Agriculture-front-end/dist/CesiumUnminified/Workers/chunk-CYAJYEKW.js

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/**
* @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 {
Cartesian3_default,
Cartographic_default,
Ellipsoid_default
} from "./chunk-C5CE4OG6.js";
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/EllipsoidRhumbLine.js
function calculateM(ellipticity, major, latitude) {
if (ellipticity === 0) {
return major * latitude;
}
const e2 = ellipticity * ellipticity;
const e4 = e2 * e2;
const e6 = e4 * e2;
const e8 = e6 * e2;
const e10 = e8 * e2;
const e12 = e10 * e2;
const phi = latitude;
const sin2Phi = Math.sin(2 * phi);
const sin4Phi = Math.sin(4 * phi);
const sin6Phi = Math.sin(6 * phi);
const sin8Phi = Math.sin(8 * phi);
const sin10Phi = Math.sin(10 * phi);
const sin12Phi = Math.sin(12 * phi);
return major * ((1 - e2 / 4 - 3 * e4 / 64 - 5 * e6 / 256 - 175 * e8 / 16384 - 441 * e10 / 65536 - 4851 * e12 / 1048576) * phi - (3 * e2 / 8 + 3 * e4 / 32 + 45 * e6 / 1024 + 105 * e8 / 4096 + 2205 * e10 / 131072 + 6237 * e12 / 524288) * sin2Phi + (15 * e4 / 256 + 45 * e6 / 1024 + 525 * e8 / 16384 + 1575 * e10 / 65536 + 155925 * e12 / 8388608) * sin4Phi - (35 * e6 / 3072 + 175 * e8 / 12288 + 3675 * e10 / 262144 + 13475 * e12 / 1048576) * sin6Phi + (315 * e8 / 131072 + 2205 * e10 / 524288 + 43659 * e12 / 8388608) * sin8Phi - (693 * e10 / 1310720 + 6237 * e12 / 5242880) * sin10Phi + 1001 * e12 / 8388608 * sin12Phi);
}
function calculateInverseM(M, ellipticity, major) {
const d = M / major;
if (ellipticity === 0) {
return d;
}
const d2 = d * d;
const d3 = d2 * d;
const d4 = d3 * d;
const e = ellipticity;
const e2 = e * e;
const e4 = e2 * e2;
const e6 = e4 * e2;
const e8 = e6 * e2;
const e10 = e8 * e2;
const e12 = e10 * e2;
const sin2D = Math.sin(2 * d);
const cos2D = Math.cos(2 * d);
const sin4D = Math.sin(4 * d);
const cos4D = Math.cos(4 * d);
const sin6D = Math.sin(6 * d);
const cos6D = Math.cos(6 * d);
const sin8D = Math.sin(8 * d);
const cos8D = Math.cos(8 * d);
const sin10D = Math.sin(10 * d);
const cos10D = Math.cos(10 * d);
const sin12D = Math.sin(12 * d);
return d + d * e2 / 4 + 7 * d * e4 / 64 + 15 * d * e6 / 256 + 579 * d * e8 / 16384 + 1515 * d * e10 / 65536 + 16837 * d * e12 / 1048576 + (3 * d * e4 / 16 + 45 * d * e6 / 256 - d * (32 * d2 - 561) * e8 / 4096 - d * (232 * d2 - 1677) * e10 / 16384 + d * (399985 - 90560 * d2 + 512 * d4) * e12 / 5242880) * cos2D + (21 * d * e6 / 256 + 483 * d * e8 / 4096 - d * (224 * d2 - 1969) * e10 / 16384 - d * (33152 * d2 - 112599) * e12 / 1048576) * cos4D + (151 * d * e8 / 4096 + 4681 * d * e10 / 65536 + 1479 * d * e12 / 16384 - 453 * d3 * e12 / 32768) * cos6D + (1097 * d * e10 / 65536 + 42783 * d * e12 / 1048576) * cos8D + 8011 * d * e12 / 1048576 * cos10D + (3 * e2 / 8 + 3 * e4 / 16 + 213 * e6 / 2048 - 3 * d2 * e6 / 64 + 255 * e8 / 4096 - 33 * d2 * e8 / 512 + 20861 * e10 / 524288 - 33 * d2 * e10 / 512 + d4 * e10 / 1024 + 28273 * e12 / 1048576 - 471 * d2 * e12 / 8192 + 9 * d4 * e12 / 4096) * sin2D + (21 * e4 / 256 + 21 * e6 / 256 + 533 * e8 / 8192 - 21 * d2 * e8 / 512 + 197 * e10 / 4096 - 315 * d2 * e10 / 4096 + 584039 * e12 / 16777216 - 12517 * d2 * e12 / 131072 + 7 * d4 * e12 / 2048) * sin4D + (151 * e6 / 6144 + 151 * e8 / 4096 + 5019 * e10 / 131072 - 453 * d2 * e10 / 16384 + 26965 * e12 / 786432 - 8607 * d2 * e12 / 131072) * sin6D + (1097 * e8 / 131072 + 1097 * e10 / 65536 + 225797 * e12 / 10485760 - 1097 * d2 * e12 / 65536) * sin8D + (8011 * e10 / 2621440 + 8011 * e12 / 1048576) * sin10D + 293393 * e12 / 251658240 * sin12D;
}
function calculateSigma(ellipticity, latitude) {
if (ellipticity === 0) {
return Math.log(Math.tan(0.5 * (Math_default.PI_OVER_TWO + latitude)));
}
const eSinL = ellipticity * Math.sin(latitude);
return Math.log(Math.tan(0.5 * (Math_default.PI_OVER_TWO + latitude))) - ellipticity / 2 * Math.log((1 + eSinL) / (1 - eSinL));
}
function calculateHeading(ellipsoidRhumbLine, firstLongitude, firstLatitude, secondLongitude, secondLatitude) {
const sigma1 = calculateSigma(ellipsoidRhumbLine._ellipticity, firstLatitude);
const sigma2 = calculateSigma(
ellipsoidRhumbLine._ellipticity,
secondLatitude
);
return Math.atan2(
Math_default.negativePiToPi(secondLongitude - firstLongitude),
sigma2 - sigma1
);
}
function calculateArcLength(ellipsoidRhumbLine, major, minor, firstLongitude, firstLatitude, secondLongitude, secondLatitude) {
const heading = ellipsoidRhumbLine._heading;
const deltaLongitude = secondLongitude - firstLongitude;
let distance = 0;
if (Math_default.equalsEpsilon(
Math.abs(heading),
Math_default.PI_OVER_TWO,
Math_default.EPSILON8
)) {
if (major === minor) {
distance = major * Math.cos(firstLatitude) * Math_default.negativePiToPi(deltaLongitude);
} else {
const sinPhi = Math.sin(firstLatitude);
distance = major * Math.cos(firstLatitude) * Math_default.negativePiToPi(deltaLongitude) / Math.sqrt(1 - ellipsoidRhumbLine._ellipticitySquared * sinPhi * sinPhi);
}
} else {
const M1 = calculateM(
ellipsoidRhumbLine._ellipticity,
major,
firstLatitude
);
const M2 = calculateM(
ellipsoidRhumbLine._ellipticity,
major,
secondLatitude
);
distance = (M2 - M1) / Math.cos(heading);
}
return Math.abs(distance);
}
var scratchCart1 = new Cartesian3_default();
var scratchCart2 = new Cartesian3_default();
function computeProperties(ellipsoidRhumbLine, start, end, ellipsoid) {
const firstCartesian = Cartesian3_default.normalize(
ellipsoid.cartographicToCartesian(start, scratchCart2),
scratchCart1
);
const lastCartesian = Cartesian3_default.normalize(
ellipsoid.cartographicToCartesian(end, scratchCart2),
scratchCart2
);
Check_default.typeOf.number.greaterThanOrEquals(
"value",
Math.abs(
Math.abs(Cartesian3_default.angleBetween(firstCartesian, lastCartesian)) - Math.PI
),
0.0125
);
const major = ellipsoid.maximumRadius;
const minor = ellipsoid.minimumRadius;
const majorSquared = major * major;
const minorSquared = minor * minor;
ellipsoidRhumbLine._ellipticitySquared = (majorSquared - minorSquared) / majorSquared;
ellipsoidRhumbLine._ellipticity = Math.sqrt(
ellipsoidRhumbLine._ellipticitySquared
);
ellipsoidRhumbLine._start = Cartographic_default.clone(
start,
ellipsoidRhumbLine._start
);
ellipsoidRhumbLine._start.height = 0;
ellipsoidRhumbLine._end = Cartographic_default.clone(end, ellipsoidRhumbLine._end);
ellipsoidRhumbLine._end.height = 0;
ellipsoidRhumbLine._heading = calculateHeading(
ellipsoidRhumbLine,
start.longitude,
start.latitude,
end.longitude,
end.latitude
);
ellipsoidRhumbLine._distance = calculateArcLength(
ellipsoidRhumbLine,
ellipsoid.maximumRadius,
ellipsoid.minimumRadius,
start.longitude,
start.latitude,
end.longitude,
end.latitude
);
}
function interpolateUsingSurfaceDistance(start, heading, distance, major, ellipticity, result) {
if (distance === 0) {
return Cartographic_default.clone(start, result);
}
const ellipticitySquared = ellipticity * ellipticity;
let longitude;
let latitude;
let deltaLongitude;
if (Math.abs(Math_default.PI_OVER_TWO - Math.abs(heading)) > Math_default.EPSILON8) {
const M1 = calculateM(ellipticity, major, start.latitude);
const deltaM = distance * Math.cos(heading);
const M2 = M1 + deltaM;
latitude = calculateInverseM(M2, ellipticity, major);
if (Math.abs(heading) < Math_default.EPSILON10) {
longitude = Math_default.negativePiToPi(start.longitude);
} else {
const sigma1 = calculateSigma(ellipticity, start.latitude);
const sigma2 = calculateSigma(ellipticity, latitude);
deltaLongitude = Math.tan(heading) * (sigma2 - sigma1);
longitude = Math_default.negativePiToPi(start.longitude + deltaLongitude);
}
} else {
latitude = start.latitude;
let localRad;
if (ellipticity === 0) {
localRad = major * Math.cos(start.latitude);
} else {
const sinPhi = Math.sin(start.latitude);
localRad = major * Math.cos(start.latitude) / Math.sqrt(1 - ellipticitySquared * sinPhi * sinPhi);
}
deltaLongitude = distance / localRad;
if (heading > 0) {
longitude = Math_default.negativePiToPi(start.longitude + deltaLongitude);
} else {
longitude = Math_default.negativePiToPi(start.longitude - deltaLongitude);
}
}
if (defined_default(result)) {
result.longitude = longitude;
result.latitude = latitude;
result.height = 0;
return result;
}
return new Cartographic_default(longitude, latitude, 0);
}
function EllipsoidRhumbLine(start, end, ellipsoid) {
const e = defaultValue_default(ellipsoid, Ellipsoid_default.WGS84);
this._ellipsoid = e;
this._start = new Cartographic_default();
this._end = new Cartographic_default();
this._heading = void 0;
this._distance = void 0;
this._ellipticity = void 0;
this._ellipticitySquared = void 0;
if (defined_default(start) && defined_default(end)) {
computeProperties(this, start, end, e);
}
}
Object.defineProperties(EllipsoidRhumbLine.prototype, {
/**
* Gets the ellipsoid.
* @memberof EllipsoidRhumbLine.prototype
* @type {Ellipsoid}
* @readonly
*/
ellipsoid: {
get: function() {
return this._ellipsoid;
}
},
/**
* Gets the surface distance between the start and end point
* @memberof EllipsoidRhumbLine.prototype
* @type {number}
* @readonly
*/
surfaceDistance: {
get: function() {
Check_default.defined("distance", this._distance);
return this._distance;
}
},
/**
* Gets the initial planetodetic point on the path.
* @memberof EllipsoidRhumbLine.prototype
* @type {Cartographic}
* @readonly
*/
start: {
get: function() {
return this._start;
}
},
/**
* Gets the final planetodetic point on the path.
* @memberof EllipsoidRhumbLine.prototype
* @type {Cartographic}
* @readonly
*/
end: {
get: function() {
return this._end;
}
},
/**
* Gets the heading from the start point to the end point.
* @memberof EllipsoidRhumbLine.prototype
* @type {number}
* @readonly
*/
heading: {
get: function() {
Check_default.defined("distance", this._distance);
return this._heading;
}
}
});
EllipsoidRhumbLine.fromStartHeadingDistance = function(start, heading, distance, ellipsoid, result) {
Check_default.defined("start", start);
Check_default.defined("heading", heading);
Check_default.defined("distance", distance);
Check_default.typeOf.number.greaterThan("distance", distance, 0);
const e = defaultValue_default(ellipsoid, Ellipsoid_default.WGS84);
const major = e.maximumRadius;
const minor = e.minimumRadius;
const majorSquared = major * major;
const minorSquared = minor * minor;
const ellipticity = Math.sqrt((majorSquared - minorSquared) / majorSquared);
heading = Math_default.negativePiToPi(heading);
const end = interpolateUsingSurfaceDistance(
start,
heading,
distance,
e.maximumRadius,
ellipticity
);
if (!defined_default(result) || defined_default(ellipsoid) && !ellipsoid.equals(result.ellipsoid)) {
return new EllipsoidRhumbLine(start, end, e);
}
result.setEndPoints(start, end);
return result;
};
EllipsoidRhumbLine.prototype.setEndPoints = function(start, end) {
Check_default.defined("start", start);
Check_default.defined("end", end);
computeProperties(this, start, end, this._ellipsoid);
};
EllipsoidRhumbLine.prototype.interpolateUsingFraction = function(fraction, result) {
return this.interpolateUsingSurfaceDistance(
fraction * this._distance,
result
);
};
EllipsoidRhumbLine.prototype.interpolateUsingSurfaceDistance = function(distance, result) {
Check_default.typeOf.number("distance", distance);
if (!defined_default(this._distance) || this._distance === 0) {
throw new DeveloperError_default(
"EllipsoidRhumbLine must have distinct start and end set."
);
}
return interpolateUsingSurfaceDistance(
this._start,
this._heading,
distance,
this._ellipsoid.maximumRadius,
this._ellipticity,
result
);
};
EllipsoidRhumbLine.prototype.findIntersectionWithLongitude = function(intersectionLongitude, result) {
Check_default.typeOf.number("intersectionLongitude", intersectionLongitude);
if (!defined_default(this._distance) || this._distance === 0) {
throw new DeveloperError_default(
"EllipsoidRhumbLine must have distinct start and end set."
);
}
const ellipticity = this._ellipticity;
const heading = this._heading;
const absHeading = Math.abs(heading);
const start = this._start;
intersectionLongitude = Math_default.negativePiToPi(intersectionLongitude);
if (Math_default.equalsEpsilon(
Math.abs(intersectionLongitude),
Math.PI,
Math_default.EPSILON14
)) {
intersectionLongitude = Math_default.sign(start.longitude) * Math.PI;
}
if (!defined_default(result)) {
result = new Cartographic_default();
}
if (Math.abs(Math_default.PI_OVER_TWO - absHeading) <= Math_default.EPSILON8) {
result.longitude = intersectionLongitude;
result.latitude = start.latitude;
result.height = 0;
return result;
} else if (Math_default.equalsEpsilon(
Math.abs(Math_default.PI_OVER_TWO - absHeading),
Math_default.PI_OVER_TWO,
Math_default.EPSILON8
)) {
if (Math_default.equalsEpsilon(
intersectionLongitude,
start.longitude,
Math_default.EPSILON12
)) {
return void 0;
}
result.longitude = intersectionLongitude;
result.latitude = Math_default.PI_OVER_TWO * Math_default.sign(Math_default.PI_OVER_TWO - heading);
result.height = 0;
return result;
}
const phi1 = start.latitude;
const eSinPhi1 = ellipticity * Math.sin(phi1);
const leftComponent = Math.tan(0.5 * (Math_default.PI_OVER_TWO + phi1)) * Math.exp((intersectionLongitude - start.longitude) / Math.tan(heading));
const denominator = (1 + eSinPhi1) / (1 - eSinPhi1);
let newPhi = start.latitude;
let phi;
do {
phi = newPhi;
const eSinPhi = ellipticity * Math.sin(phi);
const numerator = (1 + eSinPhi) / (1 - eSinPhi);
newPhi = 2 * Math.atan(
leftComponent * Math.pow(numerator / denominator, ellipticity / 2)
) - Math_default.PI_OVER_TWO;
} while (!Math_default.equalsEpsilon(newPhi, phi, Math_default.EPSILON12));
result.longitude = intersectionLongitude;
result.latitude = newPhi;
result.height = 0;
return result;
};
EllipsoidRhumbLine.prototype.findIntersectionWithLatitude = function(intersectionLatitude, result) {
Check_default.typeOf.number("intersectionLatitude", intersectionLatitude);
if (!defined_default(this._distance) || this._distance === 0) {
throw new DeveloperError_default(
"EllipsoidRhumbLine must have distinct start and end set."
);
}
const ellipticity = this._ellipticity;
const heading = this._heading;
const start = this._start;
if (Math_default.equalsEpsilon(
Math.abs(heading),
Math_default.PI_OVER_TWO,
Math_default.EPSILON8
)) {
return;
}
const sigma1 = calculateSigma(ellipticity, start.latitude);
const sigma2 = calculateSigma(ellipticity, intersectionLatitude);
const deltaLongitude = Math.tan(heading) * (sigma2 - sigma1);
const longitude = Math_default.negativePiToPi(start.longitude + deltaLongitude);
if (defined_default(result)) {
result.longitude = longitude;
result.latitude = intersectionLatitude;
result.height = 0;
return result;
}
return new Cartographic_default(longitude, intersectionLatitude, 0);
};
var EllipsoidRhumbLine_default = EllipsoidRhumbLine;
export {
EllipsoidRhumbLine_default
};