drivers/md/dm-vdo/memory-alloc.c - linux - Git at Google

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

 #include <linux/delay.h>
 #include <linux/mm.h>
 #include <linux/sched/mm.h>
 #include <linux/slab.h>
 #include <linux/vmalloc.h>

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

 /*
  * UDS and VDO keep track of which threads are allowed to allocate memory freely, and which threads
  * must be careful to not do a memory allocation that does an I/O request. The 'allocating_threads'
  * thread_registry and its associated methods implement this tracking.
  */
 static struct thread_registry allocating_threads;

 static inline bool allocations_allowed(void)
 {
 	return vdo_lookup_thread(&allocating_threads) != NULL;
 }

 /*
  * Register the current thread as an allocating thread.
  *
  * An optional flag location can be supplied indicating whether, at any given point in time, the
  * threads associated with that flag should be allocating storage. If the flag is false, a message
  * will be logged.
  *
  * If no flag is supplied, the thread is always allowed to allocate storage without complaint.
  *
  * @new_thread: registered_thread structure to use for the current thread
  * @flag_ptr: Location of the allocation-allowed flag
  */
 void vdo_register_allocating_thread(struct registered_thread *new_thread,
 				    const bool *flag_ptr)
 {
 	if (flag_ptr == NULL) {
 		static const bool allocation_always_allowed = true;

 		flag_ptr = &allocation_always_allowed;
 	}

 	vdo_register_thread(&allocating_threads, new_thread, flag_ptr);
 }

 /* Unregister the current thread as an allocating thread. */
 void vdo_unregister_allocating_thread(void)
 {
 	vdo_unregister_thread(&allocating_threads);
 }

 /*
  * We track how much memory has been allocated and freed. When we unload the module, we log an
  * error if we have not freed all the memory that we allocated. Nearly all memory allocation and
  * freeing is done using this module.
  *
  * We do not use kernel functions like the kvasprintf() method, which allocate memory indirectly
  * using kmalloc.
  *
  * These data structures and methods are used to track the amount of memory used.
  */

 /*
  * We allocate very few large objects, and allocation/deallocation isn't done in a
  * performance-critical stage for us, so a linked list should be fine.
  */
 struct vmalloc_block_info {
 	void *ptr;
 	size_t size;
 	struct vmalloc_block_info *next;
 };

 static struct {
 	spinlock_t lock;
 	size_t kmalloc_blocks;
 	size_t kmalloc_bytes;
 	size_t vmalloc_blocks;
 	size_t vmalloc_bytes;
 	size_t peak_bytes;
 	struct vmalloc_block_info *vmalloc_list;
 } memory_stats __cacheline_aligned;

 static void update_peak_usage(void)
 {
 	size_t total_bytes = memory_stats.kmalloc_bytes + memory_stats.vmalloc_bytes;

 	if (total_bytes > memory_stats.peak_bytes)
 		memory_stats.peak_bytes = total_bytes;
 }

 static void add_kmalloc_block(size_t size)
 {
 	unsigned long flags;

 	spin_lock_irqsave(&memory_stats.lock, flags);
 	memory_stats.kmalloc_blocks++;
 	memory_stats.kmalloc_bytes += size;
 	update_peak_usage();
 	spin_unlock_irqrestore(&memory_stats.lock, flags);
 }

 static void remove_kmalloc_block(size_t size)
 {
 	unsigned long flags;

 	spin_lock_irqsave(&memory_stats.lock, flags);
 	memory_stats.kmalloc_blocks--;
 	memory_stats.kmalloc_bytes -= size;
 	spin_unlock_irqrestore(&memory_stats.lock, flags);
 }

 static void add_vmalloc_block(struct vmalloc_block_info *block)
 {
 	unsigned long flags;

 	spin_lock_irqsave(&memory_stats.lock, flags);
 	block->next = memory_stats.vmalloc_list;
 	memory_stats.vmalloc_list = block;
 	memory_stats.vmalloc_blocks++;
 	memory_stats.vmalloc_bytes += block->size;
 	update_peak_usage();
 	spin_unlock_irqrestore(&memory_stats.lock, flags);
 }

 static void remove_vmalloc_block(void *ptr)
 {
 	struct vmalloc_block_info *block;
 	struct vmalloc_block_info **block_ptr;
 	unsigned long flags;

 	spin_lock_irqsave(&memory_stats.lock, flags);
 	for (block_ptr = &memory_stats.vmalloc_list;
 	     (block = *block_ptr) != NULL;
 	     block_ptr = &block->next) {
 		if (block->ptr == ptr) {
 			*block_ptr = block->next;
 			memory_stats.vmalloc_blocks--;
 			memory_stats.vmalloc_bytes -= block->size;
 			break;
 		}
 	}

 	spin_unlock_irqrestore(&memory_stats.lock, flags);
 	if (block != NULL)
 		vdo_free(block);
 	else
 		vdo_log_info("attempting to remove ptr %px not found in vmalloc list", ptr);
 }

 /*
  * Determine whether allocating a memory block should use kmalloc or __vmalloc.
  *
  * vmalloc can allocate any integral number of pages.
  *
  * kmalloc can allocate any number of bytes up to a configured limit, which defaults to 8 megabytes
  * on some systems. kmalloc is especially good when memory is being both allocated and freed, and
  * it does this efficiently in a multi CPU environment.
  *
  * kmalloc usually rounds the size of the block up to the next power of two, so when the requested
  * block is bigger than PAGE_SIZE / 2 bytes, kmalloc will never give you less space than the
  * corresponding vmalloc allocation. Sometimes vmalloc will use less overhead than kmalloc.
  *
  * The advantages of kmalloc do not help out UDS or VDO, because we allocate all our memory up
  * front and do not free and reallocate it. Sometimes we have problems using kmalloc, because the
  * Linux memory page map can become so fragmented that kmalloc will not give us a 32KB chunk. We
  * have used vmalloc as a backup to kmalloc in the past, and a follow-up vmalloc of 32KB will work.
  * But there is no strong case to be made for using kmalloc over vmalloc for these size chunks.
  *
  * The kmalloc/vmalloc boundary is set at 4KB, and kmalloc gets the 4KB requests. There is no
  * strong reason for favoring either kmalloc or vmalloc for 4KB requests, except that tracking
  * vmalloc statistics uses a linked list implementation. Using a simple test, this choice of
  * boundary results in 132 vmalloc calls. Using vmalloc for requests of exactly 4KB results in an
  * additional 6374 vmalloc calls, which is much less efficient for tracking.
  *
  * @size: How many bytes to allocate
  */
 static inline bool use_kmalloc(size_t size)
 {
 	return size <= PAGE_SIZE;
 }

 /*
  * Allocate storage based on memory size and alignment, logging an error if the allocation fails.
  * The memory will be zeroed.
  *
  * @size: The size of an object
  * @align: The required alignment
  * @what: What is being allocated (for error logging)
  * @ptr: A pointer to hold the allocated memory
  *
  * Return: VDO_SUCCESS or an error code
  */
 int vdo_allocate_memory(size_t size, size_t align, const char *what, void *ptr)
 {
 	/*
 	 * The __GFP_RETRY_MAYFAIL flag means the VM implementation will retry memory reclaim
 	 * procedures that have previously failed if there is some indication that progress has
 	 * been made elsewhere. It can wait for other tasks to attempt high level approaches to
 	 * freeing memory such as compaction (which removes fragmentation) and page-out. There is
 	 * still a definite limit to the number of retries, but it is a larger limit than with
 	 * __GFP_NORETRY. Allocations with this flag may fail, but only when there is genuinely
 	 * little unused memory. While these allocations do not directly trigger the OOM killer,
 	 * their failure indicates that the system is likely to need to use the OOM killer soon.
 	 * The caller must handle failure, but can reasonably do so by failing a higher-level
 	 * request, or completing it only in a much less efficient manner.
 	 */
 	const gfp_t gfp_flags = GFP_KERNEL | __GFP_ZERO | __GFP_RETRY_MAYFAIL;
 	unsigned int noio_flags;
 	bool allocations_restricted = !allocations_allowed();
 	unsigned long start_time;
 	void *p = NULL;

 	if (unlikely(ptr == NULL))
 		return -EINVAL;

 	if (size == 0) {
 		*((void **) ptr) = NULL;
 		return VDO_SUCCESS;
 	}

 	if (allocations_restricted)
 		noio_flags = memalloc_noio_save();

 	start_time = jiffies;
 	if (use_kmalloc(size) && (align < PAGE_SIZE)) {
 		p = kmalloc(size, gfp_flags | __GFP_NOWARN);
 		if (p == NULL) {
 			/*
 			 * It is possible for kmalloc to fail to allocate memory because there is
 			 * no page available. A short sleep may allow the page reclaimer to
 			 * free a page.
 			 */
 			fsleep(1000);
 			p = kmalloc(size, gfp_flags);
 		}

 		if (p != NULL)
 			add_kmalloc_block(ksize(p));
 	} else {
 		struct vmalloc_block_info *block;

 		if (vdo_allocate(1, struct vmalloc_block_info, __func__, &block) == VDO_SUCCESS) {
 			/*
 			 * It is possible for __vmalloc to fail to allocate memory because there
 			 * are no pages available. A short sleep may allow the page reclaimer
 			 * to free enough pages for a small allocation.
 			 *
 			 * For larger allocations, the page_alloc code is racing against the page
 			 * reclaimer. If the page reclaimer can stay ahead of page_alloc, the
 			 * __vmalloc will succeed. But if page_alloc overtakes the page reclaimer,
 			 * the allocation fails. It is possible that more retries will succeed.
 			 */
 			for (;;) {
 				p = __vmalloc(size, gfp_flags | __GFP_NOWARN);
 				if (p != NULL)
 					break;

 				if (jiffies_to_msecs(jiffies - start_time) > 1000) {
 					/* Try one more time, logging a failure for this call. */
 					p = __vmalloc(size, gfp_flags);
 					break;
 				}

 				fsleep(1000);
 			}

 			if (p == NULL) {
 				vdo_free(block);
 			} else {
 				block->ptr = p;
 				block->size = PAGE_ALIGN(size);
 				add_vmalloc_block(block);
 			}
 		}
 	}

 	if (allocations_restricted)
 		memalloc_noio_restore(noio_flags);

 	if (unlikely(p == NULL)) {
 		vdo_log_error("Could not allocate %zu bytes for %s in %u msecs",
 			      size, what, jiffies_to_msecs(jiffies - start_time));
 		return -ENOMEM;
 	}

 	*((void **) ptr) = p;
 	return VDO_SUCCESS;
 }

 /*
  * Allocate storage based on memory size, failing immediately if the required memory is not
  * available. The memory will be zeroed.
  *
  * @size: The size of an object.
  * @what: What is being allocated (for error logging)
  *
  * Return: pointer to the allocated memory, or NULL if the required space is not available.
  */
 void *vdo_allocate_memory_nowait(size_t size, const char *what __maybe_unused)
 {
 	void *p = kmalloc(size, GFP_NOWAIT | __GFP_ZERO);

 	if (p != NULL)
 		add_kmalloc_block(ksize(p));

 	return p;
 }

 void vdo_free(void *ptr)
 {
 	if (ptr != NULL) {
 		if (is_vmalloc_addr(ptr)) {
 			remove_vmalloc_block(ptr);
 			vfree(ptr);
 		} else {
 			remove_kmalloc_block(ksize(ptr));
 			kfree(ptr);
 		}
 	}
 }

 /*
  * Reallocate dynamically allocated memory. There are no alignment guarantees for the reallocated
  * memory. If the new memory is larger than the old memory, the new space will be zeroed.
  *
  * @ptr: The memory to reallocate.
  * @old_size: The old size of the memory
  * @size: The new size to allocate
  * @what: What is being allocated (for error logging)
  * @new_ptr: A pointer to hold the reallocated pointer
  *
  * Return: VDO_SUCCESS or an error code
  */
 int vdo_reallocate_memory(void *ptr, size_t old_size, size_t size, const char *what,
 			  void *new_ptr)
 {
 	int result;

 	if (size == 0) {
 		vdo_free(ptr);
 		*(void **) new_ptr = NULL;
 		return VDO_SUCCESS;
 	}

 	result = vdo_allocate(size, char, what, new_ptr);
 	if (result != VDO_SUCCESS)
 		return result;

 	if (ptr != NULL) {
 		if (old_size < size)
 			size = old_size;

 		memcpy(*((void **) new_ptr), ptr, size);
 		vdo_free(ptr);
 	}

 	return VDO_SUCCESS;
 }

 int vdo_duplicate_string(const char *string, const char *what, char **new_string)
 {
 	int result;
 	u8 *dup;

 	result = vdo_allocate(strlen(string) + 1, u8, what, &dup);
 	if (result != VDO_SUCCESS)
 		return result;

 	memcpy(dup, string, strlen(string) + 1);
 	*new_string = dup;
 	return VDO_SUCCESS;
 }

 void vdo_memory_init(void)
 {
 	spin_lock_init(&memory_stats.lock);
 	vdo_initialize_thread_registry(&allocating_threads);
 }

 void vdo_memory_exit(void)
 {
 	VDO_ASSERT_LOG_ONLY(memory_stats.kmalloc_bytes == 0,
 			    "kmalloc memory used (%zd bytes in %zd blocks) is returned to the kernel",
 			    memory_stats.kmalloc_bytes, memory_stats.kmalloc_blocks);
 	VDO_ASSERT_LOG_ONLY(memory_stats.vmalloc_bytes == 0,
 			    "vmalloc memory used (%zd bytes in %zd blocks) is returned to the kernel",
 			    memory_stats.vmalloc_bytes, memory_stats.vmalloc_blocks);
 	vdo_log_debug("peak usage %zd bytes", memory_stats.peak_bytes);
 }

 void vdo_get_memory_stats(u64 *bytes_used, u64 *peak_bytes_used)
 {
 	unsigned long flags;

 	spin_lock_irqsave(&memory_stats.lock, flags);
 	*bytes_used = memory_stats.kmalloc_bytes + memory_stats.vmalloc_bytes;
 	*peak_bytes_used = memory_stats.peak_bytes;
 	spin_unlock_irqrestore(&memory_stats.lock, flags);
 }

 /*
  * Report stats on any allocated memory that we're tracking. Not all allocation types are
  * guaranteed to be tracked in bytes (e.g., bios).
  */
 void vdo_report_memory_usage(void)
 {
 	unsigned long flags;
 	u64 kmalloc_blocks;
 	u64 kmalloc_bytes;
 	u64 vmalloc_blocks;
 	u64 vmalloc_bytes;
 	u64 peak_usage;
 	u64 total_bytes;

 	spin_lock_irqsave(&memory_stats.lock, flags);
 	kmalloc_blocks = memory_stats.kmalloc_blocks;
 	kmalloc_bytes = memory_stats.kmalloc_bytes;
 	vmalloc_blocks = memory_stats.vmalloc_blocks;
 	vmalloc_bytes = memory_stats.vmalloc_bytes;
 	peak_usage = memory_stats.peak_bytes;
 	spin_unlock_irqrestore(&memory_stats.lock, flags);
 	total_bytes = kmalloc_bytes + vmalloc_bytes;
 	vdo_log_info("current module memory tracking (actual allocation sizes, not requested):");
 	vdo_log_info("  %llu bytes in %llu kmalloc blocks",
 		     (unsigned long long) kmalloc_bytes,
 		     (unsigned long long) kmalloc_blocks);
 	vdo_log_info("  %llu bytes in %llu vmalloc blocks",
 		     (unsigned long long) vmalloc_bytes,
 		     (unsigned long long) vmalloc_blocks);
 	vdo_log_info("  total %llu bytes, peak usage %llu bytes",
 		     (unsigned long long) total_bytes, (unsigned long long) peak_usage);
 }
	// SPDX-License-Identifier: GPL-2.0-only
	/*
	* Copyright 2023 Red Hat
	*/

	#include <linux/delay.h>
	#include <linux/mm.h>
	#include <linux/sched/mm.h>
	#include <linux/slab.h>
	#include <linux/vmalloc.h>

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

	/*
	* UDS and VDO keep track of which threads are allowed to allocate memory freely, and which threads
	* must be careful to not do a memory allocation that does an I/O request. The 'allocating_threads'
	* thread_registry and its associated methods implement this tracking.
	*/
	static struct thread_registry allocating_threads;

	static inline bool allocations_allowed(void)
	{
	return vdo_lookup_thread(&allocating_threads) != NULL;
	}

	/*
	* Register the current thread as an allocating thread.
	*
	* An optional flag location can be supplied indicating whether, at any given point in time, the
	* threads associated with that flag should be allocating storage. If the flag is false, a message
	* will be logged.
	*
	* If no flag is supplied, the thread is always allowed to allocate storage without complaint.
	*
	* @new_thread: registered_thread structure to use for the current thread
	* @flag_ptr: Location of the allocation-allowed flag
	*/
	void vdo_register_allocating_thread(struct registered_thread *new_thread,
	const bool *flag_ptr)
	{
	if (flag_ptr == NULL) {
	static const bool allocation_always_allowed = true;

	flag_ptr = &allocation_always_allowed;
	}

	vdo_register_thread(&allocating_threads, new_thread, flag_ptr);
	}

	/* Unregister the current thread as an allocating thread. */
	void vdo_unregister_allocating_thread(void)
	{
	vdo_unregister_thread(&allocating_threads);
	}

	/*
	* We track how much memory has been allocated and freed. When we unload the module, we log an
	* error if we have not freed all the memory that we allocated. Nearly all memory allocation and
	* freeing is done using this module.
	*
	* We do not use kernel functions like the kvasprintf() method, which allocate memory indirectly
	* using kmalloc.
	*
	* These data structures and methods are used to track the amount of memory used.
	*/

	/*
	* We allocate very few large objects, and allocation/deallocation isn't done in a
	* performance-critical stage for us, so a linked list should be fine.
	*/
	struct vmalloc_block_info {
	void *ptr;
	size_t size;
	struct vmalloc_block_info *next;
	};

	static struct {
	spinlock_t lock;
	size_t kmalloc_blocks;
	size_t kmalloc_bytes;
	size_t vmalloc_blocks;
	size_t vmalloc_bytes;
	size_t peak_bytes;
	struct vmalloc_block_info *vmalloc_list;
	} memory_stats __cacheline_aligned;

	static void update_peak_usage(void)
	{
	size_t total_bytes = memory_stats.kmalloc_bytes + memory_stats.vmalloc_bytes;

	if (total_bytes > memory_stats.peak_bytes)
	memory_stats.peak_bytes = total_bytes;
	}

	static void add_kmalloc_block(size_t size)
	{
	unsigned long flags;

	spin_lock_irqsave(&memory_stats.lock, flags);
	memory_stats.kmalloc_blocks++;
	memory_stats.kmalloc_bytes += size;
	update_peak_usage();
	spin_unlock_irqrestore(&memory_stats.lock, flags);
	}

	static void remove_kmalloc_block(size_t size)
	{
	unsigned long flags;

	spin_lock_irqsave(&memory_stats.lock, flags);
	memory_stats.kmalloc_blocks--;
	memory_stats.kmalloc_bytes -= size;
	spin_unlock_irqrestore(&memory_stats.lock, flags);
	}

	static void add_vmalloc_block(struct vmalloc_block_info *block)
	{
	unsigned long flags;

	spin_lock_irqsave(&memory_stats.lock, flags);
	block->next = memory_stats.vmalloc_list;
	memory_stats.vmalloc_list = block;
	memory_stats.vmalloc_blocks++;
	memory_stats.vmalloc_bytes += block->size;
	update_peak_usage();
	spin_unlock_irqrestore(&memory_stats.lock, flags);
	}

	static void remove_vmalloc_block(void *ptr)
	{
	struct vmalloc_block_info *block;
	struct vmalloc_block_info **block_ptr;
	unsigned long flags;

	spin_lock_irqsave(&memory_stats.lock, flags);
	for (block_ptr = &memory_stats.vmalloc_list;
	(block = *block_ptr) != NULL;
	block_ptr = &block->next) {
	if (block->ptr == ptr) {
	*block_ptr = block->next;
	memory_stats.vmalloc_blocks--;
	memory_stats.vmalloc_bytes -= block->size;
	break;
	}
	}

	spin_unlock_irqrestore(&memory_stats.lock, flags);
	if (block != NULL)
	vdo_free(block);
	else
	vdo_log_info("attempting to remove ptr %px not found in vmalloc list", ptr);
	}

	/*
	* Determine whether allocating a memory block should use kmalloc or __vmalloc.
	*
	* vmalloc can allocate any integral number of pages.
	*
	* kmalloc can allocate any number of bytes up to a configured limit, which defaults to 8 megabytes
	* on some systems. kmalloc is especially good when memory is being both allocated and freed, and
	* it does this efficiently in a multi CPU environment.
	*
	* kmalloc usually rounds the size of the block up to the next power of two, so when the requested
	* block is bigger than PAGE_SIZE / 2 bytes, kmalloc will never give you less space than the
	* corresponding vmalloc allocation. Sometimes vmalloc will use less overhead than kmalloc.
	*
	* The advantages of kmalloc do not help out UDS or VDO, because we allocate all our memory up
	* front and do not free and reallocate it. Sometimes we have problems using kmalloc, because the
	* Linux memory page map can become so fragmented that kmalloc will not give us a 32KB chunk. We
	* have used vmalloc as a backup to kmalloc in the past, and a follow-up vmalloc of 32KB will work.
	* But there is no strong case to be made for using kmalloc over vmalloc for these size chunks.
	*
	* The kmalloc/vmalloc boundary is set at 4KB, and kmalloc gets the 4KB requests. There is no
	* strong reason for favoring either kmalloc or vmalloc for 4KB requests, except that tracking
	* vmalloc statistics uses a linked list implementation. Using a simple test, this choice of
	* boundary results in 132 vmalloc calls. Using vmalloc for requests of exactly 4KB results in an
	* additional 6374 vmalloc calls, which is much less efficient for tracking.
	*
	* @size: How many bytes to allocate
	*/
	static inline bool use_kmalloc(size_t size)
	{
	return size <= PAGE_SIZE;
	}

	/*
	* Allocate storage based on memory size and alignment, logging an error if the allocation fails.
	* The memory will be zeroed.
	*
	* @size: The size of an object
	* @align: The required alignment
	* @what: What is being allocated (for error logging)
	* @ptr: A pointer to hold the allocated memory
	*
	* Return: VDO_SUCCESS or an error code
	*/
	int vdo_allocate_memory(size_t size, size_t align, const char what, void ptr)
	{
	/*
	* The __GFP_RETRY_MAYFAIL flag means the VM implementation will retry memory reclaim
	* procedures that have previously failed if there is some indication that progress has
	* been made elsewhere. It can wait for other tasks to attempt high level approaches to
	* freeing memory such as compaction (which removes fragmentation) and page-out. There is
	* still a definite limit to the number of retries, but it is a larger limit than with
	* __GFP_NORETRY. Allocations with this flag may fail, but only when there is genuinely
	* little unused memory. While these allocations do not directly trigger the OOM killer,
	* their failure indicates that the system is likely to need to use the OOM killer soon.
	* The caller must handle failure, but can reasonably do so by failing a higher-level
	* request, or completing it only in a much less efficient manner.
	*/
	const gfp_t gfp_flags = GFP_KERNEL \| __GFP_ZERO \| __GFP_RETRY_MAYFAIL;
	unsigned int noio_flags;
	bool allocations_restricted = !allocations_allowed();
	unsigned long start_time;
	void *p = NULL;

	if (unlikely(ptr == NULL))
	return -EINVAL;

	if (size == 0) {
	((void *) ptr) = NULL;
	return VDO_SUCCESS;
	}

	if (allocations_restricted)
	noio_flags = memalloc_noio_save();

	start_time = jiffies;
	if (use_kmalloc(size) && (align < PAGE_SIZE)) {
	p = kmalloc(size, gfp_flags \| __GFP_NOWARN);
	if (p == NULL) {
	/*
	* It is possible for kmalloc to fail to allocate memory because there is
	* no page available. A short sleep may allow the page reclaimer to
	* free a page.
	*/
	fsleep(1000);
	p = kmalloc(size, gfp_flags);
	}

	if (p != NULL)
	add_kmalloc_block(ksize(p));
	} else {
	struct vmalloc_block_info *block;

	if (vdo_allocate(1, struct vmalloc_block_info, __func__, &block) == VDO_SUCCESS) {
	/*
	* It is possible for __vmalloc to fail to allocate memory because there
	* are no pages available. A short sleep may allow the page reclaimer
	* to free enough pages for a small allocation.
	*
	* For larger allocations, the page_alloc code is racing against the page
	* reclaimer. If the page reclaimer can stay ahead of page_alloc, the
	* __vmalloc will succeed. But if page_alloc overtakes the page reclaimer,
	* the allocation fails. It is possible that more retries will succeed.
	*/
	for (;;) {
	p = __vmalloc(size, gfp_flags \| __GFP_NOWARN);
	if (p != NULL)
	break;

	if (jiffies_to_msecs(jiffies - start_time) > 1000) {
	/* Try one more time, logging a failure for this call. */
	p = __vmalloc(size, gfp_flags);
	break;
	}

	fsleep(1000);
	}

	if (p == NULL) {
	vdo_free(block);
	} else {
	block->ptr = p;
	block->size = PAGE_ALIGN(size);
	add_vmalloc_block(block);
	}
	}
	}

	if (allocations_restricted)
	memalloc_noio_restore(noio_flags);

	if (unlikely(p == NULL)) {
	vdo_log_error("Could not allocate %zu bytes for %s in %u msecs",
	size, what, jiffies_to_msecs(jiffies - start_time));
	return -ENOMEM;
	}

	((void *) ptr) = p;
	return VDO_SUCCESS;
	}

	/*
	* Allocate storage based on memory size, failing immediately if the required memory is not
	* available. The memory will be zeroed.
	*
	* @size: The size of an object.
	* @what: What is being allocated (for error logging)
	*
	* Return: pointer to the allocated memory, or NULL if the required space is not available.
	*/
	void vdo_allocate_memory_nowait(size_t size, const char what __maybe_unused)
	{
	void *p = kmalloc(size, GFP_NOWAIT \| __GFP_ZERO);

	if (p != NULL)
	add_kmalloc_block(ksize(p));

	return p;
	}

	void vdo_free(void *ptr)
	{
	if (ptr != NULL) {
	if (is_vmalloc_addr(ptr)) {
	remove_vmalloc_block(ptr);
	vfree(ptr);
	} else {
	remove_kmalloc_block(ksize(ptr));
	kfree(ptr);
	}
	}
	}

	/*
	* Reallocate dynamically allocated memory. There are no alignment guarantees for the reallocated
	* memory. If the new memory is larger than the old memory, the new space will be zeroed.
	*
	* @ptr: The memory to reallocate.
	* @old_size: The old size of the memory
	* @size: The new size to allocate
	* @what: What is being allocated (for error logging)
	* @new_ptr: A pointer to hold the reallocated pointer
	*
	* Return: VDO_SUCCESS or an error code
	*/
	int vdo_reallocate_memory(void ptr, size_t old_size, size_t size, const char what,
	void *new_ptr)
	{
	int result;

	if (size == 0) {
	vdo_free(ptr);
	(void *) new_ptr = NULL;
	return VDO_SUCCESS;
	}

	result = vdo_allocate(size, char, what, new_ptr);
	if (result != VDO_SUCCESS)
	return result;

	if (ptr != NULL) {
	if (old_size < size)
	size = old_size;

	memcpy(((void *) new_ptr), ptr, size);
	vdo_free(ptr);
	}

	return VDO_SUCCESS;
	}

	int vdo_duplicate_string(const char string, const char what, char **new_string)
	{
	int result;
	u8 *dup;

	result = vdo_allocate(strlen(string) + 1, u8, what, &dup);
	if (result != VDO_SUCCESS)
	return result;

	memcpy(dup, string, strlen(string) + 1);
	*new_string = dup;
	return VDO_SUCCESS;
	}

	void vdo_memory_init(void)
	{
	spin_lock_init(&memory_stats.lock);
	vdo_initialize_thread_registry(&allocating_threads);
	}

	void vdo_memory_exit(void)
	{
	VDO_ASSERT_LOG_ONLY(memory_stats.kmalloc_bytes == 0,
	"kmalloc memory used (%zd bytes in %zd blocks) is returned to the kernel",
	memory_stats.kmalloc_bytes, memory_stats.kmalloc_blocks);
	VDO_ASSERT_LOG_ONLY(memory_stats.vmalloc_bytes == 0,
	"vmalloc memory used (%zd bytes in %zd blocks) is returned to the kernel",
	memory_stats.vmalloc_bytes, memory_stats.vmalloc_blocks);
	vdo_log_debug("peak usage %zd bytes", memory_stats.peak_bytes);
	}

	void vdo_get_memory_stats(u64 bytes_used, u64 peak_bytes_used)
	{
	unsigned long flags;

	spin_lock_irqsave(&memory_stats.lock, flags);
	*bytes_used = memory_stats.kmalloc_bytes + memory_stats.vmalloc_bytes;
	*peak_bytes_used = memory_stats.peak_bytes;
	spin_unlock_irqrestore(&memory_stats.lock, flags);
	}

	/*
	* Report stats on any allocated memory that we're tracking. Not all allocation types are
	* guaranteed to be tracked in bytes (e.g., bios).
	*/
	void vdo_report_memory_usage(void)
	{
	unsigned long flags;
	u64 kmalloc_blocks;
	u64 kmalloc_bytes;
	u64 vmalloc_blocks;
	u64 vmalloc_bytes;
	u64 peak_usage;
	u64 total_bytes;

	spin_lock_irqsave(&memory_stats.lock, flags);
	kmalloc_blocks = memory_stats.kmalloc_blocks;
	kmalloc_bytes = memory_stats.kmalloc_bytes;
	vmalloc_blocks = memory_stats.vmalloc_blocks;
	vmalloc_bytes = memory_stats.vmalloc_bytes;
	peak_usage = memory_stats.peak_bytes;
	spin_unlock_irqrestore(&memory_stats.lock, flags);
	total_bytes = kmalloc_bytes + vmalloc_bytes;
	vdo_log_info("current module memory tracking (actual allocation sizes, not requested):");
	vdo_log_info(" %llu bytes in %llu kmalloc blocks",
	(unsigned long long) kmalloc_bytes,
	(unsigned long long) kmalloc_blocks);
	vdo_log_info(" %llu bytes in %llu vmalloc blocks",
	(unsigned long long) vmalloc_bytes,
	(unsigned long long) vmalloc_blocks);
	vdo_log_info(" total %llu bytes, peak usage %llu bytes",
	(unsigned long long) total_bytes, (unsigned long long) peak_usage);
	}