1 // SPDX-License-Identifier: GPL-2.0-or-later 2 /* 3 * AMD MP2 1.1 descriptor interfaces 4 * 5 * Copyright (c) 2022, Advanced Micro Devices, Inc. 6 * All Rights Reserved. 7 * 8 * Author: Basavaraj Natikar <Basavaraj.Natikar@amd.com> 9 */ 10 11 #include <linux/hid-sensor-ids.h> 12 13 #include "amd_sfh_interface.h" 14 #include "../hid_descriptor/amd_sfh_hid_desc.h" 15 #include "../hid_descriptor/amd_sfh_hid_report_desc.h" 16 17 #define SENSOR_PROP_REPORTING_STATE_ALL_EVENTS_ENUM 0x41 18 #define SENSOR_PROP_POWER_STATE_D0_FULL_POWER_ENUM 0x51 19 #define HID_DEFAULT_REPORT_INTERVAL 0x50 20 #define HID_DEFAULT_MIN_VALUE 0X7F 21 #define HID_DEFAULT_MAX_VALUE 0x80 22 #define HID_DEFAULT_SENSITIVITY 0x7F 23 #define HID_USAGE_SENSOR_PROPERTY_CONNECTION_TYPE_PC_INTEGRATED_ENUM 0x01 24 /* state enums */ 25 #define HID_USAGE_SENSOR_STATE_READY_ENUM 0x02 26 #define HID_USAGE_SENSOR_STATE_INITIALIZING_ENUM 0x05 27 #define HID_USAGE_SENSOR_EVENT_DATA_UPDATED_ENUM 0x04 28 29 static int get_report_desc(int sensor_idx, u8 *rep_desc) 30 { 31 switch (sensor_idx) { 32 case ACCEL_IDX: /* accelerometer */ 33 memset(rep_desc, 0, sizeof(accel3_report_descriptor)); 34 memcpy(rep_desc, accel3_report_descriptor, 35 sizeof(accel3_report_descriptor)); 36 break; 37 case GYRO_IDX: /* gyroscope */ 38 memset(rep_desc, 0, sizeof(gyro3_report_descriptor)); 39 memcpy(rep_desc, gyro3_report_descriptor, 40 sizeof(gyro3_report_descriptor)); 41 break; 42 case MAG_IDX: /* magnetometer */ 43 memset(rep_desc, 0, sizeof(comp3_report_descriptor)); 44 memcpy(rep_desc, comp3_report_descriptor, 45 sizeof(comp3_report_descriptor)); 46 break; 47 case ALS_IDX: /* ambient light sensor */ 48 memset(rep_desc, 0, sizeof(als_report_descriptor)); 49 memcpy(rep_desc, als_report_descriptor, 50 sizeof(als_report_descriptor)); 51 break; 52 case HPD_IDX: /* HPD sensor */ 53 memset(rep_desc, 0, sizeof(hpd_report_descriptor)); 54 memcpy(rep_desc, hpd_report_descriptor, 55 sizeof(hpd_report_descriptor)); 56 break; 57 } 58 return 0; 59 } 60 61 static void get_common_features(struct common_feature_property *common, int report_id) 62 { 63 common->report_id = report_id; 64 common->connection_type = HID_USAGE_SENSOR_PROPERTY_CONNECTION_TYPE_PC_INTEGRATED_ENUM; 65 common->report_state = SENSOR_PROP_REPORTING_STATE_ALL_EVENTS_ENUM; 66 common->power_state = SENSOR_PROP_POWER_STATE_D0_FULL_POWER_ENUM; 67 common->sensor_state = HID_USAGE_SENSOR_STATE_INITIALIZING_ENUM; 68 common->report_interval = HID_DEFAULT_REPORT_INTERVAL; 69 } 70 71 static u8 get_feature_rep(int sensor_idx, int report_id, u8 *feature_report) 72 { 73 struct magno_feature_report magno_feature; 74 struct accel3_feature_report acc_feature; 75 struct gyro_feature_report gyro_feature; 76 struct hpd_feature_report hpd_feature; 77 struct als_feature_report als_feature; 78 u8 report_size = 0; 79 80 if (!feature_report) 81 return report_size; 82 83 switch (sensor_idx) { 84 case ACCEL_IDX: /* accelerometer */ 85 get_common_features(&acc_feature.common_property, report_id); 86 acc_feature.accel_change_sesnitivity = HID_DEFAULT_SENSITIVITY; 87 acc_feature.accel_sensitivity_min = HID_DEFAULT_MIN_VALUE; 88 acc_feature.accel_sensitivity_max = HID_DEFAULT_MAX_VALUE; 89 memcpy(feature_report, &acc_feature, sizeof(acc_feature)); 90 report_size = sizeof(acc_feature); 91 break; 92 case GYRO_IDX: /* gyroscope */ 93 get_common_features(&gyro_feature.common_property, report_id); 94 gyro_feature.gyro_change_sesnitivity = HID_DEFAULT_SENSITIVITY; 95 gyro_feature.gyro_sensitivity_min = HID_DEFAULT_MIN_VALUE; 96 gyro_feature.gyro_sensitivity_max = HID_DEFAULT_MAX_VALUE; 97 memcpy(feature_report, &gyro_feature, sizeof(gyro_feature)); 98 report_size = sizeof(gyro_feature); 99 break; 100 case MAG_IDX: /* magnetometer */ 101 get_common_features(&magno_feature.common_property, report_id); 102 magno_feature.magno_headingchange_sensitivity = HID_DEFAULT_SENSITIVITY; 103 magno_feature.heading_min = HID_DEFAULT_MIN_VALUE; 104 magno_feature.heading_max = HID_DEFAULT_MAX_VALUE; 105 magno_feature.flux_change_sensitivity = HID_DEFAULT_MIN_VALUE; 106 magno_feature.flux_min = HID_DEFAULT_MIN_VALUE; 107 magno_feature.flux_max = HID_DEFAULT_MAX_VALUE; 108 memcpy(feature_report, &magno_feature, sizeof(magno_feature)); 109 report_size = sizeof(magno_feature); 110 break; 111 case ALS_IDX: /* ambient light sensor */ 112 get_common_features(&als_feature.common_property, report_id); 113 als_feature.als_change_sesnitivity = HID_DEFAULT_SENSITIVITY; 114 als_feature.als_sensitivity_min = HID_DEFAULT_MIN_VALUE; 115 als_feature.als_sensitivity_max = HID_DEFAULT_MAX_VALUE; 116 memcpy(feature_report, &als_feature, sizeof(als_feature)); 117 report_size = sizeof(als_feature); 118 break; 119 case HPD_IDX: /* human presence detection sensor */ 120 get_common_features(&hpd_feature.common_property, report_id); 121 memcpy(feature_report, &hpd_feature, sizeof(hpd_feature)); 122 report_size = sizeof(hpd_feature); 123 break; 124 } 125 return report_size; 126 } 127 128 static void get_common_inputs(struct common_input_property *common, int report_id) 129 { 130 common->report_id = report_id; 131 common->sensor_state = HID_USAGE_SENSOR_STATE_READY_ENUM; 132 common->event_type = HID_USAGE_SENSOR_EVENT_DATA_UPDATED_ENUM; 133 } 134 135 int amd_sfh_float_to_int(u32 flt32_val) 136 { 137 int fraction, shift, mantissa, sign, exp, zeropre; 138 139 mantissa = flt32_val & GENMASK(22, 0); 140 sign = (flt32_val & BIT(31)) ? -1 : 1; 141 exp = (flt32_val & ~BIT(31)) >> 23; 142 143 if (!exp && !mantissa) 144 return 0; 145 146 /* 147 * Calculate the exponent and fraction part of floating 148 * point representation. 149 */ 150 exp -= 127; 151 if (exp < 0) { 152 exp = -exp; 153 if (exp >= BITS_PER_TYPE(u32)) 154 return 0; 155 zeropre = (((BIT(23) + mantissa) * 100) >> 23) >> exp; 156 return zeropre >= 50 ? sign : 0; 157 } 158 159 shift = 23 - exp; 160 if (abs(shift) >= BITS_PER_TYPE(u32)) 161 return 0; 162 163 if (shift < 0) { 164 shift = -shift; 165 flt32_val = BIT(exp) + (mantissa << shift); 166 shift = 0; 167 } else { 168 flt32_val = BIT(exp) + (mantissa >> shift); 169 } 170 171 fraction = (shift == 0) ? 0 : mantissa & GENMASK(shift - 1, 0); 172 173 return (((fraction * 100) >> shift) >= 50) ? sign * (flt32_val + 1) : sign * flt32_val; 174 } 175 176 static u8 get_input_rep(u8 current_index, int sensor_idx, int report_id, 177 struct amd_input_data *in_data) 178 { 179 struct amd_mp2_dev *mp2 = container_of(in_data, struct amd_mp2_dev, in_data); 180 u8 *input_report = in_data->input_report[current_index]; 181 struct magno_input_report magno_input; 182 struct accel3_input_report acc_input; 183 struct gyro_input_report gyro_input; 184 struct als_input_report als_input; 185 struct hpd_input_report hpd_input; 186 struct sfh_accel_data accel_data; 187 struct sfh_gyro_data gyro_data; 188 struct sfh_mag_data mag_data; 189 struct sfh_als_data als_data; 190 struct hpd_status hpdstatus; 191 struct sfh_base_info binfo; 192 void __iomem *sensoraddr; 193 u8 report_size = 0; 194 195 if (!input_report) 196 return report_size; 197 198 switch (sensor_idx) { 199 case ACCEL_IDX: /* accelerometer */ 200 sensoraddr = mp2->vsbase + (ACCEL_IDX * SENSOR_DATA_MEM_SIZE_DEFAULT) + 201 OFFSET_SENSOR_DATA_DEFAULT; 202 memcpy_fromio(&accel_data, sensoraddr, sizeof(struct sfh_accel_data)); 203 get_common_inputs(&acc_input.common_property, report_id); 204 acc_input.in_accel_x_value = amd_sfh_float_to_int(accel_data.acceldata.x) / 100; 205 acc_input.in_accel_y_value = amd_sfh_float_to_int(accel_data.acceldata.y) / 100; 206 acc_input.in_accel_z_value = amd_sfh_float_to_int(accel_data.acceldata.z) / 100; 207 memcpy(input_report, &acc_input, sizeof(acc_input)); 208 report_size = sizeof(acc_input); 209 break; 210 case GYRO_IDX: /* gyroscope */ 211 sensoraddr = mp2->vsbase + (GYRO_IDX * SENSOR_DATA_MEM_SIZE_DEFAULT) + 212 OFFSET_SENSOR_DATA_DEFAULT; 213 memcpy_fromio(&gyro_data, sensoraddr, sizeof(struct sfh_gyro_data)); 214 get_common_inputs(&gyro_input.common_property, report_id); 215 gyro_input.in_angel_x_value = amd_sfh_float_to_int(gyro_data.gyrodata.x) / 1000; 216 gyro_input.in_angel_y_value = amd_sfh_float_to_int(gyro_data.gyrodata.y) / 1000; 217 gyro_input.in_angel_z_value = amd_sfh_float_to_int(gyro_data.gyrodata.z) / 1000; 218 memcpy(input_report, &gyro_input, sizeof(gyro_input)); 219 report_size = sizeof(gyro_input); 220 break; 221 case MAG_IDX: /* magnetometer */ 222 sensoraddr = mp2->vsbase + (MAG_IDX * SENSOR_DATA_MEM_SIZE_DEFAULT) + 223 OFFSET_SENSOR_DATA_DEFAULT; 224 memcpy_fromio(&mag_data, sensoraddr, sizeof(struct sfh_mag_data)); 225 get_common_inputs(&magno_input.common_property, report_id); 226 magno_input.in_magno_x = amd_sfh_float_to_int(mag_data.magdata.x) / 100; 227 magno_input.in_magno_y = amd_sfh_float_to_int(mag_data.magdata.y) / 100; 228 magno_input.in_magno_z = amd_sfh_float_to_int(mag_data.magdata.z) / 100; 229 magno_input.in_magno_accuracy = mag_data.accuracy / 100; 230 memcpy(input_report, &magno_input, sizeof(magno_input)); 231 report_size = sizeof(magno_input); 232 break; 233 case ALS_IDX: 234 sensoraddr = mp2->vsbase + (ALS_IDX * SENSOR_DATA_MEM_SIZE_DEFAULT) + 235 OFFSET_SENSOR_DATA_DEFAULT; 236 memcpy_fromio(&als_data, sensoraddr, sizeof(struct sfh_als_data)); 237 get_common_inputs(&als_input.common_property, report_id); 238 als_input.illuminance_value = amd_sfh_float_to_int(als_data.lux); 239 240 memcpy_fromio(&binfo, mp2->vsbase, sizeof(struct sfh_base_info)); 241 if (binfo.sbase.s_prop[ALS_IDX].sf.feat & 0x2) { 242 als_input.light_color_temp = als_data.light_color_temp; 243 als_input.chromaticity_x_value = 244 amd_sfh_float_to_int(als_data.chromaticity_x); 245 als_input.chromaticity_y_value = 246 amd_sfh_float_to_int(als_data.chromaticity_y); 247 } 248 249 report_size = sizeof(als_input); 250 memcpy(input_report, &als_input, sizeof(als_input)); 251 break; 252 case HPD_IDX: 253 get_common_inputs(&hpd_input.common_property, report_id); 254 hpdstatus.val = readl(mp2->mmio + AMD_C2P_MSG(4)); 255 hpd_input.human_presence = hpdstatus.shpd.presence; 256 report_size = sizeof(hpd_input); 257 memcpy(input_report, &hpd_input, sizeof(hpd_input)); 258 break; 259 } 260 return report_size; 261 } 262 263 static u32 get_desc_size(int sensor_idx, int descriptor_name) 264 { 265 switch (sensor_idx) { 266 case ACCEL_IDX: 267 switch (descriptor_name) { 268 case descr_size: 269 return sizeof(accel3_report_descriptor); 270 case input_size: 271 return sizeof(struct accel3_input_report); 272 case feature_size: 273 return sizeof(struct accel3_feature_report); 274 } 275 break; 276 case GYRO_IDX: 277 switch (descriptor_name) { 278 case descr_size: 279 return sizeof(gyro3_report_descriptor); 280 case input_size: 281 return sizeof(struct gyro_input_report); 282 case feature_size: 283 return sizeof(struct gyro_feature_report); 284 } 285 break; 286 case MAG_IDX: 287 switch (descriptor_name) { 288 case descr_size: 289 return sizeof(comp3_report_descriptor); 290 case input_size: 291 return sizeof(struct magno_input_report); 292 case feature_size: 293 return sizeof(struct magno_feature_report); 294 } 295 break; 296 case ALS_IDX: 297 switch (descriptor_name) { 298 case descr_size: 299 return sizeof(als_report_descriptor); 300 case input_size: 301 return sizeof(struct als_input_report); 302 case feature_size: 303 return sizeof(struct als_feature_report); 304 } 305 break; 306 case HPD_IDX: 307 switch (descriptor_name) { 308 case descr_size: 309 return sizeof(hpd_report_descriptor); 310 case input_size: 311 return sizeof(struct hpd_input_report); 312 case feature_size: 313 return sizeof(struct hpd_feature_report); 314 } 315 break; 316 } 317 318 return 0; 319 } 320 321 void amd_sfh1_1_set_desc_ops(struct amd_mp2_ops *mp2_ops) 322 { 323 mp2_ops->get_rep_desc = get_report_desc; 324 mp2_ops->get_feat_rep = get_feature_rep; 325 mp2_ops->get_desc_sz = get_desc_size; 326 mp2_ops->get_in_rep = get_input_rep; 327 } 328