Copyright | (C) 2017 Ryan Scott |
---|---|

License | BSD-style (see LICENSE) |

Maintainer | Ryan Scott |

Stability | experimental |

Portability | non-portable |

Safe Haskell | None |

Language | Haskell2010 |

# The

`ShowSing`

type

class (forall (z :: k). Show (Sing z)) => ShowSing k Source #

In addition to the promoted and singled versions of the `Show`

class that
`singletons`

provides, it is also useful to be able to directly define
`Show`

instances for singleton types themselves. Doing so is almost entirely
straightforward, as a derived `Show`

instance does 90 percent of the work.
The last 10 percent—getting the right instance context—is a bit tricky, and
that's where `ShowSing`

comes into play.

As an example, let's consider the singleton type for lists. We want to write an instance with the following shape:

deriving instance ??? => Show (Sing (x :: [k]))

To figure out what should go in place of `???`

, observe that we require the
type of each field to also be `Show`

instances. In other words, we need
something like `(Show (Sing (a :: k)))`

. But this isn't quite right, as the
type variable `a`

doesn't appear in the instance head. In fact, this `a`

type is really referring to an existentially quantified type variable in the
`SCons`

constructor, so it doesn't make sense to try and use it like this.

Luckily, the `QuantifiedConstraints`

language extension provides a solution
to this problem. This lets you write a context of the form
`(forall a. Show (Sing (a :: k)))`

, which demands that there be an instance
for `Show (Sing (a :: k))`

that is parametric in the use of `a`

. Thus, our
final instance looks like:

deriving instance (forall a. Show (Sing (a :: k))) => Show (Sing (x :: [k]))

Because that quantified constraint is somewhat lengthy, we provide the
`ShowSing`

class synonym as a convenient shorthand. Thus, the above instance
is equivalent to:

deriving instance ShowSing k => Show (Sing (x :: [k]))

When singling a derived `Show`

instance, `singletons`

will also derive
a `Show`

instance for the corresponding singleton type using `ShowSing`

.
In other words, if you give `singletons`

a derived `Show`

instance, then
you'll receive the following in return:

- A promoted (
`PShow`

) instance - A singled (
`SShow`

) instance - A
`Show`

instance for the singleton type

What a bargain!

# Orphan instances

Show (SSymbol s) Source # | |

Show (SNat n) Source # | |

Show (Sing z) Source # | |

(ShowSing a, ShowSing [a]) => Show (Sing z) Source # | |

ShowSing a => Show (Sing z) Source # | |

Show (Sing z) Source # | |

(ShowSing a, ShowSing b) => Show (Sing z) Source # | |

Show (Sing z) Source # | |

(ShowSing a, ShowSing b) => Show (Sing z) Source # | |

(ShowSing a, ShowSing b, ShowSing c) => Show (Sing z) Source # | |

(ShowSing a, ShowSing b, ShowSing c, ShowSing d) => Show (Sing z) Source # | |

(ShowSing a, ShowSing b, ShowSing c, ShowSing d, ShowSing e) => Show (Sing z) Source # | |

(ShowSing a, ShowSing b, ShowSing c, ShowSing d, ShowSing e, ShowSing f) => Show (Sing z) Source # | |

(ShowSing a, ShowSing b, ShowSing c, ShowSing d, ShowSing e, ShowSing f, ShowSing g) => Show (Sing z) Source # | |

Show (Sing z) Source # | |

ShowSing a => Show (Sing z) Source # | |

(ShowSing a, ShowSing [a]) => Show (Sing z) Source # | |