numam-spdk/lib/util/dif.c

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/*-
* BSD LICENSE
*
* Copyright (c) Intel Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Intel Corporation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "spdk/dif.h"
#include "spdk/crc16.h"
#include "spdk/crc32.h"
#include "spdk/endian.h"
#include "spdk/log.h"
#include "spdk/util.h"
/* Context to iterate or create a iovec array.
* Each sgl is either iterated or created at a time.
*/
struct _dif_sgl {
/* Current iovec in the iteration or creation */
struct iovec *iov;
/* Remaining count of iovecs in the iteration or creation. */
int iovcnt;
/* Current offset in the iovec */
uint32_t iov_offset;
/* Size of the created iovec array in bytes */
uint32_t total_size;
};
static inline void
_dif_sgl_init(struct _dif_sgl *s, struct iovec *iovs, int iovcnt)
{
s->iov = iovs;
s->iovcnt = iovcnt;
s->iov_offset = 0;
s->total_size = 0;
}
static void
_dif_sgl_advance(struct _dif_sgl *s, uint32_t step)
{
s->iov_offset += step;
while (s->iovcnt != 0) {
if (s->iov_offset < s->iov->iov_len) {
break;
}
s->iov_offset -= s->iov->iov_len;
s->iov++;
s->iovcnt--;
}
}
static inline void
_dif_sgl_get_buf(struct _dif_sgl *s, void **_buf, uint32_t *_buf_len)
{
if (_buf != NULL) {
*_buf = s->iov->iov_base + s->iov_offset;
}
if (_buf_len != NULL) {
*_buf_len = s->iov->iov_len - s->iov_offset;
}
}
static inline bool
_dif_sgl_append(struct _dif_sgl *s, uint8_t *data, uint32_t data_len)
{
assert(s->iovcnt > 0);
s->iov->iov_base = data;
s->iov->iov_len = data_len;
s->total_size += data_len;
s->iov++;
s->iovcnt--;
if (s->iovcnt > 0) {
return true;
} else {
return false;
}
}
static inline bool
_dif_sgl_append_split(struct _dif_sgl *dst, struct _dif_sgl *src, uint32_t data_len)
{
uint8_t *buf;
uint32_t buf_len;
while (data_len != 0) {
_dif_sgl_get_buf(src, (void *)&buf, &buf_len);
buf_len = spdk_min(buf_len, data_len);
if (!_dif_sgl_append(dst, buf, buf_len)) {
return false;
}
_dif_sgl_advance(src, buf_len);
data_len -= buf_len;
}
return true;
}
/* This function must be used before starting iteration. */
static bool
_dif_sgl_is_bytes_multiple(struct _dif_sgl *s, uint32_t bytes)
{
int i;
for (i = 0; i < s->iovcnt; i++) {
if (s->iov[i].iov_len % bytes) {
return false;
}
}
return true;
}
/* This function must be used before starting iteration. */
static bool
_dif_sgl_is_valid(struct _dif_sgl *s, uint32_t bytes)
{
uint64_t total = 0;
int i;
for (i = 0; i < s->iovcnt; i++) {
total += s->iov[i].iov_len;
}
return total >= bytes;
}
dif: Add spdk_dif_remap_ref_tag to remap ref. tag for extended LBA payload When using stacked virtual bdev (e.g. split virtual bdev), block address space will be remapped during I/O processing and so reference tag will have to be remapped accordingly. The use case is explained in detail as follows: - Format a single NVMe SSD with DIF enabled. - Create a NVMe bdev on the NVMe SSD with DIF enabled. - Create four split vbdevs on the NVMe bdev. - Add the split vbdevs to a NVMe-oF target. - Application is aware of block address space of the split vbdevs. - Application submits read/write I/O to the NVMe-oF target. Case 1: - Configure NVMe-oF target to DIF pass-through. Case 2: - Configure NVMe-oF target to DIF insert/strip For the case 1, - Application inserts DIF for write I/O and verifies DIF for read I/O. - The split vbdevs remaps reference tags of DIF both for read and write I/O because application expects reference tags are based on the block address space of split vbdevs. - The NVMe bdev processs read/write I/Os without remapping reference tags because reference tags are already based on the block address space of the NVMe bdev. For the case 2, - NVMe-oF target inserts DIF for write I/O, and verifies and strips DIF or read I/O. - The split vbdevs remaps reference tags of DIF both for read and write I/O because NVMe-oF target expects reference tags are based on the block address space of split vbdevs. - The NVMe bdev processs read/write I/Os without remapping reference tags because reference tags are already based on the block address space of the NVMe bdev. This patch adds two APIs, spdk_dif_ctx_set_remapped_init_ref_tag and spdk_dif_remap_ref_tag to satisfy the use case. UT code is added together in this patch. Signed-off-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Change-Id: Ib3101129225b334d2f578eab75197790b1818770 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/461103 Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com> Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
2019-07-08 06:45:21 +00:00
static void
_dif_sgl_copy(struct _dif_sgl *to, struct _dif_sgl *from)
{
memcpy(to, from, sizeof(struct _dif_sgl));
}
static bool
_dif_type_is_valid(enum spdk_dif_type dif_type, uint32_t dif_flags)
{
switch (dif_type) {
case SPDK_DIF_TYPE1:
case SPDK_DIF_TYPE2:
case SPDK_DIF_DISABLE:
break;
case SPDK_DIF_TYPE3:
if (dif_flags & SPDK_DIF_FLAGS_REFTAG_CHECK) {
SPDK_ERRLOG("Reference Tag should not be checked for Type 3\n");
return false;
}
break;
default:
SPDK_ERRLOG("Unknown DIF Type: %d\n", dif_type);
return false;
}
return true;
}
static bool
_dif_is_disabled(enum spdk_dif_type dif_type)
{
if (dif_type == SPDK_DIF_DISABLE) {
return true;
} else {
return false;
}
}
static uint32_t
_get_guard_interval(uint32_t block_size, uint32_t md_size, bool dif_loc, bool md_interleave)
{
if (!dif_loc) {
/* For metadata formats with more than 8 bytes, if the DIF is
* contained in the last 8 bytes of metadata, then the CRC
* covers all metadata up to but excluding these last 8 bytes.
*/
if (md_interleave) {
return block_size - sizeof(struct spdk_dif);
} else {
return md_size - sizeof(struct spdk_dif);
}
} else {
/* For metadata formats with more than 8 bytes, if the DIF is
* contained in the first 8 bytes of metadata, then the CRC
* does not cover any metadata.
*/
if (md_interleave) {
return block_size - md_size;
} else {
return 0;
}
}
}
int
spdk_dif_ctx_init(struct spdk_dif_ctx *ctx, uint32_t block_size, uint32_t md_size,
bool md_interleave, bool dif_loc, enum spdk_dif_type dif_type, uint32_t dif_flags,
uint32_t init_ref_tag, uint16_t apptag_mask, uint16_t app_tag,
uint32_t data_offset, uint16_t guard_seed)
{
uint32_t data_block_size;
if (md_size < sizeof(struct spdk_dif)) {
SPDK_ERRLOG("Metadata size is smaller than DIF size.\n");
return -EINVAL;
}
if (md_interleave) {
if (block_size < md_size) {
SPDK_ERRLOG("Block size is smaller than DIF size.\n");
return -EINVAL;
}
data_block_size = block_size - md_size;
} else {
if (block_size == 0 || (block_size % 512) != 0) {
SPDK_ERRLOG("Zero block size is not allowed\n");
return -EINVAL;
}
data_block_size = block_size;
}
if (!_dif_type_is_valid(dif_type, dif_flags)) {
SPDK_ERRLOG("DIF type is invalid.\n");
return -EINVAL;
}
ctx->block_size = block_size;
ctx->md_size = md_size;
ctx->md_interleave = md_interleave;
ctx->guard_interval = _get_guard_interval(block_size, md_size, dif_loc, md_interleave);
ctx->dif_type = dif_type;
ctx->dif_flags = dif_flags;
ctx->init_ref_tag = init_ref_tag;
ctx->apptag_mask = apptag_mask;
ctx->app_tag = app_tag;
ctx->data_offset = data_offset;
ctx->ref_tag_offset = data_offset / data_block_size;
ctx->last_guard = guard_seed;
ctx->guard_seed = guard_seed;
dif: Add spdk_dif_remap_ref_tag to remap ref. tag for extended LBA payload When using stacked virtual bdev (e.g. split virtual bdev), block address space will be remapped during I/O processing and so reference tag will have to be remapped accordingly. The use case is explained in detail as follows: - Format a single NVMe SSD with DIF enabled. - Create a NVMe bdev on the NVMe SSD with DIF enabled. - Create four split vbdevs on the NVMe bdev. - Add the split vbdevs to a NVMe-oF target. - Application is aware of block address space of the split vbdevs. - Application submits read/write I/O to the NVMe-oF target. Case 1: - Configure NVMe-oF target to DIF pass-through. Case 2: - Configure NVMe-oF target to DIF insert/strip For the case 1, - Application inserts DIF for write I/O and verifies DIF for read I/O. - The split vbdevs remaps reference tags of DIF both for read and write I/O because application expects reference tags are based on the block address space of split vbdevs. - The NVMe bdev processs read/write I/Os without remapping reference tags because reference tags are already based on the block address space of the NVMe bdev. For the case 2, - NVMe-oF target inserts DIF for write I/O, and verifies and strips DIF or read I/O. - The split vbdevs remaps reference tags of DIF both for read and write I/O because NVMe-oF target expects reference tags are based on the block address space of split vbdevs. - The NVMe bdev processs read/write I/Os without remapping reference tags because reference tags are already based on the block address space of the NVMe bdev. This patch adds two APIs, spdk_dif_ctx_set_remapped_init_ref_tag and spdk_dif_remap_ref_tag to satisfy the use case. UT code is added together in this patch. Signed-off-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Change-Id: Ib3101129225b334d2f578eab75197790b1818770 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/461103 Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com> Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
2019-07-08 06:45:21 +00:00
ctx->remapped_init_ref_tag = 0;
return 0;
}
void
spdk_dif_ctx_set_data_offset(struct spdk_dif_ctx *ctx, uint32_t data_offset)
{
uint32_t data_block_size;
if (ctx->md_interleave) {
data_block_size = ctx->block_size - ctx->md_size;
} else {
data_block_size = ctx->block_size;
}
ctx->data_offset = data_offset;
ctx->ref_tag_offset = data_offset / data_block_size;
}
dif: Add spdk_dif_remap_ref_tag to remap ref. tag for extended LBA payload When using stacked virtual bdev (e.g. split virtual bdev), block address space will be remapped during I/O processing and so reference tag will have to be remapped accordingly. The use case is explained in detail as follows: - Format a single NVMe SSD with DIF enabled. - Create a NVMe bdev on the NVMe SSD with DIF enabled. - Create four split vbdevs on the NVMe bdev. - Add the split vbdevs to a NVMe-oF target. - Application is aware of block address space of the split vbdevs. - Application submits read/write I/O to the NVMe-oF target. Case 1: - Configure NVMe-oF target to DIF pass-through. Case 2: - Configure NVMe-oF target to DIF insert/strip For the case 1, - Application inserts DIF for write I/O and verifies DIF for read I/O. - The split vbdevs remaps reference tags of DIF both for read and write I/O because application expects reference tags are based on the block address space of split vbdevs. - The NVMe bdev processs read/write I/Os without remapping reference tags because reference tags are already based on the block address space of the NVMe bdev. For the case 2, - NVMe-oF target inserts DIF for write I/O, and verifies and strips DIF or read I/O. - The split vbdevs remaps reference tags of DIF both for read and write I/O because NVMe-oF target expects reference tags are based on the block address space of split vbdevs. - The NVMe bdev processs read/write I/Os without remapping reference tags because reference tags are already based on the block address space of the NVMe bdev. This patch adds two APIs, spdk_dif_ctx_set_remapped_init_ref_tag and spdk_dif_remap_ref_tag to satisfy the use case. UT code is added together in this patch. Signed-off-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Change-Id: Ib3101129225b334d2f578eab75197790b1818770 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/461103 Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com> Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
2019-07-08 06:45:21 +00:00
void
spdk_dif_ctx_set_remapped_init_ref_tag(struct spdk_dif_ctx *ctx,
uint32_t remapped_init_ref_tag)
{
ctx->remapped_init_ref_tag = remapped_init_ref_tag;
}
static void
_dif_generate(void *_dif, uint16_t guard, uint32_t offset_blocks,
const struct spdk_dif_ctx *ctx)
{
struct spdk_dif *dif = _dif;
uint32_t ref_tag;
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
to_be16(&dif->guard, guard);
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_APPTAG_CHECK) {
to_be16(&dif->app_tag, ctx->app_tag);
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_REFTAG_CHECK) {
/* For type 1 and 2, the reference tag is incremented for each
* subsequent logical block. For type 3, the reference tag
* remains the same as the initial reference tag.
*/
if (ctx->dif_type != SPDK_DIF_TYPE3) {
ref_tag = ctx->init_ref_tag + ctx->ref_tag_offset + offset_blocks;
} else {
ref_tag = ctx->init_ref_tag + ctx->ref_tag_offset;
}
to_be32(&dif->ref_tag, ref_tag);
}
}
static void
dif_generate(struct _dif_sgl *sgl, uint32_t num_blocks, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_blocks = 0;
void *buf;
uint16_t guard = 0;
while (offset_blocks < num_blocks) {
_dif_sgl_get_buf(sgl, &buf, NULL);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(ctx->guard_seed, buf, ctx->guard_interval);
}
_dif_generate(buf + ctx->guard_interval, guard, offset_blocks, ctx);
_dif_sgl_advance(sgl, ctx->block_size);
offset_blocks++;
}
}
static uint16_t
_dif_generate_split(struct _dif_sgl *sgl, uint32_t offset_in_block, uint32_t data_len,
uint16_t guard, uint32_t offset_blocks, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_in_dif, buf_len;
void *buf;
struct spdk_dif dif = {};
assert(offset_in_block < ctx->guard_interval);
assert(offset_in_block + data_len < ctx->guard_interval ||
offset_in_block + data_len == ctx->block_size);
/* Compute CRC over split logical block data. */
while (data_len != 0 && offset_in_block < ctx->guard_interval) {
_dif_sgl_get_buf(sgl, &buf, &buf_len);
buf_len = spdk_min(buf_len, data_len);
buf_len = spdk_min(buf_len, ctx->guard_interval - offset_in_block);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(guard, buf, buf_len);
}
_dif_sgl_advance(sgl, buf_len);
offset_in_block += buf_len;
data_len -= buf_len;
}
if (offset_in_block < ctx->guard_interval) {
return guard;
}
/* If a whole logical block data is parsed, generate DIF
* and save it to the temporary DIF area.
*/
_dif_generate(&dif, guard, offset_blocks, ctx);
/* Copy generated DIF field to the split DIF field, and then
* skip metadata field after DIF field (if any).
*/
while (offset_in_block < ctx->block_size) {
_dif_sgl_get_buf(sgl, &buf, &buf_len);
if (offset_in_block < ctx->guard_interval + sizeof(struct spdk_dif)) {
offset_in_dif = offset_in_block - ctx->guard_interval;
buf_len = spdk_min(buf_len, sizeof(struct spdk_dif) - offset_in_dif);
memcpy(buf, ((uint8_t *)&dif) + offset_in_dif, buf_len);
} else {
buf_len = spdk_min(buf_len, ctx->block_size - offset_in_block);
}
_dif_sgl_advance(sgl, buf_len);
offset_in_block += buf_len;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->guard_seed;
}
return guard;
}
static void
dif_generate_split(struct _dif_sgl *sgl, uint32_t num_blocks,
const struct spdk_dif_ctx *ctx)
{
uint32_t offset_blocks;
uint16_t guard = 0;
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->guard_seed;
}
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
_dif_generate_split(sgl, 0, ctx->block_size, guard, offset_blocks, ctx);
}
}
int
spdk_dif_generate(struct iovec *iovs, int iovcnt, uint32_t num_blocks,
const struct spdk_dif_ctx *ctx)
{
struct _dif_sgl sgl;
_dif_sgl_init(&sgl, iovs, iovcnt);
if (!_dif_sgl_is_valid(&sgl, ctx->block_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec array is not valid.\n");
return -EINVAL;
}
if (_dif_is_disabled(ctx->dif_type)) {
return 0;
}
if (_dif_sgl_is_bytes_multiple(&sgl, ctx->block_size)) {
dif_generate(&sgl, num_blocks, ctx);
} else {
dif_generate_split(&sgl, num_blocks, ctx);
}
return 0;
}
static void
_dif_error_set(struct spdk_dif_error *err_blk, uint8_t err_type,
uint32_t expected, uint32_t actual, uint32_t err_offset)
{
if (err_blk) {
err_blk->err_type = err_type;
err_blk->expected = expected;
err_blk->actual = actual;
err_blk->err_offset = err_offset;
}
}
static int
_dif_verify(void *_dif, uint16_t guard, uint32_t offset_blocks,
const struct spdk_dif_ctx *ctx, struct spdk_dif_error *err_blk)
{
struct spdk_dif *dif = _dif;
uint16_t _guard;
uint16_t _app_tag;
uint32_t ref_tag, _ref_tag;
switch (ctx->dif_type) {
case SPDK_DIF_TYPE1:
case SPDK_DIF_TYPE2:
/* If Type 1 or 2 is used, then all DIF checks are disabled when
* the Application Tag is 0xFFFF.
*/
if (dif->app_tag == 0xFFFF) {
return 0;
}
break;
case SPDK_DIF_TYPE3:
/* If Type 3 is used, then all DIF checks are disabled when the
* Application Tag is 0xFFFF and the Reference Tag is 0xFFFFFFFF.
*/
if (dif->app_tag == 0xFFFF && dif->ref_tag == 0xFFFFFFFF) {
return 0;
}
break;
default:
break;
}
/* For type 1 and 2, the reference tag is incremented for each
* subsequent logical block. For type 3, the reference tag
* remains the same as the initial reference tag.
*/
if (ctx->dif_type != SPDK_DIF_TYPE3) {
ref_tag = ctx->init_ref_tag + ctx->ref_tag_offset + offset_blocks;
} else {
ref_tag = ctx->init_ref_tag + ctx->ref_tag_offset;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
/* Compare the DIF Guard field to the CRC computed over the logical
* block data.
*/
_guard = from_be16(&dif->guard);
if (_guard != guard) {
_dif_error_set(err_blk, SPDK_DIF_GUARD_ERROR, _guard, guard,
offset_blocks);
SPDK_ERRLOG("Failed to compare Guard: LBA=%" PRIu32 "," \
" Expected=%x, Actual=%x\n",
ref_tag, _guard, guard);
return -1;
}
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_APPTAG_CHECK) {
/* Compare unmasked bits in the DIF Application Tag field to the
* passed Application Tag.
*/
_app_tag = from_be16(&dif->app_tag);
if ((_app_tag & ctx->apptag_mask) != ctx->app_tag) {
_dif_error_set(err_blk, SPDK_DIF_APPTAG_ERROR, ctx->app_tag,
(_app_tag & ctx->apptag_mask), offset_blocks);
SPDK_ERRLOG("Failed to compare App Tag: LBA=%" PRIu32 "," \
" Expected=%x, Actual=%x\n",
ref_tag, ctx->app_tag, (_app_tag & ctx->apptag_mask));
return -1;
}
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_REFTAG_CHECK) {
switch (ctx->dif_type) {
case SPDK_DIF_TYPE1:
case SPDK_DIF_TYPE2:
/* Compare the DIF Reference Tag field to the passed Reference Tag.
* The passed Reference Tag will be the least significant 4 bytes
* of the LBA when Type 1 is used, and application specific value
* if Type 2 is used,
*/
_ref_tag = from_be32(&dif->ref_tag);
if (_ref_tag != ref_tag) {
_dif_error_set(err_blk, SPDK_DIF_REFTAG_ERROR, ref_tag,
_ref_tag, offset_blocks);
SPDK_ERRLOG("Failed to compare Ref Tag: LBA=%" PRIu32 "," \
" Expected=%x, Actual=%x\n",
ref_tag, ref_tag, _ref_tag);
return -1;
}
break;
case SPDK_DIF_TYPE3:
/* For Type 3, computed Reference Tag remains unchanged.
* Hence ignore the Reference Tag field.
*/
break;
default:
break;
}
}
return 0;
}
static int
dif_verify(struct _dif_sgl *sgl, uint32_t num_blocks,
const struct spdk_dif_ctx *ctx, struct spdk_dif_error *err_blk)
{
uint32_t offset_blocks = 0;
int rc;
void *buf;
uint16_t guard = 0;
while (offset_blocks < num_blocks) {
_dif_sgl_get_buf(sgl, &buf, NULL);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(ctx->guard_seed, buf, ctx->guard_interval);
}
rc = _dif_verify(buf + ctx->guard_interval, guard, offset_blocks, ctx, err_blk);
if (rc != 0) {
return rc;
}
_dif_sgl_advance(sgl, ctx->block_size);
offset_blocks++;
}
return 0;
}
static int
_dif_verify_split(struct _dif_sgl *sgl, uint32_t offset_in_block, uint32_t data_len,
uint16_t *_guard, uint32_t offset_blocks,
const struct spdk_dif_ctx *ctx, struct spdk_dif_error *err_blk)
{
uint32_t offset_in_dif, buf_len;
void *buf;
uint16_t guard;
struct spdk_dif dif = {};
int rc;
assert(_guard != NULL);
assert(offset_in_block < ctx->guard_interval);
assert(offset_in_block + data_len < ctx->guard_interval ||
offset_in_block + data_len == ctx->block_size);
guard = *_guard;
/* Compute CRC over split logical block data. */
while (data_len != 0 && offset_in_block < ctx->guard_interval) {
_dif_sgl_get_buf(sgl, &buf, &buf_len);
buf_len = spdk_min(buf_len, data_len);
buf_len = spdk_min(buf_len, ctx->guard_interval - offset_in_block);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(guard, buf, buf_len);
}
_dif_sgl_advance(sgl, buf_len);
offset_in_block += buf_len;
data_len -= buf_len;
}
if (offset_in_block < ctx->guard_interval) {
*_guard = guard;
return 0;
}
/* Copy the split DIF field to the temporary DIF buffer, and then
* skip metadata field after DIF field (if any). */
while (offset_in_block < ctx->block_size) {
_dif_sgl_get_buf(sgl, &buf, &buf_len);
if (offset_in_block < ctx->guard_interval + sizeof(struct spdk_dif)) {
offset_in_dif = offset_in_block - ctx->guard_interval;
buf_len = spdk_min(buf_len, sizeof(struct spdk_dif) - offset_in_dif);
memcpy((uint8_t *)&dif + offset_in_dif, buf, buf_len);
} else {
buf_len = spdk_min(buf_len, ctx->block_size - offset_in_block);
}
_dif_sgl_advance(sgl, buf_len);
offset_in_block += buf_len;
}
rc = _dif_verify(&dif, guard, offset_blocks, ctx, err_blk);
if (rc != 0) {
return rc;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->guard_seed;
}
*_guard = guard;
return 0;
}
static int
dif_verify_split(struct _dif_sgl *sgl, uint32_t num_blocks,
const struct spdk_dif_ctx *ctx, struct spdk_dif_error *err_blk)
{
uint32_t offset_blocks;
uint16_t guard = 0;
int rc;
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->guard_seed;
}
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
rc = _dif_verify_split(sgl, 0, ctx->block_size, &guard, offset_blocks,
ctx, err_blk);
if (rc != 0) {
return rc;
}
}
return 0;
}
int
spdk_dif_verify(struct iovec *iovs, int iovcnt, uint32_t num_blocks,
const struct spdk_dif_ctx *ctx, struct spdk_dif_error *err_blk)
{
struct _dif_sgl sgl;
_dif_sgl_init(&sgl, iovs, iovcnt);
if (!_dif_sgl_is_valid(&sgl, ctx->block_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec array is not valid.\n");
return -EINVAL;
}
if (_dif_is_disabled(ctx->dif_type)) {
return 0;
}
if (_dif_sgl_is_bytes_multiple(&sgl, ctx->block_size)) {
return dif_verify(&sgl, num_blocks, ctx, err_blk);
} else {
return dif_verify_split(&sgl, num_blocks, ctx, err_blk);
}
}
static uint32_t
dif_update_crc32c(struct _dif_sgl *sgl, uint32_t num_blocks,
uint32_t crc32c, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_blocks;
void *buf;
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
_dif_sgl_get_buf(sgl, &buf, NULL);
crc32c = spdk_crc32c_update(buf, ctx->block_size - ctx->md_size, crc32c);
_dif_sgl_advance(sgl, ctx->block_size);
}
return crc32c;
}
static uint32_t
_dif_update_crc32c_split(struct _dif_sgl *sgl, uint32_t offset_in_block, uint32_t data_len,
uint32_t crc32c, const struct spdk_dif_ctx *ctx)
{
uint32_t data_block_size, buf_len;
void *buf;
data_block_size = ctx->block_size - ctx->md_size;
assert(offset_in_block + data_len <= ctx->block_size);
while (data_len != 0) {
_dif_sgl_get_buf(sgl, &buf, &buf_len);
buf_len = spdk_min(buf_len, data_len);
if (offset_in_block < data_block_size) {
buf_len = spdk_min(buf_len, data_block_size - offset_in_block);
crc32c = spdk_crc32c_update(buf, buf_len, crc32c);
}
_dif_sgl_advance(sgl, buf_len);
offset_in_block += buf_len;
data_len -= buf_len;
}
return crc32c;
}
static uint32_t
dif_update_crc32c_split(struct _dif_sgl *sgl, uint32_t num_blocks,
uint32_t crc32c, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_blocks;
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
crc32c = _dif_update_crc32c_split(sgl, 0, ctx->block_size, crc32c, ctx);
}
return crc32c;
}
int
spdk_dif_update_crc32c(struct iovec *iovs, int iovcnt, uint32_t num_blocks,
uint32_t *_crc32c, const struct spdk_dif_ctx *ctx)
{
struct _dif_sgl sgl;
if (_crc32c == NULL) {
return -EINVAL;
}
_dif_sgl_init(&sgl, iovs, iovcnt);
if (!_dif_sgl_is_valid(&sgl, ctx->block_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec array is not valid.\n");
return -EINVAL;
}
if (_dif_sgl_is_bytes_multiple(&sgl, ctx->block_size)) {
*_crc32c = dif_update_crc32c(&sgl, num_blocks, *_crc32c, ctx);
} else {
*_crc32c = dif_update_crc32c_split(&sgl, num_blocks, *_crc32c, ctx);
}
return 0;
}
static void
dif_generate_copy(struct _dif_sgl *src_sgl, struct _dif_sgl *dst_sgl,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_blocks = 0, data_block_size;
void *src, *dst;
uint16_t guard;
data_block_size = ctx->block_size - ctx->md_size;
while (offset_blocks < num_blocks) {
_dif_sgl_get_buf(src_sgl, &src, NULL);
_dif_sgl_get_buf(dst_sgl, &dst, NULL);
guard = 0;
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif_copy(ctx->guard_seed, dst, src, data_block_size);
guard = spdk_crc16_t10dif(guard, dst + data_block_size,
ctx->guard_interval - data_block_size);
} else {
memcpy(dst, src, data_block_size);
}
_dif_generate(dst + ctx->guard_interval, guard, offset_blocks, ctx);
_dif_sgl_advance(src_sgl, data_block_size);
_dif_sgl_advance(dst_sgl, ctx->block_size);
offset_blocks++;
}
}
static void
_dif_generate_copy_split(struct _dif_sgl *src_sgl, struct _dif_sgl *dst_sgl,
uint32_t offset_blocks, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_in_block, src_len, data_block_size;
uint16_t guard = 0;
void *src, *dst;
_dif_sgl_get_buf(dst_sgl, &dst, NULL);
data_block_size = ctx->block_size - ctx->md_size;
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->guard_seed;
}
offset_in_block = 0;
while (offset_in_block < data_block_size) {
/* Compute CRC over split logical block data and copy
* data to bounce buffer.
*/
_dif_sgl_get_buf(src_sgl, &src, &src_len);
src_len = spdk_min(src_len, data_block_size - offset_in_block);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif_copy(guard, dst + offset_in_block,
src, src_len);
} else {
memcpy(dst + offset_in_block, src, src_len);
}
_dif_sgl_advance(src_sgl, src_len);
offset_in_block += src_len;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(guard, dst + data_block_size,
ctx->guard_interval - data_block_size);
}
_dif_sgl_advance(dst_sgl, ctx->block_size);
_dif_generate(dst + ctx->guard_interval, guard, offset_blocks, ctx);
}
static void
dif_generate_copy_split(struct _dif_sgl *src_sgl, struct _dif_sgl *dst_sgl,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_blocks;
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
_dif_generate_copy_split(src_sgl, dst_sgl, offset_blocks, ctx);
}
}
int
spdk_dif_generate_copy(struct iovec *iovs, int iovcnt, struct iovec *bounce_iov,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx)
{
struct _dif_sgl src_sgl, dst_sgl;
uint32_t data_block_size;
_dif_sgl_init(&src_sgl, iovs, iovcnt);
_dif_sgl_init(&dst_sgl, bounce_iov, 1);
data_block_size = ctx->block_size - ctx->md_size;
if (!_dif_sgl_is_valid(&src_sgl, data_block_size * num_blocks) ||
!_dif_sgl_is_valid(&dst_sgl, ctx->block_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec arrays are not valid.\n");
return -EINVAL;
}
if (_dif_is_disabled(ctx->dif_type)) {
return 0;
}
if (_dif_sgl_is_bytes_multiple(&src_sgl, data_block_size)) {
dif_generate_copy(&src_sgl, &dst_sgl, num_blocks, ctx);
} else {
dif_generate_copy_split(&src_sgl, &dst_sgl, num_blocks, ctx);
}
return 0;
}
static int
dif_verify_copy(struct _dif_sgl *src_sgl, struct _dif_sgl *dst_sgl,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
uint32_t offset_blocks = 0, data_block_size;
void *src, *dst;
int rc;
uint16_t guard;
data_block_size = ctx->block_size - ctx->md_size;
while (offset_blocks < num_blocks) {
_dif_sgl_get_buf(src_sgl, &src, NULL);
_dif_sgl_get_buf(dst_sgl, &dst, NULL);
guard = 0;
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif_copy(ctx->guard_seed, dst, src, data_block_size);
guard = spdk_crc16_t10dif(guard, src + data_block_size,
ctx->guard_interval - data_block_size);
} else {
memcpy(dst, src, data_block_size);
}
rc = _dif_verify(src + ctx->guard_interval, guard, offset_blocks, ctx, err_blk);
if (rc != 0) {
return rc;
}
_dif_sgl_advance(src_sgl, ctx->block_size);
_dif_sgl_advance(dst_sgl, data_block_size);
offset_blocks++;
}
return 0;
}
static int
_dif_verify_copy_split(struct _dif_sgl *src_sgl, struct _dif_sgl *dst_sgl,
uint32_t offset_blocks, const struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
uint32_t offset_in_block, dst_len, data_block_size;
uint16_t guard = 0;
void *src, *dst;
_dif_sgl_get_buf(src_sgl, &src, NULL);
data_block_size = ctx->block_size - ctx->md_size;
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->guard_seed;
}
offset_in_block = 0;
while (offset_in_block < data_block_size) {
/* Compute CRC over split logical block data and copy
* data to bounce buffer.
*/
_dif_sgl_get_buf(dst_sgl, &dst, &dst_len);
dst_len = spdk_min(dst_len, data_block_size - offset_in_block);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif_copy(guard, dst,
src + offset_in_block, dst_len);
} else {
memcpy(dst, src + offset_in_block, dst_len);
}
_dif_sgl_advance(dst_sgl, dst_len);
offset_in_block += dst_len;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(guard, src + data_block_size,
ctx->guard_interval - data_block_size);
}
_dif_sgl_advance(src_sgl, ctx->block_size);
return _dif_verify(src + ctx->guard_interval, guard, offset_blocks, ctx, err_blk);
}
static int
dif_verify_copy_split(struct _dif_sgl *src_sgl, struct _dif_sgl *dst_sgl,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
uint32_t offset_blocks;
int rc;
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
rc = _dif_verify_copy_split(src_sgl, dst_sgl, offset_blocks, ctx, err_blk);
if (rc != 0) {
return rc;
}
}
return 0;
}
int
spdk_dif_verify_copy(struct iovec *iovs, int iovcnt, struct iovec *bounce_iov,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
struct _dif_sgl src_sgl, dst_sgl;
uint32_t data_block_size;
_dif_sgl_init(&src_sgl, bounce_iov, 1);
_dif_sgl_init(&dst_sgl, iovs, iovcnt);
data_block_size = ctx->block_size - ctx->md_size;
if (!_dif_sgl_is_valid(&dst_sgl, data_block_size * num_blocks) ||
!_dif_sgl_is_valid(&src_sgl, ctx->block_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec arrays are not valid\n");
return -EINVAL;
}
if (_dif_is_disabled(ctx->dif_type)) {
return 0;
}
if (_dif_sgl_is_bytes_multiple(&dst_sgl, data_block_size)) {
return dif_verify_copy(&src_sgl, &dst_sgl, num_blocks, ctx, err_blk);
} else {
return dif_verify_copy_split(&src_sgl, &dst_sgl, num_blocks, ctx, err_blk);
}
}
static void
_bit_flip(uint8_t *buf, uint32_t flip_bit)
{
uint8_t byte;
byte = *buf;
byte ^= 1 << flip_bit;
*buf = byte;
}
static int
_dif_inject_error(struct _dif_sgl *sgl,
uint32_t block_size, uint32_t num_blocks,
uint32_t inject_offset_blocks,
uint32_t inject_offset_bytes,
uint32_t inject_offset_bits)
{
uint32_t offset_in_block, buf_len;
void *buf;
_dif_sgl_advance(sgl, block_size * inject_offset_blocks);
offset_in_block = 0;
while (offset_in_block < block_size) {
_dif_sgl_get_buf(sgl, &buf, &buf_len);
buf_len = spdk_min(buf_len, block_size - offset_in_block);
if (inject_offset_bytes >= offset_in_block &&
inject_offset_bytes < offset_in_block + buf_len) {
buf += inject_offset_bytes - offset_in_block;
_bit_flip(buf, inject_offset_bits);
return 0;
}
_dif_sgl_advance(sgl, buf_len);
offset_in_block += buf_len;
}
return -1;
}
static int
dif_inject_error(struct _dif_sgl *sgl, uint32_t block_size, uint32_t num_blocks,
uint32_t start_inject_bytes, uint32_t inject_range_bytes,
uint32_t *inject_offset)
{
uint32_t inject_offset_blocks, inject_offset_bytes, inject_offset_bits;
uint32_t offset_blocks;
int rc;
srand(time(0));
inject_offset_blocks = rand() % num_blocks;
inject_offset_bytes = start_inject_bytes + (rand() % inject_range_bytes);
inject_offset_bits = rand() % 8;
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
if (offset_blocks == inject_offset_blocks) {
rc = _dif_inject_error(sgl, block_size, num_blocks,
inject_offset_blocks,
inject_offset_bytes,
inject_offset_bits);
if (rc == 0) {
*inject_offset = inject_offset_blocks;
}
return rc;
}
}
return -1;
}
#define _member_size(type, member) sizeof(((type *)0)->member)
int
spdk_dif_inject_error(struct iovec *iovs, int iovcnt, uint32_t num_blocks,
const struct spdk_dif_ctx *ctx, uint32_t inject_flags,
uint32_t *inject_offset)
{
struct _dif_sgl sgl;
int rc;
_dif_sgl_init(&sgl, iovs, iovcnt);
if (!_dif_sgl_is_valid(&sgl, ctx->block_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec array is not valid.\n");
return -EINVAL;
}
if (inject_flags & SPDK_DIF_REFTAG_ERROR) {
rc = dif_inject_error(&sgl, ctx->block_size, num_blocks,
ctx->guard_interval + offsetof(struct spdk_dif, ref_tag),
_member_size(struct spdk_dif, ref_tag),
inject_offset);
if (rc != 0) {
SPDK_ERRLOG("Failed to inject error to Reference Tag.\n");
return rc;
}
}
if (inject_flags & SPDK_DIF_APPTAG_ERROR) {
rc = dif_inject_error(&sgl, ctx->block_size, num_blocks,
ctx->guard_interval + offsetof(struct spdk_dif, app_tag),
_member_size(struct spdk_dif, app_tag),
inject_offset);
if (rc != 0) {
SPDK_ERRLOG("Failed to inject error to Application Tag.\n");
return rc;
}
}
if (inject_flags & SPDK_DIF_GUARD_ERROR) {
rc = dif_inject_error(&sgl, ctx->block_size, num_blocks,
ctx->guard_interval,
_member_size(struct spdk_dif, guard),
inject_offset);
if (rc != 0) {
SPDK_ERRLOG("Failed to inject error to Guard.\n");
return rc;
}
}
if (inject_flags & SPDK_DIF_DATA_ERROR) {
/* If the DIF information is contained within the last 8 bytes of
* metadata, then the CRC covers all metadata bytes up to but excluding
* the last 8 bytes. But error injection does not cover these metadata
* because classification is not determined yet.
*
* Note: Error injection to data block is expected to be detected as
* guard error.
*/
rc = dif_inject_error(&sgl, ctx->block_size, num_blocks,
0,
ctx->block_size - ctx->md_size,
inject_offset);
if (rc != 0) {
SPDK_ERRLOG("Failed to inject error to data block.\n");
return rc;
}
}
return 0;
}
static void
dix_generate(struct _dif_sgl *data_sgl, struct _dif_sgl *md_sgl,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_blocks = 0;
uint16_t guard;
void *data_buf, *md_buf;
while (offset_blocks < num_blocks) {
_dif_sgl_get_buf(data_sgl, &data_buf, NULL);
_dif_sgl_get_buf(md_sgl, &md_buf, NULL);
guard = 0;
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(ctx->guard_seed, data_buf, ctx->block_size);
guard = spdk_crc16_t10dif(guard, md_buf, ctx->guard_interval);
}
_dif_generate(md_buf + ctx->guard_interval, guard, offset_blocks, ctx);
_dif_sgl_advance(data_sgl, ctx->block_size);
_dif_sgl_advance(md_sgl, ctx->md_size);
offset_blocks++;
}
}
static void
_dix_generate_split(struct _dif_sgl *data_sgl, struct _dif_sgl *md_sgl,
uint32_t offset_blocks, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_in_block, data_buf_len;
uint16_t guard = 0;
void *data_buf, *md_buf;
_dif_sgl_get_buf(md_sgl, &md_buf, NULL);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->guard_seed;
}
offset_in_block = 0;
while (offset_in_block < ctx->block_size) {
_dif_sgl_get_buf(data_sgl, &data_buf, &data_buf_len);
data_buf_len = spdk_min(data_buf_len, ctx->block_size - offset_in_block);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(guard, data_buf, data_buf_len);
}
_dif_sgl_advance(data_sgl, data_buf_len);
offset_in_block += data_buf_len;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(guard, md_buf, ctx->guard_interval);
}
_dif_sgl_advance(md_sgl, ctx->md_size);
_dif_generate(md_buf + ctx->guard_interval, guard, offset_blocks, ctx);
}
static void
dix_generate_split(struct _dif_sgl *data_sgl, struct _dif_sgl *md_sgl,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx)
{
uint32_t offset_blocks;
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
_dix_generate_split(data_sgl, md_sgl, offset_blocks, ctx);
}
}
int
spdk_dix_generate(struct iovec *iovs, int iovcnt, struct iovec *md_iov,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx)
{
struct _dif_sgl data_sgl, md_sgl;
_dif_sgl_init(&data_sgl, iovs, iovcnt);
_dif_sgl_init(&md_sgl, md_iov, 1);
if (!_dif_sgl_is_valid(&data_sgl, ctx->block_size * num_blocks) ||
!_dif_sgl_is_valid(&md_sgl, ctx->md_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec array is not valid.\n");
return -EINVAL;
}
if (_dif_is_disabled(ctx->dif_type)) {
return 0;
}
if (_dif_sgl_is_bytes_multiple(&data_sgl, ctx->block_size)) {
dix_generate(&data_sgl, &md_sgl, num_blocks, ctx);
} else {
dix_generate_split(&data_sgl, &md_sgl, num_blocks, ctx);
}
return 0;
}
static int
dix_verify(struct _dif_sgl *data_sgl, struct _dif_sgl *md_sgl,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
uint32_t offset_blocks = 0;
uint16_t guard;
void *data_buf, *md_buf;
int rc;
while (offset_blocks < num_blocks) {
_dif_sgl_get_buf(data_sgl, &data_buf, NULL);
_dif_sgl_get_buf(md_sgl, &md_buf, NULL);
guard = 0;
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(ctx->guard_seed, data_buf, ctx->block_size);
guard = spdk_crc16_t10dif(guard, md_buf, ctx->guard_interval);
}
rc = _dif_verify(md_buf + ctx->guard_interval, guard, offset_blocks, ctx, err_blk);
if (rc != 0) {
return rc;
}
_dif_sgl_advance(data_sgl, ctx->block_size);
_dif_sgl_advance(md_sgl, ctx->md_size);
offset_blocks++;
}
return 0;
}
static int
_dix_verify_split(struct _dif_sgl *data_sgl, struct _dif_sgl *md_sgl,
uint32_t offset_blocks, const struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
uint32_t offset_in_block, data_buf_len;
uint16_t guard = 0;
void *data_buf, *md_buf;
_dif_sgl_get_buf(md_sgl, &md_buf, NULL);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->guard_seed;
}
offset_in_block = 0;
while (offset_in_block < ctx->block_size) {
_dif_sgl_get_buf(data_sgl, &data_buf, &data_buf_len);
data_buf_len = spdk_min(data_buf_len, ctx->block_size - offset_in_block);
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(guard, data_buf, data_buf_len);
}
_dif_sgl_advance(data_sgl, data_buf_len);
offset_in_block += data_buf_len;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = spdk_crc16_t10dif(guard, md_buf, ctx->guard_interval);
}
_dif_sgl_advance(md_sgl, ctx->md_size);
return _dif_verify(md_buf + ctx->guard_interval, guard, offset_blocks, ctx, err_blk);
}
static int
dix_verify_split(struct _dif_sgl *data_sgl, struct _dif_sgl *md_sgl,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
uint32_t offset_blocks;
int rc;
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
rc = _dix_verify_split(data_sgl, md_sgl, offset_blocks, ctx, err_blk);
if (rc != 0) {
return rc;
}
}
return 0;
}
int
spdk_dix_verify(struct iovec *iovs, int iovcnt, struct iovec *md_iov,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
struct _dif_sgl data_sgl, md_sgl;
_dif_sgl_init(&data_sgl, iovs, iovcnt);
_dif_sgl_init(&md_sgl, md_iov, 1);
if (!_dif_sgl_is_valid(&data_sgl, ctx->block_size * num_blocks) ||
!_dif_sgl_is_valid(&md_sgl, ctx->md_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec array is not valid.\n");
return -EINVAL;
}
if (_dif_is_disabled(ctx->dif_type)) {
return 0;
}
if (_dif_sgl_is_bytes_multiple(&data_sgl, ctx->block_size)) {
return dix_verify(&data_sgl, &md_sgl, num_blocks, ctx, err_blk);
} else {
return dix_verify_split(&data_sgl, &md_sgl, num_blocks, ctx, err_blk);
}
}
int
spdk_dix_inject_error(struct iovec *iovs, int iovcnt, struct iovec *md_iov,
uint32_t num_blocks, const struct spdk_dif_ctx *ctx,
uint32_t inject_flags, uint32_t *inject_offset)
{
struct _dif_sgl data_sgl, md_sgl;
int rc;
_dif_sgl_init(&data_sgl, iovs, iovcnt);
_dif_sgl_init(&md_sgl, md_iov, 1);
if (!_dif_sgl_is_valid(&data_sgl, ctx->block_size * num_blocks) ||
!_dif_sgl_is_valid(&md_sgl, ctx->md_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec array is not valid.\n");
return -EINVAL;
}
if (inject_flags & SPDK_DIF_REFTAG_ERROR) {
rc = dif_inject_error(&md_sgl, ctx->md_size, num_blocks,
ctx->guard_interval + offsetof(struct spdk_dif, ref_tag),
_member_size(struct spdk_dif, ref_tag),
inject_offset);
if (rc != 0) {
SPDK_ERRLOG("Failed to inject error to Reference Tag.\n");
return rc;
}
}
if (inject_flags & SPDK_DIF_APPTAG_ERROR) {
rc = dif_inject_error(&md_sgl, ctx->md_size, num_blocks,
ctx->guard_interval + offsetof(struct spdk_dif, app_tag),
_member_size(struct spdk_dif, app_tag),
inject_offset);
if (rc != 0) {
SPDK_ERRLOG("Failed to inject error to Application Tag.\n");
return rc;
}
}
if (inject_flags & SPDK_DIF_GUARD_ERROR) {
rc = dif_inject_error(&md_sgl, ctx->md_size, num_blocks,
ctx->guard_interval,
_member_size(struct spdk_dif, guard),
inject_offset);
if (rc != 0) {
SPDK_ERRLOG("Failed to inject error to Guard.\n");
return rc;
}
}
if (inject_flags & SPDK_DIF_DATA_ERROR) {
/* Note: Error injection to data block is expected to be detected
* as guard error.
*/
rc = dif_inject_error(&data_sgl, ctx->block_size, num_blocks,
0,
ctx->block_size,
inject_offset);
if (rc != 0) {
SPDK_ERRLOG("Failed to inject error to Guard.\n");
return rc;
}
}
return 0;
}
static uint32_t
_to_next_boundary(uint32_t offset, uint32_t boundary)
{
return boundary - (offset % boundary);
}
static uint32_t
_to_size_with_md(uint32_t size, uint32_t data_block_size, uint32_t block_size)
{
return (size / data_block_size) * block_size + (size % data_block_size);
}
int
spdk_dif_set_md_interleave_iovs(struct iovec *iovs, int iovcnt,
struct iovec *buf_iovs, int buf_iovcnt,
uint32_t data_offset, uint32_t data_len,
uint32_t *_mapped_len,
const struct spdk_dif_ctx *ctx)
{
uint32_t data_block_size, data_unalign, buf_len, buf_offset, len;
struct _dif_sgl dif_sgl;
struct _dif_sgl buf_sgl;
if (iovs == NULL || iovcnt == 0 || buf_iovs == NULL || buf_iovcnt == 0) {
return -EINVAL;
}
data_block_size = ctx->block_size - ctx->md_size;
data_unalign = ctx->data_offset % data_block_size;
buf_len = _to_size_with_md(data_unalign + data_offset + data_len, data_block_size,
ctx->block_size);
buf_len -= data_unalign;
_dif_sgl_init(&dif_sgl, iovs, iovcnt);
_dif_sgl_init(&buf_sgl, buf_iovs, buf_iovcnt);
if (!_dif_sgl_is_valid(&buf_sgl, buf_len)) {
SPDK_ERRLOG("Buffer overflow will occur.\n");
return -ERANGE;
}
buf_offset = _to_size_with_md(data_unalign + data_offset, data_block_size, ctx->block_size);
buf_offset -= data_unalign;
_dif_sgl_advance(&buf_sgl, buf_offset);
while (data_len != 0) {
len = spdk_min(data_len, _to_next_boundary(ctx->data_offset + data_offset, data_block_size));
if (!_dif_sgl_append_split(&dif_sgl, &buf_sgl, len)) {
break;
}
_dif_sgl_advance(&buf_sgl, ctx->md_size);
data_offset += len;
data_len -= len;
}
if (_mapped_len != NULL) {
*_mapped_len = dif_sgl.total_size;
}
return iovcnt - dif_sgl.iovcnt;
}
static int
_dif_sgl_setup_stream(struct _dif_sgl *sgl, uint32_t *_buf_offset, uint32_t *_buf_len,
uint32_t data_offset, uint32_t data_len,
const struct spdk_dif_ctx *ctx)
{
uint32_t data_block_size, data_unalign, buf_len, buf_offset;
data_block_size = ctx->block_size - ctx->md_size;
data_unalign = ctx->data_offset % data_block_size;
/* If the last data block is complete, DIF of the data block is
* inserted or verified in this turn.
*/
buf_len = _to_size_with_md(data_unalign + data_offset + data_len, data_block_size,
ctx->block_size);
buf_len -= data_unalign;
if (!_dif_sgl_is_valid(sgl, buf_len)) {
return -ERANGE;
}
buf_offset = _to_size_with_md(data_unalign + data_offset, data_block_size, ctx->block_size);
buf_offset -= data_unalign;
_dif_sgl_advance(sgl, buf_offset);
buf_len -= buf_offset;
buf_offset += data_unalign;
*_buf_offset = buf_offset;
*_buf_len = buf_len;
return 0;
}
int
spdk_dif_generate_stream(struct iovec *iovs, int iovcnt,
uint32_t data_offset, uint32_t data_len,
struct spdk_dif_ctx *ctx)
{
uint32_t buf_len = 0, buf_offset = 0;
uint32_t len, offset_in_block, offset_blocks;
uint16_t guard = 0;
struct _dif_sgl sgl;
int rc;
if (iovs == NULL || iovcnt == 0) {
return -EINVAL;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->last_guard;
}
_dif_sgl_init(&sgl, iovs, iovcnt);
rc = _dif_sgl_setup_stream(&sgl, &buf_offset, &buf_len, data_offset, data_len, ctx);
if (rc != 0) {
return rc;
}
while (buf_len != 0) {
len = spdk_min(buf_len, _to_next_boundary(buf_offset, ctx->block_size));
offset_in_block = buf_offset % ctx->block_size;
offset_blocks = buf_offset / ctx->block_size;
guard = _dif_generate_split(&sgl, offset_in_block, len, guard, offset_blocks, ctx);
buf_len -= len;
buf_offset += len;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
ctx->last_guard = guard;
}
return 0;
}
int
spdk_dif_verify_stream(struct iovec *iovs, int iovcnt,
uint32_t data_offset, uint32_t data_len,
struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
uint32_t buf_len = 0, buf_offset = 0;
uint32_t len, offset_in_block, offset_blocks;
uint16_t guard = 0;
struct _dif_sgl sgl;
int rc = 0;
if (iovs == NULL || iovcnt == 0) {
return -EINVAL;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
guard = ctx->last_guard;
}
_dif_sgl_init(&sgl, iovs, iovcnt);
rc = _dif_sgl_setup_stream(&sgl, &buf_offset, &buf_len, data_offset, data_len, ctx);
if (rc != 0) {
return rc;
}
while (buf_len != 0) {
len = spdk_min(buf_len, _to_next_boundary(buf_offset, ctx->block_size));
offset_in_block = buf_offset % ctx->block_size;
offset_blocks = buf_offset / ctx->block_size;
rc = _dif_verify_split(&sgl, offset_in_block, len, &guard, offset_blocks,
ctx, err_blk);
if (rc != 0) {
goto error;
}
buf_len -= len;
buf_offset += len;
}
if (ctx->dif_flags & SPDK_DIF_FLAGS_GUARD_CHECK) {
ctx->last_guard = guard;
}
error:
return rc;
}
int
spdk_dif_update_crc32c_stream(struct iovec *iovs, int iovcnt,
uint32_t data_offset, uint32_t data_len,
uint32_t *_crc32c, const struct spdk_dif_ctx *ctx)
{
uint32_t buf_len = 0, buf_offset = 0, len, offset_in_block;
uint32_t crc32c;
struct _dif_sgl sgl;
int rc;
if (iovs == NULL || iovcnt == 0) {
return -EINVAL;
}
crc32c = *_crc32c;
_dif_sgl_init(&sgl, iovs, iovcnt);
rc = _dif_sgl_setup_stream(&sgl, &buf_offset, &buf_len, data_offset, data_len, ctx);
if (rc != 0) {
return rc;
}
while (buf_len != 0) {
len = spdk_min(buf_len, _to_next_boundary(buf_offset, ctx->block_size));
offset_in_block = buf_offset % ctx->block_size;
crc32c = _dif_update_crc32c_split(&sgl, offset_in_block, len, crc32c, ctx);
buf_len -= len;
buf_offset += len;
}
*_crc32c = crc32c;
return 0;
}
void
spdk_dif_get_range_with_md(uint32_t data_offset, uint32_t data_len,
uint32_t *_buf_offset, uint32_t *_buf_len,
const struct spdk_dif_ctx *ctx)
{
uint32_t data_block_size, data_unalign, buf_offset, buf_len;
if (!ctx->md_interleave) {
buf_offset = data_offset;
buf_len = data_len;
} else {
data_block_size = ctx->block_size - ctx->md_size;
data_unalign = data_offset % data_block_size;
buf_offset = _to_size_with_md(data_offset, data_block_size, ctx->block_size);
buf_len = _to_size_with_md(data_unalign + data_len, data_block_size, ctx->block_size) -
data_unalign;
}
if (_buf_offset != NULL) {
*_buf_offset = buf_offset;
}
if (_buf_len != NULL) {
*_buf_len = buf_len;
}
}
uint32_t
spdk_dif_get_length_with_md(uint32_t data_len, const struct spdk_dif_ctx *ctx)
{
uint32_t data_block_size;
if (!ctx->md_interleave) {
return data_len;
} else {
data_block_size = ctx->block_size - ctx->md_size;
return _to_size_with_md(data_len, data_block_size, ctx->block_size);
}
}
dif: Add spdk_dif_remap_ref_tag to remap ref. tag for extended LBA payload When using stacked virtual bdev (e.g. split virtual bdev), block address space will be remapped during I/O processing and so reference tag will have to be remapped accordingly. The use case is explained in detail as follows: - Format a single NVMe SSD with DIF enabled. - Create a NVMe bdev on the NVMe SSD with DIF enabled. - Create four split vbdevs on the NVMe bdev. - Add the split vbdevs to a NVMe-oF target. - Application is aware of block address space of the split vbdevs. - Application submits read/write I/O to the NVMe-oF target. Case 1: - Configure NVMe-oF target to DIF pass-through. Case 2: - Configure NVMe-oF target to DIF insert/strip For the case 1, - Application inserts DIF for write I/O and verifies DIF for read I/O. - The split vbdevs remaps reference tags of DIF both for read and write I/O because application expects reference tags are based on the block address space of split vbdevs. - The NVMe bdev processs read/write I/Os without remapping reference tags because reference tags are already based on the block address space of the NVMe bdev. For the case 2, - NVMe-oF target inserts DIF for write I/O, and verifies and strips DIF or read I/O. - The split vbdevs remaps reference tags of DIF both for read and write I/O because NVMe-oF target expects reference tags are based on the block address space of split vbdevs. - The NVMe bdev processs read/write I/Os without remapping reference tags because reference tags are already based on the block address space of the NVMe bdev. This patch adds two APIs, spdk_dif_ctx_set_remapped_init_ref_tag and spdk_dif_remap_ref_tag to satisfy the use case. UT code is added together in this patch. Signed-off-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com> Change-Id: Ib3101129225b334d2f578eab75197790b1818770 Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/461103 Reviewed-by: Changpeng Liu <changpeng.liu@intel.com> Reviewed-by: Ben Walker <benjamin.walker@intel.com> Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
2019-07-08 06:45:21 +00:00
static int
_dif_remap_ref_tag(struct _dif_sgl *sgl, uint32_t offset_blocks,
const struct spdk_dif_ctx *ctx, struct spdk_dif_error *err_blk)
{
uint32_t offset, buf_len, expected = 0, _actual, remapped;
void *buf;
struct _dif_sgl tmp_sgl;
struct spdk_dif dif;
/* Fast forward to DIF field. */
_dif_sgl_advance(sgl, ctx->guard_interval);
_dif_sgl_copy(&tmp_sgl, sgl);
/* Copy the split DIF field to the temporary DIF buffer */
offset = 0;
while (offset < sizeof(struct spdk_dif)) {
_dif_sgl_get_buf(sgl, &buf, &buf_len);
buf_len = spdk_min(buf_len, sizeof(struct spdk_dif) - offset);
memcpy((uint8_t *)&dif + offset, buf, buf_len);
_dif_sgl_advance(sgl, buf_len);
offset += buf_len;
}
switch (ctx->dif_type) {
case SPDK_DIF_TYPE1:
case SPDK_DIF_TYPE2:
/* If Type 1 or 2 is used, then all DIF checks are disabled when
* the Application Tag is 0xFFFF.
*/
if (dif.app_tag == 0xFFFF) {
goto end;
}
break;
case SPDK_DIF_TYPE3:
/* If Type 3 is used, then all DIF checks are disabled when the
* Application Tag is 0xFFFF and the Reference Tag is 0xFFFFFFFF.
*/
if (dif.app_tag == 0xFFFF && dif.ref_tag == 0xFFFFFFFF) {
goto end;
}
break;
default:
break;
}
/* For type 1 and 2, the Reference Tag is incremented for each
* subsequent logical block. For type 3, the Reference Tag
* remains the same as the initial Reference Tag.
*/
if (ctx->dif_type != SPDK_DIF_TYPE3) {
expected = ctx->init_ref_tag + ctx->ref_tag_offset + offset_blocks;
remapped = ctx->remapped_init_ref_tag + ctx->ref_tag_offset + offset_blocks;
} else {
remapped = ctx->remapped_init_ref_tag;
}
/* Verify the stored Reference Tag. */
switch (ctx->dif_type) {
case SPDK_DIF_TYPE1:
case SPDK_DIF_TYPE2:
/* Compare the DIF Reference Tag field to the computed Reference Tag.
* The computed Reference Tag will be the least significant 4 bytes
* of the LBA when Type 1 is used, and application specific value
* if Type 2 is used.
*/
_actual = from_be32(&dif.ref_tag);
if (_actual != expected) {
_dif_error_set(err_blk, SPDK_DIF_REFTAG_ERROR, expected,
_actual, offset_blocks);
SPDK_ERRLOG("Failed to compare Ref Tag: LBA=%" PRIu32 "," \
" Expected=%x, Actual=%x\n",
expected, expected, _actual);
return -1;
}
break;
case SPDK_DIF_TYPE3:
/* For type 3, the computed Reference Tag remains unchanged.
* Hence ignore the Reference Tag field.
*/
break;
default:
break;
}
/* Update the stored Reference Tag to the remapped one. */
to_be32(&dif.ref_tag, remapped);
offset = 0;
while (offset < sizeof(struct spdk_dif)) {
_dif_sgl_get_buf(&tmp_sgl, &buf, &buf_len);
buf_len = spdk_min(buf_len, sizeof(struct spdk_dif) - offset);
memcpy(buf, (uint8_t *)&dif + offset, buf_len);
_dif_sgl_advance(&tmp_sgl, buf_len);
offset += buf_len;
}
end:
_dif_sgl_advance(sgl, ctx->block_size - ctx->guard_interval - sizeof(struct spdk_dif));
return 0;
}
int
spdk_dif_remap_ref_tag(struct iovec *iovs, int iovcnt, uint32_t num_blocks,
const struct spdk_dif_ctx *ctx, struct spdk_dif_error *err_blk)
{
struct _dif_sgl sgl;
uint32_t offset_blocks;
int rc;
_dif_sgl_init(&sgl, iovs, iovcnt);
if (!_dif_sgl_is_valid(&sgl, ctx->block_size * num_blocks)) {
SPDK_ERRLOG("Size of iovec array is not valid.\n");
return -EINVAL;
}
if (_dif_is_disabled(ctx->dif_type)) {
return 0;
}
if (!(ctx->dif_flags & SPDK_DIF_FLAGS_REFTAG_CHECK)) {
return 0;
}
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
rc = _dif_remap_ref_tag(&sgl, offset_blocks, ctx, err_blk);
if (rc != 0) {
return rc;
}
}
return 0;
}
static int
_dix_remap_ref_tag(struct _dif_sgl *md_sgl, uint32_t offset_blocks,
const struct spdk_dif_ctx *ctx, struct spdk_dif_error *err_blk)
{
uint32_t expected = 0, _actual, remapped;
uint8_t *md_buf;
struct spdk_dif *dif;
_dif_sgl_get_buf(md_sgl, (void *)&md_buf, NULL);
dif = (struct spdk_dif *)(md_buf + ctx->guard_interval);
switch (ctx->dif_type) {
case SPDK_DIF_TYPE1:
case SPDK_DIF_TYPE2:
/* If Type 1 or 2 is used, then all DIF checks are disabled when
* the Application Tag is 0xFFFF.
*/
if (dif->app_tag == 0xFFFF) {
goto end;
}
break;
case SPDK_DIF_TYPE3:
/* If Type 3 is used, then all DIF checks are disabled when the
* Application Tag is 0xFFFF and the Reference Tag is 0xFFFFFFFF.
*/
if (dif->app_tag == 0xFFFF && dif->ref_tag == 0xFFFFFFFF) {
goto end;
}
break;
default:
break;
}
/* For type 1 and 2, the Reference Tag is incremented for each
* subsequent logical block. For type 3, the Reference Tag
* remains the same as the initialReference Tag.
*/
if (ctx->dif_type != SPDK_DIF_TYPE3) {
expected = ctx->init_ref_tag + ctx->ref_tag_offset + offset_blocks;
remapped = ctx->remapped_init_ref_tag + ctx->ref_tag_offset + offset_blocks;
} else {
remapped = ctx->remapped_init_ref_tag;
}
/* Verify the stored Reference Tag. */
switch (ctx->dif_type) {
case SPDK_DIF_TYPE1:
case SPDK_DIF_TYPE2:
/* Compare the DIF Reference Tag field to the computed Reference Tag.
* The computed Reference Tag will be the least significant 4 bytes
* of the LBA when Type 1 is used, and application specific value
* if Type 2 is used.
*/
_actual = from_be32(&dif->ref_tag);
if (_actual != expected) {
_dif_error_set(err_blk, SPDK_DIF_REFTAG_ERROR, expected,
_actual, offset_blocks);
SPDK_ERRLOG("Failed to compare Ref Tag: LBA=%" PRIu32 "," \
" Expected=%x, Actual=%x\n",
expected, expected, _actual);
return -1;
}
break;
case SPDK_DIF_TYPE3:
/* For type 3, the computed Reference Tag remains unchanged.
* Hence ignore the Reference Tag field.
*/
break;
default:
break;
}
/* Update the stored Reference Tag to the remapped one. */
to_be32(&dif->ref_tag, remapped);
end:
_dif_sgl_advance(md_sgl, ctx->md_size);
return 0;
}
int
spdk_dix_remap_ref_tag(struct iovec *md_iov, uint32_t num_blocks,
const struct spdk_dif_ctx *ctx,
struct spdk_dif_error *err_blk)
{
struct _dif_sgl md_sgl;
uint32_t offset_blocks;
int rc;
_dif_sgl_init(&md_sgl, md_iov, 1);
if (!_dif_sgl_is_valid(&md_sgl, ctx->md_size * num_blocks)) {
SPDK_ERRLOG("Size of metadata iovec array is not valid.\n");
return -EINVAL;
}
if (_dif_is_disabled(ctx->dif_type)) {
return 0;
}
if (!(ctx->dif_flags & SPDK_DIF_FLAGS_REFTAG_CHECK)) {
return 0;
}
for (offset_blocks = 0; offset_blocks < num_blocks; offset_blocks++) {
rc = _dix_remap_ref_tag(&md_sgl, offset_blocks, ctx, err_blk);
if (rc != 0) {
return rc;
}
}
return 0;
}