// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license. use crate::args::TsConfig; use crate::args::TypeCheckMode; use crate::cache::FastInsecureHasher; use crate::cache::ModuleInfoCache; use crate::node; use crate::npm::CliNpmResolver; use crate::resolver::CjsTracker; use crate::util::checksum; use crate::util::path::mapped_specifier_for_tsc; use crate::worker::create_isolate_create_params; use deno_ast::MediaType; use deno_core::anyhow::anyhow; use deno_core::anyhow::Context; use deno_core::ascii_str; use deno_core::error::AnyError; use deno_core::located_script_name; use deno_core::op2; use deno_core::resolve_url_or_path; use deno_core::serde::Deserialize; use deno_core::serde::Deserializer; use deno_core::serde::Serialize; use deno_core::serde::Serializer; use deno_core::serde_json::json; use deno_core::serde_v8; use deno_core::url::Url; use deno_core::JsRuntime; use deno_core::ModuleSpecifier; use deno_core::OpState; use deno_core::RuntimeOptions; use deno_graph::GraphKind; use deno_graph::Module; use deno_graph::ModuleGraph; use deno_graph::ResolutionResolved; use deno_resolver::npm::ResolvePkgFolderFromDenoReqError; use deno_runtime::deno_fs; use deno_runtime::deno_node::NodeResolver; use deno_semver::npm::NpmPackageReqReference; use node_resolver::errors::NodeJsErrorCode; use node_resolver::errors::NodeJsErrorCoded; use node_resolver::errors::PackageSubpathResolveError; use node_resolver::NodeModuleKind; use node_resolver::NodeResolutionMode; use once_cell::sync::Lazy; use std::borrow::Cow; use std::collections::HashMap; use std::fmt; use std::path::Path; use std::path::PathBuf; use std::sync::Arc; use thiserror::Error; mod diagnostics; pub use self::diagnostics::Diagnostic; pub use self::diagnostics::DiagnosticCategory; pub use self::diagnostics::Diagnostics; pub use self::diagnostics::Position; pub static COMPILER_SNAPSHOT: Lazy> = Lazy::new( #[cold] #[inline(never)] || { static COMPRESSED_COMPILER_SNAPSHOT: &[u8] = include_bytes!(concat!(env!("OUT_DIR"), "/COMPILER_SNAPSHOT.bin")); // NOTE(bartlomieju): Compressing the TSC snapshot in debug build took // ~45s on M1 MacBook Pro; without compression it took ~1s. // Thus we're not using compressed snapshot, trading off // a lot of build time for some startup time in debug build. #[cfg(debug_assertions)] return COMPRESSED_COMPILER_SNAPSHOT.to_vec().into_boxed_slice(); #[cfg(not(debug_assertions))] zstd::bulk::decompress( &COMPRESSED_COMPILER_SNAPSHOT[4..], u32::from_le_bytes(COMPRESSED_COMPILER_SNAPSHOT[0..4].try_into().unwrap()) as usize, ) .unwrap() .into_boxed_slice() }, ); pub fn get_types_declaration_file_text() -> String { let mut assets = get_asset_texts_from_new_runtime() .unwrap() .into_iter() .map(|a| (a.specifier, a.text)) .collect::>(); let lib_names = vec![ "deno.ns", "deno.console", "deno.url", "deno.web", "deno.fetch", "deno.webgpu", "deno.websocket", "deno.webstorage", "deno.canvas", "deno.crypto", "deno.broadcast_channel", "deno.net", "deno.shared_globals", "deno.cache", "deno.window", "deno.unstable", ]; lib_names .into_iter() .map(|name| { let asset_url = format!("asset:///lib.{name}.d.ts"); assets.remove(&asset_url).unwrap() }) .collect::>() .join("\n") } fn get_asset_texts_from_new_runtime() -> Result, AnyError> { deno_core::extension!( deno_cli_tsc, ops = [ op_create_hash, op_emit, op_is_node_file, op_load, op_resolve, op_respond, ] ); // the assets are stored within the typescript isolate, so take them out of there let mut runtime = JsRuntime::new(RuntimeOptions { startup_snapshot: Some(compiler_snapshot()), extensions: vec![deno_cli_tsc::init_ops()], ..Default::default() }); let global = runtime .execute_script("get_assets.js", ascii_str!("globalThis.getAssets()"))?; let scope = &mut runtime.handle_scope(); let local = deno_core::v8::Local::new(scope, global); Ok(serde_v8::from_v8::>(scope, local)?) } pub fn compiler_snapshot() -> &'static [u8] { &COMPILER_SNAPSHOT } macro_rules! inc { ($e:expr) => { include_str!(concat!("./dts/", $e)) }; } /// Contains static assets that are not preloaded in the compiler snapshot. /// /// We lazily load these because putting them in the compiler snapshot will /// increase memory usage when not used (last time checked by about 0.5MB). pub static LAZILY_LOADED_STATIC_ASSETS: Lazy< HashMap<&'static str, &'static str>, > = Lazy::new(|| { ([ ( "lib.dom.asynciterable.d.ts", inc!("lib.dom.asynciterable.d.ts"), ), ("lib.dom.d.ts", inc!("lib.dom.d.ts")), ("lib.dom.extras.d.ts", inc!("lib.dom.extras.d.ts")), ("lib.dom.iterable.d.ts", inc!("lib.dom.iterable.d.ts")), ("lib.es6.d.ts", inc!("lib.es6.d.ts")), ("lib.es2016.full.d.ts", inc!("lib.es2016.full.d.ts")), ("lib.es2017.full.d.ts", inc!("lib.es2017.full.d.ts")), ("lib.es2018.full.d.ts", inc!("lib.es2018.full.d.ts")), ("lib.es2019.full.d.ts", inc!("lib.es2019.full.d.ts")), ("lib.es2020.full.d.ts", inc!("lib.es2020.full.d.ts")), ("lib.es2021.full.d.ts", inc!("lib.es2021.full.d.ts")), ("lib.es2022.full.d.ts", inc!("lib.es2022.full.d.ts")), ("lib.esnext.full.d.ts", inc!("lib.esnext.full.d.ts")), ("lib.scripthost.d.ts", inc!("lib.scripthost.d.ts")), ("lib.webworker.d.ts", inc!("lib.webworker.d.ts")), ( "lib.webworker.importscripts.d.ts", inc!("lib.webworker.importscripts.d.ts"), ), ( "lib.webworker.iterable.d.ts", inc!("lib.webworker.iterable.d.ts"), ), ( // Special file that can be used to inject the @types/node package. // This is used for `node:` specifiers. "node_types.d.ts", "/// \n", ), ]) .iter() .cloned() .collect() }); /// A structure representing stats from a type check operation for a graph. #[derive(Clone, Debug, Default, Eq, PartialEq)] pub struct Stats(pub Vec<(String, u32)>); impl<'de> Deserialize<'de> for Stats { fn deserialize(deserializer: D) -> Result where D: Deserializer<'de>, { let items: Vec<(String, u32)> = Deserialize::deserialize(deserializer)?; Ok(Stats(items)) } } impl Serialize for Stats { fn serialize(&self, serializer: S) -> Result where S: Serializer, { Serialize::serialize(&self.0, serializer) } } impl fmt::Display for Stats { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { writeln!(f, "Compilation statistics:")?; for (key, value) in self.0.clone() { writeln!(f, " {key}: {value}")?; } Ok(()) } } #[derive(Debug, Deserialize)] #[serde(rename_all = "camelCase")] pub struct AssetText { pub specifier: String, pub text: String, } /// Retrieve a static asset that are included in the binary. fn get_lazily_loaded_asset(asset: &str) -> Option<&'static str> { LAZILY_LOADED_STATIC_ASSETS.get(asset).map(|s| s.to_owned()) } fn get_maybe_hash( maybe_source: Option<&str>, hash_data: u64, ) -> Option { maybe_source.map(|source| get_hash(source, hash_data)) } fn get_hash(source: &str, hash_data: u64) -> String { FastInsecureHasher::new_without_deno_version() .write_str(source) .write_u64(hash_data) .finish() .to_string() } /// Hash the URL so it can be sent to `tsc` in a supportable way fn hash_url(specifier: &ModuleSpecifier, media_type: MediaType) -> String { let hash = checksum::gen(&[specifier.path().as_bytes()]); format!( "{}:///{}{}", specifier.scheme(), hash, media_type.as_ts_extension() ) } /// If the provided URLs derivable tsc media type doesn't match the media type, /// we will add an extension to the output. This is to avoid issues with /// specifiers that don't have extensions, that tsc refuses to emit because they /// think a `.js` version exists, when it doesn't. fn maybe_remap_specifier( specifier: &ModuleSpecifier, media_type: MediaType, ) -> Option { let path = if specifier.scheme() == "file" { if let Ok(path) = specifier.to_file_path() { path } else { PathBuf::from(specifier.path()) } } else { PathBuf::from(specifier.path()) }; if path.extension().is_none() { Some(format!("{}{}", specifier, media_type.as_ts_extension())) } else { None } } #[derive(Debug, Clone, Default, Eq, PartialEq)] pub struct EmittedFile { pub data: String, pub maybe_specifiers: Option>, pub media_type: MediaType, } pub fn into_specifier_and_media_type( specifier: Option, ) -> (ModuleSpecifier, MediaType) { match specifier { Some(specifier) => { let media_type = MediaType::from_specifier(&specifier); (specifier, media_type) } None => ( Url::parse("internal:///missing_dependency.d.ts").unwrap(), MediaType::Dts, ), } } #[derive(Debug)] pub struct TypeCheckingCjsTracker { cjs_tracker: Arc, module_info_cache: Arc, } impl TypeCheckingCjsTracker { pub fn new( cjs_tracker: Arc, module_info_cache: Arc, ) -> Self { Self { cjs_tracker, module_info_cache, } } pub fn is_cjs( &self, specifier: &ModuleSpecifier, media_type: MediaType, code: &Arc, ) -> bool { let maybe_is_script = self .module_info_cache .as_module_analyzer() .analyze_sync(specifier, media_type, code) .ok() .map(|info| info.is_script); maybe_is_script .and_then(|is_script| { self .cjs_tracker .is_cjs_with_known_is_script(specifier, media_type, is_script) .ok() }) .unwrap_or_else(|| { self .cjs_tracker .is_maybe_cjs(specifier, media_type) .unwrap_or(false) }) } pub fn is_cjs_with_known_is_script( &self, specifier: &ModuleSpecifier, media_type: MediaType, is_script: bool, ) -> Result { self .cjs_tracker .is_cjs_with_known_is_script(specifier, media_type, is_script) } } #[derive(Debug)] pub struct RequestNpmState { pub cjs_tracker: Arc, pub node_resolver: Arc, pub npm_resolver: Arc, } /// A structure representing a request to be sent to the tsc runtime. #[derive(Debug)] pub struct Request { /// The TypeScript compiler options which will be serialized and sent to /// tsc. pub config: TsConfig, /// Indicates to the tsc runtime if debug logging should occur. pub debug: bool, pub graph: Arc, pub hash_data: u64, pub maybe_npm: Option, pub maybe_tsbuildinfo: Option, /// A vector of strings that represent the root/entry point modules for the /// program. pub root_names: Vec<(ModuleSpecifier, MediaType)>, pub check_mode: TypeCheckMode, } #[derive(Debug, Clone, Eq, PartialEq)] pub struct Response { /// Any diagnostics that have been returned from the checker. pub diagnostics: Diagnostics, /// If there was any build info associated with the exec request. pub maybe_tsbuildinfo: Option, /// Statistics from the check. pub stats: Stats, } // TODO(bartlomieju): we have similar struct in `tsc.rs` - maybe at least change // the name of the struct to avoid confusion? #[derive(Debug)] struct State { hash_data: u64, graph: Arc, maybe_tsbuildinfo: Option, maybe_response: Option, maybe_npm: Option, remapped_specifiers: HashMap, root_map: HashMap, current_dir: PathBuf, } impl Default for State { fn default() -> Self { Self { hash_data: Default::default(), graph: Arc::new(ModuleGraph::new(GraphKind::All)), maybe_tsbuildinfo: Default::default(), maybe_response: Default::default(), maybe_npm: Default::default(), remapped_specifiers: Default::default(), root_map: Default::default(), current_dir: Default::default(), } } } impl State { pub fn new( graph: Arc, hash_data: u64, maybe_npm: Option, maybe_tsbuildinfo: Option, root_map: HashMap, remapped_specifiers: HashMap, current_dir: PathBuf, ) -> Self { State { hash_data, graph, maybe_npm, maybe_tsbuildinfo, maybe_response: None, remapped_specifiers, root_map, current_dir, } } } fn normalize_specifier( specifier: &str, current_dir: &Path, ) -> Result { resolve_url_or_path(specifier, current_dir).map_err(|err| err.into()) } #[op2] #[string] fn op_create_hash(s: &mut OpState, #[string] text: &str) -> String { op_create_hash_inner(s, text) } #[inline] fn op_create_hash_inner(s: &mut OpState, text: &str) -> String { let state = s.borrow_mut::(); get_hash(text, state.hash_data) } #[derive(Debug, Deserialize)] #[serde(rename_all = "camelCase")] struct EmitArgs { /// The text data/contents of the file. data: String, /// The _internal_ filename for the file. This will be used to determine how /// the file is cached and stored. file_name: String, } #[op2(fast)] fn op_emit( state: &mut OpState, #[string] data: String, #[string] file_name: String, ) -> bool { op_emit_inner(state, EmitArgs { data, file_name }) } #[inline] fn op_emit_inner(state: &mut OpState, args: EmitArgs) -> bool { let state = state.borrow_mut::(); match args.file_name.as_ref() { "internal:///.tsbuildinfo" => state.maybe_tsbuildinfo = Some(args.data), _ => { if cfg!(debug_assertions) { panic!("Unhandled emit write: {}", args.file_name); } } } true } pub fn as_ts_script_kind(media_type: MediaType) -> i32 { match media_type { MediaType::JavaScript => 1, MediaType::Jsx => 2, MediaType::Mjs => 1, MediaType::Cjs => 1, MediaType::TypeScript => 3, MediaType::Mts => 3, MediaType::Cts => 3, MediaType::Dts => 3, MediaType::Dmts => 3, MediaType::Dcts => 3, MediaType::Tsx => 4, MediaType::Json => 6, MediaType::SourceMap | MediaType::Css | MediaType::Wasm | MediaType::Unknown => 0, } } pub const MISSING_DEPENDENCY_SPECIFIER: &str = "internal:///missing_dependency.d.ts"; #[derive(Debug, Serialize)] #[serde(rename_all = "camelCase")] struct LoadResponse { data: String, version: Option, script_kind: i32, is_cjs: bool, } #[op2] #[serde] fn op_load( state: &mut OpState, #[string] load_specifier: &str, ) -> Result, AnyError> { op_load_inner(state, load_specifier) } fn op_load_inner( state: &mut OpState, load_specifier: &str, ) -> Result, AnyError> { fn load_from_node_modules( specifier: &ModuleSpecifier, npm_state: Option<&RequestNpmState>, media_type: &mut MediaType, is_cjs: &mut bool, ) -> Result { *media_type = MediaType::from_specifier(specifier); let file_path = specifier.to_file_path().unwrap(); let code = std::fs::read_to_string(&file_path) .with_context(|| format!("Unable to load {}", file_path.display()))?; let code: Arc = code.into(); *is_cjs = npm_state .map(|npm_state| { npm_state.cjs_tracker.is_cjs(specifier, *media_type, &code) }) .unwrap_or(false); // todo(dsherret): how to avoid cloning here? Ok(code.to_string()) } let state = state.borrow_mut::(); let specifier = normalize_specifier(load_specifier, &state.current_dir) .context("Error converting a string module specifier for \"op_load\".")?; let mut hash: Option = None; let mut media_type = MediaType::Unknown; let graph = &state.graph; let mut is_cjs = false; let data = if load_specifier == "internal:///.tsbuildinfo" { state.maybe_tsbuildinfo.as_deref().map(Cow::Borrowed) // in certain situations we return a "blank" module to tsc and we need to // handle the request for that module here. } else if load_specifier == MISSING_DEPENDENCY_SPECIFIER { None } else if let Some(name) = load_specifier.strip_prefix("asset:///") { let maybe_source = get_lazily_loaded_asset(name); hash = get_maybe_hash(maybe_source, state.hash_data); media_type = MediaType::from_str(load_specifier); maybe_source.map(Cow::Borrowed) } else { let specifier = if let Some(remapped_specifier) = state.remapped_specifiers.get(load_specifier) { remapped_specifier } else if let Some(remapped_specifier) = state.root_map.get(load_specifier) { remapped_specifier } else { &specifier }; let maybe_module = match graph.try_get(specifier) { Ok(maybe_module) => maybe_module, Err(err) => match err { deno_graph::ModuleError::UnsupportedMediaType(_, media_type, _) => { return Ok(Some(LoadResponse { data: "".to_string(), version: Some("1".to_string()), script_kind: as_ts_script_kind(*media_type), is_cjs: false, })) } _ => None, }, }; let maybe_source = if let Some(module) = maybe_module { match module { Module::Js(module) => { media_type = module.media_type; if let Some(npm_state) = &state.maybe_npm { is_cjs = npm_state.cjs_tracker.is_cjs_with_known_is_script( specifier, module.media_type, module.is_script, )?; } let source = module .fast_check_module() .map(|m| &*m.source) .unwrap_or(&*module.source); Some(Cow::Borrowed(source)) } Module::Json(module) => { media_type = MediaType::Json; Some(Cow::Borrowed(&*module.source)) } Module::Npm(_) | Module::Node(_) => None, Module::External(module) => { // means it's Deno code importing an npm module let specifier = node::resolve_specifier_into_node_modules( &module.specifier, &deno_fs::RealFs, ); Some(Cow::Owned(load_from_node_modules( &specifier, state.maybe_npm.as_ref(), &mut media_type, &mut is_cjs, )?)) } } } else if let Some(npm) = state .maybe_npm .as_ref() .filter(|npm| npm.node_resolver.in_npm_package(specifier)) { Some(Cow::Owned(load_from_node_modules( specifier, Some(npm), &mut media_type, &mut is_cjs, )?)) } else { None }; hash = get_maybe_hash(maybe_source.as_deref(), state.hash_data); maybe_source }; let Some(data) = data else { return Ok(None); }; Ok(Some(LoadResponse { data: data.into_owned(), version: hash, script_kind: as_ts_script_kind(media_type), is_cjs, })) } #[derive(Debug, Deserialize, Serialize)] #[serde(rename_all = "camelCase")] pub struct ResolveArgs { /// The base specifier that the supplied specifier strings should be resolved /// relative to. pub base: String, /// If the base is cjs. pub is_base_cjs: bool, /// A list of specifiers that should be resolved. pub specifiers: Vec, } #[op2] #[serde] fn op_resolve( state: &mut OpState, #[string] base: String, is_base_cjs: bool, #[serde] specifiers: Vec, ) -> Result, AnyError> { op_resolve_inner( state, ResolveArgs { base, is_base_cjs, specifiers, }, ) } #[inline] fn op_resolve_inner( state: &mut OpState, args: ResolveArgs, ) -> Result, AnyError> { let state = state.borrow_mut::(); let mut resolved: Vec<(String, &'static str)> = Vec::with_capacity(args.specifiers.len()); let referrer_kind = if args.is_base_cjs { NodeModuleKind::Cjs } else { NodeModuleKind::Esm }; let referrer = if let Some(remapped_specifier) = state.remapped_specifiers.get(&args.base) { remapped_specifier.clone() } else if let Some(remapped_base) = state.root_map.get(&args.base) { remapped_base.clone() } else { normalize_specifier(&args.base, &state.current_dir).context( "Error converting a string module specifier for \"op_resolve\".", )? }; let referrer_module = state.graph.get(&referrer); for specifier in args.specifiers { if specifier.starts_with("node:") { resolved.push(( MISSING_DEPENDENCY_SPECIFIER.to_string(), MediaType::Dts.as_ts_extension(), )); continue; } if specifier.starts_with("asset:///") { let ext = MediaType::from_str(&specifier).as_ts_extension(); resolved.push((specifier, ext)); continue; } let resolved_dep = referrer_module .and_then(|m| m.js()) .and_then(|m| m.dependencies_prefer_fast_check().get(&specifier)) .and_then(|d| d.maybe_type.ok().or_else(|| d.maybe_code.ok())); let maybe_result = match resolved_dep { Some(ResolutionResolved { specifier, .. }) => { resolve_graph_specifier_types( specifier, &referrer, referrer_kind, state, )? } _ => { match resolve_non_graph_specifier_types( &specifier, &referrer, referrer_kind, state, ) { Ok(maybe_result) => maybe_result, Err( err @ ResolveNonGraphSpecifierTypesError::ResolvePkgFolderFromDenoReq( ResolvePkgFolderFromDenoReqError::Managed(_), ), ) => { // it's most likely requesting the jsxImportSource, which isn't loaded // into the graph when not using jsx, so just ignore this error if specifier.ends_with("/jsx-runtime") { None } else { return Err(err.into()); } } Err(err) => return Err(err.into()), } } }; let result = match maybe_result { Some((specifier, media_type)) => { let specifier_str = match specifier.scheme() { "data" | "blob" => { let specifier_str = hash_url(&specifier, media_type); state .remapped_specifiers .insert(specifier_str.clone(), specifier); specifier_str } _ => { if let Some(specifier_str) = maybe_remap_specifier(&specifier, media_type) { state .remapped_specifiers .insert(specifier_str.clone(), specifier); specifier_str } else { specifier.to_string() } } }; ( specifier_str, match media_type { MediaType::Css => ".js", // surface these as .js for typescript media_type => media_type.as_ts_extension(), }, ) } None => ( MISSING_DEPENDENCY_SPECIFIER.to_string(), MediaType::Dts.as_ts_extension(), ), }; log::debug!("Resolved {} to {:?}", specifier, result); resolved.push(result); } Ok(resolved) } fn resolve_graph_specifier_types( specifier: &ModuleSpecifier, referrer: &ModuleSpecifier, referrer_kind: NodeModuleKind, state: &State, ) -> Result, AnyError> { let graph = &state.graph; let maybe_module = match graph.try_get(specifier) { Ok(Some(module)) => Some(module), Ok(None) => None, Err(err) => match err { deno_graph::ModuleError::UnsupportedMediaType( specifier, media_type, _, ) => { return Ok(Some((specifier.clone(), *media_type))); } _ => None, }, }; // follow the types reference directive, which may be pointing at an npm package let maybe_module = match maybe_module { Some(Module::Js(module)) => { let maybe_types_dep = module .maybe_types_dependency .as_ref() .map(|d| &d.dependency); match maybe_types_dep.and_then(|d| d.maybe_specifier()) { Some(specifier) => graph.get(specifier), _ => maybe_module, } } maybe_module => maybe_module, }; // now get the types from the resolved module match maybe_module { Some(Module::Js(module)) => { Ok(Some((module.specifier.clone(), module.media_type))) } Some(Module::Json(module)) => { Ok(Some((module.specifier.clone(), module.media_type))) } Some(Module::Npm(module)) => { if let Some(npm) = &state.maybe_npm.as_ref() { let package_folder = npm .npm_resolver .as_managed() .unwrap() // should never be byonm because it won't create Module::Npm .resolve_pkg_folder_from_deno_module(module.nv_reference.nv())?; let res_result = npm.node_resolver.resolve_package_subpath_from_deno_module( &package_folder, module.nv_reference.sub_path(), Some(referrer), referrer_kind, NodeResolutionMode::Types, ); let maybe_url = match res_result { Ok(url) => Some(url), Err(err) => match err.code() { NodeJsErrorCode::ERR_TYPES_NOT_FOUND | NodeJsErrorCode::ERR_MODULE_NOT_FOUND => None, _ => return Err(err.into()), }, }; Ok(Some(into_specifier_and_media_type(maybe_url))) } else { Ok(None) } } Some(Module::External(module)) => { // we currently only use "External" for when the module is in an npm package Ok(state.maybe_npm.as_ref().map(|_| { let specifier = node::resolve_specifier_into_node_modules( &module.specifier, &deno_fs::RealFs, ); into_specifier_and_media_type(Some(specifier)) })) } Some(Module::Node(_)) | None => Ok(None), } } #[derive(Debug, Error)] enum ResolveNonGraphSpecifierTypesError { #[error(transparent)] ResolvePkgFolderFromDenoReq(#[from] ResolvePkgFolderFromDenoReqError), #[error(transparent)] PackageSubpathResolve(#[from] PackageSubpathResolveError), } fn resolve_non_graph_specifier_types( raw_specifier: &str, referrer: &ModuleSpecifier, referrer_kind: NodeModuleKind, state: &State, ) -> Result< Option<(ModuleSpecifier, MediaType)>, ResolveNonGraphSpecifierTypesError, > { let npm = match state.maybe_npm.as_ref() { Some(npm) => npm, None => return Ok(None), // we only support non-graph types for npm packages }; let node_resolver = &npm.node_resolver; if node_resolver.in_npm_package(referrer) { // we're in an npm package, so use node resolution Ok(Some(into_specifier_and_media_type( node_resolver .resolve( raw_specifier, referrer, referrer_kind, NodeResolutionMode::Types, ) .ok() .map(|res| res.into_url()), ))) } else if let Ok(npm_req_ref) = NpmPackageReqReference::from_str(raw_specifier) { debug_assert_eq!(referrer_kind, NodeModuleKind::Esm); // todo(dsherret): add support for injecting this in the graph so // we don't need this special code here. // This could occur when resolving npm:@types/node when it is // injected and not part of the graph let package_folder = npm .npm_resolver .resolve_pkg_folder_from_deno_module_req(npm_req_ref.req(), referrer)?; let res_result = node_resolver.resolve_package_subpath_from_deno_module( &package_folder, npm_req_ref.sub_path(), Some(referrer), referrer_kind, NodeResolutionMode::Types, ); let maybe_url = match res_result { Ok(url) => Some(url), Err(err) => match err.code() { NodeJsErrorCode::ERR_TYPES_NOT_FOUND | NodeJsErrorCode::ERR_MODULE_NOT_FOUND => None, _ => return Err(err.into()), }, }; Ok(Some(into_specifier_and_media_type(maybe_url))) } else { Ok(None) } } #[op2(fast)] fn op_is_node_file(state: &mut OpState, #[string] path: &str) -> bool { let state = state.borrow::(); ModuleSpecifier::parse(path) .ok() .and_then(|specifier| { state .maybe_npm .as_ref() .map(|n| n.node_resolver.in_npm_package(&specifier)) }) .unwrap_or(false) } #[derive(Debug, Deserialize, Eq, PartialEq)] struct RespondArgs { pub diagnostics: Diagnostics, pub stats: Stats, } // TODO(bartlomieju): this mechanism is questionable. // Can't we use something more efficient here? #[op2] fn op_respond(state: &mut OpState, #[serde] args: RespondArgs) { op_respond_inner(state, args) } #[inline] fn op_respond_inner(state: &mut OpState, args: RespondArgs) { let state = state.borrow_mut::(); state.maybe_response = Some(args); } /// Execute a request on the supplied snapshot, returning a response which /// contains information, like any emitted files, diagnostics, statistics and /// optionally an updated TypeScript build info. pub fn exec(request: Request) -> Result { // tsc cannot handle root specifiers that don't have one of the "acceptable" // extensions. Therefore, we have to check the root modules against their // extensions and remap any that are unacceptable to tsc and add them to the // op state so when requested, we can remap to the original specifier. let mut root_map = HashMap::new(); let mut remapped_specifiers = HashMap::new(); let root_names: Vec = request .root_names .iter() .map(|(s, mt)| match s.scheme() { "data" | "blob" => { let specifier_str = hash_url(s, *mt); remapped_specifiers.insert(specifier_str.clone(), s.clone()); specifier_str } _ => { if let Some(new_specifier) = mapped_specifier_for_tsc(s, *mt) { root_map.insert(new_specifier.clone(), s.clone()); new_specifier } else { s.to_string() } } }) .collect(); deno_core::extension!(deno_cli_tsc, ops = [ op_create_hash, op_emit, op_is_node_file, op_load, op_resolve, op_respond, ], options = { request: Request, root_map: HashMap, remapped_specifiers: HashMap, }, state = |state, options| { state.put(State::new( options.request.graph, options.request.hash_data, options.request.maybe_npm, options.request.maybe_tsbuildinfo, options.root_map, options.remapped_specifiers, std::env::current_dir() .context("Unable to get CWD") .unwrap(), )); }, ); let request_value = json!({ "config": request.config, "debug": request.debug, "rootNames": root_names, "localOnly": request.check_mode == TypeCheckMode::Local, }); let exec_source = format!("globalThis.exec({request_value})"); let mut runtime = JsRuntime::new(RuntimeOptions { startup_snapshot: Some(compiler_snapshot()), extensions: vec![deno_cli_tsc::init_ops( request, root_map, remapped_specifiers, )], create_params: create_isolate_create_params(), ..Default::default() }); runtime.execute_script(located_script_name!(), exec_source)?; let op_state = runtime.op_state(); let mut op_state = op_state.borrow_mut(); let state = op_state.take::(); if let Some(response) = state.maybe_response { let diagnostics = response.diagnostics; let maybe_tsbuildinfo = state.maybe_tsbuildinfo; let stats = response.stats; Ok(Response { diagnostics, maybe_tsbuildinfo, stats, }) } else { Err(anyhow!("The response for the exec request was not set.")) } } #[cfg(test)] mod tests { use super::Diagnostic; use super::DiagnosticCategory; use super::*; use crate::args::TsConfig; use deno_core::futures::future; use deno_core::serde_json; use deno_core::OpState; use deno_graph::GraphKind; use deno_graph::ModuleGraph; use test_util::PathRef; #[derive(Debug, Default)] pub struct MockLoader { pub fixtures: PathRef, } impl deno_graph::source::Loader for MockLoader { fn load( &self, specifier: &ModuleSpecifier, _options: deno_graph::source::LoadOptions, ) -> deno_graph::source::LoadFuture { let specifier_text = specifier .to_string() .replace(":///", "_") .replace("://", "_") .replace('/', "-"); let source_path = self.fixtures.join(specifier_text); let response = source_path.read_to_bytes_if_exists().map(|c| { Some(deno_graph::source::LoadResponse::Module { specifier: specifier.clone(), maybe_headers: None, content: c.into(), }) }); Box::pin(future::ready(response)) } } async fn setup( maybe_specifier: Option, maybe_hash_data: Option, maybe_tsbuildinfo: Option, ) -> OpState { let specifier = maybe_specifier .unwrap_or_else(|| ModuleSpecifier::parse("file:///main.ts").unwrap()); let hash_data = maybe_hash_data.unwrap_or(0); let fixtures = test_util::testdata_path().join("tsc2"); let loader = MockLoader { fixtures }; let mut graph = ModuleGraph::new(GraphKind::TypesOnly); graph .build(vec![specifier], &loader, Default::default()) .await; let state = State::new( Arc::new(graph), hash_data, None, maybe_tsbuildinfo, HashMap::new(), HashMap::new(), std::env::current_dir() .context("Unable to get CWD") .unwrap(), ); let mut op_state = OpState::new(None); op_state.put(state); op_state } async fn test_exec( specifier: &ModuleSpecifier, ) -> Result { let hash_data = 123; // something random let fixtures = test_util::testdata_path().join("tsc2"); let loader = MockLoader { fixtures }; let mut graph = ModuleGraph::new(GraphKind::TypesOnly); graph .build(vec![specifier.clone()], &loader, Default::default()) .await; let config = TsConfig::new(json!({ "allowJs": true, "checkJs": false, "esModuleInterop": true, "emitDecoratorMetadata": false, "incremental": true, "jsx": "react", "jsxFactory": "React.createElement", "jsxFragmentFactory": "React.Fragment", "lib": ["deno.window"], "noEmit": true, "outDir": "internal:///", "strict": true, "target": "esnext", "tsBuildInfoFile": "internal:///.tsbuildinfo", })); let request = Request { config, debug: false, graph: Arc::new(graph), hash_data, maybe_npm: None, maybe_tsbuildinfo: None, root_names: vec![(specifier.clone(), MediaType::TypeScript)], check_mode: TypeCheckMode::All, }; exec(request) } // TODO(bartlomieju): this test is segfaulting in V8, saying that there are too // few external references registered. It seems to be a bug in our snapshotting // logic. Because when we create TSC snapshot we register a few ops that // are called during snapshotting time, V8 expects at least as many references // when it starts up. The thing is that these ops are one-off - ie. they will never // be used again after the snapshot is taken. We should figure out a mechanism // to allow removing some of the ops before taking a snapshot. #[ignore] #[tokio::test] async fn test_compiler_snapshot() { let mut js_runtime = JsRuntime::new(RuntimeOptions { startup_snapshot: Some(compiler_snapshot()), ..Default::default() }); js_runtime .execute_script( "", r#" if (!(globalThis.exec)) { throw Error("bad"); } console.log(`ts version: ${ts.version}`); "#, ) .unwrap(); } #[tokio::test] async fn test_create_hash() { let mut state = setup(None, Some(123), None).await; let actual = op_create_hash_inner(&mut state, "some sort of content"); assert_eq!(actual, "11905938177474799758"); } #[tokio::test] async fn test_hash_url() { let specifier = deno_core::resolve_url( "data:application/javascript,console.log(\"Hello%20Deno\");", ) .unwrap(); assert_eq!(hash_url(&specifier, MediaType::JavaScript), "data:///d300ea0796bd72b08df10348e0b70514c021f2e45bfe59cec24e12e97cd79c58.js"); } #[tokio::test] async fn test_emit_tsbuildinfo() { let mut state = setup(None, None, None).await; let actual = op_emit_inner( &mut state, EmitArgs { data: "some file content".to_string(), file_name: "internal:///.tsbuildinfo".to_string(), }, ); assert!(actual); let state = state.borrow::(); assert_eq!( state.maybe_tsbuildinfo, Some("some file content".to_string()) ); } #[tokio::test] async fn test_load() { let mut state = setup( Some(ModuleSpecifier::parse("https://deno.land/x/mod.ts").unwrap()), None, Some("some content".to_string()), ) .await; let actual = op_load_inner(&mut state, "https://deno.land/x/mod.ts").unwrap(); assert_eq!( serde_json::to_value(actual).unwrap(), json!({ "data": "console.log(\"hello deno\");\n", "version": "7821807483407828376", "scriptKind": 3, "isCjs": false, }) ); } #[tokio::test] async fn test_load_asset() { let mut state = setup( Some(ModuleSpecifier::parse("https://deno.land/x/mod.ts").unwrap()), None, Some("some content".to_string()), ) .await; let actual = op_load_inner(&mut state, "asset:///lib.dom.d.ts") .expect("should have invoked op") .expect("load should have succeeded"); let expected = get_lazily_loaded_asset("lib.dom.d.ts").unwrap(); assert_eq!(actual.data, expected); assert!(actual.version.is_some()); assert_eq!(actual.script_kind, 3); } #[tokio::test] async fn test_load_tsbuildinfo() { let mut state = setup( Some(ModuleSpecifier::parse("https://deno.land/x/mod.ts").unwrap()), None, Some("some content".to_string()), ) .await; let actual = op_load_inner(&mut state, "internal:///.tsbuildinfo") .expect("should have invoked op") .expect("load should have succeeded"); assert_eq!( serde_json::to_value(actual).unwrap(), json!({ "data": "some content", "version": null, "scriptKind": 0, "isCjs": false, }) ); } #[tokio::test] async fn test_load_missing_specifier() { let mut state = setup(None, None, None).await; let actual = op_load_inner(&mut state, "https://deno.land/x/mod.ts") .expect("should have invoked op"); assert_eq!(serde_json::to_value(actual).unwrap(), json!(null)); } #[tokio::test] async fn test_resolve() { let mut state = setup( Some(ModuleSpecifier::parse("https://deno.land/x/a.ts").unwrap()), None, None, ) .await; let actual = op_resolve_inner( &mut state, ResolveArgs { base: "https://deno.land/x/a.ts".to_string(), is_base_cjs: false, specifiers: vec!["./b.ts".to_string()], }, ) .expect("should have invoked op"); assert_eq!(actual, vec![("https://deno.land/x/b.ts".into(), ".ts")]); } #[tokio::test] async fn test_resolve_empty() { let mut state = setup( Some(ModuleSpecifier::parse("https://deno.land/x/a.ts").unwrap()), None, None, ) .await; let actual = op_resolve_inner( &mut state, ResolveArgs { base: "https://deno.land/x/a.ts".to_string(), is_base_cjs: false, specifiers: vec!["./bad.ts".to_string()], }, ) .expect("should have not errored"); assert_eq!(actual, vec![(MISSING_DEPENDENCY_SPECIFIER.into(), ".d.ts")]); } #[tokio::test] async fn test_respond() { let mut state = setup(None, None, None).await; let args = serde_json::from_value(json!({ "diagnostics": [ { "messageText": "Unknown compiler option 'invalid'.", "category": 1, "code": 5023 } ], "stats": [["a", 12]] })) .unwrap(); op_respond_inner(&mut state, args); let state = state.borrow::(); assert_eq!( state.maybe_response, Some(RespondArgs { diagnostics: Diagnostics::new(vec![Diagnostic { category: DiagnosticCategory::Error, code: 5023, start: None, end: None, original_source_start: None, message_text: Some( "Unknown compiler option \'invalid\'.".to_string() ), message_chain: None, source: None, source_line: None, file_name: None, related_information: None, }]), stats: Stats(vec![("a".to_string(), 12)]) }) ); } #[tokio::test] async fn test_exec_basic() { let specifier = ModuleSpecifier::parse("https://deno.land/x/a.ts").unwrap(); let actual = test_exec(&specifier) .await .expect("exec should not have errored"); assert!(actual.diagnostics.is_empty()); assert!(actual.maybe_tsbuildinfo.is_some()); assert_eq!(actual.stats.0.len(), 12); } #[tokio::test] async fn test_exec_reexport_dts() { let specifier = ModuleSpecifier::parse("file:///reexports.ts").unwrap(); let actual = test_exec(&specifier) .await .expect("exec should not have errored"); assert!(actual.diagnostics.is_empty()); assert!(actual.maybe_tsbuildinfo.is_some()); assert_eq!(actual.stats.0.len(), 12); } #[tokio::test] async fn fix_lib_ref() { let specifier = ModuleSpecifier::parse("file:///libref.ts").unwrap(); let actual = test_exec(&specifier) .await .expect("exec should not have errored"); assert!(actual.diagnostics.is_empty()); } }