/* This file is automatically rebuilt by the Cesium build process. */ define(['exports', './defined-26bd4a03', './Math-fa6e45cb', './Cartesian2-2a723276', './Transforms-65aba0a4', './PolylineVolumeGeometryLibrary-57289189', './PolylinePipeline-b4161aaf'], function (exports, defined, _Math, Cartesian2, Transforms, PolylineVolumeGeometryLibrary, PolylinePipeline) { 'use strict'; /** * @private */ var CorridorGeometryLibrary = {}; var scratch1 = new Cartesian2.Cartesian3(); var scratch2 = new Cartesian2.Cartesian3(); var scratch3 = new Cartesian2.Cartesian3(); var scratch4 = new Cartesian2.Cartesian3(); var scaleArray2 = [new Cartesian2.Cartesian3(), new Cartesian2.Cartesian3()]; var cartesian1 = new Cartesian2.Cartesian3(); var cartesian2 = new Cartesian2.Cartesian3(); var cartesian3 = new Cartesian2.Cartesian3(); var cartesian4 = new Cartesian2.Cartesian3(); var cartesian5 = new Cartesian2.Cartesian3(); var cartesian6 = new Cartesian2.Cartesian3(); var cartesian7 = new Cartesian2.Cartesian3(); var cartesian8 = new Cartesian2.Cartesian3(); var cartesian9 = new Cartesian2.Cartesian3(); var cartesian10 = new Cartesian2.Cartesian3(); var quaterion = new Transforms.Quaternion(); var rotMatrix = new Transforms.Matrix3(); function computeRoundCorner(cornerPoint, startPoint, endPoint, cornerType, leftIsOutside) { var angle = Cartesian2.Cartesian3.angleBetween(Cartesian2.Cartesian3.subtract(startPoint, cornerPoint, scratch1), Cartesian2.Cartesian3.subtract(endPoint, cornerPoint, scratch2)); var granularity = (cornerType === PolylineVolumeGeometryLibrary.CornerType.BEVELED) ? 1 : Math.ceil(angle / _Math.CesiumMath.toRadians(5)) + 1; var size = granularity * 3; var array = new Array(size); array[size - 3] = endPoint.x; array[size - 2] = endPoint.y; array[size - 1] = endPoint.z; var m; if (leftIsOutside) { m = Transforms.Matrix3.fromQuaternion(Transforms.Quaternion.fromAxisAngle(Cartesian2.Cartesian3.negate(cornerPoint, scratch1), angle / granularity, quaterion), rotMatrix); } else { m = Transforms.Matrix3.fromQuaternion(Transforms.Quaternion.fromAxisAngle(cornerPoint, angle / granularity, quaterion), rotMatrix); } var index = 0; startPoint = Cartesian2.Cartesian3.clone(startPoint, scratch1); for (var i = 0; i < granularity; i++) { startPoint = Transforms.Matrix3.multiplyByVector(m, startPoint, startPoint); array[index++] = startPoint.x; array[index++] = startPoint.y; array[index++] = startPoint.z; } return array; } function addEndCaps(calculatedPositions) { var cornerPoint = cartesian1; var startPoint = cartesian2; var endPoint = cartesian3; var leftEdge = calculatedPositions[1]; startPoint = Cartesian2.Cartesian3.fromArray(calculatedPositions[1], leftEdge.length - 3, startPoint); endPoint = Cartesian2.Cartesian3.fromArray(calculatedPositions[0], 0, endPoint); cornerPoint = Cartesian2.Cartesian3.midpoint(startPoint, endPoint, cornerPoint); var firstEndCap = computeRoundCorner(cornerPoint, startPoint, endPoint, PolylineVolumeGeometryLibrary.CornerType.ROUNDED, false); var length = calculatedPositions.length - 1; var rightEdge = calculatedPositions[length - 1]; leftEdge = calculatedPositions[length]; startPoint = Cartesian2.Cartesian3.fromArray(rightEdge, rightEdge.length - 3, startPoint); endPoint = Cartesian2.Cartesian3.fromArray(leftEdge, 0, endPoint); cornerPoint = Cartesian2.Cartesian3.midpoint(startPoint, endPoint, cornerPoint); var lastEndCap = computeRoundCorner(cornerPoint, startPoint, endPoint, PolylineVolumeGeometryLibrary.CornerType.ROUNDED, false); return [firstEndCap, lastEndCap]; } function computeMiteredCorner(position, leftCornerDirection, lastPoint, leftIsOutside) { var cornerPoint = scratch1; if (leftIsOutside) { cornerPoint = Cartesian2.Cartesian3.add(position, leftCornerDirection, cornerPoint); } else { leftCornerDirection = Cartesian2.Cartesian3.negate(leftCornerDirection, leftCornerDirection); cornerPoint = Cartesian2.Cartesian3.add(position, leftCornerDirection, cornerPoint); } return [cornerPoint.x, cornerPoint.y, cornerPoint.z, lastPoint.x, lastPoint.y, lastPoint.z]; } function addShiftedPositions(positions, left, scalar, calculatedPositions) { var rightPositions = new Array(positions.length); var leftPositions = new Array(positions.length); var scaledLeft = Cartesian2.Cartesian3.multiplyByScalar(left, scalar, scratch1); var scaledRight = Cartesian2.Cartesian3.negate(scaledLeft, scratch2); var rightIndex = 0; var leftIndex = positions.length - 1; for (var i = 0; i < positions.length; i += 3) { var pos = Cartesian2.Cartesian3.fromArray(positions, i, scratch3); var rightPos = Cartesian2.Cartesian3.add(pos, scaledRight, scratch4); rightPositions[rightIndex++] = rightPos.x; rightPositions[rightIndex++] = rightPos.y; rightPositions[rightIndex++] = rightPos.z; var leftPos = Cartesian2.Cartesian3.add(pos, scaledLeft, scratch4); leftPositions[leftIndex--] = leftPos.z; leftPositions[leftIndex--] = leftPos.y; leftPositions[leftIndex--] = leftPos.x; } calculatedPositions.push(rightPositions, leftPositions); return calculatedPositions; } /** * @private */ CorridorGeometryLibrary.addAttribute = function(attribute, value, front, back) { var x = value.x; var y = value.y; var z = value.z; if (defined.defined(front)) { attribute[front] = x; attribute[front + 1] = y; attribute[front + 2] = z; } if (defined.defined(back)) { attribute[back] = z; attribute[back - 1] = y; attribute[back - 2] = x; } }; var scratchForwardProjection = new Cartesian2.Cartesian3(); var scratchBackwardProjection = new Cartesian2.Cartesian3(); /** * @private */ CorridorGeometryLibrary.computePositions = function(params) { var granularity = params.granularity; var positions = params.positions; var ellipsoid = params.ellipsoid; var width = params.width / 2; var cornerType = params.cornerType; var saveAttributes = params.saveAttributes; var normal = cartesian1; var forward = cartesian2; var backward = cartesian3; var left = cartesian4; var cornerDirection = cartesian5; var startPoint = cartesian6; var previousPos = cartesian7; var rightPos = cartesian8; var leftPos = cartesian9; var center = cartesian10; var calculatedPositions = []; var calculatedLefts = (saveAttributes) ? [] : undefined; var calculatedNormals = (saveAttributes) ? [] : undefined; var position = positions[0]; //add first point var nextPosition = positions[1]; forward = Cartesian2.Cartesian3.normalize(Cartesian2.Cartesian3.subtract(nextPosition, position, forward), forward); normal = ellipsoid.geodeticSurfaceNormal(position, normal); left = Cartesian2.Cartesian3.normalize(Cartesian2.Cartesian3.cross(normal, forward, left), left); if (saveAttributes) { calculatedLefts.push(left.x, left.y, left.z); calculatedNormals.push(normal.x, normal.y, normal.z); } previousPos = Cartesian2.Cartesian3.clone(position, previousPos); position = nextPosition; backward = Cartesian2.Cartesian3.negate(forward, backward); var subdividedPositions; var corners = []; var i; var length = positions.length; for (i = 1; i < length - 1; i++) { // add middle points and corners normal = ellipsoid.geodeticSurfaceNormal(position, normal); nextPosition = positions[i + 1]; forward = Cartesian2.Cartesian3.normalize(Cartesian2.Cartesian3.subtract(nextPosition, position, forward), forward); cornerDirection = Cartesian2.Cartesian3.normalize(Cartesian2.Cartesian3.add(forward, backward, cornerDirection), cornerDirection); var forwardProjection = Cartesian2.Cartesian3.multiplyByScalar(normal, Cartesian2.Cartesian3.dot(forward, normal), scratchForwardProjection); Cartesian2.Cartesian3.subtract(forward, forwardProjection, forwardProjection); Cartesian2.Cartesian3.normalize(forwardProjection, forwardProjection); var backwardProjection = Cartesian2.Cartesian3.multiplyByScalar(normal, Cartesian2.Cartesian3.dot(backward, normal), scratchBackwardProjection); Cartesian2.Cartesian3.subtract(backward, backwardProjection, backwardProjection); Cartesian2.Cartesian3.normalize(backwardProjection, backwardProjection); var doCorner = !_Math.CesiumMath.equalsEpsilon(Math.abs(Cartesian2.Cartesian3.dot(forwardProjection, backwardProjection)), 1.0, _Math.CesiumMath.EPSILON7); if (doCorner) { cornerDirection = Cartesian2.Cartesian3.cross(cornerDirection, normal, cornerDirection); cornerDirection = Cartesian2.Cartesian3.cross(normal, cornerDirection, cornerDirection); cornerDirection = Cartesian2.Cartesian3.normalize(cornerDirection, cornerDirection); var scalar = width / Math.max(0.25, Cartesian2.Cartesian3.magnitude(Cartesian2.Cartesian3.cross(cornerDirection, backward, scratch1))); var leftIsOutside = PolylineVolumeGeometryLibrary.PolylineVolumeGeometryLibrary.angleIsGreaterThanPi(forward, backward, position, ellipsoid); cornerDirection = Cartesian2.Cartesian3.multiplyByScalar(cornerDirection, scalar, cornerDirection); if (leftIsOutside) { rightPos = Cartesian2.Cartesian3.add(position, cornerDirection, rightPos); center = Cartesian2.Cartesian3.add(rightPos, Cartesian2.Cartesian3.multiplyByScalar(left, width, center), center); leftPos = Cartesian2.Cartesian3.add(rightPos, Cartesian2.Cartesian3.multiplyByScalar(left, width * 2, leftPos), leftPos); scaleArray2[0] = Cartesian2.Cartesian3.clone(previousPos, scaleArray2[0]); scaleArray2[1] = Cartesian2.Cartesian3.clone(center, scaleArray2[1]); subdividedPositions = PolylinePipeline.PolylinePipeline.generateArc({ positions: scaleArray2, granularity: granularity, ellipsoid: ellipsoid }); calculatedPositions = addShiftedPositions(subdividedPositions, left, width, calculatedPositions); if (saveAttributes) { calculatedLefts.push(left.x, left.y, left.z); calculatedNormals.push(normal.x, normal.y, normal.z); } startPoint = Cartesian2.Cartesian3.clone(leftPos, startPoint); left = Cartesian2.Cartesian3.normalize(Cartesian2.Cartesian3.cross(normal, forward, left), left); leftPos = Cartesian2.Cartesian3.add(rightPos, Cartesian2.Cartesian3.multiplyByScalar(left, width * 2, leftPos), leftPos); previousPos = Cartesian2.Cartesian3.add(rightPos, Cartesian2.Cartesian3.multiplyByScalar(left, width, previousPos), previousPos); if (cornerType === PolylineVolumeGeometryLibrary.CornerType.ROUNDED || cornerType === PolylineVolumeGeometryLibrary.CornerType.BEVELED) { corners.push({ leftPositions : computeRoundCorner(rightPos, startPoint, leftPos, cornerType, leftIsOutside) }); } else { corners.push({ leftPositions : computeMiteredCorner(position, Cartesian2.Cartesian3.negate(cornerDirection, cornerDirection), leftPos, leftIsOutside) }); } } else { leftPos = Cartesian2.Cartesian3.add(position, cornerDirection, leftPos); center = Cartesian2.Cartesian3.add(leftPos, Cartesian2.Cartesian3.negate(Cartesian2.Cartesian3.multiplyByScalar(left, width, center), center), center); rightPos = Cartesian2.Cartesian3.add(leftPos, Cartesian2.Cartesian3.negate(Cartesian2.Cartesian3.multiplyByScalar(left, width * 2, rightPos), rightPos), rightPos); scaleArray2[0] = Cartesian2.Cartesian3.clone(previousPos, scaleArray2[0]); scaleArray2[1] = Cartesian2.Cartesian3.clone(center, scaleArray2[1]); subdividedPositions = PolylinePipeline.PolylinePipeline.generateArc({ positions: scaleArray2, granularity: granularity, ellipsoid: ellipsoid }); calculatedPositions = addShiftedPositions(subdividedPositions, left, width, calculatedPositions); if (saveAttributes) { calculatedLefts.push(left.x, left.y, left.z); calculatedNormals.push(normal.x, normal.y, normal.z); } startPoint = Cartesian2.Cartesian3.clone(rightPos, startPoint); left = Cartesian2.Cartesian3.normalize(Cartesian2.Cartesian3.cross(normal, forward, left), left); rightPos = Cartesian2.Cartesian3.add(leftPos, Cartesian2.Cartesian3.negate(Cartesian2.Cartesian3.multiplyByScalar(left, width * 2, rightPos), rightPos), rightPos); previousPos = Cartesian2.Cartesian3.add(leftPos, Cartesian2.Cartesian3.negate(Cartesian2.Cartesian3.multiplyByScalar(left, width, previousPos), previousPos), previousPos); if (cornerType === PolylineVolumeGeometryLibrary.CornerType.ROUNDED || cornerType === PolylineVolumeGeometryLibrary.CornerType.BEVELED) { corners.push({ rightPositions : computeRoundCorner(leftPos, startPoint, rightPos, cornerType, leftIsOutside) }); } else { corners.push({ rightPositions : computeMiteredCorner(position, cornerDirection, rightPos, leftIsOutside) }); } } backward = Cartesian2.Cartesian3.negate(forward, backward); } position = nextPosition; } normal = ellipsoid.geodeticSurfaceNormal(position, normal); scaleArray2[0] = Cartesian2.Cartesian3.clone(previousPos, scaleArray2[0]); scaleArray2[1] = Cartesian2.Cartesian3.clone(position, scaleArray2[1]); subdividedPositions = PolylinePipeline.PolylinePipeline.generateArc({ positions: scaleArray2, granularity: granularity, ellipsoid: ellipsoid }); calculatedPositions = addShiftedPositions(subdividedPositions, left, width, calculatedPositions); if (saveAttributes) { calculatedLefts.push(left.x, left.y, left.z); calculatedNormals.push(normal.x, normal.y, normal.z); } var endPositions; if (cornerType === PolylineVolumeGeometryLibrary.CornerType.ROUNDED) { endPositions = addEndCaps(calculatedPositions); } return { positions : calculatedPositions, corners : corners, lefts : calculatedLefts, normals : calculatedNormals, endPositions : endPositions }; }; exports.CorridorGeometryLibrary = CorridorGeometryLibrary; });