fs/verity/verify.c - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /*
  * Data verification functions, i.e. hooks for ->readahead()
  *
  * Copyright 2019 Google LLC
  */

 #include "fsverity_private.h"

 #include <crypto/hash.h>
 #include <linux/bio.h>

 static struct workqueue_struct *fsverity_read_workqueue;

 /*
  * Returns true if the hash block with index @hblock_idx in the tree, located in
  * @hpage, has already been verified.
  */
 static bool is_hash_block_verified(struct fsverity_info *vi, struct page *hpage,
 				   unsigned long hblock_idx)
 {
 	bool verified;
 	unsigned int blocks_per_page;
 	unsigned int i;

 	/*
 	 * When the Merkle tree block size and page size are the same, then the
 	 * ->hash_block_verified bitmap isn't allocated, and we use PG_checked
 	 * to directly indicate whether the page's block has been verified.
 	 *
 	 * Using PG_checked also guarantees that we re-verify hash pages that
 	 * get evicted and re-instantiated from the backing storage, as new
 	 * pages always start out with PG_checked cleared.
 	 */
 	if (!vi->hash_block_verified)
 		return PageChecked(hpage);

 	/*
 	 * When the Merkle tree block size and page size differ, we use a bitmap
 	 * to indicate whether each hash block has been verified.
 	 *
 	 * However, we still need to ensure that hash pages that get evicted and
 	 * re-instantiated from the backing storage are re-verified.  To do
 	 * this, we use PG_checked again, but now it doesn't really mean
 	 * "checked".  Instead, now it just serves as an indicator for whether
 	 * the hash page is newly instantiated or not.
 	 *
 	 * The first thread that sees PG_checked=0 must clear the corresponding
 	 * bitmap bits, then set PG_checked=1.  This requires a spinlock.  To
 	 * avoid having to take this spinlock in the common case of
 	 * PG_checked=1, we start with an opportunistic lockless read.
 	 */
 	if (PageChecked(hpage)) {
 		/*
 		 * A read memory barrier is needed here to give ACQUIRE
 		 * semantics to the above PageChecked() test.
 		 */
 		smp_rmb();
 		return test_bit(hblock_idx, vi->hash_block_verified);
 	}
 	spin_lock(&vi->hash_page_init_lock);
 	if (PageChecked(hpage)) {
 		verified = test_bit(hblock_idx, vi->hash_block_verified);
 	} else {
 		blocks_per_page = vi->tree_params.blocks_per_page;
 		hblock_idx = round_down(hblock_idx, blocks_per_page);
 		for (i = 0; i < blocks_per_page; i++)
 			clear_bit(hblock_idx + i, vi->hash_block_verified);
 		/*
 		 * A write memory barrier is needed here to give RELEASE
 		 * semantics to the below SetPageChecked() operation.
 		 */
 		smp_wmb();
 		SetPageChecked(hpage);
 		verified = false;
 	}
 	spin_unlock(&vi->hash_page_init_lock);
 	return verified;
 }

 /*
  * Verify a single data block against the file's Merkle tree.
  *
  * In principle, we need to verify the entire path to the root node.  However,
  * for efficiency the filesystem may cache the hash blocks.  Therefore we need
  * only ascend the tree until an already-verified hash block is seen, and then
  * verify the path to that block.
  *
  * Return: %true if the data block is valid, else %false.
  */
 static bool
 verify_data_block(struct inode *inode, struct fsverity_info *vi,
 		  const void *data, u64 data_pos, unsigned long max_ra_pages)
 {
 	const struct merkle_tree_params *params = &vi->tree_params;
 	const unsigned int hsize = params->digest_size;
 	int level;
 	u8 _want_hash[FS_VERITY_MAX_DIGEST_SIZE];
 	const u8 *want_hash;
 	u8 real_hash[FS_VERITY_MAX_DIGEST_SIZE];
 	/* The hash blocks that are traversed, indexed by level */
 	struct {
 		/* Page containing the hash block */
 		struct page *page;
 		/* Mapped address of the hash block (will be within @page) */
 		const void *addr;
 		/* Index of the hash block in the tree overall */
 		unsigned long index;
 		/* Byte offset of the wanted hash relative to @addr */
 		unsigned int hoffset;
 	} hblocks[FS_VERITY_MAX_LEVELS];
 	/*
 	 * The index of the previous level's block within that level; also the
 	 * index of that block's hash within the current level.
 	 */
 	u64 hidx = data_pos >> params->log_blocksize;

 	/* Up to 1 + FS_VERITY_MAX_LEVELS pages may be mapped at once */
 	BUILD_BUG_ON(1 + FS_VERITY_MAX_LEVELS > KM_MAX_IDX);

 	if (unlikely(data_pos >= inode->i_size)) {
 		/*
 		 * This can happen in the data page spanning EOF when the Merkle
 		 * tree block size is less than the page size.  The Merkle tree
 		 * doesn't cover data blocks fully past EOF.  But the entire
 		 * page spanning EOF can be visible to userspace via a mmap, and
 		 * any part past EOF should be all zeroes.  Therefore, we need
 		 * to verify that any data blocks fully past EOF are all zeroes.
 		 */
 		if (memchr_inv(data, 0, params->block_size)) {
 			fsverity_err(inode,
 				     "FILE CORRUPTED!  Data past EOF is not zeroed");
 			return false;
 		}
 		return true;
 	}

 	/*
 	 * Starting at the leaf level, ascend the tree saving hash blocks along
 	 * the way until we find a hash block that has already been verified, or
 	 * until we reach the root.
 	 */
 	for (level = 0; level < params->num_levels; level++) {
 		unsigned long next_hidx;
 		unsigned long hblock_idx;
 		pgoff_t hpage_idx;
 		unsigned int hblock_offset_in_page;
 		unsigned int hoffset;
 		struct page *hpage;
 		const void *haddr;

 		/*
 		 * The index of the block in the current level; also the index
 		 * of that block's hash within the next level.
 		 */
 		next_hidx = hidx >> params->log_arity;

 		/* Index of the hash block in the tree overall */
 		hblock_idx = params->level_start[level] + next_hidx;

 		/* Index of the hash page in the tree overall */
 		hpage_idx = hblock_idx >> params->log_blocks_per_page;

 		/* Byte offset of the hash block within the page */
 		hblock_offset_in_page =
 			(hblock_idx << params->log_blocksize) & ~PAGE_MASK;

 		/* Byte offset of the hash within the block */
 		hoffset = (hidx << params->log_digestsize) &
 			  (params->block_size - 1);

 		hpage = inode->i_sb->s_vop->read_merkle_tree_page(inode,
 				hpage_idx, level == 0 ? min(max_ra_pages,
 					params->tree_pages - hpage_idx) : 0);
 		if (IS_ERR(hpage)) {
 			fsverity_err(inode,
 				     "Error %ld reading Merkle tree page %lu",
 				     PTR_ERR(hpage), hpage_idx);
 			goto error;
 		}
 		haddr = kmap_local_page(hpage) + hblock_offset_in_page;
 		if (is_hash_block_verified(vi, hpage, hblock_idx)) {
 			memcpy(_want_hash, haddr + hoffset, hsize);
 			want_hash = _want_hash;
 			kunmap_local(haddr);
 			put_page(hpage);
 			goto descend;
 		}
 		hblocks[level].page = hpage;
 		hblocks[level].addr = haddr;
 		hblocks[level].index = hblock_idx;
 		hblocks[level].hoffset = hoffset;
 		hidx = next_hidx;
 	}

 	want_hash = vi->root_hash;
 descend:
 	/* Descend the tree verifying hash blocks. */
 	for (; level > 0; level--) {
 		struct page *hpage = hblocks[level - 1].page;
 		const void *haddr = hblocks[level - 1].addr;
 		unsigned long hblock_idx = hblocks[level - 1].index;
 		unsigned int hoffset = hblocks[level - 1].hoffset;

 		if (fsverity_hash_block(params, inode, haddr, real_hash) != 0)
 			goto error;
 		if (memcmp(want_hash, real_hash, hsize) != 0)
 			goto corrupted;
 		/*
 		 * Mark the hash block as verified.  This must be atomic and
 		 * idempotent, as the same hash block might be verified by
 		 * multiple threads concurrently.
 		 */
 		if (vi->hash_block_verified)
 			set_bit(hblock_idx, vi->hash_block_verified);
 		else
 			SetPageChecked(hpage);
 		memcpy(_want_hash, haddr + hoffset, hsize);
 		want_hash = _want_hash;
 		kunmap_local(haddr);
 		put_page(hpage);
 	}

 	/* Finally, verify the data block. */
 	if (fsverity_hash_block(params, inode, data, real_hash) != 0)
 		goto error;
 	if (memcmp(want_hash, real_hash, hsize) != 0)
 		goto corrupted;
 	return true;

 corrupted:
 	fsverity_err(inode,
 		     "FILE CORRUPTED! pos=%llu, level=%d, want_hash=%s:%*phN, real_hash=%s:%*phN",
 		     data_pos, level - 1,
 		     params->hash_alg->name, hsize, want_hash,
 		     params->hash_alg->name, hsize, real_hash);
 error:
 	for (; level > 0; level--) {
 		kunmap_local(hblocks[level - 1].addr);
 		put_page(hblocks[level - 1].page);
 	}
 	return false;
 }

 static bool
 verify_data_blocks(struct folio *data_folio, size_t len, size_t offset,
 		   unsigned long max_ra_pages)
 {
 	struct inode *inode = data_folio->mapping->host;
 	struct fsverity_info *vi = inode->i_verity_info;
 	const unsigned int block_size = vi->tree_params.block_size;
 	u64 pos = (u64)data_folio->index << PAGE_SHIFT;

 	if (WARN_ON_ONCE(len <= 0 || !IS_ALIGNED(len | offset, block_size)))
 		return false;
 	if (WARN_ON_ONCE(!folio_test_locked(data_folio) ||
 			 folio_test_uptodate(data_folio)))
 		return false;
 	do {
 		void *data;
 		bool valid;

 		data = kmap_local_folio(data_folio, offset);
 		valid = verify_data_block(inode, vi, data, pos + offset,
 					  max_ra_pages);
 		kunmap_local(data);
 		if (!valid)
 			return false;
 		offset += block_size;
 		len -= block_size;
 	} while (len);
 	return true;
 }

 /**
  * fsverity_verify_blocks() - verify data in a folio
  * @folio: the folio containing the data to verify
  * @len: the length of the data to verify in the folio
  * @offset: the offset of the data to verify in the folio
  *
  * Verify data that has just been read from a verity file.  The data must be
  * located in a pagecache folio that is still locked and not yet uptodate.  The
  * length and offset of the data must be Merkle tree block size aligned.
  *
  * Return: %true if the data is valid, else %false.
  */
 bool fsverity_verify_blocks(struct folio *folio, size_t len, size_t offset)
 {
 	return verify_data_blocks(folio, len, offset, 0);
 }
 EXPORT_SYMBOL_GPL(fsverity_verify_blocks);

 #ifdef CONFIG_BLOCK
 /**
  * fsverity_verify_bio() - verify a 'read' bio that has just completed
  * @bio: the bio to verify
  *
  * Verify the bio's data against the file's Merkle tree.  All bio data segments
  * must be aligned to the file's Merkle tree block size.  If any data fails
  * verification, then bio->bi_status is set to an error status.
  *
  * This is a helper function for use by the ->readahead() method of filesystems
  * that issue bios to read data directly into the page cache.  Filesystems that
  * populate the page cache without issuing bios (e.g. non block-based
  * filesystems) must instead call fsverity_verify_page() directly on each page.
  * All filesystems must also call fsverity_verify_page() on holes.
  */
 void fsverity_verify_bio(struct bio *bio)
 {
 	struct folio_iter fi;
 	unsigned long max_ra_pages = 0;

 	if (bio->bi_opf & REQ_RAHEAD) {
 		/*
 		 * If this bio is for data readahead, then we also do readahead
 		 * of the first (largest) level of the Merkle tree.  Namely,
 		 * when a Merkle tree page is read, we also try to piggy-back on
 		 * some additional pages -- up to 1/4 the number of data pages.
 		 *
 		 * This improves sequential read performance, as it greatly
 		 * reduces the number of I/O requests made to the Merkle tree.
 		 */
 		max_ra_pages = bio->bi_iter.bi_size >> (PAGE_SHIFT + 2);
 	}

 	bio_for_each_folio_all(fi, bio) {
 		if (!verify_data_blocks(fi.folio, fi.length, fi.offset,
 					max_ra_pages)) {
 			bio->bi_status = BLK_STS_IOERR;
 			break;
 		}
 	}
 }
 EXPORT_SYMBOL_GPL(fsverity_verify_bio);
 #endif /* CONFIG_BLOCK */

 /**
  * fsverity_enqueue_verify_work() - enqueue work on the fs-verity workqueue
  * @work: the work to enqueue
  *
  * Enqueue verification work for asynchronous processing.
  */
 void fsverity_enqueue_verify_work(struct work_struct *work)
 {
 	queue_work(fsverity_read_workqueue, work);
 }
 EXPORT_SYMBOL_GPL(fsverity_enqueue_verify_work);

 void __init fsverity_init_workqueue(void)
 {
 	/*
 	 * Use a high-priority workqueue to prioritize verification work, which
 	 * blocks reads from completing, over regular application tasks.
 	 *
 	 * For performance reasons, don't use an unbound workqueue.  Using an
 	 * unbound workqueue for crypto operations causes excessive scheduler
 	 * latency on ARM64.
 	 */
 	fsverity_read_workqueue = alloc_workqueue("fsverity_read_queue",
 						  WQ_HIGHPRI,
 						  num_online_cpus());
 	if (!fsverity_read_workqueue)
 		panic("failed to allocate fsverity_read_queue");
 }
	// SPDX-License-Identifier: GPL-2.0
	/*
	* Data verification functions, i.e. hooks for ->readahead()
	*
	* Copyright 2019 Google LLC
	*/

	#include "fsverity_private.h"

	#include <crypto/hash.h>
	#include <linux/bio.h>

	static struct workqueue_struct *fsverity_read_workqueue;

	/*
	* Returns true if the hash block with index @hblock_idx in the tree, located in
	* @hpage, has already been verified.
	*/
	static bool is_hash_block_verified(struct fsverity_info vi, struct page hpage,
	unsigned long hblock_idx)
	{
	bool verified;
	unsigned int blocks_per_page;
	unsigned int i;

	/*
	* When the Merkle tree block size and page size are the same, then the
	* ->hash_block_verified bitmap isn't allocated, and we use PG_checked
	* to directly indicate whether the page's block has been verified.
	*
	* Using PG_checked also guarantees that we re-verify hash pages that
	* get evicted and re-instantiated from the backing storage, as new
	* pages always start out with PG_checked cleared.
	*/
	if (!vi->hash_block_verified)
	return PageChecked(hpage);

	/*
	* When the Merkle tree block size and page size differ, we use a bitmap
	* to indicate whether each hash block has been verified.
	*
	* However, we still need to ensure that hash pages that get evicted and
	* re-instantiated from the backing storage are re-verified. To do
	* this, we use PG_checked again, but now it doesn't really mean
	* "checked". Instead, now it just serves as an indicator for whether
	* the hash page is newly instantiated or not.
	*
	* The first thread that sees PG_checked=0 must clear the corresponding
	* bitmap bits, then set PG_checked=1. This requires a spinlock. To
	* avoid having to take this spinlock in the common case of
	* PG_checked=1, we start with an opportunistic lockless read.
	*/
	if (PageChecked(hpage)) {
	/*
	* A read memory barrier is needed here to give ACQUIRE
	* semantics to the above PageChecked() test.
	*/
	smp_rmb();
	return test_bit(hblock_idx, vi->hash_block_verified);
	}
	spin_lock(&vi->hash_page_init_lock);
	if (PageChecked(hpage)) {
	verified = test_bit(hblock_idx, vi->hash_block_verified);
	} else {
	blocks_per_page = vi->tree_params.blocks_per_page;
	hblock_idx = round_down(hblock_idx, blocks_per_page);
	for (i = 0; i < blocks_per_page; i++)
	clear_bit(hblock_idx + i, vi->hash_block_verified);
	/*
	* A write memory barrier is needed here to give RELEASE
	* semantics to the below SetPageChecked() operation.
	*/
	smp_wmb();
	SetPageChecked(hpage);
	verified = false;
	}
	spin_unlock(&vi->hash_page_init_lock);
	return verified;
	}

	/*
	* Verify a single data block against the file's Merkle tree.
	*
	* In principle, we need to verify the entire path to the root node. However,
	* for efficiency the filesystem may cache the hash blocks. Therefore we need
	* only ascend the tree until an already-verified hash block is seen, and then
	* verify the path to that block.
	*
	* Return: %true if the data block is valid, else %false.
	*/
	static bool
	verify_data_block(struct inode inode, struct fsverity_info vi,
	const void *data, u64 data_pos, unsigned long max_ra_pages)
	{
	const struct merkle_tree_params *params = &vi->tree_params;
	const unsigned int hsize = params->digest_size;
	int level;
	u8 _want_hash[FS_VERITY_MAX_DIGEST_SIZE];
	const u8 *want_hash;
	u8 real_hash[FS_VERITY_MAX_DIGEST_SIZE];
	/* The hash blocks that are traversed, indexed by level */
	struct {
	/* Page containing the hash block */
	struct page *page;
	/* Mapped address of the hash block (will be within @page) */
	const void *addr;
	/* Index of the hash block in the tree overall */
	unsigned long index;
	/* Byte offset of the wanted hash relative to @addr */
	unsigned int hoffset;
	} hblocks[FS_VERITY_MAX_LEVELS];
	/*
	* The index of the previous level's block within that level; also the
	* index of that block's hash within the current level.
	*/
	u64 hidx = data_pos >> params->log_blocksize;

	/* Up to 1 + FS_VERITY_MAX_LEVELS pages may be mapped at once */
	BUILD_BUG_ON(1 + FS_VERITY_MAX_LEVELS > KM_MAX_IDX);

	if (unlikely(data_pos >= inode->i_size)) {
	/*
	* This can happen in the data page spanning EOF when the Merkle
	* tree block size is less than the page size. The Merkle tree
	* doesn't cover data blocks fully past EOF. But the entire
	* page spanning EOF can be visible to userspace via a mmap, and
	* any part past EOF should be all zeroes. Therefore, we need
	* to verify that any data blocks fully past EOF are all zeroes.
	*/
	if (memchr_inv(data, 0, params->block_size)) {
	fsverity_err(inode,
	"FILE CORRUPTED! Data past EOF is not zeroed");
	return false;
	}
	return true;
	}

	/*
	* Starting at the leaf level, ascend the tree saving hash blocks along
	* the way until we find a hash block that has already been verified, or
	* until we reach the root.
	*/
	for (level = 0; level < params->num_levels; level++) {
	unsigned long next_hidx;
	unsigned long hblock_idx;
	pgoff_t hpage_idx;
	unsigned int hblock_offset_in_page;
	unsigned int hoffset;
	struct page *hpage;
	const void *haddr;

	/*
	* The index of the block in the current level; also the index
	* of that block's hash within the next level.
	*/
	next_hidx = hidx >> params->log_arity;

	/* Index of the hash block in the tree overall */
	hblock_idx = params->level_start[level] + next_hidx;

	/* Index of the hash page in the tree overall */
	hpage_idx = hblock_idx >> params->log_blocks_per_page;

	/* Byte offset of the hash block within the page */
	hblock_offset_in_page =
	(hblock_idx << params->log_blocksize) & ~PAGE_MASK;

	/* Byte offset of the hash within the block */
	hoffset = (hidx << params->log_digestsize) &
	(params->block_size - 1);

	hpage = inode->i_sb->s_vop->read_merkle_tree_page(inode,
	hpage_idx, level == 0 ? min(max_ra_pages,
	params->tree_pages - hpage_idx) : 0);
	if (IS_ERR(hpage)) {
	fsverity_err(inode,
	"Error %ld reading Merkle tree page %lu",
	PTR_ERR(hpage), hpage_idx);
	goto error;
	}
	haddr = kmap_local_page(hpage) + hblock_offset_in_page;
	if (is_hash_block_verified(vi, hpage, hblock_idx)) {
	memcpy(_want_hash, haddr + hoffset, hsize);
	want_hash = _want_hash;
	kunmap_local(haddr);
	put_page(hpage);
	goto descend;
	}
	hblocks[level].page = hpage;
	hblocks[level].addr = haddr;
	hblocks[level].index = hblock_idx;
	hblocks[level].hoffset = hoffset;
	hidx = next_hidx;
	}

	want_hash = vi->root_hash;
	descend:
	/* Descend the tree verifying hash blocks. */
	for (; level > 0; level--) {
	struct page *hpage = hblocks[level - 1].page;
	const void *haddr = hblocks[level - 1].addr;
	unsigned long hblock_idx = hblocks[level - 1].index;
	unsigned int hoffset = hblocks[level - 1].hoffset;

	if (fsverity_hash_block(params, inode, haddr, real_hash) != 0)
	goto error;
	if (memcmp(want_hash, real_hash, hsize) != 0)
	goto corrupted;
	/*
	* Mark the hash block as verified. This must be atomic and
	* idempotent, as the same hash block might be verified by
	* multiple threads concurrently.
	*/
	if (vi->hash_block_verified)
	set_bit(hblock_idx, vi->hash_block_verified);
	else
	SetPageChecked(hpage);
	memcpy(_want_hash, haddr + hoffset, hsize);
	want_hash = _want_hash;
	kunmap_local(haddr);
	put_page(hpage);
	}

	/* Finally, verify the data block. */
	if (fsverity_hash_block(params, inode, data, real_hash) != 0)
	goto error;
	if (memcmp(want_hash, real_hash, hsize) != 0)
	goto corrupted;
	return true;

	corrupted:
	fsverity_err(inode,
	"FILE CORRUPTED! pos=%llu, level=%d, want_hash=%s:%phN, real_hash=%s:%phN",
	data_pos, level - 1,
	params->hash_alg->name, hsize, want_hash,
	params->hash_alg->name, hsize, real_hash);
	error:
	for (; level > 0; level--) {
	kunmap_local(hblocks[level - 1].addr);
	put_page(hblocks[level - 1].page);
	}
	return false;
	}

	static bool
	verify_data_blocks(struct folio *data_folio, size_t len, size_t offset,
	unsigned long max_ra_pages)
	{
	struct inode *inode = data_folio->mapping->host;
	struct fsverity_info *vi = inode->i_verity_info;
	const unsigned int block_size = vi->tree_params.block_size;
	u64 pos = (u64)data_folio->index << PAGE_SHIFT;

	if (WARN_ON_ONCE(len <= 0 \|\| !IS_ALIGNED(len \| offset, block_size)))
	return false;
	if (WARN_ON_ONCE(!folio_test_locked(data_folio) \|\|
	folio_test_uptodate(data_folio)))
	return false;
	do {
	void *data;
	bool valid;

	data = kmap_local_folio(data_folio, offset);
	valid = verify_data_block(inode, vi, data, pos + offset,
	max_ra_pages);
	kunmap_local(data);
	if (!valid)
	return false;
	offset += block_size;
	len -= block_size;
	} while (len);
	return true;
	}

	/**
	* fsverity_verify_blocks() - verify data in a folio
	* @folio: the folio containing the data to verify
	* @len: the length of the data to verify in the folio
	* @offset: the offset of the data to verify in the folio
	*
	* Verify data that has just been read from a verity file. The data must be
	* located in a pagecache folio that is still locked and not yet uptodate. The
	* length and offset of the data must be Merkle tree block size aligned.
	*
	* Return: %true if the data is valid, else %false.
	*/
	bool fsverity_verify_blocks(struct folio *folio, size_t len, size_t offset)
	{
	return verify_data_blocks(folio, len, offset, 0);
	}
	EXPORT_SYMBOL_GPL(fsverity_verify_blocks);

	#ifdef CONFIG_BLOCK
	/**
	* fsverity_verify_bio() - verify a 'read' bio that has just completed
	* @bio: the bio to verify
	*
	* Verify the bio's data against the file's Merkle tree. All bio data segments
	* must be aligned to the file's Merkle tree block size. If any data fails
	* verification, then bio->bi_status is set to an error status.
	*
	* This is a helper function for use by the ->readahead() method of filesystems
	* that issue bios to read data directly into the page cache. Filesystems that
	* populate the page cache without issuing bios (e.g. non block-based
	* filesystems) must instead call fsverity_verify_page() directly on each page.
	* All filesystems must also call fsverity_verify_page() on holes.
	*/
	void fsverity_verify_bio(struct bio *bio)
	{
	struct folio_iter fi;
	unsigned long max_ra_pages = 0;

	if (bio->bi_opf & REQ_RAHEAD) {
	/*
	* If this bio is for data readahead, then we also do readahead
	* of the first (largest) level of the Merkle tree. Namely,
	* when a Merkle tree page is read, we also try to piggy-back on
	* some additional pages -- up to 1/4 the number of data pages.
	*
	* This improves sequential read performance, as it greatly
	* reduces the number of I/O requests made to the Merkle tree.
	*/
	max_ra_pages = bio->bi_iter.bi_size >> (PAGE_SHIFT + 2);
	}

	bio_for_each_folio_all(fi, bio) {
	if (!verify_data_blocks(fi.folio, fi.length, fi.offset,
	max_ra_pages)) {
	bio->bi_status = BLK_STS_IOERR;
	break;
	}
	}
	}
	EXPORT_SYMBOL_GPL(fsverity_verify_bio);
	#endif /* CONFIG_BLOCK */

	/**
	* fsverity_enqueue_verify_work() - enqueue work on the fs-verity workqueue
	* @work: the work to enqueue
	*
	* Enqueue verification work for asynchronous processing.
	*/
	void fsverity_enqueue_verify_work(struct work_struct *work)
	{
	queue_work(fsverity_read_workqueue, work);
	}
	EXPORT_SYMBOL_GPL(fsverity_enqueue_verify_work);

	void __init fsverity_init_workqueue(void)
	{
	/*
	* Use a high-priority workqueue to prioritize verification work, which
	* blocks reads from completing, over regular application tasks.
	*
	* For performance reasons, don't use an unbound workqueue. Using an
	* unbound workqueue for crypto operations causes excessive scheduler
	* latency on ARM64.
	*/
	fsverity_read_workqueue = alloc_workqueue("fsverity_read_queue",
	WQ_HIGHPRI,
	num_online_cpus());
	if (!fsverity_read_workqueue)
	panic("failed to allocate fsverity_read_queue");
	}