I have come out with a solution in O(logN) if the dots are sorted on x coordinate.

It uses a divide-and-conquer approach. I divide the dots array based on their x coordinate in the 2D space.

Consider the 2D case.

Assume each dot is expressed in the following data structure:

```
class Point {
public float getX();
public float getY();
}
```

We have two inputs: dot array `ARRAY`

, and another dot `D`

.

Initially, we would like to partition `ARRAY`

into two parts: those dots that are on the "left" of `D`

, and those dots are on the "right" of `D`

.

```
int pivotIndex = partition(array, 0, array.length() - 1, d);
```

After partition, the dots with index less than `pivotIndex`

have x coordinate less than `d.getX()`

; the dots with index equal or greater than `pivotIndex`

have x coordinate equal or greater than `d.getX()`

.

If all dots are on the left side of `D`

, `pivotIndex`

would be `array.length() - 1`

. If all dots are on the right side of `D`

, `pivotIndex`

would be `-1`

. If some dots are on the left of `D`

and some dots are on the right of `D`

, then `pivotIndex`

would be between `0`

and `array.length() - 1`

. For dots having the same x coordinate as `D`

, they are considered as on the "right" side.

Now, the next step is to search the nearest dot on each partition:

```
Point p1 = getNearestDot(array, 0, pivotIndex, d);
Point p2 = getNearestDot(array, pivotIndex + 1, array.length() - 1, d);
if (p1 == null) return p2;
if (p2 == null) return p1;
return nearer(p1, p2, d);
```

It is possible that all the dots in the `ARRAY`

are on the left side of `D`

, then p2 would be null in this case. Similarly, if all dots in the `ARRAY`

are on the right side of `D`

, then p1 would be null.

The algorithm of `getNearestDot`

works as below:

```
// Find the nearest dot in array[low...high] inclusive which is closest to point d
Point getNearestDot(Point[] array, int low, int high, Point d) {
if (low > high)
return null;
if (low == high)
return array[low];
int middle = low + (high - low) >> 1;
Point p1 = getNearestDot(array, low, middle, d);
Point p2 = getNearestDot(array, middle + 1, high, d);
if (p1 == null) return p2;
if (p2 == null) return p1;
return nearer(p1, p2, d);
}
```

And finally, the function nearer(p1, p2, d) is to return either p1 or p2, whose distance to d is shorter.

sayduplicate or did I say that it wasrelated? – Nitrodist Aug 17 '10 at 3:27