# How many subrectangle exists on a m x n grid

Given a `m x n` grid, how many unique sub-rectangles exist on such a grid?

For example,

`1 x 1` grid has 1 sub-rectangle.

`1 x 2` grid has 3 sub-rectangles.

I am looking for a general formula that can be used to directly compute the number existing sub-rectangle.

• How many triangles of size a x b are there on an m x n grid? Now sum that up for all a and b. – Chris Taylor Jul 29 '13 at 15:12
• I am looking for a single formula. – q0987 Jul 29 '13 at 15:12
• And I am trying to help you find it. – Chris Taylor Jul 29 '13 at 15:13
• @q0987 Right! So you get the answer by summing that over all i=1...m and j=1...n. It will help to expand the brackets some. Do you know the formula for the sum of whole numbers between 1 and N? – Chris Taylor Jul 29 '13 at 15:21
• This question appears to be off-topic because it is about mathematics. – David Eisenstat Jul 30 '13 at 17:03

The answer is `m(m+1)n(n+1)/4`.

a rectangle is defined by its two projections on the x-axis and on the y-axis.

projection on x-axis : number of pairs (a,b) such that 1 <= a <= b <= m = m(m+1)/2

idem for y-axis

Same answer as @Thomash provided, but with a bit more explanation, posting for posterity:

If you can figure this out in one dimension, it's easy to move it into two dimensions.

Let's look at a 1x5:

`````` 5 1x1 squares
+4 1x2 squares
+3 1x3 squares
+2 1x4 squares
+1 1x5 squares = 15 squares.
``````

The formula for this is simple: `sum = n(1 + n)/ 2`. In the case of 5, you want 5(1+5)/2 = 15.

So, to get your answer, just do this for n and m, and multiply them:

``````sumN = n(1+n)/2
sumM = m(1+m)/2
totalRectangles = nm(1+n)(1+m)/4
``````

For this lets assume you've `m` columns and `n` rows:

``````. . . .
. . . .
. . . .
``````

In above grid, `m` is 4 and `n` is 3. Let say you need to know how many rectangle you can form if you select top-left point. If you select top left-corner i.e.

``````* . . .
. . . .
. . . .
``````

You have have `3` point to choose in right and 2 points to choose at bottom, therefore total combinations are: `3*2 = 6`.

Therefore total number rectangle you can form will correspond to total number of rectangles at each point starting from `(0, 0)` (`top left` assume to be `0, 0`) till `(m-1, n-1)`.

If you try to find summation of this:

``````[(m-1)*(n-1) + (m-2)*(n-1) + (m-3)*(n-1) ... + (n-1)] +
[(m-1)*(n-2) + (m-2)*(n-2) ... + 1*(n-2)] +
[(m-1)*(n-3) + (m-2)*(n-3) ... + 1*(n-3)] +
...
``````

Which is equal to

``````(n-1)*(1 + 2 + .. + m-1)
+
(n-2)*(1 + 2 + .. + m-1)
+
.
.
+
1*(1 + 2 + ... + m-1)
``````

So you get

``````(1 + 2 + ... + n-1) * ( 1 + 2 + 3 ... + m-1)
= mn(n-1)(m-1)/4
``````

Since `m` and `n` is your case are not number of point but number of line segments formed. Above formula can be transformed:

``````m = m + 1
&
n = n + 1
``````

And it becomes

``````(n+1)(m+1)mn / 4
``````
• let's take `n=1` and `m=2`, then `[(m-1)*(n-1)(m+n)]/2=0` !!! Don't you think there is something wrong? – Thomash Jul 29 '13 at 15:37
• @Thomash If I understand it right, `n=1` means it single line so you should be making `0` rectangles. – Shivam Jul 29 '13 at 15:39
• You should read the question again: `1 x 2` grid has 3 sub-rectangles. – Thomash Jul 29 '13 at 15:41
• @Thomash Thanks! I've corrected my solution. – Shivam Jul 29 '13 at 15:56

I found a nice solution,
Lets look at the table borders of the grid.
And to create a rectangle we need four points on the borders.
2 points horizontal and 2 vertical

for example (n = 4, , m = 5)
Note that the choice is for N + 1 and M + 1 Because we look at the borders and not the rectangles themselves

Here is an example of one choose: We can calculate all the possible choices to chose 2 horizontal point and 2 vertical point using the binomial formula: An alternate solution,

In a m*n grid, we have m+1 lines and n+1 lines intersecting.

We use the fact, a rectangle can be formed by choosing a intersection point between these lines and another point which is not in either the horizontal or vertical line.

So, number of ways to choose a intersection point is (m+1)(n+1). and subsequently the number of ways to choose the second point is [which is number of ways to choose a intersection point excluding the points in the same horizontal and vertical line] is ((m+1)(n+1)-n-m-1)

Now consider a 1x1 grid , we use the fact this grid can be counted 4 times each uniquely by the 4 points.

Therefore the total number of rectangles which can formed is [(m+1)(n+1)((m+1)(n+1)-n-m-1)]/4

which can be simplified further to [(m+1)(n+1)(m)(n)]/4

The correct answer should be `(m(m+1)n(n+1))/4` minus the number of squares in the rectangular grid.

• Hi Shashank. You are answering to a pretty old question that already has an accepted answer. Can you explain in your post why it is better than the other answers? – Noel Widmer May 29 '17 at 12:41