Difference between revisions of "Netwire"

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Netwire is a library for [[Functional Reactive Programming|functional reactive programming]], which uses the concept of [[Arrow|arrows]] for modelling an embedded domain-specific language. This language lets you express reactive systems, which means systems that change over time. It shares the basic concept with [[Yampa]] and its fork Animas, but it is itself not a fork.
 +
Netwire is a library for [[Functional Reactive Programming|functional reactive programming]], which uses the concept of [[Arrow|arrows]] for modelling an embedded domain-specific language. This language lets you express reactive systems, which means systems that change over time. It shares the basic concept with [[Yampa]] and its fork Animas, but it is itself not a fork and has many additional features.
  +
  +
* [http://hackage.haskell.org/package/netwire Download netwire]
  +
  +
This wiki page corresponds to Netwire version 3 and is currently a work in progress.
   
:[http://hackage.haskell.org/package/netwire Download netwire]
  
   
 
== Features ==
  
== Features ==
   
Here is a list of some of the features of ''netwire'':
 +
Here is a list of some of the features of Netwire:
   
* arrowized interface,
 +
* arrow interface (or optionally an applicative interface),
  +
* signal inhibition (ArrowZero / Alternative),
* applicative interface,
  
* signal inhibition (''ArrowZero'' / ''Alternative''),
 +
* signal selection (ArrowPlus / Alternative),
  +
* self-adjusting wires (ArrowChoice),
* choice and combination (''ArrowPlus'' / ''Alternative''),
  
* self-adjusting wires (''ArrowChoice''),
  
 
* rich set of event wires,
  
* rich set of event wires,
 
* signal analysis wires (average, peak, etc.),
  
* signal analysis wires (average, peak, etc.),
* impure wires.
 +
* effectful wires.
   
== Quickstart ==
  
   
  +
== Basics ==
This is a quickstart introduction to Netwire for Haskell programmers familiar with arrowized functional reactive programming (AFRP), for example Yampa or Animas. It should quickly give you an idea of how the library works and how it differs from the two mentioned.
  
   
  +
The Netwire library is based around a data type called <hask>Wire</hask>. You need to import the <hask>Control.Wire</hask> module to work with wires:
=== The wire ===
  
 
Netwire calls its signal transformation functions ''wires''. You can think of a wire as a device with an input line and an output line. The difference between a function and a wire is that a wire can change itself throughout its lifetime. This is the basic idea of arrowized FRP. It gives you time-dependent values.
  
 
A wire is parameterized over an underlying monad and its input and output types:
  
   
 
<haskell>
  
<haskell>
  +
import Control.Wire
data Wire m a b
  
</haskell>
  
   
  +
data Wire e (>~) a b
 
=== Differences from Yampa ===
  
 
If you are not familiar with Yampa or Animas, you can safely skip this section.
  
 
The main difference between Yampa and Netwire is that the underlying arrow is impure. While you can choose not to use the impure wires inside of the '''FRP.NetWire.IO''' module, it is a design choice for this library to explicitly allow impure computations. One theoretical implication is that you need to differentiate between pure stateless, pure stateful and impure signal transformations.
  
 
A concept not found in Yampa is signal inhibition. A wire can choose not to return anything. This way you can temporarily block entire subnetworks. This is most useful with the combination operator ''<+>''. Example:
  
 
<haskell>
  
w = w1 <+> w2
  
 
</haskell>
  
</haskell>
   
  +
For some arrows <hask>(>~)</hask> and all monoids <hask>e</hask> the type <hask>Wire e (>~)</hask> is an arrow. Only certain arrows are allowed for <hask>(>~)</hask>, because <hask>Wire</hask> is actually a data family. These arrows are called base arrows in Netwire.
The ''w'' wire runs its signal through the wire ''w1'', and if it inhibits, it passes the signal to ''w2''.
  
 
Another concept not found in Yampa is choice. Through the ''ArrowChoice'' instance wires allow you to choose one of a set of subwires for its signal without needing a switch. Essentially you can write ''if'' and ''case'' constructs inside of arrow notation.
  
 
=== Using a wire ===
  
 
To run a wire you will need to use the ''withWire'' and ''stepWire'' functions. The ''withWire'' initializes a wire and gives you a ''Session'' value. As mentioned earlier in general a wire is a function, which can mutate itself over time. The session value captures the current state of the wire.
  
   
 
<haskell>
  
<haskell>
withWire :: Wire IO a b -> (Session IO a b -> IO c) -> IO c
 +
comp :: Wire e (>~) a b
stepWire :: a -> Session IO a b -> IO (Output b)
  
 
</haskell>
  
</haskell>
   
  +
Values of type <hask>Wire e (>~) a b</hask> are time-varying functions, which resemble the following type:
The ''stepWire'' function passes the given input value through the wire. If you use ''stepWire'', then the wire will mutate in real time. If you need a different rate of time, you can use ''stepWireDelta'' or ''stepWireTime'' instead. The ''stepWireDelta'' function takes a time delta, and the ''stepWireTime'' function takes the current time (which doesn't need to be the real time):
  
   
 
<haskell>
  
<haskell>
  +
a >~ Either e b
stepWireDelta :: NominalDiffTime -> a -> Session IO a b -> IO (Output b)
  
stepWireTime :: UTCTime -> a -> Session IO a b -> IO (Output b)
  
 
</haskell>
  
</haskell>
   
  +
So it's a function that takes a value of type <hask>a</hask> and either produces a value of type <hask>b</hask> or produces no value, but instead ''inhibits'' with a value of type <hask>e</hask>. The act of running a wire is called ''stepping'' and the process is called an ''instant''. You can step a wire through one of the stepping functions, which we will cover later. When you step a wire, it will return a new version of itself along with its result. You are supposed to call the new version the next time you step.
(These type signatures are not actually the same as you'll find in the library; they have been simplified for the sake of teaching.)
  
   
  +
=== The inhibition monoid ===
Note that it is allowed to give zero or negative deltas and times, which are earlier than the last time. This lets you run the system backwards in time. If you do that, your wire should be prepared to handle it properly.
  
   
  +
The <hask>e</hask> argument to <hask>Wire</hask> is called the inhibition monoid. For simple applications you can just use <hask>()</hask> here, but you may want to actually assign exception values to inhibition. We will cover that later. For now just use <hask>()</hask>.
The stepping functions return a ''Output b'', which is just an alias for ''Either SomeException b'':
  
   
  +
=== Base arrows ===
<haskell>
  
type Output a = Either SomeException a
  
</haskell>
  
   
  +
The <hask>(>~)</hask> argument to <hask>Wire</hask> is called the base arrow. In most cases you will use a <hask>Kleisli</hask> arrow here, and this is currently the only type of arrow supported, though more will be added in the future. For simple applications you can just use the <hask>IO</hask> monad, and it is useful to define a type alias for your custom wire type:
If the wire inhibits, then the result is ''Left e'' (where ''e :: SomeException''), otherwise it will be ''Right b'', with ''b'' being the output. Here is a complete example:
  
   
 
<haskell>
  
<haskell>
  +
type MyWire = Wire () (Kleisli IO)
{-# LANGUAGE Arrows #-}
  
 
module Main where
  
 
import Control.Monad
  
import FRP.NetWire
  
import Text.Printf
  
 
 
myWire :: Wire IO () String
  
myWire =
  
proc _ -> do
  
t <- time -< ()
  
fps <- avgFps 1000 -< ()
  
fpsPeak <- highPeak -< fps
  
 
if t < 4
  
then identity -< "Waiting four seconds."
  
else identity -<
  
printf "Got them! (%8.0f FPS, peak: %8.0f)"
  
fps fpsPeak
  
 
 
main :: IO ()
  
main = withWire myWire loop
  
where
  
loop :: Session IO () String -> IO ()
  
loop session =
  
forever $ do
  
output <- stepWire () session
  
case output of
  
Left e -> putStrLn $ "Wire failed with " ++ show e
  
Right x -> putStrLn x
  
 
</haskell>
  
</haskell>
   
This program should display the string "Waiting four seconds." for four seconds and then switch to a string, which displays the current average frames per second and peak frames per second.
  
   
  +
== Running wires ==
Note: Sessions are thread-safe. You are allowed to use the stepping functions for the same session from multiple threads. This makes it easy to implement conditional stepping based on system events.
  
   
  +
For running a wire you can use the stepping functions available in the <hask>Control.Wire.Session</hask> module. There is no need to import that module. It is automatically imported with <hask>Control.Wire</hask>. For Kleisli-based wires you will want to use the <hask>stepWireM</hask> function:
Note: The type signatures of all Wires have an implicit ''Monad'' constraint on its first parameter. This constraint has been omitted for the sake of brevity.
  
 
== Signal inhibition ==
  
 
A wire may choose not to return anything, at which point it is said to be inhibiting. If the whole wire network inhibits, then the stepping functions will return ''Left e'', where ''e :: SomeException''. Otherwise, a ''Right'' value is returned.
  
 
If a wire in a sequence of wires inhibits, the later wires are not run.
  
 
== Writing a wire ==
  
 
I will assume that you are familiar with arrow notation, and I will use it instead of the raw arrow combinators most of the time. If you haven't used arrow notation before, see the [http://www.haskell.org/ghc/docs/latest/html/users_guide/arrow-notation.html GHC arrow notation manual].
  
 
=== Time ===
  
 
To use this library you need to understand the concept of time very well. Netwire has a continuous time model, which means that when you write your applications you disregard the discrete steps, in which your wire is executed.
  
 
Technically at each execution instant (i.e. each time you run ''stepWire'' or one of the other stepping functions) the wire is fed with the input as well as a time delta, which is the time passed since the last instant. Hence wires do not by themselves keep track of what time it is, since most applications don't need that anyway. If you need a clock, you can use the predefined ''time'' wire, which will be explained later.
  
 
Wires have a local time, which can be different from the global time. This can happen, when a wire is not actually run, because an earlier wire inhibited the signal. It also happens, when you use choice. For example you can easily write a gateway, which repeatedly runs one wire the one second and another wire the other second. While one wire is run, the other wire is suspended, including its local time.
  
 
Local time is a switching effect, which is especially visible, when you use the switching combinators from '''FRP.NetWire.Switch'''. Local time starts when switching in.
  
 
Time is measured in ''Double'' in Netwire. To improve type signatures there is a type alias defined for you:
  
   
 
<haskell>
  
<haskell>
  +
stepWireM ::
type Time = Double
  
  +
Monad m
  +
=> Wire e (Kleisli m) a b
  +
-> a
  +
-> m (Either e b, Wire e (Kleisli m) a b)
 
</haskell>
  
</haskell>
   
  +
In our case we have <hask>m = IO</hask>, so our type signature is simply:
''Time'' is used to refer to local time and time deltas, i.e. time differences. It is represented in seconds.
  
 
=== Pure stateless wires ===
  
 
Pure stateless wires are easy to explain, so let's start with them. A pure stateless wire is essentially just a function of input. The simplest wire is the ''identity'' wire. It just returns its input verbatim:
  
   
 
<haskell>
  
<haskell>
  +
stepWireM :: MyWire a b -> a -> IO (Either () b, MyWire a b)
identity :: Wire m a a
  
 
</haskell>
  
</haskell>
   
  +
This function takes a wire and an input value. It passes the input value to the wire and returns its result value of type <hask>Either () b</hask>. Along with the result it also returns a new wire. Normally you would call <hask>stepWireM</hask> in a loop, which performs instant after instant. This is the basic structure:
If you run such a wire (see the previous section), then you will just get your input back all the time. Another simple wire is the ''constant'' wire, which also disregards time:
  
   
 
<haskell>
  
<haskell>
  +
system :: MyWire Int String
constant :: b -> Wire m a b
  
  +
system = {- ... -}
</haskell>
  
   
  +
main :: IO ()
If you run the wire <code>constant 15</code>, you will get as output the number 15 all the time, regardless of the current time and the input.
  
  +
main = loop system
  +
where
  +
loop :: MyWire Int String -> IO ()
  +
loop w' = do
  +
(mx, w) <- stepWireM w' 15
   
  +
{- ... do something with mx ... -}
:'''Note''': You can express ''identity'' as ''arr id'', but you should prefer ''identity'', because it's faster. Likewise you can express ''constant x'' as ''arr (const x)'', but again you should prefer ''constant''.
  
   
  +
loop w -- loop with the new wire.
=== Pure stateful wires ===
  
 
Let's see a slightly more interesting wire. The ''time'' wire will return the current local time. What ''local'' means in this context was explained earlier.
  
 
<haskell>
  
time :: Wire m a Time
  
</haskell>
  
 
As the type suggests, time is measured in seconds and represented as a ''Time''. The local time starts from 0 at the point, where the wire starts to run. There is also a wire, which counts time from a different origin:
  
 
<haskell>
  
timeFrom :: Time -> Wire a Time
  
 
</haskell>
  
</haskell>
   
  +
Note: Even though the FRP idea suggests it, there is no reason to run wires continuously or even regularly. You can totally have an instant depending on user input, a GUI event or network traffic, so instants can be minutes apart.
The difference between these stateful and the stateless wires from the previous section is that stateful wires mutate themselves over time. The ''timeFrom x'' wire calculates the current time as ''x'' plus the current time delta. Let's say that sum is ''y''. It then mutates into the wire ''timeFrom y''. As you can see there is no internal clock. It is really this self-mutation, which gives you a clock.
  
   
=== Calculus ===
 +
=== Testing wires ===
   
  +
There is a convenient function for testing wires, which does all the plumbing for you. It's called <hask>testWireM</hask>:
One of the compelling features of FRP is integration and differentiation over time. It is a very cheap operation to integrate over time. In fact the ''time'' wire you have seen in the last section is really just the integral of the constant 1. Here is the type of the ''integral'' wire, which integrates over time:
  
   
 
<haskell>
  
<haskell>
  +
testWireM ::
integral :: Double -> Wire m Double Double
  
  +
(Show e, MonadIO m)
  +
=> Int
  +
-> m a
  +
-> Wire e (Kleisli m) a String
  +
-> m ()
 
</haskell>
  
</haskell>
   
  +
For wires returning a string, you can easily test them using this function. The first argument is a FPS/accuracy tradeoff. If it's 100, it will only print the output of every 100th instant. The second argument is an input generator action. At each instant, this action is run and its result is passed as input to the wire. The wire's output is then printed. <hask>testWireM</hask> prints the output continuously on a single line:
The argument is the integration constant or starting value. The input is the subject of integration. Let's write a clock, which runs at half the speed of the real clock:
  
   
 
<haskell>
  
<haskell>
  +
main :: IO ()
slowClock :: Wire m a Double
  
  +
main = testWireM 1000 (return 15) system
slowClock = proc _ -> integral 0 -< 0.5
  
 
</haskell>
  
</haskell>
   
Since the integration constant is 0, the time will start at zero. Integration becomes more interesting, as soon as you integrate non-constants:
  
   
  +
== Writing wires ==
<haskell>
  
particle :: Monad m => Wire m a Double
  
particle =
  
proc _ -> do
  
v <- integral 1 -< -0.1
  
integral 15 -< v
  
</haskell>
  
   
  +
=== Predefined wires ===
This wire models a one-dimensional particle, which starts at position 15 and velocity +1. A constant acceleration of -0.1 per second per second is applied to the velocity, hence the particle moves right towards positive infinity at first, while gradually becoming slower, until it reverses its direction and moves left towards negative infinity.
  
   
  +
There are numerous predefined wires, which you can compose using the arrow interface. We will practice that with three very simple predefined wires (the type signatures are simplified for the sake of learning):
The above type signature is actually a special case, which I provided for the sake of simplicity. The real type signature is a bit more interesting:
  
   
 
<haskell>
  
<haskell>
  +
constant :: b -> Wire e (>~) a b
integral ::
  
  +
identity :: Wire e (>~) b b
(Monad m, NFData v, VectorSpace v, Scalar v ~ Double) =>
  
v -> Wire m v v
 +
countFrom :: Enum b => b -> Wire e (>~) a b
 
</haskell>
  
</haskell>
   
  +
The ''constant'' function takes an output value and produces a wire which produces that value constantly. So the wire <hask>constant 15</hask> will output 15 constantly at every instant. In other words, <hask>stepWireM</hask> will return <hask>Right 15</hask> along with a new wire that outputs 15 again:
You can integrate over time in any real vector space. Some examples of vector spaces include tuples, complex numbers and any type, for which you define ''NFData'' and ''VectorSpace'' instances. Let's see the particle example in two dimensions:
  
   
 
<haskell>
  
<haskell>
  +
stepWireM (constant 15) inp
particle2D :: Monad m => Wire m a (Double, Double)
  
  +
-> (Right 15, constant 15)
particle2D =
  
proc _ -> do
  
v <- integral (1, -0.5) -< (-0.1, 0.4)
  
integral (0, 0) -< v
  
 
</haskell>
  
</haskell>
   
  +
Note the fully polymorphic input type <hask>a</hask>. This basically means that the wire disregards its input, so whatever <hask>inp</hask> is, it is ignored.
Differentiation works similarly, although there are two variants:
  
   
  +
The ''identity'' wire is slightly more interesting. It has input and output of type <hask>b</hask>. What it does is: It simply outputs its input value at every instant:
<haskell>
  
derivative :: Wire m Double Double
  
derivativeFrom :: Double -> Wire m Double Double
  
</haskell>
  
 
The difference between the two variants is that ''derivative'' will inhibit at the first instant (inhibition is explained later), because it needs at least two samples to compute the rate of change over time. The ''derivativeFrom'' variant does not have that shortcoming, but you need to provide the first sample as an argument.
  
 
Again I have simplified the types to help understanding. Just like with integration you can differentiate over any vectorspace, as long as your type has an ''NFData'' instance.
  
 
=== Events ===
  
 
Events are a useful tool to add discrete values to the system. As the name states an event usually denotes some condition or external event, which can be present at some instants and absent at others. A common use case for events is user input. Events are wires that run if the event that it models has occurred and inhibit if otherwise.
  
 
There is a large number of event wires in the '''FRP.NetWire.Event''' module. I will give you examples for some of the common ones here. It is worthwhile to have a look at the aforementioned module.
  
 
==== after ====
  
   
 
<haskell>
  
<haskell>
  +
stepWireM identity inp
after :: Time -> Wire m a a
  
  +
-> (Right inp, identity)
 
</haskell>
  
</haskell>
   
  +
Both identity and constant wires are examples of ''stateless'' wires. They don't change over time. You can see this in the stepping examples above. They always return themselves for the next instant.
The ''after'' wire causes an event after a certain number of seconds. This means that the wire inhibits until the specified time has passed, at which point it runs for a single instant. After that the event never happens again, i.e. it always inhibits.
  
   
  +
The ''countFrom'' function takes a starting value and returns a wire that returns sequential values instant by instant. This is the first example of a ''stateful'' wire, because it changes over time:
==== once ====
  
   
 
<haskell>
  
<haskell>
  +
stepWireM (countFrom 15) inp
once :: Wire m a a
  
  +
-> (Right 15, countFrom 16)
</haskell>
  
   
  +
stepWireM (countFrom 16) inp
This wire produces an event at the first instant and never again.
  
  +
-> (Right 16, countFrom 17)
 
==== repeatedly ====
  
 
<haskell>
  
repeatedly :: Wire m (Time, a) a
  
 
</haskell>
  
</haskell>
   
  +
=== Composing wires ===
This wire takes two input signals. It produces events repeatedly after the time delta given by the left signal. This delta can change over time, making the event happen more or less frequently. The right signal is the desired event value.
  
   
  +
The main feature of wires is that you can compose them using the arrow interface. There is a rich set of ways for composing, and you will want to use arrow notation for your convenience:
==== hold ====
  
   
 
<haskell>
  
<haskell>
  +
system :: MyWire a String
hold :: Wire m a b -> Wire m a b
  
  +
system =
  +
proc _ -> do
  +
c1 <- countFrom 10 -< ()
  +
c2 <- countFrom 20 -< ()
  +
identity -< printf "%d %d" (c1 :: Int) (c2 :: Int)
 
</haskell>
  
</haskell>
   
  +
In applications it is common to write wires that ignore their input. For those wires you should make the input type fully polymorphic to indicate this. Running this wire produces:
This wire turns events into continuous signals. It inhibits until the first signal from the argument wire. Each time the input event occurs, the output switches to its value and keeps it until the next event occurs.
  
 
=== Random numbers ===
  
 
Netwire provides a few wires for random noise generation. Probably the most important one is the ''noise'' wire:
  
   
 
<haskell>
  
<haskell>
  +
stepWireM system ()
noise :: Wire m a Double
  
</haskell>
  
   
  +
1st instant: Right "10 20"
This wire outputs a random number between 0 (inclusive) and 1 (exclusive). The underlying random number generator is a fast implementation of the Mersenne Twister algorithm provided by Don Stewart's [http://hackage.haskell.org/package/mersenne-random mersenne-random] package.
  
  +
2nd instant: Right "11 21"
 
  +
3rd instant: Right "12 22"
=== Signal analysis ===
  
 
Netwire provides some wires to perform signal analysis. One useful wire is ''diff'':
  
 
<haskell>
  
diff :: Eq a => Wire m a (a, Time)
  
 
</haskell>
  
</haskell>
   
  +
Note: You can use the ''testWireM'' function with this wire. The following action will run the wire continuously printing its result at every 1000th instant:
This wire emits an event, whenever the input signal changes. The event contains the last value as well as the time elapsed since then. One possible use case is file monitoring. Pass the file's modification time or even its contents as the input signal. This wire inhibits on no change.
  
 
Another useful wire is ''avg'', which computes the average value of the input signal over the specified number of most recent samples:
  
   
 
<haskell>
  
<haskell>
  +
main :: IO ()
avg :: Int -> Wire m Double Double
  
  +
main = testWireM 1000 (return ()) system
 
</haskell>
  
</haskell>
   
  +
In the FRP context we often talk about ''signals''. Particularly in the context of ''arrowized'' FRP (AFRP) like Netwire we talk about ''signal networks'' and signals passing through them. The ''system'' wire is your first signal network. It ignores its input signal and passes the signal <hask>()</hask> to the two counters (which ignore their input signals, too). It takes the output signals <hask>c1</hask> and <hask>c2</hask> and makes a formatted string out of them. Finally this string is passed to the <hask>identity</hask> wire. This is the last wire in the signal network ''system'', so its output signal is the output signal of ''system''. As a side note the ''identity'' wire behaves like ''returnA''.
Since the ''noise'' wire returns random numbers between 0 and 1, if you pass the output of ''noise'' through ''avg x'' you should get a value close to 0.5, if the argument ''x'' is suitably large:
  
   
  +
The main feature to note here is that all of the subwires in the composition evolve individually. So in the second instant, each of the two counters will have gone up by one. This alone gives you a powerful abstraction for stateful computations. The equivalent when using a state monad or mutable variables would be to have a global state value with two counter values. By having time-varying functions you can have something called ''local state''. Each of the two counters (or as many as you use) have their own individual local state, which is the current counter value. This is way more convenient and composable than a state monad or other imperative state abstractions.
<haskell>
  
avgOfNoise :: Wire m a Double
  
avgOfNoise = avg 1000 <<< noise
  
</haskell>
  
   
  +
=== Choice ===
An interesting special case of ''avg'' is the ''avgFps'' wire, which is very useful for performance analysis. It returns the average frames per second:
  
   
  +
In traditional AFRP solutions like Yampa the path of a signal is fully determined by the structure of the signal network. In Netwire a signal can choose one of multiple paths by using the <hask>case</hask> and <hask>if</hask> constructs:
<haskell>
  
avgFps :: Int -> Wire m a Double
  
</haskell>
  
 
Both ''avg'' and ''avgFps'' calculate the average over a certain number of most recent samples. While they have a constant time complexity O(1) they have a linear space complexity of O(n), where ''n'' is the number of samples. In some cases it can be fine to consider calculating the average over all samples forever. The ''avgAll'' wire does exactly that:
  
   
 
<haskell>
  
<haskell>
  +
system =
avgAll :: Wire Double Double
  
  +
proc _ -> do
  +
c1 <- countFrom 10 -< ()
  +
if even c1
  +
then returnA -< "We don't want even c1"
  +
else do
  +
c2 <- countFrom 20 -< ()
  +
returnA -< printf "%d %d" (c1 :: Int) (c2 :: Int)
 
</haskell>
  
</haskell>
   
  +
If the <hask>c1</hask> signal is even, then the wire outputs the string "We don't want even c1". Otherwise it takes the second path. Here it is important to know that the second counter will be suspended, when <hask>c1</hask> is even, because the <hask>else</hask> branch is not reached. A wire can only evolve, when it is actually reached. So in this example <hask>c2</hask> will run at half the speed of <hask>c1</hask> and the output will look like:
Unlike ''avg'' and ''avgFps'' this variant uses not only constant time, but also constant space.
  
 
There are also wires for finding peaks. The ''highPeak'' and ''lowPeak'' wires output the high and low peaks respectively for their input:
  
   
 
<haskell>
  
<haskell>
  +
1st instant: "We don't want even c1"
highPeak :: (NFData a, Ord a) => Wire m a a
  
  +
2nd instant: "11 20"
lowPeak :: (NFData a, Ord a) => Wire m a a
  
  +
3rd instant: "We don't want even c1"
  +
4th instant: "13 21"
  +
5th instant: "We don't want even c1"
  +
6th instant: "15 22"
  +
7th instant: "We don't want even c1"
 
</haskell>
  
</haskell>
   
  +
[[Category:FRP]]
Again the type signatures are only special cases. See the library documentation for the real types. In short, you can get averages of any fractional input value.
  
 
=== Unique request numbers ===
  
 
Sometimes you might want to generate numbers, which are unique throughout the wire session. For example you might want to manage game objects, open file handles or something similar. The ''identifier'' wire generates such unique numbers:
  
 
<haskell>
  
identifier :: MonadIO m => Wire m a Int
  
</haskell>
  
 
At the first instance it chooses a unique number and then returns that number forever.
  
 
=== Impure wires ===
  
 
As noted earlier wires are allowed to perform impure operations:
  
 
<haskell>
  
execute :: MonadIO m => Wire m (m a) a
  
</haskell>
  
 
The ''execute'' wire is the simplest wire for impure operations. It takes an ''IO'' action as its input signal and outputs its result. If the action throws an exception, then this wire inhibits.
  
 
You may want to combine this wire with the ''diff'' wire to develop a wire, which reacts to changes, or with the ''sample'' wire, which periodically samples a wire given a time delta, or with the ''swallow'' wire, which transmits the first signal from an input wire forever.
  
 
<haskell>
  
liftWire :: Monad m => Wire m (m a) a
  
</haskell>
  
 
The ''liftWire'' wire lifts the given monadic computation to a wire. The action is run at every instant, and never inhibits.
  
 
== Choice ==
  
 
Wires can branch into multiple subwires, sending a signal to a subset of them. The easiest method to do that is using the ''ArrowChoice'' instance, which effectively enables you to use ''if'' and ''case'' inside of arrow notation:
  
 
<haskell>
  
myWire :: Monad m => Wire m Double Double
  
myWire =
  
proc x -> do
  
t <- time -< ()
  
if t < 4
  
then identity -< x
  
else integral 0 -< 0.2
  
</haskell>
  
 
This wire acts like the identity wire for four seconds and then switches into a clock, which starts at 0 and runs at 1/5 of the speed of time. The clock indeed starts at 0, because choice is exclusive. The wires, which have not been chosen are suspended. This effectively freezes their local time.
  
 
Another method to perform choice is to use one of the parallel switches, which are explained in a later section.
  
 
=== Inhibiting ===
  
 
There are many ways to inhibit, the simplest being unconditional inhibition, which can be done with the ''inhibit_'' wire:
  
 
<haskell>
  
inhibit_ :: Wire m a b
  
</haskell>
  
 
This wire disregards its input and doesn't return. Internally, this wire throws an ''InhibitException'' which you'll notice when running ''stepWire''. Note that ''inhibit'' is just a better name for the ''zeroArrow'' wire from the ''ArrowZero'' type class. You can use that one, if you prefer.
  
 
If you would like to inhibit with your custom exception type, you can use the ''inhibit'' wire:
  
 
<haskell>
  
inhibit :: Exception e => Wire m e b
  
</haskell>
  
 
In general you would prefer inhibition based on a predicate, for which there exist multiple ways. One simple way is to use ''inhibit_'' together with choice:
  
 
<haskell>
  
waitOneSecond :: Monad m => Wire m a a
  
waitOneSecond =
  
proc x -> do
  
t <- time -< ()
  
if t < 1 then inhibit_ -< ()
  
else identity -< x
  
</haskell>
  
 
This wire inhibits for one second and after that acts like the identity wire. Note that there is another way to write this wire using some of the predefined wires:
  
 
<haskell>
  
waitOneSecond :: Monad m => Wire m a a
  
waitOneSecond =
  
proc x -> do
  
ev <- after 1 -< ()
  
swallow wait -< ev
  
identity -< x
  
</haskell>
  
 
The ''after'' wire was explained earlier. It will emit an event after one second. The ''wait'' wire extracts the event's value and returns it, unless no event happened, at which point it simply inhibits. However, the event occurs only once, so this would normally act like the identity wire for an instant and then return to inhibition. This is where ''swallow'' comes into play.
  
 
<haskell>
  
swallow :: Wire m a b -> Wire m a b
  
</haskell>
  
 
The ''swallow'' wire encapsulates the wire given as its argument and modifies its behaviour in the following way: As long as the inner wire inhibits, the ''swallow'' wire also inhibits, but as soon as the inner wire produces a result, ''swallow'' switches into the constant wire with that result. In other words, it waits for the first signal from the inner wire and then keeps that result forever.
  
 
In this case ''wait'' would only produce a result once, but because it is wrapped by ''swallow'' this result is kept forever and the inner ''wait'' wire is dropped from the network.
  
 
The ''swallow'' function is actually our first wire transformer. It takes a wire and encapsulates it, modifying its behaviour.
  
 
=== Combining ===
  
 
You can combine two wires using the ''<+>'' combinator. This combinator comes from the ''ArrowPlus'' class and takes two wires as its argument. It passes the signal through the left wire. If that wire inhibits, it passes the signal to the right wire. The result of the first non-inhibiting wire is returned. If both wires inhibit, their combination inhibits.
  
 
Note that if the first wire results, the second one is not run at all, thus ''<+>'' is left-biased. The following identities hold:
  
 
<haskell>
  
w1 <+> inhibit = w1
  
inhibit <+> w2 = w2
  
</haskell>
  
 
=== Exhibition ===
  
 
Sometimes you may want to observe inhibition. You can use the ''exhibit'' wire transformer for that purpose:
  
 
<haskell>
  
exhibit :: Wire m a b -> Wire m a (Output b)
  
-- type Output a = Either SomeExpection a
  
</haskell>
  
 
It takes its argument wire and runs the input signal through it. If the inner wire inhibits, then ''exhibit'' returns a ''Left'' value. It never inhibits. Thus the following identity holds:
  
 
<haskell>
  
exhibit w1 <+> w2 = exhibit w1
  
</haskell>
  
 
Note that this suggests correctly that signal inhibition can be interpreted as arrow exceptions, and ''exhibit'' acts like the ''try'' combinator.
  
 
== Looping ==
  
 
''Wires'' have a ''ArrowLoop'' instance. There is a catch, though: Right now wires which produce values used recursively must not inhibit. There is an inherent problem handling the inhibition case, which you will observe as a pattern match error.
  

Revision as of 18:17, 1 December 2011

Netwire is a library for functional reactive programming, which uses the concept of arrows for modelling an embedded domain-specific language. This language lets you express reactive systems, which means systems that change over time. It shares the basic concept with Yampa and its fork Animas, but it is itself not a fork and has many additional features.

This wiki page corresponds to Netwire version 3 and is currently a work in progress.


Features

Here is a list of some of the features of Netwire:

  • arrow interface (or optionally an applicative interface),
  • signal inhibition (ArrowZero / Alternative),
  • signal selection (ArrowPlus / Alternative),
  • self-adjusting wires (ArrowChoice),
  • rich set of event wires,
  • signal analysis wires (average, peak, etc.),
  • effectful wires.


Basics

The Netwire library is based around a data type called Wire. You need to import the Control.Wire module to work with wires: 

import Control.Wire

data Wire e (>~) a b

For some arrows (>~) and all monoids e the type Wire e (>~) is an arrow. Only certain arrows are allowed for (>~), because Wire is actually a data family. These arrows are called base arrows in Netwire. 

comp :: Wire e (>~) a b

Values of type Wire e (>~) a b are time-varying functions, which resemble the following type: 

a >~ Either e b

So it's a function that takes a value of type a and either produces a value of type b or produces no value, but instead inhibits with a value of type e. The act of running a wire is called stepping and the process is called an instant. You can step a wire through one of the stepping functions, which we will cover later. When you step a wire, it will return a new version of itself along with its result. You are supposed to call the new version the next time you step.

The inhibition monoid

The e argument to Wire is called the inhibition monoid. For simple applications you can just use () here, but you may want to actually assign exception values to inhibition. We will cover that later. For now just use ().

Base arrows

The (>~) argument to Wire is called the base arrow. In most cases you will use a Kleisli arrow here, and this is currently the only type of arrow supported, though more will be added in the future. For simple applications you can just use the IO monad, and it is useful to define a type alias for your custom wire type: 

type MyWire = Wire () (Kleisli IO)


Running wires

For running a wire you can use the stepping functions available in the Control.Wire.Session module. There is no need to import that module. It is automatically imported with Control.Wire. For Kleisli-based wires you will want to use the stepWireM function: 

stepWireM ::
    Monad m
    => Wire e (Kleisli m) a b
    -> a
    -> m (Either e b, Wire e (Kleisli m) a b)

In our case we have m = IO, so our type signature is simply: 

stepWireM :: MyWire a b -> a -> IO (Either () b, MyWire a b)

This function takes a wire and an input value. It passes the input value to the wire and returns its result value of type Either () b. Along with the result it also returns a new wire. Normally you would call stepWireM in a loop, which performs instant after instant. This is the basic structure: 

system :: MyWire Int String
system = {- ... -}

main :: IO ()
main = loop system
    where
    loop :: MyWire Int String -> IO ()
    loop w' = do
        (mx, w) <- stepWireM w' 15

        {- ... do something with mx ... -}

        loop w  -- loop with the new wire.

Note: Even though the FRP idea suggests it, there is no reason to run wires continuously or even regularly. You can totally have an instant depending on user input, a GUI event or network traffic, so instants can be minutes apart.

Testing wires

There is a convenient function for testing wires, which does all the plumbing for you. It's called testWireM: 

testWireM ::
    (Show e, MonadIO m)
    => Int
    -> m a
    -> Wire e (Kleisli m) a String
    -> m ()

For wires returning a string, you can easily test them using this function. The first argument is a FPS/accuracy tradeoff. If it's 100, it will only print the output of every 100th instant. The second argument is an input generator action. At each instant, this action is run and its result is passed as input to the wire. The wire's output is then printed. testWireM prints the output continuously on a single line: 

main :: IO ()
main = testWireM 1000 (return 15) system


Writing wires

Predefined wires

There are numerous predefined wires, which you can compose using the arrow interface. We will practice that with three very simple predefined wires (the type signatures are simplified for the sake of learning): 

constant  :: b -> Wire e (>~) a b
identity  :: Wire e (>~) b b
countFrom :: Enum b => b -> Wire e (>~) a b

The constant function takes an output value and produces a wire which produces that value constantly. So the wire constant 15 will output 15 constantly at every instant. In other words, stepWireM will return Right 15 along with a new wire that outputs 15 again: 

stepWireM (constant 15) inp
-> (Right 15, constant 15)

Note the fully polymorphic input type a. This basically means that the wire disregards its input, so whatever inp is, it is ignored.

The identity wire is slightly more interesting. It has input and output of type b. What it does is: It simply outputs its input value at every instant: 

stepWireM identity inp
-> (Right inp, identity)

Both identity and constant wires are examples of stateless wires. They don't change over time. You can see this in the stepping examples above. They always return themselves for the next instant.

The countFrom function takes a starting value and returns a wire that returns sequential values instant by instant. This is the first example of a stateful wire, because it changes over time: 

stepWireM (countFrom 15) inp
-> (Right 15, countFrom 16)

stepWireM (countFrom 16) inp
-> (Right 16, countFrom 17)

Composing wires

The main feature of wires is that you can compose them using the arrow interface. There is a rich set of ways for composing, and you will want to use arrow notation for your convenience: 

system :: MyWire a String
system =
    proc _ -> do
        c1 <- countFrom 10 -< ()
        c2 <- countFrom 20 -< ()
        identity -< printf "%d %d" (c1 :: Int) (c2 :: Int)

In applications it is common to write wires that ignore their input. For those wires you should make the input type fully polymorphic to indicate this. Running this wire produces: 

stepWireM system ()

1st instant: Right "10 20"
2nd instant: Right "11 21"
3rd instant: Right "12 22"

Note: You can use the testWireM function with this wire. The following action will run the wire continuously printing its result at every 1000th instant: 

main :: IO ()
main = testWireM 1000 (return ()) system

In the FRP context we often talk about signals. Particularly in the context of arrowized FRP (AFRP) like Netwire we talk about signal networks and signals passing through them. The system wire is your first signal network. It ignores its input signal and passes the signal () to the two counters (which ignore their input signals, too). It takes the output signals c1 and c2 and makes a formatted string out of them. Finally this string is passed to the identity wire. This is the last wire in the signal network system, so its output signal is the output signal of system. As a side note the identity wire behaves like returnA.

The main feature to note here is that all of the subwires in the composition evolve individually. So in the second instant, each of the two counters will have gone up by one. This alone gives you a powerful abstraction for stateful computations. The equivalent when using a state monad or mutable variables would be to have a global state value with two counter values. By having time-varying functions you can have something called local state. Each of the two counters (or as many as you use) have their own individual local state, which is the current counter value. This is way more convenient and composable than a state monad or other imperative state abstractions.

Choice

In traditional AFRP solutions like Yampa the path of a signal is fully determined by the structure of the signal network. In Netwire a signal can choose one of multiple paths by using the case and if constructs: 

system =
    proc _ -> do
        c1 <- countFrom 10 -< ()
        if even c1
          then returnA -< "We don't want even c1"
          else do
              c2 <- countFrom 20 -< ()
              returnA -< printf "%d %d" (c1 :: Int) (c2 :: Int)

If the c1 signal is even, then the wire outputs the string "We don't want even c1". Otherwise it takes the second path. Here it is important to know that the second counter will be suspended, when c1 is even, because the else branch is not reached. A wire can only evolve, when it is actually reached. So in this example c2 will run at half the speed of c1 and the output will look like: 

1st instant: "We don't want even c1"
2nd instant: "11 20"
3rd instant: "We don't want even c1"
4th instant: "13 21"
5th instant: "We don't want even c1"
6th instant: "15 22"
7th instant: "We don't want even c1"
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