The simplest way to handle your problem is indeed recursive modules. I don't advise you to use them, as recursive modules can make your code harder to read, compile and can in the most complex cases break your code at run time. Not to mention if you use side-effects in your module definitions (please don't).
I will use the OCaml syntax, you should be able to easily translate to Reason.
If you want to go with that anyway, here is the quick and dirty solution, using recursive module and functors.
The quick and dirty solution
1) Create a module myModTypes that will indicate the expected types of module2 and module3. It should look like:
module type Module2type = sig ... end
module type Module3type = sig ... end
... being the expected signatures of your modules (if you already have interface files written, just copy/paste them here, if you don't write those, they are important)
2) Put module2 and module3 within functors expecting the other module
For example, the code of module2 should now look like
module MakeModule2(Module3 : MyModTypes.Module3type) = struct
(* the code of module2 *)
The code of module3 will be in the same way, just swap 2 and 3 in the added lines.
3) Create a module makemodules2and3 with that code (translated to Reason):
module rec Module2 : MyModTypes.Module2type = Module2.MakeModule2(Module3)
and Module3 : MyModTypes.Module3type = Module3.MakeModule3(Module2)
Note that recursive module definitions always expect a module type.
4) Subsequent uses of
Module3 should now
open Makemodules2and3 before being able to use them.
The right solution
You have to change the architecture of your program. Slightly.
As the OP said, there are no cycle of dependency in the functions, and that's a relief. Just split module2 and module3 into two new modules each. One with the functions that only depend on module1 and their own module, one with the "next step" functions.
This is a better way to approach how you declare your modules: they should be one with the types they define. Ideally, you have a module for each type, plus one additional module for each interaction between types.