/**
* @license
* Cesium - https://github.com/CesiumGS/cesium
* Version 1.99
*
* 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.
*/
define(['exports', './Transforms-ac2d28a9', './ComponentDatatype-ebdce3ba', './defaultValue-135942ca', './Check-40d84a28', './Matrix3-ea964448', './GeometryAttribute-51d61732', './GeometryAttributes-899f8bd0', './GeometryPipeline-576f16cd', './IndexDatatype-fa75fe25', './Matrix2-f9f1b94b', './WebMercatorProjection-7dd32693'], (function (exports, Transforms, ComponentDatatype, defaultValue, Check, Matrix3, GeometryAttribute, GeometryAttributes, GeometryPipeline, IndexDatatype, Matrix2, WebMercatorProjection) { 'use strict';
/**
* Value and type information for per-instance geometry attribute that determines the geometry instance offset
*
* @alias OffsetGeometryInstanceAttribute
* @constructor
*
* @param {Number} [x=0] The x translation
* @param {Number} [y=0] The y translation
* @param {Number} [z=0] The z translation
*
* @private
*
* @see GeometryInstance
* @see GeometryInstanceAttribute
*/
function OffsetGeometryInstanceAttribute(x, y, z) {
x = defaultValue.defaultValue(x, 0);
y = defaultValue.defaultValue(y, 0);
z = defaultValue.defaultValue(z, 0);
/**
* The values for the attributes stored in a typed array.
*
* @type Float32Array
*/
this.value = new Float32Array([x, y, z]);
}
Object.defineProperties(OffsetGeometryInstanceAttribute.prototype, {
/**
* The datatype of each component in the attribute, e.g., individual elements in
* {@link OffsetGeometryInstanceAttribute#value}.
*
* @memberof OffsetGeometryInstanceAttribute.prototype
*
* @type {ComponentDatatype}
* @readonly
*
* @default {@link ComponentDatatype.FLOAT}
*/
componentDatatype: {
get: function () {
return ComponentDatatype.ComponentDatatype.FLOAT;
},
},
/**
* The number of components in the attributes, i.e., {@link OffsetGeometryInstanceAttribute#value}.
*
* @memberof OffsetGeometryInstanceAttribute.prototype
*
* @type {Number}
* @readonly
*
* @default 3
*/
componentsPerAttribute: {
get: function () {
return 3;
},
},
/**
* When true
and componentDatatype
is an integer format,
* indicate that the components should be mapped to the range [0, 1] (unsigned)
* or [-1, 1] (signed) when they are accessed as floating-point for rendering.
*
* @memberof OffsetGeometryInstanceAttribute.prototype
*
* @type {Boolean}
* @readonly
*
* @default false
*/
normalize: {
get: function () {
return false;
},
},
});
/**
* Creates a new {@link OffsetGeometryInstanceAttribute} instance given the provided an enabled flag and {@link DistanceDisplayCondition}.
*
* @param {Cartesian3} offset The cartesian offset
* @returns {OffsetGeometryInstanceAttribute} The new {@link OffsetGeometryInstanceAttribute} instance.
*/
OffsetGeometryInstanceAttribute.fromCartesian3 = function (offset) {
//>>includeStart('debug', pragmas.debug);
Check.Check.defined("offset", offset);
//>>includeEnd('debug');
return new OffsetGeometryInstanceAttribute(offset.x, offset.y, offset.z);
};
/**
* Converts a distance display condition to a typed array that can be used to assign a distance display condition attribute.
*
* @param {Cartesian3} offset The cartesian offset
* @param {Float32Array} [result] The array to store the result in, if undefined a new instance will be created.
* @returns {Float32Array} The modified result parameter or a new instance if result was undefined.
*
* @example
* const attributes = primitive.getGeometryInstanceAttributes('an id');
* attributes.modelMatrix = Cesium.OffsetGeometryInstanceAttribute.toValue(modelMatrix, attributes.modelMatrix);
*/
OffsetGeometryInstanceAttribute.toValue = function (offset, result) {
//>>includeStart('debug', pragmas.debug);
Check.Check.defined("offset", offset);
//>>includeEnd('debug');
if (!defaultValue.defined(result)) {
result = new Float32Array([offset.x, offset.y, offset.z]);
}
result[0] = offset.x;
result[1] = offset.y;
result[2] = offset.z;
return result;
};
function transformToWorldCoordinates(
instances,
primitiveModelMatrix,
scene3DOnly
) {
let toWorld = !scene3DOnly;
const length = instances.length;
let i;
if (!toWorld && length > 1) {
const modelMatrix = instances[0].modelMatrix;
for (i = 1; i < length; ++i) {
if (!Matrix2.Matrix4.equals(modelMatrix, instances[i].modelMatrix)) {
toWorld = true;
break;
}
}
}
if (toWorld) {
for (i = 0; i < length; ++i) {
if (defaultValue.defined(instances[i].geometry)) {
GeometryPipeline.GeometryPipeline.transformToWorldCoordinates(instances[i]);
}
}
} else {
// Leave geometry in local coordinate system; auto update model-matrix.
Matrix2.Matrix4.multiplyTransformation(
primitiveModelMatrix,
instances[0].modelMatrix,
primitiveModelMatrix
);
}
}
function addGeometryBatchId(geometry, batchId) {
const attributes = geometry.attributes;
const positionAttr = attributes.position;
const numberOfComponents =
positionAttr.values.length / positionAttr.componentsPerAttribute;
attributes.batchId = new GeometryAttribute.GeometryAttribute({
componentDatatype: ComponentDatatype.ComponentDatatype.FLOAT,
componentsPerAttribute: 1,
values: new Float32Array(numberOfComponents),
});
const values = attributes.batchId.values;
for (let j = 0; j < numberOfComponents; ++j) {
values[j] = batchId;
}
}
function addBatchIds(instances) {
const length = instances.length;
for (let i = 0; i < length; ++i) {
const instance = instances[i];
if (defaultValue.defined(instance.geometry)) {
addGeometryBatchId(instance.geometry, i);
} else if (
defaultValue.defined(instance.westHemisphereGeometry) &&
defaultValue.defined(instance.eastHemisphereGeometry)
) {
addGeometryBatchId(instance.westHemisphereGeometry, i);
addGeometryBatchId(instance.eastHemisphereGeometry, i);
}
}
}
function geometryPipeline(parameters) {
const instances = parameters.instances;
const projection = parameters.projection;
const uintIndexSupport = parameters.elementIndexUintSupported;
const scene3DOnly = parameters.scene3DOnly;
const vertexCacheOptimize = parameters.vertexCacheOptimize;
const compressVertices = parameters.compressVertices;
const modelMatrix = parameters.modelMatrix;
let i;
let geometry;
let primitiveType;
let length = instances.length;
for (i = 0; i < length; ++i) {
if (defaultValue.defined(instances[i].geometry)) {
primitiveType = instances[i].geometry.primitiveType;
break;
}
}
//>>includeStart('debug', pragmas.debug);
for (i = 1; i < length; ++i) {
if (
defaultValue.defined(instances[i].geometry) &&
instances[i].geometry.primitiveType !== primitiveType
) {
throw new Check.DeveloperError(
"All instance geometries must have the same primitiveType."
);
}
}
//>>includeEnd('debug');
// Unify to world coordinates before combining.
transformToWorldCoordinates(instances, modelMatrix, scene3DOnly);
// Clip to IDL
if (!scene3DOnly) {
for (i = 0; i < length; ++i) {
if (defaultValue.defined(instances[i].geometry)) {
GeometryPipeline.GeometryPipeline.splitLongitude(instances[i]);
}
}
}
addBatchIds(instances);
// Optimize for vertex shader caches
if (vertexCacheOptimize) {
for (i = 0; i < length; ++i) {
const instance = instances[i];
if (defaultValue.defined(instance.geometry)) {
GeometryPipeline.GeometryPipeline.reorderForPostVertexCache(instance.geometry);
GeometryPipeline.GeometryPipeline.reorderForPreVertexCache(instance.geometry);
} else if (
defaultValue.defined(instance.westHemisphereGeometry) &&
defaultValue.defined(instance.eastHemisphereGeometry)
) {
GeometryPipeline.GeometryPipeline.reorderForPostVertexCache(
instance.westHemisphereGeometry
);
GeometryPipeline.GeometryPipeline.reorderForPreVertexCache(
instance.westHemisphereGeometry
);
GeometryPipeline.GeometryPipeline.reorderForPostVertexCache(
instance.eastHemisphereGeometry
);
GeometryPipeline.GeometryPipeline.reorderForPreVertexCache(
instance.eastHemisphereGeometry
);
}
}
}
// Combine into single geometry for better rendering performance.
let geometries = GeometryPipeline.GeometryPipeline.combineInstances(instances);
length = geometries.length;
for (i = 0; i < length; ++i) {
geometry = geometries[i];
// Split positions for GPU RTE
const attributes = geometry.attributes;
if (!scene3DOnly) {
for (const name in attributes) {
if (
attributes.hasOwnProperty(name) &&
attributes[name].componentDatatype === ComponentDatatype.ComponentDatatype.DOUBLE
) {
const name3D = `${name}3D`;
const name2D = `${name}2D`;
// Compute 2D positions
GeometryPipeline.GeometryPipeline.projectTo2D(
geometry,
name,
name3D,
name2D,
projection
);
if (defaultValue.defined(geometry.boundingSphere) && name === "position") {
geometry.boundingSphereCV = Transforms.BoundingSphere.fromVertices(
geometry.attributes.position2D.values
);
}
GeometryPipeline.GeometryPipeline.encodeAttribute(
geometry,
name3D,
`${name3D}High`,
`${name3D}Low`
);
GeometryPipeline.GeometryPipeline.encodeAttribute(
geometry,
name2D,
`${name2D}High`,
`${name2D}Low`
);
}
}
} else {
for (const name in attributes) {
if (
attributes.hasOwnProperty(name) &&
attributes[name].componentDatatype === ComponentDatatype.ComponentDatatype.DOUBLE
) {
GeometryPipeline.GeometryPipeline.encodeAttribute(
geometry,
name,
`${name}3DHigh`,
`${name}3DLow`
);
}
}
}
// oct encode and pack normals, compress texture coordinates
if (compressVertices) {
GeometryPipeline.GeometryPipeline.compressVertices(geometry);
}
}
if (!uintIndexSupport) {
// Break into multiple geometries to fit within unsigned short indices if needed
let splitGeometries = [];
length = geometries.length;
for (i = 0; i < length; ++i) {
geometry = geometries[i];
splitGeometries = splitGeometries.concat(
GeometryPipeline.GeometryPipeline.fitToUnsignedShortIndices(geometry)
);
}
geometries = splitGeometries;
}
return geometries;
}
function createPickOffsets(instances, geometryName, geometries, pickOffsets) {
let offset;
let indexCount;
let geometryIndex;
const offsetIndex = pickOffsets.length - 1;
if (offsetIndex >= 0) {
const pickOffset = pickOffsets[offsetIndex];
offset = pickOffset.offset + pickOffset.count;
geometryIndex = pickOffset.index;
indexCount = geometries[geometryIndex].indices.length;
} else {
offset = 0;
geometryIndex = 0;
indexCount = geometries[geometryIndex].indices.length;
}
const length = instances.length;
for (let i = 0; i < length; ++i) {
const instance = instances[i];
const geometry = instance[geometryName];
if (!defaultValue.defined(geometry)) {
continue;
}
const count = geometry.indices.length;
if (offset + count > indexCount) {
offset = 0;
indexCount = geometries[++geometryIndex].indices.length;
}
pickOffsets.push({
index: geometryIndex,
offset: offset,
count: count,
});
offset += count;
}
}
function createInstancePickOffsets(instances, geometries) {
const pickOffsets = [];
createPickOffsets(instances, "geometry", geometries, pickOffsets);
createPickOffsets(
instances,
"westHemisphereGeometry",
geometries,
pickOffsets
);
createPickOffsets(
instances,
"eastHemisphereGeometry",
geometries,
pickOffsets
);
return pickOffsets;
}
/**
* @private
*/
const PrimitivePipeline = {};
/**
* @private
*/
PrimitivePipeline.combineGeometry = function (parameters) {
let geometries;
let attributeLocations;
const instances = parameters.instances;
const length = instances.length;
let pickOffsets;
let offsetInstanceExtend;
let hasOffset = false;
if (length > 0) {
geometries = geometryPipeline(parameters);
if (geometries.length > 0) {
attributeLocations = GeometryPipeline.GeometryPipeline.createAttributeLocations(
geometries[0]
);
if (parameters.createPickOffsets) {
pickOffsets = createInstancePickOffsets(instances, geometries);
}
}
if (
defaultValue.defined(instances[0].attributes) &&
defaultValue.defined(instances[0].attributes.offset)
) {
offsetInstanceExtend = new Array(length);
hasOffset = true;
}
}
const boundingSpheres = new Array(length);
const boundingSpheresCV = new Array(length);
for (let i = 0; i < length; ++i) {
const instance = instances[i];
const geometry = instance.geometry;
if (defaultValue.defined(geometry)) {
boundingSpheres[i] = geometry.boundingSphere;
boundingSpheresCV[i] = geometry.boundingSphereCV;
if (hasOffset) {
offsetInstanceExtend[i] = instance.geometry.offsetAttribute;
}
}
const eastHemisphereGeometry = instance.eastHemisphereGeometry;
const westHemisphereGeometry = instance.westHemisphereGeometry;
if (defaultValue.defined(eastHemisphereGeometry) && defaultValue.defined(westHemisphereGeometry)) {
if (
defaultValue.defined(eastHemisphereGeometry.boundingSphere) &&
defaultValue.defined(westHemisphereGeometry.boundingSphere)
) {
boundingSpheres[i] = Transforms.BoundingSphere.union(
eastHemisphereGeometry.boundingSphere,
westHemisphereGeometry.boundingSphere
);
}
if (
defaultValue.defined(eastHemisphereGeometry.boundingSphereCV) &&
defaultValue.defined(westHemisphereGeometry.boundingSphereCV)
) {
boundingSpheresCV[i] = Transforms.BoundingSphere.union(
eastHemisphereGeometry.boundingSphereCV,
westHemisphereGeometry.boundingSphereCV
);
}
}
}
return {
geometries: geometries,
modelMatrix: parameters.modelMatrix,
attributeLocations: attributeLocations,
pickOffsets: pickOffsets,
offsetInstanceExtend: offsetInstanceExtend,
boundingSpheres: boundingSpheres,
boundingSpheresCV: boundingSpheresCV,
};
};
function transferGeometry(geometry, transferableObjects) {
const attributes = geometry.attributes;
for (const name in attributes) {
if (attributes.hasOwnProperty(name)) {
const attribute = attributes[name];
if (defaultValue.defined(attribute) && defaultValue.defined(attribute.values)) {
transferableObjects.push(attribute.values.buffer);
}
}
}
if (defaultValue.defined(geometry.indices)) {
transferableObjects.push(geometry.indices.buffer);
}
}
function transferGeometries(geometries, transferableObjects) {
const length = geometries.length;
for (let i = 0; i < length; ++i) {
transferGeometry(geometries[i], transferableObjects);
}
}
// This function was created by simplifying packCreateGeometryResults into a count-only operation.
function countCreateGeometryResults(items) {
let count = 1;
const length = items.length;
for (let i = 0; i < length; i++) {
const geometry = items[i];
++count;
if (!defaultValue.defined(geometry)) {
continue;
}
const attributes = geometry.attributes;
count +=
7 +
2 * Transforms.BoundingSphere.packedLength +
(defaultValue.defined(geometry.indices) ? geometry.indices.length : 0);
for (const property in attributes) {
if (
attributes.hasOwnProperty(property) &&
defaultValue.defined(attributes[property])
) {
const attribute = attributes[property];
count += 5 + attribute.values.length;
}
}
}
return count;
}
/**
* @private
*/
PrimitivePipeline.packCreateGeometryResults = function (
items,
transferableObjects
) {
const packedData = new Float64Array(countCreateGeometryResults(items));
const stringTable = [];
const stringHash = {};
const length = items.length;
let count = 0;
packedData[count++] = length;
for (let i = 0; i < length; i++) {
const geometry = items[i];
const validGeometry = defaultValue.defined(geometry);
packedData[count++] = validGeometry ? 1.0 : 0.0;
if (!validGeometry) {
continue;
}
packedData[count++] = geometry.primitiveType;
packedData[count++] = geometry.geometryType;
packedData[count++] = defaultValue.defaultValue(geometry.offsetAttribute, -1);
const validBoundingSphere = defaultValue.defined(geometry.boundingSphere) ? 1.0 : 0.0;
packedData[count++] = validBoundingSphere;
if (validBoundingSphere) {
Transforms.BoundingSphere.pack(geometry.boundingSphere, packedData, count);
}
count += Transforms.BoundingSphere.packedLength;
const validBoundingSphereCV = defaultValue.defined(geometry.boundingSphereCV)
? 1.0
: 0.0;
packedData[count++] = validBoundingSphereCV;
if (validBoundingSphereCV) {
Transforms.BoundingSphere.pack(geometry.boundingSphereCV, packedData, count);
}
count += Transforms.BoundingSphere.packedLength;
const attributes = geometry.attributes;
const attributesToWrite = [];
for (const property in attributes) {
if (
attributes.hasOwnProperty(property) &&
defaultValue.defined(attributes[property])
) {
attributesToWrite.push(property);
if (!defaultValue.defined(stringHash[property])) {
stringHash[property] = stringTable.length;
stringTable.push(property);
}
}
}
packedData[count++] = attributesToWrite.length;
for (let q = 0; q < attributesToWrite.length; q++) {
const name = attributesToWrite[q];
const attribute = attributes[name];
packedData[count++] = stringHash[name];
packedData[count++] = attribute.componentDatatype;
packedData[count++] = attribute.componentsPerAttribute;
packedData[count++] = attribute.normalize ? 1 : 0;
packedData[count++] = attribute.values.length;
packedData.set(attribute.values, count);
count += attribute.values.length;
}
const indicesLength = defaultValue.defined(geometry.indices)
? geometry.indices.length
: 0;
packedData[count++] = indicesLength;
if (indicesLength > 0) {
packedData.set(geometry.indices, count);
count += indicesLength;
}
}
transferableObjects.push(packedData.buffer);
return {
stringTable: stringTable,
packedData: packedData,
};
};
/**
* @private
*/
PrimitivePipeline.unpackCreateGeometryResults = function (
createGeometryResult
) {
const stringTable = createGeometryResult.stringTable;
const packedGeometry = createGeometryResult.packedData;
let i;
const result = new Array(packedGeometry[0]);
let resultIndex = 0;
let packedGeometryIndex = 1;
while (packedGeometryIndex < packedGeometry.length) {
const valid = packedGeometry[packedGeometryIndex++] === 1.0;
if (!valid) {
result[resultIndex++] = undefined;
continue;
}
const primitiveType = packedGeometry[packedGeometryIndex++];
const geometryType = packedGeometry[packedGeometryIndex++];
let offsetAttribute = packedGeometry[packedGeometryIndex++];
if (offsetAttribute === -1) {
offsetAttribute = undefined;
}
let boundingSphere;
let boundingSphereCV;
const validBoundingSphere = packedGeometry[packedGeometryIndex++] === 1.0;
if (validBoundingSphere) {
boundingSphere = Transforms.BoundingSphere.unpack(
packedGeometry,
packedGeometryIndex
);
}
packedGeometryIndex += Transforms.BoundingSphere.packedLength;
const validBoundingSphereCV = packedGeometry[packedGeometryIndex++] === 1.0;
if (validBoundingSphereCV) {
boundingSphereCV = Transforms.BoundingSphere.unpack(
packedGeometry,
packedGeometryIndex
);
}
packedGeometryIndex += Transforms.BoundingSphere.packedLength;
let length;
let values;
let componentsPerAttribute;
const attributes = new GeometryAttributes.GeometryAttributes();
const numAttributes = packedGeometry[packedGeometryIndex++];
for (i = 0; i < numAttributes; i++) {
const name = stringTable[packedGeometry[packedGeometryIndex++]];
const componentDatatype = packedGeometry[packedGeometryIndex++];
componentsPerAttribute = packedGeometry[packedGeometryIndex++];
const normalize = packedGeometry[packedGeometryIndex++] !== 0;
length = packedGeometry[packedGeometryIndex++];
values = ComponentDatatype.ComponentDatatype.createTypedArray(componentDatatype, length);
for (let valuesIndex = 0; valuesIndex < length; valuesIndex++) {
values[valuesIndex] = packedGeometry[packedGeometryIndex++];
}
attributes[name] = new GeometryAttribute.GeometryAttribute({
componentDatatype: componentDatatype,
componentsPerAttribute: componentsPerAttribute,
normalize: normalize,
values: values,
});
}
let indices;
length = packedGeometry[packedGeometryIndex++];
if (length > 0) {
const numberOfVertices = values.length / componentsPerAttribute;
indices = IndexDatatype.IndexDatatype.createTypedArray(numberOfVertices, length);
for (i = 0; i < length; i++) {
indices[i] = packedGeometry[packedGeometryIndex++];
}
}
result[resultIndex++] = new GeometryAttribute.Geometry({
primitiveType: primitiveType,
geometryType: geometryType,
boundingSphere: boundingSphere,
boundingSphereCV: boundingSphereCV,
indices: indices,
attributes: attributes,
offsetAttribute: offsetAttribute,
});
}
return result;
};
function packInstancesForCombine(instances, transferableObjects) {
const length = instances.length;
const packedData = new Float64Array(1 + length * 19);
let count = 0;
packedData[count++] = length;
for (let i = 0; i < length; i++) {
const instance = instances[i];
Matrix2.Matrix4.pack(instance.modelMatrix, packedData, count);
count += Matrix2.Matrix4.packedLength;
if (defaultValue.defined(instance.attributes) && defaultValue.defined(instance.attributes.offset)) {
const values = instance.attributes.offset.value;
packedData[count] = values[0];
packedData[count + 1] = values[1];
packedData[count + 2] = values[2];
}
count += 3;
}
transferableObjects.push(packedData.buffer);
return packedData;
}
function unpackInstancesForCombine(data) {
const packedInstances = data;
const result = new Array(packedInstances[0]);
let count = 0;
let i = 1;
while (i < packedInstances.length) {
const modelMatrix = Matrix2.Matrix4.unpack(packedInstances, i);
let attributes;
i += Matrix2.Matrix4.packedLength;
if (defaultValue.defined(packedInstances[i])) {
attributes = {
offset: new OffsetGeometryInstanceAttribute(
packedInstances[i],
packedInstances[i + 1],
packedInstances[i + 2]
),
};
}
i += 3;
result[count++] = {
modelMatrix: modelMatrix,
attributes: attributes,
};
}
return result;
}
/**
* @private
*/
PrimitivePipeline.packCombineGeometryParameters = function (
parameters,
transferableObjects
) {
const createGeometryResults = parameters.createGeometryResults;
const length = createGeometryResults.length;
for (let i = 0; i < length; i++) {
transferableObjects.push(createGeometryResults[i].packedData.buffer);
}
return {
createGeometryResults: parameters.createGeometryResults,
packedInstances: packInstancesForCombine(
parameters.instances,
transferableObjects
),
ellipsoid: parameters.ellipsoid,
isGeographic: parameters.projection instanceof Transforms.GeographicProjection,
elementIndexUintSupported: parameters.elementIndexUintSupported,
scene3DOnly: parameters.scene3DOnly,
vertexCacheOptimize: parameters.vertexCacheOptimize,
compressVertices: parameters.compressVertices,
modelMatrix: parameters.modelMatrix,
createPickOffsets: parameters.createPickOffsets,
};
};
/**
* @private
*/
PrimitivePipeline.unpackCombineGeometryParameters = function (
packedParameters
) {
const instances = unpackInstancesForCombine(packedParameters.packedInstances);
const createGeometryResults = packedParameters.createGeometryResults;
const length = createGeometryResults.length;
let instanceIndex = 0;
for (let resultIndex = 0; resultIndex < length; resultIndex++) {
const geometries = PrimitivePipeline.unpackCreateGeometryResults(
createGeometryResults[resultIndex]
);
const geometriesLength = geometries.length;
for (
let geometryIndex = 0;
geometryIndex < geometriesLength;
geometryIndex++
) {
const geometry = geometries[geometryIndex];
const instance = instances[instanceIndex];
instance.geometry = geometry;
++instanceIndex;
}
}
const ellipsoid = Matrix3.Ellipsoid.clone(packedParameters.ellipsoid);
const projection = packedParameters.isGeographic
? new Transforms.GeographicProjection(ellipsoid)
: new WebMercatorProjection.WebMercatorProjection(ellipsoid);
return {
instances: instances,
ellipsoid: ellipsoid,
projection: projection,
elementIndexUintSupported: packedParameters.elementIndexUintSupported,
scene3DOnly: packedParameters.scene3DOnly,
vertexCacheOptimize: packedParameters.vertexCacheOptimize,
compressVertices: packedParameters.compressVertices,
modelMatrix: Matrix2.Matrix4.clone(packedParameters.modelMatrix),
createPickOffsets: packedParameters.createPickOffsets,
};
};
function packBoundingSpheres(boundingSpheres) {
const length = boundingSpheres.length;
const bufferLength = 1 + (Transforms.BoundingSphere.packedLength + 1) * length;
const buffer = new Float32Array(bufferLength);
let bufferIndex = 0;
buffer[bufferIndex++] = length;
for (let i = 0; i < length; ++i) {
const bs = boundingSpheres[i];
if (!defaultValue.defined(bs)) {
buffer[bufferIndex++] = 0.0;
} else {
buffer[bufferIndex++] = 1.0;
Transforms.BoundingSphere.pack(boundingSpheres[i], buffer, bufferIndex);
}
bufferIndex += Transforms.BoundingSphere.packedLength;
}
return buffer;
}
function unpackBoundingSpheres(buffer) {
const result = new Array(buffer[0]);
let count = 0;
let i = 1;
while (i < buffer.length) {
if (buffer[i++] === 1.0) {
result[count] = Transforms.BoundingSphere.unpack(buffer, i);
}
++count;
i += Transforms.BoundingSphere.packedLength;
}
return result;
}
/**
* @private
*/
PrimitivePipeline.packCombineGeometryResults = function (
results,
transferableObjects
) {
if (defaultValue.defined(results.geometries)) {
transferGeometries(results.geometries, transferableObjects);
}
const packedBoundingSpheres = packBoundingSpheres(results.boundingSpheres);
const packedBoundingSpheresCV = packBoundingSpheres(
results.boundingSpheresCV
);
transferableObjects.push(
packedBoundingSpheres.buffer,
packedBoundingSpheresCV.buffer
);
return {
geometries: results.geometries,
attributeLocations: results.attributeLocations,
modelMatrix: results.modelMatrix,
pickOffsets: results.pickOffsets,
offsetInstanceExtend: results.offsetInstanceExtend,
boundingSpheres: packedBoundingSpheres,
boundingSpheresCV: packedBoundingSpheresCV,
};
};
/**
* @private
*/
PrimitivePipeline.unpackCombineGeometryResults = function (packedResult) {
return {
geometries: packedResult.geometries,
attributeLocations: packedResult.attributeLocations,
modelMatrix: packedResult.modelMatrix,
pickOffsets: packedResult.pickOffsets,
offsetInstanceExtend: packedResult.offsetInstanceExtend,
boundingSpheres: unpackBoundingSpheres(packedResult.boundingSpheres),
boundingSpheresCV: unpackBoundingSpheres(packedResult.boundingSpheresCV),
};
};
var PrimitivePipeline$1 = PrimitivePipeline;
exports.PrimitivePipeline = PrimitivePipeline$1;
}));