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lvm2/lib/metadata/vdo_manip.c

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/*
* Copyright (C) 2018-2019 Red Hat, Inc. All rights reserved.
*
* This file is part of LVM2.
*
* This copyrighted material is made available to anyone wishing to use,
* modify, copy, or redistribute it subject to the terms and conditions
* of the GNU Lesser General Public License v.2.1.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include "lib/misc/lib.h"
#include "lib/metadata/metadata.h"
#include "lib/locking/locking.h"
#include "lib/misc/lvm-string.h"
#include "lib/commands/toolcontext.h"
#include "lib/display/display.h"
#include "lib/metadata/segtype.h"
#include "lib/activate/activate.h"
#include "lib/config/defaults.h"
#include "lib/misc/lvm-exec.h"
#include <sys/sysinfo.h> // sysinfo
#include <stdarg.h>
const char *get_vdo_compression_state_name(enum dm_vdo_compression_state state)
{
switch (state) {
case DM_VDO_COMPRESSION_ONLINE:
return "online";
default:
log_debug(INTERNAL_ERROR "Unrecognized compression state: %u.", state);
/* Fall through */
case DM_VDO_COMPRESSION_OFFLINE:
return "offline";
}
}
const char *get_vdo_index_state_name(enum dm_vdo_index_state state)
{
switch (state) {
case DM_VDO_INDEX_ERROR:
return "error";
case DM_VDO_INDEX_CLOSED:
return "closed";
case DM_VDO_INDEX_OPENING:
return "opening";
case DM_VDO_INDEX_CLOSING:
return "closing";
case DM_VDO_INDEX_OFFLINE:
return "offline";
case DM_VDO_INDEX_ONLINE:
return "online";
default:
log_debug(INTERNAL_ERROR "Unrecognized index state: %u.", state);
/* Fall through */
case DM_VDO_INDEX_UNKNOWN:
return "unknown";
}
}
const char *get_vdo_operating_mode_name(enum dm_vdo_operating_mode mode)
{
switch (mode) {
case DM_VDO_MODE_RECOVERING:
return "recovering";
case DM_VDO_MODE_READ_ONLY:
return "read-only";
default:
log_debug(INTERNAL_ERROR "Unrecognized operating mode: %u.", mode);
/* Fall through */
case DM_VDO_MODE_NORMAL:
return "normal";
}
}
const char *get_vdo_write_policy_name(enum dm_vdo_write_policy policy)
{
switch (policy) {
case DM_VDO_WRITE_POLICY_SYNC:
return "sync";
case DM_VDO_WRITE_POLICY_ASYNC:
return "async";
case DM_VDO_WRITE_POLICY_ASYNC_UNSAFE:
return "async-unsafe";
default:
log_debug(INTERNAL_ERROR "Unrecognized VDO write policy: %u.", policy);
/* Fall through */
case DM_VDO_WRITE_POLICY_AUTO:
return "auto";
}
}
/*
* Size of VDO virtual LV is adding header_size in front and back of device
* to avoid colission with blkid checks.
*/
static uint64_t _get_virtual_size(uint32_t extents, uint32_t extent_size,
uint32_t header_size)
{
return (uint64_t) extents * extent_size + 2 * header_size;
}
uint64_t get_vdo_pool_virtual_size(const struct lv_segment *vdo_pool_seg)
{
return _get_virtual_size(vdo_pool_seg->vdo_pool_virtual_extents,
vdo_pool_seg->lv->vg->extent_size,
vdo_pool_seg->vdo_pool_header_size);
}
int update_vdo_pool_virtual_size(struct lv_segment *vdo_pool_seg)
{
struct seg_list *sl;
uint32_t extents = 0;
/* FIXME: as long as we have only SINGLE VDO with vdo-pool this works */
/* after adding support for multiple VDO LVs - this needs heavy rework */
dm_list_iterate_items(sl, &vdo_pool_seg->lv->segs_using_this_lv)
extents += sl->seg->len;
/* Only growing virtual/logical VDO size */
if (extents > vdo_pool_seg->vdo_pool_virtual_extents)
vdo_pool_seg->vdo_pool_virtual_extents = extents;
return 1;
}
uint32_t get_vdo_pool_max_extents(const struct dm_vdo_target_params *vtp,
uint32_t extent_size)
{
uint64_t max_extents = (DM_VDO_PHYSICAL_SIZE_MAXIMUM + extent_size - 1) / extent_size;
uint64_t max_slab_extents = ((extent_size - 1 + DM_VDO_SLABS_MAXIMUM *
((uint64_t)vtp->slab_size_mb << (20 - SECTOR_SHIFT))) /
extent_size);
max_extents = (max_slab_extents < max_extents) ? max_slab_extents : max_extents;
return (max_extents > UINT32_MAX) ? UINT32_MAX : (uint32_t)max_extents;
}
static int _sysfs_get_kvdo_value(const char *dm_name, const struct dm_info *dminfo,
const char *vdo_param, uint64_t *value)
{
char path[PATH_MAX];
char temp[64];
int fd, size, r = 0;
if (dm_snprintf(path, sizeof(path), "%sblock/dm-%d/vdo/%s",
dm_sysfs_dir(), dminfo->minor, vdo_param) < 0) {
log_debug("Failed to build kvdo path.");
return 0;
}
if ((fd = open(path, O_RDONLY)) < 0) {
/* try with older location */
if (dm_snprintf(path, sizeof(path), "%skvdo/%s/%s",
dm_sysfs_dir(), dm_name, vdo_param) < 0) {
log_debug("Failed to build kvdo path.");
return 0;
}
if ((fd = open(path, O_RDONLY)) < 0) {
log_sys_debug("open", path);
goto bad;
}
}
if ((size = read(fd, temp, sizeof(temp) - 1)) < 0) {
log_sys_debug("read", path);
goto bad;
}
temp[size] = 0;
errno = 0;
*value = strtoll(temp, NULL, 0);
if (errno) {
log_sys_debug("strtool", path);
goto bad;
}
r = 1;
bad:
if (fd >= 0 && close(fd))
log_sys_debug("close", path);
return r;
}
int parse_vdo_pool_status(struct dm_pool *mem, const struct logical_volume *vdo_pool_lv,
const char *params, const struct dm_info *dminfo,
struct lv_status_vdo *status)
{
struct dm_vdo_status_parse_result result;
char *dm_name;
status->usage = DM_PERCENT_INVALID;
status->saving = DM_PERCENT_INVALID;
status->data_usage = DM_PERCENT_INVALID;
if (!(dm_name = dm_build_dm_name(mem, vdo_pool_lv->vg->name,
vdo_pool_lv->name, lv_layer(vdo_pool_lv)))) {
log_error("Failed to build VDO DM name %s.",
display_lvname(vdo_pool_lv));
return 0;
}
if (!dm_vdo_status_parse(mem, params, &result)) {
log_error("Cannot parse %s VDO pool status %s.",
display_lvname(vdo_pool_lv), result.error);
return 0;
}
status->vdo = result.status;
if ((result.status->operating_mode == DM_VDO_MODE_NORMAL) &&
_sysfs_get_kvdo_value(dm_name, dminfo, "statistics/data_blocks_used",
&status->data_blocks_used) &&
_sysfs_get_kvdo_value(dm_name, dminfo, "statistics/logical_blocks_used",
&status->logical_blocks_used)) {
status->usage = dm_make_percent(result.status->used_blocks,
result.status->total_blocks);
status->saving = dm_make_percent(status->logical_blocks_used - status->data_blocks_used,
status->logical_blocks_used);
status->data_usage = dm_make_percent(status->data_blocks_used * DM_VDO_BLOCK_SIZE,
first_seg(vdo_pool_lv)->vdo_pool_virtual_extents *
(uint64_t) vdo_pool_lv->vg->extent_size);
}
return 1;
}
/*
* Formats data LV for a use as a VDO pool LV.
*
* Calls tool 'vdoformat' on the already active volume.
*/
static int _format_vdo_pool_data_lv(struct logical_volume *data_lv,
const struct dm_vdo_target_params *vtp,
uint64_t *logical_size)
{
char *dpath, *c;
const struct dm_config_node *cn;
const struct dm_config_value *cv;
struct pipe_data pdata;
uint64_t logical_size_aligned = 1;
FILE *f;
uint64_t lb;
unsigned slabbits;
unsigned reformating = 0;
int args = 1;
char buf_args[5][128];
char buf[256]; /* buffer for short disk header (64B) */
const char *argv[19] = { /* Max supported args */
find_config_tree_str_allow_empty(data_lv->vg->cmd, global_vdo_format_executable_CFG, NULL)
};
if (!(dpath = lv_path_dup(data_lv->vg->cmd->mem, data_lv))) {
log_error("Failed to build device path for VDO formatting of data volume %s.",
display_lvname(data_lv));
return 0;
}
if (*logical_size) {
logical_size_aligned = 0;
if (dm_snprintf(buf_args[args], sizeof(buf_args[0]), "--logical-size=" FMTu64 "K",
(*logical_size / 2)) < 0)
return_0;
argv[args] = buf_args[args];
args++;
}
slabbits = 31 - clz(vtp->slab_size_mb / DM_VDO_BLOCK_SIZE * 2 * 1024); /* to KiB / block_size */
log_debug("Slab size %s converted to %u bits.",
display_size(data_lv->vg->cmd, vtp->slab_size_mb * UINT64_C(2 * 1024)), slabbits);
if (dm_snprintf(buf_args[args], sizeof(buf_args[0]), "--slab-bits=%u", slabbits) < 0)
return_0;
argv[args] = buf_args[args];
args++;
if (vtp->check_point_frequency) {
if (dm_snprintf(buf_args[args], sizeof(buf_args[0]), "--uds-checkpoint-frequency=%u",
vtp->check_point_frequency) < 0)
return_0;
argv[args] = buf_args[args];
args++;
}
/* Convert size to GiB units or one of these strings: 0.25, 0.50, 0.75 */
if (vtp->index_memory_size_mb >= 1024) {
if (dm_snprintf(buf_args[args], sizeof(buf_args[0]), "--uds-memory-size=%u",
vtp->index_memory_size_mb / 1024) < 0)
return_0;
} else if (dm_snprintf(buf_args[args], sizeof(buf_args[0]), "--uds-memory-size=0.%u",
(vtp->index_memory_size_mb < 512) ? 25 :
(vtp->index_memory_size_mb < 768) ? 50 : 75) < 0)
return_0;
argv[args] = buf_args[args];
args++;
if (vtp->use_sparse_index) {
if (dm_snprintf(buf_args[args], sizeof(buf_args[0]), "--uds-sparse") < 0)
return_0;
argv[args] = buf_args[args];
args++;
}
/* Any other user opts add here */
if (!(cn = find_config_tree_array(data_lv->vg->cmd, global_vdo_format_options_CFG, NULL))) {
log_error(INTERNAL_ERROR "Unable to find configuration for vdoformat command options.");
return 0;
}
for (cv = cn->v; cv && args < 16; cv = cv->next) {
if (cv->type != DM_CFG_STRING) {
log_error("Invalid string in config file: "
"global/vdoformat_options.");
return 0;
}
if (cv->v.str[0])
argv[++args] = cv->v.str;
}
/* Only unused VDO data LV could be activated and wiped */
if (!dm_list_empty(&data_lv->segs_using_this_lv)) {
log_error(INTERNAL_ERROR "Failed to wipe logical VDO data for volume %s.",
display_lvname(data_lv));
return 0;
}
argv[args] = dpath;
if (!(f = pipe_open(data_lv->vg->cmd, argv, 0, &pdata))) {
log_error("WARNING: Cannot read output from %s.", argv[0]);
return 0;
}
while (!feof(f) && fgets(buf, sizeof(buf), f)) {
/* TODO: Watch out for locales */
if (!*logical_size)
if (sscanf(buf, "Logical blocks defaulted to " FMTu64 " blocks", &lb) == 1) {
*logical_size = lb * DM_VDO_BLOCK_SIZE;
log_verbose("Available VDO logical blocks " FMTu64 " (%s).",
lb, display_size(data_lv->vg->cmd, *logical_size));
}
if ((c = strchr(buf, '\n')))
*c = 0; /* cut last '\n' away */
if (buf[0]) {
if (reformating)
log_verbose(" %s", buf); /* Print vdo_format messages */
else
log_print_unless_silent(" %s", buf); /* Print vdo_format messages */
}
}
if (!pipe_close(&pdata)) {
log_error("Command %s failed.", argv[0]);
return 0;
}
if (!*logical_size) {
log_error("Number of VDO logical blocks was not provided by vdo_format output.");
return 0;
}
if (logical_size_aligned) {
// align obtained size to extent size
logical_size_aligned = *logical_size / data_lv->vg->extent_size * data_lv->vg->extent_size;
if (*logical_size != logical_size_aligned) {
log_debug("Using bigger VDO virtual size unaligned on extent size by %s.",
display_size(data_lv->vg->cmd, *logical_size - logical_size_aligned));
}
}
return 1;
}
/*
* convert_vdo_pool_lv
* @data_lv
* @vtp
* @virtual_extents
*
* Convert given data LV and its target parameters into a VDO LV with VDO pool.
*
* Returns: old data LV on success (passed data LV becomes VDO LV), NULL on failure
*/
struct logical_volume *convert_vdo_pool_lv(struct logical_volume *data_lv,
const struct dm_vdo_target_params *vtp,
uint32_t *virtual_extents,
int format,
uint64_t vdo_pool_header_size)
{
const uint32_t extent_size = data_lv->vg->extent_size;
struct cmd_context *cmd = data_lv->vg->cmd;
struct logical_volume *vdo_pool_lv = data_lv;
const struct segment_type *vdo_pool_segtype;
struct lv_segment *vdo_pool_seg;
uint64_t vdo_logical_size = 0;
uint64_t adjust;
if (!(vdo_pool_segtype = get_segtype_from_string(cmd, SEG_TYPE_NAME_VDO_POOL)))
return_NULL;
adjust = (*virtual_extents * (uint64_t) extent_size) % DM_VDO_BLOCK_SIZE;
if (adjust) {
*virtual_extents += (DM_VDO_BLOCK_SIZE - adjust) / extent_size;
log_print_unless_silent("Rounding size up to 4,00 KiB VDO logical extent boundary: %s.",
display_size(data_lv->vg->cmd, *virtual_extents * (uint64_t) extent_size));
}
if (*virtual_extents)
vdo_logical_size =
_get_virtual_size(*virtual_extents, extent_size, vdo_pool_header_size);
if (!dm_vdo_validate_target_params(vtp, vdo_logical_size))
return_0;
/* Format data LV as VDO volume */
if (format) {
if (test_mode()) {
log_verbose("Test mode: Skipping formatting of VDO pool volume.");
} else if (!_format_vdo_pool_data_lv(data_lv, vtp, &vdo_logical_size)) {
log_error("Cannot format VDO pool volume %s.", display_lvname(data_lv));
return NULL;
}
} else {
log_verbose("Skiping VDO formatting %s.", display_lvname(data_lv));
/* TODO: parse existing VDO data and retrieve vdo_logical_size */
if (!*virtual_extents)
vdo_logical_size = data_lv->size;
}
if (!deactivate_lv(data_lv->vg->cmd, data_lv)) {
log_error("Cannot deactivate formated VDO pool volume %s.",
display_lvname(data_lv));
return NULL;
}
vdo_logical_size -= 2 * vdo_pool_header_size;
if (vdo_logical_size < extent_size) {
if (!*virtual_extents)
/* User has not specified size and at least 1 extent is necessary */
log_error("Cannot create fully fitting VDO volume, "
"--virtualsize has to be specified.");
log_error("Size %s for VDO volume cannot be smaller then extent size %s.",
display_size(data_lv->vg->cmd, vdo_logical_size),
display_size(data_lv->vg->cmd, extent_size));
return NULL;
}
*virtual_extents = vdo_logical_size / extent_size;
/* Move segments from existing data_lv into LV_vdata */
if (!(data_lv = insert_layer_for_lv(cmd, vdo_pool_lv, 0, "_vdata")))
return_NULL;
vdo_pool_seg = first_seg(vdo_pool_lv);
vdo_pool_seg->segtype = vdo_pool_segtype;
vdo_pool_seg->vdo_params = *vtp;
vdo_pool_seg->vdo_pool_header_size = vdo_pool_header_size;
vdo_pool_seg->vdo_pool_virtual_extents = *virtual_extents;
vdo_pool_lv->status |= LV_VDO_POOL;
data_lv->status |= LV_VDO_POOL_DATA;
return data_lv;
}
int set_vdo_write_policy(enum dm_vdo_write_policy *vwp, const char *policy)
{
if (strcasecmp(policy, "sync") == 0)
*vwp = DM_VDO_WRITE_POLICY_SYNC;
else if (strcasecmp(policy, "async") == 0)
*vwp = DM_VDO_WRITE_POLICY_ASYNC;
else if (strcasecmp(policy, "async-unsafe") == 0)
*vwp = DM_VDO_WRITE_POLICY_ASYNC_UNSAFE;
else if (strcasecmp(policy, "auto") == 0)
*vwp = DM_VDO_WRITE_POLICY_AUTO;
else {
log_error("Unknown VDO write policy %s.", policy);
return 0;
}
return 1;
}
int fill_vdo_target_params(struct cmd_context *cmd,
struct dm_vdo_target_params *vtp,
uint64_t *vdo_pool_header_size,
struct profile *profile)
{
const char *policy;
// TODO: Postpone filling data to the moment when VG is known with profile.
// TODO: Maybe add more lvm cmdline switches to set profile settings.
vtp->use_compression =
find_config_tree_int(cmd, allocation_vdo_use_compression_CFG, profile);
vtp->use_deduplication =
find_config_tree_int(cmd, allocation_vdo_use_deduplication_CFG, profile);
vtp->use_metadata_hints =
find_config_tree_int(cmd, allocation_vdo_use_metadata_hints_CFG, profile);
vtp->minimum_io_size =
2019-10-04 15:58:18 +03:00
find_config_tree_int(cmd, allocation_vdo_minimum_io_size_CFG, profile) >> SECTOR_SHIFT;
vtp->block_map_cache_size_mb =
find_config_tree_int64(cmd, allocation_vdo_block_map_cache_size_mb_CFG, profile);
vtp->block_map_era_length =
find_config_tree_int(cmd, allocation_vdo_block_map_era_length_CFG, profile);
vtp->check_point_frequency =
find_config_tree_int(cmd, allocation_vdo_check_point_frequency_CFG, profile);
vtp->use_sparse_index =
find_config_tree_int(cmd, allocation_vdo_use_sparse_index_CFG, profile);
vtp->index_memory_size_mb =
find_config_tree_int64(cmd, allocation_vdo_index_memory_size_mb_CFG, profile);
vtp->slab_size_mb =
find_config_tree_int(cmd, allocation_vdo_slab_size_mb_CFG, profile);
vtp->ack_threads =
find_config_tree_int(cmd, allocation_vdo_ack_threads_CFG, profile);
vtp->bio_threads =
find_config_tree_int(cmd, allocation_vdo_bio_threads_CFG, profile);
vtp->bio_rotation =
find_config_tree_int(cmd, allocation_vdo_bio_rotation_CFG, profile);
vtp->cpu_threads =
find_config_tree_int(cmd, allocation_vdo_cpu_threads_CFG, profile);
vtp->hash_zone_threads =
find_config_tree_int(cmd, allocation_vdo_hash_zone_threads_CFG, profile);
vtp->logical_threads =
find_config_tree_int(cmd, allocation_vdo_logical_threads_CFG, profile);
vtp->physical_threads =
find_config_tree_int(cmd, allocation_vdo_physical_threads_CFG, profile);
vtp->max_discard =
find_config_tree_int(cmd, allocation_vdo_max_discard_CFG, profile);
policy = find_config_tree_str(cmd, allocation_vdo_write_policy_CFG, profile);
if (!set_vdo_write_policy(&vtp->write_policy, policy))
return_0;
*vdo_pool_header_size = 2 * find_config_tree_int64(cmd, allocation_vdo_pool_header_size_CFG, profile);
return 1;
}
static int _get_sysinfo_memory(uint64_t *total_mb, uint64_t *available_mb)
{
struct sysinfo si = { 0 };
*total_mb = *available_mb = UINT64_MAX;
if (sysinfo(&si) != 0)
return 0;
log_debug("Sysinfo free:%lu bufferram:%lu sharedram:%lu freehigh:%lu unit:%u.",
si.freeram >> 20, si.bufferram >> 20, si.sharedram >> 20,
si.freehigh >> 20, si.mem_unit);
*available_mb = ((uint64_t)(si.freeram + si.bufferram) * si.mem_unit) >> 30;
*total_mb = si.totalram >> 30;
return 1;
}
typedef struct mem_table_s {
const char *name;
uint64_t *value;
} mem_table_t;
static int _compare_mem_table_s(const void *a, const void *b){
return strcmp(((const mem_table_t*)a)->name, ((const mem_table_t*)b)->name);
}
static int _get_memory_info(uint64_t *total_mb, uint64_t *available_mb)
{
uint64_t anon_pages, mem_available, mem_free, mem_total, shmem, swap_free;
uint64_t can_swap;
mem_table_t mt[] = {
{ "AnonPages", &anon_pages },
{ "MemAvailable", &mem_available },
{ "MemFree", &mem_free },
{ "MemTotal", &mem_total },
{ "Shmem", &shmem },
{ "SwapFree", &swap_free },
};
char line[128], namebuf[32], *e, *tail;
FILE *fp;
mem_table_t findme = { namebuf, NULL };
mem_table_t *found;
if (!(fp = fopen("/proc/meminfo", "r")))
return _get_sysinfo_memory(total_mb, available_mb);
while (fgets(line, sizeof(line), fp)) {
if (!(e = strchr(line, ':')))
break;
if ((++e - line) > sizeof(namebuf))
continue; // something too long
(void)dm_strncpy((char*)findme.name, line, e - line);
found = bsearch(&findme, mt, DM_ARRAY_SIZE(mt), sizeof(mem_table_t),
_compare_mem_table_s);
if (!found)
continue; // not interesting
errno = 0;
*(found->value) = (uint64_t) strtoull(e, &tail, 10);
if ((e == tail) || errno)
log_debug("Failing to parse value from %s.", line);
else
log_debug("Parsed %s = " FMTu64 " KiB.", found->name, *(found->value));
}
(void)fclose(fp);
// use at most 2/3 of swap space to keep machine usable
can_swap = (anon_pages + shmem) * 2 / 3;
swap_free = swap_free * 2 / 3;
if (can_swap > swap_free)
can_swap = swap_free;
// TODO: add more constrains, i.e. 3/4 of physical RAM...
*total_mb = mem_total >> 10;
*available_mb = (mem_available + can_swap) >> 10;
return 1;
}
static uint64_t _round_1024(uint64_t s)
{
return (s + ((1 << 10) - 1)) >> 10;
}
static uint64_t _round_sectors_to_tib(uint64_t s)
{
return (s + ((UINT64_C(1) << (40 - SECTOR_SHIFT)) - 1)) >> (40 - SECTOR_SHIFT);
}
__attribute__ ((format(printf, 3, 4)))
static int _vdo_snprintf(char **buf, size_t *bufsize, const char *format, ...)
{
int n;
va_list ap;
va_start(ap, format);
n = vsnprintf(*buf, *bufsize, format, ap);
va_end(ap);
if (n < 0 || ((unsigned) n >= *bufsize))
return -1;
*buf += n;
*bufsize -= n;
return n;
}
int check_vdo_constrains(struct cmd_context *cmd, const struct vdo_pool_size_config *cfg)
{
static const char *_split[] = { "", " and", ",", "," };
uint64_t req_mb, total_mb, available_mb;
uint64_t phy_mb = _round_sectors_to_tib(UINT64_C(268) * cfg->physical_size); // 268 MiB per 1 TiB of physical size
uint64_t virt_mb = _round_1024(UINT64_C(1638) * _round_sectors_to_tib(cfg->virtual_size)); // 1.6 MiB per 1 TiB
uint64_t cache_mb = _round_1024(UINT64_C(1177) * cfg->block_map_cache_size_mb); // 1.15 MiB per 1 MiB cache size
char msg[512];
size_t mlen = sizeof(msg);
char *pmsg = msg;
int cnt, has_cnt;
if (cfg->block_map_cache_size_mb && (cache_mb < 150))
cache_mb = 150; // always at least 150 MiB for block map
// total required memory for VDO target
req_mb = 38 + cfg->index_memory_size_mb + virt_mb + phy_mb + cache_mb;
_get_memory_info(&total_mb, &available_mb);
has_cnt = cnt = (phy_mb ? 1 : 0) +
(virt_mb ? 1 : 0) +
(cfg->block_map_cache_size_mb ? 1 : 0) +
(cfg->index_memory_size_mb ? 1 : 0);
if (phy_mb)
(void)_vdo_snprintf(&pmsg, &mlen, " %s RAM for physical volume size %s%s",
display_size(cmd, phy_mb << (20 - SECTOR_SHIFT)),
display_size(cmd, cfg->physical_size), _split[--cnt]);
if (virt_mb)
(void)_vdo_snprintf(&pmsg, &mlen, " %s RAM for virtual volume size %s%s",
display_size(cmd, virt_mb << (20 - SECTOR_SHIFT)),
display_size(cmd, cfg->virtual_size), _split[--cnt]);
if (cfg->block_map_cache_size_mb)
(void)_vdo_snprintf(&pmsg, &mlen, " %s RAM for block map cache size %s%s",
display_size(cmd, cache_mb << (20 - SECTOR_SHIFT)),
display_size(cmd, ((uint64_t)cfg->block_map_cache_size_mb) << (20 - SECTOR_SHIFT)),
_split[--cnt]);
if (cfg->index_memory_size_mb)
(void)_vdo_snprintf(&pmsg, &mlen, " %s RAM for index memory",
display_size(cmd, ((uint64_t)cfg->index_memory_size_mb) << (20 - SECTOR_SHIFT)));
if (req_mb > available_mb) {
log_error("Not enough free memory for VDO target. %s RAM is required, but only %s RAM is available.",
display_size(cmd, req_mb << (20 - SECTOR_SHIFT)),
display_size(cmd, available_mb << (20 - SECTOR_SHIFT)));
if (has_cnt)
log_print_unless_silent("VDO configuration needs%s.", msg);
return 0;
}
log_debug("VDO requires %s RAM, currently available %s RAM.",
display_size(cmd, req_mb << (20 - SECTOR_SHIFT)),
display_size(cmd, available_mb << (20 - SECTOR_SHIFT)));
if (has_cnt)
log_verbose("VDO configuration needs%s.", msg);
return 1;
}