This is not a flaw with the `Cont`

monad so much as `sequence`

. You can get similar results for `Either`

, for example:

```
import Control.Monad.Instances ()
xs :: [Either a Int]
xs = map Right [0..] -- Note: return = Right, for Either
ys :: Either a [Int]
ys = sequence xs
```

You can't retrieve any elements of `ys`

until it computes the entire list, which will never happen.

Also, note that: `sequence (map f xs) = mapM f xs`

, so we can simplify this example to:

```
>>> import Control.Monad.Instances
>>> mapM Right [0..]
<Hangs forever>
```

There are a few monads where `mapM`

will work on an infinite list of values, specifically the lazy `StateT`

monad and `Identity`

, but they are the exception to the rule.

Generally, `mapM`

/`sequence`

/`replicateM`

(without trailing underscores) are anti-patterns and the correct solution is to use `pipes`

, which allows you to build effectful streams that don't try to compute all the results up front. The beginning of the `pipes`

tutorial describes how to solve this in more detail, but the general rule of thumb is that any time you write something like:

```
example1 = mapM f xs
example2 = sequence xs
```

You can transform it into a lazy `Producer`

by just transforming it to:

```
example1' = each xs >-> Pipes.Prelude.mapM f
example2' = each xs >-> Pipes.Prelude.sequence
```

Using the above example with `Either`

, you would write:

```
>>> import Pipes
>>> let xs = each [0..] >-> mapM Right :: Producer Int (Either a) ()
```

Then you can lazily process the stream without generating all elements:

```
>>> Pipes.Prelude.any (> 10) xs
Right True
```