# Big-O time complexity of recursive algorithm with nested for loops

I have a recursive algorithm with two nested for loops. I'm trying to figure out what the Big-O time complexity will be.

``````public Set<Person> getDistinctCombinedPersons(Collection<Person> persons) {
return permutatePersons(new ArrayList(persons), new HashSet<>(persons));
}
``````

``````private Set<Person> permutatePersons(List<Person> personList, Set<Person> personSet) {
if(personList.isEmpty() {
return personSet;
}

Set<Person> deepCopyPersonSet = new HashSet<>(personSet);

for(Person lPerson : personList) {
for(Person sPerson : deepCopyPersonSet) {
Person uniquePerson = CombinePeople.combine(lPerson, sPerson);
}
}

personList.remove(personList.size()-1);

return permutatePersons(personList, personSet);
}
``````
• (By the way, "deep copy" doesn't mean what you think it does.) – ruakh Nov 9 '17 at 23:05
• @ruakh yea I should have just said clone – Grammin Nov 9 '17 at 23:12
• @ruakh What is the Big-O complexity of my algorithm – Grammin Nov 9 '17 at 23:13
• I might be wrong here but it looks like `O(n^ n+2)`. – thebenman Nov 9 '17 at 23:18
• I'm wondering if I can just remove the outer for loop somehow? – Grammin Nov 10 '17 at 0:05

Assuming that you call `permutatePersons` with a list of length `N` the following recursion applies:

``````T(N) = T(N-1) + O(N^2)
``````

That's because in every recursive step you call function with list of length N-1 (where N the current length) and also you do computations of total complexity O(N^2) (outer loop O(N) -just traversing list and inner loop traversing the hash map in O(N) -O(1) for each element and total N element, So the nested loops are overall O(N^2)).

You can easily see:

``````T(N) = T(N-1) + O(N^2) = T(N-2) + O(N^2) + O((N-1)^2) =...

= O(n(n+1)(2n+1)/6) = O(n^3)
``````
• Thank you for the excellent answer. I'm now wonder if I take out the outer for loop is the algorithm still doing the same thing? – Grammin Nov 10 '17 at 0:03
• In terms of complexity no it will be reduced in `O(N^2)` due to the recursion now will be: `T(N)= T(N-1) + O(N)`. – game0ver Nov 10 '17 at 0:08
• Yea I'm wondering though if my algorithm is the exact same if I remove the outer for loop just less complex – Grammin Nov 10 '17 at 0:14
• No if I understand correctly what you're trying to do-to generate all 2-combinations of persons you need two loops-O(N^2) and O(N^3) overall... – game0ver Nov 10 '17 at 0:17

Because you have two nested loops you have the runtime complexity of `O(m*n)`. It's because for `n`-`Person`s in `deepCopyPersonSet` you iterate `m` times. `n` in this example is the quantity of `Person`s in `personList`.

``````for(int i = 0, i < m, i++)
for(int j = 0, j < n, j++)
``````

For every iteration of m, we have n iterations of code

• I also have the recursive call in there too – Grammin Nov 10 '17 at 0:06

Looks like it would be a big-O of n^2 for the nested loop:

``````  for(Person lPerson : personList) {
for(Person sPerson : deepCopyPersonSet) {
Person uniquePerson = CombinePeople.combine(lPerson, sPerson);
}
}
``````

You have to iterate over the each element for each element in the set.

And then the recursive call has a big O of n since it will call your method once for each element in the set.

Combining the two: `n * n^2` will result in a big O of n^3

• What effect does the recursion have? – jhpratt Nov 10 '17 at 0:01
• @jhpratt I don't this the method is using any recursion unless I'm missing something. Do you mean iteration? – luckydog32 Nov 10 '17 at 0:04
• Nope, the last line is a recursive call. – jhpratt Nov 10 '17 at 0:05
• I also have the recursive call in there too – Grammin Nov 10 '17 at 0:06