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In computer science, coinduction is a technique for defining and proving properties of systems of concurrent interacting objects.
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Coinduction is the mathematical dual to structural induction.[citation needed] Coinductively defined data types are known as codata and are typically infinite data structures, such as streams.
As a definition or specification, coinduction describes how an object may be "observed", "broken down" or "destructed" into simpler objects. As a proof technique, it may be used to show that an equation is satisfied by all possible implementations of such a specification.
To generate and manipulate codata, one typically uses corecursive functions, in conjunction with lazy evaluation. Informally, rather than defining a function by pattern-matching on each of the inductive constructors, one defines each of the "destructors" or "observers" over the function result.
In programming, co-logic programming (co-LP for brevity) "is a natural generalization of logic programming and coinductive logic programming, which in turn generalizes other extensions of logic programming, such as infinite trees, lazy predicates, and concurrent communicating predicates. Co-LP has applications to rational trees, verifying infinitary properties, lazy evaluation, concurrent logic programming, model checking, bisimilarity proofs, etc."[1] Experimental implementations of co-LP are available from the University of Texas at Dallas[2] and in the language Logtalk (for examples see [3]) and SWI-Prolog.
In [4] a concise statement is given of both the principle of induction and the principle of coinduction. While this article is not primarily concerned with induction, it is useful to consider their somewhat generalized forms at once. In order to state the principles, a few preliminaries are required.
Let be a set and be a monotone function , that is:
Unless otherwise stated, will be assumed to be monotone.
These terms can be intuitively understood in the following way. Suppose that is a set of assertions, and is the operation that yields the consequences of . Then is F-closed when you cannot conclude anymore than you've already asserted, while is F-consistent when all of your assertions are supported by other assertions (i.e. there are no "non-F-logical assumptions").
The Knaster–Tarski theorem tells us that the least fixed-point of (denoted ) is given by the intersection of all F-closed sets, while the greatest fixed-point (denoted ) is given by the union of all F-consistent sets. We can now state the principles of induction and coinduction.
The principles, as stated, are somewhat opaque, but can be usefully thought of in the following way. Suppose you wish to prove a property of . By the principle of induction, it suffices to exhibit an F-closed set for which the property holds. Dually, suppose you wish to show that . Then it suffices to exhibit an F-consistent set that is known to be a member of.
Consider the following grammar of datatypes:
That is, the set of types includes the "bottom type" , the "top type" , and (non-homogenous) lists. These types can be identified with strings over the alphabet . Let denote all (possibly infinite) strings over . Consider the function :
In this context, means "the concatenation of string , the symbol , and string ." We should now define our set of datatypes as a fixpoint of , but it matters whether we take the least or greatest fixpoint.
Suppose we take as our set of datatypes. Using the principle of induction, we can prove the following claim:
To arrive at this conclusion, consider the set of all finite strings over . Clearly cannot produce an infinite string, so it turns out this set is F-closed and the conclusion follows.
Now suppose that we take as our set of datatypes. We would like to use the principle of coinduction to prove the following claim:
Here denotes the infinite list consisting of all . To use the principle of coinduction, consider the set:
This set turns out to be F-consistent, and therefore . This depends on the suspicious statement that
The formal justification of this is technical and depends on interpreting strings as sequences, i.e. functions from . Intuitively, the argument is similar to the argument that (see Repeating decimal).
Consider the following definition of a stream:[5]
data Stream a = S a (Stream a)
-- Stream "destructors"
head (S a astream) = a
tail (S a astream) = astream
This would seem to be a definition that is not well-founded, but it is nonetheless useful in programming and can be reasoned about. In any case, a stream is an infinite list of elements from which you may observe the first element, or place an element in front of to get another stream.
Source:[6]
Consider the endofunctor in the category of sets:
The final F-coalgebra has the following morphism associated with it:
This induces another coalgebra with associated morphism . Because is final, there is a unique morphism
such that
The composition induces another F-coalgebra homomorphism . Since is final, this homomorphism is unique and therefore . Altogether we have:
This witnesses the isomorphism , which in categorical terms indicates that is a fixpoint of and justifies the notation.
We will show that
Stream A
is the final coalgebra of the functor . Consider the following implementations:
out astream = (head astream, tail astream)
out' (a, astream) = S a astream
These are easily seen to be mutually inverse, witnessing the isomorphism. See the reference for more details.
We will demonstrate how the principle of induction subsumes mathematical induction. Let be some property of natural numbers. We will take the following definition of mathematical induction:
Now consider the function :
It should not be difficult to see that . Therefore, by the principle of induction, if we wish to prove some property of , it suffices to show that is F-closed. In detail, we require:
That is,
This is precisely mathematical induction as stated.
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