1 //! Oracles. 2 //! 3 //! Oracles take a test case and determine whether we have a bug. For example, 4 //! one of the simplest oracles is to take a Wasm binary as our input test case, 5 //! validate and instantiate it, and (implicitly) check that no assertions 6 //! failed or segfaults happened. A more complicated oracle might compare the 7 //! result of executing a Wasm file with and without optimizations enabled, and 8 //! make sure that the two executions are observably identical. 9 //! 10 //! When an oracle finds a bug, it should report it to the fuzzing engine by 11 //! panicking. 12 13 pub mod component_api; 14 pub mod component_async; 15 #[cfg(feature = "fuzz-spec-interpreter")] 16 pub mod diff_spec; 17 pub mod diff_wasmi; 18 pub mod diff_wasmtime; 19 pub mod dummy; 20 pub mod engine; 21 pub mod memory; 22 mod stacks; 23 24 use self::diff_wasmtime::WasmtimeInstance; 25 use self::engine::{DiffEngine, DiffInstance}; 26 use crate::generators::ExceptionOps; 27 use crate::generators::GcOps; 28 use crate::generators::{self, CompilerStrategy, DiffValue, DiffValueType}; 29 use crate::single_module_fuzzer::KnownValid; 30 use crate::{YieldN, block_on}; 31 use arbitrary::Arbitrary; 32 pub use stacks::check_stacks; 33 use std::future::Future; 34 use std::pin::Pin; 35 use std::sync::atomic::{AtomicBool, AtomicUsize, Ordering::SeqCst}; 36 use std::sync::{Arc, Condvar, Mutex}; 37 use std::task::{Context, Poll}; 38 use std::time::{Duration, Instant}; 39 use wasmtime::*; 40 use wasmtime_wast::WastContext; 41 42 #[cfg(not(any(windows, target_arch = "s390x", target_arch = "riscv64")))] 43 mod diff_v8; 44 45 static CNT: AtomicUsize = AtomicUsize::new(0); 46 47 /// Logs a wasm file to the filesystem to make it easy to figure out what wasm 48 /// was used when debugging. 49 pub fn log_wasm(wasm: &[u8]) { 50 super::init_fuzzing(); 51 52 if !log::log_enabled!(log::Level::Debug) { 53 return; 54 } 55 56 let i = CNT.fetch_add(1, SeqCst); 57 let name = format!("testcase{i}.wasm"); 58 std::fs::write(&name, wasm).expect("failed to write wasm file"); 59 log::debug!("wrote wasm file to `{name}`"); 60 let wat = format!("testcase{i}.wat"); 61 match wasmprinter::print_bytes(wasm) { 62 Ok(s) => { 63 std::fs::write(&wat, s).expect("failed to write wat file"); 64 log::debug!("wrote wat file to `{wat}`"); 65 } 66 // If wasmprinter failed remove a `*.wat` file, if any, to avoid 67 // confusing a preexisting one with this wasm which failed to get 68 // printed. 69 Err(e) => { 70 log::debug!("failed to print to wat: {e}"); 71 drop(std::fs::remove_file(&wat)); 72 } 73 } 74 } 75 76 /// The `T` in `Store<T>` for fuzzing stores, used to limit resource 77 /// consumption during fuzzing. 78 #[derive(Clone)] 79 pub struct StoreLimits(Arc<LimitsState>); 80 81 struct LimitsState { 82 /// Remaining memory, in bytes, left to allocate 83 remaining_memory: AtomicUsize, 84 /// Remaining amount of memory that's allowed to be copied via a growth. 85 remaining_copy_allowance: AtomicUsize, 86 /// Whether or not an allocation request has been denied 87 oom: AtomicBool, 88 } 89 90 /// Allow up to 1G which is well below the 2G limit on OSS-Fuzz and should allow 91 /// most interesting behavior. 92 const MAX_MEMORY: usize = 1 << 30; 93 94 /// Allow up to 4G of bytes to be copied (conservatively) which should enable 95 /// growth up to `MAX_MEMORY` or at least up to a relatively large amount. 96 const MAX_MEMORY_MOVED: usize = 4 << 30; 97 98 impl StoreLimits { 99 /// Creates the default set of limits for all fuzzing stores. 100 pub fn new() -> StoreLimits { 101 StoreLimits(Arc::new(LimitsState { 102 remaining_memory: AtomicUsize::new(MAX_MEMORY), 103 remaining_copy_allowance: AtomicUsize::new(MAX_MEMORY_MOVED), 104 oom: AtomicBool::new(false), 105 })) 106 } 107 108 fn alloc(&mut self, amt: usize) -> bool { 109 log::trace!("alloc {amt:#x} bytes"); 110 111 // Assume that on each allocation of memory that all previous 112 // allocations of memory are moved. This is pretty coarse but is used to 113 // help prevent against fuzz test cases that just move tons of bytes 114 // around continuously. This assumes that all previous memory was 115 // allocated in a single linear memory and growing by `amt` will require 116 // moving all the bytes to a new location. This isn't actually required 117 // all the time nor does it accurately reflect what happens all the 118 // time, but it's a coarse approximation that should be "good enough" 119 // for allowing interesting fuzz behaviors to happen while not timing 120 // out just copying bytes around. 121 let prev_size = MAX_MEMORY - self.0.remaining_memory.load(SeqCst); 122 if self 123 .0 124 .remaining_copy_allowance 125 .fetch_update(SeqCst, SeqCst, |remaining| remaining.checked_sub(prev_size)) 126 .is_err() 127 { 128 self.0.oom.store(true, SeqCst); 129 log::debug!("-> too many bytes moved, rejecting allocation"); 130 return false; 131 } 132 133 // If we're allowed to move the bytes, then also check if we're allowed 134 // to actually have this much residence at once. 135 match self 136 .0 137 .remaining_memory 138 .fetch_update(SeqCst, SeqCst, |remaining| remaining.checked_sub(amt)) 139 { 140 Ok(_) => true, 141 Err(_) => { 142 self.0.oom.store(true, SeqCst); 143 log::debug!("-> OOM hit"); 144 false 145 } 146 } 147 } 148 149 fn is_oom(&self) -> bool { 150 self.0.oom.load(SeqCst) 151 } 152 } 153 154 impl ResourceLimiter for StoreLimits { 155 fn memory_growing( 156 &mut self, 157 current: usize, 158 desired: usize, 159 _maximum: Option<usize>, 160 ) -> Result<bool> { 161 Ok(self.alloc(desired - current)) 162 } 163 164 fn table_growing( 165 &mut self, 166 current: usize, 167 desired: usize, 168 _maximum: Option<usize>, 169 ) -> Result<bool> { 170 let delta = (desired - current).saturating_mul(std::mem::size_of::<usize>()); 171 Ok(self.alloc(delta)) 172 } 173 } 174 175 /// Methods of timing out execution of a WebAssembly module 176 #[derive(Clone, Debug)] 177 pub enum Timeout { 178 /// No timeout is used, it should be guaranteed via some other means that 179 /// the input does not infinite loop. 180 None, 181 /// Fuel-based timeouts are used where the specified fuel is all that the 182 /// provided wasm module is allowed to consume. 183 Fuel(u64), 184 /// An epoch-interruption-based timeout is used with a sleeping 185 /// thread bumping the epoch counter after the specified duration. 186 Epoch(Duration), 187 } 188 189 /// Instantiate the Wasm buffer, and implicitly fail if we have an unexpected 190 /// panic or segfault or anything else that can be detected "passively". 191 /// 192 /// The engine will be configured using provided config. 193 pub fn instantiate( 194 wasm: &[u8], 195 known_valid: KnownValid, 196 config: &generators::Config, 197 timeout: Timeout, 198 ) { 199 let mut store = config.to_store(); 200 201 let module = match compile_module(store.engine(), wasm, known_valid, config) { 202 Some(module) => module, 203 None => return, 204 }; 205 206 let mut timeout_state = HelperThread::default(); 207 match timeout { 208 Timeout::Fuel(fuel) => store.set_fuel(fuel).unwrap(), 209 210 // If a timeout is requested then we spawn a helper thread to wait for 211 // the requested time and then send us a signal to get interrupted. We 212 // also arrange for the thread's sleep to get interrupted if we return 213 // early (or the wasm returns within the time limit), which allows the 214 // thread to get torn down. 215 // 216 // This prevents us from creating a huge number of sleeping threads if 217 // this function is executed in a loop, like it does on nightly fuzzing 218 // infrastructure. 219 Timeout::Epoch(timeout) => { 220 let engine = store.engine().clone(); 221 timeout_state.run_periodically(timeout, move || engine.increment_epoch()); 222 } 223 Timeout::None => {} 224 } 225 226 instantiate_with_dummy(&mut store, &module); 227 } 228 229 /// Represents supported commands to the `instantiate_many` function. 230 #[derive(Arbitrary, Debug)] 231 pub enum Command { 232 /// Instantiates a module. 233 /// 234 /// The value is the index of the module to instantiate. 235 /// 236 /// The module instantiated will be this value modulo the number of modules provided to `instantiate_many`. 237 Instantiate(usize), 238 /// Terminates a "running" instance. 239 /// 240 /// The value is the index of the instance to terminate. 241 /// 242 /// The instance terminated will be this value modulo the number of currently running 243 /// instances. 244 /// 245 /// If no instances are running, the command will be ignored. 246 Terminate(usize), 247 } 248 249 /// Instantiates many instances from the given modules. 250 /// 251 /// The engine will be configured using the provided config. 252 /// 253 /// The modules are expected to *not* have start functions as no timeouts are configured. 254 pub fn instantiate_many( 255 modules: &[Vec<u8>], 256 known_valid: KnownValid, 257 config: &generators::Config, 258 commands: &[Command], 259 ) { 260 log::debug!("instantiate_many: {commands:#?}"); 261 262 assert!(!config.module_config.config.allow_start_export); 263 264 let engine = Engine::new(&config.to_wasmtime()).unwrap(); 265 266 let modules = modules 267 .iter() 268 .enumerate() 269 .filter_map( 270 |(i, bytes)| match compile_module(&engine, bytes, known_valid, config) { 271 Some(m) => { 272 log::debug!("successfully compiled module {i}"); 273 Some(m) 274 } 275 None => { 276 log::debug!("failed to compile module {i}"); 277 None 278 } 279 }, 280 ) 281 .collect::<Vec<_>>(); 282 283 // If no modules were valid, we're done 284 if modules.is_empty() { 285 return; 286 } 287 288 // This stores every `Store` where a successful instantiation takes place 289 let mut stores = Vec::new(); 290 let limits = StoreLimits::new(); 291 292 for command in commands { 293 match command { 294 Command::Instantiate(index) => { 295 let index = *index % modules.len(); 296 log::info!("instantiating {index}"); 297 let module = &modules[index]; 298 let mut store = Store::new(&engine, limits.clone()); 299 config.configure_store(&mut store); 300 301 if instantiate_with_dummy(&mut store, module).is_some() { 302 stores.push(Some(store)); 303 } else { 304 log::warn!("instantiation failed"); 305 } 306 } 307 Command::Terminate(index) => { 308 if stores.is_empty() { 309 continue; 310 } 311 let index = *index % stores.len(); 312 313 log::info!("dropping {index}"); 314 stores.swap_remove(index); 315 } 316 } 317 } 318 } 319 320 fn compile_module( 321 engine: &Engine, 322 bytes: &[u8], 323 known_valid: KnownValid, 324 config: &generators::Config, 325 ) -> Option<Module> { 326 log_wasm(bytes); 327 328 match config.compile(engine, bytes) { 329 Ok(module) => Some(module), 330 Err(_) if known_valid == KnownValid::No => None, 331 Err(e) => { 332 if let generators::InstanceAllocationStrategy::Pooling(c) = &config.wasmtime.strategy { 333 // When using the pooling allocator, accept failures to compile 334 // when arbitrary table element limits have been exceeded as 335 // there is currently no way to constrain the generated module 336 // table types. 337 let string = format!("{e:?}"); 338 if string.contains("minimum element size") { 339 return None; 340 } 341 342 // Allow modules-failing-to-compile which exceed the requested 343 // size for each instance. This is something that is difficult 344 // to control and ensure it always succeeds, so we simply have a 345 // "random" instance size limit and if a module doesn't fit we 346 // move on to the next fuzz input. 347 if string.contains("instance allocation for this module requires") { 348 return None; 349 } 350 351 // If the pooling allocator is more restrictive on the number of 352 // tables and memories than we allowed wasm-smith to generate 353 // then allow compilation errors along those lines. 354 if c.max_tables_per_module < (config.module_config.config.max_tables as u32) 355 && string.contains("defined tables count") 356 && string.contains("exceeds the per-instance limit") 357 { 358 return None; 359 } 360 361 if c.max_memories_per_module < (config.module_config.config.max_memories as u32) 362 && string.contains("defined memories count") 363 && string.contains("exceeds the per-instance limit") 364 { 365 return None; 366 } 367 } 368 369 panic!("failed to compile module: {e:?}"); 370 } 371 } 372 } 373 374 /// Create a Wasmtime [`Instance`] from a [`Module`] and fill in all imports 375 /// with dummy values (e.g., zeroed values, immediately-trapping functions). 376 /// Also, this function catches certain fuzz-related instantiation failures and 377 /// returns `None` instead of panicking. 378 /// 379 /// TODO: we should implement tracing versions of these dummy imports that 380 /// record a trace of the order that imported functions were called in and with 381 /// what values. Like the results of exported functions, calls to imports should 382 /// also yield the same values for each configuration, and we should assert 383 /// that. 384 pub fn instantiate_with_dummy(store: &mut Store<StoreLimits>, module: &Module) -> Option<Instance> { 385 // Creation of imports can fail due to resource limit constraints, and then 386 // instantiation can naturally fail for a number of reasons as well. Bundle 387 // the two steps together to match on the error below. 388 let linker = dummy::dummy_linker(store, module); 389 if let Err(e) = &linker { 390 log::warn!("failed to create dummy linker: {e:?}"); 391 } 392 let instance = linker.and_then(|l| l.instantiate(&mut *store, module)); 393 unwrap_instance(store, instance) 394 } 395 396 fn unwrap_instance( 397 store: &Store<StoreLimits>, 398 instance: wasmtime::Result<Instance>, 399 ) -> Option<Instance> { 400 let e = match instance { 401 Ok(i) => return Some(i), 402 Err(e) => e, 403 }; 404 405 log::debug!("failed to instantiate: {e:?}"); 406 407 // If the instantiation hit OOM for some reason then that's ok, it's 408 // expected that fuzz-generated programs try to allocate lots of 409 // stuff. 410 if store.data().is_oom() { 411 return None; 412 } 413 414 // Allow traps which can happen normally with `unreachable` or a timeout or 415 // such. 416 if e.is::<Trap>() 417 // Also allow failures to instantiate as a result of hitting pooling 418 // limits. 419 || e.is::<wasmtime::PoolConcurrencyLimitError>() 420 // And GC heap OOMs. 421 || e.is::<wasmtime::GcHeapOutOfMemory<()>>() 422 // And thrown exceptions. 423 || e.is::<wasmtime::ThrownException>() 424 { 425 return None; 426 } 427 428 let string = e.to_string(); 429 430 // Currently we instantiate with a `Linker` which can't instantiate 431 // every single module under the sun due to using name-based resolution 432 // rather than positional-based resolution 433 if string.contains("incompatible import type") { 434 return None; 435 } 436 437 // Everything else should be a bug in the fuzzer or a bug in wasmtime 438 panic!("failed to instantiate: {e:?}"); 439 } 440 441 /// Evaluate the function identified by `name` in two different engine 442 /// instances--`lhs` and `rhs`. 443 /// 444 /// Returns `Ok(true)` if more evaluations can happen or `Ok(false)` if the 445 /// instances may have drifted apart and no more evaluations can happen. 446 /// 447 /// # Panics 448 /// 449 /// This will panic if the evaluation is different between engines (e.g., 450 /// results are different, hashed instance is different, one side traps, etc.). 451 pub fn differential( 452 lhs: &mut dyn DiffInstance, 453 lhs_engine: &dyn DiffEngine, 454 rhs: &mut WasmtimeInstance, 455 name: &str, 456 args: &[DiffValue], 457 result_tys: &[DiffValueType], 458 ) -> wasmtime::Result<bool> { 459 log::debug!("Evaluating: `{name}` with {args:?}"); 460 let lhs_results = match lhs.evaluate(name, args, result_tys) { 461 Ok(Some(results)) => Ok(results), 462 Err(e) => Err(e), 463 // this engine couldn't execute this type signature, so discard this 464 // execution by returning success. 465 Ok(None) => return Ok(true), 466 }; 467 log::debug!(" -> lhs results on {}: {:?}", lhs.name(), &lhs_results); 468 469 let rhs_results = rhs 470 .evaluate(name, args, result_tys) 471 // wasmtime should be able to invoke any signature, so unwrap this result 472 .map(|results| results.unwrap()); 473 log::debug!(" -> rhs results on {}: {:?}", rhs.name(), &rhs_results); 474 475 // If Wasmtime hit its OOM condition, which is possible since it's set 476 // somewhat low while fuzzing, then don't return an error but return 477 // `false` indicating that differential fuzzing must stop. There's no 478 // guarantee the other engine has the same OOM limits as Wasmtime, and 479 // it's assumed that Wasmtime is configured to have a more conservative 480 // limit than the other engine. 481 if rhs.is_oom() { 482 return Ok(false); 483 } 484 485 match DiffEqResult::new(lhs_engine, lhs_results, rhs_results) { 486 DiffEqResult::Success(lhs, rhs) => assert_eq!(lhs, rhs), 487 DiffEqResult::Poisoned => return Ok(false), 488 DiffEqResult::Failed => {} 489 } 490 491 for (global, ty) in rhs.exported_globals() { 492 log::debug!("Comparing global `{global}`"); 493 let lhs = match lhs.get_global(&global, ty) { 494 Some(val) => val, 495 None => continue, 496 }; 497 let rhs = rhs.get_global(&global, ty).unwrap(); 498 assert_eq!(lhs, rhs); 499 } 500 for (memory, shared) in rhs.exported_memories() { 501 log::debug!("Comparing memory `{memory}`"); 502 let lhs = match lhs.get_memory(&memory, shared) { 503 Some(val) => val, 504 None => continue, 505 }; 506 let rhs = rhs.get_memory(&memory, shared).unwrap(); 507 if lhs == rhs { 508 continue; 509 } 510 eprintln!("differential memory is {} bytes long", lhs.len()); 511 eprintln!("wasmtime memory is {} bytes long", rhs.len()); 512 panic!("memories have differing values"); 513 } 514 515 Ok(true) 516 } 517 518 /// Result of comparing the result of two operations during differential 519 /// execution. 520 pub enum DiffEqResult<T, U> { 521 /// Both engines succeeded. 522 Success(T, U), 523 /// The result has reached the state where engines may have diverged and 524 /// results can no longer be compared. 525 Poisoned, 526 /// Both engines failed with the same error message, and internal state 527 /// should still match between the two engines. 528 Failed, 529 } 530 531 fn wasmtime_trap_is_non_deterministic(trap: &Trap) -> bool { 532 match trap { 533 // Allocations being too large for the GC are 534 // implementation-defined. 535 Trap::AllocationTooLarge | 536 // Stack size, and therefore when overflow happens, is 537 // implementation-defined. 538 Trap::StackOverflow => true, 539 _ => false, 540 } 541 } 542 543 fn wasmtime_error_is_non_deterministic(error: &wasmtime::Error) -> bool { 544 match error.downcast_ref::<Trap>() { 545 Some(trap) => wasmtime_trap_is_non_deterministic(trap), 546 547 // For general, unknown errors, we can't rely on this being 548 // a deterministic Wasm failure that both engines handled 549 // identically, leaving Wasm in identical states. We could 550 // just as easily be hitting engine-specific failures, like 551 // different implementation-defined limits. So simply poison 552 // this execution and move on to the next test. 553 None => true, 554 } 555 } 556 557 impl<T, U> DiffEqResult<T, U> { 558 /// Computes the differential result from executing in two different 559 /// engines. 560 pub fn new( 561 lhs_engine: &dyn DiffEngine, 562 lhs_result: Result<T>, 563 rhs_result: Result<U>, 564 ) -> DiffEqResult<T, U> { 565 match (lhs_result, rhs_result) { 566 (Ok(lhs_result), Ok(rhs_result)) => DiffEqResult::Success(lhs_result, rhs_result), 567 568 // Handle all non-deterministic errors by poisoning this execution's 569 // state, so that we simply move on to the next test. 570 (Err(lhs), _) if lhs_engine.is_non_deterministic_error(&lhs) => { 571 log::debug!("lhs failed non-deterministically: {lhs:?}"); 572 DiffEqResult::Poisoned 573 } 574 (_, Err(rhs)) if wasmtime_error_is_non_deterministic(&rhs) => { 575 log::debug!("rhs failed non-deterministically: {rhs:?}"); 576 DiffEqResult::Poisoned 577 } 578 579 // Both sides failed deterministically. Check that the trap and 580 // state at the time of failure is the same. 581 (Err(lhs), Err(rhs)) => { 582 let rhs = rhs 583 .downcast::<Trap>() 584 .expect("non-traps handled in earlier match arm"); 585 586 debug_assert!( 587 !lhs_engine.is_non_deterministic_error(&lhs), 588 "non-deterministic traps handled in earlier match arm", 589 ); 590 debug_assert!( 591 !wasmtime_trap_is_non_deterministic(&rhs), 592 "non-deterministic traps handled in earlier match arm", 593 ); 594 595 lhs_engine.assert_error_match(&lhs, &rhs); 596 DiffEqResult::Failed 597 } 598 599 // A real bug is found if only one side fails. 600 (Ok(_), Err(err)) => panic!("only the `rhs` failed for this input: {err:?}"), 601 (Err(err), Ok(_)) => panic!("only the `lhs` failed for this input: {err:?}"), 602 } 603 } 604 } 605 606 /// Invoke the given API calls. 607 pub fn make_api_calls(api: generators::api::ApiCalls) { 608 use crate::generators::api::ApiCall; 609 use std::collections::HashMap; 610 611 let mut store: Option<Store<StoreLimits>> = None; 612 let mut modules: HashMap<usize, Module> = Default::default(); 613 let mut instances: HashMap<usize, Instance> = Default::default(); 614 615 for call in api.calls { 616 match call { 617 ApiCall::StoreNew(config) => { 618 log::trace!("creating store"); 619 assert!(store.is_none()); 620 store = Some(config.to_store()); 621 } 622 623 ApiCall::ModuleNew { id, wasm } => { 624 log::debug!("creating module: {id}"); 625 log_wasm(&wasm); 626 let module = match Module::new(store.as_ref().unwrap().engine(), &wasm) { 627 Ok(m) => m, 628 Err(_) => continue, 629 }; 630 let old = modules.insert(id, module); 631 assert!(old.is_none()); 632 } 633 634 ApiCall::ModuleDrop { id } => { 635 log::trace!("dropping module: {id}"); 636 drop(modules.remove(&id)); 637 } 638 639 ApiCall::InstanceNew { id, module } => { 640 log::trace!("instantiating module {module} as {id}"); 641 let module = match modules.get(&module) { 642 Some(m) => m, 643 None => continue, 644 }; 645 646 let store = store.as_mut().unwrap(); 647 if let Some(instance) = instantiate_with_dummy(store, module) { 648 instances.insert(id, instance); 649 } 650 } 651 652 ApiCall::InstanceDrop { id } => { 653 log::trace!("dropping instance {id}"); 654 instances.remove(&id); 655 } 656 657 ApiCall::CallExportedFunc { instance, nth } => { 658 log::trace!("calling instance export {instance} / {nth}"); 659 let instance = match instances.get(&instance) { 660 Some(i) => i, 661 None => { 662 // Note that we aren't guaranteed to instantiate valid 663 // modules, see comments in `InstanceNew` for details on 664 // that. But the API call generator can't know if 665 // instantiation failed, so we might not actually have 666 // this instance. When that's the case, just skip the 667 // API call and keep going. 668 continue; 669 } 670 }; 671 let store = store.as_mut().unwrap(); 672 673 let funcs = instance 674 .exports(&mut *store) 675 .filter_map(|e| match e.into_extern() { 676 Extern::Func(f) => Some(f), 677 _ => None, 678 }) 679 .collect::<Vec<_>>(); 680 681 if funcs.is_empty() { 682 continue; 683 } 684 685 let nth = nth % funcs.len(); 686 let f = &funcs[nth]; 687 let ty = f.ty(&store); 688 if let Some(params) = ty 689 .params() 690 .map(|p| p.default_value()) 691 .collect::<Option<Vec<_>>>() 692 { 693 let mut results = vec![Val::I32(0); ty.results().len()]; 694 let _ = f.call(store, ¶ms, &mut results); 695 } 696 } 697 } 698 } 699 } 700 701 /// Executes the wast `test` with the `config` specified. 702 /// 703 /// Ensures that wast tests pass regardless of the `Config`. 704 pub fn wast_test(u: &mut arbitrary::Unstructured<'_>) -> arbitrary::Result<()> { 705 crate::init_fuzzing(); 706 707 let mut fuzz_config: generators::Config = u.arbitrary()?; 708 fuzz_config.module_config.shared_memory = true; 709 let test: generators::WastTest = u.arbitrary()?; 710 711 let test = &test.test; 712 713 if test.config.component_model_async() || u.arbitrary()? { 714 fuzz_config.enable_async(u)?; 715 } 716 717 // Discard tests that allocate a lot of memory as we don't want to OOM the 718 // fuzzer and we also limit memory growth which would cause the test to 719 // fail. 720 if test.config.hogs_memory.unwrap_or(false) { 721 return Err(arbitrary::Error::IncorrectFormat); 722 } 723 724 // Transform `fuzz_config` to be valid for `test` and make sure that this 725 // test is supposed to pass. 726 let wast_config = fuzz_config.make_wast_test_compliant(test); 727 if test.should_fail(&wast_config) { 728 return Err(arbitrary::Error::IncorrectFormat); 729 } 730 731 // Winch requires AVX and AVX2 for SIMD tests to pass so don't run the test 732 // if either isn't enabled. 733 if fuzz_config.wasmtime.compiler_strategy == CompilerStrategy::Winch 734 && test.config.simd() 735 && (fuzz_config 736 .wasmtime 737 .codegen_flag("has_avx") 738 .is_some_and(|value| value == "false") 739 || fuzz_config 740 .wasmtime 741 .codegen_flag("has_avx2") 742 .is_some_and(|value| value == "false")) 743 { 744 log::warn!( 745 "Skipping Wast test because Winch doesn't support SIMD tests with AVX or AVX2 disabled" 746 ); 747 return Err(arbitrary::Error::IncorrectFormat); 748 } 749 750 // Fuel and epochs don't play well with threads right now, so exclude any 751 // thread-spawning test if it looks like threads are spawned in that case. 752 if fuzz_config.wasmtime.consume_fuel || fuzz_config.wasmtime.epoch_interruption { 753 if test.contents.contains("(thread") { 754 return Err(arbitrary::Error::IncorrectFormat); 755 } 756 } 757 758 log::debug!("running {:?}", test.path); 759 let async_ = if fuzz_config.wasmtime.async_config == generators::AsyncConfig::Disabled { 760 wasmtime_wast::Async::No 761 } else { 762 wasmtime_wast::Async::Yes 763 }; 764 log::debug!("async: {async_:?}"); 765 let engine = Engine::new(&fuzz_config.to_wasmtime()).unwrap(); 766 let mut wast_context = WastContext::new(&engine, async_, move |store| { 767 fuzz_config.configure_store_epoch_and_fuel(store); 768 }); 769 wast_context 770 .register_spectest(&wasmtime_wast::SpectestConfig { 771 use_shared_memory: true, 772 suppress_prints: true, 773 }) 774 .unwrap(); 775 wast_context.register_wasmtime().unwrap(); 776 wast_context 777 .run_wast(test.path.to_str().unwrap(), test.contents.as_bytes()) 778 .unwrap(); 779 Ok(()) 780 } 781 782 /// Execute a series of `gc` operations. 783 /// 784 /// Returns the number of `gc` operations which occurred throughout the test 785 /// case -- used to test below that gc happens reasonably soon and eventually. 786 pub fn gc_ops(mut fuzz_config: generators::Config, mut ops: GcOps) -> Result<usize> { 787 let expected_drops = Arc::new(AtomicUsize::new(0)); 788 let num_dropped = Arc::new(AtomicUsize::new(0)); 789 790 let num_gcs = Arc::new(AtomicUsize::new(0)); 791 { 792 fuzz_config.wasmtime.consume_fuel = true; 793 let mut store = fuzz_config.to_store(); 794 store.set_fuel(1_000).unwrap(); 795 796 let wasm = ops.to_wasm_binary(); 797 log_wasm(&wasm); 798 let module = match compile_module(store.engine(), &wasm, KnownValid::No, &fuzz_config) { 799 Some(m) => m, 800 None => return Ok(0), 801 }; 802 803 let mut linker = Linker::new(store.engine()); 804 805 // To avoid timeouts, limit the number of explicit GCs we perform per 806 // test case. 807 const MAX_GCS: usize = 5; 808 809 let func_ty = FuncType::new( 810 store.engine(), 811 vec![], 812 vec![ValType::EXTERNREF, ValType::EXTERNREF, ValType::EXTERNREF], 813 ); 814 let func = Func::new(&mut store, func_ty, { 815 let num_dropped = num_dropped.clone(); 816 let expected_drops = expected_drops.clone(); 817 let num_gcs = num_gcs.clone(); 818 move |mut caller: Caller<'_, StoreLimits>, _params, results| { 819 log::info!("gc_ops: GC"); 820 if num_gcs.fetch_add(1, SeqCst) < MAX_GCS { 821 caller.gc(None)?; 822 } 823 824 let a = ExternRef::new( 825 &mut caller, 826 CountDrops::new(&expected_drops, num_dropped.clone()), 827 )?; 828 let b = ExternRef::new( 829 &mut caller, 830 CountDrops::new(&expected_drops, num_dropped.clone()), 831 )?; 832 let c = ExternRef::new( 833 &mut caller, 834 CountDrops::new(&expected_drops, num_dropped.clone()), 835 )?; 836 837 log::info!("gc_ops: gc() -> ({a:?}, {b:?}, {c:?})"); 838 results[0] = Some(a).into(); 839 results[1] = Some(b).into(); 840 results[2] = Some(c).into(); 841 Ok(()) 842 } 843 }); 844 linker.define(&store, "", "gc", func).unwrap(); 845 846 linker 847 .func_wrap("", "take_refs", { 848 let expected_drops = expected_drops.clone(); 849 move |caller: Caller<'_, StoreLimits>, 850 a: Option<Rooted<ExternRef>>, 851 b: Option<Rooted<ExternRef>>, 852 c: Option<Rooted<ExternRef>>| 853 -> Result<()> { 854 log::info!("gc_ops: take_refs({a:?}, {b:?}, {c:?})",); 855 856 // Do the assertion on each ref's inner data, even though it 857 // all points to the same atomic, so that if we happen to 858 // run into a use-after-free bug with one of these refs we 859 // are more likely to trigger a segfault. 860 if let Some(a) = a { 861 let a = a 862 .data(&caller)? 863 .unwrap() 864 .downcast_ref::<CountDrops>() 865 .unwrap(); 866 assert!(a.0.load(SeqCst) <= expected_drops.load(SeqCst)); 867 } 868 if let Some(b) = b { 869 let b = b 870 .data(&caller)? 871 .unwrap() 872 .downcast_ref::<CountDrops>() 873 .unwrap(); 874 assert!(b.0.load(SeqCst) <= expected_drops.load(SeqCst)); 875 } 876 if let Some(c) = c { 877 let c = c 878 .data(&caller)? 879 .unwrap() 880 .downcast_ref::<CountDrops>() 881 .unwrap(); 882 assert!(c.0.load(SeqCst) <= expected_drops.load(SeqCst)); 883 } 884 Ok(()) 885 } 886 }) 887 .unwrap(); 888 889 let func_ty = FuncType::new( 890 store.engine(), 891 vec![], 892 vec![ValType::EXTERNREF, ValType::EXTERNREF, ValType::EXTERNREF], 893 ); 894 let func = Func::new(&mut store, func_ty, { 895 let num_dropped = num_dropped.clone(); 896 let expected_drops = expected_drops.clone(); 897 move |mut caller, _params, results| { 898 log::info!("gc_ops: make_refs"); 899 900 let a = ExternRef::new( 901 &mut caller, 902 CountDrops::new(&expected_drops, num_dropped.clone()), 903 )?; 904 let b = ExternRef::new( 905 &mut caller, 906 CountDrops::new(&expected_drops, num_dropped.clone()), 907 )?; 908 let c = ExternRef::new( 909 &mut caller, 910 CountDrops::new(&expected_drops, num_dropped.clone()), 911 )?; 912 913 log::info!("gc_ops: make_refs() -> ({a:?}, {b:?}, {c:?})"); 914 915 results[0] = Some(a).into(); 916 results[1] = Some(b).into(); 917 results[2] = Some(c).into(); 918 919 Ok(()) 920 } 921 }); 922 linker.define(&store, "", "make_refs", func).unwrap(); 923 924 let func_ty = FuncType::new( 925 store.engine(), 926 vec![ValType::Ref(RefType::new(true, HeapType::Struct))], 927 vec![], 928 ); 929 930 let func = Func::new(&mut store, func_ty, { 931 move |_caller: Caller<'_, StoreLimits>, _params, _results| { 932 log::info!("gc_ops: take_struct(<ref null struct>)"); 933 Ok(()) 934 } 935 }); 936 937 linker.define(&store, "", "take_struct", func).unwrap(); 938 939 for imp in module.imports() { 940 if imp.module() == "" { 941 let name = imp.name(); 942 if name.starts_with("take_struct_") { 943 if let wasmtime::ExternType::Func(ft) = imp.ty() { 944 let imp_name = name.to_string(); 945 let func = 946 Func::new(&mut store, ft.clone(), move |_caller, _params, _results| { 947 log::info!("gc_ops: {imp_name}(<typed structref>)"); 948 Ok(()) 949 }); 950 linker.define(&store, "", name, func).unwrap(); 951 } 952 } 953 } 954 } 955 956 let instance = linker.instantiate(&mut store, &module).unwrap(); 957 let run = instance.get_func(&mut store, "run").unwrap(); 958 959 { 960 let mut scope = RootScope::new(&mut store); 961 962 log::info!( 963 "gc_ops: begin allocating {} externref arguments", 964 ops.limits.num_globals 965 ); 966 let args: Vec<_> = (0..ops.limits.num_params) 967 .map(|_| { 968 Ok(Val::ExternRef(Some(ExternRef::new( 969 &mut scope, 970 CountDrops::new(&expected_drops, num_dropped.clone()), 971 )?))) 972 }) 973 .collect::<Result<_>>()?; 974 log::info!( 975 "gc_ops: end allocating {} externref arguments", 976 ops.limits.num_globals 977 ); 978 979 // The generated function should always return a trap. The only two 980 // valid traps are table-out-of-bounds which happens through `table.get` 981 // and `table.set` generated or an out-of-fuel trap. Otherwise any other 982 // error is unexpected and should fail fuzzing. 983 log::info!("gc_ops: calling into Wasm `run` function"); 984 let err = run.call(&mut scope, &args, &mut []).unwrap_err(); 985 if err.is::<GcHeapOutOfMemory<CountDrops>>() || err.is::<GcHeapOutOfMemory<()>>() { 986 // Accept GC OOM as an allowed outcome for this fuzzer. 987 } else { 988 let trap = err 989 .downcast::<Trap>() 990 .expect("if not GC oom, error should be a Wasm trap"); 991 match trap { 992 Trap::TableOutOfBounds | Trap::OutOfFuel | Trap::AllocationTooLarge => {} 993 _ => panic!("unexpected trap: {trap}"), 994 } 995 } 996 } 997 998 // Do a final GC after running the Wasm. 999 store.gc(None)?; 1000 } 1001 1002 assert_eq!(num_dropped.load(SeqCst), expected_drops.load(SeqCst)); 1003 return Ok(num_gcs.load(SeqCst)); 1004 1005 struct CountDrops(Arc<AtomicUsize>); 1006 1007 impl CountDrops { 1008 fn new(expected_drops: &AtomicUsize, num_dropped: Arc<AtomicUsize>) -> Self { 1009 let expected = expected_drops.fetch_add(1, SeqCst); 1010 log::info!( 1011 "CountDrops::new: expected drops: {expected} -> {}", 1012 expected + 1 1013 ); 1014 Self(num_dropped) 1015 } 1016 } 1017 1018 impl Drop for CountDrops { 1019 fn drop(&mut self) { 1020 let drops = self.0.fetch_add(1, SeqCst); 1021 log::info!("CountDrops::drop: actual drops: {drops} -> {}", drops + 1); 1022 } 1023 } 1024 } 1025 1026 /// Execute a series of exception-related operations. 1027 pub fn exception_ops(mut fuzz_config: generators::Config, mut ops: ExceptionOps) -> Result<()> { 1028 match fuzz_config.wasmtime.compiler_strategy { 1029 // Winch doesn't support exceptions; force to Cranelift. 1030 CompilerStrategy::Winch => { 1031 fuzz_config.wasmtime.compiler_strategy = CompilerStrategy::CraneliftNative; 1032 } 1033 CompilerStrategy::CraneliftNative | CompilerStrategy::CraneliftPulley => {} 1034 } 1035 1036 let module_cfg = &mut fuzz_config.module_config.config; 1037 // Force exceptions + GC on (exceptions require GC). 1038 module_cfg.gc_enabled = true; 1039 module_cfg.exceptions_enabled = true; 1040 module_cfg.reference_types_enabled = true; 1041 1042 let expected = ops.expected_result(); 1043 1044 let wasm = ops.to_wasm_binary(); 1045 log_wasm(&wasm); 1046 1047 let mut store = fuzz_config.to_store(); 1048 1049 let module = compile_module(store.engine(), &wasm, KnownValid::No, &fuzz_config) 1050 .ok_or_else(|| wasmtime::format_err!("Compilation failed"))?; 1051 let mut linker = Linker::new(store.engine()); 1052 1053 let check_ty = FuncType::new(store.engine(), [ValType::I32, ValType::I32], []); 1054 let check_func = Func::new(&mut store, check_ty, |_caller, params, _results| { 1055 let actual = params[0].unwrap_i32(); 1056 let expected = params[1].unwrap_i32(); 1057 assert_eq!(actual, expected, "check_i32 mismatch"); 1058 Ok(()) 1059 }); 1060 linker.define(&store, "", "check_i32", check_func).unwrap(); 1061 1062 let instance = linker.instantiate(&mut store, &module).unwrap(); 1063 let run = instance.get_func(&mut store, "run").unwrap(); 1064 1065 let mut results = [Val::I32(0)]; 1066 match run.call(&mut store, &[], &mut results) { 1067 Ok(()) => { 1068 let actual = results[0].unwrap_i32(); 1069 assert_eq!( 1070 actual, expected, 1071 "exception_ops: run returned {actual}, expected {expected} \ 1072 (one catch per scenario)" 1073 ); 1074 } 1075 Err(e) => { 1076 // AllocationTooLarge / GcHeapOutOfMemory are acceptable resource-limit traps. 1077 if let Some(trap) = e.downcast_ref::<Trap>() { 1078 match trap { 1079 Trap::AllocationTooLarge => return Ok(()), 1080 _ => {} 1081 } 1082 } 1083 if e.is::<GcHeapOutOfMemory<()>>() { 1084 return Ok(()); 1085 } 1086 // Any other error (including ThrownException) is unexpected. 1087 panic!("exception_ops: unexpected error during execution: {e:?}"); 1088 } 1089 } 1090 1091 Ok(()) 1092 } 1093 1094 #[derive(Default)] 1095 struct HelperThread { 1096 state: Arc<HelperThreadState>, 1097 thread: Option<std::thread::JoinHandle<()>>, 1098 } 1099 1100 #[derive(Default)] 1101 struct HelperThreadState { 1102 should_exit: Mutex<bool>, 1103 should_exit_cvar: Condvar, 1104 } 1105 1106 impl HelperThread { 1107 fn run_periodically(&mut self, dur: Duration, mut closure: impl FnMut() + Send + 'static) { 1108 let state = self.state.clone(); 1109 self.thread = Some(std::thread::spawn(move || { 1110 // Using our mutex/condvar we wait here for the first of `dur` to 1111 // pass or the `HelperThread` instance to get dropped. 1112 let mut should_exit = state.should_exit.lock().unwrap(); 1113 while !*should_exit { 1114 let (lock, result) = state 1115 .should_exit_cvar 1116 .wait_timeout(should_exit, dur) 1117 .unwrap(); 1118 should_exit = lock; 1119 // If we timed out for sure then there's no need to continue 1120 // since we'll just abort on the next `checked_sub` anyway. 1121 if result.timed_out() { 1122 closure(); 1123 } 1124 } 1125 })); 1126 } 1127 } 1128 1129 impl Drop for HelperThread { 1130 fn drop(&mut self) { 1131 let thread = match self.thread.take() { 1132 Some(thread) => thread, 1133 None => return, 1134 }; 1135 // Signal our thread that it should exit and wake it up in case it's 1136 // sleeping. 1137 *self.state.should_exit.lock().unwrap() = true; 1138 self.state.should_exit_cvar.notify_one(); 1139 1140 // ... and then wait for the thread to exit to ensure we clean up 1141 // after ourselves. 1142 thread.join().unwrap(); 1143 } 1144 } 1145 1146 /// Instantiates a wasm module and runs its exports with dummy values, all in 1147 /// an async fashion. 1148 /// 1149 /// Attempts to stress yields in host functions to ensure that exiting and 1150 /// resuming a wasm function call works. 1151 pub fn call_async(wasm: &[u8], config: &generators::Config, mut poll_amts: &[u32]) { 1152 let mut store = config.to_store(); 1153 let module = match compile_module(store.engine(), wasm, KnownValid::Yes, config) { 1154 Some(module) => module, 1155 None => return, 1156 }; 1157 1158 // Configure a helper thread to periodically increment the epoch to 1159 // forcibly enable yields-via-epochs if epochs are in use. Note that this 1160 // is required because the wasm isn't otherwise guaranteed to necessarily 1161 // call any imports which will also increment the epoch. 1162 let mut helper_thread = HelperThread::default(); 1163 if let generators::AsyncConfig::YieldWithEpochs { dur, .. } = &config.wasmtime.async_config { 1164 let engine = store.engine().clone(); 1165 helper_thread.run_periodically(*dur, move || engine.increment_epoch()); 1166 } 1167 1168 // Generate a `Linker` where all function imports are custom-built to yield 1169 // periodically and additionally increment the epoch. 1170 let mut imports = Vec::new(); 1171 for import in module.imports() { 1172 let item = match import.ty() { 1173 ExternType::Func(ty) => { 1174 let poll_amt = take_poll_amt(&mut poll_amts); 1175 Func::new_async(&mut store, ty.clone(), move |caller, _, results| { 1176 let ty = ty.clone(); 1177 Box::new(async move { 1178 caller.engine().increment_epoch(); 1179 log::info!("yielding {poll_amt} times in import"); 1180 YieldN(poll_amt).await; 1181 for (ret_ty, result) in ty.results().zip(results) { 1182 *result = ret_ty.default_value().unwrap(); 1183 } 1184 Ok(()) 1185 }) 1186 }) 1187 .into() 1188 } 1189 other_ty => match other_ty.default_value(&mut store) { 1190 Ok(item) => item, 1191 Err(e) => { 1192 log::warn!("couldn't create import for {import:?}: {e:?}"); 1193 return; 1194 } 1195 }, 1196 }; 1197 imports.push(item); 1198 } 1199 1200 // Run the instantiation process, asynchronously, and if everything 1201 // succeeds then pull out the instance. 1202 // log::info!("starting instantiation"); 1203 let instance = block_on(Timeout { 1204 future: Instance::new_async(&mut store, &module, &imports), 1205 polls: take_poll_amt(&mut poll_amts), 1206 end: Instant::now() + Duration::from_millis(2_000), 1207 }); 1208 let instance = match instance { 1209 Ok(instantiation_result) => match unwrap_instance(&store, instantiation_result) { 1210 Some(instance) => instance, 1211 None => { 1212 log::info!("instantiation hit a nominal error"); 1213 return; // resource exhaustion or limits met 1214 } 1215 }, 1216 Err(_) => { 1217 log::info!("instantiation failed to complete"); 1218 return; // Timed out or ran out of polls 1219 } 1220 }; 1221 1222 // Run each export of the instance in the same manner as instantiation 1223 // above. Dummy values are passed in for argument values here: 1224 // 1225 // TODO: this should probably be more clever about passing in arguments for 1226 // example they might be used as pointers or something and always using 0 1227 // isn't too interesting. 1228 let funcs = instance 1229 .exports(&mut store) 1230 .filter_map(|e| { 1231 let name = e.name().to_string(); 1232 let func = e.into_extern().into_func()?; 1233 Some((name, func)) 1234 }) 1235 .collect::<Vec<_>>(); 1236 for (name, func) in funcs { 1237 let ty = func.ty(&store); 1238 let params = ty 1239 .params() 1240 .map(|ty| ty.default_value().unwrap()) 1241 .collect::<Vec<_>>(); 1242 let mut results = ty 1243 .results() 1244 .map(|ty| ty.default_value().unwrap()) 1245 .collect::<Vec<_>>(); 1246 1247 log::info!("invoking export {name:?}"); 1248 let future = func.call_async(&mut store, ¶ms, &mut results); 1249 match block_on(Timeout { 1250 future, 1251 polls: take_poll_amt(&mut poll_amts), 1252 end: Instant::now() + Duration::from_millis(2_000), 1253 }) { 1254 // On success or too many polls, try the next export. 1255 Ok(_) | Err(Exhausted::Polls) => {} 1256 1257 // If time ran out then stop the current test case as we might have 1258 // already sucked up a lot of time for this fuzz test case so don't 1259 // keep it going. 1260 Err(Exhausted::Time) => return, 1261 } 1262 } 1263 1264 fn take_poll_amt(polls: &mut &[u32]) -> u32 { 1265 match polls.split_first() { 1266 Some((a, rest)) => { 1267 *polls = rest; 1268 *a 1269 } 1270 None => 0, 1271 } 1272 } 1273 1274 /// Helper future for applying a timeout to `future` up to either when `end` 1275 /// is the current time or `polls` polls happen. 1276 /// 1277 /// Note that this helps to time out infinite loops in wasm, for example. 1278 struct Timeout<F> { 1279 future: F, 1280 /// If the future isn't ready by this time then the `Timeout<F>` future 1281 /// will return `None`. 1282 end: Instant, 1283 /// If the future doesn't resolve itself in this many calls to `poll` 1284 /// then the `Timeout<F>` future will return `None`. 1285 polls: u32, 1286 } 1287 1288 enum Exhausted { 1289 Time, 1290 Polls, 1291 } 1292 1293 impl<F: Future> Future for Timeout<F> { 1294 type Output = Result<F::Output, Exhausted>; 1295 1296 fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> { 1297 let (end, polls, future) = unsafe { 1298 let me = self.get_unchecked_mut(); 1299 (me.end, &mut me.polls, Pin::new_unchecked(&mut me.future)) 1300 }; 1301 match future.poll(cx) { 1302 Poll::Ready(val) => Poll::Ready(Ok(val)), 1303 Poll::Pending => { 1304 if Instant::now() >= end { 1305 log::warn!("future operation timed out"); 1306 return Poll::Ready(Err(Exhausted::Time)); 1307 } 1308 if *polls == 0 { 1309 log::warn!("future operation ran out of polls"); 1310 return Poll::Ready(Err(Exhausted::Polls)); 1311 } 1312 *polls -= 1; 1313 Poll::Pending 1314 } 1315 } 1316 } 1317 } 1318 } 1319 1320 #[cfg(test)] 1321 mod tests { 1322 use super::*; 1323 use crate::test::{gen_until_pass, test_n_times}; 1324 use wasmparser::{Validator, WasmFeatures}; 1325 1326 // Test that the `gc_ops` fuzzer eventually runs the gc function in the host. 1327 // We've historically had issues where this fuzzer accidentally wasn't fuzzing 1328 // anything for a long time so this is an attempt to prevent that from happening 1329 // again. 1330 #[test] 1331 fn gc_ops_eventually_gcs() { 1332 // Skip if we're under emulation because some fuzz configurations will do 1333 // large address space reservations that QEMU doesn't handle well. 1334 if std::env::var("WASMTIME_TEST_NO_HOG_MEMORY").is_ok() { 1335 return; 1336 } 1337 1338 let ok = gen_until_pass(|(config, test), _| { 1339 let result = gc_ops(config, test)?; 1340 Ok(result > 0) 1341 }); 1342 1343 if !ok { 1344 panic!("gc was never found"); 1345 } 1346 } 1347 1348 #[test] 1349 fn module_generation_uses_expected_proposals() { 1350 // Proposals that Wasmtime supports. Eventually a module should be 1351 // generated that needs these proposals. 1352 let mut expected = WasmFeatures::MUTABLE_GLOBAL 1353 | WasmFeatures::FLOATS 1354 | WasmFeatures::SIGN_EXTENSION 1355 | WasmFeatures::SATURATING_FLOAT_TO_INT 1356 | WasmFeatures::MULTI_VALUE 1357 | WasmFeatures::BULK_MEMORY 1358 | WasmFeatures::REFERENCE_TYPES 1359 | WasmFeatures::SIMD 1360 | WasmFeatures::MULTI_MEMORY 1361 | WasmFeatures::RELAXED_SIMD 1362 | WasmFeatures::TAIL_CALL 1363 | WasmFeatures::WIDE_ARITHMETIC 1364 | WasmFeatures::MEMORY64 1365 | WasmFeatures::FUNCTION_REFERENCES 1366 | WasmFeatures::GC 1367 | WasmFeatures::GC_TYPES 1368 | WasmFeatures::CUSTOM_PAGE_SIZES 1369 | WasmFeatures::EXTENDED_CONST 1370 | WasmFeatures::EXCEPTIONS; 1371 1372 // All other features that wasmparser supports, which is presumably a 1373 // superset of the features that wasm-smith supports, are listed here as 1374 // unexpected. This means, for example, that if wasm-smith updates to 1375 // include a new proposal by default that wasmtime implements then it 1376 // will be required to be listed above. 1377 let unexpected = WasmFeatures::all() ^ expected; 1378 1379 let ok = gen_until_pass(|config: generators::Config, u| { 1380 let wasm = config.generate(u, None)?.to_bytes(); 1381 1382 // Double-check the module is valid 1383 Validator::new_with_features(WasmFeatures::all()).validate_all(&wasm)?; 1384 1385 // If any of the unexpected features are removed then this module 1386 // should always be valid, otherwise something went wrong. 1387 for feature in unexpected.iter() { 1388 let ok = 1389 Validator::new_with_features(WasmFeatures::all() ^ feature).validate_all(&wasm); 1390 if ok.is_err() { 1391 wasmtime::bail!("generated a module with {feature:?} but that wasn't expected"); 1392 } 1393 } 1394 1395 // If any of `expected` is removed and the module fails to validate, 1396 // then that means the module requires that feature. Remove that 1397 // from the set of features we're then expecting. 1398 for feature in expected.iter() { 1399 let ok = 1400 Validator::new_with_features(WasmFeatures::all() ^ feature).validate_all(&wasm); 1401 if ok.is_err() { 1402 expected ^= feature; 1403 } 1404 } 1405 1406 Ok(expected.is_empty()) 1407 }); 1408 1409 if !ok { 1410 panic!("never generated wasm module using {expected:?}"); 1411 } 1412 } 1413 1414 #[test] 1415 fn wast_smoke_test() { 1416 test_n_times(50, |(), u| super::wast_test(u)); 1417 } 1418 } 1419