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1.8 KiB
1.8 KiB
Conditional Constraints
Syntax
The front-end AST has a new constructor:
data BindDef name = DPropGuards [([Prop name], Expr name)] | ...
which is parsed from the following syntax:
<name> : <signature>
<name> <pats>
[ | <props> => <expr> ]
Expanding PropGuards
- Before renaming, a
Bind
with abDef = DPropGuards ...
will be expanded into severalBind
s, one for each guard case. - The generated
Bind
s will have fresh names, but the names will have the same location as the original function's name. - These generated
Bind
's will have the same type as the original function, except that the list of type constraints will also include theProp name
s that appeared on the LHS of the originating ase ofDPropGuards
. - The original function will have the
Expr name
in each of theDPropGuards
cases replaced with a function call the appropriate, generated function.
Renaming
The new constructor of BindDef
is traversed as normal during renaming. This ensures that a function with DPropGuards
ends up in the same mutual-recursion group as the generated functions that it calls.
Typechecking
The back-end AST has a new constructor:
data Expr = EPropGuards [([Prop], Expr)] | ...
During typechecking, a BindDef
of the form
DPropGuards [(props1, f1 x y), (prop2, f2 x y)]
is processed into a Decl
of the form
Decl
{ dDefinition =
DExpr (EPropGuards
[ (props1, f1 x y)
, (props2, f2 x y) ])
}
Each case of an EPropGuards
is typechecked by first asssuming the props
and then typechecking the expression. However, this typechecking isn't really that important because by construction the expression is just a simple application that is ensured to be well-typed. But we can use this structure for more general purposes.