Simulation Extensions
By using OpenRocket's extension and listener mechanism, it's possible to modify the program itself to add features that are not supported by the program as distributed; some extensions that have been created already provide the ability to air-start a rocket, to add active roll control, and to calculate and save extra flight data.
This page will discuss extensions and simulations. We'll start by showing how a simulation is executed (so you can get a taste of what's possible), and then document the process of creating the extension. WARNING: writing an extension inserts new code into the program. It is entirely possible to disrupt a simulation in a way that invalidates simulation results, or can even crash the program. Be careful!
Adding an Existing Extension to a Simulation
Extensions are added to a simulation through a menu in the "Simulation Options" tab.
- Open a .ork file and go to the Flight Simulations tab
- Click the Edit simulation button to open the Edit simulation dialog.
- Go to the Simulation options tab.
- Click the Add extension button
This will open a menu similar to the one in the following screenshot:
Clicking on the name of an extension will add it to the simulation; if it has a configuration dialog the dialog will be opened:
In the case of the air-start extension, the configuration dialog allows you to set the altitude and velocity at which your simulation will begin. After you close the configuration dialog (if any), a new panel will be added to the Simulation options pane, showing the new extension with buttons to reconfigure it, obtain information about it, or remove it from the simulation:
Creating a New OpenRocket Extension
The remainder of this page will describe how a new simulation extension is created.
Preliminary Concepts
Before we can discuss writing an extension, we need to briefly discuss some of the internals of OpenRocket. In particular, we need to talk about the simulation status, flight data, and simulation listeners.
Simulation Status
As a simulation proceeds, it maintains its state in a SimulationStatus
. The SimulationStatus
object contains information about the rocket's current position, orientation, velocity and simulation state. It also contains a reference to a copy of the rocket design and its configuration. Any simulation listener method may modify the state of the rocket by changing the properties of the SimulationStatus
object.
You can obtain current information regarding the state of the simulation by calling get*()
methods. For instance, the rocket's current position is returned by calling getRocketPosition()
; the rocket's position can be changed by calling setRocketPosition<Coordinate position>
. All of the get*()
and set*()
methods can be found in code/src/net/sf/openrocket/simulation/SimulationStatus.java
. Note that while some information can be obtained in this way, it is not as complete as that found in FlightData
and FlightDataBranch
objects.
Flight Data
OpenRocket refers to simulation variables as FlightDataType
s, which are List<Double>
objects with one list for each simulation variable and one element in the list for each time step. To obtain a FlightDataType
, for example the current motor mass, from flightData
, we call flightData.get(FlightDataType.TYPE_MOTOR_MASS))
. The standard FlightDataType
lists are all created in core/src/net/sf/openrocket/simulation/FlightDataType.java
; the mechanism for creating a new FlightDataType
if needed for your extension will be described later.
Data from the current simulation step can be obtained with e.g. flightData.getLast(FlightDataType.TYPE_MOTOR_MASS)
.
The simulation data for each stage of the rocket's flight is referred to as a FlightDataBranch
. Every simulation has at least one FlightDataBranch
for its sustainer, and will have additional branches for its boosters.
Finally, the collection of all of the FlightDataBranch
es and some summary data for the simulation is stored in a FlightData
object.
Flight Conditions
Current data regarding the aerodynamics of the flight itself are stored in a FlightConditions
object. This includes things like the velocity, angle of attack, and roll and pitch angle and rates. It also contains a reference to the current AtmosphericConditions
Simulation Listeners
Simulation listeners are methods that OpenRocket calls at specified points in the computation to either record information or modify the simulation state. These are divided into three interface classes, named SimulationListener
, SimulationComputationListener
, and SimulationEventListener
.
All of these interfaces are implemented by the abstract class AbstractSimulationListener
. This class provides empty methods for all of the methods defined in the three interfaces, which are overridden as needed when writing a listener. A typical listener method (which is actually in the Air-start listener), would be
public void startSimulation(SimulationStatus status) throws SimulationException { status.setRocketPosition(new Coordinate(0, 0, getLaunchAltitude())); status.setRocketVelocity(status.getRocketOrientationQuaternion().rotate(new Coordinate(0, 0, getLaunchVelocity()))); }
This method is called when the simulation is first started. It obtains the desired launch altitude and velocity from its configuration, and inserts them into the simulation status to simulate an air-start.
The full set of listener methods, with documentation regarding when they are called, can be found in core/src/net/sf/openrocket/AbstractSimulationListener.java
.
The listener methods can have three return value types:
- The
startSimulation()
,endSimulation()
, andpostStep()
are called at a specific point of the simulation. They are void methods and do not return any value.
- The
preStep()
and event-related hook methods return a boolean value indicating whether the associated action should be taken or not. A return value oftrue
indicates that the action should be taken as normally would be (default),false
will inhibit the action.
- The pre- and post-computation methods may return the computed value, either as an object or a double value. The pre-computation methods allow pre-empting the entire computation, while the post-computation methods allow augmenting the computed values. These methods may return
null
orDouble.NaN
to use the original values (default), or return an overriding value.
Every listener receives a SimulationStatus
(see above) object as the first argument, and may also have additional arguments.
Each listener method may also throw a SimulationException
. This is considered an error during simulation (not a bug), and an error dialog is displayed to the user with the exception message. The simulation data produced thus far is not stored in the simulation. Throwing a RuntimeException
is considered a bug in the software and will result in a bug report dialog.
If a simulation listener wants to stop a simulation prematurely without an error condition, it needs to add a flight event of type FlightEvent.SIMULATION_END
to the simulation event queue:
status.getEventQueue().add(new FlightEvent(FlightEvent.Type.SIMULATION_END, status.getSimulationTime(), null));
This will cause the simulation to be terminated normally.
Creating a New Simulation Extension
Creating an extension for OpenRocket requires writing three classes:
- A listener, which extends
AbstractSimulationListener
. This will be the bulk of your extension, and performs all the real work.
- An extension, which extends
AbstractSimulationExtension
. This inserts your listener into the simulation. Your listener can (and ordinarily will) be private to your extension.
- A provider, which extends
AbstractSimulationExtensionProvider
This puts your extension into the menu described above.
In addition, if your extension will have a configuration GUI, you will need to write:
- A configurator, which extends
AbstractSwingSimulationExtensionConfigurator<E>
You can either create your extension outside the source tree and make sure it is in a directory that is in your Java classpath when OpenRocket is executed, or you can insert it in the source tree and compile it along with OpenRocket. Since all of OpenRocket's code is freely available, and reading the code for the existing extensions will be very helpful in writing your own, the easiest approach is to simply insert it in the source tree. If you select this option, a very logical place to put your extension is in
core/src/net/sf/openrocket/simulation/extension/example/
This is where the extension examples provided with OpenRocket are located. Your configurator, if any, will logically go in
swing/src/net/sf/openrocket/simulation/extension/example/
Extension Example
To make things concrete, we'll start by creating a simple example extension, to air-start a rocket from a hard-coded altitude. Later, we'll add a configurator to the extension so we can set the launch altitude through a GUI at run time. This is a simplified version of the AirStart
extension located in the OpenRocket source code tree; that class also sets a start velocity.
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package net.sf.openrocket.simulation.extension.example; import net.sf.openrocket.simulation.SimulationStatus; import net.sf.openrocket.simulation.exception.SimulationException; import net.sf.openrocket.simulation.extension.AbstractSimulationExtension; import net.sf.openrocket.simulation.listeners.AbstractSimulationListener; import net.sf.openrocket.util.Coordinate; /** * Simulation extension that launches a rocket from a specific altitude. */ public class AirStartExample extends AbstractSimulationExtension { public void initialize(SimulationConditions conditions) throws SimulationException { conditions.getSimulationListenerList().add(new AirStartListener()); } @Override public String getName() { return "Air-Start Example"; } @Override public String getDescription() { return "Simple extension example for air-start"; } private class AirStartListener extends AbstractSimulationListener { @Override public void startSimulation(SimulationStatus status) throws SimulationException { status.setRocketPosition(new Coordinate(0, 0, 1000.0)); } } } |
There are several important features in this example:
- The
initialize()
method, which adds the listener to theList
of simulation listeners. This is the only method that is required to be defined in your extension. - The
getName()
method, which provides the extension's name. A defaultgetName()
is provided byAbstractSimulationExtension
, which simply uses the classname (so for this example,
getName()
would return "AirStartExample"
if hadn't overridden it).
- The
getDescription()
method, which provides a brief description of the purpose of the extension. This is the method that provides the text for the anInfo
button in the first section of this page. - The listener itself, which provides a single
startSimulation()
method. When the simulation for starts executing, this listener is called and the rocket is set to an altitude of 1000 meters.
This will create the extension when it's compiled, but it won't put it in the simulation extension menu (so it'll be pretty much useless!). To be able to actually use it, we need a provider, like this:
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package net.sf.openrocket.simulation.extension.example; import net.sf.openrocket.plugin.Plugin; import net.sf.openrocket.simulation.extension.AbstractSimulationExtensionProvider; @Plugin public class AirStartExampleProvider extends AbstractSimulationExtensionProvider { public AirStartExampleProvider() { super(AirStartExample.class, "Launch conditions", "Air-start example"); } } |
This class adds your extension to the extension menu. The first String
("Launch Conditions"
) is the first level, while the second ("Air-start example"
) is the actual menu entry. These strings can be anything you want; using a first level entry that didn't previously exist will add it to the first level menu.
Try it! Putting the extension in a file named core/src/net/sf/openrocket/simulation/extensions/example/AirStartExample.java
and the provider in core/src/net/sf/openrocket/simulation/extensions/example/AirStartExampleProvider.java
, compiling, and running will give you a new entry in the extensions menu; adding it to the simulation will cause your simulation to start at an altitude of 1000 meters.
Adding a Configurator
To be able to configure the extension at run time, we need to write a configurator and provide it with a way to communicate with the extension, first, we'll modify the extension as follows:
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package net.sf.openrocket.simulation.extension.example; import net.sf.openrocket.simulation.SimulationStatus; import net.sf.openrocket.simulation.exception.SimulationException; import net.sf.openrocket.simulation.extension.AbstractSimulationExtension; import net.sf.openrocket.simulation.listeners.AbstractSimulationListener; import net.sf.openrocket.util.Coordinate; /** * Simulation extension that launches a rocket from a specific altitude. */ public class AirStartExample extends AbstractSimulationExtension { public void initialize(SimulationConditions conditions) throws SimulationException { conditions.getSimulationListenerList().add(new AirStartListener()); } @Override public String getName() { return "Air-Start Example"; } @Override public String getDescription() { return "Simple extension example for air-start"; } public double getLaunchAltitude() { return config.getDouble("launchAltitude", 1000.0); } public void setLaunchAltitude(double launchAltitude) { config.put("launchAltitude", launchAltitude); fireChangeEvent(); } private class AirStartListener extends AbstractSimulationListener { @Override public void startSimulation(SimulationStatus status) throws SimulationException { status.setRocketPosition(new Coordinate(0, 0, getLaunchAltitude())); } } } |
This adds two methods to the extension (getLaunchAltitude()
and setLaunchAltitude()
), and calls getLaunchAltitude()
from within the listener to obtain the configured launch altitude. config
is a Config
object, provided by AbstractSimulationExtension
.
One thing to notice is that the call to config.getDouble()
, the value 1000.0
is the default airstart altitude (in meters). This is the value that will appear when the configurator is first opened.
The configurator itself looks like this
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package net.sf.openrocket.simulation.extension.example; import javax.swing.JComponent; import javax.swing.JLabel; import javax.swing.JPanel; import javax.swing.JSpinner; import net.sf.openrocket.document.Simulation; import net.sf.openrocket.gui.SpinnerEditor; import net.sf.openrocket.gui.adaptors.DoubleModel; import net.sf.openrocket.gui.components.BasicSlider; import net.sf.openrocket.gui.components.UnitSelector; import net.sf.openrocket.plugin.Plugin; import net.sf.openrocket.simulation.extension.AbstractSwingSimulationExtensionConfigurator; import net.sf.openrocket.unit.UnitGroup; @Plugin public class AirStartConfigurator extends AbstractSwingSimulationExtensionConfigurator<AirStart> { public AirStartConfigurator() { super(AirStart.class); } @Override protected JComponent getConfigurationComponent(AirStart extension, Simulation simulation, JPanel panel) { panel.add(new JLabel("Launch altitude:")); DoubleModel m = new DoubleModel(extension, "LaunchAltitude", UnitGroup.UNITS_DISTANCE, 0); JSpinner spin = new JSpinner(m.getSpinnerModel()); spin.setEditor(new SpinnerEditor(spin)); panel.add(spin, "w 65lp!"); UnitSelector unit = new UnitSelector(m); panel.add(unit, "w 25"); BasicSlider slider = new BasicSlider(m.getSliderModel(0, 5000)); panel.add(slider, "w 75lp, wrap"); return panel; } } |
After some boilerplate, this class creates a new DoubleModel
to manage the airstart altitude. The most things to notice about the DoubleModel
constructor are the parameters "LaunchAltitude"
and UnitGroup.UNITS_DISTANCE
.
"LaunchAltitude"
is used by the system to synthesize calls to thegetLaunchAltitude()
andsetLaunchAltitude()
methods mentioned earlier; of course, they have to match.UnitGroup.UNITS_DISTANCE
specifies the unit group to be used by thisDoubleModel
. OpenRocket uses SI (MKS) units internally, but allows users to select the units they wish to use for their interface. Specifying aUnitGroup
provides the conversions and unit displays for the interface. The availableUnitGroup
s are defined incore/src/net/sf/openrocket/unit/UnitGroup.java
The remaining code in this method creates a JSpinner
, a UnitSelector
, and a BasicSlider
all referring to this DoubleModel. When the resulting configurator is displayed, it looks like this:
The surrounding Dialog window and the Close button are all provided by the system.