use embedded_hal_async::spi::SpiDevice;
use crate::socket;
use crate::spi::SpiInterface;
pub const MODE: u16 = 0x00;
pub const MAC: u16 = 0x09;
pub const SOCKET_INTR: u16 = 0x18;
pub const PHY_CFG: u16 = 0x2E;
#[repr(u8)]
pub enum RegisterBlock {
Common = 0x00,
Socket0 = 0x01,
TxBuf = 0x02,
RxBuf = 0x03,
}
/// W5500 in MACRAW mode
#[derive(Debug)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub struct W5500<SPI> {
bus: SpiInterface<SPI>,
}
impl<SPI: SpiDevice> W5500<SPI> {
/// Create and initialize the W5500 driver
pub async fn new(spi: SPI, mac_addr: [u8; 6]) -> Result<W5500<SPI>, SPI::Error> {
let mut bus = SpiInterface(spi);
// Reset device
bus.write_frame(RegisterBlock::Common, MODE, &[0x80]).await?;
// Enable interrupt pin
bus.write_frame(RegisterBlock::Common, SOCKET_INTR, &[0x01]).await?;
// Enable receive interrupt
bus.write_frame(
RegisterBlock::Socket0,
socket::SOCKET_INTR_MASK,
&[socket::Interrupt::Receive as u8],
)
.await?;
// Set MAC address
bus.write_frame(RegisterBlock::Common, MAC, &mac_addr).await?;
// Set the raw socket RX/TX buffer sizes to 16KB
bus.write_frame(RegisterBlock::Socket0, socket::TXBUF_SIZE, &[16])
.await?;
bus.write_frame(RegisterBlock::Socket0, socket::RXBUF_SIZE, &[16])
.await?;
// MACRAW mode with MAC filtering.
let mode: u8 = (1 << 2) | (1 << 7);
bus.write_frame(RegisterBlock::Socket0, socket::MODE, &[mode]).await?;
socket::command(&mut bus, socket::Command::Open).await?;
Ok(Self { bus })
}
/// Read bytes from the RX buffer. Returns the number of bytes read.
async fn read_bytes(&mut self, buffer: &mut [u8], offset: u16) -> Result<usize, SPI::Error> {
let rx_size = socket::get_rx_size(&mut self.bus).await? as usize;
let read_buffer = if rx_size > buffer.len() + offset as usize {
buffer
} else {
&mut buffer[..rx_size - offset as usize]
};
let read_ptr = socket::get_rx_read_ptr(&mut self.bus).await?.wrapping_add(offset);
self.bus.read_frame(RegisterBlock::RxBuf, read_ptr, read_buffer).await?;
socket::set_rx_read_ptr(&mut self.bus, read_ptr.wrapping_add(read_buffer.len() as u16)).await?;
Ok(read_buffer.len())
}
/// Read an ethernet frame from the device. Returns the number of bytes read.
pub async fn read_frame(&mut self, frame: &mut [u8]) -> Result<usize, SPI::Error> {
let rx_size = socket::get_rx_size(&mut self.bus).await? as usize;
if rx_size == 0 {
return Ok(0);
}
socket::reset_interrupt(&mut self.bus, socket::Interrupt::Receive).await?;
// First two bytes gives the size of the received ethernet frame
let expected_frame_size: usize = {
let mut frame_bytes = [0u8; 2];
assert!(self.read_bytes(&mut frame_bytes[..], 0).await? == 2);
u16::from_be_bytes(frame_bytes) as usize - 2
};
// Read the ethernet frame
let read_buffer = if frame.len() > expected_frame_size {
&mut frame[..expected_frame_size]
} else {
frame
};
let recvd_frame_size = self.read_bytes(read_buffer, 2).await?;
// Register RX as completed
socket::command(&mut self.bus, socket::Command::Receive).await?;
// If the whole frame wasn't read, drop it
if recvd_frame_size < expected_frame_size {
Ok(0)
} else {
Ok(recvd_frame_size)
}
}
/// Write an ethernet frame to the device. Returns number of bytes written
pub async fn write_frame(&mut self, frame: &[u8]) -> Result<usize, SPI::Error> {
while socket::get_tx_free_size(&mut self.bus).await? < frame.len() as u16 {}
let write_ptr = socket::get_tx_write_ptr(&mut self.bus).await?;
self.bus.write_frame(RegisterBlock::TxBuf, write_ptr, frame).await?;
socket::set_tx_write_ptr(&mut self.bus, write_ptr.wrapping_add(frame.len() as u16)).await?;
socket::command(&mut self.bus, socket::Command::Send).await?;
Ok(frame.len())
}
pub async fn is_link_up(&mut self) -> bool {
let mut link = [0];
self.bus
.read_frame(RegisterBlock::Common, PHY_CFG, &mut link)
.await
.ok();
link[0] & 1 == 1
}
}