Here's a possible solution that I can think from the top of my mind:

- Iterate over each pair of circles (c
_{1}, c_{2}) and calculate two values *(P.S (c*_{1}, c_{2}) is not the same as (c_{2}, c_{1}))
- If c
_{2} lies completely inside c_{1} then ignore this pair.
*Value*_{1} - The shortest distance between the circle c_{1} and c_{2}, - which is *distance between their centers - r*_{1} - r_{2} for disjoint circles, *0* for intersecting circles and *r*_{2} - dist - r_{1} for cases where c_{1} lies inside c_{2}.
*Value*_{2} - Minimum value with which r_{1} should be increased such that c_{1} completely engulfs c_{2} such that they don't intersect at all - which is *distance between their centers + r*_{2} - r_{1} for disjoint or intersecting circles and *dist + r2* for rest.

- This range [
*Value*_{1}, *Value*_{2}] defines the quantity with which the radius of circle c_{1} should be increased such that it intersects with c_{2}, which in our case is defined by K. If K belongs to the range [*Value*_{1}, *Value*_{2}], then we can gaurantee that there will exits a point P_{1} on c_{1} and point P_{2} on c_{2} such that distance between them is K. This is because if we increment the radius of c_{1} in that range, it will intersect with c_{2}.
- The above operation will be of time-complexity O(n
^{2}). We can collect all the ranges from all possible pairs of circles and to answer any query we just need to check if there's a range in which the given K lies.
- To faciliate the query we can use a Binary Indexed Tree for storing our ranges wherein which we add +1 at index
*Value*_{1} and -1 at index (*Value*_{2} + 1) for the Binary Indexed Tree and then for every query we check if read on index K is > 0. The enables us to return the answer for any query in O(log(K)). The cost of constructing the tree is O(N^{2}log(K)) - inclusive of forming all pairs of circle.
- We can also use an auxiliary array instead of a Binary Indexed Tree to answer query in O(1), the scope of which I'm willing to discuss if required.

As for the auxiliary array approach, initialize an array of length K i.e. 10^6 with all elements initially set to 0. Now maintain a min heap of all Value_{1} and another min heap of all the values Value_{2}.
Now,

```
aux_array = [0, 0, ... ]
curVal = 0
for i in range(0, 10^6):
while minHeapValue1.root() == i:
curVal += 1
minHeapValue1.rootPop()
while minHeapValue2.root() == i:
curVal -= 1
minHeapValue2.rootPop()
aux_array[i] = curVal
```

Now if aux_array[query_k_value] > 0, then it means there is a range which includes `query_k_value`

, else not.

Hence the total time complexity of the problem is O(Qlog(K) + N^{2}log(K)).

`pow()`

, to compute small integer powers, especially squares. (2) Do not compute square roots at all; instead, compare squared distances. Most of all, (3) read all the distances first and store them in an array, so that you can make the the loop over those the innermost one. That will allow you to avoid redundantly repeating computations of inter-circle distances and overlap cases.6more comments