.. _sect-interfaces: ********** Interfaces ********** We often want to define functions which work across several different data types. For example, we would like arithmetic operators to work on ``Int``, ``Integer`` and ``Double`` at the very least. We would like ``==`` to work on the majority of data types. We would like to be able to display different types in a uniform way. To achieve this, we use *interfaces*, which are similar to type classes in Haskell or traits in Rust. To define an interface, we provide a collection of overloadable functions. A simple example is the ``Show`` interface, which is defined in the prelude and provides an interface for converting values to ``String``: .. code-block:: idris interface Show a where show : a -> String This generates a function of the following type (which we call a *method* of the ``Show`` interface): .. code-block:: idris show : Show a => a -> String We can read this as: “under the constraint that ``a`` has an implementation of ``Show``, take an input ``a`` and return a ``String``.” An implementation of an interface is defined by giving definitions of the methods of the interface. For example, the ``Show`` implementation for ``Nat`` could be defined as: .. code-block:: idris Show Nat where show Z = "Z" show (S k) = "s" ++ show k :: Main> show (S (S (S Z))) "sssZ" : String Only one implementation of an interface can be given for a type — implementations may not overlap. Implementation declarations can themselves have constraints. To help with resolution, the arguments of an implementation must be constructors (either data or type constructors) or variables (i.e. you cannot give an implementation for a function). For example, to define a ``Show`` implementation for vectors, we need to know that there is a ``Show`` implementation for the element type, because we are going to use it to convert each element to a ``String``: .. code-block:: idris Show a => Show (Vect n a) where show xs = "[" ++ show' xs ++ "]" where show' : forall n . Vect n a -> String show' Nil = "" show' (x :: Nil) = show x show' (x :: xs) = show x ++ ", " ++ show' xs Note that we need the explicit ``forall n .`` in the ``show'`` function because otherwise the ``n`` is already in scope, and fixed to the value of the top level ``n``. Default Definitions =================== The Prelude defines an ``Eq`` interface which provides methods for comparing values for equality or inequality, with implementations for all of the built-in types: .. code-block:: idris interface Eq a where (==) : a -> a -> Bool (/=) : a -> a -> Bool To declare an implementation for a type, we have to give definitions of all of the methods. For example, for an implementation of ``Eq`` for ``Nat``: .. code-block:: idris Eq Nat where Z == Z = True (S x) == (S y) = x == y Z == (S y) = False (S x) == Z = False x /= y = not (x == y) It is hard to imagine many cases where the ``/=`` method will be anything other than the negation of the result of applying the ``==`` method. It is therefore convenient to give a default definition for each method in the interface declaration, in terms of the other method: .. code-block:: idris interface Eq a where (==) : a -> a -> Bool (/=) : a -> a -> Bool x /= y = not (x == y) x == y = not (x /= y) A minimal complete implementation of ``Eq`` requires either ``==`` or ``/=`` to be defined, but does not require both. If a method definition is missing, and there is a default definition for it, then the default is used instead. Extending Interfaces ==================== Interfaces can also be extended. A logical next step from an equality relation ``Eq`` is to define an ordering relation ``Ord``. We can define an ``Ord`` interface which inherits methods from ``Eq`` as well as defining some of its own: .. code-block:: idris data Ordering = LT | EQ | GT .. code-block:: idris interface Eq a => Ord a where compare : a -> a -> Ordering (<) : a -> a -> Bool (>) : a -> a -> Bool (<=) : a -> a -> Bool (>=) : a -> a -> Bool max : a -> a -> a min : a -> a -> a The ``Ord`` interface allows us to compare two values and determine their ordering. Only the ``compare`` method is required; every other method has a default definition. Using this we can write functions such as ``sort``, a function which sorts a list into increasing order, provided that the element type of the list is in the ``Ord`` interface. We give the constraints on the type variables left of the fat arrow ``=>``, and the function type to the right of the fat arrow: .. code-block:: idris sort : Ord a => List a -> List a Functions, interfaces and implementations can have multiple constraints. Multiple constraints are written in brackets in a comma separated list, for example: .. code-block:: idris sortAndShow : (Ord a, Show a) => List a -> String sortAndShow xs = show (sort xs) Constraints are, like types, first class objects in the language. You can see this at the REPL: :: Main> :t Ord Prelude.Ord : Type -> Type So, ``(Ord a, Show a)`` is an ordinary pair of ``Types``, with two constraints as the first and second element of the pair. Note: Interfaces and ``mutual`` blocks ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Idris is strictly "define before use", except in ``mutual`` blocks. In a ``mutual`` block, Idris elaborates in two passes: types on the first pass and definitions on the second. When the mutual block contains an interface declaration, it elaborates the interface header but none of the method types on the first pass, and elaborates the method types and any default definitions on the second pass. Functors and Applicatives ========================= So far, we have seen single parameter interfaces, where the parameter is of type ``Type``. In general, there can be any number of parameters (even zero), and the parameters can have *any* type. If the type of the parameter is not ``Type``, we need to give an explicit type declaration. For example, the ``Functor`` interface is defined in the prelude: .. code-block:: idris interface Functor (f : Type -> Type) where map : (m : a -> b) -> f a -> f b A functor allows a function to be applied across a structure, for example to apply a function to every element in a ``List``: .. code-block:: idris Functor List where map f [] = [] map f (x::xs) = f x :: map f xs :: Idris> map (*2) [1..10] [2, 4, 6, 8, 10, 12, 14, 16, 18, 20] : List Integer Having defined ``Functor``, we can define ``Applicative`` which abstracts the notion of function application: .. code-block:: idris infixl 2 <*> interface Functor f => Applicative (f : Type -> Type) where pure : a -> f a (<*>) : f (a -> b) -> f a -> f b .. _monadsdo: Monads and ``do``-notation ========================== The ``Monad`` interface allows us to encapsulate binding and computation, and is the basis of ``do``-notation introduced in Section :ref:`sect-do`. It extends ``Applicative`` as defined above, and is defined as follows: .. code-block:: idris interface Applicative m => Monad (m : Type -> Type) where (>>=) : m a -> (a -> m b) -> m b Inside a ``do`` block, the following syntactic transformations are applied: - ``x <- v; e`` becomes ``v >>= (\x => e)`` - ``v; e`` becomes ``v >>= (\_ => e)`` - ``let x = v; e`` becomes ``let x = v in e`` ``IO`` has an implementation of ``Monad``, defined using primitive functions. We can also define an implementation for ``Maybe``, as follows: .. code-block:: idris Monad Maybe where Nothing >>= k = Nothing (Just x) >>= k = k x Using this we can, for example, define a function which adds two ``Maybe Int``, using the monad to encapsulate the error handling: .. code-block:: idris m_add : Maybe Int -> Maybe Int -> Maybe Int m_add x y = do x' <- x -- Extract value from x y' <- y -- Extract value from y pure (x' + y') -- Add them This function will extract the values from ``x`` and ``y``, if they are both available, or return ``Nothing`` if one or both are not ("fail fast"). Managing the ``Nothing`` cases is achieved by the ``>>=`` operator, hidden by the ``do`` notation. :: Main> m_add (Just 82) (Just 22) Just 94 Main> m_add (Just 82) Nothing Nothing Pattern Matching Bind ~~~~~~~~~~~~~~~~~~~~~ Sometimes we want to pattern match immediately on the result of a function in ``do`` notation. For example, let's say we have a function ``readNumber`` which reads a number from the console, returning a value of the form ``Just x`` if the number is valid, or ``Nothing`` otherwise: .. code-block:: idris import Data.Strings readNumber : IO (Maybe Nat) readNumber = do input <- getLine if all isDigit (unpack input) then pure (Just (stringToNatOrZ input)) else pure Nothing If we then use it to write a function to read two numbers, returning ``Nothing`` if neither are valid, then we would like to pattern match on the result of ``readNumber``: .. code-block:: idris readNumbers : IO (Maybe (Nat, Nat)) readNumbers = do x <- readNumber case x of Nothing => pure Nothing Just x_ok => do y <- readNumber case y of Nothing => pure Nothing Just y_ok => pure (Just (x_ok, y_ok)) If there's a lot of error handling, this could get deeply nested very quickly! So instead, we can combine the bind and the pattern match in one line. For example, we could try pattern matching on values of the form ``Just x_ok``: .. code-block:: idris readNumbers : IO (Maybe (Nat, Nat)) readNumbers = do Just x_ok <- readNumber Just y_ok <- readNumber pure (Just (x_ok, y_ok)) There is still a problem, however, because we've now omitted the case for ``Nothing`` so ``readNumbers`` is no longer total! We can add the ``Nothing`` case back as follows: .. code-block:: idris readNumbers : IO (Maybe (Nat, Nat)) readNumbers = do Just x_ok <- readNumber | Nothing => pure Nothing Just y_ok <- readNumber | Nothing => pure Nothing pure (Just (x_ok, y_ok)) The effect of this version of ``readNumbers`` is identical to the first (in fact, it is syntactic sugar for it and directly translated back into that form). The first part of each statement (``Just x_ok <-`` and ``Just y_ok <-``) gives the preferred binding - if this matches, execution will continue with the rest of the ``do`` block. The second part gives the alternative bindings, of which there may be more than one. ``!``-notation ~~~~~~~~~~~~~~ In many cases, using ``do``-notation can make programs unnecessarily verbose, particularly in cases such as ``m_add`` above where the value bound is used once, immediately. In these cases, we can use a shorthand version, as follows: .. code-block:: idris m_add : Maybe Int -> Maybe Int -> Maybe Int m_add x y = pure (!x + !y) The notation ``!expr`` means that the expression ``expr`` should be evaluated and then implicitly bound. Conceptually, we can think of ``!`` as being a prefix function with the following type: .. code-block:: idris (!) : m a -> a Note, however, that it is not really a function, merely syntax! In practice, a subexpression ``!expr`` will lift ``expr`` as high as possible within its current scope, bind it to a fresh name ``x``, and replace ``!expr`` with ``x``. Expressions are lifted depth first, left to right. In practice, ``!``-notation allows us to program in a more direct style, while still giving a notational clue as to which expressions are monadic. For example, the expression: .. code-block:: idris let y = 94 in f !(g !(print y) !x) is lifted to: .. code-block:: idris let y = 94 in do y' <- print y x' <- x g' <- g y' x' f g' Monad comprehensions ~~~~~~~~~~~~~~~~~~~~ The list comprehension notation we saw in Section :ref:`sect-more-expr` is more general, and applies to anything which has an implementation of both ``Monad`` and ``Alternative``: .. code-block:: idris interface Applicative f => Alternative (f : Type -> Type) where empty : f a (<|>) : f a -> f a -> f a In general, a comprehension takes the form ``[ exp | qual1, qual2, …, qualn ]`` where ``quali`` can be one of: - A generator ``x <- e`` - A *guard*, which is an expression of type ``Bool`` - A let binding ``let x = e`` To translate a comprehension ``[exp | qual1, qual2, …, qualn]``, first any qualifier ``qual`` which is a *guard* is translated to ``guard qual``, using the following function: .. code-block:: idris guard : Alternative f => Bool -> f () Then the comprehension is converted to ``do`` notation: .. code-block:: idris do { qual1; qual2; ...; qualn; pure exp; } Using monad comprehensions, an alternative definition for ``m_add`` would be: .. code-block:: idris m_add : Maybe Int -> Maybe Int -> Maybe Int m_add x y = [ x' + y' | x' <- x, y' <- y ] Interfaces and IO ================= In general, ``IO`` operations in the libraries aren't written using ``IO`` directly, but rather via the ``HasIO`` interface: .. code-block:: idris interface Monad io => HasIO io where liftIO : (1 _ : IO a) -> io a ``HasIO`` explains, via ``liftIO``, how to convert a primitive ``IO`` operation to an operation in some underlying type, as long as that type has a ``Monad`` implementation. These interface allows a programmer to define some more expressive notion of interactive program, while still giving direct access to ``IO`` primitives. Idiom brackets ============== While ``do`` notation gives an alternative meaning to sequencing, idioms give an alternative meaning to *application*. The notation and larger example in this section is inspired by Conor McBride and Ross Paterson’s paper “Applicative Programming with Effects” [#ConorRoss]_. First, let us revisit ``m_add`` above. All it is really doing is applying an operator to two values extracted from ``Maybe Int``. We could abstract out the application: .. code-block:: idris m_app : Maybe (a -> b) -> Maybe a -> Maybe b m_app (Just f) (Just a) = Just (f a) m_app _ _ = Nothing Using this, we can write an alternative ``m_add`` which uses this alternative notion of function application, with explicit calls to ``m_app``: .. code-block:: idris m_add' : Maybe Int -> Maybe Int -> Maybe Int m_add' x y = m_app (m_app (Just (+)) x) y Rather than having to insert ``m_app`` everywhere there is an application, we can use idiom brackets to do the job for us. To do this, we can give ``Maybe`` an implementation of ``Applicative`` as follows, where ``<*>`` is defined in the same way as ``m_app`` above (this is defined in the Idris library): .. code-block:: idris Applicative Maybe where pure = Just (Just f) <*> (Just a) = Just (f a) _ <*> _ = Nothing Using ``<*>`` we can use this implementation as follows, where a function application ``[| f a1 …an |]`` is translated into ``pure f <*> a1 <*> … <*> an``: .. code-block:: idris m_add' : Maybe Int -> Maybe Int -> Maybe Int m_add' x y = [| x + y |] An error-handling interpreter ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Idiom notation is commonly useful when defining evaluators. McBride and Paterson describe such an evaluator [#ConorRoss]_, for a language similar to the following: .. code-block:: idris data Expr = Var String -- variables | Val Int -- values | Add Expr Expr -- addition Evaluation will take place relative to a context mapping variables (represented as ``String``\s) to ``Int`` values, and can possibly fail. We define a data type ``Eval`` to wrap an evaluator: .. code-block:: idris data Eval : Type -> Type where MkEval : (List (String, Int) -> Maybe a) -> Eval a Wrapping the evaluator in a data type means we will be able to provide implementations of interfaces for it later. We begin by defining a function to retrieve values from the context during evaluation: .. code-block:: idris fetch : String -> Eval Int fetch x = MkEval (\e => fetchVal e) where fetchVal : List (String, Int) -> Maybe Int fetchVal [] = Nothing fetchVal ((v, val) :: xs) = if (x == v) then (Just val) else (fetchVal xs) When defining an evaluator for the language, we will be applying functions in the context of an ``Eval``, so it is natural to give ``Eval`` an implementation of ``Applicative``. Before ``Eval`` can have an implementation of ``Applicative`` it is necessary for ``Eval`` to have an implementation of ``Functor``: .. code-block:: idris Functor Eval where map f (MkEval g) = MkEval (\e => map f (g e)) Applicative Eval where pure x = MkEval (\e => Just x) (<*>) (MkEval f) (MkEval g) = MkEval (\x => app (f x) (g x)) where app : Maybe (a -> b) -> Maybe a -> Maybe b app (Just fx) (Just gx) = Just (fx gx) app _ _ = Nothing Evaluating an expression can now make use of the idiomatic application to handle errors: .. code-block:: idris eval : Expr -> Eval Int eval (Var x) = fetch x eval (Val x) = [| x |] eval (Add x y) = [| eval x + eval y |] runEval : List (String, Int) -> Expr -> Maybe Int runEval env e = case eval e of MkEval envFn => envFn env For example: :: InterpE> runEval [("x", 10), ("y",84)] (Add (Var "x") (Var "y")) Just 94 InterpE> runEval [("x", 10), ("y",84)] (Add (Var "x") (Var "z")) Nothing Named Implementations ===================== It can be desirable to have multiple implementations of an interface for the same type, for example to provide alternative methods for sorting or printing values. To achieve this, implementations can be *named* as follows: .. code-block:: idris [myord] Ord Nat where compare Z (S n) = GT compare (S n) Z = LT compare Z Z = EQ compare (S x) (S y) = compare @{myord} x y This declares an implementation as normal, but with an explicit name, ``myord``. The syntax ``compare @{myord}`` gives an explicit implementation to ``compare``, otherwise it would use the default implementation for ``Nat``. We can use this, for example, to sort a list of ``Nat`` in reverse. Given the following list: .. code-block:: idris testList : List Nat testList = [3,4,1] We can sort it using the default ``Ord`` implementation, by using the ``sort`` function available with ``import Data.List``, then we can try with the named implementation ``myord`` as follows, at the Idris prompt: :: Main> show (sort testList) "[1, 3, 4]" Main> show (sort @{myord} testList) "[4, 3, 1]" Sometimes, we also need access to a named parent implementation. For example, the prelude defines the following ``Semigroup`` interface: .. code-block:: idris interface Semigroup ty where (<+>) : ty -> ty -> ty Then it defines ``Monoid``, which extends ``Semigroup`` with a “neutral” value: .. code-block:: idris interface Semigroup ty => Monoid ty where neutral : ty We can define two different implementations of ``Semigroup`` and ``Monoid`` for ``Nat``, one based on addition and one on multiplication: .. code-block:: idris [PlusNatSemi] Semigroup Nat where (<+>) x y = x + y [MultNatSemi] Semigroup Nat where (<+>) x y = x * y The neutral value for addition is ``0``, but the neutral value for multiplication is ``1``. It's important, therefore, that when we define implementations of ``Monoid`` they extend the correct ``Semigroup`` implementation. We can do this with a ``using`` clause in the implementation as follows: .. code-block:: idris [PlusNatMonoid] Monoid Nat using PlusNatSemi where neutral = 0 [MultNatMonoid] Monoid Nat using MultNatSemi where neutral = 1 The ``using PlusNatSemi`` clause indicates that ``PlusNatMonoid`` should extend ``PlusNatSemi`` specifically. Determining Parameters ====================== When an interface has more than one parameter, it can help resolution if the parameters used to find an implementation are restricted. For example: .. code-block:: idris interface Monad m => MonadState s (m : Type -> Type) | m where get : m s put : s -> m () In this interface, only ``m`` needs to be known to find an implementation of this interface, and ``s`` can then be determined from the implementation. This is declared with the ``| m`` after the interface declaration. We call ``m`` a *determining parameter* of the ``MonadState`` interface, because it is the parameter used to find an implementation. .. [#ConorRoss] Conor McBride and Ross Paterson. 2008. Applicative programming with effects. J. Funct. Program. 18, 1 (January 2008), 1-13. DOI=10.1017/S0956796807006326 https://dx.doi.org/10.1017/S0956796807006326