// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details #include "lua.h" #include "lualib.h" #include "luacode.h" #include "luacodegen.h" #include "Luau/BuiltinDefinitions.h" #include "Luau/DenseHash.h" #include "Luau/ModuleResolver.h" #include "Luau/TypeInfer.h" #include "Luau/BytecodeBuilder.h" #include "Luau/Frontend.h" #include "Luau/Compiler.h" #include "Luau/CodeGen.h" #include "Luau/BytecodeSummary.h" #include "doctest.h" #include "ScopedFlags.h" #include #include #include #include extern bool verbose; extern bool codegen; extern int optimizationLevel; LUAU_FASTFLAG(LuauTaggedLuData); LUAU_FASTFLAG(LuauSciNumberSkipTrailDot); LUAU_FASTINT(CodegenHeuristicsInstructionLimit); static lua_CompileOptions defaultOptions() { lua_CompileOptions copts = {}; copts.optimizationLevel = optimizationLevel; copts.debugLevel = 1; copts.vectorCtor = "vector"; copts.vectorType = "vector"; return copts; } static int lua_collectgarbage(lua_State* L) { static const char* const opts[] = {"stop", "restart", "collect", "count", "isrunning", "step", "setgoal", "setstepmul", "setstepsize", nullptr}; static const int optsnum[] = { LUA_GCSTOP, LUA_GCRESTART, LUA_GCCOLLECT, LUA_GCCOUNT, LUA_GCISRUNNING, LUA_GCSTEP, LUA_GCSETGOAL, LUA_GCSETSTEPMUL, LUA_GCSETSTEPSIZE}; int o = luaL_checkoption(L, 1, "collect", opts); int ex = luaL_optinteger(L, 2, 0); int res = lua_gc(L, optsnum[o], ex); switch (optsnum[o]) { case LUA_GCSTEP: case LUA_GCISRUNNING: { lua_pushboolean(L, res); return 1; } default: { lua_pushnumber(L, res); return 1; } } } static int lua_loadstring(lua_State* L) { size_t l = 0; const char* s = luaL_checklstring(L, 1, &l); const char* chunkname = luaL_optstring(L, 2, s); lua_setsafeenv(L, LUA_ENVIRONINDEX, false); size_t bytecodeSize = 0; char* bytecode = luau_compile(s, l, nullptr, &bytecodeSize); int result = luau_load(L, chunkname, bytecode, bytecodeSize, 0); free(bytecode); if (result == 0) return 1; lua_pushnil(L); lua_insert(L, -2); // put before error message return 2; // return nil plus error message } static int lua_vector(lua_State* L) { double x = luaL_checknumber(L, 1); double y = luaL_checknumber(L, 2); double z = luaL_checknumber(L, 3); #if LUA_VECTOR_SIZE == 4 double w = luaL_optnumber(L, 4, 0.0); lua_pushvector(L, float(x), float(y), float(z), float(w)); #else lua_pushvector(L, float(x), float(y), float(z)); #endif return 1; } static int lua_vector_dot(lua_State* L) { const float* a = luaL_checkvector(L, 1); const float* b = luaL_checkvector(L, 2); lua_pushnumber(L, a[0] * b[0] + a[1] * b[1] + a[2] * b[2]); return 1; } static int lua_vector_index(lua_State* L) { const float* v = luaL_checkvector(L, 1); const char* name = luaL_checkstring(L, 2); if (strcmp(name, "Magnitude") == 0) { lua_pushnumber(L, sqrtf(v[0] * v[0] + v[1] * v[1] + v[2] * v[2])); return 1; } if (strcmp(name, "Dot") == 0) { lua_pushcfunction(L, lua_vector_dot, "Dot"); return 1; } luaL_error(L, "%s is not a valid member of vector", name); } static int lua_vector_namecall(lua_State* L) { if (const char* str = lua_namecallatom(L, nullptr)) { if (strcmp(str, "Dot") == 0) return lua_vector_dot(L); } luaL_error(L, "%s is not a valid method of vector", luaL_checkstring(L, 1)); } int lua_silence(lua_State* L) { return 0; } using StateRef = std::unique_ptr; static StateRef runConformance(const char* name, void (*setup)(lua_State* L) = nullptr, void (*yield)(lua_State* L) = nullptr, lua_State* initialLuaState = nullptr, lua_CompileOptions* options = nullptr, bool skipCodegen = false) { #ifdef LUAU_CONFORMANCE_SOURCE_DIR std::string path = LUAU_CONFORMANCE_SOURCE_DIR; path += "/"; path += name; #else std::string path = __FILE__; path.erase(path.find_last_of("\\/")); path += "/conformance/"; path += name; #endif std::fstream stream(path, std::ios::in | std::ios::binary); INFO(path); REQUIRE(stream); std::string source(std::istreambuf_iterator(stream), {}); stream.close(); if (!initialLuaState) initialLuaState = luaL_newstate(); StateRef globalState(initialLuaState, lua_close); lua_State* L = globalState.get(); if (codegen && !skipCodegen && luau_codegen_supported()) luau_codegen_create(L); luaL_openlibs(L); // Register a few global functions for conformance tests std::vector funcs = { {"collectgarbage", lua_collectgarbage}, {"loadstring", lua_loadstring}, }; if (!verbose) { funcs.push_back({"print", lua_silence}); } // "null" terminate the list of functions to register funcs.push_back({nullptr, nullptr}); lua_pushvalue(L, LUA_GLOBALSINDEX); luaL_register(L, nullptr, funcs.data()); lua_pop(L, 1); // In some configurations we have a larger C stack consumption which trips some conformance tests #if defined(LUAU_ENABLE_ASAN) || defined(_NOOPT) || defined(_DEBUG) lua_pushboolean(L, true); lua_setglobal(L, "limitedstack"); #endif // Extra test-specific setup if (setup) setup(L); // Protect core libraries and metatables from modification luaL_sandbox(L); // Create a new writable global table for current thread luaL_sandboxthread(L); // Lua conformance tests treat _G synonymously with getfenv(); for now cater to them lua_pushvalue(L, LUA_GLOBALSINDEX); lua_pushvalue(L, LUA_GLOBALSINDEX); lua_setfield(L, -1, "_G"); std::string chunkname = "=" + std::string(name); // note: luau_compile supports nullptr options, but we need to customize our defaults to improve test coverage lua_CompileOptions opts = options ? *options : defaultOptions(); size_t bytecodeSize = 0; char* bytecode = luau_compile(source.data(), source.size(), &opts, &bytecodeSize); int result = luau_load(L, chunkname.c_str(), bytecode, bytecodeSize, 0); free(bytecode); if (result == 0 && codegen && !skipCodegen && luau_codegen_supported()) Luau::CodeGen::compile(L, -1, Luau::CodeGen::CodeGen_ColdFunctions); int status = (result == 0) ? lua_resume(L, nullptr, 0) : LUA_ERRSYNTAX; while (yield && (status == LUA_YIELD || status == LUA_BREAK)) { yield(L); status = lua_resume(L, nullptr, 0); } extern void luaC_validate(lua_State * L); // internal function, declared in lgc.h - not exposed via lua.h luaC_validate(L); if (status == 0) { REQUIRE(lua_isstring(L, -1)); CHECK(std::string(lua_tostring(L, -1)) == "OK"); } else { std::string error = (status == LUA_YIELD) ? "thread yielded unexpectedly" : lua_tostring(L, -1); error += "\nstacktrace:\n"; error += lua_debugtrace(L); FAIL(error); } return globalState; } static void* limitedRealloc(void* ud, void* ptr, size_t osize, size_t nsize) { if (nsize == 0) { free(ptr); return nullptr; } else if (nsize > 8 * 1024 * 1024) { // For testing purposes return null for large allocations so we can generate errors related to memory allocation failures return nullptr; } else { return realloc(ptr, nsize); } } static std::vector analyzeFile(const char* source, const unsigned nestingLimit) { Luau::BytecodeBuilder bcb; Luau::CompileOptions options; options.optimizationLevel = optimizationLevel; options.debugLevel = 1; compileOrThrow(bcb, source, options); const std::string& bytecode = bcb.getBytecode(); std::unique_ptr globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); int result = luau_load(L, "source", bytecode.data(), bytecode.size(), 0); REQUIRE(result == 0); return Luau::CodeGen::summarizeBytecode(L, -1, nestingLimit); } TEST_SUITE_BEGIN("Conformance"); TEST_CASE("CodegenSupported") { if (codegen && !luau_codegen_supported()) MESSAGE("Native code generation is not supported by the current configuration and will be disabled"); } TEST_CASE("Assert") { runConformance("assert.lua"); } TEST_CASE("Basic") { runConformance("basic.lua"); } TEST_CASE("Buffers") { runConformance("buffers.lua"); } TEST_CASE("Math") { runConformance("math.lua"); } TEST_CASE("Tables") { runConformance("tables.lua", [](lua_State* L) { lua_pushcfunction( L, [](lua_State* L) { if (lua_type(L, 1) == LUA_TNUMBER) { unsigned v = luaL_checkunsigned(L, 1); lua_pushlightuserdata(L, reinterpret_cast(uintptr_t(v))); } else { const void* p = lua_topointer(L, 1); LUAU_ASSERT(p); // we expect the test call to only pass GC values here lua_pushlightuserdata(L, const_cast(p)); } return 1; }, "makelud"); lua_setglobal(L, "makelud"); }); } TEST_CASE("PatternMatch") { runConformance("pm.lua"); } TEST_CASE("Sort") { runConformance("sort.lua"); } TEST_CASE("Move") { runConformance("move.lua"); } TEST_CASE("Clear") { runConformance("clear.lua"); } TEST_CASE("Strings") { runConformance("strings.lua"); } TEST_CASE("StringInterp") { runConformance("stringinterp.lua"); } TEST_CASE("VarArg") { runConformance("vararg.lua"); } TEST_CASE("Locals") { runConformance("locals.lua"); } TEST_CASE("Literals") { runConformance("literals.lua"); } TEST_CASE("Errors") { runConformance("errors.lua"); } TEST_CASE("Events") { runConformance("events.lua"); } TEST_CASE("Constructs") { runConformance("constructs.lua"); } TEST_CASE("Closure") { runConformance("closure.lua"); } TEST_CASE("Calls") { runConformance("calls.lua"); } TEST_CASE("Attrib") { runConformance("attrib.lua"); } TEST_CASE("GC") { runConformance("gc.lua"); } TEST_CASE("Bitwise") { runConformance("bitwise.lua"); } TEST_CASE("UTF8") { runConformance("utf8.lua"); } TEST_CASE("Coroutine") { runConformance("coroutine.lua"); } static int cxxthrow(lua_State* L) { #if LUA_USE_LONGJMP luaL_error(L, "oops"); #else throw std::runtime_error("oops"); #endif } TEST_CASE("PCall") { runConformance( "pcall.lua", [](lua_State* L) { lua_pushcfunction(L, cxxthrow, "cxxthrow"); lua_setglobal(L, "cxxthrow"); lua_pushcfunction( L, [](lua_State* L) -> int { lua_State* co = lua_tothread(L, 1); lua_xmove(L, co, 1); lua_resumeerror(co, L); return 0; }, "resumeerror"); lua_setglobal(L, "resumeerror"); }, nullptr, lua_newstate(limitedRealloc, nullptr)); } TEST_CASE("Pack") { runConformance("tpack.lua"); } TEST_CASE("Vector") { runConformance( "vector.lua", [](lua_State* L) { lua_pushcfunction(L, lua_vector, "vector"); lua_setglobal(L, "vector"); #if LUA_VECTOR_SIZE == 4 lua_pushvector(L, 0.0f, 0.0f, 0.0f, 0.0f); #else lua_pushvector(L, 0.0f, 0.0f, 0.0f); #endif luaL_newmetatable(L, "vector"); lua_pushstring(L, "__index"); lua_pushcfunction(L, lua_vector_index, nullptr); lua_settable(L, -3); lua_pushstring(L, "__namecall"); lua_pushcfunction(L, lua_vector_namecall, nullptr); lua_settable(L, -3); lua_setreadonly(L, -1, true); lua_setmetatable(L, -2); lua_pop(L, 1); }, nullptr, nullptr, nullptr); } static void populateRTTI(lua_State* L, Luau::TypeId type) { if (auto p = Luau::get(type)) { switch (p->type) { case Luau::PrimitiveType::Boolean: lua_pushstring(L, "boolean"); break; case Luau::PrimitiveType::NilType: lua_pushstring(L, "nil"); break; case Luau::PrimitiveType::Number: lua_pushstring(L, "number"); break; case Luau::PrimitiveType::String: lua_pushstring(L, "string"); break; case Luau::PrimitiveType::Thread: lua_pushstring(L, "thread"); break; case Luau::PrimitiveType::Buffer: lua_pushstring(L, "buffer"); break; default: LUAU_ASSERT(!"Unknown primitive type"); } } else if (auto t = Luau::get(type)) { lua_newtable(L); for (const auto& [name, prop] : t->props) { populateRTTI(L, prop.type()); lua_setfield(L, -2, name.c_str()); } } else if (Luau::get(type)) { lua_pushstring(L, "function"); } else if (Luau::get(type)) { lua_pushstring(L, "any"); } else if (auto i = Luau::get(type)) { for (const auto& part : i->parts) LUAU_ASSERT(Luau::get(part)); lua_pushstring(L, "function"); } else { LUAU_ASSERT(!"Unknown type"); } } TEST_CASE("Types") { runConformance("types.lua", [](lua_State* L) { Luau::NullModuleResolver moduleResolver; Luau::NullFileResolver fileResolver; Luau::NullConfigResolver configResolver; Luau::Frontend frontend{&fileResolver, &configResolver}; Luau::registerBuiltinGlobals(frontend, frontend.globals); Luau::freeze(frontend.globals.globalTypes); lua_newtable(L); for (const auto& [name, binding] : frontend.globals.globalScope->bindings) { populateRTTI(L, binding.typeId); lua_setfield(L, -2, toString(name).c_str()); } lua_setglobal(L, "RTTI"); }); } TEST_CASE("DateTime") { runConformance("datetime.lua"); } TEST_CASE("Debug") { runConformance("debug.lua"); } TEST_CASE("Debugger") { static int breakhits = 0; static lua_State* interruptedthread = nullptr; static bool singlestep = false; static int stephits = 0; SUBCASE("") { singlestep = false; } SUBCASE("SingleStep") { singlestep = true; } breakhits = 0; interruptedthread = nullptr; stephits = 0; lua_CompileOptions copts = defaultOptions(); copts.debugLevel = 2; runConformance( "debugger.lua", [](lua_State* L) { lua_Callbacks* cb = lua_callbacks(L); lua_singlestep(L, singlestep); // this will only be called in single-step mode cb->debugstep = [](lua_State* L, lua_Debug* ar) { stephits++; }; // for breakpoints to work we should make sure debugbreak is installed cb->debugbreak = [](lua_State* L, lua_Debug* ar) { breakhits++; // make sure we can trace the stack for every breakpoint we hit lua_debugtrace(L); // for every breakpoint, we break on the first invocation and continue on second // this allows us to easily step off breakpoints // (real implementaiton may require singlestepping) if (breakhits % 2 == 1) lua_break(L); }; // for resuming off a breakpoint inside a coroutine we need to resume the interrupted coroutine cb->debuginterrupt = [](lua_State* L, lua_Debug* ar) { CHECK(interruptedthread == nullptr); CHECK(ar->userdata); // userdata contains the interrupted thread interruptedthread = static_cast(ar->userdata); }; // add breakpoint() function lua_pushcclosurek( L, [](lua_State* L) -> int { int line = luaL_checkinteger(L, 1); bool enabled = luaL_optboolean(L, 2, true); lua_Debug ar = {}; lua_getinfo(L, lua_stackdepth(L) - 1, "f", &ar); lua_breakpoint(L, -1, line, enabled); return 0; }, "breakpoint", 0, nullptr); lua_setglobal(L, "breakpoint"); }, [](lua_State* L) { CHECK(breakhits % 2 == 1); lua_checkstack(L, LUA_MINSTACK); if (breakhits == 1) { // test lua_getargument int a = lua_getargument(L, 0, 1); REQUIRE(a); CHECK(lua_tointeger(L, -1) == 50); lua_pop(L, 1); int v = lua_getargument(L, 0, 2); REQUIRE(v); CHECK(lua_tointeger(L, -1) == 42); lua_pop(L, 1); // test lua_getlocal const char* l = lua_getlocal(L, 0, 1); REQUIRE(l); CHECK(strcmp(l, "b") == 0); CHECK(lua_tointeger(L, -1) == 50); lua_pop(L, 1); // test lua_getupvalue lua_Debug ar = {}; lua_getinfo(L, 0, "f", &ar); const char* u = lua_getupvalue(L, -1, 1); REQUIRE(u); CHECK(strcmp(u, "a") == 0); CHECK(lua_tointeger(L, -1) == 5); lua_pop(L, 2); } else if (breakhits == 3) { // validate assignment via lua_getlocal const char* l = lua_getlocal(L, 0, 1); REQUIRE(l); CHECK(strcmp(l, "a") == 0); CHECK(lua_tointeger(L, -1) == 6); lua_pop(L, 1); } else if (breakhits == 5) { // validate assignment via lua_getlocal const char* l = lua_getlocal(L, 1, 1); REQUIRE(l); CHECK(strcmp(l, "a") == 0); CHECK(lua_tointeger(L, -1) == 7); lua_pop(L, 1); } else if (breakhits == 7) { // validate assignment via lua_getlocal const char* l = lua_getlocal(L, 1, 1); REQUIRE(l); CHECK(strcmp(l, "a") == 0); CHECK(lua_tointeger(L, -1) == 8); lua_pop(L, 1); } else if (breakhits == 9) { // validate assignment via lua_getlocal const char* l = lua_getlocal(L, 1, 1); REQUIRE(l); CHECK(strcmp(l, "a") == 0); CHECK(lua_tointeger(L, -1) == 9); lua_pop(L, 1); } else if (breakhits == 13) { // validate assignment via lua_getlocal const char* l = lua_getlocal(L, 0, 1); REQUIRE(l); CHECK(strcmp(l, "a") == 0); CHECK(lua_isnil(L, -1)); lua_pop(L, 1); } if (interruptedthread) { lua_resume(interruptedthread, nullptr, 0); interruptedthread = nullptr; } }, nullptr, &copts, /* skipCodegen */ true); // Native code doesn't support debugging yet CHECK(breakhits == 14); // 2 hits per breakpoint if (singlestep) CHECK(stephits > 100); // note; this will depend on number of instructions which can vary, so we just make sure the callback gets hit often } TEST_CASE("NDebugGetUpValue") { lua_CompileOptions copts = defaultOptions(); copts.debugLevel = 0; // Don't optimize away any upvalues copts.optimizationLevel = 0; runConformance( "ndebug_upvalues.lua", nullptr, [](lua_State* L) { lua_checkstack(L, LUA_MINSTACK); // push the second frame's closure to the stack lua_Debug ar = {}; REQUIRE(lua_getinfo(L, 1, "f", &ar)); // get the first upvalue const char* u = lua_getupvalue(L, -1, 1); REQUIRE(u); // upvalue name is unknown without debug info CHECK(strcmp(u, "") == 0); CHECK(lua_tointeger(L, -1) == 5); lua_pop(L, 2); }, nullptr, &copts, /* skipCodegen */ false); } TEST_CASE("SameHash") { extern unsigned int luaS_hash(const char* str, size_t len); // internal function, declared in lstring.h - not exposed via lua.h // To keep VM and compiler separate, we duplicate the hash function definition // This test validates that the hash function in question returns the same results on basic inputs // If this is violated, some code may regress in performance due to hash slot misprediction in inline caches CHECK(luaS_hash("", 0) == Luau::BytecodeBuilder::getStringHash({"", 0})); CHECK(luaS_hash("lua", 3) == Luau::BytecodeBuilder::getStringHash({"lua", 3})); CHECK(luaS_hash("luau", 4) == Luau::BytecodeBuilder::getStringHash({"luau", 4})); CHECK(luaS_hash("luaubytecode", 12) == Luau::BytecodeBuilder::getStringHash({"luaubytecode", 12})); CHECK(luaS_hash("luaubytecodehash", 16) == Luau::BytecodeBuilder::getStringHash({"luaubytecodehash", 16})); // Also hash should work on unaligned source data even when hashing long strings char buf[128] = {}; CHECK(luaS_hash(buf + 1, 120) == luaS_hash(buf + 2, 120)); } TEST_CASE("Reference") { static int dtorhits = 0; dtorhits = 0; StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); // note, we push two userdata objects but only pin one of them (the first one) lua_newuserdatadtor(L, 0, [](void*) { dtorhits++; }); lua_newuserdatadtor(L, 0, [](void*) { dtorhits++; }); lua_gc(L, LUA_GCCOLLECT, 0); CHECK(dtorhits == 0); int ref = lua_ref(L, -2); lua_pop(L, 2); lua_gc(L, LUA_GCCOLLECT, 0); CHECK(dtorhits == 1); lua_getref(L, ref); CHECK(lua_isuserdata(L, -1)); lua_pop(L, 1); lua_gc(L, LUA_GCCOLLECT, 0); CHECK(dtorhits == 1); lua_unref(L, ref); lua_gc(L, LUA_GCCOLLECT, 0); CHECK(dtorhits == 2); } TEST_CASE("NewUserdataOverflow") { StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); lua_pushcfunction( L, [](lua_State* L1) { // The following userdata request might cause an overflow. lua_newuserdatadtor(L1, SIZE_MAX, [](void* d) {}); // The overflow might segfault in the following call. lua_getmetatable(L1, -1); return 0; }, nullptr); CHECK(lua_pcall(L, 0, 0, 0) == LUA_ERRRUN); CHECK(strcmp(lua_tostring(L, -1), "memory allocation error: block too big") == 0); } TEST_CASE("ApiTables") { StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); lua_newtable(L); lua_pushnumber(L, 123.0); lua_setfield(L, -2, "key"); lua_pushnumber(L, 456.0); lua_rawsetfield(L, -2, "key2"); lua_pushstring(L, "test"); lua_rawseti(L, -2, 5); // lua_gettable lua_pushstring(L, "key"); CHECK(lua_gettable(L, -2) == LUA_TNUMBER); CHECK(lua_tonumber(L, -1) == 123.0); lua_pop(L, 1); // lua_getfield CHECK(lua_getfield(L, -1, "key") == LUA_TNUMBER); CHECK(lua_tonumber(L, -1) == 123.0); lua_pop(L, 1); // lua_rawgetfield CHECK(lua_rawgetfield(L, -1, "key2") == LUA_TNUMBER); CHECK(lua_tonumber(L, -1) == 456.0); lua_pop(L, 1); // lua_rawget lua_pushstring(L, "key"); CHECK(lua_rawget(L, -2) == LUA_TNUMBER); CHECK(lua_tonumber(L, -1) == 123.0); lua_pop(L, 1); // lua_rawgeti CHECK(lua_rawgeti(L, -1, 5) == LUA_TSTRING); CHECK(strcmp(lua_tostring(L, -1), "test") == 0); lua_pop(L, 1); // lua_cleartable lua_cleartable(L, -1); lua_pushnil(L); CHECK(lua_next(L, -2) == 0); lua_pop(L, 1); } TEST_CASE("ApiIter") { StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); lua_newtable(L); lua_pushnumber(L, 123.0); lua_setfield(L, -2, "key"); lua_pushnumber(L, 456.0); lua_rawsetfield(L, -2, "key2"); lua_pushstring(L, "test"); lua_rawseti(L, -2, 1); // Lua-compatible iteration interface: lua_next double sum1 = 0; lua_pushnil(L); while (lua_next(L, -2)) { sum1 += lua_tonumber(L, -2); // key sum1 += lua_tonumber(L, -1); // value lua_pop(L, 1); // pop value, key is used by lua_next } CHECK(sum1 == 580); // Luau iteration interface: lua_rawiter (faster and preferable to lua_next) double sum2 = 0; for (int index = 0; index = lua_rawiter(L, -1, index), index >= 0;) { sum2 += lua_tonumber(L, -2); // key sum2 += lua_tonumber(L, -1); // value lua_pop(L, 2); // pop both key and value } CHECK(sum2 == 580); // pop table lua_pop(L, 1); } TEST_CASE("ApiCalls") { StateRef globalState = runConformance("apicalls.lua", nullptr, nullptr, lua_newstate(limitedRealloc, nullptr)); lua_State* L = globalState.get(); // lua_call { lua_getfield(L, LUA_GLOBALSINDEX, "add"); lua_pushnumber(L, 40); lua_pushnumber(L, 2); lua_call(L, 2, 1); CHECK(lua_isnumber(L, -1)); CHECK(lua_tonumber(L, -1) == 42); lua_pop(L, 1); } // lua_pcall { lua_getfield(L, LUA_GLOBALSINDEX, "add"); lua_pushnumber(L, 40); lua_pushnumber(L, 2); lua_pcall(L, 2, 1, 0); CHECK(lua_isnumber(L, -1)); CHECK(lua_tonumber(L, -1) == 42); lua_pop(L, 1); } // lua_equal with a sleeping thread wake up { lua_State* L2 = lua_newthread(L); lua_getfield(L2, LUA_GLOBALSINDEX, "create_with_tm"); lua_pushnumber(L2, 42); lua_pcall(L2, 1, 1, 0); lua_getfield(L2, LUA_GLOBALSINDEX, "create_with_tm"); lua_pushnumber(L2, 42); lua_pcall(L2, 1, 1, 0); // Reset GC lua_gc(L2, LUA_GCCOLLECT, 0); // Try to mark 'L2' as sleeping // Can't control GC precisely, even in tests lua_gc(L2, LUA_GCSTEP, 8); CHECK(lua_equal(L2, -1, -2) == 1); lua_pop(L2, 2); } // lua_clonefunction + fenv { lua_getfield(L, LUA_GLOBALSINDEX, "getpi"); lua_call(L, 0, 1); CHECK(lua_tonumber(L, -1) == 3.1415926); lua_pop(L, 1); lua_getfield(L, LUA_GLOBALSINDEX, "getpi"); // clone & override env lua_clonefunction(L, -1); lua_newtable(L); lua_pushnumber(L, 42); lua_setfield(L, -2, "pi"); lua_setfenv(L, -2); lua_call(L, 0, 1); CHECK(lua_tonumber(L, -1) == 42); lua_pop(L, 1); // this one calls original function again lua_call(L, 0, 1); CHECK(lua_tonumber(L, -1) == 3.1415926); lua_pop(L, 1); } // lua_clonefunction + upvalues { lua_getfield(L, LUA_GLOBALSINDEX, "incuv"); lua_call(L, 0, 1); CHECK(lua_tonumber(L, -1) == 1); lua_pop(L, 1); lua_getfield(L, LUA_GLOBALSINDEX, "incuv"); // two clones lua_clonefunction(L, -1); lua_clonefunction(L, -2); lua_call(L, 0, 1); CHECK(lua_tonumber(L, -1) == 2); lua_pop(L, 1); lua_call(L, 0, 1); CHECK(lua_tonumber(L, -1) == 3); lua_pop(L, 1); // this one calls original function again lua_call(L, 0, 1); CHECK(lua_tonumber(L, -1) == 4); lua_pop(L, 1); } // lua_pcall on OOM { lua_getfield(L, LUA_GLOBALSINDEX, "largealloc"); int res = lua_pcall(L, 0, 0, 0); CHECK(res == LUA_ERRMEM); } // lua_pcall on OOM with an error handler { lua_getfield(L, LUA_GLOBALSINDEX, "oops"); lua_getfield(L, LUA_GLOBALSINDEX, "largealloc"); int res = lua_pcall(L, 0, 1, -2); CHECK(res == LUA_ERRMEM); CHECK((lua_isstring(L, -1) && strcmp(lua_tostring(L, -1), "oops") == 0)); lua_pop(L, 1); } // lua_pcall on OOM with an error handler that errors { lua_getfield(L, LUA_GLOBALSINDEX, "error"); lua_getfield(L, LUA_GLOBALSINDEX, "largealloc"); int res = lua_pcall(L, 0, 1, -2); CHECK(res == LUA_ERRERR); CHECK((lua_isstring(L, -1) && strcmp(lua_tostring(L, -1), "error in error handling") == 0)); lua_pop(L, 1); } // lua_pcall on OOM with an error handler that OOMs { lua_getfield(L, LUA_GLOBALSINDEX, "largealloc"); lua_getfield(L, LUA_GLOBALSINDEX, "largealloc"); int res = lua_pcall(L, 0, 1, -2); CHECK(res == LUA_ERRMEM); CHECK((lua_isstring(L, -1) && strcmp(lua_tostring(L, -1), "not enough memory") == 0)); lua_pop(L, 1); } // lua_pcall on error with an error handler that OOMs { lua_getfield(L, LUA_GLOBALSINDEX, "largealloc"); lua_getfield(L, LUA_GLOBALSINDEX, "error"); int res = lua_pcall(L, 0, 1, -2); CHECK(res == LUA_ERRERR); CHECK((lua_isstring(L, -1) && strcmp(lua_tostring(L, -1), "error in error handling") == 0)); lua_pop(L, 1); } } TEST_CASE("ApiAtoms") { StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); lua_callbacks(L)->useratom = [](const char* s, size_t l) -> int16_t { if (strcmp(s, "string") == 0) return 0; if (strcmp(s, "important") == 0) return 1; return -1; }; lua_pushstring(L, "string"); lua_pushstring(L, "import"); lua_pushstring(L, "ant"); lua_concat(L, 2); lua_pushstring(L, "unimportant"); int a1, a2, a3; const char* s1 = lua_tostringatom(L, -3, &a1); const char* s2 = lua_tostringatom(L, -2, &a2); const char* s3 = lua_tostringatom(L, -1, &a3); CHECK(strcmp(s1, "string") == 0); CHECK(a1 == 0); CHECK(strcmp(s2, "important") == 0); CHECK(a2 == 1); CHECK(strcmp(s3, "unimportant") == 0); CHECK(a3 == -1); } static bool endsWith(const std::string& str, const std::string& suffix) { if (suffix.length() > str.length()) return false; return suffix == std::string_view(str.c_str() + str.length() - suffix.length(), suffix.length()); } TEST_CASE("ApiType") { StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); lua_pushnumber(L, 2); CHECK(strcmp(luaL_typename(L, -1), "number") == 0); CHECK(strcmp(luaL_typename(L, 1), "number") == 0); CHECK(lua_type(L, -1) == LUA_TNUMBER); CHECK(lua_type(L, 1) == LUA_TNUMBER); CHECK(strcmp(luaL_typename(L, 2), "no value") == 0); CHECK(lua_type(L, 2) == LUA_TNONE); CHECK(strcmp(lua_typename(L, lua_type(L, 2)), "no value") == 0); lua_newuserdata(L, 0); CHECK(strcmp(luaL_typename(L, -1), "userdata") == 0); CHECK(lua_type(L, -1) == LUA_TUSERDATA); lua_newtable(L); lua_pushstring(L, "hello"); lua_setfield(L, -2, "__type"); lua_setmetatable(L, -2); CHECK(strcmp(luaL_typename(L, -1), "hello") == 0); CHECK(lua_type(L, -1) == LUA_TUSERDATA); } TEST_CASE("ApiBuffer") { StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); lua_newbuffer(L, 1000); REQUIRE(lua_type(L, -1) == LUA_TBUFFER); CHECK(lua_isbuffer(L, -1)); CHECK(lua_objlen(L, -1) == 1000); CHECK(strcmp(lua_typename(L, LUA_TBUFFER), "buffer") == 0); CHECK(strcmp(luaL_typename(L, -1), "buffer") == 0); void* p1 = lua_tobuffer(L, -1, nullptr); size_t len = 0; void* p2 = lua_tobuffer(L, -1, &len); CHECK(len == 1000); CHECK(p1 == p2); void* p3 = luaL_checkbuffer(L, -1, nullptr); CHECK(p1 == p3); len = 0; void* p4 = luaL_checkbuffer(L, -1, &len); CHECK(len == 1000); CHECK(p1 == p4); memset(p1, 0xab, 1000); CHECK(lua_topointer(L, -1) != nullptr); lua_newbuffer(L, 0); lua_pushvalue(L, -2); CHECK(lua_equal(L, -3, -1)); CHECK(!lua_equal(L, -2, -1)); lua_pop(L, 1); } TEST_CASE("AllocApi") { int ud = 0; StateRef globalState(lua_newstate(limitedRealloc, &ud), lua_close); lua_State* L = globalState.get(); void* udCheck = nullptr; bool allocfIsSet = lua_getallocf(L, &udCheck) == limitedRealloc; CHECK(allocfIsSet); CHECK(udCheck == &ud); } #if !LUA_USE_LONGJMP TEST_CASE("ExceptionObject") { struct ExceptionResult { bool exceptionGenerated; std::string description; }; auto captureException = [](lua_State* L, const char* functionToRun) { try { lua_State* threadState = lua_newthread(L); lua_getfield(threadState, LUA_GLOBALSINDEX, functionToRun); CHECK(lua_isLfunction(threadState, -1)); lua_call(threadState, 0, 0); } catch (std::exception& e) { CHECK(e.what() != nullptr); return ExceptionResult{true, e.what()}; } return ExceptionResult{false, ""}; }; StateRef globalState = runConformance("exceptions.lua", nullptr, nullptr, lua_newstate(limitedRealloc, nullptr)); lua_State* L = globalState.get(); { ExceptionResult result = captureException(L, "infinite_recursion_error"); CHECK(result.exceptionGenerated); } { ExceptionResult result = captureException(L, "empty_function"); CHECK_FALSE(result.exceptionGenerated); } { ExceptionResult result = captureException(L, "pass_number_to_error"); CHECK(result.exceptionGenerated); CHECK(endsWith(result.description, "42")); } { ExceptionResult result = captureException(L, "pass_string_to_error"); CHECK(result.exceptionGenerated); CHECK(endsWith(result.description, "string argument")); } { ExceptionResult result = captureException(L, "pass_table_to_error"); CHECK(result.exceptionGenerated); } { ExceptionResult result = captureException(L, "large_allocation_error"); CHECK(result.exceptionGenerated); } } #endif TEST_CASE("IfElseExpression") { runConformance("ifelseexpr.lua"); } // Optionally returns debug info for the first Luau stack frame that is encountered on the callstack. static std::optional getFirstLuauFrameDebugInfo(lua_State* L) { static std::string_view kLua = "Lua"; lua_Debug ar; for (int i = 0; lua_getinfo(L, i, "sl", &ar); i++) { if (kLua == ar.what) return ar; } return std::nullopt; } TEST_CASE("TagMethodError") { static std::vector expectedHits; // Loop over two modes: // when doLuaBreak is false the test only verifies that callbacks occur on the expected lines in the Luau source // when doLuaBreak is true the test additionally calls lua_break to ensure breaking the debugger doesn't cause the VM to crash for (bool doLuaBreak : {false, true}) { expectedHits = {22, 32}; static int index; static bool luaBreak; index = 0; luaBreak = doLuaBreak; // 'yieldCallback' doesn't do anything, but providing the callback to runConformance // ensures that the call to lua_break doesn't cause an error to be generated because // runConformance doesn't expect the VM to be in the state LUA_BREAK. auto yieldCallback = [](lua_State* L) {}; runConformance( "tmerror.lua", [](lua_State* L) { auto* cb = lua_callbacks(L); cb->debugprotectederror = [](lua_State* L) { std::optional ar = getFirstLuauFrameDebugInfo(L); CHECK(lua_isyieldable(L)); REQUIRE(ar.has_value()); REQUIRE(index < int(std::size(expectedHits))); CHECK(ar->currentline == expectedHits[index++]); if (luaBreak) { // Cause luau execution to break when 'error' is called via 'pcall' // This call to lua_break is a regression test for an issue where debugprotectederror // was called on a thread that couldn't be yielded even though lua_isyieldable was true. lua_break(L); } }; }, yieldCallback); // Make sure the number of break points hit was the expected number CHECK(index == std::size(expectedHits)); } } TEST_CASE("Coverage") { lua_CompileOptions copts = defaultOptions(); copts.optimizationLevel = 1; // disable inlining to get fixed expected hit results copts.coverageLevel = 2; runConformance( "coverage.lua", [](lua_State* L) { lua_pushcfunction( L, [](lua_State* L) -> int { luaL_argexpected(L, lua_isLfunction(L, 1), 1, "function"); lua_newtable(L); lua_getcoverage(L, 1, L, [](void* context, const char* function, int linedefined, int depth, const int* hits, size_t size) { lua_State* L = static_cast(context); lua_newtable(L); lua_pushstring(L, function); lua_setfield(L, -2, "name"); lua_pushinteger(L, linedefined); lua_setfield(L, -2, "linedefined"); lua_pushinteger(L, depth); lua_setfield(L, -2, "depth"); for (size_t i = 0; i < size; ++i) if (hits[i] != -1) { lua_pushinteger(L, hits[i]); lua_rawseti(L, -2, int(i)); } lua_rawseti(L, -2, lua_objlen(L, -2) + 1); }); return 1; }, "getcoverage"); lua_setglobal(L, "getcoverage"); }, nullptr, nullptr, &copts); } TEST_CASE("StringConversion") { ScopedFastFlag luauSciNumberSkipTrailDot{FFlag::LuauSciNumberSkipTrailDot, true}; runConformance("strconv.lua"); } TEST_CASE("GCDump") { // internal function, declared in lgc.h - not exposed via lua.h extern void luaC_dump(lua_State * L, void* file, const char* (*categoryName)(lua_State * L, uint8_t memcat)); extern void luaC_enumheap(lua_State * L, void* context, void (*node)(void* context, void* ptr, uint8_t tt, uint8_t memcat, size_t size, const char* name), void (*edge)(void* context, void* from, void* to, const char* name)); StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); // push various objects on stack to cover different paths lua_createtable(L, 1, 2); lua_pushstring(L, "value"); lua_setfield(L, -2, "key"); lua_pushstring(L, "u42"); lua_setfield(L, -2, "__type"); lua_pushinteger(L, 42); lua_rawseti(L, -2, 1000); lua_pushinteger(L, 42); lua_rawseti(L, -2, 1); lua_pushvalue(L, -1); lua_setmetatable(L, -2); lua_newuserdata(L, 42); lua_pushvalue(L, -2); lua_setmetatable(L, -2); lua_pushinteger(L, 1); lua_pushcclosure(L, lua_silence, "test", 1); lua_newbuffer(L, 100); lua_State* CL = lua_newthread(L); lua_pushstring(CL, "local x x = {} local function f() x[1] = math.abs(42) end function foo() coroutine.yield() end foo() return f"); lua_loadstring(CL); lua_resume(CL, nullptr, 0); #ifdef _WIN32 const char* path = "NUL"; #else const char* path = "/dev/null"; #endif FILE* f = fopen(path, "w"); REQUIRE(f); luaC_dump(L, f, nullptr); fclose(f); struct Node { void* ptr; uint8_t tag; uint8_t memcat; size_t size; std::string name; }; struct EnumContext { EnumContext() : nodes{nullptr} , edges{nullptr} { } Luau::DenseHashMap nodes; Luau::DenseHashMap edges; } ctx; luaC_enumheap( L, &ctx, [](void* ctx, void* gco, uint8_t tt, uint8_t memcat, size_t size, const char* name) { EnumContext& context = *(EnumContext*)ctx; if (tt == LUA_TUSERDATA) CHECK(strcmp(name, "u42") == 0); context.nodes[gco] = {gco, tt, memcat, size, name ? name : ""}; }, [](void* ctx, void* s, void* t, const char*) { EnumContext& context = *(EnumContext*)ctx; context.edges[s] = t; }); CHECK(!ctx.nodes.empty()); CHECK(!ctx.edges.empty()); } TEST_CASE("Interrupt") { lua_CompileOptions copts = defaultOptions(); copts.optimizationLevel = 1; // disable loop unrolling to get fixed expected hit results static int index; StateRef globalState = runConformance("interrupt.lua", nullptr, nullptr, nullptr, &copts); lua_State* L = globalState.get(); // note: for simplicity here we setup the interrupt callback when the test starts // however, this carries a noticeable performance cost. in a real application, // it's advised to set interrupt callback on a timer from a different thread, // and set it back to nullptr once the interrupt triggered. // define the interrupt to check the expected hits static const int expectedhits[] = {11, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 8, 20, 15, 15, 15, 15, 18, 25, 23, 26}; lua_callbacks(L)->interrupt = [](lua_State* L, int gc) { if (gc >= 0) return; CHECK(index < int(std::size(expectedhits))); lua_Debug ar = {}; lua_getinfo(L, 0, "l", &ar); CHECK(ar.currentline == expectedhits[index]); index++; // check that we can yield inside an interrupt if (index == 4) lua_yield(L, 0); }; { lua_State* T = lua_newthread(L); lua_getglobal(T, "test"); index = 0; int status = lua_resume(T, nullptr, 0); CHECK(status == LUA_YIELD); CHECK(index == 4); status = lua_resume(T, nullptr, 0); CHECK(status == LUA_OK); CHECK(index == int(std::size(expectedhits))); lua_pop(L, 1); } // redefine the interrupt to break after 10 iterations of a loop that would otherwise be infinite // the test exposes a few global functions that we will call; the interrupt will force a yield lua_callbacks(L)->interrupt = [](lua_State* L, int gc) { if (gc >= 0) return; CHECK(index < 11); if (++index == 11) lua_yield(L, 0); }; for (int test = 1; test <= 10; ++test) { lua_State* T = lua_newthread(L); std::string name = "infloop" + std::to_string(test); lua_getglobal(T, name.c_str()); index = 0; int status = lua_resume(T, nullptr, 0); CHECK(status == LUA_YIELD); CHECK(index == 11); // abandon the thread lua_pop(L, 1); } } TEST_CASE("UserdataApi") { static int dtorhits = 0; dtorhits = 0; StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); // setup dtor for tag 42 (created later) auto dtor = [](lua_State* l, void* data) { dtorhits += *(int*)data; }; bool dtorIsNull = lua_getuserdatadtor(L, 42) == nullptr; CHECK(dtorIsNull); lua_setuserdatadtor(L, 42, dtor); bool dtorIsSet = lua_getuserdatadtor(L, 42) == dtor; CHECK(dtorIsSet); // light user data int lud; lua_pushlightuserdata(L, &lud); CHECK(lua_tolightuserdata(L, -1) == &lud); CHECK(lua_touserdata(L, -1) == &lud); CHECK(lua_topointer(L, -1) == &lud); // regular user data int* ud1 = (int*)lua_newuserdata(L, 4); *ud1 = 42; CHECK(lua_tolightuserdata(L, -1) == nullptr); CHECK(lua_touserdata(L, -1) == ud1); CHECK(lua_topointer(L, -1) == ud1); // tagged user data int* ud2 = (int*)lua_newuserdatatagged(L, 4, 42); *ud2 = -4; CHECK(lua_touserdatatagged(L, -1, 42) == ud2); CHECK(lua_touserdatatagged(L, -1, 41) == nullptr); CHECK(lua_userdatatag(L, -1) == 42); lua_setuserdatatag(L, -1, 43); CHECK(lua_userdatatag(L, -1) == 43); lua_setuserdatatag(L, -1, 42); // user data with inline dtor void* ud3 = lua_newuserdatadtor(L, 4, [](void* data) { dtorhits += *(int*)data; }); void* ud4 = lua_newuserdatadtor(L, 1, [](void* data) { dtorhits += *(char*)data; }); *(int*)ud3 = 43; *(char*)ud4 = 3; // user data with named metatable luaL_newmetatable(L, "udata1"); luaL_newmetatable(L, "udata2"); void* ud5 = lua_newuserdata(L, 0); lua_getfield(L, LUA_REGISTRYINDEX, "udata1"); lua_setmetatable(L, -2); void* ud6 = lua_newuserdata(L, 0); lua_getfield(L, LUA_REGISTRYINDEX, "udata2"); lua_setmetatable(L, -2); CHECK(luaL_checkudata(L, -2, "udata1") == ud5); CHECK(luaL_checkudata(L, -1, "udata2") == ud6); globalState.reset(); CHECK(dtorhits == 42); } TEST_CASE("LightuserdataApi") { ScopedFastFlag luauTaggedLuData{FFlag::LuauTaggedLuData, true}; StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); void* value = (void*)0x12345678; lua_pushlightuserdatatagged(L, value, 1); CHECK(lua_lightuserdatatag(L, -1) == 1); CHECK(lua_tolightuserdatatagged(L, -1, 0) == nullptr); CHECK(lua_tolightuserdatatagged(L, -1, 1) == value); lua_setlightuserdataname(L, 1, "id"); CHECK(!lua_getlightuserdataname(L, 0)); CHECK(strcmp(lua_getlightuserdataname(L, 1), "id") == 0); CHECK(strcmp(luaL_typename(L, -1), "id") == 0); lua_pop(L, 1); lua_pushlightuserdatatagged(L, value, 0); lua_pushlightuserdatatagged(L, value, 1); CHECK(lua_rawequal(L, -1, -2) == 0); lua_pop(L, 2); // Check lightuserdata table key uniqueness lua_newtable(L); lua_pushlightuserdatatagged(L, value, 2); lua_pushinteger(L, 20); lua_settable(L, -3); lua_pushlightuserdatatagged(L, value, 3); lua_pushinteger(L, 30); lua_settable(L, -3); lua_pushlightuserdatatagged(L, value, 2); lua_gettable(L, -2); lua_pushinteger(L, 20); CHECK(lua_rawequal(L, -1, -2) == 1); lua_pop(L, 2); lua_pushlightuserdatatagged(L, value, 3); lua_gettable(L, -2); lua_pushinteger(L, 30); CHECK(lua_rawequal(L, -1, -2) == 1); lua_pop(L, 2); lua_pop(L, 1); globalState.reset(); } TEST_CASE("Iter") { runConformance("iter.lua"); } const int kInt64Tag = 1; static int gInt64MT = -1; static int64_t getInt64(lua_State* L, int idx) { if (void* p = lua_touserdatatagged(L, idx, kInt64Tag)) return *static_cast(p); if (lua_isnumber(L, idx)) return lua_tointeger(L, idx); luaL_typeerror(L, 1, "int64"); } static void pushInt64(lua_State* L, int64_t value) { void* p = lua_newuserdatatagged(L, sizeof(int64_t), kInt64Tag); lua_getref(L, gInt64MT); lua_setmetatable(L, -2); *static_cast(p) = value; } TEST_CASE("Userdata") { runConformance("userdata.lua", [](lua_State* L) { // create metatable with all the metamethods lua_newtable(L); gInt64MT = lua_ref(L, -1); // __index lua_pushcfunction( L, [](lua_State* L) { void* p = lua_touserdatatagged(L, 1, kInt64Tag); if (!p) luaL_typeerror(L, 1, "int64"); const char* name = luaL_checkstring(L, 2); if (strcmp(name, "value") == 0) { lua_pushnumber(L, double(*static_cast(p))); return 1; } luaL_error(L, "unknown field %s", name); }, nullptr); lua_setfield(L, -2, "__index"); // __newindex lua_pushcfunction( L, [](lua_State* L) { void* p = lua_touserdatatagged(L, 1, kInt64Tag); if (!p) luaL_typeerror(L, 1, "int64"); const char* name = luaL_checkstring(L, 2); if (strcmp(name, "value") == 0) { double value = luaL_checknumber(L, 3); *static_cast(p) = int64_t(value); return 0; } luaL_error(L, "unknown field %s", name); }, nullptr); lua_setfield(L, -2, "__newindex"); // __eq lua_pushcfunction( L, [](lua_State* L) { lua_pushboolean(L, getInt64(L, 1) == getInt64(L, 2)); return 1; }, nullptr); lua_setfield(L, -2, "__eq"); // __lt lua_pushcfunction( L, [](lua_State* L) { lua_pushboolean(L, getInt64(L, 1) < getInt64(L, 2)); return 1; }, nullptr); lua_setfield(L, -2, "__lt"); // __le lua_pushcfunction( L, [](lua_State* L) { lua_pushboolean(L, getInt64(L, 1) <= getInt64(L, 2)); return 1; }, nullptr); lua_setfield(L, -2, "__le"); // __add lua_pushcfunction( L, [](lua_State* L) { pushInt64(L, getInt64(L, 1) + getInt64(L, 2)); return 1; }, nullptr); lua_setfield(L, -2, "__add"); // __sub lua_pushcfunction( L, [](lua_State* L) { pushInt64(L, getInt64(L, 1) - getInt64(L, 2)); return 1; }, nullptr); lua_setfield(L, -2, "__sub"); // __mul lua_pushcfunction( L, [](lua_State* L) { pushInt64(L, getInt64(L, 1) * getInt64(L, 2)); return 1; }, nullptr); lua_setfield(L, -2, "__mul"); // __div lua_pushcfunction( L, [](lua_State* L) { // ideally we'd guard against 0 but it's a test so eh pushInt64(L, getInt64(L, 1) / getInt64(L, 2)); return 1; }, nullptr); lua_setfield(L, -2, "__div"); // __idiv lua_pushcfunction( L, [](lua_State* L) { // for testing we use different semantics here compared to __div: __idiv rounds to negative inf, __div truncates (rounds to zero) // additionally, division loses precision here outside of 2^53 range // we do not necessarily recommend this behavior in production code! pushInt64(L, int64_t(floor(double(getInt64(L, 1)) / double(getInt64(L, 2))))); return 1; }, nullptr); lua_setfield(L, -2, "__idiv"); // __mod lua_pushcfunction( L, [](lua_State* L) { // ideally we'd guard against 0 and INT64_MIN but it's a test so eh pushInt64(L, getInt64(L, 1) % getInt64(L, 2)); return 1; }, nullptr); lua_setfield(L, -2, "__mod"); // __pow lua_pushcfunction( L, [](lua_State* L) { pushInt64(L, int64_t(pow(double(getInt64(L, 1)), double(getInt64(L, 2))))); return 1; }, nullptr); lua_setfield(L, -2, "__pow"); // __unm lua_pushcfunction( L, [](lua_State* L) { pushInt64(L, -getInt64(L, 1)); return 1; }, nullptr); lua_setfield(L, -2, "__unm"); // __tostring lua_pushcfunction( L, [](lua_State* L) { int64_t value = getInt64(L, 1); std::string str = std::to_string(value); lua_pushlstring(L, str.c_str(), str.length()); return 1; }, nullptr); lua_setfield(L, -2, "__tostring"); // ctor lua_pushcfunction( L, [](lua_State* L) { double v = luaL_checknumber(L, 1); pushInt64(L, int64_t(v)); return 1; }, "int64"); lua_setglobal(L, "int64"); }); } TEST_CASE("SafeEnv") { runConformance("safeenv.lua"); } TEST_CASE("Native") { runConformance("native.lua"); } TEST_CASE("NativeTypeAnnotations") { // This tests requires code to run natively, otherwise all 'is_native' checks will fail if (!codegen || !luau_codegen_supported()) return; runConformance( "native_types.lua", [](lua_State* L) { // add is_native() function lua_pushcclosurek( L, [](lua_State* L) -> int { extern int luaG_isnative(lua_State * L, int level); lua_pushboolean(L, luaG_isnative(L, 1)); return 1; }, "is_native", 0, nullptr); lua_setglobal(L, "is_native"); // for vector tests lua_pushcfunction(L, lua_vector, "vector"); lua_setglobal(L, "vector"); #if LUA_VECTOR_SIZE == 4 lua_pushvector(L, 0.0f, 0.0f, 0.0f, 0.0f); #else lua_pushvector(L, 0.0f, 0.0f, 0.0f); #endif luaL_newmetatable(L, "vector"); lua_setreadonly(L, -1, true); lua_setmetatable(L, -2); lua_pop(L, 1); }, nullptr, nullptr, nullptr); } TEST_CASE("HugeFunction") { std::string source; // add non-executed block that requires JUMPKX and generates a lot of constants that take available short (15-bit) constant space source += "if ... then\n"; source += "local _ = {\n"; for (int i = 0; i < 40000; ++i) { source += "0."; source += std::to_string(i); source += ","; } source += "}\n"; source += "end\n"; // use failed fast-calls with imports and constants to exercise all of the more complex fallback sequences source += "return bit32.lshift('84', -1)"; StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); if (codegen && luau_codegen_supported()) luau_codegen_create(L); luaL_openlibs(L); luaL_sandbox(L); luaL_sandboxthread(L); size_t bytecodeSize = 0; char* bytecode = luau_compile(source.data(), source.size(), nullptr, &bytecodeSize); int result = luau_load(L, "=HugeFunction", bytecode, bytecodeSize, 0); free(bytecode); REQUIRE(result == 0); if (codegen && luau_codegen_supported()) Luau::CodeGen::compile(L, -1, Luau::CodeGen::CodeGen_ColdFunctions); int status = lua_resume(L, nullptr, 0); REQUIRE(status == 0); CHECK(lua_tonumber(L, -1) == 42); } TEST_CASE("IrInstructionLimit") { if (!codegen || !luau_codegen_supported()) return; ScopedFastInt codegenHeuristicsInstructionLimit{FInt::CodegenHeuristicsInstructionLimit, 50'000}; std::string source; // Generate a hundred fat functions for (int fn = 0; fn < 100; fn++) { source += "local function fn" + std::to_string(fn) + "(...)\n"; source += "if ... then\n"; source += "local p1, p2 = ...\n"; source += "local _ = {\n"; for (int i = 0; i < 100; ++i) { source += "p1*0." + std::to_string(i) + ","; source += "p2+0." + std::to_string(i) + ","; } source += "}\n"; source += "return _\n"; source += "end\n"; source += "end\n"; } StateRef globalState(luaL_newstate(), lua_close); lua_State* L = globalState.get(); luau_codegen_create(L); luaL_openlibs(L); luaL_sandbox(L); luaL_sandboxthread(L); size_t bytecodeSize = 0; char* bytecode = luau_compile(source.data(), source.size(), nullptr, &bytecodeSize); int result = luau_load(L, "=HugeFunction", bytecode, bytecodeSize, 0); free(bytecode); REQUIRE(result == 0); Luau::CodeGen::CompilationStats nativeStats = {}; Luau::CodeGen::CodeGenCompilationResult nativeResult = Luau::CodeGen::compile(L, -1, Luau::CodeGen::CodeGen_ColdFunctions, &nativeStats); // Limit is not hit immediately, so with some functions compiled it should be a success CHECK(nativeResult != Luau::CodeGen::CodeGenCompilationResult::CodeGenFailed); // We should be able to compile at least one of our functions CHECK(nativeStats.functionsCompiled > 0); // But because of the limit, not all of them (101 because there's an extra global function) CHECK(nativeStats.functionsCompiled < 101); } TEST_CASE("BytecodeDistributionPerFunctionTest") { const char* source = R"( local function first(n, p) local t = {} for i=1,p do t[i] = i*10 end local function inner(_,n) if n > 0 then n = n-1 return n, unpack(t) end end return inner, nil, n end local function second(x) return x[1] end )"; std::vector summaries(analyzeFile(source, 0)); CHECK_EQ(summaries[0].getName(), "inner"); CHECK_EQ(summaries[0].getLine(), 6); CHECK_EQ(summaries[0].getCounts(0), std::vector({0, 0, 0, 0, 1, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 1, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0})); CHECK_EQ(summaries[1].getName(), "first"); CHECK_EQ(summaries[1].getLine(), 2); CHECK_EQ(summaries[1].getCounts(0), std::vector({0, 0, 1, 0, 2, 0, 3, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0})); CHECK_EQ(summaries[2].getName(), "second"); CHECK_EQ(summaries[2].getLine(), 15); CHECK_EQ(summaries[2].getCounts(0), std::vector({0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0})); CHECK_EQ(summaries[3].getName(), ""); CHECK_EQ(summaries[3].getLine(), 1); CHECK_EQ(summaries[3].getCounts(0), std::vector({0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 2, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0})); } TEST_SUITE_END();