## Important Advice

It would really be worth working through Learn You a Haskell for Great Good. It's an excellent tutorial.

Practice! Play! Extend this assignment, by changing the brief. Can you do it for Strings instead of Integers? Can you do a tree with three subtrees? Can you do one where the branches have data too? Can you make a tree that takes any data type? Find out about `Functor`

s. Why are they any good? Can you make a tree that represents a calculation, with branches for operations like `+`

and leaves for numbers?

The more you play, the more confident you'll be. Be the guy in class that found out about something before it came up. Everyone will ask you for help, then you'll learn even more when you're asked to solve the tricky problems anyone in your group has.

## Question 1: Tree datatype

Here are some hints.

This binary tree has two subtrees or a Boolean leaf:

```
data BTree = Leaf Bool | Branch BTree BTree
deriving (Eq,Show)
```

This data structure has three items, including a list of `Bool`

s:

```
data Triple = Triple Int String [Bool]
deriving (Eq,Show)
```

This one has three different possibilities, and because `Expr`

appears on the right hand side, it's a bit like a tree.

```
data Expr = Var Char | Lam Char Expr | Let Char Expr Expr
deriving (Eq,Show)
```

Now you need one with three possibilities, where the leaf has a list of Integers, and the other two have one subtree, or two subtrees. Put the ideas in the examples together.

## Question 2: map a function over your tree

We call this apply-a-function-everywhere-you-can "map"ping the function. `map`

does it for lists, and `fmap`

does it for other things.

Let's define a function that takes a `Bool -> Bool`

and maps it over the first example:

```
mapBTree :: (Bool -> Bool) -> BTree -> BTree
mapBTree f (Leaf b) = Leaf (f b)
mapBTree f (Branch b1 b2) = Branch (mapBTree f b1) (mapBTree f b2)
```

and another one that maps over the triple. This time we have to make it work on each of the `Bool`

s in the list.

```
mapBoolTriple :: (Bool -> Bool) -> Triple -> Triple
mapBoolTriple f (Triple i xs bs) = Triple i xs (map f bs)
```

Notice I used the standard function `map`

which works like this:

```
map :: (a -> b) -> [a] -> [b]
map f [] = []
map f (x:xs) = f x : map f xs
```

so it applies `f`

to each `x`

in my list, starting at the front.

## How I'd really do this kind of thing

This isn't how I'd do this for real, though. I'd add

```
{-# LANGUAGE DeriveFunctor #-}
```

at the top of my file, which would let me write

```
data BinTree a = ALeaf a | ABranch (BinTree a) (BinTree a)
deriving (Eq, Show, Functor)
```

and then I could do

```
fmap (*100) (ABranch (ALeaf 12) (ALeaf 34))
```

which would give me

```
ABranch (ALeaf 1200) (ALeaf 3400)
```

but `fmap`

is more flexible: I could also do

```
fmap (<20) (ABranch (ALeaf 12) (ALeaf 34))
-- ABranch (ALeaf True) (ALeaf False)
```

or

```
fmap show (ABranch (ALeaf 12) (ALeaf 34))
-- ABranch (ALeaf "12") (ALeaf "34")
```

without me writing a single line of the function `fmap`

. I think that would give you 10/10 for using additional language features but 0/10 for solving the problem as set, so don't do that, but keep it in mind and use it when you can.

## More advice

Have fun learning Haskell. It can be mind-blowing at times, but it rewards you strongly for learning. You'll be able to write some programs in Haskell a tenth of the length of programs in more conventional languages. Think more! Write less!