#if __GLASGOW_HASKELL__ >= 701
{-# LANGUAGE Safe #-}
#endif

-----------------------------------------------------------------------------
-- |
-- Module      :  Text.XHtml.BlockTable
-- Copyright   :  (c) Andy Gill, and the Oregon Graduate Institute of 
--                    Science and Technology, 1999-2001
-- License     :  BSD-style (see the file LICENSE)
-- Maintainer  :  Chris Dornan <chris@chrisdornan.com>
-- Stability   :  Stable
-- Portability :  Portable
--
-- An XHTML combinator library
--
-- These combinators can be used to build formated 2D tables.
-- The specific target usage is for HTML table generation.
-----------------------------------------------------------------------------

{-
   Examples of use:

  	> table1 :: BlockTable String
  	> table1 = single "Hello"	+-----+
					|Hello|
	  This is a 1x1 cell		+-----+
	  Note: single has type
	 
		single :: a -> BlockTable a
	
	  So the cells can contain anything.
	
	> table2 :: BlockTable String
	> table2 = single "World"	+-----+
					|World|
					+-----+


	> table3 :: BlockTable String
	> table3 = table1 %-% table2	+-----%-----+
					|Hello%World|
	 % is used to indicate		+-----%-----+
	 the join edge between
	 the two Tables.  

	> table4 :: BlockTable String
	> table4 = table3 %/% table2	+-----+-----+
					|Hello|World|
	  Notice the padding on the	%%%%%%%%%%%%%
	  smaller (bottom) cell to	|World      |
	  force the table to be a	+-----------+
	  rectangle.

	> table5 :: BlockTable String
	> table5 = table1 %-% table4	+-----%-----+-----+
					|Hello%Hello|World|
	  Notice the padding on the	|     %-----+-----+
	  leftmost cell, again to	|     %World      |
	  force the table to be a	+-----%-----------+
	  rectangle.
 
   Now the table can be rendered with processTable, for example:
	Main> processTable table5
	[[("Hello",(1,2)),
	  ("Hello",(1,1)),
	  ("World",(1,1))],
	 [("World",(2,1))]] :: [[([Char],(Int,Int))]]
	Main> 
-}
module Text.XHtml.BlockTable (
      -- * Datatypes
      BlockTable,
      -- * Contruction Functions
      single,
      above,
      beside,
      -- * Investigation Functions
      getMatrix,
      showsTable,
      showTable,
      ) where

infixr 4 `beside`
infixr 3 `above`



-- 
-- * Construction Functions
--

-- Perhaps one day I'll write the Show instance
-- to show boxes aka the above ascii renditions.

instance (Show a) => Show (BlockTable a) where
      showsPrec _ = showsTable

type TableI a = [[(a,(Int,Int))]] -> [[(a,(Int,Int))]]

data BlockTable a = Table (Int -> Int -> TableI a) Int Int


-- | Creates a (1x1) table entry
single :: a -> BlockTable a
single a = Table (\ x y z -> [(a,(x+1,y+1))] : z) 1 1


-- | Composes tables vertically.
above  :: BlockTable a -> BlockTable a -> BlockTable a

-- | Composes tables horizontally.
beside :: BlockTable a -> BlockTable a -> BlockTable a

t1 `above` t2 = trans (combine (trans t1) (trans t2) (.))

t1 `beside` t2 = combine t1 t2 (\ lst1 lst2 r ->
    let
      -- Note this depends on the fact that
      -- that the result has the same number
      -- of lines as the y dimention; one list
      -- per line. This is not true in general
      -- but is always true for these combinators.
      -- I should assert this!
      -- I should even prove this.
      beside' (x:xs) (y:ys) = (x ++ y) : beside' xs ys
      beside' (x:xs) []     = x        : xs ++ r
      beside' []     (y:ys) = y        : ys ++ r
      beside' []     []     =                  r
    in
      beside' (lst1 []) (lst2 []))

-- | trans flips (transposes) over the x and y axis of
-- the table. It is only used internally, and typically
-- in pairs, ie. (flip ... munge ... (un)flip).
trans :: BlockTable a -> BlockTable a
trans (Table f1 x1 y1) = Table (flip f1) y1 x1

combine :: BlockTable a 
      -> BlockTable b 
      -> (TableI a -> TableI b -> TableI c) 
      -> BlockTable c
combine (Table f1 x1 y1) (Table f2 x2 y2) comb = Table new_fn (x1+x2) max_y
    where
      max_y = max y1 y2
      new_fn x y =
         case compare y1 y2 of
          EQ -> comb (f1 0 y)             (f2 x y)
          GT -> comb (f1 0 y)             (f2 x (y + y1 - y2))
          LT -> comb (f1 0 (y + y2 - y1)) (f2 x y)

-- 
-- * Investigation Functions
--

-- | This is the other thing you can do with a Table;
-- turn it into a 2D list, tagged with the (x,y)
-- sizes of each cell in the table.
getMatrix :: BlockTable a -> [[(a,(Int,Int))]]
getMatrix (Table r _ _) = r 0 0 []

-- You can also look at a table

showsTable :: (Show a) => BlockTable a -> ShowS
showsTable table = shows (getMatrix table)

showTable :: (Show a) => BlockTable a -> String
showTable table = showsTable table ""