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denoland-deno/http/server.ts
2019-05-20 17:44:58 -07:00

323 lines
9.5 KiB
TypeScript

// Copyright 2018-2019 the Deno authors. All rights reserved. MIT license.
const { listen, copy, toAsyncIterator } = Deno;
type Listener = Deno.Listener;
type Conn = Deno.Conn;
type Reader = Deno.Reader;
type Writer = Deno.Writer;
import { BufReader, BufState, BufWriter } from "../io/bufio.ts";
import { TextProtoReader } from "../textproto/mod.ts";
import { STATUS_TEXT } from "./http_status.ts";
import { assert, fail } from "../testing/asserts.ts";
import { deferred, Deferred, MuxAsyncIterator } from "../util/async.ts";
function bufWriter(w: Writer): BufWriter {
if (w instanceof BufWriter) {
return w;
} else {
return new BufWriter(w);
}
}
export function setContentLength(r: Response): void {
if (!r.headers) {
r.headers = new Headers();
}
if (r.body) {
if (!r.headers.has("content-length")) {
if (r.body instanceof Uint8Array) {
const bodyLength = r.body.byteLength;
r.headers.append("Content-Length", bodyLength.toString());
} else {
r.headers.append("Transfer-Encoding", "chunked");
}
}
}
}
async function writeChunkedBody(w: Writer, r: Reader): Promise<void> {
const writer = bufWriter(w);
const encoder = new TextEncoder();
for await (const chunk of toAsyncIterator(r)) {
if (chunk.byteLength <= 0) continue;
const start = encoder.encode(`${chunk.byteLength.toString(16)}\r\n`);
const end = encoder.encode("\r\n");
await writer.write(start);
await writer.write(chunk);
await writer.write(end);
}
const endChunk = encoder.encode("0\r\n\r\n");
await writer.write(endChunk);
}
export async function writeResponse(w: Writer, r: Response): Promise<void> {
const protoMajor = 1;
const protoMinor = 1;
const statusCode = r.status || 200;
const statusText = STATUS_TEXT.get(statusCode);
const writer = bufWriter(w);
if (!statusText) {
throw Error("bad status code");
}
let out = `HTTP/${protoMajor}.${protoMinor} ${statusCode} ${statusText}\r\n`;
setContentLength(r);
if (r.headers) {
for (const [key, value] of r.headers) {
out += `${key}: ${value}\r\n`;
}
}
out += "\r\n";
const header = new TextEncoder().encode(out);
let n = await writer.write(header);
assert(header.byteLength == n);
if (r.body) {
if (r.body instanceof Uint8Array) {
n = await writer.write(r.body);
assert(r.body.byteLength == n);
} else {
if (r.headers.has("content-length")) {
const bodyLength = parseInt(r.headers.get("content-length"));
const n = await copy(writer, r.body);
assert(n == bodyLength);
} else {
await writeChunkedBody(writer, r.body);
}
}
}
await writer.flush();
}
async function readAllIterator(
it: AsyncIterableIterator<Uint8Array>
): Promise<Uint8Array> {
const chunks = [];
let len = 0;
for await (const chunk of it) {
chunks.push(chunk);
len += chunk.length;
}
if (chunks.length === 0) {
// No need for copy
return chunks[0];
}
const collected = new Uint8Array(len);
let offset = 0;
for (let chunk of chunks) {
collected.set(chunk, offset);
offset += chunk.length;
}
return collected;
}
export class ServerRequest {
url: string;
method: string;
proto: string;
headers: Headers;
conn: Conn;
r: BufReader;
w: BufWriter;
done: Deferred<void> = deferred();
public async *bodyStream(): AsyncIterableIterator<Uint8Array> {
if (this.headers.has("content-length")) {
const len = +this.headers.get("content-length");
if (Number.isNaN(len)) {
return new Uint8Array(0);
}
let buf = new Uint8Array(1024);
let rr = await this.r.read(buf);
let nread = rr.nread;
while (!rr.eof && nread < len) {
yield buf.subarray(0, rr.nread);
buf = new Uint8Array(1024);
rr = await this.r.read(buf);
nread += rr.nread;
}
yield buf.subarray(0, rr.nread);
} else {
if (this.headers.has("transfer-encoding")) {
const transferEncodings = this.headers
.get("transfer-encoding")
.split(",")
.map((e): string => e.trim().toLowerCase());
if (transferEncodings.includes("chunked")) {
// Based on https://tools.ietf.org/html/rfc2616#section-19.4.6
const tp = new TextProtoReader(this.r);
let [line] = await tp.readLine();
// TODO: handle chunk extension
let [chunkSizeString] = line.split(";");
let chunkSize = parseInt(chunkSizeString, 16);
if (Number.isNaN(chunkSize) || chunkSize < 0) {
throw new Error("Invalid chunk size");
}
while (chunkSize > 0) {
let data = new Uint8Array(chunkSize);
let [nread] = await this.r.readFull(data);
if (nread !== chunkSize) {
throw new Error("Chunk data does not match size");
}
yield data;
await this.r.readLine(); // Consume \r\n
[line] = await tp.readLine();
chunkSize = parseInt(line, 16);
}
const [entityHeaders, err] = await tp.readMIMEHeader();
if (!err) {
for (let [k, v] of entityHeaders) {
this.headers.set(k, v);
}
}
/* Pseudo code from https://tools.ietf.org/html/rfc2616#section-19.4.6
length := 0
read chunk-size, chunk-extension (if any) and CRLF
while (chunk-size > 0) {
read chunk-data and CRLF
append chunk-data to entity-body
length := length + chunk-size
read chunk-size and CRLF
}
read entity-header
while (entity-header not empty) {
append entity-header to existing header fields
read entity-header
}
Content-Length := length
Remove "chunked" from Transfer-Encoding
*/
return; // Must return here to avoid fall through
}
// TODO: handle other transfer-encoding types
}
// Otherwise...
yield new Uint8Array(0);
}
}
// Read the body of the request into a single Uint8Array
public async body(): Promise<Uint8Array> {
return readAllIterator(this.bodyStream());
}
async respond(r: Response): Promise<void> {
// Write our response!
await writeResponse(this.w, r);
// Signal that this request has been processed and the next pipelined
// request on the same connection can be accepted.
this.done.resolve();
}
}
async function readRequest(
conn: Conn,
bufr: BufReader
): Promise<[ServerRequest, BufState]> {
const req = new ServerRequest();
req.conn = conn;
req.r = bufr;
req.w = new BufWriter(conn);
const tp = new TextProtoReader(bufr);
let err: BufState;
// First line: GET /index.html HTTP/1.0
let firstLine: string;
[firstLine, err] = await tp.readLine();
if (err) {
return [null, err];
}
[req.method, req.url, req.proto] = firstLine.split(" ", 3);
[req.headers, err] = await tp.readMIMEHeader();
return [req, err];
}
export class Server implements AsyncIterable<ServerRequest> {
private closing = false;
constructor(public listener: Listener) {}
close(): void {
this.closing = true;
this.listener.close();
}
// Yields all HTTP requests on a single TCP connection.
private async *iterateHttpRequests(
conn: Conn
): AsyncIterableIterator<ServerRequest> {
const bufr = new BufReader(conn);
let bufStateErr: BufState;
let req: ServerRequest;
while (!this.closing) {
[req, bufStateErr] = await readRequest(conn, bufr);
if (bufStateErr) break;
yield req;
// Wait for the request to be processed before we accept a new request on
// this connection.
await req.done;
}
if (bufStateErr === "EOF") {
// The connection was gracefully closed.
} else if (bufStateErr instanceof Error) {
// TODO(ry): send something back like a HTTP 500 status.
} else if (this.closing) {
// There are more requests incoming but the server is closing.
// TODO(ry): send a back a HTTP 503 Service Unavailable status.
} else {
fail(`unexpected BufState: ${bufStateErr}`);
}
conn.close();
}
// Accepts a new TCP connection and yields all HTTP requests that arrive on
// it. When a connection is accepted, it also creates a new iterator of the
// same kind and adds it to the request multiplexer so that another TCP
// connection can be accepted.
private async *acceptConnAndIterateHttpRequests(
mux: MuxAsyncIterator<ServerRequest>
): AsyncIterableIterator<ServerRequest> {
if (this.closing) return;
// Wait for a new connection.
const conn = await this.listener.accept();
// Try to accept another connection and add it to the multiplexer.
mux.add(this.acceptConnAndIterateHttpRequests(mux));
// Yield the requests that arrive on the just-accepted connection.
yield* this.iterateHttpRequests(conn);
}
[Symbol.asyncIterator](): AsyncIterableIterator<ServerRequest> {
const mux: MuxAsyncIterator<ServerRequest> = new MuxAsyncIterator();
mux.add(this.acceptConnAndIterateHttpRequests(mux));
return mux.iterate();
}
}
export function serve(addr: string): Server {
const listener = listen("tcp", addr);
return new Server(listener);
}
export async function listenAndServe(
addr: string,
handler: (req: ServerRequest) => void
): Promise<void> {
const server = serve(addr);
for await (const request of server) {
handler(request);
}
}
export interface Response {
status?: number;
headers?: Headers;
body?: Uint8Array | Reader;
}