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lvm2/lib/report/report.c
Peter Rajnoha 81839cc4eb report: report numeric values (not string synonyms) for NUM and BIN fields with json_std format 
Internally, NUM and BIN fields are marked as DM_REPORT_FIELD_TYPE_NUM_NUMBER
through libdevmapper API. The new 'json_std' format mandates that the report
string representing such a value must be a number, not an arbitrary string.
This is because numeric values in 'json_std' format do not have double quotes
around them. This practically means, we can't use string synonyms
("named reserved values") for such values and the report string must always
represent a proper number.

With 'json' and 'basic' formats, this is not an issue because 'basic' format
doesn't have any structure or typing at all and 'json' format puts all values
in quotes, including numeric ones.
2022-08-16 13:42:50 +02:00

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/*
* Copyright (C) 2002-2004 Sistina Software, Inc. All rights reserved.
* Copyright (C) 2004-2019 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/report/report.h"
#include "lib/commands/toolcontext.h"
#include "lib/misc/lvm-string.h"
#include "lib/display/display.h"
#include "lib/activate/activate.h"
#include "lib/metadata/segtype.h"
#include "lib/cache/lvmcache.h"
#include "lib/device/device-types.h"
#include "lib/datastruct/str_list.h"
#include <stddef.h> /* offsetof() */
#include <float.h> /* DBL_MAX */
#include <time.h>
struct lvm_report_object {
struct volume_group *vg;
struct lv_with_info_and_seg_status *lvdm;
struct physical_volume *pv;
struct lv_segment *seg;
struct pv_segment *pvseg;
struct label *label;
};
static uint32_t _log_seqnum = 1;
/*
* Enum for field_num index to use in per-field reserved value definition.
* Each field is represented by enum value with name "field_<id>" where <id>
* is the field_id of the field as registered in columns.h.
*/
#define FIELD(type, strct, sorttype, head, field_name, width, func, id, desc, writeable) field_ ## id,
enum {
/* coverity[unnecessary_header] */
#include "columns.h"
};
#undef FIELD
static const uint64_t _zero64 = UINT64_C(0);
static const uint64_t _one64 = UINT64_C(1);
static const uint64_t _two64 = UINT64_C(2);
static const char _str_zero[] = "0";
static const char _str_one[] = "1";
static const char _str_no[] = "no";
static const char _str_yes[] = "yes";
static const char _str_unknown[] = "unknown";
static const double _siz_max = DBL_MAX;
/*
* 32 bit signed is casted to 64 bit unsigned in dm_report_field internally!
* So when stored in the struct, the _reserved_num_undef_32 is actually
* equal to _reserved_num_undef_64.
*/
static const int32_t _reserved_num_undef_32 = INT32_C(-1);
typedef enum {
/* top-level identification */
TIME_NULL,
TIME_NUM,
TIME_STR,
/* direct numeric value */
TIME_NUM__START,
TIME_NUM_MULTIPLIER,
TIME_NUM_MULTIPLIER_NEGATIVE,
TIME_NUM_DAY,
TIME_NUM_YEAR,
TIME_NUM__END,
/* direct string value */
TIME_STR_TIMEZONE,
/* time frame strings */
TIME_FRAME__START,
TIME_FRAME_AGO,
TIME_FRAME__END,
/* labels for dates */
TIME_LABEL_DATE__START,
TIME_LABEL_DATE_TODAY,
TIME_LABEL_DATE_YESTERDAY,
/* weekday name strings */
TIME_WEEKDAY__START,
TIME_WEEKDAY_SUNDAY,
TIME_WEEKDAY_MONDAY,
TIME_WEEKDAY_TUESDAY,
TIME_WEEKDAY_WEDNESDAY,
TIME_WEEKDAY_THURSDAY,
TIME_WEEKDAY_FRIDAY,
TIME_WEEKDAY_SATURDAY,
TIME_WEEKDAY__END,
TIME_LABEL_DATE__END,
/* labels for times */
TIME_LABEL_TIME__START,
TIME_LABEL_TIME_NOON,
TIME_LABEL_TIME_MIDNIGHT,
TIME_LABEL_TIME__END,
/* time unit strings */
TIME_UNIT__START,
TIME_UNIT_SECOND,
TIME_UNIT_SECOND_REL,
TIME_UNIT_MINUTE,
TIME_UNIT_MINUTE_REL,
TIME_UNIT_HOUR,
TIME_UNIT_HOUR_REL,
TIME_UNIT_AM,
TIME_UNIT_PM,
TIME_UNIT_DAY,
TIME_UNIT_WEEK,
TIME_UNIT_MONTH,
TIME_UNIT_YEAR,
TIME_UNIT_TZ_MINUTE,
TIME_UNIT_TZ_HOUR,
TIME_UNIT__END,
/* month name strings */
TIME_MONTH__START,
TIME_MONTH_JANUARY,
TIME_MONTH_FEBRUARY,
TIME_MONTH_MARCH,
TIME_MONTH_APRIL,
TIME_MONTH_MAY,
TIME_MONTH_JUNE,
TIME_MONTH_JULY,
TIME_MONTH_AUGUST,
TIME_MONTH_SEPTEMBER,
TIME_MONTH_OCTOBER,
TIME_MONTH_NOVEMBER,
TIME_MONTH_DECEMBER,
TIME_MONTH__END,
} time_id_t;
#define TIME_PROP_DATE 0x00000001 /* date-related */
#define TIME_PROP_TIME 0x00000002 /* time-related */
#define TIME_PROP_ABS 0x00000004 /* absolute value */
#define TIME_PROP_REL 0x00000008 /* relative value */
struct time_prop {
time_id_t id;
uint32_t prop_flags;
time_id_t granularity;
};
#define ADD_TIME_PROP(id, flags, granularity) [(id)] = {(id), (flags), (granularity)},
static const struct time_prop _time_props[] = {
ADD_TIME_PROP(TIME_NULL, 0, TIME_NULL)
ADD_TIME_PROP(TIME_NUM, 0, TIME_NULL)
ADD_TIME_PROP(TIME_STR, 0, TIME_NULL)
ADD_TIME_PROP(TIME_NUM_MULTIPLIER, 0, TIME_NULL)
ADD_TIME_PROP(TIME_NUM_MULTIPLIER_NEGATIVE, 0, TIME_NULL)
ADD_TIME_PROP(TIME_NUM_DAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_NUM_YEAR, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_YEAR)
ADD_TIME_PROP(TIME_STR_TIMEZONE, TIME_PROP_TIME | TIME_PROP_ABS, TIME_NULL)
ADD_TIME_PROP(TIME_FRAME_AGO, TIME_PROP_DATE | TIME_PROP_TIME | TIME_PROP_REL, TIME_NULL)
ADD_TIME_PROP(TIME_LABEL_DATE_TODAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_LABEL_DATE_YESTERDAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_WEEKDAY_SUNDAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_WEEKDAY_MONDAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_WEEKDAY_TUESDAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_WEEKDAY_WEDNESDAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_WEEKDAY_THURSDAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_WEEKDAY_FRIDAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_WEEKDAY_SATURDAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_LABEL_TIME_NOON, TIME_PROP_TIME | TIME_PROP_ABS, TIME_UNIT_SECOND)
ADD_TIME_PROP(TIME_LABEL_TIME_MIDNIGHT, TIME_PROP_TIME | TIME_PROP_ABS, TIME_UNIT_SECOND)
ADD_TIME_PROP(TIME_UNIT_SECOND, TIME_PROP_TIME | TIME_PROP_ABS, TIME_UNIT_SECOND)
ADD_TIME_PROP(TIME_UNIT_SECOND_REL, TIME_PROP_TIME | TIME_PROP_REL, TIME_UNIT_SECOND)
ADD_TIME_PROP(TIME_UNIT_MINUTE, TIME_PROP_TIME | TIME_PROP_ABS, TIME_UNIT_MINUTE)
ADD_TIME_PROP(TIME_UNIT_MINUTE_REL, TIME_PROP_TIME | TIME_PROP_REL, TIME_UNIT_MINUTE)
ADD_TIME_PROP(TIME_UNIT_HOUR, TIME_PROP_TIME | TIME_PROP_ABS, TIME_UNIT_HOUR)
ADD_TIME_PROP(TIME_UNIT_HOUR_REL, TIME_PROP_TIME | TIME_PROP_REL, TIME_UNIT_HOUR)
ADD_TIME_PROP(TIME_UNIT_AM, TIME_PROP_TIME | TIME_PROP_ABS, TIME_UNIT_HOUR)
ADD_TIME_PROP(TIME_UNIT_PM, TIME_PROP_TIME | TIME_PROP_ABS, TIME_UNIT_HOUR)
ADD_TIME_PROP(TIME_UNIT_DAY, TIME_PROP_DATE | TIME_PROP_REL, TIME_UNIT_DAY)
ADD_TIME_PROP(TIME_UNIT_WEEK, TIME_PROP_DATE | TIME_PROP_REL, TIME_UNIT_WEEK)
ADD_TIME_PROP(TIME_UNIT_MONTH, TIME_PROP_DATE | TIME_PROP_REL, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_UNIT_YEAR, TIME_PROP_DATE | TIME_PROP_REL, TIME_UNIT_YEAR)
ADD_TIME_PROP(TIME_UNIT_TZ_MINUTE, TIME_PROP_TIME | TIME_PROP_ABS, TIME_NULL)
ADD_TIME_PROP(TIME_UNIT_TZ_HOUR, TIME_PROP_TIME | TIME_PROP_ABS, TIME_NULL)
ADD_TIME_PROP(TIME_MONTH_JANUARY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_FEBRUARY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_MARCH, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_APRIL, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_MAY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_JUNE, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_JULY, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_AUGUST, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_SEPTEMBER, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_OCTOBER, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_NOVEMBER, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
ADD_TIME_PROP(TIME_MONTH_DECEMBER, TIME_PROP_DATE | TIME_PROP_ABS, TIME_UNIT_MONTH)
};
#define TIME_REG_PLURAL_S 0x00000001 /* also recognize plural form with "s" suffix */
struct time_reg {
const char *name;
const struct time_prop *prop;
uint32_t reg_flags;
};
#define TIME_PROP(id) (_time_props + (id))
static const struct time_reg _time_reg[] = {
/*
* Group of tokens representing time frame and used
* with relative date/time to specify different flavours
* of relativity.
*/
{"ago", TIME_PROP(TIME_FRAME_AGO), 0},
/*
* Group of tokens labeling some date and used
* instead of direct absolute specification.
*/
{"today", TIME_PROP(TIME_LABEL_DATE_TODAY), 0}, /* 0:00 - 23:59:59 for current date */
{"yesterday", TIME_PROP(TIME_LABEL_DATE_YESTERDAY), 0}, /* 0:00 - 23:59:59 for current date minus 1 day*/
/*
* Group of tokens labeling some date - weekday
* names used to build up date.
*/
{"Sunday", TIME_PROP(TIME_WEEKDAY_SUNDAY), TIME_REG_PLURAL_S},
{"Sun", TIME_PROP(TIME_WEEKDAY_SUNDAY), 0},
{"Monday", TIME_PROP(TIME_WEEKDAY_MONDAY), TIME_REG_PLURAL_S},
{"Mon", TIME_PROP(TIME_WEEKDAY_MONDAY), 0},
{"Tuesday", TIME_PROP(TIME_WEEKDAY_TUESDAY), TIME_REG_PLURAL_S},
{"Tue", TIME_PROP(TIME_WEEKDAY_TUESDAY), 0},
{"Wednesday", TIME_PROP(TIME_WEEKDAY_WEDNESDAY), TIME_REG_PLURAL_S},
{"Wed", TIME_PROP(TIME_WEEKDAY_WEDNESDAY), 0},
{"Thursday", TIME_PROP(TIME_WEEKDAY_THURSDAY), TIME_REG_PLURAL_S},
{"Thu", TIME_PROP(TIME_WEEKDAY_THURSDAY), 0},
{"Friday", TIME_PROP(TIME_WEEKDAY_FRIDAY), TIME_REG_PLURAL_S},
{"Fri", TIME_PROP(TIME_WEEKDAY_FRIDAY), 0},
{"Saturday", TIME_PROP(TIME_WEEKDAY_SATURDAY), TIME_REG_PLURAL_S},
{"Sat", TIME_PROP(TIME_WEEKDAY_SATURDAY), 0},
/*
* Group of tokens labeling some time and used
* instead of direct absolute specification.
*/
{"noon", TIME_PROP(TIME_LABEL_TIME_NOON), TIME_REG_PLURAL_S}, /* 12:00:00 */
{"midnight", TIME_PROP(TIME_LABEL_TIME_MIDNIGHT), TIME_REG_PLURAL_S}, /* 00:00:00 */
/*
* Group of tokens used to build up time. Most of these
* are used either as relative or absolute time units.
* The absolute ones are always used with TIME_FRAME_*
* token, otherwise the unit is relative.
*/
{"second", TIME_PROP(TIME_UNIT_SECOND), TIME_REG_PLURAL_S},
{"sec", TIME_PROP(TIME_UNIT_SECOND), TIME_REG_PLURAL_S},
{"s", TIME_PROP(TIME_UNIT_SECOND), 0},
{"minute", TIME_PROP(TIME_UNIT_MINUTE), TIME_REG_PLURAL_S},
{"min", TIME_PROP(TIME_UNIT_MINUTE), TIME_REG_PLURAL_S},
{"m", TIME_PROP(TIME_UNIT_MINUTE), 0},
{"hour", TIME_PROP(TIME_UNIT_HOUR), TIME_REG_PLURAL_S},
{"hr", TIME_PROP(TIME_UNIT_HOUR), TIME_REG_PLURAL_S},
{"h", TIME_PROP(TIME_UNIT_HOUR), 0},
{"AM", TIME_PROP(TIME_UNIT_AM), 0},
{"PM", TIME_PROP(TIME_UNIT_PM), 0},
/*
* Group of tokens used to build up date.
* These are all relative ones.
*/
{"day", TIME_PROP(TIME_UNIT_DAY), TIME_REG_PLURAL_S},
{"week", TIME_PROP(TIME_UNIT_WEEK), TIME_REG_PLURAL_S},
{"month", TIME_PROP(TIME_UNIT_MONTH), TIME_REG_PLURAL_S},
{"year", TIME_PROP(TIME_UNIT_YEAR), TIME_REG_PLURAL_S},
{"yr", TIME_PROP(TIME_UNIT_YEAR), TIME_REG_PLURAL_S},
/*
* Group of tokes used to build up date.
* These are all absolute.
*/
{"January", TIME_PROP(TIME_MONTH_JANUARY), 0},
{"Jan", TIME_PROP(TIME_MONTH_JANUARY), 0},
{"February", TIME_PROP(TIME_MONTH_FEBRUARY), 0},
{"Feb", TIME_PROP(TIME_MONTH_FEBRUARY), 0},
{"March", TIME_PROP(TIME_MONTH_MARCH), 0},
{"Mar", TIME_PROP(TIME_MONTH_MARCH), 0},
{"April", TIME_PROP(TIME_MONTH_APRIL), 0},
{"Apr", TIME_PROP(TIME_MONTH_APRIL), 0},
{"May", TIME_PROP(TIME_MONTH_MAY), 0},
{"June", TIME_PROP(TIME_MONTH_JUNE), 0},
{"Jun", TIME_PROP(TIME_MONTH_JUNE), 0},
{"July", TIME_PROP(TIME_MONTH_JULY), 0},
{"Jul", TIME_PROP(TIME_MONTH_JULY), 0},
{"August", TIME_PROP(TIME_MONTH_AUGUST), 0},
{"Aug", TIME_PROP(TIME_MONTH_AUGUST), 0},
{"September", TIME_PROP(TIME_MONTH_SEPTEMBER), 0},
{"Sep", TIME_PROP(TIME_MONTH_SEPTEMBER), 0},
{"October", TIME_PROP(TIME_MONTH_OCTOBER), 0},
{"Oct", TIME_PROP(TIME_MONTH_OCTOBER), 0},
{"November", TIME_PROP(TIME_MONTH_NOVEMBER), 0},
{"Nov", TIME_PROP(TIME_MONTH_NOVEMBER), 0},
{"December", TIME_PROP(TIME_MONTH_DECEMBER), 0},
{"Dec", TIME_PROP(TIME_MONTH_DECEMBER), 0},
{NULL, TIME_PROP(TIME_NULL), 0},
};
struct time_item {
struct dm_list list;
const struct time_prop *prop;
const char *s;
size_t len;
};
struct time_info {
struct dm_pool *mem;
struct dm_list *ti_list;
time_t *now;
time_id_t min_abs_date_granularity;
time_id_t max_abs_date_granularity;
time_id_t min_abs_time_granularity;
time_id_t min_rel_time_granularity;
};
static int _is_time_num(time_id_t id)
{
return ((id > TIME_NUM__START) && (id < TIME_NUM__END));
}
/*
static int _is_time_frame(time_id_t id)
{
return ((id > TIME_FRAME__START) && (id < TIME_FRAME__END));
}
*/
static int _is_time_label_date(time_id_t id)
{
return ((id > TIME_LABEL_DATE__START) && (id < TIME_LABEL_DATE__END));
}
static int _is_time_label_time(time_id_t id)
{
return ((id > TIME_LABEL_TIME__START) && (id < TIME_LABEL_TIME__END));
}
static int _is_time_unit(time_id_t id)
{
return ((id > TIME_UNIT__START) && (id < TIME_UNIT__END));
}
static int _is_time_weekday(time_id_t id)
{
return ((id > TIME_WEEKDAY__START) && (id < TIME_WEEKDAY__END));
}
static int _is_time_month(time_id_t id)
{
return ((id > TIME_MONTH__START) && (id < TIME_MONTH__END));
}
static const char *_skip_space(const char *s)
{
while (*s && isspace(*s))
s++;
return s;
}
/* Move till delim or space */
static const char *_move_till_item_end(const char *s)
{
char c = *s;
int is_num = isdigit(c);
/*
* Allow numbers to be attached to next token, for example
* it's correct to write "12 hours" as well as "12hours".
*/
while (c && !isspace(c) && (is_num ? (is_num = isdigit(c)) : 1))
c = *++s;
return s;
}
static struct time_item *_alloc_time_item(struct dm_pool *mem, time_id_t id,
const char *s, size_t len)
{
struct time_item *ti;
if (!(ti = dm_pool_zalloc(mem, sizeof(struct time_item)))) {
log_error("alloc_time_item: dm_pool_zalloc failed");
return NULL;
}
ti->prop = &_time_props[id];
ti->s = s;
ti->len = len;
return ti;
}
static int _add_time_part_to_list(struct dm_pool *mem, struct dm_list *list,
time_id_t id, int minus, const char *s, size_t len)
{
struct time_item *ti1, *ti2;
if (!(ti1 = _alloc_time_item(mem, minus ? TIME_NUM_MULTIPLIER_NEGATIVE
: TIME_NUM_MULTIPLIER, s, len)) ||
!(ti2 = _alloc_time_item(mem, id, s + len, 0)))
return 0;
dm_list_add(list, &ti1->list);
dm_list_add(list, &ti2->list);
return 1;
}
static int _get_time(struct dm_pool *mem, const char **str,
struct dm_list *list, int tz)
{
const char *end, *s = *str;
int r = 0;
/* hour */
end = _move_till_item_end(s);
if (!_add_time_part_to_list(mem, list, tz ? TIME_UNIT_TZ_HOUR : TIME_UNIT_HOUR,
tz == -1, s, end - s))
goto out;
/* minute */
if (*end != ':')
/* minute required */
goto out;
s = end + 1;
end = _move_till_item_end(s);
if (!_add_time_part_to_list(mem, list, tz ? TIME_UNIT_TZ_MINUTE : TIME_UNIT_MINUTE,
tz == -1, s, end - s))
goto out;
/* second */
if (*end != ':') {
/* second not required */
s = end + 1;
r = 1;
goto out;
} else if (tz)
/* timezone does not have seconds */
goto out;
s = end + 1;
end = _move_till_item_end(s);
if (!_add_time_part_to_list(mem, list, TIME_UNIT_SECOND, 0, s, end - s))
goto out;
s = end + 1;
r = 1;
out:
*str = s;
return r;
}
static int _preparse_fuzzy_time(const char *s, struct time_info *info)
{
struct dm_list *list;
struct time_item *ti;
const char *end;
int fuzzy = 0;
time_id_t id;
size_t len;
int r = 0;
char c;
if (!(list = dm_pool_alloc(info->mem, sizeof(struct dm_list)))) {
log_error("_preparse_fuzzy_time: dm_pool_alloc failed");
goto out;
}
dm_list_init(list);
s = _skip_space(s);
while ((c = *s)) {
/*
* If the string consists of -:+, digits or spaces,
* it's not worth looking for fuzzy names here -
* it's standard YYYY-MM-DD HH:MM:SS +-HH:MM format
* and that is parseable by libdm directly.
*/
if (!(isdigit(c) || (c == '-') || (c == ':') || (c == '+')))
fuzzy = 1;
end = _move_till_item_end(s);
if (isalpha(c))
id = TIME_STR;
else if (isdigit(c)) {
if (*end == ':') {
/* we have time */
if (!_get_time(info->mem, &s, list, 0))
goto out;
continue;
}
/* we have some other number */
id = TIME_NUM;
} else if ((c == '-') || (c == '+')) {
s++;
/* we have timezone */
if (!_get_time(info->mem, &s, list, (c == '-') ? -1 : 1))
goto out;
continue;
} else
goto out;
len = end - s;
if (!(ti = _alloc_time_item(info->mem, id, s, len)))
goto out;
dm_list_add(list, &ti->list);
s += len;
s = _skip_space(s);
}
info->ti_list = list;
r = 1;
out:
if (!(r && fuzzy)) {
dm_pool_free(info->mem, list);
return 0;
}
return 1;
}
static int _match_time_str(struct dm_list *ti_list, struct time_item *ti)
{
struct time_item *ti_context_p = (struct time_item *) dm_list_prev(ti_list, &ti->list);
size_t reg_len;
int i;
ti->prop = TIME_PROP(TIME_NULL);
for (i = 0; _time_reg[i].name; i++) {
reg_len = strlen(_time_reg[i].name);
if ((ti->len != reg_len) &&
!((_time_reg[i].reg_flags & TIME_REG_PLURAL_S) &&
(ti->len == reg_len+1) && (ti->s[reg_len] == 's')))
continue;
if (!strncasecmp(ti->s, _time_reg[i].name, reg_len)) {
ti->prop = _time_reg[i].prop;
if ((ti->prop->id > TIME_UNIT__START) && (ti->prop->id < TIME_UNIT__END) &&
ti_context_p && (ti_context_p->prop->id == TIME_NUM))
ti_context_p->prop = TIME_PROP(TIME_NUM_MULTIPLIER);
break;
}
}
return ti->prop->id;
}
static int _match_time_num(struct dm_list *ti_list, struct time_item *ti)
{
struct time_item *ti_context_p = (struct time_item *) dm_list_prev(ti_list, &ti->list);
struct time_item *ti_context_n = (struct time_item *) dm_list_next(ti_list, &ti->list);
struct time_item *ti_context_nn = ti_context_n ? (struct time_item *) dm_list_next(ti_list, &ti_context_n->list) : NULL;
if (ti_context_n &&
(ti_context_n->prop->id > TIME_MONTH__START) &&
(ti_context_n->prop->id < TIME_MONTH__END)) {
if (ti_context_nn && ti_context_nn->prop->id == TIME_NUM) {
if (ti->len < ti_context_nn->len) {
/* 24 Feb 2015 */
ti->prop = TIME_PROP(TIME_NUM_DAY);
ti_context_nn->prop = TIME_PROP(TIME_NUM_YEAR);
} else {
/* 2015 Feb 24 */
ti->prop = TIME_PROP(TIME_NUM_YEAR);
ti_context_nn->prop = TIME_PROP(TIME_NUM_DAY);
}
} else {
if (ti->len <= 2)
/* 24 Feb */
ti->prop = TIME_PROP(TIME_NUM_DAY);
else
/* 2015 Feb */
ti->prop = TIME_PROP(TIME_NUM_YEAR);
}
} else if (ti_context_p &&
(ti_context_p->prop->id > TIME_MONTH__START) &&
(ti_context_p->prop->id < TIME_MONTH__END)) {
if (ti->len <= 2)
/* Feb 24 */
ti->prop = TIME_PROP(TIME_NUM_DAY);
else
/* Feb 2015 */
ti->prop = TIME_PROP(TIME_NUM_YEAR);
} else
ti->prop = TIME_PROP(TIME_NUM_YEAR);
return ti->prop->id;
}
static void _detect_time_granularity(struct time_info *info, struct time_item *ti)
{
time_id_t gran = ti->prop->granularity;
int is_date, is_abs, is_rel;
if (gran == TIME_NULL)
return;
is_date = ti->prop->prop_flags & TIME_PROP_DATE;
is_abs = ti->prop->prop_flags & TIME_PROP_ABS;
is_rel = ti->prop->prop_flags & TIME_PROP_REL;
if (is_date && is_abs) {
if (gran > info->max_abs_date_granularity)
info->max_abs_date_granularity = gran;
if (gran < info->min_abs_date_granularity)
info->min_abs_date_granularity = gran;
} else {
if (is_abs && (gran < info->min_abs_time_granularity))
info->min_abs_time_granularity = gran;
else if (is_rel && (gran < info->min_rel_time_granularity))
info->min_rel_time_granularity = gran;
}
}
static void _change_to_relative(struct time_info *info, struct time_item *ti)
{
struct time_item *ti2;
ti2 = ti;
while ((ti2 = (struct time_item *) dm_list_prev(info->ti_list, &ti2->list))) {
if (ti2->prop->id == TIME_FRAME_AGO)
break;
switch (ti2->prop->id) {
case TIME_UNIT_SECOND:
ti2->prop = TIME_PROP(TIME_UNIT_SECOND_REL);
break;
case TIME_UNIT_MINUTE:
ti2->prop = TIME_PROP(TIME_UNIT_MINUTE_REL);
break;
case TIME_UNIT_HOUR:
ti2->prop = TIME_PROP(TIME_UNIT_HOUR_REL);
break;
default:
break;
}
}
}
static int _recognize_time_items(struct time_info *info)
{
struct time_item *ti;
/*
* At first, try to recognize strings.
* Also, if there are any items which may be absolute or
* relative and we have "TIME_FRAME_AGO", change them to relative.
*/
dm_list_iterate_items(ti, info->ti_list) {
if ((ti->prop->id == TIME_STR) && !_match_time_str(info->ti_list, ti)) {
log_error("Unrecognized string in date/time "
"specification at \"%s\".", ti->s);
return 0;
}
if (ti->prop->id == TIME_FRAME_AGO)
_change_to_relative(info, ti);
}
/*
* Now, recognize any numbers and be sensitive to the context
* given by strings we recognized before. Also, detect time
* granularity used (both for absolute and/or relative parts).
*/
dm_list_iterate_items(ti, info->ti_list) {
if ((ti->prop->id == TIME_NUM) && !_match_time_num(info->ti_list, ti)) {
log_error("Unrecognized number in date/time "
"specification at \"%s\".", ti->s);
return 0;
}
_detect_time_granularity(info, ti);
}
return 1;
}
static int _check_time_items(struct time_info *info)
{
struct time_item *ti;
uint32_t flags;
int rel;
int date_is_relative = -1, time_is_relative = -1;
int label_time = 0, label_date = 0;
dm_list_iterate_items(ti, info->ti_list) {
flags = ti->prop->prop_flags;
rel = flags & TIME_PROP_REL;
if (flags & TIME_PROP_DATE) {
if (date_is_relative < 0)
date_is_relative = rel;
else if ((date_is_relative ^ rel) &&
(info->max_abs_date_granularity >= info->min_rel_time_granularity)) {
log_error("Mixed absolute and relative date "
"specification found at \"%s\".", ti->s);
return 0;
}
/* Date label can be used only once and not mixed with other date spec. */
if (label_date) {
log_error("Ambiguous date specification found at \"%s\".", ti->s);
return 0;
}
if (_is_time_label_date(ti->prop->id))
label_date = 1;
}
else if (flags & TIME_PROP_TIME) {
if (time_is_relative < 0)
time_is_relative = rel;
else if ((time_is_relative ^ rel)) {
log_error("Mixed absolute and relative time "
"specification found at \"%s\".", ti->s);
return 0;
}
/* Time label can be used only once and not mixed with other time spec. */
if (label_time) {
log_error("Ambiguous time specification found at \"%s\".", ti->s);
return 0;
}
if (_is_time_label_time(ti->prop->id))
label_time = 1;
}
}
return 1;
}
#define CACHE_ID_TIME_NOW "time_now"
static time_t *_get_now(struct dm_report *rh, struct dm_pool *mem)
{
const void *cached_obj;
time_t *now;
if (!(cached_obj = dm_report_value_cache_get(rh, CACHE_ID_TIME_NOW))) {
if (!(now = dm_pool_zalloc(mem, sizeof(time_t)))) {
log_error("_get_now: dm_pool_zalloc failed");
return NULL;
}
time(now);
if (!dm_report_value_cache_set(rh, CACHE_ID_TIME_NOW, now)) {
log_error("_get_now: failed to cache current time");
return NULL;
}
} else
now = (time_t *) cached_obj;
return now;
}
static void _adjust_time_for_granularity(struct time_info *info, struct tm *tm, time_t *t)
{
switch (info->min_abs_date_granularity) {
case TIME_UNIT_YEAR:
tm->tm_mon = 0;
/* fall through */
case TIME_UNIT_MONTH:
tm->tm_mday = 1;
break;
default:
break;
}
switch (info->min_abs_time_granularity) {
case TIME_UNIT_HOUR:
tm->tm_min = 0;
/* fall through */
case TIME_UNIT_MINUTE:
tm->tm_sec = 0;
break;
case TIME_UNIT__END:
if (info->min_rel_time_granularity == TIME_UNIT__END)
tm->tm_hour = tm->tm_min = tm->tm_sec = 0;
break;
default:
break;
}
if ((info->min_abs_time_granularity == TIME_UNIT__END) &&
(info->min_rel_time_granularity >= TIME_UNIT_DAY) &&
(info->min_rel_time_granularity <= TIME_UNIT_YEAR))
tm->tm_hour = tm->tm_min = tm->tm_sec = 0;
}
#define SECS_PER_MINUTE 60
#define SECS_PER_HOUR 3600
#define SECS_PER_DAY ((time_t)86400)
static int _days_in_month[12] = {31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
static int _is_leap_year(long year)
{
return (((year % 4==0) && (year % 100 != 0)) || (year % 400 == 0));
}
static int _get_days_in_month(long month, long year)
{
return (month == 2 && _is_leap_year(year)) ? _days_in_month[month-1] + 1
: _days_in_month[month-1];
}
static void _get_resulting_time_span(struct time_info *info,
struct tm *tm, time_t t,
time_t *t_result1, time_t *t_result2)
{
time_t t1 = mktime(tm) - t;
time_t t2 = t1;
struct tm tmp;
if (info->min_abs_time_granularity != TIME_UNIT__END) {
if (info->min_abs_time_granularity == TIME_UNIT_MINUTE)
t2 += (SECS_PER_MINUTE - 1);
else if (info->min_abs_time_granularity == TIME_UNIT_HOUR)
t2 += (SECS_PER_HOUR - 1);
} else if (info->min_rel_time_granularity != TIME_UNIT__END) {
if (info->min_rel_time_granularity == TIME_UNIT_MINUTE)
t1 -= (SECS_PER_MINUTE + 1);
else if (info->min_rel_time_granularity == TIME_UNIT_HOUR)
t1 -= (SECS_PER_HOUR + 1);
else if ((info->min_rel_time_granularity >= TIME_UNIT_DAY) &&
(info->min_rel_time_granularity <= TIME_UNIT_YEAR))
t2 += (SECS_PER_DAY - 1);
} else {
if (info->min_abs_date_granularity == TIME_UNIT_MONTH)
t2 += (SECS_PER_DAY * _get_days_in_month(tm->tm_mon + 1, tm->tm_year) - 1);
else if (info->min_abs_date_granularity != TIME_UNIT__END)
t2 += (SECS_PER_DAY - 1);
}
/* Adjust for DST if needed. */
localtime_r(&t1, &tmp);
if (tmp.tm_isdst)
t1 -= SECS_PER_HOUR;
localtime_r(&t2, &tmp);
if (tmp.tm_isdst)
t2 -= SECS_PER_HOUR;
*t_result1 = t1;
*t_result2 = t2;
}
static int _translate_time_items(struct dm_report *rh, struct time_info *info,
const char **data_out)
{
struct time_item *ti, *ti_p = NULL;
long multiplier = 1;
struct tm tm_now;
time_id_t id;
long num;
struct tm tm; /* absolute time */
time_t t = 0; /* offset into past before absolute time */
time_t t1, t2;
char buf[32];
localtime_r(info->now, &tm_now);
tm = tm_now;
tm.tm_isdst = 0; /* we'll adjust for dst later */
tm.tm_wday = tm.tm_yday = -1;
dm_list_iterate_items(ti, info->ti_list) {
id = ti->prop->id;
if (_is_time_num(id)) {
errno = 0;
num = strtol(ti->s, NULL, 10);
if (errno) {
log_error("_translate_time_items: invalid time.");
return 0;
}
switch (id) {
case TIME_NUM_MULTIPLIER_NEGATIVE:
multiplier = -num;
break;
case TIME_NUM_MULTIPLIER:
multiplier = num;
break;
case TIME_NUM_DAY:
tm.tm_mday = num;
break;
case TIME_NUM_YEAR:
tm.tm_year = num - 1900;
break;
default:
break;
}
} else if (_is_time_month(id)) {
tm.tm_mon = id - TIME_MONTH__START - 1;
} else if (_is_time_label_date(id)) {
if (_is_time_weekday(id)) {
num = id - TIME_WEEKDAY__START - 1;
if (tm_now.tm_wday < num)
num = 7 - num + tm_now.tm_wday;
else
num = tm_now.tm_wday - num;
t += num * SECS_PER_DAY;
} else switch (id) {
case TIME_LABEL_DATE_YESTERDAY:
t += SECS_PER_DAY;
break;
case TIME_LABEL_DATE_TODAY:
/* Nothing to do here - we started with today. */
break;
default:
break;
}
} else if (_is_time_label_time(id)) {
switch (id) {
case TIME_LABEL_TIME_NOON:
tm.tm_hour = 12;
tm.tm_min = tm.tm_sec = 0;
break;
case TIME_LABEL_TIME_MIDNIGHT:
tm.tm_hour = tm.tm_min = tm.tm_sec = 0;
break;
default:
break;
}
} else if (_is_time_unit(id)) {
switch (id) {
case TIME_UNIT_SECOND:
tm.tm_sec = multiplier;
break;
case TIME_UNIT_SECOND_REL:
t += multiplier;
break;
case TIME_UNIT_MINUTE:
tm.tm_min = multiplier;
break;
case TIME_UNIT_MINUTE_REL:
t += (multiplier * SECS_PER_MINUTE);
break;
case TIME_UNIT_HOUR:
tm.tm_hour = multiplier;
break;
case TIME_UNIT_HOUR_REL:
t += (multiplier * SECS_PER_HOUR);
break;
case TIME_UNIT_AM:
if (ti_p && ti_p->prop->id == TIME_NUM_MULTIPLIER)
tm.tm_hour = multiplier;
break;
case TIME_UNIT_PM:
if (ti_p && _is_time_unit(ti_p->prop->id))
t -= 12 * SECS_PER_HOUR;
else if (ti_p && ti_p->prop->id == TIME_NUM_MULTIPLIER)
tm.tm_hour = multiplier + 12;
break;
case TIME_UNIT_DAY:
t += multiplier * SECS_PER_DAY;
break;
case TIME_UNIT_WEEK:
t += multiplier * 7 * SECS_PER_DAY;
break;
case TIME_UNIT_MONTH:
/* if months > 12, convert to years first */
num = multiplier / 12;
tm.tm_year -= num;
num = multiplier % 12;
if (num > (tm.tm_mon + 1)) {
tm.tm_year--;
tm.tm_mon = 12 - num + tm.tm_mon;
} else
tm.tm_mon -= num;
break;
case TIME_UNIT_YEAR:
tm.tm_year -= multiplier;
break;
default:
break;
}
}
ti_p = ti;
}
_adjust_time_for_granularity(info, &tm, &t);
_get_resulting_time_span(info, &tm, t, &t1, &t2);
dm_pool_free(info->mem, info->ti_list);
info->ti_list = NULL;
if (dm_snprintf(buf, sizeof(buf), "@" FMTd64 ":@" FMTd64, (int64_t)t1, (int64_t)t2) == -1) {
log_error("_translate_time_items: dm_snprintf failed");
return 0;
}
if (!(*data_out = dm_pool_strdup(info->mem, buf))) {
log_error("_translate_time_items: dm_pool_strdup failed");
return 0;
}
return 1;
}
static const char *_lv_time_handler_parse_fuzzy_name(struct dm_report *rh,
struct dm_pool *mem,
const char *data_in)
{
const char *s = data_in;
const char *data_out = NULL;
struct time_info info = {.mem = mem,
.ti_list = NULL,
.now = _get_now(rh, mem),
.min_abs_date_granularity = TIME_UNIT__END,
.max_abs_date_granularity = TIME_UNIT__START,
.min_abs_time_granularity = TIME_UNIT__END,
.min_rel_time_granularity = TIME_UNIT__END};
if (!info.now)
goto_out;
/* recognize top-level parts - string/number/time/timezone? */
if (!_preparse_fuzzy_time(s, &info))
goto out;
/* recognize each part in more detail, also look at the context around if needed */
if (!_recognize_time_items(&info))
goto out;
/* check if the combination of items is allowed or whether it makes sense at all */
if (!_check_time_items(&info))
goto out;
/* translate items into final time range */
if (!_translate_time_items(rh, &info, &data_out))
goto out;
out:
if (info.ti_list)
dm_pool_free(info.mem, info.ti_list);
return data_out;
}
static void *_lv_time_handler_get_dynamic_value(struct dm_report *rh,
struct dm_pool *mem,
const char *data_in)
{
int64_t t1, t2;
time_t *result;
if (sscanf(data_in, "@" FMTd64 ":@" FMTd64, &t1, &t2) != 2) {
log_error("Failed to get value for parsed time specification.");
return NULL;
}
if (!(result = dm_pool_alloc(mem, 2 * sizeof(time_t)))) {
log_error("Failed to allocate space to store time range.");
return NULL;
}
result[0] = (time_t) t1; /* Validate range for 32b arch ? */
result[1] = (time_t) t2;
return result;
}
static int _lv_time_handler(struct dm_report *rh, struct dm_pool *mem,
uint32_t field_num,
dm_report_reserved_action_t action,
const void *data_in, const void **data_out)
{
*data_out = NULL;
if (!data_in)
return 1;
switch (action) {
case DM_REPORT_RESERVED_PARSE_FUZZY_NAME:
*data_out = _lv_time_handler_parse_fuzzy_name(rh, mem, data_in);
break;
case DM_REPORT_RESERVED_GET_DYNAMIC_VALUE:
if (!(*data_out = _lv_time_handler_get_dynamic_value(rh, mem, data_in)))
return 0;
break;
default:
return -1;
}
return 1;
}
/*
* Get type reserved value - the value returned is the direct value of that type.
*/
#define GET_TYPE_RESERVED_VALUE(id) _reserved_ ## id
/*
* Get field reserved value - the value returned is always a pointer (const void *).
*/
#define GET_FIELD_RESERVED_VALUE(id) _reserved_ ## id.value
/*
* Get first name assigned to the reserved value - this is the one that
* should be reported/displayed. All the other names assigned for the reserved
* value are synonyms recognized in selection criteria.
*/
#define GET_FIRST_RESERVED_NAME(id) _reserved_ ## id ## _names[0]
/*
* Reserved values and their assigned names.
* The first name is the one that is also used for reporting.
* All names listed are synonyms recognized in selection criteria.
* For binary-based values we map all reserved names listed onto value 1, blank onto value 0.
*
* TYPE_RESERVED_VALUE(type, reserved_value_id, description, value, reserved name, ...)
* FIELD_RESERVED_VALUE(field_id, reserved_value_id, description, value, reserved name, ...)
* FIELD_RESERVED_BINARY_VALUE(field_id, reserved_value_id, description, reserved name for 1, ...)
*
* Note: FIELD_RESERVED_BINARY_VALUE creates:
* - 'reserved_value_id_y' (for 1)
* - 'reserved_value_id_n' (for 0)
*/
#define NUM uint64_t
#define NUM_HND dm_report_reserved_handler
#define HND (dm_report_reserved_handler)
#define NOFLAG 0
#define NAMED DM_REPORT_FIELD_RESERVED_VALUE_NAMED
#define RANGE DM_REPORT_FIELD_RESERVED_VALUE_RANGE
#define FUZZY DM_REPORT_FIELD_RESERVED_VALUE_FUZZY_NAMES
#define DYNAMIC DM_REPORT_FIELD_RESERVED_VALUE_DYNAMIC_VALUE
#define TYPE_RESERVED_VALUE(type, flags, id, desc, value, ...) \
static const char *_reserved_ ## id ## _names[] = { __VA_ARGS__, NULL}; \
static const type _reserved_ ## id = value;
#define FIELD_RESERVED_VALUE(flags, field_id, id, desc, value, ...) \
static const char *_reserved_ ## id ## _names[] = { __VA_ARGS__ , NULL}; \
static const struct dm_report_field_reserved_value _reserved_ ## id = {field_ ## field_id, value};
#define FIELD_RESERVED_BINARY_VALUE(field_id, id, desc, ...) \
FIELD_RESERVED_VALUE(NAMED, field_id, id ## _y, desc, &_one64, __VA_ARGS__, _str_yes) \
FIELD_RESERVED_VALUE(NAMED, field_id, id ## _n, desc, &_zero64, __VA_ARGS__, _str_no)
#include "values.h"
#undef NUM
#undef NUM_HND
#undef HND
#undef NOFLAG
#undef NAMED
#undef RANGE
#undef TYPE_RESERVED_VALUE
#undef FIELD_RESERVED_VALUE
#undef FIELD_RESERVED_BINARY_VALUE
#undef FUZZY
#undef DYNAMIC
/*
* Create array of reserved values to be registered with reporting code via
* dm_report_init_with_selection function that initializes report with
* selection criteria. Selection code then recognizes these reserved values
* when parsing selection criteria.
*/
#define NUM DM_REPORT_FIELD_TYPE_NUMBER
#define NUM_HND DM_REPORT_FIELD_TYPE_NUMBER
#define HND 0
#define NOFLAG 0
#define NAMED DM_REPORT_FIELD_RESERVED_VALUE_NAMED
#define RANGE DM_REPORT_FIELD_RESERVED_VALUE_RANGE
#define FUZZY DM_REPORT_FIELD_RESERVED_VALUE_FUZZY_NAMES
#define DYNAMIC DM_REPORT_FIELD_RESERVED_VALUE_DYNAMIC_VALUE
#define TYPE_RESERVED_VALUE(type, flags, id, desc, value, ...) {type | flags, &_reserved_ ## id, _reserved_ ## id ## _names, desc},
#define FIELD_RESERVED_VALUE(flags, field_id, id, desc, value, ...) {DM_REPORT_FIELD_TYPE_NONE | flags, &_reserved_ ## id, _reserved_ ## id ## _names, desc},
#define FIELD_RESERVED_BINARY_VALUE(field_id, id, desc, ...) \
FIELD_RESERVED_VALUE(NAMED, field_id, id ## _y, desc, &_one64, __VA_ARGS__) \
FIELD_RESERVED_VALUE(NAMED, field_id, id ## _n, desc, &_zero64, __VA_ARGS__)
static const struct dm_report_reserved_value _report_reserved_values[] = {
#include "values.h"
{0, NULL, NULL, NULL}
};
#undef NUM
#undef NUM_HND
#undef HND
#undef NOFLAG
#undef NAMED
#undef RANGE
#undef FUZZY
#undef DYNAMIC
#undef TYPE_RESERVED_VALUE
#undef FIELD_RESERVED_VALUE
#undef FIELD_RESERVED_BINARY_VALUE
static int _field_string(struct dm_report *rh, struct dm_report_field *field, const char *data)
{
return dm_report_field_string(rh, field, &data);
}
static int _field_set_value(struct dm_report_field *field, const void *data, const void *sort)
{
dm_report_field_set_value(field, data, sort);
return 1;
}
static int _field_set_string_list(struct dm_report *rh, struct dm_report_field *field,
const struct dm_list *list, void *private, int sorted,
const char *delimiter)
{
struct cmd_context *cmd = (struct cmd_context *) private;
return sorted ? dm_report_field_string_list(rh, field, list, delimiter ? : cmd->report_list_item_separator)
: dm_report_field_string_list_unsorted(rh, field, list, delimiter ? : cmd->report_list_item_separator);
}
/*
* Data-munging functions to prepare each data type for display and sorting
*/
/*
* Display either "0"/"1" or ""/"word" based on bin_value,
* cmd->report_binary_values_as_numeric selects the mode to use.
*/
static int _binary_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field, int bin_value, const char *word,
void *private)
{
const struct cmd_context *cmd = (const struct cmd_context *) private;
if (cmd->report_strict_type_mode || cmd->report_binary_values_as_numeric)
/* "0"/"1" */
return _field_set_value(field, bin_value ? _str_one : _str_zero, bin_value ? &_one64 : &_zero64);
/* blank/"word" */
return _field_set_value(field, bin_value ? word : "", bin_value ? &_one64 : &_zero64);
}
static int _binary_undef_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field, void *private)
{
const struct cmd_context *cmd = (const struct cmd_context *) private;
if (cmd->report_strict_type_mode || cmd->report_binary_values_as_numeric)
return _field_set_value(field, GET_FIRST_RESERVED_NAME(num_undef_64), &GET_TYPE_RESERVED_VALUE(num_undef_64));
return _field_set_value(field, _str_unknown, &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _string_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return dm_report_field_string(rh, field, (const char * const *) data);
}
static int _chars_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _field_string(rh, field, data);
}
static int _uuid_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
char *repstr;
if (!(repstr = id_format_and_copy(mem, data)))
return_0;
return _field_set_value(field, repstr, NULL);
}
static int _devminor_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int devminor = (int) MINOR((*(const struct device * const *) data)->dev);
return dm_report_field_int(rh, field, &devminor);
}
static int _devmajor_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int devmajor = (int) MAJOR((*(const struct device * const *) data)->dev);
return dm_report_field_int(rh, field, &devmajor);
}
static int _dev_name_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
return _field_string(rh, field, dev_name(*(const struct device * const *) data));
}
static int _devices_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
struct dm_list *list;
if (!(list = lvseg_devices(mem, seg)))
return_0;
return _field_set_string_list(rh, field, list, private, 0, ",");
}
static int _metadatadevices_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
struct dm_list *list;
if (!(list = lvseg_metadata_devices(mem, seg)))
return_0;
return _field_set_string_list(rh, field, list, private, 0, ",");
}
static int _peranges_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
struct dm_list *list;
if (!(list = lvseg_seg_pe_ranges(mem, seg)))
return_0;
return _field_set_string_list(rh, field, list, private, 0, " ");
}
static int _leranges_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
struct dm_list *list;
if (!(list = lvseg_seg_le_ranges(mem, seg)))
return_0;
return _field_set_string_list(rh, field, list, private, 0, NULL);
}
static int _metadataleranges_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
struct dm_list *list;
if (!(list = lvseg_seg_metadata_le_ranges(mem, seg)))
return_0;
return _field_set_string_list(rh, field, list, private, 0, NULL);
}
static int _tags_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct dm_list *tagsl = (const struct dm_list *) data;
return _field_set_string_list(rh, field, tagsl, private, 1, NULL);
}
struct _str_list_append_baton {
struct dm_pool *mem;
struct dm_list *result;
};
static int _str_list_append(const char *line, void *baton)
{
struct _str_list_append_baton *b = baton;
const char *line2 = dm_pool_strdup(b->mem, line);
if (!line2)
return_0;
if (!str_list_add(b->mem, b->result, line2))
return_0;
return 1;
}
static int _cache_settings_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
const struct lv_segment *setting_seg = NULL;
const struct dm_config_node *settings;
struct dm_list *result;
struct _str_list_append_baton baton;
struct dm_list dummy_list; /* dummy list to display "nothing" */
if (seg_is_writecache(seg)) {
if (!(result = str_list_create(mem)))
return_0;
if (!writecache_settings_to_str_list((struct writecache_settings *)&seg->writecache_settings, result, mem))
return_0;
return _field_set_string_list(rh, field, result, private, 0, NULL);
}
if (seg_is_cache(seg) && lv_is_cache_vol(seg->pool_lv))
setting_seg = seg;
else if (seg_is_cache_pool(seg))
setting_seg = seg;
else if (seg_is_cache(seg))
setting_seg = first_seg(seg->pool_lv);
if (!setting_seg || !setting_seg->policy_settings) {
dm_list_init(&dummy_list);
return _field_set_string_list(rh, field, &dummy_list, private, 0, NULL);
/* TODO: once we have support for STR_LIST reserved values, replace with:
* return _field_set_value(field, GET_FIRST_RESERVED_NAME(cache_settings_undef), GET_FIELD_RESERVED_VALUE(cache_settings_undef));
*/
}
settings = setting_seg->policy_settings->child;
if (!(result = str_list_create(mem)))
return_0;
baton.mem = mem;
baton.result = result;
while (settings) {
dm_config_write_one_node(settings, _str_list_append, &baton);
settings = settings->sib;
};
return _field_set_string_list(rh, field, result, private, 0, NULL);
}
static int _do_get_kernel_cache_settings_list(struct dm_pool *mem,
int cache_argc, char **cache_argv,
struct dm_list *result)
{
const char *key, *value;
char *buf;
size_t buf_len;
int i;
for (i = 0; i+1 < cache_argc; i += 2) {
key = cache_argv[i];
value = cache_argv[i+1];
/* +1 for "=" char and +1 for trailing zero */
buf_len = strlen(key) + strlen(value) + 2;
if (!(buf = dm_pool_alloc(mem, buf_len)))
return_0;
if (dm_snprintf(buf, buf_len, "%s=%s", key, value) < 0)
return_0;
if (!str_list_add_no_dup_check(mem, result, buf))
return_0;
}
return 1;
}
static int _get_kernel_cache_settings_list(struct dm_pool *mem,
struct dm_status_cache *cache_status,
struct dm_list **result)
{
if (!(*result = str_list_create(mem)))
return_0;
if (!_do_get_kernel_cache_settings_list(mem, cache_status->core_argc,
cache_status->core_argv, *result))
return_0;
if (!_do_get_kernel_cache_settings_list(mem, cache_status->policy_argc,
cache_status->policy_argv, *result))
return_0;
return 1;
}
static int _kernel_cache_settings_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
struct dm_list dummy_list; /* dummy list to display "nothing" */
struct dm_list *result;
int r = 0;
if (lvdm->seg_status.type != SEG_STATUS_CACHE) {
dm_list_init(&dummy_list);
return _field_set_string_list(rh, field, &dummy_list, private, 0, NULL);
}
if (!(mem = dm_pool_create("reporter_pool", 1024)))
return_0;
if (!_get_kernel_cache_settings_list(mem, lvdm->seg_status.cache, &result))
goto_out;
r = _field_set_string_list(rh, field, result, private, 0, NULL);
out:
dm_pool_destroy(mem);
return r;
}
static int _kernel_cache_policy_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if ((lvdm->seg_status.type == SEG_STATUS_CACHE) &&
lvdm->seg_status.cache->policy_name)
return _field_string(rh, field, lvdm->seg_status.cache->policy_name);
return _field_set_value(field, GET_FIRST_RESERVED_NAME(cache_policy_undef),
GET_FIELD_RESERVED_VALUE(cache_policy_undef));
}
static int _kernelmetadataformat_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
unsigned format;
if (lvdm->seg_status.type == SEG_STATUS_CACHE) {
format = (lvdm->seg_status.cache->feature_flags & DM_CACHE_FEATURE_METADATA2);
return dm_report_field_uint64(rh, field, format ? &_two64 : &_one64);
}
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _cache_policy_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
const struct lv_segment *setting_seg = NULL;
if (seg_is_cache(seg) && lv_is_cache_vol(seg->pool_lv))
setting_seg = seg;
else if (seg_is_cache_pool(seg))
setting_seg = seg;
else if (seg_is_cache(seg))
setting_seg = first_seg(seg->pool_lv);
if (!setting_seg || !setting_seg->policy_name)
return _field_set_value(field, GET_FIRST_RESERVED_NAME(cache_policy_undef),
GET_FIELD_RESERVED_VALUE(cache_policy_undef));
return _field_string(rh, field, setting_seg->policy_name);
}
static int _modules_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
struct dm_list *modules;
if (!(modules = str_list_create(mem))) {
log_error("modules str_list allocation failed");
return 0;
}
if (!(list_lv_modules(mem, lv, modules)))
return_0;
return _field_set_string_list(rh, field, modules, private, 1, NULL);
}
static int _lvprofile_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
if (lv->profile)
return _field_string(rh, field, lv->profile->name);
return _field_set_value(field, "", NULL);
}
static int _lvlockargs_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
return _field_string(rh, field, lv->lock_args ? : "");
}
static int _vgfmt_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
if (vg->fid && vg->fid->fmt)
return _field_string(rh, field, vg->fid->fmt->name);
return _field_set_value(field, "", NULL);
}
static int _pvfmt_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct label *l = (const struct label *) data;
if (l->labeller && l->labeller->fmt)
return _field_string(rh, field, l->labeller->fmt->name);
return _field_set_value(field, "", NULL);
}
static int _lvkmaj_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (lvdm->info.exists && lvdm->info.major >= 0)
return dm_report_field_int(rh, field, &lvdm->info.major);
return dm_report_field_int32(rh, field, &GET_TYPE_RESERVED_VALUE(num_undef_32));
}
static int _lvkmin_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (lvdm->info.exists && lvdm->info.minor >= 0)
return dm_report_field_int(rh, field, &lvdm->info.minor);
return dm_report_field_int32(rh, field, &GET_TYPE_RESERVED_VALUE(num_undef_32));
}
static int _lvstatus_disp(struct dm_report *rh __attribute__((unused)), struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
char *repstr;
if (!(repstr = lv_attr_dup_with_info_and_seg_status(mem, lvdm)))
return_0;
return _field_set_value(field, repstr, NULL);
}
static int _pvstatus_disp(struct dm_report *rh __attribute__((unused)), struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct physical_volume *pv =
(const struct physical_volume *) data;
char *repstr;
if (!(repstr = pv_attr_dup(mem, pv)))
return_0;
return _field_set_value(field, repstr, NULL);
}
static int _vgstatus_disp(struct dm_report *rh __attribute__((unused)), struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct volume_group *vg = (const struct volume_group *) data;
char *repstr;
if (!(repstr = vg_attr_dup(mem, vg)))
return_0;
return _field_set_value(field, repstr, NULL);
}
static int _segtype_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct lv_segment *seg = (const struct lv_segment *) data;
char *name;
if (!(name = lvseg_segtype_dup(mem, seg))) {
log_error("Failed to get segtype name.");
return 0;
}
return _field_set_value(field, name, NULL);
}
static int _lvname_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
struct cmd_context *cmd = (struct cmd_context *) private;
const struct logical_volume *lv = (const struct logical_volume *) data;
int is_historical = lv_is_historical(lv);
const char *tmp_lvname;
char *repstr, *lvname;
size_t len;
if (!is_historical && (lv_is_visible(lv) || !cmd->report_mark_hidden_devices))
return _field_string(rh, field, lv->name);
if (is_historical) {
tmp_lvname = lv->this_glv->historical->name;
len = strlen(tmp_lvname) + strlen(HISTORICAL_LV_PREFIX) + 1;
} else {
tmp_lvname = lv->name;
len = strlen(tmp_lvname) + 3;
}
if (!(repstr = dm_pool_zalloc(mem, len))) {
log_error("dm_pool_alloc failed");
return 0;
}
if (dm_snprintf(repstr, len, "%s%s%s",
is_historical ? HISTORICAL_LV_PREFIX : "[",
tmp_lvname,
is_historical ? "" : "]") < 0) {
log_error("lvname snprintf failed");
return 0;
}
if (!(lvname = dm_pool_strdup(mem, tmp_lvname))) {
log_error("dm_pool_strdup failed");
return 0;
}
return _field_set_value(field, repstr, lvname);
}
static int _do_loglv_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private,
int uuid)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
struct logical_volume *mirror_log_lv = lv_mirror_log_lv(lv);
if (!mirror_log_lv)
return _field_set_value(field, "", NULL);
if (uuid)
return _uuid_disp(rh, mem, field, &mirror_log_lv->lvid.id[1], private);
return _lvname_disp(rh, mem, field, mirror_log_lv, private);
}
static int _loglv_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_loglv_disp(rh, mem, field, data, private, 0);
}
static int _loglvuuid_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_loglv_disp(rh, mem, field, data, private, 1);
}
static int _lvfullname_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
char *repstr;
if (!(repstr = lv_fullname_dup(mem, lv)))
return_0;
return _field_set_value(field, repstr, NULL);
}
static int _lvparent_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
struct logical_volume *parent_lv = lv_parent(lv);
if (!parent_lv)
return _field_set_value(field, "", NULL);
return _lvname_disp(rh, mem, field, parent_lv, private);
}
static int _do_datalv_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)),
int uuid)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
struct logical_volume *data_lv = lv_data_lv(lv);
if (!data_lv)
return _field_set_value(field, "", NULL);
if (uuid)
return _uuid_disp(rh, mem, field, &data_lv->lvid.id[1], private);
return _lvname_disp(rh, mem, field, data_lv, private);
}
static int _datalv_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_datalv_disp(rh, mem, field, data, private, 0);
}
static int _datalvuuid_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_datalv_disp(rh, mem, field, data, private, 1);
}
static int _do_metadatalv_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)),
int uuid)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
struct logical_volume *metadata_lv = lv_metadata_lv(lv);
if (!metadata_lv)
return _field_set_value(field, "", NULL);
if (uuid)
return _uuid_disp(rh, mem, field, &metadata_lv->lvid.id[1], private);
return _lvname_disp(rh, mem, field, metadata_lv, private);
}
static int _metadatalv_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_metadatalv_disp(rh, mem, field, data, private, 0);
}
static int _metadatalvuuid_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_metadatalv_disp(rh, mem, field, data, private, 1);
}
static int _do_poollv_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private,
int uuid)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
struct logical_volume *pool_lv = lv_pool_lv(lv);
if (!pool_lv)
return _field_set_value(field, "", NULL);
if (uuid)
return _uuid_disp(rh, mem, field, &pool_lv->lvid.id[1], private);
return _lvname_disp(rh, mem, field, pool_lv, private);
}
static int _poollv_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_poollv_disp(rh, mem, field, data, private, 0);
}
static int _poollvuuid_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_poollv_disp(rh, mem, field, data, private, 1);
}
static int _lvpath_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
char *repstr;
if (!(repstr = lv_path_dup(mem, lv)))
return_0;
return _field_set_value(field, repstr, NULL);
}
static int _lvdmpath_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
char *repstr;
if (!(repstr = lv_dmpath_dup(mem, lv)))
return_0;
return _field_set_value(field, repstr, NULL);
}
static int _do_origin_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private,
int uuid)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
struct logical_volume *origin_lv = lv_origin_lv(lv);
if (!origin_lv)
return _field_set_value(field, "", NULL);
if (uuid)
return _uuid_disp(rh, mem, field, &origin_lv->lvid.id[1], private);
return _lvname_disp(rh, mem, field, origin_lv, private);
}
static int _origin_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
return _do_origin_disp(rh, mem, field, data, private, 0);
}
static int _originuuid_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
return _do_origin_disp(rh, mem, field, data, private, 1);
}
static const char *_get_glv_str(char *buf, size_t buf_len,
struct generic_logical_volume *glv)
{
if (!glv->is_historical)
return glv->live->name;
if (dm_snprintf(buf, buf_len, "%s%s", HISTORICAL_LV_PREFIX, glv->historical->name) < 0) {
log_error("_get_glv_str: dm_snprintf failed");
return NULL;
}
return buf;
}
static int _find_ancestors(struct _str_list_append_baton *ancestors,
struct generic_logical_volume glv,
int full, int include_historical_lvs)
{
struct lv_segment *seg;
void *orig_p = glv.live;
const char *ancestor_str;
char buf[NAME_LEN + strlen(HISTORICAL_LV_PREFIX) + 1];
if (glv.is_historical) {
if (full && glv.historical->indirect_origin)
glv = *glv.historical->indirect_origin;
} else if (lv_is_cow(glv.live)) {
glv.live = origin_from_cow(glv.live);
} else if (lv_is_thin_volume(glv.live)) {
seg = first_seg(glv.live);
if (seg->origin)
glv.live = seg->origin;
else if (seg->external_lv)
glv.live = seg->external_lv;
else if (full && seg->indirect_origin)
glv = *seg->indirect_origin;
}
if (orig_p != glv.live) {
if (!(ancestor_str = _get_glv_str(buf, sizeof(buf), &glv)))
return_0;
if (!glv.is_historical || include_historical_lvs) {
if (!_str_list_append(ancestor_str, ancestors))
return_0;
}
if (!_find_ancestors(ancestors, glv, full, include_historical_lvs))
return_0;
}
return 1;
}
static int _lvancestors_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
struct cmd_context *cmd = (struct cmd_context *) private;
struct logical_volume *lv = (struct logical_volume *) data;
struct _str_list_append_baton ancestors;
struct generic_logical_volume glv;
ancestors.mem = mem;
if (!(ancestors.result = str_list_create(mem)))
return_0;
if ((glv.is_historical = lv_is_historical(lv)))
glv.historical = lv->this_glv->historical;
else
glv.live = lv;
if (!_find_ancestors(&ancestors, glv, 0, cmd->include_historical_lvs)) {
dm_pool_free(ancestors.mem, ancestors.result);
return_0;
}
return _field_set_string_list(rh, field, ancestors.result, private, 0, NULL);
}
static int _lvfullancestors_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
struct cmd_context *cmd = (struct cmd_context *) private;
struct logical_volume *lv = (struct logical_volume *) data;
struct _str_list_append_baton full_ancestors;
struct generic_logical_volume glv;
full_ancestors.mem = mem;
if (!(full_ancestors.result = str_list_create(mem)))
return_0;
if ((glv.is_historical = lv_is_historical(lv)))
glv.historical = lv->this_glv->historical;
else
glv.live = lv;
if (!_find_ancestors(&full_ancestors, glv, 1, cmd->include_historical_lvs)) {
dm_pool_free(full_ancestors.mem, full_ancestors.result);
return_0;
}
return _field_set_string_list(rh, field, full_ancestors.result, private, 0, NULL);
}
static int _find_descendants(struct _str_list_append_baton *descendants,
struct generic_logical_volume glv,
int full, int include_historical_lvs)
{
struct generic_logical_volume glv_next = {0};
const struct seg_list *sl;
struct lv_segment *seg;
struct glv_list *glvl;
struct dm_list *list;
const char *descendant_str;
char buf[64];
if (glv.is_historical) {
if (full) {
list = &glv.historical->indirect_glvs;
dm_list_iterate_items(glvl, list) {
if (!glvl->glv->is_historical || include_historical_lvs) {
if (!(descendant_str = _get_glv_str(buf, sizeof(buf), glvl->glv)))
return_0;
if (!_str_list_append(descendant_str, descendants))
return_0;
}
if (!_find_descendants(descendants, *glvl->glv, full, include_historical_lvs))
return_0;
}
}
} else if (lv_is_origin(glv.live)) {
list = &glv.live->snapshot_segs;
dm_list_iterate_items_gen(seg, list, origin_list) {
if ((glv.live = seg->cow)) {
if (!(descendant_str = _get_glv_str(buf, sizeof(buf), &glv)))
return_0;
if (!_str_list_append(descendant_str, descendants))
return_0;
if (!_find_descendants(descendants, glv, full, include_historical_lvs))
return_0;
}
}
} else {
list = &glv.live->segs_using_this_lv;
dm_list_iterate_items(sl, list) {
if (lv_is_thin_volume(sl->seg->lv)) {
seg = first_seg(sl->seg->lv);
if ((seg->origin == glv.live) || (seg->external_lv == glv.live)) {
glv_next.live = sl->seg->lv;
if (!(descendant_str = _get_glv_str(buf, sizeof(buf), &glv_next)))
return_0;
if (!_str_list_append(descendant_str, descendants))
return_0;
if (!_find_descendants(descendants, glv_next, full, include_historical_lvs))
return_0;
}
}
}
if (full) {
list = &glv.live->indirect_glvs;
dm_list_iterate_items(glvl, list) {
if (!glvl->glv->is_historical || include_historical_lvs) {
if (!(descendant_str = _get_glv_str(buf, sizeof(buf), glvl->glv)))
return_0;
if (!_str_list_append(descendant_str, descendants))
return_0;
}
if (!_find_descendants(descendants, *glvl->glv, full, include_historical_lvs))
return_0;
}
}
}
return 1;
}
static int _lvdescendants_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
struct cmd_context *cmd = (struct cmd_context *) private;
struct logical_volume *lv = (struct logical_volume *) data;
struct _str_list_append_baton descendants;
struct generic_logical_volume glv;
descendants.mem = mem;
if (!(descendants.result = str_list_create(mem)))
return_0;
if ((glv.is_historical = lv_is_historical(lv)))
glv.historical = lv->this_glv->historical;
else
glv.live = lv;
if (!_find_descendants(&descendants, glv, 0, cmd->include_historical_lvs)) {
dm_pool_free(descendants.mem, descendants.result);
return_0;
}
return _field_set_string_list(rh, field, descendants.result, private, 0, NULL);
}
static int _lvfulldescendants_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
struct cmd_context *cmd = (struct cmd_context *) private;
struct logical_volume *lv = (struct logical_volume *) data;
struct _str_list_append_baton descendants;
struct generic_logical_volume glv;
descendants.mem = mem;
if (!(descendants.result = str_list_create(mem)))
return_0;
if ((glv.is_historical = lv_is_historical(lv)))
glv.historical = lv->this_glv->historical;
else
glv.live = lv;
if (!_find_descendants(&descendants, glv, 1, cmd->include_historical_lvs)) {
dm_pool_free(descendants.mem, descendants.result);
return_0;
}
return _field_set_string_list(rh, field, descendants.result, private, 0, NULL);
}
static int _do_movepv_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private,
int uuid)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
const char *repstr;
if (uuid)
repstr = lv_move_pv_uuid_dup(mem, lv);
else
repstr = lv_move_pv_dup(mem, lv);
if (repstr)
return _field_string(rh, field, repstr);
return _field_set_value(field, "", NULL);
}
static int _movepv_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_movepv_disp(rh, mem, field, data, private, 0);
}
static int _movepvuuid_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_movepv_disp(rh, mem, field, data, private, 1);
}
static int _do_convertlv_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private,
int uuid)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
const struct logical_volume *convert_lv = lv_convert_lv(lv);
if (!convert_lv)
return _field_set_value(field, "", NULL);
if (uuid)
return _uuid_disp(rh, mem, field, &convert_lv->lvid.id[1], private);
return _lvname_disp(rh, mem, field, convert_lv, private);
}
static int _convertlv_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_convertlv_disp(rh, mem, field, data, private, 0);
}
static int _convertlvuuid_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return _do_convertlv_disp(rh, mem, field, data, private, 1);
}
static int _size32_disp(struct dm_report *rh __attribute__((unused)), struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const uint32_t size = *(const uint32_t *) data;
const char *disp, *repstr;
double *sortval;
if (!*(disp = display_size_units(private, (uint64_t) size)))
return_0;
if (!(repstr = dm_pool_strdup(mem, disp))) {
log_error("dm_pool_strdup failed");
return 0;
}
if (!(sortval = dm_pool_alloc(mem, sizeof(uint64_t)))) {
log_error("dm_pool_alloc failed");
return 0;
}
*sortval = (double) size;
return _field_set_value(field, repstr, sortval);
}
static int _size64_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const uint64_t size = *(const uint64_t *) data;
const char *disp, *repstr;
double *sortval;
if (!*(disp = display_size_units(private, size)))
return_0;
if (!(repstr = dm_pool_strdup(mem, disp))) {
log_error("dm_pool_strdup failed");
return 0;
}
if (!(sortval = dm_pool_alloc(mem, sizeof(double)))) {
log_error("dm_pool_alloc failed");
return 0;
}
*sortval = (double) size;
return _field_set_value(field, repstr, sortval);
}
static int _lv_size_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
const struct lv_segment *seg = first_seg(lv);
uint64_t size = lv->le_count;
if (seg && !lv_is_raid_image(lv))
size -= (uint64_t) seg->reshape_len * (seg->area_count > 2 ? (seg->area_count - seg->segtype->parity_devs) : 1);
size *= lv->vg->extent_size;
return _size64_disp(rh, mem, field, &size, private);
}
static int _uint32_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return dm_report_field_uint32(rh, field, data);
}
static int _int8_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const int32_t val = *(const int8_t *)data;
return dm_report_field_int32(rh, field, &val);
}
static int _int32_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
return dm_report_field_int32(rh, field, data);
}
static int _lvwhenfull_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
if (lv_is_thin_pool(lv)) {
if (lv->status & LV_ERROR_WHEN_FULL)
return _field_set_value(field, GET_FIRST_RESERVED_NAME(lv_when_full_error),
GET_FIELD_RESERVED_VALUE(lv_when_full_error));
return _field_set_value(field, GET_FIRST_RESERVED_NAME(lv_when_full_queue),
GET_FIELD_RESERVED_VALUE(lv_when_full_queue));
}
return _field_set_value(field, GET_FIRST_RESERVED_NAME(lv_when_full_undef),
GET_FIELD_RESERVED_VALUE(lv_when_full_undef));
}
static int _lvreadahead_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
if (lv->read_ahead == DM_READ_AHEAD_AUTO)
return _field_set_value(field, GET_FIRST_RESERVED_NAME(lv_read_ahead_auto),
GET_FIELD_RESERVED_VALUE(lv_read_ahead_auto));
return _size32_disp(rh, mem, field, &lv->read_ahead, private);
}
static int _lvkreadahead_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (!lvdm->info.exists)
return dm_report_field_int32(rh, field, &GET_TYPE_RESERVED_VALUE(num_undef_32));
return _size32_disp(rh, mem, field, &lvdm->info.read_ahead, private);
}
static int _vdo_operating_mode_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if ((lv_is_vdo_pool(lvdm->lv) || lv_is_vdo(lvdm->lv)) &&
(lvdm->seg_status.type == SEG_STATUS_VDO_POOL))
return _field_string(rh, field, get_vdo_operating_mode_name(lvdm->seg_status.vdo_pool.vdo->operating_mode));
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vdo_compression_state_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if ((lv_is_vdo_pool(lvdm->lv) || lv_is_vdo(lvdm->lv)) &&
(lvdm->seg_status.type == SEG_STATUS_VDO_POOL))
return _field_string(rh, field, get_vdo_compression_state_name(lvdm->seg_status.vdo_pool.vdo->compression_state));
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vdo_index_state_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if ((lv_is_vdo_pool(lvdm->lv) || lv_is_vdo(lvdm->lv)) &&
(lvdm->seg_status.type == SEG_STATUS_VDO_POOL))
return _field_string(rh, field, get_vdo_index_state_name(lvdm->seg_status.vdo_pool.vdo->index_state));
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vdo_used_size_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
uint64_t size;
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if ((lv_is_vdo_pool(lvdm->lv) || lv_is_vdo(lvdm->lv)) &&
(lvdm->seg_status.type == SEG_STATUS_VDO_POOL)) {
size = lvdm->seg_status.vdo_pool.vdo->used_blocks * DM_VDO_BLOCK_SIZE;
return _size64_disp(rh, mem, field, &size, private);
}
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vdo_saving_percent_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if ((lv_is_vdo_pool(lvdm->lv) || lv_is_vdo(lvdm->lv)) &&
(lvdm->seg_status.type == SEG_STATUS_VDO_POOL))
return dm_report_field_percent(rh, field, &lvdm->seg_status.vdo_pool.saving);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vgsize_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
uint64_t size = vg_size(vg);
return _size64_disp(rh, mem, field, &size, private);
}
static int _segmonitor_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *)data;
char *str;
if (!(str = lvseg_monitor_dup(mem, seg)))
return_0;
if (*str)
return _field_set_value(field, str, NULL);
return _field_set_value(field, GET_FIRST_RESERVED_NAME(seg_monitor_undef),
GET_FIELD_RESERVED_VALUE(seg_monitor_undef));
}
static int _segstart_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
uint64_t start = lvseg_start(seg);
return _size64_disp(rh, mem, field, &start, private);
}
static int _segstartpe_disp(struct dm_report *rh,
struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
const struct lv_segment *seg = (const struct lv_segment *) data;
return dm_report_field_uint32(rh, field, &seg->le);
}
/* Hepler: get used stripes = total stripes minux any to remove after reshape */
static int _get_seg_used_stripes(const struct lv_segment *seg)
{
uint32_t s;
uint32_t stripes = seg->area_count;
for (s = seg->area_count - 1; stripes && s; s--) {
if (seg_type(seg, s) == AREA_LV &&
seg_lv(seg, s)->status & LV_REMOVE_AFTER_RESHAPE)
stripes--;
else
break;
}
return stripes;
}
static int _seg_stripes_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = ((const struct lv_segment *) data);
return dm_report_field_uint32(rh, field, &seg->area_count);
}
/* Report the number of data stripes, which is less than total stripes (e.g. 2 less for raid6) */
static int _seg_data_stripes_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
uint32_t stripes = _get_seg_used_stripes(seg) - seg->segtype->parity_devs;
/* FIXME: in case of odd numbers of raid10 stripes */
if (seg_is_raid10(seg))
stripes /= seg->data_copies;
return dm_report_field_uint32(rh, field, &stripes);
}
/* Helper: return the top-level, reshapable raid LV in case @seg belongs to an raid rimage LV */
static struct logical_volume *_lv_for_raid_image_seg(const struct lv_segment *seg, struct dm_pool *mem)
{
char *lv_name;
if (seg_is_reshapable_raid(seg))
return seg->lv;
if (seg->lv &&
lv_is_raid_image(seg->lv) && !seg->le &&
(lv_name = dm_pool_strdup(mem, seg->lv->name))) {
char *p = strchr(lv_name, '_');
if (p) {
/* Handle duplicated sub LVs */
if (strstr(p, "_dup_"))
p = strchr(p + 5, '_');
if (p) {
struct lv_list *lvl;
*p = '\0';
if ((lvl = find_lv_in_vg(seg->lv->vg, lv_name)) &&
seg_is_reshapable_raid(first_seg(lvl->lv)))
return lvl->lv;
}
}
}
return NULL;
}
/* Helper: return the top-level raid LV in case it is reshapale for @seg or @seg if it is */
static const struct lv_segment *_get_reshapable_seg(const struct lv_segment *seg, struct dm_pool *mem)
{
return _lv_for_raid_image_seg(seg, mem) ? seg : NULL;
}
/* Display segment reshape length in current units */
static int _seg_reshape_len_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = _get_reshapable_seg((const struct lv_segment *) data, mem);
if (seg) {
uint32_t reshape_len = seg->reshape_len * seg->area_count * seg->lv->vg->extent_size;
return _size32_disp(rh, mem, field, &reshape_len, private);
}
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
/* Display segment reshape length of in logical extents */
static int _seg_reshape_len_le_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = _get_reshapable_seg((const struct lv_segment *) data, mem);
if (seg) {
uint32_t reshape_len = seg->reshape_len* seg->area_count;
return dm_report_field_uint32(rh, field, &reshape_len);
}
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
/* Display segment data copies (e.g. 3 for raid6) */
static int _seg_data_copies_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
if (seg->data_copies)
return dm_report_field_uint32(rh, field, &seg->data_copies);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
/* Helper: display segment data offset/new data offset in sectors */
static int _segdata_offset(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private, int new_data_offset)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
struct logical_volume *lv;
if ((lv = _lv_for_raid_image_seg(seg, mem))) {
uint64_t data_offset = 0;
if (lv_raid_data_offset(lv, &data_offset)) {
if (new_data_offset && lv_is_raid_image(lv) && !lv_raid_image_in_sync(lv))
data_offset = data_offset ? 0 : (uint64_t) seg->reshape_len * lv->vg->extent_size;
return dm_report_field_uint64(rh, field, &data_offset);
}
}
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _seg_data_offset_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
return _segdata_offset(rh, mem, field, data, private, 0);
}
static int _seg_new_data_offset_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
return _segdata_offset(rh, mem, field, data, private, 1);
}
static int _seg_parity_chunks_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
uint32_t parity_chunks = seg->segtype->parity_devs ?: seg->data_copies - 1;
if (parity_chunks) {
uint32_t s, resilient_sub_lvs = 0;
for (s = 0; s < seg->area_count; s++) {
if (seg_type(seg, s) == AREA_LV) {
struct lv_segment *seg1 = first_seg(seg_lv(seg, s));
if (seg1->segtype->parity_devs ||
seg1->data_copies > 1)
resilient_sub_lvs++;
}
}
if (resilient_sub_lvs && resilient_sub_lvs == seg->area_count)
parity_chunks++;
return dm_report_field_uint32(rh, field, &parity_chunks);
}
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _segsize_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
uint64_t size = lvseg_size(seg);
return _size64_disp(rh, mem, field, &size, private);
}
static int _segsizepe_disp(struct dm_report *rh,
struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
const struct lv_segment *seg = (const struct lv_segment *) data;
return dm_report_field_uint32(rh, field, &seg->len);
}
static int _chunksize_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
uint64_t size = lvseg_chunksize(seg);
return _size64_disp(rh, mem, field, &size, private);
}
static int _transactionid_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
if (seg_is_thin_pool(seg) || seg_is_thin_volume(seg))
return dm_report_field_uint64(rh, field, &seg->transaction_id);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _thinid_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
if (seg_is_thin_volume(seg))
return dm_report_field_uint32(rh, field, &seg->device_id);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _discards_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
const char *discards_str;
if (seg_is_thin_volume(seg))
seg = first_seg(seg->pool_lv);
if (seg_is_thin_pool(seg)) {
discards_str = get_pool_discards_name(seg->discards);
return _field_string(rh, field, discards_str);
}
return _field_set_value(field, "", NULL);
}
static int _kdiscards_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
const char *discards_str;
if (!(discards_str = lvseg_kernel_discards_dup_with_info_and_seg_status(mem, lvdm)))
return_0;
if (*discards_str)
return _field_set_value(field, discards_str, NULL);
return _field_set_value(field, GET_FIRST_RESERVED_NAME(seg_kernel_discards_undef),
GET_FIELD_RESERVED_VALUE(seg_kernel_discards_undef));
}
static int _cachemode_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
return _field_string(rh, field, display_cache_mode(seg));
}
static int _cachemetadataformat_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
const struct lv_segment *setting_seg = NULL;
const uint64_t *fmt;
if (seg_is_cache(seg) && lv_is_cache_vol(seg->pool_lv))
setting_seg = seg;
else if (seg_is_cache_pool(seg))
setting_seg = seg;
else if (seg_is_cache(seg))
setting_seg = first_seg(seg->pool_lv);
else
goto undef;
switch (setting_seg->cache_metadata_format) {
case CACHE_METADATA_FORMAT_1:
case CACHE_METADATA_FORMAT_2:
fmt = (setting_seg->cache_metadata_format == CACHE_METADATA_FORMAT_2) ? &_two64 : &_one64;
return dm_report_field_uint64(rh, field, fmt);
default: /* unselected/undefined for all other cases */;
}
undef:
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _originsize_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
uint64_t size = lv_origin_size(lv);
if (size)
return _size64_disp(rh, mem, field, &size, private);
return _field_set_value(field, "", &_zero64);
}
static int _pvused_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct physical_volume *pv =
(const struct physical_volume *) data;
uint64_t used = pv_used(pv);
return _size64_disp(rh, mem, field, &used, private);
}
static int _pvfree_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct physical_volume *pv =
(const struct physical_volume *) data;
uint64_t freespace;
if (is_orphan(pv) && is_used_pv(pv))
freespace = 0;
else
freespace = pv_free(pv);
return _size64_disp(rh, mem, field, &freespace, private);
}
static int _pvsize_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct physical_volume *pv =
(const struct physical_volume *) data;
uint64_t size = pv_size_field(pv);
return _size64_disp(rh, mem, field, &size, private);
}
static int _devsize_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
struct device *dev = *(struct device * const *) data;
uint64_t size;
if (!dev || !dev->dev || !dev_get_size(dev, &size))
size = _zero64;
return _size64_disp(rh, mem, field, &size, private);
}
static int _vgfree_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
uint64_t freespace = vg_free(vg);
return _size64_disp(rh, mem, field, &freespace, private);
}
static int _vgsystemid_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
const char *repstr = (vg->system_id && *vg->system_id) ? vg->system_id : "";
return _field_string(rh, field, repstr);
}
static int _vglocktype_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
const char *locktype;
if (!vg->lock_type || !strcmp(vg->lock_type, "none"))
locktype = "";
else
locktype = vg->lock_type;
return _field_string(rh, field, locktype);
}
static int _vglockargs_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
return _field_string(rh, field, vg->lock_args ? : "");
}
static int _lvuuid_disp(struct dm_report *rh __attribute__((unused)), struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
const union lvid *lvid;
char *repstr;
if (lv_is_historical(lv))
lvid = &lv->this_glv->historical->lvid;
else
lvid = &lv->lvid;
if (!(repstr = id_format_and_copy(mem, &lvid->id[1])))
return_0;
return _field_set_value(field, repstr, NULL);
}
static int _pvuuid_disp(struct dm_report *rh __attribute__((unused)), struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct label *label = (const struct label *) data;
if (!label->dev)
return _field_set_value(field, "", NULL);
return _uuid_disp(rh, mem, field, label->dev->pvid, private);
}
static int _pvmdas_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct physical_volume *pv =
(const struct physical_volume *) data;
uint32_t count = pv_mda_count(pv);
return _uint32_disp(rh, mem, field, &count, private);
}
static int _pvmdasused_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct physical_volume *pv =
(const struct physical_volume *) data;
uint32_t count = pv_mda_used_count(pv);
return _uint32_disp(rh, mem, field, &count, private);
}
static int _vgmdas_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
uint32_t count = vg_mda_count(vg);
return _uint32_disp(rh, mem, field, &count, private);
}
static int _vgmdasused_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
uint32_t count = vg_mda_used_count(vg);
return _uint32_disp(rh, mem, field, &count, private);
}
static int _vgmdacopies_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
struct cmd_context *cmd = (struct cmd_context *) private;
const struct volume_group *vg = (const struct volume_group *) data;
uint32_t count = vg_mda_copies(vg);
if (count == VGMETADATACOPIES_UNMANAGED && !cmd->report_strict_type_mode)
return _field_set_value(field, GET_FIRST_RESERVED_NAME(vg_mda_copies_unmanaged),
GET_FIELD_RESERVED_VALUE(vg_mda_copies_unmanaged));
return _uint32_disp(rh, mem, field, &count, private);
}
static int _vgprofile_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
if (vg->profile)
return _field_string(rh, field, vg->profile->name);
return _field_set_value(field, "", NULL);
}
static int _vgmissingpvcount_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
uint32_t count = vg_missing_pv_count(vg);
return _uint32_disp(rh, mem, field, &count, private);
}
static int _pvmdafree_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct label *label = (const struct label *) data;
uint64_t freespace = lvmcache_info_mda_free(label->info);
return _size64_disp(rh, mem, field, &freespace, private);
}
static int _pvmdasize_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct label *label = (const struct label *) data;
uint64_t min_mda_size = lvmcache_smallest_mda_size(label->info);
return _size64_disp(rh, mem, field, &min_mda_size, private);
}
static int _pvextvsn_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct label *label = (const struct label *) data;
struct lvmcache_info *info = label->info;
uint32_t ext_version;
if (info) {
ext_version = lvmcache_ext_version(info);
return _uint32_disp(rh, mem, field, &ext_version, private);
}
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vgmdasize_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
uint64_t min_mda_size = vg_mda_size(vg);
return _size64_disp(rh, mem, field, &min_mda_size, private);
}
static int _vgmdafree_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
uint64_t freespace = vg_mda_free(vg);
return _size64_disp(rh, mem, field, &freespace, private);
}
static int _lvcount_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
uint32_t count = vg_visible_lvs(vg);
return _uint32_disp(rh, mem, field, &count, private);
}
static int _lvsegcount_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
uint32_t count = dm_list_size(&lv->segments);
return _uint32_disp(rh, mem, field, &count, private);
}
static int _snapcount_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *) data;
uint32_t count = snapshot_count(vg);
return _uint32_disp(rh, mem, field, &count, private);
}
static int _snpercent_disp(struct dm_report *rh, struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
dm_percent_t percent = lvseg_percent_with_info_and_seg_status(lvdm, PERCENT_GET_DATA);
return dm_report_field_percent(rh, field, &percent);
}
static int _copypercent_disp(struct dm_report *rh,
struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private __attribute__((unused)))
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
const struct logical_volume *lv = lvdm->lv;
dm_percent_t percent = DM_PERCENT_INVALID;
/* TODO: just cache passes through lvseg_percent... */
if (lv_is_integrity(lv) || lv_is_cache(lv) || lv_is_used_cache_pool(lv) ||
(!lv_is_merging_origin(lv) && lv_is_raid(lv) && !seg_is_any_raid0(first_seg(lv))))
percent = lvseg_percent_with_info_and_seg_status(lvdm, PERCENT_GET_DIRTY);
else if (lv_is_raid(lv) && !seg_is_any_raid0(first_seg(lv)))
/* old way for percentage when merging snapshot into raid origin */
(void) lv_raid_percent(lv, &percent);
else if (((lv_is_mirror(lv) &&
lv_mirror_percent(lv->vg->cmd, lv, 0, &percent, NULL))) &&
(percent != DM_PERCENT_INVALID))
percent = copy_percent(lv);
return dm_report_field_percent(rh, field, &percent);
}
static int _raidsyncaction_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
char *sync_action;
if (lv_is_raid(lv) && lv_raid_sync_action(lv, &sync_action))
return _field_string(rh, field, sync_action);
return _field_set_value(field, "", NULL);
}
static int _raidmismatchcount_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
uint64_t mismatch_count;
if (lv_is_raid(lv) && lv_raid_mismatch_count(lv, &mismatch_count))
return dm_report_field_uint64(rh, field, &mismatch_count);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _raidwritebehind_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
if (lv_is_raid_type(lv) && first_seg(lv)->writebehind)
return dm_report_field_uint32(rh, field, &first_seg(lv)->writebehind);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _raidminrecoveryrate_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
if (lv_is_raid_type(lv) && first_seg(lv)->min_recovery_rate)
return dm_report_field_uint32(rh, field,
&first_seg(lv)->min_recovery_rate);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _raidmaxrecoveryrate_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
const struct logical_volume *lv = (const struct logical_volume *) data;
if (lv_is_raid_type(lv) && first_seg(lv)->max_recovery_rate)
return dm_report_field_uint32(rh, field,
&first_seg(lv)->max_recovery_rate);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _raidintegritymode_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
struct logical_volume *lv = (struct logical_volume *) data;
struct integrity_settings *settings = NULL;
const char *mode = NULL;
char *repstr;
if (lv_raid_has_integrity(lv))
lv_get_raid_integrity_settings(lv, &settings);
else if (lv_is_integrity(lv))
settings = &first_seg(lv)->integrity_settings;
else
goto out;
if (settings && settings->mode[0]) {
if (settings->mode[0] == 'B')
mode = "bitmap";
else if (settings->mode[0] == 'J')
mode = "journal";
if (mode) {
if (!(repstr = dm_pool_strdup(mem, mode))) {
log_error("Failed to allocate buffer for mode.");
return 0;
}
return _field_set_value(field, repstr, NULL);
}
}
out:
return _field_set_value(field, "", NULL);
}
static int _raidintegrityblocksize_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
struct logical_volume *lv = (struct logical_volume *) data;
struct integrity_settings *settings = NULL;
if (lv_raid_has_integrity(lv))
lv_get_raid_integrity_settings(lv, &settings);
else if (lv_is_integrity(lv))
settings = &first_seg(lv)->integrity_settings;
if (!settings)
return dm_report_field_int32(rh, field, &GET_TYPE_RESERVED_VALUE(num_undef_32));
return dm_report_field_uint32(rh, field, &settings->block_size);
}
static int _integritymismatches_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
struct logical_volume *lv = (struct logical_volume *) data;
uint64_t mismatches = 0;
if (lv_is_integrity(lv) && lv_integrity_mismatches(lv->vg->cmd, lv, &mismatches))
return dm_report_field_uint64(rh, field, &mismatches);
if (lv_is_raid(lv) && lv_raid_has_integrity(lv) &&
lv_raid_integrity_total_mismatches(lv->vg->cmd, lv, &mismatches))
return dm_report_field_uint64(rh, field, &mismatches);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _writecache_block_size_disp(struct dm_report *rh __attribute__((unused)),
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private __attribute__((unused)))
{
struct logical_volume *lv = (struct logical_volume *) data;
uint32_t bs = 0;
if (lv_is_writecache(lv)) {
struct lv_segment *seg = first_seg(lv);
bs = seg->writecache_block_size;
}
if (!bs)
return dm_report_field_int32(rh, field, &GET_TYPE_RESERVED_VALUE(num_undef_32));
return dm_report_field_uint32(rh, field, &bs);
}
static int _datapercent_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
dm_percent_t percent = lvseg_percent_with_info_and_seg_status(lvdm, PERCENT_GET_DATA);
return dm_report_field_percent(rh, field, &percent);
}
static int _metadatapercent_disp(struct dm_report *rh,
struct dm_pool *mem __attribute__((unused)),
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
dm_percent_t percent;
switch (lvdm->seg_status.type) {
case SEG_STATUS_CACHE:
case SEG_STATUS_THIN_POOL:
percent = lvseg_percent_with_info_and_seg_status(lvdm, PERCENT_GET_METADATA);
break;
default:
percent = DM_PERCENT_INVALID;
}
return dm_report_field_percent(rh, field, &percent);
}
static int _lvmetadatasize_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
uint64_t size;
if (lv_is_cache(lv) && lv_is_cache_vol(first_seg(lv)->pool_lv)) {
size = lv_metadata_size(lv);
return _size64_disp(rh, mem, field, &size, private);
}
if (lv_is_thin_pool(lv) || lv_is_cache_pool(lv)) {
size = lv_metadata_size(lv);
return _size64_disp(rh, mem, field, &size, private);
}
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _thincount_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
uint32_t count;
if (seg_is_thin_pool(seg)) {
count = dm_list_size(&seg->lv->segs_using_this_lv);
return _uint32_disp(rh, mem, field, &count, private);
}
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _lvtime_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
char *repstr;
uint64_t *sortval;
if (!(repstr = lv_creation_time_dup(mem, lv, 0)) ||
!(sortval = dm_pool_alloc(mem, sizeof(uint64_t)))) {
log_error("Failed to allocate buffer for time.");
return 0;
}
*sortval = lv_is_historical(lv) ? lv->this_glv->historical->timestamp : lv->timestamp;
return _field_set_value(field, repstr, sortval);
}
static int _lvtimeremoved_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
char *repstr;
uint64_t *sortval;
if (!(repstr = lv_removal_time_dup(mem, lv, 0)) ||
!(sortval = dm_pool_alloc(mem, sizeof(uint64_t)))) {
log_error("Failed to allocate buffer for time.");
return 0;
}
*sortval = lv_is_historical(lv) ? lv->this_glv->historical->timestamp_removed : 0;
return _field_set_value(field, repstr, sortval);
}
static int _lvhost_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
char *repstr;
if (!(repstr = lv_host_dup(mem, lv))) {
log_error("Failed to allocate buffer for host.");
return 0;
}
return _field_set_value(field, repstr, NULL);
}
/* PV/VG/LV Attributes */
static int _pvallocatable_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int allocatable = (((const struct physical_volume *) data)->status & ALLOCATABLE_PV) != 0;
return _binary_disp(rh, mem, field, allocatable, GET_FIRST_RESERVED_NAME(pv_allocatable_y), private);
}
static int _pvexported_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int exported = (((const struct physical_volume *) data)->status & EXPORTED_VG) != 0;
return _binary_disp(rh, mem, field, exported, GET_FIRST_RESERVED_NAME(pv_exported_y), private);
}
static int _pvmissing_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int missing = (((const struct physical_volume *) data)->status & MISSING_PV) != 0;
return _binary_disp(rh, mem, field, missing, GET_FIRST_RESERVED_NAME(pv_missing_y), private);
}
static int _pvinuse_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct physical_volume *pv = (const struct physical_volume *) data;
int used = is_used_pv(pv);
if (used < 0)
return _binary_undef_disp(rh, mem, field, private);
return _binary_disp(rh, mem, field, used, GET_FIRST_RESERVED_NAME(pv_in_use_y), private);
}
static int _pvduplicate_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct physical_volume *pv = (const struct physical_volume *) data;
int duplicate = lvmcache_dev_is_unused_duplicate(pv->dev);
return _binary_disp(rh, mem, field, duplicate, GET_FIRST_RESERVED_NAME(pv_duplicate_y), private);
}
static int _pvdeviceid_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct physical_volume *pv = (const struct physical_volume *) data;
char *repstr;
if (!pv->device_id)
return _field_set_value(field, "", NULL);
if (!(repstr = pv_deviceid_dup(mem, pv))) {
log_error("Failed to allocate buffer.");
return 0;
}
return _field_set_value(field, repstr, NULL);
}
static int _pvdeviceidtype_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct physical_volume *pv = (const struct physical_volume *) data;
char *repstr;
if (!pv->device_id_type)
return _field_set_value(field, "", NULL);
if (!(repstr = pv_deviceidtype_dup(mem, pv))) {
log_error("Failed to allocate buffer.");
return 0;
}
return _field_set_value(field, repstr, NULL);
}
static int _vgpermissions_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const char *perms = ((const struct volume_group *) data)->status & LVM_WRITE ? GET_FIRST_RESERVED_NAME(vg_permissions_rw)
: GET_FIRST_RESERVED_NAME(vg_permissions_r);
return _field_string(rh, field, perms);
}
static int _vgextendable_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int extendable = (vg_is_resizeable((const struct volume_group *) data)) != 0;
return _binary_disp(rh, mem, field, extendable, GET_FIRST_RESERVED_NAME(vg_extendable_y),private);
}
static int _vgexported_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int exported = (vg_is_exported((const struct volume_group *) data)) != 0;
return _binary_disp(rh, mem, field, exported, GET_FIRST_RESERVED_NAME(vg_exported_y), private);
}
static int _vgautoactivation_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct volume_group *vg = (const struct volume_group *)data;
int aa_yes = (vg->status & NOAUTOACTIVATE) ? 0 : 1;
return _binary_disp(rh, mem, field, aa_yes, "enabled", private);
}
static int _vgpartial_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int partial = (vg_missing_pv_count((const struct volume_group *) data)) != 0;
return _binary_disp(rh, mem, field, partial, GET_FIRST_RESERVED_NAME(vg_partial_y), private);
}
static int _vgallocationpolicy_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const char *alloc_policy = get_alloc_string(((const struct volume_group *) data)->alloc) ? : _str_unknown;
return _field_string(rh, field, alloc_policy);
}
static int _vgclustered_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int clustered = (vg_is_clustered((const struct volume_group *) data)) != 0;
return _binary_disp(rh, mem, field, clustered, GET_FIRST_RESERVED_NAME(vg_clustered_y), private);
}
static int _vgshared_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int shared = (vg_is_shared((const struct volume_group *) data)) != 0;
return _binary_disp(rh, mem, field, shared, GET_FIRST_RESERVED_NAME(vg_shared_y), private);
}
static int _lvlayout_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
struct dm_list *lv_layout;
struct dm_list *lv_role;
if (!lv_layout_and_role(mem, lv, &lv_layout, &lv_role)) {
log_error("Failed to display layout for LV %s/%s.", lv->vg->name, lv->name);
return 0;
}
return _field_set_string_list(rh, field, lv_layout, private, 0, NULL);
}
static int _lvrole_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
struct dm_list *lv_layout;
struct dm_list *lv_role;
if (!lv_layout_and_role(mem, lv, &lv_layout, &lv_role)) {
log_error("Failed to display role for LV %s/%s.", lv->vg->name, lv->name);
return 0;
}
return _field_set_string_list(rh, field, lv_role, private, 0, NULL);
}
static int _lvinitialimagesync_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
int initial_image_sync;
if (lv_is_raid(lv) || lv_is_mirrored(lv))
initial_image_sync = !lv_is_not_synced(lv);
else
initial_image_sync = 0;
return _binary_disp(rh, mem, field, initial_image_sync, GET_FIRST_RESERVED_NAME(lv_initial_image_sync_y), private);
}
static int _lvimagesynced_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
int image_synced;
if (lv_is_raid_image(lv))
image_synced = !lv_is_visible(lv) && lv_raid_image_in_sync(lv);
else if (lv_is_mirror_image(lv))
image_synced = lv_mirror_image_in_sync(lv);
else
image_synced = 0;
return _binary_disp(rh, mem, field, image_synced, GET_FIRST_RESERVED_NAME(lv_image_synced_y), private);
}
static int _lvmerging_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
int merging;
if (lv_is_origin(lv) || lv_is_external_origin(lv))
merging = lv_is_merging_origin(lv);
else if (lv_is_cow(lv))
merging = lv_is_merging_cow(lv);
else if (lv_is_thin_volume(lv))
merging = lv_is_merging_thin_snapshot(lv);
else
merging = 0;
return _binary_disp(rh, mem, field, merging, GET_FIRST_RESERVED_NAME(lv_merging_y), private);
}
static int _lvconverting_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int converting = lv_is_converting((const struct logical_volume *) data);
return _binary_disp(rh, mem, field, converting, "converting", private);
}
static int _lvpermissions_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
const char *perms = "";
if (!lv_is_pvmove(lvdm->lv)) {
if (lvdm->lv->status & LVM_WRITE) {
if (!lvdm->info.exists)
perms = _str_unknown;
else if (lvdm->info.read_only)
perms = GET_FIRST_RESERVED_NAME(lv_permissions_r_override);
else
perms = GET_FIRST_RESERVED_NAME(lv_permissions_rw);
} else if (lvdm->lv->status & LVM_READ)
perms = GET_FIRST_RESERVED_NAME(lv_permissions_r);
else
perms = _str_unknown;
}
return _field_string(rh, field, perms);
}
static int _lvallocationpolicy_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const char *alloc_policy = get_alloc_string(((const struct logical_volume *) data)->alloc) ? : _str_unknown;
return _field_string(rh, field, alloc_policy);
}
static int _lvallocationlocked_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int alloc_locked = (((const struct logical_volume *) data)->status & LOCKED) != 0;
return _binary_disp(rh, mem, field, alloc_locked, GET_FIRST_RESERVED_NAME(lv_allocation_locked_y), private);
}
static int _lvfixedminor_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int fixed_minor = (((const struct logical_volume *) data)->status & FIXED_MINOR) != 0;
return _binary_disp(rh, mem, field, fixed_minor, GET_FIRST_RESERVED_NAME(lv_fixed_minor_y), private);
}
static int _lvactive_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
char *repstr;
if (!(repstr = lv_active_dup(mem, (const struct logical_volume *) data))) {
log_error("Failed to allocate buffer for active.");
return 0;
}
return _field_set_value(field, repstr, NULL);
}
static int _lvactivelocally_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
int active_locally;
if (!activation())
return _binary_undef_disp(rh, mem, field, private);
active_locally = lv_is_active(lv);
return _binary_disp(rh, mem, field, active_locally, GET_FIRST_RESERVED_NAME(lv_active_locally_y), private);
}
static int _lvactiveremotely_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int active_remotely;
if (!activation())
return _binary_undef_disp(rh, mem, field, private);
active_remotely = 0;
return _binary_disp(rh, mem, field, active_remotely, GET_FIRST_RESERVED_NAME(lv_active_remotely_y), private);
}
static int _lvactiveexclusively_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
int active_exclusively;
if (!activation())
return _binary_undef_disp(rh, mem, field, private);
active_exclusively = lv_is_active(lv);
return _binary_disp(rh, mem, field, active_exclusively, GET_FIRST_RESERVED_NAME(lv_active_exclusively_y), private);
}
static int _lvmergefailed_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (lvdm->seg_status.type != SEG_STATUS_SNAPSHOT)
return _binary_undef_disp(rh, mem, field, private);
return _binary_disp(rh, mem, field, lvdm->seg_status.snapshot->merge_failed,
GET_FIRST_RESERVED_NAME(lv_merge_failed_y), private);
}
static int _lvsnapshotinvalid_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (lvdm->seg_status.type != SEG_STATUS_SNAPSHOT)
return _binary_undef_disp(rh, mem, field, private);
return _binary_disp(rh, mem, field, lvdm->seg_status.snapshot->invalid,
GET_FIRST_RESERVED_NAME(lv_snapshot_invalid_y), private);
}
static int _lvsuspended_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (lvdm->info.exists)
return _binary_disp(rh, mem, field, lvdm->info.suspended, GET_FIRST_RESERVED_NAME(lv_suspended_y), private);
return _binary_undef_disp(rh, mem, field, private);
}
static int _lvlivetable_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (lvdm->info.exists)
return _binary_disp(rh, mem, field, lvdm->info.live_table, GET_FIRST_RESERVED_NAME(lv_live_table_y), private);
return _binary_undef_disp(rh, mem, field, private);
}
static int _lvinactivetable_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (lvdm->info.exists)
return _binary_disp(rh, mem, field, lvdm->info.inactive_table, GET_FIRST_RESERVED_NAME(lv_inactive_table_y), private);
return _binary_undef_disp(rh, mem, field, private);
}
static int _lvdeviceopen_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (lvdm->info.exists)
return _binary_disp(rh, mem, field, lvdm->info.open_count, GET_FIRST_RESERVED_NAME(lv_device_open_y), private);
return _binary_undef_disp(rh, mem, field, private);
}
static int _thinzero_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
if (seg_is_thin_volume(seg))
seg = first_seg(seg->pool_lv);
if (seg_is_thin_pool(seg))
return _binary_disp(rh, mem, field, (seg->zero_new_blocks == THIN_ZERO_YES), GET_FIRST_RESERVED_NAME(zero_y), private);
return _binary_undef_disp(rh, mem, field, private);
}
static int _lvhealthstatus_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
const struct logical_volume *lv = lvdm->lv;
const char *health = "";
uint64_t n;
if (lv_is_partial(lv))
health = "partial";
else if (lv_is_raid_type(lv)) {
if (!activation())
health = "unknown";
else if (!lv_raid_healthy(lv))
health = "refresh needed";
else if (lv_is_raid(lv)) {
if (lv_raid_mismatch_count(lv, &n) && n)
health = "mismatches exist";
} else if (lv->status & LV_WRITEMOSTLY)
health = "writemostly";
} else if (lv_is_cache(lv) && (lvdm->seg_status.type != SEG_STATUS_NONE)) {
if (lvdm->seg_status.type != SEG_STATUS_CACHE)
return _field_set_value(field, GET_FIRST_RESERVED_NAME(health_undef),
GET_FIELD_RESERVED_VALUE(health_undef));
if (lvdm->seg_status.cache->fail)
health = "failed";
else if (lvdm->seg_status.cache->read_only)
health = "metadata_read_only";
} else if (lv_is_writecache(lv) && (lvdm->seg_status.type != SEG_STATUS_NONE)) {
if (lvdm->seg_status.type != SEG_STATUS_WRITECACHE)
return _field_set_value(field, GET_FIRST_RESERVED_NAME(health_undef),
GET_FIELD_RESERVED_VALUE(health_undef));
if (lvdm->seg_status.writecache->error)
health = "error";
} else if (lv_is_thin_pool(lv) && (lvdm->seg_status.type != SEG_STATUS_NONE)) {
if (lvdm->seg_status.type != SEG_STATUS_THIN_POOL)
return _field_set_value(field, GET_FIRST_RESERVED_NAME(health_undef),
GET_FIELD_RESERVED_VALUE(health_undef));
if (lvdm->seg_status.thin_pool->fail)
health = "failed";
else if (lvdm->seg_status.thin_pool->out_of_data_space)
health = "out_of_data";
else if (lvdm->seg_status.thin_pool->read_only)
health = "metadata_read_only";
}
return _field_string(rh, field, health);
}
static int _lvcheckneeded_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data;
if (lv_is_thin_pool(lvdm->lv) && lvdm->seg_status.type == SEG_STATUS_THIN_POOL)
return _binary_disp(rh, mem, field, lvdm->seg_status.thin_pool->needs_check,
GET_FIRST_RESERVED_NAME(lv_check_needed_y), private);
if (lv_is_cache(lvdm->lv) && lvdm->seg_status.type == SEG_STATUS_CACHE)
return _binary_disp(rh, mem, field, lvdm->seg_status.cache->needs_check,
GET_FIRST_RESERVED_NAME(lv_check_needed_y), private);
return _binary_undef_disp(rh, mem, field, private);
}
static int _lvskipactivation_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int skip_activation = (((const struct logical_volume *) data)->status & LV_ACTIVATION_SKIP) != 0;
return _binary_disp(rh, mem, field, skip_activation, "skip activation", private);
}
static int _lvautoactivation_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
int aa_yes = (((const struct logical_volume *) data)->status & LV_NOAUTOACTIVATE) ? 0 : 1;
return _binary_disp(rh, mem, field, aa_yes, "enabled", private);
}
static int _lvhistorical_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct logical_volume *lv = (const struct logical_volume *) data;
return _binary_disp(rh, mem, field, lv_is_historical(lv), "historical", private);
}
/*
* Macro to generate '_cache_<cache_status_field_name>_disp' reporting function.
* The 'cache_status_field_name' is field name from struct dm_cache_status.
*/
#define GENERATE_CACHE_STATUS_DISP_FN(cache_status_field_name) \
static int _cache_ ## cache_status_field_name ## _disp (struct dm_report *rh, \
struct dm_pool *mem, \
struct dm_report_field *field, \
const void *data, \
void *private) \
{ \
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data; \
if (lvdm->seg_status.type != SEG_STATUS_CACHE) \
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64)); \
return dm_report_field_uint64(rh, field, &lvdm->seg_status.cache->cache_status_field_name); \
}
GENERATE_CACHE_STATUS_DISP_FN(total_blocks)
GENERATE_CACHE_STATUS_DISP_FN(used_blocks)
GENERATE_CACHE_STATUS_DISP_FN(dirty_blocks)
GENERATE_CACHE_STATUS_DISP_FN(read_hits)
GENERATE_CACHE_STATUS_DISP_FN(read_misses)
GENERATE_CACHE_STATUS_DISP_FN(write_hits)
GENERATE_CACHE_STATUS_DISP_FN(write_misses)
/*
* Macro to generate '_writecache_<cache_status_field_name>_disp' reporting function.
* The 'writecache_status_field_name' is field name from struct dm_writecache_status.
*/
#define GENERATE_WRITECACHE_STATUS_DISP_FN(writecache_status_field_name) \
static int _writecache_ ## writecache_status_field_name ## _disp (struct dm_report *rh, \
struct dm_pool *mem, \
struct dm_report_field *field, \
const void *data, \
void *private) \
{ \
const struct lv_with_info_and_seg_status *lvdm = (const struct lv_with_info_and_seg_status *) data; \
if (lvdm->seg_status.type != SEG_STATUS_WRITECACHE) \
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64)); \
return dm_report_field_uint64(rh, field, &lvdm->seg_status.writecache->writecache_status_field_name); \
}
GENERATE_WRITECACHE_STATUS_DISP_FN(total_blocks)
GENERATE_WRITECACHE_STATUS_DISP_FN(free_blocks)
GENERATE_WRITECACHE_STATUS_DISP_FN(writeback_blocks)
GENERATE_WRITECACHE_STATUS_DISP_FN(error)
/*
* Macro to generate '_vdo_<vdo_field_name>_disp' reporting function.
* The 'vdo_field_name' is field name from struct lv_vdo_status.
*/
#define GENERATE_VDO_FIELD_DISP_FN(vdo_field_name) \
static int _vdo_ ## vdo_field_name ## _disp (struct dm_report *rh, struct dm_pool *mem, \
struct dm_report_field *field, \
const void *data, void *private) \
{ \
const struct lv_segment *seg = (const struct lv_segment *) data; \
\
if (seg_is_vdo(seg)) \
seg = first_seg(seg_lv(seg, 0)); \
\
if (!seg_is_vdo_pool(seg)) \
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64)); \
\
return dm_report_field_uint32(rh, field, &seg->vdo_params.vdo_field_name); \
}
GENERATE_VDO_FIELD_DISP_FN(block_map_era_length)
GENERATE_VDO_FIELD_DISP_FN(ack_threads)
GENERATE_VDO_FIELD_DISP_FN(bio_threads)
GENERATE_VDO_FIELD_DISP_FN(bio_rotation)
GENERATE_VDO_FIELD_DISP_FN(cpu_threads)
GENERATE_VDO_FIELD_DISP_FN(hash_zone_threads)
GENERATE_VDO_FIELD_DISP_FN(logical_threads)
GENERATE_VDO_FIELD_DISP_FN(physical_threads)
GENERATE_VDO_FIELD_DISP_FN(max_discard)
/*
* Macro to generate '_vdo_<vdo_field_name>_disp' reporting function.
* The 'vdo_field_name' is field name from struct lv_vdo_status.
*/
#define GENERATE_VDO_FIELDSZMB_DISP_FN(vdo_field_name) \
static int _vdo_ ## vdo_field_name ## _disp (struct dm_report *rh, struct dm_pool *mem, \
struct dm_report_field *field, \
const void *data, void *private) \
{ \
uint64_t size; \
const struct lv_segment *seg = (const struct lv_segment *) data; \
\
if (seg_is_vdo(seg)) \
seg = first_seg(seg_lv(seg, 0)); \
\
if (!seg_is_vdo_pool(seg)) \
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64)); \
\
size = seg->vdo_params.vdo_field_name ## _mb * (UINT64_C(1024) * 1024 >> SECTOR_SHIFT); \
\
return _size64_disp(rh, mem, field, &size, private);\
}
GENERATE_VDO_FIELDSZMB_DISP_FN(block_map_cache_size)
GENERATE_VDO_FIELDSZMB_DISP_FN(index_memory_size)
GENERATE_VDO_FIELDSZMB_DISP_FN(slab_size)
static int _vdo_compression_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data; \
if (seg_is_vdo(seg))
seg = first_seg(seg_lv(seg, 0));
if (seg_is_vdo_pool(seg))
return _binary_disp(rh, mem, field, seg->vdo_params.use_compression,
GET_FIRST_RESERVED_NAME(vdo_compression_y), private);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64)); \
}
static int _vdo_deduplication_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data; \
if (seg_is_vdo(seg))
seg = first_seg(seg_lv(seg, 0));
if (seg_is_vdo_pool(seg))
return _binary_disp(rh, mem, field, seg->vdo_params.use_deduplication,
GET_FIRST_RESERVED_NAME(vdo_deduplication_y), private);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64)); \
}
static int _vdo_use_metadata_hints_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
if (seg_is_vdo(seg))
seg = first_seg(seg_lv(seg, 0));
if (seg_is_vdo_pool(seg))
return _binary_disp(rh, mem, field, seg->vdo_params.use_metadata_hints,
GET_FIRST_RESERVED_NAME(vdo_use_metadata_hints_y),
private);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vdo_use_sparse_index_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
if (seg_is_vdo(seg))
seg = first_seg(seg_lv(seg, 0));
if (seg_is_vdo_pool(seg))
return _binary_disp(rh, mem, field, seg->vdo_params.use_sparse_index,
GET_FIRST_RESERVED_NAME(vdo_use_sparse_index_y),
private);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vdo_minimum_io_size_disp(struct dm_report *rh, struct dm_pool *mem,
struct dm_report_field *field,
const void *data, void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
if (seg_is_vdo(seg))
seg = first_seg(seg_lv(seg, 0));
if (seg_is_vdo_pool(seg))
return _size32_disp(rh, mem, field, &seg->vdo_params.minimum_io_size, private);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vdo_header_size_disp(struct dm_report *rh,
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
if (seg_is_vdo(seg))
seg = first_seg(seg_lv(seg, 0));
if (seg_is_vdo_pool(seg))
return _size32_disp(rh, mem, field, &seg->vdo_pool_header_size, private);
return _field_set_value(field, "", &GET_TYPE_RESERVED_VALUE(num_undef_64));
}
static int _vdo_write_policy_disp(struct dm_report *rh,
struct dm_pool *mem,
struct dm_report_field *field,
const void *data,
void *private)
{
const struct lv_segment *seg = (const struct lv_segment *) data;
if (seg_is_vdo(seg))
seg = first_seg(seg_lv(seg, 0));
if (seg_is_vdo_pool(seg))
return _field_string(rh, field, get_vdo_write_policy_name(seg->vdo_params.write_policy));
return _field_set_value(field, GET_FIRST_RESERVED_NAME(vdo_write_policy_undef),
GET_FIELD_RESERVED_VALUE(vdo_write_policy_undef));
}
/* Report object types */
/* necessary for displaying something for PVs not belonging to VG */
static struct format_instance _dummy_fid = {
.metadata_areas_in_use = DM_LIST_HEAD_INIT(_dummy_fid.metadata_areas_in_use),
.metadata_areas_ignored = DM_LIST_HEAD_INIT(_dummy_fid.metadata_areas_ignored),
};
static struct volume_group _dummy_vg = {
.fid = &_dummy_fid,
.name = "",
.system_id = (char *) "",
.pvs = DM_LIST_HEAD_INIT(_dummy_vg.pvs),
.lvs = DM_LIST_HEAD_INIT(_dummy_vg.lvs),
.historical_lvs = DM_LIST_HEAD_INIT(_dummy_vg.historical_lvs),
.tags = DM_LIST_HEAD_INIT(_dummy_vg.tags),
};
static struct volume_group _unknown_vg = {
.fid = &_dummy_fid,
.name = "[unknown]",
.system_id = (char *) "",
.pvs = DM_LIST_HEAD_INIT(_unknown_vg.pvs),
.lvs = DM_LIST_HEAD_INIT(_unknown_vg.lvs),
.historical_lvs = DM_LIST_HEAD_INIT(_unknown_vg.historical_lvs),
.tags = DM_LIST_HEAD_INIT(_unknown_vg.tags),
};
static void *_obj_get_vg(void *obj)
{
struct volume_group *vg = ((struct lvm_report_object *)obj)->vg;
return vg ? vg : &_dummy_vg;
}
static void *_obj_get_lv(void *obj)
{
return (struct logical_volume *)((struct lvm_report_object *)obj)->lvdm->lv;
}
static void *_obj_get_lv_with_info_and_seg_status(void *obj)
{
return ((struct lvm_report_object *)obj)->lvdm;
}
static void *_obj_get_pv(void *obj)
{
return ((struct lvm_report_object *)obj)->pv;
}
static void *_obj_get_label(void *obj)
{
return ((struct lvm_report_object *)obj)->label;
}
static void *_obj_get_seg(void *obj)
{
return ((struct lvm_report_object *)obj)->seg;
}
static void *_obj_get_pvseg(void *obj)
{
return ((struct lvm_report_object *)obj)->pvseg;
}
static void *_obj_get_devtypes(void *obj)
{
return obj;
}
static void *_obj_get_cmdlog(void *obj)
{
return obj;
}
static const struct dm_report_object_type _log_report_types[] = {
{ CMDLOG, "Command Log", "log_", _obj_get_cmdlog },
{ 0, "", "", NULL },
};
static const struct dm_report_object_type _report_types[] = {
{ VGS, "Volume Group", "vg_", _obj_get_vg },
{ LVS, "Logical Volume", "lv_", _obj_get_lv },
{ LVSINFO, "Logical Volume Device Info", "lv_", _obj_get_lv_with_info_and_seg_status },
{ LVSSTATUS, "Logical Volume Device Status", "lv_", _obj_get_lv_with_info_and_seg_status },
{ LVSINFOSTATUS, "Logical Volume Device Info and Status Combined", "lv_", _obj_get_lv_with_info_and_seg_status },
{ PVS, "Physical Volume", "pv_", _obj_get_pv },
{ LABEL, "Physical Volume Label", "pv_", _obj_get_label },
{ SEGS, "Logical Volume Segment", "seg_", _obj_get_seg },
{ PVSEGS, "Physical Volume Segment", "pvseg_", _obj_get_pvseg },
{ 0, "", "", NULL },
};
static const struct dm_report_object_type _devtypes_report_types[] = {
{ DEVTYPES, "Device Types", "devtype_", _obj_get_devtypes },
{ 0, "", "", NULL },
};
/*
* Import column definitions
*/
#define STR DM_REPORT_FIELD_TYPE_STRING
#define NUM DM_REPORT_FIELD_TYPE_NUMBER
#define BIN DM_REPORT_FIELD_TYPE_NUMBER
#define SIZ DM_REPORT_FIELD_TYPE_SIZE
#define PCT DM_REPORT_FIELD_TYPE_PERCENT
#define TIM DM_REPORT_FIELD_TYPE_TIME
#define STR_LIST DM_REPORT_FIELD_TYPE_STRING_LIST
#define SNUM DM_REPORT_FIELD_TYPE_NUMBER
#define FIELD(type, strct, sorttype, head, field, width, func, id, desc, writeable) \
{type, sorttype, offsetof(type_ ## strct, field), (width) ? : sizeof(head) - 1, \
#id, head, &_ ## func ## _disp, desc},
typedef struct cmd_log_item type_cmd_log_item;
typedef struct physical_volume type_pv;
typedef struct logical_volume type_lv;
typedef struct volume_group type_vg;
typedef struct lv_segment type_seg;
typedef struct pv_segment type_pvseg;
typedef struct label type_label;
typedef dev_known_type_t type_devtype;
static const struct dm_report_field_type _fields[] = {
/* coverity[unnecessary_header] */
#include "columns.h"
{0, 0, 0, 0, "", "", NULL, NULL},
};
static const struct dm_report_field_type _devtypes_fields[] = {
#include "columns-devtypes.h"
{0, 0, 0, 0, "", "", NULL, NULL},
};
static const struct dm_report_field_type _log_fields[] = {
/* coverity[unnecessary_header] */
#include "columns-cmdlog.h"
{0, 0, 0, 0, "", "", NULL, NULL},
};
#undef STR
#undef NUM
#undef BIN
#undef SIZ
#undef STR_LIST
#undef SNUM
#undef FIELD
void *report_init(struct cmd_context *cmd, const char *format, const char *keys,
report_type_t *report_type, const char *separator,
int aligned, int buffered, int headings, int field_prefixes,
int quoted, int columns_as_rows, const char *selection,
int multiple_output)
{
uint32_t report_flags = 0;
const struct dm_report_object_type *types;
const struct dm_report_field_type *fields;
const struct dm_report_reserved_value *reserved_values;
void *rh;
if (aligned)
report_flags |= DM_REPORT_OUTPUT_ALIGNED;
if (buffered)
report_flags |= DM_REPORT_OUTPUT_BUFFERED;
if (headings)
report_flags |= DM_REPORT_OUTPUT_HEADINGS;
if (field_prefixes)
report_flags |= DM_REPORT_OUTPUT_FIELD_NAME_PREFIX;
if (!quoted)
report_flags |= DM_REPORT_OUTPUT_FIELD_UNQUOTED;
if (columns_as_rows)
report_flags |= DM_REPORT_OUTPUT_COLUMNS_AS_ROWS;
if (multiple_output)
report_flags |= DM_REPORT_OUTPUT_MULTIPLE_TIMES;
if (*report_type & CMDLOG) {
types = _log_report_types;
fields = _log_fields;
reserved_values = NULL;
} else if (*report_type & DEVTYPES) {
types = _devtypes_report_types;
fields = _devtypes_fields;
reserved_values = NULL;
} else {
types = _report_types;
fields = _fields;
reserved_values = _report_reserved_values;
}
rh = dm_report_init_with_selection(report_type, types, fields,
format, separator, report_flags, keys,
selection, reserved_values, cmd);
if (rh && field_prefixes)
dm_report_set_output_field_name_prefix(rh, "lvm2_");
return rh;
}
void *report_init_for_selection(struct cmd_context *cmd,
report_type_t *report_type,
const char *selection_criteria)
{
return dm_report_init_with_selection(report_type, _report_types, _fields,
"", DEFAULT_REP_SEPARATOR,
DM_REPORT_OUTPUT_FIELD_UNQUOTED,
"", selection_criteria,
_report_reserved_values,
cmd);
}
int report_get_prefix_and_desc(report_type_t report_type_id,
const char **report_prefix,
const char **report_desc)
{
const struct dm_report_object_type *report_types, *report_type;
if (report_type_id & CMDLOG)
report_types = _log_report_types;
else if (report_type_id & DEVTYPES)
report_types = _devtypes_report_types;
else
report_types = _report_types;
for (report_type = report_types; report_type->id; report_type++) {
if (report_type_id & report_type->id) {
*report_prefix = report_type->prefix;
*report_desc = report_type->desc;
return 1;
}
}
*report_prefix = *report_desc = "";
return 0;
}
/*
* Create a row of data for an object
*/
int report_object(void *handle, int selection_only, const struct volume_group *vg,
const struct logical_volume *lv, const struct physical_volume *pv,
const struct lv_segment *seg, const struct pv_segment *pvseg,
const struct lv_with_info_and_seg_status *lvdm,
const struct label *label)
{
struct selection_handle *sh = selection_only ? (struct selection_handle *) handle : NULL;
struct device dummy_device = { .dev = 0 };
struct label dummy_label = { .dev = &dummy_device };
struct lvm_report_object obj = {
.vg = (struct volume_group *) vg,
.lvdm = (struct lv_with_info_and_seg_status *) lvdm,
.pv = (struct physical_volume *) pv,
.seg = (struct lv_segment *) seg,
.pvseg = (struct pv_segment *) pvseg,
.label = (struct label *) (label ? : (pv ? pv_label(pv) : NULL))
};
/* FIXME workaround for pv_label going through cache; remove once struct
* physical_volume gains a proper "label" pointer */
if (!obj.label) {
if (pv) {
if (pv->fmt)
dummy_label.labeller = pv->fmt->labeller;
if (pv->dev)
dummy_label.dev = pv->dev;
else
memcpy(dummy_device.pvid, &pv->id, ID_LEN);
}
obj.label = &dummy_label;
}
/* Never report orphan VGs. */
if (vg && is_orphan_vg(vg->name)) {
obj.vg = &_dummy_vg;
if (pv)
_dummy_fid.fmt = pv->fmt;
}
if (vg && is_orphan_vg(vg->name) && pv && is_used_pv(pv)) {
obj.vg = &_unknown_vg;
_dummy_fid.fmt = pv->fmt;
}
return sh ? dm_report_object_is_selected(sh->selection_rh, &obj, 0, &sh->selected)
: dm_report_object(handle, &obj);
}
static int _report_devtype_single(void *handle, const dev_known_type_t *devtype)
{
return dm_report_object(handle, (void *)devtype);
}
int report_devtypes(void *handle)
{
int devtypeind = 0;
while (_dev_known_types[devtypeind].name[0])
if (!_report_devtype_single(handle, &_dev_known_types[devtypeind++]))
return 0;
return 1;
}
int report_cmdlog(void *handle, const char *type, const char *context,
const char *object_type_name, const char *object_name,
const char *object_id, const char *object_group,
const char *object_group_id, const char *msg,
int current_errno, int ret_code)
{
struct cmd_log_item log_item = {_log_seqnum++, type, context, object_type_name,
object_name ? : "", object_id ? : "",
object_group ? : "", object_group_id ? : "",
msg ? : "", current_errno, ret_code};
if (handle)
return dm_report_object(handle, &log_item);
return 1;
}
void report_reset_cmdlog_seqnum(void)
{
_log_seqnum = 1;
}
int report_current_object_cmdlog(const char *type, const char *msg, int32_t ret_code)
{
log_report_t log_state = log_get_report_state();
return report_cmdlog(log_state.report, type, log_get_report_context_name(log_state.context),
log_get_report_object_type_name(log_state.object_type),
log_state.object_name, log_state.object_id,
log_state.object_group, log_state.object_group_id,
msg, stored_errno(), ret_code);
}
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