#![no_std] #![feature(generic_associated_types)] #![feature(type_alias_impl_trait)] //! Implements HID functionality for a usb-device device. // This mod MUST go first, so that the others see its macros. pub(crate) mod fmt; use core::mem::MaybeUninit; use core::ops::Range; use embassy::time::Duration; use embassy_usb::driver::EndpointOut; use embassy_usb::{ control::{ControlHandler, InResponse, OutResponse, Request, RequestType}, driver::{Driver, Endpoint, EndpointIn, WriteError}, UsbDeviceBuilder, }; #[cfg(feature = "usbd-hid")] use ssmarshal::serialize; #[cfg(feature = "usbd-hid")] use usbd_hid::descriptor::AsInputReport; const USB_CLASS_HID: u8 = 0x03; const USB_SUBCLASS_NONE: u8 = 0x00; const USB_PROTOCOL_NONE: u8 = 0x00; // HID const HID_DESC_DESCTYPE_HID: u8 = 0x21; const HID_DESC_DESCTYPE_HID_REPORT: u8 = 0x22; const HID_DESC_SPEC_1_10: [u8; 2] = [0x10, 0x01]; const HID_DESC_COUNTRY_UNSPEC: u8 = 0x00; const HID_REQ_SET_IDLE: u8 = 0x0a; const HID_REQ_GET_IDLE: u8 = 0x02; const HID_REQ_GET_REPORT: u8 = 0x01; const HID_REQ_SET_REPORT: u8 = 0x09; const HID_REQ_GET_PROTOCOL: u8 = 0x03; const HID_REQ_SET_PROTOCOL: u8 = 0x0b; #[derive(Debug, Clone, Copy, PartialEq, Eq)] #[cfg_attr(feature = "defmt", derive(defmt::Format))] pub enum ReportId { In(u8), Out(u8), Feature(u8), } impl ReportId { fn try_from(value: u16) -> Result { match value >> 8 { 1 => Ok(ReportId::In(value as u8)), 2 => Ok(ReportId::Out(value as u8)), 3 => Ok(ReportId::Feature(value as u8)), _ => Err(()), } } } pub struct State<'a, const IN_N: usize, const OUT_N: usize> { control: MaybeUninit>, } impl<'a, const IN_N: usize, const OUT_N: usize> State<'a, IN_N, OUT_N> { pub fn new() -> Self { State { control: MaybeUninit::uninit(), } } } pub struct HidClass<'d, D: Driver<'d>, T, const IN_N: usize> { input: ReportWriter<'d, D, IN_N>, output: T, } impl<'d, D: Driver<'d>, const IN_N: usize> HidClass<'d, D, (), IN_N> { /// Creates a new HidClass. /// /// poll_ms configures how frequently the host should poll for reading/writing /// HID reports. A lower value means better throughput & latency, at the expense /// of CPU on the device & bandwidth on the bus. A value of 10 is reasonable for /// high performance uses, and a value of 255 is good for best-effort usecases. /// /// This allocates an IN endpoint only. pub fn new( builder: &mut UsbDeviceBuilder<'d, D>, state: &'d mut State<'d, IN_N, OUT_N>, report_descriptor: &'static [u8], request_handler: Option<&'d dyn RequestHandler>, poll_ms: u8, max_packet_size: u16, ) -> Self { let ep_in = builder.alloc_interrupt_endpoint_in(max_packet_size, poll_ms); let control = state .control .write(Control::new(report_descriptor, request_handler)); control.build(builder, None, &ep_in); Self { input: ReportWriter { ep_in }, output: (), } } } impl<'d, D: Driver<'d>, T, const IN_N: usize> HidClass<'d, D, T, IN_N> { /// Gets the [`ReportWriter`] for input reports. /// /// **Note:** If the `HidClass` was created with [`new_ep_out()`](Self::new_ep_out) /// this writer will be useless as no endpoint is availabe to send reports. pub fn input(&mut self) -> &mut ReportWriter<'d, D, IN_N> { &mut self.input } } impl<'d, D: Driver<'d>, const IN_N: usize, const OUT_N: usize> HidClass<'d, D, ReportReader<'d, D, OUT_N>, IN_N> { /// Creates a new HidClass. /// /// poll_ms configures how frequently the host should poll for reading/writing /// HID reports. A lower value means better throughput & latency, at the expense /// of CPU on the device & bandwidth on the bus. A value of 10 is reasonable for /// high performance uses, and a value of 255 is good for best-effort usecases. /// /// This allocates two endpoints (IN and OUT). pub fn with_output_ep( builder: &mut UsbDeviceBuilder<'d, D>, state: &'d mut State<'d, IN_N, OUT_N>, report_descriptor: &'static [u8], request_handler: Option<&'d dyn RequestHandler>, poll_ms: u8, max_packet_size: u16, ) -> Self { let ep_out = builder.alloc_interrupt_endpoint_out(max_packet_size, poll_ms); let ep_in = builder.alloc_interrupt_endpoint_in(max_packet_size, poll_ms); let control = state .control .write(Control::new(report_descriptor, request_handler)); control.build(builder, Some(&ep_out), &ep_in); Self { input: ReportWriter { ep_in }, output: ReportReader { ep_out, offset: 0 }, } } /// Gets the [`ReportReader`] for output reports. pub fn output(&mut self) -> &mut ReportReader<'d, D, OUT_N> { &mut self.output } /// Splits this `HidClass` into seperate readers/writers for input and output reports. pub fn split(self) -> (ReportWriter<'d, D, IN_N>, ReportReader<'d, D, OUT_N>) { (self.input, self.output) } } pub struct ReportWriter<'d, D: Driver<'d>, const N: usize> { ep_in: D::EndpointIn, } pub struct ReportReader<'d, D: Driver<'d>, const N: usize> { ep_out: D::EndpointOut, offset: usize, } #[derive(Debug, Clone, PartialEq, Eq)] #[cfg_attr(feature = "defmt", derive(defmt::Format))] pub enum ReadError { BufferOverflow, Disabled, Sync(Range), } impl From for ReadError { fn from(val: embassy_usb::driver::ReadError) -> Self { use embassy_usb::driver::ReadError::*; match val { BufferOverflow => ReadError::BufferOverflow, Disabled => ReadError::Disabled, } } } impl<'d, D: Driver<'d>, const N: usize> ReportWriter<'d, D, N> { /// Tries to write an input report by serializing the given report structure. /// /// Panics if no endpoint is available. #[cfg(feature = "usbd-hid")] pub async fn serialize(&mut self, r: &IR) -> Result<(), WriteError> { let mut buf: [u8; N] = [0; N]; let size = match serialize(&mut buf, r) { Ok(size) => size, Err(_) => return Err(WriteError::BufferOverflow), }; self.write(&buf[0..size]).await } /// Writes `report` to its interrupt endpoint. /// /// Panics if no endpoint is available. pub async fn write(&mut self, report: &[u8]) -> Result<(), WriteError> { assert!(report.len() <= N); let max_packet_size = usize::from(self.ep_in.info().max_packet_size); let zlp_needed = report.len() < N && (report.len() % max_packet_size == 0); for chunk in report.chunks(max_packet_size) { self.ep_in.write(chunk).await?; } if zlp_needed { self.ep_in.write(&[]).await?; } Ok(()) } } impl<'d, D: Driver<'d>, const N: usize> ReportReader<'d, D, N> { /// Starts a task to deliver output reports from the Interrupt Out pipe to /// `handler`. pub async fn run(mut self, handler: &T) -> ! { assert!(self.offset == 0); let mut buf = [0; N]; loop { match self.read(&mut buf).await { Ok(len) => { handler.set_report(ReportId::Out(0), &buf[0..len]); } Err(ReadError::BufferOverflow) => warn!("Host sent output report larger than the configured maximum output report length ({})", N), Err(ReadError::Disabled) => self.ep_out.wait_enabled().await, Err(ReadError::Sync(_)) => unreachable!(), } } } /// Reads an output report from the Interrupt Out pipe. /// /// **Note:** Any reports sent from the host over the control pipe will be /// passed to [`RequestHandler::set_report()`] for handling. The application /// is responsible for ensuring output reports from both pipes are handled /// correctly. /// /// **Note:** If `N` > the maximum packet size of the endpoint (i.e. output /// reports may be split across multiple packets) and this method's future /// is dropped after some packets have been read, the next call to `read()` /// will return a [`ReadError::SyncError()`]. The range in the sync error /// indicates the portion `buf` that was filled by the current call to /// `read()`. If the dropped future used the same `buf`, then `buf` will /// contain the full report. pub async fn read(&mut self, buf: &mut [u8]) -> Result { assert!(buf.len() >= N); // Read packets from the endpoint let max_packet_size = usize::from(self.ep_out.info().max_packet_size); let starting_offset = self.offset; for chunk in buf[starting_offset..].chunks_mut(max_packet_size) { let size = self.ep_out.read(chunk).await?; self.offset += size; if size < max_packet_size || self.offset == N { break; } } let total = self.offset; self.offset = 0; if starting_offset > 0 { Err(ReadError::Sync(starting_offset..total)) } else { Ok(total) } } } pub trait RequestHandler { /// Reads the value of report `id` into `buf` returning the size. /// /// Returns `None` if `id` is invalid or no data is available. fn get_report(&self, id: ReportId, buf: &mut [u8]) -> Option { let _ = (id, buf); None } /// Sets the value of report `id` to `data`. fn set_report(&self, id: ReportId, data: &[u8]) -> OutResponse { let _ = (id, data); OutResponse::Rejected } /// Get the idle rate for `id`. /// /// If `id` is `None`, get the idle rate for all reports. Returning `None` /// will reject the control request. Any duration at or above 1.024 seconds /// or below 4ms will be returned as an indefinite idle rate. fn get_idle(&self, id: Option) -> Option { let _ = id; None } /// Set the idle rate for `id` to `dur`. /// /// If `id` is `None`, set the idle rate of all input reports to `dur`. If /// an indefinite duration is requested, `dur` will be set to `Duration::MAX`. fn set_idle(&self, id: Option, dur: Duration) { let _ = (id, dur); } } struct Control<'d> { report_descriptor: &'static [u8], request_handler: Option<&'d dyn RequestHandler>, hid_descriptor: [u8; 9], } impl<'a> Control<'a> { fn new( report_descriptor: &'static [u8], request_handler: Option<&'a dyn RequestHandler>, ) -> Self { Control { report_descriptor, request_handler, hid_descriptor: [ // Length of buf inclusive of size prefix 9, // Descriptor type HID_DESC_DESCTYPE_HID, // HID Class spec version HID_DESC_SPEC_1_10[0], HID_DESC_SPEC_1_10[1], // Country code not supported HID_DESC_COUNTRY_UNSPEC, // Number of following descriptors 1, // We have a HID report descriptor the host should read HID_DESC_DESCTYPE_HID_REPORT, // HID report descriptor size, (report_descriptor.len() & 0xFF) as u8, (report_descriptor.len() >> 8 & 0xFF) as u8, ], } } fn build<'d, D: Driver<'d>>( &'d mut self, builder: &mut UsbDeviceBuilder<'d, D>, ep_out: Option<&D::EndpointOut>, ep_in: &D::EndpointIn, ) { let len = self.report_descriptor.len(); let if_num = builder.alloc_interface_with_handler(self); builder.config_descriptor.interface( if_num, USB_CLASS_HID, USB_SUBCLASS_NONE, USB_PROTOCOL_NONE, ); // HID descriptor builder.config_descriptor.write( HID_DESC_DESCTYPE_HID, &[ // HID Class spec version HID_DESC_SPEC_1_10[0], HID_DESC_SPEC_1_10[1], // Country code not supported HID_DESC_COUNTRY_UNSPEC, // Number of following descriptors 1, // We have a HID report descriptor the host should read HID_DESC_DESCTYPE_HID_REPORT, // HID report descriptor size, (len & 0xFF) as u8, (len >> 8 & 0xFF) as u8, ], ); builder.config_descriptor.endpoint(ep_in.info()); if let Some(ep) = ep_out { builder.config_descriptor.endpoint(ep.info()); } } } impl<'d> ControlHandler for Control<'d> { fn reset(&mut self) {} fn control_out(&mut self, req: embassy_usb::control::Request, data: &[u8]) -> OutResponse { trace!("HID control_out {:?} {=[u8]:x}", req, data); if let RequestType::Class = req.request_type { match req.request { HID_REQ_SET_IDLE => { if let Some(handler) = self.request_handler { let id = req.value as u8; let id = (id != 0).then(|| ReportId::In(id)); let dur = u64::from(req.value >> 8); let dur = if dur == 0 { Duration::MAX } else { Duration::from_millis(4 * dur) }; handler.set_idle(id, dur); } OutResponse::Accepted } HID_REQ_SET_REPORT => match (ReportId::try_from(req.value), self.request_handler) { (Ok(id), Some(handler)) => handler.set_report(id, data), _ => OutResponse::Rejected, }, HID_REQ_SET_PROTOCOL => { if req.value == 1 { OutResponse::Accepted } else { warn!("HID Boot Protocol is unsupported."); OutResponse::Rejected // UNSUPPORTED: Boot Protocol } } _ => OutResponse::Rejected, } } else { OutResponse::Rejected // UNSUPPORTED: SET_DESCRIPTOR } } fn control_in<'a>(&'a mut self, req: Request, buf: &'a mut [u8]) -> InResponse<'a> { trace!("HID control_in {:?}", req); match (req.request_type, req.request) { (RequestType::Standard, Request::GET_DESCRIPTOR) => match (req.value >> 8) as u8 { HID_DESC_DESCTYPE_HID_REPORT => InResponse::Accepted(self.report_descriptor), HID_DESC_DESCTYPE_HID => InResponse::Accepted(&self.hid_descriptor), _ => InResponse::Rejected, }, (RequestType::Class, HID_REQ_GET_REPORT) => { let size = match ReportId::try_from(req.value) { Ok(id) => self.request_handler.and_then(|x| x.get_report(id, buf)), Err(_) => None, }; if let Some(size) = size { InResponse::Accepted(&buf[0..size]) } else { InResponse::Rejected } } (RequestType::Class, HID_REQ_GET_IDLE) => { if let Some(handler) = self.request_handler { let id = req.value as u8; let id = (id != 0).then(|| ReportId::In(id)); if let Some(dur) = handler.get_idle(id) { let dur = u8::try_from(dur.as_millis() / 4).unwrap_or(0); buf[0] = dur; InResponse::Accepted(&buf[0..1]) } else { InResponse::Rejected } } else { InResponse::Rejected } } (RequestType::Class, HID_REQ_GET_PROTOCOL) => { // UNSUPPORTED: Boot Protocol buf[0] = 1; InResponse::Accepted(&buf[0..1]) } _ => InResponse::Rejected, } } }