void SixenseManager::update(float deltaTime) {
#ifdef HAVE_SIXENSE
// if the controllers haven't been moved in a while, disable
const unsigned int MOVEMENT_DISABLE_SECONDS = 3;
if (usecTimestampNow() - _lastMovement > (MOVEMENT_DISABLE_SECONDS * USECS_PER_SECOND)) {
Hand* hand = Application::getInstance()->getAvatar()->getHand();
for (std::vector<PalmData>::iterator it = hand->getPalms().begin(); it != hand->getPalms().end(); it++) {
it->setActive(false);
}
_lastMovement = usecTimestampNow();
}
if (sixenseGetNumActiveControllers() == 0) {
_hydrasConnected = false;
return;
}
PerformanceTimer perfTimer("sixense");
if (!_hydrasConnected) {
_hydrasConnected = true;
UserActivityLogger::getInstance().connectedDevice("spatial_controller", "hydra");
}
MyAvatar* avatar = Application::getInstance()->getAvatar();
Hand* hand = avatar->getHand();
int maxControllers = sixenseGetMaxControllers();
// we only support two controllers
sixenseControllerData controllers[2];
int numActiveControllers = 0;
for (int i = 0; i < maxControllers && numActiveControllers < 2; i++) {
if (!sixenseIsControllerEnabled(i)) {
continue;
}
sixenseControllerData* data = controllers + numActiveControllers;
++numActiveControllers;
sixenseGetNewestData(i, data);
// Set palm position and normal based on Hydra position/orientation
// Either find a palm matching the sixense controller, or make a new one
PalmData* palm;
bool foundHand = false;
for (size_t j = 0; j < hand->getNumPalms(); j++) {
if (hand->getPalms()[j].getSixenseID() == data->controller_index) {
palm = &(hand->getPalms()[j]);
foundHand = true;
}
}
if (!foundHand) {
PalmData newPalm(hand);
hand->getPalms().push_back(newPalm);
palm = &(hand->getPalms()[hand->getNumPalms() - 1]);
palm->setSixenseID(data->controller_index);
qDebug("Found new Sixense controller, ID %i", data->controller_index);
}
palm->setActive(true);
// Read controller buttons and joystick into the hand
palm->setControllerButtons(data->buttons);
palm->setTrigger(data->trigger);
palm->setJoystick(data->joystick_x, data->joystick_y);
// Emulate the mouse so we can use scripts
if (Menu::getInstance()->isOptionChecked(MenuOption::SixenseMouseInput)) {
emulateMouse(palm, numActiveControllers - 1);
}
// NOTE: Sixense API returns pos data in millimeters but we IMMEDIATELY convert to meters.
glm::vec3 position(data->pos[0], data->pos[1], data->pos[2]);
position *= METERS_PER_MILLIMETER;
// Transform the measured position into body frame.
glm::vec3 neck = _neckBase;
// Zeroing y component of the "neck" effectively raises the measured position a little bit.
neck.y = 0.f;
position = _orbRotation * (position - neck);
// Rotation of Palm
glm::quat rotation(data->rot_quat[3], -data->rot_quat[0], data->rot_quat[1], -data->rot_quat[2]);
rotation = glm::angleAxis(PI, glm::vec3(0.f, 1.f, 0.f)) * _orbRotation * rotation;
// Compute current velocity from position change
glm::vec3 rawVelocity;
if (deltaTime > 0.f) {
rawVelocity = (position - palm->getRawPosition()) / deltaTime;
} else {
rawVelocity = glm::vec3(0.0f);
}
palm->setRawVelocity(rawVelocity); // meters/sec
// adjustment for hydra controllers fit into hands
float sign = (i == 0) ? -1.0f : 1.0f;
rotation *= glm::angleAxis(sign * PI/4.0f, glm::vec3(0.0f, 0.0f, 1.0f));
if (_lowVelocityFilter) {
// Use a velocity sensitive filter to damp small motions and preserve large ones with
// no latency.
float velocityFilter = glm::clamp(1.0f - glm::length(rawVelocity), 0.0f, 1.0f);
position = palm->getRawPosition() * velocityFilter + position * (1.0f - velocityFilter);
rotation = safeMix(palm->getRawRotation(), rotation, 1.0f - velocityFilter);
palm->setRawPosition(position);
palm->setRawRotation(rotation);
} else {
palm->setRawPosition(position);
palm->setRawRotation(rotation);
}
// use the velocity to determine whether there's any movement (if the hand isn't new)
const float MOVEMENT_DISTANCE_THRESHOLD = 0.003f;
_amountMoved += rawVelocity * deltaTime;
if (glm::length(_amountMoved) > MOVEMENT_DISTANCE_THRESHOLD && foundHand) {
_lastMovement = usecTimestampNow();
_amountMoved = glm::vec3(0.0f);
}
// Store the one fingertip in the palm structure so we can track velocity
const float FINGER_LENGTH = 0.3f; // meters
const glm::vec3 FINGER_VECTOR(0.0f, 0.0f, FINGER_LENGTH);
const glm::vec3 newTipPosition = position + rotation * FINGER_VECTOR;
glm::vec3 oldTipPosition = palm->getTipRawPosition();
if (deltaTime > 0.f) {
palm->setTipVelocity((newTipPosition - oldTipPosition) / deltaTime);
} else {
palm->setTipVelocity(glm::vec3(0.f));
}
palm->setTipPosition(newTipPosition);
}
if (numActiveControllers == 2) {
updateCalibration(controllers);
}
#endif // HAVE_SIXENSE
}
void SixenseManager::update(float deltaTime) {
#ifdef HAVE_SIXENSE
if (sixenseGetNumActiveControllers() == 0) {
return;
}
MyAvatar* avatar = Application::getInstance()->getAvatar();
Hand* hand = avatar->getHand();
int maxControllers = sixenseGetMaxControllers();
// we only support two controllers
sixenseControllerData controllers[2];
int numActiveControllers = 0;
for (int i = 0; i < maxControllers && numActiveControllers < 2; i++) {
if (!sixenseIsControllerEnabled(i)) {
continue;
}
sixenseControllerData* data = controllers + numActiveControllers;
++numActiveControllers;
sixenseGetNewestData(i, data);
// Set palm position and normal based on Hydra position/orientation
// Either find a palm matching the sixense controller, or make a new one
PalmData* palm;
bool foundHand = false;
for (size_t j = 0; j < hand->getNumPalms(); j++) {
if (hand->getPalms()[j].getSixenseID() == data->controller_index) {
palm = &(hand->getPalms()[j]);
foundHand = true;
}
}
if (!foundHand) {
PalmData newPalm(hand);
hand->getPalms().push_back(newPalm);
palm = &(hand->getPalms()[hand->getNumPalms() - 1]);
palm->setSixenseID(data->controller_index);
printf("Found new Sixense controller, ID %i\n", data->controller_index);
}
palm->setActive(true);
// Read controller buttons and joystick into the hand
palm->setControllerButtons(data->buttons);
palm->setTrigger(data->trigger);
palm->setJoystick(data->joystick_x, data->joystick_y);
glm::vec3 position(data->pos[0], data->pos[1], data->pos[2]);
// Transform the measured position into body frame.
glm::vec3 neck = _neckBase;
// Zeroing y component of the "neck" effectively raises the measured position a little bit.
neck.y = 0.f;
position = _orbRotation * (position - neck);
// Rotation of Palm
glm::quat rotation(data->rot_quat[3], -data->rot_quat[0], data->rot_quat[1], -data->rot_quat[2]);
rotation = glm::angleAxis(PI, glm::vec3(0.f, 1.f, 0.f)) * _orbRotation * rotation;
const glm::vec3 PALM_VECTOR(0.0f, -1.0f, 0.0f);
glm::vec3 newNormal = rotation * PALM_VECTOR;
palm->setRawNormal(newNormal);
palm->setRawRotation(rotation);
// Compute current velocity from position change
glm::vec3 rawVelocity = (position - palm->getRawPosition()) / deltaTime / 1000.f;
palm->setRawVelocity(rawVelocity); // meters/sec
palm->setRawPosition(position);
// use the velocity to determine whether there's any movement (if the hand isn't new)
const float MOVEMENT_SPEED_THRESHOLD = 0.05f;
if (glm::length(rawVelocity) > MOVEMENT_SPEED_THRESHOLD && foundHand) {
_lastMovement = usecTimestampNow();
}
// initialize the "finger" based on the direction
FingerData finger(palm, hand);
finger.setActive(true);
finger.setRawRootPosition(position);
const float FINGER_LENGTH = 300.0f; // Millimeters
const glm::vec3 FINGER_VECTOR(0.0f, 0.0f, FINGER_LENGTH);
const glm::vec3 newTipPosition = position + rotation * FINGER_VECTOR;
finger.setRawTipPosition(position + rotation * FINGER_VECTOR);
// Store the one fingertip in the palm structure so we can track velocity
glm::vec3 oldTipPosition = palm->getTipRawPosition();
palm->setTipVelocity((newTipPosition - oldTipPosition) / deltaTime / 1000.f);
palm->setTipPosition(newTipPosition);
// three fingers indicates to the skeleton that we have enough data to determine direction
palm->getFingers().clear();
palm->getFingers().push_back(finger);
palm->getFingers().push_back(finger);
palm->getFingers().push_back(finger);
}
if (numActiveControllers == 2) {
updateCalibration(controllers);
}
// if the controllers haven't been moved in a while, disable
const unsigned int MOVEMENT_DISABLE_DURATION = 30 * 1000 * 1000;
if (usecTimestampNow() - _lastMovement > MOVEMENT_DISABLE_DURATION) {
for (std::vector<PalmData>::iterator it = hand->getPalms().begin(); it != hand->getPalms().end(); it++) {
it->setActive(false);
}
}
#endif // HAVE_SIXENSE
}
void SixenseManager::update(float deltaTime) {
#ifdef HAVE_SIXENSE
Hand* hand = DependencyManager::get<AvatarManager>()->getMyAvatar()->getHand();
if (_isInitialized && _isEnabled) {
#ifdef __APPLE__
SixenseBaseFunction sixenseGetNumActiveControllers =
(SixenseBaseFunction) _sixenseLibrary->resolve("sixenseGetNumActiveControllers");
#endif
if (sixenseGetNumActiveControllers() == 0) {
_hydrasConnected = false;
return;
}
PerformanceTimer perfTimer("sixense");
if (!_hydrasConnected) {
_hydrasConnected = true;
UserActivityLogger::getInstance().connectedDevice("spatial_controller", "hydra");
}
#ifdef __APPLE__
SixenseBaseFunction sixenseGetMaxControllers =
(SixenseBaseFunction) _sixenseLibrary->resolve("sixenseGetMaxControllers");
#endif
int maxControllers = sixenseGetMaxControllers();
// we only support two controllers
sixenseControllerData controllers[2];
#ifdef __APPLE__
SixenseTakeIntFunction sixenseIsControllerEnabled =
(SixenseTakeIntFunction) _sixenseLibrary->resolve("sixenseIsControllerEnabled");
SixenseTakeIntAndSixenseControllerData sixenseGetNewestData =
(SixenseTakeIntAndSixenseControllerData) _sixenseLibrary->resolve("sixenseGetNewestData");
#endif
int numControllersAtBase = 0;
int numActiveControllers = 0;
for (int i = 0; i < maxControllers && numActiveControllers < 2; i++) {
if (!sixenseIsControllerEnabled(i)) {
continue;
}
sixenseControllerData* data = controllers + numActiveControllers;
++numActiveControllers;
sixenseGetNewestData(i, data);
// Set palm position and normal based on Hydra position/orientation
// Either find a palm matching the sixense controller, or make a new one
PalmData* palm;
bool foundHand = false;
for (size_t j = 0; j < hand->getNumPalms(); j++) {
if (hand->getPalms()[j].getSixenseID() == data->controller_index) {
palm = &(hand->getPalms()[j]);
foundHand = true;
}
}
if (!foundHand) {
PalmData newPalm(hand);
hand->getPalms().push_back(newPalm);
palm = &(hand->getPalms()[hand->getNumPalms() - 1]);
palm->setSixenseID(data->controller_index);
qCDebug(interfaceapp, "Found new Sixense controller, ID %i", data->controller_index);
}
// Disable the hands (and return to default pose) if both controllers are at base station
if (foundHand) {
palm->setActive(!_controllersAtBase);
} else {
palm->setActive(false); // if this isn't a Sixsense ID palm, always make it inactive
}
// Read controller buttons and joystick into the hand
palm->setControllerButtons(data->buttons);
palm->setTrigger(data->trigger);
palm->setJoystick(data->joystick_x, data->joystick_y);
// Emulate the mouse so we can use scripts
if (Menu::getInstance()->isOptionChecked(MenuOption::SixenseMouseInput) && !_controllersAtBase) {
emulateMouse(palm, numActiveControllers - 1);
}
// NOTE: Sixense API returns pos data in millimeters but we IMMEDIATELY convert to meters.
glm::vec3 position(data->pos[0], data->pos[1], data->pos[2]);
position *= METERS_PER_MILLIMETER;
// Check to see if this hand/controller is on the base
const float CONTROLLER_AT_BASE_DISTANCE = 0.075f;
if (glm::length(position) < CONTROLLER_AT_BASE_DISTANCE) {
numControllersAtBase++;
}
// Transform the measured position into body frame.
glm::vec3 neck = _neckBase;
// Zeroing y component of the "neck" effectively raises the measured position a little bit.
neck.y = 0.0f;
position = _orbRotation * (position - neck);
// Rotation of Palm
glm::quat rotation(data->rot_quat[3], -data->rot_quat[0], data->rot_quat[1], -data->rot_quat[2]);
rotation = glm::angleAxis(PI, glm::vec3(0.0f, 1.0f, 0.0f)) * _orbRotation * rotation;
// Compute current velocity from position change
glm::vec3 rawVelocity;
if (deltaTime > 0.0f) {
rawVelocity = (position - palm->getRawPosition()) / deltaTime;
} else {
rawVelocity = glm::vec3(0.0f);
}
palm->setRawVelocity(rawVelocity); // meters/sec
// adjustment for hydra controllers fit into hands
float sign = (i == 0) ? -1.0f : 1.0f;
rotation *= glm::angleAxis(sign * PI/4.0f, glm::vec3(0.0f, 0.0f, 1.0f));
// Angular Velocity of Palm
glm::quat deltaRotation = rotation * glm::inverse(palm->getRawRotation());
glm::vec3 angularVelocity(0.0f);
float rotationAngle = glm::angle(deltaRotation);
if ((rotationAngle > EPSILON) && (deltaTime > 0.0f)) {
angularVelocity = glm::normalize(glm::axis(deltaRotation));
angularVelocity *= (rotationAngle / deltaTime);
palm->setRawAngularVelocity(angularVelocity);
} else {
palm->setRawAngularVelocity(glm::vec3(0.0f));
}
if (_lowVelocityFilter) {
// Use a velocity sensitive filter to damp small motions and preserve large ones with
// no latency.
float velocityFilter = glm::clamp(1.0f - glm::length(rawVelocity), 0.0f, 1.0f);
position = palm->getRawPosition() * velocityFilter + position * (1.0f - velocityFilter);
rotation = safeMix(palm->getRawRotation(), rotation, 1.0f - velocityFilter);
palm->setRawPosition(position);
palm->setRawRotation(rotation);
} else {
palm->setRawPosition(position);
palm->setRawRotation(rotation);
}
// Store the one fingertip in the palm structure so we can track velocity
const float FINGER_LENGTH = 0.3f; // meters
const glm::vec3 FINGER_VECTOR(0.0f, 0.0f, FINGER_LENGTH);
const glm::vec3 newTipPosition = position + rotation * FINGER_VECTOR;
glm::vec3 oldTipPosition = palm->getTipRawPosition();
if (deltaTime > 0.0f) {
palm->setTipVelocity((newTipPosition - oldTipPosition) / deltaTime);
} else {
palm->setTipVelocity(glm::vec3(0.0f));
}
palm->setTipPosition(newTipPosition);
}
if (numActiveControllers == 2) {
updateCalibration(controllers);
}
_controllersAtBase = (numControllersAtBase == 2);
}
#endif // HAVE_SIXENSE
}