# Differences between pattern matching and unification?

I thought I understand how pattern matching like found in Scala and Haskell is different from unification found in Prolog but my misunderstands of Prolog is great. What is some simple problems solvable by one that cannot be solved by the other? Thank you

Simple statement: pattern matching is one-way, unification is two-way. That is, in Prolog the right-hand side (the one being matched against) can include unbound variables. E.g., if you have two unbound variables X and Y, this will work fine:

X = Y,
X = 5,
%% Y = 5 now as well

In Erlang (which uses pattern-matching with syntax close to Prolog), the line X = Y will produce an error: variable 'Y' is unbound. Note that X being unbound is fine: it is supposed to be pattern-matched.

This can be useful when you want to deal with partially-defined values. A very good example is difference lists.

This is also what allows use of Prolog predicate in multiple modes. E.g. in Scala/Haskell/Erlang, if you want to 1) find A ++ B, 2) solve the equation A ++ X == B, or 3) solve the equation X ++ A == B for given lists A and B, you need to write 3 separate functions; in Prolog, all these jobs (and more!) are done by one predicate.

• Exercise your Prolog pattern-matching skills at the SWI Prolog interactive editor SWISH, use the lower right REPL window. Note that unification is actually about imposing a series of constraints across expression trees (try to run f(g(X,Y),H) = f(Z,g(a,[L,X,Y])), X=12.), it may even handle infinite trees. Unification is an amazingly powerful idea, whole books have been written about this lowly algorithm, in particular about how to optimize it and there is still work to do. Nov 29, 2014 at 9:10
• Nonsense. Try to unificate this: ?- B = X + A, B is 3, A is 2. Jan 18, 2016 at 8:29
• @Feofilakt, "is" is a one way binding. You need to write terms for peano numbers: 0, s(0), s(s(0)), ... or depending on the problem you might expicityle state succ(zero, one), succ(one, two), ... In either case arithmetic becomes unifiable. Mar 13, 2016 at 21:00
• @Samuel Danielson, I know that arithmetic is unifiable, I just was resented by the Alexey Romanov's answer, that describes only advantages of unification in prolog and hides disadvantages. Explanations like this confuses prolog's beginners who will think that unification always works well (like me in some time). In real tasks unification becomes as powerful as pattern-matching, not more. Mar 15, 2016 at 7:26
• @Feofilakt Your example doesn't demonstrate any disadvantages of unification compared to pattern matching, because it won't work with PM either. So what are those disadvantages which this answer is hiding? Mar 15, 2016 at 9:41

I think it is useful to formalize the concepts, instead of looking into a specific language. Matching and unification are fundamental concepts that are used in more contexts than pattern matching and prolog.

• A term s matches t, iff there is a substitution phi such that phi(s) = t
• A term s unifies with a term t, iff there is a substitution such that phi(s) = phi(t)

To give an example we inspect the terms s = f(Y,a) and t = f(a,X) where X,Y are variables and a is a constant. s does not match t, because we cannot universally quantify the constant a. However, there is a unifier for s and t: phi = {X\a, Y\a}

The following in Scala would fail to compile, as it's first case branch attempts to declare the variable x twice.

(1, 1) match{
case (x, x) => println("equals")
case _      => println("not equals")
}

If Scala used unification instead of pattern matching this would succeed and print "equals" while

(1, 2) match{
case (x, x) => println("equals")
case _      => println("not equals")
}

would print "not equals". This is because the unification would fail when attempting to bind the variable x to both 1 and 2.

• Actually, this is the difference between linear (as in Scala and Haskell) and non-linear (as in Erlang and Mathematica) pattern matching. Dec 14, 2010 at 18:14

In Prolog, you can append [3] to [1,2] like this:

?- append([1,2], [3], Z).
Z = [1, 2, 3].

The neat thing about unification is that you can use the same code (the internal definition of 'append'), but instead find the second argument needed to get the result from the first argument:

?- append([1,2], Y, [1,2,3]).
Y = [3].

Rather than coding by writing "do this, then do that", you code in Prolog by saying what you know. Prolog treats the facts you give it as equations. Unification lets it take those equations and solve for whatever variables you don't yet know the values of, whether they're on the right or left side.

So, for instance, you can write a planner in Prolog, and you can run it "forward", giving it a plan and having it predict its results; or you can run it "backward", giving it a set of results and having it construct a plan. You could even run it both ways at once (if you were careful in your coding), specifying a set of goals and a set of constraints on the plan, so that you could say "Find a plan for getting to work that does not involve taking the subway."