camlspotter's answer is good enough already. I just want to add several more points here.
First of all, for the problem of
write a function that receives a finite list and returns an infinite, circular version of it, it can be done in code / implementation level, just if you really use the function, it will have stackoverflow problem and will never return.
A simple version of what you were trying to do is like this:
let rec circle1 xs = List.rev_append (List.rev xs) (circle1 xs)
val circle: 'a list -> 'a list = <fun>
It can be compiled and theoretically it is correct. On
[1;2;3], it is supposed to generate
However, of course, it will fail because its run will be endless and eventually stackoverflow.
let rec circle2 = 1::2::3::circle2 will work?
Let's see what will happen if you do it.
circle2 is a value and it is a list. After OCaml get this info, it can create a static address for circle2 with memory representation of list.
The memory's real value is
1::2::3::circle2, which actually is
Node (1, Node (2, Node (3, circle2))), i.e., A Node with int 1 and address of a Node with int 2 and address of a Node with int 3 and address of circle2. But we already know circle2's address, right? So OCaml just put circle2's address there.
Everything will work.
Also, through this example, we can also know a fact that for a infinite circled list defined like this actually doesn't cost limited memory. It is not generating a real infinite list to consume all memory, instead, when a circle finishes, it just jumps "back" to the head of the list.
Let's then go back to example of
circle1. Circle1 is a function, yes, it has an address, but we do not need or want it. What we want is the address of the function application
circle1 xs. It is not like circle2, it is a function application which means we need to compute something to get the address. So,
OCaml will do
List.rev xs, then try to get address
circle1 xs, then repeat, repeat.
Ok, then why we sometimes get
Error: This kind of expression is not allowed as right-hand side of 'let rec'?
the let rec binding construct, in addition to the definition of
recursive functions, also supports a certain class of recursive
definitions of non-functional values, such as
let rec name1 = 1 :: name2 and name2 = 2 :: name1 in expr which
binds name1 to the cyclic list 1::2::1::2::…, and name2 to the cyclic
list 2::1::2::1::…Informally, the class of accepted definitions
consists of those definitions where the defined names occur only
inside function bodies or as argument to a data constructor.
If you use
let rec to define a binding, say
let rec name. This
name can be only in either a function body or a data constructor.
In previous two examples,
circle1 is in a function body (
let rec circle1 = fun xs -> ...) and
circle2 is in a data constructor.
If you do
let rec circle = circle, it will give error as circle is not in the two allowed cases.
let rec x = let y = x in y won't do either, because again, x not in constructor or function.
Here is also a clear explanation:
Limitations of let rec