Auto ==== ~~~bash $ cabal install auto ~~~ Check it out! ------------- ~~~haskell -- Let's impliement a PID feedback controller over a black box system. import Control.Auto import Prelude hiding ((.), id) -- We represent a system as `System`, an `Auto` that takes stream of `Double`s -- as input and transforms it into a stream of `Double`s as output. The `m` -- means that a `System IO` might do IO in the process of creating its ouputs, -- for instance. -- type System m = Auto m Double Double -- A PID controller adjusts the input to the black box system until the -- response matches the target. It does this by adjusting the input based on -- the current error, the cumulative sum, and the consecutative differences. -- -- See http://en.wikipedia.org/wiki/PID_controller -- -- Here, we just lay out the "concepts"/time-varying values in our system as a -- recursive/cyclic graph of dependencies. It's a feedback system, after all. -- pid :: MonadFix m => (Double, Double, Double) -> System m -> System m pid (kp, ki, kd) blackbox = proc target -> do -- proc syntax; see tutorial rec -- err :: Double -- the difference of the response from the target let err = target - response -- cumulativeSum :: Double -- the cumulative sum of the errs cumulativeSum <- sumFrom 0 -< err -- changes :: Maybe Double -- the consecutive differences of the errors, with 'Nothing' at first. changes <- deltas -< err -- adjustment :: Double -- the adjustment term, from the PID algorithm let adjustment = kp * err + ki * cumulativeSum + kd * fromMaybe 0 changes -- the control input is the cumulative sum of the adjustments control <- sumFromD 0 -< adjustment -- the response of the system, feeding the control into the blackbox response <- blackbox -< control -- the output of this all is the value of the response id -< response ~~~ What is it? ----------- **Auto** is a Haskell DSL and platform providing an API with declarative, compositional, denotative semantics for discrete-step, locally stateful, interactive programs, games, and automations, with implicitly derived serialization. It is suited for any domain where your program's input or output is a stream of values, input events, or output views. At the high-level, it allows you to describe your interactive program or simulation as a *value stream transformer*, by composition and transformation of other stream transformers. * **Haskell DSL/library**: It's a Haskell library that provides a domain-specific language for composing and declaring your programs/games. Why Haskell? Well, Haskell is one of the only languages that has a type system expressive enough to allow type-safe compositions without getting in your way. Every composition and component is checked at compile-time to make sure they even make sense, so you can work with an assurance that everything fits together in the end --- and also in the correct way. The type system can also guide you in your development as well. All this without the productivity overhead of explicit type annotations. In all honesty, it cuts the headache of large projects down --- and what you need to keep in your head as you develop and maintain --- by at least 90%. * **Platform**: Not only gives the minimal tools for creating your programs, but also provides a platform to run and develop and integrate them, as well as many library/API functions for common processes. * **Declarative**: It's not imperative. That is, unlike in other languages, you don't program your program by saying "this happens, then this happens...and then in case A, this happens; in case B, something else happens". Instead of specifying your program/game by a series of state-changing steps and procedures (a "game loop"), you instead declare "how things are". You declare fixed or evolving relationships between entities and processes and interactions. And this declaration process is high-level and pure. * **Denotative**: Instead of your program being built of pieces that change things and execute things sequentially, your entire program is composed of meaningful semantic building blocks that "denote" constant relationships and concepts. The composition of such building blocks also denote new concepts. Your building blocks are well-defined *ideas*. * **Compositional**: You build your eventually complex program/game out of small, simple components. These simple components compose with eachother; and compositions of components compose as well with other components. Every "layer" of composition is seamless. It's the [scalable program architecture][spa] principle in practice: If you combine an A with an A, you don't get a B; you get another A, which can combine with any other A. Like unix pipes, where you can build up complex programs by simply piping together simple, basic ones. * **Discrete-step**: This library is meant for things that step discretely; there is no meaningful concept of "continuous time". Good examples include turn-based games, chat bots, and cellular automata; bad examples include real-time games and day trading simulations. * **Locally stateful**: Every component encapsulates its own local (and "hidden") state. There is no global or impicitly shared state. This is in contrast to those "giant state monad" libraries/abstractions where you carry around the entire game/program state in some giant data type, and have your game loop simply be an update of that state. If you have a component representing a player, and a component representing an enemy --- the two components do not have to ever worry about the state of the other, or the structure of their shared state. Also, you never have to worry about something reading or modifying a part of the shared/global state it wasn't meant to read or modify! (Something you cannot guaruntee in the naive implementatation of the "giant state monad" technique). * **Interactive**: The behavior and structure of your program can respond and vary dynamically with outside interaction. I'm not sure how else to elaborate on the word "interactive", actually! * **Interactive programs, games and automations**: Programs, games, and automations/simulations. If you're making anything discrete-time that encapsulates some sort of internal state, especially if it's interactive, this is for you!! :D * **Implicitly derived serialization**: All components and their compositions by construction are automatically "freezable" and serializable, and re-loaded and resumed with all internal state restored. As it has been called by ertes, it's "save states for free". [spa]: http://www.haskellforall.com/2014/04/scalable-program-architectures.html Intrigued? Excited? Start at [the tutorial][tutorial]! [tutorial]: https://github.com/mstksg/auto/blob/master/tutorial/tutorial.md It's a part of this package directory and also on github at the above link. The current development documentation server is found at . From there, you can check out my [All About Auto][aaa] series on my blog, where I break sample projects and show to approach projects in real life. You can also find examples and demonstrations in the [auto-examples][] repo on github. [aaa]: http://blog.jle.im/entries/series/+all-about-auto [auto-examples]: https://github.com/mstksg/auto-examples ### Support The official support and discussion channel is *#haskell-auto* on freenode. You can also usually find me (the maintainer and developer) as *jle`* on *#haskell-game* or *#haskell*. Also, contributions to documentation and tests are welcome! :D Why Auto? --------- Auto is distinct from a "state transformer" (state monad, or explicit state passing) in that it gives you the ability to implicitly *compose and isolate* state transformers and state. That is, imagine you have two different state monads with different states, and you can compose them together into one giant loop, and: 1. You don't have to make a new "composite type"; you can add a new component dealing with its own state without changing the total state type. 2. You can't write anything cross-talking. You can't write anything that can interfere with the internal state of any components; each one is isolated. So --- Auto is useful over a state monad/state transformer approach in cases where you like to build your problem out of multiple individual components, and compose them all together at once. Examples include a multiple-module stateful chat bot, where every module of the chat bot consists of its own internal state. If you used a state monad approach, every time you added a new module with its own state, you'd have to "add it into" your total state type. This simply does *not* scale. Imagine a large architecture, where every composition adds more and more complexity. Now, imagine you can just throw in another module with its own state without any other component even "caring". Or be able to limit access implicitly, without explicit "limiting through lifting" with `zoom` from lens, etc. (Without that, you basically have "global state" --- the very thing that we went to Functional Programming/Haskell to avoid in the first place! And the thing that languages have been trying to prevent in the last twenty years of language development. Why go "backwards"?) In addition to all of these practical reasons, State imposes a large *imperative* shift in your design. State forces you to begin modeling your problem as "this happens, then this happens, then this happens". When you choose to use a State monad or State passing approach, you immediately begin to frame your entire program from an imperative approach. Auto lets you structure your program *denotatively* and declaratively. It gives you that awesome style that functional programming promised in the first place. Instead of saying "do this then that", you say "this is how things...just *are*. This is the structure of my program, and this is the nature of the relationship between each component". If you're already using Haskell...I shouldn't have to explain to you the benefits of a high-level declarative style over an imperative one :) Why not Auto? ------------- That being said, there are cases where **Auto** is either the wrong tool or not very helpful. * Cases involving inherently continuous time. **Auto** is meant for situations where time progresses in discrete ticks --- integers, not reals. You can "fake" it by faking continuous time with discrete sampling...but FRP is a much, much more powerful and safe abstraction/system for handling this than **Auto** is. See the later section on FRP. * Cases where you really don't have interactions/compositions between different stateful components. If all your program is just one `foldr` or `scanl` or `iterate`, and you don't have multiple interacting parts of your state, **Auto** really can't offer much. If, however, you have multiple folds or states that you want run together and compose, then this might be useful! * Intense IO stuff and resource handling. **Auto** is not *pipes* or *conduit*. All IO is done "outside" of the **Auto** components; **Auto** can be useful for file processing and stream modification, but only if you separately handle the IO portions. **Auto** works very well with *pipes* or *conduit*; those libraries are used to "connect" **Auto** to the outside word, and provide a safe interface. In other words, Auto handles "value streams", while pipes/conduit handle "effect streams" Relation to FRP --------------- **Auto** borrows a lot of concepts from *[Functional Reactive Programming][frp]* --- especially arrowized, locally stateful libraries like [netwire][]. At best, **Auto** can be said to bring a lot of API ideas and borrows certain aspects of the semantic model of FRP and incorporates them as a part of a broader semantic model more suitable for discrete-time discrete-stel contexts. But, users of such libraries would likely be able to quickly pick up **Auto**, and the reverse is (hopefully) true too. Note that this library is not meant to be any sort of meaningful substitution for implementing situations which involve concepts of continuous ("real number-valued", as opposed to "integer valued") time (like real-time games); you can "fake" it using **Auto**, but in those situations, FRP provides a much superior semantics and set of concepts for working in such contexts. That is, you can "fake" it, but you then lose almost all of the benefits of FRP in the first place. [frp]: http://en.wikipedia.org/wiki/Functional_reactive_programming [netwire]: https://hackage.haskell.org/package/netwire A chatbot --------- ~~~haskell import qualified Data.Map as M import Data.Map (Map) import Control.Auto import Prelude hiding ((.), id) -- Let's build a big chat bot by combining small chat bots. -- A "ChatBot" is going to be an `Auto` taking in a stream of tuples of -- incoming nick, message, and timestamps; the result is a "blip stream" that -- emits with messages whenever it wants to respond. type Message = String type Nick = String type ChatBot m = Auto m (Nick, Message, UTCTime) (Blip [Message]) -- Keeps track of last time a nick has spoken, and allows queries seenBot :: Monad m => ChatBot m seenBot = proc (nick, msg, time) -> do -- proc syntax; see tutorial -- seens :: Map Nick UTCTime -- Map containing last time each nick has spoken seens <- accum addToMap M.empty -< (nick, time) -- query :: Blip Nick -- blip stream emits whenever someone queries for a last time seen; -- emits with the nick queried for query <- emitJusts getRequest -< words msg -- a function to get a response from a nick query let respond :: Nick -> [Message] respond qry = case M.lookup qry seens of Just t -> [qry ++ " last seen at " ++ show t ++ "."] Nothing -> ["No record of " ++ qry ++ "."] -- output is, whenever the `query` stream emits, map `respond` to it. id -< respond <$> query where addToMap :: Map Nick UTCTime -> (Nick, UTCTime) -> Map Nick UTCTime addToMap mp (nick, time) = M.insert nick time mp getRequest ("@seen":request:_) = Just request getRequest _ = Nothing -- Users can increase and decrease imaginary internet points for other users karmaBot :: Monad m => ChatBot m karmaBot = proc (_, msg, _) -> do -- karmaBlip :: Blip (Nick, Int) -- blip stream emits when someone modifies karma, with nick and increment karmaBlip <- emitJusts getComm -< msg -- karmas :: Map Nick Int -- keeps track of the total karma for each user by updating with karmaBlip karmas <- scanB updateMap M.empty -< karmaBlip -- function to look up a nick, if one is asked for let lookupKarma :: Nick -> [Message] lookupKarma nick = let karm = M.findWithDefault 0 nick karmas in [nick ++ " has a karma of " ++ show karm ++ "."] -- output is, whenever `karmaBlip` stream emits, look up the result id -< lookupKarma . fst <$> karmaBlip where getComm :: String -> Maybe (Nick, Int) getComm msg = case words msg of "@addKarma":nick:_ -> Just (nick, 1 ) "@subKarma":nick:_ -> Just (nick, -1) "@karma":nick:_ -> Just (nick, 0) _ -> Nothing updateMap :: Map Nick Int -> (Nick, Int) -> Map Nick Int updateMap mp (nick, change) = M.insertWith (+) nick change mp -- Echos inputs prefaced with "@echo"...unless flood limit has been reached echoBot :: Monad m => ChatBot m echoBot = proc (nick, msg, time) -> do -- echoBlip :: Blip [Message] -- blip stream emits when someone wants an echo, with the message echoBlip <- emitJusts getEcho -< msg -- newDayBlip :: Blip UTCTime -- blip stream emits whenever the day changes newDayBlip <- onChange -< utctDay time -- echoCounts :: Map Nick Int -- `countEchos` counts the number of times each user asks for an echo, and -- `resetOn` makes it "reset" itself whenever `newDayBlip` emits. echoCounts <- resetOn countEchos -< (nick <$ echoBlip, newDayBlip) -- has this user flooded today...? let hasFlooded = M.lookup nick echoCounts > Just floodLimit -- output :: Blip [Message] -- blip stream emits whenever someone asks for an echo, limiting flood output | hasFlooded = ["No flooding!"] <$ echoBlip | otherwise = echoBlip -- output is the `output` blip stream id -< output where floodLimit = 5 getEcho msg = case words msg of "@echo":xs -> Just [unwords xs] _ -> Nothing countEchos :: Auto m (Blip Nick) (Map Nick Int) countEchos = scanB countingFunction M.empty countingFunction :: Map Nick Int -> Nick -> Map Nick Int countingFunction mp nick = M.insertWith (+) nick 1 mp -- Our final chat bot is the `mconcat` of all the small ones...it forks the -- input between all three, and mconcats the outputs. chatBot :: Monad m => ChatBot m chatBot = mconcat [seenBot, karmaBot, echoBot] -- Here, our chatbot will automatically serialize itself to "data.dat" -- whenever it is run. chatBotSerialized :: ChatBot IO chatBotSerialized = serializing' "data.dat" chatBot ~~~ Open questions -------------- * "Safecopy problem"; serialization schemes are implicitly derived, but if your program changes, it is unlikely that the new serialization scheme will be able to resume something from the old one. Right now the solution is to only serialize small aspects of your program that you *can* manage and manipulate directly when changing your program. A better solution might exist. * In principle very little of your program should be over `IO` as a monad...but sometimes, it becomes quite convenient for abstraction purposes. Handling IO errors in a robust way isn't quite my strong point, and so while almost all *auto* idioms avoid `IO` and runtime, for some applications it might be unavoidable. *auto* is not and will never be about streaming IO effects...but knowing what parts of IO fit into the semantic model of *value stream transformers* would yield a lot of insight. Also, most of the `Auto` "runners" (the functions that translate an `Auto` into `IO` that executes it) might be able to benefit from a more rigorous look too. * Tests; tests aren't really done yet, sorry! Working on those :)