Agriculture-front-end/public/CesiumUnminified/Workers/createPolygonGeometry.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 {
BoundingRectangle_default
} from "./chunk-QKF7XXEQ.js";
import {
PolygonGeometryLibrary_default
} from "./chunk-LVJCR7DH.js";
import {
ArcType_default
} from "./chunk-YLZTCEBJ.js";
import {
GeometryInstance_default
} from "./chunk-AOIKO5Y7.js";
import {
GeometryPipeline_default
} from "./chunk-PK7TEP3J.js";
import "./chunk-PS6AEMBR.js";
import "./chunk-AOFMPKUB.js";
import {
GeometryOffsetAttribute_default
} from "./chunk-S4XDCPKD.js";
import {
VertexFormat_default
} from "./chunk-4KIUON73.js";
import {
EllipsoidTangentPlane_default
} from "./chunk-CE6GTZ4I.js";
import "./chunk-6HCAQOVK.js";
import {
PolygonPipeline_default,
WindingOrder_default
} from "./chunk-RR7EOKGZ.js";
import "./chunk-V7JB576Q.js";
import "./chunk-CYAJYEKW.js";
import {
IntersectionTests_default,
Ray_default
} from "./chunk-G7CJQKKD.js";
import "./chunk-FOZQIHZK.js";
import {
IndexDatatype_default
} from "./chunk-WWP3I7R5.js";
import "./chunk-RL73GOEF.js";
import {
GeometryAttribute_default,
Geometry_default
} from "./chunk-34DGOKCO.js";
import {
BoundingSphere_default
} from "./chunk-NI2R52QD.js";
import {
Quaternion_default,
Rectangle_default
} from "./chunk-I5TDPPC4.js";
import {
ComponentDatatype_default
} from "./chunk-TMMOULW3.js";
import {
Cartesian2_default,
Cartesian3_default,
Cartographic_default,
Ellipsoid_default,
Matrix3_default
} from "./chunk-C5CE4OG6.js";
import {
Math_default
} from "./chunk-4PHPQRSH.js";
import "./chunk-PEABJLCK.js";
import "./chunk-WFICTTOE.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/Stereographic.js
function Stereographic(position, tangentPlane) {
this.position = position;
if (!defined_default(this.position)) {
this.position = new Cartesian2_default();
}
this.tangentPlane = tangentPlane;
if (!defined_default(this.tangentPlane)) {
this.tangentPlane = Stereographic.NORTH_POLE_TANGENT_PLANE;
}
}
Object.defineProperties(Stereographic.prototype, {
/**
* Gets the ellipsoid.
* @memberof Stereographic.prototype
* @type {Ellipsoid}
*/
ellipsoid: {
get: function() {
return this.tangentPlane.ellipsoid;
}
},
/**
* Gets the x coordinate
* @memberof Stereographic.prototype
* @type {number}
*/
x: {
get: function() {
return this.position.x;
}
},
/**
* Gets the y coordinate
* @memberof Stereographic.prototype
* @type {number}
*/
y: {
get: function() {
return this.position.y;
}
},
/**
* Computes the conformal latitude, or the ellipsoidal latitude projected onto an arbitrary sphere.
* @memberof Stereographic.prototype
* @type {number}
*/
conformalLatitude: {
get: function() {
const r = Cartesian2_default.magnitude(this.position);
const d = 2 * this.ellipsoid.maximumRadius;
const sign = this.tangentPlane.plane.normal.z;
return sign * (Math_default.PI_OVER_TWO - 2 * Math.atan2(r, d));
}
},
/**
* Computes the longitude
* @memberof Stereographic.prototype
* @type {number}
*/
longitude: {
get: function() {
let longitude = Math_default.PI_OVER_TWO + Math.atan2(this.y, this.x);
if (longitude > Math.PI) {
longitude -= Math_default.TWO_PI;
}
return longitude;
}
}
});
var scratchCartographic = new Cartographic_default();
var scratchCartesian = new Cartesian3_default();
Stereographic.prototype.getLatitude = function(ellipsoid) {
if (!defined_default(ellipsoid)) {
ellipsoid = Ellipsoid_default.WGS84;
}
scratchCartographic.latitude = this.conformalLatitude;
scratchCartographic.longitude = this.longitude;
scratchCartographic.height = 0;
const cartesian = this.ellipsoid.cartographicToCartesian(
scratchCartographic,
scratchCartesian
);
ellipsoid.cartesianToCartographic(cartesian, scratchCartographic);
return scratchCartographic.latitude;
};
var scratchProjectPointOntoPlaneRay = new Ray_default();
var scratchProjectPointOntoPlaneRayDirection = new Cartesian3_default();
var scratchProjectPointOntoPlaneCartesian3 = new Cartesian3_default();
Stereographic.fromCartesian = function(cartesian, result) {
Check_default.defined("cartesian", cartesian);
const sign = Math_default.signNotZero(cartesian.z);
let tangentPlane = Stereographic.NORTH_POLE_TANGENT_PLANE;
let origin = Stereographic.SOUTH_POLE;
if (sign < 0) {
tangentPlane = Stereographic.SOUTH_POLE_TANGENT_PLANE;
origin = Stereographic.NORTH_POLE;
}
const ray = scratchProjectPointOntoPlaneRay;
ray.origin = tangentPlane.ellipsoid.scaleToGeocentricSurface(
cartesian,
ray.origin
);
ray.direction = Cartesian3_default.subtract(
ray.origin,
origin,
scratchProjectPointOntoPlaneRayDirection
);
Cartesian3_default.normalize(ray.direction, ray.direction);
const intersectionPoint = IntersectionTests_default.rayPlane(
ray,
tangentPlane.plane,
scratchProjectPointOntoPlaneCartesian3
);
const v = Cartesian3_default.subtract(intersectionPoint, origin, intersectionPoint);
const x = Cartesian3_default.dot(tangentPlane.xAxis, v);
const y = sign * Cartesian3_default.dot(tangentPlane.yAxis, v);
if (!defined_default(result)) {
return new Stereographic(new Cartesian2_default(x, y), tangentPlane);
}
result.position = new Cartesian2_default(x, y);
result.tangentPlane = tangentPlane;
return result;
};
Stereographic.fromCartesianArray = 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] = Stereographic.fromCartesian(cartesians[i], result[i]);
}
return result;
};
Stereographic.clone = function(stereographic, result) {
if (!defined_default(stereographic)) {
return void 0;
}
if (!defined_default(result)) {
return new Stereographic(
stereographic.position,
stereographic.tangentPlane
);
}
result.position = stereographic.position;
result.tangentPlane = stereographic.tangentPlane;
return result;
};
Stereographic.HALF_UNIT_SPHERE = Object.freeze(new Ellipsoid_default(0.5, 0.5, 0.5));
Stereographic.NORTH_POLE = Object.freeze(new Cartesian3_default(0, 0, 0.5));
Stereographic.SOUTH_POLE = Object.freeze(new Cartesian3_default(0, 0, -0.5));
Stereographic.NORTH_POLE_TANGENT_PLANE = Object.freeze(
new EllipsoidTangentPlane_default(
Stereographic.NORTH_POLE,
Stereographic.HALF_UNIT_SPHERE
)
);
Stereographic.SOUTH_POLE_TANGENT_PLANE = Object.freeze(
new EllipsoidTangentPlane_default(
Stereographic.SOUTH_POLE,
Stereographic.HALF_UNIT_SPHERE
)
);
var Stereographic_default = Stereographic;
// packages/engine/Source/Core/PolygonGeometry.js
var scratchCarto1 = new Cartographic_default();
var scratchCarto2 = new Cartographic_default();
function adjustPosHeightsForNormal(position, p1, p2, ellipsoid) {
const carto1 = ellipsoid.cartesianToCartographic(position, scratchCarto1);
const height = carto1.height;
const p1Carto = ellipsoid.cartesianToCartographic(p1, scratchCarto2);
p1Carto.height = height;
ellipsoid.cartographicToCartesian(p1Carto, p1);
const p2Carto = ellipsoid.cartesianToCartographic(p2, scratchCarto2);
p2Carto.height = height - 100;
ellipsoid.cartographicToCartesian(p2Carto, p2);
}
var scratchBoundingRectangle = new BoundingRectangle_default();
var scratchPosition = new Cartesian3_default();
var scratchNormal = new Cartesian3_default();
var scratchTangent = new Cartesian3_default();
var scratchBitangent = new Cartesian3_default();
var p1Scratch = new Cartesian3_default();
var p2Scratch = new Cartesian3_default();
var scratchPerPosNormal = new Cartesian3_default();
var scratchPerPosTangent = new Cartesian3_default();
var scratchPerPosBitangent = new Cartesian3_default();
var appendTextureCoordinatesOrigin = new Cartesian2_default();
var appendTextureCoordinatesCartesian2 = new Cartesian2_default();
var appendTextureCoordinatesCartesian3 = new Cartesian3_default();
var appendTextureCoordinatesQuaternion = new Quaternion_default();
var appendTextureCoordinatesMatrix3 = new Matrix3_default();
var tangentMatrixScratch = new Matrix3_default();
function computeAttributes(options) {
const vertexFormat = options.vertexFormat;
const geometry = options.geometry;
const shadowVolume = options.shadowVolume;
const flatPositions = geometry.attributes.position.values;
const flatTexcoords = defined_default(geometry.attributes.st) ? geometry.attributes.st.values : void 0;
let length = flatPositions.length;
const wall = options.wall;
const top = options.top || wall;
const bottom = options.bottom || wall;
if (vertexFormat.st || vertexFormat.normal || vertexFormat.tangent || vertexFormat.bitangent || shadowVolume) {
const boundingRectangle = options.boundingRectangle;
const rotationAxis = options.rotationAxis;
const projectTo2d = options.projectTo2d;
const ellipsoid = options.ellipsoid;
const stRotation = options.stRotation;
const perPositionHeight = options.perPositionHeight;
const origin = appendTextureCoordinatesOrigin;
origin.x = boundingRectangle.x;
origin.y = boundingRectangle.y;
const textureCoordinates = vertexFormat.st ? new Float32Array(2 * (length / 3)) : void 0;
let normals;
if (vertexFormat.normal) {
if (perPositionHeight && top && !wall) {
normals = geometry.attributes.normal.values;
} else {
normals = new Float32Array(length);
}
}
const tangents = vertexFormat.tangent ? new Float32Array(length) : void 0;
const bitangents = vertexFormat.bitangent ? new Float32Array(length) : void 0;
const extrudeNormals = shadowVolume ? new Float32Array(length) : void 0;
let textureCoordIndex = 0;
let attrIndex = 0;
let normal = scratchNormal;
let tangent = scratchTangent;
let bitangent = scratchBitangent;
let recomputeNormal = true;
let textureMatrix = appendTextureCoordinatesMatrix3;
let tangentRotationMatrix = tangentMatrixScratch;
if (stRotation !== 0) {
let rotation = Quaternion_default.fromAxisAngle(
rotationAxis,
stRotation,
appendTextureCoordinatesQuaternion
);
textureMatrix = Matrix3_default.fromQuaternion(rotation, textureMatrix);
rotation = Quaternion_default.fromAxisAngle(
rotationAxis,
-stRotation,
appendTextureCoordinatesQuaternion
);
tangentRotationMatrix = Matrix3_default.fromQuaternion(
rotation,
tangentRotationMatrix
);
} else {
textureMatrix = Matrix3_default.clone(Matrix3_default.IDENTITY, textureMatrix);
tangentRotationMatrix = Matrix3_default.clone(
Matrix3_default.IDENTITY,
tangentRotationMatrix
);
}
let bottomOffset = 0;
let bottomOffset2 = 0;
if (top && bottom) {
bottomOffset = length / 2;
bottomOffset2 = length / 3;
length /= 2;
}
for (let i = 0; i < length; i += 3) {
const position = Cartesian3_default.fromArray(
flatPositions,
i,
appendTextureCoordinatesCartesian3
);
if (vertexFormat.st) {
if (!defined_default(flatTexcoords)) {
let p = Matrix3_default.multiplyByVector(
textureMatrix,
position,
scratchPosition
);
p = ellipsoid.scaleToGeodeticSurface(p, p);
const st = projectTo2d([p], appendTextureCoordinatesCartesian2)[0];
Cartesian2_default.subtract(st, origin, st);
const stx = Math_default.clamp(st.x / boundingRectangle.width, 0, 1);
const sty = Math_default.clamp(st.y / boundingRectangle.height, 0, 1);
if (bottom) {
textureCoordinates[textureCoordIndex + bottomOffset2] = stx;
textureCoordinates[textureCoordIndex + 1 + bottomOffset2] = sty;
}
if (top) {
textureCoordinates[textureCoordIndex] = stx;
textureCoordinates[textureCoordIndex + 1] = sty;
}
textureCoordIndex += 2;
}
}
if (vertexFormat.normal || vertexFormat.tangent || vertexFormat.bitangent || shadowVolume) {
const attrIndex1 = attrIndex + 1;
const attrIndex2 = attrIndex + 2;
if (wall) {
if (i + 3 < length) {
const p1 = Cartesian3_default.fromArray(flatPositions, i + 3, p1Scratch);
if (recomputeNormal) {
const p2 = Cartesian3_default.fromArray(
flatPositions,
i + length,
p2Scratch
);
if (perPositionHeight) {
adjustPosHeightsForNormal(position, p1, p2, ellipsoid);
}
Cartesian3_default.subtract(p1, position, p1);
Cartesian3_default.subtract(p2, position, p2);
normal = Cartesian3_default.normalize(
Cartesian3_default.cross(p2, p1, normal),
normal
);
recomputeNormal = false;
}
if (Cartesian3_default.equalsEpsilon(p1, position, Math_default.EPSILON10)) {
recomputeNormal = true;
}
}
if (vertexFormat.tangent || vertexFormat.bitangent) {
bitangent = ellipsoid.geodeticSurfaceNormal(position, bitangent);
if (vertexFormat.tangent) {
tangent = Cartesian3_default.normalize(
Cartesian3_default.cross(bitangent, normal, tangent),
tangent
);
}
}
} else {
normal = ellipsoid.geodeticSurfaceNormal(position, normal);
if (vertexFormat.tangent || vertexFormat.bitangent) {
if (perPositionHeight) {
scratchPerPosNormal = Cartesian3_default.fromArray(
normals,
attrIndex,
scratchPerPosNormal
);
scratchPerPosTangent = Cartesian3_default.cross(
Cartesian3_default.UNIT_Z,
scratchPerPosNormal,
scratchPerPosTangent
);
scratchPerPosTangent = Cartesian3_default.normalize(
Matrix3_default.multiplyByVector(
tangentRotationMatrix,
scratchPerPosTangent,
scratchPerPosTangent
),
scratchPerPosTangent
);
if (vertexFormat.bitangent) {
scratchPerPosBitangent = Cartesian3_default.normalize(
Cartesian3_default.cross(
scratchPerPosNormal,
scratchPerPosTangent,
scratchPerPosBitangent
),
scratchPerPosBitangent
);
}
}
tangent = Cartesian3_default.cross(Cartesian3_default.UNIT_Z, normal, tangent);
tangent = Cartesian3_default.normalize(
Matrix3_default.multiplyByVector(tangentRotationMatrix, tangent, tangent),
tangent
);
if (vertexFormat.bitangent) {
bitangent = Cartesian3_default.normalize(
Cartesian3_default.cross(normal, tangent, bitangent),
bitangent
);
}
}
}
if (vertexFormat.normal) {
if (options.wall) {
normals[attrIndex + bottomOffset] = normal.x;
normals[attrIndex1 + bottomOffset] = normal.y;
normals[attrIndex2 + bottomOffset] = normal.z;
} else if (bottom) {
normals[attrIndex + bottomOffset] = -normal.x;
normals[attrIndex1 + bottomOffset] = -normal.y;
normals[attrIndex2 + bottomOffset] = -normal.z;
}
if (top && !perPositionHeight || wall) {
normals[attrIndex] = normal.x;
normals[attrIndex1] = normal.y;
normals[attrIndex2] = normal.z;
}
}
if (shadowVolume) {
if (wall) {
normal = ellipsoid.geodeticSurfaceNormal(position, normal);
}
extrudeNormals[attrIndex + bottomOffset] = -normal.x;
extrudeNormals[attrIndex1 + bottomOffset] = -normal.y;
extrudeNormals[attrIndex2 + bottomOffset] = -normal.z;
}
if (vertexFormat.tangent) {
if (options.wall) {
tangents[attrIndex + bottomOffset] = tangent.x;
tangents[attrIndex1 + bottomOffset] = tangent.y;
tangents[attrIndex2 + bottomOffset] = tangent.z;
} else if (bottom) {
tangents[attrIndex + bottomOffset] = -tangent.x;
tangents[attrIndex1 + bottomOffset] = -tangent.y;
tangents[attrIndex2 + bottomOffset] = -tangent.z;
}
if (top) {
if (perPositionHeight) {
tangents[attrIndex] = scratchPerPosTangent.x;
tangents[attrIndex1] = scratchPerPosTangent.y;
tangents[attrIndex2] = scratchPerPosTangent.z;
} else {
tangents[attrIndex] = tangent.x;
tangents[attrIndex1] = tangent.y;
tangents[attrIndex2] = tangent.z;
}
}
}
if (vertexFormat.bitangent) {
if (bottom) {
bitangents[attrIndex + bottomOffset] = bitangent.x;
bitangents[attrIndex1 + bottomOffset] = bitangent.y;
bitangents[attrIndex2 + bottomOffset] = bitangent.z;
}
if (top) {
if (perPositionHeight) {
bitangents[attrIndex] = scratchPerPosBitangent.x;
bitangents[attrIndex1] = scratchPerPosBitangent.y;
bitangents[attrIndex2] = scratchPerPosBitangent.z;
} else {
bitangents[attrIndex] = bitangent.x;
bitangents[attrIndex1] = bitangent.y;
bitangents[attrIndex2] = bitangent.z;
}
}
}
attrIndex += 3;
}
}
if (vertexFormat.st && !defined_default(flatTexcoords)) {
geometry.attributes.st = new GeometryAttribute_default({
componentDatatype: ComponentDatatype_default.FLOAT,
componentsPerAttribute: 2,
values: textureCoordinates
});
}
if (vertexFormat.normal) {
geometry.attributes.normal = new GeometryAttribute_default({
componentDatatype: ComponentDatatype_default.FLOAT,
componentsPerAttribute: 3,
values: normals
});
}
if (vertexFormat.tangent) {
geometry.attributes.tangent = new GeometryAttribute_default({
componentDatatype: ComponentDatatype_default.FLOAT,
componentsPerAttribute: 3,
values: tangents
});
}
if (vertexFormat.bitangent) {
geometry.attributes.bitangent = new GeometryAttribute_default({
componentDatatype: ComponentDatatype_default.FLOAT,
componentsPerAttribute: 3,
values: bitangents
});
}
if (shadowVolume) {
geometry.attributes.extrudeDirection = new GeometryAttribute_default({
componentDatatype: ComponentDatatype_default.FLOAT,
componentsPerAttribute: 3,
values: extrudeNormals
});
}
}
if (options.extrude && defined_default(options.offsetAttribute)) {
const size = flatPositions.length / 3;
let offsetAttribute = new Uint8Array(size);
if (options.offsetAttribute === GeometryOffsetAttribute_default.TOP) {
if (top && bottom || wall) {
offsetAttribute = offsetAttribute.fill(1, 0, size / 2);
} else if (top) {
offsetAttribute = offsetAttribute.fill(1);
}
} else {
const offsetValue = options.offsetAttribute === GeometryOffsetAttribute_default.NONE ? 0 : 1;
offsetAttribute = offsetAttribute.fill(offsetValue);
}
geometry.attributes.applyOffset = new GeometryAttribute_default({
componentDatatype: ComponentDatatype_default.UNSIGNED_BYTE,
componentsPerAttribute: 1,
values: offsetAttribute
});
}
return geometry;
}
var createGeometryFromPositionsExtrudedPositions = [];
function createGeometryFromPositionsExtruded(ellipsoid, polygon2, textureCoordinates, granularity, hierarchy, perPositionHeight, closeTop, closeBottom, vertexFormat, arcType) {
const geos = {
walls: []
};
let i;
if (closeTop || closeBottom) {
const topGeo = PolygonGeometryLibrary_default.createGeometryFromPositions(
ellipsoid,
polygon2,
textureCoordinates,
granularity,
perPositionHeight,
vertexFormat,
arcType
);
const edgePoints = topGeo.attributes.position.values;
const indices = topGeo.indices;
let numPositions;
let newIndices;
if (closeTop && closeBottom) {
const topBottomPositions = edgePoints.concat(edgePoints);
numPositions = topBottomPositions.length / 3;
newIndices = IndexDatatype_default.createTypedArray(
numPositions,
indices.length * 2
);
newIndices.set(indices);
const ilength = indices.length;
const length = numPositions / 2;
for (i = 0; i < ilength; i += 3) {
const i0 = newIndices[i] + length;
const i1 = newIndices[i + 1] + length;
const i2 = newIndices[i + 2] + length;
newIndices[i + ilength] = i2;
newIndices[i + 1 + ilength] = i1;
newIndices[i + 2 + ilength] = i0;
}
topGeo.attributes.position.values = topBottomPositions;
if (perPositionHeight && vertexFormat.normal) {
const normals = topGeo.attributes.normal.values;
topGeo.attributes.normal.values = new Float32Array(
topBottomPositions.length
);
topGeo.attributes.normal.values.set(normals);
}
if (vertexFormat.st && defined_default(textureCoordinates)) {
const texcoords = topGeo.attributes.st.values;
topGeo.attributes.st.values = new Float32Array(numPositions * 2);
topGeo.attributes.st.values = texcoords.concat(texcoords);
}
topGeo.indices = newIndices;
} else if (closeBottom) {
numPositions = edgePoints.length / 3;
newIndices = IndexDatatype_default.createTypedArray(numPositions, indices.length);
for (i = 0; i < indices.length; i += 3) {
newIndices[i] = indices[i + 2];
newIndices[i + 1] = indices[i + 1];
newIndices[i + 2] = indices[i];
}
topGeo.indices = newIndices;
}
geos.topAndBottom = new GeometryInstance_default({
geometry: topGeo
});
}
let outerRing = hierarchy.outerRing;
const tangentPlane = EllipsoidTangentPlane_default.fromPoints(outerRing, ellipsoid);
let positions2D = tangentPlane.projectPointsOntoPlane(
outerRing,
createGeometryFromPositionsExtrudedPositions
);
let windingOrder = PolygonPipeline_default.computeWindingOrder2D(positions2D);
if (windingOrder === WindingOrder_default.CLOCKWISE) {
outerRing = outerRing.slice().reverse();
}
let wallGeo = PolygonGeometryLibrary_default.computeWallGeometry(
outerRing,
textureCoordinates,
ellipsoid,
granularity,
perPositionHeight,
arcType
);
geos.walls.push(
new GeometryInstance_default({
geometry: wallGeo
})
);
const holes = hierarchy.holes;
for (i = 0; i < holes.length; i++) {
let hole = holes[i];
positions2D = tangentPlane.projectPointsOntoPlane(
hole,
createGeometryFromPositionsExtrudedPositions
);
windingOrder = PolygonPipeline_default.computeWindingOrder2D(positions2D);
if (windingOrder === WindingOrder_default.COUNTER_CLOCKWISE) {
hole = hole.slice().reverse();
}
wallGeo = PolygonGeometryLibrary_default.computeWallGeometry(
hole,
textureCoordinates,
ellipsoid,
granularity,
perPositionHeight,
arcType
);
geos.walls.push(
new GeometryInstance_default({
geometry: wallGeo
})
);
}
return geos;
}
function PolygonGeometry(options) {
Check_default.typeOf.object("options", options);
Check_default.typeOf.object("options.polygonHierarchy", options.polygonHierarchy);
if (defined_default(options.perPositionHeight) && options.perPositionHeight && defined_default(options.height)) {
throw new DeveloperError_default(
"Cannot use both options.perPositionHeight and options.height"
);
}
if (defined_default(options.arcType) && options.arcType !== ArcType_default.GEODESIC && options.arcType !== ArcType_default.RHUMB) {
throw new DeveloperError_default(
"Invalid arcType. Valid options are ArcType.GEODESIC and ArcType.RHUMB."
);
}
const polygonHierarchy = options.polygonHierarchy;
const vertexFormat = defaultValue_default(options.vertexFormat, VertexFormat_default.DEFAULT);
const ellipsoid = defaultValue_default(options.ellipsoid, Ellipsoid_default.WGS84);
const granularity = defaultValue_default(
options.granularity,
Math_default.RADIANS_PER_DEGREE
);
const stRotation = defaultValue_default(options.stRotation, 0);
const textureCoordinates = options.textureCoordinates;
const perPositionHeight = defaultValue_default(options.perPositionHeight, false);
const perPositionHeightExtrude = perPositionHeight && defined_default(options.extrudedHeight);
let height = defaultValue_default(options.height, 0);
let extrudedHeight = defaultValue_default(options.extrudedHeight, height);
if (!perPositionHeightExtrude) {
const h = Math.max(height, extrudedHeight);
extrudedHeight = Math.min(height, extrudedHeight);
height = h;
}
this._vertexFormat = VertexFormat_default.clone(vertexFormat);
this._ellipsoid = Ellipsoid_default.clone(ellipsoid);
this._granularity = granularity;
this._stRotation = stRotation;
this._height = height;
this._extrudedHeight = extrudedHeight;
this._closeTop = defaultValue_default(options.closeTop, true);
this._closeBottom = defaultValue_default(options.closeBottom, true);
this._polygonHierarchy = polygonHierarchy;
this._perPositionHeight = perPositionHeight;
this._perPositionHeightExtrude = perPositionHeightExtrude;
this._shadowVolume = defaultValue_default(options.shadowVolume, false);
this._workerName = "createPolygonGeometry";
this._offsetAttribute = options.offsetAttribute;
this._arcType = defaultValue_default(options.arcType, ArcType_default.GEODESIC);
this._rectangle = void 0;
this._textureCoordinateRotationPoints = void 0;
this._textureCoordinates = textureCoordinates;
this.packedLength = PolygonGeometryLibrary_default.computeHierarchyPackedLength(
polygonHierarchy,
Cartesian3_default
) + Ellipsoid_default.packedLength + VertexFormat_default.packedLength + (textureCoordinates ? PolygonGeometryLibrary_default.computeHierarchyPackedLength(
textureCoordinates,
Cartesian2_default
) : 1) + 12;
}
PolygonGeometry.fromPositions = function(options) {
options = defaultValue_default(options, defaultValue_default.EMPTY_OBJECT);
Check_default.defined("options.positions", options.positions);
const newOptions = {
polygonHierarchy: {
positions: options.positions
},
height: options.height,
extrudedHeight: options.extrudedHeight,
vertexFormat: options.vertexFormat,
stRotation: options.stRotation,
ellipsoid: options.ellipsoid,
granularity: options.granularity,
perPositionHeight: options.perPositionHeight,
closeTop: options.closeTop,
closeBottom: options.closeBottom,
offsetAttribute: options.offsetAttribute,
arcType: options.arcType,
textureCoordinates: options.textureCoordinates
};
return new PolygonGeometry(newOptions);
};
PolygonGeometry.pack = function(value, array, startingIndex) {
Check_default.typeOf.object("value", value);
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
startingIndex = PolygonGeometryLibrary_default.packPolygonHierarchy(
value._polygonHierarchy,
array,
startingIndex,
Cartesian3_default
);
Ellipsoid_default.pack(value._ellipsoid, array, startingIndex);
startingIndex += Ellipsoid_default.packedLength;
VertexFormat_default.pack(value._vertexFormat, array, startingIndex);
startingIndex += VertexFormat_default.packedLength;
array[startingIndex++] = value._height;
array[startingIndex++] = value._extrudedHeight;
array[startingIndex++] = value._granularity;
array[startingIndex++] = value._stRotation;
array[startingIndex++] = value._perPositionHeightExtrude ? 1 : 0;
array[startingIndex++] = value._perPositionHeight ? 1 : 0;
array[startingIndex++] = value._closeTop ? 1 : 0;
array[startingIndex++] = value._closeBottom ? 1 : 0;
array[startingIndex++] = value._shadowVolume ? 1 : 0;
array[startingIndex++] = defaultValue_default(value._offsetAttribute, -1);
array[startingIndex++] = value._arcType;
if (defined_default(value._textureCoordinates)) {
startingIndex = PolygonGeometryLibrary_default.packPolygonHierarchy(
value._textureCoordinates,
array,
startingIndex,
Cartesian2_default
);
} else {
array[startingIndex++] = -1;
}
array[startingIndex++] = value.packedLength;
return array;
};
var scratchEllipsoid = Ellipsoid_default.clone(Ellipsoid_default.UNIT_SPHERE);
var scratchVertexFormat = new VertexFormat_default();
var dummyOptions = {
polygonHierarchy: {}
};
PolygonGeometry.unpack = function(array, startingIndex, result) {
Check_default.defined("array", array);
startingIndex = defaultValue_default(startingIndex, 0);
const polygonHierarchy = PolygonGeometryLibrary_default.unpackPolygonHierarchy(
array,
startingIndex,
Cartesian3_default
);
startingIndex = polygonHierarchy.startingIndex;
delete polygonHierarchy.startingIndex;
const ellipsoid = Ellipsoid_default.unpack(array, startingIndex, scratchEllipsoid);
startingIndex += Ellipsoid_default.packedLength;
const vertexFormat = VertexFormat_default.unpack(
array,
startingIndex,
scratchVertexFormat
);
startingIndex += VertexFormat_default.packedLength;
const height = array[startingIndex++];
const extrudedHeight = array[startingIndex++];
const granularity = array[startingIndex++];
const stRotation = array[startingIndex++];
const perPositionHeightExtrude = array[startingIndex++] === 1;
const perPositionHeight = array[startingIndex++] === 1;
const closeTop = array[startingIndex++] === 1;
const closeBottom = array[startingIndex++] === 1;
const shadowVolume = array[startingIndex++] === 1;
const offsetAttribute = array[startingIndex++];
const arcType = array[startingIndex++];
const textureCoordinates = array[startingIndex] === -1 ? void 0 : PolygonGeometryLibrary_default.unpackPolygonHierarchy(
array,
startingIndex,
Cartesian2_default
);
if (defined_default(textureCoordinates)) {
startingIndex = textureCoordinates.startingIndex;
delete textureCoordinates.startingIndex;
} else {
startingIndex++;
}
const packedLength = array[startingIndex++];
if (!defined_default(result)) {
result = new PolygonGeometry(dummyOptions);
}
result._polygonHierarchy = polygonHierarchy;
result._ellipsoid = Ellipsoid_default.clone(ellipsoid, result._ellipsoid);
result._vertexFormat = VertexFormat_default.clone(vertexFormat, result._vertexFormat);
result._height = height;
result._extrudedHeight = extrudedHeight;
result._granularity = granularity;
result._stRotation = stRotation;
result._perPositionHeightExtrude = perPositionHeightExtrude;
result._perPositionHeight = perPositionHeight;
result._closeTop = closeTop;
result._closeBottom = closeBottom;
result._shadowVolume = shadowVolume;
result._offsetAttribute = offsetAttribute === -1 ? void 0 : offsetAttribute;
result._arcType = arcType;
result._textureCoordinates = textureCoordinates;
result.packedLength = packedLength;
return result;
};
var scratchCartesian0 = new Cartesian2_default();
var scratchCartesian1 = new Cartesian2_default();
var scratchPolarClosest = new Stereographic_default();
function expandRectangle(polar, lastPolar, ellipsoid, arcType, polygon2, result) {
const longitude = polar.longitude;
const lonAdjusted = longitude >= 0 ? longitude : longitude + Math_default.TWO_PI;
polygon2.westOverIdl = Math.min(polygon2.westOverIdl, lonAdjusted);
polygon2.eastOverIdl = Math.max(polygon2.eastOverIdl, lonAdjusted);
result.west = Math.min(result.west, longitude);
result.east = Math.max(result.east, longitude);
const latitude = polar.getLatitude(ellipsoid);
let segmentLatitude = latitude;
result.south = Math.min(result.south, latitude);
result.north = Math.max(result.north, latitude);
if (arcType !== ArcType_default.RHUMB) {
const segment = Cartesian2_default.subtract(
lastPolar.position,
polar.position,
scratchCartesian0
);
const t = Cartesian2_default.dot(lastPolar.position, segment) / Cartesian2_default.dot(segment, segment);
if (t > 0 && t < 1) {
const projected = Cartesian2_default.add(
lastPolar.position,
Cartesian2_default.multiplyByScalar(segment, -t, segment),
scratchCartesian1
);
const closestPolar = Stereographic_default.clone(lastPolar, scratchPolarClosest);
closestPolar.position = projected;
const adjustedLatitude = closestPolar.getLatitude(ellipsoid);
result.south = Math.min(result.south, adjustedLatitude);
result.north = Math.max(result.north, adjustedLatitude);
if (Math.abs(latitude) > Math.abs(adjustedLatitude)) {
segmentLatitude = adjustedLatitude;
}
}
}
const direction = lastPolar.x * polar.y - polar.x * lastPolar.y;
let angle = Math.sign(direction);
if (angle !== 0) {
angle *= Cartesian2_default.angleBetween(lastPolar.position, polar.position);
}
if (segmentLatitude >= 0) {
polygon2.northAngle += angle;
}
if (segmentLatitude <= 0) {
polygon2.southAngle += angle;
}
}
var scratchPolar = new Stereographic_default();
var scratchPolarPrevious = new Stereographic_default();
var polygon = {
northAngle: 0,
southAngle: 0,
westOverIdl: 0,
eastOverIdl: 0
};
PolygonGeometry.computeRectangleFromPositions = function(positions, ellipsoid, arcType, result) {
Check_default.defined("positions", positions);
if (!defined_default(result)) {
result = new Rectangle_default();
}
if (positions.length < 3) {
return result;
}
result.west = Number.POSITIVE_INFINITY;
result.east = Number.NEGATIVE_INFINITY;
result.south = Number.POSITIVE_INFINITY;
result.north = Number.NEGATIVE_INFINITY;
polygon.northAngle = 0;
polygon.southAngle = 0;
polygon.westOverIdl = Number.POSITIVE_INFINITY;
polygon.eastOverIdl = Number.NEGATIVE_INFINITY;
const positionsLength = positions.length;
let lastPolarPosition = Stereographic_default.fromCartesian(
positions[0],
scratchPolarPrevious
);
for (let i = 1; i < positionsLength; i++) {
const polarPosition = Stereographic_default.fromCartesian(
positions[i],
scratchPolar
);
expandRectangle(
polarPosition,
lastPolarPosition,
ellipsoid,
arcType,
polygon,
result
);
lastPolarPosition = Stereographic_default.clone(polarPosition, lastPolarPosition);
}
expandRectangle(
Stereographic_default.fromCartesian(positions[0], scratchPolar),
lastPolarPosition,
ellipsoid,
arcType,
polygon,
result
);
if (result.east - result.west > polygon.eastOverIdl - polygon.westOverIdl) {
result.west = polygon.westOverIdl;
result.east = polygon.eastOverIdl;
if (result.east > Math_default.PI) {
result.east = result.east - Math_default.TWO_PI;
}
if (result.west > Math_default.PI) {
result.west = result.west - Math_default.TWO_PI;
}
}
if (Math_default.equalsEpsilon(
Math.abs(polygon.northAngle),
Math_default.TWO_PI,
Math_default.EPSILON10
)) {
result.north = Math_default.PI_OVER_TWO;
result.east = Math_default.PI;
result.west = -Math_default.PI;
}
if (Math_default.equalsEpsilon(
Math.abs(polygon.southAngle),
Math_default.TWO_PI,
Math_default.EPSILON10
)) {
result.south = -Math_default.PI_OVER_TWO;
result.east = Math_default.PI;
result.west = -Math_default.PI;
}
return result;
};
var scratchPolarForPlane = new Stereographic_default();
function getTangentPlane(rectangle, positions, ellipsoid) {
if (rectangle.height >= Math_default.PI || rectangle.width >= Math_default.PI) {
const polar = Stereographic_default.fromCartesian(
positions[0],
scratchPolarForPlane
);
return polar.tangentPlane;
}
return EllipsoidTangentPlane_default.fromPoints(positions, ellipsoid);
}
var scratchCartographicCyllindrical = new Cartographic_default();
function createProjectTo2d(rectangle, outerPositions, ellipsoid) {
return (positions, results) => {
if (rectangle.height >= Math_default.PI || rectangle.width >= Math_default.PI) {
if (rectangle.south < 0 && rectangle.north > 0) {
if (!defined_default(results)) {
results = [];
}
for (let i = 0; i < positions.length; ++i) {
const cartographic = ellipsoid.cartesianToCartographic(
positions[i],
scratchCartographicCyllindrical
);
results[i] = new Cartesian2_default(
cartographic.longitude / Math_default.PI,
cartographic.latitude / Math_default.PI_OVER_TWO
);
}
results.length = positions.length;
return results;
}
return Stereographic_default.fromCartesianArray(positions, results);
}
const tangentPlane = EllipsoidTangentPlane_default.fromPoints(
outerPositions,
ellipsoid
);
return tangentPlane.projectPointsOntoPlane(positions, results);
};
}
function createProjectPositionTo2d(rectangle, outerRing, ellipsoid) {
if (rectangle.height >= Math_default.PI || rectangle.width >= Math_default.PI) {
return (position, result) => {
if (rectangle.south < 0 && rectangle.north > 0) {
const cartographic = ellipsoid.cartesianToCartographic(
position,
scratchCartographicCyllindrical
);
if (!defined_default(result)) {
result = new Cartesian2_default();
}
result.x = cartographic.longitude / Math_default.PI;
result.y = cartographic.latitude / Math_default.PI_OVER_TWO;
return result;
}
return Stereographic_default.fromCartesian(position, result);
};
}
const tangentPlane = EllipsoidTangentPlane_default.fromPoints(outerRing, ellipsoid);
return (position, result) => {
return tangentPlane.projectPointsOntoPlane(position, result);
};
}
function createSplitPolygons(rectangle, ellipsoid, arcType, perPositionHeight) {
return (polygons, results) => {
if (!perPositionHeight && (rectangle.height >= Math_default.PI_OVER_TWO || rectangle.width >= 2 * Math_default.PI_OVER_THREE)) {
return PolygonGeometryLibrary_default.splitPolygonsOnEquator(
polygons,
ellipsoid,
arcType,
results
);
}
return polygons;
};
}
function computeBoundingRectangle(outerRing, rectangle, ellipsoid, stRotation) {
if (rectangle.height >= Math_default.PI || rectangle.width >= Math_default.PI) {
return BoundingRectangle_default.fromRectangle(
rectangle,
void 0,
scratchBoundingRectangle
);
}
const outerPositions = outerRing;
const tangentPlane = EllipsoidTangentPlane_default.fromPoints(
outerPositions,
ellipsoid
);
return PolygonGeometryLibrary_default.computeBoundingRectangle(
tangentPlane.plane.normal,
tangentPlane.projectPointOntoPlane.bind(tangentPlane),
outerPositions,
stRotation,
scratchBoundingRectangle
);
}
PolygonGeometry.createGeometry = function(polygonGeometry) {
const vertexFormat = polygonGeometry._vertexFormat;
const ellipsoid = polygonGeometry._ellipsoid;
const granularity = polygonGeometry._granularity;
const stRotation = polygonGeometry._stRotation;
const polygonHierarchy = polygonGeometry._polygonHierarchy;
const perPositionHeight = polygonGeometry._perPositionHeight;
const closeTop = polygonGeometry._closeTop;
const closeBottom = polygonGeometry._closeBottom;
const arcType = polygonGeometry._arcType;
const textureCoordinates = polygonGeometry._textureCoordinates;
const hasTextureCoordinates = defined_default(textureCoordinates);
const outerPositions = polygonHierarchy.positions;
if (outerPositions.length < 3) {
return;
}
const rectangle = polygonGeometry.rectangle;
const results = PolygonGeometryLibrary_default.polygonsFromHierarchy(
polygonHierarchy,
hasTextureCoordinates,
createProjectTo2d(rectangle, outerPositions, ellipsoid),
!perPositionHeight,
ellipsoid,
createSplitPolygons(rectangle, ellipsoid, arcType, perPositionHeight)
);
const hierarchy = results.hierarchy;
const polygons = results.polygons;
const dummyFunction = function(identity) {
return identity;
};
const textureCoordinatePolygons = hasTextureCoordinates ? PolygonGeometryLibrary_default.polygonsFromHierarchy(
textureCoordinates,
true,
dummyFunction,
false,
ellipsoid
).polygons : void 0;
if (hierarchy.length === 0) {
return;
}
const outerRing = hierarchy[0].outerRing;
const boundingRectangle = computeBoundingRectangle(
outerRing,
rectangle,
ellipsoid,
stRotation
);
const geometries = [];
const height = polygonGeometry._height;
const extrudedHeight = polygonGeometry._extrudedHeight;
const extrude = polygonGeometry._perPositionHeightExtrude || !Math_default.equalsEpsilon(height, extrudedHeight, 0, Math_default.EPSILON2);
const options = {
perPositionHeight,
vertexFormat,
geometry: void 0,
rotationAxis: getTangentPlane(rectangle, outerRing, ellipsoid).plane.normal,
projectTo2d: createProjectPositionTo2d(rectangle, outerRing, ellipsoid),
boundingRectangle,
ellipsoid,
stRotation,
textureCoordinates: void 0,
bottom: false,
top: true,
wall: false,
extrude: false,
arcType
};
let i;
if (extrude) {
options.extrude = true;
options.top = closeTop;
options.bottom = closeBottom;
options.shadowVolume = polygonGeometry._shadowVolume;
options.offsetAttribute = polygonGeometry._offsetAttribute;
for (i = 0; i < polygons.length; i++) {
const splitGeometry = createGeometryFromPositionsExtruded(
ellipsoid,
polygons[i],
hasTextureCoordinates ? textureCoordinatePolygons[i] : void 0,
granularity,
hierarchy[i],
perPositionHeight,
closeTop,
closeBottom,
vertexFormat,
arcType
);
let topAndBottom;
if (closeTop && closeBottom) {
topAndBottom = splitGeometry.topAndBottom;
options.geometry = PolygonGeometryLibrary_default.scaleToGeodeticHeightExtruded(
topAndBottom.geometry,
height,
extrudedHeight,
ellipsoid,
perPositionHeight
);
} else if (closeTop) {
topAndBottom = splitGeometry.topAndBottom;
topAndBottom.geometry.attributes.position.values = PolygonPipeline_default.scaleToGeodeticHeight(
topAndBottom.geometry.attributes.position.values,
height,
ellipsoid,
!perPositionHeight
);
options.geometry = topAndBottom.geometry;
} else if (closeBottom) {
topAndBottom = splitGeometry.topAndBottom;
topAndBottom.geometry.attributes.position.values = PolygonPipeline_default.scaleToGeodeticHeight(
topAndBottom.geometry.attributes.position.values,
extrudedHeight,
ellipsoid,
true
);
options.geometry = topAndBottom.geometry;
}
if (closeTop || closeBottom) {
options.wall = false;
topAndBottom.geometry = computeAttributes(options);
geometries.push(topAndBottom);
}
const walls = splitGeometry.walls;
options.wall = true;
for (let k = 0; k < walls.length; k++) {
const wall = walls[k];
options.geometry = PolygonGeometryLibrary_default.scaleToGeodeticHeightExtruded(
wall.geometry,
height,
extrudedHeight,
ellipsoid,
perPositionHeight
);
wall.geometry = computeAttributes(options);
geometries.push(wall);
}
}
} else {
for (i = 0; i < polygons.length; i++) {
const geometryInstance = new GeometryInstance_default({
geometry: PolygonGeometryLibrary_default.createGeometryFromPositions(
ellipsoid,
polygons[i],
hasTextureCoordinates ? textureCoordinatePolygons[i] : void 0,
granularity,
perPositionHeight,
vertexFormat,
arcType
)
});
geometryInstance.geometry.attributes.position.values = PolygonPipeline_default.scaleToGeodeticHeight(
geometryInstance.geometry.attributes.position.values,
height,
ellipsoid,
!perPositionHeight
);
options.geometry = geometryInstance.geometry;
geometryInstance.geometry = computeAttributes(options);
if (defined_default(polygonGeometry._offsetAttribute)) {
const length = geometryInstance.geometry.attributes.position.values.length;
const offsetValue = polygonGeometry._offsetAttribute === GeometryOffsetAttribute_default.NONE ? 0 : 1;
const applyOffset = new Uint8Array(length / 3).fill(offsetValue);
geometryInstance.geometry.attributes.applyOffset = new GeometryAttribute_default(
{
componentDatatype: ComponentDatatype_default.UNSIGNED_BYTE,
componentsPerAttribute: 1,
values: applyOffset
}
);
}
geometries.push(geometryInstance);
}
}
const geometry = GeometryPipeline_default.combineInstances(geometries)[0];
geometry.attributes.position.values = new Float64Array(
geometry.attributes.position.values
);
geometry.indices = IndexDatatype_default.createTypedArray(
geometry.attributes.position.values.length / 3,
geometry.indices
);
const attributes = geometry.attributes;
const boundingSphere = BoundingSphere_default.fromVertices(
attributes.position.values
);
if (!vertexFormat.position) {
delete attributes.position;
}
return new Geometry_default({
attributes,
indices: geometry.indices,
primitiveType: geometry.primitiveType,
boundingSphere,
offsetAttribute: polygonGeometry._offsetAttribute
});
};
PolygonGeometry.createShadowVolume = function(polygonGeometry, minHeightFunc, maxHeightFunc) {
const granularity = polygonGeometry._granularity;
const ellipsoid = polygonGeometry._ellipsoid;
const minHeight = minHeightFunc(granularity, ellipsoid);
const maxHeight = maxHeightFunc(granularity, ellipsoid);
return new PolygonGeometry({
polygonHierarchy: polygonGeometry._polygonHierarchy,
ellipsoid,
stRotation: polygonGeometry._stRotation,
granularity,
perPositionHeight: false,
extrudedHeight: minHeight,
height: maxHeight,
vertexFormat: VertexFormat_default.POSITION_ONLY,
shadowVolume: true,
arcType: polygonGeometry._arcType
});
};
function textureCoordinateRotationPoints(polygonGeometry) {
const stRotation = -polygonGeometry._stRotation;
if (stRotation === 0) {
return [0, 0, 0, 1, 1, 0];
}
const ellipsoid = polygonGeometry._ellipsoid;
const positions = polygonGeometry._polygonHierarchy.positions;
const boundingRectangle = polygonGeometry.rectangle;
return Geometry_default._textureCoordinateRotationPoints(
positions,
stRotation,
ellipsoid,
boundingRectangle
);
}
Object.defineProperties(PolygonGeometry.prototype, {
/**
* @private
*/
rectangle: {
get: function() {
if (!defined_default(this._rectangle)) {
const positions = this._polygonHierarchy.positions;
this._rectangle = PolygonGeometry.computeRectangleFromPositions(
positions,
this._ellipsoid,
this._arcType
);
}
return this._rectangle;
}
},
/**
* For remapping texture coordinates when rendering PolygonGeometries as GroundPrimitives.
* @private
*/
textureCoordinateRotationPoints: {
get: function() {
if (!defined_default(this._textureCoordinateRotationPoints)) {
this._textureCoordinateRotationPoints = textureCoordinateRotationPoints(
this
);
}
return this._textureCoordinateRotationPoints;
}
}
});
var PolygonGeometry_default = PolygonGeometry;
// packages/engine/Source/Workers/createPolygonGeometry.js
function createPolygonGeometry(polygonGeometry, offset) {
if (defined_default(offset)) {
polygonGeometry = PolygonGeometry_default.unpack(polygonGeometry, offset);
}
polygonGeometry._ellipsoid = Ellipsoid_default.clone(polygonGeometry._ellipsoid);
return PolygonGeometry_default.createGeometry(polygonGeometry);
}
var createPolygonGeometry_default = createPolygonGeometry;
export {
createPolygonGeometry_default as default
};