static bool createRotation(ParserContext* ctx, const xmlChar** att)
{
double period = 0.0;
double obliquity = 0.0;
double axisLongitude = 0.0;
double offset = 0.0;
double epoch = astro::J2000;
if (att != NULL)
{
for (int i = 0; att[i] != NULL; i += 2)
{
if (matchName(att[i], "period"))
{
if (matchName(att[i + 1], "sync"))
period = 0.0;
else
parseTime(att[i + 1], period, "h");
}
else if (matchName(att[i], "obliquity"))
parseAngle(att[i + 1], obliquity);
else if (matchName(att[i], "axis-longitude"))
parseAngle(att[i + 1], axisLongitude);
else if (matchName(att[i], "offset"))
parseAngle(att[i + 1], offset);
else if (matchName(att[i], "epoch"))
parseEpoch(att[i + 1], epoch);
}
}
assert(ctx->body != NULL);
RotationElements re;
// A period of 0 means that the object is in synchronous rotation, so
// we'll set its rotation period equal to its orbital period. The catch
// is that we require that the orbit was specified before the rotation
// elements within the XML file.
Orbit* orbit = ctx->body->getOrbit();
if (orbit == NULL)
return false;
if (period == 0.0)
re.period = (float) orbit->getPeriod();
else
re.period = (float) period / 24.0f;
re.obliquity = (float) degToRad(obliquity);
re.axisLongitude = (float) degToRad(axisLongitude);
re.offset = (float) degToRad(offset);
re.epoch = epoch;
ctx->body->setRotationElements(re);
return true;
}
static bool CreateTimeline(Body* body,
PlanetarySystem* system,
Universe& universe,
Hash* planetData,
const string& path,
Disposition disposition,
BodyType bodyType)
{
FrameTree* parentFrameTree = NULL;
Selection parentObject = GetParentObject(system);
bool orbitsPlanet = false;
if (parentObject.body())
{
parentFrameTree = parentObject.body()->getOrCreateFrameTree();
orbitsPlanet = true;
}
else if (parentObject.star())
{
SolarSystem* solarSystem = universe.getSolarSystem(parentObject.star());
if (solarSystem == NULL)
solarSystem = universe.createSolarSystem(parentObject.star());
parentFrameTree = solarSystem->getFrameTree();
}
else
{
// Bad orbit barycenter specified
return false;
}
ReferenceFrame* defaultOrbitFrame = NULL;
ReferenceFrame* defaultBodyFrame = NULL;
if (bodyType == SurfaceObject)
{
defaultOrbitFrame = new BodyFixedFrame(parentObject, parentObject);
defaultBodyFrame = CreateTopocentricFrame(parentObject, parentObject, Selection(body));
defaultOrbitFrame->addRef();
defaultBodyFrame->addRef();
}
else
{
defaultOrbitFrame = parentFrameTree->getDefaultReferenceFrame();
defaultBodyFrame = parentFrameTree->getDefaultReferenceFrame();
}
// If there's an explicit timeline definition, parse that. Otherwise, we'll do
// things the old way.
Value* value = planetData->getValue("Timeline");
if (value != NULL)
{
if (value->getType() != Value::ArrayType)
{
clog << "Error: Timeline must be an array\n";
return false;
}
Timeline* timeline = CreateTimelineFromArray(body, universe, value->getArray(), path,
defaultOrbitFrame, defaultBodyFrame);
if (timeline == NULL)
{
return false;
}
else
{
body->setTimeline(timeline);
return true;
}
}
// Information required for the object timeline.
ReferenceFrame* orbitFrame = NULL;
ReferenceFrame* bodyFrame = NULL;
Orbit* orbit = NULL;
RotationModel* rotationModel = NULL;
double beginning = -numeric_limits<double>::infinity();
double ending = numeric_limits<double>::infinity();
// If any new timeline values are specified, we need to overrideOldTimeline will
// be set to true.
bool overrideOldTimeline = false;
// The interaction of Modify with timelines is slightly complicated. If the timeline
// is specified by putting the OrbitFrame, Orbit, BodyFrame, or RotationModel directly
// in the object definition (i.e. not inside a Timeline structure), it will completely
// replace the previous timeline if it contained more than one phase. Otherwise, the
// properties of the single phase will be modified individually, for compatibility with
// Celestia versions 1.5.0 and earlier.
if (disposition == ModifyObject)
{
const Timeline* timeline = body->getTimeline();
if (timeline->phaseCount() == 1)
{
const TimelinePhase* phase = timeline->getPhase(0);
orbitFrame = phase->orbitFrame();
bodyFrame = phase->bodyFrame();
orbit = phase->orbit();
rotationModel = phase->rotationModel();
beginning = phase->startTime();
ending = phase->endTime();
}
}
// Get the object's orbit reference frame.
bool newOrbitFrame = false;
Value* frameValue = planetData->getValue("OrbitFrame");
if (frameValue != NULL)
{
ReferenceFrame* frame = CreateReferenceFrame(universe, frameValue, parentObject, body);
if (frame != NULL)
{
orbitFrame = frame;
newOrbitFrame = true;
overrideOldTimeline = true;
}
}
// Get the object's body frame.
bool newBodyFrame = false;
Value* bodyFrameValue = planetData->getValue("BodyFrame");
if (bodyFrameValue != NULL)
{
ReferenceFrame* frame = CreateReferenceFrame(universe, bodyFrameValue, parentObject, body);
if (frame != NULL)
{
bodyFrame = frame;
newBodyFrame = true;
overrideOldTimeline = true;
}
}
// If no orbit or body frame was specified, use the default ones
if (orbitFrame == NULL)
orbitFrame = defaultOrbitFrame;
if (bodyFrame == NULL)
bodyFrame = defaultBodyFrame;
// If the center of the is a star, orbital element units are
// in AU; otherwise, use kilometers.
if (orbitFrame->getCenter().star() != NULL)
orbitsPlanet = false;
else
orbitsPlanet = true;
Orbit* newOrbit = CreateOrbit(orbitFrame->getCenter(), planetData, path, !orbitsPlanet);
if (newOrbit == NULL && orbit == NULL)
{
if (body->getTimeline() && disposition == ModifyObject)
{
// The object definition is modifying an existing object with a multiple phase
// timeline, but no orbit definition was given. This can happen for completely
// sensible reasons, such a Modify definition that just changes visual properties.
// Or, the definition may try to change other timeline phase properties such as
// the orbit frame, but without providing an orbit. In both cases, we'll just
// leave the original timeline alone.
return true;
}
else
{
clog << "No valid orbit specified for object '" << body->getName() << "'. Skipping.\n";
return false;
}
}
// If a new orbit was given, override any old orbit
if (newOrbit != NULL)
{
orbit = newOrbit;
overrideOldTimeline = true;
}
// Get the rotation model for this body
double syncRotationPeriod = orbit->getPeriod();
RotationModel* newRotationModel = CreateRotationModel(planetData, path, syncRotationPeriod);
// If a new rotation model was given, override the old one
if (newRotationModel != NULL)
{
rotationModel = newRotationModel;
overrideOldTimeline = true;
}
// If there was no rotation model specified, nor a previous rotation model to
// override, create the default one.
if (rotationModel == NULL)
{
// If no rotation model is provided, use a default rotation model--
// a uniform rotation that's synchronous with the orbit (appropriate
// for nearly all natural satellites in the solar system.)
rotationModel = CreateDefaultRotationModel(syncRotationPeriod);
}
if (ParseDate(planetData, "Beginning", beginning))
overrideOldTimeline = true;
if (ParseDate(planetData, "Ending", ending))
overrideOldTimeline = true;
// Something went wrong if the disposition isn't modify and no timeline
// is to be created.
assert(disposition == ModifyObject || overrideOldTimeline);
if (overrideOldTimeline)
{
if (beginning >= ending)
{
clog << "Beginning time must be before Ending time.\n";
return false;
}
// We finally have an orbit, rotation model, frames, and time range. Create
// the object timeline.
TimelinePhase* phase = TimelinePhase::CreateTimelinePhase(universe,
body,
beginning, ending,
*orbitFrame,
*orbit,
*bodyFrame,
*rotationModel);
// We've already checked that beginning < ending; nothing else should go
// wrong during the creation of a TimelinePhase.
assert(phase != NULL);
if (phase == NULL)
{
clog << "Internal error creating TimelinePhase.\n";
return false;
}
Timeline* timeline = new Timeline();
timeline->appendPhase(phase);
body->setTimeline(timeline);
// Check for circular references in frames; this can only be done once the timeline
// has actually been set.
// TIMELINE-TODO: This check is not comprehensive; it won't find recursion in
// multiphase timelines.
if (newOrbitFrame && isFrameCircular(*body->getOrbitFrame(0.0), ReferenceFrame::PositionFrame))
{
clog << "Orbit frame for " << body->getName() << " is nested too deep (probably circular)\n";
return false;
}
if (newBodyFrame && isFrameCircular(*body->getBodyFrame(0.0), ReferenceFrame::OrientationFrame))
{
clog << "Body frame for " << body->getName() << " is nested too deep (probably circular)\n";
return false;
}
}
return true;
}
TimelinePhase* CreateTimelinePhase(Body* body,
Universe& universe,
Hash* phaseData,
const string& path,
ReferenceFrame* defaultOrbitFrame,
ReferenceFrame* defaultBodyFrame,
bool isFirstPhase,
bool isLastPhase,
double previousPhaseEnd)
{
double beginning = previousPhaseEnd;
double ending = numeric_limits<double>::infinity();
// Beginning is optional for the first phase of a timeline, and not
// allowed for the other phases, where beginning is always the ending
// of the previous phase.
bool hasBeginning = ParseDate(phaseData, "Beginning", beginning);
if (!isFirstPhase && hasBeginning)
{
clog << "Error: Beginning can only be specified for initial phase of timeline.\n";
return NULL;
}
// Ending is required for all phases except for the final one.
bool hasEnding = ParseDate(phaseData, "Ending", ending);
if (!isLastPhase && !hasEnding)
{
clog << "Error: Ending is required for all timeline phases other than the final one.\n";
return NULL;
}
// Get the orbit reference frame.
ReferenceFrame* orbitFrame;
Value* frameValue = phaseData->getValue("OrbitFrame");
if (frameValue != NULL)
{
orbitFrame = CreateReferenceFrame(universe, frameValue, defaultOrbitFrame->getCenter(), body);
if (orbitFrame == NULL)
{
return NULL;
}
}
else
{
// No orbit frame specified; use the default frame.
orbitFrame = defaultOrbitFrame;
}
orbitFrame->addRef();
// Get the body reference frame
ReferenceFrame* bodyFrame;
Value* bodyFrameValue = phaseData->getValue("BodyFrame");
if (bodyFrameValue != NULL)
{
bodyFrame = CreateReferenceFrame(universe, bodyFrameValue, defaultBodyFrame->getCenter(), body);
if (bodyFrame == NULL)
{
orbitFrame->release();
return NULL;
}
}
else
{
// No body frame specified; use the default frame.
bodyFrame = defaultBodyFrame;
}
bodyFrame->addRef();
// Use planet units (AU for semimajor axis) if the center of the orbit
// reference frame is a star.
bool usePlanetUnits = orbitFrame->getCenter().star() != NULL;
// Get the orbit
Orbit* orbit = CreateOrbit(orbitFrame->getCenter(), phaseData, path, usePlanetUnits);
if (!orbit)
{
clog << "Error: missing orbit in timeline phase.\n";
bodyFrame->release();
orbitFrame->release();
return NULL;
}
// Get the rotation model
// TIMELINE-TODO: default rotation model is UniformRotation with a period
// equal to the orbital period. Should we do something else?
RotationModel* rotationModel = CreateRotationModel(phaseData, path, orbit->getPeriod());
if (!rotationModel)
{
// TODO: Should distinguish between a missing rotation model (where it's
// appropriate to use a default one) and a bad rotation model (where
// we should report an error.)
rotationModel = new ConstantOrientation(Quaterniond::Identity());
}
TimelinePhase* phase = TimelinePhase::CreateTimelinePhase(universe,
body,
beginning, ending,
*orbitFrame,
*orbit,
*bodyFrame,
*rotationModel);
// Frame ownership transfered to phase; release local references
orbitFrame->release();
bodyFrame->release();
return phase;
}