I'm trying to solve this MaxCollatzLength kata but I'm struggling to optimise it to run fast enough for really large numbers.

In this kata we will take a look at the length of collatz sequences. And how they evolve. Write a function that take a positive integer n and return the number between 1 and n that has the maximum Collatz sequence length and the maximum length. The output has to take the form of an array [number, maxLength] For exemple the Collatz sequence of 4 is [4,2,1], 3 is [3,10,5,16,8,4,2,1], 2 is [2,1], 1 is [ 1 ], so MaxCollatzLength(4) should return [3,8]. If n is not a positive integer, the function have to return [].

As you can see, numbers in Collatz sequences may exceed n. The last tests use random big numbers so you may consider some optimisation in your code:

You may get very unlucky and get only hard numbers: try submitting 2-3 times if it times out; if it still does, probably you need to optimize your code more;

Optimisation 1: when calculating the length of a sequence, if n is odd, what 3n+1 will be ?

Optimisation 2: when looping through 1 to n, take i such that i < n/2, what will be the length of the sequence for 2i ?

A recursive solution quickly blows the stack, so I'm using a while loop. I think I've understood and applied the first optimisation. I also spotted that for n that is a power of 2, the max length will be (log2 of n) + 1 (that only shaves off a very small amount of time for an arbirtarily large number). Finally I have memoised the collatz lengths computed so far to avoid recalculations.

I don't understand what is meant by the second optimisation, however. I've tried to notice a pattern with a few random samples and loops and I've plotted the max collatz lengths for n < 50000. I noticed it seems to roughly follow a curve but I don't know how to proceed - is this a red herring?

I'm ideally looking for a hints in the right direction so I can work towards the solution myself.

```
function collatz(n) {
let result = [];
while (n !== 1) {
result.push(n);
if (n % 2 === 0) n /= 2;
else {
n = n * 3 + 1;
result.push(n);
n = n / 2;
}
}
result.push(1);
return result;
}
function collatzLength(n) {
if (n <= 1) return 1;
if (!collatzLength.precomputed.hasOwnProperty(n)) {
// powers of 2 are logarithm2 + 1 long
if ((n & (n - 1)) === 0) {
collatzLength.precomputed[n] = Math.log2(n) + 1;
} else {
collatzLength.precomputed[n] = collatz(n).length;
}
}
return collatzLength.precomputed[n];
}
collatzLength.precomputed = {};
function MaxCollatzLength(n) {
if (typeof n !== 'number' || n === 0) return [];
let maxLen = 0;
let numeralWithMaxLen = Infinity;
while (n !== 0) {
let lengthOfN = collatzLength(n);
if (lengthOfN > maxLen) {
maxLen = lengthOfN;
numeralWithMaxLen = n;
}
n--;
}
return [numeralWithMaxLen, maxLen];
}
```

`collatz(n)`

, but only in the front end code, which you call once for each`n`

. There is no chance of getting a memoized value. Your core function always interates down until you reach 1. It is here that you should make use of the precomputed values to cut the sequences short. – M Oehm Dec 3 '15 at 14:10`collatz()`

is the length of the list so far and the current value on it (which you already have in`n`

). Even if appending to an array can be done in amortised constant time, this will still be a moderately large constant factor slower than just adding 1 to an integer! – j_random_hacker Dec 3 '15 at 17:23`collatzLength`

`n`

times, each time with a different value. Try removing the precomputed values and return`collatz(n).length`

directly. I think you won't see a slow-down. The memoization belongs to the`collatz`

function. – M Oehm Dec 3 '15 at 17:34`collatzLength(42)`

is not already in the table of precomputed values, it'snotusually necessary to calculate the entire sequence back down to 1 -- it's sufficient to keep calculating the sequenceuntil you hit some number that. As soon as you hit such a number, you can just add its length to the length you have calculated "the hard way" so far. – j_random_hacker Dec 3 '15 at 17:36isalready in the table of precomputed values