def test_if_statement_requires_test_to_be_boolean(self):
test = Literal('String', 'not a boolean')
if_case = Literal('Int', 123)
else_case = Literal('Int', 456)
if_block = If(test, if_case, else_case)
if_id = if_block.add_to_rules(self._rules, self._registry)
with self.assertRaises(InferenceError):
self._rules.infer()
def test_if_statement_requires_branches_to_equal(self):
test = Literal('Bool', True)
if_case = Literal('Int', 123)
else_case = Literal('Float', 456)
if_block = If(test, if_case, else_case)
if_id = if_block.add_to_rules(self._rules, self._registry)
with self.assertRaises(InferenceError):
self._rules.infer()
def test_if_statement(self):
test = Literal('Bool', True)
if_case = Literal('Int', 123)
else_case = Literal('Int', 456)
if_block = If(test, if_case, else_case)
if_id = if_block.add_to_rules(self._rules, self._registry)
result = self._rules.infer()
self.assertEqual('Int', result.get_type_by_id(if_id))
def test_simple_let(self):
l1 = Literal('Int', 123)
l2 = Literal('Int', 456)
lt = Let([('x', l1)], l2)
lt_id = lt.add_to_rules(self._rules, self._registry)
l1_id = self._registry.get_id_for(l1)
l2_id = self._registry.get_id_for(l2)
# TODO: the test is dependent on order for the name of var_x_1
self.assertIn(('var_x_2', l1_id), self._rules.equal_calls)
self.assertIn((lt_id, l2_id), self._rules.equal_calls)
self.assertEqual([], self._rules.instance_of_calls)
self.assertIn((l1_id, 'Int'), self._rules.specify_calls)
self.assertIn((l2_id, 'Int'), self._rules.specify_calls)
def primary(self):
if self.match(TokenType.FALSE):
return Literal(False)
elif self.match(TokenType.TRUE):
return Literal(True)
elif self.match(TokenType.NIL):
return Literal(None)
elif self.match(TokenType.NUMBER, TokenType.STRING):
return Literal(self.previous().literal)
elif self.match(TokenType.LEFT_PAREN):
expr = self.expression()
self.consume(TokenType.RIGHT_PAREN, "Expect ')' after expression")
else:
self.error(self.peek(), "Expect expression")
def test_let(self):
l = Literal('Int', 123)
lt = Let([('x', l)], Variable('x'))
lt_id = lt.add_to_rules(self._rules, self._registry)
result = self._rules.infer()
self.assertEqual('Int', result.get_type_by_id(lt_id))
def test_typed_expression_match(self):
lit = Literal('Int', 123)
te = TypedExpression('Int', lit)
te_id = te.add_to_rules(self._rules, self._registry)
lit_id = self._registry.get_id_for(lit)
result = self._rules.infer()
self.assertEqual('Int', result.get_type_by_id(te_id))
self.assertEqual('Int', result.get_type_by_id(lit_id))
def test_let_with_lambda(self):
lm = Lambda(['x'], Variable('x'))
var_id = Variable('id')
app = Application(var_id, [Literal('Int', 123)])
lt = Let([('id', lm)], app)
lt_id = lt.add_to_rules(self._rules, self._registry)
app_id = self._registry.get_id_for(app)
self.assertIn((lt_id, app_id), self._rules.equal_calls)
def test_simple_lambda_expression(self):
lit = Literal('Int', 123)
lm = Lambda(['x'], lit) # The `x` argument is unused
lm_id = lm.add_to_rules(self._rules, self._registry)
lit_id = self._registry.get_id_for(lit)
# TODO: test is dependant on order for the name of var_x_2
self.assertIn(
(1, ('Fn_1', 'var_x_2', lit_id)),
self._rules.specify_calls
)
self.assertIn((lit_id, 'Int'), self._rules.specify_calls)
def test_typed_expression(self):
l = Literal('Int', 123)
te = TypedExpression('Num', l)
self.assertEqual('TypedExpression(Num, Literal(Int, 123))', repr(te))
te_id = te.add_to_rules(self._rules, self._registry)
l_id = self._registry.get_id_for(l)
self.assertNotEqual(l_id, te_id)
self.assertSetEqual(
set([(te_id, 'Num'), (l_id, 'Int')]),
set(self._rules.specify_calls)
)
def test_application(self):
self._registry.push_new_scope({'times2': ('var_times2_1', True)})
v = Variable('times2')
l = Literal('Int', 123)
a = Application(v, [l])
a_id = a.add_to_rules(self._rules, self._registry)
v_id = self._registry.get_id_for(v)
l_id = self._registry.get_id_for(l)
result = self._rules.infer()
self.assertEqual('Int', result.get_type_by_id(l_id))
self.assertEqual(None, result.get_type_by_id(a_id))
def test_application(self):
scoped_id = 'var_times2_1'
self._registry.push_new_scope({'times2': (scoped_id, True)})
v = Variable('times2')
l = Literal('Int', 123)
a = Application(v, [l])
a_id = a.add_to_rules(self._rules, self._registry)
v_id = self._registry.get_id_for(v)
l_id = self._registry.get_id_for(l)
self.assertIn((v_id, scoped_id), self._rules.instance_of_calls)
self.assertIn((v_id, ('Fn_1', l_id, a_id)), self._rules.specify_calls)
def test_let(self):
l = Literal('Int', 123)
var_x = Variable('x')
var_y = Variable('y')
lt = Let([('x', var_y), ('y', l)], var_x)
lt_id = lt.add_to_rules(self._rules, self._registry)
l_id = self._registry.get_id_for(l)
var_x_id = self._registry.get_id_for(var_x)
var_y_id = self._registry.get_id_for(var_y)
self.assertIn((lt_id, var_x_id), self._rules.equal_calls)
self.assertIn(('var_x_2', var_y_id), self._rules.equal_calls)
self.assertIn(('var_y_3', l_id), self._rules.equal_calls)
def test_polymorphism(self):
''' ML code:
let id = \\x -> x
in (id id) 123
'''
lm = Lambda(['x'], Variable('x'))
app1 = Application(Variable('id'), [Variable('id')])
app2 = Application(app1, [Literal('Int', 123)])
lt = Let([('id', lm)], app2)
lt_id = lt.add_to_rules(self._rules, self._registry)
result = self._rules.infer()
self.assertEqual('Int', result.get_type_by_id(lt_id))
def test_let_with_lambda(self):
''' ML code:
let id = \\x -> x
in id 'foo'
'''
lm = Lambda(['x'], Variable('x'))
var_id = Variable('id')
app = Application(var_id, [Literal('String', 'foo')])
lt = Let([('id', lm)], app)
lt_id = lt.add_to_rules(self._rules, self._registry)
result = self._rules.infer()
self.assertEqual('String', result.get_type_by_id(lt_id))
def test_mutual_recursion(self):
'''
Equivalent ML:
let-rec f = if True then 123 else g
g = f
in f
'''
test = Literal('Bool', True)
if_case = Literal('Int', 123)
else_case = Application(Variable('g'), [])
if_block = If(test, if_case, else_case)
f_func = Lambda([], if_block)
g_body = Application(Variable('f'), [])
g_func = Lambda([], g_body)
let_body = Variable('f')
let_expr = Let([('f', f_func), ('g', g_func)], let_body)
let_id = let_expr.add_to_rules(self._rules, self._registry)
result = self._rules.infer()
self.assertEqual(('Fn_0', 'Int'), result.get_full_type_by_id(let_id))
def test_generic_mutual_recursion(self):
'''
Equivalent ML:
let-rec f x = if True then x else g x
g y = f y
in g
'''
test = Literal('Bool', True)
if_case = Variable('x')
else_case = Application(Variable('g'), [Variable('x')])
if_block = If(test, if_case, else_case)
f_func = Lambda(['x'], if_block)
g_body = Application(Variable('f'), [Variable('y')])
g_func = Lambda(['y'], g_body)
let_body = Variable('f')
let_expr = Let([('f', f_func), ('g', g_func)], let_body)
let_id = let_expr.add_to_rules(self._rules, self._registry)
result = self._rules.infer()
self.assertEqual(('Fn_1', 'a0', 'a0'), result.get_full_type_by_id(let_id))
def visitBinaryExpr(self, expr_instance):
return self.parenthesize(expr_instance.operator.lexeme, expr_instance.left, expr_instance.right)
def visitGroupingExpr(self, expr_instance):
return self.parenthesize('group', expr_instance.expression);
def visitLiteralExpr(self, expr_instance):
if expr_instance.value == None:
return 'nil'
else:
return str(expr_instance.value)
def visitUnaryExpr(self, expr_instance):
return self.parenthesize(expr_instance.operator, expr_instance.right)
def parenthesize(self, name, *expressions):
output = ''
output += f'({name}'
for expression in expressions:
output += ' '
output += expression.accept(self)
output += ')'
return output
if __name__ == '__main__':
# Test to see if AstPrinter does what it should
expression = Binary(Unary(Token(TokenType.MINUS, '-', '', 1), Literal(123)), Token(TokenType.STAR, '*', '', 1), Grouping(Literal(45.67)))
print(AstPrinter().print(expression))
def test_literal(self):
l = Literal('Int', 123)
l_id = l.add_to_rules(self._rules, self._registry)
self.assertTrue(l_id > 0)
self.assertEqual([(l_id, 'Int')], self._rules.specify_calls)
def test_literal_repr(self):
self.assertEqual('Literal(Int, 123)', repr(Literal('Int', 123)))
def test_literal(self):
l = Literal('Int', 123)
l_id = l.add_to_rules(self._rules, self._registry)
self.assertEqual(Result({l_id: 'Int'}, {}), self._rules.infer())
def test_typed_expression_mismatch(self):
te = TypedExpression('String', Literal('Int', 123))
te_id = te.add_to_rules(self._rules, self._registry)
with self.assertRaises(InferenceError):
self._rules.infer()
