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linux/arch/sparc/kernel/entry.S

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/* 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/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>
#include <asm/pgtable.h>
#include <asm/pgtsun4c.h>
#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;
.text
#ifdef CONFIG_KGDB
.align 4
.globl arch_kgdb_breakpoint
.type arch_kgdb_breakpoint,#function
arch_kgdb_breakpoint:
ta 0x7d
retl
nop
.size arch_kgdb_breakpoint,.-arch_kgdb_breakpoint
#endif
#if defined(CONFIG_BLK_DEV_FD) || defined(CONFIG_BLK_DEV_FD_MODULE)
.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)
sethi %hi(sun4m_irq_percpu), %l5
sll %o3, 2, %o3
or %l5, %lo(sun4m_irq_percpu), %o5
sethi %hi(0x40000000), %o2
ld [%o5 + %o3], %o1
ld [%o1 + 0x00], %o3 ! sun4m_irq_percpu[cpu]->pending
andcc %o3, %o2, %g0
be,a smp4m_ticker
cmp %l7, 14
st %o2, [%o1 + 0x04] ! sun4m_irq_percpu[cpu]->clear=0x40000000
WRITE_PAUSE
ld [%o1 + 0x00], %g0 ! sun4m_irq_percpu[cpu]->pending
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)
sethi %hi(sun4m_irq_percpu), %l5
or %l5, %lo(sun4m_irq_percpu), %o5
sll %o0, 2, %o0
ld [%o5 + %o0], %o5
ld [%o5 + 0x00], %o3 ! sun4m_irq_percpu[cpu]->pending
andcc %o3, %o2, %g0
be 1f ! Must be an NMI async memory error
st %o2, [%o5 + 0x04] ! sun4m_irq_percpu[cpu]->clear=0x80000000
WRITE_PAUSE
ld [%o5 + 0x00], %g0 ! sun4m_irq_percpu[cpu]->pending
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(sun4m_irq_global), %o5
ld [%o5 + %lo(sun4m_irq_global)], %l5
st %l4, [%l5 + 0x0c] ! sun4m_irq_global->mask_set=0x80000000
WRITE_PAUSE
ld [%l5 + 0x00], %g0 ! sun4m_irq_global->pending
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 + 0x08] ! sun4m_irq_global->mask_clear=0x80000000
WRITE_PAUSE
ld [%l5 + 0x00], %g0 ! sun4m_irq_global->pending
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)
*/
vac_hwflush_patch1_on: addcc %l7, -PAGE_SIZE, %l7
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:
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
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
andcc %l4, PAGE_MASK, %g0
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.
sethi %hi((64 * 1024)), %l7
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
and %l4, PAGE_MASK, %l4
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
.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
.globl sunos_execv
sunos_execv:
st %g0, [%sp + STACKFRAME_SZ + PT_I2]
call sparc_execve
add %sp, STACKFRAME_SZ, %o0
b ret_sys_call
ld [%sp + STACKFRAME_SZ + PT_I0], %o0
.align 4
.globl sys_sparc_pipe
sys_sparc_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
add %sp, STACKFRAME_SZ, %o0
call syscall_trace
mov 1, %o1
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:
add %sp, STACKFRAME_SZ, %o0
call syscall_trace
mov 0, %o1
cmp %o0, 0
bne 3f
mov -ENOSYS, %o0
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 system calls enter here... */
.align 4
.globl linux_sparc_syscall
linux_sparc_syscall:
sparc: Fix debugger syscall restart interactions. So, forever, we've had this ptrace_signal_deliver implementation which tries to handle all of the nasties that can occur when the debugger looks at a process about to take a signal. It's meant to address all of these issues inside of the kernel so that the debugger need not be mindful of such things. Problem is, this doesn't work. The idea was that we should do the syscall restart business first, so that the debugger captures that state. Otherwise, if the debugger for example saves the child's state, makes the child execute something else, then restores the saved state, we won't handle the syscall restart properly because we lose the "we're in a syscall" state. The code here worked for most cases, but if the debugger actually passes the signal through to the child unaltered, it's possible that we would do a syscall restart when we shouldn't have. In particular this breaks the case of debugging a process under a gdb which is being debugged by yet another gdb. gdb uses sigsuspend to wait for SIGCHLD of the inferior, but if gdb itself is being debugged by a top-level gdb we get a ptrace_stop(). The top-level gdb does a PTRACE_CONT with SIGCHLD to let the inferior gdb see the signal. But ptrace_signal_deliver() assumed the debugger would cancel out the signal and therefore did a syscall restart, because the return error was ERESTARTNOHAND. Fix this by simply making ptrace_signal_deliver() a nop, and providing a way for the debugger to control system call restarting properly: 1) Report a "in syscall" software bit in regs->{tstate,psr}. It is set early on in trap entry to a system call and is fully visible to the debugger via ptrace() and regsets. 2) Test this bit right before doing a syscall restart. We have to do a final recheck right after get_signal_to_deliver() in case the debugger cleared the bit during ptrace_stop(). 3) Clear the bit in trap return so we don't accidently try to set that bit in the real register. As a result we also get a ptrace_{is,clear}_syscall() for sparc32 just like sparc64 has. M68K has this same exact bug, and is now the only other user of the ptrace_signal_deliver hook. It needs to be fixed in the same exact way as sparc. Signed-off-by: David S. Miller <davem@davemloft.net>
2008-05-11 02:07:19 -07:00
sethi %hi(PSR_SYSCALL), %l4
or %l0, %l4, %l0
/* 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 */
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
3:
st %o0, [%sp + STACKFRAME_SZ + PT_I0]
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:
add %sp, STACKFRAME_SZ, %o0
mov 1, %o1
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]
/* 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
#ifdef CONFIG_KGDB
.align 4
.globl kgdb_trap_low
.type kgdb_trap_low,#function
kgdb_trap_low:
rd %wim,%l3
SAVE_ALL
wr %l0, PSR_ET, %psr
WRITE_PAUSE
call kgdb_trap
add %sp, STACKFRAME_SZ, %o0
RESTORE_ALL
.size kgdb_trap_low,.-kgdb_trap_low
#endif
.align 4
sparc/kernel/: possible cleanups This patch contains the following possible cleanups: - make the following needlessly global code static: - apc.c: apc_swift_idle() - ebus.c: ebus_blacklist_irq() - ebus.c: fill_ebus_child() - ebus.c: fill_ebus_device() - entry.S: syscall_is_too_hard - etra: tsetup_sun4c_stackchk - head.S: cputyp - head.S: prom_vector_p - idprom.c: Sun_Machines[] - ioport.c: _sparc_find_resource() - ioport.c: create_proc_read_entry() - irq.c: struct sparc_irq[] - rtrap.S: sun4c_rett_stackchk - setup.c: prom_sync_me() - setup.c: boot_flags - sun4c_irq.c: sun4c_sbint_to_irq() - sun4d_irq.c: sbus_tid[] - sun4d_irq.c: struct sbus_actions - sun4d_irq.c: sun4d_sbint_to_irq() - sun4m_irq.c: sun4m_sbint_to_irq() - sun4m_irq.c: sun4m_get_irqmask() - sun4m_irq.c: sun4m_timers - sun4m_smp.c: smp4m_cross_call() - sun4m_smp.c: smp4m_blackbox_id() - sun4m_smp.c: smp4m_blackbox_current() - time.c: sp_clock_typ - time.c: sbus_time_init() - traps.c: instruction_dump() - wof.S: spwin_sun4c_stackchk - wuf.S: sun4c_fwin_stackchk - #if 0 the following unused code: - process.c: sparc_backtrace_lock - process.c: __show_backtrace() - process.c: show_backtrace() - process.c: smp_show_backtrace_all_cpus() - remove the following unused code: - entry.S: __handle_exception - smp.c: smp_num_cpus - smp.c: smp_activated - smp.c: __cpu_number_map[] - smp.c: __cpu_logical_map[] - smp.c: bitops_spinlock - traps.c: trap_curbuf - traps.c: trapbuf[] - traps.c: linux_smp_still_initting - traps.c: thiscpus_tbr - traps.c: thiscpus_mid Signed-off-by: Adrian Bunk <bunk@kernel.org> Signed-off-by: David S. Miller <davem@davemloft.net>
2008-06-05 11:40:58 -07:00
.globl flush_patch_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 */
.globl flushw_all
flushw_all:
save %sp, -0x40, %sp
save %sp, -0x40, %sp
save %sp, -0x40, %sp
save %sp, -0x40, %sp
save %sp, -0x40, %sp
save %sp, -0x40, %sp
save %sp, -0x40, %sp
restore
restore
restore
restore
restore
restore
ret
restore
/* End of entry.S */