cxp protocol: init

testing: add packet printing helper function testing: add rx loopback proto FW: use memory buffer for tx and rx proto FW: use byteoder crate to handle endianness proto FW: add event packet reader and writer proto FW: add error correction for 4x char
2024-09-12 12:20:21 +08:00 · 2024-09-12 12:20:21 +08:00 · a3ace6ff0c
parent 0c83810519
commit a3ace6ff0c
1 changed files with 606 additions and 0 deletions
--- a/src/libboard_artiq/src/cxp_proto.rs
+++ b/src/libboard_artiq/src/cxp_proto.rs
@ -0,0 +1,606 @@
 use core::slice;
 use byteorder::{ByteOrder, NetworkEndian};
 use core_io::{Error as IoError, Read, Write};
 use crc::crc32::checksum_ieee;
 use io::Cursor;
 use libboard_zynq::println;
 use crate::{mem::mem::{CXP_LOOPBACK_MEM, CXP_RX_MEM, CXP_TX_MEM},
            pl::csr::CXP};
 const BUF_LEN: usize = 0x800;
 const DATA_MAXSIZE: usize = 48;
 const EV_MAXSIZE: usize = 253;
 #[derive(Debug)]
 pub enum Error {
    BufferError,
    CorruptedPacket,
    CtrlAckError(u8),
    LinkDown,
    UnknownPacket(u8),
 }
 impl From<IoError> for Error {
    fn from(_: IoError) -> Error {
        Error::BufferError
    }
 }
 // Section 9.2.2.2 (CXP-001-2021)
 // Only Control packet need CRC32 appended in the end of the packet
 // CoaXpress use the polynomial of IEEE-802.3 (Ethernet) CRC but the checksum calculation is different
 fn get_cxp_crc(bytes: &[u8]) -> u32 {
    (!checksum_ieee(bytes)).swap_bytes()
 }
 trait CxpRead {
    fn read_u8(&mut self) -> Result<u8, Error>;
    fn read_u16(&mut self) -> Result<u16, Error>;
    fn read_u32(&mut self) -> Result<u32, Error>;
    fn read_u64(&mut self) -> Result<u64, Error>;
    fn read_exact_4x(&mut self, buf: &mut [u8]) -> Result<(), Error>;
    fn read_4x_u8(&mut self) -> Result<u8, Error>;
    fn read_4x_u16(&mut self) -> Result<u16, Error>;
    fn read_4x_u32(&mut self) -> Result<u32, Error>;
    fn read_4x_u64(&mut self) -> Result<u64, Error>;
 }
 impl<Cursor: Read> CxpRead for Cursor {
    fn read_u8(&mut self) -> Result<u8, Error> {
        let mut bytes = [0; 1];
        self.read_exact(&mut bytes)?;
        Ok(bytes[0])
    }
    fn read_u16(&mut self) -> Result<u16, Error> {
        let mut bytes = [0; 2];
        self.read_exact(&mut bytes)?;
        Ok(NetworkEndian::read_u16(&bytes))
    }
    fn read_u32(&mut self) -> Result<u32, Error> {
        let mut bytes = [0; 4];
        self.read_exact(&mut bytes)?;
        Ok(NetworkEndian::read_u32(&bytes))
    }
    fn read_u64(&mut self) -> Result<u64, Error> {
        let mut bytes = [0; 8];
        self.read_exact(&mut bytes)?;
        Ok(NetworkEndian::read_u64(&bytes))
    }
    fn read_exact_4x(&mut self, buf: &mut [u8]) -> Result<(), Error> {
        for byte in buf {
            // Section 9.2.2.1 (CXP-001-2021)
            // decoder should immune to single bit errors when handling 4x duplicated characters
            let a = self.read_u8()?;
            let b = self.read_u8()?;
            let c = self.read_u8()?;
            let d = self.read_u8()?;
            // vote and return majority
            *byte = a & b & c | a & b & d | a & c & d | b & c & d;
        }
        Ok(())
    }
    fn read_4x_u8(&mut self) -> Result<u8, Error> {
        let mut bytes = [0; 1];
        self.read_exact_4x(&mut bytes)?;
        Ok(bytes[0])
    }
    fn read_4x_u16(&mut self) -> Result<u16, Error> {
        let mut bytes = [0; 2];
        self.read_exact_4x(&mut bytes)?;
        Ok(NetworkEndian::read_u16(&bytes))
    }
    fn read_4x_u32(&mut self) -> Result<u32, Error> {
        let mut bytes = [0; 4];
        self.read_exact_4x(&mut bytes)?;
        Ok(NetworkEndian::read_u32(&bytes))
    }
    fn read_4x_u64(&mut self) -> Result<u64, Error> {
        let mut bytes = [0; 6];
        self.read_exact_4x(&mut bytes)?;
        Ok(NetworkEndian::read_u64(&bytes))
    }
 }
 #[derive(Debug)]
 pub enum NameSpace {
    GenICam,
    DeviceSpecific,
 }
 #[derive(Debug)]
 pub enum DownConnPacket {
    CtrlReply {
        tag: Option<u8>,
        length: u32,
        data: [u8; DATA_MAXSIZE],
    },
    CtrlDelay {
        tag: Option<u8>,
        length: u32,
        time: [u8; DATA_MAXSIZE],
    },
    CtrlAck {
        tag: Option<u8>,
    },
    Event {
        conn_id: u32,
        packet_tag: u8,
        length: u16,
        ev_size: u16,
        namespace: NameSpace,
        event_id: u16,
        timestamp: u64,
        ev: [u8; EV_MAXSIZE],
    },
 }
 impl DownConnPacket {
    pub fn read_from(reader: &mut Cursor<&mut [u8]>, packet_type: u8) -> Result<Self, Error> {
        match packet_type {
            0x03 => DownConnPacket::get_ctrl_packet(reader, false),
            0x06 => DownConnPacket::get_ctrl_packet(reader, true),
            0x07 => DownConnPacket::get_event_packet(reader),
            _ => Err(Error::UnknownPacket(packet_type)),
        }
    }
    fn get_ctrl_packet(reader: &mut Cursor<&mut [u8]>, with_tag: bool) -> Result<Self, Error> {
        let mut tag: Option<u8> = None;
        if with_tag {
            tag = Some(reader.read_4x_u8()?);
        }
        let ackcode = reader.read_4x_u8()?;
        match ackcode {
            0x00 | 0x04 => {
                let length = reader.read_u32()?;
                let mut data: [u8; DATA_MAXSIZE] = [0; DATA_MAXSIZE];
                reader.read(&mut data[0..length as usize])?;
                let checksum = get_cxp_crc(&reader.get_ref()[0..reader.position()]);
                if reader.read_u32()? != checksum {
                    return Err(Error::CorruptedPacket);
                }
                if ackcode == 0x00 {
                    return Ok(DownConnPacket::CtrlReply { tag, length, data });
                } else {
                    return Ok(DownConnPacket::CtrlDelay {
                        tag,
                        length,
                        time: data,
                    });
                }
            }
            0x01 => return Ok(DownConnPacket::CtrlAck { tag }),
            _ => return Err(Error::CtrlAckError(ackcode)),
        }
    }
    fn get_event_packet(reader: &mut Cursor<&mut [u8]>) -> Result<Self, Error> {
        let conn_id = reader.read_4x_u32()?;
        let packet_tag = reader.read_4x_u8()?;
        let length = reader.read_4x_u16()?;
        let ev_size = reader.read_u16()?;
        if ev_size + 3 != length {
            println!("length mismatch");
            return Err(Error::CorruptedPacket);
        }
        let mut bytes = [0; 2];
        reader.read_exact(&mut bytes)?;
        let namespace_bits = (bytes[0] & 0xC0) >> 6;
        let namespace = match namespace_bits {
            0 => NameSpace::GenICam,
            2 => NameSpace::DeviceSpecific,
            _ => {
                println!("namespace = {} error", namespace_bits);
                return Err(Error::CorruptedPacket);
            }
        };
        let event_id = (bytes[0] & 0xF) as u16 | (bytes[1] as u16);
        let timestamp = reader.read_u64()?;
        let mut ev: [u8; EV_MAXSIZE] = [0; EV_MAXSIZE];
        reader.read(&mut ev[0..ev_size as usize])?;
        let checksum = get_cxp_crc(&reader.get_ref()[0..reader.position()]);
        if reader.read_u32()? != checksum {
            println!("crc error");
            return Err(Error::CorruptedPacket);
        }
        Ok(DownConnPacket::Event {
            conn_id,
            packet_tag,
            length,
            ev_size,
            namespace,
            event_id,
            timestamp,
            ev,
        })
    }
 }
 pub fn receive(channel: usize) -> Result<Option<DownConnPacket>, Error> {
    unsafe {
        if (CXP[channel].downconn_pending_packet_read)() == 1 {
            let read_buffer_ptr = (CXP[channel].downconn_read_ptr_read)() as usize;
            println!("buffer ptr = {}", read_buffer_ptr);
            let ptr = (CXP_RX_MEM[channel].base + read_buffer_ptr * BUF_LEN) as *mut u32;
            let mut reader = Cursor::new(slice::from_raw_parts_mut(ptr as *mut u8, BUF_LEN));
            let packet_type = (CXP[channel].downconn_packet_type_read)();
            let packet = DownConnPacket::read_from(&mut reader, packet_type);
            println!("{:X?}", packet);
            (CXP[channel].downconn_pending_packet_write)(1);
            Ok(Some(packet?))
        } else {
            Ok(None)
        }
    }
 }
 trait CxpWrite {
    fn write_all_4x(&mut self, buf: &[u8]) -> Result<(), Error>;
    fn write_4x_u8(&mut self, value: u8) -> Result<(), Error>;
    fn write_4x_u16(&mut self, value: u16) -> Result<(), Error>;
    fn write_4x_u32(&mut self, value: u32) -> Result<(), Error>;
    fn write_4x_u64(&mut self, value: u64) -> Result<(), Error>;
    fn write_u32(&mut self, value: u32) -> Result<(), Error>;
 }
 impl<Cursor: Write> CxpWrite for Cursor {
    fn write_all_4x(&mut self, buf: &[u8]) -> Result<(), Error> {
        for byte in buf {
            self.write_all(&[*byte; 4])?;
        }
        Ok(())
    }
    fn write_4x_u8(&mut self, value: u8) -> Result<(), Error> {
        self.write_all_4x(&[value])
    }
    fn write_4x_u16(&mut self, value: u16) -> Result<(), Error> {
        let mut bytes = [0; 2];
        NetworkEndian::write_u16(&mut bytes, value);
        self.write_all_4x(&bytes)
    }
    fn write_4x_u32(&mut self, value: u32) -> Result<(), Error> {
        let mut bytes = [0; 4];
        NetworkEndian::write_u32(&mut bytes, value);
        self.write_all_4x(&bytes)
    }
    fn write_4x_u64(&mut self, value: u64) -> Result<(), Error> {
        let mut bytes = [0; 6];
        NetworkEndian::write_u64(&mut bytes, value);
        self.write_all_4x(&bytes)
    }
    fn write_u32(&mut self, value: u32) -> Result<(), Error> {
        let mut bytes = [0; 4];
        NetworkEndian::write_u32(&mut bytes, value);
        self.write_all(&bytes)?;
        Ok(())
    }
 }
 #[derive(Debug)]
 pub enum UpConnPacket {
    CtrlRead {
        tag: Option<u8>,
        addr: u32,
        length: u8,
    },
    CtrlWrite {
        tag: Option<u8>,
        addr: u32,
        length: u8,
        data: [u8; DATA_MAXSIZE],
    }, // max register size is 8 bytes
    EventAck {
        packet_tag: u8,
    },
    TestPacket,
    // DEBUG: Loopback message
    CtrlAckLoopback {
        ackcode: u8,
        length: u8,
        data: [u8; DATA_MAXSIZE],
    },
    Event {
        conn_id: u32,
        packet_tag: u8,
        length: u16,
        event_size: u16,
        namespace: u8,
        event_id: u16,
        timestamp: u64,
        data: [u8; 253],
    },
 }
 impl UpConnPacket {
    pub fn write_to(&self, writer: &mut Cursor<&mut [u8]>) -> Result<(), Error> {
        match *self {
            UpConnPacket::CtrlRead { tag, addr, length } => {
                match tag {
                    Some(t) => {
                        writer.write_4x_u8(0x05)?;
                        writer.write_4x_u8(t)?;
                    }
                    None => {
                        writer.write_4x_u8(0x02)?;
                    }
                }
                writer.write_all(&[0x00, 0x00, 0x00, length])?;
                writer.write_u32(addr)?;
                // Section 9.6.2 (CXP-001-2021)
                // only bytes after the first 4 are used in calculating the checksum
                let checksum = get_cxp_crc(&writer.get_ref()[4..writer.position()]);
                writer.write_u32(checksum)?;
            }
            UpConnPacket::CtrlWrite {
                tag,
                addr,
                length,
                data,
            } => {
                match tag {
                    Some(t) => {
                        writer.write_4x_u8(0x05)?;
                        writer.write_4x_u8(t)?;
                    }
                    None => {
                        writer.write_4x_u8(0x02)?;
                    }
                }
                writer.write_all(&[0x01, 0x00, 0x00, length])?;
                writer.write_u32(addr)?;
                writer.write_all(&data[0..length as usize])?;
                // Section 9.6.2 (CXP-001-2021)
                // only bytes after the first 4 are used in calculating the checksum
                let checksum = get_cxp_crc(&writer.get_ref()[4..writer.position()]);
                writer.write_u32(checksum)?;
            }
            UpConnPacket::EventAck { packet_tag } => {
                writer.write_4x_u8(0x08)?;
                writer.write_4x_u8(packet_tag)?;
            }
            // DEBUG: Loopback message
            UpConnPacket::CtrlAckLoopback { ackcode, length, data } => {
                writer.write_4x_u8(0x03)?;
                writer.write_4x_u8(ackcode)?;
                if ackcode == 0x00 || ackcode == 0x04 {
                    writer.write_all(&[0x00, 0x00, 0x00, length])?;
                    writer.write_all(&data[0..length as usize])?;
                }
                let checksum = get_cxp_crc(&writer.get_ref()[4..writer.position()]);
                writer.write_u32(checksum)?;
            }
            UpConnPacket::Event {
                conn_id,
                packet_tag,
                length,
                event_size,
                namespace,
                event_id,
                timestamp,
                data,
            } => {
                // event packet header
                writer.write_4x_u8(0x07)?;
                writer.write_4x_u32(conn_id)?;
                writer.write_4x_u8(packet_tag)?;
                writer.write_4x_u16(length)?;
                // event message
                let ev_size = event_size.to_be_bytes();
                let p2: u8 = ((namespace & 0b11) << 6) | ((event_id & 0xF00) >> 8) as u8;
                let p3: u8 = (event_id & 0xFF) as u8;
                writer.write_all(&[ev_size[0], ev_size[1], p2, p3])?;
                writer.write_all(&timestamp.to_be_bytes())?;
                writer.write_all(&data[0..event_size as usize])?;
                let checksum = get_cxp_crc(&writer.get_ref()[4..writer.position()]);
                writer.write_u32(checksum)?;
            }
            _ => {}
        }
        Ok(())
    }
 }
 pub fn send(channel: usize, packet: &UpConnPacket) -> Result<(), Error> {
    if unsafe { (CXP[channel].upconn_tx_enable_read)() } == 0 {
        Err(Error::LinkDown)?
    }
    match *packet {
        UpConnPacket::TestPacket => send_test_packet(channel),
        _ => send_data_packet(channel, packet),
    }
 }
 fn send_data_packet(channel: usize, packet: &UpConnPacket) -> Result<(), Error> {
    unsafe {
        while (CXP[channel].upconn_bootstrap_tx_busy_read)() == 1 {}
        let ptr = CXP_TX_MEM[0].base as *mut u32;
        let mut writer = Cursor::new(slice::from_raw_parts_mut(ptr as *mut u8, BUF_LEN));
        packet.write_to(&mut writer)?;
        (CXP[channel].upconn_bootstrap_tx_word_len_write)(writer.position() as u16 / 4);
        (CXP[channel].upconn_bootstrap_tx_write)(1);
    }
    Ok(())
 }
 fn send_test_packet(channel: usize) -> Result<(), Error> {
    unsafe {
        while (CXP[channel].upconn_bootstrap_tx_busy_read)() == 1 {}
        (CXP[channel].upconn_bootstrap_tx_testseq_write)(1);
    }
    Ok(())
 }
 pub fn write_u32(channel: u8, addr: u32, val: u32) -> Result<(), Error> {
    // TODO: add tags after connection & verify it's CXPv2
    let mut data: [u8; DATA_MAXSIZE] = [0; DATA_MAXSIZE];
    NetworkEndian::write_u32(&mut data[..4], val);
    send(
        channel as usize,
        &UpConnPacket::CtrlWrite {
            tag: None,
            addr,
            length: 4,
            data,
        },
    )?;
    Ok(())
 }
 pub fn read_u32(channel: u8, addr: u32) -> Result<(), Error> {
    // TODO: add tags after connection & verify it's CXPv2
    send(
        channel as usize,
        &UpConnPacket::CtrlRead {
            tag: None,
            addr,
            length: 4,
        },
    )?;
    Ok(())
 }
 // pub fn write_u64(channel: usize, addr: u32, data: u64) -> Result<(), Error> {
 //     let mut data_slice: [u8; DATA_MAXSIZE] = [0; DATA_MAXSIZE];
 //     data_slice[..8].clone_from_slice(&data.to_be_bytes());
 //     send(
 //         channel,
 //         &UpConnPacket::CtrlWrite {
 //             tag: None,
 //             addr,
 //             length: 8,
 //             data: data_slice,
 //         },
 //     )?;
 //     Ok(())
 // }
 //
 // DEBUG: use only
 //
 //
 //
 pub fn print_packet(pak: &[u8]) {
    println!("pak = [");
    for i in 0..(pak.len() / 4) {
        println!(
            "{:#03}     {:#04X} {:#04X} {:#04X} {:#04X},",
            i + 1,
            pak[i * 4],
            pak[i * 4 + 1],
            pak[i * 4 + 2],
            pak[i * 4 + 3]
        )
    }
    println!("]");
    println!("============================================");
 }
 pub fn print_packetu32(pak: &[u32], k: &[u8]) {
    println!("pak = [");
    for i in 0..(pak.len()) {
        let data: [u8; 4] = pak[i].to_le_bytes();
        println!(
            "{:#03}     {:#04X} {:#04X} {:#04X} {:#04X} | K {:04b},",
            i + 1,
            data[0],
            data[1],
            data[2],
            data[3],
            k[i],
        )
    }
    println!("]");
    println!("============================================");
 }
 pub fn downconn_debug_send(channel: usize, packet: &UpConnPacket) -> Result<(), Error> {
    unsafe {
        while (CXP[channel].downconn_bootstrap_loopback_tx_busy_read)() == 1 {}
        let ptr = CXP_LOOPBACK_MEM[0].base as *mut u32;
        let mut writer = Cursor::new(slice::from_raw_parts_mut(ptr as *mut u8, BUF_LEN));
        packet.write_to(&mut writer)?;
        (CXP[channel].downconn_bootstrap_loopback_tx_word_len_write)(writer.position() as u16 / 4);
        (CXP[channel].downconn_bootstrap_loopback_tx_write)(1);
    }
    Ok(())
 }
 pub fn downconn_debug_mem_print(channel: usize) {
    unsafe {
        let ptr = CXP_RX_MEM[channel].base as *mut u32;
        let arr = slice::from_raw_parts_mut(ptr as *mut u8, BUF_LEN * 4);
        print_packet(arr);
    }
 }
 pub fn downconn_debug_send_trig_ack(channel: usize) {
    unsafe {
        (CXP[channel].downconn_ack_write)(1);
    }
 }
 pub fn downconn_send_test_packet(channel: usize) {
    unsafe {
        while (CXP[channel].downconn_bootstrap_loopback_tx_busy_read)() == 1 {}
        (CXP[channel].downconn_bootstrap_loopback_tx_testseq_write)(1);
    }
 }