# Tag Info

98

During every iteration you increment i and decrement j which is equivalent to just incrementing i by 2. Therefore, total number of iterations is n^2 / 2 and that is still O(n^2).

47

big-O complexity ignores coefficients. For example: O(n), O(2n), and O(1000n) are all the same O(n) running time. Likewise, O(n^2) and O(0.5n^2) are both O(n^2) running time. In your situation, you're essentially incrementing your loop counter by 2 each time through your loop (since j-- has the same effect as i++). So your running time is O(0.5n^2), but ...

9

You will have exactly n*n/2 loop iterations (or (n*n-1)/2 if n is odd). In the big O notation we have O((n*n-1)/2) = O(n*n/2) = O(n*n) because constant factors "don't count".

7

Am I right in saying that the time complexity in big O notation would just be O(1)? No. This is so common a misconception among students/pupils that I can only constantly repeat this: Big-O notation is meant to give the complexity of something, with respect to a certain measure, over another number: For example, saying: "The algorithm for ...

7

Your algorithm is equivalent to while (i += 2 < n*n) ... which is O(n^2/2) which is the same to O(n^2) because big O complexity does not care about constants.

4

Although there are some good answers for this question. I would like to give another answer here with several examples of loop. O(n): Time Complexity of a loop is considered as O(n) if the loop variables is incremented / decremented by a constant amount. For example following functions have O(n) time complexity. // Here c is a positive integer constant ...

4

give all possible solutions for which expression is satisfiable No, because there can be exponentially many. Or is this expression is satisfiable for input having total k literals = 1 No, because if this were easy, then so too would be weighted 2-satisfiability (NP-hard). Or how many minimum number of literals have value 1 for expression to be ...

4

This method is having only O(n), because if you run it with 5, it goes to recursion with 4, then with 3 etc. Unsigned func (unsigned n) { if (n ==0) return 1; if(n==1) return 2; \\do somthing(in O(1) ) return 2*func(n-1); } However what about this : Unsigned func (unsigned n) { if (n ==0) return 1; if(n==1) return 2; \\do somthing(in O(1) ) ...

4

If you write the program the following way #include <stdio.h> #define N 20 int main( void ) { int a[N]; int n; int i; for ( i = 0; i < N; i++ ) scanf( "%d", &a[i] ); n = 0; for ( i = 0; i < N; i++ ) { int j = 0; while ( j < n && a[i] != a[j] ) ++j; if ( j == n ) a[n++] = ...

3

So, the total number of times the whole block of code would run = n + (n-1) + ...+ 1 = n * (n+1) / 2 = O(n^2). The other statements would take O(1), so their's would have no effect(not much role) on complexity(their's being a constant).

3

The complexity does not grow with n, thus O(1)

3

Sorry to disappoint, but the class is called DTIME(nn) (technically you need a decision problem, e.g., given k and n, are there at least k distinct n-Queens solutions?). It doesn't have a fancy name because it's just not that interesting to complexity theorists. It's contained in EXPTIME, which is the union of DTIME(2p(n)) for all polynomials p(n). The naive ...

3

Let m be the number of iterations taken. Then, i+m = n^2 - m which gives, m = (n^2-i)/2 In Big-O notation, this implies a complexity of O(n^2).

2

Intuitively it is O(1) because as n increases the runtime does not increase after a certain point. However, this is an edge case, as were n bounded by a much higher number, say the maximum value of an int, it would seem to be no different than if n was not bounded at all. However, when considering runtime using complexity theory we usually ignore things like ...

2

Yes, this algorithm is O(n^2). To calculate complexity, we have a table the complexities: O(1) O(log n) O(n) O(n log n) O(n²) O(n^a) O(a^n) O(n!) Each row represent a set of algorithms. A set of algorithms that is in O(1), too it is in O(n), and O(n^2), etc. But not at reverse. So, your algorithm realize n*n/2 sentences. O(n) < O(nlogn) < O(n*n/2) ...

2

The time complexity of computing f(n) is O(1), and the space complexity is either O(1) or zero (depending on whether you count temporary registers as space)1. If (hypothetically) f(n) was a cost function2 for a computation, then its complexity class would be O(1/n). However, that makes no sense3. How can you possibly have a cost function that tends ...

2

It depends on the semantic of your programming/algorithm language. If by f(n) you mean "call the function no matter if it was called with the same argument before" (as it is the case with most programming languages), then your change will reduce the complexity dramatically to O(n). You have one O(1) function call per decrement of the argument. Otherwise ...

2

Since your validation checks are returning false, you don't need to else part so the code can just continue to the next check: public override bool Validate(Control control, object value) { if (value == null && !_IsAllowNull) { ErrorText = "Please provided valid number without a decimal point."; return false; } if ...

2

You could achieve this by modifying the Bucket sort algorithm, below I have included a JavaScript implementation, see Github for further details on the source code. This implementation uses 16 buckets, you will have to modify it to allow for k buckets and you can omit the sorting of buckets itself. One approach would be to use 2^p buckets where p is the ...

2

Note that the problem statement is to separate n different numbers into k groups. This would get more complicated if there were duplicates as noted in the wiki links below. Any process that can determine the kth smallest element with less than O(n log(k)) complexity could be used k-1 times to produce an array of the elements corresponding to the boundaries ...

1

Use K-selection algorithm with partition function from QuickSort - QuickSelect. Let's K is power of 2 for simplicity. At the first stage we make partition of N elements, it takes O(N) ~ p* N time, where p is some constant At the second stage we recursively make 2 partitions of N/2 elements, it takes 2* p* N/2 = p*N time. At the third stage we make 4 ...

1

public override bool Validate(Control control, object value) { if ((value == null && !_IsAllowNull) || !value.IsNumber()) { ErrorText = "Please provided valid number without a decimal point."; return false; } if (value.ToString().Contains(".")) { ErrorText ...

1

With this your method complexcity score goes to 2 public Validation() { _Validations = new List<Action<object>> { ValidateNull, ValidateDecimal, ValidateIsNumber, ValidateRange, }; } public bool Validate(Control control, object value) { try ...

1

O(Log(A)) is definitely better than O(A), but this can be done in O(1). The data structure you are looking for is HashMap, if you are going to do this in C. I haven't worked in C in a very long time so I don't know if it is natively available now. It surely is available in C++. Also there are some libraries which you can use in the worst case. For MongoDB, ...

1

You're confusing the computation with the amount of time the computation takes. If θ≤0.1, then T(θ) is 1. Otherwise, it is T(θ/3)+k, where k is the time it takes to do four multiplications, a subtraction, and some miscellaneous bookkeeping. It is evident that the argument for the ith recursion will be θ/3i, and therefore that the ...

1

Yes, it's the array.index that makes it quadratic. Let's first cut all irrelevant stuff away. The conditionals are for the complexity reasoning irrelevant (we will have array != [] and that check takes O(1) time). The same goes with the multiplication with array[-1]. So you're left with: sum(i for i in array if array.index(i) % 2 == 0) Now the inner is a ...

1

First of all your inner loop access elements in [z, 20-t+1], which is 1 element beyond the array. The 'shift numbers' loop should be: for(int z = j; z<20-t-1; z++) array[z] = array[z+1];//shift numbers. To reply your question, it works with i = -1 because i is going to be incremented by the for-j loop. Therefore it will be 0 next iteration (and not ...

1

outer loop | inner loop i=n       |   inner loop executes n times i=n-1    |   inner loop executes n-1 times i=n-2    |   inner loop executes n-2 times . . . i=1    | inner loop executes 1 time and exits now summing up total no of times inner loop executes : n + (n-1) +(n-2)+.....+1= ...

1

If you look to these two lines j <- j + 1; inv <- inv + 1; //Counting inversions They are both T(1) arithmetic operations, they are in same depth, therefore T(1)+T(1) = T(1). The extra line of inv <- inv + 1; cant change complexity, because time to execute remains constant.

1

Your implementation does indeed seem to have exponential complexity. I did not really think about this part of your question. It is perhaps a bit tedious to come up with a worst case scenario. But one "at-least-pretty-bad" scenario would be to have the first n-m elements in arr set to 0 and the last m elements set to 1. A lot of branching right there, not ...

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