %hi(pdma_size), %l5
st %l6, [%l5 + %lo(pdma_size)]
/* Flip terminal count pin */
set auxio_register, %l7
ld [%l7], %l7
set sparc_cpu_model, %l5
ld [%l5], %l5
subcc %l5, 1, %g0 /* enum { sun4c = 1 }; */
be 1f
ldub [%l7], %l5
or %l5, 0xc2, %l5
stb %l5, [%l7]
andn %l5, 0x02, %l5
b 2f
nop
1:
or %l5, 0xf4, %l5
stb %l5, [%l7]
andn %l5, 0x04, %l5
2:
/* Kill some time so the bits set */
WRITE_PAUSE
WRITE_PAUSE
stb %l5, [%l7]
/* Prevent recursion */
sethi %hi(doing_pdma), %l7
b floppy_dosoftint
st %g0, [%l7 + %lo(doing_pdma)]
/* We emptied the FIFO, but we haven't read everything
* as of yet. Store the current transfer address and
* bytes left to read so we can continue when the next
* fast IRQ comes in.
*/
floppy_fifo_emptied:
sethi %hi(pdma_vaddr), %l5
st %l4, [%l5 + %lo(pdma_vaddr)]
sethi %hi(pdma_size), %l7
st %l6, [%l7 + %lo(pdma_size)]
/* Restore condition codes */
wr %l0, 0x0, %psr
WRITE_PAUSE
jmp %l1
rett %l2
floppy_overrun:
sethi %hi(pdma_vaddr), %l5
st %l4, [%l5 + %lo(pdma_vaddr)]
sethi %hi(pdma_size), %l5
st %l6, [%l5 + %lo(pdma_size)]
/* Prevent recursion */
sethi %hi(doing_pdma), %l7
st %g0, [%l7 + %lo(doing_pdma)]
/* fall through... */
floppy_dosoftint:
rd %wim, %l3
SAVE_ALL
/* Set all IRQs off. */
or %l0, PSR_PIL, %l4
wr %l4, 0x0, %psr
WRITE_PAUSE
wr %l4, PSR_ET, %psr
WRITE_PAUSE
mov 11, %o0 ! floppy irq level (unused anyway)
mov %g0, %o1 ! devid is not used in fast interrupts
call sparc_floppy_irq
add %sp, STACKFRAME_SZ, %o2 ! struct pt_regs *regs
RESTORE_ALL
#endif /* (CONFIG_BLK_DEV_FD) */
/* Bad trap handler */
.globl bad_trap_handler
bad_trap_handler:
SAVE_ALL
wr %l0, PSR_ET, %psr
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0 ! pt_regs
call do_hw_interrupt
mov %l7, %o1 ! trap number
RESTORE_ALL
/* For now all IRQ's not registered get sent here. handler_irq() will
* see if a routine is registered to handle this interrupt and if not
* it will say so on the console.
*/
.align 4
.globl real_irq_entry, patch_handler_irq
real_irq_entry:
SAVE_ALL
#ifdef CONFIG_SMP
.globl patchme_maybe_smp_msg
cmp %l7, 12
patchme_maybe_smp_msg:
bgu maybe_smp4m_msg
nop
#endif
real_irq_continue:
or %l0, PSR_PIL, %g2
wr %g2, 0x0, %psr
WRITE_PAUSE
wr %g2, PSR_ET, %psr
WRITE_PAUSE
mov %l7, %o0 ! irq level
patch_handler_irq:
call handler_irq
add %sp, STACKFRAME_SZ, %o1 ! pt_regs ptr
or %l0, PSR_PIL, %g2 ! restore PIL after handler_irq
wr %g2, PSR_ET, %psr ! keep ET up
WRITE_PAUSE
RESTORE_ALL
#ifdef CONFIG_SMP
/* SMP per-cpu ticker interrupts are handled specially. */
smp4m_ticker:
bne real_irq_continue+4
or %l0, PSR_PIL, %g2
wr %g2, 0x0, %psr
WRITE_PAUSE
wr %g2, PSR_ET, %psr
WRITE_PAUSE
call smp4m_percpu_timer_interrupt
add %sp, STACKFRAME_SZ, %o0
wr %l0, PSR_ET, %psr
WRITE_PAUSE
RESTORE_ALL
/* Here is where we check for possible SMP IPI passed to us
* on some level other than 15 which is the NMI and only used
* for cross calls. That has a separate entry point below.
*/
maybe_smp4m_msg:
GET_PROCESSOR4M_ID(o3)
set sun4m_interrupts, %l5
ld [%l5], %o5
sethi %hi(0x40000000), %o2
sll %o3, 12, %o3
ld [%o5 + %o3], %o1
andcc %o1, %o2, %g0
be,a smp4m_ticker
cmp %l7, 14
st %o2, [%o5 + 0x4]
WRITE_PAUSE
ld [%o5], %g0
WRITE_PAUSE
or %l0, PSR_PIL, %l4
wr %l4, 0x0, %psr
WRITE_PAUSE
wr %l4, PSR_ET, %psr
WRITE_PAUSE
call smp_reschedule_irq
nop
RESTORE_ALL
.align 4
.globl linux_trap_ipi15_sun4m
linux_trap_ipi15_sun4m:
SAVE_ALL
sethi %hi(0x80000000), %o2
GET_PROCESSOR4M_ID(o0)
set sun4m_interrupts, %l5
ld [%l5], %o5
sll %o0, 12, %o0
add %o5, %o0, %o5
ld [%o5], %o3
andcc %o3, %o2, %g0
be 1f ! Must be an NMI async memory error
st %o2, [%o5 + 4]
WRITE_PAUSE
ld [%o5], %g0
WRITE_PAUSE
or %l0, PSR_PIL, %l4
wr %l4, 0x0, %psr
WRITE_PAUSE
wr %l4, PSR_ET, %psr
WRITE_PAUSE
call smp4m_cross_call_irq
nop
b ret_trap_lockless_ipi
clr %l6
1:
/* NMI async memory error handling. */
sethi %hi(0x80000000), %l4
sethi %hi(0x4000), %o3
sub %o5, %o0, %o5
add %o5, %o3, %l5
st %l4, [%l5 + 0xc]
WRITE_PAUSE
ld [%l5], %g0
WRITE_PAUSE
or %l0, PSR_PIL, %l4
wr %l4, 0x0, %psr
WRITE_PAUSE
wr %l4, PSR_ET, %psr
WRITE_PAUSE
call sun4m_nmi
nop
st %l4, [%l5 + 0x8]
WRITE_PAUSE
ld [%l5], %g0
WRITE_PAUSE
RESTORE_ALL
.globl smp4d_ticker
/* SMP per-cpu ticker interrupts are handled specially. */
smp4d_ticker:
SAVE_ALL
or %l0, PSR_PIL, %g2
sethi %hi(CC_ICLR), %o0
sethi %hi(1 << 14), %o1
or %o0, %lo(CC_ICLR), %o0
stha %o1, [%o0] ASI_M_MXCC /* Clear PIL 14 in MXCC's ICLR */
wr %g2, 0x0, %psr
WRITE_PAUSE
wr %g2, PSR_ET, %psr
WRITE_PAUSE
call smp4d_percpu_timer_interrupt
add %sp, STACKFRAME_SZ, %o0
wr %l0, PSR_ET, %psr
WRITE_PAUSE
RESTORE_ALL
.align 4
.globl linux_trap_ipi15_sun4d
linux_trap_ipi15_sun4d:
SAVE_ALL
sethi %hi(CC_BASE), %o4
sethi %hi(MXCC_ERR_ME|MXCC_ERR_PEW|MXCC_ERR_ASE|MXCC_ERR_PEE), %o2
or %o4, (CC_EREG - CC_BASE), %o0
ldda [%o0] ASI_M_MXCC, %o0
andcc %o0, %o2, %g0
bne 1f
sethi %hi(BB_STAT2), %o2
lduba [%o2] ASI_M_CTL, %o2
andcc %o2, BB_STAT2_MASK, %g0
bne 2f
or %o4, (CC_ICLR - CC_BASE), %o0
sethi %hi(1 << 15), %o1
stha %o1, [%o0] ASI_M_MXCC /* Clear PIL 15 in MXCC's ICLR */
or %l0, PSR_PIL, %l4
wr %l4, 0x0, %psr
WRITE_PAUSE
wr %l4, PSR_ET, %psr
WRITE_PAUSE
call smp4d_cross_call_irq
nop
b ret_trap_lockless_ipi
clr %l6
1: /* MXCC error */
2: /* BB error */
/* Disable PIL 15 */
set CC_IMSK, %l4
lduha [%l4] ASI_M_MXCC, %l5
sethi %hi(1 << 15), %l7
or %l5, %l7, %l5
stha %l5, [%l4] ASI_M_MXCC
/* FIXME */
1: b,a 1b
#endif /* CONFIG_SMP */
/* This routine handles illegal instructions and privileged
* instruction attempts from user code.
*/
.align 4
.globl bad_instruction
bad_instruction:
sethi %hi(0xc1f80000), %l4
ld [%l1], %l5
sethi %hi(0x81d80000), %l7
and %l5, %l4, %l5
cmp %l5, %l7
be 1f
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call do_illegal_instruction
mov %l0, %o3
RESTORE_ALL
1: /* unimplemented flush - just skip */
jmpl %l2, %g0
rett %l2 + 4
.align 4
.globl priv_instruction
priv_instruction:
SAVE_ALL
wr %l0, PSR_ET, %psr
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call do_priv_instruction
mov %l0, %o3
RESTORE_ALL
/* This routine handles unaligned data accesses. */
.align 4
.globl mna_handler
mna_handler:
andcc %l0, PSR_PS, %g0
be mna_fromuser
nop
SAVE_ALL
wr %l0, PSR_ET, %psr
WRITE_PAUSE
ld [%l1], %o1
call kernel_unaligned_trap
add %sp, STACKFRAME_SZ, %o0
RESTORE_ALL
mna_fromuser:
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
ld [%l1], %o1
call user_unaligned_trap
add %sp, STACKFRAME_SZ, %o0
RESTORE_ALL
/* This routine handles floating point disabled traps. */
.align 4
.globl fpd_trap_handler
fpd_trap_handler:
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call do_fpd_trap
mov %l0, %o3
RESTORE_ALL
/* This routine handles Floating Point Exceptions. */
.align 4
.globl fpe_trap_handler
fpe_trap_handler:
set fpsave_magic, %l5
cmp %l1, %l5
be 1f
sethi %hi(fpsave), %l5
or %l5, %lo(fpsave), %l5
cmp %l1, %l5
bne 2f
sethi %hi(fpsave_catch2), %l5
or %l5, %lo(fpsave_catch2), %l5
wr %l0, 0x0, %psr
WRITE_PAUSE
jmp %l5
rett %l5 + 4
1:
sethi %hi(fpsave_catch), %l5
or %l5, %lo(fpsave_catch), %l5
wr %l0, 0x0, %psr
WRITE_PAUSE
jmp %l5
rett %l5 + 4
2:
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call do_fpe_trap
mov %l0, %o3
RESTORE_ALL
/* This routine handles Tag Overflow Exceptions. */
.align 4
.globl do_tag_overflow
do_tag_overflow:
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call handle_tag_overflow
mov %l0, %o3
RESTORE_ALL
/* This routine handles Watchpoint Exceptions. */
.align 4
.globl do_watchpoint
do_watchpoint:
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call handle_watchpoint
mov %l0, %o3
RESTORE_ALL
/* This routine handles Register Access Exceptions. */
.align 4
.globl do_reg_access
do_reg_access:
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call handle_reg_access
mov %l0, %o3
RESTORE_ALL
/* This routine handles Co-Processor Disabled Exceptions. */
.align 4
.globl do_cp_disabled
do_cp_disabled:
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call handle_cp_disabled
mov %l0, %o3
RESTORE_ALL
/* This routine handles Co-Processor Exceptions. */
.align 4
.globl do_cp_exception
do_cp_exception:
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call handle_cp_exception
mov %l0, %o3
RESTORE_ALL
/* This routine handles Hardware Divide By Zero Exceptions. */
.align 4
.globl do_hw_divzero
do_hw_divzero:
SAVE_ALL
wr %l0, PSR_ET, %psr ! re-enable traps
WRITE_PAUSE
add %sp, STACKFRAME_SZ, %o0
mov %l1, %o1
mov %l2, %o2
call handle_hw_divzero
mov %l0, %o3
RESTORE_ALL
.align 4
.globl do_flush_windows
do_flush_windows:
SAVE_ALL
wr %l0, PSR_ET, %psr
WRITE_PAUSE
andcc %l0, PSR_PS, %g0
bne dfw_kernel
nop
call flush_user_windows
nop
/* Advance over the trap instruction. */
ld [%sp + STACKFRAME_SZ + PT_NPC], %l1
add %l1, 0x4, %l2
st %l1, [%sp + STACKFRAME_SZ + PT_PC]
st %l2, [%sp + STACKFRAME_SZ + PT_NPC]
RESTORE_ALL
.globl flush_patch_one
/* We get these for debugging routines using __builtin_return_address() */
dfw_kernel:
flush_patch_one:
FLUSH_ALL_KERNEL_WINDOWS
/* Advance over the trap instruction. */
ld [%sp + STACKFRAME_SZ + PT_NPC], %l1
add %l1, 0x4, %l2
st %l1, [%sp + STACKFRAME_SZ + PT_PC]
st %l2, [%sp + STACKFRAME_SZ + PT_NPC]
RESTORE_ALL
/* The getcc software trap. The user wants the condition codes from
* the %psr in register %g1.
*/
.align 4
.globl getcc_trap_handler
getcc_trap_handler:
srl %l0, 20, %g1 ! give user
and %g1, 0xf, %g1 ! only ICC bits in %psr
jmp %l2 ! advance over trap instruction
rett %l2 + 0x4 ! like this...
/* The setcc software trap. The user has condition codes in %g1
* that it would like placed in the %psr. Be careful not to flip
* any unintentional bits!
*/
.align 4
.globl setcc_trap_handler
setcc_trap_handler:
sll %g1, 0x14, %l4
set PSR_ICC, %l5
andn %l0, %l5, %l0 ! clear ICC bits in %psr
and %l4, %l5, %l4 ! clear non-ICC bits in user value
or %l4, %l0, %l4 ! or them in... mix mix mix
wr %l4, 0x0, %psr ! set new %psr
WRITE_PAUSE ! TI scumbags...
jmp %l2 ! advance over trap instruction
rett %l2 + 0x4 ! like this...
.align 4
.globl linux_trap_nmi_sun4c
linux_trap_nmi_sun4c:
SAVE_ALL
/* Ugh, we need to clear the IRQ line. This is now
* a very sun4c specific trap handler...
*/
sethi %hi(interrupt_enable), %l5
ld [%l5 + %lo(interrupt_enable)], %l5
ldub [%l5], %l6
andn %l6, INTS_ENAB, %l6
stb %l6, [%l5]
/* Now it is safe to re-enable traps without recursion. */
or %l0, PSR_PIL, %l0
wr %l0, PSR_ET, %psr
WRITE_PAUSE
/* Now call the c-code with the pt_regs frame ptr and the
* memory error registers as arguments. The ordering chosen
* here is due to unlatching semantics.
*/
sethi %hi(AC_SYNC_ERR), %o0
add %o0, 0x4, %o0
lda [%o0] ASI_CONTROL, %o2 ! sync vaddr
sub %o0, 0x4, %o0
lda [%o0] ASI_CONTROL, %o1 ! sync error
add %o0, 0xc, %o0
lda [%o0] ASI_CONTROL, %o4 ! async vaddr
sub %o0, 0x4, %o0
lda [%o0] ASI_CONTROL, %o3 ! async error
call sparc_lvl15_nmi
add %sp, STACKFRAME_SZ, %o0
RESTORE_ALL
.align 4
.globl invalid_segment_patch1_ff
.globl invalid_segment_patch2_ff
invalid_segment_patch1_ff: cmp %l4, 0xff
invalid_segment_patch2_ff: mov 0xff, %l3
.align 4
.globl invalid_segment_patch1_1ff
.globl invalid_segment_patch2_1ff
invalid_segment_patch1_1ff: cmp %l4, 0x1ff
invalid_segment_patch2_1ff: mov 0x1ff, %l3
.align 4
.globl num_context_patch1_16, num_context_patch2_16
num_context_patch1_16: mov 0x10, %l7
num_context_patch2_16: mov 0x10, %l7
.align 4
.globl vac_linesize_patch_32
vac_linesize_patch_32: subcc %l7, 32, %l7
.align 4
.globl vac_hwflush_patch1_on, vac_hwflush_patch2_on
/*
* Ugly, but we cant use hardware flushing on the sun4 and we'd require
* two instructions (Anton)
*/
#ifdef CONFIG_SUN4
vac_hwflush_patch1_on: nop
#else
vac_hwflush_patch1_on: addcc %l7, -PAGE_SIZE, %l7
#endif
vac_hwflush_patch2_on: sta %g0, [%l3 + %l7] ASI_HWFLUSHSEG
.globl invalid_segment_patch1, invalid_segment_patch2
.globl num_context_patch1
.globl vac_linesize_patch, vac_hwflush_patch1
.globl vac_hwflush_patch2
.align 4
.globl sun4c_fault
! %l0 = %psr
! %l1 = %pc
! %l2 = %npc
! %l3 = %wim
! %l7 = 1 for textfault
! We want error in %l5, vaddr in %l6
sun4c_fault:
#ifdef CONFIG_SUN4
sethi %hi(sun4c_memerr_reg), %l4
ld [%l4+%lo(sun4c_memerr_reg)], %l4 ! memerr ctrl reg addr
ld [%l4], %l6 ! memerr ctrl reg
ld [%l4 + 4], %l5 ! memerr vaddr reg
andcc %l6, 0x80, %g0 ! check for error type
st %g0, [%l4 + 4] ! clear the error
be 0f ! normal error
sethi %hi(AC_BUS_ERROR), %l4 ! bus err reg addr
call prom_halt ! something weird happened
! what exactly did happen?
! what should we do here?
0: or %l4, %lo(AC_BUS_ERROR), %l4 ! bus err reg addr
lduba [%l4] ASI_CONTROL, %l6 ! bus err reg
cmp %l7, 1 ! text fault?
be 1f ! yes
nop
ld [%l1], %l4 ! load instruction that caused fault
srl %l4, 21, %l4
andcc %l4, 1, %g0 ! store instruction?
be 1f ! no
sethi %hi(SUN4C_SYNC_BADWRITE), %l4 ! yep
! %lo(SUN4C_SYNC_BADWRITE) = 0
or %l4, %l6, %l6 ! set write bit to emulate sun4c
1:
#else
sethi %hi(AC_SYNC_ERR), %l4
add %l4, 0x4, %l6 ! AC_SYNC_VA in %l6
lda [%l6] ASI_CONTROL, %l5 ! Address
lda [%l4] ASI_CONTROL, %l6 ! Error, retained for a bit
#endif
andn %l5, 0xfff, %l5 ! Encode all info into l7
srl %l6, 14, %l4
and %l4, 2, %l4
or %l5, %l4, %l4
or %l4, %l7, %l7 ! l7 = [addr,write,txtfault]
andcc %l0, PSR_PS, %g0
be sun4c_fault_fromuser
andcc %l7, 1, %g0 ! Text fault?
be 1f
sethi %hi(KERNBASE), %l4
mov %l1, %l5 ! PC
1:
cmp %l5, %l4
blu sun4c_fault_fromuser
sethi %hi(~((1 << SUN4C_REAL_PGDIR_SHIFT) - 1)), %l4
/* If the kernel references a bum kernel pointer, or a pte which
* points to a non existant page in ram, we will run this code
* _forever_ and lock up the machine!!!!! So we must check for
* this condition, the AC_SYNC_ERR bits are what we must examine.
* Also a parity error would make this happen as well. So we just
* check that we are in fact servicing a tlb miss and not some
* other type of fault for the kernel.
*/
andcc %l6, 0x80, %g0
be sun4c_fault_fromuser
and %l5, %l4, %l5
/* Test for NULL pte_t * in vmalloc area. */
sethi %hi(VMALLOC_START), %l4
cmp %l5, %l4
blu,a invalid_segment_patch1
lduXa [%l5] ASI_SEGMAP, %l4
sethi %hi(swapper_pg_dir), %l4
srl %l5, SUN4C_PGDIR_SHIFT, %l6
or %l4, %lo(swapper_pg_dir), %l4
sll %l6, 2, %l6
ld [%l4 + %l6], %l4
#ifdef CONFIG_SUN4
sethi %hi(PAGE_MASK), %l6
andcc %l4, %l6, %g0
#else
andcc %l4, PAGE_MASK, %g0
#endif
be sun4c_fault_fromuser
lduXa [%l5] ASI_SEGMAP, %l4
invalid_segment_patch1:
cmp %l4, 0x7f
bne 1f
sethi %hi(sun4c_kfree_ring), %l4
or %l4, %lo(sun4c_kfree_ring), %l4
ld [%l4 + 0x18], %l3
deccc %l3 ! do we have a free entry?
bcs,a 2f ! no, unmap one.
sethi %hi(sun4c_kernel_ring), %l4
st %l3, [%l4 + 0x18] ! sun4c_kfree_ring.num_entries--
ld [%l4 + 0x00], %l6 ! entry = sun4c_kfree_ring.ringhd.next
st %l5, [%l6 + 0x08] ! entry->vaddr = address
ld [%l6 + 0x00], %l3 ! next = entry->next
ld [%l6 + 0x04], %l7 ! entry->prev
st %l7, [%l3 + 0x04] ! next->prev = entry->prev
st %l3, [%l7 + 0x00] ! entry->prev->next = next
sethi %hi(sun4c_kernel_ring), %l4
or %l4, %lo(sun4c_kernel_ring), %l4
! head = &sun4c_kernel_ring.ringhd
ld [%l4 + 0x00], %l7 ! head->next
st %l4, [%l6 + 0x04] ! entry->prev = head
st %l7, [%l6 + 0x00] ! entry->next = head->next
st %l6, [%l7 + 0x04] ! head->next->prev = entry
st %l6, [%l4 + 0x00] ! head->next = entry
ld [%l4 + 0x18], %l3
inc %l3 ! sun4c_kernel_ring.num_entries++
st %l3, [%l4 + 0x18]
b 4f
ld [%l6 + 0x08], %l5
2:
or %l4, %lo(sun4c_kernel_ring), %l4
! head = &sun4c_kernel_ring.ringhd
ld [%l4 + 0x04], %l6 ! entry = head->prev
ld [%l6 + 0x08], %l3 ! tmp = entry->vaddr
! Flush segment from the cache.
#ifdef CONFIG_SUN4
sethi %hi((128 * 1024)), %l7
#else
sethi %hi((64 * 1024)), %l7
#endif
9:
vac_hwflush_patch1:
vac_linesize_patch:
subcc %l7, 16, %l7
bne 9b
vac_hwflush_patch2:
sta %g0, [%l3 + %l7] ASI_FLUSHSEG
st %l5, [%l6 + 0x08] ! entry->vaddr = address
ld [%l6 + 0x00], %l5 ! next = entry->next
ld [%l6 + 0x04], %l7 ! entry->prev
st %l7, [%l5 + 0x04] ! next->prev = entry->prev
st %l5, [%l7 + 0x00] ! entry->prev->next = next
st %l4, [%l6 + 0x04] ! entry->prev = head
ld [%l4 + 0x00], %l7 ! head->next
st %l7, [%l6 + 0x00] ! entry->next = head->next
st %l6, [%l7 + 0x04] ! head->next->prev = entry
st %l6, [%l4 + 0x00] ! head->next = entry
mov %l3, %l5 ! address = tmp
4:
num_context_patch1:
mov 0x08, %l7
ld [%l6 + 0x08], %l4
ldub [%l6 + 0x0c], %l3
or %l4, %l3, %l4 ! encode new vaddr/pseg into l4
sethi %hi(AC_CONTEXT), %l3
lduba [%l3] ASI_CONTROL, %l6
/* Invalidate old mapping, instantiate new mapping,
* for each context. Registers l6/l7 are live across
* this loop.
*/
3: deccc %l7
sethi %hi(AC_CONTEXT), %l3
stba %l7, [%l3] ASI_CONTROL
invalid_segment_patch2:
mov 0x7f, %l3
stXa %l3, [%l5] ASI_SEGMAP
andn %l4, 0x1ff, %l3
bne 3b
stXa %l4, [%l3] ASI_SEGMAP
sethi %hi(AC_CONTEXT), %l3
stba %l6, [%l3] ASI_CONTROL
andn %l4, 0x1ff, %l5
1:
sethi %hi(VMALLOC_START), %l4
cmp %l5, %l4
bgeu 1f
mov 1 << (SUN4C_REAL_PGDIR_SHIFT - PAGE_SHIFT), %l7
sethi %hi(KERNBASE), %l6
sub %l5, %l6, %l4
srl %l4, PAGE_SHIFT, %l4
sethi %hi((SUN4C_PAGE_KERNEL & 0xf4000000)), %l3
or %l3, %l4, %l3
sethi %hi(PAGE_SIZE), %l4
2:
sta %l3, [%l5] ASI_PTE
deccc %l7
inc %l3
bne 2b
add %l5, %l4, %l5
b 7f
sethi %hi(sun4c_kernel_faults), %l4
1:
srl %l5, SUN4C_PGDIR_SHIFT, %l3
sethi %hi(swapper_pg_dir), %l4
or %l4, %lo(swapper_pg_dir), %l4
sll %l3, 2, %l3
ld [%l4 + %l3], %l4
#ifndef CONFIG_SUN4
and %l4, PAGE_MASK, %l4
#else
sethi %hi(PAGE_MASK), %l6
and %l4, %l6, %l4
#endif
srl %l5, (PAGE_SHIFT - 2), %l6
and %l6, ((SUN4C_PTRS_PER_PTE - 1) << 2), %l6
add %l6, %l4, %l6
sethi %hi(PAGE_SIZE), %l4
2:
ld [%l6], %l3
deccc %l7
sta %l3, [%l5] ASI_PTE
add %l6, 0x4, %l6
bne 2b
add %l5, %l4, %l5
sethi %hi(sun4c_kernel_faults), %l4
7:
ld [%l4 + %lo(sun4c_kernel_faults)], %l3
inc %l3
st %l3, [%l4 + %lo(sun4c_kernel_faults)]
/* Restore condition codes */
wr %l0, 0x0, %psr
WRITE_PAUSE
jmp %l1
rett %l2
sun4c_fault_fromuser:
SAVE_ALL
nop
mov %l7, %o1 ! Decode the info from %l7
mov %l7, %o2
and %o1, 1, %o1 ! arg2 = text_faultp
mov %l7, %o3
and %o2, 2, %o2 ! arg3 = writep
andn %o3, 0xfff, %o3 ! arg4 = faulting address
wr %l0, PSR_ET, %psr
WRITE_PAUSE
call do_sun4c_fault
add %sp, STACKFRAME_SZ, %o0 ! arg1 = pt_regs ptr
RESTORE_ALL
.align 4
.globl srmmu_fault
srmmu_fault:
mov 0x400, %l5
mov 0x300, %l4
lda [%l5] ASI_M_MMUREGS, %l6 ! read sfar first
lda [%l4] ASI_M_MMUREGS, %l5 ! read sfsr last
andn %l6, 0xfff, %l6
srl %l5, 6, %l5 ! and encode all info into l7
and %l5, 2, %l5
or %l5, %l6, %l6
or %l6, %l7, %l7 ! l7 = [addr,write,txtfault]
SAVE_ALL
mov %l7, %o1
mov %l7, %o2
and %o1, 1, %o1 ! arg2 = text_faultp
mov %l7, %o3
and %o2, 2, %o2 ! arg3 = writep
andn %o3, 0xfff, %o3 ! arg4 = faulting address
wr %l0, PSR_ET, %psr
WRITE_PAUSE
call do_sparc_fault
add %sp, STACKFRAME_SZ, %o0 ! arg1 = pt_regs ptr
RESTORE_ALL
#ifdef CONFIG_SUNOS_EMUL
/* SunOS uses syscall zero as the 'indirect syscall' it looks
* like indir_syscall(scall_num, arg0, arg1, arg2...); etc.
* This is complete brain damage.
*/
.globl sunos_indir
sunos_indir:
mov %o7, %l4
cmp %o0, NR_SYSCALLS
blu,a 1f
sll %o0, 0x2, %o0
sethi %hi(sunos_nosys), %l6
b 2f
or %l6, %lo(sunos_nosys), %l6
1:
set sunos_sys_table, %l7
ld [%l7 + %o0], %l6
2:
mov %o1, %o0
mov %o2, %o1
mov %o3, %o2
mov %o4, %o3
mov %o5, %o4
call %l6
mov %l4, %o7
#endif
.align 4
.globl sys_nis_syscall
sys_nis_syscall:
mov %o7, %l5
add %sp, STACKFRAME_SZ, %o0 ! pt_regs *regs arg
call c_sys_nis_syscall
mov %l5, %o7
.align 4
.globl sys_execve
sys_execve:
mov %o7, %l5
add %sp, STACKFRAME_SZ, %o0 ! pt_regs *regs arg
call sparc_execve
mov %l5, %o7
.align 4
.globl sys_pipe
sys_pipe:
mov %o7, %l5
add %sp, STACKFRAME_SZ, %o0 ! pt_regs *regs arg
call sparc_pipe
mov %l5, %o7
.align 4
.globl sys_sigaltstack
sys_sigaltstack:
mov %o7, %l5
mov %fp, %o2
call do_sigaltstack
mov %l5, %o7
.align 4
.globl sys_sigstack
sys_sigstack:
mov %o7, %l5
mov %fp, %o2
call do_sys_sigstack
mov %l5, %o7
.align 4
.globl sys_sigreturn
sys_sigreturn:
call do_sigreturn
add %sp, STACKFRAME_SZ, %o0
ld [%curptr + TI_FLAGS], %l5
andcc %l5, _TIF_SYSCALL_TRACE, %g0
be 1f
nop
call syscall_trace
nop
1:
/* We don't want to muck with user registers like a
* normal syscall, just return.
*/
RESTORE_ALL
.align 4
.globl sys_rt_sigreturn
sys_rt_sigreturn:
call do_rt_sigreturn
add %sp, STACKFRAME_SZ, %o0
ld [%curptr + TI_FLAGS], %l5
andcc %l5, _TIF_SYSCALL_TRACE, %g0
be 1f
nop
call syscall_trace
nop
1:
/* We are returning to a signal handler. */
RESTORE_ALL
/* Now that we have a real sys_clone, sys_fork() is
* implemented in terms of it. Our _real_ implementation
* of SunOS vfork() will use sys_vfork().
*
* XXX These three should be consolidated into mostly shared
* XXX code just like on sparc64... -DaveM
*/
.align 4
.globl sys_fork, flush_patch_two
sys_fork:
mov %o7, %l5
flush_patch_two:
FLUSH_ALL_KERNEL_WINDOWS;
ld [%curptr + TI_TASK], %o4
rd %psr, %g4
WRITE_PAUSE
mov SIGCHLD, %o0 ! arg0: clone flags
rd %wim, %g5
WRITE_PAUSE
mov %fp, %o1 ! arg1: usp
std %g4, [%o4 + AOFF_task_thread + AOFF_thread_fork_kpsr]
add %sp, STACKFRAME_SZ, %o2 ! arg2: pt_regs ptr
mov 0, %o3
call sparc_do_fork
mov %l5, %o7
/* Whee, kernel threads! */
.globl sys_clone, flush_patch_three
sys_clone:
mov %o7, %l5
flush_patch_three:
FLUSH_ALL_KERNEL_WINDOWS;
ld [%curptr + TI_TASK], %o4
rd %psr, %g4
WRITE_PAUSE
/* arg0,1: flags,usp -- loaded already */
cmp %o1, 0x0 ! Is new_usp NULL?
rd %wim, %g5
WRITE_PAUSE
be,a 1f
mov %fp, %o1 ! yes, use callers usp
andn %o1, 7, %o1 ! no, align to 8 bytes
1:
std %g4, [%o4 + AOFF_task_thread + AOFF_thread_fork_kpsr]
add %sp, STACKFRAME_SZ, %o2 ! arg2: pt_regs ptr
mov 0, %o3
call sparc_do_fork
mov %l5, %o7
/* Whee, real vfork! */
.globl sys_vfork, flush_patch_four
sys_vfork:
flush_patch_four:
FLUSH_ALL_KERNEL_WINDOWS;
ld [%curptr + TI_TASK], %o4
rd %psr, %g4
WRITE_PAUSE
rd %wim, %g5
WRITE_PAUSE
std %g4, [%o4 + AOFF_task_thread + AOFF_thread_fork_kpsr]
sethi %hi(0x4000 | 0x0100 | SIGCHLD), %o0
mov %fp, %o1
or %o0, %lo(0x4000 | 0x0100 | SIGCHLD), %o0
sethi %hi(sparc_do_fork), %l1
mov 0, %o3
jmpl %l1 + %lo(sparc_do_fork), %g0
add %sp, STACKFRAME_SZ, %o2
.align 4
linux_sparc_ni_syscall:
sethi %hi(sys_ni_syscall), %l7
b syscall_is_too_hard
or %l7, %lo(sys_ni_syscall), %l7
linux_fast_syscall:
andn %l7, 3, %l7
mov %i0, %o0
mov %i1, %o1
mov %i2, %o2
jmpl %l7 + %g0, %g0
mov %i3, %o3
linux_syscall_trace:
call syscall_trace
nop
mov %i0, %o0
mov %i1, %o1
mov %i2, %o2
mov %i3, %o3
b 2f
mov %i4, %o4
.globl ret_from_fork
ret_from_fork:
call schedule_tail
mov %g3, %o0
b ret_sys_call
ld [%sp + STACKFRAME_SZ + PT_I0], %o0
/* Linux native and SunOS system calls enter here... */
.align 4
.globl linux_sparc_syscall
linux_sparc_syscall:
/* Direct access to user regs, must faster. */
cmp %g1, NR_SYSCALLS
bgeu linux_sparc_ni_syscall
sll %g1, 2, %l4
ld [%l7 + %l4], %l7
andcc %l7, 1, %g0
bne linux_fast_syscall
/* Just do first insn from SAVE_ALL in the delay slot */
.globl syscall_is_too_hard
syscall_is_too_hard:
SAVE_ALL_HEAD
rd %wim, %l3
wr %l0, PSR_ET, %psr
mov %i0, %o0
mov %i1, %o1
mov %i2, %o2
ld [%curptr + TI_FLAGS], %l5
mov %i3, %o3
andcc %l5, _TIF_SYSCALL_TRACE, %g0
mov %i4, %o4
bne linux_syscall_trace
mov %i0, %l5
2:
call %l7
mov %i5, %o5
st %o0, [%sp + STACKFRAME_SZ + PT_I0]
.globl ret_sys_call
ret_sys_call:
ld [%curptr + TI_FLAGS], %l6
cmp %o0, -ERESTART_RESTARTBLOCK
ld [%sp + STACKFRAME_SZ + PT_PSR], %g3
set PSR_C, %g2
bgeu 1f
andcc %l6, _TIF_SYSCALL_TRACE, %g0
/* System call success, clear Carry condition code. */
andn %g3, %g2, %g3
clr %l6
st %g3, [%sp + STACKFRAME_SZ + PT_PSR]
bne linux_syscall_trace2
ld [%sp + STACKFRAME_SZ + PT_NPC], %l1 /* pc = npc */
add %l1, 0x4, %l2 /* npc = npc+4 */
st %l1, [%sp + STACKFRAME_SZ + PT_PC]
b ret_trap_entry
st %l2, [%sp + STACKFRAME_SZ + PT_NPC]
1:
/* System call failure, set Carry condition code.
* Also, get abs(errno) to return to the process.
*/
sub %g0, %o0, %o0
or %g3, %g2, %g3
st %o0, [%sp + STACKFRAME_SZ + PT_I0]
mov 1, %l6
st %g3, [%sp + STACKFRAME_SZ + PT_PSR]
bne linux_syscall_trace2
ld [%sp + STACKFRAME_SZ + PT_NPC], %l1 /* pc = npc */
add %l1, 0x4, %l2 /* npc = npc+4 */
st %l1, [%sp + STACKFRAME_SZ + PT_PC]
b ret_trap_entry
st %l2, [%sp + STACKFRAME_SZ + PT_NPC]
linux_syscall_trace2:
call syscall_trace
add %l1, 0x4, %l2 /* npc = npc+4 */
st %l1, [%sp + STACKFRAME_SZ + PT_PC]
b ret_trap_entry
st %l2, [%sp + STACKFRAME_SZ + PT_NPC]
/*
* Solaris system calls and indirect system calls enter here.
*
* I have named the solaris indirect syscalls like that because
* it seems like Solaris has some fast path syscalls that can
* be handled as indirect system calls. - mig
*/
linux_syscall_for_solaris:
sethi %hi(sys_call_table), %l7
b linux_sparc_syscall
or %l7, %lo(sys_call_table), %l7
.align 4
.globl solaris_syscall
solaris_syscall:
cmp %g1,59
be linux_syscall_for_solaris
cmp %g1,2
be linux_syscall_for_solaris
cmp %g1,42
be linux_syscall_for_solaris
cmp %g1,119
be,a linux_syscall_for_solaris
mov 2, %g1
1:
SAVE_ALL_HEAD
rd %wim, %l3
wr %l0, PSR_ET, %psr
nop
nop
mov %i0, %l5
call do_solaris_syscall
add %sp, STACKFRAME_SZ, %o0
st %o0, [%sp + STACKFRAME_SZ + PT_I0]
set PSR_C, %g2
cmp %o0, -ERESTART_RESTARTBLOCK
bgeu 1f
ld [%sp + STACKFRAME_SZ + PT_PSR], %g3
/* System call success, clear Carry condition code. */
andn %g3, %g2, %g3
clr %l6
b 2f
st %g3, [%sp + STACKFRAME_SZ + PT_PSR]
1:
/* System call failure, set Carry condition code.
* Also, get abs(errno) to return to the process.
*/
sub %g0, %o0, %o0
mov 1, %l6
st %o0, [%sp + STACKFRAME_SZ + PT_I0]
or %g3, %g2, %g3
st %g3, [%sp + STACKFRAME_SZ + PT_PSR]
/* Advance the pc and npc over the trap instruction.
* If the npc is unaligned (has a 1 in the lower byte), it means
* the kernel does not want us to play magic (ie, skipping over
* traps). Mainly when the Solaris code wants to set some PC and
* nPC (setcontext).
*/
2:
ld [%sp + STACKFRAME_SZ + PT_NPC], %l1 /* pc = npc */
andcc %l1, 1, %g0
bne 1f
add %l1, 0x4, %l2 /* npc = npc+4 */
st %l1, [%sp + STACKFRAME_SZ + PT_PC]
b ret_trap_entry
st %l2, [%sp + STACKFRAME_SZ + PT_NPC]
/* kernel knows what it is doing, fixup npc and continue */
1:
sub %l1, 1, %l1
b ret_trap_entry
st %l1, [%sp + STACKFRAME_SZ + PT_NPC]
#ifndef CONFIG_SUNOS_EMUL
.align 4
.globl sunos_syscall
sunos_syscall:
SAVE_ALL_HEAD
rd %wim, %l3
wr %l0, PSR_ET, %psr
nop
nop
mov %i0, %l5
call do_sunos_syscall
add %sp, STACKFRAME_SZ, %o0
#endif
/* {net, open}bsd system calls enter here... */
.align 4
.globl bsd_syscall
bsd_syscall:
/* Direct access to user regs, must faster. */
cmp %g1, NR_SYSCALLS
blu,a 1f
sll %g1, 2, %l4
set sys_ni_syscall, %l7
b bsd_is_too_hard
nop
1:
ld [%l7 + %l4], %l7
.globl bsd_is_too_hard
bsd_is_too_hard:
rd %wim, %l3
SAVE_ALL
wr %l0, PSR_ET, %psr
WRITE_PAUSE
2:
mov %i0, %o0
mov %i1, %o1
mov %i2, %o2
mov %i0, %l5
mov %i3, %o3
mov %i4, %o4
call %l7
mov %i5, %o5
st %o0, [%sp + STACKFRAME_SZ + PT_I0]
set PSR_C, %g2
cmp %o0, -ERESTART_RESTARTBLOCK
bgeu 1f
ld [%sp + STACKFRAME_SZ + PT_PSR], %g3
/* System call success, clear Carry condition code. */
andn %g3, %g2, %g3
clr %l6
b 2f
st %g3, [%sp + STACKFRAME_SZ + PT_PSR]
1:
/* System call failure, set Carry condition code.
* Also, get abs(errno) to return to the process.
*/
sub %g0, %o0, %o0
#if 0 /* XXX todo XXX */
sethi %hi(bsd_xlatb_rorl), %o3
or %o3, %lo(bsd_xlatb_rorl), %o3
sll %o0, 2, %o0
ld [%o3 + %o0], %o0
#endif
mov 1, %l6
st %o0, [%sp + STACKFRAME_SZ + PT_I0]
or %g3, %g2, %g3
st %g3, [%sp + STACKFRAME_SZ + PT_PSR]
/* Advance the pc and npc over the trap instruction. */
2:
ld [%sp + STACKFRAME_SZ + PT_NPC], %l1 /* pc = npc */
add %l1, 0x4, %l2 /* npc = npc+4 */
st %l1, [%sp + STACKFRAME_SZ + PT_PC]
b ret_trap_entry
st %l2, [%sp + STACKFRAME_SZ + PT_NPC]
/* Saving and restoring the FPU state is best done from lowlevel code.
*
* void fpsave(unsigned long *fpregs, unsigned long *fsr,
* void *fpqueue, unsigned long *fpqdepth)
*/
.globl fpsave
fpsave:
st %fsr, [%o1] ! this can trap on us if fpu is in bogon state
ld [%o1], %g1
set 0x2000, %g4
andcc %g1, %g4, %g0
be 2f
mov 0, %g2
/* We have an fpqueue to save. */
1:
std %fq, [%o2]
fpsave_magic:
st %fsr, [%o1]
ld [%o1], %g3
andcc %g3, %g4, %g0
add %g2, 1, %g2
bne 1b
add %o2, 8, %o2
2:
st %g2, [%o3]
std %f0, [%o0 + 0x00]
std %f2, [%o0 + 0x08]
std %f4, [%o0 + 0x10]
std %f6, [%o0 + 0x18]
std %f8, [%o0 + 0x20]
std %f10, [%o0 + 0x28]
std %f12, [%o0 + 0x30]
std %f14, [%o0 + 0x38]
std %f16, [%o0 + 0x40]
std %f18, [%o0 + 0x48]
std %f20, [%o0 + 0x50]
std %f22, [%o0 + 0x58]
std %f24, [%o0 + 0x60]
std %f26, [%o0 + 0x68]
std %f28, [%o0 + 0x70]
retl
std %f30, [%o0 + 0x78]
/* Thanks for Theo Deraadt and the authors of the Sprite/netbsd/openbsd
* code for pointing out this possible deadlock, while we save state
* above we could trap on the fsr store so our low level fpu trap
* code has to know how to deal with this.
*/
fpsave_catch:
b fpsave_magic + 4
st %fsr, [%o1]
fpsave_catch2:
b fpsave + 4
st %fsr, [%o1]
/* void fpload(unsigned long *fpregs, unsigned long *fsr); */
.globl fpload
fpload:
ldd [%o0 + 0x00], %f0
ldd [%o0 + 0x08], %f2
ldd [%o0 + 0x10], %f4
ldd [%o0 + 0x18], %f6
ldd [%o0 + 0x20], %f8
ldd [%o0 + 0x28], %f10
ldd [%o0 + 0x30], %f12
ldd [%o0 + 0x38], %f14
ldd [%o0 + 0x40], %f16
ldd [%o0 + 0x48], %f18
ldd [%o0 + 0x50], %f20
ldd [%o0 + 0x58], %f22
ldd [%o0 + 0x60], %f24
ldd [%o0 + 0x68], %f26
ldd [%o0 + 0x70], %f28
ldd [%o0 + 0x78], %f30
ld [%o1], %fsr
retl
nop
/* __ndelay and __udelay take two arguments:
* 0 - nsecs or usecs to delay
* 1 - per_cpu udelay_val (loops per jiffy)
*
* Note that ndelay gives HZ times higher resolution but has a 10ms
* limit. udelay can handle up to 1s.
*/
.globl __ndelay
__ndelay:
save %sp, -STACKFRAME_SZ, %sp
mov %i0, %o0
call .umul ! round multiplier up so large ns ok
mov 0x1ae, %o1 ! 2**32 / (1 000 000 000 / HZ)
call .umul
mov %i1, %o1 ! udelay_val
ba delay_continue
mov %o1, %o0 ! >>32 later for better resolution
.globl __udelay
__udelay:
save %sp, -STACKFRAME_SZ, %sp
mov %i0, %o0
sethi %hi(0x10c7), %o1 ! round multiplier up so large us ok
call .umul
or %o1, %lo(0x10c7), %o1 ! 2**32 / 1 000 000
call .umul
mov %i1, %o1 ! udelay_val
sethi %hi(0x028f4b62), %l0 ! Add in rounding constant * 2**32,
or %g0, %lo(0x028f4b62), %l0
addcc %o0, %l0, %o0 ! 2**32 * 0.009 999
bcs,a 3f
add %o1, 0x01, %o1
3:
call .umul
mov HZ, %o0 ! >>32 earlier for wider range
delay_continue:
cmp %o0, 0x0
1:
bne 1b
subcc %o0, 1, %o0
ret
restore
/* Handle a software breakpoint */
/* We have to inform parent that child has stopped */
.align 4
.globl breakpoint_trap
breakpoint_trap:
rd %wim,%l3
SAVE_ALL
wr %l0, PSR_ET, %psr
WRITE_PAUSE
st %i0, [%sp + STACKFRAME_SZ + PT_G0] ! for restarting syscalls
call sparc_breakpoint
add %sp, STACKFRAME_SZ, %o0
RESTORE_ALL
.align 4
.globl __handle_exception, flush_patch_exception
__handle_exception:
flush_patch_exception:
FLUSH_ALL_KERNEL_WINDOWS;
ldd [%o0], %o6
jmpl %o7 + 0xc, %g0 ! see asm-sparc/processor.h
mov 1, %g1 ! signal EFAULT condition
.align 4
.globl kill_user_windows, kuw_patch1_7win
.globl kuw_patch1
kuw_patch1_7win: sll %o3, 6, %o3
/* No matter how much overhead this routine has in the worst
* case scenerio, it is several times better than taking the
* traps with the old method of just doing flush_user_windows().
*/
kill_user_windows:
ld [%g6 + TI_UWINMASK], %o0 ! get current umask
orcc %g0, %o0, %g0 ! if no bits set, we are done
be 3f ! nothing to do
rd %psr, %o5 ! must clear interrupts
or %o5, PSR_PIL, %o4 ! or else that could change
wr %o4, 0x0, %psr ! the uwinmask state
WRITE_PAUSE ! burn them cycles
1:
ld [%g6 + TI_UWINMASK], %o0 ! get consistent state
orcc %g0, %o0, %g0 ! did an interrupt come in?
be 4f ! yep, we are done
rd %wim, %o3 ! get current wim
srl %o3, 1, %o4 ! simulate a save
kuw_patch1:
sll %o3, 7, %o3 ! compute next wim
or %o4, %o3, %o3 ! result
andncc %o0, %o3, %o0 ! clean this bit in umask
bne kuw_patch1 ! not done yet
srl %o3, 1, %o4 ! begin another save simulation
wr %o3, 0x0, %wim ! set the new wim
st %g0, [%g6 + TI_UWINMASK] ! clear uwinmask
4:
wr %o5, 0x0, %psr ! re-enable interrupts
WRITE_PAUSE ! burn baby burn
3:
retl ! return
st %g0, [%g6 + TI_W_SAVED] ! no windows saved
.align 4
.globl restore_current
restore_current:
LOAD_CURRENT(g6, o0)
retl
nop
#ifdef CONFIG_PCI
#include <asm/pcic.h>
.align 4
.globl linux_trap_ipi15_pcic
linux_trap_ipi15_pcic:
rd %wim, %l3
SAVE_ALL
/*
* First deactivate NMI
* or we cannot drop ET, cannot get window spill traps.
* The busy loop is necessary because the PIO error
* sometimes does not go away quickly and we trap again.
*/
sethi %hi(pcic_regs), %o1
ld [%o1 + %lo(pcic_regs)], %o2
! Get pending status for printouts later.
ld [%o2 + PCI_SYS_INT_PENDING], %o0
mov PCI_SYS_INT_PENDING_CLEAR_ALL, %o1
stb %o1, [%o2 + PCI_SYS_INT_PENDING_CLEAR]
1:
ld [%o2 + PCI_SYS_INT_PENDING], %o1
andcc %o1, ((PCI_SYS_INT_PENDING_PIO|PCI_SYS_INT_PENDING_PCI)>>24), %g0
bne 1b
nop
or %l0, PSR_PIL, %l4
wr %l4, 0x0, %psr
WRITE_PAUSE
wr %l4, PSR_ET, %psr
WRITE_PAUSE
call pcic_nmi
add %sp, STACKFRAME_SZ, %o1 ! struct pt_regs *regs
RESTORE_ALL
.globl pcic_nmi_trap_patch
pcic_nmi_trap_patch:
sethi %hi(linux_trap_ipi15_pcic), %l3
jmpl %l3 + %lo(linux_trap_ipi15_pcic), %g0
rd %psr, %l0
.word 0
#endif /* CONFIG_PCI */
/* End of entry.S */