I am reading Robert Sedgewick's book *Algorithms 4th edition*, and he has the following exercise question: *What is the expected number of subarrays of size 0, 1 and 2 when quicksort is used to sort an array of N items with distinct keys?*

Then he says that if you're mathematically inclined, do the math, if not, run experiments, I have run the experiments and it seems like the arrays of size 0 and 1 have precisely the same number of occurrences and the arrays of size 2 are only half as occurrent.

**The version of quicksort in question is the one with 2 way partitioning.**

I understand that we get subarrays of size 0 when the partitioning item is the smallest/biggest one in the subarray, so the consequent 2 calls for the sort will be

```
sort(a, lo, j-1); // here if j-1 < lo, we have an array of size 0
sort(a, j+1, hi); // here if j+1 > hi, we have an array of size 0
```

The arrays of size 1 happen when the partitioning item is 2nd to first smallest/biggest item, and of size 2 when it's 3rd to first smallest/biggest item.

So, *how exactly do I derive a mathematical formula?*

Here is the code in C#

```
class QuickSort
{
private static int zero = 0, one = 0, two = 0;
private static int Partition<T>(T[] a, int lo, int hi) where T : IComparable<T>
{
T v = a[lo];
int i = lo, j = hi + 1;
while(true)
{
while(Alg.Less(a[++i], v)) if(i == hi) break;
while(Alg.Less(v, a[--j])) if(j == lo) break;
if(i >= j) break;
Alg.Swap(ref a[i], ref a[j]);
}
Alg.Swap(ref a[lo], ref a[j]);
return j;
}
private static void Sort<T>(T[] a, int lo, int hi) where T : IComparable<T>
{
if(hi < lo) zero++;
if(hi == lo) one++;
if(hi - lo == 1) two++;
if(hi <= lo) return;
int j = Partition(a, lo, hi);
Sort(a, lo, j - 1);
Sort(a, j + 1, hi);
}
public static void Sort<T>(T[] a) where T : IComparable<T>
{
Alg.Shuffle(a);
int N = a.Length;
Sort(a, 0, N - 1);
Console.WriteLine("zero = {0}, one = {1}, two = {2}", zero, one, two);
}
}
```

**There's a proof that says that on average quicksort uses 2NlnN ~ 1.39NlgN compares to sort an array of length N with distinct keys.**

**I guess we can think of 1.39NlgN as we do N comparisons ~lgN times, so on average we divide our array in half, hence at some point we will be left with pairs to compare, and since there are only pairs to compare, for example : <1,2>,<3,4>,<5,6>,etc..., we will get subarrays of size 0 and 1 after partitioning them, that only proves that sizes of 0 and 1, are more frequent, but I still don't understand why sizes of 2 are almost exactly half as frequent.**