Everything necessary to run rs-matter on the ESP-IDF:
- Bluedroid implementation of
rs-matter'sGattPeripheralfor BLE comissioning support. rs-matter-stacksupport withNetif,Ble,WirelessandKvBlobStoreimplementations.
Since ESP-IDF does support the Rust Standard Library, UDP networking just works.
(See also All examples)
//! An example utilizing the `EspWifiNCMatterStack` struct.
//!
//! As the name suggests, this Matter stack assembly uses Wifi as the main transport,
//! (and thus BLE for commissioning), where `NC` stands for non-concurrent commisisoning
//! (i.e., the stack will not run the BLE and Wifi radio simultaneously, which saves memory).
//!
//! If you want to use Ethernet, utilize `EspEthMatterStack` instead.
//! If you want to use concurrent commissioning, utilize `EspWifiMatterStack` instead
//! (Alexa does not work (yet) with non-concurrent commissioning).
//!
//! The example implements a fictitious Light device (an On-Off Matter cluster).
use core::pin::pin;
use embassy_futures::select::select;
use embassy_time::{Duration, Timer};
use esp_idf_matter::{init_async_io, EspMatterBle, EspMatterWifi, EspWifiNCMatterStack};
use esp_idf_svc::eventloop::EspSystemEventLoop;
use esp_idf_svc::hal::peripherals::Peripherals;
use esp_idf_svc::hal::task::block_on;
use esp_idf_svc::log::EspLogger;
use esp_idf_svc::nvs::EspDefaultNvsPartition;
use esp_idf_svc::timer::EspTaskTimerService;
use log::{error, info};
use rs_matter::data_model::cluster_basic_information::BasicInfoConfig;
use rs_matter::data_model::cluster_on_off;
use rs_matter::data_model::device_types::DEV_TYPE_ON_OFF_LIGHT;
use rs_matter::data_model::objects::{Dataver, Endpoint, HandlerCompat, Node};
use rs_matter::data_model::system_model::descriptor;
use rs_matter::utils::init::InitMaybeUninit;
use rs_matter::utils::select::Coalesce;
use rs_matter::BasicCommData;
use rs_matter_stack::persist::DummyPersist;
use static_cell::StaticCell;
#[path = "dev_att/dev_att.rs"]
mod dev_att;
fn main() -> Result<(), anyhow::Error> {
EspLogger::initialize_default();
info!("Starting...");
// Run in a higher-prio thread to avoid issues with `async-io` getting
// confused by the low priority of the ESP IDF main task
// Also allocate a very large stack (for now) as `rs-matter` futures do occupy quite some space
let thread = std::thread::Builder::new()
.stack_size(75 * 1024)
.spawn(|| {
// Eagerly initialize `async-io` to minimize the risk of stack blowups later on
init_async_io()?;
run()
})
.unwrap();
thread.join().unwrap()
}
#[inline(never)]
#[cold]
fn run() -> Result<(), anyhow::Error> {
let result = block_on(matter());
if let Err(e) = &result {
error!("Matter aborted execution with error: {:?}", e);
}
{
info!("Matter finished execution successfully");
}
result
}
async fn matter() -> Result<(), anyhow::Error> {
// Initialize the Matter stack (can be done only once),
// as we'll run it in this thread
let stack = MATTER_STACK
.uninit()
.init_with(EspWifiNCMatterStack::init_default(
&BasicInfoConfig {
vid: 0xFFF1,
pid: 0x8000,
hw_ver: 2,
sw_ver: 1,
sw_ver_str: "1",
serial_no: "aabbccdd",
device_name: "MyLight",
product_name: "ACME Light",
vendor_name: "ACME",
},
BasicCommData {
password: 20202021,
discriminator: 3840,
},
&DEV_ATT,
));
// Take some generic ESP-IDF stuff we'll need later
let sysloop = EspSystemEventLoop::take()?;
let timers = EspTaskTimerService::new()?;
let nvs = EspDefaultNvsPartition::take()?;
let peripherals = Peripherals::take()?;
// Our "light" on-off cluster.
// Can be anything implementing `rs_matter::data_model::AsyncHandler`
let on_off = cluster_on_off::OnOffCluster::new(Dataver::new_rand(stack.matter().rand()));
// Chain our endpoint clusters with the
// (root) Endpoint 0 system clusters in the final handler
let handler = stack
.root_handler()
// Our on-off cluster, on Endpoint 1
.chain(
LIGHT_ENDPOINT_ID,
cluster_on_off::ID,
HandlerCompat(&on_off),
)
// Each Endpoint needs a Descriptor cluster too
// Just use the one that `rs-matter` provides out of the box
.chain(
LIGHT_ENDPOINT_ID,
descriptor::ID,
HandlerCompat(descriptor::DescriptorCluster::new(Dataver::new_rand(
stack.matter().rand(),
))),
);
let (mut wifi_modem, mut bt_modem) = peripherals.modem.split();
// Run the Matter stack with our handler
// Using `pin!` is completely optional, but saves some memory due to `rustc`
// not being very intelligent w.r.t. stack usage in async functions
let mut matter = pin!(stack.run(
// The Matter stack needs the Wifi modem peripheral
EspMatterWifi::new(&mut wifi_modem, sysloop, timers, nvs.clone()),
// The Matter stack needs the BT modem peripheral
EspMatterBle::new(&mut bt_modem, nvs, stack),
// The Matter stack needs a persister to store its state
// `EspPersist`+`EspKvBlobStore` saves to a user-supplied NVS partition
// under namespace `esp-idf-matter`
DummyPersist,
//EspPersist::new_wifi_ble(EspKvBlobStore::new_default(nvs.clone())?, stack),
// Our `AsyncHandler` + `AsyncMetadata` impl
(NODE, handler),
// No user future to run
core::future::pending(),
));
// Just for demoing purposes:
//
// Run a sample loop that simulates state changes triggered by the HAL
// Changes will be properly communicated to the Matter controllers
// (i.e. Google Home, Alexa) and other Matter devices thanks to subscriptions
let mut device = pin!(async {
loop {
// Simulate user toggling the light with a physical switch every 5 seconds
Timer::after(Duration::from_secs(5)).await;
// Toggle
on_off.set(!on_off.get());
// Let the Matter stack know that we have changed
// the state of our Light device
stack.notify_changed();
info!("Light toggled");
}
});
// Schedule the Matter run & the device loop together
select(&mut matter, &mut device).coalesce().await?;
Ok(())
}
/// The Matter stack is allocated statically to avoid
/// program stack blowups.
/// It is also a mandatory requirement when the `WifiBle` stack variation is used.
static MATTER_STACK: StaticCell<EspWifiNCMatterStack<()>> = StaticCell::new();
static DEV_ATT: dev_att::HardCodedDevAtt = dev_att::HardCodedDevAtt::new();
/// Endpoint 0 (the root endpoint) always runs
/// the hidden Matter system clusters, so we pick ID=1
const LIGHT_ENDPOINT_ID: u16 = 1;
/// The Matter Light device Node
const NODE: Node = Node {
id: 0,
endpoints: &[
EspWifiNCMatterStack::<()>::root_metadata(),
Endpoint {
id: LIGHT_ENDPOINT_ID,
device_types: &[DEV_TYPE_ON_OFF_LIGHT],
clusters: &[descriptor::CLUSTER, cluster_on_off::CLUSTER],
},
],
};- Thread networking (for ESP32H2 and ESP32C6)
- Device Attestation data support using secure flash storage
- Setting system time via Matter
- Matter OTA support based on the ESP IDF OTA API
Follow the Prerequisites section in the esp-idf-template crate.
The examples could be built and flashed conveniently with cargo-espflash. To run e.g. light on an e.g. ESP32-C3:
(Swap the Rust target and example name with the target corresponding for your ESP32 MCU and with the example you would like to build)
with cargo-espflash:
$ MCU=esp32c3 cargo espflash flash --target riscv32imc-esp-espidf --example light --features examples --monitor| MCU | "--target" |
|---|---|
| esp32c2 | riscv32imc-esp-espidf |
| esp32c3 | riscv32imc-esp-espidf |
| esp32c6 | riscv32imac-esp-espidf |
| esp32h2 | riscv32imac-esp-espidf |
| esp32p4 | riscv32imafc-esp-espidf |
| esp32 | xtensa-esp32-espidf |
| esp32s2 | xtensa-esp32s2-espidf |
| esp32s3 | xtensa-esp32s3-espidf |