#[cfg(feature = "alloc")] use alloc::vec::Vec; #[cfg(feature = "alloc")] use hashbrown::HashSet; use spacepackets::PacketId; use crate::tmtc::ReceivesTcCore; pub trait PacketIdLookup { fn validate(&self, packet_id: u16) -> bool; } #[cfg(feature = "alloc")] impl PacketIdLookup for Vec { fn validate(&self, packet_id: u16) -> bool { self.contains(&packet_id) } } #[cfg(feature = "alloc")] impl PacketIdLookup for HashSet { fn validate(&self, packet_id: u16) -> bool { self.contains(&packet_id) } } impl PacketIdLookup for [u16] { fn validate(&self, packet_id: u16) -> bool { self.binary_search(&packet_id).is_ok() } } #[cfg(feature = "alloc")] impl PacketIdLookup for Vec { fn validate(&self, packet_id: u16) -> bool { self.contains(&PacketId::from(packet_id)) } } #[cfg(feature = "alloc")] impl PacketIdLookup for HashSet { fn validate(&self, packet_id: u16) -> bool { self.contains(&PacketId::from(packet_id)) } } impl PacketIdLookup for [PacketId] { fn validate(&self, packet_id: u16) -> bool { self.binary_search(&PacketId::from(packet_id)).is_ok() } } /// This function parses a given buffer for tightly packed CCSDS space packets. It uses the /// [PacketId] field of the CCSDS packets to detect the start of a CCSDS space packet and then /// uses the length field of the packet to extract CCSDS packets. /// /// This function is also able to deal with broken tail packets at the end as long a the parser /// can read the full 6 bytes which constitue a space packet header. If broken tail packets are /// detected, they are moved to the front of the buffer, and the write index for future write /// operations will be written to the `next_write_idx` argument. /// /// The parser will write all packets which were decoded successfully to the given `tc_receiver` /// and return the number of packets found. If the [ReceivesTcCore::pass_tc] calls fails, the /// error will be returned. pub fn parse_buffer_for_ccsds_space_packets( buf: &mut [u8], packet_id_lookup: &(impl PacketIdLookup + ?Sized), tc_receiver: &mut impl ReceivesTcCore, next_write_idx: &mut usize, ) -> Result { let mut packets_found = 0; let mut current_idx = 0; let buf_len = buf.len(); loop { if current_idx + 7 >= buf.len() { break; } let packet_id = u16::from_be_bytes(buf[current_idx..current_idx + 2].try_into().unwrap()); if packet_id_lookup.validate(packet_id) { let length_field = u16::from_be_bytes(buf[current_idx + 4..current_idx + 6].try_into().unwrap()); let packet_size = length_field + 7; if (current_idx + packet_size as usize) < buf_len { tc_receiver.pass_tc(&buf[current_idx..current_idx + packet_size as usize])?; packets_found += 1; } else { // Move packet to start of buffer if applicable. if current_idx > 0 { buf.copy_within(current_idx.., 0); *next_write_idx = current_idx; } } current_idx += packet_size as usize; continue; } current_idx += 1; } Ok(packets_found) } #[cfg(test)] mod tests { use spacepackets::{ ecss::{tc::PusTcCreator, SerializablePusPacket}, PacketId, SpHeader, }; use crate::encoding::tests::TcCacher; use super::parse_buffer_for_ccsds_space_packets; const TEST_APID_0: u16 = 0x02; const TEST_APID_1: u16 = 0x10; const TEST_PACKET_ID_0: PacketId = PacketId::const_tc(true, TEST_APID_0); const TEST_PACKET_ID_1: PacketId = PacketId::const_tc(true, TEST_APID_1); #[test] fn test_basic() { let mut sph = SpHeader::tc_unseg(TEST_APID_0, 0, 0).unwrap(); let ping_tc = PusTcCreator::new_simple(&mut sph, 17, 1, None, true); let mut buffer: [u8; 32] = [0; 32]; let packet_len = ping_tc .write_to_bytes(&mut buffer) .expect("writing packet failed"); let valid_packet_ids = [TEST_PACKET_ID_0]; let mut tc_cacher = TcCacher::default(); let mut next_write_idx = 0; let parse_result = parse_buffer_for_ccsds_space_packets( &mut buffer, valid_packet_ids.as_slice(), &mut tc_cacher, &mut next_write_idx, ); assert!(parse_result.is_ok()); let parsed_packets = parse_result.unwrap(); assert_eq!(parsed_packets, 1); assert_eq!(tc_cacher.tc_queue.len(), 1); assert_eq!( tc_cacher.tc_queue.pop_front().unwrap(), buffer[..packet_len] ); } #[test] fn test_multi_packet() { let mut sph = SpHeader::tc_unseg(TEST_APID_0, 0, 0).unwrap(); let ping_tc = PusTcCreator::new_simple(&mut sph, 17, 1, None, true); let action_tc = PusTcCreator::new_simple(&mut sph, 8, 0, None, true); let mut buffer: [u8; 32] = [0; 32]; let packet_len_ping = ping_tc .write_to_bytes(&mut buffer) .expect("writing packet failed"); let packet_len_action = action_tc .write_to_bytes(&mut buffer[packet_len_ping..]) .expect("writing packet failed"); let valid_packet_ids = [TEST_PACKET_ID_0]; let mut tc_cacher = TcCacher::default(); let mut next_write_idx = 0; let parse_result = parse_buffer_for_ccsds_space_packets( &mut buffer, valid_packet_ids.as_slice(), &mut tc_cacher, &mut next_write_idx, ); assert!(parse_result.is_ok()); let parsed_packets = parse_result.unwrap(); assert_eq!(parsed_packets, 2); assert_eq!(tc_cacher.tc_queue.len(), 2); assert_eq!( tc_cacher.tc_queue.pop_front().unwrap(), buffer[..packet_len_ping] ); assert_eq!( tc_cacher.tc_queue.pop_front().unwrap(), buffer[packet_len_ping..packet_len_ping + packet_len_action] ); } #[test] fn test_multi_apid() { let mut sph = SpHeader::tc_unseg(TEST_APID_0, 0, 0).unwrap(); let ping_tc = PusTcCreator::new_simple(&mut sph, 17, 1, None, true); sph = SpHeader::tc_unseg(TEST_APID_1, 0, 0).unwrap(); let action_tc = PusTcCreator::new_simple(&mut sph, 8, 0, None, true); let mut buffer: [u8; 32] = [0; 32]; let packet_len_ping = ping_tc .write_to_bytes(&mut buffer) .expect("writing packet failed"); let packet_len_action = action_tc .write_to_bytes(&mut buffer[packet_len_ping..]) .expect("writing packet failed"); let valid_packet_ids = [TEST_PACKET_ID_0, TEST_PACKET_ID_1]; let mut tc_cacher = TcCacher::default(); let mut next_write_idx = 0; let parse_result = parse_buffer_for_ccsds_space_packets( &mut buffer, valid_packet_ids.as_slice(), &mut tc_cacher, &mut next_write_idx, ); assert!(parse_result.is_ok()); let parsed_packets = parse_result.unwrap(); assert_eq!(parsed_packets, 2); assert_eq!(tc_cacher.tc_queue.len(), 2); assert_eq!( tc_cacher.tc_queue.pop_front().unwrap(), buffer[..packet_len_ping] ); assert_eq!( tc_cacher.tc_queue.pop_front().unwrap(), buffer[packet_len_ping..packet_len_ping + packet_len_action] ); } #[test] fn test_split_packet() { } }