luau/tests/TypeInfer.classes.test.cpp
2024-05-03 09:38:34 -07:00

793 lines
22 KiB
C++

// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details
#include "Luau/BuiltinDefinitions.h"
#include "Luau/Common.h"
#include "Luau/TypeInfer.h"
#include "Luau/Type.h"
#include "Fixture.h"
#include "ClassFixture.h"
#include "doctest.h"
using namespace Luau;
using std::nullopt;
LUAU_FASTFLAG(DebugLuauDeferredConstraintResolution);
LUAU_FASTFLAG(LuauAlwaysCommitInferencesOfFunctionCalls);
TEST_SUITE_BEGIN("TypeInferClasses");
TEST_CASE_FIXTURE(ClassFixture, "Luau.Analyze.CLI_crashes_on_this_test")
{
CheckResult result = check(R"(
local CircularQueue = {}
CircularQueue.__index = CircularQueue
function CircularQueue:new()
local newCircularQueue = {
head = nil,
}
setmetatable(newCircularQueue, CircularQueue)
return newCircularQueue
end
function CircularQueue:push()
local newListNode
if self.head then
newListNode = {
prevNode = self.head.prevNode,
nextNode = self.head,
}
newListNode.prevNode.nextNode = newListNode
newListNode.nextNode.prevNode = newListNode
end
end
return CircularQueue
)");
}
TEST_CASE_FIXTURE(ClassFixture, "call_method_of_a_class")
{
CheckResult result = check(R"(
local m = BaseClass.StaticMethod()
)");
LUAU_REQUIRE_NO_ERRORS(result);
REQUIRE_EQ("number", toString(requireType("m")));
}
TEST_CASE_FIXTURE(ClassFixture, "call_method_of_a_child_class")
{
CheckResult result = check(R"(
local m = ChildClass.StaticMethod()
)");
LUAU_REQUIRE_NO_ERRORS(result);
REQUIRE_EQ("number", toString(requireType("m")));
}
TEST_CASE_FIXTURE(ClassFixture, "call_instance_method")
{
CheckResult result = check(R"(
local i = ChildClass.New()
local result = i:Method()
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK_EQ("string", toString(requireType("result")));
}
TEST_CASE_FIXTURE(ClassFixture, "call_base_method")
{
CheckResult result = check(R"(
local i = ChildClass.New()
i:BaseMethod(41)
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "cannot_call_unknown_method_of_a_class")
{
CheckResult result = check(R"(
local m = BaseClass.Nope()
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
}
TEST_CASE_FIXTURE(ClassFixture, "cannot_call_method_of_child_on_base_instance")
{
CheckResult result = check(R"(
local i = BaseClass.New()
i:Method()
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
}
TEST_CASE_FIXTURE(ClassFixture, "we_can_infer_that_a_parameter_must_be_a_particular_class")
{
CheckResult result = check(R"(
function makeClone(o)
return BaseClass.Clone(o)
end
local a = makeClone(ChildClass.New())
)");
CHECK_EQ("BaseClass", toString(requireType("a")));
}
TEST_CASE_FIXTURE(ClassFixture, "we_can_report_when_someone_is_trying_to_use_a_table_rather_than_a_class")
{
CheckResult result = check(R"(
function makeClone(o)
return BaseClass.Clone(o)
end
type Oopsies = { BaseMethod: (Oopsies, number) -> ()}
local oopsies: Oopsies = {
BaseMethod = function (self: Oopsies, i: number)
print('gadzooks!')
end
}
makeClone(oopsies)
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
TypeMismatch* tm = get<TypeMismatch>(result.errors.at(0));
REQUIRE(tm != nullptr);
CHECK_EQ("Oopsies", toString(tm->givenType));
CHECK_EQ("BaseClass", toString(tm->wantedType));
}
TEST_CASE_FIXTURE(ClassFixture, "assign_to_prop_of_class")
{
CheckResult result = check(R"(
local v = Vector2.New(0, 5)
v.X = 55
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "can_read_prop_of_base_class")
{
CheckResult result = check(R"(
local c = ChildClass.New()
local x = 1 + c.BaseField
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "can_assign_to_prop_of_base_class")
{
CheckResult result = check(R"(
local c = ChildClass.New()
c.BaseField = 444
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "can_read_prop_of_base_class_using_string")
{
CheckResult result = check(R"(
local c = ChildClass.New()
local x = 1 + c["BaseField"]
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "can_assign_to_prop_of_base_class_using_string")
{
CheckResult result = check(R"(
local c = ChildClass.New()
c["BaseField"] = 444
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "cannot_unify_class_instance_with_primitive")
{
CheckResult result = check(R"(
local v = Vector2.New(0, 5)
v = 444
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
}
TEST_CASE_FIXTURE(ClassFixture, "warn_when_prop_almost_matches")
{
CheckResult result = check(R"(
Vector2.new(0, 0)
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
auto err = get<UnknownPropButFoundLikeProp>(result.errors.at(0));
REQUIRE(err != nullptr);
REQUIRE_EQ(1, err->candidates.size());
CHECK_EQ("New", *err->candidates.begin());
}
TEST_CASE_FIXTURE(ClassFixture, "classes_can_have_overloaded_operators")
{
CheckResult result = check(R"(
local a = Vector2.New(1, 2)
local b = Vector2.New(3, 4)
local c = a + b
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK_EQ("Vector2", toString(requireType("c")));
}
TEST_CASE_FIXTURE(ClassFixture, "classes_without_overloaded_operators_cannot_be_added")
{
CheckResult result = check(R"(
local a = BaseClass.New()
local b = BaseClass.New()
local c = a + b
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
}
TEST_CASE_FIXTURE(ClassFixture, "function_arguments_are_covariant")
{
CheckResult result = check(R"(
function f(b: BaseClass) end
f(ChildClass.New())
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "higher_order_function_arguments_are_contravariant")
{
CheckResult result = check(R"(
function apply(f: (BaseClass) -> ())
f(ChildClass.New()) -- 2
end
apply(function (c: ChildClass) end) -- 5
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
}
TEST_CASE_FIXTURE(ClassFixture, "higher_order_function_return_values_are_covariant")
{
CheckResult result = check(R"(
function apply(f: () -> BaseClass)
return f()
end
apply(function ()
return ChildClass.New()
end)
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "higher_order_function_return_type_is_not_contravariant")
{
CheckResult result = check(R"(
function apply(f: () -> BaseClass)
return f()
end
apply(function ()
return ChildClass.New()
end)
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "table_properties_are_invariant")
{
CheckResult result = check(R"(
function f(a: {foo: BaseClass})
a.foo = AnotherChild.New()
end
local t: {foo: ChildClass}
f(t) -- line 6. Breaks soundness.
function g(t: {foo: ChildClass})
end
local t2: {foo: BaseClass} = {foo=BaseClass.New()}
t2.foo = AnotherChild.New()
g(t2) -- line 13. Breaks soundness
)");
LUAU_REQUIRE_ERROR_COUNT(2, result);
CHECK_EQ(6, result.errors.at(0).location.begin.line);
CHECK_EQ(13, result.errors[1].location.begin.line);
}
TEST_CASE_FIXTURE(ClassFixture, "table_indexers_are_invariant")
{
CheckResult result = check(R"(
function f(a: {[number]: BaseClass})
a[1] = AnotherChild.New()
end
local t: {[number]: ChildClass}
f(t) -- line 6. Breaks soundness.
function g(t: {[number]: ChildClass})
end
local t2: {[number]: BaseClass} = {BaseClass.New()}
t2[1] = AnotherChild.New()
g(t2) -- line 13. Breaks soundness
)");
LUAU_REQUIRE_ERROR_COUNT(2, result);
CHECK_EQ(6, result.errors.at(0).location.begin.line);
CHECK_EQ(13, result.errors[1].location.begin.line);
}
TEST_CASE_FIXTURE(ClassFixture, "table_class_unification_reports_sane_errors_for_missing_properties")
{
CheckResult result = check(R"(
function foo(bar)
bar.Y = 1 -- valid
bar.x = 2 -- invalid, wanted 'X'
bar.w = 2 -- invalid
end
local a: Vector2
foo(a)
)");
LUAU_REQUIRE_ERROR_COUNT(2, result);
REQUIRE_EQ("Key 'w' not found in class 'Vector2'", toString(result.errors.at(0)));
REQUIRE_EQ("Key 'x' not found in class 'Vector2'. Did you mean 'X'?", toString(result.errors[1]));
}
TEST_CASE_FIXTURE(ClassFixture, "class_unification_type_mismatch_is_correct_order")
{
CheckResult result = check(R"(
local p: BaseClass
local foo: number = p
local foo2: BaseClass = 1
)");
LUAU_REQUIRE_ERROR_COUNT(2, result);
REQUIRE_EQ("Type 'BaseClass' could not be converted into 'number'", toString(result.errors.at(0)));
REQUIRE_EQ("Type 'number' could not be converted into 'BaseClass'", toString(result.errors[1]));
}
TEST_CASE_FIXTURE(ClassFixture, "optional_class_field_access_error")
{
CheckResult result = check(R"(
local b: Vector2? = nil
local a = b.X + b.Z
b.X = 2 -- real Vector2.X is also read-only
)");
LUAU_REQUIRE_ERROR_COUNT(4, result);
CHECK_EQ("Value of type 'Vector2?' could be nil", toString(result.errors.at(0)));
CHECK_EQ("Value of type 'Vector2?' could be nil", toString(result.errors[1]));
CHECK_EQ("Key 'Z' not found in class 'Vector2'", toString(result.errors[2]));
CHECK_EQ("Value of type 'Vector2?' could be nil", toString(result.errors[3]));
}
TEST_CASE_FIXTURE(ClassFixture, "detailed_class_unification_error")
{
ScopedFastFlag sff[] = {
{FFlag::LuauAlwaysCommitInferencesOfFunctionCalls, true},
};
CheckResult result = check(R"(
local function foo(v)
return v.X :: number + string.len(v.Y)
end
local a: Vector2
local b = foo
b(a)
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
const std::string expected = R"(Type 'Vector2' could not be converted into '{- X: number, Y: string -}'
caused by:
Property 'Y' is not compatible.
Type 'number' could not be converted into 'string')";
CHECK_EQ(expected, toString(result.errors.at(0)));
}
TEST_CASE_FIXTURE(ClassFixture, "class_type_mismatch_with_name_conflict")
{
CheckResult result = check(R"(
local i = ChildClass.New()
type ChildClass = { x: number }
local a: ChildClass = i
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
CHECK_EQ("Type 'ChildClass' from 'Test' could not be converted into 'ChildClass' from 'MainModule'", toString(result.errors.at(0)));
}
TEST_CASE_FIXTURE(ClassFixture, "intersections_of_unions_of_classes")
{
CheckResult result = check(R"(
local x : (BaseClass | Vector2) & (ChildClass | AnotherChild)
local y : (ChildClass | AnotherChild)
x = y
y = x
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "unions_of_intersections_of_classes")
{
CheckResult result = check(R"(
local x : (BaseClass & ChildClass) | (BaseClass & AnotherChild) | (BaseClass & Vector2)
local y : (ChildClass | AnotherChild)
x = y
y = x
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "index_instance_property")
{
CheckResult result = check(R"(
local function execute(object: BaseClass, name: string)
print(object[name])
end
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
CHECK_EQ("Attempting a dynamic property access on type 'BaseClass' is unsafe and may cause exceptions at runtime", toString(result.errors.at(0)));
}
TEST_CASE_FIXTURE(ClassFixture, "index_instance_property_nonstrict")
{
CheckResult result = check(R"(
--!nonstrict
local function execute(object: BaseClass, name: string)
print(object[name])
end
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(ClassFixture, "type_mismatch_invariance_required_for_error")
{
CheckResult result = check(R"(
type A = { x: ChildClass }
type B = { x: BaseClass }
local a: A = { x = ChildClass.New() }
local b: B = a
)");
LUAU_REQUIRE_ERRORS(result);
if (FFlag::DebugLuauDeferredConstraintResolution)
CHECK(toString(result.errors.at(0)) == "Type 'A' could not be converted into 'B'; at [read \"x\"], ChildClass is not exactly BaseClass");
else
{
const std::string expected = R"(Type 'A' could not be converted into 'B'
caused by:
Property 'x' is not compatible.
Type 'ChildClass' could not be converted into 'BaseClass' in an invariant context)";
CHECK_EQ(expected, toString(result.errors.at(0)));
}
}
TEST_CASE_FIXTURE(ClassFixture, "callable_classes")
{
CheckResult result = check(R"(
local x : CallableClass
local y = x("testing")
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK_EQ("number", toString(requireType("y")));
}
TEST_CASE_FIXTURE(ClassFixture, "indexable_classes")
{
// Test reading from an index
{
CheckResult result = check(R"(
local x : IndexableClass
local y = x.stringKey
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
{
CheckResult result = check(R"(
local x : IndexableClass
local y = x["stringKey"]
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
{
CheckResult result = check(R"(
local x : IndexableClass
local str : string
local y = x[str] -- Index with a non-const string
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
{
CheckResult result = check(R"(
local x : IndexableClass
local y = x[7] -- Index with a numeric key
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
// Test writing to an index
{
CheckResult result = check(R"(
local x : IndexableClass
x.stringKey = 42
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
{
CheckResult result = check(R"(
local x : IndexableClass
x["stringKey"] = 42
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
{
CheckResult result = check(R"(
local x : IndexableClass
local str : string
x[str] = 42 -- Index with a non-const string
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
{
CheckResult result = check(R"(
local x : IndexableClass
x[1] = 42 -- Index with a numeric key
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
// Try to index the class using an invalid type for the key (key type is 'number | string'.)
{
CheckResult result = check(R"(
local x : IndexableClass
local y = x[true]
)");
CHECK_EQ(
toString(result.errors.at(0)), "Type 'boolean' could not be converted into 'number | string'; none of the union options are compatible");
}
{
CheckResult result = check(R"(
local x : IndexableClass
x[true] = 42
)");
CHECK_EQ(
toString(result.errors.at(0)), "Type 'boolean' could not be converted into 'number | string'; none of the union options are compatible");
}
// Test type checking for the return type of the indexer (i.e. a number)
{
CheckResult result = check(R"(
local x : IndexableClass
x.key = "string value"
)");
CHECK_EQ(toString(result.errors.at(0)), "Type 'string' could not be converted into 'number'");
}
{
CheckResult result = check(R"(
local x : IndexableClass
local str : string = x.key
)");
CHECK_EQ(toString(result.errors.at(0)), "Type 'number' could not be converted into 'string'");
}
// Check that we string key are rejected if the indexer's key type is not compatible with string
{
CheckResult result = check(R"(
local x : IndexableNumericKeyClass
x.key = 1
)");
CHECK_EQ(toString(result.errors.at(0)), "Key 'key' not found in class 'IndexableNumericKeyClass'");
}
{
CheckResult result = check(R"(
local x : IndexableNumericKeyClass
x["key"] = 1
)");
if (FFlag::DebugLuauDeferredConstraintResolution)
CHECK_EQ(toString(result.errors.at(0)), "Key 'key' not found in class 'IndexableNumericKeyClass'");
else
CHECK_EQ(toString(result.errors.at(0)), "Type 'string' could not be converted into 'number'");
}
{
CheckResult result = check(R"(
local x : IndexableNumericKeyClass
local str : string
x[str] = 1 -- Index with a non-const string
)");
CHECK_EQ(toString(result.errors.at(0)), "Type 'string' could not be converted into 'number'");
}
{
CheckResult result = check(R"(
local x : IndexableNumericKeyClass
local y = x.key
)");
CHECK_EQ(toString(result.errors.at(0)), "Key 'key' not found in class 'IndexableNumericKeyClass'");
}
{
CheckResult result = check(R"(
local x : IndexableNumericKeyClass
local y = x["key"]
)");
if (FFlag::DebugLuauDeferredConstraintResolution)
CHECK_EQ(toString(result.errors.at(0)), "Key 'key' not found in class 'IndexableNumericKeyClass'");
else
CHECK_EQ(toString(result.errors.at(0)), "Type 'string' could not be converted into 'number'");
}
{
CheckResult result = check(R"(
local x : IndexableNumericKeyClass
local str : string
local y = x[str] -- Index with a non-const string
)");
CHECK_EQ(toString(result.errors.at(0)), "Type 'string' could not be converted into 'number'");
}
}
TEST_CASE_FIXTURE(Fixture, "read_write_class_properties")
{
ScopedFastFlag sff{FFlag::DebugLuauDeferredConstraintResolution, true};
TypeArena& arena = frontend.globals.globalTypes;
unfreeze(arena);
TypeId instanceType = arena.addType(ClassType{"Instance", {}, nullopt, nullopt, {}, {}, "Test"});
getMutable<ClassType>(instanceType)->props = {{"Parent", Property::rw(instanceType)}};
//
TypeId workspaceType = arena.addType(ClassType{"Workspace", {}, nullopt, nullopt, {}, {}, "Test"});
TypeId scriptType =
arena.addType(ClassType{"Script", {{"Parent", Property::rw(workspaceType, instanceType)}}, instanceType, nullopt, {}, {}, "Test"});
TypeId partType = arena.addType(
ClassType{"Part", {{"BrickColor", Property::rw(builtinTypes->stringType)}, {"Parent", Property::rw(workspaceType, instanceType)}},
instanceType, nullopt, {}, {}, "Test"});
getMutable<ClassType>(workspaceType)->props = {{"Script", Property::readonly(scriptType)}, {"Part", Property::readonly(partType)}};
frontend.globals.globalScope->bindings[frontend.globals.globalNames.names->getOrAdd("script")] = Binding{scriptType};
freeze(arena);
CheckResult result = check(R"(
script.Parent.Part.BrickColor = 0xFFFFFF
script.Parent.Part.Parent = script
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
CHECK(Location{{1, 40}, {1, 48}} == result.errors[0].location);
TypeMismatch* tm = get<TypeMismatch>(result.errors[0]);
REQUIRE(tm);
CHECK(builtinTypes->stringType == tm->wantedType);
CHECK(builtinTypes->numberType == tm->givenType);
}
TEST_CASE_FIXTURE(ClassFixture, "cannot_index_a_class_with_no_indexer")
{
CheckResult result = check(R"(
local a = BaseClass.New()
local c = a[1]
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
CHECK_MESSAGE(
get<DynamicPropertyLookupOnClassesUnsafe>(result.errors[0]), "Expected DynamicPropertyLookupOnClassesUnsafe but got " << result.errors[0]);
CHECK(builtinTypes->errorType == requireType("c"));
}
TEST_CASE_FIXTURE(ClassFixture, "cyclic_tables_are_assumed_to_be_compatible_with_classes")
{
/*
* This is technically documenting a case where we are intentionally
* unsound.
*
* Our builtins are essentially defined like so:
*
* declare class BaseClass
* BaseField: number
* function BaseMethod(self, number): ()
* read Touched: Connection
* end
*
* declare class Connection
* Connect: (Connection, (BaseClass) -> ()) -> ()
* end
*
* The type we infer for `onTouch` is
*
* (t1) -> () where t1 = { read BaseField: unknown, read BaseMethod: (t1, number) -> () }
*
* In order to validate that onTouch can be passed to Connect, we must
* verify the following relation:
*
* BaseClass <: t1 where t1 = { read BaseField: unknown, read BaseMethod: (t1, number) -> () }
*
* However, the cycle between the table and the function gums up the works
* here and the worst thing is that it's perfectly reasonable in principle.
* Just from these types, we cannot see that BaseMethod will only be passed
* t1. Without that guarantee, BaseClass cannot be used as a subtype of t1.
*
* I think the theoretically-correct way to untangle this would be to infer
* t1 as a bounded existential type.
*
* For now, we have a subtyping has a rule that provisionally substitutes
* the table for the class type when performing the subtyping test. We
* essentially assume that, for all cyclic functions, that the table and the
* class are mutually subtypes of one another.
*
* For more information, read uses of Subtyping::substitutions.
*/
CheckResult result = check(R"(
local c = BaseClass.New()
function requiresNothing() end
function onTouch(other)
requiresNothing(other:BaseMethod(0))
print(other.BaseField)
end
c.Touched:Connect(onTouch)
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_SUITE_END();