There is no algorithm that can determine a complexity of a program [at all]. It is a part of the Halting Problem - you cannot determine if a certain algorithm will stop or not. [You cannot estimate if it is `Theta(infinity)`

or anything less then it]

As a rule of thumb - **usually** `O(n!)`

algorithms are invoking recursive call in a loop with a decreasing range, while `O(2^n)`

algorithms invoke a recursive call twice in each call.

**Note**: Not all algorithms that invokes a recursive call twice are `O(2^n)`

- a quicksort is a good example for an `O(nlogn)`

algorithm which also invokes a recursive call twice.

**EDIT: For example:**

SAT brute-force solution `O(2^n)`

:

```
SAT(formula,vars,i):
if i == vars.length:
return formula.isSatisfied(vars)
vars[i] = true
temp = SAT(formula,vars,i+1) //first recursive call
if (temp == true) return true
vars[i] = false
return SAT(formula,vars,i+1) //second recursive call
```

Find all permutations: `O(n!)`

```
permutations(source,sol):
if (source.length == 0):
print sol
return
for each e in source:
sol.append(e)
source.remove(e)
permutations(source,sol) //recursive call in a loop
source.add(e)
sol.removeLast()
```