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