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alknet/docs/architecture/crates/vault/service.md
glm-5.2 323ee85d40 docs(vault): remove drift tracking artifacts, bump vault docs to stable
The vault spec-to-implementation sync is complete. Remove the drift
tracking tools that were only needed during sync:

- Remove the Known Source Drift table from vault/README.md
- Remove 'known drift' / 'current source uses X' prose from Security
  Constraints sections in vault/README.md, encryption.md, and service.md.
  The permanent constraint statements (OsRng for IVs, zeroized drop,
  no unwrap, etc.) are preserved.
- Remove the drift paragraph in encryption.md Key Versioning.
- Remove stale 'to be updated per ADR-025' / 'postcard tests to be
  removed' notes in protocol.md References.
- Bump status: draft -> stable in the frontmatter of all vault docs
  (README, mnemonic-derivation, encryption, service, protocol).
- Update architecture/README.md: vault doc status entries to stable,
  Current State paragraph reflects vault implementation complete (no
  'pending ADR-025/026 refactor' language).
2026-06-23 14:15:13 +00:00

16 KiB

status, last_updated
status last_updated
stable 2026-06-23

Service

The VaultServiceHandle runtime API: unlock/lock lifecycle, key derivation, encryption, caching, and the direct method-call dispatch path.

What

The service layer wraps the vault's cryptographic primitives in a stateful runtime with a clear lifecycle. It holds the master seed in Zeroize-protected memory and provides methods for the unlock/lock lifecycle, key derivation, and encryption/decryption.

This is the API the assembly layer (CLI binary) calls. No other component calls these methods directly (ADR-019). The vault is local-only by construction (ADR-025) — direct method calls, no actor, no message enum, no remote dispatch.

VaultServiceHandle

The primary API for local (in-process) use. Thread-safe via std::sync::RwLock — all methods are synchronous (no async, no .await). The RwLock provides concurrent reads (derive operations) and exclusive writes (unlock/lock). tokio is not a dependency of the vault (ADR-025); std::sync::RwLock is sufficient because no method holds the lock across an await point.

#[derive(Clone)]
pub struct VaultServiceHandle {
    inner: Arc<std::sync::RwLock<VaultServiceInner>>,
}

struct VaultServiceInner {
    mnemonic: Option<Mnemonic>,  // None if locked
    seed: Option<Seed>,         // None if locked
    unlocked: bool,
    cache: KeyCache,            // TTL + LRU, see Cache section
}

Invariant: unlocked is true iff seed.is_some(). The unlocked flag exists for cheap read-only checks (is_unlocked); the ground truth is seed.is_some(). lock() sets unlocked = false and clears seed/mnemonic to None; unlock/unlock_new set unlocked = true and populate seed.

VaultServiceHandle is Clone — cloning shares the underlying state via Arc. This is how the actor and the assembly layer share the same vault.

Lifecycle

Locked (initial state)
  │
  │ unlock(phrase, passphrase) / unlock_new(word_count)
  ▼
Unlocked — derive, encrypt, decrypt available
  │
  │ lock()
  ▼
Locked — seed and cache purged

unlock(phrase, passphrase)

pub fn unlock(&self, phrase: &str, passphrase: Option<&str>) -> Result<(), VaultServiceError>;

Unlock with an existing mnemonic phrase. Validates the phrase against the BIP39 word list, derives the seed, and stores both in VaultServiceInner. Returns AlreadyUnlocked if the vault is already unlocked.

The passphrase is the BIP39 password extension (the "25th word"). None means no passphrase (equivalent to empty string). Different passphrases produce different seeds.

unlock_new(word_count) → phrase

pub fn unlock_new(&self, word_count: usize) -> Result<Zeroizing<String>, VaultServiceError>;

Generate a new random mnemonic, unlock with it, and return the phrase as a Zeroizing<String>. The returned phrase is the root of trust — it is heap-allocated and zeroized on drop, so it does not linger in freed memory. The caller should extract the phrase for secure storage (write down, display to user) and let the Zeroizing<String> drop when done. Do not clone the returned value or store it in a non-zeroizing container. Supported word counts: 12, 15, 18, 21, 24.

Returns VaultServiceError::AlreadyUnlocked if the vault is already unlocked (matching unlock's behavior — unlock_new is a "first run" operation and should not silently replace an existing mnemonic).

This is the "first run" path — a new node generates its mnemonic, writes it down, and the vault is unlocked for the process lifetime. The Zeroizing<String> wrapper (from the zeroize crate) ensures the mnemonic is wiped from memory once the caller is done with it, matching the Mnemonic type's own ZeroizeOnDrop behavior. This resolves review #002 W7.

lock()

pub fn lock(&self);

Purge the seed, mnemonic, and all cached derived keys. Calls zeroize() on all sensitive material. After locking, no derive/encrypt/decrypt operations are possible until unlock is called again.

lock() on an already-locked service is a no-op (not an error).

is_unlocked()

pub fn is_unlocked(&self) -> bool;

Check whether the vault is currently unlocked. Cheap (read lock only).

Derive Methods

All derive methods require an unlocked vault and return VaultServiceError::VaultLocked if called while locked.

derive_ed25519(path) → DerivedKey

pub fn derive_ed25519(&self, path: &str) -> Result<DerivedKey, VaultServiceError>;

Derive an Ed25519 keypair at the given SLIP-0010 path. Checks the cache first; on a miss, derives from the seed and caches the result. Returns a DerivedKey with KeyType::Ed25519.

derive_encryption_key(path) → DerivedKey

pub fn derive_encryption_key(&self, path: &str) -> Result<DerivedKey, VaultServiceError>;

Derive an AES-256-GCM encryption key at the given path. Same cache behavior as derive_ed25519. Returns a DerivedKey with KeyType::Aes256Gcm.

derive_encryption_key_for_version(version) → DerivedKey

pub fn derive_encryption_key_for_version(&self, version: u32) -> Result<DerivedKey, VaultServiceError>;

Derive the encryption key for a specific key version. Maps the version to its derivation path via encryption_path_for_version(version) (ADR-021): v2 → m/74'/2'/0'/0', v3 → m/74'/2'/0'/1', etc. Cached by path. This is the version-aware method that encrypt and decrypt use to select the correct key for each blob — see encryption.md and ADR-021. Returns VaultServiceError::InvalidPath for version < 2 (v1 is TS PBKDF2 legacy — the vault cannot derive it; v0 is meaningless).

derive_encryption_key(path) (above) remains as the path-based API for deriving at arbitrary paths. derive_encryption_key_for_version(version) is the version-aware API used by encrypt and decrypt. Both return DerivedKey with KeyType::Aes256Gcm and share the same cache (keyed by derivation path). encrypt and decrypt extract the EncryptionKey from the DerivedKey via EncryptionKey::from_derived_bytes (see encryption.md).

derive_ethereum_key(path) → DerivedKey (feature-gated)

pub fn derive_ethereum_key(&self, path: &str) -> Result<DerivedKey, VaultServiceError>;

Derive a secp256k1 keypair at the given BIP-0032 path. Returns UnsupportedKeyType when the secp256k1 feature is disabled. Returns a DerivedKey with KeyType::Secp256k1 (33-byte compressed public key).

Encrypt and Decrypt

encrypt(plaintext, key_version) → EncryptedData

pub fn encrypt(&self, plaintext: &str, key_version: u32) -> Result<EncryptedData, VaultServiceError>;

Encrypt plaintext using the encryption key derived at encryption_path_for_version(key_version) (ADR-021). The same key_version is stamped on the resulting EncryptedData. Derives (and caches) the encryption key on first call, then uses the cache for subsequent calls. See encryption.md for the cryptographic details.

decrypt(encrypted) → String

pub fn decrypt(&self, encrypted: &EncryptedData) -> Result<String, VaultServiceError>;

Decrypt an EncryptedData blob. Derives (and caches) the encryption key at the version-indexed path indicated by encrypted.key_version via derive_encryption_key_for_version (ADR-021). Each version maps to a distinct path (m/74'/2'/0'/{version-2}'), so old and new keys can coexist during partial rotation. See encryption.md.

rotate(encrypted, to_version) → EncryptedData

pub fn rotate(&self, encrypted: &EncryptedData, to_version: u32) -> Result<EncryptedData, VaultServiceError>;

Re-encrypt an EncryptedData blob from its current key version to a new version. Decrypts with the old version's key, re-encrypts with the new version's key. Returns the new EncryptedData — the caller replaces the blob in storage. No new mnemonic needed; the same seed produces all version keys via different derivation paths (ADR-021).

This is the rotation primitive. The assembly layer or a migration tool iterates stored blobs and calls rotate on each. The vault does not self-rotate — rotation is an operational action.

Cache

Derived keys are cached for performance — HD derivation involves HMAC operations that are not free. The cache is keyed by derivation path and has TTL-based expiry and LRU eviction.

pub struct KeyCache {
    entries: HashMap<String, CachedKey>,
    order: Vec<String>,         // LRU ordering
    config: CacheConfig,
}

/// A cached derived key. Wraps a `DerivedKey` with cache metadata.
/// Derives `Zeroize` and `ZeroizeOnDrop` — the private key is zeroized
/// when the entry is evicted (LRU/TTL) or the cache is cleared.
pub struct CachedKey {
    key: DerivedKey,            // the derived key (zeroized on drop)
    cached_at: Instant,         // when the entry was inserted (for TTL)
    last_accessed: Instant,     // for LRU ordering
}

pub struct CacheConfig {
    pub ttl: Duration,          // default: 1 hour
    pub max_entries: usize,     // default: 64
}
  • TTL: entries expire after ttl (default 1 hour). Expired entries are evicted lazily on access (get checks expiry) or via evict_expired().
  • LRU: when the cache exceeds max_entries (default 64), the least recently used entry is evicted. Access (get) updates the LRU order.
  • Zeroized: CachedKey derives Zeroize and ZeroizeOnDrop (via the DerivedKey it holds, which is #[zeroize(drop)]). Evicted and cleared entries are zeroized — derived private keys do not linger in freed heap memory.
  • Cleared on lock: lock() calls cache.clear(), which removes and zeroizes all entries.

What is and isn't cached

Operation Cached? Why
derive_ed25519 Yes Derivation is expensive; keys are reused
derive_encryption_key Yes Same — encryption key reused across calls
derive_ethereum_key Yes Same
encrypt / decrypt Key cached The encryption DerivedKey (at encryption_path_for_version(key_version)) is cached; the plaintext is not

Dispatch

The vault uses direct method calls on VaultServiceHandle — no actor, no message enum, no channels, no serialization (ADR-025). The handle is Arc<std::sync::RwLock<VaultServiceInner>> — clone it, share it, call methods directly. The std::sync::RwLock provides concurrent reads (derive operations) and exclusive writes (unlock/lock). All methods are synchronous (no async), so std::sync::RwLock is correct — a tokio::sync::RwLock would require async methods or risk blocking a tokio runtime when held across an await point. The vault does not depend on tokio (ADR-025).

Assembly layer (CLI binary):
  1. Create VaultServiceHandle
  2. Unlock with mnemonic (local, from secure prompt or file)
  3. Call derive/encrypt/decrypt methods directly
  4. Extract bytes, construct alknet-core types at the assembly boundary
  5. Inject into handler capabilities (ADR-014)

There is no VaultProtocol enum, no VaultServiceActor, no Client<S>, and no remote dispatch capability. The vault is local-only by construction (ADR-025). If remote vault access is ever needed, it requires a separate vault-server crate with its own ADR (OQ-021, ADR-025).

The pre-ADR-025 design had an actor path (mpsc channel + oneshot backchannels, using irpc's Service trait) that was described as "secondary" to direct calls. ADR-025 removed it — the actor existed only to make irpc's dispatch work, and the direct path was always preferred. The RwLock-based concurrency model is both simpler and better for throughput (concurrent reads vs. sequential processing).

Errors

#[derive(Debug, thiserror::Error)]
pub enum VaultServiceError {
    VaultLocked,          // called derive/encrypt/decrypt while locked
    AlreadyUnlocked,      // called unlock while already unlocked
    Mnemonic(String),     // mnemonic generation/validation failed
    Derivation(String),   // HD derivation failed (bad path, HMAC error)
    Encryption(String),    // AES-GCM encrypt/decrypt failed
    InvalidPath(String),   // derivation path is malformed
    UnsupportedKeyType,   // secp256k1 called without the feature
}

VaultServiceError is a plain thiserror::Error enum (ADR-025 dropped the Serialize/Deserialize derives that were needed for irpc dispatch). It wraps sub-errors as strings. The CLI binary converts vault errors to alknet-core error types at the assembly boundary (ADR-018).

Design Decisions

Decision ADR Summary
Assembly layer is the sole caller ADR-019 Handlers never hold a vault reference
Encryption key via HD derivation ADR-020 Seed-derived key at m/74'/2'/0'/0', not PBKDF2
Version-indexed paths for rotation ADR-021 decrypt selects key by version; rotate re-encrypts
RwLock for thread safety Multiple readers (derive), exclusive writer (unlock/lock)
TTL + LRU cache Bounded memory, fresh keys, zeroized eviction
Direct method calls (no actor) ADR-025 No irpc, no message enum, no remote dispatch capability
derive_password removed ADR-025 Password-manager pattern not relevant to RPC system's vault; resolves C9

Open Questions

See open-questions.md for full details.

  • OQ-21 (resolved by ADR-025): Remote vault access is not a feature of the vault crate. The vault is local-only by construction — direct method calls on VaultServiceHandle, no remote dispatch capability. If remote access is ever needed, it requires a separate vault-server crate with its own ADR. See protocol.md → Local-Only by Construction.

Security Constraints

These are security-critical implementation requirements, not architectural decisions. They are documented here so implementation agents don't miss them.

  • OsRng for IVs: AES-GCM IVs and any cryptographic nonces must use OsRng (or equivalent CSPRNG), not rand::random(). IV reuse under the same key is catastrophic for GCM (authenticity breaks, two-time-pad on plaintext).
  • Zeroized drop: Seed, Mnemonic, CachedKey, EncryptionKey, ExtendedPrivKey, Secp256k1ExtendedPrivKey, and DerivedKey all derive Zeroize and ZeroizeOnDrop. The cache must clear on drop, not just on explicit lock().
  • No unwrap() or expect() outside tests: poisoned lock recovery uses unwrap_or_else(|e| e.into_inner()) or explicit error propagation. A panic in one vault operation must not brick the vault for all other operations. A poisoned lock should be recovered with unwrap_or_else(|e| e.into_inner()), not panicked.
  • DerivedKey is move-only, not Clone: DerivedKey does not derive Clone. It is move-only — consumers receive it by value and zeroize it when done (handled by #[zeroize(drop)]). This prevents accidental duplication of secret material.
  • Cache eviction zeroizes: when the cache evicts an entry (LRU or TTL), the CachedKey is dropped, which triggers ZeroizeOnDrop. Do not replace CachedKey with a type that doesn't zeroize.

References

  • Implementation: crates/alknet-vault/src/service.rs, crates/alknet-vault/src/cache.rs
  • Tests: crates/alknet-vault/tests/service_tests.rs, crates/alknet-vault/src/service.rs (unit tests), crates/alknet-vault/src/cache.rs (unit tests)
  • protocol.mdDerivedKey and KeyType
  • encryption.mdencrypt / decrypt cryptographic details