This is available here as a .lhs file.

The `MaybeT`

transformer will allow us to break out of a monad computation much like throwing an exception.

I'll first quickly go over some preliminaries. Skip down to **Adding Maybe powers to IO** for a worked example.

First some imports:

```
import Control.Monad
import Control.Monad.Trans
import Control.Monad.Trans.Maybe
```

Rules of thumb:

In a monad stack IO is always on the bottom.

Other IO-like monads will also, as a rule, always appear on the bottom, e.g. the state transformer monad `ST`

.

`MaybeT m`

is a new monad type which adds the power of the Maybe monad to the monad `m`

- e.g. `MaybeT IO`

.

We'll get into what that power is later. For now, get used to thinking of `MaybeT IO`

as the maybe+IO monad stack.

Just like `IO Int`

is a monad expression returning an `Int`

, `MaybeT IO Int`

is a `MaybeT IO`

expression returning an `Int`

.

Getting used to reading compound type signatures is half the battle to understanding monad transformers.

Every expression in a `do`

block must be from the same monad.

I.e. this works because each statement is in the IO-monad:

```
greet :: IO () -- type:
greet = do putStr "What is your name? " -- IO ()
n <- getLine -- IO String
putStrLn $ "Hello, " ++ n -- IO ()
```

This will not work because `putStr`

is not in the `MaybeT IO`

monad:

```
mgreet :: MaybeT IO ()
mgreet = do putStr "What is your name? " -- IO monad - need MaybeT IO here
...
```

Fortunately there is a way to fix this.

To transform an `IO`

expression into a `MaybeT IO`

expression use `liftIO`

.

`liftIO`

is polymorphic, but in our case it has the type:

```
liftIO :: IO a -> MaybeT IO a
mgreet :: MaybeT IO () -- types:
mgreet = do liftIO $ putStr "What is your name? " -- MaybeT IO ()
n <- liftIO getLine -- MaybeT IO String
liftIO $ putStrLn $ "Hello, " ++ n -- MaybeT IO ()
```

Now all of the statement in `mgreet`

are from the `MaybeT IO`

monad.

Every monad transformer has a "run" function.

The run function "runs" the top-most layer of a monad stack returning
a value from the inside layer.

For `MaybeT IO`

, the run function is:

```
runMaybeT :: MaybeT IO a -> IO (Maybe a)
```

Example:

```
ghci> :t runMaybeT mgreet
mgreet :: IO (Maybe ())
ghci> runMaybeT mgreet
What is your name? user5402
Hello, user5402
Just ()
```

Also try running:

```
runMaybeT (forever mgreet)
```

You'll need to use Ctrl-C to break out of the loop.

So far `mgreet`

doesn't do anything more than what we could do in IO.
Now we'll work on an example which demonstrates the power of mixing
the Maybe monad with IO.

# Adding Maybe powers to IO

We'll start with a program which asks some questions:

```
askfor :: String -> IO String
askfor prompt = do
putStr $ "What is your " ++ prompt ++ "? "
getLine
survey :: IO (String,String)
survey = do n <- askfor "name"
c <- askfor "favorite color"
return (n,c)
```

Now suppose we want to give the user the ability to end the survey
early by typing END in response to a question. We might handle it
this way:

```
askfor1 :: String -> IO (Maybe String)
askfor1 prompt = do
putStr $ "What is your " ++ prompt ++ " (type END to quit)? "
r <- getLine
if r == "END"
then return Nothing
else return (Just r)
survey1 :: IO (Maybe (String, String))
survey1 = do
ma <- askfor1 "name"
case ma of
Nothing -> return Nothing
Just n -> do mc <- askfor1 "favorite color"
case mc of
Nothing -> return Nothing
Just c -> return (Just (n,c))
```

The problem is that `survey1`

has the familiar staircasing issue which
doesn't scale if we add more questions.

We can use the MaybeT monad transformer to help us here.

```
askfor2 :: String -> MaybeT IO String
askfor2 prompt = do
liftIO $ putStr $ "What is your " ++ prompt ++ " (type END to quit)? "
r <- liftIO getLine
if r == "END"
then MaybeT (return Nothing) -- has type: MaybeT IO String
else MaybeT (return (Just r)) -- has type: MaybeT IO String
```

Note how all of the statemens in `askfor2`

have the same monad type.

We've used a new function:

```
MaybeT :: IO (Maybe a) -> MaybeT IO a
```

Here is how the types work out:

```
Nothing :: Maybe String
return Nothing :: IO (Maybe String)
MaybeT (return Nothing) :: MaybeT IO String
Just "foo" :: Maybe String
return (Just "foo") :: IO (Maybe String)
MaybeT (return (Just "foo")) :: MaybeT IO String
```

Here `return`

is from the IO-monad.

Now we can write our survey function like this:

```
survey2 :: IO (Maybe (String,String))
survey2 =
runMaybeT $ do a <- askfor2 "name"
b <- askfor2 "favorite color"
return (a,b)
```

Try running `survey2`

and ending the questions early by typing END as a response to either question.

# Short-cuts

I know I'll get comments from people if I don't mention the following short-cuts.

The expression:

```
MaybeT (return (Just r)) -- return is from the IO monad
```

may also be written simply as:

```
return r -- return is from the MaybeT IO monad
```

Also, another way of writing `MaybeT (return Nothing)`

is:

```
mzero
```

Furthermore, two consecutive `liftIO`

statements may always combined into a single `liftIO`

, e.g.:

```
do liftIO $ statement1
liftIO $ statement2
```

is the same as:

```
liftIO $ do statement1
statement2
```

With these changes our `askfor2`

function may be written:

```
askfor2 prompt = do
r <- liftIO $ do
putStr $ "What is your " ++ prompt ++ " (type END to quit)?"
getLine
if r == "END"
then mzero -- break out of the monad
else return r -- continue, returning r
```

In a sense, `mzero`

becomes a way of breaking out of the monad - like throwing an exception.

# Another example

Consider this simple password asking loop:

```
loop1 = do putStr "Password:"
p <- getLine
if p == "SECRET"
then return ()
else loop1
```

This is a (tail) recursive function and works just fine.

In a conventional language we might write this as a infinite while loop with a break statement:

```
def loop():
while True:
p = raw_prompt("Password: ")
if p == "SECRET":
break
```

With MaybeT we can write the loop in the same manner as the Python code:

```
loop2 :: IO (Maybe ())
loop2 = runMaybeT $
forever $
do liftIO $ putStr "Password: "
p <- liftIO $ getLine
if p == "SECRET"
then mzero -- break out of the loop
else return ()
```

The last `return ()`

continues execution, and since we are in a `forever`

loop, control passes back to the top of the do block. Note that the only value that `loop2`

can return is `Nothing`

which corresponds to breaking out of the loop.

Depending on the situation you might find it easier to write `loop2`

rather than the recursive `loop1`

.

`MaybeT IO`

, but not`IOT Maybe`

, because`IO`

, when present, must always be at the bottom of the monad stack.`ContT r (ExceptT e m) a`

for any`m`

, you can use it in a pure context by letting`m`

be`Identity`

. This sort of thing is done, for instance, in streaming libraries, to use effectful streaming code in a situation where no effects ate needed.