numam-spdk/lib/reduce/reduce.c
paul luse 12f7aeb4ce lib/reduce: avoid extra operation in write path
Change-Id: I92355d3deb25f818e6d4c7a72d2f4fd45e6879ac
Signed-off-by: paul luse <paul.e.luse@intel.com>
Reviewed-on: https://review.gerrithub.io/c/spdk/spdk/+/457523
Reviewed-by: Darek Stojaczyk <dariusz.stojaczyk@intel.com>
Reviewed-by: Ben Walker <benjamin.walker@intel.com>
Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
2019-06-11 18:13:10 +00:00

1399 lines
41 KiB
C

/*-
* 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/stdinc.h"
#include "spdk/reduce.h"
#include "spdk/env.h"
#include "spdk/string.h"
#include "spdk/bit_array.h"
#include "spdk/util.h"
#include "spdk_internal/log.h"
#include "libpmem.h"
/* Always round up the size of the PM region to the nearest cacheline. */
#define REDUCE_PM_SIZE_ALIGNMENT 64
/* Offset into the backing device where the persistent memory file's path is stored. */
#define REDUCE_BACKING_DEV_PATH_OFFSET 4096
#define REDUCE_EMPTY_MAP_ENTRY -1ULL
#define REDUCE_NUM_VOL_REQUESTS 256
/* Structure written to offset 0 of both the pm file and the backing device. */
struct spdk_reduce_vol_superblock {
uint8_t signature[8];
struct spdk_reduce_vol_params params;
uint8_t reserved[4048];
};
SPDK_STATIC_ASSERT(sizeof(struct spdk_reduce_vol_superblock) == 4096, "size incorrect");
#define SPDK_REDUCE_SIGNATURE "SPDKREDU"
/* null terminator counts one */
SPDK_STATIC_ASSERT(sizeof(SPDK_REDUCE_SIGNATURE) - 1 ==
sizeof(((struct spdk_reduce_vol_superblock *)0)->signature), "size incorrect");
#define REDUCE_PATH_MAX 4096
/**
* Describes a persistent memory file used to hold metadata associated with a
* compressed volume.
*/
struct spdk_reduce_pm_file {
char path[REDUCE_PATH_MAX];
void *pm_buf;
int pm_is_pmem;
uint64_t size;
};
#define REDUCE_IO_READV 1
#define REDUCE_IO_WRITEV 2
struct spdk_reduce_chunk_map {
uint32_t compressed_size;
uint32_t reserved;
uint64_t io_unit_index[0];
};
struct spdk_reduce_vol_request {
/**
* Scratch buffer used for uncompressed chunk. This is used for:
* 1) source buffer for compression operations
* 2) destination buffer for decompression operations
* 3) data buffer when writing uncompressed chunk to disk
* 4) data buffer when reading uncompressed chunk from disk
*/
uint8_t *decomp_buf;
struct iovec *decomp_buf_iov;
/**
* Scratch buffer used for compressed chunk. This is used for:
* 1) destination buffer for compression operations
* 2) source buffer for decompression operations
* 3) data buffer when writing compressed chunk to disk
* 4) data buffer when reading compressed chunk from disk
*/
uint8_t *comp_buf;
struct iovec *comp_buf_iov;
struct iovec *iov;
struct spdk_reduce_vol *vol;
int type;
int reduce_errno;
int iovcnt;
int num_backing_ops;
uint32_t num_io_units;
bool chunk_is_compressed;
uint64_t offset;
uint64_t logical_map_index;
uint64_t length;
uint64_t chunk_map_index;
struct spdk_reduce_chunk_map *chunk;
spdk_reduce_vol_op_complete cb_fn;
void *cb_arg;
TAILQ_ENTRY(spdk_reduce_vol_request) tailq;
struct spdk_reduce_vol_cb_args backing_cb_args;
};
struct spdk_reduce_vol {
struct spdk_reduce_vol_params params;
uint32_t backing_io_units_per_chunk;
uint32_t backing_lba_per_io_unit;
uint32_t logical_blocks_per_chunk;
struct spdk_reduce_pm_file pm_file;
struct spdk_reduce_backing_dev *backing_dev;
struct spdk_reduce_vol_superblock *backing_super;
struct spdk_reduce_vol_superblock *pm_super;
uint64_t *pm_logical_map;
uint64_t *pm_chunk_maps;
struct spdk_bit_array *allocated_chunk_maps;
struct spdk_bit_array *allocated_backing_io_units;
struct spdk_reduce_vol_request *request_mem;
TAILQ_HEAD(, spdk_reduce_vol_request) free_requests;
TAILQ_HEAD(, spdk_reduce_vol_request) executing_requests;
TAILQ_HEAD(, spdk_reduce_vol_request) queued_requests;
/* Single contiguous buffer used for all request buffers for this volume. */
uint8_t *buf_mem;
struct iovec *buf_iov_mem;
};
static void _start_readv_request(struct spdk_reduce_vol_request *req);
static void _start_writev_request(struct spdk_reduce_vol_request *req);
/*
* Allocate extra metadata chunks and corresponding backing io units to account for
* outstanding IO in worst case scenario where logical map is completely allocated
* and no data can be compressed. We need extra chunks in this case to handle
* in-flight writes since reduce never writes data in place.
*/
#define REDUCE_NUM_EXTRA_CHUNKS 128
static void
_reduce_persist(struct spdk_reduce_vol *vol, const void *addr, size_t len)
{
if (vol->pm_file.pm_is_pmem) {
pmem_persist(addr, len);
} else {
pmem_msync(addr, len);
}
}
static uint64_t
_get_pm_logical_map_size(uint64_t vol_size, uint64_t chunk_size)
{
uint64_t chunks_in_logical_map, logical_map_size;
chunks_in_logical_map = vol_size / chunk_size;
logical_map_size = chunks_in_logical_map * sizeof(uint64_t);
/* Round up to next cacheline. */
return spdk_divide_round_up(logical_map_size, REDUCE_PM_SIZE_ALIGNMENT) *
REDUCE_PM_SIZE_ALIGNMENT;
}
static uint64_t
_get_total_chunks(uint64_t vol_size, uint64_t chunk_size)
{
uint64_t num_chunks;
num_chunks = vol_size / chunk_size;
num_chunks += REDUCE_NUM_EXTRA_CHUNKS;
return num_chunks;
}
static uint64_t
_get_pm_total_chunks_size(uint64_t vol_size, uint64_t chunk_size, uint64_t backing_io_unit_size)
{
uint64_t io_units_per_chunk, num_chunks, total_chunks_size;
num_chunks = _get_total_chunks(vol_size, chunk_size);
io_units_per_chunk = chunk_size / backing_io_unit_size;
total_chunks_size = num_chunks * io_units_per_chunk * sizeof(uint64_t);
return spdk_divide_round_up(total_chunks_size, REDUCE_PM_SIZE_ALIGNMENT) *
REDUCE_PM_SIZE_ALIGNMENT;
}
static inline uint32_t
_reduce_vol_get_chunk_struct_size(struct spdk_reduce_vol *vol)
{
return sizeof(struct spdk_reduce_chunk_map) + sizeof(uint64_t) * vol->backing_io_units_per_chunk;
}
static struct spdk_reduce_chunk_map *
_reduce_vol_get_chunk_map(struct spdk_reduce_vol *vol, uint64_t chunk_map_index)
{
uintptr_t chunk_map_addr;
assert(chunk_map_index < _get_total_chunks(vol->params.vol_size, vol->params.chunk_size));
chunk_map_addr = (uintptr_t)vol->pm_chunk_maps;
chunk_map_addr += chunk_map_index * _reduce_vol_get_chunk_struct_size(vol);
return (struct spdk_reduce_chunk_map *)chunk_map_addr;
}
static int
_validate_vol_params(struct spdk_reduce_vol_params *params)
{
if (params->vol_size > 0) {
/**
* User does not pass in the vol size - it gets calculated by libreduce from
* values in this structure plus the size of the backing device.
*/
return -EINVAL;
}
if (params->chunk_size == 0 || params->backing_io_unit_size == 0 ||
params->logical_block_size == 0) {
return -EINVAL;
}
/* Chunk size must be an even multiple of the backing io unit size. */
if ((params->chunk_size % params->backing_io_unit_size) != 0) {
return -EINVAL;
}
/* Chunk size must be an even multiple of the logical block size. */
if ((params->chunk_size % params->logical_block_size) != 0) {
return -1;
}
return 0;
}
static uint64_t
_get_vol_size(uint64_t chunk_size, uint64_t backing_dev_size)
{
uint64_t num_chunks;
num_chunks = backing_dev_size / chunk_size;
if (num_chunks <= REDUCE_NUM_EXTRA_CHUNKS) {
return 0;
}
num_chunks -= REDUCE_NUM_EXTRA_CHUNKS;
return num_chunks * chunk_size;
}
static uint64_t
_get_pm_file_size(struct spdk_reduce_vol_params *params)
{
uint64_t total_pm_size;
total_pm_size = sizeof(struct spdk_reduce_vol_superblock);
total_pm_size += _get_pm_logical_map_size(params->vol_size, params->chunk_size);
total_pm_size += _get_pm_total_chunks_size(params->vol_size, params->chunk_size,
params->backing_io_unit_size);
return total_pm_size;
}
const struct spdk_uuid *
spdk_reduce_vol_get_uuid(struct spdk_reduce_vol *vol)
{
return &vol->params.uuid;
}
static void
_initialize_vol_pm_pointers(struct spdk_reduce_vol *vol)
{
/* Superblock is at the beginning of the pm file. */
vol->pm_super = (struct spdk_reduce_vol_superblock *)vol->pm_file.pm_buf;
/* Logical map immediately follows the super block. */
vol->pm_logical_map = (uint64_t *)(vol->pm_super + 1);
/* Chunks maps follow the logical map. */
vol->pm_chunk_maps = vol->pm_logical_map + (vol->params.vol_size / vol->params.chunk_size);
}
/* We need 2 iovs during load - one for the superblock, another for the path */
#define LOAD_IOV_COUNT 2
struct reduce_init_load_ctx {
struct spdk_reduce_vol *vol;
struct spdk_reduce_vol_cb_args backing_cb_args;
spdk_reduce_vol_op_with_handle_complete cb_fn;
void *cb_arg;
struct iovec iov[LOAD_IOV_COUNT];
void *path;
};
static int
_allocate_vol_requests(struct spdk_reduce_vol *vol)
{
struct spdk_reduce_vol_request *req;
int i;
/* Allocate 2x since we need buffers for both read/write and compress/decompress
* intermediate buffers.
*/
vol->buf_mem = spdk_dma_malloc(2 * REDUCE_NUM_VOL_REQUESTS * vol->params.chunk_size, 64, NULL);
if (vol->buf_mem == NULL) {
return -ENOMEM;
}
vol->request_mem = calloc(REDUCE_NUM_VOL_REQUESTS, sizeof(*req));
if (vol->request_mem == NULL) {
spdk_dma_free(vol->buf_mem);
vol->buf_mem = NULL;
return -ENOMEM;
}
/* Allocate 2x since we need iovs for both read/write and compress/decompress intermediate
* buffers.
*/
vol->buf_iov_mem = calloc(REDUCE_NUM_VOL_REQUESTS,
2 * sizeof(struct iovec) * vol->backing_io_units_per_chunk);
if (vol->buf_iov_mem == NULL) {
free(vol->request_mem);
spdk_dma_free(vol->buf_mem);
vol->request_mem = NULL;
vol->buf_mem = NULL;
return -ENOMEM;
}
for (i = 0; i < REDUCE_NUM_VOL_REQUESTS; i++) {
req = &vol->request_mem[i];
TAILQ_INSERT_HEAD(&vol->free_requests, req, tailq);
req->decomp_buf_iov = &vol->buf_iov_mem[(2 * i) * vol->backing_io_units_per_chunk];
req->decomp_buf = vol->buf_mem + (2 * i) * vol->params.chunk_size;
req->comp_buf_iov = &vol->buf_iov_mem[(2 * i + 1) * vol->backing_io_units_per_chunk];
req->comp_buf = vol->buf_mem + (2 * i + 1) * vol->params.chunk_size;
}
return 0;
}
static void
_init_load_cleanup(struct spdk_reduce_vol *vol, struct reduce_init_load_ctx *ctx)
{
if (ctx != NULL) {
spdk_dma_free(ctx->path);
free(ctx);
}
if (vol != NULL) {
pmem_unmap(vol->pm_file.pm_buf, vol->pm_file.size);
spdk_dma_free(vol->backing_super);
spdk_bit_array_free(&vol->allocated_chunk_maps);
spdk_bit_array_free(&vol->allocated_backing_io_units);
free(vol->request_mem);
free(vol->buf_iov_mem);
spdk_dma_free(vol->buf_mem);
free(vol);
}
}
static void
_init_write_super_cpl(void *cb_arg, int reduce_errno)
{
struct reduce_init_load_ctx *init_ctx = cb_arg;
int rc;
rc = _allocate_vol_requests(init_ctx->vol);
if (rc != 0) {
init_ctx->cb_fn(init_ctx->cb_arg, NULL, rc);
_init_load_cleanup(init_ctx->vol, init_ctx);
return;
}
init_ctx->cb_fn(init_ctx->cb_arg, init_ctx->vol, reduce_errno);
/* Only clean up the ctx - the vol has been passed to the application
* for use now that initialization was successful.
*/
_init_load_cleanup(NULL, init_ctx);
}
static void
_init_write_path_cpl(void *cb_arg, int reduce_errno)
{
struct reduce_init_load_ctx *init_ctx = cb_arg;
struct spdk_reduce_vol *vol = init_ctx->vol;
init_ctx->iov[0].iov_base = vol->backing_super;
init_ctx->iov[0].iov_len = sizeof(*vol->backing_super);
init_ctx->backing_cb_args.cb_fn = _init_write_super_cpl;
init_ctx->backing_cb_args.cb_arg = init_ctx;
vol->backing_dev->writev(vol->backing_dev, init_ctx->iov, 1,
0, sizeof(*vol->backing_super) / vol->backing_dev->blocklen,
&init_ctx->backing_cb_args);
}
static int
_allocate_bit_arrays(struct spdk_reduce_vol *vol)
{
uint64_t total_chunks, total_backing_io_units;
uint32_t i, num_metadata_io_units;
total_chunks = _get_total_chunks(vol->params.vol_size, vol->params.chunk_size);
vol->allocated_chunk_maps = spdk_bit_array_create(total_chunks);
total_backing_io_units = total_chunks * (vol->params.chunk_size / vol->params.backing_io_unit_size);
vol->allocated_backing_io_units = spdk_bit_array_create(total_backing_io_units);
if (vol->allocated_chunk_maps == NULL || vol->allocated_backing_io_units == NULL) {
return -ENOMEM;
}
/* Set backing io unit bits associated with metadata. */
num_metadata_io_units = (sizeof(*vol->backing_super) + REDUCE_PATH_MAX) /
vol->backing_dev->blocklen;
for (i = 0; i < num_metadata_io_units; i++) {
spdk_bit_array_set(vol->allocated_backing_io_units, i);
}
return 0;
}
void
spdk_reduce_vol_init(struct spdk_reduce_vol_params *params,
struct spdk_reduce_backing_dev *backing_dev,
const char *pm_file_dir,
spdk_reduce_vol_op_with_handle_complete cb_fn, void *cb_arg)
{
struct spdk_reduce_vol *vol;
struct reduce_init_load_ctx *init_ctx;
uint64_t backing_dev_size;
size_t mapped_len;
int dir_len, max_dir_len, rc;
/* We need to append a path separator and the UUID to the supplied
* path.
*/
max_dir_len = REDUCE_PATH_MAX - SPDK_UUID_STRING_LEN - 1;
dir_len = strnlen(pm_file_dir, max_dir_len);
/* Strip trailing slash if the user provided one - we will add it back
* later when appending the filename.
*/
if (pm_file_dir[dir_len - 1] == '/') {
dir_len--;
}
if (dir_len == max_dir_len) {
SPDK_ERRLOG("pm_file_dir (%s) too long\n", pm_file_dir);
cb_fn(cb_arg, NULL, -EINVAL);
return;
}
rc = _validate_vol_params(params);
if (rc != 0) {
SPDK_ERRLOG("invalid vol params\n");
cb_fn(cb_arg, NULL, rc);
return;
}
backing_dev_size = backing_dev->blockcnt * backing_dev->blocklen;
params->vol_size = _get_vol_size(params->chunk_size, backing_dev_size);
if (params->vol_size == 0) {
SPDK_ERRLOG("backing device is too small\n");
cb_fn(cb_arg, NULL, -EINVAL);
return;
}
if (backing_dev->readv == NULL || backing_dev->writev == NULL ||
backing_dev->unmap == NULL) {
SPDK_ERRLOG("backing_dev function pointer not specified\n");
cb_fn(cb_arg, NULL, -EINVAL);
return;
}
vol = calloc(1, sizeof(*vol));
if (vol == NULL) {
cb_fn(cb_arg, NULL, -ENOMEM);
return;
}
TAILQ_INIT(&vol->free_requests);
TAILQ_INIT(&vol->executing_requests);
TAILQ_INIT(&vol->queued_requests);
vol->backing_super = spdk_dma_zmalloc(sizeof(*vol->backing_super), 0, NULL);
if (vol->backing_super == NULL) {
cb_fn(cb_arg, NULL, -ENOMEM);
_init_load_cleanup(vol, NULL);
return;
}
init_ctx = calloc(1, sizeof(*init_ctx));
if (init_ctx == NULL) {
cb_fn(cb_arg, NULL, -ENOMEM);
_init_load_cleanup(vol, NULL);
return;
}
init_ctx->path = spdk_dma_zmalloc(REDUCE_PATH_MAX, 0, NULL);
if (init_ctx->path == NULL) {
cb_fn(cb_arg, NULL, -ENOMEM);
_init_load_cleanup(vol, init_ctx);
return;
}
if (spdk_mem_all_zero(&params->uuid, sizeof(params->uuid))) {
spdk_uuid_generate(&params->uuid);
}
memcpy(vol->pm_file.path, pm_file_dir, dir_len);
vol->pm_file.path[dir_len] = '/';
spdk_uuid_fmt_lower(&vol->pm_file.path[dir_len + 1], SPDK_UUID_STRING_LEN,
&params->uuid);
vol->pm_file.size = _get_pm_file_size(params);
vol->pm_file.pm_buf = pmem_map_file(vol->pm_file.path, vol->pm_file.size,
PMEM_FILE_CREATE | PMEM_FILE_EXCL, 0600,
&mapped_len, &vol->pm_file.pm_is_pmem);
if (vol->pm_file.pm_buf == NULL) {
SPDK_ERRLOG("could not pmem_map_file(%s): %s\n",
vol->pm_file.path, strerror(errno));
cb_fn(cb_arg, NULL, -errno);
_init_load_cleanup(vol, init_ctx);
return;
}
if (vol->pm_file.size != mapped_len) {
SPDK_ERRLOG("could not map entire pmem file (size=%" PRIu64 " mapped=%" PRIu64 ")\n",
vol->pm_file.size, mapped_len);
cb_fn(cb_arg, NULL, -ENOMEM);
_init_load_cleanup(vol, init_ctx);
return;
}
vol->backing_io_units_per_chunk = params->chunk_size / params->backing_io_unit_size;
vol->logical_blocks_per_chunk = params->chunk_size / params->logical_block_size;
vol->backing_lba_per_io_unit = params->backing_io_unit_size / backing_dev->blocklen;
memcpy(&vol->params, params, sizeof(*params));
vol->backing_dev = backing_dev;
rc = _allocate_bit_arrays(vol);
if (rc != 0) {
cb_fn(cb_arg, NULL, rc);
_init_load_cleanup(vol, init_ctx);
return;
}
memcpy(vol->backing_super->signature, SPDK_REDUCE_SIGNATURE,
sizeof(vol->backing_super->signature));
memcpy(&vol->backing_super->params, params, sizeof(*params));
_initialize_vol_pm_pointers(vol);
memcpy(vol->pm_super, vol->backing_super, sizeof(*vol->backing_super));
/* Writing 0xFF's is equivalent of filling it all with SPDK_EMPTY_MAP_ENTRY.
* Note that this writes 0xFF to not just the logical map but the chunk maps as well.
*/
memset(vol->pm_logical_map, 0xFF, vol->pm_file.size - sizeof(*vol->backing_super));
_reduce_persist(vol, vol->pm_file.pm_buf, vol->pm_file.size);
init_ctx->vol = vol;
init_ctx->cb_fn = cb_fn;
init_ctx->cb_arg = cb_arg;
memcpy(init_ctx->path, vol->pm_file.path, REDUCE_PATH_MAX);
init_ctx->iov[0].iov_base = init_ctx->path;
init_ctx->iov[0].iov_len = REDUCE_PATH_MAX;
init_ctx->backing_cb_args.cb_fn = _init_write_path_cpl;
init_ctx->backing_cb_args.cb_arg = init_ctx;
/* Write path to offset 4K on backing device - just after where the super
* block will be written. We wait until this is committed before writing the
* super block to guarantee we don't get the super block written without the
* the path if the system crashed in the middle of a write operation.
*/
vol->backing_dev->writev(vol->backing_dev, init_ctx->iov, 1,
REDUCE_BACKING_DEV_PATH_OFFSET / vol->backing_dev->blocklen,
REDUCE_PATH_MAX / vol->backing_dev->blocklen,
&init_ctx->backing_cb_args);
}
static void
_load_read_super_and_path_cpl(void *cb_arg, int reduce_errno)
{
struct reduce_init_load_ctx *load_ctx = cb_arg;
struct spdk_reduce_vol *vol = load_ctx->vol;
uint64_t backing_dev_size;
uint64_t i, num_chunks, logical_map_index;
struct spdk_reduce_chunk_map *chunk;
size_t mapped_len;
uint32_t j;
int rc;
if (memcmp(vol->backing_super->signature,
SPDK_REDUCE_SIGNATURE,
sizeof(vol->backing_super->signature)) != 0) {
/* This backing device isn't a libreduce backing device. */
rc = -EILSEQ;
goto error;
}
memcpy(&vol->params, &vol->backing_super->params, sizeof(vol->params));
vol->backing_io_units_per_chunk = vol->params.chunk_size / vol->params.backing_io_unit_size;
vol->logical_blocks_per_chunk = vol->params.chunk_size / vol->params.logical_block_size;
vol->backing_lba_per_io_unit = vol->params.backing_io_unit_size / vol->backing_dev->blocklen;
rc = _allocate_bit_arrays(vol);
if (rc != 0) {
goto error;
}
backing_dev_size = vol->backing_dev->blockcnt * vol->backing_dev->blocklen;
if (_get_vol_size(vol->params.chunk_size, backing_dev_size) < vol->params.vol_size) {
SPDK_ERRLOG("backing device size %" PRIi64 " smaller than expected\n",
backing_dev_size);
rc = -EILSEQ;
goto error;
}
memcpy(vol->pm_file.path, load_ctx->path, sizeof(vol->pm_file.path));
vol->pm_file.size = _get_pm_file_size(&vol->params);
vol->pm_file.pm_buf = pmem_map_file(vol->pm_file.path, 0, 0, 0, &mapped_len,
&vol->pm_file.pm_is_pmem);
if (vol->pm_file.pm_buf == NULL) {
SPDK_ERRLOG("could not pmem_map_file(%s): %s\n", vol->pm_file.path, strerror(errno));
rc = -errno;
goto error;
}
if (vol->pm_file.size != mapped_len) {
SPDK_ERRLOG("could not map entire pmem file (size=%" PRIu64 " mapped=%" PRIu64 ")\n",
vol->pm_file.size, mapped_len);
rc = -ENOMEM;
goto error;
}
rc = _allocate_vol_requests(vol);
if (rc != 0) {
goto error;
}
_initialize_vol_pm_pointers(vol);
num_chunks = vol->params.vol_size / vol->params.chunk_size;
for (i = 0; i < num_chunks; i++) {
logical_map_index = vol->pm_logical_map[i];
if (logical_map_index == REDUCE_EMPTY_MAP_ENTRY) {
continue;
}
spdk_bit_array_set(vol->allocated_chunk_maps, logical_map_index);
chunk = _reduce_vol_get_chunk_map(vol, logical_map_index);
for (j = 0; j < vol->backing_io_units_per_chunk; j++) {
if (chunk->io_unit_index[j] != REDUCE_EMPTY_MAP_ENTRY) {
spdk_bit_array_set(vol->allocated_backing_io_units, chunk->io_unit_index[j]);
}
}
}
load_ctx->cb_fn(load_ctx->cb_arg, vol, 0);
/* Only clean up the ctx - the vol has been passed to the application
* for use now that volume load was successful.
*/
_init_load_cleanup(NULL, load_ctx);
return;
error:
load_ctx->cb_fn(load_ctx->cb_arg, NULL, rc);
_init_load_cleanup(vol, load_ctx);
}
void
spdk_reduce_vol_load(struct spdk_reduce_backing_dev *backing_dev,
spdk_reduce_vol_op_with_handle_complete cb_fn, void *cb_arg)
{
struct spdk_reduce_vol *vol;
struct reduce_init_load_ctx *load_ctx;
if (backing_dev->readv == NULL || backing_dev->writev == NULL ||
backing_dev->unmap == NULL) {
SPDK_ERRLOG("backing_dev function pointer not specified\n");
cb_fn(cb_arg, NULL, -EINVAL);
return;
}
vol = calloc(1, sizeof(*vol));
if (vol == NULL) {
cb_fn(cb_arg, NULL, -ENOMEM);
return;
}
TAILQ_INIT(&vol->free_requests);
TAILQ_INIT(&vol->executing_requests);
TAILQ_INIT(&vol->queued_requests);
vol->backing_super = spdk_dma_zmalloc(sizeof(*vol->backing_super), 64, NULL);
if (vol->backing_super == NULL) {
_init_load_cleanup(vol, NULL);
cb_fn(cb_arg, NULL, -ENOMEM);
return;
}
vol->backing_dev = backing_dev;
load_ctx = calloc(1, sizeof(*load_ctx));
if (load_ctx == NULL) {
_init_load_cleanup(vol, NULL);
cb_fn(cb_arg, NULL, -ENOMEM);
return;
}
load_ctx->path = spdk_dma_zmalloc(REDUCE_PATH_MAX, 64, NULL);
if (load_ctx->path == NULL) {
_init_load_cleanup(vol, load_ctx);
cb_fn(cb_arg, NULL, -ENOMEM);
return;
}
load_ctx->vol = vol;
load_ctx->cb_fn = cb_fn;
load_ctx->cb_arg = cb_arg;
load_ctx->iov[0].iov_base = vol->backing_super;
load_ctx->iov[0].iov_len = sizeof(*vol->backing_super);
load_ctx->iov[1].iov_base = load_ctx->path;
load_ctx->iov[1].iov_len = REDUCE_PATH_MAX;
load_ctx->backing_cb_args.cb_fn = _load_read_super_and_path_cpl;
load_ctx->backing_cb_args.cb_arg = load_ctx;
vol->backing_dev->readv(vol->backing_dev, load_ctx->iov, LOAD_IOV_COUNT, 0,
(sizeof(*vol->backing_super) + REDUCE_PATH_MAX) /
vol->backing_dev->blocklen,
&load_ctx->backing_cb_args);
}
void
spdk_reduce_vol_unload(struct spdk_reduce_vol *vol,
spdk_reduce_vol_op_complete cb_fn, void *cb_arg)
{
if (vol == NULL) {
/* This indicates a programming error. */
assert(false);
cb_fn(cb_arg, -EINVAL);
return;
}
_init_load_cleanup(vol, NULL);
cb_fn(cb_arg, 0);
}
struct reduce_destroy_ctx {
spdk_reduce_vol_op_complete cb_fn;
void *cb_arg;
struct spdk_reduce_vol *vol;
struct spdk_reduce_vol_superblock *super;
struct iovec iov;
struct spdk_reduce_vol_cb_args backing_cb_args;
int reduce_errno;
char pm_path[REDUCE_PATH_MAX];
};
static void
destroy_unload_cpl(void *cb_arg, int reduce_errno)
{
struct reduce_destroy_ctx *destroy_ctx = cb_arg;
if (destroy_ctx->reduce_errno == 0) {
if (unlink(destroy_ctx->pm_path)) {
SPDK_ERRLOG("%s could not be unlinked: %s\n",
destroy_ctx->pm_path, strerror(errno));
}
}
/* Even if the unload somehow failed, we still pass the destroy_ctx
* reduce_errno since that indicates whether or not the volume was
* actually destroyed.
*/
destroy_ctx->cb_fn(destroy_ctx->cb_arg, destroy_ctx->reduce_errno);
spdk_dma_free(destroy_ctx->super);
free(destroy_ctx);
}
static void
_destroy_zero_super_cpl(void *cb_arg, int reduce_errno)
{
struct reduce_destroy_ctx *destroy_ctx = cb_arg;
struct spdk_reduce_vol *vol = destroy_ctx->vol;
destroy_ctx->reduce_errno = reduce_errno;
spdk_reduce_vol_unload(vol, destroy_unload_cpl, destroy_ctx);
}
static void
destroy_load_cb(void *cb_arg, struct spdk_reduce_vol *vol, int reduce_errno)
{
struct reduce_destroy_ctx *destroy_ctx = cb_arg;
if (reduce_errno != 0) {
destroy_ctx->cb_fn(destroy_ctx->cb_arg, reduce_errno);
spdk_dma_free(destroy_ctx->super);
free(destroy_ctx);
return;
}
destroy_ctx->vol = vol;
memcpy(destroy_ctx->pm_path, vol->pm_file.path, sizeof(destroy_ctx->pm_path));
destroy_ctx->iov.iov_base = destroy_ctx->super;
destroy_ctx->iov.iov_len = sizeof(*destroy_ctx->super);
destroy_ctx->backing_cb_args.cb_fn = _destroy_zero_super_cpl;
destroy_ctx->backing_cb_args.cb_arg = destroy_ctx;
vol->backing_dev->writev(vol->backing_dev, &destroy_ctx->iov, 1, 0,
sizeof(*destroy_ctx->super) / vol->backing_dev->blocklen,
&destroy_ctx->backing_cb_args);
}
void
spdk_reduce_vol_destroy(struct spdk_reduce_backing_dev *backing_dev,
spdk_reduce_vol_op_complete cb_fn, void *cb_arg)
{
struct reduce_destroy_ctx *destroy_ctx;
destroy_ctx = calloc(1, sizeof(*destroy_ctx));
if (destroy_ctx == NULL) {
cb_fn(cb_arg, -ENOMEM);
return;
}
destroy_ctx->super = spdk_dma_zmalloc(sizeof(*destroy_ctx->super), 64, NULL);
if (destroy_ctx->super == NULL) {
free(destroy_ctx);
cb_fn(cb_arg, -ENOMEM);
return;
}
destroy_ctx->cb_fn = cb_fn;
destroy_ctx->cb_arg = cb_arg;
spdk_reduce_vol_load(backing_dev, destroy_load_cb, destroy_ctx);
}
static bool
_request_spans_chunk_boundary(struct spdk_reduce_vol *vol, uint64_t offset, uint64_t length)
{
uint64_t start_chunk, end_chunk;
start_chunk = offset / vol->logical_blocks_per_chunk;
end_chunk = (offset + length - 1) / vol->logical_blocks_per_chunk;
return (start_chunk != end_chunk);
}
typedef void (*reduce_request_fn)(void *_req, int reduce_errno);
static void
_reduce_vol_complete_req(struct spdk_reduce_vol_request *req, int reduce_errno)
{
struct spdk_reduce_vol_request *next_req;
struct spdk_reduce_vol *vol = req->vol;
req->cb_fn(req->cb_arg, reduce_errno);
TAILQ_REMOVE(&vol->executing_requests, req, tailq);
TAILQ_FOREACH(next_req, &vol->queued_requests, tailq) {
if (next_req->logical_map_index == req->logical_map_index) {
TAILQ_REMOVE(&vol->queued_requests, next_req, tailq);
if (next_req->type == REDUCE_IO_READV) {
_start_readv_request(next_req);
} else {
assert(next_req->type == REDUCE_IO_WRITEV);
_start_writev_request(next_req);
}
break;
}
}
TAILQ_INSERT_HEAD(&vol->free_requests, req, tailq);
}
static void
_write_write_done(void *_req, int reduce_errno)
{
struct spdk_reduce_vol_request *req = _req;
struct spdk_reduce_vol *vol = req->vol;
uint64_t old_chunk_map_index;
struct spdk_reduce_chunk_map *old_chunk;
uint32_t i;
if (reduce_errno != 0) {
req->reduce_errno = reduce_errno;
}
assert(req->num_backing_ops > 0);
if (--req->num_backing_ops > 0) {
return;
}
if (req->reduce_errno != 0) {
_reduce_vol_complete_req(req, req->reduce_errno);
return;
}
old_chunk_map_index = vol->pm_logical_map[req->logical_map_index];
if (old_chunk_map_index != REDUCE_EMPTY_MAP_ENTRY) {
old_chunk = _reduce_vol_get_chunk_map(vol, old_chunk_map_index);
for (i = 0; i < vol->backing_io_units_per_chunk; i++) {
if (old_chunk->io_unit_index[i] == REDUCE_EMPTY_MAP_ENTRY) {
break;
}
assert(spdk_bit_array_get(vol->allocated_backing_io_units, old_chunk->io_unit_index[i]) == true);
spdk_bit_array_clear(vol->allocated_backing_io_units, old_chunk->io_unit_index[i]);
old_chunk->io_unit_index[i] = REDUCE_EMPTY_MAP_ENTRY;
}
spdk_bit_array_clear(vol->allocated_chunk_maps, old_chunk_map_index);
}
/*
* We don't need to persist the clearing of the old chunk map here. The old chunk map
* becomes invalid after we update the logical map, since the old chunk map will no
* longer have a reference to it in the logical map.
*/
/* Persist the new chunk map. This must be persisted before we update the logical map. */
_reduce_persist(vol, req->chunk, _reduce_vol_get_chunk_struct_size(vol));
vol->pm_logical_map[req->logical_map_index] = req->chunk_map_index;
_reduce_persist(vol, &vol->pm_logical_map[req->logical_map_index], sizeof(uint64_t));
_reduce_vol_complete_req(req, 0);
}
static void
_issue_backing_ops(struct spdk_reduce_vol_request *req, struct spdk_reduce_vol *vol,
reduce_request_fn next_fn, bool is_write)
{
struct iovec *iov;
uint8_t *buf;
uint32_t i;
if (req->chunk_is_compressed) {
iov = req->comp_buf_iov;
buf = req->comp_buf;
} else {
iov = req->decomp_buf_iov;
buf = req->decomp_buf;
}
req->num_backing_ops = req->num_io_units;
req->backing_cb_args.cb_fn = next_fn;
req->backing_cb_args.cb_arg = req;
for (i = 0; i < req->num_io_units; i++) {
iov[i].iov_base = buf + i * vol->params.backing_io_unit_size;
iov[i].iov_len = vol->params.backing_io_unit_size;
if (is_write) {
vol->backing_dev->writev(vol->backing_dev, &iov[i], 1,
req->chunk->io_unit_index[i] * vol->backing_lba_per_io_unit,
vol->backing_lba_per_io_unit, &req->backing_cb_args);
} else {
vol->backing_dev->readv(vol->backing_dev, &iov[i], 1,
req->chunk->io_unit_index[i] * vol->backing_lba_per_io_unit,
vol->backing_lba_per_io_unit, &req->backing_cb_args);
}
}
}
static void
_reduce_vol_write_chunk(struct spdk_reduce_vol_request *req, reduce_request_fn next_fn,
uint32_t compressed_size)
{
struct spdk_reduce_vol *vol = req->vol;
uint32_t i;
req->chunk_map_index = spdk_bit_array_find_first_clear(vol->allocated_chunk_maps, 0);
/* TODO: fail if no chunk map found - but really this should not happen if we
* size the number of requests similarly to number of extra chunk maps
*/
assert(req->chunk_map_index != UINT32_MAX);
spdk_bit_array_set(vol->allocated_chunk_maps, req->chunk_map_index);
req->chunk = _reduce_vol_get_chunk_map(vol, req->chunk_map_index);
req->num_io_units = spdk_divide_round_up(compressed_size,
vol->params.backing_io_unit_size);
req->chunk_is_compressed = (req->num_io_units != vol->backing_io_units_per_chunk);
req->chunk->compressed_size =
req->chunk_is_compressed ? compressed_size : vol->params.chunk_size;
for (i = 0; i < req->num_io_units; i++) {
req->chunk->io_unit_index[i] = spdk_bit_array_find_first_clear(vol->allocated_backing_io_units, 0);
/* TODO: fail if no backing block found - but really this should also not
* happen (see comment above).
*/
assert(req->chunk->io_unit_index[i] != UINT32_MAX);
spdk_bit_array_set(vol->allocated_backing_io_units, req->chunk->io_unit_index[i]);
}
while (i < vol->backing_io_units_per_chunk) {
req->chunk->io_unit_index[i++] = REDUCE_EMPTY_MAP_ENTRY;
}
_issue_backing_ops(req, vol, next_fn, true /* write */);
}
static void
_write_compress_done(void *_req, int reduce_errno)
{
struct spdk_reduce_vol_request *req = _req;
/* Negative reduce_errno indicates failure for compression operations.
* Just write the uncompressed data instead. Force this to happen
* by just passing the full chunk size to _reduce_vol_write_chunk.
* When it sees the data couldn't be compressed, it will just write
* the uncompressed buffer to disk.
*/
if (reduce_errno < 0) {
reduce_errno = req->vol->params.chunk_size;
}
/* Positive reduce_errno indicates number of bytes in compressed buffer. */
_reduce_vol_write_chunk(req, _write_write_done, (uint32_t)reduce_errno);
}
static void
_reduce_vol_compress_chunk(struct spdk_reduce_vol_request *req, reduce_request_fn next_fn)
{
struct spdk_reduce_vol *vol = req->vol;
req->backing_cb_args.cb_fn = next_fn;
req->backing_cb_args.cb_arg = req;
req->comp_buf_iov[0].iov_base = req->comp_buf;
req->comp_buf_iov[0].iov_len = vol->params.chunk_size;
req->decomp_buf_iov[0].iov_base = req->decomp_buf;
req->decomp_buf_iov[0].iov_len = vol->params.chunk_size;
vol->backing_dev->compress(vol->backing_dev,
req->decomp_buf_iov, 1, req->comp_buf_iov, 1,
&req->backing_cb_args);
}
static void
_reduce_vol_decompress_chunk(struct spdk_reduce_vol_request *req, reduce_request_fn next_fn)
{
struct spdk_reduce_vol *vol = req->vol;
req->backing_cb_args.cb_fn = next_fn;
req->backing_cb_args.cb_arg = req;
req->comp_buf_iov[0].iov_base = req->comp_buf;
req->comp_buf_iov[0].iov_len = req->chunk->compressed_size;
req->decomp_buf_iov[0].iov_base = req->decomp_buf;
req->decomp_buf_iov[0].iov_len = vol->params.chunk_size;
vol->backing_dev->decompress(vol->backing_dev,
req->comp_buf_iov, 1, req->decomp_buf_iov, 1,
&req->backing_cb_args);
}
static void
_write_decompress_done(void *_req, int reduce_errno)
{
struct spdk_reduce_vol_request *req = _req;
struct spdk_reduce_vol *vol = req->vol;
uint64_t chunk_offset;
uint8_t *buf;
int i;
/* Negative reduce_errno indicates failure for compression operations. */
if (reduce_errno < 0) {
_reduce_vol_complete_req(req, reduce_errno);
return;
}
/* Positive reduce_errno indicates number of bytes in decompressed
* buffer. This should equal the chunk size - otherwise that's another
* type of failure.
*/
if ((uint32_t)reduce_errno != vol->params.chunk_size) {
_reduce_vol_complete_req(req, -EIO);
return;
}
chunk_offset = req->offset % vol->logical_blocks_per_chunk;
buf = req->decomp_buf + chunk_offset * vol->params.logical_block_size;
for (i = 0; i < req->iovcnt; i++) {
memcpy(buf, req->iov[i].iov_base, req->iov[i].iov_len);
buf += req->iov[i].iov_len;
}
_reduce_vol_compress_chunk(req, _write_compress_done);
}
static void
_write_read_done(void *_req, int reduce_errno)
{
struct spdk_reduce_vol_request *req = _req;
if (reduce_errno != 0) {
req->reduce_errno = reduce_errno;
}
assert(req->num_backing_ops > 0);
if (--req->num_backing_ops > 0) {
return;
}
if (req->reduce_errno != 0) {
_reduce_vol_complete_req(req, req->reduce_errno);
return;
}
if (req->chunk_is_compressed) {
_reduce_vol_decompress_chunk(req, _write_decompress_done);
} else {
_write_decompress_done(req, req->chunk->compressed_size);
}
}
static void
_read_decompress_done(void *_req, int reduce_errno)
{
struct spdk_reduce_vol_request *req = _req;
struct spdk_reduce_vol *vol = req->vol;
uint64_t chunk_offset;
uint8_t *buf;
int i;
/* Negative reduce_errno indicates failure for compression operations. */
if (reduce_errno < 0) {
_reduce_vol_complete_req(req, reduce_errno);
return;
}
/* Positive reduce_errno indicates number of bytes in decompressed
* buffer. This should equal the chunk size - otherwise that's another
* type of failure.
*/
if ((uint32_t)reduce_errno != vol->params.chunk_size) {
_reduce_vol_complete_req(req, -EIO);
return;
}
chunk_offset = req->offset % vol->logical_blocks_per_chunk;
buf = req->decomp_buf + chunk_offset * vol->params.logical_block_size;
for (i = 0; i < req->iovcnt; i++) {
memcpy(req->iov[i].iov_base, buf, req->iov[i].iov_len);
buf += req->iov[i].iov_len;
}
_reduce_vol_complete_req(req, 0);
}
static void
_read_read_done(void *_req, int reduce_errno)
{
struct spdk_reduce_vol_request *req = _req;
if (reduce_errno != 0) {
req->reduce_errno = reduce_errno;
}
assert(req->num_backing_ops > 0);
if (--req->num_backing_ops > 0) {
return;
}
if (req->reduce_errno != 0) {
_reduce_vol_complete_req(req, req->reduce_errno);
return;
}
if (req->chunk_is_compressed) {
_reduce_vol_decompress_chunk(req, _read_decompress_done);
} else {
_read_decompress_done(req, req->chunk->compressed_size);
}
}
static void
_reduce_vol_read_chunk(struct spdk_reduce_vol_request *req, reduce_request_fn next_fn)
{
struct spdk_reduce_vol *vol = req->vol;
req->chunk_map_index = vol->pm_logical_map[req->logical_map_index];
assert(req->chunk_map_index != UINT32_MAX);
req->chunk = _reduce_vol_get_chunk_map(vol, req->chunk_map_index);
req->num_io_units = spdk_divide_round_up(req->chunk->compressed_size,
vol->params.backing_io_unit_size);
req->chunk_is_compressed = (req->num_io_units != vol->backing_io_units_per_chunk);
_issue_backing_ops(req, vol, next_fn, false /* read */);
}
static bool
_iov_array_is_valid(struct spdk_reduce_vol *vol, struct iovec *iov, int iovcnt,
uint64_t length)
{
uint64_t size = 0;
int i;
for (i = 0; i < iovcnt; i++) {
size += iov[i].iov_len;
}
return size == (length * vol->params.logical_block_size);
}
static bool
_check_overlap(struct spdk_reduce_vol *vol, uint64_t logical_map_index)
{
struct spdk_reduce_vol_request *req;
TAILQ_FOREACH(req, &vol->executing_requests, tailq) {
if (logical_map_index == req->logical_map_index) {
return true;
}
}
return false;
}
static void
_start_readv_request(struct spdk_reduce_vol_request *req)
{
TAILQ_INSERT_TAIL(&req->vol->executing_requests, req, tailq);
_reduce_vol_read_chunk(req, _read_read_done);
}
void
spdk_reduce_vol_readv(struct spdk_reduce_vol *vol,
struct iovec *iov, int iovcnt, uint64_t offset, uint64_t length,
spdk_reduce_vol_op_complete cb_fn, void *cb_arg)
{
struct spdk_reduce_vol_request *req;
uint64_t logical_map_index;
bool overlapped;
int i;
if (length == 0) {
cb_fn(cb_arg, 0);
return;
}
if (_request_spans_chunk_boundary(vol, offset, length)) {
cb_fn(cb_arg, -EINVAL);
return;
}
if (!_iov_array_is_valid(vol, iov, iovcnt, length)) {
cb_fn(cb_arg, -EINVAL);
return;
}
logical_map_index = offset / vol->logical_blocks_per_chunk;
overlapped = _check_overlap(vol, logical_map_index);
if (!overlapped && vol->pm_logical_map[logical_map_index] == REDUCE_EMPTY_MAP_ENTRY) {
/*
* This chunk hasn't been allocated. So treat the data as all
* zeroes for this chunk - do the memset and immediately complete
* the operation.
*/
for (i = 0; i < iovcnt; i++) {
memset(iov[i].iov_base, 0, iov[i].iov_len);
}
cb_fn(cb_arg, 0);
return;
}
req = TAILQ_FIRST(&vol->free_requests);
if (req == NULL) {
cb_fn(cb_arg, -ENOMEM);
return;
}
TAILQ_REMOVE(&vol->free_requests, req, tailq);
req->type = REDUCE_IO_READV;
req->vol = vol;
req->iov = iov;
req->iovcnt = iovcnt;
req->offset = offset;
req->logical_map_index = logical_map_index;
req->length = length;
req->cb_fn = cb_fn;
req->cb_arg = cb_arg;
if (!overlapped) {
_start_readv_request(req);
} else {
TAILQ_INSERT_TAIL(&vol->queued_requests, req, tailq);
}
}
static void
_start_writev_request(struct spdk_reduce_vol_request *req)
{
struct spdk_reduce_vol *vol = req->vol;
uint64_t chunk_offset;
uint32_t lbsize, lb_per_chunk;
int i;
uint8_t *buf;
TAILQ_INSERT_TAIL(&req->vol->executing_requests, req, tailq);
if (vol->pm_logical_map[req->logical_map_index] != REDUCE_EMPTY_MAP_ENTRY) {
/* Read old chunk, then overwrite with data from this write operation.
* TODO: bypass reading old chunk if this write operation overwrites
* the entire chunk.
*/
_reduce_vol_read_chunk(req, _write_read_done);
return;
}
buf = req->decomp_buf;
lbsize = vol->params.logical_block_size;
lb_per_chunk = vol->logical_blocks_per_chunk;
/* Note: we must zero out parts of req->buf not specified by this write operation. */
chunk_offset = req->offset % lb_per_chunk;
if (chunk_offset != 0) {
memset(buf, 0, chunk_offset * lbsize);
buf += chunk_offset * lbsize;
}
for (i = 0; i < req->iovcnt; i++) {
memcpy(buf, req->iov[i].iov_base, req->iov[i].iov_len);
buf += req->iov[i].iov_len;
}
chunk_offset += req->length;
if (chunk_offset != lb_per_chunk) {
memset(buf, 0, (lb_per_chunk - chunk_offset) * lbsize);
}
_reduce_vol_compress_chunk(req, _write_compress_done);
}
void
spdk_reduce_vol_writev(struct spdk_reduce_vol *vol,
struct iovec *iov, int iovcnt, uint64_t offset, uint64_t length,
spdk_reduce_vol_op_complete cb_fn, void *cb_arg)
{
struct spdk_reduce_vol_request *req;
uint64_t logical_map_index;
bool overlapped;
if (length == 0) {
cb_fn(cb_arg, 0);
return;
}
if (_request_spans_chunk_boundary(vol, offset, length)) {
cb_fn(cb_arg, -EINVAL);
return;
}
if (!_iov_array_is_valid(vol, iov, iovcnt, length)) {
cb_fn(cb_arg, -EINVAL);
return;
}
logical_map_index = offset / vol->logical_blocks_per_chunk;
overlapped = _check_overlap(vol, logical_map_index);
req = TAILQ_FIRST(&vol->free_requests);
if (req == NULL) {
cb_fn(cb_arg, -ENOMEM);
return;
}
TAILQ_REMOVE(&vol->free_requests, req, tailq);
req->type = REDUCE_IO_WRITEV;
req->vol = vol;
req->iov = iov;
req->iovcnt = iovcnt;
req->offset = offset;
req->logical_map_index = logical_map_index;
req->length = length;
req->cb_fn = cb_fn;
req->cb_arg = cb_arg;
if (!overlapped) {
_start_writev_request(req);
} else {
TAILQ_INSERT_TAIL(&vol->queued_requests, req, tailq);
}
}
const struct spdk_reduce_vol_params *
spdk_reduce_vol_get_params(struct spdk_reduce_vol *vol)
{
return &vol->params;
}
SPDK_LOG_REGISTER_COMPONENT("reduce", SPDK_LOG_REDUCE)