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denoland-deno/core/modules.rs
Bartek Iwańczuk 4e8edafb39
perf(core): over-allocate in ModuleMap when running from snapshot (#18083)
This commit changes "ModuleMap" initialization to over-allocate by 16
for vectors storing module information and module V8 handles. In 99%
cases there's gonna be at least one additional module loaded, so it's
very wasteful to have to reallocate when the module is executed (IIRC
Rust will double the size of the vector) and move all of the elements.
2023-03-09 09:12:46 +05:30

2958 lines
87 KiB
Rust

// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license.
use crate::bindings;
use crate::error::generic_error;
use crate::extensions::ExtensionFileSource;
use crate::module_specifier::ModuleSpecifier;
use crate::resolve_import;
use crate::resolve_url;
use crate::JsRuntime;
use crate::OpState;
use anyhow::Error;
use futures::future::FutureExt;
use futures::stream::FuturesUnordered;
use futures::stream::Stream;
use futures::stream::StreamFuture;
use futures::stream::TryStreamExt;
use log::debug;
use serde::Deserialize;
use serde::Serialize;
use std::cell::RefCell;
use std::collections::HashMap;
use std::collections::HashSet;
use std::collections::VecDeque;
use std::future::Future;
use std::pin::Pin;
use std::rc::Rc;
use std::task::Context;
use std::task::Poll;
pub type ModuleId = usize;
pub(crate) type ModuleLoadId = i32;
pub const BOM_CHAR: &[u8] = &[0xef, 0xbb, 0xbf];
/// Strips the byte order mark from the provided text if it exists.
fn strip_bom(source_code: &[u8]) -> &[u8] {
if source_code.starts_with(BOM_CHAR) {
&source_code[BOM_CHAR.len()..]
} else {
source_code
}
}
const SUPPORTED_TYPE_ASSERTIONS: &[&str] = &["json"];
/// Throws V8 exception if assertions are invalid
pub(crate) fn validate_import_assertions(
scope: &mut v8::HandleScope,
assertions: &HashMap<String, String>,
) {
for (key, value) in assertions {
if key == "type" && !SUPPORTED_TYPE_ASSERTIONS.contains(&value.as_str()) {
let message = v8::String::new(
scope,
&format!("\"{value}\" is not a valid module type."),
)
.unwrap();
let exception = v8::Exception::type_error(scope, message);
scope.throw_exception(exception);
return;
}
}
}
#[derive(Debug)]
pub(crate) enum ImportAssertionsKind {
StaticImport,
DynamicImport,
}
pub(crate) fn parse_import_assertions(
scope: &mut v8::HandleScope,
import_assertions: v8::Local<v8::FixedArray>,
kind: ImportAssertionsKind,
) -> HashMap<String, String> {
let mut assertions: HashMap<String, String> = HashMap::default();
let assertions_per_line = match kind {
// For static imports, assertions are triples of (keyword, value and source offset)
// Also used in `module_resolve_callback`.
ImportAssertionsKind::StaticImport => 3,
// For dynamic imports, assertions are tuples of (keyword, value)
ImportAssertionsKind::DynamicImport => 2,
};
assert_eq!(import_assertions.length() % assertions_per_line, 0);
let no_of_assertions = import_assertions.length() / assertions_per_line;
for i in 0..no_of_assertions {
let assert_key = import_assertions
.get(scope, assertions_per_line * i)
.unwrap();
let assert_key_val = v8::Local::<v8::Value>::try_from(assert_key).unwrap();
let assert_value = import_assertions
.get(scope, (assertions_per_line * i) + 1)
.unwrap();
let assert_value_val =
v8::Local::<v8::Value>::try_from(assert_value).unwrap();
assertions.insert(
assert_key_val.to_rust_string_lossy(scope),
assert_value_val.to_rust_string_lossy(scope),
);
}
assertions
}
pub(crate) fn get_asserted_module_type_from_assertions(
assertions: &HashMap<String, String>,
) -> AssertedModuleType {
assertions
.get("type")
.map(|ty| {
if ty == "json" {
AssertedModuleType::Json
} else {
AssertedModuleType::JavaScriptOrWasm
}
})
.unwrap_or(AssertedModuleType::JavaScriptOrWasm)
}
// Clippy thinks the return value doesn't need to be an Option, it's unaware
// of the mapping that MapFnFrom<F> does for ResolveModuleCallback.
#[allow(clippy::unnecessary_wraps)]
fn json_module_evaluation_steps<'a>(
context: v8::Local<'a, v8::Context>,
module: v8::Local<v8::Module>,
) -> Option<v8::Local<'a, v8::Value>> {
// SAFETY: `CallbackScope` can be safely constructed from `Local<Context>`
let scope = &mut unsafe { v8::CallbackScope::new(context) };
let tc_scope = &mut v8::TryCatch::new(scope);
let module_map = JsRuntime::module_map(tc_scope);
let handle = v8::Global::<v8::Module>::new(tc_scope, module);
let value_handle = module_map
.borrow_mut()
.json_value_store
.remove(&handle)
.unwrap();
let value_local = v8::Local::new(tc_scope, value_handle);
let name = v8::String::new(tc_scope, "default").unwrap();
// This should never fail
assert!(
module.set_synthetic_module_export(tc_scope, name, value_local)
== Some(true)
);
assert!(!tc_scope.has_caught());
// Since TLA is active we need to return a promise.
let resolver = v8::PromiseResolver::new(tc_scope).unwrap();
let undefined = v8::undefined(tc_scope);
resolver.resolve(tc_scope, undefined.into());
Some(resolver.get_promise(tc_scope).into())
}
/// A type of module to be executed.
///
/// For non-`JavaScript` modules, this value doesn't tell
/// how to interpret the module; it is only used to validate
/// the module against an import assertion (if one is present
/// in the import statement).
#[derive(Clone, Copy, Debug, Eq, Hash, PartialEq, Serialize, Deserialize)]
#[repr(u32)]
pub enum ModuleType {
JavaScript,
Json,
}
impl std::fmt::Display for ModuleType {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
match self {
Self::JavaScript => write!(f, "JavaScript"),
Self::Json => write!(f, "JSON"),
}
}
}
/// EsModule source code that will be loaded into V8.
///
/// Users can implement `Into<ModuleInfo>` for different file types that
/// can be transpiled to valid EsModule.
///
/// Found module URL might be different from specified URL
/// used for loading due to redirections (like HTTP 303).
/// Eg. Both "`https://example.com/a.ts`" and
/// "`https://example.com/b.ts`" may point to "`https://example.com/c.ts`"
/// By keeping track of specified and found URL we can alias modules and avoid
/// recompiling the same code 3 times.
// TODO(bartlomieju): I have a strong opinion we should store all redirects
// that happened; not only first and final target. It would simplify a lot
// of things throughout the codebase otherwise we may end up requesting
// intermediate redirects from file loader.
#[derive(Debug, Clone, Eq, PartialEq)]
pub struct ModuleSource {
pub code: Box<[u8]>,
pub module_type: ModuleType,
pub module_url_specified: String,
pub module_url_found: String,
}
pub(crate) type PrepareLoadFuture =
dyn Future<Output = (ModuleLoadId, Result<RecursiveModuleLoad, Error>)>;
pub type ModuleSourceFuture = dyn Future<Output = Result<ModuleSource, Error>>;
type ModuleLoadFuture =
dyn Future<Output = Result<(ModuleRequest, ModuleSource), Error>>;
#[derive(Debug, PartialEq, Eq)]
pub enum ResolutionKind {
/// This kind is used in only one situation: when a module is loaded via
/// `JsRuntime::load_main_module` and is the top-level module, ie. the one
/// passed as an argument to `JsRuntime::load_main_module`.
MainModule,
/// This kind is returned for all other modules during module load, that are
/// static imports.
Import,
/// This kind is returned for all modules that are loaded as a result of a
/// call to `import()` API (ie. top-level module as well as all its
/// dependencies, and any other `import()` calls from that load).
DynamicImport,
}
pub trait ModuleLoader {
/// Returns an absolute URL.
/// When implementing an spec-complaint VM, this should be exactly the
/// algorithm described here:
/// <https://html.spec.whatwg.org/multipage/webappapis.html#resolve-a-module-specifier>
///
/// `is_main` can be used to resolve from current working directory or
/// apply import map for child imports.
///
/// `is_dyn_import` can be used to check permissions or deny
/// dynamic imports altogether.
fn resolve(
&self,
specifier: &str,
referrer: &str,
kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error>;
/// Given ModuleSpecifier, load its source code.
///
/// `is_dyn_import` can be used to check permissions or deny
/// dynamic imports altogether.
fn load(
&self,
module_specifier: &ModuleSpecifier,
maybe_referrer: Option<ModuleSpecifier>,
is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>>;
/// This hook can be used by implementors to do some preparation
/// work before starting loading of modules.
///
/// For example implementor might download multiple modules in
/// parallel and transpile them to final JS sources before
/// yielding control back to the runtime.
///
/// It's not required to implement this method.
fn prepare_load(
&self,
_op_state: Rc<RefCell<OpState>>,
_module_specifier: &ModuleSpecifier,
_maybe_referrer: Option<String>,
_is_dyn_import: bool,
) -> Pin<Box<dyn Future<Output = Result<(), Error>>>> {
async { Ok(()) }.boxed_local()
}
}
/// Placeholder structure used when creating
/// a runtime that doesn't support module loading.
pub struct NoopModuleLoader;
impl ModuleLoader for NoopModuleLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
_kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
Err(generic_error(
format!("Module loading is not supported; attempted to resolve: \"{specifier}\" from \"{referrer}\"")
))
}
fn load(
&self,
module_specifier: &ModuleSpecifier,
maybe_referrer: Option<ModuleSpecifier>,
_is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>> {
let err = generic_error(
format!(
"Module loading is not supported; attempted to load: \"{module_specifier}\" from \"{maybe_referrer:?}\"",
)
);
async move { Err(err) }.boxed_local()
}
}
/// Helper function, that calls into `loader.resolve()`, but denies resolution
/// of `ext` scheme if we are running with a snapshot loaded and not
/// creating a snapshot
pub(crate) fn resolve_helper(
snapshot_loaded_and_not_snapshotting: bool,
loader: Rc<dyn ModuleLoader>,
specifier: &str,
referrer: &str,
kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
if snapshot_loaded_and_not_snapshotting && specifier.starts_with("ext:") {
return Err(generic_error(
"Cannot load extension module from external code",
));
}
loader.resolve(specifier, referrer, kind)
}
/// Function that can be passed to the `ExtModuleLoader` that allows to
/// transpile sources before passing to V8.
pub type ExtModuleLoaderCb =
Box<dyn Fn(&ExtensionFileSource) -> Result<String, Error>>;
pub struct ExtModuleLoader {
module_loader: Rc<dyn ModuleLoader>,
esm_sources: Vec<ExtensionFileSource>,
used_esm_sources: RefCell<HashMap<String, bool>>,
maybe_load_callback: Option<ExtModuleLoaderCb>,
}
impl Default for ExtModuleLoader {
fn default() -> Self {
Self {
module_loader: Rc::new(NoopModuleLoader),
esm_sources: vec![],
used_esm_sources: RefCell::new(HashMap::default()),
maybe_load_callback: None,
}
}
}
impl ExtModuleLoader {
pub fn new(
module_loader: Option<Rc<dyn ModuleLoader>>,
esm_sources: Vec<ExtensionFileSource>,
maybe_load_callback: Option<ExtModuleLoaderCb>,
) -> Self {
let used_esm_sources: HashMap<String, bool> = esm_sources
.iter()
.map(|file_source| (file_source.specifier.to_string(), false))
.collect();
ExtModuleLoader {
module_loader: module_loader.unwrap_or_else(|| Rc::new(NoopModuleLoader)),
esm_sources,
used_esm_sources: RefCell::new(used_esm_sources),
maybe_load_callback,
}
}
}
impl Drop for ExtModuleLoader {
fn drop(&mut self) {
let used_esm_sources = self.used_esm_sources.get_mut();
let unused_modules: Vec<_> = used_esm_sources
.iter()
.filter(|(_s, v)| !*v)
.map(|(s, _)| s)
.collect();
if !unused_modules.is_empty() {
let mut msg =
"Following modules were passed to ExtModuleLoader but never used:\n"
.to_string();
for m in unused_modules {
msg.push_str(" - ");
msg.push_str(m);
msg.push('\n');
}
panic!("{}", msg);
}
}
}
impl ModuleLoader for ExtModuleLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
if let Ok(url_specifier) = ModuleSpecifier::parse(specifier) {
if url_specifier.scheme() == "ext" {
let referrer_specifier = ModuleSpecifier::parse(referrer).ok();
if referrer == "." || referrer_specifier.unwrap().scheme() == "ext" {
return Ok(url_specifier);
} else {
return Err(generic_error(
"Cannot load extension module from external code",
));
};
}
}
self.module_loader.resolve(specifier, referrer, kind)
}
fn load(
&self,
module_specifier: &ModuleSpecifier,
maybe_referrer: Option<ModuleSpecifier>,
is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>> {
if module_specifier.scheme() != "ext" {
return self.module_loader.load(
module_specifier,
maybe_referrer,
is_dyn_import,
);
}
let specifier = module_specifier.to_string();
let maybe_file_source = self
.esm_sources
.iter()
.find(|file_source| file_source.specifier == module_specifier.as_str());
if let Some(file_source) = maybe_file_source {
{
let mut used_esm_sources = self.used_esm_sources.borrow_mut();
let used = used_esm_sources.get_mut(&file_source.specifier).unwrap();
*used = true;
}
let result = if let Some(load_callback) = &self.maybe_load_callback {
load_callback(file_source)
} else {
match file_source.code.load() {
Ok(code) => Ok(code),
Err(err) => return futures::future::err(err).boxed_local(),
}
};
return async move {
let code = result?;
let source = ModuleSource {
code: code.into_bytes().into_boxed_slice(),
module_type: ModuleType::JavaScript,
module_url_specified: specifier.clone(),
module_url_found: specifier.clone(),
};
Ok(source)
}
.boxed_local();
}
async move {
Err(generic_error(format!(
"Cannot find extension module source for specifier {specifier}"
)))
}
.boxed_local()
}
fn prepare_load(
&self,
op_state: Rc<RefCell<OpState>>,
module_specifier: &ModuleSpecifier,
maybe_referrer: Option<String>,
is_dyn_import: bool,
) -> Pin<Box<dyn Future<Output = Result<(), Error>>>> {
if module_specifier.scheme() == "ext" {
return async { Ok(()) }.boxed_local();
}
self.module_loader.prepare_load(
op_state,
module_specifier,
maybe_referrer,
is_dyn_import,
)
}
}
/// Basic file system module loader.
///
/// Note that this loader will **block** event loop
/// when loading file as it uses synchronous FS API
/// from standard library.
pub struct FsModuleLoader;
impl ModuleLoader for FsModuleLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
_kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
Ok(resolve_import(specifier, referrer)?)
}
fn load(
&self,
module_specifier: &ModuleSpecifier,
_maybe_referrer: Option<ModuleSpecifier>,
_is_dynamic: bool,
) -> Pin<Box<ModuleSourceFuture>> {
let module_specifier = module_specifier.clone();
async move {
let path = module_specifier.to_file_path().map_err(|_| {
generic_error(format!(
"Provided module specifier \"{module_specifier}\" is not a file URL."
))
})?;
let module_type = if let Some(extension) = path.extension() {
let ext = extension.to_string_lossy().to_lowercase();
if ext == "json" {
ModuleType::Json
} else {
ModuleType::JavaScript
}
} else {
ModuleType::JavaScript
};
let code = std::fs::read(path)?;
let module = ModuleSource {
code: code.into_boxed_slice(),
module_type,
module_url_specified: module_specifier.to_string(),
module_url_found: module_specifier.to_string(),
};
Ok(module)
}
.boxed_local()
}
}
/// Describes the entrypoint of a recursive module load.
#[derive(Debug)]
enum LoadInit {
/// Main module specifier.
Main(String),
/// Module specifier for side module.
Side(String),
/// Dynamic import specifier with referrer and expected
/// module type (which is determined by import assertion).
DynamicImport(String, String, AssertedModuleType),
}
#[derive(Debug, Eq, PartialEq)]
pub enum LoadState {
Init,
LoadingRoot,
LoadingImports,
Done,
}
/// This future is used to implement parallel async module loading.
pub(crate) struct RecursiveModuleLoad {
pub id: ModuleLoadId,
pub root_module_id: Option<ModuleId>,
init: LoadInit,
root_asserted_module_type: Option<AssertedModuleType>,
root_module_type: Option<ModuleType>,
state: LoadState,
module_map_rc: Rc<RefCell<ModuleMap>>,
pending: FuturesUnordered<Pin<Box<ModuleLoadFuture>>>,
visited: HashSet<ModuleRequest>,
// These three fields are copied from `module_map_rc`, but they are cloned
// ahead of time to avoid already-borrowed errors.
op_state: Rc<RefCell<OpState>>,
loader: Rc<dyn ModuleLoader>,
snapshot_loaded_and_not_snapshotting: bool,
}
impl RecursiveModuleLoad {
/// Starts a new asynchronous load of the module graph for given specifier.
///
/// The module corresponding for the given `specifier` will be marked as
// "the main module" (`import.meta.main` will return `true` for this module).
fn main(specifier: &str, module_map_rc: Rc<RefCell<ModuleMap>>) -> Self {
Self::new(LoadInit::Main(specifier.to_string()), module_map_rc)
}
/// Starts a new asynchronous load of the module graph for given specifier.
fn side(specifier: &str, module_map_rc: Rc<RefCell<ModuleMap>>) -> Self {
Self::new(LoadInit::Side(specifier.to_string()), module_map_rc)
}
/// Starts a new asynchronous load of the module graph for given specifier
/// that was imported using `import()`.
fn dynamic_import(
specifier: &str,
referrer: &str,
asserted_module_type: AssertedModuleType,
module_map_rc: Rc<RefCell<ModuleMap>>,
) -> Self {
Self::new(
LoadInit::DynamicImport(
specifier.to_string(),
referrer.to_string(),
asserted_module_type,
),
module_map_rc,
)
}
fn new(init: LoadInit, module_map_rc: Rc<RefCell<ModuleMap>>) -> Self {
let id = {
let mut module_map = module_map_rc.borrow_mut();
let id = module_map.next_load_id;
module_map.next_load_id += 1;
id
};
let op_state = module_map_rc.borrow().op_state.clone();
let loader = module_map_rc.borrow().loader.clone();
let asserted_module_type = match init {
LoadInit::DynamicImport(_, _, module_type) => module_type,
_ => AssertedModuleType::JavaScriptOrWasm,
};
let mut load = Self {
id,
root_module_id: None,
root_asserted_module_type: None,
root_module_type: None,
init,
state: LoadState::Init,
module_map_rc: module_map_rc.clone(),
snapshot_loaded_and_not_snapshotting: module_map_rc
.borrow()
.snapshot_loaded_and_not_snapshotting,
op_state,
loader,
pending: FuturesUnordered::new(),
visited: HashSet::new(),
};
// FIXME(bartlomieju): this seems fishy
// Ignore the error here, let it be hit in `Stream::poll_next()`.
if let Ok(root_specifier) = load.resolve_root() {
if let Some(module_id) = module_map_rc
.borrow()
.get_id(root_specifier.as_str(), asserted_module_type)
{
load.root_module_id = Some(module_id);
load.root_asserted_module_type = Some(asserted_module_type);
load.root_module_type = Some(
module_map_rc
.borrow()
.get_info_by_id(module_id)
.unwrap()
.module_type,
);
}
}
load
}
fn resolve_root(&self) -> Result<ModuleSpecifier, Error> {
match self.init {
LoadInit::Main(ref specifier) => resolve_helper(
self.snapshot_loaded_and_not_snapshotting,
self.loader.clone(),
specifier,
".",
ResolutionKind::MainModule,
),
LoadInit::Side(ref specifier) => resolve_helper(
self.snapshot_loaded_and_not_snapshotting,
self.loader.clone(),
specifier,
".",
ResolutionKind::Import,
),
LoadInit::DynamicImport(ref specifier, ref referrer, _) => {
resolve_helper(
self.snapshot_loaded_and_not_snapshotting,
self.loader.clone(),
specifier,
referrer,
ResolutionKind::DynamicImport,
)
}
}
}
async fn prepare(&self) -> Result<(), Error> {
let op_state = self.op_state.clone();
let (module_specifier, maybe_referrer) = match self.init {
LoadInit::Main(ref specifier) => {
let spec = resolve_helper(
self.snapshot_loaded_and_not_snapshotting,
self.loader.clone(),
specifier,
".",
ResolutionKind::MainModule,
)?;
(spec, None)
}
LoadInit::Side(ref specifier) => {
let spec = resolve_helper(
self.snapshot_loaded_and_not_snapshotting,
self.loader.clone(),
specifier,
".",
ResolutionKind::Import,
)?;
(spec, None)
}
LoadInit::DynamicImport(ref specifier, ref referrer, _) => {
let spec = resolve_helper(
self.snapshot_loaded_and_not_snapshotting,
self.loader.clone(),
specifier,
referrer,
ResolutionKind::DynamicImport,
)?;
(spec, Some(referrer.to_string()))
}
};
self
.loader
.prepare_load(
op_state,
&module_specifier,
maybe_referrer,
self.is_dynamic_import(),
)
.await
}
fn is_currently_loading_main_module(&self) -> bool {
!self.is_dynamic_import()
&& matches!(self.init, LoadInit::Main(..))
&& self.state == LoadState::LoadingRoot
}
fn is_dynamic_import(&self) -> bool {
matches!(self.init, LoadInit::DynamicImport(..))
}
pub(crate) fn register_and_recurse(
&mut self,
scope: &mut v8::HandleScope,
module_request: &ModuleRequest,
module_source: &ModuleSource,
) -> Result<(), ModuleError> {
let expected_asserted_module_type = module_source.module_type.into();
if module_request.asserted_module_type != expected_asserted_module_type {
return Err(ModuleError::Other(generic_error(format!(
"Expected a \"{}\" module but loaded a \"{}\" module.",
module_request.asserted_module_type, module_source.module_type,
))));
}
// Register the module in the module map unless it's already there. If the
// specified URL and the "true" URL are different, register the alias.
if module_source.module_url_specified != module_source.module_url_found {
self.module_map_rc.borrow_mut().alias(
&module_source.module_url_specified,
expected_asserted_module_type,
&module_source.module_url_found,
);
}
let maybe_module_id = self.module_map_rc.borrow().get_id(
&module_source.module_url_found,
expected_asserted_module_type,
);
let module_id = match maybe_module_id {
Some(id) => {
debug!(
"Already-registered module fetched again: {}",
module_source.module_url_found
);
id
}
None => match module_source.module_type {
ModuleType::JavaScript => {
self.module_map_rc.borrow_mut().new_es_module(
scope,
self.is_currently_loading_main_module(),
&module_source.module_url_found,
&module_source.code,
self.is_dynamic_import(),
)?
}
ModuleType::Json => self.module_map_rc.borrow_mut().new_json_module(
scope,
&module_source.module_url_found,
&module_source.code,
)?,
},
};
// Recurse the module's imports. There are two cases for each import:
// 1. If the module is not in the module map, start a new load for it in
// `self.pending`. The result of that load should eventually be passed to
// this function for recursion.
// 2. If the module is already in the module map, queue it up to be
// recursed synchronously here.
// This robustly ensures that the whole graph is in the module map before
// `LoadState::Done` is set.
let mut already_registered = VecDeque::new();
already_registered.push_back((module_id, module_request.clone()));
self.visited.insert(module_request.clone());
while let Some((module_id, module_request)) = already_registered.pop_front()
{
let referrer = ModuleSpecifier::parse(&module_request.specifier).unwrap();
let imports = self
.module_map_rc
.borrow()
.get_requested_modules(module_id)
.unwrap()
.clone();
for module_request in imports {
if !self.visited.contains(&module_request) {
if let Some(module_id) = self.module_map_rc.borrow().get_id(
module_request.specifier.as_str(),
module_request.asserted_module_type,
) {
already_registered.push_back((module_id, module_request.clone()));
} else {
let request = module_request.clone();
let specifier =
ModuleSpecifier::parse(&module_request.specifier).unwrap();
let referrer = referrer.clone();
let loader = self.loader.clone();
let is_dynamic_import = self.is_dynamic_import();
let fut = async move {
let load_result = loader
.load(&specifier, Some(referrer.clone()), is_dynamic_import)
.await;
load_result.map(|s| (request, s))
};
self.pending.push(fut.boxed_local());
}
self.visited.insert(module_request);
}
}
}
// Update `self.state` however applicable.
if self.state == LoadState::LoadingRoot {
self.root_module_id = Some(module_id);
self.root_asserted_module_type = Some(module_source.module_type.into());
self.state = LoadState::LoadingImports;
}
if self.pending.is_empty() {
self.state = LoadState::Done;
}
Ok(())
}
}
impl Stream for RecursiveModuleLoad {
type Item = Result<(ModuleRequest, ModuleSource), Error>;
fn poll_next(
self: Pin<&mut Self>,
cx: &mut Context,
) -> Poll<Option<Self::Item>> {
let inner = self.get_mut();
// IMPORTANT: Do not borrow `inner.module_map_rc` here. It may not be
// available.
match inner.state {
LoadState::Init => {
let module_specifier = match inner.resolve_root() {
Ok(url) => url,
Err(error) => return Poll::Ready(Some(Err(error))),
};
let load_fut = if let Some(_module_id) = inner.root_module_id {
// FIXME(bartlomieju): this is very bad
// The root module is already in the module map.
// TODO(nayeemrmn): In this case we would ideally skip to
// `LoadState::LoadingImports` and synchronously recurse the imports
// like the bottom of `RecursiveModuleLoad::register_and_recurse()`.
// But the module map cannot be borrowed here. Instead fake a load
// event so it gets passed to that function and recursed eventually.
let asserted_module_type = inner.root_asserted_module_type.unwrap();
let module_type = inner.root_module_type.unwrap();
let module_request = ModuleRequest {
specifier: module_specifier.to_string(),
asserted_module_type,
};
let module_source = ModuleSource {
module_url_specified: module_specifier.to_string(),
module_url_found: module_specifier.to_string(),
// The code will be discarded, since this module is already in the
// module map.
code: Default::default(),
module_type,
};
futures::future::ok((module_request, module_source)).boxed()
} else {
let maybe_referrer = match inner.init {
LoadInit::DynamicImport(_, ref referrer, _) => {
resolve_url(referrer).ok()
}
_ => None,
};
let asserted_module_type = match inner.init {
LoadInit::DynamicImport(_, _, module_type) => module_type,
_ => AssertedModuleType::JavaScriptOrWasm,
};
let module_request = ModuleRequest {
specifier: module_specifier.to_string(),
asserted_module_type,
};
let loader = inner.loader.clone();
let is_dynamic_import = inner.is_dynamic_import();
async move {
let result = loader
.load(&module_specifier, maybe_referrer, is_dynamic_import)
.await;
result.map(|s| (module_request, s))
}
.boxed_local()
};
inner.pending.push(load_fut);
inner.state = LoadState::LoadingRoot;
inner.try_poll_next_unpin(cx)
}
LoadState::LoadingRoot | LoadState::LoadingImports => {
match inner.pending.try_poll_next_unpin(cx)? {
Poll::Ready(None) => unreachable!(),
Poll::Ready(Some(info)) => Poll::Ready(Some(Ok(info))),
Poll::Pending => Poll::Pending,
}
}
LoadState::Done => Poll::Ready(None),
}
}
}
#[derive(Clone, Copy, Debug, Eq, Hash, PartialEq, Serialize, Deserialize)]
#[repr(u32)]
pub(crate) enum AssertedModuleType {
JavaScriptOrWasm,
Json,
}
impl From<ModuleType> for AssertedModuleType {
fn from(module_type: ModuleType) -> AssertedModuleType {
match module_type {
ModuleType::JavaScript => AssertedModuleType::JavaScriptOrWasm,
ModuleType::Json => AssertedModuleType::Json,
}
}
}
impl std::fmt::Display for AssertedModuleType {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
match self {
Self::JavaScriptOrWasm => write!(f, "JavaScriptOrWasm"),
Self::Json => write!(f, "JSON"),
}
}
}
/// Describes a request for a module as parsed from the source code.
/// Usually executable (`JavaScriptOrWasm`) is used, except when an
/// import assertions explicitly constrains an import to JSON, in
/// which case this will have a `AssertedModuleType::Json`.
#[derive(Clone, Debug, Eq, Hash, PartialEq, Serialize, Deserialize)]
pub(crate) struct ModuleRequest {
pub specifier: String,
pub asserted_module_type: AssertedModuleType,
}
#[derive(Clone, Debug, Serialize, Deserialize, PartialEq)]
pub(crate) struct ModuleInfo {
#[allow(unused)]
pub id: ModuleId,
// Used in "bindings.rs" for "import.meta.main" property value.
pub main: bool,
pub name: String,
pub requests: Vec<ModuleRequest>,
pub module_type: ModuleType,
}
/// A symbolic module entity.
#[derive(Clone, Debug, Deserialize, Serialize, PartialEq)]
pub(crate) enum SymbolicModule {
/// This module is an alias to another module.
/// This is useful such that multiple names could point to
/// the same underlying module (particularly due to redirects).
Alias(String),
/// This module associates with a V8 module by id.
Mod(ModuleId),
}
#[derive(Debug)]
pub(crate) enum ModuleError {
Exception(v8::Global<v8::Value>),
Other(Error),
}
/// A collection of JS modules.
pub(crate) struct ModuleMap {
// Handling of specifiers and v8 objects
pub handles: Vec<v8::Global<v8::Module>>,
pub info: Vec<ModuleInfo>,
pub(crate) by_name: HashMap<(String, AssertedModuleType), SymbolicModule>,
pub(crate) next_load_id: ModuleLoadId,
// Handling of futures for loading module sources
pub loader: Rc<dyn ModuleLoader>,
op_state: Rc<RefCell<OpState>>,
pub(crate) dynamic_import_map:
HashMap<ModuleLoadId, v8::Global<v8::PromiseResolver>>,
pub(crate) preparing_dynamic_imports:
FuturesUnordered<Pin<Box<PrepareLoadFuture>>>,
pub(crate) pending_dynamic_imports:
FuturesUnordered<StreamFuture<RecursiveModuleLoad>>,
// This store is used temporarly, to forward parsed JSON
// value from `new_json_module` to `json_module_evaluation_steps`
json_value_store: HashMap<v8::Global<v8::Module>, v8::Global<v8::Value>>,
pub(crate) snapshot_loaded_and_not_snapshotting: bool,
}
impl ModuleMap {
pub fn serialize_for_snapshotting(
&self,
scope: &mut v8::HandleScope,
) -> (v8::Global<v8::Array>, Vec<v8::Global<v8::Module>>) {
let array = v8::Array::new(scope, 3);
let next_load_id = v8::Integer::new(scope, self.next_load_id);
array.set_index(scope, 0, next_load_id.into());
let info_arr = v8::Array::new(scope, self.info.len() as i32);
for (i, info) in self.info.iter().enumerate() {
let module_info_arr = v8::Array::new(scope, 5);
let id = v8::Integer::new(scope, info.id as i32);
module_info_arr.set_index(scope, 0, id.into());
let main = v8::Boolean::new(scope, info.main);
module_info_arr.set_index(scope, 1, main.into());
let name = v8::String::new(scope, &info.name).unwrap();
module_info_arr.set_index(scope, 2, name.into());
let array_len = 2 * info.requests.len() as i32;
let requests_arr = v8::Array::new(scope, array_len);
for (i, request) in info.requests.iter().enumerate() {
let specifier = v8::String::new(scope, &request.specifier).unwrap();
requests_arr.set_index(scope, 2 * i as u32, specifier.into());
let asserted_module_type =
v8::Integer::new(scope, request.asserted_module_type as i32);
requests_arr.set_index(
scope,
(2 * i) as u32 + 1,
asserted_module_type.into(),
);
}
module_info_arr.set_index(scope, 3, requests_arr.into());
let module_type = v8::Integer::new(scope, info.module_type as i32);
module_info_arr.set_index(scope, 4, module_type.into());
info_arr.set_index(scope, i as u32, module_info_arr.into());
}
array.set_index(scope, 1, info_arr.into());
let by_name_array = v8::Array::new(scope, self.by_name.len() as i32);
{
for (i, elem) in self.by_name.iter().enumerate() {
let arr = v8::Array::new(scope, 3);
let (specifier, asserted_module_type) = elem.0;
let specifier = v8::String::new(scope, specifier).unwrap();
arr.set_index(scope, 0, specifier.into());
let asserted_module_type =
v8::Integer::new(scope, *asserted_module_type as i32);
arr.set_index(scope, 1, asserted_module_type.into());
let symbolic_module: v8::Local<v8::Value> = match &elem.1 {
SymbolicModule::Alias(alias) => {
let alias = v8::String::new(scope, alias).unwrap();
alias.into()
}
SymbolicModule::Mod(id) => {
let id = v8::Integer::new(scope, *id as i32);
id.into()
}
};
arr.set_index(scope, 2, symbolic_module);
by_name_array.set_index(scope, i as u32, arr.into());
}
}
array.set_index(scope, 2, by_name_array.into());
let array_global = v8::Global::new(scope, array);
let handles = self.handles.clone();
(array_global, handles)
}
pub fn update_with_snapshot_data(
&mut self,
scope: &mut v8::HandleScope,
data: v8::Global<v8::Array>,
module_handles: Vec<v8::Global<v8::Module>>,
) {
let local_data: v8::Local<v8::Array> = v8::Local::new(scope, data);
{
let next_load_id = local_data.get_index(scope, 0).unwrap();
assert!(next_load_id.is_int32());
let integer = next_load_id.to_integer(scope).unwrap();
let val = integer.int32_value(scope).unwrap();
self.next_load_id = val;
}
{
let info_val = local_data.get_index(scope, 1).unwrap();
let info_arr: v8::Local<v8::Array> = info_val.try_into().unwrap();
let len = info_arr.length() as usize;
// Over allocate so executing a few scripts doesn't have to resize this vec.
let mut info = Vec::with_capacity(len + 16);
for i in 0..len {
let module_info_arr: v8::Local<v8::Array> = info_arr
.get_index(scope, i as u32)
.unwrap()
.try_into()
.unwrap();
let id = module_info_arr
.get_index(scope, 0)
.unwrap()
.to_integer(scope)
.unwrap()
.value() as ModuleId;
let main = module_info_arr
.get_index(scope, 1)
.unwrap()
.to_boolean(scope)
.is_true();
let name = module_info_arr
.get_index(scope, 2)
.unwrap()
.to_rust_string_lossy(scope);
let requests_arr: v8::Local<v8::Array> = module_info_arr
.get_index(scope, 3)
.unwrap()
.try_into()
.unwrap();
let len = (requests_arr.length() as usize) / 2;
let mut requests = Vec::with_capacity(len);
for i in 0..len {
let specifier = requests_arr
.get_index(scope, (2 * i) as u32)
.unwrap()
.to_rust_string_lossy(scope);
let asserted_module_type_no = requests_arr
.get_index(scope, (2 * i + 1) as u32)
.unwrap()
.to_integer(scope)
.unwrap()
.value();
let asserted_module_type = match asserted_module_type_no {
0 => AssertedModuleType::JavaScriptOrWasm,
1 => AssertedModuleType::Json,
_ => unreachable!(),
};
requests.push(ModuleRequest {
specifier,
asserted_module_type,
});
}
let module_type_no = module_info_arr
.get_index(scope, 4)
.unwrap()
.to_integer(scope)
.unwrap()
.value();
let module_type = match module_type_no {
0 => ModuleType::JavaScript,
1 => ModuleType::Json,
_ => unreachable!(),
};
let module_info = ModuleInfo {
id,
main,
name,
requests,
module_type,
};
info.push(module_info);
}
self.info = info;
}
{
let by_name_arr: v8::Local<v8::Array> =
local_data.get_index(scope, 2).unwrap().try_into().unwrap();
let len = by_name_arr.length() as usize;
let mut by_name = HashMap::with_capacity(len);
for i in 0..len {
let arr: v8::Local<v8::Array> = by_name_arr
.get_index(scope, i as u32)
.unwrap()
.try_into()
.unwrap();
let specifier =
arr.get_index(scope, 0).unwrap().to_rust_string_lossy(scope);
let asserted_module_type = match arr
.get_index(scope, 1)
.unwrap()
.to_integer(scope)
.unwrap()
.value()
{
0 => AssertedModuleType::JavaScriptOrWasm,
1 => AssertedModuleType::Json,
_ => unreachable!(),
};
let key = (specifier, asserted_module_type);
let symbolic_module_val = arr.get_index(scope, 2).unwrap();
let val = if symbolic_module_val.is_number() {
SymbolicModule::Mod(
symbolic_module_val
.to_integer(scope)
.unwrap()
.value()
.try_into()
.unwrap(),
)
} else {
SymbolicModule::Alias(symbolic_module_val.to_rust_string_lossy(scope))
};
by_name.insert(key, val);
}
self.by_name = by_name;
}
self.handles = module_handles;
}
pub(crate) fn new(
loader: Rc<dyn ModuleLoader>,
op_state: Rc<RefCell<OpState>>,
snapshot_loaded_and_not_snapshotting: bool,
) -> ModuleMap {
Self {
handles: vec![],
info: vec![],
by_name: HashMap::new(),
next_load_id: 1,
loader,
op_state,
dynamic_import_map: HashMap::new(),
preparing_dynamic_imports: FuturesUnordered::new(),
pending_dynamic_imports: FuturesUnordered::new(),
json_value_store: HashMap::new(),
snapshot_loaded_and_not_snapshotting,
}
}
/// Get module id, following all aliases in case of module specifier
/// that had been redirected.
fn get_id(
&self,
name: &str,
asserted_module_type: AssertedModuleType,
) -> Option<ModuleId> {
let mut mod_name = name;
loop {
let symbolic_module = self
.by_name
.get(&(mod_name.to_string(), asserted_module_type))?;
match symbolic_module {
SymbolicModule::Alias(target) => {
mod_name = target;
}
SymbolicModule::Mod(mod_id) => return Some(*mod_id),
}
}
}
fn new_json_module(
&mut self,
scope: &mut v8::HandleScope,
name: &str,
source: &[u8],
) -> Result<ModuleId, ModuleError> {
let name_str = v8::String::new(scope, name).unwrap();
let source_str = v8::String::new_from_utf8(
scope,
strip_bom(source),
v8::NewStringType::Normal,
)
.unwrap();
let tc_scope = &mut v8::TryCatch::new(scope);
let parsed_json = match v8::json::parse(tc_scope, source_str) {
Some(parsed_json) => parsed_json,
None => {
assert!(tc_scope.has_caught());
let exception = tc_scope.exception().unwrap();
let exception = v8::Global::new(tc_scope, exception);
return Err(ModuleError::Exception(exception));
}
};
let export_names = [v8::String::new(tc_scope, "default").unwrap()];
let module = v8::Module::create_synthetic_module(
tc_scope,
name_str,
&export_names,
json_module_evaluation_steps,
);
let handle = v8::Global::<v8::Module>::new(tc_scope, module);
let value_handle = v8::Global::<v8::Value>::new(tc_scope, parsed_json);
self.json_value_store.insert(handle.clone(), value_handle);
let id =
self.create_module_info(name, ModuleType::Json, handle, false, vec![]);
Ok(id)
}
// Create and compile an ES module.
pub(crate) fn new_es_module(
&mut self,
scope: &mut v8::HandleScope,
main: bool,
name: &str,
source: &[u8],
is_dynamic_import: bool,
) -> Result<ModuleId, ModuleError> {
let name_str = v8::String::new(scope, name).unwrap();
let source_str =
v8::String::new_from_utf8(scope, source, v8::NewStringType::Normal)
.unwrap();
let origin = bindings::module_origin(scope, name_str);
let source = v8::script_compiler::Source::new(source_str, Some(&origin));
let tc_scope = &mut v8::TryCatch::new(scope);
let maybe_module = v8::script_compiler::compile_module(tc_scope, source);
if tc_scope.has_caught() {
assert!(maybe_module.is_none());
let exception = tc_scope.exception().unwrap();
let exception = v8::Global::new(tc_scope, exception);
return Err(ModuleError::Exception(exception));
}
let module = maybe_module.unwrap();
let mut requests: Vec<ModuleRequest> = vec![];
let module_requests = module.get_module_requests();
for i in 0..module_requests.length() {
let module_request = v8::Local::<v8::ModuleRequest>::try_from(
module_requests.get(tc_scope, i).unwrap(),
)
.unwrap();
let import_specifier = module_request
.get_specifier()
.to_rust_string_lossy(tc_scope);
let import_assertions = module_request.get_import_assertions();
let assertions = parse_import_assertions(
tc_scope,
import_assertions,
ImportAssertionsKind::StaticImport,
);
// FIXME(bartomieju): there are no stack frames if exception
// is thrown here
validate_import_assertions(tc_scope, &assertions);
if tc_scope.has_caught() {
let exception = tc_scope.exception().unwrap();
let exception = v8::Global::new(tc_scope, exception);
return Err(ModuleError::Exception(exception));
}
let module_specifier = match resolve_helper(
self.snapshot_loaded_and_not_snapshotting,
self.loader.clone(),
&import_specifier,
name,
if is_dynamic_import {
ResolutionKind::DynamicImport
} else {
ResolutionKind::Import
},
) {
Ok(s) => s,
Err(e) => return Err(ModuleError::Other(e)),
};
let asserted_module_type =
get_asserted_module_type_from_assertions(&assertions);
let request = ModuleRequest {
specifier: module_specifier.to_string(),
asserted_module_type,
};
requests.push(request);
}
if main {
let maybe_main_module = self.info.iter().find(|module| module.main);
if let Some(main_module) = maybe_main_module {
return Err(ModuleError::Other(generic_error(
format!("Trying to create \"main\" module ({:?}), when one already exists ({:?})",
name,
main_module.name,
))));
}
}
let handle = v8::Global::<v8::Module>::new(tc_scope, module);
let id = self.create_module_info(
name,
ModuleType::JavaScript,
handle,
main,
requests,
);
Ok(id)
}
fn create_module_info(
&mut self,
name: &str,
module_type: ModuleType,
handle: v8::Global<v8::Module>,
main: bool,
requests: Vec<ModuleRequest>,
) -> ModuleId {
let id = self.handles.len();
self.by_name.insert(
(name.to_string(), module_type.into()),
SymbolicModule::Mod(id),
);
self.handles.push(handle);
self.info.push(ModuleInfo {
id,
main,
name: name.to_string(),
requests,
module_type,
});
id
}
fn get_requested_modules(&self, id: ModuleId) -> Option<&Vec<ModuleRequest>> {
self.info.get(id).map(|i| &i.requests)
}
fn is_registered(
&self,
specifier: &ModuleSpecifier,
asserted_module_type: AssertedModuleType,
) -> bool {
if let Some(id) = self.get_id(specifier.as_str(), asserted_module_type) {
let info = self.get_info_by_id(id).unwrap();
return asserted_module_type == info.module_type.into();
}
false
}
fn alias(
&mut self,
name: &str,
asserted_module_type: AssertedModuleType,
target: &str,
) {
self.by_name.insert(
(name.to_string(), asserted_module_type),
SymbolicModule::Alias(target.to_string()),
);
}
#[cfg(test)]
fn is_alias(
&self,
name: &str,
asserted_module_type: AssertedModuleType,
) -> bool {
let cond = self.by_name.get(&(name.to_string(), asserted_module_type));
matches!(cond, Some(SymbolicModule::Alias(_)))
}
pub(crate) fn get_handle(
&self,
id: ModuleId,
) -> Option<v8::Global<v8::Module>> {
self.handles.get(id).cloned()
}
pub(crate) fn get_info(
&self,
global: &v8::Global<v8::Module>,
) -> Option<&ModuleInfo> {
if let Some(id) = self.handles.iter().position(|module| module == global) {
return self.info.get(id);
}
None
}
pub(crate) fn get_info_by_id(&self, id: ModuleId) -> Option<&ModuleInfo> {
self.info.get(id)
}
pub(crate) async fn load_main(
module_map_rc: Rc<RefCell<ModuleMap>>,
specifier: &str,
) -> Result<RecursiveModuleLoad, Error> {
let load = RecursiveModuleLoad::main(specifier, module_map_rc.clone());
load.prepare().await?;
Ok(load)
}
pub(crate) async fn load_side(
module_map_rc: Rc<RefCell<ModuleMap>>,
specifier: &str,
) -> Result<RecursiveModuleLoad, Error> {
let load = RecursiveModuleLoad::side(specifier, module_map_rc.clone());
load.prepare().await?;
Ok(load)
}
// Initiate loading of a module graph imported using `import()`.
pub(crate) fn load_dynamic_import(
module_map_rc: Rc<RefCell<ModuleMap>>,
specifier: &str,
referrer: &str,
asserted_module_type: AssertedModuleType,
resolver_handle: v8::Global<v8::PromiseResolver>,
) {
let load = RecursiveModuleLoad::dynamic_import(
specifier,
referrer,
asserted_module_type,
module_map_rc.clone(),
);
module_map_rc
.borrow_mut()
.dynamic_import_map
.insert(load.id, resolver_handle);
let (loader, snapshot_loaded_and_not_snapshotting) = {
let module_map = module_map_rc.borrow();
(
module_map.loader.clone(),
module_map.snapshot_loaded_and_not_snapshotting,
)
};
let resolve_result = resolve_helper(
snapshot_loaded_and_not_snapshotting,
loader,
specifier,
referrer,
ResolutionKind::DynamicImport,
);
let fut = match resolve_result {
Ok(module_specifier) => {
if module_map_rc
.borrow()
.is_registered(&module_specifier, asserted_module_type)
{
async move { (load.id, Ok(load)) }.boxed_local()
} else {
async move { (load.id, load.prepare().await.map(|()| load)) }
.boxed_local()
}
}
Err(error) => async move { (load.id, Err(error)) }.boxed_local(),
};
module_map_rc
.borrow_mut()
.preparing_dynamic_imports
.push(fut);
}
pub(crate) fn has_pending_dynamic_imports(&self) -> bool {
!(self.preparing_dynamic_imports.is_empty()
&& self.pending_dynamic_imports.is_empty())
}
/// Called by `module_resolve_callback` during module instantiation.
pub(crate) fn resolve_callback<'s>(
&self,
scope: &mut v8::HandleScope<'s>,
specifier: &str,
referrer: &str,
import_assertions: HashMap<String, String>,
) -> Option<v8::Local<'s, v8::Module>> {
let resolved_specifier = resolve_helper(
self.snapshot_loaded_and_not_snapshotting,
self.loader.clone(),
specifier,
referrer,
ResolutionKind::Import,
)
.expect("Module should have been already resolved");
let module_type =
get_asserted_module_type_from_assertions(&import_assertions);
if let Some(id) = self.get_id(resolved_specifier.as_str(), module_type) {
if let Some(handle) = self.get_handle(id) {
return Some(v8::Local::new(scope, handle));
}
}
None
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::Extension;
use crate::JsRuntime;
use crate::RuntimeOptions;
use crate::Snapshot;
use deno_ops::op;
use futures::future::FutureExt;
use parking_lot::Mutex;
use std::fmt;
use std::future::Future;
use std::io;
use std::path::PathBuf;
use std::sync::atomic::AtomicUsize;
use std::sync::atomic::Ordering;
use std::sync::Arc;
// deno_ops macros generate code assuming deno_core in scope.
mod deno_core {
pub use crate::*;
}
// TODO(ry) Sadly FuturesUnordered requires the current task to be set. So
// even though we are only using poll() in these tests and not Tokio, we must
// nevertheless run it in the tokio executor. Ideally run_in_task can be
// removed in the future.
use crate::runtime::tests::run_in_task;
#[derive(Default)]
struct MockLoader {
pub loads: Arc<Mutex<Vec<String>>>,
}
impl MockLoader {
fn new() -> Rc<Self> {
Default::default()
}
}
fn mock_source_code(url: &str) -> Option<(&'static str, &'static str)> {
const A_SRC: &str = r#"
import { b } from "/b.js";
import { c } from "/c.js";
if (b() != 'b') throw Error();
if (c() != 'c') throw Error();
if (!import.meta.main) throw Error();
if (import.meta.url != 'file:///a.js') throw Error();
"#;
const B_SRC: &str = r#"
import { c } from "/c.js";
if (c() != 'c') throw Error();
export function b() { return 'b'; }
if (import.meta.main) throw Error();
if (import.meta.url != 'file:///b.js') throw Error();
"#;
const C_SRC: &str = r#"
import { d } from "/d.js";
export function c() { return 'c'; }
if (d() != 'd') throw Error();
if (import.meta.main) throw Error();
if (import.meta.url != 'file:///c.js') throw Error();
"#;
const D_SRC: &str = r#"
export function d() { return 'd'; }
if (import.meta.main) throw Error();
if (import.meta.url != 'file:///d.js') throw Error();
"#;
const CIRCULAR1_SRC: &str = r#"
import "/circular2.js";
Deno.core.print("circular1");
"#;
const CIRCULAR2_SRC: &str = r#"
import "/circular3.js";
Deno.core.print("circular2");
"#;
const CIRCULAR3_SRC: &str = r#"
import "/circular1.js";
import "/circular2.js";
Deno.core.print("circular3");
"#;
const REDIRECT1_SRC: &str = r#"
import "./redirect2.js";
Deno.core.print("redirect1");
"#;
const REDIRECT2_SRC: &str = r#"
import "./redirect3.js";
Deno.core.print("redirect2");
"#;
const REDIRECT3_SRC: &str = r#"Deno.core.print("redirect3");"#;
const MAIN_SRC: &str = r#"
// never_ready.js never loads.
import "/never_ready.js";
// slow.js resolves after one tick.
import "/slow.js";
"#;
const SLOW_SRC: &str = r#"
// Circular import of never_ready.js
// Does this trigger two ModuleLoader calls? It shouldn't.
import "/never_ready.js";
import "/a.js";
"#;
const BAD_IMPORT_SRC: &str = r#"import "foo";"#;
// (code, real_module_name)
let spec: Vec<&str> = url.split("file://").collect();
match spec[1] {
"/a.js" => Some((A_SRC, "file:///a.js")),
"/b.js" => Some((B_SRC, "file:///b.js")),
"/c.js" => Some((C_SRC, "file:///c.js")),
"/d.js" => Some((D_SRC, "file:///d.js")),
"/circular1.js" => Some((CIRCULAR1_SRC, "file:///circular1.js")),
"/circular2.js" => Some((CIRCULAR2_SRC, "file:///circular2.js")),
"/circular3.js" => Some((CIRCULAR3_SRC, "file:///circular3.js")),
"/redirect1.js" => Some((REDIRECT1_SRC, "file:///redirect1.js")),
// pretend redirect - real module name is different than one requested
"/redirect2.js" => Some((REDIRECT2_SRC, "file:///dir/redirect2.js")),
"/dir/redirect3.js" => Some((REDIRECT3_SRC, "file:///redirect3.js")),
"/slow.js" => Some((SLOW_SRC, "file:///slow.js")),
"/never_ready.js" => {
Some(("should never be Ready", "file:///never_ready.js"))
}
"/main.js" => Some((MAIN_SRC, "file:///main.js")),
"/bad_import.js" => Some((BAD_IMPORT_SRC, "file:///bad_import.js")),
// deliberately empty code.
"/main_with_code.js" => Some(("", "file:///main_with_code.js")),
_ => None,
}
}
#[derive(Debug, PartialEq)]
enum MockError {
ResolveErr,
LoadErr,
}
impl fmt::Display for MockError {
fn fmt(&self, _f: &mut fmt::Formatter) -> fmt::Result {
unimplemented!()
}
}
impl std::error::Error for MockError {
fn cause(&self) -> Option<&dyn std::error::Error> {
unimplemented!()
}
}
struct DelayedSourceCodeFuture {
url: String,
counter: u32,
}
impl Future for DelayedSourceCodeFuture {
type Output = Result<ModuleSource, Error>;
fn poll(self: Pin<&mut Self>, cx: &mut Context) -> Poll<Self::Output> {
let inner = self.get_mut();
inner.counter += 1;
if inner.url == "file:///never_ready.js" {
return Poll::Pending;
}
if inner.url == "file:///slow.js" && inner.counter < 2 {
// TODO(ry) Hopefully in the future we can remove current task
// notification. See comment above run_in_task.
cx.waker().wake_by_ref();
return Poll::Pending;
}
match mock_source_code(&inner.url) {
Some(src) => Poll::Ready(Ok(ModuleSource {
code: src.0.as_bytes().to_vec().into_boxed_slice(),
module_type: ModuleType::JavaScript,
module_url_specified: inner.url.clone(),
module_url_found: src.1.to_owned(),
})),
None => Poll::Ready(Err(MockError::LoadErr.into())),
}
}
}
impl ModuleLoader for MockLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
_kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
let referrer = if referrer == "." {
"file:///"
} else {
referrer
};
let output_specifier = match resolve_import(specifier, referrer) {
Ok(specifier) => specifier,
Err(..) => return Err(MockError::ResolveErr.into()),
};
if mock_source_code(output_specifier.as_ref()).is_some() {
Ok(output_specifier)
} else {
Err(MockError::ResolveErr.into())
}
}
fn load(
&self,
module_specifier: &ModuleSpecifier,
_maybe_referrer: Option<ModuleSpecifier>,
_is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>> {
let mut loads = self.loads.lock();
loads.push(module_specifier.to_string());
let url = module_specifier.to_string();
DelayedSourceCodeFuture { url, counter: 0 }.boxed()
}
}
#[test]
fn test_recursive_load() {
let loader = MockLoader::new();
let loads = loader.loads.clone();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
let spec = resolve_url("file:///a.js").unwrap();
let a_id_fut = runtime.load_main_module(&spec, None);
let a_id = futures::executor::block_on(a_id_fut).unwrap();
#[allow(clippy::let_underscore_future)]
let _ = runtime.mod_evaluate(a_id);
futures::executor::block_on(runtime.run_event_loop(false)).unwrap();
let l = loads.lock();
assert_eq!(
l.to_vec(),
vec![
"file:///a.js",
"file:///b.js",
"file:///c.js",
"file:///d.js"
]
);
let module_map_rc = JsRuntime::module_map(runtime.v8_isolate());
let modules = module_map_rc.borrow();
assert_eq!(
modules.get_id("file:///a.js", AssertedModuleType::JavaScriptOrWasm),
Some(a_id)
);
let b_id = modules
.get_id("file:///b.js", AssertedModuleType::JavaScriptOrWasm)
.unwrap();
let c_id = modules
.get_id("file:///c.js", AssertedModuleType::JavaScriptOrWasm)
.unwrap();
let d_id = modules
.get_id("file:///d.js", AssertedModuleType::JavaScriptOrWasm)
.unwrap();
assert_eq!(
modules.get_requested_modules(a_id),
Some(&vec![
ModuleRequest {
specifier: "file:///b.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
},
ModuleRequest {
specifier: "file:///c.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
},
])
);
assert_eq!(
modules.get_requested_modules(b_id),
Some(&vec![ModuleRequest {
specifier: "file:///c.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
},])
);
assert_eq!(
modules.get_requested_modules(c_id),
Some(&vec![ModuleRequest {
specifier: "file:///d.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
},])
);
assert_eq!(modules.get_requested_modules(d_id), Some(&vec![]));
}
#[test]
fn test_mods() {
#[derive(Default)]
struct ModsLoader {
pub count: Arc<AtomicUsize>,
}
impl ModuleLoader for ModsLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
_kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
self.count.fetch_add(1, Ordering::Relaxed);
assert_eq!(specifier, "./b.js");
assert_eq!(referrer, "file:///a.js");
let s = resolve_import(specifier, referrer).unwrap();
Ok(s)
}
fn load(
&self,
_module_specifier: &ModuleSpecifier,
_maybe_referrer: Option<ModuleSpecifier>,
_is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>> {
unreachable!()
}
}
let loader = Rc::new(ModsLoader::default());
let resolve_count = loader.count.clone();
static DISPATCH_COUNT: AtomicUsize = AtomicUsize::new(0);
#[op]
fn op_test(control: u8) -> u8 {
DISPATCH_COUNT.fetch_add(1, Ordering::Relaxed);
assert_eq!(control, 42);
43
}
let ext = Extension::builder("test_ext")
.ops(vec![op_test::decl()])
.build();
let mut runtime = JsRuntime::new(RuntimeOptions {
extensions: vec![ext],
module_loader: Some(loader),
..Default::default()
});
runtime
.execute_script(
"setup.js",
r#"
function assert(cond) {
if (!cond) {
throw Error("assert");
}
}
"#,
)
.unwrap();
assert_eq!(DISPATCH_COUNT.load(Ordering::Relaxed), 0);
let module_map_rc = JsRuntime::module_map(runtime.v8_isolate());
let (mod_a, mod_b) = {
let scope = &mut runtime.handle_scope();
let mut module_map = module_map_rc.borrow_mut();
let specifier_a = "file:///a.js".to_string();
let mod_a = module_map
.new_es_module(
scope,
true,
&specifier_a,
br#"
import { b } from './b.js'
if (b() != 'b') throw Error();
let control = 42;
Deno.core.ops.op_test(control);
"#,
false,
)
.unwrap();
assert_eq!(DISPATCH_COUNT.load(Ordering::Relaxed), 0);
let imports = module_map.get_requested_modules(mod_a);
assert_eq!(
imports,
Some(&vec![ModuleRequest {
specifier: "file:///b.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
},])
);
let mod_b = module_map
.new_es_module(
scope,
false,
"file:///b.js",
b"export function b() { return 'b' }",
false,
)
.unwrap();
let imports = module_map.get_requested_modules(mod_b).unwrap();
assert_eq!(imports.len(), 0);
(mod_a, mod_b)
};
runtime.instantiate_module(mod_b).unwrap();
assert_eq!(DISPATCH_COUNT.load(Ordering::Relaxed), 0);
assert_eq!(resolve_count.load(Ordering::SeqCst), 1);
runtime.instantiate_module(mod_a).unwrap();
assert_eq!(DISPATCH_COUNT.load(Ordering::Relaxed), 0);
#[allow(clippy::let_underscore_future)]
let _ = runtime.mod_evaluate(mod_a);
assert_eq!(DISPATCH_COUNT.load(Ordering::Relaxed), 1);
}
#[test]
fn test_json_module() {
#[derive(Default)]
struct ModsLoader {
pub count: Arc<AtomicUsize>,
}
impl ModuleLoader for ModsLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
_kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
self.count.fetch_add(1, Ordering::Relaxed);
assert_eq!(specifier, "./b.json");
assert_eq!(referrer, "file:///a.js");
let s = resolve_import(specifier, referrer).unwrap();
Ok(s)
}
fn load(
&self,
_module_specifier: &ModuleSpecifier,
_maybe_referrer: Option<ModuleSpecifier>,
_is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>> {
unreachable!()
}
}
let loader = Rc::new(ModsLoader::default());
let resolve_count = loader.count.clone();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
runtime
.execute_script(
"setup.js",
r#"
function assert(cond) {
if (!cond) {
throw Error("assert");
}
}
"#,
)
.unwrap();
let module_map_rc = JsRuntime::module_map(runtime.v8_isolate());
let (mod_a, mod_b) = {
let scope = &mut runtime.handle_scope();
let mut module_map = module_map_rc.borrow_mut();
let specifier_a = "file:///a.js".to_string();
let mod_a = module_map
.new_es_module(
scope,
true,
&specifier_a,
br#"
import jsonData from './b.json' assert {type: "json"};
assert(jsonData.a == "b");
assert(jsonData.c.d == 10);
"#,
false,
)
.unwrap();
let imports = module_map.get_requested_modules(mod_a);
assert_eq!(
imports,
Some(&vec![ModuleRequest {
specifier: "file:///b.json".to_string(),
asserted_module_type: AssertedModuleType::Json,
},])
);
let mod_b = module_map
.new_json_module(
scope,
"file:///b.json",
b"{\"a\": \"b\", \"c\": {\"d\": 10}}",
)
.unwrap();
let imports = module_map.get_requested_modules(mod_b).unwrap();
assert_eq!(imports.len(), 0);
(mod_a, mod_b)
};
runtime.instantiate_module(mod_b).unwrap();
assert_eq!(resolve_count.load(Ordering::SeqCst), 1);
runtime.instantiate_module(mod_a).unwrap();
let receiver = runtime.mod_evaluate(mod_a);
futures::executor::block_on(runtime.run_event_loop(false)).unwrap();
futures::executor::block_on(receiver).unwrap().unwrap();
}
#[test]
fn dyn_import_err() {
#[derive(Clone, Default)]
struct DynImportErrLoader {
pub count: Arc<AtomicUsize>,
}
impl ModuleLoader for DynImportErrLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
_kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
self.count.fetch_add(1, Ordering::Relaxed);
assert_eq!(specifier, "/foo.js");
assert_eq!(referrer, "file:///dyn_import2.js");
let s = resolve_import(specifier, referrer).unwrap();
Ok(s)
}
fn load(
&self,
_module_specifier: &ModuleSpecifier,
_maybe_referrer: Option<ModuleSpecifier>,
_is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>> {
async { Err(io::Error::from(io::ErrorKind::NotFound).into()) }.boxed()
}
}
let loader = Rc::new(DynImportErrLoader::default());
let count = loader.count.clone();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
// Test an erroneous dynamic import where the specified module isn't found.
run_in_task(move |cx| {
runtime
.execute_script(
"file:///dyn_import2.js",
r#"
(async () => {
await import("/foo.js");
})();
"#,
)
.unwrap();
// We should get an error here.
let result = runtime.poll_event_loop(cx, false);
if let Poll::Ready(Ok(_)) = result {
unreachable!();
}
assert_eq!(count.load(Ordering::Relaxed), 4);
})
}
#[derive(Clone, Default)]
struct DynImportOkLoader {
pub prepare_load_count: Arc<AtomicUsize>,
pub resolve_count: Arc<AtomicUsize>,
pub load_count: Arc<AtomicUsize>,
}
impl ModuleLoader for DynImportOkLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
_kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
let c = self.resolve_count.fetch_add(1, Ordering::Relaxed);
assert!(c < 7);
assert_eq!(specifier, "./b.js");
assert_eq!(referrer, "file:///dyn_import3.js");
let s = resolve_import(specifier, referrer).unwrap();
Ok(s)
}
fn load(
&self,
specifier: &ModuleSpecifier,
_maybe_referrer: Option<ModuleSpecifier>,
_is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>> {
self.load_count.fetch_add(1, Ordering::Relaxed);
let info = ModuleSource {
module_url_specified: specifier.to_string(),
module_url_found: specifier.to_string(),
code: b"export function b() { return 'b' }"
.to_vec()
.into_boxed_slice(),
module_type: ModuleType::JavaScript,
};
async move { Ok(info) }.boxed()
}
fn prepare_load(
&self,
_op_state: Rc<RefCell<OpState>>,
_module_specifier: &ModuleSpecifier,
_maybe_referrer: Option<String>,
_is_dyn_import: bool,
) -> Pin<Box<dyn Future<Output = Result<(), Error>>>> {
self.prepare_load_count.fetch_add(1, Ordering::Relaxed);
async { Ok(()) }.boxed_local()
}
}
#[test]
fn dyn_import_ok() {
let loader = Rc::new(DynImportOkLoader::default());
let prepare_load_count = loader.prepare_load_count.clone();
let resolve_count = loader.resolve_count.clone();
let load_count = loader.load_count.clone();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
run_in_task(move |cx| {
// Dynamically import mod_b
runtime
.execute_script(
"file:///dyn_import3.js",
r#"
(async () => {
let mod = await import("./b.js");
if (mod.b() !== 'b') {
throw Error("bad1");
}
// And again!
mod = await import("./b.js");
if (mod.b() !== 'b') {
throw Error("bad2");
}
})();
"#,
)
.unwrap();
assert!(matches!(
runtime.poll_event_loop(cx, false),
Poll::Ready(Ok(_))
));
assert_eq!(prepare_load_count.load(Ordering::Relaxed), 1);
assert_eq!(resolve_count.load(Ordering::Relaxed), 7);
assert_eq!(load_count.load(Ordering::Relaxed), 1);
assert!(matches!(
runtime.poll_event_loop(cx, false),
Poll::Ready(Ok(_))
));
assert_eq!(resolve_count.load(Ordering::Relaxed), 7);
assert_eq!(load_count.load(Ordering::Relaxed), 1);
})
}
#[test]
fn dyn_import_borrow_mut_error() {
// https://github.com/denoland/deno/issues/6054
let loader = Rc::new(DynImportOkLoader::default());
let prepare_load_count = loader.prepare_load_count.clone();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
run_in_task(move |cx| {
runtime
.execute_script(
"file:///dyn_import3.js",
r#"
(async () => {
let mod = await import("./b.js");
if (mod.b() !== 'b') {
throw Error("bad");
}
})();
"#,
)
.unwrap();
// First poll runs `prepare_load` hook.
let _ = runtime.poll_event_loop(cx, false);
assert_eq!(prepare_load_count.load(Ordering::Relaxed), 1);
// Second poll triggers error
let _ = runtime.poll_event_loop(cx, false);
})
}
// Regression test for https://github.com/denoland/deno/issues/3736.
#[test]
fn dyn_concurrent_circular_import() {
#[derive(Clone, Default)]
struct DynImportCircularLoader {
pub resolve_count: Arc<AtomicUsize>,
pub load_count: Arc<AtomicUsize>,
}
impl ModuleLoader for DynImportCircularLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
_kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
self.resolve_count.fetch_add(1, Ordering::Relaxed);
let s = resolve_import(specifier, referrer).unwrap();
Ok(s)
}
fn load(
&self,
specifier: &ModuleSpecifier,
_maybe_referrer: Option<ModuleSpecifier>,
_is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>> {
self.load_count.fetch_add(1, Ordering::Relaxed);
let filename = PathBuf::from(specifier.to_string())
.file_name()
.unwrap()
.to_string_lossy()
.to_string();
let code = match filename.as_str() {
"a.js" => "import './b.js';",
"b.js" => "import './c.js';\nimport './a.js';",
"c.js" => "import './d.js';",
"d.js" => "// pass",
_ => unreachable!(),
};
let info = ModuleSource {
module_url_specified: specifier.to_string(),
module_url_found: specifier.to_string(),
code: code.as_bytes().to_vec().into_boxed_slice(),
module_type: ModuleType::JavaScript,
};
async move { Ok(info) }.boxed()
}
}
let loader = Rc::new(DynImportCircularLoader::default());
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
runtime
.execute_script(
"file:///entry.js",
"import('./b.js');\nimport('./a.js');",
)
.unwrap();
let result = futures::executor::block_on(runtime.run_event_loop(false));
assert!(result.is_ok());
}
#[test]
fn test_circular_load() {
let loader = MockLoader::new();
let loads = loader.loads.clone();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
let fut = async move {
let spec = resolve_url("file:///circular1.js").unwrap();
let result = runtime.load_main_module(&spec, None).await;
assert!(result.is_ok());
let circular1_id = result.unwrap();
#[allow(clippy::let_underscore_future)]
let _ = runtime.mod_evaluate(circular1_id);
runtime.run_event_loop(false).await.unwrap();
let l = loads.lock();
assert_eq!(
l.to_vec(),
vec![
"file:///circular1.js",
"file:///circular2.js",
"file:///circular3.js"
]
);
let module_map_rc = JsRuntime::module_map(runtime.v8_isolate());
let modules = module_map_rc.borrow();
assert_eq!(
modules
.get_id("file:///circular1.js", AssertedModuleType::JavaScriptOrWasm),
Some(circular1_id)
);
let circular2_id = modules
.get_id("file:///circular2.js", AssertedModuleType::JavaScriptOrWasm)
.unwrap();
assert_eq!(
modules.get_requested_modules(circular1_id),
Some(&vec![ModuleRequest {
specifier: "file:///circular2.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
}])
);
assert_eq!(
modules.get_requested_modules(circular2_id),
Some(&vec![ModuleRequest {
specifier: "file:///circular3.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
}])
);
assert!(modules
.get_id("file:///circular3.js", AssertedModuleType::JavaScriptOrWasm)
.is_some());
let circular3_id = modules
.get_id("file:///circular3.js", AssertedModuleType::JavaScriptOrWasm)
.unwrap();
assert_eq!(
modules.get_requested_modules(circular3_id),
Some(&vec![
ModuleRequest {
specifier: "file:///circular1.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
},
ModuleRequest {
specifier: "file:///circular2.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
}
])
);
}
.boxed_local();
futures::executor::block_on(fut);
}
#[test]
fn test_redirect_load() {
let loader = MockLoader::new();
let loads = loader.loads.clone();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
let fut = async move {
let spec = resolve_url("file:///redirect1.js").unwrap();
let result = runtime.load_main_module(&spec, None).await;
assert!(result.is_ok());
let redirect1_id = result.unwrap();
#[allow(clippy::let_underscore_future)]
let _ = runtime.mod_evaluate(redirect1_id);
runtime.run_event_loop(false).await.unwrap();
let l = loads.lock();
assert_eq!(
l.to_vec(),
vec![
"file:///redirect1.js",
"file:///redirect2.js",
"file:///dir/redirect3.js"
]
);
let module_map_rc = JsRuntime::module_map(runtime.v8_isolate());
let modules = module_map_rc.borrow();
assert_eq!(
modules
.get_id("file:///redirect1.js", AssertedModuleType::JavaScriptOrWasm),
Some(redirect1_id)
);
let redirect2_id = modules
.get_id(
"file:///dir/redirect2.js",
AssertedModuleType::JavaScriptOrWasm,
)
.unwrap();
assert!(modules.is_alias(
"file:///redirect2.js",
AssertedModuleType::JavaScriptOrWasm
));
assert!(!modules.is_alias(
"file:///dir/redirect2.js",
AssertedModuleType::JavaScriptOrWasm
));
assert_eq!(
modules
.get_id("file:///redirect2.js", AssertedModuleType::JavaScriptOrWasm),
Some(redirect2_id)
);
let redirect3_id = modules
.get_id("file:///redirect3.js", AssertedModuleType::JavaScriptOrWasm)
.unwrap();
assert!(modules.is_alias(
"file:///dir/redirect3.js",
AssertedModuleType::JavaScriptOrWasm
));
assert!(!modules.is_alias(
"file:///redirect3.js",
AssertedModuleType::JavaScriptOrWasm
));
assert_eq!(
modules.get_id(
"file:///dir/redirect3.js",
AssertedModuleType::JavaScriptOrWasm
),
Some(redirect3_id)
);
}
.boxed_local();
futures::executor::block_on(fut);
}
#[test]
fn slow_never_ready_modules() {
let loader = MockLoader::new();
let loads = loader.loads.clone();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
run_in_task(move |cx| {
let spec = resolve_url("file:///main.js").unwrap();
let mut recursive_load =
runtime.load_main_module(&spec, None).boxed_local();
let result = recursive_load.poll_unpin(cx);
assert!(result.is_pending());
// TODO(ry) Arguably the first time we poll only the following modules
// should be loaded:
// "file:///main.js",
// "file:///never_ready.js",
// "file:///slow.js"
// But due to current task notification in DelayedSourceCodeFuture they
// all get loaded in a single poll. Also see the comment above
// run_in_task.
for _ in 0..10 {
let result = recursive_load.poll_unpin(cx);
assert!(result.is_pending());
let l = loads.lock();
assert_eq!(
l.to_vec(),
vec![
"file:///main.js",
"file:///never_ready.js",
"file:///slow.js",
"file:///a.js",
"file:///b.js",
"file:///c.js",
"file:///d.js"
]
);
}
})
}
#[test]
fn loader_disappears_after_error() {
let loader = MockLoader::new();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
run_in_task(move |cx| {
let spec = resolve_url("file:///bad_import.js").unwrap();
let mut load_fut = runtime.load_main_module(&spec, None).boxed_local();
let result = load_fut.poll_unpin(cx);
if let Poll::Ready(Err(err)) = result {
assert_eq!(
err.downcast_ref::<MockError>().unwrap(),
&MockError::ResolveErr
);
} else {
unreachable!();
}
})
}
#[test]
fn recursive_load_main_with_code() {
const MAIN_WITH_CODE_SRC: &str = r#"
import { b } from "/b.js";
import { c } from "/c.js";
if (b() != 'b') throw Error();
if (c() != 'c') throw Error();
if (!import.meta.main) throw Error();
if (import.meta.url != 'file:///main_with_code.js') throw Error();
"#;
let loader = MockLoader::new();
let loads = loader.loads.clone();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
// In default resolution code should be empty.
// Instead we explicitly pass in our own code.
// The behavior should be very similar to /a.js.
let spec = resolve_url("file:///main_with_code.js").unwrap();
let main_id_fut = runtime
.load_main_module(&spec, Some(MAIN_WITH_CODE_SRC.to_owned()))
.boxed_local();
let main_id = futures::executor::block_on(main_id_fut).unwrap();
#[allow(clippy::let_underscore_future)]
let _ = runtime.mod_evaluate(main_id);
futures::executor::block_on(runtime.run_event_loop(false)).unwrap();
let l = loads.lock();
assert_eq!(
l.to_vec(),
vec!["file:///b.js", "file:///c.js", "file:///d.js"]
);
let module_map_rc = JsRuntime::module_map(runtime.v8_isolate());
let modules = module_map_rc.borrow();
assert_eq!(
modules.get_id(
"file:///main_with_code.js",
AssertedModuleType::JavaScriptOrWasm
),
Some(main_id)
);
let b_id = modules
.get_id("file:///b.js", AssertedModuleType::JavaScriptOrWasm)
.unwrap();
let c_id = modules
.get_id("file:///c.js", AssertedModuleType::JavaScriptOrWasm)
.unwrap();
let d_id = modules
.get_id("file:///d.js", AssertedModuleType::JavaScriptOrWasm)
.unwrap();
assert_eq!(
modules.get_requested_modules(main_id),
Some(&vec![
ModuleRequest {
specifier: "file:///b.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
},
ModuleRequest {
specifier: "file:///c.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
}
])
);
assert_eq!(
modules.get_requested_modules(b_id),
Some(&vec![ModuleRequest {
specifier: "file:///c.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
}])
);
assert_eq!(
modules.get_requested_modules(c_id),
Some(&vec![ModuleRequest {
specifier: "file:///d.js".to_string(),
asserted_module_type: AssertedModuleType::JavaScriptOrWasm,
}])
);
assert_eq!(modules.get_requested_modules(d_id), Some(&vec![]));
}
#[test]
fn main_and_side_module() {
struct ModsLoader {}
let main_specifier = resolve_url("file:///main_module.js").unwrap();
let side_specifier = resolve_url("file:///side_module.js").unwrap();
impl ModuleLoader for ModsLoader {
fn resolve(
&self,
specifier: &str,
referrer: &str,
_kind: ResolutionKind,
) -> Result<ModuleSpecifier, Error> {
let s = resolve_import(specifier, referrer).unwrap();
Ok(s)
}
fn load(
&self,
module_specifier: &ModuleSpecifier,
_maybe_referrer: Option<ModuleSpecifier>,
_is_dyn_import: bool,
) -> Pin<Box<ModuleSourceFuture>> {
let module_source = match module_specifier.as_str() {
"file:///main_module.js" => Ok(ModuleSource {
module_url_specified: "file:///main_module.js".to_string(),
module_url_found: "file:///main_module.js".to_string(),
code: b"if (!import.meta.main) throw Error();"
.to_vec()
.into_boxed_slice(),
module_type: ModuleType::JavaScript,
}),
"file:///side_module.js" => Ok(ModuleSource {
module_url_specified: "file:///side_module.js".to_string(),
module_url_found: "file:///side_module.js".to_string(),
code: b"if (import.meta.main) throw Error();"
.to_vec()
.into_boxed_slice(),
module_type: ModuleType::JavaScript,
}),
_ => unreachable!(),
};
async move { module_source }.boxed()
}
}
let loader = Rc::new(ModsLoader {});
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
..Default::default()
});
let main_id_fut = runtime
.load_main_module(&main_specifier, None)
.boxed_local();
let main_id = futures::executor::block_on(main_id_fut).unwrap();
#[allow(clippy::let_underscore_future)]
let _ = runtime.mod_evaluate(main_id);
futures::executor::block_on(runtime.run_event_loop(false)).unwrap();
// Try to add another main module - it should error.
let side_id_fut = runtime
.load_main_module(&side_specifier, None)
.boxed_local();
futures::executor::block_on(side_id_fut).unwrap_err();
// And now try to load it as a side module
let side_id_fut = runtime
.load_side_module(&side_specifier, None)
.boxed_local();
let side_id = futures::executor::block_on(side_id_fut).unwrap();
#[allow(clippy::let_underscore_future)]
let _ = runtime.mod_evaluate(side_id);
futures::executor::block_on(runtime.run_event_loop(false)).unwrap();
}
#[test]
fn dynamic_imports_snapshot() {
//TODO: Once the issue with the ModuleNamespaceEntryGetter is fixed, we can maintain a reference to the module
// and use it when loading the snapshot
let snapshot = {
const MAIN_WITH_CODE_SRC: &str = r#"
await import("./b.js");
"#;
let loader = MockLoader::new();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
will_snapshot: true,
..Default::default()
});
// In default resolution code should be empty.
// Instead we explicitly pass in our own code.
// The behavior should be very similar to /a.js.
let spec = resolve_url("file:///main_with_code.js").unwrap();
let main_id_fut = runtime
.load_main_module(&spec, Some(MAIN_WITH_CODE_SRC.to_owned()))
.boxed_local();
let main_id = futures::executor::block_on(main_id_fut).unwrap();
#[allow(clippy::let_underscore_future)]
let _ = runtime.mod_evaluate(main_id);
futures::executor::block_on(runtime.run_event_loop(false)).unwrap();
runtime.snapshot()
};
let snapshot = Snapshot::JustCreated(snapshot);
let mut runtime2 = JsRuntime::new(RuntimeOptions {
startup_snapshot: Some(snapshot),
..Default::default()
});
//Evaluate the snapshot with an empty function
runtime2.execute_script("check.js", "true").unwrap();
}
#[test]
fn import_meta_snapshot() {
let snapshot = {
const MAIN_WITH_CODE_SRC: &str = r#"
if (import.meta.url != 'file:///main_with_code.js') throw Error();
globalThis.meta = import.meta;
globalThis.url = import.meta.url;
"#;
let loader = MockLoader::new();
let mut runtime = JsRuntime::new(RuntimeOptions {
module_loader: Some(loader),
will_snapshot: true,
..Default::default()
});
// In default resolution code should be empty.
// Instead we explicitly pass in our own code.
// The behavior should be very similar to /a.js.
let spec = resolve_url("file:///main_with_code.js").unwrap();
let main_id_fut = runtime
.load_main_module(&spec, Some(MAIN_WITH_CODE_SRC.to_owned()))
.boxed_local();
let main_id = futures::executor::block_on(main_id_fut).unwrap();
#[allow(clippy::let_underscore_future)]
let _ = runtime.mod_evaluate(main_id);
futures::executor::block_on(runtime.run_event_loop(false)).unwrap();
runtime.snapshot()
};
let snapshot = Snapshot::JustCreated(snapshot);
let mut runtime2 = JsRuntime::new(RuntimeOptions {
startup_snapshot: Some(snapshot),
..Default::default()
});
runtime2
.execute_script(
"check.js",
"if (globalThis.url !== 'file:///main_with_code.js') throw Error('x')",
)
.unwrap();
}
#[test]
fn ext_module_loader() {
let loader = ExtModuleLoader::default();
assert!(loader
.resolve("ext:foo", "ext:bar", ResolutionKind::Import)
.is_ok());
assert_eq!(
loader
.resolve("ext:foo", "file://bar", ResolutionKind::Import)
.err()
.map(|e| e.to_string()),
Some("Cannot load extension module from external code".to_string())
);
assert_eq!(
loader
.resolve("file://foo", "file://bar", ResolutionKind::Import)
.err()
.map(|e| e.to_string()),
Some(
"Module loading is not supported; attempted to resolve: \"file://foo\" from \"file://bar\""
.to_string()
)
);
assert_eq!(
loader
.resolve("file://foo", "ext:bar", ResolutionKind::Import)
.err()
.map(|e| e.to_string()),
Some(
"Module loading is not supported; attempted to resolve: \"file://foo\" from \"ext:bar\""
.to_string()
)
);
assert_eq!(
resolve_helper(
true,
Rc::new(loader),
"ext:core.js",
"file://bar",
ResolutionKind::Import,
)
.err()
.map(|e| e.to_string()),
Some("Cannot load extension module from external code".to_string())
);
}
}