/*
* Copyright (C) 2015-2016 Intel Corporation. All rights reserved.
*
* This file is free software: you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This file 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.
*
* You should have received a copy of the GNU General Public License along
* with this program. If not, see .
*/
#pragma once
#include
#include "AP_HAL_Namespace.h"
#include "utility/functor.h"
/*
* This is an interface abstracting I2C and SPI devices
*/
class AP_HAL::Device {
public:
enum BusType {
BUS_TYPE_UNKNOWN = 0,
BUS_TYPE_I2C = 1,
BUS_TYPE_SPI = 2,
BUS_TYPE_UAVCAN = 3,
BUS_TYPE_SITL = 4
};
enum Speed {
SPEED_HIGH,
SPEED_LOW,
};
FUNCTOR_TYPEDEF(PeriodicCb, void);
typedef void* PeriodicHandle;
Device(enum BusType type)
{
_bus_id.devid_s.bus_type = type;
}
// return bus type
enum BusType bus_type(void) const {
return _bus_id.devid_s.bus_type;
}
// return bus number
uint8_t bus_num(void) const {
return _bus_id.devid_s.bus;
}
// return 24 bit bus identifier
uint32_t get_bus_id(void) const {
return _bus_id.devid;
}
// return address on bus
uint8_t get_bus_address(void) const {
return _bus_id.devid_s.address;
}
// set device type within a device class (eg. AP_COMPASS_TYPE_LSM303D)
void set_device_type(uint8_t devtype) {
_bus_id.devid_s.devtype = devtype;
}
virtual ~Device() {
if (_checked.regs != nullptr) {
delete[] _checked.regs;
}
}
/*
* Change device address. Note that this is the 7 bit address, it
* does not include the bit for read/write. Only works on I2C
*/
virtual void set_address(uint8_t address) {};
/*
* Set the speed of future transfers. Depending on the bus the speed may
* be shared for all devices on the same bus.
*
* Return: true if speed was successfully set or platform doesn't implement
* it; false otherwise.
*/
virtual bool set_speed(Speed speed) = 0;
/*
* Core transfer function. This does a single bus transaction which
* sends send_len bytes and receives recv_len bytes back from the slave.
*
* Return: true on a successful transfer, false on failure.
*/
virtual bool transfer(const uint8_t *send, uint32_t send_len,
uint8_t *recv, uint32_t recv_len) = 0;
/**
* Wrapper function over #transfer() to read recv_len registers, starting
* by first_reg, into the array pointed by recv. The read flag passed to
* #set_read_flag(uint8_t) is ORed with first_reg before performing the
* transfer.
*
* Return: true on a successful transfer, false on failure.
*/
bool read_registers(uint8_t first_reg, uint8_t *recv, uint32_t recv_len)
{
first_reg |= _read_flag;
return transfer(&first_reg, 1, recv, recv_len);
}
/**
* Wrapper function over #transfer() to write a byte to the register reg.
* The transfer is done by sending reg and val in that order.
*
* Return: true on a successful transfer, false on failure.
*/
bool write_register(uint8_t reg, uint8_t val, bool checked=false)
{
uint8_t buf[2] = { reg, val };
if (checked) {
set_checked_register(reg, val);
}
return transfer(buf, sizeof(buf), nullptr, 0);
}
/**
* set a value for a checked register
*/
void set_checked_register(uint8_t reg, uint8_t val);
/**
* setup for register value checking. Frequency is how often to check registers. If set to 10 then
* every 10th call to check_next_register will check a register
*/
bool setup_checked_registers(uint8_t num_regs, uint8_t frequency=10);
/**
* check next register value for correctness. Return false if value is incorrect
* or register checking has not been setup
*/
bool check_next_register(void);
/**
* Wrapper function over #transfer() to read a sequence of bytes from
* device. No value is written, differently from the #read_registers()
* method and hence doesn't include the read flag set by #set_read_flag()
*/
bool read(uint8_t *recv, uint32_t recv_len)
{
return transfer(nullptr, 0, recv, recv_len);
}
/*
* Get the semaphore for the bus this device is in. This is intended for
* drivers to use during initialization phase only.
*/
virtual AP_HAL::Semaphore *get_semaphore() = 0;
/*
* Register a periodic callback for this bus. All callbacks on the
* same bus are made from the same thread with lock already taken. In
* other words, the callback is not executed on the main thread (or the
* thread which registered the callback), but in a separate per-bus
* thread.
*
* After registering the periodic callback, the other functions should not
* be used anymore from other contexts. If it really needs to be done, the
* lock must be taken.
*
* Return: A handle for this periodic callback. To cancel the callback
* call #unregister_callback() or return false on the callback.
*/
virtual PeriodicHandle register_periodic_callback(uint32_t period_usec, PeriodicCb) = 0;
/*
* Adjust the time for the periodic callback registered with
* #register_periodic_callback. Note that the time will be re-calculated
* from the moment this call is made and expire after @period_usec.
*
* Return: true if periodic callback was successfully adjusted, false otherwise.
*/
virtual bool adjust_periodic_callback(PeriodicHandle h, uint32_t period_usec) = 0;
/*
* Cancel a periodic callback on this bus.
*
* Return: true if callback was successfully unregistered, false
* otherwise.
*/
virtual bool unregister_callback(PeriodicHandle h) { return false; }
/*
allows to set callback that will be called after DMA transfer complete.
if this callback is set then any read/write operation will return directly after transfer setup and
bus semaphore must not be released until register_completion_callback(0) called from callback itself
*/
virtual void register_completion_callback(AP_HAL::MemberProc proc) {}
virtual void register_completion_callback(AP_HAL::Proc proc) {}
/*
* support for direct control of SPI chip select. Needed for
* devices with unusual SPI transfer patterns that include
* specific delays
*/
virtual bool set_chip_select(bool set) { return false; }
/**
* Some devices connected on the I2C or SPI bus require a bit to be set on
* the register address in order to perform a read operation. This sets a
* flag to be used by #read_registers(). The flag's default value is zero.
*/
void set_read_flag(uint8_t flag)
{
_read_flag = flag;
}
/**
* make a bus id given bus type, bus number, bus address and
* device type This is for use by devices that do not use one of
* the standard HAL Device types, such as UAVCAN devices
*/
static uint32_t make_bus_id(enum BusType bus_type, uint8_t bus, uint8_t address, uint8_t devtype) {
union DeviceId d {};
d.devid_s.bus_type = bus_type;
d.devid_s.bus = bus;
d.devid_s.address = address;
d.devid_s.devtype = devtype;
return d.devid;
}
/**
* return a new bus ID for the same bus connection but a new device type.
* This is used for auxillary bus connections
*/
static uint32_t change_bus_id(uint32_t old_id, uint8_t devtype) {
union DeviceId d;
d.devid = old_id;
d.devid_s.devtype = devtype;
return d.devid;
}
/**
* return bus ID with a new devtype
*/
uint32_t get_bus_id_devtype(uint8_t devtype) {
return change_bus_id(get_bus_id(), devtype);
}
/* set number of retries on transfers */
virtual void set_retries(uint8_t retries) {};
protected:
uint8_t _read_flag = 0;
/*
broken out device elements. The bitfields are used to keep
the overall value small enough to fit in a float accurately,
which makes it possible to transport over the MAVLink
parameter protocol without loss of information.
*/
struct DeviceStructure {
enum BusType bus_type : 3;
uint8_t bus: 5; // which instance of the bus type
uint8_t address; // address on the bus (eg. I2C address)
uint8_t devtype; // device class specific device type
};
union DeviceId {
struct DeviceStructure devid_s;
uint32_t devid;
};
union DeviceId _bus_id;
// set device address (eg. i2c bus address or spi CS)
void set_device_address(uint8_t address) {
_bus_id.devid_s.address = address;
}
// set device bus number
void set_device_bus(uint8_t bus) {
_bus_id.devid_s.bus = bus;
}
private:
// checked registers
struct checkreg {
uint8_t regnum;
uint8_t value;
};
struct {
uint8_t n_allocated;
uint8_t n_set;
uint8_t next;
uint8_t frequency;
uint8_t counter;
struct checkreg *regs;
} _checked;
};