Audit: - docs/AUDIT-2026-05-25.md: full protocol audit covering 8 findings (4 critical, 2 high, 5 medium, 4 low) with code references and fix effort estimates - vault/Audit/Tasks.md: Obsidian Tasks plugin file tracking all audit items with priorities, due dates, and per-step checklists Architecture docs updated for Wire format v2 and Wave 5/6 features: - ARCHITECTURE.md: adds wzp-video to dependency graph and project structure; wire format updated to v2 (16B header, 5B MiniHeader); relay concurrency section corrected (DashMap+RwLock is current, not a future optimization); test count 571→702; Android note - PROGRESS.md: Wave 5 and Wave 6 sections appended; test count 372→702; current status and open blockers as of 2026-05-25 - ROAD-TO-VIDEO.md: implementation status table inserted (✅/🟡/🔴/🔲 per phase); 6-step critical path to first video call - WZP-SPEC.md: MediaHeader updated to v2 (16B byte-aligned); MiniHeader updated to 5B with seq_delta; codec IDs 9-12 added (H.264/H.265/AV1); version negotiation section added Obsidian vault (vault/): - 114 files across Architecture/, PRDs/, Reports/, Android/, Reference/, Audit/ with YAML frontmatter - 00 - Home.md index note with wiki links - .obsidian/app.json config Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
145 lines
7.4 KiB
Markdown
145 lines
7.4 KiB
Markdown
---
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tags: [prd, wzp]
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type: prd
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---
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# PRD: Network Awareness
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> Phase: Implemented (core path)
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> Status: Ready for testing
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> Platform: Android native Kotlin app (com.wzp)
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## Problem
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WarzonePhone's quality controller (`AdaptiveQualityController`) had a `signal_network_change()` API for proactive adaptation to WiFi↔cellular transitions, but nothing called it. Network handoffs during calls were only detected reactively via jitter spikes — by which time the user had already experienced degraded audio.
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## Solution
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Integrate Android's `ConnectivityManager.NetworkCallback` to detect network transport changes in real-time and feed them to the quality controller. This enables:
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1. **Preemptive quality downgrade** when switching from WiFi to cellular
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2. **FEC boost** (10-second window with +0.2 ratio) after any network change
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3. **Faster downgrade thresholds** on cellular (2 consecutive reports vs 3 on WiFi)
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## Architecture
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```
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┌──────────────────────────────────────────────────────────────┐
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│ Android │
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│ │
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│ ConnectivityManager │
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│ │ NetworkCallback │
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│ ▼ │
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│ NetworkMonitor.kt │
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│ │ onNetworkChanged(type, bandwidthKbps) │
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│ ▼ │
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│ CallViewModel.kt ──► WzpEngine.onNetworkChanged() │
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│ │ JNI │
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│ ▼ │
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│ jni_bridge.rs: nativeOnNetworkChanged(handle, type, bw) │
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│ │ │
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│ ▼ │
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│ engine.rs: state.pending_network_type.store(type) │
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│ │ AtomicU8 (lock-free) │
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│ ▼ │
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│ recv task: quality_ctrl.signal_network_change(ctx) │
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│ │ │
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│ ├─ Preemptive downgrade (WiFi → cellular) │
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│ ├─ FEC boost 10s │
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│ └─ Faster cellular thresholds │
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└──────────────────────────────────────────────────────────────┘
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```
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## Network Classification
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`NetworkMonitor` classifies the active transport without requiring `READ_PHONE_STATE` permission by using bandwidth heuristics:
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| Downstream Bandwidth | Classification | Rust `NetworkContext` |
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|----------------------|---------------|----------------------|
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| N/A (WiFi transport) | WiFi | `WiFi` |
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| >= 100 Mbps | 5G NR | `Cellular5g` |
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| >= 10 Mbps | LTE | `CellularLte` |
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| < 10 Mbps | 3G or worse | `Cellular3g` |
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| Ethernet | WiFi (equivalent) | `WiFi` |
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| Network lost | None | `Unknown` |
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## Cross-Task Signaling
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The network type is communicated from the JNI thread to the recv task via `AtomicU8` — the same pattern used for `pending_profile` (adaptive quality profile switches):
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```
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JNI thread recv task (tokio)
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│ │
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│ store(type, Release) │
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│──────────────────────────────►│
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│ │ swap(0xFF, Acquire)
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│ │ if != 0xFF:
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│ │ quality_ctrl.signal_network_change(ctx)
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│ │
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```
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Sentinel value `0xFF` means "no change pending". The recv task polls on every received packet (~20-40ms), so latency is bounded by the inter-packet interval.
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## Components
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### New File
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| File | Purpose |
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|------|---------|
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| `android/.../net/NetworkMonitor.kt` | ConnectivityManager callback, transport classification, deduplication |
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### Modified Files
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| File | Change |
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|------|--------|
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| `android/.../engine/WzpEngine.kt` | Added `onNetworkChanged()` method + `nativeOnNetworkChanged` external |
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| `android/.../ui/call/CallViewModel.kt` | Instantiates NetworkMonitor, wires callback, register/unregister lifecycle |
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| `crates/wzp-android/src/jni_bridge.rs` | Added `Java_com_wzp_engine_WzpEngine_nativeOnNetworkChanged` JNI entry |
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| `crates/wzp-android/src/engine.rs` | Added `pending_network_type: AtomicU8` to EngineState, recv task polls it |
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### Unchanged (already implemented)
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| File | API |
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|------|-----|
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| `crates/wzp-proto/src/quality.rs` | `AdaptiveQualityController::signal_network_change(NetworkContext)` |
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| `crates/wzp-transport/src/path_monitor.rs` | `PathMonitor::detect_handoff()` (available for future use) |
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## Deferred Work
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### Tauri Desktop App (com.wzp.desktop)
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~~The Tauri engine doesn't use `AdaptiveQualityController` — quality is resolved once at call start.~~ **Update (2026-04-13):** Desktop now has `AdaptiveQualityController` wired into the recv task with `pending_profile` AtomicU8 bridge. Network monitoring on desktop is now feasible — the blocker was adaptive quality, which is done. Remaining work: platform-specific network change detection (macOS: `SCNetworkReachability` or `NWPathMonitor`; Linux: `netlink` socket).
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### Mid-Call ICE Re-gathering — PARTIALLY IMPLEMENTED (2026-04-14)
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When the device's IP address changes, the system now:
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1. Re-gather local host candidates (`local_host_candidates()`) ✅
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2. Re-probe STUN (`stun::discover_reflexive()` + `portmap::acquire_port_mapping()`) ✅
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3. Send updated candidates to the peer (`CandidateUpdate` signal message) ✅
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4. Relay forwards `CandidateUpdate` to peer (same pattern as `MediaPathReport`) ✅
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5. Peer receives and can parse via `IceAgent::apply_peer_update()` ✅
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6. Attempt new dual-path race for path upgrade — **NOT YET WIRED** (transport hot-swap)
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`NetworkMonitor.onIpChanged` fires on `onLinkPropertiesChanged` — the hook is ready.
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The signaling plane is fully implemented via `IceAgent` + `CandidateUpdate`.
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Remaining: wire `onIpChanged` → JNI → `pending_ice_regather` AtomicBool → recv task → `ice_agent.re_gather()` → transport swap.
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New modules added in Phase 8 (Tailscale-inspired):
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- `crates/wzp-client/src/ice_agent.rs` — candidate lifecycle management
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- `crates/wzp-client/src/stun.rs` — public STUN server probing (independent of relay)
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- `crates/wzp-client/src/portmap.rs` — NAT-PMP/PCP/UPnP port mapping
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- `crates/wzp-client/src/netcheck.rs` — comprehensive network diagnostic
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## Testing
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1. Build native APK
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2. Start a call on WiFi
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3. Verify logcat: `quality controller: network context updated` with `ctx=WiFi`
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4. Disable WiFi → device falls to cellular
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5. Verify logcat: `ctx=CellularLte` (or `Cellular5g`/`Cellular3g`)
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6. Verify FEC boost activates (check quality_ctrl logs)
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7. Verify preemptive quality downgrade (tier drops one level on WiFi→cellular)
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8. Re-enable WiFi → verify transition back
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9. Rapid WiFi toggle (5x in 10s) → verify no crashes, deduplication works
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10. Airplane mode → verify `onLost` fires with `TYPE_NONE`
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