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apache / incubator-teaclave-sgx-sdk / refs/tags/v0.9.0 / . / third_party / byteorder / src / lib.rs
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/*!
This crate provides convenience methods for encoding and decoding numbers
in either big-endian or little-endian order.
The organization of the crate is pretty simple. A trait, `ByteOrder`, specifies
byte conversion methods for each type of number in Rust (sans numbers that have
a platform dependent size like `usize` and `isize`). Two types, `BigEndian`
and `LittleEndian` implement these methods. Finally, `ReadBytesExt` and
`WriteBytesExt` provide convenience methods available to all types that
implement `Read` and `Write`.
# Examples
Read unsigned 16 bit big-endian integers from a `Read` type:
```rust
use std::io::Cursor;
use byteorder::{BigEndian, ReadBytesExt};
let mut rdr = Cursor::new(vec![2, 5, 3, 0]);
// Note that we use type parameters to indicate which kind of byte order
// we want!
assert_eq!(517, rdr.read_u16::<BigEndian>().unwrap());
assert_eq!(768, rdr.read_u16::<BigEndian>().unwrap());
```
Write unsigned 16 bit little-endian integers to a `Write` type:
```rust
use byteorder::{LittleEndian, WriteBytesExt};
let mut wtr = vec![];
wtr.write_u16::<LittleEndian>(517).unwrap();
wtr.write_u16::<LittleEndian>(768).unwrap();
assert_eq!(wtr, vec![5, 2, 0, 3]);
```
*/
#![deny(missing_docs)]
#![cfg_attr(feature = "i128", feature(i128_type))]
#![cfg_attr(all(feature = "i128", test), feature(i128))]
#![doc(html_root_url = "https://docs.rs/byteorder/1.0.0")]
#![no_std]
//#[cfg(feature = "std")]
//extern crate core;
extern crate sgx_tstd as std;
use core::fmt::Debug;
use core::hash::Hash;
use core::mem::transmute;
use core::ptr::copy_nonoverlapping;
//#[cfg(feature = "std")]
pub use io::{ReadBytesExt, WriteBytesExt};
//#[cfg(feature = "std")]
mod io;
#[inline]
fn extend_sign(val: u64, nbytes: usize) -> i64 {
let shift = (8 - nbytes) * 8;
(val << shift) as i64 >> shift
}
#[cfg(feature = "i128")]
#[inline]
fn extend_sign128(val: u128, nbytes: usize) -> i128 {
let shift = (16 - nbytes) * 8;
(val << shift) as i128 >> shift
}
#[inline]
fn unextend_sign(val: i64, nbytes: usize) -> u64 {
let shift = (8 - nbytes) * 8;
(val << shift) as u64 >> shift
}
#[cfg(feature = "i128")]
#[inline]
fn unextend_sign128(val: i128, nbytes: usize) -> u128 {
let shift = (16 - nbytes) * 8;
(val << shift) as u128 >> shift
}
#[inline]
fn pack_size(n: u64) -> usize {
if n < 1 << 8 {
1
} else if n < 1 << 16 {
2
} else if n < 1 << 24 {
3
} else if n < 1 << 32 {
4
} else if n < 1 << 40 {
5
} else if n < 1 << 48 {
6
} else if n < 1 << 56 {
7
} else {
8
}
}
#[cfg(feature = "i128")]
#[inline]
fn pack_size128(n: u128) -> usize {
if n < 1 << 8 {
1
} else if n < 1 << 16 {
2
} else if n < 1 << 24 {
3
} else if n < 1 << 32 {
4
} else if n < 1 << 40 {
5
} else if n < 1 << 48 {
6
} else if n < 1 << 56 {
7
} else if n < 1 << 64 {
8
} else if n < 1 << 72 {
9
} else if n < 1 << 80 {
10
} else if n < 1 << 88 {
11
} else if n < 1 << 96 {
12
} else if n < 1 << 104 {
13
} else if n < 1 << 112 {
14
} else if n < 1 << 120 {
15
} else {
16
}
}
mod private {
/// Sealed stops crates other than byteorder from implementing any traits
/// that use it.
pub trait Sealed{}
impl Sealed for super::LittleEndian {}
impl Sealed for super::BigEndian {}
}
/// ByteOrder describes types that can serialize integers as bytes.
///
/// Note that `Self` does not appear anywhere in this trait's definition!
/// Therefore, in order to use it, you'll need to use syntax like
/// `T::read_u16(&[0, 1])` where `T` implements `ByteOrder`.
///
/// This crate provides two types that implement `ByteOrder`: `BigEndian`
/// and `LittleEndian`.
/// This trait is sealed and cannot be implemented for callers to avoid
/// breaking backwards compatibility when adding new derived traits.
///
/// # Examples
///
/// Write and read `u32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 4];
/// LittleEndian::write_u32(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u32(&buf));
/// ```
///
/// Write and read `i16` numbers in big endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut buf = [0; 2];
/// BigEndian::write_i16(&mut buf, -50_000);
/// assert_eq!(-50_000, BigEndian::read_i16(&buf));
/// ```
pub trait ByteOrder
: Clone + Copy + Debug + Default + Eq + Hash + Ord + PartialEq + PartialOrd
+ private::Sealed
{
/// Reads an unsigned 16 bit integer from `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 2`.
fn read_u16(buf: &[u8]) -> u16;
/// Reads an unsigned 24 bit integer from `buf`, stored in u32.
///
/// # Panics
///
/// Panics when `buf.len() < 3`.
///
/// # Examples
///
/// Write and read 24 bit `u32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_u24(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u24(&buf));
/// ```
fn read_u24(buf: &[u8]) -> u32 {
Self::read_uint(buf, 3) as u32
}
/// Reads an unsigned 32 bit integer from `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 4`.
///
/// # Examples
///
/// Write and read `u32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 4];
/// LittleEndian::write_u32(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u32(&buf));
/// ```
fn read_u32(buf: &[u8]) -> u32;
/// Reads an unsigned 64 bit integer from `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 8`.
///
/// # Examples
///
/// Write and read `u64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 8];
/// LittleEndian::write_u64(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u64(&buf));
/// ```
fn read_u64(buf: &[u8]) -> u64;
/// Reads an unsigned 128 bit integer from `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 16`.
///
/// # Examples
///
/// Write and read `u128` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 16];
/// LittleEndian::write_u128(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u128(&buf));
/// ```
#[cfg(feature = "i128")]
fn read_u128(buf: &[u8]) -> u128;
/// Reads an unsigned n-bytes integer from `buf`.
///
/// # Panics
///
/// Panics when `nbytes < 1` or `nbytes > 8` or
/// `buf.len() < nbytes`
///
/// # Examples
///
/// Write and read an n-byte number in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_uint(&mut buf, 1_000_000, 3);
/// assert_eq!(1_000_000, LittleEndian::read_uint(&buf, 3));
/// ```
fn read_uint(buf: &[u8], nbytes: usize) -> u64;
/// Reads an unsigned n-bytes integer from `buf`.
///
/// # Panics
///
/// Panics when `nbytes < 1` or `nbytes > 16` or
/// `buf.len() < nbytes`
///
/// # Examples
///
/// Write and read an n-byte number in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_uint128(&mut buf, 1_000_000, 3);
/// assert_eq!(1_000_000, LittleEndian::read_uint128(&buf, 3));
/// ```
#[cfg(feature = "i128")]
fn read_uint128(buf: &[u8], nbytes: usize) -> u128;
/// Writes an unsigned 16 bit integer `n` to `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 2`.
///
/// # Examples
///
/// Write and read `u16` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 2];
/// LittleEndian::write_u16(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u16(&buf));
/// ```
fn write_u16(buf: &mut [u8], n: u16);
/// Writes an unsigned 24 bit integer `n` to `buf`, stored in u32.
///
/// # Panics
///
/// Panics when `buf.len() < 3`.
///
/// # Examples
///
/// Write and read 24 bit `u32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_u24(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u24(&buf));
/// ```
fn write_u24(buf: &mut [u8], n: u32) {
Self::write_uint(buf, n as u64, 3)
}
/// Writes an unsigned 32 bit integer `n` to `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 4`.
///
/// # Examples
///
/// Write and read `u32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 4];
/// LittleEndian::write_u32(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u32(&buf));
/// ```
fn write_u32(buf: &mut [u8], n: u32);
/// Writes an unsigned 64 bit integer `n` to `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 8`.
///
/// # Examples
///
/// Write and read `u64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 8];
/// LittleEndian::write_u64(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u64(&buf));
/// ```
fn write_u64(buf: &mut [u8], n: u64);
/// Writes an unsigned 128 bit integer `n` to `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 16`.
///
/// # Examples
///
/// Write and read `u128` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 16];
/// LittleEndian::write_u128(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u128(&buf));
/// ```
#[cfg(feature = "i128")]
fn write_u128(buf: &mut [u8], n: u128);
/// Writes an unsigned integer `n` to `buf` using only `nbytes`.
///
/// # Panics
///
/// If `n` is not representable in `nbytes`, or if `nbytes` is `> 8`, then
/// this method panics.
///
/// # Examples
///
/// Write and read an n-byte number in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_uint(&mut buf, 1_000_000, 3);
/// assert_eq!(1_000_000, LittleEndian::read_uint(&buf, 3));
/// ```
fn write_uint(buf: &mut [u8], n: u64, nbytes: usize);
/// Writes an unsigned integer `n` to `buf` using only `nbytes`.
///
/// # Panics
///
/// If `n` is not representable in `nbytes`, or if `nbytes` is `> 16`, then
/// this method panics.
///
/// # Examples
///
/// Write and read an n-byte number in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_uint128(&mut buf, 1_000_000, 3);
/// assert_eq!(1_000_000, LittleEndian::read_uint128(&buf, 3));
/// ```
#[cfg(feature = "i128")]
fn write_uint128(buf: &mut [u8], n: u128, nbytes: usize);
/// Reads a signed 16 bit integer from `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 2`.
///
/// # Examples
///
/// Write and read `i16` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 2];
/// LittleEndian::write_i16(&mut buf, -1_000);
/// assert_eq!(-1_000, LittleEndian::read_i16(&buf));
/// ```
#[inline]
fn read_i16(buf: &[u8]) -> i16 {
Self::read_u16(buf) as i16
}
/// Reads a signed 24 bit integer from `buf`, stored in i32.
///
/// # Panics
///
/// Panics when `buf.len() < 3`.
///
/// # Examples
///
/// Write and read 24 bit `i32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_i24(&mut buf, -1_000_000);
/// assert_eq!(-1_000_000, LittleEndian::read_i24(&buf));
/// ```
#[inline]
fn read_i24(buf: &[u8]) -> i32 {
Self::read_int(buf, 3) as i32
}
/// Reads a signed 32 bit integer from `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 4`.
///
/// # Examples
///
/// Write and read `i32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 4];
/// LittleEndian::write_i32(&mut buf, -1_000_000);
/// assert_eq!(-1_000_000, LittleEndian::read_i32(&buf));
/// ```
#[inline]
fn read_i32(buf: &[u8]) -> i32 {
Self::read_u32(buf) as i32
}
/// Reads a signed 64 bit integer from `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 8`.
///
/// # Examples
///
/// Write and read `i64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 8];
/// LittleEndian::write_i64(&mut buf, -1_000_000_000);
/// assert_eq!(-1_000_000_000, LittleEndian::read_i64(&buf));
/// ```
#[inline]
fn read_i64(buf: &[u8]) -> i64 {
Self::read_u64(buf) as i64
}
/// Reads a signed 128 bit integer from `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 16`.
///
/// # Examples
///
/// Write and read `i128` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 16];
/// LittleEndian::write_i128(&mut buf, -1_000_000_000);
/// assert_eq!(-1_000_000_000, LittleEndian::read_i128(&buf));
/// ```
#[cfg(feature = "i128")]
#[inline]
fn read_i128(buf: &[u8]) -> i128 {
Self::read_u128(buf) as i128
}
/// Reads a signed n-bytes integer from `buf`.
///
/// # Panics
///
/// Panics when `nbytes < 1` or `nbytes > 8` or
/// `buf.len() < nbytes`
///
/// # Examples
///
/// Write and read n-length signed numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_int(&mut buf, -1_000, 3);
/// assert_eq!(-1_000, LittleEndian::read_int(&buf, 3));
/// ```
#[inline]
fn read_int(buf: &[u8], nbytes: usize) -> i64 {
extend_sign(Self::read_uint(buf, nbytes), nbytes)
}
/// Reads a signed n-bytes integer from `buf`.
///
/// # Panics
///
/// Panics when `nbytes < 1` or `nbytes > 16` or
/// `buf.len() < nbytes`
///
/// # Examples
///
/// Write and read n-length signed numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_int128(&mut buf, -1_000, 3);
/// assert_eq!(-1_000, LittleEndian::read_int128(&buf, 3));
/// ```
#[cfg(feature = "i128")]
#[inline]
fn read_int128(buf: &[u8], nbytes: usize) -> i128 {
extend_sign128(Self::read_uint128(buf, nbytes), nbytes)
}
/// Reads a IEEE754 single-precision (4 bytes) floating point number.
///
/// The return value is always defined; signaling NaN's may be turned into
/// quiet NaN's.
///
/// # Panics
///
/// Panics when `buf.len() < 4`.
///
/// # Examples
///
/// Write and read `f32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let e = 2.71828;
/// let mut buf = [0; 4];
/// LittleEndian::write_f32(&mut buf, e);
/// assert_eq!(e, LittleEndian::read_f32(&buf));
/// ```
#[inline]
fn read_f32(buf: &[u8]) -> f32 {
safe_u32_bits_to_f32(Self::read_u32(buf))
}
/// Reads a IEEE754 double-precision (8 bytes) floating point number.
///
/// The return value is always defined; signaling NaN's may be turned into
/// quiet NaN's.
///
/// # Panics
///
/// Panics when `buf.len() < 8`.
///
/// # Examples
///
/// Write and read `f64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let phi = 1.6180339887;
/// let mut buf = [0; 8];
/// LittleEndian::write_f64(&mut buf, phi);
/// assert_eq!(phi, LittleEndian::read_f64(&buf));
/// ```
#[inline]
fn read_f64(buf: &[u8]) -> f64 {
safe_u64_bits_to_f64(Self::read_u64(buf))
}
/// Writes a signed 16 bit integer `n` to `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 2`.
///
/// # Examples
///
/// Write and read `i16` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 2];
/// LittleEndian::write_i16(&mut buf, -1_000);
/// assert_eq!(-1_000, LittleEndian::read_i16(&buf));
/// ```
#[inline]
fn write_i16(buf: &mut [u8], n: i16) {
Self::write_u16(buf, n as u16)
}
/// Writes a signed 24 bit integer `n` to `buf`, stored in i32.
///
/// # Panics
///
/// Panics when `buf.len() < 3`.
///
/// # Examples
///
/// Write and read 24 bit `i32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_i24(&mut buf, -1_000_000);
/// assert_eq!(-1_000_000, LittleEndian::read_i24(&buf));
/// ```
#[inline]
fn write_i24(buf: &mut [u8], n: i32) {
Self::write_int(buf, n as i64, 3)
}
/// Writes a signed 32 bit integer `n` to `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 4`.
///
/// # Examples
///
/// Write and read `i32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 4];
/// LittleEndian::write_i32(&mut buf, -1_000_000);
/// assert_eq!(-1_000_000, LittleEndian::read_i32(&buf));
/// ```
#[inline]
fn write_i32(buf: &mut [u8], n: i32) {
Self::write_u32(buf, n as u32)
}
/// Writes a signed 64 bit integer `n` to `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 8`.
///
/// # Examples
///
/// Write and read `i64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 8];
/// LittleEndian::write_i64(&mut buf, -1_000_000_000);
/// assert_eq!(-1_000_000_000, LittleEndian::read_i64(&buf));
/// ```
#[inline]
fn write_i64(buf: &mut [u8], n: i64) {
Self::write_u64(buf, n as u64)
}
/// Writes a signed 128 bit integer `n` to `buf`.
///
/// # Panics
///
/// Panics when `buf.len() < 16`.
///
/// # Examples
///
/// Write and read n-byte `i128` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 16];
/// LittleEndian::write_i128(&mut buf, -1_000_000_000);
/// assert_eq!(-1_000_000_000, LittleEndian::read_i128(&buf));
/// ```
#[cfg(feature = "i128")]
#[inline]
fn write_i128(buf: &mut [u8], n: i128) {
Self::write_u128(buf, n as u128)
}
/// Writes a signed integer `n` to `buf` using only `nbytes`.
///
/// # Panics
///
/// If `n` is not representable in `nbytes`, or if `nbytes` is `> 8`, then
/// this method panics.
///
/// # Examples
///
/// Write and read an n-byte number in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_int(&mut buf, -1_000, 3);
/// assert_eq!(-1_000, LittleEndian::read_int(&buf, 3));
/// ```
#[inline]
fn write_int(buf: &mut [u8], n: i64, nbytes: usize) {
Self::write_uint(buf, unextend_sign(n, nbytes), nbytes)
}
/// Writes a signed integer `n` to `buf` using only `nbytes`.
///
/// # Panics
///
/// If `n` is not representable in `nbytes`, or if `nbytes` is `> 16`, then
/// this method panics.
///
/// # Examples
///
/// Write and read n-length signed numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 3];
/// LittleEndian::write_int128(&mut buf, -1_000, 3);
/// assert_eq!(-1_000, LittleEndian::read_int128(&buf, 3));
/// ```
#[cfg(feature = "i128")]
#[inline]
fn write_int128(buf: &mut [u8], n: i128, nbytes: usize) {
Self::write_uint128(buf, unextend_sign128(n, nbytes), nbytes)
}
/// Writes a IEEE754 single-precision (4 bytes) floating point number.
///
/// # Panics
///
/// Panics when `buf.len() < 4`.
///
/// # Examples
///
/// Write and read `f32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let e = 2.71828;
/// let mut buf = [0; 4];
/// LittleEndian::write_f32(&mut buf, e);
/// assert_eq!(e, LittleEndian::read_f32(&buf));
/// ```
#[inline]
fn write_f32(buf: &mut [u8], n: f32) {
Self::write_u32(buf, unsafe { transmute(n) })
}
/// Writes a IEEE754 double-precision (8 bytes) floating point number.
///
/// # Panics
///
/// Panics when `buf.len() < 8`.
///
/// # Examples
///
/// Write and read `f64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let phi = 1.6180339887;
/// let mut buf = [0; 8];
/// LittleEndian::write_f64(&mut buf, phi);
/// assert_eq!(phi, LittleEndian::read_f64(&buf));
/// ```
#[inline]
fn write_f64(buf: &mut [u8], n: f64) {
Self::write_u64(buf, unsafe { transmute(n) })
}
/// Reads unsigned 16 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `src.len() != 2*dst.len()`.
///
/// # Examples
///
/// Write and read `u16` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 8];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_u16_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_u16_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn read_u16_into(src: &[u8], dst: &mut [u16]);
/// Reads unsigned 32 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `src.len() != 4*dst.len()`.
///
/// # Examples
///
/// Write and read `u32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 16];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_u32_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_u32_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn read_u32_into(src: &[u8], dst: &mut [u32]);
/// Reads unsigned 64 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `src.len() != 8*dst.len()`.
///
/// # Examples
///
/// Write and read `u64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 32];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_u64_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_u64_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn read_u64_into(src: &[u8], dst: &mut [u64]);
/// Reads unsigned 128 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `src.len() != 16*dst.len()`.
///
/// # Examples
///
/// Write and read `u128` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 64];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_u128_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_u128_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
#[cfg(feature = "i128")]
fn read_u128_into(src: &[u8], dst: &mut [u128]);
/// Reads signed 16 bit integers from `src` to `dst`.
///
/// # Panics
///
/// Panics when `buf.len() != 2*dst.len()`.
///
/// # Examples
///
/// Write and read `i16` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 8];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_i16_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_i16_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
#[inline]
fn read_i16_into(src: &[u8], dst: &mut [i16]) {
Self::read_u16_into(src, unsafe { transmute(dst) });
}
/// Reads signed 32 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `src.len() != 4*dst.len()`.
///
/// # Examples
///
/// Write and read `i32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 16];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_i32_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_i32_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
#[inline]
fn read_i32_into(src: &[u8], dst: &mut [i32]) {
Self::read_u32_into(src, unsafe { transmute(dst) });
}
/// Reads signed 64 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `src.len() != 8*dst.len()`.
///
/// # Examples
///
/// Write and read `i64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 32];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_i64_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_i64_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
#[inline]
fn read_i64_into(src: &[u8], dst: &mut [i64]) {
Self::read_u64_into(src, unsafe { transmute(dst) });
}
/// Reads signed 128 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `src.len() != 16*dst.len()`.
///
/// # Examples
///
/// Write and read `i128` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 64];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_i128_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_i128_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
#[cfg(feature = "i128")]
#[inline]
fn read_i128_into(src: &[u8], dst: &mut [i128]) {
Self::read_u128_into(src, unsafe { transmute(dst) });
}
/// Reads IEEE754 single-precision (4 bytes) floating point numbers from
/// `src` into `dst`.
///
/// Note that this does not perform any checks on the floating point
/// conversion. In particular, if the `src` data encodes an undefined
/// floating point value for your environment, then the result may be
/// undefined behavior. For example, this function may produce signaling
/// NaN floating point values.
///
/// # Panics
///
/// Panics when `src.len() != 4*dst.len()`.
///
/// # Examples
///
/// Write and read `f32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 16];
/// let numbers_given = [1.0, 2.0, 31.312e311, -11.32e91];
/// LittleEndian::write_f32_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0.0; 4];
/// unsafe {
/// LittleEndian::read_f32_into_unchecked(&bytes, &mut numbers_got);
/// }
/// assert_eq!(numbers_given, numbers_got);
/// ```
#[inline]
unsafe fn read_f32_into_unchecked(src: &[u8], dst: &mut [f32]) {
Self::read_u32_into(src, transmute(dst));
}
/// Reads IEEE754 single-precision (4 bytes) floating point numbers from
/// `src` into `dst`.
///
/// Note that this does not perform any checks on the floating point
/// conversion. In particular, if the `src` data encodes an undefined
/// floating point value for your environment, then the result may be
/// undefined behavior. For example, this function may produce signaling
/// NaN floating point values.
///
/// # Panics
///
/// Panics when `src.len() != 8*dst.len()`.
///
/// # Examples
///
/// Write and read `f64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 32];
/// let numbers_given = [1.0, 2.0, 31.312e311, -11.32e91];
/// LittleEndian::write_f64_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0.0; 4];
/// unsafe {
/// LittleEndian::read_f64_into_unchecked(&bytes, &mut numbers_got);
/// }
/// assert_eq!(numbers_given, numbers_got);
/// ```
#[inline]
unsafe fn read_f64_into_unchecked(src: &[u8], dst: &mut [f64]) {
Self::read_u64_into(src, transmute(dst));
}
/// Writes unsigned 16 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `dst.len() != 2*src.len()`.
///
/// # Examples
///
/// Write and read `u16` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 8];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_u16_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_u16_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn write_u16_into(src: &[u16], dst: &mut [u8]);
/// Writes unsigned 32 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `dst.len() != 4*src.len()`.
///
/// # Examples
///
/// Write and read `u32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 16];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_u32_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_u32_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn write_u32_into(src: &[u32], dst: &mut [u8]);
/// Writes unsigned 64 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `dst.len() != 8*src.len()`.
///
/// # Examples
///
/// Write and read `u64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 32];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_u64_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_u64_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn write_u64_into(src: &[u64], dst: &mut [u8]);
/// Writes unsigned 128 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `dst.len() != 16*src.len()`.
///
/// # Examples
///
/// Write and read `u128` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 64];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_u128_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_u128_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
#[cfg(feature = "i128")]
fn write_u128_into(src: &[u128], dst: &mut [u8]);
/// Writes signed 16 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `buf.len() != 2*src.len()`.
///
/// # Examples
///
/// Write and read `i16` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 8];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_i16_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_i16_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn write_i16_into(src: &[i16], dst: &mut [u8]) {
Self::write_u16_into(unsafe { transmute(src) }, dst);
}
/// Writes signed 32 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `dst.len() != 4*src.len()`.
///
/// # Examples
///
/// Write and read `i32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 16];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_i32_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_i32_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn write_i32_into(src: &[i32], dst: &mut [u8]) {
Self::write_u32_into(unsafe { transmute(src) }, dst);
}
/// Writes signed 64 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `dst.len() != 8*src.len()`.
///
/// # Examples
///
/// Write and read `i64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 32];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_i64_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_i64_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn write_i64_into(src: &[i64], dst: &mut [u8]) {
Self::write_u64_into(unsafe { transmute(src) }, dst);
}
/// Writes signed 128 bit integers from `src` into `dst`.
///
/// # Panics
///
/// Panics when `dst.len() != 16*src.len()`.
///
/// # Examples
///
/// Write and read `i128` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 64];
/// let numbers_given = [1, 2, 0xf00f, 0xffee];
/// LittleEndian::write_i128_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0; 4];
/// LittleEndian::read_i128_into(&bytes, &mut numbers_got);
/// assert_eq!(numbers_given, numbers_got);
/// ```
#[cfg(feature = "i128")]
fn write_i128_into(src: &[i128], dst: &mut [u8]) {
Self::write_u128_into(unsafe { transmute(src) }, dst);
}
/// Writes IEEE754 single-precision (4 bytes) floating point numbers from
/// `src` into `dst`.
///
/// # Panics
///
/// Panics when `src.len() != 4*dst.len()`.
///
/// # Examples
///
/// Write and read `f32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 16];
/// let numbers_given = [1.0, 2.0, 31.312e311, -11.32e91];
/// LittleEndian::write_f32_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0.0; 4];
/// unsafe {
/// LittleEndian::read_f32_into_unchecked(&bytes, &mut numbers_got);
/// }
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn write_f32_into(src: &[f32], dst: &mut [u8]) {
Self::write_u32_into(unsafe { transmute(src) }, dst);
}
/// Writes IEEE754 double-precision (8 bytes) floating point numbers from
/// `src` into `dst`.
///
/// # Panics
///
/// Panics when `src.len() != 8*dst.len()`.
///
/// # Examples
///
/// Write and read `f64` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut bytes = [0; 32];
/// let numbers_given = [1.0, 2.0, 31.312e311, -11.32e91];
/// LittleEndian::write_f64_into(&numbers_given, &mut bytes);
///
/// let mut numbers_got = [0.0; 4];
/// unsafe {
/// LittleEndian::read_f64_into_unchecked(&bytes, &mut numbers_got);
/// }
/// assert_eq!(numbers_given, numbers_got);
/// ```
fn write_f64_into(src: &[f64], dst: &mut [u8]) {
Self::write_u64_into(unsafe { transmute(src) }, dst);
}
/// Converts the given slice of unsigned 16 bit integers to a particular
/// endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// # Examples
///
/// Convert the host platform's endianness to big-endian:
///
/// ```rust
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut numbers = [5, 65000];
/// BigEndian::from_slice_u16(&mut numbers);
/// if cfg!(target_endian = "little") {
/// assert_eq!(numbers, [5u16.swap_bytes(), 65000u16.swap_bytes()]);
/// } else {
/// assert_eq!(numbers, [5, 65000]);
/// }
/// ```
fn from_slice_u16(numbers: &mut [u16]);
/// Converts the given slice of unsigned 32 bit integers to a particular
/// endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// # Examples
///
/// Convert the host platform's endianness to big-endian:
///
/// ```rust
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut numbers = [5, 65000];
/// BigEndian::from_slice_u32(&mut numbers);
/// if cfg!(target_endian = "little") {
/// assert_eq!(numbers, [5u32.swap_bytes(), 65000u32.swap_bytes()]);
/// } else {
/// assert_eq!(numbers, [5, 65000]);
/// }
/// ```
fn from_slice_u32(numbers: &mut [u32]);
/// Converts the given slice of unsigned 64 bit integers to a particular
/// endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// # Examples
///
/// Convert the host platform's endianness to big-endian:
///
/// ```rust
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut numbers = [5, 65000];
/// BigEndian::from_slice_u64(&mut numbers);
/// if cfg!(target_endian = "little") {
/// assert_eq!(numbers, [5u64.swap_bytes(), 65000u64.swap_bytes()]);
/// } else {
/// assert_eq!(numbers, [5, 65000]);
/// }
/// ```
fn from_slice_u64(numbers: &mut [u64]);
/// Converts the given slice of unsigned 128 bit integers to a particular
/// endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// # Examples
///
/// Convert the host platform's endianness to big-endian:
///
/// ```rust
/// #![feature(i128_type)]
///
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut numbers = [5, 65000];
/// BigEndian::from_slice_u128(&mut numbers);
/// if cfg!(target_endian = "little") {
/// assert_eq!(numbers, [5u128.swap_bytes(), 65000u128.swap_bytes()]);
/// } else {
/// assert_eq!(numbers, [5, 65000]);
/// }
/// ```
#[cfg(feature = "i128")]
fn from_slice_u128(numbers: &mut [u128]);
/// Converts the given slice of signed 16 bit integers to a particular
/// endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// # Examples
///
/// Convert the host platform's endianness to big-endian:
///
/// ```rust
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut numbers = [5, 65000];
/// BigEndian::from_slice_i16(&mut numbers);
/// if cfg!(target_endian = "little") {
/// assert_eq!(numbers, [5i16.swap_bytes(), 65000i16.swap_bytes()]);
/// } else {
/// assert_eq!(numbers, [5, 65000]);
/// }
/// ```
#[inline]
fn from_slice_i16(numbers: &mut [i16]) {
Self::from_slice_u16(unsafe { transmute(numbers) });
}
/// Converts the given slice of signed 32 bit integers to a particular
/// endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// # Examples
///
/// Convert the host platform's endianness to big-endian:
///
/// ```rust
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut numbers = [5, 65000];
/// BigEndian::from_slice_i32(&mut numbers);
/// if cfg!(target_endian = "little") {
/// assert_eq!(numbers, [5i32.swap_bytes(), 65000i32.swap_bytes()]);
/// } else {
/// assert_eq!(numbers, [5, 65000]);
/// }
/// ```
#[inline]
fn from_slice_i32(numbers: &mut [i32]) {
Self::from_slice_u32(unsafe { transmute(numbers) });
}
/// Converts the given slice of signed 64 bit integers to a particular
/// endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// # Examples
///
/// Convert the host platform's endianness to big-endian:
///
/// ```rust
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut numbers = [5, 65000];
/// BigEndian::from_slice_i64(&mut numbers);
/// if cfg!(target_endian = "little") {
/// assert_eq!(numbers, [5i64.swap_bytes(), 65000i64.swap_bytes()]);
/// } else {
/// assert_eq!(numbers, [5, 65000]);
/// }
/// ```
#[inline]
fn from_slice_i64(numbers: &mut [i64]) {
Self::from_slice_u64(unsafe { transmute(numbers) });
}
/// Converts the given slice of signed 128 bit integers to a particular
/// endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// # Examples
///
/// Convert the host platform's endianness to big-endian:
///
/// ```rust
/// #![feature(i128_type)]
///
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut numbers = [5, 65000];
/// BigEndian::from_slice_i128(&mut numbers);
/// if cfg!(target_endian = "little") {
/// assert_eq!(numbers, [5i128.swap_bytes(), 65000i128.swap_bytes()]);
/// } else {
/// assert_eq!(numbers, [5, 65000]);
/// }
/// ```
#[cfg(feature = "i128")]
#[inline]
fn from_slice_i128(numbers: &mut [i128]) {
Self::from_slice_u128(unsafe { transmute(numbers) });
}
/// Converts the given slice of IEEE754 single-precision (4 bytes) floating
/// point numbers to a particular endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// Note that the results of this operation are guaranteed to be defined.
/// In particular, this method may replace signaling NaN values with
/// quiet NaN values.
fn from_slice_f32(numbers: &mut [f32]);
/// Converts the given slice of IEEE754 double-precision (8 bytes) floating
/// point numbers to a particular endianness.
///
/// If the endianness matches the endianness of the host platform, then
/// this is a no-op.
///
/// Note that the results of this operation are guaranteed to be defined.
/// In particular, this method may replace signaling NaN values with
/// quiet NaN values.
fn from_slice_f64(numbers: &mut [f64]);
}
/// Defines big-endian serialization.
///
/// Note that this type has no value constructor. It is used purely at the
/// type level.
///
/// # Examples
///
/// Write and read `u32` numbers in big endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, BigEndian};
///
/// let mut buf = [0; 4];
/// BigEndian::write_u32(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, BigEndian::read_u32(&buf));
/// ```
#[derive(Clone, Copy, Debug, Eq, Hash, Ord, PartialEq, PartialOrd)]
pub enum BigEndian {}
impl Default for BigEndian {
fn default() -> BigEndian {
panic!("BigEndian default")
}
}
/// A type alias for `BigEndian`.
pub type BE = BigEndian;
/// Defines little-endian serialization.
///
/// Note that this type has no value constructor. It is used purely at the
/// type level.
///
/// # Examples
///
/// Write and read `u32` numbers in little endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, LittleEndian};
///
/// let mut buf = [0; 4];
/// LittleEndian::write_u32(&mut buf, 1_000_000);
/// assert_eq!(1_000_000, LittleEndian::read_u32(&buf));
/// ```
#[derive(Clone, Copy, Debug, Eq, Hash, Ord, PartialEq, PartialOrd)]
pub enum LittleEndian {}
impl Default for LittleEndian {
fn default() -> LittleEndian {
panic!("LittleEndian default")
}
}
/// A type alias for `LittleEndian`.
pub type LE = LittleEndian;
/// Defines network byte order serialization.
///
/// Network byte order is defined by [RFC 1700][1] to be big-endian, and is
/// referred to in several protocol specifications. This type is an alias of
/// BigEndian.
///
/// [1]: https://tools.ietf.org/html/rfc1700
///
/// Note that this type has no value constructor. It is used purely at the
/// type level.
///
/// # Examples
///
/// Write and read `i16` numbers in big endian order:
///
/// ```rust
/// use byteorder::{ByteOrder, NetworkEndian, BigEndian};
///
/// let mut buf = [0; 2];
/// BigEndian::write_i16(&mut buf, -50_000);
/// assert_eq!(-50_000, NetworkEndian::read_i16(&buf));
/// ```
pub type NetworkEndian = BigEndian;
/// Defines system native-endian serialization.
///
/// Note that this type has no value constructor. It is used purely at the
/// type level.
#[cfg(target_endian = "little")]
pub type NativeEndian = LittleEndian;
/// Defines system native-endian serialization.
///
/// Note that this type has no value constructor. It is used purely at the
/// type level.
#[cfg(target_endian = "big")]
pub type NativeEndian = BigEndian;
macro_rules! read_num_bytes {
($ty:ty, $size:expr, $src:expr, $which:ident) => ({
assert!($size == ::core::mem::size_of::<$ty>());
assert!($size <= $src.len());
let mut data: $ty = 0;
unsafe {
copy_nonoverlapping(
$src.as_ptr(),
&mut data as *mut $ty as *mut u8,
$size);
}
data.$which()
});
}
macro_rules! write_num_bytes {
($ty:ty, $size:expr, $n:expr, $dst:expr, $which:ident) => ({
assert!($size <= $dst.len());
unsafe {
// N.B. https://github.com/rust-lang/rust/issues/22776
let bytes = transmute::<_, [u8; $size]>($n.$which());
copy_nonoverlapping((&bytes).as_ptr(), $dst.as_mut_ptr(), $size);
}
});
}
macro_rules! read_slice {
($src:expr, $dst:expr, $size:expr, $which:ident) => {{
assert_eq!($src.len(), $size * $dst.len());
unsafe {
copy_nonoverlapping(
$src.as_ptr(),
$dst.as_mut_ptr() as *mut u8,
$src.len());
}
for v in $dst.iter_mut() {
*v = v.$which();
}
}};
}
macro_rules! write_slice_native {
($src:expr, $dst:expr, $ty:ty, $size:expr) => {{
assert!($size == ::core::mem::size_of::<$ty>());
assert_eq!($size * $src.len(), $dst.len());
unsafe {
copy_nonoverlapping(
$src.as_ptr() as *const u8,
$dst.as_mut_ptr(),
$dst.len());
}
}};
}
macro_rules! write_slice {
($src:expr, $dst:expr, $ty:ty, $size:expr, $write:expr) => ({
assert!($size == ::core::mem::size_of::<$ty>());
assert_eq!($size * $src.len(), $dst.len());
for (&n, chunk) in $src.iter().zip($dst.chunks_mut($size)) {
$write(chunk, n);
}
});
}
impl ByteOrder for BigEndian {
#[inline]
fn read_u16(buf: &[u8]) -> u16 {
read_num_bytes!(u16, 2, buf, to_be)
}
#[inline]
fn read_u32(buf: &[u8]) -> u32 {
read_num_bytes!(u32, 4, buf, to_be)
}
#[inline]
fn read_u64(buf: &[u8]) -> u64 {
read_num_bytes!(u64, 8, buf, to_be)
}
#[cfg(feature = "i128")]
#[inline]
fn read_u128(buf: &[u8]) -> u128 {
read_num_bytes!(u128, 16, buf, to_be)
}
#[inline]
fn read_uint(buf: &[u8], nbytes: usize) -> u64 {
assert!(1 <= nbytes && nbytes <= 8 && nbytes <= buf.len());
let mut out = [0u8; 8];
let ptr_out = out.as_mut_ptr();
unsafe {
copy_nonoverlapping(
buf.as_ptr(), ptr_out.offset((8 - nbytes) as isize), nbytes);
(*(ptr_out as *const u64)).to_be()
}
}
#[cfg(feature = "i128")]
#[inline]
fn read_uint128(buf: &[u8], nbytes: usize) -> u128 {
assert!(1 <= nbytes && nbytes <= 16 && nbytes <= buf.len());
let mut out = [0u8; 16];
let ptr_out = out.as_mut_ptr();
unsafe {
copy_nonoverlapping(
buf.as_ptr(), ptr_out.offset((16 - nbytes) as isize), nbytes);
(*(ptr_out as *const u128)).to_be()
}
}
#[inline]
fn write_u16(buf: &mut [u8], n: u16) {
write_num_bytes!(u16, 2, n, buf, to_be);
}
#[inline]
fn write_u32(buf: &mut [u8], n: u32) {
write_num_bytes!(u32, 4, n, buf, to_be);
}
#[inline]
fn write_u64(buf: &mut [u8], n: u64) {
write_num_bytes!(u64, 8, n, buf, to_be);
}
#[cfg(feature = "i128")]
#[inline]
fn write_u128(buf: &mut [u8], n: u128) {
write_num_bytes!(u128, 16, n, buf, to_be);
}
#[inline]
fn write_uint(buf: &mut [u8], n: u64, nbytes: usize) {
assert!(pack_size(n) <= nbytes && nbytes <= 8);
assert!(nbytes <= buf.len());
unsafe {
let bytes: [u8; 8] = transmute(n.to_be());
copy_nonoverlapping(
bytes.as_ptr().offset((8 - nbytes) as isize),
buf.as_mut_ptr(),
nbytes);
}
}
#[cfg(feature = "i128")]
#[inline]
fn write_uint128(buf: &mut [u8], n: u128, nbytes: usize) {
assert!(pack_size128(n) <= nbytes && nbytes <= 16);
assert!(nbytes <= buf.len());
unsafe {
let bytes: [u8; 16] = transmute(n.to_be());
copy_nonoverlapping(
bytes.as_ptr().offset((16 - nbytes) as isize),
buf.as_mut_ptr(),
nbytes);
}
}
#[inline]
fn read_u16_into(src: &[u8], dst: &mut [u16]) {
read_slice!(src, dst, 2, to_be);
}
#[inline]
fn read_u32_into(src: &[u8], dst: &mut [u32]) {
read_slice!(src, dst, 4, to_be);
}
#[inline]
fn read_u64_into(src: &[u8], dst: &mut [u64]) {
read_slice!(src, dst, 8, to_be);
}
#[cfg(feature = "i128")]
#[inline]
fn read_u128_into(src: &[u8], dst: &mut [u128]) {
read_slice!(src, dst, 16, to_be);
}
#[inline]
fn write_u16_into(src: &[u16], dst: &mut [u8]) {
if cfg!(target_endian = "big") {
write_slice_native!(src, dst, u16, 2);
} else {
write_slice!(src, dst, u16, 2, Self::write_u16);
}
}
#[inline]
fn write_u32_into(src: &[u32], dst: &mut [u8]) {
if cfg!(target_endian = "big") {
write_slice_native!(src, dst, u32, 4);
} else {
write_slice!(src, dst, u32, 4, Self::write_u32);
}
}
#[inline]
fn write_u64_into(src: &[u64], dst: &mut [u8]) {
if cfg!(target_endian = "big") {
write_slice_native!(src, dst, u64, 8);
} else {
write_slice!(src, dst, u64, 8, Self::write_u64);
}
}
#[cfg(feature = "i128")]
#[inline]
fn write_u128_into(src: &[u128], dst: &mut [u8]) {
if cfg!(target_endian = "big") {
write_slice_native!(src, dst, u128, 16);
} else {
write_slice!(src, dst, u128, 16, Self::write_u128);
}
}
#[inline]
fn from_slice_u16(numbers: &mut [u16]) {
if cfg!(target_endian = "little") {
for n in numbers {
*n = n.to_be();
}
}
}
#[inline]
fn from_slice_u32(numbers: &mut [u32]) {
if cfg!(target_endian = "little") {
for n in numbers {
*n = n.to_be();
}
}
}
#[inline]
fn from_slice_u64(numbers: &mut [u64]) {
if cfg!(target_endian = "little") {
for n in numbers {
*n = n.to_be();
}
}
}
#[cfg(feature = "i128")]
#[inline]
fn from_slice_u128(numbers: &mut [u128]) {
if cfg!(target_endian = "little") {
for n in numbers {
*n = n.to_be();
}
}
}
#[inline]
fn from_slice_f32(numbers: &mut [f32]) {
if cfg!(target_endian = "little") {
for n in numbers {
let int: u32 = unsafe { transmute(*n) };
*n = safe_u32_bits_to_f32(int.to_be());
}
}
}
#[inline]
fn from_slice_f64(numbers: &mut [f64]) {
if cfg!(target_endian = "little") {
for n in numbers {
let int: u64 = unsafe { transmute(*n) };
*n = safe_u64_bits_to_f64(int.to_be());
}
}
}
}
impl ByteOrder for LittleEndian {
#[inline]
fn read_u16(buf: &[u8]) -> u16 {
read_num_bytes!(u16, 2, buf, to_le)
}
#[inline]
fn read_u32(buf: &[u8]) -> u32 {
read_num_bytes!(u32, 4, buf, to_le)
}
#[inline]
fn read_u64(buf: &[u8]) -> u64 {
read_num_bytes!(u64, 8, buf, to_le)
}
#[cfg(feature = "i128")]
#[inline]
fn read_u128(buf: &[u8]) -> u128 {
read_num_bytes!(u128, 16, buf, to_le)
}
#[inline]
fn read_uint(buf: &[u8], nbytes: usize) -> u64 {
assert!(1 <= nbytes && nbytes <= 8 && nbytes <= buf.len());
let mut out = [0u8; 8];
let ptr_out = out.as_mut_ptr();
unsafe {
copy_nonoverlapping(buf.as_ptr(), ptr_out, nbytes);
(*(ptr_out as *const u64)).to_le()
}
}
#[cfg(feature = "i128")]
#[inline]
fn read_uint128(buf: &[u8], nbytes: usize) -> u128 {
assert!(1 <= nbytes && nbytes <= 16 && nbytes <= buf.len());
let mut out = [0u8; 16];
let ptr_out = out.as_mut_ptr();
unsafe {
copy_nonoverlapping(buf.as_ptr(), ptr_out, nbytes);
(*(ptr_out as *const u128)).to_le()
}
}
#[inline]
fn write_u16(buf: &mut [u8], n: u16) {
write_num_bytes!(u16, 2, n, buf, to_le);
}
#[inline]
fn write_u32(buf: &mut [u8], n: u32) {
write_num_bytes!(u32, 4, n, buf, to_le);
}
#[inline]
fn write_u64(buf: &mut [u8], n: u64) {
write_num_bytes!(u64, 8, n, buf, to_le);
}
#[cfg(feature = "i128")]
#[inline]
fn write_u128(buf: &mut [u8], n: u128) {
write_num_bytes!(u128, 16, n, buf, to_le);
}
#[inline]
fn write_uint(buf: &mut [u8], n: u64, nbytes: usize) {
assert!(pack_size(n as u64) <= nbytes && nbytes <= 8);
assert!(nbytes <= buf.len());
unsafe {
let bytes: [u8; 8] = transmute(n.to_le());
copy_nonoverlapping(bytes.as_ptr(), buf.as_mut_ptr(), nbytes);
}
}
#[cfg(feature = "i128")]
#[inline]
fn write_uint128(buf: &mut [u8], n: u128, nbytes: usize) {
assert!(pack_size128(n as u128) <= nbytes && nbytes <= 16);
assert!(nbytes <= buf.len());
unsafe {
let bytes: [u8; 16] = transmute(n.to_le());
copy_nonoverlapping(bytes.as_ptr(), buf.as_mut_ptr(), nbytes);
}
}
#[inline]
fn read_u16_into(src: &[u8], dst: &mut [u16]) {
read_slice!(src, dst, 2, to_le);
}
#[inline]
fn read_u32_into(src: &[u8], dst: &mut [u32]) {
read_slice!(src, dst, 4, to_le);
}
#[inline]
fn read_u64_into(src: &[u8], dst: &mut [u64]) {
read_slice!(src, dst, 8, to_le);
}
#[cfg(feature = "i128")]
#[inline]
fn read_u128_into(src: &[u8], dst: &mut [u128]) {
read_slice!(src, dst, 16, to_le);
}
#[inline]
fn write_u16_into(src: &[u16], dst: &mut [u8]) {
if cfg!(target_endian = "little") {
write_slice_native!(src, dst, u16, 2);
} else {
write_slice!(src, dst, u16, 2, Self::write_u16);
}
}
#[inline]
fn write_u32_into(src: &[u32], dst: &mut [u8]) {
if cfg!(target_endian = "little") {
write_slice_native!(src, dst, u32, 4);
} else {
write_slice!(src, dst, u32, 4, Self::write_u32);
}
}
#[inline]
fn write_u64_into(src: &[u64], dst: &mut [u8]) {
if cfg!(target_endian = "little") {
write_slice_native!(src, dst, u64, 8);
} else {
write_slice!(src, dst, u64, 8, Self::write_u64);
}
}
#[cfg(feature = "i128")]
#[inline]
fn write_u128_into(src: &[u128], dst: &mut [u8]) {
if cfg!(target_endian = "little") {
write_slice_native!(src, dst, u128, 16);
} else {
write_slice!(src, dst, u128, 16, Self::write_u128);
}
}
#[inline]
fn from_slice_u16(numbers: &mut [u16]) {
if cfg!(target_endian = "big") {
for n in numbers {
*n = n.to_le();
}
}
}
#[inline]
fn from_slice_u32(numbers: &mut [u32]) {
if cfg!(target_endian = "big") {
for n in numbers {
*n = n.to_le();
}
}
}
#[inline]
fn from_slice_u64(numbers: &mut [u64]) {
if cfg!(target_endian = "big") {
for n in numbers {
*n = n.to_le();
}
}
}
#[cfg(feature = "i128")]
#[inline]
fn from_slice_u128(numbers: &mut [u128]) {
if cfg!(target_endian = "big") {
for n in numbers {
*n = n.to_le();
}
}
}
#[inline]
fn from_slice_f32(numbers: &mut [f32]) {
if cfg!(target_endian = "big") {
for n in numbers {
let int: u32 = unsafe { transmute(*n) };
*n = safe_u32_bits_to_f32(int.to_le());
}
}
}
#[inline]
fn from_slice_f64(numbers: &mut [f64]) {
if cfg!(target_endian = "big") {
for n in numbers {
let int: u64 = unsafe { transmute(*n) };
*n = safe_u64_bits_to_f64(int.to_le());
}
}
}
}
#[inline]
fn safe_u32_bits_to_f32(u: u32) -> f32 {
use core::f32::NAN;
const EXP_MASK: u32 = 0x7F800000;
const FRACT_MASK: u32 = 0x007FFFFF;
if u & EXP_MASK == EXP_MASK && u & FRACT_MASK != 0 {
// While IEEE 754-2008 specifies encodings for quiet NaNs and
// signaling ones, certains MIPS and PA-RISC CPUs treat signaling
// NaNs differently. Therefore, to be safe, we pass a known quiet
// NaN if u is any kind of NaN. The check above only assumes
// IEEE 754-1985 to be valid.
NAN
} else {
unsafe { transmute(u) }
}
}
#[inline]
fn safe_u64_bits_to_f64(u: u64) -> f64 {
use core::f64::NAN;
const EXP_MASK: u64 = 0x7FF0000000000000;
const FRACT_MASK: u64 = 0x000FFFFFFFFFFFFF;
if u & EXP_MASK == EXP_MASK && u & FRACT_MASK != 0 {
// While IEEE 754-2008 specifies encodings for quiet NaNs and
// signaling ones, certains MIPS and PA-RISC CPUs treat signaling
// NaNs differently. Therefore, to be safe, we pass a known quiet
// NaN if u is any kind of NaN. The check above only assumes
// IEEE 754-1985 to be valid.
NAN
} else {
unsafe { transmute(u) }
}
}
//#[cfg(test)]
//mod test {
// extern crate quickcheck;
// extern crate rand;
//
// use self::quickcheck::{QuickCheck, StdGen, Testable};
// use self::rand::thread_rng;
// #[cfg(feature = "i128")] use self::quickcheck::{Arbitrary, Gen};
//
// pub const U24_MAX: u32 = 16_777_215;
// pub const I24_MAX: i32 = 8_388_607;
//
// pub const U64_MAX: u64 = ::core::u64::MAX;
// pub const I64_MAX: u64 = ::core::i64::MAX as u64;
//
// macro_rules! calc_max {
// ($max:expr, $bytes:expr) => { calc_max!($max, $bytes, 8) };
// ($max:expr, $bytes:expr, $maxbytes:expr) => {
// ($max - 1) >> (8 * ($maxbytes - $bytes))
// };
// }
//
// #[derive(Clone, Debug)]
// pub struct Wi128<T>(pub T);
//
// #[cfg(feature = "i128")]
// impl<T: Clone> Wi128<T> {
// pub fn clone(&self) -> T {
// self.0.clone()
// }
// }
//
// impl<T: PartialEq> PartialEq<T> for Wi128<T> {
// fn eq(&self, other: &T) -> bool {
// self.0.eq(other)
// }
// }
//
// #[cfg(feature = "i128")]
// impl Arbitrary for Wi128<u128> {
// fn arbitrary<G: Gen>(gen: &mut G) -> Wi128<u128> {
// let max = calc_max!(::core::u128::MAX, gen.size(), 16);
// let output =
// (gen.gen::<u64>() as u128) |
// ((gen.gen::<u64>() as u128) << 64);
// Wi128(output & (max - 1))
// }
// }
//
// #[cfg(feature = "i128")]
// impl Arbitrary for Wi128<i128> {
// fn arbitrary<G: Gen>(gen: &mut G) -> Wi128<i128> {
// let max = calc_max!(::core::i128::MAX, gen.size(), 16);
// let output =
// (gen.gen::<i64>() as i128) |
// ((gen.gen::<i64>() as i128) << 64);
// Wi128(output & (max - 1))
// }
// }
//
// pub fn qc_sized<A: Testable>(f: A, size: u64) {
// QuickCheck::new()
// .gen(StdGen::new(thread_rng(), size as usize))
// .tests(1_00)
// .max_tests(10_000)
// .quickcheck(f);
// }
//
// macro_rules! qc_byte_order {
// ($name:ident, $ty_int:ty, $max:expr,
// $bytes:expr, $read:ident, $write:ident) => (
// mod $name {
// use {BigEndian, ByteOrder, NativeEndian, LittleEndian};
// #[allow(unused_imports)] use super::{ qc_sized, Wi128 };
//
// #[test]
// fn big_endian() {
// fn prop(n: $ty_int) -> bool {
// let mut buf = [0; 16];
// BigEndian::$write(&mut buf, n.clone(), $bytes);
// n == BigEndian::$read(&mut buf[..$bytes], $bytes)
// }
// qc_sized(prop as fn($ty_int) -> bool, $max);
// }
//
// #[test]
// fn little_endian() {
// fn prop(n: $ty_int) -> bool {
// let mut buf = [0; 16];
// LittleEndian::$write(&mut buf, n.clone(), $bytes);
// n == LittleEndian::$read(&mut buf[..$bytes], $bytes)
// }
// qc_sized(prop as fn($ty_int) -> bool, $max);
// }
//
// #[test]
// fn native_endian() {
// fn prop(n: $ty_int) -> bool {
// let mut buf = [0; 16];
// NativeEndian::$write(&mut buf, n.clone(), $bytes);
// n == NativeEndian::$read(&mut buf[..$bytes], $bytes)
// }
// qc_sized(prop as fn($ty_int) -> bool, $max);
// }
// }
// );
// ($name:ident, $ty_int:ty, $max:expr,
// $read:ident, $write:ident) => (
// mod $name {
// use core::mem::size_of;
// use {BigEndian, ByteOrder, NativeEndian, LittleEndian};
// #[allow(unused_imports)] use super::{ qc_sized, Wi128 };
//
// #[test]
// fn big_endian() {
// fn prop(n: $ty_int) -> bool {
// let bytes = size_of::<$ty_int>();
// let mut buf = [0; 16];
// BigEndian::$write(&mut buf[16 - bytes..], n.clone());
// n == BigEndian::$read(&mut buf[16 - bytes..])
// }
// qc_sized(prop as fn($ty_int) -> bool, $max - 1);
// }
//
// #[test]
// fn little_endian() {
// fn prop(n: $ty_int) -> bool {
// let bytes = size_of::<$ty_int>();
// let mut buf = [0; 16];
// LittleEndian::$write(&mut buf[..bytes], n.clone());
// n == LittleEndian::$read(&mut buf[..bytes])
// }
// qc_sized(prop as fn($ty_int) -> bool, $max - 1);
// }
//
// #[test]
// fn native_endian() {
// fn prop(n: $ty_int) -> bool {
// let bytes = size_of::<$ty_int>();
// let mut buf = [0; 16];
// NativeEndian::$write(&mut buf[..bytes], n.clone());
// n == NativeEndian::$read(&mut buf[..bytes])
// }
// qc_sized(prop as fn($ty_int) -> bool, $max - 1);
// }
// }
// );
// }
//
// qc_byte_order!(prop_u16, u16, ::core::u16::MAX as u64, read_u16, write_u16);
// qc_byte_order!(prop_i16, i16, ::core::i16::MAX as u64, read_i16, write_i16);
// qc_byte_order!(prop_u24, u32, ::test::U24_MAX as u64, read_u24, write_u24);
// qc_byte_order!(prop_i24, i32, ::test::I24_MAX as u64, read_i24, write_i24);
// qc_byte_order!(prop_u32, u32, ::core::u32::MAX as u64, read_u32, write_u32);
// qc_byte_order!(prop_i32, i32, ::core::i32::MAX as u64, read_i32, write_i32);
// qc_byte_order!(prop_u64, u64, ::core::u64::MAX as u64, read_u64, write_u64);
// qc_byte_order!(prop_i64, i64, ::core::i64::MAX as u64, read_i64, write_i64);
// qc_byte_order!(prop_f32, f32, ::core::u64::MAX as u64, read_f32, write_f32);
// qc_byte_order!(prop_f64, f64, ::core::i64::MAX as u64, read_f64, write_f64);
//
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_u128, Wi128<u128>, 16 + 1, read_u128, write_u128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_i128, Wi128<i128>, 16 + 1, read_i128, write_i128);
//
// qc_byte_order!(prop_uint_1,
// u64, calc_max!(super::U64_MAX, 1), 1, read_uint, write_uint);
// qc_byte_order!(prop_uint_2,
// u64, calc_max!(super::U64_MAX, 2), 2, read_uint, write_uint);
// qc_byte_order!(prop_uint_3,
// u64, calc_max!(super::U64_MAX, 3), 3, read_uint, write_uint);
// qc_byte_order!(prop_uint_4,
// u64, calc_max!(super::U64_MAX, 4), 4, read_uint, write_uint);
// qc_byte_order!(prop_uint_5,
// u64, calc_max!(super::U64_MAX, 5), 5, read_uint, write_uint);
// qc_byte_order!(prop_uint_6,
// u64, calc_max!(super::U64_MAX, 6), 6, read_uint, write_uint);
// qc_byte_order!(prop_uint_7,
// u64, calc_max!(super::U64_MAX, 7), 7, read_uint, write_uint);
// qc_byte_order!(prop_uint_8,
// u64, calc_max!(super::U64_MAX, 8), 8, read_uint, write_uint);
//
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_1,
// Wi128<u128>, 1, 1, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_2,
// Wi128<u128>, 2, 2, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_3,
// Wi128<u128>, 3, 3, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_4,
// Wi128<u128>, 4, 4, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_5,
// Wi128<u128>, 5, 5, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_6,
// Wi128<u128>, 6, 6, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_7,
// Wi128<u128>, 7, 7, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_8,
// Wi128<u128>, 8, 8, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_9,
// Wi128<u128>, 9, 9, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_10,
// Wi128<u128>, 10, 10, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_11,
// Wi128<u128>, 11, 11, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_12,
// Wi128<u128>, 12, 12, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_13,
// Wi128<u128>, 13, 13, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_14,
// Wi128<u128>, 14, 14, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_15,
// Wi128<u128>, 15, 15, read_uint128, write_uint128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_uint128_16,
// Wi128<u128>, 16, 16, read_uint128, write_uint128);
//
// qc_byte_order!(prop_int_1,
// i64, calc_max!(super::I64_MAX, 1), 1, read_int, write_int);
// qc_byte_order!(prop_int_2,
// i64, calc_max!(super::I64_MAX, 2), 2, read_int, write_int);
// qc_byte_order!(prop_int_3,
// i64, calc_max!(super::I64_MAX, 3), 3, read_int, write_int);
// qc_byte_order!(prop_int_4,
// i64, calc_max!(super::I64_MAX, 4), 4, read_int, write_int);
// qc_byte_order!(prop_int_5,
// i64, calc_max!(super::I64_MAX, 5), 5, read_int, write_int);
// qc_byte_order!(prop_int_6,
// i64, calc_max!(super::I64_MAX, 6), 6, read_int, write_int);
// qc_byte_order!(prop_int_7,
// i64, calc_max!(super::I64_MAX, 7), 7, read_int, write_int);
// qc_byte_order!(prop_int_8,
// i64, calc_max!(super::I64_MAX, 8), 8, read_int, write_int);
//
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_1,
// Wi128<i128>, 1, 1, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_2,
// Wi128<i128>, 2, 2, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_3,
// Wi128<i128>, 3, 3, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_4,
// Wi128<i128>, 4, 4, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_5,
// Wi128<i128>, 5, 5, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_6,
// Wi128<i128>, 6, 6, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_7,
// Wi128<i128>, 7, 7, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_8,
// Wi128<i128>, 8, 8, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_9,
// Wi128<i128>, 9, 9, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_10,
// Wi128<i128>, 10, 10, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_11,
// Wi128<i128>, 11, 11, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_12,
// Wi128<i128>, 12, 12, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_13,
// Wi128<i128>, 13, 13, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_14,
// Wi128<i128>, 14, 14, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_15,
// Wi128<i128>, 15, 15, read_int128, write_int128);
// #[cfg(feature = "i128")]
// qc_byte_order!(prop_int128_16,
// Wi128<i128>, 16, 16, read_int128, write_int128);
//
//
// // Test that all of the byte conversion functions panic when given a
// // buffer that is too small.
// //
// // These tests are critical to ensure safety, otherwise we might end up
// // with a buffer overflow.
// macro_rules! too_small {
// ($name:ident, $maximally_small:expr, $zero:expr,
// $read:ident, $write:ident) => (
// mod $name {
// use {BigEndian, ByteOrder, NativeEndian, LittleEndian};
//
// #[test]
// #[should_panic]
// fn read_big_endian() {
// let buf = [0; $maximally_small];
// BigEndian::$read(&buf);
// }
//
// #[test]
// #[should_panic]
// fn read_little_endian() {
// let buf = [0; $maximally_small];
// LittleEndian::$read(&buf);
// }
//
// #[test]
// #[should_panic]
// fn read_native_endian() {
// let buf = [0; $maximally_small];
// NativeEndian::$read(&buf);
// }
//
// #[test]
// #[should_panic]
// fn write_big_endian() {
// let mut buf = [0; $maximally_small];
// BigEndian::$write(&mut buf, $zero);
// }
//
// #[test]
// #[should_panic]
// fn write_little_endian() {
// let mut buf = [0; $maximally_small];
// LittleEndian::$write(&mut buf, $zero);
// }
//
// #[test]
// #[should_panic]
// fn write_native_endian() {
// let mut buf = [0; $maximally_small];
// NativeEndian::$write(&mut buf, $zero);
// }
// }
// );
// ($name:ident, $maximally_small:expr, $read:ident) => (
// mod $name {
// use {BigEndian, ByteOrder, NativeEndian, LittleEndian};
//
// #[test]
// #[should_panic]
// fn read_big_endian() {
// let buf = [0; $maximally_small];
// BigEndian::$read(&buf, $maximally_small + 1);
// }
//
// #[test]
// #[should_panic]
// fn read_little_endian() {
// let buf = [0; $maximally_small];
// LittleEndian::$read(&buf, $maximally_small + 1);
// }
//
// #[test]
// #[should_panic]
// fn read_native_endian() {
// let buf = [0; $maximally_small];
// NativeEndian::$read(&buf, $maximally_small + 1);
// }
// }
// );
// }
//
// too_small!(small_u16, 1, 0, read_u16, write_u16);
// too_small!(small_i16, 1, 0, read_i16, write_i16);
// too_small!(small_u32, 3, 0, read_u32, write_u32);
// too_small!(small_i32, 3, 0, read_i32, write_i32);
// too_small!(small_u64, 7, 0, read_u64, write_u64);
// too_small!(small_i64, 7, 0, read_i64, write_i64);
// too_small!(small_f32, 3, 0.0, read_f32, write_f32);
// too_small!(small_f64, 7, 0.0, read_f64, write_f64);
// #[cfg(feature = "i128")]
// too_small!(small_u128, 15, 0, read_u128, write_u128);
// #[cfg(feature = "i128")]
// too_small!(small_i128, 15, 0, read_i128, write_i128);
//
// too_small!(small_uint_1, 1, read_uint);
// too_small!(small_uint_2, 2, read_uint);
// too_small!(small_uint_3, 3, read_uint);
// too_small!(small_uint_4, 4, read_uint);
// too_small!(small_uint_5, 5, read_uint);
// too_small!(small_uint_6, 6, read_uint);
// too_small!(small_uint_7, 7, read_uint);
//
// #[cfg(feature = "i128")]
// too_small!(small_uint128_1, 1, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_2, 2, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_3, 3, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_4, 4, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_5, 5, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_6, 6, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_7, 7, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_8, 8, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_9, 9, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_10, 10, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_11, 11, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_12, 12, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_13, 13, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_14, 14, read_uint128);
// #[cfg(feature = "i128")]
// too_small!(small_uint128_15, 15, read_uint128);
//
// too_small!(small_int_1, 1, read_int);
// too_small!(small_int_2, 2, read_int);
// too_small!(small_int_3, 3, read_int);
// too_small!(small_int_4, 4, read_int);
// too_small!(small_int_5, 5, read_int);
// too_small!(small_int_6, 6, read_int);
// too_small!(small_int_7, 7, read_int);
//
// #[cfg(feature = "i128")]
// too_small!(small_int128_1, 1, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_2, 2, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_3, 3, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_4, 4, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_5, 5, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_6, 6, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_7, 7, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_8, 8, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_9, 9, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_10, 10, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_11, 11, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_12, 12, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_13, 13, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_14, 14, read_int128);
// #[cfg(feature = "i128")]
// too_small!(small_int128_15, 15, read_int128);
//
// // Test that reading/writing slices enforces the correct lengths.
// macro_rules! slice_lengths {
// ($name:ident, $read:ident, $write:ident,
// $num_bytes:expr, $numbers:expr) => {
// mod $name {
// use {ByteOrder, BigEndian, NativeEndian, LittleEndian};
//
// #[test]
// #[should_panic]
// fn read_big_endian() {
// let bytes = [0; $num_bytes];
// let mut numbers = $numbers;
// BigEndian::$read(&bytes, &mut numbers);
// }
//
// #[test]
// #[should_panic]
// fn read_little_endian() {
// let bytes = [0; $num_bytes];
// let mut numbers = $numbers;
// LittleEndian::$read(&bytes, &mut numbers);
// }
//
// #[test]
// #[should_panic]
// fn read_native_endian() {
// let bytes = [0; $num_bytes];
// let mut numbers = $numbers;
// NativeEndian::$read(&bytes, &mut numbers);
// }
//
// #[test]
// #[should_panic]
// fn write_big_endian() {
// let mut bytes = [0; $num_bytes];
// let numbers = $numbers;
// BigEndian::$write(&numbers, &mut bytes);
// }
//
// #[test]
// #[should_panic]
// fn write_little_endian() {
// let mut bytes = [0; $num_bytes];
// let numbers = $numbers;
// LittleEndian::$write(&numbers, &mut bytes);
// }
//
// #[test]
// #[should_panic]
// fn write_native_endian() {
// let mut bytes = [0; $num_bytes];
// let numbers = $numbers;
// NativeEndian::$write(&numbers, &mut bytes);
// }
// }
// }
// }
//
// slice_lengths!(
// slice_len_too_small_u16, read_u16_into, write_u16_into, 3, [0, 0]);
// slice_lengths!(
// slice_len_too_big_u16, read_u16_into, write_u16_into, 5, [0, 0]);
// slice_lengths!(
// slice_len_too_small_i16, read_i16_into, write_i16_into, 3, [0, 0]);
// slice_lengths!(
// slice_len_too_big_i16, read_i16_into, write_i16_into, 5, [0, 0]);
//
// slice_lengths!(
// slice_len_too_small_u32, read_u32_into, write_u32_into, 7, [0, 0]);
// slice_lengths!(
// slice_len_too_big_u32, read_u32_into, write_u32_into, 9, [0, 0]);
// slice_lengths!(
// slice_len_too_small_i32, read_i32_into, write_i32_into, 7, [0, 0]);
// slice_lengths!(
// slice_len_too_big_i32, read_i32_into, write_i32_into, 9, [0, 0]);
//
// slice_lengths!(
// slice_len_too_small_u64, read_u64_into, write_u64_into, 15, [0, 0]);
// slice_lengths!(
// slice_len_too_big_u64, read_u64_into, write_u64_into, 17, [0, 0]);
// slice_lengths!(
// slice_len_too_small_i64, read_i64_into, write_i64_into, 15, [0, 0]);
// slice_lengths!(
// slice_len_too_big_i64, read_i64_into, write_i64_into, 17, [0, 0]);
//
// #[cfg(feature = "i128")]
// slice_lengths!(
// slice_len_too_small_u128, read_u128_into, write_u128_into, 31, [0, 0]);
// #[cfg(feature = "i128")]
// slice_lengths!(
// slice_len_too_big_u128, read_u128_into, write_u128_into, 33, [0, 0]);
// #[cfg(feature = "i128")]
// slice_lengths!(
// slice_len_too_small_i128, read_i128_into, write_i128_into, 31, [0, 0]);
// #[cfg(feature = "i128")]
// slice_lengths!(
// slice_len_too_big_i128, read_i128_into, write_i128_into, 33, [0, 0]);
//
// #[test]
// fn uint_bigger_buffer() {
// use {ByteOrder, LittleEndian};
// let n = LittleEndian::read_uint(&[1, 2, 3, 4, 5, 6, 7, 8], 5);
// assert_eq!(n, 0x0504030201);
// }
//
// #[test]
// fn read_snan() {
// use core::f32;
// use core::f64;
// use core::mem::transmute;
//
// use {ByteOrder, BigEndian, LittleEndian};
//
// let sf = BigEndian::read_f32(&[0xFF, 0x80, 0x00, 0x01]);
// let sbits: u32 = unsafe { transmute(sf) };
// assert_eq!(sbits, unsafe { transmute(f32::NAN) });
// assert_eq!(sf.classify(), ::core::num::FpCategory::Nan);
//
// let df = BigEndian::read_f64(&[0x7F, 0xF0, 0, 0, 0, 0, 0, 0x01]);
// let dbits: u64 = unsafe { ::core::mem::transmute(df) };
// assert_eq!(dbits, unsafe { transmute(f64::NAN) });
// assert_eq!(df.classify(), ::core::num::FpCategory::Nan);
//
// let sf = LittleEndian::read_f32(&[0x01, 0x00, 0x80, 0xFF]);
// let sbits: u32 = unsafe { transmute(sf) };
// assert_eq!(sbits, unsafe { transmute(f32::NAN) });
// assert_eq!(sf.classify(), ::core::num::FpCategory::Nan);
//
// let df = LittleEndian::read_f64(&[0x01, 0, 0, 0, 0, 0, 0xF0, 0x7F]);
// let dbits: u64 = unsafe { ::core::mem::transmute(df) };
// assert_eq!(dbits, unsafe { transmute(f64::NAN) });
// assert_eq!(df.classify(), ::core::num::FpCategory::Nan);
// }
//}
//#[cfg(test)]
//#[cfg(feature = "std")]
//mod stdtests {
// extern crate quickcheck;
// extern crate rand;
//
// use self::quickcheck::{QuickCheck, StdGen, Testable};
// use self::rand::thread_rng;
//
// fn qc_unsized<A: Testable>(f: A) {
//
// QuickCheck::new()
// .gen(StdGen::new(thread_rng(), 16))
// .tests(1_00)
// .max_tests(10_000)
// .quickcheck(f);
// }
//
// macro_rules! calc_max {
// ($max:expr, $bytes:expr) => { ($max - 1) >> (8 * (8 - $bytes)) };
// }
//
// macro_rules! qc_bytes_ext {
// ($name:ident, $ty_int:ty, $max:expr,
// $bytes:expr, $read:ident, $write:ident) => (
// mod $name {
// use std::io::Cursor;
// use {
// ReadBytesExt, WriteBytesExt,
// BigEndian, NativeEndian, LittleEndian,
// };
// #[allow(unused_imports)] use test::{qc_sized, Wi128};
//
// #[test]
// fn big_endian() {
// fn prop(n: $ty_int) -> bool {
// let mut wtr = vec![];
// wtr.$write::<BigEndian>(n.clone()).unwrap();
// let mut rdr = Vec::new();
// rdr.extend(wtr[wtr.len()-$bytes..].iter().map(|&x| x));
// let mut rdr = Cursor::new(rdr);
// n == rdr.$read::<BigEndian>($bytes).unwrap()
// }
// qc_sized(prop as fn($ty_int) -> bool, $max);
// }
//
// #[test]
// fn little_endian() {
// fn prop(n: $ty_int) -> bool {
// let mut wtr = vec![];
// wtr.$write::<LittleEndian>(n.clone()).unwrap();
// let mut rdr = Cursor::new(wtr);
// n == rdr.$read::<LittleEndian>($bytes).unwrap()
// }
// qc_sized(prop as fn($ty_int) -> bool, $max);
// }
//
// #[test]
// fn native_endian() {
// fn prop(n: $ty_int) -> bool {
// let mut wtr = vec![];
// wtr.$write::<NativeEndian>(n.clone()).unwrap();
// let mut rdr = Cursor::new(wtr);
// n == rdr.$read::<NativeEndian>($bytes).unwrap()
// }
// qc_sized(prop as fn($ty_int) -> bool, $max);
// }
// }
// );
// ($name:ident, $ty_int:ty, $max:expr, $read:ident, $write:ident) => (
// mod $name {
// use std::io::Cursor;
// use {
// ReadBytesExt, WriteBytesExt,
// BigEndian, NativeEndian, LittleEndian,
// };
// #[allow(unused_imports)] use test::{qc_sized, Wi128};
//
// #[test]
// fn big_endian() {
// fn prop(n: $ty_int) -> bool {
// let mut wtr = vec![];
// wtr.$write::<BigEndian>(n.clone()).unwrap();
// let mut rdr = Cursor::new(wtr);
// n == rdr.$read::<BigEndian>().unwrap()
// }
// qc_sized(prop as fn($ty_int) -> bool, $max - 1);
// }
//
// #[test]
// fn little_endian() {
// fn prop(n: $ty_int) -> bool {
// let mut wtr = vec![];
// wtr.$write::<LittleEndian>(n.clone()).unwrap();
// let mut rdr = Cursor::new(wtr);
// n == rdr.$read::<LittleEndian>().unwrap()
// }
// qc_sized(prop as fn($ty_int) -> bool, $max - 1);
// }
//
// #[test]
// fn native_endian() {
// fn prop(n: $ty_int) -> bool {
// let mut wtr = vec![];
// wtr.$write::<NativeEndian>(n.clone()).unwrap();
// let mut rdr = Cursor::new(wtr);
// n == rdr.$read::<NativeEndian>().unwrap()
// }
// qc_sized(prop as fn($ty_int) -> bool, $max - 1);
// }
// }
// );
// }
//
// qc_bytes_ext!(prop_ext_u16,
// u16, ::std::u16::MAX as u64, read_u16, write_u16);
// qc_bytes_ext!(prop_ext_i16,
// i16, ::std::i16::MAX as u64, read_i16, write_i16);
// qc_bytes_ext!(prop_ext_u32,
// u32, ::std::u32::MAX as u64, read_u32, write_u32);
// qc_bytes_ext!(prop_ext_i32,
// i32, ::std::i32::MAX as u64, read_i32, write_i32);
// qc_bytes_ext!(prop_ext_u64,
// u64, ::std::u64::MAX as u64, read_u64, write_u64);
// qc_bytes_ext!(prop_ext_i64,
// i64, ::std::i64::MAX as u64, read_i64, write_i64);
// qc_bytes_ext!(prop_ext_f32,
// f32, ::std::u64::MAX as u64, read_f32, write_f32);
// qc_bytes_ext!(prop_ext_f64,
// f64, ::std::i64::MAX as u64, read_f64, write_f64);
//
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_u128, Wi128<u128>, 16 + 1, read_u128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_i128, Wi128<i128>, 16 + 1, read_i128, write_i128);
//
// qc_bytes_ext!(prop_ext_uint_1,
// u64, calc_max!(::test::U64_MAX, 1), 1, read_uint, write_u64);
// qc_bytes_ext!(prop_ext_uint_2,
// u64, calc_max!(::test::U64_MAX, 2), 2, read_uint, write_u64);
// qc_bytes_ext!(prop_ext_uint_3,
// u64, calc_max!(::test::U64_MAX, 3), 3, read_uint, write_u64);
// qc_bytes_ext!(prop_ext_uint_4,
// u64, calc_max!(::test::U64_MAX, 4), 4, read_uint, write_u64);
// qc_bytes_ext!(prop_ext_uint_5,
// u64, calc_max!(::test::U64_MAX, 5), 5, read_uint, write_u64);
// qc_bytes_ext!(prop_ext_uint_6,
// u64, calc_max!(::test::U64_MAX, 6), 6, read_uint, write_u64);
// qc_bytes_ext!(prop_ext_uint_7,
// u64, calc_max!(::test::U64_MAX, 7), 7, read_uint, write_u64);
// qc_bytes_ext!(prop_ext_uint_8,
// u64, calc_max!(::test::U64_MAX, 8), 8, read_uint, write_u64);
//
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_1,
// Wi128<u128>, 1, 1, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_2,
// Wi128<u128>, 2, 2, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_3,
// Wi128<u128>, 3, 3, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_4,
// Wi128<u128>, 4, 4, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_5,
// Wi128<u128>, 5, 5, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_6,
// Wi128<u128>, 6, 6, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_7,
// Wi128<u128>, 7, 7, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_8,
// Wi128<u128>, 8, 8, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_9,
// Wi128<u128>, 9, 9, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_10,
// Wi128<u128>, 10, 10, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_11,
// Wi128<u128>, 11, 11, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_12,
// Wi128<u128>, 12, 12, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_13,
// Wi128<u128>, 13, 13, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_14,
// Wi128<u128>, 14, 14, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_15,
// Wi128<u128>, 15, 15, read_uint128, write_u128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_uint128_16,
// Wi128<u128>, 16, 16, read_uint128, write_u128);
//
// qc_bytes_ext!(prop_ext_int_1,
// i64, calc_max!(::test::I64_MAX, 1), 1, read_int, write_i64);
// qc_bytes_ext!(prop_ext_int_2,
// i64, calc_max!(::test::I64_MAX, 2), 2, read_int, write_i64);
// qc_bytes_ext!(prop_ext_int_3,
// i64, calc_max!(::test::I64_MAX, 3), 3, read_int, write_i64);
// qc_bytes_ext!(prop_ext_int_4,
// i64, calc_max!(::test::I64_MAX, 4), 4, read_int, write_i64);
// qc_bytes_ext!(prop_ext_int_5,
// i64, calc_max!(::test::I64_MAX, 5), 5, read_int, write_i64);
// qc_bytes_ext!(prop_ext_int_6,
// i64, calc_max!(::test::I64_MAX, 6), 6, read_int, write_i64);
// qc_bytes_ext!(prop_ext_int_7,
// i64, calc_max!(::test::I64_MAX, 1), 7, read_int, write_i64);
// qc_bytes_ext!(prop_ext_int_8,
// i64, calc_max!(::test::I64_MAX, 8), 8, read_int, write_i64);
//
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_1,
// Wi128<i128>, 1, 1, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_2,
// Wi128<i128>, 2, 2, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_3,
// Wi128<i128>, 3, 3, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_4,
// Wi128<i128>, 4, 4, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_5,
// Wi128<i128>, 5, 5, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_6,
// Wi128<i128>, 6, 6, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_7,
// Wi128<i128>, 7, 7, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_8,
// Wi128<i128>, 8, 8, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_9,
// Wi128<i128>, 9, 9, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_10,
// Wi128<i128>, 10, 10, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_11,
// Wi128<i128>, 11, 11, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_12,
// Wi128<i128>, 12, 12, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_13,
// Wi128<i128>, 13, 13, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_14,
// Wi128<i128>, 14, 14, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_15,
// Wi128<i128>, 15, 15, read_int128, write_i128);
// #[cfg(feature = "i128")]
// qc_bytes_ext!(prop_ext_int128_16,
// Wi128<i128>, 16, 16, read_int128, write_i128);
//
// // Test slice serialization/deserialization.
// macro_rules! qc_slice {
// ($name:ident, $ty_int:ty, $read:ident, $write:ident, $zero:expr) => {
// mod $name {
// use core::mem::size_of;
// use {ByteOrder, BigEndian, NativeEndian, LittleEndian};
// use super::qc_unsized;
// #[allow(unused_imports)]
// use test::Wi128;
//
// #[test]
// fn big_endian() {
// #[allow(unused_unsafe)]
// fn prop(numbers: Vec<$ty_int>) -> bool {
// let numbers: Vec<_> = numbers
// .into_iter()
// .map(|x| x.clone())
// .collect();
// let num_bytes = size_of::<$ty_int>() * numbers.len();
// let mut bytes = vec![0; num_bytes];
//
// BigEndian::$write(&numbers, &mut bytes);
//
// let mut got = vec![$zero; numbers.len()];
// unsafe { BigEndian::$read(&bytes, &mut got); }
//
// numbers == got
// }
// qc_unsized(prop as fn(_) -> bool);
// }
//
// #[test]
// fn little_endian() {
// #[allow(unused_unsafe)]
// fn prop(numbers: Vec<$ty_int>) -> bool {
// let numbers: Vec<_> = numbers
// .into_iter()
// .map(|x| x.clone())
// .collect();
// let num_bytes = size_of::<$ty_int>() * numbers.len();
// let mut bytes = vec![0; num_bytes];
//
// LittleEndian::$write(&numbers, &mut bytes);
//
// let mut got = vec![$zero; numbers.len()];
// unsafe { LittleEndian::$read(&bytes, &mut got); }
//
// numbers == got
// }
// qc_unsized(prop as fn(_) -> bool);
// }
//
// #[test]
// fn native_endian() {
// #[allow(unused_unsafe)]
// fn prop(numbers: Vec<$ty_int>) -> bool {
// let numbers: Vec<_> = numbers
// .into_iter()
// .map(|x| x.clone())
// .collect();
// let num_bytes = size_of::<$ty_int>() * numbers.len();
// let mut bytes = vec![0; num_bytes];
//
// NativeEndian::$write(&numbers, &mut bytes);
//
// let mut got = vec![$zero; numbers.len()];
// unsafe { NativeEndian::$read(&bytes, &mut got); }
//
// numbers == got
// }
// qc_unsized(prop as fn(_) -> bool);
// }
// }
// }
// }
//
// qc_slice!(prop_slice_u16, u16, read_u16_into, write_u16_into, 0);
// qc_slice!(prop_slice_i16, i16, read_i16_into, write_i16_into, 0);
// qc_slice!(prop_slice_u32, u32, read_u32_into, write_u32_into, 0);
// qc_slice!(prop_slice_i32, i32, read_i32_into, write_i32_into, 0);
// qc_slice!(prop_slice_u64, u64, read_u64_into, write_u64_into, 0);
// qc_slice!(prop_slice_i64, i64, read_i64_into, write_i64_into, 0);
// #[cfg(feature = "i128")]
// qc_slice!(
// prop_slice_u128, Wi128<u128>, read_u128_into, write_u128_into, 0);
// #[cfg(feature = "i128")]
// qc_slice!(
// prop_slice_i128, Wi128<i128>, read_i128_into, write_i128_into, 0);
//
// qc_slice!(
// prop_slice_f32, f32, read_f32_into_unchecked, write_f32_into, 0.0);
// qc_slice!(
// prop_slice_f64, f64, read_f64_into_unchecked, write_f64_into, 0.0);
//}