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|
use managed::ManagedSlice;
use crate::storage::{Full, RingBuffer};
use super::Empty;
/// Size and header of a packet.
#[derive(Debug, Clone, Copy)]
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
pub struct PacketMetadata<H> {
size: usize,
header: Option<H>,
}
impl<H> PacketMetadata<H> {
/// Empty packet description.
pub const EMPTY: PacketMetadata<H> = PacketMetadata {
size: 0,
header: None,
};
fn padding(size: usize) -> PacketMetadata<H> {
PacketMetadata {
size: size,
header: None,
}
}
fn packet(size: usize, header: H) -> PacketMetadata<H> {
PacketMetadata {
size: size,
header: Some(header),
}
}
fn is_padding(&self) -> bool {
self.header.is_none()
}
}
/// An UDP packet ring buffer.
#[derive(Debug)]
pub struct PacketBuffer<'a, H: 'a> {
metadata_ring: RingBuffer<'a, PacketMetadata<H>>,
payload_ring: RingBuffer<'a, u8>,
}
impl<'a, H> PacketBuffer<'a, H> {
/// Create a new packet buffer with the provided metadata and payload storage.
///
/// Metadata storage limits the maximum _number_ of packets in the buffer and payload
/// storage limits the maximum _total size_ of packets.
pub fn new<MS, PS>(metadata_storage: MS, payload_storage: PS) -> PacketBuffer<'a, H>
where
MS: Into<ManagedSlice<'a, PacketMetadata<H>>>,
PS: Into<ManagedSlice<'a, u8>>,
{
PacketBuffer {
metadata_ring: RingBuffer::new(metadata_storage),
payload_ring: RingBuffer::new(payload_storage),
}
}
/// Query whether the buffer is empty.
pub fn is_empty(&self) -> bool {
self.metadata_ring.is_empty()
}
/// Query whether the buffer is full.
pub fn is_full(&self) -> bool {
self.metadata_ring.is_full()
}
// There is currently no enqueue_with() because of the complexity of managing padding
// in case of failure.
/// Enqueue a single packet with the given header into the buffer, and
/// return a reference to its payload, or return `Err(Full)`
/// if the buffer is full.
pub fn enqueue(&mut self, size: usize, header: H) -> Result<&mut [u8], Full> {
if self.payload_ring.capacity() < size || self.metadata_ring.is_full() {
return Err(Full);
}
// Ring is currently empty. Clear it (resetting `read_at`) to maximize
// for contiguous space.
if self.payload_ring.is_empty() {
self.payload_ring.clear();
}
let window = self.payload_ring.window();
let contig_window = self.payload_ring.contiguous_window();
if window < size {
return Err(Full);
} else if contig_window < size {
if window - contig_window < size {
// The buffer length is larger than the current contiguous window
// and is larger than the contiguous window will be after adding
// the padding necessary to circle around to the beginning of the
// ring buffer.
return Err(Full);
} else {
// Add padding to the end of the ring buffer so that the
// contiguous window is at the beginning of the ring buffer.
*self.metadata_ring.enqueue_one()? = PacketMetadata::padding(contig_window);
// note(discard): function does not write to the result
// enqueued padding buffer location
let _buf_enqueued = self.payload_ring.enqueue_many(contig_window);
}
}
*self.metadata_ring.enqueue_one()? = PacketMetadata::packet(size, header);
let payload_buf = self.payload_ring.enqueue_many(size);
debug_assert!(payload_buf.len() == size);
Ok(payload_buf)
}
/// Call `f` with a packet from the buffer large enough to fit `max_size` bytes. The packet
/// is shrunk to the size returned from `f` and enqueued into the buffer.
pub fn enqueue_with_infallible<'b, F>(
&'b mut self,
max_size: usize,
header: H,
f: F,
) -> Result<usize, Full>
where
F: FnOnce(&'b mut [u8]) -> usize,
{
if self.payload_ring.capacity() < max_size || self.metadata_ring.is_full() {
return Err(Full);
}
let window = self.payload_ring.window();
let contig_window = self.payload_ring.contiguous_window();
if window < max_size {
return Err(Full);
} else if contig_window < max_size {
if window - contig_window < max_size {
// The buffer length is larger than the current contiguous window
// and is larger than the contiguous window will be after adding
// the padding necessary to circle around to the beginning of the
// ring buffer.
return Err(Full);
} else {
// Add padding to the end of the ring buffer so that the
// contiguous window is at the beginning of the ring buffer.
*self.metadata_ring.enqueue_one()? = PacketMetadata::padding(contig_window);
// note(discard): function does not write to the result
// enqueued padding buffer location
let _buf_enqueued = self.payload_ring.enqueue_many(contig_window);
}
}
let (size, _) = self
.payload_ring
.enqueue_many_with(|data| (f(&mut data[..max_size]), ()));
*self.metadata_ring.enqueue_one()? = PacketMetadata::packet(size, header);
Ok(size)
}
fn dequeue_padding(&mut self) {
let _ = self.metadata_ring.dequeue_one_with(|metadata| {
if metadata.is_padding() {
// note(discard): function does not use value of dequeued padding bytes
let _buf_dequeued = self.payload_ring.dequeue_many(metadata.size);
Ok(()) // dequeue metadata
} else {
Err(()) // don't dequeue metadata
}
});
}
/// Call `f` with a single packet from the buffer, and dequeue the packet if `f`
/// returns successfully, or return `Err(EmptyError)` if the buffer is empty.
pub fn dequeue_with<'c, R, E, F>(&'c mut self, f: F) -> Result<Result<R, E>, Empty>
where
F: FnOnce(&mut H, &'c mut [u8]) -> Result<R, E>,
{
self.dequeue_padding();
self.metadata_ring.dequeue_one_with(|metadata| {
self.payload_ring
.dequeue_many_with(|payload_buf| {
debug_assert!(payload_buf.len() >= metadata.size);
match f(
metadata.header.as_mut().unwrap(),
&mut payload_buf[..metadata.size],
) {
Ok(val) => (metadata.size, Ok(val)),
Err(err) => (0, Err(err)),
}
})
.1
})
}
/// Dequeue a single packet from the buffer, and return a reference to its payload
/// as well as its header, or return `Err(Error::Exhausted)` if the buffer is empty.
pub fn dequeue(&mut self) -> Result<(H, &mut [u8]), Empty> {
self.dequeue_padding();
let meta = self.metadata_ring.dequeue_one()?;
let payload_buf = self.payload_ring.dequeue_many(meta.size);
debug_assert!(payload_buf.len() == meta.size);
Ok((meta.header.take().unwrap(), payload_buf))
}
/// Peek at a single packet from the buffer without removing it, and return a reference to
/// its payload as well as its header, or return `Err(Error:Exhausted)` if the buffer is empty.
///
/// This function otherwise behaves identically to [dequeue](#method.dequeue).
pub fn peek(&mut self) -> Result<(&H, &[u8]), Empty> {
self.dequeue_padding();
if let Some(metadata) = self.metadata_ring.get_allocated(0, 1).first() {
Ok((
metadata.header.as_ref().unwrap(),
self.payload_ring.get_allocated(0, metadata.size),
))
} else {
Err(Empty)
}
}
/// Return the maximum number packets that can be stored.
pub fn packet_capacity(&self) -> usize {
self.metadata_ring.capacity()
}
/// Return the maximum number of bytes in the payload ring buffer.
pub fn payload_capacity(&self) -> usize {
self.payload_ring.capacity()
}
/// Reset the packet buffer and clear any staged.
#[allow(unused)]
pub(crate) fn reset(&mut self) {
self.payload_ring.clear();
self.metadata_ring.clear();
}
}
#[cfg(test)]
mod test {
use super::*;
fn buffer() -> PacketBuffer<'static, ()> {
PacketBuffer::new(vec![PacketMetadata::EMPTY; 4], vec![0u8; 16])
}
#[test]
fn test_simple() {
let mut buffer = buffer();
buffer.enqueue(6, ()).unwrap().copy_from_slice(b"abcdef");
assert_eq!(buffer.enqueue(16, ()), Err(Full));
assert_eq!(buffer.metadata_ring.len(), 1);
assert_eq!(buffer.dequeue().unwrap().1, &b"abcdef"[..]);
assert_eq!(buffer.dequeue(), Err(Empty));
}
#[test]
fn test_peek() {
let mut buffer = buffer();
assert_eq!(buffer.peek(), Err(Empty));
buffer.enqueue(6, ()).unwrap().copy_from_slice(b"abcdef");
assert_eq!(buffer.metadata_ring.len(), 1);
assert_eq!(buffer.peek().unwrap().1, &b"abcdef"[..]);
assert_eq!(buffer.dequeue().unwrap().1, &b"abcdef"[..]);
assert_eq!(buffer.peek(), Err(Empty));
}
#[test]
fn test_padding() {
let mut buffer = buffer();
assert!(buffer.enqueue(6, ()).is_ok());
assert!(buffer.enqueue(8, ()).is_ok());
assert!(buffer.dequeue().is_ok());
buffer.enqueue(4, ()).unwrap().copy_from_slice(b"abcd");
assert_eq!(buffer.metadata_ring.len(), 3);
assert!(buffer.dequeue().is_ok());
assert_eq!(buffer.dequeue().unwrap().1, &b"abcd"[..]);
assert_eq!(buffer.metadata_ring.len(), 0);
}
#[test]
fn test_padding_with_large_payload() {
let mut buffer = buffer();
assert!(buffer.enqueue(12, ()).is_ok());
assert!(buffer.dequeue().is_ok());
buffer
.enqueue(12, ())
.unwrap()
.copy_from_slice(b"abcdefghijkl");
}
#[test]
fn test_dequeue_with() {
let mut buffer = buffer();
assert!(buffer.enqueue(6, ()).is_ok());
assert!(buffer.enqueue(8, ()).is_ok());
assert!(buffer.dequeue().is_ok());
buffer.enqueue(4, ()).unwrap().copy_from_slice(b"abcd");
assert_eq!(buffer.metadata_ring.len(), 3);
assert!(buffer.dequeue().is_ok());
assert!(matches!(
buffer.dequeue_with(|_, _| Result::<(), u32>::Err(123)),
Ok(Err(_))
));
assert_eq!(buffer.metadata_ring.len(), 1);
assert!(buffer
.dequeue_with(|&mut (), payload| {
assert_eq!(payload, &b"abcd"[..]);
Result::<(), ()>::Ok(())
})
.is_ok());
assert_eq!(buffer.metadata_ring.len(), 0);
}
#[test]
fn test_metadata_full_empty() {
let mut buffer = buffer();
assert!(buffer.is_empty());
assert!(!buffer.is_full());
assert!(buffer.enqueue(1, ()).is_ok());
assert!(!buffer.is_empty());
assert!(buffer.enqueue(1, ()).is_ok());
assert!(buffer.enqueue(1, ()).is_ok());
assert!(!buffer.is_full());
assert!(!buffer.is_empty());
assert!(buffer.enqueue(1, ()).is_ok());
assert!(buffer.is_full());
assert!(!buffer.is_empty());
assert_eq!(buffer.metadata_ring.len(), 4);
assert_eq!(buffer.enqueue(1, ()), Err(Full));
}
#[test]
fn test_window_too_small() {
let mut buffer = buffer();
assert!(buffer.enqueue(4, ()).is_ok());
assert!(buffer.enqueue(8, ()).is_ok());
assert!(buffer.dequeue().is_ok());
assert_eq!(buffer.enqueue(16, ()), Err(Full));
assert_eq!(buffer.metadata_ring.len(), 1);
}
#[test]
fn test_contiguous_window_too_small() {
let mut buffer = buffer();
assert!(buffer.enqueue(4, ()).is_ok());
assert!(buffer.enqueue(8, ()).is_ok());
assert!(buffer.dequeue().is_ok());
assert_eq!(buffer.enqueue(8, ()), Err(Full));
assert_eq!(buffer.metadata_ring.len(), 1);
}
#[test]
fn test_contiguous_window_wrap() {
let mut buffer = buffer();
assert!(buffer.enqueue(15, ()).is_ok());
assert!(buffer.dequeue().is_ok());
assert!(buffer.enqueue(16, ()).is_ok());
}
#[test]
fn test_capacity_too_small() {
let mut buffer = buffer();
assert_eq!(buffer.enqueue(32, ()), Err(Full));
}
#[test]
fn test_contig_window_prioritized() {
let mut buffer = buffer();
assert!(buffer.enqueue(4, ()).is_ok());
assert!(buffer.dequeue().is_ok());
assert!(buffer.enqueue(5, ()).is_ok());
}
#[test]
fn clear() {
let mut buffer = buffer();
// Ensure enqueuing data in the buffer fills it somewhat.
assert!(buffer.is_empty());
assert!(buffer.enqueue(6, ()).is_ok());
// Ensure that resetting the buffer causes it to be empty.
assert!(!buffer.is_empty());
buffer.reset();
assert!(buffer.is_empty());
}
}
|
