Skip to main content

wit_component/
encoding.rs

1//! Support for encoding a core wasm module into a component.
2//!
3//! This module, at a high level, is tasked with transforming a core wasm
4//! module into a component. This will process the imports/exports of the core
5//! wasm module and translate between the `wit-parser` AST and the component
6//! model binary format, producing a final component which will import
7//! `*.wit` defined interfaces and export `*.wit` defined interfaces as well
8//! with everything wired up internally according to the canonical ABI and such.
9//!
10//! This doc block here is not currently 100% complete and doesn't cover the
11//! full functionality of this module.
12//!
13//! # Adapter Modules
14//!
15//! One feature of this encoding process which is non-obvious is the support for
16//! "adapter modules". The general idea here is that historical host API
17//! definitions have been around for quite some time, such as
18//! `wasi_snapshot_preview1`, but these host API definitions are not compatible
19//! with the canonical ABI or component model exactly. These APIs, however, can
20//! in most situations be roughly adapted to component-model equivalents. This
21//! is where adapter modules come into play, they're converting from some
22//! arbitrary API/ABI into a component-model using API.
23//!
24//! An adapter module is a separately compiled `*.wasm` blob which will export
25//! functions matching the desired ABI (e.g. exporting functions matching the
26//! `wasi_snapshot_preview1` ABI). The `*.wasm` blob will then import functions
27//! in the canonical ABI and internally adapt the exported functions to the
28//! imported functions. The encoding support in this module is what wires
29//! everything up and makes sure that everything is imported and exported to the
30//! right place. Adapter modules currently always use "indirect lowerings"
31//! meaning that a shim module is created and provided as the imports to the
32//! main core wasm module, and the shim module is "filled in" at a later time
33//! during the instantiation process.
34//!
35//! Adapter modules are not intended to be general purpose and are currently
36//! very restrictive, namely:
37//!
38//! * They must import a linear memory and not define their own linear memory
39//!   otherwise. In other words they import memory and cannot use multi-memory.
40//! * They cannot define any `elem` or `data` segments since otherwise there's
41//!   no knowledge ahead-of-time of where their data or element segments could
42//!   go. This means things like no panics, no indirect calls, etc.
43//! * If the adapter uses a shadow stack, the global that points to it must be a
44//!   mutable `i32` named `__stack_pointer`. This stack is automatically
45//!   allocated with an injected `allocate_stack` function that will either use
46//!   the main module's `cabi_realloc` export (if present) or `memory.grow`. It
47//!   allocates only 64KB of stack space, and there is no protection if that
48//!   overflows.
49//! * If the adapter has a global, mutable `i32` named `allocation_state`, it
50//!   will be used to keep track of stack allocation status and avoid infinite
51//!   recursion if the main module's `cabi_realloc` function calls back into the
52//!   adapter.  `allocate_stack` will check this global on entry; if it is zero,
53//!   it will set it to one, then allocate the stack, and finally set it to two.
54//!   If it is non-zero, `allocate_stack` will do nothing and return immediately
55//!   (because either the stack has already been allocated or is in the process
56//!   of being allocated).  If the adapter does not have an `allocation_state`,
57//!   `allocate_stack` will use `memory.grow` to allocate the stack; it will
58//!   _not_ use the main module's `cabi_realloc` even if it's available.
59//! * If the adapter imports a `cabi_realloc` function, and the main module
60//!   exports one, they'll be linked together via an alias. If the adapter
61//!   imports such a function but the main module does _not_ export one, we'll
62//!   synthesize one based on `memory.grow` (which will trap for any size other
63//!   than 64KB). Note that the main module's `cabi_realloc` function may call
64//!   back into the adapter before the shadow stack has been allocated. In this
65//!   case (when `allocation_state` is zero or one), the adapter should return
66//!   whatever dummy value(s) it can immediately without touching the stack.
67//!
68//! This means that adapter modules are not meant to be written by everyone.
69//! It's assumed that these will be relatively few and far between yet still a
70//! crucial part of the transition process from to the component model since
71//! otherwise there's no way to run a `wasi_snapshot_preview1` module within the
72//! component model.
73
74use crate::StringEncoding;
75use crate::metadata::{self, Bindgen, ModuleMetadata};
76use crate::validation::{
77    Export, ExportMap, Import, ImportInstance, ImportMap, PayloadInfo, PayloadType,
78};
79use anyhow::{Context, Result, anyhow, bail};
80use indexmap::{IndexMap, IndexSet};
81use std::borrow::Cow;
82use std::collections::HashMap;
83use std::hash::Hash;
84use std::mem;
85use wasm_encoder::*;
86use wasmparser::{Validator, WasmFeatures};
87use wit_parser::{
88    Function, FunctionKind, InterfaceId, LiveTypes, Param, Resolve, Stability, Type, TypeDefKind,
89    TypeId, TypeOwner, WorldItem, WorldKey,
90    abi::{AbiVariant, WasmSignature, WasmType},
91};
92
93const INDIRECT_TABLE_NAME: &str = "$imports";
94
95mod wit;
96pub use wit::{encode, encode_world};
97
98mod types;
99use types::{InstanceTypeEncoder, RootTypeEncoder, TypeEncodingMaps, ValtypeEncoder};
100mod world;
101use world::{ComponentWorld, ImportedInterface, Lowering};
102
103mod dedupe;
104pub(crate) use dedupe::ModuleImportMap;
105use wasm_metadata::AddMetadataField;
106
107fn to_val_type(ty: &WasmType) -> ValType {
108    match ty {
109        WasmType::I32 => ValType::I32,
110        WasmType::I64 => ValType::I64,
111        WasmType::F32 => ValType::F32,
112        WasmType::F64 => ValType::F64,
113        WasmType::Pointer => ValType::I32,
114        WasmType::PointerOrI64 => ValType::I64,
115        WasmType::Length => ValType::I32,
116    }
117}
118
119fn import_func_name(f: &Function) -> String {
120    match f.kind {
121        FunctionKind::Freestanding | FunctionKind::AsyncFreestanding => {
122            format!("import-func-{}", f.item_name())
123        }
124
125        // transform `[method]foo.bar` into `import-method-foo-bar` to
126        // have it be a valid kebab-name which can't conflict with
127        // anything else.
128        //
129        // There's probably a better and more "formal" way to do this
130        // but quick-and-dirty string manipulation should work well
131        // enough for now hopefully.
132        FunctionKind::Method(_)
133        | FunctionKind::AsyncMethod(_)
134        | FunctionKind::Static(_)
135        | FunctionKind::AsyncStatic(_)
136        | FunctionKind::Constructor(_) => {
137            format!(
138                "import-{}",
139                f.name.replace('[', "").replace([']', '.', ' '], "-")
140            )
141        }
142    }
143}
144
145bitflags::bitflags! {
146    /// Options in the `canon lower` or `canon lift` required for a particular
147    /// function.
148    #[derive(Copy, Clone, Debug)]
149    pub struct RequiredOptions: u8 {
150        /// A memory must be specified, typically the "main module"'s memory
151        /// export.
152        const MEMORY = 1 << 0;
153        /// A `realloc` function must be specified, typically named
154        /// `cabi_realloc`.
155        const REALLOC = 1 << 1;
156        /// A string encoding must be specified, which is always utf-8 for now
157        /// today.
158        const STRING_ENCODING = 1 << 2;
159        const ASYNC = 1 << 3;
160    }
161}
162
163impl RequiredOptions {
164    fn for_import(resolve: &Resolve, func: &Function, abi: AbiVariant) -> RequiredOptions {
165        let sig = resolve.wasm_signature(abi, func);
166        let mut ret = RequiredOptions::empty();
167        // Lift the params and lower the results for imports
168        ret.add_lift(TypeContents::for_types(
169            resolve,
170            func.params.iter().map(|p| &p.ty),
171        ));
172        ret.add_lower(TypeContents::for_types(resolve, &func.result));
173
174        // If anything is indirect then `memory` will be required to read the
175        // indirect values.
176        if sig.retptr || sig.indirect_params {
177            ret |= RequiredOptions::MEMORY;
178        }
179        if abi == AbiVariant::GuestImportAsync {
180            ret |= RequiredOptions::ASYNC;
181        }
182        ret
183    }
184
185    fn for_export(resolve: &Resolve, func: &Function, abi: AbiVariant) -> RequiredOptions {
186        let sig = resolve.wasm_signature(abi, func);
187        let mut ret = RequiredOptions::empty();
188        // Lower the params and lift the results for exports
189        ret.add_lower(TypeContents::for_types(
190            resolve,
191            func.params.iter().map(|p| &p.ty),
192        ));
193        ret.add_lift(TypeContents::for_types(resolve, &func.result));
194
195        // If anything is indirect then `memory` will be required to read the
196        // indirect values, but if the arguments are indirect then `realloc` is
197        // additionally required to allocate space for the parameters.
198        if sig.retptr || sig.indirect_params {
199            ret |= RequiredOptions::MEMORY;
200            if sig.indirect_params {
201                ret |= RequiredOptions::REALLOC;
202            }
203        }
204        if let AbiVariant::GuestExportAsync | AbiVariant::GuestExportAsyncStackful = abi {
205            ret |= RequiredOptions::ASYNC;
206            ret |= task_return_options_and_type(resolve, func).0;
207        }
208        ret
209    }
210
211    fn add_lower(&mut self, types: TypeContents) {
212        // If lists/strings are lowered into wasm then memory is required as
213        // usual but `realloc` is also required to allow the external caller to
214        // allocate space in the destination for the list/string.
215        if types.contains(TypeContents::NEEDS_MEMORY) {
216            *self |= RequiredOptions::MEMORY | RequiredOptions::REALLOC;
217        }
218        if types.contains(TypeContents::STRING) {
219            *self |= RequiredOptions::MEMORY
220                | RequiredOptions::STRING_ENCODING
221                | RequiredOptions::REALLOC;
222        }
223    }
224
225    fn add_lift(&mut self, types: TypeContents) {
226        // Unlike for `lower` when lifting a string/list all that's needed is
227        // memory, since the string/list already resides in memory `realloc`
228        // isn't needed.
229        if types.contains(TypeContents::NEEDS_MEMORY) {
230            *self |= RequiredOptions::MEMORY;
231        }
232        if types.contains(TypeContents::STRING) {
233            *self |= RequiredOptions::MEMORY | RequiredOptions::STRING_ENCODING;
234        }
235    }
236
237    fn into_iter(
238        self,
239        encoding: StringEncoding,
240        memory_index: Option<u32>,
241        realloc_index: Option<u32>,
242    ) -> Result<impl ExactSizeIterator<Item = CanonicalOption>> {
243        #[derive(Default)]
244        struct Iter {
245            options: [Option<CanonicalOption>; 5],
246            current: usize,
247            count: usize,
248        }
249
250        impl Iter {
251            fn push(&mut self, option: CanonicalOption) {
252                assert!(self.count < self.options.len());
253                self.options[self.count] = Some(option);
254                self.count += 1;
255            }
256        }
257
258        impl Iterator for Iter {
259            type Item = CanonicalOption;
260
261            fn next(&mut self) -> Option<Self::Item> {
262                if self.current == self.count {
263                    return None;
264                }
265                let option = self.options[self.current];
266                self.current += 1;
267                option
268            }
269
270            fn size_hint(&self) -> (usize, Option<usize>) {
271                (self.count - self.current, Some(self.count - self.current))
272            }
273        }
274
275        impl ExactSizeIterator for Iter {}
276
277        let mut iter = Iter::default();
278
279        if self.contains(RequiredOptions::MEMORY) {
280            iter.push(CanonicalOption::Memory(memory_index.ok_or_else(|| {
281                anyhow!("module does not export a memory named `memory`")
282            })?));
283        }
284
285        if self.contains(RequiredOptions::REALLOC) {
286            iter.push(CanonicalOption::Realloc(realloc_index.ok_or_else(
287                || anyhow!("module does not export a function named `cabi_realloc`"),
288            )?));
289        }
290
291        if self.contains(RequiredOptions::STRING_ENCODING) {
292            iter.push(encoding.into());
293        }
294
295        if self.contains(RequiredOptions::ASYNC) {
296            iter.push(CanonicalOption::Async);
297        }
298
299        Ok(iter)
300    }
301}
302
303bitflags::bitflags! {
304    /// Flags about what kinds of types are present within the recursive
305    /// structure of a type.
306    struct TypeContents: u8 {
307        const STRING = 1 << 0;
308        const NEEDS_MEMORY = 1 << 1;
309    }
310}
311
312impl TypeContents {
313    fn for_types<'a>(resolve: &Resolve, types: impl IntoIterator<Item = &'a Type>) -> Self {
314        let mut cur = TypeContents::empty();
315        for ty in types {
316            cur |= Self::for_type(resolve, ty);
317        }
318        cur
319    }
320
321    fn for_optional_types<'a>(
322        resolve: &Resolve,
323        types: impl Iterator<Item = Option<&'a Type>>,
324    ) -> Self {
325        Self::for_types(resolve, types.flatten())
326    }
327
328    fn for_optional_type(resolve: &Resolve, ty: Option<&Type>) -> Self {
329        match ty {
330            Some(ty) => Self::for_type(resolve, ty),
331            None => Self::empty(),
332        }
333    }
334
335    fn for_type(resolve: &Resolve, ty: &Type) -> Self {
336        match ty {
337            Type::Id(id) => match &resolve.types[*id].kind {
338                TypeDefKind::Handle(h) => match h {
339                    wit_parser::Handle::Own(_) => Self::empty(),
340                    wit_parser::Handle::Borrow(_) => Self::empty(),
341                },
342                TypeDefKind::Resource => Self::empty(),
343                TypeDefKind::Record(r) => Self::for_types(resolve, r.fields.iter().map(|f| &f.ty)),
344                TypeDefKind::Tuple(t) => Self::for_types(resolve, t.types.iter()),
345                TypeDefKind::Flags(_) => Self::empty(),
346                TypeDefKind::Option(t) => Self::for_type(resolve, t),
347                TypeDefKind::Result(r) => {
348                    Self::for_optional_type(resolve, r.ok.as_ref())
349                        | Self::for_optional_type(resolve, r.err.as_ref())
350                }
351                TypeDefKind::Variant(v) => {
352                    Self::for_optional_types(resolve, v.cases.iter().map(|c| c.ty.as_ref()))
353                }
354                TypeDefKind::Enum(_) => Self::empty(),
355                TypeDefKind::List(t) => Self::for_type(resolve, t) | Self::NEEDS_MEMORY,
356                TypeDefKind::Map(k, v) => {
357                    Self::for_type(resolve, k) | Self::for_type(resolve, v) | Self::NEEDS_MEMORY
358                }
359                TypeDefKind::FixedLengthList(t, _elements) => Self::for_type(resolve, t),
360                TypeDefKind::Type(t) => Self::for_type(resolve, t),
361                TypeDefKind::Future(_) => Self::empty(),
362                TypeDefKind::Stream(_) => Self::empty(),
363                TypeDefKind::Unknown => unreachable!(),
364            },
365            Type::String => Self::STRING,
366            _ => Self::empty(),
367        }
368    }
369}
370
371/// State relating to encoding a component.
372pub struct EncodingState<'a> {
373    /// The component being encoded.
374    component: ComponentBuilder,
375    /// The index into the core module index space for the inner core module.
376    ///
377    /// If `None`, the core module has not been encoded.
378    module_index: Option<u32>,
379    /// The index into the core instance index space for the inner core module.
380    ///
381    /// If `None`, the core module has not been instantiated.
382    instance_index: Option<u32>,
383    /// The index in the core memory index space for the exported memory.
384    ///
385    /// If `None`, then the memory has not yet been aliased.
386    memory_index: Option<u32>,
387    /// The index of the shim instance used for lowering imports into the core instance.
388    ///
389    /// If `None`, then the shim instance how not yet been encoded.
390    shim_instance_index: Option<u32>,
391    /// The index of the fixups module to instantiate to fill in the lowered imports.
392    ///
393    /// If `None`, then a fixup module has not yet been encoded.
394    fixups_module_index: Option<u32>,
395
396    /// A map of named adapter modules and the index that the module was defined
397    /// at.
398    adapter_modules: IndexMap<&'a str, u32>,
399    /// A map of adapter module instances and the index of their instance.
400    adapter_instances: IndexMap<&'a str, u32>,
401
402    /// Imported/exported instances and what index they were imported as.
403    instances: IndexMap<InterfaceId, u32>,
404    imported_funcs: IndexMap<String, u32>,
405
406    /// Maps used when translating types to the component model binary format.
407    /// Note that imports and exports are stored in separate maps since they
408    /// need fresh hierarchies of types in case the same interface is both
409    /// imported and exported.
410    type_encoding_maps: TypeEncodingMaps<'a>,
411
412    /// Cache of items that have been aliased from core instances.
413    ///
414    /// This is a helper to reduce the number of aliases created by ensuring
415    /// that repeated requests for the same item return the same index of an
416    /// original `core alias` item.
417    aliased_core_items: HashMap<(u32, String), u32>,
418
419    /// Metadata about the world inferred from the input to `ComponentEncoder`.
420    info: &'a ComponentWorld<'a>,
421
422    /// Maps from original export name to task initialization wrapper function index.
423    /// Used to wrap exports with __wasm_init_(async_)task calls.
424    export_task_initialization_wrappers: HashMap<String, u32>,
425}
426
427impl<'a> EncodingState<'a> {
428    fn encode_core_modules(&mut self) {
429        assert!(self.module_index.is_none());
430        let idx = self
431            .component
432            .core_module_raw(Some("main"), &self.info.encoder.module);
433        self.module_index = Some(idx);
434
435        for (name, adapter) in self.info.adapters.iter() {
436            let debug_name = if adapter.library_info.is_some() {
437                name.to_string()
438            } else {
439                format!("wit-component:adapter:{name}")
440            };
441            let idx = if self.info.encoder.debug_names {
442                let mut add_meta = wasm_metadata::AddMetadata::default();
443                add_meta.name = AddMetadataField::Set(debug_name.clone());
444                let wasm = add_meta
445                    .to_wasm(&adapter.wasm)
446                    .expect("core wasm can get name added");
447                self.component.core_module_raw(Some(&debug_name), &wasm)
448            } else {
449                self.component
450                    .core_module_raw(Some(&debug_name), &adapter.wasm)
451            };
452            let prev = self.adapter_modules.insert(name, idx);
453            assert!(prev.is_none());
454        }
455    }
456
457    fn root_import_type_encoder(
458        &mut self,
459        interface: Option<InterfaceId>,
460    ) -> RootTypeEncoder<'_, 'a> {
461        RootTypeEncoder {
462            state: self,
463            interface,
464            import_types: true,
465        }
466    }
467
468    fn root_export_type_encoder(
469        &mut self,
470        interface: Option<InterfaceId>,
471    ) -> RootTypeEncoder<'_, 'a> {
472        RootTypeEncoder {
473            state: self,
474            interface,
475            import_types: false,
476        }
477    }
478
479    fn instance_type_encoder(&mut self, interface: InterfaceId) -> InstanceTypeEncoder<'_, 'a> {
480        InstanceTypeEncoder {
481            state: self,
482            interface,
483            type_encoding_maps: Default::default(),
484            ty: Default::default(),
485        }
486    }
487
488    fn encode_imports(&mut self, name_map: &HashMap<String, String>) -> Result<()> {
489        let mut has_funcs = false;
490        for (name, info) in self.info.import_map.iter() {
491            match name {
492                Some(name) => {
493                    self.encode_interface_import(name_map.get(name).unwrap_or(name), info)?
494                }
495                None => has_funcs = true,
496            }
497        }
498
499        let resolve = &self.info.encoder.metadata.resolve;
500        let world = &resolve.worlds[self.info.encoder.metadata.world];
501
502        // FIXME: ideally this would use the liveness analysis from
503        // world-building to only encode live types, not all type in a world.
504        for (_name, item) in world.imports.iter() {
505            if let WorldItem::Type { id, .. } = item {
506                self.root_import_type_encoder(None)
507                    .encode_valtype(resolve, &Type::Id(*id))?;
508            }
509        }
510
511        if has_funcs {
512            let info = &self.info.import_map[&None];
513            self.encode_root_import_funcs(info)?;
514        }
515        Ok(())
516    }
517
518    fn encode_interface_import(&mut self, name: &str, info: &ImportedInterface) -> Result<()> {
519        let resolve = &self.info.encoder.metadata.resolve;
520        let interface_id = info.interface.as_ref().unwrap();
521        let interface_id = *interface_id;
522        let interface = &resolve.interfaces[interface_id];
523        log::trace!("encoding imports for `{name}` as {interface_id:?}");
524        let mut encoder = self.instance_type_encoder(interface_id);
525
526        // First encode all type information
527        if let Some(live) = encoder.state.info.live_type_imports.get(&interface_id) {
528            for ty in live {
529                log::trace!(
530                    "encoding extra type {ty:?} name={:?}",
531                    resolve.types[*ty].name
532                );
533                encoder.encode_valtype(resolve, &Type::Id(*ty))?;
534            }
535        }
536
537        // Next encode all required functions from this imported interface
538        // into the instance type.
539        for (_, func) in interface.functions.iter() {
540            if !(info
541                .lowerings
542                .contains_key(&(func.name.clone(), AbiVariant::GuestImport))
543                || info
544                    .lowerings
545                    .contains_key(&(func.name.clone(), AbiVariant::GuestImportAsync)))
546            {
547                continue;
548            }
549            log::trace!("encoding function type for `{}`", func.name);
550            let idx = encoder.encode_func_type(resolve, func)?;
551
552            encoder.ty.export(
553                crate::encoding::types::extern_name(&func.name, func.external_id.as_deref()),
554                ComponentTypeRef::Func(idx),
555            );
556        }
557
558        let ty = encoder.ty;
559        // Don't encode empty instance types since they're not
560        // meaningful to the runtime of the component anyway.
561        if ty.is_empty() {
562            return Ok(());
563        }
564        let instance_type_idx = self
565            .component
566            .type_instance(Some(&format!("ty-{name}")), &ty);
567        let instance_idx = self.component.import(
568            wasm_encoder::ComponentExternName {
569                name: name.into(),
570                implements: info.implements.as_deref().map(|s| s.into()),
571                external_id: info.external_id.as_deref().map(|s| s.into()),
572                version_suffix: None,
573            },
574            ComponentTypeRef::Instance(instance_type_idx),
575        );
576        let prev = self.instances.insert(interface_id, instance_idx);
577        assert!(prev.is_none());
578        Ok(())
579    }
580
581    fn encode_root_import_funcs(&mut self, info: &ImportedInterface) -> Result<()> {
582        let resolve = &self.info.encoder.metadata.resolve;
583        let world = self.info.encoder.metadata.world;
584        for (name, item) in resolve.worlds[world].imports.iter() {
585            let func = match item {
586                WorldItem::Function(f) => f,
587                WorldItem::Interface { .. } | WorldItem::Type { .. } => continue,
588            };
589            let name = resolve.name_world_key(name);
590            if !(info
591                .lowerings
592                .contains_key(&(name.clone(), AbiVariant::GuestImport))
593                || info
594                    .lowerings
595                    .contains_key(&(name.clone(), AbiVariant::GuestImportAsync)))
596            {
597                continue;
598            }
599            log::trace!("encoding function type for `{}`", func.name);
600            let idx = self
601                .root_import_type_encoder(None)
602                .encode_func_type(resolve, func)?;
603            let func_idx = self.component.import(
604                crate::encoding::types::extern_name(name.as_str(), func.external_id.as_deref()),
605                ComponentTypeRef::Func(idx),
606            );
607            let prev = self.imported_funcs.insert(name, func_idx);
608            assert!(prev.is_none());
609        }
610        Ok(())
611    }
612
613    fn alias_instance_type_export(&mut self, interface: InterfaceId, id: TypeId) -> u32 {
614        let ty = &self.info.encoder.metadata.resolve.types[id];
615        let name = ty.name.as_ref().expect("type must have a name");
616        let instance = self.instances[&interface];
617        self.component
618            .alias_export(instance, name, ComponentExportKind::Type)
619    }
620
621    fn encode_core_instantiation(&mut self) -> Result<()> {
622        // Encode a shim instantiation if needed
623        let shims = self.encode_shim_instantiation()?;
624
625        // Next declare any types needed for imported intrinsics. This
626        // populates `export_type_map` and will additionally be used for
627        // imports to modules instantiated below.
628        self.declare_types_for_imported_intrinsics(&shims)?;
629
630        // Next instantiate the main module. This provides the linear memory to
631        // use for all future adapters and enables creating indirect lowerings
632        // at the end.
633        self.instantiate_main_module(&shims)?;
634
635        // Create any wrappers needed for initializing tasks if task initialization
636        // exports are present in the main module.
637        self.create_export_task_initialization_wrappers()?;
638
639        // Separate the adapters according which should be instantiated before
640        // and after indirect lowerings are encoded.
641        let (before, after) = self
642            .info
643            .adapters
644            .iter()
645            .partition::<Vec<_>, _>(|(_, adapter)| {
646                !matches!(
647                    adapter.library_info,
648                    Some(LibraryInfo {
649                        instantiate_after_shims: true,
650                        ..
651                    })
652                )
653            });
654
655        for (name, _adapter) in before {
656            self.instantiate_adapter_module(&shims, name)?;
657        }
658
659        // With all the relevant core wasm instances in play now the original shim
660        // module, if present, can be filled in with lowerings/adapters/etc.
661        self.encode_indirect_lowerings(&shims)?;
662
663        for (name, _adapter) in after {
664            self.instantiate_adapter_module(&shims, name)?;
665        }
666
667        self.encode_initialize_with_start()?;
668
669        Ok(())
670    }
671
672    fn lookup_resource_index(&mut self, id: TypeId) -> u32 {
673        let resolve = &self.info.encoder.metadata.resolve;
674        let ty = &resolve.types[id];
675        match ty.owner {
676            // If this resource is owned by a world then it's a top-level
677            // resource which means it must have already been translated so
678            // it's available for lookup in `import_type_map`.
679            TypeOwner::World(_) => self.type_encoding_maps.id_to_index[&id],
680            TypeOwner::Interface(i) => {
681                let instance = self.instances[&i];
682                let name = ty.name.as_ref().expect("resources must be named");
683                self.component
684                    .alias_export(instance, name, ComponentExportKind::Type)
685            }
686            TypeOwner::None => panic!("resources must have an owner"),
687        }
688    }
689
690    fn encode_exports(&mut self, module: CustomModule) -> Result<()> {
691        let resolve = &self.info.encoder.metadata.resolve;
692        let exports = match module {
693            CustomModule::Main => &self.info.encoder.main_module_exports,
694            CustomModule::Adapter(name) => &self.info.encoder.adapters[name].required_exports,
695        };
696
697        if exports.is_empty() {
698            return Ok(());
699        }
700
701        let mut interface_func_core_names = IndexMap::new();
702        let mut world_func_core_names = IndexMap::new();
703        for (core_name, export) in self.info.exports_for(module).iter() {
704            match export {
705                Export::WorldFunc(_, name, _) => {
706                    let prev = world_func_core_names.insert(name, core_name);
707                    assert!(prev.is_none());
708                }
709                Export::InterfaceFunc(key, _, name, _) => {
710                    let prev = interface_func_core_names
711                        .entry(key)
712                        .or_insert(IndexMap::new())
713                        .insert(name.as_str(), core_name);
714                    assert!(prev.is_none());
715                }
716                Export::WorldFuncCallback(..)
717                | Export::InterfaceFuncCallback(..)
718                | Export::WorldFuncPostReturn(..)
719                | Export::InterfaceFuncPostReturn(..)
720                | Export::ResourceDtor(..)
721                | Export::Memory
722                | Export::GeneralPurposeRealloc
723                | Export::GeneralPurposeExportRealloc
724                | Export::GeneralPurposeImportRealloc
725                | Export::Initialize
726                | Export::ReallocForAdapter
727                | Export::IndirectFunctionTable
728                | Export::WasmInitTask
729                | Export::WasmInitAsyncTask => continue,
730            }
731        }
732
733        let world = &resolve.worlds[self.info.encoder.metadata.world];
734
735        for export_name in exports {
736            let export_string = resolve.name_world_key(export_name);
737            match &world.exports[export_name] {
738                WorldItem::Function(func) => {
739                    let ty = self
740                        .root_import_type_encoder(None)
741                        .encode_func_type(resolve, func)?;
742                    let core_name = world_func_core_names[&func.name];
743                    let idx = self.encode_lift(module, &core_name, export_name, func, ty)?;
744                    self.component.export(
745                        crate::encoding::types::extern_name(
746                            &export_string,
747                            func.external_id.as_deref(),
748                        ),
749                        ComponentExportKind::Func,
750                        idx,
751                        None,
752                    );
753                }
754                item @ WorldItem::Interface { id, .. } => {
755                    let core_names = interface_func_core_names.get(export_name);
756                    self.encode_interface_export(
757                        &export_string,
758                        module,
759                        export_name,
760                        item,
761                        *id,
762                        core_names,
763                    )?;
764                }
765                WorldItem::Type { .. } => unreachable!(),
766            }
767        }
768
769        Ok(())
770    }
771
772    fn encode_interface_export(
773        &mut self,
774        export_name: &str,
775        module: CustomModule<'_>,
776        key: &WorldKey,
777        item: &WorldItem,
778        export: InterfaceId,
779        interface_func_core_names: Option<&IndexMap<&str, &str>>,
780    ) -> Result<()> {
781        log::trace!("encode interface export `{export_name}`");
782        let resolve = &self.info.encoder.metadata.resolve;
783
784        // First execute a `canon lift` for all the functions in this interface
785        // from the core wasm export. This requires type information but notably
786        // not exported type information since we don't want to export this
787        // interface's types from the root of the component. Each lifted
788        // function is saved off into an `imports` array to get imported into
789        // the nested component synthesized below.
790        let mut imports = Vec::new();
791        let mut root = self.root_export_type_encoder(Some(export));
792        for (_, func) in &resolve.interfaces[export].functions {
793            let core_name = interface_func_core_names.unwrap()[func.name.as_str()];
794            let ty = root.encode_func_type(resolve, func)?;
795            let func_index = root.state.encode_lift(module, &core_name, key, func, ty)?;
796            imports.push((
797                import_func_name(func),
798                ComponentExportKind::Func,
799                func_index,
800            ));
801        }
802
803        // Next a nested component is created which will import the functions
804        // above and then reexport them. The purpose of them is to "re-type" the
805        // functions through type ascription on each `func` item.
806        let mut nested = NestedComponentTypeEncoder {
807            component: ComponentBuilder::default(),
808            type_encoding_maps: Default::default(),
809            export_types: false,
810            interface: export,
811            state: self,
812            imports: IndexMap::new(),
813        };
814
815        // Import all transitively-referenced types from other interfaces into
816        // this component. This temporarily switches the `interface` listed to
817        // the interface of the referred-to-type to generate the import. After
818        // this loop `interface` is rewritten to `export`.
819        //
820        // Each component is a standalone "island" so the necessary type
821        // information needs to be rebuilt within this component. This ensures
822        // that we're able to build a valid component and additionally connect
823        // all the type information to the outer context.
824        let mut types_to_import = LiveTypes::default();
825        types_to_import.add_interface(resolve, export);
826        let exports_used = &nested.state.info.exports_used[&export];
827        for ty in types_to_import.iter() {
828            if let TypeOwner::Interface(owner) = resolve.types[ty].owner {
829                if owner == export {
830                    // Here this deals with the current exported interface which
831                    // is handled below.
832                    continue;
833                }
834
835                // Ensure that `self` has encoded this type before. If so this
836                // is a noop but otherwise it generates the type here.
837                let mut encoder = if exports_used.contains(&owner) {
838                    nested.state.root_export_type_encoder(Some(export))
839                } else {
840                    nested.state.root_import_type_encoder(Some(export))
841                };
842                encoder.encode_valtype(resolve, &Type::Id(ty))?;
843
844                // Next generate the same type but this time within the
845                // component itself. The type generated above (or prior) will be
846                // used to satisfy this type import.
847                nested.interface = owner;
848                nested.encode_valtype(resolve, &Type::Id(ty))?;
849            }
850        }
851        nested.interface = export;
852
853        // Record the map of types imported to their index at where they were
854        // imported. This is used after imports are encoded as exported types
855        // will refer to these.
856        let imported_type_maps = nested.type_encoding_maps.clone();
857
858        // Handle resource types for this instance specially, namely importing
859        // them into the nested component. This models how the resource is
860        // imported from its definition in the outer component to get reexported
861        // internally. This chiefly avoids creating a second resource which is
862        // not desired in this situation.
863        let mut resources = HashMap::new();
864        for (_name, ty) in resolve.interfaces[export].types.iter() {
865            if !matches!(resolve.types[*ty].kind, TypeDefKind::Resource) {
866                continue;
867            }
868            let idx = match nested.encode_valtype(resolve, &Type::Id(*ty))? {
869                ComponentValType::Type(idx) => idx,
870                _ => unreachable!(),
871            };
872            resources.insert(*ty, idx);
873        }
874
875        // Next import each function of this interface. This will end up
876        // defining local types as necessary or using the types as imported
877        // above.
878        for (_, func) in resolve.interfaces[export].functions.iter() {
879            let ty = nested.encode_func_type(resolve, func)?;
880            nested
881                .component
882                .import(&import_func_name(func), ComponentTypeRef::Func(ty));
883        }
884
885        // Swap the `nested.type_map` which was previously from `TypeId` to
886        // `u32` to instead being from `u32` to `TypeId`. This reverse map is
887        // then used in conjunction with `self.type_map` to satisfy all type
888        // imports of the nested component generated. The type import's index in
889        // the inner component is translated to a `TypeId` via `reverse_map`
890        // which is then translated back to our own index space via `type_map`.
891        let reverse_map = nested
892            .type_encoding_maps
893            .id_to_index
894            .drain()
895            .map(|p| (p.1, p.0))
896            .collect::<HashMap<_, _>>();
897        nested.type_encoding_maps.def_to_index.clear();
898        for (name, idx) in nested.imports.drain(..) {
899            let id = reverse_map[&idx];
900            let idx = nested.state.type_encoding_maps.id_to_index[&id];
901            imports.push((name, ComponentExportKind::Type, idx))
902        }
903
904        // Before encoding exports reset the type map to what all was imported
905        // from foreign interfaces. This will enable any encoded types below to
906        // refer to imports which, after type substitution, will point to the
907        // correct type in the outer component context.
908        nested.type_encoding_maps = imported_type_maps;
909
910        // Next the component reexports all of its imports, but notably uses the
911        // type ascription feature to change the type of the function. Note that
912        // no structural change is happening to the types here but instead types
913        // are getting proper names and such now that this nested component is a
914        // new type index space. Hence the `export_types = true` flag here which
915        // flows through the type encoding and when types are emitted.
916        nested.export_types = true;
917        nested.type_encoding_maps.func_type_map.clear();
918
919        // To start off all type information is encoded. This will be used by
920        // functions below but notably this also has special handling for
921        // resources. Resources reexport their imported resource type under
922        // the final name which achieves the desired goal of threading through
923        // the original resource without creating a new one.
924        for (_, id) in resolve.interfaces[export].types.iter() {
925            let ty = &resolve.types[*id];
926            match ty.kind {
927                TypeDefKind::Resource => {
928                    let idx = nested.component.export(
929                        crate::encoding::types::extern_name(
930                            ty.name.as_ref().expect("resources must be named"),
931                            ty.external_id.as_deref(),
932                        ),
933                        ComponentExportKind::Type,
934                        resources[id],
935                        None,
936                    );
937                    nested.type_encoding_maps.id_to_index.insert(*id, idx);
938                }
939                _ => {
940                    nested.encode_valtype(resolve, &Type::Id(*id))?;
941                }
942            }
943        }
944
945        for (i, (_, func)) in resolve.interfaces[export].functions.iter().enumerate() {
946            let ty = nested.encode_func_type(resolve, func)?;
947            nested.component.export(
948                crate::encoding::types::extern_name(&func.name, func.external_id.as_deref()),
949                ComponentExportKind::Func,
950                i as u32,
951                Some(ComponentTypeRef::Func(ty)),
952            );
953        }
954
955        // Embed the component within our component and then instantiate it with
956        // the lifted functions. That final instance is then exported under the
957        // appropriate name as the final typed export of this component.
958        let component = nested.component;
959        let component_index = self
960            .component
961            .component(Some(&format!("{export_name}-shim-component")), component);
962        let instance_index = self.component.instantiate(
963            Some(&format!("{export_name}-shim-instance")),
964            component_index,
965            imports,
966        );
967        let idx = self.component.export(
968            wasm_encoder::ComponentExternName {
969                name: export_name.into(),
970                implements: resolve.implements_value(key, item).map(|s| s.into()),
971                external_id: resolve.external_id_value(key, item).map(|s| s.into()),
972                version_suffix: None,
973            },
974            ComponentExportKind::Instance,
975            instance_index,
976            None,
977        );
978        let prev = self.instances.insert(export, idx);
979        assert!(prev.is_none());
980
981        // After everything is all said and done remove all the type information
982        // about type exports of this interface. Any entries in the map
983        // currently were used to create the instance above but aren't the
984        // actual copy of the exported type since that comes from the exported
985        // instance itself. Entries will be re-inserted into this map as
986        // necessary via aliases from the exported instance which is the new
987        // source of truth for all these types.
988        for (_name, id) in resolve.interfaces[export].types.iter() {
989            self.type_encoding_maps.id_to_index.remove(id);
990            self.type_encoding_maps
991                .def_to_index
992                .remove(&resolve.types[*id].kind);
993        }
994
995        return Ok(());
996
997        struct NestedComponentTypeEncoder<'state, 'a> {
998            component: ComponentBuilder,
999            type_encoding_maps: TypeEncodingMaps<'a>,
1000            export_types: bool,
1001            interface: InterfaceId,
1002            state: &'state mut EncodingState<'a>,
1003            imports: IndexMap<String, u32>,
1004        }
1005
1006        impl<'a> ValtypeEncoder<'a> for NestedComponentTypeEncoder<'_, 'a> {
1007            fn defined_type(&mut self) -> (u32, ComponentDefinedTypeEncoder<'_>) {
1008                self.component.type_defined(None)
1009            }
1010            fn define_function_type(&mut self) -> (u32, ComponentFuncTypeEncoder<'_>) {
1011                self.component.type_function(None)
1012            }
1013            fn export_type(
1014                &mut self,
1015                idx: u32,
1016                name: wasm_encoder::ComponentExternName<'a>,
1017            ) -> Option<u32> {
1018                if self.export_types {
1019                    Some(
1020                        self.component
1021                            .export(name, ComponentExportKind::Type, idx, None),
1022                    )
1023                } else {
1024                    let name = self.unique_import_name(&name.name);
1025                    let ret = self
1026                        .component
1027                        .import(&name, ComponentTypeRef::Type(TypeBounds::Eq(idx)));
1028                    self.imports.insert(name, ret);
1029                    Some(ret)
1030                }
1031            }
1032            fn export_resource(&mut self, name: wasm_encoder::ComponentExternName<'a>) -> u32 {
1033                if self.export_types {
1034                    panic!("resources should already be exported")
1035                } else {
1036                    let name = self.unique_import_name(&name.name);
1037                    let ret = self
1038                        .component
1039                        .import(&name, ComponentTypeRef::Type(TypeBounds::SubResource));
1040                    self.imports.insert(name, ret);
1041                    ret
1042                }
1043            }
1044            fn import_type(&mut self, _: InterfaceId, _id: TypeId) -> u32 {
1045                unreachable!()
1046            }
1047            fn type_encoding_maps(&mut self) -> &mut TypeEncodingMaps<'a> {
1048                &mut self.type_encoding_maps
1049            }
1050            fn interface(&self) -> Option<InterfaceId> {
1051                Some(self.interface)
1052            }
1053        }
1054
1055        impl NestedComponentTypeEncoder<'_, '_> {
1056            fn unique_import_name(&mut self, name: &str) -> String {
1057                let mut name = format!("import-type-{name}");
1058                let mut n = 0;
1059                while self.imports.contains_key(&name) {
1060                    name = format!("{name}{n}");
1061                    n += 1;
1062                }
1063                name
1064            }
1065        }
1066    }
1067
1068    fn encode_lift(
1069        &mut self,
1070        module: CustomModule<'_>,
1071        core_name: &str,
1072        key: &WorldKey,
1073        func: &Function,
1074        ty: u32,
1075    ) -> Result<u32> {
1076        let resolve = &self.info.encoder.metadata.resolve;
1077        let metadata = self.info.module_metadata_for(module);
1078        let instance_index = self.instance_for(module);
1079        // If we generated an init task wrapper for this export, use that,
1080        // otherwise alias the original export.
1081        let core_func_index =
1082            if let Some(&wrapper_idx) = self.export_task_initialization_wrappers.get(core_name) {
1083                wrapper_idx
1084            } else {
1085                self.core_alias_export(Some(core_name), instance_index, core_name, ExportKind::Func)
1086            };
1087        let exports = self.info.exports_for(module);
1088
1089        let options = RequiredOptions::for_export(
1090            resolve,
1091            func,
1092            exports
1093                .abi(key, func)
1094                .ok_or_else(|| anyhow!("no ABI found for {}", func.name))?,
1095        );
1096
1097        let encoding = metadata
1098            .export_encodings
1099            .get(resolve, key, &func.name)
1100            .unwrap();
1101        let exports = self.info.exports_for(module);
1102        let realloc_index = exports
1103            .export_realloc_for(key, &func.name)
1104            .map(|name| self.core_alias_export(Some(name), instance_index, name, ExportKind::Func));
1105        let mut options = options
1106            .into_iter(encoding, self.memory_index, realloc_index)?
1107            .collect::<Vec<_>>();
1108
1109        if let Some(post_return) = exports.post_return(key, func) {
1110            let post_return = self.core_alias_export(
1111                Some(post_return),
1112                instance_index,
1113                post_return,
1114                ExportKind::Func,
1115            );
1116            options.push(CanonicalOption::PostReturn(post_return));
1117        }
1118        if let Some(callback) = exports.callback(key, func) {
1119            let callback =
1120                self.core_alias_export(Some(callback), instance_index, callback, ExportKind::Func);
1121            options.push(CanonicalOption::Callback(callback));
1122        }
1123        let func_index = self
1124            .component
1125            .lift_func(Some(&func.name), core_func_index, ty, options);
1126        Ok(func_index)
1127    }
1128
1129    fn encode_shim_instantiation(&mut self) -> Result<Shims<'a>> {
1130        let mut ret = Shims::default();
1131
1132        ret.append_indirect(self.info, CustomModule::Main)
1133            .context("failed to register indirect shims for main module")?;
1134
1135        // For all required adapter modules a shim is created for each required
1136        // function and additionally a set of shims are created for the
1137        // interface imported into the shim module itself.
1138        for (adapter_name, _adapter) in self.info.adapters.iter() {
1139            ret.append_indirect(self.info, CustomModule::Adapter(adapter_name))
1140                .with_context(|| {
1141                    format!("failed to register indirect shims for adapter {adapter_name}")
1142                })?;
1143        }
1144
1145        if ret.shims.is_empty() {
1146            return Ok(ret);
1147        }
1148
1149        assert!(self.shim_instance_index.is_none());
1150        assert!(self.fixups_module_index.is_none());
1151
1152        // This function encodes two modules:
1153        // - A shim module that defines a table and exports functions
1154        //   that indirectly call through the table.
1155        // - A fixup module that imports that table and a set of functions
1156        //   and populates the imported table via active element segments. The
1157        //   fixup module is used to populate the shim's table once the
1158        //   imported functions have been lowered.
1159
1160        let mut types = TypeSection::new();
1161        let mut tables = TableSection::new();
1162        let mut functions = FunctionSection::new();
1163        let mut exports = ExportSection::new();
1164        let mut code = CodeSection::new();
1165        let mut sigs = IndexMap::new();
1166        let mut imports_section = ImportSection::new();
1167        let mut elements = ElementSection::new();
1168        let mut func_indexes = Vec::new();
1169        let mut func_names = NameMap::new();
1170
1171        for (i, shim) in ret.shims.values().enumerate() {
1172            let i = i as u32;
1173            let type_index = *sigs.entry(&shim.sig).or_insert_with(|| {
1174                let index = types.len();
1175                types.ty().function(
1176                    shim.sig.params.iter().map(to_val_type),
1177                    shim.sig.results.iter().map(to_val_type),
1178                );
1179                index
1180            });
1181
1182            functions.function(type_index);
1183            Self::encode_shim_function(type_index, i, &mut code, shim.sig.params.len() as u32);
1184            exports.export(&shim.name, ExportKind::Func, i);
1185
1186            imports_section.import("", &shim.name, EntityType::Function(type_index));
1187            func_indexes.push(i);
1188            func_names.append(i, &shim.debug_name);
1189        }
1190        let mut names = NameSection::new();
1191        names.module("wit-component:shim");
1192        names.functions(&func_names);
1193
1194        let table_type = TableType {
1195            element_type: RefType::FUNCREF,
1196            minimum: ret.shims.len() as u64,
1197            maximum: Some(ret.shims.len() as u64),
1198            table64: false,
1199            shared: false,
1200        };
1201
1202        tables.table(table_type);
1203
1204        exports.export(INDIRECT_TABLE_NAME, ExportKind::Table, 0);
1205        imports_section.import("", INDIRECT_TABLE_NAME, table_type);
1206
1207        elements.active(
1208            None,
1209            &ConstExpr::i32_const(0),
1210            Elements::Functions(func_indexes.into()),
1211        );
1212
1213        let mut shim = Module::new();
1214        shim.section(&types);
1215        shim.section(&functions);
1216        shim.section(&tables);
1217        shim.section(&exports);
1218        shim.section(&code);
1219        shim.section(&RawCustomSection(
1220            &crate::base_producers().raw_custom_section(),
1221        ));
1222        if self.info.encoder.debug_names {
1223            shim.section(&names);
1224        }
1225
1226        let mut fixups = Module::default();
1227        fixups.section(&types);
1228        fixups.section(&imports_section);
1229        fixups.section(&elements);
1230        fixups.section(&RawCustomSection(
1231            &crate::base_producers().raw_custom_section(),
1232        ));
1233
1234        if self.info.encoder.debug_names {
1235            let mut names = NameSection::new();
1236            names.module("wit-component:fixups");
1237            fixups.section(&names);
1238        }
1239
1240        let shim_module_index = self
1241            .component
1242            .core_module(Some("wit-component-shim-module"), &shim);
1243        let fixup_index = self
1244            .component
1245            .core_module(Some("wit-component-fixup"), &fixups);
1246        self.fixups_module_index = Some(fixup_index);
1247        let shim_instance = self.component.core_instantiate(
1248            Some("wit-component-shim-instance"),
1249            shim_module_index,
1250            [],
1251        );
1252        self.shim_instance_index = Some(shim_instance);
1253
1254        return Ok(ret);
1255    }
1256
1257    fn encode_shim_function(
1258        type_index: u32,
1259        func_index: u32,
1260        code: &mut CodeSection,
1261        param_count: u32,
1262    ) {
1263        let mut func = wasm_encoder::Function::new(std::iter::empty());
1264        for i in 0..param_count {
1265            func.instructions().local_get(i);
1266        }
1267        func.instructions().i32_const(func_index as i32);
1268        func.instructions().call_indirect(0, type_index);
1269        func.instructions().end();
1270        code.function(&func);
1271    }
1272
1273    fn encode_indirect_lowerings(&mut self, shims: &Shims<'_>) -> Result<()> {
1274        if shims.shims.is_empty() {
1275            return Ok(());
1276        }
1277
1278        let shim_instance_index = self
1279            .shim_instance_index
1280            .expect("must have an instantiated shim");
1281
1282        let table_index = self.core_alias_export(
1283            Some("shim table"),
1284            shim_instance_index,
1285            INDIRECT_TABLE_NAME,
1286            ExportKind::Table,
1287        );
1288
1289        let resolve = &self.info.encoder.metadata.resolve;
1290
1291        let mut exports = Vec::new();
1292        exports.push((INDIRECT_TABLE_NAME, ExportKind::Table, table_index));
1293
1294        for shim in shims.shims.values() {
1295            let core_func_index = match &shim.kind {
1296                // Indirect lowerings are a `canon lower`'d function with
1297                // options specified from a previously instantiated instance.
1298                // This previous instance could either be the main module or an
1299                // adapter module, which affects the `realloc` option here.
1300                // Currently only one linear memory is supported so the linear
1301                // memory always comes from the main module.
1302                ShimKind::IndirectLowering {
1303                    interface,
1304                    index,
1305                    realloc,
1306                    encoding,
1307                } => {
1308                    let interface = &self.info.import_map[interface];
1309                    let ((name, _), _) = interface.lowerings.get_index(*index).unwrap();
1310                    let func_index = match &interface.interface {
1311                        Some(interface_id) => {
1312                            let instance_index = self.instances[interface_id];
1313                            self.component.alias_export(
1314                                instance_index,
1315                                name,
1316                                ComponentExportKind::Func,
1317                            )
1318                        }
1319                        None => self.imported_funcs[name],
1320                    };
1321
1322                    let realloc = self
1323                        .info
1324                        .exports_for(*realloc)
1325                        .import_realloc_for(interface.interface, name)
1326                        .map(|name| {
1327                            let instance = self.instance_for(*realloc);
1328                            self.core_alias_export(
1329                                Some("realloc"),
1330                                instance,
1331                                name,
1332                                ExportKind::Func,
1333                            )
1334                        });
1335
1336                    self.component.lower_func(
1337                        Some(&shim.debug_name),
1338                        func_index,
1339                        shim.options
1340                            .into_iter(*encoding, self.memory_index, realloc)?,
1341                    )
1342                }
1343
1344                // Adapter shims are defined by an export from an adapter
1345                // instance, so use the specified name here and the previously
1346                // created instances to get the core item that represents the
1347                // shim.
1348                ShimKind::Adapter { adapter, func } => self.core_alias_export(
1349                    Some(func),
1350                    self.adapter_instances[adapter],
1351                    func,
1352                    ExportKind::Func,
1353                ),
1354
1355                // Resources are required for a module to be instantiated
1356                // meaning that any destructor for the resource must be called
1357                // indirectly due to the otherwise circular dependency between
1358                // the module and the resource itself.
1359                ShimKind::ResourceDtor { module, export } => self.core_alias_export(
1360                    Some(export),
1361                    self.instance_for(*module),
1362                    export,
1363                    ExportKind::Func,
1364                ),
1365
1366                ShimKind::PayloadFunc {
1367                    for_module,
1368                    info,
1369                    kind,
1370                } => {
1371                    let metadata = self.info.module_metadata_for(*for_module);
1372                    let exports = self.info.exports_for(*for_module);
1373                    let instance_index = self.instance_for(*for_module);
1374                    let (encoding, realloc) = match &info.ty {
1375                        PayloadType::Type { function, .. } => {
1376                            if info.imported {
1377                                (
1378                                    metadata.import_encodings.get(resolve, &info.key, function),
1379                                    exports.import_realloc_for(info.interface, function),
1380                                )
1381                            } else {
1382                                (
1383                                    metadata.export_encodings.get(resolve, &info.key, function),
1384                                    exports.export_realloc_for(&info.key, function),
1385                                )
1386                            }
1387                        }
1388                        PayloadType::UnitFuture | PayloadType::UnitStream => (None, None),
1389                    };
1390                    let encoding = encoding.unwrap_or(StringEncoding::UTF8);
1391                    let realloc_index = realloc.map(|name| {
1392                        self.core_alias_export(
1393                            Some("realloc"),
1394                            instance_index,
1395                            name,
1396                            ExportKind::Func,
1397                        )
1398                    });
1399                    let type_index = self.payload_type_index(info)?;
1400                    let options =
1401                        shim.options
1402                            .into_iter(encoding, self.memory_index, realloc_index)?;
1403
1404                    match kind {
1405                        PayloadFuncKind::FutureWrite => {
1406                            self.component.future_write(type_index, options)
1407                        }
1408                        PayloadFuncKind::FutureRead => {
1409                            self.component.future_read(type_index, options)
1410                        }
1411                        PayloadFuncKind::StreamWrite => {
1412                            self.component.stream_write(type_index, options)
1413                        }
1414                        PayloadFuncKind::StreamRead => {
1415                            self.component.stream_read(type_index, options)
1416                        }
1417                    }
1418                }
1419
1420                ShimKind::WaitableSetWait { cancellable } => self
1421                    .component
1422                    .waitable_set_wait(*cancellable, self.memory_index.unwrap()),
1423                ShimKind::WaitableSetPoll { cancellable } => self
1424                    .component
1425                    .waitable_set_poll(*cancellable, self.memory_index.unwrap()),
1426                ShimKind::ErrorContextNew { encoding } => self.component.error_context_new(
1427                    shim.options.into_iter(*encoding, self.memory_index, None)?,
1428                ),
1429                ShimKind::ErrorContextDebugMessage {
1430                    for_module,
1431                    encoding,
1432                } => {
1433                    let instance_index = self.instance_for(*for_module);
1434                    let realloc = self.info.exports_for(*for_module).import_realloc_fallback();
1435                    let realloc_index = realloc.map(|r| {
1436                        self.core_alias_export(Some("realloc"), instance_index, r, ExportKind::Func)
1437                    });
1438
1439                    self.component
1440                        .error_context_debug_message(shim.options.into_iter(
1441                            *encoding,
1442                            self.memory_index,
1443                            realloc_index,
1444                        )?)
1445                }
1446                ShimKind::TaskReturn {
1447                    interface,
1448                    func,
1449                    result,
1450                    encoding,
1451                    for_module,
1452                } => {
1453                    // See `Import::ExportedTaskReturn` handling for why this
1454                    // encoder is treated specially.
1455                    let mut encoder = if interface.is_none() {
1456                        self.root_import_type_encoder(*interface)
1457                    } else {
1458                        self.root_export_type_encoder(*interface)
1459                    };
1460                    let result = match result {
1461                        Some(ty) => Some(encoder.encode_valtype(resolve, ty)?),
1462                        None => None,
1463                    };
1464
1465                    let exports = self.info.exports_for(*for_module);
1466                    let realloc = exports.import_realloc_for(*interface, func);
1467
1468                    let instance_index = self.instance_for(*for_module);
1469                    let realloc_index = realloc.map(|r| {
1470                        self.core_alias_export(Some("realloc"), instance_index, r, ExportKind::Func)
1471                    });
1472                    let options =
1473                        shim.options
1474                            .into_iter(*encoding, self.memory_index, realloc_index)?;
1475                    self.component.task_return(result, options)
1476                }
1477                ShimKind::ThreadNewIndirect {
1478                    for_module,
1479                    func_ty,
1480                } => {
1481                    // Encode the function type for the thread start function so we can reference it in the `canon` call.
1482                    let (func_ty_idx, f) = self.component.core_type(Some("thread-start"));
1483                    f.core().func_type(func_ty);
1484
1485                    // In order for the funcref table referenced by `thread.new-indirect` to be used,
1486                    // it must have been exported by the module.
1487                    let exports = self.info.exports_for(*for_module);
1488                    let instance_index = self.instance_for(*for_module);
1489                    let table_idx = exports.indirect_function_table().map(|table| {
1490                        self.core_alias_export(
1491                            Some("indirect-function-table"),
1492                            instance_index,
1493                            table,
1494                            ExportKind::Table,
1495                        )
1496                    }).ok_or_else(|| {
1497                        anyhow!(
1498                            "table __indirect_function_table must be an exported funcref table for thread.new-indirect"
1499                        )
1500                    })?;
1501
1502                    self.component.thread_new_indirect(func_ty_idx, table_idx)
1503                }
1504            };
1505
1506            exports.push((shim.name.as_str(), ExportKind::Func, core_func_index));
1507        }
1508
1509        let instance_index = self
1510            .component
1511            .core_instantiate_exports(Some("fixup-args"), exports);
1512        self.component.core_instantiate(
1513            Some("fixup"),
1514            self.fixups_module_index.expect("must have fixup module"),
1515            [("", ModuleArg::Instance(instance_index))],
1516        );
1517        Ok(())
1518    }
1519
1520    /// Encode the specified `stream` or `future` type in the component using
1521    /// either the `root_import_type_encoder` or the `root_export_type_encoder`
1522    /// depending on the value of `imported`.
1523    ///
1524    /// Note that the payload type `T` of `stream<T>` or `future<T>` may be an
1525    /// imported or exported type, and that determines the appropriate type
1526    /// encoder to use.
1527    fn payload_type_index(&mut self, info: &PayloadInfo) -> Result<u32> {
1528        let resolve = &self.info.encoder.metadata.resolve;
1529        // What exactly is selected here as the encoder is a bit unusual here.
1530        // If the interface is imported, an import encoder is used. An import
1531        // encoder is also used though if `info` is exported and
1532        // `info.interface` is `None`, meaning that this is for a function that
1533        // is in the top-level of a world. At the top level of a world all
1534        // types are imported.
1535        //
1536        // Additionally for the import encoder the interface passed in is
1537        // `None`, not `info.interface`. Notably this means that references to
1538        // named types will be aliased from their imported versions, which is
1539        // what we want here.
1540        //
1541        // Finally though exports do use `info.interface`. Honestly I'm not
1542        // really entirely sure why. Fuzzing is happy though, and truly
1543        // everything must be ok if the fuzzers are happy, right?
1544        let mut encoder = if info.imported || info.interface.is_none() {
1545            self.root_import_type_encoder(None)
1546        } else {
1547            self.root_export_type_encoder(info.interface)
1548        };
1549        match info.ty {
1550            PayloadType::Type { id, .. } => match encoder.encode_valtype(resolve, &Type::Id(id))? {
1551                ComponentValType::Type(index) => Ok(index),
1552                ComponentValType::Primitive(_) => unreachable!(),
1553            },
1554            PayloadType::UnitFuture => Ok(encoder.encode_unit_future()),
1555            PayloadType::UnitStream => Ok(encoder.encode_unit_stream()),
1556        }
1557    }
1558
1559    /// This is a helper function that will declare any types necessary for
1560    /// declaring intrinsics that are imported into the module or adapter.
1561    ///
1562    /// For example resources must be declared to generate
1563    /// destructors/constructors/etc. Additionally types must also be declared
1564    /// for `task.return` with the component model async feature.
1565    fn declare_types_for_imported_intrinsics(&mut self, shims: &Shims<'_>) -> Result<()> {
1566        let resolve = &self.info.encoder.metadata.resolve;
1567        let world = &resolve.worlds[self.info.encoder.metadata.world];
1568
1569        // Iterate over the main module's exports and the exports of all
1570        // adapters. Look for exported interfaces.
1571        let main_module_keys = self.info.encoder.main_module_exports.iter();
1572        let main_module_keys = main_module_keys.map(|key| (CustomModule::Main, key));
1573        let adapter_keys = self.info.encoder.adapters.iter().flat_map(|(name, info)| {
1574            info.required_exports
1575                .iter()
1576                .map(move |key| (CustomModule::Adapter(name), key))
1577        });
1578        for (for_module, key) in main_module_keys.chain(adapter_keys) {
1579            let id = match &world.exports[key] {
1580                WorldItem::Interface { id, .. } => *id,
1581                WorldItem::Type { .. } => unreachable!(),
1582                WorldItem::Function(_) => continue,
1583            };
1584
1585            for ty in resolve.interfaces[id].types.values() {
1586                let def = &resolve.types[*ty];
1587                match &def.kind {
1588                    // Declare exported resources specially as they generally
1589                    // need special treatment for later handling exports and
1590                    // such.
1591                    TypeDefKind::Resource => {
1592                        // Load the destructor, previously detected in module
1593                        // validation, if one is present.
1594                        let exports = self.info.exports_for(for_module);
1595                        let dtor = exports.resource_dtor(*ty).map(|name| {
1596                            let shim = &shims.shims[&ShimKind::ResourceDtor {
1597                                module: for_module,
1598                                export: name,
1599                            }];
1600                            let index = self.shim_instance_index.unwrap();
1601                            self.core_alias_export(
1602                                Some(&shim.debug_name),
1603                                index,
1604                                &shim.name,
1605                                ExportKind::Func,
1606                            )
1607                        });
1608
1609                        // Declare the resource with this destructor and register it in
1610                        // our internal map. This should be the first and only time this
1611                        // type is inserted into this map.
1612                        let resource_idx = self.component.type_resource(
1613                            Some(def.name.as_ref().unwrap()),
1614                            ValType::I32,
1615                            dtor,
1616                        );
1617                        let prev = self
1618                            .type_encoding_maps
1619                            .id_to_index
1620                            .insert(*ty, resource_idx);
1621                        assert!(prev.is_none());
1622                    }
1623                    _other => {
1624                        self.root_export_type_encoder(Some(id))
1625                            .encode_valtype(resolve, &Type::Id(*ty))?;
1626                    }
1627                }
1628            }
1629        }
1630        Ok(())
1631    }
1632
1633    /// Helper to instantiate the main module and record various results of its
1634    /// instantiation within `self`.
1635    fn instantiate_main_module(&mut self, shims: &Shims<'_>) -> Result<()> {
1636        assert!(self.instance_index.is_none());
1637
1638        let instance_index = self.instantiate_core_module(shims, CustomModule::Main)?;
1639
1640        if let Some(memory) = self.info.info.exports.memory() {
1641            self.memory_index = Some(self.core_alias_export(
1642                Some("memory"),
1643                instance_index,
1644                memory,
1645                ExportKind::Memory,
1646            ));
1647        }
1648
1649        self.instance_index = Some(instance_index);
1650        Ok(())
1651    }
1652
1653    /// This function will instantiate the specified adapter module, which may
1654    /// depend on previously-instantiated modules.
1655    fn instantiate_adapter_module(&mut self, shims: &Shims<'_>, name: &'a str) -> Result<()> {
1656        let instance = self.instantiate_core_module(shims, CustomModule::Adapter(name))?;
1657        self.adapter_instances.insert(name, instance);
1658        Ok(())
1659    }
1660
1661    /// Generic helper to instantiate a module.
1662    ///
1663    /// The `for_module` provided will have all of its imports satisfied from
1664    /// either previous instantiations or the `shims` module present. This
1665    /// iterates over the metadata produced during validation to determine what
1666    /// hooks up to what import.
1667    fn instantiate_core_module(
1668        &mut self,
1669        shims: &Shims,
1670        for_module: CustomModule<'_>,
1671    ) -> Result<u32> {
1672        let module = self.module_for(for_module);
1673
1674        let mut args = Vec::new();
1675        for (core_wasm_name, instance) in self.info.imports_for(for_module).modules() {
1676            match instance {
1677                // For import modules that are a "bag of names" iterate over
1678                // each name and materialize it into this component with the
1679                // `materialize_import` helper. This is then all bottled up into
1680                // a bag-of-exports instance which is then used for
1681                // instantiation.
1682                ImportInstance::Names(names) => {
1683                    let mut exports = Vec::new();
1684                    for (name, import) in names {
1685                        log::trace!(
1686                            "attempting to materialize import of `{core_wasm_name}::{name}` for {for_module:?}"
1687                        );
1688                        let (kind, index) = self
1689                            .materialize_import(&shims, for_module, import)
1690                            .with_context(|| {
1691                                format!("failed to satisfy import `{core_wasm_name}::{name}`")
1692                            })?;
1693                        exports.push((name.as_str(), kind, index));
1694                    }
1695                    let index = self
1696                        .component
1697                        .core_instantiate_exports(Some(core_wasm_name), exports);
1698                    args.push((core_wasm_name.as_str(), ModuleArg::Instance(index)));
1699                }
1700
1701                // Some imports are entire instances, so use the instance for
1702                // the module identifier as the import.
1703                ImportInstance::Whole(which) => {
1704                    let instance = self.instance_for(which.to_custom_module());
1705                    args.push((core_wasm_name.as_str(), ModuleArg::Instance(instance)));
1706                }
1707            }
1708        }
1709
1710        // And with all arguments prepared now, instantiate the module.
1711        Ok(self
1712            .component
1713            .core_instantiate(Some(for_module.debug_name()), module, args))
1714    }
1715
1716    /// Helper function to materialize an import into a core module within the
1717    /// component being built.
1718    ///
1719    /// This function is called for individual imports and uses the results of
1720    /// validation, notably the `Import` type, to determine what WIT-level or
1721    /// component-level construct is being hooked up.
1722    fn materialize_import(
1723        &mut self,
1724        shims: &Shims<'_>,
1725        for_module: CustomModule<'_>,
1726        import: &'a Import,
1727    ) -> Result<(ExportKind, u32)> {
1728        let resolve = &self.info.encoder.metadata.resolve;
1729        match import {
1730            // Main module dependencies on an adapter in use are done with an
1731            // indirection here, so load the shim function and use that.
1732            Import::AdapterExport {
1733                adapter,
1734                func,
1735                ty: _,
1736            } => {
1737                assert!(self.info.encoder.adapters.contains_key(adapter));
1738                Ok(self.materialize_shim_import(shims, &ShimKind::Adapter { adapter, func }))
1739            }
1740
1741            // Adapters might use the main module's memory, in which case it
1742            // should have been previously instantiated.
1743            Import::MainModuleMemory => {
1744                let index = self
1745                    .memory_index
1746                    .ok_or_else(|| anyhow!("main module cannot import memory"))?;
1747                Ok((ExportKind::Memory, index))
1748            }
1749
1750            // Grab-bag of "this adapter wants this thing from the main module".
1751            Import::MainModuleExport { name, kind } => {
1752                let instance = self.instance_index.unwrap();
1753                let index = self.core_alias_export(Some(name), instance, name, *kind);
1754                Ok((*kind, index))
1755            }
1756
1757            // A similar grab-bag to above but with a slightly different
1758            // structure. Should probably refactor to make these two the same in
1759            // the future.
1760            Import::Item(item) => {
1761                let instance = self.instance_for(item.which.to_custom_module());
1762                let index =
1763                    self.core_alias_export(Some(&item.name), instance, &item.name, item.kind);
1764                Ok((item.kind, index))
1765            }
1766
1767            // Resource intrinsics related to exported resources. Despite being
1768            // an exported resource the component still provides necessary
1769            // intrinsics for manipulating resource state. These are all
1770            // handled here using the resource types created during
1771            // `declare_types_for_imported_intrinsics` above.
1772            Import::ExportedResourceDrop(_key, id) => {
1773                let index = self
1774                    .component
1775                    .resource_drop(self.type_encoding_maps.id_to_index[id]);
1776                Ok((ExportKind::Func, index))
1777            }
1778            Import::ExportedResourceRep(_key, id) => {
1779                let index = self
1780                    .component
1781                    .resource_rep(self.type_encoding_maps.id_to_index[id]);
1782                Ok((ExportKind::Func, index))
1783            }
1784            Import::ExportedResourceNew(_key, id) => {
1785                let index = self
1786                    .component
1787                    .resource_new(self.type_encoding_maps.id_to_index[id]);
1788                Ok((ExportKind::Func, index))
1789            }
1790
1791            // And finally here at the end these cases are going to all fall
1792            // through to the code below. This is where these are connected to a
1793            // WIT `ImportedInterface` one way or another with the name that was
1794            // detected during validation.
1795            Import::ImportedResourceDrop(key, iface, id) => {
1796                let ty = &resolve.types[*id];
1797                let name = ty.name.as_ref().unwrap();
1798                self.materialize_wit_import(
1799                    shims,
1800                    for_module,
1801                    iface.map(|_| resolve.name_world_key(key)),
1802                    &format!("{name}_drop"),
1803                    key,
1804                    AbiVariant::GuestImport,
1805                )
1806            }
1807            Import::ExportedTaskReturn(key, interface, func) => {
1808                let (options, _sig) = task_return_options_and_type(resolve, func);
1809                let result_ty = func.result;
1810                if options.is_empty() {
1811                    // Note that an "import type encoder" is used here despite
1812                    // this being for an exported function if the `interface`
1813                    // is none, meaning that this is for a top-level world
1814                    // function. In that situation all types that can be
1815                    // referred to are imported, not exported.
1816                    let mut encoder = if interface.is_none() {
1817                        self.root_import_type_encoder(*interface)
1818                    } else {
1819                        self.root_export_type_encoder(*interface)
1820                    };
1821
1822                    let result = match result_ty.as_ref() {
1823                        Some(ty) => Some(encoder.encode_valtype(resolve, ty)?),
1824                        None => None,
1825                    };
1826                    let index = self.component.task_return(result, []);
1827                    Ok((ExportKind::Func, index))
1828                } else {
1829                    let metadata = &self.info.module_metadata_for(for_module);
1830                    let encoding = metadata
1831                        .export_encodings
1832                        .get(resolve, key, &func.name)
1833                        .unwrap();
1834                    Ok(self.materialize_shim_import(
1835                        shims,
1836                        &ShimKind::TaskReturn {
1837                            for_module,
1838                            interface: *interface,
1839                            func: &func.name,
1840                            result: result_ty,
1841                            encoding,
1842                        },
1843                    ))
1844                }
1845            }
1846            Import::BackpressureInc => {
1847                let index = self.component.backpressure_inc();
1848                Ok((ExportKind::Func, index))
1849            }
1850            Import::BackpressureDec => {
1851                let index = self.component.backpressure_dec();
1852                Ok((ExportKind::Func, index))
1853            }
1854            Import::WaitableSetWait { cancellable } => Ok(self.materialize_shim_import(
1855                shims,
1856                &ShimKind::WaitableSetWait {
1857                    cancellable: *cancellable,
1858                },
1859            )),
1860            Import::WaitableSetPoll { cancellable } => Ok(self.materialize_shim_import(
1861                shims,
1862                &ShimKind::WaitableSetPoll {
1863                    cancellable: *cancellable,
1864                },
1865            )),
1866            Import::SubtaskDrop => {
1867                let index = self.component.subtask_drop();
1868                Ok((ExportKind::Func, index))
1869            }
1870            Import::SubtaskCancel { async_ } => {
1871                let index = self.component.subtask_cancel(*async_);
1872                Ok((ExportKind::Func, index))
1873            }
1874            Import::StreamNew(info) => {
1875                let ty = self.payload_type_index(info)?;
1876                let index = self.component.stream_new(ty);
1877                Ok((ExportKind::Func, index))
1878            }
1879            Import::StreamRead { info, .. } => Ok(self.materialize_payload_import(
1880                shims,
1881                for_module,
1882                info,
1883                PayloadFuncKind::StreamRead,
1884            )),
1885            Import::StreamWrite { info, .. } => Ok(self.materialize_payload_import(
1886                shims,
1887                for_module,
1888                info,
1889                PayloadFuncKind::StreamWrite,
1890            )),
1891            Import::StreamCancelRead { info, async_ } => {
1892                let ty = self.payload_type_index(info)?;
1893                let index = self.component.stream_cancel_read(ty, *async_);
1894                Ok((ExportKind::Func, index))
1895            }
1896            Import::StreamCancelWrite { info, async_ } => {
1897                let ty = self.payload_type_index(info)?;
1898                let index = self.component.stream_cancel_write(ty, *async_);
1899                Ok((ExportKind::Func, index))
1900            }
1901            Import::StreamDropReadable(info) => {
1902                let type_index = self.payload_type_index(info)?;
1903                let index = self.component.stream_drop_readable(type_index);
1904                Ok((ExportKind::Func, index))
1905            }
1906            Import::StreamDropWritable(info) => {
1907                let type_index = self.payload_type_index(info)?;
1908                let index = self.component.stream_drop_writable(type_index);
1909                Ok((ExportKind::Func, index))
1910            }
1911            Import::FutureNew(info) => {
1912                let ty = self.payload_type_index(info)?;
1913                let index = self.component.future_new(ty);
1914                Ok((ExportKind::Func, index))
1915            }
1916            Import::FutureRead { info, .. } => Ok(self.materialize_payload_import(
1917                shims,
1918                for_module,
1919                info,
1920                PayloadFuncKind::FutureRead,
1921            )),
1922            Import::FutureWrite { info, .. } => Ok(self.materialize_payload_import(
1923                shims,
1924                for_module,
1925                info,
1926                PayloadFuncKind::FutureWrite,
1927            )),
1928            Import::FutureCancelRead { info, async_ } => {
1929                let ty = self.payload_type_index(info)?;
1930                let index = self.component.future_cancel_read(ty, *async_);
1931                Ok((ExportKind::Func, index))
1932            }
1933            Import::FutureCancelWrite { info, async_ } => {
1934                let ty = self.payload_type_index(info)?;
1935                let index = self.component.future_cancel_write(ty, *async_);
1936                Ok((ExportKind::Func, index))
1937            }
1938            Import::FutureDropReadable(info) => {
1939                let type_index = self.payload_type_index(info)?;
1940                let index = self.component.future_drop_readable(type_index);
1941                Ok((ExportKind::Func, index))
1942            }
1943            Import::FutureDropWritable(info) => {
1944                let type_index = self.payload_type_index(info)?;
1945                let index = self.component.future_drop_writable(type_index);
1946                Ok((ExportKind::Func, index))
1947            }
1948            Import::ErrorContextNew { encoding } => Ok(self.materialize_shim_import(
1949                shims,
1950                &ShimKind::ErrorContextNew {
1951                    encoding: *encoding,
1952                },
1953            )),
1954            Import::ErrorContextDebugMessage { encoding } => Ok(self.materialize_shim_import(
1955                shims,
1956                &ShimKind::ErrorContextDebugMessage {
1957                    for_module,
1958                    encoding: *encoding,
1959                },
1960            )),
1961            Import::ErrorContextDrop => {
1962                let index = self.component.error_context_drop();
1963                Ok((ExportKind::Func, index))
1964            }
1965            Import::WorldFunc(key, name, abi) => {
1966                self.materialize_wit_import(shims, for_module, None, name, key, *abi)
1967            }
1968            Import::InterfaceFunc(key, _, name, abi) => self.materialize_wit_import(
1969                shims,
1970                for_module,
1971                Some(resolve.name_world_key(key)),
1972                name,
1973                key,
1974                *abi,
1975            ),
1976
1977            Import::WaitableSetNew => {
1978                let index = self.component.waitable_set_new();
1979                Ok((ExportKind::Func, index))
1980            }
1981            Import::WaitableSetDrop => {
1982                let index = self.component.waitable_set_drop();
1983                Ok((ExportKind::Func, index))
1984            }
1985            Import::WaitableJoin => {
1986                let index = self.component.waitable_join();
1987                Ok((ExportKind::Func, index))
1988            }
1989            Import::ContextGet { ty, slot } => {
1990                let index = self.component.context_get((*ty).try_into()?, *slot);
1991                Ok((ExportKind::Func, index))
1992            }
1993            Import::ContextSet { ty, slot } => {
1994                let index = self.component.context_set((*ty).try_into()?, *slot);
1995                Ok((ExportKind::Func, index))
1996            }
1997            Import::ExportedTaskCancel => {
1998                let index = self.component.task_cancel();
1999                Ok((ExportKind::Func, index))
2000            }
2001            Import::ThreadIndex => {
2002                let index = self.component.thread_index();
2003                Ok((ExportKind::Func, index))
2004            }
2005            Import::ThreadNewIndirect => Ok(self.materialize_shim_import(
2006                shims,
2007                &ShimKind::ThreadNewIndirect {
2008                    for_module,
2009                    // This is fixed for now
2010                    func_ty: FuncType::new([ValType::I32], []),
2011                },
2012            )),
2013            Import::ThreadResumeLater => {
2014                let index = self.component.thread_resume_later();
2015                Ok((ExportKind::Func, index))
2016            }
2017            Import::ThreadSuspend { cancellable } => {
2018                let index = self.component.thread_suspend(*cancellable);
2019                Ok((ExportKind::Func, index))
2020            }
2021            Import::ThreadYield { cancellable } => {
2022                let index = self.component.thread_yield(*cancellable);
2023                Ok((ExportKind::Func, index))
2024            }
2025            Import::ThreadSuspendThenResume { cancellable } => {
2026                let index = self.component.thread_suspend_then_resume(*cancellable);
2027                Ok((ExportKind::Func, index))
2028            }
2029            Import::ThreadYieldThenResume { cancellable } => {
2030                let index = self.component.thread_yield_then_resume(*cancellable);
2031                Ok((ExportKind::Func, index))
2032            }
2033            Import::ThreadSuspendThenPromote { cancellable } => {
2034                let index = self.component.thread_suspend_then_promote(*cancellable);
2035                Ok((ExportKind::Func, index))
2036            }
2037            Import::ThreadYieldThenPromote { cancellable } => {
2038                let index = self.component.thread_yield_then_promote(*cancellable);
2039                Ok((ExportKind::Func, index))
2040            }
2041        }
2042    }
2043
2044    /// Helper for `materialize_import` above for materializing functions that
2045    /// are part of the "shim module" generated.
2046    fn materialize_shim_import(&mut self, shims: &Shims<'_>, kind: &ShimKind) -> (ExportKind, u32) {
2047        let index = self.core_alias_export(
2048            Some(&shims.shims[kind].debug_name),
2049            self.shim_instance_index
2050                .expect("shim should be instantiated"),
2051            &shims.shims[kind].name,
2052            ExportKind::Func,
2053        );
2054        (ExportKind::Func, index)
2055    }
2056
2057    /// Helper for `materialize_import` above for generating imports for
2058    /// future/stream read/write intrinsics.
2059    fn materialize_payload_import(
2060        &mut self,
2061        shims: &Shims<'_>,
2062        for_module: CustomModule<'_>,
2063        info: &PayloadInfo,
2064        kind: PayloadFuncKind,
2065    ) -> (ExportKind, u32) {
2066        self.materialize_shim_import(
2067            shims,
2068            &ShimKind::PayloadFunc {
2069                for_module,
2070                info,
2071                kind,
2072            },
2073        )
2074    }
2075
2076    /// Helper for `materialize_import` above which specifically operates on
2077    /// WIT-level functions identified by `interface_key`, `name`, and `abi`.
2078    fn materialize_wit_import(
2079        &mut self,
2080        shims: &Shims<'_>,
2081        for_module: CustomModule<'_>,
2082        interface_key: Option<String>,
2083        name: &String,
2084        key: &WorldKey,
2085        abi: AbiVariant,
2086    ) -> Result<(ExportKind, u32)> {
2087        let resolve = &self.info.encoder.metadata.resolve;
2088        let import = &self.info.import_map[&interface_key];
2089        let (index, _, lowering) = import.lowerings.get_full(&(name.clone(), abi)).unwrap();
2090        let metadata = self.info.module_metadata_for(for_module);
2091
2092        let index = match lowering {
2093            // All direct lowerings can be `canon lower`'d here immediately
2094            // and passed as arguments.
2095            Lowering::Direct => {
2096                let func_index = match &import.interface {
2097                    Some(interface) => {
2098                        let instance_index = self.instances[interface];
2099                        self.component
2100                            .alias_export(instance_index, name, ComponentExportKind::Func)
2101                    }
2102                    None => self.imported_funcs[name],
2103                };
2104                self.component.lower_func(
2105                    Some(name),
2106                    func_index,
2107                    if let AbiVariant::GuestImportAsync = abi {
2108                        vec![CanonicalOption::Async]
2109                    } else {
2110                        Vec::new()
2111                    },
2112                )
2113            }
2114
2115            // Indirect lowerings come from the shim that was previously
2116            // created, so the specific export is loaded here and used as an
2117            // import.
2118            Lowering::Indirect { .. } => {
2119                let encoding = metadata.import_encodings.get(resolve, key, name).unwrap();
2120                return Ok(self.materialize_shim_import(
2121                    shims,
2122                    &ShimKind::IndirectLowering {
2123                        interface: interface_key,
2124                        index,
2125                        realloc: for_module,
2126                        encoding,
2127                    },
2128                ));
2129            }
2130
2131            // A "resource drop" intrinsic only needs to find the index of the
2132            // resource type itself and then the intrinsic is declared.
2133            Lowering::ResourceDrop(id) => {
2134                let resource_idx = self.lookup_resource_index(*id);
2135                self.component.resource_drop(resource_idx)
2136            }
2137        };
2138        Ok((ExportKind::Func, index))
2139    }
2140
2141    /// Generates component bits that are responsible for executing
2142    /// `_initialize`, if found, in the original component.
2143    ///
2144    /// The `_initialize` function was a part of WASIp1 where it generally is
2145    /// intended to run after imports and memory and such are all "hooked up"
2146    /// and performs other various initialization tasks. This is additionally
2147    /// specified in https://github.com/WebAssembly/component-model/pull/378
2148    /// to be part of the component model lowerings as well.
2149    ///
2150    /// This implements this functionality by encoding a core module that
2151    /// imports a function and then registers a `start` section with that
2152    /// imported function. This is all encoded after the
2153    /// imports/lowerings/tables/etc are all filled in above meaning that this
2154    /// is the last piece to run. That means that when this is running
2155    /// everything should be hooked up for all imported functions to work.
2156    ///
2157    /// Note that at this time `_initialize` is only detected in the "main
2158    /// module", not adapters/libraries.
2159    fn encode_initialize_with_start(&mut self) -> Result<()> {
2160        let initialize = match self.info.info.exports.initialize() {
2161            Some(name) => name,
2162            // If this core module didn't have `_initialize` or similar, then
2163            // there's nothing to do here.
2164            None => return Ok(()),
2165        };
2166        let initialize_index = self.core_alias_export(
2167            Some("start"),
2168            self.instance_index.unwrap(),
2169            initialize,
2170            ExportKind::Func,
2171        );
2172        let mut shim = Module::default();
2173        let mut section = TypeSection::new();
2174        section.ty().function([], []);
2175        shim.section(&section);
2176        let mut section = ImportSection::new();
2177        section.import("", "", EntityType::Function(0));
2178        shim.section(&section);
2179        shim.section(&StartSection { function_index: 0 });
2180
2181        // Declare the core module within the component, create a dummy core
2182        // instance with one export of our `_initialize` function, and then use
2183        // that to instantiate the module we emit to run the `start` function in
2184        // core wasm to run `_initialize`.
2185        let shim_module_index = self.component.core_module(Some("start-shim-module"), &shim);
2186        let shim_args_instance_index = self.component.core_instantiate_exports(
2187            Some("start-shim-args"),
2188            [("", ExportKind::Func, initialize_index)],
2189        );
2190        self.component.core_instantiate(
2191            Some("start-shim-instance"),
2192            shim_module_index,
2193            [("", ModuleArg::Instance(shim_args_instance_index))],
2194        );
2195        Ok(())
2196    }
2197
2198    /// Convenience function to go from `CustomModule` to the instance index
2199    /// corresponding to what that points to.
2200    fn instance_for(&self, module: CustomModule) -> u32 {
2201        match module {
2202            CustomModule::Main => self.instance_index.expect("instantiated by now"),
2203            CustomModule::Adapter(name) => self.adapter_instances[name],
2204        }
2205    }
2206
2207    /// Convenience function to go from `CustomModule` to the module index
2208    /// corresponding to what that points to.
2209    fn module_for(&self, module: CustomModule) -> u32 {
2210        match module {
2211            CustomModule::Main => self.module_index.unwrap(),
2212            CustomModule::Adapter(name) => self.adapter_modules[name],
2213        }
2214    }
2215
2216    /// Convenience function which caches aliases created so repeated calls to
2217    /// this function will all return the same index.
2218    fn core_alias_export(
2219        &mut self,
2220        debug_name: Option<&str>,
2221        instance: u32,
2222        name: &str,
2223        kind: ExportKind,
2224    ) -> u32 {
2225        *self
2226            .aliased_core_items
2227            .entry((instance, name.to_string()))
2228            .or_insert_with(|| {
2229                self.component
2230                    .core_alias_export(debug_name, instance, name, kind)
2231            })
2232    }
2233
2234    /// Modules may define `__wasm_init_(async_)task` functions that must be called
2235    /// at the start of every exported function to set up the stack pointer and
2236    /// thread-local storage. To achieve this, we create a wrapper module called
2237    /// `task-init-wrappers` that imports the original exports and the
2238    /// task initialization functions, and defines wrapper functions that call
2239    /// the relevant task initialization function before delegating to the original export.
2240    /// We then instantiate this wrapper module and use its exports as the final
2241    /// exports of the component. If we don't find a `__wasm_init_task` export,
2242    /// we elide the wrapper module entirely.
2243    fn create_export_task_initialization_wrappers(&mut self) -> Result<()> {
2244        let instance_index = self.instance_index.unwrap();
2245        let resolve = &self.info.encoder.metadata.resolve;
2246        let world = &resolve.worlds[self.info.encoder.metadata.world];
2247        let exports = self.info.exports_for(CustomModule::Main);
2248
2249        let wasm_init_task_export = exports.wasm_init_task();
2250        let wasm_init_async_task_export = exports.wasm_init_async_task();
2251        if wasm_init_task_export.is_none() || wasm_init_async_task_export.is_none() {
2252            // __wasm_init_(async_)task was not exported by the main module,
2253            // so no wrappers are needed.
2254            return Ok(());
2255        }
2256        let wasm_init_task = wasm_init_task_export.unwrap();
2257        let wasm_init_async_task = wasm_init_async_task_export.unwrap();
2258
2259        // Collect the exports that we will need to wrap, alongside information
2260        // that we'll need to build the wrappers.
2261        let funcs_to_wrap: Vec<_> = exports
2262            .iter()
2263            .flat_map(|(core_name, export)| match export {
2264                Export::WorldFunc(key, _, abi) => match &world.exports[key] {
2265                    WorldItem::Function(f) => Some((core_name, f, abi)),
2266                    _ => None,
2267                },
2268                Export::InterfaceFunc(_, id, func_name, abi) => {
2269                    let func = &resolve.interfaces[*id].functions[func_name.as_str()];
2270                    Some((core_name, func, abi))
2271                }
2272                _ => None,
2273            })
2274            .collect();
2275
2276        if funcs_to_wrap.is_empty() {
2277            // No exports, so no wrappers are needed.
2278            return Ok(());
2279        }
2280
2281        // Now we build the wrapper module
2282        let mut types = TypeSection::new();
2283        let mut imports = ImportSection::new();
2284        let mut functions = FunctionSection::new();
2285        let mut exports_section = ExportSection::new();
2286        let mut code = CodeSection::new();
2287
2288        // Type for __wasm_init_(async_)task: () -> ()
2289        types.ty().function([], []);
2290        let wasm_init_task_type_idx = 0;
2291
2292        // Import __wasm_init_task and __wasm_init_async_task into the wrapper module
2293        imports.import(
2294            "",
2295            wasm_init_task,
2296            EntityType::Function(wasm_init_task_type_idx),
2297        );
2298        imports.import(
2299            "",
2300            wasm_init_async_task,
2301            EntityType::Function(wasm_init_task_type_idx),
2302        );
2303        let wasm_init_task_func_idx = 0u32;
2304        let wasm_init_async_task_func_idx = 1u32;
2305
2306        let mut type_indices = HashMap::new();
2307        let mut next_type_idx = 1u32;
2308        let mut next_func_idx = 2u32;
2309
2310        // First pass: create all types and import all original functions
2311        struct FuncInfo<'a> {
2312            name: &'a str,
2313            type_idx: u32,
2314            orig_func_idx: u32,
2315            is_async: bool,
2316            n_params: usize,
2317        }
2318        let mut func_info = Vec::new();
2319        for &(name, func, abi) in funcs_to_wrap.iter() {
2320            let sig = resolve.wasm_signature(*abi, func);
2321            let type_idx = *type_indices.entry(sig.clone()).or_insert_with(|| {
2322                let idx = next_type_idx;
2323                types.ty().function(
2324                    sig.params.iter().map(to_val_type),
2325                    sig.results.iter().map(to_val_type),
2326                );
2327                next_type_idx += 1;
2328                idx
2329            });
2330
2331            imports.import("", &import_func_name(func), EntityType::Function(type_idx));
2332            let orig_func_idx = next_func_idx;
2333            next_func_idx += 1;
2334
2335            func_info.push(FuncInfo {
2336                name,
2337                type_idx,
2338                orig_func_idx,
2339                is_async: abi.is_async(),
2340                n_params: sig.params.len(),
2341            });
2342        }
2343
2344        // Second pass: define wrapper functions
2345        for info in func_info.iter() {
2346            let wrapper_func_idx = next_func_idx;
2347            functions.function(info.type_idx);
2348
2349            let mut func = wasm_encoder::Function::new([]);
2350            if info.is_async {
2351                func.instruction(&Instruction::Call(wasm_init_async_task_func_idx));
2352            } else {
2353                func.instruction(&Instruction::Call(wasm_init_task_func_idx));
2354            }
2355            for i in 0..info.n_params as u32 {
2356                func.instruction(&Instruction::LocalGet(i));
2357            }
2358            func.instruction(&Instruction::Call(info.orig_func_idx));
2359            func.instruction(&Instruction::End);
2360            code.function(&func);
2361
2362            exports_section.export(info.name, ExportKind::Func, wrapper_func_idx);
2363            next_func_idx += 1;
2364        }
2365
2366        let mut wrapper_module = Module::new();
2367        wrapper_module.section(&types);
2368        wrapper_module.section(&imports);
2369        wrapper_module.section(&functions);
2370        wrapper_module.section(&exports_section);
2371        wrapper_module.section(&code);
2372
2373        let wrapper_module_idx = self
2374            .component
2375            .core_module(Some("init-task-wrappers"), &wrapper_module);
2376
2377        // Prepare imports for instantiating the wrapper module
2378        let mut wrapper_imports = Vec::new();
2379        let init_idx = self.core_alias_export(
2380            Some(wasm_init_task),
2381            instance_index,
2382            wasm_init_task,
2383            ExportKind::Func,
2384        );
2385        let init_async_idx = self.core_alias_export(
2386            Some(wasm_init_async_task),
2387            instance_index,
2388            wasm_init_async_task,
2389            ExportKind::Func,
2390        );
2391        wrapper_imports.push((wasm_init_task.into(), ExportKind::Func, init_idx));
2392        wrapper_imports.push((
2393            wasm_init_async_task.into(),
2394            ExportKind::Func,
2395            init_async_idx,
2396        ));
2397
2398        // Import all original exports to be wrapped
2399        for (name, func, _) in &funcs_to_wrap {
2400            let orig_idx =
2401                self.core_alias_export(Some(name), instance_index, name, ExportKind::Func);
2402            wrapper_imports.push((import_func_name(func), ExportKind::Func, orig_idx));
2403        }
2404
2405        let wrapper_args_idx = self.component.core_instantiate_exports(
2406            Some("init-task-wrappers-args"),
2407            wrapper_imports.iter().map(|(n, k, i)| (n.as_str(), *k, *i)),
2408        );
2409
2410        let wrapper_instance = self.component.core_instantiate(
2411            Some("init-task-wrappers-instance"),
2412            wrapper_module_idx,
2413            [("", ModuleArg::Instance(wrapper_args_idx))],
2414        );
2415
2416        // Map original names to wrapper indices
2417        for (name, _, _) in funcs_to_wrap {
2418            let wrapper_idx =
2419                self.core_alias_export(Some(&name), wrapper_instance, &name, ExportKind::Func);
2420            self.export_task_initialization_wrappers
2421                .insert(name.into(), wrapper_idx);
2422        }
2423
2424        Ok(())
2425    }
2426}
2427
2428/// A list of "shims" which start out during the component instantiation process
2429/// as functions which immediately trap due to a `call_indirect`-to-`null` but
2430/// will get filled in by the time the component instantiation process
2431/// completes.
2432///
2433/// Shims currently include:
2434///
2435/// * "Indirect functions" lowered from imported instances where the lowering
2436///   requires an item exported from the main module. These are indirect due to
2437///   the circular dependency between the module needing an import and the
2438///   import needing the module.
2439///
2440/// * Adapter modules which convert from a historical ABI to the component
2441///   model's ABI (e.g. wasi preview1 to preview2) get a shim since the adapters
2442///   are currently indicated as always requiring the memory of the main module.
2443///
2444/// This structure is created by `encode_shim_instantiation`.
2445#[derive(Default)]
2446struct Shims<'a> {
2447    /// The list of all shims that a module will require.
2448    shims: IndexMap<ShimKind<'a>, Shim<'a>>,
2449}
2450
2451struct Shim<'a> {
2452    /// Canonical ABI options required by this shim, used during `canon lower`
2453    /// operations.
2454    options: RequiredOptions,
2455
2456    /// The name, in the shim instance, of this shim.
2457    ///
2458    /// Currently this is `"0"`, `"1"`, ...
2459    name: String,
2460
2461    /// A human-readable debugging name for this shim, used in a core wasm
2462    /// `name` section.
2463    debug_name: String,
2464
2465    /// Precise information about what this shim is a lowering of.
2466    kind: ShimKind<'a>,
2467
2468    /// Wasm type of this shim.
2469    sig: WasmSignature,
2470}
2471
2472/// Which variation of `{stream|future}.{read|write}` we're emitting for a
2473/// `ShimKind::PayloadFunc`.
2474#[derive(Debug, Clone, Hash, Eq, PartialEq)]
2475enum PayloadFuncKind {
2476    FutureWrite,
2477    FutureRead,
2478    StreamWrite,
2479    StreamRead,
2480}
2481
2482#[derive(Debug, Clone, Hash, Eq, PartialEq)]
2483enum ShimKind<'a> {
2484    /// This shim is a late indirect lowering of an imported function in a
2485    /// component which is only possible after prior core wasm modules are
2486    /// instantiated so their memories and functions are available.
2487    IndirectLowering {
2488        /// The name of the interface that's being lowered.
2489        interface: Option<String>,
2490        /// The index within the `lowerings` array of the function being lowered.
2491        index: usize,
2492        /// Which instance to pull the `realloc` function from, if necessary.
2493        realloc: CustomModule<'a>,
2494        /// The string encoding that this lowering is going to use.
2495        encoding: StringEncoding,
2496    },
2497    /// This shim is a core wasm function defined in an adapter module but isn't
2498    /// available until the adapter module is itself instantiated.
2499    Adapter {
2500        /// The name of the adapter module this shim comes from.
2501        adapter: &'a str,
2502        /// The name of the export in the adapter module this shim points to.
2503        func: &'a str,
2504    },
2505    /// A shim used as the destructor for a resource which allows defining the
2506    /// resource before the core module being instantiated.
2507    ResourceDtor {
2508        /// Which instance to pull the destructor function from.
2509        module: CustomModule<'a>,
2510        /// The exported function name of this destructor in the core module.
2511        export: &'a str,
2512    },
2513    /// A shim used for a `{stream|future}.{read|write}` built-in function,
2514    /// which must refer to the core module instance's memory from/to which
2515    /// payload values must be lifted/lowered.
2516    PayloadFunc {
2517        /// Which instance to pull the `realloc` function and string encoding
2518        /// from, if necessary.
2519        for_module: CustomModule<'a>,
2520        /// Additional information regarding the function where this `stream` or
2521        /// `future` type appeared, which we use in combination with
2522        /// `for_module` to determine which `realloc` and string encoding to
2523        /// use, as well as which type to specify when emitting the built-in.
2524        info: &'a PayloadInfo,
2525        /// Which variation of `{stream|future}.{read|write}` we're emitting.
2526        kind: PayloadFuncKind,
2527    },
2528    /// A shim used for the `waitable-set.wait` built-in function, which must
2529    /// refer to the core module instance's memory to which results will be
2530    /// written.
2531    WaitableSetWait { cancellable: bool },
2532    /// A shim used for the `waitable-set.poll` built-in function, which must
2533    /// refer to the core module instance's memory to which results will be
2534    /// written.
2535    WaitableSetPoll { cancellable: bool },
2536    /// Shim for `task.return` to handle a reference to a `memory` which may
2537    TaskReturn {
2538        /// The interface (optional) that owns `func` below. If `None` then it's
2539        /// a world export.
2540        interface: Option<InterfaceId>,
2541        /// The function that this `task.return` is returning for, owned
2542        /// within `interface` above.
2543        func: &'a str,
2544        /// The WIT type that `func` returns.
2545        result: Option<Type>,
2546        /// Which instance to pull the `realloc` function from, if necessary.
2547        for_module: CustomModule<'a>,
2548        /// String encoding to use in the ABI options.
2549        encoding: StringEncoding,
2550    },
2551    /// A shim used for the `error-context.new` built-in function, which must
2552    /// refer to the core module instance's memory from which the debug message
2553    /// will be read.
2554    ErrorContextNew {
2555        /// String encoding to use when lifting the debug message.
2556        encoding: StringEncoding,
2557    },
2558    /// A shim used for the `error-context.debug-message` built-in function,
2559    /// which must refer to the core module instance's memory to which results
2560    /// will be written.
2561    ErrorContextDebugMessage {
2562        /// Which instance to pull the `realloc` function from, if necessary.
2563        for_module: CustomModule<'a>,
2564        /// The string encoding to use when lowering the debug message.
2565        encoding: StringEncoding,
2566    },
2567    /// A shim used for the `thread.new-indirect` built-in function, which
2568    /// must refer to the core module instance's indirect function table.
2569    ThreadNewIndirect {
2570        /// Which instance to pull the function table from.
2571        for_module: CustomModule<'a>,
2572        /// The function type to use when creating the thread.
2573        func_ty: FuncType,
2574    },
2575}
2576
2577/// Indicator for which module is being used for a lowering or where options
2578/// like `realloc` are drawn from.
2579///
2580/// This is necessary for situations such as an imported function being lowered
2581/// into the main module and additionally into an adapter module. For example an
2582/// adapter might adapt from preview1 to preview2 for the standard library of a
2583/// programming language but the main module's custom application code may also
2584/// explicitly import from preview2. These two different lowerings of a preview2
2585/// function are parameterized by this enumeration.
2586#[derive(Debug, Copy, Clone, Hash, Eq, PartialEq)]
2587enum CustomModule<'a> {
2588    /// This points to the "main module" which is generally the "output of LLVM"
2589    /// or what a user wrote.
2590    Main,
2591    /// This is selecting an adapter module, identified by name here, where
2592    /// something is being lowered into.
2593    Adapter(&'a str),
2594}
2595
2596impl<'a> CustomModule<'a> {
2597    fn debug_name(&self) -> &'a str {
2598        match self {
2599            CustomModule::Main => "main",
2600            CustomModule::Adapter(s) => s,
2601        }
2602    }
2603}
2604
2605impl<'a> Shims<'a> {
2606    /// Adds all shims necessary for the instantiation of `for_module`.
2607    ///
2608    /// This function will iterate over all the imports required by this module
2609    /// and for those that require a shim they're registered here.
2610    fn append_indirect(
2611        &mut self,
2612        world: &'a ComponentWorld<'a>,
2613        for_module: CustomModule<'a>,
2614    ) -> Result<()> {
2615        let module_imports = world.imports_for(for_module);
2616        let module_exports = world.exports_for(for_module);
2617        let resolve = &world.encoder.metadata.resolve;
2618
2619        for (module, field, import) in module_imports.imports() {
2620            match import {
2621                // These imports don't require shims, they can be satisfied
2622                // as-needed when required.
2623                Import::ImportedResourceDrop(..)
2624                | Import::MainModuleMemory
2625                | Import::MainModuleExport { .. }
2626                | Import::Item(_)
2627                | Import::ExportedResourceDrop(..)
2628                | Import::ExportedResourceRep(..)
2629                | Import::ExportedResourceNew(..)
2630                | Import::ExportedTaskCancel
2631                | Import::ErrorContextDrop
2632                | Import::BackpressureInc
2633                | Import::BackpressureDec
2634                | Import::SubtaskDrop
2635                | Import::SubtaskCancel { .. }
2636                | Import::FutureNew(..)
2637                | Import::StreamNew(..)
2638                | Import::FutureCancelRead { .. }
2639                | Import::FutureCancelWrite { .. }
2640                | Import::FutureDropWritable { .. }
2641                | Import::FutureDropReadable { .. }
2642                | Import::StreamCancelRead { .. }
2643                | Import::StreamCancelWrite { .. }
2644                | Import::StreamDropWritable { .. }
2645                | Import::StreamDropReadable { .. }
2646                | Import::WaitableSetNew
2647                | Import::WaitableSetDrop
2648                | Import::WaitableJoin
2649                | Import::ContextGet { .. }
2650                | Import::ContextSet { .. }
2651                | Import::ThreadIndex
2652                | Import::ThreadResumeLater
2653                | Import::ThreadSuspend { .. }
2654                | Import::ThreadYield { .. }
2655                | Import::ThreadSuspendThenResume { .. }
2656                | Import::ThreadYieldThenResume { .. }
2657                | Import::ThreadSuspendThenPromote { .. }
2658                | Import::ThreadYieldThenPromote { .. } => {}
2659
2660                // If `task.return` needs to be indirect then generate a shim
2661                // for it, otherwise skip the shim and let it get materialized
2662                // naturally later.
2663                Import::ExportedTaskReturn(key, interface, func) => {
2664                    let (options, sig) = task_return_options_and_type(resolve, func);
2665                    if options.is_empty() {
2666                        continue;
2667                    }
2668                    let name = self.shims.len().to_string();
2669                    let encoding = world
2670                        .module_metadata_for(for_module)
2671                        .export_encodings
2672                        .get(resolve, key, &func.name)
2673                        .ok_or_else(|| {
2674                            anyhow::anyhow!(
2675                                "missing component metadata for export of \
2676                                `{module}::{field}`"
2677                            )
2678                        })?;
2679                    self.push(Shim {
2680                        name,
2681                        debug_name: format!("task-return-{}", func.name),
2682                        options,
2683                        kind: ShimKind::TaskReturn {
2684                            interface: *interface,
2685                            func: &func.name,
2686                            result: func.result,
2687                            for_module,
2688                            encoding,
2689                        },
2690                        sig,
2691                    });
2692                }
2693
2694                Import::FutureWrite { async_, info } => {
2695                    self.append_indirect_payload_push(
2696                        resolve,
2697                        for_module,
2698                        module,
2699                        *async_,
2700                        info,
2701                        PayloadFuncKind::FutureWrite,
2702                        vec![WasmType::I32; 2],
2703                        vec![WasmType::I32],
2704                    );
2705                }
2706                Import::FutureRead { async_, info } => {
2707                    self.append_indirect_payload_push(
2708                        resolve,
2709                        for_module,
2710                        module,
2711                        *async_,
2712                        info,
2713                        PayloadFuncKind::FutureRead,
2714                        vec![WasmType::I32; 2],
2715                        vec![WasmType::I32],
2716                    );
2717                }
2718                Import::StreamWrite { async_, info } => {
2719                    self.append_indirect_payload_push(
2720                        resolve,
2721                        for_module,
2722                        module,
2723                        *async_,
2724                        info,
2725                        PayloadFuncKind::StreamWrite,
2726                        vec![WasmType::I32; 3],
2727                        vec![WasmType::I32],
2728                    );
2729                }
2730                Import::StreamRead { async_, info } => {
2731                    self.append_indirect_payload_push(
2732                        resolve,
2733                        for_module,
2734                        module,
2735                        *async_,
2736                        info,
2737                        PayloadFuncKind::StreamRead,
2738                        vec![WasmType::I32; 3],
2739                        vec![WasmType::I32],
2740                    );
2741                }
2742
2743                Import::WaitableSetWait { cancellable } => {
2744                    let name = self.shims.len().to_string();
2745                    self.push(Shim {
2746                        name,
2747                        debug_name: "waitable-set.wait".to_string(),
2748                        options: RequiredOptions::empty(),
2749                        kind: ShimKind::WaitableSetWait {
2750                            cancellable: *cancellable,
2751                        },
2752                        sig: WasmSignature {
2753                            params: vec![WasmType::I32; 2],
2754                            results: vec![WasmType::I32],
2755                            indirect_params: false,
2756                            retptr: false,
2757                        },
2758                    });
2759                }
2760
2761                Import::WaitableSetPoll { cancellable } => {
2762                    let name = self.shims.len().to_string();
2763                    self.push(Shim {
2764                        name,
2765                        debug_name: "waitable-set.poll".to_string(),
2766                        options: RequiredOptions::empty(),
2767                        kind: ShimKind::WaitableSetPoll {
2768                            cancellable: *cancellable,
2769                        },
2770                        sig: WasmSignature {
2771                            params: vec![WasmType::I32; 2],
2772                            results: vec![WasmType::I32],
2773                            indirect_params: false,
2774                            retptr: false,
2775                        },
2776                    });
2777                }
2778
2779                Import::ErrorContextNew { encoding } => {
2780                    let name = self.shims.len().to_string();
2781                    self.push(Shim {
2782                        name,
2783                        debug_name: "error-new".to_string(),
2784                        options: RequiredOptions::MEMORY | RequiredOptions::STRING_ENCODING,
2785                        kind: ShimKind::ErrorContextNew {
2786                            encoding: *encoding,
2787                        },
2788                        sig: WasmSignature {
2789                            params: vec![WasmType::I32; 2],
2790                            results: vec![WasmType::I32],
2791                            indirect_params: false,
2792                            retptr: false,
2793                        },
2794                    });
2795                }
2796
2797                Import::ErrorContextDebugMessage { encoding } => {
2798                    let name = self.shims.len().to_string();
2799                    self.push(Shim {
2800                        name,
2801                        debug_name: "error-debug-message".to_string(),
2802                        options: RequiredOptions::MEMORY
2803                            | RequiredOptions::STRING_ENCODING
2804                            | RequiredOptions::REALLOC,
2805                        kind: ShimKind::ErrorContextDebugMessage {
2806                            for_module,
2807                            encoding: *encoding,
2808                        },
2809                        sig: WasmSignature {
2810                            params: vec![WasmType::I32; 2],
2811                            results: vec![],
2812                            indirect_params: false,
2813                            retptr: false,
2814                        },
2815                    });
2816                }
2817
2818                Import::ThreadNewIndirect => {
2819                    let name = self.shims.len().to_string();
2820                    self.push(Shim {
2821                        name,
2822                        debug_name: "thread.new-indirect".to_string(),
2823                        options: RequiredOptions::empty(),
2824                        kind: ShimKind::ThreadNewIndirect {
2825                            for_module,
2826                            // This is fixed for now
2827                            func_ty: FuncType::new([ValType::I32], vec![]),
2828                        },
2829                        sig: WasmSignature {
2830                            params: vec![WasmType::I32; 2],
2831                            results: vec![WasmType::I32],
2832                            indirect_params: false,
2833                            retptr: false,
2834                        },
2835                    });
2836                }
2837
2838                // Adapter imports into the main module must got through an
2839                // indirection, so that's registered here.
2840                Import::AdapterExport { adapter, func, ty } => {
2841                    let name = self.shims.len().to_string();
2842                    log::debug!("shim {name} is adapter `{module}::{field}`");
2843                    self.push(Shim {
2844                        name,
2845                        debug_name: format!("adapt-{module}-{field}"),
2846                        // Pessimistically assume that all adapters require
2847                        // memory in one form or another. While this isn't
2848                        // technically true it's true enough for WASI.
2849                        options: RequiredOptions::MEMORY,
2850                        kind: ShimKind::Adapter { adapter, func },
2851                        sig: WasmSignature {
2852                            params: ty.params().iter().map(to_wasm_type).collect(),
2853                            results: ty.results().iter().map(to_wasm_type).collect(),
2854                            indirect_params: false,
2855                            retptr: false,
2856                        },
2857                    });
2858
2859                    fn to_wasm_type(ty: &wasmparser::ValType) -> WasmType {
2860                        match ty {
2861                            wasmparser::ValType::I32 => WasmType::I32,
2862                            wasmparser::ValType::I64 => WasmType::I64,
2863                            wasmparser::ValType::F32 => WasmType::F32,
2864                            wasmparser::ValType::F64 => WasmType::F64,
2865                            _ => unreachable!(),
2866                        }
2867                    }
2868                }
2869
2870                // WIT-level functions may require an indirection, so yield some
2871                // metadata out of this `match` to the loop below to figure that
2872                // out.
2873                Import::InterfaceFunc(key, _, name, abi) => {
2874                    self.append_indirect_wit_func(
2875                        world,
2876                        for_module,
2877                        module,
2878                        field,
2879                        key,
2880                        name,
2881                        Some(resolve.name_world_key(key)),
2882                        *abi,
2883                    )?;
2884                }
2885                Import::WorldFunc(key, name, abi) => {
2886                    self.append_indirect_wit_func(
2887                        world, for_module, module, field, key, name, None, *abi,
2888                    )?;
2889                }
2890            }
2891        }
2892
2893        // In addition to all the shims added for imports above this module also
2894        // requires shims for resource destructors that it exports. Resource
2895        // types are declared before the module is instantiated so the actual
2896        // destructor is registered as a shim (defined here) and it's then
2897        // filled in with the module's exports later.
2898        for (export_name, export) in module_exports.iter() {
2899            let id = match export {
2900                Export::ResourceDtor(id) => id,
2901                _ => continue,
2902            };
2903            let resource = resolve.types[*id].name.as_ref().unwrap();
2904            let name = self.shims.len().to_string();
2905            self.push(Shim {
2906                name,
2907                debug_name: format!("dtor-{resource}"),
2908                options: RequiredOptions::empty(),
2909                kind: ShimKind::ResourceDtor {
2910                    module: for_module,
2911                    export: export_name,
2912                },
2913                sig: WasmSignature {
2914                    params: vec![WasmType::I32],
2915                    results: Vec::new(),
2916                    indirect_params: false,
2917                    retptr: false,
2918                },
2919            });
2920        }
2921
2922        Ok(())
2923    }
2924
2925    /// Helper of `append_indirect` above which pushes information for
2926    /// futures/streams read/write intrinsics.
2927    fn append_indirect_payload_push(
2928        &mut self,
2929        resolve: &Resolve,
2930        for_module: CustomModule<'a>,
2931        module: &str,
2932        async_: bool,
2933        info: &'a PayloadInfo,
2934        kind: PayloadFuncKind,
2935        params: Vec<WasmType>,
2936        results: Vec<WasmType>,
2937    ) {
2938        let debug_name = format!("{module}-{}", info.name);
2939        let name = self.shims.len().to_string();
2940
2941        let payload = info.payload(resolve);
2942        let (wit_param, wit_result) = match kind {
2943            PayloadFuncKind::StreamRead | PayloadFuncKind::FutureRead => (None, payload),
2944            PayloadFuncKind::StreamWrite | PayloadFuncKind::FutureWrite => (payload, None),
2945        };
2946        self.push(Shim {
2947            name,
2948            debug_name,
2949            options: RequiredOptions::MEMORY
2950                | RequiredOptions::for_import(
2951                    resolve,
2952                    &Function {
2953                        name: String::new(),
2954                        kind: FunctionKind::Freestanding,
2955                        params: match wit_param {
2956                            Some(ty) => vec![Param {
2957                                name: "a".to_string(),
2958                                ty,
2959                                span: Default::default(),
2960                            }],
2961                            None => Vec::new(),
2962                        },
2963                        result: wit_result,
2964                        docs: Default::default(),
2965                        stability: Stability::Unknown,
2966                        span: Default::default(),
2967                        external_id: None,
2968                    },
2969                    if async_ {
2970                        AbiVariant::GuestImportAsync
2971                    } else {
2972                        AbiVariant::GuestImport
2973                    },
2974                ),
2975            kind: ShimKind::PayloadFunc {
2976                for_module,
2977                info,
2978                kind,
2979            },
2980            sig: WasmSignature {
2981                params,
2982                results,
2983                indirect_params: false,
2984                retptr: false,
2985            },
2986        });
2987    }
2988
2989    /// Helper for `append_indirect` above which will conditionally push a shim
2990    /// for the WIT function specified by `interface_key`, `name`, and `abi`.
2991    fn append_indirect_wit_func(
2992        &mut self,
2993        world: &'a ComponentWorld<'a>,
2994        for_module: CustomModule<'a>,
2995        module: &str,
2996        field: &str,
2997        key: &WorldKey,
2998        name: &String,
2999        interface_key: Option<String>,
3000        abi: AbiVariant,
3001    ) -> Result<()> {
3002        let resolve = &world.encoder.metadata.resolve;
3003        let metadata = world.module_metadata_for(for_module);
3004        let interface = &world.import_map[&interface_key];
3005        let (index, _, lowering) = interface.lowerings.get_full(&(name.clone(), abi)).unwrap();
3006        let shim_name = self.shims.len().to_string();
3007        match lowering {
3008            Lowering::Direct | Lowering::ResourceDrop(_) => {}
3009
3010            Lowering::Indirect { sig, options } => {
3011                log::debug!(
3012                    "shim {shim_name} is import `{module}::{field}` lowering {index} `{name}`",
3013                );
3014                let encoding = metadata
3015                    .import_encodings
3016                    .get(resolve, key, name)
3017                    .ok_or_else(|| {
3018                        anyhow::anyhow!(
3019                            "missing component metadata for import of \
3020                                `{module}::{field}`"
3021                        )
3022                    })?;
3023                self.push(Shim {
3024                    name: shim_name,
3025                    debug_name: format!("indirect-{module}-{field}"),
3026                    options: *options,
3027                    kind: ShimKind::IndirectLowering {
3028                        interface: interface_key,
3029                        index,
3030                        realloc: for_module,
3031                        encoding,
3032                    },
3033                    sig: sig.clone(),
3034                });
3035            }
3036        }
3037
3038        Ok(())
3039    }
3040
3041    fn push(&mut self, shim: Shim<'a>) {
3042        // Only one shim per `ShimKind` is retained, so if it's already present
3043        // don't overwrite it. If it's not present though go ahead and insert
3044        // it.
3045        if !self.shims.contains_key(&shim.kind) {
3046            self.shims.insert(shim.kind.clone(), shim);
3047        }
3048    }
3049}
3050
3051fn task_return_options_and_type(
3052    resolve: &Resolve,
3053    func: &Function,
3054) -> (RequiredOptions, WasmSignature) {
3055    let func_tmp = Function {
3056        name: String::new(),
3057        kind: FunctionKind::Freestanding,
3058        params: match &func.result {
3059            Some(ty) => vec![Param {
3060                name: "a".to_string(),
3061                ty: *ty,
3062                span: Default::default(),
3063            }],
3064            None => Vec::new(),
3065        },
3066        result: None,
3067        docs: Default::default(),
3068        stability: Stability::Unknown,
3069        span: Default::default(),
3070        external_id: None,
3071    };
3072    let abi = AbiVariant::GuestImport;
3073    let mut options = RequiredOptions::for_import(resolve, func, abi);
3074    // `task.return` does not support a `realloc` canonical option.
3075    options.remove(RequiredOptions::REALLOC);
3076    let sig = resolve.wasm_signature(abi, &func_tmp);
3077    (options, sig)
3078}
3079
3080/// Alias argument to an instantiation
3081#[derive(Clone, Debug)]
3082pub struct Item {
3083    pub alias: String,
3084    pub kind: ExportKind,
3085    pub which: MainOrAdapter,
3086    pub name: String,
3087}
3088
3089/// Module argument to an instantiation
3090#[derive(Debug, PartialEq, Clone)]
3091pub enum MainOrAdapter {
3092    Main,
3093    Adapter(String),
3094}
3095
3096impl MainOrAdapter {
3097    fn to_custom_module(&self) -> CustomModule<'_> {
3098        match self {
3099            MainOrAdapter::Main => CustomModule::Main,
3100            MainOrAdapter::Adapter(s) => CustomModule::Adapter(s),
3101        }
3102    }
3103}
3104
3105/// Module instantiation argument
3106#[derive(Clone)]
3107pub enum Instance {
3108    /// Module argument
3109    MainOrAdapter(MainOrAdapter),
3110
3111    /// Alias argument
3112    Items(Vec<Item>),
3113}
3114
3115/// Provides fine-grained control of how a library module is instantiated
3116/// relative to other module instances
3117#[derive(Clone)]
3118pub struct LibraryInfo {
3119    /// If true, instantiate any shims prior to this module
3120    pub instantiate_after_shims: bool,
3121
3122    /// Instantiation arguments
3123    pub arguments: Vec<(String, Instance)>,
3124}
3125
3126/// Represents an adapter or library to be instantiated as part of the component
3127pub(super) struct Adapter {
3128    /// The wasm of the module itself, with `component-type` sections stripped
3129    wasm: Vec<u8>,
3130
3131    /// The metadata for the adapter
3132    metadata: ModuleMetadata,
3133
3134    /// The set of exports from the final world which are defined by this
3135    /// adapter or library
3136    required_exports: IndexSet<WorldKey>,
3137
3138    /// If present, treat this module as a library rather than a "minimal" adapter
3139    ///
3140    /// TODO: We should refactor how various flavors of module are represented
3141    /// and differentiated to avoid mistaking one for another.
3142    library_info: Option<LibraryInfo>,
3143}
3144
3145/// An encoder of components based on `wit` interface definitions.
3146#[derive(Default)]
3147pub struct ComponentEncoder {
3148    module: Vec<u8>,
3149    module_import_map: Option<ModuleImportMap>,
3150    pub(super) metadata: Bindgen,
3151    validate: bool,
3152    pub(super) main_module_exports: IndexSet<WorldKey>,
3153    pub(super) adapters: IndexMap<String, Adapter>,
3154    import_name_map: HashMap<String, String>,
3155    realloc_via_memory_grow: bool,
3156    merge_imports_based_on_semver: Option<bool>,
3157    pub(super) reject_legacy_names: bool,
3158    debug_names: bool,
3159}
3160
3161impl ComponentEncoder {
3162    /// Set the core module to encode as a component.
3163    /// This method will also parse any component type information stored in custom sections
3164    /// inside the module and add them as the interface, imports, and exports.
3165    /// It will also add any producers information inside the component type information to the
3166    /// core module.
3167    pub fn module(mut self, module: &[u8]) -> Result<Self> {
3168        let (wasm, metadata) = self.decode(module.as_ref())?;
3169        let (wasm, module_import_map) = ModuleImportMap::new(wasm)?;
3170        let exports = self
3171            .merge_metadata(metadata)
3172            .context("failed merge WIT metadata for module with previous metadata")?;
3173        self.main_module_exports.extend(exports);
3174        self.module = if let Some(producers) = &self.metadata.producers {
3175            producers.add_to_wasm(&wasm)?
3176        } else {
3177            wasm.to_vec()
3178        };
3179        self.module_import_map = module_import_map;
3180        Ok(self)
3181    }
3182
3183    fn decode<'a>(&self, wasm: &'a [u8]) -> Result<(Cow<'a, [u8]>, Bindgen)> {
3184        let (bytes, metadata) = metadata::decode(wasm)?;
3185        match bytes {
3186            Some(wasm) => Ok((Cow::Owned(wasm), metadata)),
3187            None => Ok((Cow::Borrowed(wasm), metadata)),
3188        }
3189    }
3190
3191    fn merge_metadata(&mut self, metadata: Bindgen) -> Result<IndexSet<WorldKey>> {
3192        self.metadata.merge(metadata)
3193    }
3194
3195    /// Sets whether or not the encoder will validate its output.
3196    pub fn validate(mut self, validate: bool) -> Self {
3197        self.validate = validate;
3198        self
3199    }
3200
3201    /// Sets whether or not to generate debug names in the output component.
3202    pub fn debug_names(mut self, debug_names: bool) -> Self {
3203        self.debug_names = debug_names;
3204        self
3205    }
3206
3207    /// Sets whether to merge imports based on semver to the specified value.
3208    ///
3209    /// This affects how when to WIT worlds are merged together, for example
3210    /// from two different libraries, whether their imports are unified when the
3211    /// semver version ranges for interface allow it.
3212    ///
3213    /// This is enabled by default.
3214    pub fn merge_imports_based_on_semver(mut self, merge: bool) -> Self {
3215        self.merge_imports_based_on_semver = Some(merge);
3216        self
3217    }
3218
3219    /// Sets whether to reject the historical mangling/name scheme for core wasm
3220    /// imports/exports as they map to the component model.
3221    ///
3222    /// The `wit-component` crate supported a different set of names prior to
3223    /// WebAssembly/component-model#378 and this can be used to disable this
3224    /// support.
3225    ///
3226    /// This is disabled by default.
3227    pub fn reject_legacy_names(mut self, reject: bool) -> Self {
3228        self.reject_legacy_names = reject;
3229        self
3230    }
3231
3232    /// Specifies a new adapter which is used to translate from a historical
3233    /// wasm ABI to the canonical ABI and the `interface` provided.
3234    ///
3235    /// This is primarily used to polyfill, for example,
3236    /// `wasi_snapshot_preview1` with a component-model using interface. The
3237    /// `name` provided is the module name of the adapter that is being
3238    /// polyfilled, for example `"wasi_snapshot_preview1"`.
3239    ///
3240    /// The `bytes` provided is a core wasm module which implements the `name`
3241    /// interface in terms of the `interface` interface. This core wasm module
3242    /// is severely restricted in its shape, for example it cannot have any data
3243    /// segments or element segments.
3244    ///
3245    /// The `interface` provided is the component-model-using-interface that the
3246    /// wasm module specified by `bytes` imports. The `bytes` will then import
3247    /// `interface` and export functions to get imported from the module `name`
3248    /// in the core wasm that's being wrapped.
3249    pub fn adapter(self, name: &str, bytes: &[u8]) -> Result<Self> {
3250        self.library_or_adapter(name, bytes, None)
3251    }
3252
3253    /// Specifies a shared-everything library to link into the component.
3254    ///
3255    /// Unlike adapters, libraries _may_ have data and/or element segments, but
3256    /// they must operate on an imported memory and table, respectively.  In
3257    /// this case, the correct amount of space is presumed to have been
3258    /// statically allocated in the main module's memory and table at the
3259    /// offsets which the segments target, e.g. as arranged by
3260    /// [super::linking::Linker].
3261    ///
3262    /// Libraries are treated similarly to adapters, except that they are not
3263    /// "minified" the way adapters are, and instantiation is controlled
3264    /// declaratively via the `library_info` parameter.
3265    pub fn library(self, name: &str, bytes: &[u8], library_info: LibraryInfo) -> Result<Self> {
3266        self.library_or_adapter(name, bytes, Some(library_info))
3267    }
3268
3269    fn library_or_adapter(
3270        mut self,
3271        name: &str,
3272        bytes: &[u8],
3273        library_info: Option<LibraryInfo>,
3274    ) -> Result<Self> {
3275        let (wasm, mut metadata) = self.decode(bytes)?;
3276        // Merge the adapter's document into our own document to have one large
3277        // document, and then afterwards merge worlds as well.
3278        //
3279        // Note that the `metadata` tracking import/export encodings is removed
3280        // since this adapter can get different lowerings and is allowed to
3281        // differ from the main module. This is then tracked within the
3282        // `Adapter` structure produced below.
3283        let adapter_metadata = mem::take(&mut metadata.metadata);
3284        let exports = self.merge_metadata(metadata).with_context(|| {
3285            format!("failed to merge WIT packages of adapter `{name}` into main packages")
3286        })?;
3287        if let Some(library_info) = &library_info {
3288            // Validate that all referenced modules can be resolved.
3289            for (_, instance) in &library_info.arguments {
3290                let resolve = |which: &_| match which {
3291                    MainOrAdapter::Main => Ok(()),
3292                    MainOrAdapter::Adapter(name) => {
3293                        if self.adapters.contains_key(name.as_str()) {
3294                            Ok(())
3295                        } else {
3296                            Err(anyhow!("instance refers to unknown adapter `{name}`"))
3297                        }
3298                    }
3299                };
3300
3301                match instance {
3302                    Instance::MainOrAdapter(which) => resolve(which)?,
3303                    Instance::Items(items) => {
3304                        for item in items {
3305                            resolve(&item.which)?;
3306                        }
3307                    }
3308                }
3309            }
3310        }
3311        self.adapters.insert(
3312            name.to_string(),
3313            Adapter {
3314                wasm: wasm.to_vec(),
3315                metadata: adapter_metadata,
3316                required_exports: exports,
3317                library_info,
3318            },
3319        );
3320        Ok(self)
3321    }
3322
3323    /// True if the realloc and stack allocation should use memory.grow
3324    /// The default is to use the main module realloc
3325    /// Can be useful if cabi_realloc cannot be called before the host
3326    /// runtime is initialized.
3327    pub fn realloc_via_memory_grow(mut self, value: bool) -> Self {
3328        self.realloc_via_memory_grow = value;
3329        self
3330    }
3331
3332    /// The instance import name map to use.
3333    ///
3334    /// This is used to rename instance imports in the final component.
3335    ///
3336    /// For example, if there is an instance import `foo:bar/baz` and it is
3337    /// desired that the import actually be an `unlocked-dep` name, then
3338    /// `foo:bar/baz` can be mapped to `unlocked-dep=<a:b/c@{>=x.y.z}>`.
3339    ///
3340    /// Note: the replacement names are not validated during encoding unless
3341    /// the `validate` option is set to true.
3342    pub fn import_name_map(mut self, map: HashMap<String, String>) -> Self {
3343        self.import_name_map = map;
3344        self
3345    }
3346
3347    /// Encode the component and return the bytes.
3348    pub fn encode(&mut self) -> Result<Vec<u8>> {
3349        if self.module.is_empty() {
3350            bail!("a module is required when encoding a component");
3351        }
3352
3353        if self.merge_imports_based_on_semver.unwrap_or(true) {
3354            self.metadata
3355                .resolve
3356                .merge_world_imports_based_on_semver(self.metadata.world)?;
3357        }
3358
3359        self.finalize_resolve_with_nominal_ids();
3360
3361        let world = ComponentWorld::new(self).context("failed to decode world from module")?;
3362        let mut state = EncodingState {
3363            component: ComponentBuilder::default(),
3364            module_index: None,
3365            instance_index: None,
3366            memory_index: None,
3367            shim_instance_index: None,
3368            fixups_module_index: None,
3369            adapter_modules: IndexMap::new(),
3370            adapter_instances: IndexMap::new(),
3371            type_encoding_maps: Default::default(),
3372            instances: Default::default(),
3373            imported_funcs: Default::default(),
3374            aliased_core_items: Default::default(),
3375            info: &world,
3376            export_task_initialization_wrappers: HashMap::new(),
3377        };
3378        state.encode_imports(&self.import_name_map)?;
3379        state.encode_core_modules();
3380        state.encode_core_instantiation()?;
3381        state.encode_exports(CustomModule::Main)?;
3382        for name in self.adapters.keys() {
3383            state.encode_exports(CustomModule::Adapter(name))?;
3384        }
3385        state.component.append_names();
3386        state
3387            .component
3388            .raw_custom_section(&crate::base_producers().raw_custom_section());
3389        let bytes = state.component.finish();
3390
3391        if self.validate {
3392            Validator::new_with_features(WasmFeatures::all())
3393                .validate_all(&bytes)
3394                .context("failed to validate component output")?;
3395        }
3396
3397        Ok(bytes)
3398    }
3399
3400    /// Call the `generate_nominal_type_ids` method on the `Resolve` that we're
3401    /// using, adjusting any preexisting keys/pointers as necessary.
3402    ///
3403    /// This is the final step after merging all known `Resolve`s together
3404    /// before a component is actually created. By creating a unique
3405    /// `InterfaceId` for all interfaces it makes the generation process easier
3406    /// since there's no need to fret about whether an `InterfaceId` is an
3407    /// import or an export for example.
3408    fn finalize_resolve_with_nominal_ids(&mut self) {
3409        // Before calling `generate_nominal_type_ids` we need to handle the fact
3410        // that the exports of the world are going to be rewritten. The only
3411        // pointers we have into those are the exports of the main module and
3412        // adapters. To handle this, before we generate nominal ids, indices of
3413        // exports are saved here on the stack to get restored later on.
3414        // Effectively we're clearing out the exports and rebuilding them later.
3415        let world = &self.metadata.resolve.worlds[self.metadata.world];
3416        let main_module_exports = self
3417            .main_module_exports
3418            .iter()
3419            .map(|i| world.exports.get_index_of(i).unwrap())
3420            .collect::<Vec<_>>();
3421        let adapter_exports = self
3422            .adapters
3423            .values()
3424            .map(|adapter| {
3425                adapter
3426                    .required_exports
3427                    .iter()
3428                    .map(|i| world.exports.get_index_of(i).unwrap())
3429                    .collect::<Vec<_>>()
3430            })
3431            .collect::<Vec<_>>();
3432
3433        // With everything saved this will modify `Resolve` to ensure there's a
3434        // nominal identifier for all interfaces (e.g. not both simultaneously
3435        // imported and exported).
3436        self.metadata
3437            .resolve
3438            .generate_nominal_type_ids(self.metadata.world);
3439
3440        // Rebuild the sets of exports now that the world's exports have been
3441        // clobbered.
3442        self.main_module_exports.clear();
3443        let world = &self.metadata.resolve.worlds[self.metadata.world];
3444        for index in main_module_exports {
3445            let (key, _) = world.exports.get_index(index).unwrap();
3446            self.main_module_exports.insert(key.clone());
3447        }
3448        for (exports, adapter) in adapter_exports.into_iter().zip(self.adapters.values_mut()) {
3449            adapter.required_exports.clear();
3450            for index in exports {
3451                let (key, _) = world.exports.get_index(index).unwrap();
3452                adapter.required_exports.insert(key.clone());
3453            }
3454        }
3455    }
3456}
3457
3458impl ComponentWorld<'_> {
3459    /// Convenience function to lookup a module's import map.
3460    fn imports_for(&self, module: CustomModule) -> &ImportMap {
3461        match module {
3462            CustomModule::Main => &self.info.imports,
3463            CustomModule::Adapter(name) => &self.adapters[name].info.imports,
3464        }
3465    }
3466
3467    /// Convenience function to lookup a module's export map.
3468    fn exports_for(&self, module: CustomModule) -> &ExportMap {
3469        match module {
3470            CustomModule::Main => &self.info.exports,
3471            CustomModule::Adapter(name) => &self.adapters[name].info.exports,
3472        }
3473    }
3474
3475    /// Convenience function to lookup a module's metadata.
3476    fn module_metadata_for(&self, module: CustomModule) -> &ModuleMetadata {
3477        match module {
3478            CustomModule::Main => &self.encoder.metadata.metadata,
3479            CustomModule::Adapter(name) => &self.encoder.adapters[name].metadata,
3480        }
3481    }
3482}
3483
3484#[cfg(all(test, feature = "dummy-module"))]
3485mod test {
3486    use super::*;
3487    use crate::{dummy_module, embed_component_metadata};
3488    use wit_parser::ManglingAndAbi;
3489
3490    #[test]
3491    fn it_renames_imports() {
3492        let mut resolve = Resolve::new();
3493        let pkg = resolve
3494            .push_str(
3495                "test.wit",
3496                r#"
3497package test:wit;
3498
3499interface i {
3500    f: func();
3501}
3502
3503world test {
3504    import i;
3505    import foo: interface {
3506        f: func();
3507    }
3508}
3509"#,
3510            )
3511            .unwrap();
3512        let world = resolve.select_world(&[pkg], None).unwrap();
3513
3514        let mut module = dummy_module(&resolve, world, ManglingAndAbi::Standard32);
3515
3516        embed_component_metadata(&mut module, &resolve, world, StringEncoding::UTF8).unwrap();
3517
3518        let encoded = ComponentEncoder::default()
3519            .import_name_map(HashMap::from([
3520                (
3521                    "foo".to_string(),
3522                    "unlocked-dep=<foo:bar/foo@{>=1.0.0 <1.1.0}>".to_string(),
3523                ),
3524                (
3525                    "test:wit/i".to_string(),
3526                    "locked-dep=<foo:bar/i@1.2.3>".to_string(),
3527                ),
3528            ]))
3529            .module(&module)
3530            .unwrap()
3531            .validate(true)
3532            .encode()
3533            .unwrap();
3534
3535        let wat = wasmprinter::print_bytes(encoded).unwrap();
3536        assert!(wat.contains("unlocked-dep=<foo:bar/foo@{>=1.0.0 <1.1.0}>"));
3537        assert!(wat.contains("locked-dep=<foo:bar/i@1.2.3>"));
3538    }
3539}