fractured-hive-pulse-z7we/index.html

<!DOCTYPE html>
<html lang="en">
<head>
    <meta charset="UTF-8">
    <meta name="viewport" content="width=device-width, initial-scale=1.0">
    <title>Neurameba Fractal Pulse</title>
    <style>
        body {
            margin: 0;
            overflow: hidden;
            background-color: #0a0a0a;
            color: #ddd;
            font-family: 'Courier New', monospace;
            display: flex;
            flex-direction: column;
            height: 100vh;
        }
        canvas {
            display: block;
            flex: 1;
        }
        .attribution {
            text-align: right;
            padding: 8px 16px;
            font-size: 10px;
            opacity: 0.6;
            background: rgba(0,0,0,0.3);
        }
    </style>
</head>
<body>
    <canvas id="canvas"></canvas>
    <div class="attribution">neurameba · motd.social</div>

    <script>
        const canvas = document.getElementById('canvas');
        const ctx = canvas.getContext('2d');

        // Set canvas to full window size
        function resizeCanvas() {
            canvas.width = window.innerWidth;
            canvas.height = window.innerHeight;
        }
        window.addEventListener('resize', resizeCanvas);
        resizeCanvas();

        // Parameters derived from input
        const params = {
            motion: 0.473,
            density: 0.477,
            complexity: 0.494,
            connectedness: 0.494,
            lifespan: 0.489,
            pulse: { avg: 0.40, min: 0.30, max: 1.95 },
            tone: { anger: 0.00, sadness: 0.00, curiosity: 0.10, dryness: 0.90, playfulness: 0.00, tension: 0.00 },
            metrics: {
                survivingNodes: 146,
                branchCount: 131,
                loops: 1228,
                maxDepth: 27,
                thicknessRatio: 1.50,
                fractalDimension: 1.331,
                finalEnergy: 909.5
            }
        };

        // Derived values
        const pointCount = Math.floor(100 + params.metrics.survivingNodes * 2 * params.density);
        const voronoiMultiplier = 0.8 + params.complexity * 0.4;
        const edgeLife = 200 + params.metrics.maxDepth * 5;
        const lineThickness = 1.2 + params.metrics.thicknessRatio * 0.8;
        const pulseRange = params.pulse.max - params.pulse.min;

        // Generate random points with some clustering
        const points = [];
        const centerX = canvas.width / 2;
        const centerY = canvas.height / 2;
        const maxRadius = Math.min(canvas.width, canvas.height) * 0.45;

        for (let i = 0; i < pointCount; i++) {
            const angle = Math.random() * Math.PI * 2;
            const radius = Math.random() * maxRadius;
            const x = centerX + Math.cos(angle) * radius * (0.7 + Math.random() * 0.6);
            const y = centerY + Math.sin(angle) * radius * (0.7 + Math.random() * 0.6);

            // Add slight movement based on motion parameter
            const vx = (Math.random() - 0.5) * params.motion * 2;
            const vy = (Math.random() - 0.5) * params.motion * 2;

            points.push({
                x, y,
                vx, vy,
                baseX: x, baseY: y,
                energy: 0.5 + Math.random() * 0.5,
                lifespan: 50 + Math.random() * 100
            });
        }

        // Create voronoi diagram using relative points
        function createVoronoi(p) {
            return points.map(pt => ({
                x: pt.x + p * pt.vx * 2,
                y: pt.y + p * pt.vy * 2
            }));
        }

        // Generate edges between nearby points (based on complexity/connectedness)
        function generateEdges(voronoiPoints, t) {
            const edges = [];
            const maxDist = 80 * (0.5 + params.connectedness * 0.8);
            const influence = params.motion * 2;

            for (let i = 0; i < voronoiPoints.length; i++) {
                for (let j = i + 1; j < voronoiPoints.length; j++) {
                    const dx = voronoiPoints[j].x - voronoiPoints[i].x;
                    const dy = voronoiPoints[j].y - voronoiPoints[i].y;
                    const dist = Math.sqrt(dx * dx + dy * dy);

                    if (dist < maxDist) {
                        const strength = 1 - dist / maxDist;
                        const age = (t + (i + j) * 0.1) % edgeLife;
                        const opacity = Math.min(1, strength * (1 - age / edgeLife));

                        edges.push({
                            i, j,
                            length: dist,
                            strength,
                            age,
                            maxAge: edgeLife,
                            pulse: Math.sin(t * 0.002 + (i + j) * 0.1) * 0.5 + 0.5
                        });
                    }
                }
            }

            return edges;
        }

        // Animation state
        let t = 0;
        const trails = [];

        function animate() {
            // Clear with slight trail
            ctx.fillStyle = 'rgba(10, 10, 10, 0.05)';
            ctx.fillRect(0, 0, canvas.width, canvas.height);

            // Calculate pulse effect
            const pulse = params.pulse.avg + Math.sin(t * 0.003) * pulseRange * 0.3;

            // Create voronoi points with motion
            const voronoiPoints = createVoronoi(pulse * 0.15);

            // Generate edges
            const edges = generateEdges(voronoiPoints, t);

            // Draw edges with pulse-based thickness
            edges.forEach(edge => {
                const pulseFactor = edge.pulse < 0.5 ? edge.pulse * 2 : 1 - (edge.pulse - 0.5) * 2;
                const thickness = lineThickness * (0.8 + pulseFactor * 0.4);
                const opacity = 0.6 + params.metrics.finalEnergy / 2000;
                const alpha = opacity * (1 - edge.age / edge.maxAge) * (0.3 + params.density * 0.7);

                ctx.lineWidth = thickness;
                ctx.globalAlpha = alpha;
                ctx.beginPath();
                ctx.moveTo(voronoiPoints[edge.i].x, voronoiPoints[edge.i].y);
                ctx.lineTo(voronoiPoints[edge.j].x, voronoiPoints[edge.j].y);
                ctx.strokeStyle = `hsl(0, 0%, ${60 + Math.sin(t * 0.001 + edge.i) * 10}%)`;
                ctx.stroke();
            });

            // Draw points with some pulsing
            points.forEach((pt, i) => {
                const size = 1.5 + Math.sin(t * 0.002 + i) * 0.5;
                ctx.globalAlpha = pt.energy * (0.7 + pulse * 0.3);
                ctx.beginPath();
                ctx.arc(voronoiPoints[i].x, voronoiPoints[i].y, size, 0, Math.PI * 2);
                ctx.fillStyle = `hsl(0, 0%, ${30 + Math.sin(t * 0.001 + i * 0.3) * 10}%)`;
                ctx.fill();
            });

            t += 1;

            // Add to trails occasionally
            if (t % 15 === 0 && trails.length < 200) {
                trails.push({
                    points: [...voronoiPoints],
                    alpha: 0.1,
                    age: 0
                });
            }

            // Draw trails
            trails.forEach((trail, idx) => {
                trail.age++;
                trail.alpha = 0.1 * (1 - trail.age / 50);

                if (trail.alpha > 0) {
                    trail.points.forEach((pt, i) => {
                        ctx.globalAlpha = trail.alpha * (0.5 + Math.sin(t * 0.002 + i) * 0.3);
                        ctx.beginPath();
                        ctx.arc(pt.x, pt.y, 1, 0, Math.PI * 2);
                        ctx.fillStyle = `hsl(0, 0%, ${50 + Math.sin(t * 0.001 + i * 0.3) * 5}%)`;
                        ctx.fill();
                    });
                } else {
                    trails.splice(idx, 1);
                }
            });

            // Reset opacity
            ctx.globalAlpha = 1;

            requestAnimationFrame(animate);
        }

        animate();
    </script>
</body>
</html>