Here's a sketch of a proof.
Given that a program must be of finite size, all types defined within the program must contain only finitely many members and reference only finitely many other types. The same holds for any program entrypoint and for any objects defined before program initialisation.
In the absence of contiguous arrays (which are the product of a type with a runtime natural number and are therefore unconstrained in size), all types must be arrived at through the composition of types as above; derivation of types (pointer-to-pointer-to-
A) is still constrained by the size of the program. There are no facilities other than contiguous arrays to compose a runtime value with a type.
This is a little contentious; if e.g. mappings are considered primitive then one can approximate an array with a map whose keys are the natural numbers. Of course, any implementation of a map must use self-referential data structures (B-trees) or contiguous arrays (hash tables).
Next, if the types are non-recursive then any chain of types (
C...) must terminate, and can be of no greater length than the number of types defined in the program. Thus the total size of data referenceable by the program is limited to the product of the sizes of each type multiplied by the number of names defined in the program (in its entrypoint and static data).
This holds even if functions are recursive (which strictly speaking breaks the prohibition on recursive types, since functions are types); the amount of data immediately visible at any one point in the program is still limited to the product of the sizes of each type multiplied by the number of names visible at that point.
An exception to this is if you store a "container" in a stack of recursive function calls; however such a program would not be able to traverse its data at random without unwinding the stack and having to reread data, which is something of a disqualification.
Finally, if it is possible to create types dynamically the above proof does not hold; we could for example create a Lisp-style list structure where each cell is of a distinct type:
cons<4>('h', cons<3>('e', cons<2>('l', cons<1>('l', cons<0>('o', nil))))). This is not possible in most static-typed languages, although it is possible in some dynamic languages e.g. Python.