I'm writing a little Haskell compiler, and I want to implement as much Haskell 2010 as possible. My compiler can parse a module, but completing modules to a program seems to be a non-trivial task. I made up some examples of tricky, but maybe valid, Haskell modules:
module F(G.x) where import F as G x = 2
Here the module
G.x is the same as
F.x, so module
x if, and only if, it exports
module A(a) where import B(a) a = 2 module B(a) where import A(a)
In this example, to resolve the exports of module
A the compiler has to check if
a imported from
B is the same as the declared
a = 2, but
a if, and only if,
module A(f) where import B(f) module B(f) where import A(f)
During resolving module
A, the compiler may've assumed that
f imported from
B exists, implying that
B can import
A(f) and export
f. The only problem is that there's no
f defined anywhere :).
module A(module X) where import A as X import B as X import C as X a = 2 module B(module C, C.b) where import C b = 3 module C(module C) import B as C c = 4
module exports cause that export lists are dependent on each other and on themselves.
All these examples should be valid Haskell, as defined by the Haskell 2010 spec.
I want to ask if there is any idea how to correctly and completely implement Haskell modules?
Assume that a module contains just (simple) variable bindings,
imports (possibly with
qualified), and exports list of possibly qualified variables and
module ... abbreviations. The algorithm has to be able to:
- compute finite list of exported variables of each module
- link every exported variable to its binding
- link every (maybe qualified) variable used in every module to its binding