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index.js
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index.js
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AFRAME.registerComponent("gaussian_splatting", {
schema: {
src: {type: 'string', default: "train.splat"},
cutoutEntity: {type: 'selector'},
pixelRatio: {type: 'number', default: 1},
xrPixelRatio: {type: 'number', default: 0.5}
},
init: function () {
// aframe-specific data
if(this.data.pixelRatio > 0){
this.el.sceneEl.renderer.setPixelRatio(this.data.pixelRatio);
}
if(this.data.xrPixelRatio > 0){
this.el.sceneEl.renderer.xr.setFramebufferScaleFactor(this.data.xrPixelRatio);
}
document.querySelector('a-scene').addEventListener('loaded', () => {
this.loadData(this.el.sceneEl.camera.el.components.camera.camera, this.el.object3D, this.el.sceneEl.renderer, this.data.src);
if (!!this.data.cutoutEntity) {
this.cutout = this.data.cutoutEntity.object3D;
}
})
},
// also works from vanilla three.js
initGL: async function(numVertexes){
console.log("initGL", numVertexes);
this.object.frustumCulled = false;
let gl = this.renderer.getContext();
let mexTextureSize = gl.getParameter(gl.MAX_TEXTURE_SIZE);
this.maxVertexes = mexTextureSize * mexTextureSize;
if(numVertexes > this.maxVertexes){
console.log("numVertexes limited to ", this.maxVertexes, numVertexes);
numVertexes = this.maxVertexes;
}
this.bufferTextureWidth = mexTextureSize;
this.bufferTextureHeight = Math.floor((numVertexes - 1)/mexTextureSize) + 1;
this.centerAndScaleData = new Float32Array(this.bufferTextureWidth * this.bufferTextureHeight * 4);
this.covAndColorData = new Uint32Array(this.bufferTextureWidth * this.bufferTextureHeight * 4);
this.centerAndScaleTexture = new THREE.DataTexture(this.centerAndScaleData, this.bufferTextureWidth, this.bufferTextureHeight, THREE.RGBA, THREE.FloatType);
this.centerAndScaleTexture.needsUpdate = true;
this.covAndColorTexture = new THREE.DataTexture(this.covAndColorData, this.bufferTextureWidth, this.bufferTextureHeight, THREE.RGBAIntegerFormat, THREE.UnsignedIntType);
this.covAndColorTexture.internalFormat = "RGBA32UI";
this.covAndColorTexture.needsUpdate = true;
let splatIndexArray = new Uint32Array(this.bufferTextureWidth * this.bufferTextureHeight);
const splatIndexes = new THREE.InstancedBufferAttribute(splatIndexArray, 1, false);
splatIndexes.setUsage(THREE.DynamicDrawUsage);
const baseGeometry = new THREE.BufferGeometry();
const positionsArray = new Float32Array(6 * 3);
const positions = new THREE.BufferAttribute(positionsArray, 3);
baseGeometry.setAttribute('position', positions);
positions.setXYZ(2, -2.0, 2.0, 0.0);
positions.setXYZ(1, 2.0, 2.0, 0.0);
positions.setXYZ(0, -2.0, -2.0, 0.0);
positions.setXYZ(5, -2.0, -2.0, 0.0);
positions.setXYZ(4, 2.0, 2.0, 0.0);
positions.setXYZ(3, 2.0, -2.0, 0.0);
positions.needsUpdate = true;
const geometry = new THREE.InstancedBufferGeometry().copy(baseGeometry);
geometry.setAttribute('splatIndex', splatIndexes);
geometry.instanceCount = 1;
const material = new THREE.ShaderMaterial( {
uniforms : {
viewport: {value: new Float32Array([1980, 1080])}, // Dummy. will be overwritten
focal: {value: 1000.0}, // Dummy. will be overwritten
centerAndScaleTexture: {value: this.centerAndScaleTexture},
covAndColorTexture: {value: this.covAndColorTexture},
gsProjectionMatrix: {value: this.getProjectionMatrix()},
gsModelViewMatrix: {value: this.getModelViewMatrix()},
},
vertexShader: `
precision highp sampler2D;
precision highp usampler2D;
out vec4 vColor;
out vec2 vPosition;
uniform vec2 viewport;
uniform float focal;
uniform mat4 gsProjectionMatrix;
uniform mat4 gsModelViewMatrix;
attribute uint splatIndex;
uniform sampler2D centerAndScaleTexture;
uniform usampler2D covAndColorTexture;
vec2 unpackInt16(in uint value) {
int v = int(value);
int v0 = v >> 16;
int v1 = (v & 0xFFFF);
if((v & 0x8000) != 0)
v1 |= 0xFFFF0000;
return vec2(float(v1), float(v0));
}
void main () {
ivec2 texSize = textureSize(centerAndScaleTexture, 0);
ivec2 texPos = ivec2(splatIndex%uint(texSize.x), splatIndex/uint(texSize.x));
vec4 centerAndScaleData = texelFetch(centerAndScaleTexture, texPos, 0);
vec4 center = vec4(centerAndScaleData.xyz, 1);
vec4 camspace = gsModelViewMatrix * center;
vec4 pos2d = gsProjectionMatrix * camspace;
float bounds = 1.2 * pos2d.w;
if (pos2d.z < -pos2d.w || pos2d.x < -bounds || pos2d.x > bounds
|| pos2d.y < -bounds || pos2d.y > bounds) {
gl_Position = vec4(0.0, 0.0, 2.0, 1.0);
return;
}
uvec4 covAndColorData = texelFetch(covAndColorTexture, texPos, 0);
vec2 cov3D_M11_M12 = unpackInt16(covAndColorData.x) * centerAndScaleData.w;
vec2 cov3D_M13_M22 = unpackInt16(covAndColorData.y) * centerAndScaleData.w;
vec2 cov3D_M23_M33 = unpackInt16(covAndColorData.z) * centerAndScaleData.w;
mat3 Vrk = mat3(
cov3D_M11_M12.x, cov3D_M11_M12.y, cov3D_M13_M22.x,
cov3D_M11_M12.y, cov3D_M13_M22.y, cov3D_M23_M33.x,
cov3D_M13_M22.x, cov3D_M23_M33.x, cov3D_M23_M33.y
);
mat3 J = mat3(
focal / camspace.z, 0., -(focal * camspace.x) / (camspace.z * camspace.z),
0., -focal / camspace.z, (focal * camspace.y) / (camspace.z * camspace.z),
0., 0., 0.
);
mat3 W = transpose(mat3(gsModelViewMatrix));
mat3 T = W * J;
mat3 cov = transpose(T) * Vrk * T;
vec2 vCenter = vec2(pos2d) / pos2d.w;
float diagonal1 = cov[0][0] + 0.3;
float offDiagonal = cov[0][1];
float diagonal2 = cov[1][1] + 0.3;
float mid = 0.5 * (diagonal1 + diagonal2);
float radius = length(vec2((diagonal1 - diagonal2) / 2.0, offDiagonal));
float lambda1 = mid + radius;
float lambda2 = max(mid - radius, 0.1);
vec2 diagonalVector = normalize(vec2(offDiagonal, lambda1 - diagonal1));
vec2 v1 = min(sqrt(2.0 * lambda1), 1024.0) * diagonalVector;
vec2 v2 = min(sqrt(2.0 * lambda2), 1024.0) * vec2(diagonalVector.y, -diagonalVector.x);
uint colorUint = covAndColorData.w;
vColor = vec4(
float(colorUint & uint(0xFF)) / 255.0,
float((colorUint >> uint(8)) & uint(0xFF)) / 255.0,
float((colorUint >> uint(16)) & uint(0xFF)) / 255.0,
float(colorUint >> uint(24)) / 255.0
);
vPosition = position.xy;
gl_Position = vec4(
vCenter
+ position.x * v2 / viewport * 2.0
+ position.y * v1 / viewport * 2.0, pos2d.z / pos2d.w, 1.0);
}
`,
fragmentShader: `
in vec4 vColor;
in vec2 vPosition;
void main () {
float A = -dot(vPosition, vPosition);
if (A < -4.0) discard;
float B = exp(A) * vColor.a;
gl_FragColor = vec4(vColor.rgb, B);
}
`,
blending : THREE.CustomBlending,
blendSrcAlpha : THREE.OneFactor,
depthTest : true,
depthWrite: false,
transparent: true
} );
material.onBeforeRender = ((renderer, scene, camera, geometry, object, group) => {
let projectionMatrix = this.getProjectionMatrix(camera);
mesh.material.uniforms.gsProjectionMatrix.value = projectionMatrix;
mesh.material.uniforms.gsModelViewMatrix.value = this.getModelViewMatrix(camera);
let viewport = new THREE.Vector4();
renderer.getCurrentViewport(viewport);
const focal = (viewport.w / 2.0) * Math.abs(projectionMatrix.elements[5]);
material.uniforms.viewport.value[0] = viewport.z;
material.uniforms.viewport.value[1] = viewport.w;
material.uniforms.focal.value = focal;
});
const mesh = new THREE.Mesh(geometry, material);
mesh.frustumCulled = false;
this.object.add(mesh);
this.worker.onmessage = (e) => {
let indexes = new Uint32Array(e.data.sortedIndexes);
mesh.geometry.attributes.splatIndex.set(indexes);
mesh.geometry.attributes.splatIndex.needsUpdate = true;
mesh.geometry.instanceCount = indexes.length;
this.sortReady = true;
};
// Wait texture is ready
while(true){
const centerAndScaleTextureProperties = this.renderer.properties.get( this.centerAndScaleTexture );
const covAndColorTextureProperties = this.renderer.properties.get( this.covAndColorTexture );
if(centerAndScaleTextureProperties && centerAndScaleTextureProperties.__webglTexture &&
covAndColorTextureProperties && centerAndScaleTextureProperties.__webglTexture){
break;
}
await new Promise(resolve => setTimeout(resolve, 10));
}
this.sortReady = true;
},
loadData: function(camera, object, renderer, src) {
this.camera = camera;
this.object = object;
this.renderer = renderer;
this.loadedVertexCount = 0;
this.rowLength = 3 * 4 + 3 * 4 + 4 + 4;
this.worker = new Worker(
URL.createObjectURL(
new Blob(["(", this.createWorker.toString(), ")(self)"], {
type: "application/javascript",
}),
),
);
this.worker.postMessage({method: "clear"});
fetch(src)
.then(async (data) => {
const reader = data.body.getReader();
let glInitialized = false;
let bytesDownloaded = 0;
let bytesProcesses = 0;
let _totalDownloadBytes = data.headers.get("Content-Length");
let totalDownloadBytes = _totalDownloadBytes ? parseInt(_totalDownloadBytes) : undefined;
if(totalDownloadBytes != undefined){
let numVertexes = Math.floor(totalDownloadBytes / this.rowLength);
await this.initGL(numVertexes);
glInitialized = true;
}
const chunks = [];
const start = Date.now();
let lastReportedProgress = 0;
let isPly = src.endsWith(".ply");
while (true) {
try {
const { value, done } = await reader.read();
if (done) {
console.log("Completed download.");
break;
}
bytesDownloaded += value.length;
if (totalDownloadBytes != undefined) {
const mbps = (bytesDownloaded / 1024 / 1024) / ((Date.now() - start) / 1000);
const percent = bytesDownloaded / totalDownloadBytes * 100;
if (percent - lastReportedProgress > 1) {
console.log("download progress:", percent.toFixed(2) + "%", mbps.toFixed(2) + " Mbps");
lastReportedProgress = percent;
}
} else {
console.log("download progress:", bytesDownloaded, ", unknown total");
}
chunks.push(value);
const bytesRemains = bytesDownloaded - bytesProcesses;
if(!isPly && totalDownloadBytes != undefined && bytesRemains > this.rowLength){
let vertexCount = Math.floor(bytesRemains / this.rowLength);
const concatenatedChunksbuffer = new Uint8Array(bytesRemains);
let offset = 0;
for (const chunk of chunks) {
concatenatedChunksbuffer.set(chunk, offset);
offset += chunk.length;
}
chunks.length = 0;
if(bytesRemains > vertexCount * this.rowLength){
const extra_data = new Uint8Array(bytesRemains - vertexCount * this.rowLength);
extra_data.set(concatenatedChunksbuffer.subarray(bytesRemains - extra_data.length, bytesRemains), 0);
chunks.push(extra_data);
}
const buffer = new Uint8Array(vertexCount * this.rowLength);
buffer.set(concatenatedChunksbuffer.subarray(0, buffer.byteLength), 0);
this.pushDataBuffer(buffer.buffer, vertexCount);
bytesProcesses += vertexCount * this.rowLength;
}
} catch (error) {
console.error(error);
break;
}
}
if(bytesDownloaded - bytesProcesses > 0){
// Concatenate the chunks into a single Uint8Array
let concatenatedChunks = new Uint8Array(
chunks.reduce((acc, chunk) => acc + chunk.length, 0)
);
let offset = 0;
for (const chunk of chunks) {
concatenatedChunks.set(chunk, offset);
offset += chunk.length;
}
if(isPly){
concatenatedChunks = new Uint8Array(this.processPlyBuffer(concatenatedChunks.buffer));
}
let numVertexes = Math.floor(concatenatedChunks.byteLength/this.rowLength);
if(!glInitialized){
await this.initGL(numVertexes);
glInitialized = true;
}
this.pushDataBuffer(concatenatedChunks.buffer, numVertexes);
}
});
},
pushDataBuffer: function(buffer, vertexCount) {
if(this.loadedVertexCount + vertexCount > this.maxVertexes){
console.log("vertexCount limited to ", this.maxVertexes, vertexCount);
vertexCount = this.maxVertexes - this.loadedVertexCount;
}
if(vertexCount <= 0){
return;
}
let u_buffer = new Uint8Array(buffer);
let f_buffer = new Float32Array(buffer);
let matrices = new Float32Array(vertexCount * 16);
const covAndColorData_uint8 = new Uint8Array(this.covAndColorData.buffer);
const covAndColorData_int16 = new Int16Array(this.covAndColorData.buffer);
for (let i = 0; i < vertexCount; i++) {
let quat = new THREE.Quaternion(
(u_buffer[32 * i + 28 + 1] - 128) / 128.0,
(u_buffer[32 * i + 28 + 2] - 128) / 128.0,
-(u_buffer[32 * i + 28 + 3] - 128) / 128.0,
(u_buffer[32 * i + 28 + 0] - 128) / 128.0,
);
let center = new THREE.Vector3(
f_buffer[8 * i + 0],
f_buffer[8 * i + 1],
-f_buffer[8 * i + 2]
);
let scale = new THREE.Vector3(
f_buffer[8 * i + 3 + 0],
f_buffer[8 * i + 3 + 1],
f_buffer[8 * i + 3 + 2]
);
let mtx = new THREE.Matrix4();
mtx.makeRotationFromQuaternion(quat);
mtx.transpose();
mtx.scale(scale);
let mtx_t = mtx.clone()
mtx.transpose();
mtx.premultiply(mtx_t);
mtx.setPosition(center);
let cov_indexes = [0, 1, 2, 5, 6, 10];
let max_value = 0.0;
for(let j = 0; j < cov_indexes.length; j++){
if(Math.abs(mtx.elements[cov_indexes[j]]) > max_value){
max_value = Math.abs(mtx.elements[cov_indexes[j]]);
}
}
let destOffset = this.loadedVertexCount * 4 + i * 4;
this.centerAndScaleData[destOffset + 0] = center.x;
this.centerAndScaleData[destOffset + 1] = center.y;
this.centerAndScaleData[destOffset + 2] = center.z;
this.centerAndScaleData[destOffset + 3] = max_value / 32767.0;
destOffset = this.loadedVertexCount * 8 + i * 4 * 2;
for(let j = 0; j < cov_indexes.length; j++){
covAndColorData_int16[destOffset + j] = parseInt(mtx.elements[cov_indexes[j]] * 32767.0 / max_value);
}
// RGBA
destOffset = this.loadedVertexCount * 16 + (i * 4 + 3) * 4;
covAndColorData_uint8[destOffset + 0] = u_buffer[32 * i + 24 + 0];
covAndColorData_uint8[destOffset + 1] = u_buffer[32 * i + 24 + 1];
covAndColorData_uint8[destOffset + 2] = u_buffer[32 * i + 24 + 2];
covAndColorData_uint8[destOffset + 3] = u_buffer[32 * i + 24 + 3];
// Store scale and transparent to remove splat in sorting process
mtx.elements[15] = Math.max(scale.x, scale.y, scale.z) * u_buffer[32 * i + 24 + 3] / 255.0;
for(let j = 0; j < 16; j++){
matrices[i * 16 + j] = mtx.elements[j];
}
}
const gl = this.renderer.getContext();
while(vertexCount > 0){
let width = 0;
let height = 0;
let xoffset = (this.loadedVertexCount%this.bufferTextureWidth);
let yoffset = Math.floor(this.loadedVertexCount/this.bufferTextureWidth);
if(this.loadedVertexCount%this.bufferTextureWidth != 0){
width = Math.min(this.bufferTextureWidth, xoffset + vertexCount) - xoffset;
height = 1;
}else if(Math.floor(vertexCount/this.bufferTextureWidth) > 0){
width = this.bufferTextureWidth;
height = Math.floor(vertexCount/this.bufferTextureWidth);
}else{
width = vertexCount%this.bufferTextureWidth;
height = 1;
}
const centerAndScaleTextureProperties = this.renderer.properties.get( this.centerAndScaleTexture );
gl.bindTexture(gl.TEXTURE_2D, centerAndScaleTextureProperties.__webglTexture);
gl.texSubImage2D(gl.TEXTURE_2D, 0, xoffset, yoffset, width, height, gl.RGBA, gl.FLOAT, this.centerAndScaleData, this.loadedVertexCount * 4);
const covAndColorTextureProperties = this.renderer.properties.get( this.covAndColorTexture );
gl.bindTexture(gl.TEXTURE_2D, covAndColorTextureProperties.__webglTexture);
gl.texSubImage2D(gl.TEXTURE_2D, 0, xoffset, yoffset, width, height, gl.RGBA_INTEGER, gl.UNSIGNED_INT, this.covAndColorData, this.loadedVertexCount * 4);
this.loadedVertexCount += width * height;
vertexCount -= width * height;
}
this.worker.postMessage({
method: "push",
matrices: matrices.buffer
}, [matrices.buffer]);
},
tick: function(time, timeDelta) {
if(this.sortReady){
this.sortReady = false;
let camera_mtx = this.getModelViewMatrix().elements;
let view = new Float32Array([camera_mtx[2], camera_mtx[6], camera_mtx[10], camera_mtx[14]]);
let worldToCutout = new THREE.Matrix4();
if (this.cutout) {
worldToCutout.copy(this.cutout.matrixWorld);
worldToCutout.invert();
worldToCutout.multiply(this.object.matrixWorld);
}
this.worker.postMessage({
method: "sort",
view: view.buffer,
cutout: this.cutout ? new Float32Array(worldToCutout.elements) : undefined
}, [view.buffer]);
}
},
getProjectionMatrix: function(camera) {
if(!camera){
camera = this.camera;
}
let mtx = camera.projectionMatrix.clone();
mtx.elements[4] *= -1;
mtx.elements[5] *= -1;
mtx.elements[6] *= -1;
mtx.elements[7] *= -1;
return mtx;
},
getModelViewMatrix: function(camera) {
if(!camera){
camera = this.camera;
}
const viewMatrix = camera.matrixWorld.clone();
viewMatrix.elements[1] *= -1.0;
viewMatrix.elements[4] *= -1.0;
viewMatrix.elements[6] *= -1.0;
viewMatrix.elements[9] *= -1.0;
viewMatrix.elements[13] *= -1.0;
const mtx = this.object.matrixWorld.clone();
mtx.invert();
mtx.elements[1] *= -1.0;
mtx.elements[4] *= -1.0;
mtx.elements[6] *= -1.0;
mtx.elements[9] *= -1.0;
mtx.elements[13] *= -1.0;
mtx.multiply(viewMatrix);
mtx.invert();
return mtx;
},
createWorker: function (self) {
let matrices = undefined;
// multiply: matrix4x4 * vector3
const mul = function mul(e, x, y, z){
const w = 1 / ( e[ 3 ] * x + e[ 7 ] * y + e[ 11 ] * z + e[ 15 ] );
return [
(e[0] * x + e[4] * y + e[8] * z + e[12]) * w,
(e[1] * x + e[5] * y + e[9] * z + e[13]) * w,
(e[2] * x + e[6] * y + e[10] * z + e[14]) * w,
];
}
// dot: vector3 * vector3
const dot = function dot(vec1, vec2){
return vec1[0] * vec2[0] + vec1[1] * vec2[1] + vec1[2] * vec2[2];
}
const sortSplats = function sortSplats(matrices, view, cutout = undefined){
const vertexCount = matrices.length/16;
let threshold = -0.0001;
let maxDepth = -Infinity;
let minDepth = Infinity;
let depthList = new Float32Array(vertexCount);
let sizeList = new Int32Array(depthList.buffer);
let validIndexList = new Int32Array(vertexCount);
let validCount = 0;
for (let i = 0; i < vertexCount; i++) {
// Sign of depth is reversed
let depth =
( view[0] * matrices[i * 16 + 12]
+ view[1] * matrices[i * 16 + 13]
+ view[2] * matrices[i * 16 + 14]
+ view[3]);
let cutoutArea = true;
if (cutout !== undefined) {
// Position-based culling
let posX = matrices[i * 16 + 12];
let posY = matrices[i * 16 + 13];
let posZ = matrices[i * 16 + 14];
// convert to cutout space – not sure why Y axis is inverted
const cutoutSpacePos = mul(cutout, posX, -posY, posZ);
const len = dot(cutoutSpacePos, cutoutSpacePos);
// box cutout
if (cutoutSpacePos[0] < -0.5 || cutoutSpacePos[0] > 0.5 ||
cutoutSpacePos[1] < -0.5 || cutoutSpacePos[1] > 0.5 ||
cutoutSpacePos[2] < -0.5 || cutoutSpacePos[2] > 0.5)
cutoutArea = false;
// spherical cutout
// if (dot(cutoutSpacePos, cutoutSpacePos) > 1)
// cutoutArea = false;
}
// Skip behind of camera and small, transparent splat
if(depth < 0 && matrices[i * 16 + 15] > threshold * depth && cutoutArea){
depthList[validCount] = depth;
validIndexList[validCount] = i;
validCount++;
if (depth > maxDepth) maxDepth = depth;
if (depth < minDepth) minDepth = depth;
};
}
// This is a 16 bit single-pass counting sort
let depthInv = (256 * 256 - 1) / (maxDepth - minDepth);
let counts0 = new Uint32Array(256*256);
for (let i = 0; i < validCount; i++) {
sizeList[i] = ((depthList[i] - minDepth) * depthInv) | 0;
counts0[sizeList[i]]++;
}
let starts0 = new Uint32Array(256*256);
for (let i = 1; i < 256*256; i++) starts0[i] = starts0[i - 1] + counts0[i - 1];
let depthIndex = new Uint32Array(validCount);
for (let i = 0; i < validCount; i++) depthIndex[starts0[sizeList[i]]++] = validIndexList[i];
return depthIndex;
};
self.onmessage = (e) => {
if(e.data.method == "clear"){
matrices = undefined;
}
if(e.data.method == "push"){
const new_matrices = new Float32Array(e.data.matrices);
if(matrices === undefined){
matrices = new_matrices;
}else{
resized = new Float32Array(matrices.length + new_matrices.length);
resized.set(matrices);
resized.set(new_matrices, matrices.length);
matrices = resized;
}
}
if(e.data.method == "sort"){
if(matrices === undefined){
const sortedIndexes = new Uint32Array(1);
self.postMessage({sortedIndexes}, [sortedIndexes.buffer]);
}else{
const view = new Float32Array(e.data.view);
const cutout = e.data.cutout !== undefined ? new Float32Array(e.data.cutout) : undefined;
const sortedIndexes = sortSplats(matrices, view, cutout);
self.postMessage({sortedIndexes}, [sortedIndexes.buffer]);
}
}
};
},
processPlyBuffer: function (inputBuffer) {
const ubuf = new Uint8Array(inputBuffer);
// 10KB ought to be enough for a header...
const header = new TextDecoder().decode(ubuf.slice(0, 1024 * 10));
const header_end = "end_header\n";
const header_end_index = header.indexOf(header_end);
if (header_end_index < 0)
throw new Error("Unable to read .ply file header");
const vertexCount = parseInt(/element vertex (\d+)\n/.exec(header)[1]);
console.log("Vertex Count", vertexCount);
let row_offset = 0,
offsets = {},
types = {};
const TYPE_MAP = {
double: "getFloat64",
int: "getInt32",
uint: "getUint32",
float: "getFloat32",
short: "getInt16",
ushort: "getUint16",
uchar: "getUint8",
};
for (let prop of header
.slice(0, header_end_index)
.split("\n")
.filter((k) => k.startsWith("property "))) {
const [p, type, name] = prop.split(" ");
const arrayType = TYPE_MAP[type] || "getInt8";
types[name] = arrayType;
offsets[name] = row_offset;
row_offset += parseInt(arrayType.replace(/[^\d]/g, "")) / 8;
}
console.log("Bytes per row", row_offset, types, offsets);
let dataView = new DataView(
inputBuffer,
header_end_index + header_end.length,
);
let row = 0;
const attrs = new Proxy(
{},
{
get(target, prop) {
if (!types[prop]) throw new Error(prop + " not found");
return dataView[types[prop]](
row * row_offset + offsets[prop],
true,
);
},
},
);
console.time("calculate importance");
let sizeList = new Float32Array(vertexCount);
let sizeIndex = new Uint32Array(vertexCount);
for (row = 0; row < vertexCount; row++) {
sizeIndex[row] = row;
if (!types["scale_0"]) continue;
const size =
Math.exp(attrs.scale_0) *
Math.exp(attrs.scale_1) *
Math.exp(attrs.scale_2);
const opacity = 1 / (1 + Math.exp(-attrs.opacity));
sizeList[row] = size * opacity;
}
console.timeEnd("calculate importance");
console.time("sort");
sizeIndex.sort((b, a) => sizeList[a] - sizeList[b]);
console.timeEnd("sort");
// 6*4 + 4 + 4 = 8*4
// XYZ - Position (Float32)
// XYZ - Scale (Float32)
// RGBA - colors (uint8)
// IJKL - quaternion/rot (uint8)
const rowLength = 3 * 4 + 3 * 4 + 4 + 4;
const buffer = new ArrayBuffer(rowLength * vertexCount);
console.time("build buffer");
for (let j = 0; j < vertexCount; j++) {
row = sizeIndex[j];
const position = new Float32Array(buffer, j * rowLength, 3);
const scales = new Float32Array(buffer, j * rowLength + 4 * 3, 3);
const rgba = new Uint8ClampedArray(
buffer,
j * rowLength + 4 * 3 + 4 * 3,
4,
);
const rot = new Uint8ClampedArray(
buffer,
j * rowLength + 4 * 3 + 4 * 3 + 4,
4,
);
if (types["scale_0"]) {
const qlen = Math.sqrt(
attrs.rot_0 ** 2 +
attrs.rot_1 ** 2 +
attrs.rot_2 ** 2 +
attrs.rot_3 ** 2,
);
rot[0] = (attrs.rot_0 / qlen) * 128 + 128;
rot[1] = (attrs.rot_1 / qlen) * 128 + 128;
rot[2] = (attrs.rot_2 / qlen) * 128 + 128;
rot[3] = (attrs.rot_3 / qlen) * 128 + 128;
scales[0] = Math.exp(attrs.scale_0);
scales[1] = Math.exp(attrs.scale_1);
scales[2] = Math.exp(attrs.scale_2);
} else {
scales[0] = 0.01;
scales[1] = 0.01;
scales[2] = 0.01;
rot[0] = 255;
rot[1] = 0;
rot[2] = 0;
rot[3] = 0;
}
position[0] = attrs.x;
position[1] = attrs.y;
position[2] = attrs.z;
if (types["f_dc_0"]) {
const SH_C0 = 0.28209479177387814;
rgba[0] = (0.5 + SH_C0 * attrs.f_dc_0) * 255;
rgba[1] = (0.5 + SH_C0 * attrs.f_dc_1) * 255;
rgba[2] = (0.5 + SH_C0 * attrs.f_dc_2) * 255;
} else {
rgba[0] = attrs.red;
rgba[1] = attrs.green;
rgba[2] = attrs.blue;
}
if (types["opacity"]) {
rgba[3] = (1 / (1 + Math.exp(-attrs.opacity))) * 255;
} else {
rgba[3] = 255;
}
}
console.timeEnd("build buffer");
return buffer;
}
});