#include "enumeration.h"
#include "description.h"
#include "utils.h"
+#include "transform.h"
#define IIO_SENSOR_HAL_VERSION 1
return IIO_SENSOR_HAL_VERSION;
}
+void sensor_update_max_range(int s)
+{
+ if (sensor[s].max_range)
+ return;
+
+ if (sensor[s].num_channels && sensor[s].channel[0].type_info.realbits) {
+ switch (sensor[s].type) {
+ case SENSOR_TYPE_MAGNETIC_FIELD:
+ sensor[s].max_range = (1ULL << sensor[s].channel[0].type_info.realbits) *
+ CONVERT_MICROTESLA_TO_GAUSS(sensor[s].resolution) +
+ (sensor[s].offset || sensor[s].channel[0].offset);
+ sensor[s].max_range = CONVERT_GAUSS_TO_MICROTESLA(sensor[s].max_range);
+ break;
+ case SENSOR_TYPE_PROXIMITY:
+ break;
+ default:
+ sensor[s].max_range = (1ULL << sensor[s].channel[0].type_info.realbits) *
+ sensor[s].resolution + (sensor[s].offset || sensor[s].channel[0].offset);
+ break;
+ }
+ }
+
+ if (!sensor[s].max_range) {
+ /* Try returning a sensible value given the sensor type */
+ /* We should cap returned samples accordingly... */
+ switch (sensor[s].type) {
+ case SENSOR_TYPE_ACCELEROMETER: /* m/s^2 */
+ sensor[s].max_range = 50;
+ break;
+ case SENSOR_TYPE_MAGNETIC_FIELD: /* micro-tesla */
+ sensor[s].max_range = 500;
+ break;
+ case SENSOR_TYPE_ORIENTATION: /* degrees */
+ sensor[s].max_range = 360;
+ break;
+ case SENSOR_TYPE_GYROSCOPE: /* radians/s */
+ sensor[s].max_range = 10;
+ break;
+ case SENSOR_TYPE_LIGHT: /* SI lux units */
+ sensor[s].max_range = 50000;
+ break;
+ case SENSOR_TYPE_AMBIENT_TEMPERATURE: /* °C */
+ case SENSOR_TYPE_TEMPERATURE: /* °C */
+ case SENSOR_TYPE_PROXIMITY: /* centimeters */
+ case SENSOR_TYPE_PRESSURE: /* hecto-pascal */
+ case SENSOR_TYPE_RELATIVE_HUMIDITY: /* percent */
+ sensor[s].max_range = 100;
+ break;
+ }
+ }
+
+ if (sensor[s].max_range)
+ sensor_desc[s].maxRange = sensor[s].max_range;
+}
float sensor_get_max_range (int s)
{
!sensor_get_fl_prop(s, "max_range", &sensor[s].max_range))
return sensor[s].max_range;
- /* Try returning a sensible value given the sensor type */
-
- /* We should cap returned samples accordingly... */
-
- switch (sensor_desc[s].type) {
- case SENSOR_TYPE_ACCELEROMETER: /* m/s^2 */
- return 50;
-
- case SENSOR_TYPE_MAGNETIC_FIELD: /* micro-tesla */
- return 500;
-
- case SENSOR_TYPE_ORIENTATION: /* degrees */
- return 360;
-
- case SENSOR_TYPE_GYROSCOPE: /* radians/s */
- return 10;
-
- case SENSOR_TYPE_LIGHT: /* SI lux units */
- return 50000;
-
- case SENSOR_TYPE_AMBIENT_TEMPERATURE: /* °C */
- case SENSOR_TYPE_TEMPERATURE: /* °C */
- case SENSOR_TYPE_PROXIMITY: /* centimeters */
- case SENSOR_TYPE_PRESSURE: /* hecto-pascal */
- case SENSOR_TYPE_RELATIVE_HUMIDITY: /* percent */
- return 100;
-
- default:
- return 0;
- }
+ return 0;
}
static float sensor_get_min_freq (int s)
}
if (sensor[s].resolution != 0.0 ||
- !sensor_get_fl_prop(s, "resolution", &sensor[s].resolution))
- return sensor[s].resolution;
+ !sensor_get_fl_prop(s, "resolution", &sensor[s].resolution)) {
+ return sensor[s].resolution;
+ }
- return 0;
+ sensor[s].resolution = sensor[s].scale;
+ if (!sensor[s].resolution && sensor[s].num_channels)
+ sensor[s].resolution = sensor[s].channel[0].scale;
+
+ if (sensor[s].type == SENSOR_TYPE_MAGNETIC_FIELD)
+ sensor[s].resolution = CONVERT_GAUSS_TO_MICROTESLA(sensor[s].resolution);
+
+ return sensor[s].resolution ? : 1;
}
*/
max_delay_t sensor_get_max_delay (int s)
{
- char avail_sysfs_path[PATH_MAX];
- int dev_num = sensor[s].dev_num;
- char freqs_buf[100];
- char* cursor;
+ int dev_num = sensor[s].dev_num, i;
float min_supported_rate;
float rate_cap;
- float sr;
/*
* continuous, on-change: maximum sampling period allowed in microseconds.
switch (sensor[s].mode) {
case MODE_TRIGGER:
/* For interrupt-based devices, obey the list of supported sampling rates */
- sprintf(avail_sysfs_path, DEVICE_AVAIL_FREQ_PATH, dev_num);
if (!(sensor_get_quirks(s) & QUIRK_HRTIMER) &&
- sysfs_read_str(avail_sysfs_path, freqs_buf, sizeof(freqs_buf)) > 0) {
-
+ sensor[s].avail_freqs_count) {
min_supported_rate = 1000;
- cursor = freqs_buf;
-
- while (*cursor && cursor[0]) {
-
- /* Decode a single value */
- sr = strtod(cursor, NULL);
-
- if (sr < min_supported_rate)
- min_supported_rate = sr;
-
- /* Skip digits */
- while (cursor[0] && !isspace(cursor[0]))
- cursor++;
-
- /* Skip spaces */
- while (cursor[0] && isspace(cursor[0]))
- cursor++;
+ for (i = 0; i < sensor[s].avail_freqs_count; i++) {
+ if (sensor[s].avail_freqs[i] < min_supported_rate)
+ min_supported_rate = sensor[s].avail_freqs[i];
}
-
break;
}
-
/* Fall through ... */
default:
int32_t sensor_get_min_delay (int s)
{
- char avail_sysfs_path[PATH_MAX];
- int dev_num = sensor[s].dev_num;
- char freqs_buf[100];
- char* cursor;
+ int dev_num = sensor[s].dev_num, i;
float max_supported_rate = 0;
float max_from_prop = sensor_get_max_freq(s);
- float sr;
int hrtimer_quirk_enabled = sensor_get_quirks(s) & QUIRK_HRTIMER;
/* continuous, on change: minimum sampling period allowed in microseconds.
}
}
- sprintf(avail_sysfs_path, DEVICE_AVAIL_FREQ_PATH, dev_num);
-
- if (hrtimer_quirk_enabled || sysfs_read_str(avail_sysfs_path, freqs_buf, sizeof(freqs_buf)) < 0) {
+ if (hrtimer_quirk_enabled || !sensor[s].avail_freqs_count) {
if (hrtimer_quirk_enabled || (sensor[s].mode == MODE_POLL)) {
/* If we have max specified via a property use it */
if (max_from_prop != ANDROID_MAX_FREQ)
max_supported_rate = get_cdd_freq(s, 0);
}
} else {
- cursor = freqs_buf;
- while (*cursor && cursor[0]) {
-
- /* Decode a single value */
- sr = strtod(cursor, NULL);
-
- if (sr > max_supported_rate && sr <= max_from_prop)
- max_supported_rate = sr;
-
- /* Skip digits */
- while (cursor[0] && !isspace(cursor[0]))
- cursor++;
-
- /* Skip spaces */
- while (cursor[0] && isspace(cursor[0]))
- cursor++;
+ for (i = 0; i < sensor[s].avail_freqs_count; i++) {
+ if (sensor[s].avail_freqs[i] > max_supported_rate &&
+ sensor[s].avail_freqs[i] <= max_from_prop) {
+ max_supported_rate = sensor[s].avail_freqs[i];
+ }
}
}