I am studying compiler construction using Haskell. I am using fixed point data type recursion to represent abstract syntax trees (ast).
I am investigating how to write the type checker for a toy language having simple expressions (numeric and logic constants, binary operations and local variable declarations).
The type checker is a read-write-state (
- reader because it uses a context consisting of an environment with symbol definitions (an association list of a symbol and its type);
- writer because it generates a list of error messages;
- state will be needed later for implementing nominal type equivalence, and by now I am just counting how many variables are defined in the program (just as a demonstration of its use).
The value returned by the monad is an ast annotated with types (for expressions) or environments (for declarations).
checker receives an ast of the input program and results in a new ast annotated with
RWS monad actions that, when run, gives the type (if the ast is an expression) or the environment (if the ast is a declaration).
For instance, consider the input program
let x = 2 + 3 in 1 + x
with the corresponding ast:
Let | ----------------------- | | VarDec: x Bin Add | | | ------------ | | | Bin Add Num 1.0 Var x | ----------- | | Num 2.0 Num 3.0
Type checking it will produce the following ast:
action1 Let | ----------------------- | | action2 action3 VarDec: x Bin Add | | | ------------ | | | action4 action5 action6 Bin Add Num 1.0 Var x | ----------- | | action7 action8 Num 2.0 Num 3.0
which is recursively annotated with
RWS monad actions.
Later phases of the compiler will need to know the information produced by the annotations in the ast (and its children, recursively). Therefore it will be needed to run the corresponding action to get it.
A root action is constructed by composing the actions of the children, according to the rules of the language.
For instance, in order to get the type of the root expression (a let expression),
action1 has to be run, and that will make
action3 to be run as well, because when
action1 was created, it used
When the type of the addition
1+x is needed,
action3 has to be run in order to get it.
So actions will be run repeatedly. The way the type checker is structured (using
RWS monad actions) loses sharing of the computed information for each node of the ast.
Is there any technique to recover this sharing, eliminating the need of recomputing actions?