analysing an algorithm for time complexity

I have written a function that merges two linked list. (Note that the function is based on pre-given code in case you wonder why i'm calling a function `node(i)`).

``````public SLL mergeUnsorted(SLL otherList)
{
// find length of this list
int length = 0 ;
Iterator itr = this.iterator() ;
while (itr.hasNext())
{
Object elem  = itr.next() ;
length++ ;
}

// get each node from this list and
// add it to front of otherList list
int i = length -1 ;
while (i >= 0)
{
// returns node from this list
SLLNode ins = node(i) ;

ins.succ = otherList.first ;
otherList.first = ins ;
i-- ;
}
return this ;
}
``````

first part O(n) second part O(n)

overall complexity O(n)

or is it O(n^2) because i traverse the list twice?

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Because you traversed the list twice, it's O(2n).. which is O(n). It is linear growth.

Also, in most programming languages, the length of a collection is already tracked, so you can just pull that property instead of iterating twice.

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Traversing twice is just a constant multiplier. As long as the multiplier doesn't depend on n, it's still O(n). EDIT: However, do make sure that inserting into the other list is constant-time. If the time to do it is proportional to the size of the other list, well, I think you can see what happens then.

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From an academic p.o.v. and big-Oh notation p.o.v. this is 100% correct. I thought it would be interesting to note though that for comparing two O(n) algorithms the number of atomic operations per N is also interesting (for atomic in this context think of (floating) point operations, logical operations and branching) –  Roy T. Mar 26 '11 at 21:23