{-# LANGUAGE OverloadedStrings #-} module Data.CSS.Preprocessor.Conditions.Expr( Expr, Op(..), parse, parse', eval, Datum(..) ) where import Data.CSS.Syntax.Tokens(Token(..)) import Data.Text.Internal (Text(..)) import Data.Text (stripPrefix) type Expr = [Op] data Op = And | Or | Not | Var Text | Tok Token | MkRatio | Func Text [Token] | Less | LessEq | Equal | Greater | GreaterEq deriving (Show, Eq) parse :: Token -> [Token] -> (Expr, [Token]) parse end toks = let (toks', rest) = break (== end) toks in (parse' toks' [], rest) -------- ---- Shunting Yard parser -------- parse' :: [Token] -> [(Op, Int)] -> Expr parse' (Whitespace:toks) ops = parse' toks ops parse' (Comma:toks) ops = pushOp toks Or 10 ops parse' (Ident "not":toks) ops = pushOp toks Not 20 ops parse' (Function "not":toks) ops = pushOp toks Not 0 ops parse' (Ident "only":toks) ops = parse' toks ops parse' (Ident "and":toks) ops = pushOp toks And 30 ops parse' (Ident "or":toks) ops = pushOp toks Or 30 ops parse' (Delim '<':Delim '=':toks) ops = pushOp toks LessEq 40 ops parse' (Delim '<':toks) ops = pushOp toks Less 40 ops parse' (Delim '>':Delim '=':toks) ops = pushOp toks GreaterEq 40 ops parse' (Delim '>':toks) ops = pushOp toks Greater 40 ops parse' (Colon:tok:toks) ops = Tok tok : pushOp toks Equal 40 ops parse' (Delim '/':toks) ops = pushOp toks MkRatio 50 ops parse' (LeftParen:toks) ops = pushOp toks (Var ")") 0 ops parse' (RightParen:toks) ((Var ")", 0):ops) = parse' toks ops parse' (RightParen:toks) ((Not, 0):ops) = Not : parse' toks ops -- Functional not syntax parse' toks@(RightParen:_) ((op, _):ops) = op : parse' toks ops parse' (RightParen:_) [] = [] -- Invalid! parse' (Ident var:toks) ops@((peek, _):ops') -- First, fix up various range syntaxes. | peek `elem` [Less, LessEq, Greater, GreaterEq] = -- Chained conditions Var var : peek : Var var : parse' toks ops' | Just var' <- stripPrefix "max-" var = Var var' : pushOp toks LessEq 1000 ops | Just var' <- stripPrefix "min-" var = Var var' : pushOp toks GreaterEq 1000 ops | otherwise = Var var : parse' toks ops parse' (tok:toks) ops = Tok tok : parse' toks ops parse' [] ops = [op | (op, _) <- ops] pushOp :: [Token] -> Op -> Int -> [(Op, Int)] -> Expr pushOp toks op b ((peek, b'):ops') | b' >= b = peek : pushOp toks op b ops' pushOp toks op b ops = parse' toks ((op, b):ops) -------- ---- Shunting Yard Evaluator -------- data Datum = B Bool | N Float | Ratio Float Float deriving Eq eval :: (Text -> Datum) -> (Token -> Datum) -> Expr -> Bool eval = eval' [] eval' :: [Datum] -> (Text -> Datum) -> (Token -> Datum) -> Expr -> Bool eval' (B y:B x:stack) v t (And:ops) = eval' (B (x && y):stack) v t ops eval' (B y:B x:stack) v t (Or:ops) = eval' (B (x || y):stack) v t ops eval' (B x:stack) v t (Not:ops) = eval' (B (not x):stack) v t ops eval' stack v t (Var name:ops) = eval' (v name:stack) v t ops -- Have tokens lower to variables, to make things easier for the callee. eval' stack v t (Tok tok:ops) | t tok /= B False = eval' (t tok:stack) v t ops eval' stack v t (Tok (Ident name):ops) = eval' (v name:stack) v t ops -- TODO: How should I handle ratios? eval' (N y:N x:stack) v t (MkRatio:ops) = eval' (Ratio x y:stack) v t ops eval' (N y:N x:stack) v t (Less:ops) = eval' (B (x < y):stack) v t ops eval' (N y:N x:stack) v t (LessEq:ops) = eval' (B (x <= y):stack) v t ops eval' (y:x:stack) v t (Equal:ops) = eval' (B (x == y):stack) v t ops eval' (N y:N x:stack) v t (Greater:ops) = eval' (B (x > y):stack) v t ops eval' (N y:N x:stack) v t (GreaterEq:ops) = eval' (B (x >= y):stack) v t ops eval' (B ret:_) _ _ [] = ret eval' [] _ _ [] = True -- Special case eval' _ _ _ _ = False -- Error handling fallback.