{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE OverloadedStrings #-}
module Text.Pandoc.Readers.LaTeX.Table
( tableEnvironments )
where
import Data.Functor (($>))
import Text.Pandoc.Class
import Text.Pandoc.Readers.LaTeX.Parsing
import Text.Pandoc.Readers.LaTeX.Types
import Text.Pandoc.Builder as B
import qualified Data.Map as M
import Data.Text (Text)
import Data.Maybe (fromMaybe)
import qualified Data.Text as T
import Control.Applicative ((<|>), optional, many)
import Control.Monad (when, void)
import Text.Pandoc.Shared (safeRead, trim)
import Text.Pandoc.Logging (LogMessage(SkippedContent))
import Text.Pandoc.Walk (walkM)
import Text.Pandoc.Parsing hiding (blankline, many, mathDisplay, mathInline,
optional, space, spaces, withRaw, (<|>))
tableEnvironments :: PandocMonad m
=> LP m Blocks
-> LP m Inlines
-> M.Map Text (LP m Blocks)
tableEnvironments blocks inline =
M.fromList
[ ("longtable", env "longtable" $
resetCaption *>
simpTable blocks inline "longtable" False >>= addTableCaption)
, ("table", env "table" $
skipopts *> resetCaption *> blocks >>= addTableCaption)
, ("tabular*", env "tabular*" $ simpTable blocks inline "tabular*" True)
, ("tabularx", env "tabularx" $ simpTable blocks inline "tabularx" True)
, ("tabular", env "tabular" $ simpTable blocks inline "tabular" False)
]
hline :: PandocMonad m => LP m ()
hline = try $ do
spaces
controlSeq "hline" <|>
(controlSeq "cline" <* braced) <|>
-- booktabs rules:
controlSeq "toprule" <|>
controlSeq "bottomrule" <|>
controlSeq "midrule" <|>
controlSeq "endhead" <|>
controlSeq "endfirsthead"
spaces
optional rawopt
return ()
lbreak :: PandocMonad m => LP m Tok
lbreak = (controlSeq "\\" <|> controlSeq "tabularnewline")
<* skipopts <* spaces
amp :: PandocMonad m => LP m Tok
amp = symbol '&'
-- Split a Word into individual Symbols (for parseAligns)
splitWordTok :: PandocMonad m => LP m ()
splitWordTok = do
inp <- getInput
case inp of
(Tok spos Word t : rest) ->
setInput $ map (Tok spos Symbol . T.singleton) (T.unpack t) <> rest
_ -> return ()
parseAligns :: PandocMonad m => LP m [(Alignment, ColWidth, ([Tok], [Tok]))]
parseAligns = try $ do
let maybeBar = skipMany
(try $ sp *> (() <$ symbol '|' <|> () <$ (symbol '@' >> braced)))
let cAlign = AlignCenter <$ symbol 'c'
let lAlign = AlignLeft <$ symbol 'l'
let rAlign = AlignRight <$ symbol 'r'
let parAlign = AlignLeft <$ symbol 'p'
-- aligns from tabularx
let xAlign = AlignLeft <$ symbol 'X'
let mAlign = AlignLeft <$ symbol 'm'
let bAlign = AlignLeft <$ symbol 'b'
let alignChar = splitWordTok *> ( cAlign <|> lAlign <|> rAlign <|> parAlign
<|> xAlign <|> mAlign <|> bAlign )
let alignPrefix = symbol '>' >> braced
let alignSuffix = symbol '<' >> braced
let colWidth = try $ do
symbol '{'
ds <- trim . untokenize <$> manyTill anyTok (controlSeq "linewidth")
spaces
symbol '}'
return $ safeRead ds
let alignSpec = do
pref <- option [] alignPrefix
spaces
al <- alignChar
width <- colWidth <|> option Nothing (do s <- untokenize <$> braced
pos <- getPosition
report $ SkippedContent s pos
return Nothing)
spaces
suff <- option [] alignSuffix
return (al, width, (pref, suff))
let starAlign = do -- '*{2}{r}' == 'rr', we just expand like a macro
symbol '*'
spaces
ds <- trim . untokenize <$> braced
spaces
spec <- braced
case safeRead ds of
Just n ->
getInput >>= setInput . (mconcat (replicate n spec) ++)
Nothing -> Prelude.fail $ "Could not parse " <> T.unpack ds <> " as number"
bgroup
spaces
maybeBar
aligns' <- many $ try $ spaces >> optional starAlign >>
(alignSpec <* maybeBar)
spaces
egroup
spaces
return $ map toSpec aligns'
where
toColWidth (Just w) | w > 0 = ColWidth w
toColWidth _ = ColWidthDefault
toSpec (x, y, z) = (x, toColWidth y, z)
-- N.B. this parser returns a Row that may have erroneous empty cells
-- in it. See the note above fixTableHead for details.
parseTableRow :: PandocMonad m
=> LP m Blocks -- ^ block parser
-> LP m Inlines -- ^ inline parser
-> Text -- ^ table environment name
-> [([Tok], [Tok])] -- ^ pref/suffixes
-> LP m Row
parseTableRow blocks inline envname prefsufs = do
notFollowedBy (spaces *> end_ envname)
-- contexts that can contain & that is not colsep:
let canContainAmp (Tok _ (CtrlSeq "begin") _) = True
canContainAmp (Tok _ (CtrlSeq "verb") _) = True
canContainAmp (Tok _ (CtrlSeq "Verb") _) = True
canContainAmp _ = False
-- add prefixes and suffixes in token stream:
let celltoks (pref, suff) = do
prefpos <- getPosition
contents <- mconcat <$>
many ( snd <$> withRaw
((lookAhead (controlSeq "parbox") >>
void blocks) -- #5711
<|>
(lookAhead (satisfyTok canContainAmp) >> void inline)
<|>
(lookAhead (symbol '$') >> void inline))
<|>
(do notFollowedBy
(() <$ amp <|> () <$ lbreak <|> end_ envname)
count 1 anyTok) )
suffpos <- getPosition
option [] (count 1 amp)
return $ map (setpos prefpos) pref ++ contents ++ map (setpos suffpos) suff
rawcells <- mapM celltoks prefsufs
cells <- mapM (parseFromToks (parseTableCell blocks)) rawcells
spaces
return $ Row nullAttr cells
parseTableCell :: PandocMonad m => LP m Blocks -> LP m Cell
parseTableCell blocks = do
spaces
updateState $ \st -> st{ sInTableCell = True }
cell' <- multicolumnCell blocks
<|> multirowCell blocks
<|> parseSimpleCell
<|> parseEmptyCell
updateState $ \st -> st{ sInTableCell = False }
spaces
return cell'
where
-- The parsing of empty cells is important in LaTeX, especially when dealing
-- with multirow/multicolumn. See #6603.
parseEmptyCell = spaces $> emptyCell
parseSimpleCell = simpleCell <$> (plainify <$> blocks)
cellAlignment :: PandocMonad m => LP m Alignment
cellAlignment = skipMany (symbol '|') *> alignment <* skipMany (symbol '|')
where
alignment = do
c <- untoken <$> singleChar
return $ case c of
"l" -> AlignLeft
"r" -> AlignRight
"c" -> AlignCenter
"*" -> AlignDefault
_ -> AlignDefault
plainify :: Blocks -> Blocks
plainify bs = case toList bs of
[Para ils] -> plain (fromList ils)
_ -> bs
multirowCell :: PandocMonad m => LP m Blocks -> LP m Cell
multirowCell blocks = controlSeq "multirow" >> do
-- Full prototype for \multirow macro is:
-- \multirow[vpos]{nrows}[bigstruts]{width}[vmove]{text}
-- However, everything except `nrows` and `text` make
-- sense in the context of the Pandoc AST
_ <- optional $ symbol '[' *> cellAlignment <* symbol ']' -- vertical position
nrows <- fmap (fromMaybe 1 . safeRead . untokenize) braced
_ <- optional $ symbol '[' *> manyTill anyTok (symbol ']') -- bigstrut-related
_ <- symbol '{' *> manyTill anyTok (symbol '}') -- Cell width
_ <- optional $ symbol '[' *> manyTill anyTok (symbol ']') -- Length used for fine-tuning
content <- symbol '{' *> (plainify <$> blocks) <* symbol '}'
return $ cell AlignDefault (RowSpan nrows) (ColSpan 1) content
multicolumnCell :: PandocMonad m => LP m Blocks -> LP m Cell
multicolumnCell blocks = controlSeq "multicolumn" >> do
span' <- fmap (fromMaybe 1 . safeRead . untokenize) braced
alignment <- symbol '{' *> cellAlignment <* symbol '}'
let singleCell = do
content <- plainify <$> blocks
return $ cell alignment (RowSpan 1) (ColSpan span') content
-- Two possible contents: either a \multirow cell, or content.
-- E.g. \multicol{1}{c}{\multirow{2}{1em}{content}}
-- Note that a \multirow cell can be nested in a \multicolumn,
-- but not the other way around. See #6603
let nestedCell = do
(Cell _ _ (RowSpan rs) _ bs) <- multirowCell blocks
return $ cell
alignment
(RowSpan rs)
(ColSpan span')
(fromList bs)
symbol '{' *> (nestedCell <|> singleCell) <* symbol '}'
-- LaTeX tables are stored with empty cells underneath multirow cells
-- denoting the grid spaces taken up by them. More specifically, if a
-- cell spans m rows, then it will overwrite all the cells in the
-- columns it spans for (m-1) rows underneath it, requiring padding
-- cells in these places. These padding cells need to be removed for
-- proper table reading. See #6603.
--
-- These fixTable functions do not otherwise fix up malformed
-- input tables: that is left to the table builder.
fixTableHead :: TableHead -> TableHead
fixTableHead (TableHead attr rows) = TableHead attr rows'
where
rows' = fixTableRows rows
fixTableBody :: TableBody -> TableBody
fixTableBody (TableBody attr rhc th tb)
= TableBody attr rhc th' tb'
where
th' = fixTableRows th
tb' = fixTableRows tb
fixTableRows :: [Row] -> [Row]
fixTableRows = fixTableRows' $ repeat Nothing
where
fixTableRows' oldHang (Row attr cells : rs)
= let (newHang, cells') = fixTableRow oldHang cells
rs' = fixTableRows' newHang rs
in Row attr cells' : rs'
fixTableRows' _ [] = []
-- The overhang is represented as Just (relative cell dimensions) or
-- Nothing for an empty grid space.
fixTableRow :: [Maybe (ColSpan, RowSpan)] -> [Cell] -> ([Maybe (ColSpan, RowSpan)], [Cell])
fixTableRow oldHang cells
-- If there's overhang, drop cells until their total width meets the
-- width of the occupied grid spaces (or we run out)
| (n, prefHang, restHang) <- splitHang oldHang
, n > 0
= let cells' = dropToWidth getCellW n cells
(restHang', cells'') = fixTableRow restHang cells'
in (prefHang restHang', cells'')
-- Otherwise record the overhang of a pending cell and fix the rest
-- of the row
| c@(Cell _ _ h w _):cells' <- cells
= let h' = max 1 h
w' = max 1 w
oldHang' = dropToWidth getHangW w' oldHang
(newHang, cells'') = fixTableRow oldHang' cells'
in (toHang w' h' <> newHang, c : cells'')
| otherwise
= (oldHang, [])
where
getCellW (Cell _ _ _ w _) = w
getHangW = maybe 1 fst
getCS (ColSpan n) = n
toHang c r
| r > 1 = [Just (c, r)]
| otherwise = replicate (getCS c) Nothing
-- Take the prefix of the overhang list representing filled grid
-- spaces. Also return the remainder and the length of this prefix.
splitHang = splitHang' 0 id
splitHang' !n l (Just (c, r):xs)
= splitHang' (n + c) (l . (toHang c (r-1) ++)) xs
splitHang' n l xs = (n, l, xs)
-- Drop list items until the total width of the dropped items
-- exceeds the passed width.
dropToWidth _ n l | n < 1 = l
dropToWidth wproj n (c:cs) = dropToWidth wproj (n - wproj c) cs
dropToWidth _ _ [] = []
simpTable :: PandocMonad m
=> LP m Blocks
-> LP m Inlines
-> Text
-> Bool
-> LP m Blocks
simpTable blocks inline envname hasWidthParameter = try $ do
when hasWidthParameter $ () <$ tokWith inline
skipopts
colspecs <- parseAligns
let (aligns, widths, prefsufs) = unzip3 colspecs
optional $ controlSeq "caption" *> setCaption inline
spaces
optional label
spaces
optional lbreak
spaces
skipMany hline
spaces
header' <- option [] . try . fmap (:[]) $
parseTableRow blocks inline envname prefsufs <*
lbreak <* many1 hline
spaces
rows <- sepEndBy (parseTableRow blocks inline envname prefsufs)
(lbreak <* optional (skipMany hline))
spaces
optional $ controlSeq "caption" *> setCaption inline
spaces
optional label
spaces
optional lbreak
spaces
lookAhead $ controlSeq "end" -- make sure we're at end
let th = fixTableHead $ TableHead nullAttr header'
let tbs = [fixTableBody $ TableBody nullAttr 0 [] rows]
let tf = TableFoot nullAttr []
return $ table emptyCaption (zip aligns widths) th tbs tf
addTableCaption :: PandocMonad m => Blocks -> LP m Blocks
addTableCaption = walkM go
where go (Table attr c spec th tb tf) = do
st <- getState
let mblabel = sLastLabel st
capt <- case (sCaption st, mblabel) of
(Just ils, Nothing) -> return $ caption Nothing (plain ils)
(Just ils, Just lab) -> do
num <- getNextNumber sLastTableNum
setState
st{ sLastTableNum = num
, sLabels = M.insert lab
[Str (renderDottedNum num)]
(sLabels st) }
return $ caption Nothing (plain ils) -- add number??
(Nothing, _) -> return c
let attr' = case (attr, mblabel) of
((_,classes,kvs), Just ident) ->
(ident,classes,kvs)
_ -> attr
return $ addAttrDiv attr' $ Table nullAttr capt spec th tb tf
go x = return x
-- TODO: For now we add a Div to contain table attributes, since
-- most writers don't do anything yet with attributes on Table.
-- This can be removed when that changes.
addAttrDiv :: Attr -> Block -> Block
addAttrDiv ("",[],[]) b = b
addAttrDiv attr b = Div attr [b]