// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license. import { assertEquals, assertRejects, fail } from "./test_util.ts"; const { core, resourceForReadableStream, // @ts-expect-error TypeScript (as of 3.7) does not support indexing namespaces by symbol } = Deno[Deno.internal]; const LOREM = "Lorem ipsum dolor sit amet, consectetur adipiscing elit, sed do eiusmod tempor incididunt ut labore et dolore magna aliqua."; // Hello world, with optional close function helloWorldStream( close?: boolean, cancelResolve?: (value: unknown) => void, ) { return new ReadableStream({ start(controller) { controller.enqueue("hello, world"); if (close == true) { controller.close(); } }, cancel(reason) { if (cancelResolve != undefined) { cancelResolve(reason); } }, }).pipeThrough(new TextEncoderStream()); } // Hello world, with optional close function errorStream(type: "string" | "controller" | "TypeError") { return new ReadableStream({ start(controller) { controller.enqueue("hello, world"); }, pull(controller) { if (type == "string") { throw "Uh oh (string)!"; } if (type == "TypeError") { throw TypeError("Uh oh (TypeError)!"); } controller.error("Uh oh (controller)!"); }, }).pipeThrough(new TextEncoderStream()); } // Long stream with Lorem Ipsum text. function longStream() { return new ReadableStream({ start(controller) { for (let i = 0; i < 4; i++) { setTimeout(() => { controller.enqueue(LOREM); if (i == 3) { controller.close(); } }, i * 100); } }, }).pipeThrough(new TextEncoderStream()); } // Long stream with Lorem Ipsum text. function longAsyncStream(cancelResolve?: (value: unknown) => void) { let currentTimeout: number | undefined = undefined; return new ReadableStream({ async start(controller) { for (let i = 0; i < 100; i++) { await new Promise((r) => currentTimeout = setTimeout(r, 1)); currentTimeout = undefined; controller.enqueue(LOREM); } controller.close(); }, cancel(reason) { if (cancelResolve != undefined) { cancelResolve(reason); } if (currentTimeout !== undefined) { clearTimeout(currentTimeout); } }, }).pipeThrough(new TextEncoderStream()); } // Empty stream, closes either immediately or on a call to pull. function emptyStream(onPull: boolean) { return new ReadableStream({ start(controller) { if (!onPull) { controller.close(); } }, pull(controller) { if (onPull) { controller.close(); } }, }).pipeThrough(new TextEncoderStream()); } function largePacketStream(packetSize: number, count: number) { return new ReadableStream({ pull(controller) { if (count-- > 0) { const buffer = new Uint8Array(packetSize); for (let i = 0; i < 256; i++) { buffer[i * (packetSize / 256)] = i; } controller.enqueue(buffer); } else { controller.close(); } }, }); } // Include an empty chunk function emptyChunkStream() { return new ReadableStream({ start(controller) { controller.enqueue(new Uint8Array([1])); controller.enqueue(new Uint8Array([])); controller.enqueue(new Uint8Array([2])); controller.close(); }, }); } // Try to blow up any recursive reads. function veryLongTinyPacketStream(length: number) { return new ReadableStream({ start(controller) { for (let i = 0; i < length; i++) { controller.enqueue(new Uint8Array([1])); } controller.close(); }, }); } // Creates a stream with the given number of packets, a configurable delay between packets, and a final // action (either "Throw" or "Close"). function makeStreamWithCount( count: number, delay: number, action: "Throw" | "Close", ): ReadableStream { function doAction(controller: ReadableStreamDefaultController, i: number) { if (i == count) { if (action == "Throw") { controller.error(new Error("Expected error!")); } else { controller.close(); } } else { controller.enqueue(String.fromCharCode("a".charCodeAt(0) + i)); if (delay == 0) { doAction(controller, i + 1); } else { setTimeout(() => doAction(controller, i + 1), delay); } } } return new ReadableStream({ start(controller) { if (delay == 0) { doAction(controller, 0); } else { setTimeout(() => doAction(controller, 0), delay); } }, }).pipeThrough(new TextEncoderStream()); } // Normal stream operation Deno.test(async function readableStream() { const rid = resourceForReadableStream(helloWorldStream()); const buffer = new Uint8Array(1024); const nread = await core.read(rid, buffer); assertEquals(nread, 12); core.close(rid); }); // Close the stream after reading everything Deno.test(async function readableStreamClose() { const cancel = Promise.withResolvers(); const rid = resourceForReadableStream( helloWorldStream(false, cancel.resolve), ); const buffer = new Uint8Array(1024); const nread = await core.read(rid, buffer); assertEquals(nread, 12); core.close(rid); assertEquals(await cancel.promise, "resource closed"); }); // Close the stream without reading everything Deno.test(async function readableStreamClosePartialRead() { const cancel = Promise.withResolvers(); const rid = resourceForReadableStream( helloWorldStream(false, cancel.resolve), ); const buffer = new Uint8Array(5); const nread = await core.read(rid, buffer); assertEquals(nread, 5); core.close(rid); assertEquals(await cancel.promise, "resource closed"); }); // Close the stream without reading anything Deno.test(async function readableStreamCloseWithoutRead() { const cancel = Promise.withResolvers(); const rid = resourceForReadableStream( helloWorldStream(false, cancel.resolve), ); core.close(rid); assertEquals(await cancel.promise, "resource closed"); }); // Close the stream without reading anything Deno.test(async function readableStreamCloseWithoutRead2() { const cancel = Promise.withResolvers(); const rid = resourceForReadableStream(longAsyncStream(cancel.resolve)); core.close(rid); assertEquals(await cancel.promise, "resource closed"); }); Deno.test(async function readableStreamPartial() { const rid = resourceForReadableStream(helloWorldStream()); const buffer = new Uint8Array(5); const nread = await core.read(rid, buffer); assertEquals(nread, 5); const buffer2 = new Uint8Array(1024); const nread2 = await core.read(rid, buffer2); assertEquals(nread2, 7); core.close(rid); }); Deno.test(async function readableStreamLongReadAll() { const rid = resourceForReadableStream(longStream()); const buffer = await core.readAll(rid); assertEquals(buffer.length, LOREM.length * 4); core.close(rid); }); Deno.test(async function readableStreamLongAsyncReadAll() { const rid = resourceForReadableStream(longAsyncStream()); const buffer = await core.readAll(rid); assertEquals(buffer.length, LOREM.length * 100); core.close(rid); }); Deno.test(async function readableStreamVeryLongReadAll() { const rid = resourceForReadableStream(veryLongTinyPacketStream(1_000_000)); const buffer = await core.readAll(rid); assertEquals(buffer.length, 1_000_000); core.close(rid); }); Deno.test(async function readableStreamLongByPiece() { const rid = resourceForReadableStream(longStream()); let total = 0; for (let i = 0; i < 100; i++) { const length = await core.read(rid, new Uint8Array(16)); total += length; if (length == 0) { break; } } assertEquals(total, LOREM.length * 4); core.close(rid); }); for ( const type of [ "string", "TypeError", "controller", ] as ("string" | "TypeError" | "controller")[] ) { Deno.test(`readableStreamError_${type}`, async function () { const rid = resourceForReadableStream(errorStream(type)); let nread; try { nread = await core.read(rid, new Uint8Array(16)); } catch (_) { fail("Should not have thrown"); } assertEquals(12, nread); try { await core.read(rid, new Uint8Array(1)); fail(); } catch (e) { assertEquals((e as Error).message, `Uh oh (${type})!`); } core.close(rid); }); } Deno.test(async function readableStreamEmptyOnStart() { const rid = resourceForReadableStream(emptyStream(true)); const buffer = new Uint8Array(1024); const nread = await core.read(rid, buffer); assertEquals(nread, 0); core.close(rid); }); Deno.test(async function readableStreamEmptyOnPull() { const rid = resourceForReadableStream(emptyStream(false)); const buffer = new Uint8Array(1024); const nread = await core.read(rid, buffer); assertEquals(nread, 0); core.close(rid); }); Deno.test(async function readableStreamEmptyReadAll() { const rid = resourceForReadableStream(emptyStream(false)); const buffer = await core.readAll(rid); assertEquals(buffer.length, 0); core.close(rid); }); Deno.test(async function readableStreamWithEmptyChunk() { const rid = resourceForReadableStream(emptyChunkStream()); const buffer = await core.readAll(rid); assertEquals(buffer, new Uint8Array([1, 2])); core.close(rid); }); Deno.test(async function readableStreamWithEmptyChunkOneByOne() { const rid = resourceForReadableStream(emptyChunkStream()); assertEquals(1, await core.read(rid, new Uint8Array(1))); assertEquals(1, await core.read(rid, new Uint8Array(1))); assertEquals(0, await core.read(rid, new Uint8Array(1))); core.close(rid); }); // Ensure that we correctly transmit all the sub-chunks of the larger chunks. Deno.test(async function readableStreamReadSmallerChunks() { const packetSize = 16 * 1024; const rid = resourceForReadableStream(largePacketStream(packetSize, 1)); const buffer = new Uint8Array(packetSize); for (let i = 0; i < packetSize / 1024; i++) { await core.read(rid, buffer.subarray(i * 1024, i * 1024 + 1024)); } for (let i = 0; i < 256; i++) { assertEquals( i, buffer[i * (packetSize / 256)], `at index ${i * (packetSize / 256)}`, ); } core.close(rid); }); Deno.test(async function readableStreamLargePackets() { const packetSize = 128 * 1024; const rid = resourceForReadableStream(largePacketStream(packetSize, 1024)); for (let i = 0; i < 1024; i++) { const buffer = new Uint8Array(packetSize); assertEquals(packetSize, await core.read(rid, buffer)); for (let i = 0; i < 256; i++) { assertEquals( i, buffer[i * (packetSize / 256)], `at index ${i * (packetSize / 256)}`, ); } } assertEquals(0, await core.read(rid, new Uint8Array(1))); core.close(rid); }); Deno.test(async function readableStreamVeryLargePackets() { // 1024 packets of 1MB const rid = resourceForReadableStream(largePacketStream(1024 * 1024, 1024)); let total = 0; // Read 96kB up to 12,288 times (96kB is not an even multiple of the 1MB packet size to test this) const readCounts: Record = {}; for (let i = 0; i < 12 * 1024; i++) { const nread = await core.read(rid, new Uint8Array(96 * 1024)); total += nread; readCounts[nread] = (readCounts[nread] || 0) + 1; if (nread == 0) { break; } } assertEquals({ 0: 1, 65536: 1024, 98304: 10 * 1024 }, readCounts); assertEquals(total, 1024 * 1024 * 1024); core.close(rid); }); for (const count of [0, 1, 2, 3]) { for (const delay of [0, 1, 10]) { // Creating a stream that errors in start will throw if (delay > 0) { createStreamTest(count, delay, "Throw"); } createStreamTest(count, delay, "Close"); } } function createStreamTest( count: number, delay: number, action: "Throw" | "Close", ) { Deno.test(`streamCount${count}Delay${delay}${action}`, async () => { let rid; try { rid = resourceForReadableStream( makeStreamWithCount(count, delay, action), ); for (let i = 0; i < count; i++) { const buffer = new Uint8Array(1); await core.read(rid, buffer); } if (action == "Throw") { try { const buffer = new Uint8Array(1); assertEquals(1, await core.read(rid, buffer)); fail(); } catch (e) { // We expect this to be thrown assertEquals((e as Error).message, "Expected error!"); } } else { const buffer = new Uint8Array(1); assertEquals(0, await core.read(rid, buffer)); } } finally { core.close(rid); } }); } // 1024 is the size of the internal packet buffer -- we want to make sure we fill the internal pipe fully. for (const packetCount of [1, 1024]) { Deno.test(`readableStreamWithAggressiveResourceClose_${packetCount}`, async function () { let first = true; const { promise, resolve } = Promise.withResolvers(); const rid = resourceForReadableStream( new ReadableStream({ pull(controller) { if (first) { // We queue this up and then immediately close the resource (not the reader) for (let i = 0; i < packetCount; i++) { controller.enqueue(new Uint8Array(1)); } core.close(rid); // This doesn't throw, even though the resource is closed controller.enqueue(new Uint8Array(1)); first = false; } }, cancel(reason) { resolve(reason); }, }), ); try { for (let i = 0; i < packetCount; i++) { await core.read(rid, new Uint8Array(1)); } fail(); } catch (e) { assertEquals((e as Error).message, "operation canceled"); } assertEquals(await promise, "resource closed"); }); } Deno.test(async function compressionStreamWritableMayBeAborted() { await Promise.all([ new CompressionStream("gzip").writable.getWriter().abort(), new CompressionStream("deflate").writable.getWriter().abort(), new CompressionStream("deflate-raw").writable.getWriter().abort(), ]); }); Deno.test(async function compressionStreamReadableMayBeCancelled() { await Promise.all([ new CompressionStream("gzip").readable.getReader().cancel(), new CompressionStream("deflate").readable.getReader().cancel(), new CompressionStream("deflate-raw").readable.getReader().cancel(), ]); }); Deno.test(async function decompressionStreamWritableMayBeAborted() { await Promise.all([ new DecompressionStream("gzip").writable.getWriter().abort(), new DecompressionStream("deflate").writable.getWriter().abort(), new DecompressionStream("deflate-raw").writable.getWriter().abort(), ]); }); Deno.test(async function decompressionStreamReadableMayBeCancelled() { await Promise.all([ new DecompressionStream("gzip").readable.getReader().cancel(), new DecompressionStream("deflate").readable.getReader().cancel(), new DecompressionStream("deflate-raw").readable.getReader().cancel(), ]); }); Deno.test(async function decompressionStreamValidGzipDoesNotThrow() { const cs = new CompressionStream("gzip"); const ds = new DecompressionStream("gzip"); cs.readable.pipeThrough(ds); const writer = cs.writable.getWriter(); await writer.write(new Uint8Array([1])); writer.releaseLock(); await cs.writable.close(); let result = new Uint8Array(); for await (const chunk of ds.readable.values()) { result = new Uint8Array([...result, ...chunk]); } assertEquals(result, new Uint8Array([1])); }); Deno.test(async function decompressionStreamInvalidGzipStillReported() { await assertRejects( async () => { await new DecompressionStream("gzip").writable.close(); }, TypeError, "corrupt gzip stream does not have a matching checksum", ); });