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nodejs/lib/perf_hooks.js
Michaël Zasso 1182539307
perf_hooks: fix error message for invalid entryTypes
Will now print a more meaningful value instead of always [object Object]

PR-URL: https://github.com/nodejs/node/pull/33285
Reviewed-By: James M Snell <jasnell@gmail.com>
Reviewed-By: Colin Ihrig <cjihrig@gmail.com>
Reviewed-By: Anna Henningsen <anna@addaleax.net>
Reviewed-By: Chengzhong Wu <legendecas@gmail.com>
Reviewed-By: Luigi Pinca <luigipinca@gmail.com>
2020-05-10 13:53:15 +02:00

595 lines
15 KiB
JavaScript

'use strict';
const {
ArrayIsArray,
Boolean,
NumberIsSafeInteger,
ObjectDefineProperties,
ObjectDefineProperty,
ObjectKeys,
Set,
Symbol,
} = primordials;
const {
ELDHistogram: _ELDHistogram,
PerformanceEntry,
mark: _mark,
clearMark: _clearMark,
measure: _measure,
milestones,
observerCounts,
setupObservers,
timeOrigin,
timeOriginTimestamp,
timerify,
constants,
installGarbageCollectionTracking,
removeGarbageCollectionTracking
} = internalBinding('performance');
const {
NODE_PERFORMANCE_ENTRY_TYPE_NODE,
NODE_PERFORMANCE_ENTRY_TYPE_MARK,
NODE_PERFORMANCE_ENTRY_TYPE_MEASURE,
NODE_PERFORMANCE_ENTRY_TYPE_GC,
NODE_PERFORMANCE_ENTRY_TYPE_FUNCTION,
NODE_PERFORMANCE_ENTRY_TYPE_HTTP2,
NODE_PERFORMANCE_ENTRY_TYPE_HTTP,
NODE_PERFORMANCE_MILESTONE_NODE_START,
NODE_PERFORMANCE_MILESTONE_V8_START,
NODE_PERFORMANCE_MILESTONE_LOOP_START,
NODE_PERFORMANCE_MILESTONE_LOOP_EXIT,
NODE_PERFORMANCE_MILESTONE_BOOTSTRAP_COMPLETE,
NODE_PERFORMANCE_MILESTONE_ENVIRONMENT
} = constants;
const { AsyncResource } = require('async_hooks');
const L = require('internal/linkedlist');
const kInspect = require('internal/util').customInspectSymbol;
const {
ERR_INVALID_CALLBACK,
ERR_INVALID_ARG_TYPE,
ERR_INVALID_OPT_VALUE,
ERR_VALID_PERFORMANCE_ENTRY_TYPE,
ERR_INVALID_PERFORMANCE_MARK
} = require('internal/errors').codes;
const {
Histogram,
kHandle,
} = require('internal/histogram');
const { setImmediate } = require('timers');
const kCallback = Symbol('callback');
const kTypes = Symbol('types');
const kEntries = Symbol('entries');
const kBuffer = Symbol('buffer');
const kBuffering = Symbol('buffering');
const kQueued = Symbol('queued');
const kTimerified = Symbol('timerified');
const kInsertEntry = Symbol('insert-entry');
const kGetEntries = Symbol('get-entries');
const kIndex = Symbol('index');
const kMarks = Symbol('marks');
const kCount = Symbol('count');
const observers = {};
const observerableTypes = [
'node',
'mark',
'measure',
'gc',
'function',
'http2',
'http'
];
const IDX_STREAM_STATS_ID = 0;
const IDX_STREAM_STATS_TIMETOFIRSTBYTE = 1;
const IDX_STREAM_STATS_TIMETOFIRSTHEADER = 2;
const IDX_STREAM_STATS_TIMETOFIRSTBYTESENT = 3;
const IDX_STREAM_STATS_SENTBYTES = 4;
const IDX_STREAM_STATS_RECEIVEDBYTES = 5;
const IDX_SESSION_STATS_TYPE = 0;
const IDX_SESSION_STATS_PINGRTT = 1;
const IDX_SESSION_STATS_FRAMESRECEIVED = 2;
const IDX_SESSION_STATS_FRAMESSENT = 3;
const IDX_SESSION_STATS_STREAMCOUNT = 4;
const IDX_SESSION_STATS_STREAMAVERAGEDURATION = 5;
const IDX_SESSION_STATS_DATA_SENT = 6;
const IDX_SESSION_STATS_DATA_RECEIVED = 7;
const IDX_SESSION_STATS_MAX_CONCURRENT_STREAMS = 8;
let http2;
let sessionStats;
let streamStats;
function collectHttp2Stats(entry) {
if (http2 === undefined) http2 = internalBinding('http2');
switch (entry.name) {
case 'Http2Stream':
if (streamStats === undefined)
streamStats = http2.streamStats;
entry.id =
streamStats[IDX_STREAM_STATS_ID] >>> 0;
entry.timeToFirstByte =
streamStats[IDX_STREAM_STATS_TIMETOFIRSTBYTE];
entry.timeToFirstHeader =
streamStats[IDX_STREAM_STATS_TIMETOFIRSTHEADER];
entry.timeToFirstByteSent =
streamStats[IDX_STREAM_STATS_TIMETOFIRSTBYTESENT];
entry.bytesWritten =
streamStats[IDX_STREAM_STATS_SENTBYTES];
entry.bytesRead =
streamStats[IDX_STREAM_STATS_RECEIVEDBYTES];
break;
case 'Http2Session':
if (sessionStats === undefined)
sessionStats = http2.sessionStats;
entry.type =
sessionStats[IDX_SESSION_STATS_TYPE] >>> 0 === 0 ? 'server' : 'client';
entry.pingRTT =
sessionStats[IDX_SESSION_STATS_PINGRTT];
entry.framesReceived =
sessionStats[IDX_SESSION_STATS_FRAMESRECEIVED];
entry.framesSent =
sessionStats[IDX_SESSION_STATS_FRAMESSENT];
entry.streamCount =
sessionStats[IDX_SESSION_STATS_STREAMCOUNT];
entry.streamAverageDuration =
sessionStats[IDX_SESSION_STATS_STREAMAVERAGEDURATION];
entry.bytesWritten =
sessionStats[IDX_SESSION_STATS_DATA_SENT];
entry.bytesRead =
sessionStats[IDX_SESSION_STATS_DATA_RECEIVED];
entry.maxConcurrentStreams =
sessionStats[IDX_SESSION_STATS_MAX_CONCURRENT_STREAMS];
break;
}
}
function now() {
const hr = process.hrtime();
return hr[0] * 1000 + hr[1] / 1e6;
}
function getMilestoneTimestamp(milestoneIdx) {
const ns = milestones[milestoneIdx];
if (ns === -1)
return ns;
return ns / 1e6 - timeOrigin;
}
class PerformanceNodeTiming extends PerformanceEntry {
get name() {
return 'node';
}
get entryType() {
return 'node';
}
get startTime() {
return 0;
}
get duration() {
return now() - timeOrigin;
}
get nodeStart() {
return getMilestoneTimestamp(NODE_PERFORMANCE_MILESTONE_NODE_START);
}
get v8Start() {
return getMilestoneTimestamp(NODE_PERFORMANCE_MILESTONE_V8_START);
}
get environment() {
return getMilestoneTimestamp(NODE_PERFORMANCE_MILESTONE_ENVIRONMENT);
}
get loopStart() {
return getMilestoneTimestamp(NODE_PERFORMANCE_MILESTONE_LOOP_START);
}
get loopExit() {
return getMilestoneTimestamp(NODE_PERFORMANCE_MILESTONE_LOOP_EXIT);
}
get bootstrapComplete() {
return getMilestoneTimestamp(NODE_PERFORMANCE_MILESTONE_BOOTSTRAP_COMPLETE);
}
[kInspect]() {
return {
name: 'node',
entryType: 'node',
startTime: this.startTime,
duration: this.duration,
nodeStart: this.nodeStart,
v8Start: this.v8Start,
bootstrapComplete: this.bootstrapComplete,
environment: this.environment,
loopStart: this.loopStart,
loopExit: this.loopExit
};
}
}
const nodeTiming = new PerformanceNodeTiming();
// Maintains a list of entries as a linked list stored in insertion order.
class PerformanceObserverEntryList {
constructor() {
ObjectDefineProperties(this, {
[kEntries]: {
writable: true,
enumerable: false,
value: {}
},
[kCount]: {
writable: true,
enumerable: false,
value: 0
}
});
L.init(this[kEntries]);
}
[kInsertEntry](entry) {
const item = { entry };
L.append(this[kEntries], item);
this[kCount]++;
}
get length() {
return this[kCount];
}
[kGetEntries](name, type) {
const ret = [];
const list = this[kEntries];
if (!L.isEmpty(list)) {
let item = L.peek(list);
while (item && item !== list) {
const entry = item.entry;
if ((name && entry.name !== name) ||
(type && entry.entryType !== type)) {
item = item._idlePrev;
continue;
}
sortedInsert(ret, entry);
item = item._idlePrev;
}
}
return ret;
}
// While the items are stored in insertion order, getEntries() is
// required to return items sorted by startTime.
getEntries() {
return this[kGetEntries]();
}
getEntriesByType(type) {
return this[kGetEntries](undefined, `${type}`);
}
getEntriesByName(name, type) {
return this[kGetEntries](`${name}`, type !== undefined ? `${type}` : type);
}
}
class PerformanceObserver extends AsyncResource {
constructor(callback) {
if (typeof callback !== 'function') {
throw new ERR_INVALID_CALLBACK(callback);
}
super('PerformanceObserver');
ObjectDefineProperties(this, {
[kTypes]: {
enumerable: false,
writable: true,
value: {}
},
[kCallback]: {
enumerable: false,
writable: true,
value: callback
},
[kBuffer]: {
enumerable: false,
writable: true,
value: new PerformanceObserverEntryList()
},
[kBuffering]: {
enumerable: false,
writable: true,
value: false
},
[kQueued]: {
enumerable: false,
writable: true,
value: false
}
});
}
disconnect() {
const observerCountsGC = observerCounts[NODE_PERFORMANCE_ENTRY_TYPE_GC];
const types = this[kTypes];
for (const key of ObjectKeys(types)) {
const item = types[key];
if (item) {
L.remove(item);
observerCounts[key]--;
}
}
this[kTypes] = {};
if (observerCountsGC === 1 &&
observerCounts[NODE_PERFORMANCE_ENTRY_TYPE_GC] === 0) {
removeGarbageCollectionTracking();
}
}
observe(options) {
if (typeof options !== 'object' || options === null) {
throw new ERR_INVALID_ARG_TYPE('options', 'Object', options);
}
const { entryTypes } = options;
if (!ArrayIsArray(entryTypes)) {
throw new ERR_INVALID_OPT_VALUE('entryTypes', entryTypes);
}
const filteredEntryTypes = entryTypes.filter(filterTypes).map(mapTypes);
if (filteredEntryTypes.length === 0) {
throw new ERR_VALID_PERFORMANCE_ENTRY_TYPE();
}
this.disconnect();
const observerCountsGC = observerCounts[NODE_PERFORMANCE_ENTRY_TYPE_GC];
this[kBuffer][kEntries] = [];
L.init(this[kBuffer][kEntries]);
this[kBuffering] = Boolean(options.buffered);
for (const entryType of filteredEntryTypes) {
const list = getObserversList(entryType);
if (this[kTypes][entryType]) continue;
const item = { obs: this };
this[kTypes][entryType] = item;
L.append(list, item);
observerCounts[entryType]++;
}
if (observerCountsGC === 0 &&
observerCounts[NODE_PERFORMANCE_ENTRY_TYPE_GC] === 1) {
installGarbageCollectionTracking();
}
}
}
class Performance {
constructor() {
this[kIndex] = {
[kMarks]: new Set()
};
}
get nodeTiming() {
return nodeTiming;
}
get timeOrigin() {
return timeOriginTimestamp;
}
now() {
return now() - timeOrigin;
}
mark(name) {
name = `${name}`;
_mark(name);
this[kIndex][kMarks].add(name);
}
measure(name, startMark, endMark) {
name = `${name}`;
const marks = this[kIndex][kMarks];
if (arguments.length >= 3) {
if (!marks.has(endMark) && !(endMark in nodeTiming))
throw new ERR_INVALID_PERFORMANCE_MARK(endMark);
else
endMark = `${endMark}`;
}
startMark = startMark !== undefined ? `${startMark}` : '';
_measure(name, startMark, endMark);
}
clearMarks(name) {
if (name !== undefined) {
name = `${name}`;
this[kIndex][kMarks].delete(name);
_clearMark(name);
} else {
this[kIndex][kMarks].clear();
_clearMark();
}
}
timerify(fn) {
if (typeof fn !== 'function') {
throw new ERR_INVALID_ARG_TYPE('fn', 'Function', fn);
}
if (fn[kTimerified])
return fn[kTimerified];
const ret = timerify(fn, fn.length);
ObjectDefineProperty(fn, kTimerified, {
enumerable: false,
configurable: true,
writable: false,
value: ret
});
ObjectDefineProperties(ret, {
[kTimerified]: {
enumerable: false,
configurable: true,
writable: false,
value: ret
},
name: {
enumerable: false,
configurable: true,
writable: false,
value: `timerified ${fn.name}`
}
});
return ret;
}
[kInspect]() {
return {
nodeTiming: this.nodeTiming,
timeOrigin: this.timeOrigin
};
}
}
const performance = new Performance();
function getObserversList(type) {
let list = observers[type];
if (list === undefined) {
list = observers[type] = {};
L.init(list);
}
return list;
}
function doNotify(observer) {
observer[kQueued] = false;
observer.runInAsyncScope(observer[kCallback],
observer,
observer[kBuffer],
observer);
observer[kBuffer][kEntries] = [];
L.init(observer[kBuffer][kEntries]);
}
// Set up the callback used to receive PerformanceObserver notifications
function observersCallback(entry) {
const type = mapTypes(entry.entryType);
if (type === NODE_PERFORMANCE_ENTRY_TYPE_HTTP2)
collectHttp2Stats(entry);
const list = getObserversList(type);
let current = L.peek(list);
while (current && current.obs) {
const observer = current.obs;
// First, add the item to the observers buffer
const buffer = observer[kBuffer];
buffer[kInsertEntry](entry);
// Second, check to see if we're buffering
if (observer[kBuffering]) {
// If we are, schedule a setImmediate call if one hasn't already
if (!observer[kQueued]) {
observer[kQueued] = true;
// Use setImmediate instead of nextTick to give more time
// for multiple entries to collect.
setImmediate(doNotify, observer);
}
} else {
// If not buffering, notify immediately
doNotify(observer);
}
current = current._idlePrev;
}
}
setupObservers(observersCallback);
function filterTypes(i) {
return observerableTypes.indexOf(`${i}`) >= 0;
}
function mapTypes(i) {
switch (i) {
case 'node': return NODE_PERFORMANCE_ENTRY_TYPE_NODE;
case 'mark': return NODE_PERFORMANCE_ENTRY_TYPE_MARK;
case 'measure': return NODE_PERFORMANCE_ENTRY_TYPE_MEASURE;
case 'gc': return NODE_PERFORMANCE_ENTRY_TYPE_GC;
case 'function': return NODE_PERFORMANCE_ENTRY_TYPE_FUNCTION;
case 'http2': return NODE_PERFORMANCE_ENTRY_TYPE_HTTP2;
case 'http': return NODE_PERFORMANCE_ENTRY_TYPE_HTTP;
}
}
// The specification requires that PerformanceEntry instances are sorted
// according to startTime. Unfortunately, they are not necessarily created
// in that same order, and can be reported to the JS layer in any order,
// which means we need to keep the list sorted as we insert.
function getInsertLocation(list, entryStartTime) {
let start = 0;
let end = list.length;
while (start < end) {
const pivot = (end + start) >>> 1;
if (list[pivot].startTime === entryStartTime)
return pivot;
if (list[pivot].startTime < entryStartTime)
start = pivot + 1;
else
end = pivot;
}
return start;
}
function sortedInsert(list, entry) {
const entryStartTime = entry.startTime;
if (list.length === 0 ||
(list[list.length - 1].startTime < entryStartTime)) {
list.push(entry);
return;
}
if (list[0] && (list[0].startTime > entryStartTime)) {
list.unshift(entry);
return;
}
const location = getInsertLocation(list, entryStartTime);
list.splice(location, 0, entry);
}
class ELDHistogram extends Histogram {
enable() { return this[kHandle].enable(); }
disable() { return this[kHandle].disable(); }
}
function monitorEventLoopDelay(options = {}) {
if (typeof options !== 'object' || options === null) {
throw new ERR_INVALID_ARG_TYPE('options', 'Object', options);
}
const { resolution = 10 } = options;
if (typeof resolution !== 'number') {
throw new ERR_INVALID_ARG_TYPE('options.resolution',
'number', resolution);
}
if (resolution <= 0 || !NumberIsSafeInteger(resolution)) {
throw new ERR_INVALID_OPT_VALUE.RangeError('resolution', resolution);
}
return new ELDHistogram(new _ELDHistogram(resolution));
}
module.exports = {
performance,
PerformanceObserver,
monitorEventLoopDelay
};
ObjectDefineProperty(module.exports, 'constants', {
configurable: false,
enumerable: true,
value: constants
});