{-# LANGUAGE DataKinds #-} {-# OPTIONS_GHC -Wall -fno-warn-unused-imports -fno-warn-unticked-promoted-constructors -Werror #-} -- | Build backend-agnostic columnar encodings that can be -- used to visualize tabular data. module Colonnade ( -- * Example -- $setup -- * Types Colonnade , Headed(..) , Headless(..) -- * Create , headed , headless , singleton -- * Transform , mapHeaderContent , fromMaybe , columns , bool , replaceWhen , modifyWhen -- * Cornice -- ** Types , Cornice , Pillar(..) , Fascia(..) -- ** Create , cap , recap -- * Ascii Table , ascii , asciiCapped ) where import Colonnade.Encode (Colonnade,Cornice, Pillar(..),Fascia(..),Headed(..),Headless(..)) import Data.Foldable import Control.Monad import qualified Data.Bool import qualified Data.Maybe import qualified Colonnade.Encode as E import qualified Data.List as List import qualified Data.Vector as Vector -- $setup -- -- First, let\'s bring in some neccessary imports that will be -- used for the remainder of the examples in the docs: -- -- >>> import Data.Monoid (mconcat,(<>)) -- >>> import Data.Profunctor (lmap) -- -- The data types we wish to encode are: -- -- >>> data Color = Red | Green | Blue deriving (Show,Eq) -- >>> data Person = Person { name :: String, age :: Int } -- >>> data House = House { color :: Color, price :: Int } -- -- One potential columnar encoding of a @Person@ would be: -- -- >>> :{ -- let colPerson :: Colonnade Headed Person String -- colPerson = mconcat -- [ headed "Name" name -- , headed "Age" (show . age) -- ] -- :} -- -- The type signature on @colPerson@ is not neccessary -- but is included for clarity. We can feed data into this encoding -- to build a table: -- -- >>> let people = [Person "David" 63, Person "Ava" 34, Person "Sonia" 12] -- >>> putStr (ascii colPerson people) -- +-------+-----+ -- | Name | Age | -- +-------+-----+ -- | David | 63 | -- | Ava | 34 | -- | Sonia | 12 | -- +-------+-----+ -- -- Similarly, we can build a table of houses with: -- -- >>> let showDollar = (('$':) . show) :: Int -> String -- >>> colHouse = mconcat [headed "Color" (show . color), headed "Price" (showDollar . price)] -- >>> :t colHouse -- colHouse :: Colonnade Headed House [Char] -- >>> let houses = [House Green 170000, House Blue 115000, House Green 150000] -- >>> putStr (ascii colHouse houses) -- +-------+---------+ -- | Color | Price | -- +-------+---------+ -- | Green | $170000 | -- | Blue | $115000 | -- | Green | $150000 | -- +-------+---------+ -- | A single column with a header. headed :: c -> (a -> c) -> Colonnade Headed a c headed h = singleton (Headed h) -- | A single column without a header. headless :: (a -> c) -> Colonnade Headless a c headless = singleton Headless -- | A single column with any kind of header. This is not typically needed. singleton :: h c -> (a -> c) -> Colonnade h a c singleton h = E.Colonnade . Vector.singleton . E.OneColonnade h -- | Map over the content in the header. This is similar performing 'fmap' -- on a 'Colonnade' except that the body content is unaffected. mapHeaderContent :: Functor h => (c -> c) -> Colonnade h a c -> Colonnade h a c mapHeaderContent f (E.Colonnade v) = E.Colonnade (Vector.map (\(E.OneColonnade h e) -> E.OneColonnade (fmap f h) e) v) -- | Lift a column over a 'Maybe'. For example, if some people -- have houses and some do not, the data that pairs them together -- could be represented as: -- -- >>> :{ -- let owners :: [(Person,Maybe House)] -- owners = -- [ (Person "Jordan" 18, Nothing) -- , (Person "Ruth" 25, Just (House Red 125000)) -- , (Person "Sonia" 12, Just (House Green 145000)) -- ] -- :} -- -- The column encodings defined earlier can be reused with -- the help of 'fromMaybe': -- -- >>> :{ -- let colOwners :: Colonnade Headed (Person,Maybe House) String -- colOwners = mconcat -- [ lmap fst colPerson -- , lmap snd (fromMaybe "" colHouse) -- ] -- :} -- -- >>> putStr (ascii colOwners owners) -- +--------+-----+-------+---------+ -- | Name | Age | Color | Price | -- +--------+-----+-------+---------+ -- | Jordan | 18 | | | -- | Ruth | 25 | Red | $125000 | -- | Sonia | 12 | Green | $145000 | -- +--------+-----+-------+---------+ fromMaybe :: c -> Colonnade f a c -> Colonnade f (Maybe a) c fromMaybe c (E.Colonnade v) = E.Colonnade $ flip Vector.map v $ \(E.OneColonnade h encode) -> E.OneColonnade h (maybe c encode) -- | Convert a collection of @b@ values into a columnar encoding of -- the same size. Suppose we decide to show a house\'s color -- by putting a check mark in the column corresponding to -- the color instead of by writing out the name of the color: -- -- >>> let allColors = [Red,Green,Blue] -- >>> let encColor = columns (\c1 c2 -> if c1 == c2 then "✓" else "") (Headed . show) allColors -- >>> :t encColor -- encColor :: Colonnade Headed Color [Char] -- >>> let encHouse = headed "Price" (showDollar . price) <> lmap color encColor -- >>> :t encHouse -- encHouse :: Colonnade Headed House [Char] -- >>> putStr (ascii encHouse houses) -- +---------+-----+-------+------+ -- | Price | Red | Green | Blue | -- +---------+-----+-------+------+ -- | $170000 | | ✓ | | -- | $115000 | | | ✓ | -- | $150000 | | ✓ | | -- +---------+-----+-------+------+ columns :: Foldable g => (b -> a -> c) -- ^ Cell content function -> (b -> f c) -- ^ Header content function -> g b -- ^ Basis for column encodings -> Colonnade f a c columns getCell getHeader = id . E.Colonnade . Vector.map (\b -> E.OneColonnade (getHeader b) (getCell b)) . Vector.fromList . toList bool :: f c -- ^ Heading -> (a -> Bool) -- ^ Predicate -> (a -> c) -- ^ Contents when predicate is false -> (a -> c) -- ^ Contents when predicate is true -> Colonnade f a c bool h p onTrue onFalse = singleton h (Data.Bool.bool <$> onFalse <*> onTrue <*> p) -- | Modify the contents of cells in rows whose values satisfy the -- given predicate. Header content is unaffected. With an HTML backend, -- this can be used to strikethrough the contents of cells with data that is -- considered invalid. modifyWhen :: (c -> c) -- ^ Content change -> (a -> Bool) -- ^ Row predicate -> Colonnade f a c -- ^ Original 'Colonnade' -> Colonnade f a c modifyWhen changeContent p (E.Colonnade v) = E.Colonnade ( Vector.map (\(E.OneColonnade h encode) -> E.OneColonnade h $ \a -> if p a then changeContent (encode a) else encode a ) v ) -- | Replace the contents of cells in rows whose values satisfy the -- given predicate. Header content is unaffected. replaceWhen :: c -- ^ New content -> (a -> Bool) -- ^ Row predicate -> Colonnade f a c -- ^ Original 'Colonnade' -> Colonnade f a c replaceWhen newContent p (E.Colonnade v) = E.Colonnade ( Vector.map (\(E.OneColonnade h encode) -> E.OneColonnade h $ \a -> if p a then newContent else encode a ) v ) -- | Augment a 'Colonnade' with a header spans over all of the -- existing headers. This is best demonstrated by example. -- Let\'s consider how we might encode a pairing of the people -- and houses from the initial example: -- -- >>> let personHomePairs = zip people houses -- >>> let colPersonFst = lmap fst colPerson -- >>> let colHouseSnd = lmap snd colHouse -- >>> putStr (ascii (colPersonFst <> colHouseSnd) personHomePairs) -- +-------+-----+-------+---------+ -- | Name | Age | Color | Price | -- +-------+-----+-------+---------+ -- | David | 63 | Green | $170000 | -- | Ava | 34 | Blue | $115000 | -- | Sonia | 12 | Green | $150000 | -- +-------+-----+-------+---------+ -- -- This tabular encoding leaves something to be desired. The heading -- not indicate that the name and age refer to a person and that -- the color and price refer to a house. Without reaching for 'Cornice', -- we can still improve this situation with 'mapHeaderContent': -- -- >>> let colPersonFst' = mapHeaderContent ("Person " ++) colPersonFst -- >>> let colHouseSnd' = mapHeaderContent ("House " ++) colHouseSnd -- >>> putStr (ascii (colPersonFst' <> colHouseSnd') personHomePairs) -- +-------------+------------+-------------+-------------+ -- | Person Name | Person Age | House Color | House Price | -- +-------------+------------+-------------+-------------+ -- | David | 63 | Green | $170000 | -- | Ava | 34 | Blue | $115000 | -- | Sonia | 12 | Green | $150000 | -- +-------------+------------+-------------+-------------+ -- -- This is much better, but for longer tables, the redundancy -- of prefixing many column headers can become annoying. The solution -- that a 'Cornice' offers is to nest headers: -- -- >>> let cor = mconcat [cap "Person" colPersonFst, cap "House" colHouseSnd] -- >>> :t cor -- cor :: Cornice ('Cap 'Base) (Person, House) [Char] -- >>> putStr (asciiCapped cor personHomePairs) -- +-------------+-----------------+ -- | Person | House | -- +-------+-----+-------+---------+ -- | Name | Age | Color | Price | -- +-------+-----+-------+---------+ -- | David | 63 | Green | $170000 | -- | Ava | 34 | Blue | $115000 | -- | Sonia | 12 | Green | $150000 | -- +-------+-----+-------+---------+ -- cap :: c -> Colonnade Headed a c -> Cornice (Cap Base) a c cap h = E.CorniceCap . Vector.singleton . E.OneCornice h . E.CorniceBase -- | Add another cap to a cornice. There is no limit to how many times -- this can be applied: -- -- >>> data Day = Weekday | Weekend deriving (Show) -- >>> :{ -- let cost :: Int -> Day -> String -- cost base w = case w of -- Weekday -> showDollar base -- Weekend -> showDollar (base + 1) -- colStandard = foldMap (\c -> headed c (cost 8)) ["Yt","Ad","Sr"] -- colSpecial = mconcat [headed "Stud" (cost 6), headed "Mltry" (cost 7)] -- corStatus = mconcat -- [ cap "Standard" colStandard -- , cap "Special" colSpecial -- ] -- corShowtime = mconcat -- [ recap "" (cap "" (headed "Day" show)) -- , foldMap (\c -> recap c corStatus) ["Matinee","Evening"] -- ] -- :} -- -- >>> putStr (asciiCapped corShowtime [Weekday,Weekend]) -- +---------+-----------------------------+-----------------------------+ -- | | Matinee | Evening | -- +---------+--------------+--------------+--------------+--------------+ -- | | Standard | Special | Standard | Special | -- +---------+----+----+----+------+-------+----+----+----+------+-------+ -- | Day | Yt | Ad | Sr | Stud | Mltry | Yt | Ad | Sr | Stud | Mltry | -- +---------+----+----+----+------+-------+----+----+----+------+-------+ -- | Weekday | $8 | $8 | $8 | $6 | $7 | $8 | $8 | $8 | $6 | $7 | -- | Weekend | $9 | $9 | $9 | $7 | $8 | $9 | $9 | $9 | $7 | $8 | -- +---------+----+----+----+------+-------+----+----+----+------+-------+ recap :: c -> Cornice p a c -> Cornice (Cap p) a c recap h cor = E.CorniceCap (Vector.singleton (E.OneCornice h cor)) asciiCapped :: Foldable f => Cornice p a String -- ^ columnar encoding -> f a -- ^ rows -> String asciiCapped cor xs = let annCor = E.annotateFinely (\x y -> x + y + 3) id List.length xs cor sizedCol = E.uncapAnnotated annCor in E.headersMonoidal Nothing [ (\sz _ -> hyphens (sz + 2) ++ "+", \s -> "+" ++ s ++ "\n") , (\sz c -> " " ++ rightPad sz ' ' c ++ " |", \s -> "|" ++ s ++ "\n") ] annCor ++ asciiBody sizedCol xs -- | Render a collection of rows as an ascii table. The table\'s columns are -- specified by the given 'Colonnade'. This implementation is inefficient and -- does not provide any wrapping behavior. It is provided so that users can -- try out @colonnade@ in ghci and so that @doctest@ can verify example -- code in the haddocks. ascii :: Foldable f => Colonnade Headed a String -- ^ columnar encoding -> f a -- ^ rows -> String ascii col xs = let sizedCol = E.sizeColumns List.length xs col divider = concat [ "+" , E.headerMonoidalFull sizedCol (\(E.Sized sz _) -> hyphens (sz + 2) ++ "+") , "\n" ] in List.concat [ divider , concat [ "|" , E.headerMonoidalFull sizedCol (\(E.Sized s (Headed h)) -> " " ++ rightPad s ' ' h ++ " |") , "\n" ] , asciiBody sizedCol xs ] asciiBody :: Foldable f => Colonnade (E.Sized Headed) a String -> f a -> String asciiBody sizedCol xs = let divider = concat [ "+" , E.headerMonoidalFull sizedCol (\(E.Sized sz _) -> hyphens (sz + 2) ++ "+") , "\n" ] rowContents = foldMap (\x -> concat [ "|" , E.rowMonoidalHeader sizedCol (\(E.Sized sz _) c -> " " ++ rightPad sz ' ' c ++ " |") x , "\n" ] ) xs in List.concat [ divider , rowContents , divider ] hyphens :: Int -> String hyphens n = List.replicate n '-' rightPad :: Int -> a -> [a] -> [a] rightPad m a xs = take m $ xs ++ repeat a -- data Company = Company String String Int -- -- data Company = Company -- { companyName :: String -- , companyCountry :: String -- , companyValue :: Int -- } deriving (Show) -- -- myCompanies :: [Company] -- myCompanies = -- [ Company "eCommHub" "United States" 50 -- , Company "Layer 3 Communications" "United States" 10000000 -- , Company "Microsoft" "England" 500000000 -- ]