The library defines the type `Memo a`

, which is a "memoizer" for functions taking arguments of type `a`

. The key to understanding how to use this library is to understand how to use and compose these memoizers.

In the simple case, you have a single argument function and a simple memoizer, for example a Fibonacci function and a memoizer for `Integral`

arguments. In such a case, we obtain the memoized function by applying the memoizer to the function to be memoized:

```
fib = Memo.integral fib'
where
fib' 0 = 0
fib' 1 = 1
fib' x = fib (x-1) + fib (x-2)
```

Some memoizers take arguments to customize their behavior, for example `arrayRange`

. In the following example, `fib n`

will only be memoized if `n`

is between 1 and 100.

```
fib = Memo.arrayRange (1, 100) fib'
where ...
```

The library also provides combinators for building more complex memoizers out of simple ones. For example, `list`

, which turns a memoizer for `a`

into a memoizer for `[a]`

.

Finally, to memoize functions of multiple arguments there are the functions `memo2`

and `memo3`

, which take a memoizer for each argument plus a function and returns a memoized function.

So to memoize your two-argument function, we will need to use `memo2`

. We can use the `integral`

memoizer for the `Int`

argument, and for the `[Int]`

argument we can use `list integral`

. Putting this together, we get something like this:

```
memo2 (list integral) integral foo
```

However, you can also use more specific memoizers if you know the numbers are in some specified range. For example, if the numbers in the list are between 1 and 10 and the second argument is between 15 and 20:

```
memo2 (list $ arrayRange (1, 10)) (arrayRange (15, 20)) foo
```

Whether this makes sense or not, depends on your application.