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420 lines
16 KiB
JavaScript

"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.MonitorInterval = exports.RTTPinger = exports.Monitor = void 0;
const timers_1 = require("timers");
const bson_1 = require("../bson");
const connect_1 = require("../cmap/connect");
const connection_1 = require("../cmap/connection");
const constants_1 = require("../constants");
const error_1 = require("../error");
const mongo_types_1 = require("../mongo_types");
const utils_1 = require("../utils");
const common_1 = require("./common");
const events_1 = require("./events");
const server_1 = require("./server");
/** @internal */
const kServer = Symbol('server');
/** @internal */
const kMonitorId = Symbol('monitorId');
/** @internal */
const kConnection = Symbol('connection');
/** @internal */
const kCancellationToken = Symbol('cancellationToken');
/** @internal */
const kRTTPinger = Symbol('rttPinger');
/** @internal */
const kRoundTripTime = Symbol('roundTripTime');
const STATE_IDLE = 'idle';
const STATE_MONITORING = 'monitoring';
const stateTransition = (0, utils_1.makeStateMachine)({
[common_1.STATE_CLOSING]: [common_1.STATE_CLOSING, STATE_IDLE, common_1.STATE_CLOSED],
[common_1.STATE_CLOSED]: [common_1.STATE_CLOSED, STATE_MONITORING],
[STATE_IDLE]: [STATE_IDLE, STATE_MONITORING, common_1.STATE_CLOSING],
[STATE_MONITORING]: [STATE_MONITORING, STATE_IDLE, common_1.STATE_CLOSING]
});
const INVALID_REQUEST_CHECK_STATES = new Set([common_1.STATE_CLOSING, common_1.STATE_CLOSED, STATE_MONITORING]);
function isInCloseState(monitor) {
return monitor.s.state === common_1.STATE_CLOSED || monitor.s.state === common_1.STATE_CLOSING;
}
/** @internal */
class Monitor extends mongo_types_1.TypedEventEmitter {
get connection() {
return this[kConnection];
}
constructor(server, options) {
super();
this[kServer] = server;
this[kConnection] = undefined;
this[kCancellationToken] = new mongo_types_1.CancellationToken();
this[kCancellationToken].setMaxListeners(Infinity);
this[kMonitorId] = undefined;
this.s = {
state: common_1.STATE_CLOSED
};
this.address = server.description.address;
this.options = Object.freeze({
connectTimeoutMS: options.connectTimeoutMS ?? 10000,
heartbeatFrequencyMS: options.heartbeatFrequencyMS ?? 10000,
minHeartbeatFrequencyMS: options.minHeartbeatFrequencyMS ?? 500
});
const cancellationToken = this[kCancellationToken];
// TODO: refactor this to pull it directly from the pool, requires new ConnectionPool integration
const connectOptions = Object.assign({
id: '<monitor>',
generation: server.pool.generation,
connectionType: connection_1.Connection,
cancellationToken,
hostAddress: server.description.hostAddress
}, options,
// force BSON serialization options
{
raw: false,
useBigInt64: false,
promoteLongs: true,
promoteValues: true,
promoteBuffers: true
});
// ensure no authentication is used for monitoring
delete connectOptions.credentials;
if (connectOptions.autoEncrypter) {
delete connectOptions.autoEncrypter;
}
this.connectOptions = Object.freeze(connectOptions);
}
connect() {
if (this.s.state !== common_1.STATE_CLOSED) {
return;
}
// start
const heartbeatFrequencyMS = this.options.heartbeatFrequencyMS;
const minHeartbeatFrequencyMS = this.options.minHeartbeatFrequencyMS;
this[kMonitorId] = new MonitorInterval(monitorServer(this), {
heartbeatFrequencyMS: heartbeatFrequencyMS,
minHeartbeatFrequencyMS: minHeartbeatFrequencyMS,
immediate: true
});
}
requestCheck() {
if (INVALID_REQUEST_CHECK_STATES.has(this.s.state)) {
return;
}
this[kMonitorId]?.wake();
}
reset() {
const topologyVersion = this[kServer].description.topologyVersion;
if (isInCloseState(this) || topologyVersion == null) {
return;
}
stateTransition(this, common_1.STATE_CLOSING);
resetMonitorState(this);
// restart monitor
stateTransition(this, STATE_IDLE);
// restart monitoring
const heartbeatFrequencyMS = this.options.heartbeatFrequencyMS;
const minHeartbeatFrequencyMS = this.options.minHeartbeatFrequencyMS;
this[kMonitorId] = new MonitorInterval(monitorServer(this), {
heartbeatFrequencyMS: heartbeatFrequencyMS,
minHeartbeatFrequencyMS: minHeartbeatFrequencyMS
});
}
close() {
if (isInCloseState(this)) {
return;
}
stateTransition(this, common_1.STATE_CLOSING);
resetMonitorState(this);
// close monitor
this.emit('close');
stateTransition(this, common_1.STATE_CLOSED);
}
}
exports.Monitor = Monitor;
function resetMonitorState(monitor) {
monitor[kMonitorId]?.stop();
monitor[kMonitorId] = undefined;
monitor[kRTTPinger]?.close();
monitor[kRTTPinger] = undefined;
monitor[kCancellationToken].emit('cancel');
monitor[kConnection]?.destroy({ force: true });
monitor[kConnection] = undefined;
}
function checkServer(monitor, callback) {
let start = (0, utils_1.now)();
const topologyVersion = monitor[kServer].description.topologyVersion;
const isAwaitable = topologyVersion != null;
monitor.emit(server_1.Server.SERVER_HEARTBEAT_STARTED, new events_1.ServerHeartbeatStartedEvent(monitor.address, isAwaitable));
function failureHandler(err) {
monitor[kConnection]?.destroy({ force: true });
monitor[kConnection] = undefined;
monitor.emit(server_1.Server.SERVER_HEARTBEAT_FAILED, new events_1.ServerHeartbeatFailedEvent(monitor.address, (0, utils_1.calculateDurationInMs)(start), err, isAwaitable));
const error = !(err instanceof error_1.MongoError)
? new error_1.MongoError(error_1.MongoError.buildErrorMessage(err), { cause: err })
: err;
error.addErrorLabel(error_1.MongoErrorLabel.ResetPool);
if (error instanceof error_1.MongoNetworkTimeoutError) {
error.addErrorLabel(error_1.MongoErrorLabel.InterruptInUseConnections);
}
monitor.emit('resetServer', error);
callback(err);
}
const connection = monitor[kConnection];
if (connection && !connection.closed) {
const { serverApi, helloOk } = connection;
const connectTimeoutMS = monitor.options.connectTimeoutMS;
const maxAwaitTimeMS = monitor.options.heartbeatFrequencyMS;
const cmd = {
[serverApi?.version || helloOk ? 'hello' : constants_1.LEGACY_HELLO_COMMAND]: 1,
...(isAwaitable && topologyVersion
? { maxAwaitTimeMS, topologyVersion: makeTopologyVersion(topologyVersion) }
: {})
};
const options = isAwaitable
? {
socketTimeoutMS: connectTimeoutMS ? connectTimeoutMS + maxAwaitTimeMS : 0,
exhaustAllowed: true
}
: { socketTimeoutMS: connectTimeoutMS };
if (isAwaitable && monitor[kRTTPinger] == null) {
monitor[kRTTPinger] = new RTTPinger(monitor[kCancellationToken], Object.assign({ heartbeatFrequencyMS: monitor.options.heartbeatFrequencyMS }, monitor.connectOptions));
}
connection.command((0, utils_1.ns)('admin.$cmd'), cmd, options, (err, hello) => {
if (err) {
return failureHandler(err);
}
if (!('isWritablePrimary' in hello)) {
// Provide hello-style response document.
hello.isWritablePrimary = hello[constants_1.LEGACY_HELLO_COMMAND];
}
const rttPinger = monitor[kRTTPinger];
const duration = isAwaitable && rttPinger ? rttPinger.roundTripTime : (0, utils_1.calculateDurationInMs)(start);
const awaited = isAwaitable && hello.topologyVersion != null;
monitor.emit(server_1.Server.SERVER_HEARTBEAT_SUCCEEDED, new events_1.ServerHeartbeatSucceededEvent(monitor.address, duration, hello, awaited));
// if we are using the streaming protocol then we immediately issue another `started`
// event, otherwise the "check" is complete and return to the main monitor loop
if (awaited) {
monitor.emit(server_1.Server.SERVER_HEARTBEAT_STARTED, new events_1.ServerHeartbeatStartedEvent(monitor.address, true));
start = (0, utils_1.now)();
}
else {
monitor[kRTTPinger]?.close();
monitor[kRTTPinger] = undefined;
callback(undefined, hello);
}
});
return;
}
// connecting does an implicit `hello`
(0, connect_1.connect)(monitor.connectOptions, (err, conn) => {
if (err) {
monitor[kConnection] = undefined;
failureHandler(err);
return;
}
if (conn) {
// Tell the connection that we are using the streaming protocol so that the
// connection's message stream will only read the last hello on the buffer.
conn.isMonitoringConnection = true;
if (isInCloseState(monitor)) {
conn.destroy({ force: true });
return;
}
monitor[kConnection] = conn;
monitor.emit(server_1.Server.SERVER_HEARTBEAT_SUCCEEDED, new events_1.ServerHeartbeatSucceededEvent(monitor.address, (0, utils_1.calculateDurationInMs)(start), conn.hello, false));
callback(undefined, conn.hello);
}
});
}
function monitorServer(monitor) {
return (callback) => {
if (monitor.s.state === STATE_MONITORING) {
process.nextTick(callback);
return;
}
stateTransition(monitor, STATE_MONITORING);
function done() {
if (!isInCloseState(monitor)) {
stateTransition(monitor, STATE_IDLE);
}
callback();
}
checkServer(monitor, (err, hello) => {
if (err) {
// otherwise an error occurred on initial discovery, also bail
if (monitor[kServer].description.type === common_1.ServerType.Unknown) {
return done();
}
}
// if the check indicates streaming is supported, immediately reschedule monitoring
if (hello && hello.topologyVersion) {
(0, timers_1.setTimeout)(() => {
if (!isInCloseState(monitor)) {
monitor[kMonitorId]?.wake();
}
}, 0);
}
done();
});
};
}
function makeTopologyVersion(tv) {
return {
processId: tv.processId,
// tests mock counter as just number, but in a real situation counter should always be a Long
// TODO(NODE-2674): Preserve int64 sent from MongoDB
counter: bson_1.Long.isLong(tv.counter) ? tv.counter : bson_1.Long.fromNumber(tv.counter)
};
}
/** @internal */
class RTTPinger {
constructor(cancellationToken, options) {
this[kConnection] = undefined;
this[kCancellationToken] = cancellationToken;
this[kRoundTripTime] = 0;
this.closed = false;
const heartbeatFrequencyMS = options.heartbeatFrequencyMS;
this[kMonitorId] = (0, timers_1.setTimeout)(() => measureRoundTripTime(this, options), heartbeatFrequencyMS);
}
get roundTripTime() {
return this[kRoundTripTime];
}
close() {
this.closed = true;
(0, timers_1.clearTimeout)(this[kMonitorId]);
this[kConnection]?.destroy({ force: true });
this[kConnection] = undefined;
}
}
exports.RTTPinger = RTTPinger;
function measureRoundTripTime(rttPinger, options) {
const start = (0, utils_1.now)();
options.cancellationToken = rttPinger[kCancellationToken];
const heartbeatFrequencyMS = options.heartbeatFrequencyMS;
if (rttPinger.closed) {
return;
}
function measureAndReschedule(conn) {
if (rttPinger.closed) {
conn?.destroy({ force: true });
return;
}
if (rttPinger[kConnection] == null) {
rttPinger[kConnection] = conn;
}
rttPinger[kRoundTripTime] = (0, utils_1.calculateDurationInMs)(start);
rttPinger[kMonitorId] = (0, timers_1.setTimeout)(() => measureRoundTripTime(rttPinger, options), heartbeatFrequencyMS);
}
const connection = rttPinger[kConnection];
if (connection == null) {
(0, connect_1.connect)(options, (err, conn) => {
if (err) {
rttPinger[kConnection] = undefined;
rttPinger[kRoundTripTime] = 0;
return;
}
measureAndReschedule(conn);
});
return;
}
connection.command((0, utils_1.ns)('admin.$cmd'), { [constants_1.LEGACY_HELLO_COMMAND]: 1 }, undefined, err => {
if (err) {
rttPinger[kConnection] = undefined;
rttPinger[kRoundTripTime] = 0;
return;
}
measureAndReschedule();
});
}
/**
* @internal
*/
class MonitorInterval {
constructor(fn, options = {}) {
this.isExpeditedCallToFnScheduled = false;
this.stopped = false;
this.isExecutionInProgress = false;
this.hasExecutedOnce = false;
this._executeAndReschedule = () => {
if (this.stopped)
return;
if (this.timerId) {
(0, timers_1.clearTimeout)(this.timerId);
}
this.isExpeditedCallToFnScheduled = false;
this.isExecutionInProgress = true;
this.fn(() => {
this.lastExecutionEnded = (0, utils_1.now)();
this.isExecutionInProgress = false;
this._reschedule(this.heartbeatFrequencyMS);
});
};
this.fn = fn;
this.lastExecutionEnded = -Infinity;
this.heartbeatFrequencyMS = options.heartbeatFrequencyMS ?? 1000;
this.minHeartbeatFrequencyMS = options.minHeartbeatFrequencyMS ?? 500;
if (options.immediate) {
this._executeAndReschedule();
}
else {
this._reschedule(undefined);
}
}
wake() {
const currentTime = (0, utils_1.now)();
const timeSinceLastCall = currentTime - this.lastExecutionEnded;
// TODO(NODE-4674): Add error handling and logging to the monitor
if (timeSinceLastCall < 0) {
return this._executeAndReschedule();
}
if (this.isExecutionInProgress) {
return;
}
// debounce multiple calls to wake within the `minInterval`
if (this.isExpeditedCallToFnScheduled) {
return;
}
// reschedule a call as soon as possible, ensuring the call never happens
// faster than the `minInterval`
if (timeSinceLastCall < this.minHeartbeatFrequencyMS) {
this.isExpeditedCallToFnScheduled = true;
this._reschedule(this.minHeartbeatFrequencyMS - timeSinceLastCall);
return;
}
this._executeAndReschedule();
}
stop() {
this.stopped = true;
if (this.timerId) {
(0, timers_1.clearTimeout)(this.timerId);
this.timerId = undefined;
}
this.lastExecutionEnded = -Infinity;
this.isExpeditedCallToFnScheduled = false;
}
toString() {
return JSON.stringify(this);
}
toJSON() {
const currentTime = (0, utils_1.now)();
const timeSinceLastCall = currentTime - this.lastExecutionEnded;
return {
timerId: this.timerId != null ? 'set' : 'cleared',
lastCallTime: this.lastExecutionEnded,
isExpeditedCheckScheduled: this.isExpeditedCallToFnScheduled,
stopped: this.stopped,
heartbeatFrequencyMS: this.heartbeatFrequencyMS,
minHeartbeatFrequencyMS: this.minHeartbeatFrequencyMS,
currentTime,
timeSinceLastCall
};
}
_reschedule(ms) {
if (this.stopped)
return;
if (this.timerId) {
(0, timers_1.clearTimeout)(this.timerId);
}
this.timerId = (0, timers_1.setTimeout)(this._executeAndReschedule, ms || this.heartbeatFrequencyMS);
}
}
exports.MonitorInterval = MonitorInterval;
//# sourceMappingURL=monitor.js.map