Files
alknet/tasks/vault/cache-zeroization-test.md
glm-5.2 098fd8b9b9 tasks: decompose vault, core, call crates into 28 atomic implementation tasks
Break down the three initial crates (alknet-vault, alknet-core, alknet-call)
into dependency-ordered task files for implementation agents.

Structure:
- tasks/vault/ (10 tasks) — drift fixes from ADR-025/026 refactor, review,
  spec sync. Vault is independent and can run fully in parallel with core/call.
- tasks/core/ (6 tasks) — crate init, core types, config, auth, endpoint,
  review. Core is foundational; call depends on it.
- tasks/call/ (12 tasks) — split into registry/ and protocol/ topic subdirs
  reflecting the two subsystems. CallAdapter is the merge point.

Key decisions:
- Drifts 3+9+10 grouped as one task (key-versioning-rotation) — the complete
  ADR-021 rotation feature that doesn't compile in pieces
- Reviews injected at end of each crate phase (vault, core, call)
- Vault spec-sync task removes the drift table and bumps doc status to stable
- ACME deferred in core/endpoint (noted as TODO; X509 manual certs for now)
- OperationEnv kept as a trait (load-bearing for ADR-024 layering)

Validated: 28 tasks, no cycles, 11 generations of parallel work.
Critical path runs through call (11 tasks). Vault completes by generation 4.
6 high-risk tasks identified (21%): irpc-removal, endpoint, operation-context,
operation-env, call-adapter, abort-cascade.
2026-06-23 12:41:47 +00:00

85 lines
3.2 KiB
Markdown

---
id: vault/cache-zeroization-test
name: Verify and test that HashMap::clear() drops CachedKey values triggering zeroization
status: pending
depends_on: []
scope: single
risk: low
impact: isolated
level: implementation
---
## Description
Fix drift item #6: `KeyCache::clear()` removes entries and relies on
`CachedKey`'s `Drop` impl for zeroization. The spec says to verify that
`HashMap::clear()` actually drops the values (it does, but this is worth a
test). This task adds a test that proves zeroization happens on cache eviction
and clear.
### Background
`CachedKey` derives `Zeroize` and `ZeroizeOnDrop` (via the `DerivedKey` it
holds, which is `#[zeroize(drop)]`). When the cache evicts an entry (LRU or TTL)
or `clear()` is called, the `CachedKey` is dropped, which triggers
`ZeroizeOnDrop` — the private key bytes are zeroized before deallocation.
`HashMap::clear()` drops all values, which triggers their `Drop` impls. This
is standard Rust behavior, but the security-critical nature of key material
warrants an explicit test.
### What to add
A test in `cache.rs` (or `tests/`) that:
1. Inserts a `CachedKey` with a known private key into the cache
2. Verifies the key is present
3. Calls `clear()` (or evicts via LRU/TTL)
4. Verifies the `CachedKey` was dropped and zeroized
Testing zeroization directly is tricky because the memory is freed — you can't
easily inspect it after drop. A practical approach:
- **Option A**: Use a custom type with a `Drop` impl that sets a flag (e.g., an
`Arc<AtomicBool>`) when zeroized. Insert it into the cache, clear, verify the
flag is set. This tests the drop path, not the zeroize path directly, but
confirms `clear()` drops values.
- **Option B**: Test the LRU eviction path — fill the cache to `max_entries`,
insert one more, verify the LRU entry was evicted (dropped).
- **Option C**: Test that `lock()` calls `cache.clear()` and the cache is empty
afterward (integration test via `VaultServiceHandle`).
At minimum, implement Option B and C. Option A is a bonus if feasible without
over-engineering the test type.
### Scope
This task touches `cache.rs` (test additions) and possibly `tests/`. It does
not depend on the irpc removal task (drift #4) because `cache.rs` is a separate
file. It can run in parallel with drift #4.
## Acceptance Criteria
- [ ] Test: LRU eviction drops the evicted `CachedKey` (cache exceeds `max_entries`, oldest evicted)
- [ ] Test: `lock()` clears the cache (verify cache is empty after lock)
- [ ] Test: TTL expiry evicts entries (set short TTL, wait, verify entry gone)
- [ ] Test: `clear()` removes all entries (verify empty after clear)
- [ ] `cargo test` succeeds
- [ ] `cargo clippy` succeeds with no warnings
## References
- docs/architecture/crates/vault/README.md — Known Source Drift table item #6
- docs/architecture/crates/vault/service.md — Cache section, Security Constraints
- docs/architecture/crates/vault/encryption.md — Security Constraints
## Notes
> `HashMap::clear()` does drop values, triggering their `Drop` impls. This is
> standard Rust behavior, but key material is security-critical enough to
> warrant an explicit test. This task touches only `cache.rs` and can run in
> parallel with the irpc removal task (drift #4).
## Summary
> To be filled on completion