/*
* Copyright (c) 2024 Jiri Svoboda
* Copyright (c) 2008 Jakub Jermar
* Copyright (c) 2008 Martin Decky
* Copyright (c) 2011 Martin Sucha
* 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.
* - The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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.
*/
/** @addtogroup libblock
* @{
*/
/**
* @file
* @brief
*/
#include <ipc/loc.h>
#include <ipc/services.h>
#include <errno.h>
#include <async.h>
#include <as.h>
#include <assert.h>
#include <bd.h>
#include <fibril_synch.h>
#include <adt/list.h>
#include <adt/hash_table.h>
#include <macros.h>
#include <mem.h>
#include <stdlib.h>
#include <stdio.h>
#include <stacktrace.h>
#include <str_error.h>
#include <offset.h>
#include <inttypes.h>
#include "block.h"
#define MAX_WRITE_RETRIES 10
/** Lock protecting the device connection list */
static FIBRIL_MUTEX_INITIALIZE(dcl_lock);
/** Device connection list head. */
static LIST_INITIALIZE(dcl);
typedef struct {
fibril_mutex_t lock;
size_t lblock_size; /**< Logical block size. */
unsigned blocks_cluster; /**< Physical blocks per block_t */
unsigned block_count; /**< Total number of blocks. */
unsigned blocks_cached; /**< Number of cached blocks. */
hash_table_t block_hash;
list_t free_list;
enum cache_mode mode;
} cache_t;
typedef struct {
link_t link;
service_id_t service_id;
async_sess_t *sess;
bd_t *bd;
void *bb_buf;
aoff64_t bb_addr;
aoff64_t pblocks; /**< Number of physical blocks */
size_t pblock_size; /**< Physical block size. */
cache_t *cache;
} devcon_t;
static errno_t read_blocks(devcon_t *, aoff64_t, size_t, void *, size_t);
static errno_t write_blocks(devcon_t *, aoff64_t, size_t, void *, size_t);
static aoff64_t ba_ltop(devcon_t *, aoff64_t);
static devcon_t *devcon_search(service_id_t service_id)
{
fibril_mutex_lock(&dcl_lock);
list_foreach(dcl, link, devcon_t, devcon) {
if (devcon->service_id == service_id) {
fibril_mutex_unlock(&dcl_lock);
return devcon;
}
}
fibril_mutex_unlock(&dcl_lock);
return NULL;
}
static errno_t devcon_add(service_id_t service_id, async_sess_t *sess,
size_t bsize, aoff64_t dev_size, bd_t *bd)
{
devcon_t *devcon;
devcon = malloc(sizeof(devcon_t));
if (!devcon)
return ENOMEM;
link_initialize(&devcon->link);
devcon->service_id = service_id;
devcon->sess = sess;
devcon->bd = bd;
devcon->bb_buf = NULL;
devcon->bb_addr = 0;
devcon->pblock_size = bsize;
devcon->pblocks = dev_size;
devcon->cache = NULL;
fibril_mutex_lock(&dcl_lock);
list_foreach(dcl, link, devcon_t, d) {
if (d->service_id == service_id) {
fibril_mutex_unlock(&dcl_lock);
free(devcon);
return EEXIST;
}
}
list_append(&devcon->link, &dcl);
fibril_mutex_unlock(&dcl_lock);
return EOK;
}
static void devcon_remove(devcon_t *devcon)
{
fibril_mutex_lock(&dcl_lock);
list_remove(&devcon->link);
fibril_mutex_unlock(&dcl_lock);
}
errno_t block_init(service_id_t service_id)
{
bd_t *bd;
async_sess_t *sess = loc_service_connect(service_id, INTERFACE_BLOCK,
IPC_FLAG_BLOCKING);
if (!sess) {
return ENOENT;
}
errno_t rc = bd_open(sess, &bd);
if (rc != EOK) {
async_hangup(sess);
return rc;
}
size_t bsize;
rc = bd_get_block_size(bd, &bsize);
if (rc != EOK) {
bd_close(bd);
async_hangup(sess);
return rc;
}
aoff64_t dev_size;
rc = bd_get_num_blocks(bd, &dev_size);
if (rc != EOK) {
bd_close(bd);
async_hangup(sess);
return rc;
}
rc = devcon_add(service_id, sess, bsize, dev_size, bd);
if (rc != EOK) {
bd_close(bd);
async_hangup(sess);
return rc;
}
return EOK;
}
void block_fini(service_id_t service_id)
{
devcon_t *devcon = devcon_search(service_id);
assert(devcon);
if (devcon->cache)
(void) block_cache_fini(service_id);
(void)bd_sync_cache(devcon->bd, 0, 0);
devcon_remove(devcon);
if (devcon->bb_buf)
free(devcon->bb_buf);
bd_close(devcon->bd);
async_hangup(devcon->sess);
free(devcon);
}
errno_t block_bb_read(service_id_t service_id, aoff64_t ba)
{
void *bb_buf;
errno_t rc;
devcon_t *devcon = devcon_search(service_id);
if (!devcon)
return ENOENT;
if (devcon->bb_buf)
return EEXIST;
bb_buf = malloc(devcon->pblock_size);
if (!bb_buf)
return ENOMEM;
rc = read_blocks(devcon, 0, 1, bb_buf, devcon->pblock_size);
if (rc != EOK) {
free(bb_buf);
return rc;
}
devcon->bb_buf = bb_buf;
devcon->bb_addr = ba;
return EOK;
}
void *block_bb_get(service_id_t service_id)
{
devcon_t *devcon = devcon_search(service_id);
assert(devcon);
return devcon->bb_buf;
}
static size_t cache_key_hash(const void *key)
{
const aoff64_t *lba = key;
return *lba;
}
static size_t cache_hash(const ht_link_t *item)
{
block_t *b = hash_table_get_inst(item, block_t, hash_link);
return b->lba;
}
static bool cache_key_equal(const void *key, size_t hash, const ht_link_t *item)
{
const aoff64_t *lba = key;
block_t *b = hash_table_get_inst(item, block_t, hash_link);
return b->lba == *lba;
}
static const hash_table_ops_t cache_ops = {
.hash = cache_hash,
.key_hash = cache_key_hash,
.key_equal = cache_key_equal,
.equal = NULL,
.remove_callback = NULL
};
errno_t block_cache_init(service_id_t service_id, size_t size, unsigned blocks,
enum cache_mode mode)
{
devcon_t *devcon = devcon_search(service_id);
cache_t *cache;
if (!devcon)
return ENOENT;
if (devcon->cache)
return EEXIST;
cache = malloc(sizeof(cache_t));
if (!cache)
return ENOMEM;
fibril_mutex_initialize(&cache->lock);
list_initialize(&cache->free_list);
cache->lblock_size = size;
cache->block_count = blocks;
cache->blocks_cached = 0;
cache->mode = mode;
/* Allow 1:1 or small-to-large block size translation */
if (cache->lblock_size % devcon->pblock_size != 0) {
free(cache);
return ENOTSUP;
}
cache->blocks_cluster = cache->lblock_size / devcon->pblock_size;
if (!hash_table_create(&cache->block_hash, 0, 0, &cache_ops)) {
free(cache);
return ENOMEM;
}
devcon->cache = cache;
return EOK;
}
errno_t block_cache_fini(service_id_t service_id)
{
devcon_t *devcon = devcon_search(service_id);
cache_t *cache;
errno_t rc;
if (!devcon)
return ENOENT;
if (!devcon->cache)
return EOK;
cache = devcon->cache;
/*
* We are expecting to find all blocks for this device handle on the
* free list, i.e. the block reference count should be zero. Do not
* bother with the cache and block locks because we are single-threaded.
*/
while (!list_empty(&cache->free_list)) {
block_t *b = list_get_instance(list_first(&cache->free_list),
block_t, free_link);
list_remove(&b->free_link);
if (b->dirty) {
rc = write_blocks(devcon, b->pba, cache->blocks_cluster,
b->data, b->size);
if (rc != EOK)
return rc;
}
hash_table_remove_item(&cache->block_hash, &b->hash_link);
free(b->data);
free(b);
}
hash_table_destroy(&cache->block_hash);
devcon->cache = NULL;
free(cache);
return EOK;
}
#define CACHE_LO_WATERMARK 10
#define CACHE_HI_WATERMARK 20
static bool cache_can_grow(cache_t *cache)
{
if (cache->blocks_cached < CACHE_LO_WATERMARK)
return true;
if (!list_empty(&cache->free_list))
return false;
return true;
}
static void block_initialize(block_t *b)
{
fibril_mutex_initialize(&b->lock);
b->refcnt = 1;
b->write_failures = 0;
b->dirty = false;
b->toxic = false;
fibril_rwlock_initialize(&b->contents_lock);
link_initialize(&b->free_link);
}
/** Instantiate a block in memory and get a reference to it.
*
* @param block Pointer to where the function will store the
* block pointer on success.
* @param service_id Service ID of the block device.
* @param ba Block address (logical).
* @param flags If BLOCK_FLAGS_NOREAD is specified, block_get()
* will not read the contents of the block from the
* device.
*
* @return EOK on success or an error code.
*/
errno_t block_get(block_t **block, service_id_t service_id, aoff64_t ba, int flags)
{
devcon_t *devcon;
cache_t *cache;
block_t *b;
link_t *link;
aoff64_t p_ba;
errno_t rc;
devcon = devcon_search(service_id);
assert(devcon);
assert(devcon->cache);
cache = devcon->cache;
/*
* Check whether the logical block (or part of it) is beyond
* the end of the device or not.
*/
p_ba = ba_ltop(devcon, ba);
p_ba += cache->blocks_cluster;
if (p_ba >= devcon->pblocks) {
/* This request cannot be satisfied */
return EIO;
}
retry:
rc = EOK;
b = NULL;
fibril_mutex_lock(&cache->lock);
ht_link_t *hlink = hash_table_find(&cache->block_hash, &ba);
if (hlink) {
found:
/*
* We found the block in the cache.
*/
b = hash_table_get_inst(hlink, block_t, hash_link);
fibril_mutex_lock(&b->lock);
if (b->refcnt++ == 0)
list_remove(&b->free_link);
if (b->toxic)
rc = EIO;
fibril_mutex_unlock(&b->lock);
fibril_mutex_unlock(&cache->lock);
} else {
/*
* The block was not found in the cache.
*/
if (cache_can_grow(cache)) {
/*
* We can grow the cache by allocating new blocks.
* Should the allocation fail, we fail over and try to
* recycle a block from the cache.
*/
b = malloc(sizeof(block_t));
if (!b)
goto recycle;
b->data = malloc(cache->lblock_size);
if (!b->data) {
free(b);
b = NULL;
goto recycle;
}
cache->blocks_cached++;
} else {
/*
* Try to recycle a block from the free list.
*/
recycle:
if (list_empty(&cache->free_list)) {
fibril_mutex_unlock(&cache->lock);
rc = ENOMEM;
goto out;
}
link = list_first(&cache->free_list);
b = list_get_instance(link, block_t, free_link);
fibril_mutex_lock(&b->lock);
if (b->dirty) {
/*
* The block needs to be written back to the
* device before it changes identity. Do this
* while not holding the cache lock so that
* concurrency is not impeded. Also move the
* block to the end of the free list so that we
* do not slow down other instances of
* block_get() draining the free list.
*/
list_remove(&b->free_link);
list_append(&b->free_link, &cache->free_list);
fibril_mutex_unlock(&cache->lock);
rc = write_blocks(devcon, b->pba,
cache->blocks_cluster, b->data, b->size);
if (rc != EOK) {
/*
* We did not manage to write the block
* to the device. Keep it around for
* another try. Hopefully, we will grab
* another block next time.
*/
if (b->write_failures < MAX_WRITE_RETRIES) {
b->write_failures++;
fibril_mutex_unlock(&b->lock);
goto retry;
} else {
printf("Too many errors writing block %"
PRIuOFF64 "from device handle %" PRIun "\n"
"SEVERE DATA LOSS POSSIBLE\n",
b->lba, devcon->service_id);
}
} else
b->write_failures = 0;
b->dirty = false;
if (!fibril_mutex_trylock(&cache->lock)) {
/*
* Somebody is probably racing with us.
* Unlock the block and retry.
*/
fibril_mutex_unlock(&b->lock);
goto retry;
}
hlink = hash_table_find(&cache->block_hash, &ba);
if (hlink) {
/*
* Someone else must have already
* instantiated the block while we were
* not holding the cache lock.
* Leave the recycled block on the
* freelist and continue as if we
* found the block of interest during
* the first try.
*/
fibril_mutex_unlock(&b->lock);
goto found;
}
}
fibril_mutex_unlock(&b->lock);
/*
* Unlink the block from the free list and the hash
* table.
*/
list_remove(&b->free_link);
hash_table_remove_item(&cache->block_hash, &b->hash_link);
}
block_initialize(b);
b->service_id = service_id;
b->size = cache->lblock_size;
b->lba = ba;
b->pba = ba_ltop(devcon, b->lba);
hash_table_insert(&cache->block_hash, &b->hash_link);
/*
* Lock the block before releasing the cache lock. Thus we don't
* kill concurrent operations on the cache while doing I/O on
* the block.
*/
fibril_mutex_lock(&b->lock);
fibril_mutex_unlock(&cache->lock);
if (!(flags & BLOCK_FLAGS_NOREAD)) {
/*
* The block contains old or no data. We need to read
* the new contents from the device.
*/
rc = read_blocks(devcon, b->pba, cache->blocks_cluster,
b->data, cache->lblock_size);
if (rc != EOK)
b->toxic = true;
} else
rc = EOK;
fibril_mutex_unlock(&b->lock);
}
out:
if ((rc != EOK) && b) {
assert(b->toxic);
(void) block_put(b);
b = NULL;
}
*block = b;
return rc;
}
/** Release a reference to a block.
*
* If the last reference is dropped, the block is put on the free list.
*
* @param block Block of which a reference is to be released.
*
* @return EOK on success or an error code.
*/
errno_t block_put(block_t *block)
{
devcon_t *devcon = devcon_search(block->service_id);
cache_t *cache;
unsigned blocks_cached;
enum cache_mode mode;
errno_t rc = EOK;
assert(devcon);
assert(devcon->cache);
assert(block->refcnt >= 1);
cache = devcon->cache;
retry:
fibril_mutex_lock(&cache->lock);
blocks_cached = cache->blocks_cached;
mode = cache->mode;
fibril_mutex_unlock(&cache->lock);
/*
* Determine whether to sync the block. Syncing the block is best done
* when not holding the cache lock as it does not impede concurrency.
* Since the situation may have changed when we unlocked the cache, the
* blocks_cached and mode variables are mere hints. We will recheck the
* conditions later when the cache lock is held again.
*/
fibril_mutex_lock(&block->lock);
if (block->toxic)
block->dirty = false; /* will not write back toxic block */
if (block->dirty && (block->refcnt == 1) &&
(blocks_cached > CACHE_HI_WATERMARK || mode != CACHE_MODE_WB)) {
rc = write_blocks(devcon, block->pba, cache->blocks_cluster,
block->data, block->size);
if (rc == EOK)
block->write_failures = 0;
block->dirty = false;
}
fibril_mutex_unlock(&block->lock);
fibril_mutex_lock(&cache->lock);
fibril_mutex_lock(&block->lock);
if (!--block->refcnt) {
/*
* Last reference to the block was dropped. Either free the
* block or put it on the free list. In case of an I/O error,
* free the block.
*/
if ((cache->blocks_cached > CACHE_HI_WATERMARK) ||
(rc != EOK)) {
/*
* Currently there are too many cached blocks or there
* was an I/O error when writing the block back to the
* device.
*/
if (block->dirty) {
/*
* We cannot sync the block while holding the
* cache lock. Release everything and retry.
*/
block->refcnt++;
if (block->write_failures < MAX_WRITE_RETRIES) {
block->write_failures++;
fibril_mutex_unlock(&block->lock);
fibril_mutex_unlock(&cache->lock);
goto retry;
} else {
printf("Too many errors writing block %"
PRIuOFF64 "from device handle %" PRIun "\n"
"SEVERE DATA LOSS POSSIBLE\n",
block->lba, devcon->service_id);
}
}
/*
* Take the block out of the cache and free it.
*/
hash_table_remove_item(&cache->block_hash, &block->hash_link);
fibril_mutex_unlock(&block->lock);
free(block->data);
free(block);
cache->blocks_cached--;
fibril_mutex_unlock(&cache->lock);
return rc;
}
/*
* Put the block on the free list.
*/
if (cache->mode != CACHE_MODE_WB && block->dirty) {
/*
* We cannot sync the block while holding the cache
* lock. Release everything and retry.
*/
block->refcnt++;
fibril_mutex_unlock(&block->lock);
fibril_mutex_unlock(&cache->lock);
goto retry;
}
list_append(&block->free_link, &cache->free_list);
}
fibril_mutex_unlock(&block->lock);
fibril_mutex_unlock(&cache->lock);
return rc;
}
/** Read sequential data from a block device.
*
* @param service_id Service ID of the block device.
* @param buf Buffer for holding one block
* @param bufpos Pointer to the first unread valid offset within the
* communication buffer.
* @param buflen Pointer to the number of unread bytes that are ready in
* the communication buffer.
* @param pos Device position to be read.
* @param dst Destination buffer.
* @param size Size of the destination buffer.
* @param block_size Block size to be used for the transfer.
*
* @return EOK on success or an error code on failure.
*/
errno_t block_seqread(service_id_t service_id, void *buf, size_t *bufpos,
size_t *buflen, aoff64_t *pos, void *dst, size_t size)
{
size_t offset = 0;
size_t left = size;
size_t block_size;
devcon_t *devcon;
devcon = devcon_search(service_id);
assert(devcon);
block_size = devcon->pblock_size;
while (left > 0) {
size_t rd;
if (*bufpos + left < *buflen)
rd = left;
else
rd = *buflen - *bufpos;
if (rd > 0) {
/*
* Copy the contents of the communication buffer to the
* destination buffer.
*/
memcpy(dst + offset, buf + *bufpos, rd);
offset += rd;
*bufpos += rd;
*pos += rd;
left -= rd;
}
if (*bufpos == *buflen) {
/* Refill the communication buffer with a new block. */
errno_t rc;
rc = read_blocks(devcon, *pos / block_size, 1, buf,
devcon->pblock_size);
if (rc != EOK) {
return rc;
}
*bufpos = 0;
*buflen = block_size;
}
}
return EOK;
}
/** Read blocks directly from device (bypass cache).
*
* @param service_id Service ID of the block device.
* @param ba Address of first block (physical).
* @param cnt Number of blocks.
* @param src Buffer for storing the data.
*
* @return EOK on success or an error code on failure.
*/
errno_t block_read_direct(service_id_t service_id, aoff64_t ba, size_t cnt, void *buf)
{
devcon_t *devcon;
devcon = devcon_search(service_id);
assert(devcon);
return read_blocks(devcon, ba, cnt, buf, devcon->pblock_size * cnt);
}
/** Write blocks directly to device (bypass cache).
*
* @param service_id Service ID of the block device.
* @param ba Address of first block (physical).
* @param cnt Number of blocks.
* @param src The data to be written.
*
* @return EOK on success or an error code on failure.
*/
errno_t block_write_direct(service_id_t service_id, aoff64_t ba, size_t cnt,
const void *data)
{
devcon_t *devcon;
devcon = devcon_search(service_id);
assert(devcon);
return write_blocks(devcon, ba, cnt, (void *)data, devcon->pblock_size * cnt);
}
/** Synchronize blocks to persistent storage.
*
* @param service_id Service ID of the block device.
* @param ba Address of first block (physical).
* @param cnt Number of blocks.
*
* @return EOK on success or an error code on failure.
*/
errno_t block_sync_cache(service_id_t service_id, aoff64_t ba, size_t cnt)
{
devcon_t *devcon;
devcon = devcon_search(service_id);
assert(devcon);
return bd_sync_cache(devcon->bd, ba, cnt);
}
/** Get device block size.
*
* @param service_id Service ID of the block device.
* @param bsize Output block size.
*
* @return EOK on success or an error code on failure.
*/
errno_t block_get_bsize(service_id_t service_id, size_t *bsize)
{
devcon_t *devcon;
devcon = devcon_search(service_id);
assert(devcon);
return bd_get_block_size(devcon->bd, bsize);
}
/** Get number of blocks on device.
*
* @param service_id Service ID of the block device.
* @param nblocks Output number of blocks.
*
* @return EOK on success or an error code on failure.
*/
errno_t block_get_nblocks(service_id_t service_id, aoff64_t *nblocks)
{
devcon_t *devcon = devcon_search(service_id);
assert(devcon);
return bd_get_num_blocks(devcon->bd, nblocks);
}
/** Read bytes directly from the device (bypass cache)
*
* @param service_id Service ID of the block device.
* @param abs_offset Absolute offset in bytes where to start reading
* @param bytes Number of bytes to read
* @param data Buffer that receives the data
*
* @return EOK on success or an error code on failure.
*/
errno_t block_read_bytes_direct(service_id_t service_id, aoff64_t abs_offset,
size_t bytes, void *data)
{
errno_t rc;
size_t phys_block_size;
size_t buf_size;
void *buffer;
aoff64_t first_block;
aoff64_t last_block;
size_t blocks;
size_t offset;
rc = block_get_bsize(service_id, &phys_block_size);
if (rc != EOK) {
return rc;
}
/* calculate data position and required space */
first_block = abs_offset / phys_block_size;
offset = abs_offset % phys_block_size;
last_block = (abs_offset + bytes - 1) / phys_block_size;
blocks = last_block - first_block + 1;
buf_size = blocks * phys_block_size;
/* read the data into memory */
buffer = malloc(buf_size);
if (buffer == NULL) {
return ENOMEM;
}
rc = block_read_direct(service_id, first_block, blocks, buffer);
if (rc != EOK) {
free(buffer);
return rc;
}
/* copy the data from the buffer */
memcpy(data, buffer + offset, bytes);
free(buffer);
return EOK;
}
/** Get TOC from device.
*
* @param service_id Service ID of the block device.
* @param session Starting session.
*
* @return Allocated TOC structure.
* @return EOK on success or an error code.
*
*/
errno_t block_read_toc(service_id_t service_id, uint8_t session, void *buf,
size_t bufsize)
{
devcon_t *devcon = devcon_search(service_id);
assert(devcon);
return bd_read_toc(devcon->bd, session, buf, bufsize);
}
/** Read blocks from block device.
*
* @param devcon Device connection.
* @param ba Address of first block.
* @param cnt Number of blocks.
* @param src Buffer for storing the data.
*
* @return EOK on success or an error code on failure.
*/
static errno_t read_blocks(devcon_t *devcon, aoff64_t ba, size_t cnt, void *buf,
size_t size)
{
assert(devcon);
errno_t rc = bd_read_blocks(devcon->bd, ba, cnt, buf, size);
if (rc != EOK) {
printf("Error %s reading %zu blocks starting at block %" PRIuOFF64
" from device handle %" PRIun "\n", str_error_name(rc), cnt, ba,
devcon->service_id);
#ifndef NDEBUG
stacktrace_print();
#endif
}
return rc;
}
/** Write block to block device.
*
* @param devcon Device connection.
* @param ba Address of first block.
* @param cnt Number of blocks.
* @param src Buffer containing the data to write.
*
* @return EOK on success or an error code on failure.
*/
static errno_t write_blocks(devcon_t *devcon, aoff64_t ba, size_t cnt, void *data,
size_t size)
{
assert(devcon);
errno_t rc = bd_write_blocks(devcon->bd, ba, cnt, data, size);
if (rc != EOK) {
printf("Error %s writing %zu blocks starting at block %" PRIuOFF64
" to device handle %" PRIun "\n", str_error_name(rc), cnt, ba, devcon->service_id);
#ifndef NDEBUG
stacktrace_print();
#endif
}
return rc;
}
/** Convert logical block address to physical block address. */
static aoff64_t ba_ltop(devcon_t *devcon, aoff64_t lba)
{
assert(devcon->cache != NULL);
return lba * devcon->cache->blocks_cluster;
}
/** @}
*/