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denoland-deno/ext/node/polyfills/internal/child_process.ts
Nathan Whitaker 4b022103a1
chore: Revert child_process close ordering change (#25781)
From
https://github.com/denoland/deno/commit/18b89d948dcb849c4dc577478794c3d5fb23b59

May have caused the recent flakiness of
parallel/test-child-process-ipc-next-tick.js
2024-09-20 23:46:42 +00:00

1445 lines
36 KiB
TypeScript

// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
// This module implements 'child_process' module of Node.JS API.
// ref: https://nodejs.org/api/child_process.html
// TODO(petamoriken): enable prefer-primordials for node polyfills
// deno-lint-ignore-file prefer-primordials
import { core, internals } from "ext:core/mod.js";
import {
op_node_ipc_read,
op_node_ipc_ref,
op_node_ipc_unref,
op_node_ipc_write,
} from "ext:core/ops";
import {
ArrayIsArray,
ArrayPrototypeFilter,
ArrayPrototypeJoin,
ArrayPrototypePush,
ArrayPrototypeSlice,
ArrayPrototypeSort,
ArrayPrototypeUnshift,
ObjectHasOwn,
StringPrototypeStartsWith,
StringPrototypeToUpperCase,
} from "ext:deno_node/internal/primordials.mjs";
import { assert } from "ext:deno_node/_util/asserts.ts";
import { EventEmitter } from "node:events";
import { os } from "ext:deno_node/internal_binding/constants.ts";
import { notImplemented } from "ext:deno_node/_utils.ts";
import { Readable, Stream, Writable } from "node:stream";
import { isWindows } from "ext:deno_node/_util/os.ts";
import { nextTick } from "ext:deno_node/_next_tick.ts";
import {
AbortError,
ERR_INVALID_ARG_TYPE,
ERR_INVALID_ARG_VALUE,
ERR_IPC_CHANNEL_CLOSED,
ERR_UNKNOWN_SIGNAL,
} from "ext:deno_node/internal/errors.ts";
import { Buffer } from "node:buffer";
import { errnoException } from "ext:deno_node/internal/errors.ts";
import { ErrnoException } from "ext:deno_node/_global.d.ts";
import { codeMap } from "ext:deno_node/internal_binding/uv.ts";
import {
isInt32,
validateBoolean,
validateObject,
validateString,
} from "ext:deno_node/internal/validators.mjs";
import { kEmptyObject } from "ext:deno_node/internal/util.mjs";
import { getValidatedPath } from "ext:deno_node/internal/fs/utils.mjs";
import process from "node:process";
import { StringPrototypeSlice } from "ext:deno_node/internal/primordials.mjs";
import { StreamBase } from "ext:deno_node/internal_binding/stream_wrap.ts";
import { Pipe, socketType } from "ext:deno_node/internal_binding/pipe_wrap.ts";
import { Socket } from "node:net";
import { kDetached, kExtraStdio, kIpc } from "ext:runtime/40_process.js";
export function mapValues<T, O>(
record: Readonly<Record<string, T>>,
transformer: (value: T) => O,
): Record<string, O> {
const ret: Record<string, O> = {};
const entries = Object.entries(record);
for (const [key, value] of entries) {
if (typeof value === "undefined") {
continue;
}
if (value === null) {
continue;
}
const mappedValue = transformer(value);
ret[key] = mappedValue;
}
return ret;
}
type NodeStdio = "pipe" | "overlapped" | "ignore" | "inherit" | "ipc";
type DenoStdio = "inherit" | "piped" | "null";
export function stdioStringToArray(
stdio: NodeStdio,
channel: NodeStdio | number,
) {
const options: (NodeStdio | number)[] = [];
switch (stdio) {
case "ignore":
case "overlapped":
case "pipe":
options.push(stdio, stdio, stdio);
break;
case "inherit":
options.push(stdio, stdio, stdio);
break;
default:
throw new ERR_INVALID_ARG_VALUE("stdio", stdio);
}
if (channel) options.push(channel);
return options;
}
const kClosesNeeded = Symbol("_closesNeeded");
const kClosesReceived = Symbol("_closesReceived");
const kCanDisconnect = Symbol("_canDisconnect");
// We only want to emit a close event for the child process when all of
// the writable streams have closed. The value of `child[kClosesNeeded]` should be 1 +
// the number of opened writable streams (note this excludes `stdin`).
function maybeClose(child: ChildProcess) {
child[kClosesReceived]++;
if (child[kClosesNeeded] === child[kClosesReceived]) {
child.emit("close", child.exitCode, child.signalCode);
}
}
function flushStdio(subprocess: ChildProcess) {
const stdio = subprocess.stdio;
if (stdio == null) return;
for (let i = 0; i < stdio.length; i++) {
const stream = stdio[i];
if (!stream || !stream.readable) {
continue;
}
stream.resume();
}
}
// Wraps a resource in a class that implements
// StreamBase, so it can be used with node streams
class StreamResource implements StreamBase {
#rid: number;
constructor(rid: number) {
this.#rid = rid;
}
close(): void {
core.close(this.#rid);
}
async read(p: Uint8Array): Promise<number | null> {
const readPromise = core.read(this.#rid, p);
core.unrefOpPromise(readPromise);
const nread = await readPromise;
return nread > 0 ? nread : null;
}
ref(): void {
return;
}
unref(): void {
return;
}
write(p: Uint8Array): Promise<number> {
return core.write(this.#rid, p);
}
}
export class ChildProcess extends EventEmitter {
/**
* The exit code of the child process. This property will be `null` until the child process exits.
*/
exitCode: number | null = null;
/**
* This property is set to `true` after `kill()` is called.
*/
killed = false;
/**
* The PID of this child process.
*/
pid!: number;
/**
* The signal received by this child process.
*/
signalCode: string | null = null;
/**
* Command line arguments given to this child process.
*/
spawnargs: string[];
/**
* The executable file name of this child process.
*/
spawnfile: string;
/**
* This property represents the child process's stdin.
*/
stdin: Writable | null = null;
/**
* This property represents the child process's stdout.
*/
stdout: Readable | null = null;
/**
* This property represents the child process's stderr.
*/
stderr: Readable | null = null;
/**
* Pipes to this child process.
*/
stdio: [Writable | null, Readable | null, Readable | null] = [
null,
null,
null,
];
disconnect?: () => void;
#process!: Deno.ChildProcess;
#spawned = Promise.withResolvers<void>();
[kClosesNeeded] = 1;
[kClosesReceived] = 0;
[kCanDisconnect] = false;
constructor(
command: string,
args?: string[],
options?: ChildProcessOptions,
) {
super();
const {
env = {},
stdio = ["pipe", "pipe", "pipe"],
cwd,
shell = false,
signal,
windowsVerbatimArguments = false,
detached,
} = options || {};
const normalizedStdio = normalizeStdioOption(stdio);
const [
stdin = "pipe",
stdout = "pipe",
stderr = "pipe",
...extraStdio
] = normalizedStdio;
const [cmd, cmdArgs] = buildCommand(
command,
args || [],
shell,
);
this.spawnfile = cmd;
this.spawnargs = [cmd, ...cmdArgs];
const ipc = normalizedStdio.indexOf("ipc");
const extraStdioOffset = 3; // stdin, stdout, stderr
const extraStdioNormalized: DenoStdio[] = [];
for (let i = 0; i < extraStdio.length; i++) {
const fd = i + extraStdioOffset;
if (fd === ipc) extraStdioNormalized.push("null");
extraStdioNormalized.push(toDenoStdio(extraStdio[i]));
}
const stringEnv = mapValues(env, (value) => value.toString());
try {
this.#process = new Deno.Command(cmd, {
args: cmdArgs,
cwd,
env: stringEnv,
stdin: toDenoStdio(stdin),
stdout: toDenoStdio(stdout),
stderr: toDenoStdio(stderr),
windowsRawArguments: windowsVerbatimArguments,
[kIpc]: ipc, // internal
[kExtraStdio]: extraStdioNormalized,
[kDetached]: detached,
}).spawn();
this.pid = this.#process.pid;
if (stdin === "pipe") {
assert(this.#process.stdin);
this.stdin = Writable.fromWeb(this.#process.stdin);
}
if (stdin instanceof Stream) {
this.stdin = stdin;
}
if (stdout instanceof Stream) {
this.stdout = stdout;
}
if (stderr instanceof Stream) {
this.stderr = stderr;
}
if (stdout === "pipe") {
assert(this.#process.stdout);
this[kClosesNeeded]++;
this.stdout = Readable.fromWeb(this.#process.stdout);
this.stdout.on("close", () => {
maybeClose(this);
});
}
if (stderr === "pipe") {
assert(this.#process.stderr);
this[kClosesNeeded]++;
this.stderr = Readable.fromWeb(this.#process.stderr);
this.stderr.on("close", () => {
maybeClose(this);
});
}
this.stdio[0] = this.stdin;
this.stdio[1] = this.stdout;
this.stdio[2] = this.stderr;
if (ipc >= 0) {
this.stdio[ipc] = null;
}
const pipeRids = internals.getExtraPipeRids(this.#process);
for (let i = 0; i < pipeRids.length; i++) {
const rid: number | null = pipeRids[i];
const fd = i + extraStdioOffset;
if (rid) {
this[kClosesNeeded]++;
this.stdio[fd] = new Socket(
{
handle: new Pipe(
socketType.IPC,
new StreamResource(rid),
),
// deno-lint-ignore no-explicit-any
} as any,
);
this.stdio[fd]?.on("close", () => {
maybeClose(this);
});
}
}
nextTick(() => {
this.emit("spawn");
this.#spawned.resolve();
});
if (signal) {
const onAbortListener = () => {
try {
if (this.kill("SIGKILL")) {
this.emit("error", new AbortError());
}
} catch (err) {
this.emit("error", err);
}
};
if (signal.aborted) {
nextTick(onAbortListener);
} else {
signal.addEventListener("abort", onAbortListener, { once: true });
this.addListener(
"exit",
() => signal.removeEventListener("abort", onAbortListener),
);
}
}
const pipeRid = internals.getIpcPipeRid(this.#process);
if (typeof pipeRid == "number") {
setupChannel(this, pipeRid);
this[kClosesNeeded]++;
this.on("disconnect", () => {
maybeClose(this);
});
}
(async () => {
const status = await this.#process.status;
this.exitCode = status.code;
this.#spawned.promise.then(async () => {
const exitCode = this.signalCode == null ? this.exitCode : null;
const signalCode = this.signalCode == null ? null : this.signalCode;
// The 'exit' and 'close' events must be emitted after the 'spawn' event.
this.emit("exit", exitCode, signalCode);
await this.#_waitForChildStreamsToClose();
this.#closePipes();
maybeClose(this);
nextTick(flushStdio, this);
});
})();
} catch (err) {
let e = err;
if (e instanceof Deno.errors.NotFound) {
e = _createSpawnSyncError("ENOENT", command, args);
}
this.#_handleError(e);
}
}
/**
* @param signal NOTE: this parameter is not yet implemented.
*/
kill(signal?: number | string): boolean {
if (this.killed) {
return this.killed;
}
const denoSignal = signal == null ? "SIGTERM" : toDenoSignal(signal);
this.#closePipes();
try {
this.#process.kill(denoSignal);
} catch (err) {
const alreadyClosed = err instanceof TypeError ||
err instanceof Deno.errors.PermissionDenied;
if (!alreadyClosed) {
throw err;
}
}
/* Cancel any pending IPC I/O */
if (this[kCanDisconnect]) {
this.disconnect?.();
}
this.killed = true;
this.signalCode = denoSignal;
return this.killed;
}
ref() {
this.#process.ref();
}
unref() {
this.#process.unref();
}
async #_waitForChildStreamsToClose() {
const promises = [] as Array<Promise<void>>;
// Don't close parent process stdin if that's passed through
if (this.stdin && !this.stdin.destroyed && this.stdin !== process.stdin) {
assert(this.stdin);
this.stdin.destroy();
promises.push(waitForStreamToClose(this.stdin));
}
// Only readable streams need to be closed
if (
this.stdout && !this.stdout.destroyed && this.stdout instanceof Readable
) {
promises.push(waitForReadableToClose(this.stdout));
}
// Only readable streams need to be closed
if (
this.stderr && !this.stderr.destroyed && this.stderr instanceof Readable
) {
promises.push(waitForReadableToClose(this.stderr));
}
await Promise.all(promises);
}
#_handleError(err: unknown) {
nextTick(() => {
this.emit("error", err); // TODO(uki00a) Convert `err` into nodejs's `SystemError` class.
});
}
#closePipes() {
if (this.stdin) {
assert(this.stdin);
this.stdin.destroy();
}
}
}
const supportedNodeStdioTypes: NodeStdio[] = [
"pipe",
"ignore",
"inherit",
"ipc",
];
function toDenoStdio(
pipe: NodeStdio | number | Stream | null | undefined,
): DenoStdio {
if (pipe instanceof Stream) {
return "inherit";
}
if (typeof pipe === "number") {
/* Assume it's a rid returned by fs APIs */
return pipe;
}
if (
!supportedNodeStdioTypes.includes(pipe as NodeStdio)
) {
notImplemented(`toDenoStdio pipe=${typeof pipe} (${pipe})`);
}
switch (pipe) {
case "pipe":
case undefined:
case null:
return "piped";
case "ignore":
return "null";
case "inherit":
return "inherit";
case "ipc":
return "ipc_for_internal_use";
default:
notImplemented(`toDenoStdio pipe=${typeof pipe} (${pipe})`);
}
}
function toDenoSignal(signal: number | string): Deno.Signal {
if (typeof signal === "number") {
for (const name of keys(os.signals)) {
if (os.signals[name] === signal) {
return name as Deno.Signal;
}
}
throw new ERR_UNKNOWN_SIGNAL(String(signal));
}
const denoSignal = signal as Deno.Signal;
if (denoSignal in os.signals) {
return denoSignal;
}
throw new ERR_UNKNOWN_SIGNAL(signal);
}
function keys<T extends Record<string, unknown>>(object: T): Array<keyof T> {
return Object.keys(object);
}
export interface ChildProcessOptions {
/**
* Current working directory of the child process.
*/
cwd?: string | URL;
/**
* Environment variables passed to the child process.
*/
env?: Record<string, string | number | boolean>;
/**
* This option defines child process's stdio configuration.
* @see https://nodejs.org/api/child_process.html#child_process_options_stdio
*/
stdio?: Array<NodeStdio | number | Stream | null | undefined> | NodeStdio;
/**
* Whether to spawn the process in a detached state.
*/
detached?: boolean;
/**
* NOTE: This option is not yet implemented.
*/
uid?: number;
/**
* NOTE: This option is not yet implemented.
*/
gid?: number;
/**
* NOTE: This option is not yet implemented.
*/
argv0?: string;
/**
* * If this option is `true`, run the command in the shell.
* * If this option is a string, run the command in the specified shell.
*/
shell?: string | boolean;
/**
* Allows aborting the child process using an AbortSignal.
*/
signal?: AbortSignal;
/**
* NOTE: This option is not yet implemented.
*/
serialization?: "json" | "advanced";
/** No quoting or escaping of arguments is done on Windows. Ignored on Unix.
* Default: false. */
windowsVerbatimArguments?: boolean;
/**
* NOTE: This option is not yet implemented.
*/
windowsHide?: boolean;
}
function copyProcessEnvToEnv(
env: Record<string, string | number | boolean | undefined>,
name: string,
optionEnv?: Record<string, string | number | boolean>,
) {
if (
Deno.env.get(name) &&
(!optionEnv ||
!ObjectHasOwn(optionEnv, name))
) {
env[name] = Deno.env.get(name);
}
}
function normalizeStdioOption(
stdio: Array<NodeStdio | number | null | undefined | Stream> | NodeStdio = [
"pipe",
"pipe",
"pipe",
],
): [
Stream | NodeStdio | number,
Stream | NodeStdio | number,
Stream | NodeStdio | number,
...Array<Stream | NodeStdio | number>,
] {
if (Array.isArray(stdio)) {
// `[0, 1, 2]` is equivalent to `"inherit"`
if (
stdio.length === 3 &&
(stdio[0] === 0 && stdio[1] === 1 && stdio[2] === 2)
) {
return ["inherit", "inherit", "inherit"];
}
// `[null, null, null]` is equivalent to `"pipe"
if (
stdio.length === 3 &&
stdio[0] === null || stdio[1] === null || stdio[2] === null
) {
return ["pipe", "pipe", "pipe"];
}
// At least 3 stdio must be created to match node
while (stdio.length < 3) {
ArrayPrototypePush(stdio, undefined);
}
return stdio;
} else {
switch (stdio) {
case "overlapped":
if (isWindows) {
notImplemented("normalizeStdioOption overlapped (on windows)");
}
// 'overlapped' is same as 'piped' on non Windows system.
return ["pipe", "pipe", "pipe"];
case "pipe":
return ["pipe", "pipe", "pipe"];
case "inherit":
return ["inherit", "inherit", "inherit"];
case "ignore":
return ["ignore", "ignore", "ignore"];
default:
notImplemented(`normalizeStdioOption stdio=${typeof stdio} (${stdio})`);
}
}
}
export function normalizeSpawnArguments(
file: string,
args: string[],
options: SpawnOptions & SpawnSyncOptions,
) {
validateString(file, "file");
if (file.length === 0) {
throw new ERR_INVALID_ARG_VALUE("file", file, "cannot be empty");
}
if (ArrayIsArray(args)) {
args = ArrayPrototypeSlice(args);
} else if (args == null) {
args = [];
} else if (typeof args !== "object") {
throw new ERR_INVALID_ARG_TYPE("args", "object", args);
} else {
options = args;
args = [];
}
if (options === undefined) {
options = kEmptyObject;
} else {
validateObject(options, "options");
}
let cwd = options.cwd;
// Validate the cwd, if present.
if (cwd != null) {
cwd = getValidatedPath(cwd, "options.cwd") as string;
}
// Validate detached, if present.
if (options.detached != null) {
validateBoolean(options.detached, "options.detached");
}
// Validate the uid, if present.
if (options.uid != null && !isInt32(options.uid)) {
throw new ERR_INVALID_ARG_TYPE("options.uid", "int32", options.uid);
}
// Validate the gid, if present.
if (options.gid != null && !isInt32(options.gid)) {
throw new ERR_INVALID_ARG_TYPE("options.gid", "int32", options.gid);
}
// Validate the shell, if present.
if (
options.shell != null &&
typeof options.shell !== "boolean" &&
typeof options.shell !== "string"
) {
throw new ERR_INVALID_ARG_TYPE(
"options.shell",
["boolean", "string"],
options.shell,
);
}
// Validate argv0, if present.
if (options.argv0 != null) {
validateString(options.argv0, "options.argv0");
}
// Validate windowsHide, if present.
if (options.windowsHide != null) {
validateBoolean(options.windowsHide, "options.windowsHide");
}
// Validate windowsVerbatimArguments, if present.
let { windowsVerbatimArguments } = options;
if (windowsVerbatimArguments != null) {
validateBoolean(
windowsVerbatimArguments,
"options.windowsVerbatimArguments",
);
}
if (options.shell) {
const command = ArrayPrototypeJoin([file, ...args], " ");
// Set the shell, switches, and commands.
if (process.platform === "win32") {
if (typeof options.shell === "string") {
file = options.shell;
} else {
file = Deno.env.get("comspec") || "cmd.exe";
}
// '/d /s /c' is used only for cmd.exe.
if (/^(?:.*\\)?cmd(?:\.exe)?$/i.exec(file) !== null) {
args = ["/d", "/s", "/c", `"${command}"`];
windowsVerbatimArguments = true;
} else {
args = ["-c", command];
}
} else {
/** TODO: add Android condition */
if (typeof options.shell === "string") {
file = options.shell;
} else {
file = "/bin/sh";
}
args = ["-c", command];
}
}
if (typeof options.argv0 === "string") {
ArrayPrototypeUnshift(args, options.argv0);
} else {
ArrayPrototypeUnshift(args, file);
}
const env = options.env || Deno.env.toObject();
const envPairs: string[][] = [];
// process.env.NODE_V8_COVERAGE always propagates, making it possible to
// collect coverage for programs that spawn with white-listed environment.
copyProcessEnvToEnv(env, "NODE_V8_COVERAGE", options.env);
/** TODO: add `isZOS` condition */
let envKeys: string[] = [];
// Prototype values are intentionally included.
for (const key in env) {
if (Object.hasOwn(env, key)) {
ArrayPrototypePush(envKeys, key);
}
}
if (process.platform === "win32") {
// On Windows env keys are case insensitive. Filter out duplicates,
// keeping only the first one (in lexicographic order)
/** TODO: implement SafeSet and makeSafe */
const sawKey = new Set();
envKeys = ArrayPrototypeFilter(
ArrayPrototypeSort(envKeys),
(key: string) => {
const uppercaseKey = StringPrototypeToUpperCase(key);
if (sawKey.has(uppercaseKey)) {
return false;
}
sawKey.add(uppercaseKey);
return true;
},
);
}
for (const key of envKeys) {
const value = env[key];
if (value !== undefined) {
ArrayPrototypePush(envPairs, `${key}=${value}`);
}
}
return {
// Make a shallow copy so we don't clobber the user's options object.
...options,
args,
cwd,
detached: !!options.detached,
envPairs,
file,
windowsHide: !!options.windowsHide,
windowsVerbatimArguments: !!windowsVerbatimArguments,
};
}
function waitForReadableToClose(readable: Readable) {
readable.resume(); // Ensure buffered data will be consumed.
return waitForStreamToClose(readable as unknown as Stream);
}
function waitForStreamToClose(stream: Stream) {
const deferred = Promise.withResolvers<void>();
const cleanup = () => {
stream.removeListener("close", onClose);
stream.removeListener("error", onError);
};
const onClose = () => {
cleanup();
deferred.resolve();
};
const onError = (err: Error) => {
cleanup();
deferred.reject(err);
};
stream.once("close", onClose);
stream.once("error", onError);
return deferred.promise;
}
/**
* This function is based on https://github.com/nodejs/node/blob/fc6426ccc4b4cb73076356fb6dbf46a28953af01/lib/child_process.js#L504-L528.
* Copyright Joyent, Inc. and other Node contributors. All rights reserved. MIT license.
*/
function buildCommand(
file: string,
args: string[],
shell: string | boolean,
): [string, string[]] {
if (file === Deno.execPath()) {
// The user is trying to spawn another Deno process as Node.js.
args = toDenoArgs(args);
}
if (shell) {
const command = [file, ...args].join(" ");
// Set the shell, switches, and commands.
if (isWindows) {
if (typeof shell === "string") {
file = shell;
} else {
file = Deno.env.get("comspec") || "cmd.exe";
}
// '/d /s /c' is used only for cmd.exe.
if (/^(?:.*\\)?cmd(?:\.exe)?$/i.test(file)) {
args = ["/d", "/s", "/c", `"${command}"`];
} else {
args = ["-c", command];
}
} else {
if (typeof shell === "string") {
file = shell;
} else {
file = "/bin/sh";
}
args = ["-c", command];
}
}
return [file, args];
}
function _createSpawnSyncError(
status: string,
command: string,
args: string[] = [],
): ErrnoException {
const error = errnoException(
codeMap.get(status),
"spawnSync " + command,
);
error.path = command;
error.spawnargs = args;
return error;
}
export interface SpawnOptions extends ChildProcessOptions {
/**
* NOTE: This option is not yet implemented.
*/
timeout?: number;
/**
* NOTE: This option is not yet implemented.
*/
killSignal?: string;
}
export interface SpawnSyncOptions extends
Pick<
ChildProcessOptions,
| "cwd"
| "env"
| "argv0"
| "stdio"
| "uid"
| "gid"
| "shell"
| "windowsVerbatimArguments"
| "windowsHide"
> {
input?: string | Buffer | DataView;
timeout?: number;
maxBuffer?: number;
encoding?: string;
/**
* NOTE: This option is not yet implemented.
*/
killSignal?: string;
}
export interface SpawnSyncResult {
pid?: number;
output?: [string | null, string | Buffer | null, string | Buffer | null];
stdout?: Buffer | string | null;
stderr?: Buffer | string | null;
status?: number | null;
signal?: string | null;
error?: Error;
}
function parseSpawnSyncOutputStreams(
output: Deno.CommandOutput,
name: "stdout" | "stderr",
): string | Buffer | null {
// new Deno.Command().outputSync() returns getters for stdout and stderr that throw when set
// to 'inherit'.
try {
return Buffer.from(output[name]) as string | Buffer;
} catch {
return null;
}
}
export function spawnSync(
command: string,
args: string[],
options: SpawnSyncOptions,
): SpawnSyncResult {
const {
env = Deno.env.toObject(),
stdio = ["pipe", "pipe", "pipe"],
shell = false,
cwd,
encoding,
uid,
gid,
maxBuffer,
windowsVerbatimArguments = false,
} = options;
const [
stdin_ = "pipe",
stdout_ = "pipe",
stderr_ = "pipe",
_channel, // TODO(kt3k): handle this correctly
] = normalizeStdioOption(stdio);
[command, args] = buildCommand(command, args ?? [], shell);
const result: SpawnSyncResult = {};
try {
const output = new Deno.Command(command, {
args,
cwd,
env: mapValues(env, (value) => value.toString()),
stdout: toDenoStdio(stdout_),
stderr: toDenoStdio(stderr_),
stdin: stdin_ == "inherit" ? "inherit" : "null",
uid,
gid,
windowsRawArguments: windowsVerbatimArguments,
}).outputSync();
const status = output.signal ? null : output.code;
let stdout = parseSpawnSyncOutputStreams(output, "stdout");
let stderr = parseSpawnSyncOutputStreams(output, "stderr");
if (
(stdout && stdout.length > maxBuffer!) ||
(stderr && stderr.length > maxBuffer!)
) {
result.error = _createSpawnSyncError("ENOBUFS", command, args);
}
if (encoding && encoding !== "buffer") {
stdout = stdout && stdout.toString(encoding);
stderr = stderr && stderr.toString(encoding);
}
result.status = status;
result.signal = output.signal;
result.stdout = stdout;
result.stderr = stderr;
result.output = [output.signal, stdout, stderr];
} catch (err) {
if (err instanceof Deno.errors.NotFound) {
result.error = _createSpawnSyncError("ENOENT", command, args);
}
}
return result;
}
// These are Node.js CLI flags that expect a value. It's necessary to
// understand these flags in order to properly replace flags passed to the
// child process. For example, -e is a Node flag for eval mode if it is part
// of process.execArgv. However, -e could also be an application flag if it is
// part of process.execv instead. We only want to process execArgv flags.
const kLongArgType = 1;
const kShortArgType = 2;
const kLongArg = { type: kLongArgType };
const kShortArg = { type: kShortArgType };
const kNodeFlagsMap = new Map([
["--build-snapshot", kLongArg],
["-c", kShortArg],
["--check", kLongArg],
["-C", kShortArg],
["--conditions", kLongArg],
["--cpu-prof-dir", kLongArg],
["--cpu-prof-interval", kLongArg],
["--cpu-prof-name", kLongArg],
["--diagnostic-dir", kLongArg],
["--disable-proto", kLongArg],
["--dns-result-order", kLongArg],
["-e", kShortArg],
["--eval", kLongArg],
["--experimental-loader", kLongArg],
["--experimental-policy", kLongArg],
["--experimental-specifier-resolution", kLongArg],
["--heapsnapshot-near-heap-limit", kLongArg],
["--heapsnapshot-signal", kLongArg],
["--heap-prof-dir", kLongArg],
["--heap-prof-interval", kLongArg],
["--heap-prof-name", kLongArg],
["--icu-data-dir", kLongArg],
["--input-type", kLongArg],
["--inspect-publish-uid", kLongArg],
["--max-http-header-size", kLongArg],
["--openssl-config", kLongArg],
["-p", kShortArg],
["--print", kLongArg],
["--policy-integrity", kLongArg],
["--prof-process", kLongArg],
["-r", kShortArg],
["--require", kLongArg],
["--redirect-warnings", kLongArg],
["--report-dir", kLongArg],
["--report-directory", kLongArg],
["--report-filename", kLongArg],
["--report-signal", kLongArg],
["--secure-heap", kLongArg],
["--secure-heap-min", kLongArg],
["--snapshot-blob", kLongArg],
["--title", kLongArg],
["--tls-cipher-list", kLongArg],
["--tls-keylog", kLongArg],
["--unhandled-rejections", kLongArg],
["--use-largepages", kLongArg],
["--v8-pool-size", kLongArg],
]);
const kDenoSubcommands = new Set([
"add",
"bench",
"cache",
"check",
"compile",
"completions",
"coverage",
"doc",
"eval",
"fmt",
"help",
"info",
"init",
"install",
"lint",
"lsp",
"publish",
"repl",
"run",
"tasks",
"test",
"types",
"uninstall",
"upgrade",
"vendor",
]);
function toDenoArgs(args: string[]): string[] {
if (args.length === 0) {
return args;
}
// Update this logic as more CLI arguments are mapped from Node to Deno.
const denoArgs: string[] = [];
let useRunArgs = true;
for (let i = 0; i < args.length; i++) {
const arg = args[i];
if (arg.charAt(0) !== "-" || arg === "--") {
// Not a flag or no more arguments.
// If the arg is a Deno subcommand, then the child process is being
// spawned as Deno, not Deno in Node compat mode. In this case, bail out
// and return the original args.
if (kDenoSubcommands.has(arg)) {
return args;
}
// Copy of the rest of the arguments to the output.
for (let j = i; j < args.length; j++) {
denoArgs.push(args[j]);
}
break;
}
// Something that looks like a flag was passed.
let flag = arg;
let flagInfo = kNodeFlagsMap.get(arg);
let isLongWithValue = false;
let flagValue;
if (flag === "--v8-options") {
// If --v8-options is passed, it should be replaced with --v8-flags="--help".
denoArgs.push("--v8-flags=--help");
continue;
}
if (flagInfo === undefined) {
// If the flag was not found, it's either not a known flag or it's a long
// flag containing an '='.
const splitAt = arg.indexOf("=");
if (splitAt !== -1) {
flag = arg.slice(0, splitAt);
flagInfo = kNodeFlagsMap.get(flag);
flagValue = arg.slice(splitAt + 1);
isLongWithValue = true;
}
}
if (flagInfo === undefined) {
// Not a known flag that expects a value. Just copy it to the output.
denoArgs.push(arg);
continue;
}
// This is a flag with a value. Get the value if we don't already have it.
if (flagValue === undefined) {
i++;
if (i >= args.length) {
// There was user error. There should be another arg for the value, but
// there isn't one. Just copy the arg to the output. It's not going
// to work anyway.
denoArgs.push(arg);
continue;
}
flagValue = args[i];
}
// Remap Node's eval flags to Deno.
if (flag === "-e" || flag === "--eval") {
denoArgs.push("eval", flagValue);
useRunArgs = false;
} else if (isLongWithValue) {
denoArgs.push(arg);
} else {
denoArgs.push(flag, flagValue);
}
}
if (useRunArgs) {
// -A is not ideal, but needed to propagate permissions.
denoArgs.unshift("run", "-A");
}
return denoArgs;
}
const kControlDisconnect = Symbol("kControlDisconnect");
const kPendingMessages = Symbol("kPendingMessages");
// controls refcounting for the IPC channel
class Control extends EventEmitter {
#channel: number;
#refs: number = 0;
#refExplicitlySet = false;
#connected = true;
[kPendingMessages] = [];
constructor(channel: number) {
super();
this.#channel = channel;
}
#ref() {
if (this.#connected) {
op_node_ipc_ref(this.#channel);
}
}
#unref() {
if (this.#connected) {
op_node_ipc_unref(this.#channel);
}
}
[kControlDisconnect]() {
this.#unref();
this.#connected = false;
}
refCounted() {
if (++this.#refs === 1 && !this.#refExplicitlySet) {
this.#ref();
}
}
unrefCounted() {
if (--this.#refs === 0 && !this.#refExplicitlySet) {
this.#unref();
this.emit("unref");
}
}
ref() {
this.#refExplicitlySet = true;
this.#ref();
}
unref() {
this.#refExplicitlySet = false;
this.#unref();
}
}
type InternalMessage = {
cmd: `NODE_${string}`;
};
// deno-lint-ignore no-explicit-any
function isInternal(msg: any): msg is InternalMessage {
if (msg && typeof msg === "object") {
const cmd = msg["cmd"];
if (typeof cmd === "string") {
return StringPrototypeStartsWith(cmd, "NODE_");
}
}
return false;
}
function internalCmdName(msg: InternalMessage): string {
return StringPrototypeSlice(msg.cmd, 5);
}
// deno-lint-ignore no-explicit-any
export function setupChannel(target: any, ipc: number) {
const control = new Control(ipc);
target.channel = control;
async function readLoop() {
try {
while (true) {
if (!target.connected || target.killed) {
return;
}
const prom = op_node_ipc_read(ipc);
// there will always be a pending read promise,
// but it shouldn't keep the event loop from exiting
core.unrefOpPromise(prom);
const msg = await prom;
if (isInternal(msg)) {
const cmd = internalCmdName(msg);
if (cmd === "CLOSE") {
// Channel closed.
target.disconnect();
return;
} else {
// TODO(nathanwhit): once we add support for sending
// handles, if we want to support deno-node IPC interop,
// we'll need to handle the NODE_HANDLE_* messages here.
continue;
}
}
process.nextTick(handleMessage, msg);
}
} catch (err) {
if (
err instanceof Deno.errors.Interrupted ||
err instanceof Deno.errors.BadResource
) {
return;
}
}
}
function handleMessage(msg) {
if (!target.channel) {
return;
}
if (target.listenerCount("message") !== 0) {
target.emit("message", msg);
return;
}
ArrayPrototypePush(target.channel[kPendingMessages], msg);
}
target.on("newListener", () => {
nextTick(() => {
if (!target.channel || !target.listenerCount("message")) {
return;
}
for (const msg of target.channel[kPendingMessages]) {
target.emit("message", msg);
}
target.channel[kPendingMessages] = [];
});
});
target.send = function (message, handle, options, callback) {
if (typeof handle === "function") {
callback = handle;
handle = undefined;
options = undefined;
} else if (typeof options === "function") {
callback = options;
options = undefined;
} else if (options !== undefined) {
validateObject(options, "options");
}
options = { swallowErrors: false, ...options };
if (message === undefined) {
throw new TypeError("ERR_MISSING_ARGS", "message");
}
if (handle !== undefined) {
notImplemented("ChildProcess.send with handle");
}
if (!target.connected) {
const err = new ERR_IPC_CHANNEL_CLOSED();
if (typeof callback === "function") {
process.nextTick(callback, err);
} else {
nextTick(() => target.emit("error", err));
}
return false;
}
// signals whether the queue is within the limit.
// if false, the sender should slow down.
// this acts as a backpressure mechanism.
const queueOk = [true];
control.refCounted();
op_node_ipc_write(ipc, message, queueOk)
.then(() => {
control.unrefCounted();
if (callback) {
process.nextTick(callback, null);
}
});
return queueOk[0];
};
target.connected = true;
target.disconnect = function () {
if (!target.connected) {
target.emit("error", new Error("IPC channel is already disconnected"));
return;
}
target.connected = false;
target[kCanDisconnect] = false;
control[kControlDisconnect]();
process.nextTick(() => {
target.channel = null;
core.close(ipc);
target.emit("disconnect");
});
};
target[kCanDisconnect] = true;
// Start reading messages from the channel.
readLoop();
return control;
}
export default {
ChildProcess,
normalizeSpawnArguments,
stdioStringToArray,
spawnSync,
setupChannel,
};