use qubit_codec::{
Codec,
CodecValueEncoder,
ValueEncoder,
};
#[derive(Default)]
struct ByteIncrementCodec;
unsafe impl Codec for ByteIncrementCodec {
type Value = u8;
type Unit = u8;
type DecodeError = core::convert::Infallible;
type EncodeError = core::convert::Infallible;
fn min_units_per_value(&self) -> core::num::NonZeroUsize {
core::num::NonZeroUsize::MIN
}
fn max_units_per_value(&self) -> core::num::NonZeroUsize {
core::num::NonZeroUsize::MIN
}
unsafe fn decode(
&mut self,
input: &[u8],
index: usize,
) -> Result<(u8, core::num::NonZeroUsize), Self::DecodeError> {
debug_assert!(index < input.len());
let value = unsafe { *input.as_ptr().add(index) };
Ok((value.wrapping_sub(1), core::num::NonZeroUsize::MIN))
}
unsafe fn encode(
&mut self,
value: &u8,
output: &mut [u8],
index: usize,
) -> Result<core::num::NonZeroUsize, Self::EncodeError> {
debug_assert!(index < output.len());
unsafe {
*output.as_mut_ptr().add(index) = value.wrapping_add(1);
}
Ok(qubit_io::nz!(1))
}
}
#[derive(Default)]
struct StatefulLifecycleCodec {
decode_state: usize,
encode_state: usize,
}
unsafe impl Codec for StatefulLifecycleCodec {
type Value = u8;
type Unit = u8;
type DecodeError = core::convert::Infallible;
type EncodeError = core::convert::Infallible;
fn min_units_per_value(&self) -> core::num::NonZeroUsize {
core::num::NonZeroUsize::MIN
}
fn max_units_per_value(&self) -> core::num::NonZeroUsize {
core::num::NonZeroUsize::MIN
}
fn max_encode_reset_units(&self) -> usize {
1
}
fn max_decode_flush_values(&self) -> usize {
1
}
unsafe fn decode(
&mut self,
input: &[u8],
index: usize,
) -> Result<(u8, core::num::NonZeroUsize), Self::DecodeError> {
let decoded = input[index].wrapping_sub(self.decode_state as u8);
self.decode_state += 1;
Ok((decoded, core::num::NonZeroUsize::MIN))
}
unsafe fn encode(
&mut self,
value: &u8,
output: &mut [u8],
index: usize,
) -> Result<core::num::NonZeroUsize, Self::EncodeError> {
output[index] = value.wrapping_add(self.encode_state as u8);
self.encode_state += 1;
Ok(qubit_io::nz!(1))
}
unsafe fn encode_reset(
&mut self,
output: &mut [u8],
index: usize,
) -> Result<usize, Self::EncodeError> {
output[index] = 0xfe;
self.encode_state = 1;
Ok(1)
}
unsafe fn decode_flush(
&mut self,
output: &mut [u8],
index: usize,
) -> Result<usize, Self::DecodeError> {
output[index] = self.decode_state as u8;
self.decode_state = 0;
Ok(1)
}
}
#[derive(Default)]
struct InvalidBoundsCodec;
unsafe impl Codec for InvalidBoundsCodec {
type Value = u8;
type Unit = u8;
type DecodeError = core::convert::Infallible;
type EncodeError = core::convert::Infallible;
fn min_units_per_value(&self) -> core::num::NonZeroUsize {
core::num::NonZeroUsize::new(2).expect("literal is non-zero")
}
fn max_units_per_value(&self) -> core::num::NonZeroUsize {
core::num::NonZeroUsize::MIN
}
unsafe fn decode(
&mut self,
_input: &[u8],
_index: usize,
) -> Result<(u8, core::num::NonZeroUsize), Self::DecodeError> {
Ok((0, core::num::NonZeroUsize::MIN))
}
unsafe fn encode(
&mut self,
_value: &u8,
_output: &mut [u8],
_index: usize,
) -> Result<core::num::NonZeroUsize, Self::EncodeError> {
Ok(qubit_io::nz!(1))
}
}
#[test]
fn test_codec_trait_encodes_and_decodes_one_value() {
let mut codec = ByteIncrementCodec;
let mut output = [0_u8; 1];
let written = unsafe { codec.encode(&41, &mut output, 0) }
.expect("encoding should be infallible");
let (decoded, consumed) = unsafe { Codec::decode(&mut codec, &output, 0) }
.expect("decoding should be infallible");
assert_eq!(1, codec.min_units_per_value().get());
assert_eq!(1, codec.max_units_per_value().get());
assert!(codec.can_encode_value(&41));
assert_eq!(1, written.get());
assert_eq!(1, consumed.get());
assert_eq!(41, decoded);
}
#[test]
fn test_codec_trait_default_lifecycle_methods_are_noop() {
let mut codec = ByteIncrementCodec;
let mut reset_output = [0_u8; 1];
let mut flush_output = [0_u8; 1];
let reset_written = unsafe { codec.encode_reset(&mut reset_output, 0) }
.expect("default reset should be infallible");
let flushed = unsafe { codec.decode_flush(&mut flush_output, 0) }
.expect("default flush should be infallible");
assert_eq!(1, codec.encode_len(&41).get());
assert_eq!(0, codec.max_encode_reset_units());
assert_eq!(0, codec.max_decode_flush_values());
assert_eq!(0, reset_written);
assert_eq!(0, flushed);
assert_eq!([0], reset_output);
assert_eq!([0], flush_output);
}
#[test]
fn test_codec_trait_exposes_stateful_lifecycle_methods() {
let mut codec = StatefulLifecycleCodec::default();
let mut encoded = [0_u8; 2];
let mut flushed = [0_u8; 1];
let reset_written = unsafe { codec.encode_reset(&mut encoded, 0) }
.expect("reset should be infallible");
let value_written =
unsafe { codec.encode(&41, &mut encoded, reset_written) }
.expect("encoding should be infallible");
assert_eq!(1, reset_written);
assert_eq!(1, value_written.get());
assert_eq!([0xfe, 42], encoded);
assert_eq!(2, codec.encode_state);
let (decoded, consumed) = unsafe { Codec::decode(&mut codec, &[42], 0) }
.expect("decoding should be infallible");
let flushed_len = unsafe { codec.decode_flush(&mut flushed, 0) }
.expect("flush should be infallible");
assert_eq!(42, decoded);
assert_eq!(1, consumed.get());
assert_eq!(1, flushed_len);
assert_eq!([1], flushed);
assert_eq!(0, codec.decode_state);
}
#[test]
#[should_panic(
expected = "Codec::min_units_per_value() must not exceed Codec::max_units_per_value()"
)]
fn test_codec_unit_bounds_panics_when_min_exceeds_max() {
let mut encoder = CodecValueEncoder::new(InvalidBoundsCodec);
let _ = encoder
.encode(&42)
.expect("unit-bound assertion should panic before encoding");
}