// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details #include "Luau/Scope.h" #include "Luau/ToString.h" #include "Fixture.h" #include "doctest.h" using namespace Luau; LUAU_FASTFLAG(LuauRecursiveTypeParameterRestriction); LUAU_FASTFLAG(LuauFixNameMaps); LUAU_FASTFLAG(LuauFunctionReturnStringificationFixup); TEST_SUITE_BEGIN("ToString"); TEST_CASE_FIXTURE(Fixture, "primitive") { CheckResult result = check("local a = nil local b = 44 local c = 'lalala' local d = true"); LUAU_REQUIRE_NO_ERRORS(result); // A variable without an annotation and with a nil literal should infer as 'free', not 'nil' CHECK_NE("nil", toString(requireType("a"))); CHECK_EQ("number", toString(requireType("b"))); CHECK_EQ("string", toString(requireType("c"))); CHECK_EQ("boolean", toString(requireType("d"))); } TEST_CASE_FIXTURE(Fixture, "bound_types") { CheckResult result = check("local a = 444 local b = a"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("number", toString(requireType("b"))); } TEST_CASE_FIXTURE(Fixture, "free_types") { CheckResult result = check("local a"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("a", toString(requireType("a"))); } TEST_CASE_FIXTURE(Fixture, "cyclic_table") { TypeVar cyclicTable{TypeVariant(TableTypeVar())}; TableTypeVar* tableOne = getMutable(&cyclicTable); tableOne->props["self"] = {&cyclicTable}; CHECK_EQ("t1 where t1 = { self: t1 }", toString(&cyclicTable)); } TEST_CASE_FIXTURE(Fixture, "named_table") { TypeVar table{TypeVariant(TableTypeVar())}; TableTypeVar* t = getMutable(&table); t->name = "TheTable"; CHECK_EQ("TheTable", toString(&table)); } TEST_CASE_FIXTURE(Fixture, "empty_table") { CheckResult result = check(R"( local a: {} )"); CHECK_EQ("{| |}", toString(requireType("a"))); // Should stay the same with useLineBreaks enabled ToStringOptions opts; opts.useLineBreaks = true; CHECK_EQ("{| |}", toString(requireType("a"), opts)); } TEST_CASE_FIXTURE(Fixture, "table_respects_use_line_break") { CheckResult result = check(R"( local a: { prop: string, anotherProp: number, thirdProp: boolean } )"); ToStringOptions opts; opts.useLineBreaks = true; opts.indent = true; //clang-format off CHECK_EQ("{|\n" " anotherProp: number,\n" " prop: string,\n" " thirdProp: boolean\n" "|}", toString(requireType("a"), opts)); //clang-format on } TEST_CASE_FIXTURE(Fixture, "metatable") { TypeVar table{TypeVariant(TableTypeVar())}; TypeVar metatable{TypeVariant(TableTypeVar())}; TypeVar mtv{TypeVariant(MetatableTypeVar{&table, &metatable})}; CHECK_EQ("{ @metatable { }, { } }", toString(&mtv)); } TEST_CASE_FIXTURE(Fixture, "named_metatable") { TypeVar table{TypeVariant(TableTypeVar())}; TypeVar metatable{TypeVariant(TableTypeVar())}; TypeVar mtv{TypeVariant(MetatableTypeVar{&table, &metatable, "NamedMetatable"})}; CHECK_EQ("NamedMetatable", toString(&mtv)); } TEST_CASE_FIXTURE(BuiltinsFixture, "named_metatable_toStringNamedFunction") { CheckResult result = check(R"( local function createTbl(): NamedMetatable return setmetatable({}, {}) end type NamedMetatable = typeof(createTbl()) )"); TypeId ty = requireType("createTbl"); const FunctionTypeVar* ftv = get(follow(ty)); REQUIRE(ftv); CHECK_EQ("createTbl(): NamedMetatable", toStringNamedFunction("createTbl", *ftv)); } TEST_CASE_FIXTURE(BuiltinsFixture, "exhaustive_toString_of_cyclic_table") { CheckResult result = check(R"( --!strict local Vec3 = {} Vec3.__index = Vec3 function Vec3.new() return setmetatable({x=0, y=0, z=0}, Vec3) end export type Vec3 = typeof(Vec3.new()) local thefun: any = function(self, o) return self end local multiply: ((Vec3, Vec3) -> Vec3) & ((Vec3, number) -> Vec3) = thefun Vec3.__mul = multiply local a = Vec3.new() )"); std::string a = toString(requireType("a"), {true}); CHECK_EQ(std::string::npos, a.find("CYCLE")); CHECK_EQ(std::string::npos, a.find("TRUNCATED")); //clang-format off CHECK_EQ("t2 where " "t1 = { __index: t1, __mul: ((t2, number) -> t2) & ((t2, t2) -> t2), new: () -> t2 } ; " "t2 = { @metatable t1, {| x: number, y: number, z: number |} }", a); //clang-format on } TEST_CASE_FIXTURE(Fixture, "intersection_parenthesized_only_if_needed") { auto utv = TypeVar{UnionTypeVar{{typeChecker.numberType, typeChecker.stringType}}}; auto itv = TypeVar{IntersectionTypeVar{{&utv, typeChecker.booleanType}}}; CHECK_EQ(toString(&itv), "(number | string) & boolean"); } TEST_CASE_FIXTURE(Fixture, "union_parenthesized_only_if_needed") { auto itv = TypeVar{IntersectionTypeVar{{typeChecker.numberType, typeChecker.stringType}}}; auto utv = TypeVar{UnionTypeVar{{&itv, typeChecker.booleanType}}}; CHECK_EQ(toString(&utv), "(number & string) | boolean"); } TEST_CASE_FIXTURE(Fixture, "functions_are_always_parenthesized_in_unions_or_intersections") { auto stringAndNumberPack = TypePackVar{TypePack{{typeChecker.stringType, typeChecker.numberType}}}; auto numberAndStringPack = TypePackVar{TypePack{{typeChecker.numberType, typeChecker.stringType}}}; auto sn2ns = TypeVar{FunctionTypeVar{&stringAndNumberPack, &numberAndStringPack}}; auto ns2sn = TypeVar{FunctionTypeVar(typeChecker.globalScope->level, &numberAndStringPack, &stringAndNumberPack)}; auto utv = TypeVar{UnionTypeVar{{&ns2sn, &sn2ns}}}; auto itv = TypeVar{IntersectionTypeVar{{&ns2sn, &sn2ns}}}; CHECK_EQ(toString(&utv), "((number, string) -> (string, number)) | ((string, number) -> (number, string))"); CHECK_EQ(toString(&itv), "((number, string) -> (string, number)) & ((string, number) -> (number, string))"); } TEST_CASE_FIXTURE(Fixture, "intersections_respects_use_line_breaks") { CheckResult result = check(R"( local a: ((string) -> string) & ((number) -> number) )"); ToStringOptions opts; opts.useLineBreaks = true; //clang-format off CHECK_EQ("((number) -> number)\n" "& ((string) -> string)", toString(requireType("a"), opts)); //clang-format on } TEST_CASE_FIXTURE(Fixture, "unions_respects_use_line_breaks") { CheckResult result = check(R"( local a: string | number | boolean )"); ToStringOptions opts; opts.useLineBreaks = true; //clang-format off CHECK_EQ("boolean\n" "| number\n" "| string", toString(requireType("a"), opts)); //clang-format on } TEST_CASE_FIXTURE(Fixture, "quit_stringifying_table_type_when_length_is_exceeded") { TableTypeVar ttv{}; for (char c : std::string("abcdefghijklmno")) ttv.props[std::string(1, c)] = {typeChecker.numberType}; TypeVar tv{ttv}; ToStringOptions o; o.exhaustive = false; o.maxTableLength = 40; CHECK_EQ(toString(&tv, o), "{ a: number, b: number, c: number, d: number, e: number, ... 10 more ... }"); } TEST_CASE_FIXTURE(Fixture, "stringifying_table_type_is_still_capped_when_exhaustive") { TableTypeVar ttv{}; for (char c : std::string("abcdefg")) ttv.props[std::string(1, c)] = {typeChecker.numberType}; TypeVar tv{ttv}; ToStringOptions o; o.exhaustive = true; o.maxTableLength = 40; CHECK_EQ(toString(&tv, o), "{ a: number, b: number, c: number, d: number, e: number, ... 2 more ... }"); } TEST_CASE_FIXTURE(Fixture, "quit_stringifying_type_when_length_is_exceeded") { CheckResult result = check(R"( function f0() end function f1(f) return f or f0 end function f2(f) return f or f1 end function f3(f) return f or f2 end )"); LUAU_REQUIRE_NO_ERRORS(result); ToStringOptions o; o.exhaustive = false; o.maxTypeLength = 40; CHECK_EQ(toString(requireType("f0"), o), "() -> ()"); CHECK_EQ(toString(requireType("f1"), o), "(() -> ()) -> () -> ()"); CHECK_EQ(toString(requireType("f2"), o), "((() -> ()) -> () -> ()) -> (() -> ()) -> ... *TRUNCATED*"); CHECK_EQ(toString(requireType("f3"), o), "(((() -> ()) -> () -> ()) -> (() -> ()) -> ... *TRUNCATED*"); } TEST_CASE_FIXTURE(Fixture, "stringifying_type_is_still_capped_when_exhaustive") { CheckResult result = check(R"( function f0() end function f1(f) return f or f0 end function f2(f) return f or f1 end function f3(f) return f or f2 end )"); LUAU_REQUIRE_NO_ERRORS(result); ToStringOptions o; o.exhaustive = true; o.maxTypeLength = 40; CHECK_EQ(toString(requireType("f0"), o), "() -> ()"); CHECK_EQ(toString(requireType("f1"), o), "(() -> ()) -> () -> ()"); CHECK_EQ(toString(requireType("f2"), o), "((() -> ()) -> () -> ()) -> (() -> ()) -> ... *TRUNCATED*"); CHECK_EQ(toString(requireType("f3"), o), "(((() -> ()) -> () -> ()) -> (() -> ()) -> ... *TRUNCATED*"); } TEST_CASE_FIXTURE(Fixture, "stringifying_table_type_correctly_use_matching_table_state_braces") { TableTypeVar ttv{TableState::Sealed, TypeLevel{}}; for (char c : std::string("abcdefghij")) ttv.props[std::string(1, c)] = {typeChecker.numberType}; TypeVar tv{ttv}; ToStringOptions o; o.maxTableLength = 40; CHECK_EQ(toString(&tv, o), "{| a: number, b: number, c: number, d: number, e: number, ... 5 more ... |}"); } TEST_CASE_FIXTURE(Fixture, "stringifying_cyclic_union_type_bails_early") { TypeVar tv{UnionTypeVar{{typeChecker.stringType, typeChecker.numberType}}}; UnionTypeVar* utv = getMutable(&tv); utv->options.push_back(&tv); utv->options.push_back(&tv); CHECK_EQ("t1 where t1 = number | string", toString(&tv)); } TEST_CASE_FIXTURE(Fixture, "stringifying_cyclic_intersection_type_bails_early") { TypeVar tv{IntersectionTypeVar{}}; IntersectionTypeVar* itv = getMutable(&tv); itv->parts.push_back(&tv); itv->parts.push_back(&tv); CHECK_EQ("t1 where t1 = t1 & t1", toString(&tv)); } TEST_CASE_FIXTURE(Fixture, "stringifying_array_uses_array_syntax") { TableTypeVar ttv{TableState::Sealed, TypeLevel{}}; ttv.indexer = TableIndexer{typeChecker.numberType, typeChecker.stringType}; CHECK_EQ("{string}", toString(TypeVar{ttv})); ttv.props["A"] = {typeChecker.numberType}; CHECK_EQ("{| [number]: string, A: number |}", toString(TypeVar{ttv})); ttv.props.clear(); ttv.state = TableState::Unsealed; CHECK_EQ("{string}", toString(TypeVar{ttv})); } TEST_CASE_FIXTURE(Fixture, "generic_packs_are_stringified_differently_from_generic_types") { TypePackVar tpv{GenericTypePack{"a"}}; CHECK_EQ(toString(&tpv), "a..."); TypeVar tv{GenericTypeVar{"a"}}; CHECK_EQ(toString(&tv), "a"); } TEST_CASE_FIXTURE(Fixture, "function_type_with_argument_names") { CheckResult result = check("type MyFunc = (a: number, string, c: number) -> string; local a : MyFunc"); LUAU_REQUIRE_NO_ERRORS(result); ToStringOptions opts; opts.functionTypeArguments = true; CHECK_EQ("(a: number, string, c: number) -> string", toString(requireType("a"), opts)); } TEST_CASE_FIXTURE(Fixture, "function_type_with_argument_names_generic") { CheckResult result = check("local function f(n: number, ...: a...): (a...) return ... end"); LUAU_REQUIRE_NO_ERRORS(result); ToStringOptions opts; opts.functionTypeArguments = true; CHECK_EQ("(n: number, a...) -> (a...)", toString(requireType("f"), opts)); } TEST_CASE_FIXTURE(Fixture, "function_type_with_argument_names_and_self") { CheckResult result = check(R"( local tbl = {} tbl.a = 2 function tbl:foo(b: number, c: number) return (self.a :: number) + b + c end type Table = typeof(tbl) type Foo = typeof(tbl.foo) local u: Foo )"); LUAU_REQUIRE_NO_ERRORS(result); ToStringOptions opts; opts.functionTypeArguments = true; // Can't guess the name of 'self' to compare name, but at least there should be no assertion toString(requireType("u"), opts); } TEST_CASE_FIXTURE(Fixture, "generate_friendly_names_for_inferred_generics") { CheckResult result = check(R"( function id(x) return x end function id2(a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11, a12, a13, a14, a15, a16, a17, a18, a19, a20, a21, a22, a23, a24, a25, a26, a27, a28, a29, a30) return a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11, a12, a13, a14, a15, a16, a17, a18, a19, a20, a21, a22, a23, a24, a25, a26, a27, a28, a29, a30 end )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("(a) -> a", toString(requireType("id"))); CHECK_EQ("(a, b, c, d, e, f, g, h, i, j, k, l, " "m, n, o, p, q, r, s, t, u, v, w, x, y, z, a1, b1, c1, d1) -> (a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v, w, " "x, y, z, a1, b1, c1, d1)", toString(requireType("id2"))); } TEST_CASE_FIXTURE(Fixture, "toStringDetailed") { CheckResult result = check(R"( function id3(a, b, c) return a, b, c end )"); LUAU_REQUIRE_NO_ERRORS(result); ToStringOptions opts; TypeId id3Type = requireType("id3"); ToStringResult nameData = toStringDetailed(id3Type, opts); if (FFlag::LuauFixNameMaps) REQUIRE(3 == opts.nameMap.typeVars.size()); else REQUIRE_EQ(3, nameData.DEPRECATED_nameMap.typeVars.size()); REQUIRE_EQ("(a, b, c) -> (a, b, c)", nameData.name); ToStringOptions opts2; // TODO: delete opts2 when clipping FFlag::LuauFixNameMaps if (FFlag::LuauFixNameMaps) opts2.nameMap = std::move(opts.nameMap); else opts2.DEPRECATED_nameMap = std::move(nameData.DEPRECATED_nameMap); const FunctionTypeVar* ftv = get(follow(id3Type)); REQUIRE(ftv != nullptr); auto params = flatten(ftv->argTypes).first; REQUIRE(3 == params.size()); CHECK("a" == toString(params[0], opts2)); CHECK("b" == toString(params[1], opts2)); CHECK("c" == toString(params[2], opts2)); } TEST_CASE_FIXTURE(BuiltinsFixture, "toStringDetailed2") { ScopedFastFlag sff[] = { {"DebugLuauSharedSelf", true}, }; CheckResult result = check(R"( local base = {} function base:one() return 1 end local child = {} setmetatable(child, {__index=base}) function child:two() return 2 end local inst = {} setmetatable(inst, {__index=child}) )"); LUAU_REQUIRE_NO_ERRORS(result); ToStringOptions opts; TypeId tType = requireType("inst"); ToStringResult r = toStringDetailed(tType, opts); CHECK_EQ("{ @metatable { __index: { @metatable {| __index: base |}, child } }, inst }", r.name); if (FFlag::LuauFixNameMaps) CHECK(0 == opts.nameMap.typeVars.size()); else CHECK_EQ(0, r.DEPRECATED_nameMap.typeVars.size()); if (!FFlag::LuauFixNameMaps) opts.DEPRECATED_nameMap = r.DEPRECATED_nameMap; const MetatableTypeVar* tMeta = get(tType); REQUIRE(tMeta); TableTypeVar* tMeta2 = getMutable(tMeta->metatable); REQUIRE(tMeta2); REQUIRE(tMeta2->props.count("__index")); const MetatableTypeVar* tMeta3 = get(tMeta2->props["__index"].type); REQUIRE(tMeta3); TableTypeVar* tMeta4 = getMutable(tMeta3->metatable); REQUIRE(tMeta4); REQUIRE(tMeta4->props.count("__index")); TableTypeVar* tMeta5 = getMutable(tMeta4->props["__index"].type); REQUIRE(tMeta5); REQUIRE(tMeta5->props.count("one") > 0); TableTypeVar* tMeta6 = getMutable(tMeta3->table); REQUIRE(tMeta6); REQUIRE(tMeta6->props.count("two") > 0); ToStringResult oneResult = toStringDetailed(tMeta5->props["one"].type, opts); if (!FFlag::LuauFixNameMaps) opts.DEPRECATED_nameMap = oneResult.DEPRECATED_nameMap; std::string twoResult = toString(tMeta6->props["two"].type, opts); CHECK_EQ("(a) -> number", oneResult.name); CHECK_EQ("(b) -> number", twoResult); } TEST_CASE_FIXTURE(Fixture, "toStringErrorPack") { CheckResult result = check(R"( local function target(callback: nil) return callback(4, "hello") end )"); LUAU_REQUIRE_ERRORS(result); CHECK_EQ("(nil) -> (*error-type*)", toString(requireType("target"))); } TEST_CASE_FIXTURE(Fixture, "toStringGenericPack") { CheckResult result = check(R"( function foo(a, b) return a(b) end )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ(toString(requireType("foo")), "((a) -> (b...), a) -> (b...)"); } TEST_CASE_FIXTURE(Fixture, "toString_the_boundTo_table_type_contained_within_a_TypePack") { TypeVar tv1{TableTypeVar{}}; TableTypeVar* ttv = getMutable(&tv1); ttv->state = TableState::Sealed; ttv->props["hello"] = {typeChecker.numberType}; ttv->props["world"] = {typeChecker.numberType}; TypePackVar tpv1{TypePack{{&tv1}}}; TypeVar tv2{TableTypeVar{}}; TableTypeVar* bttv = getMutable(&tv2); bttv->state = TableState::Free; bttv->props["hello"] = {typeChecker.numberType}; bttv->boundTo = &tv1; TypePackVar tpv2{TypePack{{&tv2}}}; CHECK_EQ("{| hello: number, world: number |}", toString(&tpv1)); CHECK_EQ("{| hello: number, world: number |}", toString(&tpv2)); } TEST_CASE_FIXTURE(Fixture, "no_parentheses_around_return_type_if_pack_has_an_empty_head_link") { TypeArena arena; TypePackId realTail = arena.addTypePack({singletonTypes->stringType}); TypePackId emptyTail = arena.addTypePack({}, realTail); TypePackId argList = arena.addTypePack({singletonTypes->stringType}); TypeId functionType = arena.addType(FunctionTypeVar{argList, emptyTail}); if (FFlag::LuauFunctionReturnStringificationFixup) CHECK("(string) -> string" == toString(functionType)); else CHECK("(string) -> (string)" == toString(functionType)); } TEST_CASE_FIXTURE(Fixture, "no_parentheses_around_cyclic_function_type_in_union") { CheckResult result = check(R"( type F = ((() -> number)?) -> F? local function f(p) return f end local g: F = f )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("t1 where t1 = ((() -> number)?) -> t1?", toString(requireType("g"))); } TEST_CASE_FIXTURE(Fixture, "no_parentheses_around_cyclic_function_type_in_intersection") { CheckResult result = check(R"( function f() return f end local a: ((number) -> ()) & typeof(f) )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK_EQ("((number) -> ()) & t1 where t1 = () -> t1", toString(requireType("a"))); } TEST_CASE_FIXTURE(Fixture, "self_recursive_instantiated_param") { TypeVar tableTy{TableTypeVar{}}; TableTypeVar* ttv = getMutable(&tableTy); ttv->name = "Table"; ttv->instantiatedTypeParams.push_back(&tableTy); CHECK_EQ(toString(tableTy), "Table"); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_id") { CheckResult result = check(R"( local function id(x) return x end )"); TypeId ty = requireType("id"); const FunctionTypeVar* ftv = get(follow(ty)); CHECK_EQ("id(x: a): a", toStringNamedFunction("id", *ftv)); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_map") { CheckResult result = check(R"( local function map(arr, fn) local t = {} for i = 0, #arr do t[i] = fn(arr[i]) end return t end )"); TypeId ty = requireType("map"); const FunctionTypeVar* ftv = get(follow(ty)); CHECK_EQ("map(arr: {a}, fn: (a) -> b): {b}", toStringNamedFunction("map", *ftv)); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_generic_pack") { CheckResult result = check(R"( local function f(a: number, b: string) end local function test(...: T...): U... f(...) return 1, 2, 3 end )"); TypeId ty = requireType("test"); const FunctionTypeVar* ftv = get(follow(ty)); CHECK_EQ("test(...: T...): U...", toStringNamedFunction("test", *ftv)); } TEST_CASE("toStringNamedFunction_unit_f") { TypePackVar empty{TypePack{}}; FunctionTypeVar ftv{&empty, &empty, {}, false}; CHECK_EQ("f(): ()", toStringNamedFunction("f", ftv)); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_variadics") { CheckResult result = check(R"( local function f(x: a, ...): (a, a, b...) return x, x, ... end )"); TypeId ty = requireType("f"); auto ftv = get(follow(ty)); CHECK_EQ("f(x: a, ...: any): (a, a, b...)", toStringNamedFunction("f", *ftv)); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_variadics2") { CheckResult result = check(R"( local function f(): ...number return 1, 2, 3 end )"); TypeId ty = requireType("f"); auto ftv = get(follow(ty)); CHECK_EQ("f(): ...number", toStringNamedFunction("f", *ftv)); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_variadics3") { CheckResult result = check(R"( local function f(): (string, ...number) return 'a', 1, 2, 3 end )"); TypeId ty = requireType("f"); auto ftv = get(follow(ty)); CHECK_EQ("f(): (string, ...number)", toStringNamedFunction("f", *ftv)); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_type_annotation_has_partial_argnames") { CheckResult result = check(R"( local f: (number, y: number) -> number )"); TypeId ty = requireType("f"); auto ftv = get(follow(ty)); CHECK_EQ("f(_: number, y: number): number", toStringNamedFunction("f", *ftv)); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_hide_type_params") { CheckResult result = check(R"( local function f(x: T, g: (T) -> U)): () end )"); TypeId ty = requireType("f"); auto ftv = get(follow(ty)); ToStringOptions opts; opts.hideNamedFunctionTypeParameters = true; CHECK_EQ("f(x: T, g: (T) -> U): ()", toStringNamedFunction("f", *ftv, opts)); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_overrides_param_names") { CheckResult result = check(R"( local function test(a, b : string, ... : number) return a end )"); TypeId ty = requireType("test"); const FunctionTypeVar* ftv = get(follow(ty)); ToStringOptions opts; opts.namedFunctionOverrideArgNames = {"first", "second", "third"}; CHECK_EQ("test(first: a, second: string, ...: number): a", toStringNamedFunction("test", *ftv, opts)); } TEST_CASE_FIXTURE(Fixture, "pick_distinct_names_for_mixed_explicit_and_implicit_generics") { CheckResult result = check(R"( function foo(x: a, y) end )"); CHECK("(a, b) -> ()" == toString(requireType("foo"))); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_include_self_param") { ScopedFastFlag sff[]{ {"DebugLuauSharedSelf", true}, }; CheckResult result = check(R"( local foo = {} function foo:method(arg: string): () end )"); TypeId parentTy = requireType("foo"); auto ttv = get(follow(parentTy)); auto ftv = get(ttv->props.at("method").type); CHECK_EQ("foo:method(self: a, arg: string): ()", toStringNamedFunction("foo:method", *ftv)); } TEST_CASE_FIXTURE(Fixture, "toStringNamedFunction_hide_self_param") { ScopedFastFlag sff[]{ {"DebugLuauSharedSelf", true}, }; CheckResult result = check(R"( local foo = {} function foo:method(arg: string): () end )"); TypeId parentTy = requireType("foo"); auto ttv = get(follow(parentTy)); auto ftv = get(ttv->props.at("method").type); ToStringOptions opts; opts.hideFunctionSelfArgument = true; CHECK_EQ("foo:method(arg: string): ()", toStringNamedFunction("foo:method", *ftv, opts)); } TEST_CASE_FIXTURE(Fixture, "tostring_unsee_ttv_if_array") { ScopedFastFlag sff("LuauUnseeArrayTtv", true); CheckResult result = check(R"( local x: {string} -- This code is constructed very specifically to use the same (by pointer -- identity) type in the function twice. local y: (typeof(x), typeof(x)) -> () )"); LUAU_REQUIRE_NO_ERRORS(result); CHECK(toString(requireType("y")) == "({string}, {string}) -> ()"); } TEST_SUITE_END();