sat-rs/satrs/src/seq_count.rs
Robin Mueller de4e6183b3
All checks were successful
Rust/sat-rs/pipeline/pr-main This commit looks good
Re-structure sat-rs
- Add new shared subcrate satrs-shared to split off some shared
  components not expected to change very often.
- Renmame `satrs-core` to `satrs`. It is expected that sat-rs will remain
  the primary crate, so the core information is superfluous, and core also
  implies stability, which will not be the case for some time.
2024-02-12 15:51:37 +01:00

251 lines
7.7 KiB
Rust

use core::cell::Cell;
#[cfg(feature = "alloc")]
use dyn_clone::DynClone;
use paste::paste;
use spacepackets::MAX_SEQ_COUNT;
#[cfg(feature = "std")]
pub use stdmod::*;
/// Core trait for objects which can provide a sequence count.
///
/// The core functions are not mutable on purpose to allow easier usage with
/// static structs when using the interior mutability pattern. This can be achieved by using
/// [Cell], [core::cell::RefCell] or atomic types.
pub trait SequenceCountProviderCore<Raw> {
fn get(&self) -> Raw;
fn increment(&self);
fn get_and_increment(&self) -> Raw {
let val = self.get();
self.increment();
val
}
}
/// Extension trait which allows cloning a sequence count provider after it was turned into
/// a trait object.
#[cfg(feature = "alloc")]
pub trait SequenceCountProvider<Raw>: SequenceCountProviderCore<Raw> + DynClone {}
#[cfg(feature = "alloc")]
dyn_clone::clone_trait_object!(SequenceCountProvider<u16>);
#[cfg(feature = "alloc")]
impl<T, Raw> SequenceCountProvider<Raw> for T where T: SequenceCountProviderCore<Raw> + Clone {}
#[derive(Default, Clone)]
pub struct SeqCountProviderSimple<T: Copy> {
seq_count: Cell<T>,
max_val: T,
}
macro_rules! impl_for_primitives {
($($ty: ident,)+) => {
$(
paste! {
impl SeqCountProviderSimple<$ty> {
pub fn [<new_ $ty _max_val>](max_val: $ty) -> Self {
Self {
seq_count: Cell::new(0),
max_val,
}
}
pub fn [<new_ $ty>]() -> Self {
Self {
seq_count: Cell::new(0),
max_val: $ty::MAX
}
}
}
impl SequenceCountProviderCore<$ty> for SeqCountProviderSimple<$ty> {
fn get(&self) -> $ty {
self.seq_count.get()
}
fn increment(&self) {
self.get_and_increment();
}
fn get_and_increment(&self) -> $ty {
let curr_count = self.seq_count.get();
if curr_count == self.max_val {
self.seq_count.set(0);
} else {
self.seq_count.set(curr_count + 1);
}
curr_count
}
}
}
)+
}
}
impl_for_primitives!(u8, u16, u32, u64,);
/// This is a sequence count provider which wraps around at [MAX_SEQ_COUNT].
pub struct CcsdsSimpleSeqCountProvider {
provider: SeqCountProviderSimple<u16>,
}
impl CcsdsSimpleSeqCountProvider {
pub fn new() -> Self {
Self {
provider: SeqCountProviderSimple::new_u16_max_val(MAX_SEQ_COUNT),
}
}
}
impl Default for CcsdsSimpleSeqCountProvider {
fn default() -> Self {
Self::new()
}
}
impl SequenceCountProviderCore<u16> for CcsdsSimpleSeqCountProvider {
delegate::delegate! {
to self.provider {
fn get(&self) -> u16;
fn increment(&self);
fn get_and_increment(&self) -> u16;
}
}
}
#[cfg(feature = "std")]
pub mod stdmod {
use super::*;
use std::sync::{Arc, Mutex};
macro_rules! sync_clonable_seq_counter_impl {
($($ty: ident,)+) => {
$(paste! {
/// These sequence counters can be shared between threads and can also be
/// configured to wrap around at specified maximum values. Please note that
/// that the API provided by this class will not panic und [Mutex] lock errors,
/// but it will yield 0 for the getter functions.
#[derive(Clone, Default)]
pub struct [<SeqCountProviderSync $ty:upper>] {
seq_count: Arc<Mutex<$ty>>,
max_val: $ty
}
impl [<SeqCountProviderSync $ty:upper>] {
pub fn new() -> Self {
Self::new_with_max_val($ty::MAX)
}
pub fn new_with_max_val(max_val: $ty) -> Self {
Self {
seq_count: Arc::default(),
max_val
}
}
}
impl SequenceCountProviderCore<$ty> for [<SeqCountProviderSync $ty:upper>] {
fn get(&self) -> $ty {
match self.seq_count.lock() {
Ok(counter) => *counter,
Err(_) => 0
}
}
fn increment(&self) {
self.get_and_increment();
}
fn get_and_increment(&self) -> $ty {
match self.seq_count.lock() {
Ok(mut counter) => {
let val = *counter;
if val == self.max_val {
*counter = 0;
} else {
*counter += 1;
}
val
}
Err(_) => 0,
}
}
}
})+
}
}
sync_clonable_seq_counter_impl!(u8, u16, u32, u64,);
}
#[cfg(test)]
mod tests {
use crate::seq_count::{
CcsdsSimpleSeqCountProvider, SeqCountProviderSimple, SeqCountProviderSyncU8,
SequenceCountProviderCore,
};
use spacepackets::MAX_SEQ_COUNT;
#[test]
fn test_u8_counter() {
let u8_counter = SeqCountProviderSimple::new_u8();
assert_eq!(u8_counter.get(), 0);
assert_eq!(u8_counter.get_and_increment(), 0);
assert_eq!(u8_counter.get_and_increment(), 1);
assert_eq!(u8_counter.get(), 2);
}
#[test]
fn test_u8_counter_overflow() {
let u8_counter = SeqCountProviderSimple::new_u8();
for _ in 0..256 {
u8_counter.increment();
}
assert_eq!(u8_counter.get(), 0);
}
#[test]
fn test_ccsds_counter() {
let ccsds_counter = CcsdsSimpleSeqCountProvider::default();
assert_eq!(ccsds_counter.get(), 0);
assert_eq!(ccsds_counter.get_and_increment(), 0);
assert_eq!(ccsds_counter.get_and_increment(), 1);
assert_eq!(ccsds_counter.get(), 2);
}
#[test]
fn test_ccsds_counter_overflow() {
let ccsds_counter = CcsdsSimpleSeqCountProvider::default();
for _ in 0..MAX_SEQ_COUNT + 1 {
ccsds_counter.increment();
}
assert_eq!(ccsds_counter.get(), 0);
}
#[test]
fn test_atomic_ref_counters() {
let sync_u8_counter = SeqCountProviderSyncU8::new();
assert_eq!(sync_u8_counter.get(), 0);
assert_eq!(sync_u8_counter.get_and_increment(), 0);
assert_eq!(sync_u8_counter.get_and_increment(), 1);
assert_eq!(sync_u8_counter.get(), 2);
}
#[test]
fn test_atomic_ref_counters_overflow() {
let sync_u8_counter = SeqCountProviderSyncU8::new();
for _ in 0..u8::MAX as u16 + 1 {
sync_u8_counter.increment();
}
assert_eq!(sync_u8_counter.get(), 0);
}
#[test]
fn test_atomic_ref_counters_overflow_custom_max_val() {
let sync_u8_counter = SeqCountProviderSyncU8::new_with_max_val(128);
for _ in 0..129 {
sync_u8_counter.increment();
}
assert_eq!(sync_u8_counter.get(), 0);
}
}