# complexity theory-sorting algorithm

I'am taking a course in complexity theory,and so it's need some mathematical background which i have a problem,. so while i'am trying to do some practicing i stuck in the bellow example

``````1)  for (i = 1; i < n; i++) {
2)      SmallPos = i;
3)      Smallest = Array[SmallPos];
4)      for (j = i+1; j <= n; j++)
5)          if (Array[j] < Smallest) {
6)              SmallPos = j;
7)              Smallest = Array[SmallPos]
}
8)       Array[SmallPos] = Array[i];
9)       Array[i] = Smallest;
}
``````

Thus, the total computing time is:

``````T(n)    = (n) + 4(n-1) + n(n+1)/2 – 1 + 3[n(n-1) / 2]
= n  + 4n - 4 + (n^2 + n)/2 – 1 + (3n^2 - 3n) / 2
= 5n - 5 + (4n2 - 2n) / 2
= 5n - 5 + 2n^2 - n
= 2n^2 + 4n - 5
= O(n^2)
``````

and what i don't understand or confused about line 4 analyzed to n(n+1)/2 – 1, and line 5 3[n(n-1) / 2]. i knew that the sum of positive series is =n(first+last)/2 ,but when i tried to calculate it as i understand it it gives me different result. i calculate for line no 4 so it shoulb be =n((n-1)+2)/2 according to n(first+last)/2 ,but here it's n(n+1)/2 – 1. and same for 3[n(n-1) / 2].....i don't understand this too

also here's what is written in the analysis it could help if anyone can explain to me,

Statement 1 is executed n times (n - 1 + 1); statements 2, 3, 8, and 9 (each representing O(1) time) are executed n - 1 times each, once on each pass through the outer loop. On the first pass through this loop with i = 1, statement 4 is executed n times; statement 5 is executed n - 1 times, and assuming a worst case where the elements of the array are in descending order, statements 6 and 7 (each O(1) time) are executed n - 1 times.

On the second pass through the outer loop with i = 2, statement 4 is executed n - 1 times and statements 5, 6, and 7 are executed n - 2 times, etc. Thus, statement 4 is executed (n) + (n-1) +... + 2 times and statements 5, 6, and 7 are executed (n-1) + (n-2) + ... + 2 + 1 times. The first sum is equal to n(n+1)/2 - 1, and the second is equal to n(n-1)/2.

Thus, the total computing time is:

``````T(n)    = (n) + 4(n-1) + n(n+1)/2 – 1 + 3[n(n-1) / 2]
= n  + 4n - 4 + (n^2 + n)/2 – 1 + (3n^2 - 3n) / 2
= 5n - 5 + (4n2 - 2n) / 2
= 5n - 5 + 2n^2 - n
= 2n^2 + 4n - 5
= O(n^2)
``````
-
And your question is? –  Scott Hunter Oct 6 '12 at 20:23
What's the question? –  Robert Oct 6 '12 at 20:23
`T(n) = O(n^2)` is not syntatically correct, it should be: `T(n) is in O(n^2)`, since O(n^2) is a set of functions. –  amit Oct 6 '12 at 20:58

line 4: as the analysis says, it is executed `n+(n-1)+...+2` times. This is a sum of `(n-1)` terms. In the formula you use, `n(first+last)/2`, `n` represents the number of terms. If you apply the formula to your sequence of `n-1` terms, then it should be `(n-1)((n)+(2))/2=(n²+n-2)/2=n(n+1)/2-1`.
line 5: the same formula can be used. As the analysis says, you have to calculate `(n-1)+...+1`. This is a sum of `n-1` terms, with the first and last being `n-1` and `1`. The sum is given by `(n-1)(n-1+1)/2`. The factor 3 is from the 3 lines (5,6,7) that are each being done `(n-1)(n)/2` times
line 5: in your first inner loop, j will assume all values for 2 to n. For each value in that loop, you will execute line 5 1 time. In the formula `(n-1)+...+1` you are actually calculating how many times (in total) line 5 is executed by counting the number of times it is executed during each loop: n-1 times in the first loop (for i=1), n-2 times for i=2... If you do `n+n-1+...+2` you are summing all j-values, while you want to be summing the number of times line 5 is executed. –  Origin Oct 7 '12 at 9:13