use std::any::{Any, TypeId}; use std::borrow::Cow; use std::collections::HashMap; use std::fmt::Write; use std::os::raw::{c_char, c_int, c_void}; use std::panic::{catch_unwind, resume_unwind, AssertUnwindSafe}; use std::sync::{Arc, Mutex}; use std::{mem, ptr, slice}; use crate::error::{Error, Result}; use crate::ffi; lazy_static::lazy_static! { // The capacity must(!) be greater than number of stored keys static ref METATABLE_CACHE: Mutex> = Mutex::new(HashMap::with_capacity(32)); } // Checks that Lua has enough free stack space for future stack operations. On failure, this will // panic with an internal error message. pub unsafe fn assert_stack(state: *mut ffi::lua_State, amount: c_int) { // TODO: This should only be triggered when there is a logic error in `mlua`. In the future, // when there is a way to be confident about stack safety and test it, this could be enabled // only when `cfg!(debug_assertions)` is true. mlua_assert!( ffi::lua_checkstack(state, amount) != 0, "out of stack space" ); } // Checks that Lua has enough free stack space and returns `Error::StackError` on failure. pub unsafe fn check_stack(state: *mut ffi::lua_State, amount: c_int) -> Result<()> { if ffi::lua_checkstack(state, amount) == 0 { Err(Error::StackError) } else { Ok(()) } } pub struct StackGuard { state: *mut ffi::lua_State, top: c_int, } impl StackGuard { // Creates a StackGuard instance with wa record of the stack size, and on Drop will check the // stack size and drop any extra elements. If the stack size at the end is *smaller* than at // the beginning, this is considered a fatal logic error and will result in a panic. pub unsafe fn new(state: *mut ffi::lua_State) -> StackGuard { StackGuard { state, top: ffi::lua_gettop(state), } } } impl Drop for StackGuard { fn drop(&mut self) { unsafe { let top = ffi::lua_gettop(self.state); if top < self.top { mlua_panic!("{} too many stack values popped", self.top - top) } if top > self.top { ffi::lua_settop(self.state, self.top); } } } } // Call a function that calls into the Lua API and may trigger a Lua error (longjmp) in a safe way. // Wraps the inner function in a call to `lua_pcall`, so the inner function only has access to a // limited lua stack. `nargs` is the same as the the parameter to `lua_pcall`, and `nresults` is // always LUA_MULTRET. Internally uses 2 extra stack spaces, and does not call checkstack. // Provided function must *never* panic. pub unsafe fn protect_lua( state: *mut ffi::lua_State, nargs: c_int, f: unsafe extern "C" fn(*mut ffi::lua_State) -> c_int, ) -> Result<()> { let stack_start = ffi::lua_gettop(state) - nargs; ffi::lua_pushcfunction(state, error_traceback); ffi::lua_pushcfunction(state, f); if nargs > 0 { ffi::lua_rotate(state, stack_start + 1, 2); } let ret = ffi::lua_pcall(state, nargs, ffi::LUA_MULTRET, stack_start + 1); ffi::lua_remove(state, stack_start + 1); if ret == ffi::LUA_OK { Ok(()) } else { Err(pop_error(state, ret)) } } // Call a function that calls into the Lua API and may trigger a Lua error (longjmp) in a safe way. // Wraps the inner function in a call to `lua_pcall`, so the inner function only has access to a // limited lua stack. `nargs` and `nresults` are similar to the parameters of `lua_pcall`, but the // given function return type is not the return value count, instead the inner function return // values are assumed to match the `nresults` param. Internally uses 3 extra stack spaces, and does // not call checkstack. Provided function must *not* panic, and since it will generally be // lonjmping, should not contain any values that implement Drop. pub unsafe fn protect_lua_closure( state: *mut ffi::lua_State, nargs: c_int, nresults: c_int, f: F, ) -> Result where F: Fn(*mut ffi::lua_State) -> R, R: Copy, { union URes { uninit: (), init: R, } struct Params { function: F, result: URes, nresults: c_int, } unsafe extern "C" fn do_call(state: *mut ffi::lua_State) -> c_int where R: Copy, F: Fn(*mut ffi::lua_State) -> R, { let params = ffi::lua_touserdata(state, -1) as *mut Params; ffi::lua_pop(state, 1); (*params).result.init = ((*params).function)(state); if (*params).nresults == ffi::LUA_MULTRET { ffi::lua_gettop(state) } else { (*params).nresults } } let stack_start = ffi::lua_gettop(state) - nargs; ffi::lua_pushcfunction(state, error_traceback); ffi::lua_pushcfunction(state, do_call::); if nargs > 0 { ffi::lua_rotate(state, stack_start + 1, 2); } let mut params = Params { function: f, result: URes { uninit: () }, nresults, }; ffi::lua_pushlightuserdata(state, &mut params as *mut Params as *mut c_void); let ret = ffi::lua_pcall(state, nargs + 1, nresults, stack_start + 1); ffi::lua_remove(state, stack_start + 1); if ret == ffi::LUA_OK { // LUA_OK is only returned when the do_call function has completed successfully, so // params.result is definitely initialized. Ok(params.result.init) } else { Err(pop_error(state, ret)) } } // Pops an error off of the stack and returns it. The specific behavior depends on the type of the // error at the top of the stack: // 1) If the error is actually a WrappedPanic, this will continue the panic. // 2) If the error on the top of the stack is actually a WrappedError, just returns it. // 3) Otherwise, interprets the error as the appropriate lua error. // Uses 2 stack spaces, does not call lua_checkstack. pub unsafe fn pop_error(state: *mut ffi::lua_State, err_code: c_int) -> Error { mlua_debug_assert!( err_code != ffi::LUA_OK && err_code != ffi::LUA_YIELD, "pop_error called with non-error return code" ); if let Some(err) = get_wrapped_error(state, -1).as_ref() { ffi::lua_pop(state, 1); err.clone() } else if let Some(panic) = get_gc_userdata::(state, -1).as_mut() { if let Some(p) = (*panic).0.take() { resume_unwind(p); } else { Error::PreviouslyResumedPanic } } else { let err_string = to_string(state, -1).into_owned(); ffi::lua_pop(state, 1); match err_code { ffi::LUA_ERRRUN => Error::RuntimeError(err_string), ffi::LUA_ERRSYNTAX => { Error::SyntaxError { // This seems terrible, but as far as I can tell, this is exactly what the // stock Lua REPL does. incomplete_input: err_string.ends_with("") || err_string.ends_with("''"), message: err_string, } } ffi::LUA_ERRERR => { // This error is raised when the error handler raises an error too many times // recursively, and continuing to trigger the error handler would cause a stack // overflow. It is not very useful to differentiate between this and "ordinary" // runtime errors, so we handle them the same way. Error::RuntimeError(err_string) } ffi::LUA_ERRMEM => Error::MemoryError(err_string), #[cfg(any(feature = "lua53", feature = "lua52"))] ffi::LUA_ERRGCMM => Error::GarbageCollectorError(err_string), _ => mlua_panic!("unrecognized lua error code"), } } } // Internally uses 4 stack spaces, does not call checkstack pub unsafe fn push_string>( state: *mut ffi::lua_State, s: &S, ) -> Result<()> { protect_lua_closure(state, 0, 1, |state| { let s = s.as_ref(); ffi::lua_pushlstring(state, s.as_ptr() as *const c_char, s.len()); }) } // Internally uses 4 stack spaces, does not call checkstack pub unsafe fn push_userdata(state: *mut ffi::lua_State, t: T) -> Result<()> { let ud = protect_lua_closure(state, 0, 1, move |state| { ffi::lua_newuserdata(state, mem::size_of::()) as *mut T })?; ptr::write(ud, t); Ok(()) } pub unsafe fn get_userdata(state: *mut ffi::lua_State, index: c_int) -> *mut T { let ud = ffi::lua_touserdata(state, index) as *mut T; mlua_debug_assert!(!ud.is_null(), "userdata pointer is null"); ud } // Pops the userdata off of the top of the stack and returns it to rust, invalidating the lua // userdata and gives it the special "destructed" userdata metatable. Userdata must not have been // previously invalidated, and this method does not check for this. Uses 1 extra stack space and // does not call checkstack pub unsafe fn take_userdata(state: *mut ffi::lua_State) -> T { // We set the metatable of userdata on __gc to a special table with no __gc method and with // metamethods that trigger an error on access. We do this so that it will not be double // dropped, and also so that it cannot be used or identified as any particular userdata type // after the first call to __gc. get_destructed_userdata_metatable(state); ffi::lua_setmetatable(state, -2); let ud = ffi::lua_touserdata(state, -1) as *mut T; mlua_debug_assert!(!ud.is_null(), "userdata pointer is null"); ffi::lua_pop(state, 1); ptr::read(ud) } // Pushes the userdata and attaches a metatable with __gc method // Internally uses 5 stack spaces, does not call checkstack pub unsafe fn push_gc_userdata(state: *mut ffi::lua_State, t: T) -> Result<()> { push_meta_gc_userdata::(state, t) } pub unsafe fn push_meta_gc_userdata(state: *mut ffi::lua_State, t: T) -> Result<()> { let ud = protect_lua_closure(state, 0, 1, move |state| { ffi::lua_newuserdata(state, mem::size_of::()) as *mut T })?; ptr::write(ud, t); get_gc_metatable_for::(state); ffi::lua_setmetatable(state, -2); Ok(()) } // Uses 2 stack spaces, does not call checkstack pub unsafe fn get_gc_userdata(state: *mut ffi::lua_State, index: c_int) -> *mut T { let ud = ffi::lua_touserdata(state, index) as *mut T; if ud.is_null() || ffi::lua_getmetatable(state, index) == 0 { return ptr::null_mut(); } get_gc_metatable_for::(state); let res = ffi::lua_rawequal(state, -1, -2) != 0; ffi::lua_pop(state, 2); if !res { return ptr::null_mut(); } ud } // Populates the given table with the appropriate members to be a userdata metatable for the given // type. This function takes the given table at the `metatable` index, and adds an appropriate __gc // member to it for the given type and a __metatable entry to protect the table from script access. // The function also, if given a `members` table index, will set up an __index metamethod to return // the appropriate member on __index. Additionally, if there is already an __index entry on the // given metatable, instead of simply overwriting the __index, instead the created __index method // will capture the previous one, and use it as a fallback only if the given key is not found in the // provided members table. Internally uses 6 stack spaces and does not call checkstack. pub unsafe fn init_userdata_metatable( state: *mut ffi::lua_State, metatable: c_int, members: Option, ) -> Result<()> { // Used if both an __index metamethod is set and regular methods, checks methods table // first, then __index metamethod. unsafe extern "C" fn meta_index_impl(state: *mut ffi::lua_State) -> c_int { ffi::luaL_checkstack(state, 2, ptr::null()); ffi::lua_pushvalue(state, -1); ffi::lua_gettable(state, ffi::lua_upvalueindex(2)); if ffi::lua_isnil(state, -1) == 0 { ffi::lua_insert(state, -3); ffi::lua_pop(state, 2); 1 } else { ffi::lua_pop(state, 1); ffi::lua_pushvalue(state, ffi::lua_upvalueindex(1)); ffi::lua_insert(state, -3); ffi::lua_call(state, 2, 1); 1 } } let members = members.map(|i| ffi::lua_absindex(state, i)); ffi::lua_pushvalue(state, metatable); if let Some(members) = members { push_string(state, "__index")?; ffi::lua_pushvalue(state, -1); let index_type = ffi::lua_rawget(state, -3); if index_type == ffi::LUA_TNIL { ffi::lua_pop(state, 1); ffi::lua_pushvalue(state, members); } else if index_type == ffi::LUA_TFUNCTION { ffi::lua_pushvalue(state, members); protect_lua_closure(state, 2, 1, |state| { ffi::lua_pushcclosure(state, meta_index_impl, 2); })?; } else { mlua_panic!("improper __index type {}", index_type); } protect_lua_closure(state, 3, 1, |state| { ffi::lua_rawset(state, -3); })?; } push_string(state, "__gc")?; ffi::lua_pushcfunction(state, userdata_destructor::); protect_lua_closure(state, 3, 1, |state| { ffi::lua_rawset(state, -3); })?; push_string(state, "__metatable")?; ffi::lua_pushboolean(state, 0); protect_lua_closure(state, 3, 1, |state| { ffi::lua_rawset(state, -3); })?; ffi::lua_pop(state, 1); Ok(()) } pub unsafe extern "C" fn userdata_destructor(state: *mut ffi::lua_State) -> c_int { callback_error(state, |_| { check_stack(state, 1)?; take_userdata::(state); Ok(0) }) } // In the context of a lua callback, this will call the given function and if the given function // returns an error, *or if the given function panics*, this will result in a call to lua_error (a // longjmp). The error or panic is wrapped in such a way that when calling pop_error back on // the rust side, it will resume the panic. // // This function assumes the structure of the stack at the beginning of a callback, that the only // elements on the stack are the arguments to the callback. // // This function uses some of the bottom of the stack for error handling, the given callback will be // given the number of arguments available as an argument, and should return the number of returns // as normal, but cannot assume that the arguments available start at 0. pub unsafe fn callback_error(state: *mut ffi::lua_State, f: F) -> R where F: FnOnce(c_int) -> Result, { let nargs = ffi::lua_gettop(state); // We need one extra stack space to store preallocated memory, and at least 3 stack spaces // overall for handling error metatables let extra_stack = if nargs < 3 { 3 - nargs } else { 1 }; ffi::luaL_checkstack( state, extra_stack, cstr!("not enough stack space for callback error handling"), ); // We cannot shadow rust errors with Lua ones, we pre-allocate enough memory to store a wrapped // error or panic *before* we proceed. let ud = ffi::lua_newuserdata( state, mem::size_of::().max(mem::size_of::()), ); ffi::lua_rotate(state, 1, 1); match catch_unwind(AssertUnwindSafe(|| f(nargs))) { Ok(Ok(r)) => { ffi::lua_remove(state, 1); r } Ok(Err(err)) => { ffi::lua_settop(state, 1); ptr::write(ud as *mut WrappedError, WrappedError(err)); get_gc_metatable_for::(state); ffi::lua_setmetatable(state, -2); ffi::lua_error(state) } Err(p) => { ffi::lua_settop(state, 1); ptr::write(ud as *mut WrappedPanic, WrappedPanic(Some(p))); get_gc_metatable_for::(state); ffi::lua_setmetatable(state, -2); ffi::lua_error(state) } } } // Takes an error at the top of the stack, and if it is a WrappedError, converts it to an // Error::CallbackError with a traceback, if it is some lua type, prints the error along with a // traceback, and if it is a WrappedPanic, does not modify it. This function does its best to avoid // triggering another error and shadowing previous rust errors, but it may trigger Lua errors that // shadow rust errors under certain memory conditions. This function ensures that such behavior // will *never* occur with a rust panic, however. pub unsafe extern "C" fn error_traceback(state: *mut ffi::lua_State) -> c_int { // I believe luaL_traceback requires this much free stack to not error. const LUA_TRACEBACK_STACK: c_int = 11; if ffi::lua_checkstack(state, 2) == 0 { // If we don't have enough stack space to even check the error type, do nothing so we don't // risk shadowing a rust panic. } else if let Some(error) = get_wrapped_error(state, -1).as_ref() { // lua_newuserdata and luaL_traceback may error, but nothing that implements Drop should be // on the rust stack at this time. let ud = ffi::lua_newuserdata(state, mem::size_of::()) as *mut WrappedError; let traceback = if ffi::lua_checkstack(state, LUA_TRACEBACK_STACK) != 0 { ffi::luaL_traceback(state, state, ptr::null(), 0); let traceback = to_string(state, -1).into_owned(); ffi::lua_pop(state, 1); traceback } else { "".to_owned() }; let error = error.clone(); ffi::lua_remove(state, -2); ptr::write( ud, WrappedError(Error::CallbackError { traceback, cause: Arc::new(error), }), ); get_gc_metatable_for::(state); ffi::lua_setmetatable(state, -2); } else if get_gc_userdata::(state, -1).is_null() && ffi::lua_checkstack(state, LUA_TRACEBACK_STACK) != 0 { let s = ffi::luaL_tolstring(state, -1, ptr::null_mut()); ffi::luaL_traceback(state, state, s, 0); ffi::lua_remove(state, -2); } 1 } // Does not call lua_checkstack, uses 1 stack space. pub unsafe fn get_main_state(state: *mut ffi::lua_State) -> Option<*mut ffi::lua_State> { #[cfg(any(feature = "lua54", feature = "lua53", feature = "lua52"))] { ffi::lua_rawgeti(state, ffi::LUA_REGISTRYINDEX, ffi::LUA_RIDX_MAINTHREAD); let main_state = ffi::lua_tothread(state, -1); ffi::lua_pop(state, 1); Some(main_state) } #[cfg(any(feature = "lua51", feature = "luajit"))] { // Check the current state first let is_main_state = ffi::lua_pushthread(state) == 1; ffi::lua_pop(state, 1); if is_main_state { Some(state) } else { None } } } // Pushes a WrappedError to the top of the stack. Uses two stack spaces and does not call // lua_checkstack. pub unsafe fn push_wrapped_error(state: *mut ffi::lua_State, err: Error) -> Result<()> { push_gc_userdata::(state, WrappedError(err)) } // Checks if the value at the given index is a WrappedError, and if it is returns a pointer to it, // otherwise returns null. Uses 2 stack spaces and does not call lua_checkstack. pub unsafe fn get_wrapped_error(state: *mut ffi::lua_State, index: c_int) -> *const Error { let ud = get_gc_userdata::(state, index); if ud.is_null() { return ptr::null(); } &(*ud).0 } // Initialize the internal (with __gc) metatable for a type T pub unsafe fn init_gc_metatable_for( state: *mut ffi::lua_State, customize_fn: Option, ) { let type_id = TypeId::of::(); let ref_addr = { let mut mt_cache = mlua_expect!(METATABLE_CACHE.lock(), "cannot lock metatable cache"); mlua_assert!( mt_cache.capacity() - mt_cache.len() > 0, "out of metatable cache capacity" ); mt_cache.insert(type_id, 0); &mt_cache[&type_id] as *const u8 }; ffi::lua_newtable(state); ffi::lua_pushstring(state, cstr!("__gc")); ffi::lua_pushcfunction(state, userdata_destructor::); ffi::lua_rawset(state, -3); ffi::lua_pushstring(state, cstr!("__metatable")); ffi::lua_pushboolean(state, 0); ffi::lua_rawset(state, -3); if let Some(f) = customize_fn { f(state) } ffi::lua_rawsetp(state, ffi::LUA_REGISTRYINDEX, ref_addr as *mut c_void); } pub unsafe fn get_gc_metatable_for(state: *mut ffi::lua_State) { let type_id = TypeId::of::(); let ref_addr = { let mt_cache = mlua_expect!(METATABLE_CACHE.lock(), "cannot lock metatable cache"); mlua_expect!(mt_cache.get(&type_id), "gc metatable does not exist") as *const u8 }; ffi::lua_rawgetp(state, ffi::LUA_REGISTRYINDEX, ref_addr as *mut c_void); } // Initialize the error, panic, and destructed userdata metatables. pub unsafe fn init_error_registry(state: *mut ffi::lua_State) { assert_stack(state, 8); // Create error and panic metatables unsafe extern "C" fn error_tostring(state: *mut ffi::lua_State) -> c_int { let err_buf = callback_error(state, |_| { check_stack(state, 3)?; if let Some(error) = get_wrapped_error(state, -1).as_ref() { ffi::lua_pushlightuserdata( state, &ERROR_PRINT_BUFFER_KEY as *const u8 as *mut c_void, ); ffi::lua_rawget(state, ffi::LUA_REGISTRYINDEX); let err_buf = ffi::lua_touserdata(state, -1) as *mut String; ffi::lua_pop(state, 2); (*err_buf).clear(); // Depending on how the API is used and what error types scripts are given, it may // be possible to make this consume arbitrary amounts of memory (for example, some // kind of recursive error structure?) let _ = write!(&mut (*err_buf), "{}", error); Ok(err_buf) } else if let Some(panic) = get_gc_userdata::(state, -1).as_ref() { if let Some(ref p) = (*panic).0 { let err_buf_key = &ERROR_PRINT_BUFFER_KEY as *const u8 as *const c_void; ffi::lua_rawgetp(state, ffi::LUA_REGISTRYINDEX, err_buf_key); let err_buf = ffi::lua_touserdata(state, -1) as *mut String; (*err_buf).clear(); ffi::lua_pop(state, 2); if let Some(msg) = p.downcast_ref::<&str>() { let _ = write!(&mut (*err_buf), "{}", msg); } else if let Some(msg) = p.downcast_ref::() { let _ = write!(&mut (*err_buf), "{}", msg); } else { let _ = write!(&mut (*err_buf), ""); }; Ok(err_buf) } else { Err(Error::PreviouslyResumedPanic) } } else { // I'm not sure whether this is possible to trigger without bugs in mlua? Err(Error::UserDataTypeMismatch) } }); ffi::lua_pushlstring( state, (*err_buf).as_ptr() as *const c_char, (*err_buf).len(), ); (*err_buf).clear(); 1 } init_gc_metatable_for::( state, Some(|state| { ffi::lua_pushstring(state, cstr!("__tostring")); ffi::lua_pushcfunction(state, error_tostring); ffi::lua_rawset(state, -3); }), ); init_gc_metatable_for::( state, Some(|state| { ffi::lua_pushstring(state, cstr!("__tostring")); ffi::lua_pushcfunction(state, error_tostring); ffi::lua_rawset(state, -3); }), ); // Create destructed userdata metatable unsafe extern "C" fn destructed_error(state: *mut ffi::lua_State) -> c_int { ffi::luaL_checkstack(state, 2, ptr::null()); let ud = ffi::lua_newuserdata(state, mem::size_of::()) as *mut WrappedError; ptr::write(ud, WrappedError(Error::CallbackDestructed)); get_gc_metatable_for::(state); ffi::lua_setmetatable(state, -2); ffi::lua_error(state) } ffi::lua_pushlightuserdata( state, &DESTRUCTED_USERDATA_METATABLE as *const u8 as *mut c_void, ); ffi::lua_newtable(state); for &method in &[ cstr!("__add"), cstr!("__sub"), cstr!("__mul"), cstr!("__div"), cstr!("__mod"), cstr!("__pow"), cstr!("__unm"), #[cfg(any(feature = "lua54", feature = "lua53"))] cstr!("__idiv"), #[cfg(any(feature = "lua54", feature = "lua53"))] cstr!("__band"), #[cfg(any(feature = "lua54", feature = "lua53"))] cstr!("__bor"), #[cfg(any(feature = "lua54", feature = "lua53"))] cstr!("__bxor"), #[cfg(any(feature = "lua54", feature = "lua53"))] cstr!("__bnot"), #[cfg(any(feature = "lua54", feature = "lua53"))] cstr!("__shl"), #[cfg(any(feature = "lua54", feature = "lua53"))] cstr!("__shr"), cstr!("__concat"), cstr!("__len"), cstr!("__eq"), cstr!("__lt"), cstr!("__le"), cstr!("__index"), cstr!("__newindex"), cstr!("__call"), cstr!("__tostring"), #[cfg(any(feature = "lua54", feature = "lua53", feature = "lua52"))] cstr!("__pairs"), #[cfg(any(feature = "lua53", feature = "lua52"))] cstr!("__ipairs"), #[cfg(feature = "lua54")] cstr!("__close"), ] { ffi::lua_pushstring(state, method); ffi::lua_pushcfunction(state, destructed_error); ffi::lua_rawset(state, -3); } ffi::lua_rawset(state, ffi::LUA_REGISTRYINDEX); // Create error print buffer ffi::lua_pushlightuserdata(state, &ERROR_PRINT_BUFFER_KEY as *const u8 as *mut c_void); let ud = ffi::lua_newuserdata(state, mem::size_of::()) as *mut String; ptr::write(ud, String::new()); ffi::lua_newtable(state); ffi::lua_pushstring(state, cstr!("__gc")); ffi::lua_pushcfunction(state, userdata_destructor::); ffi::lua_rawset(state, -3); ffi::lua_setmetatable(state, -2); ffi::lua_rawset(state, ffi::LUA_REGISTRYINDEX); } struct WrappedError(pub Error); pub(crate) struct WrappedPanic(pub Option>); // Converts the given lua value to a string in a reasonable format without causing a Lua error or // panicking. unsafe fn to_string<'a>(state: *mut ffi::lua_State, index: c_int) -> Cow<'a, str> { match ffi::lua_type(state, index) { ffi::LUA_TNONE => "".into(), ffi::LUA_TNIL => "".into(), ffi::LUA_TBOOLEAN => (ffi::lua_toboolean(state, index) != 1).to_string().into(), ffi::LUA_TLIGHTUSERDATA => { format!("", ffi::lua_topointer(state, index)).into() } ffi::LUA_TNUMBER => { let mut isint = 0; let i = ffi::lua_tointegerx(state, -1, &mut isint); if isint == 0 { ffi::lua_tonumber(state, index).to_string().into() } else { i.to_string().into() } } ffi::LUA_TSTRING => { let mut size = 0; let data = ffi::lua_tolstring(state, index, &mut size); String::from_utf8_lossy(slice::from_raw_parts(data as *const u8, size)) } ffi::LUA_TTABLE => format!("", ffi::lua_topointer(state, index)).into(), ffi::LUA_TFUNCTION => format!("", ffi::lua_topointer(state, index)).into(), ffi::LUA_TUSERDATA => format!("", ffi::lua_topointer(state, index)).into(), ffi::LUA_TTHREAD => format!("", ffi::lua_topointer(state, index)).into(), _ => "".into(), } } pub(crate) unsafe fn get_destructed_userdata_metatable(state: *mut ffi::lua_State) { ffi::lua_pushlightuserdata( state, &DESTRUCTED_USERDATA_METATABLE as *const u8 as *mut c_void, ); ffi::lua_rawget(state, ffi::LUA_REGISTRYINDEX); } static DESTRUCTED_USERDATA_METATABLE: u8 = 0; static ERROR_PRINT_BUFFER_KEY: u8 = 0;