// SPDX-License-Identifier: GPL-2.0 /* * Machine check handler * * Copyright IBM Corp. 2000, 2009 * Author(s): Ingo Adlung , * Martin Schwidefsky , * Cornelia Huck , * Heiko Carstens , */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include struct mcck_struct { unsigned int kill_task : 1; unsigned int channel_report : 1; unsigned int warning : 1; unsigned int stp_queue : 1; unsigned long mcck_code; }; static DEFINE_PER_CPU(struct mcck_struct, cpu_mcck); static struct kmem_cache *mcesa_cache; static unsigned long mcesa_origin_lc; static inline int nmi_needs_mcesa(void) { return MACHINE_HAS_VX || MACHINE_HAS_GS; } static inline unsigned long nmi_get_mcesa_size(void) { if (MACHINE_HAS_GS) return MCESA_MAX_SIZE; return MCESA_MIN_SIZE; } /* * The initial machine check extended save area for the boot CPU. * It will be replaced on the boot CPU reinit with an allocated * structure. The structure is required for machine check happening * early in the boot process. */ static struct mcesa boot_mcesa __initdata __aligned(MCESA_MAX_SIZE); void __init nmi_alloc_mcesa_early(u64 *mcesad) { if (!nmi_needs_mcesa()) return; *mcesad = __pa(&boot_mcesa); if (MACHINE_HAS_GS) *mcesad |= ilog2(MCESA_MAX_SIZE); } static void __init nmi_alloc_cache(void) { unsigned long size; if (!nmi_needs_mcesa()) return; size = nmi_get_mcesa_size(); if (size > MCESA_MIN_SIZE) mcesa_origin_lc = ilog2(size); /* create slab cache for the machine-check-extended-save-areas */ mcesa_cache = kmem_cache_create("nmi_save_areas", size, size, 0, NULL); if (!mcesa_cache) panic("Couldn't create nmi save area cache"); } int __ref nmi_alloc_mcesa(u64 *mcesad) { unsigned long origin; *mcesad = 0; if (!nmi_needs_mcesa()) return 0; if (!mcesa_cache) nmi_alloc_cache(); origin = (unsigned long) kmem_cache_alloc(mcesa_cache, GFP_KERNEL); if (!origin) return -ENOMEM; /* The pointer is stored with mcesa_bits ORed in */ kmemleak_not_leak((void *) origin); *mcesad = __pa(origin) | mcesa_origin_lc; return 0; } void nmi_free_mcesa(u64 *mcesad) { if (!nmi_needs_mcesa()) return; kmem_cache_free(mcesa_cache, __va(*mcesad & MCESA_ORIGIN_MASK)); } static notrace void s390_handle_damage(void) { smp_emergency_stop(); disabled_wait(); while (1); } NOKPROBE_SYMBOL(s390_handle_damage); /* * Main machine check handler function. Will be called with interrupts disabled * and machine checks enabled. */ void __s390_handle_mcck(void) { struct mcck_struct mcck; /* * Disable machine checks and get the current state of accumulated * machine checks. Afterwards delete the old state and enable machine * checks again. */ local_mcck_disable(); mcck = *this_cpu_ptr(&cpu_mcck); memset(this_cpu_ptr(&cpu_mcck), 0, sizeof(mcck)); local_mcck_enable(); if (mcck.channel_report) crw_handle_channel_report(); /* * A warning may remain for a prolonged period on the bare iron. * (actually until the machine is powered off, or the problem is gone) * So we just stop listening for the WARNING MCH and avoid continuously * being interrupted. One caveat is however, that we must do this per * processor and cannot use the smp version of ctl_clear_bit(). * On VM we only get one interrupt per virtally presented machinecheck. * Though one suffices, we may get one interrupt per (virtual) cpu. */ if (mcck.warning) { /* WARNING pending ? */ static int mchchk_wng_posted = 0; /* Use single cpu clear, as we cannot handle smp here. */ __ctl_clear_bit(14, 24); /* Disable WARNING MCH */ if (xchg(&mchchk_wng_posted, 1) == 0) kill_cad_pid(SIGPWR, 1); } if (mcck.stp_queue) stp_queue_work(); if (mcck.kill_task) { local_irq_enable(); printk(KERN_EMERG "mcck: Terminating task because of machine " "malfunction (code 0x%016lx).\n", mcck.mcck_code); printk(KERN_EMERG "mcck: task: %s, pid: %d.\n", current->comm, current->pid); make_task_dead(SIGSEGV); } } void noinstr s390_handle_mcck(void) { trace_hardirqs_off(); __s390_handle_mcck(); trace_hardirqs_on(); } /* * returns 0 if all required registers are available * returns 1 otherwise */ static int notrace s390_validate_registers(union mci mci, int umode) { struct mcesa *mcesa; void *fpt_save_area; union ctlreg2 cr2; int kill_task; u64 zero; kill_task = 0; zero = 0; if (!mci.gr) { /* * General purpose registers couldn't be restored and have * unknown contents. Stop system or terminate process. */ if (!umode) s390_handle_damage(); kill_task = 1; } if (!mci.fp) { /* * Floating point registers can't be restored. If the * kernel currently uses floating point registers the * system is stopped. If the process has its floating * pointer registers loaded it is terminated. */ if (S390_lowcore.fpu_flags & KERNEL_VXR_V0V7) s390_handle_damage(); if (!test_cpu_flag(CIF_FPU)) kill_task = 1; } fpt_save_area = &S390_lowcore.floating_pt_save_area; if (!mci.fc) { /* * Floating point control register can't be restored. * If the kernel currently uses the floating pointer * registers and needs the FPC register the system is * stopped. If the process has its floating pointer * registers loaded it is terminated. Otherwise the * FPC is just validated. */ if (S390_lowcore.fpu_flags & KERNEL_FPC) s390_handle_damage(); asm volatile( " lfpc %0\n" : : "Q" (zero)); if (!test_cpu_flag(CIF_FPU)) kill_task = 1; } else { asm volatile( " lfpc %0\n" : : "Q" (S390_lowcore.fpt_creg_save_area)); } mcesa = __va(S390_lowcore.mcesad & MCESA_ORIGIN_MASK); if (!MACHINE_HAS_VX) { /* Validate floating point registers */ asm volatile( " ld 0,0(%0)\n" " ld 1,8(%0)\n" " ld 2,16(%0)\n" " ld 3,24(%0)\n" " ld 4,32(%0)\n" " ld 5,40(%0)\n" " ld 6,48(%0)\n" " ld 7,56(%0)\n" " ld 8,64(%0)\n" " ld 9,72(%0)\n" " ld 10,80(%0)\n" " ld 11,88(%0)\n" " ld 12,96(%0)\n" " ld 13,104(%0)\n" " ld 14,112(%0)\n" " ld 15,120(%0)\n" : : "a" (fpt_save_area) : "memory"); } else { /* Validate vector registers */ union ctlreg0 cr0; if (!mci.vr) { /* * Vector registers can't be restored. If the kernel * currently uses vector registers the system is * stopped. If the process has its vector registers * loaded it is terminated. Otherwise just validate * the registers. */ if (S390_lowcore.fpu_flags & KERNEL_VXR) s390_handle_damage(); if (!test_cpu_flag(CIF_FPU)) kill_task = 1; } cr0.val = S390_lowcore.cregs_save_area[0]; cr0.afp = cr0.vx = 1; __ctl_load(cr0.val, 0, 0); asm volatile( " la 1,%0\n" " .word 0xe70f,0x1000,0x0036\n" /* vlm 0,15,0(1) */ " .word 0xe70f,0x1100,0x0c36\n" /* vlm 16,31,256(1) */ : : "Q" (*(struct vx_array *)mcesa->vector_save_area) : "1"); __ctl_load(S390_lowcore.cregs_save_area[0], 0, 0); } /* Validate access registers */ asm volatile( " lam 0,15,0(%0)\n" : : "a" (&S390_lowcore.access_regs_save_area) : "memory"); if (!mci.ar) { /* * Access registers have unknown contents. * Terminating task. */ kill_task = 1; } /* Validate guarded storage registers */ cr2.val = S390_lowcore.cregs_save_area[2]; if (cr2.gse) { if (!mci.gs) { /* * Guarded storage register can't be restored and * the current processes uses guarded storage. * It has to be terminated. */ kill_task = 1; } else { load_gs_cb((struct gs_cb *)mcesa->guarded_storage_save_area); } } /* * The getcpu vdso syscall reads CPU number from the programmable * field of the TOD clock. Disregard the TOD programmable register * validity bit and load the CPU number into the TOD programmable * field unconditionally. */ set_tod_programmable_field(raw_smp_processor_id()); /* Validate clock comparator register */ set_clock_comparator(S390_lowcore.clock_comparator); if (!mci.ms || !mci.pm || !mci.ia) kill_task = 1; return kill_task; } NOKPROBE_SYMBOL(s390_validate_registers); /* * Backup the guest's machine check info to its description block */ static void notrace s390_backup_mcck_info(struct pt_regs *regs) { struct mcck_volatile_info *mcck_backup; struct sie_page *sie_page; /* r14 contains the sie block, which was set in sie64a */ struct kvm_s390_sie_block *sie_block = (struct kvm_s390_sie_block *) regs->gprs[14]; if (sie_block == NULL) /* Something's seriously wrong, stop system. */ s390_handle_damage(); sie_page = container_of(sie_block, struct sie_page, sie_block); mcck_backup = &sie_page->mcck_info; mcck_backup->mcic = S390_lowcore.mcck_interruption_code & ~(MCCK_CODE_CP | MCCK_CODE_EXT_DAMAGE); mcck_backup->ext_damage_code = S390_lowcore.external_damage_code; mcck_backup->failing_storage_address = S390_lowcore.failing_storage_address; } NOKPROBE_SYMBOL(s390_backup_mcck_info); #define MAX_IPD_COUNT 29 #define MAX_IPD_TIME (5 * 60 * USEC_PER_SEC) /* 5 minutes */ #define ED_STP_ISLAND 6 /* External damage STP island check */ #define ED_STP_SYNC 7 /* External damage STP sync check */ #define MCCK_CODE_NO_GUEST (MCCK_CODE_CP | MCCK_CODE_EXT_DAMAGE) /* * machine check handler. */ int notrace s390_do_machine_check(struct pt_regs *regs) { static int ipd_count; static DEFINE_SPINLOCK(ipd_lock); static unsigned long long last_ipd; struct mcck_struct *mcck; unsigned long long tmp; union mci mci; unsigned long mcck_dam_code; int mcck_pending = 0; nmi_enter(); if (user_mode(regs)) update_timer_mcck(); inc_irq_stat(NMI_NMI); mci.val = S390_lowcore.mcck_interruption_code; mcck = this_cpu_ptr(&cpu_mcck); /* * Reinject the instruction processing damages' machine checks * including Delayed Access Exception into the guest * instead of damaging the host if they happen in the guest. */ if (mci.pd && !test_cpu_flag(CIF_MCCK_GUEST)) { if (mci.b) { /* Processing backup -> verify if we can survive this */ u64 z_mcic, o_mcic, t_mcic; z_mcic = (1ULL<<63 | 1ULL<<59 | 1ULL<<29); o_mcic = (1ULL<<43 | 1ULL<<42 | 1ULL<<41 | 1ULL<<40 | 1ULL<<36 | 1ULL<<35 | 1ULL<<34 | 1ULL<<32 | 1ULL<<30 | 1ULL<<21 | 1ULL<<20 | 1ULL<<17 | 1ULL<<16); t_mcic = mci.val; if (((t_mcic & z_mcic) != 0) || ((t_mcic & o_mcic) != o_mcic)) { s390_handle_damage(); } /* * Nullifying exigent condition, therefore we might * retry this instruction. */ spin_lock(&ipd_lock); tmp = get_tod_clock(); if (((tmp - last_ipd) >> 12) < MAX_IPD_TIME) ipd_count++; else ipd_count = 1; last_ipd = tmp; if (ipd_count == MAX_IPD_COUNT) s390_handle_damage(); spin_unlock(&ipd_lock); } else { /* Processing damage -> stopping machine */ s390_handle_damage(); } } if (s390_validate_registers(mci, user_mode(regs))) { /* * Couldn't restore all register contents for the * user space process -> mark task for termination. */ mcck->kill_task = 1; mcck->mcck_code = mci.val; mcck_pending = 1; } /* * Backup the machine check's info if it happens when the guest * is running. */ if (test_cpu_flag(CIF_MCCK_GUEST)) s390_backup_mcck_info(regs); if (mci.cd) { /* Timing facility damage */ s390_handle_damage(); } if (mci.ed && mci.ec) { /* External damage */ if (S390_lowcore.external_damage_code & (1U << ED_STP_SYNC)) mcck->stp_queue |= stp_sync_check(); if (S390_lowcore.external_damage_code & (1U << ED_STP_ISLAND)) mcck->stp_queue |= stp_island_check(); mcck_pending = 1; } if (mci.cp) { /* Channel report word pending */ mcck->channel_report = 1; mcck_pending = 1; } if (mci.w) { /* Warning pending */ mcck->warning = 1; mcck_pending = 1; } /* * If there are only Channel Report Pending and External Damage * machine checks, they will not be reinjected into the guest * because they refer to host conditions only. */ mcck_dam_code = (mci.val & MCIC_SUBCLASS_MASK); if (test_cpu_flag(CIF_MCCK_GUEST) && (mcck_dam_code & MCCK_CODE_NO_GUEST) != mcck_dam_code) { /* Set exit reason code for host's later handling */ *((long *)(regs->gprs[15] + __SF_SIE_REASON)) = -EINTR; } clear_cpu_flag(CIF_MCCK_GUEST); if (user_mode(regs) && mcck_pending) { nmi_exit(); return 1; } if (mcck_pending) schedule_mcck_handler(); nmi_exit(); return 0; } NOKPROBE_SYMBOL(s390_do_machine_check); static int __init machine_check_init(void) { ctl_set_bit(14, 25); /* enable external damage MCH */ ctl_set_bit(14, 27); /* enable system recovery MCH */ ctl_set_bit(14, 24); /* enable warning MCH */ return 0; } early_initcall(machine_check_init);