1
linux/arch/ia64/kernel/mca.c
Russ Anderson 1612b18ccb [IA64] Support multiple CPUs going through OS_MCA
Linux does not gracefully deal with multiple processors going
through OS_MCA aa part of the same MCA event.  The first cpu
into OS_MCA grabs the ia64_mca_serialize lock.  Subsequent
cpus wait for that lock, preventing them from reporting in as
rendezvoused.  The first cpu waits 5 seconds then complains
that all the cpus have not rendezvoused.  The first cpu then
handles its MCA and frees up all the rendezvoused cpus and
releases the ia64_mca_serialize lock.  One of the subsequent
cpus going thought OS_MCA then gets the ia64_mca_serialize
lock, waits another 5 seconds and then complains that none of
the other cpus have rendezvoused.

This patch allows multiple CPUs to gracefully go through OS_MCA.

The first CPU into ia64_mca_handler() grabs a mca_count lock.
Subsequent CPUs into ia64_mca_handler() are added to a list of cpus
that need to go through OS_MCA (a bit set in mca_cpu), and report
in as rendezvoused, and but spin waiting their turn.

The first CPU sees everyone rendezvous, handles his MCA, wakes up
one of the other CPUs waiting to process their MCA (by clearing
one mca_cpu bit), and then waits for the other cpus to complete
their MCA handling.  The next CPU handles his MCA and the process
repeats until all the CPUs have handled their MCA.  When the last
CPU has handled it's MCA, it sets monarch_cpu to -1, releasing all
the CPUs.

In testing this works more reliably and faster.

Thanks to Keith Owens for suggesting numerous improvements
to this code.

Signed-off-by: Russ Anderson <rja@sgi.com>
Signed-off-by: Tony Luck <tony.luck@intel.com>
2007-07-11 11:50:11 -07:00

2040 lines
59 KiB
C

/*
* File: mca.c
* Purpose: Generic MCA handling layer
*
* Updated for latest kernel
* Copyright (C) 2003 Hewlett-Packard Co
* David Mosberger-Tang <davidm@hpl.hp.com>
*
* Copyright (C) 2002 Dell Inc.
* Copyright (C) Matt Domsch (Matt_Domsch@dell.com)
*
* Copyright (C) 2002 Intel
* Copyright (C) Jenna Hall (jenna.s.hall@intel.com)
*
* Copyright (C) 2001 Intel
* Copyright (C) Fred Lewis (frederick.v.lewis@intel.com)
*
* Copyright (C) 2000 Intel
* Copyright (C) Chuck Fleckenstein (cfleck@co.intel.com)
*
* Copyright (C) 1999, 2004 Silicon Graphics, Inc.
* Copyright (C) Vijay Chander(vijay@engr.sgi.com)
*
* 03/04/15 D. Mosberger Added INIT backtrace support.
* 02/03/25 M. Domsch GUID cleanups
*
* 02/01/04 J. Hall Aligned MCA stack to 16 bytes, added platform vs. CPU
* error flag, set SAL default return values, changed
* error record structure to linked list, added init call
* to sal_get_state_info_size().
*
* 01/01/03 F. Lewis Added setup of CMCI and CPEI IRQs, logging of corrected
* platform errors, completed code for logging of
* corrected & uncorrected machine check errors, and
* updated for conformance with Nov. 2000 revision of the
* SAL 3.0 spec.
* 00/03/29 C. Fleckenstein Fixed PAL/SAL update issues, began MCA bug fixes, logging issues,
* added min save state dump, added INIT handler.
*
* 2003-12-08 Keith Owens <kaos@sgi.com>
* smp_call_function() must not be called from interrupt context (can
* deadlock on tasklist_lock). Use keventd to call smp_call_function().
*
* 2004-02-01 Keith Owens <kaos@sgi.com>
* Avoid deadlock when using printk() for MCA and INIT records.
* Delete all record printing code, moved to salinfo_decode in user space.
* Mark variables and functions static where possible.
* Delete dead variables and functions.
* Reorder to remove the need for forward declarations and to consolidate
* related code.
*
* 2005-08-12 Keith Owens <kaos@sgi.com>
* Convert MCA/INIT handlers to use per event stacks and SAL/OS state.
*
* 2005-10-07 Keith Owens <kaos@sgi.com>
* Add notify_die() hooks.
*
* 2006-09-15 Hidetoshi Seto <seto.hidetoshi@jp.fujitsu.com>
* Add printing support for MCA/INIT.
*
* 2007-04-27 Russ Anderson <rja@sgi.com>
* Support multiple cpus going through OS_MCA in the same event.
*/
#include <linux/types.h>
#include <linux/init.h>
#include <linux/sched.h>
#include <linux/interrupt.h>
#include <linux/irq.h>
#include <linux/bootmem.h>
#include <linux/acpi.h>
#include <linux/timer.h>
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/smp.h>
#include <linux/workqueue.h>
#include <linux/cpumask.h>
#include <linux/kdebug.h>
#include <asm/delay.h>
#include <asm/machvec.h>
#include <asm/meminit.h>
#include <asm/page.h>
#include <asm/ptrace.h>
#include <asm/system.h>
#include <asm/sal.h>
#include <asm/mca.h>
#include <asm/kexec.h>
#include <asm/irq.h>
#include <asm/hw_irq.h>
#include "mca_drv.h"
#include "entry.h"
#if defined(IA64_MCA_DEBUG_INFO)
# define IA64_MCA_DEBUG(fmt...) printk(fmt)
#else
# define IA64_MCA_DEBUG(fmt...)
#endif
/* Used by mca_asm.S */
DEFINE_PER_CPU(u64, ia64_mca_data); /* == __per_cpu_mca[smp_processor_id()] */
DEFINE_PER_CPU(u64, ia64_mca_per_cpu_pte); /* PTE to map per-CPU area */
DEFINE_PER_CPU(u64, ia64_mca_pal_pte); /* PTE to map PAL code */
DEFINE_PER_CPU(u64, ia64_mca_pal_base); /* vaddr PAL code granule */
unsigned long __per_cpu_mca[NR_CPUS];
/* In mca_asm.S */
extern void ia64_os_init_dispatch_monarch (void);
extern void ia64_os_init_dispatch_slave (void);
static int monarch_cpu = -1;
static ia64_mc_info_t ia64_mc_info;
#define MAX_CPE_POLL_INTERVAL (15*60*HZ) /* 15 minutes */
#define MIN_CPE_POLL_INTERVAL (2*60*HZ) /* 2 minutes */
#define CMC_POLL_INTERVAL (1*60*HZ) /* 1 minute */
#define CPE_HISTORY_LENGTH 5
#define CMC_HISTORY_LENGTH 5
#ifdef CONFIG_ACPI
static struct timer_list cpe_poll_timer;
#endif
static struct timer_list cmc_poll_timer;
/*
* This variable tells whether we are currently in polling mode.
* Start with this in the wrong state so we won't play w/ timers
* before the system is ready.
*/
static int cmc_polling_enabled = 1;
/*
* Clearing this variable prevents CPE polling from getting activated
* in mca_late_init. Use it if your system doesn't provide a CPEI,
* but encounters problems retrieving CPE logs. This should only be
* necessary for debugging.
*/
static int cpe_poll_enabled = 1;
extern void salinfo_log_wakeup(int type, u8 *buffer, u64 size, int irqsafe);
static int mca_init __initdata;
/*
* limited & delayed printing support for MCA/INIT handler
*/
#define mprintk(fmt...) ia64_mca_printk(fmt)
#define MLOGBUF_SIZE (512+256*NR_CPUS)
#define MLOGBUF_MSGMAX 256
static char mlogbuf[MLOGBUF_SIZE];
static DEFINE_SPINLOCK(mlogbuf_wlock); /* mca context only */
static DEFINE_SPINLOCK(mlogbuf_rlock); /* normal context only */
static unsigned long mlogbuf_start;
static unsigned long mlogbuf_end;
static unsigned int mlogbuf_finished = 0;
static unsigned long mlogbuf_timestamp = 0;
static int loglevel_save = -1;
#define BREAK_LOGLEVEL(__console_loglevel) \
oops_in_progress = 1; \
if (loglevel_save < 0) \
loglevel_save = __console_loglevel; \
__console_loglevel = 15;
#define RESTORE_LOGLEVEL(__console_loglevel) \
if (loglevel_save >= 0) { \
__console_loglevel = loglevel_save; \
loglevel_save = -1; \
} \
mlogbuf_finished = 0; \
oops_in_progress = 0;
/*
* Push messages into buffer, print them later if not urgent.
*/
void ia64_mca_printk(const char *fmt, ...)
{
va_list args;
int printed_len;
char temp_buf[MLOGBUF_MSGMAX];
char *p;
va_start(args, fmt);
printed_len = vscnprintf(temp_buf, sizeof(temp_buf), fmt, args);
va_end(args);
/* Copy the output into mlogbuf */
if (oops_in_progress) {
/* mlogbuf was abandoned, use printk directly instead. */
printk(temp_buf);
} else {
spin_lock(&mlogbuf_wlock);
for (p = temp_buf; *p; p++) {
unsigned long next = (mlogbuf_end + 1) % MLOGBUF_SIZE;
if (next != mlogbuf_start) {
mlogbuf[mlogbuf_end] = *p;
mlogbuf_end = next;
} else {
/* buffer full */
break;
}
}
mlogbuf[mlogbuf_end] = '\0';
spin_unlock(&mlogbuf_wlock);
}
}
EXPORT_SYMBOL(ia64_mca_printk);
/*
* Print buffered messages.
* NOTE: call this after returning normal context. (ex. from salinfod)
*/
void ia64_mlogbuf_dump(void)
{
char temp_buf[MLOGBUF_MSGMAX];
char *p;
unsigned long index;
unsigned long flags;
unsigned int printed_len;
/* Get output from mlogbuf */
while (mlogbuf_start != mlogbuf_end) {
temp_buf[0] = '\0';
p = temp_buf;
printed_len = 0;
spin_lock_irqsave(&mlogbuf_rlock, flags);
index = mlogbuf_start;
while (index != mlogbuf_end) {
*p = mlogbuf[index];
index = (index + 1) % MLOGBUF_SIZE;
if (!*p)
break;
p++;
if (++printed_len >= MLOGBUF_MSGMAX - 1)
break;
}
*p = '\0';
if (temp_buf[0])
printk(temp_buf);
mlogbuf_start = index;
mlogbuf_timestamp = 0;
spin_unlock_irqrestore(&mlogbuf_rlock, flags);
}
}
EXPORT_SYMBOL(ia64_mlogbuf_dump);
/*
* Call this if system is going to down or if immediate flushing messages to
* console is required. (ex. recovery was failed, crash dump is going to be
* invoked, long-wait rendezvous etc.)
* NOTE: this should be called from monarch.
*/
static void ia64_mlogbuf_finish(int wait)
{
BREAK_LOGLEVEL(console_loglevel);
spin_lock_init(&mlogbuf_rlock);
ia64_mlogbuf_dump();
printk(KERN_EMERG "mlogbuf_finish: printing switched to urgent mode, "
"MCA/INIT might be dodgy or fail.\n");
if (!wait)
return;
/* wait for console */
printk("Delaying for 5 seconds...\n");
udelay(5*1000000);
mlogbuf_finished = 1;
}
/*
* Print buffered messages from INIT context.
*/
static void ia64_mlogbuf_dump_from_init(void)
{
if (mlogbuf_finished)
return;
if (mlogbuf_timestamp && (mlogbuf_timestamp + 30*HZ > jiffies)) {
printk(KERN_ERR "INIT: mlogbuf_dump is interrupted by INIT "
" and the system seems to be messed up.\n");
ia64_mlogbuf_finish(0);
return;
}
if (!spin_trylock(&mlogbuf_rlock)) {
printk(KERN_ERR "INIT: mlogbuf_dump is interrupted by INIT. "
"Generated messages other than stack dump will be "
"buffered to mlogbuf and will be printed later.\n");
printk(KERN_ERR "INIT: If messages would not printed after "
"this INIT, wait 30sec and assert INIT again.\n");
if (!mlogbuf_timestamp)
mlogbuf_timestamp = jiffies;
return;
}
spin_unlock(&mlogbuf_rlock);
ia64_mlogbuf_dump();
}
static void inline
ia64_mca_spin(const char *func)
{
if (monarch_cpu == smp_processor_id())
ia64_mlogbuf_finish(0);
mprintk(KERN_EMERG "%s: spinning here, not returning to SAL\n", func);
while (1)
cpu_relax();
}
/*
* IA64_MCA log support
*/
#define IA64_MAX_LOGS 2 /* Double-buffering for nested MCAs */
#define IA64_MAX_LOG_TYPES 4 /* MCA, INIT, CMC, CPE */
typedef struct ia64_state_log_s
{
spinlock_t isl_lock;
int isl_index;
unsigned long isl_count;
ia64_err_rec_t *isl_log[IA64_MAX_LOGS]; /* need space to store header + error log */
} ia64_state_log_t;
static ia64_state_log_t ia64_state_log[IA64_MAX_LOG_TYPES];
#define IA64_LOG_ALLOCATE(it, size) \
{ia64_state_log[it].isl_log[IA64_LOG_CURR_INDEX(it)] = \
(ia64_err_rec_t *)alloc_bootmem(size); \
ia64_state_log[it].isl_log[IA64_LOG_NEXT_INDEX(it)] = \
(ia64_err_rec_t *)alloc_bootmem(size);}
#define IA64_LOG_LOCK_INIT(it) spin_lock_init(&ia64_state_log[it].isl_lock)
#define IA64_LOG_LOCK(it) spin_lock_irqsave(&ia64_state_log[it].isl_lock, s)
#define IA64_LOG_UNLOCK(it) spin_unlock_irqrestore(&ia64_state_log[it].isl_lock,s)
#define IA64_LOG_NEXT_INDEX(it) ia64_state_log[it].isl_index
#define IA64_LOG_CURR_INDEX(it) 1 - ia64_state_log[it].isl_index
#define IA64_LOG_INDEX_INC(it) \
{ia64_state_log[it].isl_index = 1 - ia64_state_log[it].isl_index; \
ia64_state_log[it].isl_count++;}
#define IA64_LOG_INDEX_DEC(it) \
ia64_state_log[it].isl_index = 1 - ia64_state_log[it].isl_index
#define IA64_LOG_NEXT_BUFFER(it) (void *)((ia64_state_log[it].isl_log[IA64_LOG_NEXT_INDEX(it)]))
#define IA64_LOG_CURR_BUFFER(it) (void *)((ia64_state_log[it].isl_log[IA64_LOG_CURR_INDEX(it)]))
#define IA64_LOG_COUNT(it) ia64_state_log[it].isl_count
/*
* ia64_log_init
* Reset the OS ia64 log buffer
* Inputs : info_type (SAL_INFO_TYPE_{MCA,INIT,CMC,CPE})
* Outputs : None
*/
static void __init
ia64_log_init(int sal_info_type)
{
u64 max_size = 0;
IA64_LOG_NEXT_INDEX(sal_info_type) = 0;
IA64_LOG_LOCK_INIT(sal_info_type);
// SAL will tell us the maximum size of any error record of this type
max_size = ia64_sal_get_state_info_size(sal_info_type);
if (!max_size)
/* alloc_bootmem() doesn't like zero-sized allocations! */
return;
// set up OS data structures to hold error info
IA64_LOG_ALLOCATE(sal_info_type, max_size);
memset(IA64_LOG_CURR_BUFFER(sal_info_type), 0, max_size);
memset(IA64_LOG_NEXT_BUFFER(sal_info_type), 0, max_size);
}
/*
* ia64_log_get
*
* Get the current MCA log from SAL and copy it into the OS log buffer.
*
* Inputs : info_type (SAL_INFO_TYPE_{MCA,INIT,CMC,CPE})
* irq_safe whether you can use printk at this point
* Outputs : size (total record length)
* *buffer (ptr to error record)
*
*/
static u64
ia64_log_get(int sal_info_type, u8 **buffer, int irq_safe)
{
sal_log_record_header_t *log_buffer;
u64 total_len = 0;
unsigned long s;
IA64_LOG_LOCK(sal_info_type);
/* Get the process state information */
log_buffer = IA64_LOG_NEXT_BUFFER(sal_info_type);
total_len = ia64_sal_get_state_info(sal_info_type, (u64 *)log_buffer);
if (total_len) {
IA64_LOG_INDEX_INC(sal_info_type);
IA64_LOG_UNLOCK(sal_info_type);
if (irq_safe) {
IA64_MCA_DEBUG("%s: SAL error record type %d retrieved. "
"Record length = %ld\n", __FUNCTION__, sal_info_type, total_len);
}
*buffer = (u8 *) log_buffer;
return total_len;
} else {
IA64_LOG_UNLOCK(sal_info_type);
return 0;
}
}
/*
* ia64_mca_log_sal_error_record
*
* This function retrieves a specified error record type from SAL
* and wakes up any processes waiting for error records.
*
* Inputs : sal_info_type (Type of error record MCA/CMC/CPE)
* FIXME: remove MCA and irq_safe.
*/
static void
ia64_mca_log_sal_error_record(int sal_info_type)
{
u8 *buffer;
sal_log_record_header_t *rh;
u64 size;
int irq_safe = sal_info_type != SAL_INFO_TYPE_MCA;
#ifdef IA64_MCA_DEBUG_INFO
static const char * const rec_name[] = { "MCA", "INIT", "CMC", "CPE" };
#endif
size = ia64_log_get(sal_info_type, &buffer, irq_safe);
if (!size)
return;
salinfo_log_wakeup(sal_info_type, buffer, size, irq_safe);
if (irq_safe)
IA64_MCA_DEBUG("CPU %d: SAL log contains %s error record\n",
smp_processor_id(),
sal_info_type < ARRAY_SIZE(rec_name) ? rec_name[sal_info_type] : "UNKNOWN");
/* Clear logs from corrected errors in case there's no user-level logger */
rh = (sal_log_record_header_t *)buffer;
if (rh->severity == sal_log_severity_corrected)
ia64_sal_clear_state_info(sal_info_type);
}
/*
* search_mca_table
* See if the MCA surfaced in an instruction range
* that has been tagged as recoverable.
*
* Inputs
* first First address range to check
* last Last address range to check
* ip Instruction pointer, address we are looking for
*
* Return value:
* 1 on Success (in the table)/ 0 on Failure (not in the table)
*/
int
search_mca_table (const struct mca_table_entry *first,
const struct mca_table_entry *last,
unsigned long ip)
{
const struct mca_table_entry *curr;
u64 curr_start, curr_end;
curr = first;
while (curr <= last) {
curr_start = (u64) &curr->start_addr + curr->start_addr;
curr_end = (u64) &curr->end_addr + curr->end_addr;
if ((ip >= curr_start) && (ip <= curr_end)) {
return 1;
}
curr++;
}
return 0;
}
/* Given an address, look for it in the mca tables. */
int mca_recover_range(unsigned long addr)
{
extern struct mca_table_entry __start___mca_table[];
extern struct mca_table_entry __stop___mca_table[];
return search_mca_table(__start___mca_table, __stop___mca_table-1, addr);
}
EXPORT_SYMBOL_GPL(mca_recover_range);
#ifdef CONFIG_ACPI
int cpe_vector = -1;
int ia64_cpe_irq = -1;
static irqreturn_t
ia64_mca_cpe_int_handler (int cpe_irq, void *arg)
{
static unsigned long cpe_history[CPE_HISTORY_LENGTH];
static int index;
static DEFINE_SPINLOCK(cpe_history_lock);
IA64_MCA_DEBUG("%s: received interrupt vector = %#x on CPU %d\n",
__FUNCTION__, cpe_irq, smp_processor_id());
/* SAL spec states this should run w/ interrupts enabled */
local_irq_enable();
spin_lock(&cpe_history_lock);
if (!cpe_poll_enabled && cpe_vector >= 0) {
int i, count = 1; /* we know 1 happened now */
unsigned long now = jiffies;
for (i = 0; i < CPE_HISTORY_LENGTH; i++) {
if (now - cpe_history[i] <= HZ)
count++;
}
IA64_MCA_DEBUG(KERN_INFO "CPE threshold %d/%d\n", count, CPE_HISTORY_LENGTH);
if (count >= CPE_HISTORY_LENGTH) {
cpe_poll_enabled = 1;
spin_unlock(&cpe_history_lock);
disable_irq_nosync(local_vector_to_irq(IA64_CPE_VECTOR));
/*
* Corrected errors will still be corrected, but
* make sure there's a log somewhere that indicates
* something is generating more than we can handle.
*/
printk(KERN_WARNING "WARNING: Switching to polling CPE handler; error records may be lost\n");
mod_timer(&cpe_poll_timer, jiffies + MIN_CPE_POLL_INTERVAL);
/* lock already released, get out now */
goto out;
} else {
cpe_history[index++] = now;
if (index == CPE_HISTORY_LENGTH)
index = 0;
}
}
spin_unlock(&cpe_history_lock);
out:
/* Get the CPE error record and log it */
ia64_mca_log_sal_error_record(SAL_INFO_TYPE_CPE);
return IRQ_HANDLED;
}
#endif /* CONFIG_ACPI */
#ifdef CONFIG_ACPI
/*
* ia64_mca_register_cpev
*
* Register the corrected platform error vector with SAL.
*
* Inputs
* cpev Corrected Platform Error Vector number
*
* Outputs
* None
*/
static void __init
ia64_mca_register_cpev (int cpev)
{
/* Register the CPE interrupt vector with SAL */
struct ia64_sal_retval isrv;
isrv = ia64_sal_mc_set_params(SAL_MC_PARAM_CPE_INT, SAL_MC_PARAM_MECHANISM_INT, cpev, 0, 0);
if (isrv.status) {
printk(KERN_ERR "Failed to register Corrected Platform "
"Error interrupt vector with SAL (status %ld)\n", isrv.status);
return;
}
IA64_MCA_DEBUG("%s: corrected platform error "
"vector %#x registered\n", __FUNCTION__, cpev);
}
#endif /* CONFIG_ACPI */
/*
* ia64_mca_cmc_vector_setup
*
* Setup the corrected machine check vector register in the processor.
* (The interrupt is masked on boot. ia64_mca_late_init unmask this.)
* This function is invoked on a per-processor basis.
*
* Inputs
* None
*
* Outputs
* None
*/
void __cpuinit
ia64_mca_cmc_vector_setup (void)
{
cmcv_reg_t cmcv;
cmcv.cmcv_regval = 0;
cmcv.cmcv_mask = 1; /* Mask/disable interrupt at first */
cmcv.cmcv_vector = IA64_CMC_VECTOR;
ia64_setreg(_IA64_REG_CR_CMCV, cmcv.cmcv_regval);
IA64_MCA_DEBUG("%s: CPU %d corrected "
"machine check vector %#x registered.\n",
__FUNCTION__, smp_processor_id(), IA64_CMC_VECTOR);
IA64_MCA_DEBUG("%s: CPU %d CMCV = %#016lx\n",
__FUNCTION__, smp_processor_id(), ia64_getreg(_IA64_REG_CR_CMCV));
}
/*
* ia64_mca_cmc_vector_disable
*
* Mask the corrected machine check vector register in the processor.
* This function is invoked on a per-processor basis.
*
* Inputs
* dummy(unused)
*
* Outputs
* None
*/
static void
ia64_mca_cmc_vector_disable (void *dummy)
{
cmcv_reg_t cmcv;
cmcv.cmcv_regval = ia64_getreg(_IA64_REG_CR_CMCV);
cmcv.cmcv_mask = 1; /* Mask/disable interrupt */
ia64_setreg(_IA64_REG_CR_CMCV, cmcv.cmcv_regval);
IA64_MCA_DEBUG("%s: CPU %d corrected "
"machine check vector %#x disabled.\n",
__FUNCTION__, smp_processor_id(), cmcv.cmcv_vector);
}
/*
* ia64_mca_cmc_vector_enable
*
* Unmask the corrected machine check vector register in the processor.
* This function is invoked on a per-processor basis.
*
* Inputs
* dummy(unused)
*
* Outputs
* None
*/
static void
ia64_mca_cmc_vector_enable (void *dummy)
{
cmcv_reg_t cmcv;
cmcv.cmcv_regval = ia64_getreg(_IA64_REG_CR_CMCV);
cmcv.cmcv_mask = 0; /* Unmask/enable interrupt */
ia64_setreg(_IA64_REG_CR_CMCV, cmcv.cmcv_regval);
IA64_MCA_DEBUG("%s: CPU %d corrected "
"machine check vector %#x enabled.\n",
__FUNCTION__, smp_processor_id(), cmcv.cmcv_vector);
}
/*
* ia64_mca_cmc_vector_disable_keventd
*
* Called via keventd (smp_call_function() is not safe in interrupt context) to
* disable the cmc interrupt vector.
*/
static void
ia64_mca_cmc_vector_disable_keventd(struct work_struct *unused)
{
on_each_cpu(ia64_mca_cmc_vector_disable, NULL, 1, 0);
}
/*
* ia64_mca_cmc_vector_enable_keventd
*
* Called via keventd (smp_call_function() is not safe in interrupt context) to
* enable the cmc interrupt vector.
*/
static void
ia64_mca_cmc_vector_enable_keventd(struct work_struct *unused)
{
on_each_cpu(ia64_mca_cmc_vector_enable, NULL, 1, 0);
}
/*
* ia64_mca_wakeup
*
* Send an inter-cpu interrupt to wake-up a particular cpu
* and mark that cpu to be out of rendez.
*
* Inputs : cpuid
* Outputs : None
*/
static void
ia64_mca_wakeup(int cpu)
{
platform_send_ipi(cpu, IA64_MCA_WAKEUP_VECTOR, IA64_IPI_DM_INT, 0);
ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_NOTDONE;
}
/*
* ia64_mca_wakeup_all
*
* Wakeup all the cpus which have rendez'ed previously.
*
* Inputs : None
* Outputs : None
*/
static void
ia64_mca_wakeup_all(void)
{
int cpu;
/* Clear the Rendez checkin flag for all cpus */
for_each_online_cpu(cpu) {
if (ia64_mc_info.imi_rendez_checkin[cpu] == IA64_MCA_RENDEZ_CHECKIN_DONE)
ia64_mca_wakeup(cpu);
}
}
/*
* ia64_mca_rendez_interrupt_handler
*
* This is handler used to put slave processors into spinloop
* while the monarch processor does the mca handling and later
* wake each slave up once the monarch is done.
*
* Inputs : None
* Outputs : None
*/
static irqreturn_t
ia64_mca_rendez_int_handler(int rendez_irq, void *arg)
{
unsigned long flags;
int cpu = smp_processor_id();
struct ia64_mca_notify_die nd =
{ .sos = NULL, .monarch_cpu = &monarch_cpu };
/* Mask all interrupts */
local_irq_save(flags);
if (notify_die(DIE_MCA_RENDZVOUS_ENTER, "MCA", get_irq_regs(),
(long)&nd, 0, 0) == NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_DONE;
/* Register with the SAL monarch that the slave has
* reached SAL
*/
ia64_sal_mc_rendez();
if (notify_die(DIE_MCA_RENDZVOUS_PROCESS, "MCA", get_irq_regs(),
(long)&nd, 0, 0) == NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
/* Wait for the monarch cpu to exit. */
while (monarch_cpu != -1)
cpu_relax(); /* spin until monarch leaves */
if (notify_die(DIE_MCA_RENDZVOUS_LEAVE, "MCA", get_irq_regs(),
(long)&nd, 0, 0) == NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
/* Enable all interrupts */
local_irq_restore(flags);
return IRQ_HANDLED;
}
/*
* ia64_mca_wakeup_int_handler
*
* The interrupt handler for processing the inter-cpu interrupt to the
* slave cpu which was spinning in the rendez loop.
* Since this spinning is done by turning off the interrupts and
* polling on the wakeup-interrupt bit in the IRR, there is
* nothing useful to be done in the handler.
*
* Inputs : wakeup_irq (Wakeup-interrupt bit)
* arg (Interrupt handler specific argument)
* Outputs : None
*
*/
static irqreturn_t
ia64_mca_wakeup_int_handler(int wakeup_irq, void *arg)
{
return IRQ_HANDLED;
}
/* Function pointer for extra MCA recovery */
int (*ia64_mca_ucmc_extension)
(void*,struct ia64_sal_os_state*)
= NULL;
int
ia64_reg_MCA_extension(int (*fn)(void *, struct ia64_sal_os_state *))
{
if (ia64_mca_ucmc_extension)
return 1;
ia64_mca_ucmc_extension = fn;
return 0;
}
void
ia64_unreg_MCA_extension(void)
{
if (ia64_mca_ucmc_extension)
ia64_mca_ucmc_extension = NULL;
}
EXPORT_SYMBOL(ia64_reg_MCA_extension);
EXPORT_SYMBOL(ia64_unreg_MCA_extension);
static inline void
copy_reg(const u64 *fr, u64 fnat, u64 *tr, u64 *tnat)
{
u64 fslot, tslot, nat;
*tr = *fr;
fslot = ((unsigned long)fr >> 3) & 63;
tslot = ((unsigned long)tr >> 3) & 63;
*tnat &= ~(1UL << tslot);
nat = (fnat >> fslot) & 1;
*tnat |= (nat << tslot);
}
/* Change the comm field on the MCA/INT task to include the pid that
* was interrupted, it makes for easier debugging. If that pid was 0
* (swapper or nested MCA/INIT) then use the start of the previous comm
* field suffixed with its cpu.
*/
static void
ia64_mca_modify_comm(const struct task_struct *previous_current)
{
char *p, comm[sizeof(current->comm)];
if (previous_current->pid)
snprintf(comm, sizeof(comm), "%s %d",
current->comm, previous_current->pid);
else {
int l;
if ((p = strchr(previous_current->comm, ' ')))
l = p - previous_current->comm;
else
l = strlen(previous_current->comm);
snprintf(comm, sizeof(comm), "%s %*s %d",
current->comm, l, previous_current->comm,
task_thread_info(previous_current)->cpu);
}
memcpy(current->comm, comm, sizeof(current->comm));
}
/* On entry to this routine, we are running on the per cpu stack, see
* mca_asm.h. The original stack has not been touched by this event. Some of
* the original stack's registers will be in the RBS on this stack. This stack
* also contains a partial pt_regs and switch_stack, the rest of the data is in
* PAL minstate.
*
* The first thing to do is modify the original stack to look like a blocked
* task so we can run backtrace on the original task. Also mark the per cpu
* stack as current to ensure that we use the correct task state, it also means
* that we can do backtrace on the MCA/INIT handler code itself.
*/
static struct task_struct *
ia64_mca_modify_original_stack(struct pt_regs *regs,
const struct switch_stack *sw,
struct ia64_sal_os_state *sos,
const char *type)
{
char *p;
ia64_va va;
extern char ia64_leave_kernel[]; /* Need asm address, not function descriptor */
const pal_min_state_area_t *ms = sos->pal_min_state;
struct task_struct *previous_current;
struct pt_regs *old_regs;
struct switch_stack *old_sw;
unsigned size = sizeof(struct pt_regs) +
sizeof(struct switch_stack) + 16;
u64 *old_bspstore, *old_bsp;
u64 *new_bspstore, *new_bsp;
u64 old_unat, old_rnat, new_rnat, nat;
u64 slots, loadrs = regs->loadrs;
u64 r12 = ms->pmsa_gr[12-1], r13 = ms->pmsa_gr[13-1];
u64 ar_bspstore = regs->ar_bspstore;
u64 ar_bsp = regs->ar_bspstore + (loadrs >> 16);
const u64 *bank;
const char *msg;
int cpu = smp_processor_id();
previous_current = curr_task(cpu);
set_curr_task(cpu, current);
if ((p = strchr(current->comm, ' ')))
*p = '\0';
/* Best effort attempt to cope with MCA/INIT delivered while in
* physical mode.
*/
regs->cr_ipsr = ms->pmsa_ipsr;
if (ia64_psr(regs)->dt == 0) {
va.l = r12;
if (va.f.reg == 0) {
va.f.reg = 7;
r12 = va.l;
}
va.l = r13;
if (va.f.reg == 0) {
va.f.reg = 7;
r13 = va.l;
}
}
if (ia64_psr(regs)->rt == 0) {
va.l = ar_bspstore;
if (va.f.reg == 0) {
va.f.reg = 7;
ar_bspstore = va.l;
}
va.l = ar_bsp;
if (va.f.reg == 0) {
va.f.reg = 7;
ar_bsp = va.l;
}
}
/* mca_asm.S ia64_old_stack() cannot assume that the dirty registers
* have been copied to the old stack, the old stack may fail the
* validation tests below. So ia64_old_stack() must restore the dirty
* registers from the new stack. The old and new bspstore probably
* have different alignments, so loadrs calculated on the old bsp
* cannot be used to restore from the new bsp. Calculate a suitable
* loadrs for the new stack and save it in the new pt_regs, where
* ia64_old_stack() can get it.
*/
old_bspstore = (u64 *)ar_bspstore;
old_bsp = (u64 *)ar_bsp;
slots = ia64_rse_num_regs(old_bspstore, old_bsp);
new_bspstore = (u64 *)((u64)current + IA64_RBS_OFFSET);
new_bsp = ia64_rse_skip_regs(new_bspstore, slots);
regs->loadrs = (new_bsp - new_bspstore) * 8 << 16;
/* Verify the previous stack state before we change it */
if (user_mode(regs)) {
msg = "occurred in user space";
/* previous_current is guaranteed to be valid when the task was
* in user space, so ...
*/
ia64_mca_modify_comm(previous_current);
goto no_mod;
}
if (r13 != sos->prev_IA64_KR_CURRENT) {
msg = "inconsistent previous current and r13";
goto no_mod;
}
if (!mca_recover_range(ms->pmsa_iip)) {
if ((r12 - r13) >= KERNEL_STACK_SIZE) {
msg = "inconsistent r12 and r13";
goto no_mod;
}
if ((ar_bspstore - r13) >= KERNEL_STACK_SIZE) {
msg = "inconsistent ar.bspstore and r13";
goto no_mod;
}
va.p = old_bspstore;
if (va.f.reg < 5) {
msg = "old_bspstore is in the wrong region";
goto no_mod;
}
if ((ar_bsp - r13) >= KERNEL_STACK_SIZE) {
msg = "inconsistent ar.bsp and r13";
goto no_mod;
}
size += (ia64_rse_skip_regs(old_bspstore, slots) - old_bspstore) * 8;
if (ar_bspstore + size > r12) {
msg = "no room for blocked state";
goto no_mod;
}
}
ia64_mca_modify_comm(previous_current);
/* Make the original task look blocked. First stack a struct pt_regs,
* describing the state at the time of interrupt. mca_asm.S built a
* partial pt_regs, copy it and fill in the blanks using minstate.
*/
p = (char *)r12 - sizeof(*regs);
old_regs = (struct pt_regs *)p;
memcpy(old_regs, regs, sizeof(*regs));
/* If ipsr.ic then use pmsa_{iip,ipsr,ifs}, else use
* pmsa_{xip,xpsr,xfs}
*/
if (ia64_psr(regs)->ic) {
old_regs->cr_iip = ms->pmsa_iip;
old_regs->cr_ipsr = ms->pmsa_ipsr;
old_regs->cr_ifs = ms->pmsa_ifs;
} else {
old_regs->cr_iip = ms->pmsa_xip;
old_regs->cr_ipsr = ms->pmsa_xpsr;
old_regs->cr_ifs = ms->pmsa_xfs;
}
old_regs->pr = ms->pmsa_pr;
old_regs->b0 = ms->pmsa_br0;
old_regs->loadrs = loadrs;
old_regs->ar_rsc = ms->pmsa_rsc;
old_unat = old_regs->ar_unat;
copy_reg(&ms->pmsa_gr[1-1], ms->pmsa_nat_bits, &old_regs->r1, &old_unat);
copy_reg(&ms->pmsa_gr[2-1], ms->pmsa_nat_bits, &old_regs->r2, &old_unat);
copy_reg(&ms->pmsa_gr[3-1], ms->pmsa_nat_bits, &old_regs->r3, &old_unat);
copy_reg(&ms->pmsa_gr[8-1], ms->pmsa_nat_bits, &old_regs->r8, &old_unat);
copy_reg(&ms->pmsa_gr[9-1], ms->pmsa_nat_bits, &old_regs->r9, &old_unat);
copy_reg(&ms->pmsa_gr[10-1], ms->pmsa_nat_bits, &old_regs->r10, &old_unat);
copy_reg(&ms->pmsa_gr[11-1], ms->pmsa_nat_bits, &old_regs->r11, &old_unat);
copy_reg(&ms->pmsa_gr[12-1], ms->pmsa_nat_bits, &old_regs->r12, &old_unat);
copy_reg(&ms->pmsa_gr[13-1], ms->pmsa_nat_bits, &old_regs->r13, &old_unat);
copy_reg(&ms->pmsa_gr[14-1], ms->pmsa_nat_bits, &old_regs->r14, &old_unat);
copy_reg(&ms->pmsa_gr[15-1], ms->pmsa_nat_bits, &old_regs->r15, &old_unat);
if (ia64_psr(old_regs)->bn)
bank = ms->pmsa_bank1_gr;
else
bank = ms->pmsa_bank0_gr;
copy_reg(&bank[16-16], ms->pmsa_nat_bits, &old_regs->r16, &old_unat);
copy_reg(&bank[17-16], ms->pmsa_nat_bits, &old_regs->r17, &old_unat);
copy_reg(&bank[18-16], ms->pmsa_nat_bits, &old_regs->r18, &old_unat);
copy_reg(&bank[19-16], ms->pmsa_nat_bits, &old_regs->r19, &old_unat);
copy_reg(&bank[20-16], ms->pmsa_nat_bits, &old_regs->r20, &old_unat);
copy_reg(&bank[21-16], ms->pmsa_nat_bits, &old_regs->r21, &old_unat);
copy_reg(&bank[22-16], ms->pmsa_nat_bits, &old_regs->r22, &old_unat);
copy_reg(&bank[23-16], ms->pmsa_nat_bits, &old_regs->r23, &old_unat);
copy_reg(&bank[24-16], ms->pmsa_nat_bits, &old_regs->r24, &old_unat);
copy_reg(&bank[25-16], ms->pmsa_nat_bits, &old_regs->r25, &old_unat);
copy_reg(&bank[26-16], ms->pmsa_nat_bits, &old_regs->r26, &old_unat);
copy_reg(&bank[27-16], ms->pmsa_nat_bits, &old_regs->r27, &old_unat);
copy_reg(&bank[28-16], ms->pmsa_nat_bits, &old_regs->r28, &old_unat);
copy_reg(&bank[29-16], ms->pmsa_nat_bits, &old_regs->r29, &old_unat);
copy_reg(&bank[30-16], ms->pmsa_nat_bits, &old_regs->r30, &old_unat);
copy_reg(&bank[31-16], ms->pmsa_nat_bits, &old_regs->r31, &old_unat);
/* Next stack a struct switch_stack. mca_asm.S built a partial
* switch_stack, copy it and fill in the blanks using pt_regs and
* minstate.
*
* In the synthesized switch_stack, b0 points to ia64_leave_kernel,
* ar.pfs is set to 0.
*
* unwind.c::unw_unwind() does special processing for interrupt frames.
* It checks if the PRED_NON_SYSCALL predicate is set, if the predicate
* is clear then unw_unwind() does _not_ adjust bsp over pt_regs. Not
* that this is documented, of course. Set PRED_NON_SYSCALL in the
* switch_stack on the original stack so it will unwind correctly when
* unwind.c reads pt_regs.
*
* thread.ksp is updated to point to the synthesized switch_stack.
*/
p -= sizeof(struct switch_stack);
old_sw = (struct switch_stack *)p;
memcpy(old_sw, sw, sizeof(*sw));
old_sw->caller_unat = old_unat;
old_sw->ar_fpsr = old_regs->ar_fpsr;
copy_reg(&ms->pmsa_gr[4-1], ms->pmsa_nat_bits, &old_sw->r4, &old_unat);
copy_reg(&ms->pmsa_gr[5-1], ms->pmsa_nat_bits, &old_sw->r5, &old_unat);
copy_reg(&ms->pmsa_gr[6-1], ms->pmsa_nat_bits, &old_sw->r6, &old_unat);
copy_reg(&ms->pmsa_gr[7-1], ms->pmsa_nat_bits, &old_sw->r7, &old_unat);
old_sw->b0 = (u64)ia64_leave_kernel;
old_sw->b1 = ms->pmsa_br1;
old_sw->ar_pfs = 0;
old_sw->ar_unat = old_unat;
old_sw->pr = old_regs->pr | (1UL << PRED_NON_SYSCALL);
previous_current->thread.ksp = (u64)p - 16;
/* Finally copy the original stack's registers back to its RBS.
* Registers from ar.bspstore through ar.bsp at the time of the event
* are in the current RBS, copy them back to the original stack. The
* copy must be done register by register because the original bspstore
* and the current one have different alignments, so the saved RNAT
* data occurs at different places.
*
* mca_asm does cover, so the old_bsp already includes all registers at
* the time of MCA/INIT. It also does flushrs, so all registers before
* this function have been written to backing store on the MCA/INIT
* stack.
*/
new_rnat = ia64_get_rnat(ia64_rse_rnat_addr(new_bspstore));
old_rnat = regs->ar_rnat;
while (slots--) {
if (ia64_rse_is_rnat_slot(new_bspstore)) {
new_rnat = ia64_get_rnat(new_bspstore++);
}
if (ia64_rse_is_rnat_slot(old_bspstore)) {
*old_bspstore++ = old_rnat;
old_rnat = 0;
}
nat = (new_rnat >> ia64_rse_slot_num(new_bspstore)) & 1UL;
old_rnat &= ~(1UL << ia64_rse_slot_num(old_bspstore));
old_rnat |= (nat << ia64_rse_slot_num(old_bspstore));
*old_bspstore++ = *new_bspstore++;
}
old_sw->ar_bspstore = (unsigned long)old_bspstore;
old_sw->ar_rnat = old_rnat;
sos->prev_task = previous_current;
return previous_current;
no_mod:
printk(KERN_INFO "cpu %d, %s %s, original stack not modified\n",
smp_processor_id(), type, msg);
return previous_current;
}
/* The monarch/slave interaction is based on monarch_cpu and requires that all
* slaves have entered rendezvous before the monarch leaves. If any cpu has
* not entered rendezvous yet then wait a bit. The assumption is that any
* slave that has not rendezvoused after a reasonable time is never going to do
* so. In this context, slave includes cpus that respond to the MCA rendezvous
* interrupt, as well as cpus that receive the INIT slave event.
*/
static void
ia64_wait_for_slaves(int monarch, const char *type)
{
int c, wait = 0, missing = 0;
for_each_online_cpu(c) {
if (c == monarch)
continue;
if (ia64_mc_info.imi_rendez_checkin[c] == IA64_MCA_RENDEZ_CHECKIN_NOTDONE) {
udelay(1000); /* short wait first */
wait = 1;
break;
}
}
if (!wait)
goto all_in;
for_each_online_cpu(c) {
if (c == monarch)
continue;
if (ia64_mc_info.imi_rendez_checkin[c] == IA64_MCA_RENDEZ_CHECKIN_NOTDONE) {
udelay(5*1000000); /* wait 5 seconds for slaves (arbitrary) */
if (ia64_mc_info.imi_rendez_checkin[c] == IA64_MCA_RENDEZ_CHECKIN_NOTDONE)
missing = 1;
break;
}
}
if (!missing)
goto all_in;
/*
* Maybe slave(s) dead. Print buffered messages immediately.
*/
ia64_mlogbuf_finish(0);
mprintk(KERN_INFO "OS %s slave did not rendezvous on cpu", type);
for_each_online_cpu(c) {
if (c == monarch)
continue;
if (ia64_mc_info.imi_rendez_checkin[c] == IA64_MCA_RENDEZ_CHECKIN_NOTDONE)
mprintk(" %d", c);
}
mprintk("\n");
return;
all_in:
mprintk(KERN_INFO "All OS %s slaves have reached rendezvous\n", type);
return;
}
/*
* ia64_mca_handler
*
* This is uncorrectable machine check handler called from OS_MCA
* dispatch code which is in turn called from SAL_CHECK().
* This is the place where the core of OS MCA handling is done.
* Right now the logs are extracted and displayed in a well-defined
* format. This handler code is supposed to be run only on the
* monarch processor. Once the monarch is done with MCA handling
* further MCA logging is enabled by clearing logs.
* Monarch also has the duty of sending wakeup-IPIs to pull the
* slave processors out of rendezvous spinloop.
*
* If multiple processors call into OS_MCA, the first will become
* the monarch. Subsequent cpus will be recorded in the mca_cpu
* bitmask. After the first monarch has processed its MCA, it
* will wake up the next cpu in the mca_cpu bitmask and then go
* into the rendezvous loop. When all processors have serviced
* their MCA, the last monarch frees up the rest of the processors.
*/
void
ia64_mca_handler(struct pt_regs *regs, struct switch_stack *sw,
struct ia64_sal_os_state *sos)
{
int recover, cpu = smp_processor_id();
struct task_struct *previous_current;
struct ia64_mca_notify_die nd =
{ .sos = sos, .monarch_cpu = &monarch_cpu };
static atomic_t mca_count;
static cpumask_t mca_cpu;
if (atomic_add_return(1, &mca_count) == 1) {
monarch_cpu = cpu;
sos->monarch = 1;
} else {
cpu_set(cpu, mca_cpu);
sos->monarch = 0;
}
mprintk(KERN_INFO "Entered OS MCA handler. PSP=%lx cpu=%d "
"monarch=%ld\n", sos->proc_state_param, cpu, sos->monarch);
previous_current = ia64_mca_modify_original_stack(regs, sw, sos, "MCA");
if (notify_die(DIE_MCA_MONARCH_ENTER, "MCA", regs, (long)&nd, 0, 0)
== NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
if (sos->monarch) {
ia64_wait_for_slaves(cpu, "MCA");
} else {
ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_CONCURRENT_MCA;
while (cpu_isset(cpu, mca_cpu))
cpu_relax(); /* spin until monarch wakes us */
ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_NOTDONE;
}
/* Wakeup all the processors which are spinning in the rendezvous loop.
* They will leave SAL, then spin in the OS with interrupts disabled
* until this monarch cpu leaves the MCA handler. That gets control
* back to the OS so we can backtrace the other cpus, backtrace when
* spinning in SAL does not work.
*/
ia64_mca_wakeup_all();
if (notify_die(DIE_MCA_MONARCH_PROCESS, "MCA", regs, (long)&nd, 0, 0)
== NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
/* Get the MCA error record and log it */
ia64_mca_log_sal_error_record(SAL_INFO_TYPE_MCA);
/* MCA error recovery */
recover = (ia64_mca_ucmc_extension
&& ia64_mca_ucmc_extension(
IA64_LOG_CURR_BUFFER(SAL_INFO_TYPE_MCA),
sos));
if (recover) {
sal_log_record_header_t *rh = IA64_LOG_CURR_BUFFER(SAL_INFO_TYPE_MCA);
rh->severity = sal_log_severity_corrected;
ia64_sal_clear_state_info(SAL_INFO_TYPE_MCA);
sos->os_status = IA64_MCA_CORRECTED;
} else {
/* Dump buffered message to console */
ia64_mlogbuf_finish(1);
#ifdef CONFIG_KEXEC
atomic_set(&kdump_in_progress, 1);
monarch_cpu = -1;
#endif
}
if (notify_die(DIE_MCA_MONARCH_LEAVE, "MCA", regs, (long)&nd, 0, recover)
== NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
if (atomic_dec_return(&mca_count) > 0) {
int i;
/* wake up the next monarch cpu,
* and put this cpu in the rendez loop.
*/
ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_CONCURRENT_MCA;
for_each_online_cpu(i) {
if (cpu_isset(i, mca_cpu)) {
monarch_cpu = i;
cpu_clear(i, mca_cpu); /* wake next cpu */
while (monarch_cpu != -1)
cpu_relax(); /* spin until last cpu leaves */
ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_NOTDONE;
set_curr_task(cpu, previous_current);
return;
}
}
}
set_curr_task(cpu, previous_current);
monarch_cpu = -1;
}
static DECLARE_WORK(cmc_disable_work, ia64_mca_cmc_vector_disable_keventd);
static DECLARE_WORK(cmc_enable_work, ia64_mca_cmc_vector_enable_keventd);
/*
* ia64_mca_cmc_int_handler
*
* This is corrected machine check interrupt handler.
* Right now the logs are extracted and displayed in a well-defined
* format.
*
* Inputs
* interrupt number
* client data arg ptr
*
* Outputs
* None
*/
static irqreturn_t
ia64_mca_cmc_int_handler(int cmc_irq, void *arg)
{
static unsigned long cmc_history[CMC_HISTORY_LENGTH];
static int index;
static DEFINE_SPINLOCK(cmc_history_lock);
IA64_MCA_DEBUG("%s: received interrupt vector = %#x on CPU %d\n",
__FUNCTION__, cmc_irq, smp_processor_id());
/* SAL spec states this should run w/ interrupts enabled */
local_irq_enable();
spin_lock(&cmc_history_lock);
if (!cmc_polling_enabled) {
int i, count = 1; /* we know 1 happened now */
unsigned long now = jiffies;
for (i = 0; i < CMC_HISTORY_LENGTH; i++) {
if (now - cmc_history[i] <= HZ)
count++;
}
IA64_MCA_DEBUG(KERN_INFO "CMC threshold %d/%d\n", count, CMC_HISTORY_LENGTH);
if (count >= CMC_HISTORY_LENGTH) {
cmc_polling_enabled = 1;
spin_unlock(&cmc_history_lock);
/* If we're being hit with CMC interrupts, we won't
* ever execute the schedule_work() below. Need to
* disable CMC interrupts on this processor now.
*/
ia64_mca_cmc_vector_disable(NULL);
schedule_work(&cmc_disable_work);
/*
* Corrected errors will still be corrected, but
* make sure there's a log somewhere that indicates
* something is generating more than we can handle.
*/
printk(KERN_WARNING "WARNING: Switching to polling CMC handler; error records may be lost\n");
mod_timer(&cmc_poll_timer, jiffies + CMC_POLL_INTERVAL);
/* lock already released, get out now */
goto out;
} else {
cmc_history[index++] = now;
if (index == CMC_HISTORY_LENGTH)
index = 0;
}
}
spin_unlock(&cmc_history_lock);
out:
/* Get the CMC error record and log it */
ia64_mca_log_sal_error_record(SAL_INFO_TYPE_CMC);
return IRQ_HANDLED;
}
/*
* ia64_mca_cmc_int_caller
*
* Triggered by sw interrupt from CMC polling routine. Calls
* real interrupt handler and either triggers a sw interrupt
* on the next cpu or does cleanup at the end.
*
* Inputs
* interrupt number
* client data arg ptr
* Outputs
* handled
*/
static irqreturn_t
ia64_mca_cmc_int_caller(int cmc_irq, void *arg)
{
static int start_count = -1;
unsigned int cpuid;
cpuid = smp_processor_id();
/* If first cpu, update count */
if (start_count == -1)
start_count = IA64_LOG_COUNT(SAL_INFO_TYPE_CMC);
ia64_mca_cmc_int_handler(cmc_irq, arg);
for (++cpuid ; cpuid < NR_CPUS && !cpu_online(cpuid) ; cpuid++);
if (cpuid < NR_CPUS) {
platform_send_ipi(cpuid, IA64_CMCP_VECTOR, IA64_IPI_DM_INT, 0);
} else {
/* If no log record, switch out of polling mode */
if (start_count == IA64_LOG_COUNT(SAL_INFO_TYPE_CMC)) {
printk(KERN_WARNING "Returning to interrupt driven CMC handler\n");
schedule_work(&cmc_enable_work);
cmc_polling_enabled = 0;
} else {
mod_timer(&cmc_poll_timer, jiffies + CMC_POLL_INTERVAL);
}
start_count = -1;
}
return IRQ_HANDLED;
}
/*
* ia64_mca_cmc_poll
*
* Poll for Corrected Machine Checks (CMCs)
*
* Inputs : dummy(unused)
* Outputs : None
*
*/
static void
ia64_mca_cmc_poll (unsigned long dummy)
{
/* Trigger a CMC interrupt cascade */
platform_send_ipi(first_cpu(cpu_online_map), IA64_CMCP_VECTOR, IA64_IPI_DM_INT, 0);
}
/*
* ia64_mca_cpe_int_caller
*
* Triggered by sw interrupt from CPE polling routine. Calls
* real interrupt handler and either triggers a sw interrupt
* on the next cpu or does cleanup at the end.
*
* Inputs
* interrupt number
* client data arg ptr
* Outputs
* handled
*/
#ifdef CONFIG_ACPI
static irqreturn_t
ia64_mca_cpe_int_caller(int cpe_irq, void *arg)
{
static int start_count = -1;
static int poll_time = MIN_CPE_POLL_INTERVAL;
unsigned int cpuid;
cpuid = smp_processor_id();
/* If first cpu, update count */
if (start_count == -1)
start_count = IA64_LOG_COUNT(SAL_INFO_TYPE_CPE);
ia64_mca_cpe_int_handler(cpe_irq, arg);
for (++cpuid ; cpuid < NR_CPUS && !cpu_online(cpuid) ; cpuid++);
if (cpuid < NR_CPUS) {
platform_send_ipi(cpuid, IA64_CPEP_VECTOR, IA64_IPI_DM_INT, 0);
} else {
/*
* If a log was recorded, increase our polling frequency,
* otherwise, backoff or return to interrupt mode.
*/
if (start_count != IA64_LOG_COUNT(SAL_INFO_TYPE_CPE)) {
poll_time = max(MIN_CPE_POLL_INTERVAL, poll_time / 2);
} else if (cpe_vector < 0) {
poll_time = min(MAX_CPE_POLL_INTERVAL, poll_time * 2);
} else {
poll_time = MIN_CPE_POLL_INTERVAL;
printk(KERN_WARNING "Returning to interrupt driven CPE handler\n");
enable_irq(local_vector_to_irq(IA64_CPE_VECTOR));
cpe_poll_enabled = 0;
}
if (cpe_poll_enabled)
mod_timer(&cpe_poll_timer, jiffies + poll_time);
start_count = -1;
}
return IRQ_HANDLED;
}
/*
* ia64_mca_cpe_poll
*
* Poll for Corrected Platform Errors (CPEs), trigger interrupt
* on first cpu, from there it will trickle through all the cpus.
*
* Inputs : dummy(unused)
* Outputs : None
*
*/
static void
ia64_mca_cpe_poll (unsigned long dummy)
{
/* Trigger a CPE interrupt cascade */
platform_send_ipi(first_cpu(cpu_online_map), IA64_CPEP_VECTOR, IA64_IPI_DM_INT, 0);
}
#endif /* CONFIG_ACPI */
static int
default_monarch_init_process(struct notifier_block *self, unsigned long val, void *data)
{
int c;
struct task_struct *g, *t;
if (val != DIE_INIT_MONARCH_PROCESS)
return NOTIFY_DONE;
#ifdef CONFIG_KEXEC
if (atomic_read(&kdump_in_progress))
return NOTIFY_DONE;
#endif
/*
* FIXME: mlogbuf will brim over with INIT stack dumps.
* To enable show_stack from INIT, we use oops_in_progress which should
* be used in real oops. This would cause something wrong after INIT.
*/
BREAK_LOGLEVEL(console_loglevel);
ia64_mlogbuf_dump_from_init();
printk(KERN_ERR "Processes interrupted by INIT -");
for_each_online_cpu(c) {
struct ia64_sal_os_state *s;
t = __va(__per_cpu_mca[c] + IA64_MCA_CPU_INIT_STACK_OFFSET);
s = (struct ia64_sal_os_state *)((char *)t + MCA_SOS_OFFSET);
g = s->prev_task;
if (g) {
if (g->pid)
printk(" %d", g->pid);
else
printk(" %d (cpu %d task 0x%p)", g->pid, task_cpu(g), g);
}
}
printk("\n\n");
if (read_trylock(&tasklist_lock)) {
do_each_thread (g, t) {
printk("\nBacktrace of pid %d (%s)\n", t->pid, t->comm);
show_stack(t, NULL);
} while_each_thread (g, t);
read_unlock(&tasklist_lock);
}
/* FIXME: This will not restore zapped printk locks. */
RESTORE_LOGLEVEL(console_loglevel);
return NOTIFY_DONE;
}
/*
* C portion of the OS INIT handler
*
* Called from ia64_os_init_dispatch
*
* Inputs: pointer to pt_regs where processor info was saved. SAL/OS state for
* this event. This code is used for both monarch and slave INIT events, see
* sos->monarch.
*
* All INIT events switch to the INIT stack and change the previous process to
* blocked status. If one of the INIT events is the monarch then we are
* probably processing the nmi button/command. Use the monarch cpu to dump all
* the processes. The slave INIT events all spin until the monarch cpu
* returns. We can also get INIT slave events for MCA, in which case the MCA
* process is the monarch.
*/
void
ia64_init_handler(struct pt_regs *regs, struct switch_stack *sw,
struct ia64_sal_os_state *sos)
{
static atomic_t slaves;
static atomic_t monarchs;
struct task_struct *previous_current;
int cpu = smp_processor_id();
struct ia64_mca_notify_die nd =
{ .sos = sos, .monarch_cpu = &monarch_cpu };
(void) notify_die(DIE_INIT_ENTER, "INIT", regs, (long)&nd, 0, 0);
mprintk(KERN_INFO "Entered OS INIT handler. PSP=%lx cpu=%d monarch=%ld\n",
sos->proc_state_param, cpu, sos->monarch);
salinfo_log_wakeup(SAL_INFO_TYPE_INIT, NULL, 0, 0);
previous_current = ia64_mca_modify_original_stack(regs, sw, sos, "INIT");
sos->os_status = IA64_INIT_RESUME;
/* FIXME: Workaround for broken proms that drive all INIT events as
* slaves. The last slave that enters is promoted to be a monarch.
* Remove this code in September 2006, that gives platforms a year to
* fix their proms and get their customers updated.
*/
if (!sos->monarch && atomic_add_return(1, &slaves) == num_online_cpus()) {
mprintk(KERN_WARNING "%s: Promoting cpu %d to monarch.\n",
__FUNCTION__, cpu);
atomic_dec(&slaves);
sos->monarch = 1;
}
/* FIXME: Workaround for broken proms that drive all INIT events as
* monarchs. Second and subsequent monarchs are demoted to slaves.
* Remove this code in September 2006, that gives platforms a year to
* fix their proms and get their customers updated.
*/
if (sos->monarch && atomic_add_return(1, &monarchs) > 1) {
mprintk(KERN_WARNING "%s: Demoting cpu %d to slave.\n",
__FUNCTION__, cpu);
atomic_dec(&monarchs);
sos->monarch = 0;
}
if (!sos->monarch) {
ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_INIT;
while (monarch_cpu == -1)
cpu_relax(); /* spin until monarch enters */
if (notify_die(DIE_INIT_SLAVE_ENTER, "INIT", regs, (long)&nd, 0, 0)
== NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
if (notify_die(DIE_INIT_SLAVE_PROCESS, "INIT", regs, (long)&nd, 0, 0)
== NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
while (monarch_cpu != -1)
cpu_relax(); /* spin until monarch leaves */
if (notify_die(DIE_INIT_SLAVE_LEAVE, "INIT", regs, (long)&nd, 0, 0)
== NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
mprintk("Slave on cpu %d returning to normal service.\n", cpu);
set_curr_task(cpu, previous_current);
ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_NOTDONE;
atomic_dec(&slaves);
return;
}
monarch_cpu = cpu;
if (notify_die(DIE_INIT_MONARCH_ENTER, "INIT", regs, (long)&nd, 0, 0)
== NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
/*
* Wait for a bit. On some machines (e.g., HP's zx2000 and zx6000, INIT can be
* generated via the BMC's command-line interface, but since the console is on the
* same serial line, the user will need some time to switch out of the BMC before
* the dump begins.
*/
mprintk("Delaying for 5 seconds...\n");
udelay(5*1000000);
ia64_wait_for_slaves(cpu, "INIT");
/* If nobody intercepts DIE_INIT_MONARCH_PROCESS then we drop through
* to default_monarch_init_process() above and just print all the
* tasks.
*/
if (notify_die(DIE_INIT_MONARCH_PROCESS, "INIT", regs, (long)&nd, 0, 0)
== NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
if (notify_die(DIE_INIT_MONARCH_LEAVE, "INIT", regs, (long)&nd, 0, 0)
== NOTIFY_STOP)
ia64_mca_spin(__FUNCTION__);
mprintk("\nINIT dump complete. Monarch on cpu %d returning to normal service.\n", cpu);
atomic_dec(&monarchs);
set_curr_task(cpu, previous_current);
monarch_cpu = -1;
return;
}
static int __init
ia64_mca_disable_cpe_polling(char *str)
{
cpe_poll_enabled = 0;
return 1;
}
__setup("disable_cpe_poll", ia64_mca_disable_cpe_polling);
static struct irqaction cmci_irqaction = {
.handler = ia64_mca_cmc_int_handler,
.flags = IRQF_DISABLED,
.name = "cmc_hndlr"
};
static struct irqaction cmcp_irqaction = {
.handler = ia64_mca_cmc_int_caller,
.flags = IRQF_DISABLED,
.name = "cmc_poll"
};
static struct irqaction mca_rdzv_irqaction = {
.handler = ia64_mca_rendez_int_handler,
.flags = IRQF_DISABLED,
.name = "mca_rdzv"
};
static struct irqaction mca_wkup_irqaction = {
.handler = ia64_mca_wakeup_int_handler,
.flags = IRQF_DISABLED,
.name = "mca_wkup"
};
#ifdef CONFIG_ACPI
static struct irqaction mca_cpe_irqaction = {
.handler = ia64_mca_cpe_int_handler,
.flags = IRQF_DISABLED,
.name = "cpe_hndlr"
};
static struct irqaction mca_cpep_irqaction = {
.handler = ia64_mca_cpe_int_caller,
.flags = IRQF_DISABLED,
.name = "cpe_poll"
};
#endif /* CONFIG_ACPI */
/* Minimal format of the MCA/INIT stacks. The pseudo processes that run on
* these stacks can never sleep, they cannot return from the kernel to user
* space, they do not appear in a normal ps listing. So there is no need to
* format most of the fields.
*/
static void __cpuinit
format_mca_init_stack(void *mca_data, unsigned long offset,
const char *type, int cpu)
{
struct task_struct *p = (struct task_struct *)((char *)mca_data + offset);
struct thread_info *ti;
memset(p, 0, KERNEL_STACK_SIZE);
ti = task_thread_info(p);
ti->flags = _TIF_MCA_INIT;
ti->preempt_count = 1;
ti->task = p;
ti->cpu = cpu;
p->stack = ti;
p->state = TASK_UNINTERRUPTIBLE;
cpu_set(cpu, p->cpus_allowed);
INIT_LIST_HEAD(&p->tasks);
p->parent = p->real_parent = p->group_leader = p;
INIT_LIST_HEAD(&p->children);
INIT_LIST_HEAD(&p->sibling);
strncpy(p->comm, type, sizeof(p->comm)-1);
}
/* Do per-CPU MCA-related initialization. */
void __cpuinit
ia64_mca_cpu_init(void *cpu_data)
{
void *pal_vaddr;
static int first_time = 1;
if (first_time) {
void *mca_data;
int cpu;
first_time = 0;
mca_data = alloc_bootmem(sizeof(struct ia64_mca_cpu)
* NR_CPUS + KERNEL_STACK_SIZE);
mca_data = (void *)(((unsigned long)mca_data +
KERNEL_STACK_SIZE - 1) &
(-KERNEL_STACK_SIZE));
for (cpu = 0; cpu < NR_CPUS; cpu++) {
format_mca_init_stack(mca_data,
offsetof(struct ia64_mca_cpu, mca_stack),
"MCA", cpu);
format_mca_init_stack(mca_data,
offsetof(struct ia64_mca_cpu, init_stack),
"INIT", cpu);
__per_cpu_mca[cpu] = __pa(mca_data);
mca_data += sizeof(struct ia64_mca_cpu);
}
}
/*
* The MCA info structure was allocated earlier and its
* physical address saved in __per_cpu_mca[cpu]. Copy that
* address * to ia64_mca_data so we can access it as a per-CPU
* variable.
*/
__get_cpu_var(ia64_mca_data) = __per_cpu_mca[smp_processor_id()];
/*
* Stash away a copy of the PTE needed to map the per-CPU page.
* We may need it during MCA recovery.
*/
__get_cpu_var(ia64_mca_per_cpu_pte) =
pte_val(mk_pte_phys(__pa(cpu_data), PAGE_KERNEL));
/*
* Also, stash away a copy of the PAL address and the PTE
* needed to map it.
*/
pal_vaddr = efi_get_pal_addr();
if (!pal_vaddr)
return;
__get_cpu_var(ia64_mca_pal_base) =
GRANULEROUNDDOWN((unsigned long) pal_vaddr);
__get_cpu_var(ia64_mca_pal_pte) = pte_val(mk_pte_phys(__pa(pal_vaddr),
PAGE_KERNEL));
}
/*
* ia64_mca_init
*
* Do all the system level mca specific initialization.
*
* 1. Register spinloop and wakeup request interrupt vectors
*
* 2. Register OS_MCA handler entry point
*
* 3. Register OS_INIT handler entry point
*
* 4. Initialize MCA/CMC/INIT related log buffers maintained by the OS.
*
* Note that this initialization is done very early before some kernel
* services are available.
*
* Inputs : None
*
* Outputs : None
*/
void __init
ia64_mca_init(void)
{
ia64_fptr_t *init_hldlr_ptr_monarch = (ia64_fptr_t *)ia64_os_init_dispatch_monarch;
ia64_fptr_t *init_hldlr_ptr_slave = (ia64_fptr_t *)ia64_os_init_dispatch_slave;
ia64_fptr_t *mca_hldlr_ptr = (ia64_fptr_t *)ia64_os_mca_dispatch;
int i;
s64 rc;
struct ia64_sal_retval isrv;
u64 timeout = IA64_MCA_RENDEZ_TIMEOUT; /* platform specific */
static struct notifier_block default_init_monarch_nb = {
.notifier_call = default_monarch_init_process,
.priority = 0/* we need to notified last */
};
IA64_MCA_DEBUG("%s: begin\n", __FUNCTION__);
/* Clear the Rendez checkin flag for all cpus */
for(i = 0 ; i < NR_CPUS; i++)
ia64_mc_info.imi_rendez_checkin[i] = IA64_MCA_RENDEZ_CHECKIN_NOTDONE;
/*
* Register the rendezvous spinloop and wakeup mechanism with SAL
*/
/* Register the rendezvous interrupt vector with SAL */
while (1) {
isrv = ia64_sal_mc_set_params(SAL_MC_PARAM_RENDEZ_INT,
SAL_MC_PARAM_MECHANISM_INT,
IA64_MCA_RENDEZ_VECTOR,
timeout,
SAL_MC_PARAM_RZ_ALWAYS);
rc = isrv.status;
if (rc == 0)
break;
if (rc == -2) {
printk(KERN_INFO "Increasing MCA rendezvous timeout from "
"%ld to %ld milliseconds\n", timeout, isrv.v0);
timeout = isrv.v0;
(void) notify_die(DIE_MCA_NEW_TIMEOUT, "MCA", NULL, timeout, 0, 0);
continue;
}
printk(KERN_ERR "Failed to register rendezvous interrupt "
"with SAL (status %ld)\n", rc);
return;
}
/* Register the wakeup interrupt vector with SAL */
isrv = ia64_sal_mc_set_params(SAL_MC_PARAM_RENDEZ_WAKEUP,
SAL_MC_PARAM_MECHANISM_INT,
IA64_MCA_WAKEUP_VECTOR,
0, 0);
rc = isrv.status;
if (rc) {
printk(KERN_ERR "Failed to register wakeup interrupt with SAL "
"(status %ld)\n", rc);
return;
}
IA64_MCA_DEBUG("%s: registered MCA rendezvous spinloop and wakeup mech.\n", __FUNCTION__);
ia64_mc_info.imi_mca_handler = ia64_tpa(mca_hldlr_ptr->fp);
/*
* XXX - disable SAL checksum by setting size to 0; should be
* ia64_tpa(ia64_os_mca_dispatch_end) - ia64_tpa(ia64_os_mca_dispatch);
*/
ia64_mc_info.imi_mca_handler_size = 0;
/* Register the os mca handler with SAL */
if ((rc = ia64_sal_set_vectors(SAL_VECTOR_OS_MCA,
ia64_mc_info.imi_mca_handler,
ia64_tpa(mca_hldlr_ptr->gp),
ia64_mc_info.imi_mca_handler_size,
0, 0, 0)))
{
printk(KERN_ERR "Failed to register OS MCA handler with SAL "
"(status %ld)\n", rc);
return;
}
IA64_MCA_DEBUG("%s: registered OS MCA handler with SAL at 0x%lx, gp = 0x%lx\n", __FUNCTION__,
ia64_mc_info.imi_mca_handler, ia64_tpa(mca_hldlr_ptr->gp));
/*
* XXX - disable SAL checksum by setting size to 0, should be
* size of the actual init handler in mca_asm.S.
*/
ia64_mc_info.imi_monarch_init_handler = ia64_tpa(init_hldlr_ptr_monarch->fp);
ia64_mc_info.imi_monarch_init_handler_size = 0;
ia64_mc_info.imi_slave_init_handler = ia64_tpa(init_hldlr_ptr_slave->fp);
ia64_mc_info.imi_slave_init_handler_size = 0;
IA64_MCA_DEBUG("%s: OS INIT handler at %lx\n", __FUNCTION__,
ia64_mc_info.imi_monarch_init_handler);
/* Register the os init handler with SAL */
if ((rc = ia64_sal_set_vectors(SAL_VECTOR_OS_INIT,
ia64_mc_info.imi_monarch_init_handler,
ia64_tpa(ia64_getreg(_IA64_REG_GP)),
ia64_mc_info.imi_monarch_init_handler_size,
ia64_mc_info.imi_slave_init_handler,
ia64_tpa(ia64_getreg(_IA64_REG_GP)),
ia64_mc_info.imi_slave_init_handler_size)))
{
printk(KERN_ERR "Failed to register m/s INIT handlers with SAL "
"(status %ld)\n", rc);
return;
}
if (register_die_notifier(&default_init_monarch_nb)) {
printk(KERN_ERR "Failed to register default monarch INIT process\n");
return;
}
IA64_MCA_DEBUG("%s: registered OS INIT handler with SAL\n", __FUNCTION__);
/*
* Configure the CMCI/P vector and handler. Interrupts for CMC are
* per-processor, so AP CMC interrupts are setup in smp_callin() (smpboot.c).
*/
register_percpu_irq(IA64_CMC_VECTOR, &cmci_irqaction);
register_percpu_irq(IA64_CMCP_VECTOR, &cmcp_irqaction);
ia64_mca_cmc_vector_setup(); /* Setup vector on BSP */
/* Setup the MCA rendezvous interrupt vector */
register_percpu_irq(IA64_MCA_RENDEZ_VECTOR, &mca_rdzv_irqaction);
/* Setup the MCA wakeup interrupt vector */
register_percpu_irq(IA64_MCA_WAKEUP_VECTOR, &mca_wkup_irqaction);
#ifdef CONFIG_ACPI
/* Setup the CPEI/P handler */
register_percpu_irq(IA64_CPEP_VECTOR, &mca_cpep_irqaction);
#endif
/* Initialize the areas set aside by the OS to buffer the
* platform/processor error states for MCA/INIT/CMC
* handling.
*/
ia64_log_init(SAL_INFO_TYPE_MCA);
ia64_log_init(SAL_INFO_TYPE_INIT);
ia64_log_init(SAL_INFO_TYPE_CMC);
ia64_log_init(SAL_INFO_TYPE_CPE);
mca_init = 1;
printk(KERN_INFO "MCA related initialization done\n");
}
/*
* ia64_mca_late_init
*
* Opportunity to setup things that require initialization later
* than ia64_mca_init. Setup a timer to poll for CPEs if the
* platform doesn't support an interrupt driven mechanism.
*
* Inputs : None
* Outputs : Status
*/
static int __init
ia64_mca_late_init(void)
{
if (!mca_init)
return 0;
/* Setup the CMCI/P vector and handler */
init_timer(&cmc_poll_timer);
cmc_poll_timer.function = ia64_mca_cmc_poll;
/* Unmask/enable the vector */
cmc_polling_enabled = 0;
schedule_work(&cmc_enable_work);
IA64_MCA_DEBUG("%s: CMCI/P setup and enabled.\n", __FUNCTION__);
#ifdef CONFIG_ACPI
/* Setup the CPEI/P vector and handler */
cpe_vector = acpi_request_vector(ACPI_INTERRUPT_CPEI);
init_timer(&cpe_poll_timer);
cpe_poll_timer.function = ia64_mca_cpe_poll;
{
irq_desc_t *desc;
unsigned int irq;
if (cpe_vector >= 0) {
/* If platform supports CPEI, enable the irq. */
cpe_poll_enabled = 0;
for (irq = 0; irq < NR_IRQS; ++irq)
if (irq_to_vector(irq) == cpe_vector) {
desc = irq_desc + irq;
desc->status |= IRQ_PER_CPU;
setup_irq(irq, &mca_cpe_irqaction);
ia64_cpe_irq = irq;
}
ia64_mca_register_cpev(cpe_vector);
IA64_MCA_DEBUG("%s: CPEI/P setup and enabled.\n", __FUNCTION__);
} else {
/* If platform doesn't support CPEI, get the timer going. */
if (cpe_poll_enabled) {
ia64_mca_cpe_poll(0UL);
IA64_MCA_DEBUG("%s: CPEP setup and enabled.\n", __FUNCTION__);
}
}
}
#endif
return 0;
}
device_initcall(ia64_mca_late_init);