I have heard the term "coalgebras" several times in functional programming and PLT circles, especially when the discussion is about objects, comonads, lenses, and such. Googling this term gives pages that give mathematical description of these structures which is pretty much incomprehensible to me. Can anyone please explain what coalgebras mean in the context of programming, what is their significance, and how they relate to objects and comonads?
I think the place to start would be to understand the idea of an algebra. This is just a generalization of algebraic structures like groups, rings, monoids and so on. Most of the time, these things are introduced in terms of sets, but since we're among friends, I'll talk about Haskell types instead. (I can't resist using some Greek letters though—they make everything look cooler!)
An algebra, then, is just a type
The simplest example of this is the monoid. A monoid is any type
All the functions operate on
An algebra is just a common pattern in mathematics that's been "factored out", just like we do with code. People noticed that a whole bunch of interesting things—the aforementioned monoids, groups, lattices and so on—all follow a similar pattern, so they abstracted it out. The advantage of doing this is the same as in programming: it creates reusable proofs and makes certain kinds of reasoning easier.
However, we're not quite done with factoring. So far, we have a bunch of functions
We can actually use this transformation repeatedly to combine all the
This lets us talk about algebras as a type
We can do the same thing for groups and rings and lattices and all the other possible structures.
What else is special about all these types? Well, they're all
So we can generalize our idea of an algebra even more. It's just some type
This is often called an "F-algebra" because it's determined by the functor
Now, hopefully you have a good grasp of what an algebra is and how it's just a generalization of normal algebraic structures. So what is an F-coalgebra? Well, the co implies that it's the "dual" of an algebra—that is, we take an algebra and flip some arrows. I only see one arrow in the above definition, so I'll just flip that:
And that's all it is! Now, this conclusion may seem a little flippant (heh). It tells you what a coalgebra is, but does not really give any insight on how it's useful or why we care. I'll get to that in a bit, once I find or come up with a good example or two :P.
Classes and Objects
After reading around a bit, I think I have a good idea of how to use coalgebras to represent classes and objects. We have a type
As shown in the algebra example, if we have a bunch of functions like
The elements of our type
We want methods that can take an argument and modify state. To do this, we need to take all the arguments and produce a new
The important pattern here is that the "methods" and "properties" of the object take the object itself as their first argument. This is just like the
So let's put it all together. Let's imagine a class with a
We need two parts to represent this class. First, we need to represent the internal state of the object; in this case it just holds two
We have two properties to write. They're pretty trivial:
Now we just need to be able to update the position:
This is just like a Python class with its explicit
This lets us use coalgebraic reasoning to deal with classes. For example, we can bring in the notion of an "F-coalgebra homomorphism" to represent transformations between classes. This is a scary sounding term that just means a transformation between coalgebras that preserves structure. This makes it much easier to think about mapping classes onto other classes.
In short, an F-coalgebra represents a class by having a bunch of properties and methods that all depend on a
So far, we've talked about algebras and coalgebras as Haskell types. An algebra is just a type
However, nothing really ties these ideas to Haskell per se. In fact, they're usually introduced in terms of sets and mathematical functions rather than types and Haskell functions. Indeed,we can generalize these concepts to any categories!
We can define an F-algebra for some category
What do we gain by considering other categories? Well, we can use the same ideas in different contexts. Like monads. In Haskell, a monad is some type
Functors form a category themselves, with morphisms between them being so-called "natural transformations". A natural transformation is just a way to transform one functor into another while preserving its structure. Here's a nice article helping explain the idea. It talks about
With Haskell functors, the composition of two functors is a functor itself. In pseudocode, we could write this:
This helps us think about
Now we can think about a monad as just an algebra based around some functor
So a monad is just like a monoid, except instead of having a type we have a functor. It's the same sort of algebra, just in a different category. (This is where the phrase "A monad is just a monoid in the category of endofunctors" comes from as far as I know.)
Now, we have these two operations:
So a comonad is then a coalgebra in a category of endofunctors.
F-algebras and F-coalgebras are mathematical structures which are instrumental in reasoning about inductive types (or recursive types).
We'll start first with F-algebras. I will try to be as simple as possible.
I guess you know what is a recursive type. For example, this is a type for a list of integers:
It is obvious that it is recursive - indeed, its definition refers to itself. Its definition consists of two data constructors, which have the following types:
Note that I have written type of
If we write signatures of these functions in a more set-theoretical way, we will get
Disjoint union of two sets
We can 'join'
Now consider another datatype:
It has the following constructors:
which also can be joined into one function:
It can be seen that both of this
We can immediately notice that any algebraic type can be written in this way. Indeed, that is why they are called 'algebraic': they consist of a number of 'sums' (unions) and 'products' (cross products) of other types.
Now we can define F-algebra. F-algebra is just a pair
Afterwards we can introduce F-algebra homomorphisms and then initial F-algebras, which have very useful properties. In fact,
Nonetheless, the fact that, say,
It is possible to generalize such operation on any recursive datatype.
The following is a signature of
Note that I have used braces to separate first two arguments from the last one. This is not real
We can see that this is a function which takes a list of integers and returns a single integer. Let's define such function in terms of our
We see that this function consists of two parts: first part defines this function's behavior on
Now suppose that we are programming not in Haskell but in some language which allows usage of algebraic types directly in type signatures (well, technically Haskell allows usage of algebraic types via tuples and
It can be seen that
Just to make it more clear and help you see the pattern, here is another example, and we again begin from the resulting folding function. Consider
This how it looks on our
Again, let's try to write out the reductor:
So, essentially, F-algebras allow us to define 'folds' on recursive datastructures, that is, operations which reduce our structures to some value.
F-coalgebras are so-called 'dual' term for F-algebras. They allow us to define
Suppose you have the following type:
This is an infinite stream of integers. Its only constructor has the following type:
Or, in terms of sets
Haskell allows you to pattern match on data constructors, so you can define the following functions working on
You can naturally 'join' these functions into single function of type
Notice how the result of the function coincides with algebraic representation of our
Now, F-coalgebra is a pair
Among all F-coalgebras there are so-called terminal F-coalgebras, which are dual to initial F-algebras. For example,
Consider the following function, which generates a stream of successive integers starting from the given one:
Now let's inspect a function
Again, we can see some similarity between
Another example, a function which takes a value and a function and returns a stream of successive applications of the function to the value:
Its builder function is the following one:
So, in short, F-algebras allow to define folds, that is, operations which reduce recursive structure down into a single value, and F-coalgebras allow to do the opposite: construct a [potentially] infinite structure from a single value.
In fact in Haskell F-algebras and F-coalgebras coincide. This is a very nice property which is a consequence of presence of 'bottom' value in each type. So in Haskell both folds and unfolds can be created for every recursive type. However, theoretical model behind this is more complex than the one I have presented above, so I deliberately have avoided it.
Hope this helps.
Going through the tutorial paper A tutorial on (co)algebras and (co)induction should give you some insight about co-algebra in computer science.
Below is a citation of it to convince you,
Prelude, about Category theory. Category theory should be rename theory of functors. As categories are what one must define in order to define functors. (Moreover, functors are what one must define in order to define natural transformations.)
What's a functor? It's a transformation from one set to another which preserving their structure. (For more detail there is a lot of good description on the net).
What's is an F-algebra? It's the algebra of functor. It's just the study of the universal propriety of functor.
How can it be link to computer science ? Program can be view as a structured set of information. Program's execution correspond to modification of this structured set of information. It sound good that execution should preserve the program structure. Then execution can be view as the application of a functor over this set of information. (The one defining the program).
Why F-co-algebra ? Program are dual by essence as they are describe by information and they act on it. Then mainly the information which compose program and make them changed can be view in two way.
Then at this stage, I'd like to say that,
During the life of a program, data and state co-exist, and they complete each other. They are dual.