extern crate lebe;
use lebe::prelude::*;
use std::mem;
use byteorder::{WriteBytesExt, LittleEndian, BigEndian, ReadBytesExt};
#[test]
fn make_le_u32_slice() {
let n = 0x1Au32;
let mut n_le = [n];
n_le.convert_current_to_little_endian();
if cfg!(target_endian = "little") {
assert_eq!(n_le, [n])
}
else {
assert_eq!(n_le, [u32::swap_bytes(n)])
}
}
#[test]
fn make_be_u32_slice() {
let n = 0x1Au32;
let mut n_be = [n];
n_be.convert_current_to_big_endian();
if cfg!(target_endian = "big") {
assert_eq!(n_be, [n])
}
else {
assert_eq!(n_be, [n.swap_bytes()])
}
}
#[test]
fn make_le_u16_slice() {
let n = 0x1Au16;
let mut n_le = [n];
n_le.convert_current_to_little_endian();
if cfg!(target_endian = "little") {
assert_eq!(n_le, [n])
}
else {
assert_eq!(n_le, [n.swap_bytes()])
}
}
#[test]
fn make_le_i64_slice() {
let n1 = 0x14F3EEBCCD93895A_i64;
let n2 = 0x114F3EF99B81CC5A_i64;
let mut n_be = [n1, n2];
n_be.convert_current_to_big_endian();
if cfg!(target_endian = "big") {
assert_eq!(n_be, [n1, n2])
}
else {
assert_eq!(n_be, [n1.swap_bytes(), n2.swap_bytes()])
}
}
#[test]
fn make_be_f64() {
let i = 0x14F3EEBCCD93895A_u64;
let mut f: f64 = unsafe { mem::transmute(i) };
f.convert_current_to_big_endian();
assert_eq!(f, unsafe { mem::transmute(i.to_be()) })
}
#[test]
fn into_be_f64() {
let i = 0x14F3EEBCCD93895A_u64;
let f: f64 = unsafe { mem::transmute(i) };
let f = f.from_current_into_big_endian();
assert_eq!(f, unsafe { mem::transmute(i.to_be()) })
}
#[test]
fn into_be_i16() {
let i = 0x195A_i16;
let be = i.from_current_into_big_endian();
if cfg!(target_endian = "big") {
assert_eq!(be, i)
}
else {
assert_eq!(be, i.swap_bytes())
}
}
#[test]
fn into_be_u32() {
let i = 0x1220943_u32;
let be = i.from_current_into_big_endian();
if cfg!(target_endian = "big") {
assert_eq!(be, i)
}
else {
assert_eq!(be, i.swap_bytes())
}
}
#[test]
fn cmp_read_be_u16() {
let read: &[u8] = &[0x33, 0xbb];
let a = u16::read_from_big_endian(&mut read.clone()).unwrap();
let b: u16 = read.clone().read_from_big_endian().unwrap();
let c = read.clone().read_u16::<BigEndian>().unwrap();
assert_eq!(a, b);
assert_eq!(a, c);
}
#[test]
fn cmp_read_le_u16() {
let read: &[u8] = &[0x33, 0xbb];
let a = u16::read_from_little_endian(&mut read.clone()).unwrap();
let b: u16 = read.clone().read_from_little_endian().unwrap();
let c = read.clone().read_u16::<LittleEndian>().unwrap();
assert_eq!(a, b);
assert_eq!(a, c);
}
#[test]
fn cmp_read_le_f32() {
let read: &[u8] = &[0x33, 0xBB, 0x44, 0xCC];
let a = f32::read_from_little_endian(&mut read.clone()).unwrap();
let b: f32 = read.clone().read_from_little_endian().unwrap();
let c = read.clone().read_f32::<LittleEndian>().unwrap();
assert_eq!(a, b);
assert_eq!(a, c);
}
#[test]
fn cmp_read_be_slice() {
let mut write_expected = Vec::new();
let mut write_actual = Vec::new();
let data: Vec<f32> = (0..31*31).map(|i| i as f32).collect();
for number in &data {
write_expected.write_f32::<BigEndian>(*number).unwrap();
}
write_actual.write_as_big_endian(data.as_slice()).unwrap();
assert_eq!(write_actual, write_expected);
}
#[test]
fn cmp_write_le_slice() {
let mut write_expected = Vec::new();
let mut write_actual = Vec::new();
let data: Vec<f32> = (0..31*31).map(|i| i as f32).collect();
for number in &data {
write_expected.write_f32::<LittleEndian>(*number).unwrap();
}
write_actual.write_as_little_endian(data.as_slice()).unwrap();
assert_eq!(write_actual, write_expected);
}
#[test]
fn cmp_write_le_u32() {
let mut write_expected = Vec::new();
let mut write_actual = Vec::new();
let data = 0x23573688_u32;
write_expected.write_u32::<LittleEndian>(data).unwrap();
write_actual.write_as_little_endian(&data).unwrap();
assert_eq!(write_actual, write_expected);
}
#[test]
fn cmp_write_le_slice_u64() {
let mut write_expected = Vec::new();
let mut write_actual = Vec::new();
let data: Vec<u64> = (1000..1000+310*31).map(|i| i as u64).collect();
for number in &data {
write_expected.write_u64::<LittleEndian>(*number).unwrap();
}
write_actual.write_as_little_endian(data.as_slice()).unwrap();
assert_eq!(write_actual, write_expected);
}