If I have an randomly shuffled array with the numbers 1 to n, what is a good way to find that the array contains the range 1 to n (no repeats)? For example,
n = 6; [1, 3, 6, 2, 4, 5] => true
n = 6; [1, 1, 2, 4, 5, 6] => false

Make an array of size n, pass through your array and increment the position in the array with that as an index. If at any time the counts array has non 0 or non 1 value, you can stop. If you can't find the index, you can stop now since you know you don't have it. Here's a quick Java example. In this example, you do not need to count at the end because anything that would cause a non1 value would cause a failure during the middle.



Sounds suspiciously like homework, but... This is very simple using a Set:



Use the Gauss formula to precompute what the final sum will be:
Do a linear loop over your shuffled list, adding the numbers as you go, and if your running sum is the same as your final sum, return true. 

You're going to want to sort the array. Here is a link to some popular choices, http://en.wikipedia.org/wiki/Sorting_algorithm. Personally I recommend bubble sort for a simple solution, and merge sort for a harder, faster version. Once the list is sorted, you can check for repeats by iterating through the array and making sure that the next # is greater than the previous. Also, this can be added to the sort to shorten computing time. Finally, check the first and last numbers to make sure they equal 1 and n. 


If extra space is not allowed(typical constraint in an interview question), then you can sort the array first and scan the sorted array sequentially from left to right to see if every element is larger than its previous element by 1. The time complexity is O(n*logn). 

