This is the lambda calculus representation for the AND operator:
lambda(m).lambda(n).lambda (a).lambda (b). m(n a b) b
Can anyone help me in understanding this representation?
To understand how to represent Booleans in lambda calculus, it helps to think about an IF expression, "if a then b else c". This is an expression which chooses the first branch, b, if it is true, and the second, c, if it is false. Lambda expressions can do that very easily:
will give you the first of its arguments, and
gives you the second. So if a is one of those expressions, then
Looking inside your expression at
This expression evaluates to
All this was invented by Alonzo Church, who invented the lambda calculus.
In the lambda calculus, a Boolean is represented by a function that takes two arguments, one for success and one for failure. The arguments are called continuations, because they continue with the rest of the computation; the boolean True calls the success continuation and the Boolean False calls the failure continuation. This coding is called the Church encoding, and the idea is that a Boolean is very much like an "if-then-else function".
So we can say
Now I hope you can see where this is going. How do we code
Only these are functions, so
BUT, the ternary construct, when coded in the lambda calculus, is just function application, so we have
So finally we arrive at
And if we rename the success and failure continuations to
As with other computations in lambda calculus, especially when using Church encodings, it is often easier to work things out with algebraic laws and equational reasoning, then convert to lambdas at the end.
Actually it's a little more than just the AND operator. It's the lambda calculus' version of
In lambda calculus true is represented as a function taking two arguments* and returning the first. False is represented as function taking two arguments* and returning the second.
The function you showed above takes four arguments*. From the looks of it m and n are supposed to be booleans and a and b some other values. If m is true, it will evaluate to its first argument which is
So basically the function returns a if both m and n are true and b otherwise.
(*) Where "taking two arguments" means "taking an argument and returning a function taking another argument".
Edit in response to your comment:
The first step is simply to replace each identifier with its definition, i.e.