// Copyright 2018-2020 the Deno authors. All rights reserved. MIT license. // This module is the entry point for "compiler" isolate, ie. the one // that is created when Deno needs to compile TS/WASM to JS. // // It provides two functions that should be called by Rust: // - `bootstrapCompilerRuntime` // This functions must be called when creating isolate // to properly setup runtime. // - `tsCompilerOnMessage` // This function must be called when sending a request // to the compiler. // Removes the `__proto__` for security reasons. This intentionally makes // Deno non compliant with ECMA-262 Annex B.2.2.1 // delete Object.prototype.__proto__; ((window) => { const core = window.Deno.core; let logDebug = false; let logSource = "JS"; function setLogDebug(debug, source) { logDebug = debug; if (source) { logSource = source; } } function log(...args) { if (logDebug) { const stringifiedArgs = args.map(JSON.stringify).join(" "); core.print(`DEBUG ${logSource} - ${stringifiedArgs}\n`); } } class AssertionError extends Error { constructor(msg) { super(msg); this.name = "AssertionError"; } } function assert(cond, msg = "Assertion failed.") { if (!cond) { throw new AssertionError(msg); } } function notImplemented() { throw new Error("not implemented"); } /** * @param {import("../dts/typescript").DiagnosticRelatedInformation} diagnostic */ function fromRelatedInformation({ start, length, file, messageText: msgText, ...ri }) { let messageText; let messageChain; if (typeof msgText === "object") { messageChain = msgText; } else { messageText = msgText; } if (start !== undefined && length !== undefined && file) { const startPos = file.getLineAndCharacterOfPosition(start); const sourceLine = file.getFullText().split("\n")[startPos.line]; const fileName = file.fileName; return { start: startPos, end: file.getLineAndCharacterOfPosition(start + length), fileName, messageChain, messageText, sourceLine, ...ri, }; } else { return { messageChain, messageText, ...ri, }; } } /** * @param {import("../dts/typescript").Diagnostic[]} diagnostics */ function fromTypeScriptDiagnostic(diagnostics) { return diagnostics.map(({ relatedInformation: ri, source, ...diag }) => { const value = fromRelatedInformation(diag); value.relatedInformation = ri ? ri.map(fromRelatedInformation) : undefined; value.source = source; return value; }); } function opNow() { const res = core.jsonOpSync("op_now"); return res.seconds * 1e3 + res.subsecNanos / 1e6; } // We really don't want to depend on JSON dispatch during snapshotting, so // this op exchanges strings with Rust as raw byte arrays. function getAsset(name) { const opId = core.ops()["op_fetch_asset"]; const sourceCodeBytes = core.dispatch(opId, core.encode(name)); return core.decode(sourceCodeBytes); } // Constants used by `normalizeString` and `resolvePath` const CHAR_DOT = 46; /* . */ const CHAR_FORWARD_SLASH = 47; /* / */ // Using incremental compile APIs requires that all // paths must be either relative or absolute. Since // analysis in Rust operates on fully resolved URLs, // it makes sense to use the same scheme here. const ASSETS = "asset://"; const OUT_DIR = "deno://"; const CACHE = "cache:///"; // This constant is passed to compiler settings when // doing incremental compiles. Contents of this // file are passed back to Rust and saved to $DENO_DIR. const TS_BUILD_INFO = "cache:///tsbuildinfo.json"; const DEFAULT_COMPILE_OPTIONS = { allowJs: false, allowNonTsExtensions: true, checkJs: false, esModuleInterop: true, jsx: ts.JsxEmit.React, module: ts.ModuleKind.ESNext, outDir: OUT_DIR, sourceMap: true, strict: true, removeComments: true, target: ts.ScriptTarget.ESNext, }; const CompilerHostTarget = { Main: "main", Runtime: "runtime", Worker: "worker", }; // Warning! The values in this enum are duplicated in `cli/msg.rs` // Update carefully! const MediaType = { 0: "JavaScript", 1: "JSX", 2: "TypeScript", 3: "Dts", 4: "TSX", 5: "Json", 6: "Wasm", 7: "BuildInfo", 8: "Unknown", JavaScript: 0, JSX: 1, TypeScript: 2, Dts: 3, TSX: 4, Json: 5, Wasm: 6, BuildInfo: 7, Unknown: 6, }; function getExtension(fileName, mediaType) { switch (mediaType) { case MediaType.JavaScript: return ts.Extension.Js; case MediaType.JSX: return ts.Extension.Jsx; case MediaType.TypeScript: return fileName.endsWith(".d.ts") ? ts.Extension.Dts : ts.Extension.Ts; case MediaType.TSX: return ts.Extension.Tsx; case MediaType.Wasm: // Custom marker for Wasm type. return ts.Extension.Js; case MediaType.Unknown: default: throw TypeError( `Cannot resolve extension for "${fileName}" with mediaType "${ MediaType[mediaType] }".`, ); } } /** A global cache of module source files that have been loaded. * This cache will be rewritten to be populated on compiler startup * with files provided from Rust in request message. */ const SOURCE_FILE_CACHE = new Map(); /** A map of maps which cache resolved specifier for each import in a file. * This cache is used so `resolveModuleNames` ops is called as few times * as possible. * * First map's key is "referrer" URL ("file://a/b/c/mod.ts") * Second map's key is "raw" import specifier ("./foo.ts") * Second map's value is resolved import URL ("file:///a/b/c/foo.ts") */ const RESOLVED_SPECIFIER_CACHE = new Map(); function parseCompilerOptions(compilerOptions) { const { options, errors } = ts.convertCompilerOptionsFromJson( compilerOptions, "", "tsconfig.json", ); return { options, diagnostics: errors.length ? errors : undefined, }; } class SourceFile { constructor(json) { this.processed = false; Object.assign(this, json); this.extension = getExtension(this.url, this.mediaType); } static addToCache(json) { if (SOURCE_FILE_CACHE.has(json.url)) { throw new TypeError("SourceFile already exists"); } const sf = new SourceFile(json); SOURCE_FILE_CACHE.set(sf.url, sf); return sf; } static getCached(url) { return SOURCE_FILE_CACHE.get(url); } static cacheResolvedUrl(resolvedUrl, rawModuleSpecifier, containingFile) { containingFile = containingFile || ""; let innerCache = RESOLVED_SPECIFIER_CACHE.get(containingFile); if (!innerCache) { innerCache = new Map(); RESOLVED_SPECIFIER_CACHE.set(containingFile, innerCache); } innerCache.set(rawModuleSpecifier, resolvedUrl); } static getResolvedUrl(moduleSpecifier, containingFile) { const containingCache = RESOLVED_SPECIFIER_CACHE.get(containingFile); if (containingCache) { return containingCache.get(moduleSpecifier); } return undefined; } } function getAssetInternal(filename) { const lastSegment = filename.split("/").pop(); const url = ts.libMap.has(lastSegment) ? ts.libMap.get(lastSegment) : lastSegment; const sourceFile = SourceFile.getCached(url); if (sourceFile) { return sourceFile; } const name = url.includes(".") ? url : `${url}.d.ts`; const sourceCode = getAsset(name); return SourceFile.addToCache({ url, filename: `${ASSETS}/${name}`, mediaType: MediaType.TypeScript, versionHash: "1", sourceCode, }); } class Host { #options; #target; #writeFile; /* Deno specific APIs */ constructor( options, target, writeFile, ) { this.#target = target; this.#writeFile = writeFile; this.#options = options; } get options() { return this.#options; } /* TypeScript CompilerHost APIs */ fileExists(fileName) { log(`compiler::host.fileExists("${fileName}")`); return false; } getCanonicalFileName(fileName) { return fileName; } getCompilationSettings() { log("compiler::host.getCompilationSettings()"); return this.#options; } getCurrentDirectory() { return CACHE; } getDefaultLibFileName(_options) { log("compiler::host.getDefaultLibFileName()"); switch (this.#target) { case CompilerHostTarget.Main: case CompilerHostTarget.Runtime: return `${ASSETS}/lib.deno.window.d.ts`; case CompilerHostTarget.Worker: return `${ASSETS}/lib.deno.worker.d.ts`; } } getNewLine() { return "\n"; } getSourceFile( fileName, languageVersion, onError, shouldCreateNewSourceFile, ) { log("compiler::host.getSourceFile", fileName); try { assert(!shouldCreateNewSourceFile); const sourceFile = fileName.startsWith(ASSETS) ? getAssetInternal(fileName) : SourceFile.getCached(fileName); assert(sourceFile != null); if (!sourceFile.tsSourceFile) { assert(sourceFile.sourceCode != null); const tsSourceFileName = fileName.startsWith(ASSETS) ? sourceFile.filename : fileName; sourceFile.tsSourceFile = ts.createSourceFile( tsSourceFileName, sourceFile.sourceCode, languageVersion, ); sourceFile.tsSourceFile.version = sourceFile.versionHash; delete sourceFile.sourceCode; } return sourceFile.tsSourceFile; } catch (e) { if (onError) { onError(String(e)); } else { throw e; } return undefined; } } readFile(_fileName) { return notImplemented(); } resolveModuleNames(moduleNames, containingFile) { log("compiler::host.resolveModuleNames", { moduleNames, containingFile, }); const resolved = moduleNames.map((specifier) => { const maybeUrl = SourceFile.getResolvedUrl(specifier, containingFile); log("compiler::host.resolveModuleNames maybeUrl", { specifier, maybeUrl, }); let sourceFile = undefined; if (specifier.startsWith(ASSETS)) { sourceFile = getAssetInternal(specifier); } else if (typeof maybeUrl !== "undefined") { sourceFile = SourceFile.getCached(maybeUrl); } if (!sourceFile) { return undefined; } return { resolvedFileName: sourceFile.url, isExternalLibraryImport: specifier.startsWith(ASSETS), extension: sourceFile.extension, }; }); log(resolved); return resolved; } useCaseSensitiveFileNames() { return true; } writeFile(fileName, data, _writeByteOrderMark, _onError, sourceFiles) { log("compiler::host.writeFile", fileName); this.#writeFile(fileName, data, sourceFiles); } } class IncrementalCompileHost extends Host { #buildInfo = ""; constructor( options, target, writeFile, buildInfo, ) { super(options, target, writeFile); if (buildInfo) { this.#buildInfo = buildInfo; } } readFile(fileName) { if (fileName == TS_BUILD_INFO) { return this.#buildInfo; } throw new Error("unreachable"); } } // NOTE: target doesn't really matter here, // this is in fact a mock host created just to // load all type definitions and snapshot them. let SNAPSHOT_HOST = new Host( DEFAULT_COMPILE_OPTIONS, CompilerHostTarget.Main, () => {}, ); const SNAPSHOT_COMPILER_OPTIONS = SNAPSHOT_HOST.getCompilationSettings(); // This is a hacky way of adding our libs to the libs available in TypeScript() // as these are internal APIs of TypeScript which maintain valid libs ts.libs.push("deno.ns", "deno.window", "deno.worker", "deno.shared_globals"); ts.libMap.set("deno.ns", "lib.deno.ns.d.ts"); ts.libMap.set("deno.web", "lib.deno.web.d.ts"); ts.libMap.set("deno.fetch", "lib.deno.fetch.d.ts"); ts.libMap.set("deno.window", "lib.deno.window.d.ts"); ts.libMap.set("deno.worker", "lib.deno.worker.d.ts"); ts.libMap.set("deno.shared_globals", "lib.deno.shared_globals.d.ts"); ts.libMap.set("deno.unstable", "lib.deno.unstable.d.ts"); // this pre-populates the cache at snapshot time of our library files, so they // are available in the future when needed. SNAPSHOT_HOST.getSourceFile( `${ASSETS}/lib.deno.ns.d.ts`, ts.ScriptTarget.ESNext, ); SNAPSHOT_HOST.getSourceFile( `${ASSETS}/lib.deno.web.d.ts`, ts.ScriptTarget.ESNext, ); SNAPSHOT_HOST.getSourceFile( `${ASSETS}/lib.deno.fetch.d.ts`, ts.ScriptTarget.ESNext, ); SNAPSHOT_HOST.getSourceFile( `${ASSETS}/lib.deno.window.d.ts`, ts.ScriptTarget.ESNext, ); SNAPSHOT_HOST.getSourceFile( `${ASSETS}/lib.deno.worker.d.ts`, ts.ScriptTarget.ESNext, ); SNAPSHOT_HOST.getSourceFile( `${ASSETS}/lib.deno.shared_globals.d.ts`, ts.ScriptTarget.ESNext, ); SNAPSHOT_HOST.getSourceFile( `${ASSETS}/lib.deno.unstable.d.ts`, ts.ScriptTarget.ESNext, ); // We never use this program; it's only created // during snapshotting to hydrate and populate // source file cache with lib declaration files. const _TS_SNAPSHOT_PROGRAM = ts.createProgram({ rootNames: [`${ASSETS}/bootstrap.ts`], options: SNAPSHOT_COMPILER_OPTIONS, host: SNAPSHOT_HOST, }); // Derference the snapshot host so it can be GCed SNAPSHOT_HOST = undefined; // This function is called only during snapshotting process const SYSTEM_LOADER = getAsset("system_loader.js"); const SYSTEM_LOADER_ES5 = getAsset("system_loader_es5.js"); function buildLocalSourceFileCache(sourceFileMap) { for (const entry of Object.values(sourceFileMap)) { assert(entry.sourceCode.length > 0); SourceFile.addToCache({ url: entry.url, filename: entry.url, mediaType: entry.mediaType, sourceCode: entry.sourceCode, versionHash: entry.versionHash, }); for (const importDesc of entry.imports) { let mappedUrl = importDesc.resolvedSpecifier; const importedFile = sourceFileMap[importDesc.resolvedSpecifier]; assert(importedFile); const isJsOrJsx = importedFile.mediaType === MediaType.JavaScript || importedFile.mediaType === MediaType.JSX; // If JS or JSX perform substitution for types if available if (isJsOrJsx) { // @deno-types has highest precedence, followed by // X-TypeScript-Types header if (importDesc.resolvedTypeDirective) { mappedUrl = importDesc.resolvedTypeDirective; } else if (importedFile.typeHeaders.length > 0) { const typeHeaders = importedFile.typeHeaders[0]; mappedUrl = typeHeaders.resolvedSpecifier; } else if (importedFile.typesDirectives.length > 0) { const typeDirective = importedFile.typesDirectives[0]; mappedUrl = typeDirective.resolvedSpecifier; } } mappedUrl = mappedUrl.replace("memory://", ""); SourceFile.cacheResolvedUrl(mappedUrl, importDesc.specifier, entry.url); } for (const fileRef of entry.referencedFiles) { SourceFile.cacheResolvedUrl( fileRef.resolvedSpecifier.replace("memory://", ""), fileRef.specifier, entry.url, ); } for (const fileRef of entry.libDirectives) { SourceFile.cacheResolvedUrl( fileRef.resolvedSpecifier.replace("memory://", ""), fileRef.specifier, entry.url, ); } } } function buildSourceFileCache(sourceFileMap) { for (const entry of Object.values(sourceFileMap)) { SourceFile.addToCache({ url: entry.url, filename: entry.url, mediaType: entry.mediaType, sourceCode: entry.sourceCode, versionHash: entry.versionHash, }); for (const importDesc of entry.imports) { let mappedUrl = importDesc.resolvedSpecifier; const importedFile = sourceFileMap[importDesc.resolvedSpecifier]; // IMPORTANT: due to HTTP redirects we might end up in situation // where URL points to a file with completely different URL. // In that case we take value of `redirect` field and cache // resolved specifier pointing to the value of the redirect. // It's not very elegant solution and should be rethinked. assert(importedFile); if (importedFile.redirect) { mappedUrl = importedFile.redirect; } const isJsOrJsx = importedFile.mediaType === MediaType.JavaScript || importedFile.mediaType === MediaType.JSX; // If JS or JSX perform substitution for types if available if (isJsOrJsx) { // @deno-types has highest precedence, followed by // X-TypeScript-Types header if (importDesc.resolvedTypeDirective) { mappedUrl = importDesc.resolvedTypeDirective; } else if (importedFile.typeHeaders.length > 0) { const typeHeaders = importedFile.typeHeaders[0]; mappedUrl = typeHeaders.resolvedSpecifier; } else if (importedFile.typesDirectives.length > 0) { const typeDirective = importedFile.typesDirectives[0]; mappedUrl = typeDirective.resolvedSpecifier; } } SourceFile.cacheResolvedUrl(mappedUrl, importDesc.specifier, entry.url); } for (const fileRef of entry.referencedFiles) { SourceFile.cacheResolvedUrl( fileRef.resolvedSpecifier, fileRef.specifier, entry.url, ); } for (const fileRef of entry.libDirectives) { SourceFile.cacheResolvedUrl( fileRef.resolvedSpecifier, fileRef.specifier, entry.url, ); } } } // Warning! The values in this enum are duplicated in `cli/msg.rs` // Update carefully! const CompilerRequestType = { Compile: 0, Bundle: 1, RuntimeCompile: 2, RuntimeBundle: 3, RuntimeTranspile: 4, }; function createBundleWriteFile(state) { return function writeFile(_fileName, data, sourceFiles) { assert(sourceFiles != null); assert(state.host); // we only support single root names for bundles assert(state.rootNames.length === 1); state.bundleOutput = buildBundle( state.rootNames[0], data, sourceFiles, state.host.options.target ?? ts.ScriptTarget.ESNext, ); }; } function createCompileWriteFile(state) { return function writeFile(fileName, data, sourceFiles) { const isBuildInfo = fileName === TS_BUILD_INFO; if (isBuildInfo) { assert(isBuildInfo); state.buildInfo = data; return; } assert(sourceFiles); assert(sourceFiles.length === 1); state.emitMap[fileName] = { filename: sourceFiles[0].fileName, contents: data, }; }; } function createRuntimeCompileWriteFile(state) { return function writeFile(fileName, data, sourceFiles) { assert(sourceFiles); assert(sourceFiles.length === 1); state.emitMap[fileName] = { filename: sourceFiles[0].fileName, contents: data, }; }; } const IGNORED_DIAGNOSTICS = [ // TS2306: File 'file:///Users/rld/src/deno/cli/tests/subdir/amd_like.js' is // not a module. 2306, // TS1375: 'await' expressions are only allowed at the top level of a file // when that file is a module, but this file has no imports or exports. // Consider adding an empty 'export {}' to make this file a module. 1375, // TS1103: 'for-await-of' statement is only allowed within an async function // or async generator. 1103, // TS2691: An import path cannot end with a '.ts' extension. Consider // importing 'bad-module' instead. 2691, // TS5009: Cannot find the common subdirectory path for the input files. 5009, // TS5055: Cannot write file // 'http://localhost:4545/cli/tests/subdir/mt_application_x_javascript.j4.js' // because it would overwrite input file. 5055, // TypeScript is overly opinionated that only CommonJS modules kinds can // support JSON imports. Allegedly this was fixed in // Microsoft/TypeScript#26825 but that doesn't seem to be working here, // so we will ignore complaints about this compiler setting. 5070, // TS7016: Could not find a declaration file for module '...'. '...' // implicitly has an 'any' type. This is due to `allowJs` being off by // default but importing of a JavaScript module. 7016, ]; const IGNORED_COMPILE_DIAGNOSTICS = [ // TS1208: All files must be modules when the '--isolatedModules' flag is // provided. We can ignore because we guarantuee that all files are // modules. 1208, ]; const stats = []; let statsStart = 0; function performanceStart() { stats.length = 0; // TODO(kitsonk) replace with performance.mark() when landed statsStart = opNow(); ts.performance.enable(); } function performanceProgram({ program, fileCount }) { if (program) { if ("getProgram" in program) { program = program.getProgram(); } stats.push({ key: "Files", value: program.getSourceFiles().length }); stats.push({ key: "Nodes", value: program.getNodeCount() }); stats.push({ key: "Identifiers", value: program.getIdentifierCount() }); stats.push({ key: "Symbols", value: program.getSymbolCount() }); stats.push({ key: "Types", value: program.getTypeCount() }); stats.push({ key: "Instantiations", value: program.getInstantiationCount(), }); } else if (fileCount != null) { stats.push({ key: "Files", value: fileCount }); } const programTime = ts.performance.getDuration("Program"); const bindTime = ts.performance.getDuration("Bind"); const checkTime = ts.performance.getDuration("Check"); const emitTime = ts.performance.getDuration("Emit"); stats.push({ key: "Parse time", value: programTime }); stats.push({ key: "Bind time", value: bindTime }); stats.push({ key: "Check time", value: checkTime }); stats.push({ key: "Emit time", value: emitTime }); stats.push({ key: "Total TS time", value: programTime + bindTime + checkTime + emitTime, }); } function performanceEnd() { // TODO(kitsonk) replace with performance.measure() when landed const duration = opNow() - statsStart; stats.push({ key: "Compile time", value: duration }); return stats; } function normalizeString(path) { let res = ""; let lastSegmentLength = 0; let lastSlash = -1; let dots = 0; let code; for (let i = 0, len = path.length; i <= len; ++i) { if (i < len) code = path.charCodeAt(i); else if (code === CHAR_FORWARD_SLASH) break; else code = CHAR_FORWARD_SLASH; if (code === CHAR_FORWARD_SLASH) { if (lastSlash === i - 1 || dots === 1) { // NOOP } else if (lastSlash !== i - 1 && dots === 2) { if ( res.length < 2 || lastSegmentLength !== 2 || res.charCodeAt(res.length - 1) !== CHAR_DOT || res.charCodeAt(res.length - 2) !== CHAR_DOT ) { if (res.length > 2) { const lastSlashIndex = res.lastIndexOf("/"); if (lastSlashIndex === -1) { res = ""; lastSegmentLength = 0; } else { res = res.slice(0, lastSlashIndex); lastSegmentLength = res.length - 1 - res.lastIndexOf("/"); } lastSlash = i; dots = 0; continue; } else if (res.length === 2 || res.length === 1) { res = ""; lastSegmentLength = 0; lastSlash = i; dots = 0; continue; } } } else { if (res.length > 0) res += "/" + path.slice(lastSlash + 1, i); else res = path.slice(lastSlash + 1, i); lastSegmentLength = i - lastSlash - 1; } lastSlash = i; dots = 0; } else if (code === CHAR_DOT && dots !== -1) { ++dots; } else { dots = -1; } } return res; } function commonPath(paths, sep = "/") { const [first = "", ...remaining] = paths; if (first === "" || remaining.length === 0) { return first.substring(0, first.lastIndexOf(sep) + 1); } const parts = first.split(sep); let endOfPrefix = parts.length; for (const path of remaining) { const compare = path.split(sep); for (let i = 0; i < endOfPrefix; i++) { if (compare[i] !== parts[i]) { endOfPrefix = i; } } if (endOfPrefix === 0) { return ""; } } const prefix = parts.slice(0, endOfPrefix).join(sep); return prefix.endsWith(sep) ? prefix : `${prefix}${sep}`; } let rootExports; function normalizeUrl(rootName) { const match = /^(\S+:\/{2,3})(.+)$/.exec(rootName); if (match) { const [, protocol, path] = match; return `${protocol}${normalizeString(path)}`; } else { return rootName; } } function buildBundle(rootName, data, sourceFiles, target) { // when outputting to AMD and a single outfile, TypeScript makes up the module // specifiers which are used to define the modules, and doesn't expose them // publicly, so we have to try to replicate const sources = sourceFiles.map((sf) => sf.fileName); const sharedPath = commonPath(sources); rootName = normalizeUrl(rootName) .replace(sharedPath, "") .replace(/\.\w+$/i, ""); // If one of the modules requires support for top-level-await, TypeScript will // emit the execute function as an async function. When this is the case we // need to bubble up the TLA to the instantiation, otherwise we instantiate // synchronously. const hasTla = data.match(/execute:\sasync\sfunction\s/); let instantiate; if (rootExports && rootExports.length) { instantiate = hasTla ? `const __exp = await __instantiate("${rootName}", true);\n` : `const __exp = __instantiate("${rootName}", false);\n`; for (const rootExport of rootExports) { if (rootExport === "default") { instantiate += `export default __exp["${rootExport}"];\n`; } else { instantiate += `export const ${rootExport} = __exp["${rootExport}"];\n`; } } } else { instantiate = hasTla ? `await __instantiate("${rootName}", true);\n` : `__instantiate("${rootName}", false);\n`; } const es5Bundle = target === ts.ScriptTarget.ES3 || target === ts.ScriptTarget.ES5 || target === ts.ScriptTarget.ES2015 || target === ts.ScriptTarget.ES2016; return `${ es5Bundle ? SYSTEM_LOADER_ES5 : SYSTEM_LOADER }\n${data}\n${instantiate}`; } function setRootExports(program, rootModule) { // get a reference to the type checker, this will let us find symbols from // the AST. const checker = program.getTypeChecker(); // get a reference to the main source file for the bundle const mainSourceFile = program.getSourceFile(rootModule); assert(mainSourceFile); // retrieve the internal TypeScript symbol for this AST node const mainSymbol = checker.getSymbolAtLocation(mainSourceFile); if (!mainSymbol) { return; } rootExports = checker .getExportsOfModule(mainSymbol) // .getExportsOfModule includes type only symbols which are exported from // the module, so we need to try to filter those out. While not critical // someone looking at the bundle would think there is runtime code behind // that when there isn't. There appears to be no clean way of figuring that // out, so inspecting SymbolFlags that might be present that are type only .filter( (sym) => sym.flags & ts.SymbolFlags.Class || !( sym.flags & ts.SymbolFlags.Interface || sym.flags & ts.SymbolFlags.TypeLiteral || sym.flags & ts.SymbolFlags.Signature || sym.flags & ts.SymbolFlags.TypeParameter || sym.flags & ts.SymbolFlags.TypeAlias || sym.flags & ts.SymbolFlags.Type || sym.flags & ts.SymbolFlags.Namespace || sym.flags & ts.SymbolFlags.InterfaceExcludes || sym.flags & ts.SymbolFlags.TypeParameterExcludes || sym.flags & ts.SymbolFlags.TypeAliasExcludes ), ) .map((sym) => sym.getName()); } function compile({ buildInfo, compilerOptions, rootNames, target, sourceFileMap, type, performance, }) { if (performance) { performanceStart(); } log(">>> compile start", { rootNames, type: CompilerRequestType[type] }); // When a programme is emitted, TypeScript will call `writeFile` with // each file that needs to be emitted. The Deno compiler host delegates // this, to make it easier to perform the right actions, which vary // based a lot on the request. const state = { rootNames, emitMap: {}, }; let diagnostics = []; const { options, diagnostics: diags } = parseCompilerOptions( compilerOptions, ); diagnostics = diags.filter( ({ code }) => code != 5023 && !IGNORED_DIAGNOSTICS.includes(code), ); // TODO(bartlomieju): this options is excluded by `ts.convertCompilerOptionsFromJson` // however stuff breaks if it's not passed (type_directives_js_main.js, compiler_js_error.ts) options.allowNonTsExtensions = true; const host = new IncrementalCompileHost( options, target, createCompileWriteFile(state), buildInfo, ); buildSourceFileCache(sourceFileMap); // if there was a configuration and no diagnostics with it, we will continue // to generate the program and possibly emit it. if (diagnostics.length === 0) { const options = host.getCompilationSettings(); const program = ts.createIncrementalProgram({ rootNames, options, host, }); // TODO(bartlomieju): check if this is ok diagnostics = [ ...program.getConfigFileParsingDiagnostics(), ...program.getSyntacticDiagnostics(), ...program.getOptionsDiagnostics(), ...program.getGlobalDiagnostics(), ...program.getSemanticDiagnostics(), ]; diagnostics = diagnostics.filter( ({ code }) => !IGNORED_DIAGNOSTICS.includes(code) && !IGNORED_COMPILE_DIAGNOSTICS.includes(code), ); // We will only proceed with the emit if there are no diagnostics. if (diagnostics.length === 0) { const emitResult = program.emit(); // If `checkJs` is off we still might be compiling entry point JavaScript file // (if it has `.ts` imports), but it won't be emitted. In that case we skip // assertion. if (options.checkJs) { assert( emitResult.emitSkipped === false, "Unexpected skip of the emit.", ); } // emitResult.diagnostics is `readonly` in TS3.5+ and can't be assigned // without casting. diagnostics = emitResult.diagnostics; } performanceProgram({ program }); } log("<<< compile end", { rootNames, type: CompilerRequestType[type] }); const stats = performance ? performanceEnd() : undefined; return { emitMap: state.emitMap, buildInfo: state.buildInfo, diagnostics: fromTypeScriptDiagnostic(diagnostics), stats, }; } function bundle({ compilerOptions, rootNames, target, sourceFileMap, type, performance, }) { if (performance) { performanceStart(); } log(">>> bundle start", { rootNames, type: CompilerRequestType[type], }); // When a programme is emitted, TypeScript will call `writeFile` with // each file that needs to be emitted. The Deno compiler host delegates // this, to make it easier to perform the right actions, which vary // based a lot on the request. const state = { rootNames, bundleOutput: undefined, }; const { options, diagnostics: diags } = parseCompilerOptions( compilerOptions, ); diagnostics = diags.filter( ({ code }) => code != 5023 && !IGNORED_DIAGNOSTICS.includes(code), ); // TODO(bartlomieju): this options is excluded by `ts.convertCompilerOptionsFromJson` // however stuff breaks if it's not passed (type_directives_js_main.js) options.allowNonTsExtensions = true; const host = new Host( options, target, createBundleWriteFile(state), ); state.host = host; buildSourceFileCache(sourceFileMap); // if there was a configuration and no diagnostics with it, we will continue // to generate the program and possibly emit it. if (diagnostics.length === 0) { const options = host.getCompilationSettings(); const program = ts.createProgram({ rootNames, options, host, }); diagnostics = ts .getPreEmitDiagnostics(program) .filter(({ code }) => !IGNORED_DIAGNOSTICS.includes(code)); // We will only proceed with the emit if there are no diagnostics. if (diagnostics.length === 0) { // we only support a single root module when bundling assert(rootNames.length === 1); setRootExports(program, rootNames[0]); const emitResult = program.emit(); assert( emitResult.emitSkipped === false, "Unexpected skip of the emit.", ); // emitResult.diagnostics is `readonly` in TS3.5+ and can't be assigned // without casting. diagnostics = emitResult.diagnostics; } if (performance) { performanceProgram({ program }); } } let bundleOutput; if (diagnostics.length === 0) { assert(state.bundleOutput); bundleOutput = state.bundleOutput; } const stats = performance ? performanceEnd() : undefined; const result = { bundleOutput, diagnostics: fromTypeScriptDiagnostic(diagnostics), stats, }; log("<<< bundle end", { rootNames, type: CompilerRequestType[type], }); return result; } function runtimeCompile(request) { const { compilerOptions, rootNames, target, sourceFileMap } = request; log(">>> runtime compile start", { rootNames, }); // if there are options, convert them into TypeScript compiler options, // and resolve any external file references const result = parseCompilerOptions( compilerOptions, ); const options = result.options; // TODO(bartlomieju): this options is excluded by `ts.convertCompilerOptionsFromJson` // however stuff breaks if it's not passed (type_directives_js_main.js, compiler_js_error.ts) options.allowNonTsExtensions = true; buildLocalSourceFileCache(sourceFileMap); const state = { rootNames, emitMap: {}, }; const host = new Host( options, target, createRuntimeCompileWriteFile(state), ); const program = ts.createProgram({ rootNames, options: host.getCompilationSettings(), host, }); const diagnostics = ts .getPreEmitDiagnostics(program) .filter(({ code }) => !IGNORED_DIAGNOSTICS.includes(code) && !IGNORED_COMPILE_DIAGNOSTICS.includes(code) ); const emitResult = program.emit(); assert(emitResult.emitSkipped === false, "Unexpected skip of the emit."); log("<<< runtime compile finish", { rootNames, emitMap: Object.keys(state.emitMap), }); const maybeDiagnostics = diagnostics.length ? fromTypeScriptDiagnostic(diagnostics) : []; return { diagnostics: maybeDiagnostics, emitMap: state.emitMap, }; } function runtimeBundle(request) { const { compilerOptions, rootNames, target, sourceFileMap } = request; log(">>> runtime bundle start", { rootNames, }); // if there are options, convert them into TypeScript compiler options, // and resolve any external file references const result = parseCompilerOptions( compilerOptions, ); const options = result.options; // TODO(bartlomieju): this options is excluded by `ts.convertCompilerOptionsFromJson` // however stuff breaks if it's not passed (type_directives_js_main.js, compiler_js_error.ts) options.allowNonTsExtensions = true; buildLocalSourceFileCache(sourceFileMap); const state = { rootNames, bundleOutput: undefined, }; const host = new Host( options, target, createBundleWriteFile(state), ); state.host = host; const program = ts.createProgram({ rootNames, options: host.getCompilationSettings(), host, }); setRootExports(program, rootNames[0]); const diagnostics = ts .getPreEmitDiagnostics(program) .filter(({ code }) => !IGNORED_DIAGNOSTICS.includes(code)); const emitResult = program.emit(); assert(emitResult.emitSkipped === false, "Unexpected skip of the emit."); log("<<< runtime bundle finish", { rootNames, }); const maybeDiagnostics = diagnostics.length ? fromTypeScriptDiagnostic(diagnostics) : []; return { diagnostics: maybeDiagnostics, output: state.bundleOutput, }; } function runtimeTranspile(request) { const result = {}; const { sources, compilerOptions } = request; const parseResult = parseCompilerOptions( compilerOptions, ); const options = parseResult.options; // TODO(bartlomieju): this options is excluded by `ts.convertCompilerOptionsFromJson` // however stuff breaks if it's not passed (type_directives_js_main.js, compiler_js_error.ts) options.allowNonTsExtensions = true; for (const [fileName, inputText] of Object.entries(sources)) { const { outputText: source, sourceMapText: map } = ts.transpileModule( inputText, { fileName, compilerOptions: options, }, ); result[fileName] = { source, map }; } return Promise.resolve(result); } function opCompilerRespond(msg) { core.jsonOpSync("op_compiler_respond", msg); } async function tsCompilerOnMessage(msg) { const request = msg.data; switch (request.type) { case CompilerRequestType.Compile: { const result = compile(request); opCompilerRespond(result); break; } case CompilerRequestType.Bundle: { const result = bundle(request); opCompilerRespond(result); break; } case CompilerRequestType.RuntimeCompile: { const result = runtimeCompile(request); opCompilerRespond(result); break; } case CompilerRequestType.RuntimeBundle: { const result = runtimeBundle(request); opCompilerRespond(result); break; } case CompilerRequestType.RuntimeTranspile: { const result = await runtimeTranspile(request); opCompilerRespond(result); break; } default: throw new Error( `!!! unhandled CompilerRequestType: ${request.type} (${ CompilerRequestType[request.type] })`, ); } } function runtimeStart(source) { core.ops(); // First we send an empty `Start` message to let the privileged side know we // are ready. The response should be a `StartRes` message containing the CLI // args and other info. const s = core.jsonOpSync("op_start"); setLogDebug(s.debugFlag, source); return s; } let hasBootstrapped = false; function bootstrapCompilerRuntime() { if (hasBootstrapped) { throw new Error("Worker runtime already bootstrapped"); } hasBootstrapped = true; runtimeStart("TS"); } globalThis.bootstrapCompilerRuntime = bootstrapCompilerRuntime; globalThis.tsCompilerOnMessage = tsCompilerOnMessage; })(this);