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use rotary_core::{Buf, BufMut, Channel, ChannelMut, ExactSizeBuf, ReadBuf, WriteBuf}; /// Make any mutable buffer into a write adapter that implements /// [ReadBuf] and [WriteBuf]. /// /// # Examples /// /// ```rust /// use rotary::{Buf as _, ReadBuf as _, WriteBuf as _}; /// use rotary::io; /// /// let from = rotary::interleaved![[1.0f32, 2.0f32, 3.0f32, 4.0f32]; 2]; /// let to = rotary::interleaved![[0.0f32; 4]; 2]; /// /// // Make `to` into a read / write adapter. /// let mut to = io::ReadWrite::new(to); /// /// io::copy_remaining(io::Read::new((&from).skip(2).limit(1)), &mut to); /// assert_eq!(to.remaining(), 1); /// /// io::copy_remaining(io::Read::new((&from).limit(1)), &mut to); /// assert_eq!(to.remaining(), 2); /// /// assert_eq! { /// to.as_ref().as_slice(), /// &[3.0, 3.0, 1.0, 1.0, 0.0, 0.0, 0.0, 0.0], /// }; /// /// // Note: 4 channels, 2 frames each. /// let mut read_out = io::Write::new(rotary::Interleaved::with_topology(4, 2)); /// /// assert_eq!(read_out.remaining_mut(), 2); /// assert!(read_out.has_remaining_mut()); /// /// assert_eq!(to.remaining(), 2); /// assert!(to.has_remaining()); /// /// io::copy_remaining(&mut to, &mut read_out); /// /// assert_eq!(read_out.remaining_mut(), 0); /// assert!(!read_out.has_remaining_mut()); /// /// assert_eq!(to.remaining(), 0); /// assert!(!to.has_remaining()); /// /// assert_eq! { /// read_out.as_ref().as_slice(), /// &[3.0, 3.0, 0.0, 0.0, 1.0, 1.0, 0.0, 0.0], /// } /// ``` pub struct ReadWrite<B> { buf: B, // Number of bytes available for reading. Conversely, the number of bytes // available for writing is the length of the buffer subtracted by this. read: usize, // The position in frames to write at. written: usize, } impl<B> ReadWrite<B> { /// Construct a new read / write buffer around an audio buffer. pub fn new(buf: B) -> Self { Self { buf, read: 0, written: 0, } } /// Access the underlying buffer. /// /// # Examples /// /// ```rust /// use rotary::Buf as _; /// use rotary::io; /// /// let buffer: rotary::Interleaved<i16> = rotary::interleaved![[1, 2, 3, 4]; 4]; /// let mut buffer = io::ReadWrite::new(buffer); /// /// let from = rotary::wrap::interleaved(&[1i16, 2i16, 3i16, 4i16][..], 2); /// /// io::translate_remaining(from, &mut buffer); /// /// assert_eq!(buffer.as_ref().channels(), 4); /// ``` #[inline] pub fn as_ref(&self) -> &B { &self.buf } /// Access the underlying buffer mutably. /// /// # Examples /// /// ```rust /// use rotary::Buf as _; /// use rotary::io; /// /// let buffer: rotary::Interleaved<i16> = rotary::interleaved![[1, 2, 3, 4]; 4]; /// let mut buffer = io::ReadWrite::new(buffer); /// /// let from = rotary::wrap::interleaved(&[1i16, 2i16, 3i16, 4i16][..], 2); /// /// io::translate_remaining(from, &mut buffer); /// /// buffer.as_mut().resize_channels(2); /// /// assert_eq!(buffer.channels(), 2); /// ``` #[inline] pub fn as_mut(&mut self) -> &mut B { &mut self.buf } /// Convert into the underlying buffer. /// /// # Examples /// /// ```rust /// use rotary::Buf as _; /// use rotary::io; /// /// let buffer: rotary::Interleaved<i16> = rotary::interleaved![[1, 2, 3, 4]; 4]; /// let mut buffer = io::ReadWrite::new(buffer); /// /// let from = rotary::wrap::interleaved(&[1i16, 2i16, 3i16, 4i16][..], 2); /// /// io::translate_remaining(from, &mut buffer); /// /// let buffer = buffer.into_inner(); /// /// assert_eq!(buffer.channels(), 4); /// ``` #[inline] pub fn into_inner(self) -> B { self.buf } /// Clear the state of the read / write adapter, setting both read and /// written to zero. #[inline] pub fn clear(&mut self) { self.read = 0; self.written = 0; } /// Set the number of frames which have been read. /// /// This is clamped to always be < written. #[inline] pub fn set_read(&mut self, read: usize) { self.read = read; } /// Set the number of frames which have been written. #[inline] pub fn set_written(&mut self, written: usize) { self.written = written; } } impl<B> ExactSizeBuf for ReadWrite<B> where B: ExactSizeBuf, { fn frames(&self) -> usize { self.buf.frames() } } impl<B, T> Buf<T> for ReadWrite<B> where B: Buf<T>, { #[inline] fn frames_hint(&self) -> Option<usize> { self.buf.frames_hint() } #[inline] fn channels(&self) -> usize { self.buf.channels() } #[inline] fn channel(&self, channel: usize) -> Channel<'_, T> { let len = self.remaining(); self.buf.channel(channel).skip(self.read).limit(len) } } impl<B, T> BufMut<T> for ReadWrite<B> where B: ExactSizeBuf + BufMut<T>, { #[inline] fn channel_mut(&mut self, channel: usize) -> ChannelMut<'_, T> { self.buf.channel_mut(channel).skip(self.written) } } impl<B> ReadBuf for ReadWrite<B> { #[inline] fn remaining(&self) -> usize { self.written.saturating_sub(self.read) } #[inline] fn advance(&mut self, n: usize) { self.read = self.read.saturating_add(n); } } impl<B> WriteBuf for ReadWrite<B> where B: ExactSizeBuf, { #[inline] fn remaining_mut(&self) -> usize { self.buf.frames().saturating_sub(self.written) } #[inline] fn advance_mut(&mut self, n: usize) { self.written = self.written.saturating_add(n); } }