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denoland-deno/cli/js/compiler.ts
Bartek Iwańczuk 2b66b8a03e
BREAKING: Remove support for .wasm imports (#5135)
Importing .wasm files is non-standardized therefore deciding to
support current functionality past 1.0 release is risky.

Besides that .wasm import posed many challenges in our codebase
due to complex interactions with TS compiler which spawned
thread for each encountered .wasm import.

This commit removes:
- cli/compilers/wasm.rs
- cli/compilers/wasm_wrap.js
- two integration tests related to .wasm imports
2020-05-07 20:43:27 +02:00

1596 lines
45 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 { sendAsync, sendSync } from "./ops/dispatch_json.ts";
import { bootstrapWorkerRuntime } from "./runtime_worker.ts";
import { assert, log } from "./util.ts";
import * as util from "./util.ts";
import { TextDecoder, TextEncoder } from "./web/text_encoding.ts";
import { core } from "./core.ts";
export function resolveModules(
specifiers: string[],
referrer?: string
): string[] {
util.log("compiler::resolveModules", { specifiers, referrer });
return sendSync("op_resolve_modules", { specifiers, referrer });
}
export function fetchSourceFiles(
specifiers: string[],
referrer?: string
): Promise<
Array<{
url: string;
filename: string;
mediaType: number;
sourceCode: string;
}>
> {
util.log("compiler::fetchSourceFiles", { specifiers, referrer });
return sendAsync("op_fetch_source_files", {
specifiers,
referrer,
});
}
const encoder = new TextEncoder();
const decoder = new TextDecoder();
function getAsset(name: string): string {
const opId = core.ops()["op_fetch_asset"];
// We really don't want to depend on JSON dispatch during snapshotting, so
// this op exchanges strings with Rust as raw byte arrays.
const sourceCodeBytes = core.dispatch(opId, encoder.encode(name));
return decoder.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 "${MediaType[mediaType]}".`
);
}
}
/** Because we support providing types for JS files as well as X-TypeScript-Types
* header we might be feeding TS compiler with different files than import specifiers
* suggest. To accomplish that we keep track of two different specifiers:
* - original - the one in import statement (import "./foo.js")
* - mapped - if there's no type directive it's the same as original, otherwise
* it's unresolved specifier for type directive (/// @deno-types="./foo.d.ts")
*/
interface SourceFileSpecifierMap {
original: string;
mapped: string;
}
/** A global cache of module source files that have been loaded.
* This cache will be rewritten to be populated on compiler startup
* with files provided from Rust in request message.
*/
const SOURCE_FILE_CACHE: Map<string, SourceFile> = new Map();
/** A map of maps which cache resolved specifier for each import in a file.
* This cache is used so `resolveModuleNames` ops is called as few times
* as possible.
*
* First map's key is "referrer" URL ("file://a/b/c/mod.ts")
* Second map's key is "raw" import specifier ("./foo.ts")
* Second map's value is resolved import URL ("file:///a/b/c/foo.ts")
*/
const RESOLVED_SPECIFIER_CACHE: Map<string, Map<string, string>> = new Map();
class SourceFile {
extension!: ts.Extension;
filename!: string;
mediaType!: MediaType;
processed = false;
sourceCode?: string;
tsSourceFile?: ts.SourceFile;
url!: string;
constructor(json: SourceFileJson) {
Object.assign(this, json);
this.extension = getExtension(this.url, this.mediaType);
}
imports(processJsImports: boolean): SourceFileSpecifierMap[] {
if (this.processed) {
throw new Error("SourceFile has already been processed.");
}
assert(this.sourceCode != null);
// we shouldn't process imports for files which contain the nocheck pragma
// (like bundles)
if (this.sourceCode.match(/\/{2}\s+@ts-nocheck/)) {
log(`Skipping imports for "${this.filename}"`);
return [];
}
const readImportFiles = true;
const isJsOrJsx =
this.mediaType === MediaType.JavaScript ||
this.mediaType === MediaType.JSX;
const detectJsImports = isJsOrJsx;
const preProcessedFileInfo = ts.preProcessFile(
this.sourceCode,
readImportFiles,
detectJsImports
);
this.processed = true;
const files: SourceFileSpecifierMap[] = [];
function process(references: Array<{ fileName: string }>): void {
for (const { fileName } of references) {
files.push({ original: fileName, mapped: fileName });
}
}
const {
importedFiles,
referencedFiles,
libReferenceDirectives,
typeReferenceDirectives,
} = preProcessedFileInfo;
const typeDirectives = parseTypeDirectives(this.sourceCode);
if (typeDirectives) {
for (const importedFile of importedFiles) {
// If there's a type directive for current processed file; then we provide
// different `mapped` specifier.
const mappedModuleName = getMappedModuleName(
importedFile,
typeDirectives
);
files.push({
original: importedFile.fileName,
mapped: mappedModuleName ?? importedFile.fileName,
});
}
} else if (processJsImports || !isJsOrJsx) {
process(importedFiles);
}
process(referencedFiles);
// built in libs comes across as `"dom"` for example, and should be filtered
// out during pre-processing as they are either already cached or they will
// be lazily fetched by the compiler host. Ones that contain full files are
// not filtered out and will be fetched as normal.
const filteredLibs = libReferenceDirectives.filter(
({ fileName }) => !ts.libMap.has(fileName.toLowerCase())
);
process(filteredLibs);
process(typeReferenceDirectives);
return files;
}
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",
];
}
}
configure(
cwd: string,
path: string,
configurationText: string
): ConfigureResponse {
util.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 util.notImplemented();
}
getCanonicalFileName(fileName: string): string {
return fileName;
}
getCompilationSettings(): ts.CompilerOptions {
util.log("compiler::host.getCompilationSettings()");
return this.#options;
}
getCurrentDirectory(): string {
return "";
}
getDefaultLibFileName(_options: ts.CompilerOptions): string {
util.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 {
util.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 util.notImplemented();
}
resolveModuleNames(
moduleNames: string[],
containingFile: string
): Array<ts.ResolvedModuleFull | undefined> {
util.log("compiler::host.resolveModuleNames", {
moduleNames,
containingFile,
});
return moduleNames.map((specifier) => {
const maybeUrl = SourceFile.getResolvedUrl(specifier, containingFile);
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 {
util.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
);
const TS_SNAPSHOT_PROGRAM = ts.createProgram({
rootNames: [`${ASSETS}/bootstrap.ts`],
options: SNAPSHOT_COMPILER_OPTIONS,
host: SNAPSHOT_HOST,
});
// This function is called only during snapshotting process
const SYSTEM_LOADER = getAsset("system_loader.js");
function resolveSpecifier(specifier: string, referrer: string): string {
// The resolveModules op only handles fully qualified URLs for referrer.
// However we will have cases where referrer is "/foo.ts". We add this dummy
// prefix "file://" in order to use the op.
// TODO(ry) Maybe we should perhaps ModuleSpecifier::resolve_import() to
// handle this situation.
let dummyPrefix = false;
const prefix = "file://";
if (referrer.startsWith("/")) {
dummyPrefix = true;
referrer = prefix + referrer;
}
let r = resolveModules([specifier], referrer)[0];
if (dummyPrefix) {
r = r.replace(prefix, "");
}
return r;
}
function getMediaType(filename: string): MediaType {
const maybeExtension = /\.([a-zA-Z]+)$/.exec(filename);
if (!maybeExtension) {
util.log(`!!! Could not identify valid extension: "${filename}"`);
return MediaType.Unknown;
}
const [, extension] = maybeExtension;
switch (extension.toLowerCase()) {
case "js":
return MediaType.JavaScript;
case "jsx":
return MediaType.JSX;
case "ts":
return MediaType.TypeScript;
case "tsx":
return MediaType.TSX;
case "wasm":
return MediaType.Wasm;
default:
util.log(`!!! Unknown extension: "${extension}"`);
return MediaType.Unknown;
}
}
function processLocalImports(
sources: Record<string, string>,
specifiers: SourceFileSpecifierMap[],
referrer?: string,
processJsImports = false
): string[] {
if (!specifiers.length) {
return [];
}
const moduleNames = specifiers.map((specifierMap) => {
if (referrer) {
return resolveSpecifier(specifierMap.mapped, referrer);
} else {
return specifierMap.mapped;
}
});
for (let i = 0; i < moduleNames.length; i++) {
const moduleName = moduleNames[i];
const specifierMap = specifiers[i];
assert(moduleName in sources, `Missing module in sources: "${moduleName}"`);
let sourceFile = SourceFile.getCached(moduleName);
if (typeof sourceFile === "undefined") {
sourceFile = SourceFile.addToCache({
url: moduleName,
filename: moduleName,
sourceCode: sources[moduleName],
mediaType: getMediaType(moduleName),
});
}
assert(sourceFile);
SourceFile.cacheResolvedUrl(
sourceFile.url,
specifierMap.original,
referrer
);
if (!sourceFile.processed) {
processLocalImports(
sources,
sourceFile.imports(processJsImports),
sourceFile.url,
processJsImports
);
}
}
return moduleNames;
}
async function processImports(
specifiers: SourceFileSpecifierMap[],
referrer?: string,
processJsImports = false
): Promise<string[]> {
if (!specifiers.length) {
return [];
}
const sources = specifiers.map(({ mapped }) => mapped);
const resolvedSources = resolveModules(sources, referrer);
const sourceFiles = await fetchSourceFiles(resolvedSources, referrer);
assert(sourceFiles.length === specifiers.length);
for (let i = 0; i < sourceFiles.length; i++) {
const specifierMap = specifiers[i];
const sourceFileJson = sourceFiles[i];
let sourceFile = SourceFile.getCached(sourceFileJson.url);
if (typeof sourceFile === "undefined") {
sourceFile = SourceFile.addToCache(sourceFileJson);
}
assert(sourceFile);
SourceFile.cacheResolvedUrl(
sourceFile.url,
specifierMap.original,
referrer
);
if (!sourceFile.processed) {
const sourceFileImports = sourceFile.imports(processJsImports);
await processImports(sourceFileImports, sourceFile.url, processJsImports);
}
}
return resolvedSources;
}
interface FileReference {
fileName: string;
pos: number;
end: number;
}
function getMappedModuleName(
source: FileReference,
typeDirectives: Map<FileReference, string>
): string | undefined {
const { fileName: sourceFileName, pos: sourcePos } = source;
for (const [{ fileName, pos }, value] of typeDirectives.entries()) {
if (sourceFileName === fileName && sourcePos === pos) {
return value;
}
}
return undefined;
}
const typeDirectiveRegEx = /@deno-types\s*=\s*(["'])((?:(?=(\\?))\3.)*?)\1/gi;
const importExportRegEx = /(?:import|export)(?:\s+|\s+[\s\S]*?from\s+)?(["'])((?:(?=(\\?))\3.)*?)\1/;
function parseTypeDirectives(
sourceCode: string | undefined
): Map<FileReference, string> | undefined {
if (!sourceCode) {
return;
}
// collect all the directives in the file and their start and end positions
const directives: FileReference[] = [];
let maybeMatch: RegExpExecArray | null = null;
while ((maybeMatch = typeDirectiveRegEx.exec(sourceCode))) {
const [matchString, , fileName] = maybeMatch;
const { index: pos } = maybeMatch;
directives.push({
fileName,
pos,
end: pos + matchString.length,
});
}
if (!directives.length) {
return;
}
// work from the last directive backwards for the next `import`/`export`
// statement
directives.reverse();
const results = new Map<FileReference, string>();
for (const { end, fileName, pos } of directives) {
const searchString = sourceCode.substring(end);
const maybeMatch = importExportRegEx.exec(searchString);
if (maybeMatch) {
const [matchString, , targetFileName] = maybeMatch;
const targetPos =
end + maybeMatch.index + matchString.indexOf(targetFileName) - 1;
const target: FileReference = {
fileName: targetFileName,
pos: targetPos,
end: targetPos + targetFileName.length,
};
results.set(target, fileName);
}
sourceCode = sourceCode.substring(0, pos);
}
return results;
}
interface EmmitedSource {
// original filename
filename: string;
// compiled contents
contents: string;
}
type WriteFileCallback = (
fileName: string,
data: string,
sourceFiles?: readonly ts.SourceFile[]
) => void;
interface WriteFileState {
type: CompilerRequestType;
bundle?: boolean;
bundleOutput?: string;
host?: Host;
rootNames: string[];
emitMap?: Record<string, EmmitedSource>;
sources?: Record<string, string>;
}
// Warning! The values in this enum are duplicated in `cli/msg.rs`
// Update carefully!
enum CompilerRequestType {
Compile = 0,
RuntimeCompile = 1,
RuntimeTranspile = 2,
}
// TODO(bartlomieju): probably could be defined inline?
function createBundleWriteFile(state: WriteFileState): WriteFileCallback {
return function writeFile(
_fileName: string,
data: string,
sourceFiles?: readonly ts.SourceFile[]
): void {
assert(sourceFiles != null);
assert(state.host);
assert(state.emitMap);
assert(state.bundle);
// we only support single root names for bundles
assert(state.rootNames.length === 1);
state.bundleOutput = buildBundle(state.rootNames[0], data, sourceFiles);
};
}
// TODO(bartlomieju): probably could be defined inline?
function createCompileWriteFile(state: WriteFileState): WriteFileCallback {
return function writeFile(
fileName: string,
data: string,
sourceFiles?: readonly ts.SourceFile[]
): void {
assert(sourceFiles != null);
assert(state.host);
assert(state.emitMap);
assert(!state.bundle);
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[]
): 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+$/i, "");
// If one of the modules requires support for top-level-await, TypeScript will
// emit the execute function as an async function. When this is the case we
// need to bubble up the TLA to the instantiation, otherwise we instantiate
// synchronously.
const hasTla = data.match(/execute:\sasync\sfunction\s/);
let instantiate: string;
if (rootExports && rootExports.length) {
instantiate = hasTla
? `const __exp = await __instantiateAsync("${rootName}");\n`
: `const __exp = __instantiate("${rootName}");\n`;
for (const rootExport of rootExports) {
if (rootExport === "default") {
instantiate += `export default __exp["${rootExport}"];\n`;
} else {
instantiate += `export const ${rootExport} = __exp["${rootExport}"];\n`;
}
}
} else {
instantiate = hasTla
? `await __instantiateAsync("${rootName}");\n`
: `__instantiate("${rootName}");\n`;
}
return `${SYSTEM_LOADER}\n${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 CompilerRequestCompile {
type: CompilerRequestType.Compile;
target: CompilerHostTarget;
rootNames: string[];
// TODO(ry) add compiler config to this interface.
// options: ts.CompilerOptions;
configPath?: string;
config?: string;
unstable: boolean;
bundle: boolean;
cwd: string;
}
interface CompilerRequestRuntimeCompile {
type: CompilerRequestType.RuntimeCompile;
target: CompilerHostTarget;
rootName: string;
sources?: Record<string, string>;
unstable?: boolean;
bundle?: boolean;
options?: string;
}
interface CompilerRequestRuntimeTranspile {
type: CompilerRequestType.RuntimeTranspile;
sources: Record<string, string>;
options?: string;
}
type CompilerRequest =
| CompilerRequestCompile
| CompilerRequestRuntimeCompile
| CompilerRequestRuntimeTranspile;
interface CompileResult {
emitMap?: Record<string, EmmitedSource>;
bundleOutput?: string;
diagnostics: Diagnostic;
}
interface RuntimeCompileResult {
emitMap: Record<string, EmmitedSource>;
diagnostics: DiagnosticItem[];
}
interface RuntimeBundleResult {
output: string;
diagnostics: DiagnosticItem[];
}
async function compile(
request: CompilerRequestCompile
): Promise<CompileResult> {
const {
bundle,
config,
configPath,
rootNames,
target,
unstable,
cwd,
} = request;
util.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: WriteFileState = {
type: request.type,
emitMap: {},
bundle,
host: undefined,
rootNames,
};
let writeFile: WriteFileCallback;
if (bundle) {
writeFile = createBundleWriteFile(state);
} else {
writeFile = createCompileWriteFile(state);
}
const host = (state.host = new Host({
bundle,
target,
writeFile,
unstable,
}));
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) || [];
}
// This will recursively analyse all the code for other imports,
// requesting those from the privileged side, populating the in memory
// cache which will be used by the host, before resolving.
const specifiers = rootNames.map((rootName) => {
return { original: rootName, mapped: rootName };
});
const resolvedRootModules = await processImports(
specifiers,
undefined,
bundle || host.getCompilationSettings().checkJs
);
// 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,
oldProgram: TS_SNAPSHOT_PROGRAM,
});
diagnostics = ts
.getPreEmitDiagnostics(program)
.filter(({ code }) => !ignoredDiagnostics.includes(code));
// We will only proceed with the emit if there are no diagnostics.
if (diagnostics && diagnostics.length === 0) {
if (bundle) {
// we only support a single root module when bundling
assert(resolvedRootModules.length === 1);
setRootExports(program, resolvedRootModules[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 = undefined;
if (bundle) {
assert(state.bundleOutput);
bundleOutput = state.bundleOutput;
}
assert(state.emitMap);
const result: CompileResult = {
emitMap: state.emitMap,
bundleOutput,
diagnostics: fromTypeScriptDiagnostic(diagnostics),
};
util.log("<<< compile end", {
rootNames,
type: CompilerRequestType[request.type],
});
return result;
}
async function runtimeCompile(
request: CompilerRequestRuntimeCompile
): Promise<RuntimeCompileResult | RuntimeBundleResult> {
const { bundle, options, rootName, sources, target, unstable } = request;
util.log(">>> runtime compile start", {
rootName,
bundle,
sources: sources ? Object.keys(sources) : undefined,
});
// resolve the root name, if there are sources, the root name does not
// get resolved
const resolvedRootName = sources ? rootName : resolveModules([rootName])[0];
// if there are options, convert them into TypeScript compiler options,
// and resolve any external file references
let convertedOptions: ts.CompilerOptions | undefined;
let additionalFiles: string[] | undefined;
if (options) {
const result = convertCompilerOptions(options);
convertedOptions = result.options;
additionalFiles = result.files;
}
const checkJsImports =
bundle || (convertedOptions && convertedOptions.checkJs);
// recursively process imports, loading each file into memory. If there
// are sources, these files are pulled out of the there, otherwise the
// files are retrieved from the privileged side
const specifiers = [
{
original: resolvedRootName,
mapped: resolvedRootName,
},
];
const rootNames = sources
? processLocalImports(sources, specifiers, undefined, checkJsImports)
: await processImports(specifiers, undefined, checkJsImports);
if (additionalFiles) {
// any files supplied in the configuration are resolved externally,
// even if sources are provided
const resolvedNames = resolveModules(additionalFiles);
const resolvedSpecifiers = resolvedNames.map((rn) => {
return {
original: rn,
mapped: rn,
};
});
const additionalImports = await processImports(
resolvedSpecifiers,
undefined,
checkJsImports
);
rootNames.push(...additionalImports);
}
const state: WriteFileState = {
type: request.type,
bundle,
host: undefined,
rootNames,
sources,
emitMap: {},
bundleOutput: undefined,
};
let writeFile: WriteFileCallback;
if (bundle) {
writeFile = createBundleWriteFile(state);
} else {
writeFile = createCompileWriteFile(state);
}
const host = (state.host = new Host({
bundle,
target,
writeFile,
}));
const compilerOptions = [DEFAULT_RUNTIME_COMPILE_OPTIONS];
if (convertedOptions) {
compilerOptions.push(convertedOptions);
}
if (unstable) {
compilerOptions.push({
lib: [
"deno.unstable",
...((convertedOptions && convertedOptions.lib) || ["deno.window"]),
],
});
}
if (bundle) {
compilerOptions.push(DEFAULT_BUNDLER_OPTIONS);
}
host.mergeOptions(...compilerOptions);
const program = ts.createProgram({
rootNames,
options: host.getCompilationSettings(),
host,
oldProgram: TS_SNAPSHOT_PROGRAM,
});
if (bundle) {
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.");
assert(state.emitMap);
util.log("<<< runtime compile finish", {
rootName,
sources: sources ? Object.keys(sources) : undefined,
bundle,
emitMap: Object.keys(state.emitMap),
});
const maybeDiagnostics = diagnostics.length
? fromTypeScriptDiagnostic(diagnostics).items
: [];
if (bundle) {
return {
diagnostics: maybeDiagnostics,
output: state.bundleOutput,
} as RuntimeBundleResult;
} else {
return {
diagnostics: maybeDiagnostics,
emitMap: state.emitMap,
} as RuntimeCompileResult;
}
}
function runtimeTranspile(
request: CompilerRequestRuntimeTranspile
): 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 = await compile(request as CompilerRequestCompile);
globalThis.postMessage(result);
break;
}
case CompilerRequestType.RuntimeCompile: {
const result = await runtimeCompile(
request as CompilerRequestRuntimeCompile
);
globalThis.postMessage(result);
break;
}
case CompilerRequestType.RuntimeTranspile: {
const result = await runtimeTranspile(
request as CompilerRequestRuntimeTranspile
);
globalThis.postMessage(result);
break;
}
default:
util.log(
`!!! unhandled CompilerRequestType: ${
(request as CompilerRequest).type
} (${CompilerRequestType[(request as CompilerRequest).type]})`
);
}
// Currently Rust shuts down worker after single request
}
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,
},
});