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a62ee5bac22e4d6c0050d4d8872e26fc63e83b04
lm-sensors/lib/access.c
Jean Delvare a62ee5bac2 Speed up sensors_get_ignored() a bit. We can return as soon as an ignore 
statement is found to match, even if it isn't an exact match.


git-svn-id: http://lm-sensors.org/svn/lm-sensors/branches/lm-sensors-3.0.0@4642 7894878c-1315-0410-8ee3-d5d059ff63e0
2007-07-22 12:51:57 +00:00

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/*
access.c - Part of libsensors, a Linux library for reading sensor data.
Copyright (c) 1998, 1999 Frodo Looijaard <frodol@dds.nl>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program 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 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., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include "access.h"
#include "sensors.h"
#include "data.h"
#include "error.h"
#include "sysfs.h"
#include "general.h"
static int sensors_eval_expr(sensors_chip_name chipname,
const sensors_expr *expr,
double val, double *result);
/* Compare two chips name descriptions, to see whether they could match.
Return 0 if it does not match, return 1 if it does match. */
int sensors_match_chip(sensors_chip_name chip1, sensors_chip_name chip2)
{
if ((chip1.prefix != SENSORS_CHIP_NAME_PREFIX_ANY) &&
(chip2.prefix != SENSORS_CHIP_NAME_PREFIX_ANY) &&
strcasecmp(chip1.prefix, chip2.prefix))
return 0;
if ((chip1.bus != SENSORS_CHIP_NAME_BUS_ANY) &&
(chip2.bus != SENSORS_CHIP_NAME_BUS_ANY) &&
(chip1.bus != chip2.bus)) {
if ((chip1.bus == SENSORS_CHIP_NAME_BUS_ISA) ||
(chip2.bus == SENSORS_CHIP_NAME_BUS_ISA))
return 0;
if ((chip1.bus == SENSORS_CHIP_NAME_BUS_PCI) ||
(chip2.bus == SENSORS_CHIP_NAME_BUS_PCI))
return 0;
if ((chip1.bus != SENSORS_CHIP_NAME_BUS_ANY_I2C) &&
(chip2.bus != SENSORS_CHIP_NAME_BUS_ANY_I2C))
return 0;
}
if ((chip1.addr != chip2.addr) &&
(chip1.addr != SENSORS_CHIP_NAME_ADDR_ANY) &&
(chip2.addr != SENSORS_CHIP_NAME_ADDR_ANY))
return 0;
return 1;
}
/* Returns, one by one, a pointer to all sensor_chip structs of the
config file which match with the given chip name. Last should be
the value returned by the last call, or NULL if this is the first
call. Returns NULL if no more matches are found. Do not modify
the struct the return value points to!
Note that this visits the list of chips from last to first. Usually,
you want the match that was latest in the config file. */
static sensors_chip *
sensors_for_all_config_chips(sensors_chip_name chip_name,
const sensors_chip *last)
{
int nr, i;
sensors_chip_name_list chips;
for (nr = last ? last - sensors_config_chips - 1 :
sensors_config_chips_count - 1; nr >= 0; nr--) {
chips = sensors_config_chips[nr].chips;
for (i = 0; i < chips.fits_count; i++) {
if (sensors_match_chip(chips.fits[i], chip_name))
return sensors_config_chips + nr;
}
}
return NULL;
}
/* Look up a resource in the intern chip list, and return a pointer to it.
Do not modify the struct the return value points to! Returns NULL if
not found.*/
const sensors_chip_feature *sensors_lookup_feature_nr(const sensors_chip_name *chip,
int feature)
{
int i, j;
const sensors_chip_feature *features;
for (i = 0; i < sensors_proc_chips_count; i++)
if (sensors_match_chip(sensors_proc_chips[i].chip, *chip)) {
features = sensors_proc_chips[i].feature;
for (j = 0; features[j].data.name; j++)
if (features[j].data.number == feature)
return features + j;
}
return NULL;
}
/* Look up a resource in the intern chip list, and return a pointer to it.
Do not modify the struct the return value points to! Returns NULL if
not found.*/
static const sensors_chip_feature *
sensors_lookup_feature_name(const sensors_chip_name *chip, const char *feature)
{
int i, j;
const sensors_chip_feature *features;
for (i = 0; i < sensors_proc_chips_count; i++)
if (sensors_match_chip(sensors_proc_chips[i].chip, *chip)) {
features = sensors_proc_chips[i].feature;
for (j = 0; features[j].data.name; j++)
if (!strcasecmp(features[j].data.name, feature))
return features + j;
}
return NULL;
}
/* Check whether the chip name is an 'absolute' name, which can only match
one chip, or whether it has wildcards. Returns 0 if it is absolute, 1
if there are wildcards. */
int sensors_chip_name_has_wildcards(sensors_chip_name chip)
{
if ((chip.prefix == SENSORS_CHIP_NAME_PREFIX_ANY) ||
(chip.bus == SENSORS_CHIP_NAME_BUS_ANY) ||
(chip.bus == SENSORS_CHIP_NAME_BUS_ANY_I2C) ||
(chip.addr == SENSORS_CHIP_NAME_ADDR_ANY))
return 1;
else
return 0;
}
/* Look up the label which belongs to this chip. Note that chip should not
contain wildcard values! *result is newly allocated (free it yourself).
This function will return 0 on success, and <0 on failure.
If no label exists for this feature, its name is returned itself. */
int sensors_get_label(sensors_chip_name name, int feature, char **result)
{
const sensors_chip *chip;
const sensors_chip_feature *featureptr;
char buf[128], path[PATH_MAX];
FILE *f;
int i;
*result = NULL;
if (sensors_chip_name_has_wildcards(name))
return -SENSORS_ERR_WILDCARDS;
if (!(featureptr = sensors_lookup_feature_nr(&name, feature)))
return -SENSORS_ERR_NO_ENTRY;
for (chip = NULL; (chip = sensors_for_all_config_chips(name, chip));)
for (i = 0; i < chip->labels_count; i++)
if (!strcasecmp(featureptr->data.name,chip->labels[i].name)){
*result = strdup(chip->labels[i].value);
goto sensors_get_label_exit;
}
/* No user specified label, check for a _label sysfs file */
snprintf(path, PATH_MAX, "%s/%s_label", name.busname,
featureptr->data.name);
if ((f = fopen(path, "r"))) {
i = fread(buf, 1, sizeof(buf) - 1, f);
fclose(f);
if (i > 0) {
/* i - 1 to strip the '\n' at the end */
buf[i - 1] = 0;
*result = strdup(buf);
goto sensors_get_label_exit;
}
}
/* No label, return the feature name instead */
*result = strdup(featureptr->data.name);
sensors_get_label_exit:
if (*result == NULL)
sensors_fatal_error("sensors_get_label",
"Allocating label text");
return 0;
}
int sensors_get_ignored(sensors_chip_name name, int feature)
{
const sensors_chip *chip;
const sensors_chip_feature *featureptr;
const sensors_chip_feature *alt_featureptr;
int i;
if (sensors_chip_name_has_wildcards(name))
return -SENSORS_ERR_WILDCARDS;
if (!(featureptr = sensors_lookup_feature_nr(&name, feature)))
return -SENSORS_ERR_NO_ENTRY;
if (featureptr->data.mapping == SENSORS_NO_MAPPING)
alt_featureptr = NULL;
else if (!(alt_featureptr =
sensors_lookup_feature_nr(&name,
featureptr->data.mapping)))
return -SENSORS_ERR_NO_ENTRY;
for (chip = NULL; (chip = sensors_for_all_config_chips(name, chip));)
for (i = 0; i < chip->ignores_count; i++)
if (!strcasecmp(featureptr->data.name, chip->ignores[i].name) ||
(alt_featureptr &&
!strcasecmp(alt_featureptr->data.name, chip->ignores[i].name)))
return 0;
/* valid */
return 1;
}
/* Read the value of a feature of a certain chip. Note that chip should not
contain wildcard values! This function will return 0 on success, and <0
on failure. */
int sensors_get_feature(sensors_chip_name name, int feature, double *result)
{
const sensors_chip_feature *main_feature;
const sensors_chip_feature *alt_feature;
const sensors_chip *chip;
const sensors_expr *expr = NULL;
double val;
int res, i;
int final_expr = 0;
if (sensors_chip_name_has_wildcards(name))
return -SENSORS_ERR_WILDCARDS;
if (!(main_feature = sensors_lookup_feature_nr(&name, feature)))
return -SENSORS_ERR_NO_ENTRY;
if (main_feature->data.compute_mapping == SENSORS_NO_MAPPING)
alt_feature = NULL;
else if (!(alt_feature = sensors_lookup_feature_nr(&name,
main_feature->data.compute_mapping)))
return -SENSORS_ERR_NO_ENTRY;
if (!(main_feature->data.mode & SENSORS_MODE_R))
return -SENSORS_ERR_ACCESS_R;
for (chip = NULL;
!expr && (chip = sensors_for_all_config_chips(name, chip));)
for (i = 0; !final_expr && (i < chip->computes_count); i++) {
if (!strcasecmp(main_feature->data.name, chip->computes[i].name)) {
expr = chip->computes[i].from_proc;
final_expr = 1;
} else if (alt_feature && !strcasecmp(alt_feature->data.name,
chip->computes[i].name)) {
expr = chip->computes[i].from_proc;
}
}
if (sensors_read_sysfs_attr(name, feature, &val))
return -SENSORS_ERR_PROC;
if (!expr)
*result = val;
else if ((res = sensors_eval_expr(name, expr, val, result)))
return res;
return 0;
}
/* Set the value of a feature of a certain chip. Note that chip should not
contain wildcard values! This function will return 0 on success, and <0
on failure. */
int sensors_set_feature(sensors_chip_name name, int feature, double value)
{
const sensors_chip_feature *main_feature;
const sensors_chip_feature *alt_feature;
const sensors_chip *chip;
const sensors_expr *expr = NULL;
int i, res;
int final_expr = 0;
double to_write;
if (sensors_chip_name_has_wildcards(name))
return -SENSORS_ERR_WILDCARDS;
if (!(main_feature = sensors_lookup_feature_nr(&name, feature)))
return -SENSORS_ERR_NO_ENTRY;
if (main_feature->data.compute_mapping == SENSORS_NO_MAPPING)
alt_feature = NULL;
else if (!(alt_feature = sensors_lookup_feature_nr(&name,
main_feature->data.compute_mapping)))
return -SENSORS_ERR_NO_ENTRY;
if (!(main_feature->data.mode & SENSORS_MODE_W))
return -SENSORS_ERR_ACCESS_W;
for (chip = NULL;
!expr && (chip = sensors_for_all_config_chips(name, chip));)
for (i = 0; !final_expr && (i < chip->computes_count); i++)
if (!strcasecmp(main_feature->data.name, chip->computes[i].name)) {
expr = chip->computes->to_proc;
final_expr = 1;
} else if (alt_feature && !strcasecmp(alt_feature->data.name,
chip->computes[i].name)) {
expr = chip->computes[i].to_proc;
}
to_write = value;
if (expr)
if ((res = sensors_eval_expr(name, expr, value, &to_write)))
return res;
if (sensors_write_sysfs_attr(name, feature, to_write))
return -SENSORS_ERR_PROC;
return 0;
}
const sensors_chip_name *sensors_get_detected_chips(int *nr)
{
const sensors_chip_name *res;
res = (*nr >= sensors_proc_chips_count ?
NULL : &sensors_proc_chips[*nr].chip);
(*nr)++;
return res;
}
const char *sensors_get_adapter_name(int bus_nr)
{
int i;
if (bus_nr == SENSORS_CHIP_NAME_BUS_ISA)
return "ISA adapter";
if (bus_nr == SENSORS_CHIP_NAME_BUS_PCI)
return "PCI adapter";
if (bus_nr == SENSORS_CHIP_NAME_BUS_DUMMY)
return "Dummy adapter";
for (i = 0; i < sensors_proc_bus_count; i++)
if (sensors_proc_bus[i].number == bus_nr)
return sensors_proc_bus[i].adapter;
return NULL;
}
/* nr1-1 is the last main feature found; nr2-1 is the last subfeature found */
const sensors_feature_data *sensors_get_all_features(sensors_chip_name name,
int *nr1, int *nr2)
{
sensors_chip_feature *feature_list;
int i;
for (i = 0; i < sensors_proc_chips_count; i++)
if (sensors_match_chip(sensors_proc_chips[i].chip, name)) {
feature_list = sensors_proc_chips[i].feature;
if (!*nr1 && !*nr2) { /* Return the first entry */
*nr1 = *nr2 = 1;
return &feature_list->data;
}
for ((*nr2)++; feature_list[*nr2 - 1].data.name; (*nr2)++)
if (feature_list[*nr2 - 1].data.mapping ==
feature_list[*nr1 - 1].data.number)
return &((feature_list + *nr2 - 1)->data);
for ((*nr1)++;
feature_list[*nr1 - 1].data.name
&& (feature_list[*nr1 - 1].data.mapping !=
SENSORS_NO_MAPPING); (*nr1)++) ;
*nr2 = *nr1;
if (!feature_list[*nr1 - 1].data.name)
return NULL;
return &((feature_list + *nr1 - 1)->data);
}
return NULL;
}
/* Evaluate an expression */
int sensors_eval_expr(sensors_chip_name chipname, const sensors_expr * expr,
double val, double *result)
{
double res1, res2;
int res;
const sensors_chip_feature *feature;
if (expr->kind == sensors_kind_val) {
*result = expr->data.val;
return 0;
}
if (expr->kind == sensors_kind_source) {
*result = val;
return 0;
}
if (expr->kind == sensors_kind_var) {
if (!(feature = sensors_lookup_feature_name(&chipname,
expr->data.var)))
return SENSORS_ERR_NO_ENTRY;
if (!(res = sensors_get_feature(chipname, feature->data.number, result)))
return res;
return 0;
}
if ((res = sensors_eval_expr(chipname, expr->data.subexpr.sub1, val, &res1)))
return res;
if (expr->data.subexpr.sub2 &&
(res = sensors_eval_expr(chipname, expr->data.subexpr.sub2, val, &res2)))
return res;
switch (expr->data.subexpr.op) {
case sensors_add:
*result = res1 + res2;
return 0;
case sensors_sub:
*result = res1 - res2;
return 0;
case sensors_multiply:
*result = res1 * res2;
return 0;
case sensors_divide:
if (res2 == 0.0)
return -SENSORS_ERR_DIV_ZERO;
*result = res1 / res2;
return 0;
case sensors_negate:
*result = -res1;
return 0;
case sensors_exp:
*result = exp(res1);
return 0;
case sensors_log:
if (res1 < 0.0)
return -SENSORS_ERR_DIV_ZERO;
*result = log(res1);
return 0;
}
return 0;
}
/* Execute all set statements for this particular chip. The chip may not
contain wildcards! This function will return 0 on success, and <0 on
failure. */
static int sensors_do_this_chip_sets(sensors_chip_name name)
{
sensors_chip *chip;
double value;
int i, j;
int err = 0, res;
const sensors_chip_feature *feature;
int *feature_list = NULL;
int feature_count = 0;
int feature_max = 0;
int feature_nr;
for (chip = NULL; (chip = sensors_for_all_config_chips(name, chip));)
for (i = 0; i < chip->sets_count; i++) {
feature = sensors_lookup_feature_name(&name,
chip->sets[i].name);
if (!feature) {
sensors_parse_error("Unknown feature name",
chip->sets[i].lineno);
err = SENSORS_ERR_NO_ENTRY;
continue;
}
feature_nr = feature->data.number;
/* Check whether we already set this feature */
for (j = 0; j < feature_count; j++)
if (feature_list[j] == feature_nr)
break;
if (j != feature_count)
continue;
sensors_add_array_el(&feature_nr, &feature_list,
&feature_count, &feature_max,
sizeof(int));
res = sensors_eval_expr(name, chip->sets[i].value, 0,
&value);
if (res) {
sensors_parse_error("Error parsing expression",
chip->sets[i].lineno);
err = res;
continue;
}
if ((res = sensors_set_feature(name, feature_nr, value))) {
sensors_parse_error("Failed to set feature",
chip->sets[i].lineno);
err = res;
continue;
}
}
free(feature_list);
return err;
}
/* Execute all set statements for this particular chip. The chip may contain
wildcards! This function will return 0 on success, and <0 on failure. */
int sensors_do_chip_sets(sensors_chip_name name)
{
int nr, this_res;
const sensors_chip_name *found_name;
int res = 0;
for (nr = 0; (found_name = sensors_get_detected_chips(&nr));)
if (sensors_match_chip(name, *found_name)) {
this_res = sensors_do_this_chip_sets(*found_name);
if (!res)
res = this_res;
}
return res;
}
/* Execute all set statements for all detected chips. This is the same as
calling sensors_do_chip_sets with an all wildcards chip name */
int sensors_do_all_sets(void)
{
static const sensors_chip_name name = {
.prefix = SENSORS_CHIP_NAME_PREFIX_ANY,
.bus = SENSORS_CHIP_NAME_BUS_ANY,
.addr = SENSORS_CHIP_NAME_ADDR_ANY,
};
return sensors_do_chip_sets(name);
}
/* Static mappings for use by sensors_feature_get_type() */
struct feature_subtype_match
{
const char *name;
sensors_feature_type type;
};
struct feature_type_match
{
const char *name;
const struct feature_subtype_match *submatches;
};
static const struct feature_subtype_match temp_matches[] = {
{ "input", SENSORS_FEATURE_TEMP },
{ "max", SENSORS_FEATURE_TEMP_MAX },
{ "max_hyst", SENSORS_FEATURE_TEMP_MAX_HYST },
{ "min", SENSORS_FEATURE_TEMP_MIN },
{ "crit", SENSORS_FEATURE_TEMP_CRIT },
{ "crit_hyst", SENSORS_FEATURE_TEMP_CRIT_HYST },
{ "alarm", SENSORS_FEATURE_TEMP_ALARM },
{ "min_alarm", SENSORS_FEATURE_TEMP_MIN_ALARM },
{ "max_alarm", SENSORS_FEATURE_TEMP_MAX_ALARM },
{ "crit_alarm", SENSORS_FEATURE_TEMP_CRIT_ALARM },
{ "fault", SENSORS_FEATURE_TEMP_FAULT },
{ "type", SENSORS_FEATURE_TEMP_SENS },
{ NULL, 0 }
};
static const struct feature_subtype_match in_matches[] = {
{ "input", SENSORS_FEATURE_IN },
{ "min", SENSORS_FEATURE_IN_MIN },
{ "max", SENSORS_FEATURE_IN_MAX },
{ "alarm", SENSORS_FEATURE_IN_ALARM },
{ "min_alarm", SENSORS_FEATURE_IN_MIN_ALARM },
{ "max_alarm", SENSORS_FEATURE_IN_MAX_ALARM },
{ NULL, 0 }
};
static const struct feature_subtype_match fan_matches[] = {
{ "input", SENSORS_FEATURE_FAN },
{ "min", SENSORS_FEATURE_FAN_MIN },
{ "div", SENSORS_FEATURE_FAN_DIV },
{ "alarm", SENSORS_FEATURE_FAN_ALARM },
{ "fault", SENSORS_FEATURE_FAN_FAULT },
{ NULL, 0 }
};
static const struct feature_subtype_match cpu_matches[] = {
{ "vid", SENSORS_FEATURE_VID },
{ 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 },
};
/* Return the feature type and channel number based on the feature name */
sensors_feature_type sensors_feature_get_type(const char *name, int *nr)
{
char c;
int i, count;
const struct feature_subtype_match *submatches;
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_FEATURE_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_FEATURE_UNKNOWN;
}
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