Rust implementation of the EmberZNet Serial Protocol (EZSP) host side.
EZSP is the command protocol used by a host application processor to communicate with the EmberZNet PRO stack running on a Silicon Labs Network Co-Processor (NCP). The crate models the EZSP command/response surface, frame headers, parameter payloads, asynchronous callbacks, and the UART transport used by EZSP-UART NCP firmware.
The crate documentation is based on these Silicon Labs references:
UG100: EZSP Reference Guide, Rev. 5.1, for EmberZNet PRO 7.4.2.UG101: UART-EZSP Gateway Protocol Reference, Rev. 1.3, for ASHv2 over UART.- https://docs.silabs.com/zigbee/latest/sisdk-ezsp-reference-guide/, which currently documents the Simplicity SDK EZSP guide for Zigbee 9.1.0 / EmberZNet PRO 8.1 and notes the v8 API/type renaming split from UG100.
- https://docs.silabs.com/zigbee/6.6/em35x/, the older EmberZNet API reference used by several Ember type descriptions.
The implementation keeps the legacy EZSP naming used throughout UG100 and the EmberZNet 6.x/7.x API surface where that naming is reflected in the crate.
ashv2: enables the ASHv2 serial transport (uart::Uart).apis-saltans: enablesapis_saltans_hwintegration forNcp/Builderand pulls inapis-saltansAPS/core/hardware/ZDP crates.semver: enablessemversupport for EZSP version APIs.
EZSP messages are exchanged between a host and an NCP over SPI or UART. This crate currently provides the UART path via ASHv2.
- The host starts normal EZSP use by sending the
versioncommand after NCP reset. A successful version transaction establishes the protocol version that both sides will use. - EZSP fields wider than one byte are serialized little-endian, including EUI64 values.
- Frames contain a sequence number, frame control, frame ID, and typed parameters. EZSP protocol versions before 8 use a three-byte legacy header; versions 8 and newer use the extended five-byte header.
- Most commands form a two-message transaction: host command, then NCP response. UART NCPs may also send callbacks asynchronously as they occur.
- The response frame control reports NCP status bits such as overflow, truncation, callback-pending state, and callback type.
UG101 describes ASH as the data-link layer below EZSP and above the serial driver. ASHv2 frames add reliability around EZSP payloads: CRC validation, byte stuffing, data-field randomization, sliding-window acknowledgements, ACK/NAK frames, reset handling, and optional not-ready flow control.
EZSP and ASHv2 do not add a protocol-level fragmentation layer. On UART, one EZSP frame is carried in exactly one ASHv2 DATA payload, and one ASHv2 DATA payload is decoded as exactly one EZSP frame.
The ashv2 feature delegates this link layer to the ashv2 crate and keeps the
EZSP-specific work in this crate:
uart::Encoderserializes EZSP headers and parameters into ASHv2 payloads.uart::Decoderparses ASHv2 payloads back into typed EZSP frames.uart::Splitterroutes normal responses to the pending request path and UART asynchronous callbacks to the callback channel. Its future returns an error if one of those destination channels closes before the splitter finishes.uartre-exports the ASHv2 types and helpers used by the public transport API:FlowControl,Handle,NativeSerialPort,Payload,SerialPort,open, andstart.
The crate is transport-first:
Transportdefines the low-level async connection and request/response primitives.- EZSP command traits (
Configuration,Messaging,Networking,Security, ...) are blanket-implemented for anyT: Transport. Ezspis a convenience trait that combines all command traits.Ncp<T>wraps a transport and adds host-side NCP helpers for scans, APS send confirmation, transaction/message sequence counters, and callback correlation.- Protocol types are exposed through
ember,ezsp, and the typed frame/parameter model.
Implementing Transport gives access to the full typed command surface.
The crate currently ships one concrete transport implementation: uart::Uart (feature = "ashv2").
Uart provides:
- protocol negotiation through
Transport::connect()/Transport::ensure_connection() - typed EZSP request/response handling over ASHv2 payload framing
- response/callback demultiplexing
- caller-driven transport futures through
uart::Futures - serial constructors:
Uart::open(path, flow_control, protocol_version, &ChannelSizes)returns(Uart, callbacks, Futures<_>)Uart::from_serial_port(serial_port, protocol_version, &ChannelSizes)returns(Uart, callbacks, Futures<_>)Uart::new(handle, ash_rx, callbacks_tx, protocol_version, channel_size)returns(Uart, splitter_future)for advanced integration. The splitter future resolves tostd::io::Result<()>.
Additional types:
uart::ChannelSizesto tune queue capacities forUart::open/from_serial_portuart::Buffersfor ASHv2 queue sizing in integration helper constructorsuart::Futuresfor the serial worker, ASHv2 transmitter/receiver, and EZSP frame splitter futures that the caller must poll or spawn. The frame splitter future resolves tostd::io::Result<()>.uart::SerialPort,uart::FlowControl, and the other re-exported ASHv2 items needed to integrate the UART transport without importingashv2paths directly
use ezsp::uart::{ChannelSizes, SerialPort, Uart};
use ezsp::{Transport, Utilities};
use tokio::task::LocalSet;
// Requires feature = "ashv2"
// Requires a Tokio runtime. The returned futures must be driven by the caller.
async fn example() -> Result<(), ezsp::Error> {
let serial_port = /* your serial port implementing SerialPort */;
let sizes = ChannelSizes::default();
let (mut uart, _callbacks, futures) =
Uart::from_serial_port(serial_port, ezsp::MIN_NON_LEGACY_VERSION, &sizes)?;
let local = LocalSet::new();
local.spawn_local(futures.serial_worker);
local.spawn_local(futures.ash_transmitter);
local.spawn_local(futures.ash_receiver);
local.spawn_local(async move {
futures
.frame_splitter
.await
.expect("EZSP frame splitter failed");
});
local
.run_until(async move {
uart.ensure_connection().await?;
let _eui64 = uart.get_eui64().await?;
Ok(())
})
.await
}Ncp<T> is the high-level host helper for an EZSP Network Co-Processor. It owns
the transport and dereferences to it, so all normal command traits remain
available.
Ncp adds behavior that needs more than a single command/response exchange:
- active and energy scans with callback aggregation,
- neighbor table collection,
- unicast and multicast APS sends with
messageSentconfirmation, - broadcast APS sends with immediate confirmation,
- source endpoint selection for outgoing APS frames from the configured local endpoint output clusters,
- message tag and APS sequence counters,
- clean event-handler shutdown through
Ncp::terminate().
Ncp::build(transport, callbacks) returns Builder<T>. The builder stores
policies, configuration values, security keys, APS options, concentrator
settings, network formation settings, and channel buffer sizing for the startup
implementation.
Outgoing APS helper methods take the APS profile ID, cluster ID, destination
endpoint, and message payload. They derive the source endpoint from the first
configured local endpoint that advertises the cluster ID as an output cluster.
If no endpoint matches, the send fails with Error::NoMatchingSourceEndpoint.
If ashv2 is enabled, Ncp::ashv2(serial_port) and
Builder::<uart::Uart>::ashv2(serial_port) create a builder backed by the
crate's ASHv2 UART transport. The serial port type is constrained by the
re-exported uart::SerialPort trait. These constructors return the builder and
the uart::Futures set that must be driven alongside the NCP.
When apis-saltans is enabled, the crate adapts Ncp to the
apis_saltans_hw driver traits and provides custom Builder startup helpers.
Ncp<T>: apis_saltans_hw::DriverwhenT: Configuration + Security + Messaging + Networking + Utilities + Send + Sync.Builder::start(endpoints)configures the EZSP stack, starts callback translation, registers eachSimpleDescriptoras an EZSP endpoint, stores the descriptor cluster lists for later source endpoint selection, spawns the NCP actor, and returns(apis_saltans_hw::NcpHandle, tokio::sync::mpsc::Receiver<apis_saltans_hw::Event>).Ncp::terminate()stops the event handler and returns the underlying transport.
The integration layer translates EZSP callbacks into apis_saltans_hw::Event,
including network-up/down/open/closed events, child join/leave events,
trust-center join/rejoin/leave events, and incoming APS messages. It also
aggregates scan callbacks for Driver scan calls and correlates
messageSent callbacks with outgoing message tags. Outgoing Driver frames
use the frame metadata for the APS profile and cluster; unicast calls use the
requested destination endpoint, while multicast and broadcast calls use the
profile's broadcast endpoint. Unicast sends target one destination endpoint per
call; callers that need fan-out should issue multiple unicast requests.
This project is free software and is not affiliated with Silicon Labs. Silicon Labs documentation is cited only to describe the public protocol implemented by this crate.
- Format:
cargo +nightly fmt - Lint:
cargo clippy