Time Complexity for nested loops with half-size - time-complexity

void function(int n)
{
int count = 0;
// outer loop
for (int i=n/2; i<=n; i++)
// middle loop
for (int j=1; j+n/2<=n; j = j++)
// inner loop executes log n times
for (int k=1; k<=n; k = k * 2)
count++;
}
I am doing some exercise, and can someone please help me to figure out the Big-Oh of the above algorithm? I understand that the inner most loop executes for log n times. What about the outermost loop and middle loop ? Would that also be log n or n/2 ?

Assuming your code with full indentation is this:
void function(int n)
{
int count = 0;
// outer loop
for (int i=n/2; i<=n; i++){
// middle loop
for (int j=1; j+n/2<=n; j++){
// inner loop executes log n times
for (int k=1; k<=n; k = k * 2){
count++;
}
}
}
}
The time complexity can be calculated as follows:
The innermost loop executes (log n) times, so its complexity is O(log n).
The middle loop with j as the loop variable executes n / 2 times, with the innermost loop executing, each time in its iteration. Therefore, the time complexity of the middle loop is (n / 2) * O(log n) = O(n * log n).
Similarly, the outermost loop also executes (n / 2) times, with the middle loop executing completely in it each iteration. So, its time complexity will be (n / 2) * O(n * log n) = O(n * n * log n).
Hence, the overall time complexity will be O(n^2 * log n).

Related

What is the time function of this loop

For (i=0, i < n, i++) // n+1
{
for(j=0; j < n, j++) // n * (n+1)
{
C[i][j]+ B[i,j]; // n * n
}
}
The instructor said the time function is f(n) = 2n^2 +2n +1
How come it's not 2n^2+ 2n + 2 because both loops run one extra time when i=n and j=n?
Each time we increment i, we check if the new value becomes equal to or greater than n, so we perform the comparison n + 1 times (n times when i <n and an additional comparison when i becomes equal to n). the same thing for j => (n+1) * (n times when i<n).
So, n*n+(n+1)*n+(n+1)=2n^2+ 2n +1

What is the complexity of this for loop, for (int j = i; j < n; j++)?

what is the complexity of the second for loop? would it be n-i? from my understanding a the first for loop will go n times, but the index in the second for loop is set to i instead.
//where n is the number elements in an array
for (int i = 0; i < n; i++) {
for (int j = i; j < n; j++) {
// Some Constant time task
}
}
In all, the inner loop iterates sum(1..n) times, which is n * (n + 1) / 2, which is O(n2)
If you try to visualise this as a matrix where lines represents i and each columns represents j you'll see that this forms a triangle with the sides n
Example with n being 4
0 1 2 3
1 2 3
2 3
3
The inner loop has (on average) complexity n/2 which is O(n).
The total complexity is n*(n+1)/2 or O(n^2)
The number of steps this takes is a Triangle Number. Here's a bit of code I put together in LINQpad (yeah, sorry about answering in C#, but hopefully this is still readable):
void Main()
{
long k = 0;
// Whatever you want
const int n = 13;
for (int i = 0; i < n; i++)
{
for (int j = i; j < n; j++)
{
k++;
}
}
k.Dump();
triangleNumber(n).Dump();
(((n * n) + n) / 2).Dump();
}
int triangleNumber(int number)
{
if (number == 0) return 0;
else return number + triangleNumber(number - 1);
}
All 3 print statements (.Dump() in LINQpad) produce the same answer (91 for the value of n I selected, but again you can choose whatever you want).
As others indicated, this is O(n^2). (You can also see this Q&A for more details on that).
We can see that the total iteration of the loop is n*(n+1)/2. I am assuming that you are clear with that from the above explanations.
Now let's find the asymptotic time complexity in an easy logical way.
Big Oh, comes to play when the value of n is a large number, in such cases we need not consider the dividing by 2 ( 2 is a constant) because (large number / 2) is also a large number.
This leaves us with n*(n+1).
As explained above, since n is a large number, (n+1) can be approximated to (n).
thus leaving us with (n*n).
hence the time complexity O(n^2).

Big O of Nested Loop (int j = 0; j < i * i; ++j)

Question 1
for (i = 0; i < n; i++) {
for (j = 0; j < i * i ; j++){
}
}
Answer: O(n^3)
At first glance, O(n^3) made sense to me, but I remember a previous problem I did:
Question 2
for (int i = n; i > 0; i /= 2) {
for (int j = 0; j < i; j++) {
//statement
}
}
Answer: O(n)
For Question 2, the outer loop is O(log n) and the inner loop is O(2n / log n) resulting in O(n). The inner loop is O(2n / log n) because - see explanation here: Big O of Nested Loop (int j = 0; j < i; j++)
Why we don't do Question 1 like Question 2 since in Question 1, j also depends on i which means we should really be taking the average of how many iterations will occur in the inner loop (as we do in Question 2).
My answer would be: O(n) for the outer loop and O(n^2 / n) for the inner loop which results in O(n^2) for Question 1.
Your answer is wrong. The code is Θ(n³).
To see that note that the inner loop takes i² steps which is at most n² but for half of the outer loop iterations is at least (n/2)² = n²/4.
Therefore the number of total inner iterations is at most n * n² = n³ but at least n/2 * n²/4 = n³/8.
Your consideration is wrong in that the inner loop takes on average proportional to n² many iterations, not n² / n.
What your inner for loop is doing, in combination with the outer for loop, is calculating the sum of i^2. If you write it out you are adding the following terms:
1 + 4 + 9 + 16 + ...
The result of that is (2n^3+3n^2+n)/6. If you want to calculate the average of the number of iterations of the inner for loop, you divide it by n as this is the number of iterations of the outer for loop. So you get (2n^2+3n+1)/6, in terms of Big O notation this will be O(n^2). And having that gives you... nothing. You have not gain any new information as you already knew the complexity of the inner for loop is O(n^2). Having O(n^2) running n times gives you O(n^3) of total complexity, that you already knew...
So, you can calculate the average number of iterations of the inner for loop, but you will not gain any new information. There were no cuts in the number of iteration steps as there were in your previous question (the i /= 2 stuff).
void fun(int n, int k)
{
for (int i=1; i<=n; i++)
{
int p = pow(i, k);
for (int j=1; j<=p; j++)
{
// Some O(1) work
}
}
}
Time complexity of above function can be written as 1k + 2k + 3k + … n1k.
In your case k = 2
Sum = 12 + 22 + 32 + ... n12.
= n(n+1)(2n+1)/6
= n3/3 + n2/2 + n/6

Why does following code has complexity of O(n)?

I was going through some practice problem at this page. The question asks for the time complexity for below code and answer is O(n). However, as per my understanding outer loop runs log(n) times and inner one by O(n) thus it should have complexity of O(n*log(n)).
int count = 0;
for (int i = N; i > 0; i /= 2) {
for (int j = 0; j < i; j++) {
count += 1;
}
}
Please clarify what am I missing here.
The inner statement is run N + N/2 + N/4 + N/8 + ... times. Which is 2*N = O(N).

Finding the big theta bound

Give big theta bound for:
for (int i = 0; i < n; i++) {
if (i * i < n) {
for (int j = 0; j < n; j++) {
count++;
}
}
else {
int k = i;
while (k > 0) {
count++;
k = k / 2;
}
}
}
So here's what I think..Not sure if it's right though:
The first for loop will run for n iterations. Then the for for loop within the first for loop will run for n iterations as well, giving O(n^2).
For the else statement, the while loop will run for n iterations and the k = k/ 2 will run for logn time giving O(nlogn). So then the entire thing will look like n^2 + nlogn and by taking the bigger run time, the answer would be theta n^2 ?
I would say the result is O(nlogn) because i*i is typically not smaller than n for a linear n. The else branch will dominate.
Example:
n= 10000
after i=100 the else part will be calculated instead of the inner for loop