// Copyright (c) 2015 Andrew Gallant
use std::io;
use std::io::Result;
use std::ptr::copy_nonoverlapping;
#[ derive(Copy, Clone)]
pub struct LittleEndian;
#[ derive(Copy, Clone)]
pub struct BigEndian;
#[ cfg(target_endian =
"little" )]
pub type NativeEndian = LittleEndian;
#[ cfg(target_endian =
"big" )]
pub type NativeEndian = BigEndian;
macro_rules! read_num_bytes {
($ty:ty, $size:expr, $src:expr, $which:ident) => {{
assert!($size == ::std::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 u
8, $size);
}
data.$which()
}};
}
macro_rules! write_num_bytes {
($ty:ty, $size:expr, $n:expr, $dst:expr, $which:ident) => {{
assert!($size <= $dst.len());
unsafe {
// N.B. https://github.com/rust-lang/rust/issues/22776
let bytes = *(&$n.$which() as *const _ as *const [u8; $size]);
copy_nonoverlapping((&bytes).as_ptr(), $dst.as_mut_ptr(), $size);
}
}};
}
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)
}
#[ 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);
}
serde_if_integer128! {
#[ inline]
fn write_u128(buf: &mut [u8], n: u128) {
write_num_bytes!(u128, 16 , n, buf, to_le);
}
#[ inline]
fn read_u128(buf: &[u8]) -> u128 {
read_num_bytes!(u128, 16 , buf, to_le)
}
}
}
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)
}
#[ 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);
}
serde_if_integer128! {
#[ inline]
fn write_u128(buf: &mut [u8], n: u128) {
write_num_bytes!(u128, 16 , n, buf, to_be);
}
#[ inline]
fn read_u128(buf: &[u8]) -> u128 {
read_num_bytes!(u128, 16 , buf, to_be)
}
}
}
pub trait ByteOrder: Clone + Copy {
fn read_u16(buf: &[u8]) -> u16;
fn read_u32(buf: &[u8]) -> u32;
fn read_u64(buf: &[u8]) -> u64;
fn write_u16(buf: &mut [u8], n: u16);
fn write_u32(buf: &mut [u8], n: u32);
fn write_u64(buf: &mut [u8], n: u64);
#[ inline]
fn read_i16(buf: &[u8]) -> i16 {
Self ::read_u16(buf) as i16
}
#[ inline]
fn read_i32(buf: &[u8]) -> i32 {
Self ::read_u32(buf) as i32
}
#[ inline]
fn read_i64(buf: &[u8]) -> i64 {
Self ::read_u64(buf) as i64
}
#[ inline]
fn read_f32(buf: &[u8]) -> f32 {
unsafe { *(&Self ::read_u32(buf) as *const u32 as *const f32) }
}
#[ inline]
fn read_f64(buf: &[u8]) -> f64 {
unsafe { *(&Self ::read_u64(buf) as *const u64 as *const f64) }
}
#[ inline]
fn write_i16(buf: &mut [u8], n: i16) {
Self ::write_u16(buf, n as u16)
}
#[ inline]
fn write_i32(buf: &mut [u8], n: i32) {
Self ::write_u32(buf, n as u32)
}
#[ inline]
fn write_i64(buf: &mut [u8], n: i64) {
Self ::write_u64(buf, n as u64)
}
#[ inline]
fn write_f32(buf: &mut [u8], n: f32) {
let n = unsafe { *(&n as *const f32 as *const u32) };
Self ::write_u32(buf, n)
}
#[ inline]
fn write_f64(buf: &mut [u8], n: f64) {
let n = unsafe { *(&n as *const f64 as *const u64) };
Self ::write_u64(buf, n)
}
serde_if_integer128! {
fn read_u128(buf: &[u8]) -> u128;
fn write_u128(buf: &mut [u8], n: u128);
#[ inline]
fn read_i128(buf: &[u8]) -> i128 {
Self ::read_u128(buf) as i128
}
#[ inline]
fn write_i128(buf: &mut [u8], n: i128) {
Self ::write_u128(buf, n as u128)
}
}
}
pub trait ReadBytesExt: io::Read {
#[ inline]
fn read_u8(&mut self ) -> Result<u8> {
let mut buf = [0 ; 1 ];
try !(self .read_exact(&mut buf));
Ok(buf[0 ])
}
#[ inline]
fn read_i8(&mut self ) -> Result<i8> {
let mut buf = [0 ; 1 ];
try !(self .read_exact(&mut buf));
Ok(buf[0 ] as i8)
}
#[ inline]
fn read_u16<T: ByteOrder>(&mut self ) -> Result<u16> {
let mut buf = [0 ; 2 ];
try !(self .read_exact(&mut buf));
Ok(T::read_u16(&buf))
}
#[ inline]
fn read_i16<T: ByteOrder>(&mut self ) -> Result<i16> {
let mut buf = [0 ; 2 ];
try !(self .read_exact(&mut buf));
Ok(T::read_i16(&buf))
}
#[ inline]
fn read_u32<T: ByteOrder>(&mut self ) -> Result<u32> {
let mut buf = [0 ; 4 ];
try !(self .read_exact(&mut buf));
Ok(T::read_u32(&buf))
}
#[ inline]
fn read_i32<T: ByteOrder>(&mut self ) -> Result<i32> {
let mut buf = [0 ; 4 ];
try !(self .read_exact(&mut buf));
Ok(T::read_i32(&buf))
}
#[ inline]
fn read_u64<T: ByteOrder>(&mut self ) -> Result<u64> {
let mut buf = [0 ; 8 ];
try !(self .read_exact(&mut buf));
Ok(T::read_u64(&buf))
}
#[ inline]
fn read_i64<T: ByteOrder>(&mut self ) -> Result<i64> {
let mut buf = [0 ; 8 ];
try !(self .read_exact(&mut buf));
Ok(T::read_i64(&buf))
}
#[ inline]
fn read_f32<T: ByteOrder>(&mut self ) -> Result<f32> {
let mut buf = [0 ; 4 ];
try !(self .read_exact(&mut buf));
Ok(T::read_f32(&buf))
}
#[ inline]
fn read_f64<T: ByteOrder>(&mut self ) -> Result<f64> {
let mut buf = [0 ; 8 ];
try !(self .read_exact(&mut buf));
Ok(T::read_f64(&buf))
}
serde_if_integer128! {
#[ inline]
fn read_u128<T: ByteOrder>(&mut self ) -> Result<u128> {
let mut buf = [0 ; 16 ];
try !(self .read_exact(&mut buf));
Ok(T::read_u128(&buf))
}
#[ inline]
fn read_i128<T: ByteOrder>(&mut self ) -> Result<i128> {
let mut buf = [0 ; 16 ];
try !(self .read_exact(&mut buf));
Ok(T::read_i128(&buf))
}
}
}
impl <R: io::Read + ?Sized> ReadBytesExt for R {}
pub trait WriteBytesExt: io::Write {
#[ inline]
fn write_u8(&mut self , n: u8) -> Result<()> {
self .write_all(&[n])
}
#[ inline]
fn write_i8(&mut self , n: i8) -> Result<()> {
self .write_all(&[n as u8])
}
#[ inline]
fn write_u16<T: ByteOrder>(&mut self , n: u16) -> Result<()> {
let mut buf = [0 ; 2 ];
T::write_u16(&mut buf, n);
self .write_all(&buf)
}
#[ inline]
fn write_i16<T: ByteOrder>(&mut self , n: i16) -> Result<()> {
let mut buf = [0 ; 2 ];
T::write_i16(&mut buf, n);
self .write_all(&buf)
}
#[ inline]
fn write_u32<T: ByteOrder>(&mut self , n: u32) -> Result<()> {
let mut buf = [0 ; 4 ];
T::write_u32(&mut buf, n);
self .write_all(&buf)
}
#[ inline]
fn write_i32<T: ByteOrder>(&mut self , n: i32) -> Result<()> {
let mut buf = [0 ; 4 ];
T::write_i32(&mut buf, n);
self .write_all(&buf)
}
#[ inline]
fn write_u64<T: ByteOrder>(&mut self , n: u64) -> Result<()> {
let mut buf = [0 ; 8 ];
T::write_u64(&mut buf, n);
self .write_all(&buf)
}
#[ inline]
fn write_i64<T: ByteOrder>(&mut self , n: i64) -> Result<()> {
let mut buf = [0 ; 8 ];
T::write_i64(&mut buf, n);
self .write_all(&buf)
}
#[ inline]
fn write_f32<T: ByteOrder>(&mut self , n: f32) -> Result<()> {
let mut buf = [0 ; 4 ];
T::write_f32(&mut buf, n);
self .write_all(&buf)
}
#[ inline]
fn write_f64<T: ByteOrder>(&mut self , n: f64) -> Result<()> {
let mut buf = [0 ; 8 ];
T::write_f64(&mut buf, n);
self .write_all(&buf)
}
serde_if_integer128! {
#[ inline]
fn write_u128<T: ByteOrder>(&mut self , n: u128) -> Result<()> {
let mut buf = [0 ; 16 ];
T::write_u128(&mut buf, n);
self .write_all(&buf)
}
#[ inline]
fn write_i128<T: ByteOrder>(&mut self , n: i128) -> Result<()> {
let mut buf = [0 ; 16 ];
T::write_i128(&mut buf, n);
self .write_all(&buf)
}
}
}
impl <W: io::Write + ?Sized> WriteBytesExt for W {}
Messung V0.5 in Prozent C=100 H=97 G=98
¤ Dauer der Verarbeitung: 0.13 Sekunden
(vorverarbeitet am 2026-06-19)
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