denoland-deno/core/http_bench.js

// This is not a real HTTP server. We read blindly one time into 'requestBuf',
// then write this fixed 'responseBuf'. The point of this benchmark is to
// exercise the event loop in a simple yet semi-realistic way.
const shared32 = new Int32Array(libdeno.shared);

const INDEX_NUM_RECORDS = 0;
const INDEX_RECORDS = 1;
const RECORD_OFFSET_PROMISE_ID = 0;
const RECORD_OFFSET_OP = 1;
const RECORD_OFFSET_ARG = 2;
const RECORD_OFFSET_RESULT = 3;
const RECORD_SIZE = 4;
const OP_LISTEN = 1;
const OP_ACCEPT = 2;
const OP_READ = 3;
const OP_WRITE = 4;
const OP_CLOSE = 5;

const NUM_RECORDS = (shared32.length - INDEX_RECORDS) / RECORD_SIZE;
if (NUM_RECORDS != 100) {
  throw Error("expected 100 entries");
}

const requestBuf = new Uint8Array(64 * 1024);
const responseBuf = new Uint8Array(
  "HTTP/1.1 200 OK\r\nContent-Length: 12\r\n\r\nHello World\n"
    .split("")
    .map(c => c.charCodeAt(0))
);

const promiseMap = new Map();
let nextPromiseId = 1;

function createResolvable() {
  let methods;
  const promise = new Promise((resolve, reject) => {
    methods = { resolve, reject };
  });
  return Object.assign(promise, methods);
}

/** Returns Promise<number> */
function sendAsync(op, arg, zeroCopyData) {
  const id = nextPromiseId++;
  const p = createResolvable();
  shared32[INDEX_NUM_RECORDS] = 1;
  setRecord(0, RECORD_OFFSET_PROMISE_ID, id);
  setRecord(0, RECORD_OFFSET_OP, op);
  setRecord(0, RECORD_OFFSET_ARG, arg);
  setRecord(0, RECORD_OFFSET_RESULT, -1);
  promiseMap.set(id, p);
  libdeno.send(null, zeroCopyData);
  return p;
}

/** Returns u32 number */
function sendSync(op, arg) {
  shared32[INDEX_NUM_RECORDS] = 1;
  setRecord(0, RECORD_OFFSET_PROMISE_ID, 0);
  setRecord(0, RECORD_OFFSET_OP, op);
  setRecord(0, RECORD_OFFSET_ARG, arg);
  setRecord(0, RECORD_OFFSET_RESULT, -1);
  libdeno.send();
  return getRecord(0, RECORD_OFFSET_RESULT);
}

function setRecord(i, off, value) {
  if (i >= NUM_RECORDS) {
    throw Error("out of range");
  }
  shared32[INDEX_RECORDS + RECORD_SIZE * i + off] = value;
}

function getRecord(i, off) {
  if (i >= NUM_RECORDS) {
    throw Error("out of range");
  }
  return shared32[INDEX_RECORDS + RECORD_SIZE * i + off];
}

function handleAsyncMsgFromRust() {
  for (let i = 0; i < shared32[INDEX_NUM_RECORDS]; i++) {
    let id = getRecord(i, RECORD_OFFSET_PROMISE_ID);
    const p = promiseMap.get(id);
    promiseMap.delete(id);
    p.resolve(getRecord(i, RECORD_OFFSET_RESULT));
  }
}

/** Listens on 0.0.0.0:4500, returns rid. */
function listen() {
  return sendSync(OP_LISTEN, -1);
}

/** Accepts a connection, returns rid. */
async function accept(rid) {
  return await sendAsync(OP_ACCEPT, rid);
}

/**
 * Reads a packet from the rid, presumably an http request. data is ignored.
 * Returns bytes read.
 */
async function read(rid, data) {
  return await sendAsync(OP_READ, rid, data);
}

/** Writes a fixed HTTP response to the socket rid. Returns bytes written. */
async function write(rid, data) {
  return await sendAsync(OP_WRITE, rid, data);
}

function close(rid) {
  return sendSync(OP_CLOSE, rid);
}

async function serve(rid) {
  while (true) {
    const nread = await read(rid, requestBuf);
    if (nread <= 0) {
      break;
    }

    const nwritten = await write(rid, responseBuf);
    if (nwritten < 0) {
      break;
    }
  }
  close(rid);
}

async function main() {
  libdeno.recv(handleAsyncMsgFromRust);

  libdeno.print("http_bench.js start");

  const listener_rid = listen();
  libdeno.print(`listening http://127.0.0.1:4544/ rid = ${listener_rid}`);
  while (true) {
    const rid = await accept(listener_rid);
    // libdeno.print(`accepted ${rid}`);
    if (rid < 0) {
      libdeno.print(`accept error ${rid}`);
      return;
    }
    serve(rid);
  }
}

main();
deno_core (#1827) A new low-level crate with focus on speed. This doesn't yet hook into the existing code base. 2019-02-26 17:36:05 -05:00			`// This is not a real HTTP server. We read blindly one time into 'requestBuf',`
			`// then write this fixed 'responseBuf'. The point of this benchmark is to`
			`// exercise the event loop in a simple yet semi-realistic way.`
			`const shared32 = new Int32Array(libdeno.shared);`

			`const INDEX_NUM_RECORDS = 0;`
			`const INDEX_RECORDS = 1;`
			`const RECORD_OFFSET_PROMISE_ID = 0;`
			`const RECORD_OFFSET_OP = 1;`
			`const RECORD_OFFSET_ARG = 2;`
			`const RECORD_OFFSET_RESULT = 3;`
			`const RECORD_SIZE = 4;`
			`const OP_LISTEN = 1;`
			`const OP_ACCEPT = 2;`
			`const OP_READ = 3;`
			`const OP_WRITE = 4;`
			`const OP_CLOSE = 5;`

			`const NUM_RECORDS = (shared32.length - INDEX_RECORDS) / RECORD_SIZE;`
			`if (NUM_RECORDS != 100) {`
			`throw Error("expected 100 entries");`
			`}`

			`const requestBuf = new Uint8Array(64 * 1024);`
			`const responseBuf = new Uint8Array(`
			`"HTTP/1.1 200 OK\r\nContent-Length: 12\r\n\r\nHello World\n"`
			`.split("")`
			`.map(c => c.charCodeAt(0))`
			`);`

			`const promiseMap = new Map();`
			`let nextPromiseId = 1;`

			`function createResolvable() {`
			`let methods;`
			`const promise = new Promise((resolve, reject) => {`
			`methods = { resolve, reject };`
			`});`
			`return Object.assign(promise, methods);`
			`}`

			`/** Returns Promise<number> */`
			`function sendAsync(op, arg, zeroCopyData) {`
			`const id = nextPromiseId++;`
			`const p = createResolvable();`
			`shared32[INDEX_NUM_RECORDS] = 1;`
			`setRecord(0, RECORD_OFFSET_PROMISE_ID, id);`
			`setRecord(0, RECORD_OFFSET_OP, op);`
			`setRecord(0, RECORD_OFFSET_ARG, arg);`
			`setRecord(0, RECORD_OFFSET_RESULT, -1);`
			`promiseMap.set(id, p);`
			`libdeno.send(null, zeroCopyData);`
			`return p;`
			`}`

			`/** Returns u32 number */`
			`function sendSync(op, arg) {`
			`shared32[INDEX_NUM_RECORDS] = 1;`
			`setRecord(0, RECORD_OFFSET_PROMISE_ID, 0);`
			`setRecord(0, RECORD_OFFSET_OP, op);`
			`setRecord(0, RECORD_OFFSET_ARG, arg);`
			`setRecord(0, RECORD_OFFSET_RESULT, -1);`
			`libdeno.send();`
			`return getRecord(0, RECORD_OFFSET_RESULT);`
			`}`

			`function setRecord(i, off, value) {`
			`if (i >= NUM_RECORDS) {`
			`throw Error("out of range");`
			`}`
			`shared32[INDEX_RECORDS + RECORD_SIZE * i + off] = value;`
			`}`

			`function getRecord(i, off) {`
			`if (i >= NUM_RECORDS) {`
			`throw Error("out of range");`
			`}`
			`return shared32[INDEX_RECORDS + RECORD_SIZE * i + off];`
			`}`

			`function handleAsyncMsgFromRust() {`
			`for (let i = 0; i < shared32[INDEX_NUM_RECORDS]; i++) {`
			`let id = getRecord(i, RECORD_OFFSET_PROMISE_ID);`
			`const p = promiseMap.get(id);`
			`promiseMap.delete(id);`
			`p.resolve(getRecord(i, RECORD_OFFSET_RESULT));`
			`}`
			`}`

			`/** Listens on 0.0.0.0:4500, returns rid. */`
			`function listen() {`
			`return sendSync(OP_LISTEN, -1);`
			`}`

			`/** Accepts a connection, returns rid. */`
			`async function accept(rid) {`
			`return await sendAsync(OP_ACCEPT, rid);`
			`}`

			`/**`
			`* Reads a packet from the rid, presumably an http request. data is ignored.`
			`* Returns bytes read.`
			`*/`
			`async function read(rid, data) {`
			`return await sendAsync(OP_READ, rid, data);`
			`}`

			`/** Writes a fixed HTTP response to the socket rid. Returns bytes written. */`
			`async function write(rid, data) {`
			`return await sendAsync(OP_WRITE, rid, data);`
			`}`

			`function close(rid) {`
			`return sendSync(OP_CLOSE, rid);`
			`}`

			`async function serve(rid) {`
			`while (true) {`
			`const nread = await read(rid, requestBuf);`
			`if (nread <= 0) {`
			`break;`
			`}`

			`const nwritten = await write(rid, responseBuf);`
			`if (nwritten < 0) {`
			`break;`
			`}`
			`}`
			`close(rid);`
			`}`

			`async function main() {`
			`libdeno.recv(handleAsyncMsgFromRust);`

			`libdeno.print("http_bench.js start");`

			`const listener_rid = listen();`
			libdeno.print(`listening http://127.0.0.1:4544/ rid = ${listener_rid}`);
			`while (true) {`
			`const rid = await accept(listener_rid);`
			// libdeno.print(`accepted ${rid}`);
			`if (rid < 0) {`
			libdeno.print(`accept error ${rid}`);
			`return;`
			`}`
			`serve(rid);`
			`}`
			`}`

			`main();`