Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Matthew Sakai | 5860 | 98.62% | 1 | 11.11% |
Mike Snitzer | 77 | 1.30% | 7 | 77.78% |
Bruce Johnston | 5 | 0.08% | 1 | 11.11% |
Total | 5942 | 9 |
// SPDX-License-Identifier: GPL-2.0-only /* * Copyright 2023 Red Hat */ #include "recovery-journal.h" #include <linux/atomic.h> #include <linux/bio.h> #include "logger.h" #include "memory-alloc.h" #include "permassert.h" #include "block-map.h" #include "completion.h" #include "constants.h" #include "data-vio.h" #include "encodings.h" #include "io-submitter.h" #include "slab-depot.h" #include "types.h" #include "vdo.h" #include "vio.h" #include "wait-queue.h" static const u64 RECOVERY_COUNT_MASK = 0xff; /* * The number of reserved blocks must be large enough to prevent a new recovery journal * block write from overwriting a block which appears to still be a valid head block of the * journal. Currently, that means reserving enough space for all 2048 data_vios. */ #define RECOVERY_JOURNAL_RESERVED_BLOCKS \ ((MAXIMUM_VDO_USER_VIOS / RECOVERY_JOURNAL_ENTRIES_PER_BLOCK) + 2) /** * DOC: Lock Counters. * * A lock_counter is intended to keep all of the locks for the blocks in the recovery journal. The * per-zone counters are all kept in a single array which is arranged by zone (i.e. zone 0's lock 0 * is at index 0, zone 0's lock 1 is at index 1, and zone 1's lock 0 is at index 'locks'. This * arrangement is intended to minimize cache-line contention for counters from different zones. * * The locks are implemented as a single object instead of as a lock counter per lock both to * afford this opportunity to reduce cache line contention and also to eliminate the need to have a * completion per lock. * * Lock sets are laid out with the set for recovery journal first, followed by the logical zones, * and then the physical zones. */ enum lock_counter_state { LOCK_COUNTER_STATE_NOT_NOTIFYING, LOCK_COUNTER_STATE_NOTIFYING, LOCK_COUNTER_STATE_SUSPENDED, }; /** * get_zone_count_ptr() - Get a pointer to the zone count for a given lock on a given zone. * @journal: The recovery journal. * @lock_number: The lock to get. * @zone_type: The zone type whose count is desired. * * Return: A pointer to the zone count for the given lock and zone. */ static inline atomic_t *get_zone_count_ptr(struct recovery_journal *journal, block_count_t lock_number, enum vdo_zone_type zone_type) { return ((zone_type == VDO_ZONE_TYPE_LOGICAL) ? &journal->lock_counter.logical_zone_counts[lock_number] : &journal->lock_counter.physical_zone_counts[lock_number]); } /** * get_counter() - Get the zone counter for a given lock on a given zone. * @journal: The recovery journal. * @lock_number: The lock to get. * @zone_type: The zone type whose count is desired. * @zone_id: The zone index whose count is desired. * * Return: The counter for the given lock and zone. */ static inline u16 *get_counter(struct recovery_journal *journal, block_count_t lock_number, enum vdo_zone_type zone_type, zone_count_t zone_id) { struct lock_counter *counter = &journal->lock_counter; block_count_t zone_counter = (counter->locks * zone_id) + lock_number; if (zone_type == VDO_ZONE_TYPE_JOURNAL) return &counter->journal_counters[zone_counter]; if (zone_type == VDO_ZONE_TYPE_LOGICAL) return &counter->logical_counters[zone_counter]; return &counter->physical_counters[zone_counter]; } static atomic_t *get_decrement_counter(struct recovery_journal *journal, block_count_t lock_number) { return &journal->lock_counter.journal_decrement_counts[lock_number]; } /** * is_journal_zone_locked() - Check whether the journal zone is locked for a given lock. * @journal: The recovery journal. * @lock_number: The lock to check. * * Return: true if the journal zone is locked. */ static bool is_journal_zone_locked(struct recovery_journal *journal, block_count_t lock_number) { u16 journal_value = *get_counter(journal, lock_number, VDO_ZONE_TYPE_JOURNAL, 0); u32 decrements = atomic_read(get_decrement_counter(journal, lock_number)); /* Pairs with barrier in vdo_release_journal_entry_lock() */ smp_rmb(); VDO_ASSERT_LOG_ONLY((decrements <= journal_value), "journal zone lock counter must not underflow"); return (journal_value != decrements); } /** * vdo_release_recovery_journal_block_reference() - Release a reference to a recovery journal * block. * @journal: The recovery journal. * @sequence_number: The journal sequence number of the referenced block. * @zone_type: The type of the zone making the adjustment. * @zone_id: The ID of the zone making the adjustment. * * If this is the last reference for a given zone type, an attempt will be made to reap the * journal. */ void vdo_release_recovery_journal_block_reference(struct recovery_journal *journal, sequence_number_t sequence_number, enum vdo_zone_type zone_type, zone_count_t zone_id) { u16 *current_value; block_count_t lock_number; int prior_state; if (sequence_number == 0) return; lock_number = vdo_get_recovery_journal_block_number(journal, sequence_number); current_value = get_counter(journal, lock_number, zone_type, zone_id); VDO_ASSERT_LOG_ONLY((*current_value >= 1), "decrement of lock counter must not underflow"); *current_value -= 1; if (zone_type == VDO_ZONE_TYPE_JOURNAL) { if (is_journal_zone_locked(journal, lock_number)) return; } else { atomic_t *zone_count; if (*current_value != 0) return; zone_count = get_zone_count_ptr(journal, lock_number, zone_type); if (atomic_add_return(-1, zone_count) > 0) return; } /* * Extra barriers because this was original developed using a CAS operation that implicitly * had them. */ smp_mb__before_atomic(); prior_state = atomic_cmpxchg(&journal->lock_counter.state, LOCK_COUNTER_STATE_NOT_NOTIFYING, LOCK_COUNTER_STATE_NOTIFYING); /* same as before_atomic */ smp_mb__after_atomic(); if (prior_state != LOCK_COUNTER_STATE_NOT_NOTIFYING) return; vdo_launch_completion(&journal->lock_counter.completion); } static inline struct recovery_journal_block * __must_check get_journal_block(struct list_head *list) { return list_first_entry_or_null(list, struct recovery_journal_block, list_node); } /** * pop_free_list() - Get a block from the end of the free list. * @journal: The journal. * * Return: The block or NULL if the list is empty. */ static struct recovery_journal_block * __must_check pop_free_list(struct recovery_journal *journal) { struct recovery_journal_block *block; if (list_empty(&journal->free_tail_blocks)) return NULL; block = list_last_entry(&journal->free_tail_blocks, struct recovery_journal_block, list_node); list_del_init(&block->list_node); return block; } /** * is_block_dirty() - Check whether a recovery block is dirty. * @block: The block to check. * * Indicates it has any uncommitted entries, which includes both entries not written and entries * written but not yet acknowledged. * * Return: true if the block has any uncommitted entries. */ static inline bool __must_check is_block_dirty(const struct recovery_journal_block *block) { return (block->uncommitted_entry_count > 0); } /** * is_block_empty() - Check whether a journal block is empty. * @block: The block to check. * * Return: true if the block has no entries. */ static inline bool __must_check is_block_empty(const struct recovery_journal_block *block) { return (block->entry_count == 0); } /** * is_block_full() - Check whether a journal block is full. * @block: The block to check. * * Return: true if the block is full. */ static inline bool __must_check is_block_full(const struct recovery_journal_block *block) { return ((block == NULL) || (block->journal->entries_per_block == block->entry_count)); } /** * assert_on_journal_thread() - Assert that we are running on the journal thread. * @journal: The journal. * @function_name: The function doing the check (for logging). */ static void assert_on_journal_thread(struct recovery_journal *journal, const char *function_name) { VDO_ASSERT_LOG_ONLY((vdo_get_callback_thread_id() == journal->thread_id), "%s() called on journal thread", function_name); } /** * continue_waiter() - Release a data_vio from the journal. * * Invoked whenever a data_vio is to be released from the journal, either because its entry was * committed to disk, or because there was an error. Implements waiter_callback_fn. */ static void continue_waiter(struct vdo_waiter *waiter, void *context) { continue_data_vio_with_error(vdo_waiter_as_data_vio(waiter), *((int *) context)); } /** * has_block_waiters() - Check whether the journal has any waiters on any blocks. * @journal: The journal in question. * * Return: true if any block has a waiter. */ static inline bool has_block_waiters(struct recovery_journal *journal) { struct recovery_journal_block *block = get_journal_block(&journal->active_tail_blocks); /* * Either the first active tail block (if it exists) has waiters, or no active tail block * has waiters. */ return ((block != NULL) && (vdo_waitq_has_waiters(&block->entry_waiters) || vdo_waitq_has_waiters(&block->commit_waiters))); } static void recycle_journal_blocks(struct recovery_journal *journal); static void recycle_journal_block(struct recovery_journal_block *block); static void notify_commit_waiters(struct recovery_journal *journal); /** * suspend_lock_counter() - Prevent the lock counter from notifying. * @counter: The counter. * * Return: true if the lock counter was not notifying and hence the suspend was efficacious. */ static bool suspend_lock_counter(struct lock_counter *counter) { int prior_state; /* * Extra barriers because this was originally developed using a CAS operation that * implicitly had them. */ smp_mb__before_atomic(); prior_state = atomic_cmpxchg(&counter->state, LOCK_COUNTER_STATE_NOT_NOTIFYING, LOCK_COUNTER_STATE_SUSPENDED); /* same as before_atomic */ smp_mb__after_atomic(); return ((prior_state == LOCK_COUNTER_STATE_SUSPENDED) || (prior_state == LOCK_COUNTER_STATE_NOT_NOTIFYING)); } static inline bool is_read_only(struct recovery_journal *journal) { return vdo_is_read_only(journal->flush_vio->completion.vdo); } /** * check_for_drain_complete() - Check whether the journal has drained. * @journal: The journal which may have just drained. */ static void check_for_drain_complete(struct recovery_journal *journal) { int result = VDO_SUCCESS; if (is_read_only(journal)) { result = VDO_READ_ONLY; /* * Clean up any full active blocks which were not written due to read-only mode. * * FIXME: This would probably be better as a short-circuit in write_block(). */ notify_commit_waiters(journal); recycle_journal_blocks(journal); /* Release any data_vios waiting to be assigned entries. */ vdo_waitq_notify_all_waiters(&journal->entry_waiters, continue_waiter, &result); } if (!vdo_is_state_draining(&journal->state) || journal->reaping || has_block_waiters(journal) || vdo_waitq_has_waiters(&journal->entry_waiters) || !suspend_lock_counter(&journal->lock_counter)) return; if (vdo_is_state_saving(&journal->state)) { if (journal->active_block != NULL) { VDO_ASSERT_LOG_ONLY(((result == VDO_READ_ONLY) || !is_block_dirty(journal->active_block)), "journal being saved has clean active block"); recycle_journal_block(journal->active_block); } VDO_ASSERT_LOG_ONLY(list_empty(&journal->active_tail_blocks), "all blocks in a journal being saved must be inactive"); } vdo_finish_draining_with_result(&journal->state, result); } /** * notify_recovery_journal_of_read_only_mode() - Notify a recovery journal that the VDO has gone * read-only. * @listener: The journal. * @parent: The completion to notify in order to acknowledge the notification. * * Implements vdo_read_only_notification_fn. */ static void notify_recovery_journal_of_read_only_mode(void *listener, struct vdo_completion *parent) { check_for_drain_complete(listener); vdo_finish_completion(parent); } /** * enter_journal_read_only_mode() - Put the journal in read-only mode. * @journal: The journal which has failed. * @error_code: The error result triggering this call. * * All attempts to add entries after this function is called will fail. All VIOs waiting for * commits will be awakened with an error. */ static void enter_journal_read_only_mode(struct recovery_journal *journal, int error_code) { vdo_enter_read_only_mode(journal->flush_vio->completion.vdo, error_code); check_for_drain_complete(journal); } /** * vdo_get_recovery_journal_current_sequence_number() - Obtain the recovery journal's current * sequence number. * @journal: The journal in question. * * Exposed only so the block map can be initialized therefrom. * * Return: The sequence number of the tail block. */ sequence_number_t vdo_get_recovery_journal_current_sequence_number(struct recovery_journal *journal) { return journal->tail; } /** * get_recovery_journal_head() - Get the head of the recovery journal. * @journal: The journal. * * The head is the lowest sequence number of the block map head and the slab journal head. * * Return: the head of the journal. */ static inline sequence_number_t get_recovery_journal_head(const struct recovery_journal *journal) { return min(journal->block_map_head, journal->slab_journal_head); } /** * compute_recovery_count_byte() - Compute the recovery count byte for a given recovery count. * @recovery_count: The recovery count. * * Return: The byte corresponding to the recovery count. */ static inline u8 __must_check compute_recovery_count_byte(u64 recovery_count) { return (u8)(recovery_count & RECOVERY_COUNT_MASK); } /** * check_slab_journal_commit_threshold() - Check whether the journal is over the threshold, and if * so, force the oldest slab journal tail block to commit. * @journal: The journal. */ static void check_slab_journal_commit_threshold(struct recovery_journal *journal) { block_count_t current_length = journal->tail - journal->slab_journal_head; if (current_length > journal->slab_journal_commit_threshold) { journal->events.slab_journal_commits_requested++; vdo_commit_oldest_slab_journal_tail_blocks(journal->depot, journal->slab_journal_head); } } static void reap_recovery_journal(struct recovery_journal *journal); static void assign_entries(struct recovery_journal *journal); /** * finish_reaping() - Finish reaping the journal. * @journal: The journal being reaped. */ static void finish_reaping(struct recovery_journal *journal) { block_count_t blocks_reaped; sequence_number_t old_head = get_recovery_journal_head(journal); journal->block_map_head = journal->block_map_reap_head; journal->slab_journal_head = journal->slab_journal_reap_head; blocks_reaped = get_recovery_journal_head(journal) - old_head; journal->available_space += blocks_reaped * journal->entries_per_block; journal->reaping = false; check_slab_journal_commit_threshold(journal); assign_entries(journal); check_for_drain_complete(journal); } /** * complete_reaping() - Finish reaping the journal after flushing the lower layer. * @completion: The journal's flush VIO. * * This is the callback registered in reap_recovery_journal(). */ static void complete_reaping(struct vdo_completion *completion) { struct recovery_journal *journal = completion->parent; finish_reaping(journal); /* Try reaping again in case more locks were released while flush was out. */ reap_recovery_journal(journal); } /** * handle_flush_error() - Handle an error when flushing the lower layer due to reaping. * @completion: The journal's flush VIO. */ static void handle_flush_error(struct vdo_completion *completion) { struct recovery_journal *journal = completion->parent; vio_record_metadata_io_error(as_vio(completion)); journal->reaping = false; enter_journal_read_only_mode(journal, completion->result); } static void flush_endio(struct bio *bio) { struct vio *vio = bio->bi_private; struct recovery_journal *journal = vio->completion.parent; continue_vio_after_io(vio, complete_reaping, journal->thread_id); } /** * initialize_journal_state() - Set all journal fields appropriately to start journaling from the * current active block. * @journal: The journal to be reset based on its active block. */ static void initialize_journal_state(struct recovery_journal *journal) { journal->append_point.sequence_number = journal->tail; journal->last_write_acknowledged = journal->tail; journal->block_map_head = journal->tail; journal->slab_journal_head = journal->tail; journal->block_map_reap_head = journal->tail; journal->slab_journal_reap_head = journal->tail; journal->block_map_head_block_number = vdo_get_recovery_journal_block_number(journal, journal->block_map_head); journal->slab_journal_head_block_number = vdo_get_recovery_journal_block_number(journal, journal->slab_journal_head); journal->available_space = (journal->entries_per_block * vdo_get_recovery_journal_length(journal->size)); } /** * vdo_get_recovery_journal_length() - Get the number of usable recovery journal blocks. * @journal_size: The size of the recovery journal in blocks. * * Return: the number of recovery journal blocks usable for entries. */ block_count_t vdo_get_recovery_journal_length(block_count_t journal_size) { block_count_t reserved_blocks = journal_size / 4; if (reserved_blocks > RECOVERY_JOURNAL_RESERVED_BLOCKS) reserved_blocks = RECOVERY_JOURNAL_RESERVED_BLOCKS; return (journal_size - reserved_blocks); } /** * reap_recovery_journal_callback() - Attempt to reap the journal. * @completion: The lock counter completion. * * Attempts to reap the journal now that all the locks on some journal block have been released. * This is the callback registered with the lock counter. */ static void reap_recovery_journal_callback(struct vdo_completion *completion) { struct recovery_journal *journal = (struct recovery_journal *) completion->parent; /* * The acknowledgment must be done before reaping so that there is no race between * acknowledging the notification and unlocks wishing to notify. */ smp_wmb(); atomic_set(&journal->lock_counter.state, LOCK_COUNTER_STATE_NOT_NOTIFYING); if (vdo_is_state_quiescing(&journal->state)) { /* * Don't start reaping when the journal is trying to quiesce. Do check if this * notification is the last thing the is waiting on. */ check_for_drain_complete(journal); return; } reap_recovery_journal(journal); check_slab_journal_commit_threshold(journal); } /** * initialize_lock_counter() - Initialize a lock counter. * * @journal: The recovery journal. * @vdo: The vdo. * * Return: VDO_SUCCESS or an error. */ static int __must_check initialize_lock_counter(struct recovery_journal *journal, struct vdo *vdo) { int result; struct thread_config *config = &vdo->thread_config; struct lock_counter *counter = &journal->lock_counter; result = vdo_allocate(journal->size, u16, __func__, &counter->journal_counters); if (result != VDO_SUCCESS) return result; result = vdo_allocate(journal->size, atomic_t, __func__, &counter->journal_decrement_counts); if (result != VDO_SUCCESS) return result; result = vdo_allocate(journal->size * config->logical_zone_count, u16, __func__, &counter->logical_counters); if (result != VDO_SUCCESS) return result; result = vdo_allocate(journal->size, atomic_t, __func__, &counter->logical_zone_counts); if (result != VDO_SUCCESS) return result; result = vdo_allocate(journal->size * config->physical_zone_count, u16, __func__, &counter->physical_counters); if (result != VDO_SUCCESS) return result; result = vdo_allocate(journal->size, atomic_t, __func__, &counter->physical_zone_counts); if (result != VDO_SUCCESS) return result; vdo_initialize_completion(&counter->completion, vdo, VDO_LOCK_COUNTER_COMPLETION); vdo_prepare_completion(&counter->completion, reap_recovery_journal_callback, reap_recovery_journal_callback, config->journal_thread, journal); counter->logical_zones = config->logical_zone_count; counter->physical_zones = config->physical_zone_count; counter->locks = journal->size; return VDO_SUCCESS; } /** * set_journal_tail() - Set the journal's tail sequence number. * @journal: The journal whose tail is to be set. * @tail: The new tail value. */ static void set_journal_tail(struct recovery_journal *journal, sequence_number_t tail) { /* VDO does not support sequence numbers above 1 << 48 in the slab journal. */ if (tail >= (1ULL << 48)) enter_journal_read_only_mode(journal, VDO_JOURNAL_OVERFLOW); journal->tail = tail; } /** * initialize_recovery_block() - Initialize a journal block. * @vdo: The vdo from which to construct vios. * @journal: The journal to which the block will belong. * @block: The block to initialize. * * Return: VDO_SUCCESS or an error. */ static int initialize_recovery_block(struct vdo *vdo, struct recovery_journal *journal, struct recovery_journal_block *block) { char *data; int result; /* * Ensure that a block is large enough to store RECOVERY_JOURNAL_ENTRIES_PER_BLOCK entries. */ BUILD_BUG_ON(RECOVERY_JOURNAL_ENTRIES_PER_BLOCK > ((VDO_BLOCK_SIZE - sizeof(struct packed_journal_header)) / sizeof(struct packed_recovery_journal_entry))); /* * Allocate a full block for the journal block even though not all of the space is used * since the VIO needs to write a full disk block. */ result = vdo_allocate(VDO_BLOCK_SIZE, char, __func__, &data); if (result != VDO_SUCCESS) return result; result = allocate_vio_components(vdo, VIO_TYPE_RECOVERY_JOURNAL, VIO_PRIORITY_HIGH, block, 1, data, &block->vio); if (result != VDO_SUCCESS) { vdo_free(data); return result; } list_add_tail(&block->list_node, &journal->free_tail_blocks); block->journal = journal; return VDO_SUCCESS; } /** * vdo_decode_recovery_journal() - Make a recovery journal and initialize it with the state that * was decoded from the super block. * * @state: The decoded state of the journal. * @nonce: The nonce of the VDO. * @vdo: The VDO. * @partition: The partition for the journal. * @recovery_count: The VDO's number of completed recoveries. * @journal_size: The number of blocks in the journal on disk. * @journal_ptr: The pointer to hold the new recovery journal. * * Return: A success or error code. */ int vdo_decode_recovery_journal(struct recovery_journal_state_7_0 state, nonce_t nonce, struct vdo *vdo, struct partition *partition, u64 recovery_count, block_count_t journal_size, struct recovery_journal **journal_ptr) { block_count_t i; struct recovery_journal *journal; int result; result = vdo_allocate_extended(struct recovery_journal, RECOVERY_JOURNAL_RESERVED_BLOCKS, struct recovery_journal_block, __func__, &journal); if (result != VDO_SUCCESS) return result; INIT_LIST_HEAD(&journal->free_tail_blocks); INIT_LIST_HEAD(&journal->active_tail_blocks); vdo_waitq_init(&journal->pending_writes); journal->thread_id = vdo->thread_config.journal_thread; journal->origin = partition->offset; journal->nonce = nonce; journal->recovery_count = compute_recovery_count_byte(recovery_count); journal->size = journal_size; journal->slab_journal_commit_threshold = (journal_size * 2) / 3; journal->logical_blocks_used = state.logical_blocks_used; journal->block_map_data_blocks = state.block_map_data_blocks; journal->entries_per_block = RECOVERY_JOURNAL_ENTRIES_PER_BLOCK; set_journal_tail(journal, state.journal_start); initialize_journal_state(journal); /* TODO: this will have to change if we make initial resume of a VDO a real resume */ vdo_set_admin_state_code(&journal->state, VDO_ADMIN_STATE_SUSPENDED); for (i = 0; i < RECOVERY_JOURNAL_RESERVED_BLOCKS; i++) { struct recovery_journal_block *block = &journal->blocks[i]; result = initialize_recovery_block(vdo, journal, block); if (result != VDO_SUCCESS) { vdo_free_recovery_journal(journal); return result; } } result = initialize_lock_counter(journal, vdo); if (result != VDO_SUCCESS) { vdo_free_recovery_journal(journal); return result; } result = create_metadata_vio(vdo, VIO_TYPE_RECOVERY_JOURNAL, VIO_PRIORITY_HIGH, journal, NULL, &journal->flush_vio); if (result != VDO_SUCCESS) { vdo_free_recovery_journal(journal); return result; } result = vdo_register_read_only_listener(vdo, journal, notify_recovery_journal_of_read_only_mode, journal->thread_id); if (result != VDO_SUCCESS) { vdo_free_recovery_journal(journal); return result; } result = vdo_make_default_thread(vdo, journal->thread_id); if (result != VDO_SUCCESS) { vdo_free_recovery_journal(journal); return result; } journal->flush_vio->completion.callback_thread_id = journal->thread_id; *journal_ptr = journal; return VDO_SUCCESS; } /** * vdo_free_recovery_journal() - Free a recovery journal. * @journal: The recovery journal to free. */ void vdo_free_recovery_journal(struct recovery_journal *journal) { block_count_t i; if (journal == NULL) return; vdo_free(vdo_forget(journal->lock_counter.logical_zone_counts)); vdo_free(vdo_forget(journal->lock_counter.physical_zone_counts)); vdo_free(vdo_forget(journal->lock_counter.journal_counters)); vdo_free(vdo_forget(journal->lock_counter.journal_decrement_counts)); vdo_free(vdo_forget(journal->lock_counter.logical_counters)); vdo_free(vdo_forget(journal->lock_counter.physical_counters)); free_vio(vdo_forget(journal->flush_vio)); /* * FIXME: eventually, the journal should be constructed in a quiescent state which * requires opening before use. */ if (!vdo_is_state_quiescent(&journal->state)) { VDO_ASSERT_LOG_ONLY(list_empty(&journal->active_tail_blocks), "journal being freed has no active tail blocks"); } else if (!vdo_is_state_saved(&journal->state) && !list_empty(&journal->active_tail_blocks)) { vdo_log_warning("journal being freed has uncommitted entries"); } for (i = 0; i < RECOVERY_JOURNAL_RESERVED_BLOCKS; i++) { struct recovery_journal_block *block = &journal->blocks[i]; vdo_free(vdo_forget(block->vio.data)); free_vio_components(&block->vio); } vdo_free(journal); } /** * vdo_initialize_recovery_journal_post_repair() - Initialize the journal after a repair. * @journal: The journal in question. * @recovery_count: The number of completed recoveries. * @tail: The new tail block sequence number. * @logical_blocks_used: The new number of logical blocks used. * @block_map_data_blocks: The new number of block map data blocks. */ void vdo_initialize_recovery_journal_post_repair(struct recovery_journal *journal, u64 recovery_count, sequence_number_t tail, block_count_t logical_blocks_used, block_count_t block_map_data_blocks) { set_journal_tail(journal, tail + 1); journal->recovery_count = compute_recovery_count_byte(recovery_count); initialize_journal_state(journal); journal->logical_blocks_used = logical_blocks_used; journal->block_map_data_blocks = block_map_data_blocks; } /** * vdo_get_journal_block_map_data_blocks_used() - Get the number of block map pages, allocated from * data blocks, currently in use. * @journal: The journal in question. * * Return: The number of block map pages allocated from slabs. */ block_count_t vdo_get_journal_block_map_data_blocks_used(struct recovery_journal *journal) { return journal->block_map_data_blocks; } /** * vdo_get_recovery_journal_thread_id() - Get the ID of a recovery journal's thread. * @journal: The journal to query. * * Return: The ID of the journal's thread. */ thread_id_t vdo_get_recovery_journal_thread_id(struct recovery_journal *journal) { return journal->thread_id; } /** * vdo_open_recovery_journal() - Prepare the journal for new entries. * @journal: The journal in question. * @depot: The slab depot for this VDO. * @block_map: The block map for this VDO. */ void vdo_open_recovery_journal(struct recovery_journal *journal, struct slab_depot *depot, struct block_map *block_map) { journal->depot = depot; journal->block_map = block_map; WRITE_ONCE(journal->state.current_state, VDO_ADMIN_STATE_NORMAL_OPERATION); } /** * vdo_record_recovery_journal() - Record the state of a recovery journal for encoding in the super * block. * @journal: the recovery journal. * * Return: the state of the journal. */ struct recovery_journal_state_7_0 vdo_record_recovery_journal(const struct recovery_journal *journal) { struct recovery_journal_state_7_0 state = { .logical_blocks_used = journal->logical_blocks_used, .block_map_data_blocks = journal->block_map_data_blocks, }; if (vdo_is_state_saved(&journal->state)) { /* * If the journal is saved, we should start one past the active block (since the * active block is not guaranteed to be empty). */ state.journal_start = journal->tail; } else { /* * When we're merely suspended or have gone read-only, we must record the first * block that might have entries that need to be applied. */ state.journal_start = get_recovery_journal_head(journal); } return state; } /** * get_block_header() - Get a pointer to the packed journal block header in the block buffer. * @block: The recovery block. * * Return: The block's header. */ static inline struct packed_journal_header * get_block_header(const struct recovery_journal_block *block) { return (struct packed_journal_header *) block->vio.data; } /** * set_active_sector() - Set the current sector of the current block and initialize it. * @block: The block to update. * @sector: A pointer to the first byte of the new sector. */ static void set_active_sector(struct recovery_journal_block *block, void *sector) { block->sector = sector; block->sector->check_byte = get_block_header(block)->check_byte; block->sector->recovery_count = block->journal->recovery_count; block->sector->entry_count = 0; } /** * advance_tail() - Advance the tail of the journal. * @journal: The journal whose tail should be advanced. * * Return: true if the tail was advanced. */ static bool advance_tail(struct recovery_journal *journal) { struct recovery_block_header unpacked; struct packed_journal_header *header; struct recovery_journal_block *block; block = journal->active_block = pop_free_list(journal); if (block == NULL) return false; list_move_tail(&block->list_node, &journal->active_tail_blocks); unpacked = (struct recovery_block_header) { .metadata_type = VDO_METADATA_RECOVERY_JOURNAL_2, .block_map_data_blocks = journal->block_map_data_blocks, .logical_blocks_used = journal->logical_blocks_used, .nonce = journal->nonce, .recovery_count = journal->recovery_count, .sequence_number = journal->tail, .check_byte = vdo_compute_recovery_journal_check_byte(journal, journal->tail), }; header = get_block_header(block); memset(block->vio.data, 0x0, VDO_BLOCK_SIZE); block->sequence_number = journal->tail; block->entry_count = 0; block->uncommitted_entry_count = 0; block->block_number = vdo_get_recovery_journal_block_number(journal, journal->tail); vdo_pack_recovery_block_header(&unpacked, header); set_active_sector(block, vdo_get_journal_block_sector(header, 1)); set_journal_tail(journal, journal->tail + 1); vdo_advance_block_map_era(journal->block_map, journal->tail); return true; } /** * initialize_lock_count() - Initialize the value of the journal zone's counter for a given lock. * @journal: The recovery journal. * * Context: This must be called from the journal zone. */ static void initialize_lock_count(struct recovery_journal *journal) { u16 *journal_value; block_count_t lock_number = journal->active_block->block_number; atomic_t *decrement_counter = get_decrement_counter(journal, lock_number); journal_value = get_counter(journal, lock_number, VDO_ZONE_TYPE_JOURNAL, 0); VDO_ASSERT_LOG_ONLY((*journal_value == atomic_read(decrement_counter)), "count to be initialized not in use"); *journal_value = journal->entries_per_block + 1; atomic_set(decrement_counter, 0); } /** * prepare_to_assign_entry() - Prepare the currently active block to receive an entry and check * whether an entry of the given type may be assigned at this time. * @journal: The journal receiving an entry. * * Return: true if there is space in the journal to store an entry of the specified type. */ static bool prepare_to_assign_entry(struct recovery_journal *journal) { if (journal->available_space == 0) return false; if (is_block_full(journal->active_block) && !advance_tail(journal)) return false; if (!is_block_empty(journal->active_block)) return true; if ((journal->tail - get_recovery_journal_head(journal)) > journal->size) { /* Cannot use this block since the journal is full. */ journal->events.disk_full++; return false; } /* * Don't allow the new block to be reaped until all of its entries have been committed to * the block map and until the journal block has been fully committed as well. Because the * block map update is done only after any slab journal entries have been made, the * per-entry lock for the block map entry serves to protect those as well. */ initialize_lock_count(journal); return true; } static void write_blocks(struct recovery_journal *journal); /** * schedule_block_write() - Queue a block for writing. * @journal: The journal in question. * @block: The block which is now ready to write. * * The block is expected to be full. If the block is currently writing, this is a noop as the block * will be queued for writing when the write finishes. The block must not currently be queued for * writing. */ static void schedule_block_write(struct recovery_journal *journal, struct recovery_journal_block *block) { if (!block->committing) vdo_waitq_enqueue_waiter(&journal->pending_writes, &block->write_waiter); /* * At the end of adding entries, or discovering this partial block is now full and ready to * rewrite, we will call write_blocks() and write a whole batch. */ } /** * release_journal_block_reference() - Release a reference to a journal block. * @block: The journal block from which to release a reference. */ static void release_journal_block_reference(struct recovery_journal_block *block) { vdo_release_recovery_journal_block_reference(block->journal, block->sequence_number, VDO_ZONE_TYPE_JOURNAL, 0); } static void update_usages(struct recovery_journal *journal, struct data_vio *data_vio) { if (data_vio->increment_updater.operation == VDO_JOURNAL_BLOCK_MAP_REMAPPING) { journal->block_map_data_blocks++; return; } if (data_vio->new_mapped.state != VDO_MAPPING_STATE_UNMAPPED) journal->logical_blocks_used++; if (data_vio->mapped.state != VDO_MAPPING_STATE_UNMAPPED) journal->logical_blocks_used--; } /** * assign_entry() - Assign an entry waiter to the active block. * * Implements waiter_callback_fn. */ static void assign_entry(struct vdo_waiter *waiter, void *context) { struct data_vio *data_vio = vdo_waiter_as_data_vio(waiter); struct recovery_journal_block *block = context; struct recovery_journal *journal = block->journal; /* Record the point at which we will make the journal entry. */ data_vio->recovery_journal_point = (struct journal_point) { .sequence_number = block->sequence_number, .entry_count = block->entry_count, }; update_usages(journal, data_vio); journal->available_space--; if (!vdo_waitq_has_waiters(&block->entry_waiters)) journal->events.blocks.started++; vdo_waitq_enqueue_waiter(&block->entry_waiters, &data_vio->waiter); block->entry_count++; block->uncommitted_entry_count++; journal->events.entries.started++; if (is_block_full(block)) { /* * The block is full, so we can write it anytime henceforth. If it is already * committing, we'll queue it for writing when it comes back. */ schedule_block_write(journal, block); } /* Force out slab journal tail blocks when threshold is reached. */ check_slab_journal_commit_threshold(journal); } static void assign_entries(struct recovery_journal *journal) { if (journal->adding_entries) { /* Protect against re-entrancy. */ return; } journal->adding_entries = true; while (vdo_waitq_has_waiters(&journal->entry_waiters) && prepare_to_assign_entry(journal)) { vdo_waitq_notify_next_waiter(&journal->entry_waiters, assign_entry, journal->active_block); } /* Now that we've finished with entries, see if we have a batch of blocks to write. */ write_blocks(journal); journal->adding_entries = false; } /** * recycle_journal_block() - Prepare an in-memory journal block to be reused now that it has been * fully committed. * @block: The block to be recycled. */ static void recycle_journal_block(struct recovery_journal_block *block) { struct recovery_journal *journal = block->journal; block_count_t i; list_move_tail(&block->list_node, &journal->free_tail_blocks); /* Release any unused entry locks. */ for (i = block->entry_count; i < journal->entries_per_block; i++) release_journal_block_reference(block); /* * Release our own lock against reaping now that the block is completely committed, or * we're giving up because we're in read-only mode. */ if (block->entry_count > 0) release_journal_block_reference(block); if (block == journal->active_block) journal->active_block = NULL; } /** * continue_committed_waiter() - invoked whenever a VIO is to be released from the journal because * its entry was committed to disk. * * Implements waiter_callback_fn. */ static void continue_committed_waiter(struct vdo_waiter *waiter, void *context) { struct data_vio *data_vio = vdo_waiter_as_data_vio(waiter); struct recovery_journal *journal = context; int result = (is_read_only(journal) ? VDO_READ_ONLY : VDO_SUCCESS); bool has_decrement; VDO_ASSERT_LOG_ONLY(vdo_before_journal_point(&journal->commit_point, &data_vio->recovery_journal_point), "DataVIOs released from recovery journal in order. Recovery journal point is (%llu, %u), but commit waiter point is (%llu, %u)", (unsigned long long) journal->commit_point.sequence_number, journal->commit_point.entry_count, (unsigned long long) data_vio->recovery_journal_point.sequence_number, data_vio->recovery_journal_point.entry_count); journal->commit_point = data_vio->recovery_journal_point; data_vio->last_async_operation = VIO_ASYNC_OP_UPDATE_REFERENCE_COUNTS; if (result != VDO_SUCCESS) { continue_data_vio_with_error(data_vio, result); return; } /* * The increment must be launched first since it must come before the * decrement if they are in the same slab. */ has_decrement = (data_vio->decrement_updater.zpbn.pbn != VDO_ZERO_BLOCK); if ((data_vio->increment_updater.zpbn.pbn != VDO_ZERO_BLOCK) || !has_decrement) continue_data_vio(data_vio); if (has_decrement) vdo_launch_completion(&data_vio->decrement_completion); } /** * notify_commit_waiters() - Notify any VIOs whose entries have now committed. * @journal: The recovery journal to update. */ static void notify_commit_waiters(struct recovery_journal *journal) { struct recovery_journal_block *block; list_for_each_entry(block, &journal->active_tail_blocks, list_node) { if (block->committing) return; vdo_waitq_notify_all_waiters(&block->commit_waiters, continue_committed_waiter, journal); if (is_read_only(journal)) { vdo_waitq_notify_all_waiters(&block->entry_waiters, continue_committed_waiter, journal); } else if (is_block_dirty(block) || !is_block_full(block)) { /* Stop at partially-committed or partially-filled blocks. */ return; } } } /** * recycle_journal_blocks() - Recycle any journal blocks which have been fully committed. * @journal: The recovery journal to update. */ static void recycle_journal_blocks(struct recovery_journal *journal) { struct recovery_journal_block *block, *tmp; list_for_each_entry_safe(block, tmp, &journal->active_tail_blocks, list_node) { if (block->committing) { /* Don't recycle committing blocks. */ return; } if (!is_read_only(journal) && (is_block_dirty(block) || !is_block_full(block))) { /* * Don't recycle partially written or partially full blocks, except in * read-only mode. */ return; } recycle_journal_block(block); } } /** * complete_write() - Handle post-commit processing. * @completion: The completion of the VIO writing this block. * * This is the callback registered by write_block(). If more entries accumulated in the block being * committed while the commit was in progress, another commit will be initiated. */ static void complete_write(struct vdo_completion *completion) { struct recovery_journal_block *block = completion->parent; struct recovery_journal *journal = block->journal; struct recovery_journal_block *last_active_block; assert_on_journal_thread(journal, __func__); journal->pending_write_count -= 1; journal->events.blocks.committed += 1; journal->events.entries.committed += block->entries_in_commit; block->uncommitted_entry_count -= block->entries_in_commit; block->entries_in_commit = 0; block->committing = false; /* If this block is the latest block to be acknowledged, record that fact. */ if (block->sequence_number > journal->last_write_acknowledged) journal->last_write_acknowledged = block->sequence_number; last_active_block = get_journal_block(&journal->active_tail_blocks); VDO_ASSERT_LOG_ONLY((block->sequence_number >= last_active_block->sequence_number), "completed journal write is still active"); notify_commit_waiters(journal); /* * Is this block now full? Reaping, and adding entries, might have already sent it off for * rewriting; else, queue it for rewrite. */ if (is_block_dirty(block) && is_block_full(block)) schedule_block_write(journal, block); recycle_journal_blocks(journal); write_blocks(journal); check_for_drain_complete(journal); } static void handle_write_error(struct vdo_completion *completion) { struct recovery_journal_block *block = completion->parent; struct recovery_journal *journal = block->journal; vio_record_metadata_io_error(as_vio(completion)); vdo_log_error_strerror(completion->result, "cannot write recovery journal block %llu", (unsigned long long) block->sequence_number); enter_journal_read_only_mode(journal, completion->result); complete_write(completion); } static void complete_write_endio(struct bio *bio) { struct vio *vio = bio->bi_private; struct recovery_journal_block *block = vio->completion.parent; struct recovery_journal *journal = block->journal; continue_vio_after_io(vio, complete_write, journal->thread_id); } /** * add_queued_recovery_entries() - Actually add entries from the queue to the given block. * @block: The journal block. */ static void add_queued_recovery_entries(struct recovery_journal_block *block) { while (vdo_waitq_has_waiters(&block->entry_waiters)) { struct data_vio *data_vio = vdo_waiter_as_data_vio(vdo_waitq_dequeue_waiter(&block->entry_waiters)); struct tree_lock *lock = &data_vio->tree_lock; struct packed_recovery_journal_entry *packed_entry; struct recovery_journal_entry new_entry; if (block->sector->entry_count == RECOVERY_JOURNAL_ENTRIES_PER_SECTOR) set_active_sector(block, (char *) block->sector + VDO_SECTOR_SIZE); /* Compose and encode the entry. */ packed_entry = &block->sector->entries[block->sector->entry_count++]; new_entry = (struct recovery_journal_entry) { .mapping = { .pbn = data_vio->increment_updater.zpbn.pbn, .state = data_vio->increment_updater.zpbn.state, }, .unmapping = { .pbn = data_vio->decrement_updater.zpbn.pbn, .state = data_vio->decrement_updater.zpbn.state, }, .operation = data_vio->increment_updater.operation, .slot = lock->tree_slots[lock->height].block_map_slot, }; *packed_entry = vdo_pack_recovery_journal_entry(&new_entry); data_vio->recovery_sequence_number = block->sequence_number; /* Enqueue the data_vio to wait for its entry to commit. */ vdo_waitq_enqueue_waiter(&block->commit_waiters, &data_vio->waiter); } } /** * write_block() - Issue a block for writing. * * Implements waiter_callback_fn. */ static void write_block(struct vdo_waiter *waiter, void *context __always_unused) { struct recovery_journal_block *block = container_of(waiter, struct recovery_journal_block, write_waiter); struct recovery_journal *journal = block->journal; struct packed_journal_header *header = get_block_header(block); if (block->committing || !vdo_waitq_has_waiters(&block->entry_waiters) || is_read_only(journal)) return; block->entries_in_commit = vdo_waitq_num_waiters(&block->entry_waiters); add_queued_recovery_entries(block); journal->pending_write_count += 1; journal->events.blocks.written += 1; journal->events.entries.written += block->entries_in_commit; header->block_map_head = __cpu_to_le64(journal->block_map_head); header->slab_journal_head = __cpu_to_le64(journal->slab_journal_head); header->entry_count = __cpu_to_le16(block->entry_count); block->committing = true; /* * We must issue a flush and a FUA for every commit. The flush is necessary to ensure that * the data being referenced is stable. The FUA is necessary to ensure that the journal * block itself is stable before allowing overwrites of the lbn's previous data. */ vdo_submit_metadata_vio(&block->vio, journal->origin + block->block_number, complete_write_endio, handle_write_error, REQ_OP_WRITE | REQ_PRIO | REQ_PREFLUSH | REQ_SYNC | REQ_FUA); } /** * write_blocks() - Attempt to commit blocks, according to write policy. * @journal: The recovery journal. */ static void write_blocks(struct recovery_journal *journal) { assert_on_journal_thread(journal, __func__); /* * We call this function after adding entries to the journal and after finishing a block * write. Thus, when this function terminates we must either have no VIOs waiting in the * journal or have some outstanding IO to provide a future wakeup. * * We want to only issue full blocks if there are no pending writes. However, if there are * no outstanding writes and some unwritten entries, we must issue a block, even if it's * the active block and it isn't full. */ if (journal->pending_write_count > 0) return; /* Write all the full blocks. */ vdo_waitq_notify_all_waiters(&journal->pending_writes, write_block, NULL); /* * Do we need to write the active block? Only if we have no outstanding writes, even after * issuing all of the full writes. */ if ((journal->pending_write_count == 0) && (journal->active_block != NULL)) write_block(&journal->active_block->write_waiter, NULL); } /** * vdo_add_recovery_journal_entry() - Add an entry to a recovery journal. * @journal: The journal in which to make an entry. * @data_vio: The data_vio for which to add the entry. The entry will be taken * from the logical and new_mapped fields of the data_vio. The * data_vio's recovery_sequence_number field will be set to the * sequence number of the journal block in which the entry was * made. * * This method is asynchronous. The data_vio will not be called back until the entry is committed * to the on-disk journal. */ void vdo_add_recovery_journal_entry(struct recovery_journal *journal, struct data_vio *data_vio) { assert_on_journal_thread(journal, __func__); if (!vdo_is_state_normal(&journal->state)) { continue_data_vio_with_error(data_vio, VDO_INVALID_ADMIN_STATE); return; } if (is_read_only(journal)) { continue_data_vio_with_error(data_vio, VDO_READ_ONLY); return; } VDO_ASSERT_LOG_ONLY(data_vio->recovery_sequence_number == 0, "journal lock not held for new entry"); vdo_advance_journal_point(&journal->append_point, journal->entries_per_block); vdo_waitq_enqueue_waiter(&journal->entry_waiters, &data_vio->waiter); assign_entries(journal); } /** * is_lock_locked() - Check whether a lock is locked for a zone type. * @journal: The recovery journal. * @lock_number: The lock to check. * @zone_type: The type of the zone. * * If the recovery journal has a lock on the lock number, both logical and physical zones are * considered locked. * * Return: true if the specified lock has references (is locked). */ static bool is_lock_locked(struct recovery_journal *journal, block_count_t lock_number, enum vdo_zone_type zone_type) { atomic_t *zone_count; bool locked; if (is_journal_zone_locked(journal, lock_number)) return true; zone_count = get_zone_count_ptr(journal, lock_number, zone_type); locked = (atomic_read(zone_count) != 0); /* Pairs with implicit barrier in vdo_release_recovery_journal_block_reference() */ smp_rmb(); return locked; } /** * reap_recovery_journal() - Conduct a sweep on a recovery journal to reclaim unreferenced blocks. * @journal: The recovery journal. */ static void reap_recovery_journal(struct recovery_journal *journal) { if (journal->reaping) { /* * We already have an outstanding reap in progress. We need to wait for it to * finish. */ return; } if (vdo_is_state_quiescent(&journal->state)) { /* We are supposed to not do IO. Don't botch it by reaping. */ return; } /* * Start reclaiming blocks only when the journal head has no references. Then stop when a * block is referenced. */ while ((journal->block_map_reap_head < journal->last_write_acknowledged) && !is_lock_locked(journal, journal->block_map_head_block_number, VDO_ZONE_TYPE_LOGICAL)) { journal->block_map_reap_head++; if (++journal->block_map_head_block_number == journal->size) journal->block_map_head_block_number = 0; } while ((journal->slab_journal_reap_head < journal->last_write_acknowledged) && !is_lock_locked(journal, journal->slab_journal_head_block_number, VDO_ZONE_TYPE_PHYSICAL)) { journal->slab_journal_reap_head++; if (++journal->slab_journal_head_block_number == journal->size) journal->slab_journal_head_block_number = 0; } if ((journal->block_map_reap_head == journal->block_map_head) && (journal->slab_journal_reap_head == journal->slab_journal_head)) { /* Nothing happened. */ return; } /* * If the block map head will advance, we must flush any block map page modified by the * entries we are reaping. If the slab journal head will advance, we must flush the slab * summary update covering the slab journal that just released some lock. */ journal->reaping = true; vdo_submit_flush_vio(journal->flush_vio, flush_endio, handle_flush_error); } /** * vdo_acquire_recovery_journal_block_reference() - Acquire a reference to a recovery journal block * from somewhere other than the journal itself. * @journal: The recovery journal. * @sequence_number: The journal sequence number of the referenced block. * @zone_type: The type of the zone making the adjustment. * @zone_id: The ID of the zone making the adjustment. */ void vdo_acquire_recovery_journal_block_reference(struct recovery_journal *journal, sequence_number_t sequence_number, enum vdo_zone_type zone_type, zone_count_t zone_id) { block_count_t lock_number; u16 *current_value; if (sequence_number == 0) return; VDO_ASSERT_LOG_ONLY((zone_type != VDO_ZONE_TYPE_JOURNAL), "invalid lock count increment from journal zone"); lock_number = vdo_get_recovery_journal_block_number(journal, sequence_number); current_value = get_counter(journal, lock_number, zone_type, zone_id); VDO_ASSERT_LOG_ONLY(*current_value < U16_MAX, "increment of lock counter must not overflow"); if (*current_value == 0) { /* * This zone is acquiring this lock for the first time. Extra barriers because this * was original developed using an atomic add operation that implicitly had them. */ smp_mb__before_atomic(); atomic_inc(get_zone_count_ptr(journal, lock_number, zone_type)); /* same as before_atomic */ smp_mb__after_atomic(); } *current_value += 1; } /** * vdo_release_journal_entry_lock() - Release a single per-entry reference count for a recovery * journal block. * @journal: The recovery journal. * @sequence_number: The journal sequence number of the referenced block. */ void vdo_release_journal_entry_lock(struct recovery_journal *journal, sequence_number_t sequence_number) { block_count_t lock_number; if (sequence_number == 0) return; lock_number = vdo_get_recovery_journal_block_number(journal, sequence_number); /* * Extra barriers because this was originally developed using an atomic add operation that * implicitly had them. */ smp_mb__before_atomic(); atomic_inc(get_decrement_counter(journal, lock_number)); /* same as before_atomic */ smp_mb__after_atomic(); } /** * initiate_drain() - Initiate a drain. * * Implements vdo_admin_initiator_fn. */ static void initiate_drain(struct admin_state *state) { check_for_drain_complete(container_of(state, struct recovery_journal, state)); } /** * vdo_drain_recovery_journal() - Drain recovery journal I/O. * @journal: The journal to drain. * @operation: The drain operation (suspend or save). * @parent: The completion to notify once the journal is drained. * * All uncommitted entries will be written out. */ void vdo_drain_recovery_journal(struct recovery_journal *journal, const struct admin_state_code *operation, struct vdo_completion *parent) { assert_on_journal_thread(journal, __func__); vdo_start_draining(&journal->state, operation, parent, initiate_drain); } /** * resume_lock_counter() - Re-allow notifications from a suspended lock counter. * @counter: The counter. * * Return: true if the lock counter was suspended. */ static bool resume_lock_counter(struct lock_counter *counter) { int prior_state; /* * Extra barriers because this was original developed using a CAS operation that implicitly * had them. */ smp_mb__before_atomic(); prior_state = atomic_cmpxchg(&counter->state, LOCK_COUNTER_STATE_SUSPENDED, LOCK_COUNTER_STATE_NOT_NOTIFYING); /* same as before_atomic */ smp_mb__after_atomic(); return (prior_state == LOCK_COUNTER_STATE_SUSPENDED); } /** * vdo_resume_recovery_journal() - Resume a recovery journal which has been drained. * @journal: The journal to resume. * @parent: The completion to finish once the journal is resumed. */ void vdo_resume_recovery_journal(struct recovery_journal *journal, struct vdo_completion *parent) { bool saved; assert_on_journal_thread(journal, __func__); saved = vdo_is_state_saved(&journal->state); vdo_set_completion_result(parent, vdo_resume_if_quiescent(&journal->state)); if (is_read_only(journal)) { vdo_continue_completion(parent, VDO_READ_ONLY); return; } if (saved) initialize_journal_state(journal); if (resume_lock_counter(&journal->lock_counter)) { /* We might have missed a notification. */ reap_recovery_journal(journal); } vdo_launch_completion(parent); } /** * vdo_get_recovery_journal_logical_blocks_used() - Get the number of logical blocks in use by the * VDO. * @journal: The journal. * * Return: The number of logical blocks in use by the VDO. */ block_count_t vdo_get_recovery_journal_logical_blocks_used(const struct recovery_journal *journal) { return journal->logical_blocks_used; } /** * vdo_get_recovery_journal_statistics() - Get the current statistics from the recovery journal. * @journal: The recovery journal to query. * * Return: A copy of the current statistics for the journal. */ struct recovery_journal_statistics vdo_get_recovery_journal_statistics(const struct recovery_journal *journal) { return journal->events; } /** * dump_recovery_block() - Dump the contents of the recovery block to the log. * @block: The block to dump. */ static void dump_recovery_block(const struct recovery_journal_block *block) { vdo_log_info(" sequence number %llu; entries %u; %s; %zu entry waiters; %zu commit waiters", (unsigned long long) block->sequence_number, block->entry_count, (block->committing ? "committing" : "waiting"), vdo_waitq_num_waiters(&block->entry_waiters), vdo_waitq_num_waiters(&block->commit_waiters)); } /** * vdo_dump_recovery_journal_statistics() - Dump some current statistics and other debug info from * the recovery journal. * @journal: The recovery journal to dump. */ void vdo_dump_recovery_journal_statistics(const struct recovery_journal *journal) { const struct recovery_journal_block *block; struct recovery_journal_statistics stats = vdo_get_recovery_journal_statistics(journal); vdo_log_info("Recovery Journal"); vdo_log_info(" block_map_head=%llu slab_journal_head=%llu last_write_acknowledged=%llu tail=%llu block_map_reap_head=%llu slab_journal_reap_head=%llu disk_full=%llu slab_journal_commits_requested=%llu entry_waiters=%zu", (unsigned long long) journal->block_map_head, (unsigned long long) journal->slab_journal_head, (unsigned long long) journal->last_write_acknowledged, (unsigned long long) journal->tail, (unsigned long long) journal->block_map_reap_head, (unsigned long long) journal->slab_journal_reap_head, (unsigned long long) stats.disk_full, (unsigned long long) stats.slab_journal_commits_requested, vdo_waitq_num_waiters(&journal->entry_waiters)); vdo_log_info(" entries: started=%llu written=%llu committed=%llu", (unsigned long long) stats.entries.started, (unsigned long long) stats.entries.written, (unsigned long long) stats.entries.committed); vdo_log_info(" blocks: started=%llu written=%llu committed=%llu", (unsigned long long) stats.blocks.started, (unsigned long long) stats.blocks.written, (unsigned long long) stats.blocks.committed); vdo_log_info(" active blocks:"); list_for_each_entry(block, &journal->active_tail_blocks, list_node) dump_recovery_block(block); }
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