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use std::io;
use byteorder::{LittleEndian, ReadBytesExt, WriteBytesExt};
use super::{check_from_size, check_into_size, Error, FrameBuilder, FrameReader};
pub struct CompoundFrame<I: FrameReader> {
inner: I,
offset_right: usize,
}
impl<I: FrameReader> CompoundFrame<I> {
pub fn new(inner: I) -> Result<CompoundFrame<I>, Error> {
let exposed_data = inner.exposed_data();
check_from_size(4, exposed_data)?;
let offset_right =
(&exposed_data[exposed_data.len() - 4..]).read_u32::<LittleEndian>()? as usize;
Ok(CompoundFrame {
inner,
offset_right,
})
}
pub fn reader_left(&self) -> CompoundSideReader<I> {
CompoundSideReader {
frame: self,
left: true,
}
}
pub fn reader_right(&self) -> CompoundSideReader<I> {
CompoundSideReader {
frame: self,
left: false,
}
}
}
pub struct CompoundSideReader<'p, I: FrameReader> {
frame: &'p CompoundFrame<I>,
left: bool,
}
impl<'p, I: FrameReader> FrameReader for CompoundSideReader<'p, I> {
type OwnedType = Vec<u8>;
fn exposed_data(&self) -> &[u8] {
let exposed_data = self.frame.inner.exposed_data();
if self.left {
&exposed_data[..self.frame.offset_right]
} else {
&exposed_data[self.frame.offset_right..exposed_data.len() - 4]
}
}
fn whole_data(&self) -> &[u8] {
self.frame.inner.whole_data()
}
fn to_owned_frame(&self) -> Self::OwnedType {
self.exposed_data().to_vec()
}
}
pub struct CompoundFrameBuilder<A: FrameBuilder, B: FrameBuilder> {
left: A,
right: B,
}
impl<A: FrameBuilder, B: FrameBuilder> CompoundFrameBuilder<A, B> {
pub fn new(left: A, right: B) -> CompoundFrameBuilder<A, B> {
CompoundFrameBuilder { left, right }
}
pub fn inner(&mut self) -> &mut A {
&mut self.left
}
}
impl<A: FrameBuilder, B: FrameBuilder> FrameBuilder for CompoundFrameBuilder<A, B> {
type OwnedFrameType = CompoundFrame<Vec<u8>>;
fn write_to<W: io::Write>(&self, writer: &mut W) -> Result<usize, Error> {
let left_size = self.left.write_to(writer)?;
let right_size = self.right.write_to(writer)?;
writer.write_u32::<LittleEndian>(left_size as u32)?;
Ok(left_size + right_size + 4)
}
fn write_into(&self, into: &mut [u8]) -> Result<usize, Error> {
let left_size = self.left.write_into(into)?;
let right_size = self.right.write_into(&mut into[left_size..])?;
check_into_size(left_size + right_size + 4, into)?;
(&mut into[left_size + right_size..]).write_u32::<LittleEndian>(left_size as u32)?;
Ok(left_size + right_size + 4)
}
fn expected_size(&self) -> Option<usize> {
self.left.expected_size().and_then(|left_size| {
self.right
.expected_size()
.map(|right_size| left_size + right_size + 4)
})
}
fn as_owned_frame(&self) -> Self::OwnedFrameType {
CompoundFrame::new(self.as_bytes()).expect("Couldn't read just-created frame")
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::framing::assert_builder_equals;
#[test]
fn can_build_and_read() -> anyhow::Result<()> {
let left = vec![1; 10];
let right = vec![2; 15];
let builder = CompoundFrameBuilder::new(left, right);
assert_builder_equals(&builder)?;
let mut buffer = Vec::new();
builder.write_to(&mut buffer)?;
let frame = CompoundFrame::new(buffer)?;
assert_eq!(vec![1; 10], frame.reader_left().exposed_data());
assert_eq!(vec![2; 15], frame.reader_right().exposed_data());
Ok(())
}
#[test]
fn can_build_to_owned() -> anyhow::Result<()> {
let left = vec![1; 10];
let right = vec![2; 15];
let builder = CompoundFrameBuilder::new(left, right);
assert_builder_equals(&builder)?;
let frame = builder.as_owned_frame();
assert_eq!(vec![1; 10], frame.reader_left().exposed_data());
assert_eq!(vec![2; 15], frame.reader_right().exposed_data());
Ok(())
}
}