Agriculture-front-end/public/CesiumUnminified/Workers/chunk-C5CE4OG6.js

2829 lines
92 KiB
JavaScript
Raw Normal View History

/**
* @license
* Cesium - https://github.com/CesiumGS/cesium
* Version 1.117
*
* Copyright 2011-2022 Cesium Contributors
*
* 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.
*
* Columbus View (Pat. Pend.)
*
* Portions licensed separately.
* See https://github.com/CesiumGS/cesium/blob/main/LICENSE.md for full licensing details.
*/
import {
Math_default
} from "./chunk-4PHPQRSH.js";
import {
defaultValue_default
} from "./chunk-UCPPWV64.js";
import {
Check_default,
DeveloperError_default
} from "./chunk-U4IMCOF5.js";
import {
defined_default
} from "./chunk-BDUJXBVF.js";
// packages/engine/Source/Core/Cartesian3.js
function Cartesian3(x, y, z) {
this.x = defaultValue_default(x, 0);
this.y = defaultValue_default(y, 0);
this.z = defaultValue_default(z, 0);
}
Cartesian3.fromSpherical = function(spherical, result) {
Check_default.typeOf.object("spherical", spherical);
if (!defined_default(result)) {
result = new Cartesian3();
}
const clock = spherical.clock;
const cone = spherical.cone;
const magnitude = defaultValue_default(spherical.magnitude, 1);
const radial = magnitude * Math.sin(cone);
result.x = radial * Math.cos(clock);
result.y = radial * Math.sin(clock);
result.z = magnitude * Math.cos(cone);
return result;
};
Cartesian3.fromElements = function(x, y, z, result) {
if (!defined_default(result)) {
return new Cartesian3(x, y, z);
}
result.x = x;
result.y = y;
result.z = z;
return result;
};
Cartesian3.clone = function(cartesian, result) {
if (!defined_default(cartesian)) {
return void 0;
}
if (!defined_default(result)) {
return new Cartesian3(cartesian.x, cartesian.y, cartesian.z);
}
result.x = cartesian.x;
result.y = cartesian.y;
result.z = cartesian.z;
return result;
};
Cartesian3.fromCartesian4 = Cartesian3.clone;
Cartesian3.packedLength = 3;
Cartesian3.pack = function(value, array, startingIndex) {
Check_default.typeOf.object("value", value);
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
array[startingIndex++] = value.x;
array[startingIndex++] = value.y;
array[startingIndex] = value.z;
return array;
};
Cartesian3.unpack = function(array, startingIndex, result) {
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
if (!defined_default(result)) {
result = new Cartesian3();
}
result.x = array[startingIndex++];
result.y = array[startingIndex++];
result.z = array[startingIndex];
return result;
};
Cartesian3.packArray = function(array, result) {
Check_default.defined("array", array);
const length = array.length;
const resultLength = length * 3;
if (!defined_default(result)) {
result = new Array(resultLength);
} else if (!Array.isArray(result) && result.length !== resultLength) {
throw new DeveloperError_default(
"If result is a typed array, it must have exactly array.length * 3 elements"
);
} else if (result.length !== resultLength) {
result.length = resultLength;
}
for (let i = 0; i < length; ++i) {
Cartesian3.pack(array[i], result, i * 3);
}
return result;
};
Cartesian3.unpackArray = function(array, result) {
Check_default.defined("array", array);
Check_default.typeOf.number.greaterThanOrEquals("array.length", array.length, 3);
if (array.length % 3 !== 0) {
throw new DeveloperError_default("array length must be a multiple of 3.");
}
const length = array.length;
if (!defined_default(result)) {
result = new Array(length / 3);
} else {
result.length = length / 3;
}
for (let i = 0; i < length; i += 3) {
const index = i / 3;
result[index] = Cartesian3.unpack(array, i, result[index]);
}
return result;
};
Cartesian3.fromArray = Cartesian3.unpack;
Cartesian3.maximumComponent = function(cartesian) {
Check_default.typeOf.object("cartesian", cartesian);
return Math.max(cartesian.x, cartesian.y, cartesian.z);
};
Cartesian3.minimumComponent = function(cartesian) {
Check_default.typeOf.object("cartesian", cartesian);
return Math.min(cartesian.x, cartesian.y, cartesian.z);
};
Cartesian3.minimumByComponent = function(first, second, result) {
Check_default.typeOf.object("first", first);
Check_default.typeOf.object("second", second);
Check_default.typeOf.object("result", result);
result.x = Math.min(first.x, second.x);
result.y = Math.min(first.y, second.y);
result.z = Math.min(first.z, second.z);
return result;
};
Cartesian3.maximumByComponent = function(first, second, result) {
Check_default.typeOf.object("first", first);
Check_default.typeOf.object("second", second);
Check_default.typeOf.object("result", result);
result.x = Math.max(first.x, second.x);
result.y = Math.max(first.y, second.y);
result.z = Math.max(first.z, second.z);
return result;
};
Cartesian3.clamp = function(value, min, max, result) {
Check_default.typeOf.object("value", value);
Check_default.typeOf.object("min", min);
Check_default.typeOf.object("max", max);
Check_default.typeOf.object("result", result);
const x = Math_default.clamp(value.x, min.x, max.x);
const y = Math_default.clamp(value.y, min.y, max.y);
const z = Math_default.clamp(value.z, min.z, max.z);
result.x = x;
result.y = y;
result.z = z;
return result;
};
Cartesian3.magnitudeSquared = function(cartesian) {
Check_default.typeOf.object("cartesian", cartesian);
return cartesian.x * cartesian.x + cartesian.y * cartesian.y + cartesian.z * cartesian.z;
};
Cartesian3.magnitude = function(cartesian) {
return Math.sqrt(Cartesian3.magnitudeSquared(cartesian));
};
var distanceScratch = new Cartesian3();
Cartesian3.distance = function(left, right) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Cartesian3.subtract(left, right, distanceScratch);
return Cartesian3.magnitude(distanceScratch);
};
Cartesian3.distanceSquared = function(left, right) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Cartesian3.subtract(left, right, distanceScratch);
return Cartesian3.magnitudeSquared(distanceScratch);
};
Cartesian3.normalize = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
const magnitude = Cartesian3.magnitude(cartesian);
result.x = cartesian.x / magnitude;
result.y = cartesian.y / magnitude;
result.z = cartesian.z / magnitude;
if (isNaN(result.x) || isNaN(result.y) || isNaN(result.z)) {
throw new DeveloperError_default("normalized result is not a number");
}
return result;
};
Cartesian3.dot = function(left, right) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
return left.x * right.x + left.y * right.y + left.z * right.z;
};
Cartesian3.multiplyComponents = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result.x = left.x * right.x;
result.y = left.y * right.y;
result.z = left.z * right.z;
return result;
};
Cartesian3.divideComponents = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result.x = left.x / right.x;
result.y = left.y / right.y;
result.z = left.z / right.z;
return result;
};
Cartesian3.add = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result.x = left.x + right.x;
result.y = left.y + right.y;
result.z = left.z + right.z;
return result;
};
Cartesian3.subtract = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result.x = left.x - right.x;
result.y = left.y - right.y;
result.z = left.z - right.z;
return result;
};
Cartesian3.multiplyByScalar = function(cartesian, scalar, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.number("scalar", scalar);
Check_default.typeOf.object("result", result);
result.x = cartesian.x * scalar;
result.y = cartesian.y * scalar;
result.z = cartesian.z * scalar;
return result;
};
Cartesian3.divideByScalar = function(cartesian, scalar, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.number("scalar", scalar);
Check_default.typeOf.object("result", result);
result.x = cartesian.x / scalar;
result.y = cartesian.y / scalar;
result.z = cartesian.z / scalar;
return result;
};
Cartesian3.negate = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
result.x = -cartesian.x;
result.y = -cartesian.y;
result.z = -cartesian.z;
return result;
};
Cartesian3.abs = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
result.x = Math.abs(cartesian.x);
result.y = Math.abs(cartesian.y);
result.z = Math.abs(cartesian.z);
return result;
};
var lerpScratch = new Cartesian3();
Cartesian3.lerp = function(start, end, t, result) {
Check_default.typeOf.object("start", start);
Check_default.typeOf.object("end", end);
Check_default.typeOf.number("t", t);
Check_default.typeOf.object("result", result);
Cartesian3.multiplyByScalar(end, t, lerpScratch);
result = Cartesian3.multiplyByScalar(start, 1 - t, result);
return Cartesian3.add(lerpScratch, result, result);
};
var angleBetweenScratch = new Cartesian3();
var angleBetweenScratch2 = new Cartesian3();
Cartesian3.angleBetween = function(left, right) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Cartesian3.normalize(left, angleBetweenScratch);
Cartesian3.normalize(right, angleBetweenScratch2);
const cosine = Cartesian3.dot(angleBetweenScratch, angleBetweenScratch2);
const sine = Cartesian3.magnitude(
Cartesian3.cross(
angleBetweenScratch,
angleBetweenScratch2,
angleBetweenScratch
)
);
return Math.atan2(sine, cosine);
};
var mostOrthogonalAxisScratch = new Cartesian3();
Cartesian3.mostOrthogonalAxis = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
const f = Cartesian3.normalize(cartesian, mostOrthogonalAxisScratch);
Cartesian3.abs(f, f);
if (f.x <= f.y) {
if (f.x <= f.z) {
result = Cartesian3.clone(Cartesian3.UNIT_X, result);
} else {
result = Cartesian3.clone(Cartesian3.UNIT_Z, result);
}
} else if (f.y <= f.z) {
result = Cartesian3.clone(Cartesian3.UNIT_Y, result);
} else {
result = Cartesian3.clone(Cartesian3.UNIT_Z, result);
}
return result;
};
Cartesian3.projectVector = function(a, b, result) {
Check_default.defined("a", a);
Check_default.defined("b", b);
Check_default.defined("result", result);
const scalar = Cartesian3.dot(a, b) / Cartesian3.dot(b, b);
return Cartesian3.multiplyByScalar(b, scalar, result);
};
Cartesian3.equals = function(left, right) {
return left === right || defined_default(left) && defined_default(right) && left.x === right.x && left.y === right.y && left.z === right.z;
};
Cartesian3.equalsArray = function(cartesian, array, offset) {
return cartesian.x === array[offset] && cartesian.y === array[offset + 1] && cartesian.z === array[offset + 2];
};
Cartesian3.equalsEpsilon = function(left, right, relativeEpsilon, absoluteEpsilon) {
return left === right || defined_default(left) && defined_default(right) && Math_default.equalsEpsilon(
left.x,
right.x,
relativeEpsilon,
absoluteEpsilon
) && Math_default.equalsEpsilon(
left.y,
right.y,
relativeEpsilon,
absoluteEpsilon
) && Math_default.equalsEpsilon(
left.z,
right.z,
relativeEpsilon,
absoluteEpsilon
);
};
Cartesian3.cross = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
const leftX = left.x;
const leftY = left.y;
const leftZ = left.z;
const rightX = right.x;
const rightY = right.y;
const rightZ = right.z;
const x = leftY * rightZ - leftZ * rightY;
const y = leftZ * rightX - leftX * rightZ;
const z = leftX * rightY - leftY * rightX;
result.x = x;
result.y = y;
result.z = z;
return result;
};
Cartesian3.midpoint = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result.x = (left.x + right.x) * 0.5;
result.y = (left.y + right.y) * 0.5;
result.z = (left.z + right.z) * 0.5;
return result;
};
Cartesian3.fromDegrees = function(longitude, latitude, height, ellipsoid, result) {
Check_default.typeOf.number("longitude", longitude);
Check_default.typeOf.number("latitude", latitude);
longitude = Math_default.toRadians(longitude);
latitude = Math_default.toRadians(latitude);
return Cartesian3.fromRadians(longitude, latitude, height, ellipsoid, result);
};
var scratchN = new Cartesian3();
var scratchK = new Cartesian3();
var wgs84RadiiSquared = new Cartesian3(
6378137 * 6378137,
6378137 * 6378137,
6356752314245179e-9 * 6356752314245179e-9
);
Cartesian3.fromRadians = function(longitude, latitude, height, ellipsoid, result) {
Check_default.typeOf.number("longitude", longitude);
Check_default.typeOf.number("latitude", latitude);
height = defaultValue_default(height, 0);
const radiiSquared = defined_default(ellipsoid) ? ellipsoid.radiiSquared : wgs84RadiiSquared;
const cosLatitude = Math.cos(latitude);
scratchN.x = cosLatitude * Math.cos(longitude);
scratchN.y = cosLatitude * Math.sin(longitude);
scratchN.z = Math.sin(latitude);
scratchN = Cartesian3.normalize(scratchN, scratchN);
Cartesian3.multiplyComponents(radiiSquared, scratchN, scratchK);
const gamma = Math.sqrt(Cartesian3.dot(scratchN, scratchK));
scratchK = Cartesian3.divideByScalar(scratchK, gamma, scratchK);
scratchN = Cartesian3.multiplyByScalar(scratchN, height, scratchN);
if (!defined_default(result)) {
result = new Cartesian3();
}
return Cartesian3.add(scratchK, scratchN, result);
};
Cartesian3.fromDegreesArray = function(coordinates, ellipsoid, result) {
Check_default.defined("coordinates", coordinates);
if (coordinates.length < 2 || coordinates.length % 2 !== 0) {
throw new DeveloperError_default(
"the number of coordinates must be a multiple of 2 and at least 2"
);
}
const length = coordinates.length;
if (!defined_default(result)) {
result = new Array(length / 2);
} else {
result.length = length / 2;
}
for (let i = 0; i < length; i += 2) {
const longitude = coordinates[i];
const latitude = coordinates[i + 1];
const index = i / 2;
result[index] = Cartesian3.fromDegrees(
longitude,
latitude,
0,
ellipsoid,
result[index]
);
}
return result;
};
Cartesian3.fromRadiansArray = function(coordinates, ellipsoid, result) {
Check_default.defined("coordinates", coordinates);
if (coordinates.length < 2 || coordinates.length % 2 !== 0) {
throw new DeveloperError_default(
"the number of coordinates must be a multiple of 2 and at least 2"
);
}
const length = coordinates.length;
if (!defined_default(result)) {
result = new Array(length / 2);
} else {
result.length = length / 2;
}
for (let i = 0; i < length; i += 2) {
const longitude = coordinates[i];
const latitude = coordinates[i + 1];
const index = i / 2;
result[index] = Cartesian3.fromRadians(
longitude,
latitude,
0,
ellipsoid,
result[index]
);
}
return result;
};
Cartesian3.fromDegreesArrayHeights = function(coordinates, ellipsoid, result) {
Check_default.defined("coordinates", coordinates);
if (coordinates.length < 3 || coordinates.length % 3 !== 0) {
throw new DeveloperError_default(
"the number of coordinates must be a multiple of 3 and at least 3"
);
}
const length = coordinates.length;
if (!defined_default(result)) {
result = new Array(length / 3);
} else {
result.length = length / 3;
}
for (let i = 0; i < length; i += 3) {
const longitude = coordinates[i];
const latitude = coordinates[i + 1];
const height = coordinates[i + 2];
const index = i / 3;
result[index] = Cartesian3.fromDegrees(
longitude,
latitude,
height,
ellipsoid,
result[index]
);
}
return result;
};
Cartesian3.fromRadiansArrayHeights = function(coordinates, ellipsoid, result) {
Check_default.defined("coordinates", coordinates);
if (coordinates.length < 3 || coordinates.length % 3 !== 0) {
throw new DeveloperError_default(
"the number of coordinates must be a multiple of 3 and at least 3"
);
}
const length = coordinates.length;
if (!defined_default(result)) {
result = new Array(length / 3);
} else {
result.length = length / 3;
}
for (let i = 0; i < length; i += 3) {
const longitude = coordinates[i];
const latitude = coordinates[i + 1];
const height = coordinates[i + 2];
const index = i / 3;
result[index] = Cartesian3.fromRadians(
longitude,
latitude,
height,
ellipsoid,
result[index]
);
}
return result;
};
Cartesian3.ZERO = Object.freeze(new Cartesian3(0, 0, 0));
Cartesian3.ONE = Object.freeze(new Cartesian3(1, 1, 1));
Cartesian3.UNIT_X = Object.freeze(new Cartesian3(1, 0, 0));
Cartesian3.UNIT_Y = Object.freeze(new Cartesian3(0, 1, 0));
Cartesian3.UNIT_Z = Object.freeze(new Cartesian3(0, 0, 1));
Cartesian3.prototype.clone = function(result) {
return Cartesian3.clone(this, result);
};
Cartesian3.prototype.equals = function(right) {
return Cartesian3.equals(this, right);
};
Cartesian3.prototype.equalsEpsilon = function(right, relativeEpsilon, absoluteEpsilon) {
return Cartesian3.equalsEpsilon(
this,
right,
relativeEpsilon,
absoluteEpsilon
);
};
Cartesian3.prototype.toString = function() {
return `(${this.x}, ${this.y}, ${this.z})`;
};
var Cartesian3_default = Cartesian3;
// packages/engine/Source/Core/scaleToGeodeticSurface.js
var scaleToGeodeticSurfaceIntersection = new Cartesian3_default();
var scaleToGeodeticSurfaceGradient = new Cartesian3_default();
function scaleToGeodeticSurface(cartesian, oneOverRadii, oneOverRadiiSquared, centerToleranceSquared, result) {
if (!defined_default(cartesian)) {
throw new DeveloperError_default("cartesian is required.");
}
if (!defined_default(oneOverRadii)) {
throw new DeveloperError_default("oneOverRadii is required.");
}
if (!defined_default(oneOverRadiiSquared)) {
throw new DeveloperError_default("oneOverRadiiSquared is required.");
}
if (!defined_default(centerToleranceSquared)) {
throw new DeveloperError_default("centerToleranceSquared is required.");
}
const positionX = cartesian.x;
const positionY = cartesian.y;
const positionZ = cartesian.z;
const oneOverRadiiX = oneOverRadii.x;
const oneOverRadiiY = oneOverRadii.y;
const oneOverRadiiZ = oneOverRadii.z;
const x2 = positionX * positionX * oneOverRadiiX * oneOverRadiiX;
const y2 = positionY * positionY * oneOverRadiiY * oneOverRadiiY;
const z2 = positionZ * positionZ * oneOverRadiiZ * oneOverRadiiZ;
const squaredNorm = x2 + y2 + z2;
const ratio = Math.sqrt(1 / squaredNorm);
const intersection = Cartesian3_default.multiplyByScalar(
cartesian,
ratio,
scaleToGeodeticSurfaceIntersection
);
if (squaredNorm < centerToleranceSquared) {
return !isFinite(ratio) ? void 0 : Cartesian3_default.clone(intersection, result);
}
const oneOverRadiiSquaredX = oneOverRadiiSquared.x;
const oneOverRadiiSquaredY = oneOverRadiiSquared.y;
const oneOverRadiiSquaredZ = oneOverRadiiSquared.z;
const gradient = scaleToGeodeticSurfaceGradient;
gradient.x = intersection.x * oneOverRadiiSquaredX * 2;
gradient.y = intersection.y * oneOverRadiiSquaredY * 2;
gradient.z = intersection.z * oneOverRadiiSquaredZ * 2;
let lambda = (1 - ratio) * Cartesian3_default.magnitude(cartesian) / (0.5 * Cartesian3_default.magnitude(gradient));
let correction = 0;
let func;
let denominator;
let xMultiplier;
let yMultiplier;
let zMultiplier;
let xMultiplier2;
let yMultiplier2;
let zMultiplier2;
let xMultiplier3;
let yMultiplier3;
let zMultiplier3;
do {
lambda -= correction;
xMultiplier = 1 / (1 + lambda * oneOverRadiiSquaredX);
yMultiplier = 1 / (1 + lambda * oneOverRadiiSquaredY);
zMultiplier = 1 / (1 + lambda * oneOverRadiiSquaredZ);
xMultiplier2 = xMultiplier * xMultiplier;
yMultiplier2 = yMultiplier * yMultiplier;
zMultiplier2 = zMultiplier * zMultiplier;
xMultiplier3 = xMultiplier2 * xMultiplier;
yMultiplier3 = yMultiplier2 * yMultiplier;
zMultiplier3 = zMultiplier2 * zMultiplier;
func = x2 * xMultiplier2 + y2 * yMultiplier2 + z2 * zMultiplier2 - 1;
denominator = x2 * xMultiplier3 * oneOverRadiiSquaredX + y2 * yMultiplier3 * oneOverRadiiSquaredY + z2 * zMultiplier3 * oneOverRadiiSquaredZ;
const derivative = -2 * denominator;
correction = func / derivative;
} while (Math.abs(func) > Math_default.EPSILON12);
if (!defined_default(result)) {
return new Cartesian3_default(
positionX * xMultiplier,
positionY * yMultiplier,
positionZ * zMultiplier
);
}
result.x = positionX * xMultiplier;
result.y = positionY * yMultiplier;
result.z = positionZ * zMultiplier;
return result;
}
var scaleToGeodeticSurface_default = scaleToGeodeticSurface;
// packages/engine/Source/Core/Cartographic.js
function Cartographic(longitude, latitude, height) {
this.longitude = defaultValue_default(longitude, 0);
this.latitude = defaultValue_default(latitude, 0);
this.height = defaultValue_default(height, 0);
}
Cartographic.fromRadians = function(longitude, latitude, height, result) {
Check_default.typeOf.number("longitude", longitude);
Check_default.typeOf.number("latitude", latitude);
height = defaultValue_default(height, 0);
if (!defined_default(result)) {
return new Cartographic(longitude, latitude, height);
}
result.longitude = longitude;
result.latitude = latitude;
result.height = height;
return result;
};
Cartographic.fromDegrees = function(longitude, latitude, height, result) {
Check_default.typeOf.number("longitude", longitude);
Check_default.typeOf.number("latitude", latitude);
longitude = Math_default.toRadians(longitude);
latitude = Math_default.toRadians(latitude);
return Cartographic.fromRadians(longitude, latitude, height, result);
};
var cartesianToCartographicN = new Cartesian3_default();
var cartesianToCartographicP = new Cartesian3_default();
var cartesianToCartographicH = new Cartesian3_default();
var wgs84OneOverRadii = new Cartesian3_default(
1 / 6378137,
1 / 6378137,
1 / 6356752314245179e-9
);
var wgs84OneOverRadiiSquared = new Cartesian3_default(
1 / (6378137 * 6378137),
1 / (6378137 * 6378137),
1 / (6356752314245179e-9 * 6356752314245179e-9)
);
var wgs84CenterToleranceSquared = Math_default.EPSILON1;
Cartographic.fromCartesian = function(cartesian, ellipsoid, result) {
const oneOverRadii = defined_default(ellipsoid) ? ellipsoid.oneOverRadii : wgs84OneOverRadii;
const oneOverRadiiSquared = defined_default(ellipsoid) ? ellipsoid.oneOverRadiiSquared : wgs84OneOverRadiiSquared;
const centerToleranceSquared = defined_default(ellipsoid) ? ellipsoid._centerToleranceSquared : wgs84CenterToleranceSquared;
const p = scaleToGeodeticSurface_default(
cartesian,
oneOverRadii,
oneOverRadiiSquared,
centerToleranceSquared,
cartesianToCartographicP
);
if (!defined_default(p)) {
return void 0;
}
let n = Cartesian3_default.multiplyComponents(
p,
oneOverRadiiSquared,
cartesianToCartographicN
);
n = Cartesian3_default.normalize(n, n);
const h = Cartesian3_default.subtract(cartesian, p, cartesianToCartographicH);
const longitude = Math.atan2(n.y, n.x);
const latitude = Math.asin(n.z);
const height = Math_default.sign(Cartesian3_default.dot(h, cartesian)) * Cartesian3_default.magnitude(h);
if (!defined_default(result)) {
return new Cartographic(longitude, latitude, height);
}
result.longitude = longitude;
result.latitude = latitude;
result.height = height;
return result;
};
Cartographic.toCartesian = function(cartographic, ellipsoid, result) {
Check_default.defined("cartographic", cartographic);
return Cartesian3_default.fromRadians(
cartographic.longitude,
cartographic.latitude,
cartographic.height,
ellipsoid,
result
);
};
Cartographic.clone = function(cartographic, result) {
if (!defined_default(cartographic)) {
return void 0;
}
if (!defined_default(result)) {
return new Cartographic(
cartographic.longitude,
cartographic.latitude,
cartographic.height
);
}
result.longitude = cartographic.longitude;
result.latitude = cartographic.latitude;
result.height = cartographic.height;
return result;
};
Cartographic.equals = function(left, right) {
return left === right || defined_default(left) && defined_default(right) && left.longitude === right.longitude && left.latitude === right.latitude && left.height === right.height;
};
Cartographic.equalsEpsilon = function(left, right, epsilon) {
epsilon = defaultValue_default(epsilon, 0);
return left === right || defined_default(left) && defined_default(right) && Math.abs(left.longitude - right.longitude) <= epsilon && Math.abs(left.latitude - right.latitude) <= epsilon && Math.abs(left.height - right.height) <= epsilon;
};
Cartographic.ZERO = Object.freeze(new Cartographic(0, 0, 0));
Cartographic.prototype.clone = function(result) {
return Cartographic.clone(this, result);
};
Cartographic.prototype.equals = function(right) {
return Cartographic.equals(this, right);
};
Cartographic.prototype.equalsEpsilon = function(right, epsilon) {
return Cartographic.equalsEpsilon(this, right, epsilon);
};
Cartographic.prototype.toString = function() {
return `(${this.longitude}, ${this.latitude}, ${this.height})`;
};
var Cartographic_default = Cartographic;
// packages/engine/Source/Core/Cartesian2.js
function Cartesian2(x, y) {
this.x = defaultValue_default(x, 0);
this.y = defaultValue_default(y, 0);
}
Cartesian2.fromElements = function(x, y, result) {
if (!defined_default(result)) {
return new Cartesian2(x, y);
}
result.x = x;
result.y = y;
return result;
};
Cartesian2.clone = function(cartesian, result) {
if (!defined_default(cartesian)) {
return void 0;
}
if (!defined_default(result)) {
return new Cartesian2(cartesian.x, cartesian.y);
}
result.x = cartesian.x;
result.y = cartesian.y;
return result;
};
Cartesian2.fromCartesian3 = Cartesian2.clone;
Cartesian2.fromCartesian4 = Cartesian2.clone;
Cartesian2.packedLength = 2;
Cartesian2.pack = function(value, array, startingIndex) {
Check_default.typeOf.object("value", value);
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
array[startingIndex++] = value.x;
array[startingIndex] = value.y;
return array;
};
Cartesian2.unpack = function(array, startingIndex, result) {
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
if (!defined_default(result)) {
result = new Cartesian2();
}
result.x = array[startingIndex++];
result.y = array[startingIndex];
return result;
};
Cartesian2.packArray = function(array, result) {
Check_default.defined("array", array);
const length = array.length;
const resultLength = length * 2;
if (!defined_default(result)) {
result = new Array(resultLength);
} else if (!Array.isArray(result) && result.length !== resultLength) {
throw new DeveloperError_default(
"If result is a typed array, it must have exactly array.length * 2 elements"
);
} else if (result.length !== resultLength) {
result.length = resultLength;
}
for (let i = 0; i < length; ++i) {
Cartesian2.pack(array[i], result, i * 2);
}
return result;
};
Cartesian2.unpackArray = function(array, result) {
Check_default.defined("array", array);
Check_default.typeOf.number.greaterThanOrEquals("array.length", array.length, 2);
if (array.length % 2 !== 0) {
throw new DeveloperError_default("array length must be a multiple of 2.");
}
const length = array.length;
if (!defined_default(result)) {
result = new Array(length / 2);
} else {
result.length = length / 2;
}
for (let i = 0; i < length; i += 2) {
const index = i / 2;
result[index] = Cartesian2.unpack(array, i, result[index]);
}
return result;
};
Cartesian2.fromArray = Cartesian2.unpack;
Cartesian2.maximumComponent = function(cartesian) {
Check_default.typeOf.object("cartesian", cartesian);
return Math.max(cartesian.x, cartesian.y);
};
Cartesian2.minimumComponent = function(cartesian) {
Check_default.typeOf.object("cartesian", cartesian);
return Math.min(cartesian.x, cartesian.y);
};
Cartesian2.minimumByComponent = function(first, second, result) {
Check_default.typeOf.object("first", first);
Check_default.typeOf.object("second", second);
Check_default.typeOf.object("result", result);
result.x = Math.min(first.x, second.x);
result.y = Math.min(first.y, second.y);
return result;
};
Cartesian2.maximumByComponent = function(first, second, result) {
Check_default.typeOf.object("first", first);
Check_default.typeOf.object("second", second);
Check_default.typeOf.object("result", result);
result.x = Math.max(first.x, second.x);
result.y = Math.max(first.y, second.y);
return result;
};
Cartesian2.clamp = function(value, min, max, result) {
Check_default.typeOf.object("value", value);
Check_default.typeOf.object("min", min);
Check_default.typeOf.object("max", max);
Check_default.typeOf.object("result", result);
const x = Math_default.clamp(value.x, min.x, max.x);
const y = Math_default.clamp(value.y, min.y, max.y);
result.x = x;
result.y = y;
return result;
};
Cartesian2.magnitudeSquared = function(cartesian) {
Check_default.typeOf.object("cartesian", cartesian);
return cartesian.x * cartesian.x + cartesian.y * cartesian.y;
};
Cartesian2.magnitude = function(cartesian) {
return Math.sqrt(Cartesian2.magnitudeSquared(cartesian));
};
var distanceScratch2 = new Cartesian2();
Cartesian2.distance = function(left, right) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Cartesian2.subtract(left, right, distanceScratch2);
return Cartesian2.magnitude(distanceScratch2);
};
Cartesian2.distanceSquared = function(left, right) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Cartesian2.subtract(left, right, distanceScratch2);
return Cartesian2.magnitudeSquared(distanceScratch2);
};
Cartesian2.normalize = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
const magnitude = Cartesian2.magnitude(cartesian);
result.x = cartesian.x / magnitude;
result.y = cartesian.y / magnitude;
if (isNaN(result.x) || isNaN(result.y)) {
throw new DeveloperError_default("normalized result is not a number");
}
return result;
};
Cartesian2.dot = function(left, right) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
return left.x * right.x + left.y * right.y;
};
Cartesian2.cross = function(left, right) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
return left.x * right.y - left.y * right.x;
};
Cartesian2.multiplyComponents = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result.x = left.x * right.x;
result.y = left.y * right.y;
return result;
};
Cartesian2.divideComponents = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result.x = left.x / right.x;
result.y = left.y / right.y;
return result;
};
Cartesian2.add = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result.x = left.x + right.x;
result.y = left.y + right.y;
return result;
};
Cartesian2.subtract = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result.x = left.x - right.x;
result.y = left.y - right.y;
return result;
};
Cartesian2.multiplyByScalar = function(cartesian, scalar, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.number("scalar", scalar);
Check_default.typeOf.object("result", result);
result.x = cartesian.x * scalar;
result.y = cartesian.y * scalar;
return result;
};
Cartesian2.divideByScalar = function(cartesian, scalar, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.number("scalar", scalar);
Check_default.typeOf.object("result", result);
result.x = cartesian.x / scalar;
result.y = cartesian.y / scalar;
return result;
};
Cartesian2.negate = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
result.x = -cartesian.x;
result.y = -cartesian.y;
return result;
};
Cartesian2.abs = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
result.x = Math.abs(cartesian.x);
result.y = Math.abs(cartesian.y);
return result;
};
var lerpScratch2 = new Cartesian2();
Cartesian2.lerp = function(start, end, t, result) {
Check_default.typeOf.object("start", start);
Check_default.typeOf.object("end", end);
Check_default.typeOf.number("t", t);
Check_default.typeOf.object("result", result);
Cartesian2.multiplyByScalar(end, t, lerpScratch2);
result = Cartesian2.multiplyByScalar(start, 1 - t, result);
return Cartesian2.add(lerpScratch2, result, result);
};
var angleBetweenScratch3 = new Cartesian2();
var angleBetweenScratch22 = new Cartesian2();
Cartesian2.angleBetween = function(left, right) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Cartesian2.normalize(left, angleBetweenScratch3);
Cartesian2.normalize(right, angleBetweenScratch22);
return Math_default.acosClamped(
Cartesian2.dot(angleBetweenScratch3, angleBetweenScratch22)
);
};
var mostOrthogonalAxisScratch2 = new Cartesian2();
Cartesian2.mostOrthogonalAxis = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
const f = Cartesian2.normalize(cartesian, mostOrthogonalAxisScratch2);
Cartesian2.abs(f, f);
if (f.x <= f.y) {
result = Cartesian2.clone(Cartesian2.UNIT_X, result);
} else {
result = Cartesian2.clone(Cartesian2.UNIT_Y, result);
}
return result;
};
Cartesian2.equals = function(left, right) {
return left === right || defined_default(left) && defined_default(right) && left.x === right.x && left.y === right.y;
};
Cartesian2.equalsArray = function(cartesian, array, offset) {
return cartesian.x === array[offset] && cartesian.y === array[offset + 1];
};
Cartesian2.equalsEpsilon = function(left, right, relativeEpsilon, absoluteEpsilon) {
return left === right || defined_default(left) && defined_default(right) && Math_default.equalsEpsilon(
left.x,
right.x,
relativeEpsilon,
absoluteEpsilon
) && Math_default.equalsEpsilon(
left.y,
right.y,
relativeEpsilon,
absoluteEpsilon
);
};
Cartesian2.ZERO = Object.freeze(new Cartesian2(0, 0));
Cartesian2.ONE = Object.freeze(new Cartesian2(1, 1));
Cartesian2.UNIT_X = Object.freeze(new Cartesian2(1, 0));
Cartesian2.UNIT_Y = Object.freeze(new Cartesian2(0, 1));
Cartesian2.prototype.clone = function(result) {
return Cartesian2.clone(this, result);
};
Cartesian2.prototype.equals = function(right) {
return Cartesian2.equals(this, right);
};
Cartesian2.prototype.equalsEpsilon = function(right, relativeEpsilon, absoluteEpsilon) {
return Cartesian2.equalsEpsilon(
this,
right,
relativeEpsilon,
absoluteEpsilon
);
};
Cartesian2.prototype.toString = function() {
return `(${this.x}, ${this.y})`;
};
var Cartesian2_default = Cartesian2;
// packages/engine/Source/Core/Ellipsoid.js
function initialize(ellipsoid, x, y, z) {
x = defaultValue_default(x, 0);
y = defaultValue_default(y, 0);
z = defaultValue_default(z, 0);
Check_default.typeOf.number.greaterThanOrEquals("x", x, 0);
Check_default.typeOf.number.greaterThanOrEquals("y", y, 0);
Check_default.typeOf.number.greaterThanOrEquals("z", z, 0);
ellipsoid._radii = new Cartesian3_default(x, y, z);
ellipsoid._radiiSquared = new Cartesian3_default(x * x, y * y, z * z);
ellipsoid._radiiToTheFourth = new Cartesian3_default(
x * x * x * x,
y * y * y * y,
z * z * z * z
);
ellipsoid._oneOverRadii = new Cartesian3_default(
x === 0 ? 0 : 1 / x,
y === 0 ? 0 : 1 / y,
z === 0 ? 0 : 1 / z
);
ellipsoid._oneOverRadiiSquared = new Cartesian3_default(
x === 0 ? 0 : 1 / (x * x),
y === 0 ? 0 : 1 / (y * y),
z === 0 ? 0 : 1 / (z * z)
);
ellipsoid._minimumRadius = Math.min(x, y, z);
ellipsoid._maximumRadius = Math.max(x, y, z);
ellipsoid._centerToleranceSquared = Math_default.EPSILON1;
if (ellipsoid._radiiSquared.z !== 0) {
ellipsoid._squaredXOverSquaredZ = ellipsoid._radiiSquared.x / ellipsoid._radiiSquared.z;
}
}
function Ellipsoid(x, y, z) {
this._radii = void 0;
this._radiiSquared = void 0;
this._radiiToTheFourth = void 0;
this._oneOverRadii = void 0;
this._oneOverRadiiSquared = void 0;
this._minimumRadius = void 0;
this._maximumRadius = void 0;
this._centerToleranceSquared = void 0;
this._squaredXOverSquaredZ = void 0;
initialize(this, x, y, z);
}
Object.defineProperties(Ellipsoid.prototype, {
/**
* Gets the radii of the ellipsoid.
* @memberof Ellipsoid.prototype
* @type {Cartesian3}
* @readonly
*/
radii: {
get: function() {
return this._radii;
}
},
/**
* Gets the squared radii of the ellipsoid.
* @memberof Ellipsoid.prototype
* @type {Cartesian3}
* @readonly
*/
radiiSquared: {
get: function() {
return this._radiiSquared;
}
},
/**
* Gets the radii of the ellipsoid raise to the fourth power.
* @memberof Ellipsoid.prototype
* @type {Cartesian3}
* @readonly
*/
radiiToTheFourth: {
get: function() {
return this._radiiToTheFourth;
}
},
/**
* Gets one over the radii of the ellipsoid.
* @memberof Ellipsoid.prototype
* @type {Cartesian3}
* @readonly
*/
oneOverRadii: {
get: function() {
return this._oneOverRadii;
}
},
/**
* Gets one over the squared radii of the ellipsoid.
* @memberof Ellipsoid.prototype
* @type {Cartesian3}
* @readonly
*/
oneOverRadiiSquared: {
get: function() {
return this._oneOverRadiiSquared;
}
},
/**
* Gets the minimum radius of the ellipsoid.
* @memberof Ellipsoid.prototype
* @type {number}
* @readonly
*/
minimumRadius: {
get: function() {
return this._minimumRadius;
}
},
/**
* Gets the maximum radius of the ellipsoid.
* @memberof Ellipsoid.prototype
* @type {number}
* @readonly
*/
maximumRadius: {
get: function() {
return this._maximumRadius;
}
}
});
Ellipsoid.clone = function(ellipsoid, result) {
if (!defined_default(ellipsoid)) {
return void 0;
}
const radii = ellipsoid._radii;
if (!defined_default(result)) {
return new Ellipsoid(radii.x, radii.y, radii.z);
}
Cartesian3_default.clone(radii, result._radii);
Cartesian3_default.clone(ellipsoid._radiiSquared, result._radiiSquared);
Cartesian3_default.clone(ellipsoid._radiiToTheFourth, result._radiiToTheFourth);
Cartesian3_default.clone(ellipsoid._oneOverRadii, result._oneOverRadii);
Cartesian3_default.clone(ellipsoid._oneOverRadiiSquared, result._oneOverRadiiSquared);
result._minimumRadius = ellipsoid._minimumRadius;
result._maximumRadius = ellipsoid._maximumRadius;
result._centerToleranceSquared = ellipsoid._centerToleranceSquared;
return result;
};
Ellipsoid.fromCartesian3 = function(cartesian, result) {
if (!defined_default(result)) {
result = new Ellipsoid();
}
if (!defined_default(cartesian)) {
return result;
}
initialize(result, cartesian.x, cartesian.y, cartesian.z);
return result;
};
Ellipsoid.WGS84 = Object.freeze(
new Ellipsoid(6378137, 6378137, 6356752314245179e-9)
);
Ellipsoid.UNIT_SPHERE = Object.freeze(new Ellipsoid(1, 1, 1));
Ellipsoid.MOON = Object.freeze(
new Ellipsoid(
Math_default.LUNAR_RADIUS,
Math_default.LUNAR_RADIUS,
Math_default.LUNAR_RADIUS
)
);
Ellipsoid.prototype.clone = function(result) {
return Ellipsoid.clone(this, result);
};
Ellipsoid.packedLength = Cartesian3_default.packedLength;
Ellipsoid.pack = function(value, array, startingIndex) {
Check_default.typeOf.object("value", value);
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
Cartesian3_default.pack(value._radii, array, startingIndex);
return array;
};
Ellipsoid.unpack = function(array, startingIndex, result) {
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
const radii = Cartesian3_default.unpack(array, startingIndex);
return Ellipsoid.fromCartesian3(radii, result);
};
Ellipsoid.prototype.geocentricSurfaceNormal = Cartesian3_default.normalize;
Ellipsoid.prototype.geodeticSurfaceNormalCartographic = function(cartographic, result) {
Check_default.typeOf.object("cartographic", cartographic);
const longitude = cartographic.longitude;
const latitude = cartographic.latitude;
const cosLatitude = Math.cos(latitude);
const x = cosLatitude * Math.cos(longitude);
const y = cosLatitude * Math.sin(longitude);
const z = Math.sin(latitude);
if (!defined_default(result)) {
result = new Cartesian3_default();
}
result.x = x;
result.y = y;
result.z = z;
return Cartesian3_default.normalize(result, result);
};
Ellipsoid.prototype.geodeticSurfaceNormal = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
if (isNaN(cartesian.x) || isNaN(cartesian.y) || isNaN(cartesian.z)) {
throw new DeveloperError_default("cartesian has a NaN component");
}
if (Cartesian3_default.equalsEpsilon(cartesian, Cartesian3_default.ZERO, Math_default.EPSILON14)) {
return void 0;
}
if (!defined_default(result)) {
result = new Cartesian3_default();
}
result = Cartesian3_default.multiplyComponents(
cartesian,
this._oneOverRadiiSquared,
result
);
return Cartesian3_default.normalize(result, result);
};
var cartographicToCartesianNormal = new Cartesian3_default();
var cartographicToCartesianK = new Cartesian3_default();
Ellipsoid.prototype.cartographicToCartesian = function(cartographic, result) {
const n = cartographicToCartesianNormal;
const k = cartographicToCartesianK;
this.geodeticSurfaceNormalCartographic(cartographic, n);
Cartesian3_default.multiplyComponents(this._radiiSquared, n, k);
const gamma = Math.sqrt(Cartesian3_default.dot(n, k));
Cartesian3_default.divideByScalar(k, gamma, k);
Cartesian3_default.multiplyByScalar(n, cartographic.height, n);
if (!defined_default(result)) {
result = new Cartesian3_default();
}
return Cartesian3_default.add(k, n, result);
};
Ellipsoid.prototype.cartographicArrayToCartesianArray = function(cartographics, result) {
Check_default.defined("cartographics", cartographics);
const length = cartographics.length;
if (!defined_default(result)) {
result = new Array(length);
} else {
result.length = length;
}
for (let i = 0; i < length; i++) {
result[i] = this.cartographicToCartesian(cartographics[i], result[i]);
}
return result;
};
var cartesianToCartographicN2 = new Cartesian3_default();
var cartesianToCartographicP2 = new Cartesian3_default();
var cartesianToCartographicH2 = new Cartesian3_default();
Ellipsoid.prototype.cartesianToCartographic = function(cartesian, result) {
const p = this.scaleToGeodeticSurface(cartesian, cartesianToCartographicP2);
if (!defined_default(p)) {
return void 0;
}
const n = this.geodeticSurfaceNormal(p, cartesianToCartographicN2);
const h = Cartesian3_default.subtract(cartesian, p, cartesianToCartographicH2);
const longitude = Math.atan2(n.y, n.x);
const latitude = Math.asin(n.z);
const height = Math_default.sign(Cartesian3_default.dot(h, cartesian)) * Cartesian3_default.magnitude(h);
if (!defined_default(result)) {
return new Cartographic_default(longitude, latitude, height);
}
result.longitude = longitude;
result.latitude = latitude;
result.height = height;
return result;
};
Ellipsoid.prototype.cartesianArrayToCartographicArray = function(cartesians, result) {
Check_default.defined("cartesians", cartesians);
const length = cartesians.length;
if (!defined_default(result)) {
result = new Array(length);
} else {
result.length = length;
}
for (let i = 0; i < length; ++i) {
result[i] = this.cartesianToCartographic(cartesians[i], result[i]);
}
return result;
};
Ellipsoid.prototype.scaleToGeodeticSurface = function(cartesian, result) {
return scaleToGeodeticSurface_default(
cartesian,
this._oneOverRadii,
this._oneOverRadiiSquared,
this._centerToleranceSquared,
result
);
};
Ellipsoid.prototype.scaleToGeocentricSurface = function(cartesian, result) {
Check_default.typeOf.object("cartesian", cartesian);
if (!defined_default(result)) {
result = new Cartesian3_default();
}
const positionX = cartesian.x;
const positionY = cartesian.y;
const positionZ = cartesian.z;
const oneOverRadiiSquared = this._oneOverRadiiSquared;
const beta = 1 / Math.sqrt(
positionX * positionX * oneOverRadiiSquared.x + positionY * positionY * oneOverRadiiSquared.y + positionZ * positionZ * oneOverRadiiSquared.z
);
return Cartesian3_default.multiplyByScalar(cartesian, beta, result);
};
Ellipsoid.prototype.transformPositionToScaledSpace = function(position, result) {
if (!defined_default(result)) {
result = new Cartesian3_default();
}
return Cartesian3_default.multiplyComponents(position, this._oneOverRadii, result);
};
Ellipsoid.prototype.transformPositionFromScaledSpace = function(position, result) {
if (!defined_default(result)) {
result = new Cartesian3_default();
}
return Cartesian3_default.multiplyComponents(position, this._radii, result);
};
Ellipsoid.prototype.equals = function(right) {
return this === right || defined_default(right) && Cartesian3_default.equals(this._radii, right._radii);
};
Ellipsoid.prototype.toString = function() {
return this._radii.toString();
};
Ellipsoid.prototype.getSurfaceNormalIntersectionWithZAxis = function(position, buffer, result) {
Check_default.typeOf.object("position", position);
if (!Math_default.equalsEpsilon(
this._radii.x,
this._radii.y,
Math_default.EPSILON15
)) {
throw new DeveloperError_default(
"Ellipsoid must be an ellipsoid of revolution (radii.x == radii.y)"
);
}
Check_default.typeOf.number.greaterThan("Ellipsoid.radii.z", this._radii.z, 0);
buffer = defaultValue_default(buffer, 0);
const squaredXOverSquaredZ = this._squaredXOverSquaredZ;
if (!defined_default(result)) {
result = new Cartesian3_default();
}
result.x = 0;
result.y = 0;
result.z = position.z * (1 - squaredXOverSquaredZ);
if (Math.abs(result.z) >= this._radii.z - buffer) {
return void 0;
}
return result;
};
var scratchEndpoint = new Cartesian3_default();
Ellipsoid.prototype.getLocalCurvature = function(surfacePosition, result) {
Check_default.typeOf.object("surfacePosition", surfacePosition);
if (!defined_default(result)) {
result = new Cartesian2_default();
}
const primeVerticalEndpoint = this.getSurfaceNormalIntersectionWithZAxis(
surfacePosition,
0,
scratchEndpoint
);
const primeVerticalRadius = Cartesian3_default.distance(
surfacePosition,
primeVerticalEndpoint
);
const radiusRatio = this.minimumRadius * primeVerticalRadius / this.maximumRadius ** 2;
const meridionalRadius = primeVerticalRadius * radiusRatio ** 2;
return Cartesian2_default.fromElements(
1 / primeVerticalRadius,
1 / meridionalRadius,
result
);
};
var abscissas = [
0.14887433898163,
0.43339539412925,
0.67940956829902,
0.86506336668898,
0.97390652851717,
0
];
var weights = [
0.29552422471475,
0.26926671930999,
0.21908636251598,
0.14945134915058,
0.066671344308684,
0
];
function gaussLegendreQuadrature(a, b, func) {
Check_default.typeOf.number("a", a);
Check_default.typeOf.number("b", b);
Check_default.typeOf.func("func", func);
const xMean = 0.5 * (b + a);
const xRange = 0.5 * (b - a);
let sum = 0;
for (let i = 0; i < 5; i++) {
const dx = xRange * abscissas[i];
sum += weights[i] * (func(xMean + dx) + func(xMean - dx));
}
sum *= xRange;
return sum;
}
Ellipsoid.prototype.surfaceArea = function(rectangle) {
Check_default.typeOf.object("rectangle", rectangle);
const minLongitude = rectangle.west;
let maxLongitude = rectangle.east;
const minLatitude = rectangle.south;
const maxLatitude = rectangle.north;
while (maxLongitude < minLongitude) {
maxLongitude += Math_default.TWO_PI;
}
const radiiSquared = this._radiiSquared;
const a2 = radiiSquared.x;
const b2 = radiiSquared.y;
const c2 = radiiSquared.z;
const a2b2 = a2 * b2;
return gaussLegendreQuadrature(minLatitude, maxLatitude, function(lat) {
const sinPhi = Math.cos(lat);
const cosPhi = Math.sin(lat);
return Math.cos(lat) * gaussLegendreQuadrature(minLongitude, maxLongitude, function(lon) {
const cosTheta = Math.cos(lon);
const sinTheta = Math.sin(lon);
return Math.sqrt(
a2b2 * cosPhi * cosPhi + c2 * (b2 * cosTheta * cosTheta + a2 * sinTheta * sinTheta) * sinPhi * sinPhi
);
});
});
};
var Ellipsoid_default = Ellipsoid;
// packages/engine/Source/Core/Matrix3.js
function Matrix3(column0Row0, column1Row0, column2Row0, column0Row1, column1Row1, column2Row1, column0Row2, column1Row2, column2Row2) {
this[0] = defaultValue_default(column0Row0, 0);
this[1] = defaultValue_default(column0Row1, 0);
this[2] = defaultValue_default(column0Row2, 0);
this[3] = defaultValue_default(column1Row0, 0);
this[4] = defaultValue_default(column1Row1, 0);
this[5] = defaultValue_default(column1Row2, 0);
this[6] = defaultValue_default(column2Row0, 0);
this[7] = defaultValue_default(column2Row1, 0);
this[8] = defaultValue_default(column2Row2, 0);
}
Matrix3.packedLength = 9;
Matrix3.pack = function(value, array, startingIndex) {
Check_default.typeOf.object("value", value);
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
array[startingIndex++] = value[0];
array[startingIndex++] = value[1];
array[startingIndex++] = value[2];
array[startingIndex++] = value[3];
array[startingIndex++] = value[4];
array[startingIndex++] = value[5];
array[startingIndex++] = value[6];
array[startingIndex++] = value[7];
array[startingIndex++] = value[8];
return array;
};
Matrix3.unpack = function(array, startingIndex, result) {
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
if (!defined_default(result)) {
result = new Matrix3();
}
result[0] = array[startingIndex++];
result[1] = array[startingIndex++];
result[2] = array[startingIndex++];
result[3] = array[startingIndex++];
result[4] = array[startingIndex++];
result[5] = array[startingIndex++];
result[6] = array[startingIndex++];
result[7] = array[startingIndex++];
result[8] = array[startingIndex++];
return result;
};
Matrix3.packArray = function(array, result) {
Check_default.defined("array", array);
const length = array.length;
const resultLength = length * 9;
if (!defined_default(result)) {
result = new Array(resultLength);
} else if (!Array.isArray(result) && result.length !== resultLength) {
throw new DeveloperError_default(
"If result is a typed array, it must have exactly array.length * 9 elements"
);
} else if (result.length !== resultLength) {
result.length = resultLength;
}
for (let i = 0; i < length; ++i) {
Matrix3.pack(array[i], result, i * 9);
}
return result;
};
Matrix3.unpackArray = function(array, result) {
Check_default.defined("array", array);
Check_default.typeOf.number.greaterThanOrEquals("array.length", array.length, 9);
if (array.length % 9 !== 0) {
throw new DeveloperError_default("array length must be a multiple of 9.");
}
const length = array.length;
if (!defined_default(result)) {
result = new Array(length / 9);
} else {
result.length = length / 9;
}
for (let i = 0; i < length; i += 9) {
const index = i / 9;
result[index] = Matrix3.unpack(array, i, result[index]);
}
return result;
};
Matrix3.clone = function(matrix, result) {
if (!defined_default(matrix)) {
return void 0;
}
if (!defined_default(result)) {
return new Matrix3(
matrix[0],
matrix[3],
matrix[6],
matrix[1],
matrix[4],
matrix[7],
matrix[2],
matrix[5],
matrix[8]
);
}
result[0] = matrix[0];
result[1] = matrix[1];
result[2] = matrix[2];
result[3] = matrix[3];
result[4] = matrix[4];
result[5] = matrix[5];
result[6] = matrix[6];
result[7] = matrix[7];
result[8] = matrix[8];
return result;
};
Matrix3.fromArray = Matrix3.unpack;
Matrix3.fromColumnMajorArray = function(values, result) {
Check_default.defined("values", values);
return Matrix3.clone(values, result);
};
Matrix3.fromRowMajorArray = function(values, result) {
Check_default.defined("values", values);
if (!defined_default(result)) {
return new Matrix3(
values[0],
values[1],
values[2],
values[3],
values[4],
values[5],
values[6],
values[7],
values[8]
);
}
result[0] = values[0];
result[1] = values[3];
result[2] = values[6];
result[3] = values[1];
result[4] = values[4];
result[5] = values[7];
result[6] = values[2];
result[7] = values[5];
result[8] = values[8];
return result;
};
Matrix3.fromQuaternion = function(quaternion, result) {
Check_default.typeOf.object("quaternion", quaternion);
const x2 = quaternion.x * quaternion.x;
const xy = quaternion.x * quaternion.y;
const xz = quaternion.x * quaternion.z;
const xw = quaternion.x * quaternion.w;
const y2 = quaternion.y * quaternion.y;
const yz = quaternion.y * quaternion.z;
const yw = quaternion.y * quaternion.w;
const z2 = quaternion.z * quaternion.z;
const zw = quaternion.z * quaternion.w;
const w2 = quaternion.w * quaternion.w;
const m00 = x2 - y2 - z2 + w2;
const m01 = 2 * (xy - zw);
const m02 = 2 * (xz + yw);
const m10 = 2 * (xy + zw);
const m11 = -x2 + y2 - z2 + w2;
const m12 = 2 * (yz - xw);
const m20 = 2 * (xz - yw);
const m21 = 2 * (yz + xw);
const m22 = -x2 - y2 + z2 + w2;
if (!defined_default(result)) {
return new Matrix3(m00, m01, m02, m10, m11, m12, m20, m21, m22);
}
result[0] = m00;
result[1] = m10;
result[2] = m20;
result[3] = m01;
result[4] = m11;
result[5] = m21;
result[6] = m02;
result[7] = m12;
result[8] = m22;
return result;
};
Matrix3.fromHeadingPitchRoll = function(headingPitchRoll, result) {
Check_default.typeOf.object("headingPitchRoll", headingPitchRoll);
const cosTheta = Math.cos(-headingPitchRoll.pitch);
const cosPsi = Math.cos(-headingPitchRoll.heading);
const cosPhi = Math.cos(headingPitchRoll.roll);
const sinTheta = Math.sin(-headingPitchRoll.pitch);
const sinPsi = Math.sin(-headingPitchRoll.heading);
const sinPhi = Math.sin(headingPitchRoll.roll);
const m00 = cosTheta * cosPsi;
const m01 = -cosPhi * sinPsi + sinPhi * sinTheta * cosPsi;
const m02 = sinPhi * sinPsi + cosPhi * sinTheta * cosPsi;
const m10 = cosTheta * sinPsi;
const m11 = cosPhi * cosPsi + sinPhi * sinTheta * sinPsi;
const m12 = -sinPhi * cosPsi + cosPhi * sinTheta * sinPsi;
const m20 = -sinTheta;
const m21 = sinPhi * cosTheta;
const m22 = cosPhi * cosTheta;
if (!defined_default(result)) {
return new Matrix3(m00, m01, m02, m10, m11, m12, m20, m21, m22);
}
result[0] = m00;
result[1] = m10;
result[2] = m20;
result[3] = m01;
result[4] = m11;
result[5] = m21;
result[6] = m02;
result[7] = m12;
result[8] = m22;
return result;
};
Matrix3.fromScale = function(scale, result) {
Check_default.typeOf.object("scale", scale);
if (!defined_default(result)) {
return new Matrix3(scale.x, 0, 0, 0, scale.y, 0, 0, 0, scale.z);
}
result[0] = scale.x;
result[1] = 0;
result[2] = 0;
result[3] = 0;
result[4] = scale.y;
result[5] = 0;
result[6] = 0;
result[7] = 0;
result[8] = scale.z;
return result;
};
Matrix3.fromUniformScale = function(scale, result) {
Check_default.typeOf.number("scale", scale);
if (!defined_default(result)) {
return new Matrix3(scale, 0, 0, 0, scale, 0, 0, 0, scale);
}
result[0] = scale;
result[1] = 0;
result[2] = 0;
result[3] = 0;
result[4] = scale;
result[5] = 0;
result[6] = 0;
result[7] = 0;
result[8] = scale;
return result;
};
Matrix3.fromCrossProduct = function(vector, result) {
Check_default.typeOf.object("vector", vector);
if (!defined_default(result)) {
return new Matrix3(
0,
-vector.z,
vector.y,
vector.z,
0,
-vector.x,
-vector.y,
vector.x,
0
);
}
result[0] = 0;
result[1] = vector.z;
result[2] = -vector.y;
result[3] = -vector.z;
result[4] = 0;
result[5] = vector.x;
result[6] = vector.y;
result[7] = -vector.x;
result[8] = 0;
return result;
};
Matrix3.fromRotationX = function(angle, result) {
Check_default.typeOf.number("angle", angle);
const cosAngle = Math.cos(angle);
const sinAngle = Math.sin(angle);
if (!defined_default(result)) {
return new Matrix3(
1,
0,
0,
0,
cosAngle,
-sinAngle,
0,
sinAngle,
cosAngle
);
}
result[0] = 1;
result[1] = 0;
result[2] = 0;
result[3] = 0;
result[4] = cosAngle;
result[5] = sinAngle;
result[6] = 0;
result[7] = -sinAngle;
result[8] = cosAngle;
return result;
};
Matrix3.fromRotationY = function(angle, result) {
Check_default.typeOf.number("angle", angle);
const cosAngle = Math.cos(angle);
const sinAngle = Math.sin(angle);
if (!defined_default(result)) {
return new Matrix3(
cosAngle,
0,
sinAngle,
0,
1,
0,
-sinAngle,
0,
cosAngle
);
}
result[0] = cosAngle;
result[1] = 0;
result[2] = -sinAngle;
result[3] = 0;
result[4] = 1;
result[5] = 0;
result[6] = sinAngle;
result[7] = 0;
result[8] = cosAngle;
return result;
};
Matrix3.fromRotationZ = function(angle, result) {
Check_default.typeOf.number("angle", angle);
const cosAngle = Math.cos(angle);
const sinAngle = Math.sin(angle);
if (!defined_default(result)) {
return new Matrix3(
cosAngle,
-sinAngle,
0,
sinAngle,
cosAngle,
0,
0,
0,
1
);
}
result[0] = cosAngle;
result[1] = sinAngle;
result[2] = 0;
result[3] = -sinAngle;
result[4] = cosAngle;
result[5] = 0;
result[6] = 0;
result[7] = 0;
result[8] = 1;
return result;
};
Matrix3.toArray = function(matrix, result) {
Check_default.typeOf.object("matrix", matrix);
if (!defined_default(result)) {
return [
matrix[0],
matrix[1],
matrix[2],
matrix[3],
matrix[4],
matrix[5],
matrix[6],
matrix[7],
matrix[8]
];
}
result[0] = matrix[0];
result[1] = matrix[1];
result[2] = matrix[2];
result[3] = matrix[3];
result[4] = matrix[4];
result[5] = matrix[5];
result[6] = matrix[6];
result[7] = matrix[7];
result[8] = matrix[8];
return result;
};
Matrix3.getElementIndex = function(column, row) {
Check_default.typeOf.number.greaterThanOrEquals("row", row, 0);
Check_default.typeOf.number.lessThanOrEquals("row", row, 2);
Check_default.typeOf.number.greaterThanOrEquals("column", column, 0);
Check_default.typeOf.number.lessThanOrEquals("column", column, 2);
return column * 3 + row;
};
Matrix3.getColumn = function(matrix, index, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.number.greaterThanOrEquals("index", index, 0);
Check_default.typeOf.number.lessThanOrEquals("index", index, 2);
Check_default.typeOf.object("result", result);
const startIndex = index * 3;
const x = matrix[startIndex];
const y = matrix[startIndex + 1];
const z = matrix[startIndex + 2];
result.x = x;
result.y = y;
result.z = z;
return result;
};
Matrix3.setColumn = function(matrix, index, cartesian, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.number.greaterThanOrEquals("index", index, 0);
Check_default.typeOf.number.lessThanOrEquals("index", index, 2);
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
result = Matrix3.clone(matrix, result);
const startIndex = index * 3;
result[startIndex] = cartesian.x;
result[startIndex + 1] = cartesian.y;
result[startIndex + 2] = cartesian.z;
return result;
};
Matrix3.getRow = function(matrix, index, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.number.greaterThanOrEquals("index", index, 0);
Check_default.typeOf.number.lessThanOrEquals("index", index, 2);
Check_default.typeOf.object("result", result);
const x = matrix[index];
const y = matrix[index + 3];
const z = matrix[index + 6];
result.x = x;
result.y = y;
result.z = z;
return result;
};
Matrix3.setRow = function(matrix, index, cartesian, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.number.greaterThanOrEquals("index", index, 0);
Check_default.typeOf.number.lessThanOrEquals("index", index, 2);
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
result = Matrix3.clone(matrix, result);
result[index] = cartesian.x;
result[index + 3] = cartesian.y;
result[index + 6] = cartesian.z;
return result;
};
var scaleScratch1 = new Cartesian3_default();
Matrix3.setScale = function(matrix, scale, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("scale", scale);
Check_default.typeOf.object("result", result);
const existingScale = Matrix3.getScale(matrix, scaleScratch1);
const scaleRatioX = scale.x / existingScale.x;
const scaleRatioY = scale.y / existingScale.y;
const scaleRatioZ = scale.z / existingScale.z;
result[0] = matrix[0] * scaleRatioX;
result[1] = matrix[1] * scaleRatioX;
result[2] = matrix[2] * scaleRatioX;
result[3] = matrix[3] * scaleRatioY;
result[4] = matrix[4] * scaleRatioY;
result[5] = matrix[5] * scaleRatioY;
result[6] = matrix[6] * scaleRatioZ;
result[7] = matrix[7] * scaleRatioZ;
result[8] = matrix[8] * scaleRatioZ;
return result;
};
var scaleScratch2 = new Cartesian3_default();
Matrix3.setUniformScale = function(matrix, scale, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.number("scale", scale);
Check_default.typeOf.object("result", result);
const existingScale = Matrix3.getScale(matrix, scaleScratch2);
const scaleRatioX = scale / existingScale.x;
const scaleRatioY = scale / existingScale.y;
const scaleRatioZ = scale / existingScale.z;
result[0] = matrix[0] * scaleRatioX;
result[1] = matrix[1] * scaleRatioX;
result[2] = matrix[2] * scaleRatioX;
result[3] = matrix[3] * scaleRatioY;
result[4] = matrix[4] * scaleRatioY;
result[5] = matrix[5] * scaleRatioY;
result[6] = matrix[6] * scaleRatioZ;
result[7] = matrix[7] * scaleRatioZ;
result[8] = matrix[8] * scaleRatioZ;
return result;
};
var scratchColumn = new Cartesian3_default();
Matrix3.getScale = function(matrix, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("result", result);
result.x = Cartesian3_default.magnitude(
Cartesian3_default.fromElements(matrix[0], matrix[1], matrix[2], scratchColumn)
);
result.y = Cartesian3_default.magnitude(
Cartesian3_default.fromElements(matrix[3], matrix[4], matrix[5], scratchColumn)
);
result.z = Cartesian3_default.magnitude(
Cartesian3_default.fromElements(matrix[6], matrix[7], matrix[8], scratchColumn)
);
return result;
};
var scaleScratch3 = new Cartesian3_default();
Matrix3.getMaximumScale = function(matrix) {
Matrix3.getScale(matrix, scaleScratch3);
return Cartesian3_default.maximumComponent(scaleScratch3);
};
var scaleScratch4 = new Cartesian3_default();
Matrix3.setRotation = function(matrix, rotation, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("result", result);
const scale = Matrix3.getScale(matrix, scaleScratch4);
result[0] = rotation[0] * scale.x;
result[1] = rotation[1] * scale.x;
result[2] = rotation[2] * scale.x;
result[3] = rotation[3] * scale.y;
result[4] = rotation[4] * scale.y;
result[5] = rotation[5] * scale.y;
result[6] = rotation[6] * scale.z;
result[7] = rotation[7] * scale.z;
result[8] = rotation[8] * scale.z;
return result;
};
var scaleScratch5 = new Cartesian3_default();
Matrix3.getRotation = function(matrix, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("result", result);
const scale = Matrix3.getScale(matrix, scaleScratch5);
result[0] = matrix[0] / scale.x;
result[1] = matrix[1] / scale.x;
result[2] = matrix[2] / scale.x;
result[3] = matrix[3] / scale.y;
result[4] = matrix[4] / scale.y;
result[5] = matrix[5] / scale.y;
result[6] = matrix[6] / scale.z;
result[7] = matrix[7] / scale.z;
result[8] = matrix[8] / scale.z;
return result;
};
Matrix3.multiply = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
const column0Row0 = left[0] * right[0] + left[3] * right[1] + left[6] * right[2];
const column0Row1 = left[1] * right[0] + left[4] * right[1] + left[7] * right[2];
const column0Row2 = left[2] * right[0] + left[5] * right[1] + left[8] * right[2];
const column1Row0 = left[0] * right[3] + left[3] * right[4] + left[6] * right[5];
const column1Row1 = left[1] * right[3] + left[4] * right[4] + left[7] * right[5];
const column1Row2 = left[2] * right[3] + left[5] * right[4] + left[8] * right[5];
const column2Row0 = left[0] * right[6] + left[3] * right[7] + left[6] * right[8];
const column2Row1 = left[1] * right[6] + left[4] * right[7] + left[7] * right[8];
const column2Row2 = left[2] * right[6] + left[5] * right[7] + left[8] * right[8];
result[0] = column0Row0;
result[1] = column0Row1;
result[2] = column0Row2;
result[3] = column1Row0;
result[4] = column1Row1;
result[5] = column1Row2;
result[6] = column2Row0;
result[7] = column2Row1;
result[8] = column2Row2;
return result;
};
Matrix3.add = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result[0] = left[0] + right[0];
result[1] = left[1] + right[1];
result[2] = left[2] + right[2];
result[3] = left[3] + right[3];
result[4] = left[4] + right[4];
result[5] = left[5] + right[5];
result[6] = left[6] + right[6];
result[7] = left[7] + right[7];
result[8] = left[8] + right[8];
return result;
};
Matrix3.subtract = function(left, right, result) {
Check_default.typeOf.object("left", left);
Check_default.typeOf.object("right", right);
Check_default.typeOf.object("result", result);
result[0] = left[0] - right[0];
result[1] = left[1] - right[1];
result[2] = left[2] - right[2];
result[3] = left[3] - right[3];
result[4] = left[4] - right[4];
result[5] = left[5] - right[5];
result[6] = left[6] - right[6];
result[7] = left[7] - right[7];
result[8] = left[8] - right[8];
return result;
};
Matrix3.multiplyByVector = function(matrix, cartesian, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("cartesian", cartesian);
Check_default.typeOf.object("result", result);
const vX = cartesian.x;
const vY = cartesian.y;
const vZ = cartesian.z;
const x = matrix[0] * vX + matrix[3] * vY + matrix[6] * vZ;
const y = matrix[1] * vX + matrix[4] * vY + matrix[7] * vZ;
const z = matrix[2] * vX + matrix[5] * vY + matrix[8] * vZ;
result.x = x;
result.y = y;
result.z = z;
return result;
};
Matrix3.multiplyByScalar = function(matrix, scalar, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.number("scalar", scalar);
Check_default.typeOf.object("result", result);
result[0] = matrix[0] * scalar;
result[1] = matrix[1] * scalar;
result[2] = matrix[2] * scalar;
result[3] = matrix[3] * scalar;
result[4] = matrix[4] * scalar;
result[5] = matrix[5] * scalar;
result[6] = matrix[6] * scalar;
result[7] = matrix[7] * scalar;
result[8] = matrix[8] * scalar;
return result;
};
Matrix3.multiplyByScale = function(matrix, scale, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("scale", scale);
Check_default.typeOf.object("result", result);
result[0] = matrix[0] * scale.x;
result[1] = matrix[1] * scale.x;
result[2] = matrix[2] * scale.x;
result[3] = matrix[3] * scale.y;
result[4] = matrix[4] * scale.y;
result[5] = matrix[5] * scale.y;
result[6] = matrix[6] * scale.z;
result[7] = matrix[7] * scale.z;
result[8] = matrix[8] * scale.z;
return result;
};
Matrix3.multiplyByUniformScale = function(matrix, scale, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.number("scale", scale);
Check_default.typeOf.object("result", result);
result[0] = matrix[0] * scale;
result[1] = matrix[1] * scale;
result[2] = matrix[2] * scale;
result[3] = matrix[3] * scale;
result[4] = matrix[4] * scale;
result[5] = matrix[5] * scale;
result[6] = matrix[6] * scale;
result[7] = matrix[7] * scale;
result[8] = matrix[8] * scale;
return result;
};
Matrix3.negate = function(matrix, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("result", result);
result[0] = -matrix[0];
result[1] = -matrix[1];
result[2] = -matrix[2];
result[3] = -matrix[3];
result[4] = -matrix[4];
result[5] = -matrix[5];
result[6] = -matrix[6];
result[7] = -matrix[7];
result[8] = -matrix[8];
return result;
};
Matrix3.transpose = function(matrix, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("result", result);
const column0Row0 = matrix[0];
const column0Row1 = matrix[3];
const column0Row2 = matrix[6];
const column1Row0 = matrix[1];
const column1Row1 = matrix[4];
const column1Row2 = matrix[7];
const column2Row0 = matrix[2];
const column2Row1 = matrix[5];
const column2Row2 = matrix[8];
result[0] = column0Row0;
result[1] = column0Row1;
result[2] = column0Row2;
result[3] = column1Row0;
result[4] = column1Row1;
result[5] = column1Row2;
result[6] = column2Row0;
result[7] = column2Row1;
result[8] = column2Row2;
return result;
};
function computeFrobeniusNorm(matrix) {
let norm = 0;
for (let i = 0; i < 9; ++i) {
const temp = matrix[i];
norm += temp * temp;
}
return Math.sqrt(norm);
}
var rowVal = [1, 0, 0];
var colVal = [2, 2, 1];
function offDiagonalFrobeniusNorm(matrix) {
let norm = 0;
for (let i = 0; i < 3; ++i) {
const temp = matrix[Matrix3.getElementIndex(colVal[i], rowVal[i])];
norm += 2 * temp * temp;
}
return Math.sqrt(norm);
}
function shurDecomposition(matrix, result) {
const tolerance = Math_default.EPSILON15;
let maxDiagonal = 0;
let rotAxis = 1;
for (let i = 0; i < 3; ++i) {
const temp = Math.abs(
matrix[Matrix3.getElementIndex(colVal[i], rowVal[i])]
);
if (temp > maxDiagonal) {
rotAxis = i;
maxDiagonal = temp;
}
}
let c = 1;
let s = 0;
const p = rowVal[rotAxis];
const q = colVal[rotAxis];
if (Math.abs(matrix[Matrix3.getElementIndex(q, p)]) > tolerance) {
const qq = matrix[Matrix3.getElementIndex(q, q)];
const pp = matrix[Matrix3.getElementIndex(p, p)];
const qp = matrix[Matrix3.getElementIndex(q, p)];
const tau = (qq - pp) / 2 / qp;
let t;
if (tau < 0) {
t = -1 / (-tau + Math.sqrt(1 + tau * tau));
} else {
t = 1 / (tau + Math.sqrt(1 + tau * tau));
}
c = 1 / Math.sqrt(1 + t * t);
s = t * c;
}
result = Matrix3.clone(Matrix3.IDENTITY, result);
result[Matrix3.getElementIndex(p, p)] = result[Matrix3.getElementIndex(q, q)] = c;
result[Matrix3.getElementIndex(q, p)] = s;
result[Matrix3.getElementIndex(p, q)] = -s;
return result;
}
var jMatrix = new Matrix3();
var jMatrixTranspose = new Matrix3();
Matrix3.computeEigenDecomposition = function(matrix, result) {
Check_default.typeOf.object("matrix", matrix);
const tolerance = Math_default.EPSILON20;
const maxSweeps = 10;
let count = 0;
let sweep = 0;
if (!defined_default(result)) {
result = {};
}
const unitaryMatrix = result.unitary = Matrix3.clone(
Matrix3.IDENTITY,
result.unitary
);
const diagMatrix = result.diagonal = Matrix3.clone(matrix, result.diagonal);
const epsilon = tolerance * computeFrobeniusNorm(diagMatrix);
while (sweep < maxSweeps && offDiagonalFrobeniusNorm(diagMatrix) > epsilon) {
shurDecomposition(diagMatrix, jMatrix);
Matrix3.transpose(jMatrix, jMatrixTranspose);
Matrix3.multiply(diagMatrix, jMatrix, diagMatrix);
Matrix3.multiply(jMatrixTranspose, diagMatrix, diagMatrix);
Matrix3.multiply(unitaryMatrix, jMatrix, unitaryMatrix);
if (++count > 2) {
++sweep;
count = 0;
}
}
return result;
};
Matrix3.abs = function(matrix, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("result", result);
result[0] = Math.abs(matrix[0]);
result[1] = Math.abs(matrix[1]);
result[2] = Math.abs(matrix[2]);
result[3] = Math.abs(matrix[3]);
result[4] = Math.abs(matrix[4]);
result[5] = Math.abs(matrix[5]);
result[6] = Math.abs(matrix[6]);
result[7] = Math.abs(matrix[7]);
result[8] = Math.abs(matrix[8]);
return result;
};
Matrix3.determinant = function(matrix) {
Check_default.typeOf.object("matrix", matrix);
const m11 = matrix[0];
const m21 = matrix[3];
const m31 = matrix[6];
const m12 = matrix[1];
const m22 = matrix[4];
const m32 = matrix[7];
const m13 = matrix[2];
const m23 = matrix[5];
const m33 = matrix[8];
return m11 * (m22 * m33 - m23 * m32) + m12 * (m23 * m31 - m21 * m33) + m13 * (m21 * m32 - m22 * m31);
};
Matrix3.inverse = function(matrix, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("result", result);
const m11 = matrix[0];
const m21 = matrix[1];
const m31 = matrix[2];
const m12 = matrix[3];
const m22 = matrix[4];
const m32 = matrix[5];
const m13 = matrix[6];
const m23 = matrix[7];
const m33 = matrix[8];
const determinant = Matrix3.determinant(matrix);
if (Math.abs(determinant) <= Math_default.EPSILON15) {
throw new DeveloperError_default("matrix is not invertible");
}
result[0] = m22 * m33 - m23 * m32;
result[1] = m23 * m31 - m21 * m33;
result[2] = m21 * m32 - m22 * m31;
result[3] = m13 * m32 - m12 * m33;
result[4] = m11 * m33 - m13 * m31;
result[5] = m12 * m31 - m11 * m32;
result[6] = m12 * m23 - m13 * m22;
result[7] = m13 * m21 - m11 * m23;
result[8] = m11 * m22 - m12 * m21;
const scale = 1 / determinant;
return Matrix3.multiplyByScalar(result, scale, result);
};
var scratchTransposeMatrix = new Matrix3();
Matrix3.inverseTranspose = function(matrix, result) {
Check_default.typeOf.object("matrix", matrix);
Check_default.typeOf.object("result", result);
return Matrix3.inverse(
Matrix3.transpose(matrix, scratchTransposeMatrix),
result
);
};
Matrix3.equals = function(left, right) {
return left === right || defined_default(left) && defined_default(right) && left[0] === right[0] && left[1] === right[1] && left[2] === right[2] && left[3] === right[3] && left[4] === right[4] && left[5] === right[5] && left[6] === right[6] && left[7] === right[7] && left[8] === right[8];
};
Matrix3.equalsEpsilon = function(left, right, epsilon) {
epsilon = defaultValue_default(epsilon, 0);
return left === right || defined_default(left) && defined_default(right) && Math.abs(left[0] - right[0]) <= epsilon && Math.abs(left[1] - right[1]) <= epsilon && Math.abs(left[2] - right[2]) <= epsilon && Math.abs(left[3] - right[3]) <= epsilon && Math.abs(left[4] - right[4]) <= epsilon && Math.abs(left[5] - right[5]) <= epsilon && Math.abs(left[6] - right[6]) <= epsilon && Math.abs(left[7] - right[7]) <= epsilon && Math.abs(left[8] - right[8]) <= epsilon;
};
Matrix3.IDENTITY = Object.freeze(
new Matrix3(1, 0, 0, 0, 1, 0, 0, 0, 1)
);
Matrix3.ZERO = Object.freeze(
new Matrix3(0, 0, 0, 0, 0, 0, 0, 0, 0)
);
Matrix3.COLUMN0ROW0 = 0;
Matrix3.COLUMN0ROW1 = 1;
Matrix3.COLUMN0ROW2 = 2;
Matrix3.COLUMN1ROW0 = 3;
Matrix3.COLUMN1ROW1 = 4;
Matrix3.COLUMN1ROW2 = 5;
Matrix3.COLUMN2ROW0 = 6;
Matrix3.COLUMN2ROW1 = 7;
Matrix3.COLUMN2ROW2 = 8;
Object.defineProperties(Matrix3.prototype, {
/**
* Gets the number of items in the collection.
* @memberof Matrix3.prototype
*
* @type {number}
*/
length: {
get: function() {
return Matrix3.packedLength;
}
}
});
Matrix3.prototype.clone = function(result) {
return Matrix3.clone(this, result);
};
Matrix3.prototype.equals = function(right) {
return Matrix3.equals(this, right);
};
Matrix3.equalsArray = function(matrix, array, offset) {
return matrix[0] === array[offset] && matrix[1] === array[offset + 1] && matrix[2] === array[offset + 2] && matrix[3] === array[offset + 3] && matrix[4] === array[offset + 4] && matrix[5] === array[offset + 5] && matrix[6] === array[offset + 6] && matrix[7] === array[offset + 7] && matrix[8] === array[offset + 8];
};
Matrix3.prototype.equalsEpsilon = function(right, epsilon) {
return Matrix3.equalsEpsilon(this, right, epsilon);
};
Matrix3.prototype.toString = function() {
return `(${this[0]}, ${this[3]}, ${this[6]})
(${this[1]}, ${this[4]}, ${this[7]})
(${this[2]}, ${this[5]}, ${this[8]})`;
};
var Matrix3_default = Matrix3;
// packages/engine/Source/Core/Fullscreen.js
var _supportsFullscreen;
var _names = {
requestFullscreen: void 0,
exitFullscreen: void 0,
fullscreenEnabled: void 0,
fullscreenElement: void 0,
fullscreenchange: void 0,
fullscreenerror: void 0
};
var Fullscreen = {};
Object.defineProperties(Fullscreen, {
/**
* The element that is currently fullscreen, if any. To simply check if the
* browser is in fullscreen mode or not, use {@link Fullscreen#fullscreen}.
* @memberof Fullscreen
* @type {object}
* @readonly
*/
element: {
get: function() {
if (!Fullscreen.supportsFullscreen()) {
return void 0;
}
return document[_names.fullscreenElement];
}
},
/**
* The name of the event on the document that is fired when fullscreen is
* entered or exited. This event name is intended for use with addEventListener.
* In your event handler, to determine if the browser is in fullscreen mode or not,
* use {@link Fullscreen#fullscreen}.
* @memberof Fullscreen
* @type {string}
* @readonly
*/
changeEventName: {
get: function() {
if (!Fullscreen.supportsFullscreen()) {
return void 0;
}
return _names.fullscreenchange;
}
},
/**
* The name of the event that is fired when a fullscreen error
* occurs. This event name is intended for use with addEventListener.
* @memberof Fullscreen
* @type {string}
* @readonly
*/
errorEventName: {
get: function() {
if (!Fullscreen.supportsFullscreen()) {
return void 0;
}
return _names.fullscreenerror;
}
},
/**
* Determine whether the browser will allow an element to be made fullscreen, or not.
* For example, by default, iframes cannot go fullscreen unless the containing page
* adds an "allowfullscreen" attribute (or prefixed equivalent).
* @memberof Fullscreen
* @type {boolean}
* @readonly
*/
enabled: {
get: function() {
if (!Fullscreen.supportsFullscreen()) {
return void 0;
}
return document[_names.fullscreenEnabled];
}
},
/**
* Determines if the browser is currently in fullscreen mode.
* @memberof Fullscreen
* @type {boolean}
* @readonly
*/
fullscreen: {
get: function() {
if (!Fullscreen.supportsFullscreen()) {
return void 0;
}
return Fullscreen.element !== null;
}
}
});
Fullscreen.supportsFullscreen = function() {
if (defined_default(_supportsFullscreen)) {
return _supportsFullscreen;
}
_supportsFullscreen = false;
const body = document.body;
if (typeof body.requestFullscreen === "function") {
_names.requestFullscreen = "requestFullscreen";
_names.exitFullscreen = "exitFullscreen";
_names.fullscreenEnabled = "fullscreenEnabled";
_names.fullscreenElement = "fullscreenElement";
_names.fullscreenchange = "fullscreenchange";
_names.fullscreenerror = "fullscreenerror";
_supportsFullscreen = true;
return _supportsFullscreen;
}
const prefixes = ["webkit", "moz", "o", "ms", "khtml"];
let name;
for (let i = 0, len = prefixes.length; i < len; ++i) {
const prefix = prefixes[i];
name = `${prefix}RequestFullscreen`;
if (typeof body[name] === "function") {
_names.requestFullscreen = name;
_supportsFullscreen = true;
} else {
name = `${prefix}RequestFullScreen`;
if (typeof body[name] === "function") {
_names.requestFullscreen = name;
_supportsFullscreen = true;
}
}
name = `${prefix}ExitFullscreen`;
if (typeof document[name] === "function") {
_names.exitFullscreen = name;
} else {
name = `${prefix}CancelFullScreen`;
if (typeof document[name] === "function") {
_names.exitFullscreen = name;
}
}
name = `${prefix}FullscreenEnabled`;
if (document[name] !== void 0) {
_names.fullscreenEnabled = name;
} else {
name = `${prefix}FullScreenEnabled`;
if (document[name] !== void 0) {
_names.fullscreenEnabled = name;
}
}
name = `${prefix}FullscreenElement`;
if (document[name] !== void 0) {
_names.fullscreenElement = name;
} else {
name = `${prefix}FullScreenElement`;
if (document[name] !== void 0) {
_names.fullscreenElement = name;
}
}
name = `${prefix}fullscreenchange`;
if (document[`on${name}`] !== void 0) {
if (prefix === "ms") {
name = "MSFullscreenChange";
}
_names.fullscreenchange = name;
}
name = `${prefix}fullscreenerror`;
if (document[`on${name}`] !== void 0) {
if (prefix === "ms") {
name = "MSFullscreenError";
}
_names.fullscreenerror = name;
}
}
return _supportsFullscreen;
};
Fullscreen.requestFullscreen = function(element, vrDevice) {
if (!Fullscreen.supportsFullscreen()) {
return;
}
element[_names.requestFullscreen]({ vrDisplay: vrDevice });
};
Fullscreen.exitFullscreen = function() {
if (!Fullscreen.supportsFullscreen()) {
return;
}
document[_names.exitFullscreen]();
};
Fullscreen._names = _names;
var Fullscreen_default = Fullscreen;
// packages/engine/Source/Core/FeatureDetection.js
var theNavigator;
if (typeof navigator !== "undefined") {
theNavigator = navigator;
} else {
theNavigator = {};
}
function extractVersion(versionString) {
const parts = versionString.split(".");
for (let i = 0, len = parts.length; i < len; ++i) {
parts[i] = parseInt(parts[i], 10);
}
return parts;
}
var isChromeResult;
var chromeVersionResult;
function isChrome() {
if (!defined_default(isChromeResult)) {
isChromeResult = false;
if (!isEdge()) {
const fields = / Chrome\/([\.0-9]+)/.exec(theNavigator.userAgent);
if (fields !== null) {
isChromeResult = true;
chromeVersionResult = extractVersion(fields[1]);
}
}
}
return isChromeResult;
}
function chromeVersion() {
return isChrome() && chromeVersionResult;
}
var isSafariResult;
var safariVersionResult;
function isSafari() {
if (!defined_default(isSafariResult)) {
isSafariResult = false;
if (!isChrome() && !isEdge() && / Safari\/[\.0-9]+/.test(theNavigator.userAgent)) {
const fields = / Version\/([\.0-9]+)/.exec(theNavigator.userAgent);
if (fields !== null) {
isSafariResult = true;
safariVersionResult = extractVersion(fields[1]);
}
}
}
return isSafariResult;
}
function safariVersion() {
return isSafari() && safariVersionResult;
}
var isWebkitResult;
var webkitVersionResult;
function isWebkit() {
if (!defined_default(isWebkitResult)) {
isWebkitResult = false;
const fields = / AppleWebKit\/([\.0-9]+)(\+?)/.exec(theNavigator.userAgent);
if (fields !== null) {
isWebkitResult = true;
webkitVersionResult = extractVersion(fields[1]);
webkitVersionResult.isNightly = !!fields[2];
}
}
return isWebkitResult;
}
function webkitVersion() {
return isWebkit() && webkitVersionResult;
}
var isInternetExplorerResult;
var internetExplorerVersionResult;
function isInternetExplorer() {
if (!defined_default(isInternetExplorerResult)) {
isInternetExplorerResult = false;
let fields;
if (theNavigator.appName === "Microsoft Internet Explorer") {
fields = /MSIE ([0-9]{1,}[\.0-9]{0,})/.exec(theNavigator.userAgent);
if (fields !== null) {
isInternetExplorerResult = true;
internetExplorerVersionResult = extractVersion(fields[1]);
}
} else if (theNavigator.appName === "Netscape") {
fields = /Trident\/.*rv:([0-9]{1,}[\.0-9]{0,})/.exec(
theNavigator.userAgent
);
if (fields !== null) {
isInternetExplorerResult = true;
internetExplorerVersionResult = extractVersion(fields[1]);
}
}
}
return isInternetExplorerResult;
}
function internetExplorerVersion() {
return isInternetExplorer() && internetExplorerVersionResult;
}
var isEdgeResult;
var edgeVersionResult;
function isEdge() {
if (!defined_default(isEdgeResult)) {
isEdgeResult = false;
const fields = / Edg\/([\.0-9]+)/.exec(theNavigator.userAgent);
if (fields !== null) {
isEdgeResult = true;
edgeVersionResult = extractVersion(fields[1]);
}
}
return isEdgeResult;
}
function edgeVersion() {
return isEdge() && edgeVersionResult;
}
var isFirefoxResult;
var firefoxVersionResult;
function isFirefox() {
if (!defined_default(isFirefoxResult)) {
isFirefoxResult = false;
const fields = /Firefox\/([\.0-9]+)/.exec(theNavigator.userAgent);
if (fields !== null) {
isFirefoxResult = true;
firefoxVersionResult = extractVersion(fields[1]);
}
}
return isFirefoxResult;
}
var isWindowsResult;
function isWindows() {
if (!defined_default(isWindowsResult)) {
isWindowsResult = /Windows/i.test(theNavigator.appVersion);
}
return isWindowsResult;
}
var isIPadOrIOSResult;
function isIPadOrIOS() {
if (!defined_default(isIPadOrIOSResult)) {
isIPadOrIOSResult = navigator.platform === "iPhone" || navigator.platform === "iPod" || navigator.platform === "iPad";
}
return isIPadOrIOSResult;
}
function firefoxVersion() {
return isFirefox() && firefoxVersionResult;
}
var hasPointerEvents;
function supportsPointerEvents() {
if (!defined_default(hasPointerEvents)) {
hasPointerEvents = !isFirefox() && typeof PointerEvent !== "undefined" && (!defined_default(theNavigator.pointerEnabled) || theNavigator.pointerEnabled);
}
return hasPointerEvents;
}
var imageRenderingValueResult;
var supportsImageRenderingPixelatedResult;
function supportsImageRenderingPixelated() {
if (!defined_default(supportsImageRenderingPixelatedResult)) {
const canvas = document.createElement("canvas");
canvas.setAttribute(
"style",
"image-rendering: -moz-crisp-edges;image-rendering: pixelated;"
);
const tmp = canvas.style.imageRendering;
supportsImageRenderingPixelatedResult = defined_default(tmp) && tmp !== "";
if (supportsImageRenderingPixelatedResult) {
imageRenderingValueResult = tmp;
}
}
return supportsImageRenderingPixelatedResult;
}
function imageRenderingValue() {
return supportsImageRenderingPixelated() ? imageRenderingValueResult : void 0;
}
function supportsWebP() {
if (!supportsWebP.initialized) {
throw new DeveloperError_default(
"You must call FeatureDetection.supportsWebP.initialize and wait for the promise to resolve before calling FeatureDetection.supportsWebP"
);
}
return supportsWebP._result;
}
supportsWebP._promise = void 0;
supportsWebP._result = void 0;
supportsWebP.initialize = function() {
if (defined_default(supportsWebP._promise)) {
return supportsWebP._promise;
}
supportsWebP._promise = new Promise((resolve) => {
const image = new Image();
image.onload = function() {
supportsWebP._result = image.width > 0 && image.height > 0;
resolve(supportsWebP._result);
};
image.onerror = function() {
supportsWebP._result = false;
resolve(supportsWebP._result);
};
image.src = "data:image/webp;base64,UklGRiIAAABXRUJQVlA4IBYAAAAwAQCdASoBAAEADsD+JaQAA3AAAAAA";
});
return supportsWebP._promise;
};
Object.defineProperties(supportsWebP, {
initialized: {
get: function() {
return defined_default(supportsWebP._result);
}
}
});
var typedArrayTypes = [];
if (typeof ArrayBuffer !== "undefined") {
typedArrayTypes.push(
Int8Array,
Uint8Array,
Int16Array,
Uint16Array,
Int32Array,
Uint32Array,
Float32Array,
Float64Array
);
if (typeof Uint8ClampedArray !== "undefined") {
typedArrayTypes.push(Uint8ClampedArray);
}
if (typeof Uint8ClampedArray !== "undefined") {
typedArrayTypes.push(Uint8ClampedArray);
}
if (typeof BigInt64Array !== "undefined") {
typedArrayTypes.push(BigInt64Array);
}
if (typeof BigUint64Array !== "undefined") {
typedArrayTypes.push(BigUint64Array);
}
}
var FeatureDetection = {
isChrome,
chromeVersion,
isSafari,
safariVersion,
isWebkit,
webkitVersion,
isInternetExplorer,
internetExplorerVersion,
isEdge,
edgeVersion,
isFirefox,
firefoxVersion,
isWindows,
isIPadOrIOS,
hardwareConcurrency: defaultValue_default(theNavigator.hardwareConcurrency, 3),
supportsPointerEvents,
supportsImageRenderingPixelated,
supportsWebP,
imageRenderingValue,
typedArrayTypes
};
FeatureDetection.supportsBasis = function(scene) {
return FeatureDetection.supportsWebAssembly() && scene.context.supportsBasis;
};
FeatureDetection.supportsFullscreen = function() {
return Fullscreen_default.supportsFullscreen();
};
FeatureDetection.supportsTypedArrays = function() {
return typeof ArrayBuffer !== "undefined";
};
FeatureDetection.supportsBigInt64Array = function() {
return typeof BigInt64Array !== "undefined";
};
FeatureDetection.supportsBigUint64Array = function() {
return typeof BigUint64Array !== "undefined";
};
FeatureDetection.supportsBigInt = function() {
return typeof BigInt !== "undefined";
};
FeatureDetection.supportsWebWorkers = function() {
return typeof Worker !== "undefined";
};
FeatureDetection.supportsWebAssembly = function() {
return typeof WebAssembly !== "undefined";
};
FeatureDetection.supportsWebgl2 = function(scene) {
Check_default.defined("scene", scene);
return scene.context.webgl2;
};
FeatureDetection.supportsEsmWebWorkers = function() {
return !isFirefox() || parseInt(firefoxVersionResult) >= 114;
};
var FeatureDetection_default = FeatureDetection;
export {
Cartesian3_default,
Cartographic_default,
Cartesian2_default,
Ellipsoid_default,
Matrix3_default,
FeatureDetection_default
};