Difference between revisions of "DevGuide/DesignOverview"
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-Static approach | -Static approach | ||
-Modularity | -Modularity | ||
-Hardware | -Hardware abstraction | ||
-Runtime efficiency | -Runtime efficiency | ||
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Stage(1) | Stage(1) | ||
if (++_var_i > _var_i_to) Goto(endfor_12) else NextStageAndBreak(); | if (++_var_i > _var_i_to) Goto(endfor_12) else NextStageAndBreak(); | ||
Stage(2) | |||
NavVerticalAutoThrottleMode(RadOfDeg(0.000000)); | |||
NavVerticalAltitudeMode(WaypointAlt(3), 0.); | |||
NavCircleWaypoint(3, (DEFAULT_CIRCLE_RADIUS+(_var_i*10))); | |||
if ((NavCircleCount()>1)) NextStageAndBreak(); | |||
break; | |||
Stage(3) | |||
Goto(for_11) | |||
Label(endfor_12) | |||
Stage(5) | Stage(5) | ||
NextBlock(); | NextBlock(); | ||
Revision as of 23:26, 12 June 2011
Airborne Functional Diagram
Design Goals
-Static approach -Modularity -Hardware abstraction -Runtime efficiency
Static Approach
-only "things that needs to be changed during flight are changeable -maximise compilation time resolutions
advantages Error checking Efficiency Safety/Robustness
Modularity
-Separation of concerns -Maintenability -Interface -C provide no dedicated mechanism for modularity -Main issues with modularity are configuration and dependancies
Hardware abstraction
-Segregate hardware dependant modules
Runtime Efficiency
We have to take care that our code runs efficient on the autopilot board microprocessor. It is for example very unlikely that we will physically change the serial port on which we connected our telemetry modem during a flight.
bad coding practice
switch(UART) {
case UART0 : UARTO_write(...); break;
case UART1 : UART1_write(...); break;
}
good coding practice
#define UartWrite(x) UART ## _write(x) UartWrite(...);
Design Solutions
* Heavy pre-processor usage * C code generation * Heavy Makefile usage * Conventions to define our own module layer
pre-processor
header selection
conf/airframes/funjet1.xml
<makefile> ap.CFLAGS += -DACTUATORS=\"servos_4017_hw.h\" </makefile>
generated var/FJ1/Makefile.ac
ap.CFLAGS += -DACTUATORS=\"servos_4017_hw.h\"
sw/airborne/actuators.h
#include ACTUATORS
expanded by pre-processor to
#include "servos_4017_hw.h"
macros
conf/airframes/funjet1.xml
ap.CFLAGS += -DXBEE_UART=Uart1
sw/airborne/xbee.h
#define __XBeeLink(dev, _x) dev##_x #define _XBeeLink(dev, _x) __XBeeLink(dev, _x) #define XBeeLink(_x) _XBeeLink(XBEE_UART, _x) #define XBeeBuffer() XBeeLink(ChAvailable())
expanded by pre-processor to
Uart1ChAvailable()
C code generation
For problems too complex to solve with the pre processor, we use custom compilers to generate code from a description in xml
example 1 : command laws, aka mixers
conf/airframes/funjet1.xml
<command_laws> <let var="aileron" value="@ROLL * AILEVON_AILERON_RATE"/> <let var="elevator" value="@PITCH * AILEVON_ELEVATOR_RATE"/> <set servo="AILEVON_LEFT" value="$elevator + $aileron"/> <set servo="AILEVON_RIGHT" value="$elevator - $aileron"/> </command_laws>
generated var/FJ1/airframe.h
#define SetActuatorsFromCommands(values) { \
uint16_t servo_value;\
float command_value;\
int16_t _var_aileron = values[COMMAND_ROLL] * AILEVON_AILERON_RATE;\
int16_t _var_elevator = values[COMMAND_PITCH] * AILEVON_ELEVATOR_RATE;\
[....]
command_value = _var_elevator + _var_aileron;\
command_value *= command_value>0 ? SERVO_AILEVON_LEFT_TRAVEL_UP : SERVO_AILEVON_LEFT_TRAVEL_DOWN;\
servo_value = SERVO_AILEVON_LEFT_NEUTRAL + (int16_t)(command_value);\
actuators[SERVO_AILEVON_LEFT] = ChopServo(servo_value, SERVO_AILEVON_LEFT_MIN, SERVO_AILEVON_LEFT_MAX);\
Actuator(SERVO_AILEVON_LEFT) = SERVOS_TICS_OF_USEC(actuators[SERVO_AILEVON_LEFT]);\
example 2 : flight plan
conf/flight plans/example.xml
<block name="For loop (circles wp 1)">
<for from="0" to="3" var="i">
<circle radius="DEFAULT_CIRCLE_RADIUS+ $i*10" wp="1" until="NavCircleCount() > 1"/>
</for>
<deroute block="Standby"/>
</block>
generated var/flight plan.h
Block(29) // For loop (circles wp 1)
switch(nav_stage) {
static int8_t _var_i;
static int8_t _var_i_to;
Stage(0)
_var_i = 0 - 1;
_var_i_to = 3;
Label(for_11)
Stage(1)
if (++_var_i > _var_i_to) Goto(endfor_12) else NextStageAndBreak();
Stage(2)
NavVerticalAutoThrottleMode(RadOfDeg(0.000000));
NavVerticalAltitudeMode(WaypointAlt(3), 0.);
NavCircleWaypoint(3, (DEFAULT_CIRCLE_RADIUS+(_var_i*10)));
if ((NavCircleCount()>1)) NextStageAndBreak();
break;
Stage(3)
Goto(for_11)
Label(endfor_12)
Stage(5)
NextBlock();
break;
}
Makefile
Connecting and configuring modules
ap.CFLAGS += -DDOWNLINK -DDOWNLINK_TRANSPORT=XBeeTransport -DXBEE_UART=Uart1 ap.srcs += downlink.c xbee.c ap.CFLAGS += -DUSE_UART1 -DUART1_BAUD=B9600 ap.srcs += \$(SRC_ARCH)/uart_hw.c
Modules configuration
3 sources of configuration:
* airframe configuration file ( airframe.xml ) which "compiled" to C files and Makefile * specific per module configuration file ( eg radio.xml, flightplan.xml) compiled to C code to allow factorization between airframes. * specific per board configuration file ( eg tiny.h ) to describe modules configuration imposed by board routing
Conventions
Generating Doxygen Code Documentation
A way to look at the includes and dependencies is to use the graphs generated with doxygen. After installing Paparazzi, install Doxygen:
sudo apt-get install doxygen graphviz
run the generation tool from the paparazzi3/ directory:
make doxygen
Now Doxygen will have generated html documentation(open this with any web browser) in your paparazzi3/dox/html folder.
To look at a list of all of the files used by the airborne software:
paparazzi3/dox/html/files.html
The main_ap.c will also interest you.
paparazzi3/dox/html/main__ap_8c.html
This is a sample of a Doxygen Graph:
