blob: 68d0f2950cfd755a681c4bd4927b8b1b8fd03759 [file] [log] [blame]
// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
part of dart._http;
const String _webSocketGUID = "258EAFA5-E914-47DA-95CA-C5AB0DC85B11";
const String _clientNoContextTakeover = "client_no_context_takeover";
const String _serverNoContextTakeover = "server_no_context_takeover";
const String _clientMaxWindowBits = "client_max_window_bits";
const String _serverMaxWindowBits = "server_max_window_bits";
// Matches _WebSocketOpcode.
class _WebSocketMessageType {
static const int NONE = 0;
static const int TEXT = 1;
static const int BINARY = 2;
}
class _WebSocketOpcode {
static const int CONTINUATION = 0;
static const int TEXT = 1;
static const int BINARY = 2;
static const int RESERVED_3 = 3;
static const int RESERVED_4 = 4;
static const int RESERVED_5 = 5;
static const int RESERVED_6 = 6;
static const int RESERVED_7 = 7;
static const int CLOSE = 8;
static const int PING = 9;
static const int PONG = 10;
static const int RESERVED_B = 11;
static const int RESERVED_C = 12;
static const int RESERVED_D = 13;
static const int RESERVED_E = 14;
static const int RESERVED_F = 15;
}
class _EncodedString {
final List<int> bytes;
_EncodedString(this.bytes);
}
/**
* Stores the header and integer value derived from negotiation of
* client_max_window_bits and server_max_window_bits. headerValue will be
* set in the Websocket response headers.
*/
class _CompressionMaxWindowBits {
String headerValue;
int maxWindowBits;
_CompressionMaxWindowBits(this.headerValue, this.maxWindowBits);
String toString() => headerValue;
}
/**
* The web socket protocol transformer handles the protocol byte stream
* which is supplied through the `handleData`. As the protocol is processed,
* it'll output frame data as either a List<int> or String.
*
* Important information about usage: Be sure you use cancelOnError, so the
* socket will be closed when the processor encounter an error. Not using it
* will lead to undefined behaviour.
*/
class _WebSocketProtocolTransformer extends StreamTransformerBase<List<int>,
dynamic /*List<int>|_WebSocketPing|_WebSocketPong*/ >
implements EventSink<List<int>> {
static const int START = 0;
static const int LEN_FIRST = 1;
static const int LEN_REST = 2;
static const int MASK = 3;
static const int PAYLOAD = 4;
static const int CLOSED = 5;
static const int FAILURE = 6;
static const int FIN = 0x80;
static const int RSV1 = 0x40;
static const int RSV2 = 0x20;
static const int RSV3 = 0x10;
static const int OPCODE = 0xF;
int _state = START;
bool _fin = false;
bool _compressed = false;
int _opcode = -1;
int _len = -1;
bool _masked = false;
int _remainingLenBytes = -1;
int _remainingMaskingKeyBytes = 4;
int _remainingPayloadBytes = -1;
int _unmaskingIndex = 0;
int _currentMessageType = _WebSocketMessageType.NONE;
int closeCode = WebSocketStatus.NO_STATUS_RECEIVED;
String closeReason = "";
EventSink<dynamic /*List<int>|_WebSocketPing|_WebSocketPong*/ >? _eventSink;
final bool _serverSide;
final Uint8List _maskingBytes = Uint8List(4);
final BytesBuilder _payload = new BytesBuilder(copy: false);
_WebSocketPerMessageDeflate? _deflate;
_WebSocketProtocolTransformer([this._serverSide = false, this._deflate]);
Stream<dynamic /*List<int>|_WebSocketPing|_WebSocketPong*/ > bind(
Stream<List<int>> stream) {
return new Stream.eventTransformed(stream, (EventSink eventSink) {
if (_eventSink != null) {
throw new StateError("WebSocket transformer already used.");
}
_eventSink = eventSink;
return this;
});
}
void addError(Object error, [StackTrace? stackTrace]) {
// TODO(40614): Remove once non-nullability is sound.
ArgumentError.checkNotNull(error, "error");
_eventSink!.addError(error, stackTrace);
}
void close() {
_eventSink!.close();
}
/**
* Process data received from the underlying communication channel.
*/
void add(List<int> bytes) {
var buffer = bytes is Uint8List ? bytes : new Uint8List.fromList(bytes);
int index = 0;
int lastIndex = buffer.length;
if (_state == CLOSED) {
throw new WebSocketException("Data on closed connection");
}
if (_state == FAILURE) {
throw new WebSocketException("Data on failed connection");
}
while ((index < lastIndex) && _state != CLOSED && _state != FAILURE) {
int byte = buffer[index];
if (_state <= LEN_REST) {
if (_state == START) {
_fin = (byte & FIN) != 0;
if ((byte & (RSV2 | RSV3)) != 0) {
// The RSV2, RSV3 bits must both be zero.
throw new WebSocketException("Protocol error");
}
_opcode = (byte & OPCODE);
if (_opcode != _WebSocketOpcode.CONTINUATION) {
if ((byte & RSV1) != 0) {
_compressed = true;
} else {
_compressed = false;
}
}
if (_opcode <= _WebSocketOpcode.BINARY) {
if (_opcode == _WebSocketOpcode.CONTINUATION) {
if (_currentMessageType == _WebSocketMessageType.NONE) {
throw new WebSocketException("Protocol error");
}
} else {
assert(_opcode == _WebSocketOpcode.TEXT ||
_opcode == _WebSocketOpcode.BINARY);
if (_currentMessageType != _WebSocketMessageType.NONE) {
throw new WebSocketException("Protocol error");
}
_currentMessageType = _opcode;
}
} else if (_opcode >= _WebSocketOpcode.CLOSE &&
_opcode <= _WebSocketOpcode.PONG) {
// Control frames cannot be fragmented.
if (!_fin) throw new WebSocketException("Protocol error");
} else {
throw new WebSocketException("Protocol error");
}
_state = LEN_FIRST;
} else if (_state == LEN_FIRST) {
_masked = (byte & 0x80) != 0;
_len = byte & 0x7F;
if (_isControlFrame() && _len > 125) {
throw new WebSocketException("Protocol error");
}
if (_len == 126) {
_len = 0;
_remainingLenBytes = 2;
_state = LEN_REST;
} else if (_len == 127) {
_len = 0;
_remainingLenBytes = 8;
_state = LEN_REST;
} else {
assert(_len < 126);
_lengthDone();
}
} else {
assert(_state == LEN_REST);
_len = _len << 8 | byte;
_remainingLenBytes--;
if (_remainingLenBytes == 0) {
_lengthDone();
}
}
} else {
if (_state == MASK) {
_maskingBytes[4 - _remainingMaskingKeyBytes--] = byte;
if (_remainingMaskingKeyBytes == 0) {
_maskDone();
}
} else {
assert(_state == PAYLOAD);
// The payload is not handled one byte at a time but in blocks.
int payloadLength = min(lastIndex - index, _remainingPayloadBytes);
_remainingPayloadBytes -= payloadLength;
// Unmask payload if masked.
if (_masked) {
_unmask(index, payloadLength, buffer);
}
// Control frame and data frame share _payloads.
_payload.add(new Uint8List.view(
buffer.buffer, buffer.offsetInBytes + index, payloadLength));
index += payloadLength;
if (_isControlFrame()) {
if (_remainingPayloadBytes == 0) _controlFrameEnd();
} else {
if (_currentMessageType != _WebSocketMessageType.TEXT &&
_currentMessageType != _WebSocketMessageType.BINARY) {
throw new WebSocketException("Protocol error");
}
if (_remainingPayloadBytes == 0) _messageFrameEnd();
}
// Hack - as we always do index++ below.
index--;
}
}
// Move to the next byte.
index++;
}
}
void _unmask(int index, int length, Uint8List buffer) {
const int BLOCK_SIZE = 16;
// Skip Int32x4-version if message is small.
if (length >= BLOCK_SIZE) {
// Start by aligning to 16 bytes.
final int startOffset = BLOCK_SIZE - (index & 15);
final int end = index + startOffset;
for (int i = index; i < end; i++) {
buffer[i] ^= _maskingBytes[_unmaskingIndex++ & 3];
}
index += startOffset;
length -= startOffset;
final int blockCount = length ~/ BLOCK_SIZE;
if (blockCount > 0) {
// Create mask block.
int mask = 0;
for (int i = 3; i >= 0; i--) {
mask = (mask << 8) | _maskingBytes[(_unmaskingIndex + i) & 3];
}
Int32x4 blockMask = new Int32x4(mask, mask, mask, mask);
Int32x4List blockBuffer = new Int32x4List.view(
buffer.buffer, buffer.offsetInBytes + index, blockCount);
for (int i = 0; i < blockBuffer.length; i++) {
blockBuffer[i] ^= blockMask;
}
final int bytes = blockCount * BLOCK_SIZE;
index += bytes;
length -= bytes;
}
}
// Handle end.
final int end = index + length;
for (int i = index; i < end; i++) {
buffer[i] ^= _maskingBytes[_unmaskingIndex++ & 3];
}
}
void _lengthDone() {
if (_masked) {
if (!_serverSide) {
throw new WebSocketException("Received masked frame from server");
}
_state = MASK;
} else {
if (_serverSide) {
throw new WebSocketException("Received unmasked frame from client");
}
_remainingPayloadBytes = _len;
_startPayload();
}
}
void _maskDone() {
_remainingPayloadBytes = _len;
_startPayload();
}
void _startPayload() {
// If there is no actual payload perform perform callbacks without
// going through the PAYLOAD state.
if (_remainingPayloadBytes == 0) {
if (_isControlFrame()) {
switch (_opcode) {
case _WebSocketOpcode.CLOSE:
_state = CLOSED;
_eventSink!.close();
break;
case _WebSocketOpcode.PING:
_eventSink!.add(new _WebSocketPing());
break;
case _WebSocketOpcode.PONG:
_eventSink!.add(new _WebSocketPong());
break;
}
_prepareForNextFrame();
} else {
_messageFrameEnd();
}
} else {
_state = PAYLOAD;
}
}
void _messageFrameEnd() {
if (_fin) {
var bytes = _payload.takeBytes();
var deflate = _deflate;
if (deflate != null && _compressed) {
bytes = deflate.processIncomingMessage(bytes);
}
switch (_currentMessageType) {
case _WebSocketMessageType.TEXT:
_eventSink!.add(utf8.decode(bytes));
break;
case _WebSocketMessageType.BINARY:
_eventSink!.add(bytes);
break;
}
_currentMessageType = _WebSocketMessageType.NONE;
}
_prepareForNextFrame();
}
void _controlFrameEnd() {
switch (_opcode) {
case _WebSocketOpcode.CLOSE:
closeCode = WebSocketStatus.noStatusReceived;
var payload = _payload.takeBytes();
if (payload.length > 0) {
if (payload.length == 1) {
throw new WebSocketException("Protocol error");
}
closeCode = payload[0] << 8 | payload[1];
if (closeCode == WebSocketStatus.noStatusReceived) {
throw new WebSocketException("Protocol error");
}
if (payload.length > 2) {
closeReason = utf8.decode(payload.sublist(2));
}
}
_state = CLOSED;
_eventSink!.close();
break;
case _WebSocketOpcode.PING:
_eventSink!.add(new _WebSocketPing(_payload.takeBytes()));
break;
case _WebSocketOpcode.PONG:
_eventSink!.add(new _WebSocketPong(_payload.takeBytes()));
break;
}
_prepareForNextFrame();
}
bool _isControlFrame() {
return _opcode == _WebSocketOpcode.CLOSE ||
_opcode == _WebSocketOpcode.PING ||
_opcode == _WebSocketOpcode.PONG;
}
void _prepareForNextFrame() {
if (_state != CLOSED && _state != FAILURE) _state = START;
_fin = false;
_opcode = -1;
_len = -1;
_remainingLenBytes = -1;
_remainingMaskingKeyBytes = 4;
_remainingPayloadBytes = -1;
_unmaskingIndex = 0;
}
}
class _WebSocketPing {
final List<int>? payload;
_WebSocketPing([this.payload = null]);
}
class _WebSocketPong {
final List<int>? payload;
_WebSocketPong([this.payload = null]);
}
typedef /*String|Future<String>*/ _ProtocolSelector(List<String> protocols);
class _WebSocketTransformerImpl
extends StreamTransformerBase<HttpRequest, WebSocket>
implements WebSocketTransformer {
final StreamController<WebSocket> _controller =
new StreamController<WebSocket>(sync: true);
final _ProtocolSelector? _protocolSelector;
final CompressionOptions _compression;
_WebSocketTransformerImpl(this._protocolSelector, this._compression);
Stream<WebSocket> bind(Stream<HttpRequest> stream) {
stream.listen((request) {
_upgrade(request, _protocolSelector, _compression)
.then((WebSocket webSocket) => _controller.add(webSocket))
.catchError(_controller.addError);
}, onDone: () {
_controller.close();
});
return _controller.stream;
}
static List<String> _tokenizeFieldValue(String headerValue) {
List<String> tokens = <String>[];
int start = 0;
int index = 0;
while (index < headerValue.length) {
if (headerValue[index] == ",") {
tokens.add(headerValue.substring(start, index));
start = index + 1;
} else if (headerValue[index] == " " || headerValue[index] == "\t") {
start++;
}
index++;
}
tokens.add(headerValue.substring(start, index));
return tokens;
}
static Future<WebSocket> _upgrade(HttpRequest request,
_ProtocolSelector? protocolSelector, CompressionOptions compression) {
var response = request.response;
if (!_isUpgradeRequest(request)) {
// Send error response.
response
..statusCode = HttpStatus.badRequest
..close();
return new Future.error(
new WebSocketException("Invalid WebSocket upgrade request"));
}
Future<WebSocket> upgrade(String? protocol) {
// Send the upgrade response.
response
..statusCode = HttpStatus.switchingProtocols
..headers.add(HttpHeaders.connectionHeader, "Upgrade")
..headers.add(HttpHeaders.upgradeHeader, "websocket");
String key = request.headers.value("Sec-WebSocket-Key")!;
_SHA1 sha1 = new _SHA1();
sha1.add("$key$_webSocketGUID".codeUnits);
String accept = _CryptoUtils.bytesToBase64(sha1.close());
response.headers.add("Sec-WebSocket-Accept", accept);
if (protocol != null) {
response.headers.add("Sec-WebSocket-Protocol", protocol);
}
var deflate = _negotiateCompression(request, response, compression);
response.headers.contentLength = 0;
return response.detachSocket().then<WebSocket>((socket) =>
new _WebSocketImpl._fromSocket(
socket, protocol, compression, true, deflate));
}
var protocols = request.headers['Sec-WebSocket-Protocol'];
if (protocols != null && protocolSelector != null) {
// The suggested protocols can be spread over multiple lines, each
// consisting of multiple protocols. To unify all of them, first join
// the lists with ', ' and then tokenize.
var tokenizedProtocols = _tokenizeFieldValue(protocols.join(', '));
return new Future<String>(() => protocolSelector(tokenizedProtocols))
.then<String>((protocol) {
if (tokenizedProtocols.indexOf(protocol) < 0) {
throw new WebSocketException(
"Selected protocol is not in the list of available protocols");
}
return protocol;
}).catchError((error) {
response
..statusCode = HttpStatus.internalServerError
..close();
throw error;
}).then<WebSocket>(upgrade);
} else {
return upgrade(null);
}
}
static _WebSocketPerMessageDeflate? _negotiateCompression(HttpRequest request,
HttpResponse response, CompressionOptions compression) {
var extensionHeader = request.headers.value("Sec-WebSocket-Extensions");
extensionHeader ??= "";
var hv = HeaderValue.parse(extensionHeader, valueSeparator: ',');
if (compression.enabled && hv.value == _WebSocketImpl.PER_MESSAGE_DEFLATE) {
var info = compression._createHeader(hv);
response.headers.add("Sec-WebSocket-Extensions", info.headerValue);
var serverNoContextTakeover =
(hv.parameters.containsKey(_serverNoContextTakeover) &&
compression.serverNoContextTakeover);
var clientNoContextTakeover =
(hv.parameters.containsKey(_clientNoContextTakeover) &&
compression.clientNoContextTakeover);
var deflate = new _WebSocketPerMessageDeflate(
serverNoContextTakeover: serverNoContextTakeover,
clientNoContextTakeover: clientNoContextTakeover,
serverMaxWindowBits: info.maxWindowBits,
clientMaxWindowBits: info.maxWindowBits,
serverSide: true);
return deflate;
}
return null;
}
static bool _isUpgradeRequest(HttpRequest request) {
if (request.method != "GET") {
return false;
}
var connectionHeader = request.headers[HttpHeaders.connectionHeader];
if (connectionHeader == null) {
return false;
}
bool isUpgrade = false;
for (var value in connectionHeader) {
if (value.toLowerCase() == "upgrade") {
isUpgrade = true;
break;
}
}
if (!isUpgrade) return false;
String? upgrade = request.headers.value(HttpHeaders.upgradeHeader);
if (upgrade == null || upgrade.toLowerCase() != "websocket") {
return false;
}
String? version = request.headers.value("Sec-WebSocket-Version");
if (version == null || version != "13") {
return false;
}
String? key = request.headers.value("Sec-WebSocket-Key");
if (key == null) {
return false;
}
return true;
}
}
class _WebSocketPerMessageDeflate {
bool serverNoContextTakeover;
bool clientNoContextTakeover;
int clientMaxWindowBits;
int serverMaxWindowBits;
bool serverSide;
RawZLibFilter? decoder;
RawZLibFilter? encoder;
_WebSocketPerMessageDeflate(
{this.clientMaxWindowBits = _WebSocketImpl.DEFAULT_WINDOW_BITS,
this.serverMaxWindowBits = _WebSocketImpl.DEFAULT_WINDOW_BITS,
this.serverNoContextTakeover = false,
this.clientNoContextTakeover = false,
this.serverSide = false});
RawZLibFilter _ensureDecoder() => decoder ??= new RawZLibFilter.inflateFilter(
windowBits: serverSide ? clientMaxWindowBits : serverMaxWindowBits,
raw: true);
RawZLibFilter _ensureEncoder() => encoder ??= new RawZLibFilter.deflateFilter(
windowBits: serverSide ? serverMaxWindowBits : clientMaxWindowBits,
raw: true);
Uint8List processIncomingMessage(List<int> msg) {
var decoder = _ensureDecoder();
var data = <int>[];
data.addAll(msg);
data.addAll(const [0x00, 0x00, 0xff, 0xff]);
decoder.process(data, 0, data.length);
final result = new BytesBuilder();
List<int> out;
while (true) {
final out = decoder.processed();
if (out == null) break;
result.add(out);
}
if ((serverSide && clientNoContextTakeover) ||
(!serverSide && serverNoContextTakeover)) {
this.decoder = null;
}
return result.takeBytes();
}
List<int> processOutgoingMessage(List<int> msg) {
var encoder = _ensureEncoder();
var result = <int>[];
Uint8List buffer;
if (msg is! Uint8List) {
for (var i = 0; i < msg.length; i++) {
if (msg[i] < 0 || 255 < msg[i]) {
throw new ArgumentError("List element is not a byte value "
"(value ${msg[i]} at index $i)");
}
}
buffer = new Uint8List.fromList(msg);
} else {
buffer = msg;
}
encoder.process(buffer, 0, buffer.length);
while (true) {
final out = encoder.processed();
if (out == null) break;
result.addAll(out);
}
if ((!serverSide && clientNoContextTakeover) ||
(serverSide && serverNoContextTakeover)) {
this.encoder = null;
}
if (result.length > 4) {
result = result.sublist(0, result.length - 4);
}
// RFC 7692 7.2.3.6. "Generating an Empty Fragment" says that if the
// compression library doesn't generate any data when the bufer is empty,
// then an empty uncompressed deflate block is used for this purpose. The
// 0x00 block has the BFINAL header bit set to 0 and the BTYPE header set to
// 00 along with 5 bits of padding. This block decodes to zero bytes.
if (result.length == 0) {
return [0x00];
}
return result;
}
}
// TODO(ajohnsen): Make this transformer reusable.
class _WebSocketOutgoingTransformer
extends StreamTransformerBase<dynamic, List<int>> implements EventSink {
final _WebSocketImpl webSocket;
EventSink<List<int>>? _eventSink;
_WebSocketPerMessageDeflate? _deflateHelper;
_WebSocketOutgoingTransformer(this.webSocket)
: _deflateHelper = webSocket._deflate;
Stream<List<int>> bind(Stream stream) {
return new Stream<List<int>>.eventTransformed(stream,
(EventSink<List<int>> eventSink) {
if (_eventSink != null) {
throw new StateError("WebSocket transformer already used");
}
_eventSink = eventSink;
return this;
});
}
void add(message) {
if (message is _WebSocketPong) {
addFrame(_WebSocketOpcode.PONG, message.payload);
return;
}
if (message is _WebSocketPing) {
addFrame(_WebSocketOpcode.PING, message.payload);
return;
}
List<int>? data;
int opcode;
if (message != null) {
List<int> messageData;
if (message is String) {
opcode = _WebSocketOpcode.TEXT;
messageData = utf8.encode(message);
} else if (message is List<int>) {
opcode = _WebSocketOpcode.BINARY;
messageData = message;
} else if (message is _EncodedString) {
opcode = _WebSocketOpcode.TEXT;
messageData = message.bytes;
} else {
throw new ArgumentError(message);
}
var deflateHelper = _deflateHelper;
if (deflateHelper != null) {
messageData = deflateHelper.processOutgoingMessage(messageData);
}
data = messageData;
} else {
opcode = _WebSocketOpcode.TEXT;
}
addFrame(opcode, data);
}
void addError(Object error, [StackTrace? stackTrace]) {
// TODO(40614): Remove once non-nullability is sound.
ArgumentError.checkNotNull(error, "error");
_eventSink!.addError(error, stackTrace);
}
void close() {
int? code = webSocket._outCloseCode;
String? reason = webSocket._outCloseReason;
List<int>? data;
if (code != null) {
data = [
(code >> 8) & 0xFF,
code & 0xFF,
if (reason != null) ...utf8.encode(reason)
];
}
addFrame(_WebSocketOpcode.CLOSE, data);
_eventSink!.close();
}
void addFrame(int opcode, List<int>? data) {
createFrame(
opcode,
data,
webSocket._serverSide,
_deflateHelper != null &&
(opcode == _WebSocketOpcode.TEXT ||
opcode == _WebSocketOpcode.BINARY))
.forEach((e) {
_eventSink!.add(e);
});
}
static Iterable<List<int>> createFrame(
int opcode, List<int>? data, bool serverSide, bool compressed) {
bool mask = !serverSide; // Masking not implemented for server.
int dataLength = data == null ? 0 : data.length;
// Determine the header size.
int headerSize = (mask) ? 6 : 2;
if (dataLength > 65535) {
headerSize += 8;
} else if (dataLength > 125) {
headerSize += 2;
}
Uint8List header = new Uint8List(headerSize);
int index = 0;
// Set FIN and opcode.
var hoc = _WebSocketProtocolTransformer.FIN |
(compressed ? _WebSocketProtocolTransformer.RSV1 : 0) |
(opcode & _WebSocketProtocolTransformer.OPCODE);
header[index++] = hoc;
// Determine size and position of length field.
int lengthBytes = 1;
if (dataLength > 65535) {
header[index++] = 127;
lengthBytes = 8;
} else if (dataLength > 125) {
header[index++] = 126;
lengthBytes = 2;
}
// Write the length in network byte order into the header.
for (int i = 0; i < lengthBytes; i++) {
header[index++] = dataLength >> (((lengthBytes - 1) - i) * 8) & 0xFF;
}
if (mask) {
header[1] |= 1 << 7;
var maskBytes = _CryptoUtils.getRandomBytes(4);
header.setRange(index, index + 4, maskBytes);
index += 4;
if (data != null) {
Uint8List list;
// If this is a text message just do the masking inside the
// encoded data.
if (opcode == _WebSocketOpcode.TEXT && data is Uint8List) {
list = data;
} else {
if (data is Uint8List) {
list = new Uint8List.fromList(data);
} else {
list = new Uint8List(data.length);
for (int i = 0; i < data.length; i++) {
if (data[i] < 0 || 255 < data[i]) {
throw new ArgumentError("List element is not a byte value "
"(value ${data[i]} at index $i)");
}
list[i] = data[i];
}
}
}
const int BLOCK_SIZE = 16;
int blockCount = list.length ~/ BLOCK_SIZE;
if (blockCount > 0) {
// Create mask block.
int mask = 0;
for (int i = 3; i >= 0; i--) {
mask = (mask << 8) | maskBytes[i];
}
Int32x4 blockMask = new Int32x4(mask, mask, mask, mask);
Int32x4List blockBuffer =
new Int32x4List.view(list.buffer, list.offsetInBytes, blockCount);
for (int i = 0; i < blockBuffer.length; i++) {
blockBuffer[i] ^= blockMask;
}
}
// Handle end.
for (int i = blockCount * BLOCK_SIZE; i < list.length; i++) {
list[i] ^= maskBytes[i & 3];
}
data = list;
}
}
assert(index == headerSize);
if (data == null) {
return [header];
} else {
return [header, data];
}
}
}
class _WebSocketConsumer implements StreamConsumer {
final _WebSocketImpl webSocket;
final Socket socket;
StreamController? _controller;
StreamSubscription? _subscription;
bool _issuedPause = false;
bool _closed = false;
Completer _closeCompleter = new Completer<WebSocket>();
Completer? _completer;
_WebSocketConsumer(this.webSocket, this.socket);
void _onListen() {
_subscription?.cancel();
}
void _onPause() {
var subscription = _subscription;
if (subscription != null) {
subscription.pause();
} else {
_issuedPause = true;
}
}
void _onResume() {
var subscription = _subscription;
if (subscription != null) {
subscription.resume();
} else {
_issuedPause = false;
}
}
void _cancel() {
var subscription = _subscription;
if (subscription != null) {
_subscription = null;
subscription.cancel();
}
}
StreamController _ensureController() {
var controller = _controller;
if (controller != null) return controller;
controller = _controller = new StreamController(
sync: true,
onPause: _onPause,
onResume: _onResume,
onCancel: _onListen);
var stream = controller.stream
.transform(new _WebSocketOutgoingTransformer(webSocket));
socket.addStream(stream).then((_) {
_done();
_closeCompleter.complete(webSocket);
}, onError: (Object error, StackTrace stackTrace) {
_closed = true;
_cancel();
if (error is ArgumentError) {
if (!_done(error, stackTrace)) {
_closeCompleter.completeError(error, stackTrace);
}
} else {
_done();
_closeCompleter.complete(webSocket);
}
});
return controller;
}
bool _done([Object? error, StackTrace? stackTrace]) {
var completer = _completer;
if (completer == null) return false;
if (error != null) {
completer.completeError(error, stackTrace);
} else {
completer.complete(webSocket);
}
_completer = null;
return true;
}
Future addStream(Stream stream) {
if (_closed) {
stream.listen(null).cancel();
return new Future.value(webSocket);
}
_ensureController();
var completer = _completer = new Completer();
var subscription = _subscription = stream.listen((data) {
_controller!.add(data);
}, onDone: _done, onError: _done, cancelOnError: true);
if (_issuedPause) {
subscription.pause();
_issuedPause = false;
}
return completer.future;
}
Future close() {
_ensureController().close();
return _closeCompleter.future
.then((_) => socket.close().catchError((_) {}).then((_) => webSocket));
}
void add(data) {
if (_closed) return;
var controller = _ensureController();
// Stop sending message if _controller has been closed.
// https://github.com/dart-lang/sdk/issues/37441
if (controller.isClosed) return;
controller.add(data);
}
void closeSocket() {
_closed = true;
_cancel();
close();
}
}
class _WebSocketImpl extends Stream with _ServiceObject implements WebSocket {
// Use default Map so we keep order.
static Map<int, _WebSocketImpl> _webSockets = new Map<int, _WebSocketImpl>();
static const int DEFAULT_WINDOW_BITS = 15;
static const String PER_MESSAGE_DEFLATE = "permessage-deflate";
final String? protocol;
final StreamController _controller;
StreamSubscription? _subscription;
late StreamSink _sink;
final Socket _socket;
final bool _serverSide;
int _readyState = WebSocket.connecting;
bool _writeClosed = false;
int? _closeCode;
String? _closeReason;
Duration? _pingInterval;
Timer? _pingTimer;
late _WebSocketConsumer _consumer;
int? _outCloseCode;
String? _outCloseReason;
Timer? _closeTimer;
_WebSocketPerMessageDeflate? _deflate;
static final HttpClient _httpClient = new HttpClient();
static Future<WebSocket> connect(
String url, Iterable<String>? protocols, Map<String, dynamic>? headers,
{CompressionOptions compression =
CompressionOptions.compressionDefault}) {
Uri uri = Uri.parse(url);
if (uri.scheme != "ws" && uri.scheme != "wss") {
throw new WebSocketException("Unsupported URL scheme '${uri.scheme}'");
}
Random random = new Random();
// Generate 16 random bytes.
Uint8List nonceData = new Uint8List(16);
for (int i = 0; i < 16; i++) {
nonceData[i] = random.nextInt(256);
}
String nonce = _CryptoUtils.bytesToBase64(nonceData);
uri = new Uri(
scheme: uri.scheme == "wss" ? "https" : "http",
userInfo: uri.userInfo,
host: uri.host,
port: uri.port,
path: uri.path,
query: uri.query,
fragment: uri.fragment);
return _httpClient.openUrl("GET", uri).then((request) {
if (uri.userInfo != null && !uri.userInfo.isEmpty) {
// If the URL contains user information use that for basic
// authorization.
String auth = _CryptoUtils.bytesToBase64(utf8.encode(uri.userInfo));
request.headers.set(HttpHeaders.authorizationHeader, "Basic $auth");
}
if (headers != null) {
headers.forEach((field, value) => request.headers.add(field, value));
}
// Setup the initial handshake.
request.headers
..set(HttpHeaders.connectionHeader, "Upgrade")
..set(HttpHeaders.upgradeHeader, "websocket")
..set("Sec-WebSocket-Key", nonce)
..set("Cache-Control", "no-cache")
..set("Sec-WebSocket-Version", "13");
if (protocols != null) {
request.headers.add("Sec-WebSocket-Protocol", protocols.toList());
}
if (compression.enabled) {
request.headers
.add("Sec-WebSocket-Extensions", compression._createHeader());
}
return request.close();
}).then((response) {
Never error(String message) {
// Flush data.
response.detachSocket().then((socket) {
socket.destroy();
});
throw new WebSocketException(message);
}
var connectionHeader = response.headers[HttpHeaders.connectionHeader];
if (response.statusCode != HttpStatus.switchingProtocols ||
connectionHeader == null ||
!connectionHeader.any((value) => value.toLowerCase() == "upgrade") ||
response.headers.value(HttpHeaders.upgradeHeader)!.toLowerCase() !=
"websocket") {
error("Connection to '$uri' was not upgraded to websocket");
}
String? accept = response.headers.value("Sec-WebSocket-Accept");
if (accept == null) {
error("Response did not contain a 'Sec-WebSocket-Accept' header");
}
_SHA1 sha1 = new _SHA1();
sha1.add("$nonce$_webSocketGUID".codeUnits);
List<int> expectedAccept = sha1.close();
List<int> receivedAccept = _CryptoUtils.base64StringToBytes(accept);
if (expectedAccept.length != receivedAccept.length) {
error("Response header 'Sec-WebSocket-Accept' is the wrong length");
}
for (int i = 0; i < expectedAccept.length; i++) {
if (expectedAccept[i] != receivedAccept[i]) {
error("Bad response 'Sec-WebSocket-Accept' header");
}
}
var protocol = response.headers.value('Sec-WebSocket-Protocol');
_WebSocketPerMessageDeflate? deflate =
negotiateClientCompression(response, compression);
return response.detachSocket().then<WebSocket>((socket) =>
new _WebSocketImpl._fromSocket(
socket, protocol, compression, false, deflate));
});
}
static _WebSocketPerMessageDeflate? negotiateClientCompression(
HttpClientResponse response, CompressionOptions compression) {
String extensionHeader =
response.headers.value('Sec-WebSocket-Extensions') ?? "";
var hv = HeaderValue.parse(extensionHeader, valueSeparator: ',');
if (compression.enabled && hv.value == PER_MESSAGE_DEFLATE) {
var serverNoContextTakeover =
hv.parameters.containsKey(_serverNoContextTakeover);
var clientNoContextTakeover =
hv.parameters.containsKey(_clientNoContextTakeover);
int getWindowBits(String type) {
var o = hv.parameters[type];
if (o == null) {
return DEFAULT_WINDOW_BITS;
}
return int.tryParse(o) ?? DEFAULT_WINDOW_BITS;
}
return new _WebSocketPerMessageDeflate(
clientMaxWindowBits: getWindowBits(_clientMaxWindowBits),
serverMaxWindowBits: getWindowBits(_serverMaxWindowBits),
clientNoContextTakeover: clientNoContextTakeover,
serverNoContextTakeover: serverNoContextTakeover);
}
return null;
}
_WebSocketImpl._fromSocket(
this._socket, this.protocol, CompressionOptions compression,
[this._serverSide = false, _WebSocketPerMessageDeflate? deflate])
: _controller = new StreamController(sync: true) {
_consumer = new _WebSocketConsumer(this, _socket);
_sink = new _StreamSinkImpl(_consumer);
_readyState = WebSocket.open;
_deflate = deflate;
var transformer = new _WebSocketProtocolTransformer(_serverSide, deflate);
var subscription = _subscription = transformer.bind(_socket).listen((data) {
if (data is _WebSocketPing) {
if (!_writeClosed) _consumer.add(new _WebSocketPong(data.payload));
} else if (data is _WebSocketPong) {
// Simply set pingInterval, as it'll cancel any timers.
pingInterval = _pingInterval;
} else {
_controller.add(data);
}
}, onError: (Object error, StackTrace stackTrace) {
_closeTimer?.cancel();
if (error is FormatException) {
_close(WebSocketStatus.invalidFramePayloadData);
} else {
_close(WebSocketStatus.protocolError);
}
// An error happened, set the close code set above.
_closeCode = _outCloseCode;
_closeReason = _outCloseReason;
_controller.close();
}, onDone: () {
_closeTimer?.cancel();
if (_readyState == WebSocket.open) {
_readyState = WebSocket.closing;
if (!_isReservedStatusCode(transformer.closeCode)) {
_close(transformer.closeCode, transformer.closeReason);
} else {
_close();
}
_readyState = WebSocket.closed;
}
// Protocol close, use close code from transformer.
_closeCode = transformer.closeCode;
_closeReason = transformer.closeReason;
_controller.close();
}, cancelOnError: true);
subscription.pause();
_controller
..onListen = subscription.resume
..onCancel = () {
_subscription!.cancel();
_subscription = null;
}
..onPause = subscription.pause
..onResume = subscription.resume;
_webSockets[_serviceId] = this;
}
StreamSubscription listen(void onData(message)?,
{Function? onError, void onDone()?, bool? cancelOnError}) {
return _controller.stream.listen(onData,
onError: onError, onDone: onDone, cancelOnError: cancelOnError);
}
Duration? get pingInterval => _pingInterval;
void set pingInterval(Duration? interval) {
if (_writeClosed) return;
_pingTimer?.cancel();
_pingInterval = interval;
if (interval == null) return;
_pingTimer = new Timer(interval, () {
if (_writeClosed) return;
_consumer.add(new _WebSocketPing());
_pingTimer = new Timer(interval, () {
_closeTimer?.cancel();
// No pong received.
_close(WebSocketStatus.goingAway);
_closeCode = _outCloseCode;
_closeReason = _outCloseReason;
_controller.close();
});
});
}
int get readyState => _readyState;
String get extensions => "";
int? get closeCode => _closeCode;
String? get closeReason => _closeReason;
void add(data) {
_sink.add(data);
}
void addUtf8Text(List<int> bytes) {
// TODO(40614): Remove once non-nullability is sound.
ArgumentError.checkNotNull(bytes, "bytes");
_sink.add(new _EncodedString(bytes));
}
void addError(Object error, [StackTrace? stackTrace]) {
_sink.addError(error, stackTrace);
}
Future addStream(Stream stream) => _sink.addStream(stream);
Future get done => _sink.done;
Future close([int? code, String? reason]) {
if (_isReservedStatusCode(code)) {
throw new WebSocketException("Reserved status code $code");
}
if (_outCloseCode == null) {
_outCloseCode = code;
_outCloseReason = reason;
}
if (!_controller.isClosed) {
// If a close has not yet been received from the other end then
// 1) make sure to listen on the stream so the close frame will be
// processed if received.
// 2) set a timer terminate the connection if a close frame is
// not received.
if (!_controller.hasListener && _subscription != null) {
_controller.stream.drain().catchError((_) => {});
}
if (_closeTimer == null) {
// When closing the web-socket, we no longer accept data.
_closeTimer = new Timer(const Duration(seconds: 5), () {
// Reuse code and reason from the local close.
_closeCode = _outCloseCode;
_closeReason = _outCloseReason;
_subscription?.cancel();
_controller.close();
_webSockets.remove(_serviceId);
});
}
}
return _sink.close();
}
static String? get userAgent => _httpClient.userAgent;
static set userAgent(String? userAgent) {
_httpClient.userAgent = userAgent;
}
void _close([int? code, String? reason]) {
if (_writeClosed) return;
if (_outCloseCode == null) {
_outCloseCode = code;
_outCloseReason = reason;
}
_writeClosed = true;
_consumer.closeSocket();
_webSockets.remove(_serviceId);
}
String get _serviceTypePath => 'io/websockets';
String get _serviceTypeName => 'WebSocket';
Map<String, dynamic> _toJSON(bool ref) {
var name = '${_socket.address.host}:${_socket.port}';
var r = <String, dynamic>{
'id': _servicePath,
'type': _serviceType(ref),
'name': name,
'user_name': name,
};
if (ref) {
return r;
}
try {
r['socket'] = (_socket as dynamic)._toJSON(true);
} catch (_) {
r['socket'] = {
'id': _servicePath,
'type': '@Socket',
'name': 'UserSocket',
'user_name': 'UserSocket',
};
}
return r;
}
static bool _isReservedStatusCode(int? code) {
return code != null &&
(code < WebSocketStatus.normalClosure ||
code == WebSocketStatus.reserved1004 ||
code == WebSocketStatus.noStatusReceived ||
code == WebSocketStatus.abnormalClosure ||
(code > WebSocketStatus.internalServerError &&
code < WebSocketStatus.reserved1015) ||
(code >= WebSocketStatus.reserved1015 && code < 3000));
}
}