import json
import typing
from typing import Dict, List, Set, Tuple
import cloudpickle
import pytest
from pandas import DataFrame
from reflex.base import Base
from reflex.state import State
from reflex.vars import (
BaseVar,
ComputedVar,
ImportVar,
ReflexDict,
ReflexList,
ReflexSet,
Var,
get_local_storage,
)
test_vars = [
BaseVar(name="prop1", type_=int),
BaseVar(name="key", type_=str),
BaseVar(name="value", type_=str, state="state"),
BaseVar(name="local", type_=str, state="state", is_local=True),
BaseVar(name="local2", type_=str, is_local=True),
]
test_import_vars = [ImportVar(tag="DataGrid"), ImportVar(tag="DataGrid", alias="Grid")]
class BaseState(State):
"""A Test State."""
val: str = "key"
@pytest.fixture
def TestObj():
class TestObj(Base):
foo: int
bar: str
return TestObj
@pytest.fixture
def ParentState(TestObj):
class ParentState(State):
foo: int
bar: int
@ComputedVar
def var_without_annotation(self):
return TestObj
return ParentState
@pytest.fixture
def ChildState(ParentState, TestObj):
class ChildState(ParentState):
@ComputedVar
def var_without_annotation(self):
return TestObj
return ChildState
@pytest.fixture
def GrandChildState(ChildState, TestObj):
class GrandChildState(ChildState):
@ComputedVar
def var_without_annotation(self):
return TestObj
return GrandChildState
@pytest.fixture
def StateWithAnyVar(TestObj):
class StateWithAnyVar(State):
@ComputedVar
def var_without_annotation(self) -> typing.Any:
return TestObj
return StateWithAnyVar
@pytest.fixture
def StateWithCorrectVarAnnotation():
class StateWithCorrectVarAnnotation(State):
@ComputedVar
def var_with_annotation(self) -> str:
return "Correct annotation"
return StateWithCorrectVarAnnotation
@pytest.fixture
def StateWithWrongVarAnnotation(TestObj):
class StateWithWrongVarAnnotation(State):
@ComputedVar
def var_with_annotation(self) -> str:
return TestObj
return StateWithWrongVarAnnotation
@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 prop.full_name == 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",
[
(BaseVar(name="p", type_=int), 0),
(BaseVar(name="p", type_=float), 0.0),
(BaseVar(name="p", type_=str), ""),
(BaseVar(name="p", type_=bool), False),
(BaseVar(name="p", type_=list), []),
(BaseVar(name="p", type_=dict), {}),
(BaseVar(name="p", type_=tuple), ()),
(BaseVar(name="p", type_=set), set()),
],
)
def test_default_value(prop, 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, 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, None),
(1, BaseVar(name="1", type_=int, is_local=True)),
("key", BaseVar(name="key", type_=str, is_local=True)),
(3.14, BaseVar(name="3.14", type_=float, is_local=True)),
([1, 2, 3], BaseVar(name="[1, 2, 3]", type_=list, is_local=True)),
(
{"a": 1, "b": 2},
BaseVar(name='{"a": 1, "b": 2}', type_=dict, is_local=True),
),
],
)
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 = Var.create(value)
if value is None:
assert prop == expected
else:
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) as exception:
Var.create(value)
assert (
exception.value.args[0]
== f"To create a Var must be Var or JSON-serializable. Got {value} of type {type(value)}."
)
def v(value) -> Var:
val = (
Var.create(json.dumps(value), is_string=True, is_local=False)
if isinstance(value, str)
else Var.create(value, is_local=False)
)
assert val is not None
return val
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(v(1) < v(2)) == "{(1 < 2)}"
assert str(v(1) <= v(2)) == "{(1 <= 2)}"
assert str(v(1) > v(2)) == "{(1 > 2)}"
assert str(v(1) >= v(2)) == "{(1 >= 2)}"
assert str(v(1) + v(2)) == "{(1 + 2)}"
assert str(v(1) - v(2)) == "{(1 - 2)}"
assert str(v(1) * v(2)) == "{(1 * 2)}"
assert str(v(1) / v(2)) == "{(1 / 2)}"
assert str(v(1) // v(2)) == "{Math.floor(1 / 2)}"
assert str(v(1) % v(2)) == "{(1 % 2)}"
assert str(v(1) ** v(2)) == "{Math.pow(1 , 2)}"
assert str(v(1) & v(2)) == "{(1 && 2)}"
assert str(v(1) | v(2)) == "{(1 || 2)}"
assert str(v([1, 2, 3])[v(0)]) == "{[1, 2, 3].at(0)}"
assert str(v({"a": 1, "b": 2})["a"]) == '{{"a": 1, "b": 2}["a"]}'
assert (
str(BaseVar(name="foo", state="state", type_=TestObj).bar) == "{state.foo.bar}"
)
assert str(abs(v(1))) == "{Math.abs(1)}"
assert str(v([1, 2, 3]).length()) == "{[1, 2, 3].length}"
assert str(v([1, 2]) + v([3, 4])) == "{spreadArraysOrObjects([1, 2] , [3, 4])}"
# Tests for reverse operation
assert str(v([1, 2, 3]).reverse()) == "{[...[1, 2, 3]].reverse()}"
assert str(v(["1", "2", "3"]).reverse()) == '{[...["1", "2", "3"]].reverse()}'
assert (
str(BaseVar(name="foo", state="state", type_=list).reverse())
== "{[...state.foo].reverse()}"
)
assert str(BaseVar(name="foo", type_=list).reverse()) == "{[...foo].reverse()}"
@pytest.mark.parametrize(
"var, expected",
[
(v([1, 2, 3]), "[1, 2, 3]"),
(v(["1", "2", "3"]), '["1", "2", "3"]'),
(BaseVar(name="foo", state="state", type_=list), "state.foo"),
(BaseVar(name="foo", type_=list), "foo"),
(v((1, 2, 3)), "[1, 2, 3]"),
(v(("1", "2", "3")), '["1", "2", "3"]'),
(BaseVar(name="foo", state="state", type_=tuple), "state.foo"),
(BaseVar(name="foo", type_=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 = BaseVar(name="other", state="state", type_=str)
other_var = BaseVar(name="other", type_=str)
assert str(var.contains(other_state_var)) == f"{{{expected}.includes(state.other)}}"
assert str(var.contains(other_var)) == f"{{{expected}.includes(other)}}"
@pytest.mark.parametrize(
"var, expected",
[
(v("123"), json.dumps("123")),
(BaseVar(name="foo", state="state", type_=str), "state.foo"),
(BaseVar(name="foo", type_=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 = BaseVar(name="other", state="state", type_=str)
other_var = BaseVar(name="other", type_=str)
assert str(var.contains(other_state_var)) == f"{{{expected}.includes(state.other)}}"
assert str(var.contains(other_var)) == f"{{{expected}.includes(other)}}"
@pytest.mark.parametrize(
"var, expected",
[
(v({"a": 1, "b": 2}), '{"a": 1, "b": 2}'),
(BaseVar(name="foo", state="state", type_=dict), "state.foo"),
(BaseVar(name="foo", type_=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 = BaseVar(name="other", state="state", type_=str)
other_var = BaseVar(name="other", type_=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",
[
BaseVar(name="list", type_=List[int]),
BaseVar(name="tuple", type_=Tuple[int, int]),
BaseVar(name="str", type_=str),
],
)
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.name}.at(0)}}"
assert str(var[1]) == f"{{{var.name}.at(1)}}"
# Test negative indexing.
assert str(var[-1]) == f"{{{var.name}.at(-1)}}"
@pytest.mark.parametrize(
"var, index",
[
(BaseVar(name="lst", type_=List[int]), [1, 2]),
(BaseVar(name="lst", type_=List[int]), {"name": "dict"}),
(BaseVar(name="lst", type_=List[int]), {"set"}),
(
BaseVar(name="lst", type_=List[int]),
(
1,
2,
),
),
(BaseVar(name="lst", type_=List[int]), 1.5),
(BaseVar(name="lst", type_=List[int]), "str"),
(BaseVar(name="lst", type_=List[int]), BaseVar(name="string_var", type_=str)),
(BaseVar(name="lst", type_=List[int]), BaseVar(name="float_var", type_=float)),
(
BaseVar(name="lst", type_=List[int]),
BaseVar(name="list_var", type_=List[int]),
),
(BaseVar(name="lst", type_=List[int]), BaseVar(name="set_var", type_=Set[str])),
(
BaseVar(name="lst", type_=List[int]),
BaseVar(name="dict_var", type_=Dict[str, str]),
),
(BaseVar(name="str", type_=str), [1, 2]),
(BaseVar(name="lst", type_=str), {"name": "dict"}),
(BaseVar(name="lst", type_=str), {"set"}),
(BaseVar(name="lst", type_=str), BaseVar(name="string_var", type_=str)),
(BaseVar(name="lst", type_=str), BaseVar(name="float_var", type_=float)),
(BaseVar(name="str", type_=Tuple[str]), [1, 2]),
(BaseVar(name="lst", type_=Tuple[str]), {"name": "dict"}),
(BaseVar(name="lst", type_=Tuple[str]), {"set"}),
(BaseVar(name="lst", type_=Tuple[str]), BaseVar(name="string_var", type_=str)),
(BaseVar(name="lst", type_=Tuple[str]), BaseVar(name="float_var", type_=float)),
],
)
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",
[
BaseVar(name="lst", type_=List[int]),
BaseVar(name="tuple", type_=Tuple[int, int]),
BaseVar(name="str", type_=str),
],
)
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.name}.slice(0, 1)}}"
assert str(var[:1]) == f"{{{var.name}.slice(0, 1)}}"
assert str(var[:]) == f"{{{var.name}.slice(0, undefined)}}"
def test_dict_indexing():
"""Test that we can index into dict vars."""
dct = BaseVar(name="dct", type_=Dict[str, int])
# Check correct indexing.
assert str(dct["a"]) == '{dct["a"]}'
assert str(dct["asdf"]) == '{dct["asdf"]}'
@pytest.mark.parametrize(
"var, index",
[
(
BaseVar(name="dict", type_=Dict[str, str]),
[1, 2],
),
(
BaseVar(name="dict", type_=Dict[str, str]),
{"name": "dict"},
),
(
BaseVar(name="dict", type_=Dict[str, str]),
{"set"},
),
(
BaseVar(name="dict", type_=Dict[str, str]),
(
1,
2,
),
),
(
BaseVar(name="lst", type_=Dict[str, str]),
BaseVar(name="list_var", type_=List[int]),
),
(
BaseVar(name="lst", type_=Dict[str, str]),
BaseVar(name="set_var", type_=Set[str]),
),
(
BaseVar(name="lst", type_=Dict[str, str]),
BaseVar(name="dict_var", type_=Dict[str, str]),
),
(
BaseVar(name="df", type_=DataFrame),
[1, 2],
),
(
BaseVar(name="df", type_=DataFrame),
{"name": "dict"},
),
(
BaseVar(name="df", type_=DataFrame),
{"set"},
),
(
BaseVar(name="df", type_=DataFrame),
(
1,
2,
),
),
(
BaseVar(name="df", type_=DataFrame),
BaseVar(name="list_var", type_=List[int]),
),
(
BaseVar(name="df", type_=DataFrame),
BaseVar(name="set_var", type_=Set[str]),
),
(
BaseVar(name="df", type_=DataFrame),
BaseVar(name="dict_var", type_=Dict[str, str]),
),
],
)
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,full_name",
[
("ParentState", "parent_state.var_without_annotation"),
("ChildState", "parent_state.child_state.var_without_annotation"),
(
"GrandChildState",
"parent_state.child_state.grand_child_state.var_without_annotation",
),
("StateWithAnyVar", "state_with_any_var.var_without_annotation"),
],
)
def test_computed_var_without_annotation_error(request, fixture, full_name):
"""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.
full_name: The full name of the state var.
"""
with pytest.raises(TypeError) as err:
state = request.getfixturevalue(fixture)
state.var_without_annotation.foo
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,full_name",
[
(
"StateWithCorrectVarAnnotation",
"state_with_correct_var_annotation.var_with_annotation",
),
(
"StateWithWrongVarAnnotation",
"state_with_wrong_var_annotation.var_with_annotation",
),
],
)
def test_computed_var_with_annotation_error(request, fixture, full_name):
"""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.
full_name: The full name of the state var.
"""
with pytest.raises(AttributeError) as err:
state = request.getfixturevalue(fixture)
state.var_with_annotation.foo
assert (
err.value.args[0]
== f"The State var `{full_name}` has no attribute 'foo' or may have been annotated wrongly.\n"
f"original message: 'ComputedVar' object has no attribute 'foo'"
)
def test_pickleable_rx_list():
"""Test that ReflexList is pickleable."""
rx_list = ReflexList(
original_list=[1, 2, 3], reassign_field=lambda x: x, field_name="random"
)
pickled_list = cloudpickle.dumps(rx_list)
assert cloudpickle.loads(pickled_list) == rx_list
def test_pickleable_rx_dict():
"""Test that ReflexDict is pickleable."""
rx_dict = ReflexDict(
original_dict={1: 2, 3: 4}, reassign_field=lambda x: x, field_name="random"
)
pickled_dict = cloudpickle.dumps(rx_dict)
assert cloudpickle.loads(pickled_dict) == rx_dict
def test_pickleable_rx_set():
"""Test that ReflexSet is pickleable."""
rx_set = ReflexSet(
original_set={1, 2, 3}, reassign_field=lambda x: x, field_name="random"
)
pickled_set = cloudpickle.dumps(rx_set)
assert cloudpickle.loads(pickled_set) == rx_set
@pytest.mark.parametrize(
"import_var,expected",
zip(
test_import_vars,
[
"DataGrid",
"DataGrid as Grid",
],
),
)
def test_import_var(import_var, expected):
"""Test that the import var name is computed correctly.
Args:
import_var: The import var.
expected: expected name
"""
assert import_var.name == expected
@pytest.mark.parametrize(
"key, expected",
[
("test_key", BaseVar(name="localStorage.getItem('test_key')", type_=str)),
(
BaseVar(name="key_var", type_=str),
BaseVar(name="localStorage.getItem(key_var)", type_=str),
),
(
BaseState.val,
BaseVar(name="localStorage.getItem(base_state.val)", type_=str),
),
(None, BaseVar(name="getAllLocalStorageItems()", type_=Dict)),
],
)
def test_get_local_storage(key, expected):
"""Test that the right BaseVar is return when get_local_storage is called.
Args:
key: Local storage key.
expected: expected BaseVar.
"""
local_storage = get_local_storage(key)
assert local_storage.name == expected.name
assert local_storage.type_ == expected.type_
@pytest.mark.parametrize(
"key",
[
["list", "values"],
{"name": "dict"},
10,
BaseVar(name="key_var", type_=List),
BaseVar(name="key_var", type_=Dict[str, str]),
],
)
def test_get_local_storage_raise_error(key):
"""Test that a type error is thrown when the wrong key type is provided.
Args:
key: Local storage key.
"""
with pytest.raises(TypeError) as err:
get_local_storage(key)
type_ = type(key) if not isinstance(key, Var) else key.type_
assert (
err.value.args[0]
== f"Local storage keys can only be of type `str` or `var` of type `str`. Got `{type_}` instead."
)
@pytest.mark.parametrize(
"out, expected",
[
(f"{BaseVar(name='var', type_=str)}", "${var}"),
(
f"testing f-string with {BaseVar(name='myvar', state='state', type_=int)}",
"testing f-string with ${state.myvar}",
),
(
f"testing local f-string {BaseVar(name='x', is_local=True, type_=str)}",
"testing local f-string x",
),
],
)
def test_fstrings(out, expected):
assert out == expected
@pytest.mark.parametrize(
"var",
[
BaseVar(name="var", type_=int),
BaseVar(name="var", type_=float),
BaseVar(name="var", type_=str),
BaseVar(name="var", type_=bool),
BaseVar(name="var", type_=dict),
BaseVar(name="var", type_=tuple),
BaseVar(name="var", type_=set),
BaseVar(name="var", type_=None),
],
)
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] == f"Cannot reverse non-list var var."
@pytest.mark.parametrize(
"var",
[
BaseVar(name="var", type_=int),
BaseVar(name="var", type_=float),
BaseVar(name="var", type_=bool),
BaseVar(name="var", type_=set),
BaseVar(name="var", type_=None),
],
)
def test_unsupported_types_for_contains(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 var of type {var.type_} does not support contains check."
)
@pytest.mark.parametrize(
"other",
[
BaseVar(name="other", type_=int),
BaseVar(name="other", type_=float),
BaseVar(name="other", type_=bool),
BaseVar(name="other", type_=list),
BaseVar(name="other", type_=dict),
BaseVar(name="other", type_=tuple),
BaseVar(name="other", type_=set),
],
)
def test_unsupported_types_for_string_contains(other):
with pytest.raises(TypeError) as err:
assert BaseVar(name="var", type_=str).contains(other)
assert (
err.value.args[0]
== f"'in <string>' requires string as left operand, not {other.type_}"
)
def test_unsupported_default_contains():
with pytest.raises(TypeError) as err:
assert 1 in BaseVar(name="var", type_=str)
assert (
err.value.args[0]
== "'in' operator not supported for Var types, use Var.contains() instead."
)
@pytest.mark.parametrize(
"operand1_var,operand2_var,operators",
[
(
Var.create(10),
Var.create(5),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"&",
],
),
(
Var.create(10.5),
Var.create(5),
["+", "-", "/", "//", "*", "%", "**", ">", "<", "<=", ">="],
),
(
Var.create(5),
Var.create(True),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"&",
],
),
(
Var.create(10.5),
Var.create(5.5),
["+", "-", "/", "//", "*", "%", "**", ">", "<", "<=", ">="],
),
(
Var.create(10.5),
Var.create(True),
["+", "-", "/", "//", "*", "%", "**", ">", "<", "<=", ">="],
),
(Var.create("10"), Var.create("5"), ["+", ">", "<", "<=", ">="]),
(Var.create([10, 20]), Var.create([5, 6]), ["+", ">", "<", "<=", ">="]),
(Var.create([10, 20]), Var.create(5), ["*"]),
(Var.create([10, 20]), Var.create(True), ["*"]),
(
Var.create(True),
Var.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:
operand1_var.operation(op=operator, other=operand2_var)
operand1_var.operation(op=operator, other=operand2_var, flip=True)
@pytest.mark.parametrize(
"operand1_var,operand2_var,operators",
[
(
Var.create(10),
Var.create(5),
[
"^",
"<<",
">>",
],
),
(
Var.create(10.5),
Var.create(5),
[
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create(10.5),
Var.create(True),
[
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create(10.5),
Var.create(5.5),
[
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create("10"),
Var.create("5"),
[
"-",
"/",
"//",
"*",
"%",
"**",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create([10, 20]),
Var.create([5, 6]),
[
"-",
"/",
"//",
"*",
"%",
"**",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create([10, 20]),
Var.create(5),
[
"+",
"-",
"/",
"//",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create([10, 20]),
Var.create(True),
[
"+",
"-",
"/",
"//",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create([10, 20]),
Var.create("5"),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create([10, 20]),
Var.create({"key": "value"}),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create([10, 20]),
Var.create(5.5),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create({"key": "value"}),
Var.create({"another_key": "another_value"}),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create({"key": "value"}),
Var.create(5),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create({"key": "value"}),
Var.create(True),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create({"key": "value"}),
Var.create(5.5),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
(
Var.create({"key": "value"}),
Var.create("5"),
[
"+",
"-",
"/",
"//",
"*",
"%",
"**",
">",
"<",
"<=",
">=",
"|",
"^",
"<<",
">>",
"&",
],
),
],
)
def test_invalid_var_operations(operand1_var: Var, operand2_var, operators: List[str]):
for operator in operators:
with pytest.raises(TypeError):
operand1_var.operation(op=operator, other=operand2_var)
with pytest.raises(TypeError):
operand1_var.operation(op=operator, other=operand2_var, flip=True)