//! # PUS Service 1 Verification Module //! //! This module allows packaging and sending PUS Service 1 packets. It is conforming to section //! 8 of the PUS standard ECSS-E-ST-70-41C. //! //! The core object to report TC verification progress is the [VerificationReporter]. It exposes //! an API which uses type-state programming to avoid calling the verification steps in //! an invalid order. //! //! # Examples //! //! Basic single-threaded example where a full success sequence for a given ping telecommand is //! executed. Note that the verification part could also be done in a separate thread. //! //! ``` //! use std::sync::{Arc, mpsc, RwLock}; //! use std::time::Duration; //! use satrs_core::pool::{LocalPool, PoolCfg, PoolProvider, SharedPool}; //! use satrs_core::pus::verification::{MpscVerifSender, VerificationReporterCfg, VerificationReporterWithSender}; //! use satrs_core::seq_count::SeqCountProviderSimple; //! use spacepackets::ecss::PusPacket; //! use spacepackets::SpHeader; //! use spacepackets::tc::{PusTc, PusTcSecondaryHeader}; //! use spacepackets::tm::PusTm; //! //! const EMPTY_STAMP: [u8; 7] = [0; 7]; //! const TEST_APID: u16 = 0x02; //! //! let pool_cfg = PoolCfg::new(vec![(10, 32), (10, 64), (10, 128), (10, 1024)]); //! let shared_tm_pool: SharedPool = Arc::new(RwLock::new(Box::new(LocalPool::new(pool_cfg.clone())))); //! let (verif_tx, verif_rx) = mpsc::channel(); //! let sender = MpscVerifSender::new(shared_tm_pool.clone(), verif_tx); //! let cfg = VerificationReporterCfg::new(TEST_APID, Box::new(SeqCountProviderSimple::default()), 1, 2, 8).unwrap(); //! let mut reporter = VerificationReporterWithSender::new(&cfg , Box::new(sender)); //! //! let mut sph = SpHeader::tc_unseg(TEST_APID, 0, 0).unwrap(); //! let tc_header = PusTcSecondaryHeader::new_simple(17, 1); //! let pus_tc_0 = PusTc::new(&mut sph, tc_header, None, true); //! let init_token = reporter.add_tc(&pus_tc_0); //! //! // Complete success sequence for a telecommand //! let accepted_token = reporter.acceptance_success(init_token, Some(&EMPTY_STAMP)).unwrap(); //! let started_token = reporter.start_success(accepted_token, Some(&EMPTY_STAMP)).unwrap(); //! reporter.completion_success(started_token, Some(&EMPTY_STAMP)).unwrap(); //! //! // Verify it arrives correctly on receiver end //! let mut tm_buf: [u8; 1024] = [0; 1024]; //! let mut packet_idx = 0; //! while packet_idx < 3 { //! let addr = verif_rx.recv_timeout(Duration::from_millis(10)).unwrap(); //! let tm_len; //! { //! let mut rg = shared_tm_pool.write().expect("Error locking shared pool"); //! let store_guard = rg.read_with_guard(addr); //! let slice = store_guard.read().expect("Error reading TM slice"); //! tm_len = slice.len(); //! tm_buf[0..tm_len].copy_from_slice(slice); //! } //! let (pus_tm, _) = PusTm::from_bytes(&tm_buf[0..tm_len], 7) //! .expect("Error reading verification TM"); //! if packet_idx == 0 { //! assert_eq!(pus_tm.subservice(), 1); //! } else if packet_idx == 1 { //! assert_eq!(pus_tm.subservice(), 3); //! } else if packet_idx == 2 { //! assert_eq!(pus_tm.subservice(), 7); //! } //! packet_idx += 1; //! } //! ``` //! //! The [integration test](https://egit.irs.uni-stuttgart.de/rust/fsrc-launchpad/src/branch/main/fsrc-core/tests/verification_test.rs) //! for the verification module contains examples how this module could be used in a more complex //! context involving multiple threads use crate::pus::{source_buffer_large_enough, EcssTmError, EcssTmErrorWithSend, EcssTmSenderCore}; use core::fmt::{Display, Formatter}; use core::hash::{Hash, Hasher}; use core::marker::PhantomData; use core::mem::size_of; #[cfg(feature = "alloc")] use delegate::delegate; #[cfg(feature = "serde")] use serde::{Deserialize, Serialize}; use spacepackets::ecss::EcssEnumeration; use spacepackets::tc::PusTc; use spacepackets::tm::{PusTm, PusTmSecondaryHeader}; use spacepackets::{CcsdsPacket, PacketId, PacketSequenceCtrl}; use spacepackets::{SpHeader, MAX_APID}; pub use crate::seq_count::SeqCountProviderSimple; #[cfg(feature = "alloc")] pub use alloc_mod::{ VerificationReporter, VerificationReporterCfg, VerificationReporterWithSender, }; use crate::seq_count::SequenceCountProviderCore; #[cfg(all(feature = "crossbeam", feature = "std"))] pub use stdmod::CrossbeamVerifSender; #[cfg(feature = "std")] pub use stdmod::{ MpscVerifSender, SharedStdVerifReporterWithSender, StdVerifReporterWithSender, StdVerifSenderError, }; #[derive(Debug, Eq, PartialEq, Copy, Clone)] pub enum Subservice { TmAcceptanceSuccess = 1, TmAcceptanceFailure = 2, TmStartSuccess = 3, TmStartFailure = 4, TmStepSuccess = 5, TmStepFailure = 6, TmCompletionSuccess = 7, TmCompletionFailure = 8, } impl From for u8 { fn from(enumeration: Subservice) -> Self { enumeration as u8 } } /// This is a request identifier as specified in 5.4.11.2 c. of the PUS standard /// This field equivalent to the first two bytes of the CCSDS space packet header. #[derive(Debug, Eq, Copy, Clone)] #[cfg_attr(feature = "serde", derive(Serialize, Deserialize))] pub struct RequestId { version_number: u8, packet_id: PacketId, psc: PacketSequenceCtrl, } impl Display for RequestId { fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result { write!(f, "{:#08x}", self.raw()) } } impl Hash for RequestId { fn hash(&self, state: &mut H) { self.raw().hash(state); } } // Implement manually to satisfy derive_hash_xor_eq lint impl PartialEq for RequestId { fn eq(&self, other: &Self) -> bool { self.version_number == other.version_number && self.packet_id == other.packet_id && self.psc == other.psc } } impl RequestId { pub const SIZE_AS_BYTES: usize = size_of::(); pub fn raw(&self) -> u32 { ((self.version_number as u32) << 29) | ((self.packet_id.raw() as u32) << 16) | self.psc.raw() as u32 } pub fn to_bytes(&self, buf: &mut [u8]) { let raw = self.raw(); buf.copy_from_slice(raw.to_be_bytes().as_slice()); } pub fn from_bytes(buf: &[u8]) -> Option { if buf.len() < 4 { return None; } let raw = u32::from_be_bytes(buf[0..Self::SIZE_AS_BYTES].try_into().unwrap()); Some(Self { version_number: ((raw >> 29) & 0b111) as u8, packet_id: PacketId::from(((raw >> 16) & 0xffff) as u16), psc: PacketSequenceCtrl::from((raw & 0xffff) as u16), }) } } impl RequestId { /// This allows extracting the request ID from a given PUS telecommand. pub fn new(tc: &PusTc) -> Self { RequestId { version_number: tc.ccsds_version(), packet_id: tc.packet_id(), psc: tc.psc(), } } } /// If a verification operation fails, the passed token will be returned as well. This allows /// re-trying the operation at a later point. #[derive(Debug, Clone)] pub struct VerificationOrSendErrorWithToken( pub EcssTmErrorWithSend, pub VerificationToken, ); #[derive(Debug, Clone)] pub struct VerificationErrorWithToken(pub EcssTmError, pub VerificationToken); impl From> for VerificationOrSendErrorWithToken { fn from(value: VerificationErrorWithToken) -> Self { VerificationOrSendErrorWithToken(value.0.into(), value.1) } } /// Support token to allow type-state programming. This prevents calling the verification /// steps in an invalid order. #[derive(Debug, Clone, Copy, Eq, PartialEq)] pub struct VerificationToken { state: PhantomData, req_id: RequestId, } #[derive(Copy, Clone, Debug, Eq, PartialEq)] pub struct TcStateNone; #[derive(Copy, Clone, Debug, Eq, PartialEq)] pub struct TcStateAccepted; #[derive(Copy, Clone, Debug, Eq, PartialEq)] pub struct TcStateStarted; #[derive(Debug, Eq, PartialEq)] pub enum TcStateToken { None(VerificationToken), Accepted(VerificationToken), Started(VerificationToken), } impl From> for TcStateToken { fn from(t: VerificationToken) -> Self { TcStateToken::None(t) } } impl From> for TcStateToken { fn from(t: VerificationToken) -> Self { TcStateToken::Accepted(t) } } impl From> for TcStateToken { fn from(t: VerificationToken) -> Self { TcStateToken::Started(t) } } impl VerificationToken { fn new(req_id: RequestId) -> VerificationToken { VerificationToken { state: PhantomData, req_id, } } pub fn req_id(&self) -> RequestId { self.req_id } } /// Composite helper struct to pass failure parameters to the [VerificationReporter] pub struct FailParams<'stamp, 'fargs> { time_stamp: Option<&'stamp [u8]>, failure_code: &'fargs dyn EcssEnumeration, failure_data: Option<&'fargs [u8]>, } impl<'stamp, 'fargs> FailParams<'stamp, 'fargs> { pub fn new( time_stamp: Option<&'stamp [u8]>, failure_code: &'fargs impl EcssEnumeration, failure_data: Option<&'fargs [u8]>, ) -> Self { Self { time_stamp, failure_code, failure_data, } } } /// Composite helper struct to pass step failure parameters to the [VerificationReporter] pub struct FailParamsWithStep<'stamp, 'fargs> { bp: FailParams<'stamp, 'fargs>, step: &'fargs dyn EcssEnumeration, } impl<'stamp, 'fargs> FailParamsWithStep<'stamp, 'fargs> { pub fn new( time_stamp: Option<&'stamp [u8]>, step: &'fargs impl EcssEnumeration, failure_code: &'fargs impl EcssEnumeration, failure_data: Option<&'fargs [u8]>, ) -> Self { Self { bp: FailParams::new(time_stamp, failure_code, failure_data), step, } } } #[derive(Clone)] pub struct VerificationReporterCore { pub dest_id: u16, apid: u16, } pub(crate) fn increment_seq_counter( seq_counter: Option<&(impl SequenceCountProviderCore + ?Sized)>, ) { if let Some(seq_counter) = seq_counter { seq_counter.increment(); } } pub enum VerifSuccess {} pub enum VerifFailure {} /// Abstraction for a sendable PUS TM. The user is expected to send the TM packet to a TM sink. /// /// This struct generally mutably borrows the source data buffer. pub struct VerificationSendable<'src_data, State, SuccessOrFailure> { token: Option>, pus_tm: Option>, phantom: PhantomData, } impl<'src_data, State, SuccessOrFailure> VerificationSendable<'src_data, State, SuccessOrFailure> { pub(crate) fn new(pus_tm: PusTm<'src_data>, token: VerificationToken) -> Self { Self { token: Some(token), pus_tm: Some(pus_tm), phantom: PhantomData, } } pub(crate) fn new_no_token(pus_tm: PusTm<'src_data>) -> Self { Self { token: None, pus_tm: Some(pus_tm), phantom: PhantomData, } } pub fn len_packed(&self) -> usize { self.pus_tm.as_ref().unwrap().len_packed() } pub fn pus_tm(&self) -> &PusTm<'src_data> { self.pus_tm.as_ref().unwrap() } pub fn pus_tm_mut(&mut self) -> &mut PusTm<'src_data> { self.pus_tm.as_mut().unwrap() } } impl<'src_data, State> VerificationSendable<'src_data, State, VerifFailure> { pub fn send_success_verif_failure( self, seq_counter: Option<&(impl SequenceCountProviderCore + ?Sized)>, ) { increment_seq_counter(seq_counter) } } impl<'src_data, State> VerificationSendable<'src_data, State, VerifFailure> { pub fn send_failure(self) -> (PusTm<'src_data>, VerificationToken) { (self.pus_tm.unwrap(), self.token.unwrap()) } } impl<'src_data> VerificationSendable<'src_data, TcStateNone, VerifSuccess> { pub fn send_success_acceptance_success( self, seq_counter: Option<&(impl SequenceCountProviderCore + ?Sized)>, ) -> VerificationToken { increment_seq_counter(seq_counter); VerificationToken { state: PhantomData, req_id: self.token.unwrap().req_id(), } } } impl<'src_data> VerificationSendable<'src_data, TcStateAccepted, VerifSuccess> { pub fn send_success_start_success( self, seq_counter: Option<&(impl SequenceCountProviderCore + ?Sized)>, ) -> VerificationToken { increment_seq_counter(seq_counter); VerificationToken { state: PhantomData, req_id: self.token.unwrap().req_id(), } } } impl<'src_data> VerificationSendable<'src_data, TcStateStarted, VerifSuccess> { pub fn send_success_step_or_completion_success( self, seq_counter: Option<&(impl SequenceCountProviderCore + ?Sized)>, ) { increment_seq_counter(seq_counter); } } /// Primary verification handler. It provides an API to send PUS 1 verification telemetry packets /// and verify the various steps of telecommand handling as specified in the PUS standard. /// /// This is the core component which can be used without [`alloc`] support. Please note that /// the buffer passed to the API exposes by this struct will be used to serialize the source data. /// This buffer may not be re-used to serialize the whole telemetry because that would overwrite /// the source data itself. impl VerificationReporterCore { pub fn new(apid: u16) -> Option { if apid > MAX_APID { return None; } Some(Self { apid, dest_id: 0 }) } pub fn set_apid(&mut self, apid: u16) -> bool { if apid > MAX_APID { return false; } self.apid = apid; true } pub fn apid(&self) -> u16 { self.apid } pub fn dest_id(&self) -> u16 { self.dest_id } pub fn set_dest_id(&mut self, dest_id: u16) { self.dest_id = dest_id; } /// Initialize verification handling by passing a TC reference. This returns a token required /// to call the acceptance functions pub fn add_tc(&mut self, pus_tc: &PusTc) -> VerificationToken { self.add_tc_with_req_id(RequestId::new(pus_tc)) } /// Same as [Self::add_tc] but pass a request ID instead of the direct telecommand. /// This can be useful if the executing thread does not have full access to the telecommand. pub fn add_tc_with_req_id(&mut self, req_id: RequestId) -> VerificationToken { VerificationToken::::new(req_id) } fn sendable_success_no_step<'src_data, State: Copy>( &mut self, src_data_buf: &'src_data mut [u8], subservice: u8, token: VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), time_stamp: Option<&'src_data [u8]>, ) -> Result< VerificationSendable<'src_data, State, VerifSuccess>, VerificationErrorWithToken, > { Ok(VerificationSendable::new( self.create_pus_verif_success_tm( src_data_buf, subservice, seq_counter.get(), &token.req_id, time_stamp, None::<&dyn EcssEnumeration>, ) .map_err(|e| VerificationErrorWithToken(e, token))?, token, )) } fn sendable_failure_no_step<'src_data, State: Copy>( &mut self, src_data_buf: &'src_data mut [u8], subservice: u8, token: VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), step: Option<&(impl EcssEnumeration + ?Sized)>, params: &FailParams<'src_data, '_>, ) -> Result< VerificationSendable<'src_data, State, VerifFailure>, VerificationErrorWithToken, > { Ok(VerificationSendable::new( self.create_pus_verif_fail_tm( src_data_buf, subservice, seq_counter.get(), &token.req_id, step, params, ) .map_err(|e| VerificationErrorWithToken(e, token))?, token, )) } /// Package a PUS TM\[1, 1\] packet, see 8.1.2.1 of the PUS standard. pub fn acceptance_success<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], token: VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), time_stamp: Option<&'src_data [u8]>, ) -> Result< VerificationSendable<'src_data, TcStateNone, VerifSuccess>, VerificationErrorWithToken, > { self.sendable_success_no_step( src_data_buf, Subservice::TmAcceptanceSuccess.into(), token, seq_counter, time_stamp, ) } pub fn send_acceptance_success<'src_data, E>( &self, mut sendable: VerificationSendable<'src_data, TcStateNone, VerifSuccess>, seq_counter: &(impl SequenceCountProviderCore + ?Sized), sender: &mut (impl EcssTmSenderCore + ?Sized), ) -> Result, VerificationOrSendErrorWithToken> { sender .send_tm(sendable.pus_tm.take().unwrap()) .map_err(|e| VerificationOrSendErrorWithToken(e, sendable.token.unwrap()))?; Ok(sendable.send_success_acceptance_success(Some(seq_counter))) } pub fn send_acceptance_failure<'src_data, E>( &self, mut sendable: VerificationSendable<'src_data, TcStateNone, VerifFailure>, seq_counter: &(impl SequenceCountProviderCore + ?Sized), sender: &mut (impl EcssTmSenderCore + ?Sized), ) -> Result<(), VerificationOrSendErrorWithToken> { sender .send_tm(sendable.pus_tm.take().unwrap()) .map_err(|e| VerificationOrSendErrorWithToken(e, sendable.token.unwrap()))?; sendable.send_success_verif_failure(Some(seq_counter)); Ok(()) } /// Package a PUS TM\[1, 2\] packet, see 8.1.2.2 of the PUS standard. pub fn acceptance_failure<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], token: VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), params: FailParams<'src_data, '_>, ) -> Result< VerificationSendable<'src_data, TcStateNone, VerifFailure>, VerificationErrorWithToken, > { self.sendable_failure_no_step( src_data_buf, Subservice::TmAcceptanceFailure.into(), token, seq_counter, None::<&dyn EcssEnumeration>, ¶ms, ) } /// Package and send a PUS TM\[1, 3\] packet, see 8.1.2.3 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::acceptance_success]. pub fn start_success<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], token: VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), time_stamp: Option<&'src_data [u8]>, ) -> Result< VerificationSendable<'src_data, TcStateAccepted, VerifSuccess>, VerificationErrorWithToken, > { self.sendable_success_no_step( src_data_buf, Subservice::TmStartSuccess.into(), token, seq_counter, time_stamp, ) } pub fn send_start_success<'src_data, E>( &self, mut sendable: VerificationSendable<'src_data, TcStateAccepted, VerifSuccess>, seq_counter: &(impl SequenceCountProviderCore + ?Sized), sender: &mut (impl EcssTmSenderCore + ?Sized), ) -> Result< VerificationToken, VerificationOrSendErrorWithToken, > { sender .send_tm(sendable.pus_tm.take().unwrap()) .map_err(|e| VerificationOrSendErrorWithToken(e, sendable.token.unwrap()))?; Ok(sendable.send_success_start_success(Some(seq_counter))) } /// Package and send a PUS TM\[1, 4\] packet, see 8.1.2.4 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::acceptance_success]. It consumes /// the token because verification handling is done. pub fn start_failure<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], token: VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), params: FailParams<'src_data, '_>, ) -> Result< VerificationSendable<'src_data, TcStateAccepted, VerifFailure>, VerificationErrorWithToken, > { self.sendable_failure_no_step( src_data_buf, Subservice::TmStartFailure.into(), token, seq_counter, None::<&dyn EcssEnumeration>, ¶ms, ) } pub fn send_start_failure<'src_data, E>( &self, mut sendable: VerificationSendable<'src_data, TcStateAccepted, VerifFailure>, seq_counter: &(impl SequenceCountProviderCore + ?Sized), sender: &mut (impl EcssTmSenderCore + ?Sized), ) -> Result<(), VerificationOrSendErrorWithToken> { sender .send_tm(sendable.pus_tm.take().unwrap()) .map_err(|e| VerificationOrSendErrorWithToken(e, sendable.token.unwrap()))?; sendable.send_success_verif_failure(Some(seq_counter)); Ok(()) } /// Package and send a PUS TM\[1, 5\] packet, see 8.1.2.5 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::start_success]. pub fn step_success<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], token: &VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), time_stamp: Option<&'src_data [u8]>, step: impl EcssEnumeration, ) -> Result, EcssTmError> { Ok(VerificationSendable::new_no_token( self.create_pus_verif_success_tm( src_data_buf, Subservice::TmStepSuccess.into(), seq_counter.get(), &token.req_id, time_stamp, Some(&step), )?, )) } /// Package and send a PUS TM\[1, 6\] packet, see 8.1.2.6 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::start_success]. It consumes the /// token because verification handling is done. pub fn step_failure<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], token: VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), params: FailParamsWithStep<'src_data, '_>, ) -> Result< VerificationSendable<'src_data, TcStateStarted, VerifFailure>, VerificationErrorWithToken, > { Ok(VerificationSendable::new( self.create_pus_verif_fail_tm( src_data_buf, Subservice::TmStepFailure.into(), seq_counter.get(), &token.req_id, Some(params.step), ¶ms.bp, ) .map_err(|e| VerificationErrorWithToken(e, token))?, token, )) } /// Package and send a PUS TM\[1, 7\] packet, see 8.1.2.7 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::start_success]. It consumes the /// token because verification handling is done. pub fn completion_success<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], token: VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), time_stamp: Option<&'src_data [u8]>, ) -> Result< VerificationSendable<'src_data, TcStateStarted, VerifSuccess>, VerificationErrorWithToken, > { self.sendable_success_no_step( src_data_buf, Subservice::TmCompletionSuccess.into(), token, seq_counter, time_stamp, ) } /// Package and send a PUS TM\[1, 8\] packet, see 8.1.2.8 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::start_success]. It consumes the /// token because verification handling is done. pub fn completion_failure<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], token: VerificationToken, seq_counter: &(impl SequenceCountProviderCore + ?Sized), params: FailParams<'src_data, '_>, ) -> Result< VerificationSendable<'src_data, TcStateStarted, VerifFailure>, VerificationErrorWithToken, > { self.sendable_failure_no_step( src_data_buf, Subservice::TmCompletionFailure.into(), token, seq_counter, None::<&dyn EcssEnumeration>, ¶ms, ) } pub fn send_step_or_completion_success<'src_data, E>( &self, mut sendable: VerificationSendable<'src_data, TcStateStarted, VerifSuccess>, seq_counter: &(impl SequenceCountProviderCore + ?Sized), sender: &mut (impl EcssTmSenderCore + ?Sized), ) -> Result<(), VerificationOrSendErrorWithToken> { sender .send_tm(sendable.pus_tm.take().unwrap()) .map_err(|e| VerificationOrSendErrorWithToken(e, sendable.token.unwrap()))?; sendable.send_success_step_or_completion_success(Some(seq_counter)); Ok(()) } pub fn send_step_or_completion_failure<'src_data, E>( &self, mut sendable: VerificationSendable<'src_data, TcStateStarted, VerifFailure>, seq_counter: &(impl SequenceCountProviderCore + ?Sized), sender: &mut (impl EcssTmSenderCore + ?Sized), ) -> Result<(), VerificationOrSendErrorWithToken> { sender .send_tm(sendable.pus_tm.take().unwrap()) .map_err(|e| VerificationOrSendErrorWithToken(e, sendable.token.unwrap()))?; sendable.send_success_verif_failure(Some(seq_counter)); Ok(()) } fn create_pus_verif_success_tm<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], subservice: u8, msg_counter: u16, req_id: &RequestId, time_stamp: Option<&'src_data [u8]>, step: Option<&(impl EcssEnumeration + ?Sized)>, ) -> Result, EcssTmError> { let mut source_data_len = size_of::(); if let Some(step) = step { source_data_len += step.byte_width(); } source_buffer_large_enough(src_data_buf.len(), source_data_len)?; let mut idx = 0; req_id.to_bytes(&mut src_data_buf[0..RequestId::SIZE_AS_BYTES]); idx += RequestId::SIZE_AS_BYTES; if let Some(step) = step { // Size check was done beforehand step.write_to_be_bytes(&mut src_data_buf[idx..idx + step.byte_width()]) .unwrap(); } let mut sp_header = SpHeader::tm_unseg(self.apid(), 0, 0).unwrap(); Ok(self.create_pus_verif_tm_base( src_data_buf, subservice, msg_counter, &mut sp_header, time_stamp, source_data_len, )) } fn create_pus_verif_fail_tm<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], subservice: u8, msg_counter: u16, req_id: &RequestId, step: Option<&(impl EcssEnumeration + ?Sized)>, params: &FailParams<'src_data, '_>, ) -> Result, EcssTmError> { let mut idx = 0; let mut source_data_len = RequestId::SIZE_AS_BYTES + params.failure_code.byte_width(); if let Some(step) = step { source_data_len += step.byte_width(); } if let Some(failure_data) = params.failure_data { source_data_len += failure_data.len(); } source_buffer_large_enough(src_data_buf.len(), source_data_len)?; req_id.to_bytes(&mut src_data_buf[0..RequestId::SIZE_AS_BYTES]); idx += RequestId::SIZE_AS_BYTES; if let Some(step) = step { // Size check done beforehand step.write_to_be_bytes(&mut src_data_buf[idx..idx + step.byte_width()]) .unwrap(); idx += step.byte_width(); } params .failure_code .write_to_be_bytes(&mut src_data_buf[idx..idx + params.failure_code.byte_width()])?; idx += params.failure_code.byte_width(); if let Some(failure_data) = params.failure_data { src_data_buf[idx..idx + failure_data.len()].copy_from_slice(failure_data); } let mut sp_header = SpHeader::tm_unseg(self.apid(), 0, 0).unwrap(); Ok(self.create_pus_verif_tm_base( src_data_buf, subservice, msg_counter, &mut sp_header, params.time_stamp, source_data_len, )) } fn create_pus_verif_tm_base<'src_data>( &mut self, src_data_buf: &'src_data mut [u8], subservice: u8, msg_counter: u16, sp_header: &mut SpHeader, time_stamp: Option<&'src_data [u8]>, source_data_len: usize, ) -> PusTm<'src_data> { let tm_sec_header = PusTmSecondaryHeader::new(1, subservice, msg_counter, self.dest_id, time_stamp); PusTm::new( sp_header, tm_sec_header, Some(&src_data_buf[0..source_data_len]), true, ) } } #[cfg(feature = "alloc")] mod alloc_mod { use super::*; use crate::pus::alloc_mod::EcssTmSender; use crate::seq_count::SequenceCountProvider; use alloc::boxed::Box; use alloc::vec; use alloc::vec::Vec; #[derive(Clone)] pub struct VerificationReporterCfg { apid: u16, seq_counter: Box + Send>, pub step_field_width: usize, pub fail_code_field_width: usize, pub max_fail_data_len: usize, } impl VerificationReporterCfg { pub fn new( apid: u16, seq_counter: Box + Send>, step_field_width: usize, fail_code_field_width: usize, max_fail_data_len: usize, ) -> Option { if apid > MAX_APID { return None; } Some(Self { apid, seq_counter, step_field_width, fail_code_field_width, max_fail_data_len, }) } } /// Primary verification handler. It provides an API to send PUS 1 verification telemetry packets /// and verify the various steps of telecommand handling as specified in the PUS standard. #[derive(Clone)] pub struct VerificationReporter { source_data_buf: Vec, seq_counter: Box + Send + 'static>, pub reporter: VerificationReporterCore, } impl VerificationReporter { pub fn new(cfg: &VerificationReporterCfg) -> Self { let reporter = VerificationReporterCore::new(cfg.apid).unwrap(); Self { source_data_buf: vec![ 0; RequestId::SIZE_AS_BYTES + cfg.step_field_width + cfg.fail_code_field_width + cfg.max_fail_data_len ], seq_counter: cfg.seq_counter.clone(), reporter, } } delegate!( to self.reporter { pub fn set_apid(&mut self, apid: u16) -> bool; pub fn apid(&self) -> u16; pub fn add_tc(&mut self, pus_tc: &PusTc) -> VerificationToken; pub fn add_tc_with_req_id(&mut self, req_id: RequestId) -> VerificationToken; pub fn dest_id(&self) -> u16; pub fn set_dest_id(&mut self, dest_id: u16); } ); pub fn allowed_source_data_len(&self) -> usize { self.source_data_buf.capacity() } /// Package and send a PUS TM\[1, 1\] packet, see 8.1.2.1 of the PUS standard pub fn acceptance_success( &mut self, token: VerificationToken, sender: &mut (impl EcssTmSenderCore + ?Sized), time_stamp: Option<&[u8]>, ) -> Result< VerificationToken, VerificationOrSendErrorWithToken, > { let sendable = self.reporter.acceptance_success( self.source_data_buf.as_mut_slice(), token, self.seq_counter.as_ref(), time_stamp, )?; self.reporter .send_acceptance_success(sendable, self.seq_counter.as_ref(), sender) } /// Package and send a PUS TM\[1, 2\] packet, see 8.1.2.2 of the PUS standard pub fn acceptance_failure( &mut self, token: VerificationToken, sender: &mut (impl EcssTmSenderCore + ?Sized), params: FailParams, ) -> Result<(), VerificationOrSendErrorWithToken> { let sendable = self.reporter.acceptance_failure( self.source_data_buf.as_mut_slice(), token, self.seq_counter.as_ref(), params, )?; self.reporter .send_acceptance_failure(sendable, self.seq_counter.as_ref(), sender) } /// Package and send a PUS TM\[1, 3\] packet, see 8.1.2.3 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::acceptance_success]. pub fn start_success( &mut self, token: VerificationToken, sender: &mut (impl EcssTmSenderCore + ?Sized), time_stamp: Option<&[u8]>, ) -> Result< VerificationToken, VerificationOrSendErrorWithToken, > { let sendable = self.reporter.start_success( self.source_data_buf.as_mut_slice(), token, self.seq_counter.as_mut(), time_stamp, )?; self.reporter .send_start_success(sendable, self.seq_counter.as_ref(), sender) } /// Package and send a PUS TM\[1, 4\] packet, see 8.1.2.4 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::acceptance_success]. It consumes /// the token because verification handling is done. pub fn start_failure( &mut self, token: VerificationToken, sender: &mut (impl EcssTmSenderCore + ?Sized), params: FailParams, ) -> Result<(), VerificationOrSendErrorWithToken> { let sendable = self.reporter.start_failure( self.source_data_buf.as_mut_slice(), token, self.seq_counter.as_mut(), params, )?; self.reporter .send_start_failure(sendable, self.seq_counter.as_ref(), sender) } /// Package and send a PUS TM\[1, 5\] packet, see 8.1.2.5 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::start_success]. pub fn step_success( &mut self, token: &VerificationToken, sender: &mut (impl EcssTmSenderCore + ?Sized), time_stamp: Option<&[u8]>, step: impl EcssEnumeration, ) -> Result<(), EcssTmErrorWithSend> { let sendable = self.reporter.step_success( self.source_data_buf.as_mut_slice(), token, self.seq_counter.as_mut(), time_stamp, step, )?; self.reporter .send_step_or_completion_success(sendable, self.seq_counter.as_ref(), sender) .map_err(|e| e.0) } /// Package and send a PUS TM\[1, 6\] packet, see 8.1.2.6 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::start_success]. It consumes the /// token because verification handling is done. pub fn step_failure( &mut self, token: VerificationToken, sender: &mut (impl EcssTmSenderCore + ?Sized), params: FailParamsWithStep, ) -> Result<(), VerificationOrSendErrorWithToken> { let sendable = self.reporter.step_failure( self.source_data_buf.as_mut_slice(), token, self.seq_counter.as_mut(), params, )?; self.reporter.send_step_or_completion_failure( sendable, self.seq_counter.as_ref(), sender, ) } /// Package and send a PUS TM\[1, 7\] packet, see 8.1.2.7 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::start_success]. It consumes the /// token because verification handling is done. pub fn completion_success( &mut self, token: VerificationToken, sender: &mut (impl EcssTmSenderCore + ?Sized), time_stamp: Option<&[u8]>, ) -> Result<(), VerificationOrSendErrorWithToken> { let sendable = self.reporter.completion_success( self.source_data_buf.as_mut_slice(), token, self.seq_counter.as_mut(), time_stamp, )?; self.reporter.send_step_or_completion_success( sendable, self.seq_counter.as_ref(), sender, ) } /// Package and send a PUS TM\[1, 8\] packet, see 8.1.2.8 of the PUS standard. /// /// Requires a token previously acquired by calling [Self::start_success]. It consumes the /// token because verification handling is done. pub fn completion_failure( &mut self, token: VerificationToken, sender: &mut (impl EcssTmSenderCore + ?Sized), params: FailParams, ) -> Result<(), VerificationOrSendErrorWithToken> { let sendable = self.reporter.completion_failure( self.source_data_buf.as_mut_slice(), token, self.seq_counter.as_mut(), params, )?; self.reporter.send_step_or_completion_failure( sendable, self.seq_counter.as_ref(), sender, ) } } /// Helper object which caches the sender passed as a trait object. Provides the same /// API as [VerificationReporter] but without the explicit sender arguments. #[derive(Clone)] pub struct VerificationReporterWithSender { pub reporter: VerificationReporter, pub sender: Box>, } impl VerificationReporterWithSender { pub fn new( cfg: &VerificationReporterCfg, sender: Box>, ) -> Self { let reporter = VerificationReporter::new(cfg); Self::new_from_reporter(reporter, sender) } pub fn new_from_reporter( reporter: VerificationReporter, sender: Box>, ) -> Self { Self { reporter, sender } } delegate! { to self.reporter { pub fn set_apid(&mut self, apid: u16) -> bool; pub fn apid(&self) -> u16; pub fn add_tc(&mut self, pus_tc: &PusTc) -> VerificationToken; pub fn add_tc_with_req_id(&mut self, req_id: RequestId) -> VerificationToken; pub fn dest_id(&self) -> u16; pub fn set_dest_id(&mut self, dest_id: u16); } } pub fn acceptance_success( &mut self, token: VerificationToken, time_stamp: Option<&[u8]>, ) -> Result< VerificationToken, VerificationOrSendErrorWithToken, > { self.reporter .acceptance_success(token, self.sender.as_mut(), time_stamp) } pub fn acceptance_failure( &mut self, token: VerificationToken, params: FailParams, ) -> Result<(), VerificationOrSendErrorWithToken> { self.reporter .acceptance_failure(token, self.sender.as_mut(), params) } pub fn start_success( &mut self, token: VerificationToken, time_stamp: Option<&[u8]>, ) -> Result< VerificationToken, VerificationOrSendErrorWithToken, > { self.reporter .start_success(token, self.sender.as_mut(), time_stamp) } pub fn start_failure( &mut self, token: VerificationToken, params: FailParams, ) -> Result<(), VerificationOrSendErrorWithToken> { self.reporter .start_failure(token, self.sender.as_mut(), params) } pub fn step_success( &mut self, token: &VerificationToken, time_stamp: Option<&[u8]>, step: impl EcssEnumeration, ) -> Result<(), EcssTmErrorWithSend> { self.reporter .step_success(token, self.sender.as_mut(), time_stamp, step) } pub fn step_failure( &mut self, token: VerificationToken, params: FailParamsWithStep, ) -> Result<(), VerificationOrSendErrorWithToken> { self.reporter .step_failure(token, self.sender.as_mut(), params) } pub fn completion_success( &mut self, token: VerificationToken, time_stamp: Option<&[u8]>, ) -> Result<(), VerificationOrSendErrorWithToken> { self.reporter .completion_success(token, self.sender.as_mut(), time_stamp) } pub fn completion_failure( &mut self, token: VerificationToken, params: FailParams, ) -> Result<(), VerificationOrSendErrorWithToken> { self.reporter .completion_failure(token, self.sender.as_mut(), params) } } } #[cfg(feature = "std")] mod stdmod { use super::alloc_mod::VerificationReporterWithSender; use super::*; use crate::pool::{ShareablePoolProvider, SharedPool, StoreAddr, StoreError}; use delegate::delegate; use spacepackets::tm::PusTm; use std::sync::{mpsc, Arc, Mutex, RwLockWriteGuard}; pub type StdVerifReporterWithSender = VerificationReporterWithSender; pub type SharedStdVerifReporterWithSender = Arc>; #[derive(Debug, Eq, PartialEq, Clone)] pub enum StdVerifSenderError { PoisonError, StoreError(StoreError), RxDisconnected(StoreAddr), } impl From for StdVerifSenderError { fn from(e: StoreError) -> Self { StdVerifSenderError::StoreError(e) } } impl From for EcssTmErrorWithSend { fn from(e: StoreError) -> Self { EcssTmErrorWithSend::SendError(e.into()) } } trait SendBackend: Send { fn send(&self, addr: StoreAddr) -> Result<(), StoreAddr>; } #[derive(Clone)] struct StdSenderBase { pub ignore_poison_error: bool, tm_store: SharedPool, tx: S, } impl StdSenderBase { pub fn new(tm_store: SharedPool, tx: S) -> Self { Self { ignore_poison_error: false, tm_store, tx, } } } unsafe impl Sync for StdSenderBase {} unsafe impl Send for StdSenderBase {} impl SendBackend for mpsc::Sender { fn send(&self, addr: StoreAddr) -> Result<(), StoreAddr> { self.send(addr).map_err(|_| addr) } } #[derive(Clone)] pub struct MpscVerifSender { base: StdSenderBase>, } /// Verification sender with a [mpsc::Sender] backend. /// It implements the [EcssTmSenderCore] trait to be used as PUS Verification TM sender. impl MpscVerifSender { pub fn new(tm_store: SharedPool, tx: mpsc::Sender) -> Self { Self { base: StdSenderBase::new(tm_store, tx), } } } //noinspection RsTraitImplementation impl EcssTmSenderCore for MpscVerifSender { type Error = StdVerifSenderError; delegate!( to self.base { fn send_tm(&mut self, tm: PusTm) -> Result<(), EcssTmErrorWithSend>; } ); } impl SendBackend for crossbeam_channel::Sender { fn send(&self, addr: StoreAddr) -> Result<(), StoreAddr> { self.send(addr).map_err(|_| addr) } } /// Verification sender with a [crossbeam_channel::Sender] backend. /// It implements the [EcssTmSenderCore] trait to be used as PUS Verification TM sender #[cfg(feature = "crossbeam")] #[derive(Clone)] pub struct CrossbeamVerifSender { base: StdSenderBase>, } #[cfg(feature = "crossbeam")] impl CrossbeamVerifSender { pub fn new(tm_store: SharedPool, tx: crossbeam_channel::Sender) -> Self { Self { base: StdSenderBase::new(tm_store, tx), } } } //noinspection RsTraitImplementation #[cfg(feature = "crossbeam")] impl EcssTmSenderCore for CrossbeamVerifSender { type Error = StdVerifSenderError; delegate!( to self.base { fn send_tm(&mut self, tm: PusTm) -> Result<(), EcssTmErrorWithSend>; } ); } impl EcssTmSenderCore for StdSenderBase { type Error = StdVerifSenderError; fn send_tm(&mut self, tm: PusTm) -> Result<(), EcssTmErrorWithSend> { let operation = |mut mg: RwLockWriteGuard| { let (addr, buf) = mg.free_element(tm.len_packed())?; tm.write_to_bytes(buf).map_err(EcssTmError::PusError)?; drop(mg); self.tx.send(addr).map_err(|_| { EcssTmErrorWithSend::SendError(StdVerifSenderError::RxDisconnected(addr)) })?; Ok(()) }; match self.tm_store.write() { Ok(lock) => operation(lock), Err(poison_error) => { if self.ignore_poison_error { operation(poison_error.into_inner()) } else { Err(EcssTmErrorWithSend::SendError( StdVerifSenderError::PoisonError, )) } } } } } } #[cfg(test)] mod tests { use crate::pool::{LocalPool, PoolCfg, SharedPool}; use crate::pus::tests::CommonTmInfo; use crate::pus::verification::{ EcssTmError, EcssTmSenderCore, FailParams, FailParamsWithStep, MpscVerifSender, RequestId, TcStateNone, VerificationReporter, VerificationReporterCfg, VerificationReporterWithSender, VerificationToken, }; use crate::pus::EcssTmErrorWithSend; use crate::seq_count::SeqCountProviderSimple; use alloc::boxed::Box; use alloc::format; use spacepackets::ecss::{EcssEnumU16, EcssEnumU32, EcssEnumU8, EcssEnumeration, PusPacket}; use spacepackets::tc::{PusTc, PusTcSecondaryHeader}; use spacepackets::tm::PusTm; use spacepackets::{ByteConversionError, SpHeader}; use std::collections::VecDeque; use std::sync::{mpsc, Arc, RwLock}; use std::vec; use std::vec::Vec; fn is_send(_: &T) {} #[allow(dead_code)] fn is_sync(_: &T) {} const TEST_APID: u16 = 0x02; const EMPTY_STAMP: [u8; 7] = [0; 7]; #[derive(Debug, Eq, PartialEq, Clone)] struct TmInfo { pub common: CommonTmInfo, pub req_id: RequestId, pub additional_data: Option>, } #[derive(Default, Clone)] struct TestSender { pub service_queue: VecDeque, } impl EcssTmSenderCore for TestSender { type Error = (); fn send_tm(&mut self, tm: PusTm) -> Result<(), EcssTmErrorWithSend> { assert_eq!(PusPacket::service(&tm), 1); assert!(tm.source_data().is_some()); let mut time_stamp = [0; 7]; time_stamp.clone_from_slice(&tm.timestamp().unwrap()[0..7]); let src_data = tm.source_data().unwrap(); assert!(src_data.len() >= 4); let req_id = RequestId::from_bytes(&src_data[0..RequestId::SIZE_AS_BYTES]).unwrap(); let mut vec = None; if src_data.len() > 4 { let mut new_vec = Vec::new(); new_vec.extend_from_slice(&src_data[RequestId::SIZE_AS_BYTES..]); vec = Some(new_vec); } self.service_queue.push_back(TmInfo { common: CommonTmInfo::new_from_tm(&tm), req_id, additional_data: vec, }); Ok(()) } } #[derive(Debug, Copy, Clone, Eq, PartialEq)] struct DummyError {} #[derive(Default, Clone)] struct FallibleSender {} impl EcssTmSenderCore for FallibleSender { type Error = DummyError; fn send_tm(&mut self, _: PusTm) -> Result<(), EcssTmErrorWithSend> { Err(EcssTmErrorWithSend::SendError(DummyError {})) } } struct TestBase<'a> { vr: VerificationReporter, #[allow(dead_code)] tc: PusTc<'a>, } impl<'a> TestBase<'a> { fn rep(&mut self) -> &mut VerificationReporter { &mut self.vr } } struct TestBaseWithHelper<'a, E> { helper: VerificationReporterWithSender, #[allow(dead_code)] tc: PusTc<'a>, } impl<'a, E> TestBaseWithHelper<'a, E> { fn rep(&mut self) -> &mut VerificationReporter { &mut self.helper.reporter } } fn base_reporter() -> VerificationReporter { let cfg = VerificationReporterCfg::new( TEST_APID, Box::new(SeqCountProviderSimple::default()), 1, 2, 8, ) .unwrap(); VerificationReporter::new(&cfg) } fn base_tc_init(app_data: Option<&[u8]>) -> (PusTc, RequestId) { let mut sph = SpHeader::tc_unseg(TEST_APID, 0x34, 0).unwrap(); let tc_header = PusTcSecondaryHeader::new_simple(17, 1); let pus_tc = PusTc::new(&mut sph, tc_header, app_data, true); let req_id = RequestId::new(&pus_tc); (pus_tc, req_id) } fn base_init(api_sel: bool) -> (TestBase<'static>, VerificationToken) { let mut reporter = base_reporter(); let (tc, req_id) = base_tc_init(None); let init_tok; if api_sel { init_tok = reporter.add_tc_with_req_id(req_id); } else { init_tok = reporter.add_tc(&tc); } (TestBase { vr: reporter, tc }, init_tok) } fn base_with_helper_init() -> ( TestBaseWithHelper<'static, ()>, VerificationToken, ) { let mut reporter = base_reporter(); let (tc, _) = base_tc_init(None); let init_tok = reporter.add_tc(&tc); let sender = TestSender::default(); let helper = VerificationReporterWithSender::new_from_reporter(reporter, Box::new(sender)); (TestBaseWithHelper { helper, tc }, init_tok) } fn acceptance_check(sender: &mut TestSender, req_id: &RequestId) { let cmp_info = TmInfo { common: CommonTmInfo { subservice: 1, apid: TEST_APID, msg_counter: 0, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: None, req_id: req_id.clone(), }; assert_eq!(sender.service_queue.len(), 1); let info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); } #[test] fn test_mpsc_verif_send_sync() { let pool = LocalPool::new(PoolCfg::new(vec![(8, 8)])); let shared_pool: SharedPool = Arc::new(RwLock::new(Box::new(pool))); let (tx, _) = mpsc::channel(); let mpsc_verif_sender = MpscVerifSender::new(shared_pool, tx); is_send(&mpsc_verif_sender); } #[test] fn test_state() { let (mut b, _) = base_init(false); assert_eq!(b.vr.apid(), TEST_APID); b.vr.set_apid(TEST_APID + 1); assert_eq!(b.vr.apid(), TEST_APID + 1); } #[test] fn test_basic_acceptance_success() { let (mut b, tok) = base_init(false); let mut sender = TestSender::default(); b.vr.acceptance_success(tok, &mut sender, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); acceptance_check(&mut sender, &tok.req_id); } #[test] fn test_basic_acceptance_success_with_helper() { let (mut b, tok) = base_with_helper_init(); b.helper .acceptance_success(tok, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let sender: &mut TestSender = b.helper.sender.downcast_mut().unwrap(); acceptance_check(sender, &tok.req_id); } #[test] fn test_acceptance_send_fails() { let (mut b, tok) = base_init(false); let mut faulty_sender = FallibleSender::default(); let res = b.vr.acceptance_success(tok, &mut faulty_sender, Some(&EMPTY_STAMP)); assert!(res.is_err()); let err = res.unwrap_err(); assert_eq!(err.1, tok); match err.0 { EcssTmErrorWithSend::SendError(e) => { assert_eq!(e, DummyError {}) } _ => panic!("{}", format!("Unexpected error {:?}", err.0)), } } fn acceptance_fail_check(sender: &mut TestSender, req_id: RequestId, stamp_buf: [u8; 7]) { let cmp_info = TmInfo { common: CommonTmInfo { subservice: 2, apid: TEST_APID, msg_counter: 0, dest_id: 5, time_stamp: stamp_buf, }, additional_data: Some([0, 2].to_vec()), req_id, }; assert_eq!(sender.service_queue.len(), 1); let info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); } #[test] fn test_basic_acceptance_failure() { let (mut b, tok) = base_init(true); b.rep().reporter.dest_id = 5; let stamp_buf = [1, 2, 3, 4, 5, 6, 7]; let mut sender = TestSender::default(); let fail_code = EcssEnumU16::new(2); let fail_params = FailParams::new(Some(stamp_buf.as_slice()), &fail_code, None); b.vr.acceptance_failure(tok, &mut sender, fail_params) .expect("Sending acceptance success failed"); acceptance_fail_check(&mut sender, tok.req_id, stamp_buf); } #[test] fn test_basic_acceptance_failure_with_helper() { let (mut b, tok) = base_with_helper_init(); b.rep().reporter.dest_id = 5; let stamp_buf = [1, 2, 3, 4, 5, 6, 7]; let fail_code = EcssEnumU16::new(2); let fail_params = FailParams::new(Some(stamp_buf.as_slice()), &fail_code, None); b.helper .acceptance_failure(tok, fail_params) .expect("Sending acceptance success failed"); let sender: &mut TestSender = b.helper.sender.downcast_mut().unwrap(); acceptance_fail_check(sender, tok.req_id, stamp_buf); } #[test] fn test_acceptance_fail_data_too_large() { let (mut b, tok) = base_with_helper_init(); b.rep().reporter.dest_id = 5; let stamp_buf = [1, 2, 3, 4, 5, 6, 7]; let fail_code = EcssEnumU16::new(2); let fail_data: [u8; 16] = [0; 16]; // 4 req ID + 1 byte step + 2 byte error code + 8 byte fail data assert_eq!(b.rep().allowed_source_data_len(), 15); let fail_params = FailParams::new( Some(stamp_buf.as_slice()), &fail_code, Some(fail_data.as_slice()), ); let res = b.helper.acceptance_failure(tok, fail_params); assert!(res.is_err()); let err_with_token = res.unwrap_err(); assert_eq!(err_with_token.1, tok); match err_with_token.0 { EcssTmErrorWithSend::EcssTmError(EcssTmError::ByteConversionError(e)) => match e { ByteConversionError::ToSliceTooSmall(missmatch) => { assert_eq!( missmatch.expected, fail_data.len() + RequestId::SIZE_AS_BYTES + fail_code.byte_width() ); assert_eq!(missmatch.found, b.rep().allowed_source_data_len()); } _ => { panic!("{}", format!("Unexpected error {:?}", e)) } }, _ => { panic!("{}", format!("Unexpected error {:?}", err_with_token.0)) } } } #[test] fn test_basic_acceptance_failure_with_fail_data() { let (mut b, tok) = base_init(false); let mut sender = TestSender::default(); let fail_code = EcssEnumU8::new(10); let fail_data = EcssEnumU32::new(12); let mut fail_data_raw = [0; 4]; fail_data.write_to_be_bytes(&mut fail_data_raw).unwrap(); let fail_params = FailParams::new( Some(&EMPTY_STAMP), &fail_code, Some(fail_data_raw.as_slice()), ); b.vr.acceptance_failure(tok, &mut sender, fail_params) .expect("Sending acceptance success failed"); let cmp_info = TmInfo { common: CommonTmInfo { subservice: 2, apid: TEST_APID, msg_counter: 0, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: Some([10, 0, 0, 0, 12].to_vec()), req_id: tok.req_id, }; assert_eq!(sender.service_queue.len(), 1); let info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); } fn start_fail_check(sender: &mut TestSender, req_id: RequestId, fail_data_raw: [u8; 4]) { assert_eq!(sender.service_queue.len(), 2); let mut cmp_info = TmInfo { common: CommonTmInfo { subservice: 1, apid: TEST_APID, msg_counter: 0, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: None, req_id, }; let mut info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); cmp_info = TmInfo { common: CommonTmInfo { subservice: 4, apid: TEST_APID, msg_counter: 1, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: Some([&[22], fail_data_raw.as_slice()].concat().to_vec()), req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); } #[test] fn test_start_failure() { let (mut b, tok) = base_init(false); let mut sender = TestSender::default(); let fail_code = EcssEnumU8::new(22); let fail_data: i32 = -12; let mut fail_data_raw = [0; 4]; fail_data_raw.copy_from_slice(fail_data.to_be_bytes().as_slice()); let fail_params = FailParams::new( Some(&EMPTY_STAMP), &fail_code, Some(fail_data_raw.as_slice()), ); let accepted_token = b.vr.acceptance_success(tok, &mut sender, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let empty = b.vr.start_failure(accepted_token, &mut sender, fail_params) .expect("Start failure failure"); assert_eq!(empty, ()); start_fail_check(&mut sender, tok.req_id, fail_data_raw); } #[test] fn test_start_failure_with_helper() { let (mut b, tok) = base_with_helper_init(); let fail_code = EcssEnumU8::new(22); let fail_data: i32 = -12; let mut fail_data_raw = [0; 4]; fail_data_raw.copy_from_slice(fail_data.to_be_bytes().as_slice()); let fail_params = FailParams::new( Some(&EMPTY_STAMP), &fail_code, Some(fail_data_raw.as_slice()), ); let accepted_token = b .helper .acceptance_success(tok, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let empty = b .helper .start_failure(accepted_token, fail_params) .expect("Start failure failure"); assert_eq!(empty, ()); let sender: &mut TestSender = b.helper.sender.downcast_mut().unwrap(); start_fail_check(sender, tok.req_id, fail_data_raw); } fn step_success_check(sender: &mut TestSender, req_id: RequestId) { let mut cmp_info = TmInfo { common: CommonTmInfo { subservice: 1, apid: TEST_APID, msg_counter: 0, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: None, req_id, }; let mut info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); cmp_info = TmInfo { common: CommonTmInfo { subservice: 3, apid: TEST_APID, msg_counter: 1, dest_id: 0, time_stamp: [0, 1, 0, 1, 0, 1, 0], }, additional_data: None, req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); cmp_info = TmInfo { common: CommonTmInfo { subservice: 5, apid: TEST_APID, msg_counter: 2, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: Some([0].to_vec()), req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); cmp_info = TmInfo { common: CommonTmInfo { subservice: 5, apid: TEST_APID, msg_counter: 3, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: Some([1].to_vec()), req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); } #[test] fn test_steps_success() { let (mut b, tok) = base_init(false); let mut sender = TestSender::default(); let accepted_token = b .rep() .acceptance_success(tok, &mut sender, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let started_token = b .rep() .start_success(accepted_token, &mut sender, Some(&[0, 1, 0, 1, 0, 1, 0])) .expect("Sending start success failed"); let mut empty = b .rep() .step_success( &started_token, &mut sender, Some(&EMPTY_STAMP), EcssEnumU8::new(0), ) .expect("Sending step 0 success failed"); assert_eq!(empty, ()); empty = b.vr.step_success( &started_token, &mut sender, Some(&EMPTY_STAMP), EcssEnumU8::new(1), ) .expect("Sending step 1 success failed"); assert_eq!(empty, ()); assert_eq!(sender.service_queue.len(), 4); step_success_check(&mut sender, tok.req_id); } #[test] fn test_steps_success_with_helper() { let (mut b, tok) = base_with_helper_init(); let accepted_token = b .helper .acceptance_success(tok, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let started_token = b .helper .start_success(accepted_token, Some(&[0, 1, 0, 1, 0, 1, 0])) .expect("Sending start success failed"); let mut empty = b .helper .step_success(&started_token, Some(&EMPTY_STAMP), EcssEnumU8::new(0)) .expect("Sending step 0 success failed"); assert_eq!(empty, ()); empty = b .helper .step_success(&started_token, Some(&EMPTY_STAMP), EcssEnumU8::new(1)) .expect("Sending step 1 success failed"); assert_eq!(empty, ()); let sender: &mut TestSender = b.helper.sender.downcast_mut().unwrap(); assert_eq!(sender.service_queue.len(), 4); step_success_check(sender, tok.req_id); } fn check_step_failure(sender: &mut TestSender, req_id: RequestId, fail_data_raw: [u8; 4]) { assert_eq!(sender.service_queue.len(), 4); let mut cmp_info = TmInfo { common: CommonTmInfo { subservice: 1, apid: TEST_APID, msg_counter: 0, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: None, req_id, }; let mut info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); cmp_info = TmInfo { common: CommonTmInfo { subservice: 3, apid: TEST_APID, msg_counter: 1, dest_id: 0, time_stamp: [0, 1, 0, 1, 0, 1, 0], }, additional_data: None, req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); cmp_info = TmInfo { common: CommonTmInfo { subservice: 5, apid: TEST_APID, msg_counter: 2, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: Some([0].to_vec()), req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); cmp_info = TmInfo { common: CommonTmInfo { subservice: 6, apid: TEST_APID, msg_counter: 3, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: Some( [ [1].as_slice(), &[0, 0, 0x10, 0x20], fail_data_raw.as_slice(), ] .concat() .to_vec(), ), req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); } #[test] fn test_step_failure() { let (mut b, tok) = base_init(false); let mut sender = TestSender::default(); let req_id = tok.req_id; let fail_code = EcssEnumU32::new(0x1020); let fail_data: f32 = -22.3232; let mut fail_data_raw = [0; 4]; fail_data_raw.copy_from_slice(fail_data.to_be_bytes().as_slice()); let fail_step = EcssEnumU8::new(1); let fail_params = FailParamsWithStep::new( Some(&EMPTY_STAMP), &fail_step, &fail_code, Some(fail_data_raw.as_slice()), ); let accepted_token = b.vr.acceptance_success(tok, &mut sender, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let started_token = b.vr.start_success(accepted_token, &mut sender, Some(&[0, 1, 0, 1, 0, 1, 0])) .expect("Sending start success failed"); let mut empty = b.vr.step_success( &started_token, &mut sender, Some(&EMPTY_STAMP), EcssEnumU8::new(0), ) .expect("Sending completion success failed"); assert_eq!(empty, ()); empty = b.vr.step_failure(started_token, &mut sender, fail_params) .expect("Step failure failed"); assert_eq!(empty, ()); check_step_failure(&mut sender, req_id, fail_data_raw); } #[test] fn test_steps_failure_with_helper() { let (mut b, tok) = base_with_helper_init(); let req_id = tok.req_id; let fail_code = EcssEnumU32::new(0x1020); let fail_data: f32 = -22.3232; let mut fail_data_raw = [0; 4]; fail_data_raw.copy_from_slice(fail_data.to_be_bytes().as_slice()); let fail_step = EcssEnumU8::new(1); let fail_params = FailParamsWithStep::new( Some(&EMPTY_STAMP), &fail_step, &fail_code, Some(fail_data_raw.as_slice()), ); let accepted_token = b .helper .acceptance_success(tok, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let started_token = b .helper .start_success(accepted_token, Some(&[0, 1, 0, 1, 0, 1, 0])) .expect("Sending start success failed"); let mut empty = b .helper .step_success(&started_token, Some(&EMPTY_STAMP), EcssEnumU8::new(0)) .expect("Sending completion success failed"); assert_eq!(empty, ()); empty = b .helper .step_failure(started_token, fail_params) .expect("Step failure failed"); assert_eq!(empty, ()); let sender: &mut TestSender = b.helper.sender.downcast_mut().unwrap(); check_step_failure(sender, req_id, fail_data_raw); } fn completion_fail_check(sender: &mut TestSender, req_id: RequestId) { assert_eq!(sender.service_queue.len(), 3); let mut cmp_info = TmInfo { common: CommonTmInfo { subservice: 1, apid: TEST_APID, msg_counter: 0, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: None, req_id, }; let mut info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); cmp_info = TmInfo { common: CommonTmInfo { subservice: 3, apid: TEST_APID, msg_counter: 1, dest_id: 0, time_stamp: [0, 1, 0, 1, 0, 1, 0], }, additional_data: None, req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); cmp_info = TmInfo { common: CommonTmInfo { subservice: 8, apid: TEST_APID, msg_counter: 2, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: Some([0, 0, 0x10, 0x20].to_vec()), req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); } #[test] fn test_completion_failure() { let (mut b, tok) = base_init(false); let mut sender = TestSender::default(); let req_id = tok.req_id; let fail_code = EcssEnumU32::new(0x1020); let fail_params = FailParams::new(Some(&EMPTY_STAMP), &fail_code, None); let accepted_token = b.vr.acceptance_success(tok, &mut sender, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let started_token = b.vr.start_success(accepted_token, &mut sender, Some(&[0, 1, 0, 1, 0, 1, 0])) .expect("Sending start success failed"); let empty = b.vr.completion_failure(started_token, &mut sender, fail_params) .expect("Completion failure"); assert_eq!(empty, ()); completion_fail_check(&mut sender, req_id); } #[test] fn test_completion_failure_with_helper() { let (mut b, tok) = base_with_helper_init(); let req_id = tok.req_id; let fail_code = EcssEnumU32::new(0x1020); let fail_params = FailParams::new(Some(&EMPTY_STAMP), &fail_code, None); let accepted_token = b .helper .acceptance_success(tok, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let started_token = b .helper .start_success(accepted_token, Some(&[0, 1, 0, 1, 0, 1, 0])) .expect("Sending start success failed"); let empty = b .helper .completion_failure(started_token, fail_params) .expect("Completion failure"); assert_eq!(empty, ()); let sender: &mut TestSender = b.helper.sender.downcast_mut().unwrap(); completion_fail_check(sender, req_id); } fn completion_success_check(sender: &mut TestSender, req_id: RequestId) { assert_eq!(sender.service_queue.len(), 3); let cmp_info = TmInfo { common: CommonTmInfo { subservice: 1, apid: TEST_APID, msg_counter: 0, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: None, req_id, }; let mut info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); let cmp_info = TmInfo { common: CommonTmInfo { subservice: 3, apid: TEST_APID, msg_counter: 1, dest_id: 0, time_stamp: [0, 1, 0, 1, 0, 1, 0], }, additional_data: None, req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); let cmp_info = TmInfo { common: CommonTmInfo { subservice: 7, apid: TEST_APID, msg_counter: 2, dest_id: 0, time_stamp: EMPTY_STAMP, }, additional_data: None, req_id, }; info = sender.service_queue.pop_front().unwrap(); assert_eq!(info, cmp_info); } #[test] fn test_complete_success_sequence() { let (mut b, tok) = base_init(false); let mut sender = TestSender::default(); let accepted_token = b.vr.acceptance_success(tok, &mut sender, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let started_token = b.vr.start_success(accepted_token, &mut sender, Some(&[0, 1, 0, 1, 0, 1, 0])) .expect("Sending start success failed"); let empty = b.vr.completion_success(started_token, &mut sender, Some(&EMPTY_STAMP)) .expect("Sending completion success failed"); assert_eq!(empty, ()); completion_success_check(&mut sender, tok.req_id); } #[test] fn test_complete_success_sequence_with_helper() { let (mut b, tok) = base_with_helper_init(); let accepted_token = b .helper .acceptance_success(tok, Some(&EMPTY_STAMP)) .expect("Sending acceptance success failed"); let started_token = b .helper .start_success(accepted_token, Some(&[0, 1, 0, 1, 0, 1, 0])) .expect("Sending start success failed"); let empty = b .helper .completion_success(started_token, Some(&EMPTY_STAMP)) .expect("Sending completion success failed"); assert_eq!(empty, ()); let sender: &mut TestSender = b.helper.sender.downcast_mut().unwrap(); completion_success_check(sender, tok.req_id); } }