// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details #include "Luau/AstQuery.h" #include "Luau/BuiltinDefinitions.h" #include "Luau/Error.h" #include "Luau/Scope.h" #include "Luau/TypeInfer.h" #include "Luau/Type.h" #include "Luau/VisitType.h" #include "ClassFixture.h" #include "Fixture.h" #include "ScopedFlags.h" #include "doctest.h" using namespace Luau; LUAU_FASTFLAG(LuauInstantiateInSubtyping) LUAU_FASTFLAG(LuauSolverV2) LUAU_FASTINT(LuauTarjanChildLimit) LUAU_FASTFLAG(LuauRetrySubtypingWithoutHiddenPack) LUAU_FASTFLAG(LuauDontRefCountTypesInTypeFunctions) TEST_SUITE_BEGIN("TypeInferFunctions"); TEST_CASE_FIXTURE(Fixture, "general_case_table_literal_blocks") { CheckResult result = check(R"( --!strict function f(x : {[any]: number}) return x end local Foo = {bar = "$$$"} f({[Foo.bar] = 0}) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "overload_resolution") { CheckResult result = check(R"( type A = (number) -> string type B = (string) -> number local function foo(f: A & B) return f(1), f("five") end )"); LUAU_REQUIRE_NO_ERRORS(result); TypeId t = requireType("foo"); const FunctionType* fooType = get(requireType("foo")); REQUIRE(fooType != nullptr); CHECK(toString(t) == "(((number) -> string) & ((string) -> number)) -> (string, number)"); } TEST_CASE_FIXTURE(Fixture, "tc_function") { CheckResult result = check("function five() return 5 end"); LUAU_REQUIRE_NO_ERRORS(result); const FunctionType* fiveType = get(requireType("five")); REQUIRE(fiveType != nullptr); } TEST_CASE_FIXTURE(Fixture, "check_function_bodies") { CheckResult result = check(R"( function myFunction(): number local a = 0 a = true return a end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); if (FFlag::LuauSolverV2) { const TypePackMismatch* tm = get(result.errors[0]); REQUIRE(tm); CHECK(toString(tm->wantedTp) == "number"); CHECK(toString(tm->givenTp) == "boolean"); } else { CHECK_EQ( result.errors[0], (TypeError{ Location{Position{3, 16}, Position{3, 20}}, TypeMismatch{ builtinTypes->numberType, builtinTypes->booleanType, } }) ); } } TEST_CASE_FIXTURE(Fixture, "cannot_hoist_interior_defns_into_signature") { // This test verifies that the signature does not have access to types // declared within the body. Under DCR, if the function's inner scope // encompasses the entire function expression, it would be possible for this // to type check (but the solver output is somewhat undefined). This test // ensures that this isn't the case. CheckResult result = check(R"( local function f(x: T) type T = number end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK( result.errors[0] == TypeError{ Location{{1, 28}, {1, 29}}, getMainSourceModule()->name, UnknownSymbol{ "T", UnknownSymbol::Context::Type, } } ); } TEST_CASE_FIXTURE(Fixture, "infer_return_type") { CheckResult result = check("function take_five() return 5 end"); LUAU_REQUIRE_NO_ERRORS(result); const FunctionType* takeFiveType = get(requireType("take_five")); REQUIRE(takeFiveType != nullptr); std::vector retVec = flatten(takeFiveType->retTypes).first; REQUIRE(!retVec.empty()); REQUIRE_EQ(*follow(retVec[0]), *builtinTypes->numberType); } TEST_CASE_FIXTURE(Fixture, "infer_from_function_return_type") { CheckResult result = check("function take_five() return 5 end local five = take_five()"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ(*builtinTypes->numberType, *follow(requireType("five"))); } TEST_CASE_FIXTURE(Fixture, "infer_that_function_does_not_return_a_table") { CheckResult result = check(R"( function take_five() return 5 end take_five().prop = 888 )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_EQ(result.errors[0], (TypeError{Location{Position{5, 8}, Position{5, 24}}, NotATable{builtinTypes->numberType}})); } TEST_CASE_FIXTURE(Fixture, "generalize_table_property") { CheckResult result = check(R"( local T = {} T.foo = function(x) return x end )"); LUAU_REQUIRE_NO_ERRORS(result); TypeId t = requireType("T"); const TableType* tt = get(follow(t)); REQUIRE(tt); TypeId fooTy = tt->props.at("foo").type(); CHECK("(a) -> a" == toString(fooTy)); } TEST_CASE_FIXTURE(Fixture, "vararg_functions_should_allow_calls_of_any_types_and_size") { CheckResult result = check(R"( function f(...) end f(1) f("foo", 2) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "vararg_function_is_quantified") { CheckResult result = check(R"( local T = {} function T.f(...) local result = {} for i = 1, select("#", ...) do local dictionary = select(i, ...) for key, value in pairs(dictionary) do result[key] = value end end return result end return T )"); LUAU_REQUIRE_NO_ERRORS(result); auto r = first(getMainModule()->returnType); REQUIRE(r); TableType* ttv = getMutable(*r); REQUIRE(ttv); REQUIRE(ttv->props.count("f")); TypeId k = ttv->props["f"].type(); REQUIRE(k); } TEST_CASE_FIXTURE(Fixture, "list_only_alternative_overloads_that_match_argument_count") { CheckResult result = check(R"( local multiply: ((number)->number) & ((number)->string) & ((number, number)->number) multiply("") )"); LUAU_REQUIRE_ERROR_COUNT(2, result); if (FFlag::LuauSolverV2) { GenericError* g = get(result.errors[0]); REQUIRE(g); CHECK(g->message == "None of the overloads for function that accept 1 arguments are compatible."); } else { TypeMismatch* tm = get(result.errors[0]); REQUIRE(tm); CHECK_EQ(builtinTypes->numberType, tm->wantedType); CHECK_EQ(builtinTypes->stringType, tm->givenType); } ExtraInformation* ei = get(result.errors[1]); REQUIRE(ei); if (FFlag::LuauSolverV2) CHECK("Available overloads: (number) -> number; (number) -> string; and (number, number) -> number" == ei->message); else CHECK_EQ("Other overloads are also not viable: (number) -> string", ei->message); } TEST_CASE_FIXTURE(Fixture, "list_all_overloads_if_no_overload_takes_given_argument_count") { CheckResult result = check(R"( local multiply: ((number)->number) & ((number)->string) & ((number, number)->number) multiply() )"); LUAU_REQUIRE_ERROR_COUNT(2, result); GenericError* ge = get(result.errors[0]); REQUIRE(ge); CHECK_EQ("No overload for function accepts 0 arguments.", ge->message); ExtraInformation* ei = get(result.errors[1]); REQUIRE(ei); CHECK_EQ("Available overloads: (number) -> number; (number) -> string; and (number, number) -> number", ei->message); } TEST_CASE_FIXTURE(Fixture, "dont_give_other_overloads_message_if_only_one_argument_matching_overload_exists") { CheckResult result = check(R"( local multiply: ((number)->number) & ((number)->string) & ((number, number)->number) multiply(1, "") )"); LUAU_REQUIRE_ERROR_COUNT(1, result); TypeMismatch* tm = get(result.errors[0]); REQUIRE(tm); CHECK_EQ(builtinTypes->numberType, tm->wantedType); CHECK_EQ(builtinTypes->stringType, tm->givenType); } TEST_CASE_FIXTURE(Fixture, "infer_return_type_from_selected_overload") { CheckResult result = check(R"( type T = {method: ((T, number) -> number) & ((number) -> string)} local T: T local a = T.method(T, 4) local b = T.method(5) )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("number", toString(requireType("a"))); CHECK_EQ("string", toString(requireType("b"))); } TEST_CASE_FIXTURE(Fixture, "too_many_arguments") { // This is not part of the new non-strict specification currently. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( --!nonstrict function g(a: number) end g() )"); LUAU_REQUIRE_ERROR_COUNT(1, result); auto err = result.errors[0]; auto acm = get(err); REQUIRE(acm); CHECK_EQ(1, acm->expected); CHECK_EQ(0, acm->actual); } TEST_CASE_FIXTURE(Fixture, "too_many_arguments_error_location") { CheckResult result = check(R"( --!strict function myfunction(a: number, b:number) end myfunction(1) function getmyfunction() return myfunction end getmyfunction()() )"); LUAU_REQUIRE_ERROR_COUNT(2, result); { TypeError err = result.errors[0]; // Ensure the location matches the location of the function identifier CHECK_EQ(err.location, Location(Position(4, 8), Position(4, 18))); auto acm = get(err); REQUIRE(acm); CHECK_EQ(2, acm->expected); CHECK_EQ(1, acm->actual); } { TypeError err = result.errors[1]; // Ensure the location matches the location of the expression returning the function CHECK_EQ(err.location, Location(Position(9, 8), Position(9, 23))); auto acm = get(err); REQUIRE(acm); CHECK_EQ(2, acm->expected); CHECK_EQ(0, acm->actual); } } TEST_CASE_FIXTURE(Fixture, "recursive_function") { CheckResult result = check(R"( function count(n: number) if n == 0 then return 0 else return count(n - 1) end end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "lambda_form_of_local_function_cannot_be_recursive") { CheckResult result = check(R"( local f = function() return f() end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); } TEST_CASE_FIXTURE(Fixture, "recursive_local_function") { CheckResult result = check(R"( local function count(n: number) if n == 0 then return 0 else return count(n - 1) end end )"); LUAU_REQUIRE_NO_ERRORS(result); } // FIXME: This and the above case get handled very differently. It's pretty dumb. // We really should unify the two code paths, probably by deleting AstStatFunction. TEST_CASE_FIXTURE(Fixture, "another_recursive_local_function") { CheckResult result = check(R"( local count function count(n: number) if n == 0 then return 0 else return count(n - 1) end end )"); LUAU_REQUIRE_NO_ERRORS(result); } // We had a bug where we'd look up the type of a recursive call using the DFG, // not the bindings tables. As a result, we would erroneously use the // generalized type of foo() in this recursive fragment. This creates a // constraint cycle that doesn't always work itself out. // // The fix is for the DFG node within the scope of foo() to retain the // ungeneralized type of foo. TEST_CASE_FIXTURE(BuiltinsFixture, "recursive_calls_must_refer_to_the_ungeneralized_type") { CheckResult result = check(R"( function foo() string.format('%s: %s', "51", foo()) end )"); } TEST_CASE_FIXTURE(Fixture, "cyclic_function_type_in_rets") { CheckResult result = check(R"( function f() return f end )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("t1 where t1 = () -> t1", toString(requireType("f"))); } TEST_CASE_FIXTURE(Fixture, "another_higher_order_function") { CheckResult result = check(R"( local Get_des function Get_des(func) Get_des(func) end local function f(d) d:IsA("BasePart") d.Parent:FindFirstChild("Humanoid") d:IsA("Decal") end Get_des(f) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "another_other_higher_order_function") { if (FFlag::LuauSolverV2) { CheckResult result = check(R"( local function f(d) d:foo() d:foo() end )"); LUAU_REQUIRE_NO_ERRORS(result); } else { CheckResult result = check(R"( local d d:foo() d:foo() )"); LUAU_REQUIRE_NO_ERRORS(result); } } TEST_CASE_FIXTURE(Fixture, "local_function") { CheckResult result = check(R"( function f() return 8 end function g() local function f() return 'hello' end return f end local h = g() )"); LUAU_REQUIRE_NO_ERRORS(result); TypeId h = follow(requireType("h")); const FunctionType* ftv = get(h); REQUIRE(ftv != nullptr); std::optional rt = first(ftv->retTypes); REQUIRE(bool(rt)); TypeId retType = follow(*rt); CHECK_EQ(PrimitiveType::String, getPrimitiveType(retType)); } TEST_CASE_FIXTURE(Fixture, "func_expr_doesnt_leak_free") { CheckResult result = check(R"( local p = function(x) return x end )"); LUAU_REQUIRE_NO_ERRORS(result); const Luau::FunctionType* fn = get(requireType("p")); REQUIRE(fn); auto ret = first(fn->retTypes); REQUIRE(ret); REQUIRE(get(follow(*ret))); } TEST_CASE_FIXTURE(Fixture, "first_argument_can_be_optional") { CheckResult result = check(R"( local T = {} function T.new(a: number?, b: number?, c: number?) return 5 end local m = T.new() )"); LUAU_REQUIRE_NO_ERRORS(result); dumpErrors(result); } TEST_CASE_FIXTURE(Fixture, "it_is_ok_not_to_supply_enough_retvals") { CheckResult result = check(R"( function get_two() return 5, 6 end local a = get_two() )"); LUAU_REQUIRE_NO_ERRORS(result); dumpErrors(result); } TEST_CASE_FIXTURE(Fixture, "duplicate_functions2") { CheckResult result = check(R"( function foo() end function bar() local function foo() end end )"); LUAU_REQUIRE_ERROR_COUNT(0, result); } TEST_CASE_FIXTURE(Fixture, "duplicate_functions_allowed_in_nonstrict") { CheckResult result = check(R"( --!nonstrict function foo() end function foo() end function bar() local function foo() end end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "duplicate_functions_with_different_signatures_not_allowed_in_nonstrict") { // This is not part of the spec for the new non-strict mode currently. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( --!nonstrict function foo(): number return 1 end foo() function foo(n: number): number return 2 end foo() )"); LUAU_REQUIRE_ERROR_COUNT(1, result); TypeMismatch* tm = get(result.errors[0]); REQUIRE(tm); CHECK_EQ("() -> number", toString(tm->wantedType)); CHECK_EQ("(number) -> number", toString(tm->givenType)); } TEST_CASE_FIXTURE(Fixture, "complicated_return_types_require_an_explicit_annotation") { CheckResult result = check(R"( local i = 0 function most_of_the_natural_numbers(): number? if i < 10 then i += 1 return i else return nil end end )"); LUAU_REQUIRE_NO_ERRORS(result); TypeId ty = requireType("most_of_the_natural_numbers"); const FunctionType* functionType = get(ty); REQUIRE_MESSAGE(functionType, "Expected function but got " << toString(ty)); std::optional retType = first(functionType->retTypes); REQUIRE(retType); CHECK(get(*retType)); } TEST_CASE_FIXTURE(Fixture, "infer_higher_order_function") { CheckResult result = check(R"( function apply(f, x) return f(x) end )"); LUAU_REQUIRE_NO_ERRORS(result); const FunctionType* ftv = get(requireType("apply")); REQUIRE(ftv != nullptr); std::vector argVec = flatten(ftv->argTypes).first; REQUIRE_EQ(2, argVec.size()); const FunctionType* fType = get(follow(argVec[0])); REQUIRE_MESSAGE(fType != nullptr, "Expected a function but got " << toString(argVec[0])); std::vector fArgs = flatten(fType->argTypes).first; TypeId xType = follow(argVec[1]); CHECK_EQ(1, fArgs.size()); CHECK_EQ(xType, follow(fArgs[0])); } TEST_CASE_FIXTURE(Fixture, "higher_order_function_2") { // CLI-114134: this code *probably* wants the egraph in order // to work properly. The new solver either falls over or // forces so many constraints as to be unreliable. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( function bottomupmerge(comp, a, b, left, mid, right) local i, j = left, mid for k = left, right do if i < mid and (j > right or not comp(a[j], a[i])) then b[k] = a[i] i = i + 1 else b[k] = a[j] j = j + 1 end end end )"); LUAU_REQUIRE_NO_ERRORS(result); const FunctionType* ftv = get(requireType("bottomupmerge")); REQUIRE(ftv != nullptr); std::vector argVec = flatten(ftv->argTypes).first; REQUIRE_EQ(6, argVec.size()); const FunctionType* fType = get(follow(argVec[0])); REQUIRE(fType != nullptr); } TEST_CASE_FIXTURE(Fixture, "higher_order_function_3") { CheckResult result = check(R"( function swap(p) local t = p[0] p[0] = p[1] p[1] = t return nil end function swapTwice(p) swap(p) swap(p) return p end )"); LUAU_REQUIRE_NO_ERRORS(result); const FunctionType* ftv = get(requireType("swapTwice")); REQUIRE(ftv != nullptr); std::vector argVec = flatten(ftv->argTypes).first; REQUIRE_EQ(1, argVec.size()); const TableType* argType = get(follow(argVec[0])); REQUIRE_MESSAGE(argType != nullptr, argVec[0]); CHECK(bool(argType->indexer)); } TEST_CASE_FIXTURE(BuiltinsFixture, "higher_order_function_4") { // CLI-114134: this code *probably* wants the egraph in order // to work properly. The new solver either falls over or // forces so many constraints as to be unreliable. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( function bottomupmerge(comp, a, b, left, mid, right) local i, j = left, mid for k = left, right do if i < mid and (j > right or not comp(a[j], a[i])) then b[k] = a[i] i = i + 1 else b[k] = a[j] j = j + 1 end end end function mergesort(arr: {T}, comp: (T, T) -> boolean) local work = {} for i = 1, #arr do work[i] = arr[i] end local width = 1 while width < #arr do for i = 1, #arr, 2*width do bottomupmerge(comp, arr, work, i, math.min(i+width, #arr), math.min(i+2*width-1, #arr)) end local temp = work work = arr arr = temp width = width * 2 end return arr end )"); LUAU_REQUIRE_NO_ERRORS(result); /* * mergesort takes two arguments: an array of some type T and a function that takes two Ts. * We must assert that these two types are in fact the same type. * In other words, comp(arr[x], arr[y]) is well-typed. */ const FunctionType* ftv = get(requireType("mergesort")); REQUIRE(ftv != nullptr); std::vector argVec = flatten(ftv->argTypes).first; REQUIRE_EQ(2, argVec.size()); const TableType* arg0 = get(follow(argVec[0])); REQUIRE(arg0 != nullptr); REQUIRE(bool(arg0->indexer)); const FunctionType* arg1 = get(follow(argVec[1])); REQUIRE(arg1 != nullptr); REQUIRE_EQ(2, size(arg1->argTypes)); std::vector arg1Args = flatten(arg1->argTypes).first; CHECK_EQ(*arg0->indexer->indexResultType, *arg1Args[0]); CHECK_EQ(*arg0->indexer->indexResultType, *arg1Args[1]); } TEST_CASE_FIXTURE(BuiltinsFixture, "mutual_recursion") { CheckResult result = check(R"( --!strict function newPlayerCharacter() startGui() -- Unknown symbol 'startGui' end local characterAddedConnection: any function startGui() characterAddedConnection = game:GetService("Players").LocalPlayer.CharacterAdded:connect(newPlayerCharacter) end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "toposort_doesnt_break_mutual_recursion") { CheckResult result = check(R"( --!strict local x = nil function f() g() end -- make sure print(x) doesn't get toposorted here, breaking the mutual block function g() x = f end print(x) )"); LUAU_REQUIRE_NO_ERRORS(result); dumpErrors(result); } TEST_CASE_FIXTURE(Fixture, "check_function_before_lambda_that_uses_it") { CheckResult result = check(R"( --!nonstrict function f() return 114 end return function() return f():andThen() end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "it_is_ok_to_oversaturate_a_higher_order_function_argument") { CheckResult result = check(R"( function onerror() end function foo() end xpcall(foo, onerror) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "another_indirect_function_case_where_it_is_ok_to_provide_too_many_arguments") { CheckResult result = check(R"( local mycb: (number, number) -> () function f() end mycb = f )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "report_exiting_without_return_nonstrict") { // new non-strict mode spec does not include this error yet. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( --!nonstrict local function f1(v): number? if v then return 1 end end local function f2(v) if v then return 1 end end local function f3(v): () if v then return end end local function f4(v) if v then return end end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); FunctionExitsWithoutReturning* err = get(result.errors[0]); CHECK(err); } TEST_CASE_FIXTURE(Fixture, "report_exiting_without_return_strict") { CheckResult result = check(R"( --!strict local function f1(v): number? if v then return 1 end end local function f2(v) if v then return 1 end end local function f3(v): () if v then return end end local function f4(v) if v then return end end )"); LUAU_REQUIRE_ERROR_COUNT(2, result); FunctionExitsWithoutReturning* annotatedErr = get(result.errors[0]); CHECK(annotatedErr); FunctionExitsWithoutReturning* inferredErr = get(result.errors[1]); CHECK(inferredErr); } TEST_CASE_FIXTURE(Fixture, "calling_function_with_incorrect_argument_type_yields_errors_spanning_argument") { CheckResult result = check(R"( function foo(a: number, b: string) end foo("Test", 123) )"); LUAU_REQUIRE_ERROR_COUNT(2, result); CHECK_EQ( result.errors[0], (TypeError{ Location{Position{3, 12}, Position{3, 18}}, TypeMismatch{ builtinTypes->numberType, builtinTypes->stringType, } }) ); CHECK_EQ( result.errors[1], (TypeError{ Location{Position{3, 20}, Position{3, 23}}, TypeMismatch{ builtinTypes->stringType, builtinTypes->numberType, } }) ); } TEST_CASE_FIXTURE(BuiltinsFixture, "calling_function_with_anytypepack_doesnt_leak_free_types") { CheckResult result = check(R"( --!nonstrict function Test(a) return 1, "" end local tab = {} table.insert(tab, Test(1)); )"); LUAU_REQUIRE_NO_ERRORS(result); ToStringOptions opts; opts.exhaustive = true; opts.maxTableLength = 0; if (FFlag::LuauSolverV2) CHECK_EQ("{string}", toString(requireType("tab"), opts)); else CHECK_EQ("{any}", toString(requireType("tab"), opts)); } TEST_CASE_FIXTURE(Fixture, "too_many_return_values") { // FIXME: CLI-116157 variadic and generic type packs seem to be interacting incorrectly. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( --!strict function f() return 55 end local a, b = f() )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CountMismatch* acm = get(result.errors[0]); REQUIRE(acm); CHECK_EQ(acm->context, CountMismatch::FunctionResult); CHECK_EQ(acm->expected, 1); CHECK_EQ(acm->actual, 2); } TEST_CASE_FIXTURE(Fixture, "too_many_return_values_in_parentheses") { // FIXME: CLI-116157 variadic and generic type packs seem to be interacting incorrectly. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( --!strict function f() return 55 end local a, b = (f()) )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CountMismatch* acm = get(result.errors[0]); REQUIRE(acm); CHECK_EQ(acm->context, CountMismatch::FunctionResult); CHECK_EQ(acm->expected, 1); CHECK_EQ(acm->actual, 2); } TEST_CASE_FIXTURE(Fixture, "too_many_return_values_no_function") { // FIXME: CLI-116157 variadic and generic type packs seem to be interacting incorrectly. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( --!strict local a, b = 55 )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CountMismatch* acm = get(result.errors[0]); REQUIRE(acm); CHECK_EQ(acm->context, CountMismatch::ExprListResult); CHECK_EQ(acm->expected, 1); CHECK_EQ(acm->actual, 2); } TEST_CASE_FIXTURE(Fixture, "ignored_return_values") { CheckResult result = check(R"( --!strict function f() return 55, "" end local a = f() )"); LUAU_REQUIRE_ERROR_COUNT(0, result); } TEST_CASE_FIXTURE(Fixture, "function_does_not_return_enough_values") { CheckResult result = check(R"( --!strict function f(): (number, string) return 55 end )"); if (FFlag::LuauSolverV2) { LUAU_REQUIRE_ERROR_COUNT(1, result); auto tpm = get(result.errors[0]); REQUIRE(tpm); CHECK("number, string" == toString(tpm->wantedTp)); CHECK("number" == toString(tpm->givenTp)); } else { LUAU_REQUIRE_ERROR_COUNT(1, result); CountMismatch* acm = get(result.errors[0]); REQUIRE(acm); CHECK_EQ(acm->context, CountMismatch::Return); CHECK_EQ(acm->expected, 2); CHECK_EQ(acm->actual, 1); } } TEST_CASE_FIXTURE(Fixture, "function_cast_error_uses_correct_language") { CheckResult result = check(R"( function foo(a, b): number return 0 end local a: (string)->number = foo local b: (number, number)->(number, number) = foo local c: (string, number)->number = foo -- no error )"); LUAU_REQUIRE_ERROR_COUNT(2, result); auto tm1 = get(result.errors[0]); REQUIRE(tm1); CHECK_EQ("(string) -> number", toString(tm1->wantedType)); if (FFlag::LuauSolverV2) CHECK_EQ("(unknown, unknown) -> number", toString(tm1->givenType)); else CHECK_EQ("(string, *error-type*) -> number", toString(tm1->givenType)); auto tm2 = get(result.errors[1]); REQUIRE(tm2); CHECK_EQ("(number, number) -> (number, number)", toString(tm2->wantedType)); if (FFlag::LuauSolverV2) CHECK_EQ("(unknown, unknown) -> number", toString(tm1->givenType)); else CHECK_EQ("(string, *error-type*) -> number", toString(tm2->givenType)); } TEST_CASE_FIXTURE(Fixture, "no_lossy_function_type") { CheckResult result = check(R"( --!strict local tbl = {} function tbl:abc(a: number, b: number) return a end tbl:abc(1, 2) -- Line 6 -- | Column 14 )"); LUAU_REQUIRE_NO_ERRORS(result); TypeId type = requireTypeAtPosition(Position(6, 14)); if (FFlag::LuauSolverV2) CHECK_EQ("(unknown, number, number) -> number", toString(type)); else CHECK_EQ("(tbl, number, number) -> number", toString(type)); auto ftv = get(follow(type)); REQUIRE(ftv); CHECK(ftv->hasSelf); } TEST_CASE_FIXTURE(Fixture, "record_matching_overload") { CheckResult result = check(R"( type Overload = ((string) -> string) & ((number) -> number) local abc: Overload abc(1) )"); LUAU_REQUIRE_NO_ERRORS(result); // AstExprCall is the node that has the overload stored on it. // findTypeAtPosition will look at the AstExprLocal, but this is not what // we want to look at. std::vector ancestry = findAstAncestryOfPosition(*getMainSourceModule(), Position(3, 10)); REQUIRE_GE(ancestry.size(), 2); AstExpr* parentExpr = ancestry[ancestry.size() - 2]->asExpr(); REQUIRE(bool(parentExpr)); REQUIRE(parentExpr->is()); ModulePtr module = getMainModule(); auto it = module->astOverloadResolvedTypes.find(parentExpr); REQUIRE(it); CHECK_EQ(toString(*it), "(number) -> number"); } TEST_CASE_FIXTURE(Fixture, "return_type_by_overload") { CheckResult result = check(R"( type Overload = ((string) -> string) & ((number, number) -> number) local abc: Overload local x = abc(true) local y = abc(true,true) local z = abc(true,true,true) )"); LUAU_REQUIRE_ERRORS(result); CHECK_EQ("string", toString(requireType("x"))); // the new solver does not currently "favor" arity-matching overloads when the call itself is ill-typed. if (FFlag::LuauSolverV2) CHECK_EQ("string", toString(requireType("y"))); else CHECK_EQ("number", toString(requireType("y"))); // Should this be string|number? CHECK_EQ("string", toString(requireType("z"))); } TEST_CASE_FIXTURE(BuiltinsFixture, "infer_anonymous_function_arguments") { // FIXME: CLI-116133 bidirectional type inference needs to push expected types in for higher-order function calls DOES_NOT_PASS_NEW_SOLVER_GUARD(); // Simple direct arg to arg propagation CheckResult result = check(R"( type Table = { x: number, y: number } local function f(a: (Table) -> number) return a({x = 1, y = 2}) end f(function(a) return a.x + a.y end) )"); LUAU_REQUIRE_NO_ERRORS(result); // An optional function is accepted, but since we already provide a function, nil can be ignored result = check(R"( type Table = { x: number, y: number } local function f(a: ((Table) -> number)?) if a then return a({x = 1, y = 2}) else return 0 end end f(function(a) return a.x + a.y end) )"); LUAU_REQUIRE_NO_ERRORS(result); // Make sure self calls match correct index result = check(R"( type Table = { x: number, y: number } local x = {} x.b = {x = 1, y = 2} function x:f(a: (Table) -> number) return a(self.b) end x:f(function(a) return a.x + a.y end) )"); LUAU_REQUIRE_NO_ERRORS(result); // Mix inferred and explicit argument types result = check(R"( function f(a: (a: number, b: number, c: boolean) -> number) return a(1, 2, true) end f(function(a: number, b, c) return c and a + b or b - a end) )"); LUAU_REQUIRE_NO_ERRORS(result); // Anonymous function has a variadic pack result = check(R"( type Table = { x: number, y: number } local function f(a: (Table) -> number) return a({x = 1, y = 2}) end f(function(...) return select(1, ...).z end) )"); LUAU_REQUIRE_ERRORS(result); CHECK_EQ("Key 'z' not found in table 'Table'", toString(result.errors[0])); // Can't accept more arguments than provided result = check(R"( function f(a: (a: number, b: number) -> number) return a(1, 2) end f(function(a, b, c, ...) return a + b end) )"); LUAU_REQUIRE_ERRORS(result); std::string expected; if (FFlag::LuauInstantiateInSubtyping) { expected = R"(Type '(number, number, a) -> number' could not be converted into '(number, number) -> number' caused by: Argument count mismatch. Function expects 3 arguments, but only 2 are specified)"; } else { expected = R"(Type '(number, number, *error-type*) -> number' could not be converted into '(number, number) -> number' caused by: Argument count mismatch. Function expects 3 arguments, but only 2 are specified)"; } CHECK_EQ(expected, toString(result.errors[0])); // Infer from variadic packs into elements result = check(R"( function f(a: (...number) -> number) return a(1, 2) end f(function(a, b) return a + b end) )"); LUAU_REQUIRE_NO_ERRORS(result); // Infer from variadic packs into variadic packs result = check(R"( type Table = { x: number, y: number } function f(a: (...Table) -> number) return a({x = 1, y = 2}, {x = 3, y = 4}) end f(function(a, ...) local b = ... return b.z end) )"); LUAU_REQUIRE_ERRORS(result); CHECK_EQ("Key 'z' not found in table 'Table'", toString(result.errors[0])); // Return type inference result = check(R"( type Table = { x: number, y: number } function f(a: (number) -> Table) return a(4) end f(function(x) return x * 2 end) )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_EQ("Type 'number' could not be converted into 'Table'", toString(result.errors[0])); // Return type doesn't inference 'nil' result = check(R"( function f(a: (number) -> nil) return a(4) end f(function(x) print(x) end) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "infer_generic_function_function_argument") { // FIXME: CLI-116133 bidirectional type inference needs to push expected types in for higher-order function calls DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( local function sum(x: a, y: a, f: (a, a) -> a) return f(x, y) end return sum(2, 3, function(a, b) return a + b end) )"); LUAU_REQUIRE_NO_ERRORS(result); result = check(R"( local function map(arr: {a}, f: (a) -> b) local r = {} for i,v in ipairs(arr) do table.insert(r, f(v)) end return r end local a = {1, 2, 3} local r = map(a, function(a) return a + a > 100 end) )"); LUAU_REQUIRE_NO_ERRORS(result); REQUIRE_EQ("{boolean}", toString(requireType("r"))); check(R"( local function foldl(arr: {a}, init: b, f: (b, a) -> b) local r = init for i,v in ipairs(arr) do r = f(r, v) end return r end local a = {1, 2, 3} local r = foldl(a, {s=0,c=0}, function(a, b) return {s = a.s + b, c = a.c + 1} end) )"); LUAU_REQUIRE_NO_ERRORS(result); REQUIRE_EQ("{ c: number, s: number }", toString(requireType("r"))); } TEST_CASE_FIXTURE(Fixture, "infer_generic_function_function_argument_overloaded") { // FIXME: CLI-116133 bidirectional type inference needs to push expected types in for higher-order function calls DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( local function g1(a: T, f: (T) -> T) return f(a) end local function g2(a: T, b: T, f: (T, T) -> T) return f(a, b) end local g12: typeof(g1) & typeof(g2) g12(1, function(x) return x + x end) g12(1, 2, function(x, y) return x + y end) )"); LUAU_REQUIRE_NO_ERRORS(result); result = check(R"( local function g1(a: T, f: (T) -> T) return f(a) end local function g2(a: T, b: T, f: (T, T) -> T) return f(a, b) end local g12: typeof(g1) & typeof(g2) g12({x=1}, function(x) return {x=-x.x} end) g12({x=1}, {x=2}, function(x, y) return {x=x.x + y.x} end) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "infer_generic_lib_function_function_argument") { CheckResult result = check(R"( local a = {{x=4}, {x=7}, {x=1}} table.sort(a, function(x, y) return x.x < y.x end) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "variadic_any_is_compatible_with_a_generic_TypePack") { CheckResult result = check(R"( --!strict local function f(...) return ... end local g = function(...) return f(...) end )"); LUAU_REQUIRE_NO_ERRORS(result); } // https://github.com/luau-lang/luau/issues/767 TEST_CASE_FIXTURE(BuiltinsFixture, "variadic_any_is_compatible_with_a_generic_TypePack_2") { CheckResult result = check(R"( local function somethingThatsAny(...: any) print(...) end local function x(...: T...) somethingThatsAny(...) -- Failed to unify variadic type packs end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "infer_anonymous_function_arguments_outside_call") { // FIXME: CLI-116133 bidirectional type inference needs to push expected types in for higher-order function calls DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( type Table = { x: number, y: number } local f: (Table) -> number = function(t) return t.x + t.y end type TableWithFunc = { x: number, y: number, f: (number, number) -> number } local a: TableWithFunc = { x = 3, y = 4, f = function(a, b) return a + b end } )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "infer_return_value_type") { CheckResult result = check(R"( local function f(): {string|number} return {1, "b", 3} end local function g(): (number, {string|number}) return 4, {1, "b", 3} end local function h(): ...{string|number} return {4}, {1, "b", 3}, {"s"} end local function i(): ...{string|number} return {1, "b", 3}, h() end )"); // `h` regresses in the new solver, the return type is not being pushed into the body. if (FFlag::LuauSolverV2) LUAU_REQUIRE_ERROR_COUNT(1, result); else LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "error_detailed_function_mismatch_arg_count") { // FIXME: CLI-116111 test disabled until type path stringification is improved DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( type A = (number, number) -> string type B = (number) -> string local a: A local b: B = a )"); LUAU_REQUIRE_ERROR_COUNT(1, result); const std::string expected = R"(Type '(number, number) -> string' could not be converted into '(number) -> string' caused by: Argument count mismatch. Function expects 2 arguments, but only 1 is specified)"; CHECK_EQ(expected, toString(result.errors[0])); } TEST_CASE_FIXTURE(Fixture, "error_detailed_function_mismatch_arg") { // FIXME: CLI-116111 test disabled until type path stringification is improved DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( type A = (number, number) -> string type B = (number, string) -> string local a: A local b: B = a )"); LUAU_REQUIRE_ERROR_COUNT(1, result); const std::string expected = R"(Type '(number, number) -> string' could not be converted into '(number, string) -> string' caused by: Argument #2 type is not compatible. Type 'string' could not be converted into 'number')"; CHECK_EQ(expected, toString(result.errors[0])); } TEST_CASE_FIXTURE(Fixture, "error_detailed_function_mismatch_ret_count") { // FIXME: CLI-116111 test disabled until type path stringification is improved DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( type A = (number, number) -> (number) type B = (number, number) -> (number, boolean) local a: A local b: B = a )"); LUAU_REQUIRE_ERROR_COUNT(1, result); const std::string expected = R"(Type '(number, number) -> number' could not be converted into '(number, number) -> (number, boolean)' caused by: Function only returns 1 value, but 2 are required here)"; CHECK_EQ(expected, toString(result.errors[0])); } TEST_CASE_FIXTURE(Fixture, "error_detailed_function_mismatch_ret") { // FIXME: CLI-116111 test disabled until type path stringification is improved DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( type A = (number, number) -> string type B = (number, number) -> number local a: A local b: B = a )"); LUAU_REQUIRE_ERROR_COUNT(1, result); const std::string expected = R"(Type '(number, number) -> string' could not be converted into '(number, number) -> number' caused by: Return type is not compatible. Type 'string' could not be converted into 'number')"; CHECK_EQ(expected, toString(result.errors[0])); } TEST_CASE_FIXTURE(Fixture, "error_detailed_function_mismatch_ret_mult") { // FIXME: CLI-116111 test disabled until type path stringification is improved DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( type A = (number, number) -> (number, string) type B = (number, number) -> (number, boolean) local a: A local b: B = a )"); LUAU_REQUIRE_ERROR_COUNT(1, result); const std::string expected = R"(Type '(number, number) -> (number, string)' could not be converted into '(number, number) -> (number, boolean)' caused by: Return #2 type is not compatible. Type 'string' could not be converted into 'boolean')"; CHECK_EQ(expected, toString(result.errors[0])); } TEST_CASE_FIXTURE(BuiltinsFixture, "function_decl_quantify_right_type") { fileResolver.source["game/isAMagicMock"] = R"( --!nonstrict return function(value) return false end )"; CheckResult result = check(R"( --!nonstrict local MagicMock = {} MagicMock.is = require(game.isAMagicMock) function MagicMock.is(value) return false end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "function_decl_non_self_sealed_overwrite") { CheckResult result = check(R"( function string.len(): number return 1 end local s = string )"); LUAU_REQUIRE_NO_ERRORS(result); // if 'string' library property was replaced with an internal module type, it will be freed and the next check will crash frontend.clear(); CheckResult result2 = check(R"( print(string.len('hello')) )"); LUAU_REQUIRE_NO_ERRORS(result2); } TEST_CASE_FIXTURE(BuiltinsFixture, "function_decl_non_self_sealed_overwrite_2") { CheckResult result = check(R"( local t: { f: ((x: number) -> number)? } = {} function t.f(x) print(x + 5) return x .. "asd" -- 1st error: we know that return type is a number, not a string end t.f = function(x) print(x + 5) return x .. "asd" -- 2nd error: we know that return type is a number, not a string end )"); if (FFlag::LuauSolverV2) { LUAU_REQUIRE_ERROR_COUNT(2, result); CHECK_EQ( toString(result.errors[0]), R"(Type function instance add depends on generic function parameters but does not appear in the function signature; this construct cannot be type-checked at this time)" ); CHECK_EQ( toString(result.errors[1]), R"(Type function instance add depends on generic function parameters but does not appear in the function signature; this construct cannot be type-checked at this time)" ); } else { LUAU_REQUIRE_ERROR_COUNT(2, result); CHECK_EQ(toString(result.errors[0]), R"(Type 'string' could not be converted into 'number')"); CHECK_EQ(toString(result.errors[1]), R"(Type 'string' could not be converted into 'number')"); } } TEST_CASE_FIXTURE(Fixture, "inferred_higher_order_functions_are_quantified_at_the_right_time2") { CheckResult result = check(R"( --!strict local function resolveDispatcher() return (nil :: any) :: {useContext: (number?) -> any} end local useContext useContext = function(unstable_observedBits: number?) resolveDispatcher().useContext(unstable_observedBits) end )"); // LUAU_REQUIRE_NO_ERRORS is particularly unhelpful when this test is broken. // You get a TypeMismatch error where both types stringify the same. CHECK(result.errors.empty()); if (!result.errors.empty()) { for (const auto& e : result.errors) MESSAGE(e.moduleName << " " << toString(e.location) << ": " << toString(e)); } } TEST_CASE_FIXTURE(Fixture, "inferred_higher_order_functions_are_quantified_at_the_right_time3") { // This test regresses in the new solver, but is sort of nonsensical insofar as `foo` is known to be `nil`, so it's "right" to not be able to call // it. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( local foo foo():bar(function() return foo() end) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "function_decl_non_self_unsealed_overwrite") { CheckResult result = check(R"( local t = { f = nil :: ((x: number) -> number)? } function t.f(x: string): string -- 1st error: new function value type is incompatible return x .. "asd" end t.f = function(x) print(x + 5) return x .. "asd" -- 2nd error: we know that return type is a number, not a string end )"); if (FFlag::LuauSolverV2) { LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_EQ( toString(result.errors[0]), R"(Type function instance add depends on generic function parameters but does not appear in the function signature; this construct cannot be type-checked at this time)" ); } else { LUAU_REQUIRE_ERROR_COUNT(2, result); CHECK_EQ(toString(result.errors[0]), R"(Type '(string) -> string' could not be converted into '((number) -> number)?' caused by: None of the union options are compatible. For example: Type '(string) -> string' could not be converted into '(number) -> number' caused by: Argument #1 type is not compatible. Type 'number' could not be converted into 'string')"); CHECK_EQ(toString(result.errors[1]), R"(Type 'string' could not be converted into 'number')"); } } TEST_CASE_FIXTURE(Fixture, "strict_mode_ok_with_missing_arguments") { CheckResult result = check(R"( local function f(x: any) end f() )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "function_statement_sealed_table_assignment_through_indexer") { // FIXME: CLI-116122 bug where `t:b` does not check against the type from the indexer annotation on `t`. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( local t: {[string]: () -> number} = {} function t.a() return 1 end -- OK function t:b() return 2 end -- not OK )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_EQ( R"(Type '(*error-type*) -> number' could not be converted into '() -> number' caused by: Argument count mismatch. Function expects 1 argument, but none are specified)", toString(result.errors[0]) ); } TEST_CASE_FIXTURE(Fixture, "too_few_arguments_variadic") { CheckResult result = check(R"( function test(a: number, b: string, ...) end test(1) )"); LUAU_REQUIRE_ERROR_COUNT(1, result); auto err = result.errors[0]; auto acm = get(err); REQUIRE(acm); CHECK_EQ(2, acm->expected); CHECK_EQ(1, acm->actual); CHECK_EQ(CountMismatch::Context::Arg, acm->context); CHECK(acm->isVariadic); } TEST_CASE_FIXTURE(Fixture, "too_few_arguments_variadic_generic") { // FIXME: CLI-116157 variadic and generic type packs seem to be interacting incorrectly. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( function test(a: number, b: string, ...) return 1 end function wrapper(f: (A...) -> number, ...: A...) end wrapper(test) )"); LUAU_REQUIRE_ERROR_COUNT(1, result); auto err = result.errors[0]; auto acm = get(err); REQUIRE(acm); CHECK_EQ(3, acm->expected); CHECK_EQ(1, acm->actual); CHECK_EQ(CountMismatch::Context::Arg, acm->context); CHECK(acm->isVariadic); } TEST_CASE_FIXTURE(BuiltinsFixture, "too_few_arguments_variadic_generic2") { // FIXME: CLI-116157 variadic and generic type packs seem to be interacting incorrectly. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( function test(a: number, b: string, ...) return 1 end function wrapper(f: (A...) -> number, ...: A...) end pcall(wrapper, test) )"); LUAU_REQUIRE_ERROR_COUNT(1, result); auto err = result.errors[0]; auto acm = get(err); REQUIRE(acm); CHECK_EQ(4, acm->expected); CHECK_EQ(2, acm->actual); CHECK_EQ(CountMismatch::Context::Arg, acm->context); CHECK(acm->isVariadic); } TEST_CASE_FIXTURE(Fixture, "occurs_check_failure_in_function_return_type") { CheckResult result = check(R"( function f() return 5, f() end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK(nullptr != get(result.errors[0])); } TEST_CASE_FIXTURE(Fixture, "free_is_not_bound_to_unknown") { // This test only makes sense for the old solver if (FFlag::LuauSolverV2) return; CheckResult result = check(R"( local function foo(f: (unknown) -> (), x) f(x) end )"); CHECK_EQ("((unknown) -> (), a) -> ()", toString(requireType("foo"))); } TEST_CASE_FIXTURE(Fixture, "dont_infer_parameter_types_for_functions_from_their_call_site") { CheckResult result = check(R"( local t = {} function t.f(x) return x end t.__index = t function g(s) local q = s.p and s.p.q or nil return q and t.f(q) or nil end local f = t.f )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("(a) -> a", toString(requireType("f"))); if (FFlag::LuauSolverV2) CHECK_EQ("({ read p: { read q: unknown } }) -> ~(false?)?", toString(requireType("g"))); else CHECK_EQ("({+ p: {+ q: nil +} +}) -> nil", toString(requireType("g"))); } TEST_CASE_FIXTURE(Fixture, "dont_mutate_the_underlying_head_of_typepack_when_calling_with_self") { CheckResult result = check(R"( local t = {} function t:m(x) end function f(): never return 5 :: never end t:m(f()) t:m(f()) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "improved_function_arg_mismatch_errors") { CheckResult result = check(R"( local function foo1(a: number) end foo1() local function foo2(a: number, b: string?) end foo2() local function foo3(a: number, b: string?, c: any) end -- any is optional foo3() string.find() local t = {} function t.foo(x: number, y: string?, ...: any) return 1 end function t:bar(x: number, y: string?) end t.foo() t:bar() local u = { a = t, b = function() return t end } u.a.foo() local x = (u.a).foo() u.b().foo() )"); LUAU_REQUIRE_ERROR_COUNT(9, result); if (FFlag::LuauSolverV2) { // These improvements to the error messages are currently regressed in the new type solver. CHECK_EQ(toString(result.errors[0]), "Argument count mismatch. Function expects 1 argument, but none are specified"); CHECK_EQ(toString(result.errors[1]), "Argument count mismatch. Function expects 1 to 2 arguments, but none are specified"); CHECK_EQ(toString(result.errors[2]), "Argument count mismatch. Function expects 1 to 3 arguments, but none are specified"); CHECK_EQ(toString(result.errors[3]), "Argument count mismatch. Function expects 2 to 4 arguments, but none are specified"); CHECK_EQ(toString(result.errors[4]), "Argument count mismatch. Function expects at least 1 argument, but none are specified"); CHECK_EQ(toString(result.errors[5]), "Argument count mismatch. Function expects 2 to 3 arguments, but only 1 is specified"); CHECK_EQ(toString(result.errors[6]), "Argument count mismatch. Function expects at least 1 argument, but none are specified"); CHECK_EQ(toString(result.errors[7]), "Argument count mismatch. Function expects at least 1 argument, but none are specified"); CHECK_EQ(toString(result.errors[8]), "Argument count mismatch. Function expects at least 1 argument, but none are specified"); } else { CHECK_EQ(toString(result.errors[0]), "Argument count mismatch. Function 'foo1' expects 1 argument, but none are specified"); CHECK_EQ(toString(result.errors[1]), "Argument count mismatch. Function 'foo2' expects 1 to 2 arguments, but none are specified"); CHECK_EQ(toString(result.errors[2]), "Argument count mismatch. Function 'foo3' expects 1 to 3 arguments, but none are specified"); CHECK_EQ(toString(result.errors[3]), "Argument count mismatch. Function 'string.find' expects 2 to 4 arguments, but none are specified"); CHECK_EQ(toString(result.errors[4]), "Argument count mismatch. Function 't.foo' expects at least 1 argument, but none are specified"); CHECK_EQ(toString(result.errors[5]), "Argument count mismatch. Function 't.bar' expects 2 to 3 arguments, but only 1 is specified"); CHECK_EQ(toString(result.errors[6]), "Argument count mismatch. Function 'u.a.foo' expects at least 1 argument, but none are specified"); CHECK_EQ(toString(result.errors[7]), "Argument count mismatch. Function 'u.a.foo' expects at least 1 argument, but none are specified"); CHECK_EQ(toString(result.errors[8]), "Argument count mismatch. Function expects at least 1 argument, but none are specified"); } } // This might be surprising, but since 'any' became optional, unannotated functions in non-strict 'expect' 0 arguments TEST_CASE_FIXTURE(BuiltinsFixture, "improved_function_arg_mismatch_error_nonstrict") { // This behavior is not part of the current specification of the new type solver. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( --!nonstrict local function foo(a, b) end foo(string.find("hello", "e")) )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_EQ(toString(result.errors[0]), "Argument count mismatch. Function 'foo' expects 0 to 2 arguments, but 3 are specified"); } TEST_CASE_FIXTURE(Fixture, "luau_subtyping_is_np_hard") { // The case that _should_ succeed here (`z = x`) does not currently in the new solver. DOES_NOT_PASS_NEW_SOLVER_GUARD(); CheckResult result = check(R"( --!strict -- An example of coding up graph coloring in the Luau type system. -- This codes a three-node, two color problem. -- A three-node triangle is uncolorable, -- but a three-node line is colorable. type Red = "red" type Blue = "blue" type Color = Red | Blue type Coloring = (Color) -> (Color) -> (Color) -> boolean type Uncolorable = (Color) -> (Color) -> (Color) -> false type Line = Coloring & ((Red) -> (Red) -> (Color) -> false) & ((Blue) -> (Blue) -> (Color) -> false) & ((Color) -> (Red) -> (Red) -> false) & ((Color) -> (Blue) -> (Blue) -> false) type Triangle = Line & ((Red) -> (Color) -> (Red) -> false) & ((Blue) -> (Color) -> (Blue) -> false) local x : Triangle local y : Line local z : Uncolorable z = x -- OK, so the triangle is uncolorable z = y -- Not OK, so the line is colorable )"); LUAU_REQUIRE_ERROR_COUNT(1, result); const std::string expected = R"(Type '(("blue" | "red") -> ("blue" | "red") -> ("blue" | "red") -> boolean) & (("blue" | "red") -> ("blue") -> ("blue") -> false) & (("blue" | "red") -> ("red") -> ("red") -> false) & (("blue") -> ("blue") -> ("blue" | "red") -> false) & (("red") -> ("red") -> ("blue" | "red") -> false)' could not be converted into '("blue" | "red") -> ("blue" | "red") -> ("blue" | "red") -> false'; none of the intersection parts are compatible)"; CHECK_EQ(expected, toString(result.errors[0])); } TEST_CASE_FIXTURE(Fixture, "function_is_supertype_of_concrete_functions") { registerHiddenTypes(&frontend); CheckResult result = check(R"( function foo(f: fun) end function a() end function id(x) return x end foo(a) foo(id) foo(foo) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "concrete_functions_are_not_supertypes_of_function") { registerHiddenTypes(&frontend); CheckResult result = check(R"( local a: fun = function() end function one(arg: () -> ()) end function two(arg: (T) -> T) end one(a) two(a) )"); LUAU_REQUIRE_ERROR_COUNT(2, result); CHECK(6 == result.errors[0].location.begin.line); auto tm1 = get(result.errors[0]); REQUIRE(tm1); CHECK("() -> ()" == toString(tm1->wantedType)); CHECK("function" == toString(tm1->givenType)); CHECK(7 == result.errors[1].location.begin.line); auto tm2 = get(result.errors[1]); REQUIRE(tm2); CHECK("(T) -> T" == toString(tm2->wantedType)); CHECK("function" == toString(tm2->givenType)); } TEST_CASE_FIXTURE(Fixture, "other_things_are_not_related_to_function") { registerHiddenTypes(&frontend); CheckResult result = check(R"( local a: fun = function() end local b: {} = a local c: boolean = a local d: fun = true local e: fun = {} )"); LUAU_REQUIRE_ERROR_COUNT(4, result); CHECK(2 == result.errors[0].location.begin.line); CHECK(3 == result.errors[1].location.begin.line); CHECK(4 == result.errors[2].location.begin.line); CHECK(5 == result.errors[3].location.begin.line); } TEST_CASE_FIXTURE(BuiltinsFixture, "fuzz_must_follow_in_overload_resolution") { CheckResult result = check(R"( for _ in function():(t0)&((()->())&(()->())) end do _(_(_,_,_),_) end )"); LUAU_REQUIRE_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "dont_assert_when_the_tarjan_limit_is_exceeded_during_generalization") { ScopedFastFlag sff{FFlag::LuauSolverV2, true}; ScopedFastInt sfi{FInt::LuauTarjanChildLimit, 1}; CheckResult result = check(R"( function f(t) t.x.y.z = 441 end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK_MESSAGE(get(result.errors[0]), "Expected UnificationTooComplex but got: " << toString(result.errors[0])); } /* We had a bug under DCR where instantiated type packs had a nullptr scope. * * This caused an issue with promotion. */ TEST_CASE_FIXTURE(Fixture, "instantiated_type_packs_must_have_a_non_null_scope") { CheckResult result = check(R"( function pcall(...: (A...) -> R...): (boolean, R...) return nil :: any end type Dispatch = (A) -> () function mountReducer() dispatchAction() return nil :: any end function dispatchAction() end function useReducer(): Dispatch local result, setResult = pcall(mountReducer) return setResult end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "inner_frees_become_generic_in_dcr") { if (!FFlag::LuauSolverV2) return; CheckResult result = check(R"( function f(x) local z = x return x end )"); LUAU_REQUIRE_NO_ERRORS(result); std::optional ty = findTypeAtPosition(Position{3, 19}); REQUIRE(ty); CHECK(get(follow(*ty))); } TEST_CASE_FIXTURE(Fixture, "function_exprs_are_generalized_at_signature_scope_not_enclosing") { CheckResult result = check(R"( local foo local bar -- foo being a function expression is deliberate: the bug we're testing -- only existed for function expressions, not for function statements. foo = function(a) return bar end )"); LUAU_REQUIRE_NO_ERRORS(result); if (FFlag::LuauSolverV2) CHECK(toString(requireType("foo")) == "((unknown) -> nil)?"); else { // note that b is not in the generic list; it is free, the unconstrained type of `bar`. CHECK(toString(requireType("foo")) == "(a) -> b"); } } TEST_CASE_FIXTURE(BuiltinsFixture, "param_1_and_2_both_takes_the_same_generic_but_their_arguments_are_incompatible") { CheckResult result = check(R"( local function foo(x: a, y: a?) return x end local vec2 = { x = 5, y = 7 } local ret: number = foo(vec2, { x = 5 }) )"); if (FFlag::LuauSolverV2) { LUAU_REQUIRE_ERROR_COUNT(1, result); auto tm = get(result.errors[0]); REQUIRE(tm); CHECK("number" == toString(tm->wantedType)); CHECK("{ x: number }" == toString(tm->givenType)); } else { // In the old solver, this produces a very strange result: // // Here, we instantiate `(x: a, y: a?) -> a` with a fresh type `'a` for `a`. // In argument #1, we unify `vec2` with `'a`. // This is ok, so we record an equality constraint `'a` with `vec2`. // In argument #2, we unify `{ x: number }` with `'a?`. // This fails because `'a` has equality constraint with `vec2`, // so `{ x: number } <: vec2?`, which is false. // // If the unifications were to be committed, then it'd result in the following type error: // // Type '{ x: number }' could not be converted into 'vec2?' // caused by: // [...] Table type '{ x: number }' not compatible with type 'vec2' because the former is missing field 'y' // // However, whenever we check the argument list, if there's an error, we don't commit the unifications, so it actually looks like this: // // Type '{ x: number }' could not be converted into 'a?' // caused by: // [...] Table type '{ x: number }' not compatible with type 'vec2' because the former is missing field 'y' // // Then finally, that generic is left floating free, and since the function returns that generic, // that free type is then later bound to `number`, which succeeds and mutates the type graph. // This again changes the type error where `a` becomes bound to `number`. // // Type '{ x: number }' could not be converted into 'number?' // caused by: // [...] Table type '{ x: number }' not compatible with type 'vec2' because the former is missing field 'y' // // Uh oh, that type error is extremely confusing for people who doesn't know how that went down. // Really, what should happen is we roll each argument incompatibility into a union type, but that needs local type inference. LUAU_REQUIRE_ERROR_COUNT(2, result); const std::string expected = R"(Type '{ x: number }' could not be converted into 'vec2?' caused by: None of the union options are compatible. For example: Table type '{ x: number }' not compatible with type 'vec2' because the former is missing field 'y')"; CHECK_EQ(expected, toString(result.errors[0])); CHECK_EQ("Type 'vec2' could not be converted into 'number'", toString(result.errors[1])); } } TEST_CASE_FIXTURE(BuiltinsFixture, "param_1_and_2_both_takes_the_same_generic_but_their_arguments_are_incompatible_2") { CheckResult result = check(R"( local function f(x: a, y: a): a return if math.random() > 0.5 then x else y end local z: boolean = f(5, "five") )"); if (FFlag::LuauSolverV2) { LUAU_REQUIRE_ERROR_COUNT(1, result); auto tm = get(result.errors[0]); REQUIRE(tm); CHECK("boolean" == toString(tm->wantedType)); CHECK("number | string" == toString(tm->givenType)); } else { LUAU_REQUIRE_ERROR_COUNT(2, result); CHECK_EQ(toString(result.errors[0]), "Type 'string' could not be converted into 'number'"); CHECK_EQ(toString(result.errors[1]), "Type 'number' could not be converted into 'boolean'"); } } TEST_CASE_FIXTURE(Fixture, "attempt_to_call_an_intersection_of_tables") { CheckResult result = check(R"( local function f(t: { x: number } & { y: string }) t() end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); if (FFlag::LuauSolverV2) CHECK_EQ(toString(result.errors[0]), "Cannot call a value of type { x: number } & { y: string }"); else CHECK_EQ(toString(result.errors[0]), "Cannot call a value of type {| x: number |}"); } TEST_CASE_FIXTURE(BuiltinsFixture, "attempt_to_call_an_intersection_of_tables_with_call_metamethod") { CheckResult result = check(R"( type Callable = typeof(setmetatable({}, { __call = function(self, ...) return ... end })) local function f(t: Callable & { x: number }) t() end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "generic_packs_are_not_variadic") { ScopedFastFlag sff{FFlag::LuauSolverV2, true}; CheckResult result = check(R"( local function apply(f: (a, b...) -> c..., x: a) return f(x) end local function add(x: number, y: number) return x + y end apply(add, 5) )"); // FIXME: this errored at some point, but doesn't anymore. // the desired behavior here is erroring. LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "num_is_solved_before_num_or_str") { CheckResult result = check(R"( function num() return 5 end local function num_or_str() if math.random() > 0.5 then return num() else return "some string" end end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); if (FFlag::LuauSolverV2) CHECK(toString(result.errors.at(0)) == "Type pack 'string' could not be converted into 'number'; at [0], string is not a subtype of number"); else CHECK_EQ("Type 'string' could not be converted into 'number'", toString(result.errors[0])); CHECK_EQ("() -> number", toString(requireType("num_or_str"))); } TEST_CASE_FIXTURE(BuiltinsFixture, "num_is_solved_after_num_or_str") { CheckResult result = check(R"( local function num_or_str() if math.random() > 0.5 then return num() else return "some string" end end function num() return 5 end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); if (FFlag::LuauSolverV2) CHECK(toString(result.errors.at(0)) == "Type pack 'string' could not be converted into 'number'; at [0], string is not a subtype of number"); else CHECK_EQ("Type 'string' could not be converted into 'number'", toString(result.errors[0])); CHECK_EQ("() -> number", toString(requireType("num_or_str"))); } TEST_CASE_FIXTURE(BuiltinsFixture, "apply_of_lambda_with_inferred_and_explicit_types") { CheckResult result = check(R"( local function apply(f, x) return f(x) end local x = apply(function(x: string): number return 5 end, "hello!") local function apply_explicit(f: (A) -> B..., x: A): B... return f(x) end local x = apply_explicit(function(x: string): number return 5 end, "hello!") )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "regex_benchmark_string_format_minimization") { CheckResult result = check(R"( (nil :: any)(function(n) if tonumber(n) then n = tonumber(n) elseif n ~= nil then string.format("invalid argument #4 to 'sub': number expected, got %s", typeof(n)) end end); )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "subgeneric_type_function_super_monomorphic") { CheckResult result = check(R"( local a: (number, number) -> number = function(a, b) return a - b end a = function(a, b) return a + b end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "simple_unannotated_mutual_recursion") { // CLI-117118 - TypeInferFunctions.simple_unannotated_mutual_recursion relies on unstable assertions to pass. if (FFlag::LuauSolverV2) return; CheckResult result = check(R"( function even(n) if n == 0 then return true else return odd(n - 1) end end function odd(n) if n == 0 then return false elseif n == 1 then return true else return even(n - 1) end end )"); if (FFlag::LuauSolverV2) { LUAU_REQUIRE_ERROR_COUNT(5, result); // CLI-117117 Constraint solving is incomplete inTypeInferFunctions.simple_unannotated_mutual_recursion CHECK(get(result.errors[0])); // This check is unstable between different machines and different runs of DCR because it depends on string equality between // blocked type numbers, which is not guaranteed. bool r = toString(result.errors[1]) == "Type pack '*blocked-tp-1*' could not be converted into 'boolean'; type *blocked-tp-1*.tail() " "(*blocked-tp-1*) is not a subtype of boolean (boolean)"; CHECK(r); CHECK( toString(result.errors[2]) == "Operator '-' could not be applied to operands of types unknown and number; there is no corresponding overload for __sub" ); CHECK( toString(result.errors[3]) == "Operator '-' could not be applied to operands of types unknown and number; there is no corresponding overload for __sub" ); CHECK( toString(result.errors[4]) == "Operator '-' could not be applied to operands of types unknown and number; there is no corresponding overload for __sub" ); } else { LUAU_REQUIRE_ERROR_COUNT(1, result); CHECK(toString(result.errors[0]) == "Unknown type used in - operation; consider adding a type annotation to 'n'"); } } TEST_CASE_FIXTURE(BuiltinsFixture, "simple_lightly_annotated_mutual_recursion") { CheckResult result = check(R"( function even(n: number) if n == 0 then return true else return odd(n - 1) end end function odd(n: number) if n == 0 then return false elseif n == 1 then return true else return even(n - 1) end end )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("(number) -> boolean", toString(requireType("even"))); CHECK_EQ("(number) -> boolean", toString(requireType("odd"))); } TEST_CASE_FIXTURE(BuiltinsFixture, "tf_suggest_return_type") { ScopedFastFlag sffs[] = { {FFlag::LuauSolverV2, true}, {FFlag::LuauDontRefCountTypesInTypeFunctions, true} }; // CLI-114134: This test: // a) Has a kind of weird result (suggesting `number | false` is not great); // b) Is force solving some constraints. // We end up with a weird recursive type that, if you roughly look at it, is // clearly `number`. Hopefully the egraph will be able to unfold this. CheckResult result = check(R"( function fib(n) return n < 2 and 1 or fib(n-1) + fib(n-2) end )"); LUAU_REQUIRE_ERRORS(result); auto err = get(result.errors.back()); LUAU_ASSERT(err); CHECK("false | number" == toString(err->recommendedReturn)); } TEST_CASE_FIXTURE(BuiltinsFixture, "tf_suggest_arg_type") { if (!FFlag::LuauSolverV2) return; CheckResult result = check(R"( function fib(n, u) return (n or u) and (n < u and n + fib(n,u)) end )"); LUAU_REQUIRE_ERRORS(result); auto err = get(result.errors.back()); LUAU_ASSERT(err); CHECK("number" == toString(err->recommendedReturn)); REQUIRE(err->recommendedArgs.size() == 2); CHECK("number" == toString(err->recommendedArgs[0].second)); CHECK("number" == toString(err->recommendedArgs[1].second)); } TEST_CASE_FIXTURE(BuiltinsFixture, "tf_suggest_arg_type_2") { if (!FFlag::LuauSolverV2) return; // Make sure the error types are cloned to module interface frontend.options.retainFullTypeGraphs = false; CheckResult result = check(R"( local function escape_fslash(pre) return (#pre % 2 == 0 and '\\' or '') .. pre .. '.' end )"); LUAU_REQUIRE_ERRORS(result); auto err = get(result.errors.back()); REQUIRE(err); CHECK("a" == toString(err->ty)); } TEST_CASE_FIXTURE(Fixture, "local_function_fwd_decl_doesnt_crash") { CheckResult result = check(R"( local foo local function bar() foo() end function foo() end bar() )"); // This test verifies that an ICE doesn't occur, so the bulk of the test is // just from running check above. LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "bidirectional_checking_of_callback_property") { CheckResult result = check(R"( function print(x: number) end type Point = {x: number, y: number} local T : {callback: ((Point) -> ())?} = {} T.callback = function(p) -- No error here print(p.z) -- error here. Point has no property z end )"); LUAU_REQUIRE_ERROR_COUNT(1, result); if (FFlag::LuauSolverV2) { auto tm = get(result.errors[0]); REQUIRE(tm); CHECK("((Point) -> ())?" == toString(tm->wantedType)); CHECK("({ read z: number }) -> ()" == toString(tm->givenType)); Location location = result.errors[0].location; CHECK(location.begin.line == 6); CHECK(location.end.line == 8); } else { CHECK_MESSAGE(get(result.errors[0]), "Expected UnknownProperty but got " << result.errors[0]); Location location = result.errors[0].location; CHECK(location.begin.line == 7); CHECK(location.end.line == 7); } } TEST_CASE_FIXTURE(ClassFixture, "bidirectional_inference_of_class_methods") { CheckResult result = check(R"( local c = ChildClass.New() -- Instead of reporting that the lambda is the wrong type, report that we are using its argument improperly. c.Touched:Connect(function(other) print(other.ThisDoesNotExist) end) )"); LUAU_REQUIRE_ERROR_COUNT(1, result); UnknownProperty* err = get(result.errors[0]); REQUIRE(err); CHECK("ThisDoesNotExist" == err->key); CHECK("BaseClass" == toString(err->table)); } TEST_CASE_FIXTURE(Fixture, "pass_table_literal_to_function_expecting_optional_prop") { CheckResult result = check(R"( type T = {prop: number?} function f(t: T) end f({prop=5}) f({}) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "dont_infer_overloaded_functions") { CheckResult result = check(R"( function getR6Attachments(model) model:FindFirstChild("Right Leg") model:FindFirstChild("Left Leg") model:FindFirstChild("Torso") model:FindFirstChild("Torso") model:FindFirstChild("Head") model:FindFirstChild("Left Arm") model:FindFirstChild("Right Arm") end )"); LUAU_REQUIRE_NO_ERRORS(result); if (FFlag::LuauSolverV2) CHECK("(t1) -> () where t1 = { read FindFirstChild: (t1, string) -> (...unknown) }" == toString(requireType("getR6Attachments"))); else CHECK("(t1) -> () where t1 = {+ FindFirstChild: (t1, string) -> (a...) +}" == toString(requireType("getR6Attachments"))); } TEST_CASE_FIXTURE(Fixture, "param_y_is_bounded_by_x_of_type_string") { CheckResult result = check(R"( local function f(x: string, y) x = y end )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK("(string, string) -> ()" == toString(requireType("f"))); } TEST_CASE_FIXTURE(BuiltinsFixture, "function_that_could_return_anything_is_compatible_with_function_that_is_expected_to_return_nothing") { CheckResult result = check(R"( -- We infer foo : (g: (number) -> (...unknown)) -> () function foo(g) g(0) end -- a requires a function that returns no values function a(f: ((number) -> ()) -> ()) end -- "Returns an unknown number of values" is close enough to "returns no values." a(foo) )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "self_application_does_not_segfault") { (void)check(R"( function f(a) f(f) return f(), a end )"); // We only care that type checking completes without tripping a crash or an assertion. } TEST_CASE_FIXTURE(Fixture, "function_definition_in_a_do_block") { CheckResult result = check(R"( local f do function f() end end f() )"); // We are predominantly interested in this test not crashing. LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "function_definition_in_a_do_block_with_global") { CheckResult result = check(R"( function f() print("a") end do function f() print("b") end end f() )"); // We are predominantly interested in this test not crashing. LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "fuzzer_alias_global_function_doesnt_hit_nil_assert") { CheckResult result = check(R"( function _() end local function l0() function _() end end _ = _ )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "fuzzer_bug_missing_follow_causes_assertion") { CheckResult result = check(R"( local _ = ({_=function() return _ end,}),true,_[_()] for l0=_[_[_[`{function(l0) end}`]]],_[_.n6[_[_.n6]]],_[_[_.n6[_[_.n6]]]] do _ += if _ then "" end return _ )"); } TEST_CASE_FIXTURE(Fixture, "cannot_call_union_of_functions") { CheckResult result = check(R"( local f: (() -> ()) | (() -> () -> ()) = nil :: any f() )"); LUAU_REQUIRE_ERROR_COUNT(1, result); std::string expected = R"(Cannot call a value of the union type: | () -> () | () -> () -> () We are unable to determine the appropriate result type for such a call.)"; CHECK(expected == toString(result.errors[0])); } TEST_CASE_FIXTURE(Fixture, "fuzzer_missing_follow_in_ast_stat_fun") { (void)check(R"( local _ = function() end ~= _ while (_) do _,_,_,_,_,_,_,_,_,_._,_ = nil function _(...):()->() end function _(...):any _ ..= ... end _,_,_,_,_,_,_,_,_,_,_ = nil end )"); } TEST_CASE_FIXTURE(Fixture, "unifier_should_not_bind_free_types") { ScopedFastFlag _{FFlag::LuauDontRefCountTypesInTypeFunctions, true}; CheckResult result = check(R"( function foo(player) local success,result = player:thing() if(success) then return "Successfully posted message."; elseif(not result) then return false; else return result; end end )"); if (FFlag::LuauSolverV2) { // The new solver should ideally be able to do better here, but this is no worse than the old solver. LUAU_REQUIRE_ERROR_COUNT(2, result); auto tm1 = get(result.errors[0]); REQUIRE(tm1); CHECK(toString(tm1->wantedTp) == "string"); CHECK(toString(tm1->givenTp) == "boolean"); auto tm2 = get(result.errors[1]); REQUIRE(tm2); CHECK(toString(tm2->wantedTp) == "string"); CHECK(toString(tm2->givenTp) == "(buffer | class | function | number | string | table | thread | true) & unknown"); } else { LUAU_REQUIRE_ERROR_COUNT(1, result); const TypeMismatch* tm = get(result.errors[0]); REQUIRE(tm); CHECK(toString(tm->wantedType) == "string"); CHECK(toString(tm->givenType) == "boolean"); } } TEST_CASE_FIXTURE(Fixture, "captured_local_is_assigned_a_function") { CheckResult result = check(R"( local f local function g() f() end function f() end )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(BuiltinsFixture, "error_suppression_propagates_through_function_calls") { CheckResult result = check(R"( function first(x: any) return pairs(x)(x) end )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK("(any) -> (any?, any)" == toString(requireType("first"))); } TEST_CASE_FIXTURE(BuiltinsFixture, "fuzzer_normalizer_out_of_resources") { // This luau code should finish typechecking, not segfault upon dereferencing // the normalized type CheckResult result = check(R"( Module 'l0': local _ = true,...,_ if ... then while _:_(_._G) do do end _ = _ and _ _ = 0 and {# _,} local _ = "CCCCCCCCCCCCCCCCCCCCCCCCCCC" local l0 = require(module0) end local function l0() end elseif _ then l0 = _ end do end while _ do _ = if _ then _ elseif _ then _,if _ then _ else _ _ = _() do end do end if _ then end end _ = _,{} )"); } TEST_CASE_FIXTURE(BuiltinsFixture, "overload_resolution_crash_when_argExprs_is_smaller_than_type_args") { CheckResult result = check(R"( --!strict local parseError type Set = {[T]: any} local function captureDependencies( saveToSet: Set, callback: (...any) -> any, ... ) local data = table.pack(xpcall(callback, parseError, ...)) end )"); } TEST_CASE_FIXTURE(Fixture, "unpack_depends_on_rhs_pack_to_be_fully_resolved") { CheckResult result = check(R"( --!strict local function id(x) return x end local u,v = id(3), id(id(44)) )"); CHECK_EQ(builtinTypes->numberType, requireType("v")); LUAU_REQUIRE_NO_ERRORS(result); } TEST_CASE_FIXTURE(Fixture, "hidden_variadics_should_not_break_subtyping") { // Only applies to new solver. ScopedFastFlag sff{FFlag::LuauRetrySubtypingWithoutHiddenPack, true}; CheckResult result = check(R"( --!strict type FooType = { SetValue: (Value: number) -> () } local Foo: FooType = { SetValue = function(Value: number) end } )"); LUAU_REQUIRE_NO_ERRORS(result); } TEST_SUITE_END();