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Merge remote-tracking branch 'upstream/master' into plugins

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Brad Davis 2015-07-28 23:14:41 -07:00
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//
// satellite.js
// games
//
// Created by Bridget Went 7/1/2015.
// Copyright 2015 High Fidelity, Inc.
//
// A game to bring a satellite model into orbit around an animated earth model .
// - Double click to create a new satellite
// - Click on the satellite, drag a vector arrow to specify initial velocity
// - Release mouse to launch the active satellite
// - Orbital movement is calculated using equations of gravitational physics
//
// Distributed under the Apache License, Version 2.0.
// See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html
//
Script.include('../utilities/tools/vector.js');
var URL = "https://s3.amazonaws.com/hifi-public/marketplace/hificontent/Scripts/planets/";
SatelliteGame = function() {
var MAX_RANGE = 50.0;
var Y_AXIS = {
x: 0,
y: 1,
z: 0
}
var LIFETIME = 6000;
var ERROR_THRESH = 20.0;
// Create the spinning earth model
var EARTH_SIZE = 20.0;
var CLOUDS_OFFSET = 0.5;
var SPIN = 0.1;
var ZONE_DIM = 100.0;
var LIGHT_INTENSITY = 1.5;
Earth = function(position, size) {
this.earth = Entities.addEntity({
type: "Model",
shapeType: 'sphere',
modelURL: URL + "earth.fbx",
position: position,
dimensions: {
x: size,
y: size,
z: size
},
rotation: Quat.angleAxis(180, {
x: 1,
y: 0,
z: 0
}),
angularVelocity: {
x: 0.00,
y: 0.5 * SPIN,
z: 0.00
},
angularDamping: 0.0,
damping: 0.0,
ignoreCollisions: false,
lifetime: 6000,
collisionsWillMove: false,
visible: true
});
this.clouds = Entities.addEntity({
type: "Model",
shapeType: 'sphere',
modelURL: URL + "clouds.fbx?i=2",
position: position,
dimensions: {
x: size + CLOUDS_OFFSET,
y: size + CLOUDS_OFFSET,
z: size + CLOUDS_OFFSET
},
angularVelocity: {
x: 0.00,
y: SPIN,
z: 0.00
},
angularDamping: 0.0,
damping: 0.0,
ignoreCollisions: false,
lifetime: LIFETIME,
collisionsWillMove: false,
visible: true
});
this.zone = Entities.addEntity({
type: "Zone",
position: position,
dimensions: {
x: ZONE_DIM,
y: ZONE_DIM,
z: ZONE_DIM
},
keyLightDirection: Vec3.normalize(Vec3.subtract(position, Camera.getPosition())),
keyLightIntensity: LIGHT_INTENSITY
});
this.cleanup = function() {
Entities.deleteEntity(this.clouds);
Entities.deleteEntity(this.earth);
Entities.deleteEntity(this.zone);
}
}
// Create earth model
var center = Vec3.sum(Camera.getPosition(), Vec3.multiply(MAX_RANGE, Quat.getFront(Camera.getOrientation())));
var distance = Vec3.length(Vec3.subtract(center, Camera.getPosition()));
var earth = new Earth(center, EARTH_SIZE);
var satellites = [];
var SATELLITE_SIZE = 2.0;
var launched = false;
var activeSatellite;
var PERIOD = 4.0;
var LARGE_BODY_MASS = 16000.0;
var SMALL_BODY_MASS = LARGE_BODY_MASS * 0.000000333;
Satellite = function(position, planetCenter) {
// The Satellite class
this.launched = false;
this.startPosition = position;
this.readyToLaunch = false;
this.radius = Vec3.length(Vec3.subtract(position, planetCenter));
this.satellite = Entities.addEntity({
type: "Model",
modelURL: "https://s3.amazonaws.com/hifi-public/marketplace/hificontent/Scripts/planets/satellite/satellite.fbx",
position: this.startPosition,
dimensions: {
x: SATELLITE_SIZE,
y: SATELLITE_SIZE,
z: SATELLITE_SIZE
},
angularDamping: 0.0,
damping: 0.0,
ignoreCollisions: false,
lifetime: LIFETIME,
collisionsWillMove: false,
});
this.getProperties = function() {
return Entities.getEntityProperties(this.satellite);
}
this.launch = function() {
var prop = Entities.getEntityProperties(this.satellite);
var between = Vec3.subtract(planetCenter, prop.position);
var radius = Vec3.length(between);
this.gravity = (4.0 * Math.PI * Math.PI * Math.pow(radius, 3.0)) / (LARGE_BODY_MASS * PERIOD * PERIOD);
var initialVelocity = Vec3.normalize(Vec3.cross(between, Y_AXIS));
initialVelocity = Vec3.multiply(Math.sqrt((this.gravity * LARGE_BODY_MASS) / radius), initialVelocity);
initialVelocity = Vec3.multiply(this.arrow.magnitude, initialVelocity);
initialVelocity = Vec3.multiply(Vec3.length(initialVelocity), this.arrow.direction);
Entities.editEntity(this.satellite, {
velocity: initialVelocity
});
this.launched = true;
};
this.update = function(deltaTime) {
var prop = Entities.getEntityProperties(this.satellite);
var between = Vec3.subtract(prop.position, planetCenter);
var radius = Vec3.length(between);
var acceleration = -(this.gravity * LARGE_BODY_MASS) * Math.pow(radius, (-2.0));
var speed = acceleration * deltaTime;
var vel = Vec3.multiply(speed, Vec3.normalize(between));
var newVelocity = Vec3.sum(prop.velocity, vel);
var newPos = Vec3.sum(prop.position, Vec3.multiply(newVelocity, deltaTime));
Entities.editEntity(this.satellite, {
velocity: newVelocity,
position: newPos
});
};
}
function mouseDoublePressEvent(event) {
var pickRay = Camera.computePickRay(event.x, event.y);
var addVector = Vec3.multiply(pickRay.direction, distance);
var point = Vec3.sum(Camera.getPosition(), addVector);
// Create a new satellite
activeSatellite = new Satellite(point, center);
satellites.push(activeSatellite);
}
function mousePressEvent(event) {
if (!activeSatellite) {
return;
}
// Reset label
if (activeSatellite.arrow) {
activeSatellite.arrow.deleteLabel();
}
var statsPosition = Vec3.sum(Camera.getPosition(), Vec3.multiply(MAX_RANGE * 0.4, Quat.getFront(Camera.getOrientation())));
var pickRay = Camera.computePickRay(event.x, event.y)
var rayPickResult = Entities.findRayIntersection(pickRay, true);
if (rayPickResult.entityID === activeSatellite.satellite) {
// Create a draggable vector arrow at satellite position
activeSatellite.arrow = new VectorArrow(distance, true, "INITIAL VELOCITY", statsPosition);
activeSatellite.arrow.onMousePressEvent(event);
activeSatellite.arrow.isDragging = true;
}
}
function mouseMoveEvent(event) {
if (!activeSatellite || !activeSatellite.arrow || !activeSatellite.arrow.isDragging) {
return;
}
activeSatellite.arrow.onMouseMoveEvent(event);
}
function mouseReleaseEvent(event) {
if (!activeSatellite || !activeSatellite.arrow || !activeSatellite.arrow.isDragging) {
return;
}
activeSatellite.arrow.onMouseReleaseEvent(event);
activeSatellite.launch();
activeSatellite.arrow.cleanup();
}
var counter = 0.0;
var CHECK_ENERGY_PERIOD = 500;
function update(deltaTime) {
if (!activeSatellite) {
return;
}
// Update all satellites
for (var i = 0; i < satellites.length; i++) {
if (!satellites[i].launched) {
continue;
}
satellites[i].update(deltaTime);
}
counter++;
if (counter % CHECK_ENERGY_PERIOD == 0) {
var prop = activeSatellite.getProperties();
var error = calcEnergyError(prop.position, Vec3.length(prop.velocity));
if (Math.abs(error) <= ERROR_THRESH) {
activeSatellite.arrow.editLabel("Nice job! The satellite has reached a stable orbit.");
} else {
activeSatellite.arrow.editLabel("Try again! The satellite is in an unstable orbit.");
}
}
}
this.endGame = function() {
for (var i = 0; i < satellites.length; i++) {
Entities.deleteEntity(satellites[i].satellite);
satellites[i].arrow.cleanup();
}
earth.cleanup();
}
function calcEnergyError(pos, vel) {
//Calculate total energy error for active satellite's orbital motion
var radius = activeSatellite.radius;
var gravity = (4.0 * Math.PI * Math.PI * Math.pow(radius, 3.0)) / (LARGE_BODY_MASS * PERIOD * PERIOD);
var initialVelocityCalculated = Math.sqrt((gravity * LARGE_BODY_MASS) / radius);
var totalEnergy = 0.5 * LARGE_BODY_MASS * Math.pow(initialVelocityCalculated, 2.0) - ((gravity * LARGE_BODY_MASS * SMALL_BODY_MASS) / radius);
var measuredEnergy = 0.5 * LARGE_BODY_MASS * Math.pow(vel, 2.0) - ((gravity * LARGE_BODY_MASS * SMALL_BODY_MASS) / Vec3.length(Vec3.subtract(pos, center)));
var error = ((measuredEnergy - totalEnergy) / totalEnergy) * 100;
return error;
}
Controller.mousePressEvent.connect(mousePressEvent);
Controller.mouseDoublePressEvent.connect(mouseDoublePressEvent);
Controller.mouseMoveEvent.connect(mouseMoveEvent);
Controller.mouseReleaseEvent.connect(mouseReleaseEvent);
Script.update.connect(update);
Script.scriptEnding.connect(this.endGame);
}

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//
// solarsystem.js
// games
//
// Created by Bridget Went, 5/28/15.
// Copyright 2015 High Fidelity, Inc.
//
// The start to a project to build a virtual physics classroom to simulate the solar system, gravity, and orbital physics.
// - A sun with oribiting planets is created in front of the user
// - UI elements allow for adjusting the period, gravity, trails, and energy recalculations
// - Click "PAUSE" to pause the animation and show planet labels
// - In this mode, double-click a planet label to zoom in on that planet
// -Double-clicking on earth label initiates satellite orbiter game
// -Press "TAB" to toggle back to solar system view
//
//
// Distributed under the Apache License, Version 2.0.
// See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html
//
Script.include('../utilities/tools/cookies.js');
Script.include('games/satellite.js');
var BASE_URL = "https://s3.amazonaws.com/hifi-public/marketplace/hificontent/Scripts/planets/planets/";
var NUM_PLANETS = 8;
var trailsEnabled = true;
var energyConserved = true;
var planetView = false;
var earthView = false;
var satelliteGame;
var PANEL_X = 850;
var PANEL_Y = 600;
var BUTTON_SIZE = 20;
var PADDING = 20;
var DAMPING = 0.0;
var LIFETIME = 6000;
var ERROR_THRESH = 2.0;
var TIME_STEP = 70.0;
var MAX_POINTS_PER_LINE = 5;
var LINE_DIM = 10;
var LINE_WIDTH = 3.0;
var line;
var planetLines = [];
var trails = [];
var BOUNDS = 200;
// Alert user to move if they are too close to domain bounds
if (MyAvatar.position.x < BOUNDS || MyAvatar.position.x > TREE_SCALE - BOUNDS || MyAvatar.position.y < BOUNDS || MyAvatar.position.y > TREE_SCALE - BOUNDS || MyAvatar.position.z < BOUNDS || MyAvatar.position.z > TREE_SCALE - BOUNDS) {
Window.alert("Please move at least 200m away from domain bounds.");
return;
}
// Save intiial avatar and camera position
var startingPosition = MyAvatar.position;
var startFrame = Window.location.href;
// Place the sun
var MAX_RANGE = 80.0;
var SUN_SIZE = 8.0;
var center = Vec3.sum(startingPosition, Vec3.multiply(MAX_RANGE, Quat.getFront(Camera.getOrientation())));
var theSun = Entities.addEntity({
type: "Model",
modelURL: BASE_URL + "sun.fbx",
position: center,
dimensions: {
x: SUN_SIZE,
y: SUN_SIZE,
z: SUN_SIZE
},
angularDamping: DAMPING,
damping: DAMPING,
ignoreCollisions: false,
lifetime: LIFETIME,
collisionsWillMove: false
});
var planets = [];
var planet_properties = [];
// Reference values
var radius = 7.0;
var T_ref = 1.0;
var size = 1.0;
var M = 250.0;
var m = M * 0.000000333;
var G = (Math.pow(radius, 3.0) / Math.pow((T_ref / (2.0 * Math.PI)), 2.0)) / M;
var G_ref = G;
// Adjust size and distance as number of planets increases
var DELTA_RADIUS = 1.8;
var DELTA_SIZE = 0.2;
function initPlanets() {
for (var i = 0; i < NUM_PLANETS; ++i) {
var v0 = Math.sqrt((G * M) / radius);
var T = (2.0 * Math.PI) * Math.sqrt(Math.pow(radius, 3.0) / (G * M));
if (i == 0) {
var color = {
red: 255,
green: 255,
blue: 255
};
} else if (i == 1) {
var color = {
red: 255,
green: 160,
blue: 110
};
} else if (i == 2) {
var color = {
red: 10,
green: 150,
blue: 160
};
} else if (i == 3) {
var color = {
red: 180,
green: 70,
blue: 10
};
} else if (i == 4) {
var color = {
red: 250,
green: 140,
blue: 0
};
} else if (i == 5) {
var color = {
red: 235,
green: 215,
blue: 0
};
} else if (i == 6) {
var color = {
red: 135,
green: 205,
blue: 240
};
} else if (i == 7) {
var color = {
red: 30,
green: 140,
blue: 255
};
}
var prop = {
radius: radius,
position: Vec3.sum(center, {
x: radius,
y: 0.0,
z: 0.0
}),
lineColor: color,
period: T,
dimensions: size,
velocity: Vec3.multiply(v0, Vec3.normalize({
x: 0,
y: -0.2,
z: 0.9
}))
};
planet_properties.push(prop);
planets.push(Entities.addEntity({
type: "Model",
modelURL: BASE_URL + (i + 1) + ".fbx",
position: prop.position,
dimensions: {
x: prop.dimensions,
y: prop.dimensions,
z: prop.dimensions
},
velocity: prop.velocity,
angularDamping: DAMPING,
damping: DAMPING,
ignoreCollisions: false,
lifetime: LIFETIME,
collisionsWillMove: true,
}));
radius *= DELTA_RADIUS;
size += DELTA_SIZE;
}
}
// Initialize planets
initPlanets();
var labels = [];
var labelLines = [];
var labelsShowing = false;
var LABEL_X = 8.0;
var LABEL_Y = 3.0;
var LABEL_Z = 1.0;
var LABEL_DIST = 8.0;
var TEXT_HEIGHT = 1.0;
var sunLabel;
function showLabels() {
labelsShowing = true;
for (var i = 0; i < NUM_PLANETS; i++) {
var properties = planet_properties[i];
var text;
if (i == 0) {
text = "Mercury";
} else if (i == 1) {
text = "Venus";
} else if (i == 2) {
text = "Earth";
} else if (i == 3) {
text = "Mars";
} else if (i == 4) {
text = "Jupiter";
} else if (i == 5) {
text = "Saturn";
} else if (i == 6) {
text = "Uranus";
} else if (i == 7) {
text = "Neptune";
}
text = text + " Speed: " + Vec3.length(properties.velocity).toFixed(2);
var labelPos = Vec3.sum(planet_properties[i].position, {
x: 0.0,
y: LABEL_DIST,
z: LABEL_DIST
});
var linePos = planet_properties[i].position;
labelLines.push(Entities.addEntity({
type: "Line",
position: linePos,
dimensions: {
x: 20,
y: 20,
z: 20
},
lineWidth: 3.0,
color: {
red: 255,
green: 255,
blue: 255
},
linePoints: [{
x: 0,
y: 0,
z: 0
}, computeLocalPoint(linePos, labelPos)]
}));
labels.push(Entities.addEntity({
type: "Text",
text: text,
lineHeight: TEXT_HEIGHT,
dimensions: {
x: LABEL_X,
y: LABEL_Y,
z: LABEL_Z
},
position: labelPos,
backgroundColor: {
red: 10,
green: 10,
blue: 10
},
textColor: {
red: 255,
green: 255,
blue: 255
},
faceCamera: true
}));
}
}
function hideLabels() {
labelsShowing = false;
Entities.deleteEntity(sunLabel);
for (var i = 0; i < NUM_PLANETS; ++i) {
Entities.deleteEntity(labelLines[i]);
Entities.deleteEntity(labels[i]);
}
labels = [];
labelLines = [];
}
var time = 0.0;
var elapsed;
var counter = 0;
var dt = 1.0 / TIME_STEP;
function update(deltaTime) {
if (paused) {
return;
}
deltaTime = dt;
time++;
for (var i = 0; i < NUM_PLANETS; ++i) {
var properties = planet_properties[i];
var between = Vec3.subtract(properties.position, center);
var speed = getAcceleration(properties.radius) * deltaTime;
var vel = Vec3.multiply(speed, Vec3.normalize(between));
// Update velocity and position
properties.velocity = Vec3.sum(properties.velocity, vel);
properties.position = Vec3.sum(properties.position, Vec3.multiply(properties.velocity, deltaTime));
Entities.editEntity(planets[i], {
velocity: properties.velocity,
position: properties.position
});
// Create new or update current trail
if (trailsEnabled) {
var lineStack = planetLines[i];
var point = properties.position;
var prop = Entities.getEntityProperties(lineStack[lineStack.length - 1]);
var linePos = prop.position;
trails[i].push(computeLocalPoint(linePos, point));
Entities.editEntity(lineStack[lineStack.length - 1], {
linePoints: trails[i]
});
if (trails[i].length === MAX_POINTS_PER_LINE) {
trails[i] = newLine(lineStack, point, properties.period, properties.lineColor);
}
}
// Measure total energy every 10 updates, recalibrate velocity if necessary
if (energyConserved) {
if (counter % 10 === 0) {
var error = calcEnergyError(planets[i], properties.radius, properties.v0, properties.velocity, properties.position);
if (Math.abs(error) >= ERROR_THRESH) {
var speed = adjustVelocity(planets[i], properties.position);
properties.velocity = Vec3.multiply(speed, Vec3.normalize(properties.velocity));
}
}
}
}
counter++;
if (time % TIME_STEP == 0) {
elapsed++;
}
}
function computeLocalPoint(linePos, worldPoint) {
var localPoint = Vec3.subtract(worldPoint, linePos);
return localPoint;
}
function getAcceleration(radius) {
var acc = -(G * M) * Math.pow(radius, (-2.0));
return acc;
}
// Create a new trail
function resetTrails(planetIndex) {
elapsed = 0.0;
var properties = planet_properties[planetIndex];
var trail = [];
var lineStack = [];
//add the first line to both the line entity stack and the trail
trails.push(newLine(lineStack, properties.position, properties.period, properties.lineColor));
planetLines.push(lineStack);
}
// Create a new line
function newLine(lineStack, point, period, color) {
if (elapsed < period) {
var line = Entities.addEntity({
position: point,
type: "Line",
color: color,
dimensions: {
x: LINE_DIM,
y: LINE_DIM,
z: LINE_DIM
},
lifetime: LIFETIME,
lineWidth: LINE_WIDTH
});
lineStack.push(line);
} else {
// Begin overwriting first lines after one full revolution (one period)
var firstLine = lineStack.shift();
Entities.editEntity(firstLine, {
position: point,
linePoints: [{
x: 0.0,
y: 0.0,
z: 0.0
}]
});
lineStack.push(firstLine);
}
var points = [];
points.push(computeLocalPoint(point, point));
return points;
}
// Measure energy error, recalculate velocity to return to initial net energy
var totalEnergy;
var measuredEnergy;
var measuredPE;
function calcEnergyError(planet, radius, v0, v, pos) {
totalEnergy = 0.5 * M * Math.pow(v0, 2.0) - ((G * M * m) / radius);
measuredEnergy = 0.5 * M * Math.pow(v, 2.0) - ((G * M * m) / Vec3.length(Vec3.subtract(center, pos)));
var error = ((measuredEnergy - totalEnergy) / totalEnergy) * 100;
return error;
}
function adjustVelocity(planet, pos) {
var measuredPE = -(G * M * m) / Vec3.length(Vec3.subtract(center, pos));
return Math.sqrt(2 * (totalEnergy - measuredPE) / M);
}
// Allow user to toggle pausing the model, switch to planet view
var pauseButton = Overlays.addOverlay("text", {
backgroundColor: {
red: 200,
green: 200,
blue: 255
},
text: "Pause",
x: PANEL_X,
y: PANEL_Y - 30,
width: 70,
height: 20,
alpha: 1.0,
backgroundAlpha: 0.5,
visible: true
});
var paused = false;
function mousePressEvent(event) {
var clickedOverlay = Overlays.getOverlayAtPoint({
x: event.x,
y: event.y
});
if (clickedOverlay == pauseButton) {
paused = !paused;
for (var i = 0; i < NUM_PLANETS; ++i) {
Entities.editEntity(planets[i], {
velocity: {
x: 0.0,
y: 0.0,
z: 0.0
}
});
}
if (paused && !labelsShowing) {
Overlays.editOverlay(pauseButton, {
text: "Paused",
backgroundColor: {
red: 255,
green: 50,
blue: 50
}
});
showLabels();
}
if (paused == false && labelsShowing) {
Overlays.editOverlay(pauseButton, {
text: "Pause",
backgroundColor: {
red: 200,
green: 200,
blue: 255
}
});
hideLabels();
}
planetView = false;
}
}
function keyPressEvent(event) {
// Jump back to solar system view
if (event.text == "TAB" && planetView) {
if (earthView) {
satelliteGame.endGame();
earthView = false;
}
MyAvatar.position = startingPosition;
}
}
function mouseDoublePressEvent(event) {
if (earthView) {
return;
}
var pickRay = Camera.computePickRay(event.x, event.y)
var rayPickResult = Entities.findRayIntersection(pickRay, true);
for (var i = 0; i < NUM_PLANETS; ++i) {
if (rayPickResult.entityID === labels[i]) {
planetView = true;
if (i == 2) {
MyAvatar.position = Vec3.sum(center, {
x: 200,
y: 200,
z: 200
});
Camera.setPosition(Vec3.sum(center, {
x: 200,
y: 200,
z: 200
}));
earthView = true;
satelliteGame = new SatelliteGame();
} else {
MyAvatar.position = Vec3.sum({
x: 0.0,
y: 0.0,
z: 3.0
}, planet_properties[i].position);
Camera.lookAt(planet_properties[i].position);
}
break;
}
}
}
// Create UI panel
var panel = new Panel(PANEL_X, PANEL_Y);
var panelItems = [];
var g_multiplier = 1.0;
panelItems.push(panel.newSlider("Adjust Gravitational Force: ", 0.1, 5.0,
function(value) {
g_multiplier = value;
G = G_ref * g_multiplier;
},
function() {
return g_multiplier;
},
function(value) {
return value.toFixed(1) + "x";
}));
var period_multiplier = 1.0;
var last_alpha = period_multiplier;
panelItems.push(panel.newSlider("Adjust Orbital Period: ", 0.1, 3.0,
function(value) {
period_multiplier = value;
changePeriod(period_multiplier);
},
function() {
return period_multiplier;
},
function(value) {
return (value).toFixed(2) + "x";
}));
panelItems.push(panel.newCheckbox("Leave Trails: ",
function(value) {
trailsEnabled = value;
if (trailsEnabled) {
for (var i = 0; i < NUM_PLANETS; ++i) {
resetTrails(i);
}
//if trails are off and we've already created trails, remove existing trails
} else if (planetLines.length != 0) {
for (var i = 0; i < NUM_PLANETS; ++i) {
for (var j = 0; j < planetLines[i].length; ++j) {
Entities.deleteEntity(planetLines[i][j]);
}
planetLines[i] = [];
}
}
},
function() {
return trailsEnabled;
},
function(value) {
return value;
}));
panelItems.push(panel.newCheckbox("Energy Error Calculations: ",
function(value) {
energyConserved = value;
},
function() {
return energyConserved;
},
function(value) {
return value;
}));
// Update global G constant, period, poke velocity to new value
function changePeriod(alpha) {
var ratio = last_alpha / alpha;
G = Math.pow(ratio, 2.0) * G;
for (var i = 0; i < NUM_PLANETS; ++i) {
var properties = planet_properties[i];
properties.period = ratio * properties.period;
properties.velocity = Vec3.multiply(ratio, properties.velocity);
}
last_alpha = alpha;
}
// Clean up models, UI panels, lines, and button overlays
function scriptEnding() {
satelliteGame.endGame();
Entities.deleteEntity(theSun);
for (var i = 0; i < NUM_PLANETS; ++i) {
Entities.deleteEntity(planets[i]);
}
Menu.removeMenu("Developer > Scene");
panel.destroy();
Overlays.deleteOverlay(pauseButton);
var e = Entities.findEntities(MyAvatar.position, 16000);
for (i = 0; i < e.length; i++) {
var props = Entities.getEntityProperties(e[i]);
if (props.type === "Line" || props.type === "Text") {
Entities.deleteEntity(e[i]);
}
}
};
Controller.mouseMoveEvent.connect(function panelMouseMoveEvent(event) {
return panel.mouseMoveEvent(event);
});
Controller.mousePressEvent.connect(function panelMousePressEvent(event) {
return panel.mousePressEvent(event);
});
Controller.mouseDoublePressEvent.connect(function panelMouseDoublePressEvent(event) {
return panel.mouseDoublePressEvent(event);
});
Controller.mouseReleaseEvent.connect(function(event) {
return panel.mouseReleaseEvent(event);
});
Controller.mousePressEvent.connect(mousePressEvent);
Controller.mouseDoublePressEvent.connect(mouseDoublePressEvent);
Controller.keyPressEvent.connect(keyPressEvent);
Script.scriptEnding.connect(scriptEnding);
Script.update.connect(update);

3
examples/libraries/entityCameraTool.js
View file

@ -141,7 +141,7 @@ CameraManager = function() {
// Pick a point INITIAL_ZOOM_DISTANCE in front of the camera to use as a focal point // Pick a point INITIAL_ZOOM_DISTANCE in front of the camera to use as a focal point
that.zoomDistance = INITIAL_ZOOM_DISTANCE; that.zoomDistance = INITIAL_ZOOM_DISTANCE;
that.targetZoomDistance = that.zoomDistance; that.targetZoomDistance = that.zoomDistance + 3.0;
var focalPoint = Vec3.sum(Camera.getPosition(), var focalPoint = Vec3.sum(Camera.getPosition(),
Vec3.multiply(that.zoomDistance, Quat.getFront(Camera.getOrientation()))); Vec3.multiply(that.zoomDistance, Quat.getFront(Camera.getOrientation())));
@ -150,6 +150,7 @@ CameraManager = function() {
var xzDist = Math.sqrt(dPos.x * dPos.x + dPos.z * dPos.z); var xzDist = Math.sqrt(dPos.x * dPos.x + dPos.z * dPos.z);
that.targetPitch = -Math.atan2(dPos.y, xzDist) * 180 / Math.PI; that.targetPitch = -Math.atan2(dPos.y, xzDist) * 180 / Math.PI;
that.targetPitch += (90 - that.targetPitch) / 3.0; // Swing camera "up" to look down at the focal point
that.targetYaw = Math.atan2(dPos.x, dPos.z) * 180 / Math.PI; that.targetYaw = Math.atan2(dPos.x, dPos.z) * 180 / Math.PI;
that.pitch = that.targetPitch; that.pitch = that.targetPitch;
that.yaw = that.targetYaw; that.yaw = that.targetYaw;

186
examples/utilities/tools/vector.js Normal file
View file

@ -0,0 +1,186 @@
//
// vector.js
// examples
//
// Created by Bridget Went on 7/1/15.
// Copyright 2015 High Fidelity, Inc.
//
// A template for creating vector arrows using line entities. A VectorArrow object creates a
// draggable vector arrow where the user clicked at a specified distance from the viewer.
// The relative magnitude and direction of the vector may be displayed.
//
//
// Distributed under the Apache License, Version 2.0.
// See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html
//
//
var LINE_DIMENSIONS = 100;
var LIFETIME = 6000;
var RAD_TO_DEG = 180.0 / Math.PI;
var LINE_WIDTH = 4;
var ARROW_WIDTH = 6;
var line, linePosition;
var arrow1, arrow2;
var SCALE = 0.15;
var ANGLE = 150.0;
VectorArrow = function(distance, showStats, statsTitle, statsPosition) {
this.magnitude = 0;
this.direction = {x: 0, y: 0, z: 0};
this.showStats = showStats;
this.isDragging = false;
this.newLine = function(position) {
linePosition = position;
var points = [];
line = Entities.addEntity({
position: linePosition,
type: "Line",
color: {red: 255, green: 255, blue: 255},
dimensions: {
x: LINE_DIMENSIONS,
y: LINE_DIMENSIONS,
z: LINE_DIMENSIONS
},
lineWidth: LINE_WIDTH,
lifetime: LIFETIME,
linePoints: []
});
arrow1 = Entities.addEntity({
position: {x: 0, y: 0, z: 0},
type: "Line",
dimensions: {
x: LINE_DIMENSIONS,
y: LINE_DIMENSIONS,
z: LINE_DIMENSIONS
},
color: {red: 255, green: 255, blue: 255},
lineWidth: ARROW_WIDTH,
linePoints: [],
});
arrow2 = Entities.addEntity({
position: {x: 0, y: 0, z: 0},
type: "Line",
dimensions: {
x: LINE_DIMENSIONS,
y: LINE_DIMENSIONS,
z: LINE_DIMENSIONS
},
color: {red: 255, green: 255, blue: 255},
lineWidth: ARROW_WIDTH,
linePoints: [],
});
}
var STATS_DIMENSIONS = {
x: 4.0,
y: 1.5,
z: 0.1
};
var TEXT_HEIGHT = 0.3;
this.onMousePressEvent = function(event) {
this.newLine(computeWorldPoint(event));
if (this.showStats) {
this.label = Entities.addEntity({
type: "Text",
position: statsPosition,
dimensions: STATS_DIMENSIONS,
lineHeight: TEXT_HEIGHT,
faceCamera: true
});
}
this.isDragging = true;
}
this.onMouseMoveEvent = function(event) {
if (!this.isDragging) {
return;
}
var worldPoint = computeWorldPoint(event);
var localPoint = computeLocalPoint(event, linePosition);
points = [{x: 0, y: 0, z: 0}, localPoint];
Entities.editEntity(line, { linePoints: points });
var nextOffset = Vec3.multiply(SCALE, localPoint);
var normOffset = Vec3.normalize(localPoint);
var axis = Vec3.cross(normOffset, Quat.getFront(Camera.getOrientation()) );
axis = Vec3.cross(axis, normOffset);
var rotate1 = Quat.angleAxis(ANGLE, axis);
var rotate2 = Quat.angleAxis(-ANGLE, axis);
// Rotate arrow head to follow direction of the line
Entities.editEntity(arrow1, {
visible: true,
position: worldPoint,
linePoints: [{x: 0, y: 0, z: 0}, nextOffset],
rotation: rotate1
});
Entities.editEntity(arrow2, {
visible: true,
position: worldPoint,
linePoints: [{x: 0, y: 0, z: 0}, nextOffset],
rotation: rotate2
});
this.magnitude = Vec3.length(localPoint) * 0.1;
this.direction = Vec3.normalize(Vec3.subtract(worldPoint, linePosition));
if (this.showStats) {
this.editLabel(statsTitle + " Magnitude " + this.magnitude.toFixed(2) + ", Direction: " +
this.direction.x.toFixed(2) + ", " + this.direction.y.toFixed(2) + ", " + this.direction.z.toFixed(2));
}
}
this.onMouseReleaseEvent = function() {
this.isDragging = false;
}
this.cleanup = function() {
Entities.deleteEntity(line);
Entities.deleteEntity(arrow1);
Entities.deleteEntity(arrow2);
}
this.deleteLabel = function() {
Entities.deleteEntity(this.label);
}
this.editLabel = function(str) {
if(!this.showStats) {
return;
}
Entities.editEntity(this.label, {
text: str
});
}
function computeWorldPoint(event) {
var pickRay = Camera.computePickRay(event.x, event.y);
var addVector = Vec3.multiply(pickRay.direction, distance);
return Vec3.sum(Camera.getPosition(), addVector);
}
function computeLocalPoint(event, linePosition) {
var localPoint = Vec3.subtract(computeWorldPoint(event), linePosition);
return localPoint;
}
}

2
interface/src/Application.cpp
View file

@ -3603,7 +3603,7 @@ void Application::renderRearViewMirror(RenderArgs* renderArgs, const QRect& regi
// This was removed in commit 71e59cfa88c6563749594e25494102fe01db38e9 but could be further // This was removed in commit 71e59cfa88c6563749594e25494102fe01db38e9 but could be further
// investigated in order to adapt the technique while fixing the head rendering issue, // investigated in order to adapt the technique while fixing the head rendering issue,
// but the complexity of the hack suggests that a better approach // but the complexity of the hack suggests that a better approach
_mirrorCamera.setPosition(_myAvatar->getHead()->getEyePosition() + _mirrorCamera.setPosition(_myAvatar->getDefaultEyePosition() +
_myAvatar->getOrientation() * glm::vec3(0.0f, 0.0f, -1.0f) * MIRROR_REARVIEW_DISTANCE * _myAvatar->getScale()); _myAvatar->getOrientation() * glm::vec3(0.0f, 0.0f, -1.0f) * MIRROR_REARVIEW_DISTANCE * _myAvatar->getScale());
} }
_mirrorCamera.setProjection(glm::perspective(glm::radians(fov), aspect, DEFAULT_NEAR_CLIP, DEFAULT_FAR_CLIP)); _mirrorCamera.setProjection(glm::perspective(glm::radians(fov), aspect, DEFAULT_NEAR_CLIP, DEFAULT_FAR_CLIP));

7
tests/physics/src/BulletUtilTests.cpp
View file

@ -9,13 +9,16 @@
// See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html // See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html
// //
#include "BulletUtilTests.h"
#include <iostream> #include <iostream>
//#include "PhysicsTestUtil.h"
#include <BulletUtil.h> #include <BulletUtil.h>
#include <NumericalConstants.h> #include <NumericalConstants.h>
#include "BulletUtilTests.h" // Add additional qtest functionality (the include order is important!)
#include "GlmTestUtils.h"
#include "../QTestExtensions.h"
// Constants // Constants
const glm::vec3 origin(0.0f); const glm::vec3 origin(0.0f);

3
tests/physics/src/BulletUtilTests.h
View file

@ -13,9 +13,6 @@
#define hifi_BulletUtilTests_h #define hifi_BulletUtilTests_h
#include <QtTest/QtTest> #include <QtTest/QtTest>
// Add additional qtest functionality (the include order is important!)
#include "GlmTestUtils.h"
#include "../QTestExtensions.h"
class BulletUtilTests : public QObject { class BulletUtilTests : public QObject {
Q_OBJECT Q_OBJECT

70
tests/physics/src/CollisionInfoTests.cpp
View file

@ -1,70 +0,0 @@
//
// CollisionInfoTests.cpp
// tests/physics/src
//
// Created by Andrew Meadows on 2/21/2014.
// Copyright 2014 High Fidelity, Inc.
//
// Distributed under the Apache License, Version 2.0.
// See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html
//
#include <iostream>
#include <glm/glm.hpp>
#include <glm/gtx/quaternion.hpp>
#include <CollisionInfo.h>
#include <SharedUtil.h>
#include <StreamUtils.h>
#include "CollisionInfoTests.h"
QTEST_MAIN(CollisionInfoTests)
/*
static glm::vec3 xAxis(1.0f, 0.0f, 0.0f);
static glm::vec3 xZxis(0.0f, 1.0f, 0.0f);
static glm::vec3 xYxis(0.0f, 0.0f, 1.0f);
void CollisionInfoTests::rotateThenTranslate() {
CollisionInfo collision;
collision._penetration = xAxis;
collision._contactPoint = xYxis;
collision._addedVelocity = xAxis + xYxis + xZxis;
glm::quat rotation = glm::angleAxis(PI_OVER_TWO, zAxis);
float distance = 3.0f;
glm::vec3 translation = distance * xYxis;
collision.rotateThenTranslate(rotation, translation);
QCOMPARE(collision._penetration, xYxis);
glm::vec3 expectedContactPoint = -xAxis + translation;
QCOMPARE(collision._contactPoint, expectedContactPoint);
glm::vec3 expectedAddedVelocity = xYxis - xAxis + xZxis;
QCOMPARE(collision._addedVelocity, expectedAddedVelocity);
}
void CollisionInfoTests::translateThenRotate() {
CollisionInfo collision;
collision._penetration = xAxis;
collision._contactPoint = xYxis;
collision._addedVelocity = xAxis + xYxis + xZxis;
glm::quat rotation = glm::angleAxis( -PI_OVER_TWO, zAxis);
float distance = 3.0f;
glm::vec3 translation = distance * xYxis;
collision.translateThenRotate(translation, rotation);
QCOMPARE(collision._penetration, -xYxis);
glm::vec3 expectedContactPoint = (1.0f + distance) * xAxis;
QCOMPARE(collision._contactPoint, expectedContactPoint);
glm::vec3 expectedAddedVelocity = - xYxis + xAxis + xYxis;
QCOMPARE(collision._addedVelocity, expectedAddedVelocity);
}*/

29
tests/physics/src/CollisionInfoTests.h
View file

@ -1,29 +0,0 @@
//
// CollisionInfoTests.h
// tests/physics/src
//
// Created by Andrew Meadows on 2/21/2014.
// Copyright 2014 High Fidelity, Inc.
//
// Distributed under the Apache License, Version 2.0.
// See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html
//
#ifndef hifi_CollisionInfoTests_h
#define hifi_CollisionInfoTests_h
#include <QtTest/QtTest>
// Add additional qtest functionality (the include order is important!)
#include "GlmTestUtils.h"
#include "../QTestExtensions.h"
class CollisionInfoTests : public QObject {
Q_OBJECT
private slots:
// void rotateThenTranslate();
// void translateThenRotate();
};
#endif // hifi_CollisionInfoTests_h

8
tests/physics/src/MeshMassPropertiesTests.cpp
View file

@ -9,11 +9,15 @@
// See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html // See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html
// //
#include "MeshMassPropertiesTests.h"
#include <iostream> #include <iostream>
#include <string>
#include <MeshMassProperties.h> #include <MeshMassProperties.h>
#include "MeshMassPropertiesTests.h" // Add additional qtest functionality (the include order is important!)
#include "BulletTestUtils.h"
#include "GlmTestUtils.h"
#include "../QTestExtensions.h"
const btScalar acceptableRelativeError(1.0e-5f); const btScalar acceptableRelativeError(1.0e-5f);
const btScalar acceptableAbsoluteError(1.0e-4f); const btScalar acceptableAbsoluteError(1.0e-4f);

6
tests/physics/src/MeshMassPropertiesTests.h
View file

@ -13,12 +13,6 @@
#define hifi_MeshMassPropertiesTests_h #define hifi_MeshMassPropertiesTests_h
#include <QtTest/QtTest> #include <QtTest/QtTest>
#include <QtGlobal>
// Add additional qtest functionality (the include order is important!)
#include "BulletTestUtils.h"
#include "GlmTestUtils.h"
#include "../QTestExtensions.h"
// Relative error macro (see errorTest in BulletTestUtils.h) // Relative error macro (see errorTest in BulletTestUtils.h)
#define QCOMPARE_WITH_RELATIVE_ERROR(actual, expected, relativeError) \ #define QCOMPARE_WITH_RELATIVE_ERROR(actual, expected, relativeError) \

14
tests/physics/src/ShapeColliderTests.cpp
View file

@ -9,12 +9,15 @@
// See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html // See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html
// //
#include "ShapeColliderTests.h"
//#include <stdio.h> //#include <stdio.h>
#include <iostream> #include <iostream>
#include <math.h> #include <math.h>
#include <glm/glm.hpp> #include <glm/glm.hpp>
#include <glm/gtx/quaternion.hpp> #include <glm/gtx/quaternion.hpp>
#include <QtGlobal>
#include <AACubeShape.h> #include <AACubeShape.h>
#include <CapsuleShape.h> #include <CapsuleShape.h>
@ -25,7 +28,10 @@
#include <SphereShape.h> #include <SphereShape.h>
#include <StreamUtils.h> #include <StreamUtils.h>
#include "ShapeColliderTests.h" // Add additional qtest functionality (the include order is important!)
#include "BulletTestUtils.h"
#include "GlmTestUtils.h"
#include "../QTestExtensions.h"
const glm::vec3 origin(0.0f); const glm::vec3 origin(0.0f);
@ -1553,8 +1559,6 @@ void ShapeColliderTests::rayHitsCapsule() {
intersection._rayDirection = - xAxis; intersection._rayDirection = - xAxis;
QCOMPARE(capsule.findRayIntersection(intersection), true); QCOMPARE(capsule.findRayIntersection(intersection), true);
float expectedDistance = startDistance - radius * sqrtf(2.0f * delta); // using small angle approximation of cosine float expectedDistance = startDistance - radius * sqrtf(2.0f * delta); // using small angle approximation of cosine
// float relativeError = fabsf(intersection._hitDistance - expectedDistance) / startDistance;
// for edge cases we allow a LOT of error
QCOMPARE_WITH_ABS_ERROR(intersection._hitDistance, expectedDistance, startDistance * EDGE_CASE_SLOP_FACTOR * EPSILON); QCOMPARE_WITH_ABS_ERROR(intersection._hitDistance, expectedDistance, startDistance * EDGE_CASE_SLOP_FACTOR * EPSILON);
} }
@ -1564,8 +1568,6 @@ void ShapeColliderTests::rayHitsCapsule() {
intersection._rayDirection = - xAxis; intersection._rayDirection = - xAxis;
QCOMPARE(capsule.findRayIntersection(intersection), true); QCOMPARE(capsule.findRayIntersection(intersection), true);
float expectedDistance = startDistance - radius * sqrtf(2.0f * delta); // using small angle approximation of cosine float expectedDistance = startDistance - radius * sqrtf(2.0f * delta); // using small angle approximation of cosine
// float relativeError = fabsf(intersection._hitDistance - expectedDistance) / startDistance;
// for edge cases we allow a LOT of error
QCOMPARE_WITH_ABS_ERROR(intersection._hitDistance, expectedDistance, startDistance * EPSILON * EDGE_CASE_SLOP_FACTOR); QCOMPARE_WITH_ABS_ERROR(intersection._hitDistance, expectedDistance, startDistance * EPSILON * EDGE_CASE_SLOP_FACTOR);
} }
@ -1575,8 +1577,6 @@ void ShapeColliderTests::rayHitsCapsule() {
intersection._rayDirection = - xAxis; intersection._rayDirection = - xAxis;
QCOMPARE(capsule.findRayIntersection(intersection), true); QCOMPARE(capsule.findRayIntersection(intersection), true);
float expectedDistance = startDistance - radius * sqrtf(2.0f * delta); // using small angle approximation of cosine float expectedDistance = startDistance - radius * sqrtf(2.0f * delta); // using small angle approximation of cosine
float relativeError = fabsf(intersection._hitDistance - expectedDistance) / startDistance;
// for edge cases we allow a LOT of error
QCOMPARE_WITH_ABS_ERROR(intersection._hitDistance, expectedDistance, startDistance * EPSILON * EDGE_CASE_SLOP_FACTOR); QCOMPARE_WITH_ABS_ERROR(intersection._hitDistance, expectedDistance, startDistance * EPSILON * EDGE_CASE_SLOP_FACTOR);
} }
// TODO: test at steep angles near cylinder/cap junction // TODO: test at steep angles near cylinder/cap junction

7
tests/physics/src/ShapeColliderTests.h
View file

@ -13,13 +13,6 @@
#define hifi_ShapeColliderTests_h #define hifi_ShapeColliderTests_h
#include <QtTest/QtTest> #include <QtTest/QtTest>
#include <QtGlobal>
// Add additional qtest functionality (the include order is important!)
#include "BulletTestUtils.h"
#include "GlmTestUtils.h"
#include "../QTestExtensions.h"
class ShapeColliderTests : public QObject { class ShapeColliderTests : public QObject {
Q_OBJECT Q_OBJECT

1
tests/shared/src/AngularConstraintTests.cpp
View file

@ -16,6 +16,7 @@
#include <StreamUtils.h> #include <StreamUtils.h>
#include "AngularConstraintTests.h" #include "AngularConstraintTests.h"
#include "../QTestExtensions.h"
// Computes the error value between two quaternions (using glm::dot) // Computes the error value between two quaternions (using glm::dot)
float getErrorDifference(const glm::quat& a, const glm::quat& b) { float getErrorDifference(const glm::quat& a, const glm::quat& b) {

7
tests/shared/src/AngularConstraintTests.h
View file

@ -12,6 +12,7 @@
#ifndef hifi_AngularConstraintTests_h #ifndef hifi_AngularConstraintTests_h
#define hifi_AngularConstraintTests_h #define hifi_AngularConstraintTests_h
#include <glm/glm.hpp>
#include <QtTest/QtTest> #include <QtTest/QtTest>
class AngularConstraintTests : public QObject { class AngularConstraintTests : public QObject {
@ -21,10 +22,6 @@ private slots:
void testConeRollerConstraint(); void testConeRollerConstraint();
}; };
// Use QCOMPARE_WITH_ABS_ERROR and define it for glm::quat float getErrorDifference(const glm::quat& a, const glm::quat& b);
#include <glm/glm.hpp>
float getErrorDifference (const glm::quat& a, const glm::quat& b);
QTextStream & operator << (QTextStream& stream, const glm::quat& q);
#include "../QTestExtensions.h"
#endif // hifi_AngularConstraintTests_h #endif // hifi_AngularConstraintTests_h

1
tests/shared/src/MovingPercentileTests.cpp
View file

@ -16,6 +16,7 @@
#include <limits> #include <limits>
#include <qqueue.h> #include <qqueue.h>
#include <../QTestExtensions.h>
QTEST_MAIN(MovingPercentileTests) QTEST_MAIN(MovingPercentileTests)

1
tests/shared/src/MovingPercentileTests.h
View file

@ -13,7 +13,6 @@
#define hifi_MovingPercentileTests_h #define hifi_MovingPercentileTests_h
#include <QtTest/QtTest> #include <QtTest/QtTest>
#include <../QTestExtensions.h>
class MovingPercentileTests : public QObject { class MovingPercentileTests : public QObject {
Q_OBJECT Q_OBJECT

4
tests/shared/src/TransformTests.cpp
View file

@ -8,10 +8,12 @@
// See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html // See the accompanying file LICENSE or http://www.apache.org/licenses/LICENSE-2.0.html
// //
#include "TransformTests.h"
#include <Transform.h> #include <Transform.h>
#include "TransformTests.h"
#include "SharedLogging.h" #include "SharedLogging.h"
#include <../QTestExtensions.h>
using namespace glm; using namespace glm;

2
tests/shared/src/TransformTests.h
View file

@ -40,8 +40,6 @@ inline QTextStream& operator<< (QTextStream& stream, const glm::mat4& matrix) {
return stream; return stream;
} }
#include <../QTestExtensions.h>
class TransformTests : public QObject { class TransformTests : public QObject {
Q_OBJECT Q_OBJECT
private slots: private slots: