def make_norm_bijection(typ):
# TODO SKOLEM
ordered_vars = typ.gather_leaves(
lambda leaf: isinstance(leaf, TypVar), lambda *args: OrderedDict(
(a, True) for a in args))
proto_table = make_enum_table(ordered_vars.keys(), TypVar)
table, rev_table = utils.construct_bijection(proto_table)
return sub_m.Sub(table), sub_m.Sub(rev_table)
def __init__(self, typ, n):
self.tab = make_normalization_table(typ)
self.to_nf = sub.Sub(self.tab)
self.typ_nf = self.to_nf(typ)
self.n_nf = typ.get_next_var_id(
n
) # we need to ensure computation will respect the *old* typ and *old* n
def mainProgram():
print("메인프로그램")
class1 = sub.Sub(10, 20)
print(class1)
class2 = sub.Sub2(100000, 200000)
print(class2)
class2.submethod() ##print("서브에 있는 메서드입니다. ")
def denormalize_one(nf_sub_res):
sigma_nf = nf_sub_res.sub
sigma_table = {}
n = self.n_nf
for var_nf, tau_nf in sigma_nf.table.items():
var = from_nf(var_nf)
tau = from_nf(tau_nf)
sigma_table[var] = tau
n = max(n, tau.get_next_var_id())
return sub.SubRes(nf_sub_res.num, sub.Sub(sigma_table), n)
def denormalize_one(self, nf_sub_res, n):
sigma_nf = nf_sub_res.sub
sigma_table = {}
nvi = max(self.tnvi, n)
for var_nf, tau_nf in sigma_nf.table.items():
var = self.sub_from_nf(var_nf)
tau = self.sub_from_nf(tau_nf)
sigma_table[var] = tau
nvi = max(nvi, tau.get_next_var_id())
return sub.SubRes(nf_sub_res.num, sub.Sub(sigma_table), nvi)
def successors_typed(self, gamma, n):
alpha, n1 = new_var(self.typ, n)
typ_f = TypTerm.make_arrow(alpha, self.typ)
ret = [(App(UnfinishedLeaf(typ_f), UnfinishedLeaf(alpha), self.typ), sub.Sub(), n1)]
for ctx_declaration in gamma.ctx.values():
fresh_res = fresh(ctx_declaration.typ, self.typ, n)
mu = sub.mgu(self.typ, fresh_res.typ)
if not mu.is_failed():
sigma = mu.restrict(self.typ)
leaf = Leaf(ctx_declaration.sym, sigma(self.typ))
ret.append((leaf, sigma, fresh_res.n))
return ret
def subs_uf_smart(self, uf_tree, k, n):
uf_leafs = uf_tree.get_unfinished_leafs()
num_uf_leafs = len(uf_leafs)
num_fin_leafs = uf_tree.size()
if num_fin_leafs + num_uf_leafs > k:
return []
if num_uf_leafs > 0:
hax_typ = TypTerm.make_internal_tuple(
[uf_leaf.typ for uf_leaf in uf_leafs])
hax_k = k - num_fin_leafs + num_uf_leafs - 1
return self.subs(hax_k, hax_typ, n)
elif num_fin_leafs == k:
return [sub.PreSubRes(1, sub.Sub())]
else:
return []
import sub x = sub.Sub(70, 30) print(x)
import sub
a = int(input("enter a number"))
b = int(input("enter a number"))
c = sub.Sub(a, b)
print(c)
def skolemize(self):
acc = {}
skolemized = self._skolemize_acc(acc)
return skolemized, sub_m.Sub(acc)
def make_from_nf_sub(self):
rev_tab = {v: k for k, v in self.tab.items()}
return sub.Sub(rev_tab)
import sub x = sub.Sub(10, 5) print(x)
def replace_unfinished_leafs_raw(self, new_subtrees):
return self, sub.Sub()
