# Given an array of best fit sizes , tell how many elements from the other array can be fitted(more details below)

There is an old dry well. Its sides are made of concrete rings. Each such ring is one meter high, but the rings can have different (internal) diameters. Nevertheless, all the rings are centered on one another. The well is N meters deep; that is, there are N concrete rings inside it. You are about to drop M concrete disks into the well. Each disk is one meter thick, and different disks can have different diameters. Once each disk is dropped, it falls down until:

• it hits the bottom of the well;
• it hits a ring whose internal diameter is smaller then the disk's diameter; or
• it hits a previously dropped disk. (Note that if the internal diameter of a ring and the diameter of a disk are equal, then the disk can fall through the ring.)

The disks you are about to drop are ready and you know their diameters, as well as the diameters of all the rings in the well. The question arises: how many of the disks will fit into the well?

Write a function: int falling_disks(int A[], int N, int B[], int M); that, given two zero-indexed arrays of integers − A, containing the internal diameters of the N rings (in top-down order), and B, containing the diameters of the M disks (in the order they are to be dropped) − returns the number of disks that will fit into the well. For example, given the following two arrays:

``````      A[0] = 5    B[0] = 2
A[1] = 6    B[1] = 3
A[2] = 4    B[2] = 5
A[3] = 3    B[3] = 2
A[4] = 6    B[4] = 4
A[5] = 2
A[6] = 3
``````

the function should return 4, as all but the last of the disks will fit into the well. The figure shows the situation after dropping four disks.

Assume that:

• N is an integer within the range [1..200,000];
• M is an integer within the range [1..200,000];
• each element of array A is an integer within the range [1..1,000,000,000];
• each element of array B is an integer within the range [1..1,000,000,000].

Complexity:

• expected worst-case time complexity is O(N);
• expected worst-case space complexity is O(N), beyond input storage (not counting the storage required for input arguments).
• Elements of input arrays can be modified.

I tried using a stack and doing something , but i am not able to get to O(n) solution , the worst case still remains O(n^2) even after some optimizations i think.

• Are you supposed to reorder the disks or are they supposed to be inserted in the well in the same order they are given to you? – Yochai Timmer Jan 11 '13 at 20:25
• @YochaiTimmer in the same order , you can read the example given in the question , it will make it more clear – Peter Jan 11 '13 at 20:27
• O(n^2) ? you must b using two loops for iterating over `ring` array and `disk` array. Since, number of disks never exceeds number of rings so you can just one loop to iterate and then do necessary computation – exexzian Jan 11 '13 at 21:51

First you need to modify the given internal diameters of the rings to fill up the unnecessary gaps. Suppose you have a ring of internal diameter `5` below a ring with internal diameter `2`. Any disk of size greater than `2` will not be able to reach that ring. So we can change the internal diameter of the lower ring to `2`. Basically we are filling up the gaps.

before:

after:

Use the following algorithm:

1. min = A[0]
2. i = 1
3. if i == N then STOP
4. if A[i] < min then min = A[i]
5. if A[i] > min then A[i] = min
6. i++
7. go to step 3

Now that the rings have formed a structure where each lower ring has an internal diameter lesser than or equal to the internal diameter of the upper ring, the next part is fairly simple. We will start inserting the disks from the bottom. If the first disk fits the lowest ring then fine otherwise we move on to the ring above it and so on. You can use an algorithm like:

1. i = N-1
2. j = 0
3. if i < 0 or j == M then STOP
4. if A[i] >= B[j] then j++
5. i--
6. go to step 3

The final value of the variable `j` is the required answer.

• thanks for the awesome explanation bane – Peter Jan 12 '13 at 7:26
• To further simplify the solution, you can remove j and only use count. – Kristian Evensen Jan 14 '13 at 9:34
• Was finding it difficult to picture the situation for this particular problem. Thanks for this! – adamjmarkham Apr 7 '13 at 23:24
• +1 for the fantastic answer, I would have never think this way. But to improve a litle bit of it, I would make just one i-- from the second loop, since i is always decremented, and would eliminate the second if A[i] < B[j] then i-- – Tito Oct 31 '13 at 11:07
• @Tito your edit was correct and I was not the one who rejected your suggestion. – bane Nov 4 '13 at 19:39
``````public static int falling_disks(int[] A, int[] B)
{
int mymin = A[0];
int nbDisk = 0;

for (int i = 0; i < A.Length; i++)
{
if (A[i] < mymin) mymin = A[i];
if (A[i] > mymin) A[i] = mymin;
}

for (int i = A.Length - 1; i >= 0; i--)
{
if (B[nbDisk] <= A[i]) nbDisk++;
if (nbDisk == B.Length) break;
}

return nbDisk;
}
``````
• This algorithm provide correct functionality and scalability! – Yuriy Chernyshov Apr 5 '13 at 18:43

It's actually pretty easy. First you have to go from the top of the well and remove the unreachable space (set A[x] to minimum so far).

Second thing is just going from the bottom of the well and putting disks if they fit.

• Can you please explain with an example , what are you trying to do with the bottom thing – Peter Jan 11 '13 at 20:48
• @Peter, after removing unreachable space the well becomes a cone. If disk can fit in some position, it can also fall to it. So you just check if it can fit, if so then get the next disk. Then you go one level up, etc. – zch Jan 11 '13 at 20:58
• then i would like to have more clarity on what is unreachable space in your case and how do you plan to remove it , i thot it was just find the first fit for the first element and remove the remaining below ones. If it is that then it wont work – Peter Jan 11 '13 at 21:06
• Can you just take this example,[5,6,4,3,6,2,3] as well and input as [2,3,5,2,4] to be more clear – Peter Jan 11 '13 at 21:07
• @Peter, added image with unreachable in red. – zch Jan 11 '13 at 21:29

A little optimization... on the general solution that is executed in O(N) and it is correct.

If the value of the first disk in the B array is < of the first diameter in the A array you could return 0 immediately without execute the first adjustment of the A array (that represent the dry well).

Imagine attaching a fragile surrounding material to the first disk which will snap off as it drops.

Record in an array A[k] the width of this fragile disk as it reaches depth k.

This can be done in O(n) by simulating the fall of the first disk.

For the next disk we either land on the previous disk or stop at an earlier depth. We will stop at an earlier depth if and only if A[k] for our current depth is less than the size of the next disk.

So the algorithm for placing the subsequent disks is:

1. Reduce current depth by 1
2. If current depth is 0 then we have filled the well STOP
3. While A[current depth] is less than the width of current ring goto step 1
4. Move to next ring and goto step 1

Current depth is decremented on every loop so this will take O(n) steps to complete.

• [2 , 4 , 4 , 5] and [ 2 , 3] , it fails for this case – Peter Jan 11 '13 at 20:44
``````  class Program
{
static void Main(string[] args)
{
int []A= new int[] {5,6,4,3,6,2,3};
int[] B = new int[] { 2, 3, 5, 2, 4 };
// Array.Reverse(A);

Program obj = new Program();
obj.NoOfDisc(A,B);

}

public void NoOfDisc (int[] A, int[] B)
{
int i;
int count= 0;
int   n= (A.Length)-1;
for (i = 0; i < A.Length; i++)
{
if (n >= 0)
{

if (B[i] < A[n])
{
count = count + 1;
A[n] = B[i];
n = n - 1;
}

else
{
i = i - 1;
n = n - 1;
}
}
}

Console.WriteLine(count);