Grant
8ce78ab9d3
First step of TIER_UPGRADES_DESIGN.md (Grant + me, parent folder).
Schema-only commit; Phases 2-6 (quote logic, buyer endpoints, admin
endpoints, admin UI, buyer surface) ship in follow-ups.
Migration 0013_tier_upgrades.sql:
1. ALTER TABLE policies ADD COLUMN tier_rank INTEGER. Operator-defined
ladder ordering — higher = better tier. NULL means the policy isn't
in any ladder (existing operators see no behavior change). The
buyer-facing upgrade endpoint will validate
target.tier_rank > current.tier_rank for upgrades, and the reverse
for downgrades. Index on (product_id, tier_rank) supports the
"list this product's policies in ladder order" query.
2. New tier_changes table — one row per upgrade/downgrade. Captures:
- from_policy_id / to_policy_id with FKs into policies
- direction ('upgrade' | 'downgrade', CHECK enforced)
- listed_currency + proration_charge_value (smallest unit) for the
pricing snapshot; invoice_id nullable so comp-mode admin changes
(skip_payment=true) can write a row without an invoice
- effective_at decoupled from created_at so downgrades on recurring
subs can be RECORDED immediately but TAKE EFFECT at cycle end
- actor ('buyer' | 'admin', CHECK enforced) + free-form reason
- Three indexes covering the obvious query paths: by license
(history view), by created_at (operator analytics), partial on
invoice_id WHERE NOT NULL (webhook-handler lookup of
"is this settling invoice a tier-change?").
Migration regression test (8 tests now in tests/migrations.rs, was 7):
- Existing pre-0013 fixtures untouched, tier_rank defaults to NULL.
- tier_changes accepts a row referencing pre-0013 license/policy/invoice.
- CHECK constraints fire: bad direction, bad actor, negative
proration_charge_value all rejected.
- assert_db_clean confirms no FK / integrity drift.
Drive-by: branding design doc (parent folder) bumps its migration
number from 0013 → 0014 to avoid a collision with this one.
Test count: 58 (was 57; +1 for migration_0013_adds_tier_upgrades).
Keysat
Keysat is a self-hosted Bitcoin-paid software licensing server, designed to run as a Start9 0.4.0.x service alongside BTCPay Server. One instance can sell, issue, validate, and revoke licenses for any number of software products you own.
The repository directory is still called
licensing-service/on disk for continuity with earlier revisions. The crate, the binary, the StartOS package id, and all user-visible strings use Keysat.
Every developer who uses this runs their own instance on their own hardware. There is no central authority, no shared database, and no dependency on anyone else's servers. Your keys, your products, your customers, your rules.
What it does
- Exposes a REST API for selling and managing software licenses paid for in Bitcoin via BTCPay Server.
- Issues Ed25519-signed license keys that can be verified offline by any client with your server's public key — so downstream software doesn't break if your licensing server is briefly unreachable.
- Supports multiple products per instance, each with independent pricing and license pools.
- Supports closed-source, open-source-for-convenience, and open-core distribution models. The service doesn't care how you distribute source; it only validates keys against products.
- Optional per-license machine fingerprint binding with trust-on-first-use.
- Admin-gated endpoints for product management, manual license issuance (comps/press/testing), and revocation.
Architecture in two minutes
┌──────────────┐ ┌──────────────────────┐ ┌──────────────┐
│ Buyer's │──────▶│ licensing-service │──────▶│ BTCPay Server│
│ browser │ │ (this program) │ │ (Start9) │
└──────────────┘ └──────────────────────┘ └──────────────┘
▲ │ ▲ │
│ license key │ │ webhook │
│ ▼ │ │
│ ┌──────────────┐ │
└─────────────────│ SQLite │◀──────────────────┘
poll/status │ licensing.db
└──────────────┘
Downstream software (e.g. another Start9 package you sell):
on startup → POST /v1/validate { key, product_slug, fingerprint }
→ caches result, re-checks on reasonable cadence
- Buyer
POST /v1/purchase { product: "my-app" }→ we create a BTCPay invoice, return its checkout URL. - Buyer pays via BTCPay. BTCPay fires a signed webhook at
POST /v1/btcpay/webhook→ we mark the invoice settled and issue a license row. - Buyer polls
GET /v1/purchase/:invoice_id→ once settled, response contains the signedlicense_keystring. - Buyer installs the software. On startup the software calls
POST /v1/validateto check revocation and bind itself to the installation.
Why Ed25519-signed keys
Each license key is a compact, cryptographically signed envelope:
LIC1-<74-byte payload, base32>-<64-byte signature, base32>
The payload contains the product id, license id, issue time, an optional fingerprint hash, and a version byte. The server's private key signs it; anyone with the public key can verify it.
The practical benefit: downstream software can verify a key's signature offline, using a public key bundled at compile time. It only needs to reach your licensing server to check revocation, and it can cache that check. If your licensing server has an outage, existing installations keep working. If someone tries to forge a key, the signature fails instantly without a database lookup.
See src/crypto/mod.rs for the exact byte layout.
Project layout
licensing-service/
├── Cargo.toml
├── LICENSE # source-available; no redistribution
├── README.md
├── .env.example # required env vars
├── migrations/
│ └── 0001_initial.sql # SQLite schema
├── src/
│ ├── main.rs # entry point: wires everything
│ ├── config.rs # env-driven config
│ ├── error.rs # unified error → HTTP mapping
│ ├── models.rs # shared domain types
│ ├── crypto/
│ │ ├── mod.rs # license key format + sign/verify
│ │ └── keys.rs # server keypair lifecycle
│ ├── db/
│ │ ├── mod.rs # pool + migrations
│ │ └── repo.rs # all SQL queries
│ ├── btcpay/
│ │ ├── client.rs # Greenfield API client
│ │ └── webhook.rs # HMAC verification + event parsing
│ └── api/
│ ├── mod.rs # router + AppState
│ ├── products.rs # public product endpoints
│ ├── purchase.rs # buy + poll
│ ├── validate.rs # the hot path for downstream software
│ ├── webhook.rs # BTCPay landing
│ └── admin.rs # operator-only actions
└── docs/
├── API.md # full endpoint reference
├── INTEGRATION.md # for developers embedding a client
└── ARCHITECTURE.md # deeper design notes
Running locally
Prerequisites: Rust 1.75+, a BTCPay Server instance you can point at (local or hosted).
cp .env.example .env
# edit .env — generate admin key with: openssl rand -hex 32
# fill in BTCPay URL, API key, store id, webhook secret
cargo run --release
On first boot the server generates a fresh Ed25519 keypair and stores it in the SQLite database. Get the public key anytime from GET /v1/pubkey (or from the logs on first boot).
Creating your first product
curl -X POST http://localhost:8080/v1/admin/products \
-H "Authorization: Bearer $LICENSING_ADMIN_API_KEY" \
-H "Content-Type: application/json" \
-d '{
"slug": "my-app",
"name": "My App",
"description": "A cool Start9 service.",
"price_sats": 50000
}'
Walking through a purchase
# 1. Buyer starts a purchase
curl -X POST http://localhost:8080/v1/purchase \
-H "Content-Type: application/json" \
-d '{"product": "my-app"}'
# → { "invoice_id": "...", "checkout_url": "https://btcpay.../i/...", ... }
# 2. Buyer opens checkout_url, pays
# 3. Buyer polls
curl http://localhost:8080/v1/purchase/<invoice_id>
# → { "status": "settled", "license_key": "LIC1-...", ... }
# 4. Downstream software validates the key
curl -X POST http://localhost:8080/v1/validate \
-H "Content-Type: application/json" \
-d '{"key": "LIC1-...", "product_slug": "my-app", "fingerprint": "host-abc123"}'
# → { "ok": true, "license_id": "...", "product_id": "..." }
Deploying on Start9
This repository ships the service only. To package as an .s9pk for the 0.4.0.x platform you'll need a separate wrapper repository following docs.start9.com/packaging/0.4.0.x. The service is designed to slot in cleanly:
- Declares a dependency on BTCPay Server in the manifest. StartOS will make BTCPay reachable at a
.startoshostname and supply the env vars from the wrapper's action handlers. - Persists to
/data, so everything (SQLite DB including the signing key) is covered by one-click encrypted backups. - Binds to
0.0.0.0:8080and expects StartOS to handle Tor/LAN/clearnet exposure. - Graceful shutdown on SIGTERM, as StartOS expects.
- Environment-driven config, no config files needed at runtime.
When you're ready to write the manifest, the env vars you need to wire are listed in .env.example. The main gotcha is the BTCPay webhook secret: you configure it on the BTCPay side and it must match BTCPAY_WEBHOOK_SECRET exactly — we verify HMAC-SHA256 in constant time and reject any mismatch.
Developer integration
If you're a developer shipping software that should validate against a licensing-service instance, see docs/INTEGRATION.md. It covers:
- Bundling the server's public key in your client.
- Offline signature verification + online revocation check.
- Graceful handling of server outages (don't brick your users).
- Recommended caching and rate-limiting patterns.
Source-available licensing
This project is source-available, not open source. You may read, audit, self-host, and modify for your own use, but may not redistribute, resell, or publicly host for others. See LICENSE for the full terms.
Commercial redistribution / resale rights: contact licensing@keysat.xyz.
Status
v0.1 — minimal working implementation. Feature direction after this is expected to cover: SDK crates for Rust and TypeScript, s9pk wrapper repository, richer admin UI, invoice reconciliation job for dropped webhooks, per-product webhook endpoints for the operator.