The Time Complexity only tells you, how the approach will scale with (significantly) larger input. It doesn’t tell you which approach is faster.
It’s perfectly possible that a solution is faster for small input sizes (string lengths and/or array length) but scales badly for larger sizes, due to its Time Complexity. But it’s even possible that you never encounter the point where an algorithm with a better Time Complexity becomes faster, when natural limits to the input sizes prevent it.
You didn’t show the code of your approaches, but it’s likely that your first approach calls a method like
toCharArray() on the strings, followed by
Arrays.sort(char). This implies that sort operates on primitive data.
In contrast, when your second approach uses a
HashMap<Character,Integer> to record frequencies, it will be subject to boxing overhead, for the characters and the counts, and also use a significantly larger data structure that needs to be processed.
So it’s not surprising that the hash approach is slower for small strings and arrays, as it has a significantly larger fixed overhead and also a size dependent (
So first approach had to suffer from the
O(n log n) time complexity significantly to turn this result. But this won’t happen. That time complexity is a worst case of sorting in general. As explained in this answer, the algorithms specified in the documentation of
Arrays.sort should not be taken for granted. When you call
Arrays.sort(char) and the array size crosses a certain threshold, the implementation will turn to Counting Sort with an O(n) time complexity (but use more memory temporarily).
So even with large strings, you won’t suffer from a worse time complexity. In fact, the Counting Sort shares similarities with the frequency map, but usually is more efficient, as it avoids the boxing overhead, using an
int array instead of a