#![cfg(feature = "luau")] use std::env; use std::fs; use std::sync::atomic::{AtomicU64, Ordering}; use std::sync::Arc; use mlua::{Compiler, CoverageInfo, Error, Lua, Result, Table, ThreadStatus, Value, VmState}; #[test] fn test_require() -> Result<()> { let lua = Lua::new(); let temp_dir = tempfile::tempdir().unwrap(); fs::write( temp_dir.path().join("module.luau"), r#" counter = counter or 0 return counter + 1 "#, )?; env::set_var("LUAU_PATH", temp_dir.path().join("?.luau")); lua.load( r#" local module = require("module") assert(module == 1) module = require("module") assert(module == 1) "#, ) .exec() } #[test] fn test_vectors() -> Result<()> { let lua = Lua::new(); let v: [f32; 3] = lua.load("vector(1, 2, 3) + vector(3, 2, 1)").eval()?; assert_eq!(v, [4.0, 4.0, 4.0]); // Test vector methods lua.load( r#" local v = vector(1, 2, 3) assert(v.x == 1) assert(v.y == 2) assert(v.z == 3) "#, ) .exec()?; // Test vector methods (fastcall) lua.load( r#" local v = vector(1, 2, 3) assert(v.x == 1) assert(v.y == 2) assert(v.z == 3) "#, ) .set_compiler(Compiler::new().set_vector_ctor(Some("vector".to_string()))) .exec()?; Ok(()) } #[test] fn test_readonly_table() -> Result<()> { let lua = Lua::new(); let t = lua.create_table()?; assert!(!t.is_readonly()); t.set_readonly(true); assert!(t.is_readonly()); match t.set("key", "value") { Err(Error::RuntimeError(err)) if err.contains("Attempt to modify a readonly table") => {} r => panic!( "expected RuntimeError(...) with a specific message, got {:?}", r ), }; Ok(()) } #[test] fn test_sandbox() -> Result<()> { let lua = Lua::new(); lua.sandbox(true)?; lua.load("global = 123").exec()?; let n: i32 = lua.load("return global").eval()?; assert_eq!(n, 123); assert_eq!(lua.globals().get::<_, Option>("global")?, Some(123)); // Threads should inherit "main" globals let f = lua.create_function(|lua, ()| lua.globals().get::<_, i32>("global"))?; let co = lua.create_thread(f.clone())?; assert_eq!(co.resume::<_, Option>(())?, Some(123)); // Sandboxed threads should also inherit "main" globals let co = lua.create_thread(f)?; co.sandbox()?; assert_eq!(co.resume::<_, Option>(())?, Some(123)); lua.sandbox(false)?; // Previously set variable `global` should be cleared now assert_eq!(lua.globals().get::<_, Option>("global")?, None); // Readonly flags should be cleared as well let table = lua.globals().get::<_, Table>("table")?; table.set("test", "test")?; Ok(()) } #[test] fn test_sandbox_threads() -> Result<()> { let lua = Lua::new(); let f = lua.create_function(|lua, v: Value| lua.globals().set("global", v))?; let co = lua.create_thread(f.clone())?; co.resume(321)?; // The main state should see the `global` variable (as the thread is not sandboxed) assert_eq!(lua.globals().get::<_, Option>("global")?, Some(321)); let co = lua.create_thread(f.clone())?; co.sandbox()?; co.resume(123)?; // The main state should see the previous `global` value (as the thread is sandboxed) assert_eq!(lua.globals().get::<_, Option>("global")?, Some(321)); // Try to reset the (sandboxed) thread co.reset(f)?; co.resume(111)?; assert_eq!(lua.globals().get::<_, Option>("global")?, Some(111)); Ok(()) } #[test] fn test_interrupts() -> Result<()> { let lua = Lua::new(); let interrupts_count = Arc::new(AtomicU64::new(0)); let interrupts_count2 = interrupts_count.clone(); lua.set_interrupt(move || { interrupts_count2.fetch_add(1, Ordering::Relaxed); Ok(VmState::Continue) }); let f = lua .load( r#" local x = 2 + 3 local y = x * 63 local z = string.len(x..", "..y) "#, ) .into_function()?; f.call(())?; assert!(interrupts_count.load(Ordering::Relaxed) > 0); // // Test yields from interrupt // let yield_count = Arc::new(AtomicU64::new(0)); let yield_count2 = yield_count.clone(); lua.set_interrupt(move || { if yield_count2.fetch_add(1, Ordering::Relaxed) == 1 { return Ok(VmState::Yield); } Ok(VmState::Continue) }); let co = lua.create_thread( lua.load( r#" local a = {1, 2, 3} local b = 0 for _, x in ipairs(a) do b += x end return b "#, ) .into_function()?, )?; co.resume(())?; assert_eq!(co.status(), ThreadStatus::Resumable); let result: i32 = co.resume(())?; assert_eq!(result, 6); assert_eq!(yield_count.load(Ordering::Relaxed), 7); assert_eq!(co.status(), ThreadStatus::Unresumable); // // Test errors in interrupts // lua.set_interrupt(|| Err(Error::RuntimeError("error from interrupt".into()))); match f.call::<_, ()>(()) { Err(Error::CallbackError { cause, .. }) => match *cause { Error::RuntimeError(ref m) if m == "error from interrupt" => {} ref e => panic!("expected RuntimeError with a specific message, got {:?}", e), }, r => panic!("expected CallbackError, got {:?}", r), } lua.remove_interrupt(); Ok(()) } #[test] fn test_coverate() -> Result<()> { let lua = Lua::new(); lua.set_compiler(Compiler::default().set_coverage_level(1)); let f = lua .load( r#"local v = vector(1, 2, 3) assert(v.x == 1 and v.y == 2 and v.z == 3) function abc(i) if i < 5 then return 0 else return 1 end end (function() (function() abc(10) end)() end)() "#, ) .into_function()?; f.call(())?; let mut report = Vec::new(); f.coverage(|cov| { report.push(cov); }); assert_eq!( report[0], CoverageInfo { function: None, line_defined: 1, depth: 0, hits: vec![-1, 1, 1, -1, 1, -1, -1, -1, -1, -1, -1, -1, 1, -1, -1, -1], } ); assert_eq!( report[1], CoverageInfo { function: Some("abc".into()), line_defined: 4, depth: 1, hits: vec![-1, -1, -1, -1, -1, 1, 0, -1, 1, -1, -1, -1, -1, -1, -1, -1], } ); assert_eq!( report[2], CoverageInfo { function: None, line_defined: 12, depth: 1, hits: vec![-1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, 1, -1, -1], } ); assert_eq!( report[3], CoverageInfo { function: None, line_defined: 13, depth: 2, hits: vec![-1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, 1, -1, -1], } ); Ok(()) }