def interpret(self, thing):
sig = self.domain.sig
interp = sig.interp
if isinstance(thing.formula.args[1], ivy_ast.NativeType):
lhs = thing.formula.args[0].rep
if lhs in interp or lhs in self.domain.native_types:
raise IvyError(thing, "{} is already interpreted".format(lhs))
self.domain.native_types[lhs] = thing.formula.args[1]
return
lhs, rhs = (a.rep for a in thing.formula.args)
self.domain.interps[lhs].append(thing)
if lhs in self.domain.native_types:
raise IvyError(thing, "{} is already interpreted".format(lhs))
if lhs in interp:
if interp[lhs] != rhs:
raise IvyError(thing, "{} is already interpreted".format(lhs))
return
if isinstance(rhs, ivy_ast.Range):
interp[lhs] = ivy_logic.EnumeratedSort(lhs, [
"{}:{}".format(i, lhs) for i in range(int(rhs.lo),
int(rhs.hi) + 1)
])
return
for x, y, z in zip([sig.sorts, sig.symbols],
[slv.is_solver_sort, slv.is_solver_op],
['sort', 'symbol']):
if lhs in x:
if not y(rhs):
raise IvyError(thing, "{} not a native {}".format(rhs, z))
interp[lhs] = rhs
return
raise IvyUndefined(thing, lhs)
expr_context.code.append(CallAction(ivy_ast.Atom(self.rep, args), res))
return res()
return (ivy_logic.Equals if self.rep == '=' else
ivy_logic.find_polymorphic_symbol(self.rep))(*args)
ivy_ast.App.cmpl = ivy_ast.Atom.cmpl = compile_app
ivy_ast.Variable.cmpl = lambda self: ivy_logic.Variable(
self.rep,
ivy_logic.find_sort(self.sort)
if isinstance(self.sort, str) else self.sort)
ivy_ast.ConstantSort.cmpl = lambda self: ivy_logic.ConstantSort(self.rep)
ivy_ast.EnumeratedSort.cmpl = lambda self: ivy_logic.EnumeratedSort(
self.name, self.extension)
SymbolList.cmpl = lambda self: self.clone(
[find_symbol(s) for s in self.symbols])
def cquant(q):
return ivy_logic.ForAll if isinstance(q,
ivy_ast.Forall) else ivy_logic.Exists
ivy_ast.Quantifier.cmpl = lambda self: cquant(
self)([v.compile() for v in self.bounds], self.args[0].compile())
ivy_ast.LabeledFormula.cmpl = lambda self: self.clone(
[self.label, sortify_with_inference(self.formula)])
# # print clauses
# print
# z3_formula = clauses_to_z3(clauses)
# print z3_formula
# print
# print
# f = clauses_to_z3(ivy_logic.to_clauses("[[p()],[~p()]]"))
# s = z3.Solver()
# s.add(f)
# print s.check() # should be unsat
# f1 = clauses_to_z3(ivy_logic.to_clauses("[[p()]]"))
# f2 = clauses_to_z3(ivy_logic.to_clauses("[[~p()]]"))
# s = z3.Solver()
# s.add(f1)
# s.add(f2)
# print s.check() # this is also unsat
# ivy_logic.add_symbol('p',ivy_logic.RelationSort([ivy_logic.universe]))
# cls = to_clauses("p(x) & ~p(y)")
# print clauses_model_to_clauses(cls)
s = ivy_logic.EnumeratedSort(["a", "b", "c"])
for c in s.defines():
t = add_symbol(c, s)
ivy_logic.sig.constructors.add(t)
add_symbol('f', ivy_logic.FunctionSort([ivy_logic.universe], s))
cls = to_clauses("f(x) = a & f(y) = b")
print clauses_model_to_clauses(cls)
