garnet/haskell/Pre.hs

{-# LANGUAGE PackageImports #-}
{-# LANGUAGE TypeFamilies #-}

module Pre (
    module BasePrelude,
    module Control.Applicative,
    module Control.Monad,
    module Control.Monad.Loops,
    module Control.Monad.State,
    module Data.Bifunctor,
    module Data.Bool,
    module Data.Char,
    module Data.Foldable,
    module Data.Foldable1,
    module Data.Function,
    module Data.Functor,
    module Data.List,
    module Data.List.Extra,
    module Data.List.NonEmpty,
    module Data.Maybe,
    module Data.Ord,
    module Data.Sequence,
    module Data.Stream.Infinite,
    module Data.Text,
    module Data.Text.Encoding,
    module Data.Traversable,
    module Data.Tuple.Extra,
    module Data.Void,
    module Data.Word,
    module Linear,
    module Safe,
    module Text.Megaparsec,
    module Text.Megaparsec.Char,
    module Text.Megaparsec.Char.Lexer,
    Puzzle (..),
    digit,
    digitsToInt,
    listIndex,
    allUnorderedPairs,
    adjacentPairs,
    sortPair,
    HList (..),
    hlistLength,
    HListF (..),
    foldHListF,
    foldHListF0,
    mapHListF,
    hlistfLength,
    (/\),
    (/\\),
    nil,
    Fanout (..),
    TestTree (..),
    TestName,
    mkTestName,
    getTestTree,
    runTests,
    assertEqual,
    assert,
    golden,
)
where

import "base" Prelude as BasePrelude hiding (
    foldl1,
    foldr1,
    head,
    init,
    last,
    maximum,
    minimum,
    tail,
    unzip,
    (!!),
 )

import Control.Applicative
import Control.Exception (SomeException)
import Control.Monad
import Control.Monad.Catch (MonadCatch, try)
import Control.Monad.Loops
import Control.Monad.State
import Data.Bifunctor
import Data.Bool
import Data.Char
import Data.Foldable hiding (foldl1, foldr1, maximum, maximumBy, minimum, minimumBy)
import Data.Foldable1
import Data.Function
import Data.Functor
import Data.Functor.Contravariant
import Data.Kind (Type)
import Data.List (List, sortOn, transpose)
import Data.List.Extra (dropEnd, enumerate, firstJust, notNull, splitOn)
import Data.List.NonEmpty (NonEmpty ((:|)), nonEmpty, some1, tail, tails)
import Data.Maybe
import Data.Ord
import Data.Sequence (Seq)
import Data.Stream.Infinite (Stream ((:>)))
import Data.String (IsString)
import Data.Text (Text)
import Data.Text qualified as T
import Data.Text.Encoding (encodeUtf8)
import Data.Text.IO qualified as T
import Data.Traversable
import Data.Tree
import Data.Tuple.Extra ((&&&))
import Data.Void
import Data.Word
import Linear (V2 (..))
import Safe
import Text.Megaparsec hiding (Pos, State, Stream, many, some)
import Text.Megaparsec.Char
import Text.Megaparsec.Char.Lexer (decimal)

data Puzzle = forall input outputs. Puzzle
    { number :: Word
    , parser :: Bool -> Parsec Void Text input
    , parts :: PuzzleParts input outputs
    , extraTests :: Bool -> FilePath -> [TestTree IO (input, HList outputs)]
    }

digit :: (Token s ~ Char, Num b, MonadParsec e s f) => f b
digit = fromIntegral . digitToInt <$> digitChar

digitsToInt :: (Integral a) => [a] -> Int
digitsToInt = foldl' (\acc d -> acc * 10 + fromIntegral d) 0

listIndex :: Int -> [a] -> Maybe a
listIndex n =
    if n < 0
        then const Nothing
        else \case
            [] -> Nothing
            x : xs -> if n == 0 then Just x else listIndex (n - 1) xs

allUnorderedPairs :: Bool -> [a] -> [(a, a)]
allUnorderedPairs diagonals = concat . join (zipWith (flip $ map . (,)) . (bool tail toList diagonals) . tails)

adjacentPairs :: [b] -> [(b, b)]
adjacentPairs = \case
    [] -> []
    x : xs -> zip (x : xs) xs

sortPair :: (Ord a) => (a, a) -> (a, a)
sortPair (a, b) = if a <= b then (a, b) else (b, a)

type PuzzleParts input = HListF (Fanout ((->) input) (Op Text))
infixr 9 /\\
(/\\) :: (input -> output, output -> Text) -> PuzzleParts input outputs -> PuzzleParts input (output : outputs)
(/\\) (f, o) = HConsF $ Fanout (f, Op o)
infixr 9 /\
(/\) :: (Show output) => (input -> output) -> PuzzleParts input outputs -> PuzzleParts input (output : outputs)
(/\) f = HConsF $ Fanout (f, Op T.show)
nil :: PuzzleParts input '[]
nil = HNilF

data HList (as :: List Type) :: Type where
    HNil :: HList '[]
    HCons ::
        a ->
        HList as ->
        HList (a ': as)
hlistLength :: HList r -> Int
hlistLength = \case
    HNil -> 0
    HCons _ l -> 1 + hlistLength l

data HListF (f :: Type -> Type) (as :: List Type) :: Type where
    HNilF :: HListF f '[]
    HConsF ::
        f a ->
        HListF f as ->
        HListF f (a ': as)
foldHListF :: (forall x xs. f x -> r xs -> r (x ': xs)) -> r '[] -> HListF f as -> r as
foldHListF f e = \case
    HNilF -> e
    HConsF x xs -> f x $ foldHListF f e xs
foldHListF0 :: (forall x. f x -> r -> r) -> r -> HListF f as -> r
foldHListF0 f e = \case
    HNilF -> e
    HConsF x xs -> f x $ foldHListF0 f e xs
mapHListF :: (forall a. f a -> g a) -> HListF f as -> HListF g as
mapHListF t = foldHListF (\x r -> HConsF (t x) $ r) HNilF
hlistfLength :: HListF f r -> Int
hlistfLength = \case
    HNilF -> 0
    HConsF _ l -> 1 + hlistfLength l

newtype Fanout f g a = Fanout (f a, g a)

data TestTree m input where
    TestTree :: TestName -> (input -> m output) -> [TestTree m output] -> TestTree m input

data TestResult
    = Pass TestName [TestResult]
    | Fail TestName SomeExceptionLegalShow
    deriving (Show)

newtype TestName = TestName String
    deriving newtype (IsString, Show)

mkTestName :: String -> TestName
mkTestName = TestName

newtype SomeExceptionLegalShow = SomeExceptionLegalShow SomeException
instance Show SomeExceptionLegalShow where
    show (SomeExceptionLegalShow e) = show $ show e

getTestTree :: TestTree m r -> Tree TestName
getTestTree (TestTree name _ ts) = Node name $ map getTestTree ts

runTests :: (MonadCatch m) => a -> TestTree m a -> m TestResult
runTests x (TestTree name f ts) =
    Control.Monad.Catch.try (f x) >>= \case
        Left e ->
            pure $ Fail name $ SomeExceptionLegalShow e
        Right r ->
            Pass name <$> for ts (runTests r)

assertEqual :: (Eq p, MonadFail f) => p -> p -> f ()
assertEqual expected actual = assert "not equal" (expected == actual)
assert :: (MonadFail f) => String -> Bool -> f ()
assert s b = if b then pure () else fail s
golden :: FilePath -> Text -> IO ()
golden p x = do
    expected <- T.readFile p
    if expected == x then pure () else fail "golden test failure"
Use custom prelude 2025-12-08 12:48:49 +00:00			`{-# LANGUAGE PackageImports #-}`
Reuse expensive computation for day 4 extra tests Ideally we'd similarly add the ability for later tests to use the results of earlier ones. But this would probably require much heavier type family usage. 2025-12-31 01:18:05 +00:00			`{-# LANGUAGE TypeFamilies #-}`
Use custom prelude 2025-12-08 12:48:49 +00:00
			`module Pre (`
			`module BasePrelude,`
			`module Control.Applicative,`
			`module Control.Monad,`
			`module Control.Monad.Loops,`
			`module Control.Monad.State,`
			`module Data.Bifunctor,`
			`module Data.Bool,`
			`module Data.Char,`
			`module Data.Foldable,`
			`module Data.Foldable1,`
Minor refactors 2025-12-08 22:48:29 +00:00			`module Data.Function,`
Use custom prelude 2025-12-08 12:48:49 +00:00			`module Data.Functor,`
			`module Data.List,`
			`module Data.List.Extra,`
			`module Data.List.NonEmpty,`
			`module Data.Maybe,`
			`module Data.Ord,`
			`module Data.Sequence,`
			`module Data.Stream.Infinite,`
			`module Data.Text,`
			`module Data.Text.Encoding,`
Solve day 7 part 1 2025-12-08 16:34:30 +00:00			`module Data.Traversable,`
Solve day 9 part 2 2025-12-09 13:37:39 +00:00			`module Data.Tuple.Extra,`
Use custom prelude 2025-12-08 12:48:49 +00:00			`module Data.Void,`
			`module Data.Word,`
			`module Linear,`
Solve day 8 part 2 2025-12-08 22:01:49 +00:00			`module Safe,`
Use custom prelude 2025-12-08 12:48:49 +00:00			`module Text.Megaparsec,`
			`module Text.Megaparsec.Char,`
			`module Text.Megaparsec.Char.Lexer,`
			`Puzzle (..),`
Solve day 8 part 2 2025-12-08 23:38:48 +00:00			`digit,`
			`digitsToInt,`
Avoid unsafe list indexing 2025-12-09 00:02:54 +00:00			`listIndex,`
Solve day 9 part 1 2025-12-09 10:47:32 +00:00			`allUnorderedPairs,`
Solve day 9 part 2 2025-12-09 13:37:39 +00:00			`adjacentPairs,`
			`sortPair,`
Move to custom test library 2026-01-05 14:37:25 +00:00			`HList (..),`
			`hlistLength,`
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`HListF (..),`
Implement all `HList` functions in terms of single fold 2026-01-04 02:39:33 +00:00			`foldHListF,`
Add non-parameterised version of `HList` fold 2026-01-04 02:57:38 +00:00			`foldHListF0,`
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`mapHListF,`
Move to custom test library 2026-01-05 14:37:25 +00:00			`hlistfLength,`
Allow output types to vary for different parts of same day For now this applies to Haskell only, and it may turn out to be tricky for the Rust implementation. In practice, the limitation hasn't turned out to be important, and we could even go the other way and use `Integer` everywhere. This does however at least help with debugging, as well as just being conceptually right. The `nil` and `(/\)` functions are intended to be overloaded to work for other list-like things in a later commit, and from there we will investigate using `OverloadedLists` and `RebindableSyntax` to recover standard list syntax, although there are probably limitations due to `(:)` being special. 2025-12-16 16:15:11 +00:00			`(/\),`
Reuse expensive computation for day 4 extra tests Ideally we'd similarly add the ability for later tests to use the results of earlier ones. But this would probably require much heavier type family usage. 2025-12-31 01:18:05 +00:00			`(/\\),`
Allow output types to vary for different parts of same day For now this applies to Haskell only, and it may turn out to be tricky for the Rust implementation. In practice, the limitation hasn't turned out to be important, and we could even go the other way and use `Integer` everywhere. This does however at least help with debugging, as well as just being conceptually right. The `nil` and `(/\)` functions are intended to be overloaded to work for other list-like things in a later commit, and from there we will investigate using `OverloadedLists` and `RebindableSyntax` to recover standard list syntax, although there are probably limitations due to `(:)` being special. 2025-12-16 16:15:11 +00:00			`nil,`
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`Fanout (..),`
Move to custom test library 2026-01-05 14:37:25 +00:00			`TestTree (..),`
			`TestName,`
			`mkTestName,`
			`getTestTree,`
			`runTests,`
			`assertEqual,`
			`assert,`
			`golden,`
Use custom prelude 2025-12-08 12:48:49 +00:00			`)`
			`where`

			`import "base" Prelude as BasePrelude hiding (`
			`foldl1,`
			`foldr1,`
			`head,`
			`init,`
			`last,`
			`maximum,`
			`minimum,`
			`tail,`
			`unzip,`
Avoid unsafe list indexing 2025-12-09 00:02:54 +00:00			`(!!),`
Use custom prelude 2025-12-08 12:48:49 +00:00			`)`

			`import Control.Applicative`
Move to custom test library 2026-01-05 14:37:25 +00:00			`import Control.Exception (SomeException)`
Use custom prelude 2025-12-08 12:48:49 +00:00			`import Control.Monad`
Move to custom test library 2026-01-05 14:37:25 +00:00			`import Control.Monad.Catch (MonadCatch, try)`
Use custom prelude 2025-12-08 12:48:49 +00:00			`import Control.Monad.Loops`
			`import Control.Monad.State`
			`import Data.Bifunctor`
			`import Data.Bool`
			`import Data.Char`
			`import Data.Foldable hiding (foldl1, foldr1, maximum, maximumBy, minimum, minimumBy)`
			`import Data.Foldable1`
Minor refactors 2025-12-08 22:48:29 +00:00			`import Data.Function`
Use custom prelude 2025-12-08 12:48:49 +00:00			`import Data.Functor`
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`import Data.Functor.Contravariant`
Reuse expensive computation for day 4 extra tests Ideally we'd similarly add the ability for later tests to use the results of earlier ones. But this would probably require much heavier type family usage. 2025-12-31 01:18:05 +00:00			`import Data.Kind (Type)`
Allow output types to vary for different parts of same day For now this applies to Haskell only, and it may turn out to be tricky for the Rust implementation. In practice, the limitation hasn't turned out to be important, and we could even go the other way and use `Integer` everywhere. This does however at least help with debugging, as well as just being conceptually right. The `nil` and `(/\)` functions are intended to be overloaded to work for other list-like things in a later commit, and from there we will investigate using `OverloadedLists` and `RebindableSyntax` to recover standard list syntax, although there are probably limitations due to `(:)` being special. 2025-12-16 16:15:11 +00:00			`import Data.List (List, sortOn, transpose)`
Solve day 10 part 1 2025-12-11 11:34:36 +00:00			`import Data.List.Extra (dropEnd, enumerate, firstJust, notNull, splitOn)`
Minor refactor 2025-12-09 00:26:22 +00:00			`import Data.List.NonEmpty (NonEmpty ((:\|)), nonEmpty, some1, tail, tails)`
Use custom prelude 2025-12-08 12:48:49 +00:00			`import Data.Maybe`
			`import Data.Ord`
			`import Data.Sequence (Seq)`
			`import Data.Stream.Infinite (Stream ((:>)))`
Move to custom test library 2026-01-05 14:37:25 +00:00			`import Data.String (IsString)`
Use custom prelude 2025-12-08 12:48:49 +00:00			`import Data.Text (Text)`
Reuse expensive computation for day 4 extra tests Ideally we'd similarly add the ability for later tests to use the results of earlier ones. But this would probably require much heavier type family usage. 2025-12-31 01:18:05 +00:00			`import Data.Text qualified as T`
Use custom prelude 2025-12-08 12:48:49 +00:00			`import Data.Text.Encoding (encodeUtf8)`
Move to custom test library 2026-01-05 14:37:25 +00:00			`import Data.Text.IO qualified as T`
Solve day 7 part 1 2025-12-08 16:34:30 +00:00			`import Data.Traversable`
Move to custom test library 2026-01-05 14:37:25 +00:00			`import Data.Tree`
Solve day 9 part 2 2025-12-09 13:37:39 +00:00			`import Data.Tuple.Extra ((&&&))`
Use custom prelude 2025-12-08 12:48:49 +00:00			`import Data.Void`
			`import Data.Word`
			`import Linear (V2 (..))`
Solve day 8 part 2 2025-12-08 22:01:49 +00:00			`import Safe`
Use custom prelude 2025-12-08 12:48:49 +00:00			`import Text.Megaparsec hiding (Pos, State, Stream, many, some)`
			`import Text.Megaparsec.Char`
			`import Text.Megaparsec.Char.Lexer (decimal)`

Allow output types to vary for different parts of same day For now this applies to Haskell only, and it may turn out to be tricky for the Rust implementation. In practice, the limitation hasn't turned out to be important, and we could even go the other way and use `Integer` everywhere. This does however at least help with debugging, as well as just being conceptually right. The `nil` and `(/\)` functions are intended to be overloaded to work for other list-like things in a later commit, and from there we will investigate using `OverloadedLists` and `RebindableSyntax` to recover standard list syntax, although there are probably limitations due to `(:)` being special. 2025-12-16 16:15:11 +00:00			`data Puzzle = forall input outputs. Puzzle`
Use custom prelude 2025-12-08 12:48:49 +00:00			`{ number :: Word`
Add argument to parser for disambiguating real data versus examples This breaks less code than adding it to the solution functions, and is more elegant in a way. 2025-12-08 22:42:29 +00:00			`, parser :: Bool -> Parsec Void Text input`
Reuse expensive computation for day 4 extra tests Ideally we'd similarly add the ability for later tests to use the results of earlier ones. But this would probably require much heavier type family usage. 2025-12-31 01:18:05 +00:00			`, parts :: PuzzleParts input outputs`
Move to custom test library 2026-01-05 14:37:25 +00:00			`, extraTests :: Bool -> FilePath -> [TestTree IO (input, HList outputs)]`
Use custom prelude 2025-12-08 12:48:49 +00:00			`}`
Solve day 8 part 2 2025-12-08 23:38:48 +00:00
			`digit :: (Token s ~ Char, Num b, MonadParsec e s f) => f b`
			`digit = fromIntegral . digitToInt <$> digitChar`

			`digitsToInt :: (Integral a) => [a] -> Int`
Match `digitsToInt` to simpler Rust version 2025-12-13 11:24:46 +00:00			`digitsToInt = foldl' (\acc d -> acc * 10 + fromIntegral d) 0`
Avoid unsafe list indexing 2025-12-09 00:02:54 +00:00
			`listIndex :: Int -> [a] -> Maybe a`
			`listIndex n =`
			`if n < 0`
			`then const Nothing`
			`else \case`
			`[] -> Nothing`
			`x : xs -> if n == 0 then Just x else listIndex (n - 1) xs`
Solve day 9 part 1 2025-12-09 10:47:32 +00:00
Generalise `allUnorderedPairs` Now that it's in the prelude, the desire to remove diagonals is less obvious than it was. 2025-12-09 11:00:01 +00:00			`allUnorderedPairs :: Bool -> [a] -> [(a, a)]`
			`allUnorderedPairs diagonals = concat . join (zipWith (flip $ map . (,)) . (bool tail toList diagonals) . tails)`
Solve day 9 part 2 2025-12-09 13:37:39 +00:00
			`adjacentPairs :: [b] -> [(b, b)]`
			`adjacentPairs = \case`
			`[] -> []`
			`x : xs -> zip (x : xs) xs`

			`sortPair :: (Ord a) => (a, a) -> (a, a)`
			`sortPair (a, b) = if a <= b then (a, b) else (b, a)`
Show diff for golden test failures 2025-12-09 16:47:12 +00:00
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`type PuzzleParts input = HListF (Fanout ((->) input) (Op Text))`
Reuse expensive computation for day 4 extra tests Ideally we'd similarly add the ability for later tests to use the results of earlier ones. But this would probably require much heavier type family usage. 2025-12-31 01:18:05 +00:00			`infixr 9 /\\`
			`(/\\) :: (input -> output, output -> Text) -> PuzzleParts input outputs -> PuzzleParts input (output : outputs)`
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`(/\\) (f, o) = HConsF $ Fanout (f, Op o)`
Allow output types to vary for different parts of same day For now this applies to Haskell only, and it may turn out to be tricky for the Rust implementation. In practice, the limitation hasn't turned out to be important, and we could even go the other way and use `Integer` everywhere. This does however at least help with debugging, as well as just being conceptually right. The `nil` and `(/\)` functions are intended to be overloaded to work for other list-like things in a later commit, and from there we will investigate using `OverloadedLists` and `RebindableSyntax` to recover standard list syntax, although there are probably limitations due to `(:)` being special. 2025-12-16 16:15:11 +00:00			`infixr 9 /\`
Reuse expensive computation for day 4 extra tests Ideally we'd similarly add the ability for later tests to use the results of earlier ones. But this would probably require much heavier type family usage. 2025-12-31 01:18:05 +00:00			`(/\) :: (Show output) => (input -> output) -> PuzzleParts input outputs -> PuzzleParts input (output : outputs)`
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`(/\) f = HConsF $ Fanout (f, Op T.show)`
Reuse expensive computation for day 4 extra tests Ideally we'd similarly add the ability for later tests to use the results of earlier ones. But this would probably require much heavier type family usage. 2025-12-31 01:18:05 +00:00			`nil :: PuzzleParts input '[]`
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`nil = HNilF`

Move to custom test library 2026-01-05 14:37:25 +00:00			`data HList (as :: List Type) :: Type where`
			`HNil :: HList '[]`
			`HCons ::`
			`a ->`
			`HList as ->`
			`HList (a ': as)`
			`hlistLength :: HList r -> Int`
			`hlistLength = \case`
			`HNil -> 0`
			`HCons _ l -> 1 + hlistLength l`

Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`data HListF (f :: Type -> Type) (as :: List Type) :: Type where`
			`HNilF :: HListF f '[]`
			`HConsF ::`
			`f a ->`
			`HListF f as ->`
			`HListF f (a ': as)`
Implement all `HList` functions in terms of single fold 2026-01-04 02:39:33 +00:00			`foldHListF :: (forall x xs. f x -> r xs -> r (x ': xs)) -> r '[] -> HListF f as -> r as`
			`foldHListF f e = \case`
			`HNilF -> e`
			`HConsF x xs -> f x $ foldHListF f e xs`
Add non-parameterised version of `HList` fold 2026-01-04 02:57:38 +00:00			`foldHListF0 :: (forall x. f x -> r -> r) -> r -> HListF f as -> r`
			`foldHListF0 f e = \case`
			`HNilF -> e`
			`HConsF x xs -> f x $ foldHListF0 f e xs`
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00			`mapHListF :: (forall a. f a -> g a) -> HListF f as -> HListF g as`
Implement all `HList` functions in terms of single fold 2026-01-04 02:39:33 +00:00			`mapHListF t = foldHListF (\x r -> HConsF (t x) $ r) HNilF`
Move to custom test library 2026-01-05 14:37:25 +00:00			`hlistfLength :: HListF f r -> Int`
			`hlistfLength = \case`
			`HNilF -> 0`
			`HConsF _ l -> 1 + hlistfLength l`
Generalise puzzle parts type 2026-01-04 02:14:35 +00:00
			`newtype Fanout f g a = Fanout (f a, g a)`
Move to custom test library 2026-01-05 14:37:25 +00:00
			`data TestTree m input where`
			`TestTree :: TestName -> (input -> m output) -> [TestTree m output] -> TestTree m input`

			`data TestResult`
			`= Pass TestName [TestResult]`
			`\| Fail TestName SomeExceptionLegalShow`
			`deriving (Show)`

			`newtype TestName = TestName String`
			`deriving newtype (IsString, Show)`

			`mkTestName :: String -> TestName`
			`mkTestName = TestName`

			`newtype SomeExceptionLegalShow = SomeExceptionLegalShow SomeException`
			`instance Show SomeExceptionLegalShow where`
			`show (SomeExceptionLegalShow e) = show $ show e`

			`getTestTree :: TestTree m r -> Tree TestName`
			`getTestTree (TestTree name _ ts) = Node name $ map getTestTree ts`

			`runTests :: (MonadCatch m) => a -> TestTree m a -> m TestResult`
			`runTests x (TestTree name f ts) =`
			`Control.Monad.Catch.try (f x) >>= \case`
			`Left e ->`
			`pure $ Fail name $ SomeExceptionLegalShow e`
			`Right r ->`
			`Pass name <$> for ts (runTests r)`

			`assertEqual :: (Eq p, MonadFail f) => p -> p -> f ()`
			`assertEqual expected actual = assert "not equal" (expected == actual)`
			`assert :: (MonadFail f) => String -> Bool -> f ()`
			`assert s b = if b then pure () else fail s`
			`golden :: FilePath -> Text -> IO ()`
			`golden p x = do`
			`expected <- T.readFile p`
			`if expected == x then pure () else fail "golden test failure"`