// Copyright 2018-2021 the Deno authors. All rights reserved. MIT license. use crate::ast; use crate::ast::parse; use crate::ast::transpile_module; use crate::ast::BundleHook; use crate::ast::Location; use crate::ast::ParsedModule; use crate::colors; use crate::diagnostics::Diagnostics; use crate::import_map::ImportMap; use crate::info::ModuleGraphInfo; use crate::info::ModuleInfo; use crate::info::ModuleInfoMap; use crate::info::ModuleInfoMapItem; use crate::lockfile::Lockfile; use crate::media_type::MediaType; use crate::specifier_handler::CachedModule; use crate::specifier_handler::Dependency; use crate::specifier_handler::DependencyMap; use crate::specifier_handler::Emit; use crate::specifier_handler::FetchFuture; use crate::specifier_handler::SpecifierHandler; use crate::tsc; use crate::tsc_config::IgnoredCompilerOptions; use crate::tsc_config::TsConfig; use crate::version; use deno_core::error::AnyError; use deno_core::error::anyhow; use deno_core::error::custom_error; use deno_core::error::get_custom_error_class; use deno_core::error::Context; use deno_core::futures::stream::FuturesUnordered; use deno_core::futures::stream::StreamExt; 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_json::Value; use deno_core::ModuleResolutionError; use deno_core::ModuleSource; use deno_core::ModuleSpecifier; use regex::Regex; use std::collections::HashSet; use std::collections::{BTreeSet, HashMap}; use std::error::Error; use std::fmt; use std::path::PathBuf; use std::rc::Rc; use std::result; use std::sync::Arc; use std::sync::Mutex; use std::time::Instant; lazy_static! { /// Matched the `@deno-types` pragma. static ref DENO_TYPES_RE: Regex = Regex::new(r#"(?i)^\s*@deno-types\s*=\s*(?:["']([^"']+)["']|(\S+))"#) .unwrap(); /// Matches a `/// ` comment reference. static ref TRIPLE_SLASH_REFERENCE_RE: Regex = Regex::new(r"(?i)^/\s*").unwrap(); /// Matches a path reference, which adds a dependency to a module static ref PATH_REFERENCE_RE: Regex = Regex::new(r#"(?i)\spath\s*=\s*["']([^"']*)["']"#).unwrap(); /// Matches a types reference, which for JavaScript files indicates the /// location of types to use when type checking a program that includes it as /// a dependency. static ref TYPES_REFERENCE_RE: Regex = Regex::new(r#"(?i)\stypes\s*=\s*["']([^"']*)["']"#).unwrap(); } /// A group of errors that represent errors that can occur when interacting with /// a module graph. #[derive(Debug, Clone, Eq, PartialEq)] pub enum GraphError { /// A module using the HTTPS protocol is trying to import a module with an /// HTTP schema. InvalidDowngrade(ModuleSpecifier, Location), /// A remote module is trying to import a local module. InvalidLocalImport(ModuleSpecifier, Location), /// The source code is invalid, as it does not match the expected hash in the /// lockfile. InvalidSource(ModuleSpecifier, PathBuf), /// An unexpected dependency was requested for a module. MissingDependency(ModuleSpecifier, String), /// An unexpected specifier was requested. MissingSpecifier(ModuleSpecifier), /// The current feature is not supported. NotSupported(String), /// A unsupported media type was attempted to be imported as a module. UnsupportedImportType(ModuleSpecifier, MediaType), } impl fmt::Display for GraphError { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self { GraphError::InvalidDowngrade(ref specifier, ref location) => write!(f, "Modules imported via https are not allowed to import http modules.\n Importing: {}\n at {}", specifier, location), GraphError::InvalidLocalImport(ref specifier, ref location) => write!(f, "Remote modules are not allowed to import local modules. Consider using a dynamic import instead.\n Importing: {}\n at {}", specifier, location), GraphError::InvalidSource(ref specifier, ref lockfile) => write!(f, "The source code is invalid, as it does not match the expected hash in the lock file.\n Specifier: {}\n Lock file: {}", specifier, lockfile.to_str().unwrap()), GraphError::MissingDependency(ref referrer, specifier) => write!( f, "The graph is missing a dependency.\n Specifier: {} from {}", specifier, referrer ), GraphError::MissingSpecifier(ref specifier) => write!( f, "The graph is missing a specifier.\n Specifier: {}", specifier ), GraphError::NotSupported(ref msg) => write!(f, "{}", msg), GraphError::UnsupportedImportType(ref specifier, ref media_type) => write!(f, "An unsupported media type was attempted to be imported as a module.\n Specifier: {}\n MediaType: {}", specifier, media_type), } } } impl Error for GraphError {} /// A structure for handling bundle loading, which is implemented here, to /// avoid a circular dependency with `ast`. struct BundleLoader<'a> { cm: Rc, emit_options: &'a ast::EmitOptions, globals: &'a swc_common::Globals, graph: &'a Graph, } impl<'a> BundleLoader<'a> { pub fn new( graph: &'a Graph, emit_options: &'a ast::EmitOptions, globals: &'a swc_common::Globals, cm: Rc, ) -> Self { BundleLoader { cm, emit_options, globals, graph, } } } impl swc_bundler::Load for BundleLoader<'_> { fn load( &self, file: &swc_common::FileName, ) -> Result { match file { swc_common::FileName::Custom(filename) => { let specifier = ModuleSpecifier::resolve_url_or_path(filename) .context("Failed to convert swc FileName to ModuleSpecifier.")?; if let Some(src) = self.graph.get_source(&specifier) { let media_type = self .graph .get_media_type(&specifier) .context("Looking up media type during bundling.")?; let (source_file, module) = transpile_module( filename, &src, &media_type, self.emit_options, self.globals, self.cm.clone(), )?; Ok(swc_bundler::ModuleData { fm: source_file, module, helpers: Default::default(), }) } else { Err( GraphError::MissingDependency(specifier, "".to_string()) .into(), ) } } _ => unreachable!("Received request for unsupported filename {:?}", file), } } } /// An enum which represents the parsed out values of references in source code. #[derive(Debug, Clone, Eq, PartialEq)] pub enum TypeScriptReference { Path(String), Types(String), } /// Determine if a comment contains a triple slash reference and optionally /// return its kind and value. pub fn parse_ts_reference(comment: &str) -> Option { if !TRIPLE_SLASH_REFERENCE_RE.is_match(comment) { None } else if let Some(captures) = PATH_REFERENCE_RE.captures(comment) { Some(TypeScriptReference::Path( captures.get(1).unwrap().as_str().to_string(), )) } else if let Some(captures) = TYPES_REFERENCE_RE.captures(comment) { Some(TypeScriptReference::Types( captures.get(1).unwrap().as_str().to_string(), )) } else { None } } /// Determine if a comment contains a `@deno-types` pragma and optionally return /// its value. pub fn parse_deno_types(comment: &str) -> Option { if let Some(captures) = DENO_TYPES_RE.captures(comment) { if let Some(m) = captures.get(1) { Some(m.as_str().to_string()) } else if let Some(m) = captures.get(2) { Some(m.as_str().to_string()) } else { panic!("unreachable"); } } else { None } } /// A hashing function that takes the source code, version and optionally a /// user provided config and generates a string hash which can be stored to /// determine if the cached emit is valid or not. fn get_version(source: &str, version: &str, config: &[u8]) -> String { crate::checksum::gen(&[source.as_bytes(), version.as_bytes(), config]) } /// A logical representation of a module within a graph. #[derive(Debug, Clone)] pub struct Module { pub dependencies: DependencyMap, is_dirty: bool, is_parsed: bool, maybe_emit: Option, maybe_emit_path: Option<(PathBuf, Option)>, maybe_import_map: Option>>, maybe_types: Option<(String, ModuleSpecifier)>, maybe_version: Option, media_type: MediaType, specifier: ModuleSpecifier, source: String, source_path: PathBuf, } impl Default for Module { fn default() -> Self { Module { dependencies: HashMap::new(), is_dirty: false, is_parsed: false, maybe_emit: None, maybe_emit_path: None, maybe_import_map: None, maybe_types: None, maybe_version: None, media_type: MediaType::Unknown, specifier: ModuleSpecifier::resolve_url("file:///example.js").unwrap(), source: "".to_string(), source_path: PathBuf::new(), } } } impl Module { pub fn new( cached_module: CachedModule, is_root: bool, maybe_import_map: Option>>, ) -> Self { // If this is a local root file, and its media type is unknown, set the // media type to JavaScript. This allows easier ability to create "shell" // scripts with Deno. let media_type = if is_root && !cached_module.is_remote && cached_module.media_type == MediaType::Unknown { MediaType::JavaScript } else { cached_module.media_type }; let mut module = Module { specifier: cached_module.specifier, maybe_import_map, media_type, source: cached_module.source, source_path: cached_module.source_path, maybe_emit: cached_module.maybe_emit, maybe_emit_path: cached_module.maybe_emit_path, maybe_version: cached_module.maybe_version, is_dirty: false, ..Self::default() }; if module.maybe_import_map.is_none() { if let Some(dependencies) = cached_module.maybe_dependencies { module.dependencies = dependencies; module.is_parsed = true; } } module.maybe_types = if let Some(ref specifier) = cached_module.maybe_types { Some(( specifier.clone(), module .resolve_import(&specifier, None) .expect("could not resolve module"), )) } else { None }; module } /// Return `true` if the current hash of the module matches the stored /// version. pub fn is_emit_valid(&self, config: &[u8]) -> bool { if let Some(version) = self.maybe_version.clone() { version == get_version(&self.source, &version::deno(), config) } else { false } } /// Parse a module, populating the structure with data retrieved from the /// source of the module. pub fn parse(&mut self) -> Result { let parsed_module = parse(self.specifier.as_str(), &self.source, &self.media_type)?; // parse out any triple slash references for comment in parsed_module.get_leading_comments().iter() { if let Some(ts_reference) = parse_ts_reference(&comment.text) { let location = parsed_module.get_location(&comment.span); match ts_reference { TypeScriptReference::Path(import) => { let specifier = self.resolve_import(&import, Some(location.clone()))?; let dep = self .dependencies .entry(import) .or_insert_with(|| Dependency::new(location)); dep.maybe_code = Some(specifier); } TypeScriptReference::Types(import) => { let specifier = self.resolve_import(&import, Some(location.clone()))?; if self.media_type == MediaType::JavaScript || self.media_type == MediaType::JSX { // TODO(kitsonk) we need to specifically update the cache when // this value changes self.maybe_types = Some((import.clone(), specifier)); } else { let dep = self .dependencies .entry(import) .or_insert_with(|| Dependency::new(location)); dep.maybe_type = Some(specifier); } } } } } // Parse out all the syntactical dependencies for a module let dependencies = parsed_module.analyze_dependencies(); for desc in dependencies.iter().filter(|desc| { desc.kind != swc_ecmascript::dep_graph::DependencyKind::Require }) { let location = Location { filename: self.specifier.to_string(), col: desc.col, line: desc.line, }; // In situations where there is a potential issue with resolving the // import specifier, that ends up being a module resolution error for a // code dependency, we should not throw in the `ModuleGraph` but instead // wait until runtime and throw there, as with dynamic imports they need // to be catchable, which means they need to be resolved at runtime. let maybe_specifier = match self.resolve_import(&desc.specifier, Some(location.clone())) { Ok(specifier) => Some(specifier), Err(any_error) => { match any_error.downcast_ref::() { Some(ModuleResolutionError::ImportPrefixMissing(_, _)) => None, _ => { return Err(any_error); } } } }; // Parse out any `@deno-types` pragmas and modify dependency let maybe_type = if !desc.leading_comments.is_empty() { let comment = desc.leading_comments.last().unwrap(); if let Some(deno_types) = parse_deno_types(&comment.text).as_ref() { Some(self.resolve_import(deno_types, Some(location.clone()))?) } else { None } } else { None }; let dep = self .dependencies .entry(desc.specifier.to_string()) .or_insert_with(|| Dependency::new(location)); dep.is_dynamic = desc.is_dynamic; if let Some(specifier) = maybe_specifier { if desc.kind == swc_ecmascript::dep_graph::DependencyKind::ExportType || desc.kind == swc_ecmascript::dep_graph::DependencyKind::ImportType { dep.maybe_type = Some(specifier); } else { dep.maybe_code = Some(specifier); } } // If the dependency wasn't a type only dependency already, and there is // a `@deno-types` comment, then we will set the `maybe_type` dependency. if maybe_type.is_some() && dep.maybe_type.is_none() { dep.maybe_type = maybe_type; } } Ok(parsed_module) } fn resolve_import( &self, specifier: &str, maybe_location: Option, ) -> Result { let maybe_resolve = if let Some(import_map) = self.maybe_import_map.clone() { import_map .lock() .unwrap() .resolve(specifier, self.specifier.as_str())? } else { None }; let mut remapped_import = false; let specifier = if let Some(module_specifier) = maybe_resolve { remapped_import = true; module_specifier } else { ModuleSpecifier::resolve_import(specifier, self.specifier.as_str())? }; let referrer_scheme = self.specifier.as_url().scheme(); let specifier_scheme = specifier.as_url().scheme(); let location = maybe_location.unwrap_or(Location { filename: self.specifier.to_string(), line: 0, col: 0, }); // Disallow downgrades from HTTPS to HTTP if referrer_scheme == "https" && specifier_scheme == "http" { return Err( GraphError::InvalidDowngrade(specifier.clone(), location).into(), ); } // Disallow a remote URL from trying to import a local URL, unless it is a // remapped import via the import map if (referrer_scheme == "https" || referrer_scheme == "http") && !(specifier_scheme == "https" || specifier_scheme == "http") && !remapped_import { return Err( GraphError::InvalidLocalImport(specifier.clone(), location).into(), ); } Ok(specifier) } pub fn set_emit(&mut self, code: String, maybe_map: Option) { self.maybe_emit = Some(Emit::Cli((code, maybe_map))); } /// Calculate the hashed version of the module and update the `maybe_version`. pub fn set_version(&mut self, config: &[u8]) { self.maybe_version = Some(get_version(&self.source, &version::deno(), config)) } pub fn size(&self) -> usize { self.source.as_bytes().len() } } #[derive(Clone, Debug, Default, Eq, PartialEq)] pub struct Stats(pub Vec<(String, u32)>); impl<'de> Deserialize<'de> for Stats { fn deserialize(deserializer: D) -> result::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(()) } } /// A structure that provides information about a module graph result. #[derive(Debug, Default)] pub struct ResultInfo { /// A structure which provides diagnostic information (usually from `tsc`) /// about the code in the module graph. pub diagnostics: Diagnostics, /// A map of specifiers to the result of their resolution in the module graph. pub loadable_modules: HashMap>, /// Optionally ignored compiler options that represent any options that were /// ignored if there was a user provided configuration. pub maybe_ignored_options: Option, /// A structure providing key metrics around the operation performed, in /// milliseconds. pub stats: Stats, } /// Represents the "default" type library that should be used when type /// checking the code in the module graph. Note that a user provided config /// of `"lib"` would override this value. #[derive(Debug, Clone, Eq, PartialEq)] pub enum TypeLib { DenoWindow, DenoWorker, UnstableDenoWindow, UnstableDenoWorker, } impl Default for TypeLib { fn default() -> Self { TypeLib::DenoWindow } } impl Serialize for TypeLib { fn serialize(&self, serializer: S) -> Result where S: Serializer, { let value = match self { TypeLib::DenoWindow => vec!["deno.window".to_string()], TypeLib::DenoWorker => vec!["deno.worker".to_string()], TypeLib::UnstableDenoWindow => { vec!["deno.window".to_string(), "deno.unstable".to_string()] } TypeLib::UnstableDenoWorker => { vec!["deno.worker".to_string(), "deno.unstable".to_string()] } }; Serialize::serialize(&value, serializer) } } #[derive(Debug, Default)] pub struct BundleOptions { /// If `true` then debug logging will be output from the isolate. pub debug: bool, /// An optional string that points to a user supplied TypeScript configuration /// file that augments the the default configuration passed to the TypeScript /// compiler. pub maybe_config_path: Option, } #[derive(Debug, Default)] pub struct CheckOptions { /// If `true` then debug logging will be output from the isolate. pub debug: bool, /// Utilise the emit from `tsc` to update the emitted code for modules. pub emit: bool, /// The base type libraries that should be used when type checking. pub lib: TypeLib, /// An optional string that points to a user supplied TypeScript configuration /// file that augments the the default configuration passed to the TypeScript /// compiler. pub maybe_config_path: Option, /// Ignore any previously emits and ensure that all files are emitted from /// source. pub reload: bool, } #[derive(Debug, Eq, PartialEq)] pub enum BundleType { /// Return the emitted contents of the program as a single "flattened" ES /// module. Esm, /// Return the emitted contents of the program as a single script that /// executes the program using an immediately invoked function execution /// (IIFE). Iife, /// Do not bundle the emit, instead returning each of the modules that are /// part of the program as individual files. None, } impl Default for BundleType { fn default() -> Self { BundleType::None } } #[derive(Debug, Default)] pub struct EmitOptions { /// If true, then code will be type checked, otherwise type checking will be /// skipped. If false, then swc will be used for the emit, otherwise tsc will /// be used. pub check: bool, /// Indicate the form the result of the emit should take. pub bundle_type: BundleType, /// If `true` then debug logging will be output from the isolate. pub debug: bool, /// An optional map that contains user supplied TypeScript compiler /// configuration options that are passed to the TypeScript compiler. pub maybe_user_config: Option>, } /// A structure which provides options when transpiling modules. #[derive(Debug, Default)] pub struct TranspileOptions { /// If `true` then debug logging will be output from the isolate. pub debug: bool, /// An optional string that points to a user supplied TypeScript configuration /// file that augments the the default configuration passed to the TypeScript /// compiler. pub maybe_config_path: Option, /// Ignore any previously emits and ensure that all files are emitted from /// source. pub reload: bool, } #[derive(Debug, Clone)] enum ModuleSlot { /// The module fetch resulted in a non-recoverable error. Err(Arc), /// The the fetch resulted in a module. Module(Box), /// Used to denote a module that isn't part of the graph. None, /// The fetch of the module is pending. Pending, } /// A dependency graph of modules, were the modules that have been inserted via /// the builder will be loaded into the graph. Also provides an interface to /// be able to manipulate and handle the graph. #[derive(Debug, Clone)] pub struct Graph { /// A reference to the specifier handler that will retrieve and cache modules /// for the graph. handler: Arc>, /// Optional TypeScript build info that will be passed to `tsc` if `tsc` is /// invoked. maybe_tsbuildinfo: Option, /// The modules that are part of the graph. modules: HashMap, /// A map of redirects, where a module specifier is redirected to another /// module specifier by the handler. All modules references should be /// resolved internally via this, before attempting to access the module via /// the handler, to make sure the correct modules is being dealt with. redirects: HashMap, /// The module specifiers that have been uniquely added to the graph, which /// does not include any transient dependencies. roots: Vec, /// If all of the root modules are dynamically imported, then this is true. /// This is used to ensure correct `--reload` behavior, where subsequent /// calls to a module graph where the emit is already valid do not cause the /// graph to re-emit. roots_dynamic: bool, // A reference to lock file that will be used to check module integrity. maybe_lockfile: Option>>, } /// Convert a specifier and a module slot in a result to the module source which /// is needed by Deno core for loading the module. fn to_module_result( (specifier, module_slot): (&ModuleSpecifier, &ModuleSlot), ) -> (ModuleSpecifier, Result) { match module_slot { ModuleSlot::Err(err) => (specifier.clone(), Err(anyhow!(err.to_string()))), ModuleSlot::Module(module) => ( specifier.clone(), if let Some(emit) = &module.maybe_emit { match emit { Emit::Cli((code, _)) => Ok(ModuleSource { code: code.clone(), module_url_found: module.specifier.to_string(), module_url_specified: specifier.to_string(), }), } } else { match module.media_type { MediaType::JavaScript | MediaType::Unknown => Ok(ModuleSource { code: module.source.clone(), module_url_found: module.specifier.to_string(), module_url_specified: specifier.to_string(), }), _ => Err(custom_error( "NotFound", format!("Compiled module not found \"{}\"", specifier), )), } }, ), _ => ( specifier.clone(), Err(anyhow!("Module \"{}\" unavailable.", specifier)), ), } } impl Graph { /// Create a new instance of a graph, ready to have modules loaded it. /// /// The argument `handler` is an instance of a structure that implements the /// `SpecifierHandler` trait. /// pub fn new( handler: Arc>, maybe_lockfile: Option>>, ) -> Self { Graph { handler, maybe_tsbuildinfo: None, modules: HashMap::new(), redirects: HashMap::new(), roots: Vec::new(), roots_dynamic: true, maybe_lockfile, } } /// Transform the module graph into a single JavaScript module which is /// returned as a `String` in the result. pub fn bundle( &self, options: BundleOptions, ) -> Result<(String, Stats, Option), AnyError> { if self.roots.is_empty() || self.roots.len() > 1 { return Err(GraphError::NotSupported(format!("Bundling is only supported when there is a single root module in the graph. Found: {}", self.roots.len())).into()); } let start = Instant::now(); let root_specifier = self.roots[0].clone(); let mut ts_config = TsConfig::new(json!({ "checkJs": false, "emitDecoratorMetadata": false, "inlineSourceMap": true, "jsx": "react", "jsxFactory": "React.createElement", "jsxFragmentFactory": "React.Fragment", })); let maybe_ignored_options = ts_config.merge_tsconfig(options.maybe_config_path)?; let s = self.emit_bundle(&root_specifier, &ts_config.into(), &BundleType::Esm)?; let stats = Stats(vec![ ("Files".to_string(), self.modules.len() as u32), ("Total time".to_string(), start.elapsed().as_millis() as u32), ]); Ok((s, stats, maybe_ignored_options)) } /// Type check the module graph, corresponding to the options provided. pub fn check(self, options: CheckOptions) -> Result { self.validate()?; let mut config = TsConfig::new(json!({ "allowJs": true, // TODO(@kitsonk) is this really needed? "esModuleInterop": true, // Enabled by default to align to transpile/swc defaults "experimentalDecorators": true, "incremental": true, "jsx": "react", "isolatedModules": true, "lib": options.lib, "module": "esnext", "strict": true, "target": "esnext", "tsBuildInfoFile": "deno:///.tsbuildinfo", })); if options.emit { config.merge(&json!({ // TODO(@kitsonk) consider enabling this by default // see: https://github.com/denoland/deno/issues/7732 "emitDecoratorMetadata": false, "inlineSourceMap": true, "outDir": "deno://", "removeComments": true, })); } else { config.merge(&json!({ "noEmit": true, })); } let maybe_ignored_options = config.merge_tsconfig(options.maybe_config_path)?; // Short circuit if none of the modules require an emit, or all of the // modules that require an emit have a valid emit. There is also an edge // case where there are multiple imports of a dynamic module during a // single invocation, if that is the case, even if there is a reload, we // will simply look at if the emit is invalid, to avoid two checks for the // same programme. if !self.needs_emit(&config) || (self.is_emit_valid(&config) && (!options.reload || self.roots_dynamic)) { debug!("graph does not need to be checked or emitted."); return Ok(ResultInfo { maybe_ignored_options, loadable_modules: self.get_loadable_modules(), ..Default::default() }); } // TODO(@kitsonk) not totally happy with this here, but this is the first // point where we know we are actually going to check the program. If we // moved it out of here, we wouldn't know until after the check has already // happened, which isn't informative to the users. for specifier in &self.roots { info!("{} {}", colors::green("Check"), specifier); } let root_names = self.get_root_names(!config.get_check_js())?; let maybe_tsbuildinfo = self.maybe_tsbuildinfo.clone(); let hash_data = vec![config.as_bytes(), version::deno().as_bytes().to_owned()]; let graph = Arc::new(Mutex::new(self)); let response = tsc::exec(tsc::Request { config: config.clone(), debug: options.debug, graph: graph.clone(), hash_data, maybe_tsbuildinfo, root_names, })?; let mut graph = graph.lock().unwrap(); graph.maybe_tsbuildinfo = response.maybe_tsbuildinfo; // Only process changes to the graph if there are no diagnostics and there // were files emitted. if response.diagnostics.is_empty() { if !response.emitted_files.is_empty() { let mut codes = HashMap::new(); let mut maps = HashMap::new(); let check_js = config.get_check_js(); for emit in &response.emitted_files { if let Some(specifiers) = &emit.maybe_specifiers { assert!(specifiers.len() == 1, "Unexpected specifier length"); // The specifier emitted might not be the redirected specifier, and // therefore we need to ensure it is the correct one. let specifier = graph.resolve_specifier(&specifiers[0]); // Sometimes if tsc sees a CommonJS file it will _helpfully_ output it // to ESM, which we don't really want unless someone has enabled the // check_js option. if !check_js && graph.get_media_type(&specifier) == Some(MediaType::JavaScript) { debug!("skipping emit for {}", specifier); continue; } match emit.media_type { MediaType::JavaScript => { codes.insert(specifier.clone(), emit.data.clone()); } MediaType::SourceMap => { maps.insert(specifier.clone(), emit.data.clone()); } _ => unreachable!(), } } } let config = config.as_bytes(); for (specifier, code) in codes.iter() { if let ModuleSlot::Module(module) = graph.get_module_mut(specifier).unwrap() { module.set_emit(code.clone(), maps.get(specifier).cloned()); module.set_version(&config); module.is_dirty = true; } else { return Err(GraphError::MissingSpecifier(specifier.clone()).into()); } } } graph.flush()?; } Ok(ResultInfo { diagnostics: response.diagnostics, loadable_modules: graph.get_loadable_modules(), maybe_ignored_options, stats: response.stats, }) } /// Emit the module graph in a specific format. This is specifically designed /// to be an "all-in-one" API for access by the runtime, allowing both /// emitting single modules as well as bundles, using Deno module resolution /// or supplied sources. pub fn emit( mut self, options: EmitOptions, ) -> Result<(HashMap, ResultInfo), AnyError> { let mut config = TsConfig::new(json!({ "allowJs": true, "checkJs": false, // TODO(@kitsonk) consider enabling this by default // see: https://github.com/denoland/deno/issues/7732 "emitDecoratorMetadata": false, "esModuleInterop": true, "experimentalDecorators": true, "inlineSourceMap": false, "isolatedModules": true, "jsx": "react", "jsxFactory": "React.createElement", "jsxFragmentFactory": "React.Fragment", "lib": TypeLib::DenoWindow, "module": "esnext", "strict": true, "target": "esnext", })); let opts = match options.bundle_type { BundleType::Esm | BundleType::Iife => json!({ "noEmit": true, }), BundleType::None => json!({ "outDir": "deno://", "removeComments": true, "sourceMap": true, }), }; config.merge(&opts); let maybe_ignored_options = if let Some(user_options) = &options.maybe_user_config { config.merge_user_config(user_options)? } else { None }; if !options.check && config.get_declaration() { return Err(anyhow!("The option of `check` is false, but the compiler option of `declaration` is true which is not currently supported.")); } if options.bundle_type != BundleType::None && config.get_declaration() { return Err(anyhow!("The bundle option is set, but the compiler option of `declaration` is true which is not currently supported.")); } let mut emitted_files = HashMap::new(); if options.check { let root_names = self.get_root_names(!config.get_check_js())?; let hash_data = vec![config.as_bytes(), version::deno().as_bytes().to_owned()]; let graph = Arc::new(Mutex::new(self)); let response = tsc::exec(tsc::Request { config: config.clone(), debug: options.debug, graph: graph.clone(), hash_data, maybe_tsbuildinfo: None, root_names, })?; let graph = graph.lock().unwrap(); match options.bundle_type { BundleType::Esm | BundleType::Iife => { assert!( response.emitted_files.is_empty(), "No files should have been emitted from tsc." ); assert_eq!( graph.roots.len(), 1, "Only a single root module supported." ); let specifier = &graph.roots[0]; let s = graph.emit_bundle( specifier, &config.into(), &options.bundle_type, )?; emitted_files.insert("deno:///bundle.js".to_string(), s); } BundleType::None => { for emitted_file in &response.emitted_files { assert!( emitted_file.maybe_specifiers.is_some(), "Orphaned file emitted." ); let specifiers = emitted_file.maybe_specifiers.clone().unwrap(); assert_eq!( specifiers.len(), 1, "An unexpected number of specifiers associated with emitted file." ); let specifier = specifiers[0].clone(); let extension = match emitted_file.media_type { MediaType::JavaScript => ".js", MediaType::SourceMap => ".js.map", MediaType::Dts => ".d.ts", _ => unreachable!(), }; let key = format!("{}{}", specifier, extension); emitted_files.insert(key, emitted_file.data.clone()); } } }; Ok(( emitted_files, ResultInfo { diagnostics: response.diagnostics, loadable_modules: graph.get_loadable_modules(), maybe_ignored_options, stats: response.stats, }, )) } else { let start = Instant::now(); let mut emit_count = 0_u32; match options.bundle_type { BundleType::Esm | BundleType::Iife => { assert_eq!( self.roots.len(), 1, "Only a single root module supported." ); let specifier = &self.roots[0]; let s = self.emit_bundle( specifier, &config.into(), &options.bundle_type, )?; emit_count += 1; emitted_files.insert("deno:///bundle.js".to_string(), s); } BundleType::None => { let emit_options: ast::EmitOptions = config.into(); for (_, module_slot) in self.modules.iter_mut() { if let ModuleSlot::Module(module) = module_slot { if !(emit_options.check_js || module.media_type == MediaType::JSX || module.media_type == MediaType::TSX || module.media_type == MediaType::TypeScript) { emitted_files .insert(module.specifier.to_string(), module.source.clone()); } let parsed_module = module.parse()?; let (code, maybe_map) = parsed_module.transpile(&emit_options)?; emit_count += 1; emitted_files.insert(format!("{}.js", module.specifier), code); if let Some(map) = maybe_map { emitted_files .insert(format!("{}.js.map", module.specifier), map); } } } self.flush()?; } } let stats = Stats(vec![ ("Files".to_string(), self.modules.len() as u32), ("Emitted".to_string(), emit_count), ("Total time".to_string(), start.elapsed().as_millis() as u32), ]); Ok(( emitted_files, ResultInfo { diagnostics: Default::default(), loadable_modules: self.get_loadable_modules(), maybe_ignored_options, stats, }, )) } } /// Shared between `bundle()` and `emit()`. fn emit_bundle( &self, specifier: &ModuleSpecifier, emit_options: &ast::EmitOptions, bundle_type: &BundleType, ) -> Result { let cm = Rc::new(swc_common::SourceMap::new( swc_common::FilePathMapping::empty(), )); let globals = swc_common::Globals::new(); let loader = BundleLoader::new(self, emit_options, &globals, cm.clone()); let hook = Box::new(BundleHook); let module = match bundle_type { BundleType::Esm => swc_bundler::ModuleType::Es, BundleType::Iife => swc_bundler::ModuleType::Iife, _ => unreachable!("invalid bundle type"), }; let bundler = swc_bundler::Bundler::new( &globals, cm.clone(), loader, self, swc_bundler::Config { module, ..Default::default() }, hook, ); let mut entries = HashMap::new(); entries.insert( "bundle".to_string(), swc_common::FileName::Custom(specifier.to_string()), ); let output = bundler .bundle(entries) .context("Unable to output bundle during Graph::bundle().")?; let mut buf = Vec::new(); { let mut emitter = swc_ecmascript::codegen::Emitter { cfg: swc_ecmascript::codegen::Config { minify: false }, cm: cm.clone(), comments: None, wr: Box::new(swc_ecmascript::codegen::text_writer::JsWriter::new( cm, "\n", &mut buf, None, )), }; emitter .emit_module(&output[0].module) .context("Unable to emit bundle during Graph::bundle().")?; } String::from_utf8(buf).context("Emitted bundle is an invalid utf-8 string.") } /// Update the handler with any modules that are marked as _dirty_ and update /// any build info if present. fn flush(&mut self) -> Result<(), AnyError> { let mut handler = self.handler.lock().unwrap(); for (_, module_slot) in self.modules.iter_mut() { if let ModuleSlot::Module(module) = module_slot { if module.is_dirty { if let Some(emit) = &module.maybe_emit { handler.set_cache(&module.specifier, emit)?; } if let Some(version) = &module.maybe_version { handler.set_version(&module.specifier, version.clone())?; } module.is_dirty = false; } } } for root_specifier in self.roots.iter() { if let Some(tsbuildinfo) = &self.maybe_tsbuildinfo { handler.set_tsbuildinfo(root_specifier, tsbuildinfo.to_owned())?; } } Ok(()) } fn get_info( &self, specifier: &ModuleSpecifier, seen: &mut HashSet, totals: &mut HashMap, ) -> ModuleInfo { let not_seen = seen.insert(specifier.clone()); let module = match self.get_module(specifier) { ModuleSlot::Module(module) => module, ModuleSlot::Err(err) => { error!("{}: {}", colors::red_bold("error"), err.to_string()); std::process::exit(1); } _ => unreachable!(), }; let mut deps = Vec::new(); let mut total_size = None; if not_seen { let mut seen_deps = HashSet::new(); // TODO(@kitsonk) https://github.com/denoland/deno/issues/7927 for (_, dep) in module.dependencies.iter() { // Check the runtime code dependency if let Some(code_dep) = &dep.maybe_code { if seen_deps.insert(code_dep.clone()) { deps.push(self.get_info(code_dep, seen, totals)); } } } deps.sort(); total_size = if let Some(total) = totals.get(specifier) { Some(total.to_owned()) } else { let mut total = deps .iter() .map(|d| { if let Some(total_size) = d.total_size { total_size } else { 0 } }) .sum(); total += module.size(); totals.insert(specifier.clone(), total); Some(total) }; } ModuleInfo { deps, name: specifier.clone(), size: module.size(), total_size, } } fn get_info_map(&self) -> ModuleInfoMap { let map = self .modules .iter() .filter_map(|(specifier, module_slot)| { if let ModuleSlot::Module(module) = module_slot { let mut deps = BTreeSet::new(); for (_, dep) in module.dependencies.iter() { if let Some(code_dep) = &dep.maybe_code { deps.insert(code_dep.clone()); } if let Some(type_dep) = &dep.maybe_type { deps.insert(type_dep.clone()); } } if let Some((_, types_dep)) = &module.maybe_types { deps.insert(types_dep.clone()); } let item = ModuleInfoMapItem { deps: deps.into_iter().collect(), size: module.size(), }; Some((specifier.clone(), item)) } else { None } }) .collect(); ModuleInfoMap::new(map) } /// Retrieve a map that contains a representation of each module in the graph /// which can be used to provide code to a module loader without holding all /// the state to be able to operate on the graph. pub fn get_loadable_modules( &self, ) -> HashMap> { let mut loadable_modules: HashMap< ModuleSpecifier, Result, > = self.modules.iter().map(to_module_result).collect(); for (specifier, _) in self.redirects.iter() { if let Some(module_slot) = self.modules.get(self.resolve_specifier(specifier)) { let (_, result) = to_module_result((specifier, module_slot)); loadable_modules.insert(specifier.clone(), result); } } loadable_modules } pub fn get_media_type( &self, specifier: &ModuleSpecifier, ) -> Option { if let ModuleSlot::Module(module) = self.get_module(specifier) { Some(module.media_type) } else { None } } fn get_module(&self, specifier: &ModuleSpecifier) -> &ModuleSlot { let s = self.resolve_specifier(specifier); if let Some(module_slot) = self.modules.get(s) { module_slot } else { &ModuleSlot::None } } fn get_module_mut( &mut self, specifier: &ModuleSpecifier, ) -> Option<&mut ModuleSlot> { // this is duplicated code because `.resolve_specifier` requires an // immutable borrow, but if `.resolve_specifier` is mut, then everything // that calls it is is mut let mut s = specifier; while let Some(redirect) = self.redirects.get(s) { s = redirect; } self.modules.get_mut(s) } /// Consume graph and return list of all module specifiers contained in the /// graph. pub fn get_modules(&self) -> Vec { self.modules.keys().map(|s| s.to_owned()).collect() } /// Transform `self.roots` into something that works for `tsc`, because `tsc` /// doesn't like root names without extensions that match its expectations, /// nor does it have any concept of redirection, so we have to resolve all /// that upfront before feeding it to `tsc`. In addition, if checkJs is not /// true, we should pass all emittable files in as the roots, so that `tsc` /// type checks them and potentially emits them. fn get_root_names( &self, include_emittable: bool, ) -> Result, AnyError> { let root_names: Vec = if include_emittable { // in situations where there is `allowJs` with tsc, but not `checkJs`, // then tsc will not parse the whole module graph, meaning that any // JavaScript importing TypeScript will get ignored, meaning that those // files will not get emitted. To counter act that behavior, we will // include all modules that are emittable. let mut specifiers = HashSet::<&ModuleSpecifier>::new(); for (_, module_slot) in self.modules.iter() { if let ModuleSlot::Module(module) = module_slot { if module.media_type == MediaType::JSX || module.media_type == MediaType::TypeScript || module.media_type == MediaType::TSX { specifiers.insert(&module.specifier); } } } // We should include all the original roots as well. for specifier in self.roots.iter() { specifiers.insert(specifier); } specifiers.into_iter().cloned().collect() } else { self.roots.clone() }; let mut root_types = vec![]; for ms in root_names { // if the root module has a types specifier, we should be sending that // to tsc instead of the original specifier let specifier = self.resolve_specifier(&ms); let module = match self.get_module(specifier) { ModuleSlot::Module(module) => module, ModuleSlot::Err(error) => { // It would be great if we could just clone the error here... if let Some(class) = get_custom_error_class(error) { return Err(custom_error(class, error.to_string())); } else { panic!("unsupported ModuleSlot error"); } } _ => { panic!("missing module"); } }; let specifier = if let Some((_, types_specifier)) = &module.maybe_types { self.resolve_specifier(types_specifier) } else { specifier }; root_types.push(( // root modules can be redirects, so before we pass it to tsc we need // to resolve the redirect specifier.clone(), self.get_media_type(specifier).unwrap(), )); } Ok(root_types) } /// Get the source for a given module specifier. If the module is not part /// of the graph, the result will be `None`. pub fn get_source(&self, specifier: &ModuleSpecifier) -> Option { if let ModuleSlot::Module(module) = self.get_module(specifier) { Some(module.source.clone()) } else { None } } /// Return a structure which provides information about the module graph and /// the relationship of the modules in the graph. This structure is used to /// provide information for the `info` subcommand. pub fn info(&self) -> Result { if self.roots.is_empty() || self.roots.len() > 1 { return Err(GraphError::NotSupported(format!("Info is only supported when there is a single root module in the graph. Found: {}", self.roots.len())).into()); } let module = self.roots[0].clone(); let m = if let ModuleSlot::Module(module) = self.get_module(&module) { module } else { return Err(GraphError::MissingSpecifier(module.clone()).into()); }; let mut seen = HashSet::new(); let mut totals = HashMap::new(); let info = self.get_info(&module, &mut seen, &mut totals); let files = self.get_info_map(); let total_size = totals.get(&module).unwrap_or(&m.size()).to_owned(); let (compiled, map) = if let Some((emit_path, maybe_map_path)) = &m.maybe_emit_path { (Some(emit_path.clone()), maybe_map_path.clone()) } else { (None, None) }; let dep_count = self .modules .iter() .filter_map(|(_, m)| match m { ModuleSlot::Module(_) => Some(1), _ => None, }) .count() - 1; Ok(ModuleGraphInfo { compiled, dep_count, file_type: m.media_type, files, info, local: m.source_path.clone(), map, module, total_size, }) } /// Determines if all of the modules in the graph that require an emit have /// a valid emit. Returns `true` if all the modules have a valid emit, /// otherwise false. fn is_emit_valid(&self, config: &TsConfig) -> bool { let check_js = config.get_check_js(); let config = config.as_bytes(); self.modules.iter().all(|(_, m)| { if let ModuleSlot::Module(m) = m { let needs_emit = match m.media_type { MediaType::TypeScript | MediaType::TSX | MediaType::JSX => true, MediaType::JavaScript => check_js, _ => false, }; if needs_emit { m.is_emit_valid(&config) } else { true } } else { true } }) } /// Verify the subresource integrity of the graph based upon the optional /// lockfile, updating the lockfile with any missing resources. This will /// error if any of the resources do not match their lock status. pub fn lock(&self) { if let Some(lf) = self.maybe_lockfile.as_ref() { let mut lockfile = lf.lock().unwrap(); for (ms, module_slot) in self.modules.iter() { if let ModuleSlot::Module(module) = module_slot { let specifier = module.specifier.to_string(); let valid = lockfile.check_or_insert(&specifier, &module.source); if !valid { eprintln!( "{}", GraphError::InvalidSource(ms.clone(), lockfile.filename.clone()) ); std::process::exit(10); } } } } } /// Determines if any of the modules in the graph are required to be emitted. /// This is similar to `emit_valid()` except that the actual emit isn't /// checked to determine if it is valid. fn needs_emit(&self, config: &TsConfig) -> bool { let check_js = config.get_check_js(); self.modules.iter().any(|(_, m)| match m { ModuleSlot::Module(m) => match m.media_type { MediaType::TypeScript | MediaType::TSX | MediaType::JSX => true, MediaType::JavaScript => check_js, _ => false, }, _ => false, }) } /// Given a string specifier and a referring module specifier, provide the /// resulting module specifier and media type for the module that is part of /// the graph. /// /// # Arguments /// /// * `specifier` - The string form of the module specifier that needs to be /// resolved. /// * `referrer` - The referring `ModuleSpecifier`. /// * `prefer_types` - When resolving to a module specifier, determine if a /// type dependency is preferred over a code dependency. This is set to /// `true` when resolving module names for `tsc` as it needs the type /// dependency over the code, while other consumers do not handle type only /// dependencies. pub fn resolve( &self, specifier: &str, referrer: &ModuleSpecifier, prefer_types: bool, ) -> Result { let module = if let ModuleSlot::Module(module) = self.get_module(referrer) { module } else { return Err(GraphError::MissingSpecifier(referrer.clone()).into()); }; if !module.dependencies.contains_key(specifier) { return Err( GraphError::MissingDependency( referrer.to_owned(), specifier.to_owned(), ) .into(), ); } let dependency = module.dependencies.get(specifier).unwrap(); // If there is a @deno-types pragma that impacts the dependency, then the // maybe_type property will be set with that specifier, otherwise we use the // specifier that point to the runtime code. let resolved_specifier = if prefer_types && dependency.maybe_type.is_some() { dependency.maybe_type.clone().unwrap() } else if let Some(code_specifier) = dependency.maybe_code.clone() { code_specifier } else { return Err( GraphError::MissingDependency( referrer.to_owned(), specifier.to_owned(), ) .into(), ); }; let dep_module = if let ModuleSlot::Module(dep_module) = self.get_module(&resolved_specifier) { dep_module } else { return Err( GraphError::MissingDependency( referrer.to_owned(), resolved_specifier.to_string(), ) .into(), ); }; // In the case that there is a X-TypeScript-Types or a triple-slash types, // then the `maybe_types` specifier will be populated and we should use that // instead. let result = if prefer_types && dep_module.maybe_types.is_some() { let (_, types) = dep_module.maybe_types.clone().unwrap(); // It is possible that `types` points to a redirected specifier, so we // need to ensure it resolves to the final specifier in the graph. self.resolve_specifier(&types).clone() } else { dep_module.specifier.clone() }; Ok(result) } /// Takes a module specifier and returns the "final" specifier, accounting for /// any redirects that may have occurred. fn resolve_specifier<'a>( &'a self, specifier: &'a ModuleSpecifier, ) -> &'a ModuleSpecifier { let mut s = specifier; let mut seen = HashSet::new(); seen.insert(s.clone()); while let Some(redirect) = self.redirects.get(s) { if !seen.insert(redirect.clone()) { eprintln!("An infinite loop of module redirections detected.\n Original specifier: {}", specifier); break; } s = redirect; if seen.len() > 5 { eprintln!("An excessive number of module redirections detected.\n Original specifier: {}", specifier); break; } } s } /// Transpile (only transform) the graph, updating any emitted modules /// with the specifier handler. The result contains any performance stats /// from the compiler and optionally any user provided configuration compiler /// options that were ignored. /// /// # Arguments /// /// * `options` - A structure of options which impact how the code is /// transpiled. /// pub fn transpile( &mut self, options: TranspileOptions, ) -> Result { let start = Instant::now(); let mut ts_config = TsConfig::new(json!({ "checkJs": false, "emitDecoratorMetadata": false, "inlineSourceMap": true, "jsx": "react", "jsxFactory": "React.createElement", "jsxFragmentFactory": "React.Fragment", })); let maybe_ignored_options = ts_config.merge_tsconfig(options.maybe_config_path)?; let config = ts_config.as_bytes(); let emit_options: ast::EmitOptions = ts_config.into(); let mut emit_count = 0_u32; for (_, module_slot) in self.modules.iter_mut() { if let ModuleSlot::Module(module) = module_slot { // TODO(kitsonk) a lot of this logic should be refactored into `Module` as // we start to support other methods on the graph. Especially managing // the dirty state is something the module itself should "own". // if the module is a Dts file we should skip it if module.media_type == MediaType::Dts { continue; } // if we don't have check_js enabled, we won't touch non TypeScript or JSX // modules if !(emit_options.check_js || module.media_type == MediaType::JSX || module.media_type == MediaType::TSX || module.media_type == MediaType::TypeScript) { continue; } // skip modules that already have a valid emit if !options.reload && module.is_emit_valid(&config) { continue; } let parsed_module = module.parse()?; let emit = parsed_module.transpile(&emit_options)?; emit_count += 1; module.maybe_emit = Some(Emit::Cli(emit)); module.set_version(&config); module.is_dirty = true; } } self.flush()?; let stats = Stats(vec![ ("Files".to_string(), self.modules.len() as u32), ("Emitted".to_string(), emit_count), ("Total time".to_string(), start.elapsed().as_millis() as u32), ]); Ok(ResultInfo { diagnostics: Default::default(), loadable_modules: self.get_loadable_modules(), maybe_ignored_options, stats, }) } /// Validate that the module graph is "valid" in that there are not module /// slots that have errorred that should be available to be able to statically /// analyze. In certain situations, we can spin up tsc with an "invalid" /// graph. fn validate(&self) -> Result<(), AnyError> { fn validate_module( specifier: &ModuleSpecifier, seen: &mut HashSet, get_module: &F, ) -> Result<(), AnyError> where F: Fn(&ModuleSpecifier) -> ModuleSlot, { if seen.contains(specifier) { return Ok(()); } seen.insert(specifier.clone()); match get_module(specifier) { ModuleSlot::Err(err) => Err(anyhow!(err.to_string())), ModuleSlot::Module(module) => { for (_, dep) in module.dependencies.iter() { // a dynamic import should be skipped, because while it might not // be available to statically analyze, it might be available at // runtime. if !dep.is_dynamic { if let Some(code_specifier) = &dep.maybe_code { validate_module(code_specifier, seen, get_module)?; } if let Some(type_specifier) = &dep.maybe_type { validate_module(type_specifier, seen, get_module)?; } } } Ok(()) }, ModuleSlot::None => Err(custom_error("NotFound", format!("The specifier \"{}\" is unexpectedly not in the module graph.", specifier))), ModuleSlot::Pending => Err(custom_error("InvalidState", format!("The specifier \"{}\" is in an unexpected state in the module graph.", specifier))), } } let mut seen = HashSet::new(); for specifier in &self.roots { validate_module(specifier, &mut seen, &|s| self.get_module(s).clone())?; } Ok(()) } } impl swc_bundler::Resolve for Graph { fn resolve( &self, referrer: &swc_common::FileName, specifier: &str, ) -> Result { let referrer = if let swc_common::FileName::Custom(referrer) = referrer { ModuleSpecifier::resolve_url_or_path(referrer) .context("Cannot resolve swc FileName to a module specifier")? } else { unreachable!( "An unexpected referrer was passed when bundling: {:?}", referrer ) }; let specifier = self.resolve(specifier, &referrer, false)?; Ok(swc_common::FileName::Custom(specifier.to_string())) } } /// A structure for building a dependency graph of modules. pub struct GraphBuilder { graph: Graph, maybe_import_map: Option>>, pending: FuturesUnordered, } impl GraphBuilder { pub fn new( handler: Arc>, maybe_import_map: Option, maybe_lockfile: Option>>, ) -> Self { let internal_import_map = if let Some(import_map) = maybe_import_map { Some(Arc::new(Mutex::new(import_map))) } else { None }; GraphBuilder { graph: Graph::new(handler, maybe_lockfile), maybe_import_map: internal_import_map, pending: FuturesUnordered::new(), } } /// Add a module into the graph based on a module specifier. The module /// and any dependencies will be fetched from the handler. The module will /// also be treated as a _root_ module in the graph. pub async fn add( &mut self, specifier: &ModuleSpecifier, is_dynamic: bool, ) -> Result<(), AnyError> { self.fetch(specifier, &None, is_dynamic); loop { match self.pending.next().await { Some(Err((specifier, err))) => { self .graph .modules .insert(specifier, ModuleSlot::Err(Arc::new(err))); } Some(Ok(cached_module)) => { let is_root = &cached_module.specifier == specifier; self.visit(cached_module, is_root)?; } _ => {} } if self.pending.is_empty() { break; } } if !self.graph.roots.contains(specifier) { self.graph.roots.push(specifier.clone()); self.graph.roots_dynamic = self.graph.roots_dynamic && is_dynamic; if self.graph.maybe_tsbuildinfo.is_none() { let handler = self.graph.handler.lock().unwrap(); self.graph.maybe_tsbuildinfo = handler.get_tsbuildinfo(specifier)?; } } Ok(()) } /// Request a module to be fetched from the handler and queue up its future /// to be awaited to be resolved. fn fetch( &mut self, specifier: &ModuleSpecifier, maybe_referrer: &Option, is_dynamic: bool, ) { if !self.graph.modules.contains_key(&specifier) { self .graph .modules .insert(specifier.clone(), ModuleSlot::Pending); let mut handler = self.graph.handler.lock().unwrap(); let future = handler.fetch(specifier.clone(), maybe_referrer.clone(), is_dynamic); self.pending.push(future); } } /// Visit a module that has been fetched, hydrating the module, analyzing its /// dependencies if required, fetching those dependencies, and inserting the /// module into the graph. fn visit( &mut self, cached_module: CachedModule, is_root: bool, ) -> Result<(), AnyError> { let specifier = cached_module.specifier.clone(); let requested_specifier = cached_module.requested_specifier.clone(); let mut module = Module::new(cached_module, is_root, self.maybe_import_map.clone()); match module.media_type { MediaType::Json | MediaType::SourceMap | MediaType::TsBuildInfo | MediaType::Unknown => { return Err( GraphError::UnsupportedImportType( module.specifier, module.media_type, ) .into(), ); } _ => (), } if !module.is_parsed { let has_types = module.maybe_types.is_some(); module.parse()?; if self.maybe_import_map.is_none() { let mut handler = self.graph.handler.lock().unwrap(); handler.set_deps(&specifier, module.dependencies.clone())?; if !has_types { if let Some((types, _)) = module.maybe_types.clone() { handler.set_types(&specifier, types)?; } } } } for (_, dep) in module.dependencies.iter() { let maybe_referrer = Some(dep.location.clone()); if let Some(specifier) = dep.maybe_code.as_ref() { self.fetch(specifier, &maybe_referrer, dep.is_dynamic); } if let Some(specifier) = dep.maybe_type.as_ref() { self.fetch(specifier, &maybe_referrer, dep.is_dynamic); } } if let Some((_, specifier)) = module.maybe_types.as_ref() { self.fetch(specifier, &None, false); } if specifier != requested_specifier { self .graph .redirects .insert(requested_specifier, specifier.clone()); } self .graph .modules .insert(specifier, ModuleSlot::Module(Box::new(module))); Ok(()) } /// Move out the graph from the builder to be utilized further. An optional /// lockfile can be provided, where if the sources in the graph do not match /// the expected lockfile, an error will be logged and the process will exit. pub fn get_graph(self) -> Graph { self.graph.lock(); self.graph } } #[cfg(test)] pub mod tests { use super::*; use crate::specifier_handler::MemoryHandler; use deno_core::futures::future; use std::env; use std::fs; use std::path::PathBuf; use std::sync::Mutex; macro_rules! map ( { $($key:expr => $value:expr),+ } => { { let mut m = ::std::collections::HashMap::new(); $( m.insert($key, $value); )+ m } }; ); /// This is a testing mock for `SpecifierHandler` that uses a special file /// system renaming to mock local and remote modules as well as provides /// "spies" for the critical methods for testing purposes. #[derive(Debug, Default)] pub struct MockSpecifierHandler { pub fixtures: PathBuf, pub maybe_tsbuildinfo: Option, pub tsbuildinfo_calls: Vec<(ModuleSpecifier, String)>, pub cache_calls: Vec<(ModuleSpecifier, Emit)>, pub deps_calls: Vec<(ModuleSpecifier, DependencyMap)>, pub types_calls: Vec<(ModuleSpecifier, String)>, pub version_calls: Vec<(ModuleSpecifier, String)>, } impl MockSpecifierHandler { fn get_cache( &self, specifier: ModuleSpecifier, ) -> Result { let specifier_text = specifier .to_string() .replace(":///", "_") .replace("://", "_") .replace("/", "-"); let source_path = self.fixtures.join(specifier_text); let media_type = MediaType::from(&source_path); let source = fs::read_to_string(&source_path) .map_err(|err| (specifier.clone(), err.into()))?; let is_remote = specifier.as_url().scheme() != "file"; Ok(CachedModule { source, requested_specifier: specifier.clone(), source_path, specifier, media_type, is_remote, ..CachedModule::default() }) } } impl SpecifierHandler for MockSpecifierHandler { fn fetch( &mut self, specifier: ModuleSpecifier, _maybe_referrer: Option, _is_dynamic: bool, ) -> FetchFuture { Box::pin(future::ready(self.get_cache(specifier))) } fn get_tsbuildinfo( &self, _specifier: &ModuleSpecifier, ) -> Result, AnyError> { Ok(self.maybe_tsbuildinfo.clone()) } fn set_cache( &mut self, specifier: &ModuleSpecifier, emit: &Emit, ) -> Result<(), AnyError> { self.cache_calls.push((specifier.clone(), emit.clone())); Ok(()) } fn set_types( &mut self, specifier: &ModuleSpecifier, types: String, ) -> Result<(), AnyError> { self.types_calls.push((specifier.clone(), types)); Ok(()) } fn set_tsbuildinfo( &mut self, specifier: &ModuleSpecifier, tsbuildinfo: String, ) -> Result<(), AnyError> { self.maybe_tsbuildinfo = Some(tsbuildinfo.clone()); self .tsbuildinfo_calls .push((specifier.clone(), tsbuildinfo)); Ok(()) } fn set_deps( &mut self, specifier: &ModuleSpecifier, dependencies: DependencyMap, ) -> Result<(), AnyError> { self.deps_calls.push((specifier.clone(), dependencies)); Ok(()) } fn set_version( &mut self, specifier: &ModuleSpecifier, version: String, ) -> Result<(), AnyError> { self.version_calls.push((specifier.clone(), version)); Ok(()) } } async fn setup( specifier: ModuleSpecifier, ) -> (Graph, Arc>) { let c = PathBuf::from(env::var_os("CARGO_MANIFEST_DIR").unwrap()); let fixtures = c.join("tests/module_graph"); let handler = Arc::new(Mutex::new(MockSpecifierHandler { fixtures, ..MockSpecifierHandler::default() })); let mut builder = GraphBuilder::new(handler.clone(), None, None); builder .add(&specifier, false) .await .expect("module not inserted"); (builder.get_graph(), handler) } async fn setup_memory( specifier: ModuleSpecifier, sources: HashMap<&str, &str>, ) -> Graph { let sources: HashMap = sources .iter() .map(|(k, v)| (k.to_string(), v.to_string())) .collect(); let handler = Arc::new(Mutex::new(MemoryHandler::new(sources))); let mut builder = GraphBuilder::new(handler.clone(), None, None); builder .add(&specifier, false) .await .expect("module not inserted"); builder.get_graph() } #[test] fn test_get_version() { let doc_a = "console.log(42);"; let version_a = get_version(&doc_a, "1.2.3", b""); let doc_b = "console.log(42);"; let version_b = get_version(&doc_b, "1.2.3", b""); assert_eq!(version_a, version_b); let version_c = get_version(&doc_a, "1.2.3", b"options"); assert_ne!(version_a, version_c); let version_d = get_version(&doc_b, "1.2.3", b"options"); assert_eq!(version_c, version_d); let version_e = get_version(&doc_a, "1.2.4", b""); assert_ne!(version_a, version_e); let version_f = get_version(&doc_b, "1.2.4", b""); assert_eq!(version_e, version_f); } #[test] fn test_module_emit_valid() { let source = "console.log(42);".to_string(); let maybe_version = Some(get_version(&source, &version::deno(), b"")); let module = Module { source, maybe_version, ..Module::default() }; assert!(module.is_emit_valid(b"")); let source = "console.log(42);".to_string(); let old_source = "console.log(43);"; let maybe_version = Some(get_version(old_source, &version::deno(), b"")); let module = Module { source, maybe_version, ..Module::default() }; assert!(!module.is_emit_valid(b"")); let source = "console.log(42);".to_string(); let maybe_version = Some(get_version(&source, "0.0.0", b"")); let module = Module { source, maybe_version, ..Module::default() }; assert!(!module.is_emit_valid(b"")); let source = "console.log(42);".to_string(); let module = Module { source, ..Module::default() }; assert!(!module.is_emit_valid(b"")); } #[test] fn test_module_set_version() { let source = "console.log(42);".to_string(); let expected = Some(get_version(&source, &version::deno(), b"")); let mut module = Module { source, ..Module::default() }; assert!(module.maybe_version.is_none()); module.set_version(b""); assert_eq!(module.maybe_version, expected); } #[tokio::test] async fn test_graph_bundle() { let tests = vec![ ("file:///tests/fixture01.ts", "fixture01.out"), ("file:///tests/fixture02.ts", "fixture02.out"), ("file:///tests/fixture03.ts", "fixture03.out"), ("file:///tests/fixture04.ts", "fixture04.out"), ("file:///tests/fixture05.ts", "fixture05.out"), ("file:///tests/fixture06.ts", "fixture06.out"), ("file:///tests/fixture07.ts", "fixture07.out"), ("file:///tests/fixture08.ts", "fixture08.out"), ("file:///tests/fixture09.ts", "fixture09.out"), ("file:///tests/fixture10.ts", "fixture10.out"), ("file:///tests/fixture11.ts", "fixture11.out"), ("file:///tests/fixture12.ts", "fixture12.out"), ("file:///tests/fixture13.ts", "fixture13.out"), ("file:///tests/fixture14.ts", "fixture14.out"), ("file:///tests/fixture15.ts", "fixture15.out"), ]; let c = PathBuf::from(env::var_os("CARGO_MANIFEST_DIR").unwrap()); let fixtures = c.join("tests/bundle"); for (specifier, expected_str) in tests { let specifier = ModuleSpecifier::resolve_url_or_path(specifier).unwrap(); let handler = Arc::new(Mutex::new(MockSpecifierHandler { fixtures: fixtures.clone(), ..MockSpecifierHandler::default() })); let mut builder = GraphBuilder::new(handler.clone(), None, None); builder .add(&specifier, false) .await .expect("module not inserted"); let graph = builder.get_graph(); let (actual, stats, maybe_ignored_options) = graph .bundle(BundleOptions::default()) .expect("could not bundle"); assert_eq!(stats.0.len(), 2); assert_eq!(maybe_ignored_options, None); let expected_path = fixtures.join(expected_str); let expected = fs::read_to_string(expected_path).unwrap(); assert_eq!(actual, expected, "fixture: {}", specifier); } } #[tokio::test] async fn test_graph_check_emit() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/main.ts") .expect("could not resolve module"); let (graph, handler) = setup(specifier).await; let result_info = graph .check(CheckOptions { debug: false, emit: true, lib: TypeLib::DenoWindow, maybe_config_path: None, reload: false, }) .expect("should have checked"); assert!(result_info.maybe_ignored_options.is_none()); assert_eq!(result_info.stats.0.len(), 12); assert!(result_info.diagnostics.is_empty()); let h = handler.lock().unwrap(); assert_eq!(h.cache_calls.len(), 2); assert_eq!(h.tsbuildinfo_calls.len(), 1); } #[tokio::test] async fn test_graph_check_ignores_dynamic_import_errors() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/dynamicimport.ts") .expect("could not resolve module"); let (graph, _) = setup(specifier).await; let result_info = graph .check(CheckOptions { debug: false, emit: false, lib: TypeLib::DenoWindow, maybe_config_path: None, reload: false, }) .expect("should have checked"); assert!(result_info.diagnostics.is_empty()); } #[tokio::test] async fn fix_graph_check_emit_diagnostics() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/diag.ts") .expect("could not resolve module"); let (graph, handler) = setup(specifier).await; let result_info = graph .check(CheckOptions { debug: false, emit: true, lib: TypeLib::DenoWindow, maybe_config_path: None, reload: false, }) .expect("should have checked"); assert!(result_info.maybe_ignored_options.is_none()); assert_eq!(result_info.stats.0.len(), 12); assert!(!result_info.diagnostics.is_empty()); let h = handler.lock().unwrap(); // we shouldn't cache any files or write out tsbuildinfo if there are // diagnostic errors assert_eq!(h.cache_calls.len(), 0); assert_eq!(h.tsbuildinfo_calls.len(), 0); } #[tokio::test] async fn test_graph_check_no_emit() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/main.ts") .expect("could not resolve module"); let (graph, handler) = setup(specifier).await; let result_info = graph .check(CheckOptions { debug: false, emit: false, lib: TypeLib::DenoWindow, maybe_config_path: None, reload: false, }) .expect("should have checked"); assert!(result_info.maybe_ignored_options.is_none()); assert_eq!(result_info.stats.0.len(), 12); assert!(result_info.diagnostics.is_empty()); let h = handler.lock().unwrap(); assert_eq!(h.cache_calls.len(), 0); assert_eq!(h.tsbuildinfo_calls.len(), 1); } #[tokio::test] async fn fix_graph_check_mjs_root() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/a.mjs") .expect("could not resolve module"); let (graph, handler) = setup(specifier).await; let result_info = graph .check(CheckOptions { debug: false, emit: true, lib: TypeLib::DenoWindow, maybe_config_path: None, reload: false, }) .expect("should have checked"); assert!(result_info.maybe_ignored_options.is_none()); assert!(result_info.diagnostics.is_empty()); let h = handler.lock().unwrap(); assert_eq!(h.cache_calls.len(), 1); assert_eq!(h.tsbuildinfo_calls.len(), 1); } #[tokio::test] async fn fix_graph_check_types_root() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///typesref.js") .expect("could not resolve module"); let (graph, _) = setup(specifier).await; let result_info = graph .check(CheckOptions { debug: false, emit: false, lib: TypeLib::DenoWindow, maybe_config_path: None, reload: false, }) .expect("should have checked"); assert!(result_info.diagnostics.is_empty()); } #[tokio::test] async fn test_graph_check_user_config() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/checkwithconfig.ts") .expect("could not resolve module"); let (graph, handler) = setup(specifier.clone()).await; let result_info = graph .check(CheckOptions { debug: false, emit: true, lib: TypeLib::DenoWindow, maybe_config_path: Some( "tests/module_graph/tsconfig_01.json".to_string(), ), reload: true, }) .expect("should have checked"); assert!(result_info.maybe_ignored_options.is_none()); assert!(result_info.diagnostics.is_empty()); let (ver0, ver1) = { let h = handler.lock().unwrap(); assert_eq!(h.version_calls.len(), 2); (h.version_calls[0].1.clone(), h.version_calls[1].1.clone()) }; // let's do it all over again to ensure that the versions are determinstic let (graph, handler) = setup(specifier).await; let result_info = graph .check(CheckOptions { debug: false, emit: true, lib: TypeLib::DenoWindow, maybe_config_path: Some( "tests/module_graph/tsconfig_01.json".to_string(), ), reload: true, }) .expect("should have checked"); assert!(result_info.maybe_ignored_options.is_none()); assert!(result_info.diagnostics.is_empty()); let h = handler.lock().unwrap(); assert_eq!(h.version_calls.len(), 2); assert!(h.version_calls[0].1 == ver0 || h.version_calls[0].1 == ver1); assert!(h.version_calls[1].1 == ver0 || h.version_calls[1].1 == ver1); } #[tokio::test] async fn test_graph_emit() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///a.ts").unwrap(); let graph = setup_memory( specifier, map!( "/a.ts" => r#" import * as b from "./b.ts"; console.log(b); "#, "/b.ts" => r#" export const b = "b"; "# ), ) .await; let (emitted_files, result_info) = graph .emit(EmitOptions { check: true, bundle_type: BundleType::None, debug: false, maybe_user_config: None, }) .expect("should have emitted"); assert!(result_info.diagnostics.is_empty()); assert!(result_info.maybe_ignored_options.is_none()); assert_eq!(emitted_files.len(), 4); let out_a = emitted_files.get("file:///a.ts.js"); assert!(out_a.is_some()); let out_a = out_a.unwrap(); assert!(out_a.starts_with("import * as b from")); assert!(emitted_files.contains_key("file:///a.ts.js.map")); let out_b = emitted_files.get("file:///b.ts.js"); assert!(out_b.is_some()); let out_b = out_b.unwrap(); assert!(out_b.starts_with("export const b = \"b\";")); assert!(emitted_files.contains_key("file:///b.ts.js.map")); } #[tokio::test] async fn test_graph_emit_bundle() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///a.ts").unwrap(); let graph = setup_memory( specifier, map!( "/a.ts" => r#" import * as b from "./b.ts"; console.log(b); "#, "/b.ts" => r#" export const b = "b"; "# ), ) .await; let (emitted_files, result_info) = graph .emit(EmitOptions { check: true, bundle_type: BundleType::Esm, debug: false, maybe_user_config: None, }) .expect("should have emitted"); assert!(result_info.diagnostics.is_empty()); assert!(result_info.maybe_ignored_options.is_none()); assert_eq!(emitted_files.len(), 1); let actual = emitted_files.get("deno:///bundle.js"); assert!(actual.is_some()); let actual = actual.unwrap(); assert!(actual.contains("const b = \"b\";")); assert!(actual.contains("console.log(mod);")); } #[tokio::test] async fn fix_graph_emit_declaration() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///a.ts").unwrap(); let graph = setup_memory( specifier, map!( "/a.ts" => r#" import * as b from "./b.ts"; console.log(b); "#, "/b.ts" => r#" export const b = "b"; "# ), ) .await; let mut user_config = HashMap::::new(); user_config.insert("declaration".to_string(), json!(true)); let (emitted_files, result_info) = graph .emit(EmitOptions { check: true, bundle_type: BundleType::None, debug: false, maybe_user_config: Some(user_config), }) .expect("should have emitted"); assert!(result_info.diagnostics.is_empty()); assert!(result_info.maybe_ignored_options.is_none()); assert_eq!(emitted_files.len(), 6); let out_a = emitted_files.get("file:///a.ts.js"); assert!(out_a.is_some()); let out_a = out_a.unwrap(); assert!(out_a.starts_with("import * as b from")); assert!(emitted_files.contains_key("file:///a.ts.js.map")); assert!(emitted_files.contains_key("file:///a.ts.d.ts")); let out_b = emitted_files.get("file:///b.ts.js"); assert!(out_b.is_some()); let out_b = out_b.unwrap(); assert!(out_b.starts_with("export const b = \"b\";")); assert!(emitted_files.contains_key("file:///b.ts.js.map")); assert!(emitted_files.contains_key("file:///b.ts.d.ts")); } #[tokio::test] async fn test_graph_info() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/main.ts") .expect("could not resolve module"); let (graph, _) = setup(specifier).await; let info = graph.info().expect("could not get info"); assert!(info.compiled.is_none()); assert_eq!(info.dep_count, 6); assert_eq!(info.file_type, MediaType::TypeScript); assert_eq!(info.files.0.len(), 7); assert!(info.local.to_string_lossy().ends_with("file_tests-main.ts")); assert!(info.map.is_none()); assert_eq!( info.module, ModuleSpecifier::resolve_url_or_path("file:///tests/main.ts").unwrap() ); assert_eq!(info.total_size, 344); } #[tokio::test] async fn test_graph_import_json() { let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/importjson.ts") .expect("could not resolve module"); let c = PathBuf::from(env::var_os("CARGO_MANIFEST_DIR").unwrap()); let fixtures = c.join("tests/module_graph"); let handler = Arc::new(Mutex::new(MockSpecifierHandler { fixtures, ..MockSpecifierHandler::default() })); let mut builder = GraphBuilder::new(handler.clone(), None, None); builder .add(&specifier, false) .await .expect_err("should have errored"); } #[tokio::test] async fn test_graph_transpile() { // This is a complex scenario of transpiling, where we have TypeScript // importing a JavaScript file (with type definitions) which imports // TypeScript, JavaScript, and JavaScript with type definitions. // For scenarios where we transpile, we only want the TypeScript files // to be actually emitted. // // This also exercises "@deno-types" and type references. let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/main.ts") .expect("could not resolve module"); let (mut graph, handler) = setup(specifier).await; let result_info = graph.transpile(TranspileOptions::default()).unwrap(); assert_eq!(result_info.stats.0.len(), 3); assert_eq!(result_info.maybe_ignored_options, None); let h = handler.lock().unwrap(); assert_eq!(h.cache_calls.len(), 2); match &h.cache_calls[0].1 { Emit::Cli((code, maybe_map)) => { assert!( code.contains("# sourceMappingURL=data:application/json;base64,") ); assert!(maybe_map.is_none()); } }; match &h.cache_calls[1].1 { Emit::Cli((code, maybe_map)) => { assert!( code.contains("# sourceMappingURL=data:application/json;base64,") ); assert!(maybe_map.is_none()); } }; assert_eq!(h.deps_calls.len(), 7); assert_eq!( h.deps_calls[0].0, ModuleSpecifier::resolve_url_or_path("file:///tests/main.ts").unwrap() ); assert_eq!(h.deps_calls[0].1.len(), 1); assert_eq!( h.deps_calls[1].0, ModuleSpecifier::resolve_url_or_path("https://deno.land/x/lib/mod.js") .unwrap() ); assert_eq!(h.deps_calls[1].1.len(), 3); assert_eq!( h.deps_calls[2].0, ModuleSpecifier::resolve_url_or_path("https://deno.land/x/lib/mod.d.ts") .unwrap() ); assert_eq!(h.deps_calls[2].1.len(), 3, "should have 3 dependencies"); // sometimes the calls are not deterministic, and so checking the contents // can cause some failures assert_eq!(h.deps_calls[3].1.len(), 0, "should have no dependencies"); assert_eq!(h.deps_calls[4].1.len(), 0, "should have no dependencies"); assert_eq!(h.deps_calls[5].1.len(), 0, "should have no dependencies"); assert_eq!(h.deps_calls[6].1.len(), 0, "should have no dependencies"); } #[tokio::test] async fn test_graph_transpile_user_config() { let specifier = ModuleSpecifier::resolve_url_or_path("https://deno.land/x/transpile.tsx") .expect("could not resolve module"); let (mut graph, handler) = setup(specifier).await; let result_info = graph .transpile(TranspileOptions { debug: false, maybe_config_path: Some("tests/module_graph/tsconfig.json".to_string()), reload: false, }) .unwrap(); assert_eq!( result_info.maybe_ignored_options.unwrap().items, vec!["target".to_string()], "the 'target' options should have been ignored" ); let h = handler.lock().unwrap(); assert_eq!(h.cache_calls.len(), 1, "only one file should be emitted"); // FIXME(bartlomieju): had to add space in `
`, probably a quirk in swc_ecma_codegen match &h.cache_calls[0].1 { Emit::Cli((code, _)) => { assert!( code.contains("
Hello world!
"), "jsx should have been preserved" ); } } } #[tokio::test] async fn test_graph_import_map_remote_to_local() { let c = PathBuf::from(env::var_os("CARGO_MANIFEST_DIR").unwrap()); let fixtures = c.join("tests/module_graph"); let maybe_import_map = Some( ImportMap::from_json( "file:///tests/importmap.json", r#"{ "imports": { "https://deno.land/x/b/mod.js": "./b/mod.js" } } "#, ) .expect("could not parse import map"), ); let handler = Arc::new(Mutex::new(MockSpecifierHandler { fixtures, ..Default::default() })); let mut builder = GraphBuilder::new(handler, maybe_import_map, None); let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/importremap.ts") .expect("could not resolve module"); builder.add(&specifier, false).await.expect("could not add"); builder.get_graph(); } #[tokio::test] async fn test_graph_with_lockfile() { let c = PathBuf::from(env::var_os("CARGO_MANIFEST_DIR").unwrap()); let fixtures = c.join("tests/module_graph"); let lockfile_path = fixtures.join("lockfile.json"); let lockfile = Lockfile::new(lockfile_path, false).expect("could not load lockfile"); let maybe_lockfile = Some(Arc::new(Mutex::new(lockfile))); let handler = Arc::new(Mutex::new(MockSpecifierHandler { fixtures, ..MockSpecifierHandler::default() })); let mut builder = GraphBuilder::new(handler.clone(), None, maybe_lockfile); let specifier = ModuleSpecifier::resolve_url_or_path("file:///tests/main.ts") .expect("could not resolve module"); builder .add(&specifier, false) .await .expect("module not inserted"); builder.get_graph(); } }