distributed-static-0.3.10: Compositional, type-safe, polymorphic static values and closures
Safe HaskellNone
LanguageHaskell2010

Control.Distributed.Static

Description

Towards Haskell in the Cloud (Epstein et al, Haskell Symposium 2011) introduces the concept of static values: values that are known at compile time. In a distributed setting where all nodes are running the same executable, static values can be serialized simply by transmitting a code pointer to the value. This however requires special compiler support, which is not yet available in ghc. We can mimick the behaviour by keeping an explicit mapping (RemoteTable) from labels to values (and making sure that all distributed nodes are using the same RemoteTable). In this module we implement this mimickry and various extensions.

Compositionality

Static values as described in the paper are not compositional: there is no way to combine two static values and get a static value out of it. This makes sense when interpreting static strictly as known at compile time, but it severely limits expressiveness. However, the main motivation for 'static' is not that they are known at compile time but rather that they provide a free Binary instance. We therefore provide two basic constructors for Static values:

staticLabel :: String -> Static a
staticApply :: Static (a -> b) -> Static a -> Static b

The first constructor refers to a label in a RemoteTable. The second allows to apply a static function to a static argument, and makes Static compositional: once we have staticApply we can implement numerous derived combinators on Static values (we define a few in this module; see staticCompose, staticSplit, and staticConst).

Closures

Closures in functional programming arise when we partially apply a function. A closure is a code pointer together with a runtime data structure that represents the value of the free variables of the function. A Closure represents these closures explicitly so that they can be serialized:

data Closure a = Closure (Static (ByteString -> a)) ByteString

See Towards Haskell in the Cloud for the rationale behind representing the function closure environment in serialized (ByteString) form. Any static value can trivially be turned into a Closure (staticClosure). Moreover, since Static is now compositional, we can also define derived operators on Closure values (closureApplyStatic, closureApply, closureCompose, closureSplit).

Monomorphic example

Suppose we are working in the context of some distributed environment, with a monadic type Process representing processes, NodeId representing node addresses and ProcessId representing process addresses. Suppose further that we have a primitive

sendInt :: ProcessId -> Int -> Process ()

We might want to define

sendIntClosure :: ProcessId -> Closure (Int -> Process ())

In order to do that, we need a static version of send, and a static decoder for ProcessId:

sendIntStatic :: Static (ProcessId -> Int -> Process ())
sendIntStatic = staticLabel "$send"
decodeProcessIdStatic :: Static (ByteString -> Int)
decodeProcessIdStatic = staticLabel "$decodeProcessId"

where of course we have to make sure to use an appropriate RemoteTable:

rtable :: RemoteTable
rtable = registerStatic "$send" (toDynamic sendInt)
       . registerStatic "$decodeProcessId" (toDynamic (decode :: ByteString -> Int))
       $ initRemoteTable

We can now define sendIntClosure:

sendIntClosure :: ProcessId -> Closure (Int -> Process ())
sendIntClosure pid = closure decoder (encode pid)
  where
    decoder :: Static (ByteString -> Int -> Process ())
    decoder = sendIntStatic `staticCompose` decodeProcessIdStatic
Polymorphic example

Suppose we wanted to define a primitive

sendIntResult :: ProcessId -> Closure (Process Int) -> Closure (Process ())

which turns a process that computes an integer into a process that computes the integer and then sends it someplace else.

We can define

bindStatic :: (Typeable a, Typeable b) => Static (Process a -> (a -> Process b) -> Process b)
bindStatic = staticLabel "$bind"

provided that we register this label:

rtable :: RemoteTable
rtable = ...
       . registerStatic "$bind" ((>>=) :: Process ANY1 -> (ANY1 -> Process ANY2) -> Process ANY2)
       $ initRemoteTable

(Note that we are using the special ANY1 and ANY2 types from Data.Rank1Typeable to represent this polymorphic value.) Once we have a static bind we can define

sendIntResult :: ProcessId -> Closure (Process Int) -> Closure (Process ())
sendIntResult pid cl = bindStatic `closureApplyStatic` cl `closureApply` sendIntClosure pid
Dealing with qualified types

In the above we were careful to avoid qualified types. Suppose that we have instead

send :: Binary a => ProcessId -> a -> Process ()

If we now want to define sendClosure, analogous to sendIntClosure above, we somehow need to include the Binary instance in the closure -- after all, we can ship this closure someplace else, where it needs to accept an a, then encode it, and send it off. In order to do this, we need to turn the Binary instance into an explicit dictionary:

data BinaryDict a where
  BinaryDict :: Binary a => BinaryDict a

sendDict :: BinaryDict a -> ProcessId -> a -> Process ()
sendDict BinaryDict = send

Now sendDict is a normal polymorphic value:

sendDictStatic :: Static (BinaryDict a -> ProcessId -> a -> Process ())
sendDictStatic = staticLabel "$sendDict"

rtable :: RemoteTable
rtable = ...
       . registerStatic "$sendDict" (sendDict :: BinaryDict ANY -> ProcessId -> ANY -> Process ())
       $ initRemoteTable

so that we can define

sendClosure :: Static (BinaryDict a) -> Process a -> Closure (a -> Process ())
sendClosure dict pid = closure decoder (encode pid)
  where
    decoder :: Static (ByteString -> a -> Process ())
    decoder = (sendDictStatic `staticApply` dict) `staticCompose` decodeProcessIdStatic
Word of Caution

You should not define functions on ANY and co. For example, the following definition of rtable is incorrect:

rtable :: RemoteTable
rtable = registerStatic "$sdictSendPort" sdictSendPort
       $ initRemoteTable
  where
    sdictSendPort :: SerializableDict ANY -> SerializableDict (SendPort ANY)
    sdictSendPort SerializableDict = SerializableDict

This definition of sdictSendPort ignores its argument completely, and constructs a SerializableDict for the monomorphic type SendPort ANY, which isn't what you want. Instead, you should do

rtable :: RemoteTable
rtable = registerStatic "$sdictSendPort" (sdictSendPort :: SerializableDict ANY -> SerializableDict (SendPort ANY))
       $ initRemoteTable
  where
    sdictSendPort :: forall a. SerializableDict a -> SerializableDict (SendPort a)
    sdictSendPort SerializableDict = SerializableDict
Synopsis

Static values

data Static a Source #

A static value. Static is opaque; see staticLabel and staticApply.

Instances

Instances details
Show (Static a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

showsPrec :: Int -> Static a -> ShowS #

show :: Static a -> String #

showList :: [Static a] -> ShowS #

Binary (Static a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

put :: Static a -> Put #

get :: Get (Static a) #

putList :: [Static a] -> Put #

NFData (Static a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

rnf :: Static a -> () #

Eq (Static a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

(==) :: Static a -> Static a -> Bool #

(/=) :: Static a -> Static a -> Bool #

Ord (Static a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

compare :: Static a -> Static a -> Ordering #

(<) :: Static a -> Static a -> Bool #

(<=) :: Static a -> Static a -> Bool #

(>) :: Static a -> Static a -> Bool #

(>=) :: Static a -> Static a -> Bool #

max :: Static a -> Static a -> Static a #

min :: Static a -> Static a -> Static a #

staticLabel :: String -> Static a Source #

Create a primitive static value.

It is the responsibility of the client code to make sure the corresponding entry in the RemoteTable has the appropriate type.

staticApply :: Static (a -> b) -> Static a -> Static b Source #

Apply two static values

staticPtr :: Typeable a => StaticPtr a -> Static a Source #

Construct a static value from a static pointer

Since 0.3.4.0.

staticApplyPtr :: (Typeable a, Typeable b) => StaticPtr (a -> b) -> Static a -> Static b Source #

Apply a static pointer to a static value

Since 0.3.4.0.

Derived static combinators

staticCompose :: Static (b -> c) -> Static (a -> b) -> Static (a -> c) Source #

Static version of (.)

staticSplit :: Static (a -> b) -> Static (a' -> b') -> Static ((a, a') -> (b, b')) Source #

Static version of (***)

staticConst :: Static a -> Static (b -> a) Source #

Static version of const

staticFlip :: Static (a -> b -> c) -> Static (b -> a -> c) Source #

Static version of flip

Closures

data Closure a Source #

A closure is a static value and an encoded environment

Instances

Instances details
Show (Closure a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

showsPrec :: Int -> Closure a -> ShowS #

show :: Closure a -> String #

showList :: [Closure a] -> ShowS #

Binary (Closure a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

put :: Closure a -> Put #

get :: Get (Closure a) #

putList :: [Closure a] -> Put #

NFData (Closure a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

rnf :: Closure a -> () #

Eq (Closure a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

(==) :: Closure a -> Closure a -> Bool #

(/=) :: Closure a -> Closure a -> Bool #

Ord (Closure a) Source # 
Instance details

Defined in Control.Distributed.Static

Methods

compare :: Closure a -> Closure a -> Ordering #

(<) :: Closure a -> Closure a -> Bool #

(<=) :: Closure a -> Closure a -> Bool #

(>) :: Closure a -> Closure a -> Bool #

(>=) :: Closure a -> Closure a -> Bool #

max :: Closure a -> Closure a -> Closure a #

min :: Closure a -> Closure a -> Closure a #

closure Source #

Arguments

:: Static (ByteString -> a)

Decoder

-> ByteString

Encoded closure environment

-> Closure a 

Derived closure combinators

staticClosure :: Static a -> Closure a Source #

Convert a static value into a closure.

closureApplyStatic :: Static (a -> b) -> Closure a -> Closure b Source #

Apply a static function to a closure

closureApply :: Closure (a -> b) -> Closure a -> Closure b Source #

Closure application

closureCompose :: Closure (b -> c) -> Closure (a -> b) -> Closure (a -> c) Source #

Closure composition

closureSplit :: Closure (a -> b) -> Closure (a' -> b') -> Closure ((a, a') -> (b, b')) Source #

Closure version of (***)

Resolution

data RemoteTable Source #

Runtime dictionary for unstatic lookups

initRemoteTable :: RemoteTable Source #

Initial remote table

registerStatic :: String -> Dynamic -> RemoteTable -> RemoteTable Source #

Register a static label

unstatic :: Typeable a => RemoteTable -> Static a -> Either String a Source #

Resolve a static value

unclosure :: Typeable a => RemoteTable -> Closure a -> Either String a Source #

Resolve a closure