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I'm studying functional programming and lambda calculus but I'm wondering if the closure term is also present in the Church's original work or it's a more modern term strictly concerned to programming languages.

I remember that in the Church's work there were the terms: free variable, closed into..., and so on.

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2 Answers 2

up vote 1 down vote accepted

Consider the following function definition in Scheme:

(define (adder a)
  (lambda (x) (+ a x)))

The notion of explicit closure is not required in the pure lambda calculus, because variable substitution takes care of it. The above code snippet can be translated

λa λx . (a + x)

When you apply this to a value z, it becomes

λx . (z + x)

by β-reduction, which involves substitution. You can call this closure over a if you want.

(The example uses a function argument, but this holds true for any variable binding, since in the pure lambda calculus all variable bindings must occur via λ terms.)

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So in the Church's work a lambda expression "is closed" over its free variables but the closure term is not explicitly said in that work! –  xdevel2000 Feb 18 '13 at 10:13
@xdevel2000 Actually, not over its free variables, but over the ones bound by λ abstractions. Similarly, in a programming language such as Scheme, closure does not occur over free variables: after (define (adder x) (+ a x)) where a is not yet defined, (define a 2) changes the behavior of adder. Not all programming languages allow this, of course. –  larsmans Feb 18 '13 at 10:23

It is a more modern term, due to (as many things in modern FP are), P. J. Landin (1964), The mechanical evaluation of expressions

Also we represent the value of a λ-expression by a bundle of information called a "closure," comprising the λ-expression and the environment relative to which it was evaluated.

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