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@@ -68,11 +68,28 @@ export function buildCybersigil(opts: SigilOptions = {}): string {
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const emit = (d: string, cls: string) => {
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if (strokeCount >= MAX_PATHS) return;
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parts.push(
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`<path class="${cls}" d="${d}" pathLength="1" style="--i:${strokeCount % 16}"/>`,
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`<path class="${cls}" d="${d}" pathLength="1" style="--i:${strokeCount % 16}" filter="url(#cs-erosion)"/>`,
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);
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strokeCount++;
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};
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const emitText = (x: number, y: number, txt: string, cls: string) => {
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parts.push(
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`<text x="${n(x)}" y="${n(y)}" class="${cls}" style="--i:${strokeCount % 16}">${txt}</text>`,
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);
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strokeCount++;
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};
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const microFilaments = (at: Pt, ang: number) => {
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const num = 5 + Math.floor(rng() * 5);
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for (let i = 0; i < num; i++) {
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const a = ang + rnd(-0.5, 0.5);
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const l = rnd(2, 8);
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const tip: Pt = [at[0] + Math.cos(a) * l, at[1] + Math.sin(a) * l];
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emit(`M${n(at[0])} ${n(at[1])} L${n(tip[0])} ${n(tip[1])}`, 'cs-sig-micro');
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}
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};
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// Catmull-Rom → cubic Bézier through an ordered point list (organic sweep).
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const spline = (pts: Pt[], tension = 6): string => {
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if (pts.length < 2) return '';
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@@ -146,8 +163,19 @@ export function buildCybersigil(opts: SigilOptions = {}): string {
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const pts: Pt[] = [[ox, oy], mid, peak, hook, tail];
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emit(spline(pts, 5.5), 'cs-sig-main');
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// Bifurcation: split at the mid point with a secondary branch
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if (depth > 0 && rng() < 0.45) {
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const bAng = ang + (rng() < 0.5 ? 0.8 : -0.8) + rnd(-0.3, 0.3);
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const bL = L * rnd(0.4, 0.7);
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const bPeak: Pt = [mid[0] + Math.cos(bAng) * bL, mid[1] + Math.sin(bAng) * bL];
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const bPts: Pt[] = [mid, bPeak, [bPeak[0] + rnd(-10, 10), bPeak[1] + rnd(10, 20)]];
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emit(spline(bPts, 4), 'cs-sig-main');
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if (rng() < 0.3) ornament(bPeak, bAng, 0.6);
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}
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// terminal spike off the outermost point
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barb(peak, ang + rnd(-0.4, 0.4), scale * rnd(10, 22));
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if (rng() < 0.3) microFilaments(peak, ang);
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// denser filament shadows trailing the main sweep
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const numFilaments = rng() < 0.5 ? 2 : 1;
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@@ -198,15 +226,31 @@ export function buildCybersigil(opts: SigilOptions = {}): string {
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if (depth === 0 && rng() < 0.35) ornament(peak, ang, 0.9);
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};
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// ── Wavering spine: a curve from top to bottom, gently bowing in +x.
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const spineNodes = 6 + Math.floor(rng() * 3);
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// ── Harmonic spine: a weighted wave from top to bottom
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const spineNodes = 8 + Math.floor(rng() * 4);
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const spinePts: Pt[] = [];
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const sFreq = rnd(0.8, 1.8);
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const sAmp = rnd(8, 15);
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for (let i = 0; i <= spineNodes; i++) {
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const y = (H * i) / spineNodes;
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const x = i === 0 || i === spineNodes ? 0 : rnd(0, 14);
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const t = i / spineNodes;
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const y = H * t;
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const x = (i === 0 || i === spineNodes) ? 0 :
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Math.sin(t * Math.PI * sFreq) * sAmp +
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Math.sin(t * Math.PI * sFreq * 2.3) * (sAmp * 0.4);
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spinePts.push([x, y]);
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}
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emit(spline(spinePts, 5), 'cs-sig-main cs-sig-spine');
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// ── Vascular Filaments: high-frequency "shiver" paths tracking the spine
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for (let j = 0; j < 2; j++) {
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const vPts = spinePts.map(([x, y], i) => {
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const t = i / spineNodes;
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const off = Math.sin(t * 22 + rng() * 6) * 1.8;
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return [x + off + (j === 0 ? -2.5 : 2.5), y] as Pt;
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});
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emit(spline(vPts, 6.5), 'cs-sig-vessel');
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}
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// ── Chromatic Aberration: two faint, offset echoes of the spine
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emit(spline(spinePts.map(([x, y]) => [x - 1.5, y] as Pt), 5), 'cs-sig-spine-ab cs-sig-spine-ab--1');
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emit(spline(spinePts.map(([x, y]) => [x + 1.5, y] as Pt), 5), 'cs-sig-spine-ab cs-sig-spine-ab--2');
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@@ -256,6 +300,14 @@ export function buildCybersigil(opts: SigilOptions = {}): string {
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emit(`M${n(n1[0])} ${n(n1[1])} L${n(n2[0])} ${n(n2[1])}`, 'cs-sig-connect');
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}
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// ── Ghost Symbols: tiny technical fragments
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const symbols = ['0x00', 'NULL', 'VOID', 'ERR', 'INIT', 'HALT', 'RECLAIM', 'DEAD'];
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const numSymbols = 2 + Math.floor(rng() * 3);
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for (let i = 0; i < numSymbols; i++) {
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const pt = pick(nodePoints);
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emitText(pt[0] + rnd(4, 12), pt[1] + rnd(-4, 4), pick(symbols), 'cs-sig-text');
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}
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const half = parts.join('');
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const minX = -(maxX + PAD);
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const vbW = 2 * (maxX + PAD);
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@@ -263,6 +315,12 @@ export function buildCybersigil(opts: SigilOptions = {}): string {
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`<svg class="cs-sigil" viewBox="${n(minX)} ${-PAD} ${n(vbW)} ${H + 2 * PAD}" ` +
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`preserveAspectRatio="xMidYMid meet" aria-hidden="true" focusable="false" ` +
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`xmlns="http://www.w3.org/2000/svg">` +
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`<defs>` +
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`<filter id="cs-erosion" x="-20%" y="-20%" width="140%" height="140%">` +
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`<feTurbulence type="fractalNoise" baseFrequency="0.6" numOctaves="3" result="noise" />` +
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`<feDisplacementMap in="SourceGraphic" in2="noise" scale="1.5" xChannelSelector="R" yChannelSelector="G" />` +
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`</filter>` +
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`</defs>` +
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`<g class="cs-sig-half">${half}</g>` +
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`<g class="cs-sig-half" transform="scale(-1 1)">${half}</g>` +
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`</svg>`
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