// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details #include "Luau/TypeInfer.h" #include "Luau/RecursionCounter.h" #include "Fixture.h" #include "doctest.h" #include using namespace Luau; LUAU_FASTFLAG(DebugLuauDeferredConstraintResolution); TEST_SUITE_BEGIN("ProvisionalTests"); // These tests check for behavior that differs from the final behavior we'd // like to have. They serve to document the current state of the typechecker. // When making future improvements, its very likely these tests will break and // will need to be replaced. /* * This test falls into a sort of "do as I say" pit of consequences: * Technically, the type of the type() function is (T) -> string * * We thus infer that the argument to f is a free type. * While we can still learn something about this argument, we can't seem to infer a union for it. * * Is this good? Maybe not, but I'm not sure what else we should do. */ TEST_CASE_FIXTURE(Fixture, "typeguard_inference_incomplete") { const std::string code = R"( function f(a) if type(a) == "boolean" then local a1 = a elseif a.fn() then local a2 = a end end )"; const std::string expected = R"( function f(a:{fn:()->(a,b...)}): () if type(a) == 'boolean'then local a1:boolean=a elseif a.fn()then local a2:{fn:()->(a,b...)}=a end end )"; CHECK_EQ(expected, decorateWithTypes(code)); } TEST_CASE_FIXTURE(BuiltinsFixture, "luau-polyfill.Array.filter") { // This test exercises the fact that we should reduce sealed/unsealed/free tables // res is a unsealed table with type {((T & ~nil)?) & any} // Because we do not reduce it fully, we cannot unify it with `Array = { [number] : T} // TLDR; reduction needs to reduce the indexer on res so it unifies with Array CheckResult result = check(R"( --!strict -- Implements Javascript's `Array.prototype.filter` as defined below -- https://developer.cmozilla.org/en-US/docs/Web/JavaScript/Reference/Global_Objects/Array/filter type Array = { [number]: T } type callbackFn = (element: T, index: number, array: Array) -> boolean type callbackFnWithThisArg = (thisArg: U, element: T, index: number, array: Array) -> boolean type Object = { [string]: any } return function(t: Array, callback: callbackFn | callbackFnWithThisArg, thisArg: U?): Array local len = #t local res = {} if thisArg == nil then for i = 1, len do local kValue = t[i] if kValue ~= nil then if (callback :: callbackFn)(kValue, i, t) then res[i] = kValue end end end else end return res end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "xpcall_returns_what_f_returns") { const std::string code = R"( local a, b, c = xpcall(function() return 1, "foo" end, function() return "foo", 1 end) )"; const std::string expected = R"( local a:boolean,b:number,c:string=xpcall(function(): (number,string)return 1,'foo'end,function(): (string,number)return'foo',1 end) )"; CheckResult result = check(code); CHECK("boolean" == toString(requireType("a"))); CHECK("number" == toString(requireType("b"))); CHECK("string" == toString(requireType("c"))); CHECK(expected == decorateWithTypes(code)); LUAU_REQUIRE_NO_ERRORS(result); } // We had a bug where if you have two type packs that looks like: // { x, y }, ... // { x }, ... // It would infinitely grow the type pack because one WeirdIter is trying to catch up, but can't. // However, the following snippet is supposed to generate an OccursCheckFailed, but it doesn't. TEST_CASE_FIXTURE(Fixture, "weirditer_should_not_loop_forever") { // this flag is intentionally here doing nothing to demonstrate that we exit early via case detection ScopedFastInt sfis{"LuauTypeInferTypePackLoopLimit", 50}; CheckResult result = check(R"( local function toVertexList(vertices, x, y, ...) if not (x and y) then return vertices end -- no more arguments vertices[#vertices + 1] = {x = x, y = y} -- set vertex return toVertexList(vertices, ...) -- recurse end )"); LUAU_REQUIRE_NO_ERRORS(result); } // This should also generate an OccursCheckFailed error too, like the above toVertexList snippet. // at least up until we can get Luau to recognize this code as a valid function that iterates over a list of values in the pack. TEST_CASE_FIXTURE(Fixture, "it_should_be_agnostic_of_actual_size") { CheckResult result = check(R"( local function f(x, y, ...) if not y then return x end return f(x, ...) end f(3, 2, 1, 0) )"); LUAU_REQUIRE_NO_ERRORS(result); } // Ideally setmetatable's second argument would be an optional free table. // For now, infer it as just a free table. TEST_CASE_FIXTURE(BuiltinsFixture, "setmetatable_constrains_free_type_into_free_table") { CheckResult result = check(R"( local a = {} local b setmetatable(a, b) b = 1 )"); LUAU_REQUIRE_ERROR_COUNT(1, result); TypeMismatch* tm = get(result.errors[0]); REQUIRE(tm); CHECK_EQ("{- -}", toString(tm->wantedType)); CHECK_EQ("number", toString(tm->givenType)); } // Luau currently doesn't yet know how to allow assignments when the binding was refined. TEST_CASE_FIXTURE(Fixture, "while_body_are_also_refined") { CheckResult result = check(R"( type Node = { value: T, child: Node? } local function visitor(node: Node, f: (T) -> ()) local current = node while current do f(current.value) current = current.child -- TODO: Can't work just yet. It thinks 'current' can never be nil. :( end end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_EQ("Type 'Node?' could not be converted into 'Node'", toString(result.errors[0])); } // Originally from TypeInfer.test.cpp. // I dont think type checking the metamethod at every site of == is the correct thing to do. // We should be type checking the metamethod at the call site of setmetatable. TEST_CASE_FIXTURE(BuiltinsFixture, "error_on_eq_metamethod_returning_a_type_other_than_boolean") { CheckResult result = check(R"( local tab = {a = 1} setmetatable(tab, {__eq = function(a, b): number return 1 end}) local tab2 = tab local a = tab2 == tab )"); LUAU_REQUIRE_ERROR_COUNT(1, result); GenericError* ge = get(result.errors[0]); REQUIRE(ge); CHECK_EQ("Metamethod '__eq' must return type 'boolean'", ge->message); } // Belongs in TypeInfer.refinements.test.cpp. // We need refine both operands as `never` in the `==` branch. TEST_CASE_FIXTURE(Fixture, "lvalue_equals_another_lvalue_with_no_overlap") { CheckResult result = check(R"( local function f(a: string, b: boolean?) if a == b then local foo, bar = a, b else local foo, bar = a, b end end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_EQ(toString(requireTypeAtPosition({3, 33})), "string"); // a == b CHECK_EQ(toString(requireTypeAtPosition({3, 36})), "boolean?"); // a == b CHECK_EQ(toString(requireTypeAtPosition({5, 33})), "string"); // a ~= b CHECK_EQ(toString(requireTypeAtPosition({5, 36})), "boolean?"); // a ~= b } // Also belongs in TypeInfer.refinements.test.cpp. // Just needs to fully support equality refinement. Which is annoying without type states. TEST_CASE_FIXTURE(Fixture, "discriminate_from_x_not_equal_to_nil") { CheckResult result = check(R"( type T = {x: string, y: number} | {x: nil, y: nil} local function f(t: T) if t.x ~= nil then local foo = t else local bar = t end end )"); LUAU_REQUIRE_NO_ERRORS(result); if (FFlag::DebugLuauDeferredConstraintResolution) { CHECK_EQ("{ x: string, y: number }", toString(requireTypeAtPosition({5, 28}))); // Should be { x: nil, y: nil } CHECK_EQ("{ x: nil, y: nil } | { x: string, y: number }", toString(requireTypeAtPosition({7, 28}))); } else { CHECK_EQ("{| x: string, y: number |}", toString(requireTypeAtPosition({5, 28}))); // Should be {| x: nil, y: nil |} CHECK_EQ("{| x: nil, y: nil |} | {| x: string, y: number |}", toString(requireTypeAtPosition({7, 28}))); } } TEST_CASE_FIXTURE(BuiltinsFixture, "bail_early_if_unification_is_too_complicated" * doctest::timeout(0.5)) { ScopedFastInt sffi{"LuauTarjanChildLimit", 1}; ScopedFastInt sffi2{"LuauTypeInferIterationLimit", 1}; CheckResult result = check(R"LUA( local Result Result = setmetatable({}, {}) Result.__index = Result function Result.new(okValue) local self = setmetatable({}, Result) self:constructor(okValue) return self end function Result:constructor(okValue) self.okValue = okValue end function Result:ok(val) return Result.new(val) end function Result:a(p0, p1, p2, p3, p4) return Result.new((self.okValue)) or p0 or p1 or p2 or p3 or p4 end function Result:b(p0, p1, p2, p3, p4) return Result:ok((self.okValue)) or p0 or p1 or p2 or p3 or p4 end function Result:c(p0, p1, p2, p3, p4) return Result:ok((self.okValue)) or p0 or p1 or p2 or p3 or p4 end function Result:transpose(a) return a and self.okValue:z(function(some) return Result:ok(some) end) or Result:ok(self.okValue) end )LUA"); auto it = std::find_if(result.errors.begin(), result.errors.end(), [](TypeError& a) { return nullptr != get(a); }); if (it == result.errors.end()) { dumpErrors(result); FAIL("Expected a UnificationTooComplex error"); } } // FIXME: Move this test to another source file when removing FFlag::LuauLowerBoundsCalculation TEST_CASE_FIXTURE(Fixture, "do_not_ice_when_trying_to_pick_first_of_generic_type_pack") { // In-place quantification causes these types to have the wrong types but only because of nasty interaction with prototyping. // The type of f is initially () -> free1... // Then the prototype iterator advances, and checks the function expression assigned to g, which has the type () -> free2... // In the body it calls f and returns what f() returns. This binds free2... with free1..., causing f and g to have same types. // We then quantify g, leaving it with the final type () -> a... // Because free1... and free2... were bound, in combination with in-place quantification, f's return type was also turned into a... // Then the check iterator catches up, and checks the body of f, and attempts to quantify it too. // Alas, one of the requirements for quantification is that a type must contain free types. () -> a... has no free types. // Thus the quantification for f was no-op, which explains why f does not have any type parameters. // Calling f() will attempt to instantiate the function type, which turns generics in type binders into to free types. // However, instantiations only converts generics contained within the type binders of a function, so instantiation was also no-op. // Which means that calling f() simply returned a... rather than an instantiation of it. And since the call site was not in tail position, // picking first element in a... triggers an ICE because calls returning generic packs are unexpected. CheckResult result = check(R"( local function f() end local g = function() return f() end local x = (f()) -- should error: no return values to assign from the call to f )"); LUAU_REQUIRE_NO_ERRORS(result); // f and g should have the type () -> () CHECK_EQ("() -> (a...)", toString(requireType("f"))); CHECK_EQ("() -> (a...)", toString(requireType("g"))); CHECK_EQ("any", toString(requireType("x"))); // any is returned instead of ICE for now } TEST_CASE_FIXTURE(Fixture, "specialization_binds_with_prototypes_too_early") { CheckResult result = check(R"( local function id(x) return x end local n2n: (number) -> number = id local s2s: (string) -> string = id )"); LUAU_REQUIRE_ERRORS(result); // Should not have any errors. } TEST_CASE_FIXTURE(Fixture, "weird_fail_to_unify_type_pack") { ScopedFastFlag sff[] = { // I'm not sure why this is broken without DCR, but it seems to be fixed // when DCR is enabled. {"DebugLuauDeferredConstraintResolution", false}, }; CheckResult result = check(R"( local function f() return end local g = function() return f() end )"); LUAU_REQUIRE_ERRORS(result); // Should not have any errors. } // Belongs in TypeInfer.builtins.test.cpp. TEST_CASE_FIXTURE(BuiltinsFixture, "pcall_returns_at_least_two_value_but_function_returns_nothing") { CheckResult result = check(R"( local function f(): () end local ok, res = pcall(f) )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_EQ("Function only returns 1 value, but 2 are required here", toString(result.errors[0])); // LUAU_REQUIRE_NO_ERRORS(result); // CHECK_EQ("boolean", toString(requireType("ok"))); // CHECK_EQ("any", toString(requireType("res"))); } // Belongs in TypeInfer.builtins.test.cpp. TEST_CASE_FIXTURE(BuiltinsFixture, "choose_the_right_overload_for_pcall") { CheckResult result = check(R"( local function f(): number if math.random() > 0.5 then return 5 else error("something") end end local ok, res = pcall(f) )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("boolean", toString(requireType("ok"))); CHECK_EQ("number", toString(requireType("res"))); // CHECK_EQ("any", toString(requireType("res"))); } // Belongs in TypeInfer.builtins.test.cpp. TEST_CASE_FIXTURE(BuiltinsFixture, "function_returns_many_things_but_first_of_it_is_forgotten") { CheckResult result = check(R"( local function f(): (number, string, boolean) if math.random() > 0.5 then return 5, "hello", true else error("something") end end local ok, res, s, b = pcall(f) )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("boolean", toString(requireType("ok"))); CHECK_EQ("number", toString(requireType("res"))); // CHECK_EQ("any", toString(requireType("res"))); CHECK_EQ("string", toString(requireType("s"))); CHECK_EQ("boolean", toString(requireType("b"))); } TEST_CASE_FIXTURE(Fixture, "free_is_not_bound_to_any") { CheckResult result = check(R"( local function foo(f: (any) -> (), x) f(x) end )"); CHECK_EQ("((any) -> (), any) -> ()", toString(requireType("foo"))); } TEST_CASE_FIXTURE(BuiltinsFixture, "greedy_inference_with_shared_self_triggers_function_with_no_returns") { ScopedFastFlag sff{"DebugLuauSharedSelf", true}; CheckResult result = check(R"( local T = {} T.__index = T function T.new() local self = setmetatable({}, T) return self:ctor() or self end function T:ctor() -- oops, no return! end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_EQ("Not all codepaths in this function return 'self, a...'.", toString(result.errors[0])); } TEST_CASE_FIXTURE(Fixture, "dcr_can_partially_dispatch_a_constraint") { ScopedFastFlag sff[] = { {"DebugLuauDeferredConstraintResolution", true}, }; CheckResult result = check(R"( local function hasDivisors(value: number) end function prime_iter(state, index) hasDivisors(index) index += 1 end )"); LUAU_REQUIRE_NO_ERRORS(result); // Solving this requires recognizing that we can't dispatch a constraint // like this without doing further work: // // (*blocked*) -> () <: (number) -> (b...) // // We solve this by searching both types for BlockedTypes and block the // constraint on any we find. It also gets the job done, but I'm worried // about the efficiency of doing so many deep type traversals and it may // make us more prone to getting stuck on constraint cycles. // // If this doesn't pan out, a possible solution is to go further down the // path of supporting partial constraint dispatch. The way it would work is // that we'd dispatch the above constraint by binding b... to (), but we // would append a new constraint number <: *blocked* to the constraint set // to be solved later. This should be faster and theoretically less prone // to cyclic constraint dependencies. if (FFlag::DebugLuauDeferredConstraintResolution) CHECK("(unknown, number) -> ()" == toString(requireType("prime_iter"))); else CHECK("(a, number) -> ()" == toString(requireType("prime_iter"))); } TEST_CASE_FIXTURE(Fixture, "free_options_cannot_be_unified_together") { ScopedFastFlag sff[] = { {"LuauTransitiveSubtyping", true}, }; TypeArena arena; TypeId nilType = builtinTypes->nilType; std::unique_ptr scope = std::make_unique(builtinTypes->anyTypePack); TypeId free1 = arena.addType(FreeType{scope.get()}); TypeId option1 = arena.addType(UnionType{{nilType, free1}}); TypeId free2 = arena.addType(FreeType{scope.get()}); TypeId option2 = arena.addType(UnionType{{nilType, free2}}); InternalErrorReporter iceHandler; UnifierSharedState sharedState{&iceHandler}; Normalizer normalizer{&arena, builtinTypes, NotNull{&sharedState}}; Unifier u{NotNull{&normalizer}, NotNull{scope.get()}, Location{}, Variance::Covariant}; if (FFlag::DebugLuauDeferredConstraintResolution) u.enableNewSolver(); u.tryUnify(option1, option2); CHECK(!u.failure); u.log.commit(); ToStringOptions opts; CHECK("a?" == toString(option1, opts)); // CHECK("a?" == toString(option2, opts)); // This should hold, but does not. CHECK("b?" == toString(option2, opts)); // This should not hold. } TEST_CASE_FIXTURE(BuiltinsFixture, "for_in_loop_with_zero_iterators") { ScopedFastFlag sff{"DebugLuauDeferredConstraintResolution", false}; CheckResult result = check(R"( function no_iter() end for key in no_iter() do end -- This should not be ok )"); LUAU_REQUIRE_NO_ERRORS(result); } // Ideally, we would not try to export a function type with generic types from incorrect scope TEST_CASE_FIXTURE(BuiltinsFixture, "generic_type_leak_to_module_interface") { fileResolver.source["game/A"] = R"( local wrapStrictTable local metatable = { __index = function(self, key) local value = self.__tbl[key] if type(value) == "table" then -- unification of the free 'wrapStrictTable' with this function type causes generics of this function to leak out of scope return wrapStrictTable(value, self.__name .. "." .. key) end return value end, } return wrapStrictTable )"; frontend.check("game/A"); fileResolver.source["game/B"] = R"( local wrapStrictTable = require(game.A) local Constants = {} return wrapStrictTable(Constants, "Constants") )"; frontend.check("game/B"); ModulePtr m = frontend.moduleResolver.getModule("game/B"); REQUIRE(m); std::optional result = first(m->returnType); REQUIRE(result); if (FFlag::DebugLuauDeferredConstraintResolution) CHECK_EQ("(any & ~(*error-type* | table))?", toString(*result)); else CHECK_MESSAGE(get(*result), *result); } TEST_CASE_FIXTURE(BuiltinsFixture, "generic_type_leak_to_module_interface_variadic") { fileResolver.source["game/A"] = R"( local wrapStrictTable local metatable = { __index = function(self, key, ...: T) local value = self.__tbl[key] if type(value) == "table" then -- unification of the free 'wrapStrictTable' with this function type causes generics of this function to leak out of scope return wrapStrictTable(value, self.__name .. "." .. key) end return ... end, } return wrapStrictTable )"; frontend.check("game/A"); fileResolver.source["game/B"] = R"( local wrapStrictTable = require(game.A) local Constants = {} return wrapStrictTable(Constants, "Constants") )"; frontend.check("game/B"); ModulePtr m = frontend.moduleResolver.getModule("game/B"); REQUIRE(m); std::optional result = first(m->returnType); REQUIRE(result); CHECK(get(*result)); } namespace { struct IsSubtypeFixture : Fixture { bool isSubtype(TypeId a, TypeId b) { ModulePtr module = getMainModule(); REQUIRE(module); if (!module->hasModuleScope()) FAIL("isSubtype: module scope data is not available"); return ::Luau::isSubtype(a, b, NotNull{module->getModuleScope().get()}, builtinTypes, ice); } }; } // namespace TEST_CASE_FIXTURE(IsSubtypeFixture, "intersection_of_functions_of_different_arities") { check(R"( type A = (any) -> () type B = (any, any) -> () type T = A & B local a: A local b: B local t: T )"); [[maybe_unused]] TypeId a = requireType("a"); [[maybe_unused]] TypeId b = requireType("b"); // CHECK(!isSubtype(a, b)); // !! // CHECK(!isSubtype(b, a)); CHECK("((any) -> ()) & ((any, any) -> ())" == toString(requireType("t"))); } TEST_CASE_FIXTURE(IsSubtypeFixture, "functions_with_mismatching_arity") { check(R"( local a: (number) -> () local b: () -> () local c: () -> number )"); TypeId a = requireType("a"); TypeId b = requireType("b"); TypeId c = requireType("c"); // CHECK(!isSubtype(b, a)); // CHECK(!isSubtype(c, a)); CHECK(!isSubtype(a, b)); // CHECK(!isSubtype(c, b)); CHECK(!isSubtype(a, c)); CHECK(!isSubtype(b, c)); } TEST_CASE_FIXTURE(IsSubtypeFixture, "functions_with_mismatching_arity_but_optional_parameters") { /* * (T0..TN) <: (T0..TN, A?) * (T0..TN) <: (T0..TN, any) * (T0..TN, A?) R <: U -> S if U <: T and R <: S * A | B <: T if A <: T and B <: T * T <: A | B if T <: A or T <: B */ check(R"( local a: (number?) -> () local b: (number) -> () local c: (number, number?) -> () )"); TypeId a = requireType("a"); TypeId b = requireType("b"); TypeId c = requireType("c"); /* * (number) -> () () * because number? () * because number? () <: (number) -> () * because number <: number? (because number <: number) */ CHECK(isSubtype(a, b)); /* * (number, number?) -> () <: (number) -> (number) * The packs have inequal lengths, but (number) <: (number, number?) * and number <: number */ // CHECK(!isSubtype(c, b)); /* * (number?) -> () () * because (number, number?) () () * because (number, number?) () local b: (number) -> () local c: (number, any) -> () )"); TypeId a = requireType("a"); TypeId b = requireType("b"); TypeId c = requireType("c"); /* * (number) -> () () * because number? () * because number? () <: (number) -> () * because number <: number? (because number <: number) */ CHECK(isSubtype(a, b)); /* * (number, any) -> () (number) * The packs have inequal lengths */ // CHECK(!isSubtype(c, b)); /* * (number?) -> () () * The packs have inequal lengths */ // CHECK(!isSubtype(a, c)); /* * (number) -> () () * The packs have inequal lengths */ // CHECK(!isSubtype(b, c)); } TEST_CASE_FIXTURE(Fixture, "assign_table_with_refined_property_with_a_similar_type_is_illegal") { CheckResult result = check(R"( local t: {x: number?} = {x = nil} if t.x then local u: {x: number} = t end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); const std::string expected = R"(Type '{| x: number? |}' could not be converted into '{| x: number |}' caused by: Property 'x' is not compatible. Type 'number?' could not be converted into 'number' in an invariant context)"; CHECK_EQ(expected, toString(result.errors[0])); } TEST_CASE_FIXTURE(BuiltinsFixture, "table_insert_with_a_singleton_argument") { CheckResult result = check(R"( local function foo(t, x) if x == "hi" or x == "bye" then table.insert(t, x) end return t end local t = foo({}, "hi") table.insert(t, "totally_unrelated_type" :: "totally_unrelated_type") )"); LUAU_REQUIRE_NO_ERRORS(result); if (FFlag::DebugLuauDeferredConstraintResolution) CHECK_EQ("{string}", toString(requireType("t"))); else { // We'd really like for this to be {string} CHECK_EQ("{string | string}", toString(requireType("t"))); } } // We really should be warning on this. We have no guarantee that T has any properties. TEST_CASE_FIXTURE(Fixture, "lookup_prop_of_intersection_containing_unions_of_tables_that_have_the_prop") { CheckResult result = check(R"( local function mergeOptions(options: T & ({variable: string} | {variable: number})) return options.variable end )"); LUAU_REQUIRE_NO_ERRORS(result); // LUAU_REQUIRE_ERROR_COUNT(1, result); // const UnknownProperty* unknownProp = get(result.errors[0]); // REQUIRE(unknownProp); // CHECK("variable" == unknownProp->key); } TEST_CASE_FIXTURE(Fixture, "expected_type_should_be_a_helpful_deduction_guide_for_function_calls") { CheckResult result = check(R"( type Ref = { val: T } local function useRef(x: T): Ref return { val = x } end local x: Ref = useRef(nil) )"); // This is actually wrong! Sort of. It's doing the wrong thing, it's actually asking whether // `{| val: number? |} <: {| val: nil |}` // instead of the correct way, which is // `{| val: nil |} <: {| val: number? |}` LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "floating_generics_should_not_be_allowed") { CheckResult result = check(R"( local assign : (target: T, source0: U?, source1: V?, source2: W?, ...any) -> T & U & V & W = (nil :: any) -- We have a big problem here: The generics U, V, and W are not bound to anything! -- Things get strange because of this. local benchmark = assign({}) local options = benchmark.options do local resolve2: any = nil options.fn({ resolve = function(...) resolve2(...) end, }) end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "free_options_can_be_unified_together") { ScopedFastFlag sff[] = { {"LuauTransitiveSubtyping", true}, }; TypeArena arena; TypeId nilType = builtinTypes->nilType; std::unique_ptr scope = std::make_unique(builtinTypes->anyTypePack); TypeId free1 = arena.addType(FreeType{scope.get()}); TypeId option1 = arena.addType(UnionType{{nilType, free1}}); TypeId free2 = arena.addType(FreeType{scope.get()}); TypeId option2 = arena.addType(UnionType{{nilType, free2}}); InternalErrorReporter iceHandler; UnifierSharedState sharedState{&iceHandler}; Normalizer normalizer{&arena, builtinTypes, NotNull{&sharedState}}; Unifier u{NotNull{&normalizer}, NotNull{scope.get()}, Location{}, Variance::Covariant}; if (FFlag::DebugLuauDeferredConstraintResolution) u.enableNewSolver(); u.tryUnify(option1, option2); CHECK(!u.failure); u.log.commit(); ToStringOptions opts; CHECK("a?" == toString(option1, opts)); CHECK("b?" == toString(option2, opts)); // should be `a?`. } TEST_CASE_FIXTURE(Fixture, "unify_more_complex_unions_that_include_nil") { CheckResult result = check(R"( type Record = {prop: (string | boolean)?} function concatPagination(prop: (string | boolean | nil)?): Record return {prop = prop} end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "optional_class_instances_are_invariant") { createSomeClasses(&frontend); CheckResult result = check(R"( function foo(ref: {current: Parent?}) end function bar(ref: {current: Child?}) foo(ref) end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "luau-polyfill.Map.entries") { fileResolver.source["Module/Map"] = R"( --!strict type Object = { [any]: any } type Array = { [number]: T } type Table = { [T]: V } type Tuple = Array local Map = {} export type Map = { size: number, -- method definitions set: (self: Map, K, V) -> Map, get: (self: Map, K) -> V | nil, clear: (self: Map) -> (), delete: (self: Map, K) -> boolean, has: (self: Map, K) -> boolean, keys: (self: Map) -> Array, values: (self: Map) -> Array, entries: (self: Map) -> Array>, ipairs: (self: Map) -> any, [K]: V, _map: { [K]: V }, _array: { [number]: K }, } function Map:entries() return {} end local function coerceToTable(mapLike: Map | Table): Array> local e = mapLike:entries(); return e end )"; CheckResult result = frontend.check("Module/Map"); LUAU_REQUIRE_NO_ERRORS(result); } // We would prefer this unification to be able to complete, but at least it should not crash TEST_CASE_FIXTURE(BuiltinsFixture, "table_unification_infinite_recursion") { #if defined(_NOOPT) || defined(_DEBUG) ScopedFastInt LuauTypeInferRecursionLimit{"LuauTypeInferRecursionLimit", 100}; #endif fileResolver.source["game/A"] = R"( local tbl = {} function tbl:f1(state) self.someNonExistentvalue2 = state end function tbl:f2() self.someNonExistentvalue:Dc() end function tbl:f3() self:f2() self:f1(false) end return tbl )"; fileResolver.source["game/B"] = R"( local tbl = require(game.A) tbl:f3() )"; if (FFlag::DebugLuauDeferredConstraintResolution) { // TODO: DCR should transform RecursionLimitException into a CodeTooComplex error (currently it rethows it as InternalCompilerError) CHECK_THROWS_AS(frontend.check("game/B"), Luau::InternalCompilerError); } else { CheckResult result = frontend.check("game/B"); LUAU_REQUIRE_ERROR_COUNT(1, result); } } // Ideally, unification with any will not cause a 2^n normalization of a function overload TEST_CASE_FIXTURE(BuiltinsFixture, "normalization_limit_in_unify_with_any") { ScopedFastFlag sff[] = { {"LuauTransitiveSubtyping", true}, {"DebugLuauDeferredConstraintResolution", true}, }; // With default limit, this test will take 10 seconds in NoOpt ScopedFastInt luauNormalizeCacheLimit{"LuauNormalizeCacheLimit", 1000}; // Build a function type with a large overload set const int parts = 100; std::string source; for (int i = 0; i < parts; i++) formatAppend(source, "type T%d = { f%d: number }\n", i, i); source += "type Instance = { new: (('s0', extra: Instance?) -> T0)"; for (int i = 1; i < parts; i++) formatAppend(source, " & (('s%d', extra: Instance?) -> T%d)", i, i); source += " }\n"; source += R"( local Instance: Instance = {} :: any local function foo(a: typeof(Instance.new)) return if a then 2 else 3 end foo(1 :: any) )"; CheckResult result = check(source); LUAU_REQUIRE_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "luau_roact_useState_minimization") { // We don't expect this test to work on the old solver, but it also does not yet work on the new solver. // So, we can't just put a scoped fast flag here, or it would block CI. if (!FFlag::DebugLuauDeferredConstraintResolution) return; CheckResult result = check(R"( type BasicStateAction = ((S) -> S) | S type Dispatch = (A) -> () local function useState( initialState: (() -> S) | S ): (S, Dispatch>) -- fake impl that obeys types local val = if type(initialState) == "function" then initialState() else initialState return val, function(value) return value end end local test, setTest = useState(nil :: string?) setTest(nil) -- this line causes the type to be narrowed in the old solver!!! local function update(value: string) print(test) setTest(value) end update("hello") )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_SUITE_END();