So I can picture what an algorithm is that has a complexity of n^c, just the number of nested for loops.

for (var i = 0; i < dataset.len; i++ {
    for (var j = 0; j < dataset.len; j++) {
        //do stuff with i and j

Log is something that splits the data set in half every time, binary search does this (not entirely sure what code for this looks like).

But what is a simple example of an algorithm that is c^n or more specifically 2^n. Is O(2^n) based on loops through data? Or how data is split? Or something else entirely?


Algorithms with running time O(2^N) are often recursive algorithms that solve a problem of size N by recursively solving two smaller problems of size N-1.

This program, for instance prints out all the moves necessary to solve the famous "Towers of Hanoi" problem for N disks in pseudo-code

void solve_hanoi(int N, string from_peg, string to_peg, string spare_peg)
    if (N<1) {
    if (N>1) {
        solve_hanoi(N-1, from_peg, spare_peg, to_peg);
    print "move from " + from_peg + " to " + to_peg;
    if (N>1) {
        solve_hanoi(N-1, spare_peg, to_peg, from_peg);

Let T(N) be the time it takes for N disks.

We have:

T(1) = O(1)
T(N) = O(1) + 2*T(N-1) when N>1

If you repeatedly expand the last term, you get:

T(N) = 3*O(1) + 4*T(N-2)
T(N) = 7*O(1) + 8*T(N-3)
T(N) = (2^(N-1)-1)*O(1) + (2^(N-1))*T(1)
T(N) = (2^N - 1)*O(1)
T(N) = O(2^N)

To actually figure this out, you just have to know that certain patterns in the recurrence relation lead to exponential results. Generally T(N) = ... + C*T(N-1) with C > 1means O(x^N). See:


  • 1
    A naive recursive function calculating the Nth Fibonacci number is another classic example of this. – Esoteric Screen Name Jan 21 '16 at 21:10
  • I still would not look at that code and be able to derive 2^n, but this does help immensely. – dlkulp Jan 21 '16 at 21:16
  • 1
    I added an explanation that may help – Matt Timmermans Jan 22 '16 at 13:48
  • @EsotericScreenName O(2^n) is not a tight bound for the time complexity of calculating the nth Fibonacci number naively. It's O(phi^n) where phi is the golden ratio. So I think it's not a good answer to the question, which implicitly is asking for algorithms that are Theta(2^n). – Paul Hankin May 5 '18 at 9:17
  • O(2^n) can often become O(n) with DP – Ridhwaan Shakeel Jul 19 at 15:23

Think about e.g. iterating over all possible subsets of a set. This kind of algorithms is used for instance for a generalized knapsack problem.

If you find it hard to understand how iterating over subsets translates to O(2^n), imagine a set of n switches, each of them corresponding to one element of a set. Now, each of the switches can be turned on or off. Think of "on" as being in the subset. Note, how many combinations are possible: 2^n.

If you want to see an example in code, it's usually easier to think about recursion here, but I can't think od any other nice and understable example right now.

  • This is actually O(n * 2^n) complexity. – Sanket Makani Jun 12 '17 at 11:12
  • @SanketMakani how does iterating over all binary numbers of bit-length n correlate to O(n * 2^n)? Unless of course you assume incrementing an n-bit number to be O(n) (which IMHO is perfectly correct, but many will disagree) This is somewhat similar to saying, that iterating over n numbers take O(n log n) which is, if you count single bit operations, correct, but usually some assumptions are made. – Marandil Jun 12 '17 at 11:33
  • When you iterate over all possible 2^n numbers, you need to check for every bit of the number to check if an element is present or not in the subset. We consider that to check whether a bit is set or not takes O(1) time, Still you need to iterate through all n bits so this would take n iterations for each of the 2^n numbers. So total complexity would be O(n * 2^n). – Sanket Makani Jun 12 '17 at 11:45
  • @SanketMakani you are basically repeating the stuff I wrote: "Unless of course you assume incrementing an n-bit number to be O(n)". Still, the argument about iterating over n values taking O(n log n) holds. – Marandil Jun 12 '17 at 11:57
  • No, I didn't consider than incrementing n causes that another O(n)overhead. Increment is done in O(1) operation. Now consider the example you have given, You would check if the ith bulb is on or off for each of the 2^n numbers, It requires a linear loop to check state of each bulb. There you need a linear loop which causes overhead of O(n) for each number. That makes this complexity O(n * 2^n). – Sanket Makani Jun 12 '17 at 12:23
  int Fibonacci(int number)
  if (number <= 1) return number;

  return Fibonacci(number - 2) + Fibonacci(number - 1);

Growth doubles with each additon to the input data set. The growth curve of an O(2N) function is exponential - starting off very shallow, then rising meteorically. My example of big O(2^n), but much better is this:

public void solve(int n, String start, String auxiliary, String end) {
   if (n == 1) {
       System.out.println(start + " -> " + end);
   } else {
       solve(n - 1, start, end, auxiliary);
       System.out.println(start + " -> " + end);
       solve(n - 1, auxiliary, start, end);

In this method program prints all moves to solve "Tower of Hanoi" problem. Both examples are using recursive to solve problem and had big O(2^n) running time.

  • You should explain why it has exponential complexity - it's not obvious. Also, it's a bad example, because you can easily "fix" this algorithm to have linear complexity - it's as if you wanted to waste processing power on purpose. A better example would show an algorithm that calculates something that is hard/impossible to do fast. – anatolyg Jan 21 '16 at 17:29

c^N = All combinations of n elements from a c sized alphabet.

More specifically 2^N is all numbers representable with N bits.

The common cases are implemented recursively, something like:

vector<int> bits;
int N
void find_solution(int pos) {
   if (pos == N) {
   bits[pos] = 0;
   find_solution(pos + 1);
   bits[pos] = 1;
   find_solution(pos + 1);

Here is a code clip that computes value sum of every combination of values in a goods array(and value is a global array variable):

fun boom(idx: Int, pre: Int, include: Boolean) {
    if (idx < 0) return
    boom(idx - 1, pre + if (include) values[idx] else 0, true)
    boom(idx - 1, pre + if (include) values[idx] else 0, false)
    println(pre + if (include) values[idx] else 0)

As you can see, it's recursive. We can inset loops to get Polynomial complexity, and using recursive to get Exponential complexity.


Here are two simple examples in python with Big O/Landau (2^N):

def fib(num):    
    if num==0 or num==1:
        return num
        return fib(num-1)+fib(num-2)

for i in range(0,num):

#tower of Hanoi
def move(disk , from, to, aux):
    if disk >= 1:
        # from twoer , auxilart 
        move(disk-1, from, aux, to)
        print ("Move disk", disk, "from rod", from_rod, "to rod", to_rod)
        move(disk-1, aux, to, from)

n = 3
move(n, 'A', 'B', 'C')

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