```
int[] items1={1,2,3,4};
List<int> newList = new List<int>() { 1, 2, 3, 4, 5, 56, 788, 9 };
newList.RemoveAll((int i) => { return items.Contains(i); });
```

1) The interviewer replied that the
algorithm i have employed will
gradually take time if the item grows
and asked me to give even better and
faster one.What would be the efficient
algorithm ?

Your `items1`

has a length m, and `newlist`

has a length n. Since you're performing a linear lookup on `items1`

for each item in `newlist`

, your solution is O(n*m). From my point of view, your implementation is perfectly acceptable, and we probably shouldn't worry about optimizations until we need to.

Evidently, however, its not good enough for the interview. Alright, what's "good enough" to the interviewer? Who knows. Now, if you don't mind taking some risks in your interview, you can challenge your interviewer to give more detail on the problem. Inform him that lots of factors and assumptions affect the speed of our code, *especially* the choice of data structure:

Assuming you require indexed access to `newList`

, then converting `items1`

to a HashSet (which has O(1) lookup) improves your algorithm to the O(n) time required to rebuild the array.

Assuming `newList`

is a "bag" of elements, meaning we don't care about the order of elements in the collection, then representing `newList`

with a hashset allows us to remove m items in O(m) time.

Assuming we need to preserve the insertion order of elements in the collection, you can represent `newList`

as a LinkedList{T}, while using a Dictionary{T, LinkedListNode} as a lookup table. When you add an item to the collection, you add it to the LinkedList, then add the newly created node to the dictionary. The LinkedList keeps the insertion order, and the Dictionary allows us to remove m items in O(m) time. However, we sacrifice indexed access to the collection.

Assuming `newList`

keeps items in sorted order (doesn't appear to be the case with the sample code provided, but just humor me), most flavors of balanced binary trees will remove m items in O(m log n), they also support O(n) sorted-order traversal. Or if you're in right mood, a skip-list does the same job, only sillier.

3) He asked me to provide an example
for Two-Way-Closure? (General I am
aware of closure, what is meant for
Two-Way-Closure?, I replied i have
ever heard that term,but he did not
satisfy).

I've never heard of it either, and Google doesn't appear to turn up any relevant articles (apart from this thread, none of the results on the first 5 pages are programming or even computer related). The interviewer is an idiot.