# Dynamic Programming: O(N)

It has already mentioned that the problem has a solution by using a Triangle of Pascal, and its relation to the Binomial coefficient. Also the Catalan number's entry has a nice illustration for the *n* × *n* case.

*n* × *n* case

By making use of the aforementioned resources you can conclude that for a grid of size *n* × *n* you need to calculate C(2n - 2, n - 1). You can double-check it by rotating the grid by 45 degrees and mapping the Pascal's Triangle.

In practical terms, calculating this number directly requires to calculate, in a naive way, at most 3 different factorials which is a very expensive task. If you can pre-calculate them all then there's no discussion here and you can argue this problem has complexity O(1). If you are not interested in the pre-calculated way then you can continue reading.

You can calculate such ominous number using Dynamic Programming (DP). The trick here is to perform the operation in smaller steps which won't require you to calculate a large factorial number at all.

That is, to calculate C(n, k), you can start by placing yourself at C(n, 1) and walk to C(n, k). Let's start by defining C(n, k) in terms of C(n, k - 1).

```
C(n, k) = n! / k! * ( n - k )! ; k! = (k - 1)! * k
= n! / (k - 1)! * k * (n - k)! ; (n - k)! = (n - k + 1)! / (n - k + 1)
= n! * (n - k + 1) / (k - 1)! * k * (n - k + 1)! ; C(n, k - 1) = n! / (k - 1)! * ( n - k + 1 )!
= C(n, k - 1) * (n - k + 1) / k
```

Based on this, you can define a function to calculate C(n, k) as follows in Python:

```
def C(n, k):
"""
Calculate C(n, k) using Dynamic Programming.
C(n, k) = C(n, k - 1) * (n - k + 1) / k
"""
C = 1
for ki in range(1, k + 1):
C = C * (n - ki + 1) / ki
return C
```

It runs in linear time, O(N).

For the *n* × *n* case you need to calculate C(2n - 2, n - 1).

```
>> print "Response: %dx%d = %d" % (n, n, C(2 * n - 2, n - 1),)
Response: 10000x10000 = 5...
```

*n* × *m* case

For the general *n* × *m* case, you just need to calculate C(n + m - 2, m - 1).

```
>> print "Response: %dx%d = %d" % (n, m, C(n + m - 2, m - 1),)
Response: 10000x10000 = 5...
```

Last but not least, you can see a live example at Ideone here.

# Timings

I ran the algorithm for the following grid sizes.

```
N x N | Response's Length | Time
-----------------+-------------------+-----------
1 x 1 | 1 chars | 0.000001
10 x 10 | 5 chars | 0.000004
100 x 100 | 59 chars | 0.000068
1000 x 1000 | 600 chars | 0.002207
10000 x 10000 | 6018 chars | 0.163647
100000 x 100000 | 60203 chars | 40.853971
```

It seems the operations above a grid size of 100 000 x 100 000 get absurdly expensive due to the very large numbers involved. Nothing to be surprised though.