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deer-flow/frontend/src/components/ui/galaxy.jsx
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Matt Van Horn 609ff5849f fix(frontend): gracefully handle missing WebGL context (#1147) 
Wrap the OGL Renderer instantiation in a try-catch so the app does not
crash when WebGL is unavailable (e.g. hardware acceleration disabled).
The Galaxy background simply does not render instead of taking down the
entire page.

Fixes #1144

Co-authored-by: Matt Van Horn <455140+mvanhorn@users.noreply.github.com>
Co-authored-by: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
Co-authored-by: Willem Jiang <willem.jiang@gmail.com>
2026-03-16 21:22:17 +08:00

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import { Renderer, Program, Mesh, Color, Triangle } from "ogl";
import { useEffect, useRef } from "react";
import "./galaxy.css";
const vertexShader = `
attribute vec2 uv;
attribute vec2 position;
varying vec2 vUv;
void main() {
vUv = uv;
gl_Position = vec4(position, 0, 1);
}
`;
const fragmentShader = `
precision highp float;
uniform float uTime;
uniform vec3 uResolution;
uniform vec2 uFocal;
uniform vec2 uRotation;
uniform float uStarSpeed;
uniform float uDensity;
uniform float uHueShift;
uniform float uSpeed;
uniform vec2 uMouse;
uniform float uGlowIntensity;
uniform float uSaturation;
uniform bool uMouseRepulsion;
uniform float uTwinkleIntensity;
uniform float uRotationSpeed;
uniform float uRepulsionStrength;
uniform float uMouseActiveFactor;
uniform float uAutoCenterRepulsion;
uniform bool uTransparent;
varying vec2 vUv;
#define NUM_LAYER 4.0
#define STAR_COLOR_CUTOFF 0.2
#define MAT45 mat2(0.7071, -0.7071, 0.7071, 0.7071)
#define PERIOD 3.0
float Hash21(vec2 p) {
p = fract(p * vec2(123.34, 456.21));
p += dot(p, p + 45.32);
return fract(p.x * p.y);
}
float tri(float x) {
return abs(fract(x) * 2.0 - 1.0);
}
float tris(float x) {
float t = fract(x);
return 1.0 - smoothstep(0.0, 1.0, abs(2.0 * t - 1.0));
}
float trisn(float x) {
float t = fract(x);
return 2.0 * (1.0 - smoothstep(0.0, 1.0, abs(2.0 * t - 1.0))) - 1.0;
}
vec3 hsv2rgb(vec3 c) {
vec4 K = vec4(1.0, 2.0 / 3.0, 1.0 / 3.0, 3.0);
vec3 p = abs(fract(c.xxx + K.xyz) * 6.0 - K.www);
return c.z * mix(K.xxx, clamp(p - K.xxx, 0.0, 1.0), c.y);
}
float Star(vec2 uv, float flare) {
float d = length(uv);
float m = (0.05 * uGlowIntensity) / d;
float rays = smoothstep(0.0, 1.0, 1.0 - abs(uv.x * uv.y * 1000.0));
m += rays * flare * uGlowIntensity;
uv *= MAT45;
rays = smoothstep(0.0, 1.0, 1.0 - abs(uv.x * uv.y * 1000.0));
m += rays * 0.3 * flare * uGlowIntensity;
m *= smoothstep(1.0, 0.2, d);
return m;
}
vec3 StarLayer(vec2 uv) {
vec3 col = vec3(0.0);
vec2 gv = fract(uv) - 0.5;
vec2 id = floor(uv);
for (int y = -1; y <= 1; y++) {
for (int x = -1; x <= 1; x++) {
vec2 offset = vec2(float(x), float(y));
vec2 si = id + vec2(float(x), float(y));
float seed = Hash21(si);
float size = fract(seed * 345.32);
float glossLocal = tri(uStarSpeed / (PERIOD * seed + 1.0));
float flareSize = smoothstep(0.9, 1.0, size) * glossLocal;
float red = smoothstep(STAR_COLOR_CUTOFF, 1.0, Hash21(si + 1.0)) + STAR_COLOR_CUTOFF;
float blu = smoothstep(STAR_COLOR_CUTOFF, 1.0, Hash21(si + 3.0)) + STAR_COLOR_CUTOFF;
float grn = min(red, blu) * seed;
vec3 base = vec3(red, grn, blu);
float hue = atan(base.g - base.r, base.b - base.r) / (2.0 * 3.14159) + 0.5;
hue = fract(hue + uHueShift / 360.0);
float sat = length(base - vec3(dot(base, vec3(0.299, 0.587, 0.114)))) * uSaturation;
float val = max(max(base.r, base.g), base.b);
base = hsv2rgb(vec3(hue, sat, val));
vec2 pad = vec2(tris(seed * 34.0 + uTime * uSpeed / 10.0), tris(seed * 38.0 + uTime * uSpeed / 30.0)) - 0.5;
float star = Star(gv - offset - pad, flareSize);
vec3 color = base;
float twinkle = trisn(uTime * uSpeed + seed * 6.2831) * 0.5 + 1.0;
twinkle = mix(1.0, twinkle, uTwinkleIntensity);
star *= twinkle;
col += star * size * color;
}
}
return col;
}
void main() {
vec2 focalPx = uFocal * uResolution.xy;
vec2 uv = (vUv * uResolution.xy - focalPx) / uResolution.y;
vec2 mouseNorm = uMouse - vec2(0.5);
if (uAutoCenterRepulsion > 0.0) {
vec2 centerUV = vec2(0.0, 0.0);
float centerDist = length(uv - centerUV);
vec2 repulsion = normalize(uv - centerUV) * (uAutoCenterRepulsion / (centerDist + 0.1));
uv += repulsion * 0.05;
} else if (uMouseRepulsion) {
vec2 mousePosUV = (uMouse * uResolution.xy - focalPx) / uResolution.y;
float mouseDist = length(uv - mousePosUV);
vec2 repulsion = normalize(uv - mousePosUV) * (uRepulsionStrength / (mouseDist + 0.1));
uv += repulsion * 0.05 * uMouseActiveFactor;
} else {
vec2 mouseOffset = mouseNorm * 0.1 * uMouseActiveFactor;
uv += mouseOffset;
}
float autoRotAngle = uTime * uRotationSpeed;
mat2 autoRot = mat2(cos(autoRotAngle), -sin(autoRotAngle), sin(autoRotAngle), cos(autoRotAngle));
uv = autoRot * uv;
uv = mat2(uRotation.x, -uRotation.y, uRotation.y, uRotation.x) * uv;
vec3 col = vec3(0.0);
for (float i = 0.0; i < 1.0; i += 1.0 / NUM_LAYER) {
float depth = fract(i + uStarSpeed * uSpeed);
float scale = mix(20.0 * uDensity, 0.5 * uDensity, depth);
float fade = depth * smoothstep(1.0, 0.9, depth);
col += StarLayer(uv * scale + i * 453.32) * fade;
}
if (uTransparent) {
float alpha = length(col);
alpha = smoothstep(0.0, 0.3, alpha);
alpha = min(alpha, 1.0);
gl_FragColor = vec4(col, alpha);
} else {
gl_FragColor = vec4(col, 1.0);
}
}
`;
export default function Galaxy({
focal = [0.5, 0.5],
rotation = [1.0, 0.0],
starSpeed = 0.5,
density = 1,
hueShift = 140,
disableAnimation = false,
speed = 1.0,
mouseInteraction = true,
glowIntensity = 0.3,
saturation = 0.0,
mouseRepulsion = true,
repulsionStrength = 2,
twinkleIntensity = 0.3,
rotationSpeed = 0.1,
autoCenterRepulsion = 0,
transparent = true,
...rest
}) {
const ctnDom = useRef(null);
const targetMousePos = useRef({ x: 0.5, y: 0.5 });
const smoothMousePos = useRef({ x: 0.5, y: 0.5 });
const targetMouseActive = useRef(0.0);
const smoothMouseActive = useRef(0.0);
useEffect(() => {
if (!ctnDom.current) return;
const ctn = ctnDom.current;
let renderer;
try {
renderer = new Renderer({
alpha: transparent,
premultipliedAlpha: false,
});
} catch (error) {
console.warn(
"Galaxy: WebGL is not available. The galaxy background will not be rendered.",
error,
);
return;
}
const gl = renderer.gl;
if (!gl) {
console.warn(
"Galaxy: WebGL context is null. The galaxy background will not be rendered.",
);
return;
}
if (transparent) {
gl.enable(gl.BLEND);
gl.blendFunc(gl.SRC_ALPHA, gl.ONE_MINUS_SRC_ALPHA);
gl.clearColor(0, 0, 0, 0);
} else {
gl.clearColor(0, 0, 0, 1);
}
/** @type {Program | undefined} */
let program;
function resize() {
const scale = 1;
renderer.setSize(ctn.offsetWidth * scale, ctn.offsetHeight * scale);
if (program) {
program.uniforms.uResolution.value = new Color(
gl.canvas.width,
gl.canvas.height,
gl.canvas.width / gl.canvas.height,
);
}
}
window.addEventListener("resize", resize, false);
resize();
const geometry = new Triangle(gl);
program = new Program(gl, {
vertex: vertexShader,
fragment: fragmentShader,
uniforms: {
uTime: { value: 0 },
uResolution: {
value: new Color(
gl.canvas.width,
gl.canvas.height,
gl.canvas.width / gl.canvas.height,
),
},
uFocal: { value: new Float32Array(focal) },
uRotation: { value: new Float32Array(rotation) },
uStarSpeed: { value: starSpeed },
uDensity: { value: density },
uHueShift: { value: hueShift },
uSpeed: { value: speed },
uMouse: {
value: new Float32Array([
smoothMousePos.current.x,
smoothMousePos.current.y,
]),
},
uGlowIntensity: { value: glowIntensity },
uSaturation: { value: saturation },
uMouseRepulsion: { value: mouseRepulsion },
uTwinkleIntensity: { value: twinkleIntensity },
uRotationSpeed: { value: rotationSpeed },
uRepulsionStrength: { value: repulsionStrength },
uMouseActiveFactor: { value: 0.0 },
uAutoCenterRepulsion: { value: autoCenterRepulsion },
uTransparent: { value: transparent },
},
});
const mesh = new Mesh(gl, { geometry, program });
let animateId;
function update(t) {
animateId = requestAnimationFrame(update);
if (!disableAnimation) {
program.uniforms.uTime.value = t * 0.001;
program.uniforms.uStarSpeed.value = (t * 0.001 * starSpeed) / 10.0;
}
const lerpFactor = 0.05;
smoothMousePos.current.x +=
(targetMousePos.current.x - smoothMousePos.current.x) * lerpFactor;
smoothMousePos.current.y +=
(targetMousePos.current.y - smoothMousePos.current.y) * lerpFactor;
smoothMouseActive.current +=
(targetMouseActive.current - smoothMouseActive.current) * lerpFactor;
program.uniforms.uMouse.value[0] = smoothMousePos.current.x;
program.uniforms.uMouse.value[1] = smoothMousePos.current.y;
program.uniforms.uMouseActiveFactor.value = smoothMouseActive.current;
renderer.render({ scene: mesh });
}
animateId = requestAnimationFrame(update);
ctn.appendChild(gl.canvas);
function handleMouseMove(e) {
const rect = ctn.getBoundingClientRect();
const x = (e.clientX - rect.left) / rect.width;
const y = 1.0 - (e.clientY - rect.top) / rect.height;
targetMousePos.current = { x, y };
targetMouseActive.current = 1.0;
}
function handleMouseLeave() {
targetMouseActive.current = 0.0;
}
if (mouseInteraction) {
ctn.addEventListener("mousemove", handleMouseMove);
ctn.addEventListener("mouseleave", handleMouseLeave);
}
return () => {
cancelAnimationFrame(animateId);
window.removeEventListener("resize", resize);
if (mouseInteraction) {
ctn.removeEventListener("mousemove", handleMouseMove);
ctn.removeEventListener("mouseleave", handleMouseLeave);
}
ctn.removeChild(gl.canvas);
gl.getExtension("WEBGL_lose_context")?.loseContext();
};
}, [
focal,
rotation,
starSpeed,
density,
hueShift,
disableAnimation,
speed,
mouseInteraction,
glowIntensity,
saturation,
mouseRepulsion,
twinkleIntensity,
rotationSpeed,
repulsionStrength,
autoCenterRepulsion,
transparent,
]);
return <div ref={ctnDom} className="galaxy-container" {...rest} />;
}
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