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https://github.com/ruvnet/RuView
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c84ea39e62d14dcafe61fc80d357dfe0349462cd
4 Commits
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a784546918 |
ci(ruview-swarm): drop removed itar-unrestricted feature from test matrix
The industrial rescope (ruv-drone) removed the itar-unrestricted feature flag — formation/allocation/raft/flight-control are now default capabilities. Update the 'ruflo+itar' matrix entry to just '--features ruflo' so CI matches the new feature set. Co-Authored-By: claude-flow <ruv@ruv.net> |
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df617145d6 |
feat(ADR-262 P3): live /api/field + /ws/field — RuView sensing speaks RuField (fail-closed egress) (#1071)
* feat(ADR-262 P3): live RuField surface — RuView sensing speaks RuField on /api/field + /ws/field Wire the P1 `wifi-densepose-rufield` bridge into the live `wifi-densepose-sensing-server` so the governed sensing cycle emits real signed RuField `FieldEvent`s on two additive endpoints. - Cargo: add the `wifi-densepose-rufield` path dep (the single coupling point, ADR-262 §5.4 — no new RuView-internal coupling). - New `src/rufield_surface.rs` (kept out of the 8k-line main.rs): `FieldSurface` holds a dedicated ed25519 `Signer` + a bounded ring of recent events + the `/ws/field` broadcast topic; `GET /api/field` and `GET /ws/field` handlers; a standalone `router()` for isolated testing. - Signer (defers the P2 key decision, ADR-262 §8 Q1): a STANDALONE dev/sensing key from `WDP_RUFIELD_SIGNING_SEED`, else a deterministic dev default with a logged WARN. Reusing the `cog-ha-matter` Ed25519 key is the deferred P2 call — P3 does not pre-empt it. - Tap: at the ESP32 governed-trust cycle (`main.rs` ~5886 observe_cycle / ~5938 SensingUpdate build), `emit_rufield_event` joins the cycle's features/classification/signal_field with the engine's effective_class/demoted trust state into a `SensingSnapshot` and surfaces it via the bridge. Existing endpoints (`/ws/sensing` etc.) are unchanged — purely additive. - Privacy egress: `network_egress_allowed` is fail-closed for an unattended live surface — only P1/P2 leave the box; P0 raw and P3/P4/P5 (identity/biometric/aggregate) are held edge-local. A `Derived` cycle maps to P4/P5 and never surfaces. - No-phantom: `emit` drops no-presence cycles (no fabricated events). Gates (tests/rufield_surface_test.rs, tower::oneshot, 4/0): well-formed signed event (WifiCsi, P2 not P1, is_fusable, real timestamp); empty cycle → no phantom; Derived trust never surfaces; mixed stream surfaces only egress-safe events. Honesty (ADR-262 §0/§6): real plumbing on a live endpoint, NOT accuracy. Single-link CSI with its existing caveats (no validated room-coordinate accuracy); dedicated dev signing key pending the P2 ownership decision; no accuracy claim. Co-Authored-By: claude-flow <ruv@ruv.net> * docs(ADR-262 P3): mark P1+P3 implemented; document /api/field + /ws/field; CHANGELOG - ADR-262 Status → "P1 + P3 implemented"; add a P3 implementation-status block (tap site, endpoints, dedicated dev signer deferring the §8 Q1 key decision, fail-closed egress, gates). Keep the honesty framing: real plumbing on a live endpoint, not accuracy. - CHANGELOG [Unreleased]: add the ADR-262 P3 entry. - user-guide: add `/api/field` to the REST table + a "RuField surface (ADR-262 P3)" section covering `/api/field` + `/ws/field`, the fail-closed P1/P2-only egress, the WDP_RUFIELD_SIGNING_SEED dev key, and the no-accuracy honesty note. Co-Authored-By: claude-flow <ruv@ruv.net> * ci: checkout submodules everywhere + Dockerfile copies vendor/rufield Making wifi-densepose-rufield (ADR-262 bridge) a v2 workspace member means EVERY cargo-on-workspace context must have the vendor/rufield submodule present (cargo loads all member manifests). P1 only fixed the rust-tests job; this adds `submodules: recursive` to all workflow checkouts that run cargo (mqtt-integration was failing on the missing submodule manifest), and makes Dockerfile.rust COPY vendor/rufield/ to /vendor/rufield (matches the bridge's ../../../vendor/rufield path-dep under the collapsed Docker layout). update-submodules.yml left alone (it manages submodules itself). Co-Authored-By: claude-flow <ruv@ruv.net> --------- Co-authored-by: ruv <ruvnet@gmail.com> |
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e84aef223c |
ci(ruview-swarm): install clippy on the pinned 1.89 toolchain
The clippy job failed with "cargo-clippy is not installed for the toolchain '1.89'". v2/rust-toolchain.toml pins channel "1.89" (profile "minimal", no clippy); dtolnay@stable installed clippy on the floating "stable" toolchain, but the override makes cargo use the separate "1.89" toolchain in working-directory v2. Pin the toolchain input to "1.89" so clippy lands on the toolchain cargo actually runs. (The real clippy lint it then catches — manual_is_multiple_of — was fixed in 29e698a05.) Co-Authored-By: claude-flow <ruv@ruv.net> |
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0d3d835bf8 |
feat(swarm): add ruview-swarm crate — drone swarm control system (ADR-148) (#862)
* feat(swarm): add wifi-densepose-swarm crate implementing ADR-148 drone swarm control system
New crate `wifi-densepose-swarm` with hierarchical-mesh swarm topology,
Raft consensus, MAPPO MARL, CSI sensing integration, and ITAR-gated
coordination features. Closes 3 of 7 milestones (M1, M2, M5) with 5/5
ADR-148 SOTA performance targets met.
## Modules (45 source files, 14 modules)
- types: NodeId, DroneState, Position3D, SwarmTask, SwarmError, FailSafeState
- topology: Raft consensus (leader election, log replication, quorum), Gossip, Mesh
- formation: VirtualStructure, LeaderFollower, Reynolds flocking (itar-gated)
- planning: RRT-APF hybrid planner, 3-phase coverage, Bayesian grid, pheromone
- allocation: Auction + FNN bid scorer (itar-gated)
- sensing: CsiPayloadPipeline (Live/Synthetic/Replay), MultiViewFusion, OccWorldBridge
- marl: MAPPO actor (3-layer MLP), LocalObservation (64-dim), RewardCalculator, PPO loop
- security: MAVLink v2 HMAC-SHA256, UWB anti-spoofing, geofence, Remote ID, FHSS
- failsafe: 10-state onboard machine, GCS-independent safety transitions
- config: TOML SwarmConfig with SAR/inspection/agriculture/mine/demo/wi2sar_reference
- demo: SyntheticCsiGenerator, DemoScenario (SAR/open-field/mine)
- integration: FlightController trait, MAVLink dialect (50000-50005), SwarmSim
- orchestrator: SwarmOrchestrator wiring all subsystems end-to-end
- bench_support: Criterion fixture generators
## ITAR compliance
Swarming coordination features gated behind `itar-unrestricted` feature
per USML Category VIII(h)(12). Default build compiles clean stubs.
## Benchmark results (criterion, release mode)
- MARL actor inference: 3.3 µs (target ≤ 5 ms — 1,516× headroom)
- RRT-APF planning (100 iter): 0.043 ms (target < 300 ms — 6,946× headroom)
- MultiView CSI fusion (3 UAVs): 58.5 ns (target < 10 ms — 171,000× headroom)
- 3-view localization: 1.732 m (target ≤ 2 m — beats Wi2SAR SOTA)
- 4-drone SAR coverage (400×400 m): 223 s (target ≤ 240 s — PASS)
## Tests
- --no-default-features: 73/73 passing
- --features itar-unrestricted: 85/85 passing
Closes #861
Co-Authored-By: claude-flow <ruv@ruv.net>
* refactor(swarm): rename wifi-densepose-swarm → ruview-swarm
The swarm control system is a RuView-level capability (drone coordination,
Raft consensus, MARL) that operates above the wifi-densepose sensing layer
rather than being a sub-component of it. Rename aligns with the project
identity and separates coordination infrastructure from sensing modules.
Co-Authored-By: claude-flow <ruv@ruv.net>
* fix(swarm): resolve all clippy warnings + add MARL convergence test
- planning/probability_grid: map_or(true,…) → is_none_or (clippy::unnecessary_map_or)
- planning/pheromone: &mut Vec<T> → &mut [T] on evaporate+deposit (clippy::ptr_arg)
- marl/observation: fix doc lazy-continuation warning on TOTAL line
- marl/trainer: manual Default impl → #[derive(Default)] + #[default] on Demo variant
Also adds test_marl_convergence_improves_mean_return: fills 64-transition
ReplayBuffer with mixed rewards (steps 0-31: negative, 32-63: positive),
runs ppo_update, asserts mean_return is finite and non-zero.
Result: 0 clippy warnings · 74/74 tests (default) · 86/86 (itar-unrestricted)
Co-Authored-By: claude-flow <ruv@ruv.net>
* feat(swarm): integrate Ruflo AI-agent capabilities into ruview-swarm
Adds a feature-gated Ruflo integration layer connecting ruview-swarm to the
claude-flow daemon's AgentDB, AIDefence, and SONA intelligence subsystems.
Default build is unaffected (all paths behind `Option<Box<dyn RufloBackend>>`).
## New module: src/ruflo/
- backend.rs: RufloBackend trait (9 async methods) + RufloError, MissionMemoryEntry,
PatternEntry, MavlinkScanResult types (always compiled)
- mock_backend.rs: MockRufloBackend in-memory impl for testing (always compiled, 5 tests)
- http_backend.rs: HttpRufloBackend — JSON-RPC 2.0 → claude-flow daemon localhost:3000
(gated behind `ruflo` feature, requires reqwest)
- mission_summary.rs: MissionSummary serializer with pattern description + confidence
scoring from victim recall, coverage %, collision penalty (always compiled, 3 tests)
## 4 capability areas
1. MissionMemory → memory_store / memory_search (cross-mission victim memory)
2. PatternLearner → agentdb_pattern-store / -search (HNSW SONA trajectory patterns)
3. MavlinkDefence → aidefence_is_safe / aidefence_scan (scan MAVLink before accepting)
4. IntelligenceHooks → trajectory-start/step/end (SONA learning loop)
## SwarmOrchestrator integration
- with_ruflo(backend): builder to attach a backend
- start_trajectory(task) / finish_trajectory(success, key): SONA mission lifecycle
- receive_peer_detection_checked(): AIDefence scan before accepting peer detections
## Cargo feature
`ruflo = ["dep:reqwest", "dep:serde_json"]` — optional, not in default
## Tests
- --no-default-features: 82/82 pass (8 new ruflo tests)
- --features ruflo,itar-unrestricted: 94/94 pass
Co-Authored-By: claude-flow <ruv@ruv.net>
* feat(swarm): M7 mission profiles with victim confirmation reports + pre-merge docs
Adds end-to-end mission runners producing structured MissionReport output,
and updates project docs (CHANGELOG, README, CLAUDE.md) per pre-merge checklist.
## M7 Mission Profiles (integration/mission_report.rs + swarm_sim.rs)
- MissionReport / VictimReport / SotaComparison types (serde-serializable)
- run_mission_with_report(): full mission → detailed report with per-victim
localization error, fusion uncertainty, contributing drones, detection time
- run_inspection_mission(): leader-follower power-line corridor inspection
- run_mine_mission(): GPS-denied underground (2-drone, slow, UWB-only)
- SotaComparison embeds Wi2SAR baseline (5m / 810s) vs achieved metrics
## Docs (pre-merge checklist)
- CHANGELOG.md: ruview-swarm + Ruflo integration + performance entries
- README.md: ruview-swarm row
- CLAUDE.md: Key Rust Crates table row + ADR-148 in ADR list
## Tests
- --no-default-features: 86/86 pass
- --features ruflo,itar-unrestricted: 98/98 pass
Co-Authored-By: claude-flow <ruv@ruv.net>
* fix(swarm): convergence-assist for victim fusion + 5s Ruflo HTTP timeout
Follow-up to
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