use crate::export::Export; use hashbrown::{hash_map::Entry, HashMap}; use std::collections::VecDeque; use std::{ cell::{Ref, RefCell}, ffi::c_void, rc::Rc, }; pub trait LikeNamespace { fn get_export(&self, name: &str) -> Option; fn get_exports(&self) -> Vec<(String, Export)>; fn maybe_insert(&mut self, name: &str, export: Export) -> Option<()>; } pub trait IsExport { fn to_export(&self) -> Export; } impl IsExport for Export { fn to_export(&self) -> Export { self.clone() } } /// All of the import data used when instantiating. /// /// It's suggested that you use the [`imports!`] macro /// instead of creating an `ImportObject` by hand. /// /// [`imports!`]: macro.imports.html /// /// # Usage: /// ``` /// # use wasmer_runtime_core::{imports, func}; /// # use wasmer_runtime_core::vm::Ctx; /// let import_object = imports! { /// "env" => { /// "foo" => func!(foo), /// }, /// }; /// /// fn foo(_: &mut Ctx, n: i32) -> i32 { /// n /// } /// ``` pub struct ImportObject { map: Rc>>>, state_creator: Option (*mut c_void, fn(*mut c_void))>>, pub allow_missing_functions: bool, } impl ImportObject { /// Create a new `ImportObject`. pub fn new() -> Self { Self { map: Rc::new(RefCell::new(HashMap::new())), state_creator: None, allow_missing_functions: false, } } pub fn new_with_data(state_creator: F) -> Self where F: Fn() -> (*mut c_void, fn(*mut c_void)) + 'static, { Self { map: Rc::new(RefCell::new(HashMap::new())), state_creator: Some(Rc::new(state_creator)), allow_missing_functions: false, } } pub(crate) fn call_state_creator(&self) -> Option<(*mut c_void, fn(*mut c_void))> { self.state_creator.as_ref().map(|state_gen| state_gen()) } /// Register anything that implements `LikeNamespace` as a namespace. /// /// # Usage: /// ``` /// # use wasmer_runtime_core::Instance; /// # use wasmer_runtime_core::import::{ImportObject, Namespace}; /// fn register(instance: Instance, namespace: Namespace) { /// let mut import_object = ImportObject::new(); /// /// import_object.register("namespace0", instance); /// import_object.register("namespace1", namespace); /// // ... /// } /// ``` pub fn register(&mut self, name: S, namespace: N) -> Option> where S: Into, N: LikeNamespace + 'static, { let mut map = self.map.borrow_mut(); match map.entry(name.into()) { Entry::Vacant(empty) => { empty.insert(Box::new(namespace)); None } Entry::Occupied(mut occupied) => Some(occupied.insert(Box::new(namespace))), } } pub fn get_namespace(&self, namespace: &str) -> Option> { let map_ref = self.map.borrow(); if map_ref.contains_key(namespace) { Some(Ref::map(map_ref, |map| &*map[namespace])) } else { None } } pub fn clone_ref(&self) -> Self { Self { map: Rc::clone(&self.map), state_creator: self.state_creator.clone(), allow_missing_functions: false, } } fn get_objects(&self) -> VecDeque<(String, String, Export)> { let mut out = VecDeque::new(); for (name, ns) in self.map.borrow().iter() { for (id, exp) in ns.get_exports() { out.push_back((name.clone(), id, exp)); } } out } } pub struct ImportObjectIterator { elements: VecDeque<(String, String, Export)>, } impl Iterator for ImportObjectIterator { type Item = (String, String, Export); fn next(&mut self) -> Option { self.elements.pop_front() } } impl IntoIterator for ImportObject { type IntoIter = ImportObjectIterator; type Item = (String, String, Export); fn into_iter(self) -> Self::IntoIter { ImportObjectIterator { elements: self.get_objects(), } } } impl Extend<(String, String, Export)> for ImportObject { fn extend>(&mut self, iter: T) { let mut map = self.map.borrow_mut(); for (ns, id, exp) in iter.into_iter() { if let Some(like_ns) = map.get_mut(&ns) { like_ns.maybe_insert(&id, exp); } else { let mut new_ns = Namespace::new(); new_ns.insert(id, exp); map.insert(ns, Box::new(new_ns)); } } } } pub struct Namespace { map: HashMap>, } impl Namespace { pub fn new() -> Self { Self { map: HashMap::new(), } } pub fn insert(&mut self, name: S, export: E) -> Option> where S: Into, E: IsExport + 'static, { self.map.insert(name.into(), Box::new(export)) } } impl LikeNamespace for Namespace { fn get_export(&self, name: &str) -> Option { self.map.get(name).map(|is_export| is_export.to_export()) } fn get_exports(&self) -> Vec<(String, Export)> { self.map .iter() .map(|(k, v)| (k.clone(), v.to_export())) .collect() } fn maybe_insert(&mut self, name: &str, export: Export) -> Option<()> { self.map.insert(name.to_owned(), Box::new(export)); Some(()) } } #[cfg(test)] mod test { use crate::export::Export; use crate::global::Global; use crate::types::Value; #[test] fn extending_works() { let mut imports1 = imports! { "dog" => { "happy" => Global::new(Value::I32(0)), }, }; let imports2 = imports! { "dog" => { "small" => Global::new(Value::I32(2)), }, "cat" => { "small" => Global::new(Value::I32(3)), }, }; imports1.extend(imports2); let cat_ns = imports1.get_namespace("cat").unwrap(); assert!(cat_ns.get_export("small").is_some()); let dog_ns = imports1.get_namespace("dog").unwrap(); assert!(dog_ns.get_export("happy").is_some()); assert!(dog_ns.get_export("small").is_some()); } #[test] fn extending_conflict_overwrites() { let mut imports1 = imports! { "dog" => { "happy" => Global::new(Value::I32(0)), }, }; let imports2 = imports! { "dog" => { "happy" => Global::new(Value::I32(4)), }, }; imports1.extend(imports2); let dog_ns = imports1.get_namespace("dog").unwrap(); assert!( if let Export::Global(happy_dog_global) = dog_ns.get_export("happy").unwrap() { happy_dog_global.get() == Value::I32(4) } else { false } ); } }