drivers/md/dm-vdo/io-submitter.c - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0-only
 /*
  * Copyright 2023 Red Hat
  */

 #include "io-submitter.h"

 #include <linux/bio.h>
 #include <linux/kernel.h>
 #include <linux/mutex.h>

 #include "memory-alloc.h"
 #include "permassert.h"

 #include "data-vio.h"
 #include "logger.h"
 #include "types.h"
 #include "vdo.h"
 #include "vio.h"

 /*
  * Submission of bio operations to the underlying storage device will go through a separate work
  * queue thread (or more than one) to prevent blocking in other threads if the storage device has a
  * full queue. The plug structure allows that thread to do better batching of requests to make the
  * I/O more efficient.
  *
  * When multiple worker threads are used, a thread is chosen for a I/O operation submission based
  * on the PBN, so a given PBN will consistently wind up on the same thread. Flush operations are
  * assigned round-robin.
  *
  * The map (protected by the mutex) collects pending I/O operations so that the worker thread can
  * reorder them to try to encourage I/O request merging in the request queue underneath.
  */
 struct bio_queue_data {
 	struct vdo_work_queue *queue;
 	struct blk_plug plug;
 	struct int_map *map;
 	struct mutex lock;
 	unsigned int queue_number;
 };

 struct io_submitter {
 	unsigned int num_bio_queues_used;
 	unsigned int bio_queue_rotation_interval;
 	struct bio_queue_data bio_queue_data[];
 };

 static void start_bio_queue(void *ptr)
 {
 	struct bio_queue_data *bio_queue_data = ptr;

 	blk_start_plug(&bio_queue_data->plug);
 }

 static void finish_bio_queue(void *ptr)
 {
 	struct bio_queue_data *bio_queue_data = ptr;

 	blk_finish_plug(&bio_queue_data->plug);
 }

 static const struct vdo_work_queue_type bio_queue_type = {
 	.start = start_bio_queue,
 	.finish = finish_bio_queue,
 	.max_priority = BIO_Q_MAX_PRIORITY,
 	.default_priority = BIO_Q_DATA_PRIORITY,
 };

 /**
  * count_all_bios() - Determine which bio counter to use.
  * @vio: The vio associated with the bio.
  * @bio: The bio to count.
  */
 static void count_all_bios(struct vio *vio, struct bio *bio)
 {
 	struct atomic_statistics *stats = &vio->completion.vdo->stats;

 	if (is_data_vio(vio)) {
 		vdo_count_bios(&stats->bios_out, bio);
 		return;
 	}

 	vdo_count_bios(&stats->bios_meta, bio);
 	if (vio->type == VIO_TYPE_RECOVERY_JOURNAL)
 		vdo_count_bios(&stats->bios_journal, bio);
 	else if (vio->type == VIO_TYPE_BLOCK_MAP)
 		vdo_count_bios(&stats->bios_page_cache, bio);
 }

 /**
  * assert_in_bio_zone() - Assert that a vio is in the correct bio zone and not in interrupt
  *                        context.
  * @vio: The vio to check.
  */
 static void assert_in_bio_zone(struct vio *vio)
 {
 	VDO_ASSERT_LOG_ONLY(!in_interrupt(), "not in interrupt context");
 	assert_vio_in_bio_zone(vio);
 }

 /**
  * send_bio_to_device() - Update stats and tracing info, then submit the supplied bio to the OS for
  *                        processing.
  * @vio: The vio associated with the bio.
  * @bio: The bio to submit to the OS.
  */
 static void send_bio_to_device(struct vio *vio, struct bio *bio)
 {
 	struct vdo *vdo = vio->completion.vdo;

 	assert_in_bio_zone(vio);
 	atomic64_inc(&vdo->stats.bios_submitted);
 	count_all_bios(vio, bio);
 	bio_set_dev(bio, vdo_get_backing_device(vdo));
 	submit_bio_noacct(bio);
 }

 /**
  * vdo_submit_vio() - Submits a vio's bio to the underlying block device. May block if the device
  *		      is busy. This callback should be used by vios which did not attempt to merge.
  */
 void vdo_submit_vio(struct vdo_completion *completion)
 {
 	struct vio *vio = as_vio(completion);

 	send_bio_to_device(vio, vio->bio);
 }

 /**
  * get_bio_list() - Extract the list of bios to submit from a vio.
  * @vio: The vio submitting I/O.
  *
  * The list will always contain at least one entry (the bio for the vio on which it is called), but
  * other bios may have been merged with it as well.
  *
  * Return: bio  The head of the bio list to submit.
  */
 static struct bio *get_bio_list(struct vio *vio)
 {
 	struct bio *bio;
 	struct io_submitter *submitter = vio->completion.vdo->io_submitter;
 	struct bio_queue_data *bio_queue_data = &(submitter->bio_queue_data[vio->bio_zone]);

 	assert_in_bio_zone(vio);

 	mutex_lock(&bio_queue_data->lock);
 	vdo_int_map_remove(bio_queue_data->map,
 			   vio->bios_merged.head->bi_iter.bi_sector);
 	vdo_int_map_remove(bio_queue_data->map,
 			   vio->bios_merged.tail->bi_iter.bi_sector);
 	bio = vio->bios_merged.head;
 	bio_list_init(&vio->bios_merged);
 	mutex_unlock(&bio_queue_data->lock);

 	return bio;
 }

 /**
  * submit_data_vio() - Submit a data_vio's bio to the storage below along with
  *		       any bios that have been merged with it.
  *
  * Context: This call may block and so should only be called from a bio thread.
  */
 static void submit_data_vio(struct vdo_completion *completion)
 {
 	struct bio *bio, *next;
 	struct vio *vio = as_vio(completion);

 	assert_in_bio_zone(vio);
 	for (bio = get_bio_list(vio); bio != NULL; bio = next) {
 		next = bio->bi_next;
 		bio->bi_next = NULL;
 		send_bio_to_device((struct vio *) bio->bi_private, bio);
 	}
 }

 /**
  * get_mergeable_locked() - Attempt to find an already queued bio that the current bio can be
  *                          merged with.
  * @map: The bio map to use for merging.
  * @vio: The vio we want to merge.
  * @back_merge: Set to true for a back merge, false for a front merge.
  *
  * There are two types of merging possible, forward and backward, which are distinguished by a flag
  * that uses kernel elevator terminology.
  *
  * Return: the vio to merge to, NULL if no merging is possible.
  */
 static struct vio *get_mergeable_locked(struct int_map *map, struct vio *vio,
 					bool back_merge)
 {
 	struct bio *bio = vio->bio;
 	sector_t merge_sector = bio->bi_iter.bi_sector;
 	struct vio *vio_merge;

 	if (back_merge)
 		merge_sector -= VDO_SECTORS_PER_BLOCK;
 	else
 		merge_sector += VDO_SECTORS_PER_BLOCK;

 	vio_merge = vdo_int_map_get(map, merge_sector);

 	if (vio_merge == NULL)
 		return NULL;

 	if (vio->completion.priority != vio_merge->completion.priority)
 		return NULL;

 	if (bio_data_dir(bio) != bio_data_dir(vio_merge->bio))
 		return NULL;

 	if (bio_list_empty(&vio_merge->bios_merged))
 		return NULL;

 	if (back_merge) {
 		return (vio_merge->bios_merged.tail->bi_iter.bi_sector == merge_sector ?
 			vio_merge : NULL);
 	}

 	return (vio_merge->bios_merged.head->bi_iter.bi_sector == merge_sector ?
 		vio_merge : NULL);
 }

 static int map_merged_vio(struct int_map *bio_map, struct vio *vio)
 {
 	int result;
 	sector_t bio_sector;

 	bio_sector = vio->bios_merged.head->bi_iter.bi_sector;
 	result = vdo_int_map_put(bio_map, bio_sector, vio, true, NULL);
 	if (result != VDO_SUCCESS)
 		return result;

 	bio_sector = vio->bios_merged.tail->bi_iter.bi_sector;
 	return vdo_int_map_put(bio_map, bio_sector, vio, true, NULL);
 }

 static int merge_to_prev_tail(struct int_map *bio_map, struct vio *vio,
 			      struct vio *prev_vio)
 {
 	vdo_int_map_remove(bio_map, prev_vio->bios_merged.tail->bi_iter.bi_sector);
 	bio_list_merge(&prev_vio->bios_merged, &vio->bios_merged);
 	return map_merged_vio(bio_map, prev_vio);
 }

 static int merge_to_next_head(struct int_map *bio_map, struct vio *vio,
 			      struct vio *next_vio)
 {
 	/*
 	 * Handle "next merge" and "gap fill" cases the same way so as to reorder bios in a way
 	 * that's compatible with using funnel queues in work queues. This avoids removing an
 	 * existing completion.
 	 */
 	vdo_int_map_remove(bio_map, next_vio->bios_merged.head->bi_iter.bi_sector);
 	bio_list_merge_head(&next_vio->bios_merged, &vio->bios_merged);
 	return map_merged_vio(bio_map, next_vio);
 }

 /**
  * try_bio_map_merge() - Attempt to merge a vio's bio with other pending I/Os.
  * @vio: The vio to merge.
  *
  * Currently this is only used for data_vios, but is broken out for future use with metadata vios.
  *
  * Return: whether or not the vio was merged.
  */
 static bool try_bio_map_merge(struct vio *vio)
 {
 	int result;
 	bool merged = true;
 	struct bio *bio = vio->bio;
 	struct vio *prev_vio, *next_vio;
 	struct vdo *vdo = vio->completion.vdo;
 	struct bio_queue_data *bio_queue_data =
 		&vdo->io_submitter->bio_queue_data[vio->bio_zone];

 	bio->bi_next = NULL;
 	bio_list_init(&vio->bios_merged);
 	bio_list_add(&vio->bios_merged, bio);

 	mutex_lock(&bio_queue_data->lock);
 	prev_vio = get_mergeable_locked(bio_queue_data->map, vio, true);
 	next_vio = get_mergeable_locked(bio_queue_data->map, vio, false);
 	if (prev_vio == next_vio)
 		next_vio = NULL;

 	if ((prev_vio == NULL) && (next_vio == NULL)) {
 		/* no merge. just add to bio_queue */
 		merged = false;
 		result = vdo_int_map_put(bio_queue_data->map,
 					 bio->bi_iter.bi_sector,
 					 vio, true, NULL);
 	} else if (next_vio == NULL) {
 		/* Only prev. merge to prev's tail */
 		result = merge_to_prev_tail(bio_queue_data->map, vio, prev_vio);
 	} else {
 		/* Only next. merge to next's head */
 		result = merge_to_next_head(bio_queue_data->map, vio, next_vio);
 	}
 	mutex_unlock(&bio_queue_data->lock);

 	/* We don't care about failure of int_map_put in this case. */
 	VDO_ASSERT_LOG_ONLY(result == VDO_SUCCESS, "bio map insertion succeeds");
 	return merged;
 }

 /**
  * vdo_submit_data_vio() - Submit I/O for a data_vio.
  * @data_vio: the data_vio for which to issue I/O.
  *
  * If possible, this I/O will be merged other pending I/Os. Otherwise, the data_vio will be sent to
  * the appropriate bio zone directly.
  */
 void vdo_submit_data_vio(struct data_vio *data_vio)
 {
 	if (try_bio_map_merge(&data_vio->vio))
 		return;

 	launch_data_vio_bio_zone_callback(data_vio, submit_data_vio);
 }

 /**
  * __submit_metadata_vio() - Submit I/O for a metadata vio.
  * @vio: the vio for which to issue I/O
  * @physical: the physical block number to read or write
  * @callback: the bio endio function which will be called after the I/O completes
  * @error_handler: the handler for submission or I/O errors (may be NULL)
  * @operation: the type of I/O to perform
  * @data: the buffer to read or write (may be NULL)
  *
  * The vio is enqueued on a vdo bio queue so that bio submission (which may block) does not block
  * other vdo threads.
  *
  * That the error handler will run on the correct thread is only true so long as the thread calling
  * this function, and the thread set in the endio callback are the same, as well as the fact that
  * no error can occur on the bio queue. Currently this is true for all callers, but additional care
  * will be needed if this ever changes.
  */
 void __submit_metadata_vio(struct vio *vio, physical_block_number_t physical,
 			   bio_end_io_t callback, vdo_action_fn error_handler,
 			   blk_opf_t operation, char *data)
 {
 	int result;
 	struct vdo_completion *completion = &vio->completion;
 	const struct admin_state_code *code = vdo_get_admin_state(completion->vdo);


 	VDO_ASSERT_LOG_ONLY(!code->quiescent, "I/O not allowed in state %s", code->name);
 	VDO_ASSERT_LOG_ONLY(vio->bio->bi_next == NULL, "metadata bio has no next bio");

 	vdo_reset_completion(completion);
 	completion->error_handler = error_handler;
 	result = vio_reset_bio(vio, data, callback, operation | REQ_META, physical);
 	if (result != VDO_SUCCESS) {
 		continue_vio(vio, result);
 		return;
 	}

 	vdo_set_completion_callback(completion, vdo_submit_vio,
 				    get_vio_bio_zone_thread_id(vio));
 	vdo_launch_completion_with_priority(completion, get_metadata_priority(vio));
 }

 /**
  * vdo_make_io_submitter() - Create an io_submitter structure.
  * @thread_count: Number of bio-submission threads to set up.
  * @rotation_interval: Interval to use when rotating between bio-submission threads when enqueuing
  *                     completions.
  * @max_requests_active: Number of bios for merge tracking.
  * @vdo: The vdo which will use this submitter.
  * @io_submitter: pointer to the new data structure.
  *
  * Return: VDO_SUCCESS or an error.
  */
 int vdo_make_io_submitter(unsigned int thread_count, unsigned int rotation_interval,
 			  unsigned int max_requests_active, struct vdo *vdo,
 			  struct io_submitter **io_submitter_ptr)
 {
 	unsigned int i;
 	struct io_submitter *io_submitter;
 	int result;

 	result = vdo_allocate_extended(struct io_submitter, thread_count,
 				       struct bio_queue_data, "bio submission data",
 				       &io_submitter);
 	if (result != VDO_SUCCESS)
 		return result;

 	io_submitter->bio_queue_rotation_interval = rotation_interval;

 	/* Setup for each bio-submission work queue */
 	for (i = 0; i < thread_count; i++) {
 		struct bio_queue_data *bio_queue_data = &io_submitter->bio_queue_data[i];

 		mutex_init(&bio_queue_data->lock);
 		/*
 		 * One I/O operation per request, but both first & last sector numbers.
 		 *
 		 * If requests are assigned to threads round-robin, they should be distributed
 		 * quite evenly. But if they're assigned based on PBN, things can sometimes be very
 		 * uneven. So for now, we'll assume that all requests *may* wind up on one thread,
 		 * and thus all in the same map.
 		 */
 		result = vdo_int_map_create(max_requests_active * 2,
 					    &bio_queue_data->map);
 		if (result != VDO_SUCCESS) {
 			/*
 			 * Clean up the partially initialized bio-queue entirely and indicate that
 			 * initialization failed.
 			 */
 			vdo_log_error("bio map initialization failed %d", result);
 			vdo_cleanup_io_submitter(io_submitter);
 			vdo_free_io_submitter(io_submitter);
 			return result;
 		}

 		bio_queue_data->queue_number = i;
 		result = vdo_make_thread(vdo, vdo->thread_config.bio_threads[i],
 					 &bio_queue_type, 1, (void **) &bio_queue_data);
 		if (result != VDO_SUCCESS) {
 			/*
 			 * Clean up the partially initialized bio-queue entirely and indicate that
 			 * initialization failed.
 			 */
 			vdo_int_map_free(vdo_forget(bio_queue_data->map));
 			vdo_log_error("bio queue initialization failed %d", result);
 			vdo_cleanup_io_submitter(io_submitter);
 			vdo_free_io_submitter(io_submitter);
 			return result;
 		}

 		bio_queue_data->queue = vdo->threads[vdo->thread_config.bio_threads[i]].queue;
 		io_submitter->num_bio_queues_used++;
 	}

 	*io_submitter_ptr = io_submitter;

 	return VDO_SUCCESS;
 }

 /**
  * vdo_cleanup_io_submitter() - Tear down the io_submitter fields as needed for a physical layer.
  * @io_submitter: The I/O submitter data to tear down (may be NULL).
  */
 void vdo_cleanup_io_submitter(struct io_submitter *io_submitter)
 {
 	int i;

 	if (io_submitter == NULL)
 		return;

 	for (i = io_submitter->num_bio_queues_used - 1; i >= 0; i--)
 		vdo_finish_work_queue(io_submitter->bio_queue_data[i].queue);
 }

 /**
  * vdo_free_io_submitter() - Free the io_submitter fields and structure as needed.
  * @io_submitter: The I/O submitter data to destroy.
  *
  * This must be called after vdo_cleanup_io_submitter(). It is used to release resources late in
  * the shutdown process to avoid or reduce the chance of race conditions.
  */
 void vdo_free_io_submitter(struct io_submitter *io_submitter)
 {
 	int i;

 	if (io_submitter == NULL)
 		return;

 	for (i = io_submitter->num_bio_queues_used - 1; i >= 0; i--) {
 		io_submitter->num_bio_queues_used--;
 		/* vdo_destroy() will free the work queue, so just give up our reference to it. */
 		vdo_forget(io_submitter->bio_queue_data[i].queue);
 		vdo_int_map_free(vdo_forget(io_submitter->bio_queue_data[i].map));
 	}
 	vdo_free(io_submitter);
 }
	// SPDX-License-Identifier: GPL-2.0-only
	/*
	* Copyright 2023 Red Hat
	*/

	#include "io-submitter.h"

	#include <linux/bio.h>
	#include <linux/kernel.h>
	#include <linux/mutex.h>

	#include "memory-alloc.h"
	#include "permassert.h"

	#include "data-vio.h"
	#include "logger.h"
	#include "types.h"
	#include "vdo.h"
	#include "vio.h"

	/*
	* Submission of bio operations to the underlying storage device will go through a separate work
	* queue thread (or more than one) to prevent blocking in other threads if the storage device has a
	* full queue. The plug structure allows that thread to do better batching of requests to make the
	* I/O more efficient.
	*
	* When multiple worker threads are used, a thread is chosen for a I/O operation submission based
	* on the PBN, so a given PBN will consistently wind up on the same thread. Flush operations are
	* assigned round-robin.
	*
	* The map (protected by the mutex) collects pending I/O operations so that the worker thread can
	* reorder them to try to encourage I/O request merging in the request queue underneath.
	*/
	struct bio_queue_data {
	struct vdo_work_queue *queue;
	struct blk_plug plug;
	struct int_map *map;
	struct mutex lock;
	unsigned int queue_number;
	};

	struct io_submitter {
	unsigned int num_bio_queues_used;
	unsigned int bio_queue_rotation_interval;
	struct bio_queue_data bio_queue_data[];
	};

	static void start_bio_queue(void *ptr)
	{
	struct bio_queue_data *bio_queue_data = ptr;

	blk_start_plug(&bio_queue_data->plug);
	}

	static void finish_bio_queue(void *ptr)
	{
	struct bio_queue_data *bio_queue_data = ptr;

	blk_finish_plug(&bio_queue_data->plug);
	}

	static const struct vdo_work_queue_type bio_queue_type = {
	.start = start_bio_queue,
	.finish = finish_bio_queue,
	.max_priority = BIO_Q_MAX_PRIORITY,
	.default_priority = BIO_Q_DATA_PRIORITY,
	};

	/**
	* count_all_bios() - Determine which bio counter to use.
	* @vio: The vio associated with the bio.
	* @bio: The bio to count.
	*/
	static void count_all_bios(struct vio vio, struct bio bio)
	{
	struct atomic_statistics *stats = &vio->completion.vdo->stats;

	if (is_data_vio(vio)) {
	vdo_count_bios(&stats->bios_out, bio);
	return;
	}

	vdo_count_bios(&stats->bios_meta, bio);
	if (vio->type == VIO_TYPE_RECOVERY_JOURNAL)
	vdo_count_bios(&stats->bios_journal, bio);
	else if (vio->type == VIO_TYPE_BLOCK_MAP)
	vdo_count_bios(&stats->bios_page_cache, bio);
	}

	/**
	* assert_in_bio_zone() - Assert that a vio is in the correct bio zone and not in interrupt
	* context.
	* @vio: The vio to check.
	*/
	static void assert_in_bio_zone(struct vio *vio)
	{
	VDO_ASSERT_LOG_ONLY(!in_interrupt(), "not in interrupt context");
	assert_vio_in_bio_zone(vio);
	}

	/**
	* send_bio_to_device() - Update stats and tracing info, then submit the supplied bio to the OS for
	* processing.
	* @vio: The vio associated with the bio.
	* @bio: The bio to submit to the OS.
	*/
	static void send_bio_to_device(struct vio vio, struct bio bio)
	{
	struct vdo *vdo = vio->completion.vdo;

	assert_in_bio_zone(vio);
	atomic64_inc(&vdo->stats.bios_submitted);
	count_all_bios(vio, bio);
	bio_set_dev(bio, vdo_get_backing_device(vdo));
	submit_bio_noacct(bio);
	}

	/**
	* vdo_submit_vio() - Submits a vio's bio to the underlying block device. May block if the device
	* is busy. This callback should be used by vios which did not attempt to merge.
	*/
	void vdo_submit_vio(struct vdo_completion *completion)
	{
	struct vio *vio = as_vio(completion);

	send_bio_to_device(vio, vio->bio);
	}

	/**
	* get_bio_list() - Extract the list of bios to submit from a vio.
	* @vio: The vio submitting I/O.
	*
	* The list will always contain at least one entry (the bio for the vio on which it is called), but
	* other bios may have been merged with it as well.
	*
	* Return: bio The head of the bio list to submit.
	*/
	static struct bio get_bio_list(struct vio vio)
	{
	struct bio *bio;
	struct io_submitter *submitter = vio->completion.vdo->io_submitter;
	struct bio_queue_data *bio_queue_data = &(submitter->bio_queue_data[vio->bio_zone]);

	assert_in_bio_zone(vio);

	mutex_lock(&bio_queue_data->lock);
	vdo_int_map_remove(bio_queue_data->map,
	vio->bios_merged.head->bi_iter.bi_sector);
	vdo_int_map_remove(bio_queue_data->map,
	vio->bios_merged.tail->bi_iter.bi_sector);
	bio = vio->bios_merged.head;
	bio_list_init(&vio->bios_merged);
	mutex_unlock(&bio_queue_data->lock);

	return bio;
	}

	/**
	* submit_data_vio() - Submit a data_vio's bio to the storage below along with
	* any bios that have been merged with it.
	*
	* Context: This call may block and so should only be called from a bio thread.
	*/
	static void submit_data_vio(struct vdo_completion *completion)
	{
	struct bio bio, next;
	struct vio *vio = as_vio(completion);

	assert_in_bio_zone(vio);
	for (bio = get_bio_list(vio); bio != NULL; bio = next) {
	next = bio->bi_next;
	bio->bi_next = NULL;
	send_bio_to_device((struct vio *) bio->bi_private, bio);
	}
	}

	/**
	* get_mergeable_locked() - Attempt to find an already queued bio that the current bio can be
	* merged with.
	* @map: The bio map to use for merging.
	* @vio: The vio we want to merge.
	* @back_merge: Set to true for a back merge, false for a front merge.
	*
	* There are two types of merging possible, forward and backward, which are distinguished by a flag
	* that uses kernel elevator terminology.
	*
	* Return: the vio to merge to, NULL if no merging is possible.
	*/
	static struct vio get_mergeable_locked(struct int_map map, struct vio *vio,
	bool back_merge)
	{
	struct bio *bio = vio->bio;
	sector_t merge_sector = bio->bi_iter.bi_sector;
	struct vio *vio_merge;

	if (back_merge)
	merge_sector -= VDO_SECTORS_PER_BLOCK;
	else
	merge_sector += VDO_SECTORS_PER_BLOCK;

	vio_merge = vdo_int_map_get(map, merge_sector);

	if (vio_merge == NULL)
	return NULL;

	if (vio->completion.priority != vio_merge->completion.priority)
	return NULL;

	if (bio_data_dir(bio) != bio_data_dir(vio_merge->bio))
	return NULL;

	if (bio_list_empty(&vio_merge->bios_merged))
	return NULL;

	if (back_merge) {
	return (vio_merge->bios_merged.tail->bi_iter.bi_sector == merge_sector ?
	vio_merge : NULL);
	}

	return (vio_merge->bios_merged.head->bi_iter.bi_sector == merge_sector ?
	vio_merge : NULL);
	}

	static int map_merged_vio(struct int_map bio_map, struct vio vio)
	{
	int result;
	sector_t bio_sector;

	bio_sector = vio->bios_merged.head->bi_iter.bi_sector;
	result = vdo_int_map_put(bio_map, bio_sector, vio, true, NULL);
	if (result != VDO_SUCCESS)
	return result;

	bio_sector = vio->bios_merged.tail->bi_iter.bi_sector;
	return vdo_int_map_put(bio_map, bio_sector, vio, true, NULL);
	}

	static int merge_to_prev_tail(struct int_map bio_map, struct vio vio,
	struct vio *prev_vio)
	{
	vdo_int_map_remove(bio_map, prev_vio->bios_merged.tail->bi_iter.bi_sector);
	bio_list_merge(&prev_vio->bios_merged, &vio->bios_merged);
	return map_merged_vio(bio_map, prev_vio);
	}

	static int merge_to_next_head(struct int_map bio_map, struct vio vio,
	struct vio *next_vio)
	{
	/*
	* Handle "next merge" and "gap fill" cases the same way so as to reorder bios in a way
	* that's compatible with using funnel queues in work queues. This avoids removing an
	* existing completion.
	*/
	vdo_int_map_remove(bio_map, next_vio->bios_merged.head->bi_iter.bi_sector);
	bio_list_merge_head(&next_vio->bios_merged, &vio->bios_merged);
	return map_merged_vio(bio_map, next_vio);
	}

	/**
	* try_bio_map_merge() - Attempt to merge a vio's bio with other pending I/Os.
	* @vio: The vio to merge.
	*
	* Currently this is only used for data_vios, but is broken out for future use with metadata vios.
	*
	* Return: whether or not the vio was merged.
	*/
	static bool try_bio_map_merge(struct vio *vio)
	{
	int result;
	bool merged = true;
	struct bio *bio = vio->bio;
	struct vio prev_vio, next_vio;
	struct vdo *vdo = vio->completion.vdo;
	struct bio_queue_data *bio_queue_data =
	&vdo->io_submitter->bio_queue_data[vio->bio_zone];

	bio->bi_next = NULL;
	bio_list_init(&vio->bios_merged);
	bio_list_add(&vio->bios_merged, bio);

	mutex_lock(&bio_queue_data->lock);
	prev_vio = get_mergeable_locked(bio_queue_data->map, vio, true);
	next_vio = get_mergeable_locked(bio_queue_data->map, vio, false);
	if (prev_vio == next_vio)
	next_vio = NULL;

	if ((prev_vio == NULL) && (next_vio == NULL)) {
	/* no merge. just add to bio_queue */
	merged = false;
	result = vdo_int_map_put(bio_queue_data->map,
	bio->bi_iter.bi_sector,
	vio, true, NULL);
	} else if (next_vio == NULL) {
	/* Only prev. merge to prev's tail */
	result = merge_to_prev_tail(bio_queue_data->map, vio, prev_vio);
	} else {
	/* Only next. merge to next's head */
	result = merge_to_next_head(bio_queue_data->map, vio, next_vio);
	}
	mutex_unlock(&bio_queue_data->lock);

	/* We don't care about failure of int_map_put in this case. */
	VDO_ASSERT_LOG_ONLY(result == VDO_SUCCESS, "bio map insertion succeeds");
	return merged;
	}

	/**
	* vdo_submit_data_vio() - Submit I/O for a data_vio.
	* @data_vio: the data_vio for which to issue I/O.
	*
	* If possible, this I/O will be merged other pending I/Os. Otherwise, the data_vio will be sent to
	* the appropriate bio zone directly.
	*/
	void vdo_submit_data_vio(struct data_vio *data_vio)
	{
	if (try_bio_map_merge(&data_vio->vio))
	return;

	launch_data_vio_bio_zone_callback(data_vio, submit_data_vio);
	}

	/**
	* __submit_metadata_vio() - Submit I/O for a metadata vio.
	* @vio: the vio for which to issue I/O
	* @physical: the physical block number to read or write
	* @callback: the bio endio function which will be called after the I/O completes
	* @error_handler: the handler for submission or I/O errors (may be NULL)
	* @operation: the type of I/O to perform
	* @data: the buffer to read or write (may be NULL)
	*
	* The vio is enqueued on a vdo bio queue so that bio submission (which may block) does not block
	* other vdo threads.
	*
	* That the error handler will run on the correct thread is only true so long as the thread calling
	* this function, and the thread set in the endio callback are the same, as well as the fact that
	* no error can occur on the bio queue. Currently this is true for all callers, but additional care
	* will be needed if this ever changes.
	*/
	void __submit_metadata_vio(struct vio *vio, physical_block_number_t physical,
	bio_end_io_t callback, vdo_action_fn error_handler,
	blk_opf_t operation, char *data)
	{
	int result;
	struct vdo_completion *completion = &vio->completion;
	const struct admin_state_code *code = vdo_get_admin_state(completion->vdo);


	VDO_ASSERT_LOG_ONLY(!code->quiescent, "I/O not allowed in state %s", code->name);
	VDO_ASSERT_LOG_ONLY(vio->bio->bi_next == NULL, "metadata bio has no next bio");

	vdo_reset_completion(completion);
	completion->error_handler = error_handler;
	result = vio_reset_bio(vio, data, callback, operation \| REQ_META, physical);
	if (result != VDO_SUCCESS) {
	continue_vio(vio, result);
	return;
	}

	vdo_set_completion_callback(completion, vdo_submit_vio,
	get_vio_bio_zone_thread_id(vio));
	vdo_launch_completion_with_priority(completion, get_metadata_priority(vio));
	}

	/**
	* vdo_make_io_submitter() - Create an io_submitter structure.
	* @thread_count: Number of bio-submission threads to set up.
	* @rotation_interval: Interval to use when rotating between bio-submission threads when enqueuing
	* completions.
	* @max_requests_active: Number of bios for merge tracking.
	* @vdo: The vdo which will use this submitter.
	* @io_submitter: pointer to the new data structure.
	*
	* Return: VDO_SUCCESS or an error.
	*/
	int vdo_make_io_submitter(unsigned int thread_count, unsigned int rotation_interval,
	unsigned int max_requests_active, struct vdo *vdo,
	struct io_submitter **io_submitter_ptr)
	{
	unsigned int i;
	struct io_submitter *io_submitter;
	int result;

	result = vdo_allocate_extended(struct io_submitter, thread_count,
	struct bio_queue_data, "bio submission data",
	&io_submitter);
	if (result != VDO_SUCCESS)
	return result;

	io_submitter->bio_queue_rotation_interval = rotation_interval;

	/* Setup for each bio-submission work queue */
	for (i = 0; i < thread_count; i++) {
	struct bio_queue_data *bio_queue_data = &io_submitter->bio_queue_data[i];

	mutex_init(&bio_queue_data->lock);
	/*
	* One I/O operation per request, but both first & last sector numbers.
	*
	* If requests are assigned to threads round-robin, they should be distributed
	* quite evenly. But if they're assigned based on PBN, things can sometimes be very
	* uneven. So for now, we'll assume that all requests may wind up on one thread,
	* and thus all in the same map.
	*/
	result = vdo_int_map_create(max_requests_active * 2,
	&bio_queue_data->map);
	if (result != VDO_SUCCESS) {
	/*
	* Clean up the partially initialized bio-queue entirely and indicate that
	* initialization failed.
	*/
	vdo_log_error("bio map initialization failed %d", result);
	vdo_cleanup_io_submitter(io_submitter);
	vdo_free_io_submitter(io_submitter);
	return result;
	}

	bio_queue_data->queue_number = i;
	result = vdo_make_thread(vdo, vdo->thread_config.bio_threads[i],
	&bio_queue_type, 1, (void **) &bio_queue_data);
	if (result != VDO_SUCCESS) {
	/*
	* Clean up the partially initialized bio-queue entirely and indicate that
	* initialization failed.
	*/
	vdo_int_map_free(vdo_forget(bio_queue_data->map));
	vdo_log_error("bio queue initialization failed %d", result);
	vdo_cleanup_io_submitter(io_submitter);
	vdo_free_io_submitter(io_submitter);
	return result;
	}

	bio_queue_data->queue = vdo->threads[vdo->thread_config.bio_threads[i]].queue;
	io_submitter->num_bio_queues_used++;
	}

	*io_submitter_ptr = io_submitter;

	return VDO_SUCCESS;
	}

	/**
	* vdo_cleanup_io_submitter() - Tear down the io_submitter fields as needed for a physical layer.
	* @io_submitter: The I/O submitter data to tear down (may be NULL).
	*/
	void vdo_cleanup_io_submitter(struct io_submitter *io_submitter)
	{
	int i;

	if (io_submitter == NULL)
	return;

	for (i = io_submitter->num_bio_queues_used - 1; i >= 0; i--)
	vdo_finish_work_queue(io_submitter->bio_queue_data[i].queue);
	}

	/**
	* vdo_free_io_submitter() - Free the io_submitter fields and structure as needed.
	* @io_submitter: The I/O submitter data to destroy.
	*
	* This must be called after vdo_cleanup_io_submitter(). It is used to release resources late in
	* the shutdown process to avoid or reduce the chance of race conditions.
	*/
	void vdo_free_io_submitter(struct io_submitter *io_submitter)
	{
	int i;

	if (io_submitter == NULL)
	return;

	for (i = io_submitter->num_bio_queues_used - 1; i >= 0; i--) {
	io_submitter->num_bio_queues_used--;
	/* vdo_destroy() will free the work queue, so just give up our reference to it. */
	vdo_forget(io_submitter->bio_queue_data[i].queue);
	vdo_int_map_free(vdo_forget(io_submitter->bio_queue_data[i].map));
	}
	vdo_free(io_submitter);
	}