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denoland-deno/cli/js/compiler.ts
Bartek Iwańczuk 826a3135b4
refactor(compiler): split code paths for compile and bundle (#6304)
* refactor "compile" and "runtimeCompile" in "compiler.ts" and factor out
separate methods for "compile" and "bundle" operations

* remove noisy debug output from "compiler.ts"
 
* provide "Serialize" implementations for enums in "msg.rs"

* rename "analyze_dependencies_and_references" to "pre_process_file" and
move it to "tsc.rs"

* refactor ModuleGraph to use more concrete types and properly annotate
locations where errors occur

* remove dead code from "file_fetcher.rs" - "SourceFile.types_url" is no
longer needed, as type reference parsing is done in "ModuleGraph"

* remove unneeded field "source_path" from ".meta" files stored for
compiled source file (towards #6080)
2020-06-19 12:27:15 +02:00

1550 lines
43 KiB
TypeScript

// Copyright 2018-2020 the Deno authors. All rights reserved. MIT license.
// TODO(ry) Combine this implementation with //deno_typescript/compiler_main.js
// 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 a single functions that should be called by Rust:
// - `bootstrapTsCompilerRuntime`
// This functions must be called when creating isolate
// to properly setup runtime.
// NOTE: this import has side effects!
import "./ts_global.d.ts";
import { bold, cyan, yellow } from "./colors.ts";
import { CompilerOptions } from "./compiler_options.ts";
import { Diagnostic, DiagnosticItem } from "./diagnostics.ts";
import { fromTypeScriptDiagnostic } from "./diagnostics_util.ts";
import { TranspileOnlyResult } from "./ops/runtime_compiler.ts";
import { bootstrapWorkerRuntime } from "./runtime_worker.ts";
import { assert, log, notImplemented } from "./util.ts";
import { core } from "./core.ts";
// 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: string): string {
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; /* / */
const ASSETS = "$asset$";
const OUT_DIR = "$deno$";
// TODO(Bartlomieju): this check should be done in Rust
const IGNORED_COMPILER_OPTIONS: readonly string[] = [
"allowSyntheticDefaultImports",
"baseUrl",
"build",
"composite",
"declaration",
"declarationDir",
"declarationMap",
"diagnostics",
"downlevelIteration",
"emitBOM",
"emitDeclarationOnly",
"esModuleInterop",
"extendedDiagnostics",
"forceConsistentCasingInFileNames",
"help",
"importHelpers",
"incremental",
"inlineSourceMap",
"inlineSources",
"init",
"isolatedModules",
"listEmittedFiles",
"listFiles",
"mapRoot",
"maxNodeModuleJsDepth",
"module",
"moduleResolution",
"newLine",
"noEmit",
"noEmitHelpers",
"noEmitOnError",
"noLib",
"noResolve",
"out",
"outDir",
"outFile",
"paths",
"preserveSymlinks",
"preserveWatchOutput",
"pretty",
"rootDir",
"rootDirs",
"showConfig",
"skipDefaultLibCheck",
"skipLibCheck",
"sourceMap",
"sourceRoot",
"stripInternal",
"target",
"traceResolution",
"tsBuildInfoFile",
"types",
"typeRoots",
"version",
"watch",
];
const DEFAULT_BUNDLER_OPTIONS: ts.CompilerOptions = {
allowJs: true,
inlineSourceMap: false,
module: ts.ModuleKind.System,
outDir: undefined,
outFile: `${OUT_DIR}/bundle.js`,
// disabled until we have effective way to modify source maps
sourceMap: false,
};
const DEFAULT_COMPILE_OPTIONS: ts.CompilerOptions = {
allowJs: false,
allowNonTsExtensions: true,
checkJs: false,
esModuleInterop: true,
jsx: ts.JsxEmit.React,
module: ts.ModuleKind.ESNext,
outDir: OUT_DIR,
resolveJsonModule: true,
sourceMap: true,
strict: true,
stripComments: true,
target: ts.ScriptTarget.ESNext,
};
const DEFAULT_RUNTIME_COMPILE_OPTIONS: ts.CompilerOptions = {
outDir: undefined,
};
const DEFAULT_RUNTIME_TRANSPILE_OPTIONS: ts.CompilerOptions = {
esModuleInterop: true,
module: ts.ModuleKind.ESNext,
sourceMap: true,
scriptComments: true,
target: ts.ScriptTarget.ESNext,
};
enum CompilerHostTarget {
Main = "main",
Runtime = "runtime",
Worker = "worker",
}
interface CompilerHostOptions {
bundle?: boolean;
target: CompilerHostTarget;
unstable?: boolean;
writeFile: WriteFileCallback;
}
interface ConfigureResponse {
ignoredOptions?: string[];
diagnostics?: ts.Diagnostic[];
}
// Warning! The values in this enum are duplicated in `cli/msg.rs`
// Update carefully!
enum MediaType {
JavaScript = 0,
JSX = 1,
TypeScript = 2,
TSX = 3,
Json = 4,
Wasm = 5,
Unknown = 6,
}
interface SourceFileJson {
url: string;
filename: string;
mediaType: MediaType;
sourceCode: string;
}
function getExtension(fileName: string, mediaType: MediaType): ts.Extension {
switch (mediaType) {
case MediaType.JavaScript:
return ts.Extension.Js;
case MediaType.JSX:
return ts.Extension.Jsx;
case MediaType.TypeScript:
return fileName.endsWith(".d.ts") ? ts.Extension.Dts : ts.Extension.Ts;
case MediaType.TSX:
return ts.Extension.Tsx;
case MediaType.Wasm:
// Custom marker for Wasm type.
return ts.Extension.Js;
case MediaType.Unknown:
default:
throw TypeError(
`Cannot resolve extension for "${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: Map<string, SourceFile> = 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: Map<string, Map<string, string>> = new Map();
class SourceFile {
extension!: ts.Extension;
filename!: string;
mediaType!: MediaType;
processed = false;
sourceCode?: string;
tsSourceFile?: ts.SourceFile;
url!: string;
constructor(json: SourceFileJson) {
Object.assign(this, json);
this.extension = getExtension(this.url, this.mediaType);
}
static addToCache(json: SourceFileJson): SourceFile {
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: string): SourceFile | undefined {
return SOURCE_FILE_CACHE.get(url);
}
static cacheResolvedUrl(
resolvedUrl: string,
rawModuleSpecifier: string,
containingFile?: string
): void {
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: string,
containingFile: string
): string | undefined {
const containingCache = RESOLVED_SPECIFIER_CACHE.get(containingFile);
if (containingCache) {
const resolvedUrl = containingCache.get(moduleSpecifier);
return resolvedUrl;
}
return undefined;
}
}
function getAssetInternal(filename: string): SourceFile {
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,
sourceCode,
});
}
class Host implements ts.CompilerHost {
readonly #options = DEFAULT_COMPILE_OPTIONS;
#target: CompilerHostTarget;
#writeFile: WriteFileCallback;
/* Deno specific APIs */
constructor({
bundle = false,
target,
unstable,
writeFile,
}: CompilerHostOptions) {
this.#target = target;
this.#writeFile = writeFile;
if (bundle) {
// options we need to change when we are generating a bundle
Object.assign(this.#options, DEFAULT_BUNDLER_OPTIONS);
}
if (unstable) {
this.#options.lib = [
target === CompilerHostTarget.Worker
? "lib.deno.worker.d.ts"
: "lib.deno.window.d.ts",
"lib.deno.unstable.d.ts",
];
}
}
get options(): ts.CompilerOptions {
return this.#options;
}
configure(
cwd: string,
path: string,
configurationText: string
): ConfigureResponse {
log("compiler::host.configure", path);
assert(configurationText);
const { config, error } = ts.parseConfigFileTextToJson(
path,
configurationText
);
if (error) {
return { diagnostics: [error] };
}
const { options, errors } = ts.convertCompilerOptionsFromJson(
config.compilerOptions,
cwd
);
const ignoredOptions: string[] = [];
for (const key of Object.keys(options)) {
if (
IGNORED_COMPILER_OPTIONS.includes(key) &&
(!(key in this.#options) || options[key] !== this.#options[key])
) {
ignoredOptions.push(key);
delete options[key];
}
}
Object.assign(this.#options, options);
return {
ignoredOptions: ignoredOptions.length ? ignoredOptions : undefined,
diagnostics: errors.length ? errors : undefined,
};
}
mergeOptions(...options: ts.CompilerOptions[]): ts.CompilerOptions {
Object.assign(this.#options, ...options);
return Object.assign({}, this.#options);
}
/* TypeScript CompilerHost APIs */
fileExists(_fileName: string): boolean {
return notImplemented();
}
getCanonicalFileName(fileName: string): string {
return fileName;
}
getCompilationSettings(): ts.CompilerOptions {
log("compiler::host.getCompilationSettings()");
return this.#options;
}
getCurrentDirectory(): string {
return "";
}
getDefaultLibFileName(_options: ts.CompilerOptions): string {
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(): string {
return "\n";
}
getSourceFile(
fileName: string,
languageVersion: ts.ScriptTarget,
onError?: (message: string) => void,
shouldCreateNewSourceFile?: boolean
): ts.SourceFile | undefined {
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
);
delete sourceFile.sourceCode;
}
return sourceFile.tsSourceFile;
} catch (e) {
if (onError) {
onError(String(e));
} else {
throw e;
}
return undefined;
}
}
readFile(_fileName: string): string | undefined {
return notImplemented();
}
resolveModuleNames(
moduleNames: string[],
containingFile: string
): Array<ts.ResolvedModuleFull | undefined> {
log("compiler::host.resolveModuleNames", {
moduleNames,
containingFile,
});
return moduleNames.map((specifier) => {
const maybeUrl = SourceFile.getResolvedUrl(specifier, containingFile);
log("compiler::host.resolveModuleNames maybeUrl", {
specifier,
containingFile,
maybeUrl,
});
let sourceFile: SourceFile | undefined = 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,
};
});
}
useCaseSensitiveFileNames(): boolean {
return true;
}
writeFile(
fileName: string,
data: string,
_writeByteOrderMark: boolean,
_onError?: (message: string) => void,
sourceFiles?: readonly ts.SourceFile[]
): void {
log("compiler::host.writeFile", fileName);
this.#writeFile(fileName, data, sourceFiles);
}
}
// NOTE: target doesn't really matter here,
// this is in fact a mock host created just to
// load all type definitions and snapshot them.
const SNAPSHOT_HOST = new Host({
target: CompilerHostTarget.Main,
writeFile(): void {},
});
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.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.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,
});
// 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: Record<string, SourceFileMapEntry>
): void {
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,
});
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) {
if (importedFile.typeHeaders.length > 0) {
const typeHeaders = importedFile.typeHeaders[0];
mappedUrl = typeHeaders.resolvedSpecifier;
} else if (importDesc.resolvedTypeDirective) {
mappedUrl = importDesc.resolvedTypeDirective;
} 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: Record<string, SourceFileMapEntry>
): void {
for (const entry of Object.values(sourceFileMap)) {
SourceFile.addToCache({
url: entry.url,
filename: entry.url,
mediaType: entry.mediaType,
sourceCode: entry.sourceCode,
});
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) {
if (importedFile.typeHeaders.length > 0) {
const typeHeaders = importedFile.typeHeaders[0];
mappedUrl = typeHeaders.resolvedSpecifier;
} else if (importDesc.resolvedTypeDirective) {
mappedUrl = importDesc.resolvedTypeDirective;
} 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
);
}
}
}
interface EmittedSource {
// original filename
filename: string;
// compiled contents
contents: string;
}
type WriteFileCallback = (
fileName: string,
data: string,
sourceFiles?: readonly ts.SourceFile[]
) => void;
interface CompileWriteFileState {
rootNames: string[];
emitMap: Record<string, EmittedSource>;
}
interface BundleWriteFileState {
host?: Host;
bundleOutput: undefined | string;
rootNames: string[];
}
// Warning! The values in this enum are duplicated in `cli/msg.rs`
// Update carefully!
enum CompilerRequestType {
Compile = 0,
Bundle = 1,
RuntimeCompile = 2,
RuntimeBundle = 3,
RuntimeTranspile = 4,
}
function createBundleWriteFile(state: BundleWriteFileState): WriteFileCallback {
return function writeFile(
_fileName: string,
data: string,
sourceFiles?: readonly ts.SourceFile[]
): void {
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: CompileWriteFileState
): WriteFileCallback {
return function writeFile(
fileName: string,
data: string,
sourceFiles?: readonly ts.SourceFile[]
): void {
assert(sourceFiles != null);
assert(sourceFiles.length === 1);
state.emitMap[fileName] = {
filename: sourceFiles[0].fileName,
contents: data,
};
};
}
interface ConvertCompilerOptionsResult {
files?: string[];
options: ts.CompilerOptions;
}
function convertCompilerOptions(str: string): ConvertCompilerOptionsResult {
const options: CompilerOptions = JSON.parse(str);
const out: Record<string, unknown> = {};
const keys = Object.keys(options) as Array<keyof CompilerOptions>;
const files: string[] = [];
for (const key of keys) {
switch (key) {
case "jsx":
const value = options[key];
if (value === "preserve") {
out[key] = ts.JsxEmit.Preserve;
} else if (value === "react") {
out[key] = ts.JsxEmit.React;
} else {
out[key] = ts.JsxEmit.ReactNative;
}
break;
case "module":
switch (options[key]) {
case "amd":
out[key] = ts.ModuleKind.AMD;
break;
case "commonjs":
out[key] = ts.ModuleKind.CommonJS;
break;
case "es2015":
case "es6":
out[key] = ts.ModuleKind.ES2015;
break;
case "esnext":
out[key] = ts.ModuleKind.ESNext;
break;
case "none":
out[key] = ts.ModuleKind.None;
break;
case "system":
out[key] = ts.ModuleKind.System;
break;
case "umd":
out[key] = ts.ModuleKind.UMD;
break;
default:
throw new TypeError("Unexpected module type");
}
break;
case "target":
switch (options[key]) {
case "es3":
out[key] = ts.ScriptTarget.ES3;
break;
case "es5":
out[key] = ts.ScriptTarget.ES5;
break;
case "es6":
case "es2015":
out[key] = ts.ScriptTarget.ES2015;
break;
case "es2016":
out[key] = ts.ScriptTarget.ES2016;
break;
case "es2017":
out[key] = ts.ScriptTarget.ES2017;
break;
case "es2018":
out[key] = ts.ScriptTarget.ES2018;
break;
case "es2019":
out[key] = ts.ScriptTarget.ES2019;
break;
case "es2020":
out[key] = ts.ScriptTarget.ES2020;
break;
case "esnext":
out[key] = ts.ScriptTarget.ESNext;
break;
default:
throw new TypeError("Unexpected emit target.");
}
break;
case "types":
const types = options[key];
assert(types);
files.push(...types);
break;
default:
out[key] = options[key];
}
}
return {
options: out as ts.CompilerOptions,
files: files.length ? files : undefined,
};
}
const ignoredDiagnostics = [
// 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,
];
// TODO(Bartlomieju): this check should be done in Rust; there should be no
// console.log here
function processConfigureResponse(
configResult: ConfigureResponse,
configPath: string
): ts.Diagnostic[] | undefined {
const { ignoredOptions, diagnostics } = configResult;
if (ignoredOptions) {
console.warn(
yellow(`Unsupported compiler options in "${configPath}"\n`) +
cyan(` The following options were ignored:\n`) +
` ${ignoredOptions.map((value): string => bold(value)).join(", ")}`
);
}
return diagnostics;
}
function normalizeString(path: string): string {
let res = "";
let lastSegmentLength = 0;
let lastSlash = -1;
let dots = 0;
let code: number;
for (let i = 0, len = path.length; i <= len; ++i) {
if (i < len) code = path.charCodeAt(i);
else if (code! === CHAR_FORWARD_SLASH) break;
else code = CHAR_FORWARD_SLASH;
if (code === CHAR_FORWARD_SLASH) {
if (lastSlash === i - 1 || dots === 1) {
// NOOP
} else if (lastSlash !== i - 1 && dots === 2) {
if (
res.length < 2 ||
lastSegmentLength !== 2 ||
res.charCodeAt(res.length - 1) !== CHAR_DOT ||
res.charCodeAt(res.length - 2) !== CHAR_DOT
) {
if (res.length > 2) {
const lastSlashIndex = res.lastIndexOf("/");
if (lastSlashIndex === -1) {
res = "";
lastSegmentLength = 0;
} else {
res = res.slice(0, lastSlashIndex);
lastSegmentLength = res.length - 1 - res.lastIndexOf("/");
}
lastSlash = i;
dots = 0;
continue;
} else if (res.length === 2 || res.length === 1) {
res = "";
lastSegmentLength = 0;
lastSlash = i;
dots = 0;
continue;
}
}
} else {
if (res.length > 0) res += "/" + path.slice(lastSlash + 1, i);
else res = path.slice(lastSlash + 1, i);
lastSegmentLength = i - lastSlash - 1;
}
lastSlash = i;
dots = 0;
} else if (code === CHAR_DOT && dots !== -1) {
++dots;
} else {
dots = -1;
}
}
return res;
}
function commonPath(paths: string[], sep = "/"): string {
const [first = "", ...remaining] = paths;
if (first === "" || remaining.length === 0) {
return first.substring(0, first.lastIndexOf(sep) + 1);
}
const parts = first.split(sep);
let endOfPrefix = parts.length;
for (const path of remaining) {
const compare = path.split(sep);
for (let i = 0; i < endOfPrefix; i++) {
if (compare[i] !== parts[i]) {
endOfPrefix = i;
}
}
if (endOfPrefix === 0) {
return "";
}
}
const prefix = parts.slice(0, endOfPrefix).join(sep);
return prefix.endsWith(sep) ? prefix : `${prefix}${sep}`;
}
let rootExports: string[] | undefined;
function normalizeUrl(rootName: string): string {
const match = /^(\S+:\/{2,3})(.+)$/.exec(rootName);
if (match) {
const [, protocol, path] = match;
return `${protocol}${normalizeString(path)}`;
} else {
return rootName;
}
}
function buildBundle(
rootName: string,
data: string,
sourceFiles: readonly ts.SourceFile[],
target: ts.ScriptTarget
): string {
// 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+$/i, "");
// If one of the modules requires support for top-level-await, TypeScript will
// emit the execute function as an async function. When this is the case we
// need to bubble up the TLA to the instantiation, otherwise we instantiate
// synchronously.
const hasTla = data.match(/execute:\sasync\sfunction\s/);
let instantiate: string;
if (rootExports && rootExports.length) {
instantiate = hasTla
? `const __exp = await __instantiate("${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
? true
: false;
return `${
es5Bundle ? SYSTEM_LOADER_ES5 : SYSTEM_LOADER
}\n${data}\n${instantiate}`;
}
function setRootExports(program: ts.Program, rootModule: string): void {
// 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());
}
interface ImportDescriptor {
specifier: string;
resolvedSpecifier: string;
typeDirective?: string;
resolvedTypeDirective?: string;
}
interface ReferenceDescriptor {
specifier: string;
resolvedSpecifier: string;
}
interface SourceFileMapEntry {
// fully resolved URL
url: string;
sourceCode: string;
mediaType: MediaType;
redirect?: string;
imports: ImportDescriptor[];
referencedFiles: ReferenceDescriptor[];
libDirectives: ReferenceDescriptor[];
typesDirectives: ReferenceDescriptor[];
typeHeaders: ReferenceDescriptor[];
}
/** Used when "deno run" is invoked */
interface CompileRequest {
type: CompilerRequestType.Compile;
allowJs: boolean;
target: CompilerHostTarget;
rootNames: string[];
configPath?: string;
config?: string;
unstable: boolean;
cwd: string;
// key value is fully resolved URL
sourceFileMap: Record<string, SourceFileMapEntry>;
}
/** Used when "deno bundle" is invoked */
interface BundleRequest {
type: CompilerRequestType.Bundle;
target: CompilerHostTarget;
rootNames: string[];
configPath?: string;
config?: string;
unstable: boolean;
cwd: string;
// key value is fully resolved URL
sourceFileMap: Record<string, SourceFileMapEntry>;
}
/** Used when "Deno.compile()" API is called */
interface RuntimeCompileRequest {
type: CompilerRequestType.RuntimeCompile;
target: CompilerHostTarget;
rootNames: string[];
sourceFileMap: Record<string, SourceFileMapEntry>;
unstable?: boolean;
options?: string;
}
/** Used when "Deno.bundle()" API is called */
interface RuntimeBundleRequest {
type: CompilerRequestType.RuntimeBundle;
target: CompilerHostTarget;
rootNames: string[];
sourceFileMap: Record<string, SourceFileMapEntry>;
unstable?: boolean;
options?: string;
}
/** Used when "Deno.transpileOnly()" API is called */
interface RuntimeTranspileRequest {
type: CompilerRequestType.RuntimeTranspile;
sources: Record<string, string>;
options?: string;
}
type CompilerRequest =
| CompileRequest
| BundleRequest
| RuntimeCompileRequest
| RuntimeBundleRequest
| RuntimeTranspileRequest;
interface CompileResponse {
emitMap: Record<string, EmittedSource>;
diagnostics: Diagnostic;
}
interface BundleResponse {
bundleOutput?: string;
diagnostics: Diagnostic;
}
interface RuntimeCompileResponse {
emitMap: Record<string, EmittedSource>;
diagnostics: DiagnosticItem[];
}
interface RuntimeBundleResponse {
output?: string;
diagnostics: DiagnosticItem[];
}
function compile(request: CompileRequest): CompileResponse {
const {
allowJs,
config,
configPath,
rootNames,
target,
unstable,
cwd,
sourceFileMap,
} = request;
log(">>> compile start", {
rootNames,
type: CompilerRequestType[request.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: CompileWriteFileState = {
rootNames,
emitMap: {},
};
const host = new Host({
bundle: false,
target,
unstable,
writeFile: createCompileWriteFile(state),
});
let diagnostics: readonly ts.Diagnostic[] = [];
host.mergeOptions({ allowJs });
// if there is a configuration supplied, we need to parse that
if (config && config.length && configPath) {
const configResult = host.configure(cwd, configPath, config);
diagnostics = processConfigureResponse(configResult, configPath) || [];
}
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 }) => !ignoredDiagnostics.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;
}
}
log("<<< compile end", {
rootNames,
type: CompilerRequestType[request.type],
});
return {
emitMap: state.emitMap,
diagnostics: fromTypeScriptDiagnostic(diagnostics),
};
}
function bundle(request: BundleRequest): BundleResponse {
const {
config,
configPath,
rootNames,
target,
unstable,
cwd,
sourceFileMap,
} = request;
log(">>> start start", {
rootNames,
type: CompilerRequestType[request.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: BundleWriteFileState = {
rootNames,
bundleOutput: undefined,
};
const host = new Host({
bundle: true,
target,
unstable,
writeFile: createBundleWriteFile(state),
});
state.host = host;
let diagnostics: readonly ts.Diagnostic[] = [];
// if there is a configuration supplied, we need to parse that
if (config && config.length && configPath) {
const configResult = host.configure(cwd, configPath, config);
diagnostics = processConfigureResponse(configResult, configPath) || [];
}
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 }) => !ignoredDiagnostics.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;
}
}
let bundleOutput;
if (diagnostics.length === 0) {
assert(state.bundleOutput);
bundleOutput = state.bundleOutput;
}
const result: BundleResponse = {
bundleOutput,
diagnostics: fromTypeScriptDiagnostic(diagnostics),
};
log("<<< bundle end", {
rootNames,
type: CompilerRequestType[request.type],
});
return result;
}
function runtimeCompile(
request: RuntimeCompileRequest
): RuntimeCompileResponse {
const { options, rootNames, target, unstable, sourceFileMap } = request;
log(">>> runtime compile start", {
rootNames,
});
// if there are options, convert them into TypeScript compiler options,
// and resolve any external file references
let convertedOptions: ts.CompilerOptions | undefined;
if (options) {
const result = convertCompilerOptions(options);
convertedOptions = result.options;
}
buildLocalSourceFileCache(sourceFileMap);
const state: CompileWriteFileState = {
rootNames,
emitMap: {},
};
const host = new Host({
bundle: false,
target,
writeFile: createCompileWriteFile(state),
});
const compilerOptions = [DEFAULT_RUNTIME_COMPILE_OPTIONS];
if (convertedOptions) {
compilerOptions.push(convertedOptions);
}
if (unstable) {
compilerOptions.push({
lib: [
"deno.unstable",
...((convertedOptions && convertedOptions.lib) || ["deno.window"]),
],
});
}
host.mergeOptions(...compilerOptions);
const program = ts.createProgram({
rootNames,
options: host.getCompilationSettings(),
host,
});
const diagnostics = ts
.getPreEmitDiagnostics(program)
.filter(({ code }) => !ignoredDiagnostics.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).items
: [];
return {
diagnostics: maybeDiagnostics,
emitMap: state.emitMap,
};
}
function runtimeBundle(request: RuntimeBundleRequest): RuntimeBundleResponse {
const { options, rootNames, target, unstable, sourceFileMap } = request;
log(">>> runtime bundle start", {
rootNames,
});
// if there are options, convert them into TypeScript compiler options,
// and resolve any external file references
let convertedOptions: ts.CompilerOptions | undefined;
if (options) {
const result = convertCompilerOptions(options);
convertedOptions = result.options;
}
buildLocalSourceFileCache(sourceFileMap);
const state: BundleWriteFileState = {
rootNames,
bundleOutput: undefined,
};
const host = new Host({
bundle: true,
target,
writeFile: createBundleWriteFile(state),
});
state.host = host;
const compilerOptions = [DEFAULT_RUNTIME_COMPILE_OPTIONS];
if (convertedOptions) {
compilerOptions.push(convertedOptions);
}
if (unstable) {
compilerOptions.push({
lib: [
"deno.unstable",
...((convertedOptions && convertedOptions.lib) || ["deno.window"]),
],
});
}
compilerOptions.push(DEFAULT_BUNDLER_OPTIONS);
host.mergeOptions(...compilerOptions);
const program = ts.createProgram({
rootNames,
options: host.getCompilationSettings(),
host,
});
setRootExports(program, rootNames[0]);
const diagnostics = ts
.getPreEmitDiagnostics(program)
.filter(({ code }) => !ignoredDiagnostics.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).items
: [];
return {
diagnostics: maybeDiagnostics,
output: state.bundleOutput,
};
}
function runtimeTranspile(
request: RuntimeTranspileRequest
): Promise<Record<string, TranspileOnlyResult>> {
const result: Record<string, TranspileOnlyResult> = {};
const { sources, options } = request;
const compilerOptions = options
? Object.assign(
{},
DEFAULT_RUNTIME_TRANSPILE_OPTIONS,
convertCompilerOptions(options).options
)
: DEFAULT_RUNTIME_TRANSPILE_OPTIONS;
for (const [fileName, inputText] of Object.entries(sources)) {
const { outputText: source, sourceMapText: map } = ts.transpileModule(
inputText,
{
fileName,
compilerOptions,
}
);
result[fileName] = { source, map };
}
return Promise.resolve(result);
}
async function tsCompilerOnMessage({
data: request,
}: {
data: CompilerRequest;
}): Promise<void> {
switch (request.type) {
case CompilerRequestType.Compile: {
const result = compile(request as CompileRequest);
globalThis.postMessage(result);
break;
}
case CompilerRequestType.Bundle: {
const result = bundle(request as BundleRequest);
globalThis.postMessage(result);
break;
}
case CompilerRequestType.RuntimeCompile: {
const result = runtimeCompile(request as RuntimeCompileRequest);
globalThis.postMessage(result);
break;
}
case CompilerRequestType.RuntimeBundle: {
const result = runtimeBundle(request as RuntimeBundleRequest);
globalThis.postMessage(result);
break;
}
case CompilerRequestType.RuntimeTranspile: {
const result = await runtimeTranspile(request as RuntimeTranspileRequest);
globalThis.postMessage(result);
break;
}
default:
log(
`!!! unhandled CompilerRequestType: ${
(request as CompilerRequest).type
} (${CompilerRequestType[(request as CompilerRequest).type]})`
);
}
// Shutdown after single request
globalThis.close();
}
function bootstrapTsCompilerRuntime(): void {
bootstrapWorkerRuntime("TS", false);
globalThis.onmessage = tsCompilerOnMessage;
}
// Removes the `__proto__` for security reasons. This intentionally makes
// Deno non compliant with ECMA-262 Annex B.2.2.1
//
// eslint-disable-next-line @typescript-eslint/no-explicit-any
delete (Object.prototype as any).__proto__;
Object.defineProperties(globalThis, {
bootstrap: {
value: {
...globalThis.bootstrap,
tsCompilerRuntime: bootstrapTsCompilerRuntime,
},
configurable: true,
writable: true,
},
});