/*
sysfs.c - Part of libsensors, a library for reading Linux sensor data
Copyright (c) 2005 Mark M. Hoffman <mhoffman@lightlink.com>
Copyright (C) 2007-2014 Jean Delvare <jdelvare@suse.de>
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU Lesser General Public License for more details.
You should have received a copy of the GNU 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.
*/
/* this define needed for strndup() */
#define _GNU_SOURCE
#include <sys/types.h>
#include <sys/stat.h>
#include <sys/vfs.h>
#include <unistd.h>
#include <string.h>
#include <stdlib.h>
#include <limits.h>
#include <errno.h>
#include <dirent.h>
#include "data.h"
#include "error.h"
#include "access.h"
#include "general.h"
#include "sysfs.h"
/****************************************************************************/
#define ATTR_MAX 128
#define SYSFS_MAGIC 0x62656572
/*
* Read an attribute from sysfs
* Returns a pointer to a freshly allocated string; free it yourself.
* If the file doesn't exist or can't be read, NULL is returned.
*/
static char *sysfs_read_attr(const char *device, const char *attr)
{
char path[NAME_MAX];
char buf[ATTR_MAX], *p;
FILE *f;
snprintf(path, NAME_MAX, "%s/%s", device, attr);
if (!(f = fopen(path, "r")))
return NULL;
p = fgets(buf, ATTR_MAX, f);
fclose(f);
if (!p)
return NULL;
/* Last byte is a '\n'; chop that off */
p = strndup(buf, strlen(buf) - 1);
if (!p)
sensors_fatal_error(__func__, "Out of memory");
return p;
}
/*
* Call an arbitrary function for each class device of the given class
* Returns 0 on success (all calls returned 0), a positive errno for
* local errors, or a negative error value if any call fails.
*/
static int sysfs_foreach_classdev(const char *class_name,
int (*func)(const char *, const char *))
{
char path[NAME_MAX];
int path_off, ret;
DIR *dir;
struct dirent *ent;
path_off = snprintf(path, NAME_MAX, "%s/class/%s",
sensors_sysfs_mount, class_name);
if (!(dir = opendir(path)))
return errno;
ret = 0;
while (!ret && (ent = readdir(dir))) {
if (ent->d_name[0] == '.') /* skip hidden entries */
continue;
snprintf(path + path_off, NAME_MAX - path_off, "/%s",
ent->d_name);
ret = func(path, ent->d_name);
}
closedir(dir);
return ret;
}
/*
* Call an arbitrary function for each device of the given bus type
* Returns 0 on success (all calls returned 0), a positive errno for
* local errors, or a negative error value if any call fails.
*/
static int sysfs_foreach_busdev(const char *bus_type,
int (*func)(const char *, const char *))
{
char path[NAME_MAX];
int path_off, ret;
DIR *dir;
struct dirent *ent;
path_off = snprintf(path, NAME_MAX, "%s/bus/%s/devices",
sensors_sysfs_mount, bus_type);
if (!(dir = opendir(path)))
return errno;
ret = 0;
while (!ret && (ent = readdir(dir))) {
if (ent->d_name[0] == '.') /* skip hidden entries */
continue;
snprintf(path + path_off, NAME_MAX - path_off, "/%s",
ent->d_name);
ret = func(path, ent->d_name);
}
closedir(dir);
return ret;
}
/****************************************************************************/
char sensors_sysfs_mount[NAME_MAX];
static
int get_type_scaling(sensors_subfeature_type type)
{
/* Multipliers for subfeatures */
switch (type & 0xFF80) {
case SENSORS_SUBFEATURE_IN_INPUT:
case SENSORS_SUBFEATURE_TEMP_INPUT:
case SENSORS_SUBFEATURE_CURR_INPUT:
case SENSORS_SUBFEATURE_HUMIDITY_INPUT:
return 1000;
case SENSORS_SUBFEATURE_FAN_INPUT:
return 1;
case SENSORS_SUBFEATURE_POWER_AVERAGE:
case SENSORS_SUBFEATURE_ENERGY_INPUT:
return 1000000;
}
/* Multipliers for second class subfeatures
that need their own multiplier */
switch (type) {
case SENSORS_SUBFEATURE_POWER_AVERAGE_INTERVAL:
case SENSORS_SUBFEATURE_VID:
case SENSORS_SUBFEATURE_TEMP_OFFSET:
return 1000;
default:
return 1;
}
}
static
char *get_feature_name(sensors_feature_type ftype, char *sfname)
{
char *name, *underscore;
switch (ftype) {
case SENSORS_FEATURE_IN:
case SENSORS_FEATURE_FAN:
case SENSORS_FEATURE_TEMP:
case SENSORS_FEATURE_POWER:
case SENSORS_FEATURE_ENERGY:
case SENSORS_FEATURE_CURR:
case SENSORS_FEATURE_HUMIDITY:
case SENSORS_FEATURE_INTRUSION:
underscore = strchr(sfname, '_');
name = strndup(sfname, underscore - sfname);
if (!name)
sensors_fatal_error(__func__, "Out of memory");
break;
default:
name = strdup(sfname);
if (!name)
sensors_fatal_error(__func__, "Out of memory");
}
return name;
}
/* Static mappings for use by sensors_subfeature_get_type() */
struct subfeature_type_match
{
const char *name;
sensors_subfeature_type type;
};
struct feature_type_match
{
const char *name;
const struct subfeature_type_match *submatches;
};
static const struct subfeature_type_match temp_matches[] = {
{ "input", SENSORS_SUBFEATURE_TEMP_INPUT },
{ "max", SENSORS_SUBFEATURE_TEMP_MAX },
{ "max_hyst", SENSORS_SUBFEATURE_TEMP_MAX_HYST },
{ "min", SENSORS_SUBFEATURE_TEMP_MIN },
{ "min_hyst", SENSORS_SUBFEATURE_TEMP_MIN_HYST },
{ "crit", SENSORS_SUBFEATURE_TEMP_CRIT },
{ "crit_hyst", SENSORS_SUBFEATURE_TEMP_CRIT_HYST },
{ "lcrit", SENSORS_SUBFEATURE_TEMP_LCRIT },
{ "lcrit_hyst", SENSORS_SUBFEATURE_TEMP_LCRIT_HYST },
{ "emergency", SENSORS_SUBFEATURE_TEMP_EMERGENCY },
{ "emergency_hyst", SENSORS_SUBFEATURE_TEMP_EMERGENCY_HYST },
{ "lowest", SENSORS_SUBFEATURE_TEMP_LOWEST },
{ "highest", SENSORS_SUBFEATURE_TEMP_HIGHEST },
{ "alarm", SENSORS_SUBFEATURE_TEMP_ALARM },
{ "min_alarm", SENSORS_SUBFEATURE_TEMP_MIN_ALARM },
{ "max_alarm", SENSORS_SUBFEATURE_TEMP_MAX_ALARM },
{ "crit_alarm", SENSORS_SUBFEATURE_TEMP_CRIT_ALARM },
{ "emergency_alarm", SENSORS_SUBFEATURE_TEMP_EMERGENCY_ALARM },
{ "lcrit_alarm", SENSORS_SUBFEATURE_TEMP_LCRIT_ALARM },
{ "fault", SENSORS_SUBFEATURE_TEMP_FAULT },
{ "type", SENSORS_SUBFEATURE_TEMP_TYPE },
{ "offset", SENSORS_SUBFEATURE_TEMP_OFFSET },
{ "beep", SENSORS_SUBFEATURE_TEMP_BEEP },
{ NULL, 0 }
};
static const struct subfeature_type_match in_matches[] = {
{ "input", SENSORS_SUBFEATURE_IN_INPUT },
{ "min", SENSORS_SUBFEATURE_IN_MIN },
{ "max", SENSORS_SUBFEATURE_IN_MAX },
{ "lcrit", SENSORS_SUBFEATURE_IN_LCRIT },
{ "crit", SENSORS_SUBFEATURE_IN_CRIT },
{ "average", SENSORS_SUBFEATURE_IN_AVERAGE },
{ "lowest", SENSORS_SUBFEATURE_IN_LOWEST },
{ "highest", SENSORS_SUBFEATURE_IN_HIGHEST },
{ "alarm", SENSORS_SUBFEATURE_IN_ALARM },
{ "min_alarm", SENSORS_SUBFEATURE_IN_MIN_ALARM },
{ "max_alarm", SENSORS_SUBFEATURE_IN_MAX_ALARM },
{ "lcrit_alarm", SENSORS_SUBFEATURE_IN_LCRIT_ALARM },
{ "crit_alarm", SENSORS_SUBFEATURE_IN_CRIT_ALARM },
{ "beep", SENSORS_SUBFEATURE_IN_BEEP },
{ NULL, 0 }
};
static const struct subfeature_type_match fan_matches[] = {
{ "input", SENSORS_SUBFEATURE_FAN_INPUT },
{ "min", SENSORS_SUBFEATURE_FAN_MIN },
{ "max", SENSORS_SUBFEATURE_FAN_MAX },
{ "div", SENSORS_SUBFEATURE_FAN_DIV },
{ "pulses", SENSORS_SUBFEATURE_FAN_PULSES },
{ "alarm", SENSORS_SUBFEATURE_FAN_ALARM },
{ "min_alarm", SENSORS_SUBFEATURE_FAN_MIN_ALARM },
{ "max_alarm", SENSORS_SUBFEATURE_FAN_MAX_ALARM },
{ "fault", SENSORS_SUBFEATURE_FAN_FAULT },
{ "beep", SENSORS_SUBFEATURE_FAN_BEEP },
{ NULL, 0 }
};
static const struct subfeature_type_match power_matches[] = {
{ "average", SENSORS_SUBFEATURE_POWER_AVERAGE },
{ "average_highest", SENSORS_SUBFEATURE_POWER_AVERAGE_HIGHEST },
{ "average_lowest", SENSORS_SUBFEATURE_POWER_AVERAGE_LOWEST },
{ "input", SENSORS_SUBFEATURE_POWER_INPUT },
{ "input_highest", SENSORS_SUBFEATURE_POWER_INPUT_HIGHEST },
{ "input_lowest", SENSORS_SUBFEATURE_POWER_INPUT_LOWEST },
{ "cap", SENSORS_SUBFEATURE_POWER_CAP },
{ "cap_hyst", SENSORS_SUBFEATURE_POWER_CAP_HYST },
{ "cap_alarm", SENSORS_SUBFEATURE_POWER_CAP_ALARM },
{ "alarm", SENSORS_SUBFEATURE_POWER_ALARM },
{ "max", SENSORS_SUBFEATURE_POWER_MAX },
{ "max_alarm", SENSORS_SUBFEATURE_POWER_MAX_ALARM },
{ "crit", SENSORS_SUBFEATURE_POWER_CRIT },
{ "crit_alarm", SENSORS_SUBFEATURE_POWER_CRIT_ALARM },
{ "average_interval", SENSORS_SUBFEATURE_POWER_AVERAGE_INTERVAL },
{ NULL, 0 }
};
static const struct subfeature_type_match energy_matches[] = {
{ "input", SENSORS_SUBFEATURE_ENERGY_INPUT },
{ NULL, 0 }
};
static const struct subfeature_type_match curr_matches[] = {
{ "input", SENSORS_SUBFEATURE_CURR_INPUT },
{ "min", SENSORS_SUBFEATURE_CURR_MIN },
{ "max", SENSORS_SUBFEATURE_CURR_MAX },
{ "lcrit", SENSORS_SUBFEATURE_CURR_LCRIT },
{ "crit", SENSORS_SUBFEATURE_CURR_CRIT },
{ "average", SENSORS_SUBFEATURE_CURR_AVERAGE },
{ "lowest", SENSORS_SUBFEATURE_CURR_LOWEST },
{ "highest", SENSORS_SUBFEATURE_CURR_HIGHEST },
{ "alarm", SENSORS_SUBFEATURE_CURR_ALARM },
{ "min_alarm", SENSORS_SUBFEATURE_CURR_MIN_ALARM },
{ "max_alarm", SENSORS_SUBFEATURE_CURR_MAX_ALARM },
{ "lcrit_alarm", SENSORS_SUBFEATURE_CURR_LCRIT_ALARM },
{ "crit_alarm", SENSORS_SUBFEATURE_CURR_CRIT_ALARM },
{ "beep", SENSORS_SUBFEATURE_CURR_BEEP },
{ NULL, 0 }
};
static const struct subfeature_type_match humidity_matches[] = {
{ "input", SENSORS_SUBFEATURE_HUMIDITY_INPUT },
{ NULL, 0 }
};
static const struct subfeature_type_match cpu_matches[] = {
{ "vid", SENSORS_SUBFEATURE_VID },
{ NULL, 0 }
};
static const struct subfeature_type_match intrusion_matches[] = {
{ "alarm", SENSORS_SUBFEATURE_INTRUSION_ALARM },
{ "beep", SENSORS_SUBFEATURE_INTRUSION_BEEP },
{ NULL, 0 }
};
static struct feature_type_match matches[] = {
{ "temp%d%c", temp_matches },
{ "in%d%c", in_matches },
{ "fan%d%c", fan_matches },
{ "cpu%d%c", cpu_matches },
{ "power%d%c", power_matches },
{ "curr%d%c", curr_matches },
{ "energy%d%c", energy_matches },
{ "intrusion%d%c", intrusion_matches },
{ "humidity%d%c", humidity_matches },
};
/* Return the subfeature type and channel number based on the subfeature
name */
static
sensors_subfeature_type sensors_subfeature_get_type(const char *name, int *nr)
{
char c;
int i, count;
const struct subfeature_type_match *submatches;
/* Special case */
if (!strcmp(name, "beep_enable")) {
*nr = 0;
return SENSORS_SUBFEATURE_BEEP_ENABLE;
}
for (i = 0; i < ARRAY_SIZE(matches); i++)
if ((count = sscanf(name, matches[i].name, nr, &c)))
break;
if (i == ARRAY_SIZE(matches) || count != 2 || c != '_')
return SENSORS_SUBFEATURE_UNKNOWN; /* no match */
submatches = matches[i].submatches;
name = strchr(name + 3, '_') + 1;
for (i = 0; submatches[i].name != NULL; i++)
if (!strcmp(name, submatches[i].name))
return submatches[i].type;
return SENSORS_SUBFEATURE_UNKNOWN;
}
static int sensors_compute_max_sf(void)
{
int i, j, max, offset;
const struct subfeature_type_match *submatches;
sensors_feature_type ftype;
max = 0;
for (i = 0; i < ARRAY_SIZE(matches); i++) {
submatches = matches[i].submatches;
for (j = 0; submatches[j].name != NULL; j++) {
ftype = submatches[j].type >> 8;
if (ftype < SENSORS_FEATURE_VID) {
offset = submatches[j].type & 0x7F;
if (offset >= max)
max = offset + 1;
} else {
offset = submatches[j].type & 0xFF;
if (offset >= max * 2)
max = ((offset + 1) + 1) / 2;
}
}
}
return max;
}
static int sensors_get_attr_mode(const char *device, const char *attr)
{
char path[NAME_MAX];
struct stat st;
int mode = 0;
snprintf(path, NAME_MAX, "%s/%s", device, attr);
if (!stat(path, &st)) {
if (st.st_mode & S_IRUSR)
mode |= SENSORS_MODE_R;
if (st.st_mode & S_IWUSR)
mode |= SENSORS_MODE_W;
}
return mode;
}
static int sensors_read_dynamic_chip(sensors_chip_features *chip,
const char *dev_path)
{
int i, fnum = 0, sfnum = 0, prev_slot;
static int max_subfeatures, feature_size;
DIR *dir;
struct dirent *ent;
struct {
int count;
sensors_subfeature *sf;
} all_types[SENSORS_FEATURE_MAX];
sensors_subfeature *dyn_subfeatures;
sensors_feature *dyn_features;
sensors_feature_type ftype;
sensors_subfeature_type sftype;
if (!(dir = opendir(dev_path)))
return -errno;
/* Dynamically figure out the max number of subfeatures */
if (!max_subfeatures) {
max_subfeatures = sensors_compute_max_sf();
feature_size = max_subfeatures * 2;
}
/* We use a set of large sparse tables at first (one per main
feature type present) to store all found subfeatures, so that we
can store them sorted and then later create a dense sorted table. */
memset(&all_types, 0, sizeof(all_types));
while ((ent = readdir(dir))) {
char *name;
int nr;
/* Skip directories and symlinks */
if (ent->d_type != DT_REG)
continue;
name = ent->d_name;
sftype = sensors_subfeature_get_type(name, &nr);
if (sftype == SENSORS_SUBFEATURE_UNKNOWN)
continue;
ftype = sftype >> 8;
/* Adjust the channel number */
switch (ftype) {
case SENSORS_FEATURE_FAN:
case SENSORS_FEATURE_TEMP:
case SENSORS_FEATURE_POWER:
case SENSORS_FEATURE_ENERGY:
case SENSORS_FEATURE_CURR:
case SENSORS_FEATURE_HUMIDITY:
nr--;
break;
default:
break;
}
/* Skip invalid entries. The high limit is arbitrary, we just
don't want to allocate an insane amount of memory. */
if (nr < 0 || nr >= 1024) {
#ifdef DEBUG
sensors_fatal_error(__func__,
"Invalid channel number!");
#endif
continue;
}
/* (Re-)allocate memory if needed */
if (all_types[ftype].count < nr + 1) {
int old_count = all_types[ftype].count;
int step = ftype < SENSORS_FEATURE_VID ? 8 :
ftype < SENSORS_FEATURE_BEEP_ENABLE ? 2 : 1;
while (all_types[ftype].count < nr + 1)
all_types[ftype].count += step;
all_types[ftype].sf = realloc(all_types[ftype].sf,
all_types[ftype].count *
feature_size *
sizeof(sensors_subfeature));
if (!all_types[ftype].sf)
sensors_fatal_error(__func__, "Out of memory");
memset(all_types[ftype].sf + old_count * feature_size,
0, (all_types[ftype].count - old_count) *
feature_size * sizeof(sensors_subfeature));
}
/* "calculate" a place to store the subfeature in our sparse,
sorted table */
if (ftype < SENSORS_FEATURE_VID)
i = nr * feature_size +
((sftype & 0x80) >> 7) * max_subfeatures +
(sftype & 0x7F);
else
i = nr * feature_size + (sftype & 0xFF);
if (all_types[ftype].sf[i].name) {
#ifdef DEBUG
sensors_fatal_error(__func__, "Duplicate subfeature");
#endif
continue;
}
/* fill in the subfeature members */
all_types[ftype].sf[i].type = sftype;
all_types[ftype].sf[i].name = strdup(name);
if (!all_types[ftype].sf[i].name)
sensors_fatal_error(__func__, "Out of memory");
/* Other and misc subfeatures are never scaled */
if (sftype < SENSORS_SUBFEATURE_VID && !(sftype & 0x80))
all_types[ftype].sf[i].flags |= SENSORS_COMPUTE_MAPPING;
all_types[ftype].sf[i].flags |=
sensors_get_attr_mode(dev_path, name);
sfnum++;
}
closedir(dir);
if (!sfnum) { /* No subfeature */
chip->subfeature = NULL;
goto exit_free;
}
/* How many main features? */
for (ftype = 0; ftype < SENSORS_FEATURE_MAX; ftype++) {
prev_slot = -1;
for (i = 0; i < all_types[ftype].count * feature_size; i++) {
if (!all_types[ftype].sf[i].name)
continue;
if (i / feature_size != prev_slot) {
fnum++;
prev_slot = i / feature_size;
}
}
}
dyn_subfeatures = calloc(sfnum, sizeof(sensors_subfeature));
dyn_features = calloc(fnum, sizeof(sensors_feature));
if (!dyn_subfeatures || !dyn_features)
sensors_fatal_error(__func__, "Out of memory");
/* Copy from the sparse array to the compact array */
sfnum = 0;
fnum = -1;
for (ftype = 0; ftype < SENSORS_FEATURE_MAX; ftype++) {
prev_slot = -1;
for (i = 0; i < all_types[ftype].count * feature_size; i++) {
if (!all_types[ftype].sf[i].name)
continue;
/* New main feature? */
if (i / feature_size != prev_slot) {
fnum++;
prev_slot = i / feature_size;
dyn_features[fnum].name =
get_feature_name(ftype,
all_types[ftype].sf[i].name);
dyn_features[fnum].number = fnum;
dyn_features[fnum].first_subfeature = sfnum;
dyn_features[fnum].type = ftype;
}
dyn_subfeatures[sfnum] = all_types[ftype].sf[i];
dyn_subfeatures[sfnum].number = sfnum;
/* Back to the feature */
dyn_subfeatures[sfnum].mapping = fnum;
sfnum++;
}
}
chip->subfeature = dyn_subfeatures;
chip->subfeature_count = sfnum;
chip->feature = dyn_features;
chip->feature_count = ++fnum;
exit_free:
for (ftype = 0; ftype < SENSORS_FEATURE_MAX; ftype++)
free(all_types[ftype].sf);
return 0;
}
/* returns !0 if sysfs filesystem was found, 0 otherwise */
int sensors_init_sysfs(void)
{
struct statfs statfsbuf;
snprintf(sensors_sysfs_mount, NAME_MAX, "%s", "/sys");
if (statfs(sensors_sysfs_mount, &statfsbuf) < 0
|| statfsbuf.f_type != SYSFS_MAGIC)
return 0;
return 1;
}
/* returns: number of devices added (0 or 1) if successful, <0 otherwise */
static int sensors_read_one_sysfs_chip(const char *dev_path,
const char *dev_name,
const char *hwmon_path)
{
int domain, bus, slot, fn, vendor, product, id;
int err = -SENSORS_ERR_KERNEL;
char *bus_attr;
char bus_path[NAME_MAX];
char linkpath[NAME_MAX];
char subsys_path[NAME_MAX], *subsys;
int sub_len;
sensors_chip_features entry;
/* ignore any device without name attribute */
if (!(entry.chip.prefix = sysfs_read_attr(hwmon_path, "name")))
return 0;
entry.chip.path = strdup(hwmon_path);
if (!entry.chip.path)
sensors_fatal_error(__func__, "Out of memory");
if (dev_path == NULL) {
/* Virtual device */
entry.chip.bus.type = SENSORS_BUS_TYPE_VIRTUAL;
entry.chip.bus.nr = 0;
/* For now we assume that virtual devices are unique */
entry.chip.addr = 0;
goto done;
}
/* Find bus type */
snprintf(linkpath, NAME_MAX, "%s/subsystem", dev_path);
sub_len = readlink(linkpath, subsys_path, NAME_MAX - 1);
if (sub_len < 0 && errno == ENOENT) {
/* Fallback to "bus" link for kernels <= 2.6.17 */
snprintf(linkpath, NAME_MAX, "%s/bus", dev_path);
sub_len = readlink(linkpath, subsys_path, NAME_MAX - 1);
}
if (sub_len < 0) {
/* Older kernels (<= 2.6.11) have neither the subsystem
symlink nor the bus symlink */
if (errno == ENOENT)
subsys = NULL;
else
goto exit_free;
} else {
subsys_path[sub_len] = '\0';
subsys = strrchr(subsys_path, '/') + 1;
}
if ((!subsys || !strcmp(subsys, "i2c")) &&
sscanf(dev_name, "%hd-%x", &entry.chip.bus.nr,
&entry.chip.addr) == 2) {
/* find out if legacy ISA or not */
if (entry.chip.bus.nr == 9191) {
entry.chip.bus.type = SENSORS_BUS_TYPE_ISA;
entry.chip.bus.nr = 0;
} else {
entry.chip.bus.type = SENSORS_BUS_TYPE_I2C;
snprintf(bus_path, sizeof(bus_path),
"%s/class/i2c-adapter/i2c-%d/device",
sensors_sysfs_mount, entry.chip.bus.nr);
if ((bus_attr = sysfs_read_attr(bus_path, "name"))) {
if (!strncmp(bus_attr, "ISA ", 4)) {
entry.chip.bus.type = SENSORS_BUS_TYPE_ISA;
entry.chip.bus.nr = 0;
}
free(bus_attr);
}
}
} else
if ((!subsys || !strcmp(subsys, "spi")) &&
sscanf(dev_name, "spi%hd.%d", &entry.chip.bus.nr,
&entry.chip.addr) == 2) {
/* SPI */
entry.chip.bus.type = SENSORS_BUS_TYPE_SPI;
} else
if ((!subsys || !strcmp(subsys, "pci")) &&
sscanf(dev_name, "%x:%x:%x.%x", &domain, &bus, &slot, &fn) == 4) {
/* PCI */
entry.chip.addr = (domain << 16) + (bus << 8) + (slot << 3) + fn;
entry.chip.bus.type = SENSORS_BUS_TYPE_PCI;
entry.chip.bus.nr = 0;
} else
if ((!subsys || !strcmp(subsys, "platform") ||
!strcmp(subsys, "of_platform"))) {
/* must be new ISA (platform driver) */
if (sscanf(dev_name, "%*[a-z0-9_].%d", &entry.chip.addr) != 1)
entry.chip.addr = 0;
entry.chip.bus.type = SENSORS_BUS_TYPE_ISA;
entry.chip.bus.nr = 0;
} else if (subsys && !strcmp(subsys, "acpi")) {
entry.chip.bus.type = SENSORS_BUS_TYPE_ACPI;
/* For now we assume that acpi devices are unique */
entry.chip.bus.nr = 0;
entry.chip.addr = 0;
} else
if (subsys && !strcmp(subsys, "hid") &&
sscanf(dev_name, "%x:%x:%x.%x", &bus, &vendor, &product, &id) == 4) {
entry.chip.bus.type = SENSORS_BUS_TYPE_HID;
/* As of kernel 2.6.32, the hid device names don't look good */
entry.chip.bus.nr = bus;
entry.chip.addr = id;
} else
if (subsys && !strcmp(subsys, "mdio_bus")) {
if (sscanf(dev_name, "%*[^:]:%d", &entry.chip.addr) != 1)
entry.chip.addr = 0;
entry.chip.bus.type = SENSORS_BUS_TYPE_MDIO;
entry.chip.bus.nr = 0;
} else {
/* Ignore unknown device */
err = 0;
goto exit_free;
}
done:
if (sensors_read_dynamic_chip(&entry, hwmon_path) < 0)
goto exit_free;
if (!entry.subfeature) { /* No subfeature, discard chip */
err = 0;
goto exit_free;
}
sensors_add_proc_chips(&entry);
return 1;
exit_free:
free(entry.chip.prefix);
free(entry.chip.path);
return err;
}
static int sensors_add_hwmon_device_compat(const char *path,
const char *dev_name)
{
int err;
err = sensors_read_one_sysfs_chip(path, dev_name, path);
if (err < 0)
return err;
return 0;
}
/* returns 0 if successful, !0 otherwise */
static int sensors_read_sysfs_chips_compat(void)
{
int ret;
ret = sysfs_foreach_busdev("i2c", sensors_add_hwmon_device_compat);
if (ret && ret != ENOENT)
return -SENSORS_ERR_KERNEL;
return 0;
}
static int sensors_add_hwmon_device(const char *path, const char *classdev)
{
char linkpath[NAME_MAX];
char device[NAME_MAX], *device_p;
int dev_len, err;
(void)classdev; /* hide warning */
snprintf(linkpath, NAME_MAX, "%s/device", path);
dev_len = readlink(linkpath, device, NAME_MAX - 1);
if (dev_len < 0) {
/* No device link? Treat as virtual */
err = sensors_read_one_sysfs_chip(NULL, NULL, path);
} else {
device[dev_len] = '\0';
device_p = strrchr(device, '/') + 1;
/* The attributes we want might be those of the hwmon class
device, or those of the device itself. */
err = sensors_read_one_sysfs_chip(linkpath, device_p, path);
if (err == 0)
err = sensors_read_one_sysfs_chip(linkpath, device_p,
linkpath);
}
if (err < 0)
return err;
return 0;
}
/* returns 0 if successful, !0 otherwise */
int sensors_read_sysfs_chips(void)
{
int ret;
ret = sysfs_foreach_classdev("hwmon", sensors_add_hwmon_device);
if (ret == ENOENT) {
/* compatibility function for kernel 2.6.n where n <= 13 */
return sensors_read_sysfs_chips_compat();
}
if (ret > 0)
ret = -SENSORS_ERR_KERNEL;
return ret;
}
/* returns 0 if successful, !0 otherwise */
static int sensors_add_i2c_bus(const char *path, const char *classdev)
{
sensors_bus entry;
if (sscanf(classdev, "i2c-%hd", &entry.bus.nr) != 1 ||
entry.bus.nr == 9191) /* legacy ISA */
return 0;
entry.bus.type = SENSORS_BUS_TYPE_I2C;
/* Get the adapter name from the classdev "name" attribute
* (Linux 2.6.20 and later). If it fails, fall back to
* the device "name" attribute (for older kernels). */
entry.adapter = sysfs_read_attr(path, "name");
if (!entry.adapter)
entry.adapter = sysfs_read_attr(path, "device/name");
if (entry.adapter)
sensors_add_proc_bus(&entry);
return 0;
}
/* returns 0 if successful, !0 otherwise */
int sensors_read_sysfs_bus(void)
{
int ret;
ret = sysfs_foreach_classdev("i2c-adapter", sensors_add_i2c_bus);
if (ret == ENOENT)
ret = sysfs_foreach_busdev("i2c", sensors_add_i2c_bus);
if (ret && ret != ENOENT)
return -SENSORS_ERR_KERNEL;
return 0;
}
int sensors_read_sysfs_attr(const sensors_chip_name *name,
const sensors_subfeature *subfeature,
double *value)
{
char n[NAME_MAX];
FILE *f;
snprintf(n, NAME_MAX, "%s/%s", name->path, subfeature->name);
if ((f = fopen(n, "r"))) {
int res, err = 0;
errno = 0;
res = fscanf(f, "%lf", value);
if (res == EOF && errno == EIO)
err = -SENSORS_ERR_IO;
else if (res != 1)
err = -SENSORS_ERR_ACCESS_R;
res = fclose(f);
if (err)
return err;
if (res == EOF) {
if (errno == EIO)
return -SENSORS_ERR_IO;
else
return -SENSORS_ERR_ACCESS_R;
}
*value /= get_type_scaling(subfeature->type);
} else
return -SENSORS_ERR_KERNEL;
return 0;
}
int sensors_write_sysfs_attr(const sensors_chip_name *name,
const sensors_subfeature *subfeature,
double value)
{
char n[NAME_MAX];
FILE *f;
snprintf(n, NAME_MAX, "%s/%s", name->path, subfeature->name);
if ((f = fopen(n, "w"))) {
int res, err = 0;
value *= get_type_scaling(subfeature->type);
res = fprintf(f, "%d", (int) value);
if (res == -EIO)
err = -SENSORS_ERR_IO;
else if (res < 0)
err = -SENSORS_ERR_ACCESS_W;
res = fclose(f);
if (err)
return err;
if (res == EOF) {
if (errno == EIO)
return -SENSORS_ERR_IO;
else
return -SENSORS_ERR_ACCESS_W;
}
} else
return -SENSORS_ERR_KERNEL;
return 0;
}