#![no_std] // This mod MUST go first, so that the others see its macros. pub(crate) mod fmt; use core::intrinsics::copy_nonoverlapping; use core::mem::{size_of, MaybeUninit}; use embassy_usb::control::{self, ControlHandler, InResponse, OutResponse, Request}; use embassy_usb::driver::{Driver, Endpoint, EndpointError, EndpointIn, EndpointOut}; use embassy_usb::types::*; use embassy_usb::Builder; /// This should be used as `device_class` when building the `UsbDevice`. pub const USB_CLASS_CDC: u8 = 0x02; const USB_CLASS_CDC_DATA: u8 = 0x0a; const CDC_SUBCLASS_NCM: u8 = 0x0d; const CDC_PROTOCOL_NONE: u8 = 0x00; const CDC_PROTOCOL_NTB: u8 = 0x01; const CS_INTERFACE: u8 = 0x24; const CDC_TYPE_HEADER: u8 = 0x00; const CDC_TYPE_UNION: u8 = 0x06; const CDC_TYPE_ETHERNET: u8 = 0x0F; const CDC_TYPE_NCM: u8 = 0x1A; const REQ_SEND_ENCAPSULATED_COMMAND: u8 = 0x00; //const REQ_GET_ENCAPSULATED_COMMAND: u8 = 0x01; //const REQ_SET_ETHERNET_MULTICAST_FILTERS: u8 = 0x40; //const REQ_SET_ETHERNET_POWER_MANAGEMENT_PATTERN_FILTER: u8 = 0x41; //const REQ_GET_ETHERNET_POWER_MANAGEMENT_PATTERN_FILTER: u8 = 0x42; //const REQ_SET_ETHERNET_PACKET_FILTER: u8 = 0x43; //const REQ_GET_ETHERNET_STATISTIC: u8 = 0x44; const REQ_GET_NTB_PARAMETERS: u8 = 0x80; //const REQ_GET_NET_ADDRESS: u8 = 0x81; //const REQ_SET_NET_ADDRESS: u8 = 0x82; //const REQ_GET_NTB_FORMAT: u8 = 0x83; //const REQ_SET_NTB_FORMAT: u8 = 0x84; //const REQ_GET_NTB_INPUT_SIZE: u8 = 0x85; const REQ_SET_NTB_INPUT_SIZE: u8 = 0x86; //const REQ_GET_MAX_DATAGRAM_SIZE: u8 = 0x87; //const REQ_SET_MAX_DATAGRAM_SIZE: u8 = 0x88; //const REQ_GET_CRC_MODE: u8 = 0x89; //const REQ_SET_CRC_MODE: u8 = 0x8A; //const NOTIF_MAX_PACKET_SIZE: u16 = 8; //const NOTIF_POLL_INTERVAL: u8 = 20; const NTB_MAX_SIZE: usize = 2048; const SIG_NTH: u32 = 0x484d434e; const SIG_NDP_NO_FCS: u32 = 0x304d434e; const SIG_NDP_WITH_FCS: u32 = 0x314d434e; const ALTERNATE_SETTING_DISABLED: u8 = 0x00; const ALTERNATE_SETTING_ENABLED: u8 = 0x01; /// Simple NTB header (NTH+NDP all in one) for sending packets #[repr(packed)] #[allow(unused)] struct NtbOutHeader { // NTH nth_sig: u32, nth_len: u16, nth_seq: u16, nth_total_len: u16, nth_first_index: u16, // NDP ndp_sig: u32, ndp_len: u16, ndp_next_index: u16, ndp_datagram_index: u16, ndp_datagram_len: u16, ndp_term1: u16, ndp_term2: u16, } #[repr(packed)] #[allow(unused)] struct NtbParameters { length: u16, formats_supported: u16, in_params: NtbParametersDir, out_params: NtbParametersDir, } #[repr(packed)] #[allow(unused)] struct NtbParametersDir { max_size: u32, divisor: u16, payload_remainder: u16, out_alignment: u16, max_datagram_count: u16, } fn byteify(buf: &mut [u8], data: T) -> &[u8] { let len = size_of::(); unsafe { copy_nonoverlapping(&data as *const _ as *const u8, buf.as_mut_ptr(), len) } &buf[..len] } pub struct State<'a> { comm_control: MaybeUninit>, data_control: MaybeUninit, shared: ControlShared, } impl<'a> State<'a> { pub fn new() -> Self { Self { comm_control: MaybeUninit::uninit(), data_control: MaybeUninit::uninit(), shared: Default::default(), } } } /// Shared data between Control and CdcAcmClass struct ControlShared { mac_addr: [u8; 6], } impl Default for ControlShared { fn default() -> Self { ControlShared { mac_addr: [0; 6] } } } struct CommControl<'a> { mac_addr_string: StringIndex, shared: &'a ControlShared, mac_addr_str: [u8; 12], } impl<'d> ControlHandler for CommControl<'d> { fn control_out(&mut self, req: control::Request, _data: &[u8]) -> OutResponse { match req.request { REQ_SEND_ENCAPSULATED_COMMAND => { // We don't actually support encapsulated commands but pretend we do for standards // compatibility. OutResponse::Accepted } REQ_SET_NTB_INPUT_SIZE => { // TODO OutResponse::Accepted } _ => OutResponse::Rejected, } } fn control_in<'a>(&'a mut self, req: Request, buf: &'a mut [u8]) -> InResponse<'a> { match req.request { REQ_GET_NTB_PARAMETERS => { let res = NtbParameters { length: size_of::() as _, formats_supported: 1, // only 16bit, in_params: NtbParametersDir { max_size: NTB_MAX_SIZE as _, divisor: 4, payload_remainder: 0, out_alignment: 4, max_datagram_count: 0, // not used }, out_params: NtbParametersDir { max_size: NTB_MAX_SIZE as _, divisor: 4, payload_remainder: 0, out_alignment: 4, max_datagram_count: 1, // We only decode 1 packet per NTB }, }; InResponse::Accepted(byteify(buf, res)) } _ => InResponse::Rejected, } } fn get_string(&mut self, index: StringIndex, _lang_id: u16) -> Option<&str> { if index == self.mac_addr_string { let mac_addr = self.shared.mac_addr; let s = &mut self.mac_addr_str; for i in 0..12 { let n = (mac_addr[i / 2] >> ((1 - i % 2) * 4)) & 0xF; s[i] = match n { 0x0..=0x9 => b'0' + n, 0xA..=0xF => b'A' + n - 0xA, _ => unreachable!(), } } Some(unsafe { core::str::from_utf8_unchecked(s) }) } else { warn!("unknown string index requested"); None } } } struct DataControl {} impl ControlHandler for DataControl { fn set_alternate_setting(&mut self, alternate_setting: u8) { match alternate_setting { ALTERNATE_SETTING_ENABLED => info!("ncm: interface enabled"), ALTERNATE_SETTING_DISABLED => info!("ncm: interface disabled"), _ => unreachable!(), } } } pub struct CdcNcmClass<'d, D: Driver<'d>> { _comm_if: InterfaceNumber, comm_ep: D::EndpointIn, data_if: InterfaceNumber, read_ep: D::EndpointOut, write_ep: D::EndpointIn, _control: &'d ControlShared, } impl<'d, D: Driver<'d>> CdcNcmClass<'d, D> { pub fn new( builder: &mut Builder<'d, D>, state: &'d mut State<'d>, mac_address: [u8; 6], max_packet_size: u16, ) -> Self { state.shared.mac_addr = mac_address; let mut func = builder.function(USB_CLASS_CDC, CDC_SUBCLASS_NCM, CDC_PROTOCOL_NONE); // Control interface let mut iface = func.interface(); let mac_addr_string = iface.string(); iface.handler(state.comm_control.write(CommControl { mac_addr_string, shared: &state.shared, mac_addr_str: [0; 12], })); let comm_if = iface.interface_number(); let mut alt = iface.alt_setting(USB_CLASS_CDC, CDC_SUBCLASS_NCM, CDC_PROTOCOL_NONE); alt.descriptor( CS_INTERFACE, &[ CDC_TYPE_HEADER, // bDescriptorSubtype 0x10, 0x01, // bcdCDC (1.10) ], ); alt.descriptor( CS_INTERFACE, &[ CDC_TYPE_UNION, // bDescriptorSubtype comm_if.into(), // bControlInterface u8::from(comm_if) + 1, // bSubordinateInterface ], ); alt.descriptor( CS_INTERFACE, &[ CDC_TYPE_ETHERNET, // bDescriptorSubtype mac_addr_string.into(), // iMACAddress 0, // bmEthernetStatistics 0, // | 0, // | 0, // | 0xea, // wMaxSegmentSize = 1514 0x05, // | 0, // wNumberMCFilters 0, // | 0, // bNumberPowerFilters ], ); alt.descriptor( CS_INTERFACE, &[ CDC_TYPE_NCM, // bDescriptorSubtype 0x00, // bcdNCMVersion 0x01, // | 0, // bmNetworkCapabilities ], ); let comm_ep = alt.endpoint_interrupt_in(8, 255); // Data interface let mut iface = func.interface(); iface.handler(state.data_control.write(DataControl {})); let data_if = iface.interface_number(); let _alt = iface.alt_setting(USB_CLASS_CDC_DATA, 0x00, CDC_PROTOCOL_NTB); let mut alt = iface.alt_setting(USB_CLASS_CDC_DATA, 0x00, CDC_PROTOCOL_NTB); let read_ep = alt.endpoint_bulk_out(max_packet_size); let write_ep = alt.endpoint_bulk_in(max_packet_size); CdcNcmClass { _comm_if: comm_if, comm_ep, data_if, read_ep, write_ep, _control: &state.shared, } } pub fn split(self) -> (Sender<'d, D>, Receiver<'d, D>) { ( Sender { write_ep: self.write_ep, seq: 0, }, Receiver { data_if: self.data_if, comm_ep: self.comm_ep, read_ep: self.read_ep, }, ) } } pub struct Sender<'d, D: Driver<'d>> { write_ep: D::EndpointIn, seq: u16, } impl<'d, D: Driver<'d>> Sender<'d, D> { pub async fn write_packet(&mut self, data: &[u8]) -> Result<(), EndpointError> { let seq = self.seq; self.seq = self.seq.wrapping_add(1); const MAX_PACKET_SIZE: usize = 64; // TODO unhardcode const OUT_HEADER_LEN: usize = 28; let header = NtbOutHeader { nth_sig: SIG_NTH, nth_len: 0x0c, nth_seq: seq, nth_total_len: (data.len() + OUT_HEADER_LEN) as u16, nth_first_index: 0x0c, ndp_sig: SIG_NDP_NO_FCS, ndp_len: 0x10, ndp_next_index: 0x00, ndp_datagram_index: OUT_HEADER_LEN as u16, ndp_datagram_len: data.len() as u16, ndp_term1: 0x00, ndp_term2: 0x00, }; // Build first packet on a buffer, send next packets straight from `data`. let mut buf = [0; MAX_PACKET_SIZE]; let n = byteify(&mut buf, header); assert_eq!(n.len(), OUT_HEADER_LEN); if OUT_HEADER_LEN + data.len() < MAX_PACKET_SIZE { // First packet is not full, just send it. // No need to send ZLP because it's short for sure. buf[OUT_HEADER_LEN..][..data.len()].copy_from_slice(data); self.write_ep.write(&buf[..OUT_HEADER_LEN + data.len()]).await?; } else { let (d1, d2) = data.split_at(MAX_PACKET_SIZE - OUT_HEADER_LEN); buf[OUT_HEADER_LEN..].copy_from_slice(d1); self.write_ep.write(&buf).await?; for chunk in d2.chunks(MAX_PACKET_SIZE) { self.write_ep.write(&chunk).await?; } // Send ZLP if needed. if d2.len() % MAX_PACKET_SIZE == 0 { self.write_ep.write(&[]).await?; } } Ok(()) } } pub struct Receiver<'d, D: Driver<'d>> { data_if: InterfaceNumber, comm_ep: D::EndpointIn, read_ep: D::EndpointOut, } impl<'d, D: Driver<'d>> Receiver<'d, D> { /// Reads a single packet from the OUT endpoint. pub async fn read_packet(&mut self, buf: &mut [u8]) -> Result { // Retry loop loop { // read NTB let mut ntb = [0u8; NTB_MAX_SIZE]; let mut pos = 0; loop { let n = self.read_ep.read(&mut ntb[pos..]).await?; pos += n; if n < self.read_ep.info().max_packet_size as usize || pos == NTB_MAX_SIZE { break; } } let ntb = &ntb[..pos]; // Process NTB header (NTH) let nth = match ntb.get(..12) { Some(x) => x, None => { warn!("Received too short NTB"); continue; } }; let sig = u32::from_le_bytes(nth[0..4].try_into().unwrap()); if sig != SIG_NTH { warn!("Received bad NTH sig."); continue; } let ndp_idx = u16::from_le_bytes(nth[10..12].try_into().unwrap()) as usize; // Process NTB Datagram Pointer (NDP) let ndp = match ntb.get(ndp_idx..ndp_idx + 12) { Some(x) => x, None => { warn!("NTH has an NDP pointer out of range."); continue; } }; let sig = u32::from_le_bytes(ndp[0..4].try_into().unwrap()); if sig != SIG_NDP_NO_FCS && sig != SIG_NDP_WITH_FCS { warn!("Received bad NDP sig."); continue; } let datagram_index = u16::from_le_bytes(ndp[8..10].try_into().unwrap()) as usize; let datagram_len = u16::from_le_bytes(ndp[10..12].try_into().unwrap()) as usize; if datagram_index == 0 || datagram_len == 0 { // empty, ignore. This is allowed by the spec, so don't warn. continue; } // Process actual datagram, finally. let datagram = match ntb.get(datagram_index..datagram_index + datagram_len) { Some(x) => x, None => { warn!("NDP has a datagram pointer out of range."); continue; } }; buf[..datagram_len].copy_from_slice(datagram); return Ok(datagram_len); } } /// Waits for the USB host to enable this interface pub async fn wait_connection(&mut self) -> Result<(), EndpointError> { loop { self.read_ep.wait_enabled().await; self.comm_ep.wait_enabled().await; let buf = [ 0xA1, //bmRequestType 0x00, //bNotificationType = NETWORK_CONNECTION 0x01, // wValue = connected 0x00, self.data_if.into(), // wIndex = interface 0x00, 0x00, // wLength 0x00, ]; match self.comm_ep.write(&buf).await { Ok(()) => break, // Done! Err(EndpointError::Disabled) => {} // Got disabled again, wait again. Err(e) => return Err(e), } } Ok(()) } }