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#[cfg(not(feature = "std"))]
use alloc::vec::Vec;
use bigint::BigUint;
pub(crate) fn encode<T>(alpha: &[T], input: &[u8]) -> Vec<T>
where
T: Copy,
{
if input.is_empty() {
return Vec::new();
}
let base = alpha.len() as u32;
// Convert the input byte array to a BigUint
let mut big = BigUint::from_bytes_be(input);
let mut out = Vec::with_capacity(input.len());
// Find the highest power of `base` that fits in `u32`
let big_pow = 32 / (32 - base.leading_zeros());
let big_base = base.pow(big_pow);
'fast: loop {
// Instead of diving by `base`, we divide by the `big_base`,
// giving us a bigger remainder that we can further subdivide
// by the original `base`. This greatly (in case of base58 it's
// a factor of 5) reduces the amount of divisions that need to
// be done on BigUint, delegating the hard work to regular `u32`
// operations, which are blazing fast.
let mut big_rem = big.div_mod(big_base);
if big.is_zero() {
loop {
let (result, remainder) = (big_rem / base, big_rem % base);
out.push(alpha[remainder as usize]);
big_rem = result;
if big_rem == 0 {
break 'fast; // teehee
}
}
} else {
for _ in 0..big_pow {
let (result, remainder) = (big_rem / base, big_rem % base);
out.push(alpha[remainder as usize]);
big_rem = result;
}
}
}
let leaders = input
.iter()
.take(input.len() - 1)
.take_while(|i| **i == 0)
.map(|_| alpha[0]);
out.extend(leaders);
out
}