{-# LANGUAGE OverloadedStrings #-} {-# LANGUAGE NoImplicitPrelude #-} -- | Commonly useful functions, a Prelude replacement. -- -- This is designed to be imported everywhere, unqualified (generally -- the only unqualified import you should use). -- -- Alpha can be opinionated and break with other Haskell idioms. For -- example, we define our own operators which have a pattern to their -- characters: -- -- - `|` normal function-level applications -- - `/` indicates doing something inside a functor -- - `<` and `>` indicate the direction in which values flow -- - `?` is for boolean tests or assertions -- between functions -- -- It seems unnecessarily different at first but it makes things easier -- to read quickly. -- -- Pronunciations are given for operators and are taken from -- [Hoon](https://urbit.org/docs/tutorials/hoon/hoon-school/hoon-syntax/). -- Pronouncing operators as you write the code is actually a nice way to -- interact with the codebase, and I do recommend it. module Alpha ( -- * Re-export Protolude module X, String, -- * Composing compose, (.>), (<.), -- * Applying (<|), (|>), -- * Mapping (/>), (), -- * Binding bind, (+>), -- * Bool don't, (?>), (?<), (?:), (?.), (?+), (?|), -- * Text str, tshow, chomp, lchomp, CanSnakeCase (snake), wrap, -- * String capitalize, lowercase, strip, -- * Lists list, joinWith, -- * Data Validation require, ) where import qualified Data.Char as Char import qualified Data.List as List import Data.String import qualified Data.Text as Text import qualified Data.Text.Lazy as LazyText import Protolude as X hiding (list, ($), (&), (.), (>>=)) import Protolude.Conv import qualified Prelude -- | Create a list. This should be @Data.List.singleton@ but that doesn't exist. list :: a -> [a] list a = [a] -- | Composition compose :: (a -> b) -> (b -> c) -> (a -> c) compose f g x = g (f x) -- | Right-composition operator -- -- Pronunciation: dot-gar (.>) :: (a -> b) -> (b -> c) -> (a -> c) f .> g = compose f g -- | Left-composition operator -- -- Pronunciation: gal-dot (<.) :: (b -> c) -> (a -> b) -> (a -> c) g <. f = compose f g -- | Alias for map, fmap, <$> -- -- Pronunciation: gal-fas ( (a -> b) -> f a -> f b f (b -> a) -> f0 (f1 b) -> f0 (f1 a) (<%) = fmap <. fmap -- | Double fmap. A function on the left goes "into" two functors -- (i.e. it goes "two levels deep"), applies the function to the inner -- values, then returns the result wrapped in the two functors. -- -- Pronunciation: cen-gar (%>) :: (Functor f0, Functor f1) => (a -> b) -> f0 (f1 a) -> f0 (f1 b) (%>) = fmap .> fmap -- | Normal function application. Do the right side, then pass the -- return value to the function on the left side. -- -- Pronunciation: gal-bar (<|) :: (a -> b) -> a -> b f <| g = f g infixr 1 <| -- | Reverse function application. Do the left side, then pass the -- return value to the function on the right side. -- -- Pronunciation: bar-gar (|>) :: a -> (a -> b) -> b f |> g = g f infixl 1 |> -- | Alias for <&>. Can be read as "and then". Basically does into a -- functor, does some computation, then returns the same kind of -- functor. Could also be defined as `f +> return <. g` -- -- Pronunciation: fas-gar (/>) :: Functor f => f a -> (a -> b) -> f b f /> g = fmap g f infixl 1 /> bind :: Monad m => m a -> (a -> m b) -> m b bind a f = a Prelude.>>= f {- HLINT ignore "Use +>" -} (+>) :: Monad m => m a -> (a -> m b) -> m b a +> b = a Prelude.>>= b infixl 1 +> -- | If-then-else. wutcol (?:) :: Bool -> (p, p) -> p a ?: (b, c) = if a then b else c -- | Inverted if-then-else. wutdot (?.) :: Bool -> (p, p) -> p a ?. (b, c) = if a then c else b -- | Positive assertion. wutgar (?>) :: Bool -> (Bool -> Text -> a) -> Text -> a a ?> f = if a then f a else panic "wutgar failed" -- | Lisp-style cond. wutlus (?+) :: t -> [(t -> Bool, p)] -> p a ?+ ((p, v) : ls) = if p a then v else a ?+ ls _ ?+ [] = panic "wutlus: empty cond list" -- | Negative assertion. wutgal (?<) :: Bool -> (Bool -> Text -> a) -> Text -> a a ?< f = if not a then f a else panic "wutgal failed" -- | When. wutbar (?|) :: Applicative f => Bool -> f () -> f () a ?| f = when a f -- | Removes newlinse from a string. strip :: String -> String strip = filter (/= '\n') -- | Removes newlines from text. chomp :: Text -> Text chomp = Text.filter (/= '\n') -- | Removes newlines from lazy text. lchomp :: LazyText.Text -> LazyText.Text lchomp = LazyText.filter (/= '\n') -- | Join a list of things with a separator. joinWith :: [a] -> [[a]] -> [a] joinWith = intercalate -- | can you just not don't :: Bool -> Bool don't = do not {-# ANN don't ("HLint: ignore Redundant do" :: String) #-} -- | Class for turning different string types to snakeCase. class CanSnakeCase s where snake :: s -> s instance CanSnakeCase Text where snake = Text.toLower .> Text.replace " " "-" capitalize :: String -> String capitalize [] = [] capitalize s = (Char.toUpper <| List.head s) : (Char.toLower String lowercase s = [Char.toLower c | c <- s] {-# WARNING require "'require' remains in code" #-} require :: Text -> Maybe a -> a require _ (Just x) = x require s Nothing = panic <| s <> " not found" -- | Wrap text at the given limit. wrap :: Int -> Text -> Text wrap lim = Text.words .> wrap_ 0 .> Text.unwords where wrap_ :: Int -> [Text] -> [Text] wrap_ _ [] = [] wrap_ pos (w : ws) | pos == 0 = w : wrap_ (pos + lw) ws | pos + lw + 1 > lim = wrap_ 0 (Text.cons '\n' w : ws) | otherwise = w : wrap_ (pos + lw + 1) ws where lw = Text.length w str :: (StringConv a b) => a -> b str = Protolude.Conv.toS tshow :: Show a => a -> Text tshow = show