// Create the context for the scene
void SetUp()
{
// Init simulation
sofa::component::init();
sofa::simulation::setSimulation(simulation = new sofa::simulation::graph::DAGSimulation());
size_t resolutionCircumferential=7;
size_t resolutionRadial=3;
size_t resolutionHeight=7;
size_t maxIteration=3000; // maximum iteration for the CG.
vIndex=(resolutionCircumferential*(resolutionRadial-1)+1)*resolutionHeight/2;
//Load the scene
std::string sceneName = (DataTypes::sceneName);
std::string fileName = std::string(FLEXIBLE_TEST_SCENES_DIR) + "/" + sceneName;
tractionStruct.root = simulation->createNewGraph("root");
tractionStruct.root = sofa::core::objectmodel::SPtr_dynamic_cast<sofa::simulation::Node>( sofa::simulation::getSimulation()->load(fileName.c_str()));
// Get force field
typedef component::forcefield::TrianglePressureForceField<Vec3Types> TrianglePressureForceField;
tractionStruct.forceField = tractionStruct.root->get<TrianglePressureForceField>( tractionStruct.root->SearchDown);
// Get mechanical object
typedef component::container::MechanicalObject<Vec3Types> MechanicalObject;
tractionStruct.dofs = tractionStruct.root->get<MechanicalObject>( tractionStruct.root->SearchDown);
// Get child nodes
simulation::Node::SPtr behaviorNode = tractionStruct.root->getChild("behavior");
strainNode = behaviorNode->getChild("Strain");
}
/// Create the context for the tests.
void SetUp()
{
// if( sofa::simulation::getSimulation()==NULL )
sofa::simulation::setSimulation(simulation = new sofa::simulation::graph::DAGSimulation());
/// Create the scene
root = simulation->createNewGraph("root");
PointSetTopologyContainer::SPtr topology = core::objectmodel::New<PointSetTopologyContainer>();
root->addObject(topology);
dofs = core::objectmodel::New<MechanicalObject>();
root->addObject(dofs);
projection = core::objectmodel::New<ProjectToLineConstraint>();
root->addObject(projection);
/// Set the values
numNodes = 3;
dofs->resize(numNodes);
origin = CPos(0,0,0);
projection->f_origin.setValue(origin);
direction = CPos(1,1,1);
projection->f_direction.setValue(direction);
}
/// Create the context for the matrix tests.
void SetUp()
{
sofa::component::init();
// if( sofa::simulation::getSimulation()==NULL )
sofa::simulation::setSimulation(simulation = new sofa::simulation::graph::DAGSimulation());
/// Create the scene
root = simulation->createNewGraph("root");
PointSetTopologyContainer::SPtr topology = New<PointSetTopologyContainer>();
root->addObject(topology);
dofs = New<MechanicalObject>();
root->addObject(dofs);
projection = New<ProjectToPlaneConstraint>();
root->addObject(projection);
/// Set the values
numNodes = 3;
dofs->resize(numNodes);
origin = CPos(0,0,0);
projection->f_origin.setValue(origin);
normal = CPos(1,1,1);
projection->f_normal.setValue(normal);
}
/** Constrain one particle, and not the last one.
Detects bugs like not setting the projection matrix entries beyond the last constrained particle
*/
void init_2bones()
{
joints.clear();
typename MechanicalObject::WriteVecCoord x = dofs->writePositions();
x.resize(2);
VecCoord rigids(2);
DataTypes::setCPos(x[1], CPos(0,1,0));
DataTypes::setCRot(x[1], CRot(0.707107,0, 0, 0.707107)); // rotation x: 90 degree
Coord target(CPos(1,1,1), CRot(0,0.382683,0,0.92388)); //rotation y : 45 degrees
joints.resize(2);
joints[0].addChannel(x[0], 0);
joints[0].addChannel(target, 1);
joints[0].setRestPosition(x[0]);
joints[1].addChannel(x[1], 0);
joints[1].setRestPosition(x[1]);
joints[1].mParentIndex = 0;
helper::vector<int> bones(2,0); bones[1] = 1;
projection->setSkeletalMotion(joints, bones);
/// Init
sofa::simulation::getSimulation()->init(root.get());
simulation->animate(root.get(),0.25);
simulation->animate(root.get(),0.25);
}
/// Create the context for the tests.
void SetUp()
{
// if( sofa::simulation::getSimulation()==NULL )
sofa::simulation::setSimulation(simulation = new sofa::simulation::graph::DAGSimulation());
/// Create the scene
root = simulation->createNewGraph("root");
dofs = core::objectmodel::New<MechanicalObject>();
root->addObject(dofs);
projection = core::objectmodel::New<SkeletalMotionConstraint>();
root->addObject(projection);
}
// Create the context for the scene
void SetUp()
{
// Init simulation
sofa::simulation::setSimulation(simulation = new sofa::simulation::graph::DAGSimulation());
vIndex=5;
//Load the scene
std::string sceneName = (DataTypes::sceneName);
std::string fileName = std::string(FLEXIBLE_TEST_SCENES_DIR) + "/" + sceneName;
tractionStruct.root = simulation->createNewGraph("root");
tractionStruct.root = down_cast<sofa::simulation::Node>( sofa::simulation::getSimulation()->load(fileName.c_str()).get() );
// Get child nodes
simulation::Node::SPtr triangleNode = tractionStruct.root->getChild("Triangles");
simulation::Node::SPtr behaviorNode = tractionStruct.root->getChild("behavior");
strainNode = behaviorNode->getChild("Strain");
// Get force field
typedef component::forcefield::TrianglePressureForceField<Vec3Types> TrianglePressureForceField;
tractionStruct.forceField = triangleNode->get<TrianglePressureForceField>( tractionStruct.root->SearchDown);
// Get mechanical object
typedef component::container::MechanicalObject<Vec3Types> MechanicalObject;
tractionStruct.dofs = tractionStruct.root->get<MechanicalObject>( tractionStruct.root->SearchDown);
// Add behavior mechanical object
DefoDOFsSPtr defoDofs = addNew<DefoDOFs>(behaviorNode);
// Add linear mapping
typename LinearMapping::SPtr linearMapping = addNew<LinearMapping>(behaviorNode);
linearMapping->setModels(tractionStruct.dofs.get(),defoDofs.get());
// Add strain mechanical object
strainDOFsSPtr strainDOFs = addNew<StrainDOFs>(strainNode);
// Add strain mapping
typename StrainMapping::SPtr strainMapping = addNew<StrainMapping>(strainNode);
strainMapping->setModels(defoDofs.get(),strainDOFs.get());
}
//------------------------------------------------------------------------------
// Handle input devices
//------------------------------------------------------------------------------
void IoHandler::inputDevices(const LCreal dt) {
BaseClass::inputDevices(dt);
// ---
// get the Input data buffer
// ---
const Basic::IoData* const inData = getInputData();
// ---
// get the Station, Simulation and our ownship player
// ---
SimStation* const sta = static_cast<SimStation*>( findContainerByType(typeid(SimStation)) );
Simulation::Simulation* sim = 0;
Simulation::AirVehicle* av = 0;
if (sta != 0) {
sim = sta->getSimulation();
av = dynamic_cast<Simulation::AirVehicle*>(sta->getOwnship());
}
// ---
// If we have everything we need ....
// ---
if (av != 0 && sim != 0 && inData != 0) {
// find the (optional) autopilot
Simulation::Autopilot* ap = 0;
{
Basic::Pair* p = av->getPilotByType( typeid( Simulation::Autopilot) );
if (p != 0) ap = static_cast<Simulation::Autopilot*>( p->object() );
}
// ------------------------------------------------------------
// Simulation Control Inputs
// ------------------------------------------------------------
{
bool enabled = false;
inData->getDiscreteInput(CTL_ENABLE_SW, &enabled);
{ // Toggle simulation freeze
bool sw = false;
inData->getDiscreteInput(FREEZE_SW, &sw);
bool frzSw = sw && enabled;
if (frzSw && !frzSw1) {
Basic::Boolean newFrz( !sim->isFrozen() );
sim->event(FREEZE_EVENT, &newFrz);
}
frzSw1 = frzSw;
}
{ // Send a reset pulse to the station
bool sw = false;
inData->getDiscreteInput(RESET_SW, &sw);
bool rstSw = sw && enabled;
if (rstSw && !rstSw1) {
sta->event(RESET_EVENT);
}
rstSw1 = rstSw;
}
{ // Send a weapons reload pulse to the station
bool sw = false;
inData->getDiscreteInput(RELOAD_SW, &sw);
bool wpnReloadSw = sw && enabled;
if (wpnReloadSw && !wpnReloadSw1) {
sta->event(WPN_RELOAD);
}
wpnReloadSw1 = wpnReloadSw;
}
}
// ------------------------------------------------------------
// Flight Control Inputs
// ------------------------------------------------------------
{ // Process Roll Input
LCreal ai = 0;
inData->getAnalogInput(ROLL_AI, &ai);
LCreal aiLim = alim(ai, 1.0f);
if (ap != 0) ap->setControlStickRollInput(aiLim);
else av->setControlStickRollInput(aiLim);
}
{ // Process Pitch Input
LCreal ai = 0;
inData->getAnalogInput(PITCH_AI, &ai);
LCreal aiLim = alim(ai, 1.0f);
if (ap != 0) ap->setControlStickPitchInput(aiLim);
else av->setControlStickPitchInput(aiLim);
}
{ // Process Rudder Input
LCreal ai = 0;
inData->getAnalogInput(RUDDER_AI, &ai);
LCreal aiLim = alim(ai, 1.0f);
av->setRudderPedalInput(aiLim);
}
{ // Process Throttle Input
LCreal value = 0;
inData->getAnalogInput(THROTTLE_AI, &value);
if (value < 0.0f) value = 0.0f;
else if (value > 2.0f) value = 2.0f;
if (ap != 0) ap->setThrottles(&value,1);
else av->setThrottles(&value,1);
}
{ // Weapons Release
bool sw = false;
inData->getDiscreteInput(PICKLE_SW, &sw);
if (sw != wpnRelSw1) {
Basic::Boolean sw(sw);
av->event(WPN_REL_EVENT, &sw);
}
wpnRelSw1 = sw;
}
{ // Trigger switch
bool sw = false;
inData->getDiscreteInput(TRIGGER_SW2, &sw);
if (sw != trgSw1) {
Basic::Boolean sw(sw);
av->event(TRIGGER_SW_EVENT, &sw);
}
trgSw1 = sw;
}
{ // Target Step (reject)
bool sw = false;
inData->getDiscreteInput(TMS_RIGHT_SW, &sw);
if (sw && !tgtStepSw1) {
av->event(TGT_STEP_EVENT);
}
tgtStepSw1 = sw;
}
{ // Target Designate
bool sw = false;
inData->getDiscreteInput(TMS_UP_SW, &sw);
if (sw && !tgtDesSw1) {
av->event(TGT_DESIGNATE);
}
tgtDesSw1 = sw;
}
{ // Return-To-Search
bool sw = false;
inData->getDiscreteInput(TMS_DOWN_SW, &sw);
if (sw && !rtn2SrchSw1) {
av->event(SENSOR_RTS);
}
rtn2SrchSw1 = sw;
}
{ // Autopilot disengage
bool autopilotSw = false;
inData->getDiscreteInput(PADDLE_SW, &autopilotSw);
if (autopilotSw && !autopilotSw1) {
Simulation::Autopilot* ap = dynamic_cast<Simulation::Autopilot*>(av->getPilot());
if (ap != 0) {
ap->setHeadingHoldMode(false);
ap->setAltitudeHoldMode(false);
ap->setVelocityHoldMode(false);
ap->setLoiterMode(false);
ap->setNavMode(false);
}
}
autopilotSw1 = autopilotSw;
}
{ // Speedbrake switch
bool sbExtSw = false;
bool sbRetSw = false;
inData->getDiscreteInput(SB_EXT_SW, &sbExtSw);
inData->getDiscreteInput(SB_RET_SW, &sbRetSw);
LCreal sb = 0.0;
if(sbExtSw) sb = -1.0f;
if(sbRetSw) sb = 1.0f;
av->setSpeedBrakesSwitch(sb);
}
{ // Steerpoint increment
bool incStptSw = false;
inData->getDiscreteInput(DMS_UP_SW, &incStptSw);
if(incStptSw && !incStptSw1) {
// find our route and increment the steerpoint
Simulation::Navigation* myNav = av->getNavigation();
if (myNav != 0) {
myNav->ref();
Simulation::Route* myRoute = myNav->getPriRoute();
if (myRoute != 0) {
myRoute->ref();
myRoute->incStpt();
myRoute->unref();
}
}
}
incStptSw1 = incStptSw;
}
{ // Steerpoint decrement
bool decStptSw = false;
inData->getDiscreteInput(DMS_DOWN_SW, &decStptSw);
if (decStptSw && !decStptSw1) {
// find our route and increment the steerpoint
Simulation::Navigation* myNav = av->getNavigation();
if (myNav != 0) {
myNav->ref();
Simulation::Route* myRoute = myNav->getPriRoute();
if (myRoute != 0) {
myRoute->ref();
myRoute->decStpt();
myRoute->unref();
}
}
}
decStptSw1 = decStptSw;
}
}
}
//------------------------------------------------------------------------------
// entityStateManager() -- (Output support)
// -- Update the entity object for this NIB(Player)
//------------------------------------------------------------------------------
bool Nib::entityStateManager(const LCreal curExecTime)
{
bool ok = false;
// Get the player pointer
const Simulation::Player* player = getPlayer();
if (player == nullptr) return ok;
// Dummy weapon?
const Simulation::Weapon* ww = dynamic_cast<const Simulation::Weapon*>( player );
if (ww != nullptr) {
if (ww->isDummy()) return ok;
}
if (isPlayerStateUpdateRequired(curExecTime)) {
//
// Send an entity state PDU
// 1) create buffer
// 2) set state information
// 3) send data
//
// Get our NetIO and the main simulation
NetIO* disIO = static_cast<NetIO*>(getNetIO());
Simulation::Simulation* sim = disIO->getSimulation();
// Capture the player data, reset the dead reckoning and
// mark the current time.
playerState2Nib();
// ---
// Create buffer and cast it as an entity state PDU
// ---
char pduBuffer[NetIO::MAX_PDU_SIZE];
EntityStatePDU* pdu = (EntityStatePDU*) &pduBuffer[0];
//
// Entity state PDU structure
// =========================================================
// PDUHeader header;
// EntityIdentifierDIS entityID;
// uint8_t forceID;
// uint8_t numberOfArticulationParameters;
// EntityType entityType;
// EntityType alternativeType;
// VectorDIS entityLinearVelocity;
// WorldCoordinates entityLocation;
// EulerAngles entityOrientation;
// uint32_t appearance;
// uint8_t deadReckoningAlgorithm;
// uint8_t otherParameters[15];
// VectorDIS DRentityLinearAcceleration;
// AngularVelocityVectorDIS DRentityAngularVelocity;
// EntityMarking entityMarking;
// uint32_t capabilities;
// =========================================================
//
// ---
// Standard header (PDUHeader)
// ---
pdu->header.protocolVersion = disIO->getVersion();
pdu->header.exerciseIdentifier = disIO->getExerciseID();
pdu->header.PDUType = NetIO::PDU_ENTITY_STATE;
pdu->header.protocolFamily = NetIO::PDU_FAMILY_ENTITY_INFO;
//
if (disIO->getTimeline() == Simulation::NetIO::UTC)
pdu->header.timeStamp = disIO->makeTimeStamp( getTimeUtc(), true );
else
pdu->header.timeStamp = disIO->makeTimeStamp( getTimeExec(), false );
//
pdu->header.status = 0;
pdu->header.padding = 0;
// ---
// Entity ID (EntityIdentifierID)
// ---
pdu->entityID.simulationID.siteIdentification = getSiteID();
pdu->entityID.simulationID.applicationIdentification = getApplicationID();
pdu->entityID.ID = getPlayerID();
// ---
// Force ID: When mapping Player side to force IDs ...
// ---
if (getSide() == Simulation::Player::BLUE) {
// blue's are friendly, ...
pdu->forceID = NetIO::FRIENDLY_FORCE;
}
else if (getSide() == Simulation::Player::RED) {
// red's are not, ...
pdu->forceID = NetIO::OPPOSING_FORCE;
}
else if (getSide() == Simulation::Player::WHITE) {
// white is neutral, ...
pdu->forceID = NetIO::NEUTRAL_FORCE;
}
else {
// and everyone else is type OTHER.
pdu->forceID = NetIO::OTHER_FORCE;
}
// ---
// Entity type (EntityType)
// ---
pdu->entityType.kind = getEntityKind();
pdu->entityType.domain = getEntityDomain();
pdu->entityType.country = getEntityCountry();
pdu->entityType.category = getEntityCategory();
pdu->entityType.subcategory = getEntitySubcategory();
pdu->entityType.specific = getEntitySpecific();
pdu->entityType.extra = getEntityExtra();
// ---
// Alternative type (EntityType)
// ---
pdu->alternativeType.kind = getEntityKind();
pdu->alternativeType.domain = getEntityDomain();
pdu->alternativeType.country = getEntityCountry();
pdu->alternativeType.category = getEntityCategory();
pdu->alternativeType.subcategory = getEntitySubcategory();
pdu->alternativeType.specific = getEntitySpecific();
pdu->alternativeType.extra = getEntityExtra();
// ---
// Player position and orientation state data data
// 1) All data is geocentric (ECEF)
// 2) The playerState2Nib() function, which was called above, captures
// the state data and passed the state data to the dead reckoning
// system, and we're using this DR captured data.
// ---
{
// ---
// Entity linear velocity (VectorDIS)
// ---
osg::Vec3d geocVel = getDrVelocity();
pdu->entityLinearVelocity.component[0] = static_cast<float>(geocVel[0]);
pdu->entityLinearVelocity.component[1] = static_cast<float>(geocVel[1]);
pdu->entityLinearVelocity.component[2] = static_cast<float>(geocVel[2]);
// ---
// Entity location (WorldCoordinates)
// ---
osg::Vec3d geocPos = getDrPosition();
pdu->entityLocation.X_coord = geocPos[Basic::Nav::IX];
pdu->entityLocation.Y_coord = geocPos[Basic::Nav::IY];
pdu->entityLocation.Z_coord = geocPos[Basic::Nav::IZ];
// ---
// Entity orientation (EulerAngles)
// ---
osg::Vec3d geocAngles = getDrEulerAngles();
pdu->entityOrientation.phi = static_cast<float>(geocAngles[Basic::Nav::IPHI]);
pdu->entityOrientation.theta = static_cast<float>(geocAngles[Basic::Nav::ITHETA]);
pdu->entityOrientation.psi = static_cast<float>(geocAngles[Basic::Nav::IPSI]);
}
// ---
// Appearance bits generic to all domains (except munitions)
// ---
{
pdu->appearance = 0x0;
// ---
// Frozen?
// ---
if ( isFrozen() || sim->isFrozen() ) {
pdu->appearance |= FROZEN_BIT;
}
// Deactive this entity?
{
if (isMode(Simulation::Player::DELETE_REQUEST) || player->isDead() )
pdu->appearance |= DEACTIVATE_BIT;
}
// Damage or health? (Bits 3-4)
{
unsigned int bits = 0;
if (getDamage() > 0.9f) bits = 3; // Destroyed or Fatality
else if (getDamage() > 0.5) bits = 2; // Moderate
else if (getDamage() > 0.0) bits = 1; // Slight
else bits = 0; // None
pdu->appearance |= (bits << 3);
}
// Camouflage type
// Note: air platform appearance bits 17 and 18 are not used, but we're using them the same as land platforms
{
unsigned int bits = getCamouflageType();
if (bits > 0 && bits <= 4) {
pdu->appearance |= CAMOUFLAGE_BIT;
// Land based camouflage bits
if (player->isMajorType(Simulation::Player::GROUND_VEHICLE)) {
// Subtract one to match DIS camouflage bits.
// Our camouflage type for DIS is the camouflage appearance bits
// plus one because our camouflage type of zero is no camouflage.
bits--;
pdu->appearance |= (bits << 17);
}
}
}
// Life forms appearance bits
if (player->isMajorType(Simulation::Player::LIFE_FORM)) {
const Simulation::LifeForm* lf = dynamic_cast<const Simulation::LifeForm*>(player);
if (lf != nullptr) {
// Health (aka damaged for other domains) same bits (3-4) - this is from the NIB, because it IS
// updated
// bits 5-8 compliance (not implemented)
// bits 9 - 11 unused
// bit 12 flashlight (not implemented)
// bits 13-15 unused
// bits 16 - 19 life form state
// data is from the player, because NIB doesn't have actions associated with it
{
unsigned int bits = 1; // upright, standing still
if (lf->getActionState() == Simulation::LifeForm::UPRIGHT_STANDING) bits = 1; // standing
else if (lf->getActionState() == Simulation::LifeForm::UPRIGHT_WALKING) bits = 2; // walking
else if (lf->getActionState() == Simulation::LifeForm::UPRIGHT_RUNNING) bits = 3; // running
else if (lf->getActionState() == Simulation::LifeForm::KNEELING) bits = 4; // kneeling
else if (lf->getActionState() == Simulation::LifeForm::PRONE) bits = 5; // prone
else if (lf->getActionState() == Simulation::LifeForm::CRAWLING) bits = 6; // crawling
else if (lf->getActionState() == Simulation::LifeForm::SWIMMING) bits = 7; // swimming
else if (lf->getActionState() == Simulation::LifeForm::PARACHUTING) bits = 8; // parachuting
else if (lf->getActionState() == Simulation::LifeForm::JUMPING) bits = 9; // jumping
else if (lf->getActionState() == Simulation::LifeForm::SITTING) bits = 10; // sitting
else if (lf->getActionState() == Simulation::LifeForm::SQUATTING) bits = 11; // squatting
else if (lf->getActionState() == Simulation::LifeForm::CROUCHING) bits = 12; // crouching
else if (lf->getActionState() == Simulation::LifeForm::WADING) bits = 13; // wading
else if (lf->getActionState() == Simulation::LifeForm::SURRENDER) bits = 14; // surrender
else if (lf->getActionState() == Simulation::LifeForm::DETAINED) bits = 15; // detained
else bits = 1;
pdu->appearance |= (bits << 16);
}
// bit 20 unused
// bit 21 frozen status (taken care of above)
// bits 24 - 25 weapon 1 (not implemented)
// bits 26-27 weapon 2 (N/I)
// bits 28-29
}
}
// Common Non-life form appearance bits
else {
// Smoking? (Bits 5-6) Standard (IST-CF-03-01, May 5, 2003)
{
unsigned int bits = 0;
if (getSmoke() > 0.9f) bits = 3;
else if (getSmoke() > 0.5) bits = 2;
else if (getSmoke() > 0.0) bits = 1;
else bits = 0;
pdu->appearance |= (bits << 5);
}
// Flames? (Bit 15) Standard (IST-CF-03-01, May 5, 2003)
{
if (getFlames() > 0.5f)
pdu->appearance |= FLAMES_BIT;
}
// Power plant status bit (just leave ON for now)
pdu->appearance |= POWER_PLANT_BIT;
}
}
// ---
// Dead reckoning algorithm
// ---
pdu->deadReckoningAlgorithm = static_cast<unsigned char>(getDeadReckoning());
// ---
// Other parameters
// ---
for (unsigned int i=0; i<15; i++) {
pdu->otherParameters[i] = 0;
}
// ---
// Dead reckoning information
// ---
{
// ---
// Dead reckoning linear acceleration (VectorDIS)
// ---
osg::Vec3d geocAcc = getDrAcceleration();
pdu->DRentityLinearAcceleration.component[0] = static_cast<float>(geocAcc[0]);
pdu->DRentityLinearAcceleration.component[1] = static_cast<float>(geocAcc[1]);
pdu->DRentityLinearAcceleration.component[2] = static_cast<float>(geocAcc[2]);
// ---
// Dead reckoning angular velocity (AngularVelocityVectorDIS)
// ---
osg::Vec3d geocAngVel = getDrAngularVelocities();
pdu->DRentityAngularVelocity.x_axis = static_cast<float>(geocAngVel[Basic::Nav::IX]);
pdu->DRentityAngularVelocity.y_axis = static_cast<float>(geocAngVel[Basic::Nav::IY]);
pdu->DRentityAngularVelocity.z_axis = static_cast<float>(geocAngVel[Basic::Nav::IZ]);
}
// ---
// Entity marking (EntityMarking)
// ---
{
const char* const pName = getPlayerName();
size_t nameLen = std::strlen(pName);
for (unsigned int i = 0; i < EntityMarking::BUFF_SIZE; i++) {
if (i < nameLen) {
pdu->entityMarking.marking[i] = pName[i];
}
else {
pdu->entityMarking.marking[i] = '\0';
}
}
pdu->entityMarking.characterSet = 1;
}
// ---
// Capabilities
// ---
pdu->capabilites = 0x0;
// ---
// Articulation parameters
// ---
pdu->numberOfArticulationParameters = manageArticulationParameters(pdu);
// Size of the PDU package
unsigned short length = sizeof(EntityStatePDU) + (pdu->numberOfArticulationParameters * sizeof(VpArticulatedPart));
pdu->header.length = length;
if (Basic::NetHandler::isNotNetworkByteOrder()) pdu->swapBytes();
ok = disIO->sendData( reinterpret_cast<char*>(pdu), length );
}
return ok;
}
