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Kannaka Quantum

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Enables AI agents to execute quantum circuits, generate true quantum random bits, and perform resonance recall using amplitude amplification on real quantum bac

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Описание

Enables AI agents to execute quantum circuits, generate true quantum random bits, and perform resonance recall using amplitude amplification on real quantum backends via qBraid.

README

Real quantum capabilities for Kannaka, executed on actual quantum backends.

Kannaka's memory is a Holographic Resonance Medium — recall is wave interference, and "attention acts as gravity: wavefronts whose phase/amplitude align with the query are pulled forward." That is, almost verbatim, the definition of quantum amplitude amplification. This package makes the correspondence literal: it runs Kannaka's recall — plus arbitrary circuits and a true-entropy source — on real quantum hardware.

It is a multi-provider bridge with two surfaces over one core:

  • a JSON CLI — the Kannaka coding agent shells out to it to write & run quantum programs;
  • an MCP server — any MCP client (Claude Code, the kannaka-tui harness, other agents) gets the same tools.

Capabilities

tool (MCP) / subcommand (CLI) what it does
quantum_devices / devices List QPUs + simulators across providers, with status, qubit counts, and cost.
run_circuit / run Execute an OpenQASM 3 circuit on a backend; returns measurement counts.
quantum_random / qrng True quantum random bits from measurement collapse (not a PRNG) — a quantum entropy source for the medium's irrationality (Ξ) and dream noise.
harvest Harvest raw bits from a real QPU into a local entropy reservoir (the free simulator is a PRNG and is refused). Spend-guarded.
qrng-status Reservoir level, last-harvest provenance, and estimated refill cost.
qrng-draw Draw bits from the reservoir — raw, or (--expand) seed a NIST SP 800-90A HMAC-DRBG and expand. Every draw carries a provenance chain back to a QPU job_id; an empty reservoir fails loudly (no silent PRNG fallback).
resonance_recall / recall The showcase. Amplitude-encode candidate memory resonances into a quantum state and amplitude-amplify toward the strongest — Kannaka's recall, run as interference on a quantum computer.

Providers & routing

A single device string selects both the provider and the backend. The prefix routes:

device string provider notes
qbraid:… qBraid Default. The free simulator qbraid:qbraid:sim:qir-sv (≤28 qubits) needs no credits. Real QPUs spend qBraid credits ($0.01 each).
openquantum:… OpenQuantum (Quantum Rings) Real QPUs only (IonQ / Rigetti / IQM / AQT) — no free simulator; every job spends "Spark" credits (1 credit = $2; free tier 25 credits / $50 per 90 days). Form: openquantum:<backend> e.g. openquantum:iqm:garnet.

The free qBraid simulator is the default device everywhere, so casual and agent-driven use never spends money. Real hardware runs only when you name a hardware device and opt into spending (see Spend safety).

How each provider is integrated

  • qBraid — via qbraid.runtime.QbraidProvider. provider.get_device(id).run(qasm3, shots=…), then job.result(). Live per-task/per-shot/per-minute pricing is read from device.metadata()['pricing'].

  • OpenQuantum — via the openquantum-sdk package over OAuth2 client-credentials:

    from openquantum_sdk import ManagementClient, SchedulerClient
    from openquantum_sdk.auth import ClientCredentials
    from openquantum_sdk.clients import ClientCredentialsAuth, JobSubmissionConfig
    
    auth  = ClientCredentialsAuth(ClientCredentials(client_id, client_secret))
    mgmt  = ManagementClient(auth=auth)
    sched = SchedulerClient(auth=auth, management_client=mgmt)
    
    cfg = JobSubmissionConfig(
        backend_class_id="iqm:garnet",       # the part after "openquantum:"
        name="kannaka-quantum",
        job_subcategory_id="phys:oth",        # required workload tag
        shots=256,
        organization_id=org_id,               # auto-discovered (see below)
        auto_approve_quote=True,
    )
    job    = sched.submit_job(cfg, file_content=qasm.encode("utf-8"))
    output = sched.download_job_output(job)
    

    The bridge wraps all of this — you only ever pass a device string and OpenQASM. See OpenQuantum integration internals for the full authoritative SDK surface (endpoints, auth, config fields, method map).


Install

pip install kannaka-quantum        # or: pip install -e .   (from this directory)

Requires Python ≥ 3.10. Dependencies: qbraid, qiskit, numpy, mcp, and openquantum-sdk.


Authentication

Configure whichever provider(s) you'll use. The free qBraid simulator works with a qBraid key alone; OpenQuantum is optional and only needed for its real QPUs.

qBraid — an API key, resolved in order:

  1. QBRAID_API_KEY
  2. a saved ~/.qbraid/qbraidrc (QbraidProvider(api_key=…).save_config())
  3. ~/Downloads/QBraid.txt (a workstation convenience; first qbr_… match)

OpenQuantum — client credentials, resolved in order:

  1. OPENQUANTUM_CLIENT_ID + OPENQUANTUM_CLIENT_SECRET
  2. a JSON SDK key at OPENQUANTUM_SDK_KEY
  3. ~/.openquantum/sdk-key.json
  4. ~/Downloads/sdk-key-*.json (workstation convenience)

If no OpenQuantum credentials are present, the bridge simply omits OpenQuantum from device listings and stays fully usable on qBraid.


CLI

Every subcommand prints one JSON object to stdout (errors included), so a caller can parse it directly.

kannaka-quantum devices --online
kannaka-quantum run --qasm-file bell.qasm --shots 200
kannaka-quantum qrng --bits 16
kannaka-quantum recall --amplitudes 0.1,0.9,0.2,0.15 --labels alpha,beta,gamma,delta

# Entropy reservoir (real-QPU-only) + provenance-tracked DRBG
kannaka-quantum harvest --allow-spend                       # 2048 bits from a real QPU → reservoir
kannaka-quantum qrng-status                                 # level, provenance, refill cost
kannaka-quantum qrng-draw --bits 256 --expand               # HMAC-DRBG stream seeded by the reservoir

run reads OpenQASM 3 from --qasm, --qasm-file, or stdin (-). Spend options (--allow-spend, --max-credits, --subcategory) apply to run/qrng/recall/harvest.

Entropy reservoir

harvest runs qrng against a real per-shot QPU (default openquantum:rigetti:cepheus-1-108q, ~$0.000255/shot) and appends the raw bits to ~/.kannaka/entropy/reservoir.bin, with a provenance line (device, job_id, n_bits, cost_usd, timestamp) in reservoir.meta.jsonl. The free simulator is a PRNG and is refused. qrng-draw returns raw reservoir bits, or with --expand seeds a NIST SP 800-90A HMAC-DRBG (stdlib only) and expands — every draw records the harvest(s) that seeded it, so the stream chains back to a QPU job_id. An empty reservoir fails loudly; there is no silent software-PRNG fallback.

Example: resonance recall

$ kannaka-quantum recall --amplitudes 0.1,0.9,0.2,0.15 --labels alpha,beta,gamma,delta
{"distribution": {"alpha": 2, "beta": 775, "gamma": 240, "delta": 7},
 "quantum_top": "beta", "classical_top": "beta", "agree": true,
 "qubits": 2, "candidates": 4, "amplified": true,
 "device": "qbraid:qbraid:sim:qir-sv"}

Amplitude amplification sharpens the prepared resonance state toward the strongest memory — the recall ran on a quantum computer, and it agrees with the classical argmax. The iteration count is derived from the target's initial amplitude ((π/2 − θ)/2θ), not the textbook (π/4)√N, so an already-dominant memory isn't over-rotated and de-amplified.


MCP server

kannaka-quantum mcp        # stdio transport

Register with Claude Code:

claude mcp add kannaka-quantum -- python -m kannaka_quantum mcp

…then any agent can call quantum_devices, run_circuit, quantum_random, and resonance_recall. (Shipped as a Claude Code plugin too — see .claude-plugin/ and skills/kannaka-quantum/.)


OpenQuantum integration internals

The authoritative surface, verified against openquantum-sdk 0.3.7 (the docs' overview omits most of this). Everything below is wrapped by the bridge; you don't call it directly, but this is what an openquantum:… device routes through.

Services & auth

OpenQuantum is three HTTP services behind a Keycloak identity provider:

service default base URL role
Identity (Keycloak) https://id.openquantum.com (realm platform) OAuth2 client-credentials → bearer token
Management https://management.openquantum.com backends, organizations, categories
Scheduler https://scheduler.openquantum.com job submit / status / output
ClientCredentialsAuth(
    creds,                                      # ClientCredentials(client_id, client_secret)
    keycloak_base="https://id.openquantum.com",
    realm="platform",
    scope=None,
    leeway_seconds=30,                          # token-refresh clock skew
    session=None,
)

Auth is OAuth2 client-credentials with automatic token refresh — construct it once and the clients reuse/refresh the bearer token. client_id is prefixed s_…. Both clients accept either an auth= object or a raw token=:

SchedulerClient(base_url="https://scheduler.openquantum.com",  token=None, auth=None, management_client=None)
ManagementClient(base_url="https://management.openquantum.com", token=None, auth=None)

A SchedulerClient will lazily build its own ManagementClient for organization auto-discovery if you don't pass one. The bridge passes an explicit shared mgmt so both clients reuse one token.

JobSubmissionConfig fields

field type the bridge sets
backend_class_id str the part after openquantum: (e.g. iqm:garnet)
name str "kannaka-quantum"
job_subcategory_id str "phys:oth" (required workload tag; override via --subcategory / OPENQUANTUM_SUBCATEGORY)
shots int the requested shot count
organization_id Optional[str] resolved from mgmt.list_user_organizations(...)
auto_approve_quote bool True — accept the live cost quote (already bounded by the pre-flight credit cap)
configuration_data Optional[Dict]
execution_plan / queue_priority enum / auto left at the SDK's AutoChoice
job_timeout_seconds, verbose int / bool SDK defaults

SchedulerClient method map

job    = sched.submit_job(config, *, file_content=bytes | None, file_path=str | None)  # -> JobRead
output = sched.download_job_output(job)                                                # -> Any (counts)
sched.close()

The bridge submits in-memory (file_content=qasm.encode("utf-8")) rather than from a file. Other lifecycle methods the SDK exposes (not currently used): get_job, list_jobs, cancel_job, prepare_job / get_preparation_result, upload_job_input, get_job_categories / get_job_subcategories, get_backend_class.

Result shape note. download_job_output returns provider-dependent JSON. The bridge's _oq_counts tries counts / measurement_counts / histogram / meas keys and a few accessor shapes, then falls back to attaching the raw output under raw_output so the parser can be tightened once a given backend's exact shape is observed. Backend qubit-ordering for resonance_recall is treated as big-endian-no-reverse (like AWS-routed devices) pending a confirmed real recall on an OpenQuantum QPU.


Spend safety

The whole point is that casual use is free and a careless run can't drain the budget.

  • Free by default. The default device is the free qBraid simulator; nothing spends until you name a hardware device.
  • Explicit opt-in. A real-QPU run requires allow_spend=True (CLI --allow-spend) or KANNAKA_QUANTUM_ALLOW_SPEND=1. Otherwise it raises and points you back to the free simulator.
  • Credit ceiling. Every paid run is bounded by max_credits (CLI --max-credits); over-cap pre-flight estimates raise instead of submitting. Defaults: qBraid 200 credits (≈ $2), OpenQuantum 1 credit (≈ $2). Override via QBRAID_MAX_CREDITS / OPENQUANTUM_MAX_CREDITS.
  • Per-minute devices are refused. qBraid's native Rigetti bills per minute (~12000 credits/min ≈ $120/min) — cost can't be bounded from a shot count, so the bridge rejects per-minute devices outright. Use a per-shot device instead.

All three hazards (no-opt-in, over-cap, per-minute) raise before any job is submitted — verified at $0.

Cheap real QPUs

device provider ~cost (256 shots)
openquantum:iqm:garnet OpenQuantum $0.00087/shot ≈ $0.22
openquantum:rigetti:cepheus-1-108q OpenQuantum $0.000255/shot ≈ $0.07
aws:rigetti:qpu:cepheus-1-108q qBraid 30 + 0.0425/shot credits ≈ $0.41
⚠️ rigetti:rigetti:qpu:cepheus-1-108q qBraid (native) $120/min — refused

Verified benchmark (simulator vs real hardware)

Same Bell state, 256 shots:

run device result leakage
simulator qbraid:qbraid:sim:qir-sv 00: 122, 11: 134 0%
real QPU aws:rigetti:qpu:cepheus-1-108q 00: 127, 11: 115, 01+10: 14 5.5% ($0.41)

≈ 94.5% fidelity under real device noise.


Development

pip install -e .
pytest                 # 6 network-free tests (no credentials or backend needed)

The core (kannaka_quantum/core.py) is provider-agnostic; cli.py and mcp_server.py are thin surfaces over it.

Releasing

This repo doesn't tag releases yet. When it does, pushing a v* tag (e.g. v0.2.4) also updates the constellation marketplace: the notify-marketplace workflow sends a plugin-released dispatch to kannaka-constellation-marketplace, which opens a PR bumping kannaka-quantum's version in its manifest and README.

Keep pyproject.toml and .claude-plugin/plugin.json versions in step with the tag. The cascade is dormant until a KANNAKA_CASCADE_PAT secret (a PAT with contents: write + pull-requests: write on the marketplace repo) is added to this repo's Actions secrets; until then the workflow just logs a warning and no-ops.

License

MIT.

from github.com/NickFlach/kannaka-quantum

Установка Kannaka Quantum

У этого сервера нет опубликованного пакета — он собирается из исходников. Открой репозиторий и следуй инструкции в README.

▸ github.com/NickFlach/kannaka-quantum

FAQ

Kannaka Quantum MCP бесплатный?

Да, Kannaka Quantum MCP бесплатный — установка в пару кликов через Unyly без оплаты.

Нужен ли API-ключ для Kannaka Quantum?

Нет, Kannaka Quantum работает без API-ключей и переменных окружения.

Kannaka Quantum — hosted или self-hosted?

Доступен hosted-вариант: Unyly запускает сервер в облаке, локальная установка не обязательна.

Как установить Kannaka Quantum в Claude Desktop, Claude Code или Cursor?

Открой Kannaka Quantum на unyly.org, выбери вкладку своего клиента (Claude Desktop, Claude Code, Cursor) и нажми Install — конфиг сгенерируется автоматически, без правки JSON.

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