Well if you use recursion it's good to know the meaning of the function. This helps a lot to understand why the method is recursive. Furthermore calculating the function on paper is mostly done by a method called "dispatching". In this case you see that `mystrey(0) = 0`

(the if-case).

If you want to calculate the value of mystrey(10) you know it's a sum of 10, mystrey(1) and mystrey(2).

You simply create a table where one can put:

```
0: 0
10: 10+f(1)+f(2)
```

we now calculate the value of the function with the highest argument so mystrey(2):

```
2: 2+f(0)+f(0)
```

we know the value of f(0), it's already in the table, so

```
2: 2+0+0=2
```

now we calculate `f(1)=1`

We finally conclude that `f(10)=10+f(1)+f(2)=10+1+2=13`

.

Using a table becomes helpfull when there is a lot of recursion. A lot of times recursion results in overlap, where a huge number of times the function with the same arguments must be computed. With dispatching one can avoid the "branching". One can see recursion as a tree. Because `f(0)`

has a fixed value this is called the "base case" and are the leafs of the tree. The other function values are called "branches". When calculating `f(10)`

we need to calculate `f(1)`

and `f(2)`

, so one could draw edges from `f(10)`

to `f(2)`

and `f(1)`

. And so one could repeat the process.

Also in most cases a good programmer will program this dispatching in the algorithm. This is of course done by declaring an array an store values in the array and perform a lookup on it.

In recursion theory it's common the recursion consist of two parts: a base case part, where answers are "hard coded" for some function calls (in your example when `x=0`

), and a recursive part where `f(x)`

is written in parts of `f(y)`

. In general one can use dispatching by building an intial table with the hard coded values, and calculate the value of a specific `x`

by starting to fill in the entry of `x`

in the table, and work down.