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SORRY GUYS! MY MISTAKE! Thanks for your reminder, I found out f(0,k) == f(k,0) == 1. This question is about how to count the number of shortest paths from grid (0,0) to (m,n).

I have to solve the following equation now, find out exactly what f(m,n) equal to.

1) f(m,n) = 0 : when (m,n) = (0,0)
**2) f(m,n) = 1 : when f(0,k) or f(k,0)**
3) f(m,n) = f(m-1,n) + f(m,n-1) : when else

for example:

1) f(0,0) = 0; 
2) f(0,1) = 1; f(2,0) = 1; 
3) f(2,1) = f(1,1) + f(2,0) = f(0, 1) + f(1, 0) + f(2, 0) = 1 + 1 + 1 = 3  

I remember there is a standard way to solve such kinds of binary recurrence equation as I learned in my algorithm class several years ago, but I just cannot remember for now.

Could anyone give any hint? Or a keyword how to find the answer?

share|improve this question
Do you mean you need to find the formula that doesn't use recursion? Or just an algorithm that computes the recurrence efficiently? – svick Jan 26 '12 at 23:03
Are you sure about f(2,1)=3 ? I read f(2,1)=f(1,1)+f(2,0)=(f(0,1)+f(1,0))+f(2,0)=(1+1)+2=2+2=4 – Eugen Rieck Jan 26 '12 at 23:03
You are tring to find the closed form solution right? – ElKamina Jan 26 '12 at 23:05
@EugenRieck Yes Thank you!! I made a mistake on that. Your understanding is correct. – JXITC Jan 26 '12 at 23:11
@svick yes, I need to reduce a equation only contains m and n, without any recurrence formula. It's a math problem, not a programming problem. – JXITC Jan 26 '12 at 23:12
up vote 10 down vote accepted

Ugh, I was just having fun going through my old textbooks on generating functions, and you went and changed the question again!

This question is about how to count the number of shortest path from grid (0,0) to (m,n).

This is a basic combinatorics question - it doesn't require knowing anything about generating functions, or even recurrence relations.

To solve, imagine the paths being written out as a sequence of U's (for "up") and R's (for "right"). If we are moving from (0,0) to, say, (5, 8), there must be 5 R's and 8 U's. Just one example:


There will always be, in this example, 8 U's and 5 R's; different paths will just have them in different orders. So we can just choose 8 positions for our U's, and the rest must be R's. Thus, the answer is

(8+5) choose (8)

Or, in general,

(m+n) choose (m)
share|improve this answer
WOW! Pretty explanation! Love you! – JXITC Jan 26 '12 at 23:31

This is simply the binomial coefficient

f(m,n) = (m+n choose m) = (m+n choose n)

You can prove this by noting that they satisfy the same recurrence relation.

To derive the formula (if you couldn't just guess and then check), use generating functions as Chris Nash correctly suggests.

share|improve this answer
thank you so much:) – JXITC Jan 26 '12 at 23:38

Try looking up "generating functions" in the literature. One approach would be to imagine a function P(x,y) where the coefficient of x^m y^n is f(m,n). The recurrence line (line 3) tells you that P(x,y) - x.P(x,y) - y.P(x,y) = (1-x-y) P(x,y) should be pretty simple except for those pesky edge values. Then solve for P(x,y).

Are you sure f(k,0) = f(0,k) = k, and not 1, maybe? If it were, I'd say the best bet would be to write some values out, guess what they are, then prove it.

share|improve this answer
= =! I made a mistake again. Yes, it's 1...... OMG, how silly I was. I am about to rewrite the question. – JXITC Jan 26 '12 at 23:17
And thank you for your answer, I am looking at generating functions now. :) – JXITC Jan 26 '12 at 23:21
That's great news... the original problem was very ugly. The revised one is very pretty. Write out some values in a table, and turn your head 45 degrees. ;) – Chris Nash Jan 26 '12 at 23:25
Haha, that's much clearer, I now finally realize its underlying point. Thank you! – JXITC Jan 26 '12 at 23:31
grins f(0,0) is 1 too, actually. There's precisely one way to go nowhere :) – Chris Nash Jan 26 '12 at 23:36

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