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Advanced Functional Programming

Advanced Functional Programming. Tim Sheard Oregon Graduate Institute of Science & Technology. Lecture 5: Monads Generic Unification Monads. Reading Assignment. Read the paper “Generic Unification via Two-Level Types and Parameterized Modules”

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Advanced Functional Programming

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  1. Advanced Functional Programming • Tim Sheard • Oregon Graduate Institute of Science & Technology • Lecture 5: Monads • Generic Unification • Monads

  2. Reading Assignment • Read the paper • “Generic Unification via Two-Level Types and Parameterized Modules” • http://www.cse.ogi.edu/~sheard/courses/cse583W03/papers/index.html

  3. An Example Use • Unification of types is used for type inference. • data (Mutable ref m ) => • Type ref m = • Tvar (ref (Maybe (Type ref m))) • | Tgen Int • | Tarrow (Type ref m) (Type ref m) • | Ttuple [Type ref m] • | Tcon String [Type ref m]

  4. Unify • unify :: Mutable ref m => • (Type ref m -> Type ref m -> m [String]) -> • Type ref m -> Type ref m -> m [String] • unify occursAction x y = • do { t1 <- prune x • ; t2 <- prune y • ; case (t1,t2) of • (Tvar r1,Tvar r2) -> • if same r1 r2 • then return [] • else do { put r1 (Just t2); return []} • (Tvar r1,_) -> • do { b <- occursIn r1 t2 • ; if b then occursAction t1 t2 • else do { put r1 (Just t2) • ; return [] } • }

  5. Unify continued • unify occursAction x y = • do { t1 <- prune x • ; t2 <- prune y • ; case (t1,t2) of • . . . • (_,Tvar r2) -> unify occursAction t2 t1 • (Tgen n,Tgen m) -> • if n==m then return [] • else return ["generic error"] • (Tarrow a b,Tarrow x y) -> • do { e1 <- unify occursAction a x • ; e2 <- unify occursAction b y • ; return (e1 ++ e2) • } • (_,_) -> return ["shape match error"] • }

  6. Generic Unify • How can we generalize unify to work on any type? • What properties must that type have? • a variable constructor like Tvar with a reference • What functions best capture these properties? • Capture these functions in a class. • class Mutable ref m => Unify t ref m where • isVar:: t ref m -> Maybe (ref (Maybe (t ref m))) • occursCheck :: ref(Maybe (t ref m)) -> t ref m -> m Bool • occursAction :: t ref m -> t ref m -> m [String] • match :: t ref m -> t ref m -> Maybe [(t ref m, t ref m)]

  7. Tvar(Just _ ) Tvar(Just _ ) Tvar(Just _ ) Tvar(Just _ ) Tvar(Just _ ) Tvar(Just _ ) Tuple[ X, Y] Tuple[ X, Y] Generic Prune • prunefun :: Unify t ref m => t ref m -> m(t ref m) • prunefun typ = • case isVar typ of • Just r -> do { m <- get r • ; case m of • Just t -> do { newt <- prunefun t • ; put r (Just newt) • ; return newt • } • Nothing -> return typ} • Nothing -> return typ

  8. Generic Unify • uni :: Unify t ref m => t ref m -> t ref m -> m[String] • uni x y = • do { t1 <- prunefun x • ; t2 <- prunefun y • ; case (isVar t1,isVar t2) of • (Just r1,Just r2) -> • if same r1 r2 • then return [] • else do { put r1 (Just t2); return []} • (Just r1,_) -> • do { b <- occursCheck r1 t2 • ; if b then occursAction t1 t2 • else do { put r1 (Just t2); return [] }} • (_,Just r2) -> uni t2 t1 • (Nothing,Nothing) -> case match t1 t2 of • Just pairs -> • do { errs <- sequence (map (uncurry uni) pairs) • ; return (concat errs) } • Nothing -> return["Match error"] • }

  9. An instance • instance Unify Type IORef IO where • isVar (Tvar r) = Just r • isVar _ = Nothing • occursCheck = occursIn • occursAction x y = return ["Occurs Check error"] • match x y = • let mlist xs ys = if length xs == length ys • then Just(zip xs ys) • else Nothing • in case (x,y) of • (Tgen x,Tgen y) -> • if x==y then Just [] else Nothing • (Tarrow x y,Tarrow a b) -> Just[(x,a),(y,b)] • (Ttuple xs,Ttuple ys) -> mlist xs ys • (Tcon c xs,Tcon d ys) -> • if c==d then mlist xs ys else Nothing

  10. Monads • Monads & Actions • A Monad is an Abstract Data Type (ADT) • A Monad encapsulates effects • i.e. hides their implementation • A Monad uses types to separates Actions from pure computations • A Monad controls the order of effects

  11. Actions • It is sometimes useful to use actions or side effects in a functional program . • Update a piece of state (assignment) • do some IO • draw graphics on a display • return an exception rather than an answer • How do we do this? • We use a Monad • A Monad is a type constructor which has an implied action. • For example: IO Int is an action which performs some IO and then returns an Int

  12. Example Monads • IO a • Perform an IO action (like read or write to a file or stdin or stdout) and then return an item of type: a • GUI a • Perform a GUI action (like draw a pull-down menu) and then return an item of type: a • State t a • Perform an action which could change the value of a mutable variable (like an assignment) in a state thread t, and then return an item of type: a • Parser a • Read some input to build an item of type: a, then chop the items used to build it off the input device. Also a parse may fail so must handle failure as well.

  13. A monad is an ADT • A monad is an abstract datatype • It abstracts computations with effects. • It hides the details of its implementation. • It exports an abstract interface. • It specifies the order in which effects occur. • It separates pure computations from effectfull ones using the type system. • It can have multiple implementations.

  14. Monads Encapsulate Effects • A monad captures the meaning and use of computations which have effects on the real world. • A monad describes or specifies the effects in a “purely functional” way. • A monad allows one to reason about effects, using the simple rule of substitution of equals for equals. • A monad needn’t be implemented this way

  15. Sample Effects or Actions • State • Update a piece of the store (assignment) as well as return a final value. • Exceptional cases • There may be an error instead of a final value • Non-determinism • There may be multiple possible final values • Partial Computation • There may be nothing: no final value, or anything else • Communication • There may be external influence on the computation • Perform some Input or Output, as well as a final value. • Draw graphics on a display

  16. A Monad uses types to separate Actions (with effects) from pure computations • A Monad is a type constructor which has an implied action. • For example: • a computation with type (IO Int ) • an action which might perform some IO and which then returns an Int • Computations with non-monadic types cannot have any effects. They are pure computations. The user (and the compiler) can rely on this.

  17. A monad orders effects • A Monad specifies which effects come before others. • The Do operator provides this control over the order in which computations occur • do { var <- location x -- the first action • ; write var (b+1) -- the next action • }

  18. A monad’s interface hides details • A monad has an interface that hides the details of its implementation • Every monad has at least the two operations • Do Lets users control the order of actions • Return : a -> Action a makes an empty action • Each monad has its own additional operations.

  19. Monads have Axioms • Order matters (and is maintained by Do) • Do { x <- Do { y <- b; c } • ; d } = • Do { y <- b; x <- c; d } • Return introduces no effects • Do { x <- Return a; e } = e[a/x] • Do { x <- e; Return x } = e

  20. An Example: IO actions • Each function performs an action of doing some IO • ? :t getChar -- get 1 char from stdin • getChar :: IO Char • ? :t putChar -- put Char to stdout • putChar :: Char -> IO() • ? :t getLine -- get a whole line from stdin • getLine :: IO String • ? :t readFile -- read a file into a String • readFile :: FilePath -> IO String • ? :t writeFile -- write a String to a file • writeFile :: FilePath -> String -> IO ()

  21. Modelling IO • Suppose all that IO captured was the reading and writing to standard input and output. • Then we could model IO a as follows • data Io a = • Io ( String -> (a,String,String)) • instance Monad Io where • return x = Io(\ s -> (x,s,"")) • (>>=) (Io f) g = • Io(\ s -> let (x,in1,out1) = f s • (Io h) = g x • (y,in2,out2) = h in1 • in (y,in2,out1 ++ out2))

  22. Io operations • getCharX :: Io Char -- get 1 char from stdin • getCharX = Io(\ (c:cs) -> (c,cs,"")) • putCharX :: Char -> Io() -- put Char to stdout • putCharX c = Io(\ s -> ((),s,[c])) • getLineX :: Io String -- get a whole line from stdin • getLineX = do { c <- getCharX • ; if c == '\n' • then return "" • else do { cs <- getLineX • ; return (c:cs) • } }

  23. How to perform an IO action • Some thing of type: IO Int is a potential action which will return an Int, if it is ever performed. • In order for the action to occur, it must be performed. • Any thing with type : IO a typed at top level will be performed. • This is the only way that an action can be performed. • Stated another way • An actionful program builds up a potential action, which is finally performed when typed at top-level. • laziness is crucial in the implementation here • Big actionful programs can be built by combining smaller actionful programs using do. • No action is ever performed until typed at top level.

  24. Example: Combining IO actions • getLineX :: Io [Char] • getLineX = • do { c <- getCharX -- get a char • ; if c == '\n' -- if its newline • then return "" -- no-op action which • -- returns empty string • -- recursively • else do { l <- getLine' -- get a line • ; return (c:l) -- no-op action • } -- to cons c to l • } • Potentially reads a string from stdin, if it is ever performed

  25. Observations • Actions are first class. • They can be abstracted (param’s of functions) • Stored in data structures. -- It is possible to have a list of actions, etc. • Actions can be composed. • They can be built out of smaller actions by glueing them together with do and return • They are sequenced with do much like one uses semi-colon in languages like Pascal and C. • Actions can be performed (run). • separation of construction from performance is key to their versatility. • Actions of type: Action () are like statements in imperative languages. • They are used only for their side effects.

  26. Performing an action • How do we perform an action? • We need a function with type: • Io a -> a • If we have such a function then we break the abstraction which hides how Io is implemented. • In Haskell, the real IO can only be preformed at top level, when because the main function must have type IO()

  27. Modelling Io • Some Monads have models. • A model is a pure function that simulates the actions of the monad in a pure way. • Our Io monad is a model of a subset of the IO monad. • If a Monad has a model, we can often produce a run function with type: • m a -> model_of_m a • The run function uses the actual effects, but hides them in the model.

  28. The Model of Io • run (IO f) = f • Suppose the only thing IO did was getchar and putchar, then then run might be implemented as: • run g s = • { stdout := "" • ; x= perform g using s as input • ; return (x,stdin,stdout) • }

  29. Sample Monads • data Id x = Id x • data Exception x = Ok x | Fail • data Env e x = Env (e -> x) • data Store s x = Store (s -> (x,s)) • data Mult x = Mult [x] • data Output x = Output (x,String)

  30. Homework • Make Haskell Class definitions for each of the monad types on the previous page. • Think about what other operations are usefull for each monad and define those. • Recast the monad laws from the lecture interms of return and (>>=) instead of return and do. • Choose 2 of the monads. • The first should be either Exception or Output • The second should be one of Env, Store, Mult • prove the order or bind law for the two monads you choose.

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