From: Matthew Sakai <msakai@xxxxxxxxxx> Adds funnel_queue, a mostly lock-free multi-producer, single-consumer queue. It also adds the request queue used by the dm-vdo deduplication index, and the work_queue used by the dm-vdo data store. Both of these are built on top of funnel queue and are intended to support the dispatching of many short-running tasks. The work_queue also supports priorities. Finally, this commit adds vdo_completion, the structure which is enqueued on vdo's work_queues. Co-developed-by: J. corwin Coburn <corwin@xxxxxxxxxxxxxx> Signed-off-by: J. corwin Coburn <corwin@xxxxxxxxxxxxxx> Co-developed-by: Michael Sclafani <vdo-devel@xxxxxxxxxx> Signed-off-by: Michael Sclafani <vdo-devel@xxxxxxxxxx> Co-developed-by: Sweet Tea Dorminy <sweettea-kernel@xxxxxxxxxx> Signed-off-by: Sweet Tea Dorminy <sweettea-kernel@xxxxxxxxxx> Co-developed-by: Ken Raeburn <raeburn@xxxxxxxxxx> Signed-off-by: Ken Raeburn <raeburn@xxxxxxxxxx> Signed-off-by: Matthew Sakai <msakai@xxxxxxxxxx> Signed-off-by: Mike Snitzer <snitzer@xxxxxxxxxx> --- drivers/md/dm-vdo/completion.c | 141 +++++++ drivers/md/dm-vdo/completion.h | 155 +++++++ drivers/md/dm-vdo/cpu.h | 58 +++ drivers/md/dm-vdo/funnel-queue.c | 169 ++++++++ drivers/md/dm-vdo/funnel-queue.h | 110 +++++ drivers/md/dm-vdo/request-queue.c | 284 +++++++++++++ drivers/md/dm-vdo/request-queue.h | 30 ++ drivers/md/dm-vdo/work-queue.c | 659 ++++++++++++++++++++++++++++++ drivers/md/dm-vdo/work-queue.h | 53 +++ 9 files changed, 1659 insertions(+) create mode 100644 drivers/md/dm-vdo/completion.c create mode 100644 drivers/md/dm-vdo/completion.h create mode 100644 drivers/md/dm-vdo/cpu.h create mode 100644 drivers/md/dm-vdo/funnel-queue.c create mode 100644 drivers/md/dm-vdo/funnel-queue.h create mode 100644 drivers/md/dm-vdo/request-queue.c create mode 100644 drivers/md/dm-vdo/request-queue.h create mode 100644 drivers/md/dm-vdo/work-queue.c create mode 100644 drivers/md/dm-vdo/work-queue.h diff --git a/drivers/md/dm-vdo/completion.c b/drivers/md/dm-vdo/completion.c new file mode 100644 index 000000000000..e4b6ff74d098 --- /dev/null +++ b/drivers/md/dm-vdo/completion.c @@ -0,0 +1,141 @@ +// SPDX-License-Identifier: GPL-2.0-only +/* + * Copyright 2023 Red Hat + */ + +#include "completion.h" + +#include <linux/kernel.h> + +#include "logger.h" +#include "permassert.h" + +#include "status-codes.h" +#include "types.h" +#include "vio.h" +#include "vdo.h" + +/** + * DOC: vdo completions. + * + * Most of vdo's data structures are lock free, each either belonging to a single "zone," or + * divided into a number of zones whose accesses to the structure do not overlap. During normal + * operation, at most one thread will be operating in any given zone. Each zone has a + * vdo_work_queue which holds vdo_completions that are to be run in that zone. A completion may + * only be enqueued on one queue or operating in a single zone at a time. + * + * At each step of a multi-threaded operation, the completion performing the operation is given a + * callback, error handler, and thread id for the next step. A completion is "run" when it is + * operating on the correct thread (as specified by its callback_thread_id). If the value of its + * "result" field is an error (i.e. not VDO_SUCCESS), the function in its "error_handler" will be + * invoked. If the error_handler is NULL, or there is no error, the function set as its "callback" + * will be invoked. Generally, a completion will not be run directly, but rather will be + * "launched." In this case, it will check whether it is operating on the correct thread. If it is, + * it will run immediately. Otherwise, it will be enqueue on the vdo_work_queue associated with the + * completion's "callback_thread_id". When it is dequeued, it will be on the correct thread, and + * will get run. In some cases, the completion should get queued instead of running immediately, + * even if it is being launched from the correct thread. This is usually in cases where there is a + * long chain of callbacks, all on the same thread, which could overflow the stack. In such cases, + * the completion's "requeue" field should be set to true. Doing so will skip the current thread + * check and simply enqueue the completion. + * + * A completion may be "finished," in which case its "complete" field will be set to true before it + * is next run. It is a bug to attempt to set the result or re-finish a finished completion. + * Because a completion's fields are not safe to examine from any thread other than the one on + * which the completion is currently operating, this field is used only to aid in detecting + * programming errors. It can not be used for cross-thread checking on the status of an operation. + * A completion must be "reset" before it can be reused after it has been finished. Resetting will + * also clear any error from the result field. + **/ + +void vdo_initialize_completion(struct vdo_completion *completion, + struct vdo *vdo, + enum vdo_completion_type type) +{ + memset(completion, 0, sizeof(*completion)); + completion->vdo = vdo; + completion->type = type; + vdo_reset_completion(completion); +} + +static inline void assert_incomplete(struct vdo_completion *completion) +{ + ASSERT_LOG_ONLY(!completion->complete, "completion is not complete"); +} + +/** + * vdo_set_completion_result() - Set the result of a completion. + * + * Older errors will not be masked. + */ +void vdo_set_completion_result(struct vdo_completion *completion, int result) +{ + assert_incomplete(completion); + if (completion->result == VDO_SUCCESS) + completion->result = result; +} + +/** + * vdo_launch_completion_with_priority() - Run or enqueue a completion. + * @priority: The priority at which to enqueue the completion. + * + * If called on the correct thread (i.e. the one specified in the completion's callback_thread_id + * field) and not marked for requeue, the completion will be run immediately. Otherwise, the + * completion will be enqueued on the specified thread. + */ +void vdo_launch_completion_with_priority(struct vdo_completion *completion, + enum vdo_completion_priority priority) +{ + thread_id_t callback_thread = completion->callback_thread_id; + + if (completion->requeue || (callback_thread != vdo_get_callback_thread_id())) { + vdo_enqueue_completion(completion, priority); + return; + } + + vdo_run_completion(completion); +} + +/** vdo_finish_completion() - Mark a completion as complete and then launch it. */ +void vdo_finish_completion(struct vdo_completion *completion) +{ + assert_incomplete(completion); + completion->complete = true; + if (completion->callback != NULL) + vdo_launch_completion(completion); +} + +void vdo_enqueue_completion(struct vdo_completion *completion, + enum vdo_completion_priority priority) +{ + struct vdo *vdo = completion->vdo; + thread_id_t thread_id = completion->callback_thread_id; + + if (ASSERT(thread_id < vdo->thread_config.thread_count, + "thread_id %u (completion type %d) is less than thread count %u", + thread_id, + completion->type, + vdo->thread_config.thread_count) != UDS_SUCCESS) + BUG(); + + completion->requeue = false; + completion->priority = priority; + completion->my_queue = NULL; + vdo_enqueue_work_queue(vdo->threads[thread_id].queue, completion); +} + +/** + * vdo_requeue_completion_if_needed() - Requeue a completion if not called on the specified thread. + * + * Return: True if the completion was requeued; callers may not access the completion in this case. + */ +bool vdo_requeue_completion_if_needed(struct vdo_completion *completion, + thread_id_t callback_thread_id) +{ + if (vdo_get_callback_thread_id() == callback_thread_id) + return false; + + completion->callback_thread_id = callback_thread_id; + vdo_enqueue_completion(completion, VDO_WORK_Q_DEFAULT_PRIORITY); + return true; +} diff --git a/drivers/md/dm-vdo/completion.h b/drivers/md/dm-vdo/completion.h new file mode 100644 index 000000000000..b81322aea253 --- /dev/null +++ b/drivers/md/dm-vdo/completion.h @@ -0,0 +1,155 @@ +/* SPDX-License-Identifier: GPL-2.0-only */ +/* + * Copyright 2023 Red Hat + */ + +#ifndef VDO_COMPLETION_H +#define VDO_COMPLETION_H + +#include "permassert.h" + +#include "status-codes.h" +#include "types.h" + +/** + * vdo_run_completion() - Run a completion's callback or error handler on the current thread. + * + * Context: This function must be called from the correct callback thread. + */ +static inline void vdo_run_completion(struct vdo_completion *completion) +{ + if ((completion->result != VDO_SUCCESS) && (completion->error_handler != NULL)) { + completion->error_handler(completion); + return; + } + + completion->callback(completion); +} + +void vdo_set_completion_result(struct vdo_completion *completion, int result); + +void vdo_initialize_completion(struct vdo_completion *completion, + struct vdo *vdo, + enum vdo_completion_type type); + +/** + * vdo_reset_completion() - Reset a completion to a clean state, while keeping the type, vdo and + * parent information. + */ +static inline void vdo_reset_completion(struct vdo_completion *completion) +{ + completion->result = VDO_SUCCESS; + completion->complete = false; +} + +void vdo_launch_completion_with_priority(struct vdo_completion *completion, + enum vdo_completion_priority priority); + +/** + * vdo_launch_completion() - Launch a completion with default priority. + */ +static inline void vdo_launch_completion(struct vdo_completion *completion) +{ + vdo_launch_completion_with_priority(completion, VDO_WORK_Q_DEFAULT_PRIORITY); +} + +/** + * vdo_continue_completion() - Continue processing a completion. + * @result: The current result (will not mask older errors). + * + * Continue processing a completion by setting the current result and calling + * vdo_launch_completion(). + */ +static inline void vdo_continue_completion(struct vdo_completion *completion, int result) +{ + vdo_set_completion_result(completion, result); + vdo_launch_completion(completion); +} + +void vdo_finish_completion(struct vdo_completion *completion); + +/** + * vdo_fail_completion() - Set the result of a completion if it does not already have an error, + * then finish it. + */ +static inline void vdo_fail_completion(struct vdo_completion *completion, int result) +{ + vdo_set_completion_result(completion, result); + vdo_finish_completion(completion); +} + +/** + * vdo_assert_completion_type() - Assert that a completion is of the correct type. + * + * Return: VDO_SUCCESS or an error + */ +static inline int +vdo_assert_completion_type(struct vdo_completion *completion, enum vdo_completion_type expected) +{ + return ASSERT(expected == completion->type, + "completion type should be %u, not %u", + expected, + completion->type); +} + +static inline void vdo_set_completion_callback(struct vdo_completion *completion, + vdo_action *callback, + thread_id_t callback_thread_id) +{ + completion->callback = callback; + completion->callback_thread_id = callback_thread_id; +} + +/** + * vdo_launch_completion_callback() - Set the callback for a completion and launch it immediately. + */ +static inline void vdo_launch_completion_callback(struct vdo_completion *completion, + vdo_action *callback, + thread_id_t callback_thread_id) +{ + vdo_set_completion_callback(completion, callback, callback_thread_id); + vdo_launch_completion(completion); +} + +/** + * vdo_prepare_completion() - Prepare a completion for launch. + * + * Resets the completion, and then sets its callback, error handler, callback thread, and parent. + */ +static inline void vdo_prepare_completion(struct vdo_completion *completion, + vdo_action *callback, + vdo_action *error_handler, + thread_id_t callback_thread_id, + void *parent) +{ + vdo_reset_completion(completion); + vdo_set_completion_callback(completion, callback, callback_thread_id); + completion->error_handler = error_handler; + completion->parent = parent; +} + +/** + * vdo_prepare_completion_for_requeue() - Prepare a completion for launch ensuring that it will + * always be requeued. + * + * Resets the completion, and then sets its callback, error handler, callback thread, and parent. + */ +static inline void +vdo_prepare_completion_for_requeue(struct vdo_completion *completion, + vdo_action *callback, + vdo_action *error_handler, + thread_id_t callback_thread_id, + void *parent) +{ + vdo_prepare_completion(completion, callback, error_handler, callback_thread_id, parent); + completion->requeue = true; +} + +void vdo_enqueue_completion(struct vdo_completion *completion, + enum vdo_completion_priority priority); + + +bool vdo_requeue_completion_if_needed(struct vdo_completion *completion, + thread_id_t callback_thread_id); + +#endif /* VDO_COMPLETION_H */ diff --git a/drivers/md/dm-vdo/cpu.h b/drivers/md/dm-vdo/cpu.h new file mode 100644 index 000000000000..a538a4934e4b --- /dev/null +++ b/drivers/md/dm-vdo/cpu.h @@ -0,0 +1,58 @@ +/* SPDX-License-Identifier: GPL-2.0-only */ +/* + * Copyright 2023 Red Hat + */ + +#ifndef UDS_CPU_H +#define UDS_CPU_H + +#include <linux/cache.h> + +/** + * uds_prefetch_address() - Minimize cache-miss latency by attempting to move data into a CPU cache + * before it is accessed. + * + * @address: the address to fetch (may be invalid) + * @for_write: must be constant at compile time--false if for reading, true if for writing + */ +static inline void uds_prefetch_address(const void *address, bool for_write) +{ + /* + * for_write won't be a constant if we are compiled with optimization turned off, in which + * case prefetching really doesn't matter. clang can't figure out that if for_write is a + * constant, it can be passed as the second, mandatorily constant argument to prefetch(), + * at least currently on llvm 12. + */ + if (__builtin_constant_p(for_write)) { + if (for_write) + __builtin_prefetch(address, true); + else + __builtin_prefetch(address, false); + } +} + +/** + * uds_prefetch_range() - Minimize cache-miss latency by attempting to move a range of addresses + * into a CPU cache before they are accessed. + * + * @start: the starting address to fetch (may be invalid) + * @size: the number of bytes in the address range + * @for_write: must be constant at compile time--false if for reading, true if for writing + */ +static inline void uds_prefetch_range(const void *start, unsigned int size, bool for_write) +{ + /* + * Count the number of cache lines to fetch, allowing for the address range to span an + * extra cache line boundary due to address alignment. + */ + const char *address = (const char *) start; + unsigned int offset = ((uintptr_t) address % L1_CACHE_BYTES); + unsigned int cache_lines = (1 + ((size + offset) / L1_CACHE_BYTES)); + + while (cache_lines-- > 0) { + uds_prefetch_address(address, for_write); + address += L1_CACHE_BYTES; + } +} + +#endif /* UDS_CPU_H */ diff --git a/drivers/md/dm-vdo/funnel-queue.c b/drivers/md/dm-vdo/funnel-queue.c new file mode 100644 index 000000000000..bf7f0d8bc04d --- /dev/null +++ b/drivers/md/dm-vdo/funnel-queue.c @@ -0,0 +1,169 @@ +// SPDX-License-Identifier: GPL-2.0-only +/* + * Copyright 2023 Red Hat + */ + +#include "funnel-queue.h" + +#include "cpu.h" +#include "memory-alloc.h" +#include "permassert.h" +#include "uds.h" + +int uds_make_funnel_queue(struct funnel_queue **queue_ptr) +{ + int result; + struct funnel_queue *queue; + + result = UDS_ALLOCATE(1, struct funnel_queue, "funnel queue", &queue); + if (result != UDS_SUCCESS) + return result; + + /* + * Initialize the stub entry and put it in the queue, establishing the invariant that + * queue->newest and queue->oldest are never null. + */ + queue->stub.next = NULL; + queue->newest = &queue->stub; + queue->oldest = &queue->stub; + + *queue_ptr = queue; + return UDS_SUCCESS; +} + +void uds_free_funnel_queue(struct funnel_queue *queue) +{ + UDS_FREE(queue); +} + +static struct funnel_queue_entry *get_oldest(struct funnel_queue *queue) +{ + /* + * Barrier requirements: We need a read barrier between reading a "next" field pointer + * value and reading anything it points to. There's an accompanying barrier in + * uds_funnel_queue_put() between its caller setting up the entry and making it visible. + */ + struct funnel_queue_entry *oldest = queue->oldest; + struct funnel_queue_entry *next = READ_ONCE(oldest->next); + + if (oldest == &queue->stub) { + /* + * When the oldest entry is the stub and it has no successor, the queue is + * logically empty. + */ + if (next == NULL) + return NULL; + /* + * The stub entry has a successor, so the stub can be dequeued and ignored without + * breaking the queue invariants. + */ + oldest = next; + queue->oldest = oldest; + next = READ_ONCE(oldest->next); + } + + /* + * We have a non-stub candidate to dequeue. If it lacks a successor, we'll need to put the + * stub entry back on the queue first. + */ + if (next == NULL) { + struct funnel_queue_entry *newest = READ_ONCE(queue->newest); + + if (oldest != newest) + /* + * Another thread has already swung queue->newest atomically, but not yet + * assigned previous->next. The queue is really still empty. + */ + return NULL; + + /* + * Put the stub entry back on the queue, ensuring a successor will eventually be + * seen. + */ + uds_funnel_queue_put(queue, &queue->stub); + + /* Check again for a successor. */ + next = READ_ONCE(oldest->next); + if (next == NULL) + /* + * We lost a race with a producer who swapped queue->newest before we did, + * but who hasn't yet updated previous->next. Try again later. + */ + return NULL; + } + + return oldest; +} + +/* + * Poll a queue, removing the oldest entry if the queue is not empty. This function must only be + * called from a single consumer thread. + */ +struct funnel_queue_entry *uds_funnel_queue_poll(struct funnel_queue *queue) +{ + struct funnel_queue_entry *oldest = get_oldest(queue); + + if (oldest == NULL) + return oldest; + + /* + * Dequeue the oldest entry and return it. Only one consumer thread may call this function, + * so no locking, atomic operations, or fences are needed; queue->oldest is owned by the + * consumer and oldest->next is never used by a producer thread after it is swung from NULL + * to non-NULL. + */ + queue->oldest = READ_ONCE(oldest->next); + /* + * Make sure the caller sees the proper stored data for this entry. Since we've already + * fetched the entry pointer we stored in "queue->oldest", this also ensures that on entry + * to the next call we'll properly see the dependent data. + */ + smp_rmb(); + /* + * If "oldest" is a very light-weight work item, we'll be looking for the next one very + * soon, so prefetch it now. + */ + uds_prefetch_address(queue->oldest, true); + WRITE_ONCE(oldest->next, NULL); + return oldest; +} + +/* + * Check whether the funnel queue is empty or not. If the queue is in a transition state with one + * or more entries being added such that the list view is incomplete, this function will report the + * queue as empty. + */ +bool uds_is_funnel_queue_empty(struct funnel_queue *queue) +{ + return get_oldest(queue) == NULL; +} + +/* + * Check whether the funnel queue is idle or not. If the queue has entries available to be + * retrieved, it is not idle. If the queue is in a transition state with one or more entries being + * added such that the list view is incomplete, it may not be possible to retrieve an entry with + * the uds_funnel_queue_poll() function, but the queue will not be considered idle. + */ +bool uds_is_funnel_queue_idle(struct funnel_queue *queue) +{ + /* + * Oldest is not the stub, so there's another entry, though if next is NULL we can't + * retrieve it yet. + */ + if (queue->oldest != &queue->stub) + return false; + + /* + * Oldest is the stub, but newest has been updated by _put(); either there's another, + * retrievable entry in the list, or the list is officially empty but in the intermediate + * state of having an entry added. + * + * Whether anything is retrievable depends on whether stub.next has been updated and become + * visible to us, but for idleness we don't care. And due to memory ordering in _put(), the + * update to newest would be visible to us at the same time or sooner. + */ + if (READ_ONCE(queue->newest) != &queue->stub) + return false; + + return true; +} diff --git a/drivers/md/dm-vdo/funnel-queue.h b/drivers/md/dm-vdo/funnel-queue.h new file mode 100644 index 000000000000..275dd4ac29a4 --- /dev/null +++ b/drivers/md/dm-vdo/funnel-queue.h @@ -0,0 +1,110 @@ +/* SPDX-License-Identifier: GPL-2.0-only */ +/* + * Copyright 2023 Red Hat + */ + +#ifndef UDS_FUNNEL_QUEUE_H +#define UDS_FUNNEL_QUEUE_H + +#include <linux/atomic.h> +#include <linux/cache.h> + +/* + * A funnel queue is a simple (almost) lock-free queue that accepts entries from multiple threads + * (multi-producer) and delivers them to a single thread (single-consumer). "Funnel" is an attempt + * to evoke the image of requests from more than one producer being "funneled down" to a single + * consumer. + * + * This is an unsynchronized but thread-safe data structure when used as intended. There is no + * mechanism to ensure that only one thread is consuming from the queue. If more than one thread + * attempts to consume from the queue, the resulting behavior is undefined. Clients must not + * directly access or manipulate the internals of the queue, which are only exposed for the purpose + * of allowing the very simple enqueue operation to be inlined. + * + * The implementation requires that a funnel_queue_entry structure (a link pointer) is embedded in + * the queue entries, and pointers to those structures are used exclusively by the queue. No macros + * are defined to template the queue, so the offset of the funnel_queue_entry in the records placed + * in the queue must all be the same so the client can derive their structure pointer from the + * entry pointer returned by uds_funnel_queue_poll(). + * + * Callers are wholly responsible for allocating and freeing the entries. Entries may be freed as + * soon as they are returned since this queue is not susceptible to the "ABA problem" present in + * many lock-free data structures. The queue is dynamically allocated to ensure cache-line + * alignment, but no other dynamic allocation is used. + * + * The algorithm is not actually 100% lock-free. There is a single point in uds_funnel_queue_put() + * at which a preempted producer will prevent the consumers from seeing items added to the queue by + * later producers, and only if the queue is short enough or the consumer fast enough for it to + * reach what was the end of the queue at the time of the preemption. + * + * The consumer function, uds_funnel_queue_poll(), will return NULL when the queue is empty. To + * wait for data to consume, spin (if safe) or combine the queue with a struct event_count to + * signal the presence of new entries. + */ + +/* This queue link structure must be embedded in client entries. */ +struct funnel_queue_entry { + /* The next (newer) entry in the queue. */ + struct funnel_queue_entry *next; +}; + +/* + * The dynamically allocated queue structure, which is allocated on a cache line boundary so the + * producer and consumer fields in the structure will land on separate cache lines. This should be + * consider opaque but it is exposed here so uds_funnel_queue_put() can be inlined. + */ +struct __aligned(L1_CACHE_BYTES) funnel_queue { + /* + * The producers' end of the queue, an atomically exchanged pointer that will never be + * NULL. + */ + struct funnel_queue_entry *newest; + + /* The consumer's end of the queue, which is owned by the consumer and never NULL. */ + struct funnel_queue_entry *oldest __aligned(L1_CACHE_BYTES); + + /* A dummy entry used to provide the non-NULL invariants above. */ + struct funnel_queue_entry stub; +}; + +int __must_check uds_make_funnel_queue(struct funnel_queue **queue_ptr); + +void uds_free_funnel_queue(struct funnel_queue *queue); + +/* + * Put an entry on the end of the queue. + * + * The entry pointer must be to the struct funnel_queue_entry embedded in the caller's data + * structure. The caller must be able to derive the address of the start of their data structure + * from the pointer that passed in here, so every entry in the queue must have the struct + * funnel_queue_entry at the same offset within the client's structure. + */ +static inline void +uds_funnel_queue_put(struct funnel_queue *queue, struct funnel_queue_entry *entry) +{ + struct funnel_queue_entry *previous; + + /* + * Barrier requirements: All stores relating to the entry ("next" pointer, containing data + * structure fields) must happen before the previous->next store making it visible to the + * consumer. Also, the entry's "next" field initialization to NULL must happen before any + * other producer threads can see the entry (the xchg) and try to update the "next" field. + * + * xchg implements a full barrier. + */ + WRITE_ONCE(entry->next, NULL); + previous = xchg(&queue->newest, entry); + /* + * Preemptions between these two statements hide the rest of the queue from the consumer, + * preventing consumption until the following assignment runs. + */ + WRITE_ONCE(previous->next, entry); +} + +struct funnel_queue_entry *__must_check uds_funnel_queue_poll(struct funnel_queue *queue); + +bool __must_check uds_is_funnel_queue_empty(struct funnel_queue *queue); + +bool __must_check uds_is_funnel_queue_idle(struct funnel_queue *queue); + +#endif /* UDS_FUNNEL_QUEUE_H */ diff --git a/drivers/md/dm-vdo/request-queue.c b/drivers/md/dm-vdo/request-queue.c new file mode 100644 index 000000000000..1c60b09027a8 --- /dev/null +++ b/drivers/md/dm-vdo/request-queue.c @@ -0,0 +1,284 @@ +// SPDX-License-Identifier: GPL-2.0-only +/* + * Copyright 2023 Red Hat + */ + +#include "request-queue.h" + +#include <linux/atomic.h> +#include <linux/compiler.h> +#include <linux/wait.h> + +#include "funnel-queue.h" +#include "logger.h" +#include "memory-alloc.h" +#include "uds-threads.h" + +/* + * This queue will attempt to handle requests in reasonably sized batches instead of reacting + * immediately to each new request. The wait time between batches is dynamically adjusted up or + * down to try to balance responsiveness against wasted thread run time. + * + * If the wait time becomes long enough, the queue will become dormant and must be explicitly + * awoken when a new request is enqueued. The enqueue operation updates "newest" in the funnel + * queue via xchg (which is a memory barrier), and later checks "dormant" to decide whether to do a + * wakeup of the worker thread. + * + * When deciding to go to sleep, the worker thread sets "dormant" and then examines "newest" to + * decide if the funnel queue is idle. In dormant mode, the last examination of "newest" before + * going to sleep is done inside the wait_event_interruptible() macro, after a point where one or + * more memory barriers have been issued. (Preparing to sleep uses spin locks.) Even if the funnel + * queue's "next" field update isn't visible yet to make the entry accessible, its existence will + * kick the worker thread out of dormant mode and back into timer-based mode. + * + * Unbatched requests are used to communicate between different zone threads and will also cause + * the queue to awaken immediately. + */ + +enum { + NANOSECOND = 1, + MICROSECOND = 1000 * NANOSECOND, + MILLISECOND = 1000 * MICROSECOND, + DEFAULT_WAIT_TIME = 20 * MICROSECOND, + MINIMUM_WAIT_TIME = DEFAULT_WAIT_TIME / 2, + MAXIMUM_WAIT_TIME = MILLISECOND, + MINIMUM_BATCH = 32, + MAXIMUM_BATCH = 64, +}; + +struct uds_request_queue { + /* Wait queue for synchronizing producers and consumer */ + struct wait_queue_head wait_head; + /* Function to process a request */ + uds_request_queue_processor_t *processor; + /* Queue of new incoming requests */ + struct funnel_queue *main_queue; + /* Queue of old requests to retry */ + struct funnel_queue *retry_queue; + /* The thread id of the worker thread */ + struct thread *thread; + /* True if the worker was started */ + bool started; + /* When true, requests can be enqueued */ + bool running; + /* A flag set when the worker is waiting without a timeout */ + atomic_t dormant; +}; + +static inline struct uds_request *poll_queues(struct uds_request_queue *queue) +{ + struct funnel_queue_entry *entry; + + entry = uds_funnel_queue_poll(queue->retry_queue); + if (entry != NULL) + return container_of(entry, struct uds_request, queue_link); + + entry = uds_funnel_queue_poll(queue->main_queue); + if (entry != NULL) + return container_of(entry, struct uds_request, queue_link); + + return NULL; +} + +static inline bool are_queues_idle(struct uds_request_queue *queue) +{ + return uds_is_funnel_queue_idle(queue->retry_queue) && + uds_is_funnel_queue_idle(queue->main_queue); +} + +/* + * Determine if there is a next request to process, and return it if there is. Also return flags + * indicating whether the worker thread can sleep (for the use of wait_event() macros) and whether + * the thread did sleep before returning a new request. + */ +static inline bool dequeue_request(struct uds_request_queue *queue, + struct uds_request **request_ptr, + bool *waited_ptr) +{ + struct uds_request *request = poll_queues(queue); + + if (request != NULL) { + *request_ptr = request; + return true; + } + + if (!READ_ONCE(queue->running)) { + /* Wake the worker thread so it can exit. */ + *request_ptr = NULL; + return true; + } + + *request_ptr = NULL; + *waited_ptr = true; + return false; +} + +static void wait_for_request(struct uds_request_queue *queue, + bool dormant, + unsigned long timeout, + struct uds_request **request, + bool *waited) +{ + if (dormant) { + wait_event_interruptible(queue->wait_head, + (dequeue_request(queue, request, waited) || + !are_queues_idle(queue))); + return; + } + + wait_event_interruptible_hrtimeout(queue->wait_head, + dequeue_request(queue, request, waited), + ns_to_ktime(timeout)); +} + +static void request_queue_worker(void *arg) +{ + struct uds_request_queue *queue = (struct uds_request_queue *) arg; + struct uds_request *request = NULL; + unsigned long time_batch = DEFAULT_WAIT_TIME; + bool dormant = atomic_read(&queue->dormant); + bool waited = false; + long current_batch = 0; + + for (;;) { + wait_for_request(queue, dormant, time_batch, &request, &waited); + if (likely(request != NULL)) { + current_batch++; + queue->processor(request); + } else if (!READ_ONCE(queue->running)) { + break; + } + + if (dormant) { + /* + * The queue has been roused from dormancy. Clear the flag so enqueuers can + * stop broadcasting. No fence is needed for this transition. + */ + atomic_set(&queue->dormant, false); + dormant = false; + time_batch = DEFAULT_WAIT_TIME; + } else if (waited) { + /* + * We waited for this request to show up. Adjust the wait time to smooth + * out the batch size. + */ + if (current_batch < MINIMUM_BATCH) { + /* + * If the last batch of requests was too small, increase the wait + * time. + */ + time_batch += time_batch / 4; + if (time_batch >= MAXIMUM_WAIT_TIME) { + atomic_set(&queue->dormant, true); + dormant = true; + } + } else if (current_batch > MAXIMUM_BATCH) { + /* + * If the last batch of requests was too large, decrease the wait + * time. + */ + time_batch -= time_batch / 4; + if (time_batch < MINIMUM_WAIT_TIME) + time_batch = MINIMUM_WAIT_TIME; + } + current_batch = 0; + } + } + + /* + * Ensure that we process any remaining requests that were enqueued before trying to shut + * down. The corresponding write barrier is in uds_request_queue_finish(). + */ + smp_rmb(); + while ((request = poll_queues(queue)) != NULL) + queue->processor(request); +} + +int uds_make_request_queue(const char *queue_name, + uds_request_queue_processor_t *processor, + struct uds_request_queue **queue_ptr) +{ + int result; + struct uds_request_queue *queue; + + result = UDS_ALLOCATE(1, struct uds_request_queue, __func__, &queue); + if (result != UDS_SUCCESS) + return result; + + queue->processor = processor; + queue->running = true; + atomic_set(&queue->dormant, false); + init_waitqueue_head(&queue->wait_head); + + result = uds_make_funnel_queue(&queue->main_queue); + if (result != UDS_SUCCESS) { + uds_request_queue_finish(queue); + return result; + } + + result = uds_make_funnel_queue(&queue->retry_queue); + if (result != UDS_SUCCESS) { + uds_request_queue_finish(queue); + return result; + } + + result = uds_create_thread(request_queue_worker, queue, queue_name, &queue->thread); + if (result != UDS_SUCCESS) { + uds_request_queue_finish(queue); + return result; + } + + queue->started = true; + *queue_ptr = queue; + return UDS_SUCCESS; +} + +static inline void wake_up_worker(struct uds_request_queue *queue) +{ + if (wq_has_sleeper(&queue->wait_head)) + wake_up(&queue->wait_head); +} + +void uds_request_queue_enqueue(struct uds_request_queue *queue, struct uds_request *request) +{ + struct funnel_queue *sub_queue; + bool unbatched = request->unbatched; + + sub_queue = request->requeued ? queue->retry_queue : queue->main_queue; + uds_funnel_queue_put(sub_queue, &request->queue_link); + + /* + * We must wake the worker thread when it is dormant. A read fence isn't needed here since + * we know the queue operation acts as one. + */ + if (atomic_read(&queue->dormant) || unbatched) + wake_up_worker(queue); +} + +void uds_request_queue_finish(struct uds_request_queue *queue) +{ + int result; + + if (queue == NULL) + return; + + /* + * This memory barrier ensures that any requests we queued will be seen. The point is that + * when dequeue_request() sees the following update to the running flag, it will also be + * able to see any change we made to a next field in the funnel queue entry. The + * corresponding read barrier is in request_queue_worker(). + */ + smp_wmb(); + WRITE_ONCE(queue->running, false); + + if (queue->started) { + wake_up_worker(queue); + result = uds_join_threads(queue->thread); + if (result != UDS_SUCCESS) + uds_log_warning_strerror(result, "Failed to join worker thread"); + } + + uds_free_funnel_queue(queue->main_queue); + uds_free_funnel_queue(queue->retry_queue); + UDS_FREE(queue); +} diff --git a/drivers/md/dm-vdo/request-queue.h b/drivers/md/dm-vdo/request-queue.h new file mode 100644 index 000000000000..818cb14135fd --- /dev/null +++ b/drivers/md/dm-vdo/request-queue.h @@ -0,0 +1,30 @@ +/* SPDX-License-Identifier: GPL-2.0-only */ +/* + * Copyright 2023 Red Hat + */ + +#ifndef UDS_REQUEST_QUEUE_H +#define UDS_REQUEST_QUEUE_H + +#include "uds.h" + +/* + * A simple request queue which will handle new requests in the order in which they are received, + * and will attempt to handle requeued requests before new ones. However, the nature of the + * implementation means that it cannot guarantee this ordering; the prioritization is merely a + * hint. + */ + +struct uds_request_queue; + +typedef void uds_request_queue_processor_t(struct uds_request *); + +int __must_check uds_make_request_queue(const char *queue_name, + uds_request_queue_processor_t *processor, + struct uds_request_queue **queue_ptr); + +void uds_request_queue_enqueue(struct uds_request_queue *queue, struct uds_request *request); + +void uds_request_queue_finish(struct uds_request_queue *queue); + +#endif /* UDS_REQUEST_QUEUE_H */ diff --git a/drivers/md/dm-vdo/work-queue.c b/drivers/md/dm-vdo/work-queue.c new file mode 100644 index 000000000000..6adf07fc74e1 --- /dev/null +++ b/drivers/md/dm-vdo/work-queue.c @@ -0,0 +1,659 @@ +// SPDX-License-Identifier: GPL-2.0-only +/* + * Copyright 2023 Red Hat + */ + +#include "work-queue.h" + +#include <linux/atomic.h> +#include <linux/cache.h> +#include <linux/completion.h> +#include <linux/err.h> +#include <linux/kthread.h> +#include <linux/percpu.h> + +#include "funnel-queue.h" +#include "logger.h" +#include "memory-alloc.h" +#include "numeric.h" +#include "permassert.h" +#include "string-utils.h" + +#include "completion.h" +#include "status-codes.h" + +static DEFINE_PER_CPU(unsigned int, service_queue_rotor); + +/** + * DOC: Work queue definition. + * + * There are two types of work queues: simple, with one worker thread, and round-robin, which uses + * a group of the former to do the work, and assigns work to them in round-robin fashion (roughly). + * Externally, both are represented via the same common sub-structure, though there's actually not + * a great deal of overlap between the two types internally. + */ +struct vdo_work_queue { + /* Name of just the work queue (e.g., "cpuQ12") */ + char *name; + bool round_robin_mode; + struct vdo_thread *owner; + /* Life cycle functions, etc */ + const struct vdo_work_queue_type *type; +}; + +struct simple_work_queue { + struct vdo_work_queue common; + struct funnel_queue *priority_lists[VDO_WORK_Q_MAX_PRIORITY + 1]; + void *private; + + /* + * The fields above are unchanged after setup but often read, and are good candidates for + * caching -- and if the max priority is 2, just fit in one x86-64 cache line if aligned. + * The fields below are often modified as we sleep and wake, so we want a separate cache + * line for performance. + */ + + /* Any (0 or 1) worker threads waiting for new work to do */ + wait_queue_head_t waiting_worker_threads ____cacheline_aligned; + /* Hack to reduce wakeup calls if the worker thread is running */ + atomic_t idle; + + /* These are infrequently used so in terms of performance we don't care where they land. */ + struct task_struct *thread; + /* Notify creator once worker has initialized */ + struct completion *started; +}; + +struct round_robin_work_queue { + struct vdo_work_queue common; + struct simple_work_queue **service_queues; + unsigned int num_service_queues; +}; + +static inline struct simple_work_queue *as_simple_work_queue(struct vdo_work_queue *queue) +{ + return ((queue == NULL) ? NULL : container_of(queue, struct simple_work_queue, common)); +} + +static inline struct round_robin_work_queue * +as_round_robin_work_queue(struct vdo_work_queue *queue) +{ + return ((queue == NULL) ? + NULL : + container_of(queue, struct round_robin_work_queue, common)); +} + +/* Processing normal completions. */ + +/* + * Dequeue and return the next waiting completion, if any. + * + * We scan the funnel queues from highest priority to lowest, once; there is therefore a race + * condition where a high-priority completion can be enqueued followed by a lower-priority one, and + * we'll grab the latter (but we'll catch the high-priority item on the next call). If strict + * enforcement of priorities becomes necessary, this function will need fixing. + */ +static struct vdo_completion *poll_for_completion(struct simple_work_queue *queue) +{ + int i; + + for (i = queue->common.type->max_priority; i >= 0; i--) { + struct funnel_queue_entry *link = uds_funnel_queue_poll(queue->priority_lists[i]); + + if (link != NULL) + return container_of(link, struct vdo_completion, work_queue_entry_link); + } + + return NULL; +} + +static void +enqueue_work_queue_completion(struct simple_work_queue *queue, struct vdo_completion *completion) +{ + ASSERT_LOG_ONLY(completion->my_queue == NULL, + "completion %px (fn %px) to enqueue (%px) is not already queued (%px)", + completion, + completion->callback, + queue, + completion->my_queue); + if (completion->priority == VDO_WORK_Q_DEFAULT_PRIORITY) + completion->priority = queue->common.type->default_priority; + + if (ASSERT(completion->priority <= queue->common.type->max_priority, + "priority is in range for queue") != VDO_SUCCESS) + completion->priority = 0; + + completion->my_queue = &queue->common; + + /* Funnel queue handles the synchronization for the put. */ + uds_funnel_queue_put(queue->priority_lists[completion->priority], + &completion->work_queue_entry_link); + + /* + * Due to how funnel queue synchronization is handled (just atomic operations), the + * simplest safe implementation here would be to wake-up any waiting threads after + * enqueueing each item. Even if the funnel queue is not empty at the time of adding an + * item to the queue, the consumer thread may not see this since it is not guaranteed to + * have the same view of the queue as a producer thread. + * + * However, the above is wasteful so instead we attempt to minimize the number of thread + * wakeups. Using an idle flag, and careful ordering using memory barriers, we should be + * able to determine when the worker thread might be asleep or going to sleep. We use + * cmpxchg to try to take ownership (vs other producer threads) of the responsibility for + * waking the worker thread, so multiple wakeups aren't tried at once. + * + * This was tuned for some x86 boxes that were handy; it's untested whether doing the read + * first is any better or worse for other platforms, even other x86 configurations. + */ + smp_mb(); + if ((atomic_read(&queue->idle) != 1) || (atomic_cmpxchg(&queue->idle, 1, 0) != 1)) + return; + + /* There's a maximum of one thread in this list. */ + wake_up(&queue->waiting_worker_threads); +} + +static void run_start_hook(struct simple_work_queue *queue) +{ + if (queue->common.type->start != NULL) + queue->common.type->start(queue->private); +} + +static void run_finish_hook(struct simple_work_queue *queue) +{ + if (queue->common.type->finish != NULL) + queue->common.type->finish(queue->private); +} + +/* + * Wait for the next completion to process, or until kthread_should_stop indicates that it's time + * for us to shut down. + * + * If kthread_should_stop says it's time to stop but we have pending completions return a + * completion. + * + * Also update statistics relating to scheduler interactions. + */ +static struct vdo_completion *wait_for_next_completion(struct simple_work_queue *queue) +{ + struct vdo_completion *completion; + DEFINE_WAIT(wait); + + while (true) { + prepare_to_wait(&queue->waiting_worker_threads, &wait, TASK_INTERRUPTIBLE); + /* + * Don't set the idle flag until a wakeup will not be lost. + * + * Force synchronization between setting the idle flag and checking the funnel + * queue; the producer side will do them in the reverse order. (There's still a + * race condition we've chosen to allow, because we've got a timeout below that + * unwedges us if we hit it, but this may narrow the window a little.) + */ + atomic_set(&queue->idle, 1); + smp_mb(); /* store-load barrier between "idle" and funnel queue */ + + completion = poll_for_completion(queue); + if (completion != NULL) + break; + + /* + * We need to check for thread-stop after setting TASK_INTERRUPTIBLE state up + * above. Otherwise, schedule() will put the thread to sleep and might miss a + * wakeup from kthread_stop() call in vdo_finish_work_queue(). + */ + if (kthread_should_stop()) + break; + + schedule(); + + /* + * Most of the time when we wake, it should be because there's work to do. If it + * was a spurious wakeup, continue looping. + */ + completion = poll_for_completion(queue); + if (completion != NULL) + break; + } + + finish_wait(&queue->waiting_worker_threads, &wait); + atomic_set(&queue->idle, 0); + + return completion; +} + +static void process_completion(struct simple_work_queue *queue, struct vdo_completion *completion) +{ + if (ASSERT(completion->my_queue == &queue->common, + "completion %px from queue %px marked as being in this queue (%px)", + completion, + queue, + completion->my_queue) == UDS_SUCCESS) + completion->my_queue = NULL; + + vdo_run_completion(completion); +} + +static void service_work_queue(struct simple_work_queue *queue) +{ + run_start_hook(queue); + + while (true) { + struct vdo_completion *completion = poll_for_completion(queue); + + if (completion == NULL) + completion = wait_for_next_completion(queue); + + if (completion == NULL) + /* No completions but kthread_should_stop() was triggered. */ + break; + + process_completion(queue, completion); + + /* + * Be friendly to a CPU that has other work to do, if the kernel has told us to. + * This speeds up some performance tests; that "other work" might include other VDO + * threads. + */ + if (need_resched()) + cond_resched(); + } + + run_finish_hook(queue); +} + +static int work_queue_runner(void *ptr) +{ + struct simple_work_queue *queue = ptr; + + complete(queue->started); + service_work_queue(queue); + return 0; +} + +/* Creation & teardown */ + +static void free_simple_work_queue(struct simple_work_queue *queue) +{ + unsigned int i; + + for (i = 0; i <= VDO_WORK_Q_MAX_PRIORITY; i++) + uds_free_funnel_queue(queue->priority_lists[i]); + UDS_FREE(queue->common.name); + UDS_FREE(queue); +} + +static void free_round_robin_work_queue(struct round_robin_work_queue *queue) +{ + struct simple_work_queue **queue_table = queue->service_queues; + unsigned int count = queue->num_service_queues; + unsigned int i; + + queue->service_queues = NULL; + + for (i = 0; i < count; i++) + free_simple_work_queue(queue_table[i]); + UDS_FREE(queue_table); + UDS_FREE(queue->common.name); + UDS_FREE(queue); +} + +void vdo_free_work_queue(struct vdo_work_queue *queue) +{ + if (queue == NULL) + return; + + vdo_finish_work_queue(queue); + + if (queue->round_robin_mode) + free_round_robin_work_queue(as_round_robin_work_queue(queue)); + else + free_simple_work_queue(as_simple_work_queue(queue)); +} + +static int make_simple_work_queue(const char *thread_name_prefix, + const char *name, + struct vdo_thread *owner, + void *private, + const struct vdo_work_queue_type *type, + struct simple_work_queue **queue_ptr) +{ + DECLARE_COMPLETION_ONSTACK(started); + struct simple_work_queue *queue; + int i; + struct task_struct *thread = NULL; + int result; + + ASSERT_LOG_ONLY((type->max_priority <= VDO_WORK_Q_MAX_PRIORITY), + "queue priority count %u within limit %u", + type->max_priority, + VDO_WORK_Q_MAX_PRIORITY); + + result = UDS_ALLOCATE(1, struct simple_work_queue, "simple work queue", &queue); + if (result != UDS_SUCCESS) + return result; + + queue->private = private; + queue->started = &started; + queue->common.type = type; + queue->common.owner = owner; + init_waitqueue_head(&queue->waiting_worker_threads); + + result = uds_duplicate_string(name, "queue name", &queue->common.name); + if (result != VDO_SUCCESS) { + UDS_FREE(queue); + return -ENOMEM; + } + + for (i = 0; i <= type->max_priority; i++) { + result = uds_make_funnel_queue(&queue->priority_lists[i]); + if (result != UDS_SUCCESS) { + free_simple_work_queue(queue); + return result; + } + } + + thread = kthread_run(work_queue_runner, + queue, + "%s:%s", + thread_name_prefix, + queue->common.name); + if (IS_ERR(thread)) { + free_simple_work_queue(queue); + return (int) PTR_ERR(thread); + } + + queue->thread = thread; + + /* + * If we don't wait to ensure the thread is running VDO code, a quick kthread_stop (due to + * errors elsewhere) could cause it to never get as far as running VDO, skipping the + * cleanup code. + * + * Eventually we should just make that path safe too, and then we won't need this + * synchronization. + */ + wait_for_completion(&started); + + *queue_ptr = queue; + return UDS_SUCCESS; +} + +/** + * vdo_make_work_queue() - Create a work queue; if multiple threads are requested, completions will + * be distributed to them in round-robin fashion. + * + * Each queue is associated with a struct vdo_thread which has a single vdo thread id. Regardless + * of the actual number of queues and threads allocated here, code outside of the queue + * implementation will treat this as a single zone. + */ +int vdo_make_work_queue(const char *thread_name_prefix, + const char *name, + struct vdo_thread *owner, + const struct vdo_work_queue_type *type, + unsigned int thread_count, + void *thread_privates[], + struct vdo_work_queue **queue_ptr) +{ + struct round_robin_work_queue *queue; + int result; + char thread_name[TASK_COMM_LEN]; + unsigned int i; + + if (thread_count == 1) { + struct simple_work_queue *simple_queue; + void *context = ((thread_privates != NULL) ? thread_privates[0] : NULL); + + result = make_simple_work_queue(thread_name_prefix, + name, + owner, + context, + type, + &simple_queue); + if (result == VDO_SUCCESS) + *queue_ptr = &simple_queue->common; + return result; + } + + result = UDS_ALLOCATE(1, struct round_robin_work_queue, "round-robin work queue", &queue); + if (result != UDS_SUCCESS) + return result; + + result = UDS_ALLOCATE(thread_count, + struct simple_work_queue *, + "subordinate work queues", + &queue->service_queues); + if (result != UDS_SUCCESS) { + UDS_FREE(queue); + return result; + } + + queue->num_service_queues = thread_count; + queue->common.round_robin_mode = true; + queue->common.owner = owner; + + result = uds_duplicate_string(name, "queue name", &queue->common.name); + if (result != VDO_SUCCESS) { + UDS_FREE(queue->service_queues); + UDS_FREE(queue); + return -ENOMEM; + } + + *queue_ptr = &queue->common; + + for (i = 0; i < thread_count; i++) { + void *context = ((thread_privates != NULL) ? thread_privates[i] : NULL); + + snprintf(thread_name, sizeof(thread_name), "%s%u", name, i); + result = make_simple_work_queue(thread_name_prefix, + thread_name, + owner, + context, + type, + &queue->service_queues[i]); + if (result != VDO_SUCCESS) { + queue->num_service_queues = i; + /* Destroy previously created subordinates. */ + vdo_free_work_queue(UDS_FORGET(*queue_ptr)); + return result; + } + } + + return VDO_SUCCESS; +} + +static void finish_simple_work_queue(struct simple_work_queue *queue) +{ + if (queue->thread == NULL) + return; + + /* Tells the worker thread to shut down and waits for it to exit. */ + kthread_stop(queue->thread); + queue->thread = NULL; +} + +static void finish_round_robin_work_queue(struct round_robin_work_queue *queue) +{ + struct simple_work_queue **queue_table = queue->service_queues; + unsigned int count = queue->num_service_queues; + unsigned int i; + + for (i = 0; i < count; i++) + finish_simple_work_queue(queue_table[i]); +} + +/* No enqueueing of completions should be done once this function is called. */ +void vdo_finish_work_queue(struct vdo_work_queue *queue) +{ + if (queue == NULL) + return; + + if (queue->round_robin_mode) + finish_round_robin_work_queue(as_round_robin_work_queue(queue)); + else + finish_simple_work_queue(as_simple_work_queue(queue)); +} + +/* Debugging dumps */ + +static void dump_simple_work_queue(struct simple_work_queue *queue) +{ + const char *thread_status = "no threads"; + char task_state_report = '-'; + + if (queue->thread != NULL) { + task_state_report = task_state_to_char(queue->thread); + thread_status = atomic_read(&queue->idle) ? "idle" : "running"; + } + + uds_log_info("workQ %px (%s) %s (%c)", + &queue->common, + queue->common.name, + thread_status, + task_state_report); + + /* ->waiting_worker_threads wait queue status? anyone waiting? */ +} + +/* + * Write to the buffer some info about the completion, for logging. Since the common use case is + * dumping info about a lot of completions to syslog all at once, the format favors brevity over + * readability. + */ +void vdo_dump_work_queue(struct vdo_work_queue *queue) +{ + if (queue->round_robin_mode) { + struct round_robin_work_queue *round_robin = as_round_robin_work_queue(queue); + unsigned int i; + + for (i = 0; i < round_robin->num_service_queues; i++) + dump_simple_work_queue(round_robin->service_queues[i]); + } else { + dump_simple_work_queue(as_simple_work_queue(queue)); + } +} + +static void get_function_name(void *pointer, char *buffer, size_t buffer_length) +{ + if (pointer == NULL) { + /* + * Format "%ps" logs a null pointer as "(null)" with a bunch of leading spaces. We + * sometimes use this when logging lots of data; don't be so verbose. + */ + strscpy(buffer, "-", buffer_length); + } else { + /* + * Use a pragma to defeat gcc's format checking, which doesn't understand that + * "%ps" actually does support a precision spec in Linux kernel code. + */ + char *space; + +#pragma GCC diagnostic push +#pragma GCC diagnostic ignored "-Wformat" + snprintf(buffer, buffer_length, "%.*ps", buffer_length - 1, pointer); +#pragma GCC diagnostic pop + + space = strchr(buffer, ' '); + if (space != NULL) + *space = '\0'; + } +} + +void vdo_dump_completion_to_buffer(struct vdo_completion *completion, char *buffer, size_t length) +{ + size_t current_length = + scnprintf(buffer, + length, + "%.*s/", + TASK_COMM_LEN, + (completion->my_queue == NULL ? "-" : completion->my_queue->name)); + + if (current_length < length - 1) + get_function_name((void *) completion->callback, + buffer + current_length, + length - current_length); +} + +/* Completion submission */ +/* + * If the completion has a timeout that has already passed, the timeout handler function may be + * invoked by this function. + */ +void vdo_enqueue_work_queue(struct vdo_work_queue *queue, struct vdo_completion *completion) +{ + /* + * Convert the provided generic vdo_work_queue to the simple_work_queue to actually queue + * on. + */ + struct simple_work_queue *simple_queue = NULL; + + if (!queue->round_robin_mode) { + simple_queue = as_simple_work_queue(queue); + } else { + struct round_robin_work_queue *round_robin = as_round_robin_work_queue(queue); + + /* + * It shouldn't be a big deal if the same rotor gets used for multiple work queues. + * Any patterns that might develop are likely to be disrupted by random ordering of + * multiple completions and migration between cores, unless the load is so light as + * to be regular in ordering of tasks and the threads are confined to individual + * cores; with a load that light we won't care. + */ + unsigned int rotor = this_cpu_inc_return(service_queue_rotor); + unsigned int index = rotor % round_robin->num_service_queues; + + simple_queue = round_robin->service_queues[index]; + } + + enqueue_work_queue_completion(simple_queue, completion); +} + +/* Misc */ + +/* + * Return the work queue pointer recorded at initialization time in the work-queue stack handle + * initialized on the stack of the current thread, if any. + */ +static struct simple_work_queue *get_current_thread_work_queue(void) +{ + /* + * In interrupt context, if a vdo thread is what got interrupted, the calls below will find + * the queue for the thread which was interrupted. However, the interrupted thread may have + * been processing a completion, in which case starting to process another would violate + * our concurrency assumptions. + */ + if (in_interrupt()) + return NULL; + if (kthread_func(current) != work_queue_runner) + /* Not a VDO work queue thread. */ + return NULL; + return kthread_data(current); +} + +struct vdo_work_queue *vdo_get_current_work_queue(void) +{ + struct simple_work_queue *queue = get_current_thread_work_queue(); + + return (queue == NULL) ? NULL : &queue->common; +} + +struct vdo_thread *vdo_get_work_queue_owner(struct vdo_work_queue *queue) +{ + return queue->owner; +} + +/** + * vdo_get_work_queue_private_data() - Returns the private data for the current thread's work + * queue, or NULL if none or if the current thread is not a + * work queue thread. + */ +void *vdo_get_work_queue_private_data(void) +{ + struct simple_work_queue *queue = get_current_thread_work_queue(); + + return (queue != NULL) ? queue->private : NULL; +} + +bool vdo_work_queue_type_is(struct vdo_work_queue *queue, const struct vdo_work_queue_type *type) +{ + return (queue->type == type); +} diff --git a/drivers/md/dm-vdo/work-queue.h b/drivers/md/dm-vdo/work-queue.h new file mode 100644 index 000000000000..1d5aa9878b16 --- /dev/null +++ b/drivers/md/dm-vdo/work-queue.h @@ -0,0 +1,53 @@ +/* SPDX-License-Identifier: GPL-2.0-only */ +/* + * Copyright 2023 Red Hat + */ + +#ifndef VDO_WORK_QUEUE_H +#define VDO_WORK_QUEUE_H + +#include <linux/sched.h> /* for TASK_COMM_LEN */ + +#include "types.h" + +enum { + MAX_VDO_WORK_QUEUE_NAME_LEN = TASK_COMM_LEN, +}; + +struct vdo_work_queue_type { + void (*start)(void *context); + void (*finish)(void *context); + enum vdo_completion_priority max_priority; + enum vdo_completion_priority default_priority; +}; + +struct vdo_completion; +struct vdo_thread; +struct vdo_work_queue; + +int vdo_make_work_queue(const char *thread_name_prefix, + const char *name, + struct vdo_thread *owner, + const struct vdo_work_queue_type *type, + unsigned int thread_count, + void *thread_privates[], + struct vdo_work_queue **queue_ptr); + +void vdo_enqueue_work_queue(struct vdo_work_queue *queue, struct vdo_completion *completion); + +void vdo_finish_work_queue(struct vdo_work_queue *queue); + +void vdo_free_work_queue(struct vdo_work_queue *queue); + +void vdo_dump_work_queue(struct vdo_work_queue *queue); + +void vdo_dump_completion_to_buffer(struct vdo_completion *completion, char *buffer, size_t length); + +void *vdo_get_work_queue_private_data(void); +struct vdo_work_queue *vdo_get_current_work_queue(void); +struct vdo_thread *vdo_get_work_queue_owner(struct vdo_work_queue *queue); + +bool __must_check +vdo_work_queue_type_is(struct vdo_work_queue *queue, const struct vdo_work_queue_type *type); + +#endif /* VDO_WORK_QUEUE_H */ -- 2.40.0 -- dm-devel mailing list dm-devel@xxxxxxxxxx https://listman.redhat.com/mailman/listinfo/dm-devel