android_kernel_xiaomi_sm8350/arch/sparc64/kernel/entry.S

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/* $Id: entry.S,v 1.144 2002/02/09 19:49:30 davem Exp $
* arch/sparc64/kernel/entry.S: Sparc64 trap low-level entry points.
*
* Copyright (C) 1995,1997 David S. Miller (davem@caip.rutgers.edu)
* Copyright (C) 1996 Eddie C. Dost (ecd@skynet.be)
* Copyright (C) 1996 Miguel de Icaza (miguel@nuclecu.unam.mx)
* Copyright (C) 1996,98,99 Jakub Jelinek (jj@sunsite.mff.cuni.cz)
*/
#include <linux/errno.h>
#include <asm/head.h>
#include <asm/asi.h>
#include <asm/smp.h>
#include <asm/ptrace.h>
#include <asm/page.h>
#include <asm/signal.h>
#include <asm/pgtable.h>
#include <asm/processor.h>
#include <asm/visasm.h>
#include <asm/estate.h>
#include <asm/auxio.h>
#include <asm/sfafsr.h>
#include <asm/pil.h>
#define curptr g6
#define NR_SYSCALLS 300 /* Each OS is different... */
.text
.align 32
/* This is trivial with the new code... */
.globl do_fpdis
do_fpdis:
sethi %hi(TSTATE_PEF), %g4
rdpr %tstate, %g5
andcc %g5, %g4, %g0
be,pt %xcc, 1f
nop
rd %fprs, %g5
andcc %g5, FPRS_FEF, %g0
be,pt %xcc, 1f
nop
/* Legal state when DCR_IFPOE is set in Cheetah %dcr. */
sethi %hi(109f), %g7
ba,pt %xcc, etrap
109: or %g7, %lo(109b), %g7
add %g0, %g0, %g0
ba,a,pt %xcc, rtrap_clr_l6
1: TRAP_LOAD_THREAD_REG(%g6, %g1)
[SPARC64]: Elminate all usage of hard-coded trap globals. UltraSPARC has special sets of global registers which are switched to for certain trap types. There is one set for MMU related traps, one set of Interrupt Vector processing, and another set (called the Alternate globals) for all other trap types. For what seems like forever we've hard coded the values in some of these trap registers. Some examples include: 1) Interrupt Vector global %g6 holds current processors interrupt work struct where received interrupts are managed for IRQ handler dispatch. 2) MMU global %g7 holds the base of the page tables of the currently active address space. 3) Alternate global %g6 held the current_thread_info() value. Such hardcoding has resulted in some serious issues in many areas. There are some code sequences where having another register available would help clean up the implementation. Taking traps such as cross-calls from the OBP firmware requires some trick code sequences wherein we have to save away and restore all of the special sets of global registers when we enter/exit OBP. We were also using the IMMU TSB register on SMP to hold the per-cpu area base address, which doesn't work any longer now that we actually use the TSB facility of the cpu. The implementation is pretty straight forward. One tricky bit is getting the current processor ID as that is different on different cpu variants. We use a stub with a fancy calling convention which we patch at boot time. The calling convention is that the stub is branched to and the (PC - 4) to return to is in register %g1. The cpu number is left in %g6. This stub can be invoked by using the __GET_CPUID macro. We use an array of per-cpu trap state to store the current thread and physical address of the current address space's page tables. The TRAP_LOAD_THREAD_REG loads %g6 with the current thread from this table, it uses __GET_CPUID and also clobbers %g1. TRAP_LOAD_IRQ_WORK is used by the interrupt vector processing to load the current processor's IRQ software state into %g6. It also uses __GET_CPUID and clobbers %g1. Finally, TRAP_LOAD_PGD_PHYS loads the physical address base of the current address space's page tables into %g7, it clobbers %g1 and uses __GET_CPUID. Many refinements are possible, as well as some tuning, with this stuff in place. Signed-off-by: David S. Miller <davem@davemloft.net>
2006-02-27 02:24:22 -05:00
ldub [%g6 + TI_FPSAVED], %g5
wr %g0, FPRS_FEF, %fprs
andcc %g5, FPRS_FEF, %g0
be,a,pt %icc, 1f
clr %g7
ldx [%g6 + TI_GSR], %g7
1: andcc %g5, FPRS_DL, %g0
bne,pn %icc, 2f
fzero %f0
andcc %g5, FPRS_DU, %g0
bne,pn %icc, 1f
fzero %f2
faddd %f0, %f2, %f4
fmuld %f0, %f2, %f6
faddd %f0, %f2, %f8
fmuld %f0, %f2, %f10
faddd %f0, %f2, %f12
fmuld %f0, %f2, %f14
faddd %f0, %f2, %f16
fmuld %f0, %f2, %f18
faddd %f0, %f2, %f20
fmuld %f0, %f2, %f22
faddd %f0, %f2, %f24
fmuld %f0, %f2, %f26
faddd %f0, %f2, %f28
fmuld %f0, %f2, %f30
faddd %f0, %f2, %f32
fmuld %f0, %f2, %f34
faddd %f0, %f2, %f36
fmuld %f0, %f2, %f38
faddd %f0, %f2, %f40
fmuld %f0, %f2, %f42
faddd %f0, %f2, %f44
fmuld %f0, %f2, %f46
faddd %f0, %f2, %f48
fmuld %f0, %f2, %f50
faddd %f0, %f2, %f52
fmuld %f0, %f2, %f54
faddd %f0, %f2, %f56
fmuld %f0, %f2, %f58
b,pt %xcc, fpdis_exit2
faddd %f0, %f2, %f60
1: mov SECONDARY_CONTEXT, %g3
add %g6, TI_FPREGS + 0x80, %g1
faddd %f0, %f2, %f4
fmuld %f0, %f2, %f6
661: ldxa [%g3] ASI_DMMU, %g5
.section .sun4v_1insn_patch, "ax"
.word 661b
ldxa [%g3] ASI_MMU, %g5
.previous
sethi %hi(sparc64_kern_sec_context), %g2
ldx [%g2 + %lo(sparc64_kern_sec_context)], %g2
661: stxa %g2, [%g3] ASI_DMMU
.section .sun4v_1insn_patch, "ax"
.word 661b
stxa %g2, [%g3] ASI_MMU
.previous
membar #Sync
add %g6, TI_FPREGS + 0xc0, %g2
faddd %f0, %f2, %f8
fmuld %f0, %f2, %f10
membar #Sync
ldda [%g1] ASI_BLK_S, %f32
ldda [%g2] ASI_BLK_S, %f48
membar #Sync
faddd %f0, %f2, %f12
fmuld %f0, %f2, %f14
faddd %f0, %f2, %f16
fmuld %f0, %f2, %f18
faddd %f0, %f2, %f20
fmuld %f0, %f2, %f22
faddd %f0, %f2, %f24
fmuld %f0, %f2, %f26
faddd %f0, %f2, %f28
fmuld %f0, %f2, %f30
b,pt %xcc, fpdis_exit
nop
2: andcc %g5, FPRS_DU, %g0
bne,pt %icc, 3f
fzero %f32
mov SECONDARY_CONTEXT, %g3
fzero %f34
661: ldxa [%g3] ASI_DMMU, %g5
.section .sun4v_1insn_patch, "ax"
.word 661b
ldxa [%g3] ASI_MMU, %g5
.previous
add %g6, TI_FPREGS, %g1
sethi %hi(sparc64_kern_sec_context), %g2
ldx [%g2 + %lo(sparc64_kern_sec_context)], %g2
661: stxa %g2, [%g3] ASI_DMMU
.section .sun4v_1insn_patch, "ax"
.word 661b
stxa %g2, [%g3] ASI_MMU
.previous
membar #Sync
add %g6, TI_FPREGS + 0x40, %g2
faddd %f32, %f34, %f36
fmuld %f32, %f34, %f38
membar #Sync
ldda [%g1] ASI_BLK_S, %f0
ldda [%g2] ASI_BLK_S, %f16
membar #Sync
faddd %f32, %f34, %f40
fmuld %f32, %f34, %f42
faddd %f32, %f34, %f44
fmuld %f32, %f34, %f46
faddd %f32, %f34, %f48
fmuld %f32, %f34, %f50
faddd %f32, %f34, %f52
fmuld %f32, %f34, %f54
faddd %f32, %f34, %f56
fmuld %f32, %f34, %f58
faddd %f32, %f34, %f60
fmuld %f32, %f34, %f62
ba,pt %xcc, fpdis_exit
nop
3: mov SECONDARY_CONTEXT, %g3
add %g6, TI_FPREGS, %g1
661: ldxa [%g3] ASI_DMMU, %g5
.section .sun4v_1insn_patch, "ax"
.word 661b
ldxa [%g3] ASI_MMU, %g5
.previous
sethi %hi(sparc64_kern_sec_context), %g2
ldx [%g2 + %lo(sparc64_kern_sec_context)], %g2
661: stxa %g2, [%g3] ASI_DMMU
.section .sun4v_1insn_patch, "ax"
.word 661b
stxa %g2, [%g3] ASI_MMU
.previous
membar #Sync
mov 0x40, %g2
membar #Sync
ldda [%g1] ASI_BLK_S, %f0
ldda [%g1 + %g2] ASI_BLK_S, %f16
add %g1, 0x80, %g1
ldda [%g1] ASI_BLK_S, %f32
ldda [%g1 + %g2] ASI_BLK_S, %f48
membar #Sync
fpdis_exit:
661: stxa %g5, [%g3] ASI_DMMU
.section .sun4v_1insn_patch, "ax"
.word 661b
stxa %g5, [%g3] ASI_MMU
.previous
membar #Sync
fpdis_exit2:
wr %g7, 0, %gsr
ldx [%g6 + TI_XFSR], %fsr
rdpr %tstate, %g3
or %g3, %g4, %g3 ! anal...
wrpr %g3, %tstate
wr %g0, FPRS_FEF, %fprs ! clean DU/DL bits
retry
.align 32
fp_other_bounce:
call do_fpother
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
.globl do_fpother_check_fitos
.align 32
do_fpother_check_fitos:
TRAP_LOAD_THREAD_REG(%g6, %g1)
sethi %hi(fp_other_bounce - 4), %g7
or %g7, %lo(fp_other_bounce - 4), %g7
/* NOTE: Need to preserve %g7 until we fully commit
* to the fitos fixup.
*/
stx %fsr, [%g6 + TI_XFSR]
rdpr %tstate, %g3
andcc %g3, TSTATE_PRIV, %g0
bne,pn %xcc, do_fptrap_after_fsr
nop
ldx [%g6 + TI_XFSR], %g3
srlx %g3, 14, %g1
and %g1, 7, %g1
cmp %g1, 2 ! Unfinished FP-OP
bne,pn %xcc, do_fptrap_after_fsr
sethi %hi(1 << 23), %g1 ! Inexact
andcc %g3, %g1, %g0
bne,pn %xcc, do_fptrap_after_fsr
rdpr %tpc, %g1
lduwa [%g1] ASI_AIUP, %g3 ! This cannot ever fail
#define FITOS_MASK 0xc1f83fe0
#define FITOS_COMPARE 0x81a01880
sethi %hi(FITOS_MASK), %g1
or %g1, %lo(FITOS_MASK), %g1
and %g3, %g1, %g1
sethi %hi(FITOS_COMPARE), %g2
or %g2, %lo(FITOS_COMPARE), %g2
cmp %g1, %g2
bne,pn %xcc, do_fptrap_after_fsr
nop
std %f62, [%g6 + TI_FPREGS + (62 * 4)]
sethi %hi(fitos_table_1), %g1
and %g3, 0x1f, %g2
or %g1, %lo(fitos_table_1), %g1
sllx %g2, 2, %g2
jmpl %g1 + %g2, %g0
ba,pt %xcc, fitos_emul_continue
fitos_table_1:
fitod %f0, %f62
fitod %f1, %f62
fitod %f2, %f62
fitod %f3, %f62
fitod %f4, %f62
fitod %f5, %f62
fitod %f6, %f62
fitod %f7, %f62
fitod %f8, %f62
fitod %f9, %f62
fitod %f10, %f62
fitod %f11, %f62
fitod %f12, %f62
fitod %f13, %f62
fitod %f14, %f62
fitod %f15, %f62
fitod %f16, %f62
fitod %f17, %f62
fitod %f18, %f62
fitod %f19, %f62
fitod %f20, %f62
fitod %f21, %f62
fitod %f22, %f62
fitod %f23, %f62
fitod %f24, %f62
fitod %f25, %f62
fitod %f26, %f62
fitod %f27, %f62
fitod %f28, %f62
fitod %f29, %f62
fitod %f30, %f62
fitod %f31, %f62
fitos_emul_continue:
sethi %hi(fitos_table_2), %g1
srl %g3, 25, %g2
or %g1, %lo(fitos_table_2), %g1
and %g2, 0x1f, %g2
sllx %g2, 2, %g2
jmpl %g1 + %g2, %g0
ba,pt %xcc, fitos_emul_fini
fitos_table_2:
fdtos %f62, %f0
fdtos %f62, %f1
fdtos %f62, %f2
fdtos %f62, %f3
fdtos %f62, %f4
fdtos %f62, %f5
fdtos %f62, %f6
fdtos %f62, %f7
fdtos %f62, %f8
fdtos %f62, %f9
fdtos %f62, %f10
fdtos %f62, %f11
fdtos %f62, %f12
fdtos %f62, %f13
fdtos %f62, %f14
fdtos %f62, %f15
fdtos %f62, %f16
fdtos %f62, %f17
fdtos %f62, %f18
fdtos %f62, %f19
fdtos %f62, %f20
fdtos %f62, %f21
fdtos %f62, %f22
fdtos %f62, %f23
fdtos %f62, %f24
fdtos %f62, %f25
fdtos %f62, %f26
fdtos %f62, %f27
fdtos %f62, %f28
fdtos %f62, %f29
fdtos %f62, %f30
fdtos %f62, %f31
fitos_emul_fini:
ldd [%g6 + TI_FPREGS + (62 * 4)], %f62
done
.globl do_fptrap
.align 32
do_fptrap:
TRAP_LOAD_THREAD_REG(%g6, %g1)
stx %fsr, [%g6 + TI_XFSR]
do_fptrap_after_fsr:
ldub [%g6 + TI_FPSAVED], %g3
rd %fprs, %g1
or %g3, %g1, %g3
stb %g3, [%g6 + TI_FPSAVED]
rd %gsr, %g3
stx %g3, [%g6 + TI_GSR]
mov SECONDARY_CONTEXT, %g3
661: ldxa [%g3] ASI_DMMU, %g5
.section .sun4v_1insn_patch, "ax"
.word 661b
ldxa [%g3] ASI_MMU, %g5
.previous
sethi %hi(sparc64_kern_sec_context), %g2
ldx [%g2 + %lo(sparc64_kern_sec_context)], %g2
661: stxa %g2, [%g3] ASI_DMMU
.section .sun4v_1insn_patch, "ax"
.word 661b
stxa %g2, [%g3] ASI_MMU
.previous
membar #Sync
add %g6, TI_FPREGS, %g2
andcc %g1, FPRS_DL, %g0
be,pn %icc, 4f
mov 0x40, %g3
stda %f0, [%g2] ASI_BLK_S
stda %f16, [%g2 + %g3] ASI_BLK_S
andcc %g1, FPRS_DU, %g0
be,pn %icc, 5f
4: add %g2, 128, %g2
stda %f32, [%g2] ASI_BLK_S
stda %f48, [%g2 + %g3] ASI_BLK_S
5: mov SECONDARY_CONTEXT, %g1
membar #Sync
661: stxa %g5, [%g1] ASI_DMMU
.section .sun4v_1insn_patch, "ax"
.word 661b
stxa %g5, [%g1] ASI_MMU
.previous
membar #Sync
ba,pt %xcc, etrap
wr %g0, 0, %fprs
/* The registers for cross calls will be:
*
* DATA 0: [low 32-bits] Address of function to call, jmp to this
* [high 32-bits] MMU Context Argument 0, place in %g5
* DATA 1: Address Argument 1, place in %g1
* DATA 2: Address Argument 2, place in %g7
*
* With this method we can do most of the cross-call tlb/cache
* flushing very quickly.
*/
.text
.align 32
.globl do_ivec
do_ivec:
mov 0x40, %g3
ldxa [%g3 + %g0] ASI_INTR_R, %g3
sethi %hi(KERNBASE), %g4
cmp %g3, %g4
bgeu,pn %xcc, do_ivec_xcall
srlx %g3, 32, %g5
stxa %g0, [%g0] ASI_INTR_RECEIVE
membar #Sync
sethi %hi(ivector_table), %g2
sllx %g3, 3, %g3
or %g2, %lo(ivector_table), %g2
add %g2, %g3, %g3
TRAP_LOAD_IRQ_WORK(%g6, %g1)
[SPARC64]: Elminate all usage of hard-coded trap globals. UltraSPARC has special sets of global registers which are switched to for certain trap types. There is one set for MMU related traps, one set of Interrupt Vector processing, and another set (called the Alternate globals) for all other trap types. For what seems like forever we've hard coded the values in some of these trap registers. Some examples include: 1) Interrupt Vector global %g6 holds current processors interrupt work struct where received interrupts are managed for IRQ handler dispatch. 2) MMU global %g7 holds the base of the page tables of the currently active address space. 3) Alternate global %g6 held the current_thread_info() value. Such hardcoding has resulted in some serious issues in many areas. There are some code sequences where having another register available would help clean up the implementation. Taking traps such as cross-calls from the OBP firmware requires some trick code sequences wherein we have to save away and restore all of the special sets of global registers when we enter/exit OBP. We were also using the IMMU TSB register on SMP to hold the per-cpu area base address, which doesn't work any longer now that we actually use the TSB facility of the cpu. The implementation is pretty straight forward. One tricky bit is getting the current processor ID as that is different on different cpu variants. We use a stub with a fancy calling convention which we patch at boot time. The calling convention is that the stub is branched to and the (PC - 4) to return to is in register %g1. The cpu number is left in %g6. This stub can be invoked by using the __GET_CPUID macro. We use an array of per-cpu trap state to store the current thread and physical address of the current address space's page tables. The TRAP_LOAD_THREAD_REG loads %g6 with the current thread from this table, it uses __GET_CPUID and also clobbers %g1. TRAP_LOAD_IRQ_WORK is used by the interrupt vector processing to load the current processor's IRQ software state into %g6. It also uses __GET_CPUID and clobbers %g1. Finally, TRAP_LOAD_PGD_PHYS loads the physical address base of the current address space's page tables into %g7, it clobbers %g1 and uses __GET_CPUID. Many refinements are possible, as well as some tuning, with this stuff in place. Signed-off-by: David S. Miller <davem@davemloft.net>
2006-02-27 02:24:22 -05:00
lduw [%g6], %g5 /* g5 = irq_work(cpu) */
stw %g5, [%g3 + 0x00] /* bucket->irq_chain = g5 */
stw %g3, [%g6] /* irq_work(cpu) = bucket */
wr %g0, 1 << PIL_DEVICE_IRQ, %set_softint
retry
do_ivec_xcall:
mov 0x50, %g1
ldxa [%g1 + %g0] ASI_INTR_R, %g1
srl %g3, 0, %g3
mov 0x60, %g7
ldxa [%g7 + %g0] ASI_INTR_R, %g7
stxa %g0, [%g0] ASI_INTR_RECEIVE
membar #Sync
ba,pt %xcc, 1f
nop
.align 32
1: jmpl %g3, %g0
nop
.globl getcc, setcc
getcc:
ldx [%o0 + PT_V9_TSTATE], %o1
srlx %o1, 32, %o1
and %o1, 0xf, %o1
retl
stx %o1, [%o0 + PT_V9_G1]
setcc:
ldx [%o0 + PT_V9_TSTATE], %o1
ldx [%o0 + PT_V9_G1], %o2
or %g0, %ulo(TSTATE_ICC), %o3
sllx %o3, 32, %o3
andn %o1, %o3, %o1
sllx %o2, 32, %o2
and %o2, %o3, %o2
or %o1, %o2, %o1
retl
stx %o1, [%o0 + PT_V9_TSTATE]
[SPARC64]: Elminate all usage of hard-coded trap globals. UltraSPARC has special sets of global registers which are switched to for certain trap types. There is one set for MMU related traps, one set of Interrupt Vector processing, and another set (called the Alternate globals) for all other trap types. For what seems like forever we've hard coded the values in some of these trap registers. Some examples include: 1) Interrupt Vector global %g6 holds current processors interrupt work struct where received interrupts are managed for IRQ handler dispatch. 2) MMU global %g7 holds the base of the page tables of the currently active address space. 3) Alternate global %g6 held the current_thread_info() value. Such hardcoding has resulted in some serious issues in many areas. There are some code sequences where having another register available would help clean up the implementation. Taking traps such as cross-calls from the OBP firmware requires some trick code sequences wherein we have to save away and restore all of the special sets of global registers when we enter/exit OBP. We were also using the IMMU TSB register on SMP to hold the per-cpu area base address, which doesn't work any longer now that we actually use the TSB facility of the cpu. The implementation is pretty straight forward. One tricky bit is getting the current processor ID as that is different on different cpu variants. We use a stub with a fancy calling convention which we patch at boot time. The calling convention is that the stub is branched to and the (PC - 4) to return to is in register %g1. The cpu number is left in %g6. This stub can be invoked by using the __GET_CPUID macro. We use an array of per-cpu trap state to store the current thread and physical address of the current address space's page tables. The TRAP_LOAD_THREAD_REG loads %g6 with the current thread from this table, it uses __GET_CPUID and also clobbers %g1. TRAP_LOAD_IRQ_WORK is used by the interrupt vector processing to load the current processor's IRQ software state into %g6. It also uses __GET_CPUID and clobbers %g1. Finally, TRAP_LOAD_PGD_PHYS loads the physical address base of the current address space's page tables into %g7, it clobbers %g1 and uses __GET_CPUID. Many refinements are possible, as well as some tuning, with this stuff in place. Signed-off-by: David S. Miller <davem@davemloft.net>
2006-02-27 02:24:22 -05:00
.globl utrap_trap
utrap_trap: /* %g3=handler,%g4=level */
TRAP_LOAD_THREAD_REG(%g6, %g1)
[SPARC64]: Elminate all usage of hard-coded trap globals. UltraSPARC has special sets of global registers which are switched to for certain trap types. There is one set for MMU related traps, one set of Interrupt Vector processing, and another set (called the Alternate globals) for all other trap types. For what seems like forever we've hard coded the values in some of these trap registers. Some examples include: 1) Interrupt Vector global %g6 holds current processors interrupt work struct where received interrupts are managed for IRQ handler dispatch. 2) MMU global %g7 holds the base of the page tables of the currently active address space. 3) Alternate global %g6 held the current_thread_info() value. Such hardcoding has resulted in some serious issues in many areas. There are some code sequences where having another register available would help clean up the implementation. Taking traps such as cross-calls from the OBP firmware requires some trick code sequences wherein we have to save away and restore all of the special sets of global registers when we enter/exit OBP. We were also using the IMMU TSB register on SMP to hold the per-cpu area base address, which doesn't work any longer now that we actually use the TSB facility of the cpu. The implementation is pretty straight forward. One tricky bit is getting the current processor ID as that is different on different cpu variants. We use a stub with a fancy calling convention which we patch at boot time. The calling convention is that the stub is branched to and the (PC - 4) to return to is in register %g1. The cpu number is left in %g6. This stub can be invoked by using the __GET_CPUID macro. We use an array of per-cpu trap state to store the current thread and physical address of the current address space's page tables. The TRAP_LOAD_THREAD_REG loads %g6 with the current thread from this table, it uses __GET_CPUID and also clobbers %g1. TRAP_LOAD_IRQ_WORK is used by the interrupt vector processing to load the current processor's IRQ software state into %g6. It also uses __GET_CPUID and clobbers %g1. Finally, TRAP_LOAD_PGD_PHYS loads the physical address base of the current address space's page tables into %g7, it clobbers %g1 and uses __GET_CPUID. Many refinements are possible, as well as some tuning, with this stuff in place. Signed-off-by: David S. Miller <davem@davemloft.net>
2006-02-27 02:24:22 -05:00
ldx [%g6 + TI_UTRAPS], %g1
brnz,pt %g1, invoke_utrap
nop
[SPARC64]: Elminate all usage of hard-coded trap globals. UltraSPARC has special sets of global registers which are switched to for certain trap types. There is one set for MMU related traps, one set of Interrupt Vector processing, and another set (called the Alternate globals) for all other trap types. For what seems like forever we've hard coded the values in some of these trap registers. Some examples include: 1) Interrupt Vector global %g6 holds current processors interrupt work struct where received interrupts are managed for IRQ handler dispatch. 2) MMU global %g7 holds the base of the page tables of the currently active address space. 3) Alternate global %g6 held the current_thread_info() value. Such hardcoding has resulted in some serious issues in many areas. There are some code sequences where having another register available would help clean up the implementation. Taking traps such as cross-calls from the OBP firmware requires some trick code sequences wherein we have to save away and restore all of the special sets of global registers when we enter/exit OBP. We were also using the IMMU TSB register on SMP to hold the per-cpu area base address, which doesn't work any longer now that we actually use the TSB facility of the cpu. The implementation is pretty straight forward. One tricky bit is getting the current processor ID as that is different on different cpu variants. We use a stub with a fancy calling convention which we patch at boot time. The calling convention is that the stub is branched to and the (PC - 4) to return to is in register %g1. The cpu number is left in %g6. This stub can be invoked by using the __GET_CPUID macro. We use an array of per-cpu trap state to store the current thread and physical address of the current address space's page tables. The TRAP_LOAD_THREAD_REG loads %g6 with the current thread from this table, it uses __GET_CPUID and also clobbers %g1. TRAP_LOAD_IRQ_WORK is used by the interrupt vector processing to load the current processor's IRQ software state into %g6. It also uses __GET_CPUID and clobbers %g1. Finally, TRAP_LOAD_PGD_PHYS loads the physical address base of the current address space's page tables into %g7, it clobbers %g1 and uses __GET_CPUID. Many refinements are possible, as well as some tuning, with this stuff in place. Signed-off-by: David S. Miller <davem@davemloft.net>
2006-02-27 02:24:22 -05:00
ba,pt %xcc, etrap
rd %pc, %g7
mov %l4, %o1
call bad_trap
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
invoke_utrap:
sllx %g3, 3, %g3
ldx [%g1 + %g3], %g1
save %sp, -128, %sp
rdpr %tstate, %l6
rdpr %cwp, %l7
andn %l6, TSTATE_CWP, %l6
wrpr %l6, %l7, %tstate
rdpr %tpc, %l6
rdpr %tnpc, %l7
wrpr %g1, 0, %tnpc
done
/* We need to carefully read the error status, ACK
* the errors, prevent recursive traps, and pass the
* information on to C code for logging.
*
* We pass the AFAR in as-is, and we encode the status
* information as described in asm-sparc64/sfafsr.h
*/
.globl __spitfire_access_error
__spitfire_access_error:
/* Disable ESTATE error reporting so that we do not
* take recursive traps and RED state the processor.
*/
stxa %g0, [%g0] ASI_ESTATE_ERROR_EN
membar #Sync
mov UDBE_UE, %g1
ldxa [%g0] ASI_AFSR, %g4 ! Get AFSR
/* __spitfire_cee_trap branches here with AFSR in %g4 and
* UDBE_CE in %g1. It only clears ESTATE_ERR_CE in the
* ESTATE Error Enable register.
*/
__spitfire_cee_trap_continue:
ldxa [%g0] ASI_AFAR, %g5 ! Get AFAR
rdpr %tt, %g3
and %g3, 0x1ff, %g3 ! Paranoia
sllx %g3, SFSTAT_TRAP_TYPE_SHIFT, %g3
or %g4, %g3, %g4
rdpr %tl, %g3
cmp %g3, 1
mov 1, %g3
bleu %xcc, 1f
sllx %g3, SFSTAT_TL_GT_ONE_SHIFT, %g3
or %g4, %g3, %g4
/* Read in the UDB error register state, clearing the
* sticky error bits as-needed. We only clear them if
* the UE bit is set. Likewise, __spitfire_cee_trap
* below will only do so if the CE bit is set.
*
* NOTE: UltraSparc-I/II have high and low UDB error
* registers, corresponding to the two UDB units
* present on those chips. UltraSparc-IIi only
* has a single UDB, called "SDB" in the manual.
* For IIi the upper UDB register always reads
* as zero so for our purposes things will just
* work with the checks below.
*/
1: ldxa [%g0] ASI_UDBH_ERROR_R, %g3
and %g3, 0x3ff, %g7 ! Paranoia
sllx %g7, SFSTAT_UDBH_SHIFT, %g7
or %g4, %g7, %g4
andcc %g3, %g1, %g3 ! UDBE_UE or UDBE_CE
be,pn %xcc, 1f
nop
stxa %g3, [%g0] ASI_UDB_ERROR_W
membar #Sync
1: mov 0x18, %g3
ldxa [%g3] ASI_UDBL_ERROR_R, %g3
and %g3, 0x3ff, %g7 ! Paranoia
sllx %g7, SFSTAT_UDBL_SHIFT, %g7
or %g4, %g7, %g4
andcc %g3, %g1, %g3 ! UDBE_UE or UDBE_CE
be,pn %xcc, 1f
nop
mov 0x18, %g7
stxa %g3, [%g7] ASI_UDB_ERROR_W
membar #Sync
1: /* Ok, now that we've latched the error state,
* clear the sticky bits in the AFSR.
*/
stxa %g4, [%g0] ASI_AFSR
membar #Sync
rdpr %tl, %g2
cmp %g2, 1
rdpr %pil, %g2
bleu,pt %xcc, 1f
wrpr %g0, 15, %pil
ba,pt %xcc, etraptl1
rd %pc, %g7
ba,pt %xcc, 2f
nop
1: ba,pt %xcc, etrap_irq
rd %pc, %g7
2: mov %l4, %o1
mov %l5, %o2
call spitfire_access_error
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
/* This is the trap handler entry point for ECC correctable
* errors. They are corrected, but we listen for the trap
* so that the event can be logged.
*
* Disrupting errors are either:
* 1) single-bit ECC errors during UDB reads to system
* memory
* 2) data parity errors during write-back events
*
* As far as I can make out from the manual, the CEE trap
* is only for correctable errors during memory read
* accesses by the front-end of the processor.
*
* The code below is only for trap level 1 CEE events,
* as it is the only situation where we can safely record
* and log. For trap level >1 we just clear the CE bit
* in the AFSR and return.
*
* This is just like __spiftire_access_error above, but it
* specifically handles correctable errors. If an
* uncorrectable error is indicated in the AFSR we
* will branch directly above to __spitfire_access_error
* to handle it instead. Uncorrectable therefore takes
* priority over correctable, and the error logging
* C code will notice this case by inspecting the
* trap type.
*/
.globl __spitfire_cee_trap
__spitfire_cee_trap:
ldxa [%g0] ASI_AFSR, %g4 ! Get AFSR
mov 1, %g3
sllx %g3, SFAFSR_UE_SHIFT, %g3
andcc %g4, %g3, %g0 ! Check for UE
bne,pn %xcc, __spitfire_access_error
nop
/* Ok, in this case we only have a correctable error.
* Indicate we only wish to capture that state in register
* %g1, and we only disable CE error reporting unlike UE
* handling which disables all errors.
*/
ldxa [%g0] ASI_ESTATE_ERROR_EN, %g3
andn %g3, ESTATE_ERR_CE, %g3
stxa %g3, [%g0] ASI_ESTATE_ERROR_EN
membar #Sync
/* Preserve AFSR in %g4, indicate UDB state to capture in %g1 */
ba,pt %xcc, __spitfire_cee_trap_continue
mov UDBE_CE, %g1
.globl __spitfire_data_access_exception
.globl __spitfire_data_access_exception_tl1
__spitfire_data_access_exception_tl1:
rdpr %pstate, %g4
wrpr %g4, PSTATE_MG|PSTATE_AG, %pstate
mov TLB_SFSR, %g3
mov DMMU_SFAR, %g5
ldxa [%g3] ASI_DMMU, %g4 ! Get SFSR
ldxa [%g5] ASI_DMMU, %g5 ! Get SFAR
stxa %g0, [%g3] ASI_DMMU ! Clear SFSR.FaultValid bit
membar #Sync
rdpr %tt, %g3
cmp %g3, 0x80 ! first win spill/fill trap
blu,pn %xcc, 1f
cmp %g3, 0xff ! last win spill/fill trap
bgu,pn %xcc, 1f
nop
ba,pt %xcc, winfix_dax
rdpr %tpc, %g3
1: sethi %hi(109f), %g7
ba,pt %xcc, etraptl1
109: or %g7, %lo(109b), %g7
mov %l4, %o1
mov %l5, %o2
call spitfire_data_access_exception_tl1
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
__spitfire_data_access_exception:
rdpr %pstate, %g4
wrpr %g4, PSTATE_MG|PSTATE_AG, %pstate
mov TLB_SFSR, %g3
mov DMMU_SFAR, %g5
ldxa [%g3] ASI_DMMU, %g4 ! Get SFSR
ldxa [%g5] ASI_DMMU, %g5 ! Get SFAR
stxa %g0, [%g3] ASI_DMMU ! Clear SFSR.FaultValid bit
membar #Sync
sethi %hi(109f), %g7
ba,pt %xcc, etrap
109: or %g7, %lo(109b), %g7
mov %l4, %o1
mov %l5, %o2
call spitfire_data_access_exception
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
.globl __spitfire_insn_access_exception
.globl __spitfire_insn_access_exception_tl1
__spitfire_insn_access_exception_tl1:
rdpr %pstate, %g4
wrpr %g4, PSTATE_MG|PSTATE_AG, %pstate
mov TLB_SFSR, %g3
ldxa [%g3] ASI_IMMU, %g4 ! Get SFSR
rdpr %tpc, %g5 ! IMMU has no SFAR, use TPC
stxa %g0, [%g3] ASI_IMMU ! Clear FaultValid bit
membar #Sync
sethi %hi(109f), %g7
ba,pt %xcc, etraptl1
109: or %g7, %lo(109b), %g7
mov %l4, %o1
mov %l5, %o2
call spitfire_insn_access_exception_tl1
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
__spitfire_insn_access_exception:
rdpr %pstate, %g4
wrpr %g4, PSTATE_MG|PSTATE_AG, %pstate
mov TLB_SFSR, %g3
ldxa [%g3] ASI_IMMU, %g4 ! Get SFSR
rdpr %tpc, %g5 ! IMMU has no SFAR, use TPC
stxa %g0, [%g3] ASI_IMMU ! Clear FaultValid bit
membar #Sync
sethi %hi(109f), %g7
ba,pt %xcc, etrap
109: or %g7, %lo(109b), %g7
mov %l4, %o1
mov %l5, %o2
call spitfire_insn_access_exception
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
/* These get patched into the trap table at boot time
* once we know we have a cheetah processor.
*/
.globl cheetah_fecc_trap_vector, cheetah_fecc_trap_vector_tl1
cheetah_fecc_trap_vector:
membar #Sync
ldxa [%g0] ASI_DCU_CONTROL_REG, %g1
andn %g1, DCU_DC | DCU_IC, %g1
stxa %g1, [%g0] ASI_DCU_CONTROL_REG
membar #Sync
sethi %hi(cheetah_fast_ecc), %g2
jmpl %g2 + %lo(cheetah_fast_ecc), %g0
mov 0, %g1
cheetah_fecc_trap_vector_tl1:
membar #Sync
ldxa [%g0] ASI_DCU_CONTROL_REG, %g1
andn %g1, DCU_DC | DCU_IC, %g1
stxa %g1, [%g0] ASI_DCU_CONTROL_REG
membar #Sync
sethi %hi(cheetah_fast_ecc), %g2
jmpl %g2 + %lo(cheetah_fast_ecc), %g0
mov 1, %g1
.globl cheetah_cee_trap_vector, cheetah_cee_trap_vector_tl1
cheetah_cee_trap_vector:
membar #Sync
ldxa [%g0] ASI_DCU_CONTROL_REG, %g1
andn %g1, DCU_IC, %g1
stxa %g1, [%g0] ASI_DCU_CONTROL_REG
membar #Sync
sethi %hi(cheetah_cee), %g2
jmpl %g2 + %lo(cheetah_cee), %g0
mov 0, %g1
cheetah_cee_trap_vector_tl1:
membar #Sync
ldxa [%g0] ASI_DCU_CONTROL_REG, %g1
andn %g1, DCU_IC, %g1
stxa %g1, [%g0] ASI_DCU_CONTROL_REG
membar #Sync
sethi %hi(cheetah_cee), %g2
jmpl %g2 + %lo(cheetah_cee), %g0
mov 1, %g1
.globl cheetah_deferred_trap_vector, cheetah_deferred_trap_vector_tl1
cheetah_deferred_trap_vector:
membar #Sync
ldxa [%g0] ASI_DCU_CONTROL_REG, %g1;
andn %g1, DCU_DC | DCU_IC, %g1;
stxa %g1, [%g0] ASI_DCU_CONTROL_REG;
membar #Sync;
sethi %hi(cheetah_deferred_trap), %g2
jmpl %g2 + %lo(cheetah_deferred_trap), %g0
mov 0, %g1
cheetah_deferred_trap_vector_tl1:
membar #Sync;
ldxa [%g0] ASI_DCU_CONTROL_REG, %g1;
andn %g1, DCU_DC | DCU_IC, %g1;
stxa %g1, [%g0] ASI_DCU_CONTROL_REG;
membar #Sync;
sethi %hi(cheetah_deferred_trap), %g2
jmpl %g2 + %lo(cheetah_deferred_trap), %g0
mov 1, %g1
/* Cheetah+ specific traps. These are for the new I/D cache parity
* error traps. The first argument to cheetah_plus_parity_handler
* is encoded as follows:
*
* Bit0: 0=dcache,1=icache
* Bit1: 0=recoverable,1=unrecoverable
*/
.globl cheetah_plus_dcpe_trap_vector, cheetah_plus_dcpe_trap_vector_tl1
cheetah_plus_dcpe_trap_vector:
membar #Sync
sethi %hi(do_cheetah_plus_data_parity), %g7
jmpl %g7 + %lo(do_cheetah_plus_data_parity), %g0
nop
nop
nop
nop
nop
do_cheetah_plus_data_parity:
rdpr %pil, %g2
wrpr %g0, 15, %pil
ba,pt %xcc, etrap_irq
rd %pc, %g7
mov 0x0, %o0
call cheetah_plus_parity_error
add %sp, PTREGS_OFF, %o1
ba,a,pt %xcc, rtrap_irq
cheetah_plus_dcpe_trap_vector_tl1:
membar #Sync
wrpr PSTATE_IG | PSTATE_PEF | PSTATE_PRIV, %pstate
sethi %hi(do_dcpe_tl1), %g3
jmpl %g3 + %lo(do_dcpe_tl1), %g0
nop
nop
nop
nop
.globl cheetah_plus_icpe_trap_vector, cheetah_plus_icpe_trap_vector_tl1
cheetah_plus_icpe_trap_vector:
membar #Sync
sethi %hi(do_cheetah_plus_insn_parity), %g7
jmpl %g7 + %lo(do_cheetah_plus_insn_parity), %g0
nop
nop
nop
nop
nop
do_cheetah_plus_insn_parity:
rdpr %pil, %g2
wrpr %g0, 15, %pil
ba,pt %xcc, etrap_irq
rd %pc, %g7
mov 0x1, %o0
call cheetah_plus_parity_error
add %sp, PTREGS_OFF, %o1
ba,a,pt %xcc, rtrap_irq
cheetah_plus_icpe_trap_vector_tl1:
membar #Sync
wrpr PSTATE_IG | PSTATE_PEF | PSTATE_PRIV, %pstate
sethi %hi(do_icpe_tl1), %g3
jmpl %g3 + %lo(do_icpe_tl1), %g0
nop
nop
nop
nop
/* If we take one of these traps when tl >= 1, then we
* jump to interrupt globals. If some trap level above us
* was also using interrupt globals, we cannot recover.
* We may use all interrupt global registers except %g6.
*/
.globl do_dcpe_tl1, do_icpe_tl1
do_dcpe_tl1:
rdpr %tl, %g1 ! Save original trap level
mov 1, %g2 ! Setup TSTATE checking loop
sethi %hi(TSTATE_IG), %g3 ! TSTATE mask bit
1: wrpr %g2, %tl ! Set trap level to check
rdpr %tstate, %g4 ! Read TSTATE for this level
andcc %g4, %g3, %g0 ! Interrupt globals in use?
bne,a,pn %xcc, do_dcpe_tl1_fatal ! Yep, irrecoverable
wrpr %g1, %tl ! Restore original trap level
add %g2, 1, %g2 ! Next trap level
cmp %g2, %g1 ! Hit them all yet?
ble,pt %icc, 1b ! Not yet
nop
wrpr %g1, %tl ! Restore original trap level
do_dcpe_tl1_nonfatal: /* Ok we may use interrupt globals safely. */
sethi %hi(dcache_parity_tl1_occurred), %g2
lduw [%g2 + %lo(dcache_parity_tl1_occurred)], %g1
add %g1, 1, %g1
stw %g1, [%g2 + %lo(dcache_parity_tl1_occurred)]
/* Reset D-cache parity */
sethi %hi(1 << 16), %g1 ! D-cache size
mov (1 << 5), %g2 ! D-cache line size
sub %g1, %g2, %g1 ! Move down 1 cacheline
1: srl %g1, 14, %g3 ! Compute UTAG
membar #Sync
stxa %g3, [%g1] ASI_DCACHE_UTAG
membar #Sync
sub %g2, 8, %g3 ! 64-bit data word within line
2: membar #Sync
stxa %g0, [%g1 + %g3] ASI_DCACHE_DATA
membar #Sync
subcc %g3, 8, %g3 ! Next 64-bit data word
bge,pt %icc, 2b
nop
subcc %g1, %g2, %g1 ! Next cacheline
bge,pt %icc, 1b
nop
ba,pt %xcc, dcpe_icpe_tl1_common
nop
do_dcpe_tl1_fatal:
sethi %hi(1f), %g7
ba,pt %xcc, etraptl1
1: or %g7, %lo(1b), %g7
mov 0x2, %o0
call cheetah_plus_parity_error
add %sp, PTREGS_OFF, %o1
ba,pt %xcc, rtrap
clr %l6
do_icpe_tl1:
rdpr %tl, %g1 ! Save original trap level
mov 1, %g2 ! Setup TSTATE checking loop
sethi %hi(TSTATE_IG), %g3 ! TSTATE mask bit
1: wrpr %g2, %tl ! Set trap level to check
rdpr %tstate, %g4 ! Read TSTATE for this level
andcc %g4, %g3, %g0 ! Interrupt globals in use?
bne,a,pn %xcc, do_icpe_tl1_fatal ! Yep, irrecoverable
wrpr %g1, %tl ! Restore original trap level
add %g2, 1, %g2 ! Next trap level
cmp %g2, %g1 ! Hit them all yet?
ble,pt %icc, 1b ! Not yet
nop
wrpr %g1, %tl ! Restore original trap level
do_icpe_tl1_nonfatal: /* Ok we may use interrupt globals safely. */
sethi %hi(icache_parity_tl1_occurred), %g2
lduw [%g2 + %lo(icache_parity_tl1_occurred)], %g1
add %g1, 1, %g1
stw %g1, [%g2 + %lo(icache_parity_tl1_occurred)]
/* Flush I-cache */
sethi %hi(1 << 15), %g1 ! I-cache size
mov (1 << 5), %g2 ! I-cache line size
sub %g1, %g2, %g1
1: or %g1, (2 << 3), %g3
stxa %g0, [%g3] ASI_IC_TAG
membar #Sync
subcc %g1, %g2, %g1
bge,pt %icc, 1b
nop
ba,pt %xcc, dcpe_icpe_tl1_common
nop
do_icpe_tl1_fatal:
sethi %hi(1f), %g7
ba,pt %xcc, etraptl1
1: or %g7, %lo(1b), %g7
mov 0x3, %o0
call cheetah_plus_parity_error
add %sp, PTREGS_OFF, %o1
ba,pt %xcc, rtrap
clr %l6
dcpe_icpe_tl1_common:
/* Flush D-cache, re-enable D/I caches in DCU and finally
* retry the trapping instruction.
*/
sethi %hi(1 << 16), %g1 ! D-cache size
mov (1 << 5), %g2 ! D-cache line size
sub %g1, %g2, %g1
1: stxa %g0, [%g1] ASI_DCACHE_TAG
membar #Sync
subcc %g1, %g2, %g1
bge,pt %icc, 1b
nop
ldxa [%g0] ASI_DCU_CONTROL_REG, %g1
or %g1, (DCU_DC | DCU_IC), %g1
stxa %g1, [%g0] ASI_DCU_CONTROL_REG
membar #Sync
retry
/* Capture I/D/E-cache state into per-cpu error scoreboard.
*
* %g1: (TL>=0) ? 1 : 0
* %g2: scratch
* %g3: scratch
* %g4: AFSR
* %g5: AFAR
[SPARC64]: Elminate all usage of hard-coded trap globals. UltraSPARC has special sets of global registers which are switched to for certain trap types. There is one set for MMU related traps, one set of Interrupt Vector processing, and another set (called the Alternate globals) for all other trap types. For what seems like forever we've hard coded the values in some of these trap registers. Some examples include: 1) Interrupt Vector global %g6 holds current processors interrupt work struct where received interrupts are managed for IRQ handler dispatch. 2) MMU global %g7 holds the base of the page tables of the currently active address space. 3) Alternate global %g6 held the current_thread_info() value. Such hardcoding has resulted in some serious issues in many areas. There are some code sequences where having another register available would help clean up the implementation. Taking traps such as cross-calls from the OBP firmware requires some trick code sequences wherein we have to save away and restore all of the special sets of global registers when we enter/exit OBP. We were also using the IMMU TSB register on SMP to hold the per-cpu area base address, which doesn't work any longer now that we actually use the TSB facility of the cpu. The implementation is pretty straight forward. One tricky bit is getting the current processor ID as that is different on different cpu variants. We use a stub with a fancy calling convention which we patch at boot time. The calling convention is that the stub is branched to and the (PC - 4) to return to is in register %g1. The cpu number is left in %g6. This stub can be invoked by using the __GET_CPUID macro. We use an array of per-cpu trap state to store the current thread and physical address of the current address space's page tables. The TRAP_LOAD_THREAD_REG loads %g6 with the current thread from this table, it uses __GET_CPUID and also clobbers %g1. TRAP_LOAD_IRQ_WORK is used by the interrupt vector processing to load the current processor's IRQ software state into %g6. It also uses __GET_CPUID and clobbers %g1. Finally, TRAP_LOAD_PGD_PHYS loads the physical address base of the current address space's page tables into %g7, it clobbers %g1 and uses __GET_CPUID. Many refinements are possible, as well as some tuning, with this stuff in place. Signed-off-by: David S. Miller <davem@davemloft.net>
2006-02-27 02:24:22 -05:00
* %g6: unused, will have current thread ptr after etrap
* %g7: scratch
*/
__cheetah_log_error:
/* Put "TL1" software bit into AFSR. */
and %g1, 0x1, %g1
sllx %g1, 63, %g2
or %g4, %g2, %g4
/* Get log entry pointer for this cpu at this trap level. */
BRANCH_IF_JALAPENO(g2,g3,50f)
ldxa [%g0] ASI_SAFARI_CONFIG, %g2
srlx %g2, 17, %g2
ba,pt %xcc, 60f
and %g2, 0x3ff, %g2
50: ldxa [%g0] ASI_JBUS_CONFIG, %g2
srlx %g2, 17, %g2
and %g2, 0x1f, %g2
60: sllx %g2, 9, %g2
sethi %hi(cheetah_error_log), %g3
ldx [%g3 + %lo(cheetah_error_log)], %g3
brz,pn %g3, 80f
nop
add %g3, %g2, %g3
sllx %g1, 8, %g1
add %g3, %g1, %g1
/* %g1 holds pointer to the top of the logging scoreboard */
ldx [%g1 + 0x0], %g7
cmp %g7, -1
bne,pn %xcc, 80f
nop
stx %g4, [%g1 + 0x0]
stx %g5, [%g1 + 0x8]
add %g1, 0x10, %g1
/* %g1 now points to D-cache logging area */
set 0x3ff8, %g2 /* DC_addr mask */
and %g5, %g2, %g2 /* DC_addr bits of AFAR */
srlx %g5, 12, %g3
or %g3, 1, %g3 /* PHYS tag + valid */
10: ldxa [%g2] ASI_DCACHE_TAG, %g7
cmp %g3, %g7 /* TAG match? */
bne,pt %xcc, 13f
nop
/* Yep, what we want, capture state. */
stx %g2, [%g1 + 0x20]
stx %g7, [%g1 + 0x28]
/* A membar Sync is required before and after utag access. */
membar #Sync
ldxa [%g2] ASI_DCACHE_UTAG, %g7
membar #Sync
stx %g7, [%g1 + 0x30]
ldxa [%g2] ASI_DCACHE_SNOOP_TAG, %g7
stx %g7, [%g1 + 0x38]
clr %g3
12: ldxa [%g2 + %g3] ASI_DCACHE_DATA, %g7
stx %g7, [%g1]
add %g3, (1 << 5), %g3
cmp %g3, (4 << 5)
bl,pt %xcc, 12b
add %g1, 0x8, %g1
ba,pt %xcc, 20f
add %g1, 0x20, %g1
13: sethi %hi(1 << 14), %g7
add %g2, %g7, %g2
srlx %g2, 14, %g7
cmp %g7, 4
bl,pt %xcc, 10b
nop
add %g1, 0x40, %g1
/* %g1 now points to I-cache logging area */
20: set 0x1fe0, %g2 /* IC_addr mask */
and %g5, %g2, %g2 /* IC_addr bits of AFAR */
sllx %g2, 1, %g2 /* IC_addr[13:6]==VA[12:5] */
srlx %g5, (13 - 8), %g3 /* Make PTAG */
andn %g3, 0xff, %g3 /* Mask off undefined bits */
21: ldxa [%g2] ASI_IC_TAG, %g7
andn %g7, 0xff, %g7
cmp %g3, %g7
bne,pt %xcc, 23f
nop
/* Yep, what we want, capture state. */
stx %g2, [%g1 + 0x40]
stx %g7, [%g1 + 0x48]
add %g2, (1 << 3), %g2
ldxa [%g2] ASI_IC_TAG, %g7
add %g2, (1 << 3), %g2
stx %g7, [%g1 + 0x50]
ldxa [%g2] ASI_IC_TAG, %g7
add %g2, (1 << 3), %g2
stx %g7, [%g1 + 0x60]
ldxa [%g2] ASI_IC_TAG, %g7
stx %g7, [%g1 + 0x68]
sub %g2, (3 << 3), %g2
ldxa [%g2] ASI_IC_STAG, %g7
stx %g7, [%g1 + 0x58]
clr %g3
srlx %g2, 2, %g2
22: ldxa [%g2 + %g3] ASI_IC_INSTR, %g7
stx %g7, [%g1]
add %g3, (1 << 3), %g3
cmp %g3, (8 << 3)
bl,pt %xcc, 22b
add %g1, 0x8, %g1
ba,pt %xcc, 30f
add %g1, 0x30, %g1
23: sethi %hi(1 << 14), %g7
add %g2, %g7, %g2
srlx %g2, 14, %g7
cmp %g7, 4
bl,pt %xcc, 21b
nop
add %g1, 0x70, %g1
/* %g1 now points to E-cache logging area */
30: andn %g5, (32 - 1), %g2
stx %g2, [%g1 + 0x20]
ldxa [%g2] ASI_EC_TAG_DATA, %g7
stx %g7, [%g1 + 0x28]
ldxa [%g2] ASI_EC_R, %g0
clr %g3
31: ldxa [%g3] ASI_EC_DATA, %g7
stx %g7, [%g1 + %g3]
add %g3, 0x8, %g3
cmp %g3, 0x20
bl,pt %xcc, 31b
nop
80:
rdpr %tt, %g2
cmp %g2, 0x70
be c_fast_ecc
cmp %g2, 0x63
be c_cee
nop
ba,pt %xcc, c_deferred
/* Cheetah FECC trap handling, we get here from tl{0,1}_fecc
* in the trap table. That code has done a memory barrier
* and has disabled both the I-cache and D-cache in the DCU
* control register. The I-cache is disabled so that we may
* capture the corrupted cache line, and the D-cache is disabled
* because corrupt data may have been placed there and we don't
* want to reference it.
*
* %g1 is one if this trap occurred at %tl >= 1.
*
* Next, we turn off error reporting so that we don't recurse.
*/
.globl cheetah_fast_ecc
cheetah_fast_ecc:
ldxa [%g0] ASI_ESTATE_ERROR_EN, %g2
andn %g2, ESTATE_ERROR_NCEEN | ESTATE_ERROR_CEEN, %g2
stxa %g2, [%g0] ASI_ESTATE_ERROR_EN
membar #Sync
/* Fetch and clear AFSR/AFAR */
ldxa [%g0] ASI_AFSR, %g4
ldxa [%g0] ASI_AFAR, %g5
stxa %g4, [%g0] ASI_AFSR
membar #Sync
ba,pt %xcc, __cheetah_log_error
nop
c_fast_ecc:
rdpr %pil, %g2
wrpr %g0, 15, %pil
ba,pt %xcc, etrap_irq
rd %pc, %g7
mov %l4, %o1
mov %l5, %o2
call cheetah_fecc_handler
add %sp, PTREGS_OFF, %o0
ba,a,pt %xcc, rtrap_irq
/* Our caller has disabled I-cache and performed membar Sync. */
.globl cheetah_cee
cheetah_cee:
ldxa [%g0] ASI_ESTATE_ERROR_EN, %g2
andn %g2, ESTATE_ERROR_CEEN, %g2
stxa %g2, [%g0] ASI_ESTATE_ERROR_EN
membar #Sync
/* Fetch and clear AFSR/AFAR */
ldxa [%g0] ASI_AFSR, %g4
ldxa [%g0] ASI_AFAR, %g5
stxa %g4, [%g0] ASI_AFSR
membar #Sync
ba,pt %xcc, __cheetah_log_error
nop
c_cee:
rdpr %pil, %g2
wrpr %g0, 15, %pil
ba,pt %xcc, etrap_irq
rd %pc, %g7
mov %l4, %o1
mov %l5, %o2
call cheetah_cee_handler
add %sp, PTREGS_OFF, %o0
ba,a,pt %xcc, rtrap_irq
/* Our caller has disabled I-cache+D-cache and performed membar Sync. */
.globl cheetah_deferred_trap
cheetah_deferred_trap:
ldxa [%g0] ASI_ESTATE_ERROR_EN, %g2
andn %g2, ESTATE_ERROR_NCEEN | ESTATE_ERROR_CEEN, %g2
stxa %g2, [%g0] ASI_ESTATE_ERROR_EN
membar #Sync
/* Fetch and clear AFSR/AFAR */
ldxa [%g0] ASI_AFSR, %g4
ldxa [%g0] ASI_AFAR, %g5
stxa %g4, [%g0] ASI_AFSR
membar #Sync
ba,pt %xcc, __cheetah_log_error
nop
c_deferred:
rdpr %pil, %g2
wrpr %g0, 15, %pil
ba,pt %xcc, etrap_irq
rd %pc, %g7
mov %l4, %o1
mov %l5, %o2
call cheetah_deferred_handler
add %sp, PTREGS_OFF, %o0
ba,a,pt %xcc, rtrap_irq
.globl __do_privact
__do_privact:
mov TLB_SFSR, %g3
stxa %g0, [%g3] ASI_DMMU ! Clear FaultValid bit
membar #Sync
sethi %hi(109f), %g7
ba,pt %xcc, etrap
109: or %g7, %lo(109b), %g7
call do_privact
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
.globl do_mna
do_mna:
rdpr %tl, %g3
cmp %g3, 1
/* Setup %g4/%g5 now as they are used in the
* winfixup code.
*/
mov TLB_SFSR, %g3
mov DMMU_SFAR, %g4
ldxa [%g4] ASI_DMMU, %g4
ldxa [%g3] ASI_DMMU, %g5
stxa %g0, [%g3] ASI_DMMU ! Clear FaultValid bit
membar #Sync
bgu,pn %icc, winfix_mna
rdpr %tpc, %g3
1: sethi %hi(109f), %g7
ba,pt %xcc, etrap
109: or %g7, %lo(109b), %g7
mov %l4, %o1
mov %l5, %o2
call mem_address_unaligned
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
.globl do_lddfmna
do_lddfmna:
sethi %hi(109f), %g7
mov TLB_SFSR, %g4
ldxa [%g4] ASI_DMMU, %g5
stxa %g0, [%g4] ASI_DMMU ! Clear FaultValid bit
membar #Sync
mov DMMU_SFAR, %g4
ldxa [%g4] ASI_DMMU, %g4
ba,pt %xcc, etrap
109: or %g7, %lo(109b), %g7
mov %l4, %o1
mov %l5, %o2
call handle_lddfmna
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
.globl do_stdfmna
do_stdfmna:
sethi %hi(109f), %g7
mov TLB_SFSR, %g4
ldxa [%g4] ASI_DMMU, %g5
stxa %g0, [%g4] ASI_DMMU ! Clear FaultValid bit
membar #Sync
mov DMMU_SFAR, %g4
ldxa [%g4] ASI_DMMU, %g4
ba,pt %xcc, etrap
109: or %g7, %lo(109b), %g7
mov %l4, %o1
mov %l5, %o2
call handle_stdfmna
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
clr %l6
.globl breakpoint_trap
breakpoint_trap:
call sparc_breakpoint
add %sp, PTREGS_OFF, %o0
ba,pt %xcc, rtrap
nop
#if defined(CONFIG_SUNOS_EMUL) || defined(CONFIG_SOLARIS_EMUL) || \
defined(CONFIG_SOLARIS_EMUL_MODULE)
/* 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:
srl %o0, 0, %o0
mov %o7, %l4
cmp %o0, NR_SYSCALLS
blu,a,pt %icc, 1f
sll %o0, 0x2, %o0
sethi %hi(sunos_nosys), %l6
b,pt %xcc, 2f
or %l6, %lo(sunos_nosys), %l6
1: sethi %hi(sunos_sys_table), %l7
or %l7, %lo(sunos_sys_table), %l7
lduw [%l7 + %o0], %l6
2: mov %o1, %o0
mov %o2, %o1
mov %o3, %o2
mov %o4, %o3
mov %o5, %o4
call %l6
mov %l4, %o7
.globl sunos_getpid
sunos_getpid:
call sys_getppid
nop
call sys_getpid
stx %o0, [%sp + PTREGS_OFF + PT_V9_I1]
b,pt %xcc, ret_sys_call
stx %o0, [%sp + PTREGS_OFF + PT_V9_I0]
/* SunOS getuid() returns uid in %o0 and euid in %o1 */
.globl sunos_getuid
sunos_getuid:
call sys32_geteuid16
nop
call sys32_getuid16
stx %o0, [%sp + PTREGS_OFF + PT_V9_I1]
b,pt %xcc, ret_sys_call
stx %o0, [%sp + PTREGS_OFF + PT_V9_I0]
/* SunOS getgid() returns gid in %o0 and egid in %o1 */
.globl sunos_getgid
sunos_getgid:
call sys32_getegid16
nop
call sys32_getgid16
stx %o0, [%sp + PTREGS_OFF + PT_V9_I1]
b,pt %xcc, ret_sys_call
stx %o0, [%sp + PTREGS_OFF + PT_V9_I0]
#endif
/* SunOS's execv() call only specifies the argv argument, the
* environment settings are the same as the calling processes.
*/
.globl sunos_execv
sys_execve:
sethi %hi(sparc_execve), %g1
ba,pt %xcc, execve_merge
or %g1, %lo(sparc_execve), %g1
#ifdef CONFIG_COMPAT
.globl sys_execve
sunos_execv:
stx %g0, [%sp + PTREGS_OFF + PT_V9_I2]
.globl sys32_execve
sys32_execve:
sethi %hi(sparc32_execve), %g1
or %g1, %lo(sparc32_execve), %g1
#endif
execve_merge:
flushw
jmpl %g1, %g0
add %sp, PTREGS_OFF, %o0
.globl sys_pipe, sys_sigpause, sys_nis_syscall
.globl sys_rt_sigreturn
.globl sys_ptrace
.globl sys_sigaltstack
.align 32
sys_pipe: ba,pt %xcc, sparc_pipe
add %sp, PTREGS_OFF, %o0
sys_nis_syscall:ba,pt %xcc, c_sys_nis_syscall
add %sp, PTREGS_OFF, %o0
sys_memory_ordering:
ba,pt %xcc, sparc_memory_ordering
add %sp, PTREGS_OFF, %o1
sys_sigaltstack:ba,pt %xcc, do_sigaltstack
add %i6, STACK_BIAS, %o2
#ifdef CONFIG_COMPAT
.globl sys32_sigstack
sys32_sigstack: ba,pt %xcc, do_sys32_sigstack
mov %i6, %o2
.globl sys32_sigaltstack
sys32_sigaltstack:
ba,pt %xcc, do_sys32_sigaltstack
mov %i6, %o2
#endif
.align 32
#ifdef CONFIG_COMPAT
.globl sys32_sigreturn
sys32_sigreturn:
add %sp, PTREGS_OFF, %o0
call do_sigreturn32
add %o7, 1f-.-4, %o7
nop
#endif
sys_rt_sigreturn:
add %sp, PTREGS_OFF, %o0
call do_rt_sigreturn
add %o7, 1f-.-4, %o7
nop
#ifdef CONFIG_COMPAT
.globl sys32_rt_sigreturn
sys32_rt_sigreturn:
add %sp, PTREGS_OFF, %o0
call do_rt_sigreturn32
add %o7, 1f-.-4, %o7
nop
#endif
sys_ptrace: add %sp, PTREGS_OFF, %o0
call do_ptrace
add %o7, 1f-.-4, %o7
nop
.align 32
1: ldx [%curptr + TI_FLAGS], %l5
andcc %l5, (_TIF_SYSCALL_TRACE|_TIF_SECCOMP|_TIF_SYSCALL_AUDIT), %g0
be,pt %icc, rtrap
clr %l6
add %sp, PTREGS_OFF, %o0
call syscall_trace
mov 1, %o1
ba,pt %xcc, rtrap
clr %l6
/* This is how fork() was meant to be done, 8 instruction entry.
*
* I questioned the following code briefly, let me clear things
* up so you must not reason on it like I did.
*
* Know the fork_kpsr etc. we use in the sparc32 port? We don't
* need it here because the only piece of window state we copy to
* the child is the CWP register. Even if the parent sleeps,
* we are safe because we stuck it into pt_regs of the parent
* so it will not change.
*
* XXX This raises the question, whether we can do the same on
* XXX sparc32 to get rid of fork_kpsr _and_ fork_kwim. The
* XXX answer is yes. We stick fork_kpsr in UREG_G0 and
* XXX fork_kwim in UREG_G1 (global registers are considered
* XXX volatile across a system call in the sparc ABI I think
* XXX if it isn't we can use regs->y instead, anyone who depends
* XXX upon the Y register being preserved across a fork deserves
* XXX to lose).
*
* In fact we should take advantage of that fact for other things
* during system calls...
*/
.globl sys_fork, sys_vfork, sys_clone, sparc_exit
.globl ret_from_syscall
.align 32
sys_vfork: /* Under Linux, vfork and fork are just special cases of clone. */
sethi %hi(0x4000 | 0x0100 | SIGCHLD), %o0
or %o0, %lo(0x4000 | 0x0100 | SIGCHLD), %o0
ba,pt %xcc, sys_clone
sys_fork: clr %o1
mov SIGCHLD, %o0
sys_clone: flushw
movrz %o1, %fp, %o1
mov 0, %o3
ba,pt %xcc, sparc_do_fork
add %sp, PTREGS_OFF, %o2
ret_from_syscall:
/* Clear current_thread_info()->new_child, and
* check performance counter stuff too.
*/
stb %g0, [%g6 + TI_NEW_CHILD]
ldx [%g6 + TI_FLAGS], %l0
call schedule_tail
mov %g7, %o0
andcc %l0, _TIF_PERFCTR, %g0
be,pt %icc, 1f
nop
ldx [%g6 + TI_PCR], %o7
wr %g0, %o7, %pcr
/* Blackbird errata workaround. See commentary in
* smp.c:smp_percpu_timer_interrupt() for more
* information.
*/
ba,pt %xcc, 99f
nop
.align 64
99: wr %g0, %g0, %pic
rd %pic, %g0
1: b,pt %xcc, ret_sys_call
ldx [%sp + PTREGS_OFF + PT_V9_I0], %o0
sparc_exit: rdpr %pstate, %g2
wrpr %g2, PSTATE_IE, %pstate
rdpr %otherwin, %g1
rdpr %cansave, %g3
add %g3, %g1, %g3
wrpr %g3, 0x0, %cansave
wrpr %g0, 0x0, %otherwin
wrpr %g2, 0x0, %pstate
ba,pt %xcc, sys_exit
stb %g0, [%g6 + TI_WSAVED]
linux_sparc_ni_syscall:
sethi %hi(sys_ni_syscall), %l7
b,pt %xcc, 4f
or %l7, %lo(sys_ni_syscall), %l7
linux_syscall_trace32:
add %sp, PTREGS_OFF, %o0
call syscall_trace
clr %o1
srl %i0, 0, %o0
srl %i4, 0, %o4
srl %i1, 0, %o1
srl %i2, 0, %o2
b,pt %xcc, 2f
srl %i3, 0, %o3
linux_syscall_trace:
add %sp, PTREGS_OFF, %o0
call syscall_trace
clr %o1
mov %i0, %o0
mov %i1, %o1
mov %i2, %o2
mov %i3, %o3
b,pt %xcc, 2f
mov %i4, %o4
/* Linux 32-bit and SunOS system calls enter here... */
.align 32
.globl linux_sparc_syscall32
linux_sparc_syscall32:
/* Direct access to user regs, much faster. */
cmp %g1, NR_SYSCALLS ! IEU1 Group
bgeu,pn %xcc, linux_sparc_ni_syscall ! CTI
srl %i0, 0, %o0 ! IEU0
sll %g1, 2, %l4 ! IEU0 Group
srl %i4, 0, %o4 ! IEU1
lduw [%l7 + %l4], %l7 ! Load
srl %i1, 0, %o1 ! IEU0 Group
ldx [%curptr + TI_FLAGS], %l0 ! Load
srl %i5, 0, %o5 ! IEU1
srl %i2, 0, %o2 ! IEU0 Group
andcc %l0, (_TIF_SYSCALL_TRACE|_TIF_SECCOMP|_TIF_SYSCALL_AUDIT), %g0
bne,pn %icc, linux_syscall_trace32 ! CTI
mov %i0, %l5 ! IEU1
call %l7 ! CTI Group brk forced
srl %i3, 0, %o3 ! IEU0
ba,a,pt %xcc, 3f
/* Linux native and SunOS system calls enter here... */
.align 32
.globl linux_sparc_syscall, ret_sys_call
linux_sparc_syscall:
/* Direct access to user regs, much faster. */
cmp %g1, NR_SYSCALLS ! IEU1 Group
bgeu,pn %xcc, linux_sparc_ni_syscall ! CTI
mov %i0, %o0 ! IEU0
sll %g1, 2, %l4 ! IEU0 Group
mov %i1, %o1 ! IEU1
lduw [%l7 + %l4], %l7 ! Load
4: mov %i2, %o2 ! IEU0 Group
ldx [%curptr + TI_FLAGS], %l0 ! Load
mov %i3, %o3 ! IEU1
mov %i4, %o4 ! IEU0 Group
andcc %l0, (_TIF_SYSCALL_TRACE|_TIF_SECCOMP|_TIF_SYSCALL_AUDIT), %g0
bne,pn %icc, linux_syscall_trace ! CTI Group
mov %i0, %l5 ! IEU0
2: call %l7 ! CTI Group brk forced
mov %i5, %o5 ! IEU0
nop
3: stx %o0, [%sp + PTREGS_OFF + PT_V9_I0]
ret_sys_call:
ldx [%sp + PTREGS_OFF + PT_V9_TSTATE], %g3
ldx [%sp + PTREGS_OFF + PT_V9_TNPC], %l1 ! pc = npc
sra %o0, 0, %o0
mov %ulo(TSTATE_XCARRY | TSTATE_ICARRY), %g2
sllx %g2, 32, %g2
/* Check if force_successful_syscall_return()
* was invoked.
*/
ldub [%curptr + TI_SYS_NOERROR], %l2
brnz,a,pn %l2, 80f
stb %g0, [%curptr + TI_SYS_NOERROR]
cmp %o0, -ERESTART_RESTARTBLOCK
bgeu,pn %xcc, 1f
andcc %l0, (_TIF_SYSCALL_TRACE|_TIF_SECCOMP|_TIF_SYSCALL_AUDIT), %l6
80:
/* System call success, clear Carry condition code. */
andn %g3, %g2, %g3
stx %g3, [%sp + PTREGS_OFF + PT_V9_TSTATE]
bne,pn %icc, linux_syscall_trace2
add %l1, 0x4, %l2 ! npc = npc+4
stx %l1, [%sp + PTREGS_OFF + PT_V9_TPC]
ba,pt %xcc, rtrap_clr_l6
stx %l2, [%sp + PTREGS_OFF + PT_V9_TNPC]
1:
/* System call failure, set Carry condition code.
* Also, get abs(errno) to return to the process.
*/
andcc %l0, (_TIF_SYSCALL_TRACE|_TIF_SECCOMP|_TIF_SYSCALL_AUDIT), %l6
sub %g0, %o0, %o0
or %g3, %g2, %g3
stx %o0, [%sp + PTREGS_OFF + PT_V9_I0]
mov 1, %l6
stx %g3, [%sp + PTREGS_OFF + PT_V9_TSTATE]
bne,pn %icc, linux_syscall_trace2
add %l1, 0x4, %l2 ! npc = npc+4
stx %l1, [%sp + PTREGS_OFF + PT_V9_TPC]
b,pt %xcc, rtrap
stx %l2, [%sp + PTREGS_OFF + PT_V9_TNPC]
linux_syscall_trace2:
add %sp, PTREGS_OFF, %o0
call syscall_trace
mov 1, %o1
stx %l1, [%sp + PTREGS_OFF + PT_V9_TPC]
ba,pt %xcc, rtrap
stx %l2, [%sp + PTREGS_OFF + PT_V9_TNPC]
.align 32
.globl __flushw_user
__flushw_user:
rdpr %otherwin, %g1
brz,pn %g1, 2f
clr %g2
1: save %sp, -128, %sp
rdpr %otherwin, %g1
brnz,pt %g1, 1b
add %g2, 1, %g2
1: sub %g2, 1, %g2
brnz,pt %g2, 1b
restore %g0, %g0, %g0
2: retl
nop
[SPARC64]: Elminate all usage of hard-coded trap globals. UltraSPARC has special sets of global registers which are switched to for certain trap types. There is one set for MMU related traps, one set of Interrupt Vector processing, and another set (called the Alternate globals) for all other trap types. For what seems like forever we've hard coded the values in some of these trap registers. Some examples include: 1) Interrupt Vector global %g6 holds current processors interrupt work struct where received interrupts are managed for IRQ handler dispatch. 2) MMU global %g7 holds the base of the page tables of the currently active address space. 3) Alternate global %g6 held the current_thread_info() value. Such hardcoding has resulted in some serious issues in many areas. There are some code sequences where having another register available would help clean up the implementation. Taking traps such as cross-calls from the OBP firmware requires some trick code sequences wherein we have to save away and restore all of the special sets of global registers when we enter/exit OBP. We were also using the IMMU TSB register on SMP to hold the per-cpu area base address, which doesn't work any longer now that we actually use the TSB facility of the cpu. The implementation is pretty straight forward. One tricky bit is getting the current processor ID as that is different on different cpu variants. We use a stub with a fancy calling convention which we patch at boot time. The calling convention is that the stub is branched to and the (PC - 4) to return to is in register %g1. The cpu number is left in %g6. This stub can be invoked by using the __GET_CPUID macro. We use an array of per-cpu trap state to store the current thread and physical address of the current address space's page tables. The TRAP_LOAD_THREAD_REG loads %g6 with the current thread from this table, it uses __GET_CPUID and also clobbers %g1. TRAP_LOAD_IRQ_WORK is used by the interrupt vector processing to load the current processor's IRQ software state into %g6. It also uses __GET_CPUID and clobbers %g1. Finally, TRAP_LOAD_PGD_PHYS loads the physical address base of the current address space's page tables into %g7, it clobbers %g1 and uses __GET_CPUID. Many refinements are possible, as well as some tuning, with this stuff in place. Signed-off-by: David S. Miller <davem@davemloft.net>
2006-02-27 02:24:22 -05:00
#ifdef CONFIG_SMP
.globl hard_smp_processor_id
hard_smp_processor_id:
#endif
.globl real_hard_smp_processor_id
real_hard_smp_processor_id:
__GET_CPUID(%o0)
[SPARC64]: Elminate all usage of hard-coded trap globals. UltraSPARC has special sets of global registers which are switched to for certain trap types. There is one set for MMU related traps, one set of Interrupt Vector processing, and another set (called the Alternate globals) for all other trap types. For what seems like forever we've hard coded the values in some of these trap registers. Some examples include: 1) Interrupt Vector global %g6 holds current processors interrupt work struct where received interrupts are managed for IRQ handler dispatch. 2) MMU global %g7 holds the base of the page tables of the currently active address space. 3) Alternate global %g6 held the current_thread_info() value. Such hardcoding has resulted in some serious issues in many areas. There are some code sequences where having another register available would help clean up the implementation. Taking traps such as cross-calls from the OBP firmware requires some trick code sequences wherein we have to save away and restore all of the special sets of global registers when we enter/exit OBP. We were also using the IMMU TSB register on SMP to hold the per-cpu area base address, which doesn't work any longer now that we actually use the TSB facility of the cpu. The implementation is pretty straight forward. One tricky bit is getting the current processor ID as that is different on different cpu variants. We use a stub with a fancy calling convention which we patch at boot time. The calling convention is that the stub is branched to and the (PC - 4) to return to is in register %g1. The cpu number is left in %g6. This stub can be invoked by using the __GET_CPUID macro. We use an array of per-cpu trap state to store the current thread and physical address of the current address space's page tables. The TRAP_LOAD_THREAD_REG loads %g6 with the current thread from this table, it uses __GET_CPUID and also clobbers %g1. TRAP_LOAD_IRQ_WORK is used by the interrupt vector processing to load the current processor's IRQ software state into %g6. It also uses __GET_CPUID and clobbers %g1. Finally, TRAP_LOAD_PGD_PHYS loads the physical address base of the current address space's page tables into %g7, it clobbers %g1 and uses __GET_CPUID. Many refinements are possible, as well as some tuning, with this stuff in place. Signed-off-by: David S. Miller <davem@davemloft.net>
2006-02-27 02:24:22 -05:00
retl
nop
/* %o0: devhandle
* %o1: devino
*
* returns %o0: sysino
*/
.globl sun4v_devino_to_sysino
sun4v_devino_to_sysino:
mov HV_FAST_INTR_DEVINO2SYSINO, %o5
ta HV_FAST_TRAP
retl
mov %o1, %o0
/* %o0: sysino
*
* returns %o0: intr_enabled (HV_INTR_{DISABLED,ENABLED})
*/
.globl sun4v_intr_getenabled
sun4v_intr_getenabled:
mov HV_FAST_INTR_GETENABLED, %o5
ta HV_FAST_TRAP
retl
mov %o1, %o0
/* %o0: sysino
* %o1: intr_enabled (HV_INTR_{DISABLED,ENABLED})
*/
.globl sun4v_intr_setenabled
sun4v_intr_setenabled:
mov HV_FAST_INTR_SETENABLED, %o5
ta HV_FAST_TRAP
retl
nop
/* %o0: sysino
*
* returns %o0: intr_state (HV_INTR_STATE_*)
*/
.globl sun4v_intr_getstate
sun4v_intr_getstate:
mov HV_FAST_INTR_GETSTATE, %o5
ta HV_FAST_TRAP
retl
mov %o1, %o0
/* %o0: sysino
* %o1: intr_state (HV_INTR_STATE_*)
*/
.globl sun4v_intr_setstate
sun4v_intr_setstate:
mov HV_FAST_INTR_SETSTATE, %o5
ta HV_FAST_TRAP
retl
nop
/* %o0: sysino
*
* returns %o0: cpuid
*/
.globl sun4v_intr_gettarget
sun4v_intr_gettarget:
mov HV_FAST_INTR_GETTARGET, %o5
ta HV_FAST_TRAP
retl
mov %o1, %o0
/* %o0: sysino
* %o1: cpuid
*/
.globl sun4v_intr_settarget
sun4v_intr_settarget:
mov HV_FAST_INTR_SETTARGET, %o5
ta HV_FAST_TRAP
retl
nop
/* %o0: type
* %o1: queue paddr
* %o2: num queue entries
*
* returns %o0: status
*/
.globl sun4v_cpu_qconf
sun4v_cpu_qconf:
mov HV_FAST_CPU_QCONF, %o5
ta HV_FAST_TRAP
retl
nop
/* returns %o0: status
*/
.globl sun4v_cpu_yield
sun4v_cpu_yield:
mov HV_FAST_CPU_YIELD, %o5
ta HV_FAST_TRAP
retl
nop
[SPARC64]: Fix bugs in SUN4V cpu mondo dispatch. There were several bugs in the SUN4V cpu mondo dispatch code. In fact, if we ever got a EWOULDBLOCK or other error from the hypervisor call, we'd potentially send a cpu mondo multiple times to the same cpu and even worse we could loop until the timeout resending the same mondo over and over to such cpus. So let's bulletproof this thing as follows: 1) Implement cpu_mondo_send() and cpu_state() hypervisor calls in arch/sparc64/kernel/entry.S, add prototypes to asm/hypervisor.h 2) Don't build and update the cpulist using inline functions, this was causing the cpu mask to not get updated in the caller. 3) Disable interrupts during the entire mondo send, otherwise our cpu list and/or mondo block could get overwritten if we take an interrupt and do a cpu mondo send on the current cpu. 4) Check for all possible error return types from the cpu_mondo_send() hypervisor call. In particular: HV_EOK) Our work is done, all cpus have received the mondo. HV_CPUERROR) One or more of the cpus in the cpu list we passed to the hypervisor are in error state. Use cpu_state() calls over the entries in the cpu list to see which ones. Record them in "error_mask" and report this after we are done sending the mondo to cpus which are not in error state. HV_EWOULDBLOCK) We need to keep trying. Any other error we consider fatal, we report the event and exit immediately. 5) We only timeout if forward progress is not made. Forward progress is defined as having at least one cpu get the mondo successfully in a given cpu_mondo_send() call. Otherwise we bump a counter and delay a little. If the counter hits a limit, we signal an error and report the event. Also, smp_call_function_mask() error handling reports the number of cpus incorrectly. Signed-off-by: David S. Miller <davem@davemloft.net>
2006-02-28 18:10:26 -05:00
/* %o0: num cpus in cpu list
* %o1: cpu list paddr
* %o2: mondo block paddr
*
* returns %o0: status
*/
.globl sun4v_cpu_mondo_send
sun4v_cpu_mondo_send:
mov HV_FAST_CPU_MONDO_SEND, %o5
ta HV_FAST_TRAP
retl
nop
/* %o0: CPU ID
*
* returns %o0: -status if status non-zero, else
* %o0: cpu state as HV_CPU_STATE_*
*/
.globl sun4v_cpu_state
sun4v_cpu_state:
mov HV_FAST_CPU_STATE, %o5
ta HV_FAST_TRAP
brnz,pn %o0, 1f
sub %g0, %o0, %o0
mov %o1, %o0
1: retl
nop