I made a quick and dirty JavaScript implementation (note: it is O(n^2)):

```
function lis(a) {
var tmpArr = Array(),
result = Array(),
i = a.length;
while (i--) {
var theValue = a[i],
longestFound = tmpArr[theValue] || 1;
for (var j=theValue+1; j<tmpArr.length; j++) {
if (tmpArr[j] >= longestFound) {
longestFound = tmpArr[j]+1;
}
}
result[i] = tmpArr[theValue] = longestFound;
}
return result;
}
```

**jsFiddle:** http://jsfiddle.net/Bwj9s/1/

We run through the array right-to-left, keeping previous calculations in a separate temporary array for subsequent lookups.

The `tmpArray`

contains the previously found subsequences beginning with any given value, so `tmpArray[n]`

will represent the longest subsequence found (to the right of the current position) beginning with the value `n`

.

The loop goes like this: For every index, we look up the value (and all higher values) in our `tmpArray`

to see if we already found a subsequence which the value could be prepended to. If we find one, we simply add 1 to that length, update the `tmpArray`

for the value, and move to the next index. If we don't find a working (higher) subsequence, we set the `tmpArray`

for the value to 1 and move on.

In order to make it O(n log n) we observe that the `tmpArray`

will always be a decreasing array -- it can and should use a binary search rather than a partial loop.