1 use crate::linker::{Definition, DefinitionType}; 2 use crate::prelude::*; 3 use crate::runtime::vm::{ 4 Imports, InstanceAllocationRequest, ModuleRuntimeInfo, StorePtr, VMFuncRef, VMFunctionImport, 5 VMGlobalImport, VMMemoryImport, VMOpaqueContext, VMTableImport, 6 }; 7 use crate::store::{InstanceId, StoreOpaque, Stored}; 8 use crate::types::matching; 9 use crate::{ 10 AsContextMut, Engine, Export, Extern, Func, Global, Memory, Module, ModuleExport, SharedMemory, 11 StoreContext, StoreContextMut, Table, TypedFunc, 12 }; 13 use alloc::sync::Arc; 14 use core::ptr::NonNull; 15 use wasmparser::WasmFeatures; 16 use wasmtime_environ::{ 17 EntityIndex, EntityType, FuncIndex, GlobalIndex, MemoryIndex, PrimaryMap, TableIndex, TypeTrace, 18 }; 19 20 /// An instantiated WebAssembly module. 21 /// 22 /// This type represents the instantiation of a [`Module`]. Once instantiated 23 /// you can access the [`exports`](Instance::exports) which are of type 24 /// [`Extern`] and provide the ability to call functions, set globals, read 25 /// memory, etc. When interacting with any wasm code you'll want to make an 26 /// [`Instance`] to call any code or execute anything. 27 /// 28 /// Instances are owned by a [`Store`](crate::Store) which is passed in at 29 /// creation time. It's recommended to create instances with 30 /// [`Linker::instantiate`](crate::Linker::instantiate) or similar 31 /// [`Linker`](crate::Linker) methods, but a more low-level constructor is also 32 /// available as [`Instance::new`]. 33 #[derive(Copy, Clone, Debug)] 34 #[repr(transparent)] 35 pub struct Instance(Stored<InstanceData>); 36 37 pub(crate) struct InstanceData { 38 /// The id of the instance within the store, used to find the original 39 /// `InstanceHandle`. 40 id: InstanceId, 41 /// A lazily-populated list of exports of this instance. The order of 42 /// exports here matches the order of the exports in the original 43 /// module. 44 exports: Vec<Option<Extern>>, 45 } 46 47 impl InstanceData { 48 pub fn from_id(id: InstanceId) -> InstanceData { 49 InstanceData { 50 id, 51 exports: vec![], 52 } 53 } 54 } 55 56 impl Instance { 57 /// Creates a new [`Instance`] from the previously compiled [`Module`] and 58 /// list of `imports` specified. 59 /// 60 /// This method instantiates the `module` provided with the `imports`, 61 /// following the procedure in the [core specification][inst] to 62 /// instantiate. Instantiation can fail for a number of reasons (many 63 /// specified below), but if successful the `start` function will be 64 /// automatically run (if specified in the `module`) and then the 65 /// [`Instance`] will be returned. 66 /// 67 /// Per the WebAssembly spec, instantiation includes running the module's 68 /// start function, if it has one (not to be confused with the `_start` 69 /// function, which is not run). 70 /// 71 /// Note that this is a low-level function that just performs an 72 /// instantiation. See the [`Linker`](crate::Linker) struct for an API which 73 /// provides a convenient way to link imports and provides automatic Command 74 /// and Reactor behavior. 75 /// 76 /// ## Providing Imports 77 /// 78 /// The entries in the list of `imports` are intended to correspond 1:1 79 /// with the list of imports returned by [`Module::imports`]. Before 80 /// calling [`Instance::new`] you'll want to inspect the return value of 81 /// [`Module::imports`] and, for each import type, create an [`Extern`] 82 /// which corresponds to that type. These [`Extern`] values are all then 83 /// collected into a list and passed to this function. 84 /// 85 /// Note that this function is intentionally relatively low level. For an 86 /// easier time passing imports by doing name-based resolution it's 87 /// recommended to instead use the [`Linker`](crate::Linker) type. 88 /// 89 /// ## Errors 90 /// 91 /// This function can fail for a number of reasons, including, but not 92 /// limited to: 93 /// 94 /// * The number of `imports` provided doesn't match the number of imports 95 /// returned by the `module`'s [`Module::imports`] method. 96 /// * The type of any [`Extern`] doesn't match the corresponding 97 /// [`ExternType`] entry that it maps to. 98 /// * The `start` function in the instance, if present, traps. 99 /// * Module/instance resource limits are exceeded. 100 /// 101 /// When instantiation fails it's recommended to inspect the return value to 102 /// see why it failed, or bubble it upwards. If you'd like to specifically 103 /// check for trap errors, you can use `error.downcast::<Trap>()`. For more 104 /// about error handling see the [`Trap`] documentation. 105 /// 106 /// [`Trap`]: crate::Trap 107 /// 108 /// # Panics 109 /// 110 /// This function will panic if called with a store associated with a 111 /// [`asynchronous config`](crate::Config::async_support). This function 112 /// will also panic if any [`Extern`] supplied is not owned by `store`. 113 /// 114 /// [inst]: https://webassembly.github.io/spec/core/exec/modules.html#exec-instantiation 115 /// [`ExternType`]: crate::ExternType 116 pub fn new( 117 mut store: impl AsContextMut, 118 module: &Module, 119 imports: &[Extern], 120 ) -> Result<Instance> { 121 let mut store = store.as_context_mut(); 122 let imports = Instance::typecheck_externs(store.0, module, imports)?; 123 // Note that the unsafety here should be satisfied by the call to 124 // `typecheck_externs` above which satisfies the condition that all 125 // the imports are valid for this module. 126 unsafe { Instance::new_started(&mut store, module, imports.as_ref()) } 127 } 128 129 /// Same as [`Instance::new`], except for usage in [asynchronous stores]. 130 /// 131 /// For more details about this function see the documentation on 132 /// [`Instance::new`]. The only difference between these two methods is that 133 /// this one will asynchronously invoke the wasm start function in case it 134 /// calls any imported function which is an asynchronous host function (e.g. 135 /// created with [`Func::new_async`](crate::Func::new_async). 136 /// 137 /// # Panics 138 /// 139 /// This function will panic if called with a store associated with a 140 /// [`synchronous config`](crate::Config::new). This is only compatible with 141 /// stores associated with an [`asynchronous 142 /// config`](crate::Config::async_support). 143 /// 144 /// This function will also panic, like [`Instance::new`], if any [`Extern`] 145 /// specified does not belong to `store`. 146 #[cfg(feature = "async")] 147 pub async fn new_async<T>( 148 mut store: impl AsContextMut<Data = T>, 149 module: &Module, 150 imports: &[Extern], 151 ) -> Result<Instance> 152 where 153 T: Send, 154 { 155 let mut store = store.as_context_mut(); 156 let imports = Instance::typecheck_externs(store.0, module, imports)?; 157 // See `new` for notes on this unsafety 158 unsafe { Instance::new_started_async(&mut store, module, imports.as_ref()).await } 159 } 160 161 fn typecheck_externs( 162 store: &mut StoreOpaque, 163 module: &Module, 164 imports: &[Extern], 165 ) -> Result<OwnedImports> { 166 for import in imports { 167 if !import.comes_from_same_store(store) { 168 bail!("cross-`Store` instantiation is not currently supported"); 169 } 170 } 171 typecheck(module, imports, |cx, ty, item| { 172 let item = DefinitionType::from(store, item); 173 cx.definition(ty, &item) 174 })?; 175 let mut owned_imports = OwnedImports::new(module); 176 for import in imports { 177 owned_imports.push(import, store, module); 178 } 179 Ok(owned_imports) 180 } 181 182 /// Internal function to create an instance and run the start function. 183 /// 184 /// This function's unsafety is the same as `Instance::new_raw`. 185 pub(crate) unsafe fn new_started<T>( 186 store: &mut StoreContextMut<'_, T>, 187 module: &Module, 188 imports: Imports<'_>, 189 ) -> Result<Instance> { 190 assert!( 191 !store.0.async_support(), 192 "must use async instantiation when async support is enabled", 193 ); 194 Self::new_started_impl(store, module, imports) 195 } 196 197 /// Internal function to create an instance and run the start function. 198 /// 199 /// ONLY CALL THIS IF YOU HAVE ALREADY CHECKED FOR ASYNCNESS AND HANDLED 200 /// THE FIBER NONSENSE 201 pub(crate) unsafe fn new_started_impl<T>( 202 store: &mut StoreContextMut<'_, T>, 203 module: &Module, 204 imports: Imports<'_>, 205 ) -> Result<Instance> { 206 let (instance, start) = Instance::new_raw(store.0, module, imports)?; 207 if let Some(start) = start { 208 instance.start_raw(store, start)?; 209 } 210 Ok(instance) 211 } 212 213 /// Internal function to create an instance and run the start function. 214 /// 215 /// This function's unsafety is the same as `Instance::new_raw`. 216 #[cfg(feature = "async")] 217 async unsafe fn new_started_async<T>( 218 store: &mut StoreContextMut<'_, T>, 219 module: &Module, 220 imports: Imports<'_>, 221 ) -> Result<Instance> 222 where 223 T: Send, 224 { 225 assert!( 226 store.0.async_support(), 227 "must use sync instantiation when async support is disabled", 228 ); 229 230 store 231 .on_fiber(|store| Self::new_started_impl(store, module, imports)) 232 .await? 233 } 234 235 /// Internal function to create an instance which doesn't have its `start` 236 /// function run yet. 237 /// 238 /// This is not intended to be exposed from Wasmtime, it's intended to 239 /// refactor out common code from `new_started` and `new_started_async`. 240 /// 241 /// Note that this step needs to be run on a fiber in async mode even 242 /// though it doesn't do any blocking work because an async resource 243 /// limiter may need to yield. 244 /// 245 /// # Unsafety 246 /// 247 /// This method is unsafe because it does not type-check the `imports` 248 /// provided. The `imports` provided must be suitable for the module 249 /// provided as well. 250 unsafe fn new_raw( 251 store: &mut StoreOpaque, 252 module: &Module, 253 imports: Imports<'_>, 254 ) -> Result<(Instance, Option<FuncIndex>)> { 255 if !Engine::same(store.engine(), module.engine()) { 256 bail!("cross-`Engine` instantiation is not currently supported"); 257 } 258 store.bump_resource_counts(module)?; 259 260 // Allocate the GC heap, if necessary. 261 if store.engine().features().gc_types() { 262 let _ = store.gc_store_mut()?; 263 } 264 265 let compiled_module = module.compiled_module(); 266 267 // Register the module just before instantiation to ensure we keep the module 268 // properly referenced while in use by the store. 269 let module_id = store.modules_mut().register_module(module); 270 store.fill_func_refs(); 271 272 // The first thing we do is issue an instance allocation request 273 // to the instance allocator. This, on success, will give us an 274 // instance handle. 275 // 276 // Note that the `host_state` here is a pointer back to the 277 // `Instance` we'll be returning from this function. This is a 278 // circular reference so we can't construct it before we construct 279 // this instance, so we determine what the ID is and then assert 280 // it's the same later when we do actually insert it. 281 let instance_to_be = store.store_data().next_id::<InstanceData>(); 282 283 let mut instance_handle = 284 store 285 .engine() 286 .allocator() 287 .allocate_module(InstanceAllocationRequest { 288 runtime_info: &ModuleRuntimeInfo::Module(module.clone()), 289 imports, 290 host_state: Box::new(Instance(instance_to_be)), 291 store: StorePtr::new(store.traitobj()), 292 wmemcheck: store.engine().config().wmemcheck, 293 pkey: store.get_pkey(), 294 tunables: store.engine().tunables(), 295 })?; 296 297 // The instance still has lots of setup, for example 298 // data/elements/start/etc. This can all fail, but even on failure 299 // the instance may persist some state via previous successful 300 // initialization. For this reason once we have an instance handle 301 // we immediately insert it into the store to keep it alive. 302 // 303 // Note that we `clone` the instance handle just to make easier 304 // working the borrow checker here easier. Technically the `&mut 305 // instance` has somewhat of a borrow on `store` (which 306 // conflicts with the borrow on `store.engine`) but this doesn't 307 // matter in practice since initialization isn't even running any 308 // code here anyway. 309 let id = store.add_instance(instance_handle.clone(), module_id); 310 311 // Additionally, before we start doing fallible instantiation, we 312 // do one more step which is to insert an `InstanceData` 313 // corresponding to this instance. This `InstanceData` can be used 314 // via `Caller::get_export` if our instance's state "leaks" into 315 // other instances, even if we don't return successfully from this 316 // function. 317 // 318 // We don't actually load all exports from the instance at this 319 // time, instead preferring to lazily load them as they're demanded. 320 // For module/instance exports, though, those aren't actually 321 // stored in the instance handle so we need to immediately handle 322 // those here. 323 let instance = { 324 let exports = vec![None; compiled_module.module().exports.len()]; 325 let data = InstanceData { id, exports }; 326 Instance::from_wasmtime(data, store) 327 }; 328 329 // double-check our guess of what the new instance's ID would be 330 // was actually correct. 331 assert_eq!(instance.0, instance_to_be); 332 333 // Now that we've recorded all information we need to about this 334 // instance within a `Store` we can start performing fallible 335 // initialization. Note that we still defer the `start` function to 336 // later since that may need to run asynchronously. 337 // 338 // If this returns an error (or if the start function traps) then 339 // any other initialization which may have succeeded which placed 340 // items from this instance into other instances should be ok when 341 // those items are loaded and run we'll have all the metadata to 342 // look at them. 343 let bulk_memory = store 344 .engine() 345 .features() 346 .contains(WasmFeatures::BULK_MEMORY); 347 instance_handle.initialize(store, compiled_module.module(), bulk_memory)?; 348 349 Ok((instance, compiled_module.module().start_func)) 350 } 351 352 pub(crate) fn from_wasmtime(handle: InstanceData, store: &mut StoreOpaque) -> Instance { 353 Instance(store.store_data_mut().insert(handle)) 354 } 355 356 fn start_raw<T>(&self, store: &mut StoreContextMut<'_, T>, start: FuncIndex) -> Result<()> { 357 let id = store.0.store_data()[self.0].id; 358 // If a start function is present, invoke it. Make sure we use all the 359 // trap-handling configuration in `store` as well. 360 let instance = store.0.instance_mut(id); 361 let f = instance.get_exported_func(start); 362 let caller_vmctx = instance.vmctx(); 363 unsafe { 364 super::func::invoke_wasm_and_catch_traps(store, |_default_caller, vm| { 365 f.func_ref.as_ref().array_call( 366 vm, 367 VMOpaqueContext::from_vmcontext(caller_vmctx), 368 &mut [], 369 ) 370 })?; 371 } 372 Ok(()) 373 } 374 375 /// Get this instance's module. 376 pub fn module<'a, T: 'a>(&self, store: impl Into<StoreContext<'a, T>>) -> &'a Module { 377 self._module(store.into().0) 378 } 379 380 fn _module<'a>(&self, store: &'a StoreOpaque) -> &'a Module { 381 let InstanceData { id, .. } = store[self.0]; 382 store.module_for_instance(id).unwrap() 383 } 384 385 /// Returns the list of exported items from this [`Instance`]. 386 /// 387 /// # Panics 388 /// 389 /// Panics if `store` does not own this instance. 390 pub fn exports<'a, T: 'a>( 391 &'a self, 392 store: impl Into<StoreContextMut<'a, T>>, 393 ) -> impl ExactSizeIterator<Item = Export<'a>> + 'a { 394 self._exports(store.into().0) 395 } 396 397 fn _exports<'a>( 398 &'a self, 399 store: &'a mut StoreOpaque, 400 ) -> impl ExactSizeIterator<Item = Export<'a>> + 'a { 401 // If this is an `Instantiated` instance then all the `exports` may not 402 // be filled in. Fill them all in now if that's the case. 403 let InstanceData { exports, id, .. } = &store[self.0]; 404 if exports.iter().any(|e| e.is_none()) { 405 let module = Arc::clone(store.instance(*id).module()); 406 let data = &store[self.0]; 407 let id = data.id; 408 409 for name in module.exports.keys() { 410 let instance = store.instance(id); 411 if let Some((export_name_index, _, &entity)) = 412 instance.module().exports.get_full(name) 413 { 414 self._get_export(store, entity, export_name_index); 415 } 416 } 417 } 418 419 let data = &store.store_data()[self.0]; 420 let module = store.instance(data.id).module(); 421 module 422 .exports 423 .iter() 424 .zip(&data.exports) 425 .map(|((name, _), export)| Export::new(name, export.clone().unwrap())) 426 } 427 428 /// Looks up an exported [`Extern`] value by name. 429 /// 430 /// This method will search the module for an export named `name` and return 431 /// the value, if found. 432 /// 433 /// Returns `None` if there was no export named `name`. 434 /// 435 /// # Panics 436 /// 437 /// Panics if `store` does not own this instance. 438 /// 439 /// # Why does `get_export` take a mutable context? 440 /// 441 /// This method requires a mutable context because an instance's exports are 442 /// lazily populated, and we cache them as they are accessed. This makes 443 /// instantiating a module faster, but also means this method requires a 444 /// mutable context. 445 pub fn get_export(&self, mut store: impl AsContextMut, name: &str) -> Option<Extern> { 446 let store = store.as_context_mut().0; 447 let data = &store[self.0]; 448 let instance = store.instance(data.id); 449 let (export_name_index, _, &entity) = instance.module().exports.get_full(name)?; 450 self._get_export(store, entity, export_name_index) 451 } 452 453 /// Looks up an exported [`Extern`] value by a [`ModuleExport`] value. 454 /// 455 /// This is similar to [`Instance::get_export`] but uses a [`ModuleExport`] value to avoid 456 /// string lookups where possible. [`ModuleExport`]s can be obtained by calling 457 /// [`Module::get_export_index`] on the [`Module`] that this instance was instantiated with. 458 /// 459 /// This method will search the module for an export with a matching entity index and return 460 /// the value, if found. 461 /// 462 /// Returns `None` if there was no export with a matching entity index. 463 /// # Panics 464 /// 465 /// Panics if `store` does not own this instance. 466 pub fn get_module_export( 467 &self, 468 mut store: impl AsContextMut, 469 export: &ModuleExport, 470 ) -> Option<Extern> { 471 let store = store.as_context_mut().0; 472 473 // Verify the `ModuleExport` matches the module used in this instance. 474 if self._module(store).id() != export.module { 475 return None; 476 } 477 478 self._get_export(store, export.entity, export.export_name_index) 479 } 480 481 fn _get_export( 482 &self, 483 store: &mut StoreOpaque, 484 entity: EntityIndex, 485 export_name_index: usize, 486 ) -> Option<Extern> { 487 // Instantiated instances will lazily fill in exports, so we process 488 // all that lazy logic here. 489 let data = &store[self.0]; 490 491 if let Some(export) = &data.exports[export_name_index] { 492 return Some(export.clone()); 493 } 494 495 let instance = store.instance_mut(data.id); // Reborrow the &mut InstanceHandle 496 let item = 497 unsafe { Extern::from_wasmtime_export(instance.get_export_by_index(entity), store) }; 498 let data = &mut store[self.0]; 499 data.exports[export_name_index] = Some(item.clone()); 500 Some(item) 501 } 502 503 /// Looks up an exported [`Func`] value by name. 504 /// 505 /// Returns `None` if there was no export named `name`, or if there was but 506 /// it wasn't a function. 507 /// 508 /// # Panics 509 /// 510 /// Panics if `store` does not own this instance. 511 pub fn get_func(&self, store: impl AsContextMut, name: &str) -> Option<Func> { 512 self.get_export(store, name)?.into_func() 513 } 514 515 /// Looks up an exported [`Func`] value by name and with its type. 516 /// 517 /// This function is a convenience wrapper over [`Instance::get_func`] and 518 /// [`Func::typed`]. For more information see the linked documentation. 519 /// 520 /// Returns an error if `name` isn't a function export or if the export's 521 /// type did not match `Params` or `Results` 522 /// 523 /// # Panics 524 /// 525 /// Panics if `store` does not own this instance. 526 pub fn get_typed_func<Params, Results>( 527 &self, 528 mut store: impl AsContextMut, 529 name: &str, 530 ) -> Result<TypedFunc<Params, Results>> 531 where 532 Params: crate::WasmParams, 533 Results: crate::WasmResults, 534 { 535 let f = self 536 .get_export(store.as_context_mut(), name) 537 .and_then(|f| f.into_func()) 538 .ok_or_else(|| anyhow!("failed to find function export `{}`", name))?; 539 Ok(f.typed::<Params, Results>(store) 540 .with_context(|| format!("failed to convert function `{name}` to given type"))?) 541 } 542 543 /// Looks up an exported [`Table`] value by name. 544 /// 545 /// Returns `None` if there was no export named `name`, or if there was but 546 /// it wasn't a table. 547 /// 548 /// # Panics 549 /// 550 /// Panics if `store` does not own this instance. 551 pub fn get_table(&self, store: impl AsContextMut, name: &str) -> Option<Table> { 552 self.get_export(store, name)?.into_table() 553 } 554 555 /// Looks up an exported [`Memory`] value by name. 556 /// 557 /// Returns `None` if there was no export named `name`, or if there was but 558 /// it wasn't a memory. 559 /// 560 /// # Panics 561 /// 562 /// Panics if `store` does not own this instance. 563 pub fn get_memory(&self, store: impl AsContextMut, name: &str) -> Option<Memory> { 564 self.get_export(store, name)?.into_memory() 565 } 566 567 /// Looks up an exported [`SharedMemory`] value by name. 568 /// 569 /// Returns `None` if there was no export named `name`, or if there was but 570 /// it wasn't a shared memory. 571 /// 572 /// # Panics 573 /// 574 /// Panics if `store` does not own this instance. 575 pub fn get_shared_memory( 576 &self, 577 mut store: impl AsContextMut, 578 name: &str, 579 ) -> Option<SharedMemory> { 580 let mut store = store.as_context_mut(); 581 self.get_export(&mut store, name)?.into_shared_memory() 582 } 583 584 /// Looks up an exported [`Global`] value by name. 585 /// 586 /// Returns `None` if there was no export named `name`, or if there was but 587 /// it wasn't a global. 588 /// 589 /// # Panics 590 /// 591 /// Panics if `store` does not own this instance. 592 pub fn get_global(&self, store: impl AsContextMut, name: &str) -> Option<Global> { 593 self.get_export(store, name)?.into_global() 594 } 595 596 #[cfg(feature = "component-model")] 597 pub(crate) fn id(&self, store: &StoreOpaque) -> InstanceId { 598 store[self.0].id 599 } 600 601 /// Get all globals within this instance. 602 /// 603 /// Returns both import and defined globals. 604 /// 605 /// Returns both exported and non-exported globals. 606 /// 607 /// Gives access to the full globals space. 608 pub(crate) fn all_globals<'a>( 609 &'a self, 610 store: &'a mut StoreOpaque, 611 ) -> impl ExactSizeIterator<Item = (GlobalIndex, Global)> + 'a { 612 let data = &store[self.0]; 613 let instance = store.instance_mut(data.id); 614 instance 615 .all_globals() 616 .collect::<Vec<_>>() 617 .into_iter() 618 .map(|(i, g)| (i, unsafe { Global::from_wasmtime_global(g, store) })) 619 } 620 621 /// Get all memories within this instance. 622 /// 623 /// Returns both import and defined memories. 624 /// 625 /// Returns both exported and non-exported memories. 626 /// 627 /// Gives access to the full memories space. 628 pub(crate) fn all_memories<'a>( 629 &'a self, 630 store: &'a mut StoreOpaque, 631 ) -> impl ExactSizeIterator<Item = (MemoryIndex, Memory)> + 'a { 632 let data = &store[self.0]; 633 let instance = store.instance_mut(data.id); 634 instance 635 .all_memories() 636 .collect::<Vec<_>>() 637 .into_iter() 638 .map(|(i, m)| (i, unsafe { Memory::from_wasmtime_memory(m, store) })) 639 } 640 } 641 642 pub(crate) struct OwnedImports { 643 functions: PrimaryMap<FuncIndex, VMFunctionImport>, 644 tables: PrimaryMap<TableIndex, VMTableImport>, 645 memories: PrimaryMap<MemoryIndex, VMMemoryImport>, 646 globals: PrimaryMap<GlobalIndex, VMGlobalImport>, 647 } 648 649 impl OwnedImports { 650 fn new(module: &Module) -> OwnedImports { 651 let mut ret = OwnedImports::empty(); 652 ret.reserve(module); 653 return ret; 654 } 655 656 pub(crate) fn empty() -> OwnedImports { 657 OwnedImports { 658 functions: PrimaryMap::new(), 659 tables: PrimaryMap::new(), 660 memories: PrimaryMap::new(), 661 globals: PrimaryMap::new(), 662 } 663 } 664 665 pub(crate) fn reserve(&mut self, module: &Module) { 666 let raw = module.compiled_module().module(); 667 self.functions.reserve(raw.num_imported_funcs); 668 self.tables.reserve(raw.num_imported_tables); 669 self.memories.reserve(raw.num_imported_memories); 670 self.globals.reserve(raw.num_imported_globals); 671 } 672 673 #[cfg(feature = "component-model")] 674 pub(crate) fn clear(&mut self) { 675 self.functions.clear(); 676 self.tables.clear(); 677 self.memories.clear(); 678 self.globals.clear(); 679 } 680 681 fn push(&mut self, item: &Extern, store: &mut StoreOpaque, module: &Module) { 682 match item { 683 Extern::Func(i) => { 684 self.functions.push(i.vmimport(store, module)); 685 } 686 Extern::Global(i) => { 687 self.globals.push(i.vmimport(store)); 688 } 689 Extern::Table(i) => { 690 self.tables.push(i.vmimport(store)); 691 } 692 Extern::Memory(i) => { 693 self.memories.push(i.vmimport(store)); 694 } 695 Extern::SharedMemory(i) => { 696 self.memories.push(i.vmimport(store)); 697 } 698 } 699 } 700 701 /// Note that this is unsafe as the validity of `item` is not verified and 702 /// it contains a bunch of raw pointers. 703 #[cfg(feature = "component-model")] 704 pub(crate) unsafe fn push_export(&mut self, item: &crate::runtime::vm::Export) { 705 match item { 706 crate::runtime::vm::Export::Function(f) => { 707 let f = f.func_ref.as_ref(); 708 self.functions.push(VMFunctionImport { 709 wasm_call: f.wasm_call.unwrap(), 710 array_call: f.array_call, 711 vmctx: f.vmctx, 712 }); 713 } 714 crate::runtime::vm::Export::Global(g) => { 715 self.globals.push(VMGlobalImport { from: g.definition }); 716 } 717 crate::runtime::vm::Export::Table(t) => { 718 self.tables.push(VMTableImport { 719 from: t.definition, 720 vmctx: t.vmctx, 721 }); 722 } 723 crate::runtime::vm::Export::Memory(m) => { 724 self.memories.push(VMMemoryImport { 725 from: m.definition, 726 vmctx: m.vmctx, 727 index: m.index, 728 }); 729 } 730 } 731 } 732 733 pub(crate) fn as_ref(&self) -> Imports<'_> { 734 Imports { 735 tables: self.tables.values().as_slice(), 736 globals: self.globals.values().as_slice(), 737 memories: self.memories.values().as_slice(), 738 functions: self.functions.values().as_slice(), 739 } 740 } 741 } 742 743 /// An instance, pre-instantiation, that is ready to be instantiated. 744 /// 745 /// This structure represents an instance *just before* it was instantiated, 746 /// after all type-checking and imports have been resolved. The only thing left 747 /// to do for this instance is to actually run the process of instantiation. 748 /// 749 /// Note that an `InstancePre` may not be tied to any particular [`Store`] if 750 /// none of the imports it closed over are tied to any particular [`Store`]. 751 /// 752 /// This structure is created through the [`Linker::instantiate_pre`] method, 753 /// which also has some more information and examples. 754 /// 755 /// [`Store`]: crate::Store 756 /// [`Linker::instantiate_pre`]: crate::Linker::instantiate_pre 757 pub struct InstancePre<T> { 758 module: Module, 759 760 /// The items which this `InstancePre` use to instantiate the `module` 761 /// provided, passed to `Instance::new_started` after inserting them into a 762 /// `Store`. 763 /// 764 /// Note that this is stored as an `Arc<[T]>` to quickly move a strong 765 /// reference to everything internally into a `Store<T>` without having to 766 /// clone each individual item. 767 items: Arc<[Definition]>, 768 769 /// A count of `Definition::HostFunc` entries in `items` above to 770 /// preallocate space in a `Store` up front for all entries to be inserted. 771 host_funcs: usize, 772 773 /// The `VMFuncRef`s for the functions in `items` that do not 774 /// have a `wasm_call` trampoline. We pre-allocate and pre-patch these 775 /// `VMFuncRef`s so that we don't have to do it at 776 /// instantiation time. 777 /// 778 /// This is an `Arc<[T]>` for the same reason as `items`. 779 func_refs: Arc<[VMFuncRef]>, 780 781 _marker: core::marker::PhantomData<fn() -> T>, 782 } 783 784 /// InstancePre's clone does not require T: Clone 785 impl<T> Clone for InstancePre<T> { 786 fn clone(&self) -> Self { 787 Self { 788 module: self.module.clone(), 789 items: self.items.clone(), 790 host_funcs: self.host_funcs, 791 func_refs: self.func_refs.clone(), 792 _marker: self._marker, 793 } 794 } 795 } 796 797 impl<T> InstancePre<T> { 798 /// Creates a new `InstancePre` which type-checks the `items` provided and 799 /// on success is ready to instantiate a new instance. 800 /// 801 /// # Unsafety 802 /// 803 /// This method is unsafe as the `T` of the `InstancePre<T>` is not 804 /// guaranteed to be the same as the `T` within the `Store`, the caller must 805 /// verify that. 806 pub(crate) unsafe fn new(module: &Module, items: Vec<Definition>) -> Result<InstancePre<T>> { 807 typecheck(module, &items, |cx, ty, item| cx.definition(ty, &item.ty()))?; 808 809 let mut func_refs = vec![]; 810 let mut host_funcs = 0; 811 for item in &items { 812 match item { 813 Definition::Extern(_, _) => {} 814 Definition::HostFunc(f) => { 815 host_funcs += 1; 816 if f.func_ref().wasm_call.is_none() { 817 // `f` needs its `VMFuncRef::wasm_call` patched with a 818 // Wasm-to-native trampoline. 819 debug_assert!(matches!(f.host_ctx(), crate::HostContext::Array(_))); 820 func_refs.push(VMFuncRef { 821 wasm_call: module.wasm_to_array_trampoline(f.sig_index()), 822 ..*f.func_ref() 823 }); 824 } 825 } 826 } 827 } 828 829 Ok(InstancePre { 830 module: module.clone(), 831 items: items.into(), 832 host_funcs, 833 func_refs: func_refs.into(), 834 _marker: core::marker::PhantomData, 835 }) 836 } 837 838 /// Returns a reference to the module that this [`InstancePre`] will be 839 /// instantiating. 840 pub fn module(&self) -> &Module { 841 &self.module 842 } 843 844 /// Instantiates this instance, creating a new instance within the provided 845 /// `store`. 846 /// 847 /// This function will run the actual process of instantiation to 848 /// completion. This will use all of the previously-closed-over items as 849 /// imports to instantiate the module that this was originally created with. 850 /// 851 /// For more information about instantiation see [`Instance::new`]. 852 /// 853 /// # Panics 854 /// 855 /// Panics if any import closed over by this [`InstancePre`] isn't owned by 856 /// `store`, or if `store` has async support enabled. Additionally this 857 /// function will panic if the `store` provided comes from a different 858 /// [`Engine`] than the [`InstancePre`] originally came from. 859 pub fn instantiate(&self, mut store: impl AsContextMut<Data = T>) -> Result<Instance> { 860 let mut store = store.as_context_mut(); 861 let imports = pre_instantiate_raw( 862 &mut store.0, 863 &self.module, 864 &self.items, 865 self.host_funcs, 866 &self.func_refs, 867 )?; 868 869 // This unsafety should be handled by the type-checking performed by the 870 // constructor of `InstancePre` to assert that all the imports we're passing 871 // in match the module we're instantiating. 872 unsafe { Instance::new_started(&mut store, &self.module, imports.as_ref()) } 873 } 874 875 /// Creates a new instance, running the start function asynchronously 876 /// instead of inline. 877 /// 878 /// For more information about asynchronous instantiation see the 879 /// documentation on [`Instance::new_async`]. 880 /// 881 /// # Panics 882 /// 883 /// Panics if any import closed over by this [`InstancePre`] isn't owned by 884 /// `store`, or if `store` does not have async support enabled. 885 #[cfg(feature = "async")] 886 pub async fn instantiate_async( 887 &self, 888 mut store: impl AsContextMut<Data = T>, 889 ) -> Result<Instance> 890 where 891 T: Send, 892 { 893 let mut store = store.as_context_mut(); 894 let imports = pre_instantiate_raw( 895 &mut store.0, 896 &self.module, 897 &self.items, 898 self.host_funcs, 899 &self.func_refs, 900 )?; 901 902 // This unsafety should be handled by the type-checking performed by the 903 // constructor of `InstancePre` to assert that all the imports we're passing 904 // in match the module we're instantiating. 905 unsafe { Instance::new_started_async(&mut store, &self.module, imports.as_ref()).await } 906 } 907 } 908 909 /// Helper function shared between 910 /// `InstancePre::{instantiate,instantiate_async}` 911 /// 912 /// This is an out-of-line function to avoid the generic on `InstancePre` and 913 /// get this compiled into the `wasmtime` crate to avoid having it monomorphized 914 /// elsewhere. 915 fn pre_instantiate_raw( 916 store: &mut StoreOpaque, 917 module: &Module, 918 items: &Arc<[Definition]>, 919 host_funcs: usize, 920 func_refs: &Arc<[VMFuncRef]>, 921 ) -> Result<OwnedImports> { 922 if host_funcs > 0 { 923 // Any linker-defined function of the `Definition::HostFunc` variant 924 // will insert a function into the store automatically as part of 925 // instantiation, so reserve space here to make insertion more efficient 926 // as it won't have to realloc during the instantiation. 927 store.store_data_mut().reserve_funcs(host_funcs); 928 929 // The usage of `to_extern_store_rooted` requires that the items are 930 // rooted via another means, which happens here by cloning the list of 931 // items into the store once. This avoids cloning each individual item 932 // below. 933 store.push_rooted_funcs(items.clone()); 934 store.push_instance_pre_func_refs(func_refs.clone()); 935 } 936 937 let mut func_refs = func_refs.iter().map(|f| NonNull::from(f)); 938 let mut imports = OwnedImports::new(module); 939 for import in items.iter() { 940 if !import.comes_from_same_store(store) { 941 bail!("cross-`Store` instantiation is not currently supported"); 942 } 943 // This unsafety should be encapsulated in the constructor of 944 // `InstancePre` where the `T` of the original item should match the 945 // `T` of the store. Additionally the rooting necessary has happened 946 // above. 947 let item = match import { 948 Definition::Extern(e, _) => e.clone(), 949 Definition::HostFunc(func) => unsafe { 950 func.to_func_store_rooted( 951 store, 952 if func.func_ref().wasm_call.is_none() { 953 Some(func_refs.next().unwrap()) 954 } else { 955 None 956 }, 957 ) 958 .into() 959 }, 960 }; 961 imports.push(&item, store, module); 962 } 963 964 Ok(imports) 965 } 966 967 fn typecheck<I>( 968 module: &Module, 969 import_args: &[I], 970 check: impl Fn(&matching::MatchCx<'_>, &EntityType, &I) -> Result<()>, 971 ) -> Result<()> { 972 let env_module = module.compiled_module().module(); 973 let expected_len = env_module.imports().count(); 974 let actual_len = import_args.len(); 975 if expected_len != actual_len { 976 bail!("expected {expected_len} imports, found {actual_len}"); 977 } 978 let cx = matching::MatchCx::new(module.engine()); 979 for ((name, field, mut expected_ty), actual) in env_module.imports().zip(import_args) { 980 expected_ty.canonicalize_for_runtime_usage(&mut |module_index| { 981 module.signatures().shared_type(module_index).unwrap() 982 }); 983 984 check(&cx, &expected_ty, actual) 985 .with_context(|| format!("incompatible import type for `{name}::{field}`"))?; 986 } 987 Ok(()) 988 } 989