#include <linux/hid-sensor-ids.h>
#include "amd_sfh_interface.h"
#include "../hid_descriptor/amd_sfh_hid_desc.h"
#include "../hid_descriptor/amd_sfh_hid_report_desc.h"
#define SENSOR_PROP_REPORTING_STATE_ALL_EVENTS_ENUM 0x41
#define SENSOR_PROP_POWER_STATE_D0_FULL_POWER_ENUM 0x51
#define HID_DEFAULT_REPORT_INTERVAL 0x50
#define HID_DEFAULT_MIN_VALUE 0X7F
#define HID_DEFAULT_MAX_VALUE 0x80
#define HID_DEFAULT_SENSITIVITY 0x7F
#define HID_USAGE_SENSOR_PROPERTY_CONNECTION_TYPE_PC_INTEGRATED_ENUM 0x01
#define HID_USAGE_SENSOR_STATE_READY_ENUM 0x02
#define HID_USAGE_SENSOR_STATE_INITIALIZING_ENUM 0x05
#define HID_USAGE_SENSOR_EVENT_DATA_UPDATED_ENUM 0x04
static int get_report_desc(int sensor_idx, u8 *rep_desc)
{
switch (sensor_idx) {
case ACCEL_IDX:
memset(rep_desc, 0, sizeof(accel3_report_descriptor));
memcpy(rep_desc, accel3_report_descriptor,
sizeof(accel3_report_descriptor));
break;
case GYRO_IDX:
memset(rep_desc, 0, sizeof(gyro3_report_descriptor));
memcpy(rep_desc, gyro3_report_descriptor,
sizeof(gyro3_report_descriptor));
break;
case MAG_IDX:
memset(rep_desc, 0, sizeof(comp3_report_descriptor));
memcpy(rep_desc, comp3_report_descriptor,
sizeof(comp3_report_descriptor));
break;
case ALS_IDX:
memset(rep_desc, 0, sizeof(als_report_descriptor));
memcpy(rep_desc, als_report_descriptor,
sizeof(als_report_descriptor));
break;
case HPD_IDX:
memset(rep_desc, 0, sizeof(hpd_report_descriptor));
memcpy(rep_desc, hpd_report_descriptor,
sizeof(hpd_report_descriptor));
break;
}
return 0;
}
static void get_common_features(struct common_feature_property *common, int report_id)
{
common->report_id = report_id;
common->connection_type = HID_USAGE_SENSOR_PROPERTY_CONNECTION_TYPE_PC_INTEGRATED_ENUM;
common->report_state = SENSOR_PROP_REPORTING_STATE_ALL_EVENTS_ENUM;
common->power_state = SENSOR_PROP_POWER_STATE_D0_FULL_POWER_ENUM;
common->sensor_state = HID_USAGE_SENSOR_STATE_INITIALIZING_ENUM;
common->report_interval = HID_DEFAULT_REPORT_INTERVAL;
}
static u8 get_feature_rep(int sensor_idx, int report_id, u8 *feature_report)
{
struct magno_feature_report magno_feature;
struct accel3_feature_report acc_feature;
struct gyro_feature_report gyro_feature;
struct hpd_feature_report hpd_feature;
struct als_feature_report als_feature;
u8 report_size = 0;
if (!feature_report)
return report_size;
switch (sensor_idx) {
case ACCEL_IDX:
get_common_features(&acc_feature.common_property, report_id);
acc_feature.accel_change_sesnitivity = HID_DEFAULT_SENSITIVITY;
acc_feature.accel_sensitivity_min = HID_DEFAULT_MIN_VALUE;
acc_feature.accel_sensitivity_max = HID_DEFAULT_MAX_VALUE;
memcpy(feature_report, &acc_feature, sizeof(acc_feature));
report_size = sizeof(acc_feature);
break;
case GYRO_IDX:
get_common_features(&gyro_feature.common_property, report_id);
gyro_feature.gyro_change_sesnitivity = HID_DEFAULT_SENSITIVITY;
gyro_feature.gyro_sensitivity_min = HID_DEFAULT_MIN_VALUE;
gyro_feature.gyro_sensitivity_max = HID_DEFAULT_MAX_VALUE;
memcpy(feature_report, &gyro_feature, sizeof(gyro_feature));
report_size = sizeof(gyro_feature);
break;
case MAG_IDX:
get_common_features(&magno_feature.common_property, report_id);
magno_feature.magno_headingchange_sensitivity = HID_DEFAULT_SENSITIVITY;
magno_feature.heading_min = HID_DEFAULT_MIN_VALUE;
magno_feature.heading_max = HID_DEFAULT_MAX_VALUE;
magno_feature.flux_change_sensitivity = HID_DEFAULT_MIN_VALUE;
magno_feature.flux_min = HID_DEFAULT_MIN_VALUE;
magno_feature.flux_max = HID_DEFAULT_MAX_VALUE;
memcpy(feature_report, &magno_feature, sizeof(magno_feature));
report_size = sizeof(magno_feature);
break;
case ALS_IDX:
get_common_features(&als_feature.common_property, report_id);
als_feature.als_change_sesnitivity = HID_DEFAULT_SENSITIVITY;
als_feature.als_sensitivity_min = HID_DEFAULT_MIN_VALUE;
als_feature.als_sensitivity_max = HID_DEFAULT_MAX_VALUE;
memcpy(feature_report, &als_feature, sizeof(als_feature));
report_size = sizeof(als_feature);
break;
case HPD_IDX:
get_common_features(&hpd_feature.common_property, report_id);
memcpy(feature_report, &hpd_feature, sizeof(hpd_feature));
report_size = sizeof(hpd_feature);
break;
}
return report_size;
}
static void get_common_inputs(struct common_input_property *common, int report_id)
{
common->report_id = report_id;
common->sensor_state = HID_USAGE_SENSOR_STATE_READY_ENUM;
common->event_type = HID_USAGE_SENSOR_EVENT_DATA_UPDATED_ENUM;
}
int amd_sfh_float_to_int(u32 flt32_val)
{
int fraction, shift, mantissa, sign, exp, zeropre;
mantissa = flt32_val & GENMASK(22, 0);
sign = (flt32_val & BIT(31)) ? -1 : 1;
exp = (flt32_val & ~BIT(31)) >> 23;
if (!exp && !mantissa)
return 0;
exp -= 127;
if (exp < 0) {
exp = -exp;
if (exp >= BITS_PER_TYPE(u32))
return 0;
zeropre = (((BIT(23) + mantissa) * 100) >> 23) >> exp;
return zeropre >= 50 ? sign : 0;
}
shift = 23 - exp;
if (abs(shift) >= BITS_PER_TYPE(u32))
return 0;
if (shift < 0) {
shift = -shift;
flt32_val = BIT(exp) + (mantissa << shift);
shift = 0;
} else {
flt32_val = BIT(exp) + (mantissa >> shift);
}
fraction = (shift == 0) ? 0 : mantissa & GENMASK(shift - 1, 0);
return (((fraction * 100) >> shift) >= 50) ? sign * (flt32_val + 1) : sign * flt32_val;
}
static u8 get_input_rep(u8 current_index, int sensor_idx, int report_id,
struct amd_input_data *in_data)
{
struct amd_mp2_dev *mp2 = container_of(in_data, struct amd_mp2_dev, in_data);
u8 *input_report = in_data->input_report[current_index];
struct magno_input_report magno_input;
struct accel3_input_report acc_input;
struct gyro_input_report gyro_input;
struct als_input_report als_input;
struct hpd_input_report hpd_input;
struct sfh_accel_data accel_data;
struct sfh_gyro_data gyro_data;
struct sfh_mag_data mag_data;
struct sfh_als_data als_data;
struct hpd_status hpdstatus;
struct sfh_base_info binfo;
void __iomem *sensoraddr;
u8 report_size = 0;
if (!input_report)
return report_size;
switch (sensor_idx) {
case ACCEL_IDX:
sensoraddr = mp2->vsbase + (ACCEL_IDX * SENSOR_DATA_MEM_SIZE_DEFAULT) +
OFFSET_SENSOR_DATA_DEFAULT;
memcpy_fromio(&accel_data, sensoraddr, sizeof(struct sfh_accel_data));
get_common_inputs(&acc_input.common_property, report_id);
acc_input.in_accel_x_value = amd_sfh_float_to_int(accel_data.acceldata.x) / 100;
acc_input.in_accel_y_value = amd_sfh_float_to_int(accel_data.acceldata.y) / 100;
acc_input.in_accel_z_value = amd_sfh_float_to_int(accel_data.acceldata.z) / 100;
memcpy(input_report, &acc_input, sizeof(acc_input));
report_size = sizeof(acc_input);
break;
case GYRO_IDX:
sensoraddr = mp2->vsbase + (GYRO_IDX * SENSOR_DATA_MEM_SIZE_DEFAULT) +
OFFSET_SENSOR_DATA_DEFAULT;
memcpy_fromio(&gyro_data, sensoraddr, sizeof(struct sfh_gyro_data));
get_common_inputs(&gyro_input.common_property, report_id);
gyro_input.in_angel_x_value = amd_sfh_float_to_int(gyro_data.gyrodata.x) / 1000;
gyro_input.in_angel_y_value = amd_sfh_float_to_int(gyro_data.gyrodata.y) / 1000;
gyro_input.in_angel_z_value = amd_sfh_float_to_int(gyro_data.gyrodata.z) / 1000;
memcpy(input_report, &gyro_input, sizeof(gyro_input));
report_size = sizeof(gyro_input);
break;
case MAG_IDX:
sensoraddr = mp2->vsbase + (MAG_IDX * SENSOR_DATA_MEM_SIZE_DEFAULT) +
OFFSET_SENSOR_DATA_DEFAULT;
memcpy_fromio(&mag_data, sensoraddr, sizeof(struct sfh_mag_data));
get_common_inputs(&magno_input.common_property, report_id);
magno_input.in_magno_x = amd_sfh_float_to_int(mag_data.magdata.x) / 100;
magno_input.in_magno_y = amd_sfh_float_to_int(mag_data.magdata.y) / 100;
magno_input.in_magno_z = amd_sfh_float_to_int(mag_data.magdata.z) / 100;
magno_input.in_magno_accuracy = mag_data.accuracy / 100;
memcpy(input_report, &magno_input, sizeof(magno_input));
report_size = sizeof(magno_input);
break;
case ALS_IDX:
sensoraddr = mp2->vsbase + (ALS_IDX * SENSOR_DATA_MEM_SIZE_DEFAULT) +
OFFSET_SENSOR_DATA_DEFAULT;
memcpy_fromio(&als_data, sensoraddr, sizeof(struct sfh_als_data));
get_common_inputs(&als_input.common_property, report_id);
als_input.illuminance_value = amd_sfh_float_to_int(als_data.lux);
memcpy_fromio(&binfo, mp2->vsbase, sizeof(struct sfh_base_info));
if (binfo.sbase.s_prop[ALS_IDX].sf.feat & 0x2) {
als_input.light_color_temp = als_data.light_color_temp;
als_input.chromaticity_x_value =
amd_sfh_float_to_int(als_data.chromaticity_x);
als_input.chromaticity_y_value =
amd_sfh_float_to_int(als_data.chromaticity_y);
}
report_size = sizeof(als_input);
memcpy(input_report, &als_input, sizeof(als_input));
break;
case HPD_IDX:
get_common_inputs(&hpd_input.common_property, report_id);
hpdstatus.val = readl(mp2->mmio + amd_get_c2p_val(mp2, 4));
hpd_input.human_presence = hpdstatus.shpd.presence;
report_size = sizeof(hpd_input);
memcpy(input_report, &hpd_input, sizeof(hpd_input));
break;
}
return report_size;
}
static u32 get_desc_size(int sensor_idx, int descriptor_name)
{
switch (sensor_idx) {
case ACCEL_IDX:
switch (descriptor_name) {
case descr_size:
return sizeof(accel3_report_descriptor);
case input_size:
return sizeof(struct accel3_input_report);
case feature_size:
return sizeof(struct accel3_feature_report);
}
break;
case GYRO_IDX:
switch (descriptor_name) {
case descr_size:
return sizeof(gyro3_report_descriptor);
case input_size:
return sizeof(struct gyro_input_report);
case feature_size:
return sizeof(struct gyro_feature_report);
}
break;
case MAG_IDX:
switch (descriptor_name) {
case descr_size:
return sizeof(comp3_report_descriptor);
case input_size:
return sizeof(struct magno_input_report);
case feature_size:
return sizeof(struct magno_feature_report);
}
break;
case ALS_IDX:
switch (descriptor_name) {
case descr_size:
return sizeof(als_report_descriptor);
case input_size:
return sizeof(struct als_input_report);
case feature_size:
return sizeof(struct als_feature_report);
}
break;
case HPD_IDX:
switch (descriptor_name) {
case descr_size:
return sizeof(hpd_report_descriptor);
case input_size:
return sizeof(struct hpd_input_report);
case feature_size:
return sizeof(struct hpd_feature_report);
}
break;
}
return 0;
}
void amd_sfh1_1_set_desc_ops(struct amd_mp2_ops *mp2_ops)
{
mp2_ops->get_rep_desc = get_report_desc;
mp2_ops->get_feat_rep = get_feature_rep;
mp2_ops->get_desc_sz = get_desc_size;
mp2_ops->get_in_rep = get_input_rep;
}
