/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Kernel Error Queues * * A common problem when handling hardware error traps and interrupts is that * these errors frequently must be handled at high interrupt level, where * reliably producing error messages and safely examining and manipulating * other kernel state may not be possible. The kernel error queue primitive is * a common set of routines that allow a subsystem to maintain a queue of * errors that can be processed by an explicit call from a safe context or by a * soft interrupt that fires at a specific lower interrupt level. The queue * management code also ensures that if the system panics, all in-transit * errors are logged prior to reset. Each queue has an associated kstat for * observing the number of errors dispatched and logged, and mdb(1) debugging * support is provided for live and post-mortem observability. * * Memory Allocation * * All of the queue data structures are allocated in advance as part of * the errorq_create() call. No additional memory allocations are * performed as part of errorq_dispatch(), errorq_reserve(), * errorq_commit() or errorq_drain(). This design * facilitates reliable error queue processing even when the system is low * on memory, and ensures that errorq_dispatch() can be called from any * context. When the queue is created, the maximum queue length is * specified as a parameter to errorq_create() errorq_nvcreate(). This * length should represent a reasonable upper bound on the number of * simultaneous errors. If errorq_dispatch() or errorq_reserve() is * invoked and no free queue elements are available, the error is * dropped and will not be logged. Typically, the queue will only be * exhausted by an error storm, and in this case * the earlier errors provide the most important data for analysis. * When a new error is dispatched, the error data is copied into the * preallocated queue element so that the caller's buffer can be reused. * * When a new error is reserved, an element is moved from the free list * and returned to the caller. The element buffer data, eqe_data, may be * managed by the caller and dispatched to the errorq by calling * errorq_commit(). This is useful for additions to errorq's * created with errorq_nvcreate() to handle name-value pair (nvpair) data. * See below for a discussion on nvlist errorq's. * * Queue Drain Callback * * When the error queue is drained, the caller's queue drain callback is * invoked with a pointer to the saved error data. This function may be * called from passive kernel context or soft interrupt context at or * below LOCK_LEVEL, or as part of panic(). As such, the callback should * basically only be calling cmn_err (but NOT with the CE_PANIC flag). * The callback must not call panic(), attempt to allocate memory, or wait * on a condition variable. The callback may not call errorq_destroy() * or errorq_drain() on the same error queue that called it. * * The queue drain callback will always be called for each pending error * in the order in which errors were enqueued (oldest to newest). The * queue drain callback is guaranteed to provide at *least* once semantics * for all errors that are successfully dispatched (i.e. for which * errorq_dispatch() has successfully completed). If an unrelated panic * occurs while the queue drain callback is running on a vital queue, the * panic subsystem will continue the queue drain and the callback may be * invoked again for the same error. Therefore, the callback should * restrict itself to logging messages and taking other actions that are * not destructive if repeated. * * Name-Value Pair Error Queues * * During error handling, it may be more convenient to store error * queue element data as a fixed buffer of name-value pairs. The * nvpair library allows construction and destruction of nvlists in * in pre-allocated memory buffers. * * Error queues created via errorq_nvcreate() store queue element * data as fixed buffer nvlists (ereports). errorq_reserve() * allocates an errorq element from eqp->eq_free and returns a valid * pointer to a errorq_elem_t (queue element) and a pre-allocated * fixed buffer nvlist. errorq_elem_nvl() is used to gain access * to the nvlist to add name-value ereport members prior to * dispatching the error queue element in errorq_commit(). * * Once dispatched, the drain function will return the element to * eqp->eq_free and reset the associated nv_alloc structure. * error_cancel() may be called to cancel an element reservation * element that was never dispatched (committed). This is useful in * cases where a programming error prevents a queue element from being * dispatched. * * Queue Management * * The queue element structures and error data buffers are allocated in * two contiguous chunks as part of errorq_create() or errorq_nvcreate(). * Each queue element structure contains a next pointer, * a previous pointer, and a pointer to the corresponding error data * buffer. The data buffer for a nvlist errorq is a shared buffer * for the allocation of name-value pair lists. The elements are kept on * one of three lists: * * Unused elements are kept on the free list, a singly-linked list pointed * to by eqp->eq_free, and linked together using eqe_prev. The eqe_next * pointer is not used by the free list and will be set to NULL. * * Pending errors are kept on the pending list, a singly-linked list * pointed to by eqp->eq_pend, and linked together using eqe_prev. This * list is maintained in order from newest error to oldest. The eqe_next * pointer is not used by the pending list and will be set to NULL. * * The processing list is a doubly-linked list pointed to by eqp->eq_phead * (the oldest element) and eqp->eq_ptail (the newest element). The * eqe_next pointer is used to traverse from eq_phead to eq_ptail, and the * eqe_prev pointer is used to traverse from eq_ptail to eq_phead. Once a * queue drain operation begins, the current pending list is moved to the * processing list in a two-phase commit fashion, allowing the panic code * to always locate and process all pending errors in the event that a * panic occurs in the middle of queue processing. * * A fourth list is maintained for nvlist errorqs. The dump list, * eq_dump is used to link all errorq elements that should be stored * in a crash dump file in the event of a system panic. During * errorq_panic(), the list is created and subsequently traversed * in errorq_dump() during the final phases of a crash dump. * * Platform Considerations * * In order to simplify their implementation, error queues make use of the * C wrappers for compare-and-swap. If the platform itself does not * support compare-and-swap in hardware and the kernel emulation routines * are used instead, then the context in which errorq_dispatch() can be * safely invoked is further constrained by the implementation of the * compare-and-swap emulation. Specifically, if errorq_dispatch() is * called from a code path that can be executed above ATOMIC_LEVEL on such * a platform, the dispatch code could potentially deadlock unless the * corresponding error interrupt is blocked or disabled prior to calling * errorq_dispatch(). Error queues should therefore be deployed with * caution on these platforms. * * Interfaces * * errorq_t *errorq_create(name, func, private, qlen, eltsize, ipl, flags); * errorq_t *errorq_nvcreate(name, func, private, qlen, eltsize, ipl, flags); * * Create a new error queue with the specified name, callback, and * properties. A pointer to the new error queue is returned upon success, * or NULL is returned to indicate that the queue could not be created. * This function must be called from passive kernel context with no locks * held that can prevent a sleeping memory allocation from occurring. * errorq_create() will return failure if the queue kstats cannot be * created, or if a soft interrupt handler cannot be registered. * * The queue 'name' is a string that is recorded for live and post-mortem * examination by a debugger. The queue callback 'func' will be invoked * for each error drained from the queue, and will receive the 'private' * pointer as its first argument. The callback must obey the rules for * callbacks described above. The queue will have maximum length 'qlen' * and each element will be able to record up to 'eltsize' bytes of data. * The queue's soft interrupt (see errorq_dispatch(), below) will fire * at 'ipl', which should not exceed LOCK_LEVEL. The queue 'flags' may * include the following flag: * * ERRORQ_VITAL - This queue contains information that is considered * vital to problem diagnosis. Error queues that are marked vital will * be automatically drained by the panic subsystem prior to printing * the panic messages to the console. * * void errorq_destroy(errorq); * * Destroy the specified error queue. The queue is drained of any * pending elements and these are logged before errorq_destroy returns. * Once errorq_destroy() begins draining the queue, any simultaneous * calls to dispatch errors will result in the errors being dropped. * The caller must invoke a higher-level abstraction (e.g. disabling * an error interrupt) to ensure that error handling code does not * attempt to dispatch errors to the queue while it is being freed. * * void errorq_dispatch(errorq, data, len, flag); * * Attempt to enqueue the specified error data. If a free queue element * is available, the data is copied into a free element and placed on a * pending list. If no free queue element is available, the error is * dropped. The data length (len) is specified in bytes and should not * exceed the queue's maximum element size. If the data length is less * than the maximum element size, the remainder of the queue element is * filled with zeroes. The flag parameter should be one of: * * ERRORQ_ASYNC - Schedule a soft interrupt at the previously specified * IPL to asynchronously drain the queue on behalf of the caller. * * ERRORQ_SYNC - Do not schedule a soft interrupt to drain the queue. * The caller is presumed to be calling errorq_drain() or panic() in * the near future in order to drain the queue and log the error. * * The errorq_dispatch() function may be called from any context, subject * to the Platform Considerations described above. * * void errorq_drain(errorq); * * Drain the error queue of all pending errors. The queue's callback * function is invoked for each error in order from oldest to newest. * This function may be used at or below LOCK_LEVEL or from panic context. * * errorq_elem_t *errorq_reserve(errorq); * * Reserve an error queue element for later processing and dispatching. * The element is returned to the caller who may add error-specific data * to element. The element is retured to the free list when either * errorq_commit() is called and the element asynchronously processed * or immediately when errorq_cancel() is called. * * void errorq_commit(errorq, errorq_elem, flag); * * Commit an errorq element (eqep) for dispatching, see * errorq_dispatch(). * * void errorq_cancel(errorq, errorq_elem); * * Cancel a pending errorq element reservation. The errorq element is * returned to the free list upon cancelation. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static struct errorq_kstat errorq_kstat_template = { { "dispatched", KSTAT_DATA_UINT64 }, { "dropped", KSTAT_DATA_UINT64 }, { "logged", KSTAT_DATA_UINT64 }, { "reserved", KSTAT_DATA_UINT64 }, { "reserve_fail", KSTAT_DATA_UINT64 }, { "committed", KSTAT_DATA_UINT64 }, { "commit_fail", KSTAT_DATA_UINT64 }, { "cancelled", KSTAT_DATA_UINT64 } }; static uint64_t errorq_lost = 0; static errorq_t *errorq_list = NULL; static kmutex_t errorq_lock; static uint64_t errorq_vitalmin = 5; static uint_t errorq_intr(caddr_t eqp) { errorq_drain((errorq_t *)eqp); return (DDI_INTR_CLAIMED); } /* * Create a new error queue with the specified properties and add a software * interrupt handler and kstat for it. This function must be called from * passive kernel context with no locks held that can prevent a sleeping * memory allocation from occurring. This function will return NULL if the * softint or kstat for this queue cannot be created. */ errorq_t * errorq_create(const char *name, errorq_func_t func, void *private, ulong_t qlen, size_t size, uint_t ipl, uint_t flags) { errorq_t *eqp = kmem_alloc(sizeof (errorq_t), KM_SLEEP); ddi_iblock_cookie_t ibc = (ddi_iblock_cookie_t)(uintptr_t)ipltospl(ipl); dev_info_t *dip = ddi_root_node(); errorq_elem_t *eep; ddi_softintr_t id = NULL; caddr_t data; ASSERT(qlen != 0 && size != 0); ASSERT(ipl > 0 && ipl <= LOCK_LEVEL); /* * If a queue is created very early in boot before device tree services * are available, the queue softint handler cannot be created. We * manually drain these queues and create their softint handlers when * it is safe to do so as part of errorq_init(), below. */ if (modrootloaded && ddi_add_softintr(dip, DDI_SOFTINT_FIXED, &id, &ibc, NULL, errorq_intr, (caddr_t)eqp) != DDI_SUCCESS) { cmn_err(CE_WARN, "errorq_create: failed to register " "IPL %u softint for queue %s", ipl, name); kmem_free(eqp, sizeof (errorq_t)); return (NULL); } if ((eqp->eq_ksp = kstat_create("unix", 0, name, "errorq", KSTAT_TYPE_NAMED, sizeof (struct errorq_kstat) / sizeof (kstat_named_t), KSTAT_FLAG_VIRTUAL)) == NULL) { cmn_err(CE_WARN, "errorq_create: failed to create kstat " "for queue %s", name); if (id != NULL) ddi_remove_softintr(id); kmem_free(eqp, sizeof (errorq_t)); return (NULL); } bcopy(&errorq_kstat_template, &eqp->eq_kstat, sizeof (struct errorq_kstat)); eqp->eq_ksp->ks_data = &eqp->eq_kstat; eqp->eq_ksp->ks_private = eqp; kstat_install(eqp->eq_ksp); (void) strncpy(eqp->eq_name, name, ERRORQ_NAMELEN); eqp->eq_name[ERRORQ_NAMELEN] = '\0'; eqp->eq_func = func; eqp->eq_private = private; eqp->eq_data = kmem_alloc(qlen * size, KM_SLEEP); eqp->eq_qlen = qlen; eqp->eq_size = size; eqp->eq_ipl = ipl; eqp->eq_flags = flags | ERRORQ_ACTIVE; eqp->eq_id = id; mutex_init(&eqp->eq_lock, NULL, MUTEX_DEFAULT, NULL); eqp->eq_elems = kmem_alloc(qlen * sizeof (errorq_elem_t), KM_SLEEP); eqp->eq_phead = NULL; eqp->eq_ptail = NULL; eqp->eq_pend = NULL; eqp->eq_dump = NULL; eqp->eq_free = eqp->eq_elems; /* * Iterate over the array of errorq_elem_t structures and place each * one on the free list and set its data pointer. */ for (eep = eqp->eq_free, data = eqp->eq_data; qlen > 1; qlen--) { eep->eqe_next = NULL; eep->eqe_dump = NULL; eep->eqe_prev = eep + 1; eep->eqe_data = data; data += size; eep++; } eep->eqe_next = NULL; eep->eqe_prev = NULL; eep->eqe_data = data; eep->eqe_dump = NULL; /* * Once the errorq is initialized, add it to the global list of queues, * and then return a pointer to the new queue to the caller. */ mutex_enter(&errorq_lock); eqp->eq_next = errorq_list; errorq_list = eqp; mutex_exit(&errorq_lock); return (eqp); } /* * Create a new errorq as if by errorq_create(), but set the ERRORQ_NVLIST * flag and initialize each element to have the start of its data region used * as an errorq_nvelem_t with a nvlist allocator that consumes the data region. */ errorq_t * errorq_nvcreate(const char *name, errorq_func_t func, void *private, ulong_t qlen, size_t size, uint_t ipl, uint_t flags) { errorq_t *eqp; errorq_elem_t *eep; eqp = errorq_create(name, func, private, qlen, size + sizeof (errorq_nvelem_t), ipl, flags | ERRORQ_NVLIST); if (eqp == NULL) return (NULL); mutex_enter(&eqp->eq_lock); for (eep = eqp->eq_elems; qlen != 0; eep++, qlen--) { errorq_nvelem_t *eqnp = eep->eqe_data; eqnp->eqn_buf = (char *)eqnp + sizeof (errorq_nvelem_t); eqnp->eqn_nva = fm_nva_xcreate(eqnp->eqn_buf, size); } mutex_exit(&eqp->eq_lock); return (eqp); } /* * To destroy an error queue, we mark it as disabled and then explicitly drain * all pending errors. Once the drain is complete, we can remove the queue * from the global list of queues examined by errorq_panic(), and then free * the various queue data structures. The caller must use some higher-level * abstraction (e.g. disabling an error interrupt) to ensure that no one will * attempt to enqueue new errors while we are freeing this queue. */ void errorq_destroy(errorq_t *eqp) { errorq_t *p, **pp; errorq_elem_t *eep; ulong_t i; ASSERT(eqp != NULL); eqp->eq_flags &= ~ERRORQ_ACTIVE; errorq_drain(eqp); mutex_enter(&errorq_lock); pp = &errorq_list; for (p = errorq_list; p != NULL; p = p->eq_next) { if (p == eqp) { *pp = p->eq_next; break; } pp = &p->eq_next; } mutex_exit(&errorq_lock); ASSERT(p != NULL); if (eqp->eq_flags & ERRORQ_NVLIST) { for (eep = eqp->eq_elems, i = 0; i < eqp->eq_qlen; i++, eep++) { errorq_nvelem_t *eqnp = eep->eqe_data; fm_nva_xdestroy(eqnp->eqn_nva); } } mutex_destroy(&eqp->eq_lock); kstat_delete(eqp->eq_ksp); if (eqp->eq_id != NULL) ddi_remove_softintr(eqp->eq_id); kmem_free(eqp->eq_elems, eqp->eq_qlen * sizeof (errorq_elem_t)); kmem_free(eqp->eq_data, eqp->eq_qlen * eqp->eq_size); kmem_free(eqp, sizeof (errorq_t)); } /* * Dispatch a new error into the queue for later processing. The specified * data buffer is copied into a preallocated queue element. If 'len' is * smaller than the queue element size, the remainder of the queue element is * filled with zeroes. This function may be called from any context subject * to the Platform Considerations described above. */ void errorq_dispatch(errorq_t *eqp, const void *data, size_t len, uint_t flag) { errorq_elem_t *eep, *old; if (eqp == NULL || !(eqp->eq_flags & ERRORQ_ACTIVE)) { atomic_add_64(&errorq_lost, 1); return; /* drop error if queue is uninitialized or disabled */ } while ((eep = eqp->eq_free) != NULL) { if (casptr(&eqp->eq_free, eep, eep->eqe_prev) == eep) break; } if (eep == NULL) { atomic_add_64(&eqp->eq_kstat.eqk_dropped.value.ui64, 1); return; } ASSERT(len <= eqp->eq_size); bcopy(data, eep->eqe_data, MIN(eqp->eq_size, len)); if (len < eqp->eq_size) bzero((caddr_t)eep->eqe_data + len, eqp->eq_size - len); for (;;) { old = eqp->eq_pend; eep->eqe_prev = old; membar_producer(); if (casptr(&eqp->eq_pend, old, eep) == old) break; } atomic_add_64(&eqp->eq_kstat.eqk_dispatched.value.ui64, 1); if (flag == ERRORQ_ASYNC && eqp->eq_id != NULL) ddi_trigger_softintr(eqp->eq_id); } /* * Drain the specified error queue by calling eq_func() for each pending error. * This function must be called at or below LOCK_LEVEL or from panic context. * In order to synchronize with other attempts to drain the queue, we acquire * the adaptive eq_lock, blocking other consumers. Once this lock is held, * we must use compare-and-swap to move the pending list to the processing * list and to return elements to the free list in order to synchronize * with producers, who do not acquire any locks and only use compare-and-swap. * * An additional constraint on this function is that if the system panics * while this function is running, the panic code must be able to detect and * handle all intermediate states and correctly dequeue all errors. The * errorq_panic() function below will be used for detecting and handling * these intermediate states. The comments in errorq_drain() below explain * how we make sure each intermediate state is distinct and consistent. */ void errorq_drain(errorq_t *eqp) { errorq_elem_t *eep, *fep, *dep; ASSERT(eqp != NULL); mutex_enter(&eqp->eq_lock); /* * If there are one or more pending errors, set eq_ptail to point to * the first element on the pending list and then attempt to compare- * and-swap NULL to the pending list. We use membar_producer() to * make sure that eq_ptail will be visible to errorq_panic() below * before the pending list is NULLed out. This section is labeled * case (1) for errorq_panic, below. If eq_ptail is not yet set (1A) * eq_pend has all the pending errors. If casptr fails or has not * been called yet (1B), eq_pend still has all the pending errors. * If casptr succeeds (1C), eq_ptail has all the pending errors. */ while ((eep = eqp->eq_pend) != NULL) { eqp->eq_ptail = eep; membar_producer(); if (casptr(&eqp->eq_pend, eep, NULL) == eep) break; } /* * If no errors were pending, assert that eq_ptail is set to NULL, * drop the consumer lock, and return without doing anything. */ if (eep == NULL) { ASSERT(eqp->eq_ptail == NULL); mutex_exit(&eqp->eq_lock); return; } /* * Now iterate from eq_ptail (a.k.a. eep, the newest error) to the * oldest error, setting the eqe_next pointer so that we can iterate * over the errors from oldest to newest. We use membar_producer() * to make sure that these stores are visible before we set eq_phead. * If we panic before, during, or just after this loop (case 2), * errorq_panic() will simply redo this work, as described below. */ for (eep->eqe_next = NULL; eep->eqe_prev != NULL; eep = eep->eqe_prev) eep->eqe_prev->eqe_next = eep; membar_producer(); /* * Now set eq_phead to the head of the processing list (the oldest * error) and issue another membar_producer() to make sure that * eq_phead is seen as non-NULL before we clear eq_ptail. If we panic * after eq_phead is set (case 3), we will detect and log these errors * in errorq_panic(), as described below. */ eqp->eq_phead = eep; membar_producer(); eqp->eq_ptail = NULL; membar_producer(); /* * If we enter from errorq_panic_drain(), we may already have * errorq elements on the dump list. Find the tail of * the list ready for append. */ if (panicstr && (dep = eqp->eq_dump) != NULL) { while (dep->eqe_dump != NULL) dep = dep->eqe_dump; } /* * Now iterate over the processing list from oldest (eq_phead) to * newest and log each error. Once an error is logged, we use * compare-and-swap to return it to the free list. If we panic before, * during, or after calling eq_func() (case 4), the error will still be * found on eq_phead and will be logged in errorq_panic below. */ while ((eep = eqp->eq_phead) != NULL) { eqp->eq_func(eqp->eq_private, eep->eqe_data, eep); eqp->eq_kstat.eqk_logged.value.ui64++; eqp->eq_phead = eep->eqe_next; membar_producer(); eep->eqe_next = NULL; /* * On panic, we add the element to the dump list for each * nvlist errorq. Elements are stored oldest to newest. * Then continue, so we don't free and subsequently overwrite * any elements which we've put on the dump queue. */ if (panicstr && (eqp->eq_flags & ERRORQ_NVLIST)) { if (eqp->eq_dump == NULL) dep = eqp->eq_dump = eep; else dep = dep->eqe_dump = eep; membar_producer(); continue; } for (;;) { fep = eqp->eq_free; eep->eqe_prev = fep; membar_producer(); if (casptr(&eqp->eq_free, fep, eep) == fep) break; } } mutex_exit(&eqp->eq_lock); } /* * Now that device tree services are available, set up the soft interrupt * handlers for any queues that were created early in boot. We then * manually drain these queues to report any pending early errors. */ void errorq_init(void) { dev_info_t *dip = ddi_root_node(); ddi_softintr_t id; errorq_t *eqp; ASSERT(modrootloaded != 0); ASSERT(dip != NULL); mutex_enter(&errorq_lock); for (eqp = errorq_list; eqp != NULL; eqp = eqp->eq_next) { ddi_iblock_cookie_t ibc = (ddi_iblock_cookie_t)(uintptr_t)ipltospl(eqp->eq_ipl); if (eqp->eq_id != NULL) continue; /* softint already initialized */ if (ddi_add_softintr(dip, DDI_SOFTINT_FIXED, &id, &ibc, NULL, errorq_intr, (caddr_t)eqp) != DDI_SUCCESS) { panic("errorq_init: failed to register IPL %u softint " "for queue %s", eqp->eq_ipl, eqp->eq_name); } eqp->eq_id = id; errorq_drain(eqp); } mutex_exit(&errorq_lock); } /* * This function is designed to be called from panic context only, and * therefore does not need to acquire errorq_lock when iterating over * errorq_list. This function must be called no more than once for each * 'what' value (if you change this then review the manipulation of 'dep'. */ static uint64_t errorq_panic_drain(uint_t what) { errorq_elem_t *eep, *nep, *fep, *dep; errorq_t *eqp; uint64_t loggedtmp; uint64_t logged = 0; for (eqp = errorq_list; eqp != NULL; eqp = eqp->eq_next) { if ((eqp->eq_flags & (ERRORQ_VITAL | ERRORQ_NVLIST)) != what) continue; /* do not drain this queue on this pass */ loggedtmp = eqp->eq_kstat.eqk_logged.value.ui64; /* * In case (1B) above, eq_ptail may be set but the casptr may * not have been executed yet or may have failed. Either way, * we must log errors in chronological order. So we search * the pending list for the error pointed to by eq_ptail. If * it is found, we know that all subsequent errors are also * still on the pending list, so just NULL out eq_ptail and let * errorq_drain(), below, take care of the logging. */ for (eep = eqp->eq_pend; eep != NULL; eep = eep->eqe_prev) { if (eep == eqp->eq_ptail) { ASSERT(eqp->eq_phead == NULL); eqp->eq_ptail = NULL; break; } } /* * In cases (1C) and (2) above, eq_ptail will be set to the * newest error on the processing list but eq_phead will still * be NULL. We set the eqe_next pointers so we can iterate * over the processing list in order from oldest error to the * newest error. We then set eq_phead to point to the oldest * error and fall into the for-loop below. */ if (eqp->eq_phead == NULL && (eep = eqp->eq_ptail) != NULL) { for (eep->eqe_next = NULL; eep->eqe_prev != NULL; eep = eep->eqe_prev) eep->eqe_prev->eqe_next = eep; eqp->eq_phead = eep; eqp->eq_ptail = NULL; } /* * In cases (3) and (4) above (or after case (1C/2) handling), * eq_phead will be set to the oldest error on the processing * list. We log each error and return it to the free list. * * Unlike errorq_drain(), we don't need to worry about updating * eq_phead because errorq_panic() will be called at most once. * However, we must use casptr to update the freelist in case * errors are still being enqueued during panic. */ for (eep = eqp->eq_phead; eep != NULL; eep = nep) { eqp->eq_func(eqp->eq_private, eep->eqe_data, eep); eqp->eq_kstat.eqk_logged.value.ui64++; nep = eep->eqe_next; eep->eqe_next = NULL; /* * On panic, we add the element to the dump list for * each nvlist errorq, stored oldest to newest. Then * continue, so we don't free and subsequently overwrite * any elements which we've put on the dump queue. */ if (eqp->eq_flags & ERRORQ_NVLIST) { if (eqp->eq_dump == NULL) dep = eqp->eq_dump = eep; else dep = dep->eqe_dump = eep; membar_producer(); continue; } for (;;) { fep = eqp->eq_free; eep->eqe_prev = fep; membar_producer(); if (casptr(&eqp->eq_free, fep, eep) == fep) break; } } /* * Now go ahead and drain any other errors on the pending list. * This call transparently handles case (1A) above, as well as * any other errors that were dispatched after errorq_drain() * completed its first compare-and-swap. */ errorq_drain(eqp); logged += eqp->eq_kstat.eqk_logged.value.ui64 - loggedtmp; } return (logged); } /* * Drain all error queues - called only from panic context. Some drain * functions may enqueue errors to ERRORQ_NVLIST error queues so that * they may be written out in the panic dump - so ERRORQ_NVLIST queues * must be drained last. Drain ERRORQ_VITAL queues before nonvital queues * so that vital errors get to fill the ERRORQ_NVLIST queues first, and * do not drain the nonvital queues if there are many vital errors. */ void errorq_panic(void) { ASSERT(panicstr != NULL); if (errorq_panic_drain(ERRORQ_VITAL) <= errorq_vitalmin) (void) errorq_panic_drain(0); (void) errorq_panic_drain(ERRORQ_VITAL | ERRORQ_NVLIST); (void) errorq_panic_drain(ERRORQ_NVLIST); } /* * Reserve an error queue element for later processing and dispatching. The * element is returned to the caller who may add error-specific data to * element. The element is retured to the free list when either * errorq_commit() is called and the element asynchronously processed * or immediately when errorq_cancel() is called. */ errorq_elem_t * errorq_reserve(errorq_t *eqp) { errorq_elem_t *eqep; if (eqp == NULL || !(eqp->eq_flags & ERRORQ_ACTIVE)) { atomic_add_64(&errorq_lost, 1); return (NULL); } while ((eqep = eqp->eq_free) != NULL) { if (casptr(&eqp->eq_free, eqep, eqep->eqe_prev) == eqep) break; } if (eqep == NULL) { atomic_add_64(&eqp->eq_kstat.eqk_dropped.value.ui64, 1); return (NULL); } if (eqp->eq_flags & ERRORQ_NVLIST) { errorq_nvelem_t *eqnp = eqep->eqe_data; nv_alloc_reset(eqnp->eqn_nva); eqnp->eqn_nvl = fm_nvlist_create(eqnp->eqn_nva); } atomic_add_64(&eqp->eq_kstat.eqk_reserved.value.ui64, 1); return (eqep); } /* * Commit an errorq element (eqep) for dispatching. * This function may be called from any context subject * to the Platform Considerations described above. */ void errorq_commit(errorq_t *eqp, errorq_elem_t *eqep, uint_t flag) { errorq_elem_t *old; if (eqep == NULL || !(eqp->eq_flags & ERRORQ_ACTIVE)) { atomic_add_64(&eqp->eq_kstat.eqk_commit_fail.value.ui64, 1); return; } for (;;) { old = eqp->eq_pend; eqep->eqe_prev = old; membar_producer(); if (casptr(&eqp->eq_pend, old, eqep) == old) break; } atomic_add_64(&eqp->eq_kstat.eqk_committed.value.ui64, 1); if (flag == ERRORQ_ASYNC && eqp->eq_id != NULL) ddi_trigger_softintr(eqp->eq_id); } /* * Cancel an errorq element reservation by returning the specified element * to the free list. Duplicate or invalid frees are not supported. */ void errorq_cancel(errorq_t *eqp, errorq_elem_t *eqep) { errorq_elem_t *fep; if (eqep == NULL || !(eqp->eq_flags & ERRORQ_ACTIVE)) return; for (;;) { fep = eqp->eq_free; eqep->eqe_prev = fep; membar_producer(); if (casptr(&eqp->eq_free, fep, eqep) == fep) break; } atomic_add_64(&eqp->eq_kstat.eqk_cancelled.value.ui64, 1); } /* * Write elements on the dump list of each nvlist errorq to the dump device. * Upon reboot, fmd(1M) will extract and replay them for diagnosis. */ void errorq_dump(void) { errorq_elem_t *eep; errorq_t *eqp; if (ereport_dumpbuf == NULL) return; /* reboot or panic before errorq is even set up */ for (eqp = errorq_list; eqp != NULL; eqp = eqp->eq_next) { if (!(eqp->eq_flags & ERRORQ_NVLIST) || !(eqp->eq_flags & ERRORQ_ACTIVE)) continue; /* do not dump this queue on panic */ for (eep = eqp->eq_dump; eep != NULL; eep = eep->eqe_dump) { errorq_nvelem_t *eqnp = eep->eqe_data; size_t len = 0; erpt_dump_t ed; int err; (void) nvlist_size(eqnp->eqn_nvl, &len, NV_ENCODE_NATIVE); if (len > ereport_dumplen || len == 0) { cmn_err(CE_WARN, "%s: unable to save error " "report %p due to size %lu\n", eqp->eq_name, (void *)eep, len); continue; } if ((err = nvlist_pack(eqnp->eqn_nvl, (char **)&ereport_dumpbuf, &ereport_dumplen, NV_ENCODE_NATIVE, KM_NOSLEEP)) != 0) { cmn_err(CE_WARN, "%s: unable to save error " "report %p due to pack error %d\n", eqp->eq_name, (void *)eep, err); continue; } ed.ed_magic = ERPT_MAGIC; ed.ed_chksum = checksum32(ereport_dumpbuf, len); ed.ed_size = (uint32_t)len; ed.ed_pad = 0; ed.ed_hrt_nsec = 0; ed.ed_hrt_base = panic_hrtime; ed.ed_tod_base.sec = panic_hrestime.tv_sec; ed.ed_tod_base.nsec = panic_hrestime.tv_nsec; dumpvp_write(&ed, sizeof (ed)); dumpvp_write(ereport_dumpbuf, len); } } } nvlist_t * errorq_elem_nvl(errorq_t *eqp, const errorq_elem_t *eqep) { errorq_nvelem_t *eqnp = eqep->eqe_data; ASSERT(eqp->eq_flags & ERRORQ_ACTIVE && eqp->eq_flags & ERRORQ_NVLIST); return (eqnp->eqn_nvl); } nv_alloc_t * errorq_elem_nva(errorq_t *eqp, const errorq_elem_t *eqep) { errorq_nvelem_t *eqnp = eqep->eqe_data; ASSERT(eqp->eq_flags & ERRORQ_ACTIVE && eqp->eq_flags & ERRORQ_NVLIST); return (eqnp->eqn_nva); } /* * Reserve a new element and duplicate the data of the original into it. */ void * errorq_elem_dup(errorq_t *eqp, const errorq_elem_t *eqep, errorq_elem_t **neqep) { ASSERT(eqp->eq_flags & ERRORQ_ACTIVE); ASSERT(!(eqp->eq_flags & ERRORQ_NVLIST)); if ((*neqep = errorq_reserve(eqp)) == NULL) return (NULL); bcopy(eqep->eqe_data, (*neqep)->eqe_data, eqp->eq_size); return ((*neqep)->eqe_data); }