/**
* @private
*/
function bisect(items, x, lo, hi) {
var mid;
if (typeof(lo) == 'undefined') lo = 0;
if (typeof(hi) == 'undefined') hi = items.length;
while (lo < hi) {
mid = Math.floor((lo + hi) / 2);
if (x < items[mid]) hi = mid;
else lo = mid + 1;
}
return lo;
}
/**
* @private
*/
function insort(items, x) {
items.splice(bisect(items, x), 0, x);
}
/**
* @private
*/
function partialSort(items, k, comparator) {
var smallest = items.slice(0, k).sort(),
max = smallest[k-1];
for (var i = k, len = items.length; i < len; ++i) {
var item = items[i];
var cond = comparator === undefined ? item < max : comparator(item, max) < 0;
if (cond) {
insort(smallest, item);
smallest.length = k;
max = smallest[k-1];
}
}
return smallest;
}
/**
* A class that streams easily a mesh via socket.io
* @memberOf geo
* @constructor
* @param {string} path to the mesh
*/
geo.MeshStreamer = function(path) {
/**
* array of array telling if the jth face of the ith mesh has already been sent
*
* For each mesh, there is an object containing
*
* - `counter` : the number of faces currently sent
* - `array` : an array boolean telling if the ith face has already been sent
*
* @type {Object[]}
*/
this.meshFaces = [];
/**
* array of booleans telling if the ith vertex has already been sent
* @type {Boolean[]}
*/
this.vertices = [];
/**
* array of booleans telling if the ith face has already been sent
* @type {Boolean[]}
*/
this.faces = [];
/**
* array of booleans telling if the ith normal has already been sent
* @type {Boolean[]}
*/
this.normals = [];
/**
* array of booleans telling if the ith texCoord has already been sent
* @type {Boolean[]}
*/
this.texCoords = [];
/**
* Number of element to send by packet
* @type {Number}
*/
this.chunk = 1000;
if (path !== undefined) {
this.mesh = geo.availableMeshes[path];
}
};
/**
* Compute a function that can compare two faces
* @param {Camera} camera a camera seeing or not face
* @returns the function that compares two faces : the higher face is the most interesting for the camera
*/
geo.MeshStreamer.prototype.faceComparator = function(camera) {
var self = this;
var direction = {
x: camera.target.x - camera.position.x,
y: camera.target.y - camera.position.y,
z: camera.target.z - camera.position.z
};
var norm = Math.sqrt(direction.x * direction.x + direction.y * direction.y + direction.z * direction.z);
direction.x /= norm;
direction.y /= norm;
direction.z /= norm;
return function(face1, face2) {
var center1 = {
x: (self.vertices[face1.a].x + self.vertices[face1.b].x + self.vertices[face1.b].x) / 3,
y: (self.vertices[face1.a].y + self.vertices[face1.b].y + self.vertices[face1.b].y) / 3,
z: (self.vertices[face1.a].z + self.vertices[face1.b].z + self.vertices[face1.b].z) / 3
};
var dir1 = {
x: center1.x - camera.position.x,
y: center1.y - camera.position.y,
z: center1.z - camera.position.z
};
var norm1 = Math.sqrt(dir1.x * dir1.x + dir1.y * dir1.y + dir1.z + dir1.z);
dir1.x /= norm1;
dir1.y /= norm1;
dir1.z /= norm1;
var dot1 = direction.x * dir1.x + direction.y * dir1.y + direction.z * dir1.z;
var center2 = {
x: (self.vertices[face2.a].x + self.vertices[face2.b].x + self.vertices[face2.b].x) / 3,
y: (self.vertices[face2.a].y + self.vertices[face2.b].y + self.vertices[face2.b].y) / 3,
z: (self.vertices[face2.a].z + self.vertices[face2.b].z + self.vertices[face2.b].z) / 3
};
var dir2 = {
x: center2.x - camera.position.x,
y: center2.y - camera.position.y,
z: center2.z - camera.position.z
};
var norm2 = Math.sqrt(dir2.x * dir2.x + dir2.y * dir2.y + dir2.z + dir2.z);
dir2.x /= norm2;
dir2.y /= norm2;
dir2.z /= norm2;
var dot2 = direction.x * dir2.x + direction.y * dir2.y + direction.z * dir2.z;
// Decreasing order
if (dot1 > dot2) {
return -1;
}
if (dot1 < dot2) {
return 1;
}
return 0;
};
};
/**
* Initialize the socket.io callback
* @param {socket} socket the socket to initialize
*/
geo.MeshStreamer.prototype.start = function(socket) {
this.meshIndex = 0;
this.socket = socket;
var self = this;
socket.on('request', function(path) {
self.mesh = geo.availableMeshes[path];
self.meshFaces = new Array(self.mesh.meshes.length);
for (var i = 0; i < self.meshFaces.length; i++) {
self.meshFaces[i] = {
counter: 0,
array: new Array(self.mesh.meshes[i].faces.length)
};
}
var regex = /.*\.\..*/;
var filePath = path.substring(1, path.length);
if (regex.test(filePath)) {
socket.emit('refused');
socket.disconnect();
return;
}
socket.emit('ok');
});
socket.on('materials', function() {
var data = self.nextMaterials();
socket.emit('elements', data);
});
socket.on('next', function(camera) {
// Send next elements
var next = self.nextElements(camera);
if (next.data.length === 0) {
// If nothing, just serve stuff
var tmp = self.nextElements(camera, true);
next.data = tmp.data;
}
socket.emit('elements', next.data);
if (next.finished) {
socket.disconnect();
}
});
};
/**
* Prepare the array of materials
* @return array the array to send with all materials of the current mesh
*/
geo.MeshStreamer.prototype.nextMaterials = function() {
var data = [];
for (var i = 0; i < this.mesh.meshes.length; i++) {
var currentMesh = this.mesh.meshes[i];
// Send usemtl
data.push([
'u',
currentMesh.material,
currentMesh.vertices.length,
currentMesh.faces.length,
this.mesh.texCoords.length > 0,
this.mesh.normals.length > 0
]);
}
return data;
};
/**
* Prepare the next elements
* @param {camera} _camera a camera that can be usefull to do smart streaming (stream
* only interesting parts according to the camera
* @returns {array} an array of elements ready to send
*/
geo.MeshStreamer.prototype.nextElements = function(_camera, force) {
var i;
if (force === undefined) {
force = false;
}
// Prepare camera (and scale to model)
var camera = null;
var planes = [];
var direction;
if (_camera !== null) {
camera = {
position: {
x: _camera[0][0],
y: _camera[0][1],
z: _camera[0][2]
},
target: {
x: _camera[1][0],
y: _camera[1][1],
z: _camera[1][2]
}
};
for (i = 2; i < _camera.length; i++) {
planes.push({
normal: {
x: _camera[i][0],
y: _camera[i][1],
z: _camera[i][2]
},
constant: _camera[i][3]
});
}
// Compute camera direction
direction = {
x: camera.target.x - camera.position.x,
y: camera.target.y - camera.position.y,
z: camera.target.z - camera.position.z
};
}
var sent = 0;
var data = [];
// Sort faces
var mightBeCompletetlyFinished = true;
for (var meshIndex = 0; meshIndex < this.mesh.meshes.length; meshIndex++) {
var currentMesh = this.mesh.meshes[meshIndex];
if (this.isFinished(meshIndex)) {
continue;
} else {
mightBeCompletetlyFinished = false;
}
for (var faceIndex = 0; faceIndex < currentMesh.faces.length; faceIndex++) {
var currentFace = currentMesh.faces[faceIndex];
if (this.meshFaces[meshIndex].array[faceIndex] === true) {
continue;
}
var vertex1 = this.mesh.vertices[currentFace.a];
var vertex2 = this.mesh.vertices[currentFace.b];
var vertex3 = this.mesh.vertices[currentFace.c];
// if (camera !== null) {
// var v1 = {
// x: vertex1.x - camera.position.x,
// y: vertex1.y - camera.position.y,
// z: vertex1.z - camera.position.z
// };
// var v2 = {
// x: vertex2.x - camera.position.x,
// y: vertex2.y - camera.position.y,
// z: vertex2.z - camera.position.z
// };
// var v3 = {
// x: vertex3.x - camera.position.x,
// y: vertex3.y - camera.position.y,
// z: vertex3.z - camera.position.z
// };
// if (
// direction.x * v1.x + direction.y * v1.y + direction.z * v1.z < 0 &&
// direction.x * v2.x + direction.y * v2.y + direction.z * v2.z < 0 &&
// direction.x * v3.x + direction.y * v3.y + direction.z * v3.z < 0
// ) {
// continue;
// }
// }
if (!force) {
var exitToContinue = false;
threeVertices = [vertex1, vertex2, vertex3];
for (i = 0; i < threeVertices.length; i++) {
var vertex = threeVertices[i];
for (var j = 0; j < planes.length; j++) {
var plane = planes[j];
distance =
plane.normal.x * vertex.x +
plane.normal.y * vertex.y +
plane.normal.z * vertex.z +
plane.constant;
if (distance < 0)
{
exitToContinue = true;
break;
}
}
if (exitToContinue)
break;
}
if (exitToContinue)
continue;
}
if (!this.vertices[currentFace.a]) {
data.push(vertex1.toList());
this.vertices[currentFace.a] = true;
sent++;
}
if (!this.vertices[currentFace.b]) {
data.push(vertex2.toList());
this.vertices[currentFace.b] = true;
sent++;
}
if (!this.vertices[currentFace.c]) {
data.push(vertex3.toList());
this.vertices[currentFace.c] = true;
sent++;
}
var normal1 = this.mesh.normals[currentFace.aNormal];
var normal2 = this.mesh.normals[currentFace.bNormal];
var normal3 = this.mesh.normals[currentFace.cNormal];
if (normal1 !== undefined && !this.normals[currentFace.aNormal]) {
data.push(normal1.toList());
this.normals[currentFace.aNormal] = true;
sent++;
}
if (normal2 !== undefined && !this.normals[currentFace.bNormal]) {
data.push(normal2.toList());
this.normals[currentFace.bNormal] = true;
sent++;
}
if (normal3 !== undefined && !this.normals[currentFace.cNormal]) {
data.push(normal3.toList());
this.normals[currentFace.cNormal] = true;
sent++;
}
var tex1 = this.mesh.texCoords[currentFace.aTexture];
var tex2 = this.mesh.texCoords[currentFace.bTexture];
var tex3 = this.mesh.texCoords[currentFace.cTexture];
if (tex1 !== undefined && !this.texCoords[currentFace.aTexture]) {
data.push(tex1.toList());
this.texCoords[currentFace.aTexture] = true;
sent++;
}
if (tex2 !== undefined && !this.texCoords[currentFace.bTexture]) {
data.push(tex2.toList());
this.texCoords[currentFace.bTexture] = true;
sent++;
}
if (tex3 !== undefined && !this.texCoords[currentFace.cTexture]) {
data.push(tex3.toList());
this.texCoords[currentFace.cTexture] = true;
sent++;
}
data.push(currentFace.toList());
// this.meshFaces[meshIndex] = this.meshFaces[meshIndex] || [];
this.meshFaces[meshIndex].array[faceIndex] = true;
this.meshFaces[meshIndex].counter++;
currentMesh.faceIndex++;
sent++;
if (sent > 500) {
return {data: data, finished: false};
}
}
}
return {data: data, finished: mightBeCompletetlyFinished};
};
geo.MeshStreamer.prototype.isFinished = function(i) {
return this.meshFaces[i].counter === this.meshFaces[i].array.length;
};