Commits the concrete adapter shape deferred by ADR-033: read-sync / write-async split with honker NOTIFY/LISTEN for no-restart cache invalidation, against SQLite, in a separate alknet-store-sqlite crate. Two constraints drive the design: (1) the hot-path read trait (IdentityProvider::resolve_from_fingerprint, CredentialStore::get) is sync — called in the accept loop, no .await — so a SQLite-backed adapter must cache in memory and serve sync reads from the cache; (2) auth changes must take effect without a restart (an early issue the project already fixed for ConfigIdentityProvider via ArcSwap config reload). honker's SQLite NOTIFY/LISTEN (single-digit-ms wake, no polling) is the cache-invalidation mechanism that makes both hold: write commits to SQLite + emits NOTIFY, the running process's LISTEN wakes, the in-memory index reloads and atomically swaps, the next read sees the new state. Same ArcSwap-reload pattern as config, generalized from 'config file is source of truth' to 'SQLite is source of truth, honker signals when it changed.' New async IdentityStore write trait (put_peer / update_peer / remove_peer) extends the sync IdentityProvider read trait for peer mutations. ConfigIdentityProvider does NOT implement it (config reload is its write path — a posture enforced by the absence of a backend, not a type-system constraint); SqliteIdentityProvider implements both. CredentialStore::put/delete refined to async (within ADR-031's one-way door — the contract was get/put/delete keyed by provider persisting EncryptedData never decrypting; sync-vs-async was unspecified). CredentialStoreError renamed to shared StoreError covering both traits. alknet-store-sqlite is one crate implementing both IdentityStore and CredentialStore with shared SQLite connection + honker LISTEN infra (splitting later is a two-way door). Schema shape committed (one row per PeerEntry with JSON columns for fingerprints/scopes/resources; one row per EncryptedData blob keyed by provider); exact DDL is an implementation-detail two-way door in the adapter crate. The keypal adapter-factory pattern is intentionally not ported to Rust (runtime column-mapping is a TS affordance; in Rust each adapter is a concrete type, cross-cutting concerns are a shared helper module). Amends ADR-031 (put/delete async refinement, StoreError rename), ADR-033 (concrete adapter shape now specified, two-crate framing collapsed to one), ADR-034 (OQ-36 now resolved), auth.md (IdentityStore section, cache-invalidation summary, OQ-36 reference), config.md (two write paths note), and the OQ-36/OQ-34 entries in open-questions.md. Review fixed 4 criticals (error-type name divergence, duplicate IdentityProvider sketch, upsert/Duplicate ambiguity, 'shape unchanged' contradiction), 7 warnings, 5 suggestions.
28 KiB
ADR-035: Concrete Persistence Adapter Shapes — Read/Write Split, honker+SQLite
Status
Accepted. Resolves OQ-36. Refines ADR-031 §1 (put/delete → async;
CredentialStoreError → StoreError). Commits the concrete adapter
shape deferred by ADR-033 §"What this does NOT do."
Context
ADR-033 committed the repo/adapter pattern — core defines repo traits
- in-memory defaults; persistence adapters are separate crates; the
assembly layer wires the adapter. ADR-030 (
PeerEntry/ConfigIdentityProvider) and ADR-031 (CredentialStore/InMemoryCredentialStore) committed the two trait shapes and their in-memory defaults. OQ-36 left the concrete persistence adapter shapes open: table schemas, backend choice, indexing, caching, the honker+SQLite design. This ADR resolves OQ-36 by committing the concrete shape.
Two constraints drive the design:
Constraint 1: The hot-path read trait is sync
IdentityProvider::resolve_from_fingerprint is called on every
incoming QUIC connection in the accept loop (and on every
call.requested for the per-request identity path). It is synchronous
— fn resolve_from_fingerprint(&self, fingerprint: &str) -> Option<Identity>, no async, no .await. This is a deliberate design
choice locked by ADR-004/011: the hot path can't block on a DB query,
and threading .await through the accept loop and every handler's
auth resolution would be a rewrite of the dispatch surface.
A SQLite-backed adapter cannot run a SQL query inside a sync call.
Therefore a persistence-backed IdentityProvider must hold an
in-memory index and serve sync reads from it. The question this
ADR answers: how does that index stay fresh when the DB changes,
without a restart?
Constraint 2: Auth changes must take effect without a restart
The project explicitly fixed an early issue where changing auth
required restarting the server. ConfigIdentityProvider solves this
via ArcSwap<DynamicConfig> — a config reload atomically swaps the
config, and the next resolve_from_fingerprint call reads the new
state. Live resolution changes, no restart.
A persistence adapter needs the same property. A CLI admin tool
(alknet peer add), an admin call-protocol operation, or another
node writes a new PeerEntry to the SQLite DB. The running alknet
process's in-memory index must reflect that write without a
restart and without polling (polling re-introduces the staleness
window the ArcSwap pattern removed).
The honker mechanism
honker is a SQLite
extension + language bindings that adds Postgres-style NOTIFY/
LISTEN to SQLite, with single-digit-millisecond cross-process
wake-up and no polling. It works by watching PRAGMA data_version
(every 1ms, single-digit-µs read) and waking listeners on committed
updates.
This is exactly the cache-invalidation mechanism the sync-hot-path + SQLite-backend combination needs:
- A write hits SQLite (
INSERT/UPDATE/DELETEon thepeerstable) and commits. - The write emits a honker
NOTIFYalongside the business write. honker is designed so the notify is tied to the committed state — a rollback drops the notify (no spurious wake for work that didn't land). The honker docs describe thePRAGMA data_versionwatch as waking on committed updates and ignoring rolled-back work, which is the property this design relies on. Corner case: a process crash between the SQLite commit and the localLISTENwake leaves the DB updated but the crashed process's index stale until its next restart (it reloads from SQLite on boot, so it converges — just not via the live-notify path). Other live processes still wake normally. This is acceptable for the single-process-failure assumption; a multi-process crash-durability guarantee would need WAL + checkpoint engineering beyond this ADR's scope. - The running alknet process's
LISTENwakes in single-digit ms. - The process reloads its in-memory index from SQLite (one `SELECT
- FROM peers
) and atomically swaps it (sameArcSwappattern asConfigIdentityProvider`).
- FROM peers
- The next
resolve_from_fingerprintcall reads the new index. Live resolution changes, no restart, no polling.
honker is therefore not "an optional backend choice" — it is the mechanism that makes the sync-read + cached-index + no-restart combination work. Without it, the persistence adapter either polls (stale window) or requires a restart to pick up changes (the bug the project already fixed once).
The keypal reference
The keypal TypeScript library (/workspace/keypal) demonstrates the
repo pattern: a Storage interface with an in-memory default adapter
and backend adapters for Redis, Drizzle, Prisma, Kysely, Convex. The
core logic is backend-agnostic; storage is a trait; the consumer picks
the adapter at wiring time. The alknet adaptation follows the same
shape (core trait + in-memory default + separate adapter crates) but
diverges from keypal in three places, recorded here so a future reader
doesn't wonder why:
- Two trait families, not one
Storage<T>. keypal stores one kind of thing (API key records), so one trait fits. alknet has two distinct aggregates —PeerEntry(identity + ACL, hot-path read on every connection) andEncryptedDatablobs (credentials, read once at startup intoCapabilities). Different shapes, different read/write profiles, different hot-path criticality. ADR-033 §4 already committed to one trait per concern; this ADR keeps that. - Read/write trait split. keypal's
Storageis uniform (all methods async). alknet's hot path is sync, so the read trait is sync and the write trait is a separate async extension. keypal doesn't face this because JS/TS has no sync-hot-path constraint. - No adapter factory. keypal's
adapter-factoryis a runtime generic over column mapping and type coercion — a TS/JS affordance (dynamic objects, runtime schema introspection). In Rust, each adapter is a concrete type implementing the trait; column mapping is done at adapter build time with concrete types. The intent ("adapters only implement the backend-specific query, cross-cutting concerns are shared") is achieved in Rust by a shared helper module (e.g.,alknet-store-sqlitehas aschemamodule both adapters use) and by the trait itself defining the contract. The factory pattern is intentionally not ported.
Decision
1. Read trait stays sync; persistence adapters cache in memory
IdentityProvider and CredentialStore::get are sync and
unchanged. A persistence-backed adapter serves sync reads from an
in-memory index (HashMap<fingerprint, PeerEntry> for identity;
HashMap<String, EncryptedData> for credentials), loaded from the
backend at construction and refreshed on honker NOTIFY. This is the
same ArcSwap-backed "load full state, atomically swap" pattern
ConfigIdentityProvider uses for config reload — generalized from
"config file is the source of truth" to "SQLite is the source of
truth, honker signals when it changed."
The in-memory index is a full reload, not a delta apply, on each
NOTIFY. Peer/credential counts are small (10s–100s, per ADR-030
Assumption 4); a SELECT * + HashMap rebuild is cheap and avoids
the correctness hazards of incremental cache updates (missed deletes,
partial updates). This is the same posture as ConfigIdentityProvider
(reload the whole DynamicConfig, not a patch).
2. Add IdentityStore — the async write trait for peer management
IdentityProvider is read-only today and stays read-only. Peer
mutations (add/update/remove a PeerEntry) go through a new
async trait that extends IdentityProvider:
/// Read trait — hot path, sync, unchanged (ADR-004). ConfigIdentityProvider
/// and SqliteIdentityProvider both implement this. The SQLite adapter serves
/// from an in-memory index refreshed by honker LISTEN.
pub trait IdentityProvider: Send + Sync + 'static {
fn resolve_from_fingerprint(&self, fingerprint: &str) -> Option<Identity>;
fn resolve_from_token(&self, token: &AuthToken) -> Option<Identity>;
}
/// Write trait — management path, async. ConfigIdentityProvider does NOT
/// implement this (config reload is its write path). SqliteIdentityProvider
/// does: writes hit SQLite, emit honker NOTIFY, and the local LISTEN
/// refreshes the in-memory read index.
#[async_trait]
pub trait IdentityStore: IdentityProvider {
async fn put_peer(&self, peer: &PeerEntry) -> Result<(), StoreError>;
async fn update_peer(&self, peer_id: &str, peer: &PeerEntry) -> Result<(), StoreError>;
async fn remove_peer(&self, peer_id: &str) -> Result<(), StoreError>;
}
put_peer— insert or replace aPeerEntry(upsert bypeer_id).update_peer— update an existingPeerEntry(error ifpeer_idnot found; for upsert semantics useput_peer).remove_peer— delete aPeerEntrybypeer_id.
Why a separate trait, not async methods on IdentityProvider:
- The hot-path read trait is consumed by the accept loop and every
handler — those call sites are sync and must not gain
.await. Ifput_peerwere onIdentityProvider, every consumer would see the async method even though only the management path calls it. A separateIdentityStore: IdentityProvidersupertrait keeps the read surface lean and makes the write surface opt-in. ConfigIdentityProviderdoes not implementIdentityStore. Its write path is config reload (ConfigReloadHandle::reload), not a method call. This preserves the config-is-source-of-truth model for the in-memory default while the SQLite adapter gains a method- call write path.
Cache coherence on the writer's own process: when a SqliteIdentityProvider::put_peer commits, the write's own honker NOTIFY wakes the local LISTEN and the local index refreshes — the writer's own read index is consistent with the write without special handling. There is no "write-through to local cache" shortcut; the NOTIFY path is the single source of truth for index freshness, on the writer's process and on every other process listening to the same DB. This keeps one mechanism instead of two (write-through for local + NOTIFY for remote), which is simpler and avoids the local/remote divergence bug.
3. CredentialStore write methods become async
ADR-031 sketched CredentialStore::put/delete as sync. This ADR
refines that sketch: get stays sync (cached read, same as
IdentityProvider), put/delete become async (they hit the
backend). The refinement is within the one-way door ADR-031 committed
("there IS a CredentialStore trait with get/put/delete keyed
by provider, persisting EncryptedData, never decrypting") — that
contract stands; the sync-vs-async of the write methods was an
unspecified detail in the sketch, and ADR-033 §"What this does NOT
do" explicitly deferred concrete adapter shapes to this work.
pub trait CredentialStore: Send + Sync {
fn get(&self, provider: &str) -> Option<EncryptedData>;
async fn put(&self, provider: &str, data: &EncryptedData) -> Result<(), StoreError>;
async fn delete(&self, provider: &str) -> Result<(), StoreError>;
}
InMemoryCredentialStore's put/delete are async with no .await
points (trivially satisfy an async trait) — no behavior change for the
in-memory default, just the signature. The SQLite adapter's
put/delete hit SQLite and emit honker NOTIFY, refreshing the
local and remote read caches.
get stays sync for the same reason IdentityProvider reads stay
sync: the credential load happens at startup into Capabilities
(ADR-031), and a cached sync read serves it. A runtime get (e.g., a
handler fetching a newly-stored credential without restart) hits the
in-memory index, which honker keeps fresh.
4. alknet-store-sqlite — the first concrete adapter crate
A single crate, alknet-store-sqlite, implementing both
IdentityStore and CredentialStore against SQLite + honker. Two
adapters in one crate is fine because they share:
- The SQLite connection pool.
- The honker
LISTENloop (one listener, multiple channels —peers_changedandcredentials_changed). - The migration infrastructure (
CREATE TABLE IF NOT EXISTSon first open; the schema is small enough that a hand-rolled idempotent bootstrap is simpler than pulling in a migration framework — see §6).
Splitting into alknet-peer-store-sqlite +
alknet-credential-store-sqlite later is a two-way door (additive) if
a use case forces it (e.g., a deployment that wants peer persistence
but not credential persistence). The default is one crate, both
adapters, shared infra.
// alknet-store-sqlite — the concrete adapter
pub struct SqliteIdentityProvider {
// SQLite connection (writes) + honker listener handle
conn: Arc<SqliteConn>,
// In-memory read index, atomically swapped on honker NOTIFY
index: Arc<ArcSwap<PeerIndex>>,
}
impl IdentityProvider for SqliteIdentityProvider {
fn resolve_from_fingerprint(&self, fp: &str) -> Option<Identity> {
let idx = self.index.load();
idx.resolve_from_fingerprint(fp)
}
fn resolve_from_token(&self, token: &AuthToken) -> Option<Identity> {
let idx = self.index.load();
idx.resolve_from_token(token)
}
}
#[async_trait]
impl IdentityStore for SqliteIdentityProvider {
async fn put_peer(&self, peer: &PeerEntry) -> Result<(), StoreError> {
// 1. INSERT/UPDATE peers row in SQLite (transactional)
// 2. NOTIFY 'peers_changed' (same transaction — atomic)
// 3. The local+remote LISTEN loops wake, reload the index
self.conn.put_peer(peer).await
}
// update_peer, remove_peer — same shape
}
pub struct SqliteCredentialStore {
conn: Arc<SqliteConn>, // shared with the identity adapter
index: Arc<ArcSwap<HashMap<String, EncryptedData>>>,
}
impl CredentialStore for SqliteCredentialStore {
fn get(&self, provider: &str) -> Option<EncryptedData> {
self.index.load().get(provider).cloned()
}
async fn put(&self, provider: &str, data: &EncryptedData) -> Result<(), StoreError> {
// INSERT/UPDATE credentials row + NOTIFY 'credentials_changed'
self.conn.put_credential(provider, data).await
}
async fn delete(&self, provider: &str) -> Result<(), StoreError> {
// DELETE credentials row + NOTIFY 'credentials_changed'
self.conn.delete_credential(provider).await
}
}
The PeerIndex is the in-memory structure that makes
resolve_from_fingerprint and resolve_from_token O(1) —
HashMap<fingerprint, &PeerEntry> + HashMap<auth_token_hash, &PeerEntry>, built once per reload from SELECT * FROM peers. This
is the secondary-index pattern keypal's memory.ts uses
(hashIndex, ownerIndex, tagIndex); alknet needs the fingerprint
and auth-token-hash indexes. (Implementation note: the index owns
the Vec<PeerEntry> loaded from SQLite; the secondary maps borrow
with a lifetime tied to the index struct — self-referential, so the
index is built in one pass and held behind the ArcSwap as a single
Arc<PeerIndex>. Cloning entries to avoid self-reference is a
two-way-door implementation choice; the trait is agnostic.)
5. honker is the cache-invalidation mechanism — a hard dependency of the SQLite adapter
alknet-store-sqlite depends on honker (the Rust crate,
honker-core/honker-extension). This is not a core dependency
— alknet-core stays honker-free (ADR-033's "core has no backend
dependency" is preserved). The honker dependency lives in the adapter
crate, alongside the rusqlite (or sqlx) dependency.
The honker LISTEN loop is spawned by the adapter at construction
(SqliteIdentityProvider::new starts a tokio task that LISTENs on
peers_changed and reloads the index on wake). The loop is
cancellation-safe (dropping the adapter cancels the task). The
listener uses honker's PRAGMA data_version watch — single-digit-ms
wake, no polling, no daemon.
Why honker is load-bearing, not optional: without it, the
sync-read + cached-index + no-restart combination breaks down into
either (a) polling (re-introduces the staleness window the project
already fixed), or (b) restart-on-change (the bug the project already
fixed). A SQLite adapter without honker would be a strictly worse
ConfigIdentityProvider (config reload does the same thing, simpler).
honker is what makes the SQLite adapter worth building: it adds
persistence and preserves the no-restart property and keeps the
hot path sync.
6. Schema (the commitment, not the DDL)
The ADR commits to the table shape, not the exact DDL. The DDL is an implementation-detail two-way door (it lives in the adapter crate's own code/tests, not an ADR); the shape is the one-way door because it determines what the trait can express and what indexes the adapter builds.
peers table — one row per PeerEntry:
| Column | Type | Notes |
|---|---|---|
peer_id |
TEXT PK | Stable logical id ("worker-a") |
fingerprints |
TEXT (JSON array) | ["ed25519:...","SHA256:..."] |
auth_token_hash |
TEXT NULL | SHA-256 of bearer token, or NULL |
scopes |
TEXT (JSON array) | ["relay:connect"] |
resources |
TEXT (JSON object) | {"service":["gitea","registry"]} |
display_name |
TEXT NULL | |
enabled |
INTEGER (0/1) | Boolean |
The PeerIndex rebuilds from SELECT * FROM peers on each honker
wake. The fingerprint index is built by iterating rows and expanding
the fingerprints JSON array. The auth-token-hash index is built
from the non-NULL auth_token_hash rows.
credentials table — one row per EncryptedData blob:
| Column | Type | Notes |
|---|---|---|
provider |
TEXT PK | "openai", "anthropic", etc. |
key_version |
INTEGER | From EncryptedData (ADR-020) |
salt |
BLOB | Wire-format compat (OQ-20); unused in v2. Writers echo the vault's EncryptedData.salt field (even if unused in v2) so the row round-trips through the core EncryptedData mirror without loss; v2 may write a zero-length salt but must not drop the field. |
iv |
BLOB | AES-GCM IV (OsRng-generated, ADR-020) |
data |
BLOB | Ciphertext |
The EncryptedData core mirror (ADR-031 §3) round-trips through these
columns. The store never decrypts (ADR-025); the vault does.
Migrations: the adapter bootstraps with CREATE TABLE IF NOT EXISTS on first open. The schema is small and stable (locked by
ADR-020/030); a migration framework (sqlx migrations, refinery) is
not pulled in for v1. If a future schema change requires a real
migration, that's additive (a migrations/ dir + a migration runner
— two-way door). This is recorded so a future reader doesn't assume
migrations were forgotten.
7. The StoreError type (renames CredentialStoreError)
A shared error enum for both adapters, #[non_exhaustive] +
thiserror::Error. This renames the CredentialStoreError sketched
in ADR-031 §1 to StoreError — a single shared type for both the
identity and credential store traits, so both adapters and all
consumers reference one error type. The rename is within ADR-031's
one-way door (the contract was "a #[non_exhaustive] error enum for
store failures"; the name was unspecified detail). ADR-031's sketch
is amended to use StoreError by this rename.
#[non_exhaustive]
#[derive(Debug, thiserror::Error)]
pub enum StoreError {
#[error("backend error: {message}")]
Backend { message: String },
#[error("not found: {entity}")]
NotFound { entity: String },
#[error("serialization error: {message}")]
Serialization { message: String },
}
Backend covers SQLite errors (constraint failures, disk I/O,
corruption). NotFound is for update_peer/remove_peer on a
missing peer_id. #[non_exhaustive] lets the adapter add variants
without breaking downstream match arms. A Duplicate variant is
not in v1: put_peer is upsert (insert-or-replace), so
peer_id collisions are a replace, not an error; a strict-insert
mode that would return Duplicate is a future addition (with its own
method or flag, added non-breakingly). The error type lives in
alknet-core (where the traits live) so both adapters and consumers
reference one type; the adapter crate may add a wrapper error for
backend-specific failures it surfaces as Backend { message }.
What this does NOT change
IdentityProvidertrait shape (ADR-004/030) — unchanged. The read methods stay sync.IdentityStoreis a new supertrait, not a modification.CredentialStorecontract (ADR-031) —get/put/deletekeyed by provider, persistingEncryptedData, never decrypting: unchanged. The signature ofput/deletechanges sync→async (a breaking change toimpls and call sites — acknowledged in Consequences), which is within the one-way door ADR-031 committed because ADR-031's sketch left sync-vs-async unspecified and ADR-033 §"What this does NOT do" explicitly deferred concrete adapter shapes to this work. The error type is renamedCredentialStoreError→StoreError(§7), within the same one-way door (the contract was "a#[non_exhaustive]error enum"; the name was unspecified).PeerEntrystruct (ADR-030) — unchanged.EncryptedDatacore mirror (ADR-031 §3) — unchanged.ConfigIdentityProvider— unchanged, still read-only, still config-backed. It does not implementIdentityStore.InMemoryCredentialStore— unchanged behavior;put/deletebecome async-with-no-awaits (signature change only).- alknet-core has no backend dependency — ADR-033's commitment is
preserved.
honkerandrusqlite/sqlxare dependencies ofalknet-store-sqlite, notalknet-core. - The no-env-vars invariant (ADR-014) — unaffected. The
CredentialStorepath is the persistence layer for encrypted blobs; the assembly layer still loads them intoCapabilities; nostd::env::varpath exists.
Consequences
Positive:
- OQ-36 is resolved. The concrete persistence adapter shape is
committed: read-sync / write-async / honker-NOTIFY-for-cache-
invalidation, against SQLite, in a separate
alknet-store-sqlitecrate. - The no-restart-on-auth-change property is preserved across the
config-backed and SQLite-backed deployments.
ConfigIdentityProviderusesArcSwap+ config reload;SqliteIdentityProviderusesArcSwap+ honker NOTIFY. Same property, same mechanism shape, different source of truth. - The hot path stays sync. No
.awaitin the accept loop or handler auth resolution. The SQLite adapter caches in memory and serves reads from the cache, with honker keeping the cache fresh. - The keypal-style repo pattern lands in Rust with the adaptations the alknet constraints require (two trait families, read/write split, no adapter factory). The pattern is now concrete, not aspirational.
- A third-party / downstream user can implement
IdentityProviderorCredentialStoreagainst any backend (Postgres, Redis, a remote service) by implementing the trait; theIdentityStorewrite extension is opt-in. The trait shapes are the public contract.
Negative:
alknet-coregains theIdentityStoretrait and theStoreErrortype. Small surface, but it's a new public trait — downstream consumers see it. The trade is that peer management (CLI tools, admin ops) gets a typed write surface instead of each adapter rolling its own.InMemoryCredentialStore::put/deletechange signature (sync → async). Callers (the assembly layer, tests) add.await. This is within the ADR-031 sketch's unspecified detail; the in-memory adapter's behavior is unchanged.- The SQLite adapter has a hard
honkerdependency. A deployment that wants SQLite persistence but not honker would need a separate adapter (alknet-store-sqlite-pollingor similar) that polls or requires restart — strictly worse, and not built. This is the trade for the no-restart property; it's explicit. - The full-reload-on-NOTIFY strategy is O(rows) per wake. At expected scale (10s–100s of peers) this is cheap; at thousands it would matter. The peer/credential counts are small by design (ADR-030 Assumption 4); if a future use case pushes to thousands, a delta-apply strategy is a two-way-door optimization (additive, behind the same trait).
Assumptions
-
The hot path must stay sync.
IdentityProvider::resolve_from_ fingerprintandCredentialStore::getare called in contexts that cannot.await(accept loop, per-request dispatch). This is locked by ADR-004/011 and is the one-way door that drives the read/write split. Reverting to async reads would require rewriting the dispatch surface — not planned. -
Peer/credential counts are small (10s–100s). The full-reload- on-NOTIFY strategy is cheap at this scale (ADR-030 Assumption 4). A delta-apply strategy is a future two-way-door optimization if scale forces it.
-
honker is the cache-invalidation mechanism for the SQLite adapter. It is a hard dependency of
alknet-store-sqlite, not ofalknet-core. A non-honker SQLite adapter is possible but would poll or require restart — strictly worse and not built. -
ConfigIdentityProviderdoes not implementIdentityStore. Config reload is its write path; the trait stays read-only. This preserves the config-is-source-of-truth model. A deployment that wants method-call peer management uses the SQLite adapter, not the config adapter. -
The concrete SQL DDL is an implementation-detail two-way door. The table shape (one row per
PeerEntry, one row perEncryptedData, JSON columns for arrays/objects) is the one-way door this ADR commits; the exact DDL, migration tooling, and column naming live in the adapter crate. -
Redis / Postgres / on-chain adapters are not needed for the current scope. The trait shapes make them possible; the adapter crates get built when a concrete use case forces them. This is a scoping judgment, not a deferral — the SQLite adapter is the committed build; the others are not designed here.
-
One crate (
alknet-store-sqlite) for both adapters. Splitting intoalknet-peer-store-sqlite+alknet-credential-store-sqliteis a two-way door (additive) if a use case forces it; the default is one crate, shared infra.
References
- OQ-36 (resolved by this ADR) — concrete persistence adapter shapes
- ADR-003 — crate decomposition (core is lean, adapters are separate crates, the assembly layer wires — the rules this ADR's adapter-crate structure follows)
- ADR-009 — one-way door decision framework (the door-type vocabulary used throughout)
- ADR-004 —
IdentityProvider(the read trait this ADR keeps sync) - ADR-011 — AuthContext resolution flow (where the sync read is called from)
- ADR-014 —
no-env-vars invariant (the
CredentialStorepath supports it) - ADR-020 —
EncryptedDatashape (thecredentialstable row shape) - ADR-025 — vault is the sole
decryption boundary;
CredentialStorenever decrypts - ADR-030 —
PeerEntrymodel (thepeerstable row shape); Assumption 4 (small peer counts → full-reload is cheap) - ADR-031 —
CredentialStoretrait (this ADR refinesput/deleteto async, within the one-way door ADR-031 committed) - ADR-033 — the repo/adapter pattern (this ADR commits the concrete adapter shape ADR-033 §"What this does NOT do" deferred)
docs/research/alknet-storage-strategy/findings.md— the SQLite+honker foundation and the repo/adapter pattern research/workspace/keypal— TypeScript repo-pattern reference (theStorageinterface + adapters pattern; the in-memory secondary- index pattern inmemory.ts; the adapter-factory intent this ADR does not port to Rust)/workspace/honker— honker: SQLite NOTIFY/LISTEN, the cache-invalidation mechanism the SQLite adapter depends on