this has been bugging me for a while.

Lets say you have a function f x y where x and y are integers and you know that f is strictly non-decreasing in its arguments,

i.e. f (x+1) y >= f x y and f x (y+1) >= f x y.

What would be the fastest way to find the largest f x y satisfying a property given that x and y are bounded.

I was thinking that this might be a variation of saddleback search and I was wondering if there was a name for this type of problem.

Also, more specifically I was wondering if there was a faster way to solve this problem if you knew that f was the multiplication operator.

Thanks!

Edit: Seeing the comments below, the property can be anything

Given a property g (where g takes a value and returns a boolean) I am simply looking for the largest f such that g(f) == True

For example, a naive implementation (in haskell) would be:

```
maximise :: (Int -> Int -> Int) -> (Int -> Bool) -> Int -> Int -> Int
maximise f g xLim yLim = head . filter g . reverse . sort $ results
where results = [f x y | x <- [1..xLim], y <- [1..yLim]]
```

`the largest f x y satisfying a property`

... What property? – belisarius Jun 10 '11 at 2:13`f x y`

odd? Less than 100? A perfect square? All three would have different optimal solutions. – btilly Jun 10 '11 at 2:16