# Merging K Sorted Arrays/Vectors Complexity

While looking into the problem of merging k sorted contiguous arrays/vectors and how it differs in implementation from merging k sorted linked lists I found two relatively easy naive solutions for merging k contiguous arrays and a nice optimized method based off of pairwise-merging that simulates how mergeSort() works. The two naive solutions I implemented seem to have the same complexity, but in a big randomized test I ran it seems one is way more inefficient than the other.

## Naive merging

My naive merging method works as follows. We create an output `vector<int>` and set it to the first of `k` vectors we are given. We then merge in the second vector, then the third, and so on. Since a typical `merge()` method that takes in two vectors and returns one is asymptotically linear in both space and time to the number of elements in both vectors the total complexity will be `O(n + 2n + 3n + ... + kn)` where `n` is the average number of elements in each list. Since we're adding `1n + 2n + 3n + ... + kn` I believe the total complexity is `O(n*k^2)`. Consider the following code:

``````vector<int> mergeInefficient(const vector<vector<int> >& multiList) {
vector<int> finalList = multiList[0];
for (int j = 1; j < multiList.size(); ++j) {
finalList = mergeLists(multiList[j], finalList);
}

return finalList;
}
``````

## Naive selection

My second naive solution works as follows:

``````/**
* The logic behind this algorithm is fairly simple and inefficient.
* Basically we want to start with the first values of each of the k
* vectors, pick the smallest value and push it to our finalList vector.
* We then need to be looking at the next value of the vector we took the
* value from so we don't keep taking the same value. A vector of vector
* iterators is used to hold our position in each vector. While all iterators
* are not at the .end() of their corresponding vector, we maintain a minValue
* variable initialized to INT_MAX, and a minValueIndex variable and iterate over
* each of the k vector iterators and if the current iterator is not an end position
* we check to see if it is smaller than our minValue. If it is, we update our minValue
* and set our minValue index (this is so we later know which iterator to increment after
* we iterate through all of them). We do a check after our iteration to see if minValue
* still equals INT_MAX. If it has, all iterators are at the .end() position, and we have
* exhausted every vector and can stop iterative over all k of them. Regarding the complexity
* of this method, we are iterating over `k` vectors so long as at least one value has not been
* accounted for. Since there are `nk` values where `n` is the average number of elements in each
* list, the time complexity = O(nk^2) like our other naive method.
*/
vector<int> mergeInefficientV2(const vector<vector<int> >& multiList) {
vector<int> finalList;
vector<vector<int>::const_iterator> iterators(multiList.size());

// Set all iterators to the beginning of their corresponding vectors in multiList
for (int i = 0; i < multiList.size(); ++i) iterators[i] = multiList[i].begin();

int k = 0, minValue, minValueIndex;

while (1) {
minValue = INT_MAX;
for (int i = 0; i < iterators.size(); ++i){
if (iterators[i] == multiList[i].end()) continue;

if (*iterators[i] < minValue) {
minValue = *iterators[i];
minValueIndex = i;
}
}

iterators[minValueIndex]++;

if (minValue == INT_MAX) break;
finalList.push_back(minValue);
}

return finalList;
}
``````

## Random simulation

Long story short, I built a simple randomized simulation that builds a multidimensional `vector<vector<int>>`. The multidimensional vector starts with `2` vectors each of size `2`, and ends up with `600` vectors each of size `600`. Each vector is sorted, and the sizes of the larger container and each child vector increase by two elements every iteration. I time how long it takes for each algorithm to perform like this:

``````clock_t clock_a_start = clock();
finalList = mergeInefficient(multiList);
clock_t clock_a_stop = clock();

clock_t clock_b_start = clock();
finalList = mergeInefficientV2(multiList);
clock_t clock_b_stop = clock();
``````

I then built the following plot:

My calculations say the two naive solutions (merging and selecting) both have the same time complexity but the above plot shows them as very different. At first I rationalized this by saying there may be more overhead in one vs the other, but then realized that the overhead should be a constant factor and not produce a plot like the following. What is the explanation for this? I assume my complexity analysis is wrong?

Even if two algorithms have the same complexity (`O(nk^2)` in your case) they may end up having enormously different running times depending upon your size of input and the 'constant' factors involved.
For example, if an algorithm runs in `n/1000` time and another algorithm runs in `1000n` time, they both have the same asymptotic complexity but they shall have very different running times for 'reasonable' choices of `n`.
For your case, although your calculation of complexities seem to be correct, but in the first case, the actual running time shall be `(nk^2 + nk)/2` whereas in the second case, the running time shall be `nk^2`. Notice that the division by `2` may be significant because as `k` increases the `nk` term shall be negligible.
For a third algorithm, you can modify the Naive selection by maintaining a heap of `k` elements containing the first elements of all the `k` vectors. Then your selection process shall take `O(logk)` time and hence the complexity shall reduce to `O(nklogk)`.
• Yeah I naively (no pun intended) underestimated the lower order terms that still exist as well as the multiplication of constant factors (1/2 for example). Thanks your explanation makes sense. As far as `O(nklog(k))` the three ways I've found have been 1.) sorting an array of all nk elements, 2.) pairwise merging, and 3.) using a heap as you have said. Commented Aug 29, 2016 at 21:21