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5242b8d5fd
Recent changes (mainly eliminating of built-in backtracking user state) require some changes in the tests.
159 lines
5.4 KiB
Haskell
159 lines
5.4 KiB
Haskell
-- -*- Mode: Haskell; -*-
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--
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-- QuickCheck tests for Megaparsec's expression parsers.
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--
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-- Copyright © 2015 Megaparsec contributors
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--
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-- Redistribution and use in source and binary forms, with or without
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-- modification, are permitted provided that the following conditions are
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-- met:
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--
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-- * Redistributions of source code must retain the above copyright notice,
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-- this list of conditions and the following disclaimer.
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--
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-- * Redistributions in binary form must reproduce the above copyright
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-- notice, this list of conditions and the following disclaimer in the
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-- documentation and/or other materials provided with the distribution.
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--
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-- This software is provided by the copyright holders "as is" and any
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-- express or implied warranties, including, but not limited to, the implied
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-- warranties of merchantability and fitness for a particular purpose are
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-- disclaimed. In no event shall the copyright holders be liable for any
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-- direct, indirect, incidental, special, exemplary, or consequential
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-- damages (including, but not limited to, procurement of substitute goods
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-- or services; loss of use, data, or profits; or business interruption)
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-- however caused and on any theory of liability, whether in contract,
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-- strict liability, or tort (including negligence or otherwise) arising in
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-- any way out of the use of this software, even if advised of the
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-- possibility of such damage.
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module Expr (tests) where
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import Control.Applicative (some, (<|>))
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import Data.Bool (bool)
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import Test.Framework
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import Test.Framework.Providers.QuickCheck2 (testProperty)
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import Test.QuickCheck
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import Text.Megaparsec.Char
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import Text.Megaparsec.Combinator
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import Text.Megaparsec.Expr
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import Text.Megaparsec.Prim
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import Util
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tests :: Test
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tests = testGroup "Expression parsers"
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[ testProperty "correctness of expression parser" prop_correctness ]
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-- Algebraic structures to build abstract syntax tree of our expression.
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data Node
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= Val Integer -- ^ literal value
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| Neg Node -- ^ negation (prefix unary)
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| Fac Node -- ^ factorial (postfix unary)
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| Mod Node Node -- ^ modulo
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| Sum Node Node -- ^ summation (addition)
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| Sub Node Node -- ^ subtraction
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| Pro Node Node -- ^ product
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| Div Node Node -- ^ division
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| Exp Node Node -- ^ exponentiation
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deriving (Eq, Show)
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instance Enum Node where
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fromEnum (Val _) = 0
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fromEnum (Neg _) = 0
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fromEnum (Fac _) = 0
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fromEnum (Mod _ _) = 0
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fromEnum (Exp _ _) = 1
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fromEnum (Pro _ _) = 2
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fromEnum (Div _ _) = 2
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fromEnum (Sum _ _) = 3
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fromEnum (Sub _ _) = 3
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toEnum _ = error "Oops!"
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instance Ord Node where
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x `compare` y = fromEnum x `compare` fromEnum y
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showNode :: Node -> String
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showNode (Val x) = show x
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showNode n@(Neg x) = "-" ++ showGT n x
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showNode n@(Fac x) = showGT n x ++ "!"
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showNode n@(Mod x y) = showGE n x ++ " % " ++ showGE n y
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showNode n@(Sum x y) = showGT n x ++ " + " ++ showGE n y
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showNode n@(Sub x y) = showGT n x ++ " - " ++ showGE n y
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showNode n@(Pro x y) = showGT n x ++ " * " ++ showGE n y
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showNode n@(Div x y) = showGT n x ++ " / " ++ showGE n y
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showNode n@(Exp x y) = showGE n x ++ " ^ " ++ showGT n y
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showGT :: Node -> Node -> String
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showGT parent node = bool showNode showCmp (node > parent) node
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showGE :: Node -> Node -> String
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showGE parent node = bool showNode showCmp (node >= parent) node
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showCmp :: Node -> String
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showCmp node = bool inParens showNode (fromEnum node == 0) node
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inParens :: Node -> String
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inParens x = "(" ++ showNode x ++ ")"
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instance Arbitrary Node where
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arbitrary = sized arbitraryN0
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arbitraryN0 :: Int -> Gen Node
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arbitraryN0 n = frequency [ (1, Mod <$> leaf <*> leaf)
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, (9, arbitraryN1 n) ]
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where leaf = arbitraryN1 (n `div` 2)
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arbitraryN1 :: Int -> Gen Node
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arbitraryN1 n =
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frequency [ (1, Neg <$> arbitraryN2 n)
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, (1, Fac <$> arbitraryN2 n)
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, (7, arbitraryN2 n)]
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arbitraryN2 :: Int -> Gen Node
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arbitraryN2 0 = Val . getNonNegative <$> arbitrary
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arbitraryN2 n = elements [Sum,Sub,Pro,Div,Exp] <*> leaf <*> leaf
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where leaf = arbitraryN0 (n `div` 2)
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-- Some helpers put here since we don't want to depend on
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-- "Text.Megaparsec.Lexer".
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lexeme :: MonadParsec s m Char => m a -> m a
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lexeme p = p <* hidden space
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symbol :: MonadParsec s m Char => String -> m String
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symbol = lexeme . string
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parens :: MonadParsec s m Char => m a -> m a
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parens = between (symbol "(") (symbol ")")
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integer :: MonadParsec s m Char => m Integer
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integer = lexeme (read <$> some digitChar <?> "integer")
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-- Here we use table of operators that makes use of all features of
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-- 'makeExprParser'. Then we generate abstract syntax tree (AST) of complex
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-- but valid expressions and render them to get their textual
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-- representation.
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expr :: MonadParsec s m Char => m Node
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expr = makeExprParser term table <?> "expression"
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term :: MonadParsec s m Char => m Node
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term = parens expr <|> (Val <$> integer) <?> "term"
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table :: MonadParsec s m Char => [[Operator m Node]]
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table = [ [ Prefix (symbol "-" *> pure Neg)
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, Postfix (symbol "!" *> pure Fac)
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, InfixN (symbol "%" *> pure Mod) ]
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, [ InfixR (symbol "^" *> pure Exp) ]
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, [ InfixL (symbol "*" *> pure Pro)
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, InfixL (symbol "/" *> pure Div) ]
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, [ InfixL (symbol "+" *> pure Sum)
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, InfixL (symbol "-" *> pure Sub)] ]
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prop_correctness :: Node -> Property
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prop_correctness node = checkParser expr (Right node) (showNode node)
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