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#ifndef BMI160_H
#define BMI160_H

#include "mbed.h"

/**
@brief The BMI160 is a small, low power, low noise 16-bit inertial measurement
unit designed for use in mobile applications like augmented reality or indoor
navigation which require highly accurate, real-time sensor data.

In full operation mode, with both the accelerometer and gyroscope enabled, the
current consumption is typically 950 μA, enabling always-on applications in
battery driven devices. It is available in a compact 14-pin 2.5 x 3.0 x 0.8 mm³
LGA package."

This class is an abstract base class and can not be instaniated, use BMI160_I2C 
or BMI160_SPI.
*/
class BMI160
{
public:

    ///Return value on success.
    static const uint8_t RTN_NO_ERROR = 0;
    
    ///BMI160 registers
    enum Registers
    {
        CHIP_ID = 0x00,  ///<Chip Identification. 
        ERR_REG = 0x02,  ///<Reports sensor error flags.  Flags reset when read.
        PMU_STATUS,      ///<Reports current power mode for sensors.
        DATA_0,          ///<MAG_X axis bits7:0
        DATA_1,          ///<MAG_X axis bits15:8
        DATA_2,          ///<MAG_Y axis bits7:0
        DATA_3,          ///<MAG_Y axis bits15:8
        DATA_4,          ///<MAG_Z axis bits7:0
        DATA_5,          ///<MAG_Z axis bits15:8
        DATA_6,          ///<RHALL bits7:0
        DATA_7,          ///<RHALL bits15:8
        DATA_8,          ///<GYR_X axis bits7:0
        DATA_9,          ///<GYR_X axis bits15:8
        DATA_10,         ///<GYR_Y axis bits7:0
        DATA_11,         ///<GYR_Y axis bits15:8
        DATA_12,         ///<GYR_Z axis bits7:0
        DATA_13,         ///<GYR_Z axis bits15:8
        DATA_14,         ///<ACC_X axis bits7:0
        DATA_15,         ///<ACC_X axis bits15:8
        DATA_16,         ///<ACC_Y axis bits7:0
        DATA_17,         ///<ACC_Y axis bits15:8
        DATA_18,         ///<ACC_Z axis bits7:0
        DATA_19,         ///<ACC_Z axis bits15:8
        SENSORTIME_0,    ///<24bit counter synchronized with data, bits7:0
        SENSORTIME_1,    ///<24bit counter synchronized with data, bits15:8
        SENSORTIME_2,    ///<24bit counter synchronized with data, bits23:16
        STATUS,          ///<Reports sensors status flags
        INT_STATUS_0,    ///<Contains interrupt status flags
        INT_STATUS_1,    ///<Contains interrupt status flags
        INT_STATUS_2,    ///<Contains interrupt status flags
        INT_STATUS_3,    ///<Contains interrupt status flags
        TEMPERATURE_0,   ///<Contains temperature of sensor, bits7:0
        TEMPERATURE_1,   ///<Contains temperature of sensor, bits15:8
        FIFO_LENGTH_0,   ///<Current fill level of FIFO, bits7:0
        FIFO_LENGTH_1,   ///<Current fill level of FIFO, bits10:8
        FIFO_DATA,       ///<FIFO data read out register, burst read
        ACC_CONF = 0x40, ///<Set ODR, bandwidth, and read mode of accelerometer
        ACC_RANGE,       ///<Sets accelerometer g-range
        GYR_CONF,        ///<Set ODR, bandwidth, and read mode of gyroscope
        GYR_RANGE,       ///<Sets gyroscope angular rate measurement range
        MAG_CONF,        ///<Sets ODR of magnetometer interface
        FIFO_DOWNS,      ///<Sets down sampling ratios of accel and gyro data 
                         ///<for FIFO
        FIFO_CONFIG_0,   ///<Sets FIFO Watermark
        FIFO_CONFIG_1,   ///<Sets which sensor data is available in FIFO, 
                         ///<Header/Headerless mode, Ext Int tagging, Sensortime
        MAG_IF_0 = 0x4B, ///<Magnetometer 7-bit I2C address, bits7:1
        MAG_IF_1,        ///<Magnetometer interface configuration
        MAG_IF_2,        ///<Magnetometer address to read
        MAG_IF_3,        ///<Magnetometer address to write
        MAG_IF_4,        ///<Magnetometer data to write
        INT_EN_0,        ///<Interrupt enable bits
        INT_EN_1,        ///<Interrupt enable bits
        INT_EN_2,        ///<Interrupt enable bits
        INT_OUT_CTRL,    ///<Contains the behavioral configuration of INT pins
        INT_LATCH,       ///<Contains the interrupt rest bit and the interrupt 
                         ///<mode selection
        INT_MAP_0,       ///<Controls which interrupt signals are mapped to the 
                         ///<INT1 and INT2 pins
        INT_MAP_1,       ///<Controls which interrupt signals are mapped to the 
                         ///<INT1 and INT2 pins
        INT_MAP_2,       ///<Controls which interrupt signals are mapped to the 
                         ///<INT1 and INT2 pins
        INT_DATA_0,      ///<Contains the data source definition for the two 
                         ///<interrupt groups
        INT_DATA_1,      ///<Contains the data source definition for the two 
                         ///<interrupt groups
        INT_LOWHIGH_0,   ///<Contains the configuration for the low g interrupt
        INT_LOWHIGH_1,   ///<Contains the configuration for the low g interrupt
        INT_LOWHIGH_2,   ///<Contains the configuration for the low g interrupt
        INT_LOWHIGH_3,   ///<Contains the configuration for the low g interrupt
        INT_LOWHIGH_4,   ///<Contains the configuration for the low g interrupt
        INT_MOTION_0,    ///<Contains the configuration for the any motion and 
                         ///<no motion interrupts
        INT_MOTION_1,    ///<Contains the configuration for the any motion and 
                         ///<no motion interrupts
        INT_MOTION_2,    ///<Contains the configuration for the any motion and 
                         ///<no motion interrupts
        INT_MOTION_3,    ///<Contains the configuration for the any motion and 
                         ///<no motion interrupts
        INT_TAP_0,       ///<Contains the configuration for the tap interrupts
        INT_TAP_1,       ///<Contains the configuration for the tap interrupts
        INT_ORIENT_0,    ///<Contains the configuration for the oeientation 
                         ///<interrupt
        INT_ORIENT_1,    ///<Contains the configuration for the oeientation 
                         ///<interrupt
        INT_FLAT_0,      ///<Contains the configuration for the flat interrupt
        INT_FLAT_1,      ///<Contains the configuration for the flat interrupt
        FOC_CONF,        ///<Contains configuration for the fast offset 
                         ///<compensation for the accelerometer and gyroscope
        CONF,            ///<Configuration of sensor, nvm_prog_en bit
        IF_CONF,         ///<Contains settings for the digital interface
        PMU_TRIGGER,     ///<Sets trigger conditions to change gyro power modes
        SELF_TEST,       ///<Self test configuration
        NV_CONF = 0x70,  ///<Contains settings for the digital interface
        OFFSET_0,        ///<Contains offset comp values for acc_off_x7:0
        OFFSET_1,        ///<Contains offset comp values for acc_off_y7:0
        OFFSET_2,        ///<Contains offset comp values for acc_off_z7:0
        OFFSET_3,        ///<Contains offset comp values for gyr_off_x7:0
        OFFSET_4,        ///<Contains offset comp values for gyr_off_y7:0
        OFFSET_5,        ///<Contains offset comp values for gyr_off_z7:0
        OFFSET_6,        ///<gyr/acc offset enable bit and gyr_off_(zyx) bits9:8
        STEP_CNT_0,      ///<Step counter bits 15:8
        STEP_CNT_1,      ///<Step counter bits 7:0
        STEP_CONF_0,     ///<Contains configuration of the step detector
        STEP_CONF_1,     ///<Contains configuration of the step detector
        CMD = 0x7E       ///<Command register triggers operations like 
                         ///<softreset, NVM programming, etc.
    };
    
    ///ERR_REG Bit Mask bit0
    static const uint8_t FATAL_ERR = 0x01;
    ///ERR_REG Bit Mask bits4:1
    static const uint8_t ERR_CODE = 0x1E;
    ///ERR_REG Bit Mask bit5
    static const uint8_t I2C_FAIL_ERR = 0x20;
    ///ERR_REG Bit Mask bit6
    static const uint8_t DROP_CMD_ERR = 0x40;
    ///ERR_REG Bit Mask bit7
    static const uint8_t MAG_DRDY_ERR = 0x80;
    
    ///ERR_REG bits4:1 codes
    enum ErrorCodes
    {
        NO_ERROR = 0,        ///<No Error
        ERROR_1,             ///<Listed as error   
        ERROR_2,             ///<Listed as error
        LPM_INT_PFD,         ///<Low-power mode and interrupt uses pre-filtered 
                             ///<data
        ODR_MISMATCH = 0x06, ///<ODRs of enabled sensors in headerless mode do 
                             ///<not match
        PFD_USED_LPM         ///<Pre-filtered data are used in low power mode
    };
    
    enum PowerModes
    {
        SUSPEND = 0,  ///<Acc and Gyro, No sampling, No FIFO data readout
        NORMAL,       ///<Acc and Gyro, Full chip operation
        LOW_POWER,    ///<Acc duty-cycling between suspend and normal
        FAST_START_UP ///<Gyro start up delay time to normal mode <= 10 ms
    };
    
    
    ///@brief BMI160 Destructor.\n
    ///
    ///On Entry:
    ///@param[in] none 
    ///
    ///On Exit:
    ///@param[out] none
    ///
    ///@returns none
    virtual ~BMI160(){ }
    
    
    ///@brief Reads a single register.\n
    ///
    ///On Entry:
    ///@param[in] data - pointer to memory for storing read data
    ///
    ///On Exit:
    ///@param[out] data - holds contents of read register on success
    ///
    ///@returns 0 on success, non 0 on failure
    virtual int32_t readRegister(Registers reg, uint8_t *data) = 0;
    
    
    ///@brief Writes a single register.\n
    ///
    ///On Entry:
    ///@param[in] data - data to write to register
    ///
    ///On Exit:
    ///@param[out] none
    ///
    ///@returns 0 on success, non 0 on failure
    virtual int32_t writeRegister(Registers reg, const uint8_t data) = 0;
    
    
    ///@brief Reads a block of registers.\n
    ///@detail User must ensure that all registers between 'startReg' and 
    ///'stopReg' exist and are readable.  Function reads up to, including, 
    ///'stopReg'.\n
    ///
    ///On Entry:
    ///@param[in] startReg - register to start reading from
    ///@param[in] stopReg - register to stop reading from
    ///@param[in] data - pointer to memory for storing read data
    ///
    ///On Exit:
    ///@param[out] data - holds contents of read registers on success
    ///
    ///@returns 0 on success, non 0 on failure
    virtual int32_t readBlock(Registers startReg, Registers stopReg, 
    uint8_t *data) = 0;
    
    
    ///@brief Writes a block of registers.\n
    ///@detail User must ensure that all registers between 'startReg' and 
    ///'stopReg' exist and are writeable.  Function writes up to, including, 
    ///'stopReg'.\n
    ///
    ///On Entry:
    ///@param[in] startReg - register to start writing at 
    ///@param[in] stopReg - register to stop writing at
    ///@param[in] data - pointer to data to write to registers
    ///
    ///On Exit:
    ///@param[out] none
    ///
    ///@returns 0 on success, non 0 on failure
    virtual int32_t writeBlock(Registers startReg, Registers stopReg, 
    const uint8_t *data) = 0;
    
    
    ///@brief Get die temperature.\n
    ///
    ///On Entry:
    ///@param[in] temp - pointer to float for temperature 
    ///
    ///On Exit:
    ///@param[out] temp - on success, holds the die temperature
    ///
    ///@returns 0 on success, non 0 on failure
    int32_t getTemperature(float *temp);
    
    
    ///@brief fx documentation template.\n
    ///
    ///On Entry:
    ///@param[in] none 
    ///
    ///On Exit:
    ///@param[out] none
    ///
    ///@returns none
    
private:

};


/**
@brief BMI160_I2C - supports BMI160 object with I2C interface
*/
class BMI160_I2C: public BMI160
{
public:

    ///BMI160 default I2C address.
    static const uint8_t I2C_ADRS_SDO_LO = 0x68;
    ///BMI160 optional I2C address.
    static const uint8_t I2C_ADRS_SDO_HI = 0x69;
    

    ///@brief BMI160_I2C Constructor.\n
    ///
    ///On Entry:
    ///@param[in] i2cBus - reference to I2C bus for this device
    ///@param[in] i2cAdrs - 7-bit I2C address
    ///
    ///On Exit:
    ///@param[out] none
    ///
    ///@returns none
    BMI160_I2C(I2C &i2cBus, uint8_t i2cAdrs);
    
    
    virtual int32_t readRegister(Registers reg, uint8_t *data);
    virtual int32_t writeRegister(Registers reg, const uint8_t data);
    virtual int32_t readBlock(Registers startReg, Registers stopReg, 
    uint8_t *data);
    virtual int32_t writeBlock(Registers startReg, Registers stopReg, 
    const uint8_t *data);
    
private:

    I2C m_i2cBus;
    uint8_t m_Wadrs, m_Radrs;
};


/**
@brief BMI160_SPI - supports BMI160 object with SPI interface
*/
class BMI160_SPI: public BMI160
{
public:

    ///@brief BMI160_SPI Constructor.\n
    ///
    ///On Entry:
    ///@param[in] spiBus - reference to SPI bus for this device
    ///@param[in] cs - reference to DigitalOut used for chip select
    ///
    ///On Exit:
    ///@param[out] none
    ///
    ///@returns none
    BMI160_SPI(SPI &spiBus, DigitalOut &cs);
    
    virtual int32_t readRegister(Registers reg, uint8_t *data);
    virtual int32_t writeRegister(Registers reg, const uint8_t data);
    virtual int32_t readBlock(Registers startReg, Registers stopReg, 
    uint8_t *data);
    virtual int32_t writeBlock(Registers startReg, Registers stopReg, 
    const uint8_t *data);
    
private:

    SPI m_spiBus;
    DigitalOut m_cs;
};

#endif /* BMI160_H */