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---
title: On the design of a structured document format compatible with character oriented printers
published: 2016-01-11
tags: Thermoprint
---
This post is an annotated version of the file [spec/src/Thermoprint/Printout.hs](https://git.yggdrasil.li/thermoprint/tree/spec/src/Thermoprint/Printout.hs?h=rewrite&id=f6dc3d1) as of commit `f6dc3d1`.
> {-# LANGUAGE DeriveGeneric, DeriveAnyClass #-}
> {-# LANGUAGE OverloadedStrings #-}
> {-# OPTIONS_HADDOCK show-extensions #-}
Motivation
----------
We want our codebase to be compatible with as many different models of printers as we are willing to implement.
It is therefore desirable to maintain a structured document format which we can transform into a printer-specific representation of the payload to be printed with minimal effort.
In this post we present one such format.
Contents
--------
> -- | This module contains the definition of the structure -- 'Printout' -- used to represent the content of a job
> module Thermoprint.Printout
> ( Printout(..)
> , Paragraph(..)
> , Chunk(..)
> , Block(..)
> , Line( HSpace
> , SpaceSep
> )
> , text, cotext
> , prop_text
> ) where
Preliminaries
-------------
> import Data.Sequence (Seq, (|>), (<|))
A Sequence represents the same structure as the linked lists common in haskell but supports $O(1)$ `snoc`, which is desirable since we intend to iteratively build up the structure when parsing input formats.
> import Data.Text.Lazy (Text)
>
> import Data.ByteString.Lazy (ByteString)
The entire structure will be lazy by default but an instance of `NFData`, thus the lazy variants of `Text` and `ByteString`.
> import GHC.Generics (Generic)
We will use derived instances of `Generic` to get handed suitable instances of rather complicated classes such as `Arbitrary` and `FromJSON`
> import Control.DeepSeq (NFData)
Instances of `NFData` allow us to strictly evaluate our document structure when needed
> import Data.Aeson (FromJSON(..), ToJSON(..), Value(..))
> import qualified Data.Aeson as JSON (encode, decode)
> import Data.Aeson.Types (typeMismatch)
We will encode the document as a [json](https://en.wikipedia.org/wiki/JSON) object during transport
> import Test.QuickCheck.Arbitrary (Arbitrary(..), CoArbitrary, genericShrink)
> import Test.QuickCheck.Modifiers (NonNegative(..))
> import Test.QuickCheck.Gen (oneof, suchThat, scale)
> import Test.QuickCheck.Instances
> import Test.QuickCheck (forAll, Property)
We will use [QuickCheck](https://hackage.haskell.org/package/QuickCheck) for automatic test generation.
> import qualified Data.Text.Lazy as TL (split, null, pack, filter, intercalate, map)
> import qualified Data.Text as T (pack)
> import Data.Char (isSpace)
>
> import Data.Monoid (Monoid(..), (<>))
>
> import Data.List (dropWhile, dropWhileEnd, groupBy, genericLength, genericReplicate)
>
> import Data.Sequence as Seq (fromList, null, singleton)
>
> import Data.Function (on)
>
> import Data.Foldable (toList, fold)
We will need to do some parsing and pretty-printing to implement `text` and `cotext`, respectively.
> import Data.Encoding (encodeLazyByteStringExplicit, decodeLazyByteString)
> import Data.Encoding.UTF8
> import qualified Data.ByteString.Base64.Lazy as Base64 (encode, decode)
Since we want end users to be able to include direct instructions the printer in the form of a lazy [`ByteString`](https://hackage.haskell.org/package/bytestring) we need some way to encode `ByteString`s in JSON.
We chose [base64](https://hackage.haskell.org/package/base64-bytestring).
> import Prelude hiding (fold)
>
>
> -- | A 'Printout' is a sequence of visually seperated 'Paragraph's
> type Printout = Seq Paragraph
"visually seperated" will most likely end up meaning "seperated by a single blank line"
> -- | A 'Paragraph' is a non-seperated sequence of 'Chunk's
> type Paragraph = Seq Chunk
>
> -- | We introduce both 'Chunk' and 'Paragraph' mainly to allow 'Raw'.
> --
> -- Were we to disallow 'Raw', 'Block' would be identical to 'Paragraph'
> data Chunk = Cooked Block -- ^ text semantically structured to be rendered in accordance with the display format of printer
> | Raw ByteString -- ^ direct instructions to the printer
> deriving (Generic, NFData, Show, CoArbitrary)
>
> instance FromJSON Chunk where
> parseJSON s@(String _) = Raw <$> ((either fail return . decodeBase64) =<< parseJSON s)
> where
> decodeBase64 :: String -> Either String ByteString
> decodeBase64 s = (either (Left . show) Right . encodeLazyByteStringExplicit UTF8Strict $ s) >>= Base64.decode
> parseJSON o@(Object _) = Cooked <$> parseJSON o
> parseJSON v = typeMismatch "Chunk" v
>
> instance ToJSON Chunk where
> toJSON (Raw bs) = String . T.pack . decodeLazyByteString UTF8Strict . Base64.encode $ bs
> toJSON (Cooked block) = toJSON block
We provide custom instances of `FromJSON Chunk` and `ToJSON Chunk` so that we might reduce the sice of the resulting JSON somewhat (this is an opportune target since disambiguaty is simple)
> -- | 'Block' is the entry point for our structured document format
> data Block = Line Line -- ^ a single 'Line' of text
> | VSpace Integer -- ^ vertical space of height equivalent to 'Integer' lines
> | NewlSep (Seq Block) -- ^ A sequence of 'Block's seperated by newlines
> deriving (Generic, NFData, Show, CoArbitrary, FromJSON, ToJSON)
>
> {- | A 'Line' is one of:
>
> * a single word
> * horizontal space equivalent to the width of 'Integer' `em`.
> * a sequence of words seperated by spaces
>
> We don't export all constructors and instead encourage the use of 'text'.
> -}
> data Line = Word Text
> | HSpace Integer
> | SpaceSep (Seq Line)
> deriving (Generic, NFData, Show, CoArbitrary, FromJSON, ToJSON)
>
> instance Monoid Block where
> mempty = NewlSep mempty
> x@(NewlSep xs) `mappend` y@(NewlSep ys)
> | Seq.null xs = y
> | Seq.null ys = x
> | otherwise = NewlSep (xs <> ys)
> (NewlSep xs) `mappend` y
> | Seq.null xs = y
> | otherwise = NewlSep (xs |> y)
> x `mappend` (NewlSep ys)
> | Seq.null ys = x
> | otherwise = NewlSep (x <| ys)
> x `mappend` y = NewlSep $ Seq.fromList [x, y]
>
> instance Monoid Line where
> mempty = SpaceSep mempty
> x@(SpaceSep xs) `mappend` y@(SpaceSep ys)
> | Seq.null xs = y
> | Seq.null ys = x
> | otherwise = SpaceSep (xs <> ys)
> (SpaceSep xs) `mappend` y
> | Seq.null xs = y
> | otherwise = SpaceSep (xs |> y)
> x `mappend` (SpaceSep ys)
> | Seq.null ys = x
> | otherwise = SpaceSep (x <| ys)
> x `mappend` y = SpaceSep $ Seq.fromList [x, y]
The Monoid instances for `Block` and `Line` are somewhat unwieldy since we want to guarantee minimum overhead by reducing expressions such as `SpaceSep (fromList [x])` to `x` whenever possible.
The same effect would have been possible by introducing the monoid structure *one level higher* -- we could have introduced constructors such as `Line :: Seq Word -> Block`.
This was deemed undesirable since we would not have been able to implement instances such as `Monoid Line` which allow the use of more generic functions during parsing.
> text :: Text -> Either Block Line
> -- ^ Smart constructor for 'Line'/'Block' which maps word and line boundaries (as determined by 'isSpace' and '(== '\n')' respectively) to the structure of 'Block' and 'Line'.
> --
> -- Since we are unwilling to duplicate the list of chars from 'isSpace' we cannot reasonably determine a width for the various whitespace 'Char's.
> -- Thus they are all weighted equally as having width 1 `em`.
> text t = case splitLines t of
> [] -> Right mempty
> [Line x] -> Right x
> xs -> Left $ mconcat xs
> where
> splitLines :: Text -> [Block]
> splitLines t = map toBlock
> . groupBy ((==) `on` TL.null)
> $ TL.split (== '\n') t
> splitWords :: Text -> [Line]
> splitWords t = map toLine
> . groupBy ((==) `on` TL.null)
> $ TL.split isSpace t
> toBlock [] = mempty
> toBlock xs@(x:_)
> | TL.null x = VSpace $ genericLength xs - 1
> | otherwise = mconcat . map (Line . mconcat . splitWords) $ xs
> toLine [] = mempty
> toLine xs@(x:_)
> | TL.null x = HSpace $ genericLength xs - 1
> | otherwise = mconcat . map Word $ xs
> list :: b -> (a -> [a] -> b) -> [a] -> b
> list c _ [] = c
> list _ f (x:xs) = f x xs
Implementations using `TL.lines` and `TL.words` were tested.
We chose to use `TL.split`-based solutions instead because the more specific splitting functions provided by [text](https://hackage.haskell.org/package/text) drop information concerning the exact amount of whitespace.
> cotext :: Block -> Text
> -- ^ inverse of
> -- @
> -- either id Line . `text`
> -- @
> cotext (VSpace n) = TL.pack . genericReplicate n $ '\n'
> cotext (NewlSep xs) = TL.intercalate "\n" . map cotext . toList $ xs
> cotext (Line x) = cotext' x
> where
> cotext' (Word x) = x
> cotext' (HSpace n) = TL.pack . genericReplicate n $ ' '
> cotext' (SpaceSep xs) = TL.intercalate " " . map cotext' . toList $ xs
We provide cotext for testing `text` and to enable determining semantic equality of `Printout`s at a later date
> prop_text :: Text -> Bool
> -- ^ prop> (`cotext` . either id Line . `text` $ x) == x
> --
> -- Where 'x' is restricted to those `TL.Text` which do not contain whitespace besides ' ' and '\n'.
> prop_text x = (cotext . either id Line . text $ x') == x'
> where
> x' = TL.map normSpace x
> normSpace c
> | isSpace c
> , c `elem` keep = c
> | isSpace c = ' ' -- We have to do this because all whitespace gets interpreted as width 1
> | otherwise = c
> keep = [' ', '\n']
>
> -- | We don't test 'Raw' 'Chunk's
> instance Arbitrary Chunk where
> shrink = genericShrink
> arbitrary = Cooked <$> arbitrary
>
> instance Arbitrary Block where
> shrink = genericShrink
> arbitrary = oneof [ Line <$> arbitrary
> , VSpace . getNonNegative <$> arbitrary
> , NewlSep <$> scale' arbitrary
> ]
>
> instance Arbitrary Line where
> shrink = genericShrink
> arbitrary = oneof [ Word . TL.filter (not . isSpace) <$> arbitrary -- 'isSpace '\n' == True'
> , HSpace . getNonNegative <$> arbitrary
> , SpaceSep <$> scale' arbitrary
> ]
>
> scale' = scale (round . sqrt . fromInteger . toInteger)
Failing to properly scale the tested structures was shown to use more than 8GiB of RAM during testing
|