/* * This software is licensed under the terms of the GNU General Public * License version 2, as published by the Free Software Foundation, and * may be copied, distributed, and modified under those terms. * * 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. * * History: V1.0 --- [2013.03.14]Driver creation * V1.1 --- [2013.07.03]Re-write I2C function to fix the bug that * i2c access error on MT6589 platform. * V1.2 --- [2013.07.04]Add self test function. * V1.3 --- [2013.07.04]Support new chip id 0x57 and 0x58. */ #include #include #include #include #include "cust_baro.h" #include "bmp280.h" #include "barometer.h" #define POWER_NONE_MACRO MT65XX_POWER_NONE static DEFINE_MUTEX(bmp280_i2c_mutex); /* sensor type */ enum SENSOR_TYPE_ENUM { BMP280_TYPE = 0x0, INVALID_TYPE = 0xff }; /* power mode */ enum BMP_POWERMODE_ENUM { BMP_SUSPEND_MODE = 0x0, BMP_NORMAL_MODE, BMP_UNDEFINED_POWERMODE = 0xff }; /* filter */ enum BMP_FILTER_ENUM { BMP_FILTER_OFF = 0x0, BMP_FILTER_2, BMP_FILTER_4, BMP_FILTER_8, BMP_FILTER_16, BMP_UNDEFINED_FILTER = 0xff }; /* oversampling */ enum BMP_OVERSAMPLING_ENUM { BMP_OVERSAMPLING_SKIPPED = 0x0, BMP_OVERSAMPLING_1X, BMP_OVERSAMPLING_2X, BMP_OVERSAMPLING_4X, BMP_OVERSAMPLING_8X, BMP_OVERSAMPLING_16X, BMP_UNDEFINED_OVERSAMPLING = 0xff }; /* trace */ enum BAR_TRC { BAR_TRC_READ = 0x01, BAR_TRC_RAWDATA = 0x02, BAR_TRC_IOCTL = 0x04, BAR_TRC_FILTER = 0x08, }; /* s/w filter */ struct data_filter { u32 raw[C_MAX_FIR_LENGTH][BMP_DATA_NUM]; int sum[BMP_DATA_NUM]; int num; int idx; }; /* bmp280 calibration */ struct bmp280_calibration_data { BMP280_U16_t dig_T1; BMP280_S16_t dig_T2; BMP280_S16_t dig_T3; BMP280_U16_t dig_P1; BMP280_S16_t dig_P2; BMP280_S16_t dig_P3; BMP280_S16_t dig_P4; BMP280_S16_t dig_P5; BMP280_S16_t dig_P6; BMP280_S16_t dig_P7; BMP280_S16_t dig_P8; BMP280_S16_t dig_P9; }; /* bmp i2c client data */ struct bmp_i2c_data { struct i2c_client *client; struct baro_hw *hw; /* sensor info */ u8 sensor_name[MAX_SENSOR_NAME]; enum SENSOR_TYPE_ENUM sensor_type; enum BMP_POWERMODE_ENUM power_mode; u8 hw_filter; u8 oversampling_p; u8 oversampling_t; unsigned long last_temp_measurement; unsigned long temp_measurement_period; struct bmp280_calibration_data bmp280_cali; /* calculated temperature correction coefficient */ s32 t_fine; /*misc */ struct mutex lock; atomic_t trace; atomic_t suspend; atomic_t filter; #if defined(CONFIG_BMP_LOWPASS) atomic_t firlen; atomic_t fir_en; struct data_filter fir; #endif }; #define BAR_TAG "[barometer] " #define BAR_FUN(f) pr_err(BAR_TAG"%s\n", __func__) #define BAR_ERR(fmt, args...) \ pr_err(BAR_TAG"%s %d : "fmt, __func__, __LINE__, ##args) #define BAR_LOG(fmt, args...) pr_debug(BAR_TAG fmt, ##args) static struct i2c_driver bmp_i2c_driver; static struct bmp_i2c_data *obj_i2c_data; static const struct i2c_device_id bmp_i2c_id[] = { {BMP_DEV_NAME, 0}, {} }; struct baro_hw baro_cust; static struct baro_hw *hw = &baro_cust; /* For alsp driver get cust info */ struct baro_hw *get_cust_baro(void) { return &baro_cust; } static int bmp280_local_init(void); static int bmp280_remove(void); static int bmp280_init_flag = -1; static struct baro_init_info bmp280_init_info = { .name = "bmp280", .init = bmp280_local_init, .uninit = bmp280_remove, }; /* I2C operation functions */ static int bmp_i2c_read_block(struct i2c_client *client, u8 addr, u8 *data, u8 len) { u8 beg = addr; int err; struct i2c_msg msgs[2] = { {0}, {0} }; mutex_lock(&bmp280_i2c_mutex); msgs[0].addr = client->addr; msgs[0].flags = 0; msgs[0].len = 1; msgs[0].buf = &beg; msgs[1].addr = client->addr; msgs[1].flags = I2C_M_RD; msgs[1].len = len; msgs[1].buf = data; if (!client) { mutex_unlock(&bmp280_i2c_mutex); return -EINVAL; } else if (len > C_I2C_FIFO_SIZE) { BAR_ERR(" length %d exceeds %d\n", len, C_I2C_FIFO_SIZE); mutex_unlock(&bmp280_i2c_mutex); return -EINVAL; } err = i2c_transfer(client->adapter, msgs, sizeof(msgs) / sizeof(msgs[0])); if (err != 2) { BAR_ERR("i2c_transfer error: (%d %p %d) %d\n", addr, data, len, err); err = -EIO; } else { err = 0; } mutex_unlock(&bmp280_i2c_mutex); return err; } static int bmp_i2c_write_block(struct i2c_client *client, u8 addr, u8 *data, u8 len) { /*because address also occupies one byte, the maximum length for write is 7 bytes */ int err = 0, idx = 0, num = 0; char buf[C_I2C_FIFO_SIZE]; mutex_lock(&bmp280_i2c_mutex); if (!client) { mutex_unlock(&bmp280_i2c_mutex); return -EINVAL; } else if (len >= C_I2C_FIFO_SIZE) { BAR_ERR(" length %d exceeds %d\n", len, C_I2C_FIFO_SIZE); mutex_unlock(&bmp280_i2c_mutex); return -EINVAL; } num = 0; buf[num++] = addr; for (idx = 0; idx < len; idx++) buf[num++] = data[idx]; err = i2c_master_send(client, buf, num); if (err < 0) { BAR_ERR("send command error!!\n"); mutex_unlock(&bmp280_i2c_mutex); return -EFAULT; } mutex_unlock(&bmp280_i2c_mutex); return err; } static void bmp_power(struct baro_hw *hw, unsigned int on) { } /* get chip type */ static int bmp_get_chip_type(struct i2c_client *client) { int err = 0; u8 chip_id = 0; struct bmp_i2c_data *obj = i2c_get_clientdata(client); BAR_FUN(f); err = bmp_i2c_read_block(client, BMP_CHIP_ID_REG, &chip_id, 0x01); if (err != 0) return err; switch (chip_id) { case BMP280_CHIP_ID1: case BMP280_CHIP_ID2: case BMP280_CHIP_ID3: obj->sensor_type = BMP280_TYPE; strcpy(obj->sensor_name, "bmp280"); break; default: obj->sensor_type = INVALID_TYPE; strcpy(obj->sensor_name, "unknown sensor"); break; } BAR_LOG("[%s]chip id = %#x, sensor name = %s\n", __func__, chip_id, obj->sensor_name); if (obj->sensor_type == INVALID_TYPE) { BAR_ERR("unknown pressure sensor\n"); return -1; } return 0; } static int bmp_get_calibration_data(struct i2c_client *client) { struct bmp_i2c_data *obj = (struct bmp_i2c_data *)i2c_get_clientdata(client); int status = 0; if (obj->sensor_type == BMP280_TYPE) { unsigned char a_data_u8r[8]; status = bmp_i2c_read_block(client, BMP280_CALIBRATION_DATA_START, a_data_u8r, 8); if (status < 0) return status; obj->bmp280_cali.dig_T1 = (BMP280_U16_t)((( (BMP280_U16_t)((unsigned char)a_data_u8r[1])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[0]); obj->bmp280_cali.dig_T2 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[3])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[2]); obj->bmp280_cali.dig_T3 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[5])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[4]); obj->bmp280_cali.dig_P1 = (BMP280_U16_t)((( (BMP280_U16_t)((unsigned char)a_data_u8r[7])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[6]); status = bmp_i2c_read_block(client, BMP280_CALIBRATION_DATA_START + 8, a_data_u8r, 8); if (status < 0) return status; obj->bmp280_cali.dig_P2 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[1])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[0]); obj->bmp280_cali.dig_P3 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[3])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[2]); obj->bmp280_cali.dig_P4 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[5])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[4]); obj->bmp280_cali.dig_P5 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[7])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[6]); status = bmp_i2c_read_block(client, BMP280_CALIBRATION_DATA_START + 16, a_data_u8r, 8); obj->bmp280_cali.dig_P6 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[1])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[0]); obj->bmp280_cali.dig_P7 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[3])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[2]); obj->bmp280_cali.dig_P8 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[5])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[4]); obj->bmp280_cali.dig_P9 = (BMP280_S16_t)((( (BMP280_S16_t)((signed char)a_data_u8r[7])) << SHIFT_LEFT_8_POSITION) | a_data_u8r[6]); } return 0; } static int bmp_set_powermode(struct i2c_client *client, enum BMP_POWERMODE_ENUM power_mode) { struct bmp_i2c_data *obj = i2c_get_clientdata(client); u8 err = 0, data = 0, actual_power_mode = 0; BAR_LOG("[%s] power_mode = %d, old power_mode = %d\n", __func__, power_mode, obj->power_mode); if (power_mode == obj->power_mode) return 0; mutex_lock(&obj->lock); if (obj->sensor_type == BMP280_TYPE) { /* BMP280 */ if (power_mode == BMP_SUSPEND_MODE) { actual_power_mode = BMP280_SLEEP_MODE; } else if (power_mode == BMP_NORMAL_MODE) { actual_power_mode = BMP280_NORMAL_MODE; } else { err = -EINVAL; BAR_ERR("invalid power mode = %d\n", power_mode); mutex_unlock(&obj->lock); return err; } err = bmp_i2c_read_block(client, BMP280_CTRLMEAS_REG_MODE__REG, &data, 1); data = BMP_SET_BITSLICE(data, BMP280_CTRLMEAS_REG_MODE, actual_power_mode); err += bmp_i2c_write_block(client, BMP280_CTRLMEAS_REG_MODE__REG, &data, 1); } if (err < 0) BAR_ERR("set power mode failed, err = %d, sensor name = %s\n", err, obj->sensor_name); else obj->power_mode = power_mode; mutex_unlock(&obj->lock); return 0; } static int bmp_set_filter(struct i2c_client *client, enum BMP_FILTER_ENUM filter) { struct bmp_i2c_data *obj = i2c_get_clientdata(client); u8 err = 0, data = 0, actual_filter = 0; BAR_LOG("[%s] hw filter = %d, old hw filter = %d\n", __func__, filter, obj->hw_filter); if (filter == obj->hw_filter) return 0; mutex_lock(&obj->lock); if (obj->sensor_type == BMP280_TYPE) { /* BMP280 */ if (filter == BMP_FILTER_OFF) actual_filter = BMP280_FILTERCOEFF_OFF; else if (filter == BMP_FILTER_2) actual_filter = BMP280_FILTERCOEFF_2; else if (filter == BMP_FILTER_4) actual_filter = BMP280_FILTERCOEFF_4; else if (filter == BMP_FILTER_8) actual_filter = BMP280_FILTERCOEFF_8; else if (filter == BMP_FILTER_16) actual_filter = BMP280_FILTERCOEFF_16; else { err = -EINVAL; BAR_ERR("invalid hw filter = %d\n", filter); mutex_unlock(&obj->lock); return err; } err = bmp_i2c_read_block(client, BMP280_CONFIG_REG_FILTER__REG, &data, 1); data = BMP_SET_BITSLICE(data, BMP280_CONFIG_REG_FILTER, actual_filter); err += bmp_i2c_write_block(client, BMP280_CONFIG_REG_FILTER__REG, &data, 1); } if (err < 0) BAR_ERR("set hw filter failed, err = %d, sensor name = %s\n", err, obj->sensor_name); else obj->hw_filter = filter; mutex_unlock(&obj->lock); return err; } static int bmp_set_oversampling_p(struct i2c_client *client, enum BMP_OVERSAMPLING_ENUM oversampling_p) { struct bmp_i2c_data *obj = i2c_get_clientdata(client); u8 err = 0, data = 0, actual_oversampling_p = 0; BAR_LOG("[%s] oversampling_p = %d, old oversampling_p = %d\n", __func__, oversampling_p, obj->oversampling_p); if (oversampling_p == obj->oversampling_p) return 0; mutex_lock(&obj->lock); if (obj->sensor_type == BMP280_TYPE) { /* BMP280 */ if (oversampling_p == BMP_OVERSAMPLING_SKIPPED) actual_oversampling_p = BMP280_OVERSAMPLING_SKIPPED; else if (oversampling_p == BMP_OVERSAMPLING_1X) actual_oversampling_p = BMP280_OVERSAMPLING_1X; else if (oversampling_p == BMP_OVERSAMPLING_2X) actual_oversampling_p = BMP280_OVERSAMPLING_2X; else if (oversampling_p == BMP_OVERSAMPLING_4X) actual_oversampling_p = BMP280_OVERSAMPLING_4X; else if (oversampling_p == BMP_OVERSAMPLING_8X) actual_oversampling_p = BMP280_OVERSAMPLING_8X; else if (oversampling_p == BMP_OVERSAMPLING_16X) actual_oversampling_p = BMP280_OVERSAMPLING_16X; else { err = -EINVAL; BAR_ERR("invalid oversampling_p = %d\n", oversampling_p); mutex_unlock(&obj->lock); return err; } err = bmp_i2c_read_block(client, BMP280_CTRLMEAS_REG_OSRSP__REG, &data, 1); data = BMP_SET_BITSLICE(data, BMP280_CTRLMEAS_REG_OSRSP, actual_oversampling_p); err += bmp_i2c_write_block(client, BMP280_CTRLMEAS_REG_OSRSP__REG, &data, 1); } if (err < 0) BAR_ERR("set pressure oversampling failed, err = %d," "sensor name = %s\n", err, obj->sensor_name); else obj->oversampling_p = oversampling_p; mutex_unlock(&obj->lock); return err; } static int bmp_set_oversampling_t(struct i2c_client *client, enum BMP_OVERSAMPLING_ENUM oversampling_t) { struct bmp_i2c_data *obj = i2c_get_clientdata(client); u8 err = 0, data = 0, actual_oversampling_t = 0; BAR_LOG("[%s] oversampling_t = %d, old oversampling_t = %d\n", __func__, oversampling_t, obj->oversampling_t); if (oversampling_t == obj->oversampling_t) return 0; mutex_lock(&obj->lock); if (obj->sensor_type == BMP280_TYPE) { /* BMP280 */ if (oversampling_t == BMP_OVERSAMPLING_SKIPPED) actual_oversampling_t = BMP280_OVERSAMPLING_SKIPPED; else if (oversampling_t == BMP_OVERSAMPLING_1X) actual_oversampling_t = BMP280_OVERSAMPLING_1X; else if (oversampling_t == BMP_OVERSAMPLING_2X) actual_oversampling_t = BMP280_OVERSAMPLING_2X; else if (oversampling_t == BMP_OVERSAMPLING_4X) actual_oversampling_t = BMP280_OVERSAMPLING_4X; else if (oversampling_t == BMP_OVERSAMPLING_8X) actual_oversampling_t = BMP280_OVERSAMPLING_8X; else if (oversampling_t == BMP_OVERSAMPLING_16X) actual_oversampling_t = BMP280_OVERSAMPLING_16X; else { err = -EINVAL; BAR_ERR("invalid oversampling_t = %d\n", oversampling_t); mutex_unlock(&obj->lock); return err; } err = bmp_i2c_read_block(client, BMP280_CTRLMEAS_REG_OSRST__REG, &data, 1); data = BMP_SET_BITSLICE(data, BMP280_CTRLMEAS_REG_OSRST, actual_oversampling_t); err += bmp_i2c_write_block(client, BMP280_CTRLMEAS_REG_OSRST__REG, &data, 1); } if (err < 0) BAR_ERR("set temperature oversampling failed, err = %d," "sensor name = %s\n", err, obj->sensor_name); else obj->oversampling_t = oversampling_t; mutex_unlock(&obj->lock); return err; } static int bmp_read_raw_temperature(struct i2c_client *client, s32 *temperature) { struct bmp_i2c_data *obj = i2c_get_clientdata(client); s32 err = 0; if (NULL == client) { err = -EINVAL; return err; } mutex_lock(&obj->lock); if (obj->sensor_type == BMP280_TYPE) { /* BMP280 */ unsigned char a_data_u8r[3] = { 0 }; err = bmp_i2c_read_block(client, BMP280_TEMPERATURE_MSB_REG, a_data_u8r, 3); if (err < 0) { BAR_ERR("read raw temperature failed, err = %d\n", err); mutex_unlock(&obj->lock); return err; } *temperature = (BMP280_S32_t) ((((BMP280_U32_t) (a_data_u8r[0])) << SHIFT_LEFT_12_POSITION) | (((BMP280_U32_t) (a_data_u8r[1])) << SHIFT_LEFT_4_POSITION) | ((BMP280_U32_t) a_data_u8r[2] >> SHIFT_RIGHT_4_POSITION) ); } obj->last_temp_measurement = jiffies; mutex_unlock(&obj->lock); return err; } static int bmp_read_raw_pressure(struct i2c_client *client, s32 *pressure) { struct bmp_i2c_data *priv = i2c_get_clientdata(client); s32 err = 0; if (NULL == client) { err = -EINVAL; return err; } mutex_lock(&priv->lock); if (priv->sensor_type == BMP280_TYPE) { /* BMP280 */ unsigned char a_data_u8r[3] = { 0 }; err = bmp_i2c_read_block(client, BMP280_PRESSURE_MSB_REG, a_data_u8r, 3); if (err < 0) { BAR_ERR("read raw pressure failed, err = %d\n", err); mutex_unlock(&priv->lock); return err; } *pressure = (BMP280_S32_t) ((((BMP280_U32_t) (a_data_u8r[0])) << SHIFT_LEFT_12_POSITION) | (((BMP280_U32_t) (a_data_u8r[1])) << SHIFT_LEFT_4_POSITION) | ((BMP280_U32_t) a_data_u8r[2] >> SHIFT_RIGHT_4_POSITION) ); } #ifdef CONFIG_BMP_LOWPASS /* *Example: firlen = 16, filter buffer = [0] ... [15], *when 17th data come, replace [0] with this new data. *Then, average this filter buffer and report average value to upper layer. */ if (atomic_read(&priv->filter)) { if (atomic_read(&priv->fir_en) && !atomic_read(&priv->suspend)) { int idx = 0, firlen = atomic_read(&priv->firlen); if (priv->fir.num < firlen) { priv->fir.raw[priv->fir.num][BMP_PRESSURE] = *pressure; priv->fir.sum[BMP_PRESSURE] += *pressure; if (atomic_read(&priv->trace) & BAR_TRC_FILTER) BAR_LOG("add [%2d] [%5d] => [%5d]\n", priv->fir.num, priv->fir.raw [priv->fir.num][BMP_PRESSURE], priv->fir.sum[BMP_PRESSURE]); priv->fir.num++; priv->fir.idx++; } else { idx = priv->fir.idx % firlen; priv->fir.sum[BMP_PRESSURE] -= priv->fir.raw[idx][BMP_PRESSURE]; priv->fir.raw[idx][BMP_PRESSURE] = *pressure; priv->fir.sum[BMP_PRESSURE] += *pressure; priv->fir.idx++; *pressure = priv->fir.sum[BMP_PRESSURE] / firlen; if (atomic_read(&priv->trace) & BAR_TRC_FILTER) BAR_LOG("add [%2d][%5d]=>[%5d]:[%5d]\n", idx, priv->fir.raw[idx][BMP_PRESSURE], priv->fir.sum[BMP_PRESSURE], *pressure); } } } #endif mutex_unlock(&priv->lock); return err; } /* *get compensated temperature *unit:10 degrees centigrade */ static int bmp_get_temperature(struct i2c_client *client, char *buf, int bufsize) { struct bmp_i2c_data *obj = i2c_get_clientdata(client); int status; s32 utemp = 0; /* uncompensated temperature */ s32 temperature = 0; if (NULL == buf) return -1; if (NULL == client) { *buf = 0; return -2; } status = bmp_read_raw_temperature(client, &utemp); if (status != 0) return status; if (obj->sensor_type == BMP280_TYPE) { /* BMP280 */ BMP280_S32_t v_x1_u32r = 0; BMP280_S32_t v_x2_u32r = 0; v_x1_u32r = ((((utemp >> 3) - ((BMP280_S32_t) obj->bmp280_cali.dig_T1 << 1))) * ((BMP280_S32_t) obj->bmp280_cali.dig_T2)) >> 11; v_x2_u32r = (((((utemp >> 4) - ((BMP280_S32_t) obj->bmp280_cali.dig_T1)) * ((utemp >> 4) - ((BMP280_S32_t) obj->bmp280_cali.dig_T1)) ) >> 12) * ((BMP280_S32_t) obj->bmp280_cali.dig_T3)) >> 14; mutex_lock(&obj->lock); obj->t_fine = v_x1_u32r + v_x2_u32r; mutex_unlock(&obj->lock); temperature = (obj->t_fine * 5 + 128) >> 8; } sprintf(buf, "%08x", temperature); if (atomic_read(&obj->trace) & BAR_TRC_IOCTL) BAR_LOG("compensated temperature value: %s\n", buf); return status; } /* *get compensated pressure *unit: hectopascal(hPa) */ static int bmp_get_pressure(struct i2c_client *client, char *buf, int bufsize) { struct bmp_i2c_data *obj = i2c_get_clientdata(client); int status = 0, err = 0; s32 temperature = 0, upressure = 0, pressure = 0; char temp_buf[BMP_BUFSIZE]; if (NULL == buf) return -1; if (NULL == client) { *buf = 0; return -2; } /* update the ambient temperature according to the given meas. period */ if (time_after(jiffies, obj->last_temp_measurement + obj->temp_measurement_period)) { status = bmp_get_temperature(client, temp_buf, BMP_BUFSIZE); /* update t_fine */ if (status != 0) goto exit; err = kstrtoint(temp_buf, 16, &temperature); if (err) goto exit; } status = bmp_read_raw_pressure(client, &upressure); if (status != 0) goto exit; if (obj->sensor_type == BMP280_TYPE) { /* BMP280 */ BMP280_S64_t v_x1_u32r = 0; BMP280_S64_t v_x2_u32r = 0; BMP280_S64_t p = 0; v_x1_u32r = ((BMP280_S64_t) obj->t_fine) - 128000; v_x2_u32r = v_x1_u32r * v_x1_u32r * (BMP280_S64_t) obj->bmp280_cali.dig_P6; v_x2_u32r = v_x2_u32r + ((v_x1_u32r * (BMP280_S64_t) obj->bmp280_cali.dig_P5) << 17); v_x2_u32r = v_x2_u32r + (((BMP280_S64_t) obj->bmp280_cali.dig_P4) << 35); v_x1_u32r = ((v_x1_u32r * v_x1_u32r * (BMP280_S64_t) obj->bmp280_cali.dig_P3) >> 8) + ((v_x1_u32r * (BMP280_S64_t) obj->bmp280_cali.dig_P2) << 12); v_x1_u32r = (((((BMP280_S64_t) 1) << 47) + v_x1_u32r)) * ((BMP280_S64_t) obj->bmp280_cali.dig_P1) >> 33; if (v_x1_u32r == 0) /* Avoid exception caused by division by zero */ return -1; p = 1048576 - upressure; p = div64_s64(((p << 31) - v_x2_u32r) * 3125, v_x1_u32r); v_x1_u32r = (((BMP280_S64_t) obj->bmp280_cali.dig_P9) * (p >> 13) * (p >> 13)) >> 25; v_x2_u32r = (((BMP280_S64_t) obj->bmp280_cali.dig_P8) * p) >> 19; p = ((p + v_x1_u32r + v_x2_u32r) >> 8) + (((BMP280_S64_t) obj->bmp280_cali.dig_P7) << 4); pressure = (BMP280_U32_t) p / 256; } sprintf(buf, "%08x", pressure); if (atomic_read(&obj->trace) & BAR_TRC_IOCTL) BAR_LOG("compensated pressure value: %s\n", buf); exit: return status; } /* bmp setting initialization */ static int bmp_init_client(struct i2c_client *client) { int err = 0; BAR_FUN(); err = bmp_get_chip_type(client); if (err < 0) { BAR_ERR("get chip type failed, err = %d\n", err); return err; } err = bmp_get_calibration_data(client); if (err < 0) { BAR_ERR("get calibration data failed, err = %d\n", err); return err; } err = bmp_set_powermode(client, BMP_SUSPEND_MODE); if (err < 0) { BAR_ERR("set power mode failed, err = %d\n", err); return err; } err = bmp_set_filter(client, BMP_FILTER_8); if (err < 0) { BAR_ERR("set hw filter failed, err = %d\n", err); return err; } err = bmp_set_oversampling_p(client, BMP_OVERSAMPLING_8X); if (err < 0) { BAR_ERR("set pressure oversampling failed, err = %d\n", err); return err; } err = bmp_set_oversampling_t(client, BMP_OVERSAMPLING_1X); if (err < 0) { BAR_ERR("set temperature oversampling failed, err = %d\n", err); return err; } return 0; } static int bmp280_verify_i2c_disable_switch(struct bmp_i2c_data *obj) { int err = 0; u8 reg_val = 0xFF; err = bmp_i2c_read_block(obj->client, BMP280_I2C_DISABLE_SWITCH, ®_val, 1); if (err < 0) { err = -EIO; BAR_ERR("bus read failed\n"); return err; } if (reg_val == 0x00) { BAR_LOG("bmp280 i2c interface is available\n"); return 0; /* OK */ } BAR_ERR("verification of i2c interface is failure\n"); return -1; /* Failure */ } static int bmp_check_calib_param(struct bmp_i2c_data *obj) { struct bmp280_calibration_data *cali = &(obj->bmp280_cali); /* verify that not all calibration parameters are 0 */ if (cali->dig_T1 == 0 && cali->dig_T2 == 0 && cali->dig_T3 == 0 && cali->dig_P1 == 0 && cali->dig_P2 == 0 && cali->dig_P3 == 0 && cali->dig_P4 == 0 && cali->dig_P5 == 0 && cali->dig_P6 == 0 && cali->dig_P7 == 0 && cali->dig_P8 == 0 && cali->dig_P9 == 0) { BAR_ERR("all calibration parameters are zero\n"); return -2; } /* verify whether all the calibration parameters are within range */ if (cali->dig_T1 < 19000 || cali->dig_T1 > 35000) return -3; else if (cali->dig_T2 < 22000 || cali->dig_T2 > 30000) return -4; else if (cali->dig_T3 < -3000 || cali->dig_T3 > -1000) return -5; else if (cali->dig_P1 < 30000 || cali->dig_P1 > 42000) return -6; else if (cali->dig_P2 < -12970 || cali->dig_P2 > -8000) return -7; else if (cali->dig_P3 < -5000 || cali->dig_P3 > 8000) return -8; else if (cali->dig_P4 < -10000 || cali->dig_P4 > 18000) return -9; else if (cali->dig_P5 < -500 || cali->dig_P5 > 1100) return -10; else if (cali->dig_P6 < -1000 || cali->dig_P6 > 1000) return -11; else if (cali->dig_P7 < -32768 || cali->dig_P7 > 32767) return -12; else if (cali->dig_P8 < -30000 || cali->dig_P8 > 10000) return -13; else if (cali->dig_P9 < -10000 || cali->dig_P9 > 30000) return -14; BAR_LOG("calibration parameters are OK\n"); return 0; } static int bmp_check_pt(struct bmp_i2c_data *obj) { int err = 0; int temperature; int pressure; char t[BMP_BUFSIZE] = "", p[BMP_BUFSIZE] = ""; err = bmp_set_powermode(obj->client, BMP_NORMAL_MODE); if (err < 0) { BAR_ERR("set power mode failed, err = %d\n", err); return -15; } mdelay(50); /* check ut and t */ bmp_get_temperature(obj->client, t, BMP_BUFSIZE); err = kstrtoint(t, 16, &temperature); if (err == 0) if (temperature <= 0 || temperature >= 40 * 100) { BAR_ERR("temperature value is out of range:%d*0.01degree\n", temperature); return -16; } /* check up and p */ bmp_get_pressure(obj->client, p, BMP_BUFSIZE); err = kstrtoint(p, 16, &pressure); if (err == 0) if (pressure <= 900 * 100 || pressure >= 1100 * 100) { BAR_ERR("pressure value is out of range:%d Pa\n", pressure); return -17; } BAR_LOG("bmp280 temperature and pressure values are OK\n"); return 0; } static int bmp_do_selftest(struct bmp_i2c_data *obj) { int err = 0; /* 0: failed, 1: success */ u8 selftest = 0; err = bmp280_verify_i2c_disable_switch(obj); if (err) { selftest = 0; BAR_ERR("bmp280_verify_i2c_disable_switch:err=%d\n", err); goto exit; } err = bmp_check_calib_param(obj); if (err) { selftest = 0; BAR_ERR("bmp_check_calib_param:err=%d\n", err); goto exit; } err = bmp_check_pt(obj); if (err) { selftest = 0; BAR_ERR("bmp_check_pt:err=%d\n", err); goto exit; } /* selftest is OK */ selftest = 1; BAR_LOG("bmp280 self test is OK\n"); exit: return selftest; } static ssize_t show_chipinfo_value(struct device_driver *ddri, char *buf) { struct bmp_i2c_data *obj = obj_i2c_data; if (NULL == obj) { BAR_ERR("bmp i2c data pointer is null\n"); return 0; } return snprintf(buf, PAGE_SIZE, "%s\n", obj->sensor_name); } static ssize_t show_sensordata_value(struct device_driver *ddri, char *buf) { struct bmp_i2c_data *obj = obj_i2c_data; char strbuf[BMP_BUFSIZE] = ""; if (NULL == obj) { BAR_ERR("bmp i2c data pointer is null\n"); return 0; } bmp_get_pressure(obj->client, strbuf, BMP_BUFSIZE); return snprintf(buf, PAGE_SIZE, "%s\n", strbuf); } static ssize_t show_trace_value(struct device_driver *ddri, char *buf) { ssize_t res = 0; struct bmp_i2c_data *obj = obj_i2c_data; if (obj == NULL) { BAR_ERR("bmp i2c data pointer is null\n"); return 0; } res = snprintf(buf, PAGE_SIZE, "0x%04X\n", atomic_read(&obj->trace)); return res; } static ssize_t store_trace_value(struct device_driver *ddri, const char *buf, size_t count) { struct bmp_i2c_data *obj = obj_i2c_data; int trace = 0, err = 0; if (obj == NULL) { BAR_ERR("i2c_data obj is null\n"); return 0; } err = kstrtoint(buf, 10, &trace); if (err == 0) atomic_set(&obj->trace, trace); else BAR_ERR("invalid content: '%s', length = %d\n", buf, (int)count); return count; } static ssize_t show_status_value(struct device_driver *ddri, char *buf) { ssize_t len = 0; struct bmp_i2c_data *obj = obj_i2c_data; if (obj == NULL) { BAR_ERR("bmp i2c data pointer is null\n"); return 0; } if (obj->hw) len += snprintf(buf + len, PAGE_SIZE - len, "CUST: %d %d (%d %d)\n", obj->hw->i2c_num, obj->hw->direction, obj->hw->power_id, obj->hw->power_vol); else len += snprintf(buf + len, PAGE_SIZE - len, "CUST: NULL\n"); len += snprintf(buf + len, PAGE_SIZE - len, "i2c addr:%#x,ver:%s\n", obj->client->addr, BMP_DRIVER_VERSION); return len; } static ssize_t show_power_mode_value(struct device_driver *ddri, char *buf) { ssize_t len = 0; struct bmp_i2c_data *obj = obj_i2c_data; if (obj == NULL) { BAR_ERR("bmp i2c data pointer is null\n"); return 0; } len += snprintf(buf + len, PAGE_SIZE - len, "%s mode\n", obj->power_mode == BMP_NORMAL_MODE ? "normal" : "suspend"); return len; } static ssize_t store_power_mode_value(struct device_driver *ddri, const char *buf, size_t count) { struct bmp_i2c_data *obj = obj_i2c_data; unsigned long power_mode = 0; int err = 0; if (obj == NULL) { BAR_ERR("bmp i2c data pointer is null\n"); return 0; } err = kstrtoul(buf, 10, &power_mode); if (err == 0) { err = bmp_set_powermode(obj->client, (enum BMP_POWERMODE_ENUM)(!!(power_mode))); if (err) return err; return count; } return err; } static ssize_t show_selftest_value(struct device_driver *ddri, char *buf) { struct bmp_i2c_data *obj = obj_i2c_data; if (NULL == obj) { BAR_ERR("bmp i2c data pointer is null\n"); return 0; } return snprintf(buf, PAGE_SIZE, "%d\n", bmp_do_selftest(obj)); } static DRIVER_ATTR(chipinfo, S_IRUGO, show_chipinfo_value, NULL); static DRIVER_ATTR(sensordata, S_IRUGO, show_sensordata_value, NULL); static DRIVER_ATTR(trace, S_IWUSR | S_IRUGO, show_trace_value, store_trace_value); static DRIVER_ATTR(status, S_IRUGO, show_status_value, NULL); static DRIVER_ATTR(powermode, S_IWUSR | S_IRUGO, show_power_mode_value, store_power_mode_value); static DRIVER_ATTR(selftest, S_IRUGO, show_selftest_value, NULL); static struct driver_attribute *bmp_attr_list[] = { &driver_attr_chipinfo, /* chip information */ &driver_attr_sensordata, /* dump sensor data */ &driver_attr_trace, /* trace log */ &driver_attr_status, /* cust setting */ &driver_attr_powermode, /* power mode */ &driver_attr_selftest, /* self test */ }; static int bmp_create_attr(struct device_driver *driver) { int idx = 0, err = 0; int num = (int)(sizeof(bmp_attr_list) / sizeof(bmp_attr_list[0])); if (NULL == driver) return -EINVAL; for (idx = 0; idx < num; idx++) { err = driver_create_file(driver, bmp_attr_list[idx]); if (err) { BAR_ERR("driver_create_file (%s) = %d\n", bmp_attr_list[idx]->attr.name, err); break; } } return err; } static int bmp_delete_attr(struct device_driver *driver) { int idx = 0, err = 0; int num = (int)(sizeof(bmp_attr_list) / sizeof(bmp_attr_list[0])); if (NULL == driver) return -EINVAL; for (idx = 0; idx < num; idx++) driver_remove_file(driver, bmp_attr_list[idx]); return err; } static int bmp_open(struct inode *inode, struct file *file) { file->private_data = obj_i2c_data; if (file->private_data == NULL) { BAR_ERR("null pointer\n"); return -EINVAL; } return nonseekable_open(inode, file); } static int bmp_release(struct inode *inode, struct file *file) { file->private_data = NULL; return 0; } static long bmp_unlocked_ioctl(struct file *file, unsigned int cmd, unsigned long arg) { struct bmp_i2c_data *obj = (struct bmp_i2c_data *)file->private_data; struct i2c_client *client = obj->client; char strbuf[BMP_BUFSIZE]; u32 dat = 0; void __user *data; int err = 0; if (_IOC_DIR(cmd) & _IOC_READ) err = !access_ok(VERIFY_WRITE, (void __user *)arg, _IOC_SIZE(cmd)); else if (_IOC_DIR(cmd) & _IOC_WRITE) err = !access_ok(VERIFY_READ, (void __user *)arg, _IOC_SIZE(cmd)); if (err) { BAR_ERR("access error: %08X, (%2d, %2d)\n", cmd, _IOC_DIR(cmd), _IOC_SIZE(cmd)); return -EFAULT; } switch (cmd) { case BAROMETER_IOCTL_INIT: bmp_init_client(client); err = bmp_set_powermode(client, BMP_NORMAL_MODE); if (err < 0) { err = -EFAULT; break; } break; case BAROMETER_IOCTL_READ_CHIPINFO: data = (void __user *)arg; if (NULL == data) { err = -EINVAL; break; } strcpy(strbuf, obj->sensor_name); if (copy_to_user(data, strbuf, strlen(strbuf) + 1)) { err = -EFAULT; break; } break; case BAROMETER_GET_PRESS_DATA: data = (void __user *)arg; if (NULL == data) { err = -EINVAL; break; } bmp_get_pressure(client, strbuf, BMP_BUFSIZE); err = kstrtoint(strbuf, 16, &dat); if (err == 0) if (copy_to_user(data, &dat, sizeof(dat))) { err = -EFAULT; break; } break; case BAROMETER_GET_TEMP_DATA: data = (void __user *)arg; if (NULL == data) { err = -EINVAL; break; } bmp_get_temperature(client, strbuf, BMP_BUFSIZE); err = kstrtoint(strbuf, 16, &dat); if (err == 0) if (copy_to_user(data, &dat, sizeof(dat))) { err = -EFAULT; break; } break; default: BAR_ERR("unknown IOCTL: 0x%08x\n", cmd); err = -ENOIOCTLCMD; break; } return err; } static const struct file_operations bmp_fops = { .owner = THIS_MODULE, .open = bmp_open, .release = bmp_release, .unlocked_ioctl = bmp_unlocked_ioctl, }; static struct miscdevice bmp_device = { .minor = MISC_DYNAMIC_MINOR, .name = "barometer", .fops = &bmp_fops, }; static int bmp_suspend(struct i2c_client *client, pm_message_t msg) { struct bmp_i2c_data *obj = i2c_get_clientdata(client); int err = 0; BAR_FUN(); mutex_lock(&obj->lock); if (msg.event == PM_EVENT_SUSPEND) { if (NULL == obj) { BAR_ERR("null pointer\n"); mutex_unlock(&obj->lock); return -EINVAL; } atomic_set(&obj->suspend, 1); err = bmp_set_powermode(obj->client, BMP_SUSPEND_MODE); if (err) { BAR_ERR("bmp set suspend mode failed, err = %d\n", err); mutex_unlock(&obj->lock); return err; } } mutex_unlock(&obj->lock); return err; } static int bmp_resume(struct i2c_client *client) { struct bmp_i2c_data *obj = i2c_get_clientdata(client); int err = 0; BAR_FUN(); mutex_lock(&obj->lock); if (NULL == obj) { BAR_ERR("null pointer\n"); mutex_unlock(&obj->lock); return -EINVAL; } err = bmp_init_client(obj->client); if (err) { BAR_ERR("initialize client fail\n"); mutex_unlock(&obj->lock); return err; } #ifdef CONFIG_BMP_LOWPASS memset(&obj->fir, 0x00, sizeof(obj->fir)); #endif atomic_set(&obj->suspend, 0); mutex_unlock(&obj->lock); return 0; } static int bmp_i2c_detect(struct i2c_client *client, struct i2c_board_info *info) { strcpy(info->type, BMP_DEV_NAME); return 0; } static int bmp280_open_report_data(int open) { return 0; } static int bmp280_enable_nodata(int en) { int res = 0; int retry = 0; bool power = false; if (1 == en) power = true; if (0 == en) power = false; for (retry = 0; retry < 3; retry++) { res = bmp_set_powermode(obj_i2c_data->client, (enum BMP_POWERMODE_ENUM)(!!power)); if (res == 0) { BAR_LOG("bmp_set_powermode done\n"); break; } BAR_ERR("bmp_set_powermode fail\n"); } if (res != 0) { BAR_ERR("bmp_set_powermode fail!\n"); return -1; } BAR_LOG("bmp_set_powermode OK!\n"); return 0; } static int bmp280_set_delay(u64 ns) { return 0; } static int bmp280_get_data(int *value, int *status) { char buff[BMP_BUFSIZE]; int err = 0; err = bmp_get_pressure(obj_i2c_data->client, buff, BMP_BUFSIZE); if (err) { BAR_ERR("get compensated pressure value failed," "err = %d\n", err); return -1; } err = kstrtoint(buff, 16, value); if (err == 0) *status = SENSOR_STATUS_ACCURACY_MEDIUM; return 0; } static int bmp_i2c_probe(struct i2c_client *client, const struct i2c_device_id *id) { struct bmp_i2c_data *obj; struct baro_control_path ctl = { 0 }; struct baro_data_path data = { 0 }; int err = 0; BAR_FUN(); obj = kzalloc(sizeof(*obj), GFP_KERNEL); if (!obj) { err = -ENOMEM; goto exit; } obj->hw = hw; obj_i2c_data = obj; obj->client = client; i2c_set_clientdata(client, obj); atomic_set(&obj->trace, 0); atomic_set(&obj->suspend, 0); obj->power_mode = BMP_UNDEFINED_POWERMODE; obj->hw_filter = BMP_UNDEFINED_FILTER; obj->oversampling_p = BMP_UNDEFINED_OVERSAMPLING; obj->oversampling_t = BMP_UNDEFINED_OVERSAMPLING; obj->last_temp_measurement = 0; obj->temp_measurement_period = 1 * HZ; /* temperature update period:1s */ mutex_init(&obj->lock); #ifdef CONFIG_BMP_LOWPASS if (obj->hw->firlen > C_MAX_FIR_LENGTH) atomic_set(&obj->firlen, C_MAX_FIR_LENGTH); else atomic_set(&obj->firlen, obj->hw->firlen); if (atomic_read(&obj->firlen) > 0) atomic_set(&obj->fir_en, 1); #endif err = bmp_init_client(client); if (err) goto exit_init_client_failed; err = misc_register(&bmp_device); if (err) { BAR_ERR("misc device register failed, err = %d\n", err); goto exit_misc_device_register_failed; } ctl.is_use_common_factory = false; err = bmp_create_attr(&(bmp280_init_info.platform_diver_addr->driver)); if (err) { BAR_ERR("create attribute failed, err = %d\n", err); goto exit_create_attr_failed; } ctl.open_report_data = bmp280_open_report_data; ctl.enable_nodata = bmp280_enable_nodata; ctl.set_delay = bmp280_set_delay; ctl.is_report_input_direct = false; ctl.is_support_batch = obj->hw->is_batch_supported; err = baro_register_control_path(&ctl); if (err) { BAR_ERR("register baro control path err\n"); goto exit_hwmsen_attach_pressure_failed; } data.get_data = bmp280_get_data; data.vender_div = 100; err = baro_register_data_path(&data); if (err) { BAR_ERR("baro_register_data_path failed, err = %d\n", err); goto exit_hwmsen_attach_pressure_failed; } err = batch_register_support_info(ID_PRESSURE, obj->hw->is_batch_supported, data.vender_div, 0); if (err) { BAR_ERR("register baro batch support err = %d\n", err); goto exit_hwmsen_attach_pressure_failed; } bmp280_init_flag = 0; BAR_LOG("%s: OK\n", __func__); return 0; exit_hwmsen_attach_pressure_failed: bmp_delete_attr(&(bmp280_init_info.platform_diver_addr->driver)); exit_create_attr_failed: misc_deregister(&bmp_device); exit_misc_device_register_failed: exit_init_client_failed: kfree(obj); exit: BAR_ERR("err = %d\n", err); bmp280_init_flag = -1; return err; } static int bmp_i2c_remove(struct i2c_client *client) { int err = 0; err = bmp_delete_attr(&(bmp280_init_info.platform_diver_addr->driver)); if (err) BAR_ERR("bmp_delete_attr failed, err = %d\n", err); err = misc_deregister(&bmp_device); if (err) BAR_ERR("misc_deregister failed, err = %d\n", err); obj_i2c_data = NULL; i2c_unregister_device(client); kfree(i2c_get_clientdata(client)); return 0; } #ifdef CONFIG_OF static const struct of_device_id baro_of_match[] = { {.compatible = "mediatek,barometer"}, {}, }; #endif static struct i2c_driver bmp_i2c_driver = { .driver = { .name = BMP_DEV_NAME, #ifdef CONFIG_OF .of_match_table = baro_of_match, #endif }, .probe = bmp_i2c_probe, .remove = bmp_i2c_remove, .detect = bmp_i2c_detect, .suspend = bmp_suspend, .resume = bmp_resume, .id_table = bmp_i2c_id, }; static int bmp280_remove(void) { struct baro_hw *hw = hw; BAR_FUN(); bmp_power(hw, 0); i2c_del_driver(&bmp_i2c_driver); return 0; } static int bmp280_local_init(void) { struct baro_hw *hw = hw; bmp_power(hw, 1); if (i2c_add_driver(&bmp_i2c_driver)) { BAR_ERR("add driver error\n"); return -1; } if (-1 == bmp280_init_flag) return -1; return 0; } static int __init bmp_init(void) { const char *name = "mediatek,bmp280"; hw = get_baro_dts_func(name, hw); if (!hw) BAR_ERR("get dts info fail\n"); baro_driver_add(&bmp280_init_info); return 0; } static void __exit bmp_exit(void) { BAR_FUN(); } module_init(bmp_init); module_exit(bmp_exit); MODULE_LICENSE("GPLv2"); MODULE_DESCRIPTION("BMP280 I2C Driver"); MODULE_AUTHOR("hongxu.zhao@mediatek.com"); MODULE_VERSION(BMP_DRIVER_VERSION);