gleenn/README.md

## README.md

      
    Raw
  

              README.md
            
          
    Typing the technical interview

Originally written by Kyle "Aphyr" Kingsbury

Definitely check out the awesome blog post where this code originated. It's well worth the read!
To run:
$ ghci Solution.hs

*Main> :type solution (nil :: N6)


## Solution.hs
{-# OPTIONS_GHC -fno-warn-missing-methods #-}
{-# OPTIONS_GHC -fno-warn-simplifiable-class-constraints #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE FunctionalDependencies #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE UndecidableInstances #-}

nil = undefined

data Nil
data Cons x xs

class First list x | list -> x
instance First Nil Nil
instance First (Cons x more) x

class ListConcat a b c | a b -> c
instance ListConcat Nil x x
instance (ListConcat as bs cs) => ListConcat (Cons a as) bs (Cons a cs)

-- Concatenate all lists in a list
class ListConcatAll ls l | ls -> l
instance ListConcatAll Nil Nil
instance (ListConcat chunk acc result, ListConcatAll rest acc) =>
         ListConcatAll (Cons chunk rest) result

-- Is any element of this list True?
class AnyTrue list t | list -> t
instance AnyTrue Nil False
instance AnyTrue (Cons True more) True
instance (AnyTrue list t) => AnyTrue (Cons False list) t

data True
data False

class Not b1 b | b1 -> b
instance Not False True
instance Not True False

class Or b1 b2 b | b1 b2 -> b
instance Or True True True
instance Or True False True
instance Or False True True
instance Or False False False

data Z
data S n

type N0 = Z
type N1 = S N0
type N2 = S N1
type N3 = S N2
type N4 = S N3
type N5 = S N4
type N6 = S N5
type N7 = S N6
type N8 = S N7

-- Equality
class PeanoEqual a b t | a b -> t
instance PeanoEqual Z Z True
instance PeanoEqual (S a) Z False
instance PeanoEqual Z (S b) False
instance (PeanoEqual a b t) => PeanoEqual (S a) (S b) t

-- Comparison (<)
class PeanoLT a b t | a b -> t
instance PeanoLT Z Z False
instance PeanoLT (S x) Z False
instance PeanoLT Z (S x) True
instance (PeanoLT a b t) => PeanoLT (S a) (S b) t

-- Absolute difference
class PeanoAbsDiff a b c | a b -> c
instance PeanoAbsDiff Z Z Z
instance PeanoAbsDiff Z (S b) (S b)
instance PeanoAbsDiff (S a) Z (S a)
instance (PeanoAbsDiff a b c) => PeanoAbsDiff (S a) (S b) c

-- Integers from n to 0
class Range n xs | n -> xs
instance Range Z Nil
instance (Range n xs) => Range (S n) (Cons n xs)

class Apply f a r | f a -> r

data Conj1 list
instance Apply (Conj1 list) x (Cons x list)

-- Map f over a list
class Map f xs ys | f xs -> ys
instance Map f Nil Nil
instance (Apply f x y, Map f xs ys) => Map f (Cons x xs) (Cons y ys)

-- Map f over list and concatenate results together
class MapCat f xs zs | f xs -> zs
instance MapCat f Nil Nil
instance (Map f xs chunks, ListConcatAll chunks ys) => MapCat f xs ys

-- Filter a list with an Apply-able predicate function
class AppendIf pred x ys zs | pred x ys -> zs
instance AppendIf True x ys (Cons x ys)
instance AppendIf False x ys ys

class Filter f xs ys | f xs -> ys
instance Filter f Nil Nil
instance (Apply f x t, Filter f xs ys, AppendIf t x ys zs) =>
         Filter f (Cons x xs) zs

data Queen x y
data Queen1 x
instance Apply (Queen1 x) y (Queen x y)

-- A list of queens in row x with y from 0 to n.
class QueensInRow n x queens | n x -> queens
instance (Range n ys, Map (Queen1 x) ys queens) => QueensInRow n x queens

-- Does queen a threaten queen b?
class Threatens a b t | a b -> t
instance ( PeanoEqual ax bx xeq
         , PeanoEqual ay by yeq
         , Or xeq yeq xyeq
         , PeanoAbsDiff ax bx dx
         , PeanoAbsDiff ay by dy
         , PeanoEqual dx dy deq
         , Or xyeq deq res
         ) =>
         Threatens (Queen ax ay) (Queen bx by) res

-- Partial application of Threatens
data Threatens1 a
instance (Threatens a b t) => Apply (Threatens1 a) b t

-- Is queen b compatible with all queen as?
class Safe config queen t | config queen -> t
instance (Map (Threatens1 queen) config m1, AnyTrue m1 t1, Not t1 t2) =>
         Safe config queen t2

data Safe1 config
instance (Safe config queen t) => Apply (Safe1 config) queen t

-- Add a queen with the given x coordinate to a legal configuration, returning
-- a set of legal configurations.
class AddQueen n x c cs | n x c -> cs
instance ( QueensInRow n x candidates
         , Filter (Safe1 c) candidates filtered
         , Map (Conj1 c) filtered cs
         ) =>
         AddQueen n x c cs

data AddQueen2 n x
instance (AddQueen n x c cs) => Apply (AddQueen2 n x) c cs

-- Add a queen at x to every configuration, returning a set of legal
-- configurations.
class AddQueenToAll n x cs cs' | n x cs -> cs'
instance (MapCat (AddQueen2 n x) cs cs') => AddQueenToAll n x cs cs'

-- Add queens recursively
class AddQueensIf pred n x cs cs' | pred n x cs -> cs'
instance AddQueensIf False n x cs cs
instance (AddQueenToAll n x cs cs2, AddQueens n (S x) cs2 cs') =>
         AddQueensIf True n x cs cs'

class AddQueens n x cs cs' | n x cs -> cs'
instance (PeanoLT x n pred, AddQueensIf pred n x cs cs') =>
         AddQueens n x cs cs'

-- Solve
class Solution n c | n -> c where
  solution :: n -> c
instance (AddQueens n Z (Cons Nil Nil) cs, First cs c) => Solution n c where
  solution = nil
	{-# OPTIONS_GHC -fno-warn-missing-methods #-}
	{-# OPTIONS_GHC -fno-warn-simplifiable-class-constraints #-}
	{-# LANGUAGE MultiParamTypeClasses #-}
	{-# LANGUAGE FunctionalDependencies #-}
	{-# LANGUAGE FlexibleInstances #-}
	{-# LANGUAGE UndecidableInstances #-}

	nil = undefined

	data Nil
	data Cons x xs

	class First list x \| list -> x
	instance First Nil Nil
	instance First (Cons x more) x

	class ListConcat a b c \| a b -> c
	instance ListConcat Nil x x
	instance (ListConcat as bs cs) => ListConcat (Cons a as) bs (Cons a cs)

	-- Concatenate all lists in a list
	class ListConcatAll ls l \| ls -> l
	instance ListConcatAll Nil Nil
	instance (ListConcat chunk acc result, ListConcatAll rest acc) =>
	ListConcatAll (Cons chunk rest) result

	-- Is any element of this list True?
	class AnyTrue list t \| list -> t
	instance AnyTrue Nil False
	instance AnyTrue (Cons True more) True
	instance (AnyTrue list t) => AnyTrue (Cons False list) t

	data True
	data False

	class Not b1 b \| b1 -> b
	instance Not False True
	instance Not True False

	class Or b1 b2 b \| b1 b2 -> b
	instance Or True True True
	instance Or True False True
	instance Or False True True
	instance Or False False False

	data Z
	data S n

	type N0 = Z
	type N1 = S N0
	type N2 = S N1
	type N3 = S N2
	type N4 = S N3
	type N5 = S N4
	type N6 = S N5
	type N7 = S N6
	type N8 = S N7

	-- Equality
	class PeanoEqual a b t \| a b -> t
	instance PeanoEqual Z Z True
	instance PeanoEqual (S a) Z False
	instance PeanoEqual Z (S b) False
	instance (PeanoEqual a b t) => PeanoEqual (S a) (S b) t

	-- Comparison (<)
	class PeanoLT a b t \| a b -> t
	instance PeanoLT Z Z False
	instance PeanoLT (S x) Z False
	instance PeanoLT Z (S x) True
	instance (PeanoLT a b t) => PeanoLT (S a) (S b) t

	-- Absolute difference
	class PeanoAbsDiff a b c \| a b -> c
	instance PeanoAbsDiff Z Z Z
	instance PeanoAbsDiff Z (S b) (S b)
	instance PeanoAbsDiff (S a) Z (S a)
	instance (PeanoAbsDiff a b c) => PeanoAbsDiff (S a) (S b) c

	-- Integers from n to 0
	class Range n xs \| n -> xs
	instance Range Z Nil
	instance (Range n xs) => Range (S n) (Cons n xs)

	class Apply f a r \| f a -> r

	data Conj1 list
	instance Apply (Conj1 list) x (Cons x list)

	-- Map f over a list
	class Map f xs ys \| f xs -> ys
	instance Map f Nil Nil
	instance (Apply f x y, Map f xs ys) => Map f (Cons x xs) (Cons y ys)

	-- Map f over list and concatenate results together
	class MapCat f xs zs \| f xs -> zs
	instance MapCat f Nil Nil
	instance (Map f xs chunks, ListConcatAll chunks ys) => MapCat f xs ys

	-- Filter a list with an Apply-able predicate function
	class AppendIf pred x ys zs \| pred x ys -> zs
	instance AppendIf True x ys (Cons x ys)
	instance AppendIf False x ys ys

	class Filter f xs ys \| f xs -> ys
	instance Filter f Nil Nil
	instance (Apply f x t, Filter f xs ys, AppendIf t x ys zs) =>
	Filter f (Cons x xs) zs

	data Queen x y
	data Queen1 x
	instance Apply (Queen1 x) y (Queen x y)

	-- A list of queens in row x with y from 0 to n.
	class QueensInRow n x queens \| n x -> queens
	instance (Range n ys, Map (Queen1 x) ys queens) => QueensInRow n x queens

	-- Does queen a threaten queen b?
	class Threatens a b t \| a b -> t
	instance ( PeanoEqual ax bx xeq
	, PeanoEqual ay by yeq
	, Or xeq yeq xyeq
	, PeanoAbsDiff ax bx dx
	, PeanoAbsDiff ay by dy
	, PeanoEqual dx dy deq
	, Or xyeq deq res
	) =>
	Threatens (Queen ax ay) (Queen bx by) res

	-- Partial application of Threatens
	data Threatens1 a
	instance (Threatens a b t) => Apply (Threatens1 a) b t

	-- Is queen b compatible with all queen as?
	class Safe config queen t \| config queen -> t
	instance (Map (Threatens1 queen) config m1, AnyTrue m1 t1, Not t1 t2) =>
	Safe config queen t2

	data Safe1 config
	instance (Safe config queen t) => Apply (Safe1 config) queen t

	-- Add a queen with the given x coordinate to a legal configuration, returning
	-- a set of legal configurations.
	class AddQueen n x c cs \| n x c -> cs
	instance ( QueensInRow n x candidates
	, Filter (Safe1 c) candidates filtered
	, Map (Conj1 c) filtered cs
	) =>
	AddQueen n x c cs

	data AddQueen2 n x
	instance (AddQueen n x c cs) => Apply (AddQueen2 n x) c cs

	-- Add a queen at x to every configuration, returning a set of legal
	-- configurations.
	class AddQueenToAll n x cs cs' \| n x cs -> cs'
	instance (MapCat (AddQueen2 n x) cs cs') => AddQueenToAll n x cs cs'

	-- Add queens recursively
	class AddQueensIf pred n x cs cs' \| pred n x cs -> cs'
	instance AddQueensIf False n x cs cs
	instance (AddQueenToAll n x cs cs2, AddQueens n (S x) cs2 cs') =>
	AddQueensIf True n x cs cs'

	class AddQueens n x cs cs' \| n x cs -> cs'
	instance (PeanoLT x n pred, AddQueensIf pred n x cs cs') =>
	AddQueens n x cs cs'

	-- Solve
	class Solution n c \| n -> c where
	solution :: n -> c
	instance (AddQueens n Z (Cons Nil Nil) cs, First cs c) => Solution n c where
	solution = nil