compression.c 38.8 KB
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// SPDX-License-Identifier: GPL-2.0
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/*
 * Copyright (C) 2008 Oracle.  All rights reserved.
 */

#include <linux/kernel.h>
#include <linux/bio.h>
#include <linux/file.h>
#include <linux/fs.h>
#include <linux/pagemap.h>
#include <linux/highmem.h>
#include <linux/time.h>
#include <linux/init.h>
#include <linux/string.h>
#include <linux/backing-dev.h>
#include <linux/writeback.h>
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#include <linux/slab.h>
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#include <linux/sched/mm.h>
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#include <linux/log2.h>
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#include "ctree.h"
#include "disk-io.h"
#include "transaction.h"
#include "btrfs_inode.h"
#include "volumes.h"
#include "ordered-data.h"
#include "compression.h"
#include "extent_io.h"
#include "extent_map.h"

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static const char* const btrfs_compress_types[] = { "", "zlib", "lzo", "zstd" };

const char* btrfs_compress_type2str(enum btrfs_compression_type type)
{
	switch (type) {
	case BTRFS_COMPRESS_ZLIB:
	case BTRFS_COMPRESS_LZO:
	case BTRFS_COMPRESS_ZSTD:
	case BTRFS_COMPRESS_NONE:
		return btrfs_compress_types[type];
	}

	return NULL;
}

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static int btrfs_decompress_bio(struct compressed_bio *cb);
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static inline int compressed_bio_size(struct btrfs_fs_info *fs_info,
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				      unsigned long disk_size)
{
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	u16 csum_size = btrfs_super_csum_size(fs_info->super_copy);
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	return sizeof(struct compressed_bio) +
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		(DIV_ROUND_UP(disk_size, fs_info->sectorsize)) * csum_size;
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}

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static int check_compressed_csum(struct btrfs_inode *inode,
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				 struct compressed_bio *cb,
				 u64 disk_start)
{
	int ret;
	struct page *page;
	unsigned long i;
	char *kaddr;
	u32 csum;
	u32 *cb_sum = &cb->sums;

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	if (inode->flags & BTRFS_INODE_NODATASUM)
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		return 0;

	for (i = 0; i < cb->nr_pages; i++) {
		page = cb->compressed_pages[i];
		csum = ~(u32)0;

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		kaddr = kmap_atomic(page);
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		csum = btrfs_csum_data(kaddr, csum, PAGE_SIZE);
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		btrfs_csum_final(csum, (u8 *)&csum);
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		kunmap_atomic(kaddr);
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		if (csum != *cb_sum) {
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			btrfs_print_data_csum_error(inode, disk_start, csum,
81
					*cb_sum, cb->mirror_num);
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			ret = -EIO;
			goto fail;
		}
		cb_sum++;

	}
	ret = 0;
fail:
	return ret;
}

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/* when we finish reading compressed pages from the disk, we
 * decompress them and then run the bio end_io routines on the
 * decompressed pages (in the inode address space).
 *
 * This allows the checksumming and other IO error handling routines
 * to work normally
 *
 * The compressed pages are freed here, and it must be run
 * in process context
 */
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static void end_compressed_bio_read(struct bio *bio)
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{
	struct compressed_bio *cb = bio->bi_private;
	struct inode *inode;
	struct page *page;
	unsigned long index;
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	unsigned int mirror = btrfs_io_bio(bio)->mirror_num;
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	int ret = 0;
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	if (bio->bi_status)
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		cb->errors = 1;

	/* if there are more bios still pending for this compressed
	 * extent, just exit
	 */
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	if (!refcount_dec_and_test(&cb->pending_bios))
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		goto out;

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	/*
	 * Record the correct mirror_num in cb->orig_bio so that
	 * read-repair can work properly.
	 */
	ASSERT(btrfs_io_bio(cb->orig_bio));
	btrfs_io_bio(cb->orig_bio)->mirror_num = mirror;
	cb->mirror_num = mirror;

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	/*
	 * Some IO in this cb have failed, just skip checksum as there
	 * is no way it could be correct.
	 */
	if (cb->errors == 1)
		goto csum_failed;

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	inode = cb->inode;
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	ret = check_compressed_csum(BTRFS_I(inode), cb,
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				    (u64)bio->bi_iter.bi_sector << 9);
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	if (ret)
		goto csum_failed;

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	/* ok, we're the last bio for this extent, lets start
	 * the decompression.
	 */
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	ret = btrfs_decompress_bio(cb);

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csum_failed:
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	if (ret)
		cb->errors = 1;

	/* release the compressed pages */
	index = 0;
	for (index = 0; index < cb->nr_pages; index++) {
		page = cb->compressed_pages[index];
		page->mapping = NULL;
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		put_page(page);
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	}

	/* do io completion on the original bio */
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	if (cb->errors) {
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		bio_io_error(cb->orig_bio);
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	} else {
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		int i;
		struct bio_vec *bvec;
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		/*
		 * we have verified the checksum already, set page
		 * checked so the end_io handlers know about it
		 */
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		ASSERT(!bio_flagged(bio, BIO_CLONED));
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		bio_for_each_segment_all(bvec, cb->orig_bio, i)
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			SetPageChecked(bvec->bv_page);
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		bio_endio(cb->orig_bio);
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	}
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	/* finally free the cb struct */
	kfree(cb->compressed_pages);
	kfree(cb);
out:
	bio_put(bio);
}

/*
 * Clear the writeback bits on all of the file
 * pages for a compressed write
 */
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static noinline void end_compressed_writeback(struct inode *inode,
					      const struct compressed_bio *cb)
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{
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	unsigned long index = cb->start >> PAGE_SHIFT;
	unsigned long end_index = (cb->start + cb->len - 1) >> PAGE_SHIFT;
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	struct page *pages[16];
	unsigned long nr_pages = end_index - index + 1;
	int i;
	int ret;

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	if (cb->errors)
		mapping_set_error(inode->i_mapping, -EIO);

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	while (nr_pages > 0) {
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		ret = find_get_pages_contig(inode->i_mapping, index,
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				     min_t(unsigned long,
				     nr_pages, ARRAY_SIZE(pages)), pages);
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		if (ret == 0) {
			nr_pages -= 1;
			index += 1;
			continue;
		}
		for (i = 0; i < ret; i++) {
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			if (cb->errors)
				SetPageError(pages[i]);
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			end_page_writeback(pages[i]);
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			put_page(pages[i]);
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		}
		nr_pages -= ret;
		index += ret;
	}
	/* the inode may be gone now */
}

/*
 * do the cleanup once all the compressed pages hit the disk.
 * This will clear writeback on the file pages and free the compressed
 * pages.
 *
 * This also calls the writeback end hooks for the file pages so that
 * metadata and checksums can be updated in the file.
 */
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static void end_compressed_bio_write(struct bio *bio)
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{
	struct compressed_bio *cb = bio->bi_private;
	struct inode *inode;
	struct page *page;
	unsigned long index;

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	if (bio->bi_status)
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		cb->errors = 1;

	/* if there are more bios still pending for this compressed
	 * extent, just exit
	 */
243
	if (!refcount_dec_and_test(&cb->pending_bios))
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		goto out;

	/* ok, we're the last bio for this extent, step one is to
	 * call back into the FS and do all the end_io operations
	 */
	inode = cb->inode;
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	cb->compressed_pages[0]->mapping = cb->inode->i_mapping;
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	btrfs_writepage_endio_finish_ordered(cb->compressed_pages[0],
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			cb->start, cb->start + cb->len - 1,
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			bio->bi_status ? BLK_STS_OK : BLK_STS_NOTSUPP);
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	cb->compressed_pages[0]->mapping = NULL;
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	end_compressed_writeback(inode, cb);
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	/* note, our inode could be gone now */

	/*
	 * release the compressed pages, these came from alloc_page and
	 * are not attached to the inode at all
	 */
	index = 0;
	for (index = 0; index < cb->nr_pages; index++) {
		page = cb->compressed_pages[index];
		page->mapping = NULL;
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		put_page(page);
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	}

	/* finally free the cb struct */
	kfree(cb->compressed_pages);
	kfree(cb);
out:
	bio_put(bio);
}

/*
 * worker function to build and submit bios for previously compressed pages.
 * The corresponding pages in the inode should be marked for writeback
 * and the compressed pages should have a reference on them for dropping
 * when the IO is complete.
 *
 * This also checksums the file bytes and gets things ready for
 * the end io hooks.
 */
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blk_status_t btrfs_submit_compressed_write(struct inode *inode, u64 start,
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				 unsigned long len, u64 disk_start,
				 unsigned long compressed_len,
				 struct page **compressed_pages,
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				 unsigned long nr_pages,
				 unsigned int write_flags)
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{
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	struct btrfs_fs_info *fs_info = btrfs_sb(inode->i_sb);
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	struct bio *bio = NULL;
	struct compressed_bio *cb;
	unsigned long bytes_left;
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	int pg_index = 0;
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	struct page *page;
	u64 first_byte = disk_start;
	struct block_device *bdev;
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	blk_status_t ret;
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	int skip_sum = BTRFS_I(inode)->flags & BTRFS_INODE_NODATASUM;
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	WARN_ON(!PAGE_ALIGNED(start));
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	cb = kmalloc(compressed_bio_size(fs_info, compressed_len), GFP_NOFS);
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	if (!cb)
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		return BLK_STS_RESOURCE;
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	refcount_set(&cb->pending_bios, 0);
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	cb->errors = 0;
	cb->inode = inode;
	cb->start = start;
	cb->len = len;
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	cb->mirror_num = 0;
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	cb->compressed_pages = compressed_pages;
	cb->compressed_len = compressed_len;
	cb->orig_bio = NULL;
	cb->nr_pages = nr_pages;

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	bdev = fs_info->fs_devices->latest_bdev;
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	bio = btrfs_bio_alloc(bdev, first_byte);
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	bio->bi_opf = REQ_OP_WRITE | write_flags;
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	bio->bi_private = cb;
	bio->bi_end_io = end_compressed_bio_write;
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	refcount_set(&cb->pending_bios, 1);
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	/* create and submit bios for the compressed pages */
	bytes_left = compressed_len;
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	for (pg_index = 0; pg_index < cb->nr_pages; pg_index++) {
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		int submit = 0;

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		page = compressed_pages[pg_index];
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		page->mapping = inode->i_mapping;
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		if (bio->bi_iter.bi_size)
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			submit = btrfs_bio_fits_in_stripe(page, PAGE_SIZE, bio,
							  0);
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		page->mapping = NULL;
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		if (submit || bio_add_page(bio, page, PAGE_SIZE, 0) <
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		    PAGE_SIZE) {
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			/*
			 * inc the count before we submit the bio so
			 * we know the end IO handler won't happen before
			 * we inc the count.  Otherwise, the cb might get
			 * freed before we're done setting it up
			 */
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			refcount_inc(&cb->pending_bios);
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			ret = btrfs_bio_wq_end_io(fs_info, bio,
						  BTRFS_WQ_ENDIO_DATA);
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			BUG_ON(ret); /* -ENOMEM */
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			if (!skip_sum) {
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				ret = btrfs_csum_one_bio(inode, bio, start, 1);
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				BUG_ON(ret); /* -ENOMEM */
355
			}
356

357
			ret = btrfs_map_bio(fs_info, bio, 0, 1);
358
			if (ret) {
359
				bio->bi_status = ret;
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				bio_endio(bio);
			}
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363
			bio = btrfs_bio_alloc(bdev, first_byte);
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			bio->bi_opf = REQ_OP_WRITE | write_flags;
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			bio->bi_private = cb;
			bio->bi_end_io = end_compressed_bio_write;
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			bio_add_page(bio, page, PAGE_SIZE, 0);
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		}
369
		if (bytes_left < PAGE_SIZE) {
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			btrfs_info(fs_info,
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					"bytes left %lu compress len %lu nr %lu",
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			       bytes_left, cb->compressed_len, cb->nr_pages);
		}
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		bytes_left -= PAGE_SIZE;
		first_byte += PAGE_SIZE;
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		cond_resched();
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	}

379
	ret = btrfs_bio_wq_end_io(fs_info, bio, BTRFS_WQ_ENDIO_DATA);
380
	BUG_ON(ret); /* -ENOMEM */
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382
	if (!skip_sum) {
383
		ret = btrfs_csum_one_bio(inode, bio, start, 1);
384
		BUG_ON(ret); /* -ENOMEM */
385
	}
386

387
	ret = btrfs_map_bio(fs_info, bio, 0, 1);
388
	if (ret) {
389
		bio->bi_status = ret;
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		bio_endio(bio);
	}
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	return 0;
}

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static u64 bio_end_offset(struct bio *bio)
{
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	struct bio_vec *last = bio_last_bvec_all(bio);
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	return page_offset(last->bv_page) + last->bv_len + last->bv_offset;
}

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static noinline int add_ra_bio_pages(struct inode *inode,
				     u64 compressed_end,
				     struct compressed_bio *cb)
{
	unsigned long end_index;
408
	unsigned long pg_index;
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	u64 last_offset;
	u64 isize = i_size_read(inode);
	int ret;
	struct page *page;
	unsigned long nr_pages = 0;
	struct extent_map *em;
	struct address_space *mapping = inode->i_mapping;
	struct extent_map_tree *em_tree;
	struct extent_io_tree *tree;
	u64 end;
	int misses = 0;

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	last_offset = bio_end_offset(cb->orig_bio);
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	em_tree = &BTRFS_I(inode)->extent_tree;
	tree = &BTRFS_I(inode)->io_tree;

	if (isize == 0)
		return 0;

428
	end_index = (i_size_read(inode) - 1) >> PAGE_SHIFT;
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	while (last_offset < compressed_end) {
431
		pg_index = last_offset >> PAGE_SHIFT;
432

433
		if (pg_index > end_index)
434 435
			break;

436
		page = xa_load(&mapping->i_pages, pg_index);
437
		if (page && !xa_is_value(page)) {
438 439 440 441 442 443
			misses++;
			if (misses > 4)
				break;
			goto next;
		}

444 445
		page = __page_cache_alloc(mapping_gfp_constraint(mapping,
								 ~__GFP_FS));
446 447 448
		if (!page)
			break;

449
		if (add_to_page_cache_lru(page, mapping, pg_index, GFP_NOFS)) {
450
			put_page(page);
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			goto next;
		}

454
		end = last_offset + PAGE_SIZE - 1;
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		/*
		 * at this point, we have a locked page in the page cache
		 * for these bytes in the file.  But, we have to make
		 * sure they map to this compressed extent on disk.
		 */
		set_page_extent_mapped(page);
461
		lock_extent(tree, last_offset, end);
462
		read_lock(&em_tree->lock);
463
		em = lookup_extent_mapping(em_tree, last_offset,
464
					   PAGE_SIZE);
465
		read_unlock(&em_tree->lock);
466 467

		if (!em || last_offset < em->start ||
468
		    (last_offset + PAGE_SIZE > extent_map_end(em)) ||
469
		    (em->block_start >> 9) != cb->orig_bio->bi_iter.bi_sector) {
470
			free_extent_map(em);
471
			unlock_extent(tree, last_offset, end);
472
			unlock_page(page);
473
			put_page(page);
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			break;
		}
		free_extent_map(em);

		if (page->index == end_index) {
			char *userpage;
480
			size_t zero_offset = offset_in_page(isize);
481 482 483

			if (zero_offset) {
				int zeros;
484
				zeros = PAGE_SIZE - zero_offset;
485
				userpage = kmap_atomic(page);
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				memset(userpage + zero_offset, 0, zeros);
				flush_dcache_page(page);
488
				kunmap_atomic(userpage);
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			}
		}

		ret = bio_add_page(cb->orig_bio, page,
493
				   PAGE_SIZE, 0);
494

495
		if (ret == PAGE_SIZE) {
496
			nr_pages++;
497
			put_page(page);
498
		} else {
499
			unlock_extent(tree, last_offset, end);
500
			unlock_page(page);
501
			put_page(page);
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			break;
		}
next:
505
		last_offset += PAGE_SIZE;
506 507 508 509
	}
	return 0;
}

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/*
 * for a compressed read, the bio we get passed has all the inode pages
 * in it.  We don't actually do IO on those pages but allocate new ones
 * to hold the compressed pages on disk.
 *
515
 * bio->bi_iter.bi_sector points to the compressed extent on disk
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 * bio->bi_io_vec points to all of the inode pages
 *
 * After the compressed pages are read, we copy the bytes into the
 * bio we were passed and then call the bio end_io calls
 */
521
blk_status_t btrfs_submit_compressed_read(struct inode *inode, struct bio *bio,
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				 int mirror_num, unsigned long bio_flags)
{
524
	struct btrfs_fs_info *fs_info = btrfs_sb(inode->i_sb);
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	struct extent_map_tree *em_tree;
	struct compressed_bio *cb;
	unsigned long compressed_len;
	unsigned long nr_pages;
529
	unsigned long pg_index;
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	struct page *page;
	struct block_device *bdev;
	struct bio *comp_bio;
533
	u64 cur_disk_byte = (u64)bio->bi_iter.bi_sector << 9;
534 535
	u64 em_len;
	u64 em_start;
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	struct extent_map *em;
537
	blk_status_t ret = BLK_STS_RESOURCE;
538
	int faili = 0;
539
	u32 *sums;
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	em_tree = &BTRFS_I(inode)->extent_tree;

	/* we need the actual starting offset of this extent in the file */
544
	read_lock(&em_tree->lock);
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	em = lookup_extent_mapping(em_tree,
546
				   page_offset(bio_first_page_all(bio)),
547
				   PAGE_SIZE);
548
	read_unlock(&em_tree->lock);
549
	if (!em)
550
		return BLK_STS_IOERR;
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552
	compressed_len = em->block_len;
553
	cb = kmalloc(compressed_bio_size(fs_info, compressed_len), GFP_NOFS);
554 555 556
	if (!cb)
		goto out;

557
	refcount_set(&cb->pending_bios, 0);
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	cb->errors = 0;
	cb->inode = inode;
560 561
	cb->mirror_num = mirror_num;
	sums = &cb->sums;
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563
	cb->start = em->orig_start;
564 565
	em_len = em->len;
	em_start = em->start;
566

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	free_extent_map(em);
568
	em = NULL;
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	cb->len = bio->bi_iter.bi_size;
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	cb->compressed_len = compressed_len;
572
	cb->compress_type = extent_compress_type(bio_flags);
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	cb->orig_bio = bio;

575
	nr_pages = DIV_ROUND_UP(compressed_len, PAGE_SIZE);
576
	cb->compressed_pages = kcalloc(nr_pages, sizeof(struct page *),
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				       GFP_NOFS);
578 579 580
	if (!cb->compressed_pages)
		goto fail1;

581
	bdev = fs_info->fs_devices->latest_bdev;
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583 584
	for (pg_index = 0; pg_index < nr_pages; pg_index++) {
		cb->compressed_pages[pg_index] = alloc_page(GFP_NOFS |
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							      __GFP_HIGHMEM);
586 587
		if (!cb->compressed_pages[pg_index]) {
			faili = pg_index - 1;
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			ret = BLK_STS_RESOURCE;
589
			goto fail2;
590
		}
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	}
592
	faili = nr_pages - 1;
C
Chris Mason 已提交
593 594
	cb->nr_pages = nr_pages;

595
	add_ra_bio_pages(inode, em_start + em_len, cb);
596 597

	/* include any pages we added in add_ra-bio_pages */
C
Christoph Hellwig 已提交
598
	cb->len = bio->bi_iter.bi_size;
599

600
	comp_bio = btrfs_bio_alloc(bdev, cur_disk_byte);
D
David Sterba 已提交
601
	comp_bio->bi_opf = REQ_OP_READ;
C
Chris Mason 已提交
602 603
	comp_bio->bi_private = cb;
	comp_bio->bi_end_io = end_compressed_bio_read;
604
	refcount_set(&cb->pending_bios, 1);
C
Chris Mason 已提交
605

606
	for (pg_index = 0; pg_index < nr_pages; pg_index++) {
607 608
		int submit = 0;

609
		page = cb->compressed_pages[pg_index];
C
Chris Mason 已提交
610
		page->mapping = inode->i_mapping;
611
		page->index = em_start >> PAGE_SHIFT;
612

613
		if (comp_bio->bi_iter.bi_size)
614 615
			submit = btrfs_bio_fits_in_stripe(page, PAGE_SIZE,
							  comp_bio, 0);
C
Chris Mason 已提交
616

C
Chris Mason 已提交
617
		page->mapping = NULL;
618
		if (submit || bio_add_page(comp_bio, page, PAGE_SIZE, 0) <
619
		    PAGE_SIZE) {
620 621
			ret = btrfs_bio_wq_end_io(fs_info, comp_bio,
						  BTRFS_WQ_ENDIO_DATA);
622
			BUG_ON(ret); /* -ENOMEM */
C
Chris Mason 已提交
623

624 625 626 627 628 629
			/*
			 * inc the count before we submit the bio so
			 * we know the end IO handler won't happen before
			 * we inc the count.  Otherwise, the cb might get
			 * freed before we're done setting it up
			 */
630
			refcount_inc(&cb->pending_bios);
631

632
			if (!(BTRFS_I(inode)->flags & BTRFS_INODE_NODATASUM)) {
633 634
				ret = btrfs_lookup_bio_sums(inode, comp_bio,
							    sums);
635
				BUG_ON(ret); /* -ENOMEM */
636
			}
637
			sums += DIV_ROUND_UP(comp_bio->bi_iter.bi_size,
638
					     fs_info->sectorsize);
639

640
			ret = btrfs_map_bio(fs_info, comp_bio, mirror_num, 0);
641
			if (ret) {
642
				comp_bio->bi_status = ret;
643 644
				bio_endio(comp_bio);
			}
C
Chris Mason 已提交
645

646
			comp_bio = btrfs_bio_alloc(bdev, cur_disk_byte);
D
David Sterba 已提交
647
			comp_bio->bi_opf = REQ_OP_READ;
648 649 650
			comp_bio->bi_private = cb;
			comp_bio->bi_end_io = end_compressed_bio_read;

651
			bio_add_page(comp_bio, page, PAGE_SIZE, 0);
C
Chris Mason 已提交
652
		}
653
		cur_disk_byte += PAGE_SIZE;
C
Chris Mason 已提交
654 655
	}

656
	ret = btrfs_bio_wq_end_io(fs_info, comp_bio, BTRFS_WQ_ENDIO_DATA);
657
	BUG_ON(ret); /* -ENOMEM */
C
Chris Mason 已提交
658

659
	if (!(BTRFS_I(inode)->flags & BTRFS_INODE_NODATASUM)) {
660
		ret = btrfs_lookup_bio_sums(inode, comp_bio, sums);
661
		BUG_ON(ret); /* -ENOMEM */
662
	}
663

664
	ret = btrfs_map_bio(fs_info, comp_bio, mirror_num, 0);
665
	if (ret) {
666
		comp_bio->bi_status = ret;
667 668
		bio_endio(comp_bio);
	}
C
Chris Mason 已提交
669 670

	return 0;
671 672

fail2:
673 674 675 676
	while (faili >= 0) {
		__free_page(cb->compressed_pages[faili]);
		faili--;
	}
677 678 679 680 681 682 683

	kfree(cb->compressed_pages);
fail1:
	kfree(cb);
out:
	free_extent_map(em);
	return ret;
C
Chris Mason 已提交
684
}
685

686 687 688 689 690 691 692 693 694 695 696 697 698 699 700 701 702 703 704 705 706 707 708 709 710 711 712 713 714 715 716 717 718 719 720
/*
 * Heuristic uses systematic sampling to collect data from the input data
 * range, the logic can be tuned by the following constants:
 *
 * @SAMPLING_READ_SIZE - how many bytes will be copied from for each sample
 * @SAMPLING_INTERVAL  - range from which the sampled data can be collected
 */
#define SAMPLING_READ_SIZE	(16)
#define SAMPLING_INTERVAL	(256)

/*
 * For statistical analysis of the input data we consider bytes that form a
 * Galois Field of 256 objects. Each object has an attribute count, ie. how
 * many times the object appeared in the sample.
 */
#define BUCKET_SIZE		(256)

/*
 * The size of the sample is based on a statistical sampling rule of thumb.
 * The common way is to perform sampling tests as long as the number of
 * elements in each cell is at least 5.
 *
 * Instead of 5, we choose 32 to obtain more accurate results.
 * If the data contain the maximum number of symbols, which is 256, we obtain a
 * sample size bound by 8192.
 *
 * For a sample of at most 8KB of data per data range: 16 consecutive bytes
 * from up to 512 locations.
 */
#define MAX_SAMPLE_SIZE		(BTRFS_MAX_UNCOMPRESSED *		\
				 SAMPLING_READ_SIZE / SAMPLING_INTERVAL)

struct bucket_item {
	u32 count;
};
721 722

struct heuristic_ws {
723 724
	/* Partial copy of input data */
	u8 *sample;
725
	u32 sample_size;
726 727
	/* Buckets store counters for each byte value */
	struct bucket_item *bucket;
728 729
	/* Sorting buffer */
	struct bucket_item *bucket_b;
730 731 732 733 734 735 736 737 738
	struct list_head list;
};

static void free_heuristic_ws(struct list_head *ws)
{
	struct heuristic_ws *workspace;

	workspace = list_entry(ws, struct heuristic_ws, list);

739 740
	kvfree(workspace->sample);
	kfree(workspace->bucket);
741
	kfree(workspace->bucket_b);
742 743 744 745 746 747 748 749 750 751 752
	kfree(workspace);
}

static struct list_head *alloc_heuristic_ws(void)
{
	struct heuristic_ws *ws;

	ws = kzalloc(sizeof(*ws), GFP_KERNEL);
	if (!ws)
		return ERR_PTR(-ENOMEM);

753 754 755 756 757 758 759
	ws->sample = kvmalloc(MAX_SAMPLE_SIZE, GFP_KERNEL);
	if (!ws->sample)
		goto fail;

	ws->bucket = kcalloc(BUCKET_SIZE, sizeof(*ws->bucket), GFP_KERNEL);
	if (!ws->bucket)
		goto fail;
760

761 762 763 764
	ws->bucket_b = kcalloc(BUCKET_SIZE, sizeof(*ws->bucket_b), GFP_KERNEL);
	if (!ws->bucket_b)
		goto fail;

765
	INIT_LIST_HEAD(&ws->list);
766
	return &ws->list;
767 768 769
fail:
	free_heuristic_ws(&ws->list);
	return ERR_PTR(-ENOMEM);
770 771
}

772 773 774 775 776
const struct btrfs_compress_op btrfs_heuristic_compress = {
	.alloc_workspace = alloc_heuristic_ws,
	.free_workspace = free_heuristic_ws,
};

777
struct workspace_manager {
778 779
	struct list_head idle_ws;
	spinlock_t ws_lock;
780 781 782 783 784
	/* Number of free workspaces */
	int free_ws;
	/* Total number of allocated workspaces */
	atomic_t total_ws;
	/* Waiters for a free workspace */
785
	wait_queue_head_t ws_wait;
786 787
};

788
static struct workspace_manager wsm[BTRFS_NR_WORKSPACE_MANAGERS];
789

790
static const struct btrfs_compress_op * const btrfs_compress_op[] = {
791 792
	/* The heuristic is represented as compression type 0 */
	&btrfs_heuristic_compress,
793
	&btrfs_zlib_compress,
L
Li Zefan 已提交
794
	&btrfs_lzo_compress,
N
Nick Terrell 已提交
795
	&btrfs_zstd_compress,
796 797
};

798
void __init btrfs_init_compress(void)
799
{
800
	struct list_head *workspace;
801 802
	int i;

803
	for (i = 0; i < BTRFS_NR_WORKSPACE_MANAGERS; i++) {
804 805 806 807
		INIT_LIST_HEAD(&wsm[i].idle_ws);
		spin_lock_init(&wsm[i].ws_lock);
		atomic_set(&wsm[i].total_ws, 0);
		init_waitqueue_head(&wsm[i].ws_wait);
808 809 810 811 812 813 814

		/*
		 * Preallocate one workspace for each compression type so
		 * we can guarantee forward progress in the worst case
		 */
		workspace = btrfs_compress_op[i]->alloc_workspace();
		if (IS_ERR(workspace)) {
815
			pr_warn("BTRFS: cannot preallocate compression workspace, will try later\n");
816
		} else {
817 818 819
			atomic_set(&wsm[i].total_ws, 1);
			wsm[i].free_ws = 1;
			list_add(workspace, &wsm[i].idle_ws);
820
		}
821 822 823 824
	}
}

/*
825 826 827 828
 * This finds an available workspace or allocates a new one.
 * If it's not possible to allocate a new one, waits until there's one.
 * Preallocation makes a forward progress guarantees and we do not return
 * errors.
829
 */
830
static struct list_head *find_workspace(int type)
831 832 833
{
	struct list_head *workspace;
	int cpus = num_online_cpus();
834
	unsigned nofs_flag;
835 836 837 838 839 840
	struct list_head *idle_ws;
	spinlock_t *ws_lock;
	atomic_t *total_ws;
	wait_queue_head_t *ws_wait;
	int *free_ws;

841 842 843 844 845
	idle_ws	 = &wsm[type].idle_ws;
	ws_lock	 = &wsm[type].ws_lock;
	total_ws = &wsm[type].total_ws;
	ws_wait	 = &wsm[type].ws_wait;
	free_ws	 = &wsm[type].free_ws;
846 847

again:
848 849 850
	spin_lock(ws_lock);
	if (!list_empty(idle_ws)) {
		workspace = idle_ws->next;
851
		list_del(workspace);
852
		(*free_ws)--;
853
		spin_unlock(ws_lock);
854 855 856
		return workspace;

	}
857
	if (atomic_read(total_ws) > cpus) {
858 859
		DEFINE_WAIT(wait);

860 861
		spin_unlock(ws_lock);
		prepare_to_wait(ws_wait, &wait, TASK_UNINTERRUPTIBLE);
862
		if (atomic_read(total_ws) > cpus && !*free_ws)
863
			schedule();
864
		finish_wait(ws_wait, &wait);
865 866
		goto again;
	}
867
	atomic_inc(total_ws);
868
	spin_unlock(ws_lock);
869

870 871 872 873 874 875
	/*
	 * Allocation helpers call vmalloc that can't use GFP_NOFS, so we have
	 * to turn it off here because we might get called from the restricted
	 * context of btrfs_compress_bio/btrfs_compress_pages
	 */
	nofs_flag = memalloc_nofs_save();
876
	workspace = btrfs_compress_op[type]->alloc_workspace();
877 878
	memalloc_nofs_restore(nofs_flag);

879
	if (IS_ERR(workspace)) {
880
		atomic_dec(total_ws);
881
		wake_up(ws_wait);
882 883 884 885 886 887

		/*
		 * Do not return the error but go back to waiting. There's a
		 * workspace preallocated for each type and the compression
		 * time is bounded so we get to a workspace eventually. This
		 * makes our caller's life easier.
888 889 890 891
		 *
		 * To prevent silent and low-probability deadlocks (when the
		 * initial preallocation fails), check if there are any
		 * workspaces at all.
892
		 */
893 894 895 896 897 898
		if (atomic_read(total_ws) == 0) {
			static DEFINE_RATELIMIT_STATE(_rs,
					/* once per minute */ 60 * HZ,
					/* no burst */ 1);

			if (__ratelimit(&_rs)) {
899
				pr_warn("BTRFS: no compression workspaces, low memory, retrying\n");
900 901
			}
		}
902
		goto again;
903 904 905 906 907 908 909 910
	}
	return workspace;
}

/*
 * put a workspace struct back on the list or free it if we have enough
 * idle ones sitting around
 */
911
static void free_workspace(int type, struct list_head *workspace)
912
{
913 914 915 916 917 918
	struct list_head *idle_ws;
	spinlock_t *ws_lock;
	atomic_t *total_ws;
	wait_queue_head_t *ws_wait;
	int *free_ws;

919 920 921 922 923
	idle_ws	 = &wsm[type].idle_ws;
	ws_lock	 = &wsm[type].ws_lock;
	total_ws = &wsm[type].total_ws;
	ws_wait	 = &wsm[type].ws_wait;
	free_ws	 = &wsm[type].free_ws;
924 925

	spin_lock(ws_lock);
926
	if (*free_ws <= num_online_cpus()) {
927
		list_add(workspace, idle_ws);
928
		(*free_ws)++;
929
		spin_unlock(ws_lock);
930 931
		goto wake;
	}
932
	spin_unlock(ws_lock);
933

934
	btrfs_compress_op[type]->free_workspace(workspace);
935
	atomic_dec(total_ws);
936
wake:
937
	cond_wake_up(ws_wait);
938 939 940 941 942 943 944 945 946 947
}

/*
 * cleanup function for module exit
 */
static void free_workspaces(void)
{
	struct list_head *workspace;
	int i;

948
	for (i = 0; i < BTRFS_NR_WORKSPACE_MANAGERS; i++) {
949 950
		while (!list_empty(&wsm[i].idle_ws)) {
			workspace = wsm[i].idle_ws.next;
951 952
			list_del(workspace);
			btrfs_compress_op[i]->free_workspace(workspace);
953
			atomic_dec(&wsm[i].total_ws);
954 955 956 957 958
		}
	}
}

/*
959 960
 * Given an address space and start and length, compress the bytes into @pages
 * that are allocated on demand.
961
 *
962 963 964 965 966
 * @type_level is encoded algorithm and level, where level 0 means whatever
 * default the algorithm chooses and is opaque here;
 * - compression algo are 0-3
 * - the level are bits 4-7
 *
967 968
 * @out_pages is an in/out parameter, holds maximum number of pages to allocate
 * and returns number of actually allocated pages
969
 *
970 971
 * @total_in is used to return the number of bytes actually read.  It
 * may be smaller than the input length if we had to exit early because we
972 973 974
 * ran out of room in the pages array or because we cross the
 * max_out threshold.
 *
975 976
 * @total_out is an in/out parameter, must be set to the input length and will
 * be also used to return the total number of compressed bytes
977
 *
978
 * @max_out tells us the max number of bytes that we're allowed to
979 980
 * stuff into pages
 */
981
int btrfs_compress_pages(unsigned int type_level, struct address_space *mapping,
982
			 u64 start, struct page **pages,
983 984
			 unsigned long *out_pages,
			 unsigned long *total_in,
985
			 unsigned long *total_out)
986
{
987
	int type = btrfs_compress_type(type_level);
988 989 990 991 992
	struct list_head *workspace;
	int ret;

	workspace = find_workspace(type);

993 994
	btrfs_compress_op[type]->set_level(workspace, type_level);
	ret = btrfs_compress_op[type]->compress_pages(workspace, mapping,
995
						      start, pages,
996
						      out_pages,
997
						      total_in, total_out);
998 999 1000 1001 1002 1003 1004 1005 1006
	free_workspace(type, workspace);
	return ret;
}

/*
 * pages_in is an array of pages with compressed data.
 *
 * disk_start is the starting logical offset of this array in the file
 *
1007
 * orig_bio contains the pages from the file that we want to decompress into
1008 1009 1010 1011 1012 1013 1014 1015
 *
 * srclen is the number of bytes in pages_in
 *
 * The basic idea is that we have a bio that was created by readpages.
 * The pages in the bio are for the uncompressed data, and they may not
 * be contiguous.  They all correspond to the range of bytes covered by
 * the compressed extent.
 */
1016
static int btrfs_decompress_bio(struct compressed_bio *cb)
1017 1018 1019
{
	struct list_head *workspace;
	int ret;
1020
	int type = cb->compress_type;
1021 1022

	workspace = find_workspace(type);
1023
	ret = btrfs_compress_op[type]->decompress_bio(workspace, cb);
1024
	free_workspace(type, workspace);
1025

1026 1027 1028 1029 1030 1031 1032 1033 1034 1035 1036 1037 1038 1039 1040 1041
	return ret;
}

/*
 * a less complex decompression routine.  Our compressed data fits in a
 * single page, and we want to read a single page out of it.
 * start_byte tells us the offset into the compressed data we're interested in
 */
int btrfs_decompress(int type, unsigned char *data_in, struct page *dest_page,
		     unsigned long start_byte, size_t srclen, size_t destlen)
{
	struct list_head *workspace;
	int ret;

	workspace = find_workspace(type);

1042
	ret = btrfs_compress_op[type]->decompress(workspace, data_in,
1043 1044 1045 1046 1047 1048 1049
						  dest_page, start_byte,
						  srclen, destlen);

	free_workspace(type, workspace);
	return ret;
}

1050
void __cold btrfs_exit_compress(void)
1051 1052 1053
{
	free_workspaces();
}
1054 1055 1056 1057 1058 1059 1060 1061

/*
 * Copy uncompressed data from working buffer to pages.
 *
 * buf_start is the byte offset we're of the start of our workspace buffer.
 *
 * total_out is the last byte of the buffer
 */
1062
int btrfs_decompress_buf2page(const char *buf, unsigned long buf_start,
1063
			      unsigned long total_out, u64 disk_start,
1064
			      struct bio *bio)
1065 1066 1067 1068
{
	unsigned long buf_offset;
	unsigned long current_buf_start;
	unsigned long start_byte;
1069
	unsigned long prev_start_byte;
1070 1071 1072
	unsigned long working_bytes = total_out - buf_start;
	unsigned long bytes;
	char *kaddr;
1073
	struct bio_vec bvec = bio_iter_iovec(bio, bio->bi_iter);
1074 1075 1076 1077 1078

	/*
	 * start byte is the first byte of the page we're currently
	 * copying into relative to the start of the compressed data.
	 */
1079
	start_byte = page_offset(bvec.bv_page) - disk_start;
1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 1098

	/* we haven't yet hit data corresponding to this page */
	if (total_out <= start_byte)
		return 1;

	/*
	 * the start of the data we care about is offset into
	 * the middle of our working buffer
	 */
	if (total_out > start_byte && buf_start < start_byte) {
		buf_offset = start_byte - buf_start;
		working_bytes -= buf_offset;
	} else {
		buf_offset = 0;
	}
	current_buf_start = buf_start;

	/* copy bytes from the working buffer into the pages */
	while (working_bytes > 0) {
1099 1100
		bytes = min_t(unsigned long, bvec.bv_len,
				PAGE_SIZE - buf_offset);
1101
		bytes = min(bytes, working_bytes);
1102 1103 1104

		kaddr = kmap_atomic(bvec.bv_page);
		memcpy(kaddr + bvec.bv_offset, buf + buf_offset, bytes);
1105
		kunmap_atomic(kaddr);
1106
		flush_dcache_page(bvec.bv_page);
1107 1108 1109 1110 1111 1112

		buf_offset += bytes;
		working_bytes -= bytes;
		current_buf_start += bytes;

		/* check if we need to pick another page */
1113 1114 1115 1116
		bio_advance(bio, bytes);
		if (!bio->bi_iter.bi_size)
			return 0;
		bvec = bio_iter_iovec(bio, bio->bi_iter);
1117
		prev_start_byte = start_byte;
1118
		start_byte = page_offset(bvec.bv_page) - disk_start;
1119

1120
		/*
1121 1122 1123 1124
		 * We need to make sure we're only adjusting
		 * our offset into compression working buffer when
		 * we're switching pages.  Otherwise we can incorrectly
		 * keep copying when we were actually done.
1125
		 */
1126 1127 1128 1129 1130 1131 1132
		if (start_byte != prev_start_byte) {
			/*
			 * make sure our new page is covered by this
			 * working buffer
			 */
			if (total_out <= start_byte)
				return 1;
1133

1134 1135 1136 1137 1138 1139 1140 1141 1142 1143 1144
			/*
			 * the next page in the biovec might not be adjacent
			 * to the last page, but it might still be found
			 * inside this working buffer. bump our offset pointer
			 */
			if (total_out > start_byte &&
			    current_buf_start < start_byte) {
				buf_offset = start_byte - buf_start;
				working_bytes = total_out - start_byte;
				current_buf_start = buf_start + buf_offset;
			}
1145 1146 1147 1148 1149
		}
	}

	return 1;
}
1150

1151 1152 1153
/*
 * Shannon Entropy calculation
 *
1154
 * Pure byte distribution analysis fails to determine compressibility of data.
1155 1156 1157 1158 1159 1160 1161 1162 1163 1164 1165 1166 1167 1168 1169 1170 1171 1172 1173 1174 1175 1176 1177 1178 1179 1180 1181 1182 1183 1184 1185 1186 1187 1188 1189 1190 1191 1192 1193 1194 1195 1196 1197 1198 1199 1200 1201 1202 1203
 * Try calculating entropy to estimate the average minimum number of bits
 * needed to encode the sampled data.
 *
 * For convenience, return the percentage of needed bits, instead of amount of
 * bits directly.
 *
 * @ENTROPY_LVL_ACEPTABLE - below that threshold, sample has low byte entropy
 *			    and can be compressible with high probability
 *
 * @ENTROPY_LVL_HIGH - data are not compressible with high probability
 *
 * Use of ilog2() decreases precision, we lower the LVL to 5 to compensate.
 */
#define ENTROPY_LVL_ACEPTABLE		(65)
#define ENTROPY_LVL_HIGH		(80)

/*
 * For increasead precision in shannon_entropy calculation,
 * let's do pow(n, M) to save more digits after comma:
 *
 * - maximum int bit length is 64
 * - ilog2(MAX_SAMPLE_SIZE)	-> 13
 * - 13 * 4 = 52 < 64		-> M = 4
 *
 * So use pow(n, 4).
 */
static inline u32 ilog2_w(u64 n)
{
	return ilog2(n * n * n * n);
}

static u32 shannon_entropy(struct heuristic_ws *ws)
{
	const u32 entropy_max = 8 * ilog2_w(2);
	u32 entropy_sum = 0;
	u32 p, p_base, sz_base;
	u32 i;

	sz_base = ilog2_w(ws->sample_size);
	for (i = 0; i < BUCKET_SIZE && ws->bucket[i].count > 0; i++) {
		p = ws->bucket[i].count;
		p_base = ilog2_w(p);
		entropy_sum += p * (sz_base - p_base);
	}

	entropy_sum /= ws->sample_size;
	return entropy_sum * 100 / entropy_max;
}

1204 1205 1206 1207 1208 1209 1210 1211 1212 1213 1214 1215 1216 1217
#define RADIX_BASE		4U
#define COUNTERS_SIZE		(1U << RADIX_BASE)

static u8 get4bits(u64 num, int shift) {
	u8 low4bits;

	num >>= shift;
	/* Reverse order */
	low4bits = (COUNTERS_SIZE - 1) - (num % COUNTERS_SIZE);
	return low4bits;
}

/*
 * Use 4 bits as radix base
1218
 * Use 16 u32 counters for calculating new position in buf array
1219 1220 1221 1222 1223 1224
 *
 * @array     - array that will be sorted
 * @array_buf - buffer array to store sorting results
 *              must be equal in size to @array
 * @num       - array size
 */
1225
static void radix_sort(struct bucket_item *array, struct bucket_item *array_buf,
1226
		       int num)
1227
{
1228 1229 1230 1231 1232 1233 1234 1235
	u64 max_num;
	u64 buf_num;
	u32 counters[COUNTERS_SIZE];
	u32 new_addr;
	u32 addr;
	int bitlen;
	int shift;
	int i;
1236

1237 1238 1239 1240
	/*
	 * Try avoid useless loop iterations for small numbers stored in big
	 * counters.  Example: 48 33 4 ... in 64bit array
	 */
1241
	max_num = array[0].count;
1242
	for (i = 1; i < num; i++) {
1243
		buf_num = array[i].count;
1244 1245 1246 1247 1248 1249 1250 1251 1252 1253 1254 1255
		if (buf_num > max_num)
			max_num = buf_num;
	}

	buf_num = ilog2(max_num);
	bitlen = ALIGN(buf_num, RADIX_BASE * 2);

	shift = 0;
	while (shift < bitlen) {
		memset(counters, 0, sizeof(counters));

		for (i = 0; i < num; i++) {
1256
			buf_num = array[i].count;
1257 1258 1259 1260 1261 1262 1263 1264
			addr = get4bits(buf_num, shift);
			counters[addr]++;
		}

		for (i = 1; i < COUNTERS_SIZE; i++)
			counters[i] += counters[i - 1];

		for (i = num - 1; i >= 0; i--) {
1265
			buf_num = array[i].count;
1266 1267 1268
			addr = get4bits(buf_num, shift);
			counters[addr]--;
			new_addr = counters[addr];
1269
			array_buf[new_addr] = array[i];
1270 1271 1272 1273 1274 1275 1276 1277 1278 1279 1280 1281 1282
		}

		shift += RADIX_BASE;

		/*
		 * Normal radix expects to move data from a temporary array, to
		 * the main one.  But that requires some CPU time. Avoid that
		 * by doing another sort iteration to original array instead of
		 * memcpy()
		 */
		memset(counters, 0, sizeof(counters));

		for (i = 0; i < num; i ++) {
1283
			buf_num = array_buf[i].count;
1284 1285 1286 1287 1288 1289 1290 1291
			addr = get4bits(buf_num, shift);
			counters[addr]++;
		}

		for (i = 1; i < COUNTERS_SIZE; i++)
			counters[i] += counters[i - 1];

		for (i = num - 1; i >= 0; i--) {
1292
			buf_num = array_buf[i].count;
1293 1294 1295
			addr = get4bits(buf_num, shift);
			counters[addr]--;
			new_addr = counters[addr];
1296
			array[new_addr] = array_buf[i];
1297 1298 1299 1300
		}

		shift += RADIX_BASE;
	}
1301 1302 1303 1304 1305 1306 1307 1308 1309 1310 1311 1312 1313 1314 1315 1316 1317 1318 1319 1320 1321 1322 1323 1324 1325 1326 1327 1328 1329
}

/*
 * Size of the core byte set - how many bytes cover 90% of the sample
 *
 * There are several types of structured binary data that use nearly all byte
 * values. The distribution can be uniform and counts in all buckets will be
 * nearly the same (eg. encrypted data). Unlikely to be compressible.
 *
 * Other possibility is normal (Gaussian) distribution, where the data could
 * be potentially compressible, but we have to take a few more steps to decide
 * how much.
 *
 * @BYTE_CORE_SET_LOW  - main part of byte values repeated frequently,
 *                       compression algo can easy fix that
 * @BYTE_CORE_SET_HIGH - data have uniform distribution and with high
 *                       probability is not compressible
 */
#define BYTE_CORE_SET_LOW		(64)
#define BYTE_CORE_SET_HIGH		(200)

static int byte_core_set_size(struct heuristic_ws *ws)
{
	u32 i;
	u32 coreset_sum = 0;
	const u32 core_set_threshold = ws->sample_size * 90 / 100;
	struct bucket_item *bucket = ws->bucket;

	/* Sort in reverse order */
1330
	radix_sort(ws->bucket, ws->bucket_b, BUCKET_SIZE);
1331 1332 1333 1334 1335 1336 1337 1338 1339 1340 1341 1342 1343 1344 1345 1346

	for (i = 0; i < BYTE_CORE_SET_LOW; i++)
		coreset_sum += bucket[i].count;

	if (coreset_sum > core_set_threshold)
		return i;

	for (; i < BYTE_CORE_SET_HIGH && bucket[i].count > 0; i++) {
		coreset_sum += bucket[i].count;
		if (coreset_sum > core_set_threshold)
			break;
	}

	return i;
}

1347 1348 1349 1350 1351 1352 1353 1354 1355 1356 1357 1358 1359 1360 1361 1362 1363 1364 1365 1366 1367 1368 1369 1370 1371 1372 1373 1374 1375 1376 1377 1378 1379 1380 1381 1382 1383 1384 1385
/*
 * Count byte values in buckets.
 * This heuristic can detect textual data (configs, xml, json, html, etc).
 * Because in most text-like data byte set is restricted to limited number of
 * possible characters, and that restriction in most cases makes data easy to
 * compress.
 *
 * @BYTE_SET_THRESHOLD - consider all data within this byte set size:
 *	less - compressible
 *	more - need additional analysis
 */
#define BYTE_SET_THRESHOLD		(64)

static u32 byte_set_size(const struct heuristic_ws *ws)
{
	u32 i;
	u32 byte_set_size = 0;

	for (i = 0; i < BYTE_SET_THRESHOLD; i++) {
		if (ws->bucket[i].count > 0)
			byte_set_size++;
	}

	/*
	 * Continue collecting count of byte values in buckets.  If the byte
	 * set size is bigger then the threshold, it's pointless to continue,
	 * the detection technique would fail for this type of data.
	 */
	for (; i < BUCKET_SIZE; i++) {
		if (ws->bucket[i].count > 0) {
			byte_set_size++;
			if (byte_set_size > BYTE_SET_THRESHOLD)
				return byte_set_size;
		}
	}

	return byte_set_size;
}

1386 1387 1388 1389 1390 1391 1392 1393
static bool sample_repeated_patterns(struct heuristic_ws *ws)
{
	const u32 half_of_sample = ws->sample_size / 2;
	const u8 *data = ws->sample;

	return memcmp(&data[0], &data[half_of_sample], half_of_sample) == 0;
}

1394 1395 1396 1397 1398 1399 1400 1401 1402 1403 1404 1405 1406 1407 1408 1409 1410 1411 1412 1413 1414 1415 1416 1417 1418 1419 1420 1421 1422 1423 1424 1425 1426 1427 1428 1429 1430 1431 1432 1433 1434 1435 1436 1437 1438 1439 1440 1441 1442 1443 1444 1445
static void heuristic_collect_sample(struct inode *inode, u64 start, u64 end,
				     struct heuristic_ws *ws)
{
	struct page *page;
	u64 index, index_end;
	u32 i, curr_sample_pos;
	u8 *in_data;

	/*
	 * Compression handles the input data by chunks of 128KiB
	 * (defined by BTRFS_MAX_UNCOMPRESSED)
	 *
	 * We do the same for the heuristic and loop over the whole range.
	 *
	 * MAX_SAMPLE_SIZE - calculated under assumption that heuristic will
	 * process no more than BTRFS_MAX_UNCOMPRESSED at a time.
	 */
	if (end - start > BTRFS_MAX_UNCOMPRESSED)
		end = start + BTRFS_MAX_UNCOMPRESSED;

	index = start >> PAGE_SHIFT;
	index_end = end >> PAGE_SHIFT;

	/* Don't miss unaligned end */
	if (!IS_ALIGNED(end, PAGE_SIZE))
		index_end++;

	curr_sample_pos = 0;
	while (index < index_end) {
		page = find_get_page(inode->i_mapping, index);
		in_data = kmap(page);
		/* Handle case where the start is not aligned to PAGE_SIZE */
		i = start % PAGE_SIZE;
		while (i < PAGE_SIZE - SAMPLING_READ_SIZE) {
			/* Don't sample any garbage from the last page */
			if (start > end - SAMPLING_READ_SIZE)
				break;
			memcpy(&ws->sample[curr_sample_pos], &in_data[i],
					SAMPLING_READ_SIZE);
			i += SAMPLING_INTERVAL;
			start += SAMPLING_INTERVAL;
			curr_sample_pos += SAMPLING_READ_SIZE;
		}
		kunmap(page);
		put_page(page);

		index++;
	}

	ws->sample_size = curr_sample_pos;
}

1446 1447 1448 1449 1450 1451 1452 1453 1454 1455 1456 1457 1458 1459 1460 1461 1462
/*
 * Compression heuristic.
 *
 * For now is's a naive and optimistic 'return true', we'll extend the logic to
 * quickly (compared to direct compression) detect data characteristics
 * (compressible/uncompressible) to avoid wasting CPU time on uncompressible
 * data.
 *
 * The following types of analysis can be performed:
 * - detect mostly zero data
 * - detect data with low "byte set" size (text, etc)
 * - detect data with low/high "core byte" set
 *
 * Return non-zero if the compression should be done, 0 otherwise.
 */
int btrfs_compress_heuristic(struct inode *inode, u64 start, u64 end)
{
1463
	struct list_head *ws_list = find_workspace(0);
1464
	struct heuristic_ws *ws;
1465 1466
	u32 i;
	u8 byte;
1467
	int ret = 0;
1468

1469 1470
	ws = list_entry(ws_list, struct heuristic_ws, list);

1471 1472
	heuristic_collect_sample(inode, start, end, ws);

1473 1474 1475 1476 1477
	if (sample_repeated_patterns(ws)) {
		ret = 1;
		goto out;
	}

1478 1479 1480 1481 1482
	memset(ws->bucket, 0, sizeof(*ws->bucket)*BUCKET_SIZE);

	for (i = 0; i < ws->sample_size; i++) {
		byte = ws->sample[i];
		ws->bucket[byte].count++;
1483 1484
	}

1485 1486 1487 1488 1489 1490
	i = byte_set_size(ws);
	if (i < BYTE_SET_THRESHOLD) {
		ret = 2;
		goto out;
	}

1491 1492 1493 1494 1495 1496 1497 1498 1499 1500 1501
	i = byte_core_set_size(ws);
	if (i <= BYTE_CORE_SET_LOW) {
		ret = 3;
		goto out;
	}

	if (i >= BYTE_CORE_SET_HIGH) {
		ret = 0;
		goto out;
	}

1502 1503 1504 1505 1506 1507 1508 1509 1510 1511 1512 1513 1514 1515 1516 1517 1518 1519 1520 1521 1522 1523 1524 1525 1526 1527 1528 1529 1530
	i = shannon_entropy(ws);
	if (i <= ENTROPY_LVL_ACEPTABLE) {
		ret = 4;
		goto out;
	}

	/*
	 * For the levels below ENTROPY_LVL_HIGH, additional analysis would be
	 * needed to give green light to compression.
	 *
	 * For now just assume that compression at that level is not worth the
	 * resources because:
	 *
	 * 1. it is possible to defrag the data later
	 *
	 * 2. the data would turn out to be hardly compressible, eg. 150 byte
	 * values, every bucket has counter at level ~54. The heuristic would
	 * be confused. This can happen when data have some internal repeated
	 * patterns like "abbacbbc...". This can be detected by analyzing
	 * pairs of bytes, which is too costly.
	 */
	if (i < ENTROPY_LVL_HIGH) {
		ret = 5;
		goto out;
	} else {
		ret = 0;
		goto out;
	}

1531
out:
1532
	free_workspace(0, ws_list);
1533 1534
	return ret;
}
1535 1536 1537 1538 1539 1540

unsigned int btrfs_compress_str2level(const char *str)
{
	if (strncmp(str, "zlib", 4) != 0)
		return 0;

1541 1542 1543
	/* Accepted form: zlib:1 up to zlib:9 and nothing left after the number */
	if (str[4] == ':' && '1' <= str[5] && str[5] <= '9' && str[6] == 0)
		return str[5] - '0';
1544

1545
	return BTRFS_ZLIB_DEFAULT_LEVEL;
1546
}