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What does this quote mean?

the list functor represents a context of nondeterministic choice;

In the context of Functors in functional programming.

I think I understand that a Functor is a "container" of some kind along with the ability to apply a function uniformly to elements in the container without altering the structure. So maybe is a Functor that represents a context or container with possible failure, but why does list represent a context or container with nondeterministic choice?

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Where is this quote from? I've heard of the list monad representing the nondeterministic choice, but not the list functor. – ivanm Apr 18 '12 at 23:40
The quote is from: – cuberoot Apr 19 '12 at 15:15

5 Answers 5

up vote 9 down vote accepted

As best as I can tell, a calculation is "nondeterministic" if it has multiple possible answers. Well, a list can contain multiple possible answers. So that's why.

(As to why it's called nondeterministic, I have no idea... I would have expected nondeterministic to mean random, which is something quite different.)

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Nondeterminism is not pure randomness, it is making an arbitrary choice between specific options. One way to model nondeterminism is to make all of the possible choices (and lists can be used for this model), though typically, when we talk about a nondeterministic machine, it only makes one choice, and we are unable to predict which choice it will make, though we know exactly what choices it could make. – Dan Burton Apr 18 '12 at 22:02
Yes: in the sense of the quote, lists are used as a low-rent multiset, and represent "nondeterministic choice" by keeping every possible outcome. – comingstorm Apr 18 '12 at 23:29
If it helps at all, this is the same "nondeterministic" as in an NFA (nondeterministic finite-state automata) or an NTM (nondeterministic Turing machine). – Tikhon Jelvis Apr 19 '12 at 0:13
Yeah, I'm aware of NTM, which is apparently where the term comes from. I just don't get why it's called "nondeterministic" when it does clearly follow set rules. – MathematicalOrchid Apr 19 '12 at 8:30
I suspect the TM definition of nondeterminism actually predates the "random" interpretation. – Louis Wasserman Apr 19 '12 at 18:23

Traditionally, in computability and complexity, a nondeterministic computation model has referred to a model in which case you can "branch". Wikipedia explains it like so:

In computational complexity theory, nondeterministic algorithms are ones that, at every possible step, can allow for multiple continuations (imagine a man walking down a path in a forest and, every time he steps further, he must pick which fork in the road he wishes to take). These algorithms do not arrive at a solution for every possible computational path; however, they are guaranteed to arrive at a correct solution for some path (i.e., the man walking through the forest may only find his cabin if he picks some combination of "correct" paths). The choices can be interpreted as guesses in a search process.

In the list monad, this is exactly what you're doing. For example, consider this solution to the decision version of the clique problem, in the list monad:

cliques :: Int -> Graph -> [[Node]]
cliques 0 _ = [[]]
cliques minCliqueSize graph = do
  v <- nodes graph
  vs <- cliques (minCliqueSize - 1) (deleteNode v graph)
  mapM_ (\ w -> guard (isAdjacent v w graph)) vs
  return (v:vs)

This is exactly how you'd program e.g. a nondeterministic Turing machine to solve the clique problem.

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"Classical" computations take 1 input and give 1 output. What you want to represent with these non-deterministic computations is: What can I say about the output if I am not sure about the input?

Two usual ways to represent the uncertainty is to consider:

  1. that the input is an element of a given set
  2. that the input is given by a known probability distribution

As an example, consider the function (2*) that doubles it input. What can you say about the output of that function when the input is the result of a die roll?

  1. I know the die has 6 faces so the result is in the set {2,4,6,8,10,12}
  2. I know the probabilities of each face is 1/6 so I know that each of these numbers has probability 1/6 to appear

The list functor represents non-deterministic computations in the sense of 1.: it represents sets by lists.

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Consider the following:

foo = do
  x <- [1 .. 10]
  y <- [2, 3, 5, 7]
  return (x * y)

What is foo? Well, it is x * y, except with the nondeterministic choices of x being a number from 1 to 10, and y being either 2, 3, 5, or 7. Therefore, foo is [2, 3, 5, 7, 4, 6, 10, 14, etc... ]

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In addition to viewing a functor as a container, you can also view it as a certain kind of context. Your values are in that context, and if you want to operate on them, you use map to lift a function into the context. Another way of putting it is that your values are augmented with that context.

To understand how the list functor is a context of nondeterministic choice, it may be useful to see how another functor is a context: The Maybe functor is a context of a computation that may fail. If you try to apply a function to a value in a Maybe functor, the resulting value will still keep the same context of whether or not it was a failed computation in the first place.

In the same way, a list can be seen as the result of a computation that does not have a deterministic result, but whose result might instead be chosen nondeterministically from one of several values. If you tried to map a function over a list with 3 elements, those elements would be changed, but the context of being able to choose between three values would remain the same.

Borrowing a bit from Dan Burtons answer, look at the monadic notation for lists:

foo = do
  x <- [1 .. 10]
  y <- [2, 3, 5, 7]
  return (x * y)

It seems at first a bit odd, since the notation seems to indicate, that you could extract a single value from each of the lists, but then you get as result a list that is 40 elements long. It makes more sense when you look at functors (well, monads in this case) as a context for a single value. In the example, x and y are such values, but their context is that they are nondeterministic. When you multiply two such values, you get even more nondeterminism, resulting in a longer list. So with monads and >>=, the context can be changed, whereas with functors and map, it cannot.

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