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Milney Hindley

I often see notation like this in Haskell papers, but I have no clue what the hell any of it means. I have no idea what branch of mathematics it's supposed to be.

I recognize the letters of the Greek alphabet of course, and symbols such as "∉" (which usually means that something is not an element of a set).

On the other hand, I've never seen "⊢" before (Wikipedia claims it might mean "partition"). I'm also unfamiliar with the use of the vinculum here. (Usually it denotes a fraction, but that does not appear to be the case here.)

I imagine SO is not a good place to be explaining the entire Milner Hindley algorithm. But if somebody could at least tell me where to start looking to comprehend what this sea of symbols means, that would be helpful. (I'm sure I can't be the only person who's wondering...)

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L ⊢ x: T means in context L, x has type T .. –  Satvik Sep 21 '12 at 14:35
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Actually, HM is surprisingly simple--far simpler than I thought it would be. That's one of the reasons it's so magical. (More generally, that's one of the reasons CS is so magical: very often seemingly complex things turn out surprisingly elegant and simple once you see them in the right light.) –  Tikhon Jelvis Sep 21 '12 at 18:23
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I found the t-shirt in question here: cafepress.co.uk/skicalc.6225368 –  shang Sep 22 '12 at 17:58
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@AndrewC - Yes, that's the whole type system. It's still not quite an algorithm, because it's not always clear which rule to apply in a given situation; for instance you could go on forever applying Inst and Gen alternately and never terminate. Those two rules are really the problem. Fortunately the only place where you really need to use Inst is in conjunction with Var, and the only place you need to use Gen is in conjunction with Let, so it's not hard to modify these rules to make a so-called "syntax-directed" version which is close to an algorithm. –  pelotom Oct 7 '12 at 11:03

6 Answers 6

up vote 388 down vote accepted
  • The horizontal bar means that "[above] implies [below]".
  • If there are multiple expressions in [above], then consider them anded together; all of the [above] must be true in order to guarantee the [below].
  • : means has type
  • means is in. (Likewise means "is not in".)
  • Γ is usually used to refer to an environment or context; in this case it can be thought of as a set of type annotations, pairing an identifier with its type. Therefore x : σ ∈ Γ means that the environment Γ includes the fact that x has type σ.
  • can be read as proves or determines. Γ ⊢ x : σ means that the environment Γ determines that x has type σ.
  • , is a way of including specific additional assumptions into an environment Γ.
    Therefore, Γ, x : τ ⊢ e : τ' means that environment Γ with the additional, overriding assumption that x has type τ proves that e has type τ'.
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@RafaelCaetano instead of "proves", you could also read the turnstyle as "implies". The idea "assuming A, make judgement B" is essentially the same idea as "A implies B". Usually I imagine that we are dealing with some particular Γ; once under that assumption, "proves" sounds more impressive than "implies". –  Dan Burton Sep 27 '12 at 7:13
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In this context, "⊑" means "subtype of" MathematicalOrchid (see the answer supplied by Matt Fenwick). It's a partial ordering relation. –  Phil Armstrong Sep 27 '12 at 13:32
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@PhilArmstrong I didn't think Haskell had subtyping. Presumably this means that if one type can be made to look like another by substituting some of its type variables. (?) –  MathematicalOrchid Sep 29 '12 at 9:52
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@MathematicalOrchid That's right. Haskell has a kind of subtyping due to polymorphism called subsumption. You can read about it in this paper. –  pelotom Oct 7 '12 at 4:35
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@DanBurton I believe the turnstile (⊢) is also read as "entails". It's subtly different from from implication. I haven't messed with this stuff in a while, so please correct me if I'm wrong, but as I recall, it's sort of a meta statement about the logic you're using, whereas implication is within the logic. In other words, you either have to prove an implication or have it as an axiom, but an entailment is taken as a given based on the rules of your system. In typed lambda calculus, it's used to track the context and its modifications by the rules. –  acjay Apr 26 '13 at 13:40

This syntax, while it may look complicated, is actually fairly simple. The basic idea comes from logic: the whole expression is an implication with the top half being the assumptions and the bottom half being the result. That is, if you know that the top expressions are true, you can conclude that the bottom expressions are true as well.

Symbols

Another thing to keep in mind is that some letters have traditional meanings; particularly, Γ represents the "context" you're in—that is, what the types of other things you've seen are. So something like Γ ⊢ ... means "the expression ... when you know the types of every expression in Γ.

The symbol essentially means that you can prove something. So Γ ⊢ ... is a statement saying "I can prove ... in a context Γ. These statements are also called type judgements.

Another thing to keep in mind: in math, just like ML and Scala, x : σ means that x has type σ. You can read it just like Haskell's x :: σ.

What each rule means

So, knowing this, the first expression becomes easy to understand: if we know that x : σ ∈ Γ (that is, x has some type σ in some context Γ), then we know that Γ ⊢ x : σ (that is, in Γ, x has type σ). So really, this isn't telling you anything super-interesting; it just tells you how to use your context.

The other rules are also simple. For example, take [App]. This rule has two conditions: e₀ is a function from some type τ to some type τ' and e₁ is a value of type τ. Now you know what type you will get by applying e₀ to e₁! Hopefully this isn't a surprise :).

The next rule has some more new syntax. Particularly, Γ, x : τ just means the context made up of Γ and the judgement x : τ. So, if we know that the variable x has a type of τ and the expression e has a type τ', we also know the type of a function that takes x and returns e. This just tells us what to do if we've figured out what type a function takes and what type it returns, so it shouldn't be surprising either.

The next one just tells you how to handle let statements. If you know that some expression e₁ has a type τ as long as x has a type σ, then a let expression which locally binds x to a value of type σ will make e₁ have a type τ. Really, this just tells you that a let statement essentially lets you expand the context with a new binding—which is exactly what let does!

The [Inst] rule deals with sub-typing. It says that if you have a value of type σ' and it is a sub-type of σ ( represents a partial ordering relation) then that expression is also of type σ.

The final rule deals with generalizing types. A quick aside: a free variable is a variable that is not introduced by a let-statement or lambda inside some expression; this expression now depends on the value of the free variable from its context.The rule is saying that if there is some variable α which is not "free" in anything in your context, then it is safe to say that any expression whose type you know e : σ will have that type for any value of α.

How to use the rules

So, now that you understand the symbols, what do you do with these rules? Well, you can use these rules to figure out the type of various values. To do this, look at your expression (say f x y) and find a rule that has a conclusion (the bottom part) that matches your statement. Let's call the thing you're trying to find your "goal". In this case, you would look at the rule that ends in e₀ e₁. When you've found this, you now have to find rules proving everything above the line of this rule. These things generally correspond to the types of sub-expressions, so you're essentially recursing on parts of the expression. You just do this until you finish your proof tree, which gives you a proof of the type of your expression.

So all these rules do is specify exactly—and in the usual mathematically pedantic detail :P—how to figure out the types of expressions.

Now, this should sound familiar if you've ever used Prolog—you're essentially computing the proof tree like a human Prolog interpreter. There is a reason Prolog is called "logic programming"! This is also important as the first way I was introduced to the H-M inference algorithm was by implementing it in Prolog. This is actually surprisingly simple and makes what's going on clear. You should certainly try it.

Note: I probably made some mistakes in this explanation and would love it if somebody would point them out. I'll actually be covering this in class in a couple of weeks, so I'll be more confident then :P.

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\alpha is a non-free type variable, not a usual variable. So to explain generalization rule much more must be explained. –  nponeccop Sep 22 '12 at 14:55
    
@nponeccop: Hmm, good point. I haven't actually seen that particular rule before. Could you help me explain it properly? –  Tikhon Jelvis Sep 22 '12 at 18:03
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@TikhonJelvis: It's actually pretty straightforward, it allows you to generalize (assuming Γ = {x : τ}) λy.x : σ → τ to ∀ σ. σ → τ, but not to ∀ τ. σ → τ, because τ is free variable in Γ. Wikipedia article on HM explains it quite nicely. –  Vitus Sep 24 '12 at 19:57
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This is so much more helpful than the accepted answer. upvoted. Thanks! –  Jason Apr 26 '13 at 1:48

if somebody could at least tell me where to start looking to comprehend what this sea of symbols means

See "Practical Foundations of Programming Languages.", chapters 2 and 3, on the style of logic through judgements and derivations. The entire book is now available on Amazon.

Chapter 2

Inductive Definitions

Inductive definitions are an indispensable tool in the study of programming languages. In this chapter we will develop the basic framework of inductive definitions, and give some examples of their use. An inductive definition consists of a set of rules for deriving judgments, or assertions, of a variety of forms. Judgments are statements about one or more syntactic objects of a specified sort. The rules specify necessary and sufficient conditions for the validity of a judgment, and hence fully determine its meaning.

2.1 Judgments

We start with the notion of a judgment, or assertion about a syntactic object. We shall make use of many forms of judgment, including examples such as these:

  • n natn is a natural number
  • n = n1 + n2n is the sum of n1 and n2
  • τ typeτ is a type
  • e : τ — expression e has type τ
  • ev — expression e has value v

A judgment states that one or more syntactic objects have a property or stand in some relation to one another. The property or relation itself is called a judgment form, and the judgment that an object or objects have that property or stand in that relation is said to be an instance of that judgment form. A judgment form is also called a predicate, and the objects constituting an instance are its subjects. We write a J for the judgment asserting that J holds of a. When it is not important to stress the subject of the judgment, (text cuts off here)

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The notation comes from natural deduction.

⊢ symbol is called turnstile.

The 6 rules are very easy.

Var rule is rather trivial rule - it says that if type for identifier is already present in your type environment, then to infer the type you just take it from the environment as is.

App rule says that if you have two identifiers e0 and e1 and can infer their types, then you can infer the type of application e0 e1. The rule reads like this if you know that e0 :: t0 -> t1 and e1 :: t0 (the same t0!), then application is well-typed and the type is t1.

Abs and Let are rules to infer types for lambda-abstraction and let-in.

Inst rule says that you can substitute a type with less general one.

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This is sequent calculus, not natural deduction. –  Roman Cheplyaka Sep 21 '12 at 17:48
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@RomanCheplyaka well, the notation is much the same. The wikipedia article has an interesting comparison of the two techniques: en.wikipedia.org/wiki/Natural_deduction#Sequent_calculus . The sequent calculus was born in direct response to the failings of natural deduction, so if the question is "where did this notation come from", then "natural deduction" is technically a more correct answer. –  Dan Burton Sep 22 '12 at 17:59
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That's five rules.... –  AndrewC Sep 22 '12 at 21:54
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@RomanCheplyaka Another consideration is that sequent calculus is purely syntactic (that's why there are so many structural rules) while this notation is not. The first rule assumes that context is a set while in sequent calculus it's a simpler syntactic construct. –  nponeccop Sep 23 '12 at 11:24
    
@Cheplyaka actually, no, it has something that looks like a "sequent" but it is not sequent calculus. Haper develops an understanding of this in his text book as a "higher order judgment." This really is natural deduction. –  Philip JF Apr 28 '13 at 23:16

I imagine SO is not a good place to be explaining the entire Milner Hindley algorithm.

If you are looking for a good explanation of the algorithm, the best that I've found so far is in chapter 30 of Shriram Krinshnamurthi's Programming Languages: Application and Interpretation (CC licensed!). Here's one good reason why it's a good explanation: examples!

enter image description here

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I showed this to the author. He asked me to point out that the book also explains the notation from scratch, for beginners. –  Greg Hendershott Apr 25 '13 at 16:10
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Will update, thanks. –  laslowh Apr 25 '13 at 18:15

There are two ways to think of e : σ. One is "the expression e has type σ", another is "the ordered pair of the expression e and the type σ".

View Γ as the knowledge about the types of expressions, implemented as a set of pairs of expression and type, e : σ.

The turnstyle ⊢ can means that from the knowledge on the left, we can deduce what's on the right.

The first rule [Var] can thus be read: If our knowledge Γ contains the pair e : σ, then we can deduce from Γ that e has type σ.

The second rule [App] can be read: If we from Γ can deduce that e_0 has the type τ → τ', and we from Γ can deduce that e_1 has the type τ, then we from Γ can deduce that e_0 e_1 has the type τ'.

It's common to write Γ, e : σ instead of Γ ∪ {e : σ}.

The third rule [Abs] can thus be read: If we from Γ extended with x : τ can deduce that e has type τ', then we from Γ can deduce that λx e has the type τ → τ'.

The fourth rule [Let] is left as an exercise. :-)

The fifth rule [Inst] can be read: If we from Γ can deduce that e has type σ', and σ' is a subtype of σ, then we from Γ can deduce that e has type σ.

The sixth and last rule [Gen] can be read: If we from Γ can deduce that e has type σ, and α is not a free type variable in any of the types in Γ, then we from Γ can deduce that e has type ∀α σ.

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