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// Copyright 2017 Brian Langenberger
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
//! Traits and implementations for reading bits from a stream.
//!
//! ## Example
//!
//! Reading the initial STREAMINFO block from a FLAC file,
//! as documented in its
//! [specification](https://xiph.org/flac/format.html#stream).
//!
//! ```
//! use std::io::{Cursor, Read};
//! use bitstream_io::{BigEndian, BitReader};
//!
//! let flac: Vec<u8> = vec![0x66,0x4C,0x61,0x43,0x00,0x00,0x00,0x22,
//! 0x10,0x00,0x10,0x00,0x00,0x06,0x06,0x00,
//! 0x21,0x62,0x0A,0xC4,0x42,0xF0,0x00,0x04,
//! 0xA6,0xCC,0xFA,0xF2,0x69,0x2F,0xFD,0xEC,
//! 0x2D,0x5B,0x30,0x01,0x76,0xB4,0x62,0x88,
//! 0x7D,0x92];
//!
//! let mut cursor = Cursor::new(&flac);
//! {
//! let mut reader = BitReader::endian(&mut cursor, BigEndian);
//!
//! // stream marker
//! let mut file_header: [u8; 4] = [0, 0, 0, 0];
//! reader.read_bytes(&mut file_header).unwrap();
//! assert_eq!(&file_header, b"fLaC");
//!
//! // metadata block header
//! let last_block: bool = reader.read_bit().unwrap();
//! let block_type: u8 = reader.read(7).unwrap();
//! let block_size: u32 = reader.read(24).unwrap();
//! assert_eq!(last_block, false);
//! assert_eq!(block_type, 0);
//! assert_eq!(block_size, 34);
//!
//! // STREAMINFO block
//! let minimum_block_size: u16 = reader.read(16).unwrap();
//! let maximum_block_size: u16 = reader.read(16).unwrap();
//! let minimum_frame_size: u32 = reader.read(24).unwrap();
//! let maximum_frame_size: u32 = reader.read(24).unwrap();
//! let sample_rate: u32 = reader.read(20).unwrap();
//! let channels = reader.read::<u8>(3).unwrap() + 1;
//! let bits_per_sample = reader.read::<u8>(5).unwrap() + 1;
//! let total_samples: u64 = reader.read(36).unwrap();
//! assert_eq!(minimum_block_size, 4096);
//! assert_eq!(maximum_block_size, 4096);
//! assert_eq!(minimum_frame_size, 1542);
//! assert_eq!(maximum_frame_size, 8546);
//! assert_eq!(sample_rate, 44100);
//! assert_eq!(channels, 2);
//! assert_eq!(bits_per_sample, 16);
//! assert_eq!(total_samples, 304844);
//! }
//!
//! // STREAMINFO's MD5 sum
//!
//! // Note that the wrapped reader can be used once bitstream reading
//! // is finished at exactly the position one would expect.
//!
//! let mut md5 = [0; 16];
//! cursor.read_exact(&mut md5).unwrap();
//! assert_eq!(&md5,
//! b"\xFA\xF2\x69\x2F\xFD\xEC\x2D\x5B\x30\x01\x76\xB4\x62\x88\x7D\x92");
//! ```
#![warn(missing_docs)]
use std::io;
use super::{BitQueue, Endianness, Numeric, SignedNumeric};
use huffman::ReadHuffmanTree;
/// For reading non-aligned bits from a stream of bytes in a given endianness.
///
/// This will read exactly as many whole bytes needed to return
/// the requested number of bits. It may cache up to a single partial byte
/// but no more.
pub struct BitReader<R: io::Read, E: Endianness> {
reader: R,
bitqueue: BitQueue<E, u8>,
}
impl<R: io::Read, E: Endianness> BitReader<R, E> {
/// Wraps a BitReader around something that implements `Read`
pub fn new(reader: R) -> BitReader<R, E> {
BitReader {
reader,
bitqueue: BitQueue::new(),
}
}
/// Wraps a BitReader around something that implements `Read`
/// with the given endianness.
pub fn endian(reader: R, _endian: E) -> BitReader<R, E> {
BitReader {
reader,
bitqueue: BitQueue::new(),
}
}
/// Unwraps internal reader and disposes of BitReader.
/// Any unread partial bits are discarded.
#[inline]
pub fn into_reader(self) -> R {
self.reader
}
/// Reads a single bit from the stream.
/// `true` indicates 1, `false` indicates 0
///
/// # Errors
///
/// Passes along any I/O error from the underlying stream.
///
/// # Examples
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0b10110111];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), false);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), false);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// ```
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{LittleEndian, BitReader};
/// let data = [0b10110111];
/// let mut reader = BitReader::endian(Cursor::new(&data), LittleEndian);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), false);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// assert_eq!(reader.read_bit().unwrap(), false);
/// assert_eq!(reader.read_bit().unwrap(), true);
/// ```
#[inline(always)]
pub fn read_bit(&mut self) -> io::Result<bool> {
if self.bitqueue.is_empty() {
self.bitqueue.set(read_byte(&mut self.reader)?, 8);
}
Ok(self.bitqueue.pop(1) == 1)
}
/// Reads an unsigned value from the stream with
/// the given number of bits.
///
/// # Errors
///
/// Passes along any I/O error from the underlying stream.
/// Also returns an error if the output type is too small
/// to hold the requested number of bits.
///
/// # Examples
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0b10110111];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.read::<u8>(1).unwrap(), 0b1);
/// assert_eq!(reader.read::<u8>(2).unwrap(), 0b01);
/// assert_eq!(reader.read::<u8>(5).unwrap(), 0b10111);
/// ```
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{LittleEndian, BitReader};
/// let data = [0b10110111];
/// let mut reader = BitReader::endian(Cursor::new(&data), LittleEndian);
/// assert_eq!(reader.read::<u8>(1).unwrap(), 0b1);
/// assert_eq!(reader.read::<u8>(2).unwrap(), 0b11);
/// assert_eq!(reader.read::<u8>(5).unwrap(), 0b10110);
/// ```
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0;10];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert!(reader.read::<u8>(9).is_err()); // can't read 9 bits to u8
/// assert!(reader.read::<u16>(17).is_err()); // can't read 17 bits to u16
/// assert!(reader.read::<u32>(33).is_err()); // can't read 33 bits to u32
/// assert!(reader.read::<u64>(65).is_err()); // can't read 65 bits to u64
/// ```
pub fn read<U>(&mut self, mut bits: u32) -> io::Result<U>
where
U: Numeric,
{
if bits <= U::bits_size() {
let bitqueue_len = self.bitqueue.len();
if bits <= bitqueue_len {
Ok(U::from_u8(self.bitqueue.pop(bits)))
} else {
let mut acc =
BitQueue::from_value(U::from_u8(self.bitqueue.pop_all()), bitqueue_len);
bits -= bitqueue_len;
read_aligned(&mut self.reader, bits / 8, &mut acc)?;
read_unaligned(&mut self.reader, bits % 8, &mut acc, &mut self.bitqueue)?;
Ok(acc.value())
}
} else {
Err(io::Error::new(
io::ErrorKind::InvalidInput,
"excessive bits for type read",
))
}
}
/// Reads a twos-complement signed value from the stream with
/// the given number of bits.
///
/// # Errors
///
/// Passes along any I/O error from the underlying stream.
/// Also returns an error if the output type is too small
/// to hold the requested number of bits.
///
/// # Examples
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0b10110111];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.read_signed::<i8>(4).unwrap(), -5);
/// assert_eq!(reader.read_signed::<i8>(4).unwrap(), 7);
/// ```
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{LittleEndian, BitReader};
/// let data = [0b10110111];
/// let mut reader = BitReader::endian(Cursor::new(&data), LittleEndian);
/// assert_eq!(reader.read_signed::<i8>(4).unwrap(), 7);
/// assert_eq!(reader.read_signed::<i8>(4).unwrap(), -5);
/// ```
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0;10];
/// let mut r = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert!(r.read_signed::<i8>(9).is_err()); // can't read 9 bits to i8
/// assert!(r.read_signed::<i16>(17).is_err()); // can't read 17 bits to i16
/// assert!(r.read_signed::<i32>(33).is_err()); // can't read 33 bits to i32
/// assert!(r.read_signed::<i64>(65).is_err()); // can't read 65 bits to i64
/// ```
#[inline]
pub fn read_signed<S>(&mut self, bits: u32) -> io::Result<S>
where
S: SignedNumeric,
{
E::read_signed(self, bits)
}
/// Skips the given number of bits in the stream.
/// Since this method does not need an accumulator,
/// it may be slightly faster than reading to an empty variable.
/// In addition, since there is no accumulator,
/// there is no upper limit on the number of bits
/// which may be skipped.
/// These bits are still read from the stream, however,
/// and are never skipped via a `seek` method.
///
/// # Errors
///
/// Passes along any I/O error from the underlying stream.
///
/// # Examples
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0b10110111];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert!(reader.skip(3).is_ok());
/// assert_eq!(reader.read::<u8>(5).unwrap(), 0b10111);
/// ```
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{LittleEndian, BitReader};
/// let data = [0b10110111];
/// let mut reader = BitReader::endian(Cursor::new(&data), LittleEndian);
/// assert!(reader.skip(3).is_ok());
/// assert_eq!(reader.read::<u8>(5).unwrap(), 0b10110);
/// ```
pub fn skip(&mut self, mut bits: u32) -> io::Result<()> {
use std::cmp::min;
let to_drop = min(self.bitqueue.len(), bits);
if to_drop != 0 {
self.bitqueue.drop(to_drop);
bits -= to_drop;
}
skip_aligned(&mut self.reader, bits / 8)?;
skip_unaligned(&mut self.reader, bits % 8, &mut self.bitqueue)
}
/// Completely fills the given buffer with whole bytes.
/// If the stream is already byte-aligned, it will map
/// to a faster `read_exact` call. Otherwise it will read
/// bytes individually in 8-bit increments.
///
/// # Errors
///
/// Passes along any I/O error from the underlying stream.
///
/// # Example
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = b"foobar";
/// let mut reader = BitReader::endian(Cursor::new(data), BigEndian);
/// assert!(reader.skip(24).is_ok());
/// let mut buf = [0;3];
/// assert!(reader.read_bytes(&mut buf).is_ok());
/// assert_eq!(&buf, b"bar");
/// ```
pub fn read_bytes(&mut self, buf: &mut [u8]) -> io::Result<()> {
if self.byte_aligned() {
self.reader.read_exact(buf)
} else {
for b in buf.iter_mut() {
*b = self.read(8)?;
}
Ok(())
}
}
/// Counts the number of 1 bits in the stream until the next
/// 0 bit and returns the amount read.
/// Because this field is variably-sized and may be large,
/// its output is always a `u32` type.
///
/// # Errors
///
/// Passes along any I/O error from the underlying stream.
///
/// # Examples
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0b01110111, 0b11111110];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.read_unary0().unwrap(), 0);
/// assert_eq!(reader.read_unary0().unwrap(), 3);
/// assert_eq!(reader.read_unary0().unwrap(), 10);
/// ```
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{LittleEndian, BitReader};
/// let data = [0b11101110, 0b01111111];
/// let mut reader = BitReader::endian(Cursor::new(&data), LittleEndian);
/// assert_eq!(reader.read_unary0().unwrap(), 0);
/// assert_eq!(reader.read_unary0().unwrap(), 3);
/// assert_eq!(reader.read_unary0().unwrap(), 10);
/// ```
pub fn read_unary0(&mut self) -> io::Result<u32> {
if self.bitqueue.is_empty() {
read_aligned_unary(&mut self.reader, 0b1111_1111, &mut self.bitqueue)
.map(|u| u + self.bitqueue.pop_1())
} else if self.bitqueue.all_1() {
let base = self.bitqueue.len();
self.bitqueue.clear();
read_aligned_unary(&mut self.reader, 0b1111_1111, &mut self.bitqueue)
.map(|u| base + u + self.bitqueue.pop_1())
} else {
Ok(self.bitqueue.pop_1())
}
}
/// Counts the number of 0 bits in the stream until the next
/// 1 bit and returns the amount read.
/// Because this field is variably-sized and may be large,
/// its output is always a `u32` type.
///
/// # Errors
///
/// Passes along any I/O error from the underlying stream.
///
/// # Examples
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0b10001000, 0b00000001];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.read_unary1().unwrap(), 0);
/// assert_eq!(reader.read_unary1().unwrap(), 3);
/// assert_eq!(reader.read_unary1().unwrap(), 10);
/// ```
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{LittleEndian, BitReader};
/// let data = [0b00010001, 0b10000000];
/// let mut reader = BitReader::endian(Cursor::new(&data), LittleEndian);
/// assert_eq!(reader.read_unary1().unwrap(), 0);
/// assert_eq!(reader.read_unary1().unwrap(), 3);
/// assert_eq!(reader.read_unary1().unwrap(), 10);
/// ```
pub fn read_unary1(&mut self) -> io::Result<u32> {
if self.bitqueue.is_empty() {
read_aligned_unary(&mut self.reader, 0b0000_0000, &mut self.bitqueue)
.map(|u| u + self.bitqueue.pop_0())
} else if self.bitqueue.all_0() {
let base = self.bitqueue.len();
self.bitqueue.clear();
read_aligned_unary(&mut self.reader, 0b0000_0000, &mut self.bitqueue)
.map(|u| base + u + self.bitqueue.pop_0())
} else {
Ok(self.bitqueue.pop_0())
}
}
/// Returns true if the stream is aligned at a whole byte.
///
/// # Example
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.byte_aligned(), true);
/// assert!(reader.skip(1).is_ok());
/// assert_eq!(reader.byte_aligned(), false);
/// assert!(reader.skip(7).is_ok());
/// assert_eq!(reader.byte_aligned(), true);
/// ```
#[inline]
pub fn byte_aligned(&self) -> bool {
self.bitqueue.is_empty()
}
/// Throws away all unread bit values until the next whole byte.
/// Does nothing if the stream is already aligned.
///
/// # Example
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0x00, 0xFF];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.read::<u8>(4).unwrap(), 0);
/// reader.byte_align();
/// assert_eq!(reader.read::<u8>(8).unwrap(), 0xFF);
/// ```
#[inline]
pub fn byte_align(&mut self) {
self.bitqueue.clear()
}
/// Given a compiled Huffman tree, reads bits from the stream
/// until the next symbol is encountered.
///
/// # Errors
///
/// Passes along any I/O error from the underlying stream.
///
/// # Example
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// use bitstream_io::huffman::compile_read_tree;
/// let tree = compile_read_tree(
/// vec![('a', vec![0]),
/// ('b', vec![1, 0]),
/// ('c', vec![1, 1, 0]),
/// ('d', vec![1, 1, 1])]).unwrap();
/// let data = [0b10110111];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.read_huffman(&tree).unwrap(), 'b');
/// assert_eq!(reader.read_huffman(&tree).unwrap(), 'c');
/// assert_eq!(reader.read_huffman(&tree).unwrap(), 'd');
/// ```
pub fn read_huffman<T>(&mut self, tree: &[ReadHuffmanTree<E, T>]) -> io::Result<T>
where
T: Clone,
{
let mut result: &ReadHuffmanTree<E, T> = &tree[self.bitqueue.to_state()];
loop {
match result {
ReadHuffmanTree::Done(ref value, ref queue_val, ref queue_bits, _) => {
self.bitqueue.set(*queue_val, *queue_bits);
return Ok(value.clone());
}
ReadHuffmanTree::Continue(ref tree) => {
result = &tree[read_byte(&mut self.reader)? as usize];
}
ReadHuffmanTree::InvalidState => {
panic!("invalid state");
}
}
}
}
/// Consumes reader and returns any un-read partial byte
/// as a `(bits, value)` tuple.
///
/// # Examples
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0b1010_0101, 0b0101_1010];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.read::<u16>(9).unwrap(), 0b1010_0101_0);
/// let (bits, value) = reader.into_unread();
/// assert_eq!(bits, 7);
/// assert_eq!(value, 0b101_1010);
/// ```
///
/// ```
/// use std::io::{Read, Cursor};
/// use bitstream_io::{BigEndian, BitReader};
/// let data = [0b1010_0101, 0b0101_1010];
/// let mut reader = BitReader::endian(Cursor::new(&data), BigEndian);
/// assert_eq!(reader.read::<u16>(8).unwrap(), 0b1010_0101);
/// let (bits, value) = reader.into_unread();
/// assert_eq!(bits, 0);
/// assert_eq!(value, 0);
/// ```
#[inline]
pub fn into_unread(self) -> (u32, u8) {
(self.bitqueue.len(), self.bitqueue.value())
}
}
#[inline]
fn read_byte<R>(mut reader: R) -> io::Result<u8>
where
R: io::Read,
{
let mut buf = [0; 1];
reader.read_exact(&mut buf).map(|()| buf[0])
}
fn read_aligned<R, E, N>(mut reader: R, bytes: u32, acc: &mut BitQueue<E, N>) -> io::Result<()>
where
R: io::Read,
E: Endianness,
N: Numeric,
{
debug_assert!(bytes <= 16);
if bytes > 0 {
let mut buf = [0; 16];
reader.read_exact(&mut buf[0..bytes as usize])?;
for b in &buf[0..bytes as usize] {
acc.push(8, N::from_u8(*b));
}
}
Ok(())
}
fn skip_aligned<R>(mut reader: R, mut bytes: u32) -> io::Result<()>
where
R: io::Read,
{
use std::cmp::min;
/*skip up to 8 bytes at a time
(unlike with read_aligned, "bytes" may be larger than any native type)*/
let mut buf = [0; 8];
while bytes > 0 {
let to_read = min(8, bytes);
reader.read_exact(&mut buf[0..to_read as usize])?;
bytes -= to_read;
}
Ok(())
}
#[inline]
fn read_unaligned<R, E, N>(
reader: R,
bits: u32,
acc: &mut BitQueue<E, N>,
rem: &mut BitQueue<E, u8>,
) -> io::Result<()>
where
R: io::Read,
E: Endianness,
N: Numeric,
{
debug_assert!(bits <= 8);
if bits > 0 {
rem.set(read_byte(reader)?, 8);
acc.push(bits, N::from_u8(rem.pop(bits)));
}
Ok(())
}
#[inline]
fn skip_unaligned<R, E>(reader: R, bits: u32, rem: &mut BitQueue<E, u8>) -> io::Result<()>
where
R: io::Read,
E: Endianness,
{
debug_assert!(bits <= 8);
if bits > 0 {
rem.set(read_byte(reader)?, 8);
rem.pop(bits);
}
Ok(())
}
#[inline]
fn read_aligned_unary<R, E>(
mut reader: R,
continue_val: u8,
rem: &mut BitQueue<E, u8>,
) -> io::Result<u32>
where
R: io::Read,
E: Endianness,
{
let mut acc = 0;
let mut byte = read_byte(reader.by_ref())?;
while byte == continue_val {
acc += 8;
byte = read_byte(reader.by_ref())?;
}
rem.set(byte, 8);
Ok(acc)
}