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[/] [or1k/] [trunk/] [linux/] [linux-2.4/] [arch/] [ia64/] [kernel/] [mca.c] - Rev 1275
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/* * 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. */ #include <linux/config.h> #include <linux/types.h> #include <linux/init.h> #include <linux/sched.h> #include <linux/interrupt.h> #include <linux/irq.h> #include <linux/smp_lock.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/tqueue.h> #include <asm/delay.h> #include <asm/machvec.h> #include <asm/page.h> #include <asm/ptrace.h> #include <asm/system.h> #include <asm/sal.h> #include <asm/mca.h> #include <asm/irq.h> #include <asm/hw_irq.h> #if defined(IA64_MCA_DEBUG_INFO) # define IA64_MCA_DEBUG(fmt...) printk(fmt) #else # define IA64_MCA_DEBUG(fmt...) #endif extern void show_stack(struct task_struct *); typedef struct ia64_fptr { unsigned long fp; unsigned long gp; } ia64_fptr_t; /* Used by mca_asm.S */ ia64_mca_sal_to_os_state_t ia64_sal_to_os_handoff_state; ia64_mca_os_to_sal_state_t ia64_os_to_sal_handoff_state; u64 ia64_mca_proc_state_dump[512]; u64 ia64_mca_stack[1024] __attribute__((aligned(16))); u64 ia64_mca_stackframe[32]; u64 ia64_mca_bspstore[1024]; u64 ia64_init_stack[INIT_TASK_SIZE/8] __attribute__((aligned(16))); u64 ia64_mca_serialize; /* In mca_asm.S */ extern void ia64_monarch_init_handler (void); extern void ia64_slave_init_handler (void); static ia64_mc_info_t ia64_mc_info; extern struct hw_interrupt_type irq_type_iosapic_level; struct ia64_mca_tlb_info ia64_mca_tlb_list[NR_CPUS]; #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 CMC_HISTORY_LENGTH 5 static struct timer_list cpe_poll_timer; 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 struct tq_struct cmc_disable_tq, cmc_enable_tq; /* * 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 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; int 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/INIT) */ static void ia64_mca_log_sal_error_record(int sal_info_type) { u8 *buffer; u64 size; int irq_safe = sal_info_type != SAL_INFO_TYPE_MCA && sal_info_type != SAL_INFO_TYPE_INIT; static const char * const rec_name[] = { "MCA", "INIT", "CMC", "CPE" }; 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) printk(KERN_INFO "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 */ if (sal_info_type == SAL_INFO_TYPE_CPE || sal_info_type == SAL_INFO_TYPE_CMC) ia64_sal_clear_state_info(sal_info_type); } /* * platform dependent error handling */ #ifndef PLATFORM_MCA_HANDLERS static void ia64_mca_cpe_int_handler (int cpe_irq, void *arg, struct pt_regs *ptregs) { IA64_MCA_DEBUG("%s: received interrupt. CPU:%d vector = %#x\n", __FUNCTION__, smp_processor_id(), cpe_irq); /* SAL spec states this should run w/ interrupts enabled */ local_irq_enable(); /* Get the CMC error record and log it */ ia64_mca_log_sal_error_record(SAL_INFO_TYPE_CPE); } #define print_symbol(fmt, addr) printk(fmt, "(no symbol)"); static void show_min_state (pal_min_state_area_t *minstate) { u64 iip = minstate->pmsa_iip + ((struct ia64_psr *)(&minstate->pmsa_ipsr))->ri; u64 xip = minstate->pmsa_xip + ((struct ia64_psr *)(&minstate->pmsa_xpsr))->ri; printk("NaT bits\t%016lx\n", minstate->pmsa_nat_bits); printk("pr\t\t%016lx\n", minstate->pmsa_pr); printk("b0\t\t%016lx ", minstate->pmsa_br0); print_symbol("%s\n", minstate->pmsa_br0); printk("ar.rsc\t\t%016lx\n", minstate->pmsa_rsc); printk("cr.iip\t\t%016lx ", iip); print_symbol("%s\n", iip); printk("cr.ipsr\t\t%016lx\n", minstate->pmsa_ipsr); printk("cr.ifs\t\t%016lx\n", minstate->pmsa_ifs); printk("xip\t\t%016lx ", xip); print_symbol("%s\n", xip); printk("xpsr\t\t%016lx\n", minstate->pmsa_xpsr); printk("xfs\t\t%016lx\n", minstate->pmsa_xfs); printk("b1\t\t%016lx ", minstate->pmsa_br1); print_symbol("%s\n", minstate->pmsa_br1); printk("\nstatic registers r0-r15:\n"); printk(" r0- 3 %016lx %016lx %016lx %016lx\n", 0UL, minstate->pmsa_gr[0], minstate->pmsa_gr[1], minstate->pmsa_gr[2]); printk(" r4- 7 %016lx %016lx %016lx %016lx\n", minstate->pmsa_gr[3], minstate->pmsa_gr[4], minstate->pmsa_gr[5], minstate->pmsa_gr[6]); printk(" r8-11 %016lx %016lx %016lx %016lx\n", minstate->pmsa_gr[7], minstate->pmsa_gr[8], minstate->pmsa_gr[9], minstate->pmsa_gr[10]); printk("r12-15 %016lx %016lx %016lx %016lx\n", minstate->pmsa_gr[11], minstate->pmsa_gr[12], minstate->pmsa_gr[13], minstate->pmsa_gr[14]); printk("\nbank 0:\n"); printk("r16-19 %016lx %016lx %016lx %016lx\n", minstate->pmsa_bank0_gr[0], minstate->pmsa_bank0_gr[1], minstate->pmsa_bank0_gr[2], minstate->pmsa_bank0_gr[3]); printk("r20-23 %016lx %016lx %016lx %016lx\n", minstate->pmsa_bank0_gr[4], minstate->pmsa_bank0_gr[5], minstate->pmsa_bank0_gr[6], minstate->pmsa_bank0_gr[7]); printk("r24-27 %016lx %016lx %016lx %016lx\n", minstate->pmsa_bank0_gr[8], minstate->pmsa_bank0_gr[9], minstate->pmsa_bank0_gr[10], minstate->pmsa_bank0_gr[11]); printk("r28-31 %016lx %016lx %016lx %016lx\n", minstate->pmsa_bank0_gr[12], minstate->pmsa_bank0_gr[13], minstate->pmsa_bank0_gr[14], minstate->pmsa_bank0_gr[15]); printk("\nbank 1:\n"); printk("r16-19 %016lx %016lx %016lx %016lx\n", minstate->pmsa_bank1_gr[0], minstate->pmsa_bank1_gr[1], minstate->pmsa_bank1_gr[2], minstate->pmsa_bank1_gr[3]); printk("r20-23 %016lx %016lx %016lx %016lx\n", minstate->pmsa_bank1_gr[4], minstate->pmsa_bank1_gr[5], minstate->pmsa_bank1_gr[6], minstate->pmsa_bank1_gr[7]); printk("r24-27 %016lx %016lx %016lx %016lx\n", minstate->pmsa_bank1_gr[8], minstate->pmsa_bank1_gr[9], minstate->pmsa_bank1_gr[10], minstate->pmsa_bank1_gr[11]); printk("r28-31 %016lx %016lx %016lx %016lx\n", minstate->pmsa_bank1_gr[12], minstate->pmsa_bank1_gr[13], minstate->pmsa_bank1_gr[14], minstate->pmsa_bank1_gr[15]); } static void fetch_min_state (pal_min_state_area_t *ms, struct pt_regs *pt, struct switch_stack *sw) { u64 *dst_banked, *src_banked, bit, shift, nat_bits; int i; /* * First, update the pt-regs and switch-stack structures with the contents stored * in the min-state area: */ if (((struct ia64_psr *) &ms->pmsa_ipsr)->ic == 0) { pt->cr_ipsr = ms->pmsa_xpsr; pt->cr_iip = ms->pmsa_xip; pt->cr_ifs = ms->pmsa_xfs; } else { pt->cr_ipsr = ms->pmsa_ipsr; pt->cr_iip = ms->pmsa_iip; pt->cr_ifs = ms->pmsa_ifs; } pt->ar_rsc = ms->pmsa_rsc; pt->pr = ms->pmsa_pr; pt->r1 = ms->pmsa_gr[0]; pt->r2 = ms->pmsa_gr[1]; pt->r3 = ms->pmsa_gr[2]; sw->r4 = ms->pmsa_gr[3]; sw->r5 = ms->pmsa_gr[4]; sw->r6 = ms->pmsa_gr[5]; sw->r7 = ms->pmsa_gr[6]; pt->r8 = ms->pmsa_gr[7]; pt->r9 = ms->pmsa_gr[8]; pt->r10 = ms->pmsa_gr[9]; pt->r11 = ms->pmsa_gr[10]; pt->r12 = ms->pmsa_gr[11]; pt->r13 = ms->pmsa_gr[12]; pt->r14 = ms->pmsa_gr[13]; pt->r15 = ms->pmsa_gr[14]; dst_banked = &pt->r16; /* r16-r31 are contiguous in struct pt_regs */ src_banked = ms->pmsa_bank1_gr; for (i = 0; i < 16; ++i) dst_banked[i] = src_banked[i]; pt->b0 = ms->pmsa_br0; sw->b1 = ms->pmsa_br1; /* construct the NaT bits for the pt-regs structure: */ # define PUT_NAT_BIT(dst, addr) \ do { \ bit = nat_bits & 1; nat_bits >>= 1; \ shift = ((unsigned long) addr >> 3) & 0x3f; \ dst = ((dst) & ~(1UL << shift)) | (bit << shift); \ } while (0) /* Rotate the saved NaT bits such that bit 0 corresponds to pmsa_gr[0]: */ shift = ((unsigned long) &ms->pmsa_gr[0] >> 3) & 0x3f; nat_bits = (ms->pmsa_nat_bits >> shift) | (ms->pmsa_nat_bits << (64 - shift)); PUT_NAT_BIT(sw->caller_unat, &pt->r1); PUT_NAT_BIT(sw->caller_unat, &pt->r2); PUT_NAT_BIT(sw->caller_unat, &pt->r3); PUT_NAT_BIT(sw->ar_unat, &sw->r4); PUT_NAT_BIT(sw->ar_unat, &sw->r5); PUT_NAT_BIT(sw->ar_unat, &sw->r6); PUT_NAT_BIT(sw->ar_unat, &sw->r7); PUT_NAT_BIT(sw->caller_unat, &pt->r8); PUT_NAT_BIT(sw->caller_unat, &pt->r9); PUT_NAT_BIT(sw->caller_unat, &pt->r10); PUT_NAT_BIT(sw->caller_unat, &pt->r11); PUT_NAT_BIT(sw->caller_unat, &pt->r12); PUT_NAT_BIT(sw->caller_unat, &pt->r13); PUT_NAT_BIT(sw->caller_unat, &pt->r14); PUT_NAT_BIT(sw->caller_unat, &pt->r15); nat_bits >>= 16; /* skip over bank0 NaT bits */ PUT_NAT_BIT(sw->caller_unat, &pt->r16); PUT_NAT_BIT(sw->caller_unat, &pt->r17); PUT_NAT_BIT(sw->caller_unat, &pt->r18); PUT_NAT_BIT(sw->caller_unat, &pt->r19); PUT_NAT_BIT(sw->caller_unat, &pt->r20); PUT_NAT_BIT(sw->caller_unat, &pt->r21); PUT_NAT_BIT(sw->caller_unat, &pt->r22); PUT_NAT_BIT(sw->caller_unat, &pt->r23); PUT_NAT_BIT(sw->caller_unat, &pt->r24); PUT_NAT_BIT(sw->caller_unat, &pt->r25); PUT_NAT_BIT(sw->caller_unat, &pt->r26); PUT_NAT_BIT(sw->caller_unat, &pt->r27); PUT_NAT_BIT(sw->caller_unat, &pt->r28); PUT_NAT_BIT(sw->caller_unat, &pt->r29); PUT_NAT_BIT(sw->caller_unat, &pt->r30); PUT_NAT_BIT(sw->caller_unat, &pt->r31); } static void init_handler_platform (pal_min_state_area_t *ms, struct pt_regs *pt, struct switch_stack *sw) { struct unw_frame_info info; /* if a kernel debugger is available call it here else just dump the registers */ /* * 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. */ printk("Delaying for 5 seconds...\n"); udelay(5*1000000); show_min_state(ms); printk("Backtrace of current task (pid %d, %s)\n", current->pid, current->comm); fetch_min_state(ms, pt, sw); unw_init_from_interruption(&info, current, pt, sw); ia64_do_show_stack(&info, NULL); #ifdef CONFIG_SMP /* read_trylock() would be handy... */ if (!tasklist_lock.write_lock) read_lock(&tasklist_lock); #endif { struct task_struct *t; for_each_task(t) { if (t == current) continue; printk("\nBacktrace of pid %d (%s)\n", t->pid, t->comm); show_stack(t); } } #ifdef CONFIG_SMP if (!tasklist_lock.write_lock) read_unlock(&tasklist_lock); #endif printk("\nINIT dump complete. Please reboot now.\n"); while (1); /* hang city if no debugger */ } #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 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 setup and enabled\n", __FUNCTION__, cpev); } #endif /* CONFIG_ACPI */ #endif /* PLATFORM_MCA_HANDLERS */ /* * ia64_mca_cmc_vector_setup * * Setup the corrected machine check vector register in the processor and * unmask interrupt. 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 = 0; /* Unmask/enable interrupt */ cmcv.cmcv_vector = IA64_CMC_VECTOR; ia64_set_cmcv(cmcv.cmcv_regval); IA64_MCA_DEBUG("%s: CPU %d corrected " "machine check vector %#x setup and enabled.\n", __FUNCTION__, smp_processor_id(), IA64_CMC_VECTOR); IA64_MCA_DEBUG("%s: CPU %d CMCV = %#016lx\n", __FUNCTION__, smp_processor_id(), ia64_get_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_reg_t)ia64_get_cmcv(); cmcv.cmcv_mask = 1; /* Mask/disable interrupt */ ia64_set_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_reg_t)ia64_get_cmcv(); cmcv.cmcv_mask = 0; /* Unmask/enable interrupt */ ia64_set_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. * * Note: needs preempt_disable() if you apply the preempt patch to 2.4. */ static void ia64_mca_cmc_vector_disable_keventd(void *unused) { ia64_mca_cmc_vector_disable(NULL); smp_call_function(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. * * Note: needs preempt_disable() if you apply the preempt patch to 2.4. */ static void ia64_mca_cmc_vector_enable_keventd(void *unused) { smp_call_function(ia64_mca_cmc_vector_enable, NULL, 1, 0); ia64_mca_cmc_vector_enable(NULL); } /* * ia64_mca_wakeup_ipi_wait * * Wait for the inter-cpu interrupt to be sent by the * monarch processor once it is done with handling the * MCA. * * Inputs : None * Outputs : None */ static void ia64_mca_wakeup_ipi_wait(void) { int irr_num = (IA64_MCA_WAKEUP_VECTOR >> 6); int irr_bit = (IA64_MCA_WAKEUP_VECTOR & 0x3f); u64 irr = 0; do { switch(irr_num) { case 0: irr = ia64_get_irr0(); break; case 1: irr = ia64_get_irr1(); break; case 2: irr = ia64_get_irr2(); break; case 3: irr = ia64_get_irr3(); break; } } while (!(irr & (1UL << irr_bit))) ; } /* * 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(cpu = 0; cpu < NR_CPUS; cpu++) { if (!cpu_online(cpu)) continue; 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 void ia64_mca_rendez_int_handler(int rendez_irq, void *arg, struct pt_regs *ptregs) { unsigned long flags; int cpu = smp_processor_id(); /* Mask all interrupts */ local_irq_save(flags); 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(); /* Wait for the wakeup IPI from the monarch * This waiting is done by polling on the wakeup-interrupt * vector bit in the processor's IRRs */ ia64_mca_wakeup_ipi_wait(); /* Enable all interrupts */ local_irq_restore(flags); } /* * 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) * ptregs (Exception frame at the time of the interrupt) * Outputs : None * */ static void ia64_mca_wakeup_int_handler(int wakeup_irq, void *arg, struct pt_regs *ptregs) { } /* * ia64_return_to_sal_check * * This is function called before going back from the OS_MCA handler * to the OS_MCA dispatch code which finally takes the control back * to the SAL. * The main purpose of this routine is to setup the OS_MCA to SAL * return state which can be used by the OS_MCA dispatch code * just before going back to SAL. * * Inputs : None * Outputs : None */ static void ia64_return_to_sal_check(int recover) { /* Copy over some relevant stuff from the sal_to_os_mca_handoff * so that it can be used at the time of os_mca_to_sal_handoff */ ia64_os_to_sal_handoff_state.imots_sal_gp = ia64_sal_to_os_handoff_state.imsto_sal_gp; ia64_os_to_sal_handoff_state.imots_sal_check_ra = ia64_sal_to_os_handoff_state.imsto_sal_check_ra; if (recover) ia64_os_to_sal_handoff_state.imots_os_status = IA64_MCA_CORRECTED; else ia64_os_to_sal_handoff_state.imots_os_status = IA64_MCA_COLD_BOOT; /* Default = tell SAL to return to same context */ ia64_os_to_sal_handoff_state.imots_context = IA64_MCA_SAME_CONTEXT; ia64_os_to_sal_handoff_state.imots_new_min_state = (u64 *)ia64_sal_to_os_handoff_state.pal_min_state; } /* * ia64_mca_ucmc_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. * * Inputs : None * Outputs : None */ void ia64_mca_ucmc_handler(void) { pal_processor_state_info_t *psp = (pal_processor_state_info_t *) &ia64_sal_to_os_handoff_state.proc_state_param; int recover = psp->tc && !(psp->cc || psp->bc || psp->rc || psp->uc); /* Get the MCA error record and log it */ ia64_mca_log_sal_error_record(SAL_INFO_TYPE_MCA); /* * Wakeup all the processors which are spinning in the rendezvous * loop. */ ia64_mca_wakeup_all(); /* Return to SAL */ ia64_return_to_sal_check(recover); } /* * 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 * saved registers ptr * * Outputs * None */ static void ia64_mca_cmc_int_handler(int cmc_irq, void *arg, struct pt_regs *ptregs) { static unsigned long cmc_history[CMC_HISTORY_LENGTH]; static int index; static spinlock_t cmc_history_lock = SPIN_LOCK_UNLOCKED; 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(); /* Get the CMC error record and log it */ ia64_mca_log_sal_error_record(SAL_INFO_TYPE_CMC); 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); schedule_task(&cmc_disable_tq); /* * 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 */ return; } else { cmc_history[index++] = now; if (index == CMC_HISTORY_LENGTH) index = 0; } } spin_unlock(&cmc_history_lock); } /* * 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 * saved registers ptr * Outputs * None */ static void ia64_mca_cmc_int_caller(int cpe_irq, void *arg, struct pt_regs *ptregs) { 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(cpe_irq, arg, ptregs); 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_task(&cmc_enable_tq); cmc_polling_enabled = 0; } else { mod_timer(&cmc_poll_timer, jiffies + CMC_POLL_INTERVAL); } start_count = -1; } } /* * 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(__ffs(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 * saved registers ptr * Outputs * None */ static void ia64_mca_cpe_int_caller(int cpe_irq, void *arg, struct pt_regs *ptregs) { static int start_count = -1; static int poll_time = MAX_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, ptregs); 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. */ if (start_count != IA64_LOG_COUNT(SAL_INFO_TYPE_CPE)) { poll_time = max(MIN_CPE_POLL_INTERVAL, poll_time / 2); } else { poll_time = min(MAX_CPE_POLL_INTERVAL, poll_time * 2); } start_count = -1; mod_timer(&cpe_poll_timer, jiffies + poll_time); } } /* * 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(__ffs(cpu_online_map), IA64_CPEP_VECTOR, IA64_IPI_DM_INT, 0); } /* * C portion of the OS INIT handler * * Called from ia64_monarch_init_handler * * Inputs: pointer to pt_regs where processor info was saved. * * Returns: * 0 if SAL must warm boot the System * 1 if SAL must return to interrupted context using PAL_MC_RESUME * */ void ia64_init_handler (struct pt_regs *pt, struct switch_stack *sw) { pal_min_state_area_t *ms; oops_in_progress = 1; /* avoid deadlock in printk, but it makes recovery dodgy */ printk(KERN_INFO "Entered OS INIT handler. PSP=%lx\n", ia64_sal_to_os_handoff_state.proc_state_param); /* * Address of minstate area provided by PAL is physical, * uncacheable (bit 63 set). Convert to Linux virtual * address in region 6. */ ms = (pal_min_state_area_t *)(ia64_sal_to_os_handoff_state.pal_min_state | (6ul<<61)); init_handler_platform(ms, pt, sw); /* call platform specific routines */ } 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 = SA_INTERRUPT, .name = "cmc_hndlr" }; static struct irqaction cmcp_irqaction = { .handler = ia64_mca_cmc_int_caller, .flags = SA_INTERRUPT, .name = "cmc_poll" }; static struct irqaction mca_rdzv_irqaction = { .handler = ia64_mca_rendez_int_handler, .flags = SA_INTERRUPT, .name = "mca_rdzv" }; static struct irqaction mca_wkup_irqaction = { .handler = ia64_mca_wakeup_int_handler, .flags = SA_INTERRUPT, .name = "mca_wkup" }; #ifdef CONFIG_ACPI static struct irqaction mca_cpe_irqaction = { .handler = ia64_mca_cpe_int_handler, .flags = SA_INTERRUPT, .name = "cpe_hndlr" }; static struct irqaction mca_cpep_irqaction = { .handler = ia64_mca_cpe_int_caller, .flags = SA_INTERRUPT, .name = "cpe_poll" }; #endif /* CONFIG_ACPI */ /* * 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 *mon_init_ptr = (ia64_fptr_t *)ia64_monarch_init_handler; ia64_fptr_t *slave_init_ptr = (ia64_fptr_t *)ia64_slave_init_handler; 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 */ IA64_MCA_DEBUG("%s: begin\n", __FUNCTION__); INIT_TQUEUE(&cmc_disable_tq, ia64_mca_cmc_vector_disable_keventd, NULL); INIT_TQUEUE(&cmc_enable_tq, ia64_mca_cmc_vector_enable_keventd, NULL); /* 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; 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(mon_init_ptr->fp); ia64_mc_info.imi_monarch_init_handler_size = 0; ia64_mc_info.imi_slave_init_handler = ia64_tpa(slave_init_ptr->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_get_gp()), ia64_mc_info.imi_monarch_init_handler_size, ia64_mc_info.imi_slave_init_handler, ia64_tpa(ia64_get_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; } 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 & enable */ /* 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 CPE interrupt vector */ { irq_desc_t *desc; unsigned int irq; int cpev = acpi_request_vector(ACPI_INTERRUPT_CPEI); if (cpev >= 0) { for (irq = 0; irq < NR_IRQS; ++irq) if (irq_to_vector(irq) == cpev) { desc = irq_desc(irq); desc->status |= IRQ_PER_CPU; desc->handler = &irq_type_iosapic_level; setup_irq(irq, &mca_cpe_irqaction); } ia64_mca_register_cpev(cpev); } } #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); 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) { init_timer(&cmc_poll_timer); cmc_poll_timer.function = ia64_mca_cmc_poll; /* Reset to the correct state */ cmc_polling_enabled = 0; init_timer(&cpe_poll_timer); cpe_poll_timer.function = ia64_mca_cpe_poll; #ifdef CONFIG_ACPI /* If platform doesn't support CPEI, get the timer going. */ if (acpi_request_vector(ACPI_INTERRUPT_CPEI) < 0 && cpe_poll_enabled) { register_percpu_irq(IA64_CPEP_VECTOR, &mca_cpep_irqaction); ia64_mca_cpe_poll(0UL); } #endif return 0; } module_init(ia64_mca_late_init);
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