#![no_std] #![doc = include_str!("../README.md")] #![warn(missing_docs)] // must go first. mod fmt; #[macro_use] mod macros; mod bank0; mod bank1; mod bank2; mod bank3; mod common; mod header; mod phy; mod traits; use core::cmp; use core::convert::TryInto; use embassy_net_driver::{Capabilities, HardwareAddress, LinkState}; use embassy_time::Duration; use embedded_hal::digital::OutputPin; use embedded_hal::spi::{Operation, SpiDevice}; use traits::U16Ext; // Total buffer size (see section 3.2) const BUF_SZ: u16 = 8 * 1024; // Maximum frame length const MAX_FRAME_LENGTH: u16 = 1518; // value recommended in the data sheet // Size of the Frame check sequence (32-bit CRC) const CRC_SZ: u16 = 4; // define the boundaries of the TX and RX buffers // to workaround errata #5 we do the opposite of what section 6.1 of the data sheet // says: we place the RX buffer at address 0 and the TX buffer after it const RXST: u16 = 0x0000; const RXND: u16 = 0x19ff; const TXST: u16 = 0x1a00; const _TXND: u16 = 0x1fff; const MTU: usize = 1514; // 1500 IP + 14 ethernet header /// ENC28J60 embassy-net driver pub struct Enc28j60 { mac_addr: [u8; 6], spi: S, rst: Option, bank: Bank, // address of the next packet in buffer memory next_packet: u16, } impl Enc28j60 where S: SpiDevice, O: OutputPin, { /// Create a new ENC28J60 driver instance. /// /// The RST pin is optional. If None, reset will be done with a SPI /// soft reset command, instead of via the RST pin. pub fn new(spi: S, rst: Option, mac_addr: [u8; 6]) -> Self { let mut res = Self { mac_addr, spi, rst, bank: Bank::Bank0, next_packet: RXST, }; res.init(); res } fn init(&mut self) { if let Some(rst) = &mut self.rst { rst.set_low().unwrap(); embassy_time::block_for(Duration::from_millis(5)); rst.set_high().unwrap(); embassy_time::block_for(Duration::from_millis(5)); } else { embassy_time::block_for(Duration::from_millis(5)); self.soft_reset(); embassy_time::block_for(Duration::from_millis(5)); } debug!( "enc28j60: erevid {=u8:x}", self.read_control_register(bank3::Register::EREVID) ); debug!("enc28j60: waiting for clk"); while common::ESTAT(self.read_control_register(common::Register::ESTAT)).clkrdy() == 0 {} debug!("enc28j60: clk ok"); if self.read_control_register(bank3::Register::EREVID) == 0 { panic!("ErevidIsZero"); } // disable CLKOUT output self.write_control_register(bank3::Register::ECOCON, 0); self.init_rx(); // TX start // "It is recommended that an even address be used for ETXST" debug_assert_eq!(TXST % 2, 0); self.write_control_register(bank0::Register::ETXSTL, TXST.low()); self.write_control_register(bank0::Register::ETXSTH, TXST.high()); // TX end is set in `transmit` // MAC initialization (see section 6.5) // 1. Set the MARXEN bit in MACON1 to enable the MAC to receive frames. self.write_control_register( bank2::Register::MACON1, bank2::MACON1::default().marxen(1).passall(0).rxpaus(1).txpaus(1).bits(), ); // 2. Configure the PADCFG, TXCRCEN and FULDPX bits of MACON3. self.write_control_register( bank2::Register::MACON3, bank2::MACON3::default().frmlnen(1).txcrcen(1).padcfg(0b001).bits(), ); // 4. Program the MAMXFL registers with the maximum frame length to be permitted to be // received or transmitted self.write_control_register(bank2::Register::MAMXFLL, MAX_FRAME_LENGTH.low()); self.write_control_register(bank2::Register::MAMXFLH, MAX_FRAME_LENGTH.high()); // 5. Configure the Back-to-Back Inter-Packet Gap register, MABBIPG. // Use recommended value of 0x12 self.write_control_register(bank2::Register::MABBIPG, 0x12); // 6. Configure the Non-Back-to-Back Inter-Packet Gap register low byte, MAIPGL. // Use recommended value of 0x12 self.write_control_register(bank2::Register::MAIPGL, 0x12); self.write_control_register(bank2::Register::MAIPGH, 0x0c); // 9. Program the local MAC address into the MAADR1:MAADR6 registers self.write_control_register(bank3::Register::MAADR1, self.mac_addr[0]); self.write_control_register(bank3::Register::MAADR2, self.mac_addr[1]); self.write_control_register(bank3::Register::MAADR3, self.mac_addr[2]); self.write_control_register(bank3::Register::MAADR4, self.mac_addr[3]); self.write_control_register(bank3::Register::MAADR5, self.mac_addr[4]); self.write_control_register(bank3::Register::MAADR6, self.mac_addr[5]); // Set the PHCON2.HDLDIS bit to prevent automatic loopback of the data which is transmitted self.write_phy_register(phy::Register::PHCON2, phy::PHCON2::default().hdldis(1).bits()); // Globally enable interrupts //self.bit_field_set(common::Register::EIE, common::EIE::mask().intie()); // Set the per packet control byte; we'll always use the value 0 self.write_buffer_memory(Some(TXST), &mut [0]); // Enable reception self.bit_field_set(common::Register::ECON1, common::ECON1::mask().rxen()); } fn init_rx(&mut self) { // RX start // "It is recommended that the ERXST Pointer be programmed with an even address" self.write_control_register(bank0::Register::ERXSTL, RXST.low()); self.write_control_register(bank0::Register::ERXSTH, RXST.high()); // RX read pointer // NOTE Errata #14 so we are using an *odd* address here instead of ERXST self.write_control_register(bank0::Register::ERXRDPTL, RXND.low()); self.write_control_register(bank0::Register::ERXRDPTH, RXND.high()); // RX end self.write_control_register(bank0::Register::ERXNDL, RXND.low()); self.write_control_register(bank0::Register::ERXNDH, RXND.high()); // decrease the packet count to 0 while self.read_control_register(bank1::Register::EPKTCNT) != 0 { self.bit_field_set(common::Register::ECON2, common::ECON2::mask().pktdec()); } self.next_packet = RXST; } fn reset_rx(&mut self) { self.bit_field_set(common::Register::ECON1, common::ECON1::mask().rxrst()); self.bit_field_clear(common::Register::ECON1, common::ECON1::mask().rxrst()); self.init_rx(); self.bit_field_set(common::Register::ECON1, common::ECON1::mask().rxen()); } /// Returns the device's MAC address pub fn address(&self) -> [u8; 6] { self.mac_addr } /// Flushes the transmit buffer, ensuring all pending transmissions have completed /// NOTE: The returned packet *must* be `read` or `ignore`-d, otherwise this method will always /// return `None` on subsequent invocations pub fn receive(&mut self, buf: &mut [u8]) -> Option { if self.pending_packets() == 0 { // Errata #6: we can't rely on PKTIF so we check PKTCNT return None; } let curr_packet = self.next_packet; // read out the first 6 bytes let mut temp_buf = [0; 6]; self.read_buffer_memory(Some(curr_packet), &mut temp_buf); // next packet pointer let next_packet = u16::from_parts(temp_buf[0], temp_buf[1]); // status vector let status = header::RxStatus(u32::from_le_bytes(temp_buf[2..].try_into().unwrap())); let len_with_crc = status.byte_count() as u16; if len_with_crc < CRC_SZ || len_with_crc > 1600 || next_packet > RXND { warn!("RX buffer corrupted, resetting RX logic to recover..."); self.reset_rx(); return None; } let len = len_with_crc - CRC_SZ; self.read_buffer_memory(None, &mut buf[..len as usize]); // update ERXRDPT // due to Errata #14 we must write an odd address to ERXRDPT // we know that ERXST = 0, that ERXND is odd and that next_packet is even let rxrdpt = if self.next_packet < 1 || self.next_packet > RXND + 1 { RXND } else { self.next_packet - 1 }; // "To move ERXRDPT, the host controller must write to ERXRDPTL first." self.write_control_register(bank0::Register::ERXRDPTL, rxrdpt.low()); self.write_control_register(bank0::Register::ERXRDPTH, rxrdpt.high()); // decrease the packet count self.bit_field_set(common::Register::ECON2, common::ECON2::mask().pktdec()); self.next_packet = next_packet; Some(len as usize) } fn wait_tx_ready(&mut self) { for _ in 0u32..10000 { if common::ECON1(self.read_control_register(common::Register::ECON1)).txrts() == 0 { return; } } // work around errata #12 by resetting the transmit logic before every new // transmission self.bit_field_set(common::Register::ECON1, common::ECON1::mask().txrst()); self.bit_field_clear(common::Register::ECON1, common::ECON1::mask().txrst()); //self.bit_field_clear(common::Register::EIR, { // let mask = common::EIR::mask(); // mask.txerif() | mask.txif() //}); } /// Starts the transmission of `bytes` /// /// It's up to the caller to ensure that `bytes` is a valid Ethernet frame. The interface will /// take care of appending a (4 byte) CRC to the frame and of padding the frame to the minimum /// size allowed by the Ethernet specification (64 bytes, or 46 bytes of payload). /// /// NOTE This method will flush any previous transmission that's in progress /// /// # Panics /// /// If `bytes` length is greater than 1514, the maximum frame length allowed by the interface, /// or greater than the transmit buffer pub fn transmit(&mut self, bytes: &[u8]) { assert!(bytes.len() <= self.mtu() as usize); self.wait_tx_ready(); // NOTE the plus one is to not overwrite the per packet control byte let wrpt = TXST + 1; // 1. ETXST was set during initialization // 2. write the frame to the IC memory self.write_buffer_memory(Some(wrpt), bytes); let txnd = wrpt + bytes.len() as u16 - 1; // 3. Set the end address of the transmit buffer self.write_control_register(bank0::Register::ETXNDL, txnd.low()); self.write_control_register(bank0::Register::ETXNDH, txnd.high()); // 4. reset interrupt flag //self.bit_field_clear(common::Register::EIR, common::EIR::mask().txif()); // 5. start transmission self.bit_field_set(common::Register::ECON1, common::ECON1::mask().txrts()); // Wait until transmission finishes //while common::ECON1(self.read_control_register(common::Register::ECON1)).txrts() == 1 {} /* // read the transmit status vector let mut tx_stat = [0; 7]; self.read_buffer_memory(None, &mut tx_stat); let stat = common::ESTAT(self.read_control_register(common::Register::ESTAT)); if stat.txabrt() == 1 { // work around errata #12 by reading the transmit status vector if stat.latecol() == 1 || (tx_stat[2] & (1 << 5)) != 0 { panic!("LateCollision") } else { panic!("TransmitAbort") } }*/ } /// Get whether the link is up pub fn is_link_up(&mut self) -> bool { let bits = self.read_phy_register(phy::Register::PHSTAT2); phy::PHSTAT2(bits).lstat() == 1 } /// Returns the interface Maximum Transmission Unit (MTU) /// /// The value returned by this function will never exceed 1514 bytes. The actual value depends /// on the memory assigned to the transmission buffer when initializing the device pub fn mtu(&self) -> u16 { cmp::min(BUF_SZ - RXND - 1, MAX_FRAME_LENGTH - CRC_SZ) } /* Miscellaneous */ /// Returns the number of packets that have been received but have not been processed yet pub fn pending_packets(&mut self) -> u8 { self.read_control_register(bank1::Register::EPKTCNT) } /// Adjusts the receive filter to *accept* these packet types pub fn accept(&mut self, packets: &[Packet]) { let mask = bank1::ERXFCON::mask(); let mut val = 0; for packet in packets { match packet { Packet::Broadcast => val |= mask.bcen(), Packet::Multicast => val |= mask.mcen(), Packet::Unicast => val |= mask.ucen(), } } self.bit_field_set(bank1::Register::ERXFCON, val) } /// Adjusts the receive filter to *ignore* these packet types pub fn ignore(&mut self, packets: &[Packet]) { let mask = bank1::ERXFCON::mask(); let mut val = 0; for packet in packets { match packet { Packet::Broadcast => val |= mask.bcen(), Packet::Multicast => val |= mask.mcen(), Packet::Unicast => val |= mask.ucen(), } } self.bit_field_clear(bank1::Register::ERXFCON, val) } /* Private */ /* Read */ fn read_control_register(&mut self, register: R) -> u8 where R: Into, { self._read_control_register(register.into()) } fn _read_control_register(&mut self, register: Register) -> u8 { self.change_bank(register); if register.is_eth_register() { let mut buffer = [Instruction::RCR.opcode() | register.addr(), 0]; self.spi.transfer_in_place(&mut buffer).unwrap(); buffer[1] } else { // MAC, MII regs need a dummy byte. let mut buffer = [Instruction::RCR.opcode() | register.addr(), 0, 0]; self.spi.transfer_in_place(&mut buffer).unwrap(); buffer[2] } } fn read_phy_register(&mut self, register: phy::Register) -> u16 { // set PHY register address self.write_control_register(bank2::Register::MIREGADR, register.addr()); // start read operation self.write_control_register(bank2::Register::MICMD, bank2::MICMD::default().miird(1).bits()); // wait until the read operation finishes while self.read_control_register(bank3::Register::MISTAT) & 0b1 != 0 {} self.write_control_register(bank2::Register::MICMD, bank2::MICMD::default().miird(0).bits()); let l = self.read_control_register(bank2::Register::MIRDL); let h = self.read_control_register(bank2::Register::MIRDH); (l as u16) | (h as u16) << 8 } /* Write */ fn _write_control_register(&mut self, register: Register, value: u8) { self.change_bank(register); let buffer = [Instruction::WCR.opcode() | register.addr(), value]; self.spi.write(&buffer).unwrap(); } fn write_control_register(&mut self, register: R, value: u8) where R: Into, { self._write_control_register(register.into(), value) } fn write_phy_register(&mut self, register: phy::Register, value: u16) { // set PHY register address self.write_control_register(bank2::Register::MIREGADR, register.addr()); self.write_control_register(bank2::Register::MIWRL, (value & 0xff) as u8); // this starts the write operation self.write_control_register(bank2::Register::MIWRH, (value >> 8) as u8); // wait until the write operation finishes while self.read_control_register(bank3::Register::MISTAT) & 0b1 != 0 {} } /* RMW */ fn modify_control_register(&mut self, register: R, f: F) where F: FnOnce(u8) -> u8, R: Into, { self._modify_control_register(register.into(), f) } fn _modify_control_register(&mut self, register: Register, f: F) where F: FnOnce(u8) -> u8, { let r = self._read_control_register(register); self._write_control_register(register, f(r)) } /* Auxiliary */ fn change_bank(&mut self, register: Register) { let bank = register.bank(); if let Some(bank) = bank { if self.bank == bank { // already on the register bank return; } // change bank self.bank = bank; match bank { Bank::Bank0 => self.bit_field_clear(common::Register::ECON1, 0b11), Bank::Bank1 => self.modify_control_register(common::Register::ECON1, |r| (r & !0b11) | 0b01), Bank::Bank2 => self.modify_control_register(common::Register::ECON1, |r| (r & !0b11) | 0b10), Bank::Bank3 => self.bit_field_set(common::Register::ECON1, 0b11), } } else { // common register } } /* Primitive operations */ fn bit_field_clear(&mut self, register: R, mask: u8) where R: Into, { self._bit_field_clear(register.into(), mask) } fn _bit_field_clear(&mut self, register: Register, mask: u8) { debug_assert!(register.is_eth_register()); self.change_bank(register); self.spi .write(&[Instruction::BFC.opcode() | register.addr(), mask]) .unwrap(); } fn bit_field_set(&mut self, register: R, mask: u8) where R: Into, { self._bit_field_set(register.into(), mask) } fn _bit_field_set(&mut self, register: Register, mask: u8) { debug_assert!(register.is_eth_register()); self.change_bank(register); self.spi .write(&[Instruction::BFS.opcode() | register.addr(), mask]) .unwrap(); } fn read_buffer_memory(&mut self, addr: Option, buf: &mut [u8]) { if let Some(addr) = addr { self.write_control_register(bank0::Register::ERDPTL, addr.low()); self.write_control_register(bank0::Register::ERDPTH, addr.high()); } self.spi .transaction(&mut [Operation::Write(&[Instruction::RBM.opcode()]), Operation::Read(buf)]) .unwrap(); } fn soft_reset(&mut self) { self.spi.write(&[Instruction::SRC.opcode()]).unwrap(); } fn write_buffer_memory(&mut self, addr: Option, buffer: &[u8]) { if let Some(addr) = addr { self.write_control_register(bank0::Register::EWRPTL, addr.low()); self.write_control_register(bank0::Register::EWRPTH, addr.high()); } self.spi .transaction(&mut [Operation::Write(&[Instruction::WBM.opcode()]), Operation::Write(buffer)]) .unwrap(); } } #[derive(Clone, Copy, PartialEq)] enum Bank { Bank0, Bank1, Bank2, Bank3, } #[derive(Clone, Copy)] enum Instruction { /// Read Control Register RCR = 0b000_00000, /// Read Buffer Memory RBM = 0b001_11010, /// Write Control Register WCR = 0b010_00000, /// Write Buffer Memory WBM = 0b011_11010, /// Bit Field Set BFS = 0b100_00000, /// Bit Field Clear BFC = 0b101_00000, /// System Reset Command SRC = 0b111_11111, } impl Instruction { fn opcode(&self) -> u8 { *self as u8 } } #[derive(Clone, Copy)] enum Register { Bank0(bank0::Register), Bank1(bank1::Register), Bank2(bank2::Register), Bank3(bank3::Register), Common(common::Register), } impl Register { fn addr(&self) -> u8 { match *self { Register::Bank0(r) => r.addr(), Register::Bank1(r) => r.addr(), Register::Bank2(r) => r.addr(), Register::Bank3(r) => r.addr(), Register::Common(r) => r.addr(), } } fn bank(&self) -> Option { Some(match *self { Register::Bank0(_) => Bank::Bank0, Register::Bank1(_) => Bank::Bank1, Register::Bank2(_) => Bank::Bank2, Register::Bank3(_) => Bank::Bank3, Register::Common(_) => return None, }) } fn is_eth_register(&self) -> bool { match *self { Register::Bank0(r) => r.is_eth_register(), Register::Bank1(r) => r.is_eth_register(), Register::Bank2(r) => r.is_eth_register(), Register::Bank3(r) => r.is_eth_register(), Register::Common(r) => r.is_eth_register(), } } } /// Packet type, used to configure receive filters #[non_exhaustive] #[derive(Clone, Copy, Eq, PartialEq)] pub enum Packet { /// Broadcast packets Broadcast, /// Multicast packets Multicast, /// Unicast packets Unicast, } static mut TX_BUF: [u8; MTU] = [0; MTU]; static mut RX_BUF: [u8; MTU] = [0; MTU]; impl embassy_net_driver::Driver for Enc28j60 where S: SpiDevice, O: OutputPin, { type RxToken<'a> = RxToken<'a> where Self: 'a; type TxToken<'a> = TxToken<'a, S, O> where Self: 'a; fn receive(&mut self, cx: &mut core::task::Context) -> Option<(Self::RxToken<'_>, Self::TxToken<'_>)> { let rx_buf = unsafe { &mut RX_BUF }; let tx_buf = unsafe { &mut TX_BUF }; if let Some(n) = self.receive(rx_buf) { Some((RxToken { buf: &mut rx_buf[..n] }, TxToken { buf: tx_buf, eth: self })) } else { cx.waker().wake_by_ref(); None } } fn transmit(&mut self, _cx: &mut core::task::Context) -> Option> { let tx_buf = unsafe { &mut TX_BUF }; Some(TxToken { buf: tx_buf, eth: self }) } fn link_state(&mut self, cx: &mut core::task::Context) -> LinkState { cx.waker().wake_by_ref(); match self.is_link_up() { true => LinkState::Up, false => LinkState::Down, } } fn capabilities(&self) -> Capabilities { let mut caps = Capabilities::default(); caps.max_transmission_unit = MTU; caps } fn hardware_address(&self) -> HardwareAddress { HardwareAddress::Ethernet(self.mac_addr) } } /// embassy-net RX token. pub struct RxToken<'a> { buf: &'a mut [u8], } impl<'a> embassy_net_driver::RxToken for RxToken<'a> { fn consume(self, f: F) -> R where F: FnOnce(&mut [u8]) -> R, { f(self.buf) } } /// embassy-net TX token. pub struct TxToken<'a, S, O> where S: SpiDevice, O: OutputPin, { eth: &'a mut Enc28j60, buf: &'a mut [u8], } impl<'a, S, O> embassy_net_driver::TxToken for TxToken<'a, S, O> where S: SpiDevice, O: OutputPin, { fn consume(self, len: usize, f: F) -> R where F: FnOnce(&mut [u8]) -> R, { assert!(len <= self.buf.len()); let r = f(&mut self.buf[..len]); self.eth.transmit(&self.buf[..len]); r } }