I wrote some JS code using some of the ideas in this thread:

```
const BITS = 32n;
const MAX = 4294967295n;
const COPRIME = 65521n;
const INVERSE = 2166657316n;
const ROT = 6n;
const XOR1 = 10296065n;
const XOR2 = 2426476569n;
function rotRight(n, bits, size) {
const mask = (1n << bits) - 1n;
// console.log('mask',mask.toString(2).padStart(Number(size),'0'));
const left = n & mask;
const right = n >> bits;
return (left << (size - bits)) | right;
}
const pipe = fns => fns.reduce((f, g) => (...args) => g(f(...args)));
function build(...fns) {
const enc = fns.map(f => Array.isArray(f) ? f[0] : f);
const dec = fns.map(f => Array.isArray(f) ? f[1] : f).reverse();
return [
pipe(enc),
pipe(dec),
]
}
[exports.encode, exports.decode] = build(
[BigInt, Number],
[i => (i * COPRIME) % MAX, i => (i * INVERSE) % MAX],
x => x ^ XOR1,
[x => rotRight(x, ROT, BITS), x => rotRight(x, BITS-ROT, BITS)],
x => x ^ XOR2,
);
```

It produces some nice results like:

```
1 1352888202n 1 'mdh37u'
2 480471946n 2 '7y26iy'
3 3634587530n 3 '1o3xtoq'
4 2225300362n 4 '10svwqy'
5 1084456843n 5 'hxno97'
6 212040587n 6 '3i8rkb'
7 3366156171n 7 '1jo4eq3'
8 3030610827n 8 '1e4cia3'
9 1889750920n 9 'v93x54'
10 1017334664n 10 'gtp0g8'
11 4171450248n 11 '1wzknm0'
12 2762163080n 12 '19oiqo8'
13 1621319561n 13 'qtai6h'
14 748903305n 14 'cdvlhl'
15 3903018889n 15 '1sjr8nd'
16 3567473545n 16 '1mzzc7d'
17 2426613641n 17 '144qr2h'
18 1554197390n 18 'ppbudq'
19 413345678n 19 '6u3fke'
20 3299025806n 20 '1ik5klq'
21 2158182286n 21 'zoxc3y'
22 1285766031n 22 'l9iff3'
23 144914319n 23 '2ea0lr'
24 4104336271n 24 '1vvm64v'
25 2963476367n 25 '1d0dkzz'
26 2091060108n 26 'ykyob0'
27 950208396n 27 'fpq9ho'
28 3835888524n 28 '1rfsej0'
29 2695045004n 29 '18kk618'
30 1822628749n 30 'u559cd'
31 681777037n 31 'b9wuj1'
32 346231693n 32 '5q4y31'
```

Testing with:

```
const {encode,decode} = require('./obfuscate')
for(let i = 1; i <= 1000; ++i) {
const j = encode(i);
const k = decode(j);
console.log(i, j, k, j.toString(36));
}
```

`XOR1`

and `XOR2`

are just random numbers between 0 and `MAX`

. `MAX`

is `2**32-1`

; you should set this to whatever you think your highest ID will be.

`COPRIME`

is a number that's coprime w/ `MAX`

. I *think* prime numbers themselves are coprime with every other number (except multiples of themselves).

`INVERSE`

is the tricky one to figure out. These blog posts don't give a straight answer, but WolframAlpha can figure it out for you. Basically, just solve the equation `(COPRIME * x) % MAX = 1`

for `x`

.

The `build`

function is something I created to make it easier to create these encode/decode pipelines. You can feed it as many operations as you want as `[encode, decode]`

pairs. These functions have to be equal and opposite. The `XOR`

functions are their own compliments so you don't need a pair there.

Here's another fun involution:

```
function mixHalves(n) {
const mask = 2n**12n-1n;
const right = n & mask;
const left = n >> 12n;
const mix = left ^ right;
return (mix << 12n) | right;
}
```

(assumes 24-bit integers -- just change the numbers for any other size)

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