Row + Implicit arguments + MLF(WIP).
Before implementing MLF:
choose: forall a. a -> a -> a
auto : forall a. a -> a
(choose auto) : (forall a. a —> a) -> (forall a. a -> a)
// if auto is defined without annotations, polymorphisms of lambdas get lost
auto2 : a -> a
(choose auto) : (a -> a) -> (a -> a)
Kind checker is not implemented.
- Temporary restrictions: cannot automatically compute principal types, so first class polys need annotations.
- Higher Order Unification:
TCState.inst_without_structure_preservedonly works when- Any cases of unifying 2 poly types
- A poly type contains free type variables, to unify it with a monotype, this poly type can only hold one bound variables.
- Unifying a monotype with, a poly type without free type variables.
Don't do this:
TCState.inst_without_structure_preserved(forall a b. a -> 'ftv) unify (a -> a)P.S: Currently, (forall a. a -> var) unify ((i -> j) -> (j -> i)) won't lead to failure, this is in the TO-DO list.
Actually, only when i and j are inferred to point to another non-variable type should above unification fail.
from hybridts import type_encoding as te
from hybridts.tc_state import TCState
tctx = {}
tcs = TCState(tctx)
x1 = te.InternalVar(is_rigid=False)
x2 = te.InternalVar(is_rigid=False)
int_t = te.InternalNom("base.int")
tcs.unify(x1, int_t)
tcs.unify(x1, x2)
assert tcs.infer(x1) == int_t
assert tcs.infer(x2) == int_t
x3 = te.InternalVar(is_rigid=False)
r1 = te.row_of_map({'a': x1, 'b': x3}, te.empty_row)
r1 = te.Record(r1)
tho = te.InternalVar(is_rigid=False)
r2 = te.row_of_map({'a': x3}, te.RowPoly(tho))
r2 = te.Record(r2)
tcs.unify(r1, r2)
print(tcs.infer(r1)) # {b: base.int, a: base.int}
print(tcs.infer(r2)) # {a: base.int, b: base.int}
int_t = te.InternalNom("int")
class Var(te.Var):
is_rigid = False
def __init__(self, name):
self.name = name
__repr__ = lambda self: self.name
ret = Var("ret")
# f: forall x. x -> ?ret
f = te.normalize_forall(["x"], te.Arrow(te.UnboundFresh('x'), ret))
sam = Var("sam")
zak = Var("zak")
# typeof(f_) = instantiate typeof(f)
# f_: x' -> ?ret'
_, f_ = tcs.inst_with_structure_preserved(f)
# x' -> ?ret' = sam -> zak
tcs.unify(f_, te.Arrow(sam, zak))
# zak = sam
tcs.unify(zak, sam)
print(tcs.infer(f_)) # sam -> sam
print(tcs.infer(f)) # forall x. x -> x
print(tcs.infer(zak)) # sam
ret = Var("ret")
# f: forall x. x -> ?ret
f = te.normalize_forall(["x", "y"],
te.Arrow(
te.UnboundFresh('x'),
te.Tuple(
(te.UnboundFresh("x"), te.UnboundFresh("y")))))
sam = Var("sam")
zak = Var("zak")
# typeof(f_) = instantiate typeof(f)
# f_: x' -> ?ret'
_, f_ = tcs.inst_without_structure_preserved(f)
# x' -> ?ret' = sam -> zak
tcs.unify(f_, te.Arrow(sam, te.Tuple((sam, sam))))
# zak = sam
# tcs.unify(zak, sam)
print(tcs.infer(f_)) # sam -> (sam, sam)
print(tcs.infer(f)) # forall x y. x -> (x, y)
# print(tcs.infer(zak))