# Example of Big O of 2^n

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?

## 6 Answers

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) {
return;
}
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)
and
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 > 1`means O(x^N). See:

https://en.wikipedia.org/wiki/Recurrence_relation

• 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
• 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) {
check_solution();
return;
}
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):

``````#fibonacci
def fib(num):
if num==0 or num==1:
return num
else:
return fib(num-1)+fib(num-2)

num=10
for i in range(0,num):
print(fib(i))

#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')
``````