Collection of common functions used for other projects. Additional functionality added as more projects are spun up.
Current features relate to:
* Base64 encoding/decoding
* Hex encoding/decoding
* Bit manipulation
* In-set checking (values within a set of ranges)
- b64 - structs, methods and traits for working with b64 encoding/decoding
fn main() {
use cj_common::prelude::*;
let mut s2 = String::new();
for c in "Many hands make light work.".iter_to_b64() {
s2.push(c);
}
assert_eq!(s2.as_str(), "TWFueSBoYW5kcyBtYWtlIGxpZ2h0IHdvcmsu");
}fn main() {
use cj_common::prelude::*;
let mut v = Vec::new();
for b in "TWFueSBoYW5kcyBtYWtlIGxpZ2h0IHdvcmsu".iter_b64_to_byte() {
v.push(b);
}
assert!(v.len() > 0);
let r = String::from_utf8_lossy(v.as_slice());
let s = "Many hands make light work.";
assert_eq!(r.to_string().as_str(), s);
}- hex - structs, methods and traits for working with hex encoding/decoding
Note that uppercase hex is the default output. Lowercase is supported too and most methods have a corresponding _low() implementation. For example, calling to_hex_be_low() instead of to_hex_be() will result in lowercase output
fn main() {
use cj_common::prelude::*;
let x = 0x1F2i64;
let s = x.to_hex_be();
x.to_hex_be_low();
let y: Option<i64> = i64::from_hex_be(s.as_str());
assert!(y.is_some());
assert_eq!(x, y.unwrap());
let x = 0x1F2i64;
let s = x.to_hex_le();
let y: Option<i64> = i64::from_hex_le(s.as_str());
assert!(y.is_some());
assert_eq!(x, y.unwrap());
}fn main() {
use cj_common::prelude::*;
let mut s = String::new();
for c in "Many hands make light work.".iter_to_hex() {
s.push_str(c);
}
assert_eq!(
s.as_str(),
"4D616E792068616E6473206D616B65206C6967687420776F726B2E"
);
let mut v = Vec::new();
for b in s.as_str().iter_hex_to_byte() {
v.push(b);
}
let s2 = String::from_utf8_lossy(v.as_slice()).to_string();
assert_eq!(s2.as_str(), "Many hands make light work.");
}- bitbuf - structs, methods and traits for getting/setting bits at given positions of the implemented types
fn main() {
use cj_common::prelude::*;
let x = 0b00000010u8;
assert_eq!(x.get_bit(1), true);
}fn main() {
use cj_common::prelude::*;
let mut x = 0b00000000u8;
x.set_bit(1, true);
assert_eq!(x, 0b00000010u8);
}fn main() {
use cj_common::prelude::*;
let mut x = 0xABu8;
let mut v = Vec::new();
for i in x.bit_iter() {
v.push(i);
}
assert_eq!(
v.as_slice(),
&[true, true, false, true, false, true, false, true]
);
}fn main() {
use cj_common::prelude::*;
let x = vec![0xABu8, 0xAB, 0xAB];
let mut v = Vec::new();
for i in x.iter_to_bit() {
v.push(i);
}
assert_eq!(
v.as_slice(),
&[
true, true, false, true, false, true, false, true,
true, true, false, true, false, true, false, true,
true, true, false, true, false, true, false, true
]
);
let x = [2u128, 2, 2];
for i in x.as_slice().iter_to_bit().enumerate() {
match i.0 {
1 | 129 | 257 => assert_eq!(i.1, true),
_ => assert_eq!(i.1, false),
}
}
}fn main() {
use cj_common::prelude::*;
// mask examples
let mask = 0b00011010u8;
let byte = 0b01011010u8;
assert_eq!(byte.matches_mask(&mask), true);
assert_eq!(mask.as_mask_matches(&byte), true);
let read_permission = 0b00000001u8;
let write_permission = 0b00000010u8;
let mod_permission = 0b00000100u8;
let del_permission = 0b00001000u8;
let full_permission = read_permission + write_permission + mod_permission + del_permission;
let user = read_permission + write_permission;
let moderator = user + mod_permission;
let admin = full_permission;
let fred = user;
let jane = moderator;
assert_eq!(fred.matches_mask(&read_permission), true);
assert_eq!(fred.matches_mask(&write_permission), true);
assert_eq!(fred.matches_mask(&moderator), false);
assert_eq!(user.as_mask_matches(&jane), true);
assert_eq!(admin.as_mask_matches(&jane), false);
}- in_set - structs, methods and traits for checking if values are within a given set of ranges.
fn main() {
use cj_common::prelude::*;
assert_eq!('x'.in_range('a'..'z'), true);
assert_eq!('z'.in_range_inclusive('a'..='z'), true);
assert_eq!(1.in_range(1..3), true);
assert_eq!(
'z'.in_set([('a'..'r').into(), ('r'..='z').into()].as_slice()),
true
);
let list = "lmnop";
for c in list.chars() {
assert_eq!(c.in_range('k'..'q'), true);
assert_eq!(c.in_set([('k'..'q').into()].as_slice()), true);
assert_eq!(
c.in_set(
[
('k'..='l').into(), // RangeInclusive
('m'..'n').into(), // Range
('n'..='p').into(), // RangeInclusive
['a', 'b', 'c'].as_slice().into(), // Slice
"test123".into(), // str
]
.as_slice()
),
true
);
assert_eq!(c.in_range('w'..'z'), false);
}
let alpha_nums = [('a'..='z').into(), ('A'..='Z').into(), ('0'..='9').into()];
let list = "lmnop";
for c in list.chars() {
assert_eq!(c.in_set(alpha_nums.as_slice()), true);
}
let list = [1_000, 10_000, 100_000_000];
for n in list {
assert_eq!(n.in_range(1..200_000_000), true);
assert_eq!(n.in_set([(1..200_000_000).into()].as_slice()), true);
assert_eq!(
n.in_set(
[
(1..=10).into(), // RangeInclusive
(500..2_000).into(), // Range
(9_999..=100_000_000).into(), // RangeInclusive
[30, 90, 700].as_slice().into() // Slice
]
.as_slice()
),
true
);
assert_eq!(n.in_range(1_000_000_000..1_000_000_001), false);
}
assert_eq!('9'.is_ascii_numeric(), true);
assert_eq!('T'.is_ascii_numeric(), false);
assert_eq!('9'.is_ascii_alpha(), false);
assert_eq!('T'.is_ascii_alpha(), true);
for c in "9T".chars() {
assert_eq!(c.is_ascii_alpha_numeric(), true);
}
}