History

ruv a7467f5470 feat(adr-115): P7 — Matter cluster + device-type mapping (HA-FABRIC scaffolding, 16 tests) Ships the Matter cluster + device-type mapping table as pure Rust types independent of any specific Matter SDK. SDK choice between `matter-rs` and chip-tool FFI per ADR-115 §9.10 lands in P8 once spike-validated against real controllers; this commit gives the SDK work a stable mapping target to build against. ## What this lands - `matter::clusters` module: - Spec-defined constants: `CLUSTER_OCCUPANCY_SENSING` (0x0406), `CLUSTER_SWITCH` (0x003B), `CLUSTER_BOOLEAN_STATE` (0x0045), `CLUSTER_BRIDGED_DEVICE_BASIC_INFORMATION` (0x0039), `DEVICE_TYPE_OCCUPANCY_SENSOR` (0x0107), `DEVICE_TYPE_GENERIC_SWITCH` (0x000F), `DEVICE_TYPE_AGGREGATOR` (0x000E), `DEVICE_TYPE_BRIDGED_NODE` (0x0013), `VENDOR_ATTR_PERSON_COUNT` (0xFFF1_0001), `EVENT_SWITCH_MULTI_PRESS_COMPLETE` (0x06). Values transcribed from Matter Core Spec 1.3 §A.1 + Device Library 1.3. - `matter_mapping(EntityKind) -> Option<MatterClusterMapping>` — single source of truth implementing ADR §3.11.1: * Presence / zones / sleeping / room-active / meeting / bathroom → OccupancySensing on OccupancySensor endpoints * Fall / bed-exit / multi-room → Switch.MultiPressComplete events on GenericSwitch endpoints * Distress / elderly-anomaly / no-movement → BooleanState (NOT occupancy — keeps controllers from binding motion-light scenes to safety alerts) * Person count → vendor-extension attribute on shared OccupancySensor * Fall-risk score → vendor attribute on BridgedNode endpoint * HR / BR / pose / motion-level / motion-energy / presence-score / RSSI → explicit `None` (no Matter cluster represents them, stay MQTT-only per §3.11.4) - `entity_on_matter` + `next_endpoint` helpers. ## Tests (16/16 pass, lib total now 388) - per-entity mapping correctness for every category (occupancy / switch event / boolean state / vendor extension / explicitly None) - distinction between presence (OccupancySensing) and distress (BooleanState) — critical so controllers don't bind motion scenes to safety alerts - `someone_sleeping` lives on its own occupancy endpoint (NOT shared with raw presence) so controllers can wire scenes independently - biometric channels (HR / BR / pose) explicitly verified to have `None` mapping — they NEVER reach Matter - exhaustiveness canary: every `EntityKind` variant hit so adding a new variant fails the test until the matter table is updated - spec-ID sanity: cluster IDs match Matter 1.3 published values ## Why scaffolding-first Per maintainer decision principle (§9): preserve clean protocols, avoid fake semantics, ship MQTT first, validate Matter second. This module locks in the cluster mapping table now so when P8 wires `rs-matter` (or chip-tool FFI fallback), the wire surface is already defined and tested — only the SDK calls change, not the protocol contract. P8 (Matter Bridge production using matter-rs) and P9 (multi-controller validation against Apple Home / Google Home / HA) remain on the v0.7.1 docket per §9.10. Refs #776, PR #778. Co-Authored-By: claude-flow <ruv@ruv.net>		2026-05-23 14:30:32 -04:00
..
cog-person-count	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
cog-pose-estimation	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
nvsim	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
nvsim-server	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
ruv-neural	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00
wifi-densepose-cli	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-core	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-desktop	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-geo	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-hardware	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-mat	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-nn	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-pointcloud	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-ruvector	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-sensing-server	feat(adr-115): P7 — Matter cluster + device-type mapping (HA-FABRIC scaffolding, 16 tests)	2026-05-23 14:30:32 -04:00
wifi-densepose-signal	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-train	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-vitals	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-wasm	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
wifi-densepose-wasm-edge	feat(nvsim): full simulator stack — Rust crate, dashboard, server, App Store, Ghost Murmur [ADR-089/090/091/092/093]	2026-04-27 12:41:01 -04:00
wifi-densepose-wifiscan	fix(security): audit — fix RUSTSEC vulns, clippy warnings, dead code (#769 )	2026-05-23 05:36:13 -04:00
README.md	chore(repo): rename rust-port/wifi-densepose-rs → v2/ (flatten to one level) (#427 )	2026-04-25 21:28:13 -04:00

README.md

WiFi-DensePose Rust Crates

See through walls with WiFi. No cameras. No wearables. Just radio waves.

A modular Rust workspace for WiFi-based human pose estimation, vital sign monitoring, and disaster response using Channel State Information (CSI). Built on RuVector graph algorithms and the WiFi-DensePose research platform by rUv.

Performance

Operation	Python v1	Rust v2	Speedup
CSI Preprocessing	~5 ms	5.19 us	~1000x
Phase Sanitization	~3 ms	3.84 us	~780x
Feature Extraction	~8 ms	9.03 us	~890x
Motion Detection	~1 ms	186 ns	~5400x
Full Pipeline	~15 ms	18.47 us	~810x
Vital Signs	N/A	86 us (11,665 fps)	--

Crate Overview

Core Foundation

Crate	Description	crates.io
`wifi-densepose-core`	Types, traits, and utilities (`CsiFrame`, `PoseEstimate`, `SignalProcessor`)
`wifi-densepose-config`	Configuration management (env, TOML, YAML)
`wifi-densepose-db`	Database persistence (PostgreSQL, SQLite, Redis)

Signal Processing & Sensing

Crate	Description	RuVector Integration
`wifi-densepose-signal`	SOTA CSI signal processing (6 algorithms from SpotFi, FarSense, Widar 3.0)	`ruvector-mincut`, `ruvector-attn-mincut`, `ruvector-attention`, `ruvector-solver`
`wifi-densepose-vitals`	Vital sign extraction: breathing (6-30 BPM) and heart rate (40-120 BPM)	--
`wifi-densepose-wifiscan`	Multi-BSSID WiFi scanning for Windows-enhanced sensing	--

Neural Network & Training

Crate	Description	RuVector Integration	crates.io
`wifi-densepose-nn`	Multi-backend inference (ONNX, PyTorch, Candle) with DensePose head (24 body parts)	--
`wifi-densepose-train`	Training pipeline with MM-Fi dataset, 114->56 subcarrier interpolation	All 5 crates

Disaster Response

Crate	Description	RuVector Integration	crates.io
`wifi-densepose-mat`	Mass Casualty Assessment Tool -- survivor detection, triage, multi-AP localization	`ruvector-solver`, `ruvector-temporal-tensor`

Hardware & Deployment

Crate	Description	crates.io
`wifi-densepose-hardware`	ESP32, Intel 5300, Atheros CSI sensor interfaces (pure Rust, no FFI)
`wifi-densepose-wasm`	WebAssembly bindings for browser-based disaster dashboard
`wifi-densepose-sensing-server`	Axum server: ESP32 UDP ingestion, WebSocket broadcast, sensing UI

Applications

Crate	Description	crates.io
`wifi-densepose-api`	REST + WebSocket API layer
`wifi-densepose-cli`	Command-line tool for MAT disaster scanning

Architecture

                          wifi-densepose-core
                         (types, traits, errors)
                                  |
              +-------------------+-------------------+
              |                   |                   |
    wifi-densepose-signal   wifi-densepose-nn   wifi-densepose-hardware
    (CSI processing)        (inference)         (ESP32, Intel 5300)
    + ruvector-mincut       + ONNX Runtime          |
    + ruvector-attn-mincut  + PyTorch (tch)   wifi-densepose-vitals
    + ruvector-attention    + Candle          (breathing, heart rate)
    + ruvector-solver            |
              |                  |             wifi-densepose-wifiscan
              +--------+---------+            (BSSID scanning)
                       |
          +------------+------------+
          |                         |
  wifi-densepose-train    wifi-densepose-mat
  (training pipeline)     (disaster response)
  + ALL 5 ruvector        + ruvector-solver
                          + ruvector-temporal-tensor
                                |
              +-----------------+-----------------+
              |                 |                 |
    wifi-densepose-api  wifi-densepose-wasm  wifi-densepose-cli
    (REST/WS)           (browser WASM)       (CLI tool)
              |
    wifi-densepose-sensing-server
    (Axum + WebSocket)

RuVector Integration

All RuVector crates at v2.0.4 from crates.io:

RuVector Crate	Used In	Purpose
`ruvector-mincut`	signal, train	Dynamic min-cut for subcarrier selection & person matching
`ruvector-attn-mincut`	signal, train	Attention-weighted min-cut for antenna gating & spectrograms
`ruvector-temporal-tensor`	train, mat	Tiered temporal compression (4-10x memory reduction)
`ruvector-solver`	signal, train, mat	Sparse Neumann solver for interpolation & triangulation
`ruvector-attention`	signal, train	Scaled dot-product attention for spatial features & BVP

Signal Processing Algorithms

Six state-of-the-art algorithms implemented in wifi-densepose-signal:

Algorithm	Paper	Year	Module
Conjugate Multiplication	SpotFi (SIGCOMM)	2015	`csi_ratio.rs`
Hampel Filter	WiGest	2015	`hampel.rs`
Fresnel Zone Model	FarSense (MobiCom)	2019	`fresnel.rs`
CSI Spectrogram	Standard STFT	2018+	`spectrogram.rs`
Subcarrier Selection	WiDance (MobiCom)	2017	`subcarrier_selection.rs`
Body Velocity Profile	Widar 3.0 (MobiSys)	2019	`bvp.rs`

Quick Start

As a Library

use wifi_densepose_core::{CsiFrame, CsiMetadata, SignalProcessor};
use wifi_densepose_signal::{CsiProcessor, CsiProcessorConfig};

// Configure the CSI processor
let config = CsiProcessorConfig::default();
let processor = CsiProcessor::new(config);

// Process a CSI frame
let frame = CsiFrame { /* ... */ };
let processed = processor.process(&frame)?;

Vital Sign Monitoring

use wifi_densepose_vitals::{
    CsiVitalPreprocessor, BreathingExtractor, HeartRateExtractor,
    VitalAnomalyDetector,
};

let mut preprocessor = CsiVitalPreprocessor::new(56); // 56 subcarriers
let mut breathing = BreathingExtractor::new(100.0);    // 100 Hz sample rate
let mut heartrate = HeartRateExtractor::new(100.0);

// Feed CSI frames and extract vitals
for frame in csi_stream {
    let residuals = preprocessor.update(&frame.amplitudes);
    if let Some(bpm) = breathing.push_residuals(&residuals) {
        println!("Breathing: {:.1} BPM", bpm);
    }
}

Disaster Response (MAT)

use wifi_densepose_mat::{DisasterResponse, DisasterConfig, DisasterType};

let config = DisasterConfig {
    disaster_type: DisasterType::Earthquake,
    max_scan_zones: 16,
    ..Default::default()
};

let mut responder = DisasterResponse::new(config);
responder.add_scan_zone(zone)?;
responder.start_continuous_scan().await?;

Hardware (ESP32)

use wifi_densepose_hardware::{Esp32CsiParser, CsiFrame};

let parser = Esp32CsiParser::new();
let raw_bytes: &[u8] = /* UDP packet from ESP32 */;
let frame: CsiFrame = parser.parse(raw_bytes)?;
println!("RSSI: {} dBm, {} subcarriers", frame.metadata.rssi, frame.subcarriers.len());

Training

# Check training crate (no GPU needed)
cargo check -p wifi-densepose-train --no-default-features

# Run training with GPU (requires tch/libtorch)
cargo run -p wifi-densepose-train --features tch-backend --bin train -- \
    --config training.toml --dataset /path/to/mmfi

# Verify deterministic training proof
cargo run -p wifi-densepose-train --features tch-backend --bin verify-training

Building

# Clone the repository
git clone https://github.com/ruvnet/wifi-densepose.git
cd wifi-densepose/v2

# Check workspace (no GPU dependencies)
cargo check --workspace --no-default-features

# Run all tests
cargo test --workspace --no-default-features

# Build release
cargo build --release --workspace

Feature Flags

Crate	Feature	Description
`wifi-densepose-nn`	`onnx` (default)	ONNX Runtime backend
`wifi-densepose-nn`	`tch-backend`	PyTorch (libtorch) backend
`wifi-densepose-nn`	`candle-backend`	Candle (pure Rust) backend
`wifi-densepose-nn`	`cuda`	CUDA GPU acceleration
`wifi-densepose-train`	`tch-backend`	Enable GPU training modules
`wifi-densepose-mat`	`ruvector` (default)	RuVector graph algorithms
`wifi-densepose-mat`	`api` (default)	REST + WebSocket API
`wifi-densepose-mat`	`distributed`	Multi-node coordination
`wifi-densepose-mat`	`drone`	Drone-mounted scanning
`wifi-densepose-hardware`	`esp32`	ESP32 protocol support
`wifi-densepose-hardware`	`intel5300`	Intel 5300 CSI Tool
`wifi-densepose-hardware`	`linux-wifi`	Linux commodity WiFi
`wifi-densepose-wifiscan`	`wlanapi`	Windows WLAN API async scanning
`wifi-densepose-core`	`serde`	Serialization support
`wifi-densepose-core`	`async`	Async trait support

Testing

# Unit tests (all crates)
cargo test --workspace --no-default-features

# Signal processing benchmarks
cargo bench -p wifi-densepose-signal

# Training benchmarks
cargo bench -p wifi-densepose-train --no-default-features

# Detection benchmarks
cargo bench -p wifi-densepose-mat

Supported Hardware

Hardware	Crate Feature	CSI Subcarriers	Cost
ESP32-S3 Mesh (3-6 nodes)	`hardware/esp32`	52-56	~$54
Intel 5300 NIC	`hardware/intel5300`	30	~$50
Atheros AR9580	`hardware/linux-wifi`	56	~$100
Any WiFi (Windows/Linux)	`wifiscan`	RSSI-only	$0

Architecture Decision Records

Key design decisions documented in docs/adr/:

ADR	Title	Status
ADR-014	SOTA Signal Processing	Accepted
ADR-015	MM-Fi + Wi-Pose Training Datasets	Accepted
ADR-016	RuVector Training Pipeline	Accepted (Complete)
ADR-017	RuVector Signal + MAT Integration	Accepted
ADR-021	Vital Sign Detection Pipeline	Accepted
ADR-022	Windows WiFi Enhanced Sensing	Accepted
ADR-024	Contrastive CSI Embedding Model	Accepted

WiFi-DensePose -- Main repository (Python v1 + Rust v2)
RuVector -- Graph algorithms for neural networks (5 crates, v2.0.4)
rUv -- Creator and maintainer

License

All crates are dual-licensed under MIT OR Apache-2.0.