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overte-Armored-Dragon/interface/src/avatar/MyAvatar.cpp
Andrew Meadows 02c58447df merge upstream/master into "shapes" project 
Conflicts:
	interface/src/avatar/MyAvatar.cpp
	interface/src/avatar/SkeletonModel.cpp
	interface/src/avatar/SkeletonModel.h
	libraries/avatars/src/HandData.h
	libraries/shared/src/SharedUtil.h
2014-03-18 12:41:20 -07:00

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//
// MyAvatar.cpp
// interface
//
// Created by Mark Peng on 8/16/13.
// Copyright (c) 2012 High Fidelity, Inc. All rights reserved.
//
#include <algorithm>
#include <vector>
#include <QBuffer>
#include <glm/gtx/vector_angle.hpp>
#include <QtCore/QTimer>
#include <AccountManager.h>
#include <NodeList.h>
#include <PacketHeaders.h>
#include <SharedUtil.h>
#include "Application.h"
#include "Audio.h"
#include "Environment.h"
#include "Menu.h"
#include "MyAvatar.h"
#include "Physics.h"
#include "VoxelSystem.h"
#include "devices/Faceshift.h"
#include "devices/OculusManager.h"
#include "ui/TextRenderer.h"
using namespace std;
const glm::vec3 DEFAULT_UP_DIRECTION(0.0f, 1.0f, 0.0f);
const float YAW_SPEED = 500.0f; // degrees/sec
const float PITCH_SPEED = 100.0f; // degrees/sec
const float COLLISION_RADIUS_SCALAR = 1.2f; // pertains to avatar-to-avatar collisions
const float COLLISION_RADIUS_SCALE = 0.125f;
const float DATA_SERVER_LOCATION_CHANGE_UPDATE_MSECS = 5 * 1000;
MyAvatar::MyAvatar() :
Avatar(),
_mousePressed(false),
_bodyPitchDelta(0.0f),
_bodyRollDelta(0.0f),
_shouldJump(false),
_gravity(0.0f, -1.0f, 0.0f),
_distanceToNearestAvatar(std::numeric_limits<float>::max()),
_elapsedTimeMoving(0.0f),
_elapsedTimeStopped(0.0f),
_elapsedTimeSinceCollision(0.0f),
_lastCollisionPosition(0, 0, 0),
_speedBrakes(false),
_isThrustOn(false),
_thrustMultiplier(1.0f),
_moveTarget(0,0,0),
_moveTargetStepCounter(0),
_lookAtTargetAvatar(),
_shouldRender(true),
_billboardValid(false)
{
for (int i = 0; i < MAX_DRIVE_KEYS; i++) {
_driveKeys[i] = 0.0f;
}
// update our location every 5 seconds in the data-server, assuming that we are authenticated with one
QTimer* locationUpdateTimer = new QTimer(this);
connect(locationUpdateTimer, &QTimer::timeout, this, &MyAvatar::updateLocationInDataServer);
locationUpdateTimer->start(DATA_SERVER_LOCATION_CHANGE_UPDATE_MSECS);
}
MyAvatar::~MyAvatar() {
_lookAtTargetAvatar.clear();
}
void MyAvatar::reset() {
// TODO? resurrect headMouse stuff?
//_headMouseX = _glWidget->width() / 2;
//_headMouseY = _glWidget->height() / 2;
getHead()->reset();
getHand()->reset();
setVelocity(glm::vec3(0,0,0));
setThrust(glm::vec3(0,0,0));
}
void MyAvatar::setMoveTarget(const glm::vec3 moveTarget) {
_moveTarget = moveTarget;
_moveTargetStepCounter = 0;
}
void MyAvatar::update(float deltaTime) {
updateFromGyros(deltaTime);
// Update head mouse from faceshift if active
Faceshift* faceshift = Application::getInstance()->getFaceshift();
if (faceshift->isActive()) {
// TODO? resurrect headMouse stuff?
//glm::vec3 headVelocity = faceshift->getHeadAngularVelocity();
//// sets how quickly head angular rotation moves the head mouse
//const float HEADMOUSE_FACESHIFT_YAW_SCALE = 40.f;
//const float HEADMOUSE_FACESHIFT_PITCH_SCALE = 30.f;
//_headMouseX -= headVelocity.y * HEADMOUSE_FACESHIFT_YAW_SCALE;
//_headMouseY -= headVelocity.x * HEADMOUSE_FACESHIFT_PITCH_SCALE;
//
//// Constrain head-driven mouse to edges of screen
//_headMouseX = glm::clamp(_headMouseX, 0, _glWidget->width());
//_headMouseY = glm::clamp(_headMouseY, 0, _glWidget->height());
}
Head* head = getHead();
if (OculusManager::isConnected()) {
float yaw, pitch, roll; // these angles will be in radians
OculusManager::getEulerAngles(yaw, pitch, roll);
// but these euler angles are stored in degrees
head->setYaw(yaw * DEGREES_PER_RADIAN);
head->setPitch(pitch * DEGREES_PER_RADIAN);
head->setRoll(roll * DEGREES_PER_RADIAN);
}
// Get audio loudness data from audio input device
Audio* audio = Application::getInstance()->getAudio();
head->setAudioLoudness(audio->getLastInputLoudness());
head->setAudioAverageLoudness(audio->getAudioAverageInputLoudness());
if (Menu::getInstance()->isOptionChecked(MenuOption::Gravity)) {
setGravity(Application::getInstance()->getEnvironment()->getGravity(getPosition()));
} else {
setGravity(glm::vec3(0.0f, 0.0f, 0.0f));
}
simulate(deltaTime);
}
void MyAvatar::simulate(float deltaTime) {
glm::quat orientation = getOrientation();
// Update movement timers
_elapsedTimeSinceCollision += deltaTime;
const float VELOCITY_MOVEMENT_TIMER_THRESHOLD = 0.2f;
if (glm::length(_velocity) < VELOCITY_MOVEMENT_TIMER_THRESHOLD) {
_elapsedTimeMoving = 0.f;
_elapsedTimeStopped += deltaTime;
} else {
_elapsedTimeStopped = 0.f;
_elapsedTimeMoving += deltaTime;
}
if (_scale != _targetScale) {
float scale = (1.f - SMOOTHING_RATIO) * _scale + SMOOTHING_RATIO * _targetScale;
setScale(scale);
Application::getInstance()->getCamera()->setScale(scale);
}
// Collect thrust forces from keyboard and devices
updateThrust(deltaTime);
// copy velocity so we can use it later for acceleration
glm::vec3 oldVelocity = getVelocity();
// calculate speed
_speed = glm::length(_velocity);
// update the movement of the hand and process handshaking with other avatars...
updateHandMovementAndTouching(deltaTime);
// apply gravity
// For gravity, always move the avatar by the amount driven by gravity, so that the collision
// routines will detect it and collide every frame when pulled by gravity to a surface
const float MIN_DISTANCE_AFTER_COLLISION_FOR_GRAVITY = 0.02f;
if (glm::length(_position - _lastCollisionPosition) > MIN_DISTANCE_AFTER_COLLISION_FOR_GRAVITY) {
_velocity += _scale * _gravity * (GRAVITY_EARTH * deltaTime);
}
// add thrust to velocity
_velocity += _thrust * deltaTime;
// update body yaw by body yaw delta
orientation = orientation * glm::quat(glm::radians(
glm::vec3(_bodyPitchDelta, _bodyYawDelta, _bodyRollDelta) * deltaTime));
// decay body rotation momentum
const float BODY_SPIN_FRICTION = 7.5f;
float bodySpinMomentum = 1.f - BODY_SPIN_FRICTION * deltaTime;
if (bodySpinMomentum < 0.0f) { bodySpinMomentum = 0.0f; }
_bodyPitchDelta *= bodySpinMomentum;
_bodyYawDelta *= bodySpinMomentum;
_bodyRollDelta *= bodySpinMomentum;
float MINIMUM_ROTATION_RATE = 2.0f;
if (fabs(_bodyYawDelta) < MINIMUM_ROTATION_RATE) { _bodyYawDelta = 0.f; }
if (fabs(_bodyRollDelta) < MINIMUM_ROTATION_RATE) { _bodyRollDelta = 0.f; }
if (fabs(_bodyPitchDelta) < MINIMUM_ROTATION_RATE) { _bodyPitchDelta = 0.f; }
const float MAX_STATIC_FRICTION_VELOCITY = 0.5f;
const float STATIC_FRICTION_STRENGTH = _scale * 20.f;
applyStaticFriction(deltaTime, _velocity, MAX_STATIC_FRICTION_VELOCITY, STATIC_FRICTION_STRENGTH);
// Damp avatar velocity
const float LINEAR_DAMPING_STRENGTH = 0.5f;
const float SPEED_BRAKE_POWER = _scale * 10.0f;
const float SQUARED_DAMPING_STRENGTH = 0.007f;
const float SLOW_NEAR_RADIUS = 5.f;
float linearDamping = LINEAR_DAMPING_STRENGTH;
const float NEAR_AVATAR_DAMPING_FACTOR = 50.f;
if (_distanceToNearestAvatar < _scale * SLOW_NEAR_RADIUS) {
linearDamping *= 1.f + NEAR_AVATAR_DAMPING_FACTOR *
((SLOW_NEAR_RADIUS - _distanceToNearestAvatar) / SLOW_NEAR_RADIUS);
}
if (_speedBrakes) {
applyDamping(deltaTime, _velocity, linearDamping * SPEED_BRAKE_POWER, SQUARED_DAMPING_STRENGTH * SPEED_BRAKE_POWER);
} else {
applyDamping(deltaTime, _velocity, linearDamping, SQUARED_DAMPING_STRENGTH);
}
// update the euler angles
setOrientation(orientation);
// Compute instantaneous acceleration
float forwardAcceleration = glm::length(glm::dot(getBodyFrontDirection(), getVelocity() - oldVelocity)) / deltaTime;
const float OCULUS_ACCELERATION_PULL_THRESHOLD = 1.0f;
const int OCULUS_YAW_OFFSET_THRESHOLD = 10;
if (!Application::getInstance()->getFaceshift()->isActive() && OculusManager::isConnected() &&
fabsf(forwardAcceleration) > OCULUS_ACCELERATION_PULL_THRESHOLD &&
fabs(getHead()->getYaw()) > OCULUS_YAW_OFFSET_THRESHOLD) {
// if we're wearing the oculus
// and this acceleration is above the pull threshold
// and the head yaw if off the body by more than OCULUS_YAW_OFFSET_THRESHOLD
// match the body yaw to the oculus yaw
_bodyYaw = getAbsoluteHeadYaw();
// set the head yaw to zero for this draw
getHead()->setYaw(0);
// correct the oculus yaw offset
OculusManager::updateYawOffset();
}
const float WALKING_SPEED_THRESHOLD = 0.2f;
// use speed and angular velocity to determine walking vs. standing
if (_speed + fabs(_bodyYawDelta) > WALKING_SPEED_THRESHOLD) {
_mode = AVATAR_MODE_WALKING;
} else {
_mode = AVATAR_MODE_INTERACTING;
}
// update moving flag based on speed
const float MOVING_SPEED_THRESHOLD = 0.01f;
_moving = _speed > MOVING_SPEED_THRESHOLD;
// If a move target is set, update position explicitly
const float MOVE_FINISHED_TOLERANCE = 0.1f;
const float MOVE_SPEED_FACTOR = 2.f;
const int MOVE_TARGET_MAX_STEPS = 250;
if ((glm::length(_moveTarget) > EPSILON) && (_moveTargetStepCounter < MOVE_TARGET_MAX_STEPS)) {
if (glm::length(_position - _moveTarget) > MOVE_FINISHED_TOLERANCE) {
_position += (_moveTarget - _position) * (deltaTime * MOVE_SPEED_FACTOR);
_moveTargetStepCounter++;
} else {
// Move completed
_moveTarget = glm::vec3(0,0,0);
_moveTargetStepCounter = 0;
}
}
updateChatCircle(deltaTime);
_position += _velocity * deltaTime;
// update avatar skeleton and simulate hand and head
getHand()->collideAgainstOurself();
getHand()->simulate(deltaTime, true);
_skeletonModel.simulate(deltaTime);
// copy out the skeleton joints from the model
_jointData.resize(_skeletonModel.getJointStateCount());
for (int i = 0; i < _jointData.size(); i++) {
JointData& data = _jointData[i];
data.valid = _skeletonModel.getJointState(i, data.rotation);
}
Head* head = getHead();
glm::vec3 headPosition;
if (!_skeletonModel.getHeadPosition(headPosition)) {
headPosition = _position;
}
head->setPosition(headPosition);
head->setScale(_scale);
head->simulate(deltaTime, true);
// Zero thrust out now that we've added it to velocity in this frame
_thrust = glm::vec3(0, 0, 0);
// now that we're done stepping the avatar forward in time, compute new collisions
if (_collisionFlags != 0) {
Camera* myCamera = Application::getInstance()->getCamera();
float radius = getSkeletonHeight() * COLLISION_RADIUS_SCALE;
if (myCamera->getMode() == CAMERA_MODE_FIRST_PERSON && !OculusManager::isConnected()) {
radius = myCamera->getAspectRatio() * (myCamera->getNearClip() / cos(myCamera->getFieldOfView() / 2.f));
radius *= COLLISION_RADIUS_SCALAR;
}
if (_collisionFlags & COLLISION_GROUP_ENVIRONMENT) {
updateCollisionWithEnvironment(deltaTime, radius);
}
if (_collisionFlags & COLLISION_GROUP_VOXELS) {
updateCollisionWithVoxels(deltaTime, radius);
}
if (_collisionFlags & COLLISION_GROUP_AVATARS) {
updateCollisionWithAvatars(deltaTime);
}
}
// resolve collision results
_skeletonModel.syncToPalms();
// consider updating our billboard
maybeUpdateBillboard();
}
// Update avatar head rotation with sensor data
void MyAvatar::updateFromGyros(float deltaTime) {
Faceshift* faceshift = Application::getInstance()->getFaceshift();
Visage* visage = Application::getInstance()->getVisage();
glm::vec3 estimatedPosition, estimatedRotation;
bool trackerActive = false;
if (faceshift->isActive()) {
estimatedPosition = faceshift->getHeadTranslation();
estimatedRotation = glm::degrees(safeEulerAngles(faceshift->getHeadRotation()));
trackerActive = true;
} else if (visage->isActive()) {
estimatedPosition = visage->getHeadTranslation();
estimatedRotation = glm::degrees(safeEulerAngles(visage->getHeadRotation()));
trackerActive = true;
}
Head* head = getHead();
if (trackerActive) {
// Rotate the body if the head is turned beyond the screen
if (Menu::getInstance()->isOptionChecked(MenuOption::TurnWithHead)) {
const float TRACKER_YAW_TURN_SENSITIVITY = 0.5f;
const float TRACKER_MIN_YAW_TURN = 15.f;
const float TRACKER_MAX_YAW_TURN = 50.f;
if ( (fabs(estimatedRotation.y) > TRACKER_MIN_YAW_TURN) &&
(fabs(estimatedRotation.y) < TRACKER_MAX_YAW_TURN) ) {
if (estimatedRotation.y > 0.f) {
_bodyYawDelta += (estimatedRotation.y - TRACKER_MIN_YAW_TURN) * TRACKER_YAW_TURN_SENSITIVITY;
} else {
_bodyYawDelta += (estimatedRotation.y + TRACKER_MIN_YAW_TURN) * TRACKER_YAW_TURN_SENSITIVITY;
}
}
}
} else {
// restore rotation, lean to neutral positions
const float RESTORE_PERIOD = 1.f; // seconds
float restorePercentage = glm::clamp(deltaTime/RESTORE_PERIOD, 0.f, 1.f);
head->setPitchTweak(glm::mix(head->getPitchTweak(), 0.0f, restorePercentage));
head->setYawTweak(glm::mix(head->getYawTweak(), 0.0f, restorePercentage));
head->setRollTweak(glm::mix(head->getRollTweak(), 0.0f, restorePercentage));
head->setLeanSideways(glm::mix(head->getLeanSideways(), 0.0f, restorePercentage));
head->setLeanForward(glm::mix(head->getLeanForward(), 0.0f, restorePercentage));
return;
}
// Set the rotation of the avatar's head (as seen by others, not affecting view frustum)
// to be scaled. Pitch is greater to emphasize nodding behavior / synchrony.
const float AVATAR_HEAD_PITCH_MAGNIFY = 1.0f;
const float AVATAR_HEAD_YAW_MAGNIFY = 1.0f;
const float AVATAR_HEAD_ROLL_MAGNIFY = 1.0f;
head->setPitchTweak(estimatedRotation.x * AVATAR_HEAD_PITCH_MAGNIFY);
head->setYawTweak(estimatedRotation.y * AVATAR_HEAD_YAW_MAGNIFY);
head->setRollTweak(estimatedRotation.z * AVATAR_HEAD_ROLL_MAGNIFY);
// Update torso lean distance based on accelerometer data
const float TORSO_LENGTH = 0.5f;
glm::vec3 relativePosition = estimatedPosition - glm::vec3(0.0f, -TORSO_LENGTH, 0.0f);
const float MAX_LEAN = 45.0f;
head->setLeanSideways(glm::clamp(glm::degrees(atanf(relativePosition.x * _leanScale / TORSO_LENGTH)),
-MAX_LEAN, MAX_LEAN));
head->setLeanForward(glm::clamp(glm::degrees(atanf(relativePosition.z * _leanScale / TORSO_LENGTH)),
-MAX_LEAN, MAX_LEAN));
// if Faceshift drive is enabled, set the avatar drive based on the head position
if (!Menu::getInstance()->isOptionChecked(MenuOption::MoveWithLean)) {
return;
}
// Move with Lean by applying thrust proportional to leaning
glm::quat orientation = head->getCameraOrientation();
glm::vec3 front = orientation * IDENTITY_FRONT;
glm::vec3 right = orientation * IDENTITY_RIGHT;
float leanForward = head->getLeanForward();
float leanSideways = head->getLeanSideways();
// Degrees of 'dead zone' when leaning, and amount of acceleration to apply to lean angle
const float LEAN_FWD_DEAD_ZONE = 15.f;
const float LEAN_SIDEWAYS_DEAD_ZONE = 10.f;
const float LEAN_FWD_THRUST_SCALE = 4.f;
const float LEAN_SIDEWAYS_THRUST_SCALE = 3.f;
if (fabs(leanForward) > LEAN_FWD_DEAD_ZONE) {
if (leanForward > 0.f) {
addThrust(front * -(leanForward - LEAN_FWD_DEAD_ZONE) * LEAN_FWD_THRUST_SCALE);
} else {
addThrust(front * -(leanForward + LEAN_FWD_DEAD_ZONE) * LEAN_FWD_THRUST_SCALE);
}
}
if (fabs(leanSideways) > LEAN_SIDEWAYS_DEAD_ZONE) {
if (leanSideways > 0.f) {
addThrust(right * -(leanSideways - LEAN_SIDEWAYS_DEAD_ZONE) * LEAN_SIDEWAYS_THRUST_SCALE);
} else {
addThrust(right * -(leanSideways + LEAN_SIDEWAYS_DEAD_ZONE) * LEAN_SIDEWAYS_THRUST_SCALE);
}
}
}
static TextRenderer* textRenderer() {
static TextRenderer* renderer = new TextRenderer(SANS_FONT_FAMILY, 24, -1, false, TextRenderer::SHADOW_EFFECT);
return renderer;
}
void MyAvatar::renderDebugBodyPoints() {
glm::vec3 torsoPosition(getPosition());
glm::vec3 headPosition(getHead()->getEyePosition());
float torsoToHead = glm::length(headPosition - torsoPosition);
glm::vec3 position;
printf("head-above-torso %.2f, scale = %0.2f\n", torsoToHead, getScale());
// Torso Sphere
position = torsoPosition;
glPushMatrix();
glColor4f(0, 1, 0, .5f);
glTranslatef(position.x, position.y, position.z);
glutSolidSphere(0.2, 10, 10);
glPopMatrix();
// Head Sphere
position = headPosition;
glPushMatrix();
glColor4f(0, 1, 0, .5f);
glTranslatef(position.x, position.y, position.z);
glutSolidSphere(0.15, 10, 10);
glPopMatrix();
}
void MyAvatar::render(bool forShadowMapOrMirror) {
// don't render if we've been asked to disable local rendering
if (!_shouldRender) {
return; // exit early
}
if (Menu::getInstance()->isOptionChecked(MenuOption::Avatars)) {
renderBody(forShadowMapOrMirror);
}
// render body
if (Menu::getInstance()->isOptionChecked(MenuOption::RenderSkeletonCollisionProxies)) {
_skeletonModel.renderCollisionProxies(0.8f);
}
if (Menu::getInstance()->isOptionChecked(MenuOption::RenderHeadCollisionProxies)) {
getHead()->getFaceModel().renderCollisionProxies(0.8f);
}
setShowDisplayName(!forShadowMapOrMirror);
if (forShadowMapOrMirror) {
return;
}
renderDisplayName();
if (!_chatMessage.empty()) {
int width = 0;
int lastWidth = 0;
for (string::iterator it = _chatMessage.begin(); it != _chatMessage.end(); it++) {
width += (lastWidth = textRenderer()->computeWidth(*it));
}
glPushMatrix();
glm::vec3 chatPosition = getHead()->getEyePosition() + getBodyUpDirection() * CHAT_MESSAGE_HEIGHT * _scale;
glTranslatef(chatPosition.x, chatPosition.y, chatPosition.z);
glm::quat chatRotation = Application::getInstance()->getCamera()->getRotation();
glm::vec3 chatAxis = glm::axis(chatRotation);
glRotatef(glm::degrees(glm::angle(chatRotation)), chatAxis.x, chatAxis.y, chatAxis.z);
glColor3f(0.f, 0.8f, 0.f);
glRotatef(180.f, 0.f, 1.f, 0.f);
glRotatef(180.f, 0.f, 0.f, 1.f);
glScalef(_scale * CHAT_MESSAGE_SCALE, _scale * CHAT_MESSAGE_SCALE, 1.0f);
glDisable(GL_LIGHTING);
glDepthMask(false);
if (_keyState == NO_KEY_DOWN) {
textRenderer()->draw(-width / 2.0f, 0, _chatMessage.c_str());
} else {
// rather than using substr and allocating a new string, just replace the last
// character with a null, then restore it
int lastIndex = _chatMessage.size() - 1;
char lastChar = _chatMessage[lastIndex];
_chatMessage[lastIndex] = '\0';
textRenderer()->draw(-width / 2.0f, 0, _chatMessage.c_str());
_chatMessage[lastIndex] = lastChar;
glColor3f(0.f, 1.f, 0.f);
textRenderer()->draw(width / 2.0f - lastWidth, 0, _chatMessage.c_str() + lastIndex);
}
glEnable(GL_LIGHTING);
glDepthMask(true);
glPopMatrix();
}
}
void MyAvatar::renderHeadMouse() const {
// TODO? resurrect headMouse stuff?
/*
// Display small target box at center or head mouse target that can also be used to measure LOD
glColor3f(1.f, 1.f, 1.f);
glDisable(GL_LINE_SMOOTH);
const int PIXEL_BOX = 16;
glBegin(GL_LINES);
glVertex2f(_headMouseX - PIXEL_BOX/2, _headMouseY);
glVertex2f(_headMouseX + PIXEL_BOX/2, _headMouseY);
glVertex2f(_headMouseX, _headMouseY - PIXEL_BOX/2);
glVertex2f(_headMouseX, _headMouseY + PIXEL_BOX/2);
glEnd();
glEnable(GL_LINE_SMOOTH);
glColor3f(1.f, 0.f, 0.f);
glPointSize(3.0f);
glDisable(GL_POINT_SMOOTH);
glBegin(GL_POINTS);
glVertex2f(_headMouseX - 1, _headMouseY + 1);
glEnd();
// If Faceshift is active, show eye pitch and yaw as separate pointer
if (_faceshift.isActive()) {
const float EYE_TARGET_PIXELS_PER_DEGREE = 40.0;
int eyeTargetX = (_glWidget->width() / 2) - _faceshift.getEstimatedEyeYaw() * EYE_TARGET_PIXELS_PER_DEGREE;
int eyeTargetY = (_glWidget->height() / 2) - _faceshift.getEstimatedEyePitch() * EYE_TARGET_PIXELS_PER_DEGREE;
glColor3f(0.f, 1.f, 1.f);
glDisable(GL_LINE_SMOOTH);
glBegin(GL_LINES);
glVertex2f(eyeTargetX - PIXEL_BOX/2, eyeTargetY);
glVertex2f(eyeTargetX + PIXEL_BOX/2, eyeTargetY);
glVertex2f(eyeTargetX, eyeTargetY - PIXEL_BOX/2);
glVertex2f(eyeTargetX, eyeTargetY + PIXEL_BOX/2);
glEnd();
}
*/
}
void MyAvatar::saveData(QSettings* settings) {
settings->beginGroup("Avatar");
settings->setValue("bodyYaw", _bodyYaw);
settings->setValue("bodyPitch", _bodyPitch);
settings->setValue("bodyRoll", _bodyRoll);
settings->setValue("headPitch", getHead()->getPitch());
settings->setValue("position_x", _position.x);
settings->setValue("position_y", _position.y);
settings->setValue("position_z", _position.z);
settings->setValue("pupilDilation", getHead()->getPupilDilation());
settings->setValue("leanScale", _leanScale);
settings->setValue("scale", _targetScale);
settings->setValue("faceModelURL", _faceModelURL);
settings->setValue("skeletonModelURL", _skeletonModelURL);
settings->setValue("displayName", _displayName);
settings->endGroup();
}
void MyAvatar::loadData(QSettings* settings) {
settings->beginGroup("Avatar");
// in case settings is corrupt or missing loadSetting() will check for NaN
_bodyYaw = loadSetting(settings, "bodyYaw", 0.0f);
_bodyPitch = loadSetting(settings, "bodyPitch", 0.0f);
_bodyRoll = loadSetting(settings, "bodyRoll", 0.0f);
getHead()->setPitch(loadSetting(settings, "headPitch", 0.0f));
_position.x = loadSetting(settings, "position_x", 0.0f);
_position.y = loadSetting(settings, "position_y", 0.0f);
_position.z = loadSetting(settings, "position_z", 0.0f);
getHead()->setPupilDilation(loadSetting(settings, "pupilDilation", 0.0f));
_leanScale = loadSetting(settings, "leanScale", 0.05f);
_targetScale = loadSetting(settings, "scale", 1.0f);
setScale(_scale);
Application::getInstance()->getCamera()->setScale(_scale);
setFaceModelURL(settings->value("faceModelURL").toUrl());
setSkeletonModelURL(settings->value("skeletonModelURL").toUrl());
setDisplayName(settings->value("displayName").toString());
settings->endGroup();
}
void MyAvatar::sendKillAvatar() {
QByteArray killPacket = byteArrayWithPopulatedHeader(PacketTypeKillAvatar);
NodeList::getInstance()->broadcastToNodes(killPacket, NodeSet() << NodeType::AvatarMixer);
}
void MyAvatar::orbit(const glm::vec3& position, int deltaX, int deltaY) {
// first orbit horizontally
glm::quat orientation = getOrientation();
const float ANGULAR_SCALE = 0.5f;
glm::quat rotation = glm::angleAxis(glm::radians(- deltaX * ANGULAR_SCALE), orientation * IDENTITY_UP);
setPosition(position + rotation * (getPosition() - position));
orientation = rotation * orientation;
setOrientation(orientation);
// then vertically
float oldPitch = getHead()->getPitch();
getHead()->setPitch(oldPitch - deltaY * ANGULAR_SCALE);
rotation = glm::angleAxis(glm::radians((getHead()->getPitch() - oldPitch)), orientation * IDENTITY_RIGHT);
setPosition(position + rotation * (getPosition() - position));
}
void MyAvatar::updateLookAtTargetAvatar() {
Application* applicationInstance = Application::getInstance();
if (!applicationInstance->isMousePressed()) {
glm::vec3 mouseOrigin = applicationInstance->getMouseRayOrigin();
glm::vec3 mouseDirection = applicationInstance->getMouseRayDirection();
foreach (const AvatarSharedPointer& avatarPointer, Application::getInstance()->getAvatarManager().getAvatarHash()) {
Avatar* avatar = static_cast<Avatar*>(avatarPointer.data());
if (avatar == static_cast<Avatar*>(this)) {
continue;
}
float distance;
if (avatar->findRayIntersection(mouseOrigin, mouseDirection, distance)) {
_lookAtTargetAvatar = avatarPointer;
return;
}
}
_lookAtTargetAvatar.clear();
}
}
void MyAvatar::clearLookAtTargetAvatar() {
_lookAtTargetAvatar.clear();
}
float MyAvatar::getAbsoluteHeadYaw() const {
const Head* head = static_cast<const Head*>(_headData);
return glm::yaw(head->getOrientation());
}
glm::vec3 MyAvatar::getUprightHeadPosition() const {
return _position + getWorldAlignedOrientation() * glm::vec3(0.0f, getPelvisToHeadLength(), 0.0f);
}
void MyAvatar::setJointData(int index, const glm::quat& rotation) {
Avatar::setJointData(index, rotation);
if (QThread::currentThread() == thread()) {
_skeletonModel.setJointState(index, true, rotation);
}
}
void MyAvatar::clearJointData(int index) {
Avatar::clearJointData(index);
if (QThread::currentThread() == thread()) {
_skeletonModel.setJointState(index, false);
}
}
void MyAvatar::setFaceModelURL(const QUrl& faceModelURL) {
Avatar::setFaceModelURL(faceModelURL);
_billboardValid = false;
}
void MyAvatar::setSkeletonModelURL(const QUrl& skeletonModelURL) {
Avatar::setSkeletonModelURL(skeletonModelURL);
_billboardValid = false;
}
void MyAvatar::renderBody(bool forceRenderHead) {
if (!(_skeletonModel.isRenderable() && getHead()->getFaceModel().isRenderable())) {
return; // wait until both models are loaded
}
// Render the body's voxels and head
_skeletonModel.render(1.0f);
// Render head so long as the camera isn't inside it
const float RENDER_HEAD_CUTOFF_DISTANCE = 0.40f;
Camera* myCamera = Application::getInstance()->getCamera();
if (forceRenderHead || (glm::length(myCamera->getPosition() - getHead()->calculateAverageEyePosition()) >
RENDER_HEAD_CUTOFF_DISTANCE * _scale)) {
getHead()->render(1.0f);
}
getHand()->render(true);
}
void MyAvatar::updateThrust(float deltaTime) {
//
// Gather thrust information from keyboard and sensors to apply to avatar motion
//
glm::quat orientation = getHead()->getCameraOrientation();
glm::vec3 front = orientation * IDENTITY_FRONT;
glm::vec3 right = orientation * IDENTITY_RIGHT;
glm::vec3 up = orientation * IDENTITY_UP;
const float THRUST_MAG_UP = 800.0f;
const float THRUST_MAG_DOWN = 300.f;
const float THRUST_MAG_FWD = 500.f;
const float THRUST_MAG_BACK = 300.f;
const float THRUST_MAG_LATERAL = 250.f;
const float THRUST_JUMP = 120.f;
// Add Thrusts from keyboard
_thrust += _driveKeys[FWD] * _scale * THRUST_MAG_FWD * _thrustMultiplier * deltaTime * front;
_thrust -= _driveKeys[BACK] * _scale * THRUST_MAG_BACK * _thrustMultiplier * deltaTime * front;
_thrust += _driveKeys[RIGHT] * _scale * THRUST_MAG_LATERAL * _thrustMultiplier * deltaTime * right;
_thrust -= _driveKeys[LEFT] * _scale * THRUST_MAG_LATERAL * _thrustMultiplier * deltaTime * right;
_thrust += _driveKeys[UP] * _scale * THRUST_MAG_UP * _thrustMultiplier * deltaTime * up;
_thrust -= _driveKeys[DOWN] * _scale * THRUST_MAG_DOWN * _thrustMultiplier * deltaTime * up;
_bodyYawDelta -= _driveKeys[ROT_RIGHT] * YAW_SPEED * deltaTime;
_bodyYawDelta += _driveKeys[ROT_LEFT] * YAW_SPEED * deltaTime;
getHead()->setPitch(getHead()->getPitch() + (_driveKeys[ROT_UP] - _driveKeys[ROT_DOWN]) * PITCH_SPEED * deltaTime);
// If thrust keys are being held down, slowly increase thrust to allow reaching great speeds
if (_driveKeys[FWD] || _driveKeys[BACK] || _driveKeys[RIGHT] || _driveKeys[LEFT] || _driveKeys[UP] || _driveKeys[DOWN]) {
const float THRUST_INCREASE_RATE = 1.05f;
const float MAX_THRUST_MULTIPLIER = 75.0f;
//printf("m = %.3f\n", _thrustMultiplier);
if (_thrustMultiplier < MAX_THRUST_MULTIPLIER) {
_thrustMultiplier *= 1.f + deltaTime * THRUST_INCREASE_RATE;
}
} else {
_thrustMultiplier = 1.f;
}
// Add one time jumping force if requested
if (_shouldJump) {
if (glm::length(_gravity) > EPSILON) {
_thrust += _scale * THRUST_JUMP * up;
}
_shouldJump = false;
}
// Update speed brake status
const float MIN_SPEED_BRAKE_VELOCITY = _scale * 0.4f;
if ((glm::length(_thrust) == 0.0f) && _isThrustOn && (glm::length(_velocity) > MIN_SPEED_BRAKE_VELOCITY)) {
_speedBrakes = true;
}
if (_speedBrakes && (glm::length(_velocity) < MIN_SPEED_BRAKE_VELOCITY)) {
_speedBrakes = false;
}
_isThrustOn = (glm::length(_thrust) > EPSILON);
}
void MyAvatar::updateHandMovementAndTouching(float deltaTime) {
glm::quat orientation = getOrientation();
// reset hand and arm positions according to hand movement
glm::vec3 up = orientation * IDENTITY_UP;
bool pointing = false;
if (glm::length(_mouseRayDirection) > EPSILON && !Application::getInstance()->isMouseHidden()) {
// confine to the approximate shoulder plane
glm::vec3 pointDirection = _mouseRayDirection;
if (glm::dot(_mouseRayDirection, up) > 0.0f) {
glm::vec3 projectedVector = glm::cross(up, glm::cross(_mouseRayDirection, up));
if (glm::length(projectedVector) > EPSILON) {
pointDirection = glm::normalize(projectedVector);
}
}
glm::vec3 shoulderPosition;
if (_skeletonModel.getRightShoulderPosition(shoulderPosition)) {
glm::vec3 farVector = _mouseRayOrigin + pointDirection * (float)TREE_SCALE - shoulderPosition;
const float ARM_RETRACTION = 0.75f;
float retractedLength = _skeletonModel.getRightArmLength() * ARM_RETRACTION;
setHandPosition(shoulderPosition + glm::normalize(farVector) * retractedLength);
pointing = true;
}
}
if (_mousePressed) {
_handState = HAND_STATE_GRASPING;
} else if (pointing) {
_handState = HAND_STATE_POINTING;
} else {
_handState = HAND_STATE_NULL;
}
}
void MyAvatar::updateCollisionWithEnvironment(float deltaTime, float radius) {
glm::vec3 up = getBodyUpDirection();
const float ENVIRONMENT_SURFACE_ELASTICITY = 0.0f;
const float ENVIRONMENT_SURFACE_DAMPING = 0.01f;
const float ENVIRONMENT_COLLISION_FREQUENCY = 0.05f;
glm::vec3 penetration;
float pelvisFloatingHeight = getPelvisFloatingHeight();
if (Application::getInstance()->getEnvironment()->findCapsulePenetration(
_position - up * (pelvisFloatingHeight - radius),
_position + up * (getSkeletonHeight() - pelvisFloatingHeight + radius), radius, penetration)) {
_lastCollisionPosition = _position;
updateCollisionSound(penetration, deltaTime, ENVIRONMENT_COLLISION_FREQUENCY);
applyHardCollision(penetration, ENVIRONMENT_SURFACE_ELASTICITY, ENVIRONMENT_SURFACE_DAMPING);
}
}
void MyAvatar::updateCollisionWithVoxels(float deltaTime, float radius) {
const float VOXEL_ELASTICITY = 0.4f;
const float VOXEL_DAMPING = 0.0f;
const float VOXEL_COLLISION_FREQUENCY = 0.5f;
glm::vec3 penetration;
float pelvisFloatingHeight = getPelvisFloatingHeight();
if (Application::getInstance()->getVoxelTree()->findCapsulePenetration(
_position - glm::vec3(0.0f, pelvisFloatingHeight - radius, 0.0f),
_position + glm::vec3(0.0f, getSkeletonHeight() - pelvisFloatingHeight + radius, 0.0f), radius, penetration)) {
_lastCollisionPosition = _position;
updateCollisionSound(penetration, deltaTime, VOXEL_COLLISION_FREQUENCY);
applyHardCollision(penetration, VOXEL_ELASTICITY, VOXEL_DAMPING);
}
}
void MyAvatar::applyHardCollision(const glm::vec3& penetration, float elasticity, float damping) {
//
// Update the avatar in response to a hard collision. Position will be reset exactly
// to outside the colliding surface. Velocity will be modified according to elasticity.
//
// if elasticity = 0.0, collision is 100% inelastic.
// if elasticity = 1.0, collision is elastic.
//
_position -= penetration;
static float HALTING_VELOCITY = 0.2f;
// cancel out the velocity component in the direction of penetration
float penetrationLength = glm::length(penetration);
if (penetrationLength > EPSILON) {
_elapsedTimeSinceCollision = 0.0f;
glm::vec3 direction = penetration / penetrationLength;
_velocity -= glm::dot(_velocity, direction) * direction * (1.f + elasticity);
_velocity *= glm::clamp(1.f - damping, 0.0f, 1.0f);
if ((glm::length(_velocity) < HALTING_VELOCITY) && (glm::length(_thrust) == 0.f)) {
// If moving really slowly after a collision, and not applying forces, stop altogether
_velocity *= 0.f;
}
}
}
void MyAvatar::updateCollisionSound(const glm::vec3 &penetration, float deltaTime, float frequency) {
// consider whether to have the collision make a sound
const float AUDIBLE_COLLISION_THRESHOLD = 0.02f;
const float COLLISION_LOUDNESS = 1.f;
const float DURATION_SCALING = 0.004f;
const float NOISE_SCALING = 0.1f;
glm::vec3 velocity = _velocity;
glm::vec3 gravity = getGravity();
if (glm::length(gravity) > EPSILON) {
// If gravity is on, remove the effect of gravity on velocity for this
// frame, so that we are not constantly colliding with the surface
velocity -= _scale * glm::length(gravity) * GRAVITY_EARTH * deltaTime * glm::normalize(gravity);
}
float velocityTowardCollision = glm::dot(velocity, glm::normalize(penetration));
float velocityTangentToCollision = glm::length(velocity) - velocityTowardCollision;
if (velocityTowardCollision > AUDIBLE_COLLISION_THRESHOLD) {
// Volume is proportional to collision velocity
// Base frequency is modified upward by the angle of the collision
// Noise is a function of the angle of collision
// Duration of the sound is a function of both base frequency and velocity of impact
Application::getInstance()->getAudio()->startCollisionSound(
std::min(COLLISION_LOUDNESS * velocityTowardCollision, 1.f),
frequency * (1.f + velocityTangentToCollision / velocityTowardCollision),
std::min(velocityTangentToCollision / velocityTowardCollision * NOISE_SCALING, 1.f),
1.f - DURATION_SCALING * powf(frequency, 0.5f) / velocityTowardCollision, true);
}
}
bool findAvatarAvatarPenetration(const glm::vec3 positionA, float radiusA, float heightA,
const glm::vec3 positionB, float radiusB, float heightB, glm::vec3& penetration) {
glm::vec3 positionBA = positionB - positionA;
float xzDistance = sqrt(positionBA.x * positionBA.x + positionBA.z * positionBA.z);
if (xzDistance < (radiusA + radiusB)) {
float yDistance = fabs(positionBA.y);
float halfHeights = 0.5 * (heightA + heightB);
if (yDistance < halfHeights) {
// cylinders collide
if (xzDistance > 0.f) {
positionBA.y = 0.f;
// note, penetration should point from A into B
penetration = positionBA * ((radiusA + radiusB - xzDistance) / xzDistance);
return true;
} else {
// exactly coaxial -- we'll return false for this case
return false;
}
} else if (yDistance < halfHeights + radiusA + radiusB) {
// caps collide
if (positionBA.y < 0.f) {
// A is above B
positionBA.y += halfHeights;
float BA = glm::length(positionBA);
penetration = positionBA * (radiusA + radiusB - BA) / BA;
return true;
} else {
// A is below B
positionBA.y -= halfHeights;
float BA = glm::length(positionBA);
penetration = positionBA * (radiusA + radiusB - BA) / BA;
return true;
}
}
}
return false;
}
void MyAvatar::updateCollisionWithAvatars(float deltaTime) {
// Reset detector for nearest avatar
_distanceToNearestAvatar = std::numeric_limits<float>::max();
const AvatarHash& avatars = Application::getInstance()->getAvatarManager().getAvatarHash();
if (avatars.size() <= 1) {
// no need to compute a bunch of stuff if we have one or fewer avatars
return;
}
updateShapePositions();
float myBoundingRadius = getBoundingRadius();
/* TODO: Andrew to fix Avatar-Avatar body collisions
// HACK: body-body collision uses two coaxial capsules with axes parallel to y-axis
// TODO: make the collision work without assuming avatar orientation
Extents myStaticExtents = _skeletonModel.getStaticExtents();
glm::vec3 staticScale = myStaticExtents.maximum - myStaticExtents.minimum;
float myCapsuleRadius = 0.25f * (staticScale.x + staticScale.z);
float myCapsuleHeight = staticScale.y;
*/
CollisionInfo collisionInfo;
foreach (const AvatarSharedPointer& avatarPointer, avatars) {
Avatar* avatar = static_cast<Avatar*>(avatarPointer.data());
if (static_cast<Avatar*>(this) == avatar) {
// don't collide with ourselves
continue;
}
avatar->updateShapePositions();
float distance = glm::length(_position - avatar->getPosition());
if (_distanceToNearestAvatar > distance) {
_distanceToNearestAvatar = distance;
}
float theirBoundingRadius = avatar->getBoundingRadius();
if (distance < myBoundingRadius + theirBoundingRadius) {
/* TODO: Andrew to fix Avatar-Avatar body collisions
Extents theirStaticExtents = _skeletonModel.getStaticExtents();
glm::vec3 staticScale = theirStaticExtents.maximum - theirStaticExtents.minimum;
float theirCapsuleRadius = 0.25f * (staticScale.x + staticScale.z);
float theirCapsuleHeight = staticScale.y;
glm::vec3 penetration(0.f);
if (findAvatarAvatarPenetration(_position, myCapsuleRadius, myCapsuleHeight,
avatar->getPosition(), theirCapsuleRadius, theirCapsuleHeight, penetration)) {
// move the avatar out by half the penetration
setPosition(_position - 0.5f * penetration);
}
*/
// collide our hands against them
getHand()->collideAgainstAvatar(avatar, true);
// collide their hands against us
avatar->getHand()->collideAgainstAvatar(this, false);
}
}
}
class SortedAvatar {
public:
Avatar* avatar;
float distance;
glm::vec3 accumulatedCenter;
};
bool operator<(const SortedAvatar& s1, const SortedAvatar& s2) {
return s1.distance < s2.distance;
}
void MyAvatar::updateChatCircle(float deltaTime) {
if (!(_isChatCirclingEnabled = Menu::getInstance()->isOptionChecked(MenuOption::ChatCircling))) {
return;
}
// find all circle-enabled members and sort by distance
QVector<SortedAvatar> sortedAvatars;
foreach (const AvatarSharedPointer& avatarPointer, Application::getInstance()->getAvatarManager().getAvatarHash()) {
Avatar* avatar = static_cast<Avatar*>(avatarPointer.data());
if ( ! avatar->isChatCirclingEnabled() ||
avatar == static_cast<Avatar*>(this)) {
continue;
}
SortedAvatar sortedAvatar;
sortedAvatar.avatar = avatar;
sortedAvatar.distance = glm::distance(_position, sortedAvatar.avatar->getPosition());
sortedAvatars.append(sortedAvatar);
}
qSort(sortedAvatars.begin(), sortedAvatars.end());
// compute the accumulated centers
glm::vec3 center = _position;
for (int i = 0; i < sortedAvatars.size(); i++) {
SortedAvatar& sortedAvatar = sortedAvatars[i];
sortedAvatar.accumulatedCenter = (center += sortedAvatar.avatar->getPosition()) / (i + 2.0f);
}
// remove members whose accumulated circles are too far away to influence us
const float CIRCUMFERENCE_PER_MEMBER = 0.5f;
const float CIRCLE_INFLUENCE_SCALE = 2.0f;
const float MIN_RADIUS = 0.3f;
for (int i = sortedAvatars.size() - 1; i >= 0; i--) {
float radius = qMax(MIN_RADIUS, (CIRCUMFERENCE_PER_MEMBER * (i + 2)) / TWO_PI);
if (glm::distance(_position, sortedAvatars[i].accumulatedCenter) > radius * CIRCLE_INFLUENCE_SCALE) {
sortedAvatars.remove(i);
} else {
break;
}
}
if (sortedAvatars.isEmpty()) {
return;
}
center = sortedAvatars.last().accumulatedCenter;
float radius = qMax(MIN_RADIUS, (CIRCUMFERENCE_PER_MEMBER * (sortedAvatars.size() + 1)) / TWO_PI);
// compute the average up vector
glm::vec3 up = getWorldAlignedOrientation() * IDENTITY_UP;
foreach (const SortedAvatar& sortedAvatar, sortedAvatars) {
up += sortedAvatar.avatar->getWorldAlignedOrientation() * IDENTITY_UP;
}
up = glm::normalize(up);
// find reasonable corresponding right/front vectors
glm::vec3 front = glm::cross(up, IDENTITY_RIGHT);
if (glm::length(front) < EPSILON) {
front = glm::cross(up, IDENTITY_FRONT);
}
front = glm::normalize(front);
glm::vec3 right = glm::cross(front, up);
// find our angle and the angular distances to our closest neighbors
glm::vec3 delta = _position - center;
glm::vec3 projected = glm::vec3(glm::dot(right, delta), glm::dot(front, delta), 0.0f);
float myAngle = glm::length(projected) > EPSILON ? atan2f(projected.y, projected.x) : 0.0f;
float leftDistance = TWO_PI;
float rightDistance = TWO_PI;
foreach (const SortedAvatar& sortedAvatar, sortedAvatars) {
delta = sortedAvatar.avatar->getPosition() - center;
projected = glm::vec3(glm::dot(right, delta), glm::dot(front, delta), 0.0f);
float angle = glm::length(projected) > EPSILON ? atan2f(projected.y, projected.x) : 0.0f;
if (angle < myAngle) {
leftDistance = min(myAngle - angle, leftDistance);
rightDistance = min(TWO_PI - (myAngle - angle), rightDistance);
} else {
leftDistance = min(TWO_PI - (angle - myAngle), leftDistance);
rightDistance = min(angle - myAngle, rightDistance);
}
}
// if we're on top of a neighbor, we need to randomize so that they don't both go in the same direction
if (rightDistance == 0.0f && randomBoolean()) {
swap(leftDistance, rightDistance);
}
// split the difference between our neighbors
float targetAngle = myAngle + (rightDistance - leftDistance) / 4.0f;
glm::vec3 targetPosition = center + (front * sinf(targetAngle) + right * cosf(targetAngle)) * radius;
// approach the target position
const float APPROACH_RATE = 0.05f;
_position = glm::mix(_position, targetPosition, APPROACH_RATE);
}
void MyAvatar::maybeUpdateBillboard() {
if (_billboardValid || !(_skeletonModel.isLoadedWithTextures() && getHead()->getFaceModel().isLoadedWithTextures())) {
return;
}
QImage image = Application::getInstance()->renderAvatarBillboard();
_billboard.clear();
QBuffer buffer(&_billboard);
buffer.open(QIODevice::WriteOnly);
image.save(&buffer, "PNG");
_billboardValid = true;
sendBillboardPacket();
}
void MyAvatar::setGravity(glm::vec3 gravity) {
_gravity = gravity;
getHead()->setGravity(_gravity);
// use the gravity to determine the new world up direction, if possible
float gravityLength = glm::length(gravity);
if (gravityLength > EPSILON) {
_worldUpDirection = _gravity / -gravityLength;
} else {
_worldUpDirection = DEFAULT_UP_DIRECTION;
}
}
void MyAvatar::goHome() {
qDebug("Going Home!");
setPosition(START_LOCATION);
}
void MyAvatar::increaseSize() {
if ((1.f + SCALING_RATIO) * _targetScale < MAX_AVATAR_SCALE) {
_targetScale *= (1.f + SCALING_RATIO);
qDebug("Changed scale to %f", _targetScale);
}
}
void MyAvatar::decreaseSize() {
if (MIN_AVATAR_SCALE < (1.f - SCALING_RATIO) * _targetScale) {
_targetScale *= (1.f - SCALING_RATIO);
qDebug("Changed scale to %f", _targetScale);
}
}
void MyAvatar::resetSize() {
_targetScale = 1.0f;
qDebug("Reseted scale to %f", _targetScale);
}
static QByteArray createByteArray(const glm::vec3& vector) {
return QByteArray::number(vector.x) + ',' + QByteArray::number(vector.y) + ',' + QByteArray::number(vector.z);
}
void MyAvatar::updateLocationInDataServer() {
// TODO: don't re-send this when it hasn't change or doesn't change by some threshold
// This will required storing the last sent values and clearing them when the AccountManager rootURL changes
AccountManager& accountManager = AccountManager::getInstance();
if (accountManager.isLoggedIn()) {
QString positionString(createByteArray(_position));
QString orientationString(createByteArray(glm::degrees(safeEulerAngles(getOrientation()))));
// construct the json to put the user's location
QString locationPutJson = QString() + "{\"address\":{\"position\":\""
+ positionString + "\", \"orientation\":\"" + orientationString + "\"}}";
accountManager.authenticatedRequest("/api/v1/users/address", QNetworkAccessManager::PutOperation,
JSONCallbackParameters(), locationPutJson.toUtf8());
}
}
void MyAvatar::goToLocationFromResponse(const QJsonObject& jsonObject) {
if (jsonObject["status"].toString() == "success") {
// send a node kill request, indicating to other clients that they should play the "disappeared" effect
sendKillAvatar();
QJsonObject locationObject = jsonObject["data"].toObject()["address"].toObject();
QString positionString = locationObject["position"].toString();
QString orientationString = locationObject["orientation"].toString();
QString domainHostnameString = locationObject["domain"].toString();
qDebug() << "Changing domain to" << domainHostnameString <<
", position to" << positionString <<
", and orientation to" << orientationString;
QStringList coordinateItems = positionString.split(',');
QStringList orientationItems = orientationString.split(',');
NodeList::getInstance()->getDomainInfo().setHostname(domainHostnameString);
// orient the user to face the target
glm::quat newOrientation = glm::quat(glm::vec3(orientationItems[0].toFloat(),
orientationItems[1].toFloat(),
orientationItems[2].toFloat()))
* glm::angleAxis(PI, glm::vec3(0.0f, 1.0f, 0.0f));
setOrientation(newOrientation);
// move the user a couple units away
const float DISTANCE_TO_USER = 2.0f;
glm::vec3 newPosition = glm::vec3(coordinateItems[0].toFloat(), coordinateItems[1].toFloat(),
coordinateItems[2].toFloat()) - newOrientation * IDENTITY_FRONT * DISTANCE_TO_USER;
setPosition(newPosition);
}
}
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