# Intuitive explanation for why QuickSort is n log n?

Is anybody able to give a 'plain english' intuitive, yet formal, explanation of what makes QuickSort n log n? From my understanding it has to make a pass over n items, and it does this log n times...Im not sure how to put it into words why it does this log n times.

-

Each partitioning operation takes O(n) operations (one pass on the array). In average, each partitioning divides the array to two parts (which sums up to log n operations). In total we have O(n * log n) operations.

I.e. in average log n partitioning operations and each partitioning takes O(n) operations.

-

The `log n` part comes from the fact that it's (at least ideally) breaking the input in half at each iteration. Starting from N items, and breaking those in half each time means that you're down to 1 item after log2(N) iterations, at which point you obviously can't subdivide it any further. For example, starting from, say, 128 items, you divide into groups of 64, 32, 16, 8, 4, 2, 1 items -- 7 iterations (and log2(128) = 7).

Each of those iterations scans through the entire array to partition it, so you end up with O(log N) operations, each of which has O(n) complexity, for O(n log n) overall complexity.

To be technically correct, the Big-O is O(N2). This arises from the fact that a sufficiently bad choice of partition element could split the array into one element on one side, and the entire rest of the array on the other. If this happens at every iteration, it takes N iterations to split it down into pieces of one element apiece, so you get N operations, each with a complexity of O(N), for O(N * N) overall.

In a real implementation you usually stop before that, but that is the furthest you could go.

-
Thank you for this. The accepted answer here merely restated what the OP (and I) already knew (n operations done log n times), but glossed over the only important part: why is it done log n times? This answer is a nice and simple explanation of where the log term actually comes from. –  Cam Jackson Dec 13 '13 at 0:17