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denoland-deno/runtime/js/99_main.js

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// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
// Remove Intl.v8BreakIterator because it is a non-standard API.
delete Intl.v8BreakIterator;
import { core, internals, primordials } from "ext:core/mod.js";
const ops = core.ops;
import {
op_bootstrap_args,
op_bootstrap_is_stderr_tty,
op_bootstrap_is_stdout_tty,
op_bootstrap_no_color,
op_bootstrap_pid,
op_main_module,
op_ppid,
op_set_format_exception_callback,
op_snapshot_options,
op_worker_close,
op_worker_get_type,
op_worker_post_message,
op_worker_recv_message,
op_worker_sync_fetch,
} from "ext:core/ops";
const {
ArrayPrototypeFilter,
ArrayPrototypeIncludes,
ArrayPrototypeMap,
DateNow,
Error,
ErrorPrototype,
FunctionPrototypeBind,
FunctionPrototypeCall,
ObjectAssign,
ObjectDefineProperties,
ObjectDefineProperty,
ObjectHasOwn,
ObjectKeys,
ObjectPrototypeIsPrototypeOf,
ObjectSetPrototypeOf,
ObjectValues,
PromisePrototypeThen,
PromiseResolve,
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
StringPrototypePadEnd,
Symbol,
SymbolIterator,
TypeError,
} = primordials;
const {
isNativeError,
} = core;
import { registerDeclarativeServer } from "ext:deno_http/00_serve.ts";
import * as event from "ext:deno_web/02_event.js";
import * as location from "ext:deno_web/12_location.js";
import * as version from "ext:runtime/01_version.ts";
import * as os from "ext:runtime/30_os.js";
import * as timers from "ext:deno_web/02_timers.js";
import {
getDefaultInspectOptions,
getStderrNoColor,
inspectArgs,
quoteString,
setNoColorFns,
} from "ext:deno_console/01_console.js";
import * as performance from "ext:deno_web/15_performance.js";
import * as url from "ext:deno_url/00_url.js";
import * as fetch from "ext:deno_fetch/26_fetch.js";
import * as messagePort from "ext:deno_web/13_message_port.js";
import {
denoNs,
denoNsUnstable,
denoNsUnstableById,
unstableIds,
} from "ext:runtime/90_deno_ns.js";
import { errors } from "ext:runtime/01_errors.js";
import * as webidl from "ext:deno_webidl/00_webidl.js";
import { DOMException } from "ext:deno_web/01_dom_exception.js";
import {
unstableForWindowOrWorkerGlobalScope,
windowOrWorkerGlobalScope,
} from "ext:runtime/98_global_scope_shared.js";
import {
mainRuntimeGlobalProperties,
memoizeLazy,
} from "ext:runtime/98_global_scope_window.js";
import {
workerRuntimeGlobalProperties,
} from "ext:runtime/98_global_scope_worker.js";
import { SymbolDispose, SymbolMetadata } from "ext:deno_web/00_infra.js";
// deno-lint-ignore prefer-primordials
if (Symbol.metadata) {
throw "V8 supports Symbol.metadata now, no need to shim it!";
}
ObjectDefineProperties(Symbol, {
dispose: {
__proto__: null,
value: SymbolDispose,
enumerable: false,
writable: false,
configurable: false,
},
metadata: {
__proto__: null,
value: SymbolMetadata,
enumerable: false,
writable: false,
configurable: false,
},
});
let windowIsClosing = false;
let globalThis_;
// TODO(2.0): remove once all deprecated APIs are removed.
function warnOnDeprecatedApi() {}
feat: Start warning on each use of a deprecated API (#21939) This commit introduces deprecation warnings for "Deno.*" APIs. This is gonna be quite noisy, but should tremendously help with user code updates to ensure smooth migration to Deno 2.0. The warning is printed at each unique call site to help quickly identify where code needs to be adjusted. There's some stack frame filtering going on to remove frames that are not useful to the user and would only cause confusion. The warning can be silenced using "--quiet" flag or "DENO_NO_DEPRECATION_WARNINGS" env var. "Deno.run()" API is now using this warning. Other deprecated APIs will start warning in follow up PRs. Example: ```js import { runEcho as runEcho2 } from "http://localhost:4545/run/warn_on_deprecated_api/mod.ts"; const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "console.log('hello world')", ], }); await p.status(); p.close(); async function runEcho() { const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "console.log('hello world')", ], }); await p.status(); p.close(); } await runEcho(); await runEcho(); for (let i = 0; i < 10; i++) { await runEcho(); } await runEcho2(); ``` ``` $ deno run --allow-read foo.js Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: └─ at file:///Users/ib/dev/deno/foo.js:3:16 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:13:7 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:14:7 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:17:9 hello world hello world hello world hello world hello world hello world hello world hello world hello world hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ ├ Suggestion: It appears this API is used by a remote dependency. │ Try upgrading to the latest version of that dependency. │ └ Stack trace: ├─ at runEcho (http://localhost:4545/run/warn_on_deprecated_api/mod.ts:2:18) └─ at file:///Users/ib/dev/deno/foo.js:20:7 hello world ``` Closes #21839
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function windowClose() {
if (!windowIsClosing) {
windowIsClosing = true;
// Push a macrotask to exit after a promise resolve.
// This is not perfect, but should be fine for first pass.
PromisePrototypeThen(
PromiseResolve(),
() =>
FunctionPrototypeCall(timers.setTimeout, null, () => {
// This should be fine, since only Window/MainWorker has .close()
os.exit(0);
}, 0),
);
}
}
function workerClose() {
if (isClosing) {
return;
}
isClosing = true;
op_worker_close();
}
function postMessage(message, transferOrOptions = { __proto__: null }) {
const prefix =
"Failed to execute 'postMessage' on 'DedicatedWorkerGlobalScope'";
webidl.requiredArguments(arguments.length, 1, prefix);
message = webidl.converters.any(message);
let options;
if (
webidl.type(transferOrOptions) === "Object" &&
transferOrOptions !== undefined &&
transferOrOptions[SymbolIterator] !== undefined
) {
const transfer = webidl.converters["sequence<object>"](
transferOrOptions,
prefix,
"Argument 2",
);
options = { transfer };
} else {
options = webidl.converters.StructuredSerializeOptions(
transferOrOptions,
prefix,
"Argument 2",
);
}
const { transfer } = options;
const data = messagePort.serializeJsMessageData(message, transfer);
op_worker_post_message(data);
}
let isClosing = false;
let globalDispatchEvent;
function hasMessageEventListener() {
return event.listenerCount(globalThis, "message") > 0 ||
messagePort.messageEventListenerCount > 0;
}
async function pollForMessages() {
if (!globalDispatchEvent) {
globalDispatchEvent = FunctionPrototypeBind(
globalThis.dispatchEvent,
globalThis,
);
}
while (!isClosing) {
const recvMessage = op_worker_recv_message();
if (globalThis[messagePort.unrefPollForMessages] === true) {
core.unrefOpPromise(recvMessage);
}
const data = await recvMessage;
// const data = await op_worker_recv_message();
if (data === null) break;
const v = messagePort.deserializeJsMessageData(data);
const message = v[0];
const transferables = v[1];
const msgEvent = new event.MessageEvent("message", {
cancelable: false,
data: message,
ports: ArrayPrototypeFilter(
transferables,
(t) =>
ObjectPrototypeIsPrototypeOf(messagePort.MessagePortPrototype, t),
),
});
event.setIsTrusted(msgEvent, true);
try {
globalDispatchEvent(msgEvent);
} catch (e) {
const errorEvent = new event.ErrorEvent("error", {
cancelable: true,
message: e.message,
lineno: e.lineNumber ? e.lineNumber + 1 : undefined,
colno: e.columnNumber ? e.columnNumber + 1 : undefined,
filename: e.fileName,
error: e,
});
event.setIsTrusted(errorEvent, true);
globalDispatchEvent(errorEvent);
if (!errorEvent.defaultPrevented) {
throw e;
}
}
}
}
let loadedMainWorkerScript = false;
function importScripts(...urls) {
if (op_worker_get_type() === "module") {
throw new TypeError("Can't import scripts in a module worker.");
}
const baseUrl = location.getLocationHref();
const parsedUrls = ArrayPrototypeMap(urls, (scriptUrl) => {
try {
return new url.URL(scriptUrl, baseUrl ?? undefined).href;
} catch {
throw new DOMException(
"Failed to parse URL.",
"SyntaxError",
);
}
});
// A classic worker's main script has looser MIME type checks than any
// imported scripts, so we use `loadedMainWorkerScript` to distinguish them.
// TODO(andreubotella) Refactor worker creation so the main script isn't
// loaded with `importScripts()`.
const scripts = op_worker_sync_fetch(
parsedUrls,
!loadedMainWorkerScript,
);
loadedMainWorkerScript = true;
for (let i = 0; i < scripts.length; ++i) {
const { url, script } = scripts[i];
const err = core.evalContext(script, url)[1];
if (err !== null) {
throw err.thrown;
}
}
}
const opArgs = memoizeLazy(() => op_bootstrap_args());
const opPid = memoizeLazy(() => op_bootstrap_pid());
setNoColorFns(
() => op_bootstrap_no_color() || !op_bootstrap_is_stdout_tty(),
() => op_bootstrap_no_color() || !op_bootstrap_is_stderr_tty(),
);
function formatException(error) {
if (
isNativeError(error) ||
ObjectPrototypeIsPrototypeOf(ErrorPrototype, error)
) {
return null;
} else if (typeof error == "string") {
return `Uncaught ${
inspectArgs([quoteString(error, getDefaultInspectOptions())], {
colors: !getStderrNoColor(),
})
}`;
} else {
return `Uncaught ${inspectArgs([error], { colors: !getStderrNoColor() })}`;
}
}
core.registerErrorClass("NotFound", errors.NotFound);
core.registerErrorClass("ConnectionRefused", errors.ConnectionRefused);
core.registerErrorClass("ConnectionReset", errors.ConnectionReset);
core.registerErrorClass("ConnectionAborted", errors.ConnectionAborted);
core.registerErrorClass("NotConnected", errors.NotConnected);
core.registerErrorClass("AddrInUse", errors.AddrInUse);
core.registerErrorClass("AddrNotAvailable", errors.AddrNotAvailable);
core.registerErrorClass("BrokenPipe", errors.BrokenPipe);
core.registerErrorClass("AlreadyExists", errors.AlreadyExists);
core.registerErrorClass("InvalidData", errors.InvalidData);
core.registerErrorClass("TimedOut", errors.TimedOut);
core.registerErrorClass("WouldBlock", errors.WouldBlock);
core.registerErrorClass("WriteZero", errors.WriteZero);
core.registerErrorClass("UnexpectedEof", errors.UnexpectedEof);
core.registerErrorClass("Http", errors.Http);
core.registerErrorClass("Busy", errors.Busy);
core.registerErrorClass("NotSupported", errors.NotSupported);
core.registerErrorClass("FilesystemLoop", errors.FilesystemLoop);
core.registerErrorClass("IsADirectory", errors.IsADirectory);
core.registerErrorClass("NetworkUnreachable", errors.NetworkUnreachable);
core.registerErrorClass("NotADirectory", errors.NotADirectory);
core.registerErrorBuilder(
"DOMExceptionOperationError",
function DOMExceptionOperationError(msg) {
return new DOMException(msg, "OperationError");
},
);
core.registerErrorBuilder(
"DOMExceptionQuotaExceededError",
function DOMExceptionQuotaExceededError(msg) {
return new DOMException(msg, "QuotaExceededError");
},
);
core.registerErrorBuilder(
"DOMExceptionNotSupportedError",
function DOMExceptionNotSupportedError(msg) {
return new DOMException(msg, "NotSupported");
},
);
core.registerErrorBuilder(
"DOMExceptionNetworkError",
function DOMExceptionNetworkError(msg) {
return new DOMException(msg, "NetworkError");
},
);
core.registerErrorBuilder(
"DOMExceptionAbortError",
function DOMExceptionAbortError(msg) {
return new DOMException(msg, "AbortError");
},
);
core.registerErrorBuilder(
"DOMExceptionInvalidCharacterError",
function DOMExceptionInvalidCharacterError(msg) {
return new DOMException(msg, "InvalidCharacterError");
},
);
core.registerErrorBuilder(
"DOMExceptionDataError",
function DOMExceptionDataError(msg) {
return new DOMException(msg, "DataError");
},
);
function runtimeStart(
denoVersion,
v8Version,
tsVersion,
target,
) {
core.setWasmStreamingCallback(fetch.handleWasmStreaming);
core.setReportExceptionCallback(event.reportException);
op_set_format_exception_callback(formatException);
version.setVersions(
denoVersion,
v8Version,
tsVersion,
);
core.setBuildInfo(target);
}
core.setUnhandledPromiseRejectionHandler(processUnhandledPromiseRejection);
core.setHandledPromiseRejectionHandler(processRejectionHandled);
// Notification that the core received an unhandled promise rejection that is about to
// terminate the runtime. If we can handle it, attempt to do so.
function processUnhandledPromiseRejection(promise, reason) {
const rejectionEvent = new event.PromiseRejectionEvent(
"unhandledrejection",
{
cancelable: true,
promise,
reason,
},
);
// Note that the handler may throw, causing a recursive "error" event
globalThis_.dispatchEvent(rejectionEvent);
// If event was not yet prevented, try handing it off to Node compat layer
// (if it was initialized)
if (
!rejectionEvent.defaultPrevented &&
typeof internals.nodeProcessUnhandledRejectionCallback !== "undefined"
) {
internals.nodeProcessUnhandledRejectionCallback(rejectionEvent);
}
// If event was not prevented (or "unhandledrejection" listeners didn't
// throw) we will let Rust side handle it.
if (rejectionEvent.defaultPrevented) {
return true;
}
return false;
}
function processRejectionHandled(promise, reason) {
const rejectionHandledEvent = new event.PromiseRejectionEvent(
"rejectionhandled",
{ promise, reason },
);
// Note that the handler may throw, causing a recursive "error" event
globalThis_.dispatchEvent(rejectionHandledEvent);
if (typeof internals.nodeProcessRejectionHandledCallback !== "undefined") {
internals.nodeProcessRejectionHandledCallback(rejectionHandledEvent);
}
}
function dispatchLoadEvent() {
globalThis_.dispatchEvent(new Event("load"));
}
function dispatchBeforeUnloadEvent() {
return globalThis_.dispatchEvent(
new Event("beforeunload", { cancelable: true }),
);
}
function dispatchUnloadEvent() {
globalThis_.dispatchEvent(new Event("unload"));
}
let hasBootstrapped = false;
// Set up global properties shared by main and worker runtime.
ObjectDefineProperties(globalThis, windowOrWorkerGlobalScope);
// Set up global properties shared by main and worker runtime that are exposed
// by unstable features if those are enabled.
function exposeUnstableFeaturesForWindowOrWorkerGlobalScope(options) {
const { unstableFlag, unstableFeatures } = options;
if (unstableFlag) {
const all = ObjectValues(unstableForWindowOrWorkerGlobalScope);
for (let i = 0; i <= all.length; i++) {
const props = all[i];
ObjectDefineProperties(globalThis, { ...props });
}
} else {
const featureIds = ArrayPrototypeMap(
ObjectKeys(
unstableForWindowOrWorkerGlobalScope,
),
(k) => k | 0,
);
for (let i = 0; i <= featureIds.length; i++) {
const featureId = featureIds[i];
if (ArrayPrototypeIncludes(unstableFeatures, featureId)) {
const props = unstableForWindowOrWorkerGlobalScope[featureId];
ObjectDefineProperties(globalThis, { ...props });
}
}
}
}
// NOTE(bartlomieju): remove all the ops that have already been imported using
// "virtual op module" (`ext:core/ops`).
const NOT_IMPORTED_OPS = [
// Related to `Deno.bench()` API
"op_bench_now",
"op_dispatch_bench_event",
"op_register_bench",
"op_bench_get_origin",
// Related to `Deno.jupyter` API
"op_jupyter_broadcast",
"op_jupyter_input",
// Related to `Deno.test()` API
"op_test_event_step_result_failed",
"op_test_event_step_result_ignored",
"op_test_event_step_result_ok",
"op_test_event_step_wait",
"op_test_op_sanitizer_collect",
"op_test_op_sanitizer_finish",
"op_test_op_sanitizer_get_async_message",
"op_test_op_sanitizer_report",
"op_restore_test_permissions",
"op_register_test_step",
"op_register_test",
"op_test_get_origin",
"op_pledge_test_permissions",
// TODO(bartlomieju): used in various integration tests - figure out a way
// to not depend on them.
"op_set_exit_code",
"op_napi_open",
"op_npm_process_state",
];
function removeImportedOps() {
const allOpNames = ObjectKeys(ops);
for (let i = 0; i < allOpNames.length; i++) {
const opName = allOpNames[i];
if (!ArrayPrototypeIncludes(NOT_IMPORTED_OPS, opName)) {
delete ops[opName];
}
}
}
// FIXME(bartlomieju): temporarily add whole `Deno.core` to
// `Deno[Deno.internal]` namespace. It should be removed and only necessary
// methods should be left there.
feat: Start warning on each use of a deprecated API (#21939) This commit introduces deprecation warnings for "Deno.*" APIs. This is gonna be quite noisy, but should tremendously help with user code updates to ensure smooth migration to Deno 2.0. The warning is printed at each unique call site to help quickly identify where code needs to be adjusted. There's some stack frame filtering going on to remove frames that are not useful to the user and would only cause confusion. The warning can be silenced using "--quiet" flag or "DENO_NO_DEPRECATION_WARNINGS" env var. "Deno.run()" API is now using this warning. Other deprecated APIs will start warning in follow up PRs. Example: ```js import { runEcho as runEcho2 } from "http://localhost:4545/run/warn_on_deprecated_api/mod.ts"; const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "console.log('hello world')", ], }); await p.status(); p.close(); async function runEcho() { const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "console.log('hello world')", ], }); await p.status(); p.close(); } await runEcho(); await runEcho(); for (let i = 0; i < 10; i++) { await runEcho(); } await runEcho2(); ``` ``` $ deno run --allow-read foo.js Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: └─ at file:///Users/ib/dev/deno/foo.js:3:16 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:13:7 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:14:7 hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ └ Stack trace: ├─ at runEcho (file:///Users/ib/dev/deno/foo.js:8:18) └─ at file:///Users/ib/dev/deno/foo.js:17:9 hello world hello world hello world hello world hello world hello world hello world hello world hello world hello world Warning ├ Use of deprecated "Deno.run()" API. │ ├ This API will be removed in Deno 2.0. Make sure to upgrade to a stable API before then. │ ├ Suggestion: Use "Deno.Command()" API instead. │ ├ Suggestion: It appears this API is used by a remote dependency. │ Try upgrading to the latest version of that dependency. │ └ Stack trace: ├─ at runEcho (http://localhost:4545/run/warn_on_deprecated_api/mod.ts:2:18) └─ at file:///Users/ib/dev/deno/foo.js:20:7 hello world ``` Closes #21839
2024-01-18 18:30:49 -05:00
ObjectAssign(internals, { core, warnOnDeprecatedApi });
const internalSymbol = Symbol("Deno.internal");
const finalDenoNs = {
internal: internalSymbol,
[internalSymbol]: internals,
...denoNs,
// Deno.test and Deno.bench are noops here, but kept for compatibility; so
// that they don't cause errors when used outside of `deno test`/`deno bench`
// contexts.
test: () => {},
bench: () => {},
};
ObjectDefineProperties(finalDenoNs, {
pid: core.propGetterOnly(opPid),
// `ppid` should not be memoized.
// https://github.com/denoland/deno/issues/23004
ppid: core.propGetterOnly(() => op_ppid()),
noColor: core.propGetterOnly(() => op_bootstrap_no_color()),
args: core.propGetterOnly(opArgs),
mainModule: core.propGetterOnly(() => op_main_module()),
exitCode: {
__proto__: null,
get() {
return os.getExitCode();
},
set(value) {
os.setExitCode(value);
},
},
});
const {
tsVersion,
v8Version,
target,
} = op_snapshot_options();
const executionModes = {
none: 0,
worker: 1,
run: 2,
repl: 3,
eval: 4,
test: 5,
bench: 6,
serve: 7,
jupyter: 8,
};
function bootstrapMainRuntime(runtimeOptions, warmup = false) {
if (!warmup) {
if (hasBootstrapped) {
throw new Error("Worker runtime already bootstrapped");
}
const {
0: denoVersion,
1: location_,
2: unstableFlag,
3: unstableFeatures,
4: inspectFlag,
6: hasNodeModulesDir,
7: argv0,
8: nodeDebug,
9: mode,
10: servePort,
11: serveHost,
12: serveIsMain,
13: serveWorkerCount,
} = runtimeOptions;
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
if (mode === executionModes.serve) {
if (serveIsMain && serveWorkerCount) {
// deno-lint-ignore no-console
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
const origLog = console.log;
// deno-lint-ignore no-console
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
const origError = console.error;
const prefix = `[serve-worker-0 ]`;
// deno-lint-ignore no-console
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
console.log = (...args) => {
return origLog(prefix, ...new primordials.SafeArrayIterator(args));
};
// deno-lint-ignore no-console
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
console.error = (...args) => {
return origError(prefix, ...new primordials.SafeArrayIterator(args));
};
} else if (serveWorkerCount !== null) {
// deno-lint-ignore no-console
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
const origLog = console.log;
// deno-lint-ignore no-console
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
const origError = console.error;
const base = `serve-worker-${serveWorkerCount + 1}`;
// 15 = "serve-worker-nn".length, assuming
// serveWorkerCount < 100
const prefix = `[${StringPrototypePadEnd(base, 15, " ")}]`;
// deno-lint-ignore no-console
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
console.log = (...args) => {
return origLog(prefix, ...new primordials.SafeArrayIterator(args));
};
// deno-lint-ignore no-console
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
console.error = (...args) => {
return origError(prefix, ...new primordials.SafeArrayIterator(args));
};
}
}
if (mode === executionModes.run || mode === executionModes.serve) {
let serve = undefined;
core.addMainModuleHandler((main) => {
if (ObjectHasOwn(main, "default")) {
try {
serve = registerDeclarativeServer(main.default);
} catch (e) {
if (mode === executionModes.serve) {
throw e;
}
}
}
if (mode === executionModes.serve && !serve) {
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
if (serveIsMain) {
// Only error if main worker
// deno-lint-ignore no-console
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
console.error(
`%cerror: %cdeno serve requires %cexport default { fetch }%c in the main module, did you mean to run \"deno run\"?`,
"color: yellow;",
"color: inherit;",
"font-weight: bold;",
"font-weight: normal;",
);
}
return;
}
if (serve) {
if (mode === executionModes.run) {
// deno-lint-ignore no-console
console.error(
`%cwarning: %cDetected %cexport default { fetch }%c, did you mean to run \"deno serve\"?`,
"color: yellow;",
"color: inherit;",
"font-weight: bold;",
"font-weight: normal;",
);
}
if (mode === executionModes.serve) {
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
2024-08-14 18:26:21 -04:00
serve({ servePort, serveHost, serveIsMain, serveWorkerCount });
}
}
});
}
// TODO(iuioiua): remove in Deno v2. This allows us to dynamically delete
// class properties within constructors for classes that are not defined
// within the Deno namespace.
internals.future = true;
removeImportedOps();
performance.setTimeOrigin(DateNow());
globalThis_ = globalThis;
// Remove bootstrapping data from the global scope
delete globalThis.__bootstrap;
delete globalThis.bootstrap;
hasBootstrapped = true;
// If the `--location` flag isn't set, make `globalThis.location` `undefined` and
// writable, so that they can mock it themselves if they like. If the flag was
// set, define `globalThis.location`, using the provided value.
if (location_ == null) {
mainRuntimeGlobalProperties.location = {
writable: true,
};
} else {
location.setLocationHref(location_);
}
exposeUnstableFeaturesForWindowOrWorkerGlobalScope({
unstableFlag,
unstableFeatures,
});
ObjectDefineProperties(globalThis, mainRuntimeGlobalProperties);
ObjectDefineProperties(globalThis, {
// TODO(bartlomieju): in the future we might want to change the
// behavior of setting `name` to actually update the process name.
// Empty string matches what browsers do.
name: core.propWritable(""),
close: core.propWritable(windowClose),
closed: core.propGetterOnly(() => windowIsClosing),
});
ObjectSetPrototypeOf(globalThis, Window.prototype);
if (inspectFlag) {
const consoleFromDeno = globalThis.console;
core.wrapConsole(consoleFromDeno, core.v8Console);
}
event.defineEventHandler(globalThis, "error");
event.defineEventHandler(globalThis, "load");
event.defineEventHandler(globalThis, "beforeunload");
event.defineEventHandler(globalThis, "unload");
runtimeStart(
denoVersion,
v8Version,
tsVersion,
target,
);
// TODO(bartlomieju): this is not ideal, but because we use `ObjectAssign`
// above any properties that are defined elsewhere using `Object.defineProperty`
// are lost.
let jupyterNs = undefined;
ObjectDefineProperty(finalDenoNs, "jupyter", {
get() {
if (jupyterNs) {
return jupyterNs;
}
throw new Error(
"Deno.jupyter is only available in `deno jupyter` subcommand.",
);
},
set(val) {
jupyterNs = val;
},
});
// TODO(bartlomieju): deprecate --unstable
if (unstableFlag) {
ObjectAssign(finalDenoNs, denoNsUnstable);
} else {
for (let i = 0; i <= unstableFeatures.length; i++) {
const id = unstableFeatures[i];
ObjectAssign(finalDenoNs, denoNsUnstableById[id]);
}
}
if (!ArrayPrototypeIncludes(unstableFeatures, unstableIds.unsafeProto)) {
// Removes the `__proto__` for security reasons.
// https://tc39.es/ecma262/#sec-get-object.prototype.__proto__
delete Object.prototype.__proto__;
}
if (!ArrayPrototypeIncludes(unstableFeatures, unstableIds.temporal)) {
// Removes the `Temporal` API.
delete globalThis.Temporal;
delete globalThis.Date.prototype.toTemporalInstant;
} else {
// Removes the obsoleted `Temporal` API.
// https://github.com/tc39/proposal-temporal/pull/2895
// https://github.com/tc39/proposal-temporal/pull/2914
if (typeof Temporal.Instant.fromEpochSeconds === "undefined") {
throw "V8 removes obsoleted Temporal API now, no need to delete them!";
}
delete Temporal.Instant.fromEpochSeconds;
delete Temporal.Instant.fromEpochMicroseconds;
delete Temporal.Instant.prototype.epochSeconds;
delete Temporal.Instant.prototype.epochMicroseconds;
delete Temporal.PlainDateTime.prototype.withPlainDate;
delete Temporal.PlainDateTime.prototype.toPlainYearMonth;
delete Temporal.PlainDateTime.prototype.toPlainMonthDay;
delete Temporal.PlainTime.prototype.toPlainDateTime;
delete Temporal.PlainTime.prototype.toZonedDateTime;
delete Temporal.TimeZone.prototype.getNextTransition;
delete Temporal.TimeZone.prototype.getPreviousTransition;
delete Temporal.ZonedDateTime.prototype.withPlainDate;
delete Temporal.ZonedDateTime.prototype.toPlainYearMonth;
delete Temporal.ZonedDateTime.prototype.toPlainMonthDay;
delete Temporal.Now.zonedDateTime;
delete Temporal.Now.plainDateTime;
delete Temporal.Now.plainDate;
}
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// Setup `Deno` global - we're actually overriding already existing global
// `Deno` with `Deno` namespace from "./deno.ts".
ObjectDefineProperty(globalThis, "Deno", core.propReadOnly(finalDenoNs));
if (nodeBootstrap) {
nodeBootstrap({
usesLocalNodeModulesDir: hasNodeModulesDir,
runningOnMainThread: true,
argv0,
nodeDebug,
});
}
if (internals.future) {
delete globalThis.window;
delete Deno.FsFile.prototype.rid;
}
} else {
// Warmup
}
}
function bootstrapWorkerRuntime(
runtimeOptions,
name,
internalName,
workerId,
maybeWorkerMetadata,
warmup = false,
) {
if (!warmup) {
if (hasBootstrapped) {
throw new Error("Worker runtime already bootstrapped");
}
const {
0: denoVersion,
1: location_,
2: unstableFlag,
3: unstableFeatures,
5: enableTestingFeaturesFlag,
6: hasNodeModulesDir,
7: argv0,
8: nodeDebug,
} = runtimeOptions;
// TODO(iuioiua): remove in Deno v2. This allows us to dynamically delete
// class properties within constructors for classes that are not defined
// within the Deno namespace.
internals.future = true;
performance.setTimeOrigin(DateNow());
globalThis_ = globalThis;
// Remove bootstrapping data from the global scope
delete globalThis.__bootstrap;
delete globalThis.bootstrap;
hasBootstrapped = true;
exposeUnstableFeaturesForWindowOrWorkerGlobalScope({
unstableFlag,
unstableFeatures,
});
ObjectDefineProperties(globalThis, workerRuntimeGlobalProperties);
ObjectDefineProperties(globalThis, {
name: core.propWritable(name),
// TODO(bartlomieju): should be readonly?
close: core.propNonEnumerable(workerClose),
postMessage: core.propWritable(postMessage),
});
if (enableTestingFeaturesFlag) {
ObjectDefineProperty(
globalThis,
"importScripts",
core.propWritable(importScripts),
);
}
ObjectSetPrototypeOf(globalThis, DedicatedWorkerGlobalScope.prototype);
const consoleFromDeno = globalThis.console;
core.wrapConsole(consoleFromDeno, core.v8Console);
event.defineEventHandler(self, "message");
event.defineEventHandler(self, "error", undefined, true);
// `Deno.exit()` is an alias to `self.close()`. Setting and exit
// code using an op in worker context is a no-op.
os.setExitHandler((_exitCode) => {
workerClose();
});
runtimeStart(
denoVersion,
v8Version,
tsVersion,
target,
internalName ?? name,
);
location.setLocationHref(location_);
globalThis.pollForMessages = pollForMessages;
globalThis.hasMessageEventListener = hasMessageEventListener;
// TODO(bartlomieju): deprecate --unstable
if (unstableFlag) {
ObjectAssign(finalDenoNs, denoNsUnstable);
} else {
for (let i = 0; i <= unstableFeatures.length; i++) {
const id = unstableFeatures[i];
ObjectAssign(finalDenoNs, denoNsUnstableById[id]);
}
}
// Not available in workers
delete finalDenoNs.mainModule;
if (!ArrayPrototypeIncludes(unstableFeatures, unstableIds.unsafeProto)) {
// Removes the `__proto__` for security reasons.
// https://tc39.es/ecma262/#sec-get-object.prototype.__proto__
delete Object.prototype.__proto__;
}
2024-03-07 18:06:28 -05:00
if (!ArrayPrototypeIncludes(unstableFeatures, unstableIds.temporal)) {
// Removes the `Temporal` API.
delete globalThis.Temporal;
delete globalThis.Date.prototype.toTemporalInstant;
} else {
// Removes the obsoleted `Temporal` API.
// https://github.com/tc39/proposal-temporal/pull/2895
// https://github.com/tc39/proposal-temporal/pull/2914
if (typeof Temporal.Instant.fromEpochSeconds === "undefined") {
throw "V8 removes obsoleted Temporal API now, no need to delete them!";
}
delete Temporal.Instant.fromEpochSeconds;
delete Temporal.Instant.fromEpochMicroseconds;
delete Temporal.Instant.prototype.epochSeconds;
delete Temporal.Instant.prototype.epochMicroseconds;
delete Temporal.PlainDateTime.prototype.withPlainDate;
delete Temporal.PlainDateTime.prototype.toPlainYearMonth;
delete Temporal.PlainDateTime.prototype.toPlainMonthDay;
delete Temporal.PlainTime.prototype.toPlainDateTime;
delete Temporal.PlainTime.prototype.toZonedDateTime;
delete Temporal.TimeZone.prototype.getNextTransition;
delete Temporal.TimeZone.prototype.getPreviousTransition;
delete Temporal.ZonedDateTime.prototype.withPlainDate;
delete Temporal.ZonedDateTime.prototype.toPlainYearMonth;
delete Temporal.ZonedDateTime.prototype.toPlainMonthDay;
delete Temporal.Now.zonedDateTime;
delete Temporal.Now.plainDateTime;
delete Temporal.Now.plainDate;
}
// Setup `Deno` global - we're actually overriding already existing global
// `Deno` with `Deno` namespace from "./deno.ts".
ObjectDefineProperty(globalThis, "Deno", core.propReadOnly(finalDenoNs));
const workerMetadata = maybeWorkerMetadata
? messagePort.deserializeJsMessageData(maybeWorkerMetadata)
: undefined;
if (nodeBootstrap) {
nodeBootstrap({
usesLocalNodeModulesDir: hasNodeModulesDir,
runningOnMainThread: false,
argv0,
workerId,
maybeWorkerMetadata: workerMetadata,
nodeDebug,
});
}
if (internals.future) {
delete Deno.FsFile.prototype.rid;
}
} else {
// Warmup
return;
}
}
const nodeBootstrap = globalThis.nodeBootstrap;
delete globalThis.nodeBootstrap;
const dispatchProcessExitEvent = internals.dispatchProcessExitEvent;
delete internals.dispatchProcessExitEvent;
const dispatchProcessBeforeExitEvent = internals.dispatchProcessBeforeExitEvent;
delete internals.dispatchProcessBeforeExitEvent;
globalThis.bootstrap = {
mainRuntime: bootstrapMainRuntime,
workerRuntime: bootstrapWorkerRuntime,
dispatchLoadEvent,
dispatchUnloadEvent,
dispatchBeforeUnloadEvent,
dispatchProcessExitEvent,
dispatchProcessBeforeExitEvent,
};
event.setEventTargetData(globalThis);
event.saveGlobalThisReference(globalThis);
event.defineEventHandler(globalThis, "unhandledrejection");
// Nothing listens to this, but it warms up the code paths for event dispatch
(new event.EventTarget()).dispatchEvent(new Event("warmup"));
removeImportedOps();
// Run the warmup path through node and runtime/worker bootstrap functions
bootstrapMainRuntime(undefined, true);
bootstrapWorkerRuntime(
undefined,
undefined,
undefined,
undefined,
undefined,
true,
);
nodeBootstrap({ warmup: true });