mirror_zfs/module/os/linux/zfs/qat_compress.c

551 lines
15 KiB
C
Raw Normal View History

/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
#if defined(_KERNEL) && defined(HAVE_QAT)
#include <linux/slab.h>
#include <linux/vmalloc.h>
#include <linux/pagemap.h>
#include <linux/completion.h>
#include <sys/zfs_context.h>
#include <sys/byteorder.h>
#include <sys/zio.h>
#include <sys/qat.h>
/*
* Max instances in a QAT device, each instance is a channel to submit
* jobs to QAT hardware, this is only for pre-allocating instance and
* session arrays; the actual number of instances are defined in the
* QAT driver's configuration file.
*/
#define QAT_DC_MAX_INSTANCES 48
/*
* ZLIB head and foot size
*/
#define ZLIB_HEAD_SZ 2
#define ZLIB_FOOT_SZ 4
static CpaInstanceHandle dc_inst_handles[QAT_DC_MAX_INSTANCES];
static CpaDcSessionHandle session_handles[QAT_DC_MAX_INSTANCES];
static CpaBufferList **buffer_array[QAT_DC_MAX_INSTANCES];
static Cpa16U num_inst = 0;
static Cpa32U inst_num = 0;
static boolean_t qat_dc_init_done = B_FALSE;
int zfs_qat_compress_disable = 0;
boolean_t
qat_dc_use_accel(size_t s_len)
{
return (!zfs_qat_compress_disable &&
qat_dc_init_done &&
s_len >= QAT_MIN_BUF_SIZE &&
s_len <= QAT_MAX_BUF_SIZE);
}
static void
qat_dc_callback(void *p_callback, CpaStatus status)
{
if (p_callback != NULL)
complete((struct completion *)p_callback);
}
static void
qat_dc_clean(void)
{
Cpa16U buff_num = 0;
Cpa16U num_inter_buff_lists = 0;
for (Cpa16U i = 0; i < num_inst; i++) {
cpaDcStopInstance(dc_inst_handles[i]);
QAT_PHYS_CONTIG_FREE(session_handles[i]);
/* free intermediate buffers */
if (buffer_array[i] != NULL) {
cpaDcGetNumIntermediateBuffers(
dc_inst_handles[i], &num_inter_buff_lists);
for (buff_num = 0; buff_num < num_inter_buff_lists;
buff_num++) {
CpaBufferList *buffer_inter =
buffer_array[i][buff_num];
if (buffer_inter->pBuffers) {
QAT_PHYS_CONTIG_FREE(
buffer_inter->pBuffers->pData);
QAT_PHYS_CONTIG_FREE(
buffer_inter->pBuffers);
}
QAT_PHYS_CONTIG_FREE(
buffer_inter->pPrivateMetaData);
QAT_PHYS_CONTIG_FREE(buffer_inter);
}
}
}
num_inst = 0;
qat_dc_init_done = B_FALSE;
}
int
qat_dc_init(void)
{
CpaStatus status = CPA_STATUS_SUCCESS;
Cpa32U sess_size = 0;
Cpa32U ctx_size = 0;
Cpa16U num_inter_buff_lists = 0;
Cpa16U buff_num = 0;
Cpa32U buff_meta_size = 0;
CpaDcSessionSetupData sd = {0};
if (qat_dc_init_done)
return (0);
status = cpaDcGetNumInstances(&num_inst);
if (status != CPA_STATUS_SUCCESS)
return (-1);
/* if the user has configured no QAT compression units just return */
if (num_inst == 0)
return (0);
if (num_inst > QAT_DC_MAX_INSTANCES)
num_inst = QAT_DC_MAX_INSTANCES;
status = cpaDcGetInstances(num_inst, &dc_inst_handles[0]);
if (status != CPA_STATUS_SUCCESS)
return (-1);
for (Cpa16U i = 0; i < num_inst; i++) {
cpaDcSetAddressTranslation(dc_inst_handles[i],
(void*)virt_to_phys);
status = cpaDcBufferListGetMetaSize(dc_inst_handles[i],
1, &buff_meta_size);
if (status == CPA_STATUS_SUCCESS)
status = cpaDcGetNumIntermediateBuffers(
dc_inst_handles[i], &num_inter_buff_lists);
if (status == CPA_STATUS_SUCCESS && num_inter_buff_lists != 0)
status = QAT_PHYS_CONTIG_ALLOC(&buffer_array[i],
num_inter_buff_lists *
sizeof (CpaBufferList *));
for (buff_num = 0; buff_num < num_inter_buff_lists;
buff_num++) {
if (status == CPA_STATUS_SUCCESS)
status = QAT_PHYS_CONTIG_ALLOC(
&buffer_array[i][buff_num],
sizeof (CpaBufferList));
if (status == CPA_STATUS_SUCCESS)
status = QAT_PHYS_CONTIG_ALLOC(
&buffer_array[i][buff_num]->
pPrivateMetaData,
buff_meta_size);
if (status == CPA_STATUS_SUCCESS)
status = QAT_PHYS_CONTIG_ALLOC(
&buffer_array[i][buff_num]->pBuffers,
sizeof (CpaFlatBuffer));
if (status == CPA_STATUS_SUCCESS) {
/*
* implementation requires an intermediate
* buffer approximately twice the size of
* output buffer, which is 2x max buffer
* size here.
*/
status = QAT_PHYS_CONTIG_ALLOC(
&buffer_array[i][buff_num]->pBuffers->
pData, 2 * QAT_MAX_BUF_SIZE);
if (status != CPA_STATUS_SUCCESS)
goto fail;
buffer_array[i][buff_num]->numBuffers = 1;
buffer_array[i][buff_num]->pBuffers->
dataLenInBytes = 2 * QAT_MAX_BUF_SIZE;
}
}
status = cpaDcStartInstance(dc_inst_handles[i],
num_inter_buff_lists, buffer_array[i]);
if (status != CPA_STATUS_SUCCESS)
goto fail;
sd.compLevel = CPA_DC_L1;
sd.compType = CPA_DC_DEFLATE;
sd.huffType = CPA_DC_HT_FULL_DYNAMIC;
sd.sessDirection = CPA_DC_DIR_COMBINED;
sd.sessState = CPA_DC_STATELESS;
sd.deflateWindowSize = 7;
sd.checksum = CPA_DC_ADLER32;
status = cpaDcGetSessionSize(dc_inst_handles[i],
&sd, &sess_size, &ctx_size);
if (status != CPA_STATUS_SUCCESS)
goto fail;
QAT_PHYS_CONTIG_ALLOC(&session_handles[i], sess_size);
if (session_handles[i] == NULL)
goto fail;
status = cpaDcInitSession(dc_inst_handles[i],
session_handles[i],
&sd, NULL, qat_dc_callback);
if (status != CPA_STATUS_SUCCESS)
goto fail;
}
qat_dc_init_done = B_TRUE;
return (0);
fail:
qat_dc_clean();
return (-1);
}
void
qat_dc_fini(void)
{
if (!qat_dc_init_done)
return;
qat_dc_clean();
}
/*
* The "add" parameter is an additional buffer which is passed
* to QAT as a scratch buffer alongside the destination buffer
* in case the "compressed" data ends up being larger than the
* original source data. This is necessary to prevent QAT from
* generating buffer overflow warnings for incompressible data.
*/
static int
qat_compress_impl(qat_compress_dir_t dir, char *src, int src_len,
char *dst, int dst_len, char *add, int add_len, size_t *c_len)
{
CpaInstanceHandle dc_inst_handle;
CpaDcSessionHandle session_handle;
CpaBufferList *buf_list_src = NULL;
CpaBufferList *buf_list_dst = NULL;
CpaFlatBuffer *flat_buf_src = NULL;
CpaFlatBuffer *flat_buf_dst = NULL;
Cpa8U *buffer_meta_src = NULL;
Cpa8U *buffer_meta_dst = NULL;
Cpa32U buffer_meta_size = 0;
CpaDcRqResults dc_results;
CpaStatus status = CPA_STATUS_FAIL;
Cpa32U hdr_sz = 0;
Cpa32U compressed_sz;
Cpa32U num_src_buf = (src_len >> PAGE_SHIFT) + 2;
Cpa32U num_dst_buf = (dst_len >> PAGE_SHIFT) + 2;
Cpa32U num_add_buf = (add_len >> PAGE_SHIFT) + 2;
Cpa32U bytes_left;
Cpa32U dst_pages = 0;
Cpa32U adler32 = 0;
char *data;
struct page *page;
struct page **in_pages = NULL;
struct page **out_pages = NULL;
struct page **add_pages = NULL;
Cpa32U page_off = 0;
struct completion complete;
Cpa32U page_num = 0;
Cpa16U i;
/*
* We increment num_src_buf and num_dst_buf by 2 to allow
* us to handle non page-aligned buffer addresses and buffers
* whose sizes are not divisible by PAGE_SIZE.
*/
Cpa32U src_buffer_list_mem_size = sizeof (CpaBufferList) +
(num_src_buf * sizeof (CpaFlatBuffer));
Cpa32U dst_buffer_list_mem_size = sizeof (CpaBufferList) +
((num_dst_buf + num_add_buf) * sizeof (CpaFlatBuffer));
status = QAT_PHYS_CONTIG_ALLOC(&in_pages,
num_src_buf * sizeof (struct page *));
if (status != CPA_STATUS_SUCCESS)
goto fail;
status = QAT_PHYS_CONTIG_ALLOC(&out_pages,
num_dst_buf * sizeof (struct page *));
if (status != CPA_STATUS_SUCCESS)
goto fail;
status = QAT_PHYS_CONTIG_ALLOC(&add_pages,
num_add_buf * sizeof (struct page *));
if (status != CPA_STATUS_SUCCESS)
goto fail;
i = (Cpa32U)atomic_inc_32_nv(&inst_num) % num_inst;
dc_inst_handle = dc_inst_handles[i];
session_handle = session_handles[i];
cpaDcBufferListGetMetaSize(dc_inst_handle, num_src_buf,
&buffer_meta_size);
status = QAT_PHYS_CONTIG_ALLOC(&buffer_meta_src, buffer_meta_size);
if (status != CPA_STATUS_SUCCESS)
goto fail;
cpaDcBufferListGetMetaSize(dc_inst_handle, num_dst_buf + num_add_buf,
&buffer_meta_size);
status = QAT_PHYS_CONTIG_ALLOC(&buffer_meta_dst, buffer_meta_size);
if (status != CPA_STATUS_SUCCESS)
goto fail;
/* build source buffer list */
status = QAT_PHYS_CONTIG_ALLOC(&buf_list_src, src_buffer_list_mem_size);
if (status != CPA_STATUS_SUCCESS)
goto fail;
flat_buf_src = (CpaFlatBuffer *)(buf_list_src + 1);
buf_list_src->pBuffers = flat_buf_src; /* always point to first one */
/* build destination buffer list */
status = QAT_PHYS_CONTIG_ALLOC(&buf_list_dst, dst_buffer_list_mem_size);
if (status != CPA_STATUS_SUCCESS)
goto fail;
flat_buf_dst = (CpaFlatBuffer *)(buf_list_dst + 1);
buf_list_dst->pBuffers = flat_buf_dst; /* always point to first one */
buf_list_src->numBuffers = 0;
buf_list_src->pPrivateMetaData = buffer_meta_src;
bytes_left = src_len;
data = src;
page_num = 0;
while (bytes_left > 0) {
page_off = ((long)data & ~PAGE_MASK);
page = qat_mem_to_page(data);
in_pages[page_num] = page;
flat_buf_src->pData = kmap(page) + page_off;
flat_buf_src->dataLenInBytes =
min((long)PAGE_SIZE - page_off, (long)bytes_left);
bytes_left -= flat_buf_src->dataLenInBytes;
data += flat_buf_src->dataLenInBytes;
flat_buf_src++;
buf_list_src->numBuffers++;
page_num++;
}
buf_list_dst->numBuffers = 0;
buf_list_dst->pPrivateMetaData = buffer_meta_dst;
bytes_left = dst_len;
data = dst;
page_num = 0;
while (bytes_left > 0) {
page_off = ((long)data & ~PAGE_MASK);
page = qat_mem_to_page(data);
flat_buf_dst->pData = kmap(page) + page_off;
out_pages[page_num] = page;
flat_buf_dst->dataLenInBytes =
min((long)PAGE_SIZE - page_off, (long)bytes_left);
bytes_left -= flat_buf_dst->dataLenInBytes;
data += flat_buf_dst->dataLenInBytes;
flat_buf_dst++;
buf_list_dst->numBuffers++;
page_num++;
dst_pages++;
}
/* map additional scratch pages into the destination buffer list */
bytes_left = add_len;
data = add;
page_num = 0;
while (bytes_left > 0) {
page_off = ((long)data & ~PAGE_MASK);
page = qat_mem_to_page(data);
flat_buf_dst->pData = kmap(page) + page_off;
add_pages[page_num] = page;
flat_buf_dst->dataLenInBytes =
min((long)PAGE_SIZE - page_off, (long)bytes_left);
bytes_left -= flat_buf_dst->dataLenInBytes;
data += flat_buf_dst->dataLenInBytes;
flat_buf_dst++;
buf_list_dst->numBuffers++;
page_num++;
}
init_completion(&complete);
if (dir == QAT_COMPRESS) {
QAT_STAT_BUMP(comp_requests);
QAT_STAT_INCR(comp_total_in_bytes, src_len);
cpaDcGenerateHeader(session_handle,
buf_list_dst->pBuffers, &hdr_sz);
buf_list_dst->pBuffers->pData += hdr_sz;
buf_list_dst->pBuffers->dataLenInBytes -= hdr_sz;
status = cpaDcCompressData(
dc_inst_handle, session_handle,
buf_list_src, buf_list_dst,
&dc_results, CPA_DC_FLUSH_FINAL,
&complete);
if (status != CPA_STATUS_SUCCESS) {
goto fail;
}
/* we now wait until the completion of the operation. */
wait_for_completion(&complete);
if (dc_results.status != CPA_STATUS_SUCCESS) {
status = CPA_STATUS_FAIL;
goto fail;
}
compressed_sz = dc_results.produced;
if (compressed_sz + hdr_sz + ZLIB_FOOT_SZ > dst_len) {
status = CPA_STATUS_INCOMPRESSIBLE;
goto fail;
}
/* get adler32 checksum and append footer */
*(Cpa32U*)(dst + hdr_sz + compressed_sz) =
BSWAP_32(dc_results.checksum);
*c_len = hdr_sz + compressed_sz + ZLIB_FOOT_SZ;
QAT_STAT_INCR(comp_total_out_bytes, *c_len);
} else {
ASSERT3U(dir, ==, QAT_DECOMPRESS);
QAT_STAT_BUMP(decomp_requests);
QAT_STAT_INCR(decomp_total_in_bytes, src_len);
buf_list_src->pBuffers->pData += ZLIB_HEAD_SZ;
buf_list_src->pBuffers->dataLenInBytes -= ZLIB_HEAD_SZ;
status = cpaDcDecompressData(dc_inst_handle, session_handle,
buf_list_src, buf_list_dst, &dc_results, CPA_DC_FLUSH_FINAL,
&complete);
if (CPA_STATUS_SUCCESS != status) {
status = CPA_STATUS_FAIL;
goto fail;
}
/* we now wait until the completion of the operation. */
wait_for_completion(&complete);
if (dc_results.status != CPA_STATUS_SUCCESS) {
status = CPA_STATUS_FAIL;
goto fail;
}
/* verify adler checksum */
adler32 = *(Cpa32U *)(src + dc_results.consumed + ZLIB_HEAD_SZ);
if (adler32 != BSWAP_32(dc_results.checksum)) {
status = CPA_STATUS_FAIL;
goto fail;
}
*c_len = dc_results.produced;
QAT_STAT_INCR(decomp_total_out_bytes, *c_len);
}
fail:
if (status != CPA_STATUS_SUCCESS && status != CPA_STATUS_INCOMPRESSIBLE)
QAT_STAT_BUMP(dc_fails);
if (in_pages) {
for (page_num = 0;
page_num < buf_list_src->numBuffers;
page_num++) {
kunmap(in_pages[page_num]);
}
QAT_PHYS_CONTIG_FREE(in_pages);
}
if (out_pages) {
for (page_num = 0; page_num < dst_pages; page_num++) {
kunmap(out_pages[page_num]);
}
QAT_PHYS_CONTIG_FREE(out_pages);
}
if (add_pages) {
for (page_num = 0;
page_num < buf_list_dst->numBuffers - dst_pages;
page_num++) {
kunmap(add_pages[page_num]);
}
QAT_PHYS_CONTIG_FREE(add_pages);
}
QAT_PHYS_CONTIG_FREE(buffer_meta_src);
QAT_PHYS_CONTIG_FREE(buffer_meta_dst);
QAT_PHYS_CONTIG_FREE(buf_list_src);
QAT_PHYS_CONTIG_FREE(buf_list_dst);
return (status);
}
/*
* Entry point for QAT accelerated compression / decompression.
*/
int
qat_compress(qat_compress_dir_t dir, char *src, int src_len,
char *dst, int dst_len, size_t *c_len)
{
int ret;
size_t add_len = 0;
void *add = NULL;
if (dir == QAT_COMPRESS) {
add_len = dst_len;
add = zio_data_buf_alloc(add_len);
}
ret = qat_compress_impl(dir, src, src_len, dst,
dst_len, add, add_len, c_len);
if (dir == QAT_COMPRESS)
zio_data_buf_free(add, add_len);
return (ret);
}
static int
param_set_qat_compress(const char *val, zfs_kernel_param_t *kp)
{
int ret;
int *pvalue = kp->arg;
ret = param_set_int(val, kp);
if (ret)
return (ret);
/*
* zfs_qat_compress_disable = 0: enable qat compress
* try to initialize qat instance if it has not been done
*/
if (*pvalue == 0 && !qat_dc_init_done) {
ret = qat_dc_init();
if (ret != 0) {
zfs_qat_compress_disable = 1;
return (ret);
}
}
return (ret);
}
module_param_call(zfs_qat_compress_disable, param_set_qat_compress,
param_get_int, &zfs_qat_compress_disable, 0644);
MODULE_PARM_DESC(zfs_qat_compress_disable, "Enable/Disable QAT compression");
#endif