/* * Copyright (c) 2021-2022 Huawei Device Co., Ltd. * * HDF is dual licensed: you can use it either under the terms of * the GPL, or the BSD license, at your option. * See the LICENSE file in the root of this repository for complete details. */ #include "accel_bmi160.h" #include #include "osal_mem.h" #include "osal_time.h" #include "sensor_accel_driver.h" #include "sensor_config_controller.h" #include "sensor_device_manager.h" #define HDF_LOG_TAG khdf_sensor_accel_driver static struct Bmi160DrvData *g_bmi160DrvData = NULL; /* IO config for int-pin and I2C-pin */ #define SENSOR_I2C6_DATA_REG_ADDR 0x114f004c #define SENSOR_I2C6_CLK_REG_ADDR 0x114f0048 #define SENSOR_I2C_REG_CFG 0x403 static int32_t ReadBmi160RawData(struct SensorCfgData *data, struct AccelData *rawData, uint64_t *timestamp) { uint8_t status = 0; uint8_t reg[ACCEL_AXIS_BUTT]; OsalTimespec time; (void)memset_s(&time, sizeof(time), 0, sizeof(time)); (void)memset_s(reg, sizeof(reg), 0, sizeof(reg)); CHECK_NULL_PTR_RETURN_VALUE(data, HDF_ERR_INVALID_PARAM); if (OsalGetTime(&time) != HDF_SUCCESS) { HDF_LOGE("%s: Get time failed", __func__); return HDF_FAILURE; } *timestamp = time.sec * SENSOR_SECOND_CONVERT_NANOSECOND + time.usec * SENSOR_CONVERT_UNIT; /* unit nanosecond */ int32_t ret = ReadSensor(&data->busCfg, BMI160_STATUS_ADDR, &status, sizeof(uint8_t)); if (!(status & BMI160_ACCEL_DATA_READY_MASK) || (ret != HDF_SUCCESS)) { HDF_LOGE("%s: data status [%hhu] ret [%d]", __func__, status, ret); return HDF_FAILURE; } ret = ReadSensor(&data->busCfg, BMI160_ACCEL_X_LSB_ADDR, ®[ACCEL_X_AXIS_LSB], sizeof(uint8_t)); CHECK_PARSER_RESULT_RETURN_VALUE(ret, "read data"); ret = ReadSensor(&data->busCfg, BMI160_ACCEL_X_MSB_ADDR, ®[ACCEL_X_AXIS_MSB], sizeof(uint8_t)); CHECK_PARSER_RESULT_RETURN_VALUE(ret, "read data"); ret = ReadSensor(&data->busCfg, BMI160_ACCEL_Y_LSB_ADDR, ®[ACCEL_Y_AXIS_LSB], sizeof(uint8_t)); CHECK_PARSER_RESULT_RETURN_VALUE(ret, "read data"); ret = ReadSensor(&data->busCfg, BMI160_ACCEL_Y_MSB_ADDR, ®[ACCEL_Y_AXIS_MSB], sizeof(uint8_t)); CHECK_PARSER_RESULT_RETURN_VALUE(ret, "read data"); ret = ReadSensor(&data->busCfg, BMI160_ACCEL_Z_LSB_ADDR, ®[ACCEL_Z_AXIS_LSB], sizeof(uint8_t)); CHECK_PARSER_RESULT_RETURN_VALUE(ret, "read data"); ret = ReadSensor(&data->busCfg, BMI160_ACCEL_Z_MSB_ADDR, ®[ACCEL_Z_AXIS_MSB], sizeof(uint8_t)); CHECK_PARSER_RESULT_RETURN_VALUE(ret, "read data"); rawData->x = (int16_t)(SENSOR_DATA_SHIFT_LEFT(reg[ACCEL_X_AXIS_MSB], SENSOR_DATA_WIDTH_8_BIT) | reg[ACCEL_X_AXIS_LSB]); rawData->y = (int16_t)(SENSOR_DATA_SHIFT_LEFT(reg[ACCEL_Y_AXIS_MSB], SENSOR_DATA_WIDTH_8_BIT) | reg[ACCEL_Y_AXIS_LSB]); rawData->z = (int16_t)(SENSOR_DATA_SHIFT_LEFT(reg[ACCEL_Z_AXIS_MSB], SENSOR_DATA_WIDTH_8_BIT) | reg[ACCEL_Z_AXIS_LSB]); return HDF_SUCCESS; } static int32_t ReadBmi160Data(struct SensorCfgData *cfg, struct SensorReportEvent *event) { int32_t ret; struct AccelData rawData = { 0, 0, 0 }; static int32_t tmp[ACCEL_AXIS_NUM]; CHECK_NULL_PTR_RETURN_VALUE(cfg, HDF_ERR_INVALID_PARAM); CHECK_NULL_PTR_RETURN_VALUE(event, HDF_ERR_INVALID_PARAM); ret = ReadBmi160RawData(cfg, &rawData, &event->timestamp); if (ret != HDF_SUCCESS) { HDF_LOGE("%s: BMI160 read raw data failed", __func__); return HDF_FAILURE; } event->sensorId = SENSOR_TAG_ACCELEROMETER; event->option = 0; event->mode = SENSOR_WORK_MODE_REALTIME; rawData.x = rawData.x * BMI160_ACC_SENSITIVITY_2G; rawData.y = rawData.y * BMI160_ACC_SENSITIVITY_2G; rawData.z = rawData.z * BMI160_ACC_SENSITIVITY_2G; tmp[ACCEL_X_AXIS] = (rawData.x * SENSOR_CONVERT_UNIT) / SENSOR_CONVERT_UNIT; tmp[ACCEL_Y_AXIS] = (rawData.y * SENSOR_CONVERT_UNIT) / SENSOR_CONVERT_UNIT; tmp[ACCEL_Z_AXIS] = (rawData.z * SENSOR_CONVERT_UNIT) / SENSOR_CONVERT_UNIT; ret = SensorRawDataToRemapData(cfg->direction, tmp, sizeof(tmp) / sizeof(tmp[0])); if (ret != HDF_SUCCESS) { HDF_LOGE("%s: BMI160 convert raw data failed", __func__); return HDF_FAILURE; } event->dataLen = sizeof(tmp); event->data = (uint8_t *)&tmp; return ret; } static int32_t InitBmi160(struct SensorCfgData *data) { int32_t ret; CHECK_NULL_PTR_RETURN_VALUE(data, HDF_ERR_INVALID_PARAM); ret = SetSensorRegCfgArray(&data->busCfg, data->regCfgGroup[SENSOR_INIT_GROUP]); if (ret != HDF_SUCCESS) { HDF_LOGE("%s: BMI160 sensor init config failed", __func__); return HDF_FAILURE; } return HDF_SUCCESS; } static int32_t InitAccelPreConfig(void) { if (SetSensorPinMux(SENSOR_I2C6_DATA_REG_ADDR, SENSOR_ADDR_WIDTH_4_BYTE, SENSOR_I2C_REG_CFG) != HDF_SUCCESS) { HDF_LOGE("%s: Data write mux pin failed", __func__); return HDF_FAILURE; } if (SetSensorPinMux(SENSOR_I2C6_CLK_REG_ADDR, SENSOR_ADDR_WIDTH_4_BYTE, SENSOR_I2C_REG_CFG) != HDF_SUCCESS) { HDF_LOGE("%s: Clk write mux pin failed", __func__); return HDF_FAILURE; } return HDF_SUCCESS; } static int32_t DispatchBMI160(struct HdfDeviceIoClient *client, int cmd, struct HdfSBuf *data, struct HdfSBuf *reply) { (void)client; (void)cmd; (void)data; (void)reply; return HDF_SUCCESS; } static int32_t Bmi160BindDriver(struct HdfDeviceObject *device) { CHECK_NULL_PTR_RETURN_VALUE(device, HDF_ERR_INVALID_PARAM); struct Bmi160DrvData *drvData = (struct Bmi160DrvData *)OsalMemCalloc(sizeof(*drvData)); if (drvData == NULL) { HDF_LOGE("%s: Malloc Bmi160 drv data fail", __func__); return HDF_ERR_MALLOC_FAIL; } drvData->ioService.Dispatch = DispatchBMI160; drvData->device = device; device->service = &drvData->ioService; g_bmi160DrvData = drvData; return HDF_SUCCESS; } static int32_t Bmi160InitDriver(struct HdfDeviceObject *device) { int32_t ret; struct AccelOpsCall ops; CHECK_NULL_PTR_RETURN_VALUE(device, HDF_ERR_INVALID_PARAM); struct Bmi160DrvData *drvData = (struct Bmi160DrvData *)device->service; CHECK_NULL_PTR_RETURN_VALUE(drvData, HDF_ERR_INVALID_PARAM); ret = InitAccelPreConfig(); if (ret != HDF_SUCCESS) { HDF_LOGE("%s: Init BMI160 bus mux config", __func__); return HDF_FAILURE; } drvData->sensorCfg = AccelCreateCfgData(device->property); if (drvData->sensorCfg == NULL || drvData->sensorCfg->root == NULL) { HDF_LOGD("%s: Creating accelcfg failed because detection failed", __func__); return HDF_ERR_NOT_SUPPORT; } ops.Init = NULL; ops.ReadData = ReadBmi160Data; ret = AccelRegisterChipOps(&ops); if (ret != HDF_SUCCESS) { HDF_LOGE("%s: Register BMI160 accel failed", __func__); return HDF_FAILURE; } ret = InitBmi160(drvData->sensorCfg); if (ret != HDF_SUCCESS) { HDF_LOGE("%s: Init BMI160 accel failed", __func__); return HDF_FAILURE; } return HDF_SUCCESS; } static void Bmi160ReleaseDriver(struct HdfDeviceObject *device) { CHECK_NULL_PTR_RETURN(device); struct Bmi160DrvData *drvData = (struct Bmi160DrvData *)device->service; CHECK_NULL_PTR_RETURN(drvData); if (drvData->sensorCfg != NULL) { AccelReleaseCfgData(drvData->sensorCfg); drvData->sensorCfg = NULL; } OsalMemFree(drvData); } struct HdfDriverEntry g_accelBmi160DevEntry = { .moduleVersion = 1, .moduleName = "HDF_SENSOR_ACCEL_BMI160", .Bind = Bmi160BindDriver, .Init = Bmi160InitDriver, .Release = Bmi160ReleaseDriver, }; HDF_INIT(g_accelBmi160DevEntry);