1
0
Fork 0
mirror of https://github.com/denoland/deno.git synced 2024-11-13 16:26:08 -05:00
denoland-deno/js/compiler.ts
2018-11-01 19:33:18 -07:00

770 lines
27 KiB
TypeScript

// Copyright 2018 the Deno authors. All rights reserved. MIT license.
import * as ts from "typescript";
import { MediaType } from "gen/msg_generated";
import { assetSourceCode } from "./assets";
// tslint:disable-next-line:no-circular-imports
import * as deno from "./deno";
import { globalEval } from "./global_eval";
import { libdeno } from "./libdeno";
import { window } from "./globals";
import * as os from "./os";
import { RawSourceMap } from "./types";
import { assert, log, notImplemented } from "./util";
import * as sourceMaps from "./v8_source_maps";
const EOL = "\n";
const ASSETS = "$asset$";
const LIB_RUNTIME = "lib.deno_runtime.d.ts";
// tslint:disable:no-any
type AmdCallback = (...args: any[]) => void;
type AmdErrback = (err: any) => void;
export type AmdFactory = (...args: any[]) => object | void;
// tslint:enable:no-any
export type AmdDefine = (deps: ModuleSpecifier[], factory: AmdFactory) => void;
type AMDRequire = (
deps: ModuleSpecifier[],
callback: AmdCallback,
errback: AmdErrback
) => void;
/** The location that a module is being loaded from. This could be a directory,
* like `.`, or it could be a module specifier like
* `http://gist.github.com/somefile.ts`
*/
type ContainingFile = string;
/** The internal local filename of a compiled module. It will often be something
* like `/home/ry/.deno/gen/f7b4605dfbc4d3bb356e98fda6ceb1481e4a8df5.js`
*/
type ModuleFileName = string;
/** The original resolved resource name.
* Path to cached module file or URL from which dependency was retrieved
*/
type ModuleId = string;
/** The external name of a module - could be a URL or could be a relative path.
* Examples `http://gist.github.com/somefile.ts` or `./somefile.ts`
*/
type ModuleSpecifier = string;
/** The compiled source code which is cached in `.deno/gen/` */
type OutputCode = string;
/** The original source code */
type SourceCode = string;
/** The output source map */
type SourceMap = string;
/** Abstraction of the APIs required from the `os` module so they can be
* easily mocked.
* @internal
*/
export interface Os {
codeCache: typeof os.codeCache;
codeFetch: typeof os.codeFetch;
exit: typeof os.exit;
}
/** Abstraction of the APIs required from the `typescript` module so they can
* be easily mocked.
* @internal
*/
export interface Ts {
createLanguageService: typeof ts.createLanguageService;
/* tslint:disable-next-line:max-line-length */
formatDiagnosticsWithColorAndContext: typeof ts.formatDiagnosticsWithColorAndContext;
}
/** A simple object structure for caching resolved modules and their contents.
*
* Named `ModuleMetaData` to clarify it is just a representation of meta data of
* the module, not the actual module instance.
*/
export class ModuleMetaData implements ts.IScriptSnapshot {
public deps?: ModuleFileName[];
public exports = {};
public factory?: AmdFactory;
public gatheringDeps = false;
public hasRun = false;
public scriptVersion = "";
constructor(
public readonly moduleId: ModuleId,
public readonly fileName: ModuleFileName,
public readonly mediaType: MediaType,
public readonly sourceCode: SourceCode = "",
public outputCode: OutputCode = "",
public sourceMap: SourceMap = ""
) {
if (outputCode !== "" || fileName.endsWith(".d.ts")) {
this.scriptVersion = "1";
}
}
public getText(start: number, end: number): string {
return this.sourceCode.substring(start, end);
}
public getLength(): number {
return this.sourceCode.length;
}
public getChangeRange(): undefined {
// Required `IScriptSnapshot` API, but not implemented/needed in deno
return undefined;
}
}
function getExtension(
fileName: ModuleFileName,
mediaType: MediaType
): ts.Extension | undefined {
switch (mediaType) {
case MediaType.JavaScript:
return ts.Extension.Js;
case MediaType.TypeScript:
return fileName.endsWith(".d.ts") ? ts.Extension.Dts : ts.Extension.Ts;
case MediaType.Json:
return ts.Extension.Json;
case MediaType.Unknown:
default:
return undefined;
}
}
/** Generate output code for a provided JSON string along with its source. */
export function jsonAmdTemplate(
jsonString: string,
sourceFileName: string
): OutputCode {
// tslint:disable-next-line:max-line-length
return `define([], function() { return JSON.parse(\`${jsonString}\`); });\n//# sourceURL=${sourceFileName}`;
}
/** A singleton class that combines the TypeScript Language Service host API
* with Deno specific APIs to provide an interface for compiling and running
* TypeScript and JavaScript modules.
*/
export class DenoCompiler
implements ts.LanguageServiceHost, ts.FormatDiagnosticsHost {
// Modules are usually referenced by their ModuleSpecifier and ContainingFile,
// and keeping a map of the resolved module file name allows more efficient
// future resolution
private readonly _fileNamesMap = new Map<
ContainingFile,
Map<ModuleSpecifier, ModuleFileName>
>();
// A reference to global eval, so it can be monkey patched during testing
private _globalEval = globalEval;
// A reference to the log utility, so it can be monkey patched during testing
private _log = log;
// A map of module file names to module meta data
private readonly _moduleMetaDataMap = new Map<
ModuleFileName,
ModuleMetaData
>();
// TODO ideally this are not static and can be influenced by command line
// arguments
private readonly _options: ts.CompilerOptions = {
allowJs: true,
checkJs: true,
module: ts.ModuleKind.AMD,
outDir: "$deno$",
resolveJsonModule: true,
sourceMap: true,
stripComments: true,
target: ts.ScriptTarget.ESNext
};
// A reference to the `./os.ts` module, so it can be monkey patched during
// testing
private _os: Os = os;
// Contains a queue of modules that have been resolved, but not yet
// run
private _runQueue: ModuleMetaData[] = [];
// Used to contain the script file we are currently running
private _scriptFileNames: string[] = [];
// A reference to the TypeScript LanguageService instance so it can be
// monkey patched during testing
private _service: ts.LanguageService;
// A reference to `typescript` module so it can be monkey patched during
// testing
private _ts: Ts = ts;
// A reference to the global scope so it can be monkey patched during
// testing
private _window = window;
// Flags forcing recompilation of TS code
public recompile = false;
/** Drain the run queue, retrieving the arguments for the module
* factory and calling the module's factory.
*/
private _drainRunQueue(): void {
this._log(
"compiler._drainRunQueue",
this._runQueue.map(metaData => metaData.fileName)
);
let moduleMetaData: ModuleMetaData | undefined;
while ((moduleMetaData = this._runQueue.shift())) {
assert(
moduleMetaData.factory != null,
"Cannot run module without factory."
);
assert(moduleMetaData.hasRun === false, "Module has already been run.");
// asserts not tracked by TypeScripts, so using not null operator
const exports = moduleMetaData.factory!(
...this._getFactoryArguments(moduleMetaData)
);
// For JSON module support and potential future features.
// TypeScript always imports `exports` and mutates it directly, but the
// AMD specification allows values to be returned from the factory.
if (exports != null) {
moduleMetaData.exports = exports;
}
moduleMetaData.hasRun = true;
}
}
/** Get the dependencies for a given module, but don't run the module,
* just add the module factory to the run queue.
*/
private _gatherDependencies(moduleMetaData: ModuleMetaData): void {
this._log("compiler._resolveDependencies", moduleMetaData.fileName);
// if the module has already run, we can short circuit.
// it is intentional though that if we have already resolved dependencies,
// we won't short circuit, as something may have changed, or we might have
// only collected the dependencies to be able to able to obtain the graph of
// dependencies
if (moduleMetaData.hasRun) {
return;
}
this._window.define = this._makeDefine(moduleMetaData);
this._globalEval(this.compile(moduleMetaData));
this._window.define = undefined;
}
/** Retrieve the arguments to pass a module's factory function. */
// tslint:disable-next-line:no-any
private _getFactoryArguments(moduleMetaData: ModuleMetaData): any[] {
if (!moduleMetaData.deps) {
throw new Error("Cannot get arguments until dependencies resolved.");
}
return moduleMetaData.deps.map(dep => {
if (dep === "require") {
return this._makeLocalRequire(moduleMetaData);
}
if (dep === "exports") {
return moduleMetaData.exports;
}
if (dep in DenoCompiler._builtins) {
return DenoCompiler._builtins[dep];
}
const dependencyMetaData = this._getModuleMetaData(dep);
assert(dependencyMetaData != null, `Missing dependency "${dep}".`);
// TypeScript does not track assert, therefore using not null operator
return dependencyMetaData!.exports;
});
}
/** The TypeScript language service often refers to the resolved fileName of
* a module, this is a shortcut to avoid unnecessary module resolution logic
* for modules that may have been initially resolved by a `moduleSpecifier`
* and `containingFile`. Also, `resolveModule()` throws when the module
* cannot be resolved, which isn't always valid when dealing with the
* TypeScript compiler, but the TypeScript compiler shouldn't be asking about
* external modules that we haven't told it about yet.
*/
private _getModuleMetaData(
fileName: ModuleFileName
): ModuleMetaData | undefined {
return this._moduleMetaDataMap.has(fileName)
? this._moduleMetaDataMap.get(fileName)
: fileName.startsWith(ASSETS)
? this.resolveModule(fileName, "")
: undefined;
}
/** Create a localized AMD `define` function and return it. */
private _makeDefine(moduleMetaData: ModuleMetaData): AmdDefine {
return (deps: ModuleSpecifier[], factory: AmdFactory): void => {
this._log("compiler.localDefine", moduleMetaData.fileName);
moduleMetaData.factory = factory;
// when there are circular dependencies, we need to skip recursing the
// dependencies
moduleMetaData.gatheringDeps = true;
// we will recursively resolve the dependencies for any modules
moduleMetaData.deps = deps.map(dep => {
if (
dep === "require" ||
dep === "exports" ||
dep in DenoCompiler._builtins
) {
return dep;
}
const dependencyMetaData = this.resolveModule(
dep,
moduleMetaData.fileName
);
if (!dependencyMetaData.gatheringDeps) {
this._gatherDependencies(dependencyMetaData);
}
return dependencyMetaData.fileName;
});
moduleMetaData.gatheringDeps = false;
if (!this._runQueue.includes(moduleMetaData)) {
this._runQueue.push(moduleMetaData);
}
};
}
/** Returns a require that specifically handles the resolution of a transpiled
* emit of a dynamic ES `import()` from TypeScript.
*/
private _makeLocalRequire(moduleMetaData: ModuleMetaData): AMDRequire {
return (
deps: ModuleSpecifier[],
callback: AmdCallback,
errback: AmdErrback
): void => {
log("localRequire", deps);
assert(
deps.length === 1,
"Local require requires exactly one dependency."
);
const [moduleSpecifier] = deps;
try {
const requiredMetaData = this.run(
moduleSpecifier,
moduleMetaData.fileName
);
callback(requiredMetaData.exports);
} catch (e) {
errback(e);
}
};
}
/** Given a `moduleSpecifier` and `containingFile` retrieve the cached
* `fileName` for a given module. If the module has yet to be resolved
* this will return `undefined`.
*/
private _resolveFileName(
moduleSpecifier: ModuleSpecifier,
containingFile: ContainingFile
): ModuleFileName | undefined {
this._log("compiler.resolveFileName", { moduleSpecifier, containingFile });
const innerMap = this._fileNamesMap.get(containingFile);
if (innerMap) {
return innerMap.get(moduleSpecifier);
}
return undefined;
}
/** Caches the resolved `fileName` in relationship to the `moduleSpecifier`
* and `containingFile` in order to reduce calls to the privileged side
* to retrieve the contents of a module.
*/
private _setFileName(
moduleSpecifier: ModuleSpecifier,
containingFile: ContainingFile,
fileName: ModuleFileName
): void {
this._log("compiler.setFileName", { moduleSpecifier, containingFile });
let innerMap = this._fileNamesMap.get(containingFile);
if (!innerMap) {
innerMap = new Map();
this._fileNamesMap.set(containingFile, innerMap);
}
innerMap.set(moduleSpecifier, fileName);
}
/** Setup being able to map back source references back to their source
*
* TODO is this the best place for this? It is tightly coupled to how the
* compiler works, but it is also tightly coupled to how the whole runtime
* environment is bootstrapped. It also needs efficient access to the
* `outputCode` of the module information, which exists inside of the
* compiler instance.
*/
private _setupSourceMaps(): void {
let lastModule: ModuleMetaData | undefined;
sourceMaps.install({
installPrepareStackTrace: true,
getGeneratedContents: (fileName: string): string | RawSourceMap => {
this._log("compiler.getGeneratedContents", fileName);
if (fileName === "gen/bundle/main.js") {
assert(libdeno.mainSource.length > 0);
return libdeno.mainSource;
} else if (fileName === "main.js.map") {
return libdeno.mainSourceMap;
} else if (fileName === "deno_main.js") {
return "";
} else if (!fileName.endsWith(".map")) {
const moduleMetaData = this._moduleMetaDataMap.get(fileName);
if (!moduleMetaData) {
lastModule = undefined;
return "";
}
lastModule = moduleMetaData;
return moduleMetaData.outputCode;
} else {
if (lastModule && lastModule.sourceMap) {
// Assuming the the map will always be asked for after the source
// code.
const { sourceMap } = lastModule;
lastModule = undefined;
return sourceMap;
} else {
// Errors thrown here are caught by source-map.
throw new Error(`Unable to find source map: "${fileName}"`);
}
}
}
});
}
private constructor() {
if (DenoCompiler._instance) {
throw new TypeError("Attempt to create an additional compiler.");
}
this._service = this._ts.createLanguageService(this);
this._setupSourceMaps();
}
// Deno specific compiler API
/** Retrieve the output of the TypeScript compiler for a given module and
* cache the result. Re-compilation can be forced using '--recompile' flag.
*/
compile(moduleMetaData: ModuleMetaData): OutputCode {
const recompile = !!this.recompile;
if (!recompile && moduleMetaData.outputCode) {
return moduleMetaData.outputCode;
}
const { fileName, sourceCode, mediaType, moduleId } = moduleMetaData;
console.warn("Compiling", moduleId);
// Instead of using TypeScript to transpile JSON modules, we will just do
// it directly.
if (mediaType === MediaType.Json) {
moduleMetaData.outputCode = jsonAmdTemplate(sourceCode, fileName);
} else {
const service = this._service;
assert(
mediaType === MediaType.TypeScript || mediaType === MediaType.JavaScript
);
const output = service.getEmitOutput(fileName);
// Get the relevant diagnostics - this is 3x faster than
// `getPreEmitDiagnostics`.
const diagnostics = [
// 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.
...service
.getCompilerOptionsDiagnostics()
.filter(diagnostic => diagnostic.code !== 5070),
...service.getSyntacticDiagnostics(fileName),
...service.getSemanticDiagnostics(fileName)
];
if (diagnostics.length > 0) {
const errMsg = this._ts.formatDiagnosticsWithColorAndContext(
diagnostics,
this
);
console.log(errMsg);
// All TypeScript errors are terminal for deno
this._os.exit(1);
}
assert(
!output.emitSkipped,
"The emit was skipped for an unknown reason."
);
assert(
output.outputFiles.length === 2,
`Expected 2 files to be emitted, got ${output.outputFiles.length}.`
);
const [sourceMapFile, outputFile] = output.outputFiles;
assert(
sourceMapFile.name.endsWith(".map"),
"Expected first emitted file to be a source map"
);
assert(
outputFile.name.endsWith(".js"),
"Expected second emitted file to be JavaScript"
);
moduleMetaData.outputCode = `${
outputFile.text
}\n//# sourceURL=${fileName}`;
moduleMetaData.sourceMap = sourceMapFile.text;
}
moduleMetaData.scriptVersion = "1";
this._os.codeCache(
fileName,
sourceCode,
moduleMetaData.outputCode,
moduleMetaData.sourceMap
);
return moduleMetaData.outputCode;
}
/** For a given module specifier and containing file, return a list of
* absolute identifiers for dependent modules that are required by this
* module.
*/
getModuleDependencies(
moduleSpecifier: ModuleSpecifier,
containingFile: ContainingFile
): ModuleFileName[] {
assert(
this._runQueue.length === 0,
"Cannot get dependencies with modules queued to be run."
);
const moduleMetaData = this.resolveModule(moduleSpecifier, containingFile);
assert(
!moduleMetaData.hasRun,
"Cannot get dependencies for a module that has already been run."
);
this._gatherDependencies(moduleMetaData);
const dependencies = this._runQueue.map(
moduleMetaData => moduleMetaData.moduleId
);
// empty the run queue, to free up references to factories we have collected
// and to ensure that if there is a further invocation of `.run()` the
// factories don't get called
this._runQueue = [];
return dependencies;
}
/** Given a `moduleSpecifier` and `containingFile`, resolve the module and
* return the `ModuleMetaData`.
*/
resolveModule(
moduleSpecifier: ModuleSpecifier,
containingFile: ContainingFile
): ModuleMetaData {
this._log("compiler.resolveModule", { moduleSpecifier, containingFile });
assert(moduleSpecifier != null && moduleSpecifier.length > 0);
let fileName = this._resolveFileName(moduleSpecifier, containingFile);
if (fileName && this._moduleMetaDataMap.has(fileName)) {
return this._moduleMetaDataMap.get(fileName)!;
}
let moduleId: ModuleId | undefined;
let mediaType = MediaType.Unknown;
let sourceCode: SourceCode | undefined;
let outputCode: OutputCode | undefined;
let sourceMap: SourceMap | undefined;
if (
moduleSpecifier.startsWith(ASSETS) ||
containingFile.startsWith(ASSETS)
) {
// Assets are compiled into the runtime javascript bundle.
// we _know_ `.pop()` will return a string, but TypeScript doesn't so
// not null assertion
moduleId = moduleSpecifier.split("/").pop()!;
const assetName = moduleId.includes(".") ? moduleId : `${moduleId}.d.ts`;
assert(assetName in assetSourceCode, `No such asset "${assetName}"`);
mediaType = MediaType.TypeScript;
sourceCode = assetSourceCode[assetName];
fileName = `${ASSETS}/${assetName}`;
outputCode = "";
sourceMap = "";
} else {
// We query Rust with a CodeFetch message. It will load the sourceCode,
// and if there is any outputCode cached, will return that as well.
const fetchResponse = this._os.codeFetch(moduleSpecifier, containingFile);
moduleId = fetchResponse.moduleName;
fileName = fetchResponse.filename;
mediaType = fetchResponse.mediaType;
sourceCode = fetchResponse.sourceCode;
outputCode = fetchResponse.outputCode;
sourceMap = fetchResponse.sourceMap;
}
assert(moduleId != null, "No module ID.");
assert(fileName != null, "No file name.");
assert(sourceCode ? sourceCode.length > 0 : false, "No source code.");
assert(
mediaType !== MediaType.Unknown,
`Unknown media type for: "${moduleSpecifier}" from "${containingFile}".`
);
this._log(
"resolveModule sourceCode length:",
sourceCode && sourceCode.length
);
this._log("resolveModule has outputCode:", outputCode != null);
this._log("resolveModule has source map:", sourceMap != null);
this._log("resolveModule has media type:", MediaType[mediaType]);
// fileName is asserted above, but TypeScript does not track so not null
this._setFileName(moduleSpecifier, containingFile, fileName!);
if (fileName && this._moduleMetaDataMap.has(fileName)) {
return this._moduleMetaDataMap.get(fileName)!;
}
const moduleMetaData = new ModuleMetaData(
moduleId!,
fileName!,
mediaType,
sourceCode,
outputCode,
sourceMap
);
this._moduleMetaDataMap.set(fileName!, moduleMetaData);
return moduleMetaData;
}
/** Load and run a module and all of its dependencies based on a module
* specifier and a containing file
*/
run(
moduleSpecifier: ModuleSpecifier,
containingFile: ContainingFile
): ModuleMetaData {
this._log("compiler.run", { moduleSpecifier, containingFile });
const moduleMetaData = this.resolveModule(moduleSpecifier, containingFile);
this._scriptFileNames = [moduleMetaData.fileName];
if (!moduleMetaData.deps) {
this._gatherDependencies(moduleMetaData);
}
this._drainRunQueue();
return moduleMetaData;
}
// TypeScript Language Service and Format Diagnostic Host API
getCanonicalFileName(fileName: string): string {
this._log("getCanonicalFileName", fileName);
return fileName;
}
getCompilationSettings(): ts.CompilerOptions {
this._log("getCompilationSettings()");
return this._options;
}
getNewLine(): string {
return EOL;
}
getScriptFileNames(): string[] {
// This is equal to `"files"` in the `tsconfig.json`, therefore we only need
// to include the actual base source files we are evaluating at the moment,
// which would be what is set during the `.run()`
return this._scriptFileNames;
}
getScriptKind(fileName: ModuleFileName): ts.ScriptKind {
this._log("getScriptKind()", fileName);
const moduleMetaData = this._getModuleMetaData(fileName);
if (moduleMetaData) {
switch (moduleMetaData.mediaType) {
case MediaType.TypeScript:
return ts.ScriptKind.TS;
case MediaType.JavaScript:
return ts.ScriptKind.JS;
case MediaType.Json:
return ts.ScriptKind.JSON;
default:
return this._options.allowJs ? ts.ScriptKind.JS : ts.ScriptKind.TS;
}
} else {
return this._options.allowJs ? ts.ScriptKind.JS : ts.ScriptKind.TS;
}
}
getScriptVersion(fileName: ModuleFileName): string {
this._log("getScriptVersion()", fileName);
const moduleMetaData = this._getModuleMetaData(fileName);
return (moduleMetaData && moduleMetaData.scriptVersion) || "";
}
getScriptSnapshot(fileName: ModuleFileName): ts.IScriptSnapshot | undefined {
this._log("getScriptSnapshot()", fileName);
return this._getModuleMetaData(fileName);
}
getCurrentDirectory(): string {
this._log("getCurrentDirectory()");
return "";
}
getDefaultLibFileName(): string {
this._log("getDefaultLibFileName()");
const moduleSpecifier = LIB_RUNTIME;
const moduleMetaData = this.resolveModule(moduleSpecifier, ASSETS);
return moduleMetaData.fileName;
}
useCaseSensitiveFileNames(): boolean {
this._log("useCaseSensitiveFileNames()");
return true;
}
readFile(path: string): string | undefined {
this._log("readFile()", path);
return notImplemented();
}
fileExists(fileName: string): boolean {
const moduleMetaData = this._getModuleMetaData(fileName);
const exists = moduleMetaData != null;
this._log("fileExists()", fileName, exists);
return exists;
}
resolveModuleNames(
moduleNames: ModuleSpecifier[],
containingFile: ContainingFile
): Array<ts.ResolvedModuleFull | ts.ResolvedModule> {
this._log("resolveModuleNames()", { moduleNames, containingFile });
return moduleNames.map(name => {
let moduleMetaData: ModuleMetaData;
if (name === "deno") {
// builtin modules are part of the runtime lib
moduleMetaData = this.resolveModule(LIB_RUNTIME, ASSETS);
} else if (name === "typescript") {
moduleMetaData = this.resolveModule("typescript.d.ts", ASSETS);
} else {
moduleMetaData = this.resolveModule(name, containingFile);
}
// According to the interface we shouldn't return `undefined` but if we
// fail to return the same length of modules to those we cannot resolve
// then TypeScript fails on an assertion that the lengths can't be
// different, so we have to return an "empty" resolved module
// TODO: all this does is push the problem downstream, and TypeScript
// will complain it can't identify the type of the file and throw
// a runtime exception, so we need to handle missing modules better
const resolvedFileName = moduleMetaData.fileName || "";
// This flags to the compiler to not go looking to transpile functional
// code, anything that is in `/$asset$/` is just library code
const isExternalLibraryImport = resolvedFileName.startsWith(ASSETS);
return {
resolvedFileName,
isExternalLibraryImport,
extension: getExtension(resolvedFileName, moduleMetaData.mediaType)
};
});
}
// Deno specific static properties and methods
/** Built in modules which can be returned to external modules
*
* Placed as a private static otherwise we get use before
* declared with the `DenoCompiler`
*/
// tslint:disable-next-line:no-any
private static _builtins: { [mid: string]: any } = {
typescript: ts,
deno
};
private static _instance: DenoCompiler | undefined;
/** Returns the instance of `DenoCompiler` or creates a new instance. */
static instance(): DenoCompiler {
return (
DenoCompiler._instance || (DenoCompiler._instance = new DenoCompiler())
);
}
}