1 use crate::Config; 2 use crate::prelude::*; 3 #[cfg(feature = "runtime")] 4 pub use crate::runtime::code_memory::CustomCodeMemory; 5 #[cfg(feature = "runtime")] 6 use crate::runtime::type_registry::TypeRegistry; 7 #[cfg(feature = "runtime")] 8 use crate::runtime::vm::GcRuntime; 9 use alloc::sync::Arc; 10 use core::ptr::NonNull; 11 #[cfg(target_has_atomic = "64")] 12 use core::sync::atomic::{AtomicU64, Ordering}; 13 #[cfg(any(feature = "cranelift", feature = "winch"))] 14 use object::write::{Object, StandardSegment}; 15 #[cfg(feature = "std")] 16 use std::{fs::File, path::Path}; 17 use wasmparser::WasmFeatures; 18 use wasmtime_environ::{FlagValue, ObjectKind, TripleExt, Tunables}; 19 20 mod serialization; 21 22 /// An `Engine` which is a global context for compilation and management of wasm 23 /// modules. 24 /// 25 /// An engine can be safely shared across threads and is a cheap cloneable 26 /// handle to the actual engine. The engine itself will be deallocated once all 27 /// references to it have gone away. 28 /// 29 /// Engines store global configuration preferences such as compilation settings, 30 /// enabled features, etc. You'll likely only need at most one of these for a 31 /// program. 32 /// 33 /// ## Engines and `Clone` 34 /// 35 /// Using `clone` on an `Engine` is a cheap operation. It will not create an 36 /// entirely new engine, but rather just a new reference to the existing engine. 37 /// In other words it's a shallow copy, not a deep copy. 38 /// 39 /// ## Engines and `Default` 40 /// 41 /// You can create an engine with default configuration settings using 42 /// `Engine::default()`. Be sure to consult the documentation of [`Config`] for 43 /// default settings. 44 #[derive(Clone)] 45 pub struct Engine { 46 inner: Arc<EngineInner>, 47 } 48 49 struct EngineInner { 50 config: Config, 51 features: WasmFeatures, 52 tunables: Tunables, 53 #[cfg(any(feature = "cranelift", feature = "winch"))] 54 compiler: Option<Box<dyn wasmtime_environ::Compiler>>, 55 #[cfg(feature = "runtime")] 56 allocator: Box<dyn crate::runtime::vm::InstanceAllocator + Send + Sync>, 57 #[cfg(feature = "runtime")] 58 gc_runtime: Option<Arc<dyn GcRuntime>>, 59 #[cfg(feature = "runtime")] 60 profiler: Box<dyn crate::profiling_agent::ProfilingAgent>, 61 #[cfg(feature = "runtime")] 62 signatures: TypeRegistry, 63 #[cfg(all(feature = "runtime", target_has_atomic = "64"))] 64 epoch: AtomicU64, 65 66 /// One-time check of whether the compiler's settings, if present, are 67 /// compatible with the native host. 68 compatible_with_native_host: crate::sync::OnceLock<Result<(), String>>, 69 } 70 71 impl core::fmt::Debug for Engine { 72 fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result { 73 f.debug_tuple("Engine") 74 .field(&Arc::as_ptr(&self.inner)) 75 .finish() 76 } 77 } 78 79 impl Default for Engine { 80 fn default() -> Engine { 81 Engine::new(&Config::default()).unwrap() 82 } 83 } 84 85 impl Engine { 86 /// Creates a new [`Engine`] with the specified compilation and 87 /// configuration settings. 88 /// 89 /// # Errors 90 /// 91 /// This method can fail if the `config` is invalid or some 92 /// configurations are incompatible. 93 /// 94 /// For example, feature `reference_types` will need to set 95 /// the compiler setting `unwind_info` to `true`, but explicitly 96 /// disable these two compiler settings will cause errors. 97 pub fn new(config: &Config) -> Result<Engine> { 98 let config = config.clone(); 99 let (mut tunables, features) = config.validate()?; 100 101 #[cfg(feature = "runtime")] 102 if tunables.signals_based_traps { 103 // Ensure that crate::runtime::vm's signal handlers are 104 // configured. This is the per-program initialization required for 105 // handling traps, such as configuring signals, vectored exception 106 // handlers, etc. 107 #[cfg(has_native_signals)] 108 crate::runtime::vm::init_traps(config.macos_use_mach_ports); 109 if !cfg!(miri) { 110 #[cfg(all(has_host_compiler_backend, feature = "debug-builtins"))] 111 crate::runtime::vm::debug_builtins::init(); 112 } 113 } 114 115 #[cfg(any(feature = "cranelift", feature = "winch"))] 116 let (config, compiler) = if config.has_compiler() { 117 let (config, compiler) = config.build_compiler(&mut tunables, features)?; 118 (config, Some(compiler)) 119 } else { 120 (config.clone(), None) 121 }; 122 #[cfg(not(any(feature = "cranelift", feature = "winch")))] 123 let _ = &mut tunables; 124 125 Ok(Engine { 126 inner: Arc::new(EngineInner { 127 #[cfg(any(feature = "cranelift", feature = "winch"))] 128 compiler, 129 #[cfg(feature = "runtime")] 130 allocator: { 131 let allocator = config.build_allocator(&tunables)?; 132 #[cfg(feature = "gc")] 133 { 134 let mem_ty = tunables.gc_heap_memory_type(); 135 allocator.validate_memory(&mem_ty).context( 136 "instance allocator cannot support configured GC heap memory", 137 )?; 138 } 139 allocator 140 }, 141 #[cfg(feature = "runtime")] 142 gc_runtime: config.build_gc_runtime()?, 143 #[cfg(feature = "runtime")] 144 profiler: config.build_profiler()?, 145 #[cfg(feature = "runtime")] 146 signatures: TypeRegistry::new(), 147 #[cfg(all(feature = "runtime", target_has_atomic = "64"))] 148 epoch: AtomicU64::new(0), 149 compatible_with_native_host: Default::default(), 150 config, 151 tunables, 152 features, 153 }), 154 }) 155 } 156 157 /// Returns the configuration settings that this engine is using. 158 #[inline] 159 pub fn config(&self) -> &Config { 160 &self.inner.config 161 } 162 163 #[inline] 164 pub(crate) fn features(&self) -> WasmFeatures { 165 self.inner.features 166 } 167 168 pub(crate) fn run_maybe_parallel< 169 A: Send, 170 B: Send, 171 E: Send, 172 F: Fn(A) -> Result<B, E> + Send + Sync, 173 >( 174 &self, 175 input: Vec<A>, 176 f: F, 177 ) -> Result<Vec<B>, E> { 178 if self.config().parallel_compilation { 179 #[cfg(feature = "parallel-compilation")] 180 { 181 use rayon::prelude::*; 182 // If we collect into Result<Vec<B>, E> directly, the returned error is not 183 // deterministic, because any error could be returned early. So we first materialize 184 // all results in order and then return the first error deterministically, or Ok(_). 185 return input 186 .into_par_iter() 187 .map(|a| f(a)) 188 .collect::<Vec<Result<B, E>>>() 189 .into_iter() 190 .collect::<Result<Vec<B>, E>>(); 191 } 192 } 193 194 // In case the parallel-compilation feature is disabled or the parallel_compilation config 195 // was turned off dynamically fallback to the non-parallel version. 196 input 197 .into_iter() 198 .map(|a| f(a)) 199 .collect::<Result<Vec<B>, E>>() 200 } 201 202 #[cfg(any(feature = "cranelift", feature = "winch"))] 203 pub(crate) fn run_maybe_parallel_mut< 204 T: Send, 205 E: Send, 206 F: Fn(&mut T) -> Result<(), E> + Send + Sync, 207 >( 208 &self, 209 input: &mut [T], 210 f: F, 211 ) -> Result<(), E> { 212 if self.config().parallel_compilation { 213 #[cfg(feature = "parallel-compilation")] 214 { 215 use rayon::prelude::*; 216 // If we collect into `Result<(), E>` directly, the returned 217 // error is not deterministic, because any error could be 218 // returned early. So we first materialize all results in order 219 // and then return the first error deterministically, or 220 // `Ok(_)`. 221 return input 222 .into_par_iter() 223 .map(|a| f(a)) 224 .collect::<Vec<Result<(), E>>>() 225 .into_iter() 226 .collect::<Result<(), E>>(); 227 } 228 } 229 230 // In case the parallel-compilation feature is disabled or the 231 // parallel_compilation config was turned off dynamically fallback to 232 // the non-parallel version. 233 input.into_iter().map(|a| f(a)).collect::<Result<(), E>>() 234 } 235 236 /// Take a weak reference to this engine. 237 pub fn weak(&self) -> EngineWeak { 238 EngineWeak { 239 inner: Arc::downgrade(&self.inner), 240 } 241 } 242 243 #[inline] 244 pub(crate) fn tunables(&self) -> &Tunables { 245 &self.inner.tunables 246 } 247 248 /// Returns whether the engine `a` and `b` refer to the same configuration. 249 #[inline] 250 pub fn same(a: &Engine, b: &Engine) -> bool { 251 Arc::ptr_eq(&a.inner, &b.inner) 252 } 253 254 /// Returns whether the engine is configured to support async functions. 255 #[cfg(feature = "async")] 256 #[inline] 257 pub fn is_async(&self) -> bool { 258 self.config().async_support 259 } 260 261 /// Detects whether the bytes provided are a precompiled object produced by 262 /// Wasmtime. 263 /// 264 /// This function will inspect the header of `bytes` to determine if it 265 /// looks like a precompiled core wasm module or a precompiled component. 266 /// This does not validate the full structure or guarantee that 267 /// deserialization will succeed, instead it helps higher-levels of the 268 /// stack make a decision about what to do next when presented with the 269 /// `bytes` as an input module. 270 /// 271 /// If the `bytes` looks like a precompiled object previously produced by 272 /// [`Module::serialize`](crate::Module::serialize), 273 /// [`Component::serialize`](crate::component::Component::serialize), 274 /// [`Engine::precompile_module`], or [`Engine::precompile_component`], then 275 /// this will return `Some(...)` indicating so. Otherwise `None` is 276 /// returned. 277 pub fn detect_precompiled(bytes: &[u8]) -> Option<Precompiled> { 278 serialization::detect_precompiled_bytes(bytes) 279 } 280 281 /// Like [`Engine::detect_precompiled`], but performs the detection on a file. 282 #[cfg(feature = "std")] 283 pub fn detect_precompiled_file(path: impl AsRef<Path>) -> Result<Option<Precompiled>> { 284 serialization::detect_precompiled_file(path) 285 } 286 287 /// Returns the target triple which this engine is compiling code for 288 /// and/or running code for. 289 pub(crate) fn target(&self) -> target_lexicon::Triple { 290 return self.config().compiler_target(); 291 } 292 293 /// Verify that this engine's configuration is compatible with loading 294 /// modules onto the native host platform. 295 /// 296 /// This method is used as part of `Module::new` to ensure that this 297 /// engine can indeed load modules for the configured compiler (if any). 298 /// Note that if cranelift is disabled this trivially returns `Ok` because 299 /// loaded serialized modules are checked separately. 300 pub(crate) fn check_compatible_with_native_host(&self) -> Result<()> { 301 self.inner 302 .compatible_with_native_host 303 .get_or_init(|| self._check_compatible_with_native_host()) 304 .clone() 305 .map_err(anyhow::Error::msg) 306 } 307 308 fn _check_compatible_with_native_host(&self) -> Result<(), String> { 309 use target_lexicon::Triple; 310 311 let host = Triple::host(); 312 let target = self.config().compiler_target(); 313 314 let target_matches_host = || { 315 // If the host target and target triple match, then it's valid 316 // to run results of compilation on this host. 317 if host == target { 318 return true; 319 } 320 321 // If there's a mismatch and the target is a compatible pulley 322 // target, then that's also ok to run. 323 if cfg!(feature = "pulley") 324 && target.is_pulley() 325 && target.pointer_width() == host.pointer_width() 326 && target.endianness() == host.endianness() 327 { 328 return true; 329 } 330 331 // ... otherwise everything else is considered not a match. 332 false 333 }; 334 335 if !target_matches_host() { 336 return Err(format!( 337 "target '{target}' specified in the configuration does not match the host" 338 )); 339 } 340 341 #[cfg(any(feature = "cranelift", feature = "winch"))] 342 { 343 if let Some(compiler) = self.compiler() { 344 // Also double-check all compiler settings 345 for (key, value) in compiler.flags().iter() { 346 self.check_compatible_with_shared_flag(key, value)?; 347 } 348 for (key, value) in compiler.isa_flags().iter() { 349 self.check_compatible_with_isa_flag(key, value)?; 350 } 351 } 352 } 353 354 // Double-check that this configuration isn't requesting capabilities 355 // that this build of Wasmtime doesn't support. 356 if !cfg!(has_native_signals) && self.tunables().signals_based_traps { 357 return Err("signals-based-traps disabled at compile time -- cannot be enabled".into()); 358 } 359 if !cfg!(has_virtual_memory) && self.tunables().memory_init_cow { 360 return Err("virtual memory disabled at compile time -- cannot enable CoW".into()); 361 } 362 if !cfg!(target_has_atomic = "64") && self.tunables().epoch_interruption { 363 return Err("epochs currently require 64-bit atomics".into()); 364 } 365 366 // Double-check that the host's float ABI matches Cranelift's float ABI. 367 // See `Config::x86_float_abi_ok` for some more 368 // information. 369 if target == target_lexicon::triple!("x86_64-unknown-none") 370 && self.config().x86_float_abi_ok != Some(true) 371 { 372 return Err("\ 373 the x86_64-unknown-none target by default uses a soft-float ABI that is \ 374 incompatible with Cranelift and Wasmtime -- use \ 375 `Config::x86_float_abi_ok` to disable this check and see more \ 376 information about this check\ 377 " 378 .into()); 379 } 380 381 Ok(()) 382 } 383 384 /// Checks to see whether the "shared flag", something enabled for 385 /// individual compilers, is compatible with the native host platform. 386 /// 387 /// This is used both when validating an engine's compilation settings are 388 /// compatible with the host as well as when deserializing modules from 389 /// disk to ensure they're compatible with the current host. 390 /// 391 /// Note that most of the settings here are not configured by users that 392 /// often. While theoretically possible via `Config` methods the more 393 /// interesting flags are the ISA ones below. Typically the values here 394 /// represent global configuration for wasm features. Settings here 395 /// currently rely on the compiler informing us of all settings, including 396 /// those disabled. Settings then fall in a few buckets: 397 /// 398 /// * Some settings must be enabled, such as `preserve_frame_pointers`. 399 /// * Some settings must have a particular value, such as 400 /// `libcall_call_conv`. 401 /// * Some settings do not matter as to their value, such as `opt_level`. 402 pub(crate) fn check_compatible_with_shared_flag( 403 &self, 404 flag: &str, 405 value: &FlagValue, 406 ) -> Result<(), String> { 407 let target = self.target(); 408 let ok = match flag { 409 // These settings must all have be enabled, since their value 410 // can affect the way the generated code performs or behaves at 411 // runtime. 412 "libcall_call_conv" => *value == FlagValue::Enum("isa_default"), 413 "preserve_frame_pointers" => *value == FlagValue::Bool(true), 414 "enable_probestack" => *value == FlagValue::Bool(true), 415 "probestack_strategy" => *value == FlagValue::Enum("inline"), 416 "enable_multi_ret_implicit_sret" => *value == FlagValue::Bool(true), 417 418 // Features wasmtime doesn't use should all be disabled, since 419 // otherwise if they are enabled it could change the behavior of 420 // generated code. 421 "enable_llvm_abi_extensions" => *value == FlagValue::Bool(false), 422 "enable_pinned_reg" => *value == FlagValue::Bool(false), 423 "use_colocated_libcalls" => *value == FlagValue::Bool(false), 424 "use_pinned_reg_as_heap_base" => *value == FlagValue::Bool(false), 425 426 // Windows requires unwind info as part of its ABI. 427 "unwind_info" => { 428 if target.operating_system == target_lexicon::OperatingSystem::Windows { 429 *value == FlagValue::Bool(true) 430 } else { 431 return Ok(()) 432 } 433 } 434 435 // stack switch model must match the current OS 436 "stack_switch_model" => { 437 if self.features().contains(WasmFeatures::STACK_SWITCHING) { 438 use target_lexicon::OperatingSystem; 439 let expected = 440 match target.operating_system { 441 OperatingSystem::Windows => "update_windows_tib", 442 OperatingSystem::Linux 443 | OperatingSystem::MacOSX(_) 444 | OperatingSystem::Darwin(_) => "basic", 445 _ => { return Err(String::from("stack-switching feature not supported on this platform")); } 446 }; 447 *value == FlagValue::Enum(expected) 448 } else { 449 return Ok(()) 450 } 451 } 452 453 // These settings don't affect the interface or functionality of 454 // the module itself, so their configuration values shouldn't 455 // matter. 456 "enable_heap_access_spectre_mitigation" 457 | "enable_table_access_spectre_mitigation" 458 | "enable_nan_canonicalization" 459 | "enable_float" 460 | "enable_verifier" 461 | "enable_pcc" 462 | "regalloc_checker" 463 | "regalloc_verbose_logs" 464 | "regalloc_algorithm" 465 | "is_pic" 466 | "bb_padding_log2_minus_one" 467 | "log2_min_function_alignment" 468 | "machine_code_cfg_info" 469 | "tls_model" // wasmtime doesn't use tls right now 470 | "opt_level" // opt level doesn't change semantics 471 | "enable_alias_analysis" // alias analysis-based opts don't change semantics 472 | "probestack_size_log2" // probestack above asserted disabled 473 | "regalloc" // shouldn't change semantics 474 | "enable_incremental_compilation_cache_checks" // shouldn't change semantics 475 | "enable_atomics" => return Ok(()), 476 477 // Everything else is unknown and needs to be added somewhere to 478 // this list if encountered. 479 _ => { 480 return Err(format!("unknown shared setting {flag:?} configured to {value:?}")) 481 } 482 }; 483 484 if !ok { 485 return Err(format!( 486 "setting {flag:?} is configured to {value:?} which is not supported", 487 )); 488 } 489 Ok(()) 490 } 491 492 /// Same as `check_compatible_with_native_host` except used for ISA-specific 493 /// flags. This is used to test whether a configured ISA flag is indeed 494 /// available on the host platform itself. 495 pub(crate) fn check_compatible_with_isa_flag( 496 &self, 497 flag: &str, 498 value: &FlagValue, 499 ) -> Result<(), String> { 500 match value { 501 // ISA flags are used for things like CPU features, so if they're 502 // disabled then it's compatible with the native host. 503 FlagValue::Bool(false) => return Ok(()), 504 505 // Fall through below where we test at runtime that features are 506 // available. 507 FlagValue::Bool(true) => {} 508 509 // Pulley's pointer_width must match the host. 510 FlagValue::Enum("pointer32") => { 511 return if cfg!(target_pointer_width = "32") { 512 Ok(()) 513 } else { 514 Err("wrong host pointer width".to_string()) 515 }; 516 } 517 FlagValue::Enum("pointer64") => { 518 return if cfg!(target_pointer_width = "64") { 519 Ok(()) 520 } else { 521 Err("wrong host pointer width".to_string()) 522 }; 523 } 524 525 // Only `bool` values are supported right now, other settings would 526 // need more support here. 527 _ => { 528 return Err(format!( 529 "isa-specific feature {flag:?} configured to unknown value {value:?}" 530 )); 531 } 532 } 533 534 let host_feature = match flag { 535 // aarch64 features to detect 536 "has_lse" => "lse", 537 "has_pauth" => "paca", 538 "has_fp16" => "fp16", 539 540 // aarch64 features which don't need detection 541 // No effect on its own. 542 "sign_return_address_all" => return Ok(()), 543 // The pointer authentication instructions act as a `NOP` when 544 // unsupported, so it is safe to enable them. 545 "sign_return_address" => return Ok(()), 546 // No effect on its own. 547 "sign_return_address_with_bkey" => return Ok(()), 548 // The `BTI` instruction acts as a `NOP` when unsupported, so it 549 // is safe to enable it regardless of whether the host supports it 550 // or not. 551 "use_bti" => return Ok(()), 552 553 // s390x features to detect 554 "has_vxrs_ext2" => "vxrs_ext2", 555 "has_vxrs_ext3" => "vxrs_ext3", 556 "has_mie3" => "mie3", 557 "has_mie4" => "mie4", 558 559 // x64 features to detect 560 "has_cmpxchg16b" => "cmpxchg16b", 561 "has_sse3" => "sse3", 562 "has_ssse3" => "ssse3", 563 "has_sse41" => "sse4.1", 564 "has_sse42" => "sse4.2", 565 "has_popcnt" => "popcnt", 566 "has_avx" => "avx", 567 "has_avx2" => "avx2", 568 "has_fma" => "fma", 569 "has_bmi1" => "bmi1", 570 "has_bmi2" => "bmi2", 571 "has_avx512bitalg" => "avx512bitalg", 572 "has_avx512dq" => "avx512dq", 573 "has_avx512f" => "avx512f", 574 "has_avx512vl" => "avx512vl", 575 "has_avx512vbmi" => "avx512vbmi", 576 "has_lzcnt" => "lzcnt", 577 578 // pulley features 579 "big_endian" if cfg!(target_endian = "big") => return Ok(()), 580 "big_endian" if cfg!(target_endian = "little") => { 581 return Err("wrong host endianness".to_string()); 582 } 583 584 _ => { 585 // FIXME: should enumerate risc-v features and plumb them 586 // through to the `detect_host_feature` function. 587 if cfg!(target_arch = "riscv64") && flag != "not_a_flag" { 588 return Ok(()); 589 } 590 return Err(format!( 591 "don't know how to test for target-specific flag {flag:?} at runtime" 592 )); 593 } 594 }; 595 596 let detect = match self.config().detect_host_feature { 597 Some(detect) => detect, 598 None => { 599 return Err(format!( 600 "cannot determine if host feature {host_feature:?} is \ 601 available at runtime, configure a probing function with \ 602 `Config::detect_host_feature`" 603 )); 604 } 605 }; 606 607 match detect(host_feature) { 608 Some(true) => Ok(()), 609 Some(false) => Err(format!( 610 "compilation setting {flag:?} is enabled, but not \ 611 available on the host", 612 )), 613 None => Err(format!( 614 "failed to detect if target-specific flag {host_feature:?} is \ 615 available at runtime (compile setting {flag:?})" 616 )), 617 } 618 } 619 620 /// Returns whether this [`Engine`] is configured to execute with Pulley, 621 /// Wasmtime's interpreter. 622 /// 623 /// Note that Pulley is the default for host platforms that do not have a 624 /// Cranelift backend to support them. For example at the time of this 625 /// writing 32-bit x86 is not supported in Cranelift so the 626 /// `i686-unknown-linux-gnu` target would by default return `true` here. 627 pub fn is_pulley(&self) -> bool { 628 self.target().is_pulley() 629 } 630 } 631 632 #[cfg(any(feature = "cranelift", feature = "winch"))] 633 impl Engine { 634 pub(crate) fn compiler(&self) -> Option<&dyn wasmtime_environ::Compiler> { 635 self.inner.compiler.as_deref() 636 } 637 638 pub(crate) fn try_compiler(&self) -> Result<&dyn wasmtime_environ::Compiler> { 639 self.compiler() 640 .ok_or_else(|| anyhow!("Engine was not configured with a compiler")) 641 } 642 643 /// Ahead-of-time (AOT) compiles a WebAssembly module. 644 /// 645 /// The `bytes` provided must be in one of two formats: 646 /// 647 /// * A [binary-encoded][binary] WebAssembly module. This is always supported. 648 /// * A [text-encoded][text] instance of the WebAssembly text format. 649 /// This is only supported when the `wat` feature of this crate is enabled. 650 /// If this is supplied then the text format will be parsed before validation. 651 /// Note that the `wat` feature is enabled by default. 652 /// 653 /// This method may be used to compile a module for use with a different target 654 /// host. The output of this method may be used with 655 /// [`Module::deserialize`](crate::Module::deserialize) on hosts compatible 656 /// with the [`Config`](crate::Config) associated with this [`Engine`]. 657 /// 658 /// The output of this method is safe to send to another host machine for later 659 /// execution. As the output is already a compiled module, translation and code 660 /// generation will be skipped and this will improve the performance of constructing 661 /// a [`Module`](crate::Module) from the output of this method. 662 /// 663 /// [binary]: https://webassembly.github.io/spec/core/binary/index.html 664 /// [text]: https://webassembly.github.io/spec/core/text/index.html 665 pub fn precompile_module(&self, bytes: &[u8]) -> Result<Vec<u8>> { 666 crate::CodeBuilder::new(self) 667 .wasm_binary_or_text(bytes, None)? 668 .compile_module_serialized() 669 } 670 671 /// Same as [`Engine::precompile_module`] except for a 672 /// [`Component`](crate::component::Component) 673 #[cfg(feature = "component-model")] 674 pub fn precompile_component(&self, bytes: &[u8]) -> Result<Vec<u8>> { 675 crate::CodeBuilder::new(self) 676 .wasm_binary_or_text(bytes, None)? 677 .compile_component_serialized() 678 } 679 680 /// Produces a blob of bytes by serializing the `engine`'s configuration data to 681 /// be checked, perhaps in a different process, with the `check_compatible` 682 /// method below. 683 /// 684 /// The blob of bytes is inserted into the object file specified to become part 685 /// of the final compiled artifact. 686 pub(crate) fn append_compiler_info(&self, obj: &mut Object<'_>) -> Result<()> { 687 serialization::append_compiler_info(self, obj, &serialization::Metadata::new(&self)?); 688 Ok(()) 689 } 690 691 #[cfg(any(feature = "cranelift", feature = "winch"))] 692 pub(crate) fn append_bti(&self, obj: &mut Object<'_>) { 693 let section = obj.add_section( 694 obj.segment_name(StandardSegment::Data).to_vec(), 695 wasmtime_environ::obj::ELF_WASM_BTI.as_bytes().to_vec(), 696 object::SectionKind::ReadOnlyData, 697 ); 698 let contents = if self 699 .compiler() 700 .is_some_and(|c| c.is_branch_protection_enabled()) 701 { 702 1 703 } else { 704 0 705 }; 706 obj.append_section_data(section, &[contents], 1); 707 } 708 } 709 710 /// Return value from the [`Engine::detect_precompiled`] API. 711 #[derive(PartialEq, Eq, Copy, Clone, Debug)] 712 pub enum Precompiled { 713 /// The input bytes look like a precompiled core wasm module. 714 Module, 715 /// The input bytes look like a precompiled wasm component. 716 Component, 717 } 718 719 #[cfg(feature = "runtime")] 720 impl Engine { 721 /// Eagerly initialize thread-local functionality shared by all [`Engine`]s. 722 /// 723 /// Wasmtime's implementation on some platforms may involve per-thread 724 /// setup that needs to happen whenever WebAssembly is invoked. This setup 725 /// can take on the order of a few hundred microseconds, whereas the 726 /// overhead of calling WebAssembly is otherwise on the order of a few 727 /// nanoseconds. This setup cost is paid once per-OS-thread. If your 728 /// application is sensitive to the latencies of WebAssembly function 729 /// calls, even those that happen first on a thread, then this function 730 /// can be used to improve the consistency of each call into WebAssembly 731 /// by explicitly frontloading the cost of the one-time setup per-thread. 732 /// 733 /// Note that this function is not required to be called in any embedding. 734 /// Wasmtime will automatically initialize thread-local-state as necessary 735 /// on calls into WebAssembly. This is provided for use cases where the 736 /// latency of WebAssembly calls are extra-important, which is not 737 /// necessarily true of all embeddings. 738 pub fn tls_eager_initialize() { 739 crate::runtime::vm::tls_eager_initialize(); 740 } 741 742 /// Returns a [`PoolingAllocatorMetrics`](crate::PoolingAllocatorMetrics) if 743 /// this engine was configured with 744 /// [`InstanceAllocationStrategy::Pooling`](crate::InstanceAllocationStrategy::Pooling). 745 #[cfg(feature = "pooling-allocator")] 746 pub fn pooling_allocator_metrics(&self) -> Option<crate::vm::PoolingAllocatorMetrics> { 747 crate::runtime::vm::PoolingAllocatorMetrics::new(self) 748 } 749 750 pub(crate) fn allocator(&self) -> &dyn crate::runtime::vm::InstanceAllocator { 751 self.inner.allocator.as_ref() 752 } 753 754 pub(crate) fn gc_runtime(&self) -> Option<&Arc<dyn GcRuntime>> { 755 self.inner.gc_runtime.as_ref() 756 } 757 758 pub(crate) fn profiler(&self) -> &dyn crate::profiling_agent::ProfilingAgent { 759 self.inner.profiler.as_ref() 760 } 761 762 #[cfg(all(feature = "cache", any(feature = "cranelift", feature = "winch")))] 763 pub(crate) fn cache(&self) -> Option<&wasmtime_cache::Cache> { 764 self.config().cache.as_ref() 765 } 766 767 pub(crate) fn signatures(&self) -> &TypeRegistry { 768 &self.inner.signatures 769 } 770 771 #[cfg(feature = "runtime")] 772 pub(crate) fn custom_code_memory(&self) -> Option<&Arc<dyn CustomCodeMemory>> { 773 self.config().custom_code_memory.as_ref() 774 } 775 776 #[cfg(target_has_atomic = "64")] 777 pub(crate) fn epoch_counter(&self) -> &AtomicU64 { 778 &self.inner.epoch 779 } 780 781 #[cfg(target_has_atomic = "64")] 782 pub(crate) fn current_epoch(&self) -> u64 { 783 self.epoch_counter().load(Ordering::Relaxed) 784 } 785 786 /// Increments the epoch. 787 /// 788 /// When using epoch-based interruption, currently-executing Wasm 789 /// code within this engine will trap or yield "soon" when the 790 /// epoch deadline is reached or exceeded. (The configuration, and 791 /// the deadline, are set on the `Store`.) The intent of the 792 /// design is for this method to be called by the embedder at some 793 /// regular cadence, for example by a thread that wakes up at some 794 /// interval, or by a signal handler. 795 /// 796 /// See [`Config::epoch_interruption`](crate::Config::epoch_interruption) 797 /// for an introduction to epoch-based interruption and pointers 798 /// to the other relevant methods. 799 /// 800 /// When performing `increment_epoch` in a separate thread, consider using 801 /// [`Engine::weak`] to hold an [`EngineWeak`](crate::EngineWeak) and 802 /// performing [`EngineWeak::upgrade`](crate::EngineWeak::upgrade) on each 803 /// tick, so that the epoch ticking thread does not keep an [`Engine`] alive 804 /// longer than any of its consumers. 805 /// 806 /// ## Signal Safety 807 /// 808 /// This method is signal-safe: it does not make any syscalls, and 809 /// performs only an atomic increment to the epoch value in 810 /// memory. 811 #[cfg(target_has_atomic = "64")] 812 pub fn increment_epoch(&self) { 813 self.inner.epoch.fetch_add(1, Ordering::Relaxed); 814 } 815 816 /// Returns a [`std::hash::Hash`] that can be used to check precompiled WebAssembly compatibility. 817 /// 818 /// The outputs of [`Engine::precompile_module`] and [`Engine::precompile_component`] 819 /// are compatible with a different [`Engine`] instance only if the two engines use 820 /// compatible [`Config`]s. If this Hash matches between two [`Engine`]s then binaries 821 /// from one are guaranteed to deserialize in the other. 822 #[cfg(any(feature = "cranelift", feature = "winch"))] 823 pub fn precompile_compatibility_hash(&self) -> impl std::hash::Hash + '_ { 824 crate::compile::HashedEngineCompileEnv(self) 825 } 826 827 /// Returns the required alignment for a code image, if we 828 /// allocate in a way that is not a system `mmap()` that naturally 829 /// aligns it. 830 fn required_code_alignment(&self) -> usize { 831 self.custom_code_memory() 832 .map(|c| c.required_alignment()) 833 .unwrap_or(1) 834 } 835 836 /// Loads a `CodeMemory` from the specified in-memory slice, copying it to a 837 /// uniquely owned mmap. 838 /// 839 /// The `expected` marker here is whether the bytes are expected to be a 840 /// precompiled module or a component. 841 pub(crate) fn load_code_bytes( 842 &self, 843 bytes: &[u8], 844 expected: ObjectKind, 845 ) -> Result<Arc<crate::CodeMemory>> { 846 self.load_code( 847 crate::runtime::vm::MmapVec::from_slice_with_alignment( 848 bytes, 849 self.required_code_alignment(), 850 )?, 851 expected, 852 ) 853 } 854 855 /// Loads a `CodeMemory` from the specified memory region without copying 856 /// 857 /// The `expected` marker here is whether the bytes are expected to be 858 /// a precompiled module or a component. The `memory` provided is expected 859 /// to be a serialized module (.cwasm) generated by `[Module::serialize]` 860 /// or [`Engine::precompile_module] or their `Component` counterparts 861 /// [`Component::serialize`] or `[Engine::precompile_component]`. 862 /// 863 /// The memory provided is guaranteed to only be immutably by the runtime. 864 /// 865 /// # Safety 866 /// 867 /// As there is no copy here, the runtime will be making direct readonly use 868 /// of the provided memory. As such, outside writes to this memory region 869 /// will result in undefined and likely very undesirable behavior. 870 pub(crate) unsafe fn load_code_raw( 871 &self, 872 memory: NonNull<[u8]>, 873 expected: ObjectKind, 874 ) -> Result<Arc<crate::CodeMemory>> { 875 // SAFETY: the contract of this function is the same as that of 876 // `from_raw`. 877 unsafe { self.load_code(crate::runtime::vm::MmapVec::from_raw(memory)?, expected) } 878 } 879 880 /// Like `load_code_bytes`, but creates a mmap from a file on disk. 881 #[cfg(feature = "std")] 882 pub(crate) fn load_code_file( 883 &self, 884 file: File, 885 expected: ObjectKind, 886 ) -> Result<Arc<crate::CodeMemory>> { 887 self.load_code( 888 crate::runtime::vm::MmapVec::from_file(file) 889 .with_context(|| "Failed to create file mapping".to_string())?, 890 expected, 891 ) 892 } 893 894 pub(crate) fn load_code( 895 &self, 896 mmap: crate::runtime::vm::MmapVec, 897 expected: ObjectKind, 898 ) -> Result<Arc<crate::CodeMemory>> { 899 self.check_compatible_with_native_host() 900 .context("compilation settings are not compatible with the native host")?; 901 902 serialization::check_compatible(self, &mmap, expected)?; 903 let mut code = crate::CodeMemory::new(self, mmap)?; 904 code.publish()?; 905 Ok(Arc::new(code)) 906 } 907 908 /// Unload process-related trap/signal handlers and destroy this engine. 909 /// 910 /// This method is not safe and is not widely applicable. It is not required 911 /// to be called and is intended for use cases such as unloading a dynamic 912 /// library from a process. It is difficult to invoke this method correctly 913 /// and it requires careful coordination to do so. 914 /// 915 /// # Panics 916 /// 917 /// This method will panic if this `Engine` handle is not the last remaining 918 /// engine handle. 919 /// 920 /// # Aborts 921 /// 922 /// This method will abort the process on some platforms in some situations 923 /// where unloading the handler cannot be performed and an unrecoverable 924 /// state is reached. For example on Unix platforms with signal handling 925 /// the process will be aborted if the current signal handlers are not 926 /// Wasmtime's. 927 /// 928 /// # Unsafety 929 /// 930 /// This method is not generally safe to call and has a number of 931 /// preconditions that must be met to even possibly be safe. Even with these 932 /// known preconditions met there may be other unknown invariants to uphold 933 /// as well. 934 /// 935 /// * There must be no other instances of `Engine` elsewhere in the process. 936 /// Note that this isn't just copies of this `Engine` but it's any other 937 /// `Engine` at all. This unloads global state that is used by all 938 /// `Engine`s so this instance must be the last. 939 /// 940 /// * On Unix platforms no other signal handlers could have been installed 941 /// for signals that Wasmtime catches. In this situation Wasmtime won't 942 /// know how to restore signal handlers that Wasmtime possibly overwrote 943 /// when Wasmtime was initially loaded. If possible initialize other 944 /// libraries first and then initialize Wasmtime last (e.g. defer creating 945 /// an `Engine`). 946 /// 947 /// * All existing threads which have used this DLL or copy of Wasmtime may 948 /// no longer use this copy of Wasmtime. Per-thread state is not iterated 949 /// and destroyed. Only future threads may use future instances of this 950 /// Wasmtime itself. 951 /// 952 /// If other crashes are seen from using this method please feel free to 953 /// file an issue to update the documentation here with more preconditions 954 /// that must be met. 955 #[cfg(has_native_signals)] 956 pub unsafe fn unload_process_handlers(self) { 957 assert_eq!(Arc::weak_count(&self.inner), 0); 958 assert_eq!(Arc::strong_count(&self.inner), 1); 959 960 // SAFETY: the contract of this function is the same as `deinit_traps`. 961 #[cfg(not(miri))] 962 unsafe { 963 crate::runtime::vm::deinit_traps(); 964 } 965 } 966 } 967 968 /// A weak reference to an [`Engine`]. 969 #[derive(Clone)] 970 pub struct EngineWeak { 971 inner: alloc::sync::Weak<EngineInner>, 972 } 973 974 impl EngineWeak { 975 /// Upgrade this weak reference into an [`Engine`]. Returns `None` if 976 /// strong references (the [`Engine`] type itself) no longer exist. 977 pub fn upgrade(&self) -> Option<Engine> { 978 alloc::sync::Weak::upgrade(&self.inner).map(|inner| Engine { inner }) 979 } 980 } 981