// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details #include "Luau/Autocomplete.h" #include "Luau/BuiltinDefinitions.h" #include "Luau/TypeInfer.h" #include "Luau/Type.h" #include "Luau/VisitType.h" #include "Luau/StringUtils.h" #include "Fixture.h" #include "ScopedFlags.h" #include "doctest.h" #include LUAU_FASTFLAG(LuauTraceTypesInNonstrictMode2) LUAU_FASTFLAG(LuauSetMetatableDoesNotTimeTravel) LUAU_FASTINT(LuauTypeInferRecursionLimit) using namespace Luau; static std::optional nullCallback(std::string tag, std::optional ptr, std::optional contents) { return std::nullopt; } template struct ACFixtureImpl : BaseType { ACFixtureImpl() : BaseType(true) { } AutocompleteResult autocomplete(unsigned row, unsigned column) { FrontendOptions opts; opts.forAutocomplete = true; opts.retainFullTypeGraphs = true; this->frontend.check("MainModule", opts); return Luau::autocomplete(this->frontend, "MainModule", Position{row, column}, nullCallback); } AutocompleteResult autocomplete(char marker, StringCompletionCallback callback = nullCallback) { FrontendOptions opts; opts.forAutocomplete = true; opts.retainFullTypeGraphs = true; this->frontend.check("MainModule", opts); return Luau::autocomplete(this->frontend, "MainModule", getPosition(marker), callback); } AutocompleteResult autocomplete(const ModuleName& name, Position pos, StringCompletionCallback callback = nullCallback) { FrontendOptions opts; opts.forAutocomplete = true; opts.retainFullTypeGraphs = true; this->frontend.check(name, opts); return Luau::autocomplete(this->frontend, name, pos, callback); } CheckResult check(const std::string& source) { markerPosition.clear(); std::string filteredSource; filteredSource.reserve(source.size()); Position curPos(0, 0); char prevChar{}; for (char c : source) { if (prevChar == '@') { LUAU_ASSERT("Illegal marker character" && ((c >= '0' && c <= '9') || (c >= 'A' && c <= 'Z'))); LUAU_ASSERT("Duplicate marker found" && markerPosition.count(c) == 0); markerPosition.insert(std::pair{c, curPos}); } else if (c == '@') { // skip the '@' character } else { filteredSource.push_back(c); if (c == '\n') { curPos.line++; curPos.column = 0; } else { curPos.column++; } } prevChar = c; } LUAU_ASSERT("Digit expected after @ symbol" && prevChar != '@'); return BaseType::check(filteredSource); } LoadDefinitionFileResult loadDefinition(const std::string& source) { GlobalTypes& globals = this->frontend.globalsForAutocomplete; unfreeze(globals.globalTypes); LoadDefinitionFileResult result = this->frontend.loadDefinitionFile( globals, globals.globalScope, source, "@test", /* captureComments */ false, /* typeCheckForAutocomplete */ true ); freeze(globals.globalTypes); if (FFlag::LuauSolverV2) { GlobalTypes& globals = this->frontend.globals; unfreeze(globals.globalTypes); LoadDefinitionFileResult result = this->frontend.loadDefinitionFile( globals, globals.globalScope, source, "@test", /* captureComments */ false, /* typeCheckForAutocomplete */ true ); freeze(globals.globalTypes); } REQUIRE_MESSAGE(result.success, "loadDefinition: unable to load definition file"); return result; } const Position& getPosition(char marker) const { auto i = markerPosition.find(marker); LUAU_ASSERT(i != markerPosition.end()); return i->second; } // Maps a marker character (0-9 inclusive) to a position in the source code. std::map markerPosition; }; struct ACFixture : ACFixtureImpl { ACFixture() : ACFixtureImpl() { addGlobalBinding(frontend.globals, "table", Binding{builtinTypes->anyType}); addGlobalBinding(frontend.globals, "math", Binding{builtinTypes->anyType}); addGlobalBinding(frontend.globalsForAutocomplete, "table", Binding{builtinTypes->anyType}); addGlobalBinding(frontend.globalsForAutocomplete, "math", Binding{builtinTypes->anyType}); } }; struct ACBuiltinsFixture : ACFixtureImpl { }; TEST_SUITE_BEGIN("AutocompleteTest"); TEST_CASE_FIXTURE(ACFixture, "empty_program") { check(" @1"); auto ac = autocomplete('1'); CHECK(!ac.entryMap.empty()); CHECK(ac.entryMap.count("table")); CHECK(ac.entryMap.count("math")); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "local_initializer") { check("local a = @1"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("table")); CHECK(ac.entryMap.count("math")); CHECK_EQ(ac.context, AutocompleteContext::Expression); } TEST_CASE_FIXTURE(ACFixture, "leave_numbers_alone") { check("local a = 3.@11"); auto ac = autocomplete('1'); CHECK(ac.entryMap.empty()); CHECK_EQ(ac.context, AutocompleteContext::Unknown); } TEST_CASE_FIXTURE(ACFixture, "user_defined_globals") { check("local myLocal = 4; @1"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("myLocal")); CHECK(ac.entryMap.count("table")); CHECK(ac.entryMap.count("math")); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "dont_suggest_local_before_its_definition") { check(R"( local myLocal = 4 function abc() @1 local myInnerLocal = 1 @2 end @3 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("myLocal")); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "myInnerLocal"); ac = autocomplete('2'); CHECK(ac.entryMap.count("myLocal")); CHECK(ac.entryMap.count("myInnerLocal")); ac = autocomplete('3'); CHECK(ac.entryMap.count("myLocal")); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "myInnerLocal"); } TEST_CASE_FIXTURE(ACFixture, "recursive_function") { check(R"( function foo() @1 end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("foo")); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "nested_recursive_function") { check(R"( local function outer() local function inner() @1 end end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("inner")); CHECK(ac.entryMap.count("outer")); } TEST_CASE_FIXTURE(ACFixture, "user_defined_local_functions_in_own_definition") { check(R"( local function abc() @1 end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("abc")); CHECK(ac.entryMap.count("table")); CHECK(ac.entryMap.count("math")); check(R"( local abc = function() @1 end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("abc")); // FIXME: This is actually incorrect! CHECK(ac.entryMap.count("table")); CHECK(ac.entryMap.count("math")); } TEST_CASE_FIXTURE(ACFixture, "global_functions_are_not_scoped_lexically") { check(R"( if true then function abc() end end @1 )"); auto ac = autocomplete('1'); CHECK(!ac.entryMap.empty()); CHECK(ac.entryMap.count("abc")); CHECK(ac.entryMap.count("table")); CHECK(ac.entryMap.count("math")); } TEST_CASE_FIXTURE(ACFixture, "local_functions_fall_out_of_scope") { check(R"( if true then local function abc() end end @1 )"); auto ac = autocomplete('1'); CHECK_NE(0, ac.entryMap.size()); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "abc"); } TEST_CASE_FIXTURE(ACFixture, "function_parameters") { check(R"( function abc(test) @1 end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("test")); } TEST_CASE_FIXTURE(ACBuiltinsFixture, "get_member_completions") { check(R"( local a = table.@1 )"); auto ac = autocomplete('1'); CHECK_EQ(17, ac.entryMap.size()); CHECK(ac.entryMap.count("find")); CHECK(ac.entryMap.count("pack")); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "math"); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "nested_member_completions") { check(R"( local tbl = { abc = { def = 1234, egh = false } } tbl.abc. @1 )"); auto ac = autocomplete('1'); CHECK_EQ(2, ac.entryMap.size()); CHECK(ac.entryMap.count("def")); CHECK(ac.entryMap.count("egh")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "unsealed_table") { check(R"( local tbl = {} tbl.prop = 5 tbl.@1 )"); auto ac = autocomplete('1'); CHECK_EQ(1, ac.entryMap.size()); CHECK(ac.entryMap.count("prop")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "unsealed_table_2") { check(R"( local tbl = {} local inner = { prop = 5 } tbl.inner = inner tbl.inner. @1 )"); auto ac = autocomplete('1'); CHECK_EQ(1, ac.entryMap.size()); CHECK(ac.entryMap.count("prop")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "cyclic_table") { check(R"( local abc = {} local def = { abc = abc } abc.def = def abc.def. @1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("abc")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "table_union") { check(R"( type t1 = { a1 : string, b2 : number } type t2 = { b2 : string, c3 : string } function func(abc : t1 | t2) abc. @1 end )"); auto ac = autocomplete('1'); CHECK_EQ(1, ac.entryMap.size()); CHECK(ac.entryMap.count("b2")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "table_intersection") { check(R"( type t1 = { a1 : string, b2 : number } type t2 = { b2 : number, c3 : string } function func(abc : t1 & t2) abc. @1 end )"); auto ac = autocomplete('1'); CHECK_EQ(3, ac.entryMap.size()); CHECK(ac.entryMap.count("a1")); CHECK(ac.entryMap.count("b2")); CHECK(ac.entryMap.count("c3")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACBuiltinsFixture, "get_string_completions") { check(R"( local a = ("foo"):@1 )"); auto ac = autocomplete('1'); CHECK_EQ(17, ac.entryMap.size()); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "get_suggestions_for_new_statement") { check("@1"); auto ac = autocomplete('1'); CHECK_NE(0, ac.entryMap.size()); CHECK(ac.entryMap.count("table")); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "get_suggestions_for_the_very_start_of_the_script") { check(R"(@1 function aaa() end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("table")); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "method_call_inside_function_body") { check(R"( local game = { GetService=function(s) return 'hello' end } function a() game: @1 end )"); auto ac = autocomplete('1'); CHECK_NE(0, ac.entryMap.size()); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "math"); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACBuiltinsFixture, "method_call_inside_if_conditional") { check(R"( if table: @1 )"); auto ac = autocomplete('1'); CHECK_NE(0, ac.entryMap.size()); CHECK(ac.entryMap.count("concat")); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "math"); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "statement_between_two_statements") { check(R"( function getmyscripts() end g@1 getmyscripts() )"); auto ac = autocomplete('1'); CHECK_NE(0, ac.entryMap.size()); CHECK(ac.entryMap.count("getmyscripts")); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "bias_toward_inner_scope") { check(R"( local A = {one=1} function B() local A = {two=2} A @1 end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("A")); CHECK_EQ(ac.context, AutocompleteContext::Statement); TypeId t = follow(*ac.entryMap["A"].type); const TableType* tt = get(t); REQUIRE(tt); CHECK(tt->props.count("two")); } TEST_CASE_FIXTURE(ACFixture, "recommend_statement_starting_keywords") { check("@1"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("local")); CHECK_EQ(ac.context, AutocompleteContext::Statement); check("local i = @1"); auto ac2 = autocomplete('1'); CHECK(!ac2.entryMap.count("local")); CHECK_EQ(ac2.context, AutocompleteContext::Expression); } TEST_CASE_FIXTURE(ACFixture, "do_not_overwrite_context_sensitive_kws") { check(R"( local function continue() end @1 )"); auto ac = autocomplete('1'); AutocompleteEntry entry = ac.entryMap["continue"]; CHECK(entry.kind == AutocompleteEntryKind::Binding); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "dont_offer_any_suggestions_from_within_a_comment") { check(R"( --!strict local foo = {} function foo:bar() end --[[ foo:@1 ]] )"); auto ac = autocomplete('1'); CHECK_EQ(0, ac.entryMap.size()); CHECK_EQ(ac.context, AutocompleteContext::Unknown); } TEST_CASE_FIXTURE(ACFixture, "dont_offer_any_suggestions_from_the_end_of_a_comment") { check(R"( --!strict@1 )"); auto ac = autocomplete('1'); CHECK_EQ(0, ac.entryMap.size()); CHECK_EQ(ac.context, AutocompleteContext::Unknown); } TEST_CASE_FIXTURE(ACFixture, "dont_offer_any_suggestions_from_within_a_broken_comment") { check(R"( --[[ @1 )"); auto ac = autocomplete('1'); CHECK_EQ(0, ac.entryMap.size()); CHECK_EQ(ac.context, AutocompleteContext::Unknown); } TEST_CASE_FIXTURE(ACFixture, "dont_offer_any_suggestions_from_within_a_broken_comment_at_the_very_end_of_the_file") { check("--[[@1"); auto ac = autocomplete('1'); CHECK_EQ(0, ac.entryMap.size()); CHECK_EQ(ac.context, AutocompleteContext::Unknown); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_for_middle_keywords") { check(R"( for x @1= )"); auto ac1 = autocomplete('1'); CHECK_EQ(ac1.entryMap.count("do"), 0); CHECK_EQ(ac1.entryMap.count("end"), 0); CHECK_EQ(ac1.context, AutocompleteContext::Unknown); check(R"( for x =@1 1 )"); auto ac2 = autocomplete('1'); CHECK_EQ(ac2.entryMap.count("do"), 0); CHECK_EQ(ac2.entryMap.count("end"), 0); CHECK_EQ(ac2.context, AutocompleteContext::Unknown); check(R"( for x = 1,@1 2 )"); auto ac3 = autocomplete('1'); CHECK_EQ(1, ac3.entryMap.size()); CHECK_EQ(ac3.entryMap.count("do"), 1); CHECK_EQ(ac3.context, AutocompleteContext::Keyword); check(R"( for x = 1, @12, )"); auto ac4 = autocomplete('1'); CHECK_EQ(ac4.entryMap.count("do"), 0); CHECK_EQ(ac4.entryMap.count("end"), 0); CHECK_EQ(ac4.context, AutocompleteContext::Expression); check(R"( for x = 1, 2, @15 )"); auto ac5 = autocomplete('1'); CHECK_EQ(ac5.entryMap.count("math"), 1); CHECK_EQ(ac5.entryMap.count("do"), 0); CHECK_EQ(ac5.entryMap.count("end"), 0); CHECK_EQ(ac5.context, AutocompleteContext::Expression); check(R"( for x = 1, 2, 5 f@1 )"); auto ac6 = autocomplete('1'); CHECK_EQ(ac6.entryMap.size(), 1); CHECK_EQ(ac6.entryMap.count("do"), 1); CHECK_EQ(ac6.context, AutocompleteContext::Keyword); check(R"( for x = 1, 2, 5 do @1 )"); auto ac7 = autocomplete('1'); CHECK_EQ(ac7.entryMap.count("end"), 1); CHECK_EQ(ac7.context, AutocompleteContext::Statement); check(R"(local Foo = 1 for x = @11, @22, @35 )"); for (int i = 0; i < 3; ++i) { auto ac8 = autocomplete('1' + i); CHECK_EQ(ac8.entryMap.count("Foo"), 1); CHECK_EQ(ac8.entryMap.count("do"), 0); } check(R"(local Foo = 1 for x = @11, @22 )"); for (int i = 0; i < 2; ++i) { auto ac9 = autocomplete('1' + i); CHECK_EQ(ac9.entryMap.count("Foo"), 1); CHECK_EQ(ac9.entryMap.count("do"), 0); } } TEST_CASE_FIXTURE(ACFixture, "autocomplete_for_in_middle_keywords") { check(R"( for @1 )"); auto ac1 = autocomplete('1'); CHECK_EQ(0, ac1.entryMap.size()); CHECK_EQ(ac1.context, AutocompleteContext::Unknown); check(R"( for x@1 @2 )"); auto ac2 = autocomplete('1'); CHECK_EQ(0, ac2.entryMap.size()); CHECK_EQ(ac2.context, AutocompleteContext::Unknown); auto ac2a = autocomplete('2'); CHECK_EQ(1, ac2a.entryMap.size()); CHECK_EQ(1, ac2a.entryMap.count("in")); CHECK_EQ(ac2a.context, AutocompleteContext::Keyword); check(R"( for x in y@1 )"); auto ac3 = autocomplete('1'); CHECK_EQ(ac3.entryMap.count("table"), 1); CHECK_EQ(ac3.entryMap.count("do"), 0); CHECK_EQ(ac3.context, AutocompleteContext::Expression); check(R"( for x in y @1 )"); auto ac4 = autocomplete('1'); CHECK_EQ(ac4.entryMap.size(), 1); CHECK_EQ(ac4.entryMap.count("do"), 1); CHECK_EQ(ac4.context, AutocompleteContext::Keyword); check(R"( for x in f f@1 )"); auto ac5 = autocomplete('1'); CHECK_EQ(ac5.entryMap.size(), 1); CHECK_EQ(ac5.entryMap.count("do"), 1); CHECK_EQ(ac5.context, AutocompleteContext::Keyword); check(R"( for x in y do @1 )"); auto ac6 = autocomplete('1'); CHECK_EQ(ac6.entryMap.count("in"), 0); CHECK_EQ(ac6.entryMap.count("table"), 1); CHECK_EQ(ac6.entryMap.count("end"), 1); CHECK_EQ(ac6.entryMap.count("function"), 1); CHECK_EQ(ac6.context, AutocompleteContext::Statement); check(R"( for x in y do e@1 )"); auto ac7 = autocomplete('1'); CHECK_EQ(ac7.entryMap.count("in"), 0); CHECK_EQ(ac7.entryMap.count("table"), 1); CHECK_EQ(ac7.entryMap.count("end"), 1); CHECK_EQ(ac7.entryMap.count("function"), 1); CHECK_EQ(ac7.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_while_middle_keywords") { check(R"( while@1 )"); auto ac1 = autocomplete('1'); CHECK_EQ(ac1.entryMap.count("do"), 0); CHECK_EQ(ac1.entryMap.count("end"), 0); CHECK_EQ(ac1.context, AutocompleteContext::Expression); check(R"( while true @1 )"); auto ac2 = autocomplete('1'); CHECK_EQ(3, ac2.entryMap.size()); CHECK_EQ(ac2.entryMap.count("do"), 1); CHECK_EQ(ac2.entryMap.count("and"), 1); CHECK_EQ(ac2.entryMap.count("or"), 1); CHECK_EQ(ac2.context, AutocompleteContext::Keyword); check(R"( while true do @1 )"); auto ac3 = autocomplete('1'); CHECK_EQ(ac3.entryMap.count("end"), 1); CHECK_EQ(ac3.context, AutocompleteContext::Statement); check(R"( while true d@1 )"); auto ac4 = autocomplete('1'); CHECK_EQ(3, ac4.entryMap.size()); CHECK_EQ(ac4.entryMap.count("do"), 1); CHECK_EQ(ac4.entryMap.count("and"), 1); CHECK_EQ(ac4.entryMap.count("or"), 1); CHECK_EQ(ac4.context, AutocompleteContext::Keyword); check(R"( while t@1 )"); auto ac5 = autocomplete('1'); CHECK_EQ(ac5.entryMap.count("do"), 0); CHECK_EQ(ac5.entryMap.count("true"), 1); CHECK_EQ(ac5.entryMap.count("false"), 1); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_if_middle_keywords") { check(R"( if @1 )"); auto ac1 = autocomplete('1'); CHECK_EQ(ac1.entryMap.count("then"), 0); CHECK_EQ( ac1.entryMap.count("function"), 1 ); // FIXME: This is kind of dumb. It is technically syntactically valid but you can never do anything interesting with this. CHECK_EQ(ac1.entryMap.count("table"), 1); CHECK_EQ(ac1.entryMap.count("else"), 0); CHECK_EQ(ac1.entryMap.count("elseif"), 0); CHECK_EQ(ac1.entryMap.count("end"), 0); CHECK_EQ(ac1.context, AutocompleteContext::Expression); check(R"( if x @1 )"); auto ac2 = autocomplete('1'); CHECK_EQ(ac2.entryMap.count("then"), 1); CHECK_EQ(ac2.entryMap.count("function"), 0); CHECK_EQ(ac2.entryMap.count("else"), 0); CHECK_EQ(ac2.entryMap.count("elseif"), 0); CHECK_EQ(ac2.entryMap.count("end"), 0); CHECK_EQ(ac2.context, AutocompleteContext::Keyword); check(R"( if x t@1 )"); auto ac3 = autocomplete('1'); CHECK_EQ(3, ac3.entryMap.size()); CHECK_EQ(ac3.entryMap.count("then"), 1); CHECK_EQ(ac3.entryMap.count("and"), 1); CHECK_EQ(ac3.entryMap.count("or"), 1); CHECK_EQ(ac3.context, AutocompleteContext::Keyword); check(R"( if x then @1 end )"); auto ac4 = autocomplete('1'); CHECK_EQ(ac4.entryMap.count("then"), 0); CHECK_EQ(ac4.entryMap.count("else"), 1); CHECK_EQ(ac4.entryMap.count("function"), 1); CHECK_EQ(ac4.entryMap.count("elseif"), 1); CHECK_EQ(ac4.entryMap.count("end"), 0); CHECK_EQ(ac4.context, AutocompleteContext::Statement); check(R"( if x then t@1 end )"); auto ac4a = autocomplete('1'); CHECK_EQ(ac4a.entryMap.count("then"), 0); CHECK_EQ(ac4a.entryMap.count("table"), 1); CHECK_EQ(ac4a.entryMap.count("else"), 1); CHECK_EQ(ac4a.entryMap.count("elseif"), 1); CHECK_EQ(ac4a.context, AutocompleteContext::Statement); check(R"( if x then @1 elseif x then end )"); auto ac5 = autocomplete('1'); CHECK_EQ(ac5.entryMap.count("then"), 0); CHECK_EQ(ac5.entryMap.count("function"), 1); CHECK_EQ(ac5.entryMap.count("else"), 0); CHECK_EQ(ac5.entryMap.count("elseif"), 0); CHECK_EQ(ac5.entryMap.count("end"), 0); CHECK_EQ(ac5.context, AutocompleteContext::Statement); check(R"( if t@1 )"); auto ac6 = autocomplete('1'); CHECK_EQ(ac6.entryMap.count("true"), 1); CHECK_EQ(ac6.entryMap.count("false"), 1); CHECK_EQ(ac6.entryMap.count("then"), 0); CHECK_EQ(ac6.entryMap.count("function"), 1); CHECK_EQ(ac6.entryMap.count("else"), 0); CHECK_EQ(ac6.entryMap.count("elseif"), 0); CHECK_EQ(ac6.entryMap.count("end"), 0); CHECK_EQ(ac6.context, AutocompleteContext::Expression); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_until_in_repeat") { check(R"( repeat @1 )"); auto ac = autocomplete('1'); CHECK_EQ(ac.entryMap.count("table"), 1); CHECK_EQ(ac.entryMap.count("until"), 1); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_until_expression") { check(R"( repeat until @1 )"); auto ac = autocomplete('1'); CHECK_EQ(ac.entryMap.count("table"), 1); CHECK_EQ(ac.context, AutocompleteContext::Expression); } TEST_CASE_FIXTURE(ACFixture, "local_names") { check(R"( local ab@1 )"); auto ac1 = autocomplete('1'); CHECK_EQ(ac1.entryMap.size(), 1); CHECK_EQ(ac1.entryMap.count("function"), 1); CHECK_EQ(ac1.context, AutocompleteContext::Unknown); check(R"( local ab, cd@1 )"); auto ac2 = autocomplete('1'); CHECK(ac2.entryMap.empty()); CHECK_EQ(ac2.context, AutocompleteContext::Unknown); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_end_with_fn_exprs") { check(R"( local function f() @1 )"); auto ac = autocomplete('1'); CHECK_EQ(ac.entryMap.count("end"), 1); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_end_with_lambda") { check(R"( local a = function() local bar = foo en@1 )"); auto ac = autocomplete('1'); CHECK_EQ(ac.entryMap.count("end"), 1); CHECK_EQ(ac.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_end_of_do_block") { check("do @1"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("end")); check(R"( function f() do @1 end @2 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("end")); ac = autocomplete('2'); CHECK(ac.entryMap.count("end")); } TEST_CASE_FIXTURE(ACFixture, "stop_at_first_stat_when_recommending_keywords") { check(R"( repeat for x @1 )"); auto ac1 = autocomplete('1'); CHECK_EQ(ac1.entryMap.count("in"), 1); CHECK_EQ(ac1.entryMap.count("until"), 0); CHECK_EQ(ac1.context, AutocompleteContext::Keyword); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_repeat_middle_keyword") { check(R"( repeat @1 )"); auto ac1 = autocomplete('1'); CHECK_EQ(ac1.entryMap.count("do"), 1); CHECK_EQ(ac1.entryMap.count("function"), 1); CHECK_EQ(ac1.entryMap.count("until"), 1); check(R"( repeat f f@1 )"); auto ac2 = autocomplete('1'); CHECK_EQ(ac2.entryMap.count("function"), 1); CHECK_EQ(ac2.entryMap.count("until"), 1); check(R"( repeat u@1 until )"); auto ac3 = autocomplete('1'); CHECK_EQ(ac3.entryMap.count("until"), 0); } TEST_CASE_FIXTURE(ACFixture, "local_function") { check(R"( local f@1 )"); auto ac1 = autocomplete('1'); CHECK_EQ(ac1.entryMap.size(), 1); CHECK_EQ(ac1.entryMap.count("function"), 1); check(R"( local f@1, cd )"); auto ac2 = autocomplete('1'); CHECK(ac2.entryMap.empty()); } TEST_CASE_FIXTURE(ACFixture, "local_function") { check(R"( local function @1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.empty()); check(R"( local function @1s@2 )"); ac = autocomplete('1'); CHECK(ac.entryMap.empty()); ac = autocomplete('2'); CHECK(ac.entryMap.empty()); check(R"( local function @1()@2 )"); ac = autocomplete('1'); CHECK(ac.entryMap.empty()); ac = autocomplete('2'); CHECK(ac.entryMap.count("end")); check(R"( local function something@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.empty()); check(R"( local tbl = {} function tbl.something@1() end )"); ac = autocomplete('1'); CHECK(ac.entryMap.empty()); } TEST_CASE_FIXTURE(ACFixture, "local_function_params") { check(R"( local function @1a@2bc(@3d@4ef)@5 @6 )"); CHECK(autocomplete('1').entryMap.empty()); CHECK(autocomplete('2').entryMap.empty()); CHECK(autocomplete('3').entryMap.empty()); CHECK(autocomplete('4').entryMap.empty()); CHECK(!autocomplete('5').entryMap.empty()); CHECK(!autocomplete('6').entryMap.empty()); check(R"( local function abc(def) @1 end )"); for (unsigned int i = 23; i < 31; ++i) { CHECK(autocomplete(1, i).entryMap.empty()); } CHECK(!autocomplete(1, 32).entryMap.empty()); auto ac2 = autocomplete('1'); CHECK_EQ(ac2.entryMap.count("abc"), 1); CHECK_EQ(ac2.entryMap.count("def"), 1); CHECK_EQ(ac2.context, AutocompleteContext::Statement); check(R"( local function abc(def, ghi@1) end )"); auto ac3 = autocomplete('1'); CHECK(ac3.entryMap.empty()); CHECK_EQ(ac3.context, AutocompleteContext::Unknown); } TEST_CASE_FIXTURE(ACFixture, "global_function_params") { check(R"( function abc(def) )"); for (unsigned int i = 17; i < 25; ++i) { CHECK(autocomplete(1, i).entryMap.empty()); } CHECK(!autocomplete(1, 26).entryMap.empty()); check(R"( function abc(def) end )"); for (unsigned int i = 17; i < 25; ++i) { CHECK(autocomplete(1, i).entryMap.empty()); } CHECK(!autocomplete(1, 26).entryMap.empty()); check(R"( function abc(def) @1 end )"); auto ac2 = autocomplete('1'); CHECK_EQ(ac2.entryMap.count("abc"), 1); CHECK_EQ(ac2.entryMap.count("def"), 1); CHECK_EQ(ac2.context, AutocompleteContext::Statement); check(R"( function abc(def, ghi@1) end )"); auto ac3 = autocomplete('1'); CHECK(ac3.entryMap.empty()); CHECK_EQ(ac3.context, AutocompleteContext::Unknown); } TEST_CASE_FIXTURE(ACFixture, "arguments_to_global_lambda") { check(R"( abc = function(def, ghi@1) end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.empty()); } TEST_CASE_FIXTURE(ACFixture, "function_expr_params") { check(R"( abc = function(def) @1 )"); for (unsigned int i = 20; i < 27; ++i) { CHECK(autocomplete(1, i).entryMap.empty()); } CHECK(!autocomplete('1').entryMap.empty()); check(R"( abc = function(def) @1 end )"); for (unsigned int i = 20; i < 27; ++i) { CHECK(autocomplete(1, i).entryMap.empty()); } CHECK(!autocomplete('1').entryMap.empty()); check(R"( abc = function(def) @1 end )"); auto ac2 = autocomplete('1'); CHECK_EQ(ac2.entryMap.count("def"), 1); CHECK_EQ(ac2.context, AutocompleteContext::Statement); } TEST_CASE_FIXTURE(ACFixture, "local_initializer") { check(R"( local a = t@1 )"); auto ac = autocomplete('1'); CHECK_EQ(ac.entryMap.count("table"), 1); CHECK_EQ(ac.entryMap.count("true"), 1); } TEST_CASE_FIXTURE(ACFixture, "local_initializer_2") { check(R"( local a=@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("table")); } TEST_CASE_FIXTURE(ACFixture, "get_member_completions") { check(R"( local a = 12.@13 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.empty()); } TEST_CASE_FIXTURE(ACFixture, "sometimes_the_metatable_is_an_error") { check(R"( local T = {} T.__index = T function T.new() return setmetatable({x=6}, X) -- oops! end local t = T.new() t. @1 )"); autocomplete('1'); // Don't crash! } TEST_CASE_FIXTURE(ACFixture, "local_types_builtin") { check(R"( local a: n@1 local b: string = "don't trip" )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("nil")); CHECK(ac.entryMap.count("number")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "private_types") { check(R"( do type num = number local a: n@1u local b: nu@2m end local a: nu@3 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("num")); CHECK(ac.entryMap.count("number")); ac = autocomplete('2'); CHECK(ac.entryMap.count("num")); CHECK(ac.entryMap.count("number")); ac = autocomplete('3'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "num"); CHECK(ac.entryMap.count("number")); } TEST_CASE_FIXTURE(ACFixture, "type_scoping_easy") { check(R"( type Table = { a: number, b: number } do type Table = { x: string, y: string } local a: T@1 end )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("Table")); REQUIRE(ac.entryMap["Table"].type); const TableType* tv = get(follow(*ac.entryMap["Table"].type)); REQUIRE(tv); CHECK(tv->props.count("x")); } TEST_CASE_FIXTURE(ACFixture, "modules_with_types") { fileResolver.source["Module/A"] = R"( export type A = { x: number, y: number } export type B = { z: number, w: number } return {} )"; LUAU_REQUIRE_NO_ERRORS(frontend.check("Module/A")); fileResolver.source["Module/B"] = R"( local aaa = require(script.Parent.A) local a: aa )"; frontend.check("Module/B"); auto ac = autocomplete("Module/B", Position{2, 11}); CHECK(ac.entryMap.count("aaa")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "module_type_members") { fileResolver.source["Module/A"] = R"( export type A = { x: number, y: number } export type B = { z: number, w: number } return {} )"; LUAU_REQUIRE_NO_ERRORS(frontend.check("Module/A")); fileResolver.source["Module/B"] = R"( local aaa = require(script.Parent.A) local a: aaa. )"; frontend.check("Module/B"); auto ac = autocomplete("Module/B", Position{2, 13}); CHECK_EQ(2, ac.entryMap.size()); CHECK(ac.entryMap.count("A")); CHECK(ac.entryMap.count("B")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "argument_types") { check(R"( local function f(a: n@1 local b: string = "don't trip" )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("nil")); CHECK(ac.entryMap.count("number")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "return_types") { check(R"( local function f(a: number): n@1 local b: string = "don't trip" )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("nil")); CHECK(ac.entryMap.count("number")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "as_types") { check(R"( local a: any = 5 local b: number = (a :: n@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("nil")); CHECK(ac.entryMap.count("number")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "function_type_types") { check(R"( local a: (n@1 local b: (number, (n@2 local c: (number, (number) -> n@3 local d: (number, (number) -> (number, n@4 local e: (n: n@5 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("nil")); CHECK(ac.entryMap.count("number")); ac = autocomplete('2'); CHECK(ac.entryMap.count("nil")); CHECK(ac.entryMap.count("number")); ac = autocomplete('3'); CHECK(ac.entryMap.count("nil")); CHECK(ac.entryMap.count("number")); ac = autocomplete('4'); CHECK(ac.entryMap.count("nil")); CHECK(ac.entryMap.count("number")); ac = autocomplete('5'); CHECK(ac.entryMap.count("nil")); CHECK(ac.entryMap.count("number")); } TEST_CASE_FIXTURE(ACFixture, "generic_types") { check(R"( function f(a: T@1 local b: string = "don't trip" )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("Tee")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "type_correct_suggestion_in_argument") { // local check(R"( local function target(a: number, b: string) return a + #b end local one = 4 local two = "hello" return target(o@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("one")); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::None); check(R"( local function target(a: number, b: string) return a + #b end local one = 4 local two = "hello" return target(one, t@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("two")); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::None); // member check(R"( local function target(a: number, b: string) return a + #b end local a = { one = 4, two = "hello" } return target(a.@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("one")); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::None); check(R"( local function target(a: number, b: string) return a + #b end local a = { one = 4, two = "hello" } return target(a.one, a.@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("two")); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::None); // union match check(R"( local function target(a: string?) return #b end local a = { one = 4, two = "hello" } return target(a.@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("two")); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::None); } TEST_CASE_FIXTURE(ACFixture, "type_correct_suggestion_in_table") { if (FFlag::LuauSolverV2) // CLI-116815 Autocomplete cannot suggest keys while autocompleting inside of a table return; check(R"( type Foo = { a: number, b: string } local a = { one = 4, two = "hello" } local b: Foo = { a = a.@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("one")); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::None); CHECK_EQ(ac.context, AutocompleteContext::Property); check(R"( type Foo = { a: number, b: string } local a = { one = 4, two = "hello" } local b: Foo = { b = a.@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("two")); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::None); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "type_correct_function_return_types") { check(R"( local function target(a: number, b: string) return a + #b end local function bar1(a: number) return -a end local function bar2(a: string) return a .. 'x' end return target(b@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("bar1")); CHECK(ac.entryMap["bar1"].typeCorrect == TypeCorrectKind::CorrectFunctionResult); CHECK(ac.entryMap["bar2"].typeCorrect == TypeCorrectKind::None); check(R"( local function target(a: number, b: string) return a + #b end local function bar1(a: number) return -a end local function bar2(a: string) return a .. 'x' end return target(bar1, b@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("bar2")); CHECK(ac.entryMap["bar2"].typeCorrect == TypeCorrectKind::CorrectFunctionResult); CHECK(ac.entryMap["bar1"].typeCorrect == TypeCorrectKind::None); check(R"( local function target(a: number, b: string) return a + #b end local function bar1(a: number): (...number) return -a, a end local function bar2(a: string) return a .. 'x' end return target(b@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("bar1")); CHECK(ac.entryMap["bar1"].typeCorrect == TypeCorrectKind::CorrectFunctionResult); CHECK(ac.entryMap["bar2"].typeCorrect == TypeCorrectKind::None); } TEST_CASE_FIXTURE(ACFixture, "type_correct_local_type_suggestion") { check(R"( local b: s@1 = "str" )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function f() return "str" end local b: s@1 = f() )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); check(R"( local b: s@1, c: n@2 = "str", 2 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('2'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function f() return 1, "str", 3 end local a: b@1, b: n@2, c: s@3, d: n@4 = false, f() )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("boolean")); CHECK(ac.entryMap["boolean"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('2'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('3'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('4'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function f(): ...number return 1, 2, 3 end local a: boolean, b: n@1 = false, f() )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "type_correct_function_type_suggestion") { check(R"( local b: (n@1) -> number = function(a: number, b: string) return a + #b end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local b: (number, s@1 = function(a: number, b: string) return a + #b end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); check(R"( local b: (number, string) -> b@1 = function(a: number, b: string): boolean return a + #b == 0 end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("boolean")); CHECK(ac.entryMap["boolean"].typeCorrect == TypeCorrectKind::Correct); check(R"( local b: (number, ...s@1) = function(a: number, ...: string) return a end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); check(R"( local b: (number) -> ...s@1 = function(a: number): ...string return "a", "b", "c" end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "type_correct_full_type_suggestion") { check(R"( local b:@1 @2= "str" )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('2'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); check(R"( local b: @1= function(a: number) return -a end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("(number) -> number")); CHECK(ac.entryMap["(number) -> number"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "type_correct_argument_type_suggestion") { check(R"( local function target(a: number, b: string) return a + #b end local function d(a: n@1, b) return target(a, b) end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function target(a: number, b: string) return a + #b end local function d(a, b: s@1) return target(a, b) end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function target(a: number, b: string) return a + #b end local function d(a:@1 @2, b) return target(a, b) end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('2'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function target(a: number, b: string) return a + #b end local function d(a, b: @1)@2: number return target(a, b) end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('2'); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::None); } TEST_CASE_FIXTURE(ACFixture, "type_correct_expected_argument_type_suggestion") { check(R"( local function target(callback: (a: number, b: string) -> number) return callback(4, "hello") end local x = target(function(a: @1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function target(callback: (a: number, b: string) -> number) return callback(4, "hello") end local x = target(function(a: n@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function target(callback: (a: number, b: string) -> number) return callback(4, "hello") end local x = target(function(a: n@1, b: @2) return a + #b end) )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('2'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function target(callback: (...number) -> number) return callback(1, 2, 3) end local x = target(function(a: n@1) return a end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "type_correct_expected_argument_type_pack_suggestion") { check(R"( local function target(callback: (...number) -> number) return callback(1, 2, 3) end local x = target(function(...:n@1) return a end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function target(callback: (...number) -> number) return callback(1, 2, 3) end local x = target(function(a:number, b:number, ...:@1) return a + b end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "type_correct_expected_return_type_suggestion") { check(R"( local function target(callback: () -> number) return callback() end local x = target(function(): n@1 return 1 end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function target(callback: () -> (number, number)) return callback() end local x = target(function(): (number, n@1 return 1, 2 end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "type_correct_expected_return_type_pack_suggestion") { check(R"( local function target(callback: () -> ...number) return callback() end local x = target(function(): ...n@1 return 1, 2, 3 end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); check(R"( local function target(callback: () -> ...number) return callback() end local x = target(function(): (number, number, ...n@1 return 1, 2, 3 end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "type_correct_expected_argument_type_suggestion_optional") { check(R"( local function target(callback: nil | (a: number, b: string) -> number) return callback(4, "hello") end local x = target(function(a: @1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "type_correct_expected_argument_type_suggestion_self") { check(R"( local t = {} t.x = 5 function t:target(callback: (a: number, b: string) -> number) return callback(self.x, "hello") end local x = t:target(function(a: @1, b:@2 ) end) local y = t.target(t, function(a: number, b: @3) end) )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap["number"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('2'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('3'); CHECK(ac.entryMap.count("string")); CHECK(ac.entryMap["string"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "do_not_suggest_internal_module_type") { fileResolver.source["Module/A"] = R"( type done = { x: number, y: number } local function a(a: (done) -> number) return a({x=1, y=2}) end local function b(a: ((done) -> number) -> number) return a(function(done) return 1 end) end return {a = a, b = b} )"; LUAU_REQUIRE_NO_ERRORS(frontend.check("Module/A")); fileResolver.source["Module/B"] = R"( local ex = require(script.Parent.A) ex.a(function(x: )"; frontend.check("Module/B"); auto ac = autocomplete("Module/B", Position{2, 16}); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "done"); fileResolver.source["Module/C"] = R"( local ex = require(script.Parent.A) ex.b(function(x: )"; frontend.check("Module/C"); ac = autocomplete("Module/C", Position{2, 16}); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "(done) -> number"); } TEST_CASE_FIXTURE(ACBuiltinsFixture, "suggest_external_module_type") { fileResolver.source["Module/A"] = R"( export type done = { x: number, y: number } local function a(a: (done) -> number) return a({x=1, y=2}) end local function b(a: ((done) -> number) -> number) return a(function(done) return 1 end) end return {a = a, b = b} )"; LUAU_REQUIRE_NO_ERRORS(frontend.check("Module/A")); fileResolver.source["Module/B"] = R"( local ex = require(script.Parent.A) ex.a(function(x: )"; frontend.check("Module/B"); auto ac = autocomplete("Module/B", Position{2, 16}); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "done"); CHECK(ac.entryMap.count("ex.done")); CHECK(ac.entryMap["ex.done"].typeCorrect == TypeCorrectKind::Correct); fileResolver.source["Module/C"] = R"( local ex = require(script.Parent.A) ex.b(function(x: )"; frontend.check("Module/C"); ac = autocomplete("Module/C", Position{2, 16}); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "(done) -> number"); CHECK(ac.entryMap.count("(ex.done) -> number")); CHECK(ac.entryMap["(ex.done) -> number"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "do_not_suggest_synthetic_table_name") { check(R"( local foo = { a = 1, b = 2 } local bar: @1= foo )"); auto ac = autocomplete('1'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "foo"); } TEST_CASE_FIXTURE(ACFixture, "type_correct_function_no_parenthesis") { check(R"( local function target(a: (number) -> number) return a(4) end local function bar1(a: number) return -a end local function bar2(a: string) return a .. 'x' end return target(b@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("bar1")); CHECK(ac.entryMap["bar1"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["bar1"].parens == ParenthesesRecommendation::None); CHECK(ac.entryMap["bar2"].typeCorrect == TypeCorrectKind::None); } TEST_CASE_FIXTURE(ACFixture, "function_in_assignment_has_parentheses") { check(R"( local function bar(a: number) return -a end local abc = b@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("bar")); CHECK(ac.entryMap["bar"].parens == ParenthesesRecommendation::CursorInside); } TEST_CASE_FIXTURE(ACFixture, "function_result_passed_to_function_has_parentheses") { check(R"( local function foo() return 1 end local function bar(a: number) return -a end local abc = bar(@1) )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("foo")); CHECK(ac.entryMap["foo"].parens == ParenthesesRecommendation::CursorAfter); } TEST_CASE_FIXTURE(ACFixture, "type_correct_sealed_table") { check(R"( local function f(a: { x: number, y: number }) return a.x + a.y end local fp: @1= f )"); auto ac = autocomplete('1'); if (FFlag::LuauSolverV2) REQUIRE_EQ("({ x: number, y: number }) -> number", toString(requireType("f"))); else REQUIRE_EQ("({| x: number, y: number |}) -> number", toString(requireType("f"))); CHECK(ac.entryMap.count("({ x: number, y: number }) -> number")); } TEST_CASE_FIXTURE(ACFixture, "type_correct_keywords") { check(R"( local function a(x: boolean) end local function b(x: number?) end local function c(x: (number) -> string) end local function d(x: ((number) -> string)?) end local function e(x: ((number) -> string) & ((boolean) -> number)) end local tru = {} local ni = false local ac = a(t@1) local bc = b(n@2) local cc = c(f@3) local dc = d(f@4) local ec = e(f@5) )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("tru")); CHECK(ac.entryMap["tru"].typeCorrect == TypeCorrectKind::None); CHECK(ac.entryMap["true"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["false"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('2'); CHECK(ac.entryMap.count("ni")); CHECK(ac.entryMap["ni"].typeCorrect == TypeCorrectKind::None); CHECK(ac.entryMap["nil"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('3'); CHECK(ac.entryMap.count("false")); CHECK(ac.entryMap["false"].typeCorrect == TypeCorrectKind::None); CHECK(ac.entryMap["function"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('4'); CHECK(ac.entryMap["function"].typeCorrect == TypeCorrectKind::Correct); ac = autocomplete('5'); CHECK(ac.entryMap["function"].typeCorrect == TypeCorrectKind::Correct); } TEST_CASE_FIXTURE(ACFixture, "type_correct_suggestion_for_overloads") { if (FFlag::LuauSolverV2) // CLI-116814 Autocomplete needs to populate expected types for function arguments correctly // (overloads and singletons) return; check(R"( local target: ((number) -> string) & ((string) -> number)) local one = 4 local two = "hello" return target(o@1) )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("one")); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::Correct); check(R"( local target: ((number) -> string) & ((number) -> number)) local one = 4 local two = "hello" return target(o@1) )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("one")); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::None); check(R"( local target: ((number, number) -> string) & ((string) -> number)) local one = 4 local two = "hello" return target(1, o@1) )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("one")); CHECK(ac.entryMap["one"].typeCorrect == TypeCorrectKind::Correct); CHECK(ac.entryMap["two"].typeCorrect == TypeCorrectKind::None); } TEST_CASE_FIXTURE(ACFixture, "optional_members") { check(R"( local a = { x = 2, y = 3 } type A = typeof(a) local b: A? = a return b.@1 )"); auto ac = autocomplete('1'); CHECK_EQ(2, ac.entryMap.size()); CHECK(ac.entryMap.count("x")); CHECK(ac.entryMap.count("y")); check(R"( local a = { x = 2, y = 3 } type A = typeof(a) local b: nil | A = a return b.@1 )"); ac = autocomplete('1'); CHECK_EQ(2, ac.entryMap.size()); CHECK(ac.entryMap.count("x")); CHECK(ac.entryMap.count("y")); check(R"( local b: nil | nil return b.@1 )"); ac = autocomplete('1'); CHECK_EQ(0, ac.entryMap.size()); } TEST_CASE_FIXTURE(ACFixture, "no_function_name_suggestions") { check(R"( function na@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.empty()); check(R"( local function @1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.empty()); check(R"( local function na@1 )"); ac = autocomplete('1'); CHECK(ac.entryMap.empty()); } TEST_CASE_FIXTURE(ACFixture, "skip_current_local") { check(R"( local other = 1 local name = na@1 )"); auto ac = autocomplete('1'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "name"); CHECK(ac.entryMap.count("other")); check(R"( local other = 1 local name, test = na@1 )"); ac = autocomplete('1'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "name"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "test"); CHECK(ac.entryMap.count("other")); } TEST_CASE_FIXTURE(ACFixture, "keyword_members") { check(R"( local a = { done = 1, forever = 2 } local b = a.do@1 local c = a.for@2 local d = a.@3 do end )"); auto ac = autocomplete('1'); CHECK_EQ(2, ac.entryMap.size()); CHECK(ac.entryMap.count("done")); CHECK(ac.entryMap.count("forever")); ac = autocomplete('2'); CHECK_EQ(2, ac.entryMap.size()); CHECK(ac.entryMap.count("done")); CHECK(ac.entryMap.count("forever")); ac = autocomplete('3'); CHECK_EQ(2, ac.entryMap.size()); CHECK(ac.entryMap.count("done")); CHECK(ac.entryMap.count("forever")); } TEST_CASE_FIXTURE(ACFixture, "keyword_methods") { check(R"( local a = {} function a:done() end local b = a:do@1 )"); auto ac = autocomplete('1'); CHECK_EQ(1, ac.entryMap.size()); CHECK(ac.entryMap.count("done")); } TEST_CASE_FIXTURE(ACFixture, "keyword_types") { fileResolver.source["Module/A"] = R"( export type done = { x: number, y: number } export type other = { z: number, w: number } return {} )"; LUAU_REQUIRE_NO_ERRORS(frontend.check("Module/A")); fileResolver.source["Module/B"] = R"( local aaa = require(script.Parent.A) local a: aaa.do )"; frontend.check("Module/B"); auto ac = autocomplete("Module/B", Position{2, 15}); CHECK_EQ(2, ac.entryMap.size()); CHECK(ac.entryMap.count("done")); CHECK(ac.entryMap.count("other")); } TEST_CASE_FIXTURE(ACFixture, "comments") { fileResolver.source["Comments"] = "--!str"; auto ac = autocomplete("Comments", Position{0, 6}); CHECK_EQ(0, ac.entryMap.size()); } TEST_CASE_FIXTURE(ACBuiltinsFixture, "autocompleteProp_index_function_metamethod_is_variadic") { fileResolver.source["Module/A"] = R"( type Foo = {x: number} local t = {} setmetatable(t, { __index = function(index: string): ...Foo return {x = 1}, {x = 2} end }) local a = t. -- Line 9 -- | Column 20 )"; auto ac = autocomplete("Module/A", Position{9, 20}); REQUIRE_EQ(1, ac.entryMap.size()); CHECK(ac.entryMap.count("x")); } TEST_CASE_FIXTURE(ACFixture, "if_then_else_full_keywords") { check(R"( local thenceforth = false local elsewhere = false local doover = false local endurance = true if 1 then@1 else@2 end while false do@3 end repeat@4 until )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.size() == 1); CHECK(ac.entryMap.count("then")); ac = autocomplete('2'); CHECK(ac.entryMap.count("else")); CHECK(ac.entryMap.count("elseif")); ac = autocomplete('3'); CHECK(ac.entryMap.count("do")); ac = autocomplete('4'); CHECK(ac.entryMap.count("do")); // FIXME: ideally we want to handle start and end of all statements as well } TEST_CASE_FIXTURE(ACFixture, "if_then_else_elseif_completions") { check(R"( local elsewhere = false if true then return 1 el@1 end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("else")); CHECK(ac.entryMap.count("elseif")); CHECK(ac.entryMap.count("elsewhere") == 0); check(R"( local elsewhere = false if true then return 1 else return 2 el@1 end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("else") == 0); CHECK(ac.entryMap.count("elseif") == 0); CHECK(ac.entryMap.count("elsewhere")); check(R"( local elsewhere = false if true then print("1") elif true then print("2") el@1 end )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("else")); CHECK(ac.entryMap.count("elseif")); CHECK(ac.entryMap.count("elsewhere")); } TEST_CASE_FIXTURE(ACFixture, "not_the_var_we_are_defining") { fileResolver.source["Module/A"] = "abc,de"; auto ac = autocomplete("Module/A", Position{0, 6}); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "de"); } TEST_CASE_FIXTURE(ACFixture, "recursive_function_global") { fileResolver.source["global"] = R"(function abc() end )"; auto ac = autocomplete("global", Position{1, 0}); CHECK(ac.entryMap.count("abc")); } TEST_CASE_FIXTURE(ACFixture, "recursive_function_local") { fileResolver.source["local"] = R"(local function abc() end )"; auto ac = autocomplete("local", Position{1, 0}); CHECK(ac.entryMap.count("abc")); } TEST_CASE_FIXTURE(ACFixture, "suggest_table_keys") { if (FFlag::LuauSolverV2) // CLI-116812 AutocompleteTest.suggest_table_keys needs to populate expected types for nested // tables without an annotation return; check(R"( type Test = { first: number, second: number } local t: Test = { f@1 } )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("first")); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); // Intersection check(R"( type Test = { first: number } & { second: number } local t: Test = { f@1 } )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("first")); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); // Union check(R"( type Test = { first: number, second: number } | { second: number, third: number } local t: Test = { s@1 } )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("second")); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "first"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "third"); CHECK_EQ(ac.context, AutocompleteContext::Property); // No parenthesis suggestion check(R"( type Test = { first: (number) -> number, second: number } local t: Test = { f@1 } )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("first")); CHECK(ac.entryMap["first"].parens == ParenthesesRecommendation::None); CHECK_EQ(ac.context, AutocompleteContext::Property); // When key is changed check(R"( type Test = { first: number, second: number } local t: Test = { f@1 = 2 } )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("first")); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); // Alternative key syntax check(R"( type Test = { first: number, second: number } local t: Test = { ["f@1"] } )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("first")); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); // Not an alternative key syntax check(R"( type Test = { first: number, second: number } local t: Test = { "f@1" } )"); ac = autocomplete('1'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "first"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "second"); CHECK_EQ(ac.context, AutocompleteContext::String); // Skip keys that are already defined check(R"( type Test = { first: number, second: number } local t: Test = { first = 2, s@1 } )"); ac = autocomplete('1'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "first"); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); // Don't skip active key check(R"( type Test = { first: number, second: number } local t: Test = { first@1 } )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("first")); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); // Inference after first key check(R"( local t = { { first = 5, second = 10 }, { f@1 } } )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("first")); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); check(R"( local t = { [2] = { first = 5, second = 10 }, [5] = { f@1 } } )"); ac = autocomplete('1'); CHECK(ac.entryMap.count("first")); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "suggest_table_keys_no_initial_character") { check(R"( type Test = { first: number, second: number } local t: Test = { @1 } )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("first")); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "suggest_table_keys_no_initial_character_2") { check(R"( type Test = { first: number, second: number } local t: Test = { first = 1, @1 } )"); auto ac = autocomplete('1'); CHECK_EQ(ac.entryMap.count("first"), 0); CHECK(ac.entryMap.count("second")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "suggest_table_keys_no_initial_character_3") { check(R"( type Properties = { TextScaled: boolean, Text: string } local function create(props: Properties) end create({ @1 }) )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.size() > 0); CHECK(ac.entryMap.count("TextScaled")); CHECK(ac.entryMap.count("Text")); CHECK_EQ(ac.context, AutocompleteContext::Property); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_documentation_symbols") { loadDefinition(R"( declare y: { x: number, } )"); check(R"( local a = y.@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("x")); CHECK_EQ(ac.entryMap["x"].documentationSymbol, "@test/global/y.x"); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_ifelse_expressions") { check(R"( local temp = false local even = true; local a = true a = if t@1emp then t a = if temp t@2 a = if temp then e@3 a = if temp then even e@4 a = if temp then even elseif t@5 a = if temp then even elseif true t@6 a = if temp then even elseif true then t@7 a = if temp then even elseif true then temp e@8 a = if temp then even elseif true then temp else e@9 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("temp")); CHECK(ac.entryMap.count("true")); CHECK(ac.entryMap.count("then") == 0); CHECK(ac.entryMap.count("else") == 0); CHECK(ac.entryMap.count("elseif") == 0); CHECK_EQ(ac.context, AutocompleteContext::Expression); ac = autocomplete('2'); CHECK(ac.entryMap.count("temp") == 0); CHECK(ac.entryMap.count("true") == 0); CHECK(ac.entryMap.count("then")); CHECK(ac.entryMap.count("else") == 0); CHECK(ac.entryMap.count("elseif") == 0); CHECK_EQ(ac.context, AutocompleteContext::Keyword); ac = autocomplete('3'); CHECK(ac.entryMap.count("even")); CHECK(ac.entryMap.count("then") == 0); CHECK(ac.entryMap.count("else") == 0); CHECK(ac.entryMap.count("elseif") == 0); CHECK_EQ(ac.context, AutocompleteContext::Expression); ac = autocomplete('4'); CHECK(ac.entryMap.count("even") == 0); CHECK(ac.entryMap.count("then") == 0); CHECK(ac.entryMap.count("else")); CHECK(ac.entryMap.count("elseif")); CHECK_EQ(ac.context, AutocompleteContext::Keyword); ac = autocomplete('5'); CHECK(ac.entryMap.count("temp")); CHECK(ac.entryMap.count("true")); CHECK(ac.entryMap.count("then") == 0); CHECK(ac.entryMap.count("else") == 0); CHECK(ac.entryMap.count("elseif") == 0); CHECK_EQ(ac.context, AutocompleteContext::Expression); ac = autocomplete('6'); CHECK(ac.entryMap.count("temp") == 0); CHECK(ac.entryMap.count("true") == 0); CHECK(ac.entryMap.count("then")); CHECK(ac.entryMap.count("else") == 0); CHECK(ac.entryMap.count("elseif") == 0); CHECK_EQ(ac.context, AutocompleteContext::Keyword); ac = autocomplete('7'); CHECK(ac.entryMap.count("temp")); CHECK(ac.entryMap.count("true")); CHECK(ac.entryMap.count("then") == 0); CHECK(ac.entryMap.count("else") == 0); CHECK(ac.entryMap.count("elseif") == 0); CHECK_EQ(ac.context, AutocompleteContext::Expression); ac = autocomplete('8'); CHECK(ac.entryMap.count("even") == 0); CHECK(ac.entryMap.count("then") == 0); CHECK(ac.entryMap.count("else")); CHECK(ac.entryMap.count("elseif")); CHECK_EQ(ac.context, AutocompleteContext::Keyword); ac = autocomplete('9'); CHECK(ac.entryMap.count("then") == 0); CHECK(ac.entryMap.count("else") == 0); CHECK(ac.entryMap.count("elseif") == 0); CHECK_EQ(ac.context, AutocompleteContext::Expression); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_if_else_regression") { check(R"( local abcdef = 0; local temp = false local even = true; local a a = if temp then even else@1 a = if temp then even else @2 a = if temp then even else abc@3 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("else") == 0); ac = autocomplete('2'); CHECK(ac.entryMap.count("else") == 0); ac = autocomplete('3'); CHECK(ac.entryMap.count("abcdef")); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_interpolated_string_constant") { check(R"(f(`@1`))"); auto ac = autocomplete('1'); CHECK(ac.entryMap.empty()); CHECK_EQ(ac.context, AutocompleteContext::String); check(R"(f(`@1 {"a"}`))"); ac = autocomplete('1'); CHECK(ac.entryMap.empty()); CHECK_EQ(ac.context, AutocompleteContext::String); check(R"(f(`{"a"} @1`))"); ac = autocomplete('1'); CHECK(ac.entryMap.empty()); CHECK_EQ(ac.context, AutocompleteContext::String); check(R"(f(`{"a"} @1 {"b"}`))"); ac = autocomplete('1'); CHECK(ac.entryMap.empty()); CHECK_EQ(ac.context, AutocompleteContext::String); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_interpolated_string_expression") { check(R"(f(`expression = {@1}`))"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("table")); CHECK_EQ(ac.context, AutocompleteContext::Expression); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_interpolated_string_expression_with_comments") { check(R"(f(`expression = {--[[ bla bla bla ]]@1`))"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("table")); CHECK_EQ(ac.context, AutocompleteContext::Expression); check(R"(f(`expression = {@1 --[[ bla bla bla ]]`))"); ac = autocomplete('1'); CHECK(!ac.entryMap.empty()); CHECK(ac.entryMap.count("table")); CHECK_EQ(ac.context, AutocompleteContext::Expression); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_interpolated_string_as_singleton") { check(R"( --!strict local function f(a: "cat" | "dog") end f(`@1`) f(`uhhh{'try'}@2`) )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("cat")); CHECK_EQ(ac.context, AutocompleteContext::String); ac = autocomplete('2'); CHECK(ac.entryMap.empty()); CHECK_EQ(ac.context, AutocompleteContext::String); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_explicit_type_pack") { check(R"( type A = () -> T... local a: A<(number, s@1> )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap.count("string")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_first_function_arg_expected_type") { check(R"( local function foo1() return 1 end local function foo2() return "1" end local function bar0() return "got" .. a end local function bar1(a: number) return "got " .. a end local function bar2(a: number, b: string) return "got " .. a .. b end local t = {} function t:bar1(a: number) return "got " .. a end local r1 = bar0(@1) local r2 = bar1(@2) local r3 = bar2(@3) local r4 = t:bar1(@4) )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("foo1")); CHECK(ac.entryMap["foo1"].typeCorrect == TypeCorrectKind::None); REQUIRE(ac.entryMap.count("foo2")); CHECK(ac.entryMap["foo2"].typeCorrect == TypeCorrectKind::None); ac = autocomplete('2'); REQUIRE(ac.entryMap.count("foo1")); CHECK(ac.entryMap["foo1"].typeCorrect == TypeCorrectKind::CorrectFunctionResult); REQUIRE(ac.entryMap.count("foo2")); CHECK(ac.entryMap["foo2"].typeCorrect == TypeCorrectKind::None); ac = autocomplete('3'); REQUIRE(ac.entryMap.count("foo1")); CHECK(ac.entryMap["foo1"].typeCorrect == TypeCorrectKind::CorrectFunctionResult); REQUIRE(ac.entryMap.count("foo2")); CHECK(ac.entryMap["foo2"].typeCorrect == TypeCorrectKind::None); ac = autocomplete('4'); REQUIRE(ac.entryMap.count("foo1")); CHECK(ac.entryMap["foo1"].typeCorrect == TypeCorrectKind::CorrectFunctionResult); REQUIRE(ac.entryMap.count("foo2")); CHECK(ac.entryMap["foo2"].typeCorrect == TypeCorrectKind::None); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_default_type_parameters") { check(R"( type A = () -> T )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap.count("string")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_default_type_pack_parameters") { check(R"( type A = () -> T )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("number")); CHECK(ac.entryMap.count("string")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACBuiltinsFixture, "autocomplete_oop_implicit_self") { check(R"( --!strict local Class = {} Class.__index = Class type Class = typeof(setmetatable({} :: { x: number }, Class)) function Class.new(x: number): Class return setmetatable({x = x}, Class) end function Class.getx(self: Class) return self.x end function test() local c = Class.new(42) local n = c:@1 print(n) end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("getx")); } TEST_CASE_FIXTURE(ACBuiltinsFixture, "autocomplete_on_string_singletons") { check(R"( --!strict local foo: "hello" | "bye" = "hello" foo:@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("format")); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_string_singletons") { if (FFlag::LuauSolverV2) // CLI-116814 Autocomplete needs to populate expected types for function arguments correctly // (overloads and singletons) return; check(R"( type tag = "cat" | "dog" local function f(a: tag) end f("@1") f(@2) local x: tag = "@3" )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("cat")); CHECK(ac.entryMap.count("dog")); CHECK_EQ(ac.context, AutocompleteContext::String); ac = autocomplete('2'); CHECK(ac.entryMap.count("\"cat\"")); CHECK(ac.entryMap.count("\"dog\"")); CHECK_EQ(ac.context, AutocompleteContext::Expression); ac = autocomplete('3'); CHECK(ac.entryMap.count("cat")); CHECK(ac.entryMap.count("dog")); CHECK_EQ(ac.context, AutocompleteContext::String); check(R"( type tagged = {tag:"cat", fieldx:number} | {tag:"dog", fieldy:number} local x: tagged = {tag="@4"} )"); ac = autocomplete('4'); CHECK(ac.entryMap.count("cat")); CHECK(ac.entryMap.count("dog")); CHECK_EQ(ac.context, AutocompleteContext::String); } TEST_CASE_FIXTURE(ACFixture, "string_singleton_as_table_key") { check(R"( type Direction = "up" | "down" local a: {[Direction]: boolean} = {[@1] = true} local b: {[Direction]: boolean} = {["@2"] = true} local c: {[Direction]: boolean} = {u@3 = true} local d: {[Direction]: boolean} = {[u@4] = true} local e: {[Direction]: boolean} = {[@5]} local f: {[Direction]: boolean} = {["@6"]} local g: {[Direction]: boolean} = {u@7} local h: {[Direction]: boolean} = {[u@8]} )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("\"up\"")); CHECK(ac.entryMap.count("\"down\"")); ac = autocomplete('2'); CHECK(ac.entryMap.count("up")); CHECK(ac.entryMap.count("down")); ac = autocomplete('3'); CHECK(ac.entryMap.count("up")); CHECK(ac.entryMap.count("down")); ac = autocomplete('4'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "up"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "down"); CHECK(ac.entryMap.count("\"up\"")); CHECK(ac.entryMap.count("\"down\"")); ac = autocomplete('5'); CHECK(ac.entryMap.count("\"up\"")); CHECK(ac.entryMap.count("\"down\"")); ac = autocomplete('6'); CHECK(ac.entryMap.count("up")); CHECK(ac.entryMap.count("down")); ac = autocomplete('7'); CHECK(ac.entryMap.count("up")); CHECK(ac.entryMap.count("down")); ac = autocomplete('8'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "up"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "down"); CHECK(ac.entryMap.count("\"up\"")); CHECK(ac.entryMap.count("\"down\"")); } // https://github.com/Roblox/luau/issues/858 TEST_CASE_FIXTURE(ACFixture, "string_singleton_in_if_statement") { ScopedFastFlag sff[]{ {FFlag::LuauSolverV2, true}, }; check(R"( --!strict type Direction = "left" | "right" local dir: Direction = "left" if dir == @1"@2"@3 then end local a: {[Direction]: boolean} = {[@4"@5"@6]} if dir == @7`@8`@9 then end local a: {[Direction]: boolean} = {[@A`@B`@C]} )"); Luau::AutocompleteResult ac; ac = autocomplete('1'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('2'); LUAU_CHECK_HAS_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_KEY(ac.entryMap, "right"); ac = autocomplete('3'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('4'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('5'); LUAU_CHECK_HAS_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_KEY(ac.entryMap, "right"); ac = autocomplete('6'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('7'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('8'); LUAU_CHECK_HAS_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_KEY(ac.entryMap, "right"); ac = autocomplete('9'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('A'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('B'); LUAU_CHECK_HAS_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_KEY(ac.entryMap, "right"); ac = autocomplete('C'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); } // https://github.com/Roblox/luau/issues/858 TEST_CASE_FIXTURE(ACFixture, "string_singleton_in_if_statement2") { // don't run this when the DCR flag isn't set if (!FFlag::LuauSolverV2) return; check(R"( --!strict type Direction = "left" | "right" local dir: Direction -- typestate here means dir is actually typed as `"left"` dir = "left" if dir == @1"@2"@3 then end local a: {[Direction]: boolean} = {[@4"@5"@6]} if dir == @7`@8`@9 then end local a: {[Direction]: boolean} = {[@A`@B`@C]} )"); Luau::AutocompleteResult ac; ac = autocomplete('1'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('2'); LUAU_CHECK_HAS_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('3'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('4'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('5'); LUAU_CHECK_HAS_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_KEY(ac.entryMap, "right"); ac = autocomplete('6'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('7'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('8'); LUAU_CHECK_HAS_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('9'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('A'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); ac = autocomplete('B'); LUAU_CHECK_HAS_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_KEY(ac.entryMap, "right"); ac = autocomplete('C'); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "left"); LUAU_CHECK_HAS_NO_KEY(ac.entryMap, "right"); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_string_singleton_equality") { check(R"( type tagged = {tag:"cat", fieldx:number} | {tag:"dog", fieldy:number} local x: tagged = {tag="cat", fieldx=2} if x.tag == "@1" or "@2" ~= x.tag then end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("cat")); CHECK(ac.entryMap.count("dog")); ac = autocomplete('2'); CHECK(ac.entryMap.count("cat")); CHECK(ac.entryMap.count("dog")); // CLI-48823: assignment to x.tag should also autocomplete, but union l-values are not supported yet } TEST_CASE_FIXTURE(ACFixture, "autocomplete_boolean_singleton") { check(R"( local function f(x: true) end f(@1) )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("true")); CHECK(ac.entryMap["true"].typeCorrect == TypeCorrectKind::Correct); REQUIRE(ac.entryMap.count("false")); CHECK(ac.entryMap["false"].typeCorrect == TypeCorrectKind::None); CHECK_EQ(ac.context, AutocompleteContext::Expression); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_string_singleton_escape") { check(R"( type tag = "strange\t\"cat\"" | 'nice\t"dog"' local function f(x: tag) end f(@1) f("@2") )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("\"strange\\t\\\"cat\\\"\"")); CHECK(ac.entryMap.count("\"nice\\t\\\"dog\\\"\"")); ac = autocomplete('2'); CHECK(ac.entryMap.count("strange\\t\\\"cat\\\"")); CHECK(ac.entryMap.count("nice\\t\\\"dog\\\"")); } TEST_CASE_FIXTURE(ACFixture, "function_in_assignment_has_parentheses_2") { check(R"( local bar: ((number) -> number) & (number, number) -> number) local abc = b@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("bar")); CHECK(ac.entryMap["bar"].parens == ParenthesesRecommendation::CursorInside); } TEST_CASE_FIXTURE(ACFixture, "no_incompatible_self_calls_on_class") { loadDefinition(R"( declare class Foo function one(self): number two: () -> number end )"); { check(R"( local function f(t: Foo) t:@1 end )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("one")); REQUIRE(ac.entryMap.count("two")); CHECK(!ac.entryMap["one"].wrongIndexType); CHECK(ac.entryMap["two"].wrongIndexType); CHECK(ac.entryMap["one"].indexedWithSelf); CHECK(ac.entryMap["two"].indexedWithSelf); } { check(R"( local function f(t: Foo) t.@1 end )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("one")); REQUIRE(ac.entryMap.count("two")); CHECK(ac.entryMap["one"].wrongIndexType); CHECK(!ac.entryMap["two"].wrongIndexType); CHECK(!ac.entryMap["one"].indexedWithSelf); CHECK(!ac.entryMap["two"].indexedWithSelf); } } TEST_CASE_FIXTURE(ACFixture, "simple") { check(R"( local t = {} function t:m() end t:m() )"); // auto ac = autocomplete('1'); // REQUIRE(ac.entryMap.count("m")); // CHECK(!ac.entryMap["m"].wrongIndexType); } TEST_CASE_FIXTURE(ACFixture, "do_compatible_self_calls") { check(R"( local t = {} function t:m() end t:@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("m")); CHECK(!ac.entryMap["m"].wrongIndexType); CHECK(ac.entryMap["m"].indexedWithSelf); } TEST_CASE_FIXTURE(ACFixture, "no_incompatible_self_calls") { check(R"( local t = {} function t.m() end t:@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("m")); CHECK(ac.entryMap["m"].wrongIndexType); CHECK(ac.entryMap["m"].indexedWithSelf); } TEST_CASE_FIXTURE(ACFixture, "no_incompatible_self_calls_2") { check(R"( local f: (() -> number) & ((number) -> number) = function(x: number?) return 2 end local t = {} t.f = f t:@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("f")); CHECK(ac.entryMap["f"].wrongIndexType); CHECK(ac.entryMap["f"].indexedWithSelf); } TEST_CASE_FIXTURE(ACFixture, "do_wrong_compatible_self_calls") { check(R"( local t = {} function t.m(x: typeof(t)) end t:@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("m")); // We can make changes to mark this as a wrong way to call even though it's compatible CHECK(!ac.entryMap["m"].wrongIndexType); CHECK(ac.entryMap["m"].indexedWithSelf); } TEST_CASE_FIXTURE(ACFixture, "do_wrong_compatible_nonself_calls") { check(R"( local t = {} function t:m(x: string) end t.@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("m")); if (FFlag::LuauSolverV2) CHECK(ac.entryMap["m"].wrongIndexType); else CHECK(!ac.entryMap["m"].wrongIndexType); CHECK(!ac.entryMap["m"].indexedWithSelf); } TEST_CASE_FIXTURE(ACFixture, "no_wrong_compatible_self_calls_with_generics") { check(R"( local t = {} function t.m(a: T) end t:@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("m")); // While this call is compatible with the type, this requires instantiation of a generic type which we don't perform CHECK(ac.entryMap["m"].wrongIndexType); CHECK(ac.entryMap["m"].indexedWithSelf); } TEST_CASE_FIXTURE(ACFixture, "string_prim_self_calls_are_fine") { check(R"( local s = "hello" s:@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("byte")); CHECK(ac.entryMap["byte"].wrongIndexType == false); CHECK(ac.entryMap["byte"].indexedWithSelf); REQUIRE(ac.entryMap.count("char")); CHECK(ac.entryMap["char"].wrongIndexType == true); CHECK(ac.entryMap["char"].indexedWithSelf); REQUIRE(ac.entryMap.count("sub")); CHECK(ac.entryMap["sub"].wrongIndexType == false); CHECK(ac.entryMap["sub"].indexedWithSelf); } TEST_CASE_FIXTURE(ACFixture, "string_prim_non_self_calls_are_avoided") { check(R"( local s = "hello" s.@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("char")); CHECK(ac.entryMap["char"].wrongIndexType == false); CHECK(!ac.entryMap["char"].indexedWithSelf); REQUIRE(ac.entryMap.count("sub")); CHECK(ac.entryMap["sub"].wrongIndexType == true); CHECK(!ac.entryMap["sub"].indexedWithSelf); } TEST_CASE_FIXTURE(ACBuiltinsFixture, "library_non_self_calls_are_fine") { check(R"( string.@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("byte")); CHECK(ac.entryMap["byte"].wrongIndexType == false); CHECK(!ac.entryMap["byte"].indexedWithSelf); REQUIRE(ac.entryMap.count("char")); CHECK(ac.entryMap["char"].wrongIndexType == false); CHECK(!ac.entryMap["char"].indexedWithSelf); REQUIRE(ac.entryMap.count("sub")); CHECK(ac.entryMap["sub"].wrongIndexType == false); CHECK(!ac.entryMap["sub"].indexedWithSelf); check(R"( table.@1 )"); ac = autocomplete('1'); REQUIRE(ac.entryMap.count("remove")); CHECK(ac.entryMap["remove"].wrongIndexType == false); CHECK(!ac.entryMap["remove"].indexedWithSelf); REQUIRE(ac.entryMap.count("getn")); CHECK(ac.entryMap["getn"].wrongIndexType == false); CHECK(!ac.entryMap["getn"].indexedWithSelf); REQUIRE(ac.entryMap.count("insert")); CHECK(ac.entryMap["insert"].wrongIndexType == false); CHECK(!ac.entryMap["insert"].indexedWithSelf); } TEST_CASE_FIXTURE(ACBuiltinsFixture, "library_self_calls_are_invalid") { check(R"( string:@1 )"); auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count("byte")); CHECK(ac.entryMap["byte"].wrongIndexType == true); CHECK(ac.entryMap["byte"].indexedWithSelf); REQUIRE(ac.entryMap.count("char")); CHECK(ac.entryMap["char"].wrongIndexType == true); CHECK(ac.entryMap["char"].indexedWithSelf); // We want the next test to evaluate to 'true', but we have to allow function defined with 'self' to be callable with ':' // We may change the definition of the string metatable to not use 'self' types in the future (like byte/char/pack/unpack) REQUIRE(ac.entryMap.count("sub")); CHECK(ac.entryMap["sub"].wrongIndexType == false); CHECK(ac.entryMap["sub"].indexedWithSelf); } TEST_CASE_FIXTURE(ACFixture, "source_module_preservation_and_invalidation") { check(R"( local a = { x = 2, y = 4 } a.@1 )"); frontend.clear(); auto ac = autocomplete('1'); CHECK(2 == ac.entryMap.size()); CHECK(ac.entryMap.count("x")); CHECK(ac.entryMap.count("y")); frontend.check("MainModule", {}); ac = autocomplete('1'); CHECK(ac.entryMap.count("x")); CHECK(ac.entryMap.count("y")); frontend.markDirty("MainModule", nullptr); ac = autocomplete('1'); CHECK(ac.entryMap.count("x")); CHECK(ac.entryMap.count("y")); frontend.check("MainModule", {}); ac = autocomplete('1'); CHECK(ac.entryMap.count("x")); CHECK(ac.entryMap.count("y")); } TEST_CASE_FIXTURE(ACFixture, "globals_are_order_independent") { check(R"( local myLocal = 4 function abc0() local myInnerLocal = 1 @1 end function abc1() local myInnerLocal = 1 end )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("myLocal")); CHECK(ac.entryMap.count("myInnerLocal")); CHECK(ac.entryMap.count("abc0")); CHECK(ac.entryMap.count("abc1")); } TEST_CASE_FIXTURE(ACFixture, "string_contents_is_available_to_callback") { loadDefinition(R"( declare function require(path: string): any )"); GlobalTypes& globals = FFlag::LuauSolverV2 ? frontend.globals : frontend.globalsForAutocomplete; std::optional require = globals.globalScope->linearSearchForBinding("require"); REQUIRE(require); Luau::unfreeze(globals.globalTypes); attachTag(require->typeId, "RequireCall"); Luau::freeze(globals.globalTypes); check(R"( local x = require("testing/@1") )"); bool isCorrect = false; auto ac1 = autocomplete( '1', [&isCorrect](std::string, std::optional, std::optional contents) -> std::optional { isCorrect = contents && *contents == "testing/"; return std::nullopt; } ); CHECK(isCorrect); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_response_perf1" * doctest::timeout(0.5)) { if (FFlag::LuauSolverV2) return; // FIXME: This test is just barely at the threshhold which makes it very flaky under the new solver // Build a function type with a large overload set const int parts = 100; std::string source; for (int i = 0; i < parts; i++) formatAppend(source, "type T%d = { f%d: number }\n", i, i); source += "type Instance = { new: (('s0', extra: Instance?) -> T0)"; for (int i = 1; i < parts; i++) formatAppend(source, " & (('s%d', extra: Instance?) -> T%d)", i, i); source += " }\n"; source += "local Instance: Instance = {} :: any\n"; source += "local function c(): boolean return t@1 end\n"; check(source); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("true")); CHECK(ac.entryMap.count("Instance")); } TEST_CASE_FIXTURE(ACFixture, "autocomplete_subtyping_recursion_limit") { // TODO: in old solver, type resolve can't handle the type in this test without a stack overflow if (!FFlag::LuauSolverV2) return; ScopedFastInt luauTypeInferRecursionLimit{FInt::LuauTypeInferRecursionLimit, 10}; const int parts = 100; std::string source; source += "function f()\n"; std::string prefix; for (int i = 0; i < parts; i++) formatAppend(prefix, "(nil|({a%d:number}&", i); formatAppend(prefix, "(nil|{a%d:number})", parts); for (int i = 0; i < parts; i++) formatAppend(prefix, "))"); source += "local x1 : " + prefix + "\n"; source += "local y : {a1:number} = x@1\n"; source += "end\n"; check(source); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("true")); CHECK(ac.entryMap.count("x1")); } TEST_CASE_FIXTURE(ACFixture, "strict_mode_force") { check(R"( --!nonstrict local a: {x: number} = {x=1} local b = a local c = b.@1 )"); auto ac = autocomplete('1'); CHECK_EQ(1, ac.entryMap.size()); CHECK(ac.entryMap.count("x")); } TEST_CASE_FIXTURE(ACFixture, "suggest_exported_types") { check(R"( export type Type = {a: number} local a: T@1 )"); auto ac = autocomplete('1'); CHECK(ac.entryMap.count("Type")); CHECK_EQ(ac.context, AutocompleteContext::Type); } TEST_CASE_FIXTURE(ACFixture, "frontend_use_correct_global_scope") { loadDefinition(R"( declare class Instance Name: string end )"); CheckResult result = check(R"( local a: unknown = nil if typeof(a) == "Instance" then local b = a.@1 end )"); auto ac = autocomplete('1'); CHECK_EQ(1, ac.entryMap.size()); CHECK(ac.entryMap.count("Name")); } TEST_CASE_FIXTURE(ACFixture, "string_completion_outside_quotes") { loadDefinition(R"( declare function require(path: string): any )"); GlobalTypes& globals = FFlag::LuauSolverV2 ? frontend.globals : frontend.globalsForAutocomplete; std::optional require = globals.globalScope->linearSearchForBinding("require"); REQUIRE(require); Luau::unfreeze(globals.globalTypes); attachTag(require->typeId, "RequireCall"); Luau::freeze(globals.globalTypes); check(R"( local x = require(@1"@2"@3) )"); StringCompletionCallback callback = [](std::string, std::optional, std::optional contents ) -> std::optional { Luau::AutocompleteEntryMap results = {{"test", Luau::AutocompleteEntry{Luau::AutocompleteEntryKind::String, std::nullopt, false, false}}}; return results; }; auto ac = autocomplete('2', callback); CHECK_EQ(1, ac.entryMap.size()); CHECK(ac.entryMap.count("test")); ac = autocomplete('1', callback); CHECK_EQ(0, ac.entryMap.size()); ac = autocomplete('3', callback); CHECK_EQ(0, ac.entryMap.size()); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_empty") { check(R"( local function foo(a: () -> ()) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function() end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_args") { check(R"( local function foo(a: (number, string) -> ()) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(a0: number, a1: string) end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_args_single_return") { check(R"( local function foo(a: (number, string) -> (string)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(a0: number, a1: string): string end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_args_multi_return") { check(R"( local function foo(a: (number, string) -> (string, number)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(a0: number, a1: string): (string, number) end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled__noargs_multi_return") { check(R"( local function foo(a: () -> (string, number)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(): (string, number) end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled__varargs_multi_return") { check(R"( local function foo(a: (...number) -> (string, number)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(...: number): (string, number) end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_multi_varargs_multi_return") { check(R"( local function foo(a: (string, ...number) -> (string, number)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(a0: string, ...: number): (string, number) end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_multi_varargs_varargs_return") { check(R"( local function foo(a: (string, ...number) -> ...number) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(a0: string, ...: number): ...number end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_multi_varargs_multi_varargs_return") { check(R"( local function foo(a: (string, ...number) -> (boolean, ...number)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(a0: string, ...: number): (boolean, ...number) end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_named_args") { check(R"( local function foo(a: (foo: number, bar: string) -> (string, number)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(foo: number, bar: string): (string, number) end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_partially_args") { check(R"( local function foo(a: (number, bar: string) -> (string, number)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(a0: number, bar: string): (string, number) end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_partially_args_last") { check(R"( local function foo(a: (foo: number, string) -> (string, number)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(foo: number, a1: string): (string, number) end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_typeof_args") { check(R"( local t = { a = 1, b = 2 } local function foo(a: (foo: typeof(t)) -> ()) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(foo) end"; // Cannot utter this type. auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_table_literal_args") { check(R"( local function foo(a: (tbl: { x: number, y: number }) -> number) return a({x=2, y = 3}) end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(tbl: { x: number, y: number }): number end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_typeof_returns") { check(R"( local t = { a = 1, b = 2 } local function foo(a: () -> typeof(t)) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function() end"; // Cannot utter this type. auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_table_literal_args") { check(R"( local function foo(a: () -> { x: number, y: number }) return {x=2, y = 3} end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(): { x: number, y: number } end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_typeof_vararg") { check(R"( local t = { a = 1, b = 2 } local function foo(a: (...typeof(t)) -> ()) a() end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(...) end"; // Cannot utter this type. auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_generic_type_pack_vararg") { // CLI-116932 - Autocomplete on a anonymous function in a function argument should not recommend a function with a generic parameter. if (FFlag::LuauSolverV2) return; check(R"( local function foo(a: (...A) -> number, ...: A) return a(...) end foo(@1) )"); const std::optional EXPECTED_INSERT = "function(...): number end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_CASE_FIXTURE(ACFixture, "anonymous_autofilled_generic_on_argument_type_pack_vararg") { check(R"( local function foo(a: (...: T...) -> number) return a(4, 5, 6) end foo(@1) )"); const std::optional EXPECTED_INSERT = FFlag::LuauSolverV2 ? "function(...: number): number end" : "function(...): number end"; auto ac = autocomplete('1'); REQUIRE(ac.entryMap.count(kGeneratedAnonymousFunctionEntryName) == 1); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].kind == Luau::AutocompleteEntryKind::GeneratedFunction); CHECK(ac.entryMap[kGeneratedAnonymousFunctionEntryName].typeCorrect == Luau::TypeCorrectKind::Correct); REQUIRE(ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); CHECK_EQ(EXPECTED_INSERT, *ac.entryMap[kGeneratedAnonymousFunctionEntryName].insertText); } TEST_SUITE_END();