linux-sg2042/arch/s390/kernel/entry.S

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/*
* S390 low-level entry points.
*
* Copyright IBM Corp. 1999, 2012
* Author(s): Martin Schwidefsky (schwidefsky@de.ibm.com),
* Hartmut Penner (hp@de.ibm.com),
* Denis Joseph Barrow (djbarrow@de.ibm.com,barrow_dj@yahoo.com),
* Heiko Carstens <heiko.carstens@de.ibm.com>
*/
#include <linux/init.h>
#include <linux/linkage.h>
#include <asm/cache.h>
#include <asm/errno.h>
#include <asm/ptrace.h>
#include <asm/thread_info.h>
#include <asm/asm-offsets.h>
#include <asm/unistd.h>
#include <asm/page.h>
#include <asm/sigp.h>
#include <asm/irq.h>
__PT_R0 = __PT_GPRS
__PT_R1 = __PT_GPRS + 4
__PT_R2 = __PT_GPRS + 8
__PT_R3 = __PT_GPRS + 12
__PT_R4 = __PT_GPRS + 16
__PT_R5 = __PT_GPRS + 20
__PT_R6 = __PT_GPRS + 24
__PT_R7 = __PT_GPRS + 28
__PT_R8 = __PT_GPRS + 32
__PT_R9 = __PT_GPRS + 36
__PT_R10 = __PT_GPRS + 40
__PT_R11 = __PT_GPRS + 44
__PT_R12 = __PT_GPRS + 48
__PT_R13 = __PT_GPRS + 524
__PT_R14 = __PT_GPRS + 56
__PT_R15 = __PT_GPRS + 60
_TIF_WORK_SVC = (_TIF_SIGPENDING | _TIF_NOTIFY_RESUME | _TIF_NEED_RESCHED | \
_TIF_MCCK_PENDING | _TIF_PER_TRAP )
_TIF_WORK_INT = (_TIF_SIGPENDING | _TIF_NOTIFY_RESUME | _TIF_NEED_RESCHED | \
_TIF_MCCK_PENDING)
_TIF_TRACE = (_TIF_SYSCALL_TRACE | _TIF_SYSCALL_AUDIT | _TIF_SECCOMP | \
_TIF_SYSCALL_TRACEPOINT)
s390/mm,tlb: race of lazy TLB flush vs. recreation of TLB entries Git commit 050eef364ad70059 "[S390] fix tlb flushing vs. concurrent /proc accesses" introduced the attach counter to avoid using the mm_users value to decide between IPTE for every PTE and lazy TLB flushing with IDTE. That fixed the problem with mm_users but it introduced another subtle race, fortunately one that is very hard to hit. The background is the requirement of the architecture that a valid PTE may not be changed while it can be used concurrently by another cpu. The decision between IPTE and lazy TLB flushing needs to be done while the PTE is still valid. Now if the virtual cpu is temporarily stopped after the decision to use lazy TLB flushing but before the invalid bit of the PTE has been set, another cpu can attach the mm, find that flush_mm is set, do the IDTE, return to userspace, and recreate a TLB that uses the PTE in question. When the first, stopped cpu continues it will change the PTE while it is attached on another cpu. The first cpu will do another IDTE shortly after the modification of the PTE which makes the race window quite short. To fix this race the CPU that wants to attach the address space of a user space thread needs to wait for the end of the PTE modification. The number of concurrent TLB flushers for an mm is tracked in the upper 16 bits of the attach_count and finish_arch_post_lock_switch is used to wait for the end of the flush operation if required. Signed-off-by: Martin Schwidefsky <schwidefsky@de.ibm.com>
2012-09-10 19:00:09 +08:00
_TIF_TRANSFER = (_TIF_MCCK_PENDING | _TIF_TLB_WAIT)
STACK_SHIFT = PAGE_SHIFT + THREAD_ORDER
STACK_SIZE = 1 << STACK_SHIFT
STACK_INIT = STACK_SIZE - STACK_FRAME_OVERHEAD - __PT_SIZE
#define BASED(name) name-system_call(%r13)
.macro TRACE_IRQS_ON
#ifdef CONFIG_TRACE_IRQFLAGS
basr %r2,%r0
l %r1,BASED(.Lhardirqs_on)
basr %r14,%r1 # call trace_hardirqs_on_caller
#endif
.endm
.macro TRACE_IRQS_OFF
#ifdef CONFIG_TRACE_IRQFLAGS
basr %r2,%r0
l %r1,BASED(.Lhardirqs_off)
basr %r14,%r1 # call trace_hardirqs_off_caller
#endif
.endm
.macro LOCKDEP_SYS_EXIT
#ifdef CONFIG_LOCKDEP
tm __PT_PSW+1(%r11),0x01 # returning to user ?
jz .+10
l %r1,BASED(.Llockdep_sys_exit)
basr %r14,%r1 # call lockdep_sys_exit
#endif
.endm
.macro CHECK_STACK stacksize,savearea
#ifdef CONFIG_CHECK_STACK
tml %r15,\stacksize - CONFIG_STACK_GUARD
la %r14,\savearea
jz stack_overflow
#endif
.endm
.macro SWITCH_ASYNC savearea,stack,shift
tmh %r8,0x0001 # interrupting from user ?
jnz 1f
lr %r14,%r9
sl %r14,BASED(.Lcritical_start)
cl %r14,BASED(.Lcritical_length)
jhe 0f
la %r11,\savearea # inside critical section, do cleanup
bras %r14,cleanup_critical
tmh %r8,0x0001 # retest problem state after cleanup
jnz 1f
0: l %r14,\stack # are we already on the target stack?
slr %r14,%r15
sra %r14,\shift
jnz 1f
CHECK_STACK 1<<\shift,\savearea
ahi %r15,-(STACK_FRAME_OVERHEAD + __PT_SIZE)
j 2f
1: l %r15,\stack # load target stack
2: la %r11,STACK_FRAME_OVERHEAD(%r15)
.endm
.macro ADD64 high,low,timer
al \high,\timer
al \low,4+\timer
brc 12,.+8
ahi \high,1
.endm
.macro SUB64 high,low,timer
sl \high,\timer
sl \low,4+\timer
brc 3,.+8
ahi \high,-1
.endm
.macro UPDATE_VTIME high,low,enter_timer
lm \high,\low,__LC_EXIT_TIMER
SUB64 \high,\low,\enter_timer
ADD64 \high,\low,__LC_USER_TIMER
stm \high,\low,__LC_USER_TIMER
lm \high,\low,__LC_LAST_UPDATE_TIMER
SUB64 \high,\low,__LC_EXIT_TIMER
ADD64 \high,\low,__LC_SYSTEM_TIMER
stm \high,\low,__LC_SYSTEM_TIMER
mvc __LC_LAST_UPDATE_TIMER(8),\enter_timer
.endm
.macro REENABLE_IRQS
st %r8,__LC_RETURN_PSW
ni __LC_RETURN_PSW,0xbf
ssm __LC_RETURN_PSW
.endm
.section .kprobes.text, "ax"
/*
* Scheduler resume function, called by switch_to
* gpr2 = (task_struct *) prev
* gpr3 = (task_struct *) next
* Returns:
* gpr2 = prev
*/
ENTRY(__switch_to)
stm %r6,%r15,__SF_GPRS(%r15) # store gprs of prev task
st %r15,__THREAD_ksp(%r2) # store kernel stack of prev
l %r4,__THREAD_info(%r2) # get thread_info of prev
l %r5,__THREAD_info(%r3) # get thread_info of next
lr %r15,%r5
ahi %r15,STACK_INIT # end of kernel stack of next
st %r3,__LC_CURRENT # store task struct of next
st %r5,__LC_THREAD_INFO # store thread info of next
st %r15,__LC_KERNEL_STACK # store end of kernel stack
lctl %c4,%c4,__TASK_pid(%r3) # load pid to control reg. 4
mvc __LC_CURRENT_PID(4,%r0),__TASK_pid(%r3) # store pid of next
l %r15,__THREAD_ksp(%r3) # load kernel stack of next
s390/mm,tlb: race of lazy TLB flush vs. recreation of TLB entries Git commit 050eef364ad70059 "[S390] fix tlb flushing vs. concurrent /proc accesses" introduced the attach counter to avoid using the mm_users value to decide between IPTE for every PTE and lazy TLB flushing with IDTE. That fixed the problem with mm_users but it introduced another subtle race, fortunately one that is very hard to hit. The background is the requirement of the architecture that a valid PTE may not be changed while it can be used concurrently by another cpu. The decision between IPTE and lazy TLB flushing needs to be done while the PTE is still valid. Now if the virtual cpu is temporarily stopped after the decision to use lazy TLB flushing but before the invalid bit of the PTE has been set, another cpu can attach the mm, find that flush_mm is set, do the IDTE, return to userspace, and recreate a TLB that uses the PTE in question. When the first, stopped cpu continues it will change the PTE while it is attached on another cpu. The first cpu will do another IDTE shortly after the modification of the PTE which makes the race window quite short. To fix this race the CPU that wants to attach the address space of a user space thread needs to wait for the end of the PTE modification. The number of concurrent TLB flushers for an mm is tracked in the upper 16 bits of the attach_count and finish_arch_post_lock_switch is used to wait for the end of the flush operation if required. Signed-off-by: Martin Schwidefsky <schwidefsky@de.ibm.com>
2012-09-10 19:00:09 +08:00
lhi %r6,_TIF_TRANSFER # transfer TIF bits
n %r6,__TI_flags(%r4) # isolate TIF bits
jz 0f
s390/mm,tlb: race of lazy TLB flush vs. recreation of TLB entries Git commit 050eef364ad70059 "[S390] fix tlb flushing vs. concurrent /proc accesses" introduced the attach counter to avoid using the mm_users value to decide between IPTE for every PTE and lazy TLB flushing with IDTE. That fixed the problem with mm_users but it introduced another subtle race, fortunately one that is very hard to hit. The background is the requirement of the architecture that a valid PTE may not be changed while it can be used concurrently by another cpu. The decision between IPTE and lazy TLB flushing needs to be done while the PTE is still valid. Now if the virtual cpu is temporarily stopped after the decision to use lazy TLB flushing but before the invalid bit of the PTE has been set, another cpu can attach the mm, find that flush_mm is set, do the IDTE, return to userspace, and recreate a TLB that uses the PTE in question. When the first, stopped cpu continues it will change the PTE while it is attached on another cpu. The first cpu will do another IDTE shortly after the modification of the PTE which makes the race window quite short. To fix this race the CPU that wants to attach the address space of a user space thread needs to wait for the end of the PTE modification. The number of concurrent TLB flushers for an mm is tracked in the upper 16 bits of the attach_count and finish_arch_post_lock_switch is used to wait for the end of the flush operation if required. Signed-off-by: Martin Schwidefsky <schwidefsky@de.ibm.com>
2012-09-10 19:00:09 +08:00
o %r6,__TI_flags(%r5) # set TIF bits of next
st %r6,__TI_flags(%r5)
ni __TI_flags+3(%r4),255-_TIF_TRANSFER # clear TIF bits of prev
0: lm %r6,%r15,__SF_GPRS(%r15) # load gprs of next task
br %r14
__critical_start:
/*
* SVC interrupt handler routine. System calls are synchronous events and
* are executed with interrupts enabled.
*/
ENTRY(system_call)
stpt __LC_SYNC_ENTER_TIMER
sysc_stm:
stm %r8,%r15,__LC_SAVE_AREA_SYNC
l %r12,__LC_THREAD_INFO
l %r13,__LC_SVC_NEW_PSW+4
sysc_per:
l %r15,__LC_KERNEL_STACK
la %r11,STACK_FRAME_OVERHEAD(%r15) # pointer to pt_regs
sysc_vtime:
UPDATE_VTIME %r8,%r9,__LC_SYNC_ENTER_TIMER
stm %r0,%r7,__PT_R0(%r11)
mvc __PT_R8(32,%r11),__LC_SAVE_AREA_SYNC
mvc __PT_PSW(8,%r11),__LC_SVC_OLD_PSW
mvc __PT_INT_CODE(4,%r11),__LC_SVC_ILC
sysc_do_svc:
oi __TI_flags+3(%r12),_TIF_SYSCALL
l %r10,__TI_sysc_table(%r12) # 31 bit system call table
lh %r8,__PT_INT_CODE+2(%r11)
sla %r8,2 # shift and test for svc0
jnz sysc_nr_ok
# svc 0: system call number in %r1
cl %r1,BASED(.Lnr_syscalls)
jnl sysc_nr_ok
sth %r1,__PT_INT_CODE+2(%r11)
lr %r8,%r1
sla %r8,2
sysc_nr_ok:
xc __SF_BACKCHAIN(4,%r15),__SF_BACKCHAIN(%r15)
st %r2,__PT_ORIG_GPR2(%r11)
st %r7,STACK_FRAME_OVERHEAD(%r15)
l %r9,0(%r8,%r10) # get system call addr.
tm __TI_flags+2(%r12),_TIF_TRACE >> 8
jnz sysc_tracesys
basr %r14,%r9 # call sys_xxxx
st %r2,__PT_R2(%r11) # store return value
sysc_return:
LOCKDEP_SYS_EXIT
sysc_tif:
tm __PT_PSW+1(%r11),0x01 # returning to user ?
jno sysc_restore
tm __TI_flags+3(%r12),_TIF_WORK_SVC
jnz sysc_work # check for work
ni __TI_flags+3(%r12),255-_TIF_SYSCALL
sysc_restore:
mvc __LC_RETURN_PSW(8),__PT_PSW(%r11)
stpt __LC_EXIT_TIMER
lm %r0,%r15,__PT_R0(%r11)
lpsw __LC_RETURN_PSW
sysc_done:
#
# One of the work bits is on. Find out which one.
#
sysc_work:
tm __TI_flags+3(%r12),_TIF_MCCK_PENDING
jo sysc_mcck_pending
tm __TI_flags+3(%r12),_TIF_NEED_RESCHED
jo sysc_reschedule
tm __TI_flags+3(%r12),_TIF_PER_TRAP
jo sysc_singlestep
tm __TI_flags+3(%r12),_TIF_SIGPENDING
jo sysc_sigpending
tm __TI_flags+3(%r12),_TIF_NOTIFY_RESUME
jo sysc_notify_resume
j sysc_return # beware of critical section cleanup
#
# _TIF_NEED_RESCHED is set, call schedule
#
sysc_reschedule:
l %r1,BASED(.Lschedule)
la %r14,BASED(sysc_return)
br %r1 # call schedule
#
# _TIF_MCCK_PENDING is set, call handler
#
sysc_mcck_pending:
l %r1,BASED(.Lhandle_mcck)
la %r14,BASED(sysc_return)
br %r1 # TIF bit will be cleared by handler
#
# _TIF_SIGPENDING is set, call do_signal
#
sysc_sigpending:
lr %r2,%r11 # pass pointer to pt_regs
l %r1,BASED(.Ldo_signal)
basr %r14,%r1 # call do_signal
tm __TI_flags+3(%r12),_TIF_SYSCALL
jno sysc_return
lm %r2,%r7,__PT_R2(%r11) # load svc arguments
l %r10,__TI_sysc_table(%r12) # 31 bit system call table
xr %r8,%r8 # svc 0 returns -ENOSYS
clc __PT_INT_CODE+2(2,%r11),BASED(.Lnr_syscalls+2)
jnl sysc_nr_ok # invalid svc number -> do svc 0
lh %r8,__PT_INT_CODE+2(%r11) # load new svc number
sla %r8,2
j sysc_nr_ok # restart svc
#
# _TIF_NOTIFY_RESUME is set, call do_notify_resume
#
sysc_notify_resume:
lr %r2,%r11 # pass pointer to pt_regs
l %r1,BASED(.Ldo_notify_resume)
la %r14,BASED(sysc_return)
br %r1 # call do_notify_resume
#
# _TIF_PER_TRAP is set, call do_per_trap
#
sysc_singlestep:
ni __TI_flags+3(%r12),255-_TIF_PER_TRAP
lr %r2,%r11 # pass pointer to pt_regs
l %r1,BASED(.Ldo_per_trap)
la %r14,BASED(sysc_return)
br %r1 # call do_per_trap
#
# call tracehook_report_syscall_entry/tracehook_report_syscall_exit before
# and after the system call
#
sysc_tracesys:
l %r1,BASED(.Ltrace_enter)
lr %r2,%r11 # pass pointer to pt_regs
la %r3,0
xr %r0,%r0
icm %r0,3,__PT_INT_CODE+2(%r11)
st %r0,__PT_R2(%r11)
basr %r14,%r1 # call do_syscall_trace_enter
cl %r2,BASED(.Lnr_syscalls)
jnl sysc_tracenogo
lr %r8,%r2
sll %r8,2
l %r9,0(%r8,%r10)
sysc_tracego:
lm %r3,%r7,__PT_R3(%r11)
st %r7,STACK_FRAME_OVERHEAD(%r15)
l %r2,__PT_ORIG_GPR2(%r11)
basr %r14,%r9 # call sys_xxx
st %r2,__PT_R2(%r11) # store return value
sysc_tracenogo:
tm __TI_flags+2(%r12),_TIF_TRACE >> 8
jz sysc_return
l %r1,BASED(.Ltrace_exit)
lr %r2,%r11 # pass pointer to pt_regs
la %r14,BASED(sysc_return)
br %r1 # call do_syscall_trace_exit
#
# a new process exits the kernel with ret_from_fork
#
ENTRY(ret_from_fork)
la %r11,STACK_FRAME_OVERHEAD(%r15)
l %r12,__LC_THREAD_INFO
l %r13,__LC_SVC_NEW_PSW+4
l %r1,BASED(.Lschedule_tail)
basr %r14,%r1 # call schedule_tail
TRACE_IRQS_ON
ssm __LC_SVC_NEW_PSW # reenable interrupts
tm __PT_PSW+1(%r11),0x01 # forking a kernel thread ?
jne sysc_tracenogo
# it's a kernel thread
lm %r9,%r10,__PT_R9(%r11) # load gprs
ENTRY(kernel_thread_starter)
la %r2,0(%r10)
basr %r14,%r9
j sysc_tracenogo
/*
* Program check handler routine
*/
ENTRY(pgm_check_handler)
stpt __LC_SYNC_ENTER_TIMER
stm %r8,%r15,__LC_SAVE_AREA_SYNC
l %r12,__LC_THREAD_INFO
l %r13,__LC_SVC_NEW_PSW+4
lm %r8,%r9,__LC_PGM_OLD_PSW
tmh %r8,0x0001 # test problem state bit
jnz 1f # -> fault in user space
tmh %r8,0x4000 # PER bit set in old PSW ?
jnz 0f # -> enabled, can't be a double fault
tm __LC_PGM_ILC+3,0x80 # check for per exception
jnz pgm_svcper # -> single stepped svc
0: CHECK_STACK STACK_SIZE,__LC_SAVE_AREA_SYNC
ahi %r15,-(STACK_FRAME_OVERHEAD + __PT_SIZE)
j 2f
1: UPDATE_VTIME %r14,%r15,__LC_SYNC_ENTER_TIMER
l %r15,__LC_KERNEL_STACK
2: la %r11,STACK_FRAME_OVERHEAD(%r15)
stm %r0,%r7,__PT_R0(%r11)
mvc __PT_R8(32,%r11),__LC_SAVE_AREA_SYNC
stm %r8,%r9,__PT_PSW(%r11)
mvc __PT_INT_CODE(4,%r11),__LC_PGM_ILC
mvc __PT_INT_PARM_LONG(4,%r11),__LC_TRANS_EXC_CODE
tm __LC_PGM_ILC+3,0x80 # check for per exception
jz 0f
l %r1,__TI_task(%r12)
tmh %r8,0x0001 # kernel per event ?
jz pgm_kprobe
oi __TI_flags+3(%r12),_TIF_PER_TRAP
mvc __THREAD_per_address(4,%r1),__LC_PER_ADDRESS
mvc __THREAD_per_cause(2,%r1),__LC_PER_CAUSE
mvc __THREAD_per_paid(1,%r1),__LC_PER_PAID
0: REENABLE_IRQS
xc __SF_BACKCHAIN(4,%r15),__SF_BACKCHAIN(%r15)
l %r1,BASED(.Ljump_table)
la %r10,0x7f
n %r10,__PT_INT_CODE(%r11)
je sysc_return
sll %r10,2
l %r1,0(%r10,%r1) # load address of handler routine
lr %r2,%r11 # pass pointer to pt_regs
basr %r14,%r1 # branch to interrupt-handler
j sysc_return
#
# PER event in supervisor state, must be kprobes
#
pgm_kprobe:
REENABLE_IRQS
xc __SF_BACKCHAIN(4,%r15),__SF_BACKCHAIN(%r15)
l %r1,BASED(.Ldo_per_trap)
lr %r2,%r11 # pass pointer to pt_regs
basr %r14,%r1 # call do_per_trap
j sysc_return
#
# single stepped system call
#
pgm_svcper:
oi __TI_flags+3(%r12),_TIF_PER_TRAP
mvc __LC_RETURN_PSW(4),__LC_SVC_NEW_PSW
mvc __LC_RETURN_PSW+4(4),BASED(.Lsysc_per)
lpsw __LC_RETURN_PSW # branch to sysc_per and enable irqs
/*
* IO interrupt handler routine
*/
ENTRY(io_int_handler)
stck __LC_INT_CLOCK
stpt __LC_ASYNC_ENTER_TIMER
stm %r8,%r15,__LC_SAVE_AREA_ASYNC
l %r12,__LC_THREAD_INFO
l %r13,__LC_SVC_NEW_PSW+4
lm %r8,%r9,__LC_IO_OLD_PSW
tmh %r8,0x0001 # interrupting from user ?
jz io_skip
UPDATE_VTIME %r14,%r15,__LC_ASYNC_ENTER_TIMER
io_skip:
SWITCH_ASYNC __LC_SAVE_AREA_ASYNC,__LC_ASYNC_STACK,STACK_SHIFT
stm %r0,%r7,__PT_R0(%r11)
mvc __PT_R8(32,%r11),__LC_SAVE_AREA_ASYNC
stm %r8,%r9,__PT_PSW(%r11)
mvc __PT_INT_CODE(12,%r11),__LC_SUBCHANNEL_ID
TRACE_IRQS_OFF
xc __SF_BACKCHAIN(4,%r15),__SF_BACKCHAIN(%r15)
io_loop:
l %r1,BASED(.Ldo_IRQ)
lr %r2,%r11 # pass pointer to pt_regs
lhi %r3,IO_INTERRUPT
tm __PT_INT_CODE+8(%r11),0x80 # adapter interrupt ?
jz io_call
lhi %r3,THIN_INTERRUPT
io_call:
basr %r14,%r1 # call do_IRQ
tm __LC_MACHINE_FLAGS+2,0x10 # MACHINE_FLAG_LPAR
jz io_return
tpi 0
jz io_return
mvc __PT_INT_CODE(12,%r11),__LC_SUBCHANNEL_ID
j io_loop
io_return:
LOCKDEP_SYS_EXIT
TRACE_IRQS_ON
io_tif:
tm __TI_flags+3(%r12),_TIF_WORK_INT
jnz io_work # there is work to do (signals etc.)
io_restore:
mvc __LC_RETURN_PSW(8),__PT_PSW(%r11)
stpt __LC_EXIT_TIMER
lm %r0,%r15,__PT_R0(%r11)
lpsw __LC_RETURN_PSW
io_done:
#
# There is work todo, find out in which context we have been interrupted:
# 1) if we return to user space we can do all _TIF_WORK_INT work
# 2) if we return to kernel code and preemptive scheduling is enabled check
# the preemption counter and if it is zero call preempt_schedule_irq
# Before any work can be done, a switch to the kernel stack is required.
#
io_work:
tm __PT_PSW+1(%r11),0x01 # returning to user ?
jo io_work_user # yes -> do resched & signal
#ifdef CONFIG_PREEMPT
# check for preemptive scheduling
icm %r0,15,__TI_precount(%r12)
jnz io_restore # preemption disabled
tm __TI_flags+3(%r12),_TIF_NEED_RESCHED
jno io_restore
# switch to kernel stack
l %r1,__PT_R15(%r11)
ahi %r1,-(STACK_FRAME_OVERHEAD + __PT_SIZE)
mvc STACK_FRAME_OVERHEAD(__PT_SIZE,%r1),0(%r11)
xc __SF_BACKCHAIN(4,%r1),__SF_BACKCHAIN(%r1)
la %r11,STACK_FRAME_OVERHEAD(%r1)
lr %r15,%r1
# TRACE_IRQS_ON already done at io_return, call
# TRACE_IRQS_OFF to keep things symmetrical
TRACE_IRQS_OFF
l %r1,BASED(.Lpreempt_irq)
basr %r14,%r1 # call preempt_schedule_irq
j io_return
#else
j io_restore
#endif
#
# Need to do work before returning to userspace, switch to kernel stack
#
io_work_user:
l %r1,__LC_KERNEL_STACK
mvc STACK_FRAME_OVERHEAD(__PT_SIZE,%r1),0(%r11)
xc __SF_BACKCHAIN(4,%r1),__SF_BACKCHAIN(%r1)
la %r11,STACK_FRAME_OVERHEAD(%r1)
lr %r15,%r1
#
# One of the work bits is on. Find out which one.
# Checked are: _TIF_SIGPENDING, _TIF_NOTIFY_RESUME, _TIF_NEED_RESCHED
# and _TIF_MCCK_PENDING
#
io_work_tif:
tm __TI_flags+3(%r12),_TIF_MCCK_PENDING
jo io_mcck_pending
tm __TI_flags+3(%r12),_TIF_NEED_RESCHED
jo io_reschedule
tm __TI_flags+3(%r12),_TIF_SIGPENDING
jo io_sigpending
tm __TI_flags+3(%r12),_TIF_NOTIFY_RESUME
jo io_notify_resume
j io_return # beware of critical section cleanup
#
# _TIF_MCCK_PENDING is set, call handler
#
io_mcck_pending:
# TRACE_IRQS_ON already done at io_return
l %r1,BASED(.Lhandle_mcck)
basr %r14,%r1 # TIF bit will be cleared by handler
TRACE_IRQS_OFF
j io_return
#
# _TIF_NEED_RESCHED is set, call schedule
#
io_reschedule:
# TRACE_IRQS_ON already done at io_return
l %r1,BASED(.Lschedule)
ssm __LC_SVC_NEW_PSW # reenable interrupts
basr %r14,%r1 # call scheduler
ssm __LC_PGM_NEW_PSW # disable I/O and ext. interrupts
TRACE_IRQS_OFF
j io_return
#
# _TIF_SIGPENDING is set, call do_signal
#
io_sigpending:
# TRACE_IRQS_ON already done at io_return
l %r1,BASED(.Ldo_signal)
ssm __LC_SVC_NEW_PSW # reenable interrupts
lr %r2,%r11 # pass pointer to pt_regs
basr %r14,%r1 # call do_signal
ssm __LC_PGM_NEW_PSW # disable I/O and ext. interrupts
TRACE_IRQS_OFF
j io_return
#
# _TIF_SIGPENDING is set, call do_signal
#
io_notify_resume:
# TRACE_IRQS_ON already done at io_return
l %r1,BASED(.Ldo_notify_resume)
ssm __LC_SVC_NEW_PSW # reenable interrupts
lr %r2,%r11 # pass pointer to pt_regs
basr %r14,%r1 # call do_notify_resume
ssm __LC_PGM_NEW_PSW # disable I/O and ext. interrupts
TRACE_IRQS_OFF
j io_return
/*
* External interrupt handler routine
*/
ENTRY(ext_int_handler)
stck __LC_INT_CLOCK
stpt __LC_ASYNC_ENTER_TIMER
stm %r8,%r15,__LC_SAVE_AREA_ASYNC
l %r12,__LC_THREAD_INFO
l %r13,__LC_SVC_NEW_PSW+4
lm %r8,%r9,__LC_EXT_OLD_PSW
tmh %r8,0x0001 # interrupting from user ?
jz ext_skip
UPDATE_VTIME %r14,%r15,__LC_ASYNC_ENTER_TIMER
ext_skip:
SWITCH_ASYNC __LC_SAVE_AREA_ASYNC,__LC_ASYNC_STACK,STACK_SHIFT
stm %r0,%r7,__PT_R0(%r11)
mvc __PT_R8(32,%r11),__LC_SAVE_AREA_ASYNC
stm %r8,%r9,__PT_PSW(%r11)
mvc __PT_INT_CODE(4,%r11),__LC_EXT_CPU_ADDR
mvc __PT_INT_PARM(4,%r11),__LC_EXT_PARAMS
TRACE_IRQS_OFF
l %r1,BASED(.Ldo_IRQ)
lr %r2,%r11 # pass pointer to pt_regs
lhi %r3,EXT_INTERRUPT
basr %r14,%r1 # call do_IRQ
j io_return
/*
* Load idle PSW. The second "half" of this function is in cleanup_idle.
*/
ENTRY(psw_idle)
st %r3,__SF_EMPTY(%r15)
basr %r1,0
la %r1,psw_idle_lpsw+4-.(%r1)
st %r1,__SF_EMPTY+4(%r15)
oi __SF_EMPTY+4(%r15),0x80
stck __CLOCK_IDLE_ENTER(%r2)
stpt __TIMER_IDLE_ENTER(%r2)
psw_idle_lpsw:
lpsw __SF_EMPTY(%r15)
br %r14
psw_idle_end:
__critical_end:
/*
* Machine check handler routines
*/
ENTRY(mcck_int_handler)
stck __LC_MCCK_CLOCK
spt __LC_CPU_TIMER_SAVE_AREA # revalidate cpu timer
lm %r0,%r15,__LC_GPREGS_SAVE_AREA # revalidate gprs
l %r12,__LC_THREAD_INFO
l %r13,__LC_SVC_NEW_PSW+4
lm %r8,%r9,__LC_MCK_OLD_PSW
tm __LC_MCCK_CODE,0x80 # system damage?
jo mcck_panic # yes -> rest of mcck code invalid
la %r14,__LC_CPU_TIMER_SAVE_AREA
mvc __LC_MCCK_ENTER_TIMER(8),0(%r14)
tm __LC_MCCK_CODE+5,0x02 # stored cpu timer value valid?
jo 3f
la %r14,__LC_SYNC_ENTER_TIMER
clc 0(8,%r14),__LC_ASYNC_ENTER_TIMER
jl 0f
la %r14,__LC_ASYNC_ENTER_TIMER
0: clc 0(8,%r14),__LC_EXIT_TIMER
jl 1f
la %r14,__LC_EXIT_TIMER
1: clc 0(8,%r14),__LC_LAST_UPDATE_TIMER
jl 2f
la %r14,__LC_LAST_UPDATE_TIMER
2: spt 0(%r14)
mvc __LC_MCCK_ENTER_TIMER(8),0(%r14)
3: tm __LC_MCCK_CODE+2,0x09 # mwp + ia of old psw valid?
jno mcck_panic # no -> skip cleanup critical
tm %r8,0x0001 # interrupting from user ?
jz mcck_skip
UPDATE_VTIME %r14,%r15,__LC_MCCK_ENTER_TIMER
mcck_skip:
SWITCH_ASYNC __LC_GPREGS_SAVE_AREA+32,__LC_PANIC_STACK,PAGE_SHIFT
stm %r0,%r7,__PT_R0(%r11)
mvc __PT_R8(32,%r11),__LC_GPREGS_SAVE_AREA+32
stm %r8,%r9,__PT_PSW(%r11)
xc __SF_BACKCHAIN(4,%r15),__SF_BACKCHAIN(%r15)
l %r1,BASED(.Ldo_machine_check)
lr %r2,%r11 # pass pointer to pt_regs
basr %r14,%r1 # call s390_do_machine_check
tm __PT_PSW+1(%r11),0x01 # returning to user ?
jno mcck_return
l %r1,__LC_KERNEL_STACK # switch to kernel stack
mvc STACK_FRAME_OVERHEAD(__PT_SIZE,%r1),0(%r11)
xc __SF_BACKCHAIN(4,%r1),__SF_BACKCHAIN(%r1)
la %r11,STACK_FRAME_OVERHEAD(%r15)
lr %r15,%r1
ssm __LC_PGM_NEW_PSW # turn dat on, keep irqs off
tm __TI_flags+3(%r12),_TIF_MCCK_PENDING
jno mcck_return
TRACE_IRQS_OFF
l %r1,BASED(.Lhandle_mcck)
basr %r14,%r1 # call s390_handle_mcck
TRACE_IRQS_ON
mcck_return:
mvc __LC_RETURN_MCCK_PSW(8),__PT_PSW(%r11) # move return PSW
tm __LC_RETURN_MCCK_PSW+1,0x01 # returning to user ?
jno 0f
lm %r0,%r15,__PT_R0(%r11)
stpt __LC_EXIT_TIMER
lpsw __LC_RETURN_MCCK_PSW
0: lm %r0,%r15,__PT_R0(%r11)
lpsw __LC_RETURN_MCCK_PSW
mcck_panic:
l %r14,__LC_PANIC_STACK
slr %r14,%r15
sra %r14,PAGE_SHIFT
jz 0f
l %r15,__LC_PANIC_STACK
j mcck_skip
0: ahi %r15,-(STACK_FRAME_OVERHEAD + __PT_SIZE)
j mcck_skip
#
# PSW restart interrupt handler
#
ENTRY(restart_int_handler)
st %r15,__LC_SAVE_AREA_RESTART
l %r15,__LC_RESTART_STACK
ahi %r15,-__PT_SIZE # create pt_regs on stack
xc 0(__PT_SIZE,%r15),0(%r15)
stm %r0,%r14,__PT_R0(%r15)
mvc __PT_R15(4,%r15),__LC_SAVE_AREA_RESTART
mvc __PT_PSW(8,%r15),__LC_RST_OLD_PSW # store restart old psw
ahi %r15,-STACK_FRAME_OVERHEAD # create stack frame on stack
xc 0(STACK_FRAME_OVERHEAD,%r15),0(%r15)
l %r1,__LC_RESTART_FN # load fn, parm & source cpu
l %r2,__LC_RESTART_DATA
l %r3,__LC_RESTART_SOURCE
ltr %r3,%r3 # test source cpu address
jm 1f # negative -> skip source stop
0: sigp %r4,%r3,SIGP_SENSE # sigp sense to source cpu
brc 10,0b # wait for status stored
1: basr %r14,%r1 # call function
stap __SF_EMPTY(%r15) # store cpu address
lh %r3,__SF_EMPTY(%r15)
2: sigp %r4,%r3,SIGP_STOP # sigp stop to current cpu
brc 2,2b
3: j 3b
.section .kprobes.text, "ax"
#ifdef CONFIG_CHECK_STACK
/*
* The synchronous or the asynchronous stack overflowed. We are dead.
* No need to properly save the registers, we are going to panic anyway.
* Setup a pt_regs so that show_trace can provide a good call trace.
*/
stack_overflow:
l %r15,__LC_PANIC_STACK # change to panic stack
la %r11,STACK_FRAME_OVERHEAD(%r15)
stm %r0,%r7,__PT_R0(%r11)
stm %r8,%r9,__PT_PSW(%r11)
mvc __PT_R8(32,%r11),0(%r14)
l %r1,BASED(1f)
xc __SF_BACKCHAIN(4,%r15),__SF_BACKCHAIN(%r15)
lr %r2,%r11 # pass pointer to pt_regs
br %r1 # branch to kernel_stack_overflow
1: .long kernel_stack_overflow
#endif
cleanup_table:
.long system_call + 0x80000000
.long sysc_do_svc + 0x80000000
.long sysc_tif + 0x80000000
.long sysc_restore + 0x80000000
.long sysc_done + 0x80000000
.long io_tif + 0x80000000
.long io_restore + 0x80000000
.long io_done + 0x80000000
.long psw_idle + 0x80000000
.long psw_idle_end + 0x80000000
cleanup_critical:
cl %r9,BASED(cleanup_table) # system_call
jl 0f
cl %r9,BASED(cleanup_table+4) # sysc_do_svc
jl cleanup_system_call
cl %r9,BASED(cleanup_table+8) # sysc_tif
jl 0f
cl %r9,BASED(cleanup_table+12) # sysc_restore
jl cleanup_sysc_tif
cl %r9,BASED(cleanup_table+16) # sysc_done
jl cleanup_sysc_restore
cl %r9,BASED(cleanup_table+20) # io_tif
jl 0f
cl %r9,BASED(cleanup_table+24) # io_restore
jl cleanup_io_tif
cl %r9,BASED(cleanup_table+28) # io_done
jl cleanup_io_restore
cl %r9,BASED(cleanup_table+32) # psw_idle
jl 0f
cl %r9,BASED(cleanup_table+36) # psw_idle_end
jl cleanup_idle
0: br %r14
cleanup_system_call:
# check if stpt has been executed
cl %r9,BASED(cleanup_system_call_insn)
jh 0f
mvc __LC_SYNC_ENTER_TIMER(8),__LC_ASYNC_ENTER_TIMER
chi %r11,__LC_SAVE_AREA_ASYNC
je 0f
mvc __LC_SYNC_ENTER_TIMER(8),__LC_MCCK_ENTER_TIMER
0: # check if stm has been executed
cl %r9,BASED(cleanup_system_call_insn+4)
jh 0f
mvc __LC_SAVE_AREA_SYNC(32),0(%r11)
0: # set up saved registers r12, and r13
st %r12,16(%r11) # r12 thread-info pointer
st %r13,20(%r11) # r13 literal-pool pointer
# check if the user time calculation has been done
cl %r9,BASED(cleanup_system_call_insn+8)
jh 0f
l %r10,__LC_EXIT_TIMER
l %r15,__LC_EXIT_TIMER+4
SUB64 %r10,%r15,__LC_SYNC_ENTER_TIMER
ADD64 %r10,%r15,__LC_USER_TIMER
st %r10,__LC_USER_TIMER
st %r15,__LC_USER_TIMER+4
0: # check if the system time calculation has been done
cl %r9,BASED(cleanup_system_call_insn+12)
jh 0f
l %r10,__LC_LAST_UPDATE_TIMER
l %r15,__LC_LAST_UPDATE_TIMER+4
SUB64 %r10,%r15,__LC_EXIT_TIMER
ADD64 %r10,%r15,__LC_SYSTEM_TIMER
st %r10,__LC_SYSTEM_TIMER
st %r15,__LC_SYSTEM_TIMER+4
0: # update accounting time stamp
mvc __LC_LAST_UPDATE_TIMER(8),__LC_SYNC_ENTER_TIMER
# set up saved register 11
l %r15,__LC_KERNEL_STACK
la %r9,STACK_FRAME_OVERHEAD(%r15)
st %r9,12(%r11) # r11 pt_regs pointer
# fill pt_regs
mvc __PT_R8(32,%r9),__LC_SAVE_AREA_SYNC
stm %r0,%r7,__PT_R0(%r9)
mvc __PT_PSW(8,%r9),__LC_SVC_OLD_PSW
mvc __PT_INT_CODE(4,%r9),__LC_SVC_ILC
# setup saved register 15
st %r15,28(%r11) # r15 stack pointer
# set new psw address and exit
l %r9,BASED(cleanup_table+4) # sysc_do_svc + 0x80000000
br %r14
cleanup_system_call_insn:
.long system_call + 0x80000000
.long sysc_stm + 0x80000000
.long sysc_vtime + 0x80000000 + 36
.long sysc_vtime + 0x80000000 + 76
cleanup_sysc_tif:
l %r9,BASED(cleanup_table+8) # sysc_tif + 0x80000000
br %r14
cleanup_sysc_restore:
cl %r9,BASED(cleanup_sysc_restore_insn)
jhe 0f
l %r9,12(%r11) # get saved pointer to pt_regs
mvc __LC_RETURN_PSW(8),__PT_PSW(%r9)
mvc 0(32,%r11),__PT_R8(%r9)
lm %r0,%r7,__PT_R0(%r9)
0: lm %r8,%r9,__LC_RETURN_PSW
br %r14
cleanup_sysc_restore_insn:
.long sysc_done - 4 + 0x80000000
cleanup_io_tif:
l %r9,BASED(cleanup_table+20) # io_tif + 0x80000000
br %r14
cleanup_io_restore:
cl %r9,BASED(cleanup_io_restore_insn)
jhe 0f
l %r9,12(%r11) # get saved r11 pointer to pt_regs
mvc __LC_RETURN_PSW(8),__PT_PSW(%r9)
mvc 0(32,%r11),__PT_R8(%r9)
lm %r0,%r7,__PT_R0(%r9)
0: lm %r8,%r9,__LC_RETURN_PSW
br %r14
cleanup_io_restore_insn:
.long io_done - 4 + 0x80000000
cleanup_idle:
# copy interrupt clock & cpu timer
mvc __CLOCK_IDLE_EXIT(8,%r2),__LC_INT_CLOCK
mvc __TIMER_IDLE_EXIT(8,%r2),__LC_ASYNC_ENTER_TIMER
chi %r11,__LC_SAVE_AREA_ASYNC
je 0f
mvc __CLOCK_IDLE_EXIT(8,%r2),__LC_MCCK_CLOCK
mvc __TIMER_IDLE_EXIT(8,%r2),__LC_MCCK_ENTER_TIMER
0: # check if stck has been executed
cl %r9,BASED(cleanup_idle_insn)
jhe 1f
mvc __CLOCK_IDLE_ENTER(8,%r2),__CLOCK_IDLE_EXIT(%r2)
mvc __TIMER_IDLE_ENTER(8,%r2),__TIMER_IDLE_EXIT(%r3)
1: # account system time going idle
lm %r9,%r10,__LC_STEAL_TIMER
ADD64 %r9,%r10,__CLOCK_IDLE_ENTER(%r2)
SUB64 %r9,%r10,__LC_LAST_UPDATE_CLOCK
stm %r9,%r10,__LC_STEAL_TIMER
mvc __LC_LAST_UPDATE_CLOCK(8),__CLOCK_IDLE_EXIT(%r2)
lm %r9,%r10,__LC_SYSTEM_TIMER
ADD64 %r9,%r10,__LC_LAST_UPDATE_TIMER
SUB64 %r9,%r10,__TIMER_IDLE_ENTER(%r2)
stm %r9,%r10,__LC_SYSTEM_TIMER
mvc __LC_LAST_UPDATE_TIMER(8),__TIMER_IDLE_EXIT(%r2)
# prepare return psw
n %r8,BASED(cleanup_idle_wait) # clear irq & wait state bits
l %r9,24(%r11) # return from psw_idle
br %r14
cleanup_idle_insn:
.long psw_idle_lpsw + 0x80000000
cleanup_idle_wait:
.long 0xfcfdffff
/*
* Integer constants
*/
.align 4
.Lnr_syscalls:
.long NR_syscalls
.Lvtimer_max:
.quad 0x7fffffffffffffff
/*
* Symbol constants
*/
.Ldo_machine_check: .long s390_do_machine_check
.Lhandle_mcck: .long s390_handle_mcck
.Ldo_IRQ: .long do_IRQ
.Ldo_signal: .long do_signal
.Ldo_notify_resume: .long do_notify_resume
.Ldo_per_trap: .long do_per_trap
.Ljump_table: .long pgm_check_table
.Lschedule: .long schedule
#ifdef CONFIG_PREEMPT
.Lpreempt_irq: .long preempt_schedule_irq
#endif
.Ltrace_enter: .long do_syscall_trace_enter
.Ltrace_exit: .long do_syscall_trace_exit
.Lschedule_tail: .long schedule_tail
.Lsysc_per: .long sysc_per + 0x80000000
#ifdef CONFIG_TRACE_IRQFLAGS
.Lhardirqs_on: .long trace_hardirqs_on_caller
.Lhardirqs_off: .long trace_hardirqs_off_caller
#endif
#ifdef CONFIG_LOCKDEP
.Llockdep_sys_exit: .long lockdep_sys_exit
#endif
.Lcritical_start: .long __critical_start + 0x80000000
.Lcritical_length: .long __critical_end - __critical_start
.section .rodata, "a"
#define SYSCALL(esa,esame,emu) .long esa
.globl sys_call_table
sys_call_table:
#include "syscalls.S"
#undef SYSCALL