~jaro/balkon

ref: 1555a8cc7b5b6ad8c7f365564876dc6f5649f19c balkon/src/Data/Text/ParagraphLayout/Internal/Plain.hs -rw-r--r-- 14.1 KiB
1555a8ccJaro Move non-public modules into Internal namespace. 1 year, 8 months ago
                                                                                
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-- | Shaping for a paragraph of plain, unidirectional text using a single font.
--
-- The input text must be encoded as UTF-8 in a contiguous byte array.
--
-- Positions and distances are represented as 32-bit integers. Their unit must
-- be defined by the caller, who must calculate the desired dimensions of the
-- EM square of the input font and set them using @hb_font_set_scale()@. For
-- example, if @1em = 20px@, if the output pixels are square, and if the output
-- coordinates are in 1/64ths of a pixel, you should set both the @x_scale@ and
-- the @y_scale@ to @1280@.
module Data.Text.ParagraphLayout.Internal.Plain
    (Paragraph(..)
    ,ParagraphLayout(..)
    ,ParagraphOptions(..)
    ,SpanLayout(..)
    ,layoutPlain
    )
where

import Data.Int (Int32)
import Data.List (mapAccumL)
import Data.List.NonEmpty (NonEmpty((:|)))
import Data.Maybe (catMaybes, fromMaybe, listToMaybe)
import qualified Data.Text as Text
import Data.Text.Array (Array)
import Data.Text.Foreign (lengthWord8)
import Data.Text.Glyphize
    (Buffer(..)
    ,ContentType(ContentTypeUnicode)
    ,Font
    ,FontExtents(..)
    ,GlyphInfo
    ,GlyphPos(x_advance)
    ,defaultBuffer
    ,fontExtentsForDir
    ,shape
    )
import Data.Text.ICU (LocaleName(Locale), breakLine)
import qualified Data.Text.ICU as BreakStatus (Line)
import Data.Text.Internal (Text(Text))
import qualified Data.Text.Lazy as Lazy

import Data.Text.ParagraphLayout.Internal.Break
import Data.Text.ParagraphLayout.Internal.Fragment
import Data.Text.ParagraphLayout.Internal.LineHeight
import qualified Data.Text.ParagraphLayout.Internal.ProtoFragment as PF
import qualified Data.Text.ParagraphLayout.Internal.ResolvedSpan as RS
import Data.Text.ParagraphLayout.Internal.Run
import Data.Text.ParagraphLayout.Internal.Span
import Data.Text.ParagraphLayout.Internal.TextContainer
import Data.Text.ParagraphLayout.Rect

-- | Text to be laid out as a paragraph.
--
-- May be divided into any number of neighbouring spans, each of which will
-- have its own layout rectangle(s) calculated.
data Paragraph = Paragraph

    Array
    -- ^ A byte array containing the whole text to be laid out, in UTF-8.

    Int
    -- ^ Byte offset of the first span.
    -- Any characters preceding this offset will not be shaped, but may still
    -- be used to influence the shape of neighbouring characters.

    [Span]
    -- ^ Parts of the text to be laid out, in logical order.
    -- The offset plus total length of all spans must not exceed array bounds.
    -- Any characters following the last span will not be shaped, but may still
    -- be used to influence the shape of neighbouring characters.

    ParagraphOptions
    -- ^ Properties applying to the paragraph as a whole.

data ParagraphOptions = ParagraphOptions
    { paragraphFont :: Font
    , paragraphLineHeight :: LineHeight
    , paragraphMaxWidth :: Int32
    }

-- | The resulting layout of the whole paragraph.
data ParagraphLayout = ParagraphLayout
    { paragraphRect :: Rect Int32
    -- ^ The containing block (CSS3).
    , spanLayouts :: [SpanLayout]
    }
    deriving (Eq, Read, Show)

-- | The resulting layout of each span, which may include multiple fragments if
-- broken over multiple lines.
data SpanLayout = SpanLayout [Fragment]
    deriving (Eq, Read, Show)

-- | Wrapper for temporarily mapping the relationship to a `Span`.
data WithSpan a = WithSpan RS.ResolvedSpan a

instance Functor WithSpan where
    fmap f (WithSpan s a) = WithSpan s (f a)

instance TextContainer a => TextContainer (WithSpan a) where
    getText (WithSpan _ c) = getText c

instance SeparableTextContainer a => SeparableTextContainer (WithSpan a) where
    splitTextAt8 n (WithSpan rs c) = (WithSpan rs c1, WithSpan rs c2)
        where (c1, c2) = splitTextAt8 n c

splitBySpanIndex :: [WithSpan a] -> [[a]]
splitBySpanIndex xs = [getBySpanIndex i xs | i <- [0..]]

getBySpanIndex :: Int -> [WithSpan a] -> [a]
getBySpanIndex idx xs = map contents $ filter matchingIndex $ xs
    where
        matchingIndex (WithSpan rs _) = (RS.spanIndex rs) == idx
        contents (WithSpan _ x) = x

spanRects :: SpanLayout -> [Rect Int32]
spanRects (SpanLayout frags) = map fragmentRect frags

base :: (Num a) => Rect a
base = Rect 0 0 0 0

containRects :: (Ord a, Num a) => [Rect a] -> Rect a
containRects = foldr union base

-- | Interface for basic plain text layout.
--
-- The entire paragraph will be assumed to have the same text direction and
-- will be shaped using a single font, starting from the left for LTR text or
-- from the right for RTL text.
layoutPlain :: Paragraph -> ParagraphLayout
layoutPlain p@(Paragraph _ _ _ opts) = ParagraphLayout pRect sls
    where
        pRect = containRects $ concat $ map spanRects sls
        sls = map SpanLayout fragsBySpan
        fragsBySpan = take (length spans) $ splitBySpanIndex frags
        frags = layoutAndAlignLines maxWidth $ spansToRunsWrapped spans
        maxWidth = paragraphMaxWidth opts
        spans = resolveSpans p

-- | Split a number of spans into a flat array of runs and add a wrapper
-- so that each run can be traced back to its originating span.
spansToRunsWrapped :: [RS.ResolvedSpan] -> [WithSpan Run]
spansToRunsWrapped ss = concat $ map spanToRunsWrapped ss

-- | Split a span into runs and add a wrapper
-- so that each run can be traced back to its originating span.
spanToRunsWrapped :: RS.ResolvedSpan -> [WithSpan Run]
spanToRunsWrapped s = map (WithSpan s) (spanToRuns s)

-- | Create a multi-line layout from the given runs, splitting them as
-- necessary to fit within the requested line width.
--
-- The output is a flat list of fragments positioned in both dimensions.
layoutAndAlignLines :: Int32 -> [WithSpan Run] -> [WithSpan Fragment]
layoutAndAlignLines maxWidth runs = frags
    where
        frags = concat fragsInLines
        (_, fragsInLines) = mapAccumL alignLineH originY protoFragsInLines
        protoFragsInLines = layoutLines maxWidth runs
        originY = 0

-- | Create a multi-line layout from the given runs, splitting them as
-- necessary to fit within the requested line width.
--
-- The output is a two-dimensional list of fragments positioned along the
-- horizontal axis.
layoutLines :: Int32 -> [WithSpan Run] -> [[WithSpan PF.ProtoFragment]]
layoutLines maxWidth runs
    | null rest
        -- Everything fits. We are done.
        = fitting : []
    | null fitting
        -- Nothing fits. We must resolve this by overflowing.
        = overflowing : []
    | otherwise
        -- Something fits, the rest goes on the next line.
        = fitting : layoutLines maxWidth rest
    where
        (fitting, rest) = tryAddRunsH maxWidth originX runs
        overflowing = addRunsH originX runs
        originX = 0

-- TODO: Allow a run across multiple spans (e.g. if they only differ by colour).

-- | Align all the given horizontal fragments vertically on the same line,
-- using `originY` as its top edge, and return the bottom edge for continuation.
--
-- Glyphs will be aligned by their ascent line, similar to the behaviour of
-- @vertical-align: top@ in CSS.
--
-- TODO: For rich text, allow other types of vertical alignment.
alignLineH :: Int32 -> [WithSpan PF.ProtoFragment] ->
    (Int32, [WithSpan Fragment])
alignLineH originY pfs = (nextY, frags)
    where
        nextY = maximum $ map y_min rects
        rects = map (\(WithSpan _ r) -> fragmentRect r) frags
        frags = map (alignFragmentH originY) pfs

-- | Align the given horizontal fragment vertically on a line,
-- using `originY` as its top edge.
alignFragmentH :: Int32 -> WithSpan PF.ProtoFragment -> WithSpan Fragment
alignFragmentH originY (WithSpan rs pf) =
    WithSpan rs (Fragment rect (penX, penY) (PF.glyphs pf))
    where
        rect = Rect (PF.offset pf) originY (PF.advance pf) (-lineHeight)
        penX = 0
        penY = descent + leading `div` 2 - lineHeight
        lineHeight = case RS.spanLineHeight rs of
            Normal -> normalLineHeight
            Absolute h -> h
        leading = lineHeight - normalLineHeight
        normalLineHeight = ascent + descent
        ascent = ascender extents
        descent = - descender extents
        extents = fontExtentsForDir font (PF.direction pf)
        font = RS.spanFont rs

-- | Like `addRunsH`, but break the input runs as necessary to prevent
-- overflowing the maximum line width,
-- and return the remaining runs to be placed on other lines.
tryAddRunsH :: Int32 -> Int32 -> [WithSpan Run] ->
    ([WithSpan PF.ProtoFragment], [WithSpan Run])
tryAddRunsH maxWidth currentX runs =
    fromMaybe lastResortSplit $ listToMaybe validSplits
    where
        lastResortSplit = do
            let (runs1, runs2) = splitTextsAt8 1 runs
            let (_, pfs) = mapAccumL addRunH currentX runs1
            (pfs, runs2)
        applySplit (runs1, runs2) = do
            let (nextX, pfs) = mapAccumL addRunH currentX runs1
            if abs nextX <= maxWidth
                then Just (pfs, runs2)
                else Nothing
        validSplits = catMaybes $ map applySplit splits
        splits = noSplit : (filter hasContent $ breakSplits [] (reverse runs))
        noSplit = (runs, [])
        hasContent = not . null . fst

-- | Recursive function for finding all possible ways to split a list of runs
-- into two on a valid line-breaking boundary, including the start of the first
-- run and excluding the end of the last run.
--
-- The first input list is the suffix consisting of runs that have already been
-- considered for breaking. These will be appended to the output suffix as they
-- are.
--
-- The second input list is the prefix consisting of runs to be considered for
-- breaking, in reverse order.
--
-- The results in the form (prefix, suffix) will be ordered from the longest
-- prefix to shortest.
breakSplits :: [WithSpan Run] -> [WithSpan Run] ->
    [([WithSpan Run], [WithSpan Run])]
breakSplits _ [] = []
breakSplits closed (x:xs) = splits ++ breakSplits (x:closed) xs
    where
        splits = map mapFunc $ runLineSplits x
        mapFunc ((x1, x2), _) =
            (reverse $ collapse $ x1 :| xs, collapse $ x2 :| closed)

-- | If the first run is empty, remove it.
collapse :: NonEmpty (WithSpan Run) -> [WithSpan Run]
collapse (x :| xs)
    | Text.null (getText x) = xs
    | otherwise = x:xs

-- | Calculate layout for multiple runs on the same line and
-- arrange them in one horizontal direction starting from the given x_offset.
addRunsH :: Int32 -> [WithSpan Run] -> [WithSpan PF.ProtoFragment]
addRunsH currentX runs = snd $ mapAccumL addRunH currentX runs

-- | Calculate layout for the given run,
-- place the generated fragment horizontally at the given x_offset in a line,
-- and return the final x_offset for continuation.
addRunH :: Int32 -> WithSpan Run -> (Int32, WithSpan PF.ProtoFragment)
addRunH currentX run = (nextX, WithSpan rs pf)
    where
        WithSpan rs pf = layoutRun currentX run
        nextX = currentX + PF.advance pf

-- | Calculate layout for the given run and position it in a line.
layoutRun :: Int32 -> WithSpan Run -> WithSpan PF.ProtoFragment
layoutRun originX (WithSpan rs run) = WithSpan rs pf
    where
        pf = PF.ProtoFragment dir originX totalX glyphs
        glyphs = shapeRun (WithSpan rs run)
        positions = map snd glyphs
        totalX = sum $ map x_advance positions
        dir = runDirection run

-- | Calculate layout for the given run independently of its position.
shapeRun :: WithSpan Run -> [(GlyphInfo, GlyphPos)]
shapeRun (WithSpan rs run) = shape font buffer features
    where
        font = RS.spanFont rs
        -- TODO: Set beginsText / endsText.
        buffer = defaultBuffer
            { text = Lazy.fromStrict $ runText run
            , contentType = Just ContentTypeUnicode
            , direction = runDirection run
            , script = runScript run
            , language = Just $ RS.spanLanguage rs
            }
        features = []

resolveSpans :: Paragraph -> [RS.ResolvedSpan]
resolveSpans p@(Paragraph arr off spans opts) = do
    let (end, textsAndMarks) = cutsAndMarks arr off spans
    let indexes = [0..]

    (s, (o, t), i) <- zip3 spans textsAndMarks indexes
    let lang = spanLanguage s
    let breaks = paragraphLineBreaks p end lang
    return RS.ResolvedSpan
        { RS.spanIndex = i
        , RS.spanOffsetInParagraph = o - off
        , RS.spanText = t
        , RS.spanFont = paragraphFont opts
        , RS.spanLineHeight = paragraphLineHeight opts
        , RS.spanLanguage = lang
        , RS.spanLineBreaks = subOffsetsDesc (o - off) breaks
        }

paragraphLineBreaks :: Paragraph -> Int -> String -> [(Int, BreakStatus.Line)]
paragraphLineBreaks (Paragraph arr off _ _) end lang =
    breaksDesc (breakLine (localeFromLanguage lang)) paragraphText
    where
        paragraphText = Text arr off (end - off)

-- | Split the given run at every valid line break position.
runLineSplits :: WithSpan Run ->
    [((WithSpan Run, WithSpan Run), BreakStatus.Line)]
runLineSplits r = map split $ runLineBreaks r
    where
        split (i, status) = (splitTextAt8 i r, status)

runLineBreaks :: WithSpan Run -> [(Int, BreakStatus.Line)]
runLineBreaks (WithSpan rs run) = dropWhile (not . valid) $
    subOffsetsDesc (runOffsetInSpan run) $ RS.spanLineBreaks rs
    where
        valid (off, _) = off < runLength
        runLength = lengthWord8 $ getText run

-- TODO: Identify and correct for differences between the two.
localeFromLanguage :: String -> LocaleName
localeFromLanguage x = Locale x

-- | Given an underlying `Array`, an initial offset, and a list of consecutive
-- `Span`s, produce a list of `Text`s corresponding to the given spans, as well
-- as the offset of the start of each `Text` and the end of the last `Text`.
--
-- TODO: Consider adding checks for array bounds.
cutsAndMarks :: Array -> Int -> [Span] -> (Int, [(Int, Text)])
cutsAndMarks arr initialOffset spans =
    mapAccumL (cutAndMark arr) initialOffset spans

-- | Like `cut`, but also include the starting offset in the output.
cutAndMark :: Array -> Int -> Span -> (Int, (Int, Text))
cutAndMark arr off s = (end, (off, t))
    where
        (end, t) = cut arr off s

-- | Produce a `Text`, defined by an initial offset and a `Span`, out of the
-- underlying `Array`.
cut :: Array -> Int -> Span -> (Int, Text)
cut arr off s = (end, t)
    where
        len = spanLength s
        end = off + len
        t = Text arr off len