singletons 2.6
==============
[](http://hackage.haskell.org/package/singletons)
[](https://travis-ci.org/goldfirere/singletons)
This is the README file for the singletons library. This file contains all the
documentation for the definitions and functions in the library.
The singletons library was written by Richard Eisenberg, <rae@cs.brynmawr.edu>, and
with significant contributions by Jan Stolarek, <jan.stolarek@p.lodz.pl>. There
are two papers that describe the library. Original one, _Dependently typed
programming with singletons_, is available
[here](https://cs.brynmawr.edu/~rae/papers/2012/singletons/paper.pdf) and will
be referenced in this documentation as the "singletons paper". A follow-up
paper, _Promoting Functions to Type Families in Haskell_, is available
[here](https://cs.brynmawr.edu/~rae/papers/2014/promotion/promotion.pdf)
and will be referenced in this documentation as the
"promotion paper".
Ryan Scott, <ryan.gl.scott@gmail.com>, is an active maintainer.
Purpose of the singletons library
---------------------------------
The library contains a definition of _singleton types_, which allow programmers
to use dependently typed techniques to enforce rich constraints among the types
in their programs. See the singletons paper for a more thorough introduction.
The package also allows _promotion_ of term-level functions to type-level
equivalents. Accordingly, it exports a Prelude of promoted and singletonized
functions, mirroring functions and datatypes found in Prelude, `Data.Bool`,
`Data.Maybe`, `Data.Either`, `Data.Tuple` and `Data.List`. See the promotion
paper for a more thorough introduction.
[This blog series](https://blog.jle.im/entry/introduction-to-singletons-1.html),
authored by Justin Le, offers a tutorial for this library that assumes no
knowledge of dependent types.
Compatibility
-------------
The singletons library requires GHC 8.8.1 or greater. Any code that uses the
singleton generation primitives needs to enable a long list of GHC
extensions. This list includes, but is not necessarily limited to, the
following:
* `DataKinds`
* `DefaultSignatures`
* `EmptyCase`
* `ExistentialQuantification`
* `FlexibleContexts`
* `FlexibleInstances`
* `GADTs`
* `InstanceSigs`
* `KindSignatures`
* `NoStarIsType`
* `PolyKinds`
* `RankNTypes`
* `ScopedTypeVariables`
* `TemplateHaskell`
* `TypeApplications`
* `TypeFamilies`
* `TypeOperators`
* `UndecidableInstances`
In particular, `NoStarIsType` is needed to use the `*` type family from the
`PNum` class because with `StarIsType` enabled, GHC thinks `*` is a synonym
for `Type`.
You may also want
* `-Wno-redundant-constraints`
as the code that `singletons` generates uses redundant constraints, and there
seems to be no way, without a large library redesign, to avoid this.
Modules for singleton types
---------------------------
`Data.Singletons` exports all the basic singletons definitions. Import this
module if you are not using Template Haskell and wish only to define your
own singletons.
`Data.Singletons.TH` exports all the definitions needed to use the Template
Haskell code to generate new singletons.
`Data.Singletons.Prelude` re-exports `Data.Singletons` along with singleton
definitions for various Prelude types. This module provides a singletonized
equivalent of the real `Prelude`. Note that not all functions from original
`Prelude` could be turned into singletons.
`Data.Singletons.Prelude.*` modules provide singletonized equivalents of
definitions found in the following `base` library modules: `Data.Bool`,
`Data.Maybe`, `Data.Either`, `Data.List`, `Data.Tuple`, `Data.Void` and
`GHC.Base`. We also provide singletonized `Eq`, `Ord`, `Show`, `Enum`, and
`Bounded` typeclasses.
`Data.Singletons.Decide` exports type classes for propositional equality.
`Data.Singletons.TypeLits` exports definitions for working with `GHC.TypeLits`.
Modules for function promotion
------------------------------
Modules in `Data.Promotion` namespace provide functionality required for
function promotion. They mostly re-export a subset of definitions from
respective `Data.Singletons` modules.
`Data.Promotion.TH` exports all the definitions needed to use the Template
Haskell code to generate promoted definitions.
`Data.Promotion.Prelude` and `Data.Promotion.Prelude.*` modules re-export all
promoted definitions from respective `Data.Singletons.Prelude`
modules. `Data.Promotion.Prelude.List` adds a significant amount of functions
that couldn't be singletonized but can be promoted. Some functions still don't
promote - these are documented in the source code of the module. There is also
`Data.Promotion.Prelude.Bounded` module that provides promoted `PBounded`
typeclass.
Functions to generate singletons
--------------------------------
The top-level functions used to generate singletons are documented in the
`Data.Singletons.TH` module. The most common case is just calling `singletons`,
which I'll describe here:
```haskell
singletons :: Q [Dec] -> Q [Dec]
```
Generates singletons from the definitions given. Because singleton generation
requires promotion, this also promotes all of the definitions given to the
type level.
Usage example:
```haskell
$(singletons [d|
data Nat = Zero | Succ Nat
pred :: Nat -> Nat
pred Zero = Zero
pred (Succ n) = n
|])
```
Definitions used to support singletons
--------------------------------------
Please refer to the singletons paper for a more in-depth explanation of these
definitions. Many of the definitions were developed in tandem with Iavor Diatchki.
```haskell
type family Sing :: k -> Type
```
The type family of singleton types. A new instance of this type family is
generated for every new singleton type.
```haskell
class SingI (a :: k) where
sing :: Sing a
```
A class used to pass singleton values implicitly. The `sing` method produces
an explicit singleton value.
```haskell
data SomeSing k where
SomeSing :: Sing (a :: k) -> SomeSing k
```
The `SomeSing` type wraps up an _existentially-quantified_ singleton. Note that
the type parameter `a` does not appear in the `SomeSing` type. Thus, this type
can be used when you have a singleton, but you don't know at compile time what
it will be. `SomeSing Thing` is isomorphic to `Thing`.
```haskell
class SingKind k where
type Demote k :: *
fromSing :: Sing (a :: k) -> Demote k
toSing :: Demote k -> SomeSing k
```
This class is used to convert a singleton value back to a value in the
original, unrefined ADT. The `fromSing` method converts, say, a
singleton `Nat` back to an ordinary `Nat`. The `toSing` method produces
an existentially-quantified singleton, wrapped up in a `SomeSing`.
The `Demote` associated
kind-indexed type family maps the kind `Nat` back to the type `Nat`.
```haskell
data SingInstance (a :: k) where
SingInstance :: SingI a => SingInstance a
singInstance :: Sing a -> SingInstance a
```
Sometimes you have an explicit singleton (a `Sing`) where you need an implicit
one (a dictionary for `SingI`). The `SingInstance` type simply wraps a `SingI`
dictionary, and the `singInstance` function produces this dictionary from an
explicit singleton. The `singInstance` function runs in constant time, using
a little magic.
Equality classes
----------------
There are two different notions of equality applicable to singletons: Boolean
equality and propositional equality.
* Boolean equality is implemented in the type family `(:==)` (which is actually
a synonym for the type family `(==)` from `Data.Type.Equality`) and the class
`SEq`. See the `Data.Singletons.Prelude.Eq` module for more information.
* Propositional equality is implemented through the constraint `(~)`, the type
`(:~:)`, and the class `SDecide`. See modules `Data.Type.Equality` and
`Data.Singletons.Decide` for more information.
Which one do you need? That depends on your application. Boolean equality has
the advantage that your program can take action when two types do _not_ equal,
while propositional equality has the advantage that GHC can use the equality
of types during type inference.
Instances of `SEq`, `SDecide`, `TestEquality`, and `TestCoercion` are generated
when `singletons` is called on a datatype that has `deriving Eq`. You can also
generate these instances directly through functions exported from
`Data.Singletons.TH`.
`Show` classes
--------------
Promoted and singled versions of the `Show` class (`PShow` and `SShow`,
respectively) are provided in the `Data.Singletons.Prelude.Show` module. In
addition, there is a `ShowSing` constraint synonym provided in the
`Data.Singletons.ShowSing` module:
```haskell
type ShowSing k = (forall z. Show (Sing (z :: k))
```
This facilitates the ability to write `Show` instances for `Sing` instances.
What distinguishes all of these `Show`s? Let's use the `False` constructor as
an example. If you used the `PShow Bool` instance, then the output of calling
`Show_` on `False` is `"False"`, much like the value-level `Show Bool` instance
(similarly for the `SShow Bool` instance). However, the `Show (Sing (z :: Bool))`
instance (i.e., `ShowSing Bool`) is intended for printing the value of the
_singleton_ constructor `SFalse`, so calling `show SFalse` yields `"SFalse"`.
Instance of `PShow`, `SShow`, and `Show` (for the singleton type) are generated
when `singletons` is called on a datatype that has `deriving Show`. You can also
generate these instances directly through functions exported from
`Data.Singletons.TH`.
A promoted and singled `Show` instance is provided for `Symbol`, but it is only
a crude approximation of the value-level `Show` instance for `String`. On the
value level, showing `String`s escapes special characters (such as double
quotes), but implementing this requires pattern-matching on character literals,
something which is currently impossible at the type level. As a consequence, the
type-level `Show` instance for `Symbol`s does not do any character escaping.
Errors
------
The `singletons` library provides two different ways to handle errors:
* The `Error` type family, from `Data.Singletons.TypeLits`:
```haskell
type family Error (str :: a) :: k where {}
```
This is simply an empty, closed type family, which means that it will fail
to reduce regardless of its input. The typical use case is giving it a
`Symbol` as an argument, so that something akin to
`Error "This is an error message"` appears in error messages.
* The `TypeError` type family, from `Data.Singletons.TypeError`. This is a
drop-in replacement for `TypeError` from `GHC.TypeLits` which can be used
at both the type level and the value level (via the `typeError` function).
Unlike `Error`, `TypeError` will result in an actual compile-time error
message, which may be more desirable depending on the use case.
Pre-defined singletons
----------------------
The singletons library defines a number of singleton types and functions
by default:
* `Bool`
* `Maybe`
* `Either`
* `Ordering`
* `()`
* tuples up to length 7
* lists
These are all available through `Data.Singletons.Prelude`. Functions that
operate on these singletons are available from modules such as `Data.Singletons.Bool`
and `Data.Singletons.Maybe`.
Promoting functions
-------------------
Function promotion allows to generate type-level equivalents of term-level
definitions. Almost all Haskell source constructs are supported -- see last
section of this README for a full list.
Promoted definitions are usually generated by calling `promote` function:
```haskell
$(promote [d|
data Nat = Zero | Succ Nat
pred :: Nat -> Nat
pred Zero = Zero
pred (Succ n) = n
|])
```
Every promoted function and data constructor definition comes with a set of
so-called "symbols". These are required to represent partial application at the
type level. Each function gets N+1 symbols, where N is the arity. Symbols
represent application of between 0 to N arguments. When calling any of the
promoted definitions it is important refer to it using their symbol
name. Moreover, there is new function application at the type level represented
by `Apply` type family. Symbol representing arity X can have X arguments passed
in using normal function application. All other parameters must be passed by
calling `Apply`.
Users also have access to `Data.Promotion.Prelude` and its submodules (`Base`,
`Bool`, `Either`, `List`, `Maybe` and `Tuple`). These provide promoted versions
of function found in GHC's base library.
Note that GHC resolves variable names in Template Haskell quotes. You cannot
then use an undefined identifier in a quote, making idioms like this not
work:
```haskell
type family Foo a where ...
$(promote [d| ... foo x ... |])
```
In this example, `foo` would be out of scope.
Refer to the promotion paper for more details on function promotion.
Classes and instances
---------------------
This is best understood by example. Let's look at a stripped down `Ord`:
```haskell
class Eq a => Ord a where
compare :: a -> a -> Ordering
(<) :: a -> a -> Bool
x < y = case x `compare` y of
LT -> True
EQ -> False
GT -> False
```
This class gets promoted to a "kind class" thus:
```haskell
class PEq a => POrd a where
type Compare (x :: a) (y :: a) :: Ordering
type (:<) (x :: a) (y :: a) :: Bool
type x :< y = ... -- promoting `case` is yucky.
```
Note that default method definitions become default associated type family
instances. This works out quite nicely.
We also get this singleton class:
```haskell
class SEq a => SOrd a where
sCompare :: forall (x :: a) (y :: a). Sing x -> Sing y -> Sing (Compare x y)
(%:<) :: forall (x :: a) (y :: a). Sing x -> Sing y -> Sing (x :< y)
default (%:<) :: forall (x :: a) (y :: a).
((x :< y) ~ {- RHS from (:<) above -})
=> Sing x -> Sing y -> Sing (x :< y)
x %:< y = ... -- this is a bit yucky too
```
Note that a singletonized class needs to use `default` signatures, because
type-checking the default body requires that the default associated type
family instance was used in the promoted class. The extra equality constraint
on the default signature asserts this fact to the type checker.
Instances work roughly similarly.
```haskell
instance Ord Bool where
compare False False = EQ
compare False True = LT
compare True False = GT
compare True True = EQ
instance POrd Bool where
type Compare 'False 'False = 'EQ
type Compare 'False 'True = 'LT
type Compare 'True 'False = 'GT
type Compare 'True 'True = 'EQ
instance SOrd Bool where
sCompare :: forall (x :: a) (y :: a). Sing x -> Sing y -> Sing (Compare x y)
sCompare SFalse SFalse = SEQ
sCompare SFalse STrue = SLT
sCompare STrue SFalse = SGT
sCompare STrue STrue = SEQ
```
The only interesting bit here is the instance signature. It's not necessary
in such a simple scenario, but more complicated functions need to refer to
scoped type variables, which the instance signature can bring into scope.
The defaults all just work.
On names
--------
The singletons library has to produce new names for the new constructs it
generates. Here are some examples showing how this is done:
1. original datatype: `Nat`
promoted kind: `Nat`
singleton type: `SNat` (which is really a synonym for `Sing`)
2. original datatype: `/\`
promoted kind: `/\`
singleton type: `%/\`
3. original constructor: `Succ`
promoted type: `'Succ` (you can use `Succ` when unambiguous)
singleton constructor: `SSucc`
symbols: `SuccSym0`, `SuccSym1`
4. original constructor: `:+:`
promoted type: `':+:`
singleton constructor: `:%+:`
symbols: `:+:@#@$`, `:+:@#@$$`, `:+:@#@$$$`
5. original value: `pred`
promoted type: `Pred`
singleton value: `sPred`
symbols: `PredSym0`, `PredSym1`
6. original value: `+`
promoted type: `+`
singleton value: `%+`
symbols: `+@#@$`, `+@#@$$`, `+@#@$$$`
7. original class: `Num`
promoted class: `PNum`
singleton class: `SNum`
8. original class: `~>`
promoted class: `#~>`
singleton class: `%~>`
Special names
-------------
There are some special cases, listed below (with asterisks\* denoting special
treatment):
1. original datatype: `[]`
promoted kind: `[]`
singleton type\*: `SList`
2. original constructor: `[]`
promoted type: `'[]`
singleton constructor\*: `SNil`
symbols\*: `NilSym0`
3. original constructor: `:`
promoted type: `':`
singleton constructor\*: `SCons`
symbols: `:@#@$`, `:@#@$$`, `:@#@$$$`
4. original datatype: `(,)`
promoted kind: `(,)`
singleton type\*: `STuple2`
5. original constructor: `(,)`
promoted type: `'(,)`
singleton constructor\*: `STuple2`
symbols\*: `Tuple2Sym0`, `Tuple2Sym1`, `Tuple2Sym2`
All tuples (including the 0-tuple, unit) are treated similarly.
6. original value: `___foo`
promoted type\*: `US___foo` ("`US`" stands for "underscore")
singleton value\*: `___sfoo`
symbols\*: `US___fooSym0`
All functions that begin with leading underscores are treated similarly.
Supported Haskell constructs
----------------------------
The following constructs are fully supported:
* variables
* tuples
* constructors
* if statements
* infix expressions and types
* `_` patterns
* aliased patterns
* lists (including list comprehensions)
* `do`-notation
* sections
* undefined
* error
* deriving `Eq`, `Ord`, `Show`, `Bounded`, `Enum`, `Functor`, `Foldable`, and
`Traversable`, as well as the `stock` and `anyclass` deriving strategies
* class constraints (though these sometimes fail with `let`, `lambda`, and `case`)
* literals (for `Nat` and `Symbol`), including overloaded number literals
* unboxed tuples (which are treated as normal tuples)
* records
* pattern guards
* case
* let
* lambda expressions
* `!` and `~` patterns (silently but successfully ignored during promotion)
* class and instance declarations
* scoped type variables
* signatures (e.g., `(x :: Maybe a)`) in expressions and patterns
* `InstanceSigs`
* higher-kinded type variables (see below)
* finite arithmetic sequences (see below)
* functional dependencies (with limitations -- see below)
* type families (with limitations -- see below)
Higher-kinded type variables in `class`/`data` declarations must be annotated
explicitly. This is due to GHC's handling of *complete
user-specified kind signatures*, or [CUSKs](https://downloads.haskell.org/~ghc/latest/docs/html/users_guide/glasgow_exts.html#complete-user-supplied-kind-signatures-and-polymorphic-recursion).
Briefly, `singletons` has a hard
time conforming to the precise rules that GHC imposes around CUSKs and so
needs a little help around kind inference here. See
[this pull request](https://github.com/goldfirere/singletons/pull/171) for more
background.
`singletons` is slightly more conservative with respect to `deriving` than GHC is.
The stock classes listed above (`Eq`, `Ord`, `Show`, `Bounded`, `Enum`, `Functor`,
`Foldable`, and `Traversable`) are the only ones that `singletons` will derive
without an explicit deriving strategy. To do anything more exotic, one must
explicitly indicate one's intentions by using the `DerivingStrategies` extension.
`singletons` fully supports the `anyclass` strategy as well as the `stock` strategy
(at least, for the classes listed above). `singletons` does not support the
`newtype` strategy, as there is not an equivalent of `coerce` at the type level.
`singletons` has partial support for arithmetic sequences (which desugar to
methods from the `Enum` class under the hood). _Finite_ sequences (e.g.,
[0..42]) are fully supported. However, _infinite_ sequences (e.g., [0..]),
which desugar to calls to `enumFromTo` or `enumFromThenTo`, are not supported,
as these would require using infinite lists at the type level.
The following constructs are supported for promotion but not singleton generation:
* datatypes with constructors which have contexts. For example, the following
datatype does not singletonize:
```haskell
data T a where
MkT :: Show a => a -> T a
```
Constructors like these do not interact well with the current design of the
`SingKind` class. But see
[this bug report](https://github.com/goldfirere/singletons/issues/150), which
proposes a redesign for `SingKind` (in a future version of GHC with certain
bugfixes) which could permit constructors with equality constraints.
* overlapping patterns. Note that overlapping patterns are
sometimes not obvious. For example, the `filter` function does not
singletonize due
to overlapping patterns:
```haskell
filter :: (a -> Bool) -> [a] -> [a]
filter _pred [] = []
filter pred (x:xs)
| pred x = x : filter pred xs
| otherwise = filter pred xs
```
Overlap is caused by `otherwise` catch-all guard, which is always true and thus
overlaps with `pred x` guard.
Another non-obvious source of overlapping patterns comes from partial pattern
matches in `do`-notation. For example:
```haskell
f :: [()]
f = do
Just () <- [Nothing]
return ()
```
This has overlap because the partial pattern match desugars to the following:
```haskell
f :: [()]
f = case [Nothing] of
Just () -> return ()
_ -> fail "Partial pattern match in do notation"
```
Here, it is more evident that the catch-all pattern `_` overlaps with the
one above it.
The following constructs are not supported:
* datatypes that store arrows, `Nat`, or `Symbol`
* literals (limited support)
Why are these out of reach?
As described in the promotion paper, promotion of datatypes that store arrows is
currently impossible. So if you have a declaration such as
```haskell
data Foo = Bar (Bool -> Maybe Bool)
```
you will quickly run into errors.
Literals are problematic because we rely on GHC's built-in support, which
currently is limited. Functions that operate on strings will not work because
type level strings are no longer considered lists of characters. Function
working on integer literals can be promoted by rewriting them to use
`Nat`. Since `Nat` does not exist at the term level it will only be possible to
use the promoted definition, but not the original, term-level one.
This is the same line of reasoning that forbids the use of `Nat` or `Symbol`
in datatype definitions. But, see [this bug
report](https://github.com/goldfirere/singletons/issues/76) for a workaround.
Support for `*`
---------------
The built-in Haskell promotion mechanism does not yet have a full story around
the kind `*` (the kind of types that have values). Ideally, promoting some form
of `TypeRep` would yield `*`, but the implementation of `TypeRep` would have to
be updated for this to really work out. In the meantime, users who wish to
experiment with this feature have two options:
1) The module `Data.Singletons.TypeRepTYPE` has all the definitions possible for
making `*` the promoted version of `TypeRep`, as `TypeRep` is currently implemented.
The singleton associated with `TypeRep` has one constructor:
```haskell
type instance Sing @(TYPE rep) = TypeRep
```
(Recall that `type * = TYPE LiftedRep`.) Note that any datatypes that store
`TypeRep`s will not generally work as expected; the built-in promotion
mechanism will not promote `TypeRep` to `*`.
2) The module `Data.Singletons.CustomStar` allows the programmer to define a subset
of types with which to work. See the Haddock documentation for the function
`singletonStar` for more info.
Known bugs
----------
* Record updates don't singletonize
* Inference dependent on functional dependencies is unpredictably bad. The
problem is that a use of an associated type family tied to a class with
fundeps doesn't provoke the fundep to kick in. This is GHC's problem, in
the end.
* Singled code that contains uses type families is likely to fail due to GHC
Trac #12564. Note that singling type family declarations themselves is fine
(and often desired, since that produces defunctionalization symbols for them).
* Singling instances of poly-kinded type classes is likely to fail due to
[#358](https://github.com/goldfirere/singletons/issues/358).
However, one can often work around the issue by using `InstanceSigs`. For
instance, the following code will not single:
```haskell
class C (f :: k -> Type) where
method :: f a
instance C [] where
method = []
```
Adding a type signature for `method` in the `C []` is sufficient
to work around the issue, though:
```haskell
instance C [] where
method :: [a]
method = []
```