~alcinnz/haskell-stylist

ref: 9da41d4e978f1a1ba403884088c55f3e22f856f4 haskell-stylist/src/Data/CSS/Preprocessor/Conditions/Expr.hs -rw-r--r-- 3.6 KiB
9da41d4e — Adrian Cochrane Request @import'd styles concurrently. 4 years ago
                                                                                
b8daf07f Adrian Cochrane
04976d4d Adrian Cochrane
b8daf07f Adrian Cochrane
04976d4d Adrian Cochrane
b8daf07f Adrian Cochrane
04976d4d Adrian Cochrane
b8daf07f Adrian Cochrane
d5c5ddeb Adrian Cochrane
b8daf07f Adrian Cochrane
04976d4d Adrian Cochrane
b8daf07f Adrian Cochrane
d5c5ddeb Adrian Cochrane
b8daf07f Adrian Cochrane
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
{-# 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.