# What is the time complexity and space complexity of this algorithm to find Anagrams?

I am working on an interview question from Amazon Software
The question is
"Design an algorithm to take a list of strings as well as a single input string, and return the indices of the list which are anagrams of the input string, disregarding special characters."
I was able to design the algorithm fine, what I did in psuedo code was
1.Create an array character count of the single input string
2.For each string the list, construct the an array character count
3.Compare the character count of each string in list to single output string
4.If same, add it to a list that holds all the indexes of anagrams.
5.Return that list of indices.

Here is my implementation in Java(it works, tested it)

``````public static List<Integer> indicesOfAnag(List<String> li, String comp){
List<Integer> allAnas = new ArrayList<Integer>();
int[] charCounts = generateCharCounts(comp);
int listLength = li.size();
for(int c=0;c<listLength; c++ ){
int[] charCountComp = generateCharCounts(li.get(c));
if(isEqualCounts(charCounts, charCountComp))
}
return allAnas;
}
private static boolean isEqualCounts(int[] counts1, int[] counts2){
for(int c=0;c<counts1.length;c++) {
if(counts1[c]!=counts2[c])
return false;
}
return true;
}
private static int[] generateCharCounts(String comp) {
int[] charCounts = new int;
int length = comp.length();
for(int c=0;c<length;c++) {
charCounts[Character.toLowerCase(comp.charAt(c)) - 'a'] ++;
}
return charCounts;
}
``````

What I am having trouble with is analyzing the space and time complexity of this algorithm because of both of the sizes of the list and of each string.
Would the time complexity algorithm just be O(N) where N is the size of the list(processing each String once) or do I have to take into account the composite complexity of the length of each String, in that case, O(N * n) where n is the length of the string? I did N * n because you ware processing n N times. And would space complexity be O(N) because I am creating N copies of the 26 length array?

• I dont think its too broad. Theres one answer for space and time complexity..... – committedandroider Mar 2 '15 at 4:36
• If the underlying implementation of `List<String>` passed in to `indicesOfAnag(...)` is a `LinkedList`, then the `li.get(c)` will be O(N) and the whole thing becomes quadratic in the size of the input. Better overall to use an iterator to avoid this. – msandiford Mar 2 '15 at 5:05
• @msandiford so this is an example of O(N^2) ? just wondering because im learning about this this semester. – JRowan Mar 2 '15 at 5:14
• @JRowan If you see the answer below, with arraylist, it should be O(N) where N is the sum of all the lengths of strings – committedandroider Mar 2 '15 at 5:14
• so the time complexity is linear? – JRowan Mar 2 '15 at 5:15

And would space complexity be O(N) because I am creating N copies of the 26 length array?

Yes.

Would the time complexity algorithm just be O(N) where N is the size of the list

No. Time depends on size of input strings, it'll be O(comp.length+sum_of_li_lengths).

• Wouldn't it just be N * n, where n is the average length of a string? I don't get why you added comp.length and sum_of_li_lengths. – committedandroider Mar 2 '15 at 4:40
• Nope, it wouldn't. Strings in `li` can all contain only one character, but `li` can contain millions of strings. That's what called input data size in complexity theory. – Everv0id Mar 2 '15 at 4:43
• oh so you included two variables in your analysis because the runtime depends on both of them? But why do the sum of all the lengths? Each time N runs, it's just going to look at one String. – committedandroider Mar 2 '15 at 4:46
• Sorry, i missed smth in your question. In your case time complexity doesn't depend on size of the list. It depends only on total length of all your strings. This is because every symbol is handled once. – Everv0id Mar 2 '15 at 4:49
• I know it has to depend on the size of the list. Theres a for loop that ends at the size of the list. The algorithm will scale up linearly with size. – committedandroider Mar 2 '15 at 4:52