import json
import math
import sys
import typing
from typing import Dict, List, Optional, Set, Tuple, Union, cast
import pytest
from pandas import DataFrame
import reflex as rx
from reflex.base import Base
from reflex.constants.base import REFLEX_VAR_CLOSING_TAG, REFLEX_VAR_OPENING_TAG
from reflex.state import BaseState
from reflex.utils.exceptions import PrimitiveUnserializableToJSON
from reflex.utils.imports import ImportVar
from reflex.vars import VarData
from reflex.vars.base import (
ComputedVar,
LiteralVar,
Var,
computed_var,
var_operation,
var_operation_return,
)
from reflex.vars.function import (
ArgsFunctionOperation,
DestructuredArg,
FunctionStringVar,
)
from reflex.vars.number import LiteralBooleanVar, LiteralNumberVar, NumberVar
from reflex.vars.object import LiteralObjectVar, ObjectVar
from reflex.vars.sequence import (
ArrayVar,
ConcatVarOperation,
LiteralArrayVar,
LiteralStringVar,
)
test_vars = [
Var(_js_expr="prop1", _var_type=int),
Var(_js_expr="key", _var_type=str),
Var(_js_expr="value", _var_type=str)._var_set_state("state"),
Var(_js_expr="local", _var_type=str)._var_set_state("state"),
Var(_js_expr="local2", _var_type=str),
]
class ATestState(BaseState):
"""Test state."""
value: str
dict_val: Dict[str, List] = {}
@pytest.fixture
def TestObj():
class TestObj(Base):
foo: int
bar: str
return TestObj
@pytest.fixture
def ParentState(TestObj):
class ParentState(BaseState):
foo: int
bar: int
@computed_var
def var_without_annotation(self):
return TestObj
return ParentState
@pytest.fixture
def ChildState(ParentState, TestObj):
class ChildState(ParentState):
@computed_var
def var_without_annotation(self):
"""This shadows ParentState.var_without_annotation.
Returns:
TestObj: Test object.
"""
return TestObj
return ChildState
@pytest.fixture
def GrandChildState(ChildState, TestObj):
class GrandChildState(ChildState):
@computed_var
def var_without_annotation(self):
"""This shadows ChildState.var_without_annotation.
Returns:
TestObj: Test object.
"""
return TestObj
return GrandChildState
@pytest.fixture
def StateWithAnyVar(TestObj):
class StateWithAnyVar(BaseState):
@computed_var
def var_without_annotation(self) -> typing.Any:
return TestObj
return StateWithAnyVar
@pytest.fixture
def StateWithCorrectVarAnnotation():
class StateWithCorrectVarAnnotation(BaseState):
@computed_var
def var_with_annotation(self) -> str:
return "Correct annotation"
return StateWithCorrectVarAnnotation
@pytest.fixture
def StateWithWrongVarAnnotation(TestObj):
class StateWithWrongVarAnnotation(BaseState):
@computed_var
def var_with_annotation(self) -> str:
return TestObj
return StateWithWrongVarAnnotation
@pytest.fixture
def StateWithInitialComputedVar():
class StateWithInitialComputedVar(BaseState):
@computed_var(initial_value="Initial value")
def var_with_initial_value(self) -> str:
return "Runtime value"
return StateWithInitialComputedVar
@pytest.fixture
def ChildWithInitialComputedVar(StateWithInitialComputedVar):
class ChildWithInitialComputedVar(StateWithInitialComputedVar):
@computed_var(initial_value="Initial value")
def var_with_initial_value_child(self) -> str:
return "Runtime value"
return ChildWithInitialComputedVar
@pytest.fixture
def StateWithRuntimeOnlyVar():
class StateWithRuntimeOnlyVar(BaseState):
@computed_var(initial_value=None)
def var_raises_at_runtime(self) -> str:
raise ValueError("So nicht, mein Freund")
return StateWithRuntimeOnlyVar
@pytest.fixture
def ChildWithRuntimeOnlyVar(StateWithRuntimeOnlyVar):
class ChildWithRuntimeOnlyVar(StateWithRuntimeOnlyVar):
@computed_var(initial_value="Initial value")
def var_raises_at_runtime_child(self) -> str:
raise ValueError("So nicht, mein Freund")
return ChildWithRuntimeOnlyVar
@pytest.mark.parametrize(
"prop,expected",
zip(
test_vars,
[
"prop1",
"key",
"state.value",
"state.local",
"local2",
],
),
)
def test_full_name(prop, expected):
"""Test that the full name of a var is correct.
Args:
prop: The var to test.
expected: The expected full name.
"""
assert str(prop) == expected
@pytest.mark.parametrize(
"prop,expected",
zip(
test_vars,
["prop1", "key", "state.value", "state.local", "local2"],
),
)
def test_str(prop, expected):
"""Test that the string representation of a var is correct.
Args:
prop: The var to test.
expected: The expected string representation.
"""
assert str(prop) == expected
@pytest.mark.parametrize(
("prop", "expected"),
[
(Var(_js_expr="p", _var_type=int), 0),
(Var(_js_expr="p", _var_type=float), 0.0),
(Var(_js_expr="p", _var_type=str), ""),
(Var(_js_expr="p", _var_type=bool), False),
(Var(_js_expr="p", _var_type=list), []),
(Var(_js_expr="p", _var_type=dict), {}),
(Var(_js_expr="p", _var_type=tuple), ()),
(Var(_js_expr="p", _var_type=set), set()),
],
)
def test_default_value(prop: Var, expected):
"""Test that the default value of a var is correct.
Args:
prop: The var to test.
expected: The expected default value.
"""
assert prop._get_default_value() == expected
@pytest.mark.parametrize(
"prop,expected",
zip(
test_vars,
[
"set_prop1",
"set_key",
"state.set_value",
"state.set_local",
"set_local2",
],
),
)
def test_get_setter(prop: Var, expected):
"""Test that the name of the setter function of a var is correct.
Args:
prop: The var to test.
expected: The expected name of the setter function.
"""
assert prop._get_setter_name() == expected
@pytest.mark.parametrize(
"value,expected",
[
(None, Var(_js_expr="null", _var_type=None)),
(1, Var(_js_expr="1", _var_type=int)),
("key", Var(_js_expr='"key"', _var_type=str)),
(3.14, Var(_js_expr="3.14", _var_type=float)),
([1, 2, 3], Var(_js_expr="[1, 2, 3]", _var_type=List[int])),
(
{"a": 1, "b": 2},
Var(_js_expr='({ ["a"] : 1, ["b"] : 2 })', _var_type=Dict[str, int]),
),
],
)
def test_create(value, expected):
"""Test the var create function.
Args:
value: The value to create a var from.
expected: The expected name of the setter function.
"""
prop = LiteralVar.create(value)
assert prop.equals(expected) # type: ignore
def test_create_type_error():
"""Test the var create function when inputs type error."""
class ErrorType:
pass
value = ErrorType()
with pytest.raises(TypeError):
LiteralVar.create(value)
def v(value) -> Var:
return LiteralVar.create(value)
def test_basic_operations(TestObj):
"""Test the var operations.
Args:
TestObj: The test object.
"""
assert str(v(1) == v(2)) == "(1 === 2)"
assert str(v(1) != v(2)) == "(1 !== 2)"
assert str(LiteralNumberVar.create(1) < 2) == "(1 < 2)"
assert str(LiteralNumberVar.create(1) <= 2) == "(1 <= 2)"
assert str(LiteralNumberVar.create(1) > 2) == "(1 > 2)"
assert str(LiteralNumberVar.create(1) >= 2) == "(1 >= 2)"
assert str(LiteralNumberVar.create(1) + 2) == "(1 + 2)"
assert str(LiteralNumberVar.create(1) - 2) == "(1 - 2)"
assert str(LiteralNumberVar.create(1) * 2) == "(1 * 2)"
assert str(LiteralNumberVar.create(1) / 2) == "(1 / 2)"
assert str(LiteralNumberVar.create(1) // 2) == "Math.floor(1 / 2)"
assert str(LiteralNumberVar.create(1) % 2) == "(1 % 2)"
assert str(LiteralNumberVar.create(1) ** 2) == "(1 ** 2)"
assert str(LiteralNumberVar.create(1) & v(2)) == "(1 && 2)"
assert str(LiteralNumberVar.create(1) | v(2)) == "(1 || 2)"
assert str(LiteralArrayVar.create([1, 2, 3])[0]) == "[1, 2, 3].at(0)"
assert (
str(LiteralObjectVar.create({"a": 1, "b": 2})["a"])
== '({ ["a"] : 1, ["b"] : 2 })["a"]'
)
assert str(v("foo") == v("bar")) == '("foo" === "bar")'
assert str(Var(_js_expr="foo") == Var(_js_expr="bar")) == "(foo === bar)"
assert (
str(LiteralVar.create("foo") == LiteralVar.create("bar")) == '("foo" === "bar")'
)
print(Var(_js_expr="foo").to(ObjectVar, TestObj)._var_set_state("state"))
assert (
str(
Var(_js_expr="foo").to(ObjectVar, TestObj)._var_set_state("state").bar
== LiteralVar.create("bar")
)
== '(state.foo["bar"] === "bar")'
)
assert (
str(Var(_js_expr="foo").to(ObjectVar, TestObj)._var_set_state("state").bar)
== 'state.foo["bar"]'
)
assert str(abs(LiteralNumberVar.create(1))) == "Math.abs(1)"
assert str(LiteralArrayVar.create([1, 2, 3]).length()) == "[1, 2, 3].length"
assert (
str(LiteralArrayVar.create([1, 2]) + LiteralArrayVar.create([3, 4]))
== "[...[1, 2], ...[3, 4]]"
)
# Tests for reverse operation
assert (
str(LiteralArrayVar.create([1, 2, 3]).reverse())
== "[1, 2, 3].slice().reverse()"
)
assert (
str(LiteralArrayVar.create(["1", "2", "3"]).reverse())
== '["1", "2", "3"].slice().reverse()'
)
assert (
str(Var(_js_expr="foo")._var_set_state("state").to(list).reverse())
== "state.foo.slice().reverse()"
)
assert str(Var(_js_expr="foo").to(list).reverse()) == "foo.slice().reverse()"
assert str(Var(_js_expr="foo", _var_type=str).js_type()) == "(typeof(foo))"
@pytest.mark.parametrize(
"var, expected",
[
(v([1, 2, 3]), "[1, 2, 3]"),
(v({1, 2, 3}), "[1, 2, 3]"),
(v(["1", "2", "3"]), '["1", "2", "3"]'),
(
Var(_js_expr="foo")._var_set_state("state").to(list),
"state.foo",
),
(Var(_js_expr="foo").to(list), "foo"),
(v((1, 2, 3)), "[1, 2, 3]"),
(v(("1", "2", "3")), '["1", "2", "3"]'),
(
Var(_js_expr="foo")._var_set_state("state").to(tuple),
"state.foo",
),
(Var(_js_expr="foo").to(tuple), "foo"),
],
)
def test_list_tuple_contains(var, expected):
assert str(var.contains(1)) == f"{expected}.includes(1)"
assert str(var.contains("1")) == f'{expected}.includes("1")'
assert str(var.contains(v(1))) == f"{expected}.includes(1)"
assert str(var.contains(v("1"))) == f'{expected}.includes("1")'
other_state_var = Var(_js_expr="other", _var_type=str)._var_set_state("state")
other_var = Var(_js_expr="other", _var_type=str)
assert str(var.contains(other_state_var)) == f"{expected}.includes(state.other)"
assert str(var.contains(other_var)) == f"{expected}.includes(other)"
class Foo(rx.Base):
"""Foo class."""
bar: int
baz: str
class Bar(rx.Base):
"""Bar class."""
bar: str
baz: str
foo: int
@pytest.mark.parametrize(
("var", "var_type"),
(
[
(Var(_js_expr="", _var_type=Foo | Bar).guess_type(), Foo | Bar),
(Var(_js_expr="", _var_type=Foo | Bar).guess_type().bar, Union[int, str]),
]
if sys.version_info >= (3, 10)
else []
)
+ [
(Var(_js_expr="", _var_type=Union[Foo, Bar]).guess_type(), Union[Foo, Bar]),
(Var(_js_expr="", _var_type=Union[Foo, Bar]).guess_type().baz, str),
(
Var(_js_expr="", _var_type=Union[Foo, Bar]).guess_type().foo,
Union[int, None],
),
],
)
def test_var_types(var, var_type):
assert var._var_type == var_type
@pytest.mark.parametrize(
"var, expected",
[
(v("123"), json.dumps("123")),
(Var(_js_expr="foo")._var_set_state("state").to(str), "state.foo"),
(Var(_js_expr="foo").to(str), "foo"),
],
)
def test_str_contains(var, expected):
assert str(var.contains("1")) == f'{expected}.includes("1")'
assert str(var.contains(v("1"))) == f'{expected}.includes("1")'
other_state_var = Var(_js_expr="other")._var_set_state("state").to(str)
other_var = Var(_js_expr="other").to(str)
assert str(var.contains(other_state_var)) == f"{expected}.includes(state.other)"
assert str(var.contains(other_var)) == f"{expected}.includes(other)"
assert (
str(var.contains("1", "hello"))
== f'{expected}.some(obj => obj["hello"] === "1")'
)
@pytest.mark.parametrize(
"var, expected",
[
(v({"a": 1, "b": 2}), '({ ["a"] : 1, ["b"] : 2 })'),
(Var(_js_expr="foo")._var_set_state("state").to(dict), "state.foo"),
(Var(_js_expr="foo").to(dict), "foo"),
],
)
def test_dict_contains(var, expected):
assert str(var.contains(1)) == f"{expected}.hasOwnProperty(1)"
assert str(var.contains("1")) == f'{expected}.hasOwnProperty("1")'
assert str(var.contains(v(1))) == f"{expected}.hasOwnProperty(1)"
assert str(var.contains(v("1"))) == f'{expected}.hasOwnProperty("1")'
other_state_var = Var(_js_expr="other")._var_set_state("state").to(str)
other_var = Var(_js_expr="other").to(str)
assert (
str(var.contains(other_state_var)) == f"{expected}.hasOwnProperty(state.other)"
)
assert str(var.contains(other_var)) == f"{expected}.hasOwnProperty(other)"
@pytest.mark.parametrize(
"var",
[
Var(_js_expr="list", _var_type=List[int]).guess_type(),
Var(_js_expr="tuple", _var_type=Tuple[int, int]).guess_type(),
Var(_js_expr="str", _var_type=str).guess_type(),
],
)
def test_var_indexing_lists(var):
"""Test that we can index into str, list or tuple vars.
Args:
var : The str, list or tuple base var.
"""
# Test basic indexing.
assert str(var[0]) == f"{var._js_expr}.at(0)"
assert str(var[1]) == f"{var._js_expr}.at(1)"
# Test negative indexing.
assert str(var[-1]) == f"{var._js_expr}.at(-1)"
@pytest.mark.parametrize(
"var, type_",
[
(Var(_js_expr="list", _var_type=List[int]).guess_type(), [int, int]),
(
Var(_js_expr="tuple", _var_type=Tuple[int, str]).guess_type(),
[int, str],
),
],
)
def test_var_indexing_types(var, type_):
"""Test that indexing returns valid types.
Args:
var : The list, tuple base var.
type_ : The type on indexed object.
"""
assert var[0]._var_type == type_[0]
assert var[1]._var_type == type_[1]
def test_var_indexing_str():
"""Test that we can index into str vars."""
str_var = Var(_js_expr="str").to(str)
# Test that indexing gives a type of Var[str].
assert isinstance(str_var[0], Var)
assert str_var[0]._var_type is str
# Test basic indexing.
assert str(str_var[0]) == "str.at(0)"
assert str(str_var[1]) == "str.at(1)"
# Test negative indexing.
assert str(str_var[-1]) == "str.at(-1)"
@pytest.mark.parametrize(
"var",
[
(Var(_js_expr="foo", _var_type=int).guess_type()),
(Var(_js_expr="bar", _var_type=float).guess_type()),
],
)
def test_var_replace_with_invalid_kwargs(var):
with pytest.raises(TypeError) as excinfo:
var._replace(_this_should_fail=True)
assert "unexpected keyword argument" in str(excinfo.value)
def test_computed_var_replace_with_invalid_kwargs():
@computed_var(initial_value=1)
def test_var(state) -> int:
return 1
with pytest.raises(TypeError) as excinfo:
test_var._replace(_random_kwarg=True)
assert "Unexpected keyword argument" in str(excinfo.value)
@pytest.mark.parametrize(
"var, index",
[
(Var(_js_expr="lst", _var_type=List[int]).guess_type(), [1, 2]),
(
Var(_js_expr="lst", _var_type=List[int]).guess_type(),
{"name": "dict"},
),
(Var(_js_expr="lst", _var_type=List[int]).guess_type(), {"set"}),
(
Var(_js_expr="lst", _var_type=List[int]).guess_type(),
(
1,
2,
),
),
(Var(_js_expr="lst", _var_type=List[int]).guess_type(), 1.5),
(Var(_js_expr="lst", _var_type=List[int]).guess_type(), "str"),
(
Var(_js_expr="lst", _var_type=List[int]).guess_type(),
Var(_js_expr="string_var", _var_type=str).guess_type(),
),
(
Var(_js_expr="lst", _var_type=List[int]).guess_type(),
Var(_js_expr="float_var", _var_type=float).guess_type(),
),
(
Var(_js_expr="lst", _var_type=List[int]).guess_type(),
Var(_js_expr="list_var", _var_type=List[int]).guess_type(),
),
(
Var(_js_expr="lst", _var_type=List[int]).guess_type(),
Var(_js_expr="set_var", _var_type=Set[str]).guess_type(),
),
(
Var(_js_expr="lst", _var_type=List[int]).guess_type(),
Var(_js_expr="dict_var", _var_type=Dict[str, str]).guess_type(),
),
(Var(_js_expr="str", _var_type=str).guess_type(), [1, 2]),
(Var(_js_expr="lst", _var_type=str).guess_type(), {"name": "dict"}),
(Var(_js_expr="lst", _var_type=str).guess_type(), {"set"}),
(
Var(_js_expr="lst", _var_type=str).guess_type(),
Var(_js_expr="string_var", _var_type=str).guess_type(),
),
(
Var(_js_expr="lst", _var_type=str).guess_type(),
Var(_js_expr="float_var", _var_type=float).guess_type(),
),
(Var(_js_expr="str", _var_type=Tuple[str]).guess_type(), [1, 2]),
(
Var(_js_expr="lst", _var_type=Tuple[str]).guess_type(),
{"name": "dict"},
),
(Var(_js_expr="lst", _var_type=Tuple[str]).guess_type(), {"set"}),
(
Var(_js_expr="lst", _var_type=Tuple[str]).guess_type(),
Var(_js_expr="string_var", _var_type=str).guess_type(),
),
(
Var(_js_expr="lst", _var_type=Tuple[str]).guess_type(),
Var(_js_expr="float_var", _var_type=float).guess_type(),
),
],
)
def test_var_unsupported_indexing_lists(var, index):
"""Test unsupported indexing throws a type error.
Args:
var: The base var.
index: The base var index.
"""
with pytest.raises(TypeError):
var[index]
@pytest.mark.parametrize(
"var",
[
Var(_js_expr="lst", _var_type=List[int]).guess_type(),
Var(_js_expr="tuple", _var_type=Tuple[int, int]).guess_type(),
],
)
def test_var_list_slicing(var):
"""Test that we can slice into str, list or tuple vars.
Args:
var : The str, list or tuple base var.
"""
assert str(var[:1]) == f"{var._js_expr}.slice(undefined, 1)"
assert str(var[1:]) == f"{var._js_expr}.slice(1, undefined)"
assert str(var[:]) == f"{var._js_expr}.slice(undefined, undefined)"
def test_str_var_slicing():
"""Test that we can slice into str vars."""
str_var = Var(_js_expr="str").to(str)
# Test that slicing gives a type of Var[str].
assert isinstance(str_var[:1], Var)
assert str_var[:1]._var_type is str
# Test basic slicing.
assert str(str_var[:1]) == 'str.split("").slice(undefined, 1).join("")'
assert str(str_var[1:]) == 'str.split("").slice(1, undefined).join("")'
assert str(str_var[:]) == 'str.split("").slice(undefined, undefined).join("")'
assert str(str_var[1:2]) == 'str.split("").slice(1, 2).join("")'
# Test negative slicing.
assert str(str_var[:-1]) == 'str.split("").slice(undefined, -1).join("")'
assert str(str_var[-1:]) == 'str.split("").slice(-1, undefined).join("")'
assert str(str_var[:-2]) == 'str.split("").slice(undefined, -2).join("")'
assert str(str_var[-2:]) == 'str.split("").slice(-2, undefined).join("")'
def test_dict_indexing():
"""Test that we can index into dict vars."""
dct = Var(_js_expr="dct").to(ObjectVar, Dict[str, str])
# Check correct indexing.
assert str(dct["a"]) == 'dct["a"]'
assert str(dct["asdf"]) == 'dct["asdf"]'
@pytest.mark.parametrize(
"var, index",
[
(
Var(_js_expr="dict", _var_type=Dict[str, str]).guess_type(),
[1, 2],
),
(
Var(_js_expr="dict", _var_type=Dict[str, str]).guess_type(),
{"name": "dict"},
),
(
Var(_js_expr="dict", _var_type=Dict[str, str]).guess_type(),
{"set"},
),
(
Var(_js_expr="dict", _var_type=Dict[str, str]).guess_type(),
(
1,
2,
),
),
(
Var(_js_expr="lst", _var_type=Dict[str, str]).guess_type(),
Var(_js_expr="list_var", _var_type=List[int]).guess_type(),
),
(
Var(_js_expr="lst", _var_type=Dict[str, str]).guess_type(),
Var(_js_expr="set_var", _var_type=Set[str]).guess_type(),
),
(
Var(_js_expr="lst", _var_type=Dict[str, str]).guess_type(),
Var(_js_expr="dict_var", _var_type=Dict[str, str]).guess_type(),
),
(
Var(_js_expr="df", _var_type=DataFrame).guess_type(),
[1, 2],
),
(
Var(_js_expr="df", _var_type=DataFrame).guess_type(),
{"name": "dict"},
),
(
Var(_js_expr="df", _var_type=DataFrame).guess_type(),
{"set"},
),
(
Var(_js_expr="df", _var_type=DataFrame).guess_type(),
(
1,
2,
),
),
(
Var(_js_expr="df", _var_type=DataFrame).guess_type(),
Var(_js_expr="list_var", _var_type=List[int]).guess_type(),
),
(
Var(_js_expr="df", _var_type=DataFrame).guess_type(),
Var(_js_expr="set_var", _var_type=Set[str]).guess_type(),
),
(
Var(_js_expr="df", _var_type=DataFrame).guess_type(),
Var(_js_expr="dict_var", _var_type=Dict[str, str]).guess_type(),
),
],
)
def test_var_unsupported_indexing_dicts(var, index):
"""Test unsupported indexing throws a type error.
Args:
var: The base var.
index: The base var index.
"""
with pytest.raises(TypeError):
var[index]
@pytest.mark.parametrize(
"fixture",
[
"ParentState",
"StateWithAnyVar",
],
)
def test_computed_var_without_annotation_error(request, fixture):
"""Test that a type error is thrown when an attribute of a computed var is
accessed without annotating the computed var.
Args:
request: Fixture Request.
fixture: The state fixture.
"""
with pytest.raises(TypeError) as err:
state = request.getfixturevalue(fixture)
state.var_without_annotation.foo
full_name = state.var_without_annotation._var_full_name
assert (
err.value.args[0]
== f"You must provide an annotation for the state var `{full_name}`. Annotation cannot be `typing.Any`"
)
@pytest.mark.parametrize(
"fixture",
[
"ChildState",
"GrandChildState",
],
)
def test_shadow_computed_var_error(request: pytest.FixtureRequest, fixture: str):
"""Test that a name error is thrown when an attribute of a computed var is
shadowed by another attribute.
Args:
request: Fixture Request.
fixture: The state fixture.
"""
with pytest.raises(NameError):
state = request.getfixturevalue(fixture)
state.var_without_annotation.foo
@pytest.mark.parametrize(
"fixture",
[
"StateWithCorrectVarAnnotation",
"StateWithWrongVarAnnotation",
],
)
def test_computed_var_with_annotation_error(request, fixture):
"""Test that an Attribute error is thrown when a non-existent attribute of an annotated computed var is
accessed or when the wrong annotation is provided to a computed var.
Args:
request: Fixture Request.
fixture: The state fixture.
"""
with pytest.raises(AttributeError) as err:
state = request.getfixturevalue(fixture)
state.var_with_annotation.foo
full_name = state.var_with_annotation._var_full_name
assert (
err.value.args[0]
== f"The State var `{full_name}` has no attribute 'foo' or may have been annotated wrongly."
)
@pytest.mark.parametrize(
"fixture,var_name,expected_initial,expected_runtime,raises_at_runtime",
[
(
"StateWithInitialComputedVar",
"var_with_initial_value",
"Initial value",
"Runtime value",
False,
),
(
"ChildWithInitialComputedVar",
"var_with_initial_value_child",
"Initial value",
"Runtime value",
False,
),
(
"StateWithRuntimeOnlyVar",
"var_raises_at_runtime",
None,
None,
True,
),
(
"ChildWithRuntimeOnlyVar",
"var_raises_at_runtime_child",
"Initial value",
None,
True,
),
],
)
def test_state_with_initial_computed_var(
request, fixture, var_name, expected_initial, expected_runtime, raises_at_runtime
):
"""Test that the initial and runtime values of a computed var are correct.
Args:
request: Fixture Request.
fixture: The state fixture.
var_name: The name of the computed var.
expected_initial: The expected initial value of the computed var.
expected_runtime: The expected runtime value of the computed var.
raises_at_runtime: Whether the computed var is runtime only.
"""
state = request.getfixturevalue(fixture)()
state_name = state.get_full_name()
initial_dict = state.dict(initial=True)[state_name]
assert initial_dict[var_name] == expected_initial
if raises_at_runtime:
with pytest.raises(ValueError):
state.dict()[state_name][var_name]
else:
runtime_dict = state.dict()[state_name]
assert runtime_dict[var_name] == expected_runtime
def test_literal_var():
complicated_var = LiteralVar.create(
[
{"a": 1, "b": 2, "c": {"d": 3, "e": 4}},
[1, 2, 3, 4],
9,
"string",
True,
False,
None,
{1, 2, 3},
]
)
assert (
str(complicated_var)
== '[({ ["a"] : 1, ["b"] : 2, ["c"] : ({ ["d"] : 3, ["e"] : 4 }) }), [1, 2, 3, 4], 9, "string", true, false, null, [1, 2, 3]]'
)
def test_function_var():
addition_func = FunctionStringVar.create("((a, b) => a + b)")
assert str(addition_func.call(1, 2)) == "(((a, b) => a + b)(1, 2))"
manual_addition_func = ArgsFunctionOperation.create(
("a", "b"),
{
"args": [Var(_js_expr="a"), Var(_js_expr="b")],
"result": Var(_js_expr="a + b"),
},
)
assert (
str(manual_addition_func.call(1, 2))
== '(((a, b) => ({ ["args"] : [a, b], ["result"] : a + b }))(1, 2))'
)
increment_func = addition_func.partial(1)
assert (
str(increment_func.call(2))
== "(((...args) => (((a, b) => a + b)(1, ...args)))(2))"
)
create_hello_statement = ArgsFunctionOperation.create(
("name",), f"Hello, {Var(_js_expr='name')}!"
)
first_name = LiteralStringVar.create("Steven")
last_name = LiteralStringVar.create("Universe")
assert (
str(create_hello_statement.call(f"{first_name} {last_name}"))
== '(((name) => ("Hello, "+name+"!"))("Steven Universe"))'
)
# Test with destructured arguments
destructured_func = ArgsFunctionOperation.create(
(DestructuredArg(fields=("a", "b")),),
Var(_js_expr="a + b"),
)
assert (
str(destructured_func.call({"a": 1, "b": 2}))
== '((({a, b}) => a + b)(({ ["a"] : 1, ["b"] : 2 })))'
)
# Test with explicit return
explicit_return_func = ArgsFunctionOperation.create(
("a", "b"), Var(_js_expr="return a + b"), explicit_return=True
)
assert str(explicit_return_func.call(1, 2)) == "(((a, b) => {return a + b})(1, 2))"
def test_var_operation():
@var_operation
def add(a: Union[NumberVar, int], b: Union[NumberVar, int]):
return var_operation_return(js_expression=f"({a} + {b})", var_type=int)
assert str(add(1, 2)) == "(1 + 2)"
assert str(add(a=4, b=-9)) == "(4 + -9)"
five = LiteralNumberVar.create(5)
seven = add(2, five)
assert isinstance(seven, NumberVar)
def test_string_operations():
basic_string = LiteralStringVar.create("Hello, World!")
assert str(basic_string.length()) == '"Hello, World!".split("").length'
assert str(basic_string.lower()) == '"Hello, World!".toLowerCase()'
assert str(basic_string.upper()) == '"Hello, World!".toUpperCase()'
assert str(basic_string.strip()) == '"Hello, World!".trim()'
assert str(basic_string.contains("World")) == '"Hello, World!".includes("World")'
assert (
str(basic_string.split(" ").join(",")) == '"Hello, World!".split(" ").join(",")'
)
def test_all_number_operations():
starting_number = LiteralNumberVar.create(-5.4)
complicated_number = (((-(starting_number + 1)) * 2 / 3) // 2 % 3) ** 2
assert (
str(complicated_number)
== "((Math.floor(((-((-5.4 + 1)) * 2) / 3) / 2) % 3) ** 2)"
)
even_more_complicated_number = ~(
abs(math.floor(complicated_number)) | 2 & 3 & round(complicated_number)
)
assert (
str(even_more_complicated_number)
== "!(((Math.abs(Math.floor(((Math.floor(((-((-5.4 + 1)) * 2) / 3) / 2) % 3) ** 2))) || (2 && Math.round(((Math.floor(((-((-5.4 + 1)) * 2) / 3) / 2) % 3) ** 2)))) !== 0))"
)
assert str(LiteralNumberVar.create(5) > False) == "(5 > 0)"
assert str(LiteralBooleanVar.create(False) < 5) == "(Number(false) < 5)"
assert (
str(LiteralBooleanVar.create(False) < LiteralBooleanVar.create(True))
== "(Number(false) < Number(true))"
)
@pytest.mark.parametrize(
("var", "expected"),
[
(Var.create(False), "false"),
(Var.create(True), "true"),
(Var.create("false"), 'isTrue("false")'),
(Var.create([1, 2, 3]), "isTrue([1, 2, 3])"),
(Var.create({"a": 1, "b": 2}), 'isTrue(({ ["a"] : 1, ["b"] : 2 }))'),
(Var("mysterious_var"), "isTrue(mysterious_var)"),
],
)
def test_boolify_operations(var, expected):
assert str(var.bool()) == expected
def test_index_operation():
array_var = LiteralArrayVar.create([1, 2, 3, 4, 5])
assert str(array_var[0]) == "[1, 2, 3, 4, 5].at(0)"
assert str(array_var[1:2]) == "[1, 2, 3, 4, 5].slice(1, 2)"
assert (
str(array_var[1:4:2])
== "[1, 2, 3, 4, 5].slice(1, 4).filter((_, i) => i % 2 === 0)"
)
assert (
str(array_var[::-1])
== "[1, 2, 3, 4, 5].slice(0, [1, 2, 3, 4, 5].length).slice().reverse().slice(undefined, undefined).filter((_, i) => i % 1 === 0)"
)
assert str(array_var.reverse()) == "[1, 2, 3, 4, 5].slice().reverse()"
assert str(array_var[0].to(NumberVar) + 9) == "([1, 2, 3, 4, 5].at(0) + 9)"
@pytest.mark.parametrize(
"var, expected_js",
[
(Var.create(float("inf")), "Infinity"),
(Var.create(-float("inf")), "-Infinity"),
(Var.create(float("nan")), "NaN"),
],
)
def test_inf_and_nan(var, expected_js):
assert str(var) == expected_js
assert isinstance(var, NumberVar)
assert isinstance(var, LiteralVar)
with pytest.raises(PrimitiveUnserializableToJSON):
var.json()
def test_array_operations():
array_var = LiteralArrayVar.create([1, 2, 3, 4, 5])
assert str(array_var.length()) == "[1, 2, 3, 4, 5].length"
assert str(array_var.contains(3)) == "[1, 2, 3, 4, 5].includes(3)"
assert str(array_var.reverse()) == "[1, 2, 3, 4, 5].slice().reverse()"
assert (
str(ArrayVar.range(10))
== "Array.from({ length: (10 - 0) / 1 }, (_, i) => 0 + i * 1)"
)
assert (
str(ArrayVar.range(1, 10))
== "Array.from({ length: (10 - 1) / 1 }, (_, i) => 1 + i * 1)"
)
assert (
str(ArrayVar.range(1, 10, 2))
== "Array.from({ length: (10 - 1) / 2 }, (_, i) => 1 + i * 2)"
)
assert (
str(ArrayVar.range(1, 10, -1))
== "Array.from({ length: (10 - 1) / -1 }, (_, i) => 1 + i * -1)"
)
def test_object_operations():
object_var = LiteralObjectVar.create({"a": 1, "b": 2, "c": 3})
assert (
str(object_var.keys()) == 'Object.keys(({ ["a"] : 1, ["b"] : 2, ["c"] : 3 }))'
)
assert (
str(object_var.values())
== 'Object.values(({ ["a"] : 1, ["b"] : 2, ["c"] : 3 }))'
)
assert (
str(object_var.entries())
== 'Object.entries(({ ["a"] : 1, ["b"] : 2, ["c"] : 3 }))'
)
assert str(object_var.a) == '({ ["a"] : 1, ["b"] : 2, ["c"] : 3 })["a"]'
assert str(object_var["a"]) == '({ ["a"] : 1, ["b"] : 2, ["c"] : 3 })["a"]'
assert (
str(object_var.merge(LiteralObjectVar.create({"c": 4, "d": 5})))
== '({...({ ["a"] : 1, ["b"] : 2, ["c"] : 3 }), ...({ ["c"] : 4, ["d"] : 5 })})'
)
def test_var_component():
class ComponentVarState(rx.State):
field_var: rx.Component = rx.text("I am a field var")
@rx.var
def computed_var(self) -> rx.Component:
return rx.text("I am a computed var")
def has_eval_react_component(var: Var):
var_data = var._get_all_var_data()
assert var_data is not None
assert any(
any(
imported_object.name == "evalReactComponent"
for imported_object in imported_objects
)
for _, imported_objects in var_data.imports
)
has_eval_react_component(ComponentVarState.field_var) # type: ignore
has_eval_react_component(ComponentVarState.computed_var)
def test_type_chains():
object_var = LiteralObjectVar.create({"a": 1, "b": 2, "c": 3})
assert (object_var._key_type(), object_var._value_type()) == (str, int)
assert (object_var.keys()._var_type, object_var.values()._var_type) == (
List[str],
List[int],
)
assert (
str(object_var.keys()[0].upper()) # type: ignore
== 'Object.keys(({ ["a"] : 1, ["b"] : 2, ["c"] : 3 })).at(0).toUpperCase()'
)
assert (
str(object_var.entries()[1][1] - 1) # type: ignore
== '(Object.entries(({ ["a"] : 1, ["b"] : 2, ["c"] : 3 })).at(1).at(1) - 1)'
)
assert (
str(object_var["c"] + object_var["b"]) # type: ignore
== '(({ ["a"] : 1, ["b"] : 2, ["c"] : 3 })["c"] + ({ ["a"] : 1, ["b"] : 2, ["c"] : 3 })["b"])'
)
def test_nested_dict():
arr = LiteralArrayVar.create([{"bar": ["foo", "bar"]}], List[Dict[str, List[str]]])
assert (
str(arr[0]["bar"][0]) == '[({ ["bar"] : ["foo", "bar"] })].at(0)["bar"].at(0)'
)
def nested_base():
class Boo(Base):
foo: str
bar: int
class Foo(Base):
bar: Boo
baz: int
parent_obj = LiteralObjectVar.create(
Foo(bar=Boo(foo="bar", bar=5), baz=5).dict(), Foo
)
assert (
str(parent_obj.bar.foo)
== '({ ["bar"] : ({ ["foo"] : "bar", ["bar"] : 5 }), ["baz"] : 5 })["bar"]["foo"]'
)
def test_retrival():
var_without_data = Var(_js_expr="test")
assert var_without_data is not None
original_var_data = VarData(
state="Test",
imports={"react": [ImportVar(tag="useRef")]},
hooks={"const state = useContext(StateContexts.state)": None},
)
var_with_data = var_without_data._replace(merge_var_data=original_var_data)
f_string = f"foo{var_with_data}bar"
assert REFLEX_VAR_OPENING_TAG in f_string
assert REFLEX_VAR_CLOSING_TAG in f_string
result_var_data = LiteralVar.create(f_string)._get_all_var_data()
result_immutable_var_data = Var(_js_expr=f_string)._var_data
assert result_var_data is not None and result_immutable_var_data is not None
assert (
result_var_data.state
== result_immutable_var_data.state
== original_var_data.state
)
assert (
result_var_data.imports
== result_immutable_var_data.imports
== original_var_data.imports
)
assert (
tuple(result_var_data.hooks)
== tuple(result_immutable_var_data.hooks)
== tuple(original_var_data.hooks)
)
def test_fstring_concat():
original_var_with_data = LiteralVar.create(
"imagination", _var_data=VarData(state="fear")
)
immutable_var_with_data = Var(
_js_expr="consequences",
_var_data=VarData(
imports={
"react": [ImportVar(tag="useRef")],
"utils": [ImportVar(tag="useEffect")],
}
),
)
f_string = f"foo{original_var_with_data}bar{immutable_var_with_data}baz"
string_concat = LiteralStringVar.create(
f_string,
_var_data=VarData(
hooks={"const state = useContext(StateContexts.state)": None}
),
)
assert str(string_concat) == '("fooimaginationbar"+consequences+"baz")'
assert isinstance(string_concat, ConcatVarOperation)
assert string_concat._get_all_var_data() == VarData(
state="fear",
imports={
"react": [ImportVar(tag="useRef")],
"utils": [ImportVar(tag="useEffect")],
},
hooks={"const state = useContext(StateContexts.state)": None},
)
var = Var(_js_expr="var", _var_type=str)
myvar = Var(_js_expr="myvar", _var_type=int)._var_set_state("state")
x = Var(_js_expr="x", _var_type=str)
@pytest.mark.parametrize(
"out, expected",
[
(f"{var}", f"{hash(var)}var"),
(
f"testing f-string with {myvar}",
f"testing f-string with {hash(myvar)}state.myvar",
),
(
f"testing local f-string {x}",
f"testing local f-string {hash(x)}x",
),
],
)
def test_fstrings(out, expected):
assert out == expected
@pytest.mark.parametrize(
("value", "expect_state"),
[
([1], ""),
({"a": 1}, ""),
([LiteralVar.create(1)._var_set_state("foo")], "foo"),
({"a": LiteralVar.create(1)._var_set_state("foo")}, "foo"),
],
)
def test_extract_state_from_container(value, expect_state):
"""Test that _var_state is extracted from containers containing BaseVar.
Args:
value: The value to create a var from.
expect_state: The expected state.
"""
var_data = LiteralVar.create(value)._get_all_var_data()
var_state = var_data.state if var_data else ""
assert var_state == expect_state
@pytest.mark.parametrize(
"value",
[
"var",
"\nvar",
],
)
def test_fstring_roundtrip(value):
"""Test that f-string roundtrip carries state.
Args:
value: The value to create a Var from.
"""
var = Var(_js_expr=value)._var_set_state("state")
rt_var = LiteralVar.create(f"{var}")
assert var._var_state == rt_var._var_state
assert str(rt_var) == str(var)
@pytest.mark.parametrize(
"var",
[
Var(_js_expr="var", _var_type=int).guess_type(),
Var(_js_expr="var", _var_type=float).guess_type(),
Var(_js_expr="var", _var_type=str).guess_type(),
Var(_js_expr="var", _var_type=bool).guess_type(),
Var(_js_expr="var", _var_type=None).guess_type(),
],
)
def test_unsupported_types_for_reverse(var):
"""Test that unsupported types for reverse throw a type error.
Args:
var: The base var.
"""
with pytest.raises(TypeError) as err:
var.reverse()
assert err.value.args[0] == "Cannot reverse non-list var."
@pytest.mark.parametrize(
"var",
[
Var(_js_expr="var", _var_type=int).guess_type(),
Var(_js_expr="var", _var_type=float).guess_type(),
Var(_js_expr="var", _var_type=bool).guess_type(),
Var(_js_expr="var", _var_type=type(None)).guess_type(),
],
)
def test_unsupported_types_for_contains(var: Var):
"""Test that unsupported types for contains throw a type error.
Args:
var: The base var.
"""
with pytest.raises(TypeError) as err:
assert var.contains(1)
assert (
err.value.args[0]
== f"Var of type {var._var_type} does not support contains check."
)
@pytest.mark.parametrize(
"other",
[
Var(_js_expr="other", _var_type=int).guess_type(),
Var(_js_expr="other", _var_type=float).guess_type(),
Var(_js_expr="other", _var_type=bool).guess_type(),
Var(_js_expr="other", _var_type=list).guess_type(),
Var(_js_expr="other", _var_type=dict).guess_type(),
Var(_js_expr="other", _var_type=tuple).guess_type(),
Var(_js_expr="other", _var_type=set).guess_type(),
],
)
def test_unsupported_types_for_string_contains(other):
with pytest.raises(TypeError) as err:
assert Var(_js_expr="var").to(str).contains(other)
assert (
err.value.args[0]
== f"Unsupported Operand type(s) for contains: ToStringOperation, {type(other).__name__}"
)
def test_unsupported_default_contains():
with pytest.raises(TypeError) as err:
assert 1 in Var(_js_expr="var", _var_type=str).guess_type()
assert (
err.value.args[0]
== "'in' operator not supported for Var types, use Var.contains() instead."
)
@pytest.mark.parametrize(
"operand1_var,operand2_var,operators",
[
(
LiteralVar.create(10),
LiteralVar.create(5),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"&",
],
),
(
LiteralVar.create(10.5),
LiteralVar.create(5),
["+", "-", "/", "//", "*", "%", "**", ">", "<", "<=", ">="],
),
(
LiteralVar.create(5),
LiteralVar.create(True),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"&",
],
),
(
LiteralVar.create(10.5),
LiteralVar.create(5.5),
["+", "-", "/", "//", "*", "%", "**", ">", "<", "<=", ">="],
),
(
LiteralVar.create(10.5),
LiteralVar.create(True),
["+", "-", "/", "//", "*", "%", "**", ">", "<", "<=", ">="],
),
(LiteralVar.create("10"), LiteralVar.create("5"), ["+", ">", "<", "<=", ">="]),
(
LiteralVar.create([10, 20]),
LiteralVar.create([5, 6]),
["+", ">", "<", "<=", ">="],
),
(LiteralVar.create([10, 20]), LiteralVar.create(5), ["*"]),
(LiteralVar.create([10, 20]), LiteralVar.create(True), ["*"]),
(
LiteralVar.create(True),
LiteralVar.create(True),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"&",
],
),
],
)
def test_valid_var_operations(operand1_var: Var, operand2_var, operators: List[str]):
"""Test that operations do not raise a TypeError.
Args:
operand1_var: left operand.
operand2_var: right operand.
operators: list of supported operators.
"""
for operator in operators:
print(
"testing",
operator,
"on",
operand1_var,
operand2_var,
" of types",
type(operand1_var),
type(operand2_var),
)
eval(f"operand1_var {operator} operand2_var")
eval(f"operand2_var {operator} operand1_var")
@pytest.mark.parametrize(
"operand1_var,operand2_var,operators",
[
(
LiteralVar.create(10),
LiteralVar.create(5),
[
"^",
"<<",
">>",
],
),
(
LiteralVar.create(10.5),
LiteralVar.create(5),
[
"^",
"<<",
">>",
],
),
(
LiteralVar.create(10.5),
LiteralVar.create(True),
[
"^",
"<<",
">>",
],
),
(
LiteralVar.create(10.5),
LiteralVar.create(5.5),
[
"^",
"<<",
">>",
],
),
(
LiteralVar.create("10"),
LiteralVar.create("5"),
[
"-",
"/",
"//",
"*",
"%",
"**",
"^",
"<<",
">>",
],
),
(
LiteralVar.create([10, 20]),
LiteralVar.create([5, 6]),
[
"-",
"/",
"//",
"*",
"%",
"**",
"^",
"<<",
">>",
],
),
(
LiteralVar.create([10, 20]),
LiteralVar.create(5),
[
"+",
"-",
"/",
"//",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
(
LiteralVar.create([10, 20]),
LiteralVar.create(True),
[
"+",
"-",
"/",
"//",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
(
LiteralVar.create([10, 20]),
LiteralVar.create("5"),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
(
LiteralVar.create([10, 20]),
LiteralVar.create({"key": "value"}),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
(
LiteralVar.create([10, 20]),
LiteralVar.create(5.5),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
(
LiteralVar.create({"key": "value"}),
LiteralVar.create({"another_key": "another_value"}),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
(
LiteralVar.create({"key": "value"}),
LiteralVar.create(5),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
(
LiteralVar.create({"key": "value"}),
LiteralVar.create(True),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
(
LiteralVar.create({"key": "value"}),
LiteralVar.create(5.5),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
(
LiteralVar.create({"key": "value"}),
LiteralVar.create("5"),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"^",
"<<",
">>",
],
),
],
)
def test_invalid_var_operations(operand1_var: Var, operand2_var, operators: List[str]):
for operator in operators:
print(f"testing {operator} on {operand1_var!s} and {operand2_var!s}")
with pytest.raises(TypeError):
print(eval(f"operand1_var {operator} operand2_var"))
with pytest.raises(TypeError):
print(eval(f"operand2_var {operator} operand1_var"))
@pytest.mark.parametrize(
"var, expected",
[
(LiteralVar.create("string_value"), '"string_value"'),
(LiteralVar.create(1), "1"),
(LiteralVar.create([1, 2, 3]), "[1, 2, 3]"),
(LiteralVar.create({"foo": "bar"}), '({ ["foo"] : "bar" })'),
(
LiteralVar.create(ATestState.value),
f"{ATestState.get_full_name()}.value",
),
(
LiteralVar.create(f"{ATestState.value} string"),
f'({ATestState.get_full_name()}.value+" string")',
),
(
LiteralVar.create(ATestState.dict_val),
f"{ATestState.get_full_name()}.dict_val",
),
],
)
def test_var_name_unwrapped(var, expected):
assert str(var) == expected
def cv_fget(state: BaseState) -> int:
return 1
@pytest.mark.parametrize(
"deps,expected",
[
(["a"], {"a"}),
(["b"], {"b"}),
([ComputedVar(fget=cv_fget)], {"cv_fget"}),
],
)
def test_computed_var_deps(deps: List[Union[str, Var]], expected: Set[str]):
@computed_var(
deps=deps,
cache=True,
)
def test_var(state) -> int:
return 1
assert test_var._static_deps == expected
@pytest.mark.parametrize(
"deps",
[
[""],
[1],
["", "abc"],
],
)
def test_invalid_computed_var_deps(deps: List):
with pytest.raises(TypeError):
@computed_var(
deps=deps,
cache=True,
)
def test_var(state) -> int:
return 1
def test_to_string_operation():
class Email(str): ...
class TestState(BaseState):
optional_email: Optional[Email] = None
email: Email = Email("test@reflex.dev")
assert (
str(TestState.optional_email) == f"{TestState.get_full_name()}.optional_email"
)
my_state = TestState()
assert my_state.optional_email is None
assert my_state.email == "test@reflex.dev"
assert cast(Var, TestState.email)._var_type == Email
assert cast(Var, TestState.optional_email)._var_type == Optional[Email]
single_var = Var.create(Email())
assert single_var._var_type == Email