Imagine a simple (made up) language where functions look like:
function f(a, b) = c + 42 where c = a * b
(Say it's a subset of Lisp that includes 'defun' and 'let'.)
Also imagine that it includes immutable objects that look like:
struct s(a, b, c = a * b)
Again analogizing to Lisp (this time a superset), say a struct definition like that would generate functions for:
make-s(a, b) s-a(s) s-b(s) s-c(s)
Now, given the simple set up, it seems clear that there is a lot of similarity between what happens behind the scenes when you either call 'f' or 'make-s'. Once 'a' and 'b' are supplied at call/instantiate time, there is enough information to compute 'c'.
You could think of instantiating a struct as being like a calling a function, and then storing the resulting symbolic environment for later use when the generated accessor functions are called. Or you could think of a evaluting a function as being like creating a hidden struct and then using it as the symbolic environment with which to evaluate the final result expression.
Is my toy model so oversimplified that it's useless? Or is it actually a helpful way to think about how real languages work? Are there any real languages/implementations that someone without a CS background but with an interest in programming languages (i.e. me) should learn more about in order to explore this concept?
EDIT: Thanks for the answers so far. To elaborate a little, I guess what I'm wondering is if there are any real languages where it's the case that people learning the language are told e.g. "you should think of objects as being essentially closures". Or if there are any real language implementations where it's the case that instantiating an object and calling a function actually share some common (non-trivial, i.e. not just library calls) code or data structures.
Does the analogy I'm making, which I know others have made before, go any deeper than mere analogy in any real situations?