qd-changjing/public/static/Build/CesiumUnminified/Workers/createVerticesFromGoogleEar...

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22 KiB
JavaScript

/**
* Cesium - https://github.com/CesiumGS/cesium
*
* Copyright 2011-2020 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.
*/
define(['./AxisAlignedBoundingBox-2a0ca7ef', './Transforms-8b90e17c', './Matrix2-265d9610', './when-4bbc8319', './TerrainEncoding-82b55fe0', './ComponentDatatype-aad54330', './OrientedBoundingBox-1e433348', './RuntimeError-5b082e8f', './WebMercatorProjection-d67afe4b', './createTaskProcessorWorker', './combine-e9466e32', './AttributeCompression-442278a0', './WebGLConstants-508b9636', './EllipsoidTangentPlane-f1a69a20', './IntersectionTests-596e31ec', './Plane-616c9c0a'], (function (AxisAlignedBoundingBox, Transforms, Matrix2, when, TerrainEncoding, ComponentDatatype, OrientedBoundingBox, RuntimeError, WebMercatorProjection, createTaskProcessorWorker, combine, AttributeCompression, WebGLConstants, EllipsoidTangentPlane, IntersectionTests, Plane) { 'use strict';
const sizeOfUint16 = Uint16Array.BYTES_PER_ELEMENT;
const sizeOfInt32 = Int32Array.BYTES_PER_ELEMENT;
const sizeOfUint32 = Uint32Array.BYTES_PER_ELEMENT;
const sizeOfFloat = Float32Array.BYTES_PER_ELEMENT;
const sizeOfDouble = Float64Array.BYTES_PER_ELEMENT;
function indexOfEpsilon(arr, elem, elemType) {
elemType = when.defaultValue(elemType, ComponentDatatype.CesiumMath);
const count = arr.length;
for (let i = 0; i < count; ++i) {
if (elemType.equalsEpsilon(arr[i], elem, ComponentDatatype.CesiumMath.EPSILON12)) {
return i;
}
}
return -1;
}
function createVerticesFromGoogleEarthEnterpriseBuffer(
parameters,
transferableObjects
) {
parameters.ellipsoid = Matrix2.Ellipsoid.clone(parameters.ellipsoid);
parameters.rectangle = Matrix2.Rectangle.clone(parameters.rectangle);
const statistics = processBuffer(
parameters.buffer,
parameters.relativeToCenter,
parameters.ellipsoid,
parameters.rectangle,
parameters.nativeRectangle,
parameters.exaggeration,
parameters.exaggerationRelativeHeight,
parameters.skirtHeight,
parameters.includeWebMercatorT,
parameters.negativeAltitudeExponentBias,
parameters.negativeElevationThreshold
);
const vertices = statistics.vertices;
transferableObjects.push(vertices.buffer);
const indices = statistics.indices;
transferableObjects.push(indices.buffer);
return {
vertices: vertices.buffer,
indices: indices.buffer,
numberOfAttributes: statistics.encoding.stride,
minimumHeight: statistics.minimumHeight,
maximumHeight: statistics.maximumHeight,
boundingSphere3D: statistics.boundingSphere3D,
orientedBoundingBox: statistics.orientedBoundingBox,
occludeePointInScaledSpace: statistics.occludeePointInScaledSpace,
encoding: statistics.encoding,
vertexCountWithoutSkirts: statistics.vertexCountWithoutSkirts,
indexCountWithoutSkirts: statistics.indexCountWithoutSkirts,
westIndicesSouthToNorth: statistics.westIndicesSouthToNorth,
southIndicesEastToWest: statistics.southIndicesEastToWest,
eastIndicesNorthToSouth: statistics.eastIndicesNorthToSouth,
northIndicesWestToEast: statistics.northIndicesWestToEast,
};
}
const scratchCartographic = new Matrix2.Cartographic();
const scratchCartesian = new Matrix2.Cartesian3();
const minimumScratch = new Matrix2.Cartesian3();
const maximumScratch = new Matrix2.Cartesian3();
const matrix4Scratch = new Matrix2.Matrix4();
function processBuffer(
buffer,
relativeToCenter,
ellipsoid,
rectangle,
nativeRectangle,
exaggeration,
exaggerationRelativeHeight,
skirtHeight,
includeWebMercatorT,
negativeAltitudeExponentBias,
negativeElevationThreshold
) {
let geographicWest;
let geographicSouth;
let geographicEast;
let geographicNorth;
let rectangleWidth, rectangleHeight;
if (!when.defined(rectangle)) {
geographicWest = ComponentDatatype.CesiumMath.toRadians(nativeRectangle.west);
geographicSouth = ComponentDatatype.CesiumMath.toRadians(nativeRectangle.south);
geographicEast = ComponentDatatype.CesiumMath.toRadians(nativeRectangle.east);
geographicNorth = ComponentDatatype.CesiumMath.toRadians(nativeRectangle.north);
rectangleWidth = ComponentDatatype.CesiumMath.toRadians(rectangle.width);
rectangleHeight = ComponentDatatype.CesiumMath.toRadians(rectangle.height);
} else {
geographicWest = rectangle.west;
geographicSouth = rectangle.south;
geographicEast = rectangle.east;
geographicNorth = rectangle.north;
rectangleWidth = rectangle.width;
rectangleHeight = rectangle.height;
}
// Keep track of quad borders so we can remove duplicates around the borders
const quadBorderLatitudes = [geographicSouth, geographicNorth];
const quadBorderLongitudes = [geographicWest, geographicEast];
const fromENU = Transforms.Transforms.eastNorthUpToFixedFrame(
relativeToCenter,
ellipsoid
);
const toENU = Matrix2.Matrix4.inverseTransformation(fromENU, matrix4Scratch);
let southMercatorY;
let oneOverMercatorHeight;
if (includeWebMercatorT) {
southMercatorY = WebMercatorProjection.WebMercatorProjection.geodeticLatitudeToMercatorAngle(
geographicSouth
);
oneOverMercatorHeight =
1.0 /
(WebMercatorProjection.WebMercatorProjection.geodeticLatitudeToMercatorAngle(geographicNorth) -
southMercatorY);
}
const hasExaggeration = exaggeration !== 1.0;
const includeGeodeticSurfaceNormals = hasExaggeration;
const dv = new DataView(buffer);
let minHeight = Number.POSITIVE_INFINITY;
let maxHeight = Number.NEGATIVE_INFINITY;
const minimum = minimumScratch;
minimum.x = Number.POSITIVE_INFINITY;
minimum.y = Number.POSITIVE_INFINITY;
minimum.z = Number.POSITIVE_INFINITY;
const maximum = maximumScratch;
maximum.x = Number.NEGATIVE_INFINITY;
maximum.y = Number.NEGATIVE_INFINITY;
maximum.z = Number.NEGATIVE_INFINITY;
// Compute sizes
let offset = 0;
let size = 0;
let indicesSize = 0;
let quadSize;
let quad;
for (quad = 0; quad < 4; ++quad) {
let o = offset;
quadSize = dv.getUint32(o, true);
o += sizeOfUint32;
const x = ComponentDatatype.CesiumMath.toRadians(dv.getFloat64(o, true) * 180.0);
o += sizeOfDouble;
if (indexOfEpsilon(quadBorderLongitudes, x) === -1) {
quadBorderLongitudes.push(x);
}
const y = ComponentDatatype.CesiumMath.toRadians(dv.getFloat64(o, true) * 180.0);
o += sizeOfDouble;
if (indexOfEpsilon(quadBorderLatitudes, y) === -1) {
quadBorderLatitudes.push(y);
}
o += 2 * sizeOfDouble; // stepX + stepY
let c = dv.getInt32(o, true); // Read point count
o += sizeOfInt32;
size += c;
c = dv.getInt32(o, true); // Read index count
indicesSize += c * 3;
offset += quadSize + sizeOfUint32; // Jump to next quad
}
// Quad Border points to remove duplicates
const quadBorderPoints = [];
const quadBorderIndices = [];
// Create arrays
const positions = new Array(size);
const uvs = new Array(size);
const heights = new Array(size);
const webMercatorTs = includeWebMercatorT ? new Array(size) : [];
const geodeticSurfaceNormals = includeGeodeticSurfaceNormals
? new Array(size)
: [];
const indices = new Array(indicesSize);
// Points are laid out in rows starting at SW, so storing border points as we
// come across them all points will be adjacent.
const westBorder = [];
const southBorder = [];
const eastBorder = [];
const northBorder = [];
// Each tile is split into 4 parts
let pointOffset = 0;
let indicesOffset = 0;
offset = 0;
for (quad = 0; quad < 4; ++quad) {
quadSize = dv.getUint32(offset, true);
offset += sizeOfUint32;
const startQuad = offset;
const originX = ComponentDatatype.CesiumMath.toRadians(dv.getFloat64(offset, true) * 180.0);
offset += sizeOfDouble;
const originY = ComponentDatatype.CesiumMath.toRadians(dv.getFloat64(offset, true) * 180.0);
offset += sizeOfDouble;
const stepX = ComponentDatatype.CesiumMath.toRadians(dv.getFloat64(offset, true) * 180.0);
const halfStepX = stepX * 0.5;
offset += sizeOfDouble;
const stepY = ComponentDatatype.CesiumMath.toRadians(dv.getFloat64(offset, true) * 180.0);
const halfStepY = stepY * 0.5;
offset += sizeOfDouble;
const numPoints = dv.getInt32(offset, true);
offset += sizeOfInt32;
const numFaces = dv.getInt32(offset, true);
offset += sizeOfInt32;
//const level = dv.getInt32(offset, true);
offset += sizeOfInt32;
// Keep track of quad indices to overall tile indices
const indicesMapping = new Array(numPoints);
for (let i = 0; i < numPoints; ++i) {
const longitude = originX + dv.getUint8(offset++) * stepX;
scratchCartographic.longitude = longitude;
const latitude = originY + dv.getUint8(offset++) * stepY;
scratchCartographic.latitude = latitude;
let height = dv.getFloat32(offset, true);
offset += sizeOfFloat;
// In order to support old clients, negative altitude values are stored as
// height/-2^32. Old clients see the value as really close to 0 but new clients multiply
// by -2^32 to get the real negative altitude value.
if (height !== 0 && height < negativeElevationThreshold) {
height *= -Math.pow(2, negativeAltitudeExponentBias);
}
// Height is stored in units of (1/EarthRadius) or (1/6371010.0)
height *= 6371010.0;
scratchCartographic.height = height;
// Is it along a quad border - if so check if already exists and use that index
if (
indexOfEpsilon(quadBorderLongitudes, longitude) !== -1 ||
indexOfEpsilon(quadBorderLatitudes, latitude) !== -1
) {
const index = indexOfEpsilon(
quadBorderPoints,
scratchCartographic,
Matrix2.Cartographic
);
if (index === -1) {
quadBorderPoints.push(Matrix2.Cartographic.clone(scratchCartographic));
quadBorderIndices.push(pointOffset);
} else {
indicesMapping[i] = quadBorderIndices[index];
continue;
}
}
indicesMapping[i] = pointOffset;
if (Math.abs(longitude - geographicWest) < halfStepX) {
westBorder.push({
index: pointOffset,
cartographic: Matrix2.Cartographic.clone(scratchCartographic),
});
} else if (Math.abs(longitude - geographicEast) < halfStepX) {
eastBorder.push({
index: pointOffset,
cartographic: Matrix2.Cartographic.clone(scratchCartographic),
});
} else if (Math.abs(latitude - geographicSouth) < halfStepY) {
southBorder.push({
index: pointOffset,
cartographic: Matrix2.Cartographic.clone(scratchCartographic),
});
} else if (Math.abs(latitude - geographicNorth) < halfStepY) {
northBorder.push({
index: pointOffset,
cartographic: Matrix2.Cartographic.clone(scratchCartographic),
});
}
minHeight = Math.min(height, minHeight);
maxHeight = Math.max(height, maxHeight);
heights[pointOffset] = height;
const pos = ellipsoid.cartographicToCartesian(scratchCartographic);
positions[pointOffset] = pos;
if (includeWebMercatorT) {
webMercatorTs[pointOffset] =
(WebMercatorProjection.WebMercatorProjection.geodeticLatitudeToMercatorAngle(latitude) -
southMercatorY) *
oneOverMercatorHeight;
}
if (includeGeodeticSurfaceNormals) {
const normal = ellipsoid.geodeticSurfaceNormal(pos);
geodeticSurfaceNormals[pointOffset] = normal;
}
Matrix2.Matrix4.multiplyByPoint(toENU, pos, scratchCartesian);
Matrix2.Cartesian3.minimumByComponent(scratchCartesian, minimum, minimum);
Matrix2.Cartesian3.maximumByComponent(scratchCartesian, maximum, maximum);
let u = (longitude - geographicWest) / (geographicEast - geographicWest);
u = ComponentDatatype.CesiumMath.clamp(u, 0.0, 1.0);
let v =
(latitude - geographicSouth) / (geographicNorth - geographicSouth);
v = ComponentDatatype.CesiumMath.clamp(v, 0.0, 1.0);
uvs[pointOffset] = new Matrix2.Cartesian2(u, v);
++pointOffset;
}
const facesElementCount = numFaces * 3;
for (let j = 0; j < facesElementCount; ++j, ++indicesOffset) {
indices[indicesOffset] = indicesMapping[dv.getUint16(offset, true)];
offset += sizeOfUint16;
}
if (quadSize !== offset - startQuad) {
throw new RuntimeError.RuntimeError("Invalid terrain tile.");
}
}
positions.length = pointOffset;
uvs.length = pointOffset;
heights.length = pointOffset;
if (includeWebMercatorT) {
webMercatorTs.length = pointOffset;
}
if (includeGeodeticSurfaceNormals) {
geodeticSurfaceNormals.length = pointOffset;
}
const vertexCountWithoutSkirts = pointOffset;
const indexCountWithoutSkirts = indicesOffset;
// Add skirt points
const skirtOptions = {
hMin: minHeight,
lastBorderPoint: undefined,
skirtHeight: skirtHeight,
toENU: toENU,
ellipsoid: ellipsoid,
minimum: minimum,
maximum: maximum,
};
// Sort counter clockwise from NW corner
// Corner points are in the east/west arrays
westBorder.sort(function (a, b) {
return b.cartographic.latitude - a.cartographic.latitude;
});
southBorder.sort(function (a, b) {
return a.cartographic.longitude - b.cartographic.longitude;
});
eastBorder.sort(function (a, b) {
return a.cartographic.latitude - b.cartographic.latitude;
});
northBorder.sort(function (a, b) {
return b.cartographic.longitude - a.cartographic.longitude;
});
const percentage = 0.00001;
addSkirt(
positions,
heights,
uvs,
webMercatorTs,
geodeticSurfaceNormals,
indices,
skirtOptions,
westBorder,
-percentage * rectangleWidth,
true,
-percentage * rectangleHeight
);
addSkirt(
positions,
heights,
uvs,
webMercatorTs,
geodeticSurfaceNormals,
indices,
skirtOptions,
southBorder,
-percentage * rectangleHeight,
false
);
addSkirt(
positions,
heights,
uvs,
webMercatorTs,
geodeticSurfaceNormals,
indices,
skirtOptions,
eastBorder,
percentage * rectangleWidth,
true,
percentage * rectangleHeight
);
addSkirt(
positions,
heights,
uvs,
webMercatorTs,
geodeticSurfaceNormals,
indices,
skirtOptions,
northBorder,
percentage * rectangleHeight,
false
);
// Since the corner between the north and west sides is in the west array, generate the last
// two triangles between the last north vertex and the first west vertex
if (westBorder.length > 0 && northBorder.length > 0) {
const firstBorderIndex = westBorder[0].index;
const firstSkirtIndex = vertexCountWithoutSkirts;
const lastBorderIndex = northBorder[northBorder.length - 1].index;
const lastSkirtIndex = positions.length - 1;
indices.push(
lastBorderIndex,
lastSkirtIndex,
firstSkirtIndex,
firstSkirtIndex,
firstBorderIndex,
lastBorderIndex
);
}
size = positions.length; // Get new size with skirt vertices
const boundingSphere3D = Transforms.BoundingSphere.fromPoints(positions);
let orientedBoundingBox;
if (when.defined(rectangle)) {
orientedBoundingBox = OrientedBoundingBox.OrientedBoundingBox.fromRectangle(
rectangle,
minHeight,
maxHeight,
ellipsoid
);
}
const occluder = new TerrainEncoding.EllipsoidalOccluder(ellipsoid);
const occludeePointInScaledSpace = occluder.computeHorizonCullingPointPossiblyUnderEllipsoid(
relativeToCenter,
positions,
minHeight
);
const aaBox = new AxisAlignedBoundingBox.AxisAlignedBoundingBox(minimum, maximum, relativeToCenter);
const encoding = new TerrainEncoding.TerrainEncoding(
relativeToCenter,
aaBox,
skirtOptions.hMin,
maxHeight,
fromENU,
false,
includeWebMercatorT,
includeGeodeticSurfaceNormals,
exaggeration,
exaggerationRelativeHeight
);
const vertices = new Float32Array(size * encoding.stride);
let bufferIndex = 0;
for (let k = 0; k < size; ++k) {
bufferIndex = encoding.encode(
vertices,
bufferIndex,
positions[k],
uvs[k],
heights[k],
undefined,
webMercatorTs[k],
geodeticSurfaceNormals[k]
);
}
const westIndicesSouthToNorth = westBorder
.map(function (vertex) {
return vertex.index;
})
.reverse();
const southIndicesEastToWest = southBorder
.map(function (vertex) {
return vertex.index;
})
.reverse();
const eastIndicesNorthToSouth = eastBorder
.map(function (vertex) {
return vertex.index;
})
.reverse();
const northIndicesWestToEast = northBorder
.map(function (vertex) {
return vertex.index;
})
.reverse();
southIndicesEastToWest.unshift(
eastIndicesNorthToSouth[eastIndicesNorthToSouth.length - 1]
);
southIndicesEastToWest.push(westIndicesSouthToNorth[0]);
northIndicesWestToEast.unshift(
westIndicesSouthToNorth[westIndicesSouthToNorth.length - 1]
);
northIndicesWestToEast.push(eastIndicesNorthToSouth[0]);
return {
vertices: vertices,
indices: new Uint16Array(indices),
maximumHeight: maxHeight,
minimumHeight: minHeight,
encoding: encoding,
boundingSphere3D: boundingSphere3D,
orientedBoundingBox: orientedBoundingBox,
occludeePointInScaledSpace: occludeePointInScaledSpace,
vertexCountWithoutSkirts: vertexCountWithoutSkirts,
indexCountWithoutSkirts: indexCountWithoutSkirts,
westIndicesSouthToNorth: westIndicesSouthToNorth,
southIndicesEastToWest: southIndicesEastToWest,
eastIndicesNorthToSouth: eastIndicesNorthToSouth,
northIndicesWestToEast: northIndicesWestToEast,
};
}
function addSkirt(
positions,
heights,
uvs,
webMercatorTs,
geodeticSurfaceNormals,
indices,
skirtOptions,
borderPoints,
fudgeFactor,
eastOrWest,
cornerFudge
) {
const count = borderPoints.length;
for (let j = 0; j < count; ++j) {
const borderPoint = borderPoints[j];
const borderCartographic = borderPoint.cartographic;
const borderIndex = borderPoint.index;
const currentIndex = positions.length;
const longitude = borderCartographic.longitude;
let latitude = borderCartographic.latitude;
latitude = ComponentDatatype.CesiumMath.clamp(
latitude,
-ComponentDatatype.CesiumMath.PI_OVER_TWO,
ComponentDatatype.CesiumMath.PI_OVER_TWO
); // Don't go over the poles
const height = borderCartographic.height - skirtOptions.skirtHeight;
skirtOptions.hMin = Math.min(skirtOptions.hMin, height);
Matrix2.Cartographic.fromRadians(longitude, latitude, height, scratchCartographic);
// Adjust sides to angle out
if (eastOrWest) {
scratchCartographic.longitude += fudgeFactor;
}
// Adjust top or bottom to angle out
// Since corners are in the east/west arrays angle the first and last points as well
if (!eastOrWest) {
scratchCartographic.latitude += fudgeFactor;
} else if (j === count - 1) {
scratchCartographic.latitude += cornerFudge;
} else if (j === 0) {
scratchCartographic.latitude -= cornerFudge;
}
const pos = skirtOptions.ellipsoid.cartographicToCartesian(
scratchCartographic
);
positions.push(pos);
heights.push(height);
uvs.push(Matrix2.Cartesian2.clone(uvs[borderIndex])); // Copy UVs from border point
if (webMercatorTs.length > 0) {
webMercatorTs.push(webMercatorTs[borderIndex]);
}
if (geodeticSurfaceNormals.length > 0) {
geodeticSurfaceNormals.push(geodeticSurfaceNormals[borderIndex]);
}
Matrix2.Matrix4.multiplyByPoint(skirtOptions.toENU, pos, scratchCartesian);
const minimum = skirtOptions.minimum;
const maximum = skirtOptions.maximum;
Matrix2.Cartesian3.minimumByComponent(scratchCartesian, minimum, minimum);
Matrix2.Cartesian3.maximumByComponent(scratchCartesian, maximum, maximum);
const lastBorderPoint = skirtOptions.lastBorderPoint;
if (when.defined(lastBorderPoint)) {
const lastBorderIndex = lastBorderPoint.index;
indices.push(
lastBorderIndex,
currentIndex - 1,
currentIndex,
currentIndex,
borderIndex,
lastBorderIndex
);
}
skirtOptions.lastBorderPoint = borderPoint;
}
}
var createVerticesFromGoogleEarthEnterpriseBuffer$1 = createTaskProcessorWorker(
createVerticesFromGoogleEarthEnterpriseBuffer
);
return createVerticesFromGoogleEarthEnterpriseBuffer$1;
}));
//# sourceMappingURL=createVerticesFromGoogleEarthEnterpriseBuffer.js.map