OpenCloudOS-Kernel/fs/erofs/decompressor_deflate.c

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erofs: DEFLATE compression support Add DEFLATE compression as the 3rd supported algorithm. DEFLATE is a popular generic-purpose compression algorithm for quite long time (many advanced formats like gzip, zlib, zip, png are all based on that) as Apple documentation written "If you require interoperability with non-Apple devices, use COMPRESSION_ZLIB. [1]". Due to its popularity, there are several hardware on-market DEFLATE accelerators, such as (s390) DFLTCC, (Intel) IAA/QAT, (HiSilicon) ZIP accelerator, etc. In addition, there are also several high-performence IP cores and even open-source FPGA approches available for DEFLATE. Therefore, it's useful to support DEFLATE compression in order to find a way to utilize these accelerators for asynchronous I/Os and get benefits from these later. Besides, it's a good choice to trade off between compression ratios and performance compared to LZ4 and LZMA. The DEFLATE core format is simple as well as easy to understand, therefore the code size of its decompressor is small even for the bootloader use cases. The runtime memory consumption is quite limited too (e.g. 32K + ~7K for each zlib stream). As usual, EROFS ourperforms similar approaches too. Alternatively, DEFLATE could still be used for some specific files since EROFS supports multiple compression algorithms in one image. [1] https://developer.apple.com/documentation/compression/compression_algorithm Reviewed-by: Chao Yu <chao@kernel.org> Signed-off-by: Gao Xiang <hsiangkao@linux.alibaba.com> Link: https://lore.kernel.org/r/20230810154859.118330-1-hsiangkao@linux.alibaba.com
2023-08-10 23:48:59 +08:00
// SPDX-License-Identifier: GPL-2.0-or-later
#include <linux/module.h>
#include <linux/zlib.h>
#include "compress.h"
struct z_erofs_deflate {
struct z_erofs_deflate *next;
struct z_stream_s z;
u8 bounce[PAGE_SIZE];
};
static DEFINE_SPINLOCK(z_erofs_deflate_lock);
static unsigned int z_erofs_deflate_nstrms, z_erofs_deflate_avail_strms;
static struct z_erofs_deflate *z_erofs_deflate_head;
static DECLARE_WAIT_QUEUE_HEAD(z_erofs_deflate_wq);
module_param_named(deflate_streams, z_erofs_deflate_nstrms, uint, 0444);
void z_erofs_deflate_exit(void)
{
/* there should be no running fs instance */
while (z_erofs_deflate_avail_strms) {
struct z_erofs_deflate *strm;
spin_lock(&z_erofs_deflate_lock);
strm = z_erofs_deflate_head;
if (!strm) {
spin_unlock(&z_erofs_deflate_lock);
continue;
}
z_erofs_deflate_head = NULL;
spin_unlock(&z_erofs_deflate_lock);
while (strm) {
struct z_erofs_deflate *n = strm->next;
vfree(strm->z.workspace);
kfree(strm);
--z_erofs_deflate_avail_strms;
strm = n;
}
}
}
int __init z_erofs_deflate_init(void)
{
/* by default, use # of possible CPUs instead */
if (!z_erofs_deflate_nstrms)
z_erofs_deflate_nstrms = num_possible_cpus();
for (; z_erofs_deflate_avail_strms < z_erofs_deflate_nstrms;
++z_erofs_deflate_avail_strms) {
struct z_erofs_deflate *strm;
strm = kzalloc(sizeof(*strm), GFP_KERNEL);
if (!strm)
goto out_failed;
/* XXX: in-kernel zlib cannot shrink windowbits currently */
strm->z.workspace = vmalloc(zlib_inflate_workspacesize());
if (!strm->z.workspace) {
kfree(strm);
goto out_failed;
}
spin_lock(&z_erofs_deflate_lock);
strm->next = z_erofs_deflate_head;
z_erofs_deflate_head = strm;
spin_unlock(&z_erofs_deflate_lock);
}
return 0;
out_failed:
pr_err("failed to allocate zlib workspace\n");
z_erofs_deflate_exit();
return -ENOMEM;
}
int z_erofs_load_deflate_config(struct super_block *sb,
struct erofs_super_block *dsb,
struct z_erofs_deflate_cfgs *dfl, int size)
{
if (!dfl || size < sizeof(struct z_erofs_deflate_cfgs)) {
erofs_err(sb, "invalid deflate cfgs, size=%u", size);
return -EINVAL;
}
if (dfl->windowbits > MAX_WBITS) {
erofs_err(sb, "unsupported windowbits %u", dfl->windowbits);
return -EOPNOTSUPP;
}
erofs_info(sb, "EXPERIMENTAL DEFLATE feature in use. Use at your own risk!");
return 0;
}
int z_erofs_deflate_decompress(struct z_erofs_decompress_req *rq,
struct page **pagepool)
{
const unsigned int nrpages_out =
PAGE_ALIGN(rq->pageofs_out + rq->outputsize) >> PAGE_SHIFT;
const unsigned int nrpages_in =
PAGE_ALIGN(rq->inputsize) >> PAGE_SHIFT;
struct super_block *sb = rq->sb;
unsigned int insz, outsz, pofs;
struct z_erofs_deflate *strm;
u8 *kin, *kout = NULL;
bool bounced = false;
int no = -1, ni = 0, j = 0, zerr, err;
/* 1. get the exact DEFLATE compressed size */
kin = kmap_local_page(*rq->in);
err = z_erofs_fixup_insize(rq, kin + rq->pageofs_in,
min_t(unsigned int, rq->inputsize,
sb->s_blocksize - rq->pageofs_in));
if (err) {
kunmap_local(kin);
return err;
}
/* 2. get an available DEFLATE context */
again:
spin_lock(&z_erofs_deflate_lock);
strm = z_erofs_deflate_head;
if (!strm) {
spin_unlock(&z_erofs_deflate_lock);
wait_event(z_erofs_deflate_wq, READ_ONCE(z_erofs_deflate_head));
goto again;
}
z_erofs_deflate_head = strm->next;
spin_unlock(&z_erofs_deflate_lock);
/* 3. multi-call decompress */
insz = rq->inputsize;
outsz = rq->outputsize;
zerr = zlib_inflateInit2(&strm->z, -MAX_WBITS);
if (zerr != Z_OK) {
err = -EIO;
goto failed_zinit;
}
pofs = rq->pageofs_out;
strm->z.avail_in = min_t(u32, insz, PAGE_SIZE - rq->pageofs_in);
insz -= strm->z.avail_in;
strm->z.next_in = kin + rq->pageofs_in;
strm->z.avail_out = 0;
while (1) {
if (!strm->z.avail_out) {
if (++no >= nrpages_out || !outsz) {
erofs_err(sb, "insufficient space for decompressed data");
err = -EFSCORRUPTED;
break;
}
if (kout)
kunmap_local(kout);
strm->z.avail_out = min_t(u32, outsz, PAGE_SIZE - pofs);
outsz -= strm->z.avail_out;
if (!rq->out[no]) {
rq->out[no] = erofs_allocpage(pagepool,
GFP_KERNEL | __GFP_NOFAIL);
set_page_private(rq->out[no],
Z_EROFS_SHORTLIVED_PAGE);
}
kout = kmap_local_page(rq->out[no]);
strm->z.next_out = kout + pofs;
pofs = 0;
}
if (!strm->z.avail_in && insz) {
if (++ni >= nrpages_in) {
erofs_err(sb, "invalid compressed data");
err = -EFSCORRUPTED;
break;
}
if (kout) { /* unlike kmap(), take care of the orders */
j = strm->z.next_out - kout;
kunmap_local(kout);
}
kunmap_local(kin);
strm->z.avail_in = min_t(u32, insz, PAGE_SIZE);
insz -= strm->z.avail_in;
kin = kmap_local_page(rq->in[ni]);
strm->z.next_in = kin;
bounced = false;
if (kout) {
kout = kmap_local_page(rq->out[no]);
strm->z.next_out = kout + j;
}
}
/*
* Handle overlapping: Use bounced buffer if the compressed
* data is under processing; Or use short-lived pages from the
* on-stack pagepool where pages share among the same request
* and not _all_ inplace I/O pages are needed to be doubled.
*/
if (!bounced && rq->out[no] == rq->in[ni]) {
memcpy(strm->bounce, strm->z.next_in, strm->z.avail_in);
strm->z.next_in = strm->bounce;
bounced = true;
}
for (j = ni + 1; j < nrpages_in; ++j) {
struct page *tmppage;
if (rq->out[no] != rq->in[j])
continue;
DBG_BUGON(erofs_page_is_managed(EROFS_SB(sb),
rq->in[j]));
tmppage = erofs_allocpage(pagepool,
GFP_KERNEL | __GFP_NOFAIL);
set_page_private(tmppage, Z_EROFS_SHORTLIVED_PAGE);
copy_highpage(tmppage, rq->in[j]);
rq->in[j] = tmppage;
}
zerr = zlib_inflate(&strm->z, Z_SYNC_FLUSH);
if (zerr != Z_OK || !(outsz + strm->z.avail_out)) {
if (zerr == Z_OK && rq->partial_decoding)
break;
if (zerr == Z_STREAM_END && !outsz)
break;
erofs_err(sb, "failed to decompress %d in[%u] out[%u]",
zerr, rq->inputsize, rq->outputsize);
err = -EFSCORRUPTED;
break;
}
}
if (zlib_inflateEnd(&strm->z) != Z_OK && !err)
err = -EIO;
if (kout)
kunmap_local(kout);
failed_zinit:
kunmap_local(kin);
/* 4. push back DEFLATE stream context to the global list */
spin_lock(&z_erofs_deflate_lock);
strm->next = z_erofs_deflate_head;
z_erofs_deflate_head = strm;
spin_unlock(&z_erofs_deflate_lock);
wake_up(&z_erofs_deflate_wq);
return err;
}