# Return the k elements of an array farthest from val

Method needs to return the k elements a[i] such that ABS(a[i] - val) are the k largest evaluation. My code only works for integers greater than val. It will fail if integers less than val. Can I do this without importing anything other than java.util.Arrays? Could somebody just enlighten me? Any help will be much appreciated!

`````` public static int[] farthestK(int[] a, int val, int k) {// This line should not change
int[] b = new int[a.length];
for (int i = 0; i < b.length; i++) {
b[i] = Math.abs(a[i] - val);
}
Arrays.sort(b);
int[] c = new int[k];
int w = 0;
for (int i = b.length-1; i > b.length-k-1; i--) {
c[w] = b[i] + val;
w++;
}
return c;
}
``````

test case:

``````  @Test public void farthestKTest() {
int[] a = {-2, 4, -6, 7, 8, 13, 15};
int[] expected = {15, -6, 13, -2};
int[] actual = Selector.farthestK(a, 4, 4);
Assert.assertArrayEquals(expected, actual);
}

There was 1 failure:
1) farthestKTest(SelectorTest)
arrays first differed at element [1]; expected:<-6> but was:<14>
FAILURES!!!
Tests run: 1,  Failures: 1
``````
-

The top k problem can be solved in many ways. In your case you add a new parameter, but it really doesn't matter.

The first and the easiest one: just sort the array. Time complexity: O(nlogn)

``````public static int[] farthestK(Integer[] a, final int val, int k) {
Arrays.sort(a, new java.util.Comparator<Integer>() {
@Override
public int compare(Integer o1, Integer o2) {
return -Math.abs(o1 - val) + Math.abs(o2 - val);
}
});
int[] c = new int[k];
for (int i = 0; i < k; i++) {
c[i] = a[i];
}
return c;
}
``````

The second way: use a heap to save the max k values, Time complexity: O(nlogk)

``````/**
* Use a min heap to save the max k values. Time complexity: O(nlogk)
*/
public static int[] farthestKWithHeap(Integer[] a, final int val, int k) {
PriorityQueue<Integer> minHeap = new PriorityQueue<Integer>(4,
new java.util.Comparator<Integer>() {
@Override
public int compare(Integer o1, Integer o2) {
return Math.abs(o1 - val) - Math.abs(o2 - val);
}
});
for (int i : a) {
if (minHeap.size() > k) {
minHeap.poll();
}
}
int[] c = new int[k];
for (int i = 0; i < k; i++) {
c[i] = minHeap.poll();
}
return c;
}
``````

The third way: divide and conquer, just like quicksort. Partition the array to two part, and find the kth in one of them. Time complexity: O(n + klogk) The code is a little long, so i just provide link here.

Selection problem.

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Is there a reason you've changed `int` to `Integer` here? –  Chris Hayes Sep 4 '13 at 3:40
@ChrisHayes Custom comparator could only used to compare Objects, so i have to change int[] to Integer[], you can also do this copy inside the method. –  faylon Sep 4 '13 at 3:45
@Override What does this mean? Can you make the code more clear? –  catchwisdom Sep 4 '13 at 3:47
@catchwisdom you could try to learn more about Comparator in java. You always need to write your own Comparator to sort different arrays. Override is just a annotation, means that this method override a parent method or implement an interface. –  faylon Sep 4 '13 at 3:55
@catchwisdom ... Try to think by yourself since it's a homework... It's so easy to achieve your requirement, by adding a few lines. –  faylon Sep 4 '13 at 6:00

Sorting the array will cost you O(n log n) time. You can do it in O(n) time using k-selection.

1. Compute an array B, where B[i] = abs(A[i] - val). Then your problem is equivalent to finding the k values farthest from zero in B. Since each B[i] >= 0, this is equivalent to finding the k largest elements in B.
2. Run k-selection on B looking for the (n - k)th element. See Quickselect on Wikipedia for an O(n) expected time algorithm.
3. After k-selection is complete, B[n - k] through B[n - 1] contain the largest elements in B. With proper bookkeeping, you can link back to the elements in A that correspond to them (see pseudocode below).

Time complexity: O(n) time for #1, O(n) time for #2, and O(k) time for #3 => a total time complexity of `O(n)`. (Quickselect runs in O(n) expected time, and there exist complicated worst-case linear time selection algorithms).

Space complexity: `O(n)`.

Pseudocode:

``````farthest_from(k, val, A):
let n = A.length

# Compute B. Elements are objects to
# keep track of the original element in A.
let B = array[0 .. n - 1]
for i between 0 and n - 1:
B[i] = {
value: abs(A[i] - val)
index: i
}

# k_selection should know to compare
# elements in B by their "value";
# e.g., each B[i] could be java.lang.Comparable.
k_selection(n - k - 1, B)

# Use the top elements in B to link back to A.
# Return the result.
let C = array[0 .. k - 1]
for i between 0 and k - 1:
C[i] = A[B[n - k + i].index]

return C
``````
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Thanks! I'm looking through it right now. I will get back to you later. –  catchwisdom Sep 4 '13 at 4:27

You can modify this algorithm a little and use it for printing k elements according to your requirement.(This is the only work you will need to do with some changes in this algorithm.)

This algo uses Selection Sort - so the output would be a Logarithmic Time Complexity based answer which is very efficient.

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`O(n)` algorithm, from Wikipedia entry on partial sorting: