/*
* Copyright 2003-2006, 2009, 2017, United States Government, as represented by the Administrator of the
* National Aeronautics and Space Administration. All rights reserved.
*
* The NASAWorldWind/WebWorldWind platform is licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/**
* @exports WorldWindow
*/
define([
'./ArcBallCamera',
'./error/ArgumentError',
'./BasicWorldWindowController',
'./render/DrawContext',
'./globe/EarthElevationModel',
'./util/FrameStatistics',
'./geom/Frustum',
'./globe/Globe',
'./globe/Globe2D',
'./util/GoToAnimator',
'./cache/GpuResourceCache',
'./geom/Line',
'./util/Logger',
'./navigate/LookAtNavigator',
'./geom/Matrix',
'./navigate/Navigator',
'./pick/PickedObjectList',
'./geom/Position',
'./geom/Rectangle',
'./geom/Sector',
'./shapes/SurfaceShape',
'./shapes/SurfaceShapeTileBuilder',
'./globe/Terrain',
'./geom/Vec2',
'./geom/Vec3',
'./util/WWMath'
],
function (ArcBallCamera,
ArgumentError,
BasicWorldWindowController,
DrawContext,
EarthElevationModel,
FrameStatistics,
Frustum,
Globe,
Globe2D,
GoToAnimator,
GpuResourceCache,
Line,
Logger,
LookAtNavigator,
Matrix,
Navigator,
PickedObjectList,
Position,
Rectangle,
Sector,
SurfaceShape,
SurfaceShapeTileBuilder,
Terrain,
Vec2,
Vec3,
WWMath) {
"use strict";
/**
* Constructs a WorldWind window for an HTML canvas.
* @alias WorldWindow
* @constructor
* @classdesc Represents a WorldWind window for an HTML canvas.
* @param {String|HTMLCanvasElement} canvasElem The ID assigned to the HTML canvas in the document or the canvas
* element itself.
* @param {ElevationModel} elevationModel An optional argument indicating the elevation model to use for the World
* Window. If missing or null, a default elevation model is used.
* @throws {ArgumentError} If there is no HTML element with the specified ID in the document, or if the
* HTML canvas does not support WebGL.
*/
var WorldWindow = function (canvasElem, elevationModel) {
if (!(window.WebGLRenderingContext)) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "constructor", "webglNotSupported"));
}
// Get the actual canvas element either directly or by ID.
var canvas;
if (canvasElem instanceof HTMLCanvasElement) {
canvas = canvasElem;
} else {
// Attempt to get the HTML canvas with the specified ID.
canvas = document.getElementById(canvasElem);
if (!canvas) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "constructor",
"The specified canvas ID is not in the document."));
}
}
// Create the WebGL context associated with the HTML canvas.
var gl = this.createContext(canvas);
if (!gl) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "constructor", "webglNotSupported"));
}
// Internal. Intentionally not documented.
this.drawContext = new DrawContext(gl);
// Internal. Intentionally not documented. Must be initialized before the navigator is created.
this.eventListeners = {};
// Internal. Intentionally not documented. Initially true in order to redraw at least once.
this.redrawRequested = true;
// Internal. Intentionally not documented.
this.redrawRequestId = null;
// Internal. Intentionally not documented.
this.scratchModelview = Matrix.fromIdentity();
// Internal. Intentionally not documented.
this.scratchProjection = Matrix.fromIdentity();
// Internal. Intentionally not documented.
this.hasStencilBuffer = gl.getContextAttributes().stencil;
/**
* The HTML canvas associated with this WorldWindow.
* @type {HTMLElement}
* @readonly
*/
this.canvas = canvas;
/**
* The number of bits in the depth buffer associated with this WorldWindow.
* @type {number}
* @readonly
*/
this.depthBits = gl.getParameter(gl.DEPTH_BITS);
/**
* The current viewport of this WorldWindow.
* @type {Rectangle}
* @readonly
*/
this.viewport = new Rectangle(0, 0, gl.drawingBufferWidth, gl.drawingBufferHeight);
/**
* The globe displayed.
* @type {Globe}
*/
this.globe = new Globe(elevationModel || new EarthElevationModel());
/**
* The layers to display in this WorldWindow.
* This property is read-only. Use [addLayer]{@link WorldWindow#addLayer} or
* [insertLayer]{@link WorldWindow#insertLayer} to add layers to this WorldWindow.
* Use [removeLayer]{@link WorldWindow#removeLayer} to remove layers from this WorldWindow.
* @type {Layer[]}
* @readonly
*/
this.layers = [];
/**
* The navigator used to manipulate the globe.
* @type {Navigator}
* @default [Navigator]{@link Navigator}
*/
this.navigator = new Navigator(new ArcBallCamera(this));
/**
* The controller used to manipulate the globe.
* @type {WorldWindowController}
* @default [BasicWorldWindowController]{@link BasicWorldWindowController}
*/
this.worldWindowController = new BasicWorldWindowController(this);
/**
* The vertical exaggeration to apply to the terrain.
* @type {Number}
*/
this.verticalExaggeration = 1;
/**
* Indicates that picking will return all objects at the pick point, if any. The top-most object will have
* its isOnTop flag set to true.
* If deep picking is false, the default, only the top-most object is returned, plus
* the picked-terrain object if the pick point is over the terrain.
* @type {boolean}
* @default false
*/
this.deepPicking = false;
/**
* Indicates whether this WorldWindow should be configured for sub-surface rendering. If true, shapes
* below the terrain can be seen when the terrain is made transparent. If false, sub-surface shapes are
* not visible, however, performance is slightly increased.
* @type {boolean}
* @default false
*/
this.subsurfaceMode = false;
/**
* The opacity to apply to terrain and surface shapes. This property is typically used when viewing
* the sub-surface. It modifies the opacity of the terrain and surface shapes as a whole. It should be
* a number between 0 and 1. It is compounded with the individual opacities of the image layers and
* surface shapes on the terrain.
* @type {Number}
* @default 1
*/
this.surfaceOpacity = 1;
/**
* Performance statistics for this WorldWindow.
* @type {FrameStatistics}
*/
this.frameStatistics = new FrameStatistics();
/**
* The {@link GoToAnimator} used by this WorldWindow to respond to its goTo method.
* @type {GoToAnimator}
*/
this.goToAnimator = new GoToAnimator(this);
// Documented with its property accessor below.
this._redrawCallbacks = [];
// Documented with its property accessor below.
this._orderedRenderingFilters = [
function (dc) {
thisWindow.declutter(dc, 1);
},
function (dc) {
thisWindow.declutter(dc, 2);
}
];
// Intentionally not documented.
this.pixelScale = 1;
// Prevent the browser's default actions in response to mouse and touch events, which interfere with
// navigation. Register these event listeners before any others to ensure that they're called last.
function preventDefaultListener(event) {
event.preventDefault();
}
this.addEventListener("mousedown", preventDefaultListener);
this.addEventListener("touchstart", preventDefaultListener);
this.addEventListener("contextmenu", preventDefaultListener);
this.addEventListener("wheel", preventDefaultListener);
var thisWindow = this;
// Redirect various UI interactions to the appropriate handler.
function onGestureEvent(event) {
thisWindow.onGestureEvent(event);
}
if (window.PointerEvent) {
// Prevent the browser's default actions in response to pointer events which interfere with navigation.
// This CSS style property is configured here to ensure that it's set for all applications.
this.canvas.style.setProperty("touch-action", "none");
this.addEventListener("pointerdown", onGestureEvent, false);
window.addEventListener("pointermove", onGestureEvent, false); // get pointermove events outside event target
window.addEventListener("pointercancel", onGestureEvent, false); // get pointercancel events outside event target
window.addEventListener("pointerup", onGestureEvent, false); // get pointerup events outside event target
} else {
this.addEventListener("mousedown", onGestureEvent, false);
window.addEventListener("mousemove", onGestureEvent, false); // get mousemove events outside event target
window.addEventListener("mouseup", onGestureEvent, false); // get mouseup events outside event target
this.addEventListener("touchstart", onGestureEvent, false);
this.addEventListener("touchmove", onGestureEvent, false);
this.addEventListener("touchend", onGestureEvent, false);
this.addEventListener("touchcancel", onGestureEvent, false);
}
// Register wheel event listeners on the WorldWindow's canvas.
this.addEventListener("wheel", function (event) {
onGestureEvent(event);
});
// Set up to handle WebGL context lost events.
function handleContextLost(event) {
thisWindow.handleContextLost(event);
}
this.canvas.addEventListener("webglcontextlost", handleContextLost, false);
// Set up to handle WebGL context restored events.
function handleContextRestored(event) {
thisWindow.handleContextRestored(event);
}
this.canvas.addEventListener("webglcontextrestored", handleContextRestored, false);
// Set up to handle WebGL context events and WorldWind redraw request events. Imagery uses the canvas
// redraw events because images are generally specific to the WebGL context associated with the canvas.
// Elevation models use the global window redraw events because they can be shared among WorldWindows.
function handleRedrawEvent(event) {
thisWindow.handleRedrawEvent(event)
}
this.canvas.addEventListener(WorldWind.REDRAW_EVENT_TYPE, handleRedrawEvent, false);
window.addEventListener(WorldWind.REDRAW_EVENT_TYPE, handleRedrawEvent, false);
// Render to the WebGL context in an animation frame loop until the WebGL context is lost.
this.animationFrameLoop();
};
Object.defineProperties(WorldWindow.prototype, {
/**
* An array of functions to call during ordered rendering prior to rendering the ordered renderables.
* Each function is passed one argument, the current draw context. The function may modify the
* ordered renderables in the draw context's ordered renderable list, which has been sorted from front
* to back when the filter function is called. Ordered rendering filters are typically used to apply
* decluttering. The default set of filter functions contains one function that declutters shapes with
* declutter group ID of 1 ({@link GeographicText} by default) and one function that declutters shapes
* with declutter group ID 2 ({@link Placemark} by default). Applications can add functions to this
* array or remove them.
* @type {Function[]}
* @default [WorldWindow.declutter]{@link WorldWindow#declutter} with a group ID of 1
* @readonly
* @memberof WorldWindow.prototype
*/
orderedRenderingFilters: {
get: function () {
return this._orderedRenderingFilters;
}
},
/**
* The list of callbacks to call immediately before and immediately after performing a redraw. The callbacks
* have two arguments: this WorldWindow and the redraw stage, e.g., <code style='white-space:nowrap'>redrawCallback(worldWindow, stage);</code>.
* The stage will be either WorldWind.BEFORE_REDRAW or WorldWind.AFTER_REDRAW indicating whether the
* callback has been called either immediately before or immediately after a redraw, respectively.
* Applications may add functions to this array or remove them.
* @type {Function[]}
* @readonly
* @memberof WorldWindow.prototype
*/
redrawCallbacks: {
get: function () {
return this._redrawCallbacks;
}
}
});
/**
* Converts window coordinates to coordinates relative to this WorldWindow's canvas.
* @param {Number} x The X coordinate to convert.
* @param {Number} y The Y coordinate to convert.
* @returns {Vec2} The converted coordinates.
*/
WorldWindow.prototype.canvasCoordinates = function (x, y) {
var bbox = this.canvas.getBoundingClientRect(),
xc = x - (bbox.left + this.canvas.clientLeft),// * (this.canvas.width / bbox.width),
yc = y - (bbox.top + this.canvas.clientTop);// * (this.canvas.height / bbox.height);
return new Vec2(xc, yc);
};
WorldWindow.prototype.onGestureEvent = function (event) {
this.worldWindowController.onGestureEvent(event);
};
/**
* Registers an event listener for the specified event type on this WorldWindow's canvas. This function
* delegates the processing of events to the WorldWindow's canvas. For details on this function and its
* arguments, see the W3C [EventTarget]{@link https://www.w3.org/TR/DOM-Level-2-Events/events.html#Events-EventTarget}
* documentation.
*
* Registering event listeners using this function enables applications to prevent the WorldWindow's default
* navigation behavior. To prevent default navigation behavior, call the [Event]{@link https://www.w3.org/TR/DOM-Level-2-Events/events.html#Events-Event}'s
* preventDefault method from within an event listener for any events the navigator should not respond to.
*
* When an event occurs, this calls the registered event listeners in order of reverse registration. Since the
* WorldWindow registers its navigator event listeners first, application event listeners are called before
* navigator event listeners.
*
* @param type The event type to listen for.
* @param listener The function to call when the event occurs.
* @throws {ArgumentError} If any argument is null or undefined.
*/
WorldWindow.prototype.addEventListener = function (type, listener) {
if (!type) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "addEventListener", "missingType"));
}
if (!listener) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "addEventListener", "missingListener"));
}
var thisWorldWindow = this;
var entry = this.eventListeners[type];
if (!entry) {
entry = {
listeners: [],
callback: function (event) { // calls listeners in reverse registration order
event.worldWindow = thisWorldWindow;
for (var i = 0, len = entry.listeners.length; i < len; i++) {
entry.listeners[i](event);
}
}
};
this.eventListeners[type] = entry;
}
var index = entry.listeners.indexOf(listener);
if (index == -1) { // suppress duplicate listeners
entry.listeners.splice(0, 0, listener); // insert the listener at the beginning of the list
if (entry.listeners.length == 1) { // first listener added, add the event listener callback
this.canvas.addEventListener(type, entry.callback, false);
}
}
};
/**
* Removes an event listener for the specified event type from this WorldWindow's canvas. The listener must be
* the same object passed to addEventListener. Calling removeEventListener with arguments that do not identify a
* currently registered listener has no effect.
*
* @param type Indicates the event type the listener registered for.
* @param listener The listener to remove. Must be the same function object passed to addEventListener.
* @throws {ArgumentError} If any argument is null or undefined.
*/
WorldWindow.prototype.removeEventListener = function (type, listener) {
if (!type) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "removeEventListener", "missingType"));
}
if (!listener) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "removeEventListener", "missingListener"));
}
var entry = this.eventListeners[type];
if (!entry) {
return; // no entry for the specified type
}
var index = entry.listeners.indexOf(listener);
if (index != -1) {
entry.listeners.splice(index, 1); // remove the listener from the list
if (entry.listeners.length == 0) { // last listener removed, remove the event listener callback
this.canvas.removeEventListener(type, entry.callback, false);
}
}
};
/**
* Causes this WorldWindow to redraw itself at the next available opportunity. The redraw occurs on the main
* thread at a time of the browser's discretion. Applications should call redraw after changing the World
* Window's state, but should not expect that change to be reflected on screen immediately after this function
* returns. This is the preferred method for requesting a redraw of the WorldWindow.
*/
WorldWindow.prototype.redraw = function () {
this.redrawRequested = true; // redraw during the next animation frame
};
/**
* Requests the WorldWind objects displayed at a specified screen-coordinate point.
*
* If the point intersects the terrain, the returned list contains an object identifying the associated geographic
* position. This returns an empty list when nothing in the WorldWind scene intersects the specified point.
*
* @param pickPoint The point to examine in this WorldWindow's screen coordinates.
* @returns {PickedObjectList} A list of picked WorldWind objects at the specified pick point.
* @throws {ArgumentError} If the specified pick point is null or undefined.
*/
WorldWindow.prototype.pick = function (pickPoint) {
if (!pickPoint) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "pick", "missingPoint"));
}
// Suppress the picking operation and return an empty list when the WebGL context has been lost.
if (this.drawContext.currentGlContext.isContextLost()) {
return new PickedObjectList();
}
this.resize();
this.resetDrawContext();
this.drawContext.pickingMode = true;
this.drawContext.pickPoint = pickPoint;
this.drawContext.pickRay = this.rayThroughScreenPoint(pickPoint);
this.drawFrame();
return this.drawContext.objectsAtPickPoint;
};
/**
* Requests the position of the WorldWind terrain at a specified screen-coordinate point. If the point
* intersects the terrain, the returned list contains a single object identifying the associated geographic
* position. Otherwise this returns an empty list.
* @param pickPoint The point to examine in this WorldWindow's screen coordinates.
* @returns {PickedObjectList} A list containing the picked WorldWind terrain position at the specified point,
* or an empty list if the point does not intersect the terrain.
* @throws {ArgumentError} If the specified pick point is null or undefined.
*/
WorldWindow.prototype.pickTerrain = function (pickPoint) {
if (!pickPoint) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "pickTerrain", "missingPoint"));
}
// Suppress the picking operation and return an empty list when the WebGL context has been lost.
if (this.drawContext.currentGlContext.isContextLost()) {
return new PickedObjectList();
}
this.resize();
this.resetDrawContext();
this.drawContext.pickingMode = true;
this.drawContext.pickTerrainOnly = true;
this.drawContext.pickPoint = pickPoint;
this.drawContext.pickRay = this.rayThroughScreenPoint(pickPoint);
this.drawFrame();
return this.drawContext.objectsAtPickPoint;
};
/**
* Requests the WorldWind objects displayed within a specified screen-coordinate region. This returns all
* objects that intersect the specified region, regardless of whether or not an object is actually visible, and
* marks objects that are visible as on top.
* @param {Rectangle} rectangle The screen coordinate rectangle identifying the region to search.
* @returns {PickedObjectList} A list of visible WorldWind objects within the specified region.
* @throws {ArgumentError} If the specified rectangle is null or undefined.
*/
WorldWindow.prototype.pickShapesInRegion = function (rectangle) {
if (!rectangle) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "pickShapesInRegion", "missingRectangle"));
}
// Suppress the picking operation and return an empty list when the WebGL context has been lost.
if (this.drawContext.currentGlContext.isContextLost()) {
return new PickedObjectList();
}
this.resize();
this.resetDrawContext();
this.drawContext.pickingMode = true;
this.drawContext.regionPicking = true;
this.drawContext.pickRectangle =
new Rectangle(rectangle.x, this.canvas.height - rectangle.y, rectangle.width, rectangle.height);
this.drawFrame();
return this.drawContext.objectsAtPickPoint;
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.createContext = function (canvas) {
// Request a WebGL context with antialiasing is disabled. Antialiasing causes gaps to appear at the edges of
// terrain tiles.
var glAttrs = {antialias: false, stencil: true},
gl = canvas.getContext("webgl", glAttrs);
if (!gl) {
gl = canvas.getContext("experimental-webgl", glAttrs);
}
// uncomment to debug WebGL
//var gl = WebGLDebugUtils.makeDebugContext(this.canvas.getContext("webgl"),
// this.throwOnGLError,
// this.logAndValidate
//);
return gl;
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.handleContextLost = function (event) {
Logger.log(Logger.LEVEL_INFO, "WebGL context event: " + event.statusMessage);
// Inform WebGL that we handle context restoration, enabling the context restored event to be delivered.
event.preventDefault();
// Notify the draw context that the WebGL rendering context has been lost.
this.drawContext.contextLost();
// Stop the rendering animation frame loop, resuming only if the WebGL context is restored.
window.cancelAnimationFrame(this.redrawRequestId);
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.handleContextRestored = function (event) {
Logger.log(Logger.LEVEL_INFO, "WebGL context event: " + event.statusMessage);
// Notify the draw context that the WebGL rendering context has been restored.
this.drawContext.contextRestored();
// Resume the rendering animation frame loop until the WebGL context is lost.
this.redraw();
this.animationFrameLoop();
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.handleRedrawEvent = function (event) {
this.redraw(); // redraw in the next animation frame
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.animationFrameLoop = function () {
// Render to the WebGL context as needed.
this.redrawIfNeeded();
// Continue the animation frame loop until the WebGL context is lost.
var thisWindow = this;
function animationFrameCallback() {
thisWindow.animationFrameLoop();
}
this.redrawRequestId = window.requestAnimationFrame(animationFrameCallback);
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.redrawIfNeeded = function () {
// Check if the drawing buffer needs to resize to match its screen size, which requires a redraw.
this.resize();
// Redraw the WebGL drawing buffer only when necessary.
if (!this.redrawRequested) {
return;
}
try {
// Prepare to redraw and notify the redraw callbacks that a redraw is about to occur.
this.redrawRequested = false;
this.drawContext.previousRedrawTimestamp = this.drawContext.timestamp;
this.callRedrawCallbacks(WorldWind.BEFORE_REDRAW);
// Redraw the WebGL drawing buffer.
this.resetDrawContext();
this.drawFrame();
} catch (e) {
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "redrawIfNeeded",
"Exception occurred during redrawing.\n" + e.toString());
} finally {
// Notify the redraw callbacks that a redraw has completed.
this.callRedrawCallbacks(WorldWind.AFTER_REDRAW);
// Handle rendering code redraw requests.
if (this.drawContext.redrawRequested) {
this.redrawRequested = true;
}
}
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.resize = function () {
var gl = this.drawContext.currentGlContext,
width = gl.canvas.clientWidth * this.pixelScale,
height = gl.canvas.clientHeight * this.pixelScale;
if (gl.canvas.width != width ||
gl.canvas.height != height) {
// Make the canvas drawing buffer size match its screen size.
gl.canvas.width = width;
gl.canvas.height = height;
// Set the WebGL viewport to match the canvas drawing buffer size.
gl.viewport(0, 0, gl.drawingBufferWidth, gl.drawingBufferHeight);
this.viewport = new Rectangle(0, 0, gl.drawingBufferWidth, gl.drawingBufferHeight);
// Cause this WorldWindow to redraw with the new size.
this.redrawRequested = true;
}
};
// Internal. Intentionally not documented.
WorldWindow.prototype.computeViewingTransform = function (projection, modelview) {
if (!modelview) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "computeViewingTransform", "missingModelview"));
}
var globe = this.globe;
this.navigator.camera.createViewMatrix(modelview);
if (projection) {
projection.setToIdentity();
var globeRadius = WWMath.max(globe.equatorialRadius, globe.polarRadius),
eyePoint = modelview.extractEyePoint(new Vec3(0, 0, 0)),
eyePos = globe.computePositionFromPoint(eyePoint[0], eyePoint[1], eyePoint[2], new Position(0, 0, 0)),
eyeHorizon = WWMath.horizonDistanceForGlobeRadius(globeRadius, eyePos.altitude),
atmosphereHorizon = WWMath.horizonDistanceForGlobeRadius(globeRadius, 160000),
viewport = this.viewport;
// Set the far clip distance to the smallest value that does not clip the atmosphere.
// TODO adjust the clip plane distances based on the navigator's orientation - shorter distances when the
// TODO horizon is not in view
// TODO parameterize the object altitude for horizon distance
var farDistance = eyeHorizon + atmosphereHorizon;
if (farDistance < 1e3)
farDistance = 1e3;
// Compute the near clip distance in order to achieve a desired depth resolution at the far clip distance.
// This computed distance is limited such that it does not intersect the terrain when possible and is never
// less than a predetermined minimum (usually one). The computed near distance automatically scales with the
// resolution of the WebGL depth buffer.
var nearDistance = WWMath.perspectiveNearDistanceForFarDistance(farDistance, 10, this.depthBits);
// Prevent the near clip plane from intersecting the terrain.
var distanceToSurface = eyePos.altitude - globe.elevationAtLocation(eyePos.latitude, eyePos.longitude);
if (distanceToSurface > 0) {
var maxNearDistance = WWMath.perspectiveNearDistance(viewport.width, viewport.height, distanceToSurface);
if (nearDistance > maxNearDistance) {
nearDistance = maxNearDistance;
}
}
if (nearDistance < 1) {
nearDistance = 1;
}
// Compute the current projection matrix based on this navigator's perspective properties and the current
// WebGL viewport.
projection.setToPerspectiveProjection(viewport.width, viewport.height, nearDistance, farDistance);
}
};
// Internal. Intentionally not documented.
WorldWindow.prototype.computePixelMetrics = function (projection) {
var projectionInv = Matrix.fromIdentity();
projectionInv.invertMatrix(projection);
// Compute the eye coordinate rectangles carved out of the frustum by the near and far clipping planes, and
// the distance between those planes and the eye point along the -Z axis. The rectangles are determined by
// transforming the bottom-left and top-right points of the frustum from clip coordinates to eye
// coordinates.
var nbl = new Vec3(-1, -1, -1),
ntr = new Vec3(+1, +1, -1),
fbl = new Vec3(-1, -1, +1),
ftr = new Vec3(+1, +1, +1);
// Convert each frustum corner from clip coordinates to eye coordinates by multiplying by the inverse
// projection matrix.
nbl.multiplyByMatrix(projectionInv);
ntr.multiplyByMatrix(projectionInv);
fbl.multiplyByMatrix(projectionInv);
ftr.multiplyByMatrix(projectionInv);
var nrRectWidth = WWMath.fabs(ntr[0] - nbl[0]),
frRectWidth = WWMath.fabs(ftr[0] - fbl[0]),
nrDistance = -nbl[2],
frDistance = -fbl[2];
// Compute the scale and offset used to determine the width of a pixel on a rectangle carved out of the
// frustum at a distance along the -Z axis in eye coordinates. These values are found by computing the scale
// and offset of a frustum rectangle at a given distance, then dividing each by the viewport width.
var frustumWidthScale = (frRectWidth - nrRectWidth) / (frDistance - nrDistance),
frustumWidthOffset = nrRectWidth - frustumWidthScale * nrDistance;
return {
pixelSizeFactor: frustumWidthScale / this.viewport.width,
pixelSizeOffset: frustumWidthOffset / this.viewport.height
};
};
/**
* Computes the approximate size of a pixel at a specified distance from the eye point.
* <p>
* This method assumes rectangular pixels, where pixel coordinates denote
* infinitely thin spaces between pixels. The units of the returned size are in model coordinates per pixel
* (usually meters per pixel). This returns 0 if the specified distance is zero. The returned size is undefined
* if the distance is less than zero.
*
* @param {Number} distance The distance from the eye point at which to determine pixel size, in model
* coordinates.
* @returns {Number} The approximate pixel size at the specified distance from the eye point, in model
* coordinates per pixel.
*/
WorldWindow.prototype.pixelSizeAtDistance = function (distance) {
this.computeViewingTransform(this.scratchProjection, this.scratchModelview);
var pixelMetrics = this.computePixelMetrics(this.scratchProjection);
return pixelMetrics.pixelSizeFactor * distance + pixelMetrics.pixelSizeOffset;
};
// Internal. Intentionally not documented.
WorldWindow.prototype.computeDrawContext = function () {
var dc = this.drawContext;
this.computeViewingTransform(dc.projection, dc.modelview);
dc.viewport = this.viewport;
dc.eyePoint = dc.modelview.extractEyePoint(new Vec3(0, 0, 0));
dc.modelviewProjection.setToIdentity();
dc.modelviewProjection.setToMultiply(dc.projection, dc.modelview);
var pixelMetrics = this.computePixelMetrics(dc.projection);
dc.pixelSizeFactor = pixelMetrics.pixelSizeFactor;
dc.pixelSizeOffset = pixelMetrics.pixelSizeOffset;
// Compute the inverse of the modelview, projection, and modelview-projection matrices. The inverse matrices
// are used to support operations on navigator state.
var modelviewInv = Matrix.fromIdentity();
modelviewInv.invertOrthonormalMatrix(dc.modelview);
dc.modelviewNormalTransform = Matrix.fromIdentity().setToTransposeOfMatrix(modelviewInv.upper3By3());
// Compute the frustum in model coordinates. Start by computing the frustum in eye coordinates from the
// projection matrix, then transform this frustum to model coordinates by multiplying its planes by the
// transpose of the modelview matrix. We use the transpose of the modelview matrix because planes are
// transformed by the inverse transpose of a matrix, and we want to transform from eye coordinates to model
// coordinates.
var modelviewTranspose = Matrix.fromIdentity();
modelviewTranspose.setToTransposeOfMatrix(dc.modelview);
dc.frustumInModelCoordinates = Frustum.fromProjectionMatrix(dc.projection);
dc.frustumInModelCoordinates.transformByMatrix(modelviewTranspose);
dc.frustumInModelCoordinates.normalize();
};
// Internal. Intentionally not documented.
WorldWindow.prototype.resetDrawContext = function () {
this.globe.offset = 0;
var dc = this.drawContext;
dc.reset();
dc.globe = this.globe;
dc.navigator = this.navigator;
dc.layers = this.layers.slice();
dc.layers.push(dc.screenCreditController);
this.computeDrawContext();
dc.verticalExaggeration = this.verticalExaggeration;
dc.surfaceOpacity = this.surfaceOpacity;
dc.deepPicking = this.deepPicking;
dc.frameStatistics = this.frameStatistics;
dc.pixelScale = this.pixelScale;
dc.update();
};
/* useful stuff to debug WebGL */
/*
function logGLCall(functionName, args) {
console.log("gl." + functionName + "(" +
WebGLDebugUtils.glFunctionArgsToString(functionName, args) + ")");
};
function validateNoneOfTheArgsAreUndefined(functionName, args) {
for (var ii = 0; ii < args.length; ++ii) {
if (args[ii] === undefined) {
console.error("undefined passed to gl." + functionName + "(" +
WebGLDebugUtils.glFunctionArgsToString(functionName, args) + ")");
}
}
};
WorldWindow.prototype.logAndValidate = function logAndValidate(functionName, args) {
logGLCall(functionName, args);
validateNoneOfTheArgsAreUndefined (functionName, args);
};
WorldWindow.prototype.throwOnGLError = function throwOnGLError(err, funcName, args) {
throw WebGLDebugUtils.glEnumToString(err) + " was caused by call to: " + funcName;
};
*/
// Internal function. Intentionally not documented.
WorldWindow.prototype.drawFrame = function () {
try {
this.drawContext.frameStatistics.beginFrame();
this.beginFrame();
if (this.drawContext.globe.is2D() && this.drawContext.globe.continuous) {
this.do2DContiguousRepaint();
} else {
this.doNormalRepaint();
}
} finally {
this.endFrame();
this.drawContext.frameStatistics.endFrame();
//console.log(this.drawContext.frameStatistics.frameTime);
}
};
WorldWindow.prototype.doNormalRepaint = function () {
this.createTerrain();
this.clearFrame();
this.deferOrderedRendering = false;
if (this.drawContext.pickingMode) {
if (this.drawContext.makePickFrustum()) {
this.doPick();
this.resolvePick();
}
} else {
this.doDraw();
if (this.subsurfaceMode && this.hasStencilBuffer) {
this.redrawSurface();
this.drawScreenRenderables();
}
}
};
WorldWindow.prototype.do2DContiguousRepaint = function () {
this.createTerrain2DContiguous();
this.clearFrame();
if (this.drawContext.pickingMode) {
if (this.drawContext.makePickFrustum()) {
this.pick2DContiguous();
this.resolvePick();
}
} else {
this.draw2DContiguous();
}
};
WorldWindow.prototype.resolvePick = function () {
if (this.drawContext.pickTerrainOnly) {
this.resolveTerrainPick();
} else if (this.drawContext.regionPicking) {
this.resolveRegionPick();
} else {
this.resolveTopPick();
}
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.beginFrame = function () {
var gl = this.drawContext.currentGlContext;
gl.enable(gl.BLEND);
gl.enable(gl.CULL_FACE);
gl.enable(gl.DEPTH_TEST);
gl.blendFunc(gl.ONE, gl.ONE_MINUS_SRC_ALPHA);
gl.depthFunc(gl.LEQUAL);
if (this.drawContext.pickingMode) {
this.drawContext.makePickFramebuffer();
this.drawContext.bindFramebuffer(this.drawContext.pickFramebuffer);
}
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.endFrame = function () {
var gl = this.drawContext.currentGlContext;
gl.disable(gl.BLEND);
gl.disable(gl.CULL_FACE);
gl.disable(gl.DEPTH_TEST);
gl.blendFunc(gl.ONE, gl.ZERO);
gl.depthFunc(gl.LESS);
gl.clearColor(0, 0, 0, 1);
this.drawContext.bindFramebuffer(null);
this.drawContext.bindProgram(null);
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.clearFrame = function () {
var dc = this.drawContext,
gl = dc.currentGlContext;
gl.clearColor(dc.clearColor.red, dc.clearColor.green, dc.clearColor.blue, dc.clearColor.alpha);
gl.clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT);
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.doDraw = function () {
this.drawContext.renderShapes = true;
if (this.subsurfaceMode && this.hasStencilBuffer) {
// Draw the surface and collect the ordered renderables.
this.drawContext.currentGlContext.disable(this.drawContext.currentGlContext.STENCIL_TEST);
this.drawContext.surfaceShapeTileBuilder.clear();
this.drawLayers(true);
this.drawSurfaceRenderables();
this.drawContext.surfaceShapeTileBuilder.doRender(this.drawContext);
if (!this.deferOrderedRendering) {
// Clear the depth and stencil buffers prior to rendering the ordered renderables. This allows
// sub-surface renderables to be drawn beneath the terrain. Turn on stenciling to capture the
// fragments that ordered renderables draw. The terrain and surface shapes will be subsequently
// drawn again, and the stencil buffer will ensure that they are drawn only where they overlap
// the fragments drawn by the ordered renderables.
this.drawContext.currentGlContext.clear(
this.drawContext.currentGlContext.DEPTH_BUFFER_BIT | this.drawContext.currentGlContext.STENCIL_BUFFER_BIT);
this.drawContext.currentGlContext.enable(this.drawContext.currentGlContext.STENCIL_TEST);
this.drawContext.currentGlContext.stencilFunc(this.drawContext.currentGlContext.ALWAYS, 1, 1);
this.drawContext.currentGlContext.stencilOp(
this.drawContext.currentGlContext.REPLACE, this.drawContext.currentGlContext.REPLACE, this.drawContext.currentGlContext.REPLACE);
this.drawOrderedRenderables();
}
} else {
this.drawContext.surfaceShapeTileBuilder.clear();
this.drawLayers(true);
this.drawSurfaceRenderables();
this.drawContext.surfaceShapeTileBuilder.doRender(this.drawContext);
if (!this.deferOrderedRendering) {
this.drawOrderedRenderables();
this.drawScreenRenderables();
}
}
};
WorldWindow.prototype.redrawSurface = function () {
// Draw the terrain and surface shapes but only where the current stencil buffer is non-zero.
// The non-zero fragments are from drawing the ordered renderables previously.
this.drawContext.currentGlContext.enable(this.drawContext.currentGlContext.STENCIL_TEST);
this.drawContext.currentGlContext.stencilFunc(this.drawContext.currentGlContext.EQUAL, 1, 1);
this.drawContext.currentGlContext.stencilOp(
this.drawContext.currentGlContext.KEEP, this.drawContext.currentGlContext.KEEP, this.drawContext.currentGlContext.KEEP);
this.drawContext.surfaceShapeTileBuilder.clear();
this.drawLayers(false);
this.drawSurfaceRenderables();
this.drawContext.surfaceShapeTileBuilder.doRender(this.drawContext);
this.drawContext.currentGlContext.disable(this.drawContext.currentGlContext.STENCIL_TEST);
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.doPick = function () {
if (this.drawContext.terrain) {
this.drawContext.terrain.pick(this.drawContext);
}
if (!this.drawContext.pickTerrainOnly) {
if (this.subsurfaceMode && this.hasStencilBuffer) {
// Draw the surface and collect the ordered renderables.
this.drawContext.currentGlContext.disable(this.drawContext.currentGlContext.STENCIL_TEST);
this.drawContext.surfaceShapeTileBuilder.clear();
this.drawLayers(true);
this.drawSurfaceRenderables();
this.drawContext.surfaceShapeTileBuilder.doRender(this.drawContext);
if (!this.deferOrderedRendering) {
// Clear the depth and stencil buffers prior to rendering the ordered renderables. This allows
// sub-surface renderables to be drawn beneath the terrain. Turn on stenciling to capture the
// fragments that ordered renderables draw. The terrain and surface shapes will be subsequently
// drawn again, and the stencil buffer will ensure that they are drawn only where they overlap
// the fragments drawn by the ordered renderables.
this.drawContext.currentGlContext.clear(
this.drawContext.currentGlContext.DEPTH_BUFFER_BIT | this.drawContext.currentGlContext.STENCIL_BUFFER_BIT);
this.drawContext.currentGlContext.enable(this.drawContext.currentGlContext.STENCIL_TEST);
this.drawContext.currentGlContext.stencilFunc(this.drawContext.currentGlContext.ALWAYS, 1, 1);
this.drawContext.currentGlContext.stencilOp(
this.drawContext.currentGlContext.REPLACE, this.drawContext.currentGlContext.REPLACE, this.drawContext.currentGlContext.REPLACE);
this.drawOrderedRenderables();
this.drawContext.terrain.pick(this.drawContext);
this.drawScreenRenderables();
}
} else {
this.drawContext.surfaceShapeTileBuilder.clear();
this.drawLayers(true);
this.drawSurfaceRenderables();
this.drawContext.surfaceShapeTileBuilder.doRender(this.drawContext);
if (!this.deferOrderedRendering) {
this.drawOrderedRenderables();
this.drawScreenRenderables();
}
}
}
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.createTerrain = function () {
var dc = this.drawContext;
dc.terrain = this.globe.tessellator.tessellate(dc);
dc.frameStatistics.setTerrainTileCount(dc.terrain ? dc.terrain.surfaceGeometry.length : 0);
};
WorldWindow.prototype.makeCurrent = function (offset) {
var dc = this.drawContext;
dc.globe.offset = offset;
dc.globeStateKey = dc.globe.stateKey;
switch (offset) {
case -1:
dc.terrain = this.terrainLeft;
break;
case 0:
dc.terrain = this.terrainCenter;
break;
case 1:
dc.terrain = this.terrainRight;
break;
}
};
WorldWindow.prototype.createTerrain2DContiguous = function () {
var dc = this.drawContext;
this.terrainCenter = null;
dc.globe.offset = 0;
dc.globeStateKey = dc.globe.stateKey;
if (dc.globe.intersectsFrustum(dc.frustumInModelCoordinates)) {
this.terrainCenter = dc.globe.tessellator.tessellate(dc);
}
this.terrainRight = null;
dc.globe.offset = 1;
dc.globeStateKey = dc.globe.stateKey;
if (dc.globe.intersectsFrustum(dc.frustumInModelCoordinates)) {
this.terrainRight = dc.globe.tessellator.tessellate(dc);
}
this.terrainLeft = null;
dc.globe.offset = -1;
dc.globeStateKey = dc.globe.stateKey;
if (dc.globe.intersectsFrustum(dc.frustumInModelCoordinates)) {
this.terrainLeft = dc.globe.tessellator.tessellate(dc);
}
};
WorldWindow.prototype.draw2DContiguous = function () {
var drawing = "";
if (this.terrainCenter) {
drawing += " 0 ";
this.makeCurrent(0);
this.deferOrderedRendering = this.terrainLeft || this.terrainRight;
this.doDraw();
}
if (this.terrainRight) {
drawing += " 1 ";
this.makeCurrent(1);
this.deferOrderedRendering = this.terrainLeft || this.terrainLeft;
this.doDraw();
}
this.deferOrderedRendering = false;
if (this.terrainLeft) {
drawing += " -1 ";
this.makeCurrent(-1);
this.doDraw();
}
//
//console.log(drawing);
if (this.subsurfaceMode && this.hasStencilBuffer) {
this.deferOrderedRendering = true;
if (this.terrainCenter) {
drawing += " 0 ";
this.makeCurrent(0);
this.redrawSurface();
}
if (this.terrainRight) {
drawing += " 1 ";
this.makeCurrent(1);
this.redrawSurface();
}
if (this.terrainLeft) {
drawing += " -1 ";
this.makeCurrent(-1);
this.redrawSurface();
}
}
this.drawScreenRenderables();
};
WorldWindow.prototype.pick2DContiguous = function () {
if (this.terrainCenter) {
this.makeCurrent(0);
this.deferOrderedRendering = this.terrainLeft || this.terrainRight;
this.doPick();
}
if (this.terrainRight) {
this.makeCurrent(1);
this.deferOrderedRendering = this.terrainLeft || this.terrainLeft;
this.doPick();
}
this.deferOrderedRendering = false;
if (this.terrainLeft) {
this.makeCurrent(-1);
this.doPick();
}
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.drawLayers = function (accumulateOrderedRenderables) {
// Draw all the layers attached to this WorldWindow.
var beginTime = Date.now(),
dc = this.drawContext,
layers = dc.layers,
layer;
dc.accumulateOrderedRenderables = accumulateOrderedRenderables;
for (var i = 0, len = layers.length; i < len; i++) {
layer = layers[i];
if (layer) {
dc.currentLayer = layer;
try {
layer.render(dc);
} catch (e) {
Logger.log(Logger.LEVEL_SEVERE, "Error while rendering layer " + layer.displayName + ".\n"
+ e.toString());
// Keep going. Render the rest of the layers.
}
}
}
dc.currentLayer = null;
var now = Date.now();
dc.frameStatistics.layerRenderingTime = now - beginTime;
};
/**
* Adds a specified layer to the end of this WorldWindow.
* @param {Layer} layer The layer to add. May be null or undefined, in which case this WorldWindow is not
* modified.
*/
WorldWindow.prototype.addLayer = function (layer) {
if (layer) {
this.layers.push(layer);
}
};
/**
* Removes the first instance of a specified layer from this WorldWindow.
* @param {Layer} layer The layer to remove. May be null or undefined, in which case this WorldWindow is not
* modified. This WorldWindow is also not modified if the specified layer does not exist in this WorldWindow's
* layer list.
*/
WorldWindow.prototype.removeLayer = function (layer) {
var index = this.indexOfLayer(layer);
if (index >= 0) {
this.layers.splice(index, 1);
}
};
/**
* Inserts a specified layer at a specified position in this WorldWindow.
* @param {Number} index The index at which to insert the layer. May be negative to specify the position
* from the end of the array.
* @param {Layer} layer The layer to insert. May be null or undefined, in which case this WorldWindow is not
* modified.
*/
WorldWindow.prototype.insertLayer = function (index, layer) {
if (layer) {
this.layers.splice(index, 0, layer);
}
};
/**
* Returns the index of a specified layer in this WorldWindow.
* @param {Layer} layer The layer to search for.
* @returns {Number} The index of the specified layer or -1 if it doesn't exist in this WorldWindow.
*/
WorldWindow.prototype.indexOfLayer = function (layer) {
return this.layers.indexOf(layer);
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.drawSurfaceRenderables = function () {
var dc = this.drawContext,
sr;
dc.reverseSurfaceRenderables();
while (sr = dc.popSurfaceRenderable()) {
try {
sr.renderSurface(dc);
} catch (e) {
Logger.logMessage(Logger.LEVEL_WARNING, "WorldWindow", "drawSurfaceRenderables",
"Error while rendering a surface renderable.\n" + e.message);
// Keep going. Render the rest of the surface renderables.
}
}
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.drawOrderedRenderables = function () {
var beginTime = Date.now(),
dc = this.drawContext,
or;
dc.sortOrderedRenderables();
if (this._orderedRenderingFilters) {
for (var f = 0; f < this._orderedRenderingFilters.length; f++) {
this._orderedRenderingFilters[f](this.drawContext);
}
}
dc.orderedRenderingMode = true;
while (or = dc.popOrderedRenderable()) {
try {
or.renderOrdered(dc);
} catch (e) {
Logger.logMessage(Logger.LEVEL_WARNING, "WorldWindow", "drawOrderedRenderables",
"Error while rendering an ordered renderable.\n" + e.message);
// Keep going. Render the rest of the ordered renderables.
}
}
dc.orderedRenderingMode = false;
dc.frameStatistics.orderedRenderingTime = Date.now() - beginTime;
};
WorldWindow.prototype.drawScreenRenderables = function () {
var dc = this.drawContext,
or;
while (or = dc.nextScreenRenderable()) {
try {
or.renderOrdered(dc);
} catch (e) {
Logger.logMessage(Logger.LEVEL_WARNING, "WorldWindow", "drawOrderedRenderables",
"Error while rendering a screen renderable.\n" + e.message);
// Keep going. Render the rest of the screen renderables.
}
}
};
// Internal function. Intentionally not documented.
WorldWindow.prototype.resolveTopPick = function () {
if (this.drawContext.objectsAtPickPoint.objects.length == 0) {
return; // nothing picked; avoid calling readPickColor unnecessarily
}
// Make a last reading to determine what's on top.
var pickedObjects = this.drawContext.objectsAtPickPoint,
pickColor = this.drawContext.readPickColor(this.drawContext.pickPoint),
topObject = null,
terrainObject = null;
if (pickColor) {
// Find the picked object with the top color code and set its isOnTop flag.
for (var i = 0, len = pickedObjects.objects.length; i < len; i++) {
var po = pickedObjects.objects[i];
if (po.isTerrain) {
terrainObject = po;
}
if (po.color.equals(pickColor)) {
po.isOnTop = true;
topObject = po;
if (terrainObject) {
break; // no need to search for more than the top object and the terrain object
}
}
}
// In single-pick mode provide only the top-most object and the terrain object, if any.
if (!this.drawContext.deepPicking) {
pickedObjects.clear();
if (topObject) {
pickedObjects.add(topObject);
}
if (terrainObject && terrainObject != topObject) {
pickedObjects.add(terrainObject);
}
}
} else {
pickedObjects.clear(); // nothing drawn at the pick point
}
};
// Internal. Intentionally not documented.
WorldWindow.prototype.resolveTerrainPick = function () {
var pickedObjects = this.drawContext.objectsAtPickPoint,
po;
// Mark the first picked terrain object as "on top". The picked object list should contain only one entry
// indicating the picked terrain object, but we iterate over the list contents anyway.
for (var i = 0, len = pickedObjects.objects.length; i < len; i++) {
po = pickedObjects.objects[i];
if (po.isTerrain) {
po.isOnTop = true;
break;
}
}
};
// Internal. Intentionally not documented.
WorldWindow.prototype.resolveRegionPick = function () {
if (this.drawContext.objectsAtPickPoint.objects.length == 0) {
return; // nothing picked; avoid calling readPickColors unnecessarily
}
// Mark every picked object with a color in the pick buffer as "on top".
var pickedObjects = this.drawContext.objectsAtPickPoint,
uniquePickColors = this.drawContext.readPickColors(this.drawContext.pickRectangle),
po,
color;
for (var i = 0, len = pickedObjects.objects.length; i < len; i++) {
po = pickedObjects.objects[i];
if (!po) continue;
var poColor = po.color.toByteString();
color = uniquePickColors[poColor];
if (color) {
po.isOnTop = true;
} else if (po.userObject instanceof SurfaceShape) {
// SurfaceShapes ALWAYS get added to the pick list, since their rendering is deferred
// until the tile they are cached by is rendered. So a SurfaceShape may be in the pick list
// but is not seen in the pick rectangle.
//
// Remove the SurfaceShape that was not visible to the pick rectangle.
pickedObjects.objects.splice(i, 1);
i -= 1;
}
}
};
// Internal. Intentionally not documented.
WorldWindow.prototype.callRedrawCallbacks = function (stage) {
for (var i = 0, len = this._redrawCallbacks.length; i < len; i++) {
try {
this._redrawCallbacks[i](this, stage);
} catch (e) {
Logger.log(Logger.LEVEL_SEVERE, "Exception calling redraw callback.\n" + e.toString());
// Keep going. Execute the rest of the callbacks.
}
}
};
/**
* Moves this WorldWindow's navigator to a specified location or position.
* @param {Location | Position} position The location or position to move the navigator to. If this
* argument contains an "altitude" property, as {@link Position} does, the end point of the navigation is
* at the specified altitude. Otherwise the end point is at the current altitude of the navigator.
*
* This function uses this WorldWindow's {@link GoToAnimator} property to perform the move. That object's
* properties can be specified by the application to modify its behavior during calls to this function.
* It's cancel method can also be used to cancel the move initiated by this function.
* @param {Function} completionCallback If not null or undefined, specifies a function to call when the
* animation completes. The completion callback is called with a single argument, this animator.
* @throws {ArgumentError} If the specified location or position is null or undefined.
*/
WorldWindow.prototype.goTo = function (position, completionCallback) {
this.goToAnimator.goTo(position, completionCallback);
};
/**
* Declutters the current ordered renderables with a specified group ID. This function is not called by
* applications directly. It's meant to be invoked as an ordered rendering filter in this WorldWindow's
* [orderedRenderingFilters]{@link WorldWindow#orderedRenderingFilters} property.
* <p>
* The function operates by setting the target visibility of occluded shapes to 0 and unoccluded shapes to 1.
* @param {DrawContext} dc The current draw context.
* @param {Number} groupId The ID of the group to declutter. Must not be null, undefined or 0.
* @throws {ArgumentError} If the specified group ID is null, undefined or 0.
*/
WorldWindow.prototype.declutter = function (dc, groupId) {
if (!groupId) {
throw new ArgumentError(
Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "declutter",
"Group ID is null, undefined or 0."));
}
// Collect all the declutterables in the specified group.
var declutterables = [];
for (var i = 0; i < dc.orderedRenderables.length; i++) {
var orderedRenderable = dc.orderedRenderables[i].orderedRenderable;
if (orderedRenderable.declutterGroup === groupId) {
declutterables.push(orderedRenderable);
}
}
// Filter the declutterables by determining which are partially occluded. Since the ordered renderable
// list was already sorted from front to back, the front-most will represent an entire occluded group.
var rects = [];
for (var j = 0; j < declutterables.length; j++) {
var declutterable = declutterables[j],
screenBounds = declutterable.screenBounds;
if (screenBounds && screenBounds.intersectsRectangles(rects)) {
declutterable.targetVisibility = 0;
} else {
declutterable.targetVisibility = 1;
if (screenBounds) {
rects.push(screenBounds);
}
}
}
};
/**
* Computes a ray originating at the eyePoint and extending through the specified point in window
* coordinates.
* <p>
* The specified point is understood to be in the window coordinate system of the WorldWindow, with the origin
* in the top-left corner and axes that extend down and to the right from the origin point.
* <p>
* The results of this method are undefined if the specified point is outside of the WorldWindow's
* bounds.
*
* @param {Vec2} point The window coordinates point to compute a ray for.
* @returns {Line} A new Line initialized to the origin and direction of the computed ray, or null if the
* ray could not be computed.
*/
WorldWindow.prototype.rayThroughScreenPoint = function (point) {
if (!point) {
throw new ArgumentError(Logger.logMessage(Logger.LEVEL_SEVERE, "WorldWindow", "rayThroughScreenPoint",
"missingPoint"));
}
// Convert the point's xy coordinates from window coordinates to WebGL screen coordinates.
var screenPoint = new Vec3(point[0], this.viewport.height - point[1], 0),
nearPoint = new Vec3(0, 0, 0),
farPoint = new Vec3(0, 0, 0);
this.computeViewingTransform(this.scratchProjection, this.scratchModelview);
var modelviewProjection = Matrix.fromIdentity();
modelviewProjection.setToMultiply(this.scratchProjection, this.scratchModelview);
var modelviewProjectionInv = Matrix.fromIdentity();
modelviewProjectionInv.invertMatrix(modelviewProjection);
// Compute the model coordinate point on the near clip plane with the xy coordinates and depth 0.
if (!modelviewProjectionInv.unProject(screenPoint, this.viewport, nearPoint)) {
return null;
}
// Compute the model coordinate point on the far clip plane with the xy coordinates and depth 1.
screenPoint[2] = 1;
if (!modelviewProjectionInv.unProject(screenPoint, this.viewport, farPoint)) {
return null;
}
var eyePoint = this.scratchModelview.extractEyePoint(new Vec3(0, 0, 0));
// Compute a ray originating at the eye point and with direction pointing from the xy coordinate on the near
// plane to the same xy coordinate on the far plane.
var origin = new Vec3(eyePoint[0], eyePoint[1], eyePoint[2]),
direction = new Vec3(farPoint[0], farPoint[1], farPoint[2]);
direction.subtract(nearPoint);
direction.normalize();
return new Line(origin, direction);
};
return WorldWindow;
}
);