16 KiB
AP_HAL Readme
Pat Hickey
Galois Inc
11 Sept 2011
Overview
AP_HAL is hardware abstraction layer for the ArduPilot project. The goal is to separate AVR (via avr-libc) and Arduino (via the Arduino core and included libraries like SPI and Wire) dependencies from the ArduPilot programs and libraries.
This will make it possible to port the ArduPlane and ArduCopter programs (and their associated libraries) to a new platform without changing any of the ArduPlane or ArduCopter code, only implementing the AP_HAL interface for the new platform.
Currently, the AP_HAL_AVR library , found in /libraries/AP_HAL_AVR/, is an implementation of AP_HAL for the ArduPilot hardware platforms.
AP_HAL_AVR exports two HAL instances, AP_HAL_AVR_APM1
and AP_HAL_AVR_APM2
,
which provide the instances for APM1 and APM2 hardware.
Requirments
AP_HAL is designed to work with the Arduino 1.0.1 IDE with a special "Coreless" modification, or with the ArduPilot Arduino.mk makefiles with a similar Coreless extension. The Arduino.mk Makefile in the AP_HAL development branch also implements the coreless modification. You will not need to upgrade to a coreless patched IDE if you are just using Makefiles.
The Coreless modification to the Arduino IDE will be made available as a patch and as compiled IDEs on the ArduPilot project's Downloads section.
Why Coreless Arduino
todo
Consequences of Coreless Arduino
-
Need to provide an empty "Arduino.h" somewhere in the include path of each sketch. The line
#include <Arduino.h>
is added to each sketch by the Arduino IDE's sketch preprocessor, as well as by the Makefile build. -
Need to provide an entry point
int main(void)
for the application. Previously, a trivial implementation existed in the Arduino core:int main(void) { init(); /* Initialized the Arduino core functionality */ setup(); while(1) loop(); return 0; /* Never reached */ }
Each program built with the coreless Arduino build will need to provide its own
main
function. The following implementation may be used in at the bottom of the sketch PDE/INO file:extern "C" { int main(void) { hal.init(NULL); setup(); while(1) loop(); return 0; } }
The
extern "C"
wrapper is required because a PDE/INO file is compiled as C++. -
Global objects which were previously available in all Arduino sketches, such as Serial, Serial1, etc. no longer exist. This is by design - all of those hardware interfaces should be accessed through the HAL.
Using The AP_HAL Library
AP_HAL, found in /libraries/AP_HAL/, is a library of purely virtual classes: there is no concrete code in the AP_HAL library, only interfaces. All code in the core ArduPlane & ArduCopter programs, ArduPilot libraries, and example sketches should depend only on the interfaces exposed by AP_HAL.
The collection of classes in the AP_HAL library exist in the AP_HAL C++
namespace. The convention is for a program to instantiate a single instance
of the AP_HAL::HAL
class, under a reference to the name hal
.
#include <AP_HAL.h> const AP_HAL::HAL& hal = specific_hal_implementation;
This instance should be made in a single object file. All other object files,
including libraries (even those inside an AP_HAL implementation, should use
the AP_HAL interface by declaring an extern reference to hal
.
#include <AP_HAL.h> extern const AP_HAL::HAL& hal;
Using The AP_HAL_AVR library
The AP_HAL_AVR library exports AP_HAL::HAL instances for the APM1 and APM2. These instances are made of a number of concrete classes which implement the AP_HAL interfaces for the AVR platform. These implementations depend only on avr-libc and not the Arduino core.
Some of the code in AP_HAL_AVR, such as the the GPIO class's pinMode, read, and write, has been derived directly from the source code of the Arduino core pinMode, digitalRead, and digitalWrite.
When using the coreless Arduino IDE to build for AVR, you will need the following three libraries included in the top level of your sketch:
#include <AP_Common.h>
#include <AP_HAL.h>
#include <AP_HAL_AVR.h>
and then declare one of the following hal lines depending on your platform:
const AP_HAL::HAL& hal = AP_HAL_AVR_APM1;
or
const AP_HAL::HAL& hal = AP_HAL_AVR_APM2;
AP_HAL Library Contents
The AP_HAL
library is organized as follows:
AP_HAL.h : exports all other headers for the library.
AP_HAL_Namespace.h : exposes the C++ namespace AP_HAL
. The namespace
declaration declares each class by name (not implementation) and some useful
typedefs.
The AP_HAL interface classes are each defined in a header file bearing their name.
AP_HAL::HAL
The AP_HAL::HAL
class is a container for the a complete set of device
drivers. The class is defined in /libraries/AP_HAL/HAL.h
. It also has a
virtual (i.e. overridable) method to handle driver initialization. Each device
driver is exposed as a pointer an AP_HAL driver class, (e.g. each serial
driver is exposed as a public UARTDriver* uartN
).
The following drivers are public members of AP_HAL::HAL
. (Each class is in
the AP_HAL
namespace, left off for brevity.)
UARTDriver* uart0
: Corresponds to ArduPilot FastSerial library override of the Arduino core Serial objectUARTDriver* uart1
: Corresponds to Serial1 object (as above)UARTDriver* uart2
: Corresponds to Serial2 object (as above)UARTDriver* uart3
: Corresponds to Serial3 object (as above)I2CDriver* i2c
: Corresponds to ArduPilot/libraries/I2C
driverSPIDriver* spi
: Corresponds to Arduino library SPI objectAnalogIn* analogin
: Corresponds to/libraries/AP_AnalogSource/AP_AnalogSource_Arduino
driverStorage* storage
: Corresponds to avr-libc's<avr/eeprom.h>
driverDataflash* dataflash
: Corresponds to ArduPilot/libraries/DataFlash
driverBetterStream* console
: New utility for warning and error reportingGPIO* gpio
: Corresponds to Arduino corepinMode
,digitalRead
, anddigitalWrite
functionalityRCInput* rcin
: Corresponds to PPM input side of ArduPilot/libraries/APM_RC
libraryRCOutput* rcout
: Corresponds to PPM output side of ArduPilot/libraries/APM_RC
libraryScheduler* scheduler
: Encompasses both Arduino core timing functions such asmillis
anddelay
and the ArduPilot/library/AP_PeriodicProcess/
driver.
AP_HAL
also has an unimplemented virtual void init(void* opts) const
method.
This method should initialize each driver before the call to a sketch's setup
method.
AP_HAL::UARTDriver
The AP_HAL::UARTDriver
class is the AP_HAL replacment for ArduPilot's
FastSerial
library.
The AP_HAL::UARTDriver
class is a pure virtual interface. The code is derived
directly from the FastSerial
class. It provides the methods begin()
,
end()
, flush()
, is_initialized()
, set_blocking_writes
, and
tx_pending
. The class hierchary for AP_HAL::UARTDriver
is also derived
directly from the FastSerial
class's hierarchy . AP_HAL::UARTDriver
is a
public AP_HAL::BetterStream
, which is a public AP_HAL::Stream
, which is a
public AP_HAL::Print
.
The utility/
directory contains the definitions of the AP_HAL::Print
,
AP_HAL::Stream
, and AP_HAL::BetterStream
classes, as well as default
implementations for the AP_HAL::Print
class.
AP_HAL::Print
and AP_HAL::Stream
are derived directly from the classes of
the same name in the Arduino core. Some methods dealing with the Arduino core's
C++ String
s, and the Printable
class, have been left out.
The AP_HAL::Print
class has default implementations of all of the print
methods. Each of these methods is implemented in terms of
virtual size_t write(uint8_t char)
, which is expected to be implemented by
a class deriving from AP_HAL::Print
. This is the same structure as used in
the Arduino core.
The AP_HAL::Stream
class is based on the Arduino core's Stream, but reduced
to just the methods we actually use in ArduPilot - int available()
,
int read()
, and int peek()
. These methods are all pure virtual
The AP_HAL::BetterStream
class is a pure virtual version of the class by the
same name from Mike Smith's FastSerial
library. It exposes the methods
int txspace()
, void print_P()
, void println_P
, void printf()
, and
void printf_P()
. As in FastSerial's BetterStream library, function names
postfixed with _P
take a string in program space as their first argument.
To use the AVR program space types, the AP_HAL::BetterStream
class depends on
the <avr/pgmspace.h>
and AP_Common.h
header files. This is the only part of
the AP_HAL
library which still depends on an AVR specific library. We will
find a way to make this dependency modular by isolating the parts of the
AP_Common
and <avr/pgmspace.h>
headers which BetterStream depends upon
into a single header, and then conditionally defining those typedefs and
macros to innocuous implementations when compiling for other platforms.
AP_HAL::I2CDriver
The AP_HAL::I2CDriver
class is the AP_HAL replacment for ArduPilot's
I2C
library. (ArduPilot's I2C
library is a replacment for the Arduino
provided Wire
library. The Wire
library is so bad I could cry.)
The AP_HAL::I2CDriver
class is a pure virtual interface, found in
/libraries/AP_HAL/I2CDriver.h.
The methods resemble those in defined by the
I2C
class in /libraries/I2C/I2C.h
, but to ease future implementations, all
of the old Arduino Wire
class compatibility methods have been dropped.
The I2CDriver
interface supports the timeout features we require to assure
safe timing properties when polling the hardware I2C peripeheral. It also
only exposes whole-transaction interfaces to the user, to support more efficient
implementations in a threaded environment.
AP_HAL::SPIDriver
The AP_HAL::SPIDriver
class is pure virtual and can be found in
/libraries/AP_HAL/SPIDriver.h
.
The AP_HAL::SPIDriver
class is derived from, but only slightly resembles the
Arduino core's SPI
library. Methods we don't use have been removed, as has
the export of a global SPI
object. The begin
method has been swapped for a
more idiomatic init
method, and setClockDivider
has been replaced with a
more general setSpeed
method. In addition, it is not possible to operate the
SPI device as a slave. The uint8_t transfer(uint8_t data)
method remains in
common.
The SPIDriver
interface (and the existing AVR implementation) will require
significant changes to support efficient implementations in a threaded
environment. Transfers will have to be possible in bulk, and somehow incorporate
the notion of the target device so that specialized hardware can manage the
slave device select lines. Currently, device select signals are sent using the
AP_HAL::GPIO::write
method, which is the AP_HAL analog of Arduino's
digitalWrite
.
AP_HAL::AnalogIn
The AP_HAL::AnalogIn
class is pure virtual and can be found in
/libraries/AP_HAL/AnalogIn.h
. The pure virtual AP_HAL::AnalogSource
class
is also defined in that class.
The AP_HAL::AnalogSource
interface is based loosely on the AP_AnalogSource
interface in the existing AP_AnalogSource library. At this time, an
AP_HAL::AnalogSource
has a single method float read()
which returns the
latest analog measurment. There are no methods for flow control - currently you
must assume the method will block until a measurment is ready; the timing is
entirely implementation defined.
The AP_HAL::AnalogIn
interface does not have a close analog in the existing
libraries. Consider it to be, loosely, a factory for AnalogSource
objects.
There are only two methods: the standard void init(void*)
initializer and
a numbered interface to the available analog channels AP_HAL::AnalogSource* channel(int n)
. At this time the significance of each numbered channel is
determined by the implementation.
Extensions will be made to these interfaces as required to meet the needs of
other platforms. We will also have to consider making named channels, as
opposed to numbered channels, available from the AP_HAL::AnalogIn
interface
AP_HAL::Storage
The AP_HAL::Storage
class is pure virtual and can be found in
/libraries/AP_HAL/Storage.h
. It is the AP_HAL interface to take the place
of the AVR EEPROM, possibly with other nonvolatile storage.
The AP_HAL::Storage
interface very closely resembles the avr-libc eeprom
interface. The use of uint8_t*
projections into storage space are subject to
change - it seems to make more sense to use integer types to designate these
locations, as there is no valid dereference of a pointer value.
AP_HAL::Dataflash
The AP_HAL::Dataflash
class is pure virtual and can be found in
/libraries/AP_HAL/Dataflash.h
. It is based on the existing ArduPilot
DataFlash
library found in /libraries/DataFlash
. The AP_HAL::Dataflash
interface is a cleaned up version of that library's interface. Public member
variables have been replaced with getter methods, unused public interfaces
have been removed, and all methods have had their names translated to lowercase
and underscores for style.
Similar to the problems with the SPI library, the existing DataFlash
library
interface is oriented for byte-at-a-time writes to the hardware device. This
interface may have to be revised to support bulk transfers for efficient use
in a threaded environment.
AP_HAL Console driver
In the existing ArduPilot code, there is no unified way to send debugging
messages, warnings, and errors to the user. A dedicated Console driver, exposed
as an AP_HAL::BetterStream
, is envisioned as a better way to communicate that
sort of information.
In the future, I envision extending this driver to support a transport layer over a Mavlink connection.
Implementations may either leave the console unimplemented or alias it to one of the UARTDriver implementations.
AP_HAL::RCInput
The AP_HAL::RCInput
class is pure virtual and can be found in
/libraries/AP_HAL/RCInput.h
. The RCInput interface is based on the
input related methods of the existing ArduPilot APM_RC
class. RCInput methods
were separated from RCOutput methods for clarity.
The methods uint8_t valid()
and uint16_t read(uint8_t)
carry over the exact
interface found in APM_RC
, which is to specify the number of valid channels,
and then read each channel out by number.
Based on the most common use case, which is to read the valid flag and then all
input channels sequentially, a new interface uint8_t read(uint16_t* periods, uint8_t len)
makes the valid flag available as the return value, and writes
the periods as an array to the memory specified by the first argument.
This bulk read interface may be more efficient in a threaded environment.
AP_HAL::RCOutput
The AP_HAL::RCOutput
class is pure virtual and can be found in
/libraries/AP_HAL/RCOutput.h
. The RCOutput interface is based on the
input related methods of the existing ArduPilot APM_RC
class. RCOutput methods
were separated from RCInput methods for clarity.
The output methods from APM_RC
were reproduced here faithfully, with minor
differences to naming. As an extension, the read
and write
methods are
overloaded to also have versions which take or give arrays of values, as the
most common use case is to read or write all channels sequentially, and bulk
reads and writes may be more efficient in a threaded environment.
AP_HAL::Scheduler
The AP_HAL::Scheduler
class is pure virtual and can be found in
/libraries/AP_HAL/Scheduler.h
.
Remaining ArduPilot AVR dependencies
The class AP_Param
makes extensive use of AVR program space pointers and
accessors in its implementation. The definition of these types and accrssors
will have to be defined in a single external header file so they can be
replaced by innocuous types and accessors when compiling for other platforms