module Builtin -- The most primitive data types; things which are used by desugaring -- Totality assertions ||| Assert to the totality checker that the given expression will always ||| terminate. ||| ||| The multiplicity of its argument is 1, so `assert_total` won't affect how ||| many times variables are used. If you're not writing a linear function, ||| this doesn't make a difference. ||| ||| Note: assert_total can reduce at compile time, if required for unification, ||| which might mean that it's no longer guarded a subexpression. Therefore, ||| it is best to use it around the smallest possible subexpression. %inline public export assert_total : (1 _ : a) -> a assert_total x = x ||| Assert to the totality checker that y is always structurally smaller than x ||| (which is typically a pattern argument, and *must* be in normal form for ||| this to work). ||| ||| The multiplicity of x is 0, so in a linear function, you can pass values to ||| x even if they have already been used. ||| The multiplicity of y is 1, so `assert_smaller` won't affect how many times ||| its y argument is used. ||| If you're not writing a linear function, the multiplicities don't make a ||| difference. ||| ||| @ x the larger value (typically a pattern argument) ||| @ y the smaller value (typically an argument to a recursive call) %inline public export assert_smaller : (0 x : a) -> (1 y : b) -> b assert_smaller x y = y -- Unit type and pairs ||| The canonical single-element type, also known as the trivially true ||| proposition. public export data Unit = ||| The trivial constructor for `()`. MkUnit ||| The non-dependent pair type, also known as conjunction. public export data Pair : Type -> Type -> Type where ||| A pair of elements. ||| @ a the left element of the pair ||| @ b the right element of the pair MkPair : {0 a, b : Type} -> (x : a) -> (y : b) -> Pair a b ||| Return the first element of a pair. public export fst : {0 a, b : Type} -> (a, b) -> a fst (x, y) = x ||| Return the second element of a pair. public export snd : {0 a, b : Type} -> (a, b) -> b snd (x, y) = y -- This directive tells auto implicit search what to use to look inside pairs %pair Pair fst snd infix 5 # ||| A pair type where each component is linear public export data LPair : Type -> Type -> Type where (#) : (1 _ : a) -> (1 _ : b) -> LPair a b namespace DPair ||| Dependent pairs aid in the construction of dependent types by providing ||| evidence that some value resides in the type. ||| ||| Formally, speaking, dependent pairs represent existential quantification - ||| they consist of a witness for the existential claim and a proof that the ||| property holds for it. ||| ||| @ a the value to place in the type. ||| @ p the dependent type that requires the value. public export record DPair a (p : a -> Type) where constructor MkDPair fst : a snd : p fst ||| A dependent variant of LPair, pairing a result value with a resource ||| that depends on the result value public export data Res : (a : Type) -> (a -> Type) -> Type where (#) : (val : a) -> (1 r : t val) -> Res a t -- The empty type ||| The empty type, also known as the trivially false proposition. ||| ||| Use `void` or `absurd` to prove anything if you have a variable of type ||| `Void` in scope. public export data Void : Type where -- Equality public export data Equal : forall a, b . a -> b -> Type where [search a b] Refl : {0 x : a} -> Equal x x %name Equal prf infix 9 ===, ~=~ -- An equality type for when you want to assert that each side of the -- equality has the same type, but there's not other evidence available -- to help with unification public export (===) : (x : a) -> (y : a) -> Type (===) = Equal ||| Explicit heterogeneous ("John Major") equality. Use this when Idris ||| incorrectly chooses homogeneous equality for `(=)`. ||| @ a the type of the left side ||| @ b the type of the right side ||| @ x the left side ||| @ y the right side public export (~=~) : (x : a) -> (y : b) -> Type (~=~) = Equal ||| Perform substitution in a term according to some equality. ||| ||| Like `replace`, but with an explicit predicate, and applying the rewrite in ||| the other direction, which puts it in a form usable by the `rewrite` tactic ||| and term. %inline public export rewrite__impl : {0 x, y : a} -> (0 p : _) -> (0 rule : x = y) -> (val : p y) -> p x rewrite__impl p Refl prf = prf %rewrite Equal rewrite__impl ||| Perform substitution in a term according to some equality. %inline public export replace : forall x, y, p . (0 rule : x = y) -> p x -> p y replace Refl prf = prf ||| Symmetry of propositional equality. %inline public export sym : (0 rule : x = y) -> y = x sym Refl = Refl ||| Transitivity of propositional equality. %inline public export trans : forall a, b, c . (0 l : a = b) -> (0 r : b = c) -> a = c trans Refl Refl = Refl ||| Injectivity of MkDPair (first components) export mkDPairInjectiveFst : MkDPair a pa === MkDPair b qb -> a === b mkDPairInjectiveFst Refl = Refl ||| Injectivity of MkDPair (snd components) export mkDPairInjectiveSnd : MkDPair a pa === MkDPair a qa -> pa === qa mkDPairInjectiveSnd Refl = Refl ||| Subvert the type checker. This function is abstract, so it will not reduce ||| in the type checker. Use it with care - it can result in segfaults or ||| worse! public export believe_me : a -> b believe_me = prim__believe_me _ _ ||| Assert to the usage checker that the given function uses its argument linearly. public export assert_linear : (1 f : a -> b) -> (1 val : a) -> b assert_linear = believe_me id where id : (1 f : a -> b) -> a -> b id f = f export partial idris_crash : String -> a idris_crash = prim__crash _ public export %inline delay : a -> Lazy a delay x = Delay x public export %inline force : Lazy a -> a force x = Force x %stringLit fromString ||| Interface for types that can be constructed from string literals. public export interface FromString ty where ||| Conversion from String. fromString : String -> ty %allow_overloads fromString %inline public export FromString String where fromString s = s %defaulthint %inline public export defaultString : FromString String defaultString = %search