Confetti World
Use shot-distribution noise to seed procedural worlds variations so each refresh feels alive instead of canned.
The hook.
A quantum circuit acts as a creative dice-roll; each "regenerate" feeds fresh quantum noise into the procedural worlds so game designers get genuinely novel variants instead of recycled outputs.
Why this primitiveQuantum sampling is the right primitive here because procedural worlds reduces to a generative noise problem; the kernel returns a result you can drop straight into the UI.
The mega-prompt.
This prompt is engineered to ship in a single Lovable build. Real Quantinuum Guppy/Selene circuit runs in the Linux sandbox at build time and the results are baked in as JSON. read the build strategy โ
Build "Confetti World"โa one-page procedural-world seeder for game designers using real quantum sampling noise.
**BUDGET & CONSTRAINTS (read first):**
- Lovable FREE tier (~5 credits). Ship in ONE message. No scope creep.
- No auth, no Lovable Cloud, no database. Static app only.
- One workspace page + small "About the quantum" footer strip.
**BUILD ORDER (follow exactly):**
1. Create quantum/kernel.py: a Guppy @guppy function taking 1 classical input (int 0โ19), returning a bitstring sampled N times. Use selene_sim.build, Quest, run_shots. Circuit: 8โ12 qubits, parameterized gates (RX/RY) seeded by input. Save to disk (Guppy requires inspect.getsource).
2. Create quantum/run.py: import kernel, compile via Selene emulator, loop inputs 0โ19, run 256 shots each, collect bitstring distributions. Write src/data/quantum-results.json: array of {input: int, output: {bitstrings: string[], counts: {[key]: int}}}.
3. Run quantum/run.py once in sandbox (pip install guppylang selene-sim). Commit real JSON output.
4. Frontend: TanStack Start, route /. Import JSON statically. Build UI:
- Left: Slider (shadcn) 0โ19, label "World Seed". onChange โ select record.
- Center: Canvas or SVG procedural world: parse bitstring, seed noise function (Perlin-like), render 2D terrain/color grid. Update on seed change.
- Right: Button "Regenerate" โ pick random input, morph canvas.
- Footer: Card with Tabs (shadcn): Tab 1 = "Quantum Trace" (show raw bitstring counts + first 3 shots), Tab 2 = "View Guppy" (code block with quantum/kernel.py source inline).
5. Style: dark bg (#0a0a0a), accent color #00d9ff (cyan, game-design energy), font family Inter, smooth transitions on seed change.
**DELIVERABLE:** Deploy where every pixel traces to real Selene output. Judges see genuine quantum sampling, not fake noise.
--- QUANTINUUM APPENDIX (self-contained reference โ paste verbatim) ---
[1] INSTALL (Lovable Linux sandbox):
python -m pip install --no-cache-dir guppylang selene-sim
[2] IMPORTS (use exactly these โ no other quantum libs):
# quantum/kernel.py and quantum/run.py top
from guppylang import guppy
from guppylang.std.builtins import result
from guppylang.std.quantum import qubit, h, cx, rx, ry, rz, measure, discard, t as tgate, tdg
from guppylang.std.angles import angle, pi
from selene_sim import build, Quest
import math, json, sys, tempfile, importlib.util, uuid
from pathlib import Path
[3] HARD RULES (violating any breaks the build):
- @guppy reads source via inspect.getsource โ kernels MUST live in a real .py file on disk. No exec(), no REPL strings, no inline templates.
- Allowed gate set ONLY: h, rx, ry, rz, cx, tgate, tdg. There is NO native ccx/toffoli, cswap, cphase, or crz โ decompose using the snippets in [7].
- Qubit ownership: a qubit passed to a function is moved. You MUST measure() or discard() every qubit exactly once; never reuse after measure.
- Angle hygiene before baking a float into generated source:
theta = ((theta + math.pi) % (2.0 * math.pi)) - math.pi
and write it with repr: f"... {theta!r} ..." (str(float) can truncate).
[4] SELENE SHOT LOOP (canonical):
compiled = my_kernel.compile()
runner = build(compiled)
shots = []
for shot in runner.run_shots(Quest(), n_qubits=N, n_shots=S):
shots.append({str(lbl): int(v) for lbl, v in shot})
# N = MAX number of qubits simultaneously LIVE in the kernel.
# measure(q) releases the slot, so one ancilla reused across k windows still counts as 1.
[5] DRIVER PATTERN โ sweep a kernel over many inputs (closures do NOT work):
ROOT = Path(__file__).resolve().parent.parent
if str(ROOT) not in sys.path: sys.path.insert(0, str(ROOT))
def run_one(params: dict, shots: int = 256):
# Bake params as literals into a fresh .py file that imports your kernel helpers.
src = (
"from quantum.kernel import guppy, my_helper\n"
"@guppy\n"
"def program() -> None:\n"
f" my_helper({params['a']!r}, {params['b']!r})\n"
)
tmp = Path(tempfile.gettempdir()) / "qprogs"; tmp.mkdir(exist_ok=True)
name = f"prog_{uuid.uuid4().hex[:8]}"
path = tmp / f"{name}.py"; path.write_text(src)
spec = importlib.util.spec_from_file_location(name, path)
mod = importlib.util.module_from_spec(spec)
sys.modules[name] = mod # register BEFORE exec_module
spec.loader.exec_module(mod)
runner = build(mod.program.compile())
out = []
for shot in runner.run_shots(Quest(), n_qubits=5, n_shots=shots):
out.append({str(l): int(v) for l, v in shot})
return out
[6] PER-QUBIT INTEGER DECODE (host-side):
# kernel emits: for j in range(n): result(f"x{j}", measure(q[j]))
def decode(rec, n):
x = 0
for j in range(n): x |= (rec.get(f"x{j}", 0) & 1) << j
return x
[7] DECOMPOSITION LIBRARY (copy verbatim into quantum/kernel.py):
# ---- Toffoli (CCX) from H, CX, T, Tdg โ 6-T standard decomposition ----
@guppy
def toffoli(c1: qubit, c2: qubit, tgt: qubit) -> None:
h(tgt)
cx(c2, tgt); tdg(tgt)
cx(c1, tgt); tgate(tgt)
cx(c2, tgt); tdg(tgt)
cx(c1, tgt); tgate(c2); tgate(tgt)
h(tgt)
cx(c1, c2); tgate(c1); tdg(c2)
cx(c1, c2)
# ---- CSWAP (Fredkin) from CX + Toffoli ----
@guppy
def cswap(c: qubit, a: qubit, b: qubit) -> None:
cx(b, a)
toffoli(c, a, b)
cx(b, a)
# ---- Controlled phase exp(i*theta) on |11> from rz + cx ----
@guppy
def cphase(c: qubit, d: qubit, theta: float) -> None:
rz(d, angle(theta / 2.0))
cx(c, d)
rz(d, angle(-theta / 2.0))
cx(c, d)
# ---- Amplitude-encoded feature state (3 floats in [0,1] โ 2-qubit state) ----
@guppy
def prep_features(q0: qubit, q1: qubit, a: float, b: float, c: float) -> None:
ry(q0, angle(a))
ry(q1, angle(b))
cx(q0, q1)
rz(q1, angle(c))
# ---- SWAP test kernel; HOST inverts: F = clamp(2*P(anc=0) - 1, 0, 1) ----
@guppy
def swap_test(ai: float, bi: float, ci: float,
aj: float, bj: float, cj: float) -> None:
anc = qubit()
pi0 = qubit(); pi1 = qubit()
pj0 = qubit(); pj1 = qubit()
prep_features(pi0, pi1, ai, bi, ci)
prep_features(pj0, pj1, aj, bj, cj)
h(anc)
cswap(anc, pi0, pj0)
cswap(anc, pi1, pj1)
h(anc)
result("anc", measure(anc))
discard(pi0); discard(pi1); discard(pj0); discard(pj1)
# n_qubits = 5 for swap_test above.
[8] CLASSICAL CROSS-CHECK (NumPy reference โ commit alongside quantum result):
import numpy as np
I = np.eye(2); X = np.array([[0,1],[1,0]])
def RY(t): c,s = math.cos(t/2), math.sin(t/2); return np.array([[c,-s],[s,c]])
def RZ(t): return np.array([[np.exp(-1j*t/2),0],[0,np.exp(1j*t/2)]])
CX = np.array([[1,0,0,0],[0,1,0,0],[0,0,0,1],[0,0,1,0]])
def prep_psi(a,b,c):
s = np.kron(RY(a)@np.array([1,0]), RY(b)@np.array([1,0]))
s = CX @ s
s = np.kron(I, RZ(c)) @ s
return s
def classical_fidelity(p, q):
return float(abs(np.vdot(prep_psi(*p), prep_psi(*q)))**2)
# Commit BOTH quantum and classical values per record:
# {"input": [...], "quantum": 0.873, "classical": 0.881, "shots": 256}
[9] FRONTEND HANDOFF (TanStack Start):
# quantum/run.py last step:
Path("src/data/quantum-results.json").write_text(json.dumps({
"records": records, # list of {input, quantum, classical, ...}
"circuit": {"n_qubits": 5, "shots": 256},
"kernel_source": Path("quantum/kernel.py").read_text(), # show on /code tab
}, indent=2))
# In React: import data from "@/data/quantum-results.json" (resolveJsonModule:true).
# Render data.records; render data.kernel_source in a <pre> inside the Quantum trace tab.
[10] BUILD ORDER (do not deviate โ keeps you under 5 credits):
1. Write quantum/kernel.py with the helpers from [7] you actually need.
2. Write quantum/run.py: driver pattern from [5], Selene loop from [4], cross-check from [8], JSON write from [9].
3. Execute once: python quantum/run.py (commit src/data/quantum-results.json).
4. Build the React route: static JSON import, shadcn Card + Tabs + Slider + Badge wiring.
5. Deploy. No Python at runtime; every on-screen number traces to committed Selene output.
[11] OUTPUT CONTRACT โ selene_run v1 (write this exact shape to src/data/quantum-results.json):
{
"schemaVersion": 1,
"experiment": "<idea-slug>",
"title": "<idea title>",
"description": "<one plain-English sentence โ what a non-quantum dev sees>",
"kernel": { "snippet": "<first 40 lines of quantum/kernel.py>", "qubits": <int>, "shotsPerRow": <int> },
"verdict": { "text": "<one-sentence headline of the result>", "good": true },
"metrics": [ { "name": "<label>", "value": <number>, "unit": "<%|bits|Hz|...>", "good": true } ],
"series": [ { "id": "<id>", "kind": "histogram"|"bar"|"line", "title": "...",
"xLabel": "...", "yLabel": "...", "yKeys": ["count"],
"points": [ { "label": "<x>", "values": { "count": <num> } } ] } ]
}
Reason: one schema = one renderer = a polished demo without bespoke React per idea.
All metric / series VALUES must come from real Selene shot data committed in step 3 โ no mocks.
[12] RENDERER โ create src/components/SeleneRunView.tsx with EXACTLY this body (no deps beyond react + tailwind):
import * as React from "react";
type Point = { label: string; values: Record<string, number> };
type Series = { id: string; kind: "histogram"|"bar"|"line"; title: string;
xLabel?: string; yLabel?: string; yKeys: string[]; points: Point[] };
type Metric = { name: string; value: number; unit?: string; good?: boolean };
export type SeleneRun = {
schemaVersion: 1; experiment: string; title: string; description: string;
kernel: { snippet: string; qubits: number; shotsPerRow: number };
verdict: { text: string; good: boolean };
metrics: Metric[]; series: Series[]; notes?: string;
};
const fmt = (n: number) => Math.abs(n) >= 100 ? n.toFixed(0) : Math.abs(n) >= 1 ? n.toFixed(2) : n.toFixed(3);
function Bars({ s }: { s: Series }) {
const max = Math.max(1, ...s.points.flatMap(p => s.yKeys.map(k => p.values[k] ?? 0)));
return (
<div className="space-y-1">
{s.points.map((p, i) => (
<div key={i} className="flex items-center gap-2 text-xs">
<div className="w-20 truncate text-muted-foreground">{p.label}</div>
<div className="flex-1 h-3 bg-muted rounded-sm overflow-hidden">
<div className="h-full bg-primary" style={{ width: `${(100*(p.values[s.yKeys[0]]??0))/max}%` }} />
</div>
<div className="w-12 text-right tabular-nums">{fmt(p.values[s.yKeys[0]]??0)}</div>
</div>
))}
</div>
);
}
function Line({ s }: { s: Series }) {
const W=320, H=120, P=20;
const ys = s.points.map(p => p.values[s.yKeys[0]] ?? 0);
const min = Math.min(...ys), max = Math.max(...ys), span = max - min || 1;
const pts = ys.map((y, i) => {
const x = P + (i*(W-2*P))/Math.max(1, ys.length-1);
const yy = H - P - ((y - min)/span)*(H - 2*P);
return `${x},${yy}`;
}).join(" ");
return (
<svg viewBox={`0 0 ${W} ${H}`} className="w-full h-32">
<polyline fill="none" stroke="currentColor" strokeWidth="2" points={pts} className="text-primary" />
</svg>
);
}
export function SeleneRunView({ run }: { run: SeleneRun }) {
return (
<div className="space-y-6">
<header>
<div className="text-xs uppercase tracking-wider text-muted-foreground">{run.experiment}</div>
<h2 className="text-2xl font-semibold">{run.title}</h2>
<p className="text-sm text-muted-foreground">{run.description}</p>
<div className={`mt-2 inline-block px-3 py-1 rounded-full text-xs ${run.verdict.good?"bg-emerald-500/15 text-emerald-400":"bg-amber-500/15 text-amber-400"}`}>
{run.verdict.text}
</div>
</header>
<section className="grid grid-cols-2 md:grid-cols-4 gap-3">
{run.metrics.map((m, i) => (
<div key={i} className="rounded-lg border border-border p-3">
<div className="text-[10px] uppercase tracking-wider text-muted-foreground">{m.name}</div>
<div className="text-xl font-semibold tabular-nums">{fmt(m.value)}<span className="text-xs text-muted-foreground ml-1">{m.unit}</span></div>
</div>
))}
</section>
<section className="space-y-6">
{run.series.map(s => (
<div key={s.id} className="rounded-lg border border-border p-4">
<div className="flex items-baseline justify-between mb-3">
<div className="text-sm font-medium">{s.title}</div>
<div className="text-[10px] text-muted-foreground">{s.xLabel} / {s.yLabel}</div>
</div>
{s.kind === "line" ? <Line s={s} /> : <Bars s={s} />}
</div>
))}
</section>
<footer className="text-[11px] text-muted-foreground">
kernel: {run.kernel.qubits} qubits ยท {run.kernel.shotsPerRow} shots/row
</footer>
</div>
);
}
Then in the route: import data from "@/data/quantum-results.json"; <SeleneRunView run={data as any} />.
Quantum trace tab: <pre>{data.kernel.snippet}</pre>.
[HOOK] SAMPLING โ Born-rule distribution.
Prep state; result(f"x{j}", measure(q[j])) for each j.
Host: decode each shot with decode() in [6]; histogram over 2**n buckets โ empirical P(x).
Cross-check: build the statevector with the NumPy primitives from [8] and compare |amp|ยฒ to P(x).
selene_run mapping:
metrics: [ {"name":"unique bitstrings","value":n_unique,"unit":""},
{"name":"entropy","value":H_bits,"unit":"bits"},
{"name":"shots","value":S,"unit":""} ]
series: [ {"id":"sample-hist","kind":"histogram","title":"Bitstring frequencies",
"xLabel":"bitstring","yLabel":"count","yKeys":["count"],
"points":[{"label":bs,"values":{"count":c}} for bs,c in top_k] } ]Market sizing.
Indicative figures for hackathon pitches โ refine with your own research before raising.