ardupilot/libraries/AP_InertialSensor/AuxiliaryBus.cpp

#include <assert.h>
#include <stdlib.h>

#include "AuxiliaryBus.h"

AuxiliaryBusSlave::AuxiliaryBusSlave(AuxiliaryBus &bus, uint8_t addr,
                                     uint8_t instance)
    : _bus(bus)
    , _addr(addr)
    , _instance(instance)
{
}

AuxiliaryBusSlave::~AuxiliaryBusSlave()
{
}

AuxiliaryBus::AuxiliaryBus(AP_InertialSensor_Backend &backend, uint8_t max_slaves, uint32_t devid)
    : _max_slaves(max_slaves)
    , _ins_backend(backend)
    , _devid(devid)
{
    _slaves = (AuxiliaryBusSlave**) calloc(max_slaves, sizeof(AuxiliaryBusSlave*));
}

AuxiliaryBus::~AuxiliaryBus()
{
    for (int i = _n_slaves - 1; i >= 0; i--) {
        delete _slaves[i];
    }
    free(_slaves);
}

/*
 * Get the next available slave for the sensor exposing this AuxiliaryBus.
 * If a new slave cannot be registered or instantiated, `nullptr` is returned.
 * Otherwise a new slave is returned, but it's not registered (and therefore
 * not owned by the AuxiliaryBus).
 *
 * After using the slave, if it's not registered for a periodic read it must
 * be destroyed.
 *
 * @addr: the address of this slave in the bus
 *
 * Return a new slave if successful or `nullptr` otherwise.
 */
AuxiliaryBusSlave *AuxiliaryBus::request_next_slave(uint8_t addr)
{
    if (_n_slaves == _max_slaves)
        return nullptr;

    AuxiliaryBusSlave *slave = _instantiate_slave(addr, _n_slaves);
    if (!slave)
        return nullptr;

    return slave;
}

/*
 * Register a periodic read. This should be called after the slave sensor is
 * already configured and the only thing the master needs to do is to copy a
 * set of registers from the slave to its own registers.
 *
 * The sample rate is hard-coded, depending on the sensor that exports this
 * AuxiliaryBus.
 *
 * After this call the AuxiliaryBusSlave is owned by this object and should
 * not be destroyed. A typical call chain to use a sensor in an AuxiliaryBus
 * is (error checking omitted for brevity):
 *
 *      AuxiliaryBusSlave *slave = bus->request_next_slave(addr);
 *      slave->passthrough_read(WHO_AM_I, buf, 1);
 *      slave->passthrough_write(...);
 *      slave->passthrough_write(...);
 *      ...
 *      bus->register_periodic_read(slave, SAMPLE_START_REG, SAMPLE_SIZE);
 *
 * @slave: the AuxiliaryBusSlave already configured to be in continuous mode
 * @reg:   the first register of the block to use in each periodic transfer
 * @size:  the block size, usually the size of the sample multiplied by the
 *         number of axes in each sample.
 *
 * Return 0 on success or < 0 on error.
 */
int AuxiliaryBus::register_periodic_read(AuxiliaryBusSlave *slave, uint8_t reg,
                                         uint8_t size)
{
    int r = _configure_periodic_read(slave, reg, size);
    if (r < 0)
        return r;

    slave->_sample_reg_start = reg;
    slave->_sample_size = size;
    slave->_registered = true;
    _slaves[_n_slaves++] = slave;

    return 0;
}
AP_InertialSensor: Add support for auxiliary buses Add an AuxiliaryBus class that can be derived for specific implementations in inertial sensor backends. It's an abstract implementation so other libraries can use the auxiliary bus exported. In order for this to succeed the backend implementation must split the initialization of the sensor from the actual sample collecting, like is done in MPU6000. When AP_InertialSensor::get_auxiliary_bus() is called it will execute following steps: a) Force the backends to be detected if it's the first time it's being called b) Find the backend identified by the id c) call get_auxiliary_bus() on the backend so other libraries can that AuxiliaryBus to initialize a slave device Slave devices can be used by calling AuxiliaryBus::request_next_slave() and are owned by the caller until AuxiliaryBus::register_periodic_read() is called. From that time on the AuxiliaryBus object takes its ownership. This way it's possible to do the necessary cleanup later without introducing refcounts, that we don't have support to. Between these 2 functions the caller can configure the slave device by doing its specific initializations by calling the passthrough_* functions. After the initial configuration and register_periodic_read() is called only read() can be called. 2015-08-05 13:36:14 -03:00			`#include <assert.h>`
			`#include <stdlib.h>`

			`#include "AuxiliaryBus.h"`

			`AuxiliaryBusSlave::AuxiliaryBusSlave(AuxiliaryBus &bus, uint8_t addr,`
AP_Compass: HMC5843: Add support for MPU6000 auxiliary bus Allow HMC5843 to be on MPU6000's auxiliary bus. 2015-08-10 20:30:32 -03:00			`uint8_t instance)`
AP_InertialSensor: Add support for auxiliary buses Add an AuxiliaryBus class that can be derived for specific implementations in inertial sensor backends. It's an abstract implementation so other libraries can use the auxiliary bus exported. In order for this to succeed the backend implementation must split the initialization of the sensor from the actual sample collecting, like is done in MPU6000. When AP_InertialSensor::get_auxiliary_bus() is called it will execute following steps: a) Force the backends to be detected if it's the first time it's being called b) Find the backend identified by the id c) call get_auxiliary_bus() on the backend so other libraries can that AuxiliaryBus to initialize a slave device Slave devices can be used by calling AuxiliaryBus::request_next_slave() and are owned by the caller until AuxiliaryBus::register_periodic_read() is called. From that time on the AuxiliaryBus object takes its ownership. This way it's possible to do the necessary cleanup later without introducing refcounts, that we don't have support to. Between these 2 functions the caller can configure the slave device by doing its specific initializations by calling the passthrough_* functions. After the initial configuration and register_periodic_read() is called only read() can be called. 2015-08-05 13:36:14 -03:00			`: _bus(bus)`
			`, _addr(addr)`
			`, _instance(instance)`
			`{`
			`}`

			`AuxiliaryBusSlave::~AuxiliaryBusSlave()`
			`{`
			`}`

AP_InertialSensor: implement device IDs for AuxilaryBus 2016-11-04 06:23:54 -03:00			`AuxiliaryBus::AuxiliaryBus(AP_InertialSensor_Backend &backend, uint8_t max_slaves, uint32_t devid)`
AP_InertialSensor: Add support for auxiliary buses Add an AuxiliaryBus class that can be derived for specific implementations in inertial sensor backends. It's an abstract implementation so other libraries can use the auxiliary bus exported. In order for this to succeed the backend implementation must split the initialization of the sensor from the actual sample collecting, like is done in MPU6000. When AP_InertialSensor::get_auxiliary_bus() is called it will execute following steps: a) Force the backends to be detected if it's the first time it's being called b) Find the backend identified by the id c) call get_auxiliary_bus() on the backend so other libraries can that AuxiliaryBus to initialize a slave device Slave devices can be used by calling AuxiliaryBus::request_next_slave() and are owned by the caller until AuxiliaryBus::register_periodic_read() is called. From that time on the AuxiliaryBus object takes its ownership. This way it's possible to do the necessary cleanup later without introducing refcounts, that we don't have support to. Between these 2 functions the caller can configure the slave device by doing its specific initializations by calling the passthrough_* functions. After the initial configuration and register_periodic_read() is called only read() can be called. 2015-08-05 13:36:14 -03:00			`: _max_slaves(max_slaves)`
			`, _ins_backend(backend)`
AP_InertialSensor: implement device IDs for AuxilaryBus 2016-11-04 06:23:54 -03:00			`, _devid(devid)`
AP_InertialSensor: Add support for auxiliary buses Add an AuxiliaryBus class that can be derived for specific implementations in inertial sensor backends. It's an abstract implementation so other libraries can use the auxiliary bus exported. In order for this to succeed the backend implementation must split the initialization of the sensor from the actual sample collecting, like is done in MPU6000. When AP_InertialSensor::get_auxiliary_bus() is called it will execute following steps: a) Force the backends to be detected if it's the first time it's being called b) Find the backend identified by the id c) call get_auxiliary_bus() on the backend so other libraries can that AuxiliaryBus to initialize a slave device Slave devices can be used by calling AuxiliaryBus::request_next_slave() and are owned by the caller until AuxiliaryBus::register_periodic_read() is called. From that time on the AuxiliaryBus object takes its ownership. This way it's possible to do the necessary cleanup later without introducing refcounts, that we don't have support to. Between these 2 functions the caller can configure the slave device by doing its specific initializations by calling the passthrough_* functions. After the initial configuration and register_periodic_read() is called only read() can be called. 2015-08-05 13:36:14 -03:00			`{`
			`_slaves = (AuxiliaryBusSlave*) calloc(max_slaves, sizeof(AuxiliaryBusSlave));`
			`}`

			`AuxiliaryBus::~AuxiliaryBus()`
			`{`
			`for (int i = _n_slaves - 1; i >= 0; i--) {`
			`delete _slaves[i];`
			`}`
			`free(_slaves);`
			`}`

			`/*`
			`* Get the next available slave for the sensor exposing this AuxiliaryBus.`
			* If a new slave cannot be registered or instantiated, `nullptr` is returned.
			`* Otherwise a new slave is returned, but it's not registered (and therefore`
			`* not owned by the AuxiliaryBus).`
			`*`
			`* After using the slave, if it's not registered for a periodic read it must`
			`* be destroyed.`
			`*`
			`* @addr: the address of this slave in the bus`
			`*`
			* Return a new slave if successful or `nullptr` otherwise.
			`*/`
			`AuxiliaryBusSlave *AuxiliaryBus::request_next_slave(uint8_t addr)`
			`{`
			`if (_n_slaves == _max_slaves)`
			`return nullptr;`

			`AuxiliaryBusSlave *slave = _instantiate_slave(addr, _n_slaves);`
			`if (!slave)`
			`return nullptr;`

			`return slave;`
			`}`

			`/*`
			`* Register a periodic read. This should be called after the slave sensor is`
			`* already configured and the only thing the master needs to do is to copy a`
			`* set of registers from the slave to its own registers.`
			`*`
			`* The sample rate is hard-coded, depending on the sensor that exports this`
			`* AuxiliaryBus.`
			`*`
			`* After this call the AuxiliaryBusSlave is owned by this object and should`
			`* not be destroyed. A typical call chain to use a sensor in an AuxiliaryBus`
			`* is (error checking omitted for brevity):`
			`*`
			`* AuxiliaryBusSlave *slave = bus->request_next_slave(addr);`
			`* slave->passthrough_read(WHO_AM_I, buf, 1);`
			`* slave->passthrough_write(...);`
			`* slave->passthrough_write(...);`
			`* ...`
			`* bus->register_periodic_read(slave, SAMPLE_START_REG, SAMPLE_SIZE);`
			`*`
			`* @slave: the AuxiliaryBusSlave already configured to be in continuous mode`
			`* @reg: the first register of the block to use in each periodic transfer`
			`* @size: the block size, usually the size of the sample multiplied by the`
			`* number of axes in each sample.`
			`*`
			`* Return 0 on success or < 0 on error.`
			`*/`
			`int AuxiliaryBus::register_periodic_read(AuxiliaryBusSlave *slave, uint8_t reg,`
AP_Compass: HMC5843: Add support for MPU6000 auxiliary bus Allow HMC5843 to be on MPU6000's auxiliary bus. 2015-08-10 20:30:32 -03:00			`uint8_t size)`
AP_InertialSensor: Add support for auxiliary buses Add an AuxiliaryBus class that can be derived for specific implementations in inertial sensor backends. It's an abstract implementation so other libraries can use the auxiliary bus exported. In order for this to succeed the backend implementation must split the initialization of the sensor from the actual sample collecting, like is done in MPU6000. When AP_InertialSensor::get_auxiliary_bus() is called it will execute following steps: a) Force the backends to be detected if it's the first time it's being called b) Find the backend identified by the id c) call get_auxiliary_bus() on the backend so other libraries can that AuxiliaryBus to initialize a slave device Slave devices can be used by calling AuxiliaryBus::request_next_slave() and are owned by the caller until AuxiliaryBus::register_periodic_read() is called. From that time on the AuxiliaryBus object takes its ownership. This way it's possible to do the necessary cleanup later without introducing refcounts, that we don't have support to. Between these 2 functions the caller can configure the slave device by doing its specific initializations by calling the passthrough_* functions. After the initial configuration and register_periodic_read() is called only read() can be called. 2015-08-05 13:36:14 -03:00			`{`
			`int r = _configure_periodic_read(slave, reg, size);`
			`if (r < 0)`
			`return r;`

			`slave->_sample_reg_start = reg;`
			`slave->_sample_size = size;`
			`slave->_registered = true;`
			`_slaves[_n_slaves++] = slave;`

			`return 0;`
			`}`