mm: hugetlb: fix hugepage memory leak caused by wrong reserve count

[linux/fpc-iii.git] / arch / ia64 / kernel / mca.c

/*
 * File:        mca.c
 * Purpose:     Generic MCA handling layer
 *
 * 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, 2004-2008 Silicon Graphics, Inc.
 * Copyright (C) Vijay Chander <vijay@engr.sgi.com>
 *
 * Copyright (C) 2006 FUJITSU LIMITED
 * Copyright (C) Hidetoshi Seto <seto.hidetoshi@jp.fujitsu.com>
 *
 * 2000-03-29 Chuck Fleckenstein <cfleck@co.intel.com>
 *            Fixed PAL/SAL update issues, began MCA bug fixes, logging issues,
 *            added min save state dump, added INIT handler.
 *
 * 2001-01-03 Fred Lewis <frederick.v.lewis@intel.com>
 *            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.
 *
 * 2002-01-04 Jenna Hall <jenna.s.hall@intel.com>
 *            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().
 *
 * 2002-03-25 Matt Domsch <Matt_Domsch@dell.com>
 *            GUID cleanups.
 *
 * 2003-04-15 David Mosberger-Tang <davidm@hpl.hp.com>
 *            Added INIT backtrace support.
 *
 * 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/jiffies.h>
#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 <linux/cpu.h>
#include <linux/gfp.h>

#include <asm/delay.h>
#include <asm/machvec.h>
#include <asm/meminit.h>
#include <asm/page.h>
#include <asm/ptrace.h>
#include <asm/sal.h>
#include <asm/mca.h>
#include <asm/kexec.h>

#include <asm/irq.h>
#include <asm/hw_irq.h>
#include <asm/tlb.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

#define NOTIFY_INIT(event, regs, arg, spin)                             \
do {                                                                    \
        if ((notify_die((event), "INIT", (regs), (arg), 0, 0)           \
                        == NOTIFY_STOP) && ((spin) == 1))               \
                ia64_mca_spin(__func__);                                \
} while (0)

#define NOTIFY_MCA(event, regs, arg, spin)                              \
do {                                                                    \
        if ((notify_die((event), "MCA", (regs), (arg), 0, 0)            \
                        == NOTIFY_STOP) && ((spin) == 1))               \
                ia64_mca_spin(__func__);                                \
} while (0)

/* 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 */
DEFINE_PER_CPU(u64, ia64_mca_tr_reload);   /* Flag for TR reload */

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("%s", 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("%s", 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 &&
                        time_before(jiffies, mlogbuf_timestamp + 30 * HZ)) {
                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",
                                       __func__, 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",
                       __func__, 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);

        local_irq_disable();

        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
 */
void
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", __func__, 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
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",
                       __func__, smp_processor_id(), IA64_CMC_VECTOR);

        IA64_MCA_DEBUG("%s: CPU %d CMCV = %#016lx\n",
                       __func__, 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",
                       __func__, 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",
                       __func__, 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, 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, 0);
}

/*
 * ia64_mca_wakeup
 *
 *      Send an inter-cpu interrupt to wake-up a particular cpu.
 *
 *  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_mca_wakeup_all
 *
 *      Wakeup all the slave 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.  The state
 *      IA64_MCA_RENDEZ_CHECKIN_DONE indicates the cpu is rendez'ed
 *      in SAL.  The state IA64_MCA_RENDEZ_CHECKIN_NOTDONE indicates
 *      the cpu has come out of OS rendezvous.
 *
 *  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);

        NOTIFY_MCA(DIE_MCA_RENDZVOUS_ENTER, get_irq_regs(), (long)&nd, 1);

        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();

        NOTIFY_MCA(DIE_MCA_RENDZVOUS_PROCESS, get_irq_regs(), (long)&nd, 1);

        /* Wait for the monarch cpu to exit. */
        while (monarch_cpu != -1)
               cpu_relax();     /* spin until monarch leaves */

        NOTIFY_MCA(DIE_MCA_RENDZVOUS_LEAVE, get_irq_regs(), (long)&nd, 1);

        ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_NOTDONE;
        /* 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, unsigned long *tr, unsigned long *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));
}

static void
finish_pt_regs(struct pt_regs *regs, struct ia64_sal_os_state *sos,
                unsigned long *nat)
{
        const pal_min_state_area_t *ms = sos->pal_min_state;
        const u64 *bank;

        /* If ipsr.ic then use pmsa_{iip,ipsr,ifs}, else use
         * pmsa_{xip,xpsr,xfs}
         */
        if (ia64_psr(regs)->ic) {
                regs->cr_iip = ms->pmsa_iip;
                regs->cr_ipsr = ms->pmsa_ipsr;
                regs->cr_ifs = ms->pmsa_ifs;
        } else {
                regs->cr_iip = ms->pmsa_xip;
                regs->cr_ipsr = ms->pmsa_xpsr;
                regs->cr_ifs = ms->pmsa_xfs;

                sos->iip = ms->pmsa_iip;
                sos->ipsr = ms->pmsa_ipsr;
                sos->ifs = ms->pmsa_ifs;
        }
        regs->pr = ms->pmsa_pr;
        regs->b0 = ms->pmsa_br0;
        regs->ar_rsc = ms->pmsa_rsc;
        copy_reg(&ms->pmsa_gr[1-1], ms->pmsa_nat_bits, &regs->r1, nat);
        copy_reg(&ms->pmsa_gr[2-1], ms->pmsa_nat_bits, &regs->r2, nat);
        copy_reg(&ms->pmsa_gr[3-1], ms->pmsa_nat_bits, &regs->r3, nat);
        copy_reg(&ms->pmsa_gr[8-1], ms->pmsa_nat_bits, &regs->r8, nat);
        copy_reg(&ms->pmsa_gr[9-1], ms->pmsa_nat_bits, &regs->r9, nat);
        copy_reg(&ms->pmsa_gr[10-1], ms->pmsa_nat_bits, &regs->r10, nat);
        copy_reg(&ms->pmsa_gr[11-1], ms->pmsa_nat_bits, &regs->r11, nat);
        copy_reg(&ms->pmsa_gr[12-1], ms->pmsa_nat_bits, &regs->r12, nat);
        copy_reg(&ms->pmsa_gr[13-1], ms->pmsa_nat_bits, &regs->r13, nat);
        copy_reg(&ms->pmsa_gr[14-1], ms->pmsa_nat_bits, &regs->r14, nat);
        copy_reg(&ms->pmsa_gr[15-1], ms->pmsa_nat_bits, &regs->r15, nat);
        if (ia64_psr(regs)->bn)
                bank = ms->pmsa_bank1_gr;
        else
                bank = ms->pmsa_bank0_gr;
        copy_reg(&bank[16-16], ms->pmsa_nat_bits, &regs->r16, nat);
        copy_reg(&bank[17-16], ms->pmsa_nat_bits, &regs->r17, nat);
        copy_reg(&bank[18-16], ms->pmsa_nat_bits, &regs->r18, nat);
        copy_reg(&bank[19-16], ms->pmsa_nat_bits, &regs->r19, nat);
        copy_reg(&bank[20-16], ms->pmsa_nat_bits, &regs->r20, nat);
        copy_reg(&bank[21-16], ms->pmsa_nat_bits, &regs->r21, nat);
        copy_reg(&bank[22-16], ms->pmsa_nat_bits, &regs->r22, nat);
        copy_reg(&bank[23-16], ms->pmsa_nat_bits, &regs->r23, nat);
        copy_reg(&bank[24-16], ms->pmsa_nat_bits, &regs->r24, nat);
        copy_reg(&bank[25-16], ms->pmsa_nat_bits, &regs->r25, nat);
        copy_reg(&bank[26-16], ms->pmsa_nat_bits, &regs->r26, nat);
        copy_reg(&bank[27-16], ms->pmsa_nat_bits, &regs->r27, nat);
        copy_reg(&bank[28-16], ms->pmsa_nat_bits, &regs->r28, nat);
        copy_reg(&bank[29-16], ms->pmsa_nat_bits, &regs->r29, nat);
        copy_reg(&bank[30-16], ms->pmsa_nat_bits, &regs->r30, nat);
        copy_reg(&bank[31-16], ms->pmsa_nat_bits, &regs->r31, nat);
}

/* 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;
        unsigned long *old_bspstore, *old_bsp;
        unsigned long *new_bspstore, *new_bsp;
        unsigned long 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 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 = (unsigned long *)ar_bspstore;
        old_bsp = (unsigned long *)ar_bsp;
        slots = ia64_rse_num_regs(old_bspstore, old_bsp);
        new_bspstore = (unsigned long *)((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));
        old_regs->loadrs = loadrs;
        old_unat = old_regs->ar_unat;
        finish_pt_regs(old_regs, sos, &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:
        mprintk(KERN_INFO "cpu %d, %s %s, original stack not modified\n",
                        smp_processor_id(), type, msg);
        old_unat = regs->ar_unat;
        finish_pt_regs(regs, sos, &old_unat);
        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, i , wait;

        /*
         * wait 5 seconds total for slaves (arbitrary)
         */
        for (i = 0; i < 5000; i++) {
                wait = 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 */
                                wait = 1;
                                break;
                        }
                }
                if (!wait)
                        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;
}

/*  mca_insert_tr
 *
 *  Switch rid when TR reload and needed!
 *  iord: 1: itr, 2: itr;
 *
*/
static void mca_insert_tr(u64 iord)
{

        int i;
        u64 old_rr;
        struct ia64_tr_entry *p;
        unsigned long psr;
        int cpu = smp_processor_id();

        if (!ia64_idtrs[cpu])
                return;

        psr = ia64_clear_ic();
        for (i = IA64_TR_ALLOC_BASE; i < IA64_TR_ALLOC_MAX; i++) {
                p = ia64_idtrs[cpu] + (iord - 1) * IA64_TR_ALLOC_MAX;
                if (p->pte & 0x1) {
                        old_rr = ia64_get_rr(p->ifa);
                        if (old_rr != p->rr) {
                                ia64_set_rr(p->ifa, p->rr);
                                ia64_srlz_d();
                        }
                        ia64_ptr(iord, p->ifa, p->itir >> 2);
                        ia64_srlz_i();
                        if (iord & 0x1) {
                                ia64_itr(0x1, i, p->ifa, p->pte, p->itir >> 2);
                                ia64_srlz_i();
                        }
                        if (iord & 0x2) {
                                ia64_itr(0x2, i, p->ifa, p->pte, p->itir >> 2);
                                ia64_srlz_i();
                        }
                        if (old_rr != p->rr) {
                                ia64_set_rr(p->ifa, old_rr);
                                ia64_srlz_d();
                        }
                }
        }
        ia64_set_psr(psr);
}

/*
 * 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, .data = &recover };
        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 {
                cpumask_set_cpu(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");

        NOTIFY_MCA(DIE_MCA_MONARCH_ENTER, regs, (long)&nd, 1);

        ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_CONCURRENT_MCA;
        if (sos->monarch) {
                ia64_wait_for_slaves(cpu, "MCA");

                /* 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();
        } else {
                while (cpumask_test_cpu(cpu, &mca_cpu))
                        cpu_relax();    /* spin until monarch wakes us */
        }

        NOTIFY_MCA(DIE_MCA_MONARCH_PROCESS, regs, (long)&nd, 1);

        /* 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);
        }

        if (__this_cpu_read(ia64_mca_tr_reload)) {
                mca_insert_tr(0x1); /*Reload dynamic itrs*/
                mca_insert_tr(0x2); /*Reload dynamic itrs*/
        }

        NOTIFY_MCA(DIE_MCA_MONARCH_LEAVE, regs, (long)&nd, 1);

        if (atomic_dec_return(&mca_count) > 0) {
                int i;

                /* wake up the next monarch cpu,
                 * and put this cpu in the rendez loop.
                 */
                for_each_online_cpu(i) {
                        if (cpumask_test_cpu(i, &mca_cpu)) {
                                monarch_cpu = i;
                                cpumask_clear_cpu(i, &mca_cpu); /* wake next cpu */
                                while (monarch_cpu != -1)
                                        cpu_relax();    /* spin until last cpu leaves */
                                set_curr_task(cpu, previous_current);
                                ia64_mc_info.imi_rendez_checkin[cpu]
                                                = IA64_MCA_RENDEZ_CHECKIN_NOTDONE;
                                return;
                        }
                }
        }
        set_curr_task(cpu, previous_current);
        ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_NOTDONE;
        monarch_cpu = -1;       /* This frees the slaves and previous monarchs */
}

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",
                       __func__, 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);

        local_irq_disable();

        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);

        cpuid = cpumask_next(cpuid+1, cpu_online_mask);

        if (cpuid < nr_cpu_ids) {
                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(cpumask_first(cpu_online_mask), 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);

        cpuid = cpumask_next(cpuid+1, cpu_online_mask);

        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(cpumask_first(cpu_online_mask), 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 };

        NOTIFY_INIT(DIE_INIT_ENTER, regs, (long)&nd, 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",
                        __func__, 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",
                               __func__, cpu);
                atomic_dec(&monarchs);
                sos->monarch = 0;
        }

        if (!sos->monarch) {
                ia64_mc_info.imi_rendez_checkin[cpu] = IA64_MCA_RENDEZ_CHECKIN_INIT;

#ifdef CONFIG_KEXEC
                while (monarch_cpu == -1 && !atomic_read(&kdump_in_progress))
                        udelay(1000);
#else
                while (monarch_cpu == -1)
                        cpu_relax();    /* spin until monarch enters */
#endif

                NOTIFY_INIT(DIE_INIT_SLAVE_ENTER, regs, (long)&nd, 1);
                NOTIFY_INIT(DIE_INIT_SLAVE_PROCESS, regs, (long)&nd, 1);

#ifdef CONFIG_KEXEC
                while (monarch_cpu != -1 && !atomic_read(&kdump_in_progress))
                        udelay(1000);
#else
                while (monarch_cpu != -1)
                        cpu_relax();    /* spin until monarch leaves */
#endif

                NOTIFY_INIT(DIE_INIT_SLAVE_LEAVE, regs, (long)&nd, 1);

                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;
        NOTIFY_INIT(DIE_INIT_MONARCH_ENTER, regs, (long)&nd, 1);

        /*
         * 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.
         */
        NOTIFY_INIT(DIE_INIT_MONARCH_PROCESS, regs, (long)&nd, 1);
        NOTIFY_INIT(DIE_INIT_MONARCH_LEAVE, regs, (long)&nd, 1);

        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,
        .name =         "cmc_hndlr"
};

static struct irqaction cmcp_irqaction = {
        .handler =      ia64_mca_cmc_int_caller,
        .name =         "cmc_poll"
};

static struct irqaction mca_rdzv_irqaction = {
        .handler =      ia64_mca_rendez_int_handler,
        .name =         "mca_rdzv"
};

static struct irqaction mca_wkup_irqaction = {
        .handler =      ia64_mca_wakeup_int_handler,
        .name =         "mca_wkup"
};

#ifdef CONFIG_ACPI
static struct irqaction mca_cpe_irqaction = {
        .handler =      ia64_mca_cpe_int_handler,
        .name =         "cpe_hndlr"
};

static struct irqaction mca_cpep_irqaction = {
        .handler =      ia64_mca_cpe_int_caller,
        .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
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;
        cpumask_set_cpu(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);
}

/* Caller prevents this from being called after init */
static void * __init_refok mca_bootmem(void)
{
        return __alloc_bootmem(sizeof(struct ia64_mca_cpu),
                            KERNEL_STACK_SIZE, 0);
}

/* Do per-CPU MCA-related initialization.  */
void
ia64_mca_cpu_init(void *cpu_data)
{
        void *pal_vaddr;
        void *data;
        long sz = sizeof(struct ia64_mca_cpu);
        int cpu = smp_processor_id();
        static int first_time = 1;

        /*
         * Structure will already be allocated if cpu has been online,
         * then offlined.
         */
        if (__per_cpu_mca[cpu]) {
                data = __va(__per_cpu_mca[cpu]);
        } else {
                if (first_time) {
                        data = mca_bootmem();
                        first_time = 0;
                } else
                        data = (void *)__get_free_pages(GFP_KERNEL,
                                                        get_order(sz));
                if (!data)
                        panic("Could not allocate MCA memory for cpu %d\n",
                                        cpu);
        }
        format_mca_init_stack(data, offsetof(struct ia64_mca_cpu, mca_stack),
                "MCA", cpu);
        format_mca_init_stack(data, offsetof(struct ia64_mca_cpu, init_stack),
                "INIT", cpu);
        __this_cpu_write(ia64_mca_data, (__per_cpu_mca[cpu] = __pa(data)));

        /*
         * Stash away a copy of the PTE needed to map the per-CPU page.
         * We may need it during MCA recovery.
         */
        __this_cpu_write(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;
        __this_cpu_write(ia64_mca_pal_base,
                GRANULEROUNDDOWN((unsigned long) pal_vaddr));
        __this_cpu_write(ia64_mca_pal_pte, pte_val(mk_pte_phys(__pa(pal_vaddr),
                                                              PAGE_KERNEL)));
}

static void ia64_mca_cmc_vector_adjust(void *dummy)
{
        unsigned long flags;

        local_irq_save(flags);
        if (!cmc_polling_enabled)
                ia64_mca_cmc_vector_enable(NULL);
        local_irq_restore(flags);
}

static int mca_cpu_callback(struct notifier_block *nfb,
                                      unsigned long action,
                                      void *hcpu)
{
        int hotcpu = (unsigned long) hcpu;

        switch (action) {
        case CPU_ONLINE:
        case CPU_ONLINE_FROZEN:
                smp_call_function_single(hotcpu, ia64_mca_cmc_vector_adjust,
                                         NULL, 0);
                break;
        }
        return NOTIFY_OK;
}

static struct notifier_block mca_cpu_notifier = {
        .notifier_call = mca_cpu_callback
};

/*
 * 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;
        long rc;
        struct ia64_sal_retval isrv;
        unsigned long 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", __func__);

        /* 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;
                        NOTIFY_MCA(DIE_MCA_NEW_TIMEOUT, NULL, timeout, 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", __func__);

        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", __func__,
                       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", __func__,
                       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", __func__);

        /* 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");
}


/*
 * These pieces cannot be done in ia64_mca_init() because it is called before
 * early_irq_init() which would wipe out our percpu irq registrations. But we
 * cannot leave them until ia64_mca_late_init() because by then all the other
 * processors have been brought online and have set their own CMC vectors to
 * point at a non-existant action. Called from arch_early_irq_init().
 */
void __init ia64_mca_irq_init(void)
{
        /*
         *  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
}

/*
 * 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;

        register_hotcpu_notifier(&mca_cpu_notifier);

        /* Setup the CMCI/P vector and handler */
        setup_timer(&cmc_poll_timer, ia64_mca_cmc_poll, 0UL);

        /* Unmask/enable the vector */
        cmc_polling_enabled = 0;
        schedule_work(&cmc_enable_work);

        IA64_MCA_DEBUG("%s: CMCI/P setup and enabled.\n", __func__);

#ifdef CONFIG_ACPI
        /* Setup the CPEI/P vector and handler */
        cpe_vector = acpi_request_vector(ACPI_INTERRUPT_CPEI);
        setup_timer(&cpe_poll_timer, ia64_mca_cpe_poll, 0UL);

        {
                unsigned int irq;

                if (cpe_vector >= 0) {
                        /* If platform supports CPEI, enable the irq. */
                        irq = local_vector_to_irq(cpe_vector);
                        if (irq > 0) {
                                cpe_poll_enabled = 0;
                                irq_set_status_flags(irq, 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",
                                        __func__);
                                return 0;
                        }
                        printk(KERN_ERR "%s: Failed to find irq for CPE "
                                        "interrupt handler, vector %d\n",
                                        __func__, cpe_vector);
                }
                /* 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", __func__);
                }
        }
#endif

        return 0;
}

device_initcall(ia64_mca_late_init);