// deno-fmt-ignore-file // deno-lint-ignore-file // Copyright Joyent and Node contributors. All rights reserved. MIT license. // Taken from Node 18.12.1 // This file is automatically generated by `tools/node_compat/setup.ts`. Do not modify this file manually. 'use strict'; const common = require('../common'); // Ensure that subscribing the 'data' event will not make the stream flow. // The 'data' event will require calling read() by hand. // // The test is written for the (somewhat rare) highWaterMark: 0 streams to // specifically catch any regressions that might occur with these streams. const assert = require('assert'); const { Readable } = require('stream'); const streamData = [ 'a', null ]; // Track the calls so we can assert their order later. const calls = []; const r = new Readable({ read: common.mustCall(() => { calls.push('_read:' + streamData[0]); process.nextTick(() => { calls.push('push:' + streamData[0]); r.push(streamData.shift()); }); }, streamData.length), highWaterMark: 0, // Object mode is used here just for testing convenience. It really // shouldn't affect the order of events. Just the data and its format. objectMode: true, }); assert.strictEqual(r.readableFlowing, null); r.on('readable', common.mustCall(() => { calls.push('readable'); }, 2)); assert.strictEqual(r.readableFlowing, false); r.on('data', common.mustCall((data) => { calls.push('data:' + data); }, 1)); r.on('end', common.mustCall(() => { calls.push('end'); })); assert.strictEqual(r.readableFlowing, false); // The stream emits the events asynchronously but that's not guaranteed to // happen on the next tick (especially since the _read implementation above // uses process.nextTick). // // We use setImmediate here to give the stream enough time to emit all the // events it's about to emit. setImmediate(() => { // Only the _read, push, readable calls have happened. No data must be // emitted yet. assert.deepStrictEqual(calls, ['_read:a', 'push:a', 'readable']); // Calling 'r.read()' should trigger the data event. assert.strictEqual(r.read(), 'a'); assert.deepStrictEqual( calls, ['_read:a', 'push:a', 'readable', 'data:a']); // The next 'read()' will return null because hwm: 0 does not buffer any // data and the _read implementation above does the push() asynchronously. // // Note: This 'null' signals "no data available". It isn't the end-of-stream // null value as the stream doesn't know yet that it is about to reach the // end. // // Using setImmediate again to give the stream enough time to emit all the // events it wants to emit. assert.strictEqual(r.read(), null); setImmediate(() => { // There's a new 'readable' event after the data has been pushed. // The 'end' event will be emitted only after a 'read()'. // // This is somewhat special for the case where the '_read' implementation // calls 'push' asynchronously. If 'push' was synchronous, the 'end' event // would be emitted here _before_ we call read(). assert.deepStrictEqual( calls, ['_read:a', 'push:a', 'readable', 'data:a', '_read:null', 'push:null', 'readable']); assert.strictEqual(r.read(), null); // While it isn't really specified whether the 'end' event should happen // synchronously with read() or not, we'll assert the current behavior // ('end' event happening on the next tick after read()) so any changes // to it are noted and acknowledged in the future. assert.deepStrictEqual( calls, ['_read:a', 'push:a', 'readable', 'data:a', '_read:null', 'push:null', 'readable']); process.nextTick(() => { assert.deepStrictEqual( calls, ['_read:a', 'push:a', 'readable', 'data:a', '_read:null', 'push:null', 'readable', 'end']); }); }); });